Mercurial > hg > svcore
view data/model/BasicCompressedDenseThreeDimensionalModel.cpp @ 1837:1b688ab5f1b3
Unify various vectors to our base floatvec_t type; store columns in fft model cache at their desired height so we can return a reference (speeding up the peak-frequency spectrogram in particular)
author | Chris Cannam |
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date | Thu, 09 Apr 2020 11:22:55 +0100 |
parents | 21c792334c2e |
children |
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/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* Sonic Visualiser An audio file viewer and annotation editor. Centre for Digital Music, Queen Mary, University of London. This file copyright 2006 Chris Cannam and QMUL. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. See the file COPYING included with this distribution for more information. */ #include "BasicCompressedDenseThreeDimensionalModel.h" #include "base/LogRange.h" #include <QTextStream> #include <QStringList> #include <QReadLocker> #include <QWriteLocker> #include <iostream> #include <cmath> #include <cassert> using std::vector; #include "system/System.h" BasicCompressedDenseThreeDimensionalModel::BasicCompressedDenseThreeDimensionalModel(sv_samplerate_t sampleRate, int resolution, int yBinCount, bool notifyOnAdd) : m_startFrame(0), m_sampleRate(sampleRate), m_resolution(resolution), m_yBinCount(yBinCount), m_minimum(0.0), m_maximum(0.0), m_haveExtents(false), m_notifyOnAdd(notifyOnAdd), m_sinceLastNotifyMin(-1), m_sinceLastNotifyMax(-1), m_completion(100) { } bool BasicCompressedDenseThreeDimensionalModel::isOK() const { return true; } bool BasicCompressedDenseThreeDimensionalModel::isReady(int *completion) const { if (completion) *completion = getCompletion(); return true; } sv_samplerate_t BasicCompressedDenseThreeDimensionalModel::getSampleRate() const { return m_sampleRate; } sv_frame_t BasicCompressedDenseThreeDimensionalModel::getStartFrame() const { return m_startFrame; } void BasicCompressedDenseThreeDimensionalModel::setStartFrame(sv_frame_t f) { m_startFrame = f; } sv_frame_t BasicCompressedDenseThreeDimensionalModel::getTrueEndFrame() const { return m_resolution * m_data.size() + (m_resolution - 1); } int BasicCompressedDenseThreeDimensionalModel::getResolution() const { return m_resolution; } void BasicCompressedDenseThreeDimensionalModel::setResolution(int sz) { m_resolution = sz; } int BasicCompressedDenseThreeDimensionalModel::getWidth() const { return int(m_data.size()); } int BasicCompressedDenseThreeDimensionalModel::getHeight() const { return m_yBinCount; } void BasicCompressedDenseThreeDimensionalModel::setHeight(int sz) { m_yBinCount = sz; } float BasicCompressedDenseThreeDimensionalModel::getMinimumLevel() const { return m_minimum; } void BasicCompressedDenseThreeDimensionalModel::setMinimumLevel(float level) { m_minimum = level; } float BasicCompressedDenseThreeDimensionalModel::getMaximumLevel() const { return m_maximum; } void BasicCompressedDenseThreeDimensionalModel::setMaximumLevel(float level) { m_maximum = level; } BasicCompressedDenseThreeDimensionalModel::Column BasicCompressedDenseThreeDimensionalModel::getColumn(int index) const { QReadLocker locker(&m_lock); if (in_range_for(m_data, index)) return expandAndRetrieve(index); else return Column(); } float BasicCompressedDenseThreeDimensionalModel::getValueAt(int index, int n) const { Column c = getColumn(index); if (in_range_for(c, n)) return c.at(n); return m_minimum; } //static int given = 0, stored = 0; void BasicCompressedDenseThreeDimensionalModel::truncateAndStore(int index, const Column &values) { assert(in_range_for(m_data, index)); //cout << "truncateAndStore(" << index << ", " << values.size() << ")" << endl; // The default case is to store the entire column at m_data[index] // and place 0 at m_trunc[index] to indicate that it has not been // truncated. We only do clever stuff if one of the clever-stuff // tests works out. m_trunc[index] = 0; if (index == 0 || int(values.size()) != m_yBinCount) { // given += values.size(); // stored += values.size(); m_data[index] = values; return; } // Maximum distance between a column and the one we refer to as // the source of its truncated values. Limited by having to fit // in a signed char, but in any case small values are usually // better static int maxdist = 6; bool known = false; // do we know whether to truncate at top or bottom? bool top = false; // if we do