/*
 *	Implement fast SHA-1 with AVX2 instructions. (x86_64)
 *
 * This file is provided under a dual BSD/GPLv2 license.  When using or
 * redistributing this file, you may do so under either license.
 *
 * GPL LICENSE SUMMARY
 *
 * Copyright(c) 2014 Intel Corporation.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of version 2 of the GNU General Public License as
 * published by the Free Software Foundation.
 *
 * This program is distributed in the hope that it will be useful, but
 * WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * General Public License for more details.
 *
 * Contact Information:
 * Ilya Albrekht <ilya.albrekht@intel.com>
 * Maxim Locktyukhin <maxim.locktyukhin@intel.com>
 * Ronen Zohar <ronen.zohar@intel.com>
 * Chandramouli Narayanan <mouli@linux.intel.com>
 *
 * BSD LICENSE
 *
 * Copyright(c) 2014 Intel Corporation.
 *
 * 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.
 *
 */

/*
 * SHA-1 implementation with Intel(R) AVX2 instruction set extensions.
 *
 *This implementation is based on the previous SSSE3 release:
 * https://software.intel.com/en-us/articles/improving-the-performance-of-the-secure-hash-algorithm-1
 *
 *Updates 20-byte SHA-1 record in 'hash' for even number of
 *'num_blocks' consecutive 64-byte blocks
 *
 */

/*
 * Using this part of Minio codebase under the license
 * Apache License Version 2.0 with modifications
 *
 */

#ifdef HAS_AVX2
#ifndef ENTRY
#define ENTRY(name) \
        .globl name             ; \
        .align 4,0x90           ; \
        name:
#endif

#ifndef END
#define END(name) \
        .size name, .-name
#endif

#ifndef ENDPROC
#define ENDPROC(name) \
        .type name, @function   ; \
        END(name)
#endif

#define NUM_INVALID		100

#define TYPE_R32		0
#define TYPE_R64		1
#define TYPE_XMM		2
#define TYPE_INVALID	100

	.macro R32_NUM opd r32
	\opd = NUM_INVALID
	.ifc \r32,%eax
	\opd = 0
	.endif
	.ifc \r32,%ecx
	\opd = 1
	.endif
	.ifc \r32,%edx
	\opd = 2
	.endif
	.ifc \r32,%ebx
	\opd = 3
	.endif
	.ifc \r32,%esp
	\opd = 4
	.endif
	.ifc \r32,%ebp
	\opd = 5
	.endif
	.ifc \r32,%esi
	\opd = 6
	.endif
	.ifc \r32,%edi
	\opd = 7
	.endif
#ifdef X86_64
	.ifc \r32,%r8d
	\opd = 8
	.endif
	.ifc \r32,%r9d
	\opd = 9
	.endif
	.ifc \r32,%r10d
	\opd = 10
	.endif
	.ifc \r32,%r11d
	\opd = 11
	.endif
	.ifc \r32,%r12d
	\opd = 12
	.endif
	.ifc \r32,%r13d
	\opd = 13
	.endif
	.ifc \r32,%r14d
	\opd = 14
	.endif
	.ifc \r32,%r15d
	\opd = 15
	.endif
#endif
	.endm

	.macro R64_NUM opd r64
	\opd = NUM_INVALID
#ifdef X86_64
	.ifc \r64,%rax
	\opd = 0
	.endif
	.ifc \r64,%rcx
	\opd = 1
	.endif
	.ifc \r64,%rdx
	\opd = 2
	.endif
	.ifc \r64,%rbx
	\opd = 3
	.endif
	.ifc \r64,%rsp
	\opd = 4
	.endif
	.ifc \r64,%rbp
	\opd = 5
	.endif
	.ifc \r64,%rsi
	\opd = 6
	.endif
	.ifc \r64,%rdi
	\opd = 7
	.endif
	.ifc \r64,%r8
	\opd = 8
	.endif
	.ifc \r64,%r9
	\opd = 9
	.endif
	.ifc \r64,%r10
	\opd = 10
	.endif
	.ifc \r64,%r11
	\opd = 11
	.endif
	.ifc \r64,%r12
	\opd = 12
	.endif
	.ifc \r64,%r13
	\opd = 13
	.endif
	.ifc \r64,%r14
	\opd = 14
	.endif
	.ifc \r64,%r15
	\opd = 15
	.endif
#endif
	.endm

