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boringssl/crypto/aes/asm/vpaes-x86.pl

vpaes-x86.pl 27 KiB
Исходник Обычный вид История

Inital import. Initial fork from f2d678e6e89b6508147086610e985d4e8416e867 (1.0.2 beta). (This change contains substantial changes from the original and effectively starts a new history.)
10 лет назад
x86[_64] assembly pack: add Silvermont performance data. (Imported from upstream's 9dd6240201fdd9a9a0ce2aa66df04c174d08cf99) Change-Id: Ie0f6f876e06ac28c717ec949565f6b0126166b30
10 лет назад
Inital import. Initial fork from f2d678e6e89b6508147086610e985d4e8416e867 (1.0.2 beta). (This change contains substantial changes from the original and effectively starts a new history.)
10 лет назад
Switch perlasm calling convention. Depending on architecture, perlasm differed on which one or both of: perl foo.pl flavor output.S perl foo.pl flavor > output.S Upstream has now unified on the first form after making a number of changes to their files (the second does not even work for their x86 files anymore). Sync those portions of our perlasm scripts with upstream and update CMakeLists.txt and generate_build_files.py per the new convention. This imports various commits like this one: 184bc45f683c76531d7e065b6553ca9086564576 (this was done by taking a diff, so I don't have the full list) Confirmed that generate_build_files.py sees no change. BUG=14 Change-Id: Id2fb5b8bc2a7369d077221b5df9a6947d41f50d2 Reviewed-on: https://boringssl-review.googlesource.com/8518 Reviewed-by: Adam Langley <agl@google.com>
8 лет назад
Inital import. Initial fork from f2d678e6e89b6508147086610e985d4e8416e867 (1.0.2 beta). (This change contains substantial changes from the original and effectively starts a new history.)
10 лет назад
Switch perlasm calling convention. Depending on architecture, perlasm differed on which one or both of: perl foo.pl flavor output.S perl foo.pl flavor > output.S Upstream has now unified on the first form after making a number of changes to their files (the second does not even work for their x86 files anymore). Sync those portions of our perlasm scripts with upstream and update CMakeLists.txt and generate_build_files.py per the new convention. This imports various commits like this one: 184bc45f683c76531d7e065b6553ca9086564576 (this was done by taking a diff, so I don't have the full list) Confirmed that generate_build_files.py sees no change. BUG=14 Change-Id: Id2fb5b8bc2a7369d077221b5df9a6947d41f50d2 Reviewed-on: https://boringssl-review.googlesource.com/8518 Reviewed-by: Adam Langley <agl@google.com>
8 лет назад
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  1. #!/usr/bin/env perl

  2. 

  3. ######################################################################

  4. ## Constant-time SSSE3 AES core implementation.

  5. ## version 0.1

  6. ##

  7. ## By Mike Hamburg (Stanford University), 2009

  8. ## Public domain.

  9. ##

  10. ## For details see http://shiftleft.org/papers/vector_aes/ and

  11. ## http://crypto.stanford.edu/vpaes/.

  12. 

  13. ######################################################################

  14. # September 2011.

  15. #

  16. # Port vpaes-x86_64.pl as 32-bit "almost" drop-in replacement for

  17. # aes-586.pl. "Almost" refers to the fact that AES_cbc_encrypt

  18. # doesn't handle partial vectors (doesn't have to if called from

  19. # EVP only). "Drop-in" implies that this module doesn't share key

  20. # schedule structure with the original nor does it make assumption

  21. # about its alignment...

  22. #

  23. # Performance summary. aes-586.pl column lists large-block CBC

  24. # encrypt/decrypt/with-hyper-threading-off(*) results in cycles per

  25. # byte processed with 128-bit key, and vpaes-x86.pl column - [also

  26. # large-block CBC] encrypt/decrypt.

  27. #

  28. #		aes-586.pl		vpaes-x86.pl

  29. #

  30. # Core 2(**)	28.1/41.4/18.3		21.9/25.2(***)

  31. # Nehalem	27.9/40.4/18.1		10.2/11.9

  32. # Atom		70.7/92.1/60.1		61.1/75.4(***)

  33. # Silvermont	45.4/62.9/24.1		49.2/61.1(***)

  34. #

  35. # (*)	"Hyper-threading" in the context refers rather to cache shared

  36. #	among multiple cores, than to specifically Intel HTT. As vast

  37. #	majority of contemporary cores share cache, slower code path

  38. #	is common place. In other words "with-hyper-threading-off"

  39. #	results are presented mostly for reference purposes.

  40. #

  41. # (**)	"Core 2" refers to initial 65nm design, a.k.a. Conroe.

  42. #

  43. # (***)	Less impressive improvement on Core 2 and Atom is due to slow

  44. #	pshufb,	yet it's respectable +28%/64%  improvement on Core 2

  45. #	and +15% on Atom (as implied, over "hyper-threading-safe"

  46. #	code path).

  47. #

  48. #						<appro@openssl.org>

  49. 

  50. $0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;

  51. push(@INC,"${dir}","${dir}../../perlasm");

  52. require "x86asm.pl";

  53. 

  54. $output = pop;

  55. open OUT,">$output";

  56. *STDOUT=*OUT;

  57. 

  58. &asm_init($ARGV[0],"vpaes-x86.pl",$x86only = $ARGV[$#ARGV] eq "386");

  59. 

  60. $PREFIX="vpaes";

  61. 

  62. my  ($round, $base, $magic, $key, $const, $inp, $out)=

  63.     ("eax",  "ebx", "ecx",  "edx","ebp",  "esi","edi");

  64. 

  65. &static_label("_vpaes_consts");

  66. &static_label("_vpaes_schedule_low_round");

  67. 

  68. &set_label("_vpaes_consts",64);

  69. $k_inv=-0x30;		# inv, inva

  70. 	&data_word(0x0D080180,0x0E05060F,0x0A0B0C02,0x04070309);

  71. 	&data_word(0x0F0B0780,0x01040A06,0x02050809,0x030D0E0C);

  72. 

  73. $k_s0F=-0x10;		# s0F

  74. 	&data_word(0x0F0F0F0F,0x0F0F0F0F,0x0F0F0F0F,0x0F0F0F0F);

  75. 

  76. $k_ipt=0x00;		# input transform (lo, hi)

  77. 	&data_word(0x5A2A7000,0xC2B2E898,0x52227808,0xCABAE090);

  78. 	&data_word(0x317C4D00,0x4C01307D,0xB0FDCC81,0xCD80B1FC);

  79. 

