path: root/src/crypto/isa-l/isa-l_crypto/mh_sha1/mh_sha1_block_avx2.asm

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;; code to compute 16 SHA1 using AVX-2
;;

%include "reg_sizes.asm"
default rel

;; Magic functions defined in FIPS 180-1
;;
;MAGIC_F0 MACRO regF:REQ,regB:REQ,regC:REQ,regD:REQ,regT:REQ ;; ((D ^ (B & (C ^ D)))
%macro MAGIC_F0 5
%define %%regF %1
%define %%regB %2
%define %%regC %3
%define %%regD %4
%define %%regT %5
    vpxor  %%regF, %%regC,%%regD
    vpand  %%regF, %%regF,%%regB
    vpxor  %%regF, %%regF,%%regD
%endmacro

;MAGIC_F1 MACRO regF:REQ,regB:REQ,regC:REQ,regD:REQ,regT:REQ ;; (B ^ C ^ D)
%macro MAGIC_F1 5
%define %%regF %1
%define %%regB %2
%define %%regC %3
%define %%regD %4
%define %%regT %5
    vpxor  %%regF,%%regD,%%regC
    vpxor  %%regF,%%regF,%%regB
%endmacro



;MAGIC_F2 MACRO regF:REQ,regB:REQ,regC:REQ,regD:REQ,regT:REQ ;; ((B & C) | (B & D) | (C & D))
%macro MAGIC_F2 5
%define %%regF %1
%define %%regB %2
%define %%regC %3
%define %%regD %4
%define %%regT %5
    vpor   %%regF,%%regB,%%regC
    vpand  %%regT,%%regB,%%regC
    vpand  %%regF,%%regF,%%regD
    vpor   %%regF,%%regF,%%regT
%endmacro

;MAGIC_F3 MACRO regF:REQ,regB:REQ,regC:REQ,regD:REQ,regT:REQ
%macro MAGIC_F3 5
%define %%regF %1
%define %%regB %2
%define %%regC %3
%define %%regD %4
%define %%regT %5
    MAGIC_F1 %%regF,%%regB,%%regC,%%regD,%%regT
%endmacro

; PROLD reg, imm, tmp
%macro PROLD 3
%define %%reg %1
%define %%imm %2
%define %%tmp %3
	vpsrld	%%tmp, %%reg, (32-%%imm)
	vpslld	%%reg, %%reg, %%imm
	vpor	%%reg, %%reg, %%tmp
%endmacro

; PROLD reg, imm, tmp
%macro PROLD_nd 4
%define %%reg %1
%define %%imm %2
%define %%tmp %3
%define %%src %4
	vpsrld	%%tmp, %%src, (32-%%imm)
	vpslld	%%reg, %%src, %%imm
	vpor	%%reg, %%reg, %%tmp
%endmacro

%macro SHA1_STEP_00_15 11
%define %%regA  %1
%define %%regB  %2
%define %%regC  %3
%define %%regD  %4
%define %%regE  %5
%define %%regT  %6
%define %%regF  %7
%define %%memW  %8
%define %%immCNT %9
%define %%MAGIC %10
%define %%data %11
	vpaddd	%%regE, %%regE,%%immCNT
	vpaddd	%%regE, %%regE,[%%data + (%%memW * 32)]
	PROLD_nd	%%regT,5, %%regF,%%regA
	vpaddd	%%regE, %%regE,%%regT
	%%MAGIC	%%regF,%%regB,%%regC,%%regD,%%regT      ;; FUN  = MAGIC_Fi(B,C,D)
	PROLD	%%regB,30, %%regT
	vpaddd	%%regE, %%regE,%%regF
%endmacro

%macro SHA1_STEP_16_79 11
%define %%regA	%1
%define %%regB	%2
%define %%regC	%3
%define %%regD	%4
%define %%regE	%5
%define %%regT	%6
%define %%regF	%7
%define %%memW	%8
%define %%immCNT %9
%define %%MAGIC	%10
%define %%data %11
	vpaddd	%%regE, %%regE,%%immCNT

	vmovdqa	W14, [%%data + ((%%memW - 14) & 15) * 32]
	vpxor	W16, W16, W14
	vpxor	W16, W16, [%%data + ((%%memW -  8) & 15) * 32]
	vpxor	W16, W16, [%%data + ((%%memW -  3) & 15) * 32]

	vpsrld	%%regF, W16, (32-1)
	vpslld	W16, W16, 1
	vpor	%%regF, %%regF, W16
	ROTATE_W

	vmovdqa	[%%data + ((%%memW - 0) & 15) * 32],%%regF
	vpaddd	%%regE, %%regE,%%regF

	PROLD_nd	%%regT,5, %%regF, %%regA
	vpaddd	%%regE, %%regE,%%regT
	%%MAGIC	%%regF,%%regB,%%regC,%%regD,%%regT      ;; FUN  = MAGIC_Fi(B,C,D)
	PROLD	%%regB,30, %%regT
	vpaddd	%%regE,%%regE,%%regF
%endmacro

