/proc/self/cwd/libfaad/cfft.c

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Source

/*

** FAAD2 - Freeware Advanced Audio (AAC) Decoder including SBR decoding

** Copyright (C) 2003-2005 M. Bakker, Nero AG, http://www.nero.com

**

** 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.

**

** Any non-GPL usage of this software or parts of this software is strictly

** forbidden.

**

** The "appropriate copyright message" mentioned in section 2c of the GPLv2

** must read: "Code from FAAD2 is copyright (c) Nero AG, www.nero.com"

**

** Commercial non-GPL licensing of this software is possible.

** For more info contact Nero AG through Mpeg4AAClicense@nero.com.

**

** $Id: cfft.c,v 1.35 2007/11/01 12:33:29 menno Exp $

**/

/*

 * Algorithmically based on Fortran-77 FFTPACK

 * by Paul N. Swarztrauber(Version 4, 1985).

 * Does even sized fft only

*/

/* isign is +1 for backward and -1 for forward transforms */

#include "common.h"

#include "structs.h"

#include <stdlib.h>

#include "cfft.h"

#include "cfft_tab.h"

/* static function declarations */

static void passf2pos(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                      complex_t *ch, const complex_t *wa);

static void passf2neg(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                      complex_t *ch, const complex_t *wa);

static void passf3(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                   complex_t *ch, const complex_t *wa1, const complex_t *wa2, const int8_t isign);

static void passf4pos(const uint16_t ido, const uint16_t l1, const complex_t *cc, complex_t *ch,

                      const complex_t *wa1, const complex_t *wa2, const complex_t *wa3);

static void passf4neg(const uint16_t ido, const uint16_t l1, const complex_t *cc, complex_t *ch,

                      const complex_t *wa1, const complex_t *wa2, const complex_t *wa3);

static void passf5(const uint16_t ido, const uint16_t l1, const complex_t *cc, complex_t *ch,

                   const complex_t *wa1, const complex_t *wa2, const complex_t *wa3,

                   const complex_t *wa4, const int8_t isign);

static void cffti1(uint16_t n, complex_t *wa, uint16_t *ifac);

/*----------------------------------------------------------------------

   passf2, passf3, passf4, passf5. Complex FFT passes fwd and bwd.

  ----------------------------------------------------------------------*/

static void passf2pos(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                      complex_t *ch, const complex_t *wa)

610k

610k

    uint16_t i, k, ah, ac;

610k

    if (ido == 1)

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

        // TODO: remove this code once fuzzer proves it is totally unreahable

        // For supported frame lengths that have odd number of factor 2 it is

        // never the last factor; consequently `ido` should never be 1.

        __builtin_trap();

/*

#endif

        for (k = 0; k < l1; k++)

            ah = 2*k;

            ac = 4*k;

            RE(ch[ah])    = RE(cc[ac]) + RE(cc[ac+1]);

            RE(ch[ah+l1]) = RE(cc[ac]) - RE(cc[ac+1]);

            IM(ch[ah])    = IM(cc[ac]) + IM(cc[ac+1]);

            IM(ch[ah+l1]) = IM(cc[ac]) - IM(cc[ac+1]);

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

*/

#endif

610k

    } else {

1.22M

        for (k = 0; k < l1; k++)

610k

610k

            ah = k*ido;

610k

            ac = 2*k*ido;

155M

            for (i = 0; i < ido; i++)

154M

154M

                complex_t t2;

154M

                RE(ch[ah+i]) = RE(cc[ac+i]) + RE(cc[ac+i+ido]);

154M

                RE(t2)       = RE(cc[ac+i]) - RE(cc[ac+i+ido]);

154M

                IM(ch[ah+i]) = IM(cc[ac+i]) + IM(cc[ac+i+ido]);

154M

                IM(t2)       = IM(cc[ac+i]) - IM(cc[ac+i+ido]);

154M

#if 1

154M

                ComplexMult(&IM(ch[ah+i+l1*ido]), &RE(ch[ah+i+l1*ido]),

154M

                    IM(t2), RE(t2), RE(wa[i]), IM(wa[i]));

#else

                ComplexMult(&RE(ch[ah+i+l1*ido]), &IM(ch[ah+i+l1*ido]),

                    RE(t2), IM(t2), RE(wa[i]), IM(wa[i]));

#endif

154M

610k

610k

610k

static void passf2neg(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                      complex_t *ch, const complex_t *wa)

13.6k

13.6k

    uint16_t i, k, ah, ac;

13.6k

    if (ido == 1)

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

        // TODO: remove this code once fuzzer proves it is totally unreahable

        // For supported frame lengths that have odd number of factor 2 it is

        // never the last factor; consequently `ido` should never be 1.

        __builtin_trap();

/*

#endif

        for (k = 0; k < l1; k++)

            ah = 2*k;

            ac = 4*k;

            RE(ch[ah])    = RE(cc[ac]) + RE(cc[ac+1]);

            RE(ch[ah+l1]) = RE(cc[ac]) - RE(cc[ac+1]);

            IM(ch[ah])    = IM(cc[ac]) + IM(cc[ac+1]);

            IM(ch[ah+l1]) = IM(cc[ac]) - IM(cc[ac+1]);

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

*/

#endif

13.6k

    } else {

27.2k

        for (k = 0; k < l1; k++)

13.6k

13.6k

            ah = k*ido;

13.6k

            ac = 2*k*ido;

3.39M

            for (i = 0; i < ido; i++)

3.37M

3.37M

                complex_t t2;

3.37M

                RE(ch[ah+i]) = RE(cc[ac+i]) + RE(cc[ac+i+ido]);

3.37M

                RE(t2)       = RE(cc[ac+i]) - RE(cc[ac+i+ido]);

3.37M

                IM(ch[ah+i]) = IM(cc[ac+i]) + IM(cc[ac+i+ido]);

3.37M

                IM(t2)       = IM(cc[ac+i]) - IM(cc[ac+i+ido]);

3.37M

#if 1

3.37M

                ComplexMult(&RE(ch[ah+i+l1*ido]), &IM(ch[ah+i+l1*ido]),

3.37M

                    RE(t2), IM(t2), RE(wa[i]), IM(wa[i]));

#else

                ComplexMult(&IM(ch[ah+i+l1*ido]), &RE(ch[ah+i+l1*ido]),

                    IM(t2), RE(t2), RE(wa[i]), IM(wa[i]));

#endif

3.37M

13.6k

13.6k

13.6k

static void passf3(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                   complex_t *ch, const complex_t *wa1, const complex_t *wa2,

                   const int8_t isign)

219k

219k

    static real_t taur = FRAC_CONST(-0.5);

219k

    static real_t taui = FRAC_CONST(0.866025403784439);

219k

    uint16_t i, k, ac, ah;

219k

    complex_t c2, c3, d2, d3, t2;

219k

    if (ido == 1)

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

        // TODO: remove this code once fuzzer proves it is totally unreahable

        // 3 is never the the biggest factor for supported frame lengths;

        // consequently `ido` should never be 1.

        __builtin_trap();

/*

#endif

        if (isign == 1)

            for (k = 0; k < l1; k++)

                ac = 3*k+1;

                ah = k;

                RE(t2) = RE(cc[ac]) + RE(cc[ac+1]);

                IM(t2) = IM(cc[ac]) + IM(cc[ac+1]);

                RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),taur);

                IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),taur);

                RE(ch[ah]) = RE(cc[ac-1]) + RE(t2);

                IM(ch[ah]) = IM(cc[ac-1]) + IM(t2);

                RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+1])), taui);

                IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+1])), taui);

                RE(ch[ah+l1]) = RE(c2) - IM(c3);

                IM(ch[ah+l1]) = IM(c2) + RE(c3);

                RE(ch[ah+2*l1]) = RE(c2) + IM(c3);

                IM(ch[ah+2*l1]) = IM(c2) - RE(c3);

        } else {

            for (k = 0; k < l1; k++)

                ac = 3*k+1;

                ah = k;

                RE(t2) = RE(cc[ac]) + RE(cc[ac+1]);

                IM(t2) = IM(cc[ac]) + IM(cc[ac+1]);

                RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),taur);

                IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),taur);

                RE(ch[ah]) = RE(cc[ac-1]) + RE(t2);

                IM(ch[ah]) = IM(cc[ac-1]) + IM(t2);

                RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+1])), taui);

                IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+1])), taui);

                RE(ch[ah+l1]) = RE(c2) + IM(c3);

                IM(ch[ah+l1]) = IM(c2) - RE(c3);

                RE(ch[ah+2*l1]) = RE(c2) - IM(c3);

                IM(ch[ah+2*l1]) = IM(c2) + RE(c3);

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

*/

#endif

219k

    } else {

219k

        if (isign == 1)

212k

524k

            for (k = 0; k < l1; k++)

311k

18.6M

                for (i = 0; i < ido; i++)

18.3M

18.3M

                    ac = i + (3*k+1)*ido;

18.3M

                    ah = i + k * ido;

18.3M

                    RE(t2) = RE(cc[ac]) + RE(cc[ac+ido]);

18.3M

                    RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),taur);

18.3M

                    IM(t2) = IM(cc[ac]) + IM(cc[ac+ido]);

18.3M

                    IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),taur);

18.3M

                    RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2);

18.3M

                    IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2);

18.3M

                    RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+ido])), taui);

18.3M

                    IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+ido])), taui);

18.3M

                    RE(d2) = RE(c2) - IM(c3);

18.3M

                    IM(d3) = IM(c2) - RE(c3);

18.3M

                    RE(d3) = RE(c2) + IM(c3);

18.3M

                    IM(d2) = IM(c2) + RE(c3);

18.3M

#if 1

18.3M

                    ComplexMult(&IM(ch[ah+l1*ido]), &RE(ch[ah+l1*ido]),

18.3M

                        IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));

18.3M

                    ComplexMult(&IM(ch[ah+2*l1*ido]), &RE(ch[ah+2*l1*ido]),

18.3M

                        IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));

#else

                    ComplexMult(&RE(ch[ah+l1*ido]), &IM(ch[ah+l1*ido]),

                        RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));

                    ComplexMult(&RE(ch[ah+2*l1*ido]), &IM(ch[ah+2*l1*ido]),

                        RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));

#endif

18.3M

311k

212k

        } else {

21.8k

            for (k = 0; k < l1; k++)

14.5k

1.17M

                for (i = 0; i < ido; i++)

1.16M

1.16M

                    ac = i + (3*k+1)*ido;

1.16M

                    ah = i + k * ido;

1.16M

                    RE(t2) = RE(cc[ac]) + RE(cc[ac+ido]);