know, will we truncate at top? // If the previous column is not truncated, then it is the only // candidate for comparison. If it is truncated, then the column // that it refers to is the only candidate. Either way, we only // have one possible column to compare against here, and we are // being careful to ensure it is not a truncated one (to avoid // doing more work recursively when uncompressing). int tdist = 1; int ptrunc = m_trunc[index-1]; if (ptrunc < 0) { top = false; known = true; tdist = -ptrunc + 1; } else if (ptrunc > 0) { top = true; known = true; tdist = ptrunc + 1; } Column p = expandAndRetrieve(index - tdist); int h = m_yBinCount; if (int(p.size()) == h && tdist <= maxdist) { int bcount = 0, tcount = 0; if (!known || !top) { // count how many identical values there are at the bottom for (int i = 0; i < h; ++i) { if (values.at(i) == p.at(i)) ++bcount; else break; } } if (!known || top) { // count how many identical values there are at the top for (int i = h; i > 0; --i) { if (values.at(i-1) == p.at(i-1)) ++tcount; else break; } } if (!known) top = (tcount > bcount); int limit = h / 4; // don't bother unless we have at least this many if ((top ? tcount : bcount) > limit) { if (!top) { // create a new column with h - bcount values from bcount up Column tcol(h - bcount); // given += values.size(); // stored += h - bcount; for (int i = bcount; i < h; ++i) { tcol[i - bcount] = values.at(i); } m_data[index] = tcol; m_trunc[index] = (signed char)(-tdist); return; } else { // create a new column with h - tcount values from 0 up Column tcol(h - tcount); // given += values.size(); // stored += h - tcount; for (int i = 0; i < h - tcount; ++i) { tcol[i] = values.at(i); } m_data[index] = tcol; m_trunc[index] = (signed char)(tdist); return; } } } // given += values.size(); // stored += values.size(); // cout << "given: " << given << ", stored: " << stored << " (" // << ((float(stored) / float(given)) * 100.f) << "%)" << endl; // default case if nothing wacky worked out m_data[index] = values; return; } BasicCompressedDenseThreeDimensionalModel::Column BasicCompressedDenseThreeDimensionalModel::rightHeight(const Column &c) const { if (int(c.size()) == m_yBinCount) return c; else { Column cc(c); cc.resize(m_yBinCount, 0.0); return cc; } } BasicCompressedDenseThreeDimensionalModel::Column BasicCompressedDenseThreeDimensionalModel::expandAndRetrieve(int index) const { // See comment above m_trunc declaration in header assert(index >= 0 && index < int(m_data.size())); Column c = m_data.at(index); if (index == 0) { return rightHeight(c); } int trunc = (int)m_trunc[index]; if (trunc == 0) { return rightHeight(c); } bool top = true; int tdist = trunc; if (trunc < 0) { top = false; tdist = -trunc; } Column p = expandAndRetrieve(index - tdist); int psize = int(p.size()), csize = int(c.size()); if (psize != m_yBinCount) { cerr << "WARNING: BasicCompressedDenseThreeDimensionalModel::expandAndRetrieve: Trying to expand from incorrectly sized column" << endl; } if (top) { for (int i = csize; i < psize; ++i) { c.push_back(p.at(i)); } } else { Column cc(psize); for (int i = 0; i < psize - csize; ++i) { cc[i] = p.at(i); } for (int i = 0; i < csize; ++i) { cc[i + (psize - csize)] = c.at(i); } return cc; } return c; } void BasicCompressedDenseThreeDimensionalModel::setColumn(int index, const Column &values) { QWriteLocker locker(&m_lock); while (index >= int(m_data.size())) { m_data.push_back(Column()); m_trunc.push_back(0); } bool allChange = false; for (int i = 0; in_range_for(values, i); ++i) { float value = values[i]; if (ISNAN(value) || ISINF(value)) { continue; } if (!m_haveExtents || value < m_minimum) { m_minimum = value; allChange = true; } if (!m_haveExtents || value > m_maximum) { m_maximum = value; allChange = true; } m_haveExtents = true; } truncateAndStore(index, values); // assert(values == expandAndRetrieve(index)); sv_frame_t windowStart = index; windowStart *= m_resolution; if (m_notifyOnAdd) { if (allChange) { emit modelChanged(getId()); } else { emit modelChangedWithin(getId(), windowStart, windowStart + m_resolution); } } else { if (allChange) { m_sinceLastNotifyMin = -1; m_sinceLastNotifyMax = -1; emit modelChanged(getId()); } else { if (m_sinceLastNotifyMin == -1 || windowStart < m_sinceLastNotifyMin) { m_sinceLastNotifyMin = windowStart; } if (m_sinceLastNotifyMax == -1 || windowStart > m_sinceLastNotifyMax) { m_sinceLastNotifyMax = windowStart; } } } } QString