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1#!/usr/bin/env perl
2
3# ====================================================================
4# Written by Andy Polyakov <appro@fy.chalmers.se> for the OpenSSL
5# project. The module is, however, dual licensed under OpenSSL and
6# CRYPTOGAMS licenses depending on where you obtain it. For further
7# details see http://www.openssl.org/~appro/cryptogams/.
8# ====================================================================
9
10# October 2005
11#
12# This is a "teaser" code, as it can be improved in several ways...
13# First of all non-SSE2 path should be implemented (yes, for now it
14# performs Montgomery multiplication/convolution only on SSE2-capable
15# CPUs such as P4, others fall down to original code). Then inner loop
16# can be unrolled and modulo-scheduled to improve ILP and possibly
17# moved to 128-bit XMM register bank (though it would require input
18# rearrangement and/or increase bus bandwidth utilization). Dedicated
19# squaring procedure should give further performance improvement...
20# Yet, for being draft, the code improves rsa512 *sign* benchmark by
21# 110%(!), rsa1024 one - by 70% and rsa4096 - by 20%:-)
22
23# December 2006
24#
25# Modulo-scheduling SSE2 loops results in further 15-20% improvement.
26# Integer-only code [being equipped with dedicated squaring procedure]
27# gives ~40% on rsa512 sign benchmark...
28
29$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
30push(@INC,"${dir}","${dir}../../perlasm");
31require "x86asm.pl";
32
33&asm_init($ARGV[0],$0);
34
35$sse2=0;
36for (@ARGV) { $sse2=1 if (/-DOPENSSL_IA32_SSE2/); }
37
38&external_label("OPENSSL_ia32cap_P") if ($sse2);
39
40&function_begin("bn_mul_mont");
41
42$i="edx";
43$j="ecx";
44$ap="esi";	$tp="esi";		# overlapping variables!!!
45$rp="edi";	$bp="edi";		# overlapping variables!!!
46$np="ebp";
47$num="ebx";
48
49$_num=&DWP(4*0,"esp");			# stack top layout
50$_rp=&DWP(4*1,"esp");
51$_ap=&DWP(4*2,"esp");
52$_bp=&DWP(4*3,"esp");
53$_np=&DWP(4*4,"esp");
54$_n0=&DWP(4*5,"esp");	$_n0q=&QWP(4*5,"esp");
55$_sp=&DWP(4*6,"esp");
56$_bpend=&DWP(4*7,"esp");
57$frame=32;				# size of above frame rounded up to 16n
58
59	&xor	("eax","eax");
60	&mov	("edi",&wparam(5));	# int num
61	&cmp	("edi",4);
62	&jl	(&label("just_leave"));
63
64	&lea	("esi",&wparam(0));	# put aside pointer to argument block
65	&lea	("edx",&wparam(1));	# load ap
66	&mov	("ebp","esp");		# saved stack pointer!
67	&add	("edi",2);		# extra two words on top of tp
68	&neg	("edi");
69	&lea	("esp",&DWP(-$frame,"esp","edi",4));	# alloca($frame+4*(num+2))
70	&neg	("edi");
71
72	# minimize cache contention by arraning 2K window between stack
73	# pointer and ap argument [np is also position sensitive vector,
74	# but it's assumed to be near ap, as it's allocated at ~same
75	# time].
76	&mov	("eax","esp");
77	&sub	("eax","edx");
78	&and	("eax",2047);
79	&sub	("esp","eax");		# this aligns sp and ap modulo 2048
80
81	&xor	("edx","esp");
82	&and	("edx",2048);
83	&xor	("edx",2048);
84	&sub	("esp","edx");		# this splits them apart modulo 4096
85
86	&and	("esp",-64);		# align to cache line
87
88	################################# load argument block...
