/* * Copyright (c) 2003, 2007-11 Matteo Frigo * Copyright (c) 2003, 2007-11 Massachusetts Institute of Technology * * This program is free software; you can redistribute it and/or modify * it under the terms of 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. * * This program 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 a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * */ #include "api.h" #include /* a flag operation: x is either a flag, in which case xm == 0, or a mask, in which case xm == x; using this we can compactly code the various bit operations via (flags & x) ^ xm or (flags | x) ^ xm. */ typedef struct { unsigned x, xm; } flagmask; typedef struct { flagmask flag; flagmask op; } flagop; #define FLAGP(f, msk)(((f) & (msk).x) ^ (msk).xm) #define OP(f, msk)(((f) | (msk).x) ^ (msk).xm) #define YES(x) {x, 0} #define NO(x) {x, x} #define IMPLIES(predicate, consequence) { predicate, consequence } #define EQV(a, b) IMPLIES(YES(a), YES(b)), IMPLIES(NO(a), NO(b)) #define NEQV(a, b) IMPLIES(YES(a), NO(b)), IMPLIES(NO(a), YES(b)) static void map_flags(unsigned *iflags, unsigned *oflags, const flagop flagmap[], int nmap) { int i; for (i = 0; i < nmap; ++i) if (FLAGP(*iflags, flagmap[i].flag)) *oflags = OP(*oflags, flagmap[i].op); } /* encoding of the planner timelimit into a BITS_FOR_TIMELIMIT-bits nonnegative integer, such that we can still view the integer as ``impatience'': higher means *lower* time limit, and 0 is the highest possible value (about 1 year of calendar time) */ static unsigned timelimit_to_flags(double timelimit) { const double tmax = 365 * 24 * 3600; const double tstep = 1.05; const int nsteps = (1 << BITS_FOR_TIMELIMIT); int x; if (timelimit < 0 || timelimit >= tmax) return 0; if (timelimit <= 1.0e-10) return nsteps - 1; x = (int) (0.5 + (log(tmax / timelimit) / log(tstep))); if (x < 0) x = 0; if (x >= nsteps) x = nsteps - 1; return x; } void X(mapflags)(planner *plnr, unsigned flags) { unsigned l, u, t; /* map of api flags -> api flags, to implement consistency rules and combination flags */ const flagop self_flagmap[] = { /* in some cases (notably for halfcomplex->real transforms), DESTROY_INPUT is the default, so we need to support an inverse flag to disable it. (PRESERVE, DESTROY) -> (PRESERVE, DESTROY) (0, 0) (1, 0) (0, 1) (0, 1) (1, 0) (1, 0) (1, 1) (1, 0) */ IMPLIES(YES(FFTW_PRESERVE_INPUT), NO(FFTW_DESTROY_INPUT)), IMPLIES(NO(FFTW_DESTROY_INPUT), YES(FFTW_PRESERVE_INPUT)), IMPLIES(YES(FFTW_EXHAUSTIVE), YES(FFTW_PATIENT)), IMPLIES(YES(FFTW_ESTIMATE), NO(FFTW_PATIENT)), IMPLIES(YES(FFTW_ESTIMATE), YES(FFTW_ESTIMATE_PATIENT | FFTW_NO_INDIRECT_OP | FFTW_ALLOW_PRUNING)), IMPLIES(NO(FFTW_EXHAUSTIVE), YES(FFTW_NO_SLOW)), /* a canonical set of fftw2-like impatience flags */ IMPLIES(NO(FFTW_PATIENT), YES(FFTW_NO_VRECURSE | FFTW_NO_RANK_SPLITS | FFTW_NO_VRANK_SPLITS | FFTW_NO_NONTHREADED | FFTW_NO_DFT_R2HC | FFTW_NO_FIXED_RADIX_LARGE_N | FFTW_BELIEVE_PCOST)) }; /* map of (processed) api flags to internal problem/planner flags */ const flagop l_flagmap[] = { EQV(FFTW_PRESERVE_INPUT, NO_DESTROY_INPUT), EQV(FFTW_NO_SIMD, NO_SIMD), EQV(FFTW_CONSERVE_MEMORY, CONSERVE_MEMORY), EQV(FFTW_NO_BUFFERING, NO_BUFFERING), NEQV(FFTW_ALLOW_LARGE_GENERIC, NO_LARGE_GENERIC) }; const flagop u_flagmap[] = { IMPLIES(YES(FFTW_EXHAUSTIVE), NO(0xFFFFFFFF)), IMPLIES(NO(FFTW_EXHAUSTIVE), YES(NO_UGLY)), /* the following are undocumented, "beyond-guru" flags that require some understanding of FFTW internals */ EQV(FFTW_ESTIMATE_PATIENT, ESTIMATE), EQV(FFTW_ALLOW_PRUNING, ALLOW_PRUNING), EQV(FFTW_BELIEVE_PCOST, BELIEVE_PCOST), EQV(FFTW_NO_DFT_R2HC, NO_DFT_R2HC), EQV(FFTW_NO_NONTHREADED, NO_NONTHREADED), EQV(FFTW_NO_INDIRECT_OP, NO_INDIRECT_OP), EQV(FFTW_NO_RANK_SPLITS, NO_RANK_SPLITS), EQV(FFTW_NO_VRANK_SPLITS, NO_VRANK_SPLITS), EQV(FFTW_NO_VRECURSE, NO_VRECURSE), EQV(FFTW_NO_SLOW, NO_SLOW), EQV(FFTW_NO_FIXED_RADIX_LARGE_N, NO_FIXED_RADIX_LARGE_N) }; map_flags(&flags, &flags, self_flagmap, NELEM(self_flagmap)); l = u = 0; map_flags(&flags, &l, l_flagmap, NELEM(l_flagmap)); map_flags(&flags, &u, u_flagmap, NELEM(u_flagmap)); /* enforce l <= u */ PLNR_L(plnr) = l; PLNR_U(plnr) = u | l; /* assert that the conversion didn't lose bits */ A(PLNR_L(plnr) == l); A(PLNR_U(plnr) == (u | l)); /* compute flags representation of the timelimit */ t = timelimit_to_flags(plnr->timelimit); PLNR_TIMELIMIT_IMPATIENCE(plnr) = t; A(PLNR_TIMELIMIT_IMPATIENCE(plnr) == t); }