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// Copyright (C) 2023 The Qt Company Ltd.
// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR BSD-3-Clause
#include "datasource.h"
#include <QtCore/qmath.h>
#include <QtCore/qrandom.h>
#include <algorithm>
DataSource::DataSource(QObject *parent) :
QObject(parent)
{
//! [3]
qRegisterMetaType<QSurface3DSeries *>();
//! [3]
}
DataSource::~DataSource()
{
clearData();
}
void DataSource::generateData(int cacheCount, int rowCount, int columnCount,
float xMin, float xMax,
float yMin, float yMax,
float zMin, float zMax)
{
if (!cacheCount || !rowCount || !columnCount)
return;
clearData();
// Re-create the cache array
m_data.resize(cacheCount);
for (int i = 0; i < cacheCount; ++i) {
QSurfaceDataArray &array = m_data[i];
array.reserve(rowCount);
for (int j = 0; j < rowCount; ++j)
array.append(new QSurfaceDataRow(columnCount));
}
float xRange = xMax - xMin;
float yRange = yMax - yMin;
float zRange = zMax - zMin;
int cacheIndexStep = columnCount / cacheCount;
float cacheStep = float(cacheIndexStep) * xRange / float(columnCount);
//! [0]
// Populate caches
auto *generator = QRandomGenerator::global();
for (int i = 0; i < cacheCount; ++i) {
QSurfaceDataArray &cache = m_data[i];
float cacheXAdjustment = cacheStep * i;
float cacheIndexAdjustment = cacheIndexStep * i;
for (int j = 0; j < rowCount; ++j) {
QSurfaceDataRow &row = *(cache[j]);
float rowMod = (float(j)) / float(rowCount);
float yRangeMod = yRange * rowMod;
float zRangeMod = zRange * rowMod;
float z = zRangeMod + zMin;
qreal rowColWaveAngleMul = M_PI * M_PI * rowMod;
float rowColWaveMul = yRangeMod * 0.2f;
for (int k = 0; k < columnCount; k++) {
float colMod = (float(k)) / float(columnCount);
float xRangeMod = xRange * colMod;
float x = xRangeMod + xMin + cacheXAdjustment;
float colWave = float(qSin((2.0 * M_PI * colMod) - (1.0 / 2.0 * M_PI)) + 1.0);
float y = (colWave * ((float(qSin(rowColWaveAngleMul * colMod) + 1.0))))
* rowColWaveMul
+ generator->bounded(0.15f) * yRangeMod;
int index = k + cacheIndexAdjustment;
if (index >= columnCount) {
// Wrap over
index -= columnCount;
x -= xRange;
}
row[index] = QVector3D(x, y, z);
}
}
}
//! [0]
}
void DataSource::update(QSurface3DSeries *series)
{
if (series && !m_data.isEmpty()) {
//! [1]
// Each iteration uses data from a different cached array
if (++m_index >= m_data.size())
m_index = 0;
const QSurfaceDataArray &array = m_data.at(m_index);
int newRowCount = array.size();
int newColumnCount = array.at(0)->size();
// If the first time or the dimensions of the cache array have changed,
// reconstruct the reset array
if (!m_resetArray || series->dataProxy()->rowCount() != newRowCount
|| series->dataProxy()->columnCount() != newColumnCount) {
m_resetArray = new QSurfaceDataArray();
m_resetArray->reserve(newRowCount);
for (int i = 0; i < newRowCount; ++i)
m_resetArray->append(new QSurfaceDataRow(newColumnCount));
}
// Copy items from our cache to the reset array
for (int i = 0; i < newRowCount; ++i) {
const QSurfaceDataRow &sourceRow = *(array.at(i));
QSurfaceDataRow &row = *(*m_resetArray)[i];
std::copy(sourceRow.cbegin(), sourceRow.cend(), row.begin());
}
// Notify the proxy that data has changed
series->dataProxy()->resetArray(m_resetArray);
//! [1]
}
}
void DataSource::clearData()
{
for (auto &array : std::as_const(m_data))
qDeleteAll(array);
m_data.clear();
}
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