/* mpfr_exp_2 -- exponential of a floating-point number using Brent's algorithms in O(n^(1/2)*M(n)) and O(n^(1/3)*M(n)) Copyright (C) 1999, 2000, 2001 Free Software Foundation, Inc. This file is part of the MPFR Library. The MPFR Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The MPFR Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the MPFR Library; see the file COPYING.LIB. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include #include "gmp.h" #include "gmp-impl.h" #include "mpfr.h" #include "mpfr-impl.h" static int mpfr_exp2_aux _PROTO ((mpz_t, mpfr_srcptr, int, int*)); static int mpfr_exp2_aux2 _PROTO ((mpz_t, mpfr_srcptr, int, int*)); static mp_exp_t mpz_normalize _PROTO ((mpz_t, mpz_t, int)); static int mpz_normalize2 _PROTO ((mpz_t, mpz_t, int, int)); int mpfr_exp_2 _PROTO ((mpfr_ptr, mpfr_srcptr, mp_rnd_t)); /* returns floor(sqrt(n)) */ unsigned long _mpfr_isqrt (unsigned long n) { unsigned long s; s = 1; do { s = (s + n / s) / 2; } while (!(s*s <= n && n <= s*(s+2))); return s; } /* returns floor(n^(1/3)) */ unsigned long _mpfr_cuberoot (unsigned long n) { double s, is; s = 1.0; do { s = (2*s*s*s + (double) n) / (3*s*s); is = (double) ((int) s); } while (!(is*is*is <= (double) n && (double) n < (is+1)*(is+1)*(is+1))); return (unsigned long) is; } #define SWITCH 100 /* number of bits to switch from O(n^(1/2)*M(n)) method to O(n^(1/3)*M(n)) method */ #define MY_INIT_MPZ(x, s) { \ (x)->_mp_alloc = (s); \ PTR(x) = (mp_ptr) TMP_ALLOC((s)*BYTES_PER_MP_LIMB); \ (x)->_mp_size = 0; } /* #define DEBUG */ /* if k = the number of bits of z > q, divides z by 2^(k-q) and returns k-q. Otherwise do nothing and return 0. */ static mp_exp_t mpz_normalize (mpz_t rop, mpz_t z, int q) { int k; k = mpz_sizeinbase(z, 2); if (k > q) { mpz_div_2exp(rop, z, k-q); return k-q; } else { if (rop != z) mpz_set(rop, z); return 0; } } /* if expz > target, shift z by (expz-target) bits to the left. if expz < target, shift z by (target-expz) bits to the right. Returns target. */ static int mpz_normalize2 (mpz_t rop, mpz_t z, int expz, int target) { if (target > expz) mpz_div_2exp(rop, z, target-expz); else mpz_mul_2exp(rop, z, expz-target); return target; } /* use Brent's formula exp(x) = (1+r+r^2/2!+r^3/3!+...)^(2^K)*2^n where x = n*log(2)+(2^K)*r together with Brent-Kung O(t^(1/2)) algorithm for the evaluation of power series. The resulting complexity is O(n^(1/3)*M(n)). */ int mpfr_exp_2 (mpfr_ptr y, mpfr_srcptr x, mp_rnd_t rnd_mode) { int n, expx, K, precy, q, k, l, err, exps, inexact; mpfr_t r, s, t; mpz_t ss; TMP_DECL(marker); expx = MPFR_EXP(x); precy = MPFR_PREC(y); #ifdef DEBUG printf("MPFR_EXP(x)=%d\n",expx); #endif n = (int) (mpfr_get_d(x) / LOG2); /* for the O(n^(1/2)*M(n)) method, the Taylor series computation of n/K terms costs about n/(2K) multiplications when computed in fixed point */ K = (precy=0) ? GMP_RNDZ : GMP_RNDU); #ifdef DEBUG printf("n=%d log(2)=",n); mpfr_print_raw(s); putchar('\n'); #endif mpfr_mul_ui (r, s, (n<0) ? -n : n, (n>=0) ? GMP_RNDZ : GMP_RNDU); if (n<0) mpfr_neg(r, r, GMP_RNDD); /* r = floor(n*log(2)) */ #ifdef