1.explicit 2.text 3.ident "ia64.S, Version 2.1" 4.ident "IA-64 ISA artwork by Andy Polyakov <appro@fy.chalmers.se>" 5 6// 7// ==================================================================== 8// Written by Andy Polyakov <appro@fy.chalmers.se> for the OpenSSL 9// project. 10// 11// Rights for redistribution and usage in source and binary forms are 12// granted according to the OpenSSL license. Warranty of any kind is 13// disclaimed. 14// ==================================================================== 15// 16// Version 2.x is Itanium2 re-tune. Few words about how Itanum2 is 17// different from Itanium to this module viewpoint. Most notably, is it 18// "wider" than Itanium? Can you experience loop scalability as 19// discussed in commentary sections? Not really:-( Itanium2 has 6 20// integer ALU ports, i.e. it's 2 ports wider, but it's not enough to 21// spin twice as fast, as I need 8 IALU ports. Amount of floating point 22// ports is the same, i.e. 2, while I need 4. In other words, to this 23// module Itanium2 remains effectively as "wide" as Itanium. Yet it's 24// essentially different in respect to this module, and a re-tune was 25// required. Well, because some intruction latencies has changed. Most 26// noticeably those intensively used: 27// 28// Itanium Itanium2 29// ldf8 9 6 L2 hit 30// ld8 2 1 L1 hit 31// getf 2 5 32// xma[->getf] 7[+1] 4[+0] 33// add[->st8] 1[+1] 1[+0] 34// 35// What does it mean? You might ratiocinate that the original code 36// should run just faster... Because sum of latencies is smaller... 37// Wrong! Note that getf latency increased. This means that if a loop is 38// scheduled for lower latency (as they were), then it will suffer from 39// stall condition and the code will therefore turn anti-scalable, e.g. 40// original bn_mul_words spun at 5*n or 2.5 times slower than expected 41// on Itanium2! What to do? Reschedule loops for Itanium2? But then 42// Itanium would exhibit anti-scalability. So I've chosen to reschedule 43// for worst latency for every instruction aiming for best *all-round* 44// performance. 45 46// Q. How much faster does it get? 47// A. Here is the output from 'openssl speed rsa dsa' for vanilla 48// 0.9.6a compiled with gcc version 2.96 20000731 (Red Hat 49// Linux 7.1 2.96-81): 50// 51// sign verify sign/s verify/s 52// rsa 512 bits 0.0036s 0.0003s 275.3 2999.2 53// rsa 1024 bits 0.0203s 0.0011s 49.3 894.1 54// rsa 2048 bits 0.1331s 0.0040s 7.5 250.9 55// rsa 4096 bits 0.9270s 0.0147s 1.1 68.1 56// sign verify sign/s verify/s 57// dsa 512 bits 0.0035s 0.0043s 288.3 234.8 58// dsa 1024 bits 0.0111s 0.0135s 90.0 74.2 59// 60// And here is similar output but for this assembler 61// implementation:-) 62// 63// sign verify sign/s verify/s 64// rsa 512 bits 0.0021s 0.0001s 549.4 9638.5 65// rsa 1024 bits 0.0055s 0.0002s 183.8 4481.1 66// rsa 2048 bits 0.0244s 0.0006s 41.4 1726.3 67// rsa 4096 bits 0.1295s 0.0018s 7.7 561.5 68// sign verify sign/s verify/s 69// dsa 512 bits 0.0012s 0.0013s 891.9 756.6 70// dsa 1024 bits 0.0023s 0.0028s 440.4 376.2 71// 72// Yes, you may argue that it's not fair comparison as it's 73// possible to craft the C implementation with BN_UMULT_HIGH 74// inline assembler macro. But of course! Here is the output 75// with the macro: 76// 77// sign verify sign/s verify/s 78// rsa 512 bits 0.0020s 0.0002s 495.0 6561.0 79// rsa 1024 bits 0.0086s 0.0004s 116.2 2235.7 80// rsa 2048 bits 0.0519s 0.0015s 19.3 667.3 81// rsa 4096 bits 0.3464s 0.0053s 2.9 187.7 82// sign verify sign/s verify/s 83// dsa 512 bits 0.0016s 0.0020s 613.1 510.5 84// dsa 1024 bits 0.0045s 0.0054s 221.0 183.9 85// 86// My code is still way faster, huh:-) And I believe that even 87// higher performance can be achieved. Note that as keys get 88// longer, performance gain is larger. Why? According to the 89// profiler there is another player in the field, namely 90// BN_from_montgomery consuming larger and larger portion of CPU 91// time as keysize decreases. I therefore consider putting effort 92// to assembler implementation of the following routine: 93// 94// void bn_mul_add_mont (BN_ULONG *rp,BN_ULONG *np,int nl,BN_ULONG n0) 95// { 96// int i,j; 97// BN_ULONG v; 98// 99// for (i=0; i<nl; i++) 100// { 101// v=bn_mul_add_words(rp,np,nl,(rp[0]*n0)&BN_MASK2); 102// nrp++; 103// rp++; 104// if (((nrp[-1]+=v)&BN_MASK2) < v) 105// for (j=0; ((++nrp[j])&BN_MASK2) == 0; j++) ; 106// } 107// } 108// 109// It might as well be beneficial to implement even combaX 110// variants, as it appears as it can literally unleash the 111// performance (see comment section to bn_mul_comba8 below). 112// 113// And finally for your reference the output for 0.9.6a compiled 114// with SGIcc version 0.01.0-12 (keep in mind that for the moment 115// of this writing it's not possible to convince SGIcc to use 116// BN_UMULT_HIGH inline assembler macro, yet the code is fast, 117// i.e. for a compiler generated one:-): 118// 119// sign verify sign/s verify/s 120// rsa 512 bits 0.0022s 0.0002s 452.7 5894.3 121// rsa 1024 bits 0.0097s 0.0005s 102.7 2002.9 122// rsa 2048 bits 0.0578s 0.0017s 17.3 600.2 123// rsa 4096 bits 0.3838s 0.0061s 2.6 164.5 124// sign verify sign/s verify/s 125// dsa 512 bits 0.0018s 0.0022s 547.3 459.6 126// dsa 1024 bits 0.0051s 0.0062s 196.6 161.3 127// 128// Oh! Benchmarks were performed on 733MHz Lion-class Itanium 129// system running Redhat Linux 7.1 (very special thanks to Ray 130// McCaffity of Williams Communications for providing an account). 131// 132// Q. What's the heck with 'rum 1<<5' at the end of every function? 133// A. Well, by clearing the "upper FP registers written" bit of the 134// User Mask I want to excuse the kernel from preserving upper 135// (f32-f128) FP register bank over process context switch, thus 136// minimizing bus bandwidth consumption during the switch (i.e. 137// after PKI opration completes and the program is off doing 138// something else like bulk symmetric encryption). Having said 139// this, I also want to point out that it might be good idea 140// to compile the whole toolkit (as well as majority of the 141// programs for that matter) with -mfixed-range=f32-f127 command 142// line option. No, it doesn't prevent the compiler from writing 143// to upper bank, but at least discourages to do so. If you don't 144// like the idea you have the option to compile the module with 145// -Drum=nop.m in command line. 146// 147 148#if defined(_HPUX_SOURCE) && !defined(_LP64) 149#define ADDP addp4 150#else 151#define ADDP add 152#endif 153 154#if 1 155// 156// bn_[add|sub]_words routines. 