  80. $k_sb1=0x20;		# sb1u, sb1t

  81. 	&data_word(0xCB503E00,0xB19BE18F,0x142AF544,0xA5DF7A6E);

  82. 	&data_word(0xFAE22300,0x3618D415,0x0D2ED9EF,0x3BF7CCC1);

  83. $k_sb2=0x40;		# sb2u, sb2t

  84. 	&data_word(0x0B712400,0xE27A93C6,0xBC982FCD,0x5EB7E955);

  85. 	&data_word(0x0AE12900,0x69EB8840,0xAB82234A,0xC2A163C8);

  86. $k_sbo=0x60;		# sbou, sbot

  87. 	&data_word(0x6FBDC700,0xD0D26D17,0xC502A878,0x15AABF7A);

  88. 	&data_word(0x5FBB6A00,0xCFE474A5,0x412B35FA,0x8E1E90D1);

  89. 

  90. $k_mc_forward=0x80;	# mc_forward

  91. 	&data_word(0x00030201,0x04070605,0x080B0A09,0x0C0F0E0D);

  92. 	&data_word(0x04070605,0x080B0A09,0x0C0F0E0D,0x00030201);

  93. 	&data_word(0x080B0A09,0x0C0F0E0D,0x00030201,0x04070605);

  94. 	&data_word(0x0C0F0E0D,0x00030201,0x04070605,0x080B0A09);

  95. 

  96. $k_mc_backward=0xc0;	# mc_backward

  97. 	&data_word(0x02010003,0x06050407,0x0A09080B,0x0E0D0C0F);

  98. 	&data_word(0x0E0D0C0F,0x02010003,0x06050407,0x0A09080B);

  99. 	&data_word(0x0A09080B,0x0E0D0C0F,0x02010003,0x06050407);

  100. 	&data_word(0x06050407,0x0A09080B,0x0E0D0C0F,0x02010003);

  101. 

  102. $k_sr=0x100;		# sr

  103. 	&data_word(0x03020100,0x07060504,0x0B0A0908,0x0F0E0D0C);

  104. 	&data_word(0x0F0A0500,0x030E0904,0x07020D08,0x0B06010C);

  105. 	&data_word(0x0B020900,0x0F060D04,0x030A0108,0x070E050C);

  106. 	&data_word(0x070A0D00,0x0B0E0104,0x0F020508,0x0306090C);

  107. 

  108. $k_rcon=0x140;		# rcon

  109. 	&data_word(0xAF9DEEB6,0x1F8391B9,0x4D7C7D81,0x702A9808);

  110. 

  111. $k_s63=0x150;		# s63: all equal to 0x63 transformed

  112. 	&data_word(0x5B5B5B5B,0x5B5B5B5B,0x5B5B5B5B,0x5B5B5B5B);

  113. 

  114. $k_opt=0x160;		# output transform

  115. 	&data_word(0xD6B66000,0xFF9F4929,0xDEBE6808,0xF7974121);

  116. 	&data_word(0x50BCEC00,0x01EDBD51,0xB05C0CE0,0xE10D5DB1);

  117. 

  118. $k_deskew=0x180;	# deskew tables: inverts the sbox's "skew"

  119. 	&data_word(0x47A4E300,0x07E4A340,0x5DBEF91A,0x1DFEB95A);

  120. 	&data_word(0x83EA6900,0x5F36B5DC,0xF49D1E77,0x2841C2AB);

  121. ##

  122. ##  Decryption stuff

  123. ##  Key schedule constants

  124. ##

  125. $k_dksd=0x1a0;		# decryption key schedule: invskew x*D

  126. 	&data_word(0xA3E44700,0xFEB91A5D,0x5A1DBEF9,0x0740E3A4);

  127. 	&data_word(0xB5368300,0x41C277F4,0xAB289D1E,0x5FDC69EA);

  128. $k_dksb=0x1c0;		# decryption key schedule: invskew x*B

  129. 	&data_word(0x8550D500,0x9A4FCA1F,0x1CC94C99,0x03D65386);

  130. 	&data_word(0xB6FC4A00,0x115BEDA7,0x7E3482C8,0xD993256F);

  131. $k_dkse=0x1e0;		# decryption key schedule: invskew x*E + 0x63

  132. 	&data_word(0x1FC9D600,0xD5031CCA,0x994F5086,0x53859A4C);

  133. 	&data_word(0x4FDC7BE8,0xA2319605,0x20B31487,0xCD5EF96A);

  134. $k_dks9=0x200;		# decryption key schedule: invskew x*9

  135. 	&data_word(0x7ED9A700,0xB6116FC8,0x82255BFC,0x4AED9334);

  136. 	&data_word(0x27143300,0x45765162,0xE9DAFDCE,0x8BB89FAC);

  137. 

  138. ##

  139. ##  Decryption stuff

  140. ##  Round function constants

  141. ##

  142. $k_dipt=0x220;		# decryption input transform

  143. 	&data_word(0x0B545F00,0x0F505B04,0x114E451A,0x154A411E);

  144. 	&data_word(0x60056500,0x86E383E6,0xF491F194,0x12771772);

  145. 

  146. $k_dsb9=0x240;		# decryption sbox output *9*u, *9*t

  147. 	&data_word(0x9A86D600,0x851C0353,0x4F994CC9,0xCAD51F50);

  148. 	&data_word(0xECD74900,0xC03B1789,0xB2FBA565,0x725E2C9E);

  149. $k_dsbd=0x260;		# decryption sbox output *D*u, *D*t

  150. 	&data_word(0xE6B1A200,0x7D57CCDF,0x882A4439,0xF56E9B13);

  151. 	&data_word(0x24C6CB00,0x3CE2FAF7,0x15DEEFD3,0x2931180D);

  152. $k_dsbb=0x280;		# decryption sbox output *B*u, *B*t

  153. 	&data_word(0x96B44200,0xD0226492,0xB0F2D404,0x602646F6);

  154. 	&data_word(0xCD596700,0xC19498A6,0x3255AA6B,0xF3FF0C3E);

  155. $k_dsbe=0x2a0;		# decryption sbox output *E*u, *E*t

  156. 	&data_word(0x26D4D000,0x46F29296,0x64B4F6B0,0x22426004);

  157. 	&data_word(0xFFAAC100,0x0C55A6CD,0x98593E32,0x9467F36B);

  158. $k_dsbo=0x2c0;		# decryption sbox final output

  159. 	&data_word(0x7EF94000,0x1387EA53,0xD4943E2D,0xC7AA6DB9);

  160. 	&data_word(0x93441D00,0x12D7560F,0xD8C58E9C,0xCA4B8159);

  161. &asciz	("Vector Permutation AES for x86/SSSE3, Mike Hamburg (Stanford University)");

  162. &align	(64);

  163. 

