sv-dependency-builds: src/fftw-3.3.3/reodft/reodft00e-splitradix.c annotate

annotate src/fftw-3.3.3/reodft/reodft00e-splitradix.c @ 148:b4bfdf10c4b3

Update Win64 capnp builds to v0.6

author	Chris Cannam <cannam@all-day-breakfast.com>
date	Mon, 22 May 2017 18:56:49 +0100
parents	89f5e221ed7b
children

rev	line source
cannam@95	1 /*
cannam@95	2 * Copyright (c) 2005 Matteo Frigo
cannam@95	3 * Copyright (c) 2005 Massachusetts Institute of Technology
cannam@95	4 *
cannam@95	5 * This program is free software; you can redistribute it and/or modify
cannam@95	6 * it under the terms of the GNU General Public License as published by
cannam@95	7 * the Free Software Foundation; either version 2 of the License, or
cannam@95	8 * (at your option) any later version.
cannam@95	9 *
cannam@95	10 * This program is distributed in the hope that it will be useful,
cannam@95	11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
cannam@95	12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
cannam@95	13 * GNU General Public License for more details.
cannam@95	14 *
cannam@95	15 * You should have received a copy of the GNU General Public License
cannam@95	16 * along with this program; if not, write to the Free Software
cannam@95	17 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
cannam@95	18 *
cannam@95	19 */
cannam@95	20
cannam@95	21
cannam@95	22 /* Do an R{E,O}DFT00 problem (of an odd length n) recursively via an
cannam@95	23 R{E,O}DFT00 problem and an RDFT problem of half the length.
cannam@95	24
cannam@95	25 This works by "logically" expanding the array to a real-even/odd DFT of
cannam@95	26 length 2n-/+2 and then applying the split-radix algorithm.
cannam@95	27
cannam@95	28 In this way, we can avoid having to pad to twice the length
cannam@95	29 (ala redft00-r2hc-pad), saving a factor of ~2 for n=2^m+/-1,
cannam@95	30 but don't incur the accuracy loss that the "ordinary" algorithm
cannam@95	31 sacrifices (ala redft00-r2hc.c).
cannam@95	32 */
cannam@95	33
cannam@95	34 #include "reodft.h"
cannam@95	35
cannam@95	36 typedef struct {
cannam@95	37 solver super;
cannam@95	38 } S;
cannam@95	39
cannam@95	40 typedef struct {
cannam@95	41 plan_rdft super;
cannam@95	42 plan clde, cldo;
cannam@95	43 twid *td;
cannam@95	44 INT is, os;
cannam@95	45 INT n;
cannam@95	46 INT vl;
cannam@95	47 INT ivs, ovs;
cannam@95	48 } P;
cannam@95	49
cannam@95	50 /* redft00 */
cannam@95	51 static void apply_e(const plan ego_, R I, R *O)
cannam@95	52 {
cannam@95	53 const P ego = (const P ) ego_;
cannam@95	54 INT is = ego->is, os = ego->os;
cannam@95	55 INT i, j, n = ego->n + 1, n2 = (n-1)/2;
cannam@95	56 INT iv, vl = ego->vl;
cannam@95	57 INT ivs = ego->ivs, ovs = ego->ovs;
cannam@95	58 R *W = ego->td->W - 2;
cannam@95	59 R *buf;
cannam@95	60
