diff --git a/src/backend/core/column/ColumnPrivate.cpp b/src/backend/core/column/ColumnPrivate.cpp index 54c126979..5cf3e93d9 100644 --- a/src/backend/core/column/ColumnPrivate.cpp +++ b/src/backend/core/column/ColumnPrivate.cpp @@ -1,1494 +1,1496 @@ /*************************************************************************** File : ColumnPrivate.cpp Project : AbstractColumn Description : Private data class of Column -------------------------------------------------------------------- Copyright : (C) 2007-2008 Tilman Benkert (thzs@gmx.net) Copyright : (C) 2012-2019 Alexander Semke (alexander.semke@web.de) Copyright : (C) 2017 Stefan Gerlach (stefan.gerlach@uni.kn) ***************************************************************************/ /*************************************************************************** * * * 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. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the Free Software * * Foundation, Inc., 51 Franklin Street, Fifth Floor, * * Boston, MA 02110-1301 USA * * * ***************************************************************************/ #include "ColumnPrivate.h" #include "ColumnStringIO.h" #include "Column.h" #include "backend/spreadsheet/Spreadsheet.h" #include "backend/core/datatypes/filter.h" #include "backend/gsl/ExpressionParser.h" ColumnPrivate::ColumnPrivate(Column* owner, AbstractColumn::ColumnMode mode) : m_column_mode(mode), m_owner(owner) { Q_ASSERT(owner != nullptr); switch (mode) { case AbstractColumn::Numeric: m_input_filter = new String2DoubleFilter(); m_output_filter = new Double2StringFilter(); m_data = new QVector(); break; case AbstractColumn::Integer: m_input_filter = new String2IntegerFilter(); m_output_filter = new Integer2StringFilter(); m_data = new QVector(); break; case AbstractColumn::Text: m_input_filter = new SimpleCopyThroughFilter(); m_output_filter = new SimpleCopyThroughFilter(); m_data = new QStringList(); break; case AbstractColumn::DateTime: m_input_filter = new String2DateTimeFilter(); m_output_filter = new DateTime2StringFilter(); m_data = new QVector(); break; case AbstractColumn::Month: m_input_filter = new String2MonthFilter(); m_output_filter = new DateTime2StringFilter(); static_cast(m_output_filter)->setFormat("MMMM"); m_data = new QVector(); break; case AbstractColumn::Day: m_input_filter = new String2DayOfWeekFilter(); m_output_filter = new DateTime2StringFilter(); static_cast(m_output_filter)->setFormat("dddd"); m_data = new QVector(); break; } connect(m_output_filter, &AbstractSimpleFilter::formatChanged, m_owner, &Column::handleFormatChange); m_input_filter->setName("InputFilter"); m_output_filter->setName("OutputFilter"); } /** * \brief Special ctor (to be called from Column only!) */ ColumnPrivate::ColumnPrivate(Column* owner, AbstractColumn::ColumnMode mode, void* data) : m_column_mode(mode), m_data(data), m_owner(owner) { switch (mode) { case AbstractColumn::Numeric: m_input_filter = new String2DoubleFilter(); m_output_filter = new Double2StringFilter(); connect(static_cast(m_output_filter), &Double2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Integer: m_input_filter = new String2IntegerFilter(); m_output_filter = new Integer2StringFilter(); connect(static_cast(m_output_filter), &Integer2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Text: m_input_filter = new SimpleCopyThroughFilter(); m_output_filter = new SimpleCopyThroughFilter(); break; case AbstractColumn::DateTime: m_input_filter = new String2DateTimeFilter(); m_output_filter = new DateTime2StringFilter(); connect(static_cast(m_output_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Month: m_input_filter = new String2MonthFilter(); m_output_filter = new DateTime2StringFilter(); static_cast(m_output_filter)->setFormat("MMMM"); connect(static_cast(m_output_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Day: m_input_filter = new String2DayOfWeekFilter(); m_output_filter = new DateTime2StringFilter(); static_cast(m_output_filter)->setFormat("dddd"); connect(static_cast(m_output_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; } m_input_filter->setName("InputFilter"); m_output_filter->setName("OutputFilter"); } ColumnPrivate::~ColumnPrivate() { if (!m_data) return; switch (m_column_mode) { case AbstractColumn::Numeric: delete static_cast*>(m_data); break; case AbstractColumn::Integer: delete static_cast*>(m_data); break; case AbstractColumn::Text: delete static_cast*>(m_data); break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: delete static_cast*>(m_data); break; } } AbstractColumn::ColumnMode ColumnPrivate::columnMode() const { return m_column_mode; } /** * \brief Set the column mode * * This sets the column mode and, if * necessary, converts it to another datatype. * Remark: setting the mode back to undefined (the * initial value) is not supported. */ void ColumnPrivate::setColumnMode(AbstractColumn::ColumnMode mode) { DEBUG("ColumnPrivate::setColumnMode() " << ENUM_TO_STRING(AbstractColumn, ColumnMode, m_column_mode) << " -> " << ENUM_TO_STRING(AbstractColumn, ColumnMode, mode)) if (mode == m_column_mode) return; void* old_data = m_data; // remark: the deletion of the old data will be done in the dtor of a command AbstractSimpleFilter* filter = nullptr, *new_in_filter = nullptr, *new_out_filter = nullptr; bool filter_is_temporary = false; // it can also become outputFilter(), which we may not delete here Column* temp_col = nullptr; emit m_owner->modeAboutToChange(m_owner); // determine the conversion filter and allocate the new data vector switch (m_column_mode) { // old mode case AbstractColumn::Numeric: { disconnect(static_cast(m_output_filter), &Double2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); switch (mode) { case AbstractColumn::Numeric: break; case AbstractColumn::Integer: filter = new Double2IntegerFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast*>(old_data))); m_data = new QVector(); break; case AbstractColumn::Text: filter = outputFilter(); filter_is_temporary = false; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data))); m_data = new QVector(); break; case AbstractColumn::DateTime: filter = new Double2DateTimeFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data))); m_data = new QVector(); break; case AbstractColumn::Month: filter = new Double2MonthFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data))); m_data = new QVector(); break; case AbstractColumn::Day: filter = new Double2DayOfWeekFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data))); m_data = new QVector(); break; } // switch(mode) break; } case AbstractColumn::Integer: { disconnect(static_cast(m_output_filter), &Integer2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); switch (mode) { case AbstractColumn::Integer: break; case AbstractColumn::Numeric: filter = new Integer2DoubleFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast*>(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::Text: filter = outputFilter(); filter_is_temporary = false; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::DateTime: filter = new Integer2DateTimeFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::Month: filter = new Integer2MonthFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::Day: filter = new Integer2DayOfWeekFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data)), m_column_mode); m_data = new QVector(); break; } // switch(mode) break; } case AbstractColumn::Text: { switch (mode) { case AbstractColumn::Text: break; case AbstractColumn::Numeric: filter = new String2DoubleFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast*>(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::Integer: filter = new String2IntegerFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast*>(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::DateTime: filter = new String2DateTimeFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast*>(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::Month: filter = new String2MonthFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast*>(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::Day: filter = new String2DayOfWeekFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast*>(old_data)), m_column_mode); m_data = new QVector(); break; } // switch(mode) break; } case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: { disconnect(static_cast(m_output_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); switch (mode) { case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: break; case AbstractColumn::Text: filter = outputFilter(); filter_is_temporary = false; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data)), m_column_mode); m_data = new QStringList(); break; case AbstractColumn::Numeric: if (m_column_mode == AbstractColumn::Month) filter = new Month2DoubleFilter(); else if (m_column_mode == AbstractColumn::Day) filter = new DayOfWeek2DoubleFilter(); else filter = new DateTime2DoubleFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data)), m_column_mode); m_data = new QVector(); break; case AbstractColumn::Integer: if (m_column_mode == AbstractColumn::Month) filter = new Month2IntegerFilter(); else if (m_column_mode == AbstractColumn::Day) filter = new DayOfWeek2IntegerFilter(); else filter = new DateTime2IntegerFilter(); filter_is_temporary = true; temp_col = new Column("temp_col", *(static_cast< QVector* >(old_data)), m_column_mode); m_data = new QVector(); break; } // switch(mode) break; } } // determine the new input and output filters switch (mode) { // new mode case AbstractColumn::Numeric: new_in_filter = new String2DoubleFilter(); new_out_filter = new Double2StringFilter(); connect(static_cast(new_out_filter), &Double2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Integer: new_in_filter = new String2IntegerFilter(); new_out_filter = new Integer2StringFilter(); connect(static_cast(new_out_filter), &Integer2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Text: new_in_filter = new SimpleCopyThroughFilter(); new_out_filter = new SimpleCopyThroughFilter(); break; case AbstractColumn::DateTime: new_in_filter = new String2DateTimeFilter(); new_out_filter = new DateTime2StringFilter(); connect(static_cast(new_out_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Month: new_in_filter = new String2MonthFilter(); new_out_filter = new DateTime2StringFilter(); static_cast(new_out_filter)->setFormat("MMMM"); DEBUG(" Month out_filter format: " << static_cast(new_out_filter)->format().toStdString()); connect(static_cast(new_out_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Day: new_in_filter = new String2DayOfWeekFilter(); new_out_filter = new DateTime2StringFilter(); static_cast(new_out_filter)->setFormat("dddd"); connect(static_cast(new_out_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; } // switch(mode) m_column_mode = mode; new_in_filter->setName("InputFilter"); new_out_filter->setName("OutputFilter"); m_input_filter = new_in_filter; m_output_filter = new_out_filter; m_input_filter->input(0, m_owner->m_string_io); m_output_filter->input(0, m_owner); m_input_filter->setHidden(true); m_output_filter->setHidden(true); if (temp_col) { // if temp_col == 0, only the input/output filters need to be changed // copy the filtered, i.e. converted, column (mode is orig mode) DEBUG(" temp_col column mode = " << ENUM_TO_STRING(AbstractColumn, ColumnMode, temp_col->columnMode())); filter->input(0, temp_col); DEBUG(" filter->output size = " << filter->output(0)->rowCount()); copy(filter->output(0)); delete temp_col; } if (filter_is_temporary) delete filter; emit m_owner->modeChanged(m_owner); DEBUG("ColumnPrivate::setColumnMode() DONE"); } /** * \brief Replace all mode related members * * Replace column mode, data type, data pointer and filters directly */ void ColumnPrivate::replaceModeData(AbstractColumn::ColumnMode mode, void* data, AbstractSimpleFilter* in_filter, AbstractSimpleFilter* out_filter) { DEBUG("ColumnPrivate::replaceModeData()"); emit m_owner->modeAboutToChange(m_owner); // disconnect formatChanged() switch (m_column_mode) { case AbstractColumn::Numeric: disconnect(static_cast(m_output_filter), &Double2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Integer: disconnect(static_cast(m_output_filter), &Integer2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Text: break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: disconnect(static_cast(m_output_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; } m_column_mode = mode; m_data = data; in_filter->setName("InputFilter"); out_filter->setName("OutputFilter"); m_input_filter = in_filter; m_output_filter = out_filter; m_input_filter->input(0, m_owner->m_string_io); m_output_filter->input(0, m_owner); // connect formatChanged() switch (m_column_mode) { case AbstractColumn::Numeric: connect(static_cast(m_output_filter), &Double2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Integer: connect(static_cast(m_output_filter), &Integer2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; case AbstractColumn::Text: break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: connect(static_cast(m_output_filter), &DateTime2StringFilter::formatChanged, m_owner, &Column::handleFormatChange); break; } emit m_owner->modeChanged(m_owner); } /** * \brief Replace data pointer */ void ColumnPrivate::replaceData(void* data) { DEBUG("ColumnPrivate::replaceData()"); emit m_owner->dataAboutToChange(m_owner); m_data = data; if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Copy another column of the same type * * This function will return false if the data type * of 'other' is not the same as the type of 'this'. * Use a filter to convert a column to another type. */ bool ColumnPrivate::copy(const AbstractColumn* other) { DEBUG("ColumnPrivate::copy(other)"); if (other->columnMode() != columnMode()) return false; DEBUG(" mode = " << ENUM_TO_STRING(AbstractColumn, ColumnMode, columnMode())); int num_rows = other->rowCount(); DEBUG(" rows " << num_rows); emit m_owner->dataAboutToChange(m_owner); resizeTo(num_rows); // copy the data switch (m_column_mode) { case AbstractColumn::Numeric: { double* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[i] = other->valueAt(i); break; } case AbstractColumn::Integer: { int* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[i] = other->integerAt(i); break; } case AbstractColumn::Text: { for (int i = 0; i < num_rows; ++i) static_cast*>(m_data)->replace(i, other->textAt(i)); break; } case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: { for (int i = 0; i < num_rows; ++i) static_cast*>(m_data)->replace(i, other->dateTimeAt(i)); break; } } if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); return true; } /** * \brief Copies a part of another column of the same type * * This function will return false if the data type * of 'other' is not the same as the type of 'this'. * \param other pointer to the column to copy * \param src_start first row to copy in the column to copy * \param dest_start first row to copy in * \param num_rows the number of rows to copy */ bool ColumnPrivate::copy(const AbstractColumn* source, int source_start, int dest_start, int num_rows) { DEBUG("ColumnPrivate::copy()"); if (source->columnMode() != m_column_mode) return false; if (num_rows == 0) return true; emit m_owner->dataAboutToChange(m_owner); if (dest_start + num_rows > rowCount()) resizeTo(dest_start + num_rows); // copy the data switch (m_column_mode) { case AbstractColumn::Numeric: { double* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; i++) ptr[dest_start+i] = source->valueAt(source_start + i); break; } case AbstractColumn::Integer: { int* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; i++) ptr[dest_start+i] = source->integerAt(source_start + i); break; } case AbstractColumn::Text: for (int i = 0; i < num_rows; i++) static_cast*>(m_data)->replace(dest_start+i, source->textAt(source_start + i)); break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: for (int i = 0; i < num_rows; i++) static_cast*>(m_data)->replace(dest_start+i, source->dateTimeAt(source_start + i)); break; } if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); return true; } /** * \brief Copy another column of the same type * * This function will return false if the data type * of 'other' is not the same as the type of 'this'. * Use a filter to convert a column to another type. */ bool ColumnPrivate::copy(const ColumnPrivate* other) { if (other->columnMode() != m_column_mode) return false; int num_rows = other->rowCount(); emit m_owner->dataAboutToChange(m_owner); resizeTo(num_rows); // copy the data switch (m_column_mode) { case AbstractColumn::Numeric: { double* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[i] = other->valueAt(i); break; } case AbstractColumn::Integer: { int* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[i] = other->integerAt(i); break; } case AbstractColumn::Text: for (int i = 0; i < num_rows; ++i) static_cast*>(m_data)->replace(i, other->textAt(i)); break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: for (int i = 0; i < num_rows; ++i) static_cast*>(m_data)->replace(i, other->dateTimeAt(i)); break; } if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); return true; } /** * \brief Copies a part of another column of the same type * * This function will return false if the data type * of 'other' is not the same as the type of 'this'. * \param other pointer to the column to copy * \param src_start first row to copy in the column to copy * \param dest_start first row to copy in * \param num_rows the number of rows to copy */ bool ColumnPrivate::copy(const ColumnPrivate* source, int source_start, int dest_start, int num_rows) { if (source->columnMode() != m_column_mode) return false; if (num_rows == 0) return true; emit m_owner->dataAboutToChange(m_owner); if (dest_start + num_rows > rowCount()) resizeTo(dest_start + num_rows); // copy the data switch (m_column_mode) { case AbstractColumn::Numeric: { double* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[dest_start+i] = source->valueAt(source_start + i); break; } case AbstractColumn::Integer: { int* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[dest_start+i] = source->integerAt(source_start + i); break; } case AbstractColumn::Text: for (int i = 0; i < num_rows; ++i) static_cast*>(m_data)->replace(dest_start+i, source->textAt(source_start + i)); break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: for (int i = 0; i *>(m_data)->replace(dest_start+i, source->dateTimeAt(source_start + i)); break; } if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); return true; } /** * \brief Return the data vector size * * This returns the number of rows that actually contain data. * Rows beyond this can be masked etc. but should be ignored by filters, * plots etc. */ int ColumnPrivate::rowCount() const { switch (m_column_mode) { case AbstractColumn::Numeric: return static_cast*>(m_data)->size(); case AbstractColumn::Integer: return static_cast*>(m_data)->size(); case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: return static_cast*>(m_data)->size(); case AbstractColumn::Text: return static_cast*>(m_data)->size(); } return 0; } /** * \brief Resize the vector to the specified number of rows * * Since selecting and masking rows higher than the * real internal number of rows is supported, this * does not change the interval attributes. Also * no signal is emitted. If the new rows are filled * with values AbstractColumn::dataChanged() * must be emitted. */ void ColumnPrivate::resizeTo(int new_size) { int old_size = rowCount(); + if (new_size == old_size) + return; + DEBUG("ColumnPrivate::resizeTo() " << old_size << " -> " << new_size); - if (new_size == old_size) return; switch (m_column_mode) { case AbstractColumn::Numeric: { auto* numeric_data = static_cast*>(m_data); numeric_data->insert(numeric_data->end(), new_size - old_size, NAN); break; } case AbstractColumn::Integer: { auto* numeric_data = static_cast*>(m_data); numeric_data->insert(numeric_data->end(), new_size - old_size, 0); break; } case AbstractColumn::Text: { int new_rows = new_size - old_size; if (new_rows > 0) { for (int i = 0; i < new_rows; ++i) static_cast*>(m_data)->append(QString()); } else { for (int i = 0; i < -new_rows; ++i) static_cast*>(m_data)->removeLast(); } break; } case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: { int new_rows = new_size - old_size; if (new_rows > 0) { for (int i = 0; i < new_rows; ++i) static_cast*>(m_data)->append(QDateTime()); } else { for (int i = 0; i < -new_rows; ++i) static_cast*>(m_data)->removeLast(); } break; } } } /** * \brief Insert some empty (or initialized with zero) rows */ void ColumnPrivate::insertRows(int before, int count) { if (count == 0) return; m_formulas.insertRows(before, count); if (before <= rowCount()) { switch (m_column_mode) { case AbstractColumn::Numeric: static_cast*>(m_data)->insert(before, count, NAN); break; case AbstractColumn::Integer: static_cast*>(m_data)->insert(before, count, 0); break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: for (int i = 0; i < count; ++i) static_cast*>(m_data)->insert(before, QDateTime()); break; case AbstractColumn::Text: for (int i = 0; i < count; ++i) static_cast*>(m_data)->insert(before, QString()); break; } } } /** * \brief Remove 'count' rows starting from row 'first' */ void ColumnPrivate::removeRows(int first, int count) { if (count == 0) return; m_formulas.removeRows(first, count); if (first < rowCount()) { int corrected_count = count; if (first + count > rowCount()) corrected_count = rowCount() - first; switch (m_column_mode) { case AbstractColumn::Numeric: static_cast*>(m_data)->remove(first, corrected_count); break; case AbstractColumn::Integer: static_cast*>(m_data)->remove(first, corrected_count); break; case AbstractColumn::DateTime: case AbstractColumn::Month: case AbstractColumn::Day: for (int i = 0; i < corrected_count; ++i) static_cast*>(m_data)->removeAt(first); break; case AbstractColumn::Text: for (int i = 0; i < corrected_count; ++i) static_cast*>(m_data)->removeAt(first); break; } } } //! Return the column name QString ColumnPrivate::name() const { return m_owner->name(); } /** * \brief Return the column plot designation */ AbstractColumn::PlotDesignation ColumnPrivate::plotDesignation() const { return m_plot_designation; } /** * \brief Set the column plot designation */ void ColumnPrivate::setPlotDesignation(AbstractColumn::PlotDesignation pd) { emit m_owner->plotDesignationAboutToChange(m_owner); m_plot_designation = pd; emit m_owner->plotDesignationChanged(m_owner); } /** * \brief Get width */ int ColumnPrivate::width() const { return m_width; } /** * \brief Set width */ void ColumnPrivate::setWidth(int value) { m_width = value; } /** * \brief Return the data pointer */ void* ColumnPrivate::data() const { return m_data; } /** * \brief Return the input filter (for string -> data type conversion) */ AbstractSimpleFilter *ColumnPrivate::inputFilter() const { return m_input_filter; } /** * \brief Return the output filter (for data type -> string conversion) */ AbstractSimpleFilter *ColumnPrivate::outputFilter() const { return m_output_filter; } //////////////////////////////////////////////////////////////////////////////// //! \name Formula related functions //@{ //////////////////////////////////////////////////////////////////////////////// /** * \brief Return the formula last used to generate data for the column */ QString ColumnPrivate::formula() const { return m_formula; } bool ColumnPrivate::formulaAutoUpdate() const { return m_formulaAutoUpdate; } /** * \brief Sets the formula used to generate column values */ void ColumnPrivate::setFormula(const QString& formula, const QStringList& variableNames, const QVector& variableColumns, bool autoUpdate) { m_formula = formula; m_formulaVariableNames = variableNames; m_formulaVariableColumns = variableColumns; m_formulaAutoUpdate = autoUpdate; for (auto connection: m_connectionsUpdateFormula) disconnect(connection); m_formulaVariableColumnPaths.clear(); for (auto column : variableColumns) { m_formulaVariableColumnPaths << column->path(); if (autoUpdate) { m_connectionsUpdateFormula << connect(column, &Column::dataChanged, m_owner, &Column::updateFormula); connect(column->parentAspect(), &AbstractAspect::aspectAboutToBeRemoved, this, &ColumnPrivate::formulaVariableColumnRemoved); connect(column->parentAspect(), &AbstractAspect::aspectAdded, this, &ColumnPrivate::formulaVariableColumnAdded); } } } /*! * called after the import of the project was done and all columns were loaded in \sa Project::load() * to establish the required slot-signal connections for the formula update */ void ColumnPrivate::finalizeLoad() { if (m_formulaAutoUpdate) { for (auto column : m_formulaVariableColumns) { m_connectionsUpdateFormula << connect(column, &Column::dataChanged, m_owner, &Column::updateFormula); connect(column->parentAspect(), &AbstractAspect::aspectAboutToBeRemoved, this, &ColumnPrivate::formulaVariableColumnRemoved); connect(column->parentAspect(), &AbstractAspect::aspectAdded, this, &ColumnPrivate::formulaVariableColumnAdded); } } } /*! * helper function used in \c Column::load() to set parameters read from the xml file. * \param variableColumnPathes is used to restore the pointers to columns from pathes * after the project was loaded in Project::load(). */ void ColumnPrivate::setFormula(const QString& formula, const QStringList& variableNames, const QStringList& variableColumnPaths, bool autoUpdate) { m_formula = formula; m_formulaVariableNames = variableNames; m_formulaVariableColumnPaths = variableColumnPaths; m_formulaAutoUpdate = autoUpdate; } const QStringList& ColumnPrivate::formulaVariableNames() const { return m_formulaVariableNames; } const QVector& ColumnPrivate::formulaVariableColumns() const { return m_formulaVariableColumns; } const QStringList& ColumnPrivate::formulaVariableColumnPaths() const { return m_formulaVariableColumnPaths; } void ColumnPrivate::setformulVariableColumnsPath(int index, QString path) { m_formulaVariableColumnPaths[index] = path; } void ColumnPrivate::setformulVariableColumn(int index, Column* column) { m_formulaVariableColumns[index] = column; } /*! * \sa FunctionValuesDialog::generate() */ void ColumnPrivate::updateFormula() { //determine variable names and the data vectors of the specified columns QVector*> xVectors; QVector*> xNewVectors; int maxRowCount = 0; bool valid = true; for (auto column : m_formulaVariableColumns) { if (!column) { valid = false; break; } if (column->columnMode() == AbstractColumn::Integer) { //convert integers to doubles first auto* xVector = new QVector(column->rowCount()); for (int i = 0; irowCount(); ++i) xVector->operator[](i) = column->valueAt(i); xNewVectors << xVector; xVectors << xVector; } else xVectors << static_cast* >(column->data()); if (column->rowCount() > maxRowCount) maxRowCount = column->rowCount(); } if (valid) { //resize the spreadsheet if one of the data vectors from //other spreadsheet(s) has more elements than the parent spreadsheet Spreadsheet* spreadsheet = dynamic_cast(m_owner->parentAspect()); Q_ASSERT(spreadsheet); if (spreadsheet->rowCount() < maxRowCount) spreadsheet->setRowCount(maxRowCount); //create new vector for storing the calculated values //the vectors with the variable data can be smaller then the result vector. So, not all values in the result vector might get initialized. //->"clean" the result vector first QVector new_data(rowCount(), NAN); //evaluate the expression for f(x_1, x_2, ...) and write the calculated values into a new vector. ExpressionParser* parser = ExpressionParser::getInstance(); parser->evaluateCartesian(m_formula, m_formulaVariableNames, xVectors, &new_data); replaceValues(0, new_data); // initialize remaining rows with NAN int remainingRows = rowCount() - maxRowCount; if (remainingRows > 0) { QVector emptyRows(remainingRows, NAN); replaceValues(maxRowCount, emptyRows); } } else { QVector new_data(rowCount(), NAN); replaceValues(0, new_data); } //delete help vectors created for the conversion from int to double for (auto* vector : xNewVectors) delete vector; } void ColumnPrivate::formulaVariableColumnRemoved(const AbstractAspect* aspect) { const Column* column = dynamic_cast(aspect); //TODO: why is const_cast requried here?!? int index = m_formulaVariableColumns.indexOf(const_cast(column)); if (index != -1) { m_formulaVariableColumns[index] = nullptr; updateFormula(); } } void ColumnPrivate::formulaVariableColumnAdded(const AbstractAspect* aspect) { int index = m_formulaVariableColumnPaths.indexOf(aspect->path()); if (index != -1) { const Column* column = dynamic_cast(aspect); m_formulaVariableColumns[index] = const_cast(column); updateFormula(); } } /** * \brief Return the formula associated with row 'row' */ QString ColumnPrivate::formula(int row) const { return m_formulas.value(row); } /** * \brief Return the intervals that have associated formulas * * This can be used to make a list of formulas with their intervals. * Here is some example code: * * \code * QStringList list; * QVector< Interval > intervals = my_column.formulaIntervals(); * foreach(Interval interval, intervals) * list << QString(interval.toString() + ": " + my_column.formula(interval.start())); * \endcode */ QVector< Interval > ColumnPrivate::formulaIntervals() const { return m_formulas.intervals(); } /** * \brief Set a formula string for an interval of rows */ void ColumnPrivate::setFormula(Interval i, QString formula) { m_formulas.setValue(i, formula); } /** * \brief Overloaded function for convenience */ void ColumnPrivate::setFormula(int row, QString formula) { setFormula(Interval(row,row), formula); } /** * \brief Clear all formulas */ void ColumnPrivate::clearFormulas() { m_formulas.clear(); } //////////////////////////////////////////////////////////////////////////////// //@} //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// //! \name type specific functions //@{ //////////////////////////////////////////////////////////////////////////////// /** * \brief Return the content of row 'row'. * * Use this only when columnMode() is Text */ QString ColumnPrivate::textAt(int row) const { if (m_column_mode != AbstractColumn::Text) return QString(); return static_cast*>(m_data)->value(row); } /** * \brief Return the date part of row 'row' * * Use this only when columnMode() is DateTime, Month or Day */ QDate ColumnPrivate::dateAt(int row) const { if (m_column_mode != AbstractColumn::DateTime && m_column_mode != AbstractColumn::Month && m_column_mode != AbstractColumn::Day) return QDate{}; return dateTimeAt(row).date(); } /** * \brief Return the time part of row 'row' * * Use this only when columnMode() is DateTime, Month or Day */ QTime ColumnPrivate::timeAt(int row) const { if (m_column_mode != AbstractColumn::DateTime && m_column_mode != AbstractColumn::Month && m_column_mode != AbstractColumn::Day) return QTime{}; return dateTimeAt(row).time(); } /** * \brief Return the QDateTime in row 'row' * * Use this only when columnMode() is DateTime, Month or Day */ QDateTime ColumnPrivate::dateTimeAt(int row) const { if (m_column_mode != AbstractColumn::DateTime && m_column_mode != AbstractColumn::Month && m_column_mode != AbstractColumn::Day) return QDateTime(); return static_cast*>(m_data)->value(row); } /** * \brief Return the double value in row 'row' for columns with type Numeric and Integer. * This function has to be used everywhere where the exact type (double or int) is not relevant for numerical calculations. * For cases where the integer value is needed without any implicit conversions, \sa intergAt() has to be used. */ double ColumnPrivate::valueAt(int row) const { if (m_column_mode == AbstractColumn::Numeric) return static_cast*>(m_data)->value(row, NAN); else if (m_column_mode == AbstractColumn::Integer) return static_cast*>(m_data)->value(row, 0); else return NAN; } /** * \brief Return the int value in row 'row' */ int ColumnPrivate::integerAt(int row) const { if (m_column_mode != AbstractColumn::Integer) return 0; return static_cast*>(m_data)->value(row, 0); } /** * \brief Set the content of row 'row' * * Use this only when columnMode() is Text */ void ColumnPrivate::setTextAt(int row, const QString& new_value) { if (m_column_mode != AbstractColumn::Text) return; emit m_owner->dataAboutToChange(m_owner); if (row >= rowCount()) resizeTo(row+1); static_cast*>(m_data)->replace(row, new_value); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Replace a range of values * * Use this only when columnMode() is Text */ void ColumnPrivate::replaceTexts(int first, const QVector& new_values) { if (m_column_mode != AbstractColumn::Text) return; emit m_owner->dataAboutToChange(m_owner); int num_rows = new_values.size(); if (first + num_rows > rowCount()) resizeTo(first + num_rows); for (int i = 0; i < num_rows; ++i) static_cast*>(m_data)->replace(first+i, new_values.at(i)); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Set the content of row 'row' * * Use this only when columnMode() is DateTime, Month or Day */ void ColumnPrivate::setDateAt(int row, QDate new_value) { if (m_column_mode != AbstractColumn::DateTime && m_column_mode != AbstractColumn::Month && m_column_mode != AbstractColumn::Day) return; setDateTimeAt(row, QDateTime(new_value, timeAt(row))); } /** * \brief Set the content of row 'row' * * Use this only when columnMode() is DateTime, Month or Day */ void ColumnPrivate::setTimeAt(int row, QTime new_value) { if (m_column_mode != AbstractColumn::DateTime && m_column_mode != AbstractColumn::Month && m_column_mode != AbstractColumn::Day) return; setDateTimeAt(row, QDateTime(dateAt(row), new_value)); } /** * \brief Set the content of row 'row' * * Use this only when columnMode() is DateTime, Month or Day */ void ColumnPrivate::setDateTimeAt(int row, const QDateTime& new_value) { if (m_column_mode != AbstractColumn::DateTime && m_column_mode != AbstractColumn::Month && m_column_mode != AbstractColumn::Day) return; emit m_owner->dataAboutToChange(m_owner); if (row >= rowCount()) resizeTo(row+1); static_cast< QVector* >(m_data)->replace(row, new_value); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Replace a range of values * * Use this only when columnMode() is DateTime, Month or Day */ void ColumnPrivate::replaceDateTimes(int first, const QVector& new_values) { if (m_column_mode != AbstractColumn::DateTime && m_column_mode != AbstractColumn::Month && m_column_mode != AbstractColumn::Day) return; emit m_owner->dataAboutToChange(m_owner); int num_rows = new_values.size(); if (first + num_rows > rowCount()) resizeTo(first + num_rows); for (int i = 0; i < num_rows; ++i) static_cast*>(m_data)->replace(first+i, new_values.at(i)); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Set the content of row 'row' * * Use this only when columnMode() is Numeric */ void ColumnPrivate::setValueAt(int row, double new_value) { // DEBUG("ColumnPrivate::setValueAt()"); if (m_column_mode != AbstractColumn::Numeric) return; emit m_owner->dataAboutToChange(m_owner); if (row >= rowCount()) resizeTo(row+1); static_cast*>(m_data)->replace(row, new_value); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Replace a range of values * * Use this only when columnMode() is Numeric */ void ColumnPrivate::replaceValues(int first, const QVector& new_values) { DEBUG("ColumnPrivate::replaceValues()"); if (m_column_mode != AbstractColumn::Numeric) return; emit m_owner->dataAboutToChange(m_owner); int num_rows = new_values.size(); if (first + num_rows > rowCount()) resizeTo(first + num_rows); double* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[first+i] = new_values.at(i); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Set the content of row 'row' * * Use this only when columnMode() is Integer */ void ColumnPrivate::setIntegerAt(int row, int new_value) { DEBUG("ColumnPrivate::setIntegerAt()"); if (m_column_mode != AbstractColumn::Integer) return; emit m_owner->dataAboutToChange(m_owner); if (row >= rowCount()) resizeTo(row+1); static_cast*>(m_data)->replace(row, new_value); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /** * \brief Replace a range of values * * Use this only when columnMode() is Integer */ void ColumnPrivate::replaceInteger(int first, const QVector& new_values) { DEBUG("ColumnPrivate::replaceInteger()"); if (m_column_mode != AbstractColumn::Integer) return; emit m_owner->dataAboutToChange(m_owner); int num_rows = new_values.size(); if (first + num_rows > rowCount()) resizeTo(first + num_rows); int* ptr = static_cast*>(m_data)->data(); for (int i = 0; i < num_rows; ++i) ptr[first+i] = new_values.at(i); if (!m_owner->m_suppressDataChangedSignal) emit m_owner->dataChanged(m_owner); } /*! * Updates the properties. Will be called, when data in the column changed. * The properties will be used to speed up some algorithms. * See where variable properties will be used. */ void ColumnPrivate::updateProperties() { // TODO: for double Properties::Constant will never be used. Use an epsilon (difference smaller than epsilon is zero) if (rowCount() == 0) { properties = AbstractColumn::Properties::No; propertiesAvailable = true; return; } double prevValue = NAN; int prevValueInt = 0; qint64 prevValueDatetime = 0; if (m_column_mode == AbstractColumn::Integer) prevValueInt = integerAt(0); else if (m_column_mode == AbstractColumn::Numeric) prevValue = valueAt(0); else if (m_column_mode == AbstractColumn::DateTime || m_column_mode == AbstractColumn::Month || m_column_mode == AbstractColumn::Day) prevValueDatetime = dateTimeAt(0).toMSecsSinceEpoch(); else { properties = AbstractColumn::Properties::No; propertiesAvailable = true; return; } int monotonic_decreasing = -1; int monotonic_increasing = -1; double value; int valueInt; qint64 valueDateTime; for (int row = 1; row < rowCount(); row++) { if (m_column_mode == AbstractColumn::Integer) { valueInt = integerAt(row); // check monotonic increasing if (valueInt >= prevValueInt && monotonic_increasing < 0) monotonic_increasing = 1; else if (valueInt < prevValueInt && monotonic_increasing >= 0) monotonic_increasing = 0; // else: nothing // check monotonic decreasing if (valueInt <= prevValueInt && monotonic_decreasing < 0) monotonic_decreasing = 1; else if (valueInt > prevValueInt && monotonic_decreasing >= 0) monotonic_decreasing = 0; prevValueInt = valueInt; } else if (m_column_mode == AbstractColumn::Numeric) { value = valueAt(row); // check monotonic increasing if (value >= prevValue && monotonic_increasing < 0) monotonic_increasing = 1; else if (value < prevValue || std::isnan(value)) { monotonic_increasing = 0; if (monotonic_decreasing == 0) break; } // else: nothing // check monotonic decreasing if (value <= prevValue && monotonic_decreasing < 0) monotonic_decreasing = 1; else if (value > prevValue || std::isnan(value)) { monotonic_decreasing = 0; if (monotonic_increasing == 0) break; } prevValue = value; } else if (m_column_mode == AbstractColumn::DateTime || m_column_mode == AbstractColumn::Month || m_column_mode == AbstractColumn::Day) { valueDateTime = dateTimeAt(row).toMSecsSinceEpoch(); // check monotonic increasing if (valueDateTime >= prevValueDatetime && monotonic_increasing < 0) monotonic_increasing = 1; else if (valueDateTime < prevValueDatetime) monotonic_increasing = 0; // else: nothing // check monotonic decreasing if (valueDateTime <= prevValueDatetime && monotonic_decreasing < 0) monotonic_decreasing = 1; else if (valueDateTime > prevValueDatetime) monotonic_decreasing = 0; prevValueDatetime = valueDateTime; } } properties = AbstractColumn::Properties::No; if (monotonic_increasing > 0 && monotonic_decreasing > 0) properties = AbstractColumn::Properties::Constant; else if (monotonic_decreasing > 0) properties = AbstractColumn::Properties::MonotonicDecreasing; else if (monotonic_increasing > 0) properties = AbstractColumn::Properties::MonotonicIncreasing; propertiesAvailable = true; } //////////////////////////////////////////////////////////////////////////////// //@} //////////////////////////////////////////////////////////////////////////////// /** * \brief Return the interval attribute representing the formula strings */ IntervalAttribute ColumnPrivate::formulaAttribute() const { return m_formulas; } /** * \brief Replace the interval attribute for the formula strings */ void ColumnPrivate::replaceFormulas(const IntervalAttribute& formulas) { m_formulas = formulas; } diff --git a/src/backend/core/column/ColumnPrivate.h b/src/backend/core/column/ColumnPrivate.h index e2753af49..b042076a0 100644 --- a/src/backend/core/column/ColumnPrivate.h +++ b/src/backend/core/column/ColumnPrivate.h @@ -1,153 +1,153 @@ /*************************************************************************** File : ColumnPrivate.h Project : LabPlot Description : Private data class of Column -------------------------------------------------------------------- Copyright : (C) 2007,2008 Tilman Benkert (thzs@gmx.net) Copyright : (C) 2013-2019 Alexander Semke (alexander.semke@web.de) ***************************************************************************/ /*************************************************************************** * * * 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. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the Free Software * * Foundation, Inc., 51 Franklin Street, Fifth Floor, * * Boston, MA 02110-1301 USA * * * ***************************************************************************/ #ifndef COLUMNPRIVATE_H #define COLUMNPRIVATE_H #include "backend/core/AbstractColumn.h" #include "backend/lib/IntervalAttribute.h" class Column; class ColumnPrivate : public QObject { Q_OBJECT public: ColumnPrivate(Column*, AbstractColumn::ColumnMode); ~ColumnPrivate() override; ColumnPrivate(Column*, AbstractColumn::ColumnMode, void*); AbstractColumn::ColumnMode columnMode() const; void setColumnMode(AbstractColumn::ColumnMode); bool copy(const AbstractColumn*); bool copy(const AbstractColumn*, int source_start, int dest_start, int num_rows); bool copy(const ColumnPrivate*); bool copy(const ColumnPrivate*, int source_start, int dest_start, int num_rows); int rowCount() const; void resizeTo(int); void insertRows(int before, int count); void removeRows(int first, int count); QString name() const; AbstractColumn::PlotDesignation plotDesignation() const; void setPlotDesignation(AbstractColumn::PlotDesignation); int width() const; void setWidth(int); void* data() const; AbstractSimpleFilter* inputFilter() const; AbstractSimpleFilter* outputFilter() const; void replaceModeData(AbstractColumn::ColumnMode, void* data, AbstractSimpleFilter *in, AbstractSimpleFilter *out); void replaceData(void*); IntervalAttribute formulaAttribute() const; void replaceFormulas(const IntervalAttribute& formulas); //global formula defined for the whole column QString formula() const; const QStringList& formulaVariableNames() const; const QVector& formulaVariableColumns() const; const QStringList& formulaVariableColumnPaths() const; void setformulVariableColumnsPath(int index, QString path); void setformulVariableColumn(int index, Column *column); bool formulaAutoUpdate() const; void setFormula(const QString& formula, const QStringList& variableNames, const QVector& variableColumns, bool autoUpdate); void setFormula(const QString& formula, const QStringList& variableNames, const QStringList& variableColumnPaths, bool autoUpdate); void updateFormula(); //cell formulas QString formula(int row) const; QVector< Interval > formulaIntervals() const; void setFormula(Interval i, QString formula); void setFormula(int row, QString formula); void clearFormulas(); QString textAt(int row) const; void setTextAt(int row, const QString&); void replaceTexts(int first, const QVector&); QDate dateAt(int row) const; void setDateAt(int row, QDate); QTime timeAt(int row) const; void setTimeAt(int row, QTime); QDateTime dateTimeAt(int row) const; void setDateTimeAt(int row, const QDateTime&); void replaceDateTimes(int first, const QVector&); double valueAt(int row) const; void setValueAt(int row, double new_value); void replaceValues(int first, const QVector&); int integerAt(int row) const; void setIntegerAt(int row, int new_value); void replaceInteger(int first, const QVector&); void updateProperties(); void finalizeLoad(); mutable AbstractColumn::ColumnStatistics statistics; bool statisticsAvailable{false}; //is 'statistics' already available or needs to be (re-)calculated? bool hasValues{false}; bool hasValuesAvailable{false}; //is 'hasValues' already available or needs to be (re-)calculated? mutable bool propertiesAvailable{false}; //is 'properties' already available (true) or needs to be (re-)calculated (false)? mutable AbstractColumn::Properties properties{AbstractColumn::Properties::No}; // declares the properties of the curve (monotonic increasing/decreasing ...). Speed up algorithms private: AbstractColumn::ColumnMode m_column_mode; // type of column data - void* m_data; //pointer to the data container (QVector) - AbstractSimpleFilter* m_input_filter; //input filter for string -> data type conversion - AbstractSimpleFilter* m_output_filter; //output filter for data type -> string conversion + void* m_data{nullptr}; //pointer to the data container (QVector) + AbstractSimpleFilter* m_input_filter{nullptr}; //input filter for string -> data type conversion + AbstractSimpleFilter* m_output_filter{nullptr}; //output filter for data type -> string conversion QString m_formula; QStringList m_formulaVariableNames; QVector m_formulaVariableColumns; QStringList m_formulaVariableColumnPaths; bool m_formulaAutoUpdate{false}; IntervalAttribute m_formulas; AbstractColumn::PlotDesignation m_plot_designation{AbstractColumn::NoDesignation}; int m_width{0}; //column width in the view - Column* m_owner; + Column* m_owner{nullptr}; QVector m_connectionsUpdateFormula; private slots: void formulaVariableColumnRemoved(const AbstractAspect*); void formulaVariableColumnAdded(const AbstractAspect*); }; #endif diff --git a/src/backend/worksheet/plots/cartesian/CartesianPlot.cpp b/src/backend/worksheet/plots/cartesian/CartesianPlot.cpp index 4a69dc73c..70a8b24d6 100644 --- a/src/backend/worksheet/plots/cartesian/CartesianPlot.cpp +++ b/src/backend/worksheet/plots/cartesian/CartesianPlot.cpp @@ -1,3749 +1,3747 @@ /*************************************************************************** File : CartesianPlot.cpp Project : LabPlot Description : Cartesian plot -------------------------------------------------------------------- Copyright : (C) 2011-2018 by Alexander Semke (alexander.semke@web.de) Copyright : (C) 2016-2018 by Stefan Gerlach (stefan.gerlach@uni.kn) Copyright : (C) 2017-2018 by Garvit Khatri (garvitdelhi@gmail.com) ***************************************************************************/ /*************************************************************************** * * * 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. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the Free Software * * Foundation, Inc., 51 Franklin Street, Fifth Floor, * * Boston, MA 02110-1301 USA * * * ***************************************************************************/ #include "CartesianPlot.h" #include "CartesianPlotPrivate.h" #include "Axis.h" #include "XYCurve.h" #include "Histogram.h" #include "XYEquationCurve.h" #include "XYDataReductionCurve.h" #include "XYDifferentiationCurve.h" #include "XYIntegrationCurve.h" #include "XYInterpolationCurve.h" #include "XYSmoothCurve.h" #include "XYFitCurve.h" #include "XYFourierFilterCurve.h" #include "XYFourierTransformCurve.h" #include "XYConvolutionCurve.h" #include "XYCorrelationCurve.h" #include "backend/core/Project.h" #include "backend/core/datatypes/DateTime2StringFilter.h" #include "backend/spreadsheet/Spreadsheet.h" #include "backend/worksheet/plots/cartesian/CartesianPlotLegend.h" #include "backend/worksheet/plots/cartesian/CustomPoint.h" #include "backend/worksheet/plots/PlotArea.h" #include "backend/worksheet/plots/AbstractPlotPrivate.h" #include "backend/worksheet/Worksheet.h" #include "backend/worksheet/plots/cartesian/Axis.h" #include "backend/worksheet/TextLabel.h" #include "backend/lib/XmlStreamReader.h" #include "backend/lib/commandtemplates.h" #include "backend/lib/macros.h" #include "backend/lib/trace.h" #include "kdefrontend/spreadsheet/PlotDataDialog.h" //for PlotDataDialog::AnalysisAction. TODO: find a better place for this enum. #include "kdefrontend/ThemeHandler.h" #include "kdefrontend/widgets/ThemesWidget.h" #include #include #include #include #include #include #include #include #include #include #include /** * \class CartesianPlot * \brief A xy-plot. * * */ CartesianPlot::CartesianPlot(const QString &name) : AbstractPlot(name, new CartesianPlotPrivate(this), AspectType::CartesianPlot) { init(); } CartesianPlot::CartesianPlot(const QString &name, CartesianPlotPrivate *dd) : AbstractPlot(name, dd, AspectType::CartesianPlot) { init(); } CartesianPlot::~CartesianPlot() { if (m_menusInitialized) { delete addNewMenu; delete zoomMenu; delete themeMenu; } delete m_coordinateSystem; //don't need to delete objects added with addChild() //no need to delete the d-pointer here - it inherits from QGraphicsItem //and is deleted during the cleanup in QGraphicsScene } /*! initializes all member variables of \c CartesianPlot */ void CartesianPlot::init() { Q_D(CartesianPlot); d->cSystem = new CartesianCoordinateSystem(this); m_coordinateSystem = d->cSystem; d->rangeType = CartesianPlot::RangeFree; d->xRangeFormat = CartesianPlot::Numeric; d->yRangeFormat = CartesianPlot::Numeric; d->xRangeDateTimeFormat = "yyyy-MM-dd hh:mm:ss"; d->yRangeDateTimeFormat = "yyyy-MM-dd hh:mm:ss"; d->rangeFirstValues = 1000; d->rangeLastValues = 1000; d->autoScaleX = true; d->autoScaleY = true; d->xScale = ScaleLinear; d->yScale = ScaleLinear; d->xRangeBreakingEnabled = false; d->yRangeBreakingEnabled = false; //the following factor determines the size of the offset between the min/max points of the curves //and the coordinate system ranges, when doing auto scaling //Factor 0 corresponds to the exact match - min/max values of the curves correspond to the start/end values of the ranges. //TODO: make this factor optional. //Provide in the UI the possibility to choose between "exact" or 0% offset, 2%, 5% and 10% for the auto fit option d->autoScaleOffsetFactor = 0.0f; m_plotArea = new PlotArea(name() + " plot area"); addChildFast(m_plotArea); //Plot title m_title = new TextLabel(this->name() + QLatin1String("- ") + i18n("Title"), TextLabel::PlotTitle); addChild(m_title); m_title->setHidden(true); m_title->setParentGraphicsItem(m_plotArea->graphicsItem()); //offset between the plot area and the area defining the coordinate system, in scene units. d->horizontalPadding = Worksheet::convertToSceneUnits(1.5, Worksheet::Centimeter); d->verticalPadding = Worksheet::convertToSceneUnits(1.5, Worksheet::Centimeter); d->rightPadding = Worksheet::convertToSceneUnits(1.5, Worksheet::Centimeter); d->bottomPadding = Worksheet::convertToSceneUnits(1.5, Worksheet::Centimeter); d->symmetricPadding = true; connect(this, &AbstractAspect::aspectAdded, this, &CartesianPlot::childAdded); connect(this, &AbstractAspect::aspectRemoved, this, &CartesianPlot::childRemoved); connect(this, &AbstractAspect::deselected, this, &CartesianPlot::deselected); graphicsItem()->setFlag(QGraphicsItem::ItemIsMovable, true); graphicsItem()->setFlag(QGraphicsItem::ItemClipsChildrenToShape, true); graphicsItem()->setFlag(QGraphicsItem::ItemIsSelectable, true); graphicsItem()->setFlag(QGraphicsItem::ItemSendsGeometryChanges, true); graphicsItem()->setFlag(QGraphicsItem::ItemIsFocusable, true); //theme is not set at this point, initialize the color palette with default colors this->setColorPalette(KConfig()); } /*! initializes all children of \c CartesianPlot and setups a default plot of type \c type with a plot title. */ void CartesianPlot::initDefault(Type type) { Q_D(CartesianPlot); switch (type) { case FourAxes: { d->xMin = 0.0; d->xMax = 1.0; d->yMin = 0.0; d->yMax = 1.0; //Axes Axis* axis = new Axis("x axis 1", Axis::AxisHorizontal); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisBottom); axis->setStart(0); axis->setEnd(1); axis->setMajorTicksDirection(Axis::ticksIn); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksIn); axis->setMinorTicksNumber(1); QPen pen = axis->majorGridPen(); pen.setStyle(Qt::SolidLine); axis->setMajorGridPen(pen); pen = axis->minorGridPen(); pen.setStyle(Qt::DotLine); axis->setMinorGridPen(pen); axis->setSuppressRetransform(false); axis = new Axis("x axis 2", Axis::AxisHorizontal); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisTop); axis->setStart(0); axis->setEnd(1); axis->setMajorTicksDirection(Axis::ticksIn); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksIn); axis->setMinorTicksNumber(1); pen = axis->minorGridPen(); pen.setStyle(Qt::NoPen); axis->setMajorGridPen(pen); pen = axis->minorGridPen(); pen.setStyle(Qt::NoPen); axis->setMinorGridPen(pen); axis->setLabelsPosition(Axis::NoLabels); axis->title()->setText(QString()); axis->setSuppressRetransform(false); axis = new Axis("y axis 1", Axis::AxisVertical); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisLeft); axis->setStart(0); axis->setEnd(1); axis->setMajorTicksDirection(Axis::ticksIn); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksIn); axis->setMinorTicksNumber(1); pen = axis->majorGridPen(); pen.setStyle(Qt::SolidLine); axis->setMajorGridPen(pen); pen = axis->minorGridPen(); pen.setStyle(Qt::DotLine); axis->setMinorGridPen(pen); axis->setSuppressRetransform(false); axis = new Axis("y axis 