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gfiber / kernel / prism / eb337a3e45e3427d54459adefc4d5d665ad7de87 / . / drivers / staging / rt3090 / common / cmm_tkip.c
blob: 0b474f20859bde5b08ceda190b8650672bb3b43e [file] [log] [blame]
/*
*************************************************************************
* Ralink Tech Inc.
* 5F., No.36, Taiyuan St., Jhubei City,
* Hsinchu County 302,
* Taiwan, R.O.C.
*
* (c) Copyright 2002-2007, Ralink Technology, Inc.
*
* 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 *
* (at your option) 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., *
* 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
* *
*************************************************************************
Module Name:
cmm_tkip.c
Abstract:
Revision History:
Who When What
-------- ---------- ----------------------------------------------
Paul Wu 02-25-02 Initial
*/
#include "../rt_config.h"
// Rotation functions on 32 bit values
#define ROL32( A, n ) \
( ((A) << (n)) | ( ((A)>>(32-(n))) & ( (1UL << (n)) - 1 ) ) )
#define ROR32( A, n ) ROL32( (A), 32-(n) )
UINT Tkip_Sbox_Lower[256] =
{
0xA5,0x84,0x99,0x8D,0x0D,0xBD,0xB1,0x54,
0x50,0x03,0xA9,0x7D,0x19,0x62,0xE6,0x9A,
0x45,0x9D,0x40,0x87,0x15,0xEB,0xC9,0x0B,
0xEC,0x67,0xFD,0xEA,0xBF,0xF7,0x96,0x5B,
0xC2,0x1C,0xAE,0x6A,0x5A,0x41,0x02,0x4F,
0x5C,0xF4,0x34,0x08,0x93,0x73,0x53,0x3F,
0x0C,0x52,0x65,0x5E,0x28,0xA1,0x0F,0xB5,
0x09,0x36,0x9B,0x3D,0x26,0x69,0xCD,0x9F,
0x1B,0x9E,0x74,0x2E,0x2D,0xB2,0xEE,0xFB,
0xF6,0x4D,0x61,0xCE,0x7B,0x3E,0x71,0x97,
0xF5,0x68,0x00,0x2C,0x60,0x1F,0xC8,0xED,
0xBE,0x46,0xD9,0x4B,0xDE,0xD4,0xE8,0x4A,
0x6B,0x2A,0xE5,0x16,0xC5,0xD7,0x55,0x94,
0xCF,0x10,0x06,0x81,0xF0,0x44,0xBA,0xE3,
0xF3,0xFE,0xC0,0x8A,0xAD,0xBC,0x48,0x04,
0xDF,0xC1,0x75,0x63,0x30,0x1A,0x0E,0x6D,
0x4C,0x14,0x35,0x2F,0xE1,0xA2,0xCC,0x39,
0x57,0xF2,0x82,0x47,0xAC,0xE7,0x2B,0x95,
0xA0,0x98,0xD1,0x7F,0x66,0x7E,0xAB,0x83,
0xCA,0x29,0xD3,0x3C,0x79,0xE2,0x1D,0x76,
0x3B,0x56,0x4E,0x1E,0xDB,0x0A,0x6C,0xE4,
0x5D,0x6E,0xEF,0xA6,0xA8,0xA4,0x37,0x8B,
0x32,0x43,0x59,0xB7,0x8C,0x64,0xD2,0xE0,
0xB4,0xFA,0x07,0x25,0xAF,0x8E,0xE9,0x18,
0xD5,0x88,0x6F,0x72,0x24,0xF1,0xC7,0x51,
0x23,0x7C,0x9C,0x21,0xDD,0xDC,0x86,0x85,
0x90,0x42,0xC4,0xAA,0xD8,0x05,0x01,0x12,
0xA3,0x5F,0xF9,0xD0,0x91,0x58,0x27,0xB9,
0x38,0x13,0xB3,0x33,0xBB,0x70,0x89,0xA7,
0xB6,0x22,0x92,0x20,0x49,0xFF,0x78,0x7A,
0x8F,0xF8,0x80,0x17,0xDA,0x31,0xC6,0xB8,
0xC3,0xB0,0x77,0x11,0xCB,0xFC,0xD6,0x3A
};
UINT Tkip_Sbox_Upper[256] =
{
0xC6,0xF8,0xEE,0xF6,0xFF,0xD6,0xDE,0x91,
0x60,0x02,0xCE,0x56,0xE7,0xB5,0x4D,0xEC,
0x8F,0x1F,0x89,0xFA,0xEF,0xB2,0x8E,0xFB,