  164. &function_begin_B("_vpaes_preheat");

  165. 	&add	($const,&DWP(0,"esp"));

  166. 	&movdqa	("xmm7",&QWP($k_inv,$const));

  167. 	&movdqa	("xmm6",&QWP($k_s0F,$const));

  168. 	&ret	();

  169. &function_end_B("_vpaes_preheat");

  170. 

  171. ##

  172. ##  _aes_encrypt_core

  173. ##

  174. ##  AES-encrypt %xmm0.

  175. ##

  176. ##  Inputs:

  177. ##     %xmm0 = input

  178. ##     %xmm6-%xmm7 as in _vpaes_preheat

  179. ##    (%edx) = scheduled keys

  180. ##

  181. ##  Output in %xmm0

  182. ##  Clobbers  %xmm1-%xmm5, %eax, %ebx, %ecx, %edx

  183. ##

  184. ##

  185. &function_begin_B("_vpaes_encrypt_core");

  186. 	&mov	($magic,16);

  187. 	&mov	($round,&DWP(240,$key));

  188. 	&movdqa	("xmm1","xmm6")

  189. 	&movdqa	("xmm2",&QWP($k_ipt,$const));

  190. 	&pandn	("xmm1","xmm0");

  191. 	&pand	("xmm0","xmm6");

  192. 	&movdqu	("xmm5",&QWP(0,$key));

  193. 	&pshufb	("xmm2","xmm0");

  194. 	&movdqa	("xmm0",&QWP($k_ipt+16,$const));

  195. 	&pxor	("xmm2","xmm5");

  196. 	&psrld	("xmm1",4);

  197. 	&add	($key,16);

  198. 	&pshufb	("xmm0","xmm1");

  199. 	&lea	($base,&DWP($k_mc_backward,$const));

  200. 	&pxor	("xmm0","xmm2");

  201. 	&jmp	(&label("enc_entry"));

  202. 

  203. 

  204. &set_label("enc_loop",16);

  205. 	# middle of middle round

  206. 	&movdqa	("xmm4",&QWP($k_sb1,$const));	# 4 : sb1u

  207. 	&movdqa	("xmm0",&QWP($k_sb1+16,$const));# 0 : sb1t

  208. 	&pshufb	("xmm4","xmm2");		# 4 = sb1u

  209. 	&pshufb	("xmm0","xmm3");		# 0 = sb1t

  210. 	&pxor	("xmm4","xmm5");		# 4 = sb1u + k

  211. 	&movdqa	("xmm5",&QWP($k_sb2,$const));	# 4 : sb2u

  212. 	&pxor	("xmm0","xmm4");		# 0 = A

  213. 	&movdqa	("xmm1",&QWP(-0x40,$base,$magic));# .Lk_mc_forward[]

  214. 	&pshufb	("xmm5","xmm2");		# 4 = sb2u

  215. 	&movdqa	("xmm2",&QWP($k_sb2+16,$const));# 2 : sb2t

  216. 	&movdqa	("xmm4",&QWP(0,$base,$magic));	# .Lk_mc_backward[]

  217. 	&pshufb	("xmm2","xmm3");		# 2 = sb2t

  218. 	&movdqa	("xmm3","xmm0");		# 3 = A

  219. 	&pxor	("xmm2","xmm5");		# 2 = 2A

  220. 	&pshufb	("xmm0","xmm1");		# 0 = B

  221. 	&add	($key,16);			# next key

  222. 	&pxor	("xmm0","xmm2");		# 0 = 2A+B

  223. 	&pshufb	("xmm3","xmm4");		# 3 = D

  224. 	&add	($magic,16);			# next mc

  225. 	&pxor	("xmm3","xmm0");		# 3 = 2A+B+D

  226. 	&pshufb	("xmm0","xmm1");		# 0 = 2B+C

  227. 	&and	($magic,0x30);			# ... mod 4

  228. 	&sub	($round,1);			# nr--

  229. 	&pxor	("xmm0","xmm3");		# 0 = 2A+3B+C+D

  230. 

  231. &set_label("enc_entry");

  232. 	# top of round

  233. 	&movdqa	("xmm1","xmm6");		# 1 : i

  234. 	&movdqa	("xmm5",&QWP($k_inv+16,$const));# 2 : a/k

  235. 	&pandn	("xmm1","xmm0");		# 1 = i<<4

  236. 	&psrld	("xmm1",4);			# 1 = i

  237. 	&pand	("xmm0","xmm6");		# 0 = k

  238. 	&pshufb	("xmm5","xmm0");		# 2 = a/k

  239. 	&movdqa	("xmm3","xmm7");		# 3 : 1/i

  240. 	&pxor	("xmm0","xmm1");		# 0 = j

  241. 	&pshufb	("xmm3","xmm1");		# 3 = 1/i

  242. 	&movdqa	("xmm4","xmm7");		# 4 : 1/j

  243. 	&pxor	("xmm3","xmm5");		# 3 = iak = 1/i + a/k

  244. 	&pshufb	("xmm4","xmm0");		# 4 = 1/j

  245. 	&movdqa	("xmm2","xmm7");		# 2 : 1/iak

  246. 	&pxor	("xmm4","xmm5");		# 4 = jak = 1/j + a/k

  247. 	&pshufb	("xmm2","xmm3");		# 2 = 1/iak

  248. 	&movdqa	("xmm3","xmm7");		# 3 : 1/jak

  249. 	&pxor	("xmm2","xmm0");		# 2 = io

  250. 	&pshufb	("xmm3","xmm4");		# 3 = 1/jak

  251. 	&movdqu	("xmm5",&QWP(0,$key));

  252. 	&pxor	("xmm3","xmm1");		# 3 = jo

  253. 	&jnz	(&label("enc_loop"));

  254. 

  255. 	# middle of last round

  256. 	&movdqa	("xmm4",&QWP($k_sbo,$const));	# 3 : sbou      .Lk_sbo

  257. 	&movdqa	("xmm0",&QWP($k_sbo+16,$const));# 3 : sbot      .Lk_sbo+16

  258. 	&pshufb	("xmm4","xmm2");		# 4 = sbou

  259. 	&pxor	("xmm4","xmm5");		# 4 = sb1u + k

  260. 	&pshufb	("xmm0","xmm3");		# 0 = sb1t

  261. 	&movdqa	("xmm1",&QWP(0x40,$base,$magic));# .Lk_sr[]

  262. 	&pxor	("xmm0","xmm4");		# 0 = A

  263. 	&pshufb	("xmm0","xmm1");

  264. 	&ret	();

  265. &function_end_B("_vpaes_encrypt_core");

  266. 

  267. ##

  268. ##  Decryption core

  269. ##

  270. ##  Same API as encryption core.

