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|
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Copyright(c) 2011-2018 Intel Corporation All rights reserved.
;
; Redistribution and use in source and binary forms, with or without
; modification, are permitted provided that the following conditions
; are met:
; * Redistributions of source code must retain the above copyright
; notice, this list of conditions and the following disclaimer.
; * Redistributions in binary form must reproduce the above copyright
; notice, this list of conditions and the following disclaimer in
; the documentation and/or other materials provided with the
; distribution.
; * Neither the name of Intel Corporation nor the names of its
; contributors may be used to endorse or promote products derived
; from this software without specific prior written permission.
;
; THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
; "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
; LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
; A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
; OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
; SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
; LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
; DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
; THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
; (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
; OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;
; Authors:
; Erdinc Ozturk
; Vinodh Gopal
; James Guilford
;
;
; References:
; This code was derived and highly optimized from the code described in paper:
; Vinodh Gopal et. al. Optimized Galois-Counter-Mode Implementation on Intel Architecture Processors. August, 2010
;
; For the shift-based reductions used in this code, we used the method described in paper:
; Shay Gueron, Michael E. Kounavis. Intel Carry-Less Multiplication Instruction and its Usage for Computing the GCM Mode. January, 2010.
;
;
;
;
; Assumptions:
;
;
;
; 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 will be padded with 0 to the next 16byte multiple
; 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:
; Must be a multiple of 4 bytes and from the definition of the spec.
; The code additionally supports any aadLen length.
;
; TLen:
; from the definition of the spec, TLen can only be 8, 12 or 16 bytes.
;
; poly = x^128 + x^127 + x^126 + x^121 + 1
; throughout the code, one tab and two tab indentations are used. one tab is for GHASH part, two tabs is for AES part.
;
%include "os.asm"
%include "reg_sizes.asm"
%include "gcm_defines.asm"
%ifndef GCM128_MODE
%ifndef GCM192_MODE
%ifndef GCM256_MODE
%error "No GCM mode selected for gcm_avx_gen2.asm!"
%endif
%endif
%endif
%ifdef GCM128_MODE
%define FN_NAME(x,y) aes_gcm_ %+ x %+ _128 %+ y %+ avx_gen2
%define NROUNDS 9
%endif
%ifdef GCM192_MODE
%define FN_NAME(x,y) aes_gcm_ %+ x %+ _192 %+ y %+ avx_gen2
%define NROUNDS 11
%endif
%ifdef GCM256_MODE
%define FN_NAME(x,y) aes_gcm_ %+ x %+ _256 %+ y %+ avx_gen2
%define NROUNDS 13
%endif
default rel
; need to push 4 registers into stack to maintain
%define STACK_OFFSET 8*4
%define TMP2 16*0 ; Temporary storage for AES State 2 (State 1 is stored in an XMM register)
%define TMP3 16*1 ; Temporary storage for AES State 3
%define TMP4 16*2 ; Temporary storage for AES State 4
%define TMP5 16*3 ; Temporary storage for AES State 5
%define TMP6 16*4 ; Temporary storage for AES State 6
%define TMP7 16*5 ; Temporary storage for AES State 7
%define TMP8 16*6 ; Temporary storage for AES State 8
%define LOCAL_STORAGE 16*7
%ifidn __OUTPUT_FORMAT__, win64
%define XMM_STORAGE 16*10
%else
%define XMM_STORAGE 0
%endif
%define VARIABLE_OFFSET LOCAL_STORAGE + XMM_STORAGE
section .text
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Utility Macros
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; 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 7
%define %%GH %1 ; 16 Bytes
%define %%HK %2 ; 16 Bytes
%define %%T1 %3
%define %%T2 %4
%define %%T3 %5
%define %%T4 %6
%define %%T5 %7
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Karatsuba
vpshufd %%T2, %%GH, 01001110b
vpshufd %%T3, %%HK, 01001110b
vpxor %%T2, %%T2, %%GH ; %%T2 = (a1+a0)
vpxor %%T3, %%T3, %%HK ; %%T3 = (b1+b0)
vpclmulqdq %%T1, %%GH, %%HK, 0x11 ; %%T1 = a1*b1
vpclmulqdq %%GH, %%HK, 0x00 ; %%GH = a0*b0
vpclmulqdq %%T2, %%T3, 0x00 ; %%T2 = (a1+a0)*(b1+b0)
vpxor %%T2, %%T2, %%GH
vpxor %%T2, %%T2, %%T1 ; %%T2 = a0*b1+a1*b0
vpslldq %%T3, %%T2, 8 ; shift-L %%T3 2 DWs
vpsrldq %%T2, %%T2, 8 ; shift-R %%T2 2 DWs
vpxor %%GH, %%GH, %%T3
vpxor %%T1, %%T1, %%T2 ; <%%T1:%%GH> = %%GH x %%HK
;first phase of the reduction
vpslld %%T2, %%GH, 31 ; packed right shifting << 31
vpslld %%T3, %%GH, 30 ; packed right shifting shift << 30
vpslld %%T4, %%GH, 25 ; packed right shifting shift << 25
vpxor %%T2, %%T2, %%T3 ; xor the shifted versions
vpxor %%T2, %%T2, %%T4
vpsrldq %%T5, %%T2, 4 ; shift-R %%T5 1 DW
vpslldq %%T2, %%T2, 12 ; shift-L %%T2 3 DWs
vpxor %%GH, %%GH, %%T2 ; first phase of the reduction complete
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;second phase of the reduction
vpsrld %%T2,%%GH,1 ; packed left shifting >> 1
vpsrld %%T3,%%GH,2 ; packed left shifting >> 2
vpsrld %%T4,%%GH,7 ; packed left shifting >> 7
vpxor %%T2, %%T2, %%T3 ; xor the shifted versions
vpxor %%T2, %%T2, %%T4
vpxor %%T2, %%T2, %%T5
vpxor %%GH, %%GH, %%T2
vpxor %%GH, %%GH, %%T1 ; the result is in %%GH
%endmacro
%macro PRECOMPUTE 8
%define %%GDATA %1
%define %%HK %2
%define %%T1 %3
%define %%T2 %4
%define %%T3 %5
%define %%T4 %6
%define %%T5 %7
%define %%T6 %8
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Haskey_i_k holds XORed values of the low and high parts of the Haskey_i
vmovdqa %%T5, %%HK
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_k], %%T1
GHASH_MUL %%T5, %%HK, %%T1, %%T3, %%T4, %%T6, %%T2 ; %%T5 = HashKey^2<<1 mod poly
vmovdqu [%%GDATA + HashKey_2], %%T5 ; [HashKey_2] = HashKey^2<<1 mod poly
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_2_k], %%T1
GHASH_MUL %%T5, %%HK, %%T1, %%T3, %%T4, %%T6, %%T2 ; %%T5 = HashKey^3<<1 mod poly
vmovdqu [%%GDATA + HashKey_3], %%T5
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_3_k], %%T1
GHASH_MUL %%T5, %%HK, %%T1, %%T3, %%T4, %%T6, %%T2 ; %%T5 = HashKey^4<<1 mod poly
vmovdqu [%%GDATA + HashKey_4], %%T5
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_4_k], %%T1
GHASH_MUL %%T5, %%HK, %%T1, %%T3, %%T4, %%T6, %%T2 ; %%T5 = HashKey^5<<1 mod poly
vmovdqu [%%GDATA + HashKey_5], %%T5
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_5_k], %%T1
GHASH_MUL %%T5, %%HK, %%T1, %%T3, %%T4, %%T6, %%T2 ; %%T5 = HashKey^6<<1 mod poly
vmovdqu [%%GDATA + HashKey_6], %%T5
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_6_k], %%T1
GHASH_MUL %%T5, %%HK, %%T1, %%T3, %%T4, %%T6, %%T2 ; %%T5 = HashKey^7<<1 mod poly
vmovdqu [%%GDATA + HashKey_7], %%T5
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_7_k], %%T1
GHASH_MUL %%T5, %%HK, %%T1, %%T3, %%T4, %%T6, %%T2 ; %%T5 = HashKey^8<<1 mod poly
vmovdqu [%%GDATA + HashKey_8], %%T5
vpshufd %%T1, %%T5, 01001110b
vpxor %%T1, %%T5
vmovdqu [%%GDATA + HashKey_8_k], %%T1
%endmacro
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; READ_SMALL_DATA_INPUT: Packs xmm register with data when data input is less than 16 bytes.
; Returns 0 if data has length 0.
; Input: The input data (INPUT), that data's length (LENGTH).
; Output: The packed xmm register (OUTPUT).