89	&mov	("eax",&DWP(0*4,"esi"));# BN_ULONG *rp
90	&mov	("ebx",&DWP(1*4,"esi"));# const BN_ULONG *ap
91	&mov	("ecx",&DWP(2*4,"esi"));# const BN_ULONG *bp
92	&mov	("edx",&DWP(3*4,"esi"));# const BN_ULONG *np
93	&mov	("esi",&DWP(4*4,"esi"));# const BN_ULONG *n0
94	#&mov	("edi",&DWP(5*4,"esi"));# int num
95
96	&mov	("esi",&DWP(0,"esi"));	# pull n0[0]
97	&mov	($_rp,"eax");		# ... save a copy of argument block
98	&mov	($_ap,"ebx");
99	&mov	($_bp,"ecx");
100	&mov	($_np,"edx");
101	&mov	($_n0,"esi");
102	&lea	($num,&DWP(-3,"edi"));	# num=num-1 to assist modulo-scheduling
103	#&mov	($_num,$num);		# redundant as $num is not reused
104	&mov	($_sp,"ebp");		# saved stack pointer!
105
106if($sse2) {
107$acc0="mm0";	# mmx register bank layout
108$acc1="mm1";
109$car0="mm2";
110$car1="mm3";
111$mul0="mm4";
112$mul1="mm5";
113$temp="mm6";
114$mask="mm7";
115
116	&picmeup("eax","OPENSSL_ia32cap_P");
117	&bt	(&DWP(0,"eax"),26);
118	&jnc	(&label("non_sse2"));
119
120	&mov	("eax",-1);
121	&movd	($mask,"eax");		# mask 32 lower bits
122
123	&mov	($ap,$_ap);		# load input pointers
124	&mov	($bp,$_bp);
125	&mov	($np,$_np);
126
127	&xor	($i,$i);		# i=0
128	&xor	($j,$j);		# j=0
129
130	&movd	($mul0,&DWP(0,$bp));		# bp[0]
131	&movd	($mul1,&DWP(0,$ap));		# ap[0]
132	&movd	($car1,&DWP(0,$np));		# np[0]
133
134	&pmuludq($mul1,$mul0);			# ap[0]*bp[0]
135	&movq	($car0,$mul1);
136	&movq	($acc0,$mul1);			# I wish movd worked for
137	&pand	($acc0,$mask);			# inter-register transfers
138
139	&pmuludq($mul1,$_n0q);			# *=n0
140
141	&pmuludq($car1,$mul1);			# "t[0]"*np[0]*n0
142	&paddq	($car1,$acc0);
143
144	&movd	($acc1,&DWP(4,$np));		# np[1]
145	&movd	($acc0,&DWP(4,$ap));		# ap[1]
146
147	&psrlq	($car0,32);
148	&psrlq	($car1,32);
149
150	&inc	($j);				# j++
151&set_label("1st",16);
152	&pmuludq($acc0,$mul0);			# ap[j]*bp[0]
153	&pmuludq($acc1,$mul1);			# np[j]*m1
154	&paddq	($car0,$acc0);			# +=c0
155	&paddq	($car1,$acc1);			# +=c1
156
157	&movq	($acc0,$car0);
158	&pand	($acc0,$mask);
159	&movd	($acc1,&DWP(4,$np,$j,4));	# np[j+1]
160	&paddq	($car1,$acc0);			# +=ap[j]*bp[0];
161	&movd	($acc0,&DWP(4,$ap,$j,4));	# ap[j+1]
162	&psrlq	($car0,32);
163	&movd	(&DWP($frame-4,"esp",$j,4),$car1);	# tp[j-1]=
164	&psrlq	($car1,32);
165
166	&lea	($j,&DWP(1,$j));
167	&cmp	($j,$num);
168	&jl	(&label("1st"));
169
170	&pmuludq($acc0,$mul0);			# ap[num-1]*bp[0]
171	&pmuludq($acc1,$mul1);			# np[num-1]*m1
172	&paddq	($car0,$acc0);			# +=c0
173	&paddq	($car1,$acc1);			# +=c1
174
175	&movq	($acc0,$car0);
176	&pand	($acc0,$mask);
177	&paddq	($car1,$acc0);			# +=ap[num-1]*bp[0];
178	&movd	(&DWP($frame-4,"esp",$j,4),$car1);	# tp[num-2]=
179
180	&psrlq	($car0,32);
181	&psrlq	($car1,32);
182
