/* Create tuned thresholds for various algorithms. Copyright 1999-2003, 2005, 2006, 2008-2012 Free Software Foundation, Inc. This file is part of the GNU MP Library. The GNU MP Library is free software; you can redistribute it and/or modify it under the terms of either: * the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. or * the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. or both in parallel, as here. The GNU MP 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 General Public License for more details. You should have received copies of the GNU General Public License and the GNU Lesser General Public License along with the GNU MP Library. If not, see https://www.gnu.org/licenses/. */ /* Usage: tuneup [-t] [-t] [-p precision] -t turns on some diagnostic traces, a second -t turns on more traces. Notes: The code here isn't a vision of loveliness, mainly because it's subject to ongoing changes according to new things wanting to be tuned, and practical requirements of systems tested. Sometimes running the program twice produces slightly different results. This is probably because there's so little separating algorithms near their crossover, and on that basis it should make little or no difference to the final speed of the relevant routines, but nothing has been done to check that carefully. Algorithm: The thresholds are determined as follows. A crossover may not be a single size but rather a range where it oscillates between method A or method B faster. If the threshold is set making B used where A is faster (or vice versa) that's bad. Badness is the percentage time lost and total badness is the sum of this over all sizes measured. The threshold is set to minimize total badness. Suppose, as sizes increase, method B becomes faster than method A. The effect of the rule is that, as you look at increasing sizes, isolated points where B is faster are ignored, but when it's consistently faster, or faster on balance, then the threshold is set there. The same result is obtained thinking in the other direction of A becoming faster at smaller sizes. In practice the thresholds tend to be chosen to bring on the next algorithm fairly quickly. This rule is attractive because it's got a basis in reason and is fairly easy to implement, but no work has been done to actually compare it in absolute terms to other possibilities. Implementation: In a normal library build the thresholds are constants. To tune them selected objects are recompiled with the thresholds as global variables instead. #define TUNE_PROGRAM_BUILD does this, with help from code at the end of gmp-impl.h, and rules in tune/Makefile.am. MUL_TOOM22_THRESHOLD for example uses a recompiled mpn_mul_n. The threshold is set to "size+1" to avoid karatsuba, or to "size" to use one level, but recurse into the basecase. MUL_TOOM33_THRESHOLD makes use of the tuned MUL_TOOM22_THRESHOLD value. Other routines in turn will make use of both of those. Naturally the dependants must be tuned first. In a couple of cases, like DIVEXACT_1_THRESHOLD, there's no recompiling, just a threshold based on comparing two routines (mpn_divrem_1 and mpn_divexact_1), and no further use of the value determined. Flags like USE_PREINV_MOD_1 or JACOBI_BASE_METHOD are even simpler, being just comparisons between certain routines on representative data. Shortcuts are applied when native (assembler) versions of routines exist. For instance a native mpn_sqr_basecase is assumed to be always faster than mpn_mul_basecase, with no measuring. No attempt is made to tune within assembler routines, for instance DIVREM_1_NORM_THRESHOLD. An assembler mpn_divrem_1 is expected to be written and tuned all by hand. Assembler routines that might have hard limits are recompiled though, to make them accept a bigger range of sizes than normal, eg. mpn_sqr_basecase to compare against mpn_toom2_sqr. Limitations: The FFTs aren't subject to the same badness rule as the other thresholds, so each k is probably being brought on a touch early. This isn't likely to make a difference, and the simpler probing means fewer tests. */ #define TUNE_PROGRAM_BUILD 1 /* for gmp-impl.h */ #include "config.h" #include #include #include #include #if HAVE_UNISTD_H #include #endif #include "gmp.h" #include "gmp-impl.h" #include "longlong.h" #include "tests.h" #include "speed.h" #if !HAVE_DECL_OPTARG extern char *optarg; extern int optind, opterr; #endif #define DEFAULT_MAX_SIZE 1000 /* limbs */ #if WANT_FFT mp_size_t option_fft_max_size = 50000; /* limbs */ #else mp_size_t option_fft_max_size = 0; #endif int option_trace = 0; int option_fft_trace = 0; struct speed_params s; struct dat_t { mp_size_t size; double d; } *dat = NULL; int ndat = 0; int allocdat = 0; /* This is not defined if mpn_sqr_basecase doesn't declare a limit. In that case use zero here, which for params.max_size means no limit. */ #ifndef TUNE_SQR_TOOM2_MAX #define TUNE_SQR_TOOM2_MAX 0 #endif mp_size_t mul_toom22_threshold = MP_SIZE_T_MAX; mp_size_t mul_toom33_threshold = MUL_TOOM33_THRESHOLD_LIMIT; mp_size_t mul_toom44_threshold = MUL_TOOM44_THRESHOLD_LIMIT; mp_size_t mul_toom6h_threshold = MUL_TOOM6H_THRESHOLD_LIMIT; mp_size_t mul_toom8h_threshold = MUL_TOOM8H_THRESHOLD_LIMIT; mp_size_t mul_toom32_to_toom43_threshold = MP_SIZE_T_MAX; mp_size_t mul_toom32_to_toom53_threshold = MP_SIZE_T_MAX; mp_size_t mul_toom42_to_toom53_threshold = MP_SIZE_T_MAX; mp_size_t mul_toom42_to_toom63_threshold = MP_SIZE_T_MAX; mp_size_t mul_toom43_to_toom54_threshold = MP_SIZE_T_MAX; mp_size_t mul_fft_threshold = MP_SIZE_T_MAX; mp_size_t mul_fft_modf_threshold = MP_SIZE_T_MAX; mp_size_t sqr_basecase_threshold = MP_SIZE_T_MAX; mp_size_t sqr_toom2_threshold = (TUNE_SQR_TOOM2_MAX == 0 ? MP_SIZE_T_MAX : TUNE_SQR_TOOM2_MAX); mp_size_t sqr_toom3_threshold = SQR_TOOM3_THRESHOLD_LIMIT; mp_size_t sqr_toom4_threshold = SQR_TOOM4_THRESHOLD_LIMIT; mp_size_t sqr_toom6_threshold = SQR_TOOM6_THRESHOLD_LIMIT; mp_size_t sqr_toom8_threshold = SQR_TOOM8_THRESHOLD_LIMIT; mp_size_t sqr_fft_threshold = MP_SIZE_T_MAX; mp_size_t sqr_fft_modf_threshold = MP_SIZE_T_MAX; mp_size_t mullo_basecase_threshold = MP_SIZE_T_MAX; mp_size_t mullo_dc_threshold = MP_SIZE_T_MAX; mp_size_t mullo_mul_n_threshold = MP_SIZE_T_MAX; mp_size_t mulmid_toom42_threshold = MP_SIZE_T_MAX; mp_size_t mulmod_bnm1_threshold = MP_SIZE_T_MAX; mp_size_t sqrmod_bnm1_threshold = MP_SIZE_T_MAX; mp_size_t div_qr_2_pi2_threshold = MP_SIZE_T_MAX; mp_size_t dc_div_qr_threshold = MP_SIZE_T_MAX; mp_size_t dc_divappr_q_threshold = MP_SIZE_T_MAX; mp_size_t mu_div_qr_threshold = MP_SIZE_T_MAX; mp_size_t mu_divappr_q_threshold = MP_SIZE_T_MAX; mp_size_t mupi_div_qr_threshold = MP_SIZE_T_MAX; mp_size_t mu_div_q_threshold = MP_SIZE_T_MAX; mp_size_t dc_bdiv_qr_threshold = MP_SIZE_T_MAX; mp_size_t dc_bdiv_q_threshold = MP_SIZE_T_MAX; mp_size_t mu_bdiv_qr_threshold = MP_SIZE_T_MAX; mp_size_t mu_bdiv_q_threshold = MP_SIZE_T_MAX; mp_size_t inv_mulmod_bnm1_threshold = MP_SIZE_T_MAX; mp_size_t inv_newton_threshold = MP_SIZE_T_MAX; mp_size_t inv_appr_threshold = MP_SIZE_T_MAX; mp_size_t binv_newton_threshold = MP_SIZE_T_MAX; mp_size_t redc_1_to_redc_2_threshold = MP_SIZE_T_MAX; mp_size_t redc_1_to_redc_n_threshold = MP_SIZE_T_MAX; mp_size_t redc_2_to_redc_n_threshold = MP_SIZE_T_MAX; mp_size_t matrix22_strassen_threshold = MP_SIZE_T_MAX; mp_size_t hgcd_threshold = MP_SIZE_T_MAX; mp_size_t hgcd_appr_threshold = MP_SIZE_T_MAX; mp_size_t hgcd_reduce_threshold = MP_SIZE_T_MAX; mp_size_t gcd_dc_threshold = MP_SIZE_T_MAX; mp_size_t gcdext_dc_threshold = MP_SIZE_T_MAX; int div_qr_1n_pi1_method = 0; mp_size_t div_qr_1_norm_threshold = MP_SIZE_T_MAX; mp_size_t div_qr_1_unnorm_threshold = MP_SIZE_T_MAX; mp_size_t divrem_1_norm_threshold = MP_SIZE_T_MAX; mp_size_t divrem_1_unnorm_threshold = MP_SIZE_T_MAX; mp_size_t mod_1_norm_threshold = MP_SIZE_T_MAX; mp_size_t mod_1_unnorm_threshold = MP_SIZE_T_MAX; int mod_1_1p_method = 0; mp_size_t mod_1n_to_mod_1_1_threshold = MP_SIZE_T_MAX; mp_size_t mod_1u_to_mod_1_1_threshold = MP_SIZE_T_MAX; mp_size_t mod_1_1_to_mod_1_2_threshold = MP_SIZE_T_MAX; mp_size_t mod_1_2_to_mod_1_4_threshold = MP_SIZE_T_MAX; mp_size_t preinv_mod_1_to_mod_1_threshold = MP_SIZE_T_MAX; mp_size_t divrem_2_threshold = MP_SIZE_T_MAX; mp_size_t get_str_dc_threshold = MP_SIZE_T_MAX; mp_size_t get_str_precompute_threshold = MP_SIZE_T_MAX; mp_size_t set_str_dc_threshold = MP_SIZE_T_MAX; mp_size_t set_str_precompute_threshold = MP_SIZE_T_MAX; mp_size_t fac_odd_threshold = 0; mp_size_t fac_dsc_threshold = FAC_DSC_THRESHOLD_LIMIT; mp_size_t fft_modf_sqr_threshold = MP_SIZE_T_MAX; mp_size_t fft_modf_mul_threshold = MP_SIZE_T_MAX; struct param_t { const char *name; speed_function_t function; speed_function_t function2; double step_factor; /* how much to step relatively */ int step; /* how much to step absolutely */ double function_fudge; /* multiplier for "function" speeds */ int stop_since_change; double stop_factor; mp_size_t min_size; int min_is_always; mp_size_t max_size; mp_size_t check_size; mp_size_t size_extra; #define DATA_HIGH_LT_R 1 #define DATA_HIGH_GE_R 2 int data_high; int noprint; }; /* These are normally undefined when false, which suits "#if" fine. But give them zero values so they can be used in plain C "if"s. */ #ifndef UDIV_PREINV_ALWAYS #define UDIV_PREINV_ALWAYS 0 #endif #ifndef HAVE_NATIVE_mpn_divexact_1 #define HAVE_NATIVE_mpn_divexact_1 0 #endif #ifndef HAVE_NATIVE_mpn_div_qr_1n_pi1 #define HAVE_NATIVE_mpn_div_qr_1n_pi1 0 #endif #ifndef HAVE_NATIVE_mpn_divrem_1 #define HAVE_NATIVE_mpn_divrem_1 0 #endif #ifndef HAVE_NATIVE_mpn_divrem_2 #define HAVE_NATIVE_mpn_divrem_2 0 #endif #ifndef HAVE_NATIVE_mpn_mod_1 #define HAVE_NATIVE_mpn_mod_1 0 #endif #ifndef HAVE_NATIVE_mpn_mod_1_1p #define HAVE_NATIVE_mpn_mod_1_1p 0 #endif #ifndef HAVE_NATIVE_mpn_modexact_1_odd #define HAVE_NATIVE_mpn_modexact_1_odd 0 #endif #ifndef HAVE_NATIVE_mpn_preinv_divrem_1 #define HAVE_NATIVE_mpn_preinv_divrem_1 0 #endif #ifndef HAVE_NATIVE_mpn_preinv_mod_1 #define HAVE_NATIVE_mpn_preinv_mod_1 0 #endif #ifndef HAVE_NATIVE_mpn_sqr_basecase #define HAVE_NATIVE_mpn_sqr_basecase 0 #endif #define MAX3(a,b,c) MAX (MAX (a, b), c) mp_limb_t randlimb_norm (void) { mp_limb_t n; mpn_random (&n, 1); n |= GMP_NUMB_HIGHBIT; return n; } #define GMP_NUMB_HALFMASK ((CNST_LIMB(1) << (GMP_NUMB_BITS/2)) - 1) mp_limb_t randlimb_half (void) { mp_limb_t n; mpn_random (&n, 1); n &= GMP_NUMB_HALFMASK; n += (n==0); return n; } /* Add an entry to the end of the dat[] array, reallocing to make it bigger if necessary. */ void add_dat (mp_size_t size, double d) { #define ALLOCDAT_STEP 500 ASSERT_ALWAYS (ndat <= allocdat); if (ndat == allocdat) { dat = (struct dat_t *) __gmp_allocate_or_reallocate (dat, allocdat * sizeof(dat[0]), (allocdat+ALLOCDAT_STEP) * sizeof(dat[0])); allocdat += ALLOCDAT_STEP; } dat[ndat].size = size; dat[ndat].d = d; ndat++; } /* Return the threshold size based on the data accumulated. */ mp_size_t analyze_dat (int final) { double x, min_x; int j, min_j; /* If the threshold is set at dat[0].size, any positive values are bad. */ x = 0.0; for (j = 0; j < ndat; j++) if (dat[j].d > 0.0) x += dat[j].d; if (option_trace >= 2 && final) { printf ("\n"); printf ("x is the sum of the badness from setting thresh at given size\n"); printf (" (minimum x is sought)\n"); printf ("size=%ld first x=%.4f\n", (long) dat[j].size, x); } min_x = x; min_j = 0; /* When stepping to the next dat[j].size, positive values are no longer bad (so subtracted), negative values become bad (so add the absolute value, meaning subtract). */ for (j = 0; j < ndat; x -= dat[j].d, j++) { if (option_trace >= 2 && final) printf ("size=%ld x=%.4f\n", (long) dat[j].size, x); if (x < min_x) { min_x = x; min_j = j; } } return min_j; } /* Measuring for recompiled mpn/generic/div_qr_1.c, * mpn/generic/divrem_1.c, mpn/generic/mod_1.c and mpz/fac_ui.c */ mp_limb_t mpn_div_qr_1_tune (mp_ptr, mp_limb_t *, mp_srcptr, mp_size_t, mp_limb_t); mp_limb_t mpn_divrem_1_tune (mp_ptr, mp_size_t, mp_srcptr, mp_size_t, mp_limb_t); mp_limb_t mpn_mod_1_tune (mp_srcptr, mp_size_t, mp_limb_t); void mpz_fac_ui_tune (mpz_ptr, unsigned long); double speed_mpn_mod_1_tune (struct speed_params *s) { SPEED_ROUTINE_MPN_MOD_1 (mpn_mod_1_tune); } double speed_mpn_divrem_1_tune (struct speed_params *s) { SPEED_ROUTINE_MPN_DIVREM_1 (mpn_divrem_1_tune); } double speed_mpz_fac_ui_tune (struct speed_params *s) { SPEED_ROUTINE_MPZ_FAC_UI (mpz_fac_ui_tune); } double speed_mpn_div_qr_1_tune (struct speed_params *s) { SPEED_ROUTINE_MPN_DIV_QR_1 (mpn_div_qr_1_tune); } double tuneup_measure (speed_function_t fun, const struct param_t *param, struct speed_params *s) { static struct param_t dummy; double t; TMP_DECL; if (! param) param = &dummy; s->size += param->size_extra; TMP_MARK; SPEED_TMP_ALLOC_LIMBS (s->xp, s->size, 0); SPEED_TMP_ALLOC_LIMBS (s->yp, s->size, 0); mpn_random (s->xp, s->size); mpn_random (s->yp, s->size); switch (param->data_high) { case DATA_HIGH_LT_R: s->xp[s->size-1] %= s->r; s->yp[s->size-1] %= s->r; break; case DATA_HIGH_GE_R: s->xp[s->size-1] |= s->r; s->yp[s->size-1] |= s->r; break; } t = speed_measure (fun, s); s->size -= param->size_extra; TMP_FREE; return t; } #define PRINT_WIDTH 31 void print_define_start (const char *name) { printf ("#define %-*s ", PRINT_WIDTH, name); if (option_trace) printf ("...\n"); } void print_define_end_remark (const char *name, mp_size_t value, const char *remark) { if (option_trace) printf ("#define %-*s ", PRINT_WIDTH, name); if (value == MP_SIZE_T_MAX) printf ("MP_SIZE_T_MAX"); else printf ("%5ld", (long) value); if (remark != NULL) printf (" /* %s */", remark); printf ("\n"); fflush (stdout); } void print_define_end (const char *name, mp_size_t value) { const char *remark; if (value == MP_SIZE_T_MAX) remark = "never"; else if (value == 0) remark = "always"; else remark = NULL; print_define_end_remark (name, value, remark); } void print_define (const char *name, mp_size_t value) { print_define_start (name); print_define_end (name, value); } void print_define_remark (const char *name, mp_size_t value, const char *remark) { print_define_start (name); print_define_end_remark (name, value, remark); } void one (mp_size_t *threshold, struct param_t *param) { int since_positive, since_thresh_change; int thresh_idx, new_thresh_idx; #define DEFAULT(x,n) do { if (! (x)) (x) = (n); } while (0) DEFAULT (param->function_fudge, 1.0); DEFAULT (param->function2, param->function); DEFAULT (param->step_factor, 0.01); /* small steps by default */ DEFAULT (param->step, 1); /* small steps by default */ DEFAULT (param->stop_since_change, 80); DEFAULT (param->stop_factor, 1.2); DEFAULT (param->min_size, 10); DEFAULT (param->max_size, DEFAULT_MAX_SIZE); if (param->check_size != 0) { double t1, t2; s.size = param->check_size; *threshold = s.size+1; t1 = tuneup_measure (param->function, param, &s); *threshold = s.size; t2 = tuneup_measure (param->function2, param, &s); if (t1 == -1.0 || t2 == -1.0) { printf ("Oops, can't run both functions at size %ld\n", (long) s.size); abort (); } t1 *= param->function_fudge; /* ask that t2 is at least 4% below t1 */ if (t1 < t2*1.04) { if (option_trace) printf ("function2 never enough faster: t1=%.9f t2=%.9f\n", t1, t2); *threshold = MP_SIZE_T_MAX; if (! param->noprint) print_define (param->name, *threshold); return; } if (option_trace >= 2) printf ("function2 enough faster at size=%ld: t1=%.9f t2=%.9f\n", (long) s.size, t1, t2); } if (! param->noprint || option_trace) print_define_start (param->name); ndat = 0; since_positive = 0; since_thresh_change = 0; thresh_idx = 0; if (option_trace >= 2) { printf (" algorithm-A algorithm-B ratio possible\n"); printf (" (seconds) (seconds) diff thresh\n"); } for (s.size = param->min_size; s.size < param->max_size; s.size += MAX ((mp_size_t) floor (s.size * param->step_factor), param->step)) { double ti, tiplus1, d; /* FIXME: check minimum size requirements are met, possibly by just checking for the -1 returns from the speed functions. */ /* using method A at this size */ *threshold = s.size+1; ti = tuneup_measure (param->function, param, &s); if (ti == -1.0) abort (); ti *= param->function_fudge; /* using method B at this size */ *threshold = s.size; tiplus1 = tuneup_measure (param->function2, param, &s); if (tiplus1 == -1.0) abort (); /* Calculate the fraction by which the one or the other routine is slower. */ if (tiplus1 >= ti) d = (tiplus1 - ti) / tiplus1; /* negative */ else d = (tiplus1 - ti) / ti; /* positive */ add_dat (s.size, d); new_thresh_idx = analyze_dat (0); if (option_trace >= 2) printf ("size=%ld %.9f %.9f % .4f %c %ld\n", (long) s.size, ti, tiplus1, d, ti > tiplus1 ? '#' : ' ', (long) dat[new_thresh_idx].size); /* Stop if the last time method i was faster was more than a certain number of measurements ago. */ #define STOP_SINCE_POSITIVE 200 if (d >= 0) since_positive = 0; else if (++since_positive > STOP_SINCE_POSITIVE) { if (option_trace >= 1) printf ("stopped due to since_positive (%d)\n", STOP_SINCE_POSITIVE); break; } /* Stop if method A has become slower by a certain factor. */ if (ti >= tiplus1 * param->stop_factor) { if (option_trace >= 1) printf ("stopped due to ti >= tiplus1 * factor (%.1f)\n", param->stop_factor); break; } /* Stop if the threshold implied hasn't changed in a certain number of measurements. (It's this condition that usually stops the loop.) */ if (thresh_idx != new_thresh_idx) since_thresh_change = 0, thresh_idx = new_thresh_idx; else if (++since_thresh_change > param->stop_since_change) { if (option_trace >= 1) printf ("stopped due to since_thresh_change (%d)\n", param->stop_since_change); break; } /* Stop if the threshold implied is more than a certain number of measurements ago. */ #define STOP_SINCE_AFTER 500 if (ndat - thresh_idx > STOP_SINCE_AFTER) { if (option_trace >= 1) printf ("stopped due to ndat - thresh_idx > amount (%d)\n", STOP_SINCE_AFTER); break; } /* Stop when the size limit is reached before the end of the crossover, but only show this as an error for >= the default max size. FIXME: Maybe should make it a param choice whether this is an error. */ if (s.size >= param->max_size && param->max_size >= DEFAULT_MAX_SIZE) { fprintf (stderr, "%s\n", param->name); fprintf (stderr, "sizes %ld to %ld total %d measurements\n", (long) dat[0].size, (long) dat[ndat-1].size, ndat); fprintf (stderr, " max size reached before end of crossover\n"); break; } } if (option_trace >= 1) printf ("sizes %ld to %ld total %d measurements\n", (long) dat[0].size, (long) dat[ndat-1].size, ndat); *threshold = dat[analyze_dat (1)].size; if (param->min_is_always) { if (*threshold == param->min_size) *threshold = 0; } if (! param->noprint || option_trace) print_define_end (param->name, *threshold); } /* Special probing for the fft thresholds. The size restrictions on the FFTs mean the graph of time vs size has a step effect. See this for example using ./speed -s 4096-16384 -t 128 -P foo mpn_mul_fft.8 mpn_mul_fft.9 gnuplot foo.gnuplot The current approach is to compare routines at the midpoint of relevant steps. Arguably a more sophisticated system of threshold data is wanted if this step effect remains. */ struct fft_param_t { const char *table_name; const char *threshold_name; const char *modf_threshold_name; mp_size_t *p_threshold; mp_size_t *p_modf_threshold; mp_size_t first_size; mp_size_t max_size; speed_function_t function; speed_function_t mul_modf_function; speed_function_t mul_function; mp_size_t sqr; }; /* mpn_mul_fft requires pl a multiple of 2^k limbs, but with N=pl*BIT_PER_MP_LIMB it internally also pads out so N/2^k is a multiple of 2^(k-1) bits. */ mp_size_t fft_step_size (int k) { mp_size_t step; step = MAX ((mp_size_t) 1 << (k-1), GMP_LIMB_BITS) / GMP_LIMB_BITS; step *= (mp_size_t) 1 << k; if (step <= 0) { printf ("Can't handle k=%d\n", k); abort (); } return step; } mp_size_t fft_next_size (mp_size_t pl, int k) { mp_size_t m = fft_step_size (k); /* printf ("[k=%d %ld] %ld ->", k, m, pl); */ if (pl == 0 || (pl & (m-1)) != 0) pl = (pl | (m-1)) + 1; /* printf (" %ld\n", pl); */ return pl; } #define NMAX_DEFAULT 1000000 #define MAX_REPS 25 #define MIN_REPS 5 static inline size_t mpn_mul_fft_lcm (size_t a, unsigned int k) { unsigned int l = k; while (a % 2 == 0 && k > 0) { a >>= 1; k--; } return a << l; } mp_size_t fftfill (mp_size_t pl, int k, int sqr) { mp_size_t maxLK; mp_bitcnt_t N, Nprime, nprime, M; N = pl * GMP_NUMB_BITS; M = N >> k; maxLK = mpn_mul_fft_lcm ((unsigned long) GMP_NUMB_BITS, k); Nprime = (1 + (2 * M + k + 2) / maxLK) * maxLK; nprime = Nprime / GMP_NUMB_BITS; if (nprime >= (sqr ? SQR_FFT_MODF_THRESHOLD : MUL_FFT_MODF_THRESHOLD)) { size_t K2; for (;;) { K2 = 1L << mpn_fft_best_k (nprime, sqr); if ((nprime & (K2 - 1)) == 0) break; nprime = (nprime + K2 - 1) & -K2; Nprime = nprime * GMP_LIMB_BITS; } } ASSERT_ALWAYS (nprime < pl); return Nprime; } static int compare_double (const void *ap, const void *bp) { double a = * (const double *) ap; double b = * (const double *) bp; if (a < b) return -1; else if (a > b) return 1; else return 0; } double median (double *times, int n) { qsort (times, n, sizeof (double), compare_double); return times[n/2]; } #define FFT_CACHE_SIZE 25 typedef struct fft_cache { mp_size_t n; double time; } fft_cache_t; fft_cache_t fft_cache[FFT_CACHE_SIZE]; double cached_measure (mp_ptr rp, mp_srcptr ap, mp_srcptr bp, mp_size_t n, int k, int n_measurements) { int i; double t, ttab[MAX_REPS]; if (fft_cache[k].n == n) return fft_cache[k].time; for (i = 0; i < n_measurements; i++) { speed_starttime (); mpn_mul_fft (rp, n, ap, n, bp, n, k); ttab[i] = speed_endtime (); } t = median (ttab, n_measurements); fft_cache[k].n = n; fft_cache[k].time = t; return t; } #define INSERT_FFTTAB(idx, nval, kval) \ do { \ fft_tab[idx].n = nval; \ fft_tab[idx].k = kval; \ fft_tab[idx+1].n = -1; /* sentinel */ \ fft_tab[idx+1].k = -1; \ } while (0) int fftmes (mp_size_t nmin, mp_size_t nmax, int initial_k, struct fft_param_t *p, int idx, int print) { mp_size_t n, n1, prev_n1; int k, best_k, last_best_k, kmax; int eff, prev_eff; double t0, t1; int n_measurements; mp_limb_t *ap, *bp, *rp; mp_size_t alloc; char *linepref; struct fft_table_nk *fft_tab; fft_tab = mpn_fft_table3[p->sqr]; for (k = 0; k < FFT_CACHE_SIZE; k++) fft_cache[k].n = 0; if (nmin < (p->sqr ? SQR_FFT_MODF_THRESHOLD : MUL_FFT_MODF_THRESHOLD)) { nmin = (p->sqr ? SQR_FFT_MODF_THRESHOLD : MUL_FFT_MODF_THRESHOLD); } if (print) printf ("#define %s%*s", p->table_name, 38, ""); if (idx == 0) { INSERT_FFTTAB (0, nmin, initial_k); if (print) { printf ("\\\n { "); printf ("{%7u,%2u}", fft_tab[0].n, fft_tab[0].k); linepref = " "; } idx = 1; } ap = malloc (sizeof (mp_limb_t)); if (p->sqr) bp = ap; else bp = malloc (sizeof (mp_limb_t)); rp = malloc (sizeof (mp_limb_t)); alloc = 1; /* Round n to comply to initial k value */ n = (nmin + ((1ul << initial_k) - 1)) & (MP_SIZE_T_MAX << initial_k); n_measurements = (18 - initial_k) | 1; n_measurements = MAX (n_measurements, MIN_REPS); n_measurements = MIN (n_measurements, MAX_REPS); last_best_k = initial_k; best_k = initial_k; while (n < nmax) { int start_k, end_k; /* Assume the current best k is best until we hit its next FFT step. */ t0 = 99999; prev_n1 = n + 1; start_k = MAX (4, best_k - 4); end_k = MIN (24, best_k + 4); for (k = start_k; k <= end_k; k++) { n1 = mpn_fft_next_size (prev_n1, k); eff = 200 * (n1 * GMP_NUMB_BITS >> k) / fftfill (n1, k, p->sqr); if (eff < 70) /* avoid measuring too slow fft:s */ continue; if (n1 > alloc) { alloc = n1; if (p->sqr) { ap = realloc (ap, sizeof (mp_limb_t)); rp = realloc (rp, sizeof (mp_limb_t)); ap = bp = realloc (ap, alloc * sizeof (mp_limb_t)); mpn_random (ap, alloc); rp = realloc (rp, alloc * sizeof (mp_limb_t)); } else { ap = realloc (ap, sizeof (mp_limb_t)); bp = realloc (bp, sizeof (mp_limb_t)); rp = realloc (rp, sizeof (mp_limb_t)); ap = realloc (ap, alloc * sizeof (mp_limb_t)); mpn_random (ap, alloc); bp = realloc (bp, alloc * sizeof (mp_limb_t)); mpn_random (bp, alloc); rp = realloc (rp, alloc * sizeof (mp_limb_t)); } } t1 = cached_measure (rp, ap, bp, n1, k, n_measurements); if (t1 * n_measurements > 0.3) n_measurements -= 2; n_measurements = MAX (n_measurements, MIN_REPS); if (t1 < t0) { best_k = k; t0 = t1; } } n1 = mpn_fft_next_size (prev_n1, best_k); if (last_best_k != best_k) { ASSERT_ALWAYS ((prev_n1 & ((1ul << last_best_k) - 1)) == 1); if (idx >= FFT_TABLE3_SIZE) { printf ("FFT table exhausted, increase FFT_TABLE3_SIZE in gmp-impl.h\n"); abort (); } INSERT_FFTTAB (idx, prev_n1 >> last_best_k, best_k); if (print) { printf (", "); if (idx % 4 == 0) printf ("\\\n "); printf ("{%7u,%2u}", fft_tab[idx].n, fft_tab[idx].k); } if (option_trace >= 2) { printf ("{%lu,%u}\n", prev_n1, best_k); fflush (stdout); } last_best_k = best_k; idx++; } for (;;) { prev_n1 = n1; prev_eff = fftfill (prev_n1, best_k, p->sqr); n1 = mpn_fft_next_size (prev_n1 + 1, best_k); eff = fftfill (n1, best_k, p->sqr); if (eff != prev_eff) break; } n = prev_n1; } kmax = sizeof (mp_size_t) * 4; /* GMP_MP_SIZE_T_BITS / 2 */ kmax = MIN (kmax, 25-1); for (k = last_best_k + 1; k <= kmax; k++) { if (idx >= FFT_TABLE3_SIZE) { printf ("FFT table exhausted, increase FFT_TABLE3_SIZE in gmp-impl.h\n"); abort (); } INSERT_FFTTAB (idx, ((1ul << (2*k-2)) + 1) >> (k-1), k); if (print) { printf (", "); if (idx % 4 == 0) printf ("\\\n "); printf ("{%7u,%2u}", fft_tab[idx].n, fft_tab[idx].k); } idx++; } if (print) printf (" }\n"); free (ap); if (! p->sqr) free (bp); free (rp); return idx; } void fft (struct fft_param_t *p) { mp_size_t size; int k, idx, initial_k; /*** Generate MUL_FFT_MODF_THRESHOLD / SQR_FFT_MODF_THRESHOLD ***/ #if 1 { /* Use plain one() mechanism, for some reasonable initial values of k. The advantage is that we don't depend on mpn_fft_table3, which can therefore leave it completely uninitialized. */ static struct param_t param; mp_size_t thres, best_thres; int best_k; char buf[20]; best_thres = MP_SIZE_T_MAX; best_k = -1; for (k = 5; k <= 7; k++) { param.name = p->modf_threshold_name; param.min_size = 100; param.max_size = 2000; param.function = p->mul_function; param.step_factor = 0.0; param.step = 4; param.function2 = p->mul_modf_function; param.noprint = 1; s.r = k; one (&thres, ¶m); if (thres < best_thres) { best_thres = thres; best_k = k; } } *(p->p_modf_threshold) = best_thres; sprintf (buf, "k = %d", best_k); print_define_remark (p->modf_threshold_name, best_thres, buf); initial_k = best_k; } #else size = p->first_size; for (;;) { double tk, tm; size = mpn_fft_next_size (size+1, mpn_fft_best_k (size+1, p->sqr)); k = mpn_fft_best_k (size, p->sqr); if (size >= p->max_size) break; s.size = size + fft_step_size (k) / 2; s.r = k; tk = tuneup_measure (p->mul_modf_function, NULL, &s); if (tk == -1.0) abort (); tm = tuneup_measure (p->mul_function, NULL, &s); if (tm == -1.0) abort (); if (option_trace >= 2) printf ("at %ld size=%ld k=%d %.9f size=%ld modf %.9f\n", (long) size, (long) size + fft_step_size (k) / 2, k, tk, (long) s.size, tm); if (tk < tm) { *p->p_modf_threshold = s.size; print_define (p->modf_threshold_name, *p->p_modf_threshold); break; } } initial_k = ?; #endif /*** Generate MUL_FFT_TABLE3 / SQR_FFT_TABLE3 ***/ idx = fftmes (*p->p_modf_threshold, p->max_size, initial_k, p, 0, 1); printf ("#define %s_SIZE %d\n", p->table_name, idx); /*** Generate MUL_FFT_THRESHOLD / SQR_FFT_THRESHOLD ***/ size = 2 * *p->p_modf_threshold; /* OK? */ for (;;) { double tk, tm; mp_size_t mulmod_size, mul_size;; if (size >= p->max_size) break; mulmod_size = mpn_mulmod_bnm1_next_size (2 * (size + 1)) / 2; mul_size = (size + mulmod_size) / 2; /* middle of step */ s.size = mulmod_size; tk = tuneup_measure (p->function, NULL, &s); if (tk == -1.0) abort (); s.size = mul_size; tm = tuneup_measure (p->mul_function, NULL, &s); if (tm == -1.0) abort (); if (option_trace >= 2) printf ("at %ld size=%ld %.9f size=%ld mul %.9f\n", (long) size, (long) mulmod_size, tk, (long) mul_size, tm); size = mulmod_size; if (tk < tm) { *p->p_threshold = s.size; print_define (p->threshold_name, *p->p_threshold); break; } } } /* Start karatsuba from 4, since the Cray t90 ieee code is much faster at 2, giving wrong results. */ void tune_mul_n (void) { static struct param_t param; mp_size_t next_toom_start; int something_changed; param.function = speed_mpn_mul_n; param.name = "MUL_TOOM22_THRESHOLD"; param.min_size = MAX (4, MPN_TOOM22_MUL_MINSIZE); param.max_size = MUL_TOOM22_THRESHOLD_LIMIT-1; one (&mul_toom22_threshold, ¶m); param.noprint = 1; /* Threshold sequence loop. Disable functions that would be used in a very narrow range, re-measuring things when that happens. */ something_changed = 1; while (something_changed) { something_changed = 0; next_toom_start = mul_toom22_threshold; if (mul_toom33_threshold != 0) { param.name = "MUL_TOOM33_THRESHOLD"; param.min_size = MAX (next_toom_start, MPN_TOOM33_MUL_MINSIZE); param.max_size = MUL_TOOM33_THRESHOLD_LIMIT-1; one (&mul_toom33_threshold, ¶m); if (next_toom_start * 1.05 >= mul_toom33_threshold) { mul_toom33_threshold = 0; something_changed = 1; } } next_toom_start = MAX (next_toom_start, mul_toom33_threshold); if (mul_toom44_threshold != 0) { param.name = "MUL_TOOM44_THRESHOLD"; param.min_size = MAX (next_toom_start, MPN_TOOM44_MUL_MINSIZE); param.max_size = MUL_TOOM44_THRESHOLD_LIMIT-1; one (&mul_toom44_threshold, ¶m); if (next_toom_start * 1.05 >= mul_toom44_threshold) { mul_toom44_threshold = 0; something_changed = 1; } } next_toom_start = MAX (next_toom_start, mul_toom44_threshold); if (mul_toom6h_threshold != 0) { param.name = "MUL_TOOM6H_THRESHOLD"; param.min_size = MAX (next_toom_start, MPN_TOOM6H_MUL_MINSIZE); param.max_size = MUL_TOOM6H_THRESHOLD_LIMIT-1; one (&mul_toom6h_threshold, ¶m); if (next_toom_start * 1.05 >= mul_toom6h_threshold) { mul_toom6h_threshold = 0; something_changed = 1; } } next_toom_start = MAX (next_toom_start, mul_toom6h_threshold); if (mul_toom8h_threshold != 0) { param.name = "MUL_TOOM8H_THRESHOLD"; param.min_size = MAX (next_toom_start, MPN_TOOM8H_MUL_MINSIZE); param.max_size = MUL_TOOM8H_THRESHOLD_LIMIT-1; one (&mul_toom8h_threshold, ¶m); if (next_toom_start * 1.05 >= mul_toom8h_threshold) { mul_toom8h_threshold = 0; something_changed = 1; } } } print_define ("MUL_TOOM33_THRESHOLD", MUL_TOOM33_THRESHOLD); print_define ("MUL_TOOM44_THRESHOLD", MUL_TOOM44_THRESHOLD); print_define ("MUL_TOOM6H_THRESHOLD", MUL_TOOM6H_THRESHOLD); print_define ("MUL_TOOM8H_THRESHOLD", MUL_TOOM8H_THRESHOLD); /* disabled until tuned */ MUL_FFT_THRESHOLD = MP_SIZE_T_MAX; } void tune_mul (void) { static struct param_t param; mp_size_t thres; param.noprint = 1; param.function = speed_mpn_toom32_for_toom43_mul; param.function2 = speed_mpn_toom43_for_toom32_mul; param.name = "MUL_TOOM32_TO_TOOM43_THRESHOLD"; param.min_size = MPN_TOOM43_MUL_MINSIZE * 24 / 17; one (&thres, ¶m); mul_toom32_to_toom43_threshold = thres * 17 / 24; print_define ("MUL_TOOM32_TO_TOOM43_THRESHOLD", mul_toom32_to_toom43_threshold); param.function = speed_mpn_toom32_for_toom53_mul; param.function2 = speed_mpn_toom53_for_toom32_mul; param.name = "MUL_TOOM32_TO_TOOM53_THRESHOLD"; param.min_size = MPN_TOOM53_MUL_MINSIZE * 30 / 19; one (&thres, ¶m); mul_toom32_to_toom53_threshold = thres * 19 / 30; print_define ("MUL_TOOM32_TO_TOOM53_THRESHOLD", mul_toom32_to_toom53_threshold); param.function = speed_mpn_toom42_for_toom53_mul; param.function2 = speed_mpn_toom53_for_toom42_mul; param.name = "MUL_TOOM42_TO_TOOM53_THRESHOLD"; param.min_size = MPN_TOOM53_MUL_MINSIZE * 20 / 11; one (&thres, ¶m); mul_toom42_to_toom53_threshold = thres * 11 / 20; print_define ("MUL_TOOM42_TO_TOOM53_THRESHOLD", mul_toom42_to_toom53_threshold); param.function = speed_mpn_toom42_mul; param.function2 = speed_mpn_toom63_mul; param.name = "MUL_TOOM42_TO_TOOM63_THRESHOLD"; param.min_size = MPN_TOOM63_MUL_MINSIZE * 2; one (&thres, ¶m); mul_toom42_to_toom63_threshold = thres / 2; print_define ("MUL_TOOM42_TO_TOOM63_THRESHOLD", mul_toom42_to_toom63_threshold); /* Use ratio 5/6 when measuring, the middle of the range 2/3 to 1. */ param.function = speed_mpn_toom43_for_toom54_mul; param.function2 = speed_mpn_toom54_for_toom43_mul; param.name = "MUL_TOOM43_TO_TOOM54_THRESHOLD"; param.min_size = MPN_TOOM54_MUL_MINSIZE * 6 / 5; one (&thres, ¶m); mul_toom43_to_toom54_threshold = thres * 5 / 6; print_define ("MUL_TOOM43_TO_TOOM54_THRESHOLD", mul_toom43_to_toom54_threshold); } void tune_mullo (void) { static struct param_t param; param.function = speed_mpn_mullo_n; param.name = "MULLO_BASECASE_THRESHOLD"; param.min_size = 1; param.min_is_always = 1; param.max_size = MULLO_BASECASE_THRESHOLD_LIMIT-1; param.stop_factor = 1.5; param.noprint = 1; one (&mullo_basecase_threshold, ¶m); param.name = "MULLO_DC_THRESHOLD"; param.min_size = 8; param.min_is_always = 0; param.max_size = 1000; one (&mullo_dc_threshold, ¶m); if (mullo_basecase_threshold >= mullo_dc_threshold) { print_define ("MULLO_BASECASE_THRESHOLD", mullo_dc_threshold); print_define_remark ("MULLO_DC_THRESHOLD", 0, "never mpn_mullo_basecase"); } else { print_define ("MULLO_BASECASE_THRESHOLD", mullo_basecase_threshold); print_define ("MULLO_DC_THRESHOLD", mullo_dc_threshold); } #if WANT_FFT param.name = "MULLO_MUL_N_THRESHOLD"; param.min_size = mullo_dc_threshold; param.max_size = 2 * mul_fft_threshold; param.noprint = 0; param.step_factor = 0.03; one (&mullo_mul_n_threshold, ¶m); #else print_define_remark ("MULLO_MUL_N_THRESHOLD", MP_SIZE_T_MAX, "without FFT use mullo forever"); #endif } void tune_mulmid (void) { static struct param_t param; param.name = "MULMID_TOOM42_THRESHOLD"; param.function = speed_mpn_mulmid_n; param.min_size = 4; param.max_size = 100; one (&mulmid_toom42_threshold, ¶m); } void tune_mulmod_bnm1 (void) { static struct param_t param; param.name = "MULMOD_BNM1_THRESHOLD"; param.function = speed_mpn_mulmod_bnm1; param.min_size = 4; param.max_size = 100; one (&mulmod_bnm1_threshold, ¶m); } void tune_sqrmod_bnm1 (void) { static struct param_t param; param.name = "SQRMOD_BNM1_THRESHOLD"; param.function = speed_mpn_sqrmod_bnm1; param.min_size = 4; param.max_size = 100; one (&sqrmod_bnm1_threshold, ¶m); } /* Start the basecase from 3, since 1 is a special case, and if mul_basecase is faster only at size==2 then we don't want to bother with extra code just for that. Start karatsuba from 4 same as MUL above. */ void tune_sqr (void) { /* disabled until tuned */ SQR_FFT_THRESHOLD = MP_SIZE_T_MAX; if (HAVE_NATIVE_mpn_sqr_basecase) { print_define_remark ("SQR_BASECASE_THRESHOLD", 0, "always (native)"); sqr_basecase_threshold = 0; } else { static struct param_t param; param.name = "SQR_BASECASE_THRESHOLD"; param.function = speed_mpn_sqr; param.min_size = 3; param.min_is_always = 1; param.max_size = TUNE_SQR_TOOM2_MAX; param.noprint = 1; one (&sqr_basecase_threshold, ¶m); } { static struct param_t param; param.name = "SQR_TOOM2_THRESHOLD"; param.function = speed_mpn_sqr; param.min_size = MAX (4, MPN_TOOM2_SQR_MINSIZE); param.max_size = TUNE_SQR_TOOM2_MAX; param.noprint = 1; one (&sqr_toom2_threshold, ¶m); if (! HAVE_NATIVE_mpn_sqr_basecase && sqr_toom2_threshold < sqr_basecase_threshold) { /* Karatsuba becomes faster than mul_basecase before sqr_basecase does. Arrange for the expression "BELOW_THRESHOLD (un, SQR_TOOM2_THRESHOLD))" which selects mpn_sqr_basecase in mpn_sqr to be false, by setting SQR_TOOM2_THRESHOLD to zero, making SQR_BASECASE_THRESHOLD the toom2 threshold. */ sqr_basecase_threshold = SQR_TOOM2_THRESHOLD; SQR_TOOM2_THRESHOLD = 0; print_define_remark ("SQR_BASECASE_THRESHOLD", sqr_basecase_threshold, "toom2"); print_define_remark ("SQR_TOOM2_THRESHOLD",SQR_TOOM2_THRESHOLD, "never sqr_basecase"); } else { if (! HAVE_NATIVE_mpn_sqr_basecase) print_define ("SQR_BASECASE_THRESHOLD", sqr_basecase_threshold); print_define ("SQR_TOOM2_THRESHOLD", SQR_TOOM2_THRESHOLD); } } { static struct param_t param; mp_size_t next_toom_start; int something_changed; param.function = speed_mpn_sqr; param.noprint = 1; /* Threshold sequence loop. Disable functions that would be used in a very narrow range, re-measuring things when that happens. */ something_changed = 1; while (something_changed) { something_changed = 0; next_toom_start = MAX (sqr_toom2_threshold, sqr_basecase_threshold); sqr_toom3_threshold = SQR_TOOM3_THRESHOLD_LIMIT; param.name = "SQR_TOOM3_THRESHOLD"; param.min_size = MAX (next_toom_start, MPN_TOOM3_SQR_MINSIZE); param.max_size = SQR_TOOM3_THRESHOLD_LIMIT-1; one (&sqr_toom3_threshold, ¶m); next_toom_start = MAX (next_toom_start, sqr_toom3_threshold); if (sqr_toom4_threshold != 0) { param.name = "SQR_TOOM4_THRESHOLD"; sqr_toom4_threshold = SQR_TOOM4_THRESHOLD_LIMIT; param.min_size = MAX (next_toom_start, MPN_TOOM4_SQR_MINSIZE); param.max_size = SQR_TOOM4_THRESHOLD_LIMIT-1; one (&sqr_toom4_threshold, ¶m); if (next_toom_start * 1.05 >= sqr_toom4_threshold) { sqr_toom4_threshold = 0; something_changed = 1; } } next_toom_start = MAX (next_toom_start, sqr_toom4_threshold); if (sqr_toom6_threshold != 0) { param.name = "SQR_TOOM6_THRESHOLD"; sqr_toom6_threshold = SQR_TOOM6_THRESHOLD_LIMIT; param.min_size = MAX (next_toom_start, MPN_TOOM6_SQR_MINSIZE); param.max_size = SQR_TOOM6_THRESHOLD_LIMIT-1; one (&sqr_toom6_threshold, ¶m); if (next_toom_start * 1.05 >= sqr_toom6_threshold) { sqr_toom6_threshold = 0; something_changed = 1; } } next_toom_start = MAX (next_toom_start, sqr_toom6_threshold); if (sqr_toom8_threshold != 0) { param.name = "SQR_TOOM8_THRESHOLD"; sqr_toom8_threshold = SQR_TOOM8_THRESHOLD_LIMIT; param.min_size = MAX (next_toom_start, MPN_TOOM8_SQR_MINSIZE); param.max_size = SQR_TOOM8_THRESHOLD_LIMIT-1; one (&sqr_toom8_threshold, ¶m); if (next_toom_start * 1.05 >= sqr_toom8_threshold) { sqr_toom8_threshold = 0; something_changed = 1; } } } print_define ("SQR_TOOM3_THRESHOLD", SQR_TOOM3_THRESHOLD); print_define ("SQR_TOOM4_THRESHOLD", SQR_TOOM4_THRESHOLD); print_define ("SQR_TOOM6_THRESHOLD", SQR_TOOM6_THRESHOLD); print_define ("SQR_TOOM8_THRESHOLD", SQR_TOOM8_THRESHOLD); } } void tune_dc_div (void) { s.r = 0; /* clear to make speed function do 2n/n */ { static struct param_t param; param.name = "DC_DIV_QR_THRESHOLD"; param.function = speed_mpn_sbpi1_div_qr; param.function2 = speed_mpn_dcpi1_div_qr; param.min_size = 6; one (&dc_div_qr_threshold, ¶m); } { static struct param_t param; param.name = "DC_DIVAPPR_Q_THRESHOLD"; param.function = speed_mpn_sbpi1_divappr_q; param.function2 = speed_mpn_dcpi1_divappr_q; param.min_size = 6; one (&dc_divappr_q_threshold, ¶m); } } static double speed_mpn_sbordcpi1_div_qr (struct speed_params *s) { if (s->size < DC_DIV_QR_THRESHOLD) return speed_mpn_sbpi1_div_qr (s); else return speed_mpn_dcpi1_div_qr (s); } void tune_mu_div (void) { s.r = 0; /* clear to make speed function do 2n/n */ { static struct param_t param; param.name = "MU_DIV_QR_THRESHOLD"; param.function = speed_mpn_dcpi1_div_qr; param.function2 = speed_mpn_mu_div_qr; param.min_size = mul_toom22_threshold; param.max_size = 5000; param.step_factor = 0.02; one (&mu_div_qr_threshold, ¶m); } { static struct param_t param; param.name = "MU_DIVAPPR_Q_THRESHOLD"; param.function = speed_mpn_dcpi1_divappr_q; param.function2 = speed_mpn_mu_divappr_q; param.min_size = mul_toom22_threshold; param.max_size = 5000; param.step_factor = 0.02; one (&mu_divappr_q_threshold, ¶m); } { static struct param_t param; param.name = "MUPI_DIV_QR_THRESHOLD"; param.function = speed_mpn_sbordcpi1_div_qr; param.function2 = speed_mpn_mupi_div_qr; param.min_size = 6; param.min_is_always = 1; param.max_size = 1000; param.step_factor = 0.02; one (&mupi_div_qr_threshold, ¶m); } } void tune_dc_bdiv (void) { s.r = 0; /* clear to make speed function do 2n/n*/ { static struct param_t param; param.name = "DC_BDIV_QR_THRESHOLD"; param.function = speed_mpn_sbpi1_bdiv_qr; param.function2 = speed_mpn_dcpi1_bdiv_qr; param.min_size = 4; one (&dc_bdiv_qr_threshold, ¶m); } { static struct param_t param; param.name = "DC_BDIV_Q_THRESHOLD"; param.function = speed_mpn_sbpi1_bdiv_q; param.function2 = speed_mpn_dcpi1_bdiv_q; param.min_size = 4; one (&dc_bdiv_q_threshold, ¶m); } } void tune_mu_bdiv (void) { s.r = 0; /* clear to make speed function do 2n/n*/ { static struct param_t param; param.name = "MU_BDIV_QR_THRESHOLD"; param.function = speed_mpn_dcpi1_bdiv_qr; param.function2 = speed_mpn_mu_bdiv_qr; param.min_size = mul_toom22_threshold; param.max_size = 5000; param.step_factor = 0.02; one (&mu_bdiv_qr_threshold, ¶m); } { static struct param_t param; param.name = "MU_BDIV_Q_THRESHOLD"; param.function = speed_mpn_dcpi1_bdiv_q; param.function2 = speed_mpn_mu_bdiv_q; param.min_size = mul_toom22_threshold; param.max_size = 5000; param.step_factor = 0.02; one (&mu_bdiv_q_threshold, ¶m); } } void tune_invertappr (void) { static struct param_t param; param.function = speed_mpn_ni_invertappr; param.name = "INV_MULMOD_BNM1_THRESHOLD"; param.min_size = 4; one (&inv_mulmod_bnm1_threshold, ¶m); param.function = speed_mpn_invertappr; param.name = "INV_NEWTON_THRESHOLD"; param.min_size = 3; one (&inv_newton_threshold, ¶m); } void tune_invert (void) { static struct param_t param; param.function = speed_mpn_invert; param.name = "INV_APPR_THRESHOLD"; param.min_size = 3; one (&inv_appr_threshold, ¶m); } void tune_binvert (void) { static struct param_t param; param.function = speed_mpn_binvert; param.name = "BINV_NEWTON_THRESHOLD"; param.min_size = 8; /* pointless with smaller operands */ one (&binv_newton_threshold, ¶m); } void tune_redc (void) { #define TUNE_REDC_2_MAX 100 #if HAVE_NATIVE_mpn_addmul_2 || HAVE_NATIVE_mpn_redc_2 #define WANT_REDC_2 1 #endif #if WANT_REDC_2 { static struct param_t param; param.name = "REDC_1_TO_REDC_2_THRESHOLD"; param.function = speed_mpn_redc_1; param.function2 = speed_mpn_redc_2; param.min_size = 1; param.min_is_always = 1; param.max_size = TUNE_REDC_2_MAX; param.noprint = 1; param.stop_factor = 1.5; one (&redc_1_to_redc_2_threshold, ¶m); } { static struct param_t param; param.name = "REDC_2_TO_REDC_N_THRESHOLD"; param.function = speed_mpn_redc_2; param.function2 = speed_mpn_redc_n; param.min_size = 16; param.noprint = 1; one (&redc_2_to_redc_n_threshold, ¶m); } if (redc_1_to_redc_2_threshold >= redc_2_to_redc_n_threshold) { redc_2_to_redc_n_threshold = 0; /* disable redc_2 */ /* Never use redc2, measure redc_1 -> redc_n cutoff, store result as REDC_1_TO_REDC_2_THRESHOLD. */ { static struct param_t param; param.name = "REDC_1_TO_REDC_2_THRESHOLD"; param.function = speed_mpn_redc_1; param.function2 = speed_mpn_redc_n; param.min_size = 16; param.noprint = 1; one (&redc_1_to_redc_2_threshold, ¶m); } } print_define ("REDC_1_TO_REDC_2_THRESHOLD", REDC_1_TO_REDC_2_THRESHOLD); print_define ("REDC_2_TO_REDC_N_THRESHOLD", REDC_2_TO_REDC_N_THRESHOLD); #else { static struct param_t param; param.name = "REDC_1_TO_REDC_N_THRESHOLD"; param.function = speed_mpn_redc_1; param.function2 = speed_mpn_redc_n; param.min_size = 16; one (&redc_1_to_redc_n_threshold, ¶m); } #endif } void tune_matrix22_mul (void) { static struct param_t param; param.name = "MATRIX22_STRASSEN_THRESHOLD"; param.function = speed_mpn_matrix22_mul; param.min_size = 2; one (&matrix22_strassen_threshold, ¶m); } void tune_hgcd (void) { static struct param_t param; param.name = "HGCD_THRESHOLD"; param.function = speed_mpn_hgcd; /* We seem to get strange results for small sizes */ param.min_size = 30; one (&hgcd_threshold, ¶m); } void tune_hgcd_appr (void) { static struct param_t param; param.name = "HGCD_APPR_THRESHOLD"; param.function = speed_mpn_hgcd_appr; /* We seem to get strange results for small sizes */ param.min_size = 50; param.stop_since_change = 150; one (&hgcd_appr_threshold, ¶m); } void tune_hgcd_reduce (void) { static struct param_t param; param.name = "HGCD_REDUCE_THRESHOLD"; param.function = speed_mpn_hgcd_reduce; param.min_size = 30; param.max_size = 7000; param.step_factor = 0.04; one (&hgcd_reduce_threshold, ¶m); } void tune_gcd_dc (void) { static struct param_t param; param.name = "GCD_DC_THRESHOLD"; param.function = speed_mpn_gcd; param.min_size = hgcd_threshold; param.max_size = 3000; param.step_factor = 0.02; one (&gcd_dc_threshold, ¶m); } void tune_gcdext_dc (void) { static struct param_t param; param.name = "GCDEXT_DC_THRESHOLD"; param.function = speed_mpn_gcdext; param.min_size = hgcd_threshold; param.max_size = 3000; param.step_factor = 0.02; one (&gcdext_dc_threshold, ¶m); } /* In tune_powm_sec we compute the table used by the win_size function. The cutoff points are in exponent bits, disregarding other operand sizes. It is not possible to use the one framework since it currently uses a granularity of full limbs. */ /* This win_size replaces the variant in the powm code, allowing us to control k in the k-ary algorithms. */ int winsize; int win_size (mp_bitcnt_t eb) { return winsize; } void tune_powm_sec (void) { mp_size_t n; int k, i; mp_size_t itch; mp_bitcnt_t nbits, nbits_next, possible_nbits_cutoff; const int n_max = 3000 / GMP_NUMB_BITS; const int n_measurements = 5; mp_ptr rp, bp, ep, mp, tp; double ttab[n_measurements], tk, tkp1; TMP_DECL; TMP_MARK; possible_nbits_cutoff = 0; k = 1; winsize = 10; /* the itch function needs this */ itch = mpn_sec_powm_itch (n_max, n_max * GMP_NUMB_BITS, n_max); rp = TMP_ALLOC_LIMBS (n_max); bp = TMP_ALLOC_LIMBS (n_max); ep = TMP_ALLOC_LIMBS (n_max); mp = TMP_ALLOC_LIMBS (n_max); tp = TMP_ALLOC_LIMBS (itch); mpn_random (bp, n_max); mpn_random (mp, n_max); mp[0] |= 1; /* How about taking the M operand size into account? An operation R=powm(B,E,N) will take time O(log(E)*M(log(N))) (assuming