github.com/parquet-go/parquet-go@v0.20.0/bloom/xxhash/sum64uint_amd64.s (about) 1 //go:build !purego 2 3 #include "textflag.h" 4 5 /* 6 The algorithms in this file are assembly versions of the Go functions in the 7 sum64uint_default.go file. 8 9 The implementations are mostly direct translations of the Go code to assembly, 10 leveraging SIMD instructions to process chunks of the input variables in 11 parallel at each loop iteration. To maximize utilization of the CPU capacity, 12 some of the functions unroll two steps of the vectorized loop per iteration, 13 which yields further throughput because the CPU is able to process some of the 14 instruction from the two steps in parallel due to having no data dependencies 15 between the inputs and outputs. 16 17 The use of AVX-512 yields a significant increase in throughput on all the 18 algorithms, in most part thanks to the VPMULLQ instructions which compute 19 8 x 64 bits multiplication. There were no equivalent instruction in AVX2, which 20 required emulating vector multiplication with a combination of 32 bits multiply, 21 additions, shifts, and masks: the amount of instructions and data dependencies 22 resulted in the AVX2 code yielding equivalent performance characteristics for a 23 much higher complexity. 24 25 The benchmark results below showcase the improvements that the AVX-512 code 26 yields on the XXH64 algorithms: 27 28 name old speed new speed delta 29 MultiSum64Uint8/4KB 4.97GB/s ± 0% 14.59GB/s ± 1% +193.73% (p=0.000 n=10+10) 30 MultiSum64Uint16/4KB 3.55GB/s ± 0% 9.46GB/s ± 0% +166.20% (p=0.000 n=10+9) 31 MultiSum64Uint32/4KB 4.48GB/s ± 0% 13.93GB/s ± 1% +210.93% (p=0.000 n=10+10) 32 MultiSum64Uint64/4KB 3.57GB/s ± 0% 11.12GB/s ± 1% +211.73% (p=0.000 n=9+10) 33 MultiSum64Uint128/4KB 2.54GB/s ± 0% 6.49GB/s ± 1% +155.69% (p=0.000 n=10+10) 34 35 name old hash/s new hash/s delta 36 MultiSum64Uint8/4KB 621M ± 0% 1823M ± 1% +193.73% (p=0.000 n=10+10) 37 MultiSum64Uint16/4KB 444M ± 0% 1182M ± 0% +166.20% (p=0.000 n=10+9) 38 MultiSum64Uint32/4KB 560M ± 0% 1742M ± 1% +210.93% (p=0.000 n=10+10) 39 MultiSum64Uint64/4KB 446M ± 0% 1391M ± 1% +211.73% (p=0.000 n=9+10) 40 MultiSum64Uint128/4KB 317M ± 0% 811M ± 1% +155.69% (p=0.000 n=10+10) 41 42 The functions perform runtime detection of AVX-512 support by testing the value 43 of the xxhash.hasAVX512 variable declared and initialized in sum64uint_amd64.go. 44 Branch mispredictions on those tests are very unlikely since the value is never 45 modified by the application. The cost of the comparisons are also amortized by 46 the bulk APIs of the MultiSum64* functions (a single test is required per call). 