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/*-
 * Copyright (c) 2003-2009 RMI Corporation
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 * 3. Neither the name of RMI Corporation, nor the names of its contributors,
 *    may be used to endorse or promote products derived from this software
 *    without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 * SUCH DAMAGE.
 *
 * $FreeBSD: release/9.1.0/sys/mips/rmi/dev/sec/desc.h 212763 2010-09-16 20:23:22Z jchandra $
 * RMI_BSD */
#ifndef _DESC_H_
#define _DESC_H_


#define ONE_BIT              0x0000000000000001ULL
#define TWO_BITS             0x0000000000000003ULL
#define THREE_BITS           0x0000000000000007ULL
#define FOUR_BITS            0x000000000000000fULL
#define FIVE_BITS            0x000000000000001fULL
#define SIX_BITS             0x000000000000003fULL
#define SEVEN_BITS           0x000000000000007fULL
#define EIGHT_BITS           0x00000000000000ffULL
#define NINE_BITS            0x00000000000001ffULL
#define ELEVEN_BITS          0x00000000000007ffULL
#define TWELVE_BITS          0x0000000000000fffULL
#define FOURTEEN_BITS        0x0000000000003fffULL
#define TWENTYFOUR_BITS      0x0000000000ffffffULL
#define THIRTY_TWO_BITS      0x00000000ffffffffULL
#define THIRTY_FIVE_BITS     0x00000007ffffffffULL
#define FOURTY_BITS          0x000000ffffffffffULL

#define MSG_IN_CTL_LEN_BASE  40
#define MSG_IN_CTL_ADDR_BASE 0

#define GET_FIELD(word,field) \
 ((word) & (field ## _MASK)) >> (field ## _LSB)

#define FIELD_VALUE(field,value) (((value) & (field ## _BITS)) << (field ## _LSB))

/*
 * NOTE: this macro expects 'word' to be uninitialized (i.e. zeroed)
 */
#define SET_FIELD(word,field,value) \
 { (word) |=  (((value) & (field ## _BITS)) << (field ## _LSB)); }

/*
 * This macro clears 'word', then sets the value
 */
#define CLEAR_SET_FIELD(word,field,value) \
 { (word) &= ~((field ## _BITS) << (field ## _LSB)); \
   (word) |=  (((value) & (field ## _BITS)) << (field ## _LSB)); }

/*
 * NOTE: May be used to build value specific mask
 *        (e.g.  GEN_MASK(CTL_DSC_CPHR_3DES,CTL_DSC_CPHR_LSB)
 */
#define GEN_MASK(bits,lsb) ((bits) << (lsb))




/*
 * Security block data and control exchange
 *
 * A 2-word message ring descriptor is used to pass a pointer to the control descriptor data structure
 * and a pointer to the packet descriptor data structure:
 *
 *  63  61 60                 54      53      52    49 48            45 44    40
 *  39                                                     5 4                 0
 *  ---------------------------------------------------------------------------------------------------------------------------------------------------------
 * | Ctrl | Resp Dest Id Entry0 | IF_L2ALLOC | UNUSED | Control Length | UNUSED
 * | 35 MSB of address of control descriptor data structure | Software Scratch0
 * |
 *  ---------------------------------------------------------------------------------------------------------------------------------------------------------
 *    3              7                1          4             4           5
 *    35                                       5
 *
 *  63  61 60    54     53          52             51        50    46      45       44    40 39                                                    5 4      0
 *  ---------------------------------------------------------------------------------------------------------------------------------------------------------
 * | Ctrl | UNUSED | WRB_COH | WRB_L2ALLOC | DF_PTR_L2ALLOC | UNUSED | Data Length | UNUSED | 35 MSB of address of packet descriptor data structure | UNUSED |
 *  ---------------------------------------------------------------------------------------------------------------------------------------------------------
 *    3       7         1          1               1            5           1          5                                35                              5
 *
 * Addresses assumed to be cache-line aligned, i.e., Address[4:0] ignored (using 5'h00 instead)
 *
 * Control length is the number of control cachelines to be read so user needs
 * to round up
 * the control length to closest integer multiple of 32 bytes. Note that at
 * present (08/12/04)
 * the longest (sensical) ctrl structure is <= 416 bytes, i.e., 13 cachelines.
 *
 * The packet descriptor data structure size is fixed at 1 cacheline (32 bytes).
 * This effectively makes "Data Length" a Load/NoLoad bit. NoLoad causes an abort.
 *
 *
 * Upon completion of operation, the security block returns a 2-word free descriptor
 * in the following format:
 *
 *  63  61 60            54 53   52 51       49   48   47               40 39                                                  0
 *  ----------------------------------------------------------------------------------------------------------------------------
 * | Ctrl | Destination Id | 2'b00 | Desc Ctrl | 1'b0 | Instruction Error |    Address of control descriptor data structure     |
 *  ----------------------------------------------------------------------------------------------------------------------------
 * | Ctrl | Destination Id | 2'b00 | Desc Ctrl | 1'b0 |     Data Error    |    Address of packet descriptor data structure      |
 *  ----------------------------------------------------------------------------------------------------------------------------
 *
 * The Instruction and Data Error codes are enumerated in the
 * ControlDescriptor and PacketDescriptor sections below
 *
 */


/*
 * Operating assumptions
 * =====================
 *
 *
 *	        -> For all IpSec ops, I assume that all the IP/IPSec/TCP headers
 *		   and the data are present at the specified source addresses.
 *		   I also assume that all necessary header data already exists
 *		   at the destination. Additionally, in AH I assume that all
 *		   mutable fields (IP.{TOS, Flags, Offset, TTL, Header_Checksum})
 *		   and the AH.Authentication_Data have been zeroed by the client.
 *
 *
 *		-> In principle, the HW can calculate TCP checksums on both
 *		   incoming and outgoing data; however, since the TCP header
 *		   contains the TCP checksum of the plain payload and the header
 *		   is encrypted, two passes would be necessary to do checksum + encryption
 *                 for outgoing messages;
 *		   therefore the checksum engine will likely only be used during decryption
 *                 (incoming).
 *
 *
 *		-> For all operations involving TCP checksum, I assume the client has filled
 *		   the TCP checksum field with the appropriate value:
 *
 *			    - 0 for generation phase
 *			    - actual value for verification phase (expecting 0 result)
 *
 *
 *		-> For ESP tunnel, the original IP header exists between the end of the
 *		   ESP header and the beginning of the TCP header; it is assumed that the
 *		   maximum length of this header is 16 k(32bit)words (used in CkSum_Offset).
 *
 *
 *		-> The authentication data is merely written to the destination address;
 *		   the client is left with the task of comparing to the data in packet
 *		   in decrypt.
 *
 *              -> PacketDescriptor_t.dstLLWMask relevant to AES CTR mode only but it will
 *                 affect all AES-related operations. It will not affect DES/3DES/bypass ops.
 *                 The mask is applied to data as it emerges from the AES engine for the sole
 *                 purpose of providing the authenticator and cksum engines with correct data.
 *                 CAVEAT: the HW does not mask the incoming data. It is the user's responsibility
 *                 to set to 0 the corresponding data in memory. If the surplus data is not masked
 *                 in memory, cksum/auth results will be incorrect if those engines receive data
 *                 straight from memory (i.e., not from cipher, as it happens while decoding)
 */

/*
 * Fragmentation and offset related notes
 * ======================================
 *
 *
 *      A) Rebuilding packets from fragments on dword boundaries. The discussion
 *         below is exemplified by tests memcpy_all_off_frags and memcpy_same_off_frags
 *
 *	        1) The Offset before data/iv on first fragment is ALWAYS written back
 *                 Non-zero dst dword or global offsets may cause more data to be
 *                 written than the user-specified length.
 *
 *
 *                 Example:
 *                 --------
 *
 *                 Below is a source (first fragment) packet (@ ADD0 cache-aligned address).
 *                 Assume we just copy it and relevant data starts on
 *                 dword 3 so Cipher_Offset = IV_Offset = 3 (dwords).
 *                 D0X denotes relevant data and G denotes dont care data.
 *                 Offset data is also copied so Packet_Legth = 9 (dwords) * 8 = 72 (bytes)
 *                 Segment_src_address = ADD0
 *
 *                 If we want to, e.g., copy so that the relevant (i.e., D0X) data
 *                 starts at (cache-aligned address) ADD1, we need to specify
 *                 Dst_dword_offset = 1 so D00 is moved from dword position 3 to 0 on next cache-line
 *                 Cipher_dst_address = ADD1 - 0x20 so D00 is written to ADD1
 *
 *                 Note that the security engine always writes full cachelines
 *                 therefore, data written to dword0 0 of ADD1 (denoted w/ ?) is what the sec pipe
 *                 write back buffer contained from previous op.
 *
 *
 *                      SOURCE:                                                 DESTINATION:
 *                      -------                                                 ------------
 *
 *                      Segment_src_address = ADD0                              Cipher_dst_address = ADD1 - 0x20
 *                      Packet_Legth        = 72                                Dst_dword_offset   = 1
 *                      Cipher_Offset       = 3
 *                      IV_Offset           = 3
 *                      Use_IV              = ANY
 *
 *
 *
 *                         3     2     1     0                                  3     2     1     0
 *                       -----------------------                              -----------------------
 *                      | D00 | G   | G   | G   | <- ADD0                    | G   | G   | G   | ?   | <- ADD1 - 0x20
 *                       -----------------------                              -----------------------
 *                      | D04 | D03 | D02 | D01 |                            | D03 | D02 | D01 | D00 | <- ADD1
 *                       -----------------------                              -----------------------
 *                      |     |     |     | D05 |                            |     |     | D05 | D04 |
 *                       -----------------------                              -----------------------
 *
 *	        2) On fragments following the first, IV_Offset is overloaded to mean data offset
 *                 (number of dwords to skip from beginning of cacheline before starting processing)
 *                 and Use_IV is overloaded to mean do writeback the offset (in the clear).
 *                 These fields in combination with Dst_dword_offset allow packet fragments with
 *                 arbitrary boundaries/lengthd to be reasembled.
 *
 *
 *                 Example:
 *                 --------
 *
 *                 Assume data above was first fragment of a packet we'd like to merge to
 *                 (second) fragment below located at ADD2. The written data should follow
 *                 the previous data without gaps or overwrites. To achieve this, one should
 *                 assert the "Next" field on the previous fragment and use self-explanatory
 *                 set of parameters below
 *
 *
 *                      SOURCE:                                                 DESTINATION:
 *                      -------                                                 ------------
 *
 *                      Segment_src_address = ADD2                              Cipher_dst_address = ADD1 + 0x20
 *                      Packet_Legth        = 104                               Dst_dword_offset   = 1
 *                      IV_Offset           = 1
 *                      Use_IV              = 0
 *
 *
 *
 *                         3     2     1     0                                  3     2     1     0
 *                       -----------------------                              -----------------------
 *                      | D12 | D11 | D10 | G   | <- ADD2                    | G   | G   | G   | ?   | <- ADD1 - 0x20
 *                       -----------------------                              -----------------------
 *                      | D16 | D15 | D14 | D13 |                            | D03 | D02 | D01 | D00 | <- ADD1
 *                       -----------------------                              -----------------------
 *                      | D1a | D19 | D18 | D17 |                            | D11 | D10 | D05 | D04 | <- ADD1 + 0x20
 *                       -----------------------                              -----------------------
 *                      |     |     |     | D1b |                            | D15 | D14 | D13 | D12 |
 *                       -----------------------                              -----------------------
 *                                                                           | D19 | D18 | D17 | D16 |
 *                                                                            -----------------------
 *                                                                           |     |     | D1b | D1a |
 *                                                                            -----------------------
 *
 *                 It is note-worthy that the merging can only be achieved if Use_IV is 0. Indeed, the security
 *                 engine always writes full lines, therefore ADD1 + 0x20 will be re-written. Setting Use_IV to 0
 *                 will allow the sec pipe write back buffer to preserve D04, D05 from previous frag and only
 *                 receive D10, D11 thereby preserving the integrity of the previous data.
 *
 *	        3) On fragments following the first, !UseIV in combination w/ Dst_dword_offset >= (4 - IV_Offset)
 *                 will cause a wraparound of the write thus achieving all 16 possible (Initial_Location, Final_Location)
 *                 combinations for the data.
 *
 *
 *                 Example:
 *                 --------
 *
 *                 Contiguously merging 2 data sets above with a third located at ADD3. If this is the last fragment,
 *                 reset its Next bit.
 *
 *
 *                      SOURCE:                                                 DESTINATION:
 *                      -------                                                 ------------
 *
 *                      Segment_src_address = ADD3                              Cipher_dst_address = ADD1 + 0x80
 *                      Packet_Legth        = 152                               Dst_dword_offset   = 3
 *                      IV_Offset           = 3
 *                      Use_IV              = 0
 *
 *
 *
 *                         3     2     1     0                                  3     2     1     0
 *                       -----------------------                              -----------------------
 *                      | D20 | G   | G   | G   | <- ADD2                    | G   | G   | G   | ?   | <- ADD1 - 0x20
 *                       -----------------------                              -----------------------
 *                      | D24 | D23 | D22 | D21 |                            | D03 | D02 | D01 | D00 | <- ADD1
 *                       -----------------------                              -----------------------
 *                      | D28 | D27 | D26 | D25 |                            | D11 | D10 | D05 | D04 | <- ADD1 + 0x20
 *                       -----------------------                              -----------------------
 *                      | D2c | D2b | D2a | D29 |                            | D15 | D14 | D13 | D12 |
 *                       -----------------------                              -----------------------
 *                      |     | D2f | D2e | D2d |                            | D19 | D18 | D17 | D16 |
 *                       -----------------------                              -----------------------
 *                                                                           | D21 | D20 | D1b | D1a | <- ADD1 + 0x80
 *                                                                            -----------------------
 *                                                                           | D25 | D24 | D23 | D22 |
 *                                                                            -----------------------
 *                                                                           | D29 | D28 | D27 | D26 |
 *                                                                            -----------------------
 *                                                                           | D2d | D2c | D2b | D2a |
 *                                                                            -----------------------
 *                                                                           |(D2d)|(D2c)| D2f | D2e |
 *                                                                            -----------------------
 *
 *                 It is worth noticing that always writing full-lines causes the last 2 dwords in the reconstituted
 *                 packet to be unnecessarily written: (D2d) and (D2c)
 *
 *
 *
 *      B) Implications of fragmentation on AES
 *
 *	        1) AES is a 128 bit block cipher; therefore it requires an even dword total data length
 *                 Data fragments (provided there are more than 1) are allowed to have odd dword
 *                 data lengths provided the total length (cumulated over fragments) is an even dword
 *                 count; an error will be generated otherwise, upon receiving the last fragment descriptor
 *                 (see error conditions below).
 *
 *              2) While using fragments with AES, a fragment (other than first) starting with a != 0 (IV) offset
 *                 while the subsequent total dword count given to AES is odd may not be required to write
 *                 its offset (UseIV). Doing so will cause an error (see error conditions below).
 *
 *
 *                 Example:
 *                 --------
 *
 *                 Suppose the first fragment has an odd DATA dword count and USES AES (as seen below)
 *
 *                      SOURCE:                                                 DESTINATION:
 *                      -------                                                 ------------
 *
 *                      Segment_src_address = ADD0                              Cipher_dst_address = ADD1
 *                      Packet_Legth        = 64                                Dst_dword_offset   = 1
 *                      Cipher_Offset       = 3
 *                      IV_Offset           = 1
 *                      Use_IV              = 1
 *                      Cipher              = Any AES
 *                      Next                = 1
 *
 *
 *
 *
 *                         3     2     1     0                                  3     2     1     0
 *                       -----------------------                              -----------------------
 *                      | D00 | IV1 | IV0 | G   | <- ADD0                    | E00 | IV1 | IV0 | G   | <- ADD1
 *                       -----------------------                              -----------------------
 *                      | D04 | D03 | D02 | D01 |                            | X   | E03 | E02 | E01 |
 *                       -----------------------                              -----------------------
 *
 *                 At the end of processing of the previous fragment, the AES engine input buffer has D04
 *                 and waits for next dword, therefore the writeback buffer cannot finish writing the fragment
 *                 to destination (X instead of E04).
 *
 *                 If a second fragment now arrives with a non-0 offset and requires the offset data to be
 *                 written to destination, the previous write (still needing the arrival of the last dword
 *                 required by the AES to complete the previous operation) cannot complete before the present
 *                 should start causing a deadlock.
 */