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%macro READ_SMALL_DATA_INPUT 6
%define %%OUTPUT %1 ; %%OUTPUT is an xmm register
%define %%INPUT %2
%define %%LENGTH %3
%define %%END_READ_LOCATION %4 ; All this and the lower inputs are temp registers
%define %%COUNTER %5
%define %%TMP1 %6
vpxor %%OUTPUT, %%OUTPUT
mov %%COUNTER, %%LENGTH
mov %%END_READ_LOCATION, %%INPUT
add %%END_READ_LOCATION, %%LENGTH
xor %%TMP1, %%TMP1
cmp %%COUNTER, 8
jl %%_byte_loop_2
vpinsrq %%OUTPUT, [%%INPUT],0 ;Read in 8 bytes if they exists
je %%_done
sub %%COUNTER, 8
%%_byte_loop_1: ;Read in data 1 byte at a time while data is left
shl %%TMP1, 8 ;This loop handles when 8 bytes were already read in
dec %%END_READ_LOCATION
mov BYTE(%%TMP1), BYTE [%%END_READ_LOCATION]
dec %%COUNTER
jg %%_byte_loop_1
vpinsrq %%OUTPUT, %%TMP1, 1
jmp %%_done
%%_byte_loop_2: ;Read in data 1 byte at a time while data is left
cmp %%COUNTER, 0
je %%_done
shl %%TMP1, 8 ;This loop handles when no bytes were already read in
dec %%END_READ_LOCATION
mov BYTE(%%TMP1), BYTE [%%END_READ_LOCATION]
dec %%COUNTER
jg %%_byte_loop_2
vpinsrq %%OUTPUT, %%TMP1, 0
%%_done:
%endmacro ; READ_SMALL_DATA_INPUT
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; CALC_AAD_HASH: Calculates the hash of the data which will not be encrypted.
; Input: The input data (A_IN), that data's length (A_LEN), and the hash key (HASH_KEY).
; Output: The hash of the data (AAD_HASH).
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%macro CALC_AAD_HASH 14
%define %%A_IN %1
%define %%A_LEN %2
%define %%AAD_HASH %3
%define %%HASH_KEY %4
%define %%XTMP1 %5 ; xmm temp reg 5
%define %%XTMP2 %6
%define %%XTMP3 %7
%define %%XTMP4 %8
%define %%XTMP5 %9 ; xmm temp reg 5
%define %%T1 %10 ; temp reg 1
%define %%T2 %11
%define %%T3 %12
%define %%T4 %13
%define %%T5 %14 ; temp reg 5
mov %%T1, %%A_IN ; T1 = AAD
mov %%T2, %%A_LEN ; T2 = aadLen
vpxor %%AAD_HASH, %%AAD_HASH
cmp %%T2, 16
jl %%_get_small_AAD_block
%%_get_AAD_loop16:
vmovdqu %%XTMP1, [%%T1]
;byte-reflect the AAD data
vpshufb %%XTMP1, [SHUF_MASK]
vpxor %%AAD_HASH, %%XTMP1
GHASH_MUL %%AAD_HASH, %%HASH_KEY, %%XTMP1, %%XTMP2, %%XTMP3, %%XTMP4, %%XTMP5
sub %%T2, 16
je %%_CALC_AAD_done
add %%T1, 16
cmp %%T2, 16
jge %%_get_AAD_loop16
%%_get_small_AAD_block:
READ_SMALL_DATA_INPUT %%XTMP1, %%T1, %%T2, %%T3, %%T4, %%T5
;byte-reflect the AAD data
vpshufb %%XTMP1, [SHUF_MASK]
vpxor %%AAD_HASH, %%XTMP1
GHASH_MUL %%AAD_HASH, %%HASH_KEY, %%XTMP1, %%XTMP2, %%XTMP3, %%XTMP4, %%XTMP5
%%_CALC_AAD_done:
%endmacro ; CALC_AAD_HASH
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; PARTIAL_BLOCK: Handles encryption/decryption and the tag partial blocks between update calls.
; Requires the input data be at least 1 byte long.
; Input:
; GDATA_KEY - struct gcm_key_data *
; GDATA_CTX - struct gcm_context_data *
; PLAIN_CYPH_IN - input text
; PLAIN_CYPH_LEN - input text length
; DATA_OFFSET - the current data offset
; ENC_DEC - whether encoding or decoding
; Output: A cypher of the first partial block (CYPH_PLAIN_OUT), and updated GDATA_CTX
; Clobbers rax, r10, r12, r13, r15, xmm0, xmm1, xmm2, xmm3, xmm5, xmm6, xmm9, xmm10, xmm11, xmm13
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%macro PARTIAL_BLOCK 8
%define %%GDATA_KEY %1
%define %%GDATA_CTX %2
%define %%CYPH_PLAIN_OUT %3
%define %%PLAIN_CYPH_IN %4
%define %%PLAIN_CYPH_LEN %5
%define %%DATA_OFFSET %6
%define %%AAD_HASH %7
%define %%ENC_DEC %8
mov r13, [%%GDATA_CTX + PBlockLen]
cmp r13, 0
je %%_partial_block_done ;Leave Macro if no partial blocks
cmp %%PLAIN_CYPH_LEN, 16 ;Read in input data without over reading
jl %%_fewer_than_16_bytes
VXLDR xmm1, [%%PLAIN_CYPH_IN] ;If more than 16 bytes of data, just fill the xmm register
jmp %%_data_read
%%_fewer_than_16_bytes:
lea r10, [%%PLAIN_CYPH_IN + %%DATA_OFFSET]
READ_SMALL_DATA_INPUT xmm1, r10, %%PLAIN_CYPH_LEN, rax, r12, r15
%%_data_read: ;Finished reading in data
vmovdqu xmm9, [%%GDATA_CTX + PBlockEncKey] ;xmm9 = my_ctx_data.partial_block_enc_key
vmovdqu xmm13, [%%GDATA_KEY + HashKey]
lea r12, [SHIFT_MASK]
cmp r13, rax
add r12, r13 ; adjust the shuffle mask pointer to be able to shift r13 bytes (16-r13 is the number of bytes in plaintext mod 16)
vmovdqu xmm2, [r12] ; get the appropriate shuffle mask
vpshufb xmm9, xmm2 ;shift right r13 bytes
%ifidn %%ENC_DEC, DEC
vmovdqa xmm3, xmm1
vpxor xmm9, xmm1 ; Cyphertext XOR E(K, Yn)
mov r15, %%PLAIN_CYPH_LEN
add r15, r13
sub r15, 16 ;Set r15 to be the amount of data left in CYPH_PLAIN_IN after filling the block
jge %%_no_extra_mask_1 ;Determine if if partial block is not being filled and shift mask accordingly
sub r12, r15
%%_no_extra_mask_1:
vmovdqu xmm1, [r12 + ALL_F-SHIFT_MASK] ; get the appropriate mask to mask out bottom r13 bytes of xmm9
vpand xmm9, xmm1 ; mask out bottom r13 bytes of xmm9
vpand xmm3, xmm1
vpshufb xmm3, [SHUF_MASK]
vpshufb xmm3, xmm2
vpxor %%AAD_HASH, xmm3
cmp r15,0
jl %%_partial_incomplete_1
GHASH_MUL %%AAD_HASH, xmm13, xmm0, xmm10, xmm11, xmm5, xmm6 ;GHASH computation for the last <16 Byte block
xor rax,rax
mov [%%GDATA_CTX + PBlockLen], rax
jmp %%_dec_done
%%_partial_incomplete_1:
%ifidn __OUTPUT_FORMAT__, win64
mov rax, %%PLAIN_CYPH_LEN
add [%%GDATA_CTX + PBlockLen], rax
%else
add [%%GDATA_CTX + PBlockLen], %%PLAIN_CYPH_LEN
%endif
%%_dec_done:
vmovdqu [%%GDATA_CTX + AadHash], %%AAD_HASH
%else
vpxor xmm9, xmm1 ; Plaintext XOR E(K, Yn)
mov r15, %%PLAIN_CYPH_LEN
add r15, r13
sub r15, 16 ;Set r15 to be the amount of data left in CYPH_PLAIN_IN after filling the block
jge %%_no_extra_mask_2 ;Determine if if partial block is not being filled and shift mask accordingly
sub r12, r15
%%_no_extra_mask_2:
vmovdqu xmm1, [r12 + ALL_F-SHIFT_MASK] ; get the appropriate mask to mask out bottom r13 bytes of xmm9
vpand xmm9, xmm1 ; mask out bottom r13 bytes of xmm9
vpshufb xmm9, [SHUF_MASK]
vpshufb xmm9, xmm2
vpxor %%AAD_HASH, xmm9
cmp r15,0
jl %%_partial_incomplete_2
GHASH_MUL %%AAD_HASH, xmm13, xmm0, xmm10, xmm11, xmm5, xmm6 ;GHASH computation for the last <16 Byte block
xor rax,rax
mov [%%GDATA_CTX + PBlockLen], rax
jmp %%_encode_done
%%_partial_incomplete_2:
%ifidn __OUTPUT_FORMAT__, win64
mov rax, %%PLAIN_CYPH_LEN
add [%%GDATA_CTX + PBlockLen], rax
%else
add [%%GDATA_CTX + PBlockLen], %%PLAIN_CYPH_LEN
%endif
%%_encode_done:
vmovdqu [%%GDATA_CTX + AadHash], %%AAD_HASH
vpshufb xmm9, [SHUF_MASK] ; shuffle xmm9 back to output as ciphertext
vpshufb xmm9, xmm2
%endif
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; output encrypted Bytes
cmp r15,0
jl %%_partial_fill
mov r12, r13
mov r13, 16
sub r13, r12 ; Set r13 to be the number of bytes to write out
jmp %%_count_set
%%_partial_fill:
mov r13, %%PLAIN_CYPH_LEN
%%_count_set:
vmovq rax, xmm9
cmp r13, 8
jle %%_less_than_8_bytes_left
mov [%%CYPH_PLAIN_OUT+ %%DATA_OFFSET], rax
add %%DATA_OFFSET, 8
vpsrldq xmm9, xmm9, 8
vmovq rax, xmm9
sub r13, 8
%%_less_than_8_bytes_left:
mov BYTE [%%CYPH_PLAIN_OUT + %%DATA_OFFSET], al
add %%DATA_OFFSET, 1
shr rax, 8
sub r13, 1
jne %%_less_than_8_bytes_left
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%%_partial_block_done:
%endmacro ; PARTIAL_BLOCK
; if a = number of total plaintext bytes
; b = floor(a/16)
; %%num_initial_blocks = b mod 8;
; encrypt the initial %%num_initial_blocks blocks and apply ghash on the ciphertext
; %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r14 are used as a pointer only, not modified.