  271. ##

  272. &function_begin_B("_vpaes_decrypt_core");

  273. 	&lea	($base,&DWP($k_dsbd,$const));

  274. 	&mov	($round,&DWP(240,$key));

  275. 	&movdqa	("xmm1","xmm6");

  276. 	&movdqa	("xmm2",&QWP($k_dipt-$k_dsbd,$base));

  277. 	&pandn	("xmm1","xmm0");

  278. 	&mov	($magic,$round);

  279. 	&psrld	("xmm1",4)

  280. 	&movdqu	("xmm5",&QWP(0,$key));

  281. 	&shl	($magic,4);

  282. 	&pand	("xmm0","xmm6");

  283. 	&pshufb	("xmm2","xmm0");

  284. 	&movdqa	("xmm0",&QWP($k_dipt-$k_dsbd+16,$base));

  285. 	&xor	($magic,0x30);

  286. 	&pshufb	("xmm0","xmm1");

  287. 	&and	($magic,0x30);

  288. 	&pxor	("xmm2","xmm5");

  289. 	&movdqa	("xmm5",&QWP($k_mc_forward+48,$const));

  290. 	&pxor	("xmm0","xmm2");

  291. 	&add	($key,16);

  292. 	&lea	($magic,&DWP($k_sr-$k_dsbd,$base,$magic));

  293. 	&jmp	(&label("dec_entry"));

  294. 

  295. &set_label("dec_loop",16);

  296. ##

  297. ##  Inverse mix columns

  298. ##

  299. 	&movdqa	("xmm4",&QWP(-0x20,$base));	# 4 : sb9u

  300. 	&movdqa	("xmm1",&QWP(-0x10,$base));	# 0 : sb9t

  301. 	&pshufb	("xmm4","xmm2");		# 4 = sb9u

  302. 	&pshufb	("xmm1","xmm3");		# 0 = sb9t

  303. 	&pxor	("xmm0","xmm4");

  304. 	&movdqa	("xmm4",&QWP(0,$base));		# 4 : sbdu

  305. 	&pxor	("xmm0","xmm1");		# 0 = ch

  306. 	&movdqa	("xmm1",&QWP(0x10,$base));	# 0 : sbdt

  307. 

  308. 	&pshufb	("xmm4","xmm2");		# 4 = sbdu

  309. 	&pshufb	("xmm0","xmm5");		# MC ch

  310. 	&pshufb	("xmm1","xmm3");		# 0 = sbdt

  311. 	&pxor	("xmm0","xmm4");		# 4 = ch

  312. 	&movdqa	("xmm4",&QWP(0x20,$base));	# 4 : sbbu

  313. 	&pxor	("xmm0","xmm1");		# 0 = ch

  314. 	&movdqa	("xmm1",&QWP(0x30,$base));	# 0 : sbbt

  315. 

  316. 	&pshufb	("xmm4","xmm2");		# 4 = sbbu

  317. 	&pshufb	("xmm0","xmm5");		# MC ch

  318. 	&pshufb	("xmm1","xmm3");		# 0 = sbbt

  319. 	&pxor	("xmm0","xmm4");		# 4 = ch

  320. 	&movdqa	("xmm4",&QWP(0x40,$base));	# 4 : sbeu

  321. 	&pxor	("xmm0","xmm1");		# 0 = ch

  322. 	&movdqa	("xmm1",&QWP(0x50,$base));	# 0 : sbet

  323. 

  324. 	&pshufb	("xmm4","xmm2");		# 4 = sbeu

  325. 	&pshufb	("xmm0","xmm5");		# MC ch

  326. 	&pshufb	("xmm1","xmm3");		# 0 = sbet

  327. 	&pxor	("xmm0","xmm4");		# 4 = ch

  328. 	&add	($key,16);			# next round key

  329. 	&palignr("xmm5","xmm5",12);

  330. 	&pxor	("xmm0","xmm1");		# 0 = ch

  331. 	&sub	($round,1);			# nr--

  332. 

  333. &set_label("dec_entry");

  334. 	# top of round

  335. 	&movdqa	("xmm1","xmm6");		# 1 : i

  336. 	&movdqa	("xmm2",&QWP($k_inv+16,$const));# 2 : a/k

  337. 	&pandn	("xmm1","xmm0");		# 1 = i<<4

  338. 	&pand	("xmm0","xmm6");		# 0 = k

  339. 	&psrld	("xmm1",4);			# 1 = i

  340. 	&pshufb	("xmm2","xmm0");		# 2 = a/k

  341. 	&movdqa	("xmm3","xmm7");		# 3 : 1/i

  342. 	&pxor	("xmm0","xmm1");		# 0 = j

  343. 	&pshufb	("xmm3","xmm1");		# 3 = 1/i

  344. 	&movdqa	("xmm4","xmm7");		# 4 : 1/j

  345. 	&pxor	("xmm3","xmm2");		# 3 = iak = 1/i + a/k

  346. 	&pshufb	("xmm4","xmm0");		# 4 = 1/j

  347. 	&pxor	("xmm4","xmm2");		# 4 = jak = 1/j + a/k

  348. 	&movdqa	("xmm2","xmm7");		# 2 : 1/iak

  349. 	&pshufb	("xmm2","xmm3");		# 2 = 1/iak

  350. 	&movdqa	("xmm3","xmm7");		# 3 : 1/jak

  351. 	&pxor	("xmm2","xmm0");		# 2 = io

  352. 	&pshufb	("xmm3","xmm4");		# 3 = 1/jak

  353. 	&movdqu	("xmm0",&QWP(0,$key));

  354. 	&pxor	("xmm3","xmm1");		# 3 = jo

  355. 	&jnz	(&label("dec_loop"));

  356. 

  357. 	# middle of last round

  358. 	&movdqa	("xmm4",&QWP(0x60,$base));	# 3 : sbou

  359. 	&pshufb	("xmm4","xmm2");		# 4 = sbou

  360. 	&pxor	("xmm4","xmm0");		# 4 = sb1u + k

  361. 	&movdqa	("xmm0",&QWP(0x70,$base));	# 0 : sbot

  362. 	&movdqa	("xmm2",&QWP(0,$magic));

  363. 	&pshufb	("xmm0","xmm3");		# 0 = sb1t

  364. 	&pxor	("xmm0","xmm4");		# 0 = A

  365. 	&pshufb	("xmm0","xmm2");

  366. 	&ret	();

  367. &function_end_B("_vpaes_decrypt_core");

  368. 

  369. ########################################################

  370. ##                                                    ##

  371. ##                  AES key schedule                  ##

  372. ##                                                    ##

  373. ########################################################

  374. &function_begin_B("_vpaes_schedule_core");

  375. 	&add	($const,&DWP(0,"esp"));

  376. 	&movdqu	("xmm0",&QWP(0,$inp));		# load key (unaligned)

  377. 	&movdqa	("xmm2",&QWP($k_rcon,$const));	# load rcon

  378. 

