Store effects in an array of lists
[openal-soft.git] / utils / makehrtf.c
blob417b99447a70f68584654d3ca6cb3edb075fb2e5
1 /*
2 * HRTF utility for producing and demonstrating the process of creating an
3 * OpenAL Soft compatible HRIR data set.
5 * Copyright (C) 2011-2017 Christopher Fitzgerald
7 * This program is free software; you can redistribute it and/or modify
8 * it under the terms of the GNU General Public License as published by
9 * the Free Software Foundation; either version 2 of the License, or
10 * (at your option) any later version.
12 * This program is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 * GNU General Public License for more details.
17 * You should have received a copy of the GNU General Public License along
18 * with this program; if not, write to the Free Software Foundation, Inc.,
19 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
21 * Or visit: http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
23 * --------------------------------------------------------------------------
25 * A big thanks goes out to all those whose work done in the field of
26 * binaural sound synthesis using measured HRTFs makes this utility and the
27 * OpenAL Soft implementation possible.
29 * The algorithm for diffuse-field equalization was adapted from the work
30 * done by Rio Emmanuel and Larcher Veronique of IRCAM and Bill Gardner of
31 * MIT Media Laboratory. It operates as follows:
33 * 1. Take the FFT of each HRIR and only keep the magnitude responses.
34 * 2. Calculate the diffuse-field power-average of all HRIRs weighted by
35 * their contribution to the total surface area covered by their
36 * measurement.
37 * 3. Take the diffuse-field average and limit its magnitude range.
38 * 4. Equalize the responses by using the inverse of the diffuse-field
39 * average.
40 * 5. Reconstruct the minimum-phase responses.
41 * 5. Zero the DC component.
42 * 6. IFFT the result and truncate to the desired-length minimum-phase FIR.
44 * The spherical head algorithm for calculating propagation delay was adapted
45 * from the paper:
47 * Modeling Interaural Time Difference Assuming a Spherical Head
48 * Joel David Miller
49 * Music 150, Musical Acoustics, Stanford University
50 * December 2, 2001
52 * The formulae for calculating the Kaiser window metrics are from the
53 * the textbook:
55 * Discrete-Time Signal Processing
56 * Alan V. Oppenheim and Ronald W. Schafer
57 * Prentice-Hall Signal Processing Series
58 * 1999
61 #include "config.h"
63 #define _UNICODE
64 #include <stdio.h>
65 #include <stdlib.h>
66 #include <stdarg.h>
67 #include <stddef.h>
68 #include <string.h>
69 #include <limits.h>
70 #include <ctype.h>
71 #include <math.h>
72 #ifdef HAVE_STRINGS_H
73 #include <strings.h>
74 #endif
75 #ifdef HAVE_GETOPT
76 #include <unistd.h>
77 #else
78 #include "getopt.h"
79 #endif
81 #include "win_main_utf8.h"
83 /* Define int64_t and uint64_t types */
84 #if defined(__STDC_VERSION__) && __STDC_VERSION__ >= 199901L
85 #include <inttypes.h>
86 #elif defined(_WIN32) && defined(__GNUC__)
87 #include <stdint.h>
88 #elif defined(_WIN32)
89 typedef __int64 int64_t;
90 typedef unsigned __int64 uint64_t;
91 #else
92 /* Fallback if nothing above works */
93 #include <inttypes.h>
94 #endif
96 #ifndef M_PI
97 #define M_PI (3.14159265358979323846)
98 #endif
100 #ifndef HUGE_VAL
101 #define HUGE_VAL (1.0 / 0.0)
102 #endif
105 // The epsilon used to maintain signal stability.
106 #define EPSILON (1e-9)
108 // Constants for accessing the token reader's ring buffer.
109 #define TR_RING_BITS (16)
110 #define TR_RING_SIZE (1 << TR_RING_BITS)
111 #define TR_RING_MASK (TR_RING_SIZE - 1)
113 // The token reader's load interval in bytes.
114 #define TR_LOAD_SIZE (TR_RING_SIZE >> 2)
116 // The maximum identifier length used when processing the data set
117 // definition.
118 #define MAX_IDENT_LEN (16)
120 // The maximum path length used when processing filenames.
121 #define MAX_PATH_LEN (256)
123 // The limits for the sample 'rate' metric in the data set definition and for
124 // resampling.
125 #define MIN_RATE (32000)
126 #define MAX_RATE (96000)
128 // The limits for the HRIR 'points' metric in the data set definition.
129 #define MIN_POINTS (16)
130 #define MAX_POINTS (8192)
132 // The limit to the number of 'distances' listed in the data set definition.
133 #define MAX_FD_COUNT (16)
135 // The limits to the number of 'azimuths' listed in the data set definition.
136 #define MIN_EV_COUNT (5)
137 #define MAX_EV_COUNT (128)
139 // The limits for each of the 'azimuths' listed in the data set definition.
140 #define MIN_AZ_COUNT (1)
141 #define MAX_AZ_COUNT (128)
143 // The limits for the listener's head 'radius' in the data set definition.
144 #define MIN_RADIUS (0.05)
145 #define MAX_RADIUS (0.15)
147 // The limits for the 'distance' from source to listener for each field in
148 // the definition file.
149 #define MIN_DISTANCE (0.05)
150 #define MAX_DISTANCE (2.50)
152 // The maximum number of channels that can be addressed for a WAVE file
153 // source listed in the data set definition.
154 #define MAX_WAVE_CHANNELS (65535)
156 // The limits to the byte size for a binary source listed in the definition
157 // file.
158 #define MIN_BIN_SIZE (2)
159 #define MAX_BIN_SIZE (4)
161 // The minimum number of significant bits for binary sources listed in the
162 // data set definition. The maximum is calculated from the byte size.
163 #define MIN_BIN_BITS (16)
165 // The limits to the number of significant bits for an ASCII source listed in
166 // the data set definition.
167 #define MIN_ASCII_BITS (16)
168 #define MAX_ASCII_BITS (32)
170 // The limits to the FFT window size override on the command line.
171 #define MIN_FFTSIZE (65536)
172 #define MAX_FFTSIZE (131072)
174 // The limits to the equalization range limit on the command line.
175 #define MIN_LIMIT (2.0)
176 #define MAX_LIMIT (120.0)
178 // The limits to the truncation window size on the command line.
179 #define MIN_TRUNCSIZE (16)
180 #define MAX_TRUNCSIZE (512)
182 // The limits to the custom head radius on the command line.
183 #define MIN_CUSTOM_RADIUS (0.05)
184 #define MAX_CUSTOM_RADIUS (0.15)
186 // The truncation window size must be a multiple of the below value to allow
187 // for vectorized convolution.
188 #define MOD_TRUNCSIZE (8)
190 // The defaults for the command line options.
191 #define DEFAULT_FFTSIZE (65536)
192 #define DEFAULT_EQUALIZE (1)
193 #define DEFAULT_SURFACE (1)
194 #define DEFAULT_LIMIT (24.0)
195 #define DEFAULT_TRUNCSIZE (32)
196 #define DEFAULT_HEAD_MODEL (HM_DATASET)
197 #define DEFAULT_CUSTOM_RADIUS (0.0)
199 // The four-character-codes for RIFF/RIFX WAVE file chunks.
200 #define FOURCC_RIFF (0x46464952) // 'RIFF'
201 #define FOURCC_RIFX (0x58464952) // 'RIFX'
202 #define FOURCC_WAVE (0x45564157) // 'WAVE'
203 #define FOURCC_FMT (0x20746D66) // 'fmt '
204 #define FOURCC_DATA (0x61746164) // 'data'
205 #define FOURCC_LIST (0x5453494C) // 'LIST'
206 #define FOURCC_WAVL (0x6C766177) // 'wavl'
207 #define FOURCC_SLNT (0x746E6C73) // 'slnt'
209 // The supported wave formats.
210 #define WAVE_FORMAT_PCM (0x0001)
211 #define WAVE_FORMAT_IEEE_FLOAT (0x0003)
212 #define WAVE_FORMAT_EXTENSIBLE (0xFFFE)
214 // The maximum propagation delay value supported by OpenAL Soft.
215 #define MAX_HRTD (63.0)
217 // The OpenAL Soft HRTF format marker. It stands for minimum-phase head
218 // response protocol 02.
219 #define MHR_FORMAT ("MinPHR02")
221 // Sample and channel type enum values.
222 typedef enum SampleTypeT {
223 ST_S16 = 0,
224 ST_S24 = 1
225 } SampleTypeT;
227 // Certain iterations rely on these integer enum values.
228 typedef enum ChannelTypeT {
229 CT_NONE = -1,
230 CT_MONO = 0,
231 CT_STEREO = 1
232 } ChannelTypeT;
234 // Byte order for the serialization routines.
235 typedef enum ByteOrderT {
236 BO_NONE,
237 BO_LITTLE,
238 BO_BIG
239 } ByteOrderT;
241 // Source format for the references listed in the data set definition.
242 typedef enum SourceFormatT {
243 SF_NONE,
244 SF_WAVE, // RIFF/RIFX WAVE file.
245 SF_BIN_LE, // Little-endian binary file.
246 SF_BIN_BE, // Big-endian binary file.
247 SF_ASCII // ASCII text file.
248 } SourceFormatT;
250 // Element types for the references listed in the data set definition.
251 typedef enum ElementTypeT {
252 ET_NONE,
253 ET_INT, // Integer elements.
254 ET_FP // Floating-point elements.
255 } ElementTypeT;
257 // Head model used for calculating the impulse delays.
258 typedef enum HeadModelT {
259 HM_NONE,
260 HM_DATASET, // Measure the onset from the dataset.
261 HM_SPHERE // Calculate the onset using a spherical head model.
262 } HeadModelT;
264 // Unsigned integer type.
265 typedef unsigned int uint;
267 // Serialization types. The trailing digit indicates the number of bits.
268 typedef unsigned char uint8;
269 typedef int int32;
270 typedef unsigned int uint32;
271 typedef uint64_t uint64;
273 // Token reader state for parsing the data set definition.
274 typedef struct TokenReaderT {
275 FILE *mFile;
276 const char *mName;
277 uint mLine;
278 uint mColumn;
279 char mRing[TR_RING_SIZE];
280 size_t mIn;
281 size_t mOut;
282 } TokenReaderT;
284 // Source reference state used when loading sources.
285 typedef struct SourceRefT {
286 SourceFormatT mFormat;
287 ElementTypeT mType;
288 uint mSize;
289 int mBits;
290 uint mChannel;
291 uint mSkip;
292 uint mOffset;
293 char mPath[MAX_PATH_LEN+1];
294 } SourceRefT;
296 // Structured HRIR storage for stereo azimuth pairs, elevations, and fields.
297 typedef struct HrirAzT {
298 double mAzimuth;
299 uint mIndex;
300 double mDelays[2];
301 double *mIrs[2];
302 } HrirAzT;
304 typedef struct HrirEvT {
305 double mElevation;
306 uint mIrCount;
307 uint mAzCount;
308 HrirAzT *mAzs;
309 } HrirEvT;
311 typedef struct HrirFdT {
312 double mDistance;
313 uint mIrCount;
314 uint mEvCount;
315 uint mEvStart;
316 HrirEvT *mEvs;
317 } HrirFdT;
319 // The HRIR metrics and data set used when loading, processing, and storing
320 // the resulting HRTF.
321 typedef struct HrirDataT {
322 uint mIrRate;
323 SampleTypeT mSampleType;
324 ChannelTypeT mChannelType;
325 uint mIrPoints;
326 uint mFftSize;
327 uint mIrSize;
328 double mRadius;
329 uint mIrCount;
330 uint mFdCount;
331 HrirFdT *mFds;
332 } HrirDataT;
334 // The resampler metrics and FIR filter.
335 typedef struct ResamplerT {
336 uint mP, mQ, mM, mL;
337 double *mF;
338 } ResamplerT;
341 /****************************************
342 *** Complex number type and routines ***
343 ****************************************/
345 typedef struct {
346 double Real, Imag;
347 } Complex;
349 static Complex MakeComplex(double r, double i)
351 Complex c = { r, i };
352 return c;
355 static Complex c_add(Complex a, Complex b)
357 Complex r;
358 r.Real = a.Real + b.Real;
359 r.Imag = a.Imag + b.Imag;
360 return r;
363 static Complex c_sub(Complex a, Complex b)
365 Complex r;
366 r.Real = a.Real - b.Real;
367 r.Imag = a.Imag - b.Imag;
368 return r;
371 static Complex c_mul(Complex a, Complex b)
373 Complex r;
374 r.Real = a.Real*b.Real - a.Imag*b.Imag;
375 r.Imag = a.Imag*b.Real + a.Real*b.Imag;
376 return r;
379 static Complex c_muls(Complex a, double s)
381 Complex r;
382 r.Real = a.Real * s;
383 r.Imag = a.Imag * s;
384 return r;
387 static double c_abs(Complex a)
389 return sqrt(a.Real*a.Real + a.Imag*a.Imag);
392 static Complex c_exp(Complex a)
394 Complex r;
395 double e = exp(a.Real);
396 r.Real = e * cos(a.Imag);
397 r.Imag = e * sin(a.Imag);
398 return r;
401 /*****************************
402 *** Token reader routines ***
403 *****************************/
405 /* Whitespace is not significant. It can process tokens as identifiers, numbers
406 * (integer and floating-point), strings, and operators. Strings must be
407 * encapsulated by double-quotes and cannot span multiple lines.
410 // Setup the reader on the given file. The filename can be NULL if no error
411 // output is desired.
412 static void TrSetup(FILE *fp, const char *filename, TokenReaderT *tr)
414 const char *name = NULL;
416 if(filename)
418 const char *slash = strrchr(filename, '/');
419 if(slash)
421 const char *bslash = strrchr(slash+1, '\\');
422 if(bslash) name = bslash+1;
423 else name = slash+1;
425 else
427 const char *bslash = strrchr(filename, '\\');
428 if(bslash) name = bslash+1;
429 else name = filename;
433 tr->mFile = fp;
434 tr->mName = name;
435 tr->mLine = 1;
436 tr->mColumn = 1;
437 tr->mIn = 0;
438 tr->mOut = 0;
441 // Prime the reader's ring buffer, and return a result indicating that there
442 // is text to process.