1.16M

                    RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),taur);

1.16M

                    IM(t2) = IM(cc[ac]) + IM(cc[ac+ido]);

1.16M

                    IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),taur);

1.16M

                    RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2);

1.16M

                    IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2);

1.16M

                    RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+ido])), taui);

1.16M

                    IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+ido])), taui);

1.16M

                    RE(d2) = RE(c2) + IM(c3);

1.16M

                    IM(d3) = IM(c2) + RE(c3);

1.16M

                    RE(d3) = RE(c2) - IM(c3);

1.16M

                    IM(d2) = IM(c2) - RE(c3);

1.16M

#if 1

1.16M

                    ComplexMult(&RE(ch[ah+l1*ido]), &IM(ch[ah+l1*ido]),

1.16M

                        RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));

1.16M

                    ComplexMult(&RE(ch[ah+2*l1*ido]), &IM(ch[ah+2*l1*ido]),

1.16M

                        RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));

#else

                    ComplexMult(&IM(ch[ah+l1*ido]), &RE(ch[ah+l1*ido]),

                        IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));

                    ComplexMult(&IM(ch[ah+2*l1*ido]), &RE(ch[ah+2*l1*ido]),

                        IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));

#endif

1.16M

14.5k

7.32k

219k

219k

cfft.c:passf3

Line	Count	Source
184	93.4k	{
185	93.4k	static real_t taur = FRAC_CONST(-0.5);
186	93.4k	static real_t taui = FRAC_CONST(0.866025403784439);
187	93.4k	uint16_t i, k, ac, ah;
188	93.4k	complex_t c2, c3, d2, d3, t2;
189
190	93.4k	if (ido == 1)
191	0	{
192	0	#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
193		// TODO: remove this code once fuzzer proves it is totally unreahable
194		// 3 is never the the biggest factor for supported frame lengths;
195		// consequently `ido` should never be 1.
196	0	__builtin_trap();
197		/*
198		#endif
199		if (isign == 1)
200		{
201		for (k = 0; k < l1; k++)
202		{
203		ac = 3*k+1;
204		ah = k;
205
206		RE(t2) = RE(cc[ac]) + RE(cc[ac+1]);
207		IM(t2) = IM(cc[ac]) + IM(cc[ac+1]);
208		RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),taur);
209		IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),taur);
210
211		RE(ch[ah]) = RE(cc[ac-1]) + RE(t2);
212		IM(ch[ah]) = IM(cc[ac-1]) + IM(t2);
213
214		RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+1])), taui);
215		IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+1])), taui);
216
217		RE(ch[ah+l1]) = RE(c2) - IM(c3);
218		IM(ch[ah+l1]) = IM(c2) + RE(c3);
219		RE(ch[ah+2*l1]) = RE(c2) + IM(c3);
220		IM(ch[ah+2*l1]) = IM(c2) - RE(c3);
221		}
222		} else {
223		for (k = 0; k < l1; k++)
224		{
225		ac = 3*k+1;
226		ah = k;
227
228		RE(t2) = RE(cc[ac]) + RE(cc[ac+1]);
229		IM(t2) = IM(cc[ac]) + IM(cc[ac+1]);
230		RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),taur);
231		IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),taur);
232
233		RE(ch[ah]) = RE(cc[ac-1]) + RE(t2);
234		IM(ch[ah]) = IM(cc[ac-1]) + IM(t2);
235
236		RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+1])), taui);
237		IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+1])), taui);
238
239		RE(ch[ah+l1]) = RE(c2) + IM(c3);
240		IM(ch[ah+l1]) = IM(c2) - RE(c3);
241		RE(ch[ah+2*l1]) = RE(c2) - IM(c3);
242		IM(ch[ah+2*l1]) = IM(c2) + RE(c3);
243		}
244		}
245		#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
246		*/
247	0	#endif
248	93.4k	} else {
249	93.4k	if (isign == 1)
250	90.1k	{
251	221k	for (k = 0; k < l1; k++)
252	131k	{
253	7.76M	for (i = 0; i < ido; i++)
254	7.63M	{
255	7.63M	ac = i + (3k+1)ido;
256	7.63M	ah = i + k * ido;
257
258	7.63M	RE(t2) = RE(cc[ac]) + RE(cc[ac+ido]);
259	7.63M	RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),taur);
260	7.63M	IM(t2) = IM(cc[ac]) + IM(cc[ac+ido]);
261	7.63M	IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),taur);
262
263	7.63M	RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2);
264	7.63M	IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2);
265
266	7.63M	RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+ido])), taui);
267	7.63M	IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+ido])), taui);
268
269	7.63M	RE(d2) = RE(c2) - IM(c3);
270	7.63M	IM(d3) = IM(c2) - RE(c3);
271	7.63M	RE(d3) = RE(c2) + IM(c3);
272	7.63M	IM(d2) = IM(c2) + RE(c3);
273
274	7.63M	#if 1
275	7.63M	ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
276	7.63M	IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
277	7.63M	ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
278	7.63M	IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
279		#else
280		ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
281		RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
282		ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
283		RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
284		#endif
285	7.63M	}
286	131k	}
287	90.1k	} else {
288	9.68k	for (k = 0; k < l1; k++)
289	6.45k	{
290	522k	for (i = 0; i < ido; i++)
291	516k	{
292	516k	ac = i + (3k+1)ido;
293	516k	ah = i + k * ido;
294
295	516k	RE(t2) = RE(cc[ac]) + RE(cc[ac+ido]);
296	516k	RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),taur);
297	516k	IM(t2) = IM(cc[ac]) + IM(cc[ac+ido]);
298	516k	IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),taur);
299
300	516k	RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2);
301	516k	IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2);
302
303	516k	RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+ido])), taui);
304	516k	IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+ido])), taui);
305
306	516k	RE(d2) = RE(c2) + IM(c3);
307	516k	IM(d3) = IM(c2) + RE(c3);
308	516k	RE(d3) = RE(c2) - IM(c3);
309	516k	IM(d2) = IM(c2) - RE(c3);
310
311	516k	#if 1
312	516k	ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
313	516k	RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
314	516k	ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
315	516k	RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
316		#else
317		ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
318		IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
319		ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
320		IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
321		#endif
322	516k	}
323	6.45k	}
324	3.23k	}
325	93.4k	}
326	93.4k	}

cfft.c:passf3

Line	Count	Source
184	126k	{
185	126k	static real_t taur = FRAC_CONST(-0.5);
186	126k	static real_t taui = FRAC_CONST(0.866025403784439);
187	126k	uint16_t i, k, ac, ah;
188	126k	complex_t c2, c3, d2, d3, t2;
189
190	126k	if (ido == 1)
191	0	{
192	0	#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
193		// TODO: remove this code once fuzzer proves it is totally unreahable
194		// 3 is never the the biggest factor for supported frame lengths;
195		// consequently `ido` should never be 1.
196	0	__builtin_trap();
197		/*
198		#endif
199		if (isign == 1)
200		{
201		for (k = 0; k < l1; k++)
202		{
203		ac = 3*k+1;
204		ah = k;
205
206		RE(t2) = RE(cc[ac]) + RE(cc[ac+1]);
207		IM(t2) = IM(cc[ac]) + IM(cc[ac+1]);
208		RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),taur);
209		IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),taur);
210
211		RE(ch[ah]) = RE(cc[ac-1]) + RE(t2);
212		IM(ch[ah]) = IM(cc[ac-1]) + IM(t2);
213
214		RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+1])), taui);
215		IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+1])), taui);
216
217		RE(ch[ah+l1]) = RE(c2) - IM(c3);
218		IM(ch[ah+l1]) = IM(c2) + RE(c3);
219		RE(ch[ah+2*l1]) = RE(c2) + IM(c3);
220		IM(ch[ah+2*l1]) = IM(c2) - RE(c3);
221		}
222		} else {
223		for (k = 0; k < l1; k++)
224		{
225		ac = 3*k+1;
226		ah = k;
227
228		RE(t2) = RE(cc[ac]) + RE(cc[ac+1]);
229		IM(t2) = IM(cc[ac]) + IM(cc[ac+1]);
230		RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),taur);
231		IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),taur);
232
233		RE(ch[ah]) = RE(cc[ac-1]) + RE(t2);
234		IM(ch[ah]) = IM(cc[ac-1]) + IM(t2);
235
236		RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+1])), taui);
237		IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+1])), taui);
238
239		RE(ch[ah+l1]) = RE(c2) + IM(c3);
240		IM(ch[ah+l1]) = IM(c2) - RE(c3);
241		RE(ch[ah+2*l1]) = RE(c2) - IM(c3);
242		IM(ch[ah+2*l1]) = IM(c2) + RE(c3);
243		}
244		}
245		#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
246		*/
247	0	#endif
248	126k	} else {
249	126k	if (isign == 1)
250	122k	{
251	302k	for (k = 0; k < l1; k++)
252	180k	{
253	10.8M	for (i = 0; i < ido; i++)
254	10.6M	{
255	10.6M	ac = i + (3k+1)ido;
256	10.6M	ah = i + k * ido;
257
258	10.6M	RE(t2) = RE(cc[ac]) + RE(cc[ac+ido]);
259	10.6M	RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),taur);
260	10.6M	IM(t2) = IM(cc[ac]) + IM(cc[ac+ido]);
261	10.6M	IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),taur);
262
263	10.6M	RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2);
264	10.6M	IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2);
265
266	10.6M	RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+ido])), taui);
267	10.6M	IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+ido])), taui);
268
269	10.6M	RE(d2) = RE(c2) - IM(c3);
270	10.6M	IM(d3) = IM(c2) - RE(c3);
271	10.6M	RE(d3) = RE(c2) + IM(c3);
272	10.6M	IM(d2) = IM(c2) + RE(c3);
273
274	10.6M	#if 1
275	10.6M	ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
276	10.6M	IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
277	10.6M	ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
278	10.6M	IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
279		#else
280		ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
281		RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
282		ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
283		RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
284		#endif
285	10.6M	}
286	180k	}
287	122k	} else {
288	12.1k	for (k = 0; k < l1; k++)
289	8.10k	{
290	656k	for (i = 0; i < ido; i++)
291	648k	{
292	648k	ac = i + (3k+1)ido;
293	648k	ah = i + k * ido;
294
295	648k	RE(t2) = RE(cc[ac]) + RE(cc[ac+ido]);
296	648k	RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),taur);
297	648k	IM(t2) = IM(cc[ac]) + IM(cc[ac+ido]);
298	648k	IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),taur);
299
300	648k	RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2);
301	648k	IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2);
302
303	648k	RE(c3) = MUL_F((RE(cc[ac]) - RE(cc[ac+ido])), taui);
304	648k	IM(c3) = MUL_F((IM(cc[ac]) - IM(cc[ac+ido])), taui);
305
306	648k	RE(d2) = RE(c2) + IM(c3);
307	648k	IM(d3) = IM(c2) + RE(c3);
308	648k	RE(d3) = RE(c2) - IM(c3);
309	648k	IM(d2) = IM(c2) - RE(c3);
310
311	648k	#if 1
312	648k	ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
313	648k	RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
314	648k	ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
315	648k	RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
316		#else
317		ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
318		IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
319		ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
320		IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
321		#endif
322	648k	}
323	8.10k	}
324	4.09k	}
325	126k	}
326	126k	}

static void passf4pos(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                      complex_t *ch, const complex_t *wa1, const complex_t *wa2,

                      const complex_t *wa3)

