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paulstretchplugin/Source/PS_Source/StretchSource.cpp

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  1. #include "StretchSource.h"

  2. 

  3. #ifdef WIN32

  4. #include <ppl.h>

  5. //#define USE_PPL_TO_PROCESS_STRETCHERS

  6. #undef min

  7. #undef max

  8. #endif

  9. 

  10. StretchAudioSource::StretchAudioSource(int initialnumoutchans, AudioFormatManager* afm) : m_afm(afm)

  11. {

  12. 	m_resampler = std::make_unique<WDL_Resampler>();

  13. 	m_resampler_outbuf.resize(1024*1024);

  14. 	m_inputfile = std::make_unique<AInputS>(m_afm);

  15. 	m_specproc_order = { {0,false} , { 1, false} ,{2,true},{3,true},{4,true},{5,false},{6,true},{7,true} };

  16. 	setNumOutChannels(initialnumoutchans);

  17. 	m_xfadetask.buffer.setSize(8, 65536);

  18. 	m_xfadetask.buffer.clear();

  19. }

  20. 

  21. StretchAudioSource::~StretchAudioSource()

  22. {

  23. 	

  24. }

  25. 

  26. void StretchAudioSource::prepareToPlay(int samplesPerBlockExpected, double sampleRate)

  27. {

  28. 	m_outsr = sampleRate;

  29. 	m_vol_smoother.reset(sampleRate, 0.5);

  30. 	m_lastplayrate = -1.0;

  31. 	m_stop_play_requested = false;

  32. 	m_output_counter = 0;

  33. 	m_output_silence_counter = 0;

  34. 	m_stream_end_reached = false;

  35. 	m_firstbuffer = true;

  36. 	m_output_has_begun = false;

  37. 	m_drypreviewbuf.setSize(m_num_outchans, 65536);

  38. 	initObjects();

  39. 	

  40. }

  41. 

  42. void StretchAudioSource::releaseResources()

  43. {

  44. 	

  45. }

  46. 

  47. AudioBuffer<float>* StretchAudioSource::getSourceAudioBuffer()

  48. {

  49.     if (m_inputfile==nullptr)

  50.         return nullptr;

  51.     return m_inputfile->getAudioBuffer();

  52. }

  53. 

  54. bool StretchAudioSource::isResampling()

  55. {

  56.     if (m_inputfile==nullptr || m_inputfile->info.samplerate==0)

  57.         return false;

  58.     return (int)m_outsr!=m_inputfile->info.samplerate;

  59. }

  60. 

  61. std::vector<SpectrumProcess> StretchAudioSource::getSpectrumProcessOrder()

  62. {

  63. 	return m_specproc_order;

  64. }

  65. 

  66. void StretchAudioSource::setSpectrumProcessOrder(std::vector<SpectrumProcess> order)

  67. {

  68. 	ScopedLock locker(m_cs);

  69. 	m_specproc_order = order;

  70. 	for (int i = 0; i < m_stretchers.size(); ++i)

  71. 	{

  72. 		m_stretchers[i]->m_spectrum_processes = order;

  73. 	}

  74. }

  75. 

  76. std::pair<Range<double>, Range<double>> StretchAudioSource::getFileCachedRangesNormalized()

  77. {

  78. 	if (m_inputfile == nullptr)

  79. 		return {};

  80. 	return m_inputfile->getCachedRangesNormalized();

  81. }

  82. 

  83. ValueTree StretchAudioSource::getStateTree()

  84. {

  85. 	ValueTree tree("stretchsourcestate");

  86. 	storeToTreeProperties(tree, nullptr, "pitch_shift", m_ppar.pitch_shift.cents, 

  87. 		"octaves_minus2", m_ppar.octave.om2,

  88. 		"octaves_minus1",m_ppar.octave.om1,

  89. 		"octave0",m_ppar.octave.o0,

  90. 		"octave_plus1",m_ppar.octave.o1,

  91. 		"octaves_plus15",m_ppar.octave.o15,

  92. 		"octaves_plus2",m_ppar.octave.o2);

  93. 	return tree;

  94. }

  95. 

