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sha1-c64xplus.pl

sha1-c64xplus.pl 8.0 KB
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  1. #! /usr/bin/env perl
    2. 

  2. # Copyright 2012-2020 The OpenSSL Project Authors. All Rights Reserved.
    3. 

  3. #
    4. 

  4. # Licensed under the Apache License 2.0 (the "License").  You may not use
    5. 

  5. # this file except in compliance with the License.  You can obtain a copy
    6. 

  6. # in the file LICENSE in the source distribution or at
    7. 

  7. # https://www.openssl.org/source/license.html
    8. 

  8. 

  9. #
    10. 

  10. # ====================================================================
    11. 

  11. # Written by Andy Polyakov <appro@openssl.org> for the OpenSSL
    12. 

  12. # project. The module is, however, dual licensed under OpenSSL and
    13. 

  13. # CRYPTOGAMS licenses depending on where you obtain it. For further
    14. 

  14. # details see http://www.openssl.org/~appro/cryptogams/.
    15. 

  15. # ====================================================================
    16. 

  16. #
    17. 

  17. # SHA1 for C64x+.
    18. 

  18. #
    19. 

  19. # November 2011
    20. 

  20. #
    21. 

  21. # If compared to compiler-generated code with similar characteristics,
    22. 

  22. # i.e. compiled with OPENSSL_SMALL_FOOTPRINT and utilizing SPLOOPs,
    23. 

  23. # this implementation is 25% smaller and >2x faster. In absolute terms
    24. 

  24. # performance is (quite impressive) ~6.5 cycles per processed byte.
    25. 

  25. # Fully unrolled assembler would be ~5x larger and is likely to be
    26. 

  26. # ~15% faster. It would be free from references to intermediate ring
    27. 

  27. # buffer, but put more pressure on L1P [both because the code would be
    28. 

  28. # larger and won't be using SPLOOP buffer]. There are no plans to
    29. 

  29. # realize fully unrolled variant though...
    30. 

  30. #
    31. 

  31. # !!! Note that this module uses AMR, which means that all interrupt
    32. 

  32. # service routines are expected to preserve it and for own well-being
    33. 

  33. # zero it upon entry.
    34. 

  34. 

  35. $output = pop and open STDOUT,">$output";
    36. 

  36. 

  37. ($CTX,$INP,$NUM) = ("A4","B4","A6");		# arguments
    38. 

  38. 

  39. ($A,$B,$C,$D,$E, $Arot,$F,$F0,$T,$K) = map("A$_",(16..20, 21..25));
    40. 

  40. ($X0,$X2,$X8,$X13) = ("A26","B26","A27","B27");
    41. 

  41. ($TX0,$TX1,$TX2,$TX3) = map("B$_",(28..31));
    42. 

  42. ($XPA,$XPB) = ("A5","B5");			# X circular buffer
    43. 

  43. ($Actx,$Bctx,$Cctx,$Dctx,$Ectx) = map("A$_",(3,6..9));	# zaps $NUM
    44. 

  44. 

  45. $code=<<___;
    46. 

  46. 	.text
    47. 

  47. 

  48. 	.if	.ASSEMBLER_VERSION<7000000
    49. 

  49. 	.asg	0,__TI_EABI__
    50. 

  50. 	.endif
    51. 

  51. 	.if	__TI_EABI__
    52. 

  52. 	.asg	sha1_block_data_order,_sha1_block_data_order
    53. 

  53. 	.endif
    54. 

  54. 

  55. 	.asg	B3,RA
    56. 

  56. 	.asg	A15,FP
    57. 

  57. 	.asg	B15,SP
    58. 

  58. 

  59. 	.if	.BIG_ENDIAN
    60. 

  60. 	.asg	MV,SWAP2
    61. 

  61. 	.asg	MV,SWAP4
    62. 

  62. 	.endif
    63. 

  63. 

  64. 	.global	_sha1_block_data_order
    65. 

  65. _sha1_block_data_order:
    66. 

  66. 	.asmfunc stack_usage(64)
    67. 

  67. 	MV	$NUM,A0			; reassign $NUM
    68. 

  68. ||	MVK	-64,B0
    69. 

  69.   [!A0]	BNOP	RA			; if ($NUM==0) return;
    70. 