; Updated AAD_HASH is returned in %%T3
%macro INITIAL_BLOCKS 24
%define %%GDATA_KEY %1
%define %%GDATA_CTX %2
%define %%CYPH_PLAIN_OUT %3
%define %%PLAIN_CYPH_IN %4
%define %%LENGTH %5
%define %%DATA_OFFSET %6
%define %%num_initial_blocks %7 ; can be 0, 1, 2, 3, 4, 5, 6 or 7
%define %%T1 %8
%define %%HASH_KEY %9
%define %%T3 %10
%define %%T4 %11
%define %%T5 %12
%define %%CTR %13
%define %%XMM1 %14
%define %%XMM2 %15
%define %%XMM3 %16
%define %%XMM4 %17
%define %%XMM5 %18
%define %%XMM6 %19
%define %%XMM7 %20
%define %%XMM8 %21
%define %%T6 %22
%define %%T_key %23
%define %%ENC_DEC %24
%assign i (8-%%num_initial_blocks)
vmovdqu reg(i), %%XMM8 ; move AAD_HASH to temp reg
; start AES for %%num_initial_blocks blocks
vmovdqu %%CTR, [%%GDATA_CTX + CurCount] ; %%CTR = Y0
%assign i (9-%%num_initial_blocks)
%rep %%num_initial_blocks
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa reg(i), %%CTR
vpshufb reg(i), [SHUF_MASK] ; perform a 16Byte swap
%assign i (i+1)
%endrep
vmovdqu %%T_key, [%%GDATA_KEY+16*0]
%assign i (9-%%num_initial_blocks)
%rep %%num_initial_blocks
vpxor reg(i),%%T_key
%assign i (i+1)
%endrep
%assign j 1
%rep NROUNDS
vmovdqu %%T_key, [%%GDATA_KEY+16*j]
%assign i (9-%%num_initial_blocks)
%rep %%num_initial_blocks
vaesenc reg(i),%%T_key
%assign i (i+1)
%endrep
%assign j (j+1)
%endrep ; NROUNDS
vmovdqu %%T_key, [%%GDATA_KEY+16*j]
%assign i (9-%%num_initial_blocks)
%rep %%num_initial_blocks
vaesenclast reg(i),%%T_key
%assign i (i+1)
%endrep
%assign i (9-%%num_initial_blocks)
%rep %%num_initial_blocks
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET]
vpxor reg(i), %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET], reg(i) ; write back ciphertext for %%num_initial_blocks blocks
add %%DATA_OFFSET, 16
%ifidn %%ENC_DEC, DEC
vmovdqa reg(i), %%T1
%endif
vpshufb reg(i), [SHUF_MASK] ; prepare ciphertext for GHASH computations
%assign i (i+1)
%endrep
%assign i (8-%%num_initial_blocks)
%assign j (9-%%num_initial_blocks)
%rep %%num_initial_blocks
vpxor reg(j), reg(i)
GHASH_MUL reg(j), %%HASH_KEY, %%T1, %%T3, %%T4, %%T5, %%T6 ; apply GHASH on %%num_initial_blocks blocks
%assign i (i+1)
%assign j (j+1)
%endrep
; %%XMM8 has the current Hash Value
vmovdqa %%T3, %%XMM8
cmp %%LENGTH, 128
jl %%_initial_blocks_done ; no need for precomputed constants
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Haskey_i_k holds XORed values of the low and high parts of the Haskey_i
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM1, %%CTR
vpshufb %%XMM1, [SHUF_MASK] ; perform a 16Byte swap
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM2, %%CTR
vpshufb %%XMM2, [SHUF_MASK] ; perform a 16Byte swap
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM3, %%CTR
vpshufb %%XMM3, [SHUF_MASK] ; perform a 16Byte swap
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM4, %%CTR
vpshufb %%XMM4, [SHUF_MASK] ; perform a 16Byte swap
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM5, %%CTR
vpshufb %%XMM5, [SHUF_MASK] ; perform a 16Byte swap
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM6, %%CTR
vpshufb %%XMM6, [SHUF_MASK] ; perform a 16Byte swap
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM7, %%CTR
vpshufb %%XMM7, [SHUF_MASK] ; perform a 16Byte swap
vpaddd %%CTR, [ONE] ; INCR Y0
vmovdqa %%XMM8, %%CTR
vpshufb %%XMM8, [SHUF_MASK] ; perform a 16Byte swap
vmovdqu %%T_key, [%%GDATA_KEY+16*0]
vpxor %%XMM1, %%T_key
vpxor %%XMM2, %%T_key
vpxor %%XMM3, %%T_key
vpxor %%XMM4, %%T_key
vpxor %%XMM5, %%T_key
vpxor %%XMM6, %%T_key
vpxor %%XMM7, %%T_key
vpxor %%XMM8, %%T_key
%assign i 1
%rep NROUNDS
vmovdqu %%T_key, [%%GDATA_KEY+16*i]
vaesenc %%XMM1, %%T_key
vaesenc %%XMM2, %%T_key
vaesenc %%XMM3, %%T_key
vaesenc %%XMM4, %%T_key
vaesenc %%XMM5, %%T_key
vaesenc %%XMM6, %%T_key
vaesenc %%XMM7, %%T_key
vaesenc %%XMM8, %%T_key
%assign i (i+1)
%endrep
vmovdqu %%T_key, [%%GDATA_KEY+16*i]
vaesenclast %%XMM1, %%T_key
vaesenclast %%XMM2, %%T_key
vaesenclast %%XMM3, %%T_key
vaesenclast %%XMM4, %%T_key
vaesenclast %%XMM5, %%T_key
vaesenclast %%XMM6, %%T_key
vaesenclast %%XMM7, %%T_key
vaesenclast %%XMM8, %%T_key
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*0]
vpxor %%XMM1, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*0], %%XMM1
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM1, %%T1
%endif
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*1]
vpxor %%XMM2, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*1], %%XMM2
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM2, %%T1
%endif
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*2]
vpxor %%XMM3, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*2], %%XMM3
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM3, %%T1
%endif
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*3]
vpxor %%XMM4, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*3], %%XMM4
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM4, %%T1
%endif
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*4]
vpxor %%XMM5, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*4], %%XMM5
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM5, %%T1
%endif
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*5]
vpxor %%XMM6, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*5], %%XMM6
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM6, %%T1
%endif
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*6]
vpxor %%XMM7, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*6], %%XMM7
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM7, %%T1
%endif
VXLDR %%T1, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*7]
vpxor %%XMM8, %%T1
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*7], %%XMM8
%ifidn %%ENC_DEC, DEC
vmovdqa %%XMM8, %%T1
%endif
add %%DATA_OFFSET, 128
vpshufb %%XMM1, [SHUF_MASK] ; perform a 16Byte swap
vpxor %%XMM1, %%T3 ; combine GHASHed value with the corresponding ciphertext