3.70M

3.70M

    uint16_t i, k, ac, ah;

3.70M

    if (ido == 1)

958k

73.6M

        for (k = 0; k < l1; k++)

72.6M

72.6M

            complex_t t1, t2, t3, t4;

72.6M

            ac = 4*k;

72.6M

            ah = k;

72.6M

            RE(t2) = RE(cc[ac])   + RE(cc[ac+2]);

72.6M

            RE(t1) = RE(cc[ac])   - RE(cc[ac+2]);

72.6M

            IM(t2) = IM(cc[ac])   + IM(cc[ac+2]);

72.6M

            IM(t1) = IM(cc[ac])   - IM(cc[ac+2]);

72.6M

            RE(t3) = RE(cc[ac+1]) + RE(cc[ac+3]);

72.6M

            IM(t4) = RE(cc[ac+1]) - RE(cc[ac+3]);

72.6M

            IM(t3) = IM(cc[ac+3]) + IM(cc[ac+1]);

72.6M

            RE(t4) = IM(cc[ac+3]) - IM(cc[ac+1]);

72.6M

            RE(ch[ah])      = RE(t2) + RE(t3);

72.6M

            RE(ch[ah+2*l1]) = RE(t2) - RE(t3);

72.6M

            IM(ch[ah])      = IM(t2) + IM(t3);

72.6M

            IM(ch[ah+2*l1]) = IM(t2) - IM(t3);

72.6M

            RE(ch[ah+l1])   = RE(t1) + RE(t4);

72.6M

            RE(ch[ah+3*l1]) = RE(t1) - RE(t4);

72.6M

            IM(ch[ah+l1])   = IM(t1) + IM(t4);

72.6M

            IM(ch[ah+3*l1]) = IM(t1) - IM(t4);

72.6M

2.74M

    } else {

29.8M

        for (k = 0; k < l1; k++)

27.0M

27.0M

            ac = 4*k*ido;

27.0M

            ah = k*ido;

263M

            for (i = 0; i < ido; i++)

236M

236M

                complex_t c2, c3, c4, t1, t2, t3, t4;

236M

                RE(t2) = RE(cc[ac+i]) + RE(cc[ac+i+2*ido]);

236M

                RE(t1) = RE(cc[ac+i]) - RE(cc[ac+i+2*ido]);

236M

                IM(t2) = IM(cc[ac+i]) + IM(cc[ac+i+2*ido]);

236M

                IM(t1) = IM(cc[ac+i]) - IM(cc[ac+i+2*ido]);

236M

                RE(t3) = RE(cc[ac+i+ido]) + RE(cc[ac+i+3*ido]);

236M

                IM(t4) = RE(cc[ac+i+ido]) - RE(cc[ac+i+3*ido]);

236M

                IM(t3) = IM(cc[ac+i+3*ido]) + IM(cc[ac+i+ido]);

236M

                RE(t4) = IM(cc[ac+i+3*ido]) - IM(cc[ac+i+ido]);

236M

                RE(c2) = RE(t1) + RE(t4);

236M

                RE(c4) = RE(t1) - RE(t4);

236M

                IM(c2) = IM(t1) + IM(t4);

236M

                IM(c4) = IM(t1) - IM(t4);

236M

                RE(ch[ah+i]) = RE(t2) + RE(t3);

236M

                RE(c3)       = RE(t2) - RE(t3);

236M

                IM(ch[ah+i]) = IM(t2) + IM(t3);

236M

                IM(c3)       = IM(t2) - IM(t3);

236M

#if 1

236M

                ComplexMult(&IM(ch[ah+i+l1*ido]), &RE(ch[ah+i+l1*ido]),

236M

                    IM(c2), RE(c2), RE(wa1[i]), IM(wa1[i]));

236M

                ComplexMult(&IM(ch[ah+i+2*l1*ido]), &RE(ch[ah+i+2*l1*ido]),

236M

                    IM(c3), RE(c3), RE(wa2[i]), IM(wa2[i]));

236M

                ComplexMult(&IM(ch[ah+i+3*l1*ido]), &RE(ch[ah+i+3*l1*ido]),

236M

                    IM(c4), RE(c4), RE(wa3[i]), IM(wa3[i]));

#else

                ComplexMult(&RE(ch[ah+i+l1*ido]), &IM(ch[ah+i+l1*ido]),

                    RE(c2), IM(c2), RE(wa1[i]), IM(wa1[i]));

                ComplexMult(&RE(ch[ah+i+2*l1*ido]), &IM(ch[ah+i+2*l1*ido]),

                    RE(c3), IM(c3), RE(wa2[i]), IM(wa2[i]));

                ComplexMult(&RE(ch[ah+i+3*l1*ido]), &IM(ch[ah+i+3*l1*ido]),

                    RE(c4), IM(c4), RE(wa3[i]), IM(wa3[i]));

#endif

236M

27.0M

2.74M

3.70M

static void passf4neg(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                      complex_t *ch, const complex_t *wa1, const complex_t *wa2,

                      const complex_t *wa3)

41.4k

41.4k

    uint16_t i, k, ac, ah;

41.4k

    if (ido == 1)

6.70k

846k

        for (k = 0; k < l1; k++)

839k

839k

            complex_t t1, t2, t3, t4;

839k

            ac = 4*k;

839k

            ah = k;

839k

            RE(t2) = RE(cc[ac])   + RE(cc[ac+2]);

839k

            RE(t1) = RE(cc[ac])   - RE(cc[ac+2]);

839k

            IM(t2) = IM(cc[ac])   + IM(cc[ac+2]);

839k

            IM(t1) = IM(cc[ac])   - IM(cc[ac+2]);

839k

            RE(t3) = RE(cc[ac+1]) + RE(cc[ac+3]);

839k

            IM(t4) = RE(cc[ac+1]) - RE(cc[ac+3]);

839k

            IM(t3) = IM(cc[ac+3]) + IM(cc[ac+1]);

839k

            RE(t4) = IM(cc[ac+3]) - IM(cc[ac+1]);

839k

            RE(ch[ah])      = RE(t2) + RE(t3);

839k

            RE(ch[ah+2*l1]) = RE(t2) - RE(t3);

839k

            IM(ch[ah])      = IM(t2) + IM(t3);

839k

            IM(ch[ah+2*l1]) = IM(t2) - IM(t3);

839k

            RE(ch[ah+l1])   = RE(t1) - RE(t4);

839k

            RE(ch[ah+3*l1]) = RE(t1) + RE(t4);

839k

            IM(ch[ah+l1])   = IM(t1) - IM(t4);

839k

            IM(ch[ah+3*l1]) = IM(t1) + IM(t4);

839k

34.7k

    } else {

528k

        for (k = 0; k < l1; k++)

493k

493k

            ac = 4*k*ido;

493k

            ah = k*ido;

4.75M

            for (i = 0; i < ido; i++)

4.26M

4.26M

                complex_t c2, c3, c4, t1, t2, t3, t4;

4.26M

                RE(t2) = RE(cc[ac+i]) + RE(cc[ac+i+2*ido]);

4.26M

                RE(t1) = RE(cc[ac+i]) - RE(cc[ac+i+2*ido]);

4.26M

                IM(t2) = IM(cc[ac+i]) + IM(cc[ac+i+2*ido]);

4.26M

                IM(t1) = IM(cc[ac+i]) - IM(cc[ac+i+2*ido]);

4.26M

                RE(t3) = RE(cc[ac+i+ido]) + RE(cc[ac+i+3*ido]);

4.26M

                IM(t4) = RE(cc[ac+i+ido]) - RE(cc[ac+i+3*ido]);

4.26M

                IM(t3) = IM(cc[ac+i+3*ido]) + IM(cc[ac+i+ido]);

4.26M

                RE(t4) = IM(cc[ac+i+3*ido]) - IM(cc[ac+i+ido]);

4.26M

                RE(c2) = RE(t1) - RE(t4);

4.26M

                RE(c4) = RE(t1) + RE(t4);

4.26M

                IM(c2) = IM(t1) - IM(t4);

4.26M

                IM(c4) = IM(t1) + IM(t4);

4.26M

                RE(ch[ah+i]) = RE(t2) + RE(t3);

4.26M

                RE(c3)       = RE(t2) - RE(t3);

4.26M

                IM(ch[ah+i]) = IM(t2) + IM(t3);

4.26M

                IM(c3)       = IM(t2) - IM(t3);

4.26M

#if 1

4.26M

                ComplexMult(&RE(ch[ah+i+l1*ido]), &IM(ch[ah+i+l1*ido]),

4.26M

                    RE(c2), IM(c2), RE(wa1[i]), IM(wa1[i]));

4.26M

                ComplexMult(&RE(ch[ah+i+2*l1*ido]), &IM(ch[ah+i+2*l1*ido]),

4.26M

                    RE(c3), IM(c3), RE(wa2[i]), IM(wa2[i]));

4.26M

                ComplexMult(&RE(ch[ah+i+3*l1*ido]), &IM(ch[ah+i+3*l1*ido]),

4.26M

                    RE(c4), IM(c4), RE(wa3[i]), IM(wa3[i]));

#else

                ComplexMult(&IM(ch[ah+i+l1*ido]), &RE(ch[ah+i+l1*ido]),

                    IM(c2), RE(c2), RE(wa1[i]), IM(wa1[i]));

                ComplexMult(&IM(ch[ah+i+2*l1*ido]), &RE(ch[ah+i+2*l1*ido]),

                    IM(c3), RE(c3), RE(wa2[i]), IM(wa2[i]));

                ComplexMult(&IM(ch[ah+i+3*l1*ido]), &RE(ch[ah+i+3*l1*ido]),

                    IM(c4), RE(c4), RE(wa3[i]), IM(wa3[i]));