2", Axis::AxisVertical); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisRight); axis->setStart(0); axis->setEnd(1); axis->setOffset(1); axis->setMajorTicksDirection(Axis::ticksIn); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksIn); axis->setMinorTicksNumber(1); pen = axis->minorGridPen(); pen.setStyle(Qt::NoPen); axis->setMajorGridPen(pen); pen = axis->minorGridPen(); pen.setStyle(Qt::NoPen); axis->setLabelsPosition(Axis::NoLabels); axis->title()->setText(QString()); axis->setSuppressRetransform(false); break; } case TwoAxes: { d->xMin = 0.0; d->xMax = 1.0; d->yMin = 0.0; d->yMax = 1.0; Axis* axis = new Axis("x axis 1", Axis::AxisHorizontal); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisBottom); axis->setStart(0); axis->setEnd(1); axis->setMajorTicksDirection(Axis::ticksBoth); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksBoth); axis->setMinorTicksNumber(1); axis->setArrowType(Axis::FilledArrowSmall); axis->setSuppressRetransform(false); axis = new Axis("y axis 1", Axis::AxisVertical); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisLeft); axis->setStart(0); axis->setEnd(1); axis->setMajorTicksDirection(Axis::ticksBoth); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksBoth); axis->setMinorTicksNumber(1); axis->setArrowType(Axis::FilledArrowSmall); axis->setSuppressRetransform(false); break; } case TwoAxesCentered: { d->xMin = -0.5; d->xMax = 0.5; d->yMin = -0.5; d->yMax = 0.5; d->horizontalPadding = Worksheet::convertToSceneUnits(1.0, Worksheet::Centimeter); d->verticalPadding = Worksheet::convertToSceneUnits(1.0, Worksheet::Centimeter); QPen pen = m_plotArea->borderPen(); pen.setStyle(Qt::NoPen); m_plotArea->setBorderPen(pen); Axis* axis = new Axis("x axis 1", Axis::AxisHorizontal); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisCentered); axis->setStart(-0.5); axis->setEnd(0.5); axis->setMajorTicksDirection(Axis::ticksBoth); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksBoth); axis->setMinorTicksNumber(1); axis->setArrowType(Axis::FilledArrowSmall); axis->title()->setText(QString()); axis->setSuppressRetransform(false); axis = new Axis("y axis 1", Axis::AxisVertical); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisCentered); axis->setStart(-0.5); axis->setEnd(0.5); axis->setMajorTicksDirection(Axis::ticksBoth); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksBoth); axis->setMinorTicksNumber(1); axis->setArrowType(Axis::FilledArrowSmall); axis->title()->setText(QString()); axis->setSuppressRetransform(false); break; } case TwoAxesCenteredZero: { d->xMin = -0.5; d->xMax = 0.5; d->yMin = -0.5; d->yMax = 0.5; d->horizontalPadding = Worksheet::convertToSceneUnits(1.0, Worksheet::Centimeter); d->verticalPadding = Worksheet::convertToSceneUnits(1.0, Worksheet::Centimeter); QPen pen = m_plotArea->borderPen(); pen.setStyle(Qt::NoPen); m_plotArea->setBorderPen(pen); Axis* axis = new Axis("x axis 1", Axis::AxisHorizontal); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisCustom); axis->setOffset(0); axis->setStart(-0.5); axis->setEnd(0.5); axis->setMajorTicksDirection(Axis::ticksBoth); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksBoth); axis->setMinorTicksNumber(1); axis->setArrowType(Axis::FilledArrowSmall); axis->title()->setText(QString()); axis->setSuppressRetransform(false); axis = new Axis("y axis 1", Axis::AxisVertical); axis->setSuppressRetransform(true); addChild(axis); axis->setPosition(Axis::AxisCustom); axis->setOffset(0); axis->setStart(-0.5); axis->setEnd(0.5); axis->setMajorTicksDirection(Axis::ticksBoth); axis->setMajorTicksNumber(6); axis->setMinorTicksDirection(Axis::ticksBoth); axis->setMinorTicksNumber(1); axis->setArrowType(Axis::FilledArrowSmall); axis->title()->setText(QString()); axis->setSuppressRetransform(false); break; } } d->xMinPrev = d->xMin; d->xMaxPrev = d->xMax; d->yMinPrev = d->yMin; d->yMaxPrev = d->yMax; //Geometry, specify the plot rect in scene coordinates. //TODO: Use default settings for left, top, width, height and for min/max for the coordinate system float x = Worksheet::convertToSceneUnits(2, Worksheet::Centimeter); float y = Worksheet::convertToSceneUnits(2, Worksheet::Centimeter); float w = Worksheet::convertToSceneUnits(10, Worksheet::Centimeter); float h = Worksheet::convertToSceneUnits(10, Worksheet::Centimeter); //all plot children are initialized -> set the geometry of the plot in scene coordinates. d->rect = QRectF(x,y,w,h); d->retransform(); } void CartesianPlot::initActions() { //"add new" actions addCurveAction = new QAction(QIcon::fromTheme("labplot-xy-curve"), i18n("xy-curve"), this); addHistogramAction = new QAction(QIcon::fromTheme("view-object-histogram-linear"), i18n("Histogram"), this); addEquationCurveAction = new QAction(QIcon::fromTheme("labplot-xy-equation-curve"), i18n("xy-curve from a mathematical Equation"), this); // no icons yet addDataReductionCurveAction = new QAction(i18n("xy-curve from a Data Reduction"), this); addDifferentiationCurveAction = new QAction(i18n("xy-curve from a Differentiation"), this); addIntegrationCurveAction = new QAction(i18n("xy-curve from an Integration"), this); addInterpolationCurveAction = new QAction(i18n("xy-curve from an Interpolation"), this); addSmoothCurveAction = new QAction(i18n("xy-curve from a Smooth"), this); addFitCurveAction = new QAction(QIcon::fromTheme("labplot-xy-fit-curve"), i18n("xy-curve from a Fit to Data"), this); addFourierFilterCurveAction = new QAction(i18n("xy-curve from a Fourier Filter"), this); addFourierTransformCurveAction = new QAction(i18n("xy-curve from a Fourier Transform"), this); addConvolutionCurveAction = new QAction(i18n("xy-curve from a (De-)Convolution"), this); addCorrelationCurveAction = new QAction(i18n("xy-curve from a Auto-/Cross-Correlation"), this); // addInterpolationCurveAction = new QAction(QIcon::fromTheme("labplot-xy-interpolation-curve"), i18n("xy-curve from an interpolation"), this); // addSmoothCurveAction = new QAction(QIcon::fromTheme("labplot-xy-smooth-curve"), i18n("xy-curve from a smooth"), this); // addFourierFilterCurveAction = new QAction(QIcon::fromTheme("labplot-xy-fourier_filter-curve"), i18n("xy-curve from a Fourier filter"), this); // addFourierTransformCurveAction = new QAction(QIcon::fromTheme("labplot-xy-fourier_transform-curve"), i18n("xy-curve from a Fourier transform"), this); // addConvolutionCurveAction = new QAction(QIcon::fromTheme("labplot-xy-convolution-curve"), i18n("xy-curve from a (de-)convolution"), this); // addCorrelationCurveAction = new QAction(QIcon::fromTheme("labplot-xy-correlation-curve"), i18n("xy-curve from a auto-/cross-correlation"), this); addLegendAction = new QAction(QIcon::fromTheme("text-field"), i18n("Legend"), this); if (children().size()>0) addLegendAction->setEnabled(false); //only one legend is allowed -> disable the action addHorizontalAxisAction = new QAction(QIcon::fromTheme("labplot-axis-horizontal"), i18n("Horizontal Axis"), this); addVerticalAxisAction = new QAction(QIcon::fromTheme("labplot-axis-vertical"), i18n("Vertical Axis"), this); addTextLabelAction = new QAction(QIcon::fromTheme("draw-text"), i18n("Text Label"), this); addCustomPointAction = new QAction(QIcon::fromTheme("draw-cross"), i18n("Custom Point"), this); connect(addCurveAction, &QAction::triggered, this, &CartesianPlot::addCurve); connect(addHistogramAction,&QAction::triggered, this, &CartesianPlot::addHistogram); connect(addEquationCurveAction, &QAction::triggered, this, &CartesianPlot::addEquationCurve); connect(addDataReductionCurveAction, &QAction::triggered, this, &CartesianPlot::addDataReductionCurve); connect(addDifferentiationCurveAction, &QAction::triggered, this, &CartesianPlot::addDifferentiationCurve); connect(addIntegrationCurveAction, &QAction::triggered, this, &CartesianPlot::addIntegrationCurve); connect(addInterpolationCurveAction, &QAction::triggered, this, &CartesianPlot::addInterpolationCurve); connect(addSmoothCurveAction, &QAction::triggered, this, &CartesianPlot::addSmoothCurve); connect(addFitCurveAction, &QAction::triggered, this, &CartesianPlot::addFitCurve); connect(addFourierFilterCurveAction, &QAction::triggered, this, &CartesianPlot::addFourierFilterCurve); connect(addFourierTransformCurveAction, &QAction::triggered, this, &CartesianPlot::addFourierTransformCurve); connect(addConvolutionCurveAction, &QAction::triggered, this, &CartesianPlot::addConvolutionCurve); connect(addCorrelationCurveAction, &QAction::triggered, this, &CartesianPlot::addCorrelationCurve); connect(addLegendAction, &QAction::triggered, this, static_cast(&CartesianPlot::addLegend)); connect(addHorizontalAxisAction, &QAction::triggered, this, &CartesianPlot::addHorizontalAxis); connect(addVerticalAxisAction, &QAction::triggered, this, &CartesianPlot::addVerticalAxis); connect(addTextLabelAction, &QAction::triggered, this, &CartesianPlot::addTextLabel); connect(addCustomPointAction, &QAction::triggered, this, &CartesianPlot::addCustomPoint); //Analysis menu actions addDataOperationAction = new QAction(i18n("Data Operation"), this); addDataReductionAction = new QAction(i18n("Reduce Data"), this); addDifferentiationAction = new QAction(i18n("Differentiate"), this); addIntegrationAction = new QAction(i18n("Integrate"), this); addInterpolationAction = new QAction(i18n("Interpolate"), this); addSmoothAction = new QAction(i18n("Smooth"), this); addConvolutionAction = new QAction(i18n("Convolute/Deconvolute"), this); addCorrelationAction = new QAction(i18n("Auto-/Cross-Correlation"), this); QAction* fitAction = new QAction(i18n("Linear"), this); fitAction->setData(PlotDataDialog::FitLinear); addFitAction.append(fitAction); fitAction = new QAction(i18n("Power"), this); fitAction->setData(PlotDataDialog::FitPower); addFitAction.append(fitAction); fitAction = new QAction(i18n("Exponential (degree 1)"), this); fitAction->setData(PlotDataDialog::FitExp1); addFitAction.append(fitAction); fitAction = new QAction(i18n("Exponential (degree 2)"), this); fitAction->setData(PlotDataDialog::FitExp2); addFitAction.append(fitAction); fitAction = new QAction(i18n("Inverse exponential"), this); fitAction->setData(PlotDataDialog::FitInvExp); addFitAction.append(fitAction); fitAction = new QAction(i18n("Gauss"), this); fitAction->setData(PlotDataDialog::FitGauss); addFitAction.append(fitAction); fitAction = new QAction(i18n("Cauchy-Lorentz"), this); fitAction->setData(PlotDataDialog::FitCauchyLorentz); addFitAction.append(fitAction); fitAction = new QAction(i18n("Arc Tangent"), this); fitAction->setData(PlotDataDialog::FitTan); addFitAction.append(fitAction); fitAction = new QAction(i18n("Hyperbolic Tangent"), this); fitAction->setData(PlotDataDialog::FitTanh); addFitAction.append(fitAction); fitAction = new QAction(i18n("Error Function"), this); fitAction->setData(PlotDataDialog::FitErrFunc); addFitAction.append(fitAction); fitAction = new QAction(i18n("Custom"), this); fitAction->setData(PlotDataDialog::FitCustom); addFitAction.append(fitAction); addFourierFilterAction = new QAction(i18n("Fourier Filter"), this); connect(addDataReductionAction, &QAction::triggered, this, &CartesianPlot::addDataReductionCurve); connect(addDifferentiationAction, &QAction::triggered, this, &CartesianPlot::addDifferentiationCurve); connect(addIntegrationAction, &QAction::triggered, this, &CartesianPlot::addIntegrationCurve); connect(addInterpolationAction, &QAction::triggered, this, &CartesianPlot::addInterpolationCurve); connect(addSmoothAction, &QAction::triggered, this, &CartesianPlot::addSmoothCurve); connect(addConvolutionAction, &QAction::triggered, this, &CartesianPlot::addConvolutionCurve); connect(addCorrelationAction, &QAction::triggered, this, &CartesianPlot::addCorrelationCurve); for (const auto& action : addFitAction) connect(action, &QAction::triggered, this, &CartesianPlot::addFitCurve); connect(addFourierFilterAction, &QAction::triggered, this, &CartesianPlot::addFourierFilterCurve); //zoom/navigate actions scaleAutoAction = new QAction(QIcon::fromTheme("labplot-auto-scale-all"), i18n("Auto Scale"), this); scaleAutoXAction = new QAction(QIcon::fromTheme("labplot-auto-scale-x"), i18n("Auto Scale X"), this); scaleAutoYAction = new QAction(QIcon::fromTheme("labplot-auto-scale-y"), i18n("Auto Scale Y"), this); zoomInAction = new QAction(QIcon::fromTheme("zoom-in"), i18n("Zoom In"), this); zoomOutAction = new QAction(QIcon::fromTheme("zoom-out"), i18n("Zoom Out"), this); zoomInXAction = new QAction(QIcon::fromTheme("labplot-zoom-in-x"), i18n("Zoom In X"), this); zoomOutXAction = new QAction(QIcon::fromTheme("labplot-zoom-out-x"), i18n("Zoom Out X"), this); zoomInYAction = new QAction(QIcon::fromTheme("labplot-zoom-in-y"), i18n("Zoom In Y"), this); zoomOutYAction = new QAction(QIcon::fromTheme("labplot-zoom-out-y"), i18n("Zoom Out Y"), this); shiftLeftXAction = new QAction(QIcon::fromTheme("labplot-shift-left-x"), i18n("Shift Left X"), this); shiftRightXAction = new QAction(QIcon::fromTheme("labplot-shift-right-x"), i18n("Shift Right X"), this); shiftUpYAction = new QAction(QIcon::fromTheme("labplot-shift-up-y"), i18n("Shift Up Y"), this); shiftDownYAction = new QAction(QIcon::fromTheme("labplot-shift-down-y"), i18n("Shift Down Y"), this); cursorAction = new QAction(QIcon::fromTheme("labplot-shift-down-y"), i18n("Cursor"), this); // TODO: change icon