libbb/sha1: use SSE2 in unrolled x86-64 code. ~10% faster

function old new delta .rodata 108241 108305 +64 sha1_process_block64 3502 3495 -7 ------------------------------------------------------------------------------ (add/remove: 5/0 grow/shrink: 1/1 up/down: 64/-7) Total: 57 bytes Signed-off-by: Denys Vlasenko <vda.linux@googlemail.com>
2022-01-23 09:27:30 +01:00 · 2022-01-23 09:27:30 +01:00 · 39369ff460
commit 39369ff460
parent 1e825acf8d
2 changed files with 854 additions and 578 deletions
--- a/libbb/hash_md5_sha_x86-64.S
+++ b/libbb/hash_md5_sha_x86-64.S
--- a/libbb/hash_md5_sha_x86-64.S.sh
+++ b/libbb/hash_md5_sha_x86-64.S.sh
@ -6,33 +6,103 @@
 # also contains the diff of the generated file.
 exec >hash_md5_sha_x86-64.S
-# There is a way to use XMM registers (which always exist for x86-64!) for W[]
+# Based on http://arctic.org/~dean/crypto/sha1.html.
-# For example, if we load W as follows:
+# ("This SHA1 implementation is public domain.")
-#	%xmm0:  w[0x0] w[0x1] w[0x2] w[0x3]
+#
-#	%xmm4:  w[0x4] w[0x5] w[0x6] w[0x7]
+# x86-64 has at least SSE2 vector insns always available.
-#	%xmm8:  w[0x8] w[0x9] w[0xa] w[0xb]
+# We can use them without any CPUID checks (and without a need
-#	%xmm12: w[0xc] w[0xd] w[0xe] w[0xf]
+# for a fallback code if needed insns are not available).
-# then the xor'ing operation to generate next W[0..3] is:
+# This code uses them to calculate W[] ahead of time.
-#	movaps	%xmm0, %xmmT2
+#
-#	palignr	$0x8, %xmm4, %xmmT2 # form (w[0x2],w[0x3],w[0x4],w[0x5])
+# Unfortunately, results are passed from vector unit to
-#	# Right-shifts xmm4:xmmT2 by 8 bytes. Writes shifted result to xmmT2. SSSE3 insn.
+# integer ALUs on the stack. MOVD/Q insns to move them directly
-#	movaps	%xmm0, %xmmT13
+# from vector to integer registers are slower than store-to-load
-#	palignr $0x4,%xmm0,%xmmT13 # form (w[0xd],w[0xe],w[0xf],w[0x0])
+# forwarding in LSU (on Skylake at least).
-#	xmm0 = xmm0 ^ t2 ^ xmm8 ^ t13
+#
-#	xmm0 = rol32(xmm0,1)	# no such insn, have to use pslld+psrld+or
+# The win against a purely integer code is small on Skylake,
-# and then results can be extracted for use:
+# only about 7-8%. We offload about 1/3 of our operations to the vector unit.
-#	movd	%xmm0, %esi	# new W[0]
+# It can do 4 ops at once in one 128-bit register,
-#	pextrd	$1, %xmm0, %esi	# new W[1]
+# but we have to use x2 of them because of W[0] complication,
-#	# SSE4.1 insn. Can use EXTRACTPS (also SSE4.1)
+# SSE2 has no "rotate each word by N bits" insns,
-#	pextrd	$2, %xmm0, %esi	# new W[2]
+# moving data to/from vector unit is clunky, and Skylake
-#	pextrd	$3, %xmm0, %esi	# new W[3]
+# has four integer ALUs unified with three vector ALUs,
-# ... but this requires SSE4.1 and SSSE3, which are not universally available on x86-64.