157// 158// Loops are spinning in 2*(n+5) ticks on Itanuim (provided that the 159// data reside in L1 cache, i.e. 2 ticks away). It's possible to 160// compress the epilogue and get down to 2*n+6, but at the cost of 161// scalability (the neat feature of this implementation is that it 162// shall automagically spin in n+5 on "wider" IA-64 implementations:-) 163// I consider that the epilogue is short enough as it is to trade tiny 164// performance loss on Itanium for scalability. 165// 166// BN_ULONG bn_add_words(BN_ULONG *rp, BN_ULONG *ap, BN_ULONG *bp,int num) 167// 168.global bn_add_words# 169.proc bn_add_words# 170.align 64 171.skip 32 // makes the loop body aligned at 64-byte boundary 172bn_add_words: 173 .prologue 174 .save ar.pfs,r2 175{ .mii; alloc r2=ar.pfs,4,12,0,16 176 cmp4.le p6,p0=r35,r0 };; 177{ .mfb; mov r8=r0 // return value 178(p6) br.ret.spnt.many b0 };; 179 180{ .mib; sub r10=r35,r0,1 181 .save ar.lc,r3 182 mov r3=ar.lc 183 brp.loop.imp .L_bn_add_words_ctop,.L_bn_add_words_cend-16 184 } 185{ .mib; ADDP r14=0,r32 // rp 186 .save pr,r9 187 mov r9=pr };; 188 .body 189{ .mii; ADDP r15=0,r33 // ap 190 mov ar.lc=r10 191 mov ar.ec=6 } 192{ .mib; ADDP r16=0,r34 // bp 193 mov pr.rot=1<<16 };; 194 195.L_bn_add_words_ctop: 196{ .mii; (p16) ld8 r32=[r16],8 // b=*(bp++) 197 (p18) add r39=r37,r34 198 (p19) cmp.ltu.unc p56,p0=r40,r38 } 199{ .mfb; (p0) nop.m 0x0 200 (p0) nop.f 0x0 201 (p0) nop.b 0x0 } 202{ .mii; (p16) ld8 r35=[r15],8 // a=*(ap++) 203 (p58) cmp.eq.or p57,p0=-1,r41 // (p20) 204 (p58) add r41=1,r41 } // (p20) 205{ .mfb; (p21) st8 [r14]=r42,8 // *(rp++)=r 206 (p0) nop.f 0x0 207 br.ctop.sptk .L_bn_add_words_ctop };; 208.L_bn_add_words_cend: 209 210{ .mii; 211(p59) add r8=1,r8 // return value 212 mov pr=r9,0x1ffff 213 mov ar.lc=r3 } 214{ .mbb; nop.b 0x0 215 br.ret.sptk.many b0 };; 216.endp bn_add_words# 217 218// 219// BN_ULONG bn_sub_words(BN_ULONG *rp, BN_ULONG *ap, BN_ULONG *bp,int num) 220// 221.global bn_sub_words# 222.proc bn_sub_words# 223.align 64 224.skip 32 // makes the loop body aligned at 64-byte boundary 225bn_sub_words: 226 .prologue 227 .save ar.pfs,r2 228{ .mii; alloc r2=ar.pfs,4,12,0,16 229 cmp4.le p6,p0=r35,r0 };; 230{ .mfb; mov r8=r0 // return value 231(p6) br.ret.spnt.many b0 };; 232 233{ .mib; sub r10=r35,r0,1 234 .save ar.lc,r3 235 mov r3=ar.lc 236 brp.loop.imp .L_bn_sub_words_ctop,.L_bn_sub_words_cend-16 237 } 238{ .mib; ADDP r14=0,r32 // rp 239 .save pr,r9 240 mov r9=pr };; 241 .body 242{ .mii; ADDP r15=0,r33 // ap 243 mov ar.lc=r10 244 mov ar.ec=6 } 245{ .mib; ADDP r16=0,r34 // bp 246 mov pr.rot=1<<16 };; 247 248.L_bn_sub_words_ctop: 249{ .mii; (p16) ld8 r32=[r16],8 // b=*(bp++) 250 (p18) sub r39=r37,r34 251 (p19) cmp.gtu.unc p56,p0=r40,r38 } 252{ .mfb; (p0) nop.m 0x0 253 (p0) nop.f 0x0 254 (p0) nop.b 0x0 } 255{ .mii; (p16) ld8 r35=[r15],8 // a=*(ap++) 256 (p58) cmp.eq.or p57,p0=0,r41 // (p20) 257 (p58) add r41=-1,r41 } // (p20) 258{ .mbb; (p21) st8 [r14]=r42,8 // *(rp++)=r 259 (p0) nop.b 0x0 260 br.ctop.sptk .L_bn_sub_words_ctop };; 261.L_bn_sub_words_cend: 262 263{ .mii; 264(p59) add r8=1,r8 // return value 265 mov pr=r9,0x1ffff 266 mov ar.lc=r3 } 267{ .mbb; nop.b 0x0 268 br.ret.sptk.many b0 };; 269.endp bn_sub_words# 270#endif 271 272#if 0 273#define XMA_TEMPTATION 274#endif 275 276#if 1 277// 278// BN_ULONG bn_mul_words(BN_ULONG *rp, BN_ULONG *ap, int num, BN_ULONG w) 279// 280.global bn_mul_words# 281.proc bn_mul_words# 282.align 64 283.skip 32 // makes the loop body aligned at 64-byte boundary 284bn_mul_words: 285 .prologue 286 .save ar.pfs,r2 287#ifdef XMA_TEMPTATION 288{ .mfi; alloc r2=ar.pfs,4,0,0,0 };; 289#else 290{ .mfi; alloc r2=ar.pfs,4,12,0,16 };; 291#endif 292{ .mib; mov r8=r0 // return value 293 cmp4.le p6,p0=r34,r0 294(p6) br.ret.spnt.many b0 };; 295 296{ .mii; sub r10=r34,r0,1 297 .save ar.lc,r3 298 mov r3=ar.lc 299 .save pr,r9 300 mov r9=pr };; 301 302 .body 303{ .mib; setf.sig f8=r35 // w 304 mov pr.rot=0x800001<<16 305 // ------^----- serves as (p50) at first (p27) 306 brp.loop.imp .L_bn_mul_words_ctop,.L_bn_mul_words_cend-16 307 } 308 309#ifndef XMA_TEMPTATION 310 311{ .mmi; ADDP r14=0,r32 // rp 312 ADDP r15=0,r33 // ap 313 mov ar.lc=r10 } 314{ .mmi; mov r40=0 // serves as r35 at first (p27) 315 mov ar.ec=13 };; 316 317// This loop spins in 2*(n+12) ticks. It's scheduled for data in Itanium 318// L2 cache (i.e. 9 ticks away) as floating point load/store instructions 319// bypass L1 cache and L2 latency is actually best-case scenario for 320// ldf8. The loop is not scalable and shall run in 2*(n+12) even on 321// "wider" IA-64 implementations. It's a trade-off here. n+24 loop 322// would give us ~5% in *overall* performance improvement on "wider" 323// IA-64, but would hurt Itanium for about same because of longer 324// epilogue. As it's a matter of few percents in either case I've 325// chosen to trade the scalability for development time (you can see 326// this very instruction sequence in bn_mul_add_words loop which in 327// turn is scalable). 328.L_bn_mul_words_ctop: 329{ .mfi; (p25) getf.sig r36=f52 // low 330 (p21) xmpy.lu f48=f37,f8 331 (p28) cmp.ltu p54,p50=r41,r39 } 332{ .mfi; (p16) ldf8 f32=[r15],8 333 (p21) xmpy.hu f40=f37,f8 334 (p0) nop.i 0x0 };; 335{ .mii; (p25) getf.sig r32=f44 // high 336 .pred.rel "mutex",p50,p54 337 (p50) add r40=r38,r35 // (p27) 338 (p54) add r40=r38,r35,1 } // (p27) 339{ .mfb; (p28) st8 [r14]=r41,8 340 (p0) nop.f 0x0 341 br.ctop.sptk .L_bn_mul_words_ctop };; 342.L_bn_mul_words_cend: 343 344{ .mii; nop.m 0x0 345.pred.rel "mutex",p51,p55 346(p51) add r8=r36,r0 347(p55) add r8=r36,r0,1 } 348{ .mfb; nop.m 0x0 349 nop.f 0x0 350 nop.b 0x0 } 351 352#else // XMA_TEMPTATION 353 354 setf.sig f37=r0 // serves as carry at (p18) tick 355 mov ar.lc=r10 356 mov ar.ec=5;; 357 358// Most of you examining this code very likely wonder why in the name 359// of Intel the following loop is commented out? Indeed, it looks so 360// neat that you find it hard to believe that it's something wrong 361// with it, right? The catch is that every iteration depends on the 362// result from previous one and the latter isn't available instantly. 