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boringssl/crypto/sha/asm/sha512-armv4.pl

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  1. #!/usr/bin/env perl

  2. 

  3. # ====================================================================

  4. # Written by Andy Polyakov <appro@openssl.org> 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. # Permission to use under GPL terms is granted.

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

  11. 

  12. # SHA512 block procedure for ARMv4. September 2007.

  13. 

  14. # This code is ~4.5 (four and a half) times faster than code generated

  15. # by gcc 3.4 and it spends ~72 clock cycles per byte [on single-issue

  16. # Xscale PXA250 core].

  17. #

  18. # July 2010.

  19. #

  20. # Rescheduling for dual-issue pipeline resulted in 6% improvement on

  21. # Cortex A8 core and ~40 cycles per processed byte.

  22. 

  23. # February 2011.

  24. #

  25. # Profiler-assisted and platform-specific optimization resulted in 7%

  26. # improvement on Coxtex A8 core and ~38 cycles per byte.

  27. 

  28. # March 2011.

  29. #

  30. # Add NEON implementation. On Cortex A8 it was measured to process

  31. # one byte in 23.3 cycles or ~60% faster than integer-only code.

  32. 

  33. # August 2012.

  34. #

  35. # Improve NEON performance by 12% on Snapdragon S4. In absolute

  36. # terms it's 22.6 cycles per byte, which is disappointing result.

  37. # Technical writers asserted that 3-way S4 pipeline can sustain

  38. # multiple NEON instructions per cycle, but dual NEON issue could

  39. # not be observed, see http://www.openssl.org/~appro/Snapdragon-S4.html

  40. # for further details. On side note Cortex-A15 processes one byte in

  41. # 16 cycles.

  42. 

  43. # Byte order [in]dependence. =========================================

  44. #

  45. # Originally caller was expected to maintain specific *dword* order in

  46. # h[0-7], namely with most significant dword at *lower* address, which

  47. # was reflected in below two parameters as 0 and 4. Now caller is

  48. # expected to maintain native byte order for whole 64-bit values.

  49. $hi="HI";

  50. $lo="LO";

  51. # ====================================================================

  52. 

  53. while (($output=shift) && ($output!~/^\w[\w\-]*\.\w+$/)) {}

  54. open STDOUT,">$output";

  55. 

  56. $ctx="r0";	# parameter block

  57. $inp="r1";

  58. $len="r2";

  59. 

  60. $Tlo="r3";

  61. $Thi="r4";

  62. $Alo="r5";

  63. $Ahi="r6";

  64. $Elo="r7";

  65. $Ehi="r8";

  66. $t0="r9";

  67. $t1="r10";

  68. $t2="r11";

  69. $t3="r12";

  70. ############	r13 is stack pointer

  71. $Ktbl="r14";

  72. ############	r15 is program counter

  73. 

  74. $Aoff=8*0;

  75. $Boff=8*1;

  76. $Coff=8*2;

  77. $Doff=8*3;

  78. $Eoff=8*4;

  79. $Foff=8*5;

  80. $Goff=8*6;

  81. $Hoff=8*7;

  82. $Xoff=8*8;

  83. 

  84. sub BODY_00_15() {

  85. my $magic = shift;

  86. $code.=<<___;

  87. 	@ Sigma1(x)	(ROTR((x),14) ^ ROTR((x),18)  ^ ROTR((x),41))

  88. 	@ LO		lo>>14^hi<<18 ^ lo>>18^hi<<14 ^ hi>>9^lo<<23

  89. 	@ HI		hi>>14^lo<<18 ^ hi>>18^lo<<14 ^ lo>>9^hi<<23

  90. 	mov	$t0,$Elo,lsr#14

  91. 	str	$Tlo,[sp,#$Xoff+0]

  92. 	mov	$t1,$Ehi,lsr#14

  93. 	str	$Thi,[sp,#$Xoff+4]

  94. 	eor	$t0,$t0,$Ehi,lsl#18

  95. 	ldr	$t2,[sp,#$Hoff+0]	@ h.lo

  96. 	eor	$t1,$t1,$Elo,lsl#18

  97. 	ldr	$t3,[sp,#$Hoff+4]	@ h.hi

  98. 	eor	$t0,$t0,$Elo,lsr#18

  99. 	eor	$t1,$t1,$Ehi,lsr#18

  100. 	eor	$t0,$t0,$Ehi,lsl#14

  101. 	eor	$t1,$t1,$Elo,lsl#14

  102. 	eor	$t0,$t0,$Ehi,lsr#9

  103. 	eor	$t1,$t1,$Elo,lsr#9

  104. 	eor	$t0,$t0,$Elo,lsl#23

  105. 	eor	$t1,$t1,$Ehi,lsl#23	@ Sigma1(e)

  106. 	adds	$Tlo,$Tlo,$t0

  107. 	ldr	$t0,[sp,#$Foff+0]	@ f.lo

  108. 	adc	$Thi,$Thi,$t1		@ T += Sigma1(e)

  109. 	ldr	$t1,[sp,#$Foff+4]	@ f.hi

  110. 	adds	$Tlo,$Tlo,$t2

  111. 	ldr	$t2,[sp,#$Goff+0]	@ g.lo

  112. 	adc	$Thi,$Thi,$t3		@ T += h

  113. 	ldr	$t3,[sp,#$Goff+4]	@ g.hi

  114. 