+# which makes pure integer code rather fast, and makes
 # vector ops compete with integer ones.
 #
 # Zen3, with its separate vector ALUs, wins more, about 12%.
 xmmT1="%xmm4"
 xmmT2="%xmm5"
 xmmRCONST="%xmm6"
 T=`printf '\t'`
 # SSE instructions are longer than 4 bytes on average.
 # Intel CPUs (up to Tiger Lake at least) can't decode
 # more than 16 bytes of code in one cycle.
 # By interleaving SSE code and integer code
 # we mostly achieve a situation where 16-byte decode fetch window
 # contains 4 (or more) insns.
 #
 # However. On Skylake, there was no observed difference,
 # but on Zen3, non-interleaved code is ~3% faster
 # (822 Mb/s versus 795 Mb/s hashing speed).
 # Off for now:
 interleave=false
 INTERLEAVE() {
 	$interleave || \
 	{
 		# Generate non-interleaved code
 		# (it should work correctly too)
 		echo "$1"
 		echo "$2"
 		return
 	}
 	(
 	echo "$1" | grep -v '^$' >"$0.temp1"
 	echo "$2" | grep -v '^$' >"$0.temp2"
 	exec 3<"$0.temp1"
 	exec 4<"$0.temp2"
 	IFS=''
 	while :; do
 		line1=''
 		line2=''
 		while :; do
 			read -r line1 <&3
 			if test "${line1:0:1}" != "#" && test "${line1:0:2}" != "$T#"; then
 				break
 			fi
 			echo "$line1"
 		done
 		while :; do
 			read -r line2 <&4
 			if test "${line2:0:4}" = "${T}lea"; then
 				# We use 7-8 byte long forms of LEA.
 				# Do not interleave them with SSE insns
 				# which are also long.
 				echo "$line2"
 				read -r line2 <&4
 				echo "$line2"
 				continue
 			fi
 			if test "${line2:0:1}" != "#" && test "${line2:0:2}" != "$T#"; then
 				break
 			fi
 			echo "$line2"
 		done
 		test "$line1$line2" || break
 		echo "$line1"
 		echo "$line2"
 	done
 	rm "$0.temp1" "$0.temp2"
 	)
 }
 echo \
-'### Generated by hash_md5_sha_x86-64.S.sh ###
+"### Generated by hash_md5_sha_x86-64.S.sh ###
 #if CONFIG_SHA1_SMALL == 0 && defined(__GNUC__) && defined(__x86_64__)
-	.section	.text.sha1_process_block64,"ax",@progbits
+	.section	.text.sha1_process_block64,\"ax\",@progbits
 	.globl	sha1_process_block64
 	.hidden	sha1_process_block64
 	.type	sha1_process_block64, @function
@ -51,16 +121,10 @@ sha1_process_block64:
 # eax..edx: a..d
 # ebp: e
 # esi,edi: temps
-# -32+4*n(%rsp),r8...r15: W[0..7,8..15]
+# xmm0..xmm3: W[]
-# (TODO: actually W[0..7] are used a bit more often, put _them_ into r8..r15?)
+# xmm4,xmm5: temps
-	movl	$3, %eax
+# xmm6: current round constant
-1:
+# -64(%rsp): area for passing RCONST + W[] from vector to integer units
 	movq	(%rdi,%rax,8), %rsi
 	bswapq	%rsi
 	rolq	$32, %rsi
 	movq	%rsi, -32(%rsp,%rax,8)
 	decl	%eax
 	jns	1b
 	movl	80(%rdi), %eax		# a = ctx->hash[0]
 	movl	84(%rdi), %ebx		# b = ctx->hash[1]
@ -68,32 +132,120 @@ sha1_process_block64:
 	movl	92(%rdi), %edx		# d = ctx->hash[3]
 	movl	96(%rdi), %ebp		# e = ctx->hash[4]
