dnl Itanium-2 mpn_gcd_1 -- mpn by 1 gcd. dnl Copyright 2002, 2003, 2004, 2005 Free Software Foundation, Inc. dnl This file is part of the GNU MP Library. dnl The GNU MP Library is free software; you can redistribute it and/or modify dnl it under the terms of the GNU Lesser General Public License as published dnl by the Free Software Foundation; either version 3 of the License, or (at dnl your option) any later version. dnl The GNU MP Library is distributed in the hope that it will be useful, but dnl WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY dnl or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public dnl License for more details. dnl You should have received a copy of the GNU Lesser General Public License dnl along with the GNU MP Library. If not, see http://www.gnu.org/licenses/. include(`../config.m4') C cycles/bitpair (1x1 gcd) C Itanium: 14 (approx) C Itanium 2: 6.3 C mpn_gcd_1 (mp_srcptr xp, mp_size_t xsize, mp_limb_t y); C C The entry sequence is designed to expect xsize>1 and hence a modexact C call. This ought to be more common than a 1x1 operation. Our critical C path is thus stripping factors of 2 from y, calling modexact, then C stripping factors of 2 from the x remainder returned. C C The common factors of 2 between x and y must be determined using the C original x, not the remainder from the modexact. This is done with C x_orig which is xp[0]. There's plenty of time to do this while the rest C of the modexact etc is happening. C C It's possible xp[0] is zero. In this case the trailing zeros calculation C popc((x-1)&~x) gives 63, and that's clearly no less than what y will C have, making min(x_twos,y_twos) == y_twos. C C The main loop consists of transforming x,y to abs(x-y),min(x,y), and then C stripping factors of 2 from abs(x-y). Those factors of two are C determined from just y-x, without the abs(), since there's the same C number of trailing zeros on n or -n in twos complement. That makes the C dependent chain C C cycles C 1 sub x-y and x-y-1 C 3 andcm (x-y-1)&~(x-y) C 2 popcnt trailing zeros C 3 shr.u strip abs(x-y) C --- C 9 C C The selection of x-y versus y-x for abs(x-y), and the selection of the C minimum of x and y, is done in parallel with the above. C C The algorithm takes about 0.68 iterations per bit (two N bit operands) on C average, hence the final 6.3 cycles/bitpair. C C The loop is not as fast as one might hope, since there's extra latency C from andcm going across to the `multimedia' popcnt, and vice versa from C multimedia shr.u back to the integer sub. C C The loop branch is .sptk.clr since we usually expect a good number of C iterations, and the iterations are data dependent so it's unlikely past C results will predict anything much about the future. C C Not done: C C An alternate algorithm which didn't strip all twos, but instead applied C tbit and predicated extr on x, and then y, was attempted. The loop was 6 C cycles, but the algorithm is an average 1.25 iterations per bitpair for a C total 7.25 c/bp, which is slower than the current approach. C C Alternatives: C C Perhaps we could do something tricky by extracting a few high bits and a C few low bits from the operands, and looking up a table which would give a C set of predicates to control some shifts or subtracts or whatever. That C could knock off multiple bits per iteration. C C The right shifts are a bit of a bottleneck (shr at 2 or 3 cycles, or extr C only going down I0), perhaps it'd be possible to shift left instead, C using add. That would mean keeping track of the lowest not-yet-zeroed C bit, using some sort of mask. C C Itanium-1: C C This code is not designed for itanium-1 and in fact doesn't run well on C that chip. The loop seems to be about 21 cycles, probably because we end C up with a 10 cycle replay for not forcibly scheduling the shr.u latency. C Lack of branch hints might introduce a couple of bubbles too. C ASM_START() .explicit C What does this mean? C HP's assembler requires these declarations for importing mpn_modexact_1c_odd .global mpn_modexact_1c_odd .type mpn_modexact_1c_odd,@function PROLOGUE(mpn_gcd_1) C r32 xp C r33 xsize C r34 y define(x, r8) define(xp_orig, r32) define(xsize, r33) define(y, r34) define(inputs, 3) define(save_rp, r35) define(save_pfs, r36) define(x_orig, r37) define(x_orig_one, r38) define(y_twos, r39) define(locals, 5) define(out_xp, r40) define(out_xsize, r41) define(out_divisor, r42) define(out_carry, r43) define(outputs, 4) .prologue { .mmi; ifdef(`HAVE_ABI_32', ` addp4 r9 = 0, xp_orig define(xp,r9)', C M0 ` define(xp,xp_orig)') .save ar.pfs, save_pfs alloc save_pfs = ar.pfs, inputs, locals, outputs, 0 C M2 .save rp, save_rp mov save_rp = b0 C I0 }{ .body add r10 = -1, y C M3 y-1 } ;; { .mmi; ld8 x = [xp] C M0 x = xp[0] if no modexact ld8 x_orig = [xp] C M1 orig x for common twos cmp.ne p6,p0 = 1, xsize C I0 }{ .mmi; andcm y_twos = r10, y C M2 (y-1)&~y mov out_xp = xp_orig C M3 mov out_xsize = xsize C I1 } ;; mov out_carry = 0 C popcnt y_twos = y_twos C I0 y twos ;; C { .mmi; add x_orig_one = -1, x_orig C M0 orig x-1 shr.u out_divisor = y, y_twos C I0 y without twos }{ shr.u y = y, y_twos C I1 y without twos (p6) br.call.sptk.many b0 = mpn_modexact_1c_odd C if xsize>1 } ;; C modexact can leave x==0 { .mmi; cmp.eq p6,p0 = 0, x C M0 if {xp,xsize} % y == 0 andcm x_orig = x_orig_one, x_orig C M1 orig (x-1)&~x add r9 = -1, x C I0 x-1 } ;; { .mmi; andcm r9 = r9, x C M0 (x-1)&~x mov b0 = save_rp C I0 } ;; C popcnt x_orig = x_orig C I0 orig x twos popcnt r9 = r9 C I0 x twos ;; C { cmp.lt p7,p0 = x_orig, y_twos C M0 orig x_twos < y_twos shr.u x = x, r9 C I0 x odd } ;; { (p7) mov y_twos = x_orig C M0 common twos add r10 = -1, y C I0 y-1 (p6) br.dpnt.few .Ldone_y C B0 x%y==0 then result y } ;; C C No noticable difference in speed for the loop aligned to C 32 or just 16. .Ltop: C r8 x C r10 y-1 C r34 y C r38 common twos, for use at end { .mmi; cmp.gtu p8,p9 = x, y C M0 x>y cmp.ne p10,p0 = x, y C M1 x==y sub r9 = y, x C I0 d = y - x }{ .mmi; sub r10 = r10, x C M2 d-1 = y - x - 1 } ;; { .mmi; .pred.rel "mutex", p8, p9 (p8) sub x = x, y C M0 x>y use x=x-y, y unchanged (p9) mov y = x C M1 y>=x use y=x (p9) mov x = r9 C I0 y>=x use x=y-x }{ .mmi; andcm r9 = r10, r9 C M2 (d-1)&~d ;; add r10 = -1, y C M0 new y-1 popcnt r9 = r9 C I0 twos on x-y } ;; { shr.u x = x, r9 C I0 new x without twos (p10) br.sptk.few.clr .Ltop } ;; C result is y .Ldone_y: shl r8 = y, y_twos C I common factors of 2 ;; mov ar.pfs = save_pfs C I0 br.ret.sptk.many b0 EPILOGUE()