vpshufb %%XMM2, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM3, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM4, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM5, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM6, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM7, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM8, [SHUF_MASK] ; perform a 16Byte swap
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%%_initial_blocks_done:
%endmacro
; encrypt 8 blocks at a time
; ghash the 8 previously encrypted ciphertext blocks
; %%GDATA - (GCM key data), %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN are used as pointers only, not modified
; r11 is the data offset value
%macro GHASH_8_ENCRYPT_8_PARALLEL 22
%define %%GDATA %1
%define %%CYPH_PLAIN_OUT %2
%define %%PLAIN_CYPH_IN %3
%define %%DATA_OFFSET %4
%define %%T1 %5
%define %%T2 %6
%define %%T3 %7
%define %%T4 %8
%define %%T5 %9
%define %%T6 %10
%define %%CTR %11
%define %%XMM1 %12
%define %%XMM2 %13
%define %%XMM3 %14
%define %%XMM4 %15
%define %%XMM5 %16
%define %%XMM6 %17
%define %%XMM7 %18
%define %%XMM8 %19
%define %%T7 %20
%define %%loop_idx %21
%define %%ENC_DEC %22
vmovdqa %%T2, %%XMM1
vmovdqu [rsp + TMP2], %%XMM2
vmovdqu [rsp + TMP3], %%XMM3
vmovdqu [rsp + TMP4], %%XMM4
vmovdqu [rsp + TMP5], %%XMM5
vmovdqu [rsp + TMP6], %%XMM6
vmovdqu [rsp + TMP7], %%XMM7
vmovdqu [rsp + TMP8], %%XMM8
%ifidn %%loop_idx, in_order
vpaddd %%XMM1, %%CTR, [ONE] ; INCR CNT
vpaddd %%XMM2, %%XMM1, [ONE]
vpaddd %%XMM3, %%XMM2, [ONE]
vpaddd %%XMM4, %%XMM3, [ONE]
vpaddd %%XMM5, %%XMM4, [ONE]
vpaddd %%XMM6, %%XMM5, [ONE]
vpaddd %%XMM7, %%XMM6, [ONE]
vpaddd %%XMM8, %%XMM7, [ONE]
vmovdqa %%CTR, %%XMM8
vpshufb %%XMM1, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM2, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM3, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM4, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM5, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM6, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM7, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM8, [SHUF_MASK] ; perform a 16Byte swap
%else
vpaddd %%XMM1, %%CTR, [ONEf] ; INCR CNT
vpaddd %%XMM2, %%XMM1, [ONEf]
vpaddd %%XMM3, %%XMM2, [ONEf]
vpaddd %%XMM4, %%XMM3, [ONEf]
vpaddd %%XMM5, %%XMM4, [ONEf]
vpaddd %%XMM6, %%XMM5, [ONEf]
vpaddd %%XMM7, %%XMM6, [ONEf]
vpaddd %%XMM8, %%XMM7, [ONEf]
vmovdqa %%CTR, %%XMM8
%endif
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
vmovdqu %%T1, [%%GDATA + 16*0]
vpxor %%XMM1, %%T1
vpxor %%XMM2, %%T1
vpxor %%XMM3, %%T1
vpxor %%XMM4, %%T1
vpxor %%XMM5, %%T1
vpxor %%XMM6, %%T1
vpxor %%XMM7, %%T1
vpxor %%XMM8, %%T1
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
vmovdqu %%T1, [%%GDATA + 16*1]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
vmovdqu %%T1, [%%GDATA + 16*2]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
vmovdqu %%T5, [%%GDATA + HashKey_8]
vpclmulqdq %%T4, %%T2, %%T5, 0x11 ; %%T4 = a1*b1
vpclmulqdq %%T7, %%T2, %%T5, 0x00 ; %%T7 = a0*b0
vpshufd %%T6, %%T2, 01001110b
vpxor %%T6, %%T2
vmovdqu %%T5, [%%GDATA + HashKey_8_k]
vpclmulqdq %%T6, %%T6, %%T5, 0x00 ;
vmovdqu %%T1, [%%GDATA + 16*3]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
vmovdqu %%T1, [rsp + TMP2]
vmovdqu %%T5, [%%GDATA + HashKey_7]
vpclmulqdq %%T3, %%T1, %%T5, 0x11
vpxor %%T4, %%T4, %%T3
vpclmulqdq %%T3, %%T1, %%T5, 0x00
vpxor %%T7, %%T7, %%T3
vpshufd %%T3, %%T1, 01001110b
vpxor %%T3, %%T1
vmovdqu %%T5, [%%GDATA + HashKey_7_k]
vpclmulqdq %%T3, %%T3, %%T5, 0x10
vpxor %%T6, %%T6, %%T3
vmovdqu %%T1, [%%GDATA + 16*4]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
vmovdqu %%T1, [rsp + TMP3]
vmovdqu %%T5, [%%GDATA + HashKey_6]
vpclmulqdq %%T3, %%T1, %%T5, 0x11
vpxor %%T4, %%T4, %%T3
vpclmulqdq %%T3, %%T1, %%T5, 0x00
vpxor %%T7, %%T7, %%T3
vpshufd %%T3, %%T1, 01001110b
vpxor %%T3, %%T1
vmovdqu %%T5, [%%GDATA + HashKey_6_k]
vpclmulqdq %%T3, %%T3, %%T5, 0x10
vpxor %%T6, %%T6, %%T3
vmovdqu %%T1, [%%GDATA + 16*5]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
vmovdqu %%T1, [rsp + TMP4]
vmovdqu %%T5, [%%GDATA + HashKey_5]
vpclmulqdq %%T3, %%T1, %%T5, 0x11
vpxor %%T4, %%T4, %%T3
vpclmulqdq %%T3, %%T1, %%T5, 0x00
vpxor %%T7, %%T7, %%T3
vpshufd %%T3, %%T1, 01001110b
vpxor %%T3, %%T1
vmovdqu %%T5, [%%GDATA + HashKey_5_k]
vpclmulqdq %%T3, %%T3, %%T5, 0x10
vpxor %%T6, %%T6, %%T3
vmovdqu %%T1, [%%GDATA + 16*6]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
vmovdqu %%T1, [rsp + TMP5]
vmovdqu %%T5, [%%GDATA + HashKey_4]
vpclmulqdq %%T3, %%T1, %%T5, 0x11
vpxor %%T4, %%T4, %%T3
vpclmulqdq %%T3, %%T1, %%T5, 0x00
vpxor %%T7, %%T7, %%T3
vpshufd %%T3, %%T1, 01001110b
vpxor %%T3, %%T1
vmovdqu %%T5, [%%GDATA + HashKey_4_k]
vpclmulqdq %%T3, %%T3, %%T5, 0x10
vpxor %%T6, %%T6, %%T3
vmovdqu %%T1, [%%GDATA + 16*7]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
vmovdqu %%T1, [rsp + TMP6]
vmovdqu %%T5, [%%GDATA + HashKey_3]
vpclmulqdq %%T3, %%T1, %%T5, 0x11
vpxor %%T4, %%T4, %%T3
vpclmulqdq %%T3, %%T1, %%T5, 0x00
vpxor %%T7, %%T7, %%T3
vpshufd %%T3, %%T1, 01001110b
vpxor %%T3, %%T1
vmovdqu %%T5, [%%GDATA + HashKey_3_k]
vpclmulqdq %%T3, %%T3, %%T5, 0x10
vpxor %%T6, %%T6, %%T3
vmovdqu %%T1, [%%GDATA + 16*8]
vaesenc %%XMM1, %%T1
vaesenc %%XMM2, %%T1
vaesenc %%XMM3, %%T1
vaesenc %%XMM4, %%T1
vaesenc %%XMM5, %%T1
vaesenc %%XMM6, %%T1
vaesenc %%XMM7, %%T1
vaesenc %%XMM8, %%T1
vmovdqu %%T1, [rsp + TMP7]
vmovdqu %%T5, [%%GDATA + HashKey_2]
vpclmulqdq %%T3, %%T1, %%T5, 0x11
vpxor %%T4, %%T4, %%T3
vpclmulqdq %%T3, %%T1, %%T5, 0x00
vpxor %%T7, %%T7, %%T3
vpshufd %%T3, %%T1, 01001110b
vpxor %%T3, %%T1
vmovdqu %%T5, [%%GDATA + HashKey_2_k]
vpclmulqdq %%T3, %%T3, %%T5, 0x10
vpxor %%T6, %%T6, %%T3
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
vmovdqu %%T5, [%%GDATA + 16*9]
vaesenc %%XMM1, %%T5
vaesenc %%XMM2, %%T5
vaesenc %%XMM3, %%T5
