/** * OpenAL cross platform audio library * Copyright (C) 2011 by Chris Robinson * 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., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. * Or go to http://www.gnu.org/copyleft/lgpl.html */ #include "config.h" #include #include #include "AL/al.h" #include "AL/alc.h" #include "alMain.h" #include "alSource.h" #include "alu.h" #ifndef PATH_MAX #define PATH_MAX 4096 #endif /* Current data set limits defined by the makehrtf utility. */ #define MIN_IR_SIZE (8) #define MAX_IR_SIZE (128) #define MOD_IR_SIZE (8) #define MIN_EV_COUNT (5) #define MAX_EV_COUNT (128) #define MIN_AZ_COUNT (1) #define MAX_AZ_COUNT (128) struct Hrtf { ALuint sampleRate; ALuint irSize; ALubyte evCount; const ALubyte *azCount; const ALushort *evOffset; const ALshort *coeffs; const ALubyte *delays; struct Hrtf *next; }; static const ALchar magicMarker00[8] = "MinPHR00"; static const ALchar magicMarker01[8] = "MinPHR01"; /* Define the default HRTF: * ALubyte defaultAzCount [DefaultHrtf.evCount] * ALushort defaultEvOffset [DefaultHrtf.evCount] * ALshort defaultCoeffs [DefaultHrtf.irCount * defaultHrtf.irSize] * ALubyte defaultDelays [DefaultHrtf.irCount] * * struct Hrtf DefaultHrtf */ #include "hrtf_tables.inc" static struct Hrtf *LoadedHrtfs = NULL; /* Calculate the elevation indices given the polar elevation in radians. * This will return two indices between 0 and (Hrtf->evCount - 1) and an * interpolation factor between 0.0 and 1.0. */ static void CalcEvIndices(const struct Hrtf *Hrtf, ALfloat ev, ALuint *evidx, ALfloat *evmu) { ev = (F_PI_2 + ev) * (Hrtf->evCount-1) / F_PI; evidx[0] = fastf2u(ev); evidx[1] = minu(evidx[0] + 1, Hrtf->evCount-1); *evmu = ev - evidx[0]; } /* Calculate the azimuth indices given the polar azimuth in radians. This * will return two indices between 0 and (Hrtf->azCount[ei] - 1) and an * interpolation factor between 0.0 and 1.0. */ static void CalcAzIndices(const struct Hrtf *Hrtf, ALuint evidx, ALfloat az, ALuint *azidx, ALfloat *azmu) { az = (F_PI*2.0f + az) * Hrtf->azCount[evidx] / (F_PI*2.0f); azidx[0] = fastf2u(az) % Hrtf->azCount[evidx]; azidx[1] = (azidx[0] + 1) % Hrtf->azCount[evidx]; *azmu = az - floorf(az); } /* Calculates the normalized HRTF transition factor (delta) from the changes * in gain and listener to source angle between updates. The result is a * normalized delta factor that can be used to calculate moving HRIR stepping * values. */ ALfloat CalcHrtfDelta(ALfloat oldGain, ALfloat newGain, const ALfloat olddir[3], const ALfloat newdir[3]) { ALfloat gainChange, angleChange, change; // Calculate the normalized dB gain change. newGain = maxf(newGain, 0.0001f); oldGain = maxf(oldGain, 0.0001f); gainChange = fabsf(log10f(newGain / oldGain) / log10f(0.0001f)); // Calculate the normalized listener to source angle change when