  96. void StretchAudioSource::setStateTree(ValueTree state)

  97. {

  98. 	ScopedLock locker(m_cs);

  99. 	getFromTreeProperties(state, "pitch_shift", m_ppar.pitch_shift.cents,

  100. 		"octaves_minus2", m_ppar.octave.om2,

  101. 		"octaves_minus1", m_ppar.octave.om1,

  102. 		"octave0", m_ppar.octave.o0,

  103. 		"octave_plus1", m_ppar.octave.o1,

  104. 		"octaves_plus15", m_ppar.octave.o15,

  105. 		"octaves_plus2", m_ppar.octave.o2);

  106. 	for (int i = 0; i < m_stretchers.size(); ++i)

  107. 	{

  108. 		m_stretchers[i]->set_parameters(&m_ppar);

  109. 	}

  110. }

  111. 

  112. bool StretchAudioSource::isLoopingEnabled()

  113. {

  114. 	if (m_inputfile == nullptr || m_inputfile->info.nsamples == 0)

  115. 		return false;

  116. 	return m_inputfile->isLooping();

  117. }

  118. 

  119. void StretchAudioSource::setLoopingEnabled(bool b)

  120. {

  121. 	ScopedLock locker(m_cs);

  122. 	if (m_inputfile != nullptr)

  123. 	{

  124. 		m_inputfile->setLoopEnabled(b);

  125. 	}

  126. }

  127. 

  128. void StretchAudioSource::setAudioBufferAsInputSource(AudioBuffer<float>* buf, int sr, int len)

  129. {

  130. 	ScopedLock locker(m_cs);

  131. 	m_inputfile->setAudioBuffer(buf, sr, len);

  132. 	m_seekpos = 0.0;

  133. 

  134. 	m_curfile = File();

  135. 	if (m_playrange.isEmpty())

  136. 		setPlayRange({ 0.0,1.0 }, true);

  137. 	++m_param_change_count;

  138. }

  139. 

  140. void StretchAudioSource::setMainVolume(double decibels)

  141. {

  142. 	if (decibels == m_main_volume)

  143. 		return;

  144. 	if (m_cs.tryEnter())

  145. 	{

  146. 		m_main_volume = jlimit(-144.0, 12.0, decibels);

  147. 		++m_param_change_count;

  148. 		m_cs.exit();

  149. 	}

  150. }

  151. 

  152. void StretchAudioSource::setLoopXFadeLength(double lenseconds)

  153. {

  154. 	if (lenseconds == m_loopxfadelen)

  155. 		return;

  156. 	if (m_cs.tryEnter())

  157. 	{

  158. 		m_loopxfadelen = jlimit(0.0, 1.0, lenseconds);

  159. 		++m_param_change_count;

  160. 		m_cs.exit();

  161. 	}

  162. }

  163. 

  164. void StretchAudioSource::setPreviewDry(bool b)

  165. {

  166. 	if (b == m_preview_dry)

  167. 		return;

  168. 	if (m_cs.tryEnter())

  169. 	{

  170. 		m_resampler->Reset();

  171. 		m_preview_dry = b;

  172. 		++m_param_change_count;

  173. 		m_cs.exit();

  174. 	}

  175. }

  176. 

  177. bool StretchAudioSource::isPreviewingDry() const

  178. {

  179. 	return m_preview_dry;

  180. }

  181. 

  182. void StretchAudioSource::getNextAudioBlock(const AudioSourceChannelInfo & bufferToFill)

  183. {

  184. 	ScopedLock locker(m_cs);

  185. 	if (m_preview_dry == true && m_inputfile!=nullptr && m_inputfile->info.nsamples>0)

  186. 	{

  187. 		playDrySound(bufferToFill);

  188. 		return;

  189. 	}

  190. 	double maingain = Decibels::decibelsToGain(m_main_volume);

  191. 	if (m_pause_state == 2)

  192. 	{

  193. 		bufferToFill.buffer->clear(bufferToFill.startSample,bufferToFill.numSamples);

  194. 		return;

  195. 	}

  196. 	if (m_stretchoutringbuf.available() > 0)

  197. 		m_output_has_begun = true;

  198. 	bool freezing = m_freezing;

  199. 	

  200.     if (m_stretchers[0]->isFreezing() != freezing)

  201. 	{

  202. 		if (freezing == true && m_inputfile!=nullptr)

  203. 			m_freeze_pos = 1.0/m_inputfile->info.nsamples*m_inputfile->getCurrentPosition();

  204. 		for (auto& e : m_stretchers)

  205. 			e->set_freezing(m_freezing);

  206. 	}

  207.     

  208. 	