/*
 *  Command Control Word for Message Ring Descriptor
 */

/* #define MSG_CMD_CTL_CTL       */
#define MSG_CMD_CTL_CTL_LSB   61
#define MSG_CMD_CTL_CTL_BITS  THREE_BITS
#define MSG_CMD_CTL_CTL_MASK  (MSG_CMD_CTL_CTL_BITS << MSG_CMD_CTL_CTL_LSB)

/* #define MSG_CMD_CTL_ID */
#define MSG_CMD_CTL_ID_LSB    54
#define MSG_CMD_CTL_ID_BITS   SEVEN_BITS
#define MSG_CMD_CTL_ID_MASK   (MSG_CMD_CTL_ID_BITS << MSG_CMD_CTL_ID_LSB)

/* #define MSG_CMD_CTL_LEN */
#define MSG_CMD_CTL_LEN_LSB   45
#define MSG_CMD_CTL_LEN_BITS  FOUR_BITS
#define MSG_CMD_CTL_LEN_MASK  (MSG_CMD_CTL_LEN_BITS << MSG_CMD_CTL_LEN_LSB)


/* #define MSG_CMD_CTL_ADDR */
#define MSG_CMD_CTL_ADDR_LSB  0
#define MSG_CMD_CTL_ADDR_BITS FOURTY_BITS
#define MSG_CMD_CTL_ADDR_MASK (MSG_CMD_CTL_ADDR_BITS << MSG_CMD_CTL_ADDR_LSB)

#define MSG_CMD_CTL_MASK      (MSG_CMD_CTL_CTL_MASK | \
                               MSG_CMD_CTL_LEN_MASK | MSG_CMD_CTL_ADDR_MASK)

/*
 *  Command Data Word for Message Ring Descriptor
 */

/* #define MSG_IN_DATA_CTL */
#define MSG_CMD_DATA_CTL_LSB   61
#define MSG_CMD_DATA_CTL_BITS  THREE_BITS
#define MSG_CMD_DATA_CTL_MASK  (MSG_CMD_DATA_CTL_BITS  << MSG_CMD_DATA_CTL_LSB)

/* #define MSG_CMD_DATA_LEN */
#define MSG_CMD_DATA_LEN_LOAD  1
#define MSG_CMD_DATA_LEN_LSB   45
#define MSG_CMD_DATA_LEN_BITS  ONE_BIT
#define MSG_CMD_DATA_LEN_MASK  (MSG_CMD_DATA_LEN_BITS << MSG_CMD_DATA_LEN_LSB)

/* #define MSG_CMD_DATA_ADDR */
#define MSG_CMD_DATA_ADDR_LSB  0
#define MSG_CMD_DATA_ADDR_BITS FOURTY_BITS
#define MSG_CMD_DATA_ADDR_MASK (MSG_CMD_DATA_ADDR_BITS << MSG_CMD_DATA_ADDR_LSB)

#define MSG_CMD_DATA_MASK      (MSG_CMD_DATA_CTL_MASK | \
                               MSG_CMD_DATA_LEN_MASK | MSG_CMD_DATA_ADDR_MASK)


/*
 * Upon completion of operation, the Sec block returns a 2-word free descriptor
 * in the following format:
 *
 *  63  61 60            54 53   52 51       49  48          40 39             0
 *  ----------------------------------------------------------------------------
 * | Ctrl | Destination Id | 2'b00 | Desc Ctrl | Control Error | Source Address |
 *  ----------------------------------------------------------------------------
 * | Ctrl | Destination Id | 2'b00 | Desc Ctrl |   Data Error  | Dest Address   |
 *  ----------------------------------------------------------------------------
 *
 * The Control and Data Error codes are enumerated below
 *
 *                                Error conditions
 *                                ================
 *
 *             Control Error Code                  Control Error Condition
 *             ------------------                  ---------------------------
 *             9'h000                              No Error
 *             9'h001                              Unknown Cipher Op                      ( Cipher == 3'h{6,7})
 *             9'h002                              Unknown or Illegal Mode                ((Mode   == 3'h{2,3,4} & !AES) | (Mode   == 3'h{5,6,7}))
 *             9'h004                              Unsupported CkSum Src                  (CkSum_Src   == 2'h{2,3} & CKSUM)
 *             9'h008                              Forbidden CFB Mask                     (AES & CFBMode & UseNewKeysCFBMask & CFBMask[7] & (| CFBMask[6:0]))
 *             9'h010                              Unknown Ctrl Op                        ((| Ctrl[63:37]) | (| Ctrl[15:14]))
 *             9'h020                              UNUSED
 *             9'h040                              UNUSED
 *             9'h080                              Data Read Error
 *             9'h100                              Descriptor Ctrl Field Error            (D0.Ctrl != SOP || D1.Ctrl != EOP)
 *
 *             Data Error Code                     Data Error Condition
 *             ---------------                     --------------------
 *             9'h000                              No Error
 *             9'h001                              Insufficient Data To Cipher            (Packet_Length <= (Cipher_Offset or IV_Offset))
 *             9'h002                              Illegal IV Location                    ((Cipher_Offset <  IV_Offset) | (Cipher_Offset <= IV_Offset & AES & ~CTR))
 *             9'h004                              Illegal Wordcount To AES               (Packet_Length[3] != Cipher_Offset[0] & AES)
 *             9'h008                              Illegal Pad And ByteCount Spec         (Hash_Byte_Count != 0 & !Pad_Hash)
 *             9'h010                              Insufficient Data To CkSum             ({Packet_Length, 1'b0} <= CkSum_Offset)
 *             9'h020                              Unknown Data Op                        ((| dstLLWMask[63:60]) | (| dstLLWMask[57:40]) | (| authDst[63:40]) | (| ckSumDst[63:40]))
 *             9'h040                              Insufficient Data To Auth              ({Packet_Length} <= Auth_Offset)
 *             9'h080                              Data Read Error
 *             9'h100                              UNUSED
 */

/*
 * Result Control Word for Message Ring Descriptor
 */

/* #define MSG_RSLT_CTL_CTL */
#define MSG_RSLT_CTL_CTL_LSB      61
#define MSG_RSLT_CTL_CTL_BITS     THREE_BITS
#define MSG_RSLT_CTL_CTL_MASK \
 (MSG_RSLT_CTL_CTL_BITS << MSG_RSLT_CTL_CTL_LSB)

/* #define MSG_RSLT_CTL_DST_ID */
#define MSG_RSLT_CTL_DST_ID_LSB   54
#define MSG_RSLT_CTL_DST_ID_BITS  SEVEN_BITS
#define MSG_RSLT_CTL_DST_ID_MASK \
 (MSG_RSLT_CTL_DST_ID_BITS << MSG_RSLT_CTL_DST_ID_LSB)

/* #define MSG_RSLT_CTL_DSC_CTL */
#define MSG_RSLT_CTL_DSC_CTL_LSB  49
#define MSG_RSLT_CTL_DSC_CTL_BITS THREE_BITS
#define MSG_RSLT_CTL_DSC_CTL_MASK \
 (MSG_RSLT_CTL_DSC_CTL_BITS << MSG_RSLT_CTL_DSC_CTL_LSB)

/* #define MSG_RSLT_CTL_INST_ERR */
#define MSG_RSLT_CTL_INST_ERR_LSB      40
#define MSG_RSLT_CTL_INST_ERR_BITS     NINE_BITS
#define MSG_RSLT_CTL_INST_ERR_MASK \
 (MSG_RSLT_CTL_INST_ERR_BITS << MSG_RSLT_CTL_INST_ERR_LSB)

/* #define MSG_RSLT_CTL_DSC_ADDR */
#define MSG_RSLT_CTL_DSC_ADDR_LSB      0
#define MSG_RSLT_CTL_DSC_ADDR_BITS     FOURTY_BITS
#define MSG_RSLT_CTL_DSC_ADDR_MASK \
 (MSG_RSLT_CTL_DSC_ADDR_BITS << MSG_RSLT_CTL_DSC_ADDR_LSB)

/* #define MSG_RSLT_CTL_MASK */
#define MSG_RSLT_CTL_MASK \
 (MSG_RSLT_CTL_CTRL_MASK | MSG_RSLT_CTL_DST_ID_MASK | \
  MSG_RSLT_CTL_DSC_CTL_MASK | MSG_RSLT_CTL_INST_ERR_MASK | \
  MSG_RSLT_CTL_DSC_ADDR_MASK)

/*
 * Result Data Word for Message Ring Descriptor
 */
/* #define MSG_RSLT_DATA_CTL */
#define MSG_RSLT_DATA_CTL_LSB     61
#define MSG_RSLT_DATA_CTL_BITS    THREE_BITS
#define MSG_RSLT_DATA_CTL_MASK \
 (MSG_RSLT_DATA_CTL_BITS << MSG_RSLT_DATA_CTL_LSB)

/* #define MSG_RSLT_DATA_DST_ID */
#define MSG_RSLT_DATA_DST_ID_LSB  54
#define MSG_RSLT_DATA_DST_ID_BITS SEVEN_BITS
#define MSG_RSLT_DATA_DST_ID_MASK \
 (MSG_RSLT_DATA_DST_ID_BITS << MSG_RSLT_DATA_DST_ID_LSB)

/* #define MSG_RSLT_DATA_DSC_CTL */
#define MSG_RSLT_DATA_DSC_CTL_LSB       49
#define MSG_RSLT_DATA_DSC_CTL_BITS      THREE_BITS
#define MSG_RSLT_DATA_DSC_CTL_MASK \
 (MSG_RSLT_DATA_DSC_CTL_BITS << MSG_RSLT_DATA_DSC_CTL_LSB)

/* #define MSG_RSLT_DATA_INST_ERR */
#define MSG_RSLT_DATA_INST_ERR_LSB      40
#define MSG_RSLT_DATA_INST_ERR_BITS     NINE_BITS
#define MSG_RSLT_DATA_INST_ERR_MASK \
 (MSG_RSLT_DATA_INST_ERR_BITS << MSG_RSLT_DATA_INST_ERR_LSB)

/* #define MSG_RSLT_DATA_DSC_ADDR */
#define MSG_RSLT_DATA_DSC_ADDR_LSB      0
#define MSG_RSLT_DATA_DSC_ADDR_BITS     FOURTY_BITS
#define MSG_RSLT_DATA_DSC_ADDR_MASK     \
 (MSG_RSLT_DATA_DSC_ADDR_BITS << MSG_RSLT_DATA_DSC_ADDR_LSB)

#define MSG_RSLT_DATA_MASK   \
 (MSG_RSLT_DATA_CTRL_MASK | MSG_RSLT_DATA_DST_ID_MASK | \
  MSG_RSLT_DATA_DSC_CTL_MASK | MSG_RSLT_DATA_INST_ERR_MASK | \
  MSG_RSLT_DATA_DSC_ADDR_MASK)


/*
 * Common Message Definitions
 *
 */

/* #define MSG_CTL_OP_ADDR */
#define MSG_CTL_OP_ADDR_LSB      0
#define MSG_CTL_OP_ADDR_BITS     FOURTY_BITS
#define MSG_CTL_OP_ADDR_MASK     (MSG_CTL_OP_ADDR_BITS << MSG_CTL_OP_ADDR_LSB)

#define MSG_CTL_OP_TYPE
#define MSG_CTL_OP_TYPE_LSB             3
#define MSG_CTL_OP_TYPE_BITS            TWO_BITS
#define MSG_CTL_OP_TYPE_MASK            \
 (MSG_CTL_OP_TYPE_BITS << MSG_CTL_OP_TYPE_LSB)

#define MSG0_CTL_OP_ENGINE_SYMKEY       0x01
#define MSG0_CTL_OP_ENGINE_PUBKEY       0x02

#define MSG1_CTL_OP_SYMKEY_PIPE0        0x00
#define MSG1_CTL_OP_SYMKEY_PIPE1        0x01
#define MSG1_CTL_OP_SYMKEY_PIPE2        0x02
#define MSG1_CTL_OP_SYMKEY_PIPE3        0x03

#define MSG1_CTL_OP_PUBKEY_PIPE0        0x00
#define MSG1_CTL_OP_PUBKEY_PIPE1        0x01
#define MSG1_CTL_OP_PUBKEY_PIPE2        0x02
#define MSG1_CTL_OP_PUBKEY_PIPE3        0x03


/*       /----------------------------------------\
 *       |                                        |
 *       |   ControlDescriptor_s datastructure    |
 *       |                                        |
 *       \----------------------------------------/
 *
 *
 *       ControlDescriptor_t.Instruction
 *       -------------------------------
 *
 *   63    44         43               42            41              40           39        35 34    32 31  29     28
 *  --------------------------------------------------------------------------------------------------------------------
 * || UNUSED || OverrideCipher | Arc4Wait4Save | SaveArc4State | LoadArc4State | Arc4KeyLen | Cipher | Mode | InCp_Key || ... CONT ...
 *  --------------------------------------------------------------------------------------------------------------------
 *      20            1                1              1               1               5          3       3        1
 *            <-----------------------------------------------CIPHER--------------------------------------------------->
 *
 *   27    25     24      23   22     21     20      19    17    16     15     0
 *  -----------------------------------------------------------------------------
 * || UNUSED | Hash_Hi | HMAC | Hash_Lo | InHs_Key || UNUSED || CkSum || UNUSED ||
 *  -----------------------------------------------------------------------------
 *      3         1       1        2         1          3        1        16
 *  <---------------------HASH---------------------><-----------CKSUM----------->
 *
 *  X0  CIPHER.Arc4Wait4Save   =                   If op is Arc4 and it requires state saving, then
 *                                                 setting this bit will cause the current op to
 *                                                 delay subsequent op loading until saved state data
 *                                                 becomes visible.
 *      CIPHER.OverrideCipher  =                   Override encryption if PacketDescriptor_t.dstDataSettings.CipherPrefix
 *                                                 is set; data will be copied out (and optionally auth/cksum)
 *                                                 in the clear. This is used in GCM mode if auth only as we
 *                                                 still need E(K, 0) calculated by cipher. Engine behavior is
 *                                                 undefined if this bit is set and CipherPrefix is not.
 *  X0         SaveArc4State   =                   Save Arc4 state at the end of Arc4 operation
 *  X0         LoadArc4State   =                   Load Arc4 state at the beginning of an Arc4 operation
 *                                                 This overriden by the InCp_Key setting for Arc4
 *             Arc4KeyLen      =                   Length in bytes of Arc4 key (0 is interpreted as 32)
 *                                                 Ignored for other ciphers
 *                                                 For ARC4, IFetch/IDecode will always read exactly 4
 *                                                 consecutive dwords into its CipherKey{0,3} regardless
 *                                                 of this quantity; it will however only use the specified
 *                                                 number of bytes.
 *             Cipher          =        3'b000     Bypass
 *                                      3'b001     DES
 *                                      3'b010     3DES
 *                                      3'b011     AES 128-bit key
 *                                      3'b100     AES 192-bit key
 *                                      3'b101     AES 256-bit key
 *                                      3'b110     ARC4
 *                                      3'b111     Kasumi f8
 *                                      Remainder  UNDEFINED
 *             Mode            =        3'b000     ECB
 *                                      3'b001     CBC
 *                                      3'b010     CFB (AES only, otherwise undefined)
 *                                      3'b011     OFB (AES only, otherwise undefined)
 *                                      3'b100     CTR (AES only, otherwise undefined)
 *                                      3'b101     F8  (AES only, otherwise undefined)
 *                                      Remainder  UNDEFINED
 *             InCp_Key        =        1'b0       Preserve old Cipher Keys
 *                                      1'b1       Load new Cipher Keys from memory to local registers
 *                                                 and recalculate the Arc4 Sbox if Arc4 Cipher chosen;
 *                                                 This overrides LoadArc4State setting.
 *        HASH.HMAC            =        1'b0       Hash without HMAC
 *                                      1'b1       Hash with HMAC
 *                                                 Needs to be set to 0 for GCM and Kasumi F9 authenticators
 *                                                 otherwise unpredictable results will be generated
 *             Hash            =        2'b00      Hash NOP
 *                                      2'b01      MD5
 *                                      2'b10      SHA-1
 *                                      2'b11      SHA-256
 *                                      3'b100     SHA-384
 *                                      3'b101     SHA-512
 *                                      3'b110     GCM
 *                                      3'b111     Kasumi f9
 *             InHs_Key        =        1'b0       Preserve old HMAC Keys
 *                                                 If GCM is selected as authenticator, leaving this bit
 *                                                 at 0 will cause the engine to use the old H value.
 *                                                 It will use the old SCI inside the decoder if
 *                                                 CFBMask[1:0] == 2'b11.
 *                                                 If Kasumi F9 authenticator, using 0 preserves
 *                                                 old keys (IK) in decoder.
 *                                      1'b1       Load new HMAC Keys from memory to local registers
 *                                                 Setting this bit while Cipher=Arc4 and LoadArc4State=1
 *                                                 causes the decoder to load the Arc4 state from the
 *                                                 cacheline following the HMAC keys (Whether HASH.HMAC
 *                                                 is set or not).
 *                                                 If GCM is selected as authenticator, setting this bit
 *                                                 causes both H (16 bytes) and SCI (8 bytes) to be loaded
 *                                                 from memory to the decoder. H will be loaded to the engine
 *                                                 but SCI is only loaded to the engine if CFBMask[1:0] == 2'b11.
 *                                                 If Kasumi F9 authenticator, using 1 loads new keys (IK)
 *                                                 from memory to decoder.
 *    CHECKSUM.CkSum           =        1'b0       CkSum NOP
 *                                      1'b1       INTERNET_CHECKSUM
 *
 *
 *
 */