 	movaps	rconst0x5A827999(%rip), $xmmRCONST
 	# For round 1, steps 0 and 8..15, we pass W[0,8..15] in esi,r8..r15
 	# instead of spilling them to stack.
 	# (We lose parallelized addition of RCONST, but LEA
 	# can do two additions at once, so...)
 	movq	4*0(%rdi), %rsi
 	movq	4*2(%rdi), %r10
 	bswapq	%rsi
 	bswapq	%r10
 	rolq	\$32, %rsi		# rsi = W[1]:W[0]
 	rolq	\$32, %r10
 	movq	%rsi, %xmm0
 	movq	%r10, $xmmT1
 	punpcklqdq $xmmT1, %xmm0	# xmm0 = r10:rsi = (W[0],W[1],W[2],W[3])
 	movaps	%xmm0, $xmmT1
 	paddd	$xmmRCONST, $xmmT1
 	movups	$xmmT1, -64+4*0(%rsp)
 	movq	4*4(%rdi), %r8
 	movq	4*6(%rdi), %r10
 	bswapq	%r8
 	bswapq	%r10
 	rolq	\$32, %r8
 	rolq	\$32, %r10
 	movq	%r8, %xmm1
 	movq	%r10, $xmmT1
 	punpcklqdq $xmmT1, %xmm1	# xmm1 = r10:r8 = (W[4],W[5],W[6],W[7])
 	movaps	%xmm1, $xmmT1
 	paddd	$xmmRCONST, $xmmT1
 	movups	$xmmT1, -64+4*4(%rsp)
 	movq	4*8(%rdi), %r8
 	movq	4*10(%rdi), %r10
 	bswapq	%r8
 	bswapq	%r10
 	movl	%r8d, %r9d		# r9d = W[9]
 	rolq	\$32, %r8		# r8  = W[9]:W[8]
 	movl	%r10d, %r11d		# r11d = W[11]
 	rolq	\$32, %r10		# r10  = W[11]:W[10]
 	movq	%r8, %xmm2
 	movq	%r10, $xmmT1
 	punpcklqdq $xmmT1, %xmm2	# xmm2 = r10:r8 = (W[8],W[9],W[10],W[11])
 	movq	4*12(%rdi), %r12
 	movq	4*14(%rdi), %r14
 	bswapq	%r12
 	bswapq	%r14
-	movl	%r8d, %r9d
+	movl	%r12d, %r13d		# r13d = W[13]
-	shrq	$32, %r8
+	rolq	\$32, %r12		# r12  = W[13]:W[12]
-	movl	%r10d, %r11d
+	movl	%r14d, %r15d		# r15d = W[15]
-	shrq	$32, %r10
+	rolq	\$32, %r14		# r14  = W[15]:W[14]
-	movl	%r12d, %r13d
+	movq	%r12, %xmm3
-	shrq	$32, %r12
+	movq	%r14, $xmmT1
-	movl	%r14d, %r15d
+	punpcklqdq $xmmT1, %xmm3	# xmm3 = r14:r12 = (W[12],W[13],W[14],W[15])
-	shrq	$32, %r14
+"
-'
+
-W32() {
+PREP() {
-test "$1" || exit 1
+local xmmW0=$1
-test "$1" -lt 0 && exit 1
+local xmmW4=$2
-test "$1" -gt 15 && exit 1
+local xmmW8=$3
-test "$1" -lt 8 && echo "-32+4*$1(%rsp)"
+local xmmW12=$4
-test "$1" -ge 8 && echo "%r${1}d"
+# the above must be %xmm0..3 in some permutation
 local dstmem=$5
 #W[0] = rol(W[13] ^ W[8]  ^ W[2] ^ W[0], 1);
 #W[1] = rol(W[14] ^ W[9]  ^ W[3] ^ W[1], 1);
 #W[2] = rol(W[15] ^ W[10] ^ W[4] ^ W[2], 1);
 #W[3] = rol(  0   ^ W[11] ^ W[5] ^ W[3], 1);
 #W[3] ^= rol(W[0], 1);
 echo "# PREP $@
 	movaps	$xmmW12, $xmmT1
 	psrldq	\$4, $xmmT1	# rshift by 4 bytes: T1 = ([13],[14],[15],0)
 	pshufd	\$0x4e, $xmmW0, $xmmT2	# 01001110=2,3,0,1 shuffle, ([2],[3],x,x)
 	punpcklqdq $xmmW4, $xmmT2	# T2 = W4[0..63]:T2[0..63] = ([2],[3],[4],[5])
 	xorps	$xmmW8, $xmmW0	# ([8],[9],[10],[11]) ^ ([0],[1],[2],[3])
 	xorps	$xmmT1, $xmmT2	# ([13],[14],[15],0) ^ ([2],[3],[4],[5])
 	xorps	$xmmT2, $xmmW0	# ^
 	# W0 = unrotated (W[0]..W[3]), still needs W[3] fixup
 	movaps	$xmmW0, $xmmT2
 	xorps	$xmmT1, $xmmT1	# rol(W0,1):
 	pcmpgtd	$xmmW0, $xmmT1	# ffffffff for elements <0 (ones with msb bit 1)
 	paddd	$xmmW0, $xmmW0	# shift left by 1
 	psubd	$xmmT1, $xmmW0	# add 1 to those who had msb bit 1
 	# W0 = rotated (W[0]..W[3]), still needs W[3] fixup
 	pslldq	\$12, $xmmT2	# lshift by 12 bytes: T2 = (0,0,0,unrotW[0])
 	movaps	$xmmT2, $xmmT1
 	pslld	\$2, $xmmT2
 	psrld	\$30, $xmmT1
 #	xorps	$xmmT1, $xmmT2	# rol((0,0,0,unrotW[0]),2)
 	xorps	$xmmT1, $xmmW0	# same result, but does not depend on/does not modify T2
 	xorps	$xmmT2, $xmmW0	# W0 = rol(W[0]..W[3],1) ^ (0,0,0,rol(unrotW[0],2))
 "