  115. 	eor	$t0,$t0,$t2

  116. 	str	$Elo,[sp,#$Eoff+0]

  117. 	eor	$t1,$t1,$t3

  118. 	str	$Ehi,[sp,#$Eoff+4]

  119. 	and	$t0,$t0,$Elo

  120. 	str	$Alo,[sp,#$Aoff+0]

  121. 	and	$t1,$t1,$Ehi

  122. 	str	$Ahi,[sp,#$Aoff+4]

  123. 	eor	$t0,$t0,$t2

  124. 	ldr	$t2,[$Ktbl,#$lo]	@ K[i].lo

  125. 	eor	$t1,$t1,$t3		@ Ch(e,f,g)

  126. 	ldr	$t3,[$Ktbl,#$hi]	@ K[i].hi

  127. 

  128. 	adds	$Tlo,$Tlo,$t0

  129. 	ldr	$Elo,[sp,#$Doff+0]	@ d.lo

  130. 	adc	$Thi,$Thi,$t1		@ T += Ch(e,f,g)

  131. 	ldr	$Ehi,[sp,#$Doff+4]	@ d.hi

  132. 	adds	$Tlo,$Tlo,$t2

  133. 	and	$t0,$t2,#0xff

  134. 	adc	$Thi,$Thi,$t3		@ T += K[i]

  135. 	adds	$Elo,$Elo,$Tlo

  136. 	ldr	$t2,[sp,#$Boff+0]	@ b.lo

  137. 	adc	$Ehi,$Ehi,$Thi		@ d += T

  138. 	teq	$t0,#$magic

  139. 

  140. 	ldr	$t3,[sp,#$Coff+0]	@ c.lo

  141. #if __ARM_ARCH__>=7

  142. 	it	eq			@ Thumb2 thing, sanity check in ARM

  143. #endif

  144. 	orreq	$Ktbl,$Ktbl,#1

  145. 	@ Sigma0(x)	(ROTR((x),28) ^ ROTR((x),34) ^ ROTR((x),39))

  146. 	@ LO		lo>>28^hi<<4  ^ hi>>2^lo<<30 ^ hi>>7^lo<<25

  147. 	@ HI		hi>>28^lo<<4  ^ lo>>2^hi<<30 ^ lo>>7^hi<<25

  148. 	mov	$t0,$Alo,lsr#28

  149. 	mov	$t1,$Ahi,lsr#28

  150. 	eor	$t0,$t0,$Ahi,lsl#4

  151. 	eor	$t1,$t1,$Alo,lsl#4

  152. 	eor	$t0,$t0,$Ahi,lsr#2

  153. 	eor	$t1,$t1,$Alo,lsr#2

  154. 	eor	$t0,$t0,$Alo,lsl#30

  155. 	eor	$t1,$t1,$Ahi,lsl#30

  156. 	eor	$t0,$t0,$Ahi,lsr#7

  157. 	eor	$t1,$t1,$Alo,lsr#7

  158. 	eor	$t0,$t0,$Alo,lsl#25

  159. 	eor	$t1,$t1,$Ahi,lsl#25	@ Sigma0(a)

  160. 	adds	$Tlo,$Tlo,$t0

  161. 	and	$t0,$Alo,$t2

  162. 	adc	$Thi,$Thi,$t1		@ T += Sigma0(a)

  163. 

  164. 	ldr	$t1,[sp,#$Boff+4]	@ b.hi

  165. 	orr	$Alo,$Alo,$t2

  166. 	ldr	$t2,[sp,#$Coff+4]	@ c.hi

  167. 	and	$Alo,$Alo,$t3

  168. 	and	$t3,$Ahi,$t1

  169. 	orr	$Ahi,$Ahi,$t1

  170. 	orr	$Alo,$Alo,$t0		@ Maj(a,b,c).lo

  171. 	and	$Ahi,$Ahi,$t2

  172. 	adds	$Alo,$Alo,$Tlo

  173. 	orr	$Ahi,$Ahi,$t3		@ Maj(a,b,c).hi

  174. 	sub	sp,sp,#8

  175. 	adc	$Ahi,$Ahi,$Thi		@ h += T

  176. 	tst	$Ktbl,#1

  177. 	add	$Ktbl,$Ktbl,#8

  178. ___

  179. }

  180. $code=<<___;