183	&paddq	($car1,$car0);
184	&movq	(&QWP($frame,"esp",$num,4),$car1);	# tp[num].tp[num-1]
185
186	&inc	($i);				# i++
187&set_label("outer");
188	&xor	($j,$j);			# j=0
189
190	&movd	($mul0,&DWP(0,$bp,$i,4));	# bp[i]
191	&movd	($mul1,&DWP(0,$ap));		# ap[0]
192	&movd	($temp,&DWP($frame,"esp"));	# tp[0]
193	&movd	($car1,&DWP(0,$np));		# np[0]
194	&pmuludq($mul1,$mul0);			# ap[0]*bp[i]
195
196	&paddq	($mul1,$temp);			# +=tp[0]
197	&movq	($acc0,$mul1);
198	&movq	($car0,$mul1);
199	&pand	($acc0,$mask);
200
201	&pmuludq($mul1,$_n0q);			# *=n0
202
203	&pmuludq($car1,$mul1);
204	&paddq	($car1,$acc0);
205
206	&movd	($temp,&DWP($frame+4,"esp"));	# tp[1]
207	&movd	($acc1,&DWP(4,$np));		# np[1]
208	&movd	($acc0,&DWP(4,$ap));		# ap[1]
209
210	&psrlq	($car0,32);
211	&psrlq	($car1,32);
212	&paddq	($car0,$temp);			# +=tp[1]
213
214	&inc	($j);				# j++
215	&dec	($num);
216&set_label("inner");
217	&pmuludq($acc0,$mul0);			# ap[j]*bp[i]
218	&pmuludq($acc1,$mul1);			# np[j]*m1
219	&paddq	($car0,$acc0);			# +=c0
220	&paddq	($car1,$acc1);			# +=c1
221
222	&movq	($acc0,$car0);
223	&movd	($temp,&DWP($frame+4,"esp",$j,4));# tp[j+1]
224	&pand	($acc0,$mask);
225	&movd	($acc1,&DWP(4,$np,$j,4));	# np[j+1]
226	&paddq	($car1,$acc0);			# +=ap[j]*bp[i]+tp[j]
227	&movd	($acc0,&DWP(4,$ap,$j,4));	# ap[j+1]
228	&psrlq	($car0,32);
229	&movd	(&DWP($frame-4,"esp",$j,4),$car1);# tp[j-1]=
230	&psrlq	($car1,32);
231	&paddq	($car0,$temp);			# +=tp[j+1]
232
233	&dec	($num);
234	&lea	($j,&DWP(1,$j));		# j++
235	&jnz	(&label("inner"));
236
237	&mov	($num,$j);
238	&pmuludq($acc0,$mul0);			# ap[num-1]*bp[i]
239	&pmuludq($acc1,$mul1);			# np[num-1]*m1
240	&paddq	($car0,$acc0);			# +=c0
241	&paddq	($car1,$acc1);			# +=c1
242
243	&movq	($acc0,$car0);
244	&pand	($acc0,$mask);
245	&paddq	($car1,$acc0);			# +=ap[num-1]*bp[i]+tp[num-1]
246	&movd	(&DWP($frame-4,"esp",$j,4),$car1);	# tp[num-2]=
247	&psrlq	($car0,32);
248	&psrlq	($car1,32);
249
250	&movd	($temp,&DWP($frame+4,"esp",$num,4));	# += tp[num]
251	&paddq	($car1,$car0);
252	&paddq	($car1,$temp);
253	&movq	(&QWP($frame,"esp",$num,4),$car1);	# tp[num].tp[num-1]
254
255	&lea	($i,&DWP(1,$i));		# i++
256	&cmp	($i,$num);
257	&jle	(&label("outer"));
258
259	&emms	();				# done with mmx bank
260	&jmp	(&label("common_tail"));
261
262&set_label("non_sse2",16);
263}
264
265if (0) {
266	&mov	("esp",$_sp);
267	&xor	("eax","eax");	# signal "not fast enough [yet]"
268	&jmp	(&label("just_leave"));
269	# While the below code provides competitive performance for
270	# all key lengthes on modern Intel cores, it's still more
271	# than 10% slower for 4096-bit key elsewhere:-( "Competitive"
272	# means compared to the original integer-only assembler.
