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1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
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2
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3 /*
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4 Vamp
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5
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6 An API for audio analysis and feature extraction plugins.
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7
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8 Centre for Digital Music, Queen Mary, University of London.
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9 Copyright 2006-2007 Chris Cannam and QMUL.
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10
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11 Permission is hereby granted, free of charge, to any person
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12 obtaining a copy of this software and associated documentation
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13 files (the "Software"), to deal in the Software without
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14 restriction, including without limitation the rights to use, copy,
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15 modify, merge, publish, distribute, sublicense, and/or sell copies
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16 of the Software, and to permit persons to whom the Software is
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17 furnished to do so, subject to the following conditions:
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18
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19 The above copyright notice and this permission notice shall be
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20 included in all copies or substantial portions of the Software.
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21
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22 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
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23 EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
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24 MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
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25 NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR
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26 ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF
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27 CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
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28 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
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29
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30 Except as contained in this notice, the names of the Centre for
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31 Digital Music; Queen Mary, University of London; and Chris Cannam
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32 shall not be used in advertising or otherwise to promote the sale,
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33 use or other dealings in this Software without prior written
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34 authorization.
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35 */
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36
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37 #include "PluginInputDomainAdapter.h"
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38
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39 #include <cmath>
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40
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41 namespace Vamp {
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42
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43 namespace HostExt {
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44
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45 class PluginInputDomainAdapter::Impl
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46 {
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47 public:
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48 Impl(Plugin *plugin, float inputSampleRate);
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49 ~Impl();
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50
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51 bool initialise(size_t channels, size_t stepSize, size_t blockSize);
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52
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53 size_t getPreferredStepSize() const;
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54 size_t getPreferredBlockSize() const;
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55
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56 FeatureSet process(const float *const *inputBuffers, RealTime timestamp);
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57
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58 protected:
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59 Plugin *m_plugin;
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60 float m_inputSampleRate;
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61 size_t m_channels;
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62 size_t m_blockSize;
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63 float **m_freqbuf;
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64 double *m_ri;
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65 double *m_ro;
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66 double *m_io;
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67
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68 void fft(unsigned int n, bool inverse,
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69 double *ri, double *ii, double *ro, double *io);
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70
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71 size_t makeBlockSizeAcceptable(size_t) const;
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72 };
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73
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74 PluginInputDomainAdapter::PluginInputDomainAdapter(Plugin *plugin) :
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75 PluginWrapper(plugin)
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76 {
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77 m_impl = new Impl(plugin, m_inputSampleRate);
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78 }
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79
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80 PluginInputDomainAdapter::~PluginInputDomainAdapter()
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81 {
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82 delete m_impl;
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83 }
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84
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85 bool
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86 PluginInputDomainAdapter::initialise(size_t channels, size_t stepSize, size_t blockSize)
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87 {
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88 return m_impl->initialise(channels, stepSize, blockSize);
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89 }
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90
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91 Plugin::InputDomain
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92 PluginInputDomainAdapter::getInputDomain() const
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93 {
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94 return TimeDomain;
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95 }
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96
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97 size_t
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98 PluginInputDomainAdapter::getPreferredStepSize() const
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99 {
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100 return m_impl->getPreferredStepSize();
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101 }
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102
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103 size_t
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104 PluginInputDomainAdapter::getPreferredBlockSize() const
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105 {
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106 return m_impl->getPreferredBlockSize();
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107 }
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108
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109 Plugin::FeatureSet
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110 PluginInputDomainAdapter::process(const float *const *inputBuffers, RealTime timestamp)
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111 {
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112 return m_impl->process(inputBuffers, timestamp);
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113 }
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114
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115 PluginInputDomainAdapter::Impl::Impl(Plugin *plugin, float inputSampleRate) :
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116 m_plugin(plugin),
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117 m_inputSampleRate(inputSampleRate),
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118 m_channels(0),
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119 m_blockSize(0),
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120 m_freqbuf(0)
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121 {
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122 }
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123
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124 PluginInputDomainAdapter::Impl::~Impl()
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125 {
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126 // the adapter will delete the plugin
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127
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128 if (m_channels > 0) {
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129 for (size_t c = 0; c < m_channels; ++c) {
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130 delete[] m_freqbuf[c];
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131 }
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132 delete[] m_freqbuf;