 #	movq	$xmmW0, %r8	# high latency (~6 cycles)
 #	movaps	$xmmW0, $xmmT1
 #	psrldq	\$8, $xmmT1	# rshift by 8 bytes: move upper 64 bits to lower
 #	movq	$xmmT1, %r10	# high latency
 #	movq	%r8, %r9
 #	movq	%r10, %r11
 #	shrq	\$32, %r9
 #	shrq	\$32, %r11
 # ^^^ slower than passing the results on stack (!!!)
 echo "
 	movaps	$xmmW0, $xmmT2
 	paddd	$xmmRCONST, $xmmT2
 	movups	$xmmT2, $dstmem
 "
 }
-# It's possible to interleave insns in rounds to mostly eliminate
+# It's possible to interleave integer insns in rounds to mostly eliminate
 # dependency chains, but this likely to only help old Pentium-based
 # CPUs (ones without OOO, which can only simultaneously execute a pair
 # of _adjacent_ insns).
@ -107,21 +259,16 @@ local n0=$(((n+0) & 15))
 echo "
 # $n
 ";test $n0 = 0 && echo "
-	# W[0], already in %esi
+	leal	$RCONST(%r$e,%rsi), %e$e # e += RCONST + W[n]
 ";test $n0 != 0 && test $n0 -lt 8 && echo "
-	movl	`W32 $n0`, %esi		# W[n]
+	addl	-64+4*$n0(%rsp), %e$e	# e += RCONST + W[n]
 ";test $n0 -ge 8 && echo "
-	# W[n], in %r$n0
+	leal	$RCONST(%r$e,%r$n0), %e$e # e += RCONST + W[n]
 ";echo "
 	movl	%e$c, %edi		# c
 	xorl	%e$d, %edi		# ^d
 	andl	%e$b, %edi		# &b
 	xorl	%e$d, %edi		# (((c ^ d) & b) ^ d)
 ";test $n0 -lt 8 && echo "
 	leal	$RCONST(%r$e,%rsi), %e$e # e += RCONST + W[n]
 ";test $n0 -ge 8 && echo "
 	leal	$RCONST(%r$e,%r$n0), %e$e # e += RCONST + W[n]
 ";echo "
 	addl	%edi, %e$e		# e += (((c ^ d) & b) ^ d)
 	movl	%e$a, %esi		#
 	roll	\$5, %esi		# rotl32(a,5)
@ -138,28 +285,11 @@ local n2=$(((n+2) & 15))
 local n0=$(((n+0) & 15))
 echo "
 # $n
 ";test $n0 -lt 8 && echo "
 	movl	`W32 $n13`, %esi	# W[(n+13) & 15]
 	xorl	`W32 $n8`, %esi		# ^W[(n+8) & 15]
 	xorl	`W32 $n2`, %esi		# ^W[(n+2) & 15]
 	xorl	`W32 $n0`, %esi		# ^W[n & 15]
 	roll	%esi			#
 	movl	%esi, `W32 $n0`		# store to W[n & 15]
 ";test $n0 -ge 8 && echo "
 	xorl	`W32 $n13`, `W32 $n0`	# W[n & 15] ^= W[(n+13) & 15]
 	xorl	`W32 $n8`, `W32 $n0`	# ^W[(n+8) & 15]
 	xorl	`W32 $n2`, `W32 $n0`	# ^W[(n+2) & 15]
 	roll	`W32 $n0`		#
 ";echo "
 	movl	%e$c, %edi		# c
 	xorl	%e$d, %edi		# ^d
 	andl	%e$b, %edi		# &b
 	xorl	%e$d, %edi		# (((c ^ d) & b) ^ d)
-";test $n0 -lt 8 && echo "
+	addl	-64+4*$n0(%rsp), %e$e	# e += RCONST + W[n & 15]