363// The loop therefore spins at the latency of xma minus 1, or in other 364// words at 6*(n+4) ticks:-( Compare to the "production" loop above 365// that runs in 2*(n+11) where the low latency problem is worked around 366// by moving the dependency to one-tick latent interger ALU. Note that 367// "distance" between ldf8 and xma is not latency of ldf8, but the 368// *difference* between xma and ldf8 latencies. 369.L_bn_mul_words_ctop: 370{ .mfi; (p16) ldf8 f32=[r33],8 371 (p18) xma.hu f38=f34,f8,f39 } 372{ .mfb; (p20) stf8 [r32]=f37,8 373 (p18) xma.lu f35=f34,f8,f39 374 br.ctop.sptk .L_bn_mul_words_ctop };; 375.L_bn_mul_words_cend: 376 377 getf.sig r8=f41 // the return value 378 379#endif // XMA_TEMPTATION 380 381{ .mii; nop.m 0x0 382 mov pr=r9,0x1ffff 383 mov ar.lc=r3 } 384{ .mfb; rum 1<<5 // clear um.mfh 385 nop.f 0x0 386 br.ret.sptk.many b0 };; 387.endp bn_mul_words# 388#endif 389 390#if 1 391// 392// BN_ULONG bn_mul_add_words(BN_ULONG *rp, BN_ULONG *ap, int num, BN_ULONG w) 393// 394.global bn_mul_add_words# 395.proc bn_mul_add_words# 396.align 64 397.skip 48 // makes the loop body aligned at 64-byte boundary 398bn_mul_add_words: 399 .prologue 400 .save ar.pfs,r2 401{ .mmi; alloc r2=ar.pfs,4,4,0,8 402 cmp4.le p6,p0=r34,r0 403 .save ar.lc,r3 404 mov r3=ar.lc };; 405{ .mib; mov r8=r0 // return value 406 sub r10=r34,r0,1 407(p6) br.ret.spnt.many b0 };; 408 409{ .mib; setf.sig f8=r35 // w 410 .save pr,r9 411 mov r9=pr 412 brp.loop.imp .L_bn_mul_add_words_ctop,.L_bn_mul_add_words_cend-16 413 } 414 .body 415{ .mmi; ADDP r14=0,r32 // rp 416 ADDP r15=0,r33 // ap 417 mov ar.lc=r10 } 418{ .mii; ADDP r16=0,r32 // rp copy 419 mov pr.rot=0x2001<<16 420 // ------^----- serves as (p40) at first (p27) 421 mov ar.ec=11 };; 422 423// This loop spins in 3*(n+10) ticks on Itanium and in 2*(n+10) on 424// Itanium 2. Yes, unlike previous versions it scales:-) Previous 425// version was peforming *all* additions in IALU and was starving 426// for those even on Itanium 2. In this version one addition is 427// moved to FPU and is folded with multiplication. This is at cost 428// of propogating the result from previous call to this subroutine 429// to L2 cache... In other words negligible even for shorter keys. 430// *Overall* performance improvement [over previous version] varies 431// from 11 to 22 percent depending on key length. 432.L_bn_mul_add_words_ctop: 433.pred.rel "mutex",p40,p42 434{ .mfi; (p23) getf.sig r36=f45 // low 435 (p20) xma.lu f42=f36,f8,f50 // low 436 (p40) add r39=r39,r35 } // (p27) 437{ .mfi; (p16) ldf8 f32=[r15],8 // *(ap++) 438 (p20) xma.hu f36=f36,f8,f50 // high 439 (p42) add r39=r39,r35,1 };; // (p27) 440{ .mmi; (p24) getf.sig r32=f40 // high 441 (p16) ldf8 f46=[r16],8 // *(rp1++) 442 (p40) cmp.ltu p41,p39=r39,r35 } // (p27) 443{ .mib; (p26) st8 [r14]=r39,8 // *(rp2++) 444 (p42) cmp.leu p41,p39=r39,r35 // (p27) 445 br.ctop.sptk .L_bn_mul_add_words_ctop};; 446.L_bn_mul_add_words_cend: 447 448{ .mmi; .pred.rel "mutex",p40,p42 449(p40) add r8=r35,r0 450(p42) add r8=r35,r0,1 451 mov pr=r9,0x1ffff } 452{ .mib; rum 1<<5 // clear um.mfh 453 mov ar.lc=r3 454 br.ret.sptk.many b0 };; 455.endp bn_mul_add_words# 456#endif 457 458#if 1 459// 460// void bn_sqr_words(BN_ULONG *rp, BN_ULONG *ap, int num) 461// 462.global bn_sqr_words# 463.proc bn_sqr_words# 464.align 64 465.skip 32 // makes the loop body aligned at 64-byte boundary 466bn_sqr_words: 467 .prologue 468 .save ar.pfs,r2 469{ .mii; alloc r2=ar.pfs,3,0,0,0 470 sxt4 r34=r34 };; 471{ .mii; cmp.le p6,p0=r34,r0 472 mov r8=r0 } // return value 473{ .mfb; ADDP r32=0,r32 474 nop.f 0x0 475(p6) br.ret.spnt.many b0 };; 476 477{ .mii; sub r10=r34,r0,1 478 .save ar.lc,r3 479 mov r3=ar.lc 480 .save pr,r9 481 mov r9=pr };; 482 483 .body 484{ .mib; ADDP r33=0,r33 485 mov pr.rot=1<<16 486 brp.loop.imp .L_bn_sqr_words_ctop,.L_bn_sqr_words_cend-16 487 } 488{ .mii; add r34=8,r32 489 mov ar.lc=r10 490 mov ar.ec=18 };; 491 492// 2*(n+17) on Itanium, (n+17) on "wider" IA-64 implementations. It's 493// possible to compress the epilogue (I'm getting tired to write this 494// comment over and over) and get down to 2*n+16 at the cost of 495// scalability. The decision will very likely be reconsidered after the 496// benchmark program is profiled. I.e. if perfomance gain on Itanium 497// will appear larger than loss on "wider" IA-64, then the loop should 498// be explicitely split and the epilogue compressed. 499.L_bn_sqr_words_ctop: 500{ .mfi; (p16) ldf8 f32=[r33],8 501 (p25) xmpy.lu f42=f41,f41 502 (p0) nop.i 0x0 } 503{ .mib; (p33) stf8 [r32]=f50,16 504 (p0) nop.i 0x0 505 (p0) nop.b 0x0 } 506{ .mfi; (p0) nop.m 0x0 507 (p25) xmpy.hu f52=f41,f41 508 (p0) nop.i 0x0 } 509{ .mib; (p33) stf8 [r34]=f60,16 510 (p0) nop.i 0x0 511 br.ctop.sptk .L_bn_sqr_words_ctop };; 512.L_bn_sqr_words_cend: 513 514{ .mii; nop.m 0x0 515 mov pr=r9,0x1ffff 516 mov ar.lc=r3 } 517{ .mfb; rum 1<<5 // clear um.mfh 518 nop.f 0x0 519 br.ret.sptk.many b0 };; 520.endp bn_sqr_words# 521#endif 522 523#if 1 524// Apparently we win nothing by implementing special bn_sqr_comba8. 