  181. #ifndef __KERNEL__

  182. # include "arm_arch.h"

  183. # define VFP_ABI_PUSH	vstmdb	sp!,{d8-d15}

  184. # define VFP_ABI_POP	vldmia	sp!,{d8-d15}

  185. #else

  186. # define __ARM_ARCH__ __LINUX_ARM_ARCH__

  187. # define __ARM_MAX_ARCH__ 7

  188. # define VFP_ABI_PUSH

  189. # define VFP_ABI_POP

  190. #endif

  191. 

  192. #ifdef __ARMEL__

  193. # define LO 0

  194. # define HI 4

  195. # define WORD64(hi0,lo0,hi1,lo1)	.word	lo0,hi0, lo1,hi1

  196. #else

  197. # define HI 0

  198. # define LO 4

  199. # define WORD64(hi0,lo0,hi1,lo1)	.word	hi0,lo0, hi1,lo1

  200. #endif

  201. 

  202. .text

  203. #if __ARM_ARCH__<7

  204. .code	32

  205. #else

  206. .syntax unified

  207. # ifdef __thumb2__

  208. #  define adrl adr

  209. .thumb

  210. # else

  211. .code   32

  212. # endif

  213. #endif

  214. 

  215. .type	K512,%object

  216. .align	5

  217. K512:

  218. WORD64(0x428a2f98,0xd728ae22, 0x71374491,0x23ef65cd)

  219. WORD64(0xb5c0fbcf,0xec4d3b2f, 0xe9b5dba5,0x8189dbbc)

  220. WORD64(0x3956c25b,0xf348b538, 0x59f111f1,0xb605d019)

  221. WORD64(0x923f82a4,0xaf194f9b, 0xab1c5ed5,0xda6d8118)

  222. WORD64(0xd807aa98,0xa3030242, 0x12835b01,0x45706fbe)

  223. WORD64(0x243185be,0x4ee4b28c, 0x550c7dc3,0xd5ffb4e2)

  224. WORD64(0x72be5d74,0xf27b896f, 0x80deb1fe,0x3b1696b1)

  225. WORD64(0x9bdc06a7,0x25c71235, 0xc19bf174,0xcf692694)

  226. WORD64(0xe49b69c1,0x9ef14ad2, 0xefbe4786,0x384f25e3)

  227. WORD64(0x0fc19dc6,0x8b8cd5b5, 0x240ca1cc,0x77ac9c65)

  228. WORD64(0x2de92c6f,0x592b0275, 0x4a7484aa,0x6ea6e483)

  229. WORD64(0x5cb0a9dc,0xbd41fbd4, 0x76f988da,0x831153b5)

  230. WORD64(0x983e5152,0xee66dfab, 0xa831c66d,0x2db43210)

  231. WORD64(0xb00327c8,0x98fb213f, 0xbf597fc7,0xbeef0ee4)

  232. WORD64(0xc6e00bf3,0x3da88fc2, 0xd5a79147,0x930aa725)

  233. WORD64(0x06ca6351,0xe003826f, 0x14292967,0x0a0e6e70)

  234. WORD64(0x27b70a85,0x46d22ffc, 0x2e1b2138,0x5c26c926)

  235. WORD64(0x4d2c6dfc,0x5ac42aed, 0x53380d13,0x9d95b3df)

  236. WORD64(0x650a7354,0x8baf63de, 0x766a0abb,0x3c77b2a8)

  237. WORD64(0x81c2c92e,0x47edaee6, 0x92722c85,0x1482353b)

  238. WORD64(0xa2bfe8a1,0x4cf10364, 0xa81a664b,0xbc423001)

  239. WORD64(0xc24b8b70,0xd0f89791, 0xc76c51a3,0x0654be30)

  240. WORD64(0xd192e819,0xd6ef5218, 0xd6990624,0x5565a910)

  241. WORD64(0xf40e3585,0x5771202a, 0x106aa070,0x32bbd1b8)

  242. WORD64(0x19a4c116,0xb8d2d0c8, 0x1e376c08,0x5141ab53)

  243. WORD64(0x2748774c,0xdf8eeb99, 0x34b0bcb5,0xe19b48a8)

  244. WORD64(0x391c0cb3,0xc5c95a63, 0x4ed8aa4a,0xe3418acb)

  245. WORD64(0x5b9cca4f,0x7763e373, 0x682e6ff3,0xd6b2b8a3)