443 static int TrLoad(TokenReaderT *tr)
445 size_t toLoad, in, count;
447 toLoad = TR_RING_SIZE - (tr->mIn - tr->mOut);
448 if(toLoad >= TR_LOAD_SIZE && !feof(tr->mFile))
450 // Load TR_LOAD_SIZE (or less if at the end of the file) per read.
451 toLoad = TR_LOAD_SIZE;
452 in = tr->mIn&TR_RING_MASK;
453 count = TR_RING_SIZE - in;
454 if(count < toLoad)
456 tr->mIn += fread(&tr->mRing[in], 1, count, tr->mFile);
457 tr->mIn += fread(&tr->mRing[0], 1, toLoad-count, tr->mFile);
459 else
460 tr->mIn += fread(&tr->mRing[in], 1, toLoad, tr->mFile);
462 if(tr->mOut >= TR_RING_SIZE)
464 tr->mOut -= TR_RING_SIZE;
465 tr->mIn -= TR_RING_SIZE;
468 if(tr->mIn > tr->mOut)
469 return 1;
470 return 0;
473 // Error display routine. Only displays when the base name is not NULL.
474 static void TrErrorVA(const TokenReaderT *tr, uint line, uint column, const char *format, va_list argPtr)
476 if(!tr->mName)
477 return;
478 fprintf(stderr, "Error (%s:%u:%u): ", tr->mName, line, column);
479 vfprintf(stderr, format, argPtr);
482 // Used to display an error at a saved line/column.
483 static void TrErrorAt(const TokenReaderT *tr, uint line, uint column, const char *format, ...)
485 va_list argPtr;
487 va_start(argPtr, format);
488 TrErrorVA(tr, line, column, format, argPtr);
489 va_end(argPtr);
492 // Used to display an error at the current line/column.
493 static void TrError(const TokenReaderT *tr, const char *format, ...)
495 va_list argPtr;
497 va_start(argPtr, format);
498 TrErrorVA(tr, tr->mLine, tr->mColumn, format, argPtr);
499 va_end(argPtr);
502 // Skips to the next line.
503 static void TrSkipLine(TokenReaderT *tr)
505 char ch;
507 while(TrLoad(tr))
509 ch = tr->mRing[tr->mOut&TR_RING_MASK];
510 tr->mOut++;
511 if(ch == '\n')
513 tr->mLine++;
514 tr->mColumn = 1;
515 break;
517 tr->mColumn ++;
521 // Skips to the next token.
522 static int TrSkipWhitespace(TokenReaderT *tr)
524 char ch;
526 while(TrLoad(tr))
528 ch = tr->mRing[tr->mOut&TR_RING_MASK];
529 if(isspace(ch))
531 tr->mOut++;
532 if(ch == '\n')
534 tr->mLine++;
535 tr->mColumn = 1;
537 else
538 tr->mColumn++;
540 else if(ch == '#')
541 TrSkipLine(tr);
542 else
543 return 1;
545 return 0;
548 // Get the line and/or column of the next token (or the end of input).
549 static void TrIndication(TokenReaderT *tr, uint *line, uint *column)
551 TrSkipWhitespace(tr);
552 if(line) *line = tr->mLine;
553 if(column) *column = tr->mColumn;
556 // Checks to see if a token is (likely to be) an identifier. It does not
557 // display any errors and will not proceed to the next token.
558 static int TrIsIdent(TokenReaderT *tr)
560 char ch;
562 if(!TrSkipWhitespace(tr))
563 return 0;
564 ch = tr->mRing[tr->mOut&TR_RING_MASK];
565 return ch == '_' || isalpha(ch);
569 // Checks to see if a token is the given operator. It does not display any
570 // errors and will not proceed to the next token.
571 static int TrIsOperator(TokenReaderT *tr, const char *op)
573 size_t out, len;
574 char ch;
576 if(!TrSkipWhitespace(tr))
577 return 0;
578 out = tr->mOut;
579 len = 0;
580 while(op[len] != '\0' && out < tr->mIn)
582 ch = tr->mRing[out&TR_RING_MASK];
583 if(ch != op[len]) break;
584 len++;
585 out++;
587 if(op[len] == '\0')
588 return 1;
589 return 0;
592 /* The TrRead*() routines obtain the value of a matching token type. They
593 * display type, form, and boundary errors and will proceed to the next
594 * token.
597 // Reads and validates an identifier token.
598 static int TrReadIdent(TokenReaderT *tr, const uint maxLen, char *ident)
600 uint col, len;
601 char ch;
603 col = tr->mColumn;
604 if(TrSkipWhitespace(tr))
606 col = tr->mColumn;
607 ch = tr->mRing[tr->mOut&TR_RING_MASK];
608 if(ch == '_' || isalpha(ch))
610 len = 0;
611 do {
612 if(len < maxLen)
613 ident[len] = ch;
614 len++;
615 tr->mOut++;
616 if(!TrLoad(tr))
617 break;
618 ch = tr->mRing[tr->mOut&TR_RING_MASK];
619 } while(ch == '_' || isdigit(ch) || isalpha(ch));
621 tr->mColumn += len;
622 if(len < maxLen)
624 ident[len] = '\0';
625 return 1;
627 TrErrorAt(tr, tr->mLine, col, "Identifier is too long.\n");
628 return 0;
631 TrErrorAt(tr, tr->mLine, col, "Expected an identifier.\n");
632 return 0;
635 // Reads and validates (including bounds) an integer token.
636 static int TrReadInt(TokenReaderT *tr, const int loBound, const int hiBound, int *value)
638 uint col, digis, len;
639 char ch, temp[64+1];
641 col = tr->mColumn;
642 if(TrSkipWhitespace(tr))
644 col = tr->mColumn;
645 len = 0;
646 ch = tr->mRing[tr->mOut&TR_RING_MASK];
647 if(ch == '+' || ch == '-')
649 temp[len] = ch;
650 len++;
651 tr->mOut++;
653 digis = 0;
654 while(TrLoad(tr))
656 ch = tr->mRing[tr->mOut&TR_RING_MASK];
657 if(!isdigit(ch)) break;
658 if(len < 64)
659 temp[len] = ch;
660 len++;
661 digis++;
662 tr->mOut++;
664 tr->mColumn += len;
665 if(digis > 0 && ch != '.' && !isalpha(ch))
667 if(len > 64)
669 TrErrorAt(tr, tr->mLine, col, "Integer is too long.");
670 return 0;
672 temp[len] = '\0';
673 *value = strtol(temp, NULL, 10);
674 if(*value < loBound || *value > hiBound)
676 TrErrorAt(tr, tr->mLine, col, "Expected a value from %d to %d.\n", loBound, hiBound);
677 return 0;
679 return 1;
682 TrErrorAt(tr, tr->mLine, col, "Expected an integer.\n");
683 return 0;
686 // Reads and validates (including bounds) a float token.
687 static int TrReadFloat(TokenReaderT *tr, const double loBound, const double hiBound, double *value)
689 uint col, digis, len;
690 char ch, temp[64+1];
692 col = tr->mColumn;
693 if(TrSkipWhitespace(tr))
695 col = tr->mColumn;
696 len = 0;
697 ch = tr->mRing[tr->mOut&TR_RING_MASK];
698 if(ch == '+' || ch == '-')
700 temp[len] = ch;
701 len++;
702 tr->mOut++;
705 digis = 0;
706 while(TrLoad(tr))
708 ch = tr->mRing[tr->mOut&TR_RING_MASK];
709 if(!isdigit(ch)) break;
710 if(len < 64)
711 temp[len] = ch;
712 len++;
713 digis++;
714 tr->mOut++;
716 if(ch == '.')
718 if(len < 64)
719 temp[len] = ch;
720 len++;
721 tr->mOut++;
723 while(TrLoad(tr))
725 ch = tr->mRing[tr->mOut&TR_RING_MASK];
726 if(!isdigit(ch)) break;
727 if(len < 64)
728 temp[len] = ch;
729 len++;
730 digis++;
731 tr->mOut++;
733 if(digis > 0)
735 if(ch == 'E' || ch == 'e')
737 if(len < 64)
738 temp[len] = ch;
739 len++;
740 digis = 0;
741 tr->mOut++;
742 if(ch == '+' || ch == '-')
744 if(len < 64)
745 temp[len] = ch;
746 len++;
747 tr->mOut++;
749 while(TrLoad(tr))
751 ch = tr->mRing[tr->mOut&TR_RING_MASK];
752 if(!isdigit(ch)) break;
753 if(len < 64)
754 temp[len] = ch;
755 len++;
756 digis++;
757 tr->mOut++;
760 tr->mColumn += len;
761 if(digis > 0 && ch != '.' && !isalpha(ch))
763 if(len > 64)
765 TrErrorAt(tr, tr->mLine, col, "Float is too long.");
766 return 0;
768 temp[len] = '\0';
769 *value = strtod(temp, NULL);
770 if(*value < loBound || *value > hiBound)
772 TrErrorAt(tr, tr->mLine, col, "Expected a value from %f to %f.\n", loBound, hiBound);
773 return 0;
775 return 1;
778 else
779 tr->mColumn += len;
781 TrErrorAt(tr, tr->mLine, col, "Expected a float.\n");
782 return 0;
785 // Reads and validates a string token.
786 static int TrReadString(TokenReaderT *tr, const uint maxLen, char *text)
788 uint col, len;
789 char ch;
791 col = tr->mColumn;
792 if(TrSkipWhitespace(tr))
794 col = tr->mColumn;
795 ch = tr->mRing[tr->mOut&TR_RING_MASK];
796 if(ch == '\"')
798 tr->mOut++;
799 len = 0;
800 while(TrLoad(tr))
802 ch = tr->mRing[tr->mOut&TR_RING_MASK];
803 tr->mOut++;
804 if(ch == '\"')
805 break;
806 if(ch == '\n')
808 TrErrorAt(tr, tr->mLine, col, "Unterminated string at end of line.\n");
809 return 0;
811 if(len < maxLen)
812 text[len] = ch;
813 len++;
815 if(ch != '\"')
817 tr->mColumn += 1 + len;
818 TrErrorAt(tr, tr->mLine, col, "Unterminated string at end of input.\n");
819 return 0;
821 tr->mColumn += 2 + len;
822 if(len > maxLen)
824 TrErrorAt(tr, tr->mLine, col, "String is too long.\n");
825 return 0;
827 text[len] = '\0';
828 return 1;
831 TrErrorAt(tr, tr->mLine, col, "Expected a string.\n");
832 return 0;
835 // Reads and validates the given operator.
836 static int TrReadOperator(TokenReaderT *tr, const char *op)
838 uint col, len;
839 char ch;
841 col = tr->mColumn;
842 if(TrSkipWhitespace(tr))
844 col = tr->mColumn;
845 len = 0;
846 while(op[len] != '\0' && TrLoad(tr))
848 ch = tr->mRing[tr->mOut&TR_RING_MASK];
849 if(ch != op[len]) break;
850 len++;
851 tr->mOut++;
853 tr->mColumn += len;
854 if(op[len] == '\0')
855 return 1;
857 TrErrorAt(tr, tr->mLine, col, "Expected '%s' operator.\n", op);
858 return 0;
861 /* Performs a string substitution. Any case-insensitive occurrences of the
862 * pattern string are replaced with the replacement string. The result is
863 * truncated if necessary.
865 static int StrSubst(const char *in, const char *pat, const char *rep, const size_t maxLen, char *out)
867 size_t inLen, patLen, repLen;
868 size_t si, di;
869 int truncated;
871 inLen = strlen(in);
872 patLen = strlen(pat);
873 repLen = strlen(rep);
874 si = 0;
875 di = 0;
876 truncated = 0;
877 while(si < inLen && di < maxLen)
879 if(patLen <= inLen-si)
881 if(strncasecmp(&in[si], pat, patLen) == 0)
883 if(repLen > maxLen-di)
885 repLen = maxLen - di;
886 truncated = 1;
888 strncpy(&out[di], rep, repLen);
889 si += patLen;
890 di += repLen;
893 out[di] = in[si];
894 si++;
895 di++;
897 if(si < inLen)
898 truncated = 1;
899 out[di] = '\0';
900 return !truncated;
904 /*********************
905 *** Math routines ***
906 *********************/
908 // Provide missing math routines for MSVC versions < 1800 (Visual Studio 2013).
909 #if defined(_MSC_VER) && _MSC_VER < 1800
910 static double round(double val)
912 if(val < 0.0)
913 return ceil(val-0.5);
914 return floor(val+0.5);
917 static double fmin(double a, double b)
919 return (a<b) ? a : b;
922 static double fmax(double a, double b)
924 return (a>b) ? a : b;
926 #endif
928 // Simple clamp routine.
929 static double Clamp(const double val, const double lower, const double upper)
931 return fmin(fmax(val, lower), upper);
934 // Performs linear interpolation.
935 static double Lerp(const double a, const double b, const double f)
937 return a + f * (b - a);
940 static inline uint dither_rng(uint *seed)
942 *seed = *seed * 96314165 + 907633515;
943 return *seed;
946 // Performs a triangular probability density function dither. The input samples
947 // should be normalized (-1 to +1).
948 static void TpdfDither(double *restrict out, const double *restrict in, const double scale,
949 const int count, const int step, uint *seed)
951 static const double PRNG_SCALE = 1.0 / UINT_MAX;
952 uint prn0, prn1;
953 int i;
955 for(i = 0;i < count;i++)
957 prn0 = dither_rng(seed);
958 prn1 = dither_rng(seed);
959 out[i*step] = round(in[i]*scale + (prn0*PRNG_SCALE - prn1*PRNG_SCALE));
963 // Allocates an array of doubles.
964 static double *CreateDoubles(size_t n)
966 double *a;
968 a = calloc(n?n:1, sizeof(*a));
969 if(a == NULL)
971 fprintf(stderr, "Error: Out of memory.\n");
972 exit(-1);
974 return a;
977 // Allocates an array of complex numbers.
978 static Complex *CreateComplexes(size_t n)
980 Complex *a;
982 a = calloc(n?n:1, sizeof(*a));
983 if(a == NULL)
985 fprintf(stderr, "Error: Out of memory.\n");
986 exit(-1);
988 return a;
991 /* Fast Fourier transform routines. The number of points must be a power of
992 * two. In-place operation is possible only if both the real and imaginary
993 * parts are in-place together.
996 // Performs bit-reversal ordering.
