[PATCH 2/3] RFC4106 AES-GCM Driver Using Intel New Instructions

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This patch adds an optimized RFC4106 AES-GCM implementation for 64-bit
kernels. It supports 128-bit AES key size. This leverages the crypto
AEAD interface type to facilitate a combined AES & GCM operation to
be implemented in assembly code. The assembly code leverages Intel(R)
AES New Instructions and the PCLMULQDQ instruction.

Signed-off-by: Adrian Hoban <adrian.hoban@xxxxxxxxx>
Signed-off-by: Tadeusz Struk <tadeusz.struk@xxxxxxxxx>
Signed-off-by: Gabriele Paoloni <gabriele.paoloni@xxxxxxxxx>
Signed-off-by: Aidan O'Mahony <aidan.o.mahony@xxxxxxxxx>
Signed-off-by: Erdinc Ozturk <erdinc.ozturk@xxxxxxxxx>
Signed-off-by: James Guilford <james.guilford@xxxxxxxxx>
Signed-off-by: Edward Clinton <edward.clinton@xxxxxxxxx>
Signed-off-by: Wajdi Feghali <wajdi.k.feghali@xxxxxxxxx>
---
 arch/x86/crypto/aesni-intel_asm.S  | 1112 +++++++++++++++++++++++++++++++++++-
 arch/x86/crypto/aesni-intel_glue.c |  518 +++++++++++++++++-
 2 files changed, 1627 insertions(+), 3 deletions(-)

diff --git a/arch/x86/crypto/aesni-intel_asm.S b/arch/x86/crypto/aesni-intel_asm.S
index ff16756..3950769 100644
--- a/arch/x86/crypto/aesni-intel_asm.S
+++ b/arch/x86/crypto/aesni-intel_asm.S
@@ -8,6 +8,17 @@
  *    Author: Huang Ying <ying.huang@xxxxxxxxx>
  *            Vinodh Gopal <vinodh.gopal@xxxxxxxxx>
  *            Kahraman Akdemir
+ *
+ * Added RFC4106 AES-GCM support for 128-bit keys under the AEAD
+ * interface for 64-bit kernels.
+ *    Authors: Erdinc Ozturk (erdinc.ozturk@xxxxxxxxx)
+ *             Aidan O'Mahony (aidan.o.mahony@xxxxxxxxx)
+ *             Adrian Hoban <adrian.hoban@xxxxxxxxx>
+ *             James Guilford (james.guilford@xxxxxxxxx)
+ *             Gabriele Paoloni <gabriele.paoloni@xxxxxxxxx>
+ *             Tadeusz Struk (tadeusz.struk@xxxxxxxxx)
+ *             Wajdi Feghali (wajdi.k.feghali@xxxxxxxxx)
+ *    Copyright (c) 2010, Intel Corporation.
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
@@ -16,9 +27,50 @@
  */

 #include <linux/linkage.h>
-#include <asm/inst.h>
+
+
+.data
+POLY:   .octa 0xC2000000000000000000000000000001
+TWOONE: .octa 0x00000001000000000000000000000001
+
+# order of these constants should not change.
+# more specifically, ALL_F should follow SHIFT_MASK, and ZERO should follow ALL_F
+
+SHUF_MASK:  .octa 0x000102030405060708090A0B0C0D0E0F
+MASK1:      .octa 0x0000000000000000ffffffffffffffff
+MASK2:      .octa 0xffffffffffffffff0000000000000000
+SHIFT_MASK: .octa 0x0f0e0d0c0b0a09080706050403020100
+ALL_F:      .octa 0xffffffffffffffffffffffffffffffff
+ZERO:       .octa 0x00000000000000000000000000000000
+ONE:        .octa 0x00000000000000000000000000000001
+F_MIN_MASK: .octa 0xf1f2f3f4f5f6f7f8f9fafbfcfdfeff0
+dec:        .octa 0x1
+enc:        .octa 0x2
+

 .text
+#define        STACK_OFFSET    8*3
+#define        HashKey         16*0    // store HashKey <<1 mod poly here
+#define        HashKey_2       16*1    // store HashKey^2 <<1 mod poly here
+#define        HashKey_3       16*2    // store HashKey^3 <<1 mod poly here
+#define        HashKey_4       16*3    // store HashKey^4 <<1 mod poly here
+#define        HashKey_k       16*4    // store XOR of High 64 bits and Low 64 bits of  HashKey <<1 mod poly here (for Karatsuba purposes)
+#define        HashKey_2_k     16*5    // store XOR of High 64 bits and Low 64 bits of  HashKey^2 <<1 mod poly here (for Karatsuba purposes)
+#define        HashKey_3_k     16*6    // store XOR of High 64 bits and Low 64 bits of  HashKey^3 <<1 mod poly here (for Karatsuba purposes)
+#define        HashKey_4_k     16*7    // store XOR of High 64 bits and Low 64 bits of  HashKey^4 <<1 mod poly here (for Karatsuba purposes)
+#define        VARIABLE_OFFSET 16*8
+
+#define arg1 rdi
+#define arg2 rsi
+#define arg3 rdx
+#define arg4 rcx
+#define arg5 r8
+#define arg6 r9
+#define arg7 STACK_OFFSET+8(%r14)
+#define arg8 STACK_OFFSET+16(%r14)
+#define arg9 STACK_OFFSET+24(%r14)
+#define arg10 STACK_OFFSET+32(%r14)
+

 #define STATE1 %xmm0
 #define STATE2 %xmm4
@@ -47,6 +99,1064 @@
 #define T2     %r11
 #define TCTR_LOW T2