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133 delete[] m_ri;
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134 delete[] m_ro;
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135 delete[] m_io;
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136 }
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137 }
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138
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139 bool
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140 PluginInputDomainAdapter::Impl::initialise(size_t channels, size_t stepSize, size_t blockSize)
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141 {
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142 if (m_plugin->getInputDomain() == TimeDomain) {
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143
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144 m_blockSize = blockSize;
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145 m_channels = channels;
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146
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147 return m_plugin->initialise(channels, stepSize, blockSize);
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148 }
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149
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150 if (blockSize < 2) {
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151 std::cerr << "ERROR: Vamp::HostExt::PluginInputDomainAdapter::Impl::initialise: blocksize < 2 not supported" << std::endl;
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152 return false;
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153 }
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154
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155 if (blockSize & (blockSize-1)) {
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156 std::cerr << "ERROR: Vamp::HostExt::PluginInputDomainAdapter::Impl::initialise: non-power-of-two\nblocksize " << blockSize << " not supported" << std::endl;
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157 return false;
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158 }
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159
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160 if (m_channels > 0) {
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161 for (size_t c = 0; c < m_channels; ++c) {
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162 delete[] m_freqbuf[c];
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163 }
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164 delete[] m_freqbuf;
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165 delete[] m_ri;
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166 delete[] m_ro;
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167 delete[] m_io;
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168 }
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169
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170 m_blockSize = blockSize;
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171 m_channels = channels;
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172
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173 m_freqbuf = new float *[m_channels];
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174 for (size_t c = 0; c < m_channels; ++c) {
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175 m_freqbuf[c] = new float[m_blockSize + 2];
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176 }
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177 m_ri = new double[m_blockSize];
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178 m_ro = new double[m_blockSize];
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179 m_io = new double[m_blockSize];
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180
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181 return m_plugin->initialise(channels, stepSize, blockSize);
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182 }
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183
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184 size_t
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185 PluginInputDomainAdapter::Impl::getPreferredStepSize() const
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186 {
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187 size_t step = m_plugin->getPreferredStepSize();
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188
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189 if (step == 0 && (m_plugin->getInputDomain() == FrequencyDomain)) {
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190 step = getPreferredBlockSize() / 2;
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191 }
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192
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193 return step;
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194 }
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195
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196 size_t
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197 PluginInputDomainAdapter::Impl::getPreferredBlockSize() const
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198 {
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199 size_t block = m_plugin->getPreferredBlockSize();
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200
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201 if (m_plugin->getInputDomain() == FrequencyDomain) {
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202 if (block == 0) {
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203 block = 1024;
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204 } else {
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205 block = makeBlockSizeAcceptable(block);
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206 }
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207 }
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208
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209 return block;
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210 }
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211
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212 size_t
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213 PluginInputDomainAdapter::Impl::makeBlockSizeAcceptable(size_t blockSize) const
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214 {
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215 if (blockSize < 2) {
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216
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217 std::cerr << "WARNING: Vamp::HostExt::PluginInputDomainAdapter::Impl::initialise: blocksize < 2 not" << std::endl
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218 << "supported, increasing from " << blockSize << " to 2" << std::endl;
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219 blockSize = 2;
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220
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221 } else if (blockSize & (blockSize-1)) {
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222
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223 // not a power of two, can't handle that with our current fft
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224 // implementation
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225
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226 size_t nearest = blockSize;
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227 size_t power = 0;
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228 while (nearest > 1) {
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229 nearest >>= 1;
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230 ++power;
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231 }
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232 nearest = 1;
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233 while (power) {
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234 nearest <<= 1;
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235 --power;
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236 }
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237
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238 if (blockSize - nearest > (nearest*2) - blockSize) {
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239 nearest = nearest*2;
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240 }
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241
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242 std::cerr << "WARNING: Vamp::HostExt::PluginInputDomainAdapter::Impl::initialise: non-power-of-two\nblocksize " << blockSize << " not supported, using blocksize " << nearest << " instead" << std::endl;
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243 blockSize = nearest;
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244 }
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245
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246 return blockSize;
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247 }
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248
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249 // for some visual studii apparently
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250 #ifndef M_PI
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251 #define M_PI 3.14159265358979232846
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252 #endif
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253
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254 Plugin::FeatureSet
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255 PluginInputDomainAdapter::Impl::process(const float *const *inputBuffers,
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256 RealTime timestamp)
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257 {
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258 if (m_plugin->getInputDomain() == TimeDomain) {
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259 return m_plugin->process(inputBuffers, timestamp);
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260 }
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261
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262 // The timestamp supplied should be (according to the Vamp::Plugin
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263 // spec) the time of the start of the time-domain input block.
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264 // However, we want to pass to the plugin an FFT output calculated
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265 // from the block of samples _centred_ on that timestamp.
