/src/fftw3/dft/rader.c

Source
/*
 * Copyright (c) 2003, 2007-14 Matteo Frigo
 * Copyright (c) 2003, 2007-14 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., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
 *
 */

#include "dft/dft.h"

/*
 * Compute transforms of prime sizes using Rader's trick: turn them
 * into convolutions of size n - 1, which you then perform via a pair
 * of FFTs.
 */

typedef struct {
     solver super;
} S;

typedef struct {
     plan_dft super;

     plan *cld1, *cld2;
     R *omega;
     INT n, g, ginv;
     INT is, os;
     plan *cld_omega;
} P;

static rader_tl *omegas = 0;

static R *mkomega(enum wakefulness wakefulness, plan *p_, INT n, INT ginv)
{
     plan_dft *p = (plan_dft *) p_;
     R *omega;
     INT i, gpower;
     trigreal scale;
     triggen *t;

     if ((omega = X(rader_tl_find)(n, n, ginv, omegas)))
    return omega;

     omega = (R *)MALLOC(sizeof(R) * (n - 1) * 2, TWIDDLES);

     scale = n - 1.0; /* normalization for convolution */

     t = X(mktriggen)(wakefulness, n);
     for (i = 0, gpower = 1; i < n-1; ++i, gpower = MULMOD(gpower, ginv, n)) {
    trigreal w[2];
    t->cexpl(t, gpower, w);
    omega[2*i] = w[0] / scale;
    omega[2*i+1] = FFT_SIGN * w[1] / scale;
     }
     X(triggen_destroy)(t);
     A(gpower == 1);

     p->apply(p_, omega, omega + 1, omega, omega + 1);

     X(rader_tl_insert)(n, n, ginv, omega, &omegas);
     return omega;
}

static void free_omega(R *omega)
{
     X(rader_tl_delete)(omega, &omegas);
}


/***************************************************************************/

/* Below, we extensively use the identity that fft(x*)* = ifft(x) in
   order to share data between forward and backward transforms and to
   obviate the necessity of having separate forward and backward
   plans.  (Although we often compute separate plans these days anyway
   due to the differing strides, etcetera.)

   Of course, since the new FFTW gives us separate pointers to
   the real and imaginary parts, we could have instead used the
   fft(r,i) = ifft(i,r) form of this identity, but it was easier to
   reuse the code from our old version. */

static void apply(const plan *ego_, R *ri, R *ii, R *ro, R *io)
{
     const P *ego = (const P *) ego_;
     INT is, os;
     INT k, gpower, g, r;
     R *buf;
     R r0 = ri[0], i0 = ii[0];

     r = ego->n; is = ego->is; os = ego->os; g = ego->g; 
     buf = (R *) MALLOC(sizeof(R) * (r - 1) * 2, BUFFERS);

     /* First, permute the input, storing in buf: */
     for (gpower = 1, k = 0; k < r - 1; ++k, gpower = MULMOD(gpower, g, r)) {
    R rA, iA;
    rA = ri[gpower * is];
    iA = ii[gpower * is];
    buf[2*k] = rA; buf[2*k + 1] = iA;
     }
     /* gpower == g^(r-1) mod r == 1 */;


     /* compute DFT of buf, storing in output (except DC): */
     {
      plan_dft *cld = (plan_dft *) ego->cld1;
      cld->apply(ego->cld1, buf, buf+1, ro+os, io+os);
     }

     /* set output DC component: */
     {
    ro[0] = r0 + ro[os];
    io[0] = i0 + io[os];
     }

     /* now, multiply by omega: */
     {
    const R *omega = ego->omega;
    for (k = 0; k < r - 1; ++k) {
         E rB, iB, rW, iW;
         rW = omega[2*k];
         iW = omega[2*k+1];
         rB = ro[(k+1)*os];
         iB = io[(k+1)*os];
         ro[(k+1)*os] = rW * rB - iW * iB;
         io[(k+1)*os] = -(rW * iB + iW * rB);
    }
     }
     