 /* #define CTRL_DSC_OVERRIDECIPHER */
#define CTL_DSC_OVERRIDECIPHER_OFF       0
#define CTL_DSC_OVERRIDECIPHER_ON        1
#define CTL_DSC_OVERRIDECIPHER_LSB       43
#define CTL_DSC_OVERRIDECIPHER_BITS      ONE_BIT
#define CTL_DSC_OVERRIDECIPHER_MASK      (CTL_DSC_OVERRIDECIPHER_BITS << CTL_DSC_OVERRIDECIPHER_LSB)

/* #define CTRL_DSC_ARC4_WAIT4SAVE */
#define CTL_DSC_ARC4_WAIT4SAVE_OFF       0
#define CTL_DSC_ARC4_WAIT4SAVE_ON        1
#define CTL_DSC_ARC4_WAIT4SAVE_LSB       42
#define CTL_DSC_ARC4_WAIT4SAVE_BITS      ONE_BIT
#define CTL_DSC_ARC4_WAIT4SAVE_MASK      (CTL_DSC_ARC4_WAIT4SAVE_BITS << CTL_DSC_ARC4_WAIT4SAVE_LSB)

/* #define CTRL_DSC_ARC4_SAVESTATE */
#define CTL_DSC_ARC4_SAVESTATE_OFF       0
#define CTL_DSC_ARC4_SAVESTATE_ON        1
#define CTL_DSC_ARC4_SAVESTATE_LSB       41
#define CTL_DSC_ARC4_SAVESTATE_BITS      ONE_BIT
#define CTL_DSC_ARC4_SAVESTATE_MASK      (CTL_DSC_ARC4_SAVESTATE_BITS << CTL_DSC_ARC4_SAVESTATE_LSB)

/* #define CTRL_DSC_ARC4_LOADSTATE */
#define CTL_DSC_ARC4_LOADSTATE_OFF       0
#define CTL_DSC_ARC4_LOADSTATE_ON        1
#define CTL_DSC_ARC4_LOADSTATE_LSB       40
#define CTL_DSC_ARC4_LOADSTATE_BITS      ONE_BIT
#define CTL_DSC_ARC4_LOADSTATE_MASK      (CTL_DSC_ARC4_LOADSTATE_BITS << CTL_DSC_ARC4_LOADSTATE_LSB)

/* #define CTRL_DSC_ARC4_KEYLEN */
#define CTL_DSC_ARC4_KEYLEN_LSB          35
#define CTL_DSC_ARC4_KEYLEN_BITS         FIVE_BITS
#define CTL_DSC_ARC4_KEYLEN_MASK         (CTL_DSC_ARC4_KEYLEN_BITS << CTL_DSC_ARC4_KEYLEN_LSB)

/* #define CTL_DSC_CPHR  (cipher) */
#define CTL_DSC_CPHR_BYPASS       0	/* undefined */
#define CTL_DSC_CPHR_DES          1
#define CTL_DSC_CPHR_3DES         2
#define CTL_DSC_CPHR_AES128       3
#define CTL_DSC_CPHR_AES192       4
#define CTL_DSC_CPHR_AES256       5
#define CTL_DSC_CPHR_ARC4         6
#define CTL_DSC_CPHR_KASUMI_F8    7
#define CTL_DSC_CPHR_LSB          32
#define CTL_DSC_CPHR_BITS         THREE_BITS
#define CTL_DSC_CPHR_MASK         (CTL_DSC_CPHR_BITS << CTL_DSC_CPHR_LSB)

/* #define CTL_DSC_MODE  */
#define CTL_DSC_MODE_ECB          0
#define CTL_DSC_MODE_CBC          1
#define CTL_DSC_MODE_CFB          2
#define CTL_DSC_MODE_OFB          3
#define CTL_DSC_MODE_CTR          4
#define CTL_DSC_MODE_F8           5
#define CTL_DSC_MODE_LSB          29
#define CTL_DSC_MODE_BITS         THREE_BITS
#define CTL_DSC_MODE_MASK         (CTL_DSC_MODE_BITS << CTL_DSC_MODE_LSB)

/* #define CTL_DSC_ICPHR */
#define CTL_DSC_ICPHR_OKY          0	/* Old Keys */
#define CTL_DSC_ICPHR_NKY          1	/* New Keys */
#define CTL_DSC_ICPHR_LSB          28
#define CTL_DSC_ICPHR_BITS         ONE_BIT
#define CTL_DSC_ICPHR_MASK         (CTL_DSC_ICPHR_BITS << CTL_DSC_ICPHR_LSB)

/* #define CTL_DSC_HASHHI */
#define CTL_DSC_HASHHI_LSB          24
#define CTL_DSC_HASHHI_BITS         ONE_BIT
#define CTL_DSC_HASHHI_MASK         (CTL_DSC_HASHHI_BITS << CTL_DSC_HASHHI_LSB)

/* #define CTL_DSC_HMAC */
#define CTL_DSC_HMAC_OFF          0
#define CTL_DSC_HMAC_ON           1
#define CTL_DSC_HMAC_LSB          23
#define CTL_DSC_HMAC_BITS         ONE_BIT
#define CTL_DSC_HMAC_MASK         (CTL_DSC_HMAC_BITS << CTL_DSC_HMAC_LSB)

/* #define CTL_DSC_HASH */
#define CTL_DSC_HASH_NOP          0
#define CTL_DSC_HASH_MD5          1
#define CTL_DSC_HASH_SHA1         2
#define CTL_DSC_HASH_SHA256       3
#define CTL_DSC_HASH_SHA384       4
#define CTL_DSC_HASH_SHA512       5
#define CTL_DSC_HASH_GCM          6
#define CTL_DSC_HASH_KASUMI_F9    7
#define CTL_DSC_HASH_LSB          21
#define CTL_DSC_HASH_BITS         TWO_BITS
#define CTL_DSC_HASH_MASK         (CTL_DSC_HASH_BITS << CTL_DSC_HASH_LSB)

/* #define CTL_DSC_IHASH */
#define CTL_DSC_IHASH_OLD         0
#define CTL_DSC_IHASH_NEW         1
#define CTL_DSC_IHASH_LSB         20
#define CTL_DSC_IHASH_BITS        ONE_BIT
#define CTL_DSC_IHASH_MASK        (CTL_DSC_IHASH_BITS << CTL_DSC_IHASH_LSB)

/* #define CTL_DSC_CKSUM */
#define CTL_DSC_CKSUM_NOP         0
#define CTL_DSC_CKSUM_IP          1
#define CTL_DSC_CKSUM_LSB         16
#define CTL_DSC_CKSUM_BITS        ONE_BIT
#define CTL_DSC_CKSUM_MASK        (CTL_DSC_CKSUM_BITS << CTL_DSC_CKSUM_LSB)


/*
 * Component strcts and unions defining CipherHashInfo_u
 */

/* AES256, (ECB, CBC, OFB, CTR, CFB), HMAC (MD5, SHA-1, SHA-256)      - 96  bytes */
typedef struct AES256HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}            AES256HMAC_t, *AES256HMAC_pt;

/* AES256, (ECB, CBC, OFB, CTR, CFB), HMAC (SHA-384, SHA-512)      - 160  bytes */
typedef struct AES256HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}             AES256HMAC2_t, *AES256HMAC2_pt;

/* AES256, (ECB, CBC, OFB, CTR, CFB), GCM      - 56  bytes */
typedef struct AES256GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}           AES256GCM_t, *AES256GCM_pt;

/* AES256, (ECB, CBC, OFB, CTR, CFB), F9      - 56  bytes */
typedef struct AES256F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t authKey0;
	uint64_t authKey1;
}          AES256F9_t, *AES256F9_pt;

/* AES256, (ECB, CBC, OFB, CTR, CFB), Non-HMAC (MD5, SHA-1, SHA-256)  - 32  bytes */
typedef struct AES256_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
}        AES256_t, *AES256_pt;


/* All AES192 possibilities */

/* AES192, (ECB, CBC, OFB, CTR, CFB), HMAC (MD5, SHA-1, SHA-192)      - 88  bytes */
typedef struct AES192HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}            AES192HMAC_t, *AES192HMAC_pt;

/* AES192, (ECB, CBC, OFB, CTR, CFB), HMAC (SHA-384, SHA-512)      - 152  bytes */
typedef struct AES192HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}             AES192HMAC2_t, *AES192HMAC2_pt;

/* AES192, (ECB, CBC, OFB, CTR, CFB), GCM      - 48  bytes */
typedef struct AES192GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}           AES192GCM_t, *AES192GCM_pt;

/* AES192, (ECB, CBC, OFB, CTR, CFB), F9      - 48  bytes */
typedef struct AES192F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t authKey0;
	uint64_t authKey1;
}          AES192F9_t, *AES192F9_pt;

/* AES192, (ECB, CBC, OFB, CTR, CFB), Non-HMAC (MD5, SHA-1, SHA-192)  - 24  bytes */
typedef struct AES192_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
}        AES192_t, *AES192_pt;


/* All AES128 possibilities */

/* AES128, (ECB, CBC, OFB, CTR, CFB), HMAC (MD5, SHA-1, SHA-128)      - 80  bytes */
typedef struct AES128HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}            AES128HMAC_t, *AES128HMAC_pt;

/* AES128, (ECB, CBC, OFB, CTR, CFB), HMAC (SHA-384, SHA-612)      - 144  bytes */
typedef struct AES128HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}             AES128HMAC2_t, *AES128HMAC2_pt;

/* AES128, (ECB, CBC, OFB, CTR, CFB), GCM      - 40  bytes */
typedef struct AES128GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}           AES128GCM_t, *AES128GCM_pt;

/* AES128, (ECB, CBC, OFB, CTR, CFB), F9      - 48  bytes */
typedef struct AES128F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t authKey0;
	uint64_t authKey1;
}          AES128F9_t, *AES128F9_pt;

/* AES128, (ECB, CBC, OFB, CTR, CFB), Non-HMAC (MD5, SHA-1, SHA-128)  - 16  bytes */
typedef struct AES128_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
}        AES128_t, *AES128_pt;

/* AES128, (OFB F8), Non-HMAC (MD5, SHA-1, SHA-256)  - 32  bytes */
typedef struct AES128F8_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
}          AES128F8_t, *AES128F8_pt;

/* AES128, (OFB F8), HMAC (MD5, SHA-1, SHA-256)  - 96  bytes */
typedef struct AES128F8HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}              AES128F8HMAC_t, *AES128F8HMAC_pt;

/* AES128, (OFB F8), HMAC (SHA-384, SHA-512)  - 160  bytes */
typedef struct AES128F8HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}               AES128F8HMAC2_t, *AES128F8HMAC2_pt;

/* AES192, (OFB F8), Non-HMAC (MD5, SHA-1, SHA-256)  - 48  bytes */
typedef struct AES192F8_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t cipherKeyMask2;
}          AES192F8_t, *AES192F8_pt;

/* AES192, (OFB F8), HMAC (MD5, SHA-1, SHA-256)  - 112 bytes */
typedef struct AES192F8HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t cipherKeyMask2;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}              AES192F8HMAC_t, *AES192F8HMAC_pt;

/* AES192, (OFB F8), HMAC (SHA-384, SHA-512)  - 176 bytes */
typedef struct AES192F8HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t cipherKeyMask2;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}               AES192F8HMAC2_t, *AES192F8HMAC2_pt;

/* AES256, (OFB F8), Non-HMAC (MD5, SHA-1, SHA-256)  - 64  bytes */
typedef struct AES256F8_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t cipherKeyMask2;
	uint64_t cipherKeyMask3;
}          AES256F8_t, *AES256F8_pt;

/* AES256, (OFB F8), HMAC (MD5, SHA-1, SHA-256)  - 128  bytes */
typedef struct AES256F8HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t cipherKeyMask2;
	uint64_t cipherKeyMask3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}              AES256F8HMAC_t, *AES256F8HMAC_pt;

/* AES256, (OFB F8), HMAC (SHA-384, SHA-512)  - 192  bytes */
typedef struct AES256F8HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t cipherKeyMask0;
	uint64_t cipherKeyMask1;
	uint64_t cipherKeyMask2;
	uint64_t cipherKeyMask3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}               AES256F8HMAC2_t, *AES256F8HMAC2_pt;

/* AES256, (F8), GCM      - 40  bytes */
typedef struct AES128F8GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey2;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}             AES128F8GCM_t, *AES128F8GCM_pt;

/* AES256, (F8), GCM      - 48  bytes */
typedef struct AES192F8GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}             AES192F8GCM_t, *AES192F8GCM_pt;

/* AES256, (F8), GCM      - 56  bytes */
typedef struct AES256F8GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}             AES256F8GCM_t, *AES256F8GCM_pt;

/* AES256, (F8), F9      - 40  bytes */
typedef struct AES128F8F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey2;
	uint64_t authKey0;
	uint64_t authKey1;
}            AES128F8F9_t, *AES128F8F9_pt;

/* AES256, (F8), F9      - 48  bytes */
typedef struct AES192F8F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t authKey0;
	uint64_t authKey1;
}            AES192F8F9_t, *AES192F8F9_pt;

/* AES256F8, (F8), F9      - 56  bytes */
typedef struct AES256F8F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t authKey0;
	uint64_t authKey1;
}            AES256F8F9_t, *AES256F8F9_pt;

