crypto: aesni - Add support for 192 & 256 bit keys to AESNI RFC4106

These patches fix the RFC4106 implementation in the aesni-intel
module so it supports 192 & 256 bit keys.

Since the AVX support that was added to this module also only
supports 128 bit keys, and this patch only affects the SSE
implementation, changes were also made to use the SSE version
if key sizes other than 128 are specified.

RFC4106 specifies that 192 & 256 bit keys must be supported (section
8.4).

Also, this should fix Strongswan issue 341 where the aesni module
needs to be unloaded if 256 bit keys are used:

http://wiki.strongswan.org/issues/341

This patch has been tested with Sandy Bridge and Haswell processors.
With 128 bit keys and input buffers > 512 bytes a slight performance
degradation was noticed (~1%).  For input buffers of less than 512
bytes there was no performance impact.  Compared to 128 bit keys,
256 bit key size performance is approx. .5 cycles per byte slower
on Sandy Bridge, and .37 cycles per byte slower on Haswell (vs.
SSE code).

This patch has also been tested with StrongSwan IPSec connections
where it worked correctly.

I created this diff from a git clone of crypto-2.6.git.

Any questions, please feel free to contact me.

Signed-off-by: Timothy McCaffrey <timothy.mccaffrey@unisys.com>
Signed-off-by: Jarod Wilson <jarod@redhat.com>
Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
This commit is contained in:
Timothy McCaffrey 2015-01-13 13:16:43 -05:00 коммит произвёл Herbert Xu
Родитель d8219f52a7
Коммит e31ac32d3b
2 изменённых файлов: 205 добавлений и 172 удалений