+
+/* GHASH_MUL MACRO to implement: Data*HashKey mod (128,127,126,121,0)
+*
+*
+* Input: A and B (128-bits each, bit-reflected)
+* Output: C = A*B*x mod poly, (i.e. >>1 )
+* To compute GH = GH*HashKey mod poly, give HK = HashKey<<1 mod poly as input
+* GH = GH * HK * x mod poly which is equivalent to GH*HashKey mod poly.
+*
+*/
+.macro GHASH_MUL GH HK TMP1 TMP2 TMP3 TMP4 TMP5
+       movdqa    \GH, \TMP1
+       pshufd    $78, \GH, \TMP2
+       pshufd    $78, \HK, \TMP3
+       pxor      \GH, \TMP2            # TMP2 = a1+a0
+       pxor      \HK, \TMP3            # TMP3 = b1+b0
+       pclmulqdq $0x11, \HK, \TMP1     # TMP1 = a1*b1
+       pclmulqdq $0x00, \HK, \GH       # GH = a0*b0
+       pclmulqdq $0x00, \TMP3, \TMP2   # TMP2 = (a0+a1)*(b1+b0)
+       pxor      \GH, \TMP2
+       pxor      \TMP1, \TMP2          # TMP2 = (a0*b0)+(a1*b0)
+       movdqa    \TMP2, \TMP3
+       pslldq    $8, \TMP3             # left shift TMP3 2 DWs
+       psrldq    $8, \TMP2             # right shift TMP2 2 DWs
+       pxor      \TMP3, \GH
+       pxor      \TMP2, \TMP1          # TMP2:GH holds the result of GH*HK
+
+        # first phase of the reduction
+
+       movdqa    \GH, \TMP2
+       movdqa    \GH, \TMP3
+       movdqa    \GH, \TMP4            # copy GH into TMP2,TMP3 and TMP4 in in order to perform independent shifts
+       pslld     $31, \TMP2            # packed right shift <<31
+       pslld     $30, \TMP3            # packed right shift <<30
+       pslld     $25, \TMP4            # packed right shift <<25
+       pxor      \TMP3, \TMP2          # xor the shifted versions
+       pxor      \TMP4, \TMP2
+       movdqa    \TMP2, \TMP5
+       psrldq    $4, \TMP5             # right shift TMP5 1 DW
+       pslldq    $12, \TMP2            # left shift TMP2 3 DWs
+       pxor      \TMP2, \GH
+
+        # second phase of the reduction
+
+       movdqa    \GH,\TMP2             # copy GH into TMP2,TMP3 and TMP4 in in order to perform independent shifts
+       movdqa    \GH,\TMP3
+       movdqa    \GH,\TMP4
+       psrld     $1,\TMP2              # packed left shift >>1
+       psrld     $2,\TMP3              # packed left shift >>2
+       psrld     $7,\TMP4              # packed left shift >>7
+       pxor      \TMP3,\TMP2           # xor the shifted versions
+       pxor      \TMP4,\TMP2
+       pxor      \TMP5, \TMP2
+       pxor      \TMP2, \GH
+       pxor      \TMP1, \GH            # result is in TMP1
+.endm
+
+/*
+* if a = number of total plaintext bytes
+* b = floor(a/16)
+* num_initial_blocks = b mod 4
+* encrypt the initial num_initial_blocks blocks and apply ghash on the ciphertext
+* %r10, %r11, %r12, %rax, %xmm5, %xmm6, %xmm7, %xmm8, %xmm9 registers are clobbered
+* arg1, %arg2, %arg3, %r14 are used as a pointer only, not modified
+*/
+
+.macro INITIAL_BLOCKS num_initial_blocks TMP1 TMP2 TMP3 TMP4 TMP5 XMM0 XMM1 XMM2 XMM3 XMM4 XMMDst TMP6 TMP7 i i_seq operation
+
+       mov        arg7, %r10           # %r10 = AAD
+       mov        arg8, %r12           # %r12 = aadLen
+       mov        %r12, %r11
+       pxor       %xmm\i, %xmm\i
+_get_AAD_loop\num_initial_blocks\operation:
+       movd       (%r10), \TMP1
+       pslldq     $12, \TMP1
+       psrldq     $4, %xmm\i
+       pxor       \TMP1, %xmm\i
+       add        $4, %r10
+       sub        $4, %r12
+       jne        _get_AAD_loop\num_initial_blocks\operation
+       cmp        $16, %r11
+       je         _get_AAD_loop2_done\num_initial_blocks\operation
+       mov        $16, %r12
+_get_AAD_loop2\num_initial_blocks\operation:
+       psrldq     $4, %xmm\i
+       sub        $4, %r12
+       cmp        %r11, %r12
+       jne        _get_AAD_loop2\num_initial_blocks\operation
+_get_AAD_loop2_done\num_initial_blocks\operation:
+       pshufb     SHUF_MASK(%rip), %xmm\i          # byte-reflect the AAD data
+       xor        %r11, %r11                       # initialise the data pointer offset as zero
+
+
+        # start AES for num_initial_blocks blocks
+
+       mov        %arg5, %rax                      # %rax = *Y0
+       movdqu     (%rax), \XMM0                    # XMM0 = Y0
+       pshufb     SHUF_MASK(%rip), \XMM0
+.if \i_seq != 0
+.irpc index, \i_seq
+       paddd      ONE(%rip), \XMM0                 # INCR Y0
+       movdqa     \XMM0, %xmm\index
+       pshufb     SHUF_MASK(%rip), %xmm\index      # perform a 16 byte swap
+.endr
+.irpc index, \i_seq
+       pxor       16*0(%arg1), %xmm\index
+.endr
+.irpc index, \i_seq
+       aesenc     16*1(%rdi), %xmm\index          # Round 1
+.endr
+.irpc index, \i_seq
+       aesenc     16*2(%arg1), %xmm\index          # Round 2
+.endr
+.irpc index, \i_seq
+       aesenc     16*3(%arg1), %xmm\index          # Round 3
+.endr
+.irpc index, \i_seq
+       aesenc     16*4(%arg1), %xmm\index          # Round 4
+.endr
+.irpc index, \i_seq
+       aesenc     16*5(%arg1), %xmm\index          # Round 5
+.endr
+.irpc index, \i_seq
+       aesenc     16*6(%arg1), %xmm\index          # Round 6
+.endr
+.irpc index, \i_seq
+       aesenc     16*7(%arg1), %xmm\index          # Round 7
+.endr
+.irpc index, \i_seq
+       aesenc     16*8(%arg1), %xmm\index          # Round 8
+.endr
+.irpc index, \i_seq
+       aesenc     16*9(%arg1), %xmm\index          # Round 9
+.endr
+.irpc index, \i_seq
+       aesenclast 16*10(%arg1), %xmm\index         # Round 10
+.endr
+.irpc index, \i_seq
+       movdqu     (%arg3 , %r11, 1), \TMP1
+       pxor       \TMP1, %xmm\index
+       movdqu     %xmm\index, (%arg2 , %r11, 1)    # write back plaintext/ciphertext for num_initial_blocks
+       add        $16, %r11
+.if \operation == dec
+       movdqa     \TMP1, %xmm\index
+.endif
+       pshufb     SHUF_MASK(%rip), %xmm\index      # prepare plaintext/ciphertext for GHASH computation
+.endr
+.endif
+       GHASH_MUL  %xmm\i, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
+
+        # apply GHASH on num_initial_blocks blocks
+
+.if \i == 5
+        pxor       %xmm5, %xmm6
+       GHASH_MUL  %xmm6, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
+        pxor       %xmm6, %xmm7
+       GHASH_MUL  %xmm7, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
+        pxor       %xmm7, %xmm8
+       GHASH_MUL  %xmm8, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
+.elseif \i == 6
+        pxor       %xmm6, %xmm7
+       GHASH_MUL  %xmm7, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
+        pxor       %xmm7, %xmm8
+       GHASH_MUL  %xmm8, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
+.elseif \i == 7
+        pxor       %xmm7, %xmm8
+       GHASH_MUL  %xmm8, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
+.endif
+       cmp        $64, %r13
+       jl      _initial_blocks_done\num_initial_blocks\operation   # no need for precomputed values
+/*
+*
+* Precomputations for HashKey parallel with encryption of first 4 blocks.
+* Haskey_i_k holds XORed values of the low and high parts of the Haskey_i
+*/
+       paddd      ONE(%rip), \XMM0              # INCR Y0
+       movdqa     \XMM0, \XMM1
+       pshufb     SHUF_MASK(%rip), \XMM1        # perform a 16 byte swap
+       paddd      ONE(%rip), \XMM0              # INCR Y0
+       movdqa     \XMM0, \XMM2
+       pshufb     SHUF_MASK(%rip), \XMM2        # perform a 16 byte swap
+       paddd      ONE(%rip), \XMM0              # INCR Y0
+       movdqa     \XMM0, \XMM3
+       pshufb     SHUF_MASK(%rip), \XMM3        # perform a 16 byte swap
+       paddd      ONE(%rip), \XMM0              # INCR Y0
+       movdqa     \XMM0, \XMM4
+       pshufb     SHUF_MASK(%rip), \XMM4        # perform a 16 byte swap
+       pxor       16*0(%arg1), \XMM1
+       pxor       16*0(%arg1), \XMM2
+       pxor       16*0(%arg1), \XMM3
+       pxor       16*0(%arg1), \XMM4
+       movdqa     \TMP3, \TMP5
+       pshufd     $78, \TMP3, \TMP1
+       pxor       \TMP3, \TMP1
+       movdqa     \TMP1, HashKey_k(%rsp)
+       GHASH_MUL  \TMP5, \TMP3, \TMP1, \TMP2, \TMP4, \TMP6, \TMP7  # TMP5 = HashKey^2<<1 (mod poly)
+       movdqa     \TMP5, HashKey_2(%rsp)                           # HashKey_2 = HashKey^2<<1 (mod poly)
+       pshufd     $78, \TMP5, \TMP1
+       pxor       \TMP5, \TMP1
+       movdqa     \TMP1, HashKey_2_k(%rsp)
+.irpc index, 1234 # do 4 rounds
+       aesenc     16*\index(%arg1), \XMM1
+       aesenc     16*\index(%arg1), \XMM2
+       aesenc     16*\index(%arg1), \XMM3
+       aesenc     16*\index(%arg1), \XMM4
+.endr
+       GHASH_MUL  \TMP5, \TMP3, \TMP1, \TMP2, \TMP4, \TMP6, \TMP7  # TMP5 = HashKey^3<<1 (mod poly)
+       movdqa     \TMP5, HashKey_3(%rsp)
+       pshufd     $78, \TMP5, \TMP1
+       pxor       \TMP5, \TMP1
+       movdqa     \TMP1, HashKey_3_k(%rsp)
+.irpc index, 56789 # do next 5 rounds
+       aesenc     16*\index(%arg1), \XMM1
+       aesenc     16*\index(%arg1), \XMM2
+       aesenc     16*\index(%arg1), \XMM3
+       aesenc     16*\index(%arg1), \XMM4
+.endr
+       GHASH_MUL  \TMP5, \TMP3, \TMP1, \TMP2, \TMP4, \TMP6, \TMP7  # TMP5 = HashKey^3<<1 (mod poly)
+       movdqa     \TMP5, HashKey_4(%rsp)
+       pshufd     $78, \TMP5, \TMP1
+       pxor       \TMP5, \TMP1
+       movdqa     \TMP1, HashKey_4_k(%rsp)
+       aesenclast 160(%arg1), \XMM1
+       aesenclast 160(%arg1), \XMM2
+       aesenclast 160(%arg1), \XMM3
+       aesenclast 160(%arg1), \XMM4
+       movdqu     16*0(%arg3 , %r11 , 1), \TMP1
+       pxor       \TMP1, \XMM1
+.if \operation == dec
+       movdqu     \XMM1, 16*0(%arg2 , %r11 , 1)
+       movdqa     \TMP1, \XMM1
+.endif
+       movdqu     16*1(%arg3 , %r11 , 1), \TMP1
+       pxor       \TMP1, \XMM2
+.if \operation == dec
+       movdqu     \XMM2, 16*1(%arg2 , %r11 , 1)
+       movdqa     \TMP1, \XMM2
+.endif
+       movdqu     16*2(%arg3 , %r11 , 1), \TMP1
+       pxor       \TMP1, \XMM3
+.if \operation == dec
+       movdqu     \XMM3, 16*2(%arg2 , %r11 , 1)
+       movdqa     \TMP1, \XMM3
+.endif
+       movdqu     16*3(%arg3 , %r11 , 1), \TMP1
+       pxor       \TMP1, \XMM4
+.if \operation == dec
+       movdqu     \XMM4, 16*3(%arg2 , %r11 , 1)
+       movdqa     \TMP1, \XMM4
+.else
+       movdqu     \XMM1, 16*0(%arg2 , %r11 , 1)
+       movdqu     \XMM2, 16*1(%arg2 , %r11 , 1)
+       movdqu     \XMM3, 16*2(%arg2 , %r11 , 1)
+       movdqu     \XMM4, 16*3(%arg2 , %r11 , 1)
+.endif
+       add        $64, %r11
+       pshufb     SHUF_MASK(%rip), \XMM1 # perform a 16 byte swap
+       pxor       \XMMDst, \XMM1         # combine GHASHed value with the corresponding ciphertext
+       pshufb     SHUF_MASK(%rip), \XMM2 # perform a 16 byte swap
+       pshufb     SHUF_MASK(%rip), \XMM3 # perform a 16 byte swap
+       pshufb     SHUF_MASK(%rip), \XMM4 # perform a 16 byte swap
+_initial_blocks_done\num_initial_blocks\operation:
+.endm
+
+/*
+* encrypt 4 blocks at a time
+* ghash the 4 previously encrypted ciphertext blocks
+* arg1, %arg2, %arg3 are used as pointers only, not modified
+* %r11 is the data offset value
+*/
+.macro GHASH_4_ENCRYPT_4_PARALLEL TMP1 TMP2 TMP3 TMP4 TMP5 TMP6 XMM0 XMM1 XMM2 XMM3 XMM4 XMM5 XMM6 XMM7 XMM8 operation
+
+       movdqa    \XMM1, \XMM5
+       movdqa    \XMM2, \XMM6
+       movdqa    \XMM3, \XMM7
+       movdqa    \XMM4, \XMM8
+
+        # multiply TMP5 * HashKey using karatsuba
+
+       movdqa    \XMM5, \TMP4
+       pshufd    $78, \XMM5, \TMP6
+       pxor      \XMM5, \TMP6
+       paddd     ONE(%rip), \XMM0              # INCR CNT
+       movdqa    HashKey_4(%rsp), \TMP5
+       pclmulqdq $0x11, \TMP5, \TMP4           # TMP4 = a1*b1
+       movdqa    \XMM0, \XMM1