525// Yes, it is possible to reduce the number of multiplications by 526// almost factor of two, but then the amount of additions would 527// increase by factor of two (as we would have to perform those 528// otherwise performed by xma ourselves). Normally we would trade 529// anyway as multiplications are way more expensive, but not this 530// time... Multiplication kernel is fully pipelined and as we drain 531// one 128-bit multiplication result per clock cycle multiplications 532// are effectively as inexpensive as additions. Special implementation 533// might become of interest for "wider" IA-64 implementation as you'll 534// be able to get through the multiplication phase faster (there won't 535// be any stall issues as discussed in the commentary section below and 536// you therefore will be able to employ all 4 FP units)... But these 537// Itanium days it's simply too hard to justify the effort so I just 538// drop down to bn_mul_comba8 code:-) 539// 540// void bn_sqr_comba8(BN_ULONG *r, BN_ULONG *a) 541// 542.global bn_sqr_comba8# 543.proc bn_sqr_comba8# 544.align 64 545bn_sqr_comba8: 546 .prologue 547 .save ar.pfs,r2 548#if defined(_HPUX_SOURCE) && !defined(_LP64) 549{ .mii; alloc r2=ar.pfs,2,1,0,0 550 addp4 r33=0,r33 551 addp4 r32=0,r32 };; 552{ .mii; 553#else 554{ .mii; alloc r2=ar.pfs,2,1,0,0 555#endif 556 mov r34=r33 557 add r14=8,r33 };; 558 .body 559{ .mii; add r17=8,r34 560 add r15=16,r33 561 add r18=16,r34 } 562{ .mfb; add r16=24,r33 563 br .L_cheat_entry_point8 };; 564.endp bn_sqr_comba8# 565#endif 566 567#if 1 568// I've estimated this routine to run in ~120 ticks, but in reality 569// (i.e. according to ar.itc) it takes ~160 ticks. Are those extra 570// cycles consumed for instructions fetch? Or did I misinterpret some 571// clause in Itanium µ-architecture manual? Comments are welcomed and 572// highly appreciated. 573// 574// On Itanium 2 it takes ~190 ticks. This is because of stalls on 575// result from getf.sig. I do nothing about it at this point for 576// reasons depicted below. 577// 578// However! It should be noted that even 160 ticks is darn good result 579// as it's over 10 (yes, ten, spelled as t-e-n) times faster than the 580// C version (compiled with gcc with inline assembler). I really 581// kicked compiler's butt here, didn't I? Yeah! This brings us to the 582// following statement. It's damn shame that this routine isn't called 583// very often nowadays! According to the profiler most CPU time is 584// consumed by bn_mul_add_words called from BN_from_montgomery. In 585// order to estimate what we're missing, I've compared the performance 586// of this routine against "traditional" implementation, i.e. against 587// following routine: 588// 589// void bn_mul_comba8(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b) 590// { r[ 8]=bn_mul_words( &(r[0]),a,8,b[0]); 591// r[ 9]=bn_mul_add_words(&(r[1]),a,8,b[1]); 592// r[10]=bn_mul_add_words(&(r[2]),a,8,b[2]); 593// r[11]=bn_mul_add_words(&(r[3]),a,8,b[3]); 594// r[12]=bn_mul_add_words(&(r[4]),a,8,b[4]); 595// r[13]=bn_mul_add_words(&(r[5]),a,8,b[5]); 596// r[14]=bn_mul_add_words(&(r[6]),a,8,b[6]); 597// r[15]=bn_mul_add_words(&(r[7]),a,8,b[7]); 598// } 599// 600// The one below is over 8 times faster than the one above:-( Even 601// more reasons to "combafy" bn_mul_add_mont... 602// 603// And yes, this routine really made me wish there were an optimizing 604// assembler! It also feels like it deserves a dedication. 605// 606// To my wife for being there and to my kids... 607// 608// void bn_mul_comba8(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b) 609// 610#define carry1 r14 611#define carry2 r15 612#define carry3 r34 613.global bn_mul_comba8# 614.proc bn_mul_comba8# 615.align 64 616bn_mul_comba8: 617 .prologue 618 .save ar.pfs,r2 619#if defined(_HPUX_SOURCE) && !defined(_LP64) 620{ .mii; alloc r2=ar.pfs,3,0,0,0 621 addp4 r33=0,r33 622 addp4 r34=0,r34 };; 623{ .mii; addp4 r32=0,r32 624#else 625{ .mii; alloc r2=ar.pfs,3,0,0,0 626#endif 627 add r14=8,r33 628 add r17=8,r34 } 629 .body 630{ .mii; add r15=16,r33 631 add r18=16,r34 632 add r16=24,r33 } 633.L_cheat_entry_point8: 634{ .mmi; add r19=24,r34 635 636 ldf8 f32=[r33],32 };; 637 638{ .mmi; ldf8 f120=[r34],32 639 ldf8 f121=[r17],32 } 640{ .mmi; ldf8 f122=[r18],32 641 ldf8 f123=[r19],32 };; 642{ .mmi; ldf8 f124=[r34] 643 ldf8 f125=[r17] } 644{ .mmi; ldf8 f126=[r18] 645 ldf8 f127=[r19] } 646 647{ .mmi; ldf8 f33=[r14],32 648 ldf8 f34=[r15],32 } 649{ .mmi; ldf8 f35=[r16],32;; 650 ldf8 f36=[r33] } 651{ .mmi; ldf8 f37=[r14] 652 ldf8 f38=[r15] } 653{ .mfi; ldf8 f39=[r16] 654// -------\ Entering multiplier's heaven /------- 655// ------------\ /------------ 656// -----------------\ /----------------- 657// ----------------------\/---------------------- 658 xma.hu f41=f32,f120,f0 } 659{ .mfi; xma.lu f40=f32,f120,f0 };; // (*) 660{ .mfi; xma.hu f51=f32,f121,f0 } 661{ .mfi; xma.lu f50=f32,f121,f0 };; 662{ .mfi; xma.hu f61=f32,f122,f0 } 663{ .mfi; xma.lu f60=f32,f122,f0 };; 664{ .mfi; xma.hu f71=f32,f123,f0 } 665{ .mfi; xma.lu f70=f32,f123,f0 };; 666{ .mfi; xma.hu f81=f32,f124,f0 } 667{ .mfi; xma.lu f80=f32,f124,f0 };; 668{ .mfi; xma.hu f91=f32,f125,f0 } 669{ .mfi; xma.lu f90=f32,f125,f0 };; 670{ .mfi; xma.hu f101=f32,f126,f0 } 671{ .mfi; xma.lu f100=f32,f126,f0 };; 672{ .mfi; xma.hu f111=f32,f127,f0 } 673{ .mfi; xma.lu f110=f32,f127,f0 };;// 674// (*) You can argue that splitting at every second bundle would 675// prevent "wider" IA-64 implementations from achieving the peak 676// performance. Well, not really... The catch is that if you 677// intend to keep 4 FP units busy by splitting at every fourth 678// bundle and thus perform these 16 multiplications in 4 ticks, 679// the first bundle *below* would stall because the result from 680// the first xma bundle *above* won't be available for another 3 681// ticks (if not more, being an optimist, I assume that "wider" 682// implementation will have same latency:-). This stall will hold 683// you back and the performance would be as if every second bundle 684// were split *anyway*... 