Просмотреть файл

@ -32,12 +32,23 @@
#include <linux/linkage.h>
#include <asm/inst.h>
/*
* The following macros are used to move an (un)aligned 16 byte value to/from
* an XMM register. This can done for either FP or integer values, for FP use
* movaps (move aligned packed single) or integer use movdqa (move double quad
* aligned). It doesn't make a performance difference which instruction is used
* since Nehalem (original Core i7) was released. However, the movaps is a byte
* shorter, so that is the one we'll use for now. (same for unaligned).
*/
#define MOVADQ movaps
#define MOVUDQ movups
#ifdef __x86_64__
.data
.align 16
.Lgf128mul_x_ble_mask:
.octa 0x00000000000000010000000000000087
POLY: .octa 0xC2000000000000000000000000000001
TWOONE: .octa 0x00000001000000000000000000000001
@ -89,6 +100,7 @@ enc: .octa 0x2
#define arg8 STACK_OFFSET+16(%r14)
#define arg9 STACK_OFFSET+24(%r14)
#define arg10 STACK_OFFSET+32(%r14)
#define keysize 2*15*16(%arg1)
#endif
@ -213,10 +225,12 @@ enc: .octa 0x2
.macro INITIAL_BLOCKS_DEC num_initial_blocks TMP1 TMP2 TMP3 TMP4 TMP5 XMM0 XMM1 \
XMM2 XMM3 XMM4 XMMDst TMP6 TMP7 i i_seq operation
MOVADQ SHUF_MASK(%rip), %xmm14
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
@ -225,16 +239,18 @@ _get_AAD_loop\num_initial_blocks\operation:
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:
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, %xmm\i # byte-reflect the AAD data
xor %r11, %r11 # initialise the data pointer offset as zero
@ -243,59 +259,34 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
mov %arg5, %rax # %rax = *Y0
movdqu (%rax), \XMM0 # XMM0 = Y0
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM0
.if (\i == 5) || (\i == 6) || (\i == 7)
MOVADQ ONE(%RIP),\TMP1
MOVADQ (%arg1),\TMP2
.irpc index, \i_seq
paddd ONE(%rip), \XMM0 # INCR Y0
paddd \TMP1, \XMM0 # INCR Y0
movdqa \XMM0, %xmm\index
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, %xmm\index # perform a 16 byte swap
pxor \TMP2, %xmm\index
.endr
lea 0x10(%arg1),%r10
mov keysize,%eax
shr $2,%eax # 128->4, 192->6, 256->8
add $5,%eax # 128->9, 192->11, 256->13
aes_loop_initial_dec\num_initial_blocks:
MOVADQ (%r10),\TMP1
.irpc index, \i_seq
AESENC \TMP1, %xmm\index
.endr
add $16,%r10
sub $1,%eax
jnz aes_loop_initial_dec\num_initial_blocks
MOVADQ (%r10), \TMP1
.irpc index, \i_seq
pxor 16*0(%arg1), %xmm\index
.endr
.irpc index, \i_seq
movaps 0x10(%rdi), \TMP1
AESENC \TMP1, %xmm\index # Round 1
.endr
.irpc index, \i_seq
movaps 0x20(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x30(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x40(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x50(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x60(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x70(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x80(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x90(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0xa0(%arg1), \TMP1
AESENCLAST \TMP1, %xmm\index # Round 10
AESENCLAST \TMP1, %xmm\index # Last Round
.endr
.irpc index, \i_seq
movdqu (%arg3 , %r11, 1), \TMP1
@ -305,10 +296,8 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
add $16, %r11
movdqa \TMP1, %xmm\index
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, %xmm\index