47 48 If a bug is suspected in the vectorized code, compiling the program or running 49 the tests with -tags=purego can help verify whether the behavior changes when 50 the program does not use the assembly versions. 51 52 Maintenance of these functions can be complex; however, the XXH64 algorithm is 53 unlikely to evolve, and the implementations unlikely to change. The tests in 54 sum64uint_test.go compare the outputs of MultiSum64* functions with the 55 reference xxhash.Sum64 function, future maintainers can rely on those tests 56 passing as a guarantee that they have not introduced regressions. 57 */ 58 59 #define PRIME1 0x9E3779B185EBCA87 60 #define PRIME2 0xC2B2AE3D27D4EB4F 61 #define PRIME3 0x165667B19E3779F9 62 #define PRIME4 0x85EBCA77C2B2AE63 63 #define PRIME5 0x27D4EB2F165667C5 64 65 #define prime1 R12 66 #define prime2 R13 67 #define prime3 R14 68 #define prime4 R15 69 #define prime5 R15 // same as prime4 because they are not used together 70 71 #define prime1ZMM Z12 72 #define prime2ZMM Z13 73 #define prime3ZMM Z14 74 #define prime4ZMM Z15 75 #define prime5ZMM Z15 76 77 DATA prime1vec<>+0(SB)/8, $PRIME1 78 DATA prime1vec<>+8(SB)/8, $PRIME1 79 DATA prime1vec<>+16(SB)/8, $PRIME1 80 DATA prime1vec<>+24(SB)/8, $PRIME1 81 DATA prime1vec<>+32(SB)/8, $PRIME1 82 DATA prime1vec<>+40(SB)/8, $PRIME1 83 DATA prime1vec<>+48(SB)/8, $PRIME1 84 DATA prime1vec<>+56(SB)/8, $PRIME1 85 GLOBL prime1vec<>(SB), RODATA|NOPTR, $64 86 87 DATA prime2vec<>+0(SB)/8, $PRIME2 88 DATA prime2vec<>+8(SB)/8, $PRIME2 89 DATA prime2vec<>+16(SB)/8, $PRIME2 90 DATA prime2vec<>+24(SB)/8, $PRIME2 91 DATA prime2vec<>+32(SB)/8, $PRIME2 92 DATA prime2vec<>+40(SB)/8, $PRIME2 93 DATA prime2vec<>+48(SB)/8, $PRIME2 94 DATA prime2vec<>+56(SB)/8, $PRIME2 95 GLOBL prime2vec<>(SB), RODATA|NOPTR, $64 96 97 DATA prime3vec<>+0(SB)/8, $PRIME3 98 DATA prime3vec<>+8(SB)/8, $PRIME3 99 DATA prime3vec<>+16(SB)/8, $PRIME3 100 DATA prime3vec<>+24(SB)/8, $PRIME3 101 DATA prime3vec<>+32(SB)/8, $PRIME3 102 DATA prime3vec<>+40(SB)/8, $PRIME3 103 DATA prime3vec<>+48(SB)/8, $PRIME3 104 DATA prime3vec<>+56(SB)/8, $PRIME3 105 GLOBL prime3vec<>(SB), RODATA|NOPTR, $64 106 107 DATA prime4vec<>+0(SB)/8, $PRIME4 108 DATA prime4vec<>+8(SB)/8, $PRIME4 109 DATA prime4vec<>+16(SB)/8, $PRIME4 110 DATA prime4vec<>+24(SB)/8, $PRIME4 111 DATA prime4vec<>+32(SB)/8, $PRIME4 112 DATA prime4vec<>+40(SB)/8, $PRIME4 113 DATA prime4vec<>+48(SB)/8, $PRIME4 114 DATA prime4vec<>+56(SB)/8, $PRIME4 115 GLOBL prime4vec<>(SB), RODATA|NOPTR, $64 116 117 DATA prime5vec<>+0(SB)/8, $PRIME5 118 DATA