685{ .mfi; getf.sig r16=f40 686 xma.hu f42=f33,f120,f41 687 add r33=8,r32 } 688{ .mfi; xma.lu f41=f33,f120,f41 };; 689{ .mfi; getf.sig r24=f50 690 xma.hu f52=f33,f121,f51 } 691{ .mfi; xma.lu f51=f33,f121,f51 };; 692{ .mfi; st8 [r32]=r16,16 693 xma.hu f62=f33,f122,f61 } 694{ .mfi; xma.lu f61=f33,f122,f61 };; 695{ .mfi; xma.hu f72=f33,f123,f71 } 696{ .mfi; xma.lu f71=f33,f123,f71 };; 697{ .mfi; xma.hu f82=f33,f124,f81 } 698{ .mfi; xma.lu f81=f33,f124,f81 };; 699{ .mfi; xma.hu f92=f33,f125,f91 } 700{ .mfi; xma.lu f91=f33,f125,f91 };; 701{ .mfi; xma.hu f102=f33,f126,f101 } 702{ .mfi; xma.lu f101=f33,f126,f101 };; 703{ .mfi; xma.hu f112=f33,f127,f111 } 704{ .mfi; xma.lu f111=f33,f127,f111 };;// 705//-------------------------------------------------// 706{ .mfi; getf.sig r25=f41 707 xma.hu f43=f34,f120,f42 } 708{ .mfi; xma.lu f42=f34,f120,f42 };; 709{ .mfi; getf.sig r16=f60 710 xma.hu f53=f34,f121,f52 } 711{ .mfi; xma.lu f52=f34,f121,f52 };; 712{ .mfi; getf.sig r17=f51 713 xma.hu f63=f34,f122,f62 714 add r25=r25,r24 } 715{ .mfi; xma.lu f62=f34,f122,f62 716 mov carry1=0 };; 717{ .mfi; cmp.ltu p6,p0=r25,r24 718 xma.hu f73=f34,f123,f72 } 719{ .mfi; xma.lu f72=f34,f123,f72 };; 720{ .mfi; st8 [r33]=r25,16 721 xma.hu f83=f34,f124,f82 722(p6) add carry1=1,carry1 } 723{ .mfi; xma.lu f82=f34,f124,f82 };; 724{ .mfi; xma.hu f93=f34,f125,f92 } 725{ .mfi; xma.lu f92=f34,f125,f92 };; 726{ .mfi; xma.hu f103=f34,f126,f102 } 727{ .mfi; xma.lu f102=f34,f126,f102 };; 728{ .mfi; xma.hu f113=f34,f127,f112 } 729{ .mfi; xma.lu f112=f34,f127,f112 };;// 730//-------------------------------------------------// 731{ .mfi; getf.sig r18=f42 732 xma.hu f44=f35,f120,f43 733 add r17=r17,r16 } 734{ .mfi; xma.lu f43=f35,f120,f43 };; 735{ .mfi; getf.sig r24=f70 736 xma.hu f54=f35,f121,f53 } 737{ .mfi; mov carry2=0 738 xma.lu f53=f35,f121,f53 };; 739{ .mfi; getf.sig r25=f61 740 xma.hu f64=f35,f122,f63 741 cmp.ltu p7,p0=r17,r16 } 742{ .mfi; add r18=r18,r17 743 xma.lu f63=f35,f122,f63 };; 744{ .mfi; getf.sig r26=f52 745 xma.hu f74=f35,f123,f73 746(p7) add carry2=1,carry2 } 747{ .mfi; cmp.ltu p7,p0=r18,r17 748 xma.lu f73=f35,f123,f73 749 add r18=r18,carry1 };; 750{ .mfi; 751 xma.hu f84=f35,f124,f83 752(p7) add carry2=1,carry2 } 753{ .mfi; cmp.ltu p7,p0=r18,carry1 754 xma.lu f83=f35,f124,f83 };; 755{ .mfi; st8 [r32]=r18,16 756 xma.hu f94=f35,f125,f93 757(p7) add carry2=1,carry2 } 758{ .mfi; xma.lu f93=f35,f125,f93 };; 759{ .mfi; xma.hu f104=f35,f126,f103 } 760{ .mfi; xma.lu f103=f35,f126,f103 };; 761{ .mfi; xma.hu f114=f35,f127,f113 } 762{ .mfi; mov carry1=0 763 xma.lu f113=f35,f127,f113 764 add r25=r25,r24 };;// 765//-------------------------------------------------// 766{ .mfi; getf.sig r27=f43 767 xma.hu f45=f36,f120,f44 768 cmp.ltu p6,p0=r25,r24 } 769{ .mfi; xma.lu f44=f36,f120,f44 770 add r26=r26,r25 };; 771{ .mfi; getf.sig r16=f80 772 xma.hu f55=f36,f121,f54 773(p6) add carry1=1,carry1 } 774{ .mfi; xma.lu f54=f36,f121,f54 };; 775{ .mfi; getf.sig r17=f71 776 xma.hu f65=f36,f122,f64 777 cmp.ltu p6,p0=r26,r25 } 778{ .mfi; xma.lu f64=f36,f122,f64 779 add r27=r27,r26 };; 780{ .mfi; getf.sig r18=f62 781 xma.hu f75=f36,f123,f74 782(p6) add carry1=1,carry1 } 783{ .mfi; cmp.ltu p6,p0=r27,r26 784 xma.lu f74=f36,f123,f74 785 add r27=r27,carry2 };; 786{ .mfi; getf.sig r19=f53 787 xma.hu f85=f36,f124,f84 788(p6) add carry1=1,carry1 } 789{ .mfi; xma.lu f84=f36,f124,f84 790 cmp.ltu p6,p0=r27,carry2 };; 791{ .mfi; st8 [r33]=r27,16 792 xma.hu f95=f36,f125,f94 793(p6) add carry1=1,carry1 } 794{ .mfi; xma.lu f94=f36,f125,f94 };; 795{ .mfi; xma.hu f105=f36,f126,f104 } 796{ .mfi; mov carry2=0 797 xma.lu f104=f36,f126,f104 798 add r17=r17,r16 };; 799{ .mfi; xma.hu f115=f36,f127,f114 800 cmp.ltu p7,p0=r17,r16 } 801{ .mfi; xma.lu f114=f36,f127,f114 802 add r18=r18,r17 };;// 803//-------------------------------------------------// 804{ .mfi; getf.sig r20=f44 805 xma.hu f46=f37,f120,f45 806(p7) add carry2=1,carry2 } 807{ .mfi; cmp.ltu p7,p0=r18,r17 808 xma.lu f45=f37,f120,f45 809 add r19=r19,r18 };; 810{ .mfi; getf.sig r24=f90 811 xma.hu f56=f37,f121,f55 } 812{ .mfi; xma.lu f55=f37,f121,f55 };; 813{ .mfi; getf.sig r25=f81 814 xma.hu f66=f37,f122,f65 815(p7) add carry2=1,carry2 } 816{ .mfi; cmp.ltu p7,p0=r19,r18 817 xma.lu f65=f37,f122,f65 818 add r20=r20,r19 };; 819{ .mfi; getf.sig r26=f72 820 xma.hu f76=f37,f123,f75 821(p7) add carry2=1,carry2 } 822{ .mfi; cmp.ltu p7,p0=r20,r19 823 xma.lu f75=f37,f123,f75 824 add r20=r20,carry1 };; 825{ .mfi; getf.sig r27=f63 826 xma.hu f86=f37,f124,f85 827(p7) add carry2=1,carry2 } 828{ .mfi; xma.lu f85=f37,f124,f85 829 cmp.ltu p7,p0=r20,carry1 };; 830{ .mfi; getf.sig r28=f54 831 xma.hu f96=f37,f125,f95 832(p7) add carry2=1,carry2 } 833{ .mfi; st8 [r32]=r20,16 834 xma.lu f95=f37,f125,f95 };; 835{ .mfi; xma.hu f106=f37,f126,f105 } 836{ .mfi; mov carry1=0 837 xma.lu f105=f37,f126,f105 838 add r25=r25,r24 };; 839{ .mfi; xma.hu f116=f37,f127,f115 840 cmp.ltu p6,p0=r25,r24 } 841{ .mfi; xma.lu f115=f37,f127,f115 842 add r26=r26,r25 };;// 843//-------------------------------------------------// 844{ .mfi; getf.sig r29=f45 845 xma.hu f47=f38,f120,f46 846(p6) add carry1=1,carry1 } 847{ .mfi; cmp.ltu p6,p0=r26,r25 848 xma.lu f46=f38,f120,f46 849 add r27=r27,r26 };; 850{ .mfi; getf.sig r16=f100 851 xma.hu f57=f38,f121,f56 852(p6) add carry1=1,carry1 } 853{ .mfi; cmp.ltu p6,p0=r27,r26 854 xma.lu f56=f38,f121,f56 855 add r28=r28,r27 };; 856{ .mfi; getf.sig r17=f91 857 xma.hu f67=f38,f122,f66 858(p6) add carry1=1,carry1 } 859{ .mfi; cmp.ltu p6,p0=r28,r27 860 xma.lu f66=f38,f122,f66 861 add r29=r29,r28 };; 862{ .mfi; getf.sig r18=f82 863 xma.hu f77=f38,f123,f76 864(p6) add carry1=1,carry1 } 865{ .mfi; cmp.ltu p6,p0=r29,r28 866 xma.lu f76=f38,f123,f76 867 add r29=r29,carry2 };; 868{ .mfi; getf.sig r19=f73 869 xma.hu f87=f38,f124,f86 870(p6) add carry1=1,carry1 } 871{ .mfi; xma.lu f86=f38,f124,f86 872 cmp.ltu p6,p0=r29,carry2 };; 873{ .mfi; getf.sig r20=f64 874 xma.hu f97=f38,f125,f96 875(p6) add carry1=1,carry1 } 876{ .mfi; st8 [r33]=r29,16 877 xma.lu f96=f38,f125,f96 };; 878{ .mfi; getf.sig r21=f55 879 xma.hu f107=f38,f126,f106 } 880{ .mfi; mov carry2=0 881 xma.lu f106=f38,f126,f106 882 add r17=r17,r16 };; 883{ .mfi; xma.hu f117=f38,f127,f116 884 cmp.ltu p7,p0=r17,r16 } 885{ .mfi; xma.lu f116=f38,f127,f116 886 add r18=r18,r17 };;// 887//-------------------------------------------------// 888{ .mfi; getf.sig r22=f46 889 xma.hu f48=f39,f120,f47 890(p7) add carry2=1,carry2 } 891{ .mfi; cmp.ltu p7,p0=r18,r17 892 xma.lu f47=f39,f120,f47 893 add r19=r19,r18 };; 894{ .mfi; getf.sig r24=f110 895 xma.hu f58=f39,f121,f57 896(p7) add carry2=1,carry2 } 897{ .mfi; cmp.ltu p7,p0=r19,r18 898 xma.lu f57=f39,f121,f57 899 add