# prepare plaintext/ciphertext for GHASH computation
# prepare plaintext/ciphertext for GHASH computation
.endr
.endif
GHASH_MUL %xmm\i, \TMP3, \TMP1, \TMP2, \TMP4, \TMP5, \XMM1
@ -338,30 +327,28 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
* 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
movdqa SHUF_MASK(%rip), %xmm14
MOVADQ ONE(%rip), \TMP1
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM1
PSHUFB_XMM %xmm14, \XMM1 # perform a 16 byte swap
paddd ONE(%rip), \XMM0 # INCR Y0
movdqa \XMM0, \XMM2
movdqa SHUF_MASK(%rip), %xmm14
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM2
PSHUFB_XMM %xmm14, \XMM2 # perform a 16 byte swap
paddd ONE(%rip), \XMM0 # INCR Y0
movdqa \XMM0, \XMM3
movdqa SHUF_MASK(%rip), %xmm14
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM3
PSHUFB_XMM %xmm14, \XMM3 # perform a 16 byte swap
paddd ONE(%rip), \XMM0 # INCR Y0
movdqa \XMM0, \XMM4
movdqa SHUF_MASK(%rip), %xmm14
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM4
PSHUFB_XMM %xmm14, \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
MOVADQ 0(%arg1),\TMP1
pxor \TMP1, \XMM1
pxor \TMP1, \XMM2
pxor \TMP1, \XMM3
pxor \TMP1, \XMM4
movdqa \TMP3, \TMP5
pshufd $78, \TMP3, \TMP1
pxor \TMP3, \TMP1
@ -399,7 +386,23 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
pshufd $78, \TMP5, \TMP1
pxor \TMP5, \TMP1
movdqa \TMP1, HashKey_4_k(%rsp)
movaps 0xa0(%arg1), \TMP2
lea 0xa0(%arg1),%r10
mov keysize,%eax
shr $2,%eax # 128->4, 192->6, 256->8
sub $4,%eax # 128->0, 192->2, 256->4
jz aes_loop_pre_dec_done\num_initial_blocks
aes_loop_pre_dec\num_initial_blocks:
MOVADQ (%r10),\TMP2
.irpc index, 1234
AESENC \TMP2, %xmm\index
.endr
add $16,%r10
sub $1,%eax
jnz aes_loop_pre_dec\num_initial_blocks
aes_loop_pre_dec_done\num_initial_blocks:
MOVADQ (%r10), \TMP2
AESENCLAST \TMP2, \XMM1
AESENCLAST \TMP2, \XMM2
AESENCLAST \TMP2, \XMM3
@ -421,15 +424,11 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
movdqu \XMM4, 16*3(%arg2 , %r11 , 1)
movdqa \TMP1, \XMM4
add $64, %r11
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM1 # perform a 16 byte swap
pxor \XMMDst, \XMM1
# combine GHASHed value with the corresponding ciphertext
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM2 # perform a 16 byte swap
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM3 # perform a 16 byte swap
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM4 # perform a 16 byte swap
_initial_blocks_done\num_initial_blocks\operation:
@ -451,6 +450,7 @@ _initial_blocks_done\num_initial_blocks\operation:
.macro INITIAL_BLOCKS_ENC num_initial_blocks TMP1 TMP2 TMP3 TMP4 TMP5 XMM0 XMM1 \
XMM2 XMM3 XMM4 XMMDst TMP6 TMP7 i i_seq operation
MOVADQ SHUF_MASK(%rip), %xmm14
mov arg7, %r10 # %r10 = AAD
mov arg8, %r12 # %r12 = aadLen
mov %r12, %r11
@ -472,7 +472,6 @@ _get_AAD_loop2\num_initial_blocks\operation:
cmp %r11, %r12
jne _get_AAD_loop2\num_initial_blocks\operation
_get_AAD_loop2_done\num_initial_blocks\operation:
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, %xmm\i # byte-reflect the AAD data
xor %r11, %r11 # initialise the data pointer offset as zero
@ -481,59 +480,35 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
mov %arg5, %rax # %rax = *Y0
movdqu (%rax), \XMM0 # XMM0 = Y0