273	# 512-bit RSA sign is better by ~40%, but that's about all
274	# one can say about all CPUs...
275} else {
276$inp="esi";	# integer path uses these registers differently
277$word="edi";
278$carry="ebp";
279
280	&mov	($inp,$_ap);
281	&lea	($carry,&DWP(1,$num));
282	&mov	($word,$_bp);
283	&xor	($j,$j);				# j=0
284	&mov	("edx",$inp);
285	&and	($carry,1);				# see if num is even
286	&sub	("edx",$word);				# see if ap==bp
287	&lea	("eax",&DWP(4,$word,$num,4));		# &bp[num]
288	&or	($carry,"edx");
289	&mov	($word,&DWP(0,$word));			# bp[0]
290	&jz	(&label("bn_sqr_mont"));
291	&mov	($_bpend,"eax");
292	&mov	("eax",&DWP(0,$inp));
293	&xor	("edx","edx");
294
295&set_label("mull",16);
296	&mov	($carry,"edx");
297	&mul	($word);				# ap[j]*bp[0]
298	&add	($carry,"eax");
299	&lea	($j,&DWP(1,$j));
300	&adc	("edx",0);
301	&mov	("eax",&DWP(0,$inp,$j,4));		# ap[j+1]
302	&cmp	($j,$num);
303	&mov	(&DWP($frame-4,"esp",$j,4),$carry);	# tp[j]=
304	&jl	(&label("mull"));
305
306	&mov	($carry,"edx");
307	&mul	($word);				# ap[num-1]*bp[0]
308	 &mov	($word,$_n0);
309	&add	("eax",$carry);
310	 &mov	($inp,$_np);
311	&adc	("edx",0);
312	 &imul	($word,&DWP($frame,"esp"));		# n0*tp[0]
313
314	&mov	(&DWP($frame,"esp",$num,4),"eax");	# tp[num-1]=
315	&xor	($j,$j);
316	&mov	(&DWP($frame+4,"esp",$num,4),"edx");	# tp[num]=
317	&mov	(&DWP($frame+8,"esp",$num,4),$j);	# tp[num+1]=
318
319	&mov	("eax",&DWP(0,$inp));			# np[0]
320	&mul	($word);				# np[0]*m
321	&add	("eax",&DWP($frame,"esp"));		# +=tp[0]
322	&mov	("eax",&DWP(4,$inp));			# np[1]
323	&adc	("edx",0);
324	&inc	($j);
325
326	&jmp	(&label("2ndmadd"));
327
328&set_label("1stmadd",16);
329	&mov	($carry,"edx");
330	&mul	($word);				# ap[j]*bp[i]
331	&add	($carry,&DWP($frame,"esp",$j,4));	# +=tp[j]
332	&lea	($j,&DWP(1,$j));
333	&adc	("edx",0);
334	&add	($carry,"eax");
335	&mov	("eax",&DWP(0,$inp,$j,4));		# ap[j+1]
336	&adc	("edx",0);
337	&cmp	($j,$num);
338	&mov	(&DWP($frame-4,"esp",$j,4),$carry);	# tp[j]=
339	&jl	(&label("1stmadd"));
340
341	&mov	($carry,"edx");
342	&mul	($word);				# ap[num-1]*bp[i]
343	&add	("eax",&DWP($frame,"esp",$num,4));	# +=tp[num-1]
344	 &mov	($word,$_n0);
345	&adc	("edx",0);
346	 &mov	($inp,$_np);
347	&add	($carry,"eax");
348	&adc	("edx",0);
349	 &imul	($word,&DWP($frame,"esp"));		# n0*tp[0]
350
351	&xor	($j,$j);
352	&add	("edx",&DWP($frame+4,"esp",$num,4));	# carry+=tp[num]
353	&mov	(&DWP($frame,"esp",$num,4),$carry);	# tp[num-1]=
