1 files changed, 1496 insertions, 0 deletions

diff --git a/openssl/crypto/bn/asm/modexp512-x86_64.pl b/openssl/crypto/bn/asm/modexp512-x86_64.pl
new file mode 100644
index 000000000..54aeb0192
--- /dev/null
+++ b/openssl/crypto/bn/asm/modexp512-x86_64.pl
@@ -0,0 +1,1496 @@
+#!/usr/bin/env perl
+#
+# Copyright (c) 2010-2011 Intel Corp.
+#   Author: Vinodh.Gopal@intel.com
+#           Jim Guilford
+#           Erdinc.Ozturk@intel.com
+#           Maxim.Perminov@intel.com
+#
+# More information about algorithm used can be found at:
+#   http://www.cse.buffalo.edu/srds2009/escs2009_submission_Gopal.pdf
+#
+# ====================================================================
+# Copyright (c) 2011 The OpenSSL Project.  All rights reserved.
+#
+# Redistribution and use in source and binary forms, with or without
+# modification, are permitted provided that the following conditions
+# are met:
+#
+# 1. Redistributions of source code must retain the above copyright
+#    notice, this list of conditions and the following disclaimer.
+#
+# 2. 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.
+#
+# 3. All advertising materials mentioning features or use of this
+#    software must display the following acknowledgment:
+#    "This product includes software developed by the OpenSSL Project
+#    for use in the OpenSSL Toolkit. (http://www.OpenSSL.org/)"
+#
+# 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to
+#    endorse or promote products derived from this software without
+#    prior written permission. For written permission, please contact
+#    licensing@OpenSSL.org.
+#
+# 5. Products derived from this software may not be called "OpenSSL"
+#    nor may "OpenSSL" appear in their names without prior written
+#    permission of the OpenSSL Project.
+#
+# 6. Redistributions of any form whatsoever must retain the following
+#    acknowledgment:
+#    "This product includes software developed by the OpenSSL Project
+#    for use in the OpenSSL Toolkit (http://www.OpenSSL.org/)"
+#
+# THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ``AS IS'' AND ANY
+# EXPRESSED 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 OpenSSL PROJECT OR
+# ITS 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.
+# ====================================================================
+
+$flavour = shift;
+$output  = shift;
+if ($flavour =~ /\./) { $output = $flavour; undef $flavour; }
+
+my $win64=0; $win64=1 if ($flavour =~ /[nm]asm|mingw64/ || $output =~ /\.asm$/);
+
+$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
+( $xlate="${dir}x86_64-xlate.pl" and -f $xlate ) or
+( $xlate="${dir}../../perlasm/x86_64-xlate.pl" and -f $xlate) or
+die "can't locate x86_64-xlate.pl";
+
+open STDOUT,"| $^X $xlate $flavour $output";
+
+use strict;
+my $code=".text\n\n";
+my $m=0;
+
+#
+# Define x512 macros
+#
+
+#MULSTEP_512_ADD	MACRO	x7, x6, x5, x4, x3, x2, x1, x0, dst, src1, src2, add_src, tmp1, tmp2
+#
+# uses rax, rdx, and args
+sub MULSTEP_512_ADD
+{
+ my ($x, $DST, $SRC2, $ASRC, $OP, $TMP)=@_;
+ my @X=@$x;	# make a copy
+$code.=<<___;
+	 mov	(+8*0)($SRC2), %rax
+	 mul	$OP			# rdx:rax = %OP * [0]
+	 mov	($ASRC), $X[0]
+	 add	%rax, $X[0]
+	 adc	\$0, %rdx
+	 mov	$X[0], $DST
+___
+for(my $i=1;$i<8;$i++) {
+$code.=<<___;
+	 mov	%rdx, $TMP
+
+	 mov	(+8*$i)($SRC2), %rax
+	 mul	$OP			# rdx:rax = %OP * [$i]
+	 mov	(+8*$i)($ASRC), $X[$i]
+	 add	%rax, $X[$i]
+	 adc	\$0, %rdx
+	 add	$TMP, $X[$i]
+	 adc	\$0, %rdx
+___
+}
+$code.=<<___;
+	 mov	%rdx, $X[0]
+___
+}
+
+#MULSTEP_512	MACRO	x7, x6, x5, x4, x3, x2, x1, x0, dst, src2, src1_val, tmp
+#
+# uses rax, rdx, and args
+sub MULSTEP_512
+{
+ my ($x, $DST, $SRC2, $OP, $TMP)=@_;
+ my @X=@$x;	# make a copy
+$code.=<<___;
+	 mov	(+8*0)($SRC2), %rax
+	 mul	$OP			# rdx:rax = %OP * [0]
+	 add	%rax, $X[0]
+	 adc	\$0, %rdx
+	 mov	$X[0], $DST
+___
+for(my $i=1;$i<8;$i++) {
+$code.=<<___;
+	 mov	%rdx, $TMP
+
+	 mov	(+8*$i)($SRC2), %rax
+	 mul	$OP			# rdx:rax = %OP * [$i]
+	 add	%rax, $X[$i]
+	 adc	\$0, %rdx
+	 add	$TMP, $X[$i]
+	 adc	\$0, %rdx
+___
+}
+$code.=<<___;
+	 mov	%rdx, $X[0]
+___
+}
+
+#
+# Swizzle Macros
+#
+
+# macro to copy data from flat space to swizzled table
+#MACRO swizzle	pDst, pSrc, tmp1, tmp2
+# pDst and pSrc are modified
+sub swizzle
+{
+ my ($pDst, $pSrc, $cnt, $d0)=@_;
+$code.=<<___;
+	 mov	\$8, $cnt
+loop_$m:
+	 mov	($pSrc), $d0
+	 mov	$d0#w, ($pDst)
+	 shr	\$16, $d0
+	 mov	$d0#w, (+64*1)($pDst)
+	 shr	\$16, $d0
+	 mov	$d0#w, (+64*2)($pDst)
+	 shr	\$16, $d0
+	 mov	$d0#w, (+64*3)($pDst)
+	 lea	8($pSrc), $pSrc