0x41,0xB3,0x5F,0x45,0x23,0x53,0xE4,0x9B,
0x75,0xE1,0x3D,0x4C,0x6C,0x7E,0xF5,0x83,
0x68,0x51,0xD1,0xF9,0xE2,0xAB,0x62,0x2A,
0x08,0x95,0x46,0x9D,0x30,0x37,0x0A,0x2F,
0x0E,0x24,0x1B,0xDF,0xCD,0x4E,0x7F,0xEA,
0x12,0x1D,0x58,0x34,0x36,0xDC,0xB4,0x5B,
0xA4,0x76,0xB7,0x7D,0x52,0xDD,0x5E,0x13,
0xA6,0xB9,0x00,0xC1,0x40,0xE3,0x79,0xB6,
0xD4,0x8D,0x67,0x72,0x94,0x98,0xB0,0x85,
0xBB,0xC5,0x4F,0xED,0x86,0x9A,0x66,0x11,
0x8A,0xE9,0x04,0xFE,0xA0,0x78,0x25,0x4B,
0xA2,0x5D,0x80,0x05,0x3F,0x21,0x70,0xF1,
0x63,0x77,0xAF,0x42,0x20,0xE5,0xFD,0xBF,
0x81,0x18,0x26,0xC3,0xBE,0x35,0x88,0x2E,
0x93,0x55,0xFC,0x7A,0xC8,0xBA,0x32,0xE6,
0xC0,0x19,0x9E,0xA3,0x44,0x54,0x3B,0x0B,
0x8C,0xC7,0x6B,0x28,0xA7,0xBC,0x16,0xAD,
0xDB,0x64,0x74,0x14,0x92,0x0C,0x48,0xB8,
0x9F,0xBD,0x43,0xC4,0x39,0x31,0xD3,0xF2,
0xD5,0x8B,0x6E,0xDA,0x01,0xB1,0x9C,0x49,
0xD8,0xAC,0xF3,0xCF,0xCA,0xF4,0x47,0x10,
0x6F,0xF0,0x4A,0x5C,0x38,0x57,0x73,0x97,
0xCB,0xA1,0xE8,0x3E,0x96,0x61,0x0D,0x0F,
0xE0,0x7C,0x71,0xCC,0x90,0x06,0xF7,0x1C,
0xC2,0x6A,0xAE,0x69,0x17,0x99,0x3A,0x27,
0xD9,0xEB,0x2B,0x22,0xD2,0xA9,0x07,0x33,
0x2D,0x3C,0x15,0xC9,0x87,0xAA,0x50,0xA5,
0x03,0x59,0x09,0x1A,0x65,0xD7,0x84,0xD0,
0x82,0x29,0x5A,0x1E,0x7B,0xA8,0x6D,0x2C
};
//
// Expanded IV for TKIP function.
//
typedef struct PACKED _IV_CONTROL_
{
union PACKED
{
struct PACKED
{
UCHAR rc0;
UCHAR rc1;
UCHAR rc2;
union PACKED
{
struct PACKED
{
#ifdef RT_BIG_ENDIAN
UCHAR KeyID:2;
UCHAR ExtIV:1;
UCHAR Rsvd:5;
#else
UCHAR Rsvd:5;
UCHAR ExtIV:1;
UCHAR KeyID:2;
#endif
} field;
UCHAR Byte;
} CONTROL;
} field;
ULONG word;
} IV16;
ULONG IV32;
} TKIP_IV, *PTKIP_IV;
/*
========================================================================
Routine Description:
Convert from UCHAR[] to ULONG in a portable way
Arguments:
pMICKey pointer to MIC Key
Return Value:
None
Note:
========================================================================
*/
ULONG RTMPTkipGetUInt32(
IN PUCHAR pMICKey)
{
ULONG res = 0;
INT i;
for (i = 0; i < 4; i++)
{
res |= (*pMICKey++) << (8 * i);
}
return res;
}
/*
========================================================================
Routine Description:
Convert from ULONG to UCHAR[] in a portable way
Arguments:
pDst pointer to destination for convert ULONG to UCHAR[]
val the value for convert
Return Value:
None
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
VOID RTMPTkipPutUInt32(
IN OUT PUCHAR pDst,
IN ULONG val)
{
INT i;
for(i = 0; i < 4; i++)
{
*pDst++ = (UCHAR) (val & 0xff);
val >>= 8;
}
}
/*
========================================================================
Routine Description:
Set the MIC Key.