997 static void FftArrange(const uint n, const Complex *in, Complex *out)
999 uint rk, k, m;
1001 if(in == out)
1003 // Handle in-place arrangement.
1004 rk = 0;
1005 for(k = 0;k < n;k++)
1007 if(rk > k)
1009 Complex temp = in[rk];
1010 out[rk] = in[k];
1011 out[k] = temp;
1013 m = n;
1014 while(rk&(m >>= 1))
1015 rk &= ~m;
1016 rk |= m;
1019 else
1021 // Handle copy arrangement.
1022 rk = 0;
1023 for(k = 0;k < n;k++)
1025 out[rk] = in[k];
1026 m = n;
1027 while(rk&(m >>= 1))
1028 rk &= ~m;
1029 rk |= m;
1034 // Performs the summation.
1035 static void FftSummation(const int n, const double s, Complex *cplx)
1037 double pi;
1038 int m, m2;
1039 int i, k, mk;
1041 pi = s * M_PI;
1042 for(m = 1, m2 = 2;m < n; m <<= 1, m2 <<= 1)
1044 // v = Complex (-2.0 * sin (0.5 * pi / m) * sin (0.5 * pi / m), -sin (pi / m))
1045 double sm = sin(0.5 * pi / m);
1046 Complex v = MakeComplex(-2.0*sm*sm, -sin(pi / m));
1047 Complex w = MakeComplex(1.0, 0.0);
1048 for(i = 0;i < m;i++)
1050 for(k = i;k < n;k += m2)
1052 Complex t;
1053 mk = k + m;
1054 t = c_mul(w, cplx[mk]);
1055 cplx[mk] = c_sub(cplx[k], t);
1056 cplx[k] = c_add(cplx[k], t);
1058 w = c_add(w, c_mul(v, w));
1063 // Performs a forward FFT.
1064 static void FftForward(const uint n, const Complex *in, Complex *out)
1066 FftArrange(n, in, out);
1067 FftSummation(n, 1.0, out);
1070 // Performs an inverse FFT.
1071 static void FftInverse(const uint n, const Complex *in, Complex *out)
1073 double f;
1074 uint i;
1076 FftArrange(n, in, out);
1077 FftSummation(n, -1.0, out);
1078 f = 1.0 / n;
1079 for(i = 0;i < n;i++)
1080 out[i] = c_muls(out[i], f);
1083 /* Calculate the complex helical sequence (or discrete-time analytical signal)
1084 * of the given input using the Hilbert transform. Given the natural logarithm
1085 * of a signal's magnitude response, the imaginary components can be used as
1086 * the angles for minimum-phase reconstruction.
1088 static void Hilbert(const uint n, const Complex *in, Complex *out)
1090 uint i;
1092 if(in == out)
1094 // Handle in-place operation.
1095 for(i = 0;i < n;i++)
1096 out[i].Imag = 0.0;
1098 else
1100 // Handle copy operation.
1101 for(i = 0;i < n;i++)
1102 out[i] = MakeComplex(in[i].Real, 0.0);
1104 FftInverse(n, out, out);
1105 for(i = 1;i < (n+1)/2;i++)
1106 out[i] = c_muls(out[i], 2.0);
1107 /* Increment i if n is even. */
1108 i += (n&1)^1;
1109 for(;i < n;i++)
1110 out[i] = MakeComplex(0.0, 0.0);
1111 FftForward(n, out, out);
1114 /* Calculate the magnitude response of the given input. This is used in
1115 * place of phase decomposition, since the phase residuals are discarded for
1116 * minimum phase reconstruction. The mirrored half of the response is also
1117 * discarded.
1119 static void MagnitudeResponse(const uint n, const Complex *in, double *out)
1121 const uint m = 1 + (n / 2);
1122 uint i;
1123 for(i = 0;i < m;i++)
1124 out[i] = fmax(c_abs(in[i]), EPSILON);
1127 /* Apply a range limit (in dB) to the given magnitude response. This is used
1128 * to adjust the effects of the diffuse-field average on the equalization
1129 * process.
1131 static void LimitMagnitudeResponse(const uint n, const uint m, const double limit, const double *in, double *out)
1133 double halfLim;
1134 uint i, lower, upper;
1135 double ave;
1137 halfLim = limit / 2.0;
1138 // Convert the response to dB.
1139 for(i = 0;i < m;i++)
1140 out[i] = 20.0 * log10(in[i]);
1141 // Use six octaves to calculate the average magnitude of the signal.
1142 lower = ((uint)ceil(n / pow(2.0, 8.0))) - 1;
1143 upper = ((uint)floor(n / pow(2.0, 2.0))) - 1;
1144 ave = 0.0;
1145 for(i = lower;i <= upper;i++)
1146 ave += out[i];
1147 ave /= upper - lower + 1;
1148 // Keep the response within range of the average magnitude.
1149 for(i = 0;i < m;i++)
1150 out[i] = Clamp(out[i], ave - halfLim, ave + halfLim);
1151 // Convert the response back to linear magnitude.
1152 for(i = 0;i < m;i++)
1153 out[i] = pow(10.0, out[i] / 20.0);
1156 /* Reconstructs the minimum-phase component for the given magnitude response
1157 * of a signal. This is equivalent to phase recomposition, sans the missing
1158 * residuals (which were discarded). The mirrored half of the response is
1159 * reconstructed.
1161 static void MinimumPhase(const uint n, const double *in, Complex *out)
1163 const uint m = 1 + (n / 2);
1164 double *mags;
1165 uint i;
1167 mags = CreateDoubles(n);
1168 for(i = 0;i < m;i++)
1170 mags[i] = fmax(EPSILON, in[i]);
1171 out[i] = MakeComplex(log(mags[i]), 0.0);
1173 for(;i < n;i++)
1175 mags[i] = mags[n - i];
1176 out[i] = out[n - i];
1178 Hilbert(n, out, out);
1179 // Remove any DC offset the filter has.
1180 mags[0] = EPSILON;
1181 for(i = 0;i < n;i++)
1183 Complex a = c_exp(MakeComplex(0.0, out[i].Imag));
1184 out[i] = c_mul(MakeComplex(mags[i], 0.0), a);
1186 free(mags);
1190 /***************************
1191 *** Resampler functions ***
1192 ***************************/
1194 /* This is the normalized cardinal sine (sinc) function.
1196 * sinc(x) = { 1, x = 0
1197 * { sin(pi x) / (pi x), otherwise.
1199 static double Sinc(const double x)
1201 if(fabs(x) < EPSILON)
1202 return 1.0;
1203 return sin(M_PI * x) / (M_PI * x);
1206 /* The zero-order modified Bessel function of the first kind, used for the
1207 * Kaiser window.
1209 * I_0(x) = sum_{k=0}^inf (1 / k!)^2 (x / 2)^(2 k)
1210 * = sum_{k=0}^inf ((x / 2)^k / k!)^2
1212 static double BesselI_0(const double x)
1214 double term, sum, x2, y, last_sum;
1215 int k;
1217 // Start at k=1 since k=0 is trivial.
1218 term = 1.0;
1219 sum = 1.0;
1220 x2 = x/2.0;
1221 k = 1;
1223 // Let the integration converge until the term of the sum is no longer
1224 // significant.
1225 do {
1226 y = x2 / k;
1227 k++;
1228 last_sum = sum;
1229 term *= y * y;
1230 sum += term;
1231 } while(sum != last_sum);
1232 return sum;
1235 /* Calculate a Kaiser window from the given beta value and a normalized k
1236 * [-1, 1].
1238 * w(k) = { I_0(B sqrt(1 - k^2)) / I_0(B), -1 <= k <= 1
1239 * { 0, elsewhere.
1241 * Where k can be calculated as:
1243 * k = i / l, where -l <= i <= l.
1245 * or:
1247 * k = 2 i / M - 1, where 0 <= i <= M.
1249 static double Kaiser(const double b, const double k)
1251 if(!(k >= -1.0 && k <= 1.0))
1252 return 0.0;
1253 return BesselI_0(b * sqrt(1.0 - k*k)) / BesselI_0(b);
1256 // Calculates the greatest common divisor of a and b.
1257 static uint Gcd(uint x, uint y)
1259 while(y > 0)
1261 uint z = y;
1262 y = x % y;
1263 x = z;
1265 return x;
1268 /* Calculates the size (order) of the Kaiser window. Rejection is in dB and
1269 * the transition width is normalized frequency (0.5 is nyquist).
1271 * M = { ceil((r - 7.95) / (2.285 2 pi f_t)), r > 21
1272 * { ceil(5.79 / 2 pi f_t), r <= 21.
1275 static uint CalcKaiserOrder(const double rejection, const double transition)
1277 double w_t = 2.0 * M_PI * transition;
1278 if(rejection > 21.0)
1279 return (uint)ceil((rejection - 7.95) / (2.285 * w_t));
1280 return (uint)ceil(5.79 / w_t);
1283 // Calculates the beta value of the Kaiser window. Rejection is in dB.
1284 static double CalcKaiserBeta(const double rejection)
1286 if(rejection > 50.0)
1287 return 0.1102 * (rejection - 8.7);
1288 if(rejection >= 21.0)
1289 return (0.5842 * pow(rejection - 21.0, 0.4)) +
1290 (0.07886 * (rejection - 21.0));
1291 return 0.0;
1294 /* Calculates a point on the Kaiser-windowed sinc filter for the given half-
1295 * width, beta, gain, and cutoff. The point is specified in non-normalized
1296 * samples, from 0 to M, where M = (2 l + 1).
1298 * w(k) 2 p f_t sinc(2 f_t x)
1300 * x -- centered sample index (i - l)
1301 * k -- normalized and centered window index (x / l)
1302 * w(k) -- window function (Kaiser)
1303 * p -- gain compensation factor when sampling
1304 * f_t -- normalized center frequency (or cutoff; 0.5 is nyquist)
1306 static double SincFilter(const int l, const double b, const double gain, const double cutoff, const int i)
1308 return Kaiser(b, (double)(i - l) / l) * 2.0 * gain * cutoff * Sinc(2.0 * cutoff * (i - l));
1311 /* This is a polyphase sinc-filtered resampler.
1313 * Upsample Downsample
1315 * p/q = 3/2 p/q = 3/5
1317 * M-+-+-+-> M-+-+-+->
1318 * -------------------+ ---------------------+
1319 * p s * f f f f|f| | p s * f f f f f |
1320 * | 0 * 0 0 0|0|0 | | 0 * 0 0 0 0|0| |
1321 * v 0 * 0 0|0|0 0 | v 0 * 0 0 0|0|0 |
1322 * s * f|f|f f f | s * f f|f|f f |
1323 * 0 * |0|0 0 0 0 | 0 * 0|0|0 0 0 |
1324 * --------+=+--------+ 0 * |0|0 0 0 0 |
1325 * d . d .|d|. d . d ----------+=+--------+
1326 * d . . . .|d|. . . .
1327 * q->
1328 * q-+-+-+->
1330 * P_f(i,j) = q i mod p + pj
1331 * P_s(i,j) = floor(q i / p) - j
1332 * d[i=0..N-1] = sum_{j=0}^{floor((M - 1) / p)} {
1333 * { f[P_f(i,j)] s[P_s(i,j)], P_f(i,j) < M
1334 * { 0, P_f(i,j) >= M. }
1337 // Calculate the resampling metrics and build the Kaiser-windowed sinc filter
1338 // that's used to cut frequencies above the destination nyquist.
1339 static void ResamplerSetup(ResamplerT *rs, const uint srcRate, const uint dstRate)
1341 double cutoff, width, beta;
1342 uint gcd, l;
1343 int i;
1345 gcd = Gcd(srcRate, dstRate);
1346 rs->mP = dstRate / gcd;
1347 rs->mQ = srcRate / gcd;
1348 /* The cutoff is adjusted by half the transition width, so the transition
1349 * ends before the nyquist (0.5). Both are scaled by the downsampling
1350 * factor.
1352 if(rs->mP > rs->mQ)
1354 cutoff = 0.475 / rs->mP;
1355 width = 0.05 / rs->mP;
1357 else
1359 cutoff = 0.475 / rs->mQ;
1360 width = 0.05 / rs->mQ;
1362 // A rejection of -180 dB is used for the stop band. Round up when
1363 // calculating the left offset to avoid increasing the transition width.
1364 l = (CalcKaiserOrder(180.0, width)+1) / 2;
1365 beta = CalcKaiserBeta(180.0);
1366 rs->mM = l*2 + 1;
1367 rs->mL = l;
1368 rs->mF = CreateDoubles(rs->mM);
1369 for(i = 0;i < ((int)rs->mM);i++)
1370 rs->mF[i] = SincFilter((int)l, beta, rs->mP, cutoff, i);
1373 // Clean up after the resampler.
1374 static void ResamplerClear(ResamplerT *rs)
1376 free(rs->mF);
1377 rs->mF = NULL;
1380 // Perform the upsample-filter-downsample resampling operation using a
1381 // polyphase filter implementation.
1382 static void ResamplerRun(ResamplerT *rs, const uint inN, const double *in, const uint outN, double *out)
1384 const uint p = rs->mP, q = rs->mQ, m = rs->mM, l = rs->mL;
1385 const double *f = rs->mF;
1386 uint j_f, j_s;
1387 double *work;
1388 uint i;
1390 if(outN == 0)
1391 return;
1393 // Handle in-place operation.
1394 if(in == out)
1395 work = CreateDoubles(outN);
1396 else
1397 work = out;
1398 // Resample the input.
1399 for(i = 0;i < outN;i++)
1401 double r = 0.0;
1402 // Input starts at l to compensate for the filter delay. This will
1403 // drop any build-up from the first half of the filter.
1404 j_f = (l + (q * i)) % p;
1405 j_s = (l + (q * i)) / p;
1406 while(j_f < m)
1408 // Only take input when 0 <= j_s < inN. This single unsigned
1409 // comparison catches both cases.
1410 if(j_s < inN)
1411 r += f[j_f] * in[j_s];
1412 j_f += p;
1413 j_s--;
1415 work[i] = r;
1417 // Clean up after in-place operation.
1418 if(work != out)
1420 for(i = 0;i < outN;i++)
1421 out[i] = work[i];
1422 free(work);
1426 /*************************
1427 *** File source input ***
1428 *************************/
1430 // Read a binary value of the specified byte order and byte size from a file,
1431 // storing it as a 32-bit unsigned integer.