#endif

4.26M

493k

34.7k

41.4k

static void passf5(const uint16_t ido, const uint16_t l1, const complex_t *cc,

                   complex_t *ch, const complex_t *wa1, const complex_t *wa2, const complex_t *wa3,

                   const complex_t *wa4, const int8_t isign)

219k

219k

    static real_t tr11 = FRAC_CONST(0.309016994374947);

219k

    static real_t ti11 = FRAC_CONST(0.951056516295154);

219k

    static real_t tr12 = FRAC_CONST(-0.809016994374947);

219k

    static real_t ti12 = FRAC_CONST(0.587785252292473);

219k

    uint16_t k, ac, ah;

219k

    complex_t c2, c3, c4, c5, t2, t3, t4, t5;

219k

    (void)wa1;

219k

    (void)wa2;

219k

    (void)wa3;

219k

    (void)wa4;

219k

    if (ido == 1)

219k

219k

        if (isign == 1)

212k

11.2M

            for (k = 0; k < l1; k++)

10.9M

10.9M

                ac = 5*k + 1;

10.9M

                ah = k;

10.9M

                RE(t2) = RE(cc[ac]) + RE(cc[ac+3]);

10.9M

                IM(t2) = IM(cc[ac]) + IM(cc[ac+3]);

10.9M

                RE(t3) = RE(cc[ac+1]) + RE(cc[ac+2]);

10.9M

                IM(t3) = IM(cc[ac+1]) + IM(cc[ac+2]);

10.9M

                RE(t4) = RE(cc[ac+1]) - RE(cc[ac+2]);

10.9M

                IM(t4) = IM(cc[ac+1]) - IM(cc[ac+2]);

10.9M

                RE(t5) = RE(cc[ac]) - RE(cc[ac+3]);

10.9M

                IM(t5) = IM(cc[ac]) - IM(cc[ac+3]);

10.9M

                RE(ch[ah]) = RE(cc[ac-1]) + RE(t2) + RE(t3);

10.9M

                IM(ch[ah]) = IM(cc[ac-1]) + IM(t2) + IM(t3);

10.9M

                RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);

10.9M

                IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);

10.9M

                RE(c3) = RE(cc[ac-1]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);

10.9M

                IM(c3) = IM(cc[ac-1]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);

10.9M

                ComplexMult(&RE(c5), &RE(c4),

10.9M

                    ti11, ti12, RE(t5), RE(t4));

10.9M

                ComplexMult(&IM(c5), &IM(c4),

10.9M

                    ti11, ti12, IM(t5), IM(t4));

10.9M

                RE(ch[ah+l1]) = RE(c2) - IM(c5);

10.9M

                IM(ch[ah+l1]) = IM(c2) + RE(c5);

10.9M

                RE(ch[ah+2*l1]) = RE(c3) - IM(c4);

10.9M

                IM(ch[ah+2*l1]) = IM(c3) + RE(c4);

10.9M

                RE(ch[ah+3*l1]) = RE(c3) + IM(c4);

10.9M

                IM(ch[ah+3*l1]) = IM(c3) - RE(c4);

10.9M

                RE(ch[ah+4*l1]) = RE(c2) + IM(c5);

10.9M

                IM(ch[ah+4*l1]) = IM(c2) - RE(c5);

10.9M

212k

        } else {

705k

            for (k = 0; k < l1; k++)

698k

698k

                ac = 5*k + 1;

698k

                ah = k;

698k

                RE(t2) = RE(cc[ac]) + RE(cc[ac+3]);

698k

                IM(t2) = IM(cc[ac]) + IM(cc[ac+3]);

698k

                RE(t3) = RE(cc[ac+1]) + RE(cc[ac+2]);

698k

                IM(t3) = IM(cc[ac+1]) + IM(cc[ac+2]);

698k

                RE(t4) = RE(cc[ac+1]) - RE(cc[ac+2]);

698k

                IM(t4) = IM(cc[ac+1]) - IM(cc[ac+2]);

698k

                RE(t5) = RE(cc[ac]) - RE(cc[ac+3]);

698k

                IM(t5) = IM(cc[ac]) - IM(cc[ac+3]);

698k

                RE(ch[ah]) = RE(cc[ac-1]) + RE(t2) + RE(t3);

698k

                IM(ch[ah]) = IM(cc[ac-1]) + IM(t2) + IM(t3);

698k

                RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);

698k

                IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);

698k

                RE(c3) = RE(cc[ac-1]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);

698k

                IM(c3) = IM(cc[ac-1]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);

698k

                ComplexMult(&RE(c4), &RE(c5),

698k

                    ti12, ti11, RE(t5), RE(t4));

698k

                ComplexMult(&IM(c4), &IM(c5),

698k

                    ti12, ti11, IM(t5), IM(t4));

698k

                RE(ch[ah+l1]) = RE(c2) + IM(c5);

698k

                IM(ch[ah+l1]) = IM(c2) - RE(c5);

698k

                RE(ch[ah+2*l1]) = RE(c3) + IM(c4);

698k

                IM(ch[ah+2*l1]) = IM(c3) - RE(c4);

698k

                RE(ch[ah+3*l1]) = RE(c3) - IM(c4);

698k

                IM(ch[ah+3*l1]) = IM(c3) + RE(c4);

698k

                RE(ch[ah+4*l1]) = RE(c2) - IM(c5);

698k

                IM(ch[ah+4*l1]) = IM(c2) + RE(c5);

698k

7.32k

219k

    } else {

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

        // TODO: remove this code once fuzzer proves it is totally unreahable

        // 5 if the biggest factor and it never repeated for supported frame

        // lengths; consequently `ido` should always be 1.

        __builtin_trap();

/*

#else

        uint16_t i;

        complex_t d3, d4, d5, d2;

#endif

        if (isign == 1)

            for (k = 0; k < l1; k++)

                for (i = 0; i < ido; i++)

                    ac = i + (k*5 + 1) * ido;

                    ah = i + k * ido;

                    RE(t2) = RE(cc[ac]) + RE(cc[ac+3*ido]);

                    IM(t2) = IM(cc[ac]) + IM(cc[ac+3*ido]);

                    RE(t3) = RE(cc[ac+ido]) + RE(cc[ac+2*ido]);

                    IM(t3) = IM(cc[ac+ido]) + IM(cc[ac+2*ido]);

                    RE(t4) = RE(cc[ac+ido]) - RE(cc[ac+2*ido]);

                    IM(t4) = IM(cc[ac+ido]) - IM(cc[ac+2*ido]);

                    RE(t5) = RE(cc[ac]) - RE(cc[ac+3*ido]);

                    IM(t5) = IM(cc[ac]) - IM(cc[ac+3*ido]);

                    RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2) + RE(t3);

                    IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2) + IM(t3);

                    RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);

                    IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);

                    RE(c3) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);

                    IM(c3) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);

                    ComplexMult(&RE(c5), &RE(c4),

                        ti11, ti12, RE(t5), RE(t4));

                    ComplexMult(&IM(c5), &IM(c4),

                        ti11, ti12, IM(t5), IM(t4));

                    IM(d2) = IM(c2) + RE(c5);

                    IM(d3) = IM(c3) + RE(c4);

                    RE(d4) = RE(c3) + IM(c4);

                    RE(d5) = RE(c2) + IM(c5);

                    RE(d2) = RE(c2) - IM(c5);

                    IM(d5) = IM(c2) - RE(c5);

                    RE(d3) = RE(c3) - IM(c4);

                    IM(d4) = IM(c3) - RE(c4);

#if 1

                    ComplexMult(&IM(ch[ah+l1*ido]), &RE(ch[ah+l1*ido]),

                        IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));

                    ComplexMult(&IM(ch[ah+2*l1*ido]), &RE(ch[ah+2*l1*ido]),

                        IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));

                    ComplexMult(&IM(ch[ah+3*l1*ido]), &RE(ch[ah+3*l1*ido]),

                        IM(d4), RE(d4), RE(wa3[i]), IM(wa3[i]));

                    ComplexMult(&IM(ch[ah+4*l1*ido]), &RE(ch[ah+4*l1*ido]),

                        IM(d5), RE(d5), RE(wa4[i]), IM(wa4[i]));

#else

                    ComplexMult(&RE(ch[ah+l1*ido]), &IM(ch[ah+l1*ido]),

                        RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));

                    ComplexMult(&RE(ch[ah+2*l1*ido]), &IM(ch[ah+2*l1*ido]),

                        RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));

                    ComplexMult(&RE(ch[ah+3*l1*ido]), &IM(ch[ah+3*l1*ido]),

                        RE(d4), IM(d4), RE(wa3[i]), IM(wa3[i]));

                    ComplexMult(&RE(ch[ah+4*l1*ido]), &IM(ch[ah+4*l1*ido]),

                        RE(d5), IM(d5), RE(wa4[i]), IM(wa4[i]));

#endif

        } else {

            for (k = 0; k < l1; k++)

                for (i = 0; i < ido; i++)

                    ac = i + (k*5 + 1) * ido;

                    ah = i + k * ido;

                    RE(t2) = RE(cc[ac]) + RE(cc[ac+3*ido]);

                    IM(t2) = IM(cc[ac]) + IM(cc[ac+3*ido]);

                    RE(t3) = RE(cc[ac+ido]) + RE(cc[ac+2*ido]);

                    IM(t3) = IM(cc[ac+ido]) + IM(cc[ac+2*ido]);

                    RE(t4) = RE(cc[ac+ido]) - RE(cc[ac+2*ido]);

                    IM(t4) = IM(cc[ac+ido]) - IM(cc[ac+2*ido]);

                    RE(t5) = RE(cc[ac]) - RE(cc[ac+3*ido]);

                    IM(t5) = IM(cc[ac]) - IM(cc[ac+3*ido]);

                    RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2) + RE(t3);

                    IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2) + IM(t3);

                    RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);

                    IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);

                    RE(c3) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);

                    IM(c3) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);

                    ComplexMult(&RE(c4), &RE(c5),

                        ti12, ti11, RE(t5), RE(t4));

                    ComplexMult(&IM(c4), &IM(c5),

                        ti12, ti11, IM(t5), IM(t4));

                    IM(d2) = IM(c2) - RE(c5);

                    IM(d3) = IM(c3) - RE(c4);

                    RE(d4) = RE(c3) - IM(c4);

                    RE(d5) = RE(c2) - IM(c5);

                    RE(d2) = RE(c2) + IM(c5);

                    IM(d5) = IM(c2) + RE(c5);