+       paddd     ONE(%rip), \XMM0              # INCR CNT
+       movdqa    \XMM0, \XMM2
+       paddd     ONE(%rip), \XMM0              # INCR CNT
+       movdqa    \XMM0, \XMM3
+       paddd     ONE(%rip), \XMM0              # INCR CNT
+       movdqa    \XMM0, \XMM4
+       pshufb    SHUF_MASK(%rip), \XMM1        # perform a 16 byte swap
+       pclmulqdq $0x00, \TMP5, \XMM5           # XMM5 = a0*b0
+       pshufb    SHUF_MASK(%rip), \XMM2        # perform a 16 byte swap
+       pshufb    SHUF_MASK(%rip), \XMM3        # perform a 16 byte swap
+       pshufb    SHUF_MASK(%rip), \XMM4        # perform a 16 byte swap
+       pxor      (%arg1), \XMM1
+       pxor      (%arg1), \XMM2
+       pxor      (%arg1), \XMM3
+       pxor      (%arg1), \XMM4
+       movdqa    HashKey_4_k(%rsp), \TMP5
+       pclmulqdq $0x00, \TMP5, \TMP6           # TMP6 = (a1+a0)*(b1+b0)
+       aesenc    16(%arg1), \XMM1              # Round 1
+       aesenc    16(%arg1), \XMM2
+       aesenc    16(%arg1), \XMM3
+       aesenc    16(%arg1), \XMM4
+       aesenc    32(%arg1), \XMM1              # Round 2
+       aesenc    32(%arg1), \XMM2
+       aesenc    32(%arg1), \XMM3
+       aesenc    32(%arg1), \XMM4
+       movdqa    \XMM6, \TMP1
+       pshufd    $78, \XMM6, \TMP2
+       pxor      \XMM6, \TMP2
+       movdqa    HashKey_3(%rsp), \TMP5
+       pclmulqdq $0x11, \TMP5, \TMP1           # TMP1 = a1 * b1
+       aesenc    48(%arg1), \XMM1              # Round 3
+       aesenc    48(%arg1), \XMM2
+       aesenc    48(%arg1), \XMM3
+       aesenc    48(%arg1), \XMM4
+       pclmulqdq $0x00, \TMP5, \XMM6           # XMM6 = a0*b0
+       aesenc    64(%arg1), \XMM1              # Round 4
+       aesenc    64(%arg1), \XMM2
+       aesenc    64(%arg1), \XMM3
+       aesenc    64(%arg1), \XMM4
+       movdqa    HashKey_3_k(%rsp), \TMP5
+       pclmulqdq $0x00, \TMP5, \TMP2           # TMP2 = (a1+a0)*(b1+b0)
+       aesenc    80(%arg1), \XMM1              # Round 5
+       aesenc    80(%arg1), \XMM2
+       aesenc    80(%arg1), \XMM3
+       aesenc    80(%arg1), \XMM4
+       pxor      \TMP1, \TMP4                  # accumulate the results in TMP4:XMM5, TMP6 holds the middle part
+       pxor      \XMM6, \XMM5
+       pxor      \TMP2, \TMP6
+       movdqa    \XMM7, \TMP1
+       pshufd    $78, \XMM7, \TMP2
+       pxor      \XMM7, \TMP2
+       movdqa    HashKey_2(%rsp ), \TMP5
+
+        # Multiply TMP5 * HashKey using karatsuba
+
+       pclmulqdq $0x11, \TMP5, \TMP1           # TMP1 = a1*b1
+       aesenc    96(%arg1), \XMM1              # Round 6
+       aesenc    96(%arg1), \XMM2
+       aesenc    96(%arg1), \XMM3
+       aesenc    96(%arg1), \XMM4
+       pclmulqdq $0x00, \TMP5, \XMM7           # XMM7 = a0*b0
+       aesenc    112(%arg1), \XMM1             # Round 7
+       aesenc    112(%arg1), \XMM2
+       aesenc    112(%arg1), \XMM3
+       aesenc    112(%arg1), \XMM4
+       movdqa    HashKey_2_k(%rsp), \TMP5
+       pclmulqdq $0x00, \TMP5, \TMP2           # TMP2 = (a1+a0)*(b1+b0)
+       aesenc    128(%arg1), \XMM1             # Round 8
+       aesenc    128(%arg1), \XMM2
+       aesenc    128(%arg1), \XMM3
+       aesenc    128(%arg1), \XMM4
+       pxor      \TMP1, \TMP4                  # accumulate the results in TMP4:XMM5, TMP6 holds the middle part
+       pxor      \XMM7, \XMM5
+       pxor      \TMP2, \TMP6
+
+        # Multiply XMM8 * HashKey
+        # XMM8 and TMP5 hold the values for the two operands
+
+       movdqa    \XMM8, \TMP1
+       pshufd    $78, \XMM8, \TMP2
+       pxor      \XMM8, \TMP2
+       movdqa    HashKey(%rsp), \TMP5
+       pclmulqdq $0x11, \TMP5, \TMP1          # TMP1 = a1*b1
+       aesenc    144(%arg1), \XMM1            # Round 9
+       aesenc    144(%arg1), \XMM2
+       aesenc    144(%arg1), \XMM3
+       aesenc    144(%arg1), \XMM4
+       pclmulqdq $0x00, \TMP5, \XMM8          # XMM8 = a0*b0
+       aesenclast 160(%arg1), \XMM1           # Round 10
+       aesenclast 160(%arg1), \XMM2
+       aesenclast 160(%arg1), \XMM3
+       aesenclast 160(%arg1), \XMM4
+       movdqa    HashKey_k(%rsp), \TMP5
+       pclmulqdq $0x00, \TMP5, \TMP2          # TMP2 = (a1+a0)*(b1+b0)
+       movdqu    (%arg3,%r11,1), \TMP3
+       pxor      \TMP3, \XMM1                 # Ciphertext/Plaintext XOR EK
+.if \operation == dec
+       movdqu    \XMM1, (%arg2,%r11,1)        # Write to plaintext buffer
+       movdqa    \TMP3, \XMM1
+.endif
+       movdqu    16(%arg3,%r11,1), \TMP3
+       pxor      \TMP3, \XMM2                 # Ciphertext/Plaintext XOR EK
+.if \operation == dec
+       movdqu    \XMM2, 16(%arg2,%r11,1)      # Write to plaintext buffer
+       movdqa    \TMP3, \XMM2
+.endif
+       movdqu    32(%arg3,%r11,1), \TMP3
+       pxor      \TMP3, \XMM3                 # Ciphertext/Plaintext XOR EK
+.if \operation == dec
+       movdqu    \XMM3, 32(%arg2,%r11,1)      # Write to plaintext buffer
+       movdqa    \TMP3, \XMM3
+.endif
+       movdqu    48(%arg3,%r11,1), \TMP3
+       pxor      \TMP3, \XMM4                 # Ciphertext/Plaintext XOR EK
+.if \operation == dec
+       movdqu    \XMM4, 48(%arg2,%r11,1)      # Write to plaintext buffer
+       movdqa    \TMP3, \XMM4
+.else
+        movdqu    \XMM1, (%arg2,%r11,1)        # Write to the ciphertext buffer
+        movdqu    \XMM2, 16(%arg2,%r11,1)      # Write to the ciphertext buffer
+        movdqu    \XMM3, 32(%arg2,%r11,1)      # Write to the ciphertext buffer
+        movdqu    \XMM4, 48(%arg2,%r11,1)      # Write to the ciphertext buffer
+.endif
+       pshufb    SHUF_MASK(%rip), \XMM1       # perform a 16 byte swap
+       pshufb    SHUF_MASK(%rip), \XMM2       # perform a 16 byte swap
+       pshufb    SHUF_MASK(%rip), \XMM3       # perform a 16 byte swap
+       pshufb    SHUF_MASK(%rip), \XMM4       # perform a 16 byte sway
+
+       pxor      \TMP4, \TMP1
+       pxor      \XMM8, \XMM5
+       pxor      \TMP6, \TMP2
+       pxor      \TMP1, \TMP2
+       pxor      \XMM5, \TMP2
+       movdqa    \TMP2, \TMP3
+       pslldq    $8, \TMP3                    # left shift TMP3 2 DWs
+       psrldq    $8, \TMP2                    # right shift TMP2 2 DWs
+       pxor      \TMP3, \XMM5
+       pxor      \TMP2, \TMP1                 # accumulate the results in TMP1:XMM5
+
+        # first phase of reduction
+
+       movdqa    \XMM5, \TMP2
+       movdqa    \XMM5, \TMP3
+       movdqa    \XMM5, \TMP4                 # move XMM5 into TMP2, TMP3, TMP4 in order to perform shifts independently
+       pslld     $31, \TMP2                   # packed right shift << 31
+       pslld     $30, \TMP3                   # packed right shift << 30
+       pslld     $25, \TMP4                   # packed right shift << 25
+       pxor      \TMP3, \TMP2                 # xor the shifted versions
+       pxor      \TMP4, \TMP2
+       movdqa    \TMP2, \TMP5
+       psrldq    $4, \TMP5                    # right shift T5 1 DW
+       pslldq    $12, \TMP2                   # left shift T2 3 DWs
+       pxor      \TMP2, \XMM5
+
+        # second phase of reduction
+
+       movdqa    \XMM5,\TMP2                  # make 3 copies of XMM5 into TMP2, TMP3, TMP4
+       movdqa    \XMM5,\TMP3
+       movdqa    \XMM5,\TMP4
+       psrld     $1, \TMP2                    # packed left shift >>1
+       psrld     $2, \TMP3                    # packed left shift >>2
+       psrld     $7, \TMP4                    # packed left shift >>7
+       pxor      \TMP3,\TMP2                  # xor the shifted versions
+       pxor      \TMP4,\TMP2
+       pxor      \TMP5, \TMP2
+       pxor      \TMP2, \XMM5
+       pxor      \TMP1, \XMM5                 # result is in TMP1
+
+       pxor      \XMM5, \XMM1
+.endm
+
+/* GHASH the last 4 ciphertext blocks. */
+.macro GHASH_LAST_4 TMP1 TMP2 TMP3 TMP4 TMP5 TMP6 TMP7 XMM1 XMM2 XMM3 XMM4 XMMDst
+
+        # Multiply TMP6 * HashKey (using Karatsuba)
+
+       movdqa    \XMM1, \TMP6
+       pshufd    $78, \XMM1, \TMP2
+       pxor      \XMM1, \TMP2
+       movdqa    HashKey_4(%rsp), \TMP5
+       pclmulqdq $0x11, \TMP5, \TMP6       # TMP6 = a1*b1
+       pclmulqdq $0x00, \TMP5, \XMM1       # XMM1 = a0*b0
+       movdqa    HashKey_4_k(%rsp), \TMP4
+       pclmulqdq $0x00, \TMP4, \TMP2       # TMP2 = (a1+a0)*(b1+b0)
+       movdqa    \XMM1, \XMMDst
+       movdqa    \TMP2, \XMM1              # result in TMP6, XMMDst, XMM1
+
+        # Multiply TMP1 * HashKey (using Karatsuba)
+
+       movdqa    \XMM2, \TMP1
+       pshufd    $78, \XMM2, \TMP2
+       pxor      \XMM2, \TMP2
+       movdqa    HashKey_3(%rsp), \TMP5
+       pclmulqdq $0x11, \TMP5, \TMP1       # TMP1 = a1*b1
+       pclmulqdq $0x00, \TMP5, \XMM2       # XMM2 = a0*b0
+       movdqa    HashKey_3_k(%rsp), \TMP4
+       pclmulqdq $0x00, \TMP4, \TMP2       # TMP2 = (a1+a0)*(b1+b0)
+       pxor      \TMP1, \TMP6
+       pxor      \XMM2, \XMMDst
+       pxor      \TMP2, \XMM1              # results accumulated in TMP6, XMMDst, XMM1
+
+        # Multiply TMP1 * HashKey (using Karatsuba)
+
+       movdqa    \XMM3, \TMP1
+       pshufd    $78, \XMM3, \TMP2
+       pxor      \XMM3, \TMP2
+       movdqa    HashKey_2(%rsp), \TMP5
+       pclmulqdq $0x11, \TMP5, \TMP1       # TMP1 = a1*b1
+       pclmulqdq $0x00, \TMP5, \XMM3       # XMM3 = a0*b0
+       movdqa    HashKey_2_k(%rsp), \TMP4
+       pclmulqdq $0x00, \TMP4, \TMP2       # TMP2 = (a1+a0)*(b1+b0)
+       pxor      \TMP1, \TMP6
+       pxor      \XMM3, \XMMDst
+       pxor      \TMP2, \XMM1              # results accumulated in TMP6, XMMDst, XMM1
+
+        # Multiply TMP1 * HashKey (using Karatsuba)
+
+       movdqa    \XMM4, \TMP1
+       pshufd    $78, \XMM4, \TMP2
+       pxor      \XMM4, \TMP2
+       movdqa    HashKey(%rsp), \TMP5
+       pclmulqdq $0x11, \TMP5, \TMP1       # TMP1 = a1*b1
+       pclmulqdq $0x00, \TMP5, \XMM4       # XMM4 = a0*b0
+       movdqa    HashKey_k(%rsp), \TMP4
+       pclmulqdq $0x00, \TMP4, \TMP2       # TMP2 = (a1+a0)*(b1+b0)
+       pxor      \TMP1, \TMP6
+       pxor      \XMM4, \XMMDst
+       pxor      \XMM1, \TMP2
+       pxor      \TMP6, \TMP2
+       pxor      \XMMDst, \TMP2            # middle section of the temp results combined as in karatsuba algorithm
+       movdqa    \TMP2, \TMP4
+       pslldq    $8, \TMP4                 # left shift TMP4 2 DWs
+       psrldq    $8, \TMP2                 # right shift TMP2 2 DWs
+       pxor      \TMP4, \XMMDst
+       pxor      \TMP2, \TMP6              # TMP6:XMMDst holds the result of the accumulated carry-less multiplications
+
+        # first phase of the reduction
+
+       movdqa    \XMMDst, \TMP2
+       movdqa    \XMMDst, \TMP3
+       movdqa    \XMMDst, \TMP4            # move XMMDst into TMP2, TMP3, TMP4 in order to perform 3 shifts independently
+       pslld     $31, \TMP2                # packed right shifting << 31
+       pslld     $30, \TMP3                # packed right shifting << 30
+       pslld     $25, \TMP4                # packed right shifting << 25
+       pxor      \TMP3, \TMP2              # xor the shifted versions
+       pxor      \TMP4, \TMP2
+       movdqa    \TMP2, \TMP7
+       psrldq    $4, \TMP7                 # right shift TMP7 1 DW
+       pslldq    $12, \TMP2                # left shift TMP2 3 DWs
+       pxor      \TMP2, \XMMDst
+
+        # second phase of the reduction
+
+       movdqa    \XMMDst, \TMP2            # make 3 copies of XMMDst for doing 3 shift operations
+       movdqa    \XMMDst, \TMP3
+       movdqa    \XMMDst, \TMP4
+       psrld     $1, \TMP2                 # packed left shift >> 1