+	 lea	64*4($pDst), $pDst
+	 dec	$cnt
+	 jnz	loop_$m
+___
+
+ $m++;
+}
+
+# macro to copy data from swizzled table to  flat space
+#MACRO unswizzle	pDst, pSrc, tmp*3
+sub unswizzle
+{
+ my ($pDst, $pSrc, $cnt, $d0, $d1)=@_;
+$code.=<<___;
+	 mov	\$4, $cnt
+loop_$m:
+	 movzxw	(+64*3+256*0)($pSrc), $d0
+	 movzxw	(+64*3+256*1)($pSrc), $d1
+	 shl	\$16, $d0
+	 shl	\$16, $d1
+	 mov	(+64*2+256*0)($pSrc), $d0#w
+	 mov	(+64*2+256*1)($pSrc), $d1#w
+	 shl	\$16, $d0
+	 shl	\$16, $d1
+	 mov	(+64*1+256*0)($pSrc), $d0#w
+	 mov	(+64*1+256*1)($pSrc), $d1#w
+	 shl	\$16, $d0
+	 shl	\$16, $d1
+	 mov	(+64*0+256*0)($pSrc), $d0#w
+	 mov	(+64*0+256*1)($pSrc), $d1#w
+	 mov	$d0, (+8*0)($pDst)
+	 mov	$d1, (+8*1)($pDst)
+	 lea	256*2($pSrc), $pSrc
+	 lea	8*2($pDst), $pDst
+	 sub	\$1, $cnt
+	 jnz	loop_$m
+___
+
+ $m++;
+}
+
+#
+# Data Structures
+#
+
+# Reduce Data
+#
+#
+# Offset  Value
+# 0C0     Carries
+# 0B8     X2[10]
+# 0B0     X2[9]
+# 0A8     X2[8]
+# 0A0     X2[7]
+# 098     X2[6]
+# 090     X2[5]
+# 088     X2[4]
+# 080     X2[3]
+# 078     X2[2]
+# 070     X2[1]
+# 068     X2[0]
+# 060     X1[12]  P[10]
+# 058     X1[11]  P[9]  Z[8]
+# 050     X1[10]  P[8]  Z[7]
+# 048     X1[9]   P[7]  Z[6]
+# 040     X1[8]   P[6]  Z[5]
+# 038     X1[7]   P[5]  Z[4]
+# 030     X1[6]   P[4]  Z[3]
+# 028     X1[5]   P[3]  Z[2]
+# 020     X1[4]   P[2]  Z[1]
+# 018     X1[3]   P[1]  Z[0]
+# 010     X1[2]   P[0]  Y[2]
+# 008     X1[1]   Q[1]  Y[1]
+# 000     X1[0]   Q[0]  Y[0]
+
+my $X1_offset           =  0;			# 13 qwords
+my $X2_offset           =  $X1_offset + 13*8;			# 11 qwords
+my $Carries_offset      =  $X2_offset + 11*8;			# 1 qword
+my $Q_offset            =  0;			# 2 qwords
+my $P_offset            =  $Q_offset + 2*8;			# 11 qwords
+my $Y_offset            =  0;			# 3 qwords
+my $Z_offset            =  $Y_offset + 3*8;			# 9 qwords
+
+my $Red_Data_Size       =  $Carries_offset + 1*8;			# (25 qwords)
+
+#
+# Stack Frame
+#
+#
+# offset	value
+# ...		<old stack contents>
+# ...
+# 280		Garray
+
+# 278		tmp16[15]
+# ...		...
+# 200		tmp16[0]
+
+# 1F8		tmp[7]
+# ...		...
+# 1C0		tmp[0]
+
+# 1B8		GT[7]
+# ...		...
+# 180		GT[0]
+
+# 178		Reduce Data
+# ...		...
+# 0B8		Reduce Data
+# 0B0		reserved
+# 0A8		reserved
+# 0A0		reserved
+# 098		reserved
+# 090		reserved
+# 088		reduce result addr
+# 080		exp[8]
+
+# ...
+# 048		exp[1]
+# 040		exp[0]
+
+# 038		reserved
+# 030		loop_idx
+# 028		pg
+# 020		i
+# 018		pData	; arg 4
+# 010		pG	; arg 2
+# 008		pResult	; arg 1
+# 000		rsp	; stack pointer before subtract
+
+my $rsp_offset          =  0;
+my $pResult_offset      =  8*1 + $rsp_offset;
+my $pG_offset           =  8*1 + $pResult_offset;
+my $pData_offset        =  8*1 + $pG_offset;
+my $i_offset            =  8*1 + $pData_offset;
+my $pg_offset           =  8*1 + $i_offset;
+my $loop_idx_offset     =  8*1 + $pg_offset;
+my $reserved1_offset    =  8*1 + $loop_idx_offset;
+my $exp_offset          =  8*1 + $reserved1_offset;
+my $red_result_addr_offset=  8*9 + $exp_offset;
+my $reserved2_offset    =  8*1 + $red_result_addr_offset;
+my $Reduce_Data_offset  =  8*5 + $reserved2_offset;
+my $GT_offset           =  $Red_Data_Size + $Reduce_Data_offset;
+my $tmp_offset          =  8*8 + $GT_offset;
+my $tmp16_offset        =  8*8 + $tmp_offset;
+my $garray_offset       =  8*16 + $tmp16_offset;
+my $mem_size            =  8*8*32 + $garray_offset;
+
+#
+# Offsets within Reduce Data
+#
+#
+#	struct MODF_2FOLD_MONT_512_C1_DATA {
+#	UINT64 t[8][8];
+#	UINT64 m[8];
+#	UINT64 m1[8]; /* 2^768 % m */
+#	UINT64 m2[8]; /* 2^640 % m */
+#	UINT64 k1[2]; /* (- 1/m) % 2^128 */
+#	};
+
+my $T                   =  0;
+my $M                   =  512;			# = 8 * 8 * 8
+my $M1                  =  576;			# = 8 * 8 * 9 /* += 8 * 8 */
+my $M2                  =  640;			# = 8 * 8 * 10 /* += 8 * 8 */
+my $K1                  =  704;			# = 8 * 8 * 11 /* += 8 * 8 */
+
+#
+#   FUNCTIONS
+#
+
+{{{
+#
+# MULADD_128x512 : Function to multiply 128-bits (2 qwords) by 512-bits (8 qwords)
+#                       and add 512-bits (8 qwords)
+#                       to get 640 bits (10 qwords)
+# Input: 128-bit mul source: [rdi+8*1], rbp
+#        512-bit mul source: [rsi+8*n]
+#        512-bit add source: r15, r14, ..., r9, r8
+# Output: r9, r8, r15, r14, r13, r12, r11, r10, [rcx+8*1], [rcx+8*0]
+# Clobbers all regs except: rcx, rsi, rdi
+$code.=<<___;
+.type	MULADD_128x512,\@abi-omnipotent
+.align	16
+MULADD_128x512:
+___
+	&MULSTEP_512([map("%r$_",(8..15))], "(+8*0)(%rcx)", "%rsi", "%rbp", "%rbx");
+$code.=<<___;
+	 mov	(+8*1)(%rdi), %rbp