  379. 	# input transform

  380. 	&movdqa	("xmm3","xmm0");

  381. 	&lea	($base,&DWP($k_ipt,$const));

  382. 	&movdqa	(&QWP(4,"esp"),"xmm2");		# xmm8

  383. 	&call	("_vpaes_schedule_transform");

  384. 	&movdqa	("xmm7","xmm0");

  385. 

  386. 	&test	($out,$out);

  387. 	&jnz	(&label("schedule_am_decrypting"));

  388. 

  389. 	# encrypting, output zeroth round key after transform

  390. 	&movdqu	(&QWP(0,$key),"xmm0");

  391. 	&jmp	(&label("schedule_go"));

  392. 

  393. &set_label("schedule_am_decrypting");

  394. 	# decrypting, output zeroth round key after shiftrows

  395. 	&movdqa	("xmm1",&QWP($k_sr,$const,$magic));

  396. 	&pshufb	("xmm3","xmm1");

  397. 	&movdqu	(&QWP(0,$key),"xmm3");

  398. 	&xor	($magic,0x30);

  399. 

  400. &set_label("schedule_go");

  401. 	&cmp	($round,192);

  402. 	&ja	(&label("schedule_256"));

  403. 	&je	(&label("schedule_192"));

  404. 	# 128: fall though

  405. 

  406. ##

  407. ##  .schedule_128

  408. ##

  409. ##  128-bit specific part of key schedule.

  410. ##

  411. ##  This schedule is really simple, because all its parts

  412. ##  are accomplished by the subroutines.

  413. ##

  414. &set_label("schedule_128");

  415. 	&mov	($round,10);

  416. 

  417. &set_label("loop_schedule_128");

  418. 	&call	("_vpaes_schedule_round");

  419. 	&dec	($round);

  420. 	&jz	(&label("schedule_mangle_last"));

  421. 	&call	("_vpaes_schedule_mangle");	# write output

  422. 	&jmp	(&label("loop_schedule_128"));

  423. 

  424. ##

  425. ##  .aes_schedule_192

  426. ##

  427. ##  192-bit specific part of key schedule.

  428. ##

  429. ##  The main body of this schedule is the same as the 128-bit

  430. ##  schedule, but with more smearing.  The long, high side is

  431. ##  stored in %xmm7 as before, and the short, low side is in

  432. ##  the high bits of %xmm6.

  433. ##

  434. ##  This schedule is somewhat nastier, however, because each

  435. ##  round produces 192 bits of key material, or 1.5 round keys.

  436. ##  Therefore, on each cycle we do 2 rounds and produce 3 round

  437. ##  keys.

  438. ##

  439. &set_label("schedule_192",16);

  440. 	&movdqu	("xmm0",&QWP(8,$inp));		# load key part 2 (very unaligned)

  441. 	&call	("_vpaes_schedule_transform");	# input transform	

  442. 	&movdqa	("xmm6","xmm0");		# save short part

  443. 	&pxor	("xmm4","xmm4");		# clear 4

  444. 	&movhlps("xmm6","xmm4");		# clobber low side with zeros

  445. 	&mov	($round,4);

  446. 

  447. &set_label("loop_schedule_192");

  448. 	&call	("_vpaes_schedule_round");

  449. 	&palignr("xmm0","xmm6",8);

  450. 	&call	("_vpaes_schedule_mangle");	# save key n

  451. 	&call	("_vpaes_schedule_192_smear");

  452. 	&call	("_vpaes_schedule_mangle");	# save key n+1

  453. 	&call	("_vpaes_schedule_round");

  454. 	&dec	($round);

  455. 	&jz	(&label("schedule_mangle_last"));

  456. 	&call	("_vpaes_schedule_mangle");	# save key n+2

  457. 	&call	("_vpaes_schedule_192_smear");

  458. 	&jmp	(&label("loop_schedule_192"));

  459. 

  460. ##

  461. ##  .aes_schedule_256

  462. ##

  463. ##  256-bit specific part of key schedule.

  464. ##

  465. ##  The structure here is very similar to the 128-bit

  466. ##  schedule, but with an additional "low side" in

  467. ##  %xmm6.  The low side's rounds are the same as the

  468. ##  high side's, except no rcon and no rotation.

  469. ##

  470. &set_label("schedule_256",16);

  471. 	&movdqu	("xmm0",&QWP(16,$inp));		# load key part 2 (unaligned)

  472. 	&call	("_vpaes_schedule_transform");	# input transform	

  473. 	&mov	($round,7);

  474. 

  475. &set_label("loop_schedule_256");

  476. 	&call	("_vpaes_schedule_mangle");	# output low result

  477. 	&movdqa	("xmm6","xmm0");		# save cur_lo in xmm6

  478. 

  479. 	# high round

  480. 	&call	("_vpaes_schedule_round");

  481. 	&dec	($round);

  482. 	&jz	(&label("schedule_mangle_last"));

  483. 	&call	("_vpaes_schedule_mangle");	

  484. 

  485. 	# low round. swap xmm7 and xmm6

  486. 	&pshufd	("xmm0","xmm0",0xFF);

  487. 	&movdqa	(&QWP(20,"esp"),"xmm7");

  488. 	&movdqa	("xmm7","xmm6");

  489. 	&call	("_vpaes_schedule_low_round");

  490. 	&movdqa	("xmm7",&QWP(20,"esp"));

  491. 

  492. 	&jmp	(&label("loop_schedule_256"));

  493. 

  494. ##

  495. ##  .aes_schedule_mangle_last

  496. ##

  497. ##  Mangler for last round of key schedule

  498. ##  Mangles %xmm0

  499. ##    when encrypting, outputs out(%xmm0) ^ 63

  500. ##    when decrypting, outputs unskew(%xmm0)

  501. ##

  502. ##  Always called right before return... jumps to cleanup and exits

  503. ##

  504. &set_label("schedule_mangle_last",16);

  505. 	# schedule last round key from xmm0

  506. 	&lea	($base,&DWP($k_deskew,$const));

  507. 	&test	($out,$out);

  508. 	&jnz	(&label("schedule_mangle_last_dec"));

  509. 

  510. 	# encrypting

  511. 	&movdqa	("xmm1",&QWP($k_sr,$const,$magic));

  512. 	&pshufb	("xmm0","xmm1");		# output permute

  513. 	&lea	($base,&DWP($k_opt,$const));	# prepare to output transform

  514. 	&add	($key,32);

  515. 

  516. &set_label("schedule_mangle_last_dec");

  517. 	&add	($key,-16);

  518. 	&pxor	("xmm0",&QWP($k_s63,$const));

  519. 	&call	("_vpaes_schedule_transform");	# output transform

  520. 	&movdqu	(&QWP(0,$key),"xmm0");		# save last key

  521. 