     /* this will add input[0] to all of the outputs after the ifft */
     ro[os] += r0;
     io[os] -= i0;

     /* inverse FFT: */
     {
      plan_dft *cld = (plan_dft *) ego->cld2;
      cld->apply(ego->cld2, ro+os, io+os, buf, buf+1);
     }
     
     /* finally, do inverse permutation to unshuffle the output: */
     {
    INT ginv = ego->ginv;
    gpower = 1;
    for (k = 0; k < r - 1; ++k, gpower = MULMOD(gpower, ginv, r)) {
         ro[gpower * os] = buf[2*k];
         io[gpower * os] = -buf[2*k+1];
    }
    A(gpower == 1);
     }


     X(ifree)(buf);
}

/***************************************************************************/

static void awake(plan *ego_, enum wakefulness wakefulness)
{
     P *ego = (P *) ego_;

     X(plan_awake)(ego->cld1, wakefulness);
     X(plan_awake)(ego->cld2, wakefulness);
     X(plan_awake)(ego->cld_omega, wakefulness);

     switch (wakefulness) {
   case SLEEPY:
        free_omega(ego->omega);
        ego->omega = 0;
        break;
   default:
        ego->g = X(find_generator)(ego->n);
        ego->ginv = X(power_mod)(ego->g, ego->n - 2, ego->n);
        A(MULMOD(ego->g, ego->ginv, ego->n) == 1);

        ego->omega = mkomega(wakefulness,
           ego->cld_omega, ego->n, ego->ginv);
        break;
     }
}

static void destroy(plan *ego_)
{
     P *ego = (P *) ego_;
     X(plan_destroy_internal)(ego->cld_omega);
     X(plan_destroy_internal)(ego->cld2);
     X(plan_destroy_internal)(ego->cld1);
}

static void print(const plan *ego_, printer *p)
{
     const P *ego = (const P *)ego_;
     p->print(p, "(dft-rader-%D%ois=%oos=%(%p%)",
              ego->n, ego->is, ego->os, ego->cld1);
     if (ego->cld2 != ego->cld1)
          p->print(p, "%(%p%)", ego->cld2);
     if (ego->cld_omega != ego->cld1 && ego->cld_omega != ego->cld2)
          p->print(p, "%(%p%)", ego->cld_omega);
     p->putchr(p, ')');
}

static int applicable(const solver *ego_, const problem *p_,
          const planner *plnr)
{
     const problem_dft *p = (const problem_dft *) p_;
     UNUSED(ego_);
     return (1
       && p->sz->rnk == 1
       && p->vecsz->rnk == 0
       && CIMPLIES(NO_SLOWP(plnr), p->sz->dims[0].n > RADER_MAX_SLOW)
       && X(is_prime)(p->sz->dims[0].n)

       /* proclaim the solver SLOW if p-1 is not easily factorizable.
    Bluestein should take care of this case. */
       && CIMPLIES(NO_SLOWP(plnr), X(factors_into_small_primes)(p->sz->dims[0].n - 1))
    );
}

static int mkP(P *pln, INT n, INT is, INT os, R *ro, R *io,
         planner *plnr)
{
     plan *cld1 = (plan *) 0;
     plan *cld2 = (plan *) 0;
     plan *cld_omega = (plan *) 0;
     R *buf = (R *) 0;

     /* initial allocation for the purpose of planning */
     buf = (R *) MALLOC(sizeof(R) * (n - 1) * 2, BUFFERS);

     cld1 = X(mkplan_f_d)(plnr, 
        X(mkproblem_dft_d)(X(mktensor_1d)(n - 1, 2, os),
               X(mktensor_1d)(1, 0, 0),
               buf, buf + 1, ro + os, io + os),
        NO_SLOW, 0, 0);
     if (!cld1) goto nada;

     cld2 = X(mkplan_f_d)(plnr, 
        X(mkproblem_dft_d)(X(mktensor_1d)(n - 1, os, 2),
               X(mktensor_1d)(1, 0, 0),
               ro + os, io + os, buf, buf + 1),
        NO_SLOW, 0, 0);

     if (!cld2) goto nada;

