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1 /*
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2 ____ _____ _ _
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3 | __ )| ____| | / \
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4 | _ \| _| | | / _ \
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5 | |_) | |___| |___ / ___ \
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6 |____/|_____|_____/_/ \_\.io
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7
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8 */
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9
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10 /*
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11 * render.cpp
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12 *
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13 * Created on: Oct 24, 2014
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14 * Author: parallels
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15 */
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16
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17 /**
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18 \example 1_basic_audio_passthrough
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19
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20 Audio passthrough: input to output
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21 -----------------------------------------
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22
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23 This sketch demonstrates the simplest possible case of using audio: it passes
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24 audio input straight to audio output.
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25
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26 Note the nested `for` loop structure. You will see this in all Bela projects. The
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27 first `for` loop cycles through the audio frames, the second through each of the
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28 audio channels (in this case left 0 and right 1).
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29
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30
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31 We write samples to the audio output buffer like this:
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32 `context->audioOut[n * context->audioChannels + ch]` where `n` is the current audio
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33 frame and `ch` is the current channel, both provided by the nested for loop structure.
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34
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35 We can access samples in the audio input buffer in a similar way, like this:
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36 `context->audioIn[n * context->audioChannels + ch]`.
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37
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38 So a simple audio pass through is achieved by setting output buffer equal to
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39 input buffer:
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40 `context->audioOut[n * context->audioChannels + ch] = context->audioIn[n * context->audioChannels + ch]`.
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41
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42
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43 */
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44
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45
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46
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47
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48
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49 #include <BeagleRT.h>
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50 #include <Utilities.h>
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51 #include <rtdk.h>
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52
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53 // setup() is called once before the audio rendering starts.
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54 // Use it to perform any initialisation and allocation which is dependent
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55 // on the period size or sample rate.
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56 //
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57 // userData holds an opaque pointer to a data structure that was passed
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58 // in from the call to initAudio().
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59 //
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60 // Return true on success; returning false halts the program.
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61
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62 bool setup(BeagleRTContext *context, void *userData)
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63 {
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64 // Nothing to do here...
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65 return true;
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66 }
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67
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68 // render() is called regularly at the highest priority by the audio engine.
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69 // Input and output are given from the audio hardware and the other
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70 // ADCs and DACs (if available). If only audio is available, numMatrixFrames
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71 // will be 0.
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72
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73 void render(BeagleRTContext *context, void *userData)
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74 {
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75 // Simplest possible case: pass inputs through to outputs
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76 for(unsigned int n = 0; n < context->audioFrames; n++) {
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77 for(unsigned int ch = 0; ch < context->audioChannels; ch++){
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78 // Two equivalent ways to write this code
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79
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80 // The long way, using the buffers directly:
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81 // context->audioOut[n * context->audioChannels + ch] =
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82 // context->audioIn[n * context->audioChannels + ch];
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83
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84 // Or using the macros:
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85 audioWriteFrame(context, n, ch, audioReadFrame(context, n, ch));
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86 }
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87 }
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88
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89 // Same with analog channelss
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90 for(unsigned int n = 0; n < context->analogFrames; n++) {
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91 for(unsigned int ch = 0; ch < context->analogChannels; ch++) {
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92 // Two equivalent ways to write this code
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93
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94 // The long way, using the buffers directly:
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95 // context->analogOut[n * context->analogChannels + ch] = context->analogIn[n * context->analogChannels + ch];
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96
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97 // Or using the macros:
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98 analogWriteFrame(context, n, ch, analogReadFrame(context, n, ch));
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99 }
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100 }
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101 }
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102
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103 // cleanup() is called once at the end, after the audio has stopped.
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104 // Release any resources that were allocated in setup().
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105
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106 void cleanup(BeagleRTContext *context, void *userData)
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107 {
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108
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109 }
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