  522. 	# cleanup

  523. 	&pxor	("xmm0","xmm0");

  524. 	&pxor	("xmm1","xmm1");

  525. 	&pxor	("xmm2","xmm2");

  526. 	&pxor	("xmm3","xmm3");

  527. 	&pxor	("xmm4","xmm4");

  528. 	&pxor	("xmm5","xmm5");

  529. 	&pxor	("xmm6","xmm6");

  530. 	&pxor	("xmm7","xmm7");

  531. 	&ret	();

  532. &function_end_B("_vpaes_schedule_core");

  533. 

  534. ##

  535. ##  .aes_schedule_192_smear

  536. ##

  537. ##  Smear the short, low side in the 192-bit key schedule.

  538. ##

  539. ##  Inputs:

  540. ##    %xmm7: high side, b  a  x  y

  541. ##    %xmm6:  low side, d  c  0  0

  542. ##    %xmm13: 0

  543. ##

  544. ##  Outputs:

  545. ##    %xmm6: b+c+d  b+c  0  0

  546. ##    %xmm0: b+c+d  b+c  b  a

  547. ##

  548. &function_begin_B("_vpaes_schedule_192_smear");

  549. 	&pshufd	("xmm1","xmm6",0x80);		# d c 0 0 -> c 0 0 0

  550. 	&pshufd	("xmm0","xmm7",0xFE);		# b a _ _ -> b b b a

  551. 	&pxor	("xmm6","xmm1");		# -> c+d c 0 0

  552. 	&pxor	("xmm1","xmm1");

  553. 	&pxor	("xmm6","xmm0");		# -> b+c+d b+c b a

  554. 	&movdqa	("xmm0","xmm6");

  555. 	&movhlps("xmm6","xmm1");		# clobber low side with zeros

  556. 	&ret	();

  557. &function_end_B("_vpaes_schedule_192_smear");

  558. 

  559. ##

  560. ##  .aes_schedule_round

  561. ##

  562. ##  Runs one main round of the key schedule on %xmm0, %xmm7

  563. ##

  564. ##  Specifically, runs subbytes on the high dword of %xmm0

  565. ##  then rotates it by one byte and xors into the low dword of

  566. ##  %xmm7.

  567. ##

  568. ##  Adds rcon from low byte of %xmm8, then rotates %xmm8 for

  569. ##  next rcon.

  570. ##

  571. ##  Smears the dwords of %xmm7 by xoring the low into the

  572. ##  second low, result into third, result into highest.

  573. ##

  574. ##  Returns results in %xmm7 = %xmm0.

  575. ##  Clobbers %xmm1-%xmm5.

  576. ##

  577. &function_begin_B("_vpaes_schedule_round");

  578. 	# extract rcon from xmm8

  579. 	&movdqa	("xmm2",&QWP(8,"esp"));		# xmm8

  580. 	&pxor	("xmm1","xmm1");

  581. 	&palignr("xmm1","xmm2",15);

  582. 	&palignr("xmm2","xmm2",15);

  583. 	&pxor	("xmm7","xmm1");

  584. 

  585. 	# rotate

  586. 	&pshufd	("xmm0","xmm0",0xFF);

  587. 	&palignr("xmm0","xmm0",1);

  588. 

  589. 	# fall through...

  590. 	&movdqa	(&QWP(8,"esp"),"xmm2");		# xmm8

  591. 

  592. 	# low round: same as high round, but no rotation and no rcon.

  593. &set_label("_vpaes_schedule_low_round");

  594. 	# smear xmm7

  595. 	&movdqa	("xmm1","xmm7");

  596. 	&pslldq	("xmm7",4);

  597. 	&pxor	("xmm7","xmm1");

  598. 	&movdqa	("xmm1","xmm7");

  599. 	&pslldq	("xmm7",8);

  600. 	&pxor	("xmm7","xmm1");

  601. 	&pxor	("xmm7",&QWP($k_s63,$const));

  602. 

  603. 	# subbyte

  604. 	&movdqa	("xmm4",&QWP($k_s0F,$const));

  605. 	&movdqa	("xmm5",&QWP($k_inv,$const));	# 4 : 1/j

  606. 	&movdqa	("xmm1","xmm4");	

  607. 	&pandn	("xmm1","xmm0");

  608. 	&psrld	("xmm1",4);			# 1 = i

  609. 	&pand	("xmm0","xmm4");		# 0 = k

  610. 	&movdqa	("xmm2",&QWP($k_inv+16,$const));# 2 : a/k

  611. 	&pshufb	("xmm2","xmm0");		# 2 = a/k

  612. 	&pxor	("xmm0","xmm1");		# 0 = j

  613. 	&movdqa	("xmm3","xmm5");		# 3 : 1/i

  614. 	&pshufb	("xmm3","xmm1");		# 3 = 1/i

  615. 	&pxor	("xmm3","xmm2");		# 3 = iak = 1/i + a/k

  616. 	&movdqa	("xmm4","xmm5");		# 4 : 1/j

  617. 	&pshufb	("xmm4","xmm0");		# 4 = 1/j

  618. 	&pxor	("xmm4","xmm2");		# 4 = jak = 1/j + a/k

  619. 	&movdqa	("xmm2","xmm5");		# 2 : 1/iak

  620. 	&pshufb	("xmm2","xmm3");		# 2 = 1/iak

  621. 	&pxor	("xmm2","xmm0");		# 2 = io

  622. 	&movdqa	("xmm3","xmm5");		# 3 : 1/jak

  623. 	&pshufb	("xmm3","xmm4");		# 3 = 1/jak

  624. 	&pxor	("xmm3","xmm1");		# 3 = jo

  625. 	&movdqa	("xmm4",&QWP($k_sb1,$const));	# 4 : sbou

  626. 	&pshufb	("xmm4","xmm2");		# 4 = sbou

  627. 	&movdqa	("xmm0",&QWP($k_sb1+16,$const));# 0 : sbot

  628. 	&pshufb	("xmm0","xmm3");		# 0 = sb1t

  629. 	&pxor	("xmm0","xmm4");		# 0 = sbox output

  630. 

  631. 	# add in smeared stuff

  632. 	&pxor	("xmm0","xmm7");

  633. 	&movdqa	("xmm7","xmm0");

  634. 	&ret	();

  635. &function_end_B("_vpaes_schedule_round");

  636. 