	.macro XMM_NUM opd xmm
	\opd = NUM_INVALID
	.ifc \xmm,%xmm0
	\opd = 0
	.endif
	.ifc \xmm,%xmm1
	\opd = 1
	.endif
	.ifc \xmm,%xmm2
	\opd = 2
	.endif
	.ifc \xmm,%xmm3
	\opd = 3
	.endif
	.ifc \xmm,%xmm4
	\opd = 4
	.endif
	.ifc \xmm,%xmm5
	\opd = 5
	.endif
	.ifc \xmm,%xmm6
	\opd = 6
	.endif
	.ifc \xmm,%xmm7
	\opd = 7
	.endif
	.ifc \xmm,%xmm8
	\opd = 8
	.endif
	.ifc \xmm,%xmm9
	\opd = 9
	.endif
	.ifc \xmm,%xmm10
	\opd = 10
	.endif
	.ifc \xmm,%xmm11
	\opd = 11
	.endif
	.ifc \xmm,%xmm12
	\opd = 12
	.endif
	.ifc \xmm,%xmm13
	\opd = 13
	.endif
	.ifc \xmm,%xmm14
	\opd = 14
	.endif
	.ifc \xmm,%xmm15
	\opd = 15
	.endif
	.endm

	.macro TYPE type reg
	R32_NUM reg_type_r32 \reg
	R64_NUM reg_type_r64 \reg
	XMM_NUM reg_type_xmm \reg
	.if reg_type_r64 <> NUM_INVALID
	\type = TYPE_R64
	.elseif reg_type_r32 <> NUM_INVALID
	\type = TYPE_R32
	.elseif reg_type_xmm <> NUM_INVALID
	\type = TYPE_XMM
	.else
	\type = TYPE_INVALID
	.endif
	.endm

	.macro PFX_OPD_SIZE
	.byte 0x66
	.endm

	.macro PFX_REX opd1 opd2 W=0
	.if ((\opd1 | \opd2) & 8) || \W
	.byte 0x40 | ((\opd1 & 8) >> 3) | ((\opd2 & 8) >> 1) | (\W << 3)
	.endif
	.endm

	.macro MODRM mod opd1 opd2
	.byte \mod | (\opd1 & 7) | ((\opd2 & 7) << 3)
	.endm

	.macro PSHUFB_XMM xmm1 xmm2
	XMM_NUM pshufb_opd1 \xmm1
	XMM_NUM pshufb_opd2 \xmm2
	PFX_OPD_SIZE
	PFX_REX pshufb_opd1 pshufb_opd2
	.byte 0x0f, 0x38, 0x00
	MODRM 0xc0 pshufb_opd1 pshufb_opd2
	.endm

	.macro PCLMULQDQ imm8 xmm1 xmm2
	XMM_NUM clmul_opd1 \xmm1
	XMM_NUM clmul_opd2 \xmm2
	PFX_OPD_SIZE
	PFX_REX clmul_opd1 clmul_opd2
	.byte 0x0f, 0x3a, 0x44
	MODRM 0xc0 clmul_opd1 clmul_opd2
	.byte \imm8
	.endm

	.macro PEXTRD imm8 xmm gpr
	R32_NUM extrd_opd1 \gpr
	XMM_NUM extrd_opd2 \xmm
	PFX_OPD_SIZE
	PFX_REX extrd_opd1 extrd_opd2
	.byte 0x0f, 0x3a, 0x16
	MODRM 0xc0 extrd_opd1 extrd_opd2
	.byte \imm8
	.endm