B = O(M)). Using k-ary and no sliding window, the precomputation will need time O(2^(k-1)*M(log(N))) and the main computation will need O(log(E)*S(N)) + O(log(E)/k*M(N)), for the squarings, multiplications, respectively. An operation R=powm_sec(B,E,N) will take time like powm. Using k-ary, the precomputation will need time O(2^k*M(log(N))) and the main computation will need O(log(E)*S(N)) + O(log(E)/k*M(N)) + O(log(E)/k*2^k*log(N)), for the squarings, multiplications, and full table reads, respectively. */ printf ("#define POWM_SEC_TABLE "); /* For nbits == 1, we should always use k == 1, so no need to tune that. Starting with nbits == 2 also ensure that nbits always is larger than the windowsize k+1. */ for (nbits = 2; nbits <= n_max * GMP_NUMB_BITS; ) { n = (nbits - 1) / GMP_NUMB_BITS + 1; /* Generate E such that sliding-window for k and k+1 works equally well/poorly (but sliding is not used in powm_sec, of course). */ for (i = 0; i < n; i++) ep[i] = ~CNST_LIMB(0); winsize = k; for (i = 0; i < n_measurements; i++) { speed_starttime (); mpn_sec_powm (rp, bp, n, ep, nbits, mp, n, tp); ttab[i] = speed_endtime (); } tk = median (ttab, n_measurements); winsize = k + 1; speed_starttime (); for (i = 0; i < n_measurements; i++) { speed_starttime (); mpn_sec_powm (rp, bp, n, ep, nbits, mp, n, tp); ttab[i] = speed_endtime (); } tkp1 = median (ttab, n_measurements); /* printf ("testing: %ld, %d", nbits, k, ep[n-1]); printf (" %10.5f %10.5f\n", tk, tkp1); */ if (tkp1 < tk) { if (possible_nbits_cutoff) { /* Two consecutive sizes indicate k increase, obey. */ /* Must always have x[k] >= k */ ASSERT_ALWAYS (possible_nbits_cutoff >= k); if (k > 1) printf (","); printf ("%ld", (long) possible_nbits_cutoff); k++; possible_nbits_cutoff = 0; } else { /* One measurement indicate k increase, save nbits for further consideration. */ /* The new larger k gets used for sizes > the cutoff value, hence the cutoff should be one less than the smallest size where it gives a speedup. */ possible_nbits_cutoff = nbits - 1; } } else possible_nbits_cutoff = 0; nbits_next = nbits * 65 / 64; nbits = nbits_next + (nbits_next == nbits); } printf ("\n"); TMP_FREE; } /* size_extra==1 reflects the fact that with high= mod_1_2_to_mod_1_4_threshold) { /* Never use mod_1_2, measure mod_1_1 -> mod_1_4 */ mod_1_2_to_mod_1_4_threshold = 0; param.function = speed_mpn_mod_1_1; param.function2 = speed_mpn_mod_1_4; param.min_is_always = 1; param.name = "MOD_1_1_TO_MOD_1_4_THRESHOLD fake"; param.min_size = 2; one (&mod_1_1_to_mod_1_2_threshold, ¶m); } param.function = speed_mpn_mod_1_tune; param.function2 = NULL; param.name = "MOD_1U_TO_MOD_1_1_THRESHOLD"; param.min_size = 2; param.min_is_always = 0; one (&mod_1u_to_mod_1_1_threshold, ¶m); if (mod_1u_to_mod_1_1_threshold >= mod_1_1_to_mod_1_2_threshold) mod_1_1_to_mod_1_2_threshold = 0; if (mod_1u_to_mod_1_1_threshold >= mod_1_2_to_mod_1_4_threshold) mod_1_2_to_mod_1_4_threshold = 0; print_define_remark ("MOD_1U_TO_MOD_1_1_THRESHOLD", mod_1u_to_mod_1_1_threshold, NULL); print_define_remark ("MOD_1_1_TO_MOD_1_2_THRESHOLD", mod_1_1_to_mod_1_2_threshold, mod_1_1_to_mod_1_2_threshold == 0 ? "never mpn_mod_1_1p" : NULL); print_define_remark ("MOD_1_2_TO_MOD_1_4_THRESHOLD", mod_1_2_to_mod_1_4_threshold, mod_1_2_to_mod_1_4_threshold == 0 ? "never mpn_mod_1s_2p" : NULL); } { static struct param_t param; param.check_size = 256; param.name = "PREINV_MOD_1_TO_MOD_1_THRESHOLD"; s.r = randlimb_norm (); param.function = speed_mpn_preinv_mod_1; param.function2 = speed_mpn_mod_1_tune; param.min_size = 1; one (&preinv_mod_1_to_mod_1_threshold, ¶m); } } /* A non-zero DIVREM_1_UNNORM_THRESHOLD (or DIVREM_1_NORM_THRESHOLD) would imply that udiv_qrnnd_preinv is worth using, but it seems most straightforward to compare mpn_preinv_divrem_1 and mpn_divrem_1_div directly. */ void tune_preinv_divrem_1 (void) { static struct param_t param; speed_function_t divrem_1; const char *divrem_1_name; double t1, t2; if (GMP_NAIL_BITS != 0) { print_define_remark ("USE_PREINV_DIVREM_1", 0, "no preinv with nails"); return; } /* Any native version of mpn_preinv_divrem_1 is assumed to exist because it's faster than mpn_divrem_1. */ if (HAVE_NATIVE_mpn_preinv_divrem_1) { print_define_remark ("USE_PREINV_DIVREM_1", 1, "native"); return; } /* If udiv_qrnnd_preinv is the only division method then of course mpn_preinv_divrem_1 should be used. */ if (UDIV_PREINV_ALWAYS) { print_define_remark ("USE_PREINV_DIVREM_1", 1, "preinv always"); return; } /* If we've got an assembler version of mpn_divrem_1, then compare against that, not the mpn_divrem_1_div generic C. */ if (HAVE_NATIVE_mpn_divrem_1) { divrem_1 = speed_mpn_divrem_1; divrem_1_name = "mpn_divrem_1"; } else { divrem_1 = speed_mpn_divrem_1_div; divrem_1_name = "mpn_divrem_1_div"; } param.data_high = DATA_HIGH_LT_R; /* allow skip one division */ s.size = 200; /* generous but not too big */ /* Divisor, nonzero. Unnormalized so as to exercise the shift!=0 case, since in general that's probably most common, though in fact for a 64-bit limb mp_bases[10].big_base is normalized. */ s.r = urandom() & (GMP_NUMB_MASK >> 4); if (s.r == 0) s.r = 123; t1 = tuneup_measure (speed_mpn_preinv_divrem_1, ¶m, &s); t2 = tuneup_measure (divrem_1, ¶m, &s); if (t1 == -1.0 || t2 == -1.0) { printf ("Oops, can't measure mpn_preinv_divrem_1 and %s at %ld\n", divrem_1_name, (long) s.size); abort (); } if (option_trace >= 1) printf ("size=%ld, mpn_preinv_divrem_1 %.9f, %s %.9f\n", (long) s.size, t1, divrem_1_name, t2); print_define_remark ("USE_PREINV_DIVREM_1", (mp_size_t) (t1 < t2), NULL); } void tune_divrem_2 (void) { static struct param_t param; /* No support for tuning native assembler code, do that by hand and put the results in the .asm file, and there's no need for such thresholds to appear in gmp-mparam.h. */ if (HAVE_NATIVE_mpn_divrem_2) return; if (GMP_NAIL_BITS != 0) { print_define_remark ("DIVREM_2_THRESHOLD", MP_SIZE_T_MAX, "no preinv with nails"); return; } if (UDIV_PREINV_ALWAYS) { print_define_remark ("DIVREM_2_THRESHOLD", 0L, "preinv always"); return; } /* Tune for the integer part of mpn_divrem_2. This will very possibly be a bit out for the fractional part, but that's too bad, the integer part is more important. min_size must be >=2 since nsize>=2 is required, but is set to 4 to save code space if plain division is better only at size==2 or size==3. */ param.name = "DIVREM_2_THRESHOLD"; param.check_size = 256; param.min_size = 4; param.min_is_always = 1; param.size_extra = 2; /* does qsize==nsize-2 divisions */ param.stop_factor = 2.0; s.r = randlimb_norm (); param.function = speed_mpn_divrem_2; one (&divrem_2_threshold, ¶m); } void tune_div_qr_2 (void) { static struct param_t param; param.name = "DIV_QR_2_PI2_THRESHOLD"; param.function = speed_mpn_div_qr_2n; param.check_size = 500; param.min_size = 4; one (&div_qr_2_pi2_threshold, ¶m); } /* mpn_divexact_1 is vaguely expected to be used on smallish divisors, so tune for that. Its speed can differ on odd or even divisor, so take an average threshold for the two. mpn_divrem_1 can vary with high= 1) printf ("size=%ld, mpn_jacobi_base_1 %.9f\n", (long) s.size, t1); t2 = tuneup_measure (speed_mpn_jacobi_base_2, ¶m, &s); if (option_trace >= 1) printf ("size=%ld, mpn_jacobi_base_2 %.9f\n", (long) s.size, t2); t3 = tuneup_measure (speed_mpn_jacobi_base_3, ¶m, &s); if (option_trace >= 1) printf ("size=%ld, mpn_jacobi_base_3 %.9f\n", (long) s.size, t3); t4 = tuneup_measure (speed_mpn_jacobi_base_4, ¶m, &s); if (option_trace >= 1) printf ("size=%ld, mpn_jacobi_base_4 %.9f\n", (long) s.size, t4); if (t1 == -1.0 || t2 == -1.0 || t3 == -1.0 || t4 == -1.0) { printf ("Oops, can't measure all mpn_jacobi_base methods at %ld\n", (long) s.size); abort (); } if (t1 < t2 && t1 < t3 && t1 < t4) method = 1; else if (t2 < t3 && t2 < t4) method = 2; else if (t3 < t4) method = 3; else method = 4; print_define ("JACOBI_BASE_METHOD", method); } void tune_get_str (void) { /* Tune for decimal, it being most common. Some rough testing suggests other bases are different, but not by very much. */ s.r = 10; { static struct param_t param; GET_STR_PRECOMPUTE_THRESHOLD = 0; param.name = "GET_STR_DC_THRESHOLD"; param.function = speed_mpn_get_str; param.min_size = 4; param.max_size = GET_STR_THRESHOLD_LIMIT; one (&get_str_dc_threshold, ¶m); } { static struct param_t param; param.name = "GET_STR_PRECOMPUTE_THRESHOLD"; param.function = speed_mpn_get_str; param.min_size = GET_STR_DC_THRESHOLD; param.max_size = GET_STR_THRESHOLD_LIMIT; one (&get_str_precompute_threshold, ¶m); } } double speed_mpn_pre_set_str (struct speed_params *s) { unsigned char *str; mp_ptr wp; mp_size_t wn; unsigned i; int base; double t; mp_ptr powtab_mem, tp; powers_t powtab[GMP_LIMB_BITS]; mp_size_t un; int chars_per_limb; TMP_DECL; SPEED_RESTRICT_COND (s->size >= 1); base = s->r == 0 ? 10 : s->r; SPEED_RESTRICT_COND (base >= 2 && base <= 256); TMP_MARK; str = TMP_ALLOC (s->size); for (i = 0; i < s->size; i++) str[i] = s->xp[i] % base; LIMBS_PER_DIGIT_IN_BASE (wn, s->size, base); SPEED_TMP_ALLOC_LIMBS (wp, wn, s->align_wp); /* use this during development to check wn is big enough */ /* ASSERT_ALWAYS (mpn_set_str (wp, str, s->size, base) <= wn); */ speed_operand_src (s, (mp_ptr) str, s->size/GMP_LIMB_BYTES); speed_operand_dst (s, wp, wn); speed_cache_fill (s); chars_per_limb = mp_bases[base].chars_per_limb; un = s->size / chars_per_limb + 1; powtab_mem = TMP_BALLOC_LIMBS (mpn_dc_set_str_powtab_alloc (un)); mpn_set_str_compute_powtab (powtab, powtab_mem, un, base); tp = TMP_BALLOC_LIMBS (mpn_dc_set_str_itch (un)); speed_starttime (); i = s->reps; do { mpn_pre_set_str (wp, str, s->size, powtab, tp); } while (--i != 0); t = speed_endtime (); TMP_FREE; return t; } void tune_set_str (void) { s.r = 10; /* decimal */ { static struct param_t param; SET_STR_PRECOMPUTE_THRESHOLD = 0; param.step_factor = 0.01; param.name = "SET_STR_DC_THRESHOLD"; param.function = speed_mpn_pre_set_str; param.min_size = 100; param.max_size = 50000; one (&set_str_dc_threshold, ¶m); } { static struct param_t param; param.step_factor = 0.02; param.name = "SET_STR_PRECOMPUTE_THRESHOLD"; param.function = speed_mpn_set_str; param.min_size = SET_STR_DC_THRESHOLD; param.max_size = 100000; one (&set_str_precompute_threshold, ¶m); } } void tune_fft_mul (void) { static struct fft_param_t param; if (option_fft_max_size == 0) return; param.table_name = "MUL_FFT_TABLE3"; param.threshold_name = "MUL_FFT_THRESHOLD"; param.p_threshold = &mul_fft_threshold; param.modf_threshold_name = "MUL_FFT_MODF_THRESHOLD"; param.p_modf_threshold = &mul_fft_modf_threshold; param.first_size = MUL_TOOM33_THRESHOLD / 2; param.max_size = option_fft_max_size; param.function = speed_mpn_fft_mul; param.mul_modf_function = speed_mpn_mul_fft; param.mul_function = speed_mpn_mul_n; param.sqr = 0; fft (¶m); } void tune_fft_sqr (void) { static struct fft_param_t param; if (option_fft_max_size == 0) return; param.table_name = "SQR_FFT_TABLE3"; param.threshold_name = "SQR_FFT_THRESHOLD"; param.p_threshold = &sqr_fft_threshold; param.modf_threshold_name = "SQR_FFT_MODF_THRESHOLD"; param.p_modf_threshold = &sqr_fft_modf_threshold; param.first_size = SQR_TOOM3_THRESHOLD / 2; param.max_size = option_fft_max_size; param.function = speed_mpn_fft_sqr; param.mul_modf_function = speed_mpn_mul_fft_sqr; param.mul_function = speed_mpn_sqr; param.sqr = 1; fft (¶m); } void tune_fac_ui (void) { static struct param_t param; param.function = speed_mpz_fac_ui_tune; param.name = "FAC_DSC_THRESHOLD"; param.min_size = 70; param.max_size = FAC_DSC_THRESHOLD_LIMIT; one (&fac_dsc_threshold, ¶m); param.name = "FAC_ODD_THRESHOLD"; param.min_size = 22; param.stop_factor = 1.7; param.min_is_always = 1; one (&fac_odd_threshold, ¶m); } void all (void) { time_t start_time, end_time; TMP_DECL; TMP_MARK; SPEED_TMP_ALLOC_LIMBS (s.xp_block, SPEED_BLOCK_SIZE, 0); SPEED_TMP_ALLOC_LIMBS (s.yp_block, SPEED_BLOCK_SIZE, 0); mpn_random (s.xp_block, SPEED_BLOCK_SIZE); mpn_random (s.yp_block, SPEED_BLOCK_SIZE); fprintf (stderr, "Parameters for %s\n", GMP_MPARAM_H_SUGGEST); speed_time_init (); fprintf (stderr, "Using: %s\n", speed_time_string); fprintf (stderr, "speed_precision %d", speed_precision); if (speed_unittime == 1.0) fprintf (stderr, ", speed_unittime 1 cycle"); else fprintf (stderr, ", speed_unittime %.2e secs", speed_unittime); if (speed_cycletime == 1.0 || speed_cycletime == 0.0) fprintf (stderr, ", CPU freq unknown\n"); else fprintf (stderr, ", CPU freq %.2f MHz\n", 1e-6/speed_cycletime); fprintf (stderr, "DEFAULT_MAX_SIZE %d, fft_max_size %ld\n", DEFAULT_MAX_SIZE, (long) option_fft_max_size); fprintf (stderr, "\n"); time (&start_time); { struct tm *tp; tp = localtime (&start_time); printf ("/* Generated by tuneup.c, %d-%02d-%02d, ", tp->tm_year+1900, tp->tm_mon+1, tp->tm_mday); #ifdef __GNUC__ /* gcc sub-minor version doesn't seem to come through as a define */ printf ("gcc %d.%d */\n", __GNUC__, __GNUC_MINOR__); #define PRINTED_COMPILER #endif #if defined (__SUNPRO_C) printf ("Sun C %d.%d */\n", __SUNPRO_C / 0x100, __SUNPRO_C % 0x100); #define PRINTED_COMPILER #endif #if ! defined (__GNUC__) && defined (__sgi) && defined (_COMPILER_VERSION) /* gcc defines __sgi and _COMPILER_VERSION on irix 6, avoid that */ printf ("MIPSpro C %d.%d.%d */\n", _COMPILER_VERSION / 100, _COMPILER_VERSION / 10 % 10, _COMPILER_VERSION % 10); #define PRINTED_COMPILER #endif #if defined (__DECC) && defined (__DECC_VER) printf ("DEC C %d */\n", __DECC_VER); #define PRINTED_COMPILER #endif #if ! defined (PRINTED_COMPILER) printf ("system compiler */\n"); #endif } printf ("\n"); tune_divrem_1 (); tune_mod_1 (); tune_preinv_divrem_1 (); tune_div_qr_1 (); #if 0 tune_divrem_2 (); #endif tune_div_qr_2 (); tune_divexact_1 (); tune_modexact_1_odd (); printf("\n"); tune_mul_n (); printf("\n"); tune_mul (); printf("\n"); tune_sqr (); printf("\n"); tune_mulmid (); printf("\n"); tune_mulmod_bnm1 (); tune_sqrmod_bnm1 (); printf("\n"); tune_fft_mul (); printf("\n"); tune_fft_sqr (); printf ("\n"); tune_mullo (); printf("\n"); tune_dc_div (); tune_dc_bdiv (); printf("\n"); tune_invertappr (); tune_invert (); printf("\n"); tune_binvert (); tune_redc (); printf("\n"); tune_mu_div (); tune_mu_bdiv (); printf("\n"); tune_powm_sec (); printf("\n"); tune_matrix22_mul (); tune_hgcd (); tune_hgcd_appr (); tune_hgcd_reduce(); tune_gcd_dc (); tune_gcdext_dc (); tune_jacobi_base (); printf("\n"); tune_get_str (); tune_set_str (); printf("\n"); tune_fac_ui (); printf("\n"); time (&end_time); printf ("/* Tuneup completed successfully, took %ld seconds */\n", (long) (end_time - start_time)); TMP_FREE; } int main (int argc, char *argv[]) { int opt; /* Unbuffered so if output is redirected to a file it isn't lost if the program is killed part way through. */ setbuf (stdout, NULL); setbuf (stderr, NULL); while ((opt = getopt(argc, argv, "f:o:p:t")) != EOF) { switch (opt) { case 'f': if (optarg[0] == 't') option_fft_trace = 2; else option_fft_max_size = atol (optarg); break; case 'o': speed_option_set (optarg); break; case 'p': speed_precision = atoi (optarg); break; case 't': option_trace++; break; case '?': exit(1); } } all (); exit (0); }