+___
+	&MULSTEP_512([map("%r$_",(9..15,8))], "(+8*1)(%rcx)", "%rsi", "%rbp", "%rbx");
+$code.=<<___;
+	 ret
+.size	MULADD_128x512,.-MULADD_128x512
+___
+}}}
+
+{{{
+#MULADD_256x512	MACRO	pDst, pA, pB, OP, TMP, X7, X6, X5, X4, X3, X2, X1, X0
+#
+# Inputs: pDst: Destination  (768 bits, 12 qwords)
+#         pA:   Multiplicand (1024 bits, 16 qwords)
+#         pB:   Multiplicand (512 bits, 8 qwords)
+# Dst = Ah * B + Al
+# where Ah is (in qwords) A[15:12] (256 bits) and Al is A[7:0] (512 bits)
+# Results in X3 X2 X1 X0 X7 X6 X5 X4 Dst[3:0]
+# Uses registers: arguments, RAX, RDX
+sub MULADD_256x512
+{
+ my ($pDst, $pA, $pB, $OP, $TMP, $X)=@_;
+$code.=<<___;
+	mov	(+8*12)($pA), $OP
+___
+	&MULSTEP_512_ADD($X, "(+8*0)($pDst)", $pB, $pA, $OP, $TMP);
+	push(@$X,shift(@$X));
+
+$code.=<<___;
+	 mov	(+8*13)($pA), $OP
+___
+	&MULSTEP_512($X, "(+8*1)($pDst)", $pB, $OP, $TMP);
+	push(@$X,shift(@$X));
+
+$code.=<<___;
+	 mov	(+8*14)($pA), $OP
+___
+	&MULSTEP_512($X, "(+8*2)($pDst)", $pB, $OP, $TMP);
+	push(@$X,shift(@$X));
+
+$code.=<<___;
+	 mov	(+8*15)($pA), $OP
+___
+	&MULSTEP_512($X, "(+8*3)($pDst)", $pB, $OP, $TMP);
+	push(@$X,shift(@$X));
+}
+
+#
+# mont_reduce(UINT64 *x,  /* 1024 bits, 16 qwords */
+#	       UINT64 *m,  /*  512 bits,  8 qwords */
+#	       MODF_2FOLD_MONT_512_C1_DATA *data,
+#             UINT64 *r)  /*  512 bits,  8 qwords */
+# Input:  x (number to be reduced): tmp16 (Implicit)
+#         m (modulus):              [pM]  (Implicit)
+#         data (reduce data):       [pData] (Implicit)
+# Output: r (result):		     Address in [red_res_addr]
+#         result also in: r9, r8, r15, r14, r13, r12, r11, r10
+
+my @X=map("%r$_",(8..15));
+
+$code.=<<___;
+.type	mont_reduce,\@abi-omnipotent
+.align	16
+mont_reduce:
+___
+
+my $STACK_DEPTH         =  8;
+	#
+	# X1 = Xh * M1 + Xl
+$code.=<<___;
+	 lea	(+$Reduce_Data_offset+$X1_offset+$STACK_DEPTH)(%rsp), %rdi			# pX1 (Dst) 769 bits, 13 qwords
+	 mov	(+$pData_offset+$STACK_DEPTH)(%rsp), %rsi			# pM1 (Bsrc) 512 bits, 8 qwords
+	 add	\$$M1, %rsi
+	 lea	(+$tmp16_offset+$STACK_DEPTH)(%rsp), %rcx			# X (Asrc) 1024 bits, 16 qwords
+
+___
+
+	&MULADD_256x512("%rdi", "%rcx", "%rsi", "%rbp", "%rbx", \@X);	# rotates @X 4 times
+	# results in r11, r10, r9, r8, r15, r14, r13, r12, X1[3:0]
+
+$code.=<<___;
+	 xor	%rax, %rax
+	# X1 += xl
+	 add	(+8*8)(%rcx), $X[4]
+	 adc	(+8*9)(%rcx), $X[5]
+	 adc	(+8*10)(%rcx), $X[6]
+	 adc	(+8*11)(%rcx), $X[7]
+	 adc	\$0, %rax
+	# X1 is now rax, r11-r8, r15-r12, tmp16[3:0]
+
+	#
+	# check for carry ;; carry stored in rax
+	 mov	$X[4], (+8*8)(%rdi)			# rdi points to X1
+	 mov	$X[5], (+8*9)(%rdi)
+	 mov	$X[6], %rbp
+	 mov	$X[7], (+8*11)(%rdi)
+
+	 mov	%rax, (+$Reduce_Data_offset+$Carries_offset+$STACK_DEPTH)(%rsp)
+
+	 mov	(+8*0)(%rdi), $X[4]
+	 mov	(+8*1)(%rdi), $X[5]
+	 mov	(+8*2)(%rdi), $X[6]
+	 mov	(+8*3)(%rdi), $X[7]
+
+	# X1 is now stored in: X1[11], rbp, X1[9:8], r15-r8
+	# rdi -> X1
+	# rsi -> M1
+
+	#
+	# X2 = Xh * M2 + Xl
+	# do first part (X2 = Xh * M2)
+	 add	\$8*10, %rdi			# rdi -> pXh ; 128 bits, 2 qwords
+				#        Xh is actually { [rdi+8*1], rbp }
+	 add	\$`$M2-$M1`, %rsi			# rsi -> M2
+	 lea	(+$Reduce_Data_offset+$X2_offset+$STACK_DEPTH)(%rsp), %rcx			# rcx -> pX2 ; 641 bits, 11 qwords
+___
+	unshift(@X,pop(@X));	unshift(@X,pop(@X));
+$code.=<<___;
+
+	 call	MULADD_128x512			# args in rcx, rdi / rbp, rsi, r15-r8
+	# result in r9, r8, r15, r14, r13, r12, r11, r10, X2[1:0]
+	 mov	(+$Reduce_Data_offset+$Carries_offset+$STACK_DEPTH)(%rsp), %rax
+
+	# X2 += Xl
+	 add	(+8*8-8*10)(%rdi), $X[6]		# (-8*10) is to adjust rdi -> Xh to Xl
+	 adc	(+8*9-8*10)(%rdi), $X[7]
+	 mov	$X[6], (+8*8)(%rcx)
+	 mov	$X[7], (+8*9)(%rcx)
+
+	 adc	%rax, %rax
+	 mov	%rax, (+$Reduce_Data_offset+$Carries_offset+$STACK_DEPTH)(%rsp)
+
+	 lea	(+$Reduce_Data_offset+$Q_offset+$STACK_DEPTH)(%rsp), %rdi			# rdi -> pQ ; 128 bits, 2 qwords
+	 add	\$`$K1-$M2`, %rsi			# rsi -> pK1 ; 128 bits, 2 qwords
+
+	# MUL_128x128t128	rdi, rcx, rsi	; Q = X2 * K1 (bottom half)
+	# B1:B0 = rsi[1:0] = K1[1:0]
+	# A1:A0 = rcx[1:0] = X2[1:0]
+	# Result = rdi[1],rbp = Q[1],rbp
+	 mov	(%rsi), %r8			# B0
+	 mov	(+8*1)(%rsi), %rbx			# B1
+
+	 mov	(%rcx), %rax			# A0
+	 mul	%r8			# B0
+	 mov	%rax, %rbp
+	 mov	%rdx, %r9
+
+	 mov	(+8*1)(%rcx), %rax			# A1
+	 mul	%r8			# B0
+	 add	%rax, %r9
+
+	 mov	(%rcx), %rax			# A0
+	 mul	%rbx			# B1
+	 add	%rax, %r9
+
+	 mov	%r9, (+8*1)(%rdi)
+	# end MUL_128x128t128
+
+	 sub	\$`$K1-$M`, %rsi
+
+	 mov	(%rcx), $X[6]
+	 mov	(+8*1)(%rcx), $X[7]			# r9:r8 = X2[1:0]
+
