/** * OpenAL cross platform audio library * Copyright (C) 1999-2010 by authors. * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * Or go to http://www.gnu.org/copyleft/lgpl.html */ #include "config.h" #include #include #include #include #include #include "alMain.h" #include "alAuxEffectSlot.h" #include "alu.h" #include "alconfig.h" #include "bool.h" #include "ambdec.h" #include "bformatdec.h" #include "filters/splitter.h" #include "uhjfilter.h" #include "bs2b.h" extern inline void CalcDirectionCoeffs(const ALfloat dir[3], ALfloat spread, ALfloat coeffs[MAX_AMBI_COEFFS]); extern inline void CalcAngleCoeffs(ALfloat azimuth, ALfloat elevation, ALfloat spread, ALfloat coeffs[MAX_AMBI_COEFFS]); extern inline void ComputeDryPanGains(const DryMixParams *dry, const ALfloat coeffs[MAX_AMBI_COEFFS], ALfloat ingain, ALfloat gains[MAX_OUTPUT_CHANNELS]); extern inline void ComputeFirstOrderGains(const BFMixParams *foa, const ALfloat mtx[4], ALfloat ingain, ALfloat gains[MAX_OUTPUT_CHANNELS]); static const ALsizei FuMa2ACN[MAX_AMBI_COEFFS] = { 0, /* W */ 3, /* X */ 1, /* Y */ 2, /* Z */ 6, /* R */ 7, /* S */ 5, /* T */ 8, /* U */ 4, /* V */ 12, /* K */ 13, /* L */ 11, /* M */ 14, /* N */ 10, /* O */ 15, /* P */ 9, /* Q */ }; static const ALsizei ACN2ACN[MAX_AMBI_COEFFS] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 }; void CalcAmbiCoeffs(const ALfloat y, const ALfloat z, const ALfloat x, const ALfloat spread, ALfloat coeffs[MAX_AMBI_COEFFS]) { /* Zeroth-order */ coeffs[0] = 1.0f; /* ACN 0 = 1 */ /* First-order */ coeffs[1] = 1.732050808f * y; /* ACN 1 = sqrt(3) * Y */ coeffs[2] = 1.732050808f * z; /* ACN 2 = sqrt(3) * Z */ coeffs[3] = 1.732050808f * x; /* ACN 3 = sqrt(3) * X */ /* Second-order */ coeffs[4] = 3.872983346f * x * y; /* ACN 4 = sqrt(15) * X * Y */ coeffs[5] = 3.872983346f * y * z; /* ACN 5 = sqrt(15) * Y * Z */ coeffs[6] = 1.118033989f * (3.0f*z*z - 1.0f); /* ACN 6 = sqrt(5)/2 * (3*Z*Z - 1) */ coeffs[7] = 3.872983346f * x * z; /* ACN 7 = sqrt(15) * X * Z */ coeffs[8] = 1.936491673f * (x*x - y*y); /* ACN 8 = sqrt(15)/2 * (X*X - Y*Y) */ /* Third-order */ coeffs[9] = 2.091650066f * y * (3.0f*x*x - y*y); /* ACN 9 = sqrt(35/8) * Y * (3*X*X - Y*Y) */ coeffs[10] = 10.246950766f * z * x * y; /* ACN 10 = sqrt(105) * Z * X * Y */ coeffs[11] = 1.620185175f * y * (5.0f*z*z - 1.0f); /* ACN 11 = sqrt(21/8) * Y * (5*Z*Z - 1) */ coeffs[12] = 1.322875656f * z * (5.0f*z*z - 3.0f); /* ACN 12 = sqrt(7)/2 * Z * (5*Z*Z - 3) */ coeffs[13] = 1.620185175f * x * (5.0f*z*z - 1.0f); /* ACN 13 = sqrt(21/8) * X * (5*Z*Z - 1) */ coeffs[14] = 5.123475383f * z * (x*x - y*y); /* ACN 14 = sqrt(105)/2 * Z * (X*X - Y*Y) */ coeffs[15] = 2.091650066f * x * (x*x - 3.0f*y*y); /* ACN 15 = sqrt(35/8) * X * (X*X - 3*Y*Y) */ if(spread > 0.0f) { /* Implement the spread by using a spherical source that subtends the * angle spread. See: * http://www.ppsloan.org/publications/StupidSH36.pdf - Appendix A3 * * When adjusted for N3D normalization instead of SN3D, these * calculations are: * * ZH0 = -sqrt(pi) * (-1+ca); * ZH1 = 0.5*sqrt(pi) * sa*sa; * ZH2 = -0.5*sqrt(pi) * ca*(-1+ca)*(ca+1); * ZH3 = -0.125*sqrt(pi) * (-1+ca)*(ca+1)*(5*ca*ca - 1); * ZH4 = -0.125*sqrt(pi) * ca*(-1+ca)*(ca+1)*(7*ca*ca - 3); * ZH5 = -0.0625*sqrt(pi) * (-1+ca)*(ca+1)*(21*ca*ca*ca*ca - 14*ca*ca + 1); * * The gain of the source is compensated for size, so that the * loundness doesn't depend on the spread. Thus: * * ZH0 = 1.0f; * ZH1 = 0.5f * (ca+1.0f); * ZH2 = 0.5f * (ca+1.0f)*ca; * ZH3 = 0.125f * (ca+1.0f)*(5.0f*ca*ca - 1.0f); * ZH4 = 0.125f * (ca+1.0f)*(7.0f*ca*ca - 3.0f)*ca; * ZH5 = 0.0625f * (ca+1.0f)*(21.0f*ca*ca*ca*ca - 14.0f*ca*ca + 1.0f); */ ALfloat ca = cosf(spread * 0.5f); /* Increase the source volume by up to +3dB for a full spread. */ ALfloat scale = sqrtf(1.0f + spread/F_TAU); ALfloat ZH0_norm = scale; ALfloat ZH1_norm = 0.5f * (ca+1.f) * scale; ALfloat ZH2_norm = 0.5f * (ca+1.f)*ca * scale; ALfloat ZH3_norm = 0.125f * (ca+1.f)*(5.f*ca*ca-1.f) * scale; /* Zeroth-order */ coeffs[0] *= ZH0_norm; /* First-order */ coeffs[1] *= ZH1_norm; coeffs[2] *= ZH1_norm; coeffs[3] *= ZH1_norm; /* Second-order */ coeffs[4] *= ZH2_norm; coeffs[5] *= ZH2_norm; coeffs[6] *= ZH2_norm; coeffs[7] *= ZH2_norm; coeffs[8] *= ZH2_norm; /* Third-order */ coeffs[9] *= ZH3_norm; coeffs[10] *= ZH3_norm; coeffs[11] *= ZH3_norm; coeffs[12] *= ZH3_norm; coeffs[13] *= ZH3_norm; coeffs[14] *= ZH3_norm; coeffs[15] *= ZH3_norm; } } void CalcAnglePairwiseCoeffs(ALfloat azimuth, ALfloat elevation, ALfloat spread, ALfloat coeffs[MAX_AMBI_COEFFS]) { ALfloat sign = (azimuth < 0.0f) ? -1.0f : 1.0f; if(!