Arguments:
pAd Pointer to our adapter
pMICKey pointer to MIC Key
Return Value:
None
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
VOID RTMPTkipSetMICKey(
IN PTKIP_KEY_INFO pTkip,
IN PUCHAR pMICKey)
{
// Set the key
pTkip->K0 = RTMPTkipGetUInt32(pMICKey);
pTkip->K1 = RTMPTkipGetUInt32(pMICKey + 4);
// and reset the message
pTkip->L = pTkip->K0;
pTkip->R = pTkip->K1;
pTkip->nBytesInM = 0;
pTkip->M = 0;
}
/*
========================================================================
Routine Description:
Calculate the MIC Value.
Arguments:
pAd Pointer to our adapter
uChar Append this uChar
Return Value:
None
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
VOID RTMPTkipAppendByte(
IN PTKIP_KEY_INFO pTkip,
IN UCHAR uChar)
{
// Append the byte to our word-sized buffer
pTkip->M |= (uChar << (8* pTkip->nBytesInM));
pTkip->nBytesInM++;
// Process the word if it is full.
if( pTkip->nBytesInM >= 4 )
{
pTkip->L ^= pTkip->M;
pTkip->R ^= ROL32( pTkip->L, 17 );
pTkip->L += pTkip->R;
pTkip->R ^= ((pTkip->L & 0xff00ff00) >> 8) | ((pTkip->L & 0x00ff00ff) << 8);
pTkip->L += pTkip->R;
pTkip->R ^= ROL32( pTkip->L, 3 );
pTkip->L += pTkip->R;
pTkip->R ^= ROR32( pTkip->L, 2 );
pTkip->L += pTkip->R;
// Clear the buffer
pTkip->M = 0;
pTkip->nBytesInM = 0;
}
}
/*
========================================================================
Routine Description:
Calculate the MIC Value.
Arguments:
pAd Pointer to our adapter
pSrc Pointer to source data for Calculate MIC Value
Len Indicate the length of the source data
Return Value:
None
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
VOID RTMPTkipAppend(
IN PTKIP_KEY_INFO pTkip,
IN PUCHAR pSrc,
IN UINT nBytes)
{
// This is simple
while(nBytes > 0)
{
RTMPTkipAppendByte(pTkip, *pSrc++);
nBytes--;
}
}
/*
========================================================================
Routine Description:
Get the MIC Value.
Arguments:
pAd Pointer to our adapter
Return Value:
None
IRQL = DISPATCH_LEVEL
Note:
the MIC Value is store in pAd->PrivateInfo.MIC
========================================================================
*/
VOID RTMPTkipGetMIC(
IN PTKIP_KEY_INFO pTkip)
{
// Append the minimum padding
RTMPTkipAppendByte(pTkip, 0x5a );
RTMPTkipAppendByte(pTkip, 0 );
RTMPTkipAppendByte(pTkip, 0 );
RTMPTkipAppendByte(pTkip, 0 );
RTMPTkipAppendByte(pTkip, 0 );
// and then zeroes until the length is a multiple of 4
while( pTkip->nBytesInM != 0 )
{
RTMPTkipAppendByte(pTkip, 0 );
}
// The appendByte function has already computed the result.
RTMPTkipPutUInt32(pTkip->MIC, pTkip->L);
RTMPTkipPutUInt32(pTkip->MIC + 4, pTkip->R);
}
/*
========================================================================
Routine Description:
Init Tkip function.
Arguments:
pAd Pointer to our adapter
pTKey Pointer to the Temporal Key (TK), TK shall be 128bits.