     /* plan for omega array */
     cld_omega = X(mkplan_f_d)(plnr, 
             X(mkproblem_dft_d)(X(mktensor_1d)(n - 1, 2, 2),
              X(mktensor_1d)(1, 0, 0),
              buf, buf + 1, buf, buf + 1),
             NO_SLOW, ESTIMATE, 0);
     if (!cld_omega) goto nada;

     /* deallocate buffers; let awake() or apply() allocate them for real */
     X(ifree)(buf);
     buf = 0;

     pln->cld1 = cld1;
     pln->cld2 = cld2;
     pln->cld_omega = cld_omega;
     pln->omega = 0;
     pln->n = n;
     pln->is = is;
     pln->os = os;

     X(ops_add)(&cld1->ops, &cld2->ops, &pln->super.super.ops);
     pln->super.super.ops.other += (n - 1) * (4 * 2 + 6) + 6;
     pln->super.super.ops.add += (n - 1) * 2 + 4;
     pln->super.super.ops.mul += (n - 1) * 4;

     return 1;

 nada:
     X(ifree0)(buf);
     X(plan_destroy_internal)(cld_omega);
     X(plan_destroy_internal)(cld2);
     X(plan_destroy_internal)(cld1);
     return 0;
}

static plan *mkplan(const solver *ego, const problem *p_, planner *plnr)
{
     const problem_dft *p = (const problem_dft *) p_;
     P *pln;
     INT n;
     INT is, os;

     static const plan_adt padt = {
    X(dft_solve), awake, print, destroy
     };

     if (!applicable(ego, p_, plnr))
    return (plan *) 0;

     n = p->sz->dims[0].n;
     is = p->sz->dims[0].is;
     os = p->sz->dims[0].os;

     pln = MKPLAN_DFT(P, &padt, apply);
     if (!mkP(pln, n, is, os, p->ro, p->io, plnr)) {
    X(ifree)(pln);
    return (plan *) 0;
     }
     return &(pln->super.super);
}

static solver *mksolver(void)
{
     static const solver_adt sadt = { PROBLEM_DFT, mkplan, 0 };
     S *slv = MKSOLVER(S, &sadt);
     return &(slv->super);
}