prime5vec<>+8(SB)/8, $PRIME5 119 DATA prime5vec<>+16(SB)/8, $PRIME5 120 DATA prime5vec<>+24(SB)/8, $PRIME5 121 DATA prime5vec<>+32(SB)/8, $PRIME5 122 DATA prime5vec<>+40(SB)/8, $PRIME5 123 DATA prime5vec<>+48(SB)/8, $PRIME5 124 DATA prime5vec<>+56(SB)/8, $PRIME5 125 GLOBL prime5vec<>(SB), RODATA|NOPTR, $64 126 127 DATA prime5vec1<>+0(SB)/8, $PRIME5+1 128 DATA prime5vec1<>+8(SB)/8, $PRIME5+1 129 DATA prime5vec1<>+16(SB)/8, $PRIME5+1 130 DATA prime5vec1<>+24(SB)/8, $PRIME5+1 131 DATA prime5vec1<>+32(SB)/8, $PRIME5+1 132 DATA prime5vec1<>+40(SB)/8, $PRIME5+1 133 DATA prime5vec1<>+48(SB)/8, $PRIME5+1 134 DATA prime5vec1<>+56(SB)/8, $PRIME5+1 135 GLOBL prime5vec1<>(SB), RODATA|NOPTR, $64 136 137 DATA prime5vec2<>+0(SB)/8, $PRIME5+2 138 DATA prime5vec2<>+8(SB)/8, $PRIME5+2 139 DATA prime5vec2<>+16(SB)/8, $PRIME5+2 140 DATA prime5vec2<>+24(SB)/8, $PRIME5+2 141 DATA prime5vec2<>+32(SB)/8, $PRIME5+2 142 DATA prime5vec2<>+40(SB)/8, $PRIME5+2 143 DATA prime5vec2<>+48(SB)/8, $PRIME5+2 144 DATA prime5vec2<>+56(SB)/8, $PRIME5+2 145 GLOBL prime5vec2<>(SB), RODATA|NOPTR, $64 146 147 DATA prime5vec4<>+0(SB)/8, $PRIME5+4 148 DATA prime5vec4<>+8(SB)/8, $PRIME5+4 149 DATA prime5vec4<>+16(SB)/8, $PRIME5+4 150 DATA prime5vec4<>+24(SB)/8, $PRIME5+4 151 DATA prime5vec4<>+32(SB)/8, $PRIME5+4 152 DATA prime5vec4<>+40(SB)/8, $PRIME5+4 153 DATA prime5vec4<>+48(SB)/8, $PRIME5+4 154 DATA prime5vec4<>+56(SB)/8, $PRIME5+4 155 GLOBL prime5vec4<>(SB), RODATA|NOPTR, $64 156 157 DATA prime5vec8<>+0(SB)/8, $PRIME5+8 158 DATA prime5vec8<>+8(SB)/8, $PRIME5+8 159 DATA prime5vec8<>+16(SB)/8, $PRIME5+8 160 DATA prime5vec8<>+24(SB)/8, $PRIME5+8 161 DATA prime5vec8<>+32(SB)/8, $PRIME5+8 162 DATA prime5vec8<>+40(SB)/8, $PRIME5+8 163 DATA prime5vec8<>+48(SB)/8, $PRIME5+8 164 DATA prime5vec8<>+56(SB)/8, $PRIME5+8 165 GLOBL prime5vec8<>(SB), RODATA|NOPTR, $64 166 167 DATA prime5vec16<>+0(SB)/8, $PRIME5+16 168 DATA prime5vec16<>+8(SB)/8, $PRIME5+16 169 DATA prime5vec16<>+16(SB)/8, $PRIME5+16 170 DATA prime5vec16<>+24(SB)/8, $PRIME5+16 171 DATA prime5vec16<>+32(SB)/8, $PRIME5+16 172 DATA prime5vec16<>+40(SB)/8, $PRIME5+16 173 DATA prime5vec16<>+48(SB)/8, $PRIME5+16 174 DATA prime5vec16<>+56(SB)/8, $PRIME5+16 175 GLOBL prime5vec16<>(SB), RODATA|NOPTR, $64 176 177 DATA lowbytemask<>+0(SB)/8, $0xFF 178 DATA lowbytemask<>+8(SB)/8, $0xFF 179 DATA lowbytemask<>+16(SB)/8, $0xFF 180 DATA lowbytemask<>+24(SB)/8, $0xFF 181 DATA lowbytemask<>+32(SB)/8, $0xFF 182 DATA lowbytemask<>+40(SB)/8, $0xFF 183 DATA lowbytemask<>+48(SB)/8, $0xFF 184 DATA lowbytemask<>+56(SB)/8, $0xFF 185 GLOBL lowbytemask<>(SB), RODATA|NOPTR, $64 186 