KeyId TK Key ID
pTA Pointer to transmitter address
pMICKey pointer to MIC Key
Return Value:
None
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
VOID RTMPInitTkipEngine(
IN PRTMP_ADAPTER pAd,
IN PUCHAR pKey,
IN UCHAR KeyId,
IN PUCHAR pTA,
IN PUCHAR pMICKey,
IN PUCHAR pTSC,
OUT PULONG pIV16,
OUT PULONG pIV32)
{
TKIP_IV tkipIv;
// Prepare 8 bytes TKIP encapsulation for MPDU
NdisZeroMemory(&tkipIv, sizeof(TKIP_IV));
tkipIv.IV16.field.rc0 = *(pTSC + 1);
tkipIv.IV16.field.rc1 = (tkipIv.IV16.field.rc0 | 0x20) & 0x7f;
tkipIv.IV16.field.rc2 = *pTSC;
tkipIv.IV16.field.CONTROL.field.ExtIV = 1; // 0: non-extended IV, 1: an extended IV
tkipIv.IV16.field.CONTROL.field.KeyID = KeyId;
// tkipIv.IV32 = *(PULONG)(pTSC + 2);
NdisMoveMemory(&tkipIv.IV32, (pTSC + 2), 4); // Copy IV
*pIV16 = tkipIv.IV16.word;
*pIV32 = tkipIv.IV32;
}
/*
========================================================================
Routine Description:
Init MIC Value calculation function which include set MIC key &
calculate first 16 bytes (DA + SA + priority + 0)
Arguments:
pAd Pointer to our adapter
pTKey Pointer to the Temporal Key (TK), TK shall be 128bits.
pDA Pointer to DA address
pSA Pointer to SA address
pMICKey pointer to MIC Key
Return Value:
None
Note:
========================================================================
*/
VOID RTMPInitMICEngine(
IN PRTMP_ADAPTER pAd,
IN PUCHAR pKey,
IN PUCHAR pDA,
IN PUCHAR pSA,
IN UCHAR UserPriority,
IN PUCHAR pMICKey)
{
ULONG Priority = UserPriority;
// Init MIC value calculation
RTMPTkipSetMICKey(&pAd->PrivateInfo.Tx, pMICKey);
// DA
RTMPTkipAppend(&pAd->PrivateInfo.Tx, pDA, MAC_ADDR_LEN);
// SA
RTMPTkipAppend(&pAd->PrivateInfo.Tx, pSA, MAC_ADDR_LEN);
// Priority + 3 bytes of 0
RTMPTkipAppend(&pAd->PrivateInfo.Tx, (PUCHAR)&Priority, 4);
}
/*
========================================================================
Routine Description:
Compare MIC value of received MSDU
Arguments:
pAd Pointer to our adapter
pSrc Pointer to the received Plain text data
pDA Pointer to DA address
pSA Pointer to SA address
pMICKey pointer to MIC Key
Len the length of the received plain text data exclude MIC value
Return Value:
TRUE MIC value matched
FALSE MIC value mismatched
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
BOOLEAN RTMPTkipCompareMICValue(
IN PRTMP_ADAPTER pAd,
IN PUCHAR pSrc,
IN PUCHAR pDA,
IN PUCHAR pSA,
IN PUCHAR pMICKey,
IN UCHAR UserPriority,
IN UINT Len)
{
UCHAR OldMic[8];
ULONG Priority = UserPriority;
// Init MIC value calculation
RTMPTkipSetMICKey(&pAd->PrivateInfo.Rx, pMICKey);
// DA
RTMPTkipAppend(&pAd->PrivateInfo.Rx, pDA, MAC_ADDR_LEN);
// SA
RTMPTkipAppend(&pAd->PrivateInfo.Rx, pSA, MAC_ADDR_LEN);
// Priority + 3 bytes of 0
RTMPTkipAppend(&pAd->PrivateInfo.Rx, (PUCHAR)&Priority, 4);
// Calculate MIC value from plain text data
RTMPTkipAppend(&pAd->PrivateInfo.Rx, pSrc, Len);
// Get MIC valude from received frame
NdisMoveMemory(OldMic, pSrc + Len, 8);
// Get MIC value from decrypted plain data
RTMPTkipGetMIC(&pAd->PrivateInfo.Rx);
// Move MIC value from MSDU, this steps should move to data path.