void X(dft_rader_register)(planner *p)
{
     REGISTER_SOLVER(p, mksolver());
}

Coverage Report

Created: 2025-12-14 06:37

Line	Count	Source
1		/*
2		* Copyright (c) 2003, 2007-14 Matteo Frigo
3		* Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
4		*
5		* This program is free software; you can redistribute it and/or modify
6		* it under the terms of the GNU General Public License as published by
7		* the Free Software Foundation; either version 2 of the License, or
8		* (at your option) any later version.
9		*
10		* This program is distributed in the hope that it will be useful,
11		* but WITHOUT ANY WARRANTY; without even the implied warranty of
12		* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13		* GNU General Public License for more details.
14		*
15		* You should have received a copy of the GNU General Public License
16		* along with this program; if not, write to the Free Software
17		* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
18		*
19		*/
20
21		#include "dft/dft.h"
22
23		/*
24		* Compute transforms of prime sizes using Rader's trick: turn them
25		* into convolutions of size n - 1, which you then perform via a pair
26		* of FFTs.
27		*/
28
29		typedef struct {
30		solver super;
31		} S;
32
33		typedef struct {
34		plan_dft super;
35
36		plan cld1, cld2;
37		R *omega;
38		INT n, g, ginv;
39		INT is, os;
40		plan *cld_omega;
41		} P;
42
43		static rader_tl *omegas = 0;
44
45		static R mkomega(enum wakefulness wakefulness, plan p_, INT n, INT ginv)
46	46	{
47	46	plan_dft p = (plan_dft ) p_;
48	46	R *omega;
49	46	INT i, gpower;
50	46	trigreal scale;
51	46	triggen *t;
52
53	46	if ((omega = X(rader_tl_find)(n, n, ginv, omegas)))
54	0	return omega;
55
56	46	omega = (R )MALLOC(sizeof(R) (n - 1) * 2, TWIDDLES);
57
58	46	scale = n - 1.0; /* normalization for convolution */
59
60	46	t = X(mktriggen)(wakefulness, n);
61	3.96k	for (i = 0, gpower = 1; i < n-1; ++i, gpower = MULMOD(gpower, ginv, n)) {
62	3.91k	trigreal w[2];
63	3.91k	t->cexpl(t, gpower, w);
64	3.91k	omega[2*i] = w[0] / scale;
65	3.91k	omega[2i+1] = FFT_SIGN w[1] / scale;
66	3.91k	}
67	46	X(triggen_destroy)(t);
68	46	A(gpower == 1);
69
70	46	p->apply(p_, omega, omega + 1, omega, omega + 1);
71
72	46	X(rader_tl_insert)(n, n, ginv, omega, &omegas);
73	46	return omega;
74	46	}
75
76		static void free_omega(R *omega)
77	46	{
78	46	X(rader_tl_delete)(omega, &omegas);
79	46	}
80
81
82		/***************************************************************************/
83
84		/* Below, we extensively use the identity that fft(x) = ifft(x) in
85		order to share data between forward and backward transforms and to
86		obviate the necessity of having separate forward and backward
87		plans. (Although we often compute separate plans these days anyway
88		due to the differing strides, etcetera.)
89
90		Of course, since the new FFTW gives us separate pointers to
91		the real and imaginary parts, we could have instead used the
92		fft(r,i) = ifft(i,r) form of this identity, but it was easier to
93		reuse the code from our old version. */
94
95		static void apply(const plan ego_, R ri, R ii, R ro, R *io)
96	90	{
97	90	const P ego = (const P ) ego_;
98	90	INT is, os;
99	90	INT k, gpower, g, r;
100	90	R *buf;
