annotate examples/AmplitudeFollower.cpp @ 462:6ac615fd02a3

Merge from branch vampipe
author Chris Cannam
date Mon, 10 Oct 2016 15:51:33 +0100
parents 75cc9ced3b01
children 90571dcc371a
rev   line source
cannam@41 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
cannam@41 2
cannam@41 3 /*
cannam@41 4 Vamp
cannam@41 5
cannam@41 6 An API for audio analysis and feature extraction plugins.
cannam@41 7
cannam@41 8 Centre for Digital Music, Queen Mary, University of London.
cannam@41 9 This file copyright 2006 Dan Stowell.
cannam@41 10
cannam@41 11 Permission is hereby granted, free of charge, to any person
cannam@41 12 obtaining a copy of this software and associated documentation
cannam@41 13 files (the "Software"), to deal in the Software without
cannam@41 14 restriction, including without limitation the rights to use, copy,
cannam@41 15 modify, merge, publish, distribute, sublicense, and/or sell copies
cannam@41 16 of the Software, and to permit persons to whom the Software is
cannam@41 17 furnished to do so, subject to the following conditions:
cannam@41 18
cannam@41 19 The above copyright notice and this permission notice shall be
cannam@41 20 included in all copies or substantial portions of the Software.
cannam@41 21
cannam@41 22 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
cannam@41 23 EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
cannam@41 24 MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
cannam@41 25 NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR
cannam@41 26 ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF
cannam@41 27 CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
cannam@41 28 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
cannam@41 29
cannam@41 30 Except as contained in this notice, the names of the Centre for
cannam@41 31 Digital Music; Queen Mary, University of London; and Chris Cannam
cannam@41 32 shall not be used in advertising or otherwise to promote the sale,
cannam@41 33 use or other dealings in this Software without prior written
cannam@41 34 authorization.
cannam@41 35 */
cannam@41 36
cannam@41 37 #include "AmplitudeFollower.h"
cannam@41 38
cannam@41 39 #include <cmath>
cannam@41 40
cannam@41 41 #include <string>
cannam@41 42 #include <vector>
cannam@41 43 #include <iostream>
Chris@394 44 #include <algorithm>
cannam@41 45
cannam@41 46 using std::string;
cannam@41 47 using std::vector;
cannam@41 48 using std::cerr;
cannam@41 49 using std::endl;
cannam@41 50
cannam@54 51 /**
cannam@41 52 * An implementation of SuperCollider's amplitude-follower algorithm
cannam@41 53 * as a simple Vamp plugin.
cannam@41 54 */
cannam@41 55
cannam@41 56 AmplitudeFollower::AmplitudeFollower(float inputSampleRate) :
cannam@41 57 Plugin(inputSampleRate),
cannam@41 58 m_stepSize(0),
cannam@41 59 m_previn(0.0f),
cannam@41 60 m_clampcoef(0.01f),
cannam@41 61 m_relaxcoef(0.01f)
cannam@41 62 {
cannam@41 63 }
cannam@41 64
cannam@41 65 AmplitudeFollower::~AmplitudeFollower()
cannam@41 66 {
cannam@41 67 }
cannam@41 68
cannam@41 69 string
cannam@49 70 AmplitudeFollower::getIdentifier() const
cannam@41 71 {
cannam@41 72 return "amplitudefollower";
cannam@41 73 }
cannam@41 74
cannam@41 75 string
cannam@49 76 AmplitudeFollower::getName() const
cannam@49 77 {
cannam@49 78 return "Amplitude Follower";
cannam@49 79 }
cannam@49 80
cannam@49 81 string
cannam@41 82 AmplitudeFollower::getDescription() const
cannam@41 83 {
cannam@49 84 return "Track the amplitude of the audio signal";
cannam@41 85 }
cannam@41 86
cannam@41 87 string
cannam@41 88 AmplitudeFollower::getMaker() const
cannam@41 89 {
cannam@43 90 return "Vamp SDK Example Plugins";
cannam@41 91 }
cannam@41 92
cannam@41 93 int
cannam@41 94 AmplitudeFollower::getPluginVersion() const
cannam@41 95 {
cannam@41 96 return 1;
cannam@41 97 }
cannam@41 98
cannam@41 99 string
cannam@41 100 AmplitudeFollower::getCopyright() const
cannam@41 101 {
cannam@41 102 return "Code copyright 2006 Dan Stowell; method from SuperCollider. Freely redistributable (BSD license)";
cannam@41 103 }
cannam@41 104
cannam@41 105 bool
cannam@41 106 AmplitudeFollower::initialise(size_t channels, size_t stepSize, size_t blockSize)
cannam@41 107 {
cannam@41 108 if (channels < getMinChannelCount() ||
cannam@41 109 channels > getMaxChannelCount()) return false;
cannam@41 110
cannam@41 111 m_stepSize = std::min(stepSize, blockSize);
cannam@41 112
cannam@41 113 // Translate the coefficients
cannam@41 114 // from their "convenient" 60dB convergence-time values
cannam@41 115 // to real coefficients