(fabsf(azimuth) > F_PI_2)) azimuth = minf(fabsf(azimuth) * F_PI_2 / (F_PI/6.0f), F_PI_2) * sign; CalcAngleCoeffs(azimuth, elevation, spread, coeffs); } void ComputePanningGainsMC(const ChannelConfig *chancoeffs, ALsizei numchans, ALsizei numcoeffs, const ALfloat coeffs[MAX_AMBI_COEFFS], ALfloat ingain, ALfloat gains[MAX_OUTPUT_CHANNELS]) { ALsizei i, j; for(i = 0;i < numchans;i++) { float gain = 0.0f; for(j = 0;j < numcoeffs;j++) gain += chancoeffs[i][j]*coeffs[j]; gains[i] = clampf(gain, 0.0f, 1.0f) * ingain; } for(;i < MAX_OUTPUT_CHANNELS;i++) gains[i] = 0.0f; } void ComputePanningGainsBF(const BFChannelConfig *chanmap, ALsizei numchans, const ALfloat coeffs[MAX_AMBI_COEFFS], ALfloat ingain, ALfloat gains[MAX_OUTPUT_CHANNELS]) { ALsizei i; for(i = 0;i < numchans;i++) gains[i] = chanmap[i].Scale * coeffs[chanmap[i].Index] * ingain; for(;i < MAX_OUTPUT_CHANNELS;i++) gains[i] = 0.0f; } void ComputeFirstOrderGainsMC(const ChannelConfig *chancoeffs, ALsizei numchans, const ALfloat mtx[4], ALfloat ingain, ALfloat gains[MAX_OUTPUT_CHANNELS]) { ALsizei i, j; for(i = 0;i < numchans;i++) { float gain = 0.0f; for(j = 0;j < 4;j++) gain += chancoeffs[i][j] * mtx[j]; gains[i] = clampf(gain, 0.0f, 1.0f) * ingain; } for(;i < MAX_OUTPUT_CHANNELS;i++) gains[i] = 0.0f; } void ComputeFirstOrderGainsBF(const BFChannelConfig *chanmap, ALsizei numchans, const ALfloat mtx[4], ALfloat ingain, ALfloat gains[MAX_OUTPUT_CHANNELS]) { ALsizei i; for(i = 0;i < numchans;i++) gains[i] = chanmap[i].Scale * mtx[chanmap[i].Index] * ingain; for(;i < MAX_OUTPUT_CHANNELS;i++) gains[i] = 0.0f; } static inline const char *GetLabelFromChannel(enum Channel channel) { switch(channel) { case FrontLeft: return "front-left"; case FrontRight: return "front-right"; case FrontCenter: return "front-center"; case LFE: return "lfe"; case BackLeft: return "back-left"; case BackRight: return "back-right"; case BackCenter: return "back-center"; case SideLeft: return "side-left"; case SideRight: return "side-right"; case UpperFrontLeft: return "upper-front-left"; case UpperFrontRight: return "upper-front-right"; case UpperBackLeft: return "upper-back-left"; case UpperBackRight: return "upper-back-right"; case LowerFrontLeft: return "lower-front-left"; case LowerFrontRight: return "lower-front-right"; case LowerBackLeft: return "lower-back-left"; case LowerBackRight: return "lower-back-right"; case Aux0: return "aux-0"; case Aux1: return "aux-1"; case Aux2: return "aux-2"; case Aux3: return "aux-3"; case Aux4: return "aux-4"; case Aux5: return "aux-5"; case Aux6: return "aux-6"; case Aux7: return "aux-7"; case Aux8: return "aux-8"; case Aux9: return "aux-9"; case Aux10: return "aux-10"; case Aux11: return "aux-11"; case Aux12: return "aux-12"; case Aux13: return "aux-13"; case Aux14: return "aux-14"; case Aux15: return "aux-15"; case InvalidChannel: break; } return "(unknown)"; } typedef struct ChannelMap { enum Channel ChanName; ChannelConfig Config; } ChannelMap; static void SetChannelMap(const enum Channel devchans[MAX_OUTPUT_CHANNELS], ChannelConfig *ambicoeffs, const ChannelMap *chanmap, ALsizei count, ALsizei *outcount) { ALsizei maxchans = 0; ALsizei i, j; for(i = 0;i < count;i++) { ALint idx = GetChannelIndex(devchans, chanmap[i].ChanName); if(idx < 0) { ERR("Failed to find %s channel in device\n", GetLabelFromChannel(chanmap[i].ChanName)); continue; } maxchans = maxi(maxchans, idx+1); for(j = 0;j < MAX_AMBI_COEFFS;j++) ambicoeffs[idx][j] = chanmap[i].Config[j]; } *outcount = mini(maxchans, MAX_OUTPUT_CHANNELS); } static bool MakeSpeakerMap(ALCdevice *device, const AmbDecConf *conf, ALsizei speakermap[MAX_OUTPUT_CHANNELS]) { ALsizei i; for(i = 0;i < conf->NumSpeakers;i++) { enum Channel ch; int chidx = -1; /* NOTE: AmbDec does not define any standard speaker names, however * for this to work we have to by able to find the output channel * the speaker definition corresponds to. Therefore, OpenAL Soft * requires these channel labels to be recognized: * * LF = Front left * RF = Front right * LS = Side left * RS = Side right * LB = Back left * RB = Back right * CE = Front center * CB = Back center * * Additionally, surround51 will acknowledge back speakers for side * channels, and surround51rear will acknowledge side speakers for * back channels, to avoid issues with an ambdec expecting 5.1 to * use the side channels when the device is configured for back, * and vice-versa. */ if(alstr_cmp_cstr(conf->Speakers[i].Name, "LF") == 0) ch = FrontLeft; else if(alstr_cmp_cstr(conf->Speakers[i].Name, "RF") == 0) ch = FrontRight; else if(alstr_cmp_cstr(conf->Speakers[i].Name, "CE") == 0) ch = FrontCenter; else if(alstr_cmp_cstr(conf->Speakers[i].Name, "LS") == 0) { if(device->FmtChans == DevFmtX51Rear) ch = BackLeft; else ch = SideLeft; } else if(alstr_cmp_cstr(conf->Speakers[i].Name, "RS") == 0) { if(device->FmtChans == DevFmtX51Rear) ch = BackRight; else ch = SideRight; } else if(alstr_cmp_cstr(conf->Speakers[i].Name, "LB") == 0) { if(device->FmtChans == DevFmtX51) ch = SideLeft; else ch = BackLeft; } else if(alstr_cmp_cstr(conf->Speakers[i].Name, "RB") == 0) { if(device->FmtChans == DevFmtX51) ch = SideRight; else ch = BackRight; } else if(alstr_cmp_cstr(conf->Speakers[i].Name, "CB") == 0) ch = BackCenter; else { const char *name = alstr_get_cstr(conf->Speakers[i].Name); unsigned int n; char c; if(sscanf(name, "AUX%u%c", &n, &c) == 1 && n < 16) ch = Aux0+n; else { ERR("AmbDec speaker label \"%s\" not recognized\n", name); return false; } } chidx = GetChannelIdxByName(&device->RealOut, ch); if(chidx == -1) { ERR("Failed to lookup AmbDec speaker label %s\n", alstr_get_cstr(conf->Speakers[i].Name)); return false; } speakermap[i] = chidx; } return true; } static const ChannelMap MonoCfg[1] = { { FrontCenter, { 1.0f } }, }, StereoCfg[2] = { { FrontLeft, { 5.00000000e-1f, 2.88675135e-1f, 0.0f, 5.52305643e-2f } }, { FrontRight, { 5.00000000e-1f, -2.88675135e-1f, 0.0f, 5.52305643e-2f } }, }, QuadCfg[4] = { { BackLeft, { 3.53553391e-1f, 2.04124145e-1f, 0.0f, -2.04124145e-1f } }, { FrontLeft, { 3.53553391e-1f, 2.04124145e-1f, 0.0f, 2.04124145e-1f } }, { FrontRight, { 3.53553391e-1f, -2.04124145e-1f, 0.0f, 2.04124145e-1f } }, { BackRight, { 3.53553391e-1f, -2.04124145e-1f, 0.0f, -2.04124145e-1f } }, }, X51SideCfg[4] = { { SideLeft, { 3.33000782e-1f, 1.89084803e-1f, 0.0f, -2.00042375e-1f, -2.12307769e-2f, 0.0f, 0.0f, 0.0f, -1.14579885e-2f } }, { FrontLeft, { 1.88542860e-1f, 1.27709292e-1f, 0.0f, 1.66295695e-1f, 7.30571517e-2f, 0.0f, 0.0f, 0.0f, 2.10901184e-2f } }, { FrontRight, { 1.88542860e-1f, -1.27709292e-1f, 0.0f, 1.66295695e-1f, -7.30571517e-2f, 0.0f, 0.0f, 0.0f, 2.10901184e-2f } }, { SideRight, { 3.33000782e-1f, -1.89084803e-1f, 0.0f, -2.00042375e-1f, 2.12307769e-2f, 0.0f, 0.0f, 0.0f, -1.14579885e-2f } }, }, X51RearCfg[4] = { { BackLeft, { 3.33000782e-1f, 1.89084803e-1f, 0.0f, -2.00042375e-1f, -2.12307769e-2f, 0.0f, 0.0f, 0.0f, -1.14579885e-2f } }, { FrontLeft, { 1.88542860e-1f, 1.27709292e-1f, 0.0f, 1.66295695e-1f, 7.30571517e-2f, 0.0f, 0.0f, 0.0f, 2.10901184e-2f } }, { FrontRight, { 1.88542860e-1f, -1.27709292e-1f, 0.0f, 1.66295695e-1f, -7.30571517e-2f, 0.0f, 0.0f, 0.0f, 2.10901184e-2f } }, { BackRight, { 3.33000782e-1f, -1.89084803e-1f, 0.0f, -2.00042375e-1f, 2.12307769e-2f, 0.0f, 0.0f, 0.0f, -1.14579885e-2f } }, }, X61Cfg[6] = { { SideLeft, { 2.04460341e-1f, 2.17177926e-1f, 0.0f, -4.39996780e-2f, -2.60790269e-2f, 0.0f, 0.0f, 0.0f, -6.87239792e-2f } }, { FrontLeft, { 1.58923161e-1f, 9.21772680e-2f, 0.0f, 1.59658796e-1f, 6.66278083e-2f, 0.0f, 0.0f, 0.0f, 3.84686854e-2f } }, { FrontRight, { 1.58923161e-1f, -9.21772680e-2f, 0.0f, 1.59658796e-1f, -6.66278083e-2f, 0.0f, 0.0f, 0.0f, 3.84686854e-2f } }, { SideRight, { 2.04460341e-1f, -2.17177926e-1f, 0.0f, -4.39996780e-2f, 2.60790269e-2f, 0.0f, 0.0f, 0.0f, -6.87239792e-2f } }, { BackCenter, { 2.50001688e-1f, 0.00000000e+0f, 0.0f, -2.50000094e-1f, 0.00000000e+0f, 0.0f, 0.0f, 0.0f, 6.05133395e-2f } }, }, X71Cfg[6] = { { 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 } }, { 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 } }, { 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 } }, { 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 } }, { 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 } }, { 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 } }, }; static void InitNearFieldCtrl(ALCdevice *device, ALfloat ctrl_dist, ALsizei order, const ALsizei *restrict chans_per_order) { const char *devname = alstr_get_cstr(device->DeviceName); ALsizei i; if(GetConfigValueBool(devname, "decoder", "nfc", 1) && ctrl_dist > 0.0f) { /* NFC is only used when AvgSpeakerDist is greater than 0, and can only * be used when rendering to an ambisonic buffer. */ device->AvgSpeakerDist = minf(ctrl_dist, 10.0f); for(i = 0;i < order+1;i++) device->Dry.NumChannelsPerOrder[i] = chans_per_order[i]; for(;i < MAX_AMBI_ORDER+1;i++) device->Dry.NumChannelsPerOrder[i] = 0; } } static void InitDistanceComp(ALCdevice *device, const AmbDecConf *conf, const ALsizei speakermap[MAX_OUTPUT_CHANNELS]) { const char *devname = alstr_get_cstr(device->DeviceName); ALfloat maxdist = 0.0f; size_t total = 0; ALsizei i; for(i = 0;i < conf->NumSpeakers;i++) maxdist = maxf(maxdist, conf->Speakers[i].Distance); if(GetConfigValueBool(devname, "decoder", "distance-comp", 1) && maxdist > 0.0f) { ALfloat srate = (ALfloat)device->Frequency; for(i = 0;i < conf->NumSpeakers;i++) { ALsizei chan = speakermap[i]; ALfloat delay; /* Distance compensation only delays in steps of the sample rate. * This is a bit less accurate since the delay time falls to the * nearest sample time, but it's far simpler as it doesn't have to * deal with phase offsets. This means at 48khz, for instance, the * distance delay will be in steps of about 7 millimeters. */ delay = floorf((maxdist-conf->Speakers[i].Distance) / SPEEDOFSOUNDMETRESPERSEC * srate + 0.5f); if(delay >= (ALfloat)MAX_DELAY_LENGTH) ERR("Delay for speaker \"%s\" exceeds buffer length (%f >= %u)\n", alstr_get_cstr(conf->Speakers[i].Name), delay, MAX_DELAY_LENGTH); device->ChannelDelay[chan].Length = (ALsizei)clampf( delay, 0.0f, (ALfloat)(MAX_DELAY_LENGTH-1) ); device->ChannelDelay[chan].Gain = conf->Speakers[i].Distance / maxdist; TRACE("Channel %u \"%s\" distance compensation: %d samples, %f gain\n", chan, alstr_get_cstr(conf->Speakers[i].Name), device->ChannelDelay[chan].Length, device->ChannelDelay[chan].Gain ); /* Round up to the next 4th sample, so each channel buffer starts * 16-byte aligned. */ total += RoundUp(device->ChannelDelay[chan].Length, 4); } } if(total > 0) { device->ChannelDelay[0].Buffer = al_calloc(16, total * sizeof(ALfloat)); for(i = 1;i < MAX_OUTPUT_CHANNELS;i++) { size_t len = RoundUp(device->ChannelDelay[i-1].Length, 4); device->ChannelDelay[i].Buffer = device->ChannelDelay[i-1].Buffer + len; } } } static void InitPanning(ALCdevice *device) { const ChannelMap *chanmap = NULL; ALsizei coeffcount = 0; ALsizei count = 0; ALsizei i, j; switch(device->FmtChans) { case DevFmtMono: count = COUNTOF(MonoCfg); chanmap = MonoCfg; coeffcount = 1; break; case DevFmtStereo: count = COUNTOF(StereoCfg); chanmap = StereoCfg; coeffcount = 4; break; case DevFmtQuad: count = COUNTOF(QuadCfg); chanmap = QuadCfg; coeffcount = 4; break; case DevFmtX51: count = COUNTOF(X51SideCfg); chanmap = X51SideCfg; coeffcount = 9; break; case DevFmtX51Rear: count = COUNTOF(X51RearCfg); chanmap = X51RearCfg; coeffcount = 9; break; case DevFmtX61: count = COUNTOF(X61Cfg); chanmap = X61Cfg; coeffcount = 9; break; case DevFmtX71: count = COUNTOF(X71Cfg); chanmap = X71Cfg; coeffcount = 16; break; case DevFmtAmbi3D: break; } if(device->FmtChans == DevFmtAmbi3D) { const char *devname = alstr_get_cstr(device->DeviceName); const ALsizei *acnmap = (device->AmbiLayout == AmbiLayout_FuMa) ? FuMa2ACN : ACN2ACN; const ALfloat *n3dscale = (device->AmbiScale == AmbiNorm_FuMa) ? FuMa2N3DScale : (device->AmbiScale == AmbiNorm_SN3D) ? SN3D2N3DScale : /*(device->AmbiScale == AmbiNorm_N3D) ?*/ N3D2N3DScale; ALfloat nfc_delay = 0.0f; count = (device->AmbiOrder == 3) ? 16 : (device->AmbiOrder == 2) ? 9 : (device->AmbiOrder == 1) ? 4 : 1; for(i = 0;i < count;i++) { ALsizei acn = acnmap[i]; device->Dry.Ambi.Map[i].Scale = 1.0f/n3dscale[acn]; device->Dry.Ambi.Map[i].Index = acn; } device->Dry.CoeffCount = 0; device->Dry.NumChannels = count; if(device->AmbiOrder < 2) { device->FOAOut.Ambi = device->Dry.Ambi; device->FOAOut.CoeffCount = device->Dry.CoeffCount; device->FOAOut.NumChannels = 0; } else { ALfloat w_scale=1.0f, xyz_scale=1.0f; /* FOA output is always ACN+N3D for higher-order ambisonic output. * The upsampler expects this and will convert it for output. */ memset(&device->FOAOut.Ambi, 0, sizeof(device->FOAOut.Ambi)); for(i = 0;i < 4;i++) { device->FOAOut.Ambi.Map[i].Scale = 1.0f; device->FOAOut.Ambi.Map[i].Index = i; } device->FOAOut.CoeffCount = 0; device->FOAOut.NumChannels = 4; if(device->AmbiOrder >= 3) { w_scale = W_SCALE_3H3P; xyz_scale = XYZ_SCALE_3H3P; } else { w_scale = W_SCALE_2H2P; xyz_scale = XYZ_SCALE_2H2P; } ambiup_reset(device->AmbiUp, device, w_scale, xyz_scale); } if(ConfigValueFloat(devname, "decoder", "nfc-ref-delay", &nfc_delay) && nfc_delay > 0.0f) { static const ALsizei chans_per_order[MAX_AMBI_ORDER+1] = { 1, 3, 5, 7 }; nfc_delay = clampf(nfc_delay, 0.001f, 1000.0f); InitNearFieldCtrl(device, nfc_delay * SPEEDOFSOUNDMETRESPERSEC, device->AmbiOrder, chans_per_order); } } else { ALfloat w_scale, xyz_scale; SetChannelMap(device->RealOut.ChannelName, device->Dry.Ambi.Coeffs, chanmap, count, &device->Dry.NumChannels); device->Dry.CoeffCount = coeffcount; w_scale = (device->Dry.CoeffCount > 9) ? W_SCALE_3H0P : (device->Dry.CoeffCount > 4) ? W_SCALE_2H0P : 1.0f; xyz_scale = (device->Dry.CoeffCount > 9) ? XYZ_SCALE_3H0P : (device->Dry.CoeffCount > 4) ? XYZ_SCALE_2H0P : 1.0f; memset(&device->FOAOut.Ambi, 0, sizeof(device->FOAOut.Ambi)); for(i = 0;i < device->Dry.NumChannels;i++) { device->FOAOut.Ambi.Coeffs[i][0] = device->Dry.Ambi.Coeffs[i][0] * w_scale; for(j = 1;j < 