On Wednesday 24 December 2008 01:15:08 Bill Hart wrote: > Are you sure it is not in there? It is in the version I checked out. >
Yeah , sorry it is there , just not right permissions so on a color term I miss it > Bill. > > 2008/12/24 <ja...@njkfrudils.plus.com>: > > On Wednesday 24 December 2008 00:51:20 ja...@njkfrudils.plus.com wrote: > >> On Wednesday 24 December 2008 00:31:50 Bill Hart wrote: > >> > On sage.math: > >> > > >> > cd tune > >> > make tune > >> > > >> > ./.libs/libspeed.a(gcd_bin.o): In function `__gmpn_ngcd_matrix_init': > >> > gcd_bin.c:(.text+0x0): multiple definition of > >> > `__gmpn_ngcd_matrix_init' gcd.o:gcd.c:(.text+0x0): first defined here > >> > ./.libs/libspeed.a(gcd_bin.o): In function `__gmpn_nhgcd_itch': > >> > gcd_bin.c:(.text+0x80): multiple definition of `__gmpn_nhgcd_itch' > >> > gcd.o:gcd.c:(.text+0x80): first defined here > >> > ./.libs/libspeed.a(gcd_bin.o): In function `__gmpn_nhgcd': > >> > gcd_bin.c:(.text+0xc4): multiple definition of `__gmpn_nhgcd' > >> > gcd.o:gcd.c:(.text+0xc4): first defined here > >> > ./.libs/libspeed.a(gcd_bin.o): In function `mpn_basic_gcd': > >> > gcd_bin.c:(.text+0x2ed): multiple definition of `mpn_basic_gcd' > >> > gcd.o:gcd.c:(.text+0x2ed): first defined here > >> > >> On my K8-linux same problem with make speed and tune > >> > >> ./configure && make && make check passes OK , and I got bored running > >> ./try mpn_gcd :) > >> > >> get this warning from the build though > >> > >> ngcd.c: In function 'mpn_ngcd': > >> ngcd.c:75: warning: implicit declaration of function 'mpn_basic_gcd' > >> > >> > >> gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. -O2 -m64 > >> -march=k8 -mtune=k8 -c gcd.c -fPIC -DPIC -o .libs/gcd.o > >> gcd.c: In function 'mpz_rgcd': > >> gcd.c:167: warning: implicit declaration of function 'mpn_rgcd' > >> gcd.c: In function 'mpz_bgcd': > >> gcd.c:171: warning: implicit declaration of function 'mpn_bgcd' > >> gcd.c: In function 'mpz_sgcd': > >> gcd.c:175: warning: implicit declaration of function 'mpn_sgcd' > >> gcd.c: In function 'mpz_ngcd': > >> gcd.c:179: warning: implicit declaration of function 'mpn_ngcd' > >> > >> > >> ./configure --enable-alloca=debug --enable-assert && make && make check > >> passes OK > >> > >> but > >> > >> ./configure --enable-alloca=debug --enable-assert --enable-nails=2 && > >> make && make check > >> > >> PASS: t-mul_i > >> PASS: t-tdiv > >> PASS: t-tdiv_ui > >> PASS: t-fdiv > >> PASS: t-fdiv_ui > >> PASS: t-cdiv_ui > >> nhgcd2.c:206: GNU MP assertion failed: h0 == h1 > >> /bin/sh: line 4: 31599 Aborted ${dir}$tst > >> FAIL: t-gcd > >> PASS: t-gcd_ui > >> nhgcd2.c:206: GNU MP assertion failed: h0 == h1 > >> /bin/sh: line 4: 31647 Aborted ${dir}$tst > >> FAIL: t-lcm > >> PASS: dive > >> PASS: dive_ui > >> PASS: t-sqrtrem > >> PASS: convert > >> PASS: io > > > > ./configure --enable-cxx --build=none && make && make check passes > > but > > ./configure --enable-cxx && make && make check Fails to build > > > > this again on K8-linux > > > > make[4]: Leaving directory `/root/mpir/mpir/mpir/trunk/yasm' > > make[3]: Leaving directory `/root/mpir/mpir/mpir/trunk/yasm' > > make[2]: Leaving directory `/root/mpir/mpir/mpir/trunk/yasmbuild' > > Making all in mpn > > make[2]: Entering directory `/root/mpir/mpir/mpir/trunk/mpn' > > /bin/sh ../libtool --tag=CC --mode=compile > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_`echo fib_table | sed 's/_$//'` -O2 -m64 -march=k8 > > -mtune=k8 -c -o fib_table.lo fib_table.c > > mkdir .libs > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_fib_table -O2 -m64 -march=k8 -mtune=k8 -c fib_table.c -fPIC > > -DPIC -o .libs/fib_table.o > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_fib_table -O2 -m64 -march=k8 -mtune=k8 -c fib_table.c -o > > fib_table.o >/dev/null 2>&1 > > /bin/sh ../libtool --tag=CC --mode=compile > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_`echo mp_bases | sed 's/_$//'` -O2 -m64 -march=k8 > > -mtune=k8 -c -o mp_bases.lo mp_bases.c > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_mp_bases -O2 -m64 -march=k8 -mtune=k8 -c mp_bases.c -fPIC > > -DPIC -o .libs/mp_bases.o > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_mp_bases -O2 -m64 -march=k8 -mtune=k8 -c mp_bases.c -o > > mp_bases.o >/dev/null 2>&1 > > /bin/sh ../libtool --tag=CC --mode=compile > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_`echo add | sed 's/_$//'` -O2 -m64 -march=k8 -mtune=k8 -c > > -o