354	&adc	($j,0);
355	 &mov	("eax",&DWP(0,$inp));			# np[0]
356	&mov	(&DWP($frame+4,"esp",$num,4),"edx");	# tp[num]=
357	&mov	(&DWP($frame+8,"esp",$num,4),$j);	# tp[num+1]=
358
359	&mul	($word);				# np[0]*m
360	&add	("eax",&DWP($frame,"esp"));		# +=tp[0]
361	&mov	("eax",&DWP(4,$inp));			# np[1]
362	&adc	("edx",0);
363	&mov	($j,1);
364
365&set_label("2ndmadd",16);
366	&mov	($carry,"edx");
367	&mul	($word);				# np[j]*m
368	&add	($carry,&DWP($frame,"esp",$j,4));	# +=tp[j]
369	&lea	($j,&DWP(1,$j));
370	&adc	("edx",0);
371	&add	($carry,"eax");
372	&mov	("eax",&DWP(0,$inp,$j,4));		# np[j+1]
373	&adc	("edx",0);
374	&cmp	($j,$num);
375	&mov	(&DWP($frame-8,"esp",$j,4),$carry);	# tp[j-1]=
376	&jl	(&label("2ndmadd"));
377
378	&mov	($carry,"edx");
379	&mul	($word);				# np[j]*m
380	&add	($carry,&DWP($frame,"esp",$num,4));	# +=tp[num-1]
381	&adc	("edx",0);
382	&add	($carry,"eax");
383	&adc	("edx",0);
384	&mov	(&DWP($frame-4,"esp",$num,4),$carry);	# tp[num-2]=
385
386	&xor	("eax","eax");
387	 &mov	($j,$_bp);				# &bp[i]
388	&add	("edx",&DWP($frame+4,"esp",$num,4));	# carry+=tp[num]
389	&adc	("eax",&DWP($frame+8,"esp",$num,4));	# +=tp[num+1]
390	 &lea	($j,&DWP(4,$j));
391	&mov	(&DWP($frame,"esp",$num,4),"edx");	# tp[num-1]=
392	 &cmp	($j,$_bpend);
393	&mov	(&DWP($frame+4,"esp",$num,4),"eax");	# tp[num]=
394	&je	(&label("common_tail"));
395
396	&mov	($word,&DWP(0,$j));			# bp[i+1]
397	&mov	($inp,$_ap);
398	&mov	($_bp,$j);				# &bp[++i]
399	&xor	($j,$j);
400	&xor	("edx","edx");
401	&mov	("eax",&DWP(0,$inp));
402	&jmp	(&label("1stmadd"));
403
404&set_label("bn_sqr_mont",16);
405$sbit=$num;
406	&mov	($_num,$num);
407	&mov	($_bp,$j);				# i=0
408
409	&mov	("eax",$word);				# ap[0]
410	&mul	($word);				# ap[0]*ap[0]
411	&mov	(&DWP($frame,"esp"),"eax");		# tp[0]=
412	&mov	($sbit,"edx");
413	&shr	("edx",1);
414	&and	($sbit,1);
415	&inc	($j);
416&set_label("sqr",16);
417	&mov	("eax",&DWP(0,$inp,$j,4));		# ap[j]
418	&mov	($carry,"edx");
419	&mul	($word);				# ap[j]*ap[0]
420	&add	("eax",$carry);
421	&lea	($j,&DWP(1,$j));
422	&adc	("edx",0);
423	&lea	($carry,&DWP(0,$sbit,"eax",2));
424	&shr	("eax",31);
425	&cmp	($j,$_num);
426	&mov	($sbit,"eax");
427	&mov	(&DWP($frame-4,"esp",$j,4),$carry);	# tp[j]=
428	&jl	(&label("sqr"));
429
430	&mov	("eax",&DWP(0,$inp,$j,4));		# ap[num-1]
431	&mov	($carry,"edx");
432	&mul	($word);				# ap[num-1]*ap[0]
433	&add	("eax",$carry);
434	 &mov	($word,$_n0);