	.macro MOVQ_R64_XMM opd1 opd2
	TYPE movq_r64_xmm_opd1_type \opd1
	.if movq_r64_xmm_opd1_type == TYPE_XMM
	XMM_NUM movq_r64_xmm_opd1 \opd1
	R64_NUM movq_r64_xmm_opd2 \opd2
	.else
	R64_NUM movq_r64_xmm_opd1 \opd1
	XMM_NUM movq_r64_xmm_opd2 \opd2
	.endif
	PFX_OPD_SIZE
	PFX_REX movq_r64_xmm_opd1 movq_r64_xmm_opd2 1
	.if movq_r64_xmm_opd1_type == TYPE_XMM
	.byte 0x0f, 0x7e
	.else
	.byte 0x0f, 0x6e
	.endif
	MODRM 0xc0 movq_r64_xmm_opd1 movq_r64_xmm_opd2
	.endm

#define	CTX	%rdi	/* arg1 */
#define BUF	%rsi	/* arg2 */
#define CNT	%rdx	/* arg3 */

#define	REG_A	%ecx
#define	REG_B	%esi
#define	REG_C	%edi
#define	REG_D	%eax
#define	REG_E	%edx
#define	REG_TB	%ebx
#define	REG_TA	%r12d
#define	REG_RA	%rcx
#define	REG_RB	%rsi
#define	REG_RC	%rdi
#define	REG_RD	%rax
#define	REG_RE	%rdx
#define	REG_RTA	%r12
#define	REG_RTB	%rbx
#define	REG_T1	%ebp
#define	xmm_mov	vmovups
#define	avx2_zeroupper	vzeroupper
#define	RND_F1	1
#define	RND_F2	2
#define	RND_F3	3

.macro REGALLOC
	.set A, REG_A
	.set B, REG_B
	.set C, REG_C
	.set D, REG_D
	.set E, REG_E
	.set TB, REG_TB
	.set TA, REG_TA

	.set RA, REG_RA
	.set RB, REG_RB
	.set RC, REG_RC
	.set RD, REG_RD
	.set RE, REG_RE

	.set RTA, REG_RTA
	.set RTB, REG_RTB

	.set T1, REG_T1
.endm

#define K_BASE		%r8
#define HASH_PTR	%r9
#define BUFFER_PTR	%r10
#define BUFFER_PTR2	%r13
#define BUFFER_END	%r11

#define PRECALC_BUF	%r14
#define WK_BUF		%r15

#define W_TMP		%xmm0
#define WY_TMP		%ymm0
#define WY_TMP2		%ymm9

# AVX2 variables
#define WY0		%ymm3
#define WY4		%ymm5
#define WY08		%ymm7
#define WY12		%ymm8
#define WY16		%ymm12
#define WY20		%ymm13
#define WY24		%ymm14
#define WY28		%ymm15

#define YMM_SHUFB_BSWAP	%ymm10

/*
 * Keep 2 iterations precalculated at a time:
 *    - 80 DWORDs per iteration * 2
 */
#define W_SIZE		(80*2*2 +16)

#define WK(t)	((((t) % 80) / 4)*32 + ( (t) % 4)*4 + ((t)/80)*16 )(WK_BUF)
#define PRECALC_WK(t)	((t)*2*2)(PRECALC_BUF)


.macro UPDATE_HASH  hash, val
	add	\hash, \val
	mov	\val, \hash
.endm

.macro PRECALC_RESET_WY
	.set WY_00, WY0
	.set WY_04, WY4
	.set WY_08, WY08
	.set WY_12, WY12
	.set WY_16, WY16
	.set WY_20, WY20
	.set WY_24, WY24
	.set WY_28, WY28
	.set WY_32, WY_00
.endm