DEBUG printf("x=%1.20e\n",mpfr_get_d(x)); printf(" ="); mpfr_print_raw(x); putchar('\n'); printf("r=%1.20e\n",mpfr_get_d(r)); printf(" ="); mpfr_print_raw(r); putchar('\n'); #endif mpfr_sub(r, x, r, GMP_RNDU); if (MPFR_SIGN(r)<0) { /* initial approximation n was too large */ n--; mpfr_mul_ui(r, s, (n<0) ? -n : n, GMP_RNDZ); if (n<0) mpfr_neg(r, r, GMP_RNDD); mpfr_sub(r, x, r, GMP_RNDU); } #ifdef DEBUG printf("x-r=%1.20e\n",mpfr_get_d(r)); printf(" ="); mpfr_print_raw(r); putchar('\n'); if (MPFR_SIGN(r)<0) { fprintf(stderr,"Error in mpfr_exp: r<0\n"); exit(1); } #endif mpfr_div_2exp(r, r, K, GMP_RNDU); /* r = (x-n*log(2))/2^K */ TMP_MARK(marker); MY_INIT_MPZ(ss, 3 + 2*((q-1)/BITS_PER_MP_LIMB)); exps = mpz_set_fr(ss, s); /* s <- 1 + r/1! + r^2/2! + ... + r^l/l! */ l = (precy0) mpfr_mul_2exp(s, s, n, GMP_RNDU); else mpfr_div_2exp(s, s, -n, GMP_RNDU); /* error is at most 2^K*(3l*(l+1)) ulp for mpfr_exp2_aux */ if (precy>= 1; } /* now k = ceil(log(error in ulps)/log(2)) */ K += k; #ifdef DEBUG printf("after mult. by 2^n:\n"); if (MPFR_EXP(s)>-1024) printf("s=%1.20e\n",mpfr_get_d(s)); printf(" ="); mpfr_print_raw(s); putchar('\n'); printf("err=%d bits\n", K); #endif l = mpfr_can_round(s, q-K, GMP_RNDN, rnd_mode, precy); if (l==0) { #ifdef DEBUG printf("not enough precision, use %d\n", q+BITS_PER_MP_LIMB); printf("q=%d q-K=%d precy=%d\n",q,q-K,precy); #endif q += BITS_PER_MP_LIMB; mpfr_set_prec(r, q); mpfr_set_prec(s, q); mpfr_set_prec(t, q); } } while (l==0); inexact = mpfr_set (y, s, rnd_mode); mpfr_clear(r); mpfr_clear(s); mpfr_clear(t); return inexact; } /* s <- 1 + r/1! + r^2/2! + ... + r^l/l! while MPFR_EXP(r^l/l!)+MPFR_EXPR(r)>-q using naive method with O(l) multiplications. Return the number of iterations l. The absolute error on s is less than 3*l*(l+1)*2^(-q). Version using fixed-point arithmetic with mpz instead of mpfr for internal computations. s must have at least qn+1 limbs (qn should be enough, but currently fails since mpz_mul_2exp(s, s, q-1) reallocates qn+1 limbs) */ static int mpfr_exp2_aux (mpz_t s, mpfr_srcptr r, int q, int *exps) { int l, dif, qn; mpz_t t, rr; mp_exp_t expt, expr; TMP_DECL(marker); TMP_MARK(marker); qn = 1 + (q-1)/BITS_PER_MP_LIMB; MY_INIT_MPZ(t, 2*qn+1); /* 2*qn+1 is neeeded since mpz_div_2exp may need an extra limb */ MY_INIT_MPZ(rr, qn+1); mpz_set_ui(t, 1); expt=0; mpz_set_ui(s, 1); mpz_mul_2exp(s, s, q-1); *exps = 1-q; /* s = 2^(q-1) */ expr = mpz_set_fr(rr, r); /* no error here */ l = 0; do { l++; mpz_mul(t, t, rr); expt=expt+expr; dif = *exps + mpz_sizeinbase(s, 2) - expt - mpz_sizeinbase(t, 2); /* truncates the bits of t which are < ulp(s) = 2^(1-q) */ expt += mpz_normalize(t, t, q-dif); /* error at most 2^(1-q) */ mpz_div_ui(t, t, l); /* error at most 2^(1-q) */ /* the error wrt t^l/l! is here at most 3*l*ulp(s) */ #ifdef DEBUG if (expt != *exps) { fprintf(stderr, "Error: expt != exps %d %d\n", expt, *exps); exit(1); } #endif mpz_add(s, s, t); /* no error here: exact */ /* ensures rr has the same size as t: after several shifts, the error on rr is still at most ulp(t)=ulp(s) */ expr += mpz_normalize(rr, rr, mpz_sizeinbase(t, 2)); } while (mpz_cmp_ui(t, 0)); TMP_FREE(marker); return l; } /* s <- 1 + r/1! + r^2/2! + ... + r^l/l! while MPFR_EXP(r^l/l!)