// Since the MIC value might cross MPDUs.
if(!NdisEqualMemory(pAd->PrivateInfo.Rx.MIC, OldMic, 8))
{
DBGPRINT_RAW(RT_DEBUG_ERROR, ("RTMPTkipCompareMICValue(): TKIP MIC Error !\n")); //MIC error.
return (FALSE);
}
return (TRUE);
}
/*
========================================================================
Routine Description:
Compare MIC value of received MSDU
Arguments:
pAd Pointer to our adapter
pLLC LLC header
pSrc Pointer to the received Plain text data
pDA Pointer to DA address
pSA Pointer to SA address
pMICKey pointer to MIC Key
Len the length of the received plain text data exclude MIC value
Return Value:
TRUE MIC value matched
FALSE MIC value mismatched
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
BOOLEAN RTMPTkipCompareMICValueWithLLC(
IN PRTMP_ADAPTER pAd,
IN PUCHAR pLLC,
IN PUCHAR pSrc,
IN PUCHAR pDA,
IN PUCHAR pSA,
IN PUCHAR pMICKey,
IN UINT Len)
{
UCHAR OldMic[8];
ULONG Priority = 0;
// Init MIC value calculation
RTMPTkipSetMICKey(&pAd->PrivateInfo.Rx, pMICKey);
// DA
RTMPTkipAppend(&pAd->PrivateInfo.Rx, pDA, MAC_ADDR_LEN);
// SA
RTMPTkipAppend(&pAd->PrivateInfo.Rx, pSA, MAC_ADDR_LEN);
// Priority + 3 bytes of 0
RTMPTkipAppend(&pAd->PrivateInfo.Rx, (PUCHAR)&Priority, 4);
// Start with LLC header
RTMPTkipAppend(&pAd->PrivateInfo.Rx, pLLC, 8);
// Calculate MIC value from plain text data
RTMPTkipAppend(&pAd->PrivateInfo.Rx, pSrc, Len);
// Get MIC valude from received frame
NdisMoveMemory(OldMic, pSrc + Len, 8);
// Get MIC value from decrypted plain data
RTMPTkipGetMIC(&pAd->PrivateInfo.Rx);
// Move MIC value from MSDU, this steps should move to data path.
// Since the MIC value might cross MPDUs.
if(!NdisEqualMemory(pAd->PrivateInfo.Rx.MIC, OldMic, 8))
{
DBGPRINT_RAW(RT_DEBUG_ERROR, ("RTMPTkipCompareMICValueWithLLC(): TKIP MIC Error !\n")); //MIC error.
return (FALSE);
}
return (TRUE);
}
/*
========================================================================
Routine Description:
Copy frame from waiting queue into relative ring buffer and set
appropriate ASIC register to kick hardware transmit function
Arguments:
pAd Pointer to our adapter
PNDIS_PACKET Pointer to Ndis Packet for MIC calculation
pEncap Pointer to LLC encap data
LenEncap Total encap length, might be 0 which indicates no encap
Return Value:
None
IRQL = DISPATCH_LEVEL
Note:
========================================================================
*/
VOID RTMPCalculateMICValue(
IN PRTMP_ADAPTER pAd,
IN PNDIS_PACKET pPacket,
IN PUCHAR pEncap,
IN PCIPHER_KEY pKey,
IN UCHAR apidx)
{
PACKET_INFO PacketInfo;
PUCHAR pSrcBufVA;
UINT SrcBufLen;
PUCHAR pSrc;
UCHAR UserPriority;
UCHAR vlan_offset = 0;
RTMP_QueryPacketInfo(pPacket, &PacketInfo, &pSrcBufVA, &SrcBufLen);