4;j++) device->FOAOut.Ambi.Coeffs[i][j] = device->Dry.Ambi.Coeffs[i][j] * xyz_scale; } device->FOAOut.CoeffCount = 4; device->FOAOut.NumChannels = 0; } device->RealOut.NumChannels = 0; } static void InitCustomPanning(ALCdevice *device, const AmbDecConf *conf, const ALsizei speakermap[MAX_OUTPUT_CHANNELS]) { ChannelMap chanmap[MAX_OUTPUT_CHANNELS]; const ALfloat *coeff_scale = N3D2N3DScale; ALfloat w_scale = 1.0f; ALfloat xyz_scale = 1.0f; ALsizei i, j; if(conf->FreqBands != 1) ERR("Basic renderer uses the high-frequency matrix as single-band (xover_freq = %.0fhz)\n", conf->XOverFreq); if((conf->ChanMask&AMBI_PERIPHONIC_MASK)) { if(conf->ChanMask > 0x1ff) { w_scale = W_SCALE_3H3P; xyz_scale = XYZ_SCALE_3H3P; } else if(conf->ChanMask > 0xf) { w_scale = W_SCALE_2H2P; xyz_scale = XYZ_SCALE_2H2P; } } else { if(conf->ChanMask > 0x1ff) { w_scale = W_SCALE_3H0P; xyz_scale = XYZ_SCALE_3H0P; } else if(conf->ChanMask > 0xf) { w_scale = W_SCALE_2H0P; xyz_scale = XYZ_SCALE_2H0P; } } if(conf->CoeffScale == ADS_SN3D) coeff_scale = SN3D2N3DScale; else if(conf->CoeffScale == ADS_FuMa) coeff_scale = FuMa2N3DScale; for(i = 0;i < conf->NumSpeakers;i++) { ALsizei chan = speakermap[i]; ALfloat gain; ALsizei k = 0; for(j = 0;j < MAX_AMBI_COEFFS;j++) chanmap[i].Config[j] = 0.0f; chanmap[i].ChanName = device->RealOut.ChannelName[chan]; for(j = 0;j < MAX_AMBI_COEFFS;j++) { if(j == 0) gain = conf->HFOrderGain[0]; else if(j == 1) gain = conf->HFOrderGain[1]; else if(j == 4) gain = conf->HFOrderGain[2]; else if(j == 9) gain = conf->HFOrderGain[3]; if((conf->ChanMask&(1<HFMatrix[i][k++] / coeff_scale[j] * gain; } } SetChannelMap(device->RealOut.ChannelName, device->Dry.Ambi.Coeffs, chanmap, conf->NumSpeakers, &device->Dry.NumChannels); device->Dry.CoeffCount = (conf->ChanMask > 0x1ff) ? 16 : (conf->ChanMask > 0xf) ? 9 : 4; memset(&device->FOAOut.Ambi, 0, sizeof(device->FOAOut.Ambi)); for(i = 0;i < device->Dry.NumChannels;i++) { device->FOAOut.Ambi.Coeffs[i][0] = device->Dry.Ambi.Coeffs[i][0] * w_scale; for(j = 1;j < 4;j++) device->FOAOut.Ambi.Coeffs[i][j] = device->Dry.Ambi.Coeffs[i][j] * xyz_scale; } device->FOAOut.CoeffCount = 4; device->FOAOut.NumChannels = 0; device->RealOut.NumChannels = 0; InitDistanceComp(device, conf, speakermap); } static void InitHQPanning(ALCdevice *device, const AmbDecConf *conf, const ALsizei speakermap[MAX_OUTPUT_CHANNELS]) { static const ALsizei chans_per_order2d[MAX_AMBI_ORDER+1] = { 1, 2, 2, 2 }; static const ALsizei chans_per_order3d[MAX_AMBI_ORDER+1] = { 1, 3, 5, 7 }; ALfloat avg_dist; ALsizei count; ALsizei i; if((conf->ChanMask&AMBI_PERIPHONIC_MASK)) { count = (conf->ChanMask > 0x1ff) ? 16 : (conf->ChanMask > 0xf) ? 9 : 4; for(i = 0;i < count;i++) { device->Dry.Ambi.Map[i].Scale = 1.0f; device->Dry.Ambi.Map[i].Index = i; } } else { static const int map[MAX_AMBI2D_COEFFS] = { 0, 1, 3, 4, 8, 9, 15 }; count = (conf->ChanMask > 0x1ff) ? 7 : (conf->ChanMask > 0xf) ? 5 : 3; for(i = 0;i < count;i++) { device->Dry.Ambi.Map[i].Scale = 1.0f; device->Dry.Ambi.Map[i].Index = map[i]; } } device->Dry.CoeffCount = 0; device->Dry.NumChannels = count; TRACE("Enabling %s-band %s-order%s ambisonic decoder\n", (conf->FreqBands == 1) ? "single" : "dual", (conf->ChanMask > 0xf) ? (conf->ChanMask > 0x1ff) ? "third" : "second" : "first", (conf->ChanMask&AMBI_PERIPHONIC_MASK) ? " periphonic" : "" ); bformatdec_reset(device->AmbiDecoder, conf, count, device->Frequency, speakermap); if(!(conf->ChanMask > 0xf)) { device->FOAOut.Ambi = device->Dry.Ambi; device->FOAOut.CoeffCount = device->Dry.CoeffCount; device->FOAOut.NumChannels = 0; } else { memset(&device->FOAOut.Ambi, 0, sizeof(device->FOAOut.Ambi)); if((conf->ChanMask&AMBI_PERIPHONIC_MASK)) { count = 4; for(i = 0;i < count;i++) { device->FOAOut.Ambi.Map[i].Scale = 1.0f; device->FOAOut.Ambi.Map[i].Index = i; } } else { static const int map[3] = { 0, 1, 3 }; count = 3; for(i = 0;i < count;i++) { device->FOAOut.Ambi.Map[i].Scale = 1.0f; device->FOAOut.Ambi.Map[i].Index = map[i]; } } device->FOAOut.CoeffCount = 0; device->FOAOut.NumChannels = count; } device->RealOut.NumChannels = ChannelsFromDevFmt(device->FmtChans, device->AmbiOrder); avg_dist = 0.0f; for(i = 0;i < conf->NumSpeakers;i++) avg_dist += conf->Speakers[i].Distance; avg_dist /= (ALfloat)conf->NumSpeakers; InitNearFieldCtrl(device, avg_dist, (conf->ChanMask > 0x1ff) ? 3 : (conf->ChanMask > 0xf) ? 