there is // enough gain to notice it. angleChange = 0.0f; if(gainChange > 0.0001f || newGain > 0.0001f) { // No angle change when the directions are equal or degenerate (when // both have zero length). if(newdir[0]-olddir[0] || newdir[1]-olddir[1] || newdir[2]-olddir[2]) angleChange = acosf(olddir[0]*newdir[0] + olddir[1]*newdir[1] + olddir[2]*newdir[2]) / F_PI; } // Use the largest of the two changes for the delta factor, and apply a // significance shaping function to it. change = maxf(angleChange * 25.0f, gainChange) * 2.0f; return minf(change, 1.0f); } /* Calculates static HRIR coefficients and delays for the given polar * elevation and azimuth in radians. Linear interpolation is used to * increase the apparent resolution of the HRIR data set. The coefficients * are also normalized and attenuated by the specified gain. */ void GetLerpedHrtfCoeffs(const struct Hrtf *Hrtf, ALfloat elevation, ALfloat azimuth, ALfloat gain, ALfloat (*coeffs)[2], ALuint *delays) { ALuint evidx[2], azidx[2]; ALuint lidx[4], ridx[4]; ALfloat mu[3], blend[4]; ALuint i; // Claculate elevation indices and interpolation factor. CalcEvIndices(Hrtf, elevation, evidx, &mu[2]); // Calculate azimuth indices and interpolation factor for the first // elevation. CalcAzIndices(Hrtf, evidx[0], azimuth, azidx, &mu[0]); // Calculate the first set of linear HRIR indices for left and right // channels. lidx[0] = Hrtf->evOffset[evidx[0]] + azidx[0]; lidx[1] = Hrtf->evOffset[evidx[0]] + azidx[1]; ridx[0] = Hrtf->evOffset[evidx[0]] + ((Hrtf->azCount[evidx[0]]-azidx[0]) % Hrtf->azCount[evidx[0]]); ridx[1] = Hrtf->evOffset[evidx[0]] + ((Hrtf->azCount[evidx[0]]-azidx[1]) % Hrtf->azCount[evidx[0]]); // Calculate azimuth indices and interpolation factor for the second // elevation. CalcAzIndices(Hrtf, evidx[1], azimuth, azidx, &mu[1]); // Calculate the second set of linear HRIR indices for left and right // channels. lidx[2] = Hrtf->evOffset[evidx[1]] + azidx[0]; lidx[3] = Hrtf->evOffset[evidx[1]] + azidx[1]; ridx[2] = Hrtf->evOffset[evidx[1]] + ((Hrtf->azCount[evidx[1]]-azidx[0]) % Hrtf->azCount[evidx[1]]); ridx[3] = Hrtf->evOffset[evidx[1]] + ((Hrtf->azCount[evidx[1]]-azidx[1]) % Hrtf->azCount[evidx[1]]); /* Calculate 4 blending weights for 2D bilinear interpolation. */ blend[0] = (1.0f-mu[0]) * (1.0f-mu[2]); blend[1] = ( mu[0]) * (1.0f-mu[2]); blend[2] = (1.0f-mu[1]) * ( mu[2]); blend[3] = ( mu[1]) * ( mu[2]); /* Calculate the HRIR delays using linear interpolation. */ delays[0] = fastf2u(Hrtf->delays[lidx[0]]*blend[0] + Hrtf->delays[lidx[1]]*blend[1] + Hrtf->delays[lidx[2]]*blend[2] + Hrtf->delays[lidx[3]]*blend[3] + 0.5f) << HRTFDELAY_BITS; delays[1] = fastf2u(Hrtf->delays[ridx[0]]*blend[0] + Hrtf->delays[ridx[1]]*blend[1] + Hrtf->delays[ridx[2]]*blend[2] + Hrtf->delays[ridx[3]]*blend[3] + 0.5f) << HRTFDELAY_BITS; /* Calculate