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annotate projects/basic_analog_input/render.cpp @ 269:ac8eb07afcf5

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Oxygen text added to each render.cpp file for the default projects. Text includes project explanation from Wiki, edited in places. Empty project added as a default project. Doxyfile updated. Each of the project locations added to INPUT configuration option. Consider just watching the whole project file so all new projects are automatically pulled through.
author Robert Jack <robert.h.jack@gmail.com>
date Tue, 17 May 2016 15:40:16 +0100
parents 72726dd4f66c
children 5433c83ce04e
rev   line source
robert@269 1 /*
robert@269 2 ____ _____ _ _
robert@269 3 | __ )| ____| | / \
robert@269 4 | _ \| _| | | / _ \
robert@269 5 | |_) | |___| |___ / ___ \
robert@269 6 |____/|_____|_____/_/ \_\.io
robert@269 7
robert@269 8 */
robert@269 9
andrewm@57 10 /*
andrewm@57 11 * render.cpp
andrewm@57 12 *
andrewm@57 13 * Created on: Oct 24, 2014
andrewm@57 14 * Author: parallels
andrewm@57 15 */
andrewm@57 16
robert@269 17 /**
robert@269 18 \example 3_analog_input
robert@269 19
robert@269 20 Connecting potentiometers
robert@269 21 -------------------------
robert@269 22
robert@269 23 This sketch produces a sine tone, the frequency and amplitude of which are
robert@269 24 affected by data received on the analog pins. Before looping through each audio
robert@269 25 frame, we declare a value for the frequency and amplitude of our sine tone
robert@269 26 (line 55); we adjust these values by taking in data from analog sensors
robert@269 27 (for example, a potentiometer).
robert@269 28
robert@269 29 The important thing to notice is that audio is sampled twice as often as analog
robert@269 30 data. The audio sampling rate is 44.1kHz (44100 frames per second) and the
robert@269 31 analog sampling rate is 22.05kHz (22050 frames per second). On line 62 you might
robert@269 32 notice that we are processing the analog data and updating frequency and
robert@269 33 amplitude only on every second audio sample, since the analog sampling rate is
robert@269 34 half that of the audio.
robert@269 35
robert@269 36 Note that the pin numbers are stored in the variables `gAnalogInputFrequency` and
robert@269 37 `gAnalogInputAmplitude`. These are declared in the main.cpp file; if you look in
robert@269 38 that file you will see that they have the values of 0 and 1. Bear in mind that
robert@269 39 these are analog input pins which is a specific header!
robert@269 40 */
andrewm@57 41
andrewm@57 42 #include <BeagleRT.h>
andrewm@57 43 #include <Utilities.h>
andrewm@57 44 #include <rtdk.h>
andrewm@57 45 #include <cmath>
andrewm@57 46
andrewm@57 47 float gPhase;
andrewm@57 48 float gInverseSampleRate;
andrewm@57 49 int gAudioFramesPerAnalogFrame;
andrewm@57 50
andrewm@57 51 // These settings are carried over from main.cpp
andrewm@57 52 // Setting global variables is an alternative approach
andrewm@57 53 // to passing a structure to userData in setup()
andrewm@57 54
andrewm@57 55 extern int gSensorInputFrequency;
andrewm@57 56 extern int gSensorInputAmplitude;
andrewm@57 57
andrewm@57 58 // setup() is called once before the audio rendering starts.
andrewm@57 59 // Use it to perform any initialisation and allocation which is dependent
andrewm@57 60 // on the period size or sample rate.
andrewm@57 61 //
andrewm@57 62 // userData holds an opaque pointer to a data structure that was passed
andrewm@57 63 // in from the call to initAudio().
andrewm@57 64 //
andrewm@57 65 // Return true on success; returning false halts the program.
andrewm@57 66
robert@269 67
andrewm@57 68 bool setup(BeagleRTContext *context, void *userData)
andrewm@57 69 {
andrewm@57 70 if(context->analogFrames == 0 || context->analogFrames > context->audioFrames) {
andrewm@57 71 rt_printf("Error: this example needs analog enabled, with 4 or 8 channels\n");
andrewm@57 72 return false;
andrewm@57 73 }
andrewm@57 74
andrewm@57 75 gAudioFramesPerAnalogFrame = context->audioFrames / context->analogFrames;
andrewm@57 76 gInverseSampleRate = 1.0 / context->audioSampleRate;
andrewm@57 77 gPhase = 0.0;
andrewm@57 78
andrewm@57 79 return true;
andrewm@57 80 }
andrewm@57 81
andrewm@57 82 // render() is called regularly at the highest priority by the audio engine.
andrewm@57 83 // Input and output are given from the audio hardware and the other
andrewm@57 84 // ADCs and DACs (if available). If only audio is available, numMatrixFrames
andrewm@57 85 // will be 0.
andrewm@57 86
andrewm@57 87 void render(BeagleRTContext *context, void *userData)
andrewm@57 88 {
andrewm@57 89 float frequency = 440.0;
andrewm@57 90 float amplitude = 0.8;
andrewm@57 91
andrewm@57 92 // There are twice as many audio frames as matrix frames since audio sample rate
andrewm@57 93 // is twice as high
andrewm@57 94
andrewm@57 95 for(unsigned int n = 0; n < context->audioFrames; n++) {
andrewm@57 96 if(!(n % gAudioFramesPerAnalogFrame)) {
andrewm@57 97 // Even audio samples: update frequency and amplitude from the matrix
andrewm@57 98 frequency = map(analogReadFrame(context, n/gAudioFramesPerAnalogFrame, gSensorInputFrequency), 0, 1, 100, 1000);
andrewm@57 99 amplitude = analogReadFrame(context, n/gAudioFramesPerAnalogFrame, gSensorInputAmplitude);
andrewm@57 100 }
andrewm@57 101
andrewm@57 102 float out = amplitude * sinf(gPhase);
andrewm@57 103
andrewm@57 104 for(unsigned int channel = 0; channel < context->audioChannels; channel++)
andrewm@57 105 context->audioOut[n * context->audioChannels + channel] = out;
andrewm@57 106
andrewm@57 107 gPhase += 2.0 * M_PI * frequency * gInverseSampleRate;
andrewm@57 108 if(gPhase > 2.0 * M_PI)
andrewm@57 109 gPhase -= 2.0 * M_PI;
andrewm@57 110 }
andrewm@57 111 }
andrewm@57 112
andrewm@57 113 // cleanup() is called once at the end, after the audio has stopped.
andrewm@57 114 // Release any resources that were allocated in setup().
andrewm@57 115
andrewm@57 116 void cleanup(BeagleRTContext *context, void *userData)
andrewm@57 117 {
andrewm@57 118
andrewm@57 119 }