BasicCompressedDenseThreeDimensionalModel::getBinName(int n) const { if (n >= 0 && (int)m_binNames.size() > n) return m_binNames[n]; else return ""; } void BasicCompressedDenseThreeDimensionalModel::setBinName(int n, QString name) { while ((int)m_binNames.size() <= n) m_binNames.push_back(""); m_binNames[n] = name; emit modelChanged(getId()); } void BasicCompressedDenseThreeDimensionalModel::setBinNames(std::vector<QString> names) { m_binNames = names; emit modelChanged(getId()); } bool BasicCompressedDenseThreeDimensionalModel::hasBinValues() const { return !m_binValues.empty(); } float BasicCompressedDenseThreeDimensionalModel::getBinValue(int n) const { if (n < (int)m_binValues.size()) return m_binValues[n]; else return 0.f; } void BasicCompressedDenseThreeDimensionalModel::setBinValues(std::vector<float> values) { m_binValues = values; } QString BasicCompressedDenseThreeDimensionalModel::getBinValueUnit() const { return m_binValueUnit; } void BasicCompressedDenseThreeDimensionalModel::setBinValueUnit(QString unit) { m_binValueUnit = unit; } bool BasicCompressedDenseThreeDimensionalModel::shouldUseLogValueScale() const { QReadLocker locker(&m_lock); vector<double> sample; vector<int> n; for (int i = 0; i < 10; ++i) { int index = i * 10; if (in_range_for(m_data, index)) { const Column &c = m_data.at(index); while (c.size() > sample.size()) { sample.push_back(0.0); n.push_back(0); } for (int j = 0; in_range_for(c, j); ++j) { sample[j] += c.at(j); ++n[j]; } } } if (sample.empty()) return false; for (decltype(sample)::size_type j = 0; j < sample.size(); ++j) { if (n[j]) sample[j] /= n[j]; } return LogRange::shouldUseLogScale(sample); } void BasicCompressedDenseThreeDimensionalModel::setCompletion(int completion, bool update) { if (m_completion != completion) { m_completion = completion; if (completion == 100) { m_notifyOnAdd = true; // henceforth emit modelChanged(getId()); } else if (!m_notifyOnAdd) { if (update && m_sinceLastNotifyMin >= 0 && m_sinceLastNotifyMax >= 0) { emit modelChangedWithin(getId(), m_sinceLastNotifyMin, m_sinceLastNotifyMax + m_resolution); m_sinceLastNotifyMin = m_sinceLastNotifyMax = -1; } else { emit completionChanged(getId()); } } else { emit completionChanged(getId()); } } } int BasicCompressedDenseThreeDimensionalModel::getCompletion() const { return m_completion; } QVector<QString> BasicCompressedDenseThreeDimensionalModel::getStringExportHeaders(DataExportOptions) const { QVector<QString> sv; for (int i = 0; i < m_yBinCount; ++i) { sv.push_back(QString("Bin%1").arg(i+1)); } return sv; } QVector<QVector<QString>> BasicCompressedDenseThreeDimensionalModel::toStringExportRows(DataExportOptions, sv_frame_t startFrame, sv_frame_t duration) const { QReadLocker locker(&m_lock); QVector<QVector<QString>> rows; for (int i = 0; in_range_for(m_data, i); ++i) { Column c = getColumn(i); sv_frame_t fr = m_startFrame + i * m_resolution; if (fr >= startFrame && fr < startFrame + duration) { QVector<QString> row; for (int j = 0; in_range_for(c, j); ++j) { row << QString("%1").arg(c.at(j)); } rows.push_back(row); } } return rows; } void BasicCompressedDenseThreeDimensionalModel::toXml(QTextStream &out, QString indent, QString extraAttributes) const { QReadLocker locker(&m_lock); // For historical reasons we read and write "resolution" as "windowSize". // Our dataset doesn't have its own export ID, we just use // ours. Actually any model could do that, since datasets aren't // in the same id-space as models when re-read SVDEBUG << "BasicCompressedDenseThreeDimensionalModel::toXml" << endl; Model::toXml (out, indent, QString("type=\"dense\" dimensions=\"3\" windowSize=\"%1\" yBinCount=\"%2\" minimum=\"%3\" maximum=\"%4\" dataset=\"%5\" startFrame=\"%6\" %7") .arg(m_resolution) .arg(m_yBinCount) .arg(m_minimum) .arg(m_maximum) .arg(getExportId()) .arg(m_startFrame) .arg(extraAttributes)); out << indent; out << QString("<dataset id=\"%1\" dimensions=\"3\" separator=\" \">\n") .arg(getExportId()); for (int i = 0; in_range_for(m_binNames, i); ++i) { if (m_binNames[i] != "") { out << indent + " "; out << QString("<bin number=\"%1\" name=\"%2\"/>\n") .arg(i).arg(m_binNames[i]); } } for (int i = 0; in_range_for(m_data, i); ++i) { Column c = getColumn(i); out << indent + " "; out << QString("<row n=\"%1\">").arg(i); for (int j = 0; in_range_for(c, j); ++j) { if (j > 0) out << " "; out << c.at(j); } out << QString("</row>\n"); out.flush(); } out << indent + "</dataset>\n"; }