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%ifidn __OUTPUT_FORMAT__, elf64
 ; Linux
 %define arg0  rdi
 %define arg1  rsi
 %define arg2  rdx
 %define arg3  rcx

 %define arg4  r8
 %define arg5  r9

 %define tmp1  r10
 %define tmp2  r11
 %define tmp3  r12		; must be saved and restored
 %define tmp4  r13		; must be saved and restored
 %define tmp5  r14		; must be saved and restored
 %define tmp6  r15		; must be saved and restored
 %define return rax

 %define func(x) x:
 %macro FUNC_SAVE 0
	push	r12
	push	r13
	push	r14
	push	r15
 %endmacro
 %macro FUNC_RESTORE 0
	pop	r15
	pop	r14
	pop	r13
	pop	r12
 %endmacro
%else
 ; Windows
 %define arg0   rcx
 %define arg1   rdx
 %define arg2   r8
 %define arg3   r9

 %define arg4   r10
 %define arg5   r11
 %define tmp1   r12		; must be saved and restored
 %define tmp2   r13		; must be saved and restored
 %define tmp3   r14		; must be saved and restored
 %define tmp4   r15		; must be saved and restored
 %define tmp5   rdi		; must be saved and restored
 %define tmp6   rsi		; must be saved and restored
 %define return rax

 %define stack_size  10*16 + 7*8		; must be an odd multiple of 8
 %define func(x) proc_frame x
 %macro FUNC_SAVE 0
	alloc_stack	stack_size
	save_xmm128	xmm6, 0*16
	save_xmm128	xmm7, 1*16
	save_xmm128	xmm8, 2*16
	save_xmm128	xmm9, 3*16
	save_xmm128	xmm10, 4*16
	save_xmm128	xmm11, 5*16
	save_xmm128	xmm12, 6*16
	save_xmm128	xmm13, 7*16
	save_xmm128	xmm14, 8*16
	save_xmm128	xmm15, 9*16
	save_reg	r12,  10*16 + 0*8
	save_reg	r13,  10*16 + 1*8
	save_reg	r14,  10*16 + 2*8
	save_reg	r15,  10*16 + 3*8
	save_reg	rdi,  10*16 + 4*8
	save_reg	rsi,  10*16 + 5*8
	end_prolog
 %endmacro

 %macro FUNC_RESTORE 0
	movdqa	xmm6, [rsp + 0*16]
	movdqa	xmm7, [rsp + 1*16]
	movdqa	xmm8, [rsp + 2*16]
	movdqa	xmm9, [rsp + 3*16]
	movdqa	xmm10, [rsp + 4*16]
	movdqa	xmm11, [rsp + 5*16]
	movdqa	xmm12, [rsp + 6*16]
	movdqa	xmm13, [rsp + 7*16]
	movdqa	xmm14, [rsp + 8*16]
	movdqa	xmm15, [rsp + 9*16]
	mov	r12,  [rsp + 10*16 + 0*8]
	mov	r13,  [rsp + 10*16 + 1*8]
	mov	r14,  [rsp + 10*16 + 2*8]
	mov	r15,  [rsp + 10*16 + 3*8]
	mov	rdi,  [rsp + 10*16 + 4*8]
	mov	rsi,  [rsp + 10*16 + 5*8]
	add	rsp, stack_size
 %endmacro
%endif
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%define loops 		arg3
;variables of mh_sha1
%define mh_in_p  	arg0
%define mh_digests_p 	arg1
%define mh_data_p	arg2
%define mh_segs  	tmp1
;variables used by storing segs_digests on stack
%define RSP_SAVE	tmp2
%define FRAMESZ 	4*5*16		;BYTES*DWORDS*SEGS

%define pref		tmp3
%macro PREFETCH_X 1
%define %%mem  %1
	prefetchnta %%mem
%endmacro
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%define VMOVPS	vmovups