1432 static int ReadBin4(FILE *fp, const char *filename, const ByteOrderT order, const uint bytes, uint32 *out)
1434 uint8 in[4];
1435 uint32 accum;
1436 uint i;
1438 if(fread(in, 1, bytes, fp) != bytes)
1440 fprintf(stderr, "Error: Bad read from file '%s'.\n", filename);
1441 return 0;
1443 accum = 0;
1444 switch(order)
1446 case BO_LITTLE:
1447 for(i = 0;i < bytes;i++)
1448 accum = (accum<<8) | in[bytes - i - 1];
1449 break;
1450 case BO_BIG:
1451 for(i = 0;i < bytes;i++)
1452 accum = (accum<<8) | in[i];
1453 break;
1454 default:
1455 break;
1457 *out = accum;
1458 return 1;
1461 // Read a binary value of the specified byte order from a file, storing it as
1462 // a 64-bit unsigned integer.
1463 static int ReadBin8(FILE *fp, const char *filename, const ByteOrderT order, uint64 *out)
1465 uint8 in [8];
1466 uint64 accum;
1467 uint i;
1469 if(fread(in, 1, 8, fp) != 8)
1471 fprintf(stderr, "Error: Bad read from file '%s'.\n", filename);
1472 return 0;
1474 accum = 0ULL;
1475 switch(order)
1477 case BO_LITTLE:
1478 for(i = 0;i < 8;i++)
1479 accum = (accum<<8) | in[8 - i - 1];
1480 break;
1481 case BO_BIG:
1482 for(i = 0;i < 8;i++)
1483 accum = (accum<<8) | in[i];
1484 break;
1485 default:
1486 break;
1488 *out = accum;
1489 return 1;
1492 /* Read a binary value of the specified type, byte order, and byte size from
1493 * a file, converting it to a double. For integer types, the significant
1494 * bits are used to normalize the result. The sign of bits determines
1495 * whether they are padded toward the MSB (negative) or LSB (positive).
1496 * Floating-point types are not normalized.
1498 static int ReadBinAsDouble(FILE *fp, const char *filename, const ByteOrderT order, const ElementTypeT type, const uint bytes, const int bits, double *out)
1500 union {
1501 uint32 ui;
1502 int32 i;
1503 float f;
1504 } v4;
1505 union {
1506 uint64 ui;
1507 double f;
1508 } v8;
1510 *out = 0.0;
1511 if(bytes > 4)
1513 if(!ReadBin8(fp, filename, order, &v8.ui))
1514 return 0;
1515 if(type == ET_FP)
1516 *out = v8.f;
1518 else
1520 if(!ReadBin4(fp, filename, order, bytes, &v4.ui))
1521 return 0;
1522 if(type == ET_FP)
1523 *out = v4.f;
1524 else
1526 if(bits > 0)
1527 v4.ui >>= (8*bytes) - ((uint)bits);
1528 else
1529 v4.ui &= (0xFFFFFFFF >> (32+bits));
1531 if(v4.ui&(uint)(1<<(abs(bits)-1)))
1532 v4.ui |= (0xFFFFFFFF << abs (bits));
1533 *out = v4.i / (double)(1<<(abs(bits)-1));
1536 return 1;
1539 /* Read an ascii value of the specified type from a file, converting it to a
1540 * double. For integer types, the significant bits are used to normalize the
1541 * result. The sign of the bits should always be positive. This also skips
1542 * up to one separator character before the element itself.
1544 static int ReadAsciiAsDouble(TokenReaderT *tr, const char *filename, const ElementTypeT type, const uint bits, double *out)
1546 if(TrIsOperator(tr, ","))
1547 TrReadOperator(tr, ",");
1548 else if(TrIsOperator(tr, ":"))
1549 TrReadOperator(tr, ":");
1550 else if(TrIsOperator(tr, ";"))
1551 TrReadOperator(tr, ";");
1552 else if(TrIsOperator(tr, "|"))
1553 TrReadOperator(tr, "|");
1555 if(type == ET_FP)
1557 if(!TrReadFloat(tr, -HUGE_VAL, HUGE_VAL, out))
1559 fprintf(stderr, "Error: Bad read from file '%s'.\n", filename);
1560 return 0;
1563 else
1565 int v;
1566 if(!TrReadInt(tr, -(1<<(bits-1)), (1<<(bits-1))-1, &v))
1568 fprintf(stderr, "Error: Bad read from file '%s'.\n", filename);
1569 return 0;
1571 *out = v / (double)((1<<(bits-1))-1);
1573 return 1;
1576 // Read the RIFF/RIFX WAVE format chunk from a file, validating it against
1577 // the source parameters and data set metrics.
1578 static int ReadWaveFormat(FILE *fp, const ByteOrderT order, const uint hrirRate, SourceRefT *src)
1580 uint32 fourCC, chunkSize;
1581 uint32 format, channels, rate, dummy, block, size, bits;
1583 chunkSize = 0;
1584 do {
1585 if(chunkSize > 0)
1586 fseek (fp, (long) chunkSize, SEEK_CUR);
1587 if(!ReadBin4(fp, src->mPath, BO_LITTLE, 4, &fourCC) ||
1588 !ReadBin4(fp, src->mPath, order, 4, &chunkSize))
1589 return 0;
1590 } while(fourCC != FOURCC_FMT);
1591 if(!ReadBin4(fp, src->mPath, order, 2, &format) ||
1592 !ReadBin4(fp, src->mPath, order, 2, &channels) ||
1593 !ReadBin4(fp, src->mPath, order, 4, &rate) ||
1594 !ReadBin4(fp, src->mPath, order, 4, &dummy) ||
1595 !ReadBin4(fp, src->mPath, order, 2, &block))
1596 return 0;
1597 block /= channels;
1598 if(chunkSize > 14)
1600 if(!ReadBin4(fp, src->mPath, order, 2, &size))
1601 return 0;
1602 size /= 8;
1603 if(block > size)
1604 size = block;
1606 else
1607 size = block;
1608 if(format == WAVE_FORMAT_EXTENSIBLE)
1610 fseek(fp, 2, SEEK_CUR);
1611 if(!ReadBin4(fp, src->mPath, order, 2, &bits))
1612 return 0;
1613 if(bits == 0)
1614 bits = 8 * size;
1615 fseek(fp, 4, SEEK_CUR);
1616 if(!ReadBin4(fp, src->mPath, order, 2, &format))
1617 return 0;
1618 fseek(fp, (long)(chunkSize - 26), SEEK_CUR);
1620 else
1622 bits = 8 * size;
1623 if(chunkSize > 14)
1624 fseek(fp, (long)(chunkSize - 16), SEEK_CUR);
1625 else
1626 fseek(fp, (long)(chunkSize - 14), SEEK_CUR);
1628 if(format != WAVE_FORMAT_PCM && format != WAVE_FORMAT_IEEE_FLOAT)
1630 fprintf(stderr, "Error: Unsupported WAVE format in file '%s'.\n", src->mPath);
1631 return 0;
1633 if(src->mChannel >= channels)
1635 fprintf(stderr, "Error: Missing source channel in WAVE file '%s'.\n", src->mPath);
1636 return 0;
1638 if(rate != hrirRate)
1640 fprintf(stderr, "Error: Mismatched source sample rate in WAVE file '%s'.\n", src->mPath);
1641 return 0;
1643 if(format == WAVE_FORMAT_PCM)
1645 if(size < 2 || size > 4)
1647 fprintf(stderr, "Error: Unsupported sample size in WAVE file '%s'.\n", src->mPath);
1648 return 0;
1650 if(bits < 16 || bits > (8*size))
1652 fprintf (stderr, "Error: Bad significant bits in WAVE file '%s'.\n", src->mPath);
1653 return 0;
1655 src->mType = ET_INT;
1657 else
1659 if(size != 4 && size != 8)
1661 fprintf(stderr, "Error: Unsupported sample size in WAVE file '%s'.\n", src->mPath);
1662 return 0;
1664 src->mType = ET_FP;
1666 src->mSize = size;
1667 src->mBits = (int)bits;
1668 src->mSkip = channels;
1669 return 1;
1672 // Read a RIFF/RIFX WAVE data chunk, converting all elements to doubles.
1673 static int ReadWaveData(FILE *fp, const SourceRefT *src, const ByteOrderT order, const uint n, double *hrir)
1675 int pre, post, skip;
1676 uint i;
1678 pre = (int)(src->mSize * src->mChannel);
1679 post = (int)(src->mSize * (src->mSkip - src->mChannel - 1));
1680 skip = 0;
1681 for(i = 0;i < n;i++)
1683 skip += pre;
1684 if(skip > 0)
1685 fseek(fp, skip, SEEK_CUR);
1686 if(!ReadBinAsDouble(fp, src->mPath, order, src->mType, src->mSize, src->mBits, &hrir[i]))
1687 return 0;
1688 skip = post;
1690 if(skip > 0)
1691 fseek(fp, skip, SEEK_CUR);
1692 return 1;
1695 // Read the RIFF/RIFX WAVE list or data chunk, converting all elements to
1696 // doubles.
1697 static int ReadWaveList(FILE *fp, const SourceRefT *src, const ByteOrderT order, const uint n, double *hrir)
1699 uint32 fourCC, chunkSize, listSize, count;
1700 uint block, skip, offset, i;
1701 double lastSample;
1703 for(;;)
1705 if(!ReadBin4(fp, src->mPath, BO_LITTLE, 4, &fourCC) ||
1706 !ReadBin4(fp, src->mPath, order, 4, &chunkSize))
1707 return 0;
1709 if(fourCC == FOURCC_DATA)
1711 block = src->mSize * src->mSkip;
1712 count = chunkSize / block;
1713 if(count < (src->mOffset + n))
1715 fprintf(stderr, "Error: Bad read from file '%s'.\n", src->mPath);
1716 return 0;
1718 fseek(fp, (long)(src->mOffset * block), SEEK_CUR);
1719 if(!ReadWaveData(fp, src, order, n, &hrir[0]))
1720 return 0;
1721 return 1;
1723 else if(fourCC == FOURCC_LIST)
1725 if(!ReadBin4(fp, src->mPath, BO_LITTLE, 4, &fourCC))
1726 return 0;
1727 chunkSize -= 4;
1728 if(fourCC == FOURCC_WAVL)
1729 break;
1731 if(chunkSize > 0)
1732 fseek(fp, (long)chunkSize, SEEK_CUR);
1734 listSize = chunkSize;
1735 block = src->mSize * src->mSkip;
1736 skip = src->mOffset;
1737 offset = 0;
1738 lastSample = 0.0;
1739 while(offset < n && listSize > 8)
1741 if(!ReadBin4(fp, src->mPath, BO_LITTLE, 4, &fourCC) ||
1742 !ReadBin4(fp, src->mPath, order, 4, &chunkSize))
1743 return 0;
1744 listSize -= 8 + chunkSize;
1745 if(fourCC == FOURCC_DATA)
1747 count = chunkSize / block;
1748 if(count > skip)
1750 fseek(fp, (long)(skip * block), SEEK_CUR);
1751 chunkSize -= skip * block;
1752 count -= skip;
1753 skip = 0;
1754 if(count > (n - offset))
1755 count = n - offset;
1756 if(!ReadWaveData(fp, src, order, count, &hrir[offset]))
1757 return 0;
1758 chunkSize -= count * block;
1759 offset += count;
1760 lastSample = hrir [offset - 1];
1762 else
1764 skip -= count;
1765 count = 0;
1768 else if(fourCC == FOURCC_SLNT)
1770 if(!ReadBin4(fp, src->mPath, order, 4, &count))
1771 return 0;
1772 chunkSize -= 4;
1773 if(count > skip)
1775 count -= skip;
1776 skip = 0;
1777 if(count > (n - offset))
1778 count = n - offset;
1779 for(i = 0; i < count; i ++)
1780 hrir[offset + i] = lastSample;
1781 offset += count;
1783 else
1785 skip -= count;
1786 count = 0;
1789 if(chunkSize > 0)
1790 fseek(fp, (long)chunkSize, SEEK_CUR);
1792 if(offset < n)
1794 fprintf(stderr, "Error: Bad read from file '%s'.\n", src->mPath);
1795 return 0;
1797 return 1;
1800 // Load a source HRIR from a RIFF/RIFX WAVE file.
1801 static int LoadWaveSource(FILE *fp, SourceRefT *src, const uint hrirRate, const uint n, double *hrir)
1803 uint32 fourCC, dummy;
1804 ByteOrderT order;
1806 if(!ReadBin4(fp, src->mPath, BO_LITTLE, 4, &fourCC) ||
1807 !ReadBin4(fp, src->mPath, BO_LITTLE, 4, &dummy))
1808 return 0;
1809 if(fourCC == FOURCC_RIFF)
1810 order = BO_LITTLE;
1811 else if(fourCC == FOURCC_RIFX)
1812 order = BO_BIG;
1813 else
1815 fprintf(stderr, "Error: No RIFF/RIFX chunk in file '%s'.\n", src->mPath);
1816 return 0;
1819 if(!ReadBin4(fp, src->mPath, BO_LITTLE, 4, &fourCC))
1820 return 0;
1821 if(fourCC != FOURCC_WAVE)
1823 fprintf(stderr, "Error: Not a RIFF/RIFX WAVE file '%s'.\n", src->mPath);
1824 return 0;
1826 if(!ReadWaveFormat(fp, order, hrirRate, src))
1827 return 0;
1828 if(!ReadWaveList(fp, src, order, n, hrir))
1829 return 0;
1830 return 1;
1833 // Load a source HRIR from a binary file.
1834 static int LoadBinarySource(FILE *fp, const SourceRefT *src, const ByteOrderT order, const uint n, double *hrir)
1836 uint i;
1838 fseek(fp, (long)src->mOffset, SEEK_SET);
1839 for(i = 0;i < n;i++)
1841 if(!ReadBinAsDouble(fp, src->mPath, order, src->mType, src->mSize, src->mBits, &hrir[i]))
1842 return 0;
1843 if(src->mSkip > 0)
1844 fseek(fp, (long)src->mSkip, SEEK_CUR);
1846 return 1;
1849 // Load a source HRIR from an ASCII text file containing a list of elements
1850 // separated by whitespace or common list operators (',', ';', ':', '|').