the sample offsets for the HRIR indices. */ lidx[0] *= Hrtf->irSize; lidx[1] *= Hrtf->irSize; lidx[2] *= Hrtf->irSize; lidx[3] *= Hrtf->irSize; ridx[0] *= Hrtf->irSize; ridx[1] *= Hrtf->irSize; ridx[2] *= Hrtf->irSize; ridx[3] *= Hrtf->irSize; /* Calculate the normalized and attenuated HRIR coefficients using linear * interpolation when there is enough gain to warrant it. Zero the * coefficients if gain is too low. */ if(gain > 0.0001f) { gain *= 1.0f/32767.0f; for(i = 0;i < Hrtf->irSize;i++) { coeffs[i][0] = (Hrtf->coeffs[lidx[0]+i]*blend[0] + Hrtf->coeffs[lidx[1]+i]*blend[1] + Hrtf->coeffs[lidx[2]+i]*blend[2] + Hrtf->coeffs[lidx[3]+i]*blend[3]) * gain; coeffs[i][1] = (Hrtf->coeffs[ridx[0]+i]*blend[0] + Hrtf->coeffs[ridx[1]+i]*blend[1] + Hrtf->coeffs[ridx[2]+i]*blend[2] + Hrtf->coeffs[ridx[3]+i]*blend[3]) * gain; } } else { for(i = 0;i < Hrtf->irSize;i++) { coeffs[i][0] = 0.0f; coeffs[i][1] = 0.0f; } } } /* Calculates the moving HRIR target coefficients, target delays, and * stepping values for the given polar elevation and azimuth in radians. * Linear interpolation is used to increase the apparent resolution of the * HRIR data set. The coefficients are also normalized and attenuated by the * specified gain. Stepping resolution and count is determined using the * given delta factor between 0.0 and 1.0. */ ALuint GetMovingHrtfCoeffs(const struct Hrtf *Hrtf, ALfloat elevation, ALfloat azimuth, ALfloat gain, ALfloat delta, ALint counter, ALfloat (*coeffs)[2], ALuint *delays, ALfloat (*coeffStep)[2], ALint *delayStep) { ALuint evidx[2], azidx[2]; ALuint lidx[4], ridx[4]; ALfloat mu[3], blend[4]; ALfloat left, right; ALfloat step; ALuint i; // Claculate elevation indices and interpolation factor. CalcEvIndices(Hrtf, elevation, evidx, &mu[2]); // Calculate azimuth indices and interpolation factor for the first // elevation. CalcAzIndices(Hrtf, evidx[0], azimuth, azidx, &mu[0]); // Calculate the first set of linear HRIR indices for left and right // channels. lidx[0] = Hrtf->evOffset[evidx[0]] + azidx[0]; lidx[1] = Hrtf->evOffset[evidx[0]] + azidx[1]; ridx[0] = Hrtf->evOffset[evidx[0]] + ((Hrtf->azCount[evidx[0]]-azidx[0]) % Hrtf->azCount[evidx[0]]); ridx[1] = Hrtf->evOffset[evidx[0]] + ((Hrtf->azCount[evidx[0]]-azidx[1]) % Hrtf->azCount[evidx[0]]); // Calculate azimuth indices and interpolation factor for the second // elevation. CalcAzIndices(Hrtf, evidx[1], azimuth, azidx, &mu[1]); // Calculate the second set of linear HRIR indices for left and right // channels. lidx[2] = Hrtf->evOffset[evidx[1]] + azidx[0]; lidx[3] = Hrtf->evOffset[evidx[1]] + azidx[1]; ridx[2] = Hrtf->evOffset[evidx[1]] + ((Hrtf->azCount[evidx[1]]-azidx[0]) % Hrtf->azCount[evidx[1]]); ridx[3] = Hrtf->evOffset[evidx[1]] + ((Hrtf->azCount[evidx[1]]-azidx[1]) % Hrtf->azCount[evidx[1]]); // Calculate the stepping