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266 //
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267 // We have two options:
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268 //
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269 // 1. Buffer the input, calculating the fft of the values at the
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270 // passed-in block minus blockSize/2 rather than starting at the
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271 // passed-in block. So each time we call process on the plugin,
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272 // we are passing in the same timestamp as was passed to our own
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273 // process plugin, but not (the frequency domain representation
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274 // of) the same set of samples. Advantages: avoids confusion in
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275 // the host by ensuring the returned values have timestamps
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276 // comparable with that passed in to this function (in fact this
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277 // is pretty much essential for one-value-per-block outputs);
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278 // consistent with hosts such as SV that deal with the
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279 // frequency-domain transform themselves. Disadvantages: means
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280 // making the not necessarily correct assumption that the samples
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281 // preceding the first official block are all zero (or some other
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282 // known value).
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283 //
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284 // 2. Increase the passed-in timestamps by half the blocksize. So
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285 // when we call process, we are passing in the frequency domain
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286 // representation of the same set of samples as passed to us, but
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287 // with a different timestamp. Advantages: simplicity; avoids
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288 // iffy assumption mentioned above. Disadvantages: inconsistency
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289 // with SV in cases where stepSize != blockSize/2; potential
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290 // confusion arising from returned timestamps being calculated
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291 // from the adjusted input timestamps rather than the original
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292 // ones (and inaccuracy where the returned timestamp is implied,
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293 // as in one-value-per-block).
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294 //
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295 // Neither way is ideal, but I don't think either is strictly
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296 // incorrect either. I think this is just a case where the same
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297 // plugin can legitimately produce differing results from the same
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298 // input data, depending on how that data is packaged.
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299 //
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300 // We'll go for option 2, adjusting the timestamps. Note in
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301 // particular that this means some results can differ from those
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302 // produced by SV.
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303
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304 // std::cerr << "PluginInputDomainAdapter: sampleRate " << m_inputSampleRate << ", blocksize " << m_blockSize << ", adjusting time from " << timestamp;
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305
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306 timestamp = timestamp + RealTime::frame2RealTime
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307 (m_blockSize/2, int(m_inputSampleRate + 0.5));
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308
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309 // std::cerr << " to " << timestamp << std::endl;
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310
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cannam@64
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311 for (size_t c = 0; c < m_channels; ++c) {
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312
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313 for (size_t i = 0; i < m_blockSize; ++i) {
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cannam@64
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314 // Hanning window
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315 m_ri[i] = double(inputBuffers[c][i])
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316 * (0.50 - 0.50 * cos((2 * M_PI * i)
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317 / m_blockSize));
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318 }
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319
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320 for (size_t i = 0; i < m_blockSize/2; ++i) {
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cannam@64
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321 // FFT shift
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322 double value = m_ri[i];