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM0
.if (\i == 5) || (\i == 6) || (\i == 7)
.irpc index, \i_seq
paddd ONE(%rip), \XMM0 # INCR Y0
movdqa \XMM0, %xmm\index
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, %xmm\index # perform a 16 byte swap
.endr
MOVADQ ONE(%RIP),\TMP1
MOVADQ 0(%arg1),\TMP2
.irpc index, \i_seq
pxor 16*0(%arg1), %xmm\index
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, %xmm\index
PSHUFB_XMM %xmm14, %xmm\index # perform a 16 byte swap
pxor \TMP2, %xmm\index
.endr
.irpc index, \i_seq
movaps 0x10(%rdi), \TMP1
AESENC \TMP1, %xmm\index # Round 1
lea 0x10(%arg1),%r10
mov keysize,%eax
shr $2,%eax # 128->4, 192->6, 256->8
add $5,%eax # 128->9, 192->11, 256->13
aes_loop_initial_enc\num_initial_blocks:
MOVADQ (%r10),\TMP1
.irpc index, \i_seq
AESENC \TMP1, %xmm\index
.endr
add $16,%r10
sub $1,%eax
jnz aes_loop_initial_enc\num_initial_blocks
MOVADQ (%r10), \TMP1
.irpc index, \i_seq
movaps 0x20(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x30(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x40(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x50(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x60(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x70(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x80(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0x90(%arg1), \TMP1
AESENC \TMP1, %xmm\index # Round 2
.endr
.irpc index, \i_seq
movaps 0xa0(%arg1), \TMP1
AESENCLAST \TMP1, %xmm\index # Round 10
AESENCLAST \TMP1, %xmm\index # Last Round
.endr
.irpc index, \i_seq
movdqu (%arg3 , %r11, 1), \TMP1
@ -541,8 +516,6 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
movdqu %xmm\index, (%arg2 , %r11, 1)
# write back plaintext/ciphertext for num_initial_blocks
add $16, %r11
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, %xmm\index
# prepare plaintext/ciphertext for GHASH computation
@ -575,30 +548,28 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
* 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
movdqa SHUF_MASK(%rip), %xmm14
MOVADQ ONE(%RIP),\TMP1
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM1
PSHUFB_XMM %xmm14, \XMM1 # perform a 16 byte swap
paddd ONE(%rip), \XMM0 # INCR Y0
movdqa \XMM0, \XMM2
movdqa SHUF_MASK(%rip), %xmm14
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM2
PSHUFB_XMM %xmm14, \XMM2 # perform a 16 byte swap
paddd ONE(%rip), \XMM0 # INCR Y0
movdqa \XMM0, \XMM3
movdqa SHUF_MASK(%rip), %xmm14
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM3
PSHUFB_XMM %xmm14, \XMM3 # perform a 16 byte swap
paddd ONE(%rip), \XMM0 # INCR Y0
movdqa \XMM0, \XMM4
movdqa SHUF_MASK(%rip), %xmm14
paddd \TMP1, \XMM0 # INCR Y0
MOVADQ \XMM0, \XMM4
PSHUFB_XMM %xmm14, \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
MOVADQ 0(%arg1),\TMP1
pxor \TMP1, \XMM1
pxor \TMP1, \XMM2
pxor \TMP1, \XMM3
pxor \TMP1, \XMM4
movdqa \TMP3, \TMP5
pshufd $78, \TMP3, \TMP1
pxor \TMP3, \TMP1
@ -636,7 +607,23 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
pshufd $78, \TMP5, \TMP1
pxor \TMP5, \TMP1
movdqa \TMP1, HashKey_4_k(%rsp)
movaps 0xa0(%arg1), \TMP2
lea 0xa0(%arg1),%r10
mov keysize,%eax
shr $2,%eax # 128->4, 192->6, 256->8
sub $4,%eax # 128->0, 192->2, 256->4
jz aes_loop_pre_enc_done\num_initial_blocks
aes_loop_pre_enc\num_initial_blocks:
MOVADQ (%r10),\TMP2
.irpc index, 1234
AESENC \TMP2, %xmm\index
.endr
add $16,%r10
sub $1,%eax
jnz aes_loop_pre_enc\num_initial_blocks
aes_loop_pre_enc_done\num_initial_blocks:
MOVADQ (%r10), \TMP2
AESENCLAST \TMP2, \XMM1
AESENCLAST \TMP2, \XMM2
AESENCLAST \TMP2, \XMM3
@ -655,15 +642,11 @@ _get_AAD_loop2_done\num_initial_blocks\operation:
movdqu \XMM4, 16*3(%arg2 , %r11 , 1)
add $64, %r11
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM1 # perform a 16 byte swap
pxor \XMMDst, \XMM1
# combine GHASHed value with the corresponding ciphertext
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM2 # perform a 16 byte swap
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM3 # perform a 16 byte swap
movdqa SHUF_MASK(%rip), %xmm14
PSHUFB_XMM %xmm14, \XMM4 # perform a 16 byte swap
_initial_blocks_done\num_initial_blocks\operation:
@ -794,7 +777,23 @@ TMP6 XMM0 XMM1 XMM2 XMM3 XMM4 XMM5 XMM6 XMM7 XMM8 operation
AESENC \TMP3, \XMM3
AESENC \TMP3, \XMM4
PCLMULQDQ 0x00, \TMP5, \XMM8 # XMM8 = a0*b0
movaps 0xa0(%arg1), \TMP3
lea 0xa0(%arg1),%r10
mov keysize,%eax
shr $2,%eax # 128->4, 192->6, 256->8
sub $4,%eax # 128->0, 192->2, 256->4
jz aes_loop_par_enc_done
aes_loop_par_enc:
MOVADQ (%r10),\TMP3
.irpc index, 1234
AESENC \TMP3, %xmm\index
.endr
add $16,%r10
sub $1,%eax
jnz aes_loop_par_enc
aes_loop_par_enc_done:
MOVADQ (%r10), \TMP3
AESENCLAST \TMP3, \XMM1 # Round 10
AESENCLAST \TMP3, \XMM2
AESENCLAST \TMP3, \XMM3
@ -986,8 +985,24 @@ TMP6 XMM0 XMM1 XMM2 XMM3 XMM4 XMM5 XMM6 XMM7 XMM8 operation
AESENC \TMP3, \XMM3
AESENC \TMP3, \XMM4
PCLMULQDQ 0x00, \TMP5, \XMM8 # XMM8 = a0*b0
movaps 0xa0(%arg1), \TMP3
AESENCLAST \TMP3, \XMM1 # Round 10
lea 0xa0(%arg1),%r10
mov keysize,%eax
shr $2,%eax # 128->4, 192->6, 256->8
sub $4,%eax # 128->0, 192->2, 256->4
jz aes_loop_par_dec_done
aes_loop_par_dec:
MOVADQ (%r10),\TMP3
.irpc index, 1234
AESENC \TMP3, %xmm\index
.endr
add $16,%r10
sub $1,%eax
jnz aes_loop_par_dec
aes_loop_par_dec_done:
MOVADQ (%r10), \TMP3
AESENCLAST \TMP3, \XMM1 # last round
AESENCLAST \TMP3, \XMM2
AESENCLAST \TMP3, \XMM3
AESENCLAST \TMP3, \XMM4
@ -1155,33 +1170,29 @@ TMP7 XMM1 XMM2 XMM3 XMM4 XMMDst
pxor \TMP6, \XMMDst # reduced result is in XMMDst
.endm
/* Encryption of a single block done*/
/* Encryption of a single block
* uses eax & r10
*/
.macro ENCRYPT_SINGLE_BLOCK XMM0 TMP1
pxor (%arg1), \XMM0
movaps 16(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 32(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 48(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 64(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 80(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 96(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 112(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 128(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 144(%arg1), \TMP1
AESENC \TMP1, \XMM0
movaps 160(%arg1), \TMP1
AESENCLAST \TMP1, \XMM0
pxor (%arg1), \XMM0
mov keysize,%eax
shr $2,%eax # 128->4, 192->6, 256->8
add $5,%eax # 128->9, 192->11, 256->13
lea 16(%arg1), %r10 # get first expanded key address
_esb_loop_\@:
MOVADQ (%r10),\TMP1
AESENC \TMP1,\XMM0
add $16,%r10
sub $1,%eax
jnz _esb_loop_\@
MOVADQ (%r10),\TMP1
AESENCLAST \TMP1,\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.