/* All DES possibilities */

/* DES, (ECB, CBC), HMAC (MD5, SHA-1, SHA-128)              - 72  bytes */
typedef struct DESHMAC_s {
	uint64_t cipherKey0;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}         DESHMAC_t, *DESHMAC_pt;

/* DES, (ECB, CBC), HMAC (SHA-384, SHA-512)              - 136  bytes */
typedef struct DESHMAC2_s {
	uint64_t cipherKey0;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}          DESHMAC2_t, *DESHMAC2_pt;

/* DES, (ECB, CBC), GCM              - 32  bytes */
typedef struct DESGCM_s {
	uint64_t cipherKey0;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}        DESGCM_t, *DESGCM_pt;

/* DES, (ECB, CBC), F9              - 32  bytes */
typedef struct DESF9_s {
	uint64_t cipherKey0;
	uint64_t authKey0;
	uint64_t authKey1;
}       DESF9_t, *DESF9_pt;

/* DES, (ECB, CBC), Non-HMAC (MD5, SHA-1, SHA-128)          - 9   bytes */
typedef struct DES_s {
	uint64_t cipherKey0;
}     DES_t, *DES_pt;


/* All 3DES possibilities */

/* 3DES, (ECB, CBC), HMAC (MD5, SHA-1, SHA-128)             - 88  bytes */
typedef struct DES3HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}          DES3HMAC_t, *DES3HMAC_pt;

/* 3DES, (ECB, CBC), HMAC (SHA-384, SHA-512)             - 152  bytes */
typedef struct DES3HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}           DES3HMAC2_t, *DES3HMAC2_pt;

/* 3DES, (ECB, CBC), GCM             - 48  bytes */
typedef struct DES3GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}         DES3GCM_t, *DES3GCM_pt;

/* 3DES, (ECB, CBC), GCM             - 48  bytes */
typedef struct DES3F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t authKey0;
	uint64_t authKey1;
}        DES3F9_t, *DES3F9_pt;

/* 3DES, (ECB, CBC), Non-HMAC (MD5, SHA-1, SHA-128)         - 24  bytes */
typedef struct DES3_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
}      DES3_t, *DES3_pt;


/* HMAC only - no cipher */

/* HMAC (MD5, SHA-1, SHA-128)                               - 64  bytes */
typedef struct HMAC_s {
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}      HMAC_t, *HMAC_pt;

/* HMAC (SHA-384, SHA-512)                               - 128  bytes */
typedef struct HMAC2_s {
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}       HMAC2_t, *HMAC2_pt;

/* GCM                               - 24  bytes */
typedef struct GCM_s {
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}     GCM_t, *GCM_pt;

/* F9                               - 24  bytes */
typedef struct F9_s {
	uint64_t authKey0;
	uint64_t authKey1;
}    F9_t, *F9_pt;

/* All ARC4 possibilities */
/* ARC4, HMAC (MD5, SHA-1, SHA-256)      - 96 bytes */
typedef struct ARC4HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}          ARC4HMAC_t, *ARC4HMAC_pt;

/* ARC4, HMAC (SHA-384, SHA-512)      - 160 bytes */
typedef struct ARC4HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}           ARC4HMAC2_t, *ARC4HMAC2_pt;

/* ARC4, GCM      - 56 bytes */
typedef struct ARC4GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}         ARC4GCM_t, *ARC4GCM_pt;

/* ARC4, F9      - 56 bytes */
typedef struct ARC4F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t authKey0;
	uint64_t authKey1;
}        ARC4F9_t, *ARC4F9_pt;

/* ARC4, HMAC (MD5, SHA-1, SHA-256)      - 408 bytes (not including 8 bytes from instruction) */
typedef struct ARC4StateHMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t PAD0;
	uint64_t PAD1;
	uint64_t PAD2;
	uint64_t Arc4SboxData0;
	uint64_t Arc4SboxData1;
	uint64_t Arc4SboxData2;
	uint64_t Arc4SboxData3;
	uint64_t Arc4SboxData4;
	uint64_t Arc4SboxData5;
	uint64_t Arc4SboxData6;
	uint64_t Arc4SboxData7;
	uint64_t Arc4SboxData8;
	uint64_t Arc4SboxData9;
	uint64_t Arc4SboxData10;
	uint64_t Arc4SboxData11;
	uint64_t Arc4SboxData12;
	uint64_t Arc4SboxData13;
	uint64_t Arc4SboxData14;
	uint64_t Arc4SboxData15;
	uint64_t Arc4SboxData16;
	uint64_t Arc4SboxData17;
	uint64_t Arc4SboxData18;
	uint64_t Arc4SboxData19;
	uint64_t Arc4SboxData20;
	uint64_t Arc4SboxData21;
	uint64_t Arc4SboxData22;
	uint64_t Arc4SboxData23;
	uint64_t Arc4SboxData24;
	uint64_t Arc4SboxData25;
	uint64_t Arc4SboxData26;
	uint64_t Arc4SboxData27;
	uint64_t Arc4SboxData28;
	uint64_t Arc4SboxData29;
	uint64_t Arc4SboxData30;
	uint64_t Arc4SboxData31;
	uint64_t Arc4IJData;
	uint64_t PAD3;
	uint64_t PAD4;
	uint64_t PAD5;
}               ARC4StateHMAC_t, *ARC4StateHMAC_pt;

/* ARC4, HMAC (SHA-384, SHA-512)      - 480 bytes (not including 8 bytes from instruction) */
typedef struct ARC4StateHMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
	uint64_t PAD0;
	uint64_t PAD1;
	uint64_t PAD2;
	uint64_t Arc4SboxData0;
	uint64_t Arc4SboxData1;
	uint64_t Arc4SboxData2;
	uint64_t Arc4SboxData3;
	uint64_t Arc4SboxData4;
	uint64_t Arc4SboxData5;
	uint64_t Arc4SboxData6;
	uint64_t Arc4SboxData7;
	uint64_t Arc4SboxData8;
	uint64_t Arc4SboxData9;
	uint64_t Arc4SboxData10;
	uint64_t Arc4SboxData11;
	uint64_t Arc4SboxData12;
	uint64_t Arc4SboxData13;
	uint64_t Arc4SboxData14;
	uint64_t Arc4SboxData15;
	uint64_t Arc4SboxData16;
	uint64_t Arc4SboxData17;
	uint64_t Arc4SboxData18;
	uint64_t Arc4SboxData19;
	uint64_t Arc4SboxData20;
	uint64_t Arc4SboxData21;
	uint64_t Arc4SboxData22;
	uint64_t Arc4SboxData23;
	uint64_t Arc4SboxData24;
	uint64_t Arc4SboxData25;
	uint64_t Arc4SboxData26;
	uint64_t Arc4SboxData27;
	uint64_t Arc4SboxData28;
	uint64_t Arc4SboxData29;
	uint64_t Arc4SboxData30;
	uint64_t Arc4SboxData31;
	uint64_t Arc4IJData;
	uint64_t PAD3;
	uint64_t PAD4;
	uint64_t PAD5;
}                ARC4StateHMAC2_t, *ARC4StateHMAC2_pt;

/* ARC4, GCM      - 408 bytes (not including 8 bytes from instruction) */
typedef struct ARC4StateGCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
	uint64_t PAD0;
	uint64_t PAD1;
	uint64_t PAD2;
	uint64_t PAD3;
	uint64_t PAD4;
	uint64_t PAD5;
	uint64_t PAD6;
	uint64_t PAD7;
	uint64_t Arc4SboxData0;
	uint64_t Arc4SboxData1;
	uint64_t Arc4SboxData2;
	uint64_t Arc4SboxData3;
	uint64_t Arc4SboxData4;
	uint64_t Arc4SboxData5;
	uint64_t Arc4SboxData6;
	uint64_t Arc4SboxData7;
	uint64_t Arc4SboxData8;
	uint64_t Arc4SboxData9;
	uint64_t Arc4SboxData10;
	uint64_t Arc4SboxData11;
	uint64_t Arc4SboxData12;
	uint64_t Arc4SboxData13;
	uint64_t Arc4SboxData14;
	uint64_t Arc4SboxData15;
	uint64_t Arc4SboxData16;
	uint64_t Arc4SboxData17;
	uint64_t Arc4SboxData18;
	uint64_t Arc4SboxData19;
	uint64_t Arc4SboxData20;
	uint64_t Arc4SboxData21;
	uint64_t Arc4SboxData22;
	uint64_t Arc4SboxData23;
	uint64_t Arc4SboxData24;
	uint64_t Arc4SboxData25;
	uint64_t Arc4SboxData26;
	uint64_t Arc4SboxData27;
	uint64_t Arc4SboxData28;
	uint64_t Arc4SboxData29;
	uint64_t Arc4SboxData30;
	uint64_t Arc4SboxData31;
	uint64_t Arc4IJData;
	uint64_t PAD8;
	uint64_t PAD9;
	uint64_t PAD10;
}              ARC4StateGCM_t, *ARC4StateGCM_pt;

/* ARC4, F9      - 408 bytes (not including 8 bytes from instruction) */
typedef struct ARC4StateF9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t authKey0;
	uint64_t authKey1;
	uint64_t PAD0;
	uint64_t PAD1;
	uint64_t PAD2;
	uint64_t PAD3;
	uint64_t PAD4;
	uint64_t PAD5;
	uint64_t PAD6;
	uint64_t PAD7;
	uint64_t PAD8;
	uint64_t Arc4SboxData0;
	uint64_t Arc4SboxData1;
	uint64_t Arc4SboxData2;
	uint64_t Arc4SboxData3;
	uint64_t Arc4SboxData4;
	uint64_t Arc4SboxData5;
	uint64_t Arc4SboxData6;
	uint64_t Arc4SboxData7;
	uint64_t Arc4SboxData8;
	uint64_t Arc4SboxData9;
	uint64_t Arc4SboxData10;
	uint64_t Arc4SboxData11;
	uint64_t Arc4SboxData12;
	uint64_t Arc4SboxData13;
	uint64_t Arc4SboxData14;
	uint64_t Arc4SboxData15;
	uint64_t Arc4SboxData16;
	uint64_t Arc4SboxData17;
	uint64_t Arc4SboxData18;
	uint64_t Arc4SboxData19;
	uint64_t Arc4SboxData20;
	uint64_t Arc4SboxData21;
	uint64_t Arc4SboxData22;
	uint64_t Arc4SboxData23;
	uint64_t Arc4SboxData24;
	uint64_t Arc4SboxData25;
	uint64_t Arc4SboxData26;
	uint64_t Arc4SboxData27;
	uint64_t Arc4SboxData28;
	uint64_t Arc4SboxData29;
	uint64_t Arc4SboxData30;
	uint64_t Arc4SboxData31;
	uint64_t Arc4IJData;
	uint64_t PAD9;
	uint64_t PAD10;
	uint64_t PAD11;
}             ARC4StateF9_t, *ARC4StateF9_pt;

/* ARC4, Non-HMAC (MD5, SHA-1, SHA-256)  - 32  bytes */
typedef struct ARC4_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
}      ARC4_t, *ARC4_pt;

/* ARC4, Non-HMAC (MD5, SHA-1, SHA-256)  - 344  bytes (not including 8 bytes from instruction) */
typedef struct ARC4State_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t cipherKey2;
	uint64_t cipherKey3;
	uint64_t PAD0;
	uint64_t PAD1;
	uint64_t PAD2;
	uint64_t Arc4SboxData0;
	uint64_t Arc4SboxData1;
	uint64_t Arc4SboxData2;
	uint64_t Arc4SboxData3;
	uint64_t Arc4SboxData4;
	uint64_t Arc4SboxData5;
	uint64_t Arc4SboxData6;
	uint64_t Arc4SboxData7;
	uint64_t Arc4SboxData8;
	uint64_t Arc4SboxData9;
	uint64_t Arc4SboxData10;
	uint64_t Arc4SboxData11;
	uint64_t Arc4SboxData12;
	uint64_t Arc4SboxData13;
	uint64_t Arc4SboxData14;
	uint64_t Arc4SboxData15;
	uint64_t Arc4SboxData16;
	uint64_t Arc4SboxData17;
	uint64_t Arc4SboxData18;
	uint64_t Arc4SboxData19;
	uint64_t Arc4SboxData20;
	uint64_t Arc4SboxData21;
	uint64_t Arc4SboxData22;
	uint64_t Arc4SboxData23;
	uint64_t Arc4SboxData24;
	uint64_t Arc4SboxData25;
	uint64_t Arc4SboxData26;
	uint64_t Arc4SboxData27;
	uint64_t Arc4SboxData28;
	uint64_t Arc4SboxData29;
	uint64_t Arc4SboxData30;
	uint64_t Arc4SboxData31;
	uint64_t Arc4IJData;
	uint64_t PAD3;
	uint64_t PAD4;
	uint64_t PAD5;
}           ARC4State_t, *ARC4State_pt;

/* Kasumi f8  - 32  bytes */
typedef struct KASUMIF8_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
}          KASUMIF8_t, *KASUMIF8_pt;

/* Kasumi f8 + HMAC (MD5, SHA-1, SHA-256)  - 80  bytes */
typedef struct KASUMIF8HMAC_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
}              KASUMIF8HMAC_t, *KASUMIF8HMAC_pt;

/* Kasumi f8 + HMAC (SHA-384, SHA-512)  - 144 bytes */
typedef struct KASUMIF8HMAC2_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t hmacKey0;
	uint64_t hmacKey1;
	uint64_t hmacKey2;
	uint64_t hmacKey3;
	uint64_t hmacKey4;
	uint64_t hmacKey5;
	uint64_t hmacKey6;
	uint64_t hmacKey7;
	uint64_t hmacKey8;
	uint64_t hmacKey9;
	uint64_t hmacKey10;
	uint64_t hmacKey11;
	uint64_t hmacKey12;
	uint64_t hmacKey13;
	uint64_t hmacKey14;
	uint64_t hmacKey15;
}               KASUMIF8HMAC2_t, *KASUMIF8HMAC2_pt;

/* Kasumi f8 + GCM  - 144 bytes */
typedef struct KASUMIF8GCM_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t GCMH0;
	uint64_t GCMH1;
	uint64_t GCMSCI;
}             KASUMIF8GCM_t, *KASUMIF8GCM_pt;