  70. || [A0]	STW	FP,*SP--[16]		; save frame pointer and alloca(64)
    71. 

  71. || [A0]	MV	SP,FP
    72. 

  72.    [A0]	LDW	*${CTX}[0],$A		; load A-E...
    73. 

  73. || [A0]	AND	B0,SP,SP		; align stack at 64 bytes
    74. 

  74.    [A0]	LDW	*${CTX}[1],$B
    75. 

  75. || [A0]	SUBAW	SP,2,SP			; reserve two words above buffer
    76. 

  76.    [A0]	LDW	*${CTX}[2],$C
    77. 

  77. || [A0]	MVK	0x00404,B0
    78. 

  78.    [A0]	LDW	*${CTX}[3],$D
    79. 

  79. || [A0]	MVKH	0x50000,B0		; 0x050404, 64 bytes for $XP[AB]
    80. 

  80.    [A0]	LDW	*${CTX}[4],$E
    81. 

  81. || [A0]	MVC	B0,AMR			; setup circular addressing
    82. 

  82. 	LDNW	*${INP}++,$TX1		; pre-fetch input
    83. 

  83. 	NOP	1
    84. 

  84. 

  85. loop?:
    86. 

  86. 	MVK	0x00007999,$K
    87. 

  87. ||	ADDAW	SP,2,$XPA
    88. 

  88. ||	SUB	A0,1,A0
    89. 

  89. ||	MVK	13,B0
    90. 

  90. 	MVKH	0x5a820000,$K		; K_00_19
    91. 

  91. ||	ADDAW	SP,2,$XPB
    92. 

  92. ||	MV	$A,$Actx
    93. 

  93. ||	MV	$B,$Bctx
    94. 

  94. ;;==================================================
    95. 

  95. 	SPLOOPD	5			; BODY_00_13
    96. 

  96. ||	MV	$C,$Cctx
    97. 

  97. ||	MV	$D,$Dctx
    98. 

  98. ||	MV	$E,$Ectx
    99. 

  99. ||	MVC	B0,ILC
    100. 

  100. 

  101. 	ROTL	$A,5,$Arot
    102. 

  102. ||	AND	$C,$B,$F
    103. 

  103. ||	ANDN	$D,$B,$F0
    104. 

  104. ||	ADD	$K,$E,$T		; T=E+K
    105. 

  105. 

  106. 	XOR	$F0,$F,$F		; F_00_19(B,C,D)
    107. 

  107. ||	MV	$D,$E			; E=D
    108. 

  108. ||	MV	$C,$D			; D=C
    109. 

  109. ||	SWAP2	$TX1,$TX2
    110. 

  110. ||	LDNW	*${INP}++,$TX1
    111. 

  111. 

  112. 	ADD	$F,$T,$T		; T+=F_00_19(B,C,D)
    113. 

  113. ||	ROTL	$B,30,$C		; C=ROL(B,30)
    114. 

  114. ||	SWAP4	$TX2,$TX3		; byte swap
    115. 

  115. 

  116. 	ADD	$Arot,$T,$T		; T+=ROL(A,5)
    117. 

  117. ||	MV	$A,$B			; B=A
    118. 

  118. 

  119. 	ADD	$TX3,$T,$A		; A=T+Xi
    120. 

  120. ||	STW	$TX3,*${XPB}++
    121. 

  121. 	SPKERNEL
    122. 

  122. ;;==================================================
    123. 

  123. 	ROTL	$A,5,$Arot		; BODY_14
    124. 

  124. ||	AND	$C,$B,$F
    125. 

  125. ||	ANDN	$D,$B,$F0
    126. 

  126. ||	ADD	$K,$E,$T		; T=E+K
    127. 

  127. 

  128. 	XOR	$F0,$F,$F		; F_00_19(B,C,D)
    129. 

  129. ||	MV	$D,$E			; E=D
    130. 

  130. ||	MV	$C,$D			; D=C
    131. 

  131. ||	SWAP2	$TX1,$TX2
    132. 

  132. ||	LDNW	*${INP}++,$TX1
    133. 

  133. 

  134. 	ADD	$F,$T,$T		; T+=F_00_19(B,C,D)
    135. 

  135. ||	ROTL	$B,30,$C		; C=ROL(B,30)
    136. 