  246. WORD64(0x748f82ee,0x5defb2fc, 0x78a5636f,0x43172f60)

  247. WORD64(0x84c87814,0xa1f0ab72, 0x8cc70208,0x1a6439ec)

  248. WORD64(0x90befffa,0x23631e28, 0xa4506ceb,0xde82bde9)

  249. WORD64(0xbef9a3f7,0xb2c67915, 0xc67178f2,0xe372532b)

  250. WORD64(0xca273ece,0xea26619c, 0xd186b8c7,0x21c0c207)

  251. WORD64(0xeada7dd6,0xcde0eb1e, 0xf57d4f7f,0xee6ed178)

  252. WORD64(0x06f067aa,0x72176fba, 0x0a637dc5,0xa2c898a6)

  253. WORD64(0x113f9804,0xbef90dae, 0x1b710b35,0x131c471b)

  254. WORD64(0x28db77f5,0x23047d84, 0x32caab7b,0x40c72493)

  255. WORD64(0x3c9ebe0a,0x15c9bebc, 0x431d67c4,0x9c100d4c)

  256. WORD64(0x4cc5d4be,0xcb3e42b6, 0x597f299c,0xfc657e2a)

  257. WORD64(0x5fcb6fab,0x3ad6faec, 0x6c44198c,0x4a475817)

  258. .size	K512,.-K512

  259. #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__)

  260. .LOPENSSL_armcap:

  261. .word	OPENSSL_armcap_P-sha512_block_data_order

  262. .skip	32-4

  263. #else

  264. .skip	32

  265. #endif

  266. 

  267. .global	sha512_block_data_order

  268. .type	sha512_block_data_order,%function

  269. sha512_block_data_order:

  270. #if __ARM_ARCH__<7

  271. 	sub	r3,pc,#8		@ sha512_block_data_order

  272. #else

  273. 	adr	r3,sha512_block_data_order

  274. #endif

  275. #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__)

  276. 	ldr	r12,.LOPENSSL_armcap

  277. 	ldr	r12,[r3,r12]		@ OPENSSL_armcap_P

  278. 	tst	r12,#1

  279. 	bne	.LNEON

  280. #endif

  281. 	add	$len,$inp,$len,lsl#7	@ len to point at the end of inp

  282. 	stmdb	sp!,{r4-r12,lr}

  283. 	sub	$Ktbl,r3,#672		@ K512

  284. 	sub	sp,sp,#9*8

  285. 

  286. 	ldr	$Elo,[$ctx,#$Eoff+$lo]

  287. 	ldr	$Ehi,[$ctx,#$Eoff+$hi]

  288. 	ldr	$t0, [$ctx,#$Goff+$lo]

  289. 	ldr	$t1, [$ctx,#$Goff+$hi]

  290. 	ldr	$t2, [$ctx,#$Hoff+$lo]

  291. 	ldr	$t3, [$ctx,#$Hoff+$hi]

  292. .Loop:

  293. 	str	$t0, [sp,#$Goff+0]

  294. 	str	$t1, [sp,#$Goff+4]

  295. 	str	$t2, [sp,#$Hoff+0]

  296. 	str	$t3, [sp,#$Hoff+4]

  297. 	ldr	$Alo,[$ctx,#$Aoff+$lo]

  298. 	ldr	$Ahi,[$ctx,#$Aoff+$hi]

  299. 	ldr	$Tlo,[$ctx,#$Boff+$lo]

  300. 	ldr	$Thi,[$ctx,#$Boff+$hi]

  301. 	ldr	$t0, [$ctx,#$Coff+$lo]

  302. 	ldr	$t1, [$ctx,#$Coff+$hi]

  303. 	ldr	$t2, [$ctx,#$Doff+$lo]

  304. 	ldr	$t3, [$ctx,#$Doff+$hi]

  305. 	str	$Tlo,[sp,#$Boff+0]

  306. 	str	$Thi,[sp,#$Boff+4]

  307. 	str	$t0, [sp,#$Coff+0]

  308. 	str	$t1, [sp,#$Coff+4]

  309. 	str	$t2, [sp,#$Doff+0]

  310. 	str	$t3, [sp,#$Doff+4]

  311. 	ldr	$Tlo,[$ctx,#$Foff+$lo]

  312. 	ldr	$Thi,[$ctx,#$Foff+$hi]

  313. 	str	$Tlo,[sp,#$Foff+0]

  314. 	str	$Thi,[sp,#$Foff+4]

  315. 