/* Kasumi f8 + f9  - 32  bytes */
typedef struct KASUMIF8F9_s {
	uint64_t cipherKey0;
	uint64_t cipherKey1;
	uint64_t authKey0;
	uint64_t authKey1;
}            KASUMIF8F9_t, *KASUMIF8F9_pt;

typedef union CipherHashInfo_u {
	AES256HMAC_t infoAES256HMAC;
	AES256_t infoAES256;
	AES192HMAC_t infoAES192HMAC;
	AES192_t infoAES192;
	AES128HMAC_t infoAES128HMAC;
	AES128_t infoAES128;
	DESHMAC_t infoDESHMAC;
	DES_t infoDES;
	DES3HMAC_t info3DESHMAC;
	DES3_t info3DES;
	HMAC_t infoHMAC;
	/* ARC4 */
	ARC4HMAC_t infoARC4HMAC;
	ARC4StateHMAC_t infoARC4StateHMAC;
	ARC4_t infoARC4;
	ARC4State_t infoARC4State;
	/* AES mode F8 */
	AES256F8HMAC_t infoAES256F8HMAC;
	AES256F8_t infoAES256F8;
	AES192F8HMAC_t infoAES192F8HMAC;
	AES192F8_t infoAES192F8;
	AES128F8HMAC_t infoAES128F8HMAC;
	AES128F8_t infoAES128F8;
	/* KASUMI F8 */
	KASUMIF8HMAC_t infoKASUMIF8HMAC;
	KASUMIF8_t infoKASUMIF8;
	/* GCM */
	GCM_t infoGCM;
	AES256F8GCM_t infoAES256F8GCM;
	AES192F8GCM_t infoAES192F8GCM;
	AES128F8GCM_t infoAES128F8GCM;
	AES256GCM_t infoAES256GCM;
	AES192GCM_t infoAES192GCM;
	AES128GCM_t infoAES128GCM;
	DESGCM_t infoDESGCM;
	DES3GCM_t info3DESGCM;
	ARC4GCM_t infoARC4GCM;
	ARC4StateGCM_t infoARC4StateGCM;
	KASUMIF8GCM_t infoKASUMIF8GCM;
	/* HMAC2 */
	HMAC2_t infoHMAC2;
	AES256F8HMAC2_t infoAES256F8HMAC2;
	AES192F8HMAC2_t infoAES192F8HMAC2;
	AES128F8HMAC2_t infoAES128F8HMAC2;
	AES256HMAC2_t infoAES256HMAC2;
	AES192HMAC2_t infoAES192HMAC2;
	AES128HMAC2_t infoAES128HMAC2;
	DESHMAC2_t infoDESHMAC2;
	DES3HMAC2_t info3DESHMAC2;
	ARC4HMAC2_t infoARC4HMAC2;
	ARC4StateHMAC2_t infoARC4StateHMAC2;
	KASUMIF8HMAC2_t infoKASUMIF8HMAC2;
	/* F9 */
	F9_t infoF9;
	AES256F8F9_t infoAES256F8F9;
	AES192F8F9_t infoAES192F8F9;
	AES128F8F9_t infoAES128F8F9;
	AES256F9_t infoAES256F9;
	AES192F9_t infoAES192F9;
	AES128F9_t infoAES128F9;
	DESF9_t infoDESF9;
	DES3F9_t info3DESF9;
	ARC4F9_t infoARC4F9;
	ARC4StateF9_t infoARC4StateF9;
	KASUMIF8F9_t infoKASUMIF8F9;
}                CipherHashInfo_t, *CipherHashInfo_pt;


/*
 *
 *    ControlDescriptor_s datastructure
 *
 */

typedef struct ControlDescriptor_s {
	uint64_t instruction;
	CipherHashInfo_t cipherHashInfo;
}                   ControlDescriptor_t, *ControlDescriptor_pt;




/* **********************************************************************
 *       PacketDescriptor_t
 * **********************************************************************
 */

/*       /--------------------------------------------\
 *       |                                            |
 *       |    New PacketDescriptor_s datastructure    |
 *       |                                            |
 *       \--------------------------------------------/
 *
 *
 *
 *       PacketDescriptor_t.srcLengthIVOffUseIVNext
 *       ------------------------------------------
 *
 *           63           62      61             59    58        57    56       54  53           43
 *  ------------------------------------------------------------------------------------------------
 * || Load HMAC key || Pad Hash || Hash Byte Count || Next || Use IV || IV Offset || Packet length ||   ... CONT ...
 *  ------------------------------------------------------------------------------------------------
 *           1            1           3                1        1          3              11
 *
 *
 *      42          41      40    39                  5     4          3       2
 *      0
 *  ----------------------------------------------------------------------------------------------------
 * ||  NLHMAC || Break || Wait || Segment src address || SRTCP  || Reserved || Global src data offset ||
 *  ----------------------------------------------------------------------------------------------------
 *      1           1       1             35                1           1                  3
 *
 *
 *
 *             Load HMAC key           =        1'b0       Preserve old HMAC key stored in Auth engine (moot if HASH.HMAC == 0)
 *                                              1'b1       Load HMAC key from ID registers at beginning of op
 *                                                         If GCM is selected as authenticator, setting this bit
 *                                                         will cause the H value from ID to be loaded to the engine
 *                                                         If Kasumi F9 is selected as authenticator, setting this bit
 *                                                         will cause the IK value from ID to be loaded to the engine.
 *             Pad Hash                =        1'b0       HASH will assume the data was padded to be a multiple
 *                                                         of 512 bits in length and that the last 64 bit word
 *                                                         expresses the total datalength in bits seen by HASH engine
 *                                              1'b1       The data was not padded to be a multiple of 512 bits in length;
 *                                                         The Hash engine will do its own padding to generate the correct digest.
 *                                                        Ignored by GCM (always does its own padding)
 *             Hash Byte Count                             Number of BYTES on last 64-bit data word to use in digest calculation RELEVANT ONLY IF Pad Hash IS SET
 *                                              3'b000     Use all 8
 *                                              3'b001     Use first (MS) byte only (0-out rest), i.e., 0xddXXXXXXXXXXXXXX
 *                                              3'b010     Use first 2 bytes only (0-out rest), i.e., 0xddddXXXXXXXXXXXX     ... etc
 *             Next                    =        1'b0       Finish (return msg descriptor) at end of operation
 *                                              1'b1       Grab the next PacketDescriptor (i.e. next cache-line) when the current is complete.
 *                                                         This allows for fragmentation/defragmentation and processing of large (>16kB) packets.
 *                                                         The sequence of adjacent PacketDescriptor acts as a contiguous linked list of
 *                                                         pointers to the actual packets with Next==0 on the last PacketDescriptor to end processing.
 *             Use IV                  =        1'b0       On first frag:           Use old IV
 *                                                         On subsequent frags:     Do not write out to DST the (dword) offset data
 *                                              1'b1       On first frag:           Use data @ Segment_address + IV_Offset as IV
 *                                                         On subsequent frags:     Do write out to DST the (dword) offset data
 *             IV Offset               =                   On first frag:           Offset IN NB OF 8 BYTE WORDS (dwords) from beginning of packet
 *                                                                                  (i.e. (Potentially byte-shifted) Segment address) to cipher IV
 *                                                         On subsequent frags:     Offset to beginning of data to process; data to offset won't
 *                                                                                  be given to engines and will be written out to dst in the clear.
 *                                                                                  ON SUBSEQUENT FRAGS, IV_Offset MAY NOT EXCEED 3; LARGER VALUES WILL CAUSE AN ERROR
 *                                                                                  SEE ERROR CONDITIONS BELOW
 *             Packet length           =                   Nb double words to stream in (Including Segment address->CP/IV/Auth/CkSum offsets)
 *                                                         This is the total amount of data (x8 in bytes) read    (+1 dword if "Global src data offset" != 0)
 *                                                         This is the total amount of data (x8 in bytes) written (+1 dword if "Global dst data offset" != 0, if Dst dword offset == 0)
 *                                                         If Packet length == 11'h7ff and (Global src data offset != 0 or Global dst data offset != 0)
 *                                                         the operation is aborted (no mem writes occur)
 *                                                         and the "Insufficient Data To Cipher" error flag is raised
 *             NLHMAC                  =                   No last to hmac. Setting this to 1 will prevent the transmission of the last DWORD
 *                                                         to the authenticator, i.e., the DWORD before last will be designated as last for the purposes of authentication.
 *             Break                   =                   Break a wait (see below) state - causes the operation to be flushed and free descriptor to be returned.
 *                                                         Activated if DFetch blocked by Wait and Wait still active.
 *                                                         AS OF 02/10/2005 THIS FEATURE IS EXPERIMENTAL
 *             Wait                    =                   Setting that bit causes the operation to block in DFetch stage.
 *                                                         DFetch will keep polling the memory location until the bit is reset at which time
 *                                                         the pipe resumes normal operation. This feature is convenient for software dealing with fragmented packets.
 *                                                         AS OF 02/10/2005 THIS FEATURE IS EXPERIMENTAL
 *             Segment src address     =                   35 MSB of pointer to src data (i.e., cache-line aligned)
 *             SRTCP                   =                   Bypass the cipher for the last 4 bytes of data, i.e. the last 4 bytes will be sent to memory
 *                                                         and the authenticator in the clear. Applicable to last packet descriptor andlast frag only.
 *                                                         This accommodates a requirement of SRTCP.
 *             Global src data offset  =                   Nb BYTES to right-shift data by before presenting it to engines
 *                                                         (0-7); allows realignment of byte-aligned, non-double-word aligned data
 *
 *       PacketDescriptor_t.dstDataSettings
 *       ----------------------------------
 *
 *
 *         63       62           60  59   58           56  55         54     53      52          41     40
 *  ------------------------------------------------------------------------------------------------------------
 * || CipherPrefix | Arc4ByteCount | E/D | Cipher_Offset || Hash_Offset | Hash_Src || CkSum_Offset | CkSum_Src ||   ... CONT ...
 *  ------------------------------------------------------------------------------------------------------------
 *         1                3         1          3               2           1             12            1
 *  <-----------------------CIPHER-----------------------><---------HASH-----------><-------CHECKSUM----------->
 *
 *
 *             CipherPrefix            =                   128'b0 will be sent to the selected cipher
 *             KEEP VALUE ON ALL FRAGS                     after the IV is loaded, before the actual data goes in.
 *                                                         The result of that encryption (aka E(K, 0))will be stored
 *                                                         locally and XOR-ed with the auth digest to create the final
 *                                                         digest at the end of the auth OP:
 *                                                         This is covered by the GCM spec
 *                                                                   AesPrefix =  1'b1    -> Force   E=Cipher(K,0) before start of data encr.
 *                                                                                        -> Digest ^= E
 *                                                                   AesPrefix =  1'b0    -> Regular digest
 *                                                         This flag is ignored if no cipher is chosen (Bypass condition)
 *  X0         Arc4ByteCount           =                   Number of BYTES on last 64-bit data word to encrypt
 *                                              3'b000     Encrypt all 8
 *                                              3'b001     Encrypt first (MS) byte only i.e., 0xddXXXXXXXXXXXXXX
 *                                              3'b010     Encrypt first 2 bytes only i.e., 0xddddXXXXXXXXXXXX     ... etc
 *                                                         In reality, all are encrypted, however, the SBOX
 *                                                         is not written past the last byte to encrypt
 *             E/D                     =        1'b0       Decrypt
 *                                              1'b1       Encrypt
 *                                                         Overloaded to also mean IV byte offset for first frag
 *             Cipher_Offset           =                   Nb of words between the first data segment
 *                                                         and word on which to start cipher operation
 *                                                         (64 BIT WORDS !!!)
 *             Hash_Offset             =                   Nb of words between the first data segment
 *                                                         and word on which to start hashing
 *                                                         (64 bit words)
 *             Hash_Src                =        1'b0       DMA channel
 *                                              1'b1       Cipher if word count exceeded Cipher_Offset;
 *                                                         DMA channel otherwise
 *             CkSum_Offset            =                   Nb of words between the first data segment
 *                                                         and word on which to start
 *                                                         checksum calculation (32 BIT WORDS !!!)
 *             CkSum_Src               =        1'b0       DMA channel
 *                                              1'b1       Cipher if word count exceeded Cipher_Offset
 *                                                         DMA channel otherwise
 *             Cipher dst address      =                   35 MSB of pointer to dst location (i.e., cache-line aligned)
 *             Dst dword offset        =                   Nb of double-words to left-shift data from spec'ed Cipher dst address before writing it to memory
 *             Global dst data offset  =                   Nb BYTES to left-shift (double-word boundary aligned) data by before writing it to memory
 *
 *
 *       PacketDescriptor_t.authDstNonceLow
 *       ----------------------------------
 *
 *   63       40  39               5  4                0
 *  -----------------------------------------------------
 * || Nonce_Low || Auth_dst_address || Cipher_Offset_Hi ||
 *  -----------------------------------------------------
 *        24             35                    5
 *
 *
 *
 *             Nonce_Low         =                 Nonce[23:0] 24 least significant bits of 32-bit long nonce
 *                                                 Used by AES in counter mode
 *             Auth_dst_address  =                 35 MSB of pointer to authentication dst location (i.e., cache-line aligned)
 * X0          Cipher_Offset_Hi  =                 On first frag:           5 MSB of 8-bit Cipher_offset; will be concatenated to
 *                                                                          the top of PacketDescriptor_t.dstDataSettings.Cipher_Offset
 *                                                 On subsequent frags:     Ignored
 *
 *
 *       PacketDescriptor_t.ckSumDstNonceHiCFBMaskLLWMask
 *       ------------------------------------------------
 *
 *
 *   63              61  60                 58  57     56  55      48  47      40  39                5  4            0
 *  -------------------------------------------------------------------------------------------------------------------
 * || Hash_Byte_Offset || Packet length bytes || LLWMask || CFB_Mask || Nonce_Hi || CkSum_dst_address || IV_Offset_Hi ||
 *  -------------------------------------------------------------------------------------------------------------------
 *           3                    3                 2          8           8               35                 5
 *
 *
 *                 Hash_Byte_Offset    =              On first frag:            Additional offset in bytes to be added to Hash_Offset
 *                                                                              to obtain the full offset applied to the data before
 *                                                                              submitting it to authenticator
 *                                                    On subsequent frags:      Same
 *                 Packet length bytes =              On one fragment payloads: Ignored (i.e. assumed to be 0, last dword used in its entirety)
 *                                                    On fragments before last: Number of bytes on last fragment dword
 *                                                    On last fragment:         Ignored (i.e. assumed to be 0, last dword used in its entirety)
 *   LLWMask, aka, Last_long_word_mask =   2'b00      Give last 128 bit word from AES engine to auth/cksum/wrbbufer as is - applicable in AES CTR only
 *                                         2'b11      Mask (zero-out) 32 least significant bits
 *                                         2'b10      Mask 64 LSBs
 *                                         2'b01      Mask 96 LSBs
 *                                                    If the GCM authenticator is used, setting LLWMask to 2'b10 or 2'b01
 *                                                    will also prevent the transmission of the last DWORD
 *                                                    to the authenticator, i.e., the DWORD before last will
 *                                                    be designated as last for the purposes of authentication.
 *                 CFB_Mask            =              8 bit mask used by AES in CFB mode
 *                                                    In CTR mode:
 *                                                         CFB_Mask[1:0] =  2'b00   -> Counter[127:0] = {Nonce[31:0],       IV0[63:0], 4'h00000001} (only 1 IV exp
ected) regular CTR
 *                                                                          2'b01   -> Counter[127:0] = {Nonce[31:0],       IV0[63:0], IV1[31:0]}   (2 IV expected
) CCMP
 *                                                                          2'b10   -> Counter[127:0] = {IV1[63:0],         IV0[31:0], Nonce[31:0]} (2 IV expected
) GCM with SCI
 *                                                                          2'b11   -> Counter[127:0] = {IDecode.SCI[63:0], IV0[31:0], Nonce[31:0]} (1 IV expected
) GCM w/o SCI
 *                 Nonce_Hi            =              Nonce[31:24] 8 most significant bits of 32-bit long nonce
 *                                                    Used by AES in counter mode
 *                 CkSum_dst_address   =              35 MSB of pointer to cksum dst location (i.e., cache-line aligned)
 *  X0             IV_Offset_Hi        =              On first frag:           5 MSB of 8-bit IV offset; will be concatenated to
 *                                                                             the top of PacketDescriptor_t.srcLengthIVOffUseIVNext.IV_Offset
 *                                                    On subsequent frags:     Ignored
 */

/* #define PKT_DSC_LOADHMACKEY */
#define PKT_DSC_LOADHMACKEY_OLD   0
#define PKT_DSC_LOADHMACKEY_LOAD  1
#define PKT_DSC_LOADHMACKEY_LSB   63
#define PKT_DSC_LOADHMACKEY_BITS  ONE_BIT
#define PKT_DSC_LOADHMACKEY_MASK  \
 (PKT_DSC_LOADHMACKEY_BITS << PKT_DSC_LOADHMACKEY_LSB)

/* #define PKT_DSC_PADHASH */
#define PKT_DSC_PADHASH_PADDED    0
#define PKT_DSC_PADHASH_PAD       1	/* requires padding */
#define PKT_DSC_PADHASH_LSB       62
#define PKT_DSC_PADHASH_BITS      ONE_BIT
#define PKT_DSC_PADHASH_MASK      (PKT_DSC_PADHASH_BITS << PKT_DSC_PADHASH_LSB)