 	leal	$RCONST(%r$e,%rsi), %e$e # e += RCONST + W[n & 15]
 ";test $n0 -ge 8 && echo "
 	leal	$RCONST(%r$e,%r$n0), %e$e # e += RCONST + W[n & 15]
 ";echo "
 	addl	%edi, %e$e		# e += (((c ^ d) & b) ^ d)
 	movl	%e$a, %esi		#
 	roll	\$5, %esi		# rotl32(a,5)
@ -167,13 +297,6 @@ echo "
 	rorl	\$2, %e$b		# b = rotl32(b,30)
 "
 }
 {
 RCONST=0x5A827999
 RD1A ax bx cx dx bp  0; RD1A bp ax bx cx dx  1; RD1A dx bp ax bx cx  2; RD1A cx dx bp ax bx  3; RD1A bx cx dx bp ax  4
 RD1A ax bx cx dx bp  5; RD1A bp ax bx cx dx  6; RD1A dx bp ax bx cx  7; RD1A cx dx bp ax bx  8; RD1A bx cx dx bp ax  9
 RD1A ax bx cx dx bp 10; RD1A bp ax bx cx dx 11; RD1A dx bp ax bx cx 12; RD1A cx dx bp ax bx 13; RD1A bx cx dx bp ax 14
 RD1A ax bx cx dx bp 15; RD1B bp ax bx cx dx 16; RD1B dx bp ax bx cx 17; RD1B cx dx bp ax bx 18; RD1B bx cx dx bp ax 19
 } | grep -v '^$'
 RD2() {
 local a=$1;local b=$2;local c=$3;local d=$4;local e=$5
@ -184,27 +307,10 @@ local n2=$(((n+2) & 15))
 local n0=$(((n+0) & 15))
 echo "
 # $n
 ";test $n0 -lt 8 && echo "
 	movl	`W32 $n13`, %esi	# W[(n+13) & 15]
 	xorl	`W32 $n8`, %esi		# ^W[(n+8) & 15]
 	xorl	`W32 $n2`, %esi		# ^W[(n+2) & 15]
 	xorl	`W32 $n0`, %esi		# ^W[n & 15]
 	roll	%esi			#
 	movl	%esi, `W32 $n0`		# store to W[n & 15]
 ";test $n0 -ge 8 && echo "
 	xorl	`W32 $n13`, `W32 $n0`	# W[n & 15] ^= W[(n+13) & 15]
 	xorl	`W32 $n8`, `W32 $n0`	# ^W[(n+8) & 15]
 	xorl	`W32 $n2`, `W32 $n0`	# ^W[(n+2) & 15]
 	roll	`W32 $n0`		#
 ";echo "
 	movl	%e$c, %edi		# c
 	xorl	%e$d, %edi		# ^d
 	xorl	%e$b, %edi		# ^b
-";test $n0 -lt 8 && echo "
+	addl	-64+4*$n0(%rsp), %e$e	# e += RCONST + W[n & 15]
 	leal	$RCONST(%r$e,%rsi), %e$e # e += RCONST + W[n & 15]
 ";test $n0 -ge 8 && echo "
 	leal	$RCONST(%r$e,%r$n0), %e$e # e += RCONST + W[n & 15]
 ";echo "
 	addl	%edi, %e$e		# e += (c ^ d ^ b)
 	movl	%e$a, %esi		#
 	roll	\$5, %esi		# rotl32(a,5)
@ -212,13 +318,6 @@ echo "
 	rorl	\$2, %e$b		# b = rotl32(b,30)
 "
 }
 {
 RCONST=0x6ED9EBA1
 RD2 ax bx cx dx bp 20; RD2 bp ax bx cx dx 21; RD2 dx bp ax bx cx 22; RD2 cx dx bp ax bx 23; RD2 bx cx dx bp ax 24
 RD2 ax bx cx dx bp 25; RD2 bp ax bx cx dx 26; RD2 dx bp ax bx cx 27; RD2 cx dx bp ax bx 28; RD2 bx cx dx bp ax 29
 RD2 ax bx cx dx bp 30; RD2 bp ax bx cx dx 31; RD2 dx bp ax bx cx 32; RD2 cx dx bp ax bx 33; RD2 bx cx dx bp ax 34