  316. .L00_15:

  317. #if __ARM_ARCH__<7

  318. 	ldrb	$Tlo,[$inp,#7]

  319. 	ldrb	$t0, [$inp,#6]

  320. 	ldrb	$t1, [$inp,#5]

  321. 	ldrb	$t2, [$inp,#4]

  322. 	ldrb	$Thi,[$inp,#3]

  323. 	ldrb	$t3, [$inp,#2]

  324. 	orr	$Tlo,$Tlo,$t0,lsl#8

  325. 	ldrb	$t0, [$inp,#1]

  326. 	orr	$Tlo,$Tlo,$t1,lsl#16

  327. 	ldrb	$t1, [$inp],#8

  328. 	orr	$Tlo,$Tlo,$t2,lsl#24

  329. 	orr	$Thi,$Thi,$t3,lsl#8

  330. 	orr	$Thi,$Thi,$t0,lsl#16

  331. 	orr	$Thi,$Thi,$t1,lsl#24

  332. #else

  333. 	ldr	$Tlo,[$inp,#4]

  334. 	ldr	$Thi,[$inp],#8

  335. #ifdef __ARMEL__

  336. 	rev	$Tlo,$Tlo

  337. 	rev	$Thi,$Thi

  338. #endif

  339. #endif

  340. ___

  341. 	&BODY_00_15(0x94);

  342. $code.=<<___;

  343. 	tst	$Ktbl,#1

  344. 	beq	.L00_15

  345. 	ldr	$t0,[sp,#`$Xoff+8*(16-1)`+0]

  346. 	ldr	$t1,[sp,#`$Xoff+8*(16-1)`+4]

  347. 	bic	$Ktbl,$Ktbl,#1

  348. .L16_79:

  349. 	@ sigma0(x)	(ROTR((x),1)  ^ ROTR((x),8)  ^ ((x)>>7))

  350. 	@ LO		lo>>1^hi<<31  ^ lo>>8^hi<<24 ^ lo>>7^hi<<25

  351. 	@ HI		hi>>1^lo<<31  ^ hi>>8^lo<<24 ^ hi>>7

  352. 	mov	$Tlo,$t0,lsr#1

  353. 	ldr	$t2,[sp,#`$Xoff+8*(16-14)`+0]

  354. 	mov	$Thi,$t1,lsr#1

  355. 	ldr	$t3,[sp,#`$Xoff+8*(16-14)`+4]

  356. 	eor	$Tlo,$Tlo,$t1,lsl#31

  357. 	eor	$Thi,$Thi,$t0,lsl#31

  358. 	eor	$Tlo,$Tlo,$t0,lsr#8

  359. 	eor	$Thi,$Thi,$t1,lsr#8

  360. 	eor	$Tlo,$Tlo,$t1,lsl#24

  361. 	eor	$Thi,$Thi,$t0,lsl#24

  362. 	eor	$Tlo,$Tlo,$t0,lsr#7

  363. 	eor	$Thi,$Thi,$t1,lsr#7

  364. 	eor	$Tlo,$Tlo,$t1,lsl#25

  365. 

  366. 	@ sigma1(x)	(ROTR((x),19) ^ ROTR((x),61) ^ ((x)>>6))

  367. 	@ LO		lo>>19^hi<<13 ^ hi>>29^lo<<3 ^ lo>>6^hi<<26

  368. 	@ HI		hi>>19^lo<<13 ^ lo>>29^hi<<3 ^ hi>>6

  369. 	mov	$t0,$t2,lsr#19

  370. 	mov	$t1,$t3,lsr#19

  371. 	eor	$t0,$t0,$t3,lsl#13

  372. 	eor	$t1,$t1,$t2,lsl#13

  373. 	eor	$t0,$t0,$t3,lsr#29

  374. 	eor	$t1,$t1,$t2,lsr#29

  375. 	eor	$t0,$t0,$t2,lsl#3

  376. 	eor	$t1,$t1,$t3,lsl#3

  377. 	eor	$t0,$t0,$t2,lsr#6

  378. 	eor	$t1,$t1,$t3,lsr#6

  379. 	ldr	$t2,[sp,#`$Xoff+8*(16-9)`+0]

  380. 	eor	$t0,$t0,$t3,lsl#26

  381. 

  382. 	ldr	$t3,[sp,#`$Xoff+8*(16-9)`+4]

  383. 	adds	$Tlo,$Tlo,$t0

  384. 	ldr	$t0,[sp,#`$Xoff+8*16`+0]

  385. 	adc	$Thi,$Thi,$t1

  386. 

  387. 	ldr	$t1,[sp,#`$Xoff+8*16`+4]

  388. 	adds	$Tlo,$Tlo,$t2

  389. 	adc	$Thi,$Thi,$t3

  390. 	adds	$Tlo,$Tlo,$t0

  391. 	adc	$Thi,$Thi,$t1

  392. ___

  393. 	&BODY_00_15(0x17);

  394. $code.=<<___;

  395. #if __ARM_ARCH__>=7

  396. 	ittt	eq			@ Thumb2 thing, sanity check in ARM

  397. #endif

  398. 	ldreq	$t0,[sp,#`$Xoff+8*(16-1)`+0]

  399. 	ldreq	$t1,[sp,#`$Xoff+8*(16-1)`+4]

  400. 	beq	.L16_79

  401. 	bic	$Ktbl,$Ktbl,#1

  402. 