1851 static int LoadAsciiSource(FILE *fp, const SourceRefT *src, const uint n, double *hrir)
1853 TokenReaderT tr;
1854 uint i, j;
1855 double dummy;
1857 TrSetup(fp, NULL, &tr);
1858 for(i = 0;i < src->mOffset;i++)
1860 if(!ReadAsciiAsDouble(&tr, src->mPath, src->mType, (uint)src->mBits, &dummy))
1861 return 0;
1863 for(i = 0;i < n;i++)
1865 if(!ReadAsciiAsDouble(&tr, src->mPath, src->mType, (uint)src->mBits, &hrir[i]))
1866 return 0;
1867 for(j = 0;j < src->mSkip;j++)
1869 if(!ReadAsciiAsDouble(&tr, src->mPath, src->mType, (uint)src->mBits, &dummy))
1870 return 0;
1873 return 1;
1876 // Load a source HRIR from a supported file type.
1877 static int LoadSource(SourceRefT *src, const uint hrirRate, const uint n, double *hrir)
1879 int result;
1880 FILE *fp;
1882 if(src->mFormat == SF_ASCII)
1883 fp = fopen(src->mPath, "r");
1884 else
1885 fp = fopen(src->mPath, "rb");
1886 if(fp == NULL)
1888 fprintf(stderr, "Error: Could not open source file '%s'.\n", src->mPath);
1889 return 0;
1891 if(src->mFormat == SF_WAVE)
1892 result = LoadWaveSource(fp, src, hrirRate, n, hrir);
1893 else if(src->mFormat == SF_BIN_LE)
1894 result = LoadBinarySource(fp, src, BO_LITTLE, n, hrir);
1895 else if(src->mFormat == SF_BIN_BE)
1896 result = LoadBinarySource(fp, src, BO_BIG, n, hrir);
1897 else
1898 result = LoadAsciiSource(fp, src, n, hrir);
1899 fclose(fp);
1900 return result;
1904 /***************************
1905 *** File storage output ***
1906 ***************************/
1908 // Write an ASCII string to a file.
1909 static int WriteAscii(const char *out, FILE *fp, const char *filename)
1911 size_t len;
1913 len = strlen(out);
1914 if(fwrite(out, 1, len, fp) != len)
1916 fclose(fp);
1917 fprintf(stderr, "Error: Bad write to file '%s'.\n", filename);
1918 return 0;
1920 return 1;
1923 // Write a binary value of the given byte order and byte size to a file,
1924 // loading it from a 32-bit unsigned integer.
1925 static int WriteBin4(const ByteOrderT order, const uint bytes, const uint32 in, FILE *fp, const char *filename)
1927 uint8 out[4];
1928 uint i;
1930 switch(order)
1932 case BO_LITTLE:
1933 for(i = 0;i < bytes;i++)
1934 out[i] = (in>>(i*8)) & 0x000000FF;
1935 break;
1936 case BO_BIG:
1937 for(i = 0;i < bytes;i++)
1938 out[bytes - i - 1] = (in>>(i*8)) & 0x000000FF;
1939 break;
1940 default:
1941 break;
1943 if(fwrite(out, 1, bytes, fp) != bytes)
1945 fprintf(stderr, "Error: Bad write to file '%s'.\n", filename);
1946 return 0;
1948 return 1;
1951 // Store the OpenAL Soft HRTF data set.
1952 static int StoreMhr(const HrirDataT *hData, const char *filename)
1954 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
1955 uint n = hData->mIrPoints;
1956 FILE *fp;
1957 uint fi, ei, ai, i;
1958 uint dither_seed = 22222;
1960 if((fp=fopen(filename, "wb")) == NULL)
1962 fprintf(stderr, "Error: Could not open MHR file '%s'.\n", filename);
1963 return 0;
1965 if(!WriteAscii(MHR_FORMAT, fp, filename))
1966 return 0;
1967 if(!WriteBin4(BO_LITTLE, 4, (uint32)hData->mIrRate, fp, filename))
1968 return 0;
1969 if(!WriteBin4(BO_LITTLE, 1, (uint32)hData->mSampleType, fp, filename))
1970 return 0;
1971 if(!WriteBin4(BO_LITTLE, 1, (uint32)hData->mChannelType, fp, filename))
1972 return 0;
1973 if(!WriteBin4(BO_LITTLE, 1, (uint32)hData->mIrPoints, fp, filename))
1974 return 0;
1975 if(!WriteBin4(BO_LITTLE, 1, (uint32)hData->mFdCount, fp, filename))
1976 return 0;
1977 for(fi = 0;fi < hData->mFdCount;fi++)
1979 if(!WriteBin4(BO_LITTLE, 2, (uint32)(1000.0 * hData->mFds[fi].mDistance), fp, filename))
1980 return 0;
1981 if(!WriteBin4(BO_LITTLE, 1, (uint32)hData->mFds[fi].mEvCount, fp, filename))
1982 return 0;
1983 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
1985 if(!WriteBin4(BO_LITTLE, 1, (uint32)hData->mFds[fi].mEvs[ei].mAzCount, fp, filename))
1986 return 0;
1990 for(fi = 0;fi < hData->mFdCount;fi++)
1992 const double scale = (hData->mSampleType == ST_S16) ? 32767.0 :
1993 ((hData->mSampleType == ST_S24) ? 8388607.0 : 0.0);
1994 const int bps = (hData->mSampleType == ST_S16) ? 2 :
1995 ((hData->mSampleType == ST_S24) ? 3 : 0);
1997 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
1999 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2001 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2002 double out[2 * MAX_TRUNCSIZE];
2004 TpdfDither(out, azd->mIrs[0], scale, n, channels, &dither_seed);
2005 if(hData->mChannelType == CT_STEREO)
2006 TpdfDither(out+1, azd->mIrs[1], scale, n, channels, &dither_seed);
2007 for(i = 0;i < (channels * n);i++)
2009 int v = (int)Clamp(out[i], -scale-1.0, scale);
2010 if(!WriteBin4(BO_LITTLE, bps, (uint32)v, fp, filename))
2011 return 0;
2016 for(fi = 0;fi < hData->mFdCount;fi++)
2018 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
2020 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2022 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2023 int v = (int)fmin(round(hData->mIrRate * azd->mDelays[0]), MAX_HRTD);
2025 if(!WriteBin4(BO_LITTLE, 1, (uint32)v, fp, filename))
2026 return 0;
2027 if(hData->mChannelType == CT_STEREO)
2029 v = (int)fmin(round(hData->mIrRate * azd->mDelays[1]), MAX_HRTD);
2031 if(!WriteBin4(BO_LITTLE, 1, (uint32)v, fp, filename))
2032 return 0;
2037 fclose(fp);
2038 return 1;
2042 /***********************
2043 *** HRTF processing ***
2044 ***********************/
2046 // Calculate the onset time of an HRIR and average it with any existing
2047 // timing for its field, elevation, azimuth, and ear.
2048 static double AverageHrirOnset(const uint rate, const uint n, const double *hrir, const double f, const double onset)
2050 double mag = 0.0;
2051 uint i;
2053 for(i = 0;i < n;i++)
2054 mag = fmax(fabs(hrir[i]), mag);
2055 mag *= 0.15;
2056 for(i = 0;i < n;i++)
2058 if(fabs(hrir[i]) >= mag)
2059 break;
2061 return Lerp(onset, (double)i / rate, f);
2064 // Calculate the magnitude response of an HRIR and average it with any
2065 // existing responses for its field, elevation, azimuth, and ear.
2066 static void AverageHrirMagnitude(const uint points, const uint n, const double *hrir, const double f, double *mag)
2068 uint m = 1 + (n / 2), i;
2069 Complex *h = CreateComplexes(n);
2070 double *r = CreateDoubles(n);
2072 for(i = 0;i < points;i++)
2073 h[i] = MakeComplex(hrir[i], 0.0);
2074 for(;i < n;i++)
2075 h[i] = MakeComplex(0.0, 0.0);
2076 FftForward(n, h, h);
2077 MagnitudeResponse(n, h, r);
2078 for(i = 0;i < m;i++)
2079 mag[i] = Lerp(mag[i], r[i], f);
2080 free(r);
2081 free(h);
2084 /* Calculate the contribution of each HRIR to the diffuse-field average based
2085 * on the area of its surface patch. All patches are centered at the HRIR
2086 * coordinates on the unit sphere and are measured by solid angle.
2088 static void CalculateDfWeights(const HrirDataT *hData, double *weights)
2090 double sum, evs, ev, upperEv, lowerEv, solidAngle;
2091 uint fi, ei;
2093 sum = 0.0;
2094 for(fi = 0;fi < hData->mFdCount;fi++)
2096 evs = M_PI / 2.0 / (hData->mFds[fi].mEvCount - 1);
2097 for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
2099 // For each elevation, calculate the upper and lower limits of
2100 // the patch band.
2101 ev = hData->mFds[fi].mEvs[ei].mElevation;
2102 lowerEv = fmax(-M_PI / 2.0, ev - evs);
2103 upperEv = fmin(M_PI / 2.0, ev + evs);
2104 // Calculate the area of the patch band.
2105 solidAngle = 2.0 * M_PI * (sin(upperEv) - sin(lowerEv));
2106 // Each weight is the area of one patch.
2107 weights[(fi * MAX_EV_COUNT) + ei] = solidAngle / hData->mFds[fi].mEvs[ei].mAzCount;
2108 // Sum the total surface area covered by the HRIRs of all fields.
2109 sum += solidAngle;
2112 /* TODO: It may be interesting to experiment with how a volume-based
2113 weighting performs compared to the existing distance-indepenent
2114 surface patches.
2116 for(fi = 0;fi < hData->mFdCount;fi++)
2118 // Normalize the weights given the total surface coverage for all
2119 // fields.
2120 for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
2121 weights[(fi * MAX_EV_COUNT) + ei] /= sum;
2125 /* Calculate the diffuse-field average from the given magnitude responses of
2126 * the HRIR set. Weighting can be applied to compensate for the varying
2127 * surface area covered by each HRIR. The final average can then be limited
2128 * by the specified magnitude range (in positive dB; 0.0 to skip).
2130 static void CalculateDiffuseFieldAverage(const HrirDataT *hData, const uint channels, const uint m, const int weighted, const double limit, double *dfa)
2132 double *weights = CreateDoubles(hData->mFdCount * MAX_EV_COUNT);
2133 uint count, ti, fi, ei, i, ai;
2135 if(weighted)
2137 // Use coverage weighting to calculate the average.
2138 CalculateDfWeights(hData, weights);
2140 else
2142 double weight;
2144 // If coverage weighting is not used, the weights still need to be
2145 // averaged by the number of existing HRIRs.
2146 count = hData->mIrCount;
2147 for(fi = 0;fi < hData->mFdCount;fi++)
2149 for(ei = 0;ei < hData->mFds[fi].mEvStart;ei++)
2150 count -= hData->mFds[fi].mEvs[ei].mAzCount;
2152 weight = 1.0 / count;
2154 for(fi = 0;fi < hData->mFdCount;fi++)
2156 for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
2157 weights[(fi * MAX_EV_COUNT) + ei] = weight;
2160 for(ti = 0;ti < channels;ti++)
2162 for(i = 0;i < m;i++)
2163 dfa[(ti * m) + i] = 0.0;
2164 for(fi = 0;fi < hData->mFdCount;fi++)
2166 for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
2168 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2170 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2171 // Get the weight for this HRIR's contribution.
2172 double weight = weights[(fi * MAX_EV_COUNT) + ei];
2174 // Add this HRIR's weighted power average to the total.
2175 for(i = 0;i < m;i++)
2176 dfa[(ti * m) + i] += weight * azd->mIrs[ti][i] * azd->mIrs[ti][i];
2180 // Finish the average calculation and keep it from being too small.
2181 for(i = 0;i < m;i++)
2182 dfa[(ti * m) + i] = fmax(sqrt(dfa[(ti * m) + i]), EPSILON);
2183 // Apply a limit to the magnitude range of the diffuse-field average
2184 // if desired.
2185 if(limit > 0.0)
2186 LimitMagnitudeResponse(hData->mFftSize, m, limit, &dfa[ti * m], &dfa[ti * m]);
2188 free(weights);
2191 // Perform diffuse-field equalization on the magnitude responses of the HRIR
2192 // set using the given average response.
2193 static void DiffuseFieldEqualize(const uint channels, const uint m, const double *dfa, const HrirDataT *hData)
2195 uint ti, fi, ei, ai, i;
2197 for(ti = 0;ti < channels;ti++)
2199 for(fi = 0;fi < hData->mFdCount;fi++)
2201 for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
2203 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2205 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2207 for(i = 0;i < m;i++)
2208 azd->mIrs[ti][i] /= dfa[(ti * m) + i];
2215 // Perform minimum-phase reconstruction using the magnitude responses of the
2216 // HRIR set.
2217 static void ReconstructHrirs(const HrirDataT *hData)
2219 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
2220 uint n = hData->mFftSize;
2221 uint ti, fi, ei, ai, i;
2222 Complex *h = CreateComplexes(n);
2223 uint total, count, pcdone, lastpc;
2225 total = hData->mIrCount;
2226 for(fi = 0;fi < hData->mFdCount;fi++)
2228 for(ei = 0;ei < hData->mFds[fi].mEvStart;ei++)
2229 total -= hData->mFds[fi].mEvs[ei].mAzCount;
2231 total *= channels;
2232 count = pcdone = lastpc = 0;
2233 printf("%3d%% done.", pcdone);
2234 fflush(stdout);
2235 for(ti = 0;ti < channels;ti++)
2237 for(fi = 0;fi < hData->mFdCount;fi++)
2239 for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
2241 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2243 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2245 MinimumPhase(n, azd->mIrs[ti], h);
2246 FftInverse(n, h, h);
2247 for(i = 0;i < hData->mIrPoints;i++)
2248 azd->mIrs[ti][i] = h[i].Real;
2249 pcdone = ++count * 100 / total;
2250 if(pcdone != lastpc)
2252 lastpc = pcdone;
2253 printf("\r%3d%% done.", pcdone);
2254 fflush(stdout);
2260 printf("\n");
2261 free(h);
2264 // Resamples the HRIRs for use at the given sampling rate.