.macro PRECALC_ROTATE_WY
	/* Rotate macros */
	.set WY_32, WY_28
	.set WY_28, WY_24
	.set WY_24, WY_20
	.set WY_20, WY_16
	.set WY_16, WY_12
	.set WY_12, WY_08
	.set WY_08, WY_04
	.set WY_04, WY_00
	.set WY_00, WY_32

	/* Define register aliases */
	.set WY, WY_00
	.set WY_minus_04, WY_04
	.set WY_minus_08, WY_08
	.set WY_minus_12, WY_12
	.set WY_minus_16, WY_16
	.set WY_minus_20, WY_20
	.set WY_minus_24, WY_24
	.set WY_minus_28, WY_28
	.set WY_minus_32, WY
.endm

.macro PRECALC_00_15
	.if (i == 0) # Initialize and rotate registers
		PRECALC_RESET_WY
		PRECALC_ROTATE_WY
	.endif

	/* message scheduling pre-compute for rounds 0-15 */
	.if   ((i & 7) == 0)
		/*
		 * blended AVX2 and ALU instruction scheduling
		 * 1 vector iteration per 8 rounds
		 */
		vmovdqu ((i * 2) + PRECALC_OFFSET)(BUFFER_PTR), W_TMP
	.elseif ((i & 7) == 1)
		vinsertf128 $1, (((i-1) * 2)+PRECALC_OFFSET)(BUFFER_PTR2),\
			 WY_TMP, WY_TMP
	.elseif ((i & 7) == 2)
		vpshufb YMM_SHUFB_BSWAP, WY_TMP, WY
	.elseif ((i & 7) == 4)
		vpaddd  K_XMM(K_BASE), WY, WY_TMP
	.elseif ((i & 7) == 7)
		vmovdqu  WY_TMP, PRECALC_WK(i&~7)

		PRECALC_ROTATE_WY
	.endif
.endm

.macro PRECALC_16_31
	/*
	 * message scheduling pre-compute for rounds 16-31
	 * calculating last 32 w[i] values in 8 XMM registers
	 * pre-calculate K+w[i] values and store to mem
	 * for later load by ALU add instruction
	 *
	 * "brute force" vectorization for rounds 16-31 only
	 * due to w[i]->w[i-3] dependency
	 */
	.if   ((i & 7) == 0)
		/*
		 * blended AVX2 and ALU instruction scheduling
		 * 1 vector iteration per 8 rounds
		 */
		/* w[i-14] */
		vpalignr	$8, WY_minus_16, WY_minus_12, WY
		vpsrldq	$4, WY_minus_04, WY_TMP               /* w[i-3] */
	.elseif ((i & 7) == 1)
		vpxor	WY_minus_08, WY, WY
		vpxor	WY_minus_16, WY_TMP, WY_TMP
	.elseif ((i & 7) == 2)
		vpxor	WY_TMP, WY, WY
		vpslldq	$12, WY, WY_TMP2
	.elseif ((i & 7) == 3)
		vpslld	$1, WY, WY_TMP
		vpsrld	$31, WY, WY
	.elseif ((i & 7) == 4)
		vpor	WY, WY_TMP, WY_TMP
		vpslld	$2, WY_TMP2, WY
	.elseif ((i & 7) == 5)
		vpsrld	$30, WY_TMP2, WY_TMP2
		vpxor	WY, WY_TMP, WY_TMP
	.elseif ((i & 7) == 7)
		vpxor	WY_TMP2, WY_TMP, WY
		vpaddd	K_XMM(K_BASE), WY, WY_TMP
		vmovdqu	WY_TMP, PRECALC_WK(i&~7)

		PRECALC_ROTATE_WY
	.endif
.endm

.macro PRECALC_32_79
	/*
	 * in SHA-1 specification:
	 * w[i] = (w[i-3] ^ w[i-8]  ^ w[i-14] ^ w[i-16]) rol 1
	 * instead we do equal:
	 * w[i] = (w[i-6] ^ w[i-16] ^ w[i-28] ^ w[i-32]) rol 2
	 * allows more efficient vectorization
	 * since w[i]=>w[i-3] dependency is broken
	 */