                    RE(d3) = RE(c3) + IM(c4);

                    IM(d4) = IM(c3) + RE(c4);

#if 1

                    ComplexMult(&RE(ch[ah+l1*ido]), &IM(ch[ah+l1*ido]),

                        RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));

                    ComplexMult(&RE(ch[ah+2*l1*ido]), &IM(ch[ah+2*l1*ido]),

                        RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));

                    ComplexMult(&RE(ch[ah+3*l1*ido]), &IM(ch[ah+3*l1*ido]),

                        RE(d4), IM(d4), RE(wa3[i]), IM(wa3[i]));

                    ComplexMult(&RE(ch[ah+4*l1*ido]), &IM(ch[ah+4*l1*ido]),

                        RE(d5), IM(d5), RE(wa4[i]), IM(wa4[i]));

#else

                    ComplexMult(&IM(ch[ah+l1*ido]), &RE(ch[ah+l1*ido]),

                        IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));

                    ComplexMult(&IM(ch[ah+2*l1*ido]), &RE(ch[ah+2*l1*ido]),

                        IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));

                    ComplexMult(&IM(ch[ah+3*l1*ido]), &RE(ch[ah+3*l1*ido]),

                        IM(d4), RE(d4), RE(wa3[i]), IM(wa3[i]));

                    ComplexMult(&IM(ch[ah+4*l1*ido]), &RE(ch[ah+4*l1*ido]),

                        IM(d5), RE(d5), RE(wa4[i]), IM(wa4[i]));

#endif

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

*/

#endif

219k

cfft.c:passf5

Line	Count	Source
506	93.4k	{
507	93.4k	static real_t tr11 = FRAC_CONST(0.309016994374947);
508	93.4k	static real_t ti11 = FRAC_CONST(0.951056516295154);
509	93.4k	static real_t tr12 = FRAC_CONST(-0.809016994374947);
510	93.4k	static real_t ti12 = FRAC_CONST(0.587785252292473);
511	93.4k	uint16_t k, ac, ah;
512	93.4k	complex_t c2, c3, c4, c5, t2, t3, t4, t5;
513	93.4k	(void)wa1;
514	93.4k	(void)wa2;
515	93.4k	(void)wa3;
516	93.4k	(void)wa4;
517
518	93.4k	if (ido == 1)
519	93.4k	{
520	93.4k	if (isign == 1)
521	90.1k	{
522	4.66M	for (k = 0; k < l1; k++)
523	4.57M	{
524	4.57M	ac = 5*k + 1;
525	4.57M	ah = k;
526
527	4.57M	RE(t2) = RE(cc[ac]) + RE(cc[ac+3]);
528	4.57M	IM(t2) = IM(cc[ac]) + IM(cc[ac+3]);
529	4.57M	RE(t3) = RE(cc[ac+1]) + RE(cc[ac+2]);
530	4.57M	IM(t3) = IM(cc[ac+1]) + IM(cc[ac+2]);
531	4.57M	RE(t4) = RE(cc[ac+1]) - RE(cc[ac+2]);
532	4.57M	IM(t4) = IM(cc[ac+1]) - IM(cc[ac+2]);
533	4.57M	RE(t5) = RE(cc[ac]) - RE(cc[ac+3]);
534	4.57M	IM(t5) = IM(cc[ac]) - IM(cc[ac+3]);
535
536	4.57M	RE(ch[ah]) = RE(cc[ac-1]) + RE(t2) + RE(t3);
537	4.57M	IM(ch[ah]) = IM(cc[ac-1]) + IM(t2) + IM(t3);
538
539	4.57M	RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
540	4.57M	IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
541	4.57M	RE(c3) = RE(cc[ac-1]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
542	4.57M	IM(c3) = IM(cc[ac-1]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
543
544	4.57M	ComplexMult(&RE(c5), &RE(c4),
545	4.57M	ti11, ti12, RE(t5), RE(t4));
546	4.57M	ComplexMult(&IM(c5), &IM(c4),
547	4.57M	ti11, ti12, IM(t5), IM(t4));
548
549	4.57M	RE(ch[ah+l1]) = RE(c2) - IM(c5);
550	4.57M	IM(ch[ah+l1]) = IM(c2) + RE(c5);
551	4.57M	RE(ch[ah+2*l1]) = RE(c3) - IM(c4);
552	4.57M	IM(ch[ah+2*l1]) = IM(c3) + RE(c4);
553	4.57M	RE(ch[ah+3*l1]) = RE(c3) + IM(c4);
554	4.57M	IM(ch[ah+3*l1]) = IM(c3) - RE(c4);
555	4.57M	RE(ch[ah+4*l1]) = RE(c2) + IM(c5);
556	4.57M	IM(ch[ah+4*l1]) = IM(c2) - RE(c5);
557	4.57M	}
558	90.1k	} else {
559	312k	for (k = 0; k < l1; k++)
560	309k	{
561	309k	ac = 5*k + 1;
562	309k	ah = k;
563
564	309k	RE(t2) = RE(cc[ac]) + RE(cc[ac+3]);
565	309k	IM(t2) = IM(cc[ac]) + IM(cc[ac+3]);
566	309k	RE(t3) = RE(cc[ac+1]) + RE(cc[ac+2]);
567	309k	IM(t3) = IM(cc[ac+1]) + IM(cc[ac+2]);
568	309k	RE(t4) = RE(cc[ac+1]) - RE(cc[ac+2]);
569	309k	IM(t4) = IM(cc[ac+1]) - IM(cc[ac+2]);
570	309k	RE(t5) = RE(cc[ac]) - RE(cc[ac+3]);
571	309k	IM(t5) = IM(cc[ac]) - IM(cc[ac+3]);
572
573	309k	RE(ch[ah]) = RE(cc[ac-1]) + RE(t2) + RE(t3);
574	309k	IM(ch[ah]) = IM(cc[ac-1]) + IM(t2) + IM(t3);
575
576	309k	RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
577	309k	IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
578	309k	RE(c3) = RE(cc[ac-1]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
579	309k	IM(c3) = IM(cc[ac-1]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
580
581	309k	ComplexMult(&RE(c4), &RE(c5),
582	309k	ti12, ti11, RE(t5), RE(t4));
583	309k	ComplexMult(&IM(c4), &IM(c5),
584	309k	ti12, ti11, IM(t5), IM(t4));
585
586	309k	RE(ch[ah+l1]) = RE(c2) + IM(c5);
587	309k	IM(ch[ah+l1]) = IM(c2) - RE(c5);
588	309k	RE(ch[ah+2*l1]) = RE(c3) + IM(c4);
589	309k	IM(ch[ah+2*l1]) = IM(c3) - RE(c4);
590	309k	RE(ch[ah+3*l1]) = RE(c3) - IM(c4);
591	309k	IM(ch[ah+3*l1]) = IM(c3) + RE(c4);
592	309k	RE(ch[ah+4*l1]) = RE(c2) - IM(c5);
593	309k	IM(ch[ah+4*l1]) = IM(c2) + RE(c5);
594	309k	}
595	3.23k	}
596	93.4k	} else {
597	0	#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
598		// TODO: remove this code once fuzzer proves it is totally unreahable
599		// 5 if the biggest factor and it never repeated for supported frame
600		// lengths; consequently `ido` should always be 1.
601	0	__builtin_trap();
602		/*
603		#else
604		uint16_t i;
605		complex_t d3, d4, d5, d2;
606		#endif
607		if (isign == 1)
608		{
609		for (k = 0; k < l1; k++)
610		{
611		for (i = 0; i < ido; i++)
612		{
613		ac = i + (k5 + 1) ido;
614		ah = i + k * ido;
615
616		RE(t2) = RE(cc[ac]) + RE(cc[ac+3*ido]);
617		IM(t2) = IM(cc[ac]) + IM(cc[ac+3*ido]);
618		RE(t3) = RE(cc[ac+ido]) + RE(cc[ac+2*ido]);
619		IM(t3) = IM(cc[ac+ido]) + IM(cc[ac+2*ido]);
620		RE(t4) = RE(cc[ac+ido]) - RE(cc[ac+2*ido]);
621		IM(t4) = IM(cc[ac+ido]) - IM(cc[ac+2*ido]);
622		RE(t5) = RE(cc[ac]) - RE(cc[ac+3*ido]);
623		IM(t5) = IM(cc[ac]) - IM(cc[ac+3*ido]);
624
625		RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2) + RE(t3);
626		IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2) + IM(t3);
627
628		RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
629		IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
630		RE(c3) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
631		IM(c3) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
632
633		ComplexMult(&RE(c5), &RE(c4),
634		ti11, ti12, RE(t5), RE(t4));
635		ComplexMult(&IM(c5), &IM(c4),
636		ti11, ti12, IM(t5), IM(t4));
637
638		IM(d2) = IM(c2) + RE(c5);
639		IM(d3) = IM(c3) + RE(c4);
640		RE(d4) = RE(c3) + IM(c4);
641		RE(d5) = RE(c2) + IM(c5);
642		RE(d2) = RE(c2) - IM(c5);
643		IM(d5) = IM(c2) - RE(c5);
644		RE(d3) = RE(c3) - IM(c4);
645		IM(d4) = IM(c3) - RE(c4);
646
647		#if 1
648		ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
649		IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
650		ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
651		IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
652		ComplexMult(&IM(ch[ah+3l1ido]), &RE(ch[ah+3l1ido]),
653		IM(d4), RE(d4), RE(wa3[i]), IM(wa3[i]));
654		ComplexMult(&IM(ch[ah+4l1ido]), &RE(ch[ah+4l1ido]),
655		IM(d5), RE(d5), RE(wa4[i]), IM(wa4[i]));
656		#else
657		ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
658		RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
659		ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
660		RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
661		ComplexMult(&RE(ch[ah+3l1ido]), &IM(ch[ah+3l1ido]),
662		RE(d4), IM(d4), RE(wa3[i]), IM(wa3[i]));
663		ComplexMult(&RE(ch[ah+4l1ido]), &IM(ch[ah+4l1ido]),
664		RE(d5), IM(d5), RE(wa4[i]), IM(wa4[i]));
665		#endif
666		}
667		}
668		} else {
669		for (k = 0; k < l1; k++)
670		{
671		for (i = 0; i < ido; i++)
672		{
673		ac = i + (k5 + 1) ido;
674		ah = i + k * ido;
675
676		RE(t2) = RE(cc[ac]) + RE(cc[ac+3*ido]);
677		IM(t2) = IM(cc[ac]) + IM(cc[ac+3*ido]);
678		RE(t3) = RE(cc[ac+ido]) + RE(cc[ac+2*ido]);
679		IM(t3) = IM(cc[ac+ido]) + IM(cc[ac+2*ido]);
680		RE(t4) = RE(cc[ac+ido]) - RE(cc[ac+2*ido]);
681		IM(t4) = IM(cc[ac+ido]) - IM(cc[ac+2*ido]);
682		RE(t5) = RE(cc[ac]) - RE(cc[ac+3*ido]);
683		IM(t5) = IM(cc[ac]) - IM(cc[ac+3*ido]);
684
685		RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2) + RE(t3);
686		IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2) + IM(t3);
687
688		RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
689		IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
690		RE(c3) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
691		IM(c3) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
692
693		ComplexMult(&RE(c4), &RE(c5),
694		ti12, ti11, RE(t5), RE(t4));
695		ComplexMult(&IM(c4), &IM(c5),
696		ti12, ti11, IM(t5), IM(t4));
697
698		IM(d2) = IM(c2) - RE(c5);
699		IM(d3) = IM(c3) - RE(c4);
700		RE(d4) = RE(c3) - IM(c4);
701		RE(d5) = RE(c2) - IM(c5);
702		RE(d2) = RE(c2) + IM(c5);
703		IM(d5) = IM(c2) + RE(c5);
704		RE(d3) = RE(c3) + IM(c4);
705		IM(d4) = IM(c3) + RE(c4);
706
707		#if 1
708		ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
709		RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
710		ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
711		RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
712		ComplexMult(&RE(ch[ah+3l1ido]), &IM(ch[ah+3l1ido]),
713		RE(d4), IM(d4), RE(wa3[i]), IM(wa3[i]));
714		ComplexMult(&RE(ch[ah+4l1ido]), &IM(ch[ah+4l1ido]),
715		RE(d5), IM(d5), RE(wa4[i]), IM(wa4[i]));
716		#else
717		ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
718		IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
719		ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
720		IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
721		ComplexMult(&IM(ch[ah+3l1ido]), &RE(ch[ah+3l1ido]),
722		IM(d4), RE(d4), RE(wa3[i]), IM(wa3[i]));
723		ComplexMult(&IM(ch[ah+4l1ido]), &RE(ch[ah+4l1ido]),
724		IM(d5), RE(d5), RE(wa4[i]), IM(wa4[i]));
725		#endif
726		}
727		}
728		}
729		#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
730		*/
731	0	#endif
732	0	}
733	93.4k	}