435	&adc	("edx",0);
436	 &mov	($inp,$_np);
437	&lea	($carry,&DWP(0,$sbit,"eax",2));
438	 &imul	($word,&DWP($frame,"esp"));		# n0*tp[0]
439	&shr	("eax",31);
440	&mov	(&DWP($frame,"esp",$j,4),$carry);	# tp[num-1]=
441
442	&lea	($carry,&DWP(0,"eax","edx",2));
443	 &mov	("eax",&DWP(0,$inp));			# np[0]
444	&shr	("edx",31);
445	&mov	(&DWP($frame+4,"esp",$j,4),$carry);	# tp[num]=
446	&mov	(&DWP($frame+8,"esp",$j,4),"edx");	# tp[num+1]=
447
448	&mul	($word);				# np[0]*m
449	&add	("eax",&DWP($frame,"esp"));		# +=tp[0]
450	&mov	($num,$j);
451	&adc	("edx",0);
452	&mov	("eax",&DWP(4,$inp));			# np[1]
453	&mov	($j,1);
454
455&set_label("3rdmadd",16);
456	&mov	($carry,"edx");
457	&mul	($word);				# np[j]*m
458	&add	($carry,&DWP($frame,"esp",$j,4));	# +=tp[j]
459	&adc	("edx",0);
460	&add	($carry,"eax");
461	&mov	("eax",&DWP(4,$inp,$j,4));		# np[j+1]
462	&adc	("edx",0);
463	&mov	(&DWP($frame-4,"esp",$j,4),$carry);	# tp[j-1]=
464
465	&mov	($carry,"edx");
466	&mul	($word);				# np[j+1]*m
467	&add	($carry,&DWP($frame+4,"esp",$j,4));	# +=tp[j+1]
468	&lea	($j,&DWP(2,$j));
469	&adc	("edx",0);
470	&add	($carry,"eax");
471	&mov	("eax",&DWP(0,$inp,$j,4));		# np[j+2]
472	&adc	("edx",0);
473	&cmp	($j,$num);
474	&mov	(&DWP($frame-8,"esp",$j,4),$carry);	# tp[j]=
475	&jl	(&label("3rdmadd"));
476
477	&mov	($carry,"edx");
478	&mul	($word);				# np[j]*m
479	&add	($carry,&DWP($frame,"esp",$num,4));	# +=tp[num-1]
480	&adc	("edx",0);
481	&add	($carry,"eax");
482	&adc	("edx",0);
483	&mov	(&DWP($frame-4,"esp",$num,4),$carry);	# tp[num-2]=
484
485	&mov	($j,$_bp);				# i
486	&xor	("eax","eax");
487	&mov	($inp,$_ap);
488	&add	("edx",&DWP($frame+4,"esp",$num,4));	# carry+=tp[num]
489	&adc	("eax",&DWP($frame+8,"esp",$num,4));	# +=tp[num+1]
490	&mov	(&DWP($frame,"esp",$num,4),"edx");	# tp[num-1]=
491	&cmp	($j,$num);
492	&mov	(&DWP($frame+4,"esp",$num,4),"eax");	# tp[num]=
493	&je	(&label("common_tail"));
494
495	&mov	($word,&DWP(4,$inp,$j,4));		# ap[i]
496	&lea	($j,&DWP(1,$j));
497	&mov	("eax",$word);
498	&mov	($_bp,$j);				# ++i
499	&mul	($word);				# ap[i]*ap[i]
500	&add	("eax",&DWP($frame,"esp",$j,4));	# +=tp[i]
501	&adc	("edx",0);
502	&mov	(&DWP($frame,"esp",$j,4),"eax");	# tp[i]=
503	&xor	($carry,$carry);
504	&cmp	($j,$num);
505	&lea	($j,&DWP(1,$j));
506	&je	(&label("sqrlast"));
507
508	&mov	($sbit,"edx");				# zaps $num
509	&shr	("edx",1);
510	&and	($sbit,1);
511&set_label("sqradd",16);
