137 lines
3.9 KiB
NASM
137 lines
3.9 KiB
NASM
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dnl Alpha ev67 mpn_gcd_1 -- Nx1 greatest common divisor.
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dnl Copyright 2003, 2004 Free Software Foundation, Inc.
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dnl This file is part of the GNU MP Library.
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dnl
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dnl The GNU MP Library is free software; you can redistribute it and/or
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dnl modify it under the terms of the GNU Lesser General Public License as
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dnl published by the Free Software Foundation; either version 2.1 of the
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dnl License, or (at your option) any later version.
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dnl
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dnl The GNU MP Library is distributed in the hope that it will be useful,
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dnl but WITHOUT ANY WARRANTY; without even the implied warranty of
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dnl MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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dnl Lesser General Public License for more details.
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dnl
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dnl You should have received a copy of the GNU Lesser General Public
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dnl License along with the GNU MP Library; see the file COPYING.LIB. If
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dnl not, write to the Free Software Foundation, Inc., 51 Franklin Street,
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dnl Fifth Floor, Boston, MA 02110-1301, USA.
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include(`../config.m4')
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C ev67: 3.4 cycles/bitpair for 1x1 part
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C mp_limb_t mpn_gcd_1 (mp_srcptr xp, mp_size_t xsize, mp_limb_t y);
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C
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C In the 1x1 part, the algorithm is to change x,y to abs(x-y),min(x,y) and
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C strip trailing zeros from abs(x-y) to maintain x and y both odd.
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C
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C The trailing zeros are calculated from just x-y, since in twos-complement
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C there's the same number of trailing zeros on d or -d. This means the cttz
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C runs in parallel with abs(x-y).
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C
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C The loop takes 5 cycles, and at 0.68 iterations per bit for two N-bit
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C operands with this algorithm gives the measured 3.4 c/l.
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C
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C The slottings shown are for SVR4 style systems, Unicos differs in the
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C initial gp setup and the LEA.
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C
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C Enhancement:
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C
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C On the jsr, !lituse_jsr! (when available) would allow the linker to relax
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C it to a bsr, but probably only in a static binary. Plain "jsr foo" gives
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C the right object code for relaxation, and ought to be available
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C everywhere, but we prefer to schedule the GOT ldq (LEA) back earlier, for
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C the usual case of running in a shared library.
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C
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C bsr could perhaps be used explicitly anyway. We should be able to assume
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C modexact is in the same module as us (ie. shared library or mainline).
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C Would there be any worries about the size of the displacement? Could
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C always put modexact and gcd_1 in the same .o to be certain.
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ASM_START()
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PROLOGUE(mpn_gcd_1, gp)
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C r16 xp
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C r17 size
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C r18 y
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C ldah C l
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C lda C u
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ldq r0, 0(r16) C L x = xp[0]
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lda r30, -32(r30) C u alloc stack
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LEA( r27, mpn_modexact_1c_odd) C L modexact addr, ldq (gp)
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stq r10, 16(r30) C L save r10
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cttz r18, r10 C U0 y twos
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cmpeq r17, 1, r5 C u test size==1
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stq r9, 8(r30) C L save r9
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clr r19 C u zero c for modexact
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unop
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unop
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cttz r0, r6 C U0 x twos
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stq r26, 0(r30) C L save ra
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srl r18, r10, r18 C U y odd
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mov r18, r9 C l hold y across call
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cmpult r6, r10, r2 C u test x_twos < y_twos
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cmovne r2, r6, r10 C l common_twos = min(x_twos,y_twos)
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bne r5, L(one) C U no modexact if size==1
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jsr r26, (r27), mpn_modexact_1c_odd C L0
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LDGP( r29, 0(r26)) C u,l ldah,lda
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cttz r0, r6 C U0 new x twos
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ldq r26, 0(r30) C L restore ra
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L(one):
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mov r9, r1 C u y
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ldq r9, 8(r30) C L restore r9
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mov r10, r2 C u common twos
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ldq r10, 16(r30) C L restore r10
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lda r30, 32(r30) C l free stack
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beq r0, L(done) C U return y if x%y==0
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srl r0, r6, r0 C U x odd
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unop
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ALIGN(16)
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L(top):
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C r0 x
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C r1 y
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C r2 common twos, for use at end
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subq r0, r1, r7 C l0 d = x - y
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cmpult r0, r1, r16 C u0 test x >= y
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subq r1, r0, r4 C l0 new_x = y - x
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cttz r7, r8 C U0 d twos
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cmoveq r16, r7, r4 C l0 new_x = d if x>=y
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cmovne r16, r0, r1 C u0 y = x if x<y
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unop C l \ force cmoveq into l0
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unop C u /
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C C cmoveq2 L0, cmovne2 U0
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srl r4, r8, r0 C U0 x = new_x >> twos
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bne r7, L(top) C U1 stop when d==0
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L(done):
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sll r1, r2, r0 C U0 return y << common_twos
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ret r31, (r26), 1 C L0
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EPILOGUE()
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ASM_END()
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