+       psrld     $2, \TMP3                 # packed left shift >> 2
+       psrld     $7, \TMP4                 # packed left shift >> 7
+       pxor      \TMP3, \TMP2              # xor the shifted versions
+       pxor      \TMP4, \TMP2
+       pxor      \TMP7, \TMP2
+       pxor      \TMP2, \XMMDst
+       pxor      \TMP6, \XMMDst            # reduced result is in XMMDst
+.endm
+
+/* Encryption of a single block done*/
+.macro ENCRYPT_SINGLE_BLOCK XMM0
+
+       pxor    (%arg1), \XMM0
+       aesenc  16(%arg1), \XMM0
+       aesenc  32(%arg1), \XMM0
+       aesenc  48(%arg1), \XMM0
+       aesenc  64(%arg1), \XMM0
+       aesenc  80(%arg1), \XMM0
+       aesenc  96(%arg1), \XMM0
+       aesenc  112(%arg1), \XMM0
+       aesenc  128(%arg1), \XMM0
+       aesenc  144(%arg1), \XMM0
+       aesenclast 160(%arg1), \XMM0
+.endm
+
+
+/**********************************************************************************************
+*void aesni_gcm_dec(void *aes_ctx,               // AES Key schedule. Starts on a 16 byte boundary.
+*                   u8 *out,                     // Plaintext output. Encrypt in-place is allowed.
+*                   const u8 *in,                // Ciphertext input
+*                   u64 plaintext_len,           // Length of data in bytes for decryption.
+*                   u8 *iv,                      // Pre-counter block j0: 4 byte salt (from Security Association)
+*                                                // concatenated with 8 byte Initialisation Vector (from IPSec ESP Payload)
+*                                                // concatenated with 0x00000001. 16-byte aligned pointer.
+*                   u8 *hash_subkey,             // H, the Hash sub key input. Data starts on a 16-byte boundary.
+*                   const u8 *aad,               // Additional Authentication Data (AAD)
+*                   u64 aad_len,                 // Length of AAD in bytes. With RFC4106 this is going to be 8 or 12 bytes
+*                   u8  *auth_tag,               // Authenticated Tag output. The driver will compare this to the
+*                                                // given authentication tag and only return the plaintext if they match.
+*                   u64 auth_tag_len);           // Authenticated Tag Length in bytes. Valid values are 16 (most likely), 12 or 8.
+*
+*
+*
+* Assumptions:
+*
+* keys:
+*       keys are pre-expanded and aligned to 16 bytes. we are using the first set of 11 keys in the data structure void *aes_ctx
+*
+*
+* iv:
+*       0                   1                   2                   3
+*       0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                             Salt  (From the SA)               |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                     Initialization Vector                     |
+*       |         (This is the sequence number from IPSec header)       |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                              0x1                              |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*
+*
+*
+* AAD:
+*       AAD padded to 128 bits with 0
+*       for example, assume AAD is a u32 vector
+*
+*       if AAD is 8 bytes:
+*       AAD[3] = {A0, A1};
+*       padded AAD in xmm register = {A1 A0 0 0}
+*
+*       0                   1                   2                   3
+*       0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                               SPI (A1)                        |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                     32-bit Sequence Number (A0)               |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                              0x0                              |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*
+*                                       AAD Format with 32-bit Sequence Number
+*
+*       if AAD is 12 bytes:
+*       AAD[3] = {A0, A1, A2};
+*       padded AAD in xmm register = {A2 A1 A0 0}
+*
+*       0                   1                   2                   3
+*       0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                               SPI (A2)                        |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                 64-bit Extended Sequence Number {A1,A0}       |
+*       |                                                               |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                              0x0                              |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*
+*                                       AAD Format with 64-bit Extended Sequence Number
+*
+*
+* aadLen:
+*       from the definition of the spec, aadLen can only be 8 or 12 bytes. The code supports 16 too but for other sizes, the code will fail.
+*
+* TLen:
+*       from the definition of the spec, TLen can only be 8, 12 or 16 bytes. For other sizes, the code will fail.
+*
+* poly = x^128 + x^127 + x^126 + x^121 + 1
+*
+*******************************************************************************************/
+
+ENTRY(aesni_gcm_dec)
+       push    %r12
+       push    %r13
+       push    %r14
+       mov     %rsp, %r14
+/*
+* states of %xmm registers %xmm6:%xmm15 not saved
+* all %xmm registers are clobbered
+*/
+       sub     $VARIABLE_OFFSET, %rsp
+       and     $~63, %rsp                        # align rsp to 64 bytes
+       mov     %arg6, %r12
+       movdqu  (%r12), %xmm13                    # %xmm13 = HashKey
+       pshufb  SHUF_MASK(%rip), %xmm13
+
+        # Precompute HashKey<<1 (mod poly) from the hash key (this is required for GHASH)
+
+       movdqa  %xmm13, %xmm2
+       psllq   $1, %xmm13
+       psrlq   $63, %xmm2
+       movdqa  %xmm2, %xmm1
+       pslldq  $8, %xmm2
+       psrldq  $8, %xmm1
+       por     %xmm2, %xmm13
+
+        # Reduction
+
+       pshufd  $0x24, %xmm1, %xmm2
+       pcmpeqd TWOONE(%rip), %xmm2
+       pand    POLY(%rip), %xmm2
+       pxor    %xmm2, %xmm13                   # %xmm13 holds the HashKey<<1 (mod poly)
+
+
+        # Decrypt first few blocks
+
+       movdqa  %xmm13, HashKey(%rsp)           # store HashKey<<1 (mod poly)
+       mov     %arg4, %r13                     # save the number of bytes of plaintext/ciphertext
+       and     $-16, %r13                      # %r13 = %r13 - (%r13 mod 16)
+       mov     %r13, %r12
+       and     $(3<<4), %r12
+       jz      _initial_num_blocks_is_0_decrypt
+       cmp     $(2<<4), %r12
+       jb      _initial_num_blocks_is_1_decrypt
+       je      _initial_num_blocks_is_2_decrypt
+_initial_num_blocks_is_3_decrypt:
+       INITIAL_BLOCKS  3, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 5, 678, dec
+       sub     $48, %r13
+       jmp     _initial_blocks_decrypted
+_initial_num_blocks_is_2_decrypt:
+       INITIAL_BLOCKS  2, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 6, 78, dec
+       sub     $32, %r13
+       jmp     _initial_blocks_decrypted
+_initial_num_blocks_is_1_decrypt:
+       INITIAL_BLOCKS  1, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 7, 8, dec
+       sub     $16, %r13
+       jmp     _initial_blocks_decrypted
+_initial_num_blocks_is_0_decrypt:
+       INITIAL_BLOCKS  0, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 8, 0, dec
+_initial_blocks_decrypted:
+       cmp     $0, %r13
+       je      _zero_cipher_left_decrypt
+       sub     $64, %r13
+       je      _four_cipher_left_decrypt
+_decrypt_by_4:
+       GHASH_4_ENCRYPT_4_PARALLEL      %xmm9, %xmm10, %xmm11, %xmm12, %xmm13, %xmm14, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm5, %xmm6, %xmm7, %xmm8, dec
+       add     $64, %r11
+       sub     $64, %r13
+       jne     _decrypt_by_4
+_four_cipher_left_decrypt:
+       GHASH_LAST_4    %xmm9, %xmm10, %xmm11, %xmm12, %xmm13, %xmm14, %xmm15, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8
+_zero_cipher_left_decrypt:
+       mov     %arg4, %r13
+       and     $15, %r13                               # %r13 = arg4 (mod 16)
+       je      _multiple_of_16_bytes_decrypt
+
+        # Handle the last <16 byte block seperately
+
+       paddd   ONE(%rip), %xmm0                        # increment CNT to get Yn
+       pshufb  SHUF_MASK(%rip), %xmm0
+       ENCRYPT_SINGLE_BLOCK    %xmm0                   # E(K, Yn)
+       sub     $16, %r11
+       add     %r13, %r11
+       movdqu  (%arg3,%r11,1), %xmm1                   # recieve the last <16 byte block
+       lea     SHIFT_MASK+16(%rip), %r12
+       sub     %r13, %r12                              # adjust the shuffle mask pointer to be able to shift 16-%r13 bytes
+                                                        # (%r13 is the number of bytes in plaintext mod 16)
+       movdqu  (%r12), %xmm2                           # get the appropriate shuffle mask
+       pshufb  %xmm2, %xmm1                            # right shift 16-%r13 butes
+       movdqa  %xmm1, %xmm2
+       pxor    %xmm1, %xmm0                            # Ciphertext XOR E(K, Yn)
+       movdqu  ALL_F-SHIFT_MASK(%r12), %xmm1           # get the appropriate mask to mask out top 16-%r13 bytes of %xmm0
+       pand    %xmm1, %xmm0                            # mask out top 16-%r13 bytes of %xmm0
+       pand    %xmm1, %xmm2
+       pshufb  SHUF_MASK(%rip),%xmm2
+       pxor    %xmm2, %xmm8
+       GHASH_MUL       %xmm8, %xmm13, %xmm9, %xmm10, %xmm11, %xmm5, %xmm6      # GHASH computation for the last <16 byte block
+       sub     %r13, %r11
+       add     $16, %r11
+
+        # output %r13 bytes
+
+       movq    %xmm0, %rax
+       cmp     $8, %r13
+       jle     _less_than_8_bytes_left_decrypt
+       mov     %rax, (%arg2 , %r11, 1)
+       add     $8, %r11
+       psrldq  $8, %xmm0
+       movq    %xmm0, %rax
+       sub     $8, %r13
+_less_than_8_bytes_left_decrypt:
+       mov     %al,  (%arg2, %r11, 1)
+       add     $1, %r11
+       shr     $8, %rax
+       sub     $1, %r13
+       jne     _less_than_8_bytes_left_decrypt
+_multiple_of_16_bytes_decrypt:
+       mov     arg8, %r12                # %r13 = aadLen (number of bytes)
+       shl     $3, %r12                  # convert into number of bits
+       movd    %r12d, %xmm15             # len(A) in %xmm15
+       shl     $3, %arg4                 # len(C) in bits (*128)
+       movq    %arg4, %xmm1
+       pslldq  $8, %xmm15                # %xmm15 = len(A)||0x0000000000000000
+       pxor    %xmm1, %xmm15             # %xmm15 = len(A)||len(C)
+       pxor    %xmm15, %xmm8
+       GHASH_MUL       %xmm8, %xmm13, %xmm9, %xmm10, %xmm11, %xmm5, %xmm6      # final GHASH computation
+       pshufb  SHUF_MASK(%rip), %xmm8
+       mov     %arg5, %rax               # %rax = *Y0
+       movdqu  (%rax), %xmm0             # %xmm0 = Y0
+       ENCRYPT_SINGLE_BLOCK    %xmm0     # E(K, Y0)
+       pxor    %xmm8, %xmm0
+_return_T_decrypt:
+       mov     arg9, %r10                # %r10 = authTag
+       mov     arg10, %r11               # %r11 = auth_tag_len
+       cmp     $16, %r11
+       je      _T_16_decrypt
+       cmp     $12, %r11
+       je      _T_12_decrypt
+_T_8_decrypt:
+       movq    %xmm0, %rax
+       mov     %rax, (%r10)
+       jmp     _return_T_done_decrypt
+_T_12_decrypt:
+       movq    %xmm0, %rax
+       mov     %rax, (%r10)
+       psrldq  $8, %xmm0
+       movd    %xmm0, %eax
+       mov     %eax, 8(%r10)
+       jmp     _return_T_done_decrypt
+_T_16_decrypt:
+       movdqu  %xmm0, (%r10)
+_return_T_done_decrypt:
+       mov     %r14, %rsp
+       pop     %r14
+       pop     %r13
+       pop     %r12
+       ret
+
+