  209. 	if (m_vol_smoother.getTargetValue() != maingain)

  210. 		m_vol_smoother.setValue(maingain);

  211. 	FloatVectorOperations::disableDenormalisedNumberSupport();

  212. 	float** outarrays = bufferToFill.buffer->getArrayOfWritePointers();

  213. 	int outbufchans = m_num_outchans; // bufferToFill.buffer->getNumChannels();

  214. 	int offset = bufferToFill.startSample;

  215. 	if (m_stretchers.size() == 0)

  216. 		return;

  217. 	if (m_inputfile == nullptr)

  218. 		return;

  219. 	if (m_inputfile->info.nsamples == 0)

  220. 		return;

  221. 	m_inputfile->setXFadeLenSeconds(m_loopxfadelen);

  222.     

  223. 	double silencethreshold = Decibels::decibelsToGain(-70.0);

  224. 	bool tempfirst = true;

  225.     auto foofilepos0 = m_inputfile->getCurrentPosition();

  226. 	auto ringbuffilltask = [this](int framestoproduce)

  227. 	{

  228. 		while (m_stretchoutringbuf.available() < framestoproduce*m_num_outchans)

  229. 		{

  230. 			int readsize = 0;

  231. 			double in_pos = (double)m_inputfile->getCurrentPosition() / (double)m_inputfile->info.nsamples;

  232. 			if (m_firstbuffer)

  233. 			{

  234. 				readsize = m_stretchers[0]->get_nsamples_for_fill();

  235. 				m_firstbuffer = false;

  236. 			}

  237. 			else

  238. 			{

  239. 				readsize = m_stretchers[0]->get_nsamples(in_pos*100.0);

  240. 			};

  241. 			int readed = 0;

  242. 			if (readsize != 0)

  243. 			{

  244. 				readed = m_inputfile->readNextBlock(m_file_inbuf, readsize, m_num_outchans);

  245. 			}

  246. 			auto inbufptrs = m_file_inbuf.getArrayOfWritePointers();

  247. 			REALTYPE onset_max = std::numeric_limits<REALTYPE>::min();

  248. #ifdef USE_PPL_TO_PROCESS_STRETCHERS

  249. 			std::array<REALTYPE, 16> onset_values_arr;

  250. 			Concurrency::parallel_for(0, (int)m_stretchers.size(), [this, readed, &onset_values_arr](int i)

  251. 			{

  252. 				REALTYPE onset_val = m_stretchers[i]->process(m_inbufs[i].data(), readed);

  253. 				onset_values_arr[i] = onset_val;

  254. 			});

  255. 			for (int i = 0; i < m_stretchers.size(); ++i)

  256. 				onset_max = std::max(onset_max, onset_values_arr[i]);

  257. #else

  258. 			for (int i = 0; i < m_stretchers.size(); ++i)

  259. 			{

  260. 				REALTYPE onset_l = m_stretchers[i]->process(inbufptrs[i], readed);

  261. 				onset_max = std::max(onset_max, onset_l);

  262. 			}

  263. #endif

  264. 			for (int i = 0; i < m_stretchers.size(); ++i)

  265. 				m_stretchers[i]->here_is_onset(onset_max);

  266. 			int outbufsize = m_stretchers[0]->get_bufsize();

  267. 			int nskip = m_stretchers[0]->get_skip_nsamples();

  268. 			if (nskip > 0)

  269. 				m_inputfile->skip(nskip);

  270. 

  271. 			for (int i = 0; i < outbufsize; i++)

  272. 			{

  273. 				for (int ch = 0; ch < m_num_outchans; ++ch)

  274. 				{

  275. 					REALTYPE outsa = m_stretchers[ch]->out_buf[i];

  276. 					m_stretchoutringbuf.push(outsa);

  277. 

  278. 				}

  279. 			}

  280. 

  281. 		}

  282. 		

