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gitea/vendor/github.com/klauspost/crc32/crc32_amd64.s

crc32_amd64.s 6.0KB
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  1. // Copyright 2011 The Go Authors. All rights reserved.

  2. // Use of this source code is governed by a BSD-style

  3. // license that can be found in the LICENSE file.

  4. 

  5. // +build gc

  6. 

  7. #define NOSPLIT 4

  8. #define RODATA 8

  9. 

  10. // castagnoliSSE42 updates the (non-inverted) crc with the given buffer.

  11. //

  12. // func castagnoliSSE42(crc uint32, p []byte) uint32

  13. TEXT ·castagnoliSSE42(SB), NOSPLIT, $0

  14. 	MOVL crc+0(FP), AX    // CRC value

  15. 	MOVQ p+8(FP), SI      // data pointer

  16. 	MOVQ p_len+16(FP), CX // len(p)

  17. 

  18. 	// If there are fewer than 8 bytes to process, skip alignment.

  19. 	CMPQ CX, $8

  20. 	JL   less_than_8

  21. 

  22. 	MOVQ SI, BX

  23. 	ANDQ $7, BX

  24. 	JZ   aligned

  25. 

  26. 	// Process the first few bytes to 8-byte align the input.

  27. 

  28. 	// BX = 8 - BX. We need to process this many bytes to align.

  29. 	SUBQ $1, BX

  30. 	XORQ $7, BX

  31. 

  32. 	BTQ $0, BX

  33. 	JNC align_2

  34. 

  35. 	CRC32B (SI), AX

  36. 	DECQ   CX

  37. 	INCQ   SI

  38. 

  39. align_2:

  40. 	BTQ $1, BX

  41. 	JNC align_4

  42. 

  43. 	// CRC32W (SI), AX

  44. 	BYTE $0x66; BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06

  45. 

  46. 	SUBQ $2, CX

  47. 	ADDQ $2, SI

  48. 

  49. align_4:

  50. 	BTQ $2, BX

  51. 	JNC aligned

  52. 

  53. 	// CRC32L (SI), AX

  54. 	BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06

  55. 

  56. 	SUBQ $4, CX

  57. 	ADDQ $4, SI

  58. 

  59. aligned:

  60. 	// The input is now 8-byte aligned and we can process 8-byte chunks.

  61. 	CMPQ CX, $8

  62. 	JL   less_than_8

  63. 

  64. 	CRC32Q (SI), AX

  65. 	ADDQ   $8, SI

  66. 	SUBQ   $8, CX

  67. 	JMP    aligned

  68. 

  69. less_than_8:

  70. 	// We may have some bytes left over; process 4 bytes, then 2, then 1.

  71. 	BTQ $2, CX

  72. 	JNC less_than_4

  73. 

  74. 	// CRC32L (SI), AX

  75. 	BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06

  76. 	ADDQ $4, SI

  77. 

  78. less_than_4:

  79. 	BTQ $1, CX

  80. 	JNC less_than_2

  81. 

  82. 	// CRC32W (SI), AX

  83. 	BYTE $0x66; BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06

  84. 	ADDQ $2, SI

  85. 

  86. less_than_2:

  87. 	BTQ $0, CX

  88. 	JNC done

  89. 

  90. 	CRC32B (SI), AX

  91. 

  92. done:

  93. 	MOVL AX, ret+32(FP)

  94. 	RET

  95. 

  96. // castagnoliSSE42Triple updates three (non-inverted) crcs with (24*rounds)

  97. // bytes from each buffer.

  98. //

  99. // func castagnoliSSE42Triple(

  100. //     crc1, crc2, crc3 uint32,

  101. //     a, b, c []byte,

  102. //     rounds uint32,

  103. // ) (retA uint32, retB uint32, retC uint32)

  104. TEXT ·castagnoliSSE42Triple(SB), NOSPLIT, $0

  105. 	MOVL crcA+0(FP), AX

  106. 	MOVL crcB+4(FP), CX

  107. 	MOVL crcC+8(FP), DX

  108. 

  109. 	MOVQ a+16(FP), R8  // data pointer

  110. 	MOVQ b+40(FP), R9  // data pointer

  111. 	MOVQ c+64(FP), R10 // data pointer

  112. 

  113. 	MOVL rounds+88(FP), R11

  114. 