 RD2 ax bx cx dx bp 35; RD2 bp ax bx cx dx 36; RD2 dx bp ax bx cx 37; RD2 cx dx bp ax bx 38; RD2 bx cx dx bp ax 39
 } | grep -v '^$'
 RD3() {
 local a=$1;local b=$2;local c=$3;local d=$4;local e=$5
@ -235,53 +334,82 @@ echo "
 	andl	%e$c, %esi		# si: b & c
 	andl	%e$d, %edi		# di: (b | c) & d
 	orl	%esi, %edi		# ((b | c) & d) | (b & c)
 ";test $n0 -lt 8 && echo "
 	movl	`W32 $n13`, %esi	# W[(n+13) & 15]
 	xorl	`W32 $n8`, %esi		# ^W[(n+8) & 15]
 	xorl	`W32 $n2`, %esi		# ^W[(n+2) & 15]
 	xorl	`W32 $n0`, %esi		# ^W[n & 15]
 	roll	%esi			#
 	movl	%esi, `W32 $n0`		# store to W[n & 15]
 ";test $n0 -ge 8 && echo "
 	xorl	`W32 $n13`, `W32 $n0`	# W[n & 15] ^= W[(n+13) & 15]
 	xorl	`W32 $n8`, `W32 $n0`	# ^W[(n+8) & 15]
 	xorl	`W32 $n2`, `W32 $n0`	# ^W[(n+2) & 15]
 	roll	`W32 $n0`		#
 ";echo "
 	addl	%edi, %e$e		# += ((b | c) & d) | (b & c)
-";test $n0 -lt 8 && echo "
+	addl	-64+4*$n0(%rsp), %e$e	# e += RCONST + W[n & 15]
 	leal	$RCONST(%r$e,%rsi), %e$e # e += RCONST + W[n & 15]
 ";test $n0 -ge 8 && echo "
 	leal	$RCONST(%r$e,%r$n0), %e$e # e += RCONST + W[n & 15]
 ";echo "
 	movl	%e$a, %esi		#
 	roll	\$5, %esi		# rotl32(a,5)
 	addl	%esi, %e$e		# e += rotl32(a,5)
 	rorl	\$2, %e$b		# b = rotl32(b,30)
 "
 }
 {
-#RCONST=0x8F1BBCDC "out of range for signed 32bit displacement"
+# Round 1
-RCONST=-0x70E44324
+RCONST=0x5A827999
-RD3 ax bx cx dx bp 40; RD3 bp ax bx cx dx 41; RD3 dx bp ax bx cx 42; RD3 cx dx bp ax bx 43; RD3 bx cx dx bp ax 44
+RD1A ax bx cx dx bp  0; RD1A bp ax bx cx dx  1; RD1A dx bp ax bx cx  2; RD1A cx dx bp ax bx  3;
-RD3 ax bx cx dx bp 45; RD3 bp ax bx cx dx 46; RD3 dx bp ax bx cx 47; RD3 cx dx bp ax bx 48; RD3 bx cx dx bp ax 49
+RD1A bx cx dx bp ax  4; RD1A ax bx cx dx bp  5; RD1A bp ax bx cx dx  6; RD1A dx bp ax bx cx  7;
-RD3 ax bx cx dx bp 50; RD3 bp ax bx cx dx 51; RD3 dx bp ax bx cx 52; RD3 cx dx bp ax bx 53; RD3 bx cx dx bp ax 54
+a=`PREP %xmm0 %xmm1 %xmm2 %xmm3 "-64+16*0(%rsp)"`
-RD3 ax bx cx dx bp 55; RD3 bp ax bx cx dx 56; RD3 dx bp ax bx cx 57; RD3 cx dx bp ax bx 58; RD3 bx cx dx bp ax 59
+b=`RD1A cx dx bp ax bx  8; RD1A bx cx dx bp ax  9; RD1A ax bx cx dx bp 10; RD1A bp ax bx cx dx 11;`
-} | grep -v '^$'
+INTERLEAVE "$a" "$b"