  403. 	ldr	$Tlo,[sp,#$Boff+0]

  404. 	ldr	$Thi,[sp,#$Boff+4]

  405. 	ldr	$t0, [$ctx,#$Aoff+$lo]

  406. 	ldr	$t1, [$ctx,#$Aoff+$hi]

  407. 	ldr	$t2, [$ctx,#$Boff+$lo]

  408. 	ldr	$t3, [$ctx,#$Boff+$hi]

  409. 	adds	$t0,$Alo,$t0

  410. 	str	$t0, [$ctx,#$Aoff+$lo]

  411. 	adc	$t1,$Ahi,$t1

  412. 	str	$t1, [$ctx,#$Aoff+$hi]

  413. 	adds	$t2,$Tlo,$t2

  414. 	str	$t2, [$ctx,#$Boff+$lo]

  415. 	adc	$t3,$Thi,$t3

  416. 	str	$t3, [$ctx,#$Boff+$hi]

  417. 

  418. 	ldr	$Alo,[sp,#$Coff+0]

  419. 	ldr	$Ahi,[sp,#$Coff+4]

  420. 	ldr	$Tlo,[sp,#$Doff+0]

  421. 	ldr	$Thi,[sp,#$Doff+4]

  422. 	ldr	$t0, [$ctx,#$Coff+$lo]

  423. 	ldr	$t1, [$ctx,#$Coff+$hi]

  424. 	ldr	$t2, [$ctx,#$Doff+$lo]

  425. 	ldr	$t3, [$ctx,#$Doff+$hi]

  426. 	adds	$t0,$Alo,$t0

  427. 	str	$t0, [$ctx,#$Coff+$lo]

  428. 	adc	$t1,$Ahi,$t1

  429. 	str	$t1, [$ctx,#$Coff+$hi]

  430. 	adds	$t2,$Tlo,$t2

  431. 	str	$t2, [$ctx,#$Doff+$lo]

  432. 	adc	$t3,$Thi,$t3

  433. 	str	$t3, [$ctx,#$Doff+$hi]

  434. 

  435. 	ldr	$Tlo,[sp,#$Foff+0]

  436. 	ldr	$Thi,[sp,#$Foff+4]

  437. 	ldr	$t0, [$ctx,#$Eoff+$lo]

  438. 	ldr	$t1, [$ctx,#$Eoff+$hi]

  439. 	ldr	$t2, [$ctx,#$Foff+$lo]

  440. 	ldr	$t3, [$ctx,#$Foff+$hi]

  441. 	adds	$Elo,$Elo,$t0

  442. 	str	$Elo,[$ctx,#$Eoff+$lo]

  443. 	adc	$Ehi,$Ehi,$t1

  444. 	str	$Ehi,[$ctx,#$Eoff+$hi]

  445. 	adds	$t2,$Tlo,$t2

  446. 	str	$t2, [$ctx,#$Foff+$lo]

  447. 	adc	$t3,$Thi,$t3

  448. 	str	$t3, [$ctx,#$Foff+$hi]

  449. 

  450. 	ldr	$Alo,[sp,#$Goff+0]

  451. 	ldr	$Ahi,[sp,#$Goff+4]

  452. 	ldr	$Tlo,[sp,#$Hoff+0]

  453. 	ldr	$Thi,[sp,#$Hoff+4]

  454. 	ldr	$t0, [$ctx,#$Goff+$lo]

  455. 	ldr	$t1, [$ctx,#$Goff+$hi]

  456. 	ldr	$t2, [$ctx,#$Hoff+$lo]

  457. 	ldr	$t3, [$ctx,#$Hoff+$hi]

  458. 	adds	$t0,$Alo,$t0

  459. 	str	$t0, [$ctx,#$Goff+$lo]

  460. 	adc	$t1,$Ahi,$t1

  461. 	str	$t1, [$ctx,#$Goff+$hi]

  462. 	adds	$t2,$Tlo,$t2

  463. 	str	$t2, [$ctx,#$Hoff+$lo]

  464. 	adc	$t3,$Thi,$t3

  465. 	str	$t3, [$ctx,#$Hoff+$hi]

  466. 

  467. 	add	sp,sp,#640

  468. 	sub	$Ktbl,$Ktbl,#640

  469. 

  470. 	teq	$inp,$len

  471. 	bne	.Loop

  472. 

