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robert@372
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1 /*
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robert@372
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2 ____ _____ _ _
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robert@372
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3 | __ )| ____| | / \
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robert@372
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4 | _ \| _| | | / _ \
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robert@372
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5 | |_) | |___| |___ / ___ \
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robert@372
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6 |____/|_____|_____/_/ \_\.io
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robert@372
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7
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robert@372
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8 */
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robert@372
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9
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andrewm@0
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10 /*
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andrewm@0
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11 * render.cpp
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andrewm@0
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12 *
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andrewm@0
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13 * Created on: Oct 24, 2014
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andrewm@0
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14 * Author: parallels
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andrewm@0
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15 */
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andrewm@0
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16
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robert@372
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17 /**
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robert@372
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18 \example 4_oscillator_bank
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robert@372
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19
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robert@372
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20 Oscillator Bank
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robert@372
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21 ----------------------
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robert@372
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22
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robert@372
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23 These files demonstrate an oscillator bank implemented in assembly code
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robert@372
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24 that is used as part of the d-box project.
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robert@372
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25 */
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andrewm@0
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26
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giuliomoro@301
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27 #include <Bela.h>
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andrewm@56
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28 #include <Utilities.h>
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andrewm@0
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29 #include <rtdk.h>
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andrewm@0
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30 #include <cstdlib>
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andrewm@0
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31 #include <cmath>
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andrewm@0
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32 #include <cstring>
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andrewm@0
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33 #include <time.h>
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andrewm@0
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34
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andrewm@0
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35 const float kMinimumFrequency = 20.0f;
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andrewm@0
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36 const float kMaximumFrequency = 8000.0f;
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andrewm@0
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37
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andrewm@0
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38 float *gWavetable; // Buffer holding the precalculated sine lookup table
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andrewm@0
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39 float *gPhases; // Buffer holding the phase of each oscillator
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andrewm@0
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40 float *gFrequencies; // Buffer holding the frequencies of each oscillator
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andrewm@0
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41 float *gAmplitudes; // Buffer holding the amplitudes of each oscillator
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andrewm@0
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42 float *gDFrequencies; // Buffer holding the derivatives of frequency
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andrewm@0
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43 float *gDAmplitudes; // Buffer holding the derivatives of amplitude
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andrewm@0
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44
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andrewm@0
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45 float gAudioSampleRate;
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andrewm@0
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46 int gSampleCount; // Sample counter for indicating when to update frequencies
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andrewm@0
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47 float gNewMinFrequency;
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andrewm@0
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48 float gNewMaxFrequency;
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andrewm@0
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49
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andrewm@0
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50 // Task for handling the update of the frequencies using the matrix
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andrewm@0
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51 AuxiliaryTask gFrequencyUpdateTask;
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andrewm@0
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52
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andrewm@0
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53 // These settings are carried over from main.cpp
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andrewm@0
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54 // Setting global variables is an alternative approach
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andrewm@56
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55 // to passing a structure to userData in setup()
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56
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57 extern int gNumOscillators;
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58 extern int gWavetableLength;
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59
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andrewm@0
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60 void recalculate_frequencies();
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andrewm@0
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61
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62 extern "C" {
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andrewm@0
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63 // Function prototype for ARM assembly implementation of oscillator bank
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andrewm@0
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64 void oscillator_bank_neon(int numAudioFrames, float *audioOut,
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andrewm@0
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65 int activePartialNum, int lookupTableSize,
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andrewm@0
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66 float *phases, float *frequencies, float *amplitudes,
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andrewm@0
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67 float *freqDerivatives, float *ampDerivatives,
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68 float *lookupTable);
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andrewm@0
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69 }
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andrewm@0
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70
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andrewm@56
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71 // setup() is called once before the audio rendering starts.
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72 // Use it to perform any initialisation and allocation which is dependent
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73 // on the period size or sample rate.
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andrewm@0
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74 //
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75 // userData holds an opaque pointer to a data structure that was passed
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andrewm@0
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76 // in from the call to initAudio().
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andrewm@0
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77 //
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78 // Return true on success; returning false halts the program.