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323 m_ri[i] = m_ri[i + m_blockSize/2];
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324 m_ri[i + m_blockSize/2] = value;
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325 }
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326
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327 fft(m_blockSize, false, m_ri, 0, m_ro, m_io);
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328
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329 for (size_t i = 0; i <= m_blockSize/2; ++i) {
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330 m_freqbuf[c][i * 2] = m_ro[i];
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331 m_freqbuf[c][i * 2 + 1] = m_io[i];
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332 }
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cannam@64
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333 }
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334
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335 return m_plugin->process(m_freqbuf, timestamp);
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cannam@64
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336 }
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cannam@64
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337
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cannam@64
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338 void
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339 PluginInputDomainAdapter::Impl::fft(unsigned int n, bool inverse,
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340 double *ri, double *ii, double *ro, double *io)
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341 {
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342 if (!ri || !ro || !io) return;
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343
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344 unsigned int bits;
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345 unsigned int i, j, k, m;
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346 unsigned int blockSize, blockEnd;
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347
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cannam@64
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348 double tr, ti;
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cannam@64
|
349
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cannam@64
|
350 if (n < 2) return;
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cannam@64
|
351 if (n & (n-1)) return;
|
cannam@64
|
352
|
cannam@64
|
353 double angle = 2.0 * M_PI;
|
cannam@64
|
354 if (inverse) angle = -angle;
|
cannam@64
|
355
|
cannam@64
|
356 for (i = 0; ; ++i) {
|
cannam@64
|
357 if (n & (1 << i)) {
|
cannam@64
|
358 bits = i;
|
cannam@64
|
359 break;
|
cannam@64
|
360 }
|
cannam@64
|
361 }
|
cannam@64
|
362
|
cannam@64
|
363 static unsigned int tableSize = 0;
|
cannam@64
|
364 static int *table = 0;
|
cannam@64
|
365
|
cannam@64
|
366 if (tableSize != n) {
|
cannam@64
|
367
|
cannam@64
|
368 delete[] table;
|
cannam@64
|
369
|
cannam@64
|
370 table = new int[n];
|
cannam@64
|
371
|
cannam@64
|
372 for (i = 0; i < n; ++i) {
|
cannam@64
|
373
|
cannam@64
|
374 m = i;
|
cannam@64
|
375
|
cannam@64
|
376 for (j = k = 0; j < bits; ++j) {
|
cannam@64
|
377 k = (k << 1) | (m & 1);
|
cannam@64
|
378 m >>= 1;
|
cannam@64
|
379 }
|
cannam@64
|
380
|
cannam@64
|
381 table[i] = k;
|
cannam@64
|
382 }
|
cannam@64
|
383
|
cannam@64
|
384 tableSize = n;
|
cannam@64
|
385 }
|
cannam@64
|
386
|
cannam@64
|
387 if (ii) {
|
cannam@64
|
388 for (i = 0; i < n; ++i) {
|
cannam@64
|
389 ro[table[i]] = ri[i];
|
cannam@64
|
390 io[table[i]] = ii[i];
|
cannam@64
|
391 }
|
cannam@64
|
392 } else {
|
cannam@64
|
393 for (i = 0; i < n; ++i) {
|
cannam@64
|
394 ro[table[i]] = ri[i];
|
cannam@64
|
395 io[table[i]] = 0.0;
|
cannam@64
|
396 }
|
cannam@64
|
397 }
|
cannam@64
|
398
|
cannam@64
|
399 blockEnd = 1;
|
cannam@64
|
400
|
cannam@64
|
401 for (blockSize = 2; blockSize <= n; blockSize <<= 1) {
|
cannam@64
|
402
|
cannam@64
|
403 double delta = angle / (double)blockSize;
|
cannam@64
|
404 double sm2 = -sin(-2 * delta);
|
cannam@64
|
405 double sm1 = -sin(-delta);
|
cannam@64
|
406 double cm2 = cos(-2 * delta);
|
cannam@64
|
407 double cm1 = cos(-delta);
|
cannam@64
|
408 double w = 2 * cm1;
|
cannam@64
|
409 double ar[3], ai[3];
|
cannam@64
|
410
|
cannam@64
|
411 for (i = 0; i < n; i += blockSize) {
|
cannam@64
|
412
|
cannam@64
|
413 ar[2] = cm2;
|
cannam@64
|
414 ar[1] = cm1;
|
cannam@64
|
415
|
cannam@64
|
416 ai[2] = sm2;
|
cannam@64
|
417 ai[1] = sm1;
|
cannam@64
|
418
|
cannam@64
|
419 for (j = i, m = 0; m < blockEnd; j++, m++) {
|
cannam@64
|
420
|
cannam@64
|
421 ar[0] = w * ar[1] - ar[2];
|
cannam@64
|
422 ar[2] = ar[1];
|
cannam@64
|
423 ar[1] = ar[0];
|
cannam@64
|
424
|
cannam@64
|
425 ai[0] = w * ai[1] - ai[2];
|
cannam@64
|
426 ai[2] = ai[1];
|
cannam@64
|
427 ai[1] = ai[0];
|
cannam@64
|
428
|
cannam@64
|
429 k = j + blockEnd;
|
cannam@64
|
430 tr = ar[0] * ro[k] - ai[0] * io[k];
|
cannam@64
|
431 ti = ar[0] * io[k] + ai[0] * ro[k];
|
cannam@64
|
432
|
cannam@64
|
433 ro[k] = ro[j] - tr;
|
cannam@64
|
434 io[k] = io[j] - ti;
|
cannam@64
|
435
|
cannam@64
|
436 ro[j] += tr;
|
cannam@64
|
437 io[j] += ti;
|
cannam@64
|
438 }
|
cannam@64
|
439 }
|
cannam@64
|
440
|
cannam@64
|
441 blockEnd = blockSize;
|
cannam@64
|
442 }
|
cannam@64
|
443
|
cannam@64
|
444 if (inverse) {
|
cannam@64
|
445
|
cannam@64
|
446 double denom = (double)n;
|
cannam@64
|
447
|
cannam@64
|
448 for (i = 0; i < n; i++) {
|
cannam@64
|
449 ro[i] /= denom;
|
cannam@64
|
450 io[i] /= denom;
|
cannam@64
|
451 }
|
cannam@64
|
452 }
|
cannam@64
|
453 }
|
cannam@64
|
454
|
cannam@64
|
455 }
|
cannam@64
|
456
|
cannam@64
|
457 }
|
cannam@64
|
458
|