2 * OpenAL cross platform audio library
3 * Copyright (C) 1999-2010 by authors.
4 * This library is free software; you can redistribute it and/or
5 * modify it under the terms of the GNU Library General Public
6 * License as published by the Free Software Foundation; either
7 * version 2 of the License, or (at your option) any later version.
9 * This library is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
12 * Library General Public License for more details.
14 * You should have received a copy of the GNU Library General Public
15 * License along with this library; if not, write to the
16 * Free Software Foundation, Inc.,
17 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
18 * Or go to http://www.gnu.org/copyleft/lgpl.html
30 #include "alAuxEffectSlot.h"
34 #include "bformatdec.h"
35 #include "uhjfilter.h"
39 extern inline void CalcAngleCoeffs(ALfloat azimuth
, ALfloat elevation
, ALfloat spread
, ALfloat coeffs
[MAX_AMBI_COEFFS
]);
42 static const ALsizei FuMa2ACN
[MAX_AMBI_COEFFS
] = {
60 static const ALsizei ACN2ACN
[MAX_AMBI_COEFFS
] = {
61 0, 1, 2, 3, 4, 5, 6, 7,
62 8, 9, 10, 11, 12, 13, 14, 15
65 /* NOTE: These are scale factors as applied to Ambisonics content. Decoder
66 * coefficients should be divided by these values to get proper N3D scalings.
68 static const ALfloat UnitScale
[MAX_AMBI_COEFFS
] = {
69 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
,
70 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
, 1.0f
72 static const ALfloat SN3D2N3DScale
[MAX_AMBI_COEFFS
] = {
73 1.000000000f
, /* ACN 0 (W), sqrt(1) */
74 1.732050808f
, /* ACN 1 (Y), sqrt(3) */
75 1.732050808f
, /* ACN 2 (Z), sqrt(3) */
76 1.732050808f
, /* ACN 3 (X), sqrt(3) */
77 2.236067978f
, /* ACN 4 (V), sqrt(5) */
78 2.236067978f
, /* ACN 5 (T), sqrt(5) */
79 2.236067978f
, /* ACN 6 (R), sqrt(5) */
80 2.236067978f
, /* ACN 7 (S), sqrt(5) */
81 2.236067978f
, /* ACN 8 (U), sqrt(5) */
82 2.645751311f
, /* ACN 9 (Q), sqrt(7) */
83 2.645751311f
, /* ACN 10 (O), sqrt(7) */
84 2.645751311f
, /* ACN 11 (M), sqrt(7) */
85 2.645751311f
, /* ACN 12 (K), sqrt(7) */
86 2.645751311f
, /* ACN 13 (L), sqrt(7) */
87 2.645751311f
, /* ACN 14 (N), sqrt(7) */
88 2.645751311f
, /* ACN 15 (P), sqrt(7) */
90 static const ALfloat FuMa2N3DScale
[MAX_AMBI_COEFFS
] = {
91 1.414213562f
, /* ACN 0 (W), sqrt(2) */
92 1.732050808f
, /* ACN 1 (Y), sqrt(3) */
93 1.732050808f
, /* ACN 2 (Z), sqrt(3) */
94 1.732050808f
, /* ACN 3 (X), sqrt(3) */
95 1.936491673f
, /* ACN 4 (V), sqrt(15)/2 */
96 1.936491673f
, /* ACN 5 (T), sqrt(15)/2 */
97 2.236067978f
, /* ACN 6 (R), sqrt(5) */
98 1.936491673f
, /* ACN 7 (S), sqrt(15)/2 */
99 1.936491673f
, /* ACN 8 (U), sqrt(15)/2 */
100 2.091650066f
, /* ACN 9 (Q), sqrt(35/8) */
101 1.972026594f
, /* ACN 10 (O), sqrt(35)/3 */
102 2.231093404f
, /* ACN 11 (M), sqrt(224/45) */
103 2.645751311f
, /* ACN 12 (K), sqrt(7) */
104 2.231093404f
, /* ACN 13 (L), sqrt(224/45) */
105 1.972026594f
, /* ACN 14 (N), sqrt(35)/3 */
106 2.091650066f
, /* ACN 15 (P), sqrt(35/8) */
110 void CalcDirectionCoeffs(const ALfloat dir
[3], ALfloat spread
, ALfloat coeffs
[MAX_AMBI_COEFFS
])
112 /* Convert from OpenAL coords to Ambisonics. */
118 coeffs
[0] = 1.0f
; /* ACN 0 = 1 */
120 coeffs
[1] = 1.732050808f
* y
; /* ACN 1 = sqrt(3) * Y */
121 coeffs
[2] = 1.732050808f
* z
; /* ACN 2 = sqrt(3) * Z */
122 coeffs
[3] = 1.732050808f
* x
; /* ACN 3 = sqrt(3) * X */
124 coeffs
[4] = 3.872983346f
* x
* y
; /* ACN 4 = sqrt(15) * X * Y */
125 coeffs
[5] = 3.872983346f
* y
* z
; /* ACN 5 = sqrt(15) * Y * Z */
126 coeffs
[6] = 1.118033989f
* (3.0f
*z
*z
- 1.0f
); /* ACN 6 = sqrt(5)/2 * (3*Z*Z - 1) */
127 coeffs
[7] = 3.872983346f
* x
* z
; /* ACN 7 = sqrt(15) * X * Z */
128 coeffs
[8] = 1.936491673f
* (x
*x
- y
*y
); /* ACN 8 = sqrt(15)/2 * (X*X - Y*Y) */
130 coeffs
[9] = 2.091650066f
* y
* (3.0f
*x
*x
- y
*y
); /* ACN 9 = sqrt(35/8) * Y * (3*X*X - Y*Y) */
131 coeffs
[10] = 10.246950766f
* z
* x
* y
; /* ACN 10 = sqrt(105) * Z * X * Y */
132 coeffs
[11] = 1.620185175f
* y
* (5.0f
*z
*z
- 1.0f
); /* ACN 11 = sqrt(21/8) * Y * (5*Z*Z - 1) */
133 coeffs
[12] = 1.322875656f
* z
* (5.0f
*z
*z
- 3.0f
); /* ACN 12 = sqrt(7)/2 * Z * (5*Z*Z - 3) */
134 coeffs
[13] = 1.620185175f
* x
* (5.0f
*z
*z
- 1.0f
); /* ACN 13 = sqrt(21/8) * X * (5*Z*Z - 1) */
135 coeffs
[14] = 5.123475383f
* z
* (x
*x
- y
*y
); /* ACN 14 = sqrt(105)/2 * Z * (X*X - Y*Y) */
136 coeffs
[15] = 2.091650066f
* x
* (x
*x
- 3.0f
*y
*y
); /* ACN 15 = sqrt(35/8) * X * (X*X - 3*Y*Y) */
140 /* Implement the spread by using a spherical source that subtends the
142 * http://www.ppsloan.org/publications/StupidSH36.pdf - Appendix A3
144 * When adjusted for N3D normalization instead of SN3D, these
147 * ZH0 = -sqrt(pi) * (-1+ca);
148 * ZH1 = 0.5*sqrt(pi) * sa*sa;
149 * ZH2 = -0.5*sqrt(pi) * ca*(-1+ca)*(ca+1);
150 * ZH3 = -0.125*sqrt(pi) * (-1+ca)*(ca+1)*(5*ca*ca - 1);
151 * ZH4 = -0.125*sqrt(pi) * ca*(-1+ca)*(ca+1)*(7*ca*ca - 3);
152 * ZH5 = -0.0625*sqrt(pi) * (-1+ca)*(ca+1)*(21*ca*ca*ca*ca - 14*ca*ca + 1);
154 * The gain of the source is compensated for size, so that the
155 * loundness doesn't depend on the spread. That is, the factors are
156 * scaled so that ZH0 remains 1 regardless of the spread. Thus:
159 * ZH1 = 0.5f * (ca+1.0f);
160 * ZH2 = 0.5f * (ca+1.0f)*ca;
161 * ZH3 = 0.125f * (ca+1.0f)*(5.0f*ca*ca - 1.0f);
162 * ZH4 = 0.125f * (ca+1.0f)*(7.0f*ca*ca - 3.0f)*ca;
163 * ZH5 = 0.0625f * (ca+1.0f)*(21.0f*ca*ca*ca*ca - 14.0f*ca*ca + 1.0f);
165 ALfloat ca
= cosf(spread
* 0.5f
);
167 ALfloat ZH0_norm
= 1.0f
;
168 ALfloat ZH1_norm
= 0.5f
* (ca
+1.f
);
169 ALfloat ZH2_norm
= 0.5f
* (ca
+1.f
)*ca
;
170 ALfloat ZH3_norm
= 0.125f
* (ca
+1.f
)*(5.f
*ca
*ca
-1.f
);
173 coeffs
[0] *= ZH0_norm
;
175 coeffs
[1] *= ZH1_norm
;
176 coeffs
[2] *= ZH1_norm
;
177 coeffs
[3] *= ZH1_norm
;
179 coeffs
[4] *= ZH2_norm
;
180 coeffs
[5] *= ZH2_norm
;
181 coeffs
[6] *= ZH2_norm
;
182 coeffs
