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initial forking of open-al to create multiple listeners
author Robert McIntyre <rlm@mit.edu>
date Tue, 25 Oct 2011 13:02:31 -0700
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     1 /**



     2  * OpenAL cross platform audio library



     3  * Copyright (C) 2009 by Chris Robinson.



     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.



     8  *



     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.



    13  *



    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., 59 Temple Place - Suite 330,



    17  *  Boston, MA  02111-1307, USA.



    18  * Or go to http://www.gnu.org/copyleft/lgpl.html



    19  */



    20 



    21 #include "config.h"



    22 



    23 #include <math.h>



    24 #include <stdlib.h>



    25 



    26 #include "alMain.h"



    27 #include "alFilter.h"



    28 #include "alAuxEffectSlot.h"



    29 #include "alError.h"



    30 #include "alu.h"



    31 



    32 



    33 typedef struct ALechoState {



    34     // Must be first in all effects!



    35     ALeffectState state;



    36 



    37     ALfloat *SampleBuffer;



    38     ALuint BufferLength;



    39 



    40     // The echo is two tap. The delay is the number of samples from before the



    41     // current offset



    42     struct {



    43         ALuint delay;



    44     } Tap[2];



    45     ALuint Offset;



    46     // The LR gains for the first tap. The second tap uses the reverse



    47     ALfloat GainL;



    48     ALfloat GainR;



    49 



    50     ALfloat FeedGain;



    51 



    52     ALfloat Gain[MAXCHANNELS];



    53 



    54     FILTER iirFilter;



    55     ALfloat history[2];



    56 } ALechoState;



    57 



    58 static ALvoid EchoDestroy(ALeffectState *effect)



    59 {



    60     ALechoState *state = (ALechoState*)effect;



    61     if(state)



    62     {



    63         free(state->SampleBuffer);



    64         state->SampleBuffer = NULL;



    65         free(state);



    66     }



    67 }



    68 



    69 static ALboolean EchoDeviceUpdate(ALeffectState *effect, ALCdevice *Device)



    70 {



    71     ALechoState *state = (ALechoState*)effect;



    72     ALuint maxlen, i;



    73 



    74     // Use the next power of 2 for the buffer length, so the tap offsets can be



    75     // wrapped using a mask instead of a modulo



    76     maxlen  = (ALuint)(AL_ECHO_MAX_DELAY * Device->Frequency) + 1;



    77     maxlen += (ALuint)(AL_ECHO_MAX_LRDELAY * Device->Frequency) + 1;



    78     maxlen  = NextPowerOf2(maxlen);



    79 



    80     if(maxlen != state->BufferLength)



    81     {



    82         void *temp;



    83 



    84         temp = realloc(state->SampleBuffer, maxlen * sizeof(ALfloat));



    85         if(!temp)



    86             return AL_FALSE;



    87         state->SampleBuffer = temp;



    88         state->BufferLength = maxlen;



    89     }



    90     for(i = 0;i < state->BufferLength;i++)



    91         state->SampleBuffer[i] = 0.0f;



    92 



    93     return AL_TRUE;



    94 }



    95 



    96 static ALvoid EchoUpdate(ALeffectState *effect, ALCcontext *Context, const ALeffectslot *Slot)



    97 {



    98     ALechoState *state = (ALechoState*)effect;



    99     ALCdevice *Device = Context->Device;



   100     ALuint frequency = Device->Frequency;



   101     ALfloat lrpan, cw, g, gain;



   102     ALuint i;



   103 



   104     state->Tap[0].delay = (ALuint)(Slot->effect.Params.Echo.Delay * frequency) + 1;



   105     state->Tap[1].delay = (ALuint)(Slot->effect.Params.Echo.LRDelay * frequency);



   106     state->Tap[1].delay += state->Tap[0].delay;



   107 



   108     lrpan = Slot->effect.Params.Echo.Spread*0.5f + 0.5f;



   109     state->GainL = aluSqrt(     lrpan);