  283. 	};

  284. 	int previousxfadestate = m_xfadetask.state;

  285. 	auto resamplertask = [this, &ringbuffilltask, &bufferToFill]()

  286. 	{

  287. 		double* rsinbuf = nullptr;

  288. 		int outsamplestoproduce = bufferToFill.numSamples;

  289. 		if (m_xfadetask.state == 1)

  290. 			outsamplestoproduce = m_xfadetask.xfade_len;

  291. 		int wanted = m_resampler->ResamplePrepare(outsamplestoproduce, m_num_outchans, &rsinbuf);

  292. 		ringbuffilltask(wanted);

  293. 		for (int i = 0; i < wanted*m_num_outchans; ++i)

  294. 		{

  295. 			double sample = m_stretchoutringbuf.get();

  296. 			rsinbuf[i] = sample;

  297. 		}

  298. 		if (outsamplestoproduce*m_num_outchans > m_resampler_outbuf.size())

  299. 		{

  300. 			m_resampler_outbuf.resize(outsamplestoproduce*m_num_outchans);

  301. 		}

  302. 		/*int produced =*/ m_resampler->ResampleOut(m_resampler_outbuf.data(), wanted, outsamplestoproduce, m_num_outchans);

  303. 		if (m_xfadetask.state == 1)

  304. 		{

  305. 			//Logger::writeToLog("Filling xfade buffer");

  306. 			for (int i = 0; i < outsamplestoproduce; ++i)

  307. 			{

  308. 				for (int j = 0; j < m_num_outchans; ++j)

  309. 				{

  310. 					m_xfadetask.buffer.setSample(j, i, m_resampler_outbuf[i*m_num_outchans + j]);

  311. 				}

  312. 			}

  313. 			if (m_process_fftsize != m_xfadetask.requested_fft_size)

  314. 			{

  315. 				m_process_fftsize = m_xfadetask.requested_fft_size;

  316. 				//Logger::writeToLog("Initing stretcher objects");

  317. 				initObjects();

  318. 			}

  319. 			m_xfadetask.state = 2;

  320. 		}

  321. 	};

  322. 	

  323. 	resamplertask();

  324. 	if (previousxfadestate == 1 && m_xfadetask.state == 2)

  325. 	{

  326. 		//Logger::writeToLog("Rerunning resampler task");

  327. 		resamplertask();

  328. 	}

  329. 	bool source_ended = m_inputfile->hasEnded();

  330. 	double samplelimit = 16384.0;

  331. 	if (m_clip_output == true)

  332. 		samplelimit = 1.0;

  333. 	for (int i = 0; i < bufferToFill.numSamples; ++i)

  334. 	{

  335. 		double smoothed_gain = m_vol_smoother.getNextValue();

  336. 		double mixed = 0.0;

  337. 		for (int j = 0; j < outbufchans; ++j)

  338. 		{

  339. 			double outsample = m_resampler_outbuf[i*m_num_outchans + j];

  340. 			if (m_xfadetask.state == 2)

  341. 			{

  342. 				double xfadegain = 1.0 / m_xfadetask.xfade_len*m_xfadetask.counter;

  343. 				jassert(xfadegain >= 0.0 && xfadegain <= 1.0);

  344. 				double outsample2 = m_xfadetask.buffer.getSample(j, m_xfadetask.counter);

  345. 				outsample = xfadegain * outsample + (1.0 - xfadegain)*outsample2;

  346. 			}

  347. 			outarrays[j][i + offset] = jlimit(-samplelimit,samplelimit , outsample * smoothed_gain);

  348. 			mixed += outsample;

  349. 		}

  350. 		if (m_xfadetask.state == 2)

  351. 		{

  352. 			++m_xfadetask.counter;

  353. 			if (m_xfadetask.counter >= m_xfadetask.xfade_len)

  354. 				m_xfadetask.state = 0;

  355. 		}

  356. 		if (source_ended && m_output_counter>=2*m_process_fftsize)

  357. 		{

  358. 			if (fabs(mixed) < silencethreshold)

  359. 				++m_output_silence_counter;

  360. 			else

  361. 				m_output_silence_counter = 0;

  362. 		}

  363. 		

  364. 	}

  365. 	if (m_pause_state == 1)

  366. 	{

  367. 		bufferToFill.buffer->applyGainRamp(bufferToFill.startSample, bufferToFill.numSamples, 1.0f, 0.0f);

  368. 		m_pause_state = 2;

  369. 	}

  370. 	if (m_pause_state == 3)

  371. 	{

  372. 		bufferToFill.buffer->applyGainRamp(bufferToFill.startSample, bufferToFill.numSamples, 0.0f, 1.0f);

  373. 		m_pause_state = 0;

  374. 	}

  375. 	m_output_counter += bufferToFill.numSamples;

  376. }

  377. 

  378. void StretchAudioSource::setNextReadPosition(int64 /*newPosition*/)

  379. {

  380. 	