  115. loop:

  116. 	CRC32Q (R8), AX

  117. 	CRC32Q (R9), CX

  118. 	CRC32Q (R10), DX

  119. 

  120. 	CRC32Q 8(R8), AX

  121. 	CRC32Q 8(R9), CX

  122. 	CRC32Q 8(R10), DX

  123. 

  124. 	CRC32Q 16(R8), AX

  125. 	CRC32Q 16(R9), CX

  126. 	CRC32Q 16(R10), DX

  127. 

  128. 	ADDQ $24, R8

  129. 	ADDQ $24, R9

  130. 	ADDQ $24, R10

  131. 

  132. 	DECQ R11

  133. 	JNZ  loop

  134. 

  135. 	MOVL AX, retA+96(FP)

  136. 	MOVL CX, retB+100(FP)

  137. 	MOVL DX, retC+104(FP)

  138. 	RET

  139. 

  140. // func haveSSE42() bool

  141. TEXT ·haveSSE42(SB), NOSPLIT, $0

  142. 	XORQ AX, AX

  143. 	INCL AX

  144. 	CPUID

  145. 	SHRQ $20, CX

  146. 	ANDQ $1, CX

  147. 	MOVB CX, ret+0(FP)

  148. 	RET

  149. 

  150. // func haveCLMUL() bool

  151. TEXT ·haveCLMUL(SB), NOSPLIT, $0

  152. 	XORQ AX, AX

  153. 	INCL AX

  154. 	CPUID

  155. 	SHRQ $1, CX

  156. 	ANDQ $1, CX

  157. 	MOVB CX, ret+0(FP)

  158. 	RET

  159. 

  160. // func haveSSE41() bool

  161. TEXT ·haveSSE41(SB), NOSPLIT, $0

  162. 	XORQ AX, AX

  163. 	INCL AX

  164. 	CPUID

  165. 	SHRQ $19, CX

  166. 	ANDQ $1, CX

  167. 	MOVB CX, ret+0(FP)

  168. 	RET

  169. 

  170. // CRC32 polynomial data

  171. //

  172. // These constants are lifted from the

  173. // Linux kernel, since they avoid the costly

  174. // PSHUFB 16 byte reversal proposed in the

  175. // original Intel paper.

  176. DATA r2r1kp<>+0(SB)/8, $0x154442bd4

  177. DATA r2r1kp<>+8(SB)/8, $0x1c6e41596

  178. DATA r4r3kp<>+0(SB)/8, $0x1751997d0

  179. DATA r4r3kp<>+8(SB)/8, $0x0ccaa009e

  180. DATA rupolykp<>+0(SB)/8, $0x1db710641

  181. DATA rupolykp<>+8(SB)/8, $0x1f7011641

  182. DATA r5kp<>+0(SB)/8, $0x163cd6124

  183. 

  184. GLOBL r2r1kp<>(SB), RODATA, $16

  185. GLOBL r4r3kp<>(SB), RODATA, $16

  186. GLOBL rupolykp<>(SB), RODATA, $16

  187. GLOBL r5kp<>(SB), RODATA, $8

  188. 

  189. // Based on http://www.intel.com/content/dam/www/public/us/en/documents/white-papers/fast-crc-computation-generic-polynomials-pclmulqdq-paper.pdf

  190. // len(p) must be at least 64, and must be a multiple of 16.

  191. 

  192. // func ieeeCLMUL(crc uint32, p []byte) uint32

  193. TEXT ·ieeeCLMUL(SB), NOSPLIT, $0

  194. 	MOVL crc+0(FP), X0    // Initial CRC value

  195. 	MOVQ p+8(FP), SI      // data pointer

  196. 	MOVQ p_len+16(FP), CX // len(p)

  197. 

  198. 	MOVOU (SI), X1

  199. 	MOVOU 16(SI), X2

  200. 	MOVOU 32(SI), X3

  201. 	MOVOU 48(SI), X4

  202. 	PXOR  X0, X1

  203. 	ADDQ  $64, SI    // buf+=64

  204. 	SUBQ  $64, CX    // len-=64

  205. 	CMPQ  CX, $64    // Less than 64 bytes left

  206. 	JB    remain64

  207. 

  208. 	MOVOA r2r1kp<>+0(SB), X0

  209. 

  210. loopback64:

  211. 	MOVOA X1, X5

  212. 	MOVOA X2, X6

  213. 	MOVOA X3, X7

  214. 	MOVOA X4, X8

  215. 