512	&mov	("eax",&DWP(0,$inp,$j,4));		# ap[j]
513	&mov	($carry,"edx");
514	&mul	($word);				# ap[j]*ap[i]
515	&add	("eax",$carry);
516	&lea	($carry,&DWP(0,"eax","eax"));
517	&adc	("edx",0);
518	&shr	("eax",31);
519	&add	($carry,&DWP($frame,"esp",$j,4));	# +=tp[j]
520	&lea	($j,&DWP(1,$j));
521	&adc	("eax",0);
522	&add	($carry,$sbit);
523	&adc	("eax",0);
524	&cmp	($j,$_num);
525	&mov	(&DWP($frame-4,"esp",$j,4),$carry);	# tp[j]=
526	&mov	($sbit,"eax");
527	&jle	(&label("sqradd"));
528
529	&mov	($carry,"edx");
530	&add	("edx","edx");
531	&shr	($carry,31);
532	&add	("edx",$sbit);
533	&adc	($carry,0);
534&set_label("sqrlast");
535	&mov	($word,$_n0);
536	&mov	($inp,$_np);
537	&imul	($word,&DWP($frame,"esp"));		# n0*tp[0]
538
539	&add	("edx",&DWP($frame,"esp",$j,4));	# +=tp[num]
540	&mov	("eax",&DWP(0,$inp));			# np[0]
541	&adc	($carry,0);
542	&mov	(&DWP($frame,"esp",$j,4),"edx");	# tp[num]=
543	&mov	(&DWP($frame+4,"esp",$j,4),$carry);	# tp[num+1]=
544
545	&mul	($word);				# np[0]*m
546	&add	("eax",&DWP($frame,"esp"));		# +=tp[0]
547	&lea	($num,&DWP(-1,$j));
548	&adc	("edx",0);
549	&mov	($j,1);
550	&mov	("eax",&DWP(4,$inp));			# np[1]
551
552	&jmp	(&label("3rdmadd"));
553}
554
555&set_label("common_tail",16);
556	&mov	($np,$_np);			# load modulus pointer
557	&mov	($rp,$_rp);			# load result pointer
558	&lea	($tp,&DWP($frame,"esp"));	# [$ap and $bp are zapped]
559
560	&mov	("eax",&DWP(0,$tp));		# tp[0]
561	&mov	($j,$num);			# j=num-1
562	&xor	($i,$i);			# i=0 and clear CF!
563
564&set_label("sub",16);
565	&sbb	("eax",&DWP(0,$np,$i,4));
566	&mov	(&DWP(0,$rp,$i,4),"eax");	# rp[i]=tp[i]-np[i]
567	&dec	($j);				# doesn't affect CF!
568	&mov	("eax",&DWP(4,$tp,$i,4));	# tp[i+1]
569	&lea	($i,&DWP(1,$i));		# i++
570	&jge	(&label("sub"));
571
572	&sbb	("eax",0);			# handle upmost overflow bit
573	&and	($tp,"eax");
574	&not	("eax");
575	&mov	($np,$rp);
576	&and	($np,"eax");
577	&or	($tp,$np);			# tp=carry?tp:rp
578
579&set_label("copy",16);				# copy or in-place refresh
580	&mov	("eax",&DWP(0,$tp,$num,4));
581	&mov	(&DWP(0,$rp,$num,4),"eax");	# rp[i]=tp[i]
582	&mov	(&DWP($frame,"esp",$num,4),$j);	# zap temporary vector
583	&dec	($num);
584	&jge	(&label("copy"));
585
586	&mov	("esp",$_sp);		# pull saved stack pointer
587	&mov	("eax",1);
588&set_label("just_leave");
589&function_end("bn_mul_mont");
590
591&asciz("Montgomery Multiplication for x86, CRYPTOGAMS by <appro\@openssl.org>");
592
593&asm_finish();
594