cannam@95	61 buf = (R ) MALLOC(sizeof(R) n2, BUFFERS);
cannam@95	62
cannam@95	63 for (iv = 0; iv < vl; ++iv, I += ivs, O += ovs) {
cannam@95	64 /* do size (n-1)/2 r2hc transform of odd-indexed elements
cannam@95	65 with stride 4, "wrapping around" end of array with even
cannam@95	66 boundary conditions */
cannam@95	67 for (j = 0, i = 1; i < n; i += 4)
cannam@95	68 buf[j++] = I[is * i];
cannam@95	69 for (i = 2*n-2-i; i > 0; i -= 4)
cannam@95	70 buf[j++] = I[is * i];
cannam@95	71 {
cannam@95	72 plan_rdft cld = (plan_rdft ) ego->cldo;
cannam@95	73 cld->apply((plan *) cld, buf, buf);
cannam@95	74 }
cannam@95	75
cannam@95	76 /* do size (n+1)/2 redft00 of the even-indexed elements,
cannam@95	77 writing to O: */
cannam@95	78 {
cannam@95	79 plan_rdft cld = (plan_rdft ) ego->clde;
cannam@95	80 cld->apply((plan *) cld, I, O);
cannam@95	81 }
cannam@95	82
cannam@95	83 /* combine the results with the twiddle factors to get output */
cannam@95	84 { /* DC element */
cannam@95	85 E b20 = O[0], b0 = K(2.0) * buf[0];
cannam@95	86 O[0] = b20 + b0;
cannam@95	87 O[2(n2os)] = b20 - b0;
cannam@95	88 /* O[n2os] = O[n2os]; */
cannam@95	89 }
cannam@95	90 for (i = 1; i < n2 - i; ++i) {
cannam@95	91 E ap, am, br, bi, wr, wi, wbr, wbi;
cannam@95	92 br = buf[i];
cannam@95	93 bi = buf[n2 - i];
cannam@95	94 wr = W[2*i];
cannam@95	95 wi = W[2*i+1];
cannam@95	96 #if FFT_SIGN == -1
cannam@95	97 wbr = K(2.0) * (wrbr + wibi);
cannam@95	98 wbi = K(2.0) * (wrbi - wibr);
cannam@95	99 #else
cannam@95	100 wbr = K(2.0) * (wrbr - wibi);
cannam@95	101 wbi = K(2.0) * (wrbi + wibr);
cannam@95	102 #endif
cannam@95	103 ap = O[i*os];
cannam@95	104 O[i*os] = ap + wbr;
cannam@95	105 O[(2n2 - i)os] = ap - wbr;
cannam@95	106 am = O[(n2 - i)*os];
cannam@95	107 #if FFT_SIGN == -1
cannam@95	108 O[(n2 - i)*os] = am - wbi;
cannam@95	109 O[(n2 + i)*os] = am + wbi;
cannam@95	110 #else
cannam@95	111 O[(n2 - i)*os] = am + wbi;
cannam@95	112 O[(n2 + i)*os] = am - wbi;
cannam@95	113 #endif
cannam@95	114 }
cannam@95	115 if (i == n2 - i) { /* Nyquist element */
cannam@95	116 E ap, wbr;
cannam@95	117 wbr = K(2.0) * (W[2i] buf[i]);
cannam@95	118 ap = O[i*os];
cannam@95	119 O[i*os] = ap + wbr;
cannam@95	120 O[(2n2 - i)os] = ap - wbr;
cannam@95	121 }
cannam@95	122 }
cannam@95	123
cannam@95	124 X(ifree)(buf);
cannam@95	125 }
cannam@95	126
cannam@95	127 /* rodft00 */
cannam@95	128 static void apply_o(const plan ego_, R I, R *O)
cannam@95	129 {
cannam@95	130 const P ego = (const P ) ego_;
cannam@95	131 INT is = ego->is, os = ego->os;
cannam@95	132 INT i, j, n = ego->n - 1, n2 = (n+1)/2;
cannam@95	133 INT iv, vl = ego->vl;
cannam@95	134 INT ivs = ego->ivs, ovs = ego->ovs;
cannam@95	135 R *W = ego->td->W - 2;
cannam@95	136 R *buf;
cannam@95	137
cannam@95	138 buf = (R ) MALLOC(sizeof(R) n2, BUFFERS);
cannam@95	139