187 DATA vpermi2qeven<>+0(SB)/8, $0 188 DATA vpermi2qeven<>+8(SB)/8, $2 189 DATA vpermi2qeven<>+16(SB)/8, $4 190 DATA vpermi2qeven<>+24(SB)/8, $6 191 DATA vpermi2qeven<>+32(SB)/8, $(1<<3)|0 192 DATA vpermi2qeven<>+40(SB)/8, $(1<<3)|2 193 DATA vpermi2qeven<>+48(SB)/8, $(1<<3)|4 194 DATA vpermi2qeven<>+56(SB)/8, $(1<<3)|6 195 GLOBL vpermi2qeven<>(SB), RODATA|NOPTR, $64 196 197 DATA vpermi2qodd<>+0(SB)/8, $1 198 DATA vpermi2qodd<>+8(SB)/8, $3 199 DATA vpermi2qodd<>+16(SB)/8, $5 200 DATA vpermi2qodd<>+24(SB)/8, $7 201 DATA vpermi2qodd<>+32(SB)/8, $(1<<3)|1 202 DATA vpermi2qodd<>+40(SB)/8, $(1<<3)|3 203 DATA vpermi2qodd<>+48(SB)/8, $(1<<3)|5 204 DATA vpermi2qodd<>+56(SB)/8, $(1<<3)|7 205 GLOBL vpermi2qodd<>(SB), RODATA|NOPTR, $64 206 207 #define round(input, acc) \ 208 IMULQ prime2, input \ 209 ADDQ input, acc \ 210 ROLQ $31, acc \ 211 IMULQ prime1, acc 212 213 #define avalanche(tmp, acc) \ 214 MOVQ acc, tmp \ 215 SHRQ $33, tmp \ 216 XORQ tmp, acc \ 217 IMULQ prime2, acc \ 218 MOVQ acc, tmp \ 219 SHRQ $29, tmp \ 220 XORQ tmp, acc \ 221 IMULQ prime3, acc \ 222 MOVQ acc, tmp \ 223 SHRQ $32, tmp \ 224 XORQ tmp, acc 225 226 #define round8x64(input, acc) \ 227 VPMULLQ prime2ZMM, input, input \ 228 VPADDQ input, acc, acc \ 229 VPROLQ $31, acc, acc \ 230 VPMULLQ prime1ZMM, acc, acc 231 232 #define avalanche8x64(tmp, acc) \ 233 VPSRLQ $33, acc, tmp \ 234 VPXORQ tmp, acc, acc \ 235 VPMULLQ prime2ZMM, acc, acc \ 236 VPSRLQ $29, acc, tmp \ 237 VPXORQ tmp, acc, acc \ 238 VPMULLQ prime3ZMM, acc, acc \ 239 VPSRLQ $32, acc, tmp \ 240 VPXORQ tmp, acc, acc 241 242 // func MultiSum64Uint8(h []uint64, v []uint8) int 243 TEXT ·MultiSum64Uint8(SB), NOSPLIT, $0-54 244 MOVQ $PRIME1, prime1 245 MOVQ $PRIME2, prime2 246 MOVQ $PRIME3, prime3 247 MOVQ $PRIME5, prime5 248 249 MOVQ h_base+0(FP), AX 250 MOVQ h_len+8(FP), CX 251 MOVQ v_base+24(FP), BX 252 MOVQ v_len+32(FP), DX 253 254 CMPQ CX, DX 255 CMOVQGT DX, CX 256 MOVQ CX, ret+48(FP) 257 258 XORQ SI, SI 259 CMPQ CX, $32 260 JB loop 261 CMPB ·hasAVX512(SB), $0 262 JE loop 263 264 MOVQ CX, DI 265 SHRQ $5, DI 266 SHLQ $5, DI 267 268 VMOVDQU64 prime1vec<>(SB), prime1ZMM 269 VMOVDQU64 prime2vec<>(SB), prime2ZMM 270 VMOVDQU64 prime3vec<>(SB), prime3ZMM 271 VMOVDQU64 prime5vec<>(SB), prime5ZMM 272 VMOVDQU64 prime5vec1<>(SB), Z6 273 loop32x64: 274 VMOVDQA64 Z6, Z0 275 VMOVDQA64 Z6, Z3 276 VMOVDQA64 Z6, Z20 277 VMOVDQA64 Z6, Z23 278 VPMOVZXBQ (BX)(SI*1), Z1 279 VPMOVZXBQ 8(BX)(SI*1), Z4 280 VPMOVZXBQ 16(BX)(SI*1), Z21 281 VPMOVZXBQ 24(BX)(SI*1), Z24 282 283 VPMULLQ prime5ZMM, Z1, Z1 284 VPMULLQ prime5ZMM, Z4, Z4 285 VPMULLQ prime5ZMM, Z21, Z21 286 