  136. ||	SWAP4	$TX2,$TX2		; byte swap
    137. 

  137. ||	LDW	*${XPA}++,$X0		; fetches from X ring buffer are
    138. 

  138. ||	LDW	*${XPB}[4],$X2		; 2 iterations ahead
    139. 

  139. 

  140. 	ADD	$Arot,$T,$T		; T+=ROL(A,5)
    141. 

  141. ||	MV	$A,$B			; B=A
    142. 

  142. ||	LDW	*${XPA}[7],$X8
    143. 

  143. ||	MV	$TX3,$X13		; ||	LDW	*${XPB}[15],$X13
    144. 

  144. ||	MV	$TX2,$TX3
    145. 

  145. 

  146. 	ADD	$TX2,$T,$A		; A=T+Xi
    147. 

  147. ||	STW	$TX2,*${XPB}++
    148. 

  148. ;;==================================================
    149. 

  149. 	ROTL	$A,5,$Arot		; BODY_15
    150. 

  150. ||	AND	$C,$B,$F
    151. 

  151. ||	ANDN	$D,$B,$F0
    152. 

  152. ||	ADD	$K,$E,$T		; T=E+K
    153. 

  153. 

  154. 	XOR	$F0,$F,$F		; F_00_19(B,C,D)
    155. 

  155. ||	MV	$D,$E			; E=D
    156. 

  156. ||	MV	$C,$D			; D=C
    157. 

  157. ||	SWAP2	$TX1,$TX2
    158. 

  158. 

  159. 	ADD	$F,$T,$T		; T+=F_00_19(B,C,D)
    160. 

  160. ||	ROTL	$B,30,$C		; C=ROL(B,30)
    161. 

  161. ||	SWAP4	$TX2,$TX2		; byte swap
    162. 

  162. ||	XOR	$X0,$X2,$TX0		; Xupdate XORs are 1 iteration ahead
    163. 

  163. ||	LDW	*${XPA}++,$X0
    164. 

  164. ||	LDW	*${XPB}[4],$X2
    165. 

  165. 

  166. 	ADD	$Arot,$T,$T		; T+=ROL(A,5)
    167. 

  167. ||	MV	$A,$B			; B=A
    168. 

  168. ||	XOR	$X8,$X13,$TX1
    169. 

  169. ||	LDW	*${XPA}[7],$X8
    170. 

  170. ||	MV	$TX3,$X13		; ||	LDW	*${XPB}[15],$X13
    171. 

  171. ||	MV	$TX2,$TX3
    172. 

  172. 

  173. 	ADD	$TX2,$T,$A		; A=T+Xi
    174. 

  174. ||	STW	$TX2,*${XPB}++
    175. 

  175. ||	XOR	$TX0,$TX1,$TX1
    176. 

  176. ||	MVK	3,B0
    177. 

  177. ;;==================================================
    178. 

  178. 	SPLOOPD	5			; BODY_16_19
    179. 

  179. ||	MVC	B0,ILC
    180. 

  180. 

  181. 	ROTL	$A,5,$Arot
    182. 

  182. ||	AND	$C,$B,$F
    183. 

  183. ||	ANDN	$D,$B,$F0
    184. 

  184. ||	ADD	$K,$E,$T		; T=E+K
    185. 

  185. ||	ROTL	$TX1,1,$TX2		; Xupdate output
    186. 

  186. 

  187. 	XOR	$F0,$F,$F		; F_00_19(B,C,D)
    188. 

  188. ||	MV	$D,$E			; E=D
    189. 

  189. ||	MV	$C,$D			; D=C
    190. 

  190. 

  191. 	ADD	$F,$T,$T		; T+=F_00_19(B,C,D)
    192. 

  192. ||	ROTL	$B,30,$C		; C=ROL(B,30)
    193. 

  193. ||	XOR	$X0,$X2,$TX0
    194. 

  194. ||	LDW	*${XPA}++,$X0
    195. 

  195. ||	LDW	*${XPB}[4],$X2
    196. 

  196. 

  197. 	ADD	$Arot,$T,$T		; T+=ROL(A,5)
    198. 

  198. ||	MV	$A,$B			; B=A
    199. 