cfft.c:passf5

Line	Count	Source
506	126k	{
507	126k	static real_t tr11 = FRAC_CONST(0.309016994374947);
508	126k	static real_t ti11 = FRAC_CONST(0.951056516295154);
509	126k	static real_t tr12 = FRAC_CONST(-0.809016994374947);
510	126k	static real_t ti12 = FRAC_CONST(0.587785252292473);
511	126k	uint16_t k, ac, ah;
512	126k	complex_t c2, c3, c4, c5, t2, t3, t4, t5;
513	126k	(void)wa1;
514	126k	(void)wa2;
515	126k	(void)wa3;
516	126k	(void)wa4;
517
518	126k	if (ido == 1)
519	126k	{
520	126k	if (isign == 1)
521	122k	{
522	6.53M	for (k = 0; k < l1; k++)
523	6.41M	{
524	6.41M	ac = 5*k + 1;
525	6.41M	ah = k;
526
527	6.41M	RE(t2) = RE(cc[ac]) + RE(cc[ac+3]);
528	6.41M	IM(t2) = IM(cc[ac]) + IM(cc[ac+3]);
529	6.41M	RE(t3) = RE(cc[ac+1]) + RE(cc[ac+2]);
530	6.41M	IM(t3) = IM(cc[ac+1]) + IM(cc[ac+2]);
531	6.41M	RE(t4) = RE(cc[ac+1]) - RE(cc[ac+2]);
532	6.41M	IM(t4) = IM(cc[ac+1]) - IM(cc[ac+2]);
533	6.41M	RE(t5) = RE(cc[ac]) - RE(cc[ac+3]);
534	6.41M	IM(t5) = IM(cc[ac]) - IM(cc[ac+3]);
535
536	6.41M	RE(ch[ah]) = RE(cc[ac-1]) + RE(t2) + RE(t3);
537	6.41M	IM(ch[ah]) = IM(cc[ac-1]) + IM(t2) + IM(t3);
538
539	6.41M	RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
540	6.41M	IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
541	6.41M	RE(c3) = RE(cc[ac-1]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
542	6.41M	IM(c3) = IM(cc[ac-1]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
543
544	6.41M	ComplexMult(&RE(c5), &RE(c4),
545	6.41M	ti11, ti12, RE(t5), RE(t4));
546	6.41M	ComplexMult(&IM(c5), &IM(c4),
547	6.41M	ti11, ti12, IM(t5), IM(t4));
548
549	6.41M	RE(ch[ah+l1]) = RE(c2) - IM(c5);
550	6.41M	IM(ch[ah+l1]) = IM(c2) + RE(c5);
551	6.41M	RE(ch[ah+2*l1]) = RE(c3) - IM(c4);
552	6.41M	IM(ch[ah+2*l1]) = IM(c3) + RE(c4);
553	6.41M	RE(ch[ah+3*l1]) = RE(c3) + IM(c4);
554	6.41M	IM(ch[ah+3*l1]) = IM(c3) - RE(c4);
555	6.41M	RE(ch[ah+4*l1]) = RE(c2) + IM(c5);
556	6.41M	IM(ch[ah+4*l1]) = IM(c2) - RE(c5);
557	6.41M	}
558	122k	} else {
559	392k	for (k = 0; k < l1; k++)
560	388k	{
561	388k	ac = 5*k + 1;
562	388k	ah = k;
563
564	388k	RE(t2) = RE(cc[ac]) + RE(cc[ac+3]);
565	388k	IM(t2) = IM(cc[ac]) + IM(cc[ac+3]);
566	388k	RE(t3) = RE(cc[ac+1]) + RE(cc[ac+2]);
567	388k	IM(t3) = IM(cc[ac+1]) + IM(cc[ac+2]);
568	388k	RE(t4) = RE(cc[ac+1]) - RE(cc[ac+2]);
569	388k	IM(t4) = IM(cc[ac+1]) - IM(cc[ac+2]);
570	388k	RE(t5) = RE(cc[ac]) - RE(cc[ac+3]);
571	388k	IM(t5) = IM(cc[ac]) - IM(cc[ac+3]);
572
573	388k	RE(ch[ah]) = RE(cc[ac-1]) + RE(t2) + RE(t3);
574	388k	IM(ch[ah]) = IM(cc[ac-1]) + IM(t2) + IM(t3);
575
576	388k	RE(c2) = RE(cc[ac-1]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
577	388k	IM(c2) = IM(cc[ac-1]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
578	388k	RE(c3) = RE(cc[ac-1]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
579	388k	IM(c3) = IM(cc[ac-1]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
580
581	388k	ComplexMult(&RE(c4), &RE(c5),
582	388k	ti12, ti11, RE(t5), RE(t4));
583	388k	ComplexMult(&IM(c4), &IM(c5),
584	388k	ti12, ti11, IM(t5), IM(t4));
585
586	388k	RE(ch[ah+l1]) = RE(c2) + IM(c5);
587	388k	IM(ch[ah+l1]) = IM(c2) - RE(c5);
588	388k	RE(ch[ah+2*l1]) = RE(c3) + IM(c4);
589	388k	IM(ch[ah+2*l1]) = IM(c3) - RE(c4);
590	388k	RE(ch[ah+3*l1]) = RE(c3) - IM(c4);
591	388k	IM(ch[ah+3*l1]) = IM(c3) + RE(c4);
592	388k	RE(ch[ah+4*l1]) = RE(c2) - IM(c5);
593	388k	IM(ch[ah+4*l1]) = IM(c2) + RE(c5);
594	388k	}
595	4.09k	}
596	126k	} else {
597	0	#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
598		// TODO: remove this code once fuzzer proves it is totally unreahable
599		// 5 if the biggest factor and it never repeated for supported frame
600		// lengths; consequently `ido` should always be 1.
601	0	__builtin_trap();
602		/*
603		#else
604		uint16_t i;
605		complex_t d3, d4, d5, d2;
606		#endif
607		if (isign == 1)
608		{
609		for (k = 0; k < l1; k++)
610		{
611		for (i = 0; i < ido; i++)
612		{
613		ac = i + (k5 + 1) ido;
614		ah = i + k * ido;
615
616		RE(t2) = RE(cc[ac]) + RE(cc[ac+3*ido]);
617		IM(t2) = IM(cc[ac]) + IM(cc[ac+3*ido]);
618		RE(t3) = RE(cc[ac+ido]) + RE(cc[ac+2*ido]);
619		IM(t3) = IM(cc[ac+ido]) + IM(cc[ac+2*ido]);
620		RE(t4) = RE(cc[ac+ido]) - RE(cc[ac+2*ido]);
621		IM(t4) = IM(cc[ac+ido]) - IM(cc[ac+2*ido]);
622		RE(t5) = RE(cc[ac]) - RE(cc[ac+3*ido]);
623		IM(t5) = IM(cc[ac]) - IM(cc[ac+3*ido]);
624
625		RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2) + RE(t3);
626		IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2) + IM(t3);
627
628		RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
629		IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
630		RE(c3) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
631		IM(c3) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
632
633		ComplexMult(&RE(c5), &RE(c4),
634		ti11, ti12, RE(t5), RE(t4));
635		ComplexMult(&IM(c5), &IM(c4),
636		ti11, ti12, IM(t5), IM(t4));
637
638		IM(d2) = IM(c2) + RE(c5);
639		IM(d3) = IM(c3) + RE(c4);
640		RE(d4) = RE(c3) + IM(c4);
641		RE(d5) = RE(c2) + IM(c5);
642		RE(d2) = RE(c2) - IM(c5);
643		IM(d5) = IM(c2) - RE(c5);
644		RE(d3) = RE(c3) - IM(c4);
645		IM(d4) = IM(c3) - RE(c4);
646
647		#if 1
648		ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
649		IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
650		ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
651		IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
652		ComplexMult(&IM(ch[ah+3l1ido]), &RE(ch[ah+3l1ido]),
653		IM(d4), RE(d4), RE(wa3[i]), IM(wa3[i]));
654		ComplexMult(&IM(ch[ah+4l1ido]), &RE(ch[ah+4l1ido]),
655		IM(d5), RE(d5), RE(wa4[i]), IM(wa4[i]));
656		#else
657		ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
658		RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
659		ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
660		RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
661		ComplexMult(&RE(ch[ah+3l1ido]), &IM(ch[ah+3l1ido]),
662		RE(d4), IM(d4), RE(wa3[i]), IM(wa3[i]));
663		ComplexMult(&RE(ch[ah+4l1ido]), &IM(ch[ah+4l1ido]),
664		RE(d5), IM(d5), RE(wa4[i]), IM(wa4[i]));
665		#endif
666		}
667		}
668		} else {
669		for (k = 0; k < l1; k++)
670		{
671		for (i = 0; i < ido; i++)
672		{
673		ac = i + (k5 + 1) ido;
674		ah = i + k * ido;
675
676		RE(t2) = RE(cc[ac]) + RE(cc[ac+3*ido]);
677		IM(t2) = IM(cc[ac]) + IM(cc[ac+3*ido]);
678		RE(t3) = RE(cc[ac+ido]) + RE(cc[ac+2*ido]);
679		IM(t3) = IM(cc[ac+ido]) + IM(cc[ac+2*ido]);
680		RE(t4) = RE(cc[ac+ido]) - RE(cc[ac+2*ido]);
681		IM(t4) = IM(cc[ac+ido]) - IM(cc[ac+2*ido]);
682		RE(t5) = RE(cc[ac]) - RE(cc[ac+3*ido]);
683		IM(t5) = IM(cc[ac]) - IM(cc[ac+3*ido]);
684
685		RE(ch[ah]) = RE(cc[ac-ido]) + RE(t2) + RE(t3);
686		IM(ch[ah]) = IM(cc[ac-ido]) + IM(t2) + IM(t3);
687
688		RE(c2) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr11) + MUL_F(RE(t3),tr12);
689		IM(c2) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr11) + MUL_F(IM(t3),tr12);
690		RE(c3) = RE(cc[ac-ido]) + MUL_F(RE(t2),tr12) + MUL_F(RE(t3),tr11);
691		IM(c3) = IM(cc[ac-ido]) + MUL_F(IM(t2),tr12) + MUL_F(IM(t3),tr11);
692
693		ComplexMult(&RE(c4), &RE(c5),
694		ti12, ti11, RE(t5), RE(t4));
695		ComplexMult(&IM(c4), &IM(c5),
696		ti12, ti11, IM(t5), IM(t4));
697
698		IM(d2) = IM(c2) - RE(c5);
699		IM(d3) = IM(c3) - RE(c4);
700		RE(d4) = RE(c3) - IM(c4);
701		RE(d5) = RE(c2) - IM(c5);
702		RE(d2) = RE(c2) + IM(c5);
703		IM(d5) = IM(c2) + RE(c5);
704		RE(d3) = RE(c3) + IM(c4);
705		IM(d4) = IM(c3) + RE(c4);
706
707		#if 1
708		ComplexMult(&RE(ch[ah+l1ido]), &IM(ch[ah+l1ido]),
709		RE(d2), IM(d2), RE(wa1[i]), IM(wa1[i]));
710		ComplexMult(&RE(ch[ah+2l1ido]), &IM(ch[ah+2l1ido]),
711		RE(d3), IM(d3), RE(wa2[i]), IM(wa2[i]));
712		ComplexMult(&RE(ch[ah+3l1ido]), &IM(ch[ah+3l1ido]),
713		RE(d4), IM(d4), RE(wa3[i]), IM(wa3[i]));
714		ComplexMult(&RE(ch[ah+4l1ido]), &IM(ch[ah+4l1ido]),
715		RE(d5), IM(d5), RE(wa4[i]), IM(wa4[i]));
716		#else
717		ComplexMult(&IM(ch[ah+l1ido]), &RE(ch[ah+l1ido]),
718		IM(d2), RE(d2), RE(wa1[i]), IM(wa1[i]));
719		ComplexMult(&IM(ch[ah+2l1ido]), &RE(ch[ah+2l1ido]),
720		IM(d3), RE(d3), RE(wa2[i]), IM(wa2[i]));
721		ComplexMult(&IM(ch[ah+3l1ido]), &RE(ch[ah+3l1ido]),
722		IM(d4), RE(d4), RE(wa3[i]), IM(wa3[i]));
723		ComplexMult(&IM(ch[ah+4l1ido]), &RE(ch[ah+4l1ido]),
724		IM(d5), RE(d5), RE(wa4[i]), IM(wa4[i]));
725		#endif
726		}
727		}
728		}
729		#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
730		*/
731	0	#endif
732	0	}
733	126k	}