vaesenc %%XMM4, %%T5
vaesenc %%XMM5, %%T5
vaesenc %%XMM6, %%T5
vaesenc %%XMM7, %%T5
vaesenc %%XMM8, %%T5
vmovdqu %%T1, [rsp + TMP8]
vmovdqu %%T5, [%%GDATA + HashKey]
vpclmulqdq %%T3, %%T1, %%T5, 0x11
vpxor %%T4, %%T4, %%T3
vpclmulqdq %%T3, %%T1, %%T5, 0x00
vpxor %%T7, %%T7, %%T3
vpshufd %%T3, %%T1, 01001110b
vpxor %%T3, %%T1
vmovdqu %%T5, [%%GDATA + HashKey_k]
vpclmulqdq %%T3, %%T3, %%T5, 0x10
vpxor %%T6, %%T6, %%T3
vpxor %%T6, %%T4
vpxor %%T6, %%T7
%ifdef GCM128_MODE
vmovdqu %%T5, [%%GDATA + 16*10]
%endif
%ifdef GCM192_MODE
vmovdqu %%T5, [%%GDATA + 16*10]
vaesenc %%XMM1, %%T5
vaesenc %%XMM2, %%T5
vaesenc %%XMM3, %%T5
vaesenc %%XMM4, %%T5
vaesenc %%XMM5, %%T5
vaesenc %%XMM6, %%T5
vaesenc %%XMM7, %%T5
vaesenc %%XMM8, %%T5
vmovdqu %%T5, [%%GDATA + 16*11]
vaesenc %%XMM1, %%T5
vaesenc %%XMM2, %%T5
vaesenc %%XMM3, %%T5
vaesenc %%XMM4, %%T5
vaesenc %%XMM5, %%T5
vaesenc %%XMM6, %%T5
vaesenc %%XMM7, %%T5
vaesenc %%XMM8, %%T5
vmovdqu %%T5, [%%GDATA + 16*12]
%endif
%ifdef GCM256_MODE
vmovdqu %%T5, [%%GDATA + 16*10]
vaesenc %%XMM1, %%T5
vaesenc %%XMM2, %%T5
vaesenc %%XMM3, %%T5
vaesenc %%XMM4, %%T5
vaesenc %%XMM5, %%T5
vaesenc %%XMM6, %%T5
vaesenc %%XMM7, %%T5
vaesenc %%XMM8, %%T5
vmovdqu %%T5, [%%GDATA + 16*11]
vaesenc %%XMM1, %%T5
vaesenc %%XMM2, %%T5
vaesenc %%XMM3, %%T5
vaesenc %%XMM4, %%T5
vaesenc %%XMM5, %%T5
vaesenc %%XMM6, %%T5
vaesenc %%XMM7, %%T5
vaesenc %%XMM8, %%T5
vmovdqu %%T5, [%%GDATA + 16*12]
vaesenc %%XMM1, %%T5
vaesenc %%XMM2, %%T5
vaesenc %%XMM3, %%T5
vaesenc %%XMM4, %%T5
vaesenc %%XMM5, %%T5
vaesenc %%XMM6, %%T5
vaesenc %%XMM7, %%T5
vaesenc %%XMM8, %%T5
vmovdqu %%T5, [%%GDATA + 16*13]
vaesenc %%XMM1, %%T5
vaesenc %%XMM2, %%T5
vaesenc %%XMM3, %%T5
vaesenc %%XMM4, %%T5
vaesenc %%XMM5, %%T5
vaesenc %%XMM6, %%T5
vaesenc %%XMM7, %%T5
vaesenc %%XMM8, %%T5
vmovdqu %%T5, [%%GDATA + 16*14]
%endif
%assign i 0
%assign j 1
%rep 8
%ifidn %%ENC_DEC, ENC
%ifdef NT_LD
VXLDR %%T2, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*i]
vpxor %%T2, %%T2, %%T5
%else
vpxor %%T2, %%T5, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*i]
%endif ; NT_LD
vaesenclast reg(j), reg(j), %%T2
%else
VXLDR %%T2, [%%PLAIN_CYPH_IN + %%DATA_OFFSET + 16*i]
vpxor %%T2, %%T2, %%T5
vaesenclast %%T3, reg(j), %%T2
vpxor reg(j), %%T2, %%T5
VXSTR [%%CYPH_PLAIN_OUT + %%DATA_OFFSET + 16*i], %%T3
%endif ; %%ENC_DEC
%assign i (i+1)
%assign j (j+1)
%endrep
vpslldq %%T3, %%T6, 8 ; shift-L %%T3 2 DWs
vpsrldq %%T6, %%T6, 8 ; shift-R %%T2 2 DWs
vpxor %%T7, %%T3
vpxor %%T6, %%T4 ; accumulate the results in %%T6:%%T7
;first phase of the reduction
vpslld %%T2, %%T7, 31 ; packed right shifting << 31
vpslld %%T3, %%T7, 30 ; packed right shifting shift << 30
vpslld %%T4, %%T7, 25 ; packed right shifting shift << 25
vpxor %%T2, %%T2, %%T3 ; xor the shifted versions
vpxor %%T2, %%T2, %%T4
vpsrldq %%T1, %%T2, 4 ; shift-R %%T1 1 DW
vpslldq %%T2, %%T2, 12 ; shift-L %%T2 3 DWs
vpxor %%T7, %%T2 ; first phase of the reduction complete
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%ifidn %%ENC_DEC, ENC
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*0], %%XMM1 ; Write to the Ciphertext buffer
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*1], %%XMM2 ; Write to the Ciphertext buffer
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*2], %%XMM3 ; Write to the Ciphertext buffer
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*3], %%XMM4 ; Write to the Ciphertext buffer
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*4], %%XMM5 ; Write to the Ciphertext buffer
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*5], %%XMM6 ; Write to the Ciphertext buffer
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*6], %%XMM7 ; Write to the Ciphertext buffer
VXSTR [%%CYPH_PLAIN_OUT+%%DATA_OFFSET+16*7], %%XMM8 ; Write to the Ciphertext buffer
%endif
;second phase of the reduction
vpsrld %%T2,%%T7,1 ; packed left shifting >> 1
vpsrld %%T3,%%T7,2 ; packed left shifting >> 2
vpsrld %%T4,%%T7,7 ; packed left shifting >> 7
vpxor %%T2, %%T2,%%T3 ; xor the shifted versions
vpxor %%T2, %%T2,%%T4
vpxor %%T2, %%T2, %%T1
vpxor %%T7, %%T7, %%T2
vpxor %%T6, %%T6, %%T7 ; the result is in %%T6
vpshufb %%XMM1, [SHUF_MASK] ; perform a 16Byte swap
vpshufb %%XMM2, [SHUF_MASK]
vpshufb %%XMM3, [SHUF_MASK]
vpshufb %%XMM4, [SHUF_MASK]
vpshufb %%XMM5, [SHUF_MASK]
vpshufb %%XMM6, [SHUF_MASK]
vpshufb %%XMM7, [SHUF_MASK]
vpshufb %%XMM8, [SHUF_MASK]
vpxor %%XMM1, %%T6
%endmacro
; GHASH the last 4 ciphertext blocks.
; %%GDATA is GCM key data
%macro GHASH_LAST_8 16
%define %%GDATA %1
%define %%T1 %2
%define %%T2 %3
%define %%T3 %4
%define %%T4 %5
%define %%T5 %6
%define %%T6 %7
%define %%T7 %8
%define %%XMM1 %9
%define %%XMM2 %10
%define %%XMM3 %11
%define %%XMM4 %12
%define %%XMM5 %13
%define %%XMM6 %14
%define %%XMM7 %15
%define %%XMM8 %16
;; Karatsuba Method
vpshufd %%T2, %%XMM1, 01001110b
vpxor %%T2, %%XMM1
vmovdqu %%T5, [%%GDATA + HashKey_8]
vpclmulqdq %%T6, %%XMM1, %%T5, 0x11
vpclmulqdq %%T7, %%XMM1, %%T5, 0x00
vmovdqu %%T3, [%%GDATA + HashKey_8_k]
vpclmulqdq %%XMM1, %%T2, %%T3, 0x00
;;;;;;;;;;;;;;;;;;;;;;
vpshufd %%T2, %%XMM2, 01001110b
vpxor %%T2, %%XMM2
vmovdqu %%T5, [%%GDATA + HashKey_7]
vpclmulqdq %%T4, %%XMM2, %%T5, 0x11
vpxor %%T6, %%T6, %%T4
vpclmulqdq %%T4, %%XMM2, %%T5, 0x00
vpxor %%T7, %%T7, %%T4
vmovdqu %%T3, [%%GDATA + HashKey_7_k]
vpclmulqdq %%T2, %%T2, %%T3, 0x00
vpxor %%XMM1, %%XMM1, %%T2
;;;;;;;;;;;;;;;;;;;;;;
vpshufd %%T2, %%XMM3, 01001110b
vpxor %%T2, %%XMM3
vmovdqu %%T5, [%%GDATA + HashKey_6]
vpclmulqdq %%T4, %%XMM3, %%T5, 0x11
vpxor %%T6, %%T6, %%T4
vpclmulqdq %%T4, %%XMM3, %%T5, 0x00
vpxor %%T7, %%T7, %%T4
vmovdqu %%T3, [%%GDATA + HashKey_6_k]
vpclmulqdq %%T2, %%T2, %%T3, 0x00
vpxor %%XMM1, %%XMM1, %%T2
;;;;;;;;;;;;;;;;;;;;;;
vpshufd %%T2, %%XMM4, 01001110b
vpxor %%T2, %%XMM4
vmovdqu %%T5, [%%GDATA + HashKey_5]
vpclmulqdq %%T4, %%XMM4, %%T5, 0x11
vpxor %%T6, %%T6, %%T4