+MPFR_EXPR(r)>-q using Brent/Kung method with O(sqrt(l)) multiplications. Return l. Uses m multiplications of full size and 2l/m of decreasing size, i.e. a total equivalent to about m+l/m full multiplications, i.e. 2*sqrt(l) for m=sqrt(l). Version using mpz. ss must have at least (sizer+1) limbs. The error is bounded by (l^2+4*l) ulps where l is the return value. */ static int mpfr_exp2_aux2 (mpz_t s, mpfr_srcptr r, int q, int *exps) { int expr, l, m, i, sizer, *expR, expt, ql; unsigned long int c; mpz_t t, *R, rr, tmp; TMP_DECL(marker); /* estimate value of l */ l = q / (-MPFR_EXP(r)); m = (int) _mpfr_isqrt (l); /* we access R[2], thus we need m >= 2 */ if (m < 2) m = 2; TMP_MARK(marker); R = (mpz_t*) TMP_ALLOC((m+1)*sizeof(mpz_t)); /* R[i] stands for r^i */ expR = (int*) TMP_ALLOC((m+1)*sizeof(int)); /* exponent for R[i] */ sizer = 1 + (MPFR_PREC(r)-1)/BITS_PER_MP_LIMB; mpz_init(tmp); MY_INIT_MPZ(rr, sizer+2); MY_INIT_MPZ(t, 2*sizer); /* double size for products */ mpz_set_ui(s, 0); *exps = 1-q; /* initialize s to zero, 1 ulp = 2^(1-q) */ for (i=0;i<=m;i++) MY_INIT_MPZ(R[i], sizer+2); expR[1] = mpz_set_fr(R[1], r); /* exact operation: no error */ expR[1] = mpz_normalize2(R[1], R[1], expR[1], 1-q); /* error <= 1 ulp */ mpz_mul(t, R[1], R[1]); /* err(t) <= 2 ulps */ mpz_div_2exp(R[2], t, q-1); /* err(R[2]) <= 3 ulps */ expR[2] = 1-q; for (i=3;i<=m;i++) { mpz_mul(t, R[i-1], R[1]); /* err(t) <= 2*i-2 */ mpz_div_2exp(R[i], t, q-1); /* err(R[i]) <= 2*i-1 ulps */ expR[i] = 1-q; } mpz_set_ui(R[0], 1); mpz_mul_2exp(R[0], R[0], q-1); expR[0]=1-q; /* R[0]=1 */ mpz_set_ui(rr, 1); expr=0; /* rr contains r^l/l! */ /* by induction: err(rr) <= 2*l ulps */ l = 0; ql = q; /* precision used for current giant step */ do { /* all R[i] must have exponent 1-ql */ if (l) for (i=0;i=0;i--) { mpz_div_ui(t, t, l+i+1); /* err(t) += 1 ulp */ mpz_add(t, t, R[i]); } /* now err(t) <= (3m-2) ulps */ /* now multiplies t by r^l/l! and adds to s */ mpz_mul(t, t, rr); expt += expr; expt = mpz_normalize2(t, t, expt, *exps); /* err(t) <= (3m-1) + err_rr(l) <= (3m-2) + 2*l */ #ifdef DEBUG if (expt != *exps) { fprintf(stderr, "Error: expt != exps %d %d\n", expt, *exps); exit(1); } #endif mpz_add(s, s, t); /* no error here */ /* updates rr, the multiplication of the factors l+i could be done using binary splitting too, but it is not sure it would save much */ mpz_mul(t, rr, R[m]); /* err(t) <= err(rr) + 2m-1 */ expr += expR[m]; mpz_set_ui (tmp, 1); for (i=1, c=1; i<=m; i++) { if (l+i > ~((unsigned long int) 0)/c) { mpz_mul_ui(tmp, tmp, c); c = l+i; } else c *= (unsigned long int) l+i; } if (c != 1) mpz_mul_ui (tmp, tmp, c); /* tmp is exact */ mpz_fdiv_q(t, t, tmp); /* err(t) <= err(rr) + 2m */ expr += mpz_normalize(rr, t, ql); /* err_rr(l+1) <= err_rr(l) + 2m+1 */ ql = q - *exps - mpz_sizeinbase(s, 2) + expr + mpz_sizeinbase(rr, 2); l+=m; } while (expr+mpz_sizeinbase(rr, 2) > -q); TMP_FREE(marker); mpz_clear(tmp); return l; }