	.if   ((i & 7) == 0)
	/*
	 * blended AVX2 and ALU instruction scheduling
	 * 1 vector iteration per 8 rounds
	 */
		vpalignr	$8, WY_minus_08, WY_minus_04, WY_TMP
	.elseif ((i & 7) == 1)
		/* W is W_minus_32 before xor */
		vpxor	WY_minus_28, WY, WY
	.elseif ((i & 7) == 2)
		vpxor	WY_minus_16, WY_TMP, WY_TMP
	.elseif ((i & 7) == 3)
		vpxor	WY_TMP, WY, WY
	.elseif ((i & 7) == 4)
		vpslld	$2, WY, WY_TMP
	.elseif ((i & 7) == 5)
		vpsrld	$30, WY, WY
		vpor	WY, WY_TMP, WY
	.elseif ((i & 7) == 7)
		vpaddd	K_XMM(K_BASE), WY, WY_TMP
		vmovdqu	WY_TMP, PRECALC_WK(i&~7)

		PRECALC_ROTATE_WY
	.endif
.endm

.macro PRECALC r, s
	.set i, \r

	.if (i < 40)
		.set K_XMM, 32*0
	.elseif (i < 80)
		.set K_XMM, 32*1
	.elseif (i < 120)
		.set K_XMM, 32*2
	.else
		.set K_XMM, 32*3
	.endif

	.if (i<32)
		PRECALC_00_15	\s
	.elseif (i<64)
		PRECALC_16_31	\s
	.elseif (i < 160)
		PRECALC_32_79	\s
	.endif
.endm

.macro ROTATE_STATE
	.set T_REG, E
	.set E, D
	.set D, C
	.set C, B
	.set B, TB
	.set TB, A
	.set A, T_REG

	.set T_REG, RE
	.set RE, RD
	.set RD, RC
	.set RC, RB
	.set RB, RTB
	.set RTB, RA
	.set RA, T_REG
.endm

/* Macro relies on saved ROUND_Fx */

.macro RND_FUN f, r
	.if (\f == RND_F1)
		ROUND_F1	\r
	.elseif (\f == RND_F2)
		ROUND_F2	\r
	.elseif (\f == RND_F3)
		ROUND_F3	\r
	.endif
.endm

.macro RR r
	.set round_id, (\r % 80)

	.if (round_id == 0)        /* Precalculate F for first round */
		.set ROUND_FUNC, RND_F1
		mov	B, TB

		rorx	$(32-30), B, B    /* b>>>2 */
		andn	D, TB, T1
		and	C, TB
		xor	T1, TB
	.endif

	RND_FUN ROUND_FUNC, \r
	ROTATE_STATE

	.if   (round_id == 18)
		.set ROUND_FUNC, RND_F2
	.elseif (round_id == 38)
		.set ROUND_FUNC, RND_F3
	.elseif (round_id == 58)
		.set ROUND_FUNC, RND_F2
	.endif

	.set round_id, ( (\r+1) % 80)

	RND_FUN ROUND_FUNC, (\r+1)
	ROTATE_STATE
.endm

.macro ROUND_F1 r
	add	WK(\r), E

	andn	C, A, T1			/* ~b&d */
	lea	(RE,RTB), E		/* Add F from the previous round */

	rorx	$(32-5), A, TA		/* T2 = A >>> 5 */
	rorx	$(32-30),A, TB		/* b>>>2 for next round */

	PRECALC	(\r)			/* msg scheduling for next 2 blocks */

	/*
	 * Calculate F for the next round
	 * (b & c) ^ andn[b, d]
	 */
	and	B, A			/* b&c */
	xor	T1, A			/* F1 = (b&c) ^ (~b&d) */

	lea	(RE,RTA), E		/* E += A >>> 5 */
.endm

.macro ROUND_F2 r
	add	WK(\r), E
	lea	(RE,RTB), E		/* Add F from the previous round */