VPMULLQ prime5ZMM, Z24, Z24 287 VPXORQ Z1, Z0, Z0 288 VPXORQ Z4, Z3, Z3 289 VPXORQ Z21, Z20, Z20 290 VPXORQ Z24, Z23, Z23 291 VPROLQ $11, Z0, Z0 292 VPROLQ $11, Z3, Z3 293 VPROLQ $11, Z20, Z20 294 VPROLQ $11, Z23, Z23 295 VPMULLQ prime1ZMM, Z0, Z0 296 VPMULLQ prime1ZMM, Z3, Z3 297 VPMULLQ prime1ZMM, Z20, Z20 298 VPMULLQ prime1ZMM, Z23, Z23 299 300 avalanche8x64(Z1, Z0) 301 avalanche8x64(Z4, Z3) 302 avalanche8x64(Z21, Z20) 303 avalanche8x64(Z24, Z23) 304 305 VMOVDQU64 Z0, (AX)(SI*8) 306 VMOVDQU64 Z3, 64(AX)(SI*8) 307 VMOVDQU64 Z20, 128(AX)(SI*8) 308 VMOVDQU64 Z23, 192(AX)(SI*8) 309 ADDQ $32, SI 310 CMPQ SI, DI 311 JB loop32x64 312 VZEROUPPER 313 loop: 314 CMPQ SI, CX 315 JE done 316 MOVQ $PRIME5+1, R8 317 MOVBQZX (BX)(SI*1), R9 318 319 IMULQ prime5, R9 320 XORQ R9, R8 321 ROLQ $11, R8 322 IMULQ prime1, R8 323 avalanche(R9, R8) 324 325 MOVQ R8, (AX)(SI*8) 326 INCQ SI 327 JMP loop 328 done: 329 RET 330 331 // func MultiSum64Uint16(h []uint64, v []uint16) int 332 TEXT ·MultiSum64Uint16(SB), NOSPLIT, $0-54 333 MOVQ $PRIME1, prime1 334 MOVQ $PRIME2, prime2 335 MOVQ $PRIME3, prime3 336 MOVQ $PRIME5, prime5 337 338 MOVQ h_base+0(FP), AX 339 MOVQ h_len+8(FP), CX 340 MOVQ v_base+24(FP), BX 341 MOVQ v_len+32(FP), DX 342 343 CMPQ CX, DX 344 CMOVQGT DX, CX 345 MOVQ CX, ret+48(FP) 346 347 XORQ SI, SI 348 CMPQ CX, $16 349 JB loop 350 CMPB ·hasAVX512(SB), $0 351 JE loop 352 353 MOVQ CX, DI 354 SHRQ $4, DI 355 SHLQ $4, DI 356 357 VMOVDQU64 prime1vec<>(SB), prime1ZMM 358 VMOVDQU64 prime2vec<>(SB), prime2ZMM 359 VMOVDQU64 prime3vec<>(SB), prime3ZMM 360 VMOVDQU64 prime5vec<>(SB), prime5ZMM 361 VMOVDQU64 prime5vec2<>(SB), Z6 362 VMOVDQU64 lowbytemask<>(SB), Z7 363 loop16x64: 364 VMOVDQA64 Z6, Z0 365 VMOVDQA64 Z6, Z3 366 VPMOVZXWQ (BX)(SI*2), Z1 367 VPMOVZXWQ 16(BX)(SI*2), Z4 368 369 VMOVDQA64 Z1, Z8 370 VMOVDQA64 Z4, Z9 371 VPSRLQ $8, Z8, Z8 372 VPSRLQ $8, Z9, Z9 373 VPANDQ Z7, Z1, Z1 374 VPANDQ Z7, Z4, Z4 375 376 VPMULLQ prime5ZMM, Z1, Z1 377 VPMULLQ prime5ZMM, Z4, Z4 378 VPXORQ Z1, Z0, Z0 379 VPXORQ Z4, Z3, Z3 380 VPROLQ $11, Z0, Z0 381 VPROLQ $11, Z3, Z3 382 VPMULLQ prime1ZMM, Z0, Z0 383 VPMULLQ prime1ZMM, Z3, Z3 384 385 VPMULLQ prime5ZMM, Z8, Z8 386 VPMULLQ prime5ZMM, Z9, Z9 387 VPXORQ Z8, Z0, Z0 388 VPXORQ Z9, Z3, Z3 389 VPROLQ $11, Z0, Z0 390 VPROLQ $11, Z3, Z3 391 VPMULLQ prime1ZMM, Z0, Z0 392 VPMULLQ prime1ZMM, Z3, Z3 393 394 avalanche8x64(Z1, Z0) 395 avalanche8x64(Z4, Z3) 396 397 VMOVDQU64 Z0, (AX)(SI*8) 398 VMOVDQU64 Z3, 64(AX)(SI*8) 399 ADDQ $16, SI 400 CMPQ SI, DI 401 JB loop16x64 402 VZEROUPPER 403 loop: 404 CMPQ SI, CX 405 JE done 406 MOVQ $PRIME5+2, R8 407 MOVWQZX (BX)(SI*2), R9 408 409 MOVQ R9, R10 410 SHRQ $8, R10 411 ANDQ $0xFF, R9 412 413 IMULQ prime5, R9 414 XORQ R9, R8 415 ROLQ $11, R8 416 IMULQ prime1, R8 417 418 IMULQ prime5, R10 419 XORQ R10, R8 420 ROLQ $11, R8 421 IMULQ prime1, R8 422 423 avalanche(R9, R8) 424 425 MOVQ R8, (AX)(SI*8) 426 INCQ SI 427 JMP loop 428 done: 429 RET 430 431 // func MultiSum64Uint32(h []uint64, v []uint32) int 432 TEXT ·MultiSum64Uint32(SB), NOSPLIT, $0-54 433 MOVQ $PRIME1, prime1 434 MOVQ $PRIME2, prime2 435 MOVQ $PRIME3, prime3 436 437 MOVQ h_base+0(FP), AX 438 MOVQ h_len+8(FP), CX 439 MOVQ v_base+24(FP), BX 440 MOVQ v_len+32(FP), DX 441 442 CMPQ CX, DX 443 CMOVQGT DX, CX 444 MOVQ CX, ret+48(FP) 445 446 XORQ SI, SI 447 CMPQ CX, $32 448 JB loop 449 CMPB ·hasAVX512(SB), $0 450 JE loop 451 452 MOVQ CX, DI 453 SHRQ $5, DI 454 SHLQ $5, DI 455 456 VMOVDQU64 prime1vec<>(SB), prime1ZMM 457 VMOVDQU64 prime2vec<>(SB), prime2ZMM 458 VMOVDQU64 prime3vec<>(SB), prime3ZMM 459 VMOVDQU64 prime5vec4<>(SB), Z6 460 loop32x64: 461 VMOVDQA64 Z6, Z0 462 VMOVDQA64 Z6, Z3 463 VMOVDQA64 Z6, Z20 464 VMOVDQA64 Z6, Z23 465 VPMOVZXDQ (BX)(SI*4), Z1 466 VPMOVZXDQ 32(BX)(SI*4), Z4 467 VPMOVZXDQ 64(BX)(SI*4), Z21 468 VPMOVZXDQ 96(BX)(SI*4), Z24 469 470 VPMULLQ prime1ZMM, Z1, Z1 471 VPMULLQ prime1ZMM, Z4, Z4 472 VPMULLQ prime1ZMM, Z21, Z21 473 VPMULLQ prime1ZMM, Z24, Z24 474 VPXORQ Z1, Z0, Z0 475 VPXORQ Z4, Z3, Z3 476 VPXORQ Z21, Z20, Z20 477 VPXORQ Z24, Z23, Z23 478 VPROLQ $23, Z0, Z0 479 VPROLQ $23, Z3, Z3 480 VPROLQ $23, Z20, Z20 481 VPROLQ $23, Z23, Z23 482 VPMULLQ prime2ZMM, Z0, Z0 483 VPMULLQ prime2ZMM, Z3, Z3 484 VPMULLQ prime2ZMM, Z20, Z20 485 VPMULLQ prime2ZMM, Z23, Z23 486 VPADDQ prime3ZMM, Z0, Z0 487 VPADDQ prime3ZMM, Z3, Z3 488 VPADDQ prime3ZMM, Z20, Z20 489 VPADDQ prime3ZMM, Z23, Z23 490 491 avalanche8x64(Z1, Z0) 492 avalanche8x64(Z4, Z3) 493 avalanche8x64(Z21, Z20) 494 avalanche8x64(Z24, Z23) 495 496 VMOVDQU64 Z0, (AX)(SI*8) 497 VMOVDQU64 Z3, 64(AX)(SI*8) 498 VMOVDQU64 Z20, 128(AX)(SI*8) 499 VMOVDQU64 Z23, 192(AX)(SI*8) 500 ADDQ $32, SI 501 CMPQ SI, DI 502 JB loop32x64 503 VZEROUPPER 504 loop: 505 CMPQ SI, CX 506 JE done 507 MOVQ $PRIME5+4, R8 508 MOVLQZX (BX)(SI*4), R9 509 510 IMULQ prime1, R9 511 XORQ R9, R8 512 ROLQ $23, R8 513 IMULQ prime2, R8 514 ADDQ prime3, R8 515 avalanche(R9, R8) 516 517 MOVQ R8, (AX)(SI*8) 518 INCQ SI 519 JMP loop 520 done: 521 RET 522 523 // func MultiSum64Uint64(h []uint64, v []uint64) int 524 TEXT ·MultiSum64Uint64(SB), NOSPLIT, $0-54 525 MOVQ $PRIME1, prime1 526 MOVQ $PRIME2, prime2 527 MOVQ $PRIME3, prime3 528 MOVQ $PRIME4, prime4 529 530 MOVQ h_base+0(FP), AX 531 