[7] *= ZH2_norm
;
183 coeffs
[8] *= ZH2_norm
;
185 coeffs
[9] *= ZH3_norm
;
186 coeffs
[10] *= ZH3_norm
;
187 coeffs
[11] *= ZH3_norm
;
188 coeffs
[12] *= ZH3_norm
;
189 coeffs
[13] *= ZH3_norm
;
190 coeffs
[14] *= ZH3_norm
;
191 coeffs
[15] *= ZH3_norm
;
195 void CalcAnglePairwiseCoeffs(ALfloat azimuth
, ALfloat elevation
, ALfloat spread
, ALfloat coeffs
[MAX_AMBI_COEFFS
])
197 ALfloat sign
= (azimuth
< 0.0f
) ? -1.0f
: 1.0f
;
198 if(!(fabsf(azimuth
) > F_PI_2
))
199 azimuth
= minf(fabsf(azimuth
) * F_PI_2
/ (F_PI
/6.0f
), F_PI_2
) * sign
;
200 CalcAngleCoeffs(azimuth
, elevation
, spread
, coeffs
);
204 void ComputeAmbientGainsMC(const ChannelConfig
*chancoeffs
, ALsizei numchans
, ALfloat ingain
, ALfloat gains
[MAX_OUTPUT_CHANNELS
])
208 for(i
= 0;i
< numchans
;i
++)
209 gains
[i
] = chancoeffs
[i
][0] * 1.414213562f
* ingain
;
210 for(;i
< MAX_OUTPUT_CHANNELS
;i
++)
214 void ComputeAmbientGainsBF(const BFChannelConfig
*chanmap
, ALsizei numchans
, ALfloat ingain
, ALfloat gains
[MAX_OUTPUT_CHANNELS
])
219 for(i
= 0;i
< numchans
;i
++)
221 if(chanmap
[i
].Index
== 0)
222 gain
+= chanmap
[i
].Scale
;
224 gains
[0] = gain
* 1.414213562f
* ingain
;
225 for(i
= 1;i
< MAX_OUTPUT_CHANNELS
;i
++)
229 void ComputePanningGainsMC(const ChannelConfig
*chancoeffs
, ALsizei numchans
, ALsizei numcoeffs
, const ALfloat coeffs
[MAX_AMBI_COEFFS
], ALfloat ingain
, ALfloat gains
[MAX_OUTPUT_CHANNELS
])
233 for(i
= 0;i
< numchans
;i
++)
236 for(j
= 0;j
< numcoeffs
;j
++)
237 gain
+= chancoeffs
[i
][j
]*coeffs
[j
];
238 gains
[i
] = clampf(gain
, 0.0f
, 1.0f
) * ingain
;
240 for(;i
< MAX_OUTPUT_CHANNELS
;i
++)
244 void ComputePanningGainsBF(const BFChannelConfig
*chanmap
, ALsizei numchans
, const ALfloat coeffs
[MAX_AMBI_COEFFS
], ALfloat ingain
, ALfloat gains
[MAX_OUTPUT_CHANNELS
])
248 for(i
= 0;i
< numchans
;i
++)
249 gains
[i
] = chanmap
[i
].Scale
* coeffs
[chanmap
[i
].Index
] * ingain
;
250 for(;i
< MAX_OUTPUT_CHANNELS
;i
++)
254 void ComputeFirstOrderGainsMC(const ChannelConfig
*chancoeffs
, ALsizei numchans
, const ALfloat mtx
[4], ALfloat ingain
, ALfloat gains
[MAX_OUTPUT_CHANNELS
])
258 for(i
= 0;i
< numchans
;i
++)
262 gain
+= chancoeffs
[i
][j
] * mtx
[j
];
263 gains
[i
] = clampf(gain
, 0.0f
, 1.0f
) * ingain
;
265 for(;i
< MAX_OUTPUT_CHANNELS
;i
++)
269 void ComputeFirstOrderGainsBF(const BFChannelConfig
*chanmap
, ALsizei numchans
, const ALfloat mtx
[4], ALfloat ingain
, ALfloat gains
[MAX_OUTPUT_CHANNELS
])
273 for(i
= 0;i
< numchans
;i
++)
274 gains
[i
] = chanmap
[i
].Scale
* mtx
[chanmap
[i
].Index
] * ingain
;
275 for(;i
< MAX_OUTPUT_CHANNELS
;i
++)
280 static inline const char *GetLabelFromChannel(enum Channel channel
)
284 case FrontLeft
: return "front-left";
285 case FrontRight
: return "front-right";
286 case FrontCenter
: return "front-center";
287 case LFE
: return "lfe";
288 case BackLeft
: return "back-left";
289 case BackRight
: return "back-right";
290 case BackCenter
: return "back-center";
291 case SideLeft
: return "side-left";
292 case SideRight
: return "side-right";
294 case UpperFrontLeft
: return "upper-front-left";
295 case UpperFrontRight
: return "upper-front-right";
296 case UpperBackLeft
: return "upper-back-left";
297 case UpperBackRight
: return "upper-back-right";
298 case LowerFrontLeft
: return "lower-front-left";
299 case LowerFrontRight
: return "lower-front-right";
300 case LowerBackLeft
: return "lower-back-left";
301 case LowerBackRight
: return "lower-back-right";
303 case Aux0
: return "aux-0";
304 case Aux1
: return "aux-1";
305 case Aux2
: return "aux-2";
306 case Aux3
: return "aux-3";
307 case Aux4
: return "aux-4";
308 case Aux5
: return "aux-5";
309 case Aux6
: return "aux-6";
310 case Aux7
: return "aux-7";
311 case Aux8
: return "aux-8";
312 case Aux9
: return "aux-9";
313 case Aux10
: return "aux-10";
314 case Aux11
: return "aux-11";
315 case Aux12
: return "aux-12";
316 case Aux13
: return "aux-13";
317 case Aux14
: return "aux-14";
318 case Aux15
: return "aux-15";
320 case InvalidChannel
: break;
326 typedef struct ChannelMap
{
327 enum Channel ChanName
;
328 ChannelConfig Config
;
331 static void SetChannelMap(const enum Channel
*devchans
, ChannelConfig
*ambicoeffs
,
332 const ChannelMap
*chanmap
, size_t count
, ALsizei
*outcount
)
337 for(i
= 0;i
< MAX_OUTPUT_CHANNELS
&& devchans
[i
] != InvalidChannel
;i
++)
339 if(devchans
[i
] == LFE
)
341 for(j
= 0;j
< MAX_AMBI_COEFFS
;j
++)
342 ambicoeffs
[i
][j
] = 0.0f
;
346 for(j
= 0;j
< count
;j
++)
348 if(devchans
[i
] != chanmap
[j
].ChanName
)
351 for(k
= 0;k
< MAX_AMBI_COEFFS
;++k
)
352 ambicoeffs
[i
][k
] = chanmap
[j
].Config
[k
];
356 ERR("Failed to match %s channel (%u) in channel map\n", GetLabelFromChannel(devchans
[i
]), i
);
361 static bool MakeSpeakerMap(ALCdevice
*device
, const AmbDecConf
*conf
, ALsizei speakermap
[MAX_OUTPUT_CHANNELS
])
365 for(i
= 0;i
< conf
->NumSpeakers
;i
++)
369 /* NOTE: AmbDec does not define any standard speaker names, however
370 * for this to work we have to by able to find the output channel
371 * the speaker definition corresponds to. Therefore, OpenAL Soft
372 * requires these channel labels to be recognized:
383 * Additionally, surround51 will acknowledge back speakers for side
384 * channels, and surround51rear will acknowledge side speakers for
385 * back channels, to avoid issues with an ambdec expecting 5.1 to
386 * use the side channels when the device is configured for back,
389 if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "LF") == 0)
390 c
= GetChannelIdxByName(device
->RealOut
, FrontLeft
);
391 else if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "RF") == 0)
392 c
= GetChannelIdxByName(device
->RealOut
, FrontRight
);
393 else if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "CE") == 0)
394 c
= GetChannelIdxByName(device
->RealOut
, FrontCenter
);
395 else if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "LS") == 0)