2 : 1, (conf->ChanMask&AMBI_PERIPHONIC_MASK) ? chans_per_order3d : chans_per_order2d ); InitDistanceComp(device, conf, speakermap); } static void InitHrtfPanning(ALCdevice *device) { /* NOTE: azimuth goes clockwise. */ static const struct AngularPoint AmbiPoints[] = { { DEG2RAD( 90.0f), DEG2RAD( 0.0f) }, { DEG2RAD( 35.2643897f), DEG2RAD( 45.0f) }, { DEG2RAD( 35.2643897f), DEG2RAD( 135.0f) }, { DEG2RAD( 35.2643897f), DEG2RAD(-135.0f) }, { DEG2RAD( 35.2643897f), DEG2RAD( -45.0f) }, { DEG2RAD( 0.0f), DEG2RAD( 0.0f) }, { DEG2RAD( 0.0f), DEG2RAD( 45.0f) }, { DEG2RAD( 0.0f), DEG2RAD( 90.0f) }, { DEG2RAD( 0.0f), DEG2RAD( 135.0f) }, { DEG2RAD( 0.0f), DEG2RAD( 180.0f) }, { DEG2RAD( 0.0f), DEG2RAD(-135.0f) }, { DEG2RAD( 0.0f), DEG2RAD( -90.0f) }, { DEG2RAD( 0.0f), DEG2RAD( -45.0f) }, { DEG2RAD(-35.2643897f), DEG2RAD( 45.0f) }, { DEG2RAD(-35.2643897f), DEG2RAD( 135.0f) }, { DEG2RAD(-35.2643897f), DEG2RAD(-135.0f) }, { DEG2RAD(-35.2643897f), DEG2RAD( -45.0f) }, { DEG2RAD(-90.0f), DEG2RAD( 0.0f) }, }; static const ALfloat AmbiMatrixFOA[][MAX_AMBI_COEFFS] = { { 5.55555556e-02f, 0.00000000e+00f, 1.23717915e-01f, 0.00000000e+00f }, { 5.55555556e-02f, -5.00000000e-02f, 7.14285715e-02f, 5.00000000e-02f }, { 5.55555556e-02f, -5.00000000e-02f, 7.14285715e-02f, -5.00000000e-02f }, { 5.55555556e-02f, 5.00000000e-02f, 7.14285715e-02f, -5.00000000e-02f }, { 5.55555556e-02f, 5.00000000e-02f, 7.14285715e-02f, 5.00000000e-02f }, { 5.55555556e-02f, 0.00000000e+00f, 0.00000000e+00f, 8.66025404e-02f }, { 5.55555556e-02f, -6.12372435e-02f, 0.00000000e+00f, 6.12372435e-02f }, { 5.55555556e-02f, -8.66025404e-02f, 0.00000000e+00f, 0.00000000e+00f }, { 5.55555556e-02f, -6.12372435e-02f, 0.00000000e+00f, -6.12372435e-02f }, { 5.55555556e-02f, 0.00000000e+00f, 0.00000000e+00f, -8.66025404e-02f }, { 5.55555556e-02f, 6.12372435e-02f, 0.00000000e+00f, -6.12372435e-02f }, { 5.55555556e-02f, 8.66025404e-02f, 0.00000000e+00f, 0.00000000e+00f }, { 5.55555556e-02f, 6.12372435e-02f, 0.00000000e+00f, 6.12372435e-02f }, { 5.55555556e-02f, -5.00000000e-02f, -7.14285715e-02f, 5.00000000e-02f }, { 5.55555556e-02f, -5.00000000e-02f, -7.14285715e-02f, -5.00000000e-02f }, { 5.55555556e-02f, 5.00000000e-02f, -7.14285715e-02f, -5.00000000e-02f }, { 5.55555556e-02f, 5.00000000e-02f, -7.14285715e-02f, 5.00000000e-02f }, { 5.55555556e-02f, 0.00000000e+00f, -1.23717915e-01f, 0.00000000e+00f }, }, AmbiMatrixHOA[][MAX_AMBI_COEFFS] = { { 5.55555556e-02f, 0.00000000e+00f, 1.23717915e-01f, 0.00000000e+00f, 0.00000000e+00f, 0.00000000e+00f }, { 5.55555556e-02f, -5.00000000e-02f, 7.14285715e-02f, 5.00000000e-02f, -4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, -5.00000000e-02f, 7.14285715e-02f, -5.00000000e-02f, 4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 5.00000000e-02f, 7.14285715e-02f, -5.00000000e-02f, -4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 5.00000000e-02f, 7.14285715e-02f, 5.00000000e-02f, 4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 0.00000000e+00f, 0.00000000e+00f, 8.66025404e-02f, 0.00000000e+00f, 1.29099445e-01f }, { 5.55555556e-02f, -6.12372435e-02f, 0.00000000e+00f, 6.12372435e-02f, -6.83467648e-02f, 0.00000000e+00f }, { 5.55555556e-02f, -8.66025404e-02f, 0.00000000e+00f, 0.00000000e+00f, 0.00000000e+00f, -1.29099445e-01f }, { 5.55555556e-02f, -6.12372435e-02f, 0.00000000e+00f, -6.12372435e-02f, 6.83467648e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 0.00000000e+00f, 0.00000000e+00f, -8.66025404e-02f, 0.00000000e+00f, 1.29099445e-01f }, { 5.55555556e-02f, 6.12372435e-02f, 0.00000000e+00f, -6.12372435e-02f, -6.83467648e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 8.66025404e-02f, 0.00000000e+00f, 0.00000000e+00f, 0.00000000e+00f, -1.29099445e-01f }, { 5.55555556e-02f, 6.12372435e-02f, 0.00000000e+00f, 6.12372435e-02f, 6.83467648e-02f, 0.00000000e+00f }, { 5.55555556e-02f, -5.00000000e-02f, -7.14285715e-02f, 5.00000000e-02f, -4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, -5.00000000e-02f, -7.14285715e-02f, -5.00000000e-02f, 4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 5.00000000e-02f, -7.14285715e-02f, -5.00000000e-02f, -4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 5.00000000e-02f, -7.14285715e-02f, 5.00000000e-02f, 4.55645099e-02f, 0.00000000e+00f }, { 5.55555556e-02f, 0.00000000e+00f, -1.23717915e-01f, 0.00000000e+00f, 0.00000000e+00f, 0.00000000e+00f }, }; static const ALfloat AmbiOrderHFGainFOA[MAX_AMBI_ORDER+1] = { 3.00000000e+00f, 1.73205081e+00f }, AmbiOrderHFGainHOA[MAX_AMBI_ORDER+1] = { 2.40192231e+00f, 1.86052102e+00f, 9.60768923e-01f }; static const ALsizei IndexMap[6] = { 0, 1, 2, 3, 4, 8 }; static const ALsizei ChansPerOrder[MAX_AMBI_ORDER+1] = { 1, 3, 2, 0 }; const ALfloat (*restrict AmbiMatrix)[MAX_AMBI_COEFFS] = AmbiMatrixFOA; const ALfloat *restrict AmbiOrderHFGain = AmbiOrderHFGainFOA; ALsizei count = 4; ALsizei i; static_assert(COUNTOF(AmbiPoints) == COUNTOF(AmbiMatrixFOA), "FOA Ambisonic HRTF