/* #define PKT_DSC_HASHBYTES */
#define PKT_DSC_HASHBYTES_ALL8    0
#define PKT_DSC_HASHBYTES_MSB     1
#define PKT_DSC_HASHBYTES_MSW     2
#define PKT_DSC_HASHBYTES_LSB     59
#define PKT_DSC_HASHBYTES_BITS    THREE_BITS
#define PKT_DSC_HASHBYTES_MASK    \
 (PKT_DSC_HASHBYTES_BITS << PKT_DSC_HASHBYTES_LSB)

/* #define PKT_DSC_NEXT */
#define PKT_DSC_NEXT_FINISH       0
#define PKT_DSC_NEXT_DO           1
#define PKT_DSC_NEXT_LSB          58
#define PKT_DSC_NEXT_BITS         ONE_BIT
#define PKT_DSC_NEXT_MASK         (PKT_DSC_NEXT_BITS << PKT_DSC_NEXT_LSB)

/* #define PKT_DSC_IV */
#define PKT_DSC_IV_OLD            0
#define PKT_DSC_IV_NEW            1
#define PKT_DSC_IV_LSB            57
#define PKT_DSC_IV_BITS           ONE_BIT
#define PKT_DSC_IV_MASK           (PKT_DSC_IV_BITS << PKT_DSC_IV_LSB)

/* #define PKT_DSC_IVOFF */
#define PKT_DSC_IVOFF_LSB         54
#define PKT_DSC_IVOFF_BITS        THREE_BITS
#define PKT_DSC_IVOFF_MASK        (PKT_DSC_IVOFF_BITS << PKT_DSC_IVOFF_LSB)

/* #define PKT_DSC_PKTLEN */
#define PKT_DSC_PKTLEN_LSB         43
#define PKT_DSC_PKTLEN_BITS        ELEVEN_BITS
#define PKT_DSC_PKTLEN_MASK        (PKT_DSC_PKTLEN_BITS << PKT_DSC_PKTLEN_LSB)

/* #define PKT_DSC_NLHMAC */
#define PKT_DSC_NLHMAC_LSB         42
#define PKT_DSC_NLHMAC_BITS        ONE_BIT
#define PKT_DSC_NLHMAC_MASK        (PKT_DSC_NLHMAC_BITS << PKT_DSC_NLHMAC_LSB)

/* #define PKT_DSC_BREAK */
#define PKT_DSC_BREAK_OLD          0
#define PKT_DSC_BREAK_NEW          1
#define PKT_DSC_BREAK_LSB          41
#define PKT_DSC_BREAK_BITS         ONE_BIT
#define PKT_DSC_BREAK_MASK         (PKT_DSC_BREAK_BITS << PKT_DSC_BREAK_LSB)

/* #define PKT_DSC_WAIT */
#define PKT_DSC_WAIT_OLD           0
#define PKT_DSC_WAIT_NEW           1
#define PKT_DSC_WAIT_LSB           40
#define PKT_DSC_WAIT_BITS          ONE_BIT
#define PKT_DSC_WAIT_MASK          (PKT_DSC_WAIT_BITS << PKT_DSC_WAIT_LSB)

/* #define PKT_DSC_SEGADDR */
#define PKT_DSC_SEGADDR_LSB        5
#define PKT_DSC_SEGADDR_BITS       FOURTY_BITS
#define PKT_DSC_SEGADDR_MASK       \
 (PKT_DSC_SEGADDR_BITS << PKT_DSC_SEGADDR_LSB)

/* #define PKT_DSC_SRTCP */
#define PKT_DSC_SRTCP_OFF       0
#define PKT_DSC_SRTCP_ON        1
#define PKT_DSC_SRTCP_LSB       4
#define PKT_DSC_SRTCP_BITS      ONE_BIT
#define PKT_DSC_SRTCP_MASK      (PKT_DSC_SRTCP_BITS << PKT_DSC_SRTCP_LSB)

#define PKT_DSC_SEGOFFSET_LSB        0
#define PKT_DSC_SEGOFFSET_BITS       THREE_BITS
#define PKT_DSC_SEGOFFSET_MASK       \
 (PKT_DSC_SEGOFFSET_BITS << PKT_DSC_SEGOFFSET_LSB)

/* **********************************************************************
 *       PacketDescriptor_t.dstDataSettings
 * **********************************************************************
 */
/* #define PKT_DSC_ARC4BYTECOUNT */
#define PKT_DSC_ARC4BYTECOUNT_ALL8    0
#define PKT_DSC_ARC4BYTECOUNT_MSB     1
#define PKT_DSC_ARC4BYTECOUNT_MSW     2
#define PKT_DSC_ARC4BYTECOUNT_LSB     60
#define PKT_DSC_ARC4BYTECOUNT_BITS    THREE_BITS
#define PKT_DSC_ARC4BYTECOUNT_MASK    (PKT_DSC_ARC4BYTECOUNT_BITS << PKT_DSC_ARC4BYTECOUNT_LSB)

/* #define PKT_DSC_SYM_OP (symmetric key operation) */
#define PKT_DSC_SYM_OP_DECRYPT    0
#define PKT_DSC_SYM_OP_ENCRYPT    1
#define PKT_DSC_SYM_OP_LSB        59
#define PKT_DSC_SYM_OP_BITS       ONE_BIT
#define PKT_DSC_SYM_OP_MASK       (PKT_DSC_SYM_OP_BITS << PKT_DSC_SYM_OP_LSB)

/* #define PKT_DSC_CPHROFF */
#define PKT_DSC_CPHROFF_LSB        56
#define PKT_DSC_CPHROFF_BITS       THREE_BITS
#define PKT_DSC_CPHROFF_MASK       (PKT_DSC_CPHROFF_BITS << PKT_DSC_CPHROFF_LSB)

/* #define PKT_DSC_HASHOFF */
#define PKT_DSC_HASHOFF_LSB       54
#define PKT_DSC_HASHOFF_BITS      TWO_BITS
#define PKT_DSC_HASHOFF_MASK      (PKT_DSC_HASHOFF_BITS << PKT_DSC_HASHOFF_LSB)

/* #define PKT_DSC_HASHSRC */
#define PKT_DSC_HASHSRC_DMA       0
#define PKT_DSC_HASHSRC_CIPHER    1
#define PKT_DSC_HASHSRC_LSB       53
#define PKT_DSC_HASHSRC_BITS      ONE_BIT
#define PKT_DSC_HASHSRC_MASK      (PKT_DSC_HASHSRC_BITS << PKT_DSC_HASHSRC_LSB)

/* #define PKT_DSC_CKSUMOFF */
#define PKT_DSC_CKSUMOFF_LSB      41
#define PKT_DSC_CKSUMOFF_BITS     TWELVE_BITS
#define PKT_DSC_CKSUMOFF_MASK   (PKT_DSC_CKSUMOFF_BITS << PKT_DSC_CKSUMOFF_LSB)

/* #define PKT_DSC_CKSUMSRC */
#define PKT_DSC_CKSUMSRC_DMA      0
#define PKT_DSC_CKSUMSRC_CIPHER   1
#define PKT_DSC_CKSUMSRC_LSB      40
#define PKT_DSC_CKSUMSRC_BITS     ONE_BIT
#define PKT_DSC_CKSUMSRC_MASK   (PKT_DSC_CKSUMSRC_BITS << PKT_DSC_CKSUMSRC_LSB)

/* #define PKT_DSC_CPHR_DST_ADDR */
#define PKT_DSC_CPHR_DST_ADDR_LSB  0
#define PKT_DSC_CPHR_DST_ADDR_BITS FOURTY_BITS
#define PKT_DSC_CPHR_DST_ADDR_MASK \
     (PKT_DSC_CPHR_DST_ADDR_BITS << PKT_DSC_CPHR_DST_ADDR_LSB)

/* #define PKT_DSC_CPHR_DST_DWOFFSET */
#define PKT_DSC_CPHR_DST_DWOFFSET_LSB   3
#define PKT_DSC_CPHR_DST_DWOFFSET_BITS  TWO_BITS
#define PKT_DSC_CPHR_DST_DWOFFSET_MASK \
          (PKT_DSC_CPHR_DST_DWOFFSET_BITS << PKT_DSC_CPHR_DST_DWOFFSET_LSB)

 /* #define PKT_DSC_CPHR_DST_OFFSET */
#define PKT_DSC_CPHR_DST_OFFSET_LSB   0
#define PKT_DSC_CPHR_DST_OFFSET_BITS  THREE_BITS
#define PKT_DSC_CPHR_DST_OFFSET_MASK \
     (PKT_DSC_CPHR_DST_OFFSET_BITS << PKT_DSC_CPHR_DST_OFFSET_LSB)

/* **********************************************************************
 *       PacketDescriptor_t.authDstNonceLow
 * **********************************************************************
 */
/* #define PKT_DSC_NONCE_LOW */
#define PKT_DSC_NONCE_LOW_LSB  40
#define PKT_DSC_NONCE_LOW_BITS TWENTYFOUR_BITS
#define PKT_DSC_NONCE_LOW_MASK \
         (PKT_DSC_NONCE_LOW_BITS << PKT_DSC_NONCE_LOW_LSB)

/* #define PKT_DSC_AUTH_DST_ADDR */
#define PKT_DSC_AUTH_DST_ADDR_LSB  0
#define PKT_DSC_AUTH_DST_ADDR_BITS FOURTY_BITS
#define PKT_DSC_AUTH_DST_ADDR_MASK \
         (PKT_DSC_AUTH_DST_ADDR_BITS << PKT_DSC_AUTH_DST_ADDR_LSB)

/* #define PKT_DSC_CIPH_OFF_HI */
#define PKT_DSC_CIPH_OFF_HI_LSB      0
#define PKT_DSC_CIPH_OFF_HI_BITS     FIVE_BITS
#define PKT_DSC_CIPH_OFF_HI_MASK   (PKT_DSC_CIPH_OFF_HI_BITS << PKT_DSC_CIPH_OFF_HI_LSB)

/* **********************************************************************
 *       PacketDescriptor_t.ckSumDstNonceHiCFBMaskLLWMask
 * **********************************************************************
 */
/* #define PKT_DSC_HASH_BYTE_OFF */
#define PKT_DSC_HASH_BYTE_OFF_LSB  61
#define PKT_DSC_HASH_BYTE_OFF_BITS THREE_BITS
#define PKT_DSC_HASH_BYTE_OFF_MASK (PKT_DSC_HASH_BYTE_OFF_BITS << PKT_DSC_HASH_BYTE_OFF_LSB)

/* #define PKT_DSC_PKTLEN_BYTES */
#define PKT_DSC_PKTLEN_BYTES_LSB   58
#define PKT_DSC_PKTLEN_BYTES_BITS  THREE_BITS
#define PKT_DSC_PKTLEN_BYTES_MASK  (PKT_DSC_PKTLEN_BYTES_BITS << PKT_DSC_PKTLEN_BYTES_LSB)

/* #define PKT_DSC_LASTWORD */
#define PKT_DSC_LASTWORD_128       0
#define PKT_DSC_LASTWORD_96MASK    1
#define PKT_DSC_LASTWORD_64MASK    2
#define PKT_DSC_LASTWORD_32MASK    3
#define PKT_DSC_LASTWORD_LSB       56
#define PKT_DSC_LASTWORD_BITS      TWO_BITS
#define PKT_DSC_LASTWORD_MASK      (PKT_DSC_LASTWORD_BITS << PKT_DSC_LASTWORD_LSB)

/* #define PKT_DSC_CFB_MASK */
#define PKT_DSC_CFB_MASK_LSB      48
#define PKT_DSC_CFB_MASK_BITS     EIGHT_BITS
#define PKT_DSC_CFB_MASK_MASK     (PKT_DSC_CFB_MASK_BITS << PKT_DSC_CFB_MASK_LSB)

/* #define PKT_DSC_NONCE_HI */
#define PKT_DSC_NONCE_HI_LSB      40
#define PKT_DSC_NONCE_HI_BITS     EIGHT_BITS
#define PKT_DSC_NONCE_HI_MASK (PKT_DSC_NONCE_HI_BITS << PKT_DSC_NONCE_HI_LSB)

/* #define PKT_DSC_CKSUM_DST_ADDR */
#define PKT_DSC_CKSUM_DST_ADDR_LSB  5
#define PKT_DSC_CKSUM_DST_ADDR_BITS THIRTY_FIVE_BITS
#define PKT_DSC_CKSUM_DST_ADDR_MASK (PKT_DSC_CKSUM_DST_ADDR_BITS << PKT_DSC_CKSUM_DST_ADDR_LSB)

/* #define PKT_DSC_IV_OFF_HI */
#define PKT_DSC_IV_OFF_HI_LSB      0
#define PKT_DSC_IV_OFF_HI_BITS     FIVE_BITS
#define PKT_DSC_IV_OFF_HI_MASK   (PKT_DSC_IV_OFF_HI_BITS << PKT_DSC_IV_OFF_HI_LSB)


/* ******************************************************************
 *             Control Error Code and Conditions
 * ******************************************************************
 */
#define CTL_ERR_NONE         0x0000	/* No Error */
#define CTL_ERR_CIPHER_OP    0x0001	/* Unknown Cipher Op */
#define CTL_ERR_MODE         0x0002	/* Unknown or Not Allowed Mode */
#define CTL_ERR_CHKSUM_SRC   0x0004	/* Unknown CkSum Src - UNUSED */
#define CTL_ERR_CFB_MASK     0x0008	/* Forbidden CFB Mask - UNUSED */
#define CTL_ERR_OP           0x0010	/* Unknown Ctrl Op - UNUSED */
#define CTL_ERR_UNDEF1       0x0020	/* UNUSED */
#define CTL_ERR_UNDEF2       0x0040	/* UNUSED */
#define CTL_ERR_DATA_READ    0x0080	/* Data Read Error */
#define CTL_ERR_DESC_CTRL    0x0100	/* Descriptor Ctrl Field Error */

#define CTL_ERR_TIMEOUT      0x1000	/* Message Response Timeout */

/* ******************************************************************
 *             Data Error Code and Conditions
 * ******************************************************************
 */
#define DATA_ERR_NONE        0x0000	/* No Error */
#define DATA_ERR_LEN_CIPHER  0x0001	/* Not Enough Data To Cipher */
#define DATA_ERR_IV_ADDR     0x0002	/* Illegal IV Loacation */
#define DATA_ERR_WD_LEN_AES  0x0004	/* Illegal Nb Words To AES */
#define DATA_ERR_BYTE_COUNT  0x0008	/* Illegal Pad And ByteCount Spec */
#define DATA_ERR_LEN_CKSUM   0x0010	/* Not Enough Data To CkSum */
#define DATA_ERR_OP          0x0020	/* Unknown Data Op */
#define DATA_ERR_UNDEF1      0x0040	/* UNUSED */
#define DATA_ERR_READ        0x0080	/* Data Read Error */
#define DATA_ERR_WRITE       0x0100	/* Data Write Error */


/*
 * Common Descriptor
 * NOTE:  Size of struct is size of cacheline.
 */

typedef struct OperationDescriptor_s {
	uint64_t phys_self;
	uint32_t stn_id;
	uint32_t flags;
	uint32_t cpu;
	uint32_t seq_num;
	uint64_t vaddr;
}                     OperationDescriptor_t, *OperationDescriptor_pt;