parameters. delta = maxf(floorf(delta*(Hrtf->sampleRate*0.015f) + 0.5f), 1.0f); step = 1.0f / delta; /* Calculate 4 blending weights for 2D bilinear interpolation. */ blend[0] = (1.0f-mu[0]) * (1.0f-mu[2]); blend[1] = ( mu[0]) * (1.0f-mu[2]); blend[2] = (1.0f-mu[1]) * ( mu[2]); blend[3] = ( mu[1]) * ( mu[2]); /* Calculate the HRIR delays using linear interpolation. Then calculate * the delay stepping values using the target and previous running * delays. */ left = (ALfloat)(delays[0] - (delayStep[0] * counter)); right = (ALfloat)(delays[1] - (delayStep[1] * counter)); delays[0] = fastf2u(Hrtf->delays[lidx[0]]*blend[0] + Hrtf->delays[lidx[1]]*blend[1] + Hrtf->delays[lidx[2]]*blend[2] + Hrtf->delays[lidx[3]]*blend[3] + 0.5f) << HRTFDELAY_BITS; delays[1] = fastf2u(Hrtf->delays[ridx[0]]*blend[0] + Hrtf->delays[ridx[1]]*blend[1] + Hrtf->delays[ridx[2]]*blend[2] + Hrtf->delays[ridx[3]]*blend[3] + 0.5f) << HRTFDELAY_BITS; delayStep[0] = fastf2i(step * (delays[0] - left)); delayStep[1] = fastf2i(step * (delays[1] - right)); /* Calculate the sample offsets for the HRIR indices. */ lidx[0] *= Hrtf->irSize; lidx[1] *= Hrtf->irSize; lidx[2] *= Hrtf->irSize; lidx[3] *= Hrtf->irSize; ridx[0] *= Hrtf->irSize; ridx[1] *= Hrtf->irSize; ridx[2] *= Hrtf->irSize; ridx[3] *= Hrtf->irSize; /* Calculate the normalized and attenuated target HRIR coefficients using * linear interpolation when there is enough gain to warrant it. Zero * the target coefficients if gain is too low. Then calculate the * coefficient stepping values using the target and previous running * coefficients. */ if(gain > 0.0001f) { gain *= 1.0f/32767.0f; for(i = 0;i < HRIR_LENGTH;i++) { left = coeffs[i][0] - (coeffStep[i][0] * counter); right = coeffs[i][1] - (coeffStep[i][1] * counter); coeffs[i][0] = (Hrtf->coeffs[lidx[0]+i]*blend[0] + Hrtf->coeffs[lidx[1]+i]*blend[1] + Hrtf->coeffs[lidx[2]+i]*blend[2] + Hrtf->coeffs[lidx[3]+i]*blend[3]) * gain; coeffs[i][1] = (Hrtf->coeffs[ridx[0]+i]*blend[0] + Hrtf->coeffs[ridx[1]+i]*blend[1] + Hrtf->coeffs[ridx[2]+i]*blend[2] + Hrtf->coeffs[ridx[3]+i]*blend[3]) * gain; coeffStep[i][0] = step * (coeffs[i][0] - left); coeffStep[i][1] = step * (coeffs[i][1] - right); } } else { for(i = 0;i < HRIR_LENGTH;i++) { left = coeffs[i][0] - (coeffStep[i][0] * counter); right = coeffs[i][1] - (coeffStep[i][1] * counter); coeffs[i][0] = 0.0f; coeffs[i][1] = 0.0f; coeffStep[i][0] = step * -left; coeffStep[i][1] = step * -right; } } /* The stepping count is the number of samples necessary for the HRIR to * complete its transition. The mixer will only apply stepping for this * many samples. */ return fastf2u(delta); } static struct Hrtf *LoadHrtf00(FILE *f, ALuint deviceRate) { const ALubyte maxDelay = SRC_HISTORY_LENGTH-1; struct Hrtf *Hrtf = NULL; ALboolean failed = AL_FALSE; ALuint rate = 0, irCount = 0; ALushort irSize = 0; ALubyte evCount = 0; ALubyte *azCount = NULL; ALushort *evOffset = NULL; ALshort *coeffs = NULL; ALubyte *delays = NULL; ALuint i, j; rate = fgetc(f); rate |= fgetc(f)<<8; rate |= fgetc(f)<<16; rate |= fgetc(f)<<24; irCount = fgetc(f); irCount |= fgetc(f)<<8; irSize = fgetc(f); irSize |= fgetc(f)<<8; evCount = fgetc(f); if(rate != deviceRate) { ERR("HRIR rate does not match device rate: rate=%d (%d)\n", rate, deviceRate); failed = AL_TRUE; } if(irSize < MIN_IR_SIZE || irSize > MAX_IR_SIZE || (irSize%MOD_IR_SIZE)) { ERR("Unsupported HRIR size: irSize=%d (%d to %d by %d)\n", irSize, MIN_IR_SIZE, MAX_IR_SIZE, MOD_IR_SIZE); failed = AL_TRUE; } if(evCount < MIN_EV_COUNT || evCount > MAX_EV_COUNT) { ERR("Unsupported elevation count: evCount=%d (%d to %d)\n", evCount, MIN_EV_COUNT, MAX_EV_COUNT); failed = AL_TRUE; } if(failed) return NULL; azCount = malloc(sizeof(azCount[0])*evCount); evOffset = malloc(sizeof(evOffset[0])*evCount); if(azCount == NULL || evOffset == NULL) { ERR("Out of memory.\n"); failed = AL_TRUE; } if(!failed) { evOffset[0] = fgetc(f); evOffset[0] |= fgetc(f)<<8; for(i = 1;i < evCount;i++) { evOffset[i] = fgetc(f); evOffset[i] |= fgetc(f)<<8; if(evOffset[i] <= evOffset[i-1]) { ERR("Invalid evOffset: evOffset[%d]=%d (last=%d)\n", i, evOffset[i], evOffset[i-1]); failed = AL_TRUE; } azCount[i-1] = evOffset[i] - evOffset[i-1]; if(azCount[i-1] < MIN_AZ_COUNT || azCount[i-1] > MAX_AZ_COUNT) { ERR("Unsupported azimuth count: azCount[%d]=%d (%d to %d)\n", i-1, azCount[i-1], MIN_AZ_COUNT, MAX_AZ_COUNT); failed = AL_TRUE; } } if(irCount <= evOffset[i-1]) { ERR("Invalid evOffset: evOffset[%d]=%d (irCount=%d)\n", i-1, evOffset[i-1], irCount); failed = AL_TRUE; } azCount[i-1] = irCount - evOffset[i-1]; if(azCount[i-1] < MIN_AZ_COUNT || azCount[i-1] > MAX_AZ_COUNT) { ERR("Unsupported azimuth count: azCount[%d]=%d (%d to %d)\n", i-1, azCount[i-1], MIN_AZ_COUNT, MAX_AZ_COUNT); failed = AL_TRUE; } } if(!failed) { coeffs = malloc(sizeof(coeffs[0])*irSize*irCount); delays = malloc(sizeof(delays[0])*irCount); if(coeffs == NULL || delays == NULL) { ERR("Out of memory.\n"); failed = AL_TRUE; } } if(!failed) { for(i = 0;i < irCount*irSize;i+=irSize) { for(j = 0;j < irSize;j++) { ALshort coeff; coeff = fgetc(f); coeff |= fgetc(f)<<8; coeffs[i+j] = coeff; } } for(i = 0;i < irCount;i++) { delays[i] = fgetc(f); if(delays[i] > maxDelay) { ERR("Invalid delays[%d]: %d (%d)\n", i, delays[i], maxDelay); failed = AL_TRUE; } } if(feof(f)) { ERR("Premature end of data\n"); failed = AL_TRUE; } } if(!failed) { Hrtf = malloc(sizeof(struct Hrtf)); if(Hrtf == NULL) { ERR("Out of memory.