mismatch"); static_assert(COUNTOF(AmbiPoints) == COUNTOF(AmbiMatrixHOA), "HOA Ambisonic HRTF mismatch"); static_assert(COUNTOF(AmbiPoints) <= HRTF_AMBI_MAX_CHANNELS, "HRTF_AMBI_MAX_CHANNELS is too small"); if(device->AmbiUp) { AmbiMatrix = AmbiMatrixHOA; AmbiOrderHFGain = AmbiOrderHFGainHOA; count = COUNTOF(IndexMap); } device->Hrtf = al_calloc(16, FAM_SIZE(DirectHrtfState, Chan, count)); for(i = 0;i < count;i++) { device->Dry.Ambi.Map[i].Scale = 1.0f; device->Dry.Ambi.Map[i].Index = IndexMap[i]; } device->Dry.CoeffCount = 0; device->Dry.NumChannels = count; if(device->AmbiUp) { memset(&device->FOAOut.Ambi, 0, sizeof(device->FOAOut.Ambi)); for(i = 0;i < 4;i++) { device->FOAOut.Ambi.Map[i].Scale = 1.0f; device->FOAOut.Ambi.Map[i].Index = i; } device->FOAOut.CoeffCount = 0; device->FOAOut.NumChannels = 4; ambiup_reset(device->AmbiUp, device, AmbiOrderHFGainFOA[0] / AmbiOrderHFGain[0], AmbiOrderHFGainFOA[1] / AmbiOrderHFGain[1]); } else { device->FOAOut.Ambi = device->Dry.Ambi; device->FOAOut.CoeffCount = device->Dry.CoeffCount; device->FOAOut.NumChannels = 0; } device->RealOut.NumChannels = ChannelsFromDevFmt(device->FmtChans, device->AmbiOrder); BuildBFormatHrtf(device->HrtfHandle, device->Hrtf, device->Dry.NumChannels, AmbiPoints, AmbiMatrix, COUNTOF(AmbiPoints), AmbiOrderHFGain ); InitNearFieldCtrl(device, device->HrtfHandle->distance, device->AmbiUp ? 2 : 1, ChansPerOrder); } static void InitUhjPanning(ALCdevice *device) { ALsizei count = 3; ALsizei i; for(i = 0;i < count;i++) { ALsizei acn = FuMa2ACN[i]; device->Dry.Ambi.Map[i].Scale = 1.0f/FuMa2N3DScale[acn]; device->Dry.Ambi.Map[i].Index = acn; } device->Dry.CoeffCount = 0; device->Dry.NumChannels = count; device->FOAOut.Ambi = device->Dry.Ambi; device->FOAOut.CoeffCount = device->Dry.CoeffCount; device->FOAOut.NumChannels = 0; device->RealOut.NumChannels = ChannelsFromDevFmt(device->FmtChans, device->AmbiOrder); } void aluInitRenderer(ALCdevice *device, ALint hrtf_id, enum HrtfRequestMode hrtf_appreq, enum HrtfRequestMode hrtf_userreq) { /* Hold the HRTF the device last used, in case it's used again. */ struct Hrtf *old_hrtf = device->HrtfHandle; const char *mode; bool headphones; int bs2blevel; size_t i; al_free(device->Hrtf); device->Hrtf = NULL; device->HrtfHandle = NULL; alstr_clear(&device->HrtfName); device->Render_Mode = NormalRender; memset(&device->Dry.Ambi, 0, sizeof(device->Dry.Ambi)); device->Dry.CoeffCount = 0; device->Dry.NumChannels = 0; for(i = 0;i < MAX_AMBI_ORDER+1;i++) device->Dry.NumChannelsPerOrder[i] = 0; device->AvgSpeakerDist = 0.0f; memset(device->ChannelDelay, 0, sizeof(device->ChannelDelay)); for(i = 0;i < MAX_OUTPUT_CHANNELS;i++) { device->ChannelDelay[i].Gain = 1.0f; device->ChannelDelay[i].Length = 0; } al_free(device->Stablizer); device->Stablizer = NULL; if(device->FmtChans != DevFmtStereo) { ALsizei speakermap[MAX_OUTPUT_CHANNELS]; const char *devname, *layout = NULL; AmbDecConf conf, *pconf = NULL; if(old_hrtf) Hrtf_DecRef(old_hrtf); old_hrtf = NULL; if(hrtf_appreq == Hrtf_Enable) device->HrtfStatus = ALC_HRTF_UNSUPPORTED_FORMAT_SOFT; ambdec_init(&conf); devname = alstr_get_cstr(device->DeviceName); switch(device->FmtChans) { case DevFmtQuad: layout = "quad"; break; case DevFmtX51: /* fall-through */ case DevFmtX51Rear: layout = "surround51"; break; case DevFmtX61: layout = "surround61"; break; case DevFmtX71: layout = "surround71"; break; /* Mono, Stereo, and Ambisonics output don't use custom decoders. */ case DevFmtMono: case DevFmtStereo: case DevFmtAmbi3D: break; } if(layout) { const char *fname; if(ConfigValueStr(devname, "decoder", layout, &fname)) { if(!ambdec_load(&conf, fname)) ERR("Failed to load layout file %s\n", fname); else { if(conf.ChanMask > 0xffff) ERR("Unsupported channel mask 0x%04x (max 0xffff)\n", conf.ChanMask); else { if(MakeSpeakerMap(device, &conf, speakermap)) pconf = &conf; } } } } if(pconf && GetConfigValueBool(devname, "decoder", "hq-mode", 0)) { ambiup_free(&device->AmbiUp); if(!device->AmbiDecoder) device->AmbiDecoder = bformatdec_alloc(); } else { bformatdec_free(&device->AmbiDecoder); if(device->FmtChans != DevFmtAmbi3D || device->AmbiOrder < 2) ambiup_free(&device->AmbiUp); else { if(!device->AmbiUp) device->AmbiUp = ambiup_alloc(); } } if(!pconf) InitPanning(device); else if(device->AmbiDecoder) InitHQPanning(device, pconf, speakermap); else InitCustomPanning(device, pconf, speakermap); /* Enable the stablizer only for formats that have front-left, front- * right, and front-center outputs. */ switch(device->FmtChans) { case DevFmtX51: case DevFmtX51Rear: case DevFmtX61: case DevFmtX71: if(GetConfigValueBool(devname, NULL, "front-stablizer", 0)) { /* Initialize