UserPriority = RTMP_GET_PACKET_UP(pPacket);
pSrc = pSrcBufVA;
// determine if this is a vlan packet
if (((*(pSrc + 12) << 8) + *(pSrc + 13)) == 0x8100)
vlan_offset = 4;
#ifdef CONFIG_STA_SUPPORT
#endif // CONFIG_STA_SUPPORT //
{
RTMPInitMICEngine(
pAd,
pKey->Key,
pSrc,
pSrc + 6,
UserPriority,
pKey->TxMic);
}
if (pEncap != NULL)
{
// LLC encapsulation
RTMPTkipAppend(&pAd->PrivateInfo.Tx, pEncap, 6);
// Protocol Type
RTMPTkipAppend(&pAd->PrivateInfo.Tx, pSrc + 12 + vlan_offset, 2);
}
SrcBufLen -= (14 + vlan_offset);
pSrc += (14 + vlan_offset);
do
{
if (SrcBufLen > 0)
{
RTMPTkipAppend(&pAd->PrivateInfo.Tx, pSrc, SrcBufLen);
}
break; // No need handle next packet
} while (TRUE); // End of copying payload
// Compute the final MIC Value
RTMPTkipGetMIC(&pAd->PrivateInfo.Tx);
}
/************************************************************/
/* tkip_sbox() */
/* Returns a 16 bit value from a 64K entry table. The Table */
/* is synthesized from two 256 entry byte wide tables. */
/************************************************************/
UINT tkip_sbox(UINT index)
{
UINT index_low;
UINT index_high;
UINT left, right;
index_low = (index % 256);
index_high = ((index >> 8) % 256);
left = Tkip_Sbox_Lower[index_low] + (Tkip_Sbox_Upper[index_low] * 256);
right = Tkip_Sbox_Upper[index_high] + (Tkip_Sbox_Lower[index_high] * 256);
return (left ^ right);
}
UINT rotr1(UINT a)
{
unsigned int b;
if ((a & 0x01) == 0x01)
{
b = (a >> 1) | 0x8000;
}
else
{
b = (a >> 1) & 0x7fff;
}
b = b % 65536;
return b;
}
VOID RTMPTkipMixKey(
UCHAR *key,
UCHAR *ta,
ULONG pnl, /* Least significant 16 bits of PN */
ULONG pnh, /* Most significant 32 bits of PN */
UCHAR *rc4key,
UINT *p1k)
{
UINT tsc0;
UINT tsc1;
UINT tsc2;
UINT ppk0;
UINT ppk1;
UINT ppk2;
UINT ppk3;
UINT ppk4;
UINT ppk5;
INT i;
INT j;
tsc0 = (unsigned int)((pnh >> 16) % 65536); /* msb */
tsc1 = (unsigned int)(pnh % 65536);
tsc2 = (unsigned int)(pnl % 65536); /* lsb */
/* Phase 1, step 1 */
p1k[0] = tsc1;
p1k[1] = tsc0;
p1k[2] = (UINT)(ta[0] + (ta[1]*256));
p1k[3] = (UINT)(ta[2] + (ta[3]*256));
p1k[4] = (UINT)(ta[4] + (ta[5]*256));
/* Phase 1, step 2 */
for (i=0; i<8; i++)
{
j = 2*(i & 1);
p1k[0] = (p1k[0] + tkip_sbox( (p1k[4] ^ ((256*key[1+j]) + key[j])) % 65536 )) % 65536;
p1k[1] = (p1k[1] + tkip_sbox( (p1k[0] ^ ((256*key[5+j]) + key[4+j])) % 65536 )) % 65536;
p1k[2] = (p1k[2] + tkip_sbox( (p1k[1] ^ ((256*key[9+j]) + key[8+j])) % 65536 )) % 65536;
p1k[3] = (p1k[3] + tkip_sbox( (p1k[2] ^ ((256*key[13+j]) + key[12+j])) % 65536 )) % 65536;
p1k[4] = (p1k[4] + tkip_sbox( (p1k[3] ^ (((256*key[1+j]) + key[j]))) % 65536 )) % 65536;
p1k[4] = (p1k[4] + i) % 65536;
}
/* Phase 2, Step 1 */