+/***************************************************************************************************
+* void aesni_gcm_enc(void *aes_ctx,               // AES Key schedule. Starts on a 16 byte boundary.
+*                    u8 *out,                    // Ciphertext output. Encrypt in-place is allowed.
+*                    const u8 *in,               // Plaintext input
+*                    u64 plaintext_len,          // Length of data in bytes for encryption.
+*                    u8 *iv,                     // Pre-counter block j0: 4 byte salt (from Security Association)
+*                                                // concatenated with 8 byte Initialisation Vector (from IPSec ESP Payload)
+*                                                // concatenated with 0x00000001. 16-byte aligned pointer.
+*                    u8 *hash_subkey,            // H, the Hash sub key input. Data starts on a 16-byte boundary.
+*                    const u8 *aad,              // Additional Authentication Data (AAD)
+*                    u64 aad_len,                // Length of AAD in bytes. With RFC4106 this is going to be 8 or 12 bytes
+*                    u8 *auth_tag,               // Authenticated Tag output.
+*                    u64 auth_tag_len);          // Authenticated Tag Length in bytes. Valid values are 16 (most likely), 12 or 8.
+*
+*
+*
+* Assumptions:
+*
+* keys:
+*       keys are pre-expanded and aligned to 16 bytes. we are using the first set of 11 keys in the data structure void *aes_ctx
+*
+*
+* iv:
+*       0                   1                   2                   3
+*       0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                             Salt  (From the SA)               |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                     Initialization Vector                     |
+*       |         (This is the sequence number from IPSec header)       |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                              0x1                              |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*
+*
+*
+* AAD:
+*       AAD padded to 128 bits with 0
+*       for example, assume AAD is a u32 vector
+*
+*       if AAD is 8 bytes:
+*       AAD[3] = {A0, A1};
+*       padded AAD in xmm register = {A1 A0 0 0}
+*
+*       0                   1                   2                   3
+*       0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                               SPI (A1)                        |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                     32-bit Sequence Number (A0)               |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                              0x0                              |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*
+*                                       AAD Format with 32-bit Sequence Number
+*
+*       if AAD is 12 bytes:
+*       AAD[3] = {A0, A1, A2};
+*       padded AAD in xmm register = {A2 A1 A0 0}
+*
+*       0                   1                   2                   3
+*       0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                               SPI (A2)                        |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                 64-bit Extended Sequence Number {A1,A0}       |
+*       |                                                               |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*       |                              0x0                              |
+*       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+*
+*                                       AAD Format with 64-bit Extended Sequence Number
+*
+*
+* aadLen:
+*       from the definition of the spec, aadLen can only be 8 or 12 bytes. The code supports 16 too but for other sizes, the code will fail.
+*
+* TLen:
+*       from the definition of the spec, TLen can only be 8, 12 or 16 bytes. For other sizes, the code will fail.
+*
+* poly = x^128 + x^127 + x^126 + x^121 + 1
+**************************************************************************************************************************/
+ENTRY(aesni_gcm_enc)
+       push    %r12
+       push    %r13
+       push    %r14
+       mov     %rsp, %r14
+#
+# states of %xmm registers %xmm6:%xmm15 not saved
+# all %xmm registers are clobbered
+#
+       sub     $VARIABLE_OFFSET, %rsp
+       and     $~63, %rsp
+       mov     %arg6, %r12
+       movdqu  (%r12), %xmm13
+       pshufb  SHUF_MASK(%rip), %xmm13
+
+        # precompute HashKey<<1 mod poly from the HashKey (required for GHASH)
+
+       movdqa  %xmm13, %xmm2
+       psllq   $1, %xmm13
+       psrlq   $63, %xmm2
+       movdqa  %xmm2, %xmm1
+       pslldq  $8, %xmm2
+       psrldq  $8, %xmm1
+       por     %xmm2, %xmm13
+
+        # reduce HashKey<<1
+
+       pshufd  $0x24, %xmm1, %xmm2
+       pcmpeqd TWOONE(%rip), %xmm2
+       pand    POLY(%rip), %xmm2
+       pxor    %xmm2, %xmm13
+       movdqa  %xmm13, HashKey(%rsp)
+       mov     %arg4, %r13               # %xmm13 holds HashKey<<1 (mod poly)
+       and     $-16, %r13
+       mov     %r13, %r12
+
+        # Encrypt first few blocks
+
+       and     $(3<<4), %r12
+       jz      _initial_num_blocks_is_0_encrypt
+       cmp     $(2<<4), %r12
+       jb      _initial_num_blocks_is_1_encrypt
+       je      _initial_num_blocks_is_2_encrypt
+_initial_num_blocks_is_3_encrypt:
+       INITIAL_BLOCKS  3, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 5, 678, enc
+       sub     $48, %r13
+       jmp     _initial_blocks_encrypted
+_initial_num_blocks_is_2_encrypt:
+       INITIAL_BLOCKS  2, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 6, 78, enc
+       sub     $32, %r13
+       jmp     _initial_blocks_encrypted
+_initial_num_blocks_is_1_encrypt:
+       INITIAL_BLOCKS  1, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 7, 8, enc
+       sub     $16, %r13
+       jmp     _initial_blocks_encrypted
+_initial_num_blocks_is_0_encrypt:
+       INITIAL_BLOCKS  0, %xmm9, %xmm10, %xmm13, %xmm11, %xmm12, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8, %xmm5, %xmm6, 8, 0, enc
+_initial_blocks_encrypted:
+
+        # Main loop - Encrypt remaining blocks
+
+       cmp     $0, %r13
+       je      _zero_cipher_left_encrypt
+       sub     $64, %r13
+       je      _four_cipher_left_encrypt
+_encrypt_by_4_encrypt:
+       GHASH_4_ENCRYPT_4_PARALLEL      %xmm9, %xmm10, %xmm11, %xmm12, %xmm13, %xmm14, %xmm0, %xmm1, %xmm2, %xmm3, %xmm4, %xmm5, %xmm6, %xmm7, %xmm8, enc
+       add     $64, %r11
+       sub     $64, %r13
+       jne     _encrypt_by_4_encrypt
+_four_cipher_left_encrypt:
+       GHASH_LAST_4    %xmm9, %xmm10, %xmm11, %xmm12, %xmm13, %xmm14, %xmm15, %xmm1, %xmm2, %xmm3, %xmm4, %xmm8
+_zero_cipher_left_encrypt:
+       mov     %arg4, %r13
+       and     $15, %r13                       # %r13 = arg4 (mod 16)
+       je      _multiple_of_16_bytes_encrypt
+
+         # Handle the last <16 Byte block seperately
+
+       paddd   ONE(%rip), %xmm0                # INCR CNT to get Yn
+       pshufb  SHUF_MASK(%rip), %xmm0
+       ENCRYPT_SINGLE_BLOCK    %xmm0           # Encrypt(K, Yn)
+       sub     $16, %r11
+       add     %r13, %r11
+       movdqu  (%arg3,%r11,1), %xmm1           # recieve the last <16 byte blocks
+       lea     SHIFT_MASK+16(%rip), %r12
+       sub     %r13, %r12                      # adjust the shuffle mask pointer to be able to shift 16-r13 bytes
+                                                # (%r13 is the number of bytes in plaintext mod 16)
+       movdqu  (%r12), %xmm2                   # get the appropriate shuffle mask
+       pshufb  %xmm2, %xmm1                    # shift right 16-r13 byte
+       pxor    %xmm1, %xmm0                    # Plaintext XOR Encrypt(K, Yn)
+       movdqu  ALL_F-SHIFT_MASK(%r12), %xmm1   # get the appropriate mask to mask out top 16-r13 bytes of xmm0
+       pand    %xmm1, %xmm0                    # mask out top 16-r13 bytes of xmm0
+
+       pshufb  SHUF_MASK(%rip),%xmm0
+       pxor    %xmm0, %xmm8
+       GHASH_MUL %xmm8, %xmm13, %xmm9, %xmm10, %xmm11, %xmm5, %xmm6    # GHASH computation for the last <16 byte block
+       sub     %r13, %r11
+       add     $16, %r11
+       pshufb  SHUF_MASK(%rip), %xmm0          # shuffle xmm0 back to output as ciphertext
+
+        # Output %r13 bytes
+
+       movq    %xmm0, %rax
+       cmp     $8, %r13
+       jle     _less_than_8_bytes_left_encrypt
+       mov     %rax, (%arg2 , %r11, 1)
+       add     $8, %r11
+       psrldq  $8, %xmm0
+       movq    %xmm0, %rax
+       sub     $8, %r13
+_less_than_8_bytes_left_encrypt:
+       mov     %al,  (%arg2, %r11, 1)
+       add     $1, %r11
+       shr     $8, %rax
+       sub     $1, %r13
+       jne     _less_than_8_bytes_left_encrypt
+_multiple_of_16_bytes_encrypt:
+       mov     arg8, %r12                     # %r12 = addLen (number of bytes)
+       shl     $3, %r12
+       movd    %r12d, %xmm15                  # len(A) in %xmm15
+       shl     $3, %arg4                      # len(C) in bits (*128)
+       movq    %arg4, %xmm1
+       pslldq  $8, %xmm15                     # %xmm15 = len(A)||0x0000000000000000
+       pxor    %xmm1, %xmm15                  # %xmm15 = len(A)||len(C)
+       pxor    %xmm15, %xmm8
+       GHASH_MUL       %xmm8, %xmm13, %xmm9, %xmm10, %xmm11, %xmm5, %xmm6      # final GHASH computation
+
+       pshufb  SHUF_MASK(%rip), %xmm8         # perform a 16 byte swap
+       mov     %arg5, %rax                    # %rax  = *Y0
+       movdqu  (%rax), %xmm0                  # %xmm0 = Y0
+       ENCRYPT_SINGLE_BLOCK    %xmm0          # Encrypt(K, Y0)
+       pxor    %xmm8, %xmm0
+_return_T_encrypt:
+       mov     arg9, %r10                     # %r10 = authTag
+       mov     arg10, %r11                    # %r11 = auth_tag_len
+       cmp     $16, %r11
+       je      _T_16_encrypt
+       cmp     $12, %r11
+       je      _T_12_encrypt
+_T_8_encrypt:
+       movq    %xmm0, %rax
+       mov     %rax, (%r10)
+       jmp     _return_T_done_encrypt
+_T_12_encrypt:
+       movq    %xmm0, %rax
+       mov     %rax, (%r10)
+       psrldq  $8, %xmm0
+       movd    %xmm0, %eax
+       mov     %eax, 8(%r10)
+       jmp     _return_T_done_encrypt
+_T_16_encrypt:
+       movdqu  %xmm0, (%r10)
+_return_T_done_encrypt:
+       mov     %r14, %rsp
+       pop     %r14
+       pop     %r13
+       pop     %r12
+       ret
+
+#include <asm/inst.h>
+
 _key_expansion_128:
 _key_expansion_256a:
        pshufd $0b11111111, %xmm1, %xmm1
diff --git a/arch/x86/crypto/aesni-intel_glue.c b/arch/x86/crypto/aesni-intel_glue.c
index 2cb3dcc..f0b0a6f 100644
--- a/arch/x86/crypto/aesni-intel_glue.c
+++ b/arch/x86/crypto/aesni-intel_glue.c
@@ -5,6 +5,14 @@
  * Copyright (C) 2008, Intel Corp.
  *    Author: Huang Ying <ying.huang@xxxxxxxxx>
  *
+ * Added RFC4106 AES-GCM support for 128-bit keys under the AEAD
+ * interface for 64-bit kernels.
+ *    Authors: Adrian Hoban <adrian.hoban@xxxxxxxxx>
+ *             Gabriele Paoloni <gabriele.paoloni@xxxxxxxxx>
+ *             Tadeusz Struk (tadeusz.struk@xxxxxxxxx)
+ *             Aidan O'Mahony (aidan.o.mahony@xxxxxxxxx)
+ *    Copyright (c) 2010, Intel Corporation.
+ *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
  * the Free Software Foundation; either version 2 of the License, or
@@ -21,6 +29,10 @@
 #include <crypto/ctr.h>
 #include <asm/i387.h>
 #include <asm/aes.h>
+#include <crypto/scatterwalk.h>
+#include <crypto/internal/aead.h>
+#include <linux/workqueue.h>
+#include <linux/spinlock.h>