101	90	R r0 = ri[0], i0 = ii[0];
102
103	90	r = ego->n; is = ego->is; os = ego->os; g = ego->g;
104	90	buf = (R ) MALLOC(sizeof(R) (r - 1) * 2, BUFFERS);
105
106		/* First, permute the input, storing in buf: */
107	6.21k	for (gpower = 1, k = 0; k < r - 1; ++k, gpower = MULMOD(gpower, g, r)) {
108	6.12k	R rA, iA;
109	6.12k	rA = ri[gpower * is];
110	6.12k	iA = ii[gpower * is];
111	6.12k	buf[2k] = rA; buf[2k + 1] = iA;
112	6.12k	}
113	90	/* gpower == g^(r-1) mod r == 1 */;
114
115
116		/* compute DFT of buf, storing in output (except DC): */
117	90	{
118	90	plan_dft cld = (plan_dft ) ego->cld1;
119	90	cld->apply(ego->cld1, buf, buf+1, ro+os, io+os);
120	90	}
121
122		/* set output DC component: */
123	90	{
124	90	ro[0] = r0 + ro[os];
125	90	io[0] = i0 + io[os];
126	90	}
127
128		/* now, multiply by omega: */
129	90	{
130	90	const R *omega = ego->omega;
131	6.21k	for (k = 0; k < r - 1; ++k) {
132	6.12k	E rB, iB, rW, iW;
133	6.12k	rW = omega[2*k];
134	6.12k	iW = omega[2*k+1];
135	6.12k	rB = ro[(k+1)*os];
136	6.12k	iB = io[(k+1)*os];
137	6.12k	ro[(k+1)os] = rW rB - iW * iB;
138	6.12k	io[(k+1)os] = -(rW iB + iW * rB);
139	6.12k	}
140	90	}
141
142		/* this will add input[0] to all of the outputs after the ifft */
143	90	ro[os] += r0;
144	90	io[os] -= i0;
145
146		/* inverse FFT: */
147	90	{
148	90	plan_dft cld = (plan_dft ) ego->cld2;
149	90	cld->apply(ego->cld2, ro+os, io+os, buf, buf+1);
150	90	}
151
152		/* finally, do inverse permutation to unshuffle the output: */
153	90	{
154	90	INT ginv = ego->ginv;
155	90	gpower = 1;
156	6.21k	for (k = 0; k < r - 1; ++k, gpower = MULMOD(gpower, ginv, r)) {
157	6.12k	ro[gpower * os] = buf[2*k];
158	6.12k	io[gpower * os] = -buf[2*k+1];
159	6.12k	}
160	90	A(gpower == 1);
161	90	}
162
163
164	90	X(ifree)(buf);
165	90	}
166
167		/***************************************************************************/
168
169		static void awake(plan *ego_, enum wakefulness wakefulness)
170	92	{
171	92	P ego = (P ) ego_;
172
173	92	X(plan_awake)(ego->cld1, wakefulness);
174	92	X(plan_awake)(ego->cld2, wakefulness);
175	92	X(plan_awake)(ego->cld_omega, wakefulness);
176
177	92	switch (wakefulness) {
178	46	case SLEEPY:
179	46	free_omega(ego->omega);
180	46	ego->omega = 0;
181	46	break;
182	46	default:
183	46	ego->g = X(find_generator)(ego->n);
184	46	ego->ginv = X(power_mod)(ego->g, ego->n - 2, ego->n);
185	46	A(MULMOD(ego->g, ego->ginv, ego->n) == 1);
186
187	46	ego->omega = mkomega(wakefulness,
188	46	ego->cld_omega, ego->n, ego->ginv);
189	46	break;
190	92	}
191	92	}
192
193		static void destroy(plan *ego_)
194	98	{
195	98	P ego = (P ) ego_;
196	98	X(plan_destroy_internal)(ego->cld_omega);
197	98	X(plan_destroy_internal)(ego->cld2);
198	98	X(plan_destroy_internal)(ego->cld1);
199	98	}
200
201		static void print(const plan ego_, printer p)
202	0	{
203	0	const P ego = (const P )ego_;
204	0	p->print(p, "(dft-rader-%D%ois=%oos=%(%p%)",
205	0	ego->n, ego->is, ego->os, ego->cld1);
206	0	if (ego->cld2 != ego->cld1)
207	0	p->print(p, "%(%p%)", ego->cld2);
208	0	if (ego->cld_omega != ego->cld1 && ego->cld_omega != ego->cld2)
209	0	p->print(p, "%(%p%)", ego->cld_omega);
210	0	p->putchr(p, ')');
211	0	}
212
213		static int applicable(const solver ego_, const problem p_,
214		const planner *plnr)