  637. ##

  638. ##  .aes_schedule_transform

  639. ##

  640. ##  Linear-transform %xmm0 according to tables at (%ebx)

  641. ##

  642. ##  Output in %xmm0

  643. ##  Clobbers %xmm1, %xmm2

  644. ##

  645. &function_begin_B("_vpaes_schedule_transform");

  646. 	&movdqa	("xmm2",&QWP($k_s0F,$const));

  647. 	&movdqa	("xmm1","xmm2");

  648. 	&pandn	("xmm1","xmm0");

  649. 	&psrld	("xmm1",4);

  650. 	&pand	("xmm0","xmm2");

  651. 	&movdqa	("xmm2",&QWP(0,$base));

  652. 	&pshufb	("xmm2","xmm0");

  653. 	&movdqa	("xmm0",&QWP(16,$base));

  654. 	&pshufb	("xmm0","xmm1");

  655. 	&pxor	("xmm0","xmm2");

  656. 	&ret	();

  657. &function_end_B("_vpaes_schedule_transform");

  658. 

  659. ##

  660. ##  .aes_schedule_mangle

  661. ##

  662. ##  Mangle xmm0 from (basis-transformed) standard version

  663. ##  to our version.

  664. ##

  665. ##  On encrypt,

  666. ##    xor with 0x63

  667. ##    multiply by circulant 0,1,1,1

  668. ##    apply shiftrows transform

  669. ##

  670. ##  On decrypt,

  671. ##    xor with 0x63

  672. ##    multiply by "inverse mixcolumns" circulant E,B,D,9

  673. ##    deskew

  674. ##    apply shiftrows transform

  675. ##

  676. ##

  677. ##  Writes out to (%edx), and increments or decrements it

  678. ##  Keeps track of round number mod 4 in %ecx

  679. ##  Preserves xmm0

  680. ##  Clobbers xmm1-xmm5

  681. ##

  682. &function_begin_B("_vpaes_schedule_mangle");

  683. 	&movdqa	("xmm4","xmm0");	# save xmm0 for later

  684. 	&movdqa	("xmm5",&QWP($k_mc_forward,$const));

  685. 	&test	($out,$out);

  686. 	&jnz	(&label("schedule_mangle_dec"));

  687. 

  688. 	# encrypting

  689. 	&add	($key,16);

  690. 	&pxor	("xmm4",&QWP($k_s63,$const));

  691. 	&pshufb	("xmm4","xmm5");

  692. 	&movdqa	("xmm3","xmm4");

  693. 	&pshufb	("xmm4","xmm5");

  694. 	&pxor	("xmm3","xmm4");

  695. 	&pshufb	("xmm4","xmm5");

  696. 	&pxor	("xmm3","xmm4");

  697. 

  698. 	&jmp	(&label("schedule_mangle_both"));

  699. 

  700. &set_label("schedule_mangle_dec",16);

  701. 	# inverse mix columns

  702. 	&movdqa	("xmm2",&QWP($k_s0F,$const));

  703. 	&lea	($inp,&DWP($k_dksd,$const));

  704. 	&movdqa	("xmm1","xmm2");

  705. 	&pandn	("xmm1","xmm4");

  706. 	&psrld	("xmm1",4);			# 1 = hi

  707. 	&pand	("xmm4","xmm2");		# 4 = lo

  708. 

  709. 	&movdqa	("xmm2",&QWP(0,$inp));

  710. 	&pshufb	("xmm2","xmm4");

  711. 	&movdqa	("xmm3",&QWP(0x10,$inp));

  712. 	&pshufb	("xmm3","xmm1");

  713. 	&pxor	("xmm3","xmm2");

  714. 	&pshufb	("xmm3","xmm5");

  715. 

  716. 	&movdqa	("xmm2",&QWP(0x20,$inp));

  717. 	&pshufb	("xmm2","xmm4");

  718. 	&pxor	("xmm2","xmm3");

  719. 	&movdqa	("xmm3",&QWP(0x30,$inp));

  720. 	&pshufb	("xmm3","xmm1");

  721. 	&pxor	("xmm3","xmm2");

  722. 	&pshufb	("xmm3","xmm5");

  723. 

  724. 	&movdqa	("xmm2",&QWP(0x40,$inp));

  725. 	&pshufb	("xmm2","xmm4");

  726. 	&pxor	("xmm2","xmm3");

  727. 	&movdqa	("xmm3",&QWP(0x50,$inp));

  728. 	&pshufb	("xmm3","xmm1");

  729. 	&pxor	("xmm3","xmm2");

  730. 	&pshufb	("xmm3","xmm5");

  731. 

  732. 	&movdqa	("xmm2",&QWP(0x60,$inp));

  733. 	&pshufb	("xmm2","xmm4");

  734. 	&pxor	("xmm2","xmm3");

  735. 	&movdqa	("xmm3",&QWP(0x70,$inp));

  736. 	&pshufb	("xmm3","xmm1");

  737. 	&pxor	("xmm3","xmm2");

  738. 

  739. 	&add	($key,-16);

  740. 

  741. &set_label("schedule_mangle_both");

  742. 	&movdqa	("xmm1",&QWP($k_sr,$const,$magic));

  743. 	&pshufb	("xmm3","xmm1");

  744. 	&add	($magic,-16);

  745. 	&and	($magic,0x30);

  746. 	&movdqu	(&QWP(0,$key),"xmm3");

  747. 	&ret	();

  748. &function_end_B("_vpaes_schedule_mangle");

  749. 

  750. #

  751. # Interface to OpenSSL

  752. #

  753. &function_begin("${PREFIX}_set_encrypt_key");

  754. 	&mov	($inp,&wparam(0));		# inp

  755. 	&lea	($base,&DWP(-56,"esp"));

  756. 	&mov	($round,&wparam(1));		# bits

  757. 	&and	($base,-16);

  758. 	&mov	($key,&wparam(2));		# key

  759. 	&xchg	($base,"esp");			# alloca

  760. 	&mov	(&DWP(48,"esp"),$base);

  761. 

  762. 	&mov	($base,$round);

  763. 	&shr	($base,5);

  764. 	&add	($base,5);

  765. 	&mov	(&DWP(240,$key),$base);		# AES_KEY->rounds = nbits/32+5;

  766. 	&mov	($magic,0x30);

  767. 	&mov	($out,0);

  768. 

  769. 	&lea	($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point")));

  770. 	&call	("_vpaes_schedule_core");

  771. &set_label("pic_point");

  772. 

  773. 	&mov	("esp",&DWP(48,"esp"));

  774. 	&xor	("eax","eax");

  775. &function_end("${PREFIX}_set_encrypt_key");

  776. 

  777. &function_begin("${PREFIX}_set_decrypt_key");

  778. 	&mov	($inp,&wparam(0));		# inp

  779. 	&lea	($base,&DWP(-56,"esp"));

  780. 	&mov	($round,&wparam(1));		# bits

  781. 	&and	($base,-16);

  782. 	&mov	($key,&wparam(2));		# key

  783. 	&xchg	($base,"esp");			# alloca

  784. 	&mov	(&DWP(48,"esp"),$base);

  785. 