  381. }

  382. 

  383. int64 StretchAudioSource::getNextReadPosition() const

  384. {

  385. 	return int64();

  386. }

  387. 

  388. int64 StretchAudioSource::getTotalLength() const

  389. {

  390. 	if (m_inputfile == nullptr)

  391. 		return 0;

  392. 	return m_inputfile->info.nsamples;

  393. }

  394. 

  395. bool StretchAudioSource::isLooping() const

  396. {

  397. 	return false;

  398. }

  399. 

  400. String StretchAudioSource::setAudioFile(File file)

  401. {

  402. 	ScopedLock locker(m_cs);

  403. 	if (m_inputfile->openAudioFile(file))

  404. 	{

  405. 		m_curfile = file;

  406. 		return String();

  407. 	}

  408. 	return "Could not open file";

  409. }

  410. 

  411. File StretchAudioSource::getAudioFile()

  412. {

  413. 	return m_curfile;

  414. }

  415. 

  416. void StretchAudioSource::setNumOutChannels(int chans)

  417. {

  418. 	jassert(chans > 0 && chans < g_maxnumoutchans);

  419. 	m_num_outchans = chans;

  420. }

  421. 

  422. void StretchAudioSource::initObjects()

  423. {

  424. 	ScopedLock locker(m_cs);

  425. 	m_inputfile->setActiveRange(m_playrange);

  426. 	if (m_inputfile->getActiveRange().contains(m_inputfile->getCurrentPositionPercent())==false)

  427. 		m_inputfile->seek(m_playrange.getStart());

  428. 	

  429. 	m_firstbuffer = true;

  430. 	if (m_stretchoutringbuf.getSize() < m_num_outchans*m_process_fftsize)

  431. 	{

  432. 		int newsize = m_num_outchans*m_process_fftsize*2;

  433. 		//Logger::writeToLog("Resizing circular buffer to " + String(newsize));

  434. 		m_stretchoutringbuf.resize(newsize);

  435. 	}

  436. 	m_stretchoutringbuf.clear();

  437. 	m_resampler->Reset();

  438. 	m_resampler->SetRates(m_inputfile->info.samplerate, m_outsr);

  439. 	REALTYPE stretchratio = m_playrate;

  440.     FFTWindow windowtype = W_HAMMING;

  441.     if (m_fft_window_type>=0)

  442.         windowtype = (FFTWindow)m_fft_window_type;

  443. 	int inbufsize = m_process_fftsize;

  444. 	double onsetsens = m_onsetdetection;

  445. 	m_stretchers.resize(m_num_outchans);

  446. 	for (int i = 0; i < m_stretchers.size(); ++i)

  447. 	{

  448. 		if (m_stretchers[i] == nullptr)

  449. 		{

  450. 			//Logger::writeToLog("Creating stretch instance " + String(i));

  451. 			m_stretchers[i] = std::make_shared<ProcessedStretch>(stretchratio,

  452. 				m_process_fftsize, windowtype, false, (float)m_inputfile->info.samplerate, i + 1);

  453. 		}

  454. 		m_stretchers[i]->setBufferSize(m_process_fftsize);

  455. 		m_stretchers[i]->setSampleRate(m_inputfile->info.samplerate);

  456. 		m_stretchers[i]->set_onset_detection_sensitivity(onsetsens);

  457. 		m_stretchers[i]->set_parameters(&m_ppar);

  458. 		m_stretchers[i]->set_freezing(m_freezing);

  459. 		fill_container(m_stretchers[i]->out_buf, 0.0f);

  460. 		m_stretchers[i]->m_spectrum_processes = m_specproc_order;

  461. 	}

  462. 	m_file_inbuf.setSize(m_num_outchans, 3 * inbufsize);

  463. 	int poolsize = m_stretchers[0]->get_max_bufsize();

  464. }

  465. 