/*
 * This defines the security data descriptor format
 */
typedef struct PacketDescriptor_s {
	uint64_t srcLengthIVOffUseIVNext;
	uint64_t dstDataSettings;
	uint64_t authDstNonceLow;
	uint64_t ckSumDstNonceHiCFBMaskLLWMask;
}                  PacketDescriptor_t, *PacketDescriptor_pt;

typedef struct {
	uint8_t *user_auth;
	uint8_t *user_src;
	uint8_t *user_dest;
	uint8_t *user_state;
	uint8_t *kern_auth;
	uint8_t *kern_src;
	uint8_t *kern_dest;
	uint8_t *kern_state;
	uint8_t *aligned_auth;
	uint8_t *aligned_src;
	uint8_t *aligned_dest;
	uint8_t *aligned_state;
}      xlr_sec_drv_user_t, *xlr_sec_drv_user_pt;

typedef struct symkey_desc {
	OperationDescriptor_t op_ctl;	/* size is cacheline */
	PacketDescriptor_t pkt_desc[2];	/* size is cacheline  */
	ControlDescriptor_t ctl_desc;	/* makes this aligned */
	uint64_t control;	/* message word0 */
	uint64_t data;		/* message word1 */
	uint64_t ctl_result;
	uint64_t data_result;
	struct symkey_desc *alloc;	/* real allocated addr */
	xlr_sec_drv_user_t user;
	                 //volatile atomic_t flag_complete;
	       //struct semaphore sem_complete;
	        //wait_queue_t submit_wait;

	uint8_t *next_src_buf;
	uint32_t next_src_len;

	uint8_t *next_dest_buf;
	uint32_t next_dest_len;

	uint8_t *next_auth_dest;
	uint8_t *next_cksum_dest;

	void *ses;
}           symkey_desc_t, *symkey_desc_pt;


/*
 * **************************************************************************
 *                                 RSA Block
 * **************************************************************************
 */

/*
 *                                 RSA and ECC Block
 *                                 =================
 *
 * A 2-word message ring descriptor is used to pass all information
 * pertaining to the RSA or ECC operation:
 *
 *  63  61 60         54     53     52      40 39          5 4                 3 2                      0
 *  -----------------------------------------------------------------------------------------------------
 * | Ctrl |  Op Class   | Valid Op | Op Ctrl0 | Source Addr | Software Scratch0 | Global src data offset |
 *  -----------------------------------------------------------------------------------------------------
 *    3         7           1           13         35                 2                     3
 *
 *
 *  63  61 60            54     53         52             51     50      40 39        5 4                 3 2                      0
 *  --------------------------------------------------------------------------------------------------------------------------------
 * | Ctrl | Destination Id | WRB_COH | WRB_L2ALLOC | DF_L2ALLOC | Op Ctrl1 | Dest Addr | Software Scratch1 | Global dst data offset |
 *  --------------------------------------------------------------------------------------------------------------------------------
 *    3            7            1          1              1          11         35                2                     3
 *
 *
 *             Op Class                =        7'h0_0     Modular exponentiation
 *                                              7'h0_1     ECC (including prime modular ops and binary GF ops)
 *                                              REMAINDER  UNDEF
 *
 *             Valid Op                =        1'b1       Will cause operation to start; descriptors sent back at end of operation
 *                                              1'b0       No operation performed; descriptors sent back right away
 *
 *                                                                   RSA                 ECC
 *                                                                   ===                 ===
 *             Op Ctrl0                =                             BlockWidth[1]	 {TYPE[6:0], FUNCTION[5:0]}
 *                                                                   LoadConstant[1]
 *                                                                   ExponentWidth[10:0]
 *                                               RSA Only
 *                                               ========
 *                                               Block Width             =        1'b1       1024 bit op
 *                                                                       =        1'b0       512  bit op
 *                                               Load Constant           =        1'b1       Load constant from data structure
 *                                                                                1'b0       Preserve old constant (this assumes
 *                                                                                           Source Addr points to RSAData_pt->Exponent
 *                                                                                           or that the length of Constant is 0)
 *                                               Exponent Width          =                   11-bit expression of exponent width EXPRESSED IN NUMBER OF BITS
 *
 *                                               ECC Only
 *                                               ========
 *
 *                                               TYPE      = 7'h0_0 ECC prime 160
 *                                                           7'h0_1 ECC prime 192
 *                                                           7'h0_2 ECC prime 224
 *                                                           7'h0_3 ECC prime 256
 *                                                           7'h0_4 ECC prime 384
 *                                                           7'h0_5 ECC prime 512
 *
 *                                                           7'h0_6 through 7'h1_f  UNDEF
 *
 *                                                           7'h2_0 ECC bin   163
 *                                                           7'h2_1 ECC bin   191
 *                                                           7'h2_2 ECC bin   233
 *
 *                                                           7'h2_3 through 7'h6_f  UNDEF
 *
 *                                                           7'h7_0 ECC UC load
 *
 *                                                           7'b7_1 through 7'b7_f  UNDEF
 *
 *                                                                   Prime field                                    Binary field
 *                                                                   ===========                                    ============
 *                                               FUNCTION  = 6'h0_0  Point multiplication     R = k.P               Point multiplication       R = k.P
 *                                                           6'h0_1  Point addition           R = P + Q             Binary GF inversion        C(x) = 1 / A(x) mod F(x)
 *                                                           6'h0_2  Point double             R = 2 x P             Binary GF multiplication   C(x) = B(x) * A(x) mod F(x)
 *                                                           6'h0_3  Point verification       R ?                   Binary GF addition         C(x) = B(x) + A(x) mod F(x)
 *                                                           6'h0_4  Modular addition         c = x + y mod m	    UNDEF
 *                                                           6'h0_5  Modular substraction     c = x - y mod m	    UNDEF
 *                                                           6'h0_6  Modular multiplication   c = x * y mod m       UNDEF
 *                                                           6'h0_7  Modular division         c = x / y mod m       UNDEF
 *                                                           6'h0_8  Modular inversion        c = 1 / y mod m       UNDEF
 *                                                           6'h0_9  Modular reduction        c = x mod m           UNDEF
 *
 *                                                           6'h0_a
 *                                                           through UNDEF                                          UNDEF
 *                                                           6'h3_f
 *
 *             Source Addr             =                   35 MSB of pointer to source address (i.e., cache-line aligned)
 *
 *             Software Scratch0       =                   Two bit field ignored by engine and returned as is in free descriptor
 *
 *             Global src data offset  =                   Nb BYTES to right-shift data by before presenting it to engines
 *                                                         (0-7); allows realignment of byte-aligned, non-double-word aligned data
 *
 *                                                                   RSA                 ECC
 *                                                                   ===                 ===
 *             OpCtrl1                 =                             ModulusWidth[10:0]  Not used
 *                                               RSA Only
 *                                               ========
 *                                               Modulus Width           =                   11-bit expression of modulus width EXPRESSED IN NUMBER OF BITS
 *
 *             Dest Addr               =                   35 MSB of pointer to destination address (i.e., cache-line aligned)
 *
 *             Software Scratch1       =                   Two bit field ignored by engine and returned as is in free descriptor
 *
 *             Global dst data offset  =                   Nb BYTES to left-shift (double-word boundary aligned) data by before writing it to memory
 *
 *
 */

/*
 * ECC data formats
 */

/**********************************************************
 *                                                        *
 *     ECC prime data formats                             *
 *                                                        *
 **********************************************************
 *
 *
 *  The size of all quantities below is that of the precision
 *  of the chosen op (160, 192, ...) ROUNDED UP to a multiple
 *  of 8 bytes, i.e., 3 dwords (160, 192), 4 dwords (224, 256)
 *  6 dwords (384) and 8 dwords (512) and padded with zeroes
 *  when necessary.
 *
 *  The only exception to this is the key quantity (k) which
 *  needs to be rounded up to 32 bytes in all cases and padded
 *  with zeroes; therefore the key needs to be 4 dwords (160, 192,
 *  224, 256) or 8 dwords (384, 512)
 *
 *  The total lengths in dwords that are read and in
 *  bytes that are written, for each operation and
 *  length group, are specified at the bottom of each
 *  datastructure.
 *
 *  In all that follows, m is the modulus and cst is the constant,
 *  cst = 2 ^ (2*length + 4) mod m . a and b are the curve
 *  parameters.
 *
 *  0) UC load
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   Dword_0                 N/A
 *                 .
 *                 .
 *                 .
 *                 Dword_331
 *                 332 dw
 *
 *  1) Point multiplication       R(x_r, y_r) = k . P(x_p, y_p)
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x_p      dst+glb_off->  x_r
 *                 x_p                     y_r
 *                 y_p			   2x(3/4/6/8)=
 *                 y_p			   6/8/12/16 dw
 *                 a
 *                 k
 *                 m
 *                 cst
 *                 7x(3/4/6/8)+(4/4/8/8)=
 *                 25/32/50/64 dw
 *
 *  2) Point addition             R(x_r, y_r) = P(x_p, y_p) + Q(x_q, y_q)
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x_p      dst+glb_off->  x_r
 *                 y_p                     y_r
 *                 x_q			   2x(3/4/6/8)=
 *                 y_q			   6/8/12/16 dw
 *                 a
 *                 m
 *                 cst
 *                 7x(3/4/6/8)=
 *                 21/28/42/56 dw
 *
 *  3) Point double               R(x_r, y_r) = 2 . P(x_p, y_p)
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x_p      dst+glb_off->  x_r
 *                 y_p                     y_r
 *                 a			   2x(3/4/6/8)=
 *                 m			   6/8/12/16 dw
 *                 cst
 *                 5x(3/4/6/8)=
 *                 15/20/30/40 dw
 *
 *  4) Point verification         Is_On_Curve = P(x_p, y_p) on curve ? 1 : 0
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x_p      dst+glb_off->  Is_On_Curve
 *                 y_p			   1 dw
 *                 a
 *                 b
 *                 m
 *                 cst
 *                 6x(3/4/6/8)=
 *                 18/24/36/48 dw
 *
 *  5) Modular addition           c = x + y mod m
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x        dst+glb_off->  c
 *                 y			   3/4/6/8 dw
 *                 m
 *                 3x(3/4/6/8)=
 *                 9/12/18/24 dw
 *
 *  6) Modular substraction       c = x - y mod m
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x        dst+glb_off->  c
 *                 y			   3/4/6/8 dw
 *                 m
 *                 3x(3/4/6/8)=
 *                 9/12/18/24 dw
 *
 *  7) Modular multiplication     c = x * y mod m
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x        dst+glb_off->  c
 *                 y			   3/4/6/8 dw
 *                 m
 *                 cst
 *                 4x(3/4/6/8)=
 *                 12/16/24/32 dw
 *
 *  8) Modular division           c = x / y mod m
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   y        dst+glb_off->  c
 *                 x			   3/4/6/8 dw
 *                 m
 *                 3x(3/4/6/8)=
 *                 9/12/18/24 dw
 *
 *  9) Modular inversion          c = 1 / y mod m
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   y        dst+glb_off->  c
 *                 m			   3/4/6/8 dw
 *                 2x(3/4/6/8)=
 *                 6/8/12/16 dw
 *
 *  10) Modular reduction         c = x mod m
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   x        dst+glb_off->  c
 *                 m			   3/4/6/8 dw
 *                 2x(3/4/6/8)=
 *                 6/8/12/16 dw
 *
 */

/**********************************************************
 *                                                        *
 *     ECC binary data formats                            *
 *                                                        *
 **********************************************************
 *
 *
 *  The size of all quantities below is that of the precision
 *  of the chosen op (163, 191, 233) ROUNDED UP to a multiple
 *  of 8 bytes, i.e. 3 dwords for (163, 191) and 4 dwords for
 *  (233), padded with zeroes as necessary.
 *
 *  The total lengths in dwords that are read and written,
 *  for each operation and length group, are specified
 *  at the bottom of each datastructure.
 *  In all that follows, b is the curve parameter.
 *
 *  1) Point multiplication       R(x_r, y_r) = k . P(x_p, y_p)
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   b        dst+glb_off->  x_r
 *                 k                       y_r
 *                 x_p    		   2x(3/4)
 *                 y_p			   6/8 dw
 *                 4x(3/4)=
 *                 12/16 dw
 *
 *  2) Binary GF inversion        C(x) = 1 / A(x) mod F(x)
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   A        dst+glb_off->  C
 *		   1x(3/4)=                1x(3/4)
 *                 3/4 dw		   3/4 dw
 *
 *  3) Binary GF multiplication   C(x) = B(x) * A(x) mod F(x)
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   A        dst+glb_off->  C
 *                 B                       1x(3/4)
 *		   2x(3/4)=		   3/4 dw
 *                 6/8 dw
 *
 *  4) Binary GF addition         C(x) = B(x) + A(x) mod F(x)
 *
 *                 DATA IN                 DATA OUT
 *                 =======                 ========
 * src+glb_off->   A        dst+glb_off->  C
 *                 B                       1x(3/4)
 *		   2x(3/4)=		   3/4 dw
 *                 6/8dw
 *
 */

/*
 * RSA data format
 */

/*
 * IMPORTANT NOTE:
 *
 * As specified in the datastructures below,
 * the engine assumes all data (including
 * exponent and modulus) to be adjacent on
 * dword boundaries, e.g.,
 *
 * Operation length = 512 bits
 * Exponent  length = 16  bits
 * Modulus   length = 512 bits
 *
 * The engine expects to read:
 *
 *   63                    0
 *   -----------------------
 *  |                       | Constant0
 *   -----------------------
 *  |                       | Constant1
 *   -----------------------
 *  |                       | Constant2
 *   -----------------------
 *  |                       | Constant3
 *   -----------------------
 *  |                       | Constant4
 *   -----------------------
 *  |                       | Constant5
 *   -----------------------
 *  |                       | Constant6
 *   -----------------------
 *  |                       | Constant7
 *   -----------------------
 *  |      IGNORED    |B1|B0| Exponent0    (Exponent length = 16 bits = 2 bytes, so only 2 least significant bytes of exponent used)
 *   -----------------------
 *  |                       | Modulus0
 *   -----------------------
 *  |                       | Modulus1
 *   -----------------------
 *  |                       | Modulus2
 *   -----------------------
 *  |                       | Modulus3
 *   -----------------------
 *  |                       | Modulus4
 *   -----------------------
 *  |                       | Modulus5
 *   -----------------------
 *  |                       | Modulus6
 *   -----------------------
 *  |                       | Modulus7
 *   -----------------------
 *  |                       | Message0
 *   -----------------------
 *  |                       | Message1
 *   -----------------------
 *  |                       | Message2
 *   -----------------------
 *  |                       | Message3
 *   -----------------------
 *  |                       | Message4
 *   -----------------------
 *  |                       | Message5
 *   -----------------------
 *  |                       | Message6
 *   -----------------------
 *  |                       | Message7
 *   -----------------------
 *
 */

/* #define PUBKEY_CTL_CTL */
#define PUBKEY_CTL_CTL_LSB         61
#define PUBKEY_CTL_CTL_BITS        THREE_BITS
#define PUBKEY_CTL_CTL_MASK        (PUBKEY_CTL_CTL_BITS << PUBKEY_CTL_CTL_LSB)

/* #define PUBKEY_CTL_OP_CLASS */
#define PUBKEY_CTL_OP_CLASS_RSA    0
#define PUBKEY_CTL_OP_CLASS_ECC    1
#define PUBKEY_CTL_OP_CLASS_LSB    54
#define PUBKEY_CTL_OP_CLASS_BITS   SEVEN_BITS
#define PUBKEY_CTL_OP_CLASS_MASK   (PUBKEY_CTL_OP_CLASS_BITS << PUBKEY_CTL_OP_CLASS_LSB)

/* #define PUBKEY_CTL_VALID */
#define PUBKEY_CTL_VALID_FALSE     0
#define PUBKEY_CTL_VALID_TRUE      1
#define PUBKEY_CTL_VALID_LSB       53
#define PUBKEY_CTL_VALID_BITS      ONE_BIT
#define PUBKEY_CTL_VALID_MASK      \
 (PUBKEY_CTL_VALID_BITS << PUBKEY_CTL_VALID_LSB)