connect(scaleAutoAction, &QAction::triggered, this, &CartesianPlot::scaleAuto); connect(scaleAutoXAction, &QAction::triggered, this, &CartesianPlot::scaleAutoX); connect(scaleAutoYAction, &QAction::triggered, this, &CartesianPlot::scaleAutoY); connect(zoomInAction, &QAction::triggered, this, &CartesianPlot::zoomIn); connect(zoomOutAction, &QAction::triggered, this, &CartesianPlot::zoomOut); connect(zoomInXAction, &QAction::triggered, this, &CartesianPlot::zoomInX); connect(zoomOutXAction, &QAction::triggered, this, &CartesianPlot::zoomOutX); connect(zoomInYAction, &QAction::triggered, this, &CartesianPlot::zoomInY); connect(zoomOutYAction, &QAction::triggered, this, &CartesianPlot::zoomOutY); connect(shiftLeftXAction, &QAction::triggered, this, &CartesianPlot::shiftLeftX); connect(shiftRightXAction, &QAction::triggered, this, &CartesianPlot::shiftRightX); connect(shiftUpYAction, &QAction::triggered, this, &CartesianPlot::shiftUpY); connect(shiftDownYAction, &QAction::triggered, this, &CartesianPlot::shiftDownY); connect(cursorAction, &QAction::triggered, this, &CartesianPlot::cursor); //visibility action visibilityAction = new QAction(QIcon::fromTheme("view-visible"), i18n("Visible"), this); visibilityAction->setCheckable(true); connect(visibilityAction, &QAction::triggered, this, &CartesianPlot::visibilityChanged); } void CartesianPlot::initMenus() { initActions(); addNewMenu = new QMenu(i18n("Add New")); addNewMenu->setIcon(QIcon::fromTheme("list-add")); addNewMenu->addAction(addCurveAction); addNewMenu->addAction(addHistogramAction); addNewMenu->addAction(addEquationCurveAction); addNewMenu->addSeparator(); addNewMenu->addAction(addDataReductionCurveAction); addNewMenu->addAction(addDifferentiationCurveAction); addNewMenu->addAction(addIntegrationCurveAction); addNewMenu->addAction(addInterpolationCurveAction); addNewMenu->addAction(addSmoothCurveAction); addNewMenu->addAction(addFitCurveAction); addNewMenu->addAction(addFourierFilterCurveAction); addNewMenu->addAction(addFourierTransformCurveAction); addNewMenu->addAction(addConvolutionCurveAction); addNewMenu->addAction(addCorrelationCurveAction); addNewMenu->addSeparator(); addNewMenu->addAction(addLegendAction); addNewMenu->addSeparator(); addNewMenu->addAction(addHorizontalAxisAction); addNewMenu->addAction(addVerticalAxisAction); addNewMenu->addSeparator(); addNewMenu->addAction(addTextLabelAction); addNewMenu->addSeparator(); addNewMenu->addAction(addCustomPointAction); zoomMenu = new QMenu(i18n("Zoom")); zoomMenu->setIcon(QIcon::fromTheme("zoom-draw")); zoomMenu->addAction(scaleAutoAction); zoomMenu->addAction(scaleAutoXAction); zoomMenu->addAction(scaleAutoYAction); zoomMenu->addSeparator(); zoomMenu->addAction(zoomInAction); zoomMenu->addAction(zoomOutAction); zoomMenu->addSeparator(); zoomMenu->addAction(zoomInXAction); zoomMenu->addAction(zoomOutXAction); zoomMenu->addSeparator(); zoomMenu->addAction(zoomInYAction); zoomMenu->addAction(zoomOutYAction); zoomMenu->addSeparator(); zoomMenu->addAction(shiftLeftXAction); zoomMenu->addAction(shiftRightXAction); zoomMenu->addSeparator(); zoomMenu->addAction(shiftUpYAction); zoomMenu->addAction(shiftDownYAction); // Data manipulation menu QMenu* dataManipulationMenu = new QMenu(i18n("Data Manipulation")); dataManipulationMenu->setIcon(QIcon::fromTheme("zoom-draw")); dataManipulationMenu->addAction(addDataOperationAction); dataManipulationMenu->addAction(addDataReductionAction); // Data fit menu QMenu* dataFitMenu = new QMenu(i18n("Fit")); dataFitMenu->setIcon(QIcon::fromTheme("labplot-xy-fit-curve")); dataFitMenu->addAction(addFitAction.at(0)); dataFitMenu->addAction(addFitAction.at(1)); dataFitMenu->addAction(addFitAction.at(2)); dataFitMenu->addAction(addFitAction.at(3)); dataFitMenu->addAction(addFitAction.at(4)); dataFitMenu->addSeparator(); dataFitMenu->addAction(addFitAction.at(5)); dataFitMenu->addAction(addFitAction.at(6)); dataFitMenu->addSeparator(); dataFitMenu->addAction(addFitAction.at(7)); dataFitMenu->addAction(addFitAction.at(8)); dataFitMenu->addAction(addFitAction.at(9)); dataFitMenu->addSeparator(); dataFitMenu->addAction(addFitAction.at(10)); //analysis menu dataAnalysisMenu = new QMenu(i18n("Analysis")); dataAnalysisMenu->insertMenu(nullptr, dataManipulationMenu); dataAnalysisMenu->addSeparator(); dataAnalysisMenu->addAction(addDifferentiationAction); dataAnalysisMenu->addAction(addIntegrationAction); dataAnalysisMenu->addSeparator(); dataAnalysisMenu->addAction(addInterpolationAction); dataAnalysisMenu->addAction(addSmoothAction); dataAnalysisMenu->addAction(addFourierFilterAction); dataAnalysisMenu->addAction(addConvolutionAction); dataAnalysisMenu->addAction(addCorrelationAction); dataAnalysisMenu->addSeparator(); dataAnalysisMenu->addMenu(dataFitMenu); //themes menu themeMenu = new QMenu(i18n("Apply Theme")); themeMenu->setIcon(QIcon::fromTheme("color-management")); auto* themeWidget = new ThemesWidget(nullptr); connect(themeWidget, &ThemesWidget::themeSelected, this, &CartesianPlot::loadTheme); connect(themeWidget, &ThemesWidget::themeSelected, themeMenu, &QMenu::close); auto* widgetAction = new QWidgetAction(this); widgetAction->setDefaultWidget(themeWidget); themeMenu->addAction(widgetAction); m_menusInitialized = true; } QMenu* CartesianPlot::createContextMenu() { if (!m_menusInitialized) initMenus(); QMenu* menu = WorksheetElement::createContextMenu(); QAction* firstAction = menu->actions().at(1); visibilityAction->setChecked(isVisible()); menu->insertAction(firstAction, visibilityAction); menu->insertMenu(firstAction, addNewMenu); menu->insertMenu(firstAction, zoomMenu); menu->insertSeparator(firstAction); menu->insertMenu(firstAction, themeMenu); menu->insertSeparator(firstAction); return menu; } QMenu* CartesianPlot::analysisMenu() { if (!m_menusInitialized) initMenus(); return dataAnalysisMenu; } /*! Returns an icon to be used in the project explorer. */ QIcon CartesianPlot::icon() const { return QIcon::fromTheme("office-chart-line"); } QVector CartesianPlot::dependsOn() const { //aspects which the plotted data in the worksheet depends on (spreadsheets and later matrices) QVector aspects; for (const auto* curve : children()) { if (curve->xColumn() && dynamic_cast(curve->xColumn()->parentAspect()) ) aspects << curve->xColumn()->parentAspect(); if (curve->yColumn() && dynamic_cast(curve->yColumn()->parentAspect()) ) aspects << curve->yColumn()->parentAspect(); } return aspects; } void CartesianPlot::navigate(CartesianPlot::NavigationOperation op) { if (op == ScaleAuto) scaleAuto(); else if (op == ScaleAutoX) scaleAutoX(); else if (op == ScaleAutoY) scaleAutoY(); else if (op == ZoomIn) zoomIn(); else if (op == ZoomOut) zoomOut(); else if (op == ZoomInX) zoomInX(); else if (op == ZoomOutX) zoomOutX(); else if (op == ZoomInY) zoomInY(); else if (op == ZoomOutY) zoomOutY(); else if (op == ShiftLeftX) shiftLeftX(); else if (op == ShiftRightX) shiftRightX(); else if (op == ShiftUpY) shiftUpY(); else if (op == ShiftDownY) shiftDownY(); } void CartesianPlot::setSuppressDataChangedSignal(bool value) { Q_D(CartesianPlot); d->suppressRetransform = value; } void CartesianPlot::processDropEvent(QDropEvent* event) { PERFTRACE("CartesianPlot::processDropEvent"); const QMimeData* mimeData = event->mimeData(); if (!mimeData) return; //deserialize the mime data to the vector of aspect pointers QByteArray data = mimeData->data(QLatin1String("labplot-dnd")); QVector vec; QDataStream stream(&data, QIODevice::ReadOnly); stream >> vec; QVector columns; for (auto a : vec) { auto* aspect = (AbstractAspect*)a; auto* column = dynamic_cast(aspect); if (column) columns << column; } //return if there are no columns being dropped. //TODO: extend this later when we allow to drag&drop plots, etc. if (columns.isEmpty()) return; //determine the first column with "x plot designation" as the x-data column for all curves to be created const AbstractColumn* xColumn = nullptr; for (const auto* column : columns) { if (column->plotDesignation() == AbstractColumn::X) { xColumn = column; break; } } //if no column with "x plot designation" is available, use the x-data column of the first curve in the plot, if (xColumn == nullptr) { QVector curves = children(); if (!curves.isEmpty()) xColumn = curves.at(0)->xColumn(); } //use the first dropped column if no column with "x plot designation" nor curves are available if (xColumn == nullptr) xColumn = columns.at(0); //create curves bool curvesAdded = false; for (const auto* column : columns) { if (column == xColumn) continue; XYCurve* curve = new XYCurve(column->name()); curve->suppressRetransform(true); //suppress retransform, all curved will be recalculated at the end curve->setXColumn(xColumn); curve->setYColumn(column); addChild(curve); curve->suppressRetransform(false); curvesAdded = true; } if (curvesAdded) dataChanged(); } bool CartesianPlot::isPanningActive() const { Q_D(const CartesianPlot); return d->panningStarted; } //############################################################################## //################################ getter methods ############################ //############################################################################## BASIC_SHARED_D_READER_IMPL(CartesianPlot, CartesianPlot::RangeType, rangeType, rangeType) BASIC_SHARED_D_READER_IMPL(CartesianPlot, CartesianPlot::RangeFormat, xRangeFormat, xRangeFormat) BASIC_SHARED_D_READER_IMPL(CartesianPlot, CartesianPlot::RangeFormat, yRangeFormat, yRangeFormat) BASIC_SHARED_D_READER_IMPL(CartesianPlot, int, rangeLastValues, rangeLastValues) BASIC_SHARED_D_READER_IMPL(CartesianPlot, int, rangeFirstValues, rangeFirstValues) BASIC_SHARED_D_READER_IMPL(CartesianPlot, bool, autoScaleX, autoScaleX) BASIC_SHARED_D_READER_IMPL(CartesianPlot, double, xMin, xMin) BASIC_SHARED_D_READER_IMPL(CartesianPlot, double, xMax, xMax) BASIC_SHARED_D_READER_IMPL(CartesianPlot, CartesianPlot::Scale, xScale, xScale) BASIC_SHARED_D_READER_IMPL(CartesianPlot, bool, xRangeBreakingEnabled, xRangeBreakingEnabled) CLASS_SHARED_D_READER_IMPL(CartesianPlot, CartesianPlot::RangeBreaks, xRangeBreaks, xRangeBreaks) BASIC_SHARED_D_READER_IMPL(CartesianPlot, bool, autoScaleY, autoScaleY) BASIC_SHARED_D_READER_IMPL(CartesianPlot, double, yMin, yMin) BASIC_SHARED_D_READER_IMPL(CartesianPlot, double, yMax, yMax) BASIC_SHARED_D_READER_IMPL(CartesianPlot, CartesianPlot::Scale, yScale, yScale) BASIC_SHARED_D_READER_IMPL(CartesianPlot, bool, yRangeBreakingEnabled, yRangeBreakingEnabled) CLASS_SHARED_D_READER_IMPL(CartesianPlot, CartesianPlot::RangeBreaks, yRangeBreaks, yRangeBreaks) CLASS_SHARED_D_READER_IMPL(CartesianPlot, QPen, cursorPen, cursorPen); CLASS_SHARED_D_READER_IMPL(CartesianPlot, bool, cursor0Enable, cursor0Enable); CLASS_SHARED_D_READER_IMPL(CartesianPlot, bool, cursor1Enable, cursor1Enable); CLASS_SHARED_D_READER_IMPL(CartesianPlot, QString, theme, theme) /*! returns the actual bounding rectangular of the plot area showing data (plot's rectangular minus padding) in plot's coordinates */ QRectF CartesianPlot::dataRect() const { Q_D(const CartesianPlot); return d->dataRect; } CartesianPlot::MouseMode CartesianPlot::mouseMode() const { Q_D(const CartesianPlot); return d->mouseMode; } const QString& CartesianPlot::xRangeDateTimeFormat() const { Q_D(const CartesianPlot); return d->xRangeDateTimeFormat; } const QString& CartesianPlot::yRangeDateTimeFormat() const { Q_D(const CartesianPlot); return d->yRangeDateTimeFormat; } //############################################################################## //###################### setter methods and undo commands #################### //############################################################################## /*! set the rectangular, defined in scene coordinates */ class CartesianPlotSetRectCmd : public QUndoCommand { public: CartesianPlotSetRectCmd(CartesianPlotPrivate* private_obj, QRectF rect) : m_private(private_obj), m_rect(rect) { setText(i18n("%1: change geometry rect", m_private->name())); }; void redo() override { // const double horizontalRatio = m_rect.width() / m_private->rect.width(); // const double verticalRatio = m_rect.height() / m_private->rect.height(); qSwap(m_private->rect, m_rect); // m_private->q->handleResize(horizontalRatio, verticalRatio, false); m_private->retransform(); emit m_private->q->rectChanged(m_private->rect); }; void undo() override { redo(); } private: CartesianPlotPrivate* m_private; QRectF m_rect; }; void CartesianPlot::setRect(const QRectF& rect) { Q_D(CartesianPlot); if (rect != d->rect) exec(new CartesianPlotSetRectCmd(d, rect)); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetRangeType, CartesianPlot::RangeType, rangeType, rangeChanged); void CartesianPlot::setRangeType(RangeType type) { Q_D(CartesianPlot); if (type != d->rangeType) exec(new CartesianPlotSetRangeTypeCmd(d, type, ki18n("%1: set range type"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetXRangeFormat, CartesianPlot::RangeFormat, xRangeFormat, xRangeFormatChanged); void CartesianPlot::setXRangeFormat(RangeFormat format) { Q_D(CartesianPlot); if (format != d->xRangeFormat) exec(new CartesianPlotSetXRangeFormatCmd(d, format, ki18n("%1: set x-range format"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetYRangeFormat, CartesianPlot::RangeFormat, yRangeFormat, yRangeFormatChanged); void CartesianPlot::setYRangeFormat(RangeFormat format) { Q_D(CartesianPlot); if (format != d->yRangeFormat) exec(new CartesianPlotSetYRangeFormatCmd(d, format, ki18n("%1: set y-range format"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetRangeLastValues, int, rangeLastValues, rangeChanged); void CartesianPlot::setRangeLastValues(int values) { Q_D(CartesianPlot); if (values != d->rangeLastValues) exec(new