   110     state->GainR = aluSqrt(1.0f-lrpan);



   111 



   112     state->FeedGain = Slot->effect.Params.Echo.Feedback;



   113 



   114     cw = cos(2.0*M_PI * LOWPASSFREQCUTOFF / frequency);



   115     g = 1.0f - Slot->effect.Params.Echo.Damping;



   116     state->iirFilter.coeff = lpCoeffCalc(g, cw);



   117 



   118     gain = Slot->Gain;



   119     for(i = 0;i < MAXCHANNELS;i++)



   120         state->Gain[i] = 0.0f;



   121     for(i = 0;i < Device->NumChan;i++)



   122     {



   123         enum Channel chan = Device->Speaker2Chan[i];



   124         state->Gain[chan] = gain;



   125     }



   126 }



   127 



   128 static ALvoid EchoProcess(ALeffectState *effect, const ALeffectslot *Slot, ALuint SamplesToDo, const ALfloat *SamplesIn, ALfloat (*SamplesOut)[MAXCHANNELS])



   129 {



   130     ALechoState *state = (ALechoState*)effect;



   131     const ALuint mask = state->BufferLength-1;



   132     const ALuint tap1 = state->Tap[0].delay;



   133     const ALuint tap2 = state->Tap[1].delay;



   134     ALuint offset = state->Offset;



   135     ALfloat samp[2], smp;



   136     ALuint i;



   137     (void)Slot;



   138 



   139     for(i = 0;i < SamplesToDo;i++,offset++)



   140     {



   141         // Sample first tap



   142         smp = state->SampleBuffer[(offset-tap1) & mask];



   143         samp[0] = smp * state->GainL;



   144         samp[1] = smp * state->GainR;



   145         // Sample second tap. Reverse LR panning



   146         smp = state->SampleBuffer[(offset-tap2) & mask];



   147         samp[0] += smp * state->GainR;



   148         samp[1] += smp * state->GainL;



   149 



   150         // Apply damping and feedback gain to the second tap, and mix in the



   151         // new sample



   152         smp = lpFilter2P(&state->iirFilter, 0, smp+SamplesIn[i]);



   153         state->SampleBuffer[offset&mask] = smp * state->FeedGain;



   154 



   155         SamplesOut[i][FRONT_LEFT]  += state->Gain[FRONT_LEFT]  * samp[0];



   156         SamplesOut[i][FRONT_RIGHT] += state->Gain[FRONT_RIGHT] * samp[1];



   157         SamplesOut[i][SIDE_LEFT]   += state->Gain[SIDE_LEFT]   * samp[0];



   158         SamplesOut[i][SIDE_RIGHT]  += state->Gain[SIDE_RIGHT]  * samp[1];



   159         SamplesOut[i][BACK_LEFT]   += state->Gain[BACK_LEFT]   * samp[0];



   160         SamplesOut[i][BACK_RIGHT]  += state->Gain[BACK_RIGHT]  * samp[1];



   161     }



   162     state->Offset = offset;



   163 }



   164 



   165 ALeffectState *EchoCreate(void)



   166 {



   167     ALechoState *state;



   168 



   169     state = malloc(sizeof(*state));



   170     if(!state)



   171         return NULL;



   172 



   173     state->state.Destroy = EchoDestroy;



   174     state->state.DeviceUpdate = EchoDeviceUpdate;



   175     state->state.Update = EchoUpdate;



   176     state->state.Process = EchoProcess;



   177 



   178     state->BufferLength = 0;



   179     state->SampleBuffer = NULL;



   180 



   181     state->Tap[0].delay = 0;



   182     state->Tap[1].delay = 0;



   183     state->Offset = 0;



   184     state->GainL = 0.0f;



   185     state->GainR = 0.0f;



   186 



   187     state->iirFilter.coeff = 0.0f;



   188     state->iirFilter.history[0] = 0.0f;



   189     state->iirFilter.history[1] = 0.0f;



   190 



   191     return &state->state;



   192 }