397 if(device
->FmtChans
== DevFmtX51Rear
)
398 c
= GetChannelIdxByName(device
->RealOut
, BackLeft
);
400 c
= GetChannelIdxByName(device
->RealOut
, SideLeft
);
402 else if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "RS") == 0)
404 if(device
->FmtChans
== DevFmtX51Rear
)
405 c
= GetChannelIdxByName(device
->RealOut
, BackRight
);
407 c
= GetChannelIdxByName(device
->RealOut
, SideRight
);
409 else if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "LB") == 0)
411 if(device
->FmtChans
== DevFmtX51
)
412 c
= GetChannelIdxByName(device
->RealOut
, SideLeft
);
414 c
= GetChannelIdxByName(device
->RealOut
, BackLeft
);
416 else if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "RB") == 0)
418 if(device
->FmtChans
== DevFmtX51
)
419 c
= GetChannelIdxByName(device
->RealOut
, SideRight
);
421 c
= GetChannelIdxByName(device
->RealOut
, BackRight
);
423 else if(alstr_cmp_cstr(conf
->Speakers
[i
].Name
, "CB") == 0)
424 c
= GetChannelIdxByName(device
->RealOut
, BackCenter
);
427 const char *name
= alstr_get_cstr(conf
->Speakers
[i
].Name
);
431 if(sscanf(name
, "AUX%u%c", &n
, &ch
) == 1 && n
< 16)
432 c
= GetChannelIdxByName(device
->RealOut
, Aux0
+n
);
435 ERR("AmbDec speaker label \"%s\" not recognized\n", name
);
441 ERR("Failed to lookup AmbDec speaker label %s\n",
442 alstr_get_cstr(conf
->Speakers
[i
].Name
));
452 static const ChannelMap MonoCfg
[1] = {
453 { FrontCenter
, { 1.0f
} },
455 { FrontLeft
, { 5.00000000e-1f
, 2.88675135e-1f
, 0.0f
, 1.19573156e-1f
} },
456 { FrontRight
, { 5.00000000e-1f
, -2.88675135e-1f
, 0.0f
, 1.19573156e-1f
} },
458 { BackLeft
, { 3.53553391e-1f
, 2.04124145e-1f
, 0.0f
, -2.04124145e-1f
} },
459 { FrontLeft
, { 3.53553391e-1f
, 2.04124145e-1f
, 0.0f
, 2.04124145e-1f
} },
460 { FrontRight
, { 3.53553391e-1f
, -2.04124145e-1f
, 0.0f
, 2.04124145e-1f
} },
461 { BackRight
, { 3.53553391e-1f
, -2.04124145e-1f
, 0.0f
, -2.04124145e-1f
} },
463 { SideLeft
, { 3.33001372e-1f
, 1.89085671e-1f
, 0.0f
, -2.00041334e-1f
, -2.12309737e-2f
, 0.0f
, 0.0f
, 0.0f
, -1.14573483e-2f
} },
464 { FrontLeft
, { 1.47751298e-1f
, 1.28994110e-1f
, 0.0f
, 1.15190495e-1f
, 7.44949143e-2f
, 0.0f
, 0.0f
, 0.0f
, -6.47739980e-3f
} },
465 { FrontCenter
, { 7.73595729e-2f
, 0.00000000e+0f
, 0.0f
, 9.71390298e-2f
, 0.00000000e+0f
, 0.0f
, 0.0f
, 0.0f
, 5.18625335e-2f
} },
466 { FrontRight
, { 1.47751298e-1f
, -1.28994110e-1f
, 0.0f
, 1.15190495e-1f
, -7.44949143e-2f
, 0.0f
, 0.0f
, 0.0f
, -6.47739980e-3f
} },
467 { SideRight
, { 3.33001372e-1f
, -1.89085671e-1f
, 0.0f
, -2.00041334e-1f
, 2.12309737e-2f
, 0.0f
, 0.0f
, 0.0f
, -1.14573483e-2f
} },
469 { BackLeft
, { 3.33001372e-1f
, 1.89085671e-1f
, 0.0f
, -2.00041334e-1f
, -2.12309737e-2f
, 0.0f
, 0.0f
, 0.0f
, -1.14573483e-2f
} },
470 { FrontLeft
, { 1.47751298e-1f
, 1.28994110e-1f
, 0.0f
, 1.15190495e-1f
, 7.44949143e-2f
, 0.0f
, 0.0f
, 0.0f
, -6.47739980e-3f
} },
471 { FrontCenter
, { 7.73595729e-2f
, 0.00000000e+0f
, 0.0f
, 9.71390298e-2f
, 0.00000000e+0f
, 0.0f
, 0.0f
, 0.0f
, 5.18625335e-2f
} },
472 { FrontRight
, { 1.47751298e-1f
, -1.28994110e-1f
, 0.0f
, 1.15190495e-1f
, -7.44949143e-2f
, 0.0f
, 0.0f
, 0.0f
, -6.47739980e-3f
} },
473 { BackRight
, { 3.33001372e-1f
, -1.89085671e-1f
, 0.0f
, -2.00041334e-1f
, 2.12309737e-2f
, 0.0f
, 0.0f
, 0.0f
, -1.14573483e-2f
} },
475 { SideLeft
, { 2.04462744e-1f
, 2.17178497e-1f
, 0.0f
, -4.39990188e-2f
, -2.60787329e-2f
, 0.0f
, 0.0f
, 0.0f
, -6.87238843e-2f
} },
476 { FrontLeft
, { 1.18130342e-1f
, 9.34633906e-2f
, 0.0f
, 1.08553749e-1f
, 6.80658795e-2f
, 0.0f
, 0.0f
, 0.0f
, 1.08999485e-2f
} },
477 { FrontCenter
, { 7.73595729e-2f
, 0.00000000e+0f
, 0.0f
, 9.71390298e-2f
, 0.00000000e+0f
, 0.0f
, 0.0f
, 0.0f
, 5.18625335e-2f
} },
478 { FrontRight
, { 1.18130342e-1f
, -9.34633906e-2f
, 0.0f
, 1.08553749e-1f
, -6.80658795e-2f
, 0.0f
, 0.0f
, 0.0f
, 1.08999485e-2f
} },
479 { SideRight
, { 2.04462744e-1f
, -2.17178497e-1f
, 0.0f
, -4.39990188e-2f
, 2.60787329e-2f
, 0.0f
, 0.0f
, 0.0f
, -6.87238843e-2f
} },
480 { BackCenter
, { 2.50001688e-1f
, 0.00000000e+0f
, 0.0f
, -2.50000094e-1f
, 0.00000000e+0f
, 0.0f
, 0.0f
, 0.0f
, 6.05133395e-2f
} },
482 { BackLeft
, { 2.04124145e-1f
, 1.08880247e-1f
, 0.0f
, -1.88586120e-1f
, -1.29099444e-1f
, 0.0f
, 0.0f
, 0.0f
, 7.45355993e-2f
, 3.73460789e-2f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.00000000e+0f
} },
483 { SideLeft
, { 2.04124145e-1f
, 2.17760495e-1f
, 0.0f
, 0.00000000e+0f
, 0.00000000e+0f
, 0.0f
, 0.0f
, 0.0f
, -1.49071198e-1f
, -3.73460789e-2f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.00000000e+0f
} },
484 { FrontLeft
, { 2.04124145e-1f
, 1.08880247e-1f
, 0.0f
, 1.88586120e-1f
, 1.29099444e-1f
, 0.0f
, 0.0f
, 0.0f
, 7.45355993e-2f
, 3.73460789e-2f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.00000000e+0f
} },
485 { FrontRight
, { 2.04124145e-1f
, -1.08880247e-1f
, 0.0f
, 1.88586120e-1f
, -1.29099444e-1f
, 0.0f
, 0.0f
, 0.0f
, 7.45355993e-2f
, -3.73460789e-2f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.00000000e+0f
} },
486 { SideRight
, { 2.04124145e-1f
, -2.17760495e-1f
, 0.0f
, 0.00000000e+0f
, 0.00000000e+0f
, 0.0f
, 0.0f
, 0.0f
, -1.49071198e-1f
, 3.73460789e-2f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.00000000e+0f
} },
487 { BackRight
, { 2.04124145e-1f
, -1.08880247e-1f
, 0.0f
, -1.88586120e-1f
, 1.29099444e-1f
, 0.0f
, 0.0f
, 0.0f
, 7.45355993e-2f
, -3.73460789e-2f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.0f
, 0.00000000e+0f
} },
490 static void InitNearFieldCtrl(ALCdevice
*device
, ALfloat ctrl_dist
, ALsizei order
, bool periphonic
)
492 const char *devname
= alstr_get_cstr(device
->DeviceName
);
495 if(GetConfigValueBool(devname
, "decoder", "nfc", 1) && ctrl_dist
> 0.0f
)
497 /* NFC is only used when AvgSpeakerDist is greater than 0, and
498 * METERS_PER_UNIT is also greater than 0. In addition, NFC can only be
499 * used when rendering to an ambisonic buffer.