 a=`echo "	movaps	rconst0x6ED9EBA1(%rip), $xmmRCONST"
   PREP %xmm1 %xmm2 %xmm3 %xmm0 "-64+16*1(%rsp)"`
 b=`RD1A dx bp ax bx cx 12; RD1A cx dx bp ax bx 13; RD1A bx cx dx bp ax 14; RD1A ax bx cx dx bp 15;`
 INTERLEAVE "$a" "$b"
 a=`PREP %xmm2 %xmm3 %xmm0 %xmm1 "-64+16*2(%rsp)"`
 b=`RD1B bp ax bx cx dx 16; RD1B dx bp ax bx cx 17; RD1B cx dx bp ax bx 18; RD1B bx cx dx bp ax 19;`
 INTERLEAVE "$a" "$b"
 # Round 2
 RCONST=0x6ED9EBA1
 a=`PREP %xmm3 %xmm0 %xmm1 %xmm2 "-64+16*3(%rsp)"`
 b=`RD2 ax bx cx dx bp 20; RD2 bp ax bx cx dx 21; RD2 dx bp ax bx cx 22; RD2 cx dx bp ax bx 23;`
 INTERLEAVE "$a" "$b"
 a=`PREP %xmm0 %xmm1 %xmm2 %xmm3 "-64+16*0(%rsp)"`
 b=`RD2 bx cx dx bp ax 24; RD2 ax bx cx dx bp 25; RD2 bp ax bx cx dx 26; RD2 dx bp ax bx cx 27;`
 INTERLEAVE "$a" "$b"
 a=`PREP %xmm1 %xmm2 %xmm3 %xmm0 "-64+16*1(%rsp)"`
 b=`RD2 cx dx bp ax bx 28; RD2 bx cx dx bp ax 29; RD2 ax bx cx dx bp 30; RD2 bp ax bx cx dx 31;`
 INTERLEAVE "$a" "$b"
 a=`echo "	movaps	rconst0x8F1BBCDC(%rip), $xmmRCONST"
   PREP %xmm2 %xmm3 %xmm0 %xmm1 "-64+16*2(%rsp)"`
 b=`RD2 dx bp ax bx cx 32; RD2 cx dx bp ax bx 33; RD2 bx cx dx bp ax 34; RD2 ax bx cx dx bp 35;`
 INTERLEAVE "$a" "$b"
 a=`PREP %xmm3 %xmm0 %xmm1 %xmm2 "-64+16*3(%rsp)"`
 b=`RD2 bp ax bx cx dx 36; RD2 dx bp ax bx cx 37; RD2 cx dx bp ax bx 38; RD2 bx cx dx bp ax 39;`
 INTERLEAVE "$a" "$b"
 # Round 3
 RCONST=0x8F1BBCDC
 a=`PREP %xmm0 %xmm1 %xmm2 %xmm3 "-64+16*0(%rsp)"`
 b=`RD3 ax bx cx dx bp 40; RD3 bp ax bx cx dx 41; RD3 dx bp ax bx cx 42; RD3 cx dx bp ax bx 43;`
 INTERLEAVE "$a" "$b"
 a=`PREP %xmm1 %xmm2 %xmm3 %xmm0 "-64+16*1(%rsp)"`
 b=`RD3 bx cx dx bp ax 44; RD3 ax bx cx dx bp 45; RD3 bp ax bx cx dx 46; RD3 dx bp ax bx cx 47;`
 INTERLEAVE "$a" "$b"
 a=`PREP %xmm2 %xmm3 %xmm0 %xmm1 "-64+16*2(%rsp)"`
 b=`RD3 cx dx bp ax bx 48; RD3 bx cx dx bp ax 49; RD3 ax bx cx dx bp 50; RD3 bp ax bx cx dx 51;`
 INTERLEAVE "$a" "$b"
 a=`echo "	movaps	rconst0xCA62C1D6(%rip), $xmmRCONST"
   PREP %xmm3 %xmm0 %xmm1 %xmm2 "-64+16*3(%rsp)"`
 b=`RD3 dx bp ax bx cx 52; RD3 cx dx bp ax bx 53; RD3 bx cx dx bp ax 54; RD3 ax bx cx dx bp 55;`
 INTERLEAVE "$a" "$b"
 a=`PREP %xmm0 %xmm1 %xmm2 %xmm3 "-64+16*0(%rsp)"`
 b=`RD3 bp ax bx cx dx 56; RD3 dx bp ax bx cx 57; RD3 cx dx bp ax bx 58; RD3 bx cx dx bp ax 59;`
 INTERLEAVE "$a" "$b"