vpclmulqdq %%T4, %%XMM4, %%T5, 0x00
vpxor %%T7, %%T7, %%T4
vmovdqu %%T3, [%%GDATA + HashKey_5_k]
vpclmulqdq %%T2, %%T2, %%T3, 0x00
vpxor %%XMM1, %%XMM1, %%T2
;;;;;;;;;;;;;;;;;;;;;;
vpshufd %%T2, %%XMM5, 01001110b
vpxor %%T2, %%XMM5
vmovdqu %%T5, [%%GDATA + HashKey_4]
vpclmulqdq %%T4, %%XMM5, %%T5, 0x11
vpxor %%T6, %%T6, %%T4
vpclmulqdq %%T4, %%XMM5, %%T5, 0x00
vpxor %%T7, %%T7, %%T4
vmovdqu %%T3, [%%GDATA + HashKey_4_k]
vpclmulqdq %%T2, %%T2, %%T3, 0x00
vpxor %%XMM1, %%XMM1, %%T2
;;;;;;;;;;;;;;;;;;;;;;
vpshufd %%T2, %%XMM6, 01001110b
vpxor %%T2, %%XMM6
vmovdqu %%T5, [%%GDATA + HashKey_3]
vpclmulqdq %%T4, %%XMM6, %%T5, 0x11
vpxor %%T6, %%T6, %%T4
vpclmulqdq %%T4, %%XMM6, %%T5, 0x00
vpxor %%T7, %%T7, %%T4
vmovdqu %%T3, [%%GDATA + HashKey_3_k]
vpclmulqdq %%T2, %%T2, %%T3, 0x00
vpxor %%XMM1, %%XMM1, %%T2
;;;;;;;;;;;;;;;;;;;;;;
vpshufd %%T2, %%XMM7, 01001110b
vpxor %%T2, %%XMM7
vmovdqu %%T5, [%%GDATA + HashKey_2]
vpclmulqdq %%T4, %%XMM7, %%T5, 0x11
vpxor %%T6, %%T6, %%T4
vpclmulqdq %%T4, %%XMM7, %%T5, 0x00
vpxor %%T7, %%T7, %%T4
vmovdqu %%T3, [%%GDATA + HashKey_2_k]
vpclmulqdq %%T2, %%T2, %%T3, 0x00
vpxor %%XMM1, %%XMM1, %%T2
;;;;;;;;;;;;;;;;;;;;;;
vpshufd %%T2, %%XMM8, 01001110b
vpxor %%T2, %%XMM8
vmovdqu %%T5, [%%GDATA + HashKey]
vpclmulqdq %%T4, %%XMM8, %%T5, 0x11
vpxor %%T6, %%T6, %%T4
vpclmulqdq %%T4, %%XMM8, %%T5, 0x00
vpxor %%T7, %%T7, %%T4
vmovdqu %%T3, [%%GDATA + HashKey_k]
vpclmulqdq %%T2, %%T2, %%T3, 0x00
vpxor %%XMM1, %%XMM1, %%T2
vpxor %%XMM1, %%XMM1, %%T6
vpxor %%T2, %%XMM1, %%T7
vpslldq %%T4, %%T2, 8
vpsrldq %%T2, %%T2, 8
vpxor %%T7, %%T4
vpxor %%T6, %%T2 ; <%%T6:%%T7> holds the result of the accumulated carry-less multiplications
;first phase of the reduction
vpslld %%T2, %%T7, 31 ; packed right shifting << 31
vpslld %%T3, %%T7, 30 ; packed right shifting shift << 30
vpslld %%T4, %%T7, 25 ; packed right shifting shift << 25
vpxor %%T2, %%T2, %%T3 ; xor the shifted versions
vpxor %%T2, %%T2, %%T4
vpsrldq %%T1, %%T2, 4 ; shift-R %%T1 1 DW
vpslldq %%T2, %%T2, 12 ; shift-L %%T2 3 DWs
vpxor %%T7, %%T2 ; first phase of the reduction complete
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;second phase of the reduction
vpsrld %%T2,%%T7,1 ; packed left shifting >> 1
vpsrld %%T3,%%T7,2 ; packed left shifting >> 2
vpsrld %%T4,%%T7,7 ; packed left shifting >> 7
vpxor %%T2, %%T2,%%T3 ; xor the shifted versions
vpxor %%T2, %%T2,%%T4
vpxor %%T2, %%T2, %%T1
vpxor %%T7, %%T7, %%T2
vpxor %%T6, %%T6, %%T7 ; the result is in %%T6
%endmacro
; Encryption of a single block
; %%GDATA is GCM key data
%macro ENCRYPT_SINGLE_BLOCK 2
%define %%GDATA %1
%define %%XMM0 %2
vpxor %%XMM0, [%%GDATA+16*0]
%assign i 1
%rep NROUNDS
vaesenc %%XMM0, [%%GDATA+16*i]
%assign i (i+1)
%endrep ; NROUNDS
vaesenclast %%XMM0, [%%GDATA+16*i]
%endmacro
;; Start of Stack Setup
%macro FUNC_SAVE 0
;; Required for Update/GMC_ENC
;the number of pushes must equal STACK_OFFSET
push r12
push r13
push r14
push r15
mov r14, rsp
sub rsp, VARIABLE_OFFSET
and rsp, ~63
%ifidn __OUTPUT_FORMAT__, win64
; xmm6:xmm15 need to be maintained for Windows
vmovdqu [rsp + LOCAL_STORAGE + 0*16],xmm6
vmovdqu [rsp + LOCAL_STORAGE + 1*16],xmm7
vmovdqu [rsp + LOCAL_STORAGE + 2*16],xmm8
vmovdqu [rsp + LOCAL_STORAGE + 3*16],xmm9
vmovdqu [rsp + LOCAL_STORAGE + 4*16],xmm10
vmovdqu [rsp + LOCAL_STORAGE + 5*16],xmm11
vmovdqu [rsp + LOCAL_STORAGE + 6*16],xmm12
vmovdqu [rsp + LOCAL_STORAGE + 7*16],xmm13
vmovdqu [rsp + LOCAL_STORAGE + 8*16],xmm14
vmovdqu [rsp + LOCAL_STORAGE + 9*16],xmm15
%endif
%endmacro
%macro FUNC_RESTORE 0
%ifidn __OUTPUT_FORMAT__, win64
vmovdqu xmm15 , [rsp + LOCAL_STORAGE + 9*16]
vmovdqu xmm14 , [rsp + LOCAL_STORAGE + 8*16]
vmovdqu xmm13 , [rsp + LOCAL_STORAGE + 7*16]
vmovdqu xmm12 , [rsp + LOCAL_STORAGE + 6*16]
vmovdqu xmm11 , [rsp + LOCAL_STORAGE + 5*16]
vmovdqu xmm10 , [rsp + LOCAL_STORAGE + 4*16]
vmovdqu xmm9 , [rsp + LOCAL_STORAGE + 3*16]
vmovdqu xmm8 , [rsp + LOCAL_STORAGE + 2*16]
vmovdqu xmm7 , [rsp + LOCAL_STORAGE + 1*16]
vmovdqu xmm6 , [rsp + LOCAL_STORAGE + 0*16]
%endif
;; Required for Update/GMC_ENC
mov rsp, r14
pop r15
pop r14
pop r13
pop r12
%endmacro
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; GCM_INIT initializes a gcm_context_data struct to prepare for encoding/decoding.
; Input: struct gcm_key_data *(GDATA_KEY), struct gcm_context_data *(GDATA_CTX),
; IV, Additional Authentication data (A_IN), Additional
; Data length (A_LEN)
; Output: Updated GDATA with the hash of A_IN (AadHash) and initialized other parts of GDATA.
; Clobbers rax, r10-r13, and xmm0-xmm6
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%macro GCM_INIT 5
%define %%GDATA_KEY %1
%define %%GDATA_CTX %2
%define %%IV %3
%define %%A_IN %4
%define %%A_LEN %5
%define %%AAD_HASH xmm0
%define %%SUBHASH xmm1
vmovdqu %%SUBHASH, [%%GDATA_KEY + HashKey]
CALC_AAD_HASH %%A_IN, %%A_LEN, %%AAD_HASH, %%SUBHASH, xmm2, xmm3, xmm4, xmm5, xmm6, r10, r11, r12, r13, rax
vpxor xmm2, xmm3
mov r10, %%A_LEN
vmovdqu [%%GDATA_CTX + AadHash], %%AAD_HASH ; ctx_data.aad hash = aad_hash
mov [%%GDATA_CTX + AadLen], r10 ; ctx_data.aad_length = aad_length
xor r10, r10
mov [%%GDATA_CTX + InLen], r10 ; ctx_data.in_length = 0
mov [%%GDATA_CTX + PBlockLen], r10 ; ctx_data.partial_block_length = 0
vmovdqu [%%GDATA_CTX + PBlockEncKey], xmm2 ; ctx_data.partial_block_enc_key = 0
mov r10, %%IV
vmovdqa xmm2, [rel ONEf] ; read 12 IV bytes and pad with 0x00000001
vpinsrq xmm2, [r10], 0
vpinsrd xmm2, [r10+8], 2
vmovdqu [%%GDATA_CTX + OrigIV], xmm2 ; ctx_data.orig_IV = iv
vpshufb xmm2, [SHUF_MASK]
vmovdqu [%%GDATA_CTX + CurCount], xmm2 ; ctx_data.current_counter = iv
%endmacro
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; GCM_ENC_DEC Encodes/Decodes given data. Assumes that the passed gcm_context_data struct
; has been initialized by GCM_INIT
; Requires the input data be at least 1 byte long because of READ_SMALL_INPUT_DATA.