 #if defined(CONFIG_CRYPTO_CTR) || defined(CONFIG_CRYPTO_CTR_MODULE)
 #define HAS_CTR
@@ -42,8 +54,31 @@ struct async_aes_ctx {
        struct cryptd_ablkcipher *cryptd_tfm;
 };

-#define AESNI_ALIGN    16
+/* This data is stored at the end of the crypto_tfm struct.
+ * It's a type of per "session" data storage location.
+ * This needs to be 16 byte aligned.
+ */
+struct aesni_rfc4106_gcm_ctx {
+       u8 hash_subkey[16];
+       struct crypto_aes_ctx aes_key_expanded;
+       u8 nonce[4];
+       struct cryptd_aead *cryptd_tfm;
+};
+
+struct aesni_gcm_set_hash_subkey_result {
+       int err;
+       struct completion completion;
+};
+
+struct aesni_hash_subkey_req_data {
+       u8 iv[16];
+       struct aesni_gcm_set_hash_subkey_result result;
+       struct scatterlist sg;
+};
+
+#define AESNI_ALIGN    (16)
 #define AES_BLOCK_MASK (~(AES_BLOCK_SIZE-1))
+#define RFC4106_HASH_SUBKEY_SIZE 16

 asmlinkage int aesni_set_key(struct crypto_aes_ctx *ctx, const u8 *in_key,
                             unsigned int key_len);
@@ -62,6 +97,57 @@ asmlinkage void aesni_cbc_dec(struct crypto_aes_ctx *ctx, u8 *out,
 asmlinkage void aesni_ctr_enc(struct crypto_aes_ctx *ctx, u8 *out,
                              const u8 *in, unsigned int len, u8 *iv);