/*----------------------------------------------------------------------

   cfftf1, cfftf, cfftb, cffti1, cffti. Complex FFTs.

  ----------------------------------------------------------------------*/

static INLINE void cfftf1pos(uint16_t n, complex_t *c, complex_t *ch,

                             const uint16_t *ifac, const complex_t *wa,

                             const int8_t isign)

1.17M

1.17M

    uint16_t i;

1.17M

    uint16_t k1, l1, l2;

1.17M

    uint16_t na, nf, ip, iw, ix2, ix3, ix4, ido;

1.17M

    nf = ifac[1];

1.17M

    na = 0;

1.17M

    l1 = 1;

1.17M

    iw = 0;

5.91M

    for (k1 = 2; k1 <= nf+1; k1++)

4.73M

4.73M

        ip = ifac[k1];

4.73M

        l2 = ip*l1;

4.73M

        ido = n / l2;

4.73M

        switch (ip)

4.73M

3.70M

        case 4:

3.70M

            ix2 = iw + ido;

3.70M

            ix3 = ix2 + ido;

3.70M

            if (na == 0)

2.01M

                passf4pos((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw], &wa[ix2], &wa[ix3]);

1.68M

            else

1.68M

                passf4pos((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw], &wa[ix2], &wa[ix3]);

3.70M

            na = 1 - na;

3.70M

            break;

610k

        case 2:

610k

            if (na == 0)

610k

                passf2pos((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw]);

            else

                passf2pos((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw]);

610k

            na = 1 - na;

610k

            break;

212k

        case 3:

212k

            ix2 = iw + ido;

212k

            if (na == 0)

112k

                passf3((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw], &wa[ix2], isign);

99.5k

            else

99.5k

                passf3((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw], &wa[ix2], isign);

212k

            na = 1 - na;

212k

            break;

212k

        case 5:

212k

            ix2 = iw + ido;

212k

            ix3 = ix2 + ido;

212k

            ix4 = ix3 + ido;

212k

            if (na == 0)

210k

                passf5((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw], &wa[ix2], &wa[ix3], &wa[ix4], isign);

2.08k

            else

2.08k

                passf5((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw], &wa[ix2], &wa[ix3], &wa[ix4], isign);

212k

            na = 1 - na;

212k

            break;

4.73M

4.73M

        l1 = l2;

4.73M

        iw += (ip-1) * ido;

4.73M

1.17M

    if (na == 0)

4.44k

        return;

345M

    for (i = 0; i < n; i++)

344M

344M

        RE(c[i]) = RE(ch[i]);

344M

        IM(c[i]) = IM(ch[i]);

344M

1.16M

static INLINE void cfftf1neg(uint16_t n, complex_t *c, complex_t *ch,

                             const uint16_t *ifac, const complex_t *wa,

                             const int8_t isign)

14.0k

14.0k

    uint16_t i;

14.0k

    uint16_t k1, l1, l2;

14.0k

    uint16_t na, nf, ip, iw, ix2, ix3, ix4, ido;

14.0k

    nf = ifac[1];

14.0k

    na = 0;

14.0k

    l1 = 1;

14.0k

    iw = 0;

83.7k

    for (k1 = 2; k1 <= nf+1; k1++)

69.7k

69.7k

        ip = ifac[k1];

69.7k

        l2 = ip*l1;

69.7k

        ido = n / l2;

69.7k

        switch (ip)

69.7k

41.4k

        case 4:

41.4k

            ix2 = iw + ido;

41.4k

            ix3 = ix2 + ido;

41.4k

            if (na == 0)

20.7k

                passf4neg((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw], &wa[ix2], &wa[ix3]);

20.7k

            else

20.7k

                passf4neg((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw], &wa[ix2], &wa[ix3]);

41.4k

            na = 1 - na;

41.4k

            break;

13.6k

        case 2:

13.6k

            if (na == 0)

13.6k

                passf2neg((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw]);

            else

                passf2neg((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw]);

13.6k

            na = 1 - na;

13.6k

            break;

7.32k

        case 3:

7.32k

            ix2 = iw + ido;

7.32k

            if (na == 0)

                passf3((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw], &wa[ix2], isign);

7.23k

            else

7.23k

                passf3((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw], &wa[ix2], isign);

7.32k

            na = 1 - na;

7.32k

            break;

7.32k

        case 5:

7.32k

            ix2 = iw + ido;

7.32k

            ix3 = ix2 + ido;

7.32k

            ix4 = ix3 + ido;

7.32k

            if (na == 0)

7.23k

                passf5((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)c, ch, &wa[iw], &wa[ix2], &wa[ix3], &wa[ix4], isign);

            else

                passf5((const uint16_t)ido, (const uint16_t)l1, (const complex_t*)ch, c, &wa[iw], &wa[ix2], &wa[ix3], &wa[ix4], isign);

7.32k

            na = 1 - na;

7.32k

            break;

69.7k

69.7k

        l1 = l2;

69.7k

        iw += (ip-1) * ido;

69.7k

14.0k

    if (na == 0)

        return;

6.76M

    for (i = 0; i < n; i++)

6.75M

6.75M

        RE(c[i]) = RE(ch[i]);

6.75M

        IM(c[i]) = IM(ch[i]);

6.75M

13.6k

void cfftf(cfft_info *cfft, complex_t *c)

14.0k

14.0k

    cfftf1neg(cfft->n, c, cfft->work, (const uint16_t*)cfft->ifac, (const complex_t*)cfft->tab, -1);

14.0k

void cfftb(cfft_info *cfft, complex_t *c)

1.17M

1.17M

    cfftf1pos(cfft->n, c, cfft->work, (const uint16_t*)cfft->ifac, (const complex_t*)cfft->tab, +1);

1.17M

static void cffti1(uint16_t n, complex_t *wa, uint16_t *ifac)

71.2k

71.2k

    static uint16_t ntryh[4] = {3, 4, 2, 5};

#ifndef FIXED_POINT

    real_t arg, argh, argld, fi;

    uint16_t ido, ipm;

    uint16_t i1, k1, l1, l2;

    uint16_t ld, ii, ip;

#endif

71.2k

    uint16_t ntry = 0, i, j;