CartesianPlotSetRangeLastValuesCmd(d, values, ki18n("%1: set range"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetRangeFirstValues, int, rangeFirstValues, rangeChanged); void CartesianPlot::setRangeFirstValues(int values) { Q_D(CartesianPlot); if (values != d->rangeFirstValues) exec(new CartesianPlotSetRangeFirstValuesCmd(d, values, ki18n("%1: set range"))); } class CartesianPlotSetAutoScaleXCmd : public QUndoCommand { public: CartesianPlotSetAutoScaleXCmd(CartesianPlotPrivate* private_obj, bool autoScale) : m_private(private_obj), m_autoScale(autoScale), m_autoScaleOld(false), m_minOld(0.0), m_maxOld(0.0) { setText(i18n("%1: change x-range auto scaling", m_private->name())); }; void redo() override { m_autoScaleOld = m_private->autoScaleX; if (m_autoScale) { m_minOld = m_private->xMin; m_maxOld = m_private->xMax; m_private->q->scaleAutoX(); } m_private->autoScaleX = m_autoScale; emit m_private->q->xAutoScaleChanged(m_autoScale); }; void undo() override { if (!m_autoScaleOld) { m_private->xMin = m_minOld; m_private->xMax = m_maxOld; m_private->retransformScales(); } m_private->autoScaleX = m_autoScaleOld; emit m_private->q->xAutoScaleChanged(m_autoScaleOld); } private: CartesianPlotPrivate* m_private; bool m_autoScale; bool m_autoScaleOld; double m_minOld; double m_maxOld; }; void CartesianPlot::setAutoScaleX(bool autoScaleX) { Q_D(CartesianPlot); if (autoScaleX != d->autoScaleX) exec(new CartesianPlotSetAutoScaleXCmd(d, autoScaleX)); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetXMin, double, xMin, retransformScales) void CartesianPlot::setXMin(double xMin) { Q_D(CartesianPlot); if (xMin != d->xMin && xMin != -INFINITY && xMin != INFINITY) exec(new CartesianPlotSetXMinCmd(d, xMin, ki18n("%1: set min x"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetXMax, double, xMax, retransformScales) void CartesianPlot::setXMax(double xMax) { Q_D(CartesianPlot); if (xMax != d->xMax && xMax != -INFINITY && xMax != INFINITY) exec(new CartesianPlotSetXMaxCmd(d, xMax, ki18n("%1: set max x"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetXScale, CartesianPlot::Scale, xScale, retransformScales) void CartesianPlot::setXScale(Scale scale) { Q_D(CartesianPlot); if (scale != d->xScale) exec(new CartesianPlotSetXScaleCmd(d, scale, ki18n("%1: set x scale"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetXRangeBreakingEnabled, bool, xRangeBreakingEnabled, retransformScales) void CartesianPlot::setXRangeBreakingEnabled(bool enabled) { Q_D(CartesianPlot); if (enabled != d->xRangeBreakingEnabled) exec(new CartesianPlotSetXRangeBreakingEnabledCmd(d, enabled, ki18n("%1: x-range breaking enabled"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetXRangeBreaks, CartesianPlot::RangeBreaks, xRangeBreaks, retransformScales) void CartesianPlot::setXRangeBreaks(const RangeBreaks& breakings) { Q_D(CartesianPlot); exec(new CartesianPlotSetXRangeBreaksCmd(d, breakings, ki18n("%1: x-range breaks changed"))); } class CartesianPlotSetAutoScaleYCmd : public QUndoCommand { public: CartesianPlotSetAutoScaleYCmd(CartesianPlotPrivate* private_obj, bool autoScale) : m_private(private_obj), m_autoScale(autoScale), m_autoScaleOld(false), m_minOld(0.0), m_maxOld(0.0) { setText(i18n("%1: change y-range auto scaling", m_private->name())); }; void redo() override { m_autoScaleOld = m_private->autoScaleY; if (m_autoScale) { m_minOld = m_private->yMin; m_maxOld = m_private->yMax; m_private->q->scaleAutoY(); } m_private->autoScaleY = m_autoScale; emit m_private->q->yAutoScaleChanged(m_autoScale); }; void undo() override { if (!m_autoScaleOld) { m_private->yMin = m_minOld; m_private->yMax = m_maxOld; m_private->retransformScales(); } m_private->autoScaleY = m_autoScaleOld; emit m_private->q->yAutoScaleChanged(m_autoScaleOld); } private: CartesianPlotPrivate* m_private; bool m_autoScale; bool m_autoScaleOld; double m_minOld; double m_maxOld; }; void CartesianPlot::setAutoScaleY(bool autoScaleY) { Q_D(CartesianPlot); if (autoScaleY != d->autoScaleY) exec(new CartesianPlotSetAutoScaleYCmd(d, autoScaleY)); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetYMin, double, yMin, retransformScales) void CartesianPlot::setYMin(double yMin) { Q_D(CartesianPlot); if (yMin != d->yMin) exec(new CartesianPlotSetYMinCmd(d, yMin, ki18n("%1: set min y"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetYMax, double, yMax, retransformScales) void CartesianPlot::setYMax(double yMax) { Q_D(CartesianPlot); if (yMax != d->yMax) exec(new CartesianPlotSetYMaxCmd(d, yMax, ki18n("%1: set max y"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetYScale, CartesianPlot::Scale, yScale, retransformScales) void CartesianPlot::setYScale(Scale scale) { Q_D(CartesianPlot); if (scale != d->yScale) exec(new CartesianPlotSetYScaleCmd(d, scale, ki18n("%1: set y scale"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetYRangeBreakingEnabled, bool, yRangeBreakingEnabled, retransformScales) void CartesianPlot::setYRangeBreakingEnabled(bool enabled) { Q_D(CartesianPlot); if (enabled != d->yRangeBreakingEnabled) exec(new CartesianPlotSetYRangeBreakingEnabledCmd(d, enabled, ki18n("%1: y-range breaking enabled"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetYRangeBreaks, CartesianPlot::RangeBreaks, yRangeBreaks, retransformScales) void CartesianPlot::setYRangeBreaks(const RangeBreaks& breaks) { Q_D(CartesianPlot); exec(new CartesianPlotSetYRangeBreaksCmd(d, breaks, ki18n("%1: y-range breaks changed"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetCursorPen, QPen, cursorPen, update) void CartesianPlot::setCursorPen(const QPen &pen) { Q_D(CartesianPlot); if (pen != d->cursorPen) exec(new CartesianPlotSetCursorPenCmd(d, pen, ki18n("%1: y-range breaks changed"))); } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetCursor0Enable, bool, cursor0Enable, updateCursor) void CartesianPlot::setCursor0Enable(const bool &enable) { Q_D(CartesianPlot); if (enable != d->cursor0Enable) { if (std::isnan(d->cursor0Pos.x())) { // if never set, set initial position d->cursor0Pos.setX(d->cSystem->mapSceneToLogical(QPointF(0,0)).x()); mousePressCursorModeSignal(0, d->cursor0Pos); // simulate mousePress to update values in the cursor dock } exec(new CartesianPlotSetCursor0EnableCmd(d, enable, ki18n("%1: Cursor0 enable"))); } } STD_SETTER_CMD_IMPL_F_S(CartesianPlot, SetCursor1Enable, bool, cursor1Enable, updateCursor) void CartesianPlot::setCursor1Enable(const bool &enable) { Q_D(CartesianPlot); if (enable != d->cursor1Enable) { if (std::isnan(d->cursor1Pos.x())) { // if never set, set initial position d->cursor1Pos.setX(d->cSystem->mapSceneToLogical(QPointF(0,0)).x()); mousePressCursorModeSignal(1, d->cursor0Pos); // simulate mousePress to update values in the cursor dock } exec(new CartesianPlotSetCursor1EnableCmd(d, enable, ki18n("%1: Cursor1 enable"))); } } STD_SETTER_CMD_IMPL_S(CartesianPlot, SetTheme, QString, theme) void CartesianPlot::setTheme(const QString& theme) { Q_D(CartesianPlot); if (theme != d->theme) { if (!theme.isEmpty()) { beginMacro( i18n("%1: load theme %2", name(), theme) ); exec(new CartesianPlotSetThemeCmd(d, theme, ki18n("%1: set theme"))); loadTheme(theme); endMacro(); } else exec(new CartesianPlotSetThemeCmd(d, theme, ki18n("%1: disable theming"))); } } //################################################################ //########################## Slots ############################### //################################################################ void CartesianPlot::addHorizontalAxis() { Axis* axis = new Axis("x-axis", Axis::AxisHorizontal); if (axis->autoScale()) { axis->setUndoAware(false); axis->setStart(xMin()); axis->setEnd(xMax()); axis->setUndoAware(true); } addChild(axis); } void CartesianPlot::addVerticalAxis() { Axis* axis = new Axis("y-axis", Axis::AxisVertical); if (axis->autoScale()) { axis->setUndoAware(false); axis->setStart(yMin()); axis->setEnd(yMax()); axis->setUndoAware(true); } addChild(axis); } void CartesianPlot::addCurve() { addChild(new XYCurve("xy-curve")); } void CartesianPlot::addEquationCurve() { addChild(new XYEquationCurve("f(x)")); } void CartesianPlot::addHistogram() { addChild(new Histogram("Histogram")); } /*! * returns the first selected XYCurve in the plot */ const XYCurve* CartesianPlot::currentCurve() const { for (const auto* curve : this->children()) { if (curve->graphicsItem()->isSelected()) return curve; } return nullptr; } void CartesianPlot::addDataReductionCurve() { XYDataReductionCurve* curve = new XYDataReductionCurve("Data reduction"); const XYCurve* curCurve = currentCurve(); if (curCurve) { beginMacro( i18n("%1: reduce '%2'", name(), curCurve->name()) ); curve->setName( i18n("Reduction of '%1'", curCurve->name()) ); curve->setDataSourceType(XYAnalysisCurve::DataSourceCurve); curve->setDataSourceCurve(curCurve); this->addChild(curve); curve->recalculate(); emit curve->dataReductionDataChanged(curve->dataReductionData()); } else { beginMacro(i18n("%1: add data reduction curve", name())); this->addChild(curve); } endMacro(); } void CartesianPlot::addDifferentiationCurve() { XYDifferentiationCurve* curve = new XYDifferentiationCurve("Differentiation"); const XYCurve* curCurve = currentCurve(); if (curCurve) { beginMacro( i18n("%1: differentiate '%2'", name(), curCurve->name()) ); curve->setName( i18n("Derivative of '%1'", curCurve->name()) ); curve->setDataSourceType(XYAnalysisCurve::DataSourceCurve); curve->setDataSourceCurve(curCurve); this->addChild(curve); curve->recalculate(); emit curve->differentiationDataChanged(curve->differentiationData()); } else { beginMacro(i18n("%1: add differentiation curve", name())); this->addChild(curve); } endMacro(); } void CartesianPlot::addIntegrationCurve() { XYIntegrationCurve* curve = new XYIntegrationCurve("Integration"); const XYCurve* curCurve = currentCurve(); if (curCurve) { beginMacro( i18n("%1: integrate '%2'", name(), curCurve->name()) ); curve->setName( i18n("Integral of '%1'", curCurve->name()) ); curve->setDataSourceType(XYAnalysisCurve::DataSourceCurve); curve->setDataSourceCurve(curCurve); this->addChild(curve); curve->recalculate(); emit curve->integrationDataChanged(curve->integrationData()); } else { beginMacro(i18n("%1: add integration curve", name())); this->addChild(curve); } endMacro(); } void CartesianPlot::addInterpolationCurve() { XYInterpolationCurve* curve = new XYInterpolationCurve("Interpolation"); const XYCurve* curCurve = currentCurve(); if (curCurve) { beginMacro( i18n("%1: interpolate '%2'", name(), curCurve->name()) ); curve->setName( i18n("Interpolation of '%1'", curCurve->name()) ); curve->setDataSourceType(XYAnalysisCurve::DataSourceCurve); curve->setDataSourceCurve(curCurve); curve->recalculate(); this->addChild(curve); emit curve->interpolationDataChanged(curve->interpolationData()); } else { beginMacro(i18n("%1: add interpolation curve", name())); this->addChild(curve); } endMacro(); } void CartesianPlot::addSmoothCurve() { XYSmoothCurve* curve = new XYSmoothCurve("Smooth"); const XYCurve* curCurve = currentCurve(); if (curCurve) { beginMacro( i18n("%1: smooth '%2'", name(), curCurve->name()) ); curve->setName( i18n("Smoothing of '%1'", curCurve->name()) ); curve->setDataSourceType(XYAnalysisCurve::DataSourceCurve); curve->setDataSourceCurve(curCurve); this->addChild(curve); curve->recalculate(); emit curve->smoothDataChanged(curve->smoothData()); } else { beginMacro(i18n("%1: add smoothing curve", name())); this->addChild(curve); } endMacro(); } void CartesianPlot::addFitCurve() { DEBUG("CartesianPlot::addFitCurve()"); XYFitCurve* curve = new XYFitCurve("fit"); const XYCurve* curCurve = currentCurve(); if (curCurve) { beginMacro( i18n("%1: fit to '%2'", name(), curCurve->name()) ); curve->setName( i18n("Fit to '%1'", curCurve->name()) ); curve->setDataSourceType(XYAnalysisCurve::DataSourceCurve); curve->setDataSourceCurve(curCurve); //set the fit model category and type const auto* action = qobject_cast(QObject::sender()); PlotDataDialog::AnalysisAction type = (PlotDataDialog::AnalysisAction)action->data().toInt(); curve->initFitData(type); curve->initStartValues(curCurve); //fit with weights for y if the curve has error bars for y if (curCurve->yErrorType() == XYCurve::SymmetricError && curCurve->yErrorPlusColumn()) { XYFitCurve::FitData fitData = curve->fitData(); fitData.yWeightsType = nsl_fit_weight_instrumental; curve->setFitData(fitData); curve->setYErrorColumn(curCurve->yErrorPlusColumn()); } curve->recalculate(); //add the child after the fit was calculated so the dock widgets gets the fit results //and call retransform() after this to calculate and to paint the data points of the fit-curve this->addChild(curve); curve->retransform(); } else { beginMacro(i18n("%1: add fit curve", name())); this->addChild(curve); } endMacro(); } void CartesianPlot::addFourierFilterCurve() { XYFourierFilterCurve* curve = new XYFourierFilterCurve("Fourier filter"); const XYCurve* curCurve = currentCurve(); if (curCurve) { beginMacro( i18n("%1: Fourier filtering of '%2'", name(), curCurve->name()) ); curve->setName( i18n("Fourier filtering of '%1'", curCurve->name()) ); curve->setDataSourceType(XYAnalysisCurve::DataSourceCurve); curve->setDataSourceCurve(curCurve); this->addChild(curve); } else { beginMacro(i18n("%1: add Fourier filter curve", name())); this->addChild(curve); } endMacro(); } void CartesianPlot::addFourierTransformCurve() { XYFourierTransformCurve* curve = new XYFourierTransformCurve("Fourier