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giuliomoro@301
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79 bool setup(BelaContext *context, void *userData)
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andrewm@0
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80 {
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andrewm@0
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81 srandom(time(NULL));
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andrewm@0
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82
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andrewm@52
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83 if(context->audioChannels != 2) {
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andrewm@14
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84 rt_printf("Error: this example needs stereo audio enabled\n");
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andrewm@14
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85 return false;
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andrewm@14
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86 }
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andrewm@14
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87
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andrewm@0
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88 // Initialise the sine wavetable
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89 if(posix_memalign((void **)&gWavetable, 8, (gWavetableLength + 1) * sizeof(float))) {
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andrewm@0
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90 rt_printf("Error allocating wavetable\n");
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91 return false;
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andrewm@0
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92 }
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andrewm@0
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93 for(int n = 0; n < gWavetableLength + 1; n++)
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94 gWavetable[n] = sinf(2.0 * M_PI * (float)n / (float)gWavetableLength);
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andrewm@0
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95
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andrewm@0
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96 // Allocate the other buffers
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andrewm@0
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97 if(posix_memalign((void **)&gPhases, 16, gNumOscillators * sizeof(float))) {
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andrewm@0
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98 rt_printf("Error allocating phase buffer\n");
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andrewm@0
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99 return false;
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andrewm@0
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100 }
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andrewm@0
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101 if(posix_memalign((void **)&gFrequencies, 16, gNumOscillators * sizeof(float))) {
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andrewm@0
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102 rt_printf("Error allocating frequency buffer\n");
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andrewm@0
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103 return false;
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andrewm@0
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104 }
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andrewm@0
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105 if(posix_memalign((void **)&gAmplitudes, 16, gNumOscillators * sizeof(float))) {
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106 rt_printf("Error allocating amplitude buffer\n");
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107 return false;
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andrewm@0
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108 }
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109 if(posix_memalign((void **)&gDFrequencies, 16, gNumOscillators * sizeof(float))) {
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110 rt_printf("Error allocating frequency derivative buffer\n");
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111 return false;
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andrewm@0
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112 }
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andrewm@0
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113 if(posix_memalign((void **)&gDAmplitudes, 16, gNumOscillators * sizeof(float))) {
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114 rt_printf("Error allocating amplitude derivative buffer\n");
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115 return false;
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andrewm@0
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116 }
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117
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118 // Initialise buffer contents
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119
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120 float freq = kMinimumFrequency;
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121 float increment = (kMaximumFrequency - kMinimumFrequency) / (float)gNumOscillators;
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122
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123 for(int n = 0; n < gNumOscillators; n++) {
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124 gPhases[n] = 0.0;
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125
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126 if(context->analogFrames == 0) {
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andrewm@0
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127 // Random frequencies when used without matrix
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128 gFrequencies[n] = kMinimumFrequency + (kMaximumFrequency - kMinimumFrequency) * ((float)random() / (float)RAND_MAX);
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129 }
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130 else {
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andrewm@0
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131 // Constant spread of frequencies when used with matrix
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132 gFrequencies[n] = freq;
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133 freq += increment;
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134 }
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135
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136 // For efficiency, frequency is expressed in change in wavetable position per sample, not Hz or radians
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137 gFrequencies[n] *= (float)gWavetableLength / context->audioSampleRate;
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138 gAmplitudes[n] = ((float)random() / (float)RAND_MAX) / (float)gNumOscillators;
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139 gDFrequencies[n] = gDAmplitudes[n] = 0.0;
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andrewm@0
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140 }
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141
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142 increment = 0;
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143 freq = 440.0;
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144
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145 for(int n = 0; n < gNumOscillators; n++) {
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146 // Update the frequencies to a regular spread, plus a small amount of randomness
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andrewm@45
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147 // to avoid weird phase effects
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148 float randScale = 0.99 + .02 * (float)random() / (float)RAND_MAX;
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149 float newFreq = freq * randScale;
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150
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151 // For efficiency, frequency is expressed in change in wavetable position per sample, not Hz or radians
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andrewm@52
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152 gFrequencies[n] = newFreq * (float)gWavetableLength / context->audioSampleRate;
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153
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154 freq += increment;
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andrewm@45
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155 }
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andrewm@45
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156
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andrewm@0
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157 // Initialise auxiliary tasks
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andrewm@303
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158 if((gFrequencyUpdateTask = Bela_createAuxiliaryTask(&recalculate_frequencies, 85, "bela-update-frequencies")) == 0)
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159 return false;
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andrewm@0
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160
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andrewm@52
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161 //for(int n = 0; n < gNumOscillators; n++)
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162 // rt_printf("%f\n", gFrequencies[n]);
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163
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164 gAudioSampleRate = context->audioSampleRate;
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165 gSampleCount = 0;
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166
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167 return true;
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andrewm@0
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168 }
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andrewm@0
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169
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170 // render() is called regularly at the highest priority by the audio engine.