  473. 	add	sp,sp,#8*9		@ destroy frame

  474. #if __ARM_ARCH__>=5

  475. 	ldmia	sp!,{r4-r12,pc}

  476. #else

  477. 	ldmia	sp!,{r4-r12,lr}

  478. 	tst	lr,#1

  479. 	moveq	pc,lr			@ be binary compatible with V4, yet

  480. 	bx	lr			@ interoperable with Thumb ISA:-)

  481. #endif

  482. .size	sha512_block_data_order,.-sha512_block_data_order

  483. ___

  484. 

  485. {

  486. my @Sigma0=(28,34,39);

  487. my @Sigma1=(14,18,41);

  488. my @sigma0=(1, 8, 7);

  489. my @sigma1=(19,61,6);

  490. 

  491. my $Ktbl="r3";

  492. my $cnt="r12";	# volatile register known as ip, intra-procedure-call scratch

  493. 

  494. my @X=map("d$_",(0..15));

  495. my @V=($A,$B,$C,$D,$E,$F,$G,$H)=map("d$_",(16..23));

  496. 

  497. sub NEON_00_15() {

  498. my $i=shift;

  499. my ($a,$b,$c,$d,$e,$f,$g,$h)=@_;

  500. my ($t0,$t1,$t2,$T1,$K,$Ch,$Maj)=map("d$_",(24..31));	# temps

  501. 

  502. $code.=<<___ if ($i<16 || $i&1);

  503. 	vshr.u64	$t0,$e,#@Sigma1[0]	@ $i

  504. #if $i<16

  505. 	vld1.64		{@X[$i%16]},[$inp]!	@ handles unaligned

  506. #endif

  507. 	vshr.u64	$t1,$e,#@Sigma1[1]

  508. #if $i>0

  509. 	 vadd.i64	$a,$Maj			@ h+=Maj from the past

  510. #endif

  511. 	vshr.u64	$t2,$e,#@Sigma1[2]

  512. ___

  513. $code.=<<___;

  514. 	vld1.64		{$K},[$Ktbl,:64]!	@ K[i++]

  515. 	vsli.64		$t0,$e,#`64-@Sigma1[0]`

  516. 	vsli.64		$t1,$e,#`64-@Sigma1[1]`

  517. 	vmov		$Ch,$e

  518. 	vsli.64		$t2,$e,#`64-@Sigma1[2]`

  519. #if $i<16 && defined(__ARMEL__)

  520. 	vrev64.8	@X[$i],@X[$i]

  521. #endif

  522. 	veor		$t1,$t0

  523. 	vbsl		$Ch,$f,$g		@ Ch(e,f,g)

  524. 	vshr.u64	$t0,$a,#@Sigma0[0]

  525. 	veor		$t2,$t1			@ Sigma1(e)

  526. 	vadd.i64	$T1,$Ch,$h

  527. 	vshr.u64	$t1,$a,#@Sigma0[1]

  528. 	vsli.64		$t0,$a,#`64-@Sigma0[0]`

  529. 	vadd.i64	$T1,$t2

  530. 	vshr.u64	$t2,$a,#@Sigma0[2]

  531. 	vadd.i64	$K,@X[$i%16]

  532. 	vsli.64		$t1,$a,#`64-@Sigma0[1]`

  533. 	veor		$Maj,$a,$b

  534. 	vsli.64		$t2,$a,#`64-@Sigma0[2]`

  535. 	veor		$h,$t0,$t1

  536. 	vadd.i64	$T1,$K

  537. 	vbsl		$Maj,$c,$b		@ Maj(a,b,c)

  538. 	veor		$h,$t2			@ Sigma0(a)

  539. 	vadd.i64	$d,$T1

  540. 	vadd.i64	$Maj,$T1

  541. 	@ vadd.i64	$h,$Maj

  542. ___

  543. }

  544. 

  545. sub NEON_16_79() {

  546. my $i=shift;

  547. 

  548. if ($i&1)	{ &NEON_00_15($i,@_); return; }

  549. 

  550. # 2x-vectorized, therefore runs every 2nd round

  551. my @X=map("q$_",(0..7));			# view @X as 128-bit vector

  552. my ($t0,$t1,$s0,$s1) = map("q$_",(12..15));	# temps

  553. my ($d0,$d1,$d2) = map("d$_",(24..26));		# temps from NEON_00_15

  554. my $e=@_[4];					# $e from NEON_00_15

  555. $i /= 2;

  556. $code.=<<___;

  557. 	vshr.u64	$t0,@X[($i+7)%8],#@sigma1[0]

  558. 	vshr.u64	$t1,@X[($i+7)%8],#@sigma1[1]

  559. 	 vadd.i64	@_[0],d30			@ h+=Maj from the past

  560. 	vshr.u64	$s1,@X[($i+7)%8],#@sigma1[2]