\n"); failed = AL_TRUE; } } if(!failed) { Hrtf->sampleRate = rate; Hrtf->irSize = irSize; Hrtf->evCount = evCount; Hrtf->azCount = azCount; Hrtf->evOffset = evOffset; Hrtf->coeffs = coeffs; Hrtf->delays = delays; Hrtf->next = NULL; return Hrtf; } free(azCount); free(evOffset); free(coeffs); free(delays); return NULL; } static struct Hrtf *LoadHrtf01(FILE *f, ALuint deviceRate) { const ALubyte maxDelay = SRC_HISTORY_LENGTH-1; struct Hrtf *Hrtf = NULL; ALboolean failed = AL_FALSE; ALuint rate = 0, irCount = 0; ALubyte irSize = 0, evCount = 0; ALubyte *azCount = NULL; ALushort *evOffset = NULL; ALshort *coeffs = NULL; ALubyte *delays = NULL; ALuint i, j; rate = fgetc(f); rate |= fgetc(f)<<8; rate |= fgetc(f)<<16; rate |= fgetc(f)<<24; irSize = fgetc(f); evCount = fgetc(f); if(rate != deviceRate) { ERR("HRIR rate does not match device rate: rate=%d (%d)\n", rate, deviceRate); failed = AL_TRUE; } if(irSize < MIN_IR_SIZE || irSize > MAX_IR_SIZE || (irSize%MOD_IR_SIZE)) { ERR("Unsupported HRIR size: irSize=%d (%d to %d by %d)\n", irSize, MIN_IR_SIZE, MAX_IR_SIZE, MOD_IR_SIZE); failed = AL_TRUE; } if(evCount < MIN_EV_COUNT || evCount > MAX_EV_COUNT) { ERR("Unsupported elevation count: evCount=%d (%d to %d)\n", evCount, MIN_EV_COUNT, MAX_EV_COUNT); failed = AL_TRUE; } if(failed) return NULL; azCount = malloc(sizeof(azCount[0])*evCount); evOffset = malloc(sizeof(evOffset[0])*evCount); if(azCount == NULL || evOffset == NULL) { ERR("Out of memory.\n"); failed = AL_TRUE; } if(!failed) { for(i = 0;i < evCount;i++) { azCount[i] = fgetc(f); if(azCount[i] < MIN_AZ_COUNT || azCount[i] > MAX_AZ_COUNT) { ERR("Unsupported azimuth count: azCount[%d]=%d (%d to %d)\n", i, azCount[i], MIN_AZ_COUNT, MAX_AZ_COUNT); failed = AL_TRUE; } } } if(!failed) { evOffset[0] = 0; irCount = azCount[0]; for(i = 1;i < evCount;i++) { evOffset[i] = evOffset[i-1] + azCount[i-1]; irCount += azCount[i]; } coeffs = malloc(sizeof(coeffs[0])*irSize*irCount); delays = malloc(sizeof(delays[0])*irCount); if(coeffs == NULL || delays == NULL) { ERR("Out of memory.\n"); failed = AL_TRUE; } } if(!failed) { for(i = 0;i < irCount*irSize;i+=irSize) { for(j = 0;j < irSize;j++) { ALshort coeff; coeff = fgetc(f); coeff |= fgetc(f)<<8; coeffs[i+j] = coeff; } } for(i = 0;i < irCount;i++) { delays[i] = fgetc(f); if(delays[i] > maxDelay) { ERR("Invalid delays[%d]: %d (%d)\n", i, delays[i], maxDelay); failed = AL_TRUE; } } if(feof(f)) { ERR("Premature end of data\n"); failed = AL_TRUE; } } if(!failed) { Hrtf = malloc(sizeof(struct Hrtf)); if(Hrtf == NULL) { ERR("Out of memory.\n"); failed = AL_TRUE; } } if(!failed) { Hrtf->sampleRate = rate; Hrtf->irSize = irSize; Hrtf->evCount = evCount; Hrtf->azCount = azCount; Hrtf->evOffset = evOffset; Hrtf->coeffs = coeffs; Hrtf->delays = delays; Hrtf->next = NULL; return Hrtf; } free(azCount); free(evOffset); free(coeffs); free(delays); return NULL; } static struct Hrtf *LoadHrtf(ALuint deviceRate) { const char *fnamelist = NULL; if(!ConfigValueStr(NULL, "hrtf_tables", &fnamelist)) return NULL; while(*fnamelist != '\0') { struct