; Input: struct gcm_key_data* (GDATA_KEY), struct gcm_context_data * (GDATA_CTX),
; input text (PLAIN_CYPH_IN), input text length (PLAIN_CYPH_LEN),
; and whether encoding or decoding (ENC_DEC)
; Output: A cypher of the given plain text (CYPH_PLAIN_OUT), and updated GDATA_CTX
; Clobbers rax, r10-r15, and xmm0-xmm15
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%macro GCM_ENC_DEC 6
%define %%GDATA_KEY %1
%define %%GDATA_CTX %2
%define %%CYPH_PLAIN_OUT %3
%define %%PLAIN_CYPH_IN %4
%define %%PLAIN_CYPH_LEN %5
%define %%ENC_DEC %6
%define %%DATA_OFFSET r11
; Macro flow:
; calculate the number of 16byte blocks in the message
; process (number of 16byte blocks) mod 8 '%%_initial_num_blocks_is_# .. %%_initial_blocks_encrypted'
; process 8 16 byte blocks at a time until all are done '%%_encrypt_by_8_new .. %%_eight_cipher_left'
; if there is a block of less tahn 16 bytes process it '%%_zero_cipher_left .. %%_multiple_of_16_bytes'
cmp %%PLAIN_CYPH_LEN, 0
je %%_multiple_of_16_bytes
xor %%DATA_OFFSET, %%DATA_OFFSET
%ifidn __OUTPUT_FORMAT__, win64
mov rax, %%PLAIN_CYPH_LEN
add [%%GDATA_CTX + InLen], rax ; Update length of data processed
%else
add [%%GDATA_CTX + InLen], %%PLAIN_CYPH_LEN ; Update length of data processed
%endif
vmovdqu xmm13, [%%GDATA_KEY + HashKey] ; xmm13 = HashKey
vmovdqu xmm8, [%%GDATA_CTX + AadHash]
PARTIAL_BLOCK %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, %%PLAIN_CYPH_LEN, %%DATA_OFFSET, xmm8, %%ENC_DEC
mov r13, %%PLAIN_CYPH_LEN
sub r13, %%DATA_OFFSET
mov r10, r13 ; save the amount of data left to process in r10
and r13, -16 ; r13 = r13 - (r13 mod 16)
mov r12, r13
shr r12, 4
and r12, 7
jz %%_initial_num_blocks_is_0
cmp r12, 7
je %%_initial_num_blocks_is_7
cmp r12, 6
je %%_initial_num_blocks_is_6
cmp r12, 5
je %%_initial_num_blocks_is_5
cmp r12, 4
je %%_initial_num_blocks_is_4
cmp r12, 3
je %%_initial_num_blocks_is_3
cmp r12, 2
je %%_initial_num_blocks_is_2
jmp %%_initial_num_blocks_is_1
%%_initial_num_blocks_is_7:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 7, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
sub r13, 16*7
jmp %%_initial_blocks_encrypted
%%_initial_num_blocks_is_6:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 6, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
sub r13, 16*6
jmp %%_initial_blocks_encrypted
%%_initial_num_blocks_is_5:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 5, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
sub r13, 16*5
jmp %%_initial_blocks_encrypted
%%_initial_num_blocks_is_4:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 4, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
sub r13, 16*4
jmp %%_initial_blocks_encrypted
%%_initial_num_blocks_is_3:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 3, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
sub r13, 16*3
jmp %%_initial_blocks_encrypted
%%_initial_num_blocks_is_2:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 2, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
sub r13, 16*2
jmp %%_initial_blocks_encrypted
%%_initial_num_blocks_is_1:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 1, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
sub r13, 16
jmp %%_initial_blocks_encrypted
%%_initial_num_blocks_is_0:
INITIAL_BLOCKS %%GDATA_KEY, %%GDATA_CTX, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, r13, %%DATA_OFFSET, 0, xmm12, xmm13, xmm14, xmm15, xmm11, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm10, xmm0, %%ENC_DEC
%%_initial_blocks_encrypted:
cmp r13, 0
je %%_zero_cipher_left
sub r13, 128
je %%_eight_cipher_left
vmovd r15d, xmm9
and r15d, 255
vpshufb xmm9, [SHUF_MASK]
%%_encrypt_by_8_new:
cmp r15d, 255-8
jg %%_encrypt_by_8
add r15b, 8
GHASH_8_ENCRYPT_8_PARALLEL %%GDATA_KEY, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN, %%DATA_OFFSET, xmm0, xmm10, xmm11, xmm12, xmm13, xmm14, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm15, out_order, %%ENC_DEC
add %%DATA_OFFSET, 128
sub r13, 128
jne %%_encrypt_by_8_new
vpshufb xmm9, [SHUF_MASK]
jmp %%_eight_cipher_left
%%_encrypt_by_8:
vpshufb xmm9, [SHUF_MASK]
add r15b, 8
GHASH_8_ENCRYPT_8_PARALLEL %%GDATA_KEY, %%CYPH_PLAIN_OUT, %%PLAIN_CYPH_IN,%%DATA_OFFSET, xmm0, xmm10, xmm11, xmm12, xmm13, xmm14, xmm9, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8, xmm15, in_order, %%ENC_DEC
vpshufb xmm9, [SHUF_MASK]
add %%DATA_OFFSET, 128
sub r13, 128
jne %%_encrypt_by_8_new
vpshufb xmm9, [SHUF_MASK]
%%_eight_cipher_left:
GHASH_LAST_8 %%GDATA_KEY, xmm0, xmm10, xmm11, xmm12, xmm13, xmm14, xmm15, xmm1, xmm2, xmm3, xmm4, xmm5, xmm6, xmm7, xmm8
%%_zero_cipher_left:
vmovdqu [%%GDATA_CTX + AadHash], xmm14 ; ctx_data.aad hash = xmm14
vmovdqu [%%GDATA_CTX + CurCount], xmm9 ; ctx_data.current_counter = xmm9
mov r13, r10
and r13, 15 ; r13 = (%%PLAIN_CYPH_LEN mod 16)
je %%_multiple_of_16_bytes
mov [%%GDATA_CTX + PBlockLen], r13 ; ctx_data.partial_blck_length = r13
; handle the last <16 Byte block seperately
vpaddd xmm9, [ONE] ; INCR CNT to get Yn
vmovdqu [%%GDATA_CTX + CurCount], xmm9 ; my_ctx_data.current_counter = xmm9
vpshufb xmm9, [SHUF_MASK]
ENCRYPT_SINGLE_BLOCK %%GDATA_KEY, xmm9 ; E(K, Yn)
vmovdqu [%%GDATA_CTX + PBlockEncKey], xmm9 ; ctx_data.partial_block_enc_key = xmm9
cmp %%PLAIN_CYPH_LEN, 16
jge %%_large_enough_update
lea r10, [%%PLAIN_CYPH_IN + %%DATA_OFFSET]
READ_SMALL_DATA_INPUT xmm1, r10, r13, r12, r15, rax
lea r12, [SHIFT_MASK + 16]
sub r12, r13
jmp %%_data_read
%%_large_enough_update:
sub %%DATA_OFFSET, 16
add %%DATA_OFFSET, r13
vmovdqu xmm1, [%%PLAIN_CYPH_IN+%%DATA_OFFSET] ; receive the last <16 Byte block
sub %%DATA_OFFSET, r13
add %%DATA_OFFSET, 16
lea r12, [SHIFT_MASK + 16]
sub r12, r13 ; adjust the shuffle mask pointer to be able to shift 16-r13 bytes (r13 is the number of bytes in plaintext mod 16)
vmovdqu xmm2, [r12] ; get the appropriate shuffle mask
vpshufb xmm1, xmm2 ; shift right 16-r13 bytes
%%_data_read:
%ifidn %%ENC_DEC, DEC
vmovdqa xmm2, xmm1
vpxor xmm9, xmm1 ; Plaintext XOR E(K, Yn)
vmovdqu xmm1, [r12 + ALL_F - SHIFT_MASK] ; get the appropriate mask to mask out top 16-r13 bytes of xmm9
vpand xmm9, xmm1 ; mask out top 16-r13 bytes of xmm9
vpand xmm2, xmm1
vpshufb xmm2, [SHUF_MASK]
vpxor xmm14, xmm2
vmovdqu [%%GDATA_CTX + AadHash], xmm14
%else
vpxor xmm9, xmm1 ; Plaintext XOR E(K, Yn)
vmovdqu xmm1, [r12 + ALL_F - SHIFT_MASK] ; get the appropriate mask to mask out top 16-r13 bytes of xmm9
vpand xmm9, xmm1 ; mask out top 16-r13 bytes of xmm9
vpshufb xmm9, [SHUF_MASK]
vpxor xmm14, xmm9
vmovdqu [%%GDATA_CTX + AadHash], xmm14
vpshufb xmm9, [SHUF_MASK] ; shuffle xmm9 back to output as ciphertext
%endif
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; output r13 Bytes
vmovq rax, xmm9
cmp r13, 8
jle %%_less_than_8_bytes_left
mov [%%CYPH_PLAIN_OUT + %%DATA_OFFSET], rax
add %%DATA_OFFSET, 8
vpsrldq xmm9, xmm9, 8
vmovq rax, xmm9
sub r13, 8
%%_less_than_8_bytes_left:
mov BYTE [%%CYPH_PLAIN_OUT + %%DATA_OFFSET], al
add %%DATA_OFFSET, 1
shr rax, 8
sub r13, 1
jne %%_less_than_8_bytes_left
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%%_multiple_of_16_bytes:
%endmacro
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; GCM_COMPLETE Finishes Encyrption/Decryption of last partial block after GCM_UPDATE finishes.
; Input: struct gcm_key_data* (GDATA_KEY), struct gcm_context_data *(GDATA_CTX) and
; whether encoding or decoding (ENC_DEC).