ppk0 = p1k[0];
ppk1 = p1k[1];
ppk2 = p1k[2];
ppk3 = p1k[3];
ppk4 = p1k[4];
ppk5 = (p1k[4] + tsc2) % 65536;
/* Phase2, Step 2 */
ppk0 = ppk0 + tkip_sbox( (ppk5 ^ ((256*key[1]) + key[0])) % 65536);
ppk1 = ppk1 + tkip_sbox( (ppk0 ^ ((256*key[3]) + key[2])) % 65536);
ppk2 = ppk2 + tkip_sbox( (ppk1 ^ ((256*key[5]) + key[4])) % 65536);
ppk3 = ppk3 + tkip_sbox( (ppk2 ^ ((256*key[7]) + key[6])) % 65536);
ppk4 = ppk4 + tkip_sbox( (ppk3 ^ ((256*key[9]) + key[8])) % 65536);
ppk5 = ppk5 + tkip_sbox( (ppk4 ^ ((256*key[11]) + key[10])) % 65536);
ppk0 = ppk0 + rotr1(ppk5 ^ ((256*key[13]) + key[12]));
ppk1 = ppk1 + rotr1(ppk0 ^ ((256*key[15]) + key[14]));
ppk2 = ppk2 + rotr1(ppk1);
ppk3 = ppk3 + rotr1(ppk2);
ppk4 = ppk4 + rotr1(ppk3);
ppk5 = ppk5 + rotr1(ppk4);
/* Phase 2, Step 3 */
/* Phase 2, Step 3 */
tsc0 = (unsigned int)((pnh >> 16) % 65536); /* msb */
tsc1 = (unsigned int)(pnh % 65536);
tsc2 = (unsigned int)(pnl % 65536); /* lsb */
rc4key[0] = (tsc2 >> 8) % 256;
rc4key[1] = (((tsc2 >> 8) % 256) | 0x20) & 0x7f;
rc4key[2] = tsc2 % 256;
rc4key[3] = ((ppk5 ^ ((256*key[1]) + key[0])) >> 1) % 256;
rc4key[4] = ppk0 % 256;
rc4key[5] = (ppk0 >> 8) % 256;
rc4key[6] = ppk1 % 256;
rc4key[7] = (ppk1 >> 8) % 256;
rc4key[8] = ppk2 % 256;
rc4key[9] = (ppk2 >> 8) % 256;
rc4key[10] = ppk3 % 256;
rc4key[11] = (ppk3 >> 8) % 256;
rc4key[12] = ppk4 % 256;
rc4key[13] = (ppk4 >> 8) % 256;
rc4key[14] = ppk5 % 256;
rc4key[15] = (ppk5 >> 8) % 256;
}
//
// TRUE: Success!
// FALSE: Decrypt Error!
//
BOOLEAN RTMPSoftDecryptTKIP(
IN PRTMP_ADAPTER pAd,
IN PUCHAR pData,
IN ULONG DataByteCnt,
IN UCHAR UserPriority,
IN PCIPHER_KEY pWpaKey)
{
UCHAR KeyID;
UINT HeaderLen;
UCHAR fc0;
UCHAR fc1;
USHORT fc;
UINT frame_type;
UINT frame_subtype;
UINT from_ds;
UINT to_ds;
INT a4_exists;
INT qc_exists;
USHORT duration;
USHORT seq_control;
USHORT qos_control;
UCHAR TA[MAC_ADDR_LEN];
UCHAR DA[MAC_ADDR_LEN];
UCHAR SA[MAC_ADDR_LEN];
UCHAR RC4Key[16];
UINT p1k[5]; //for mix_key;
ULONG pnl;/* Least significant 16 bits of PN */
ULONG pnh;/* Most significant 32 bits of PN */
UINT num_blocks;
UINT payload_remainder;
ARCFOURCONTEXT ArcFourContext;
UINT crc32 = 0;
UINT trailfcs = 0;
UCHAR MIC[8];
UCHAR TrailMIC[8];
#ifdef RT_BIG_ENDIAN
RTMPFrameEndianChange(pAd, (PUCHAR)pData, DIR_READ, FALSE);
#endif
fc0 = *pData;
fc1 = *(pData + 1);
fc = *((PUSHORT)pData);
frame_type = ((fc0 >> 2) & 0x03);
frame_subtype = ((fc0 >> 4) & 0x0f);
from_ds = (fc1 & 0x2) >> 1;
to_ds = (fc1 & 0x1);
a4_exists = (from_ds & to_ds);
qc_exists = ((frame_subtype == 0x08) || /* Assumed QoS subtypes */
(frame_subtype == 0x09) || /* Likely to change. */
(frame_subtype == 0x0a) ||
(frame_subtype == 0x0b)
);