  199. ||	XOR	$X8,$X13,$TX1
    200. 

  200. ||	LDW	*${XPA}[7],$X8
    201. 

  201. ||	MV	$TX3,$X13		; ||	LDW	*${XPB}[15],$X13
    202. 

  202. ||	MV	$TX2,$TX3
    203. 

  203. 

  204. 	ADD	$TX2,$T,$A		; A=T+Xi
    205. 

  205. ||	STW	$TX2,*${XPB}++
    206. 

  206. ||	XOR	$TX0,$TX1,$TX1
    207. 

  207. 	SPKERNEL
    208. 

  208. 

  209. 	MVK	0xffffeba1,$K
    210. 

  210. ||	MVK	19,B0
    211. 

  211. 	MVKH	0x6ed90000,$K		; K_20_39
    212. 

  212. ___
    213. 

  213. sub BODY_20_39 {
    214. 

  214. $code.=<<___;
    215. 

  215. ;;==================================================
    216. 

  216. 	SPLOOPD	5			; BODY_20_39
    217. 

  217. ||	MVC	B0,ILC
    218. 

  218. 

  219. 	ROTL	$A,5,$Arot
    220. 

  220. ||	XOR	$B,$C,$F
    221. 

  221. ||	ADD	$K,$E,$T		; T=E+K
    222. 

  222. ||	ROTL	$TX1,1,$TX2		; Xupdate output
    223. 

  223. 

  224. 	XOR	$D,$F,$F		; F_20_39(B,C,D)
    225. 

  225. ||	MV	$D,$E			; E=D
    226. 

  226. ||	MV	$C,$D			; D=C
    227. 

  227. 

  228. 	ADD	$F,$T,$T		; T+=F_20_39(B,C,D)
    229. 

  229. ||	ROTL	$B,30,$C		; C=ROL(B,30)
    230. 

  230. ||	XOR	$X0,$X2,$TX0
    231. 

  231. ||	LDW	*${XPA}++,$X0
    232. 

  232. ||	LDW	*${XPB}[4],$X2
    233. 

  233. 

  234. 	ADD	$Arot,$T,$T		; T+=ROL(A,5)
    235. 

  235. ||	MV	$A,$B			; B=A
    236. 

  236. ||	XOR	$X8,$X13,$TX1
    237. 

  237. ||	LDW	*${XPA}[7],$X8
    238. 

  238. ||	MV	$TX3,$X13		; ||	LDW	*${XPB}[15],$X13
    239. 

  239. ||	MV	$TX2,$TX3
    240. 

  240. 

  241. 	ADD	$TX2,$T,$A		; A=T+Xi
    242. 

  242. ||	STW	$TX2,*${XPB}++		; last one is redundant
    243. 

  243. ||	XOR	$TX0,$TX1,$TX1
    244. 

  244. 	SPKERNEL
    245. 

  245. ___
    246. 

  246. $code.=<<___ if (!shift);
    247. 

  247. 	MVK	0xffffbcdc,$K
    248. 

  248. 	MVKH	0x8f1b0000,$K		; K_40_59
    249. 

  249. ___
    250. 

  250. }	&BODY_20_39();
    251. 

  251. $code.=<<___;
    252. 

  252. ;;==================================================
    253. 

  253. 	SPLOOPD	5			; BODY_40_59
    254. 

  254. ||	MVC	B0,ILC
    255. 

  255. ||	AND	$B,$C,$F
    256. 

  256. ||	AND	$B,$D,$F0
    257. 

  257. 

  258. 	ROTL	$A,5,$Arot
    259. 

  259. ||	XOR	$F0,$F,$F
    260. 

  260. ||	AND	$C,$D,$F0
    261. 

  261. ||	ADD	$K,$E,$T		; T=E+K
    262. 

  262. ||	ROTL	$TX1,1,$TX2		; Xupdate output
    263. 

  263. 

  264. 	XOR	$F0,$F,$F		; F_40_59(B,C,D)
    265. 

  265. ||	MV	$D,$E			; E=D
    266. 

  266. ||	MV	$C,$D			; D=C
    267. 

  267. 