/* #define PUBKEY_CTL_ECC_TYPE */
#define PUBKEY_CTL_ECC_TYPE_PRIME_160    0
#define PUBKEY_CTL_ECC_TYPE_PRIME_192    1
#define PUBKEY_CTL_ECC_TYPE_PRIME_224    2
#define PUBKEY_CTL_ECC_TYPE_PRIME_256    3
#define PUBKEY_CTL_ECC_TYPE_PRIME_384    4
#define PUBKEY_CTL_ECC_TYPE_PRIME_512    5
#define PUBKEY_CTL_ECC_TYPE_BIN_163      0x20
#define PUBKEY_CTL_ECC_TYPE_BIN_191      0x21
#define PUBKEY_CTL_ECC_TYPE_BIN_233      0x22
#define PUBKEY_CTL_ECC_TYPE_UC_LOAD      0x70
#define PUBKEY_CTL_ECC_TYPE_LSB    46
#define PUBKEY_CTL_ECC_TYPE_BITS   SEVEN_BITS
#define PUBKEY_CTL_ECC_TYPE_MASK   (PUBKEY_CTL_ECC_TYPE_BITS << PUBKEY_CTL_ECC_TYPE_LSB)

/* #define PUBKEY_CTL_ECC_FUNCTION */
#define PUBKEY_CTL_ECC_FUNCTION_NOP          0
#define PUBKEY_CTL_ECC_FUNCTION_POINT_MUL    0
#define PUBKEY_CTL_ECC_FUNCTION_POINT_ADD    1
#define PUBKEY_CTL_ECC_FUNCTION_POINT_DBL    2
#define PUBKEY_CTL_ECC_FUNCTION_POINT_VFY    3
#define PUBKEY_CTL_ECC_FUNCTION_MODULAR_ADD  4
#define PUBKEY_CTL_ECC_FUNCTION_MODULAR_SUB  5
#define PUBKEY_CTL_ECC_FUNCTION_MODULAR_MUL  6
#define PUBKEY_CTL_ECC_FUNCTION_MODULAR_DIV  7
#define PUBKEY_CTL_ECC_FUNCTION_MODULAR_INV  8
#define PUBKEY_CTL_ECC_FUNCTION_MODULAR_RED  9
#define PUBKEY_CTL_ECC_FUNCTION_LSB    40
#define PUBKEY_CTL_ECC_FUNCTION_BITS   SIX_BITS
#define PUBKEY_CTL_ECC_FUNCTION_MASK   (PUBKEY_CTL_ECC_FUNCTION_BITS << PUBKEY_CTL_ECC_FUNCTION_LSB)

/* #define PUBKEY_CTL_BLKWIDTH */
#define PUBKEY_CTL_BLKWIDTH_512    0
#define PUBKEY_CTL_BLKWIDTH_1024   1
#define PUBKEY_CTL_BLKWIDTH_LSB    52
#define PUBKEY_CTL_BLKWIDTH_BITS   ONE_BIT
#define PUBKEY_CTL_BLKWIDTH_MASK   \
 (PUBKEY_CTL_BLKWIDTH_BITS << PUBKEY_CTL_BLKWIDTH_LSB)

/* #define PUBKEY_CTL_LD_CONST */
#define PUBKEY_CTL_LD_CONST_OLD    0
#define PUBKEY_CTL_LD_CONST_NEW    1
#define PUBKEY_CTL_LD_CONST_LSB    51
#define PUBKEY_CTL_LD_CONST_BITS   ONE_BIT
#define PUBKEY_CTL_LD_CONST_MASK   \
 (PUBKEY_CTL_LD_CONST_BITS << PUBKEY_CTL_LD_CONST_LSB)

/* #define PUBKEY_CTL_EXPWIDTH */
#define PUBKEY_CTL_EXPWIDTH_LSB    40
#define PUBKEY_CTL_EXPWIDTH_BITS   ELEVEN_BITS
#define PUBKEY_CTL_EXPWIDTH_MASK   \
 (PUBKEY_CTL_EXPWIDTH_BITS << PUBKEY_CTL_EXPWIDTH_LSB)

/* #define PUBKEY_CTL_SRCADDR */
#define PUBKEY_CTL_SRCADDR_LSB     0
#define PUBKEY_CTL_SRCADDR_BITS    FOURTY_BITS
#define PUBKEY_CTL_SRCADDR_MASK    \
 (PUBKEY_CTL_SRCADDR_BITS << PUBKEY_CTL_SRCADDR_LSB)

/* #define PUBKEY_CTL_SRC_OFFSET */
#define PUBKEY_CTL_SRC_OFFSET_LSB  0
#define PUBKEY_CTL_SRC_OFFSET_BITS THREE_BITS
#define PUBKEY_CTL_SRC_OFFSET_MASK \
 (PUBKEY_CTL_SRC_OFFSET_BITS << PUBKEY_CTL_SRC_OFFSET_LSB)


/* #define PUBKEY_CTL1_CTL */
#define PUBKEY_CTL1_CTL_LSB        61
#define PUBKEY_CTL1_CTL_BITS       THREE_BITS
#define PUBKEY_CTL1_CTL_MASK       (PUBKEY_CTL_CTL_BITS << PUBKEY_CTL_CTL_LSB)

/* #define PUBKEY_CTL1_MODWIDTH */
#define PUBKEY_CTL1_MODWIDTH_LSB   40
#define PUBKEY_CTL1_MODWIDTH_BITS  ELEVEN_BITS
#define PUBKEY_CTL1_MODWIDTH_MASK  \
 (PUBKEY_CTL1_MODWIDTH_BITS << PUBKEY_CTL1_MODWIDTH_LSB)

/* #define PUBKEY_CTL1_DSTADDR */
#define PUBKEY_CTL1_DSTADDR_LSB    0
#define PUBKEY_CTL1_DSTADDR_BITS   FOURTY_BITS
#define PUBKEY_CTL1_DSTADDR_MASK   \
 (PUBKEY_CTL1_DSTADDR_BITS << PUBKEY_CTL1_DSTADDR_LSB)

/* #define PUBKEY_CTL1_DST_OFFSET */
#define PUBKEY_CTL1_DST_OFFSET_LSB    0
#define PUBKEY_CTL1_DST_OFFSET_BITS   THREE_BITS
#define PUBKEY_CTL1_DST_OFFSET_MASK   \
 (PUBKEY_CTL1_DST_OFFSET_BITS << PUBKEY_CTL1_DST_OFFSET_LSB)

/*
 * Upon completion of operation, the RSA block returns a 2-word free descriptor
 * in the following format:
 *
 *  63  61 60            54 53   52 51       49  48          40 39             5 4                 3 2                      0
 *  -------------------------------------------------------------------------------------------------------------------------
 * | Ctrl | Destination Id | 2'b00 | Desc Ctrl | Control Error | Source Address | Software Scratch0 | Global src data offset |
 *  -------------------------------------------------------------------------------------------------------------------------
 * | Ctrl | Destination Id | 2'b00 | Desc Ctrl |   Data Error  | Dest Address   | Software Scratch1 | Global dst data offset |
 *  -------------------------------------------------------------------------------------------------------------------------
 *
 * The Control and Data Error codes are enumerated below
 *
 *                                Error conditions
 *                                ================
 *
 *             Control Error Code                  Control Error Condition
 *             ------------------                  -----------------------
 *             9'h000                              No Error
 *             9'h001                              Undefined Op Class
 *             9'h002                              Undefined ECC TYPE       (ECC only)
 *             9'h004                              Undefined ECC FUNCTION   (ECC only)
 *             9'h008                              ECC timeout              (ECC only)
 *             9'h010                              UNUSED
 *             9'h020                              UNUSED
 *             9'h040                              UNUSED
 *             9'h080                              Data Read Error
 *             9'h100                              Descriptor Ctrl Field Error        (D0.Ctrl != SOP || D1.Ctrl != EOP)
 *
 *             Data Error Code                     Data Error Condition
 *             ---------------                     --------------------
 *             9'h000                              No Error
 *             9'h001                              Exponent Width > Block Width (RSA Only)
 *             9'h002                              Modulus Width  > Block Width (RSA Only)
 *             9'h004                              UNUSED
 *             9'h008                              UNUSED
 *             9'h010                              UNUSED
 *             9'h020                              UNUSED
 *             9'h040                              UNUSED
 *             9'h080                              Data Read Error
 *             9'h100                              UNUSED
 */

/*
 * Result Data Word for Message Ring Descriptor
 */

/* #define PUBKEY_RSLT_CTL_CTL */
#define PUBKEY_RSLT_CTL_CTL_LSB        61
#define PUBKEY_RSLT_CTL_CTL_BITS       THREE_BITS
#define PUBKEY_RSLT_CTL_CTL_MASK       \
 (PUBKEY_RSLT_CTL_CTL_BITS << PUBKEY_RSLT_CTL_CTL_LSB)

/* #define PUBKEY_RSLT_CTL_DST_ID */
#define PUBKEY_RSLT_CTL_DST_ID_LSB     54
#define PUBKEY_RSLT_CTL_DST_ID_BITS    SEVEN_BITS
#define PUBKEY_RSLT_CTL_DST_ID_MASK    \
 (PUBKEY_RSLT_CTL_DST_ID_BITS << PUBKEY_RSLT_CTL_DST_ID_LSB)

/* #define PUBKEY_RSLT_CTL_DESC_CTL */
#define PUBKEY_RSLT_CTL_DESC_CTL_LSB   49
#define PUBKEY_RSLT_CTL_DESC_CTL_BITS  THREE_BITS
#define PUBKEY_RSLT_CTL_DESC_CTL_MASK  \
 (PUBKEY_RSLT_CTL_DESC_CTL_BITS << PUBKEY_RSLT_CTL_DESC_CTL_LSB)


/* #define PUBKEY_RSLT_CTL_ERROR */
#define PUBKEY_RSLT_CTL_ERROR_LSB      40
#define PUBKEY_RSLT_CTL_ERROR_BITS     NINE_BITS
#define PUBKEY_RSLT_CTL_ERROR_MASK     \
 (PUBKEY_RSLT_CTL_ERROR_BITS << PUBKEY_RSLT_CTL_ERROR_LSB)

/* #define PUBKEY_RSLT_CTL_SRCADDR */
#define PUBKEY_RSLT_CTL_SRCADDR_LSB    0
#define PUBKEY_RSLT_CTL_SRCADDR_BITS   FOURTY_BITS
#define PUBKEY_RSLT_CTL_SRCADDR_MASK   \
 (PUBKEY_RSLT_CTL_SRCADDR_BITS << PUBKEY_RSLT_CTL_SRCADDR_LSB)


/* #define PUBKEY_RSLT_DATA_CTL */
#define PUBKEY_RSLT_DATA_CTL_LSB       61
#define PUBKEY_RSLT_DATA_CTL_BITS      THREE_BITS
#define PUBKEY_RSLT_DATA_CTL_MASK      \
 (PUBKEY_RSLT_DATA_CTL_BITS << PUBKEY_RSLT_DATA_CTL_LSB)

/* #define PUBKEY_RSLT_DATA_DST_ID */
#define PUBKEY_RSLT_DATA_DST_ID_LSB    54
#define PUBKEY_RSLT_DATA_DST_ID_BITS   SEVEN_BITS
#define PUBKEY_RSLT_DATA_DST_ID_MASK   \
 (PUBKEY_RSLT_DATA_DST_ID_BITS << PUBKEY_RSLT_DATA_DST_ID_LSB)

/* #define PUBKEY_RSLT_DATA_DESC_CTL */
#define PUBKEY_RSLT_DATA_DESC_CTL_LSB  49
#define PUBKEY_RSLT_DATA_DESC_CTL_BITS THREE_BITS
#define PUBKEY_RSLT_DATA_DESC_CTL_MASK \
 (PUBKEY_RSLT_DATA_DESC_CTL_BITS << PUBKEY_RSLT_DATA_DESC_CTL_LSB)

/* #define PUBKEY_RSLT_DATA_ERROR */
#define PUBKEY_RSLT_DATA_ERROR_LSB     40
#define PUBKEY_RSLT_DATA_ERROR_BITS    NINE_BITS
#define PUBKEY_RSLT_DATA_ERROR_MASK    \
 (PUBKEY_RSLT_DATA_ERROR_BITS << PUBKEY_RSLT_DATA_ERROR_LSB)

/* #define PUBKEY_RSLT_DATA_DSTADDR */
#define PUBKEY_RSLT_DATA_DSTADDR_LSB   40
#define PUBKEY_RSLT_DATA_DSTADDR_BITS  FOURTY_BITS
#define PUBKEY_RSLT_DATA_DSTADDR_MASK  \
 (PUBKEY_RSLT_DATA_DSTADDR_BITS << PUBKEY_RSLT_DATA_DSTADDR_LSB)

/*
 * ******************************************************************
 *             RSA Block - Data Error Code and Conditions
 * ******************************************************************
 */

#define PK_CTL_ERR_NONE        0x0000	/* No Error */
#define PK_CTL_ERR_OP_CLASS    0x0001	/* Undefined Op Class */
#define PK_CTL_ERR_ECC_TYPE    0x0002	/* Undefined ECC TYPE (ECC only) */
#define PK_CTL_ERR_ECC_FUNCT   0x0004	/* Undefined ECC FUNCTION   (ECC only) */
#define PK_CTL_ERR_ECC_TIMEOUT 0x0008	/* ECC timeout              (ECC only) */
#define PK_CTL_ERR_READ        0x0080	/* Data Read Error */
#define PK_CTL_ERR_DESC        0x0100	/* Descriptor Ctrl Field Error
					 * (D0.Ctrl != SOP || D1.Ctrl != EOP) */
#define PK_CTL_ERR_TIMEOUT     0x1000	/* Message Responce Timeout */

#define PK_DATA_ERR_NONE       0x0000	/* No Error */
#define PK_DATA_ERR_EXP_WIDTH  0x0001	/* Exponent Width > Block Width */
#define PK_DATA_ERR_MOD_WIDTH  0x0002	/* Modulus Width  > Block Width */
#define PK_DATA_ERR_READ       0x0080	/* Data Read Error */


/*
 * This defines the RSA data format
 */
/*
 * typedef struct RSAData_s {
 *  uint64_t            Constant;
 *  uint64_t            Exponent;
 *  uint64_t            Modulus;
 * uint64_t            Message;
 *} RSAData_t, *RSAData_pt;
 *
 * typedef RSAData_t DHData_t;
 * typedef RSAData_pt DHData_pt;
 */

typedef struct UserPubData_s {
	uint8_t *source;
	uint8_t *user_result;
	uint32_t result_length;
}             UserPubData_t, *UserPubData_pt;

typedef struct pubkey_desc {
	OperationDescriptor_t op_ctl;	/* size is cacheline */
	uint8_t source[1024];
	uint8_t dest[256];	/* 1024 makes cacheline-aligned */
	uint64_t control0;
	uint64_t control1;
	uint64_t ctl_result;
	uint64_t data_result;
	struct pubkey_desc *alloc;
	UserPubData_t kern;	/* ptrs for temp buffers */
	            //volatile atomic_t flag_complete;
	       //struct semaphore sem_complete;
	        //wait_queue_t submit_wait;
}           pubkey_desc_t, *pubkey_desc_pt;

/*
 * KASUMI F8 and F9 use the IV0/IV1 fields :
 *
 *  63 41      40      39   37 36        32 31                                 0
 *  ----------------------------------------------------------------------------
 * |     |FX/DIRECTION|       | F8/BEARER  |              F8/COUNT              | IV0
 *  ----------------------------------------------------------------------------
 *              1                   5                         32
 *
 *  63                                   32 31                                 0
 *  ----------------------------------------------------------------------------
 * |                F9/FRESH               |              F9/COUNT              | IV1
 *  ----------------------------------------------------------------------------
 *                     32                                     32
 */
#endif				/* _XLR_SEC_DESC_H_ */

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