  466. void StretchAudioSource::playDrySound(const AudioSourceChannelInfo & bufferToFill)

  467. {

  468. 	double maingain = Decibels::decibelsToGain(m_main_volume);

  469. 	m_inputfile->setXFadeLenSeconds(m_loopxfadelen);

  470. 	double* rsinbuf = nullptr;

  471. 	m_resampler->SetRates(m_inputfile->info.samplerate, m_outsr);

  472. 	int wanted = m_resampler->ResamplePrepare(bufferToFill.numSamples, m_num_outchans, &rsinbuf);

  473. 	m_inputfile->readNextBlock(m_drypreviewbuf, wanted, m_num_outchans);

  474. 	for (int i = 0; i < wanted; ++i)

  475. 		for (int j = 0; j < m_num_outchans; ++j)

  476. 			rsinbuf[i*m_num_outchans + j] = m_drypreviewbuf.getSample(j, i);

  477. 	m_resampler->ResampleOut(m_resampler_outbuf.data(), wanted, bufferToFill.numSamples, m_num_outchans);

  478. 	for (int i = 0; i < m_num_outchans; ++i)

  479. 		for (int j = 0; j < bufferToFill.numSamples; ++j)

  480. 			bufferToFill.buffer->setSample(i, j + bufferToFill.startSample, maingain * m_resampler_outbuf[j*m_num_outchans + i]);

  481. }

  482. 

  483. double StretchAudioSource::getInfilePositionPercent()

  484. {

  485. 	if (m_inputfile == nullptr || m_inputfile->info.nsamples == 0)

  486. 		return 0.0;

  487. 	return 1.0/m_inputfile->info.nsamples*m_inputfile->getCurrentPosition();

  488. }

  489. 

  490. double StretchAudioSource::getInfilePositionSeconds()

  491. {

  492. 	if (m_inputfile == nullptr || m_inputfile->info.nsamples == 0)

  493. 		return 0.0;

  494. 	//return m_lastinpos*m_inputfile->getLengthSeconds();

  495. 	return (double)m_inputfile->getCurrentPosition() / m_inputfile->info.samplerate;

  496. }

  497. 

  498. double StretchAudioSource::getInfileLengthSeconds()

  499. {

  500. 	if (m_inputfile == nullptr || m_inputfile->info.nsamples == 0)

  501. 		return 0.0;

  502. 	return (double)m_inputfile->info.nsamples / m_inputfile->info.samplerate;

  503. }

  504. 

  505. void StretchAudioSource::setRate(double rate)

  506. {

  507. 	if (rate == m_playrate)

  508. 		return;

  509. 	if (m_cs.tryEnter())

  510. 	{

  511. 		m_playrate = rate;

  512. 		for (int i = 0; i < m_stretchers.size(); ++i)

  513. 		{

  514. 			m_stretchers[i]->set_rap((float)rate);

  515. 		}

  516. 		++m_param_change_count;

  517. 		m_cs.exit();

  518. 	}

  519. }

  520. 

  521. void StretchAudioSource::setProcessParameters(ProcessParameters * pars)

  522. {

  523. 	if (*pars == m_ppar)

  524. 		return;

  525. 	if (m_cs.tryEnter())

  526. 	{

  527. 		m_ppar = *pars;

  528. 		for (int i = 0; i < m_stretchers.size(); ++i)

  529. 		{

  530. 			m_stretchers[i]->set_parameters(pars);

  531. 		}

  532. 		++m_param_change_count;

  533. 		m_cs.exit();

  534. 	}

  535. }

  536. 

  537. const ProcessParameters& StretchAudioSource::getProcessParameters()

  538. {

  539. 	return m_ppar;

  540. }

  541. 

  542. void StretchAudioSource::setFFTWindowingType(int windowtype)

  543. {

  544.     if (windowtype==m_fft_window_type)

  545.         return;

  546. 	if (m_cs.tryEnter())

  547. 	{

  548. 		m_fft_window_type = windowtype;

  549. 		for (int i = 0; i < m_stretchers.size(); ++i)

  550. 		{

  551. 			m_stretchers[i]->window_type = (FFTWindow)windowtype;

  552. 		}

  553. 		++m_param_change_count;

  554. 		m_cs.exit();

  555. 	}

  556. }

  557. 

  558. void StretchAudioSource::setFFTSize(int size)

  559. {

  560.     jassert(size>0);

  561.     if (m_xfadetask.state == 0 && (m_process_fftsize == 0 || size != m_process_fftsize))

  562. 	{

  563. 		ScopedLock locker(m_cs);

  564. 		if (m_xfadetask.buffer.getNumChannels() < m_num_outchans)

  565. 		{

  566. 			m_xfadetask.buffer.setSize(m_num_outchans, m_xfadetask.buffer.getNumSamples());

  567. 			