MOVQ h_len+8(FP), CX 532 MOVQ v_base+24(FP), BX 533 MOVQ v_len+32(FP), DX 534 535 CMPQ CX, DX 536 CMOVQGT DX, CX 537 MOVQ CX, ret+48(FP) 538 539 XORQ SI, SI 540 CMPQ CX, $32 541 JB loop 542 CMPB ·hasAVX512(SB), $0 543 JE loop 544 545 MOVQ CX, DI 546 SHRQ $5, DI 547 SHLQ $5, DI 548 549 VMOVDQU64 prime1vec<>(SB), prime1ZMM 550 VMOVDQU64 prime2vec<>(SB), prime2ZMM 551 VMOVDQU64 prime3vec<>(SB), prime3ZMM 552 VMOVDQU64 prime4vec<>(SB), prime4ZMM 553 VMOVDQU64 prime5vec8<>(SB), Z6 554 loop32x64: 555 VMOVDQA64 Z6, Z0 556 VMOVDQA64 Z6, Z3 557 VMOVDQA64 Z6, Z20 558 VMOVDQA64 Z6, Z23 559 VMOVDQU64 (BX)(SI*8), Z1 560 VMOVDQU64 64(BX)(SI*8), Z4 561 VMOVDQU64 128(BX)(SI*8), Z21 562 VMOVDQU64 192(BX)(SI*8), Z24 563 564 VPXORQ Z2, Z2, Z2 565 VPXORQ Z5, Z5, Z5 566 VPXORQ Z22, Z22, Z22 567 VPXORQ Z25, Z25, Z25 568 round8x64(Z1, Z2) 569 round8x64(Z4, Z5) 570 round8x64(Z21, Z22) 571 round8x64(Z24, Z25) 572 573 VPXORQ Z2, Z0, Z0 574 VPXORQ Z5, Z3, Z3 575 VPXORQ Z22, Z20, Z20 576 VPXORQ Z25, Z23, Z23 577 VPROLQ $27, Z0, Z0 578 VPROLQ $27, Z3, Z3 579 VPROLQ $27, Z20, Z20 580 VPROLQ $27, Z23, Z23 581 VPMULLQ prime1ZMM, Z0, Z0 582 VPMULLQ prime1ZMM, Z3, Z3 583 VPMULLQ prime1ZMM, Z20, Z20 584 VPMULLQ prime1ZMM, Z23, Z23 585 VPADDQ prime4ZMM, Z0, Z0 586 VPADDQ prime4ZMM, Z3, Z3 587 VPADDQ prime4ZMM, Z20, Z20 588 VPADDQ prime4ZMM, Z23, Z23 589 590 avalanche8x64(Z1, Z0) 591 avalanche8x64(Z4, Z3) 592 avalanche8x64(Z21, Z20) 593 avalanche8x64(Z24, Z23) 594 595 VMOVDQU64 Z0, (AX)(SI*8) 596 VMOVDQU64 Z3, 64(AX)(SI*8) 597 VMOVDQU64 Z20, 128(AX)(SI*8) 598 VMOVDQU64 Z23, 192(AX)(SI*8) 599 ADDQ $32, SI 600 CMPQ SI, DI 601 JB loop32x64 602 VZEROUPPER 603 loop: 604 CMPQ SI, CX 605 JE done 606 MOVQ $PRIME5+8, R8 607 MOVQ (BX)(SI*8), R9 608 609 XORQ R10, R10 610 round(R9, R10) 611 XORQ R10, R8 612 ROLQ $27, R8 613 IMULQ prime1, R8 614 ADDQ prime4, R8 615 avalanche(R9, R8) 616 617 MOVQ R8, (AX)(SI*8) 618 INCQ SI 619 JMP loop 620 done: 621 RET 622 623 // func MultiSum64Uint128(h []uint64, v [][16]byte) int 624 TEXT ·MultiSum64Uint128(SB), NOSPLIT, $0-54 625 MOVQ $PRIME1, prime1 626 MOVQ $PRIME2, prime2 627 MOVQ $PRIME3, prime3 628 MOVQ $PRIME4, prime4 629 630 MOVQ h_base+0(FP), AX 631 MOVQ h_len+8(FP), CX 632 MOVQ v_base+24(FP), BX 633 MOVQ v_len+32(FP), DX 634 635 CMPQ CX, DX 636 CMOVQGT DX, CX 637 MOVQ CX, ret+48(FP) 638 639 XORQ SI, SI 640 CMPQ CX, $16 641 JB loop 642 CMPB ·hasAVX512(SB), $0 643 JE loop 644 645 MOVQ CX, DI 646 SHRQ $4, DI 647 SHLQ $4, DI 648 649 VMOVDQU64 prime1vec<>(SB), prime1ZMM 650 VMOVDQU64 prime2vec<>(SB), prime2ZMM 651 VMOVDQU64 prime3vec<>(SB), prime3ZMM 652 VMOVDQU64 prime4vec<>(SB), prime4ZMM 653 VMOVDQU64 prime5vec16<>(SB), Z6 654 VMOVDQU64 vpermi2qeven<>(SB), Z7 655 VMOVDQU64 vpermi2qodd<>(SB), Z8 656 loop16x64: 657 // This algorithm is slightly different from the other ones, because it is 658 // the only case where the input values are larger than the output (128 bits 659 // vs 64 bits). 