501 device
->AvgSpeakerDist
= ctrl_dist
;
503 device
->Dry
.NumChannelsPerOrder
[0] = 1;
505 for(i
= 1;i
< order
+1;i
++)
506 device
->Dry
.NumChannelsPerOrder
[i
] = (i
+1)*(i
+1) - i
*i
;
508 for(i
= 1;i
< order
+1;i
++)
509 device
->Dry
.NumChannelsPerOrder
[i
] = (i
*2+1) - ((i
-1)*2+1);
510 for(;i
< MAX_AMBI_ORDER
+1;i
++)
511 device
->Dry
.NumChannelsPerOrder
[i
] = 0;
515 static void InitDistanceComp(ALCdevice
*device
, const AmbDecConf
*conf
, const ALsizei speakermap
[MAX_OUTPUT_CHANNELS
])
517 const char *devname
= alstr_get_cstr(device
->DeviceName
);
518 ALfloat maxdist
= 0.0f
;
522 for(i
= 0;i
< conf
->NumSpeakers
;i
++)
523 maxdist
= maxf(maxdist
, conf
->Speakers
[i
].Distance
);
525 if(GetConfigValueBool(devname
, "decoder", "distance-comp", 1) && maxdist
> 0.0f
)
527 ALfloat srate
= (ALfloat
)device
->Frequency
;
528 for(i
= 0;i
< conf
->NumSpeakers
;i
++)
530 ALsizei chan
= speakermap
[i
];
533 /* Distance compensation only delays in steps of the sample rate.
534 * This is a bit less accurate since the delay time falls to the
535 * nearest sample time, but it's far simpler as it doesn't have to
536 * deal with phase offsets. This means at 48khz, for instance, the
537 * distance delay will be in steps of about 7 millimeters.
539 delay
= floorf((maxdist
-conf
->Speakers
[i
].Distance
) / SPEEDOFSOUNDMETRESPERSEC
*
541 if(delay
>= (ALfloat
)MAX_DELAY_LENGTH
)
542 ERR("Delay for speaker \"%s\" exceeds buffer length (%f >= %u)\n",
543 alstr_get_cstr(conf
->Speakers
[i
].Name
), delay
, MAX_DELAY_LENGTH
);
545 device
->ChannelDelay
[chan
].Length
= (ALsizei
)clampf(
546 delay
, 0.0f
, (ALfloat
)(MAX_DELAY_LENGTH
-1)
548 device
->ChannelDelay
[chan
].Gain
= conf
->Speakers
[i
].Distance
/ maxdist
;
549 TRACE("Channel %u \"%s\" distance compensation: %d samples, %f gain\n", chan
,
550 alstr_get_cstr(conf
->Speakers
[i
].Name
), device
->ChannelDelay
[chan
].Length
,
551 device
->ChannelDelay
[chan
].Gain
554 /* Round up to the next 4th sample, so each channel buffer starts
557 total
+= RoundUp(device
->ChannelDelay
[chan
].Length
, 4);
563 device
->ChannelDelay
[0].Buffer
= al_calloc(16, total
* sizeof(ALfloat
));
564 for(i
= 1;i
< MAX_OUTPUT_CHANNELS
;i
++)
566 size_t len
= RoundUp(device
->ChannelDelay
[i
-1].Length
, 4);
567 device
->ChannelDelay
[i
].Buffer
= device
->ChannelDelay
[i
-1].Buffer
+ len
;
572 static void InitPanning(ALCdevice
*device
)
574 const ChannelMap
*chanmap
= NULL
;
575 ALsizei coeffcount
= 0;
579 switch(device
->FmtChans
)
582 count
= COUNTOF(MonoCfg
);
588 count
= COUNTOF(StereoCfg
);
594 count
= COUNTOF(QuadCfg
);
600 count
= COUNTOF(X51SideCfg
);
601 chanmap
= X51SideCfg
;
606 count
= COUNTOF(X51RearCfg
);
607 chanmap
= X51RearCfg
;
612 count
= COUNTOF(X61Cfg
);
618 count
= COUNTOF(X71Cfg
);
627 if(device
->FmtChans
== DevFmtAmbi3D
)
629 const char *devname
= alstr_get_cstr(device
->DeviceName
);
630 const ALsizei
*acnmap
= (device
->AmbiLayout
== AmbiLayout_FuMa
) ? FuMa2ACN
: ACN2ACN
;
631 const ALfloat
*n3dscale
= (device
->AmbiScale
== AmbiNorm_FuMa
) ? FuMa2N3DScale
:
632 (device
->AmbiScale
== AmbiNorm_SN3D
) ? SN3D2N3DScale
:
633 /*(device->AmbiScale == AmbiNorm_N3D) ?*/ UnitScale
;
634 ALfloat nfc_delay
= 0.0f
;
636 count
= (device
->AmbiOrder
== 3) ? 16 :
637 (device
->AmbiOrder
== 2) ? 9 :
638 (device
->AmbiOrder
== 1) ? 4 : 1;
639 for(i
= 0;i
< count
;i
++)
641 ALsizei acn
= acnmap
[i
];
642 device
->Dry
.Ambi
.Map
[i
].Scale
= 1.0f
/n3dscale
[acn
];
643 device
->Dry
.Ambi
.Map
[i
].Index
= acn
;
645 device
->Dry
.CoeffCount
= 0;
646 device
->Dry
.NumChannels
= count
;
648 if(device
->AmbiOrder
< 2)
650 device
->FOAOut
.Ambi
= device
->Dry
.Ambi
;
651 device
->FOAOut
.CoeffCount
= device
->Dry
.CoeffCount
;
652 device
->FOAOut
.NumChannels
= 0;
656 /* FOA output is always ACN+N3D for higher-order ambisonic output.
657 * The upsampler expects this and will convert it for output.