	/* Calculate F for the next round */
	rorx	$(32-5), A, TA		/* T2 = A >>> 5 */
	.if ((round_id) < 79)
		rorx	$(32-30), A, TB	/* b>>>2 for next round */
	.endif
	PRECALC	(\r)			/* msg scheduling for next 2 blocks */

	.if ((round_id) < 79)
		xor	B, A
	.endif

	add	TA, E			/* E += A >>> 5 */

	.if ((round_id) < 79)
		xor	C, A
	.endif
.endm

.macro ROUND_F3 r
	add	WK(\r), E
	PRECALC	(\r)			/* msg scheduling for next 2 blocks */

	lea	(RE,RTB), E		/* Add F from the previous round */

	mov	B, T1
	or	A, T1

	rorx	$(32-5), A, TA		/* T2 = A >>> 5 */
	rorx	$(32-30), A, TB		/* b>>>2 for next round */

	/* Calculate F for the next round
	 * (b and c) or (d and (b or c))
	 */
	and	C, T1
	and	B, A
	or	T1, A

	add	TA, E			/* E += A >>> 5 */

.endm

/*
 * macro implements 80 rounds of SHA-1, for multiple blocks with s/w pipelining
 */
.macro SHA1_PIPELINED_MAIN_BODY

	REGALLOC

	mov	(HASH_PTR), A
	mov	4(HASH_PTR), B
	mov	8(HASH_PTR), C
	mov	12(HASH_PTR), D
	mov	16(HASH_PTR), E

	mov	%rsp, PRECALC_BUF
	lea	(2*4*80+32)(%rsp), WK_BUF

	# Precalc WK for first 2 blocks
	PRECALC_OFFSET = 0
	.set i, 0
	.rept    160
		PRECALC i
		.set i, i + 1
	.endr
	PRECALC_OFFSET = 128
	xchg	WK_BUF, PRECALC_BUF

	.align 32
_loop:
	/*
	 * code loops through more than one block
	 * we use K_BASE value as a signal of a last block,
	 * it is set below by: cmovae BUFFER_PTR, K_BASE
	 */
	cmp	K_BASE, BUFFER_PTR
	jne	_begin
	.align 32
	jmp	_end
	.align 32
_begin:

	/*
	 * Do first block
	 * rounds: 0,2,4,6,8
	 */
	.set j, 0
	.rept 5
		RR	j
		.set j, j+2
	.endr

	jmp _loop0
_loop0:

	/*
	 * rounds:
	 * 10,12,14,16,18
	 * 20,22,24,26,28
	 * 30,32,34,36,38
	 * 40,42,44,46,48
	 * 50,52,54,56,58
	 */
	.rept 25
		RR	j
		.set j, j+2
	.endr

	add	$(2*64), BUFFER_PTR       /* move to next odd-64-byte block */
	cmp	BUFFER_END, BUFFER_PTR    /* is current block the last one? */
	cmovae	K_BASE, BUFFER_PTR	/* signal the last iteration smartly */

	/*
	 * rounds
	 * 60,62,64,66,68
	 * 70,72,74,76,78
	 */
	.rept 10
		RR	j
		.set j, j+2
	.endr

	UPDATE_HASH	(HASH_PTR), A
	UPDATE_HASH	4(HASH_PTR), TB
	UPDATE_HASH	8(HASH_PTR), C
	UPDATE_HASH	12(HASH_PTR), D
	UPDATE_HASH	16(HASH_PTR), E

	cmp	K_BASE, BUFFER_PTR	/* is current block the last one? */
	je	_loop

	mov	TB, B

	/* Process second block */
	/*
	 * rounds
	 *  0+80, 2+80, 4+80, 6+80, 8+80
	 * 10+80,12+80,14+80,16+80,18+80
	 */