2265 static void ResampleHrirs(const uint rate, HrirDataT *hData)
2267 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
2268 uint n = hData->mIrPoints;
2269 uint ti, fi, ei, ai;
2270 ResamplerT rs;
2272 ResamplerSetup(&rs, hData->mIrRate, rate);
2273 for(ti = 0;ti < channels;ti++)
2275 for(fi = 0;fi < hData->mFdCount;fi++)
2277 for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
2279 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2281 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2283 ResamplerRun(&rs, n, azd->mIrs[ti], n, azd->mIrs[ti]);
2288 hData->mIrRate = rate;
2289 ResamplerClear(&rs);
2292 /* Given field and elevation indices and an azimuth, calculate the indices of
2293 * the two HRIRs that bound the coordinate along with a factor for
2294 * calculating the continuous HRIR using interpolation.
2296 static void CalcAzIndices(const HrirDataT *hData, const uint fi, const uint ei, const double az, uint *a0, uint *a1, double *af)
2298 double f = (2.0*M_PI + az) * hData->mFds[fi].mEvs[ei].mAzCount / (2.0*M_PI);
2299 uint i = (uint)f % hData->mFds[fi].mEvs[ei].mAzCount;
2301 f -= floor(f);
2302 *a0 = i;
2303 *a1 = (i + 1) % hData->mFds[fi].mEvs[ei].mAzCount;
2304 *af = f;
2307 // Synthesize any missing onset timings at the bottom elevations of each
2308 // field. This just blends between slightly exaggerated known onsets (not
2309 // an accurate model).
2310 static void SynthesizeOnsets(HrirDataT *hData)
2312 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
2313 uint ti, fi, oi, ai, ei, a0, a1;
2314 double t, of, af;
2316 for(ti = 0;ti < channels;ti++)
2318 for(fi = 0;fi < hData->mFdCount;fi++)
2320 if(hData->mFds[fi].mEvStart <= 0)
2321 continue;
2322 oi = hData->mFds[fi].mEvStart;
2323 t = 0.0;
2324 for(ai = 0;ai < hData->mFds[fi].mEvs[oi].mAzCount;ai++)
2325 t += hData->mFds[fi].mEvs[oi].mAzs[ai].mDelays[ti];
2326 hData->mFds[fi].mEvs[0].mAzs[0].mDelays[ti] = 1.32e-4 + (t / hData->mFds[fi].mEvs[oi].mAzCount);
2327 for(ei = 1;ei < hData->mFds[fi].mEvStart;ei++)
2329 of = (double)ei / hData->mFds[fi].mEvStart;
2330 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2332 CalcAzIndices(hData, fi, oi, hData->mFds[fi].mEvs[ei].mAzs[ai].mAzimuth, &a0, &a1, &af);
2333 hData->mFds[fi].mEvs[ei].mAzs[ai].mDelays[ti] = Lerp(hData->mFds[fi].mEvs[0].mAzs[0].mDelays[ti], Lerp(hData->mFds[fi].mEvs[oi].mAzs[a0].mDelays[ti], hData->mFds[fi].mEvs[oi].mAzs[a1].mDelays[ti], af), of);
2340 /* Attempt to synthesize any missing HRIRs at the bottom elevations of each
2341 * field. Right now this just blends the lowest elevation HRIRs together and
2342 * applies some attenuation and high frequency damping. It is a simple, if
2343 * inaccurate model.
2345 static void SynthesizeHrirs(HrirDataT *hData)
2347 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
2348 uint n = hData->mIrPoints;
2349 uint ti, fi, oi, ai, ei, i;
2350 double lp[4], s0, s1;
2351 double of, b;
2352 uint a0, a1;
2353 double af;
2355 for(ti = 0;ti < channels;ti++)
2357 for(fi = 0;fi < hData->mFdCount;fi++)
2359 if(hData->mFds[fi].mEvStart <= 0)
2360 continue;
2361 oi = hData->mFds[fi].mEvStart;
2362 for(i = 0;i < n;i++)
2363 hData->mFds[fi].mEvs[0].mAzs[0].mIrs[ti][i] = 0.0;
2364 for(ai = 0;ai < hData->mFds[fi].mEvs[oi].mAzCount;ai++)
2366 for(i = 0;i < n;i++)
2367 hData->mFds[fi].mEvs[0].mAzs[0].mIrs[ti][i] += hData->mFds[fi].mEvs[oi].mAzs[ai].mIrs[ti][i] / hData->mFds[fi].mEvs[oi].mAzCount;
2369 for(ei = 1;ei < hData->mFds[fi].mEvStart;ei++)
2371 of = (double)ei / hData->mFds[fi].mEvStart;
2372 b = (1.0 - of) * (3.5e-6 * hData->mIrRate);
2373 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2375 CalcAzIndices(hData, fi, oi, hData->mFds[fi].mEvs[ei].mAzs[ai].mAzimuth, &a0, &a1, &af);
2376 lp[0] = 0.0;
2377 lp[1] = 0.0;
2378 lp[2] = 0.0;
2379 lp[3] = 0.0;
2380 for(i = 0;i < n;i++)
2382 s0 = hData->mFds[fi].mEvs[0].mAzs[0].mIrs[ti][i];
2383 s1 = Lerp(hData->mFds[fi].mEvs[oi].mAzs[a0].mIrs[ti][i], hData->mFds[fi].mEvs[oi].mAzs[a1].mIrs[ti][i], af);
2384 s0 = Lerp(s0, s1, of);
2385 lp[0] = Lerp(s0, lp[0], b);
2386 lp[1] = Lerp(lp[0], lp[1], b);
2387 lp[2] = Lerp(lp[1], lp[2], b);
2388 lp[3] = Lerp(lp[2], lp[3], b);
2389 hData->mFds[fi].mEvs[ei].mAzs[ai].mIrs[ti][i] = lp[3];
2393 b = 3.5e-6 * hData->mIrRate;
2394 lp[0] = 0.0;
2395 lp[1] = 0.0;
2396 lp[2] = 0.0;
2397 lp[3] = 0.0;
2398 for(i = 0;i < n;i++)
2400 s0 = hData->mFds[fi].mEvs[0].mAzs[0].mIrs[ti][i];
2401 lp[0] = Lerp(s0, lp[0], b);
2402 lp[1] = Lerp(lp[0], lp[1], b);
2403 lp[2] = Lerp(lp[1], lp[2], b);
2404 lp[3] = Lerp(lp[2], lp[3], b);
2405 hData->mFds[fi].mEvs[0].mAzs[0].mIrs[ti][i] = lp[3];
2407 hData->mFds[fi].mEvStart = 0;
2412 // The following routines assume a full set of HRIRs for all elevations.
2414 // Normalize the HRIR set and slightly attenuate the result.
2415 static void NormalizeHrirs(const HrirDataT *hData)
2417 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
2418 uint n = hData->mIrPoints;
2419 uint ti, fi, ei, ai, i;
2420 double maxLevel = 0.0;
2422 for(ti = 0;ti < channels;ti++)
2424 for(fi = 0;fi < hData->mFdCount;fi++)
2426 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
2428 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2430 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2432 for(i = 0;i < n;i++)
2433 maxLevel = fmax(fabs(azd->mIrs[ti][i]), maxLevel);
2438 maxLevel = 1.01 * maxLevel;
2439 for(ti = 0;ti < channels;ti++)
2441 for(fi = 0;fi < hData->mFdCount;fi++)
2443 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
2445 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2447 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2449 for(i = 0;i < n;i++)
2450 azd->mIrs[ti][i] /= maxLevel;
2457 // Calculate the left-ear time delay using a spherical head model.
2458 static double CalcLTD(const double ev, const double az, const double rad, const double dist)
2460 double azp, dlp, l, al;
2462 azp = asin(cos(ev) * sin(az));
2463 dlp = sqrt((dist*dist) + (rad*rad) + (2.0*dist*rad*sin(azp)));
2464 l = sqrt((dist*dist) - (rad*rad));
2465 al = (0.5 * M_PI) + azp;
2466 if(dlp > l)
2467 dlp = l + (rad * (al - acos(rad / dist)));
2468 return dlp / 343.3;
2471 // Calculate the effective head-related time delays for each minimum-phase
2472 // HRIR.
2473 static void CalculateHrtds(const HeadModelT model, const double radius, HrirDataT *hData)
2475 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
2476 double minHrtd = INFINITY, maxHrtd = -INFINITY;
2477 uint ti, fi, ei, ai;
2478 double t;
2480 if(model == HM_DATASET)
2482 for(ti = 0;ti < channels;ti++)
2484 for(fi = 0;fi < hData->mFdCount;fi++)
2486 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
2488 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2490 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
2492 t = azd->mDelays[ti] * radius / hData->mRadius;
2493 azd->mDelays[ti] = t;
2494 maxHrtd = fmax(t, maxHrtd);
2495 minHrtd = fmin(t, minHrtd);
2501 else
2503 for(ti = 0;ti < channels;ti++)
2505 for(fi = 0;fi < hData->mFdCount;fi++)
2507 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
2509 HrirEvT *evd = &hData->mFds[fi].mEvs[ei];
2511 for(ai = 0;ai < evd->mAzCount;ai++)
2513 HrirAzT *azd = &evd->mAzs[ai];
2515 t = CalcLTD(evd->mElevation, azd->mAzimuth, radius, hData->mFds[fi].mDistance);
2516 azd->mDelays[ti] = t;
2517 maxHrtd = fmax(t, maxHrtd);
2518 minHrtd = fmin(t, minHrtd);
2524 for(ti = 0;ti < channels;ti++)
2526 for(fi = 0;fi < hData->mFdCount;fi++)
2528 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
2530 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
2531 hData->mFds[fi].mEvs[ei].mAzs[ai].mDelays[ti] -= minHrtd;
2537 // Clear the initial HRIR data state.
2538 static void ResetHrirData(HrirDataT *hData)
2540 hData->mIrRate = 0;
2541 hData->mSampleType = ST_S24;
2542 hData->mChannelType = CT_NONE;
2543 hData->mIrPoints = 0;
2544 hData->mFftSize = 0;
2545 hData->mIrSize = 0;
2546 hData->mRadius = 0.0;
2547 hData->mIrCount = 0;
2548 hData->mFdCount = 0;
2549 hData->mFds = NULL;
2552 // Allocate and configure dynamic HRIR structures.
2553 static int PrepareHrirData(const uint fdCount, const double distances[MAX_FD_COUNT], const uint evCounts[MAX_FD_COUNT], const uint azCounts[MAX_FD_COUNT * MAX_EV_COUNT], HrirDataT *hData)
2555 uint evTotal = 0, azTotal = 0, fi, ei, ai;
2557 for(fi = 0;fi < fdCount;fi++)
2559 evTotal += evCounts[fi];
2560 for(ei = 0;ei < evCounts[fi];ei++)
2561 azTotal += azCounts[(fi * MAX_EV_COUNT) + ei];
2563 if(!fdCount || !evTotal || !azTotal)
2564 return 0;
2566 hData->mFds = calloc(fdCount, sizeof(*hData->mFds));
2567 if(hData->mFds == NULL)
2568 return 0;
2569 hData->mFds[0].mEvs = calloc(evTotal, sizeof(*hData->mFds[0].mEvs));
2570 if(hData->mFds[0].mEvs == NULL)
2571 return 0;
2572 hData->mFds[0].mEvs[0].mAzs = calloc(azTotal, sizeof(*hData->mFds[0].mEvs[0].mAzs));
2573 if(hData->mFds[0].mEvs[0].mAzs == NULL)
2574 return 0;
2575 hData->mIrCount = azTotal;
2576 hData->mFdCount = fdCount;
2577 evTotal = 0;
2578 azTotal = 0;
2579 for(fi = 0;fi < fdCount;fi++)
2581 hData->mFds[fi].mDistance = distances[fi];
2582 hData->mFds[fi].mEvCount = evCounts[fi];
2583 hData->mFds[fi].mEvStart = 0;
2584 hData->mFds[fi].mEvs = &hData->mFds[0].mEvs[evTotal];
2585 evTotal += evCounts[fi];
2586 for(ei = 0;ei < evCounts[fi];ei++)
2588 uint azCount = azCounts[(fi * MAX_EV_COUNT) + ei];
2590 hData->mFds[fi].mIrCount += azCount;
2591 hData->mFds[fi].mEvs[ei].mElevation = -M_PI / 2.0 + M_PI * ei / (evCounts[fi] - 1);
2592 hData->mFds[fi].mEvs[ei].mIrCount += azCount;
2593 hData->mFds[fi].mEvs[ei].mAzCount = azCount;
2594 hData->mFds[fi].mEvs[ei].mAzs = &hData->mFds[0].mEvs[0].mAzs[azTotal];
2595 for(ai = 0;ai < azCount;ai++)
2597 hData->mFds[fi].mEvs[ei].mAzs[ai].mAzimuth = 2.0 * M_PI * ai / azCount;
2598 hData->mFds[fi].mEvs[ei].mAzs[ai].mIndex = azTotal + ai;
2599 hData->mFds[fi].mEvs[ei].mAzs[ai].mDelays[0] = 0.0;
2600 hData->mFds[fi].mEvs[ei].mAzs[ai].mDelays[1] = 0.0;
2601 hData->mFds[fi].mEvs[ei].mAzs[ai].mIrs[0] = NULL;
2602 hData->mFds[fi].mEvs[ei].mAzs[ai].mIrs[1] = NULL;
2604 azTotal += azCount;
2607 return 1;
2610 // Clean up HRIR data.
2611 static void FreeHrirData(HrirDataT *hData)
2613 if(hData->mFds != NULL)
2615 if(hData->mFds[0].mEvs != NULL)
2617 if(hData->mFds[0].mEvs[0].mAzs)
2619 if(hData->mFds[0].mEvs[0].mAzs[0].mIrs[0] != NULL)
2620 free(hData->mFds[0].mEvs[0].mAzs[0].mIrs[0]);
2621 free(hData->mFds[0].mEvs[0].mAzs);
2623 free(hData->mFds[0].mEvs);
2625 free(hData->mFds);
2626 hData->mFds = NULL;
2630 // Match the channel type from a given identifier.
2631 static ChannelTypeT MatchChannelType(const char *ident)
2633 if(strcasecmp(ident, "mono") == 0)
2634 return CT_MONO;
2635 if(strcasecmp(ident, "stereo") == 0)
2636 return CT_STEREO;
2637 return CT_NONE;
2640 // Process the data set definition to read and validate the data set metrics.