cannam@41 116 m_clampcoef = m_clampcoef==0.0 ? 0.0 : exp(log(0.1)/(m_clampcoef * m_inputSampleRate));
cannam@41 117 m_relaxcoef = m_relaxcoef==0.0 ? 0.0 : exp(log(0.1)/(m_relaxcoef * m_inputSampleRate));
cannam@41 118
cannam@41 119 return true;
cannam@41 120 }
cannam@41 121
cannam@41 122 void
cannam@41 123 AmplitudeFollower::reset()
cannam@41 124 {
cannam@41 125 m_previn = 0.0f;
cannam@41 126 }
cannam@41 127
cannam@41 128 AmplitudeFollower::OutputList
cannam@41 129 AmplitudeFollower::getOutputDescriptors() const
cannam@41 130 {
cannam@41 131 OutputList list;
cannam@41 132
cannam@41 133 OutputDescriptor sca;
cannam@49 134 sca.identifier = "amplitude";
cannam@49 135 sca.name = "Amplitude";
cannam@281 136 sca.description = "The peak tracked amplitude for the current processing block";
cannam@41 137 sca.unit = "V";
cannam@41 138 sca.hasFixedBinCount = true;
cannam@41 139 sca.binCount = 1;
cannam@41 140 sca.hasKnownExtents = false;
cannam@41 141 sca.isQuantized = false;
cannam@41 142 sca.sampleType = OutputDescriptor::OneSamplePerStep;
cannam@41 143 list.push_back(sca);
cannam@41 144
cannam@41 145 return list;
cannam@41 146 }
cannam@41 147
cannam@41 148 AmplitudeFollower::ParameterList
cannam@41 149 AmplitudeFollower::getParameterDescriptors() const
cannam@41 150 {
cannam@41 151 ParameterList list;
cannam@41 152
cannam@41 153 ParameterDescriptor att;
cannam@49 154 att.identifier = "attack";
cannam@49 155 att.name = "Attack time";
cannam@281 156 att.description = "The 60dB convergence time for an increase in amplitude";
cannam@41 157 att.unit = "s";
cannam@41 158 att.minValue = 0.0f;
cannam@41 159 att.maxValue = 1.f;
cannam@41 160 att.defaultValue = 0.01f;
cannam@41 161 att.isQuantized = false;
cannam@41 162
cannam@41 163 list.push_back(att);
cannam@41 164
cannam@41 165 ParameterDescriptor dec;
cannam@49 166 dec.identifier = "release";
cannam@49 167 dec.name = "Release time";
cannam@281 168 dec.description = "The 60dB convergence time for a decrease in amplitude";
cannam@41 169 dec.unit = "s";
cannam@41 170 dec.minValue = 0.0f;
cannam@41 171 dec.maxValue = 1.f;
cannam@41 172 dec.defaultValue = 0.01f;
cannam@41 173 dec.isQuantized = false;
cannam@41 174
cannam@41 175 list.push_back(dec);
cannam@41 176
cannam@41 177 return list;
cannam@41 178 }
cannam@41 179
cannam@49 180 void AmplitudeFollower::setParameter(std::string paramid, float newval)
cannam@41 181 {
cannam@49 182 if (paramid == "attack") {
cannam@41 183 m_clampcoef = newval;
cannam@49 184 } else if (paramid == "release") {
cannam@41 185 m_relaxcoef = newval;
cannam@41 186 }
cannam@41 187 }
cannam@41 188
cannam@49 189 float AmplitudeFollower::getParameter(std::string paramid) const
cannam@41 190 {
cannam@49 191 if (paramid == "attack") {
cannam@41 192 return m_clampcoef;
cannam@49 193 } else if (paramid == "release") {
cannam@41 194 return m_relaxcoef;
cannam@41 195 }
cannam@41 196
cannam@41 197 return 0.0f;
cannam@41 198 }
cannam@41 199
cannam@41 200 AmplitudeFollower::FeatureSet
cannam@47 201 AmplitudeFollower::process(const float *const *inputBuffers,
Chris@437 202 Vamp::RealTime /* timestamp */)
cannam@41 203 {
cannam@41 204 if (m_stepSize == 0) {
cannam@41 205 cerr << "ERROR: AmplitudeFollower::process: "
cannam@41 206 << "AmplitudeFollower has not been initialised"
cannam@41 207 << endl;
cannam@41 208 return FeatureSet();
cannam@41 209 }
cannam@41 210
cannam@41 211 float previn = m_previn;
cannam@41 212
cannam@41 213 FeatureSet returnFeatures;
cannam@41 214
cannam@41 215 float val;
cannam@41 216 float peak = 0.0f;
cannam@41 217
cannam@41 218 for (size_t i = 0; i < m_stepSize; ++i) {
cannam@41 219
cannam@41 220 val = fabs(inputBuffers[0][i]);
cannam@41 221
cannam@41 222 if (val < previn) {
cannam@41 223 val = val + (previn - val) * m_relaxcoef;
cannam@41 224 } else {
cannam@41 225 val = val + (previn - val) * m_clampcoef;
cannam@41 226 }
cannam@41 227
cannam@41 228 if (val > peak) peak = val;
cannam@41 229 previn = val;
cannam@41 230 }
cannam@41 231
cannam@41 232 m_previn = previn;
cannam@41 233
cannam@41 234 // Now store the "feature" (peak amp) for this sample
cannam@41 235 Feature feature;
cannam@41 236 feature.hasTimestamp = false;
cannam@41 237 feature.values.push_back(peak);
cannam@41 238 returnFeatures[0].push_back(feature);
cannam@41 239
cannam@41 240 return returnFeatures;
cannam@41 241 }
cannam@41 242
cannam@41 243 AmplitudeFollower::FeatureSet
cannam@41 244 AmplitudeFollower::getRemainingFeatures()
cannam@41 245 {
cannam@41 246 return FeatureSet();
cannam@41 247 }
cannam@41 248