659 memset(&device
->FOAOut
.Ambi
, 0, sizeof(device
->FOAOut
.Ambi
));
662 device
->FOAOut
.Ambi
.Map
[i
].Scale
= 1.0f
;
663 device
->FOAOut
.Ambi
.Map
[i
].Index
= i
;
665 device
->FOAOut
.CoeffCount
= 0;
666 device
->FOAOut
.NumChannels
= 4;
668 ambiup_reset(device
->AmbiUp
, device
);
671 if(ConfigValueFloat(devname
, "decoder", "nfc-ref-delay", &nfc_delay
) && nfc_delay
> 0.0f
)
673 nfc_delay
= clampf(nfc_delay
, 0.001f
, 1000.0f
);
674 InitNearFieldCtrl(device
, nfc_delay
* SPEEDOFSOUNDMETRESPERSEC
,
675 device
->AmbiOrder
, true);
680 ALfloat w_scale
, xyz_scale
;
682 SetChannelMap(device
->RealOut
.ChannelName
, device
->Dry
.Ambi
.Coeffs
,
683 chanmap
, count
, &device
->Dry
.NumChannels
);
684 device
->Dry
.CoeffCount
= coeffcount
;
686 w_scale
= (device
->Dry
.CoeffCount
> 9) ? W_SCALE2D_THIRD
:
687 (device
->Dry
.CoeffCount
> 4) ? W_SCALE2D_SECOND
: 1.0f
;
688 xyz_scale
= (device
->Dry
.CoeffCount
> 9) ? XYZ_SCALE2D_THIRD
:
689 (device
->Dry
.CoeffCount
> 4) ? XYZ_SCALE2D_SECOND
: 1.0f
;
691 memset(&device
->FOAOut
.Ambi
, 0, sizeof(device
->FOAOut
.Ambi
));
692 for(i
= 0;i
< device
->Dry
.NumChannels
;i
++)
694 device
->FOAOut
.Ambi
.Coeffs
[i
][0] = device
->Dry
.Ambi
.Coeffs
[i
][0] * w_scale
;
696 device
->FOAOut
.Ambi
.Coeffs
[i
][j
] = device
->Dry
.Ambi
.Coeffs
[i
][j
] * xyz_scale
;
698 device
->FOAOut
.CoeffCount
= 4;
699 device
->FOAOut
.NumChannels
= 0;
701 device
->RealOut
.NumChannels
= 0;
704 static void InitCustomPanning(ALCdevice
*device
, const AmbDecConf
*conf
, const ALsizei speakermap
[MAX_OUTPUT_CHANNELS
])
706 ChannelMap chanmap
[MAX_OUTPUT_CHANNELS
];
707 const ALfloat
*coeff_scale
= UnitScale
;
708 ALfloat w_scale
= 1.0f
;
709 ALfloat xyz_scale
= 1.0f
;
712 if(conf
->FreqBands
!= 1)
713 ERR("Basic renderer uses the high-frequency matrix as single-band (xover_freq = %.0fhz)\n",
716 if((conf
->ChanMask
&AMBI_PERIPHONIC_MASK
))
718 if(conf
->ChanMask
> 0x1ff)
720 w_scale
= W_SCALE3D_THIRD
;
721 xyz_scale
= XYZ_SCALE3D_THIRD
;
723 else if(conf
->ChanMask
> 0xf)
725 w_scale
= W_SCALE3D_SECOND
;
726 xyz_scale
= XYZ_SCALE3D_SECOND
;
731 if(conf
->ChanMask
> 0x1ff)
733 w_scale
= W_SCALE2D_THIRD
;
734 xyz_scale
= XYZ_SCALE2D_THIRD
;
736 else if(conf
->ChanMask
> 0xf)
738 w_scale
= W_SCALE2D_SECOND
;
739 xyz_scale
= XYZ_SCALE2D_SECOND
;
743 if(conf
->CoeffScale
== ADS_SN3D
)
744 coeff_scale
= SN3D2N3DScale
;
745 else if(conf
->CoeffScale
== ADS_FuMa
)
746 coeff_scale
= FuMa2N3DScale
;
748 for(i
= 0;i
< conf
->NumSpeakers
;i
++)
750 ALsizei chan
= speakermap
[i
];
754 for(j
= 0;j
< MAX_AMBI_COEFFS
;j
++)
755 chanmap
[i
].Config
[j
] = 0.0f
;
757 chanmap
[i
].ChanName
= device
->RealOut
.ChannelName
[chan
];
758 for(j
= 0;j
< MAX_AMBI_COEFFS
;j
++)
760 if(j
== 0) gain
= conf
->HFOrderGain
[0];
761 else if(j
== 1) gain
= conf
->HFOrderGain
[1];
762 else if(j
== 4) gain
= conf
->HFOrderGain
[2];
763 else if(j
== 9) gain
= conf
->HFOrderGain
[3];
764 if((conf
->ChanMask
&(1<<j
)))
765 chanmap
[i
].Config
[j
] = conf
->HFMatrix
[i
][k
++] / coeff_scale
[j
] * gain
;
769 SetChannelMap(device
->RealOut
.ChannelName
, device
->Dry
.Ambi
.Coeffs
, chanmap
,
770 conf
->NumSpeakers
, &device
->Dry
.NumChannels
);
771 device
->Dry
.CoeffCount
= (conf
->ChanMask
> 0x1ff) ? 16 :
772 (conf
->ChanMask
> 0xf) ? 9 : 4;
774 memset(&device
->FOAOut
.Ambi
, 0, sizeof(device
->FOAOut
.Ambi
));
775 for(i
= 0;i
< device
->Dry
.NumChannels
;i
++)
777 device
->FOAOut
.Ambi
.Coeffs
[i
][0] = device
->Dry
.Ambi
.Coeffs
[i
][0] * w_scale
;
779 device
->FOAOut
.Ambi
.Coeffs
[i
][j
] = device
->Dry
.Ambi
.Coeffs
[i
][j
] * xyz_scale
;
781 device
->FOAOut
.CoeffCount
= 4;
782 device
->FOAOut
.NumChannels
= 0;
784 device
->RealOut
.NumChannels
= 0;
786 InitDistanceComp(device
, conf
, speakermap
);
789 static void InitHQPanning(ALCdevice
*device
, const AmbDecConf
*conf
, const ALsizei speakermap
[MAX_OUTPUT_CHANNELS
])
795 if((conf
->ChanMask
&AMBI_PERIPHONIC_MASK
))
797 count
= (conf
->ChanMask
> 0x1ff) ? 16 :
798 (conf
->ChanMask
> 0xf) ? 9 : 4;
799 for(i
= 0;i
< count
;i
++)
801 device
->Dry
.Ambi
.Map
[i
].Scale
= 1.0f
;
802 device
->Dry
.Ambi
.Map
[i
].Index
= i
;
807 static const int map
[MAX_AMBI2D_COEFFS
] = { 0, 1, 3, 4, 8, 9, 15 };
809 count
= (conf
->ChanMask
> 0x1ff) ? 7 :
810 (conf
->ChanMask
> 0xf) ? 5 : 3;
811 for(i
= 0;i
< count
;i
++)
813 device
->Dry
.Ambi
.Map
[i
].Scale
= 1.0f
;
814 device
->Dry
.Ambi
.Map
[i
].Index
= map
[i
];
817 device
->Dry
.CoeffCount
= 0;
818 device
->Dry
.NumChannels
= count
;
820 TRACE("Enabling %s-band %s-order%s ambisonic decoder\n",
821 (conf
->FreqBands
== 1) ? "single" : "dual",
822 (conf
->ChanMask
> 0xf) ? (conf
->ChanMask
> 0x1ff) ? "third" : "second" : "first",
823 (conf
->ChanMask
&AMBI_PERIPHONIC_MASK
) ? " periphonic" : ""
825 bformatdec_reset(device
->AmbiDecoder
, conf
, count
, device
->Frequency
, speakermap
);
827 if(!(conf
->ChanMask
> 0xf))
829 device
->FOAOut
.Ambi
= device
->Dry
.Ambi
;
830 device
->FOAOut
.CoeffCount
= device
->Dry
.CoeffCount
;
831 device
->FOAOut
.NumChannels
= 0;
835 memset(&device
->FOAOut
.Ambi
, 0, sizeof(device
->FOAOut
.Ambi
));
836 if((conf
->ChanMask
&AMBI_PERIPHONIC_MASK
))
839 for(i
= 0;i
< count
;i
++)
841 device
->FOAOut
.Ambi
.Map
[i
].Scale
= 1.0f
;
842 device
->FOAOut
.Ambi
.Map
[i
].Index
= i
;
847 static const int map
[3] = { 0, 1, 3 };
849 for(i
= 0;i
< count
;i
++)
851 device
->FOAOut
.Ambi
.Map
[i
].Scale
= 1.0f
;
852 device
->FOAOut
.Ambi
.Map
[i
].Index
= map
[i
];
855 device
->FOAOut
.CoeffCount
= 0;
856 device
->FOAOut
.NumChannels
= count
;
859 device
->RealOut
.NumChannels
= ChannelsFromDevFmt(device
->FmtChans
, device
->AmbiOrder
);
862 for(i
= 0;i
< conf
->NumSpeakers
;i
++)
863 avg_dist
+= conf
->Speakers