	.set j, 0
	.rept 10
		RR	j+80
		.set j, j+2
	.endr

	jmp	_loop1
_loop1:
	/*
	 * rounds
	 * 20+80,22+80,24+80,26+80,28+80
	 * 30+80,32+80,34+80,36+80,38+80
	 */
	.rept 10
		RR	j+80
		.set j, j+2
	.endr

	jmp	_loop2
_loop2:

	/*
	 * rounds
	 * 40+80,42+80,44+80,46+80,48+80
	 * 50+80,52+80,54+80,56+80,58+80
	 */
	.rept 10
		RR	j+80
		.set j, j+2
	.endr

	add	$(2*64), BUFFER_PTR2      /* move to next even-64-byte block */

	cmp	BUFFER_END, BUFFER_PTR2   /* is current block the last one */
	cmovae	K_BASE, BUFFER_PTR       /* signal the last iteration smartly */

	jmp	_loop3
_loop3:

	/*
	 * rounds
	 * 60+80,62+80,64+80,66+80,68+80
	 * 70+80,72+80,74+80,76+80,78+80
	 */
	.rept 10
		RR	j+80
		.set j, j+2
	.endr

	UPDATE_HASH	(HASH_PTR), A
	UPDATE_HASH	4(HASH_PTR), TB
	UPDATE_HASH	8(HASH_PTR), C
	UPDATE_HASH	12(HASH_PTR), D
	UPDATE_HASH	16(HASH_PTR), E

	/* Reset state for AVX2 reg permutation */
	mov	A, TA
	mov	TB, A
	mov	C, TB
	mov	E, C
	mov	D, B
	mov	TA, D

	REGALLOC

	xchg	WK_BUF, PRECALC_BUF

	jmp	_loop

	.align 32
	_end:

.endm

.section .rodata

#define K1 0x5a827999
#define K2 0x6ed9eba1
#define K3 0x8f1bbcdc
#define K4 0xca62c1d6

.align 128
K_XMM_AR:
	.long K1, K1, K1, K1
	.long K1, K1, K1, K1
	.long K2, K2, K2, K2
	.long K2, K2, K2, K2
	.long K3, K3, K3, K3
	.long K3, K3, K3, K3
	.long K4, K4, K4, K4
	.long K4, K4, K4, K4

BSWAP_SHUFB_CTL:
	.long 0x00010203
	.long 0x04050607
	.long 0x08090a0b
	.long 0x0c0d0e0f
	.long 0x00010203
	.long 0x04050607
	.long 0x08090a0b
	.long 0x0c0d0e0f

# void sha1_transform(int32_t *hash, const char* input, size_t num_blocks) ;
        .text
	ENTRY(sha1_transform)

	push	%rbx
	push	%rbp
	push	%r12
	push	%r13
	push	%r14
	push	%r15

	RESERVE_STACK  = (W_SIZE*4 + 8+24)

	/* Align stack */
	mov	%rsp, %rbx
	and	$~(0x20-1), %rsp
	push	%rbx
	sub	$RESERVE_STACK, %rsp

	avx2_zeroupper

	lea	K_XMM_AR(%rip), K_BASE

	mov	CTX, HASH_PTR
	mov	BUF, BUFFER_PTR
	lea	64(BUF), BUFFER_PTR2

	shl	$6, CNT			/* mul by 64 */
	add	BUF, CNT
	add	$64, CNT
	mov	CNT, BUFFER_END

	cmp	BUFFER_END, BUFFER_PTR2
	cmovae	K_BASE, BUFFER_PTR2

	xmm_mov	BSWAP_SHUFB_CTL(%rip), YMM_SHUFB_BSWAP

	SHA1_PIPELINED_MAIN_BODY

	avx2_zeroupper

	add	$RESERVE_STACK, %rsp
	pop	%rsp

	pop	%r15
	pop	%r14
	pop	%r13
	pop	%r12
	pop	%rbp
	pop	%rbx

	ret

	ENDPROC(sha1_transform)
#endif