  268. 	ADD	$F,$T,$T		; T+=F_40_59(B,C,D)
    269. 

  269. ||	ROTL	$B,30,$C		; C=ROL(B,30)
    270. 

  270. ||	XOR	$X0,$X2,$TX0
    271. 

  271. ||	LDW	*${XPA}++,$X0
    272. 

  272. ||	LDW	*${XPB}[4],$X2
    273. 

  273. 

  274. 	ADD	$Arot,$T,$T		; T+=ROL(A,5)
    275. 

  275. ||	MV	$A,$B			; B=A
    276. 

  276. ||	XOR	$X8,$X13,$TX1
    277. 

  277. ||	LDW	*${XPA}[7],$X8
    278. 

  278. ||	MV	$TX3,$X13		; ||	LDW	*${XPB}[15],$X13
    279. 

  279. ||	MV	$TX2,$TX3
    280. 

  280. 

  281. 	ADD	$TX2,$T,$A		; A=T+Xi
    282. 

  282. ||	STW	$TX2,*${XPB}++
    283. 

  283. ||	XOR	$TX0,$TX1,$TX1
    284. 

  284. ||	AND	$B,$C,$F
    285. 

  285. ||	AND	$B,$D,$F0
    286. 

  286. 	SPKERNEL
    287. 

  287. 

  288. 	MVK	0xffffc1d6,$K
    289. 

  289. ||	MVK	18,B0
    290. 

  290. 	MVKH	0xca620000,$K		; K_60_79
    291. 

  291. ___
    292. 

  292. 	&BODY_20_39(-1);		# BODY_60_78
    293. 

  293. $code.=<<___;
    294. 

  294. ;;==================================================
    295. 

  295.    [A0]	B	loop?
    296. 

  296. ||	ROTL	$A,5,$Arot		; BODY_79
    297. 

  297. ||	XOR	$B,$C,$F
    298. 

  298. ||	ROTL	$TX1,1,$TX2		; Xupdate output
    299. 

  299. 

  300.    [A0]	LDNW	*${INP}++,$TX1		; pre-fetch input
    301. 

  301. ||	ADD	$K,$E,$T		; T=E+K
    302. 

  302. ||	XOR	$D,$F,$F		; F_20_39(B,C,D)
    303. 

  303. 

  304. 	ADD	$F,$T,$T		; T+=F_20_39(B,C,D)
    305. 

  305. ||	ADD	$Ectx,$D,$E		; E=D,E+=Ectx
    306. 

  306. ||	ADD	$Dctx,$C,$D		; D=C,D+=Dctx
    307. 

  307. ||	ROTL	$B,30,$C		; C=ROL(B,30)
    308. 

  308. 

  309. 	ADD	$Arot,$T,$T		; T+=ROL(A,5)
    310. 

  310. ||	ADD	$Bctx,$A,$B		; B=A,B+=Bctx
    311. 

  311. 

  312. 	ADD	$TX2,$T,$A		; A=T+Xi
    313. 

  313. 

  314. 	ADD	$Actx,$A,$A		; A+=Actx
    315. 

  315. ||	ADD	$Cctx,$C,$C		; C+=Cctx
    316. 

  316. ;; end of loop?
    317. 

  317. 

  318. 	BNOP	RA			; return
    319. 

  319. ||	MV	FP,SP			; restore stack pointer
    320. 

  320. ||	LDW	*FP[0],FP		; restore frame pointer
    321. 

  321. 	STW	$A,*${CTX}[0]		; emit A-E...
    322. 

  322. ||	MVK	0,B0
    323. 

  323. 	STW	$B,*${CTX}[1]
    324. 

  324. ||	MVC	B0,AMR			; clear AMR
    325. 

  325. 	STW	$C,*${CTX}[2]
    326. 

  326. 	STW	$D,*${CTX}[3]
    327. 

  327. 	STW	$E,*${CTX}[4]
    328. 

  328. 	.endasmfunc
    329. 

  329. 

  330. 	.sect	.const
    331. 

  331. 	.cstring "SHA1 block transform for C64x+, CRYPTOGAMS by <appro\@openssl.org>"
    332. 

  332. 	.align	4
    333. 

  333. ___
    334. 

  334. 

  335. print $code;
    336. 

  336. close STDOUT or die "error closing STDOUT: $!";
    337.