+/* asmlinkage void aesni_gcm_enc()
+ * void *ctx,  AES Key schedule. Starts on a 16 byte boundary.
+ * u8 *out, Ciphertext output. Encrypt in-place is allowed.
+ * const u8 *in, Plaintext input
+ * unsigned long plaintext_len, Length of data in bytes for encryption.
+ * u8 *iv, Pre-counter block j0: 4 byte salt (from Security Association)
+ *         concatenated with 8 byte Initialisation Vector (from IPSec ESP
+ *         Payload) concatenated with 0x00000001. 16-byte aligned pointer.
+ * u8 *hash_subkey, the Hash sub key input. Data starts on a 16-byte boundary.
+ * const u8 *aad, Additional Authentication Data (AAD)
+ * unsigned long aad_len, Length of AAD in bytes. With RFC4106 this
+ *          is going to be 8 or 12 bytes
+ * u8 *auth_tag, Authenticated Tag output.
+ * unsigned long auth_tag_len), Authenticated Tag Length in bytes.
+ *          Valid values are 16 (most likely), 12 or 8.
+ */
+asmlinkage void aesni_gcm_enc(void *ctx, u8 *out,
+                       const u8 *in, unsigned long plaintext_len, u8 *iv,
+                       u8 *hash_subkey, const u8 *aad, unsigned long aad_len,
+                       u8 *auth_tag, unsigned long auth_tag_len);
+
+/* asmlinkage void aesni_gcm_dec()
+ * void *ctx, AES Key schedule. Starts on a 16 byte boundary.
+ * u8 *out, Plaintext output. Decrypt in-place is allowed.
+ * const u8 *in, Ciphertext input
+ * unsigned long ciphertext_len, Length of data in bytes for decryption.
+ * u8 *iv, Pre-counter block j0: 4 byte salt (from Security Association)
+ *         concatenated with 8 byte Initialisation Vector (from IPSec ESP
+ *         Payload) concatenated with 0x00000001. 16-byte aligned pointer.
+ * u8 *hash_subkey, the Hash sub key input. Data starts on a 16-byte boundary.
+ * const u8 *aad, Additional Authentication Data (AAD)
+ * unsigned long aad_len, Length of AAD in bytes. With RFC4106 this is going
+ * to be 8 or 12 bytes
+ * u8 *auth_tag, Authenticated Tag output.
+ * unsigned long auth_tag_len) Authenticated Tag Length in bytes.
+ * Valid values are 16 (most likely), 12 or 8.
+ */
+asmlinkage void aesni_gcm_dec(void *ctx, u8 *out,
+                       const u8 *in, unsigned long ciphertext_len, u8 *iv,
+                       u8 *hash_subkey, const u8 *aad, unsigned long aad_len,
+                       u8 *auth_tag, unsigned long auth_tag_len);
+
+static inline struct
+aesni_rfc4106_gcm_ctx *aesni_rfc4106_gcm_ctx_get(struct crypto_aead *tfm)
+{
+       return
+               (struct aesni_rfc4106_gcm_ctx *)
+               PTR_ALIGN((u8 *)
+               crypto_tfm_ctx(crypto_aead_tfm(tfm)), AESNI_ALIGN);
+}
+
 static inline struct crypto_aes_ctx *aes_ctx(void *raw_ctx)
 {
        unsigned long addr = (unsigned long)raw_ctx;
@@ -730,6 +816,422 @@ static struct crypto_alg ablk_xts_alg = {
 };
 #endif