Hrtf *Hrtf = NULL; char fname[PATH_MAX]; ALchar magic[8]; ALuint i; FILE *f; while(isspace(*fnamelist) || *fnamelist == ',') fnamelist++; i = 0; while(*fnamelist != '\0' && *fnamelist != ',') { const char *next = strpbrk(fnamelist, "%,"); while(fnamelist != next && *fnamelist && i < sizeof(fname)) fname[i++] = *(fnamelist++); if(!next || *next == ',') break; /* *next == '%' */ next++; if(*next == 'r') { int wrote = snprintf(&fname[i], sizeof(fname)-i, "%u", deviceRate); i += minu(wrote, sizeof(fname)-i); next++; } else if(*next == '%') { if(i < sizeof(fname)) fname[i++] = '%'; next++; } else ERR("Invalid marker '%%%c'\n", *next); fnamelist = next; } i = minu(i, sizeof(fname)-1); fname[i] = '\0'; while(i > 0 && isspace(fname[i-1])) i--; fname[i] = '\0'; if(fname[0] == '\0') continue; TRACE("Loading %s...\n", fname); f = fopen(fname, "rb"); if(f == NULL) { ERR("Could not open %s\n", fname); continue; } if(fread(magic, 1, sizeof(magic), f) != sizeof(magic)) ERR("Failed to read header from %s\n", fname); else { if(memcmp(magic, magicMarker00, sizeof(magicMarker00)) == 0) { TRACE("Detected data set format v0\n"); Hrtf = LoadHrtf00(f, deviceRate); } else if(memcmp(magic, magicMarker01, sizeof(magicMarker01)) == 0) { TRACE("Detected data set format v1\n"); Hrtf = LoadHrtf01(f, deviceRate); } else ERR("Invalid header in %s: \"%.8s\"\n", fname, magic); } fclose(f); f = NULL; if(Hrtf) { Hrtf->next = LoadedHrtfs; LoadedHrtfs = Hrtf; TRACE("Loaded HRTF support for format: %s %uhz\n", DevFmtChannelsString(DevFmtStereo), Hrtf->sampleRate); return Hrtf; } ERR("Failed to load %s\n", fname); } return NULL; } const struct Hrtf *GetHrtf(ALCdevice *device) { if(device->FmtChans == DevFmtStereo) { struct Hrtf *Hrtf = LoadedHrtfs; while(Hrtf != NULL) { if(device->Frequency == Hrtf->sampleRate) return Hrtf; Hrtf = Hrtf->next; } Hrtf = LoadHrtf(device->Frequency); if(Hrtf != NULL) return Hrtf; if(device->Frequency == DefaultHrtf.sampleRate) return &DefaultHrtf; } ERR("Incompatible format: %s %uhz\n", DevFmtChannelsString(device->FmtChans), device->Frequency); return NULL; } void FindHrtfFormat(const ALCdevice *device, enum DevFmtChannels *chans, ALCuint *srate) { const struct Hrtf *hrtf = &DefaultHrtf; if(device->Frequency != DefaultHrtf.sampleRate) { hrtf = LoadedHrtfs; while(hrtf != NULL) { if(device->Frequency == hrtf->sampleRate) break; hrtf = hrtf->next; } if(hrtf == NULL) hrtf = LoadHrtf(device->Frequency); if(hrtf == NULL) hrtf = &DefaultHrtf; } *chans = DevFmtStereo; *srate = hrtf->sampleRate; } void FreeHrtfs(void) { struct Hrtf *Hrtf = NULL; while((Hrtf=LoadedHrtfs) != NULL) { LoadedHrtfs = Hrtf->next; free((void*)Hrtf->azCount); free((void*)Hrtf->evOffset); free((void*)Hrtf->coeffs); free((void*)Hrtf->delays); free(Hrtf); } } ALuint GetHrtfIrSize (const struct Hrtf *Hrtf) { return Hrtf->irSize; }