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171 // Input and output are given from the audio hardware and the other
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172 // ADCs and DACs (if available). If only audio is available, numMatrixFrames
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173 // will be 0.
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174
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giuliomoro@301
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175 void render(BelaContext *context, void *userData)
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andrewm@0
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176 {
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andrewm@0
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177 // Initialise buffer to 0
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178 memset(context->audioOut, 0, 2 * context->audioFrames * sizeof(float));
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179
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180 // Render audio frames
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181 oscillator_bank_neon(context->audioFrames, context->audioOut,
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182 gNumOscillators, gWavetableLength,
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andrewm@0
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183 gPhases, gFrequencies, gAmplitudes,
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andrewm@0
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184 gDFrequencies, gDAmplitudes,
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andrewm@0
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185 gWavetable);
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andrewm@0
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186
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187 if(context->analogFrames != 0 && (gSampleCount += context->audioFrames) >= 128) {
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188 gSampleCount = 0;
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189 gNewMinFrequency = map(context->analogIn[0], 0, 1.0, 1000.0f, 8000.0f);
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190 gNewMaxFrequency = map(context->analogIn[1], 0, 1.0, 1000.0f, 8000.0f);
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andrewm@0
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191
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192 // Make sure max >= min
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193 if(gNewMaxFrequency < gNewMinFrequency) {
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andrewm@0
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194 float temp = gNewMaxFrequency;
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andrewm@0
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195 gNewMaxFrequency = gNewMinFrequency;
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andrewm@0
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196 gNewMinFrequency = temp;
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andrewm@0
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197 }
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andrewm@0
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198
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andrewm@0
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199 // Request that the lower-priority task run at next opportunity
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giuliomoro@301
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200 //Bela_scheduleAuxiliaryTask(gFrequencyUpdateTask);
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201 }
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andrewm@0
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202 }
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andrewm@0
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203
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andrewm@0
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204 // This is a lower-priority call to update the frequencies which will happen
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205 // periodically when the matrix is enabled. By placing it at a lower priority,
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206 // it has minimal effect on the audio performance but it will take longer to
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207 // complete if the system is under heavy audio load.
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208
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andrewm@0
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209 void recalculate_frequencies()
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andrewm@0
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210 {
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andrewm@0
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211 float freq = gNewMinFrequency;
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andrewm@0
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212 float increment = (gNewMaxFrequency - gNewMinFrequency) / (float)gNumOscillators;
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213
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214 for(int n = 0; n < gNumOscillators; n++) {
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andrewm@0
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215 // Update the frequencies to a regular spread, plus a small amount of randomness
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andrewm@0
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216 // to avoid weird phase effects
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andrewm@0
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217 float randScale = 0.99 + .02 * (float)random() / (float)RAND_MAX;
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andrewm@0
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218 float newFreq = freq * randScale;
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andrewm@0
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219
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andrewm@0
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220 // For efficiency, frequency is expressed in change in wavetable position per sample, not Hz or radians
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andrewm@0
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221 gFrequencies[n] = newFreq * (float)gWavetableLength / gAudioSampleRate;
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andrewm@0
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222
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223 freq += increment;
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andrewm@0
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224 }
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andrewm@0
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225 }
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andrewm@0
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226
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andrewm@0
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227
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andrewm@56
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228 // cleanup() is called once at the end, after the audio has stopped.
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andrewm@56
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229 // Release any resources that were allocated in setup().
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andrewm@0
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230
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giuliomoro@301
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231 void cleanup(BelaContext *context, void *userData)
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andrewm@0
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232 {
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andrewm@0
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233 free(gWavetable);
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andrewm@0
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234 free(gPhases);
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andrewm@0
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235 free(gFrequencies);
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andrewm@0
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236 free(gAmplitudes);
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andrewm@0
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237 free(gDFrequencies);
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andrewm@0
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238 free(gDAmplitudes);
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andrewm@0
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239 }
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