+static int rfc4106_init(struct crypto_tfm *tfm)
+{
+       struct cryptd_aead *cryptd_tfm;
+       struct aesni_rfc4106_gcm_ctx *ctx = (struct aesni_rfc4106_gcm_ctx *)
+               PTR_ALIGN((u8 *)crypto_tfm_ctx(tfm), AESNI_ALIGN);
+       cryptd_tfm = cryptd_alloc_aead("__driver-gcm-aes-aesni", 0, 0);
+       if (IS_ERR(cryptd_tfm))
+               return PTR_ERR(cryptd_tfm);
+       ctx->cryptd_tfm = cryptd_tfm;
+       tfm->crt_aead.reqsize = sizeof(struct aead_request)
+               + crypto_aead_reqsize(&cryptd_tfm->base);
+       return 0;
+}
+
+static void rfc4106_exit(struct crypto_tfm *tfm)
+{
+       struct aesni_rfc4106_gcm_ctx *ctx =
+               (struct aesni_rfc4106_gcm_ctx *)
+               PTR_ALIGN((u8 *)crypto_tfm_ctx(tfm), AESNI_ALIGN);
+       if (!IS_ERR(ctx->cryptd_tfm))
+               cryptd_free_aead(ctx->cryptd_tfm);
+       return;
+}
+
+static void
+rfc4106_set_hash_subkey_done(struct crypto_async_request *req, int err)
+{
+       struct aesni_gcm_set_hash_subkey_result *result = req->data;
+
+       if (err == -EINPROGRESS)
+               return;
+       result->err = err;
+       complete(&result->completion);
+}
+
+static int
+rfc4106_set_hash_subkey(u8 *hash_subkey, const u8 *key, unsigned int key_len)
+{
+       struct crypto_ablkcipher *ctr_tfm;
+       struct ablkcipher_request *req;
+       int ret = -EINVAL;
+       struct aesni_hash_subkey_req_data *req_data;
+
+       ctr_tfm = crypto_alloc_ablkcipher("ctr(aes)", 0, 0);
+       if (IS_ERR(ctr_tfm))
+               return PTR_ERR(ctr_tfm);
+
+       crypto_ablkcipher_clear_flags(ctr_tfm, ~0);
+
+       ret = crypto_ablkcipher_setkey(ctr_tfm, key, key_len);
+       if (ret) {
+               crypto_free_ablkcipher(ctr_tfm);
+               return ret;
+       }
+
+       req = ablkcipher_request_alloc(ctr_tfm, GFP_KERNEL);
+       if (!req) {
+               crypto_free_ablkcipher(ctr_tfm);
+               return -EINVAL;
+       }
+
+       req_data = kmalloc(sizeof(*req_data), GFP_KERNEL);
+       if (!req_data) {
+               crypto_free_ablkcipher(ctr_tfm);
+               return -ENOMEM;
+       }
+       memset(req_data->iv, 0, sizeof(req_data->iv));
+
+       /* Clear the data in the hash sub key container to zero.*/
+       /* We want to cipher all zeros to create the hash sub key. */
+       memset(hash_subkey, 0, RFC4106_HASH_SUBKEY_SIZE);
+
+       init_completion(&req_data->result.completion);
+       sg_init_one(&req_data->sg, hash_subkey, RFC4106_HASH_SUBKEY_SIZE);
+       ablkcipher_request_set_tfm(req, ctr_tfm);
+       ablkcipher_request_set_callback(req, CRYPTO_TFM_REQ_MAY_SLEEP |
+                                       CRYPTO_TFM_REQ_MAY_BACKLOG,
+                                       rfc4106_set_hash_subkey_done,
+                                       &req_data->result);
+
+       ablkcipher_request_set_crypt(req, &req_data->sg,
+               &req_data->sg, RFC4106_HASH_SUBKEY_SIZE, req_data->iv);
+
+       ret = crypto_ablkcipher_encrypt(req);
+       if (ret == -EINPROGRESS || ret == -EBUSY) {
+               ret = wait_for_completion_interruptible
+                       (&req_data->result.completion);
+               if (!ret)
+                       ret = req_data->result.err;
+       }
+       ablkcipher_request_free(req);
+       kfree(req_data);
+       crypto_free_ablkcipher(ctr_tfm);
+       return ret;
+}
+
+static int rfc4106_set_key(struct crypto_aead *parent, const u8 *key,
+                                                  unsigned int key_len)
+{
+       int ret = 0;
+       struct crypto_tfm *tfm = crypto_aead_tfm(parent);
+       struct aesni_rfc4106_gcm_ctx *ctx = aesni_rfc4106_gcm_ctx_get(parent);
+       u8 *new_key_mem = NULL;
+
+       if (key_len < 4) {
+               crypto_tfm_set_flags(tfm, CRYPTO_TFM_RES_BAD_KEY_LEN);
+               return -EINVAL;
+       }
+       /*Account for 4 byte nonce at the end.*/
+       key_len -= 4;
+       if (key_len != AES_KEYSIZE_128) {
+               crypto_tfm_set_flags(tfm, CRYPTO_TFM_RES_BAD_KEY_LEN);
+               return -EINVAL;
+       }
+
+       memcpy(ctx->nonce, key + key_len, sizeof(ctx->nonce));
+       /*This must be on a 16 byte boundary!*/
+       if ((unsigned long)(&(ctx->aes_key_expanded.key_enc[0])) % AESNI_ALIGN)
+               return -EINVAL;
+
+       if ((unsigned long)key % AESNI_ALIGN) {
+               /*key is not aligned: use an auxuliar aligned pointer*/
+               new_key_mem = kmalloc(key_len+AESNI_ALIGN, GFP_KERNEL);
+               if (!new_key_mem)
+                       return -ENOMEM;
+
+               new_key_mem = PTR_ALIGN(new_key_mem, AESNI_ALIGN);
+               memcpy(new_key_mem, key, key_len);
+               key = new_key_mem;
+       }
+
+       if (!irq_fpu_usable())
+               ret = crypto_aes_expand_key(&(ctx->aes_key_expanded),
+               key, key_len);
+       else {
+               kernel_fpu_begin();
+               ret = aesni_set_key(&(ctx->aes_key_expanded), key, key_len);
+               kernel_fpu_end();
+       }
+       /*This must be on a 16 byte boundary!*/
+       if ((unsigned long)(&(ctx->hash_subkey[0])) % AESNI_ALIGN) {
+               ret = -EINVAL;
+               goto exit;
+       }
+       ret = rfc4106_set_hash_subkey(ctx->hash_subkey, key, key_len);
+exit:
+       kfree(new_key_mem);
+       return ret;
+}
+
+/* This is the Integrity Check Value (aka the authentication tag length and can
+ * be 8, 12 or 16 bytes long. */
+static int rfc4106_set_authsize(struct crypto_aead *parent,
+                               unsigned int authsize)
+{
+       struct aesni_rfc4106_gcm_ctx *ctx = aesni_rfc4106_gcm_ctx_get(parent);
+       struct crypto_aead *cryptd_child = cryptd_aead_child(ctx->cryptd_tfm);
+
+       switch (authsize) {
+       case 8:
+       case 12:
+       case 16:
+               break;
+       default:
+               return -EINVAL;
+       }
+       crypto_aead_crt(parent)->authsize = authsize;
+       crypto_aead_crt(cryptd_child)->authsize = authsize;
+       return 0;
+}
+
+static int rfc4106_encrypt(struct aead_request *req)
+{
+       int ret;
+       struct crypto_aead *tfm = crypto_aead_reqtfm(req);
+       struct aesni_rfc4106_gcm_ctx *ctx = aesni_rfc4106_gcm_ctx_get(tfm);
+       struct crypto_aead *cryptd_child = cryptd_aead_child(ctx->cryptd_tfm);
+
+       if (!irq_fpu_usable()) {
+               struct aead_request *cryptd_req =
+                       (struct aead_request *) aead_request_ctx(req);
+               memcpy(cryptd_req, req, sizeof(*req));
+               aead_request_set_tfm(cryptd_req, &ctx->cryptd_tfm->base);
+               return crypto_aead_encrypt(cryptd_req);
+       } else {
+               kernel_fpu_begin();
+               ret = cryptd_child->base.crt_aead.encrypt(req);
+               kernel_fpu_end();
+               return ret;
+       }
+}
+
+static int rfc4106_decrypt(struct aead_request *req)
+{
+       int ret;
+       struct crypto_aead *tfm = crypto_aead_reqtfm(req);
+       struct aesni_rfc4106_gcm_ctx *ctx = aesni_rfc4106_gcm_ctx_get(tfm);
+       struct crypto_aead *cryptd_child = cryptd_aead_child(ctx->cryptd_tfm);
+
+       if (!irq_fpu_usable()) {
+               struct aead_request *cryptd_req =
+                       (struct aead_request *) aead_request_ctx(req);
+               memcpy(cryptd_req, req, sizeof(*req));
+               aead_request_set_tfm(cryptd_req, &ctx->cryptd_tfm->base);
+               return crypto_aead_decrypt(cryptd_req);
+       } else {
+               kernel_fpu_begin();
+               ret = cryptd_child->base.crt_aead.decrypt(req);
+               kernel_fpu_end();
+               return ret;
+       }
+}
+
+static struct crypto_alg rfc4106_alg = {
+       .cra_name = "rfc4106(gcm(aes))",
+       .cra_driver_name = "rfc4106-gcm-aesni",
+       .cra_priority = 400,
+       .cra_flags = CRYPTO_ALG_TYPE_AEAD | CRYPTO_ALG_ASYNC,
+       .cra_blocksize = 1,
+       .cra_ctxsize = sizeof(struct aesni_rfc4106_gcm_ctx) + AESNI_ALIGN,
+       .cra_alignmask = 0,
+       .cra_type = &crypto_nivaead_type,
+       .cra_module = THIS_MODULE,
+       .cra_list = LIST_HEAD_INIT(rfc4106_alg.cra_list),
+       .cra_init = rfc4106_init,
+       .cra_exit = rfc4106_exit,
+       .cra_u = {
+               .aead = {
+                       .setkey = rfc4106_set_key,
+                       .setauthsize = rfc4106_set_authsize,
+                       .encrypt = rfc4106_encrypt,
+                       .decrypt = rfc4106_decrypt,
+                       .geniv = "seqiv",
+                       .ivsize = 8,
+                       .maxauthsize = 16,
+               },
+       },
+};
+
+static int __driver_rfc4106_encrypt(struct aead_request *req)
+{
+       u8 one_entry_in_sg = 0;
+       u8 *src, *dst, *assoc;
+       __be32 counter = cpu_to_be32(1);
+       struct crypto_aead *tfm = crypto_aead_reqtfm(req);
+       struct aesni_rfc4106_gcm_ctx *ctx = aesni_rfc4106_gcm_ctx_get(tfm);
+       void *aes_ctx = &(ctx->aes_key_expanded);
+       unsigned long auth_tag_len = crypto_aead_authsize(tfm);
+       u8 iv_tab[16+AESNI_ALIGN];
+       u8* iv = (u8 *) PTR_ALIGN((u8 *)iv_tab, AESNI_ALIGN);
+       struct scatter_walk src_sg_walk;
+       struct scatter_walk assoc_sg_walk;
+       struct scatter_walk dst_sg_walk;
+       unsigned int i;
+
+       /* Assuming we are supporting rfc4106 64-bit extended */
+       /* sequence numbers We need to have the AAD length equal */
+       /* to 8 or 12 bytes */
+       if (unlikely(req->assoclen != 8 && req->assoclen != 12))
+               return -EINVAL;
+       /* IV below built */
+       for (i = 0; i < 4; i++)
+               *(iv+i) = ctx->nonce[i];
+       for (i = 0; i < 8; i++)
+               *(iv+4+i) = req->iv[i];
+       *((__be32 *)(iv+12)) = counter;
+
+       if ((sg_is_last(req->src)) && (sg_is_last(req->assoc))) {
+               one_entry_in_sg = 1;
+               scatterwalk_start(&src_sg_walk, req->src);
+               scatterwalk_start(&assoc_sg_walk, req->assoc);
+               src = scatterwalk_map(&src_sg_walk, 0);
+               assoc = scatterwalk_map(&assoc_sg_walk, 0);
+               dst = src;
+               if (unlikely(req->src != req->dst)) {
+                       scatterwalk_start(&dst_sg_walk, req->dst);
+                       dst = scatterwalk_map(&dst_sg_walk, 0);
+               }
+
+       } else {
+               /* Allocate memory for src, dst, assoc */
+               src = kmalloc(req->cryptlen + auth_tag_len + req->assoclen,
+                       GFP_ATOMIC);
+               if (unlikely(!src))
+                       return -ENOMEM;
+               assoc = (src + req->cryptlen + auth_tag_len);
+               scatterwalk_map_and_copy(src, req->src, 0, req->cryptlen, 0);
+               scatterwalk_map_and_copy(assoc, req->assoc, 0,
+                                       req->assoclen, 0);
+               dst = src;
+       }
+
+       aesni_gcm_enc(aes_ctx, dst, src, (unsigned long)req->cryptlen, iv,
+               ctx->hash_subkey, assoc, (unsigned long)req->assoclen, dst
+               + ((unsigned long)req->cryptlen), auth_tag_len);
+
+       /* The authTag (aka the Integrity Check Value) needs to be written
+        * back to the packet. */
+       if (one_entry_in_sg) {
+               if (unlikely(req->src != req->dst)) {
+                       scatterwalk_unmap(dst, 0);
+                       scatterwalk_done(&dst_sg_walk, 0, 0);
+               }
+               scatterwalk_unmap(src, 0);
+               scatterwalk_unmap(assoc, 0);
+               scatterwalk_done(&src_sg_walk, 0, 0);
+               scatterwalk_done(&assoc_sg_walk, 0, 0);
+       } else {
+               scatterwalk_map_and_copy(dst, req->dst, 0,
+                       req->cryptlen + auth_tag_len, 1);
+               kfree(src);
+       }
+       return 0;
+}
+
+static int __driver_rfc4106_decrypt(struct aead_request *req)
+{
+       u8 one_entry_in_sg = 0;
+       u8 *src, *dst, *assoc;
+       unsigned long tempCipherLen = 0;
+       __be32 counter = cpu_to_be32(1);
+       int retval = 0;
+       struct crypto_aead *tfm = crypto_aead_reqtfm(req);
+       struct aesni_rfc4106_gcm_ctx *ctx = aesni_rfc4106_gcm_ctx_get(tfm);
+       void *aes_ctx = &(ctx->aes_key_expanded);
+       unsigned long auth_tag_len = crypto_aead_authsize(tfm);
+       u8 iv_and_authTag[32+AESNI_ALIGN];
+       u8 *iv = (u8 *) PTR_ALIGN((u8 *)iv_and_authTag, AESNI_ALIGN);
+       u8 *authTag = iv + 16;
+       struct scatter_walk src_sg_walk;
+       struct scatter_walk assoc_sg_walk;
+       struct scatter_walk dst_sg_walk;
+       unsigned int i;
+
+       if (unlikely((req->cryptlen < auth_tag_len) ||
+               (req->assoclen != 8 && req->assoclen != 12)))
+               return -EINVAL;
+       /* Assuming we are supporting rfc4106 64-bit extended */
+       /* sequence numbers We need to have the AAD length */
+       /* equal to 8 or 12 bytes */
+
+       tempCipherLen = (unsigned long)(req->cryptlen - auth_tag_len);
+       /* IV below built */
+       for (i = 0; i < 4; i++)
+               *(iv+i) = ctx->nonce[i];
+       for (i = 0; i < 8; i++)
+               *(iv+4+i) = req->iv[i];
+       *((__be32 *)(iv+12)) = counter;
+
+       if ((sg_is_last(req->src)) && (sg_is_last(req->assoc))) {
+               one_entry_in_sg = 1;
+               scatterwalk_start(&src_sg_walk, req->src);
+               scatterwalk_start(&assoc_sg_walk, req->assoc);
+               src = scatterwalk_map(&src_sg_walk, 0);
+               assoc = scatterwalk_map(&assoc_sg_walk, 0);
+               dst = src;
+               if (unlikely(req->src != req->dst)) {
+                       scatterwalk_start(&dst_sg_walk, req->dst);
+                       dst = scatterwalk_map(&dst_sg_walk, 0);
+               }
+
+       } else {
+               /* Allocate memory for src, dst, assoc */
+               src = kmalloc(req->cryptlen + req->assoclen, GFP_ATOMIC);
+               if (!src)
+                       return -ENOMEM;
+               assoc = (src + req->cryptlen + auth_tag_len);
+               scatterwalk_map_and_copy(src, req->src, 0, req->cryptlen, 0);
+               scatterwalk_map_and_copy(assoc, req->assoc, 0,
+                       req->assoclen, 0);
+               dst = src;
+       }
+
+       aesni_gcm_dec(aes_ctx, dst, src, tempCipherLen, iv,
+               ctx->hash_subkey, assoc, (unsigned long)req->assoclen,
+               authTag, auth_tag_len);
+
+       /* Compare generated tag with passed in tag. */
+       retval = memcmp(src + tempCipherLen, authTag, auth_tag_len) ?
+               -EBADMSG : 0;
+
+       if (one_entry_in_sg) {
+               if (unlikely(req->src != req->dst)) {
+                       scatterwalk_unmap(dst, 0);
+                       scatterwalk_done(&dst_sg_walk, 0, 0);
+               }
+               scatterwalk_unmap(src, 0);
+               scatterwalk_unmap(assoc, 0);
+               scatterwalk_done(&src_sg_walk, 0, 0);
+               scatterwalk_done(&assoc_sg_walk, 0, 0);
+       } else {
+               scatterwalk_map_and_copy(dst, req->dst, 0, req->cryptlen, 1);
+               kfree(src);
+       }
+       return retval;
+}
+
+static struct crypto_alg __rfc4106_alg = {
+       .cra_name               = "__gcm-aes-aesni",
+       .cra_driver_name        = "__driver-gcm-aes-aesni",
+       .cra_priority           = 0,
+       .cra_flags              = CRYPTO_ALG_TYPE_AEAD,
+       .cra_blocksize          = 1,
+       .cra_ctxsize            = sizeof(struct aesni_rfc4106_gcm_ctx) + AESNI_ALIGN,
+       .cra_alignmask          = 0,
+       .cra_type               = &crypto_aead_type,
+       .cra_module             = THIS_MODULE,
+       .cra_list               = LIST_HEAD_INIT(__rfc4106_alg.cra_list),
+       .cra_u = {
+               .aead = {
+                       .encrypt        = __driver_rfc4106_encrypt,
+                       .decrypt        = __driver_rfc4106_decrypt,
+               },
+       },
+};
+
 static int __init aesni_init(void)
 {
        int err;
@@ -738,6 +1240,7 @@ static int __init aesni_init(void)
                printk(KERN_INFO "Intel AES-NI instructions are not detected.\n");
                return -ENODEV;
        }
+
        if ((err = crypto_register_alg(&aesni_alg)))
                goto aes_err;
        if ((err = crypto_register_alg(&__aesni_alg)))
@@ -770,10 +1273,19 @@ static int __init aesni_init(void)
        if ((err = crypto_register_alg(&ablk_xts_alg)))
                goto ablk_xts_err;
 #endif
-
+       err = crypto_register_alg(&__rfc4106_alg);
+       if (err)
+               goto __aead_gcm_err;
+       err = crypto_register_alg(&rfc4106_alg);
+       if (err)
+               goto aead_gcm_err;
        return err;

+aead_gcm_err:
+       crypto_unregister_alg(&__rfc4106_alg);
+__aead_gcm_err:
 #ifdef HAS_XTS
+       crypto_unregister_alg(&ablk_xts_alg);
 ablk_xts_err:
 #endif
 #ifdef HAS_PCBC
@@ -809,6 +1321,8 @@ aes_err:

 static void __exit aesni_exit(void)
 {
+       crypto_unregister_alg(&__rfc4106_alg);
+       crypto_unregister_alg(&rfc4106_alg);
 #ifdef HAS_XTS
        crypto_unregister_alg(&ablk_xts_alg);
 #endif
--
1.5.3.rc5



--------------------------------------------------------------
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Registered Number: 308263
Business address: Dromore House, East Park, Shannon, Co. Clare

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