r20=r20,r19 };; 900{ .mfi; getf.sig r25=f101 901 xma.hu f68=f39,f122,f67 902(p7) add carry2=1,carry2 } 903{ .mfi; cmp.ltu p7,p0=r20,r19 904 xma.lu f67=f39,f122,f67 905 add r21=r21,r20 };; 906{ .mfi; getf.sig r26=f92 907 xma.hu f78=f39,f123,f77 908(p7) add carry2=1,carry2 } 909{ .mfi; cmp.ltu p7,p0=r21,r20 910 xma.lu f77=f39,f123,f77 911 add r22=r22,r21 };; 912{ .mfi; getf.sig r27=f83 913 xma.hu f88=f39,f124,f87 914(p7) add carry2=1,carry2 } 915{ .mfi; cmp.ltu p7,p0=r22,r21 916 xma.lu f87=f39,f124,f87 917 add r22=r22,carry1 };; 918{ .mfi; getf.sig r28=f74 919 xma.hu f98=f39,f125,f97 920(p7) add carry2=1,carry2 } 921{ .mfi; xma.lu f97=f39,f125,f97 922 cmp.ltu p7,p0=r22,carry1 };; 923{ .mfi; getf.sig r29=f65 924 xma.hu f108=f39,f126,f107 925(p7) add carry2=1,carry2 } 926{ .mfi; st8 [r32]=r22,16 927 xma.lu f107=f39,f126,f107 };; 928{ .mfi; getf.sig r30=f56 929 xma.hu f118=f39,f127,f117 } 930{ .mfi; xma.lu f117=f39,f127,f117 };;// 931//-------------------------------------------------// 932// Leaving muliplier's heaven... Quite a ride, huh? 933 934{ .mii; getf.sig r31=f47 935 add r25=r25,r24 936 mov carry1=0 };; 937{ .mii; getf.sig r16=f111 938 cmp.ltu p6,p0=r25,r24 939 add r26=r26,r25 };; 940{ .mfb; getf.sig r17=f102 } 941{ .mii; 942(p6) add carry1=1,carry1 943 cmp.ltu p6,p0=r26,r25 944 add r27=r27,r26 };; 945{ .mfb; nop.m 0x0 } 946{ .mii; 947(p6) add carry1=1,carry1 948 cmp.ltu p6,p0=r27,r26 949 add r28=r28,r27 };; 950{ .mii; getf.sig r18=f93 951 add r17=r17,r16 952 mov carry3=0 } 953{ .mii; 954(p6) add carry1=1,carry1 955 cmp.ltu p6,p0=r28,r27 956 add r29=r29,r28 };; 957{ .mii; getf.sig r19=f84 958 cmp.ltu p7,p0=r17,r16 } 959{ .mii; 960(p6) add carry1=1,carry1 961 cmp.ltu p6,p0=r29,r28 962 add r30=r30,r29 };; 963{ .mii; getf.sig r20=f75 964 add r18=r18,r17 } 965{ .mii; 966(p6) add carry1=1,carry1 967 cmp.ltu p6,p0=r30,r29 968 add r31=r31,r30 };; 969{ .mfb; getf.sig r21=f66 } 970{ .mii; (p7) add carry3=1,carry3 971 cmp.ltu p7,p0=r18,r17 972 add r19=r19,r18 } 973{ .mfb; nop.m 0x0 } 974{ .mii; 975(p6) add carry1=1,carry1 976 cmp.ltu p6,p0=r31,r30 977 add r31=r31,carry2 };; 978{ .mfb; getf.sig r22=f57 } 979{ .mii; (p7) add carry3=1,carry3 980 cmp.ltu p7,p0=r19,r18 981 add r20=r20,r19 } 982{ .mfb; nop.m 0x0 } 983{ .mii; 984(p6) add carry1=1,carry1 985 cmp.ltu p6,p0=r31,carry2 };; 986{ .mfb; getf.sig r23=f48 } 987{ .mii; (p7) add carry3=1,carry3 988 cmp.ltu p7,p0=r20,r19 989 add r21=r21,r20 } 990{ .mii; 991(p6) add carry1=1,carry1 } 992{ .mfb; st8 [r33]=r31,16 };; 993 994{ .mfb; getf.sig r24=f112 } 995{ .mii; (p7) add carry3=1,carry3 996 cmp.ltu p7,p0=r21,r20 997 add r22=r22,r21 };; 998{ .mfb; getf.sig r25=f103 } 999{ .mii; (p7) add carry3=1,carry3 1000 cmp.ltu p7,p0=r22,r21 1001 add r23=r23,r22 };; 1002{ .mfb; getf.sig r26=f94 } 1003{ .mii; (p7) add carry3=1,carry3 1004 cmp.ltu p7,p0=r23,r22 1005 add r23=r23,carry1 };; 1006{ .mfb; getf.sig r27=f85 } 1007{ .mii; (p7) add carry3=1,carry3 1008 cmp.ltu p7,p8=r23,carry1};; 1009{ .mii; getf.sig r28=f76 1010 add r25=r25,r24 1011 mov carry1=0 } 1012{ .mii; st8 [r32]=r23,16 1013 (p7) add carry2=1,carry3 1014 (p8) add carry2=0,carry3 };; 1015 1016{ .mfb; nop.m 0x0 } 1017{ .mii; getf.sig r29=f67 1018 cmp.ltu p6,p0=r25,r24 1019 add r26=r26,r25 };; 1020{ .mfb; getf.sig r30=f58 } 1021{ .mii; 1022(p6) add carry1=1,carry1 1023 cmp.ltu p6,p0=r26,r25 1024 add r27=r27,r26 };; 1025{ .mfb; getf.sig r16=f113 } 1026{ .mii; 1027(p6) add carry1=1,carry1 1028 cmp.ltu p6,p0=r27,r26 1029 add r28=r28,r27 };; 1030{ .mfb; getf.sig r17=f104 } 1031{ .mii; 1032(p6) add carry1=1,carry1 1033 cmp.ltu p6,p0=r28,r27 1034 add r29=r29,r28 };; 1035{ .mfb; getf.sig r18=f95 } 1036{ .mii; 1037(p6) add carry1=1,carry1 1038 cmp.ltu p6,p0=r29,r28 1039 add r30=r30,r29 };; 1040{ .mii; getf.sig r19=f86 1041 add r17=r17,r16 1042 mov carry3=0 } 1043{ .mii; 1044(p6) add carry1=1,carry1 1045 cmp.ltu p6,p0=r30,r29 1046 add r30=r30,carry2 };; 1047{ .mii; getf.sig r20=f77 1048 cmp.ltu p7,p0=r17,r16 1049 add r18=r18,r17 } 1050{ .mii; 1051(p6) add carry1=1,carry1 1052 cmp.ltu p6,p0=r30,carry2 };; 1053{ .mfb; getf.sig r21=f68 } 1054{ .mii; st8 [r33]=r30,16 1055(p6) add carry1=1,carry1 };; 1056 1057{ .mfb; getf.sig r24=f114 } 1058{ .mii; (p7) add carry3=1,carry3 1059 cmp.ltu p7,p0=r18,r17 1060 add r19=r19,r18 };; 1061{ .mfb; getf.sig r25=f105 } 1062{ .mii; (p7) add carry3=1,carry3 1063 cmp.ltu p7,p0=r19,r18 1064 add r20=r20,r19 };; 1065{ .mfb; getf.sig r26=f96 } 1066{ .mii; (p7) add carry3=1,carry3 1067 cmp.ltu p7,p0=r20,r19 1068 add r21=r21,r20 };; 1069{ .mfb; getf.sig r27=f87 } 1070{ .mii; (p7) add carry3=1,carry3 1071 cmp.ltu p7,p0=r21,r20 1072 add r21=r21,carry1 };; 1073{ .mib; getf.sig r28=f78 1074 add r25=r25,r24 } 1075{ .mib; (p7) add carry3=1,carry3 1076 cmp.ltu p7,p8=r21,carry1};; 1077{ .mii; st8 [r32]=r21,16 1078 (p7) add carry2=1,carry3 1079 (p8) add carry2=0,carry3 } 1080 1081{ .mii; mov carry1=0 1082 cmp.ltu p6,p0=r25,r24 1083 add r26=r26,r25 };; 1084{ .mfb; getf.sig r16=f115 } 1085{ .mii; 1086(p6) add carry1=1,carry1 1087 cmp.ltu p6,p0=r26,r25 1088 add r27=r27,r26 };; 1089{ .mfb; getf.sig r17=f106 } 1090{ .mii; 1091(p6) add carry1=1,carry1 1092 cmp.ltu p6,p0=r27,r26 1093 add r28=r28,r27 };; 1094{ .mfb; getf.sig r18=f97 } 1095{ .mii; 1096(p6) add carry1=1,carry1 1097 cmp.ltu p6,p0=r28,r27 1098 add r28=r28,carry2 };; 1099{ .mib; getf.sig r19=f88 1100 add r17=r17,r16 } 1101{ .mib; 1102(p6) add carry1=1,carry1 1103 cmp.ltu p6,p0=r28,carry2 };; 1104{ .mii; st8 [r33]=r28,16 1105(p6) add carry1=1,carry1 } 1106 1107{ .mii; mov carry2=0 1108 cmp.ltu p7,p0=r17,r16 1109 add r18=r18,r17 };; 1110{ .mfb; getf.sig r24=f116 } 1111{ .mii; (p7) add carry2=1,carry2 1112 cmp.ltu p7,p0=r18,r17 1113 add r19=r19,r18 };; 1114{ .mfb; getf.sig r25=f107 } 1115{ .mii; (p7) add carry2=1,carry2 1116 cmp.ltu p7,p0=r19,r18 1117 add r19=r19,carry1 };; 1118{ .mfb; getf.sig r26=f98 } 1119{ .mii; (p7) add carry2=1,carry2 1120 cmp.ltu p7,p0=r19,carry1};; 1121{ .mii; st8 [r32]=r19,16 1122 (p7) add carry2=1,carry2 } 1123 1124{ .mfb; add r25=r25,r24 };; 1125 1126{ .mfb; getf.sig r16=f117 } 1127{ .mii; mov carry1=0 1128 cmp.ltu p6,p0=r25,r24 