660 // 661 // Computing the XXH64 of 128 bits values requires doing two passes over the 662 // lower and upper 64 bits. The lower and upper quad/ words are split in 663 // separate vectors, the first pass is applied on the vector holding the 664 // lower bits of 8 input values, then the second pass is applied with the 665 // vector holding the upper bits. 666 // 667 // Following the model used in the other functions, we unroll the work of 668 // two consecutive groups of 8 values per loop iteration in order to 669 // maximize utilization of CPU resources. 670 CMPQ SI, DI 671 JE loop 672 VMOVDQA64 Z6, Z0 673 VMOVDQA64 Z6, Z20 674 VMOVDQU64 (BX), Z1 675 VMOVDQU64 64(BX), Z9 676 VMOVDQU64 128(BX), Z21 677 VMOVDQU64 192(BX), Z29 678 679 VMOVDQA64 Z7, Z2 680 VMOVDQA64 Z8, Z3 681 VMOVDQA64 Z7, Z22 682 VMOVDQA64 Z8, Z23 683 684 VPERMI2Q Z9, Z1, Z2 685 VPERMI2Q Z9, Z1, Z3 686 VPERMI2Q Z29, Z21, Z22 687 VPERMI2Q Z29, Z21, Z23 688 689 // Compute the rounds on inputs. 690 VPXORQ Z4, Z4, Z4 691 VPXORQ Z5, Z5, Z5 692 VPXORQ Z24, Z24, Z24 693 VPXORQ Z25, Z25, Z25 694 round8x64(Z2, Z4) 695 round8x64(Z3, Z5) 696 round8x64(Z22, Z24) 697 round8x64(Z23, Z25) 698 699 // Lower 64 bits. 700 VPXORQ Z4, Z0, Z0 701 VPXORQ Z24, Z20, Z20 702 VPROLQ $27, Z0, Z0 703 VPROLQ $27, Z20, Z20 704 VPMULLQ prime1ZMM, Z0, Z0 705 VPMULLQ prime1ZMM, Z20, Z20 706 VPADDQ prime4ZMM, Z0, Z0 707 VPADDQ prime4ZMM, Z20, Z20 708 709 // Upper 64 bits. 710 VPXORQ Z5, Z0, Z0 711 VPXORQ Z25, Z20, Z20 712 VPROLQ $27, Z0, Z0 713 VPROLQ $27, Z20, Z20 714 VPMULLQ prime1ZMM, Z0, Z0 715 VPMULLQ prime1ZMM, Z20, Z20 716 VPADDQ prime4ZMM, Z0, Z0 717 VPADDQ prime4ZMM, Z20, Z20 718 719 avalanche8x64(Z1, Z0) 720 avalanche8x64(Z21, Z20) 721 VMOVDQU64 Z0, (AX)(SI*8) 722 VMOVDQU64 Z20, 64(AX)(SI*8) 723 ADDQ $256, BX 724 ADDQ $16, SI 725 JMP loop16x64 726 VZEROUPPER 727 loop: 728 CMPQ SI, CX 729 JE done 730 MOVQ $PRIME5+16, R8 731 MOVQ (BX), DX 732 MOVQ 8(BX), DI 733 734 XORQ R9, R9 735 XORQ R10, R10 736 round(DX, R9) 737 round(DI, R10) 738 739 XORQ R9, R8 740 ROLQ $27, R8 741 IMULQ prime1, R8 742 ADDQ prime4, R8 743 744 XORQ R10, R8 745 ROLQ $27, R8 746 IMULQ prime1, R8 747 ADDQ prime4, R8 748 749 avalanche(R9, R8) 750 MOVQ R8, (AX)(SI*8) 751 ADDQ $16, BX 752 INCQ SI 753 JMP loop 754 done: 755 RET