HeaderLen = 24;
if (a4_exists)
HeaderLen += 6;
KeyID = *((PUCHAR)(pData+ HeaderLen + 3));
KeyID = KeyID >> 6;
if (pWpaKey[KeyID].KeyLen == 0)
{
DBGPRINT(RT_DEBUG_TRACE, ("RTMPSoftDecryptTKIP failed!(KeyID[%d] Length can not be 0)\n", KeyID));
return FALSE;
}
duration = *((PUSHORT)(pData+2));
seq_control = *((PUSHORT)(pData+22));
if (qc_exists)
{
if (a4_exists)
{
qos_control = *((PUSHORT)(pData+30));
}
else
{
qos_control = *((PUSHORT)(pData+24));
}
}
if (to_ds == 0 && from_ds == 1)
{
NdisMoveMemory(DA, pData+4, MAC_ADDR_LEN);
NdisMoveMemory(SA, pData+16, MAC_ADDR_LEN);
NdisMoveMemory(TA, pData+10, MAC_ADDR_LEN); //BSSID
}
else if (to_ds == 0 && from_ds == 0 )
{
NdisMoveMemory(TA, pData+10, MAC_ADDR_LEN);
NdisMoveMemory(DA, pData+4, MAC_ADDR_LEN);
NdisMoveMemory(SA, pData+10, MAC_ADDR_LEN);
}
else if (to_ds == 1 && from_ds == 0)
{
NdisMoveMemory(SA, pData+10, MAC_ADDR_LEN);
NdisMoveMemory(TA, pData+10, MAC_ADDR_LEN);
NdisMoveMemory(DA, pData+16, MAC_ADDR_LEN);
}
else if (to_ds == 1 && from_ds == 1)
{
NdisMoveMemory(TA, pData+10, MAC_ADDR_LEN);
NdisMoveMemory(DA, pData+16, MAC_ADDR_LEN);
NdisMoveMemory(SA, pData+22, MAC_ADDR_LEN);
}
num_blocks = (DataByteCnt - 16) / 16;
payload_remainder = (DataByteCnt - 16) % 16;
pnl = (*(pData + HeaderLen)) * 256 + *(pData + HeaderLen + 2);
pnh = *((PULONG)(pData + HeaderLen + 4));
pnh = cpu2le32(pnh);
RTMPTkipMixKey(pWpaKey[KeyID].Key, TA, pnl, pnh, RC4Key, p1k);
ARCFOUR_INIT(&ArcFourContext, RC4Key, 16);
ARCFOUR_DECRYPT(&ArcFourContext, pData + HeaderLen, pData + HeaderLen + 8, DataByteCnt - HeaderLen - 8);
NdisMoveMemory(&trailfcs, pData + DataByteCnt - 8 - 4, 4);
crc32 = RTMP_CALC_FCS32(PPPINITFCS32, pData + HeaderLen, DataByteCnt - HeaderLen - 8 - 4); //Skip IV+EIV 8 bytes & Skip last 4 bytes(FCS).
crc32 ^= 0xffffffff; /* complement */
if(crc32 != cpu2le32(trailfcs))
{
DBGPRINT(RT_DEBUG_TRACE, ("RTMPSoftDecryptTKIP, WEP Data ICV Error !\n")); //ICV error.
return (FALSE);
}
NdisMoveMemory(TrailMIC, pData + DataByteCnt - 8 - 8 - 4, 8);
RTMPInitMICEngine(pAd, pWpaKey[KeyID].Key, DA, SA, UserPriority, pWpaKey[KeyID].RxMic);
RTMPTkipAppend(&pAd->PrivateInfo.Tx, pData + HeaderLen, DataByteCnt - HeaderLen - 8 - 12);
RTMPTkipGetMIC(&pAd->PrivateInfo.Tx);
NdisMoveMemory(MIC, pAd->PrivateInfo.Tx.MIC, 8);
if (!NdisEqualMemory(MIC, TrailMIC, 8))
{
DBGPRINT(RT_DEBUG_ERROR, ("RTMPSoftDecryptTKIP, WEP Data MIC Error !\n")); //MIC error.
//RTMPReportMicError(pAd, &pWpaKey[KeyID]); // marked by AlbertY @ 20060630
return (FALSE);
}
#ifdef RT_BIG_ENDIAN
RTMPFrameEndianChange(pAd, (PUCHAR)pData, DIR_READ, FALSE);
#endif
//DBGPRINT(RT_DEBUG_TRACE, "RTMPSoftDecryptTKIP Decript done!!\n");
return TRUE;
}