  216. 	PCLMULQDQ $0, X0, X1

  217. 	PCLMULQDQ $0, X0, X2

  218. 	PCLMULQDQ $0, X0, X3

  219. 	PCLMULQDQ $0, X0, X4

  220. 

  221. 	// Load next early

  222. 	MOVOU (SI), X11

  223. 	MOVOU 16(SI), X12

  224. 	MOVOU 32(SI), X13

  225. 	MOVOU 48(SI), X14

  226. 

  227. 	PCLMULQDQ $0x11, X0, X5

  228. 	PCLMULQDQ $0x11, X0, X6

  229. 	PCLMULQDQ $0x11, X0, X7

  230. 	PCLMULQDQ $0x11, X0, X8

  231. 

  232. 	PXOR X5, X1

  233. 	PXOR X6, X2

  234. 	PXOR X7, X3

  235. 	PXOR X8, X4

  236. 

  237. 	PXOR X11, X1

  238. 	PXOR X12, X2

  239. 	PXOR X13, X3

  240. 	PXOR X14, X4

  241. 

  242. 	ADDQ $0x40, DI

  243. 	ADDQ $64, SI    // buf+=64

  244. 	SUBQ $64, CX    // len-=64

  245. 	CMPQ CX, $64    // Less than 64 bytes left?

  246. 	JGE  loopback64

  247. 

  248. 	// Fold result into a single register (X1)

  249. remain64:

  250. 	MOVOA r4r3kp<>+0(SB), X0

  251. 

  252. 	MOVOA     X1, X5

  253. 	PCLMULQDQ $0, X0, X1

  254. 	PCLMULQDQ $0x11, X0, X5

  255. 	PXOR      X5, X1

  256. 	PXOR      X2, X1

  257. 

  258. 	MOVOA     X1, X5

  259. 	PCLMULQDQ $0, X0, X1

  260. 	PCLMULQDQ $0x11, X0, X5

  261. 	PXOR      X5, X1

  262. 	PXOR      X3, X1

  263. 

  264. 	MOVOA     X1, X5

  265. 	PCLMULQDQ $0, X0, X1

  266. 	PCLMULQDQ $0x11, X0, X5

  267. 	PXOR      X5, X1

  268. 	PXOR      X4, X1

  269. 

  270. 	// If there is less than 16 bytes left we are done

  271. 	CMPQ CX, $16

  272. 	JB   finish

  273. 

  274. 	// Encode 16 bytes

  275. remain16:

  276. 	MOVOU     (SI), X10

  277. 	MOVOA     X1, X5

  278. 	PCLMULQDQ $0, X0, X1

  279. 	PCLMULQDQ $0x11, X0, X5

  280. 	PXOR      X5, X1

  281. 	PXOR      X10, X1

  282. 	SUBQ      $16, CX

  283. 	ADDQ      $16, SI

  284. 	CMPQ      CX, $16

  285. 	JGE       remain16

  286. 

  287. finish:

  288. 	// Fold final result into 32 bits and return it

  289. 	PCMPEQB   X3, X3

  290. 	PCLMULQDQ $1, X1, X0

  291. 	PSRLDQ    $8, X1

  292. 	PXOR      X0, X1

  293. 

  294. 	MOVOA X1, X2

  295. 	MOVQ  r5kp<>+0(SB), X0

  296. 

  297. 	// Creates 32 bit mask. Note that we don't care about upper half.

  298. 	PSRLQ $32, X3

  299. 

  300. 	PSRLDQ    $4, X2

  301. 	PAND      X3, X1

  302. 	PCLMULQDQ $0, X0, X1

  303. 	PXOR      X2, X1

  304. 

  305. 	MOVOA rupolykp<>+0(SB), X0

  306. 

  307. 	MOVOA     X1, X2

  308. 	PAND      X3, X1

  309. 	PCLMULQDQ $0x10, X0, X1

  310. 	PAND      X3, X1

  311. 	PCLMULQDQ $0, X0, X1

  312. 	PXOR      X2, X1

  313. 

  314. 	// PEXTRD   $1, X1, AX  (SSE 4.1)

  315. 	BYTE $0x66; BYTE $0x0f; BYTE $0x3a

  316. 	BYTE $0x16; BYTE $0xc8; BYTE $0x01

  317. 	MOVL AX, ret+32(FP)

  318. 

  319. 	RET