[i
].Distance
;
864 avg_dist
/= (ALfloat
)conf
->NumSpeakers
;
865 InitNearFieldCtrl(device
, avg_dist
,
866 (conf
->ChanMask
> 0x1ff) ? 3 : (conf
->ChanMask
> 0xf) ? 2 : 1,
867 !!(conf
->ChanMask
&AMBI_PERIPHONIC_MASK
)
870 InitDistanceComp(device
, conf
, speakermap
);
873 static void InitHrtfPanning(ALCdevice
*device
)
875 /* NOTE: azimuth goes clockwise. */
876 static const ALfloat AmbiPoints
[][2] = {
877 { DEG2RAD( 90.0f
), DEG2RAD( 0.0f
) },
878 { DEG2RAD( 35.0f
), DEG2RAD( -45.0f
) },
879 { DEG2RAD( 35.0f
), DEG2RAD( 45.0f
) },
880 { DEG2RAD( 35.0f
), DEG2RAD( 135.0f
) },
881 { DEG2RAD( 35.0f
), DEG2RAD(-135.0f
) },
882 { DEG2RAD( 0.0f
), DEG2RAD( 0.0f
) },
883 { DEG2RAD( 0.0f
), DEG2RAD( 90.0f
) },
884 { DEG2RAD( 0.0f
), DEG2RAD( 180.0f
) },
885 { DEG2RAD( 0.0f
), DEG2RAD( -90.0f
) },
886 { DEG2RAD(-35.0f
), DEG2RAD( -45.0f
) },
887 { DEG2RAD(-35.0f
), DEG2RAD( 45.0f
) },
888 { DEG2RAD(-35.0f
), DEG2RAD( 135.0f
) },
889 { DEG2RAD(-35.0f
), DEG2RAD(-135.0f
) },
890 { DEG2RAD(-90.0f
), DEG2RAD( 0.0f
) },
892 static const ALfloat AmbiMatrixFOA
[][2][MAX_AMBI_COEFFS
] = {
893 { { 1.88982237e-001f
, 0.00000000e+000f
, 1.90399923e-001f
, 0.00000000e+000f
}, { 7.14285714e-002f
, 0.00000000e+000f
, 1.24646009e-001f
, 0.00000000e+000f
} },
894 { { 1.88982237e-001f
, 1.09057783e-001f
, 1.09208910e-001f
, 1.09057783e-001f
}, { 7.14285714e-002f
, 7.13950780e-002f
, 7.14940135e-002f
, 7.13950780e-002f
} },
895 { { 1.88982237e-001f
, -1.09057783e-001f
, 1.09208910e-001f
, 1.09057783e-001f
}, { 7.14285714e-002f
, -7.13950780e-002f
, 7.14940135e-002f
, 7.13950780e-002f
} },
896 { { 1.88982237e-001f
, -1.09057783e-001f
, 1.09208910e-001f
, -1.09057783e-001f
}, { 7.14285714e-002f
, -7.13950780e-002f
, 7.14940135e-002f
, -7.13950780e-002f
} },
897 { { 1.88982237e-001f
, 1.09057783e-001f
, 1.09208910e-001f
, -1.09057783e-001f
}, { 7.14285714e-002f
, 7.13950780e-002f
, 7.14940135e-002f
, -7.13950780e-002f
} },
898 { { 1.88982237e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.88281281e-001f
}, { 7.14285714e-002f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.23259031e-001f
} },
899 { { 1.88982237e-001f
, -1.88281281e-001f
, 0.00000000e+000f
, 0.00000000e+000f
}, { 7.14285714e-002f
, -1.23259031e-001f
, 0.00000000e+000f
, 0.00000000e+000f
} },
900 { { 1.88982237e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, -1.88281281e-001f
}, { 7.14285714e-002f
, 0.00000000e+000f
, 0.00000000e+000f
, -1.23259031e-001f
} },
901 { { 1.88982237e-001f
, 1.88281281e-001f
, 0.00000000e+000f
, 0.00000000e+000f
}, { 7.14285714e-002f
, 1.23259031e-001f
, 0.00000000e+000f
, 0.00000000e+000f
} },
902 { { 1.88982237e-001f
, 1.09057783e-001f
, -1.09208910e-001f
, 1.09057783e-001f
}, { 7.14285714e-002f
, 7.13950780e-002f
, -7.14940135e-002f
, 7.13950780e-002f
} },
903 { { 1.88982237e-001f
, -1.09057783e-001f
, -1.09208910e-001f
, 1.09057783e-001f
}, { 7.14285714e-002f
, -7.13950780e-002f
, -7.14940135e-002f
, 7.13950780e-002f
} },
904 { { 1.88982237e-001f
, -1.09057783e-001f
, -1.09208910e-001f
, -1.09057783e-001f
}, { 7.14285714e-002f
, -7.13950780e-002f
, -7.14940135e-002f
, -7.13950780e-002f
} },
905 { { 1.88982237e-001f
, 1.09057783e-001f
, -1.09208910e-001f
, -1.09057783e-001f
}, { 7.14285714e-002f
, 7.13950780e-002f
, -7.14940135e-002f
, -7.13950780e-002f
} },
906 { { 1.88982237e-001f
, 0.00000000e+000f
, -1.90399923e-001f
, 0.00000000e+000f
}, { 7.14285714e-002f
, 0.00000000e+000f
, -1.24646009e-001f
, 0.00000000e+000f
} }
907 }, AmbiMatrixHOA
[][2][MAX_AMBI_COEFFS
] = {
908 { { 1.43315266e-001f
, 0.00000000e+000f
, 1.90399923e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.18020996e-001f
, 0.00000000e+000f
, 0.00000000e+000f
}, { 7.26741039e-002f
, 0.00000000e+000f
, 1.24646009e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.49618920e-001f
, 0.00000000e+000f
, 0.00000000e+000f
} },
909 { { 1.40852210e-001f
, 1.09057783e-001f
, 1.09208910e-001f
, 1.09057783e-001f
, 7.58818830e-002f
, 7.66295578e-002f
, -3.28314629e-004f
, 7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, 7.13950780e-002f
, 7.14940135e-002f
, 7.13950780e-002f
, 9.61978444e-002f
, 9.71456952e-002f
, -4.16214759e-004f
, 9.71456952e-002f
, 0.00000000e+000f
} },
910 { { 1.40852210e-001f
, -1.09057783e-001f
, 1.09208910e-001f
, 1.09057783e-001f
, -7.58818830e-002f
, -7.66295578e-002f
, -3.28314629e-004f
, 7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, -7.13950780e-002f
, 7.14940135e-002f
, 7.13950780e-002f
, -9.61978444e-002f
, -9.71456952e-002f
, -4.16214759e-004f
, 9.71456952e-002f
, 0.00000000e+000f
} },
911 { { 1.40852210e-001f
, -1.09057783e-001f
, 1.09208910e-001f
, -1.09057783e-001f
, 7.58818830e-002f
, -7.66295578e-002f
, -3.28314629e-004f
, -7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, -7.13950780e-002f
, 7.14940135e-002f
, -7.13950780e-002f
, 9.61978444e-002f
, -9.71456952e-002f
, -4.16214759e-004f
, -9.71456952e-002f
, 0.00000000e+000f
} },
912 { { 1.40852210e-001f
, 1.09057783e-001f
, 1.09208910e-001f
, -1.09057783e-001f
, -7.58818830e-002f
, 7.66295578e-002f
, -3.28314629e-004f
, -7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, 7.13950780e-002f
, 7.14940135e-002f
, -7.13950780e-002f
, -9.61978444e-002f
, 9.71456952e-002f
, -4.16214759e-004f
, -9.71456952e-002f
, 0.00000000e+000f
} },
913 { { 1.39644596e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.88281281e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, -5.83538687e-002f
, 0.00000000e+000f
, 1.01835015e-001f
}, { 7.08127349e-002f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.23259031e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, -7.39770307e-002f
, 0.00000000e+000f
, 1.29099445e-001f
} },
914 { { 1.39644596e-001f