  786. 	&mov	($base,$round);

  787. 	&shr	($base,5);

  788. 	&add	($base,5);

  789. 	&mov	(&DWP(240,$key),$base);	# AES_KEY->rounds = nbits/32+5;

  790. 	&shl	($base,4);

  791. 	&lea	($key,&DWP(16,$key,$base));

  792. 

  793. 	&mov	($out,1);

  794. 	&mov	($magic,$round);

  795. 	&shr	($magic,1);

  796. 	&and	($magic,32);

  797. 	&xor	($magic,32);			# nbist==192?0:32;

  798. 

  799. 	&lea	($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point")));

  800. 	&call	("_vpaes_schedule_core");

  801. &set_label("pic_point");

  802. 

  803. 	&mov	("esp",&DWP(48,"esp"));

  804. 	&xor	("eax","eax");

  805. &function_end("${PREFIX}_set_decrypt_key");

  806. 

  807. &function_begin("${PREFIX}_encrypt");

  808. 	&lea	($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point")));

  809. 	&call	("_vpaes_preheat");

  810. &set_label("pic_point");

  811. 	&mov	($inp,&wparam(0));		# inp

  812. 	&lea	($base,&DWP(-56,"esp"));

  813. 	&mov	($out,&wparam(1));		# out

  814. 	&and	($base,-16);

  815. 	&mov	($key,&wparam(2));		# key

  816. 	&xchg	($base,"esp");			# alloca

  817. 	&mov	(&DWP(48,"esp"),$base);

  818. 

  819. 	&movdqu	("xmm0",&QWP(0,$inp));

  820. 	&call	("_vpaes_encrypt_core");

  821. 	&movdqu	(&QWP(0,$out),"xmm0");

  822. 

  823. 	&mov	("esp",&DWP(48,"esp"));

  824. &function_end("${PREFIX}_encrypt");

  825. 

  826. &function_begin("${PREFIX}_decrypt");

  827. 	&lea	($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point")));

  828. 	&call	("_vpaes_preheat");

  829. &set_label("pic_point");

  830. 	&mov	($inp,&wparam(0));		# inp

  831. 	&lea	($base,&DWP(-56,"esp"));

  832. 	&mov	($out,&wparam(1));		# out

  833. 	&and	($base,-16);

  834. 	&mov	($key,&wparam(2));		# key

  835. 	&xchg	($base,"esp");			# alloca

  836. 	&mov	(&DWP(48,"esp"),$base);

  837. 

  838. 	&movdqu	("xmm0",&QWP(0,$inp));

  839. 	&call	("_vpaes_decrypt_core");

  840. 	&movdqu	(&QWP(0,$out),"xmm0");

  841. 

  842. 	&mov	("esp",&DWP(48,"esp"));

  843. &function_end("${PREFIX}_decrypt");

  844. 

  845. &function_begin("${PREFIX}_cbc_encrypt");

  846. 	&mov	($inp,&wparam(0));		# inp

  847. 	&mov	($out,&wparam(1));		# out

  848. 	&mov	($round,&wparam(2));		# len

  849. 	&mov	($key,&wparam(3));		# key

  850. 	&sub	($round,16);

  851. 	&jc	(&label("cbc_abort"));

  852. 	&lea	($base,&DWP(-56,"esp"));

  853. 	&mov	($const,&wparam(4));		# ivp

  854. 	&and	($base,-16);

  855. 	&mov	($magic,&wparam(5));		# enc

  856. 	&xchg	($base,"esp");			# alloca

  857. 	&movdqu	("xmm1",&QWP(0,$const));	# load IV

  858. 	&sub	($out,$inp);

  859. 	&mov	(&DWP(48,"esp"),$base);

  860. 

  861. 	&mov	(&DWP(0,"esp"),$out);		# save out

  862. 	&mov	(&DWP(4,"esp"),$key)		# save key

  863. 	&mov	(&DWP(8,"esp"),$const);		# save ivp

  864. 	&mov	($out,$round);			# $out works as $len

  865. 

  866. 	&lea	($const,&DWP(&label("_vpaes_consts")."+0x30-".&label("pic_point")));

  867. 	&call	("_vpaes_preheat");

  868. &set_label("pic_point");

  869. 	&cmp	($magic,0);

  870. 	&je	(&label("cbc_dec_loop"));

  871. 	&jmp	(&label("cbc_enc_loop"));

  872. 

  873. &set_label("cbc_enc_loop",16);

  874. 	&movdqu	("xmm0",&QWP(0,$inp));		# load input

  875. 	&pxor	("xmm0","xmm1");		# inp^=iv

  876. 	&call	("_vpaes_encrypt_core");

  877. 	&mov	($base,&DWP(0,"esp"));		# restore out

  878. 	&mov	($key,&DWP(4,"esp"));		# restore key

  879. 	&movdqa	("xmm1","xmm0");

  880. 	&movdqu	(&QWP(0,$base,$inp),"xmm0");	# write output

  881. 	&lea	($inp,&DWP(16,$inp));

  882. 	&sub	($out,16);

  883. 	&jnc	(&label("cbc_enc_loop"));

  884. 	&jmp	(&label("cbc_done"));

  885. 

  886. &set_label("cbc_dec_loop",16);

  887. 	&movdqu	("xmm0",&QWP(0,$inp));		# load input

  888. 	&movdqa	(&QWP(16,"esp"),"xmm1");	# save IV

  889. 	&movdqa	(&QWP(32,"esp"),"xmm0");	# save future IV

  890. 	&call	("_vpaes_decrypt_core");

  891. 	&mov	($base,&DWP(0,"esp"));		# restore out

  892. 	&mov	($key,&DWP(4,"esp"));		# restore key

  893. 	&pxor	("xmm0",&QWP(16,"esp"));	# out^=iv

  894. 	&movdqa	("xmm1",&QWP(32,"esp"));	# load next IV

  895. 	&movdqu	(&QWP(0,$base,$inp),"xmm0");	# write output

  896. 	&lea	($inp,&DWP(16,$inp));

  897. 	&sub	($out,16);

  898. 	&jnc	(&label("cbc_dec_loop"));

  899. 

  900. &set_label("cbc_done");

  901. 	&mov	($base,&DWP(8,"esp"));		# restore ivp

  902. 	&mov	("esp",&DWP(48,"esp"));

  903. 	&movdqu	(&QWP(0,$base),"xmm1");		# write IV

  904. &set_label("cbc_abort");

  905. &function_end("${PREFIX}_cbc_encrypt");

  906. 

  907. &asm_finish();

  908. 

  909. close STDOUT;