1129 add r26=r26,r25 };; 1130{ .mfb; getf.sig r17=f108 } 1131{ .mii; 1132(p6) add carry1=1,carry1 1133 cmp.ltu p6,p0=r26,r25 1134 add r26=r26,carry2 };; 1135{ .mfb; nop.m 0x0 } 1136{ .mii; 1137(p6) add carry1=1,carry1 1138 cmp.ltu p6,p0=r26,carry2 };; 1139{ .mii; st8 [r33]=r26,16 1140(p6) add carry1=1,carry1 } 1141 1142{ .mfb; add r17=r17,r16 };; 1143{ .mfb; getf.sig r24=f118 } 1144{ .mii; mov carry2=0 1145 cmp.ltu p7,p0=r17,r16 1146 add r17=r17,carry1 };; 1147{ .mii; (p7) add carry2=1,carry2 1148 cmp.ltu p7,p0=r17,carry1};; 1149{ .mii; st8 [r32]=r17 1150 (p7) add carry2=1,carry2 };; 1151{ .mfb; add r24=r24,carry2 };; 1152{ .mib; st8 [r33]=r24 } 1153 1154{ .mib; rum 1<<5 // clear um.mfh 1155 br.ret.sptk.many b0 };; 1156.endp bn_mul_comba8# 1157#undef carry3 1158#undef carry2 1159#undef carry1 1160#endif 1161 1162#if 1 1163// It's possible to make it faster (see comment to bn_sqr_comba8), but 1164// I reckon it doesn't worth the effort. Basically because the routine 1165// (actually both of them) practically never called... So I just play 1166// same trick as with bn_sqr_comba8. 1167// 1168// void bn_sqr_comba4(BN_ULONG *r, BN_ULONG *a) 1169// 1170.global bn_sqr_comba4# 1171.proc bn_sqr_comba4# 1172.align 64 1173bn_sqr_comba4: 1174 .prologue 1175 .save ar.pfs,r2 1176#if defined(_HPUX_SOURCE) && !defined(_LP64) 1177{ .mii; alloc r2=ar.pfs,2,1,0,0 1178 addp4 r32=0,r32 1179 addp4 r33=0,r33 };; 1180{ .mii; 1181#else 1182{ .mii; alloc r2=ar.pfs,2,1,0,0 1183#endif 1184 mov r34=r33 1185 add r14=8,r33 };; 1186 .body 1187{ .mii; add r17=8,r34 1188 add r15=16,r33 1189 add r18=16,r34 } 1190{ .mfb; add r16=24,r33 1191 br .L_cheat_entry_point4 };; 1192.endp bn_sqr_comba4# 1193#endif 1194 1195#if 1 1196// Runs in ~115 cycles and ~4.5 times faster than C. Well, whatever... 1197// 1198// void bn_mul_comba4(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b) 1199// 1200#define carry1 r14 1201#define carry2 r15 1202.global bn_mul_comba4# 1203.proc bn_mul_comba4# 1204.align 64 1205bn_mul_comba4: 1206 .prologue 1207 .save ar.pfs,r2 1208#if defined(_HPUX_SOURCE) && !defined(_LP64) 1209{ .mii; alloc r2=ar.pfs,3,0,0,0 1210 addp4 r33=0,r33 1211 addp4 r34=0,r34 };; 1212{ .mii; addp4 r32=0,r32 1213#else 1214{ .mii; alloc r2=ar.pfs,3,0,0,0 1215#endif 1216 add r14=8,r33 1217 add r17=8,r34 } 1218 .body 1219{ .mii; add r15=16,r33 1220 add r18=16,r34 1221 add r16=24,r33 };; 1222.L_cheat_entry_point4: 1223{ .mmi; add r19=24,r34 1224 1225 ldf8 f32=[r33] } 1226 1227{ .mmi; ldf8 f120=[r34] 1228 ldf8 f121=[r17] };; 1229{ .mmi; ldf8 f122=[r18] 1230 ldf8 f123=[r19] } 1231 1232{ .mmi; ldf8 f33=[r14] 1233 ldf8 f34=[r15] } 1234{ .mfi; ldf8 f35=[r16] 1235 1236 xma.hu f41=f32,f120,f0 } 1237{ .mfi; xma.lu f40=f32,f120,f0 };; 1238{ .mfi; xma.hu f51=f32,f121,f0 } 1239{ .mfi; xma.lu f50=f32,f121,f0 };; 1240{ .mfi; xma.hu f61=f32,f122,f0 } 1241{ .mfi; xma.lu f60=f32,f122,f0 };; 1242{ .mfi; xma.hu f71=f32,f123,f0 } 1243{ .mfi; xma.lu f70=f32,f123,f0 };;// 1244// Major stall takes place here, and 3 more places below. Result from 1245// first xma is not available for another 3 ticks. 1246{ .mfi; getf.sig r16=f40 1247 xma.hu f42=f33,f120,f41 1248 add r33=8,r32 } 1249{ .mfi; xma.lu f41=f33,f120,f41 };; 1250{ .mfi; getf.sig r24=f50 1251 xma.hu f52=f33,f121,f51 } 1252{ .mfi; xma.lu f51=f33,f121,f51 };; 1253{ .mfi; st8 [r32]=r16,16 1254 xma.hu f62=f33,f122,f61 } 1255{ .mfi; xma.lu f61=f33,f122,f61 };; 1256{ .mfi; xma.hu f72=f33,f123,f71 } 1257{ .mfi; xma.lu f71=f33,f123,f71 };;// 1258//-------------------------------------------------// 1259{ .mfi; getf.sig r25=f41 1260 xma.hu f43=f34,f120,f42 } 1261{ .mfi; xma.lu f42=f34,f120,f42 };; 1262{ .mfi; getf.sig r16=f60 1263 xma.hu f53=f34,f121,f52 } 1264{ .mfi; xma.lu f52=f34,f121,f52 };; 1265{ .mfi; getf.sig r17=f51 1266 xma.hu f63=f34,f122,f62 1267 add r25=r25,r24 } 1268{ .mfi; mov carry1=0 1269 xma.lu f62=f34,f122,f62 };; 1270{ .mfi; st8 [r33]=r25,16 1271 xma.hu f73=f34,f123,f72 1272 cmp.ltu p6,p0=r25,r24 } 1273{ .mfi; xma.lu f72=f34,f123,f72 };;// 1274//-------------------------------------------------// 1275{ .mfi; getf.sig r18=f42 1276 xma.hu f44=f35,f120,f43 1277(p6) add carry1=1,carry1 } 1278{ .mfi; add r17=r17,r16 1279 xma.lu f43=f35,f120,f43 1280 mov carry2=0 };; 1281{ .mfi; getf.sig r24=f70 1282 xma.hu f54=f35,f121,f53 1283 cmp.ltu p7,p0=r17,r16 } 1284{ .mfi; xma.lu f53=f35,f121,f53 };; 1285{ .mfi; getf.sig r25=f61 1286 xma.hu f64=f35,f122,f63 1287 add r18=r18,r17 } 1288{ .mfi; xma.lu f63=f35,f122,f63 1289(p7) add carry2=1,carry2 };; 1290{ .mfi; getf.sig r26=f52 1291 xma.hu f74=f35,f123,f73 1292 cmp.ltu p7,p0=r18,r17 } 1293{ .mfi; xma.lu f73=f35,f123,f73 1294 add r18=r18,carry1 };; 1295//-------------------------------------------------// 1296{ .mii; st8 [r32]=r18,16 1297(p7) add carry2=1,carry2 1298 cmp.ltu p7,p0=r18,carry1 };; 1299 1300{ .mfi; getf.sig r27=f43 // last major stall 1301(p7) add carry2=1,carry2 };; 1302{ .mii; getf.sig r16=f71 1303 add r25=r25,r24 1304 mov carry1=0 };; 1305{ .mii; getf.sig r17=f62 1306 cmp.ltu p6,p0=r25,r24 1307 add r26=r26,r25 };; 1308{ .mii; 1309(p6) add carry1=1,carry1 1310 cmp.ltu p6,p0=r26,r25 1311 add r27=r27,r26 };; 1312{ .mii; 1313(p6) add carry1=1,carry1 1314 cmp.ltu p6,p0=r27,r26 1315 add r27=r27,carry2 };; 1316{ .mii; getf.sig r18=f53 1317(p6) add carry1=1,carry1 1318 cmp.ltu p6,p0=r27,carry2 };; 1319{ .mfi; st8 [r33]=r27,16 1320(p6) add carry1=1,carry1 } 1321 1322{ .mii; getf.sig r19=f44 1323 add r17=r17,r16 1324 mov carry2=0 };; 1325{ .mii; getf.sig r24=f72 1326 cmp.ltu p7,p0=r17,r16 1327 add r18=r18,r17 };; 1328{ .mii; (p7) add carry2=1,carry2 1329 cmp.ltu p7,p0=r18,r17 1330 add r19=r19,r18 };; 1331{ .mii; (p7) add carry2=1,carry2 1332 cmp.ltu p7,p0=r19,r18 1333 add r19=r19,carry1 };; 1334{ .mii; getf.sig r25=f63 1335 (p7) add carry2=1,carry2 1336 cmp.ltu p7,p0=r19,carry1};; 1337{ .mii; st8 [r32]=r19,16 1338 (p7) add carry2=1,carry2 } 1339 1340{ .mii; getf.sig r26=f54 1341 add r25=r25,r24 1342 mov carry1=0 };; 1343{ .mii; getf.sig r16=f73 1344 cmp.ltu p6,p0=r25,r24 1345 add r26=r26,r25 };; 1346{ .mii; 1347(p6) add carry1=1,carry1 1348 cmp.ltu p6,p0=r26,r25 1349 add r26=r26,carry2 };; 1350{ .mii; getf.sig r17=f64 1351(p6) add carry1=1,carry1 1352 cmp.ltu p6,p0=r26,carry2 };; 1353{ .mii; st8 [r33]=r26,16 1354(p6) add carry1=1,carry1 } 1355 1356{ .mii; getf.sig r24=f74 1357 add r17=r17,r16 1358 mov carry2=0 };; 1359{ .mii; cmp.ltu p7,p0=r17,r16 1360 add r17=r17,carry1 };; 1361 1362{ .mii; (p7) add carry2=1,carry2 1363 cmp.ltu p7,p0=r17,carry1};; 1364{ .mii; st8 [r32]=r17,16 1365 (p7) add carry2=1,carry2 };; 1366 1367{ .mii; add r24=r24,carry2 };; 1368{ .mii; st8 [r33]=r24 } 1369 1370{ .mib; rum 1<<5 // clear um.mfh 1371 br.ret.sptk.many b0 };; 1372.endp bn_mul_comba4# 1373#undef carry2 1374#undef carry1 1375#endif 1376 1377#if 1 1378// 1379// BN_ULONG bn_div_words(BN_ULONG h, BN_ULONG l, BN_ULONG d) 1380// 1381// In the nutshell it's a port of my MIPS III/IV implementation. 