, -1.88281281e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, -5.83538687e-002f
, 0.00000000e+000f
, -1.01835015e-001f
}, { 7.08127349e-002f
, -1.23259031e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, -7.39770307e-002f
, 0.00000000e+000f
, -1.29099445e-001f
} },
915 { { 1.39644596e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, -1.88281281e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, -5.83538687e-002f
, 0.00000000e+000f
, 1.01835015e-001f
}, { 7.08127349e-002f
, 0.00000000e+000f
, 0.00000000e+000f
, -1.23259031e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, -7.39770307e-002f
, 0.00000000e+000f
, 1.29099445e-001f
} },
916 { { 1.39644596e-001f
, 1.88281281e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, -5.83538687e-002f
, 0.00000000e+000f
, -1.01835015e-001f
}, { 7.08127349e-002f
, 1.23259031e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, -7.39770307e-002f
, 0.00000000e+000f
, -1.29099445e-001f
} },
917 { { 1.40852210e-001f
, 1.09057783e-001f
, -1.09208910e-001f
, 1.09057783e-001f
, 7.58818830e-002f
, -7.66295578e-002f
, -3.28314629e-004f
, -7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, 7.13950780e-002f
, -7.14940135e-002f
, 7.13950780e-002f
, 9.61978444e-002f
, -9.71456952e-002f
, -4.16214759e-004f
, -9.71456952e-002f
, 0.00000000e+000f
} },
918 { { 1.40852210e-001f
, -1.09057783e-001f
, -1.09208910e-001f
, 1.09057783e-001f
, -7.58818830e-002f
, 7.66295578e-002f
, -3.28314629e-004f
, -7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, -7.13950780e-002f
, -7.14940135e-002f
, 7.13950780e-002f
, -9.61978444e-002f
, 9.71456952e-002f
, -4.16214759e-004f
, -9.71456952e-002f
, 0.00000000e+000f
} },
919 { { 1.40852210e-001f
, -1.09057783e-001f
, -1.09208910e-001f
, -1.09057783e-001f
, 7.58818830e-002f
, 7.66295578e-002f
, -3.28314629e-004f
, 7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, -7.13950780e-002f
, -7.14940135e-002f
, -7.13950780e-002f
, 9.61978444e-002f
, 9.71456952e-002f
, -4.16214759e-004f
, 9.71456952e-002f
, 0.00000000e+000f
} },
920 { { 1.40852210e-001f
, 1.09057783e-001f
, -1.09208910e-001f
, -1.09057783e-001f
, -7.58818830e-002f
, -7.66295578e-002f
, -3.28314629e-004f
, 7.66295578e-002f
, 0.00000000e+000f
}, { 7.14251066e-002f
, 7.13950780e-002f
, -7.14940135e-002f
, -7.13950780e-002f
, -9.61978444e-002f
, -9.71456952e-002f
, -4.16214759e-004f
, 9.71456952e-002f
, 0.00000000e+000f
} },
921 { { 1.43315266e-001f
, 0.00000000e+000f
, -1.90399923e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.18020996e-001f
, 0.00000000e+000f
, 0.00000000e+000f
}, { 7.26741039e-002f
, 0.00000000e+000f
, -1.24646009e-001f
, 0.00000000e+000f
, 0.00000000e+000f
, 0.00000000e+000f
, 1.49618920e-001f
, 0.00000000e+000f
, 0.00000000e+000f
} },
923 const ALfloat (*AmbiMatrix
)[2][MAX_AMBI_COEFFS
] = device
->AmbiUp
? AmbiMatrixHOA
:
925 ALsizei count
= device
->AmbiUp
? 9 : 4;
928 static_assert(COUNTOF(AmbiPoints
) <= HRTF_AMBI_MAX_CHANNELS
, "HRTF_AMBI_MAX_CHANNELS is too small");
930 device
->Hrtf
= al_calloc(16, FAM_SIZE(DirectHrtfState
, Chan
, count
));
932 for(i
= 0;i
< count
;i
++)
934 device
->Dry
.Ambi
.Map
[i
].Scale
= 1.0f
;
935 device
->Dry
.Ambi
.Map
[i
].Index
= i
;
937 device
->Dry
.CoeffCount
= 0;
938 device
->Dry
.NumChannels
= count
;
942 memset(&device
->FOAOut
.Ambi
, 0, sizeof(device
->FOAOut
.Ambi
));
945 device
->FOAOut
.Ambi
.Map
[i
].Scale
= 1.0f
;
946 device
->FOAOut
.Ambi
.Map
[i
].Index
= i
;
948 device
->FOAOut
.CoeffCount
= 0;
949 device
->FOAOut
.NumChannels
= 4;
951 ambiup_reset(device
->AmbiUp
, device
);
955 device
->FOAOut
.Ambi
= device
->Dry
.Ambi
;
956 device
->FOAOut
.CoeffCount
= device
->Dry
.CoeffCount
;
957 device
->FOAOut
.NumChannels
= 0;
960 device
->RealOut
.NumChannels
= ChannelsFromDevFmt(device
->FmtChans
, device
->AmbiOrder
);
962 device
->Hrtf
->IrSize
= BuildBFormatHrtf(device
->HrtfHandle
,
963 device
->Hrtf
, device
->Dry
.NumChannels
,
964 AmbiPoints
, AmbiMatrix
, COUNTOF(AmbiPoints
)
967 /* Round up to the nearest multiple of 8 */
968 device
->Hrtf
->IrSize
= (device
->Hrtf
->IrSize
+7)&~7;
971 static void InitUhjPanning(ALCdevice
*device
)
976 for(i
= 0;i
< count
;i
++)
978 ALsizei acn
= FuMa2ACN
[i
];
979 device
->Dry
.Ambi
.Map
[i
].Scale
= 1.0f
/FuMa2N3DScale
[acn
];
980 device
->Dry
.Ambi
.Map
[i
].Index
= acn
;
982 device
->Dry
.CoeffCount
= 0;
983 device
->Dry
.NumChannels
= count
;
985 device
->FOAOut
.Ambi
= device
->Dry
.Ambi
;
986 device
->FOAOut
.CoeffCount
= device
->Dry
.CoeffCount
;
987 device
->FOAOut
.NumChannels
= 0;
989 device
->RealOut
.NumChannels
= ChannelsFromDevFmt(device
->FmtChans
, device
->AmbiOrder
);
992 void aluInitRenderer(ALCdevice
*device
, ALint hrtf_id
, enum HrtfRequestMode hrtf_appreq
, enum HrtfRequestMode hrtf_userreq
)
994 /* Hold the HRTF the device last used, in case it's used again. */
995 struct Hrtf
*old_hrtf
= device
->HrtfHandle
;
1001 al_free(device
->Hrtf
);
1002 device
->Hrtf
= NULL
;
1003 device
->HrtfHandle
= NULL
;
1004 alstr_clear(&device
->HrtfName
);
1005 device
->Render_Mode
= NormalRender
;
1007 memset(&device
->Dry
.Ambi
, 0, sizeof(device
->Dry
.Ambi
));
1008 device
->Dry
.CoeffCount
= 0;
1009 device
->Dry
.NumChannels
= 0;
1010 for(i
= 0;i
< MAX_AMBI_ORDER
+1;i
++)
1011 device
->Dry
.NumChannelsPerOrder
[i
] = 0;
1013 device
->AvgSpeakerDist
= 0.0f
;
1014 memset(device
->ChannelDelay
, 0, sizeof(device
->ChannelDelay
));
1015 for(i
= 0;i
< MAX_OUTPUT_CHANNELS
;i
++)
1017 device
->ChannelDelay
[i
].Gain
= 1.0f
;
1018 device
->ChannelDelay
[i
].Length
= 0;
1021 if(device
->FmtChans
!= DevFmtStereo
)
1023 ALsizei speakermap
[MAX_OUTPUT_CHANNELS
];
1024 const char *devname
, *layout
= NULL
;
1025 AmbDecConf conf
, *pconf
= NULL
;