 # Round 4 has the same logic as round 2, only n and RCONST are different
-{
+RCONST=0xCA62C1D6
-#RCONST=0xCA62C1D6 "out of range for signed 32bit displacement"
+a=`PREP %xmm1 %xmm2 %xmm3 %xmm0 "-64+16*1(%rsp)"`
-RCONST=-0x359D3E2A
+b=`RD2 ax bx cx dx bp 60; RD2 bp ax bx cx dx 61; RD2 dx bp ax bx cx 62; RD2 cx dx bp ax bx 63;`
-RD2 ax bx cx dx bp 60; RD2 bp ax bx cx dx 61; RD2 dx bp ax bx cx 62; RD2 cx dx bp ax bx 63; RD2 bx cx dx bp ax 64
+INTERLEAVE "$a" "$b"
-RD2 ax bx cx dx bp 65; RD2 bp ax bx cx dx 66; RD2 dx bp ax bx cx 67; RD2 cx dx bp ax bx 68; RD2 bx cx dx bp ax 69
+a=`PREP %xmm2 %xmm3 %xmm0 %xmm1 "-64+16*2(%rsp)"`
-RD2 ax bx cx dx bp 70; RD2 bp ax bx cx dx 71; RD2 dx bp ax bx cx 72; RD2 cx dx bp ax bx 73; RD2 bx cx dx bp ax 74
+b=`RD2 bx cx dx bp ax 64; RD2 ax bx cx dx bp 65; RD2 bp ax bx cx dx 66; RD2 dx bp ax bx cx 67;`
-RD2 ax bx cx dx bp 75; RD2 bp ax bx cx dx 76; RD2 dx bp ax bx cx 77; RD2 cx dx bp ax bx 78; RD2 bx cx dx bp ax 79
+INTERLEAVE "$a" "$b"
-# Note: new W[n&15] values generated in last 3 iterations
+a=`PREP %xmm3 %xmm0 %xmm1 %xmm2 "-64+16*3(%rsp)"`
-# (W[13,14,15]) are unused after each of these iterations.
+b=`RD2 cx dx bp ax bx 68; RD2 bx cx dx bp ax 69; RD2 ax bx cx dx bp 70; RD2 bp ax bx cx dx 71;`
-# Since we use r8..r15 for W[8..15], this does not matter.
+INTERLEAVE "$a" "$b"
-# If we switch to e.g. using r8..r15 for W[0..7], then saving of W[13,14,15]
+RD2 dx bp ax bx cx 72; RD2 cx dx bp ax bx 73; RD2 bx cx dx bp ax 74; RD2 ax bx cx dx bp 75;
-# (the "movl %esi, `W32 $n0`" insn) is a dead store and can be removed.
+RD2 bp ax bx cx dx 76; RD2 dx bp ax bx cx 77; RD2 cx dx bp ax bx 78; RD2 bx cx dx bp ax 79;
 } | grep -v '^$'
 echo "
@ -300,4 +428,28 @@ echo "
 	ret
 	.size	sha1_process_block64, .-sha1_process_block64
 	.section	.rodata.cst16.sha1const, \"aM\", @progbits, 16
 	.align	16
 rconst0x5A827999:
 	.long	0x5A827999
 	.long	0x5A827999
 	.long	0x5A827999
 	.long	0x5A827999
 rconst0x6ED9EBA1:
 	.long	0x6ED9EBA1
 	.long	0x6ED9EBA1
 	.long	0x6ED9EBA1
 	.long	0x6ED9EBA1
 rconst0x8F1BBCDC:
 	.long	0x8F1BBCDC
 	.long	0x8F1BBCDC
 	.long	0x8F1BBCDC
 	.long	0x8F1BBCDC
 rconst0xCA62C1D6:
 	.long	0xCA62C1D6
 	.long	0xCA62C1D6
 	.long	0xCA62C1D6
 	.long	0xCA62C1D6
 #endif"