%define A	ymm0
%define B	ymm1
%define C	ymm2
%define D	ymm3
%define E	ymm4

%define F	ymm5
%define T0	ymm6
%define T1	ymm7
%define T2	ymm8
%define T3	ymm9
%define T4	ymm10
%define T5	ymm11
%define T6	ymm12
%define T7	ymm13
%define T8	ymm14
%define T9	ymm15

%define AA	ymm5
%define BB	ymm6
%define CC	ymm7
%define DD	ymm8
%define EE	ymm9
%define TMP	ymm10
%define FUN	ymm11
%define K	ymm12
%define W14	ymm13
%define W15	ymm14
%define W16	ymm15


%macro ROTATE_ARGS 0
%xdefine TMP_ E
%xdefine E D
%xdefine D C
%xdefine C B
%xdefine B A
%xdefine A TMP_
%endm

%macro ROTATE_W 0
%xdefine TMP_ W16
%xdefine W16 W15
%xdefine W15 W14
%xdefine W14 TMP_
%endm


;init hash digests
; segs_digests:low addr-> high_addr
; a  | b  |  c | ...|  p | (16)
; h0 | h0 | h0 | ...| h0 |    | Aa| Ab | Ac |...| Ap |
; h1 | h1 | h1 | ...| h1 |    | Ba| Bb | Bc |...| Bp |
; ....
; h5 | h5 | h5 | ...| h5 |    | Ea| Eb | Ec |...| Ep |

align 32

;void mh_sha1_block_avx2(const uint8_t * input_data, uint32_t digests[SHA1_DIGEST_WORDS][HASH_SEGS],
;		uint8_t frame_buffer[MH_SHA1_BLOCK_SIZE], uint32_t num_blocks);
; arg 0 pointer to input data
; arg 1 pointer to digests, include segments digests(uint32_t digests[16][5])
; arg 2 pointer to aligned_frame_buffer which is used to save the big_endian data.
; arg 3 number  of 1KB blocks
;
global mh_sha1_block_avx2:function internal
func(mh_sha1_block_avx2)
	FUNC_SAVE

	; save rsp
	mov	RSP_SAVE, rsp

	cmp	loops, 0
	jle	.return

	; leave enough space to store segs_digests
	sub     rsp, FRAMESZ
	; align rsp to 32 Bytes needed by avx2
	and	rsp, ~0x1F

 %assign I 0					; copy segs_digests into stack
 %rep 2
	VMOVPS  A, [mh_digests_p + I*32*5 + 32*0]
	VMOVPS  B, [mh_digests_p + I*32*5 + 32*1]
	VMOVPS  C, [mh_digests_p + I*32*5 + 32*2]
	VMOVPS  D, [mh_digests_p + I*32*5 + 32*3]
	VMOVPS  E, [mh_digests_p + I*32*5 + 32*4]

	vmovdqa [rsp + I*32*5 + 32*0], A
	vmovdqa [rsp + I*32*5 + 32*1], B
	vmovdqa [rsp + I*32*5 + 32*2], C
	vmovdqa [rsp + I*32*5 + 32*3], D
	vmovdqa [rsp + I*32*5 + 32*4], E
 %assign I (I+1)
 %endrep

.block_loop:
	;transform to big-endian data and store on aligned_frame
	vmovdqa F, [PSHUFFLE_BYTE_FLIP_MASK]
	;transform input data from DWORD*16_SEGS*5 to DWORD*8_SEGS*5*2
%assign I 0
%rep 16
	VMOVPS   T0,[mh_in_p + I*64+0*32]
	VMOVPS   T1,[mh_in_p + I*64+1*32]

	vpshufb	T0, T0, F
	vmovdqa	[mh_data_p +I*32+0*512],T0
	vpshufb	T1, T1, F
	vmovdqa	[mh_data_p +I*32+1*512],T1
%assign I (I+1)
%endrep

	mov	mh_segs, 0			;start from the first 8 segments
	mov	pref, 1024				;avoid prefetch repeadtedly
 .segs_loop:
	;; Initialize digests
	vmovdqa	A, [rsp + 0*64 + mh_segs]
	vmovdqa	B, [rsp + 1*64 + mh_segs]
	vmovdqa	C, [rsp + 2*64 + mh_segs]
	vmovdqa	D, [rsp + 3*64 + mh_segs]
	vmovdqa	E, [rsp + 4*64 + mh_segs]

	vmovdqa  AA, A
	vmovdqa  BB, B
	vmovdqa  CC, C
	vmovdqa  DD, D
	vmovdqa  EE, E
;;
;; perform 0-79 steps
;;
	vmovdqa	K, [K00_19]
;; do rounds 0...15
 %assign I 0
 %rep 16
	SHA1_STEP_00_15 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F0, mh_data_p
	ROTATE_ARGS
%assign I (I+1)
%endrep