+	 call	MULADD_128x512			# args in rcx, rdi / rbp, rsi, r15-r8
+	# result in r9, r8, r15, r14, r13, r12, r11, r10, X2[1:0]
+
+	# load first half of m to rdx, rdi, rbx, rax
+	# moved this here for efficiency
+	 mov	(+8*0)(%rsi), %rax
+	 mov	(+8*1)(%rsi), %rbx
+	 mov	(+8*2)(%rsi), %rdi
+	 mov	(+8*3)(%rsi), %rdx
+
+	# continue with reduction
+	 mov	(+$Reduce_Data_offset+$Carries_offset+$STACK_DEPTH)(%rsp), %rbp
+
+	 add	(+8*8)(%rcx), $X[6]
+	 adc	(+8*9)(%rcx), $X[7]
+
+	#accumulate the final carry to rbp
+	 adc	%rbp, %rbp
+
+	# Add in overflow corrections: R = (X2>>128) += T[overflow]
+	# R = {r9, r8, r15, r14, ..., r10}
+	 shl	\$3, %rbp
+	 mov	(+$pData_offset+$STACK_DEPTH)(%rsp), %rcx			# rsi -> Data (and points to T)
+	 add	%rcx, %rbp			# pT ; 512 bits, 8 qwords, spread out
+
+	# rsi will be used to generate a mask after the addition
+	 xor	%rsi, %rsi
+
+	 add	(+8*8*0)(%rbp), $X[0]
+	 adc	(+8*8*1)(%rbp), $X[1]
+	 adc	(+8*8*2)(%rbp), $X[2]
+	 adc	(+8*8*3)(%rbp), $X[3]
+	 adc	(+8*8*4)(%rbp), $X[4]
+	 adc	(+8*8*5)(%rbp), $X[5]
+	 adc	(+8*8*6)(%rbp), $X[6]
+	 adc	(+8*8*7)(%rbp), $X[7]
+
+	# if there is a carry:	rsi = 0xFFFFFFFFFFFFFFFF
+	# if carry is clear:	rsi = 0x0000000000000000
+	 sbb	\$0, %rsi
+
+	# if carry is clear, subtract 0. Otherwise, subtract 256 bits of m
+	 and	%rsi, %rax
+	 and	%rsi, %rbx
+	 and	%rsi, %rdi
+	 and	%rsi, %rdx
+
+	 mov	\$1, %rbp
+	 sub	%rax, $X[0]
+	 sbb	%rbx, $X[1]
+	 sbb	%rdi, $X[2]
+	 sbb	%rdx, $X[3]
+
+	# if there is a borrow:		rbp = 0
+	# if there is no borrow:	rbp = 1
+	# this is used to save the borrows in between the first half and the 2nd half of the subtraction of m
+	 sbb	\$0, %rbp
+
+	#load second half of m to rdx, rdi, rbx, rax
+
+	 add	\$$M, %rcx
+	 mov	(+8*4)(%rcx), %rax
+	 mov	(+8*5)(%rcx), %rbx
+	 mov	(+8*6)(%rcx), %rdi
+	 mov	(+8*7)(%rcx), %rdx
+
+	# use the rsi mask as before
+	# if carry is clear, subtract 0. Otherwise, subtract 256 bits of m
+	 and	%rsi, %rax
+	 and	%rsi, %rbx
+	 and	%rsi, %rdi
+	 and	%rsi, %rdx
+
+	# if rbp = 0, there was a borrow before, it is moved to the carry flag
+	# if rbp = 1, there was not a borrow before, carry flag is cleared
+	 sub	\$1, %rbp
+
+	 sbb	%rax, $X[4]
+	 sbb	%rbx, $X[5]
+	 sbb	%rdi, $X[6]
+	 sbb	%rdx, $X[7]
+
+	# write R back to memory
+
+	 mov	(+$red_result_addr_offset+$STACK_DEPTH)(%rsp), %rsi
+	 mov	$X[0], (+8*0)(%rsi)
+	 mov	$X[1], (+8*1)(%rsi)
+	 mov	$X[2], (+8*2)(%rsi)
+	 mov	$X[3], (+8*3)(%rsi)
+	 mov	$X[4], (+8*4)(%rsi)
+	 mov	$X[5], (+8*5)(%rsi)
+	 mov	$X[6], (+8*6)(%rsi)
+	 mov	$X[7], (+8*7)(%rsi)
+
+	 ret
+.size	mont_reduce,.-mont_reduce
+___
+}}}
+
+{{{
+#MUL_512x512	MACRO	pDst, pA, pB, x7, x6, x5, x4, x3, x2, x1, x0, tmp*2
+#
+# Inputs: pDst: Destination  (1024 bits, 16 qwords)
+#         pA:   Multiplicand (512 bits, 8 qwords)
+#         pB:   Multiplicand (512 bits, 8 qwords)
+# Uses registers rax, rdx, args
+#   B operand in [pB] and also in x7...x0
+sub MUL_512x512
+{
+ my ($pDst, $pA, $pB, $x, $OP, $TMP, $pDst_o)=@_;
+ my ($pDst,  $pDst_o) = ($pDst =~ m/([^+]*)\+?(.*)?/);
+ my @X=@$x;	# make a copy
+
+$code.=<<___;
+	 mov	(+8*0)($pA), $OP
+
+	 mov	$X[0], %rax
+	 mul	$OP			# rdx:rax = %OP * [0]
+	 mov	%rax, (+$pDst_o+8*0)($pDst)
+	 mov	%rdx, $X[0]
+___
+for(my $i=1;$i<8;$i++) {
+$code.=<<___;
+	 mov	$X[$i], %rax
+	 mul	$OP			# rdx:rax = %OP * [$i]
+	 add	%rax, $X[$i-1]
+	 adc	\$0, %rdx
+	 mov	%rdx, $X[$i]
+___
+}
+
+for(my $i=1;$i<8;$i++) {
+$code.=<<___;
+	 mov	(+8*$i)($pA), $OP
+___
+
+	&MULSTEP_512(\@X, "(+$pDst_o+8*$i)($pDst)", $pB, $OP, $TMP);
+	push(@X,shift(@X));
+}
+
+$code.=<<___;
+	 mov	$X[0], (+$pDst_o+8*8)($pDst)
+	 mov	$X[1], (+$pDst_o+8*9)($pDst)
+	 mov	$X[2], (+$pDst_o+8*10)($pDst)
+	 mov	$X[3], (+$pDst_o+8*11)($pDst)
+	 mov	$X[4], (+$pDst_o+8*12)($pDst)
+	 mov	$X[5], (+$pDst_o+8*13)($pDst)
+	 mov	$X[6], (+$pDst_o+8*14)($pDst)
+	 mov	$X[7], (+$pDst_o+8*15)($pDst)
+___
+}
+
+#
+# mont_mul_a3b : subroutine to compute (Src1 * Src2) % M (all 512-bits)
+# Input:  src1: Address of source 1: rdi
+#         src2: Address of source 2: rsi
+# Output: dst:  Address of destination: [red_res_addr]
+#    src2 and result also in: r9, r8, r15, r14, r13, r12, r11, r10
+# Temp:   Clobbers [tmp16], all registers
+$code.=<<___;
+.type	mont_mul_a3b,\@abi-omnipotent
+.align	16
+mont_mul_a3b:
+	#
+	# multiply tmp = src1 * src2
+	# For multiply: dst = rcx, src1 = rdi, src2 = rsi
+	# stack depth is extra 8 from call
+___
+	&MUL_512x512("%rsp+$tmp16_offset+8", "%rdi", "%rsi", [map("%r$_",(10..15,8..9))], "%rbp", "%rbx");
+$code.=<<___;
+	#
+	# Dst = tmp % m
+	# Call reduce(tmp, m, data, dst)