71.2k

    uint16_t ib;

71.2k

    uint16_t nf, nl, nq, nr;

71.2k

    nl = n;

71.2k

    nf = 0;

71.2k

    j = 0;

193k

startloop:

193k

    j++;

193k

    if (j <= 4)

193k

        ntry = ntryh[j-1];

    else

        ntry += 2;

193k

do

406k

406k

        nq = nl / ntry;

406k

        nr = nl - ntry*nq;

406k

        if (nr != 0)

122k

            goto startloop;

284k

        nf++;

284k

        ifac[nf+1] = ntry;

284k

        nl = nq;

284k

        if (ntry == 2 && nf != 1)

27.1k

129k

            for (i = 2; i <= nf; i++)

102k

102k

                ib = nf - i + 2;

102k

                ifac[ib+1] = ifac[ib];

102k

27.1k

            ifac[2] = 2;

27.1k

284k

    } while (nl != 1);

71.2k

    ifac[0] = n;

71.2k

    ifac[1] = nf;

#ifndef FIXED_POINT

    argh = (real_t)2.0*(real_t)M_PI / (real_t)n;

    i = 0;

    l1 = 1;

212k

    for (k1 = 1; k1 <= nf; k1++)

169k

169k

        ip = ifac[k1+1];

169k

        ld = 0;

169k

        l2 = l1*ip;

169k

        ido = n / l2;

169k

        ipm = ip - 1;

645k

        for (j = 0; j < ipm; j++)

475k

475k

            i1 = i;

475k

            RE(wa[i]) = 1.0;

475k

            IM(wa[i]) = 0.0;

            ld += l1;

            fi = 0;

            argld = ld*argh;

12.2M

            for (ii = 0; ii < ido; ii++)

11.7M

11.7M

                i++;

11.7M

                fi++;

11.7M

                arg = fi * argld;

11.7M

                RE(wa[i]) = (real_t)cos(arg);

11.7M

#if 1

11.7M

                IM(wa[i]) = (real_t)sin(arg);

#else

                IM(wa[i]) = (real_t)-sin(arg);

#endif

11.7M

475k

            if (ip > 5)

                RE(wa[i1]) = RE(wa[i]);

                IM(wa[i1]) = IM(wa[i]);

475k

169k

        l1 = l2;

169k

#else  // FIXED_POINT

    (void)wa;  /* whoa! does it work for FIXED_POINT? */

#endif

71.2k

cfft.c:cffti1

Line	Count	Source
907	28.7k	{
908	28.7k	static uint16_t ntryh[4] = {3, 4, 2, 5};
909		#ifndef FIXED_POINT
910		real_t arg, argh, argld, fi;
911		uint16_t ido, ipm;
912		uint16_t i1, k1, l1, l2;
913		uint16_t ld, ii, ip;
914		#endif
915	28.7k	uint16_t ntry = 0, i, j;
916	28.7k	uint16_t ib;
917	28.7k	uint16_t nf, nl, nq, nr;
918
919	28.7k	nl = n;
920	28.7k	nf = 0;
921	28.7k	j = 0;
922
923	77.2k	startloop:
924	77.2k	j++;
925
926	77.2k	if (j <= 4)
927	77.2k	ntry = ntryh[j-1];
928	0	else
929	0	ntry += 2;
930
931	77.2k	do
932	163k	{
933	163k	nq = nl / ntry;
934	163k	nr = nl - ntry*nq;
935
936	163k	if (nr != 0)
937	48.5k	goto startloop;
938
939	114k	nf++;
940	114k	ifac[nf+1] = ntry;
941	114k	nl = nq;
942
943	114k	if (ntry == 2 && nf != 1)
944	10.1k	{
945	48.5k	for (i = 2; i <= nf; i++)
946	38.4k	{
947	38.4k	ib = nf - i + 2;
948	38.4k	ifac[ib+1] = ifac[ib];
949	38.4k	}
950	10.1k	ifac[2] = 2;
951	10.1k	}
952	114k	} while (nl != 1);
953
954	28.7k	ifac[0] = n;
955	28.7k	ifac[1] = nf;
956
957		#ifndef FIXED_POINT
958		argh = (real_t)2.0*(real_t)M_PI / (real_t)n;
959		i = 0;
960		l1 = 1;
961
962		for (k1 = 1; k1 <= nf; k1++)
963		{
964		ip = ifac[k1+1];
965		ld = 0;
966		l2 = l1*ip;
967		ido = n / l2;
968		ipm = ip - 1;
969
970		for (j = 0; j < ipm; j++)
971		{
972		i1 = i;
973		RE(wa[i]) = 1.0;
974		IM(wa[i]) = 0.0;
975		ld += l1;
976		fi = 0;
977		argld = ld*argh;
978
979		for (ii = 0; ii < ido; ii++)
980		{
981		i++;
982		fi++;
983		arg = fi * argld;
984		RE(wa[i]) = (real_t)cos(arg);
985		#if 1
986		IM(wa[i]) = (real_t)sin(arg);
987		#else
988		IM(wa[i]) = (real_t)-sin(arg);
989		#endif
990		}
991
992		if (ip > 5)
993		{
994		RE(wa[i1]) = RE(wa[i]);
995		IM(wa[i1]) = IM(wa[i]);
996		}
997		}
998		l1 = l2;
999		}
1000		#else // FIXED_POINT
1001	28.7k	(void)wa; /* whoa! does it work for FIXED_POINT? */
1002	28.7k	#endif
1003	28.7k	}

cfft.c:cffti1

Line	Count	Source
907	42.4k	{
908	42.4k	static uint16_t ntryh[4] = {3, 4, 2, 5};
909	42.4k	#ifndef FIXED_POINT
910	42.4k	real_t arg, argh, argld, fi;
911	42.4k	uint16_t ido, ipm;
912	42.4k	uint16_t i1, k1, l1, l2;
913	42.4k	uint16_t ld, ii, ip;
914	42.4k	#endif
915	42.4k	uint16_t ntry = 0, i, j;
916	42.4k	uint16_t ib;
917	42.4k	uint16_t nf, nl, nq, nr;
918
919	42.4k	nl = n;
920	42.4k	nf = 0;
921	42.4k	j = 0;
922
923	116k	startloop:
924	116k	j++;
925
926	116k	if (j <= 4)
927	116k	ntry = ntryh[j-1];
928	0	else
929	0	ntry += 2;
930
931	116k	do
932	243k	{
933	243k	nq = nl / ntry;
934	243k	nr = nl - ntry*nq;
935
936	243k	if (nr != 0)
937	73.6k	goto startloop;
938
939	169k	nf++;
940	169k	ifac[nf+1] = ntry;
941	169k	nl = nq;
942
943	169k	if (ntry == 2 && nf != 1)
944	16.9k	{
945	81.2k	for (i = 2; i <= nf; i++)
946	64.2k	{
947	64.2k	ib = nf - i + 2;
948	64.2k	ifac[ib+1] = ifac[ib];
949	64.2k	}
950	16.9k	ifac[2] = 2;
951	16.9k	}
952	169k	} while (nl != 1);
953
954	42.4k	ifac[0] = n;
955	42.4k	ifac[1] = nf;
956
957	42.4k	#ifndef FIXED_POINT
958	42.4k	argh = (real_t)2.0*(real_t)M_PI / (real_t)n;
959	42.4k	i = 0;
960	42.4k	l1 = 1;
961
962	212k	for (k1 = 1; k1 <= nf; k1++)
963	169k	{
964	169k	ip = ifac[k1+1];
965	169k	ld = 0;
966	169k	l2 = l1*ip;
967	169k	ido = n / l2;
968	169k	ipm = ip - 1;
969
970	645k	for (j = 0; j < ipm; j++)
971	475k	{
972	475k	i1 = i;
973	475k	RE(wa[i]) = 1.0;
974	475k	IM(wa[i]) = 0.0;
975	475k	ld += l1;
976	475k	fi = 0;
977	475k	argld = ld*argh;
978
979	12.2M	for (ii = 0; ii < ido; ii++)
980	11.7M	{
981	11.7M	i++;
982	11.7M	fi++;
983	11.7M	arg = fi * argld;
984	11.7M	RE(wa[i]) = (real_t)cos(arg);
985	11.7M	#if 1
986	11.7M	IM(wa[i]) = (real_t)sin(arg);
987		#else
988		IM(wa[i]) = (real_t)-sin(arg);
989		#endif
990	11.7M	}
991
992	475k	if (ip > 5)
993	0	{
994	0	RE(wa[i1]) = RE(wa[i]);
995	0	IM(wa[i1]) = IM(wa[i]);
996	0	}
997	475k	}
998	169k	l1 = l2;
999	169k	}
1000		#else // FIXED_POINT
1001		(void)wa; /* whoa! does it work for FIXED_POINT? */
1002		#endif
1003	42.4k	}

cfft_info *cffti(uint16_t n)

3.37k

3.37k

    cfft_info *cfft = (cfft_info*)faad_malloc(sizeof(cfft_info));

3.37k

    cfft->n = n;

3.37k

    cfft->work = (complex_t*)faad_malloc(n*sizeof(complex_t));

#ifndef FIXED_POINT

    cfft->tab = (complex_t*)faad_malloc(n*sizeof(complex_t));

    cffti1(n, cfft->tab, cfft->ifac);

#else

3.37k

    cffti1(n, NULL, cfft->ifac);

3.37k

    switch (n)

3.37k

1.11k

    case 64: cfft->tab = (complex_t*)cfft_tab_64; break;

1.11k

    case 512: cfft->tab = (complex_t*)cfft_tab_512; break;

#ifdef LD_DEC

    case 256: cfft->tab = (complex_t*)cfft_tab_256; break;

#endif

#ifdef ALLOW_SMALL_FRAMELENGTH

    case 60: cfft->tab = (complex_t*)cfft_tab_60; break;

    case 480: cfft->tab = (complex_t*)cfft_tab_480; break;

#ifdef LD_DEC

    case 240: cfft->tab = (complex_t*)cfft_tab_240; break;

#endif

#endif

    case 128: cfft->tab = (complex_t*)cfft_tab_128; break;

3.37k

3.37k

#endif

3.37k

    return cfft;

3.37k

void cfftu(cfft_info *cfft)

28.7k

28.7k

    if (cfft->work) faad_free(cfft->work);

#ifndef FIXED_POINT

    if (cfft->tab) faad_free(cfft->tab);

#endif

28.7k

    if (cfft) faad_free(cfft);

28.7k

Coverage Report

Created: 2025-11-24 06:22