1382// 1383#define AT r14 1384#define H r16 1385#define HH r20 1386#define L r17 1387#define D r18 1388#define DH r22 1389#define I r21 1390 1391#if 0 1392// Some preprocessors (most notably HP-UX) appear to be allergic to 1393// macros enclosed to parenthesis [as these three were]. 1394#define cont p16 1395#define break p0 // p20 1396#define equ p24 1397#else 1398cont=p16 1399break=p0 1400equ=p24 1401#endif 1402 1403.global abort# 1404.global bn_div_words# 1405.proc bn_div_words# 1406.align 64 1407bn_div_words: 1408 .prologue 1409 .save ar.pfs,r2 1410{ .mii; alloc r2=ar.pfs,3,5,0,8 1411 .save b0,r3 1412 mov r3=b0 1413 .save pr,r10 1414 mov r10=pr };; 1415{ .mmb; cmp.eq p6,p0=r34,r0 1416 mov r8=-1 1417(p6) br.ret.spnt.many b0 };; 1418 1419 .body 1420{ .mii; mov H=r32 // save h 1421 mov ar.ec=0 // don't rotate at exit 1422 mov pr.rot=0 } 1423{ .mii; mov L=r33 // save l 1424 mov r36=r0 };; 1425 1426.L_divw_shift: // -vv- note signed comparison 1427{ .mfi; (p0) cmp.lt p16,p0=r0,r34 // d 1428 (p0) shladd r33=r34,1,r0 } 1429{ .mfb; (p0) add r35=1,r36 1430 (p0) nop.f 0x0 1431(p16) br.wtop.dpnt .L_divw_shift };; 1432 1433{ .mii; mov D=r34 1434 shr.u DH=r34,32 1435 sub r35=64,r36 };; 1436{ .mii; setf.sig f7=DH 1437 shr.u AT=H,r35 1438 mov I=r36 };; 1439{ .mib; cmp.ne p6,p0=r0,AT 1440 shl H=H,r36 1441(p6) br.call.spnt.clr b0=abort };; // overflow, die... 1442 1443{ .mfi; fcvt.xuf.s1 f7=f7 1444 shr.u AT=L,r35 };; 1445{ .mii; shl L=L,r36 1446 or H=H,AT };; 1447 1448{ .mii; nop.m 0x0 1449 cmp.leu p6,p0=D,H;; 1450(p6) sub H=H,D } 1451 1452{ .mlx; setf.sig f14=D 1453 movl AT=0xffffffff };; 1454/////////////////////////////////////////////////////////// 1455{ .mii; setf.sig f6=H 1456 shr.u HH=H,32;; 1457 cmp.eq p6,p7=HH,DH };; 1458{ .mfb; 1459(p6) setf.sig f8=AT 1460(p7) fcvt.xuf.s1 f6=f6 1461(p7) br.call.sptk b6=.L_udiv64_32_b6 };; 1462 1463{ .mfi; getf.sig r33=f8 // q 1464 xmpy.lu f9=f8,f14 } 1465{ .mfi; xmpy.hu f10=f8,f14 1466 shrp H=H,L,32 };; 1467 1468{ .mmi; getf.sig r35=f9 // tl 1469 getf.sig r31=f10 };; // th 1470 1471.L_divw_1st_iter: 1472{ .mii; (p0) add r32=-1,r33 1473 (p0) cmp.eq equ,cont=HH,r31 };; 1474{ .mii; (p0) cmp.ltu p8,p0=r35,D 1475 (p0) sub r34=r35,D 1476 (equ) cmp.leu break,cont=r35,H };; 1477{ .mib; (cont) cmp.leu cont,break=HH,r31 1478 (p8) add r31=-1,r31 1479(cont) br.wtop.spnt .L_divw_1st_iter };; 1480/////////////////////////////////////////////////////////// 1481{ .mii; sub H=H,r35 1482 shl r8=r33,32 1483 shl L=L,32 };; 1484/////////////////////////////////////////////////////////// 1485{ .mii; setf.sig f6=H 1486 shr.u HH=H,32;; 1487 cmp.eq p6,p7=HH,DH };; 1488{ .mfb; 1489(p6) setf.sig f8=AT 1490(p7) fcvt.xuf.s1 f6=f6 1491(p7) br.call.sptk b6=.L_udiv64_32_b6 };; 1492 1493{ .mfi; getf.sig r33=f8 // q 1494 xmpy.lu f9=f8,f14 } 1495{ .mfi; xmpy.hu f10=f8,f14 1496 shrp H=H,L,32 };; 1497 1498{ .mmi; getf.sig r35=f9 // tl 1499 getf.sig r31=f10 };; // th 1500 1501.L_divw_2nd_iter: 1502{ .mii; (p0) add r32=-1,r33 1503 (p0) cmp.eq equ,cont=HH,r31 };; 1504{ .mii; (p0) cmp.ltu p8,p0=r35,D 1505 (p0) sub r34=r35,D 1506 (equ) cmp.leu break,cont=r35,H };; 1507{ .mib; (cont) cmp.leu cont,break=HH,r31 1508 (p8) add r31=-1,r31 1509(cont) br.wtop.spnt .L_divw_2nd_iter };; 1510/////////////////////////////////////////////////////////// 1511{ .mii; sub H=H,r35 1512 or r8=r8,r33 1513 mov ar.pfs=r2 };; 1514{ .mii; shr.u r9=H,I // remainder if anybody wants it 1515 mov pr=r10,0x1ffff } 1516{ .mfb; br.ret.sptk.many b0 };; 1517 1518// Unsigned 64 by 32 (well, by 64 for the moment) bit integer division 1519// procedure. 1520// 1521// inputs: f6 = (double)a, f7 = (double)b 1522// output: f8 = (int)(a/b) 1523// clobbered: f8,f9,f10,f11,pred 1524pred=p15 1525// One can argue that this snippet is copyrighted to Intel 1526// Corporation, as it's essentially identical to one of those 1527// found in "Divide, Square Root and Remainder" section at 1528// http://www.intel.com/software/products/opensource/libraries/num.htm. 1529// Yes, I admit that the referred code was used as template, 1530// but after I realized that there hardly is any other instruction 1531// sequence which would perform this operation. I mean I figure that 1532// any independent attempt to implement high-performance division 1533// will result in code virtually identical to the Intel code. It 1534// should be noted though that below division kernel is 1 cycle 1535// faster than Intel one (note commented splits:-), not to mention 1536// original prologue (rather lack of one) and epilogue. 1537.align 32 1538.skip 16 1539.L_udiv64_32_b6: 1540 frcpa.s1 f8,pred=f6,f7;; // [0] y0 = 1 / b 1541 1542(pred) fnma.s1 f9=f7,f8,f1 // [5] e0 = 1 - b * y0 1543(pred) fmpy.s1 f10=f6,f8;; // [5] q0 = a * y0 1544(pred) fmpy.s1 f11=f9,f9 // [10] e1 = e0 * e0 1545(pred) fma.s1 f10=f9,f10,f10;; // [10] q1 = q0 + e0 * q0 1546(pred) fma.s1 f8=f9,f8,f8 //;; // [15] y1 = y0 + e0 * y0 1547(pred) fma.s1 f9=f11,f10,f10;; // [15] q2 = q1 + e1 * q1 1548(pred) fma.s1 f8=f11,f8,f8 //;; // [20] y2 = y1 + e1 * y1 1549(pred) fnma.s1 f10=f7,f9,f6;; // [20] r2 = a - b * q2 1550(pred) fma.s1 f8=f10,f8,f9;; // [25] q3 = q2 + r2 * y2 1551 1552 fcvt.fxu.trunc.s1 f8=f8 // [30] q = trunc(q3) 1553 br.ret.sptk.many b6;; 1554.endp bn_div_words# 1555#endif 1556