+
+	# tail recursion optimization: jmp to mont_reduce and return from there
+	 jmp	mont_reduce
+	# call	mont_reduce
+	# ret
+.size	mont_mul_a3b,.-mont_mul_a3b
+___
+}}}
+
+{{{
+#SQR_512 MACRO pDest, pA, x7, x6, x5, x4, x3, x2, x1, x0, tmp*4
+#
+# Input in memory [pA] and also in x7...x0
+# Uses all argument registers plus rax and rdx
+#
+# This version computes all of the off-diagonal terms into memory,
+# and then it adds in the diagonal terms
+
+sub SQR_512
+{
+ my ($pDst, $pA, $x, $A, $tmp, $x7, $x6, $pDst_o)=@_;
+ my ($pDst,  $pDst_o) = ($pDst =~ m/([^+]*)\+?(.*)?/);
+ my @X=@$x;	# make a copy
+$code.=<<___;
+	# ------------------
+	# first pass 01...07
+	# ------------------
+	 mov	$X[0], $A
+
+	 mov	$X[1],%rax
+	 mul	$A
+	 mov	%rax, (+$pDst_o+8*1)($pDst)
+___
+for(my $i=2;$i<8;$i++) {
+$code.=<<___;
+	 mov	%rdx, $X[$i-2]
+	 mov	$X[$i],%rax
+	 mul	$A
+	 add	%rax, $X[$i-2]
+	 adc	\$0, %rdx
+___
+}
+$code.=<<___;
+	 mov	%rdx, $x7
+
+	 mov	$X[0], (+$pDst_o+8*2)($pDst)
+
+	# ------------------
+	# second pass 12...17
+	# ------------------
+
+	 mov	(+8*1)($pA), $A
+
+	 mov	(+8*2)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[1]
+	 adc	\$0, %rdx
+	 mov	$X[1], (+$pDst_o+8*3)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	(+8*3)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[2]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[2]
+	 adc	\$0, %rdx
+	 mov	$X[2], (+$pDst_o+8*4)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	(+8*4)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[3]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[3]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[0]
+	 mov	(+8*5)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[4]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[4]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[0]
+	 mov	$X[6],%rax
+	 mul	$A
+	 add	%rax, $X[5]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[5]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[0]
+	 mov	$X[7],%rax
+	 mul	$A
+	 add	%rax, $x7
+	 adc	\$0, %rdx
+	 add	$X[0], $x7
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[1]
+
+	# ------------------
+	# third pass 23...27
+	# ------------------
+	 mov	(+8*2)($pA), $A
+
+	 mov	(+8*3)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[3]
+	 adc	\$0, %rdx
+	 mov	$X[3], (+$pDst_o+8*5)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	(+8*4)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[4]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[4]
+	 adc	\$0, %rdx
+	 mov	$X[4], (+$pDst_o+8*6)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	(+8*5)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[5]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[5]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[0]
+	 mov	$X[6],%rax
+	 mul	$A
+	 add	%rax, $x7
+	 adc	\$0, %rdx
+	 add	$X[0], $x7
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[0]
+	 mov	$X[7],%rax
+	 mul	$A
+	 add	%rax, $X[1]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[1]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[2]
+
+	# ------------------
+	# fourth pass 34...37
+	# ------------------
+
+	 mov	(+8*3)($pA), $A
+
+	 mov	(+8*4)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[5]
+	 adc	\$0, %rdx
+	 mov	$X[5], (+$pDst_o+8*7)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	(+8*5)($pA),%rax
+	 mul	$A
+	 add	%rax, $x7
+	 adc	\$0, %rdx
+	 add	$X[0], $x7
+	 adc	\$0, %rdx
+	 mov	$x7, (+$pDst_o+8*8)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	$X[6],%rax
+	 mul	$A
+	 add	%rax, $X[1]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[1]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[0]
+	 mov	$X[7],%rax
+	 mul	$A
+	 add	%rax, $X[2]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[2]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[5]
+
+	# ------------------
+	# fifth pass 45...47
+	# ------------------
+	 mov	(+8*4)($pA), $A
+
+	 mov	(+8*5)($pA),%rax
+	 mul	$A
+	 add	%rax, $X[1]
+	 adc	\$0, %rdx
+	 mov	$X[1], (+$pDst_o+8*9)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	$X[6],%rax
+	 mul	$A
+	 add	%rax, $X[2]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[2]
+	 adc	\$0, %rdx
+	 mov	$X[2], (+$pDst_o+8*10)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	$X[7],%rax
+	 mul	$A
+	 add	%rax, $X[5]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[5]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $X[1]
+
+	# ------------------
+	# sixth pass 56...57
+	# ------------------
+	 mov	(+8*5)($pA), $A
+