2641 static int ProcessMetrics(TokenReaderT *tr, const uint fftSize, const uint truncSize, HrirDataT *hData)
2643 int hasRate = 0, hasType = 0, hasPoints = 0, hasRadius = 0;
2644 int hasDistance = 0, hasAzimuths = 0;
2645 char ident[MAX_IDENT_LEN+1];
2646 uint line, col;
2647 double fpVal;
2648 uint points;
2649 int intVal;
2650 double distances[MAX_FD_COUNT];
2651 uint fdCount = 0;
2652 uint evCounts[MAX_FD_COUNT];
2653 uint *azCounts = calloc(MAX_FD_COUNT * MAX_EV_COUNT, sizeof(*azCounts));
2655 if(azCounts == NULL)
2657 fprintf(stderr, "Error: Out of memory.\n");
2658 exit(-1);
2660 TrIndication(tr, &line, &col);
2661 while(TrIsIdent(tr))
2663 TrIndication(tr, &line, &col);
2664 if(!TrReadIdent(tr, MAX_IDENT_LEN, ident))
2665 goto error;
2666 if(strcasecmp(ident, "rate") == 0)
2668 if(hasRate)
2670 TrErrorAt(tr, line, col, "Redefinition of 'rate'.\n");
2671 goto error;
2673 if(!TrReadOperator(tr, "="))
2674 goto error;
2675 if(!TrReadInt(tr, MIN_RATE, MAX_RATE, &intVal))
2676 goto error;
2677 hData->mIrRate = (uint)intVal;
2678 hasRate = 1;
2680 else if(strcasecmp(ident, "type") == 0)
2682 char type[MAX_IDENT_LEN+1];
2684 if(hasType)
2686 TrErrorAt(tr, line, col, "Redefinition of 'type'.\n");
2687 goto error;
2689 if(!TrReadOperator(tr, "="))
2690 goto error;
2692 if(!TrReadIdent(tr, MAX_IDENT_LEN, type))
2693 goto error;
2694 hData->mChannelType = MatchChannelType(type);
2695 if(hData->mChannelType == CT_NONE)
2697 TrErrorAt(tr, line, col, "Expected a channel type.\n");
2698 goto error;
2700 hasType = 1;
2702 else if(strcasecmp(ident, "points") == 0)
2704 if(hasPoints)
2706 TrErrorAt(tr, line, col, "Redefinition of 'points'.\n");
2707 goto error;
2709 if(!TrReadOperator(tr, "="))
2710 goto error;
2711 TrIndication(tr, &line, &col);
2712 if(!TrReadInt(tr, MIN_POINTS, MAX_POINTS, &intVal))
2713 goto error;
2714 points = (uint)intVal;
2715 if(fftSize > 0 && points > fftSize)
2717 TrErrorAt(tr, line, col, "Value exceeds the overridden FFT size.\n");
2718 goto error;
2720 if(points < truncSize)
2722 TrErrorAt(tr, line, col, "Value is below the truncation size.\n");
2723 goto error;
2725 hData->mIrPoints = points;
2726 if(fftSize <= 0)
2728 hData->mFftSize = DEFAULT_FFTSIZE;
2729 hData->mIrSize = 1 + (DEFAULT_FFTSIZE / 2);
2731 else
2733 hData->mFftSize = fftSize;
2734 hData->mIrSize = 1 + (fftSize / 2);
2735 if(points > hData->mIrSize)
2736 hData->mIrSize = points;
2738 hasPoints = 1;
2740 else if(strcasecmp(ident, "radius") == 0)
2742 if(hasRadius)
2744 TrErrorAt(tr, line, col, "Redefinition of 'radius'.\n");
2745 goto error;
2747 if(!TrReadOperator(tr, "="))
2748 goto error;
2749 if(!TrReadFloat(tr, MIN_RADIUS, MAX_RADIUS, &fpVal))
2750 goto error;
2751 hData->mRadius = fpVal;
2752 hasRadius = 1;
2754 else if(strcasecmp(ident, "distance") == 0)
2756 uint count = 0;
2758 if(hasDistance)
2760 TrErrorAt(tr, line, col, "Redefinition of 'distance'.\n");
2761 goto error;
2763 if(!TrReadOperator(tr, "="))
2764 goto error;
2766 for(;;)
2768 if(!TrReadFloat(tr, MIN_DISTANCE, MAX_DISTANCE, &fpVal))
2769 goto error;
2770 if(count > 0 && fpVal <= distances[count - 1])
2772 TrError(tr, "Distances are not ascending.\n");
2773 goto error;
2775 distances[count++] = fpVal;
2776 if(!TrIsOperator(tr, ","))
2777 break;
2778 if(count >= MAX_FD_COUNT)
2780 TrError(tr, "Exceeded the maximum of %d fields.\n", MAX_FD_COUNT);
2781 goto error;
2783 TrReadOperator(tr, ",");
2785 if(fdCount != 0 && count != fdCount)
2787 TrError(tr, "Did not match the specified number of %d fields.\n", fdCount);
2788 goto error;
2790 fdCount = count;
2791 hasDistance = 1;
2793 else if(strcasecmp(ident, "azimuths") == 0)
2795 uint count = 0;
2797 if(hasAzimuths)
2799 TrErrorAt(tr, line, col, "Redefinition of 'azimuths'.\n");
2800 goto error;
2802 if(!TrReadOperator(tr, "="))
2803 goto error;
2805 evCounts[0] = 0;
2806 for(;;)
2808 if(!TrReadInt(tr, MIN_AZ_COUNT, MAX_AZ_COUNT, &intVal))
2809 goto error;
2810 azCounts[(count * MAX_EV_COUNT) + evCounts[count]++] = (uint)intVal;
2811 if(TrIsOperator(tr, ","))
2813 if(evCounts[count] >= MAX_EV_COUNT)
2815 TrError(tr, "Exceeded the maximum of %d elevations.\n", MAX_EV_COUNT);
2816 goto error;
2818 TrReadOperator(tr, ",");
2820 else
2822 if(evCounts[count] < MIN_EV_COUNT)
2824 TrErrorAt(tr, line, col, "Did not reach the minimum of %d azimuth counts.\n", MIN_EV_COUNT);
2825 goto error;
2827 if(azCounts[count * MAX_EV_COUNT] != 1 || azCounts[(count * MAX_EV_COUNT) + evCounts[count] - 1] != 1)
2829 TrError(tr, "Poles are not singular for field %d.\n", count - 1);
2830 goto error;
2832 count++;
2833 if(TrIsOperator(tr, ";"))
2835 if(count >= MAX_FD_COUNT)
2837 TrError(tr, "Exceeded the maximum number of %d fields.\n", MAX_FD_COUNT);
2838 goto error;
2840 evCounts[count] = 0;
2841 TrReadOperator(tr, ";");
2843 else
2845 break;
2849 if(fdCount != 0 && count != fdCount)
2851 TrError(tr, "Did not match the specified number of %d fields.\n", fdCount);
2852 goto error;
2854 fdCount = count;
2855 hasAzimuths = 1;
2857 else
2859 TrErrorAt(tr, line, col, "Expected a metric name.\n");
2860 goto error;
2862 TrSkipWhitespace(tr);
2864 if(!(hasRate && hasPoints && hasRadius && hasDistance && hasAzimuths))
2866 TrErrorAt(tr, line, col, "Expected a metric name.\n");
2867 goto error;
2869 if(distances[0] < hData->mRadius)
2871 TrError(tr, "Distance cannot start below head radius.\n");
2872 goto error;
2874 if(hData->mChannelType == CT_NONE)
2875 hData->mChannelType = CT_MONO;
2876 if(!PrepareHrirData(fdCount, distances, evCounts, azCounts, hData))
2878 fprintf(stderr, "Error: Out of memory.\n");
2879 exit(-1);
2881 free(azCounts);
2882 return 1;
2884 error:
2885 free(azCounts);
2886 return 0;
2889 // Parse an index triplet from the data set definition.
2890 static int ReadIndexTriplet(TokenReaderT *tr, const HrirDataT *hData, uint *fi, uint *ei, uint *ai)
2892 int intVal;
2894 if(hData->mFdCount > 1)
2896 if(!TrReadInt(tr, 0, (int)hData->mFdCount - 1, &intVal))
2897 return 0;
2898 *fi = (uint)intVal;
2899 if(!TrReadOperator(tr, ","))
2900 return 0;
2902 else
2904 *fi = 0;
2906 if(!TrReadInt(tr, 0, (int)hData->mFds[*fi].mEvCount - 1, &intVal))
2907 return 0;
2908 *ei = (uint)intVal;
2909 if(!TrReadOperator(tr, ","))
2910 return 0;
2911 if(!TrReadInt(tr, 0, (int)hData->mFds[*fi].mEvs[*ei].mAzCount - 1, &intVal))
2912 return 0;
2913 *ai = (uint)intVal;
2914 return 1;
2917 // Match the source format from a given identifier.
2918 static SourceFormatT MatchSourceFormat(const char *ident)
2920 if(strcasecmp(ident, "wave") == 0)
2921 return SF_WAVE;
2922 if(strcasecmp(ident, "bin_le") == 0)
2923 return SF_BIN_LE;
2924 if(strcasecmp(ident, "bin_be") == 0)
2925 return SF_BIN_BE;
2926 if(strcasecmp(ident, "ascii") == 0)
2927 return SF_ASCII;
2928 return SF_NONE;
2931 // Match the source element type from a given identifier.
2932 static ElementTypeT MatchElementType(const char *ident)
2934 if(strcasecmp(ident, "int") == 0)
2935 return ET_INT;
2936 if(strcasecmp(ident, "fp") == 0)
2937 return ET_FP;
2938 return ET_NONE;
2941 // Parse and validate a source reference from the data set definition.
2942 static int ReadSourceRef(TokenReaderT *tr, SourceRefT *src)
2944 char ident[MAX_IDENT_LEN+1];
2945 uint line, col;
2946 int intVal;
2948 TrIndication(tr, &line, &col);
2949 if(!TrReadIdent(tr, MAX_IDENT_LEN, ident))
2950 return 0;
2951 src->mFormat = MatchSourceFormat(ident);
2952 if(src->mFormat == SF_NONE)
2954 TrErrorAt(tr, line, col, "Expected a source format.\n");
2955 return 0;
2957 if(!TrReadOperator(tr, "("))
2958 return 0;
2959 if(src->mFormat == SF_WAVE)
2961 if(!TrReadInt(tr, 0, MAX_WAVE_CHANNELS, &intVal))
2962 return 0;
2963 src->mType = ET_NONE;
2964 src->mSize = 0;
2965 src->mBits = 0;
2966 src->mChannel = (uint)intVal;
2967 src->mSkip = 0;
2969 else
2971 TrIndication(tr, &line, &col);
2972 if(!TrReadIdent(tr, MAX_IDENT_LEN, ident))
2973 return 0;
2974 src->mType = MatchElementType(ident);
2975 if(src->mType == ET_NONE)
2977 TrErrorAt(tr, line, col, "Expected a source element type.\n");
2978 return 0;
2980 if(src->mFormat == SF_BIN_LE || src->mFormat == SF_BIN_BE)
2982 if(!TrReadOperator(tr, ","))
2983 return 0;
2984 if(src->mType == ET_INT)
2986 if(!TrReadInt(tr, MIN_BIN_SIZE, MAX_BIN_SIZE, &intVal))
2987 return 0;
2988 src->mSize = (uint)intVal;
2989 if(!TrIsOperator(tr, ","))
2990 src->mBits = (int)(8*src->mSize);
2991 else
2993 TrReadOperator(tr, ",");
2994 TrIndication(tr, &line, &col);
2995 if(!TrReadInt(tr, -2147483647-1, 2147483647, &intVal))
2996 return 0;
2997 if(abs(intVal) < MIN_BIN_BITS || (uint)abs(intVal) > (8*src->mSize))
2999 TrErrorAt(tr, line, col, "Expected a value of (+/-) %d to %d.\n", MIN_BIN_BITS, 8*src->mSize);
3000 return 0;
3002 src->mBits = intVal;
3005 else
3007 TrIndication(tr, &line, &col);
3008 if(!TrReadInt(tr, -2147483647-1, 2147483647, &intVal))
3009 return 0;
3010 if(intVal != 4 && intVal != 8)
3012 TrErrorAt(tr, line, col, "Expected a value of 4 or 8.\n");
3013 return 0;
3015 src->mSize = (uint)intVal;
3016 src->mBits = 0;
3019 else if(src->mFormat == SF_ASCII && src->mType == ET_INT)
3021 if(!TrReadOperator(tr, ","))
3022 return 0;
3023 if(!TrReadInt(tr, MIN_ASCII_BITS, MAX_ASCII_BITS, &intVal))
3024 return 0;
3025 src->mSize = 0;
3026 src->mBits = intVal;
3028 else
3030 src->mSize = 0;
3031 src->mBits = 0;
3034 if(!TrIsOperator(tr, ";"))
3035 src->mSkip = 0;
3036 else
3038 TrReadOperator(tr, ";");
3039 if(!TrReadInt(tr, 0, 0x7FFFFFFF, &intVal))
3040 return 0;
3041 src->mSkip = (uint)intVal;
3044 if(!TrReadOperator(tr, ")"))
3045 return 0;
3046 if(TrIsOperator(tr, "@"))
3048 TrReadOperator(tr, "@");
3049 if(!TrReadInt(tr, 0, 0x7FFFFFFF, &intVal))
3050 return 0;
3051 src->mOffset = (uint)intVal;
3053 else
3054 src->mOffset = 0;
3055 if(!TrReadOperator(tr, ":"))
3056 return 0;
3057 if(!TrReadString(tr, MAX_PATH_LEN, src->mPath))
3058 return 0;
3059 return 1;
3062 // Match the target ear (index) from a given identifier.
3063 static int MatchTargetEar(const char *ident)
3065 if(strcasecmp(ident, "left") == 0)
3066 return 0;
3067 if(strcasecmp(ident, "right") == 0)
3068 return 1;
3069 return -1;
3072 // Process the list of sources in the data set definition.