cannam@95	140 for (iv = 0; iv < vl; ++iv, I += ivs, O += ovs) {
cannam@95	141 /* do size (n+1)/2 r2hc transform of even-indexed elements
cannam@95	142 with stride 4, "wrapping around" end of array with odd
cannam@95	143 boundary conditions */
cannam@95	144 for (j = 0, i = 0; i < n; i += 4)
cannam@95	145 buf[j++] = I[is * i];
cannam@95	146 for (i = 2*n-i; i > 0; i -= 4)
cannam@95	147 buf[j++] = -I[is * i];
cannam@95	148 {
cannam@95	149 plan_rdft cld = (plan_rdft ) ego->cldo;
cannam@95	150 cld->apply((plan *) cld, buf, buf);
cannam@95	151 }
cannam@95	152
cannam@95	153 /* do size (n-1)/2 rodft00 of the odd-indexed elements,
cannam@95	154 writing to O: */
cannam@95	155 {
cannam@95	156 plan_rdft cld = (plan_rdft ) ego->clde;
cannam@95	157 if (I == O) {
cannam@95	158 /* can't use I+is and I, subplan would lose in-placeness */
cannam@95	159 cld->apply((plan *) cld, I + is, I + is);
cannam@95	160 /* we could maybe avoid this copy by modifying the
cannam@95	161 twiddle loop, but currently I can't be bothered. */
cannam@95	162 A(is >= os);
cannam@95	163 for (i = 0; i < n2-1; ++i)
cannam@95	164 O[osi] = I[is(i+1)];
cannam@95	165 }
cannam@95	166 else
cannam@95	167 cld->apply((plan *) cld, I + is, O);
cannam@95	168 }
cannam@95	169
cannam@95	170 /* combine the results with the twiddle factors to get output */
cannam@95	171 O[(n2-1)os] = K(2.0) buf[0];
cannam@95	172 for (i = 1; i < n2 - i; ++i) {
cannam@95	173 E ap, am, br, bi, wr, wi, wbr, wbi;
cannam@95	174 br = buf[i];
cannam@95	175 bi = buf[n2 - i];
cannam@95	176 wr = W[2*i];
cannam@95	177 wi = W[2*i+1];
cannam@95	178 #if FFT_SIGN == -1
cannam@95	179 wbr = K(2.0) * (wrbr + wibi);
cannam@95	180 wbi = K(2.0) * (wibr - wrbi);
cannam@95	181 #else
cannam@95	182 wbr = K(2.0) * (wrbr - wibi);
cannam@95	183 wbi = K(2.0) * (wrbi + wibr);
cannam@95	184 #endif
cannam@95	185 ap = O[(i-1)*os];
cannam@95	186 O[(i-1)*os] = wbi + ap;
cannam@95	187 O[(2n2-1 - i)os] = wbi - ap;
cannam@95	188 am = O[(n2-1 - i)*os];
cannam@95	189 #if FFT_SIGN == -1
cannam@95	190 O[(n2-1 - i)*os] = wbr + am;
cannam@95	191 O[(n2-1 + i)*os] = wbr - am;
cannam@95	192 #else
cannam@95	193 O[(n2-1 - i)*os] = wbr + am;
cannam@95	194 O[(n2-1 + i)*os] = wbr - am;
cannam@95	195 #endif
cannam@95	196 }
cannam@95	197 if (i == n2 - i) { /* Nyquist element */
cannam@95	198 E ap, wbi;
cannam@95	199 wbi = K(2.0) * (W[2i+1] buf[i]);
cannam@95	200 ap = O[(i-1)*os];
cannam@95	201 O[(i-1)*os] = wbi + ap;
cannam@95	202 O[(2n2-1 - i)os] = wbi - ap;
cannam@95	203 }
cannam@95	204 }
cannam@95	205
cannam@95	206 X(ifree)(buf);
cannam@95	207 }
cannam@95	208
cannam@95	209 static void awake(plan *ego_, enum wakefulness wakefulness)
cannam@95	210 {
cannam@95	211 P ego = (P ) ego_;
cannam@95	212 static const tw_instr reodft00e_tw[] = {