add.lo add.c > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_add -O2 -m64 -march=k8 -mtune=k8 -c add.c -fPIC -DPIC -o > > .libs/add.o > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_add -O2 -m64 -march=k8 -mtune=k8 -c add.c -o add.o >/dev/null > > 2>&1 > > /bin/sh ../libtool --tag=CC --mode=compile > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_`echo add_1 | sed 's/_$//'` -O2 -m64 -march=k8 -mtune=k8 > > -c -o add_1.lo add_1.c > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_add_1 -O2 -m64 -march=k8 -mtune=k8 -c add_1.c -fPIC -DPIC -o > > .libs/add_1.o > > > > gcc -std=gnu99 -DHAVE_CONFIG_H -I. -I.. -D__GMP_WITHIN_GMP -I.. > > -DOPERATION_add_1 -O2 -m64 -march=k8 -mtune=k8 -c add_1.c -o add_1.o > > >/dev/null 2>&1 > > /bin/sh ../libtool --mode=compile ../strip_fPIC.sh ../yasm/yasm -f elf64 > > -o add_n.lo `test -f 'add_n.as' || echo './'`add_n.as > > libtool: compile: unable to infer tagged configuration > > libtool: compile: specify a tag with `--tag' > > make[2]: *** [add_n.lo] Error 1 > > make[2]: Leaving directory `/root/mpir/mpir/mpir/trunk/mpn' > > make[1]: *** [all-recursive] Error 1 > > make[1]: Leaving directory `/root/mpir/mpir/mpir/trunk' > > make: *** [all] Error 2 > > > > config.guess from gmp is athlon64-unknown-linux-gnu > > note config.guess not in mpir , is it supposed to be ? > > > >> > Bill. > >> > > >> > 2008/12/23 Jason Martin <jason.worth.mar...@gmail.com>: > >> > > Attached are some edited versions of > >> > > > >> > > mpn/generic/gcd.c > >> > > > >> > > and > >> > > > >> > > mpn/generic/ngcd.c > >> > > > >> > > Drop them in, test them for correctness and speed. Let me know what > >> > > breaks. When everyone is happy, I'll check them in to svn > >> > > > >> > > --jason > >> > > > >> > > Jason Worth Martin > >> > > Asst. Professor of Mathematics > >> > > http://www.math.jmu.edu/~martin > >> > > > >> > > > >> > > > >> > > /* Schönhage's 1987 algorithm, reorganized into hgcd form */ > >> > > > >> > > #include <stdio.h> /* for NULL */ > >> > > > >> > > #include "gmp.h" > >> > > #include "gmp-impl.h" > >> > > #include "longlong.h" > >> > > > >> > > > >> > > /* > >> > > ****************************************************************** * > >> > > Here we are including the original GMP version of mpn_gcd * > >> > > but we rename it as mpn_basic_gcd. It needs to be available * > >> > > for the ngcd algorithm to call in the base case. > >> > > * > >> > > * Preconditions [U = (up, usize) and V = (vp, vsize)]: > >> > > * > >> > > * 1. V is odd. > >> > > * 2. numbits(U) >= numbits(V). > >> > > * > >> > > * Both U and V are destroyed by the operation. The result is > >> > > left at vp, * and its size is returned. > >> > > * > >> > > * Ken Weber (kwe...@mat.ufrgs.br, kwe...@mcs.kent.edu) > >> > > * > >> > > * Funding for this work has been partially provided by Conselho > >> > > * Nacional de Desenvolvimento Cienti'fico e Tecnolo'gico (CNPq) > >> > > do * Brazil, Grant 301314194-2, and was done while I was a > >> > > visiting * reseacher in the Instituto de Matema'tica at > >> > > Universidade Federal * do Rio Grande do Sul (UFRGS). > >> > > * > >> > > * Refer to K. Weber, The accelerated integer GCD algorithm, ACM > >> > > * Transactions on Mathematical Software, v. 21 (March), 1995, > >> > > * pp. 111-122. > >> > > * > >> > > * > >> > > *****************************************************************/ > >> > > > >> > > > >> > > > >> > > /* If MIN (usize, vsize) >= GCD_ACCEL_THRESHOLD, then the > >> > > accelerated algorithm is used, otherwise the binary algorithm is > >> > > used. This may be adjusted for different architectures. */ > >> > > #ifndef GCD_ACCEL_THRESHOLD > >> > > #define GCD_ACCEL_THRESHOLD 5 > >> > > #endif > >> > > > >> > > /* When U and V differ in size by more than BMOD_THRESHOLD, the > >> > > accelerated algorithm reduces using the bmod operation. Otherwise, > >> > > the k-ary reduction is used. 0 <= BMOD_THRESHOLD < GMP_NUMB_BITS. > >> > > */ enum > >> > > { > >> > > BMOD_THRESHOLD = GMP_NUMB_BITS/2 > >> > > }; > >> > > > >> > > > >> > > /* Use binary algorithm to compute V <-- GCD (V, U) for usize, vsize > >> > > == 2. Both U and V must be odd. */ > >> > > static inline mp_size_t > >> > > gcd_2 (mp_ptr vp, mp_srcptr up) > >> > > { > >> > > mp_limb_t u0, u1, v0, v1; > >> > > mp_size_t vsize; > >> > > > >> > > u0 = up[0]; > >> > > u1 = up[1]; > >> > > v0 = vp[0]; > >> > > v1 = vp[1]; > >> > > > >> > > while (u1 != v1 && u0 != v0) > >> > > { > >> > > unsigned long int r; > >> > > if (u1 > v1) > >> > > { > >> > > u1 -= v1 + (u0 < v0); > >> > > u0 = (u0 - v0) & GMP_NUMB_MASK; > >> > > count_trailing_zeros (r, u0); > >> > > u0 = ((u1 << (GMP_NUMB_BITS - r)) & GMP_NUMB_MASK) | (u0 >> > >> > > r); u1 >>= r; > >> > > } > >> > > else /* u1 < v1. */ > >> > > { > >> > > v1 -= u1 + (v0 < u0); > >> > > v0 = (v0 - u0) & GMP_NUMB_MASK; > >> > > count_trailing_zeros (r, v0); > >> > > v0 = ((v1 << (GMP_NUMB_BITS - r)) & GMP_NUMB_MASK) | (v0 >> > >> > > r); v1 >>= r; > >> > > } > >> > > } > >> > > > >> > > vp[0] = v0, vp[1] = v1, vsize = 1 + (v1 != 0); > >> > > > >> > > /* If U == V == GCD, done. Otherwise, compute GCD (V, |U - V|). > >> > > */ if (u1 == v1 && u0 == v0) > >> > > return vsize; > >> > > > >> > > v0 = (u0 == v0) ? (u1 > v1) ? u1-v1 : v1-u1 : (u0 > v0) ? u0-v0 : > >> > > v0-u0; vp[0] = mpn_gcd_1 (vp, vsize, v0); > >> > > > >> > > return 1; > >> > > } > >> > > > >> > > /* The function find_a finds 0 < N < 2^GMP_NUMB_BITS such that there > >> > > exists 0 < |D| < 2^GMP_NUMB_BITS, and N == D * C mod > >> > > 2^(2*GMP_NUMB_BITS). In the reference article, D was computed along > >> > > with N, but it is better to compute D separately as D <-- N / C mod > >> > > 2^(GMP_NUMB_BITS + 1), treating the result as a twos' complement > >> > > signed integer. > >> > > > >> > > Initialize N1 to C mod 2^(2*GMP_NUMB_BITS). According to the > >> > > reference article, N2 should be initialized to 2^(2*GMP_NUMB_BITS), > >> > > but we use 2^(2*GMP_NUMB_BITS) - N1 to start the calculations within > >> > > double precision. If N2 > N1 initially, the first iteration of the > >> > > while loop will swap them. In all other situations, N1 >= N2 is > >> > > maintained. */ > >> > > > >> > > #if HAVE_NATIVE_mpn_gcd_finda > >> > > #define find_a(cp) mpn_gcd_finda (cp) > >> > > > >> > > #else > >> > > static > >> > > #if ! defined (__i386__) > >> > > inline /* don't inline this for the x86 */ > >> > > #endif > >> > > mp_limb_t > >> > > find_a (mp_srcptr cp) > >> > > { > >> > > unsigned long int leading_zero_bits = 0; > >> > > > >> > > mp_limb_t n1_l = cp[0]; /* N1 == n1_h * 2^GMP_NUMB_BITS + > >> > > n1_l. */ mp_limb_t n1_h = cp[1]; > >> > > > >> > > mp_limb_t n2_l = (-n1_l & GMP_NUMB_MASK); /* N2 == n2_h * > >> > > 2^GMP_NUMB_BITS + n2_l. */ mp_limb_t n2_h = (~n1_h & > >> > > GMP_NUMB_MASK); > >> > > > >> > > /* Main loop. */ > >> > > while (n2_h != 0) /* While N2 >= 2^GMP_NUMB_BITS. */ > >> > > { > >> > > /* N1 <-- N1 % N2. */ > >> > > if (((GMP_NUMB_HIGHBIT >> leading_zero_bits) & n2_h) == 0) > >> > > { > >> > > unsigned long int i; > >> > > count_leading_zeros (i, n2_h); > >> > > i -= GMP_NAIL_BITS; > >> > > i -= leading_zero_bits; > >> > > leading_zero_bits += i; > >> > > n2_h = ((n2_h << i) & GMP_NUMB_MASK) | (n2_l >> > >> > > (GMP_NUMB_BITS - i)); n2_l = (n2_l << i) & GMP_NUMB_MASK; > >> > > do > >> > > { > >> > > if (n1_h > n2_h || (n1_h == n2_h && n1_l >= n2_l)) > >> > > { > >> > > n1_h -= n2_h + (n1_l < n2_l); > >> > > n1_l = (n1_l - n2_l) & GMP_NUMB_MASK; > >> > > } > >> > > n2_l = (n2_l >> 1) | ((n2_h << (GMP_NUMB_BITS - 1)) & > >> > > GMP_NUMB_MASK); n2_h >>= 1; > >> > > i -= 1; > >> > > } > >> > > while (i != 0); > >> > > } > >> > > if (n1_h > n2_h || (n1_h == n2_h && n1_l >= n2_l)) > >> > > { > >> > > n1_h -= n2_h + (n1_l < n2_l); > >> > > n1_l = (n1_l - n2_l) & GMP_NUMB_MASK; > >> > > } > >> > > > >> > > MP_LIMB_T_SWAP (n1_h, n2_h); > >> > > MP_LIMB_T_SWAP (n1_l, n2_l); > >> > > } > >> > > > >> > > return n2_l; > >> > > } > >> > > #endif > >> > > > >> > > > >> > > mp_size_t > >> > > mpn_basic_gcd (mp_ptr gp, mp_ptr up, mp_size_t usize, mp_ptr vp, > >> > > mp_size_t vsize) { > >> > > mp_ptr orig_vp = vp; > >> > > mp_size_t orig_vsize = vsize; > >> > > int binary_gcd_ctr; /* Number of times binary gcd will > >> > > execute. */ mp_size_t scratch; > >> > > mp_ptr tp; > >> > > TMP_DECL; > >> > > > >> > > ASSERT (usize >= 1); > >> > > ASSERT (vsize >= 1); > >> > > ASSERT (usize >= vsize); > >> > > ASSERT (vp[0] & 1); > >> > > ASSERT (up[usize - 1] != 0); > >> > > ASSERT (vp[vsize - 1] != 0); > >> > > #if WANT_ASSERT > >> > > if (usize == vsize) > >> > > { > >> > > int uzeros, vzeros; > >> > > count_leading_zeros (uzeros, up[usize - 1]); > >> > > count_leading_zeros (vzeros, vp[vsize - 1]); > >> > > ASSERT (uzeros <= vzeros); > >> > > } > >> > > #endif > >> > > ASSERT (! MPN_OVERLAP_P (up, usize, vp, vsize)); > >> > > ASSERT (MPN_SAME_OR_SEPARATE2_P (gp, vsize, up, usize)); > >> > > ASSERT (MPN_SAME_OR_SEPARATE2_P (gp, vsize, vp, vsize)); > >> > > > >> > > TMP_MARK; > >> > > > >> > > /* Use accelerated algorithm if vsize is over GCD_ACCEL_THRESHOLD. > >> > > Two EXTRA limbs for U and V are required for kary reduction. */ > >> > > if (vsize >= GCD_ACCEL_THRESHOLD) > >> > > { > >> > > unsigned long int vbitsize, d; > >> > > mp_ptr orig_up = up; > >> > > mp_size_t orig_usize = usize; > >> > > mp_ptr anchor_up = (mp_ptr) TMP_ALLOC ((usize + 2) * > >> > > BYTES_PER_MP_LIMB); > >> > > > >> > > MPN_COPY (anchor_up, orig_up, usize); > >> > > up = anchor_up; > >> > > > >> > > count_leading_zeros (d, up[usize - 1]); > >> > > d -= GMP_NAIL_BITS; > >> > > d = usize * GMP_NUMB_BITS - d; > >> > > count_leading_zeros (vbitsize, vp[vsize - 1]); > >> > > vbitsize -= GMP_NAIL_BITS; > >> > > vbitsize = vsize * GMP_NUMB_BITS - vbitsize; > >> > > ASSERT (d >= vbitsize); > >> > > d = d - vbitsize + 1; > >> > > > >> > > /* Use bmod reduction to quickly discover whether V divides U. > >> > > */ up[usize++] = 0; /* Insert leading zero. > >> > > */ mpn_bdivmod (up, up, usize, vp, vsize, d); > >> > > > >> > > /* Now skip U/V mod 2^d and any low zero limbs. */ > >> > > d /= GMP_NUMB_BITS, up += d, usize -= d; > >> > > while (usize != 0 && up[0] == 0) > >> > > up++, usize--; > >> > > > >> > > if (usize == 0) /* GCD == ORIG_V. */ > >> > > goto done; > >> > > > >> > > vp = (mp_ptr) TMP_ALLOC ((vsize + 2) * BYTES_PER_MP_LIMB); > >> > > MPN_COPY (vp, orig_vp, vsize); > >> > > > >> > > do /* Main loop. */ > >> > > { > >> > > /* mpn_com_n can't be used here because anchor_up and up > >> > > may partially overlap */ > >> > > if ((up[usize - 1] & GMP_NUMB_HIGHBIT) != 0) /* U < 0; > >> > > take twos' compl. */ { > >> > > mp_size_t i; > >> > > anchor_up[0] = -up[0] & GMP_NUMB_MASK; > >> > > for (i = 1; i < usize; i++) > >> > > anchor_up[i] = (~up[i] & GMP_NUMB_MASK); > >> > > up = anchor_up; > >> > > } > >> > > > >> > > MPN_NORMALIZE_NOT_ZERO (up, usize); > >> > > > >> > > if ((up[0] & 1) == 0) /* Result even; > >> > > remove twos. */ { > >> > > unsigned int r; > >> > > count_trailing_zeros (r, up[0]); > >> > > mpn_rshift (anchor_up, up, usize, r); > >> > > usize -= (anchor_up[usize - 1] == 0); > >> > > } > >> > > else if (anchor_up != up) > >> > > MPN_COPY_INCR (anchor_up, up, usize); > >> > > > >> > > MPN_PTR_SWAP (anchor_up,usize, vp,vsize); > >> > > up = anchor_up; > >> > > > >> > > if (vsize <= 2) /* Kary can't handle < 2 > >> > > limbs and */ break; /* isn't efficient for == 2 > >> > > limbs. */ > >> > > > >> > > d = vbitsize; > >> > > count_leading_zeros (vbitsize, vp[vsize - 1]); > >> > > vbitsize -= GMP_NAIL_BITS; > >> > > vbitsize = vsize * GMP_NUMB_BITS - vbitsize; > >> > > d = d - vbitsize + 1; > >> > > > >> > > if (d > BMOD_THRESHOLD) /* Bmod reduction. */ > >> > > { > >> > > up[usize++] = 0; > >> > > mpn_bdivmod (up, up, usize, vp, vsize, d); > >> > > d /= GMP_NUMB_BITS, up += d, usize -= d; > >> > > } > >> > > else /* Kary reduction. */ > >> > > { > >> > > mp_limb_t bp[2], cp[2]; > >> > > > >> > > /* C <-- V/U mod 2^(2*GMP_NUMB_BITS). */ > >> > > { > >> > > mp_limb_t u_inv, hi, lo; > >> > > modlimb_invert (u_inv, up[0]); > >> > > cp[0] = (vp[0] * u_inv) & GMP_NUMB_MASK; > >> > > umul_ppmm (hi, lo, cp[0], up[0] << GMP_NAIL_BITS); > >> > > lo >>= GMP_NAIL_BITS; > >> > > cp[1] = (vp[1] - hi - cp[0] * up[1]) * u_inv & > >> > > GMP_NUMB_MASK; } > >> > > > >> > > /* U <-- find_a (C) * U. */ > >> > > up[usize] = mpn_mul_1 (up, up, usize, find_a (cp)); > >> > > usize++; > >> > > > >> > > /* B <-- A/C == U/V mod 2^(GMP_NUMB_BITS + 1). > >> > > bp[0] <-- U/V mod 2^GMP_NUMB_BITS and > >> > > bp[1] <-- ( (U - bp[0] * V)/2^GMP_NUMB_BITS ) / V > >> > > mod 2 > >> > > > >> > > Like V/U above, but simplified because only the low > >> > > bit of bp[1] is wanted. */ > >> > > { > >> > > mp_limb_t v_inv, hi, lo; > >> > > modlimb_invert (v_inv, vp[0]); > >> > > bp[0] = (up[0] * v_inv) & GMP_NUMB_MASK; > >> > > umul_ppmm (hi, lo, bp[0], vp[0] << GMP_NAIL_BITS); > >> > > lo >>= GMP_NAIL_BITS; > >> > > bp[1] = (up[1] + hi + (bp[0] & vp[1])) & 1; > >> > > } > >> > > > >> > > up[usize++] = 0; > >> > > if (bp[1] != 0) /* B < 0: U <-- U + (-B) * V. */ > >> > > { > >> > > mp_limb_t c = mpn_addmul_1 (up, vp, vsize, -bp[0] > >> > > & GMP_NUMB_MASK); mpn_add_1 (up + vsize, up + vsize, usize - vsize, > >> > > c); } else /* B >= 0: U <-- U - B * V. */ { > >> > > mp_limb_t b = mpn_submul_1 (up, vp, vsize, bp[0]); > >> > > mpn_sub_1 (up + vsize, up + vsize, usize - vsize, > >> > > b); } > >> > > > >> > > up += 2, usize -= 2; /* At least two low limbs are > >> > > zero. */ } > >> > > > >> > > /* Must remove low zero limbs before complementing. */ > >> > > while (usize != 0 && up[0] == 0) > >> > > up++, usize--; > >> > > } > >> > > while (usize != 0); > >> > > > >> > > /* Compute GCD (ORIG_V, GCD (ORIG_U, V)). Binary will execute > >> > > twice. */ up = orig_up, usize = orig_usize; > >> > > binary_gcd_ctr = 2; > >> > > } > >> > > else > >> > > binary_gcd_ctr = 1; > >> > > > >> > > scratch = MPN_NGCD_LEHMER_ITCH (vsize); > >> > > if (usize + 1 > scratch) > >> > > scratch = usize + 1; > >> > > > >> > > tp = TMP_ALLOC_LIMBS (scratch); > >> > > > >> > > /* Finish up with the binary algorithm. Executes once or twice. > >> > > */ for ( ; binary_gcd_ctr--; up = orig_vp, usize = orig_vsize) { > >> > > #if 1 > >> > > if (usize > vsize) > >> > > { > >> > > /* FIXME: Could use mpn_bdivmod. */ > >> > > mp_size_t rsize; > >> > > > >> > > mpn_tdiv_qr (tp + vsize, tp, 0, up, usize, vp, vsize); > >> > > rsize = vsize; > >> > > MPN_NORMALIZE (tp, rsize); > >> > > if (rsize == 0) > >> > > continue; > >> > > > >> > > MPN_COPY (up, tp, vsize); > >> > > } > >> > > vsize = mpn_ngcd_lehmer (vp, up, vp, vsize, tp); > >> > > #else > >> > > if (usize > 2) /* First make U close to V in size. > >> > > */ { > >> > > unsigned long int vbitsize, d; > >> > > count_leading_zeros (d, up[usize - 1]); > >> > > d -= GMP_NAIL_BITS; > >> > > d = usize * GMP_NUMB_BITS - d; > >> > > count_leading_zeros (vbitsize, vp[vsize - 1]); > >> > > vbitsize -= GMP_NAIL_BITS; > >> > > vbitsize = vsize * GMP_NUMB_BITS - vbitsize; > >> > > d = d - vbitsize - 1; > >> > > if (d != -(unsigned long int)1 && d > 2) > >> > > { > >> > > mpn_bdivmod (up, up, usize, vp, vsize, d); /* Result > > >> > > 0. */ d /= (unsigned long int)GMP_NUMB_BITS, up += d, usize -= d; } > >> > > } > >> > > > >> > > /* Start binary GCD. */ > >> > > do > >> > > { > >> > > mp_size_t zeros; > >> > > > >> > > /* Make sure U is odd. */ > >> > > MPN_NORMALIZE (up, usize); > >> > > while (up[0] == 0) > >> > > up += 1, usize -= 1; > >> > > if ((up[0] & 1) == 0) > >> > > { > >> > > unsigned int r; > >> > > count_trailing_zeros (r, up[0]); > >> > > mpn_rshift (up, up, usize, r); > >> > > usize -= (up[usize - 1] == 0); > >> > > } > >> > > > >> > > /* Keep usize >= vsize. */ > >> > > if (usize < vsize) > >> > > MPN_PTR_SWAP (up, usize, vp, vsize); > >> > > > >> > > if (usize <= 2) /* Double > >> > > precision. */ { > >> > > if (vsize == 1) > >> > > vp[0] = mpn_gcd_1 (up, usize, vp[0]); > >> > > else > >> > > vsize = gcd_2 (vp, up); > >> > > break; /* Binary GCD > >> > > done. */ } > >> > > > >> > > /* Count number of low zero limbs of U - V. */ > >> > > for (zeros = 0; up[zeros] == vp[zeros] && ++zeros != vsize; > >> > > ) continue; > >> > > > >> > > /* If U < V, swap U and V; in any case, subtract V from U. > >> > > */ if (zeros == vsize) /* Subtract done. > >> > > */ up += zeros, usize -= zeros; > >> > > else if (usize == vsize) > >> > > { > >> > > mp_size_t size = vsize; > >> > > do > >> > > size--; > >> > > while (up[size] == vp[size]); > >> > > if (up[size] < vp[size]) /* usize == > >> > > vsize. */ MP_PTR_SWAP (up, vp); > >> > > up += zeros, usize = size + 1 - zeros; > >> > > mpn_sub_n (up, up, vp + zeros, usize); > >> > > } > >> > > else > >> > > { > >> > > mp_size_t size = vsize - zeros; > >> > > up += zeros, usize -= zeros; > >> > > if (mpn_sub_n (up, up, vp + zeros, size)) > >> > > { > >> > > while (up[size] == 0) /* Propagate > >> > > borrow. */ up[size++] = -(mp_limb_t)1; > >> > > up[size] -= 1; > >> > > } > >> > > } > >> > > } > >> > > while (usize); /* End binary > >> > > GCD. */ #endif > >> > > } > >> > > > >> > > done: > >> > > if (vp != gp) > >> > > MPN_COPY_INCR (gp, vp, vsize); > >> > > TMP_FREE; > >> > > return vsize; > >> > > } > >> > > > >> > > > >> > > > >> > > /* > >> > > ****************************************************************** * > >> > > END of original GMP mpn_gcd > >> > > * > >> > > *****************************************************************/ > >> > > > >> > > > >> > > > >> > > > >> > > > >> > > /* For input of size n, matrix elements are of size at most > >> > > ceil(n/2) - 1, but we need one limb extra. */ > >> > > > >> > > void > >> > > mpn_ngcd_matrix_init (struct ngcd_matrix *M, mp_size_t n, mp_ptr p) > >> > > { > >> > > mp_size_t s = (n+1)/2; > >> > > M->alloc = s; > >> > > M->n = 1; > >> > > MPN_ZERO (p, 4 * s); > >> > > M->p[0][0] = p; > >> > > M->p[0][1] = p + s; > >> > > M->p[1][0] = p + 2 * s; > >> > > M->p[1][1] = p + 3 * s; > >> > > M->tp = p + 4*s; > >> > > > >> > > M->p[0][0][0] = M->p[1][1][0] = 1; > >> > > } > >> > > > >> > > #define NHGCD_BASE_ITCH MPN_NGCD_STEP_ITCH > >> > > > >> > > /* Reduces a,b until |a-b| fits in n/2 + 1 limbs. Constructs matrix > >> > > M with elements of size at most (n+1)/2 - 1. Returns new size of a, > >> > > b, or zero if no reduction is possible. */ > >> > > static mp_size_t > >> > > nhgcd_base (mp_ptr ap, mp_ptr bp, mp_size_t n, > >> > > struct ngcd_matrix *M, mp_ptr tp) > >> > > { > >> > > mp_size_t s = n/2 + 1; > >> > > mp_size_t nn; > >> > > > >> > > ASSERT (n > s); > >> > > ASSERT (ap[n-1] > 0 || bp[n-1] > 0); > >> > > > >> > > nn = mpn_ngcd_step (n, ap, bp, s, M, tp); > >> > > if (!nn) > >> > > return 0; > >> > > > >> > > for (;;) > >> > > { > >> > > n = nn; > >> > > ASSERT (n > s); > >> > > nn = mpn_ngcd_step (n, ap, bp, s, M, tp); > >> > > if (!nn ) > >> > > return n; > >> > > } > >> > > } > >> > > > >> > > /* Size analysis for nhgcd: > >> > > > >> > > For the recursive calls, we have n1 <= ceil(n / 2). Then the > >> > > storage need is determined by the storage for the recursive call > >> > > computing M1, and ngcd_matrix_adjust and ngcd_matrix_mul calls > >> > > that use M1 (after this, the storage needed for M1 can be recycled). > >> > > > >> > > Let S(r) denote the required storage. For M1 we need 5 * > >> > > ceil(n1/2) = 5 * ceil(n/4), and for the ngcd_matrix_adjust call, we > >> > > need n + 2. In total, 5 * ceil(n/4) + n + 2 <= 9 ceil(n/4) + 2. > >> > > > >> > > For the recursive call, we need S(n1) = S(ceil(n/2)). > >> > > > >> > > S(n) <= 9*ceil(n/4) + 2 + S(ceil(n/2)) > >> > > <= 9*(ceil(n/4) + ... + ceil(n/2^(1+k))) + 2k + > >> > > S(ceil(n/2^k)) <= 9*(2 ceil(n/4) + k) + 2k + S(n/2^k) > >> > > <= 18 ceil(n/4) + 11k + S(n/2^k) > >> > > > >> > > */ > >> > > > >> > > mp_size_t > >> > > mpn_nhgcd_itch (mp_size_t n) > >> > > { > >> > > unsigned k; > >> > > mp_size_t nn; > >> > > > >> > > /* Inefficient way to almost compute > >> > > log_2(n/NHGCD_BASE_THRESHOLD) */ > >> > > for (k = 0, nn = n; > >> > > ABOVE_THRESHOLD (nn, NHGCD_THRESHOLD); > >> > > nn = (nn + 1) / 2) > >> > > k++; > >> > > > >> > > if (k == 0) > >> > > return NHGCD_BASE_ITCH (n); > >> > > > >> > > return 18 * ((n+3) / 4) + 11 * k > >> > > + NHGCD_BASE_ITCH (NHGCD_THRESHOLD); > >> > > } > >> > > > >> > > /* Reduces a,b until |a-b| fits in n/2 + 1 limbs. Constructs matrix > >> > > M with elements of size at most (n+1)/2 - 1. Returns new size of a, > >> > > b, or zero if no reduction is possible. */ > >> > > > >> > > mp_size_t > >> > > mpn_nhgcd (mp_ptr ap, mp_ptr bp, mp_size_t n, > >> > > struct ngcd_matrix *M, mp_ptr tp) > >> > > { > >> > > mp_size_t s = n/2 + 1; > >> > > mp_size_t n2 = (3*n)/4 + 1; > >> > > > >> > > mp_size_t p, nn; > >> > > unsigned count; > >> > > int success = 0; > >> > > > >> > > ASSERT (n > s); > >> > > ASSERT ((ap[n-1] | bp[n-1]) > 0); > >> > > > >> > > ASSERT ((n+1)/2 - 1 < M->alloc); > >> > > > >> > > if (BELOW_THRESHOLD (n, NHGCD_THRESHOLD)) > >> > > return nhgcd_base (ap, bp, n, M, tp); > >> > > > >> > > p = n/2; > >> > > nn = mpn_nhgcd (ap + p, bp + p, n - p, M, tp); > >> > > if (nn > 0) > >> > > { > >> > > /* Needs 2*(p + M->n) <= 2*(floor(n/2) + ceil(n/2) - 1) > >> > > = 2 (n - 1) */ > >> > > n = mpn_ngcd_matrix_adjust (M, p + nn, ap, bp, p, tp); > >> > > success = 1; > >> > > } > >> > > count = 0; > >> > > while (n > n2) > >> > > { > >> > > count++; > >> > > /* Needs n + 1 storage */ > >> > > nn = mpn_ngcd_step (n, ap, bp, s, M, tp); > >> > > if (!nn) > >> > > return success ? n : 0; > >> > > n = nn; > >> > > success = 1; > >> > > } > >> > > > >> > > if (n > s + 2) > >> > > { > >> > > struct ngcd_matrix M1; > >> > > mp_size_t scratch; > >> > > > >> > > p = 2*s - n + 1; > >> > > scratch = MPN_NGCD_MATRIX_INIT_ITCH (n-p); > >> > > > >> > > mpn_ngcd_matrix_init(&M1, n - p, tp); > >> > > nn = mpn_nhgcd (ap + p, bp + p, n - p, &M1, tp + scratch); > >> > > if (nn > 0) > >> > > { > >> > > /* Needs 2 (p + M->n) <= 2 (2*s - n2 + 1 + n2 - s - 1) > >> > > = 2*s <= 2*(floor(n/2) + 1) <= n + 2. */ > >> > > n = mpn_ngcd_matrix_adjust (&M1, p + nn, ap, bp, p, tp + > >> > > scratch); /* Needs M->n <= n2 - s - 1 < n/4 */ > >> > > mpn_ngcd_matrix_mul (M, &M1, tp + scratch); > >> > > success = 1; > >> > > } > >> > > } > >> > > > >> > > /* FIXME: This really is the base case */ > >> > > for (count = 0;; count++) > >> > > { > >> > > /* Needs s+3 < n */ > >> > > nn = mpn_ngcd_step (n, ap, bp, s, M, tp); > >> > > if (!nn) > >> > > return success ? n : 0; > >> > > > >> > > n = nn; > >> > > success = 1; > >> > > } > >> > > } > >> > > > >> > > #define EVEN_P(x) (((x) & 1) == 0) > >> > > > >> > > mp_size_t > >> > > mpn_gcd (mp_ptr gp, mp_ptr ap, mp_size_t an, mp_ptr bp, mp_size_t n) > >> > > { > >> > > mp_size_t init_scratch; > >> > > mp_size_t scratch; > >> > > mp_ptr tp; > >> > > TMP_DECL; > >> > > > >> > > ASSERT (an >= n); > >> > > > >> > > if (BELOW_THRESHOLD (n, NGCD_THRESHOLD)) > >> > > return mpn_basic_gcd (gp, ap, an, bp, n); > >> > > > >> > > init_scratch = MPN_NGCD_MATRIX_INIT_ITCH ((n+1)/2); > >> > > scratch = mpn_nhgcd_itch ((n+1)/2); > >> > > > >> > > /* Space needed for mpn_ngcd_matrix_adjust */ > >> > > if (scratch < 2*n) > >> > > scratch = 2*n; > >> > > > >> > > TMP_MARK; > >> > > > >> > > if (an + 1 > init_scratch + scratch) > >> > > tp = TMP_ALLOC_LIMBS (an + 1); > >> > > else > >> > > tp = TMP_ALLOC_LIMBS (init_scratch + scratch); > >> > > > >> > > if (an > n) > >> > > { > >> > > mp_ptr rp = tp; > >> > > mp_ptr qp = rp + n; > >> > > > >> > > mpn_tdiv_qr (qp, rp, 0, ap, an, bp, n); > >> > > MPN_COPY (ap, rp, n); > >> > > an = n; > >> > > MPN_NORMALIZE (ap, an); > >> > > if (an == 0) > >> > > { > >> > > MPN_COPY (gp, bp, n); > >> > > TMP_FREE; > >> > > return n; > >> > > } > >> > > } > >> > > > >> > > while (ABOVE_THRESHOLD (n, NGCD_THRESHOLD)) > >> > > { > >> > > struct ngcd_matrix M; > >> > > mp_size_t p = n/2; > >> > > mp_size_t nn; > >> > > > >> > > mpn_ngcd_matrix_init (&M, n - p, tp); > >> > > nn = mpn_nhgcd (ap + p, bp + p, n - p, &M, tp + init_scratch); > >> > > if (nn > 0) > >> > > /* Needs 2*(p + M->n) <= 2*(floor(n/2) + ceil(n/2) - 1) > >> > > = 2(n-1) */ > >> > > n = mpn_ngcd_matrix_adjust (&M, p + nn, ap, bp, p, tp + > >> > > init_scratch); > >> > > > >> > > else > >> > > { > >> > > mp_size_t gn; > >> > > n = mpn_ngcd_subdiv_step (gp, &gn, ap, bp, n, tp); > >> > > if (n == 0) > >> > > { > >> > > TMP_FREE; > >> > > return gn; > >> > > } > >> > > } > >> > > } > >> > > > >> > > ASSERT (ap[n-1] > 0 || bp[n-1] > 0); > >> > > #if 0 > >> > > /* FIXME: We may want to use lehmer on some systems. */ > >> > > n = mpn_ngcd_lehmer (gp, ap, bp, n, tp); > >> > > > >> > > TMP_FREE; > >> > > return n; > >> > > #endif > >> > > > >> > > if (ap[n-1] < bp[n-1]) > >> > > MP_PTR_SWAP (ap, bp); > >> > > > >> > > an = n; > >> > > MPN_NORMALIZE (bp, n); > >> > > > >> > > if (n == 0) > >> > > { > >> > > MPN_COPY (gp, ap, an); > >> > > TMP_FREE; > >> > > return an; > >> > > } > >> > > > >> > > if (EVEN_P (bp[0])) > >> > > { > >> > > /* Then a must be odd (since the calling convention implies > >> > > that there's no common factor of 2) */ > >> > > ASSERT (!EVEN_P (ap[0])); > >> > > > >> > > while (bp[0] == 0) > >> > > { > >> > > bp++; > >> > > n--; > >> > > } > >> > > > >> > > if (EVEN_P(bp[0])) > >> > > { > >> > > int count; > >> > > count_trailing_zeros (count, bp[0]); > >> > > ASSERT_NOCARRY (mpn_rshift (bp, bp, n, count)); > >> > > n -= (bp[n-1] == 0); > >> > > } > >> > > } > >> > > > >> > > TMP_FREE; > >> > > return mpn_basic_gcd (gp, ap, an, bp, n); > >> > > } > >> > > > >> > > /* Schönhage's 1987 algorithm, reorganized into hgcd form */ > >> > > > >> > > #include <stdio.h> /* for NULL */ > >> > > > >> > > #include "gmp.h" > >> > > #include "gmp-impl.h" > >> > > #include "longlong.h" > >> > > > >> > > > >> > > > >> > > > >> > > > >> > > > >> > > /* For input of size n, matrix elements are of size at most > >> > > ceil(n/2) - 1, but we need one limb extra. */ > >> > > > >> > > void > >> > > mpn_ngcd_matrix_init (struct ngcd_matrix *M, mp_size_t n, mp_ptr p); > >> > > > >> > > #define NHGCD_BASE_ITCH MPN_NGCD_STEP_ITCH > >> > > > >> > > /* Reduces a,b until |a-b| fits in n/2 + 1 limbs. Constructs matrix > >> > > M with elements of size at most (n+1)/2 - 1. Returns new size of a, > >> > > b, or zero if no reduction is possible. */ > >> > > static mp_size_t > >> > > nhgcd_base (mp_ptr ap, mp_ptr bp, mp_size_t n, > >> > > struct ngcd_matrix *M, mp_ptr tp); > >> > > > >> > > /* Size analysis for nhgcd: > >> > > > >> > > For the