3073 static int ProcessSources(const HeadModelT model, TokenReaderT *tr, HrirDataT *hData)
3075 uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
3076 double *hrirs = CreateDoubles(channels * hData->mIrCount * hData->mIrSize);
3077 double *hrir = CreateDoubles(hData->mIrPoints);
3078 uint line, col, fi, ei, ai, ti;
3079 int count;
3081 printf("Loading sources...");
3082 fflush(stdout);
3083 count = 0;
3084 while(TrIsOperator(tr, "["))
3086 double factor[2] = { 1.0, 1.0 };
3088 TrIndication(tr, &line, &col);
3089 TrReadOperator(tr, "[");
3090 if(!ReadIndexTriplet(tr, hData, &fi, &ei, &ai))
3091 goto error;
3092 if(!TrReadOperator(tr, "]"))
3093 goto error;
3094 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
3096 if(azd->mIrs[0] != NULL)
3098 TrErrorAt(tr, line, col, "Redefinition of source.\n");
3099 goto error;
3101 if(!TrReadOperator(tr, "="))
3102 goto error;
3104 for(;;)
3106 SourceRefT src;
3107 uint ti = 0;
3109 if(!ReadSourceRef(tr, &src))
3110 goto error;
3112 // TODO: Would be nice to display 'x of y files', but that would
3113 // require preparing the source refs first to get a total count
3114 // before loading them.
3115 ++count;
3116 printf("\rLoading sources... %d file%s", count, (count==1)?"":"s");
3117 fflush(stdout);
3119 if(!LoadSource(&src, hData->mIrRate, hData->mIrPoints, hrir))
3120 goto error;
3122 if(hData->mChannelType == CT_STEREO)
3124 char ident[MAX_IDENT_LEN+1];
3126 if(!TrReadIdent(tr, MAX_IDENT_LEN, ident))
3127 goto error;
3128 ti = MatchTargetEar(ident);
3129 if((int)ti < 0)
3131 TrErrorAt(tr, line, col, "Expected a target ear.\n");
3132 goto error;
3135 azd->mIrs[ti] = &hrirs[hData->mIrSize * (ti * hData->mIrCount + azd->mIndex)];
3136 if(model == HM_DATASET)
3137 azd->mDelays[ti] = AverageHrirOnset(hData->mIrRate, hData->mIrPoints, hrir, 1.0 / factor[ti], azd->mDelays[ti]);
3138 AverageHrirMagnitude(hData->mIrPoints, hData->mFftSize, hrir, 1.0 / factor[ti], azd->mIrs[ti]);
3139 factor[ti] += 1.0;
3140 if(!TrIsOperator(tr, "+"))
3141 break;
3142 TrReadOperator(tr, "+");
3144 if(hData->mChannelType == CT_STEREO)
3146 if(azd->mIrs[0] == NULL)
3148 TrErrorAt(tr, line, col, "Missing left ear source reference(s).\n");
3149 goto error;
3151 else if(azd->mIrs[1] == NULL)
3153 TrErrorAt(tr, line, col, "Missing right ear source reference(s).\n");
3154 goto error;
3158 printf("\n");
3159 for(fi = 0;fi < hData->mFdCount;fi++)
3161 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
3163 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
3165 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
3167 if(azd->mIrs[0] != NULL)
3168 break;
3170 if(ai < hData->mFds[fi].mEvs[ei].mAzCount)
3171 break;
3173 if(ei >= hData->mFds[fi].mEvCount)
3175 TrError(tr, "Missing source references [ %d, *, * ].\n", fi);
3176 goto error;
3178 hData->mFds[fi].mEvStart = ei;
3179 for(;ei < hData->mFds[fi].mEvCount;ei++)
3181 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
3183 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
3185 if(azd->mIrs[0] == NULL)
3187 TrError(tr, "Missing source reference [ %d, %d, %d ].\n", fi, ei, ai);
3188 goto error;
3193 for(ti = 0;ti < channels;ti++)
3195 for(fi = 0;fi < hData->mFdCount;fi++)
3197 for(ei = 0;ei < hData->mFds[fi].mEvCount;ei++)
3199 for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
3201 HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
3203 azd->mIrs[ti] = &hrirs[hData->mIrSize * (ti * hData->mIrCount + azd->mIndex)];
3208 if(!TrLoad(tr))
3210 free(hrir);
3211 return 1;
3213 TrError(tr, "Errant data at end of source list.\n");
3215 error:
3216 free(hrir);
3217 return 0;
3220 /* Parse the data set definition and process the source data, storing the
3221 * resulting data set as desired. If the input name is NULL it will read
3222 * from standard input.
3224 static int ProcessDefinition(const char *inName, const uint outRate, const uint fftSize, const int equalize, const int surface, const double limit, const uint truncSize, const HeadModelT model, const double radius, const char *outName)
3226 char rateStr[8+1], expName[MAX_PATH_LEN];
3227 TokenReaderT tr;
3228 HrirDataT hData;
3229 FILE *fp;
3230 int ret;
3232 ResetHrirData(&hData);
3233 fprintf(stdout, "Reading HRIR definition from %s...\n", inName?inName:"stdin");
3234 if(inName != NULL)
3236 fp = fopen(inName, "r");
3237 if(fp == NULL)
3239 fprintf(stderr, "Error: Could not open definition file '%s'\n", inName);
3240 return 0;
3242 TrSetup(fp, inName, &tr);
3244 else
3246 fp = stdin;
3247 TrSetup(fp, "<stdin>", &tr);
3249 if(!ProcessMetrics(&tr, fftSize, truncSize, &hData))
3251 if(inName != NULL)
3252 fclose(fp);
3253 return 0;
3255 if(!ProcessSources(model, &tr, &hData))
3257 FreeHrirData(&hData);
3258 if(inName != NULL)
3259 fclose(fp);
3260 return 0;
3262 if(fp != stdin)
3263 fclose(fp);
3264 if(equalize)
3266 uint c = (hData.mChannelType == CT_STEREO) ? 2 : 1;
3267 uint m = 1 + hData.mFftSize / 2;
3268 double *dfa = CreateDoubles(c * m);
3270 fprintf(stdout, "Calculating diffuse-field average...\n");
3271 CalculateDiffuseFieldAverage(&hData, c, m, surface, limit, dfa);
3272 fprintf(stdout, "Performing diffuse-field equalization...\n");
3273 DiffuseFieldEqualize(c, m, dfa, &hData);
3274 free(dfa);
3276 fprintf(stdout, "Performing minimum phase reconstruction...\n");
3277 ReconstructHrirs(&hData);
3278 if(outRate != 0 && outRate != hData.mIrRate)
3280 fprintf(stdout, "Resampling HRIRs...\n");
3281 ResampleHrirs(outRate, &hData);
3283 fprintf(stdout, "Truncating minimum-phase HRIRs...\n");
3284 hData.mIrPoints = truncSize;
3285 fprintf(stdout, "Synthesizing missing elevations...\n");
3286 if(model == HM_DATASET)
3287 SynthesizeOnsets(&hData);
3288 SynthesizeHrirs(&hData);
3289 fprintf(stdout, "Normalizing final HRIRs...\n");
3290 NormalizeHrirs(&hData);
3291 fprintf(stdout, "Calculating impulse delays...\n");
3292 CalculateHrtds(model, (radius > DEFAULT_CUSTOM_RADIUS) ? radius : hData.mRadius, &hData);
3293 snprintf(rateStr, 8, "%u", hData.mIrRate);
3294 StrSubst(outName, "%r", rateStr, MAX_PATH_LEN, expName);
3295 fprintf(stdout, "Creating MHR data set %s...\n", expName);
3296 ret = StoreMhr(&hData, expName);
3298 FreeHrirData(&hData);
3299 return ret;
3302 static void PrintHelp(const char *argv0, FILE *ofile)
3304 fprintf(ofile, "Usage: %s [<option>...]\n\n", argv0);
3305 fprintf(ofile, "Options:\n");
3306 fprintf(ofile, " -m Ignored for compatibility.\n");
3307 fprintf(ofile, " -r <rate> Change the data set sample rate to the specified value and\n");
3308 fprintf(ofile, " resample the HRIRs accordingly.\n");
3309 fprintf(ofile, " -f <points> Override the FFT window size (default: %u).\n", DEFAULT_FFTSIZE);
3310 fprintf(ofile, " -e {on|off} Toggle diffuse-field equalization (default: %s).\n", (DEFAULT_EQUALIZE ? "on" : "off"));
3311 fprintf(ofile, " -s {on|off} Toggle surface-weighted diffuse-field average (default: %s).\n", (DEFAULT_SURFACE ? "on" : "off"));
3312 fprintf(ofile, " -l {<dB>|none} Specify a limit to the magnitude range of the diffuse-field\n");
3313 fprintf(ofile, " average (default: %.2f).\n", DEFAULT_LIMIT);
3314 fprintf(ofile, " -w <points> Specify the size of the truncation window that's applied\n");
3315 fprintf(ofile, " after minimum-phase reconstruction (default: %u).\n", DEFAULT_TRUNCSIZE);
3316 fprintf(ofile, " -d {dataset| Specify the model used for calculating the head-delay timing\n");
3317 fprintf(ofile, " sphere} values (default: %s).\n", ((DEFAULT_HEAD_MODEL == HM_DATASET) ? "dataset" : "sphere"));
3318 fprintf(ofile, " -c <size> Use a customized head radius measured ear-to-ear in meters.\n");
3319 fprintf(ofile, " -i <filename> Specify an HRIR definition file to use (defaults to stdin).\n");
3320 fprintf(ofile, " -o <filename> Specify an output file. Use of '%%r' will be substituted with\n");
3321 fprintf(ofile, " the data set sample rate.\n");
3324 // Standard command line dispatch.
3325 int main(int argc, char *argv[])
3327 const char *inName = NULL, *outName = NULL;
3328 uint outRate, fftSize;
3329 int equalize, surface;
3330 char *end = NULL;
3331 HeadModelT model;
3332 uint truncSize;
3333 double radius;
3334 double limit;
3335 int opt;
3337 GET_UNICODE_ARGS(&argc, &argv);
3339 if(argc < 2)
3341 fprintf(stdout, "HRTF Processing and Composition Utility\n\n");
3342 PrintHelp(argv[0], stdout);
3343 exit(EXIT_SUCCESS);
3346 outName = "./oalsoft_hrtf_%r.mhr";
3347 outRate = 0;
3348 fftSize = 0;
3349 equalize = DEFAULT_EQUALIZE;
3350 surface = DEFAULT_SURFACE;
3351 limit = DEFAULT_LIMIT;
3352 truncSize = DEFAULT_TRUNCSIZE;
3353 model = DEFAULT_HEAD_MODEL;
3354 radius = DEFAULT_CUSTOM_RADIUS;
3356 while((opt=getopt(argc, argv, "mr:f:e:s:l:w:d:c:e:i:o:h")) != -1)
3358 switch(opt)
3360 case 'm':
3361 fprintf(stderr, "Ignoring unused command '-m'.\n");
3362 break;
3364 case 'r':
3365 outRate = strtoul(optarg, &end, 10);
3366 if(end[0] != '\0' || outRate < MIN_RATE || outRate > MAX_RATE)
3368 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected between %u to %u.\n", optarg, opt, MIN_RATE, MAX_RATE);
3369 exit(EXIT_FAILURE);
3371 break;
3373 case 'f':
3374 fftSize = strtoul(optarg, &end, 10);
3375 if(end[0] != '\0' || (fftSize&(fftSize-1)) || fftSize < MIN_FFTSIZE || fftSize > MAX_FFTSIZE)
3377 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected a power-of-two between %u to %u.\n", optarg, opt, MIN_FFTSIZE, MAX_FFTSIZE);
3378 exit(EXIT_FAILURE);
3380 break;
3382 case 'e':
3383 if(strcmp(optarg, "on") == 0)
3384 equalize = 1;
3385 else if(strcmp(optarg, "off") == 0)
3386 equalize = 0;
3387 else
3389 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected on or off.\n", optarg, opt);
3390 exit(EXIT_FAILURE);
3392 break;
3394 case 's':
3395 if(strcmp(optarg, "on") == 0)
3396 surface = 1;
3397 else if(strcmp(optarg, "off") == 0)
3398 surface = 0;
3399 else
3401 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected on or off.\n", optarg, opt);
3402 exit(EXIT_FAILURE);
3404 break;
3406 case 'l':
3407 if(strcmp(optarg, "none") == 0)
3408 limit = 0.0;
3409 else
3411 limit = strtod(optarg, &end);
3412 if(end[0] != '\0' || limit < MIN_LIMIT || limit > MAX_LIMIT)
3414 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected between %.0f to %.0f.\n", optarg, opt, MIN_LIMIT, MAX_LIMIT);
3415 exit(EXIT_FAILURE);
3418 break;
3420 case 'w':
3421 truncSize = strtoul(optarg, &end, 10);
3422 if(end[0] != '\0' || truncSize < MIN_TRUNCSIZE || truncSize > MAX_TRUNCSIZE || (truncSize%MOD_TRUNCSIZE))
3424 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected multiple of %u between %u to %u.\n", optarg, opt, MOD_TRUNCSIZE, MIN_TRUNCSIZE, MAX_TRUNCSIZE);
3425 exit(EXIT_FAILURE);
3427 break;
3429 case 'd':
3430 if(strcmp(optarg, "dataset") == 0)
3431 model = HM_DATASET;
3432 else if(strcmp(optarg, "sphere") == 0)
3433 model = HM_SPHERE;
3434 else
3436 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected dataset or sphere.\n", optarg, opt);
3437 exit(EXIT_FAILURE);
3439 break;
3441 case 'c':
3442 radius = strtod(optarg, &end);
3443 if(end[0] != '\0' || radius < MIN_CUSTOM_RADIUS || radius > MAX_CUSTOM_RADIUS)
3445 fprintf(stderr, "Error: Got unexpected value \"%s\" for option -%c, expected between %.2f to %.2f.\n", optarg, opt, MIN_CUSTOM_RADIUS, MAX_CUSTOM_RADIUS);
3446 exit(EXIT_FAILURE);
3448 break;
3450 case 'i':
3451 inName = optarg;
3452 break;
3454 case 'o':
3455 outName = optarg;
3456 break;
3458 case 'h':
3459 PrintHelp(argv[0], stdout);
3460 exit(EXIT_SUCCESS);
3462 default: /* '?' */
3463 PrintHelp(argv[0], stderr);
3464 exit(EXIT_FAILURE);
3468 if(!ProcessDefinition(inName, outRate, fftSize, equalize, surface, limit,
3469 truncSize, model, radius, outName))
3470 return -1;
3471 fprintf(stdout, "Operation completed.\n");
3473 return EXIT_SUCCESS;