;; do rounds 16...19
	vmovdqa	W16, [mh_data_p + ((16 - 16) & 15) * 32]
	vmovdqa	W15, [mh_data_p + ((16 - 15) & 15) * 32]
 %rep 4
	SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F0, mh_data_p
	ROTATE_ARGS
 %assign I (I+1)
 %endrep
	PREFETCH_X [mh_in_p + pref+128*0]
	PREFETCH_X [mh_in_p + pref+128*1]
;; do rounds 20...39
	vmovdqa	K, [K20_39]
 %rep 20
	SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F1, mh_data_p
	ROTATE_ARGS
 %assign I (I+1)
 %endrep
;; do rounds 40...59
	vmovdqa	K, [K40_59]
 %rep 20
	SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F2, mh_data_p
	ROTATE_ARGS
 %assign I (I+1)
 %endrep
	PREFETCH_X [mh_in_p + pref+128*2]
        PREFETCH_X [mh_in_p + pref+128*3]
;; do rounds 60...79
	vmovdqa	K, [K60_79]
 %rep 20
	SHA1_STEP_16_79 A,B,C,D,E, TMP,FUN, I, K, MAGIC_F3, mh_data_p
	ROTATE_ARGS
 %assign I (I+1)
 %endrep

	vpaddd  A,A, AA
	vpaddd  B,B, BB
	vpaddd  C,C, CC
	vpaddd  D,D, DD
	vpaddd  E,E, EE

	; write out digests
	vmovdqa  [rsp + 0*64 + mh_segs], A
	vmovdqa  [rsp + 1*64 + mh_segs], B
	vmovdqa  [rsp + 2*64 + mh_segs], C
	vmovdqa  [rsp + 3*64 + mh_segs], D
	vmovdqa  [rsp + 4*64 + mh_segs], E

	add	pref,      512

	add	mh_data_p, 512
	add 	mh_segs,   32
	cmp	mh_segs,   64
	jc 	.segs_loop

	sub	mh_data_p, (1024)
	add 	mh_in_p,   (1024)
	sub     loops, 1
	jne     .block_loop


 %assign I 0					; copy segs_digests back to mh_digests_p
 %rep 2
	vmovdqa A, [rsp + I*32*5 + 32*0]
	vmovdqa B, [rsp + I*32*5 + 32*1]
	vmovdqa C, [rsp + I*32*5 + 32*2]
	vmovdqa D, [rsp + I*32*5 + 32*3]
	vmovdqa E, [rsp + I*32*5 + 32*4]

	VMOVPS  [mh_digests_p + I*32*5 + 32*0], A
	VMOVPS  [mh_digests_p + I*32*5 + 32*1], B
	VMOVPS  [mh_digests_p + I*32*5 + 32*2], C
	VMOVPS  [mh_digests_p + I*32*5 + 32*3], D
	VMOVPS  [mh_digests_p + I*32*5 + 32*4], E
 %assign I (I+1)
 %endrep
	mov	rsp, RSP_SAVE			; restore rsp

.return:
	FUNC_RESTORE
	ret

endproc_frame

section .data align=32

align 32
PSHUFFLE_BYTE_FLIP_MASK: dq 0x0405060700010203, 0x0c0d0e0f08090a0b
			 dq 0x0405060700010203, 0x0c0d0e0f08090a0b
K00_19:			dq 0x5A8279995A827999, 0x5A8279995A827999
			dq 0x5A8279995A827999, 0x5A8279995A827999
K20_39:                 dq 0x6ED9EBA16ED9EBA1, 0x6ED9EBA16ED9EBA1
			dq 0x6ED9EBA16ED9EBA1, 0x6ED9EBA16ED9EBA1
K40_59:                 dq 0x8F1BBCDC8F1BBCDC, 0x8F1BBCDC8F1BBCDC
			dq 0x8F1BBCDC8F1BBCDC, 0x8F1BBCDC8F1BBCDC
K60_79:                 dq 0xCA62C1D6CA62C1D6, 0xCA62C1D6CA62C1D6
			dq 0xCA62C1D6CA62C1D6, 0xCA62C1D6CA62C1D6