Просмотреть файл

@ -43,6 +43,7 @@
#include <asm/crypto/glue_helper.h>
#endif
/* 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.
@ -182,7 +183,8 @@ static void aesni_gcm_enc_avx(void *ctx, u8 *out,
u8 *hash_subkey, const u8 *aad, unsigned long aad_len,
u8 *auth_tag, unsigned long auth_tag_len)
{
if (plaintext_len < AVX_GEN2_OPTSIZE) {
struct crypto_aes_ctx *aes_ctx = (struct crypto_aes_ctx*)ctx;
if ((plaintext_len < AVX_GEN2_OPTSIZE) || (aes_ctx-> key_length != AES_KEYSIZE_128)){
aesni_gcm_enc(ctx, out, in, plaintext_len, iv, hash_subkey, aad,
aad_len, auth_tag, auth_tag_len);
} else {
@ -197,7 +199,8 @@ static void aesni_gcm_dec_avx(void *ctx, u8 *out,
u8 *hash_subkey, const u8 *aad, unsigned long aad_len,
u8 *auth_tag, unsigned long auth_tag_len)
{
if (ciphertext_len < AVX_GEN2_OPTSIZE) {
struct crypto_aes_ctx *aes_ctx = (struct crypto_aes_ctx*)ctx;
if ((ciphertext_len < AVX_GEN2_OPTSIZE) || (aes_ctx-> key_length != AES_KEYSIZE_128)) {
aesni_gcm_dec(ctx, out, in, ciphertext_len, iv, hash_subkey, aad,
aad_len, auth_tag, auth_tag_len);
} else {
@ -231,7 +234,8 @@ static void aesni_gcm_enc_avx2(void *ctx, u8 *out,
u8 *hash_subkey, const u8 *aad, unsigned long aad_len,
u8 *auth_tag, unsigned long auth_tag_len)
{
if (plaintext_len < AVX_GEN2_OPTSIZE) {
struct crypto_aes_ctx *aes_ctx = (struct crypto_aes_ctx*)ctx;
if ((plaintext_len < AVX_GEN2_OPTSIZE) || (aes_ctx-> key_length != AES_KEYSIZE_128)) {
aesni_gcm_enc(ctx, out, in, plaintext_len, iv, hash_subkey, aad,
aad_len, auth_tag, auth_tag_len);
} else if (plaintext_len < AVX_GEN4_OPTSIZE) {
@ -250,7 +254,8 @@ static void aesni_gcm_dec_avx2(void *ctx, u8 *out,
u8 *hash_subkey, const u8 *aad, unsigned long aad_len,
u8 *auth_tag, unsigned long auth_tag_len)
{
if (ciphertext_len < AVX_GEN2_OPTSIZE) {
struct crypto_aes_ctx *aes_ctx = (struct crypto_aes_ctx*)ctx;
if ((ciphertext_len < AVX_GEN2_OPTSIZE) || (aes_ctx-> key_length != AES_KEYSIZE_128)) {
aesni_gcm_dec(ctx, out, in, ciphertext_len, iv, hash_subkey,
aad, aad_len, auth_tag, auth_tag_len);
} else if (ciphertext_len < AVX_GEN4_OPTSIZE) {
@ -511,7 +516,7 @@ static int ctr_crypt(struct blkcipher_desc *desc,
kernel_fpu_begin();
while ((nbytes = walk.nbytes) >= AES_BLOCK_SIZE) {
aesni_ctr_enc_tfm(ctx, walk.dst.virt.addr, walk.src.virt.addr,
nbytes & AES_BLOCK_MASK, walk.iv);
nbytes & AES_BLOCK_MASK, walk.iv);
nbytes &= AES_BLOCK_SIZE - 1;
err = blkcipher_walk_done(desc, &walk, nbytes);
}
@ -902,7 +907,8 @@ static int rfc4106_set_key(struct crypto_aead *parent, const u8 *key,
}
/*Account for 4 byte nonce at the end.*/
key_len -= 4;
if (key_len != AES_KEYSIZE_128) {
if (key_len != AES_KEYSIZE_128 && key_len != AES_KEYSIZE_192 &&
key_len != AES_KEYSIZE_256) {
crypto_tfm_set_flags(tfm, CRYPTO_TFM_RES_BAD_KEY_LEN);
return -EINVAL;
}
@ -1013,6 +1019,7 @@ static int __driver_rfc4106_encrypt(struct aead_request *req)
__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);
u32 key_len = ctx->aes_key_expanded.key_length;
void *aes_ctx = &(ctx->aes_key_expanded);
unsigned long auth_tag_len = crypto_aead_authsize(tfm);
u8 iv_tab[16+AESNI_ALIGN];
@ -1027,6 +1034,13 @@ static int __driver_rfc4106_encrypt(struct aead_request *req)
/* to 8 or 12 bytes */
if (unlikely(req->assoclen != 8 && req->assoclen != 12))
return -EINVAL;
if (unlikely(auth_tag_len != 8 && auth_tag_len != 12 && auth_tag_len != 16))
return -EINVAL;
if (unlikely(key_len != AES_KEYSIZE_128 &&
key_len != AES_KEYSIZE_192 &&
key_len != AES_KEYSIZE_256))
return -EINVAL;
/* IV below built */
for (i = 0; i < 4; i++)
*(iv+i) = ctx->nonce[i];
@ -1091,6 +1105,7 @@ static int __driver_rfc4106_decrypt(struct aead_request *req)
int retval = 0;
struct crypto_aead *tfm = crypto_aead_reqtfm(req);
struct aesni_rfc4106_gcm_ctx *ctx = aesni_rfc4106_gcm_ctx_get(tfm);
u32 key_len = ctx->aes_key_expanded.key_length;
void *aes_ctx = &(ctx->aes_key_expanded);
unsigned long auth_tag_len = crypto_aead_authsize(tfm);
u8 iv_and_authTag[32+AESNI_ALIGN];
@ -1104,6 +1119,13 @@ static int __driver_rfc4106_decrypt(struct aead_request *req)
if (unlikely((req->cryptlen < auth_tag_len) ||
(req->assoclen != 8 && req->assoclen != 12)))
return -EINVAL;
if (unlikely(auth_tag_len != 8 && auth_tag_len != 12 && auth_tag_len != 16))
return -EINVAL;
if (unlikely(key_len != AES_KEYSIZE_128 &&
key_len != AES_KEYSIZE_192 &&
key_len != AES_KEYSIZE_256))
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 */