cannam@95	213 { TW_COS, 1, 1 },
cannam@95	214 { TW_SIN, 1, 1 },
cannam@95	215 { TW_NEXT, 1, 0 }
cannam@95	216 };
cannam@95	217
cannam@95	218 X(plan_awake)(ego->clde, wakefulness);
cannam@95	219 X(plan_awake)(ego->cldo, wakefulness);
cannam@95	220 X(twiddle_awake)(wakefulness, &ego->td, reodft00e_tw,
cannam@95	221 2*ego->n, 1, ego->n/4);
cannam@95	222 }
cannam@95	223
cannam@95	224 static void destroy(plan *ego_)
cannam@95	225 {
cannam@95	226 P ego = (P ) ego_;
cannam@95	227 X(plan_destroy_internal)(ego->cldo);
cannam@95	228 X(plan_destroy_internal)(ego->clde);
cannam@95	229 }
cannam@95	230
cannam@95	231 static void print(const plan ego_, printer p)
cannam@95	232 {
cannam@95	233 const P ego = (const P ) ego_;
cannam@95	234 if (ego->super.apply == apply_e)
cannam@95	235 p->print(p, "(redft00e-splitradix-%D%v%(%p%)%(%p%))",
cannam@95	236 ego->n + 1, ego->vl, ego->clde, ego->cldo);
cannam@95	237 else
cannam@95	238 p->print(p, "(rodft00e-splitradix-%D%v%(%p%)%(%p%))",
cannam@95	239 ego->n - 1, ego->vl, ego->clde, ego->cldo);
cannam@95	240 }
cannam@95	241
cannam@95	242 static int applicable0(const solver ego_, const problem p_)
cannam@95	243 {
cannam@95	244 const problem_rdft p = (const problem_rdft ) p_;
cannam@95	245 UNUSED(ego_);
cannam@95	246
cannam@95	247 return (1
cannam@95	248 && p->sz->rnk == 1
cannam@95	249 && p->vecsz->rnk <= 1
cannam@95	250 && (p->kind[0] == REDFT00 \|\| p->kind[0] == RODFT00)
cannam@95	251 && p->sz->dims[0].n > 1 /* don't create size-0 sub-plans */
cannam@95	252 && p->sz->dims[0].n % 2 /* odd: 4 divides "logical" DFT */
cannam@95	253 && (p->I != p->O \|\| p->vecsz->rnk == 0
cannam@95	254 \|\| p->vecsz->dims[0].is == p->vecsz->dims[0].os)
cannam@95	255 && (p->kind[0] != RODFT00 \|\| p->I != p->O \|\|
cannam@95	256 p->sz->dims[0].is >= p->sz->dims[0].os) /* laziness */
cannam@95	257 );
cannam@95	258 }
cannam@95	259
cannam@95	260 static int applicable(const solver ego, const problem p, const planner *plnr)
cannam@95	261 {
cannam@95	262 return (!NO_SLOWP(plnr) && applicable0(ego, p));
cannam@95	263 }
cannam@95	264
cannam@95	265 static plan mkplan(const solver ego_, const problem p_, planner plnr)
cannam@95	266 {
cannam@95	267 P *pln;
cannam@95	268 const problem_rdft *p;
cannam@95	269 plan clde, cldo;
cannam@95	270 R *buf;
cannam@95	271 INT n, n0;
cannam@95	272 opcnt ops;
cannam@95	273 int inplace_odd;
cannam@95	274
cannam@95	275 static const plan_adt padt = {
cannam@95	276 X(rdft_solve), awake, print, destroy
cannam@95	277 };
cannam@95	278
cannam@95	279 if (!applicable(ego_, p_, plnr))
cannam@95	280 return (plan *)0;
cannam@95	281
cannam@95	282 p = (const problem_rdft *) p_;
cannam@95	283
cannam@95	284 n = (n0 = p->sz->dims[0].n) + (p->kind[0] == REDFT00 ? (INT)-1 : (INT)1);
cannam@95	285 A(n > 0 && n % 2 == 0);