band-splitting filters for the front-left and * front-right channels, with a crossover at 5khz (could be * higher). */ ALfloat scale = (ALfloat)(5000.0 / device->Frequency); FrontStablizer *stablizer = al_calloc(16, sizeof(*stablizer)); bandsplit_init(&stablizer->LFilter, scale); stablizer->RFilter = stablizer->LFilter; /* Initialize all-pass filters for all other channels. */ splitterap_init(&stablizer->APFilter[0], scale); for(i = 1;i < (size_t)device->RealOut.NumChannels;i++) stablizer->APFilter[i] = stablizer->APFilter[0]; device->Stablizer = stablizer; } break; case DevFmtMono: case DevFmtStereo: case DevFmtQuad: case DevFmtAmbi3D: break; } TRACE("Front stablizer %s\n", device->Stablizer ? "enabled" : "disabled"); ambdec_deinit(&conf); return; } bformatdec_free(&device->AmbiDecoder); headphones = device->IsHeadphones; if(device->Type != Loopback) { const char *mode; if(ConfigValueStr(alstr_get_cstr(device->DeviceName), NULL, "stereo-mode", &mode)) { if(strcasecmp(mode, "headphones") == 0) headphones = true; else if(strcasecmp(mode, "speakers") == 0) headphones = false; else if(strcasecmp(mode, "auto") != 0) ERR("Unexpected stereo-mode: %s\n", mode); } } if(hrtf_userreq == Hrtf_Default) { bool usehrtf = (headphones && hrtf_appreq != Hrtf_Disable) || (hrtf_appreq == Hrtf_Enable); if(!usehrtf) goto no_hrtf; device->HrtfStatus = ALC_HRTF_ENABLED_SOFT; if(headphones && hrtf_appreq != Hrtf_Disable) device->HrtfStatus = ALC_HRTF_HEADPHONES_DETECTED_SOFT; } else { if(hrtf_userreq != Hrtf_Enable) { if(hrtf_appreq == Hrtf_Enable) device->HrtfStatus = ALC_HRTF_DENIED_SOFT; goto no_hrtf; } device->HrtfStatus = ALC_HRTF_REQUIRED_SOFT; } if(VECTOR_SIZE(device->HrtfList) == 0) { VECTOR_DEINIT(device->HrtfList); device->HrtfList = EnumerateHrtf(device->DeviceName); } if(hrtf_id >= 0 && (size_t)hrtf_id < VECTOR_SIZE(device->HrtfList)) { const EnumeratedHrtf *entry = &VECTOR_ELEM(device->HrtfList, hrtf_id); struct Hrtf *hrtf = GetLoadedHrtf(entry->hrtf); if(hrtf && hrtf->sampleRate == device->Frequency) { device->HrtfHandle = hrtf; alstr_copy(&device->HrtfName, entry->name); } else if(hrtf) Hrtf_DecRef(hrtf); } for(i = 0;!device->HrtfHandle && i < VECTOR_SIZE(device->HrtfList);i++) { const EnumeratedHrtf *entry = &VECTOR_ELEM(device->HrtfList, i); struct Hrtf *hrtf = GetLoadedHrtf(entry->hrtf); if(hrtf && hrtf->sampleRate == device->Frequency) { device->HrtfHandle = hrtf; alstr_copy(&device->HrtfName, entry->name); } else if(hrtf) Hrtf_DecRef(hrtf); } if(device->HrtfHandle) { if(old_hrtf) Hrtf_DecRef(old_hrtf); old_hrtf = NULL; device->Render_Mode = HrtfRender; if(ConfigValueStr(alstr_get_cstr(device->DeviceName), NULL, "hrtf-mode", &mode)) { if(strcasecmp(mode, "full") == 0) device->Render_Mode = HrtfRender; else if(strcasecmp(mode, "basic") == 0) device->Render_Mode = NormalRender; else ERR("Unexpected hrtf-mode: %s\n", mode); } if(device->Render_Mode == HrtfRender) { /* Don't bother with HOA when using full HRTF rendering. Nothing * needs it, and it eases the CPU/memory load. */ ambiup_free(&device->AmbiUp); } else { if(!device->AmbiUp) device->AmbiUp = ambiup_alloc(); } TRACE("%s HRTF rendering enabled, using \"%s\"\n", ((device->Render_Mode == HrtfRender) ? "Full" : "Basic"), alstr_get_cstr(device->HrtfName) ); InitHrtfPanning(device); return; } device->HrtfStatus = ALC_HRTF_UNSUPPORTED_FORMAT_SOFT; no_hrtf: if(old_hrtf) Hrtf_DecRef(old_hrtf); old_hrtf = NULL; TRACE("HRTF disabled\n"); device->Render_Mode = StereoPair; ambiup_free(&device->AmbiUp); bs2blevel = ((headphones && hrtf_appreq != Hrtf_Disable) || (hrtf_appreq == Hrtf_Enable)) ? 5 : 0; if(device->Type != Loopback) ConfigValueInt(alstr_get_cstr(device->DeviceName), NULL, "cf_level", &bs2blevel); if(bs2blevel > 0 && bs2blevel <= 6) { device->Bs2b = al_calloc(16, sizeof(*device->Bs2b)); bs2b_set_params(device->Bs2b, bs2blevel, device->Frequency); TRACE("BS2B enabled\n"); InitPanning(device); return; } TRACE("BS2B disabled\n"); if(ConfigValueStr(alstr_get_cstr(device->DeviceName), NULL, "stereo-encoding", &mode)) { if(strcasecmp(mode, "uhj") == 0) device->Render_Mode = NormalRender; else if(strcasecmp(mode, "panpot") != 0) ERR("Unexpected stereo-encoding: %s\n", mode); } if(device->Render_Mode == NormalRender) { device->Uhj_Encoder = al_calloc(16, sizeof(Uhj2Encoder)); TRACE("UHJ enabled\n"); InitUhjPanning(device); return; } TRACE("UHJ disabled\n"); InitPanning(device); } void aluInitEffectPanning(ALeffectslot *slot) { ALsizei i; memset(slot->ChanMap, 0, sizeof(slot->ChanMap)); slot->NumChannels = 0; for(i = 0;i < MAX_EFFECT_CHANNELS;i++) { slot->ChanMap[i].Scale = 1.0f; slot->ChanMap[i].Index = i; } slot->NumChannels = i; }