recursive calls, we have n1 <= ceil(n / 2). Then the > >> > > storage need is determined by the storage for the recursive call > >> > > computing M1, and ngcd_matrix_adjust and ngcd_matrix_mul calls > >> > > that use M1 (after this, the storage needed for M1 can be recycled). > >> > > > >> > > Let S(r) denote the required storage. For M1 we need 5 * > >> > > ceil(n1/2) = 5 * ceil(n/4), and for the ngcd_matrix_adjust call, we > >> > > need n + 2. In total, 5 * ceil(n/4) + n + 2 <= 9 ceil(n/4) + 2. > >> > > > >> > > For the recursive call, we need S(n1) = S(ceil(n/2)). > >> > > > >> > > S(n) <= 9*ceil(n/4) + 2 + S(ceil(n/2)) > >> > > <= 9*(ceil(n/4) + ... + ceil(n/2^(1+k))) + 2k + > >> > > S(ceil(n/2^k)) <= 9*(2 ceil(n/4) + k) + 2k + S(n/2^k) > >> > > <= 18 ceil(n/4) + 11k + S(n/2^k) > >> > > > >> > > */ > >> > > > >> > > mp_size_t > >> > > mpn_nhgcd_itch (mp_size_t n); > >> > > > >> > > > >> > > /* Reduces a,b until |a-b| fits in n/2 + 1 limbs. Constructs matrix > >> > > M with elements of size at most (n+1)/2 - 1. Returns new size of a, > >> > > b, or zero if no reduction is possible. */ > >> > > > >> > > mp_size_t > >> > > mpn_nhgcd (mp_ptr ap, mp_ptr bp, mp_size_t n, > >> > > struct ngcd_matrix *M, mp_ptr tp); > >> > > > >> > > > >> > > #define EVEN_P(x) (((x) & 1) == 0) > >> > > > >> > > mp_size_t > >> > > mpn_ngcd (mp_ptr gp, mp_ptr ap, mp_size_t an, mp_ptr bp, mp_size_t > >> > > n) { > >> > > mp_size_t init_scratch; > >> > > mp_size_t scratch; > >> > > mp_ptr tp; > >> > > TMP_DECL; > >> > > > >> > > ASSERT (an >= n); > >> > > > >> > > if (BELOW_THRESHOLD (n, NGCD_THRESHOLD)) > >> > > return mpn_basic_gcd (gp, ap, an, bp, n); > >> > > > >> > > init_scratch = MPN_NGCD_MATRIX_INIT_ITCH ((n+1)/2); > >> > > scratch = mpn_nhgcd_itch ((n+1)/2); > >> > > > >> > > /* Space needed for mpn_ngcd_matrix_adjust */ > >> > > if (scratch < 2*n) > >> > > scratch = 2*n; > >> > > > >> > > TMP_MARK; > >> > > > >> > > if (an + 1 > init_scratch + scratch) > >> > > tp = TMP_ALLOC_LIMBS (an + 1); > >> > > else > >> > > tp = TMP_ALLOC_LIMBS (init_scratch + scratch); > >> > > > >> > > if (an > n) > >> > > { > >> > > mp_ptr rp = tp; > >> > > mp_ptr qp = rp + n; > >> > > > >> > > mpn_tdiv_qr (qp, rp, 0, ap, an, bp, n); > >> > > MPN_COPY (ap, rp, n); > >> > > an = n; > >> > > MPN_NORMALIZE (ap, an); > >> > > if (an == 0) > >> > > { > >> > > MPN_COPY (gp, bp, n); > >> > > TMP_FREE; > >> > > return n; > >> > > } > >> > > } > >> > > > >> > > while (ABOVE_THRESHOLD (n, NGCD_THRESHOLD)) > >> > > { > >> > > struct ngcd_matrix M; > >> > > mp_size_t p = n/2; > >> > > mp_size_t nn; > >> > > > >> > > mpn_ngcd_matrix_init (&M, n - p, tp); > >> > > nn = mpn_nhgcd (ap + p, bp + p, n - p, &M, tp + init_scratch); > >> > > if (nn > 0) > >> > > /* Needs 2*(p + M->n) <= 2*(floor(n/2) + ceil(n/2) - 1) > >> > > = 2(n-1) */ > >> > > n = mpn_ngcd_matrix_adjust (&M, p + nn, ap, bp, p, tp + > >> > > init_scratch); > >> > > > >> > > else > >> > > { > >> > > mp_size_t gn; > >> > > n = mpn_ngcd_subdiv_step (gp, &gn, ap, bp, n, tp); > >> > > if (n == 0) > >> > > { > >> > > TMP_FREE; > >> > > return gn; > >> > > } > >> > > } > >> > > } > >> > > > >> > > ASSERT (ap[n-1] > 0 || bp[n-1] > 0); > >> > > #if 0 > >> > > /* FIXME: We may want to use lehmer on some systems. */ > >> > > n = mpn_ngcd_lehmer (gp, ap, bp, n, tp); > >> > > > >> > > TMP_FREE; > >> > > return n; > >> > > #endif > >> > > > >> > > if (ap[n-1] < bp[n-1]) > >> > > MP_PTR_SWAP (ap, bp); > >> > > > >> > > an = n; > >> > > MPN_NORMALIZE (bp, n); > >> > > > >> > > if (n == 0) > >> > > { > >> > > MPN_COPY (gp, ap, an); > >> > > TMP_FREE; > >> > > return an; > >> > > } > >> > > > >> > > if (EVEN_P (bp[0])) > >> > > { > >> > > /* Then a must be odd (since the calling convention implies > >> > > that there's no common factor of 2) */ > >> > > ASSERT (!EVEN_P (ap[0])); > >> > > > >> > > while (bp[0] == 0) > >> > > { > >> > > bp++; > >> > > n--; > >> > > } > >> > > > >> > > if (EVEN_P(bp[0])) > >> > > { > >> > > int count; > >> > > count_trailing_zeros (count, bp[0]); > >> > > ASSERT_NOCARRY (mpn_rshift (bp, bp, n, count)); > >> > > n -= (bp[n-1] == 0); > >> > > } > >> > > } > >> > > > >> > > TMP_FREE; > >> > > return mpn_basic_gcd (gp, ap, an, bp, n); > >> > > } > > --~--~---------~--~----~------------~-------~--~----~ You received this message because you are subscribed to the Google Groups "mpir-devel" group. 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