+	 mov	$X[6],%rax
+	 mul	$A
+	 add	%rax, $X[5]
+	 adc	\$0, %rdx
+	 mov	$X[5], (+$pDst_o+8*11)($pDst)
+
+	 mov	%rdx, $X[0]
+	 mov	$X[7],%rax
+	 mul	$A
+	 add	%rax, $X[1]
+	 adc	\$0, %rdx
+	 add	$X[0], $X[1]
+	 adc	\$0, %rdx
+	 mov	$X[1], (+$pDst_o+8*12)($pDst)
+
+	 mov	%rdx, $X[2]
+
+	# ------------------
+	# seventh pass 67
+	# ------------------
+	 mov	$X[6], $A
+
+	 mov	$X[7],%rax
+	 mul	$A
+	 add	%rax, $X[2]
+	 adc	\$0, %rdx
+	 mov	$X[2], (+$pDst_o+8*13)($pDst)
+
+	 mov	%rdx, (+$pDst_o+8*14)($pDst)
+
+	# start finalize (add	in squares, and double off-terms)
+	 mov	(+$pDst_o+8*1)($pDst), $X[0]
+	 mov	(+$pDst_o+8*2)($pDst), $X[1]
+	 mov	(+$pDst_o+8*3)($pDst), $X[2]
+	 mov	(+$pDst_o+8*4)($pDst), $X[3]
+	 mov	(+$pDst_o+8*5)($pDst), $X[4]
+	 mov	(+$pDst_o+8*6)($pDst), $X[5]
+
+	 mov	(+8*3)($pA), %rax
+	 mul	%rax
+	 mov	%rax, $x6
+	 mov	%rdx, $X[6]
+
+	 add	$X[0], $X[0]
+	 adc	$X[1], $X[1]
+	 adc	$X[2], $X[2]
+	 adc	$X[3], $X[3]
+	 adc	$X[4], $X[4]
+	 adc	$X[5], $X[5]
+	 adc	\$0, $X[6]
+
+	 mov	(+8*0)($pA), %rax
+	 mul	%rax
+	 mov	%rax, (+$pDst_o+8*0)($pDst)
+	 mov	%rdx, $A
+
+	 mov	(+8*1)($pA), %rax
+	 mul	%rax
+
+	 add	$A, $X[0]
+	 adc	%rax, $X[1]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $A
+	 mov	$X[0], (+$pDst_o+8*1)($pDst)
+	 mov	$X[1], (+$pDst_o+8*2)($pDst)
+
+	 mov	(+8*2)($pA), %rax
+	 mul	%rax
+
+	 add	$A, $X[2]
+	 adc	%rax, $X[3]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $A
+
+	 mov	$X[2], (+$pDst_o+8*3)($pDst)
+	 mov	$X[3], (+$pDst_o+8*4)($pDst)
+
+	 xor	$tmp, $tmp
+	 add	$A, $X[4]
+	 adc	$x6, $X[5]
+	 adc	\$0, $tmp
+
+	 mov	$X[4], (+$pDst_o+8*5)($pDst)
+	 mov	$X[5], (+$pDst_o+8*6)($pDst)
+
+	# %%tmp has 0/1 in column 7
+	# %%A6 has a full value in column 7
+
+	 mov	(+$pDst_o+8*7)($pDst), $X[0]
+	 mov	(+$pDst_o+8*8)($pDst), $X[1]
+	 mov	(+$pDst_o+8*9)($pDst), $X[2]
+	 mov	(+$pDst_o+8*10)($pDst), $X[3]
+	 mov	(+$pDst_o+8*11)($pDst), $X[4]
+	 mov	(+$pDst_o+8*12)($pDst), $X[5]
+	 mov	(+$pDst_o+8*13)($pDst), $x6
+	 mov	(+$pDst_o+8*14)($pDst), $x7
+
+	 mov	$X[7], %rax
+	 mul	%rax
+	 mov	%rax, $X[7]
+	 mov	%rdx, $A
+
+	 add	$X[0], $X[0]
+	 adc	$X[1], $X[1]
+	 adc	$X[2], $X[2]
+	 adc	$X[3], $X[3]
+	 adc	$X[4], $X[4]
+	 adc	$X[5], $X[5]
+	 adc	$x6, $x6
+	 adc	$x7, $x7
+	 adc	\$0, $A
+
+	 add	$tmp, $X[0]
+
+	 mov	(+8*4)($pA), %rax
+	 mul	%rax
+
+	 add	$X[6], $X[0]
+	 adc	%rax, $X[1]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $tmp
+
+	 mov	$X[0], (+$pDst_o+8*7)($pDst)
+	 mov	$X[1], (+$pDst_o+8*8)($pDst)
+
+	 mov	(+8*5)($pA), %rax
+	 mul	%rax
+
+	 add	$tmp, $X[2]
+	 adc	%rax, $X[3]
+	 adc	\$0, %rdx
+
+	 mov	%rdx, $tmp
+
+	 mov	$X[2], (+$pDst_o+8*9)($pDst)
+	 mov	$X[3], (+$pDst_o+8*10)($pDst)
+
+	 mov	(+8*6)($pA), %rax
+	 mul	%rax
+
+	 add	$tmp, $X[4]
+	 adc	%rax, $X[5]
+	 adc	\$0, %rdx
+
+	 mov	$X[4], (+$pDst_o+8*11)($pDst)
+	 mov	$X[5], (+$pDst_o+8*12)($pDst)
+
+	 add	%rdx, $x6
+	 adc	$X[7], $x7
+	 adc	\$0, $A
+
+	 mov	$x6, (+$pDst_o+8*13)($pDst)
+	 mov	$x7, (+$pDst_o+8*14)($pDst)
+	 mov	$A, (+$pDst_o+8*15)($pDst)
+___
+}
+
+#
+# sqr_reduce: subroutine to compute Result = reduce(Result * Result)
+#
+# input and result also in: r9, r8, r15, r14, r13, r12, r11, r10
+#
+$code.=<<___;
+.type	sqr_reduce,\@abi-omnipotent
+.align	16
+sqr_reduce:
+	 mov	(+$pResult_offset+8)(%rsp), %rcx
+___
+	&SQR_512("%rsp+$tmp16_offset+8", "%rcx", [map("%r$_",(10..15,8..9))], "%rbx", "%rbp", "%rsi", "%rdi");
+$code.=<<___;
+	# tail recursion optimization: jmp to mont_reduce and return from there
+	 jmp	mont_reduce
+	# call	mont_reduce
+	# ret
+.size	sqr_reduce,.-sqr_reduce
+___
+}}}
+
+#
+# MAIN FUNCTION
+#
+
+#mod_exp_512(UINT64 *result, /* 512 bits, 8 qwords */
+#           UINT64 *g,   /* 512 bits, 8 qwords */
+#           UINT64 *exp, /* 512 bits, 8 qwords */
+#           struct mod_ctx_512 *data)
+
+# window size = 5
+# table size = 2^5 = 32
+#table_entries	equ	32
+#table_size	equ	table_entries * 8
+$code.=<<___;
+.globl	mod_exp_512
+.type	mod_exp_512,\@function,4
+mod_exp_512:
+	 push	%rbp
+	 push	%rbx
+	 push	%r12
+	 push	%r13
+	 push	%r14
+	 push	%r15
+
+	# adjust stack down and then align it with cache boundary
+	 mov	%rsp, %r8
+	 sub	\$$mem_size, %rsp
+	 and	\$-64, %rsp
+
+	# store previous stack pointer and arguments
+	 mov	%r8, (+$rsp_offset)(%rsp)
+	 mov	%rdi, (+$pResult_offset)(%rsp)
+	 mov	%rsi, (+$pG_offset)(%rsp)
+	 mov	%rcx, (+$pData_offset)(%rsp)
+.Lbody:
+	# transform g into montgomery space
+	# GT = reduce(g * C2) = reduce(g * (2^256))
+	# reduce expects to have the input in [tmp16]
+	 pxor	%xmm4, %xmm4
+	 movdqu	(+16*0)(%rsi), %xmm0