cannam@95	286 buf = (R ) MALLOC(sizeof(R) (n/2), BUFFERS);
cannam@95	287
cannam@95	288 inplace_odd = p->kind[0]==RODFT00 && p->I == p->O;
cannam@95	289 clde = X(mkplan_d)(plnr, X(mkproblem_rdft_1_d)(
cannam@95	290 X(mktensor_1d)(n0-n/2, 2*p->sz->dims[0].is,
cannam@95	291 inplace_odd ? p->sz->dims[0].is
cannam@95	292 : p->sz->dims[0].os),
cannam@95	293 X(mktensor_0d)(),
cannam@95	294 TAINT(p->I
cannam@95	295 + p->sz->dims[0].is * (p->kind[0]==RODFT00),
cannam@95	296 p->vecsz->rnk ? p->vecsz->dims[0].is : 0),
cannam@95	297 TAINT(p->O
cannam@95	298 + p->sz->dims[0].is * inplace_odd,
cannam@95	299 p->vecsz->rnk ? p->vecsz->dims[0].os : 0),
cannam@95	300 p->kind[0]));
cannam@95	301 if (!clde) {
cannam@95	302 X(ifree)(buf);
cannam@95	303 return (plan *)0;
cannam@95	304 }
cannam@95	305
cannam@95	306 cldo = X(mkplan_d)(plnr, X(mkproblem_rdft_1_d)(
cannam@95	307 X(mktensor_1d)(n/2, 1, 1),
cannam@95	308 X(mktensor_0d)(),
cannam@95	309 buf, buf, R2HC));
cannam@95	310 X(ifree)(buf);
cannam@95	311 if (!cldo)
cannam@95	312 return (plan *)0;
cannam@95	313
cannam@95	314 pln = MKPLAN_RDFT(P, &padt, p->kind[0] == REDFT00 ? apply_e : apply_o);
cannam@95	315
cannam@95	316 pln->n = n;
cannam@95	317 pln->is = p->sz->dims[0].is;
cannam@95	318 pln->os = p->sz->dims[0].os;
cannam@95	319 pln->clde = clde;
cannam@95	320 pln->cldo = cldo;
cannam@95	321 pln->td = 0;
cannam@95	322
cannam@95	323 X(tensor_tornk1)(p->vecsz, &pln->vl, &pln->ivs, &pln->ovs);
cannam@95	324
cannam@95	325 X(ops_zero)(&ops);
cannam@95	326 ops.other = n/2;
cannam@95	327 ops.add = (p->kind[0]==REDFT00 ? (INT)2 : (INT)0) +
cannam@95	328 (n/2-1)/2 * 6 + ((n/2)%2==0) * 2;
cannam@95	329 ops.mul = 1 + (n/2-1)/2 * 6 + ((n/2)%2==0) * 2;
cannam@95	330
cannam@95	331 /* tweak ops.other so that r2hc-pad is used for small sizes, which
cannam@95	332 seems to be a lot faster on my machine: */
cannam@95	333 ops.other += 256;
cannam@95	334
cannam@95	335 X(ops_zero)(&pln->super.super.ops);
cannam@95	336 X(ops_madd2)(pln->vl, &ops, &pln->super.super.ops);
cannam@95	337 X(ops_madd2)(pln->vl, &clde->ops, &pln->super.super.ops);
cannam@95	338 X(ops_madd2)(pln->vl, &cldo->ops, &pln->super.super.ops);
cannam@95	339
cannam@95	340 return &(pln->super.super);
cannam@95	341 }
cannam@95	342
cannam@95	343 /* constructor */
cannam@95	344 static solver *mksolver(void)
cannam@95	345 {
cannam@95	346 static const solver_adt sadt = { PROBLEM_RDFT, mkplan, 0 };
cannam@95	347 S *slv = MKSOLVER(S, &sadt);
cannam@95	348 return &(slv->super);
cannam@95	349 }
cannam@95	350
cannam@95	351 void X(reodft00e_splitradix_register)(planner *p)
cannam@95	352 {
cannam@95	353 REGISTER_SOLVER(p, mksolver());
cannam@95	354 }

Mercurial > hg > sv-dependency-builds

annotate src/fftw-3.3.3/reodft/reodft00e-splitradix.c @ 148:b4bfdf10c4b3