215	1.15k	{
216	1.15k	const problem_dft p = (const problem_dft ) p_;
217	1.15k	UNUSED(ego_);
218	1.15k	return (1
219	1.15k	&& p->sz->rnk == 1
220	830	&& p->vecsz->rnk == 0
221	323	&& CIMPLIES(NO_SLOWP(plnr), p->sz->dims[0].n > RADER_MAX_SLOW)
222	232	&& X(is_prime)(p->sz->dims[0].n)
223
224		/* proclaim the solver SLOW if p-1 is not easily factorizable.
225		Bluestein should take care of this case. */
226	137	&& CIMPLIES(NO_SLOWP(plnr), X(factors_into_small_primes)(p->sz->dims[0].n - 1))
227	1.15k	);
228	1.15k	}
229
230		static int mkP(P pln, INT n, INT is, INT os, R ro, R *io,
231		planner *plnr)
232	98	{
233	98	plan cld1 = (plan ) 0;
234	98	plan cld2 = (plan ) 0;
235	98	plan cld_omega = (plan ) 0;
236	98	R buf = (R ) 0;
237
238		/* initial allocation for the purpose of planning */
239	98	buf = (R ) MALLOC(sizeof(R) (n - 1) * 2, BUFFERS);
240
241	98	cld1 = X(mkplan_f_d)(plnr,
242	98	X(mkproblem_dft_d)(X(mktensor_1d)(n - 1, 2, os),
243	98	X(mktensor_1d)(1, 0, 0),
244	98	buf, buf + 1, ro + os, io + os),
245	98	NO_SLOW, 0, 0);
246	98	if (!cld1) goto nada;
247
248	98	cld2 = X(mkplan_f_d)(plnr,
249	98	X(mkproblem_dft_d)(X(mktensor_1d)(n - 1, os, 2),
250	98	X(mktensor_1d)(1, 0, 0),
251	98	ro + os, io + os, buf, buf + 1),
252	98	NO_SLOW, 0, 0);
253
254	98	if (!cld2) goto nada;
255
256		/* plan for omega array */
257	98	cld_omega = X(mkplan_f_d)(plnr,
258	98	X(mkproblem_dft_d)(X(mktensor_1d)(n - 1, 2, 2),
259	98	X(mktensor_1d)(1, 0, 0),
260	98	buf, buf + 1, buf, buf + 1),
261	98	NO_SLOW, ESTIMATE, 0);
262	98	if (!cld_omega) goto nada;
263
264		/* deallocate buffers; let awake() or apply() allocate them for real */
265	98	X(ifree)(buf);
266	98	buf = 0;
267
268	98	pln->cld1 = cld1;
269	98	pln->cld2 = cld2;
270	98	pln->cld_omega = cld_omega;
271	98	pln->omega = 0;
272	98	pln->n = n;
273	98	pln->is = is;
274	98	pln->os = os;
275
276	98	X(ops_add)(&cld1->ops, &cld2->ops, &pln->super.super.ops);
277	98	pln->super.super.ops.other += (n - 1) * (4 * 2 + 6) + 6;
278	98	pln->super.super.ops.add += (n - 1) * 2 + 4;
279	98	pln->super.super.ops.mul += (n - 1) * 4;
280
281	98	return 1;
282
283	0	nada:
284	0	X(ifree0)(buf);
285	0	X(plan_destroy_internal)(cld_omega);
286	0	X(plan_destroy_internal)(cld2);
287	0	X(plan_destroy_internal)(cld1);
288	0	return 0;
289	98	}
290
291		static plan mkplan(const solver ego, const problem p_, planner plnr)
292	1.15k	{
293	1.15k	const problem_dft p = (const problem_dft ) p_;
294	1.15k	P *pln;
295	1.15k	INT n;
296	1.15k	INT is, os;
297
298	1.15k	static const plan_adt padt = {
299	1.15k	X(dft_solve), awake, print, destroy
300	1.15k	};
301
302	1.15k	if (!applicable(ego, p_, plnr))
303	1.05k	return (plan *) 0;
304
305	98	n = p->sz->dims[0].n;
306	98	is = p->sz->dims[0].is;
307	98	os = p->sz->dims[0].os;
308
309	98	pln = MKPLAN_DFT(P, &padt, apply);
310	98	if (!mkP(pln, n, is, os, p->ro, p->io, plnr)) {
311	0	X(ifree)(pln);
312	0	return (plan *) 0;
313	0	}
314	98	return &(pln->super.super);
315	98	}
316
317		static solver *mksolver(void)
318	1	{
319	1	static const solver_adt sadt = { PROBLEM_DFT, mkplan, 0 };
320	1	S *slv = MKSOLVER(S, &sadt);
321	1	return &(slv->super);
322	1	}
323
324		void X(dft_rader_register)(planner *p)
325	1	{
326	1	REGISTER_SOLVER(p, mksolver());
327	1	}