  568. 		}

  569. 		if (m_process_fftsize > 0)

  570. 		{

  571. 			m_xfadetask.state = 1;

  572. 			m_xfadetask.counter = 0;

  573. 			m_xfadetask.xfade_len = 16384;

  574. 			m_xfadetask.requested_fft_size = size;

  575. 		}

  576. 		else

  577. 		{

  578. 			m_process_fftsize = size;

  579. 			initObjects();

  580. 		}

  581. 		

  582. 		++m_param_change_count;

  583. 	}

  584. }

  585. 

  586. void StretchAudioSource::setPaused(bool b)

  587. {

  588. 	if (b == true && m_pause_state>0)

  589. 		return;

  590. 	if (b == false && m_pause_state == 0)

  591. 		return;

  592. 	ScopedLock locker(m_cs);

  593. 	if (b == true && m_pause_state == 0)

  594. 	{

  595. 		m_pause_state = 1;

  596. 		return;

  597. 	}

  598. 	if (b == false && m_pause_state == 2)

  599. 	{

  600. 		m_pause_state = 3;

  601. 		return;

  602. 	}

  603. }

  604. 

  605. bool StretchAudioSource::isPaused() const

  606. {

  607. 	return m_pause_state > 0;

  608. }

  609. 

  610. void StretchAudioSource::seekPercent(double pos)

  611. {

  612. 	ScopedLock locker(m_cs);

  613. 	m_seekpos = pos;

  614. 	//m_resampler->Reset();

  615. 	m_inputfile->seek(pos);

  616. 	++m_param_change_count;

  617. }

  618. 

  619. double StretchAudioSource::getOutputDurationSecondsForRange(Range<double> range, int fftsize)

  620. {

  621. 	if (m_inputfile == nullptr || m_inputfile->info.nsamples == 0)

  622. 		return 0.0;

  623. 	if (m_preview_dry==true)

  624.         return (double)range.getLength()*m_inputfile->info.nsamples/m_inputfile->info.samplerate;

  625.     int64_t play_end_pos = (fftsize * 2)+range.getLength()*m_playrate*m_inputfile->info.nsamples;

  626. 	return (double)play_end_pos / m_inputfile->info.samplerate;

  627. }

  628. 

  629. void StretchAudioSource::setOnsetDetection(double x)

  630. {

  631. 	if (x == m_onsetdetection)

  632. 		return;

  633. 	if (m_cs.tryEnter())

  634. 	{

  635. 		m_onsetdetection = x;

  636. 		for (int i = 0; i < m_stretchers.size(); ++i)

  637. 		{

  638. 			m_stretchers[i]->set_onset_detection_sensitivity((float)x);

  639. 		}

  640. 		++m_param_change_count;

  641. 		m_cs.exit();

  642. 	}

  643. }

  644. 

  645. void StretchAudioSource::setPlayRange(Range<double> playrange, bool isloop)

  646. {

  647. 	if (m_playrange.isEmpty() == false && playrange == m_playrange)

  648. 		return;

  649. 	if (m_cs.tryEnter())

  650. 	{

  651. 		if (playrange.isEmpty())

  652. 			m_playrange = { 0.0,1.0 };

  653. 		else

  654. 			m_playrange = playrange;

  655. 		m_stream_end_reached = false;

  656. 		m_inputfile->setActiveRange(m_playrange);

  657. 		m_inputfile->setLoopEnabled(isloop);

  658. 		//if (m_playrange.contains(m_seekpos) == false)

  659. 		//	m_inputfile->seek(m_playrange.getStart());

  660. 		m_seekpos = m_playrange.getStart();

  661. 		++m_param_change_count;

  662. 		m_cs.exit();

  663. 	}

  664. }

  665. 

  666. bool StretchAudioSource::isLoopEnabled()

  667. {

  668. 	if (m_inputfile == nullptr)

  669. 		return false;

  670. 	return m_inputfile->isLooping();

  671. }

  672. 

  673. bool StretchAudioSource::hasReachedEnd()

  674. {

  675. 	if (m_inputfile == nullptr)

  676. 		return false;

  677. 	if (m_inputfile->isLooping() && m_maxloops == 0)

  678. 		return false;

  679. 	if (m_inputfile->isLooping() && m_inputfile->getLoopCount() > m_maxloops)

  680. 		return true;

  681. 	//return m_output_counter>=m_process_fftsize*2;

  682. 	return m_output_silence_counter>=65536;

  683. }