; Output: Authorization Tag (AUTH_TAG) and Authorization Tag length (AUTH_TAG_LEN)
; Clobbers rax, r10-r12, and xmm0, xmm1, xmm5, xmm6, xmm9, xmm11, xmm14, xmm15
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%macro GCM_COMPLETE 5
%define %%GDATA_KEY %1
%define %%GDATA_CTX %2
%define %%AUTH_TAG %3
%define %%AUTH_TAG_LEN %4
%define %%ENC_DEC %5
%define %%PLAIN_CYPH_LEN rax
mov r12, [%%GDATA_CTX + PBlockLen]
vmovdqu xmm14, [%%GDATA_CTX + AadHash]
vmovdqu xmm13, [%%GDATA_KEY + HashKey]
cmp r12, 0
je %%_partial_done
GHASH_MUL xmm14, xmm13, xmm0, xmm10, xmm11, xmm5, xmm6 ;GHASH computation for the last <16 Byte block
vmovdqu [%%GDATA_CTX + AadHash], xmm14
%%_partial_done:
mov r12, [%%GDATA_CTX + AadLen] ; r12 = aadLen (number of bytes)
mov %%PLAIN_CYPH_LEN, [%%GDATA_CTX + InLen]
shl r12, 3 ; convert into number of bits
vmovd xmm15, r12d ; len(A) in xmm15
shl %%PLAIN_CYPH_LEN, 3 ; len(C) in bits (*128)
vmovq xmm1, %%PLAIN_CYPH_LEN
vpslldq xmm15, xmm15, 8 ; xmm15 = len(A)|| 0x0000000000000000
vpxor xmm15, xmm1 ; xmm15 = len(A)||len(C)
vpxor xmm14, xmm15
GHASH_MUL xmm14, xmm13, xmm0, xmm10, xmm11, xmm5, xmm6 ; final GHASH computation
vpshufb xmm14, [SHUF_MASK] ; perform a 16Byte swap
vmovdqu xmm9, [%%GDATA_CTX + OrigIV] ; xmm9 = Y0
ENCRYPT_SINGLE_BLOCK %%GDATA_KEY, xmm9 ; E(K, Y0)
vpxor xmm9, xmm14
%%_return_T:
mov r10, %%AUTH_TAG ; r10 = authTag
mov r11, %%AUTH_TAG_LEN ; r11 = auth_tag_len
cmp r11, 16
je %%_T_16
cmp r11, 12
je %%_T_12
%%_T_8:
vmovq rax, xmm9
mov [r10], rax
jmp %%_return_T_done
%%_T_12:
vmovq rax, xmm9
mov [r10], rax
vpsrldq xmm9, xmm9, 8
vmovd eax, xmm9
mov [r10 + 8], eax
jmp %%_return_T_done
%%_T_16:
vmovdqu [r10], xmm9
%%_return_T_done:
%endmacro ; GCM_COMPLETE
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_precomp_128_avx_gen2
; (struct gcm_key_data *key_data);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(precomp,_),function,)
FN_NAME(precomp,_):
push r12
push r13
push r14
push r15
mov r14, rsp
sub rsp, VARIABLE_OFFSET
and rsp, ~63 ; align rsp to 64 bytes
%ifidn __OUTPUT_FORMAT__, win64
; only xmm6 needs to be maintained
vmovdqu [rsp + LOCAL_STORAGE + 0*16],xmm6
%endif
vpxor xmm6, xmm6
ENCRYPT_SINGLE_BLOCK arg1, xmm6 ; xmm6 = HashKey
vpshufb xmm6, [SHUF_MASK]
;;;;;;;;;;;;;;; PRECOMPUTATION of HashKey<<1 mod poly from the HashKey;;;;;;;;;;;;;;;
vmovdqa xmm2, xmm6
vpsllq xmm6, 1
vpsrlq xmm2, 63
vmovdqa xmm1, xmm2
vpslldq xmm2, xmm2, 8
vpsrldq xmm1, xmm1, 8
vpor xmm6, xmm2
;reduction
vpshufd xmm2, xmm1, 00100100b
vpcmpeqd xmm2, [TWOONE]
vpand xmm2, [POLY]
vpxor xmm6, xmm2 ; xmm6 holds the HashKey<<1 mod poly
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
vmovdqu [arg1 + HashKey], xmm6 ; store HashKey<<1 mod poly
PRECOMPUTE arg1, xmm6, xmm0, xmm1, xmm2, xmm3, xmm4, xmm5
%ifidn __OUTPUT_FORMAT__, win64
vmovdqu xmm6, [rsp + LOCAL_STORAGE + 0*16]
%endif
mov rsp, r14
pop r15
pop r14
pop r13
pop r12
ret
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_init_128_avx_gen2(
; const struct gcm_key_data *key_data,
; struct gcm_context_data *context_data,
; u8 *iv,
; const u8 *aad,
; u64 aad_len);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(init,_),function,)
FN_NAME(init,_):
push r12
push r13
%ifidn __OUTPUT_FORMAT__, win64
push r14
push r15
mov r14, rsp
; xmm6:xmm15 need to be maintained for Windows
sub rsp, 1*16
movdqu [rsp + 0*16], xmm6
%endif
GCM_INIT arg1, arg2, arg3, arg4, arg5
%ifidn __OUTPUT_FORMAT__, win64
movdqu xmm6 , [rsp + 0*16]
mov rsp, r14
pop r15
pop r14
%endif
pop r13
pop r12
ret
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_enc_128_update_avx_gen2(
; const struct gcm_key_data *key_data,
; struct gcm_context_data *context_data,
; u8 *out,
; const u8 *in,
; u64 plaintext_len);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(enc,_update_),function,)
FN_NAME(enc,_update_):
FUNC_SAVE
GCM_ENC_DEC arg1, arg2, arg3, arg4, arg5, ENC
FUNC_RESTORE
ret
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_dec_128_update_avx_gen2(
; const struct gcm_key_data *key_data,
; struct gcm_context_data *context_data,
; u8 *out,
; const u8 *in,
; u64 plaintext_len);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(dec,_update_),function,)
FN_NAME(dec,_update_):
FUNC_SAVE
GCM_ENC_DEC arg1, arg2, arg3, arg4, arg5, DEC
FUNC_RESTORE
ret
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_enc_128_finalize_avx_gen2(
; const struct gcm_key_data *key_data,
; struct gcm_context_data *context_data,
; u8 *auth_tag,
; u64 auth_tag_len);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(enc,_finalize_),function,)
FN_NAME(enc,_finalize_):
push r12
%ifidn __OUTPUT_FORMAT__, win64
; xmm6:xmm15 need to be maintained for Windows
sub rsp, 5*16
vmovdqu [rsp + 0*16],xmm6
vmovdqu [rsp + 1*16],xmm9
vmovdqu [rsp + 2*16],xmm11
vmovdqu [rsp + 3*16],xmm14
vmovdqu [rsp + 4*16],xmm15
%endif
GCM_COMPLETE arg1, arg2, arg3, arg4, ENC
%ifidn __OUTPUT_FORMAT__, win64
vmovdqu xmm15 , [rsp + 4*16]
vmovdqu xmm14 , [rsp + 3*16]
vmovdqu xmm11 , [rsp + 2*16]
vmovdqu xmm9 , [rsp + 1*16]
vmovdqu xmm6 , [rsp + 0*16]
add rsp, 5*16
%endif
pop r12
ret
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_dec_128_finalize_avx_gen2(
; const struct gcm_key_data *key_data,
; struct gcm_context_data *context_data,
; u8 *auth_tag,
; u64 auth_tag_len);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(dec,_finalize_),function,)
FN_NAME(dec,_finalize_):
push r12
%ifidn __OUTPUT_FORMAT__, win64
; xmm6:xmm15 need to be maintained for Windows
sub rsp, 5*16
vmovdqu [rsp + 0*16],xmm6
vmovdqu [rsp + 1*16],xmm9
vmovdqu [rsp + 2*16],xmm11
vmovdqu [rsp + 3*16],xmm14
vmovdqu [rsp + 4*16],xmm15
%endif
GCM_COMPLETE arg1, arg2, arg3, arg4, DEC
%ifidn __OUTPUT_FORMAT__, win64
vmovdqu xmm15 , [rsp + 4*16]
vmovdqu xmm14 , [rsp + 3*16]
vmovdqu xmm11 , [rsp + 2*16]
vmovdqu xmm9 , [rsp + 1*16]
vmovdqu xmm6 , [rsp + 0*16]
add rsp, 5*16
%endif
pop r12
ret
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_enc_128_avx_gen2(
; const struct gcm_key_data *key_data,
; struct gcm_context_data *context_data,
; u8 *out,
; const u8 *in,
; u64 plaintext_len,
; u8 *iv,
; const u8 *aad,
; u64 aad_len,
; u8 *auth_tag,
; u64 auth_tag_len);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(enc,_),function,)
FN_NAME(enc,_):
FUNC_SAVE
GCM_INIT arg1, arg2, arg6, arg7, arg8
GCM_ENC_DEC arg1, arg2, arg3, arg4, arg5, ENC
GCM_COMPLETE arg1, arg2, arg9, arg10, ENC
FUNC_RESTORE
ret
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;void aes_gcm_dec_128_avx_gen2(
; const struct gcm_key_data *key_data,
; struct gcm_context_data *context_data,
; u8 *out,
; const u8 *in,
; u64 plaintext_len,
; u8 *iv,
; const u8 *aad,
; u64 aad_len,
; u8 *auth_tag,
; u64 auth_tag_len);
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
MKGLOBAL(FN_NAME(dec,_),function,)
FN_NAME(dec,_):
FUNC_SAVE
GCM_INIT arg1, arg2, arg6, arg7, arg8
GCM_ENC_DEC arg1, arg2, arg3, arg4, arg5, DEC
GCM_COMPLETE arg1, arg2, arg9, arg10, DEC
FUNC_RESTORE
ret
%ifdef LINUX
section .note.GNU-stack noalloc noexec nowrite progbits
%endif
|