  561. 	vsli.64		$t0,@X[($i+7)%8],#`64-@sigma1[0]`

  562. 	vext.8		$s0,@X[$i%8],@X[($i+1)%8],#8	@ X[i+1]

  563. 	vsli.64		$t1,@X[($i+7)%8],#`64-@sigma1[1]`

  564. 	veor		$s1,$t0

  565. 	vshr.u64	$t0,$s0,#@sigma0[0]

  566. 	veor		$s1,$t1				@ sigma1(X[i+14])

  567. 	vshr.u64	$t1,$s0,#@sigma0[1]

  568. 	vadd.i64	@X[$i%8],$s1

  569. 	vshr.u64	$s1,$s0,#@sigma0[2]

  570. 	vsli.64		$t0,$s0,#`64-@sigma0[0]`

  571. 	vsli.64		$t1,$s0,#`64-@sigma0[1]`

  572. 	vext.8		$s0,@X[($i+4)%8],@X[($i+5)%8],#8	@ X[i+9]

  573. 	veor		$s1,$t0

  574. 	vshr.u64	$d0,$e,#@Sigma1[0]		@ from NEON_00_15

  575. 	vadd.i64	@X[$i%8],$s0

  576. 	vshr.u64	$d1,$e,#@Sigma1[1]		@ from NEON_00_15

  577. 	veor		$s1,$t1				@ sigma0(X[i+1])

  578. 	vshr.u64	$d2,$e,#@Sigma1[2]		@ from NEON_00_15

  579. 	vadd.i64	@X[$i%8],$s1

  580. ___

  581. 	&NEON_00_15(2*$i,@_);

  582. }

  583. 

  584. $code.=<<___;

  585. #if __ARM_MAX_ARCH__>=7

  586. .arch	armv7-a

  587. .fpu	neon

  588. 

  589. .global	sha512_block_data_order_neon

  590. .type	sha512_block_data_order_neon,%function

  591. .align	4

  592. sha512_block_data_order_neon:

  593. .LNEON:

  594. 	dmb				@ errata #451034 on early Cortex A8

  595. 	add	$len,$inp,$len,lsl#7	@ len to point at the end of inp

  596. 	VFP_ABI_PUSH

  597. 	adrl	$Ktbl,K512

  598. 	vldmia	$ctx,{$A-$H}		@ load context

  599. .Loop_neon:

  600. ___

  601. for($i=0;$i<16;$i++)	{ &NEON_00_15($i,@V); unshift(@V,pop(@V)); }

  602. $code.=<<___;

  603. 	mov		$cnt,#4

  604. .L16_79_neon:

  605. 	subs		$cnt,#1

  606. ___

  607. for(;$i<32;$i++)	{ &NEON_16_79($i,@V); unshift(@V,pop(@V)); }

  608. $code.=<<___;

  609. 	bne		.L16_79_neon

  610. 

  611. 	 vadd.i64	$A,d30		@ h+=Maj from the past

  612. 	vldmia		$ctx,{d24-d31}	@ load context to temp

  613. 	vadd.i64	q8,q12		@ vectorized accumulate

  614. 	vadd.i64	q9,q13

  615. 	vadd.i64	q10,q14

  616. 	vadd.i64	q11,q15

  617. 	vstmia		$ctx,{$A-$H}	@ save context

  618. 	teq		$inp,$len

  619. 	sub		$Ktbl,#640	@ rewind K512

  620. 	bne		.Loop_neon

  621. 

  622. 	VFP_ABI_POP

  623. 	ret				@ bx lr

  624. .size	sha512_block_data_order_neon,.-sha512_block_data_order_neon

  625. #endif

  626. ___

  627. }

  628. $code.=<<___;

  629. .asciz	"SHA512 block transform for ARMv4/NEON, CRYPTOGAMS by <appro\@openssl.org>"

  630. .align	2

  631. #if __ARM_MAX_ARCH__>=7 && !defined(__KERNEL__)

  632. .comm	OPENSSL_armcap_P,4,4

  633. .hidden	OPENSSL_armcap_P

  634. #endif

  635. ___

  636. 

  637. $code =~ s/\`([^\`]*)\`/eval $1/gem;

  638. $code =~ s/\bbx\s+lr\b/.word\t0xe12fff1e/gm;	# make it possible to compile with -march=armv4

  639. $code =~ s/\bret\b/bx	lr/gm;

  640. 

  641. open SELF,$0;

  642. while(<SELF>) {

  643. 	next if (/^#!/);

  644. 	last if (!s/^#/@/ and !/^$/);

  645. 	print;

  646. }

  647. close SELF;

  648. 

  649. print $code;

  650. close STDOUT; # enforce flush