+	 movdqu	(+16*1)(%rsi), %xmm1
+	 movdqu	(+16*2)(%rsi), %xmm2
+	 movdqu	(+16*3)(%rsi), %xmm3
+	 movdqa	%xmm4, (+$tmp16_offset+16*0)(%rsp)
+	 movdqa	%xmm4, (+$tmp16_offset+16*1)(%rsp)
+	 movdqa	%xmm4, (+$tmp16_offset+16*6)(%rsp)
+	 movdqa	%xmm4, (+$tmp16_offset+16*7)(%rsp)
+	 movdqa	%xmm0, (+$tmp16_offset+16*2)(%rsp)
+	 movdqa	%xmm1, (+$tmp16_offset+16*3)(%rsp)
+	 movdqa	%xmm2, (+$tmp16_offset+16*4)(%rsp)
+	 movdqa	%xmm3, (+$tmp16_offset+16*5)(%rsp)
+
+	# load pExp before rdx gets blown away
+	 movdqu	(+16*0)(%rdx), %xmm0
+	 movdqu	(+16*1)(%rdx), %xmm1
+	 movdqu	(+16*2)(%rdx), %xmm2
+	 movdqu	(+16*3)(%rdx), %xmm3
+
+	 lea	(+$GT_offset)(%rsp), %rbx
+	 mov	%rbx, (+$red_result_addr_offset)(%rsp)
+	 call	mont_reduce
+
+	# Initialize tmp = C
+	 lea	(+$tmp_offset)(%rsp), %rcx
+	 xor	%rax, %rax
+	 mov	%rax, (+8*0)(%rcx)
+	 mov	%rax, (+8*1)(%rcx)
+	 mov	%rax, (+8*3)(%rcx)
+	 mov	%rax, (+8*4)(%rcx)
+	 mov	%rax, (+8*5)(%rcx)
+	 mov	%rax, (+8*6)(%rcx)
+	 mov	%rax, (+8*7)(%rcx)
+	 mov	%rax, (+$exp_offset+8*8)(%rsp)
+	 movq	\$1, (+8*2)(%rcx)
+
+	 lea	(+$garray_offset)(%rsp), %rbp
+	 mov	%rcx, %rsi			# pTmp
+	 mov	%rbp, %rdi			# Garray[][0]
+___
+
+	&swizzle("%rdi", "%rcx", "%rax", "%rbx");
+
+	# for (rax = 31; rax != 0; rax--) {
+	#     tmp = reduce(tmp * G)
+	#     swizzle(pg, tmp);
+	#     pg += 2; }
+$code.=<<___;
+	 mov	\$31, %rax
+	 mov	%rax, (+$i_offset)(%rsp)
+	 mov	%rbp, (+$pg_offset)(%rsp)
+	# rsi -> pTmp
+	 mov	%rsi, (+$red_result_addr_offset)(%rsp)
+	 mov	(+8*0)(%rsi), %r10
+	 mov	(+8*1)(%rsi), %r11
+	 mov	(+8*2)(%rsi), %r12
+	 mov	(+8*3)(%rsi), %r13
+	 mov	(+8*4)(%rsi), %r14
+	 mov	(+8*5)(%rsi), %r15
+	 mov	(+8*6)(%rsi), %r8
+	 mov	(+8*7)(%rsi), %r9
+init_loop:
+	 lea	(+$GT_offset)(%rsp), %rdi
+	 call	mont_mul_a3b
+	 lea	(+$tmp_offset)(%rsp), %rsi
+	 mov	(+$pg_offset)(%rsp), %rbp
+	 add	\$2, %rbp
+	 mov	%rbp, (+$pg_offset)(%rsp)
+	 mov	%rsi, %rcx			# rcx = rsi = addr of tmp
+___
+
+	&swizzle("%rbp", "%rcx", "%rax", "%rbx");
+$code.=<<___;
+	 mov	(+$i_offset)(%rsp), %rax
+	 sub	\$1, %rax
+	 mov	%rax, (+$i_offset)(%rsp)
+	 jne	init_loop
+
+	#
+	# Copy exponent onto stack
+	 movdqa	%xmm0, (+$exp_offset+16*0)(%rsp)
+	 movdqa	%xmm1, (+$exp_offset+16*1)(%rsp)
+	 movdqa	%xmm2, (+$exp_offset+16*2)(%rsp)
+	 movdqa	%xmm3, (+$exp_offset+16*3)(%rsp)
+
+
+	#
+	# Do exponentiation
+	# Initialize result to G[exp{511:507}]
+	 mov	(+$exp_offset+62)(%rsp), %eax
+	 mov	%rax, %rdx
+	 shr	\$11, %rax
+	 and	\$0x07FF, %edx
+	 mov	%edx, (+$exp_offset+62)(%rsp)
+	 lea	(+$garray_offset)(%rsp,%rax,2), %rsi
+	 mov	(+$pResult_offset)(%rsp), %rdx
+___
+
+	&unswizzle("%rdx", "%rsi", "%rbp", "%rbx", "%rax");
+
+	#
+	# Loop variables
+	# rcx = [loop_idx] = index: 510-5 to 0 by 5
+$code.=<<___;
+	 movq	\$505, (+$loop_idx_offset)(%rsp)
+
+	 mov	(+$pResult_offset)(%rsp), %rcx
+	 mov	%rcx, (+$red_result_addr_offset)(%rsp)
+	 mov	(+8*0)(%rcx), %r10
+	 mov	(+8*1)(%rcx), %r11
+	 mov	(+8*2)(%rcx), %r12
+	 mov	(+8*3)(%rcx), %r13
+	 mov	(+8*4)(%rcx), %r14
+	 mov	(+8*5)(%rcx), %r15
+	 mov	(+8*6)(%rcx), %r8
+	 mov	(+8*7)(%rcx), %r9
+	 jmp	sqr_2
+
+main_loop_a3b:
+	 call	sqr_reduce
+	 call	sqr_reduce
+	 call	sqr_reduce
+sqr_2:
+	 call	sqr_reduce
+	 call	sqr_reduce
+
+	#
+	# Do multiply, first look up proper value in Garray
+	 mov	(+$loop_idx_offset)(%rsp), %rcx			# bit index
+	 mov	%rcx, %rax
+	 shr	\$4, %rax			# rax is word pointer
+	 mov	(+$exp_offset)(%rsp,%rax,2), %edx
+	 and	\$15, %rcx
+	 shrq	%cl, %rdx
+	 and	\$0x1F, %rdx
+
+	 lea	(+$garray_offset)(%rsp,%rdx,2), %rsi
+	 lea	(+$tmp_offset)(%rsp), %rdx
+	 mov	%rdx, %rdi
+___
+
+	&unswizzle("%rdx", "%rsi", "%rbp", "%rbx", "%rax");
+	# rdi = tmp = pG
+
+	#
+	# Call mod_mul_a1(pDst,  pSrc1, pSrc2, pM, pData)
+	#                 result result pG     M   Data
+$code.=<<___;
+	 mov	(+$pResult_offset)(%rsp), %rsi
+	 call	mont_mul_a3b
+
+	#
+	# finish loop
+	 mov	(+$loop_idx_offset)(%rsp), %rcx
+	 sub	\$5, %rcx
+	 mov	%rcx, (+$loop_idx_offset)(%rsp)
+	 jge	main_loop_a3b
+
+	#
+
+end_main_loop_a3b:
+	# transform result out of Montgomery space
+	# result = reduce(result)
+	 mov	(+$pResult_offset)(%rsp), %rdx
+	 pxor	%xmm4, %xmm4
+	 movdqu	(+16*0)(%rdx), %xmm0
+	 movdqu	(+16*1)(%rdx), %xmm1
+	 movdqu	(+16*2)(%rdx), %xmm2
+	 movdqu	(+16*3)(%rdx), %xmm3
+	 movdqa	%xmm4, (+$tmp16_offset+16*4)(%rsp)
+	 movdqa	%xmm4, (+$tmp16_offset+16*5)(%rsp)
+	 movdqa	%xmm4, (+$tmp16_offset+16*6)(%rsp)
+	 movdqa	%xmm4, (+$tmp16_offset+16*7)(%rsp)
+	 movdqa	%xmm0, (+$tmp16_offset+16*0)(%rsp)
+	 movdqa	%xmm1, (+$tmp16_offset+16*1)(%rsp)
+	 movdqa	%xmm2, (+$tmp16_offset+16*2)(%rsp)