1028 Hrtf_DecRef(old_hrtf
);
1030 if(hrtf_appreq
== Hrtf_Enable
)
1031 device
->HrtfStatus
= ALC_HRTF_UNSUPPORTED_FORMAT_SOFT
;
1035 devname
= alstr_get_cstr(device
->DeviceName
);
1036 switch(device
->FmtChans
)
1038 case DevFmtQuad
: layout
= "quad"; break;
1039 case DevFmtX51
: /* fall-through */
1040 case DevFmtX51Rear
: layout
= "surround51"; break;
1041 case DevFmtX61
: layout
= "surround61"; break;
1042 case DevFmtX71
: layout
= "surround71"; break;
1043 /* Mono, Stereo, and Ambisonics output don't use custom decoders. */
1052 if(ConfigValueStr(devname
, "decoder", layout
, &fname
))
1054 if(!ambdec_load(&conf
, fname
))
1055 ERR("Failed to load layout file %s\n", fname
);
1058 if(conf
.ChanMask
> 0xffff)
1059 ERR("Unsupported channel mask 0x%04x (max 0xffff)\n", conf
.ChanMask
);
1062 if(MakeSpeakerMap(device
, &conf
, speakermap
))
1069 if(pconf
&& GetConfigValueBool(devname
, "decoder", "hq-mode", 0))
1071 ambiup_free(device
->AmbiUp
);
1072 device
->AmbiUp
= NULL
;
1073 if(!device
->AmbiDecoder
)
1074 device
->AmbiDecoder
= bformatdec_alloc();
1078 bformatdec_free(device
->AmbiDecoder
);
1079 device
->AmbiDecoder
= NULL
;
1080 if(device
->FmtChans
== DevFmtAmbi3D
&& device
->AmbiOrder
> 1)
1083 device
->AmbiUp
= ambiup_alloc();
1087 ambiup_free(device
->AmbiUp
);
1088 device
->AmbiUp
= NULL
;
1093 InitPanning(device
);
1094 else if(device
->AmbiDecoder
)
1095 InitHQPanning(device
, pconf
, speakermap
);
1097 InitCustomPanning(device
, pconf
, speakermap
);
1099 ambdec_deinit(&conf
);
1103 bformatdec_free(device
->AmbiDecoder
);
1104 device
->AmbiDecoder
= NULL
;
1106 headphones
= device
->IsHeadphones
;
1107 if(device
->Type
!= Loopback
)
1110 if(ConfigValueStr(alstr_get_cstr(device
->DeviceName
), NULL
, "stereo-mode", &mode
))
1112 if(strcasecmp(mode
, "headphones") == 0)
1114 else if(strcasecmp(mode
, "speakers") == 0)
1116 else if(strcasecmp(mode
, "auto") != 0)
1117 ERR("Unexpected stereo-mode: %s\n", mode
);
1121 if(hrtf_userreq
== Hrtf_Default
)
1123 bool usehrtf
= (headphones
&& hrtf_appreq
!= Hrtf_Disable
) ||
1124 (hrtf_appreq
== Hrtf_Enable
);
1125 if(!usehrtf
) goto no_hrtf
;
1127 device
->HrtfStatus
= ALC_HRTF_ENABLED_SOFT
;
1128 if(headphones
&& hrtf_appreq
!= Hrtf_Disable
)
1129 device
->HrtfStatus
= ALC_HRTF_HEADPHONES_DETECTED_SOFT
;
1133 if(hrtf_userreq
!= Hrtf_Enable
)
1135 if(hrtf_appreq
== Hrtf_Enable
)
1136 device
->HrtfStatus
= ALC_HRTF_DENIED_SOFT
;
1139 device
->HrtfStatus
= ALC_HRTF_REQUIRED_SOFT
;
1142 if(VECTOR_SIZE(device
->HrtfList
) == 0)
1144 VECTOR_DEINIT(device
->HrtfList
);
1145 device
->HrtfList
= EnumerateHrtf(device
->DeviceName
);
1148 if(hrtf_id
>= 0 && (size_t)hrtf_id
< VECTOR_SIZE(device
->HrtfList
))
1150 const EnumeratedHrtf
*entry
= &VECTOR_ELEM(device
->HrtfList
, hrtf_id
);
1151 struct Hrtf
*hrtf
= GetLoadedHrtf(entry
->hrtf
);
1152 if(hrtf
&& hrtf
->sampleRate
== device
->Frequency
)
1154 device
->HrtfHandle
= hrtf
;
1155 alstr_copy(&device
->HrtfName
, entry
->name
);
1161 for(i
= 0;!device
->HrtfHandle
&& i
< VECTOR_SIZE(device
->HrtfList
);i
++)
1163 const EnumeratedHrtf
*entry
= &VECTOR_ELEM(device
->HrtfList
, i
);
1164 struct Hrtf
*hrtf
= GetLoadedHrtf(entry
->hrtf
);
1165 if(hrtf
&& hrtf
->sampleRate
== device
->Frequency
)
1167 device
->HrtfHandle
= hrtf
;
1168 alstr_copy(&device
->HrtfName
, entry
->name
);
1174 if(device
->HrtfHandle
)
1177 Hrtf_DecRef(old_hrtf
);
1180 device
->Render_Mode
= HrtfRender
;
1181 if(ConfigValueStr(alstr_get_cstr(device
->DeviceName
), NULL
, "hrtf-mode", &mode
))
1183 if(strcasecmp(mode
, "full") == 0)
1184 device
->Render_Mode
= HrtfRender
;
1185 else if(strcasecmp(mode
, "basic") == 0)
1186 device
->Render_Mode
= NormalRender
;
1188 ERR("Unexpected hrtf-mode: %s\n", mode
);
1191 if(device
->Render_Mode
== HrtfRender
)
1193 /* Don't bother with HOA when using full HRTF rendering. Nothing
1194 * needs it, and it eases the CPU/memory load.
1196 ambiup_free(device
->AmbiUp
);
1197 device
->AmbiUp
= NULL
;
1202 device
->AmbiUp
= ambiup_alloc();
1205 TRACE("%s HRTF rendering enabled, using \"%s\"\n",
1206 ((device
->Render_Mode
== HrtfRender
) ? "Full" : "Basic"),
1207 alstr_get_cstr(device
->HrtfName
)
1209 InitHrtfPanning(device
);
1212 device
->HrtfStatus
= ALC_HRTF_UNSUPPORTED_FORMAT_SOFT
;
1216 Hrtf_DecRef(old_hrtf
);
1218 TRACE("HRTF disabled\n");
1220 device
->Render_Mode
= StereoPair
;
1222 ambiup_free(device
->AmbiUp
);
1223 device
->AmbiUp
= NULL
;
1225 bs2blevel
= ((headphones
&& hrtf_appreq
!= Hrtf_Disable
) ||
1226 (hrtf_appreq
== Hrtf_Enable
)) ? 5 : 0;
1227 if(device
->Type
!= Loopback
)
1228 ConfigValueInt(alstr_get_cstr(device
->DeviceName
), NULL
, "cf_level", &bs2blevel
);
1229 if(bs2blevel
> 0 && bs2blevel
<= 6)
1231 device
->Bs2b
= al_calloc(16, sizeof(*device
->Bs2b
));
1232 bs2b_set_params(device
->Bs2b
, bs2blevel
, device
->Frequency
);
1233 TRACE("BS2B enabled\n");
1234 InitPanning(device
);
1238 TRACE("BS2B disabled\n");
1240 if(ConfigValueStr(alstr_get_cstr(device
->DeviceName
), NULL
, "stereo-encoding", &mode
))
1242 if(strcasecmp(mode
, "uhj") == 0)
1243 device
->Render_Mode
= NormalRender
;
1244 else if(strcasecmp(mode
, "panpot") != 0)
1245 ERR("Unexpected stereo-encoding: %s\n", mode
);
1247 if(device
->Render_Mode
== NormalRender
)
1249 device
->Uhj_Encoder
= al_calloc(16, sizeof(Uhj2Encoder
));
1250 TRACE("UHJ enabled\n");
1251 InitUhjPanning(device
);
1255 TRACE("UHJ disabled\n");
1256 InitPanning(device
);
1260 void aluInitEffectPanning(ALeffectslot
*slot
)
1264 memset(slot
->ChanMap
, 0, sizeof(slot
->ChanMap
));
1265 slot
->NumChannels
= 0;
1267 for(i
= 0;i
< MAX_EFFECT_CHANNELS
;i
++)
1269 slot
->ChanMap
[i
].Scale
= 1.0f
;
1270 slot
->ChanMap
[i
].Index
= i
;
1272 slot
->NumChannels
= i
;