+	 movdqa	%xmm3, (+$tmp16_offset+16*3)(%rsp)
+	 call	mont_reduce
+
+	# If result > m, subract m
+	# load result into r15:r8
+	 mov	(+$pResult_offset)(%rsp), %rax
+	 mov	(+8*0)(%rax), %r8
+	 mov	(+8*1)(%rax), %r9
+	 mov	(+8*2)(%rax), %r10
+	 mov	(+8*3)(%rax), %r11
+	 mov	(+8*4)(%rax), %r12
+	 mov	(+8*5)(%rax), %r13
+	 mov	(+8*6)(%rax), %r14
+	 mov	(+8*7)(%rax), %r15
+
+	# subtract m
+	 mov	(+$pData_offset)(%rsp), %rbx
+	 add	\$$M, %rbx
+
+	 sub	(+8*0)(%rbx), %r8
+	 sbb	(+8*1)(%rbx), %r9
+	 sbb	(+8*2)(%rbx), %r10
+	 sbb	(+8*3)(%rbx), %r11
+	 sbb	(+8*4)(%rbx), %r12
+	 sbb	(+8*5)(%rbx), %r13
+	 sbb	(+8*6)(%rbx), %r14
+	 sbb	(+8*7)(%rbx), %r15
+
+	# if Carry is clear, replace result with difference
+	 mov	(+8*0)(%rax), %rsi
+	 mov	(+8*1)(%rax), %rdi
+	 mov	(+8*2)(%rax), %rcx
+	 mov	(+8*3)(%rax), %rdx
+	 cmovnc	%r8, %rsi
+	 cmovnc	%r9, %rdi
+	 cmovnc	%r10, %rcx
+	 cmovnc	%r11, %rdx
+	 mov	%rsi, (+8*0)(%rax)
+	 mov	%rdi, (+8*1)(%rax)
+	 mov	%rcx, (+8*2)(%rax)
+	 mov	%rdx, (+8*3)(%rax)
+
+	 mov	(+8*4)(%rax), %rsi
+	 mov	(+8*5)(%rax), %rdi
+	 mov	(+8*6)(%rax), %rcx
+	 mov	(+8*7)(%rax), %rdx
+	 cmovnc	%r12, %rsi
+	 cmovnc	%r13, %rdi
+	 cmovnc	%r14, %rcx
+	 cmovnc	%r15, %rdx
+	 mov	%rsi, (+8*4)(%rax)
+	 mov	%rdi, (+8*5)(%rax)
+	 mov	%rcx, (+8*6)(%rax)
+	 mov	%rdx, (+8*7)(%rax)
+
+	 mov	(+$rsp_offset)(%rsp), %rsi
+	 mov	0(%rsi),%r15
+	 mov	8(%rsi),%r14
+	 mov	16(%rsi),%r13
+	 mov	24(%rsi),%r12
+	 mov	32(%rsi),%rbx
+	 mov	40(%rsi),%rbp
+	 lea	48(%rsi),%rsp
+.Lepilogue:
+	 ret
+.size mod_exp_512, . - mod_exp_512
+___
+
+if ($win64) {
+# EXCEPTION_DISPOSITION handler (EXCEPTION_RECORD *rec,ULONG64 frame,
+#		CONTEXT *context,DISPATCHER_CONTEXT *disp)
+my $rec="%rcx";
+my $frame="%rdx";
+my $context="%r8";
+my $disp="%r9";
+
+$code.=<<___;
+.extern	__imp_RtlVirtualUnwind
+.type	mod_exp_512_se_handler,\@abi-omnipotent
+.align	16
+mod_exp_512_se_handler:
+	push	%rsi
+	push	%rdi
+	push	%rbx
+	push	%rbp
+	push	%r12
+	push	%r13
+	push	%r14
+	push	%r15
+	pushfq
+	sub	\$64,%rsp
+
+	mov	120($context),%rax	# pull context->Rax
+	mov	248($context),%rbx	# pull context->Rip
+
+	lea	.Lbody(%rip),%r10
+	cmp	%r10,%rbx		# context->Rip<prologue label
+	jb	.Lin_prologue
+
+	mov	152($context),%rax	# pull context->Rsp
+
+	lea	.Lepilogue(%rip),%r10
+	cmp	%r10,%rbx		# context->Rip>=epilogue label
+	jae	.Lin_prologue
+
+	mov	$rsp_offset(%rax),%rax	# pull saved Rsp
+
+	mov	32(%rax),%rbx
+	mov	40(%rax),%rbp
+	mov	24(%rax),%r12
+	mov	16(%rax),%r13
+	mov	8(%rax),%r14
+	mov	0(%rax),%r15
+	lea	48(%rax),%rax
+	mov	%rbx,144($context)	# restore context->Rbx
+	mov	%rbp,160($context)	# restore context->Rbp
+	mov	%r12,216($context)	# restore context->R12
+	mov	%r13,224($context)	# restore context->R13
+	mov	%r14,232($context)	# restore context->R14
+	mov	%r15,240($context)	# restore context->R15
+
+.Lin_prologue:
+	mov	8(%rax),%rdi
+	mov	16(%rax),%rsi
+	mov	%rax,152($context)	# restore context->Rsp
+	mov	%rsi,168($context)	# restore context->Rsi
+	mov	%rdi,176($context)	# restore context->Rdi
+
+	mov	40($disp),%rdi		# disp->ContextRecord
+	mov	$context,%rsi		# context
+	mov	\$154,%ecx		# sizeof(CONTEXT)
+	.long	0xa548f3fc		# cld; rep movsq
+
+	mov	$disp,%rsi
+	xor	%rcx,%rcx		# arg1, UNW_FLAG_NHANDLER
+	mov	8(%rsi),%rdx		# arg2, disp->ImageBase
+	mov	0(%rsi),%r8		# arg3, disp->ControlPc
+	mov	16(%rsi),%r9		# arg4, disp->FunctionEntry
+	mov	40(%rsi),%r10		# disp->ContextRecord
+	lea	56(%rsi),%r11		# &disp->HandlerData
+	lea	24(%rsi),%r12		# &disp->EstablisherFrame
+	mov	%r10,32(%rsp)		# arg5
+	mov	%r11,40(%rsp)		# arg6
+	mov	%r12,48(%rsp)		# arg7
+	mov	%rcx,56(%rsp)		# arg8, (NULL)
+	call	*__imp_RtlVirtualUnwind(%rip)
+
+	mov	\$1,%eax		# ExceptionContinueSearch
+	add	\$64,%rsp
+	popfq
+	pop	%r15
+	pop	%r14
+	pop	%r13
+	pop	%r12
+	pop	%rbp
+	pop	%rbx
+	pop	%rdi
+	pop	%rsi
+	ret
+.size	mod_exp_512_se_handler,.-mod_exp_512_se_handler
+
+.section	.pdata
+.align	4
+	.rva	.LSEH_begin_mod_exp_512
+	.rva	.LSEH_end_mod_exp_512
+	.rva	.LSEH_info_mod_exp_512
+
+.section	.xdata
+.align	8
+.LSEH_info_mod_exp_512:
+	.byte	9,0,0,0
+	.rva	mod_exp_512_se_handler
+___
+}
+
+sub reg_part {
+my ($reg,$conv)=@_;
+    if ($reg =~ /%r[0-9]+/)	{ $reg .= $conv; }
+    elsif ($conv eq "b")	{ $reg =~ s/%[er]([^x]+)x?/%$1l/;	}
+    elsif ($conv eq "w")	{ $reg =~ s/%[er](.+)/%$1/;		}
+    elsif ($conv eq "d")	{ $reg =~ s/%[er](.+)/%e$1/;		}
+    return $reg;
+}
+
+$code =~ s/(%[a-z0-9]+)#([bwd])/reg_part($1,$2)/gem;
+$code =~ s/\`([^\`]*)\`/eval $1/gem;
+$code =~ s/(\(\+[^)]+\))/eval $1/gem;
+print $code;
+close STDOUT;