transform"); this->addChild(curve); } void CartesianPlot::addConvolutionCurve() { XYConvolutionCurve* curve = new XYConvolutionCurve("Convolution"); this->addChild(curve); } void CartesianPlot::addCorrelationCurve() { XYCorrelationCurve* curve = new XYCorrelationCurve("Auto-/Cross-Correlation"); this->addChild(curve); } /*! * public helper function to set a legend object created outside of CartesianPlot, e.g. in \c OriginProjectParser. */ void CartesianPlot::addLegend(CartesianPlotLegend* legend) { m_legend = legend; this->addChild(legend); } void CartesianPlot::addLegend() { //don't do anything if there's already a legend if (m_legend) return; m_legend = new CartesianPlotLegend(this, "legend"); this->addChild(m_legend); m_legend->retransform(); //only one legend is allowed -> disable the action if (m_menusInitialized) addLegendAction->setEnabled(false); } void CartesianPlot::addTextLabel() { TextLabel* label = new TextLabel("text label"); this->addChild(label); label->setParentGraphicsItem(graphicsItem()); } void CartesianPlot::addCustomPoint() { CustomPoint* point = new CustomPoint(this, "custom point"); this->addChild(point); } int CartesianPlot::curveCount(){ return children().length(); } const XYCurve* CartesianPlot::getCurve(int index){ return children()[index]; } double CartesianPlot::cursorPos(int cursorNumber) { Q_D(CartesianPlot); if (cursorNumber == 0) return d->cursor0Pos.x(); else return d->cursor1Pos.x(); } void CartesianPlot::childAdded(const AbstractAspect* child) { Q_D(CartesianPlot); const auto* curve = qobject_cast(child); if (curve) { connect(curve, &XYCurve::dataChanged, this, &CartesianPlot::dataChanged); connect(curve, &XYCurve::xDataChanged, this, &CartesianPlot::xDataChanged); connect(curve, &XYCurve::xErrorTypeChanged, this, &CartesianPlot::dataChanged); connect(curve, &XYCurve::xErrorPlusColumnChanged, this, &CartesianPlot::dataChanged); connect(curve, &XYCurve::xErrorMinusColumnChanged, this, &CartesianPlot::dataChanged); connect(curve, &XYCurve::yDataChanged, this, &CartesianPlot::yDataChanged); connect(curve, &XYCurve::yErrorTypeChanged, this, &CartesianPlot::dataChanged); connect(curve, &XYCurve::yErrorPlusColumnChanged, this, &CartesianPlot::dataChanged); connect(curve, &XYCurve::yErrorMinusColumnChanged, this, &CartesianPlot::dataChanged); connect(curve, static_cast(&XYCurve::visibilityChanged), this, &CartesianPlot::curveVisibilityChanged); //update the legend on changes of the name, line and symbol styles connect(curve, &XYCurve::aspectDescriptionChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::lineTypeChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::linePenChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::lineOpacityChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::symbolsStyleChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::symbolsSizeChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::symbolsRotationAngleChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::symbolsOpacityChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::symbolsBrushChanged, this, &CartesianPlot::updateLegend); connect(curve, &XYCurve::symbolsPenChanged, this, &CartesianPlot::updateLegend); - connect(curve, SIGNAL(linePenChanged(QPen)), this, SIGNAL(curveLinePenChanged(QPen))); // feed forward linePenChanged, because Worksheet needs because CursorDock must be updated too updateLegend(); d->curvesXMinMaxIsDirty = true; d->curvesYMinMaxIsDirty = true; //in case the first curve is added, check whether we start plotting datetime data if (children().size() == 1) { const auto* col = dynamic_cast(curve->xColumn()); if (col) { if (col->columnMode() == AbstractColumn::DateTime) { setUndoAware(false); setXRangeFormat(CartesianPlot::DateTime); setUndoAware(true); //set column's datetime format for all horizontal axis for (auto* axis : children()) { if (axis->orientation() == Axis::AxisHorizontal) { auto* filter = static_cast(col->outputFilter()); d->xRangeDateTimeFormat = filter->format(); axis->setUndoAware(false); axis->setLabelsDateTimeFormat(d->xRangeDateTimeFormat); axis->setUndoAware(true); } } } } col = dynamic_cast(curve->yColumn()); if (col) { if (col->columnMode() == AbstractColumn::DateTime) { setUndoAware(false); setYRangeFormat(CartesianPlot::DateTime); setUndoAware(true); //set column's datetime format for all vertical axis for (auto* axis : children()) { if (axis->orientation() == Axis::AxisVertical) { auto* filter = static_cast(col->outputFilter()); d->yRangeDateTimeFormat = filter->format(); axis->setUndoAware(false); axis->setLabelsDateTimeFormat(d->yRangeDateTimeFormat); axis->setUndoAware(true); } } } } } emit curveAdded(curve); } else { const auto* hist = qobject_cast(child); if (hist) { connect(hist, &Histogram::dataChanged, this, &CartesianPlot::dataChanged); connect(hist, &Histogram::visibilityChanged, this, &CartesianPlot::curveVisibilityChanged); updateLegend(); } // if an element is hovered, the curves which are handled manually in this class // must be unhovered const WorksheetElement* element = static_cast(child); connect(element, &WorksheetElement::hovered, this, &CartesianPlot::childHovered); } if (!isLoading()) { //if a theme was selected, apply the theme settings for newly added children, too if (!d->theme.isEmpty()) { const auto* elem = dynamic_cast(child); if (elem) { KConfig config(ThemeHandler::themeFilePath(d->theme), KConfig::SimpleConfig); const_cast(elem)->loadThemeConfig(config); } } else { //no theme is available, apply the default colors for curves only, s.a. XYCurve::loadThemeConfig() const auto* curve = dynamic_cast(child); if (curve) { int index = indexOfChild(curve); QColor themeColor; if (index < m_themeColorPalette.size()) themeColor = m_themeColorPalette.at(index); else { if (m_themeColorPalette.size()) themeColor = m_themeColorPalette.last(); } auto* c = const_cast(curve); //Line QPen p = curve->linePen(); p.setColor(themeColor); c->setLinePen(p); //Drop line p = curve->dropLinePen(); p.setColor(themeColor); c->setDropLinePen(p); //Symbol QBrush brush = c->symbolsBrush(); brush.setColor(themeColor); c->setSymbolsBrush(brush); p = c->symbolsPen(); p.setColor(themeColor); c->setSymbolsPen(p); //Filling c->setFillingFirstColor(themeColor); //Error bars p.setColor(themeColor); c->setErrorBarsPen(p); } } } } void CartesianPlot::childRemoved(const AbstractAspect* parent, const AbstractAspect* before, const AbstractAspect* child) { Q_UNUSED(parent); Q_UNUSED(before); if (m_legend == child) { if (m_menusInitialized) addLegendAction->setEnabled(true); m_legend = nullptr; } else { const auto* curve = qobject_cast(child); if (curve) { updateLegend(); emit curveRemoved(curve); } } } /*! * \brief CartesianPlot::childHovered * Unhover all curves, when another child is hovered. The hover handling for the curves is done in their parent (CartesianPlot), * because the hover should set when the curve is hovered and not just the bounding rect (for more see hoverMoveEvent) */ void CartesianPlot::childHovered() { Q_D(CartesianPlot); bool curveSender = dynamic_cast(QObject::sender()) != nullptr; if (!d->isSelected()) { if (d->m_hovered) d->m_hovered = false; d->update(); } if (!curveSender) { for (auto curve: children()) curve->setHover(false); } } void CartesianPlot::updateLegend() { if (m_legend) m_legend->retransform(); } /*! called when in one of the curves the data was changed. Autoscales the coordinate system and the x-axes, when "auto-scale" is active. */ void CartesianPlot::dataChanged() { Q_D(CartesianPlot); d->curvesXMinMaxIsDirty = true; d->curvesYMinMaxIsDirty = true; bool updated = false; if (d->autoScaleX && d->autoScaleY) updated = this->scaleAuto(); else if (d->autoScaleX) updated = this->scaleAutoX(); else if (d->autoScaleY) updated = this->scaleAutoY(); if (!updated || !QObject::sender()) { //even if the plot ranges were not changed, either no auto scale active or the new data //is within the current ranges and no change of the ranges is required, //retransform the curve in order to show the changes auto* curve = dynamic_cast(QObject::sender()); if (curve) curve->retransform(); else { auto* hist = dynamic_cast(QObject::sender()); if (hist) hist->retransform(); else { - //no sender available, the function was called in CartesianPlot::dataChanged() - //via plot->dataChaged() in the file filter (live data source got new data) - //-> retransform all available curves since we don't know which curves are affected. + //no sender available, the function was called directly in the file filter (live data source got new data) + //or in Project::load() -> retransform all available curves since we don't know which curves are affected. //TODO: this logic can be very expensive for (auto* c : children()) { c->recalcLogicalPoints(); c->retransform(); } } } } } /*! called when in one of the curves the x-data was changed. Autoscales the coordinate system and the x-axes, when "auto-scale" is active. */ void CartesianPlot::xDataChanged() { if (project() && project()->isLoading()) return; Q_D(CartesianPlot); if (d->suppressRetransform) return; d->curvesXMinMaxIsDirty = true; bool updated = false; if (d->autoScaleX) updated = this->scaleAutoX(); if (!updated) { //even if the plot ranges were not changed, either no auto scale active or the new data //is within the current ranges and no change of the ranges is required, //retransform the curve in order to show the changes auto* curve = dynamic_cast(QObject::sender()); if (curve) curve->retransform(); else { auto* hist = dynamic_cast(QObject::sender()); if (hist) hist->retransform(); } } //in case there is only one curve and its column mode was changed, check whether we start plotting datetime data if (children().size() == 1) { auto* curve = dynamic_cast(QObject::sender()); const AbstractColumn* col = curve->xColumn(); if (col->columnMode() == AbstractColumn::DateTime && d->xRangeFormat != CartesianPlot::DateTime) { setUndoAware(false); setXRangeFormat(CartesianPlot::DateTime); setUndoAware(true); } } emit curveDataChanged(dynamic_cast(QObject::sender())); } /*! called when in one of the curves the x-data was changed. Autoscales the coordinate system and the x-axes, when "auto-scale" is active. */ void CartesianPlot::yDataChanged() { if (project() && project()->isLoading()) return; Q_D(CartesianPlot); if (d->suppressRetransform) return; d->curvesYMinMaxIsDirty = true; bool updated = false; if (d->autoScaleY) this->scaleAutoY(); if (!updated) { //even if the plot ranges were not changed, either no auto scale active or the new data //is within the current ranges and no change of the ranges is required, //retransform the curve in order to show the changes auto* curve = dynamic_cast(QObject::sender()); if (curve) curve->retransform(); else { auto* hist = dynamic_cast(QObject::sender()); if (hist) hist->retransform(); } } //in case there is only one curve and its column mode was changed, check whether we start plotting datetime data if (children().size() == 1) { auto* curve = dynamic_cast(QObject::sender()); const AbstractColumn* col = curve->yColumn(); if (col->columnMode() == AbstractColumn::DateTime && d->xRangeFormat != CartesianPlot::DateTime) { setUndoAware(false); setYRangeFormat(CartesianPlot::DateTime); setUndoAware(true); } } emit curveDataChanged(dynamic_cast(QObject::sender())); } void CartesianPlot::curveVisibilityChanged() { Q_D(CartesianPlot); d->curvesXMinMaxIsDirty = true; d->curvesYMinMaxIsDirty = true; updateLegend(); if (d->autoScaleX && d->autoScaleY) this->scaleAuto(); else if (d->autoScaleX) this->scaleAutoX(); else if (d->autoScaleY) this->scaleAutoY(); emit curveVisibilityChangedSignal(); } void CartesianPlot::curveLinePenChanged(QPen pen) { const auto* curve = qobject_cast(QObject::sender()); emit curveLinePenChanged(pen, curve->name()); } void CartesianPlot::setMouseMode(const MouseMode mouseMode) { Q_D(CartesianPlot); d->mouseMode = mouseMode; d->setHandlesChildEvents(mouseMode != CartesianPlot::SelectionMode); QList items = d->childItems(); if (d->mouseMode == CartesianPlot::SelectionMode) { for (auto* item : items) item->setFlag(QGraphicsItem::ItemStacksBehindParent, false); } else { for (auto* item : items) item->setFlag(QGraphicsItem::ItemStacksBehindParent, true); } //when doing zoom selection, prevent the graphics item from being movable //if it's currently movable (no worksheet layout available) const auto* worksheet = dynamic_cast(parentAspect()); if (worksheet) { if (mouseMode == CartesianPlot::SelectionMode) { if (worksheet->layout() != Worksheet::NoLayout) graphicsItem()->setFlag(QGraphicsItem::ItemIsMovable, false); else graphicsItem()->setFlag(QGraphicsItem::ItemIsMovable, true); } else //zoom m_selection graphicsItem()->setFlag(QGraphicsItem::ItemIsMovable, false); } emit mouseModeChanged(mouseMode); } void CartesianPlot::setLocked(bool locked) { Q_D(CartesianPlot); d->locked = locked; } bool CartesianPlot::scaleAutoX() { Q_D(CartesianPlot); if (d->curvesXMinMaxIsDirty) { calculateCurvesXMinMax(); d->curvesXMinMaxIsDirty = false; } bool update = false; if (d->curvesXMin != d->xMin && d->curvesXMin != INFINITY) { d->xMin = d->curvesXMin; update = true; } if (d->curvesXMax != d->xMax && d->curvesXMax != -INFINITY) { d->xMax = d->curvesXMax; update = true; } if (update) { if (d->xMax == d->xMin) { //in case min and max are equal (e.g. if we plot a single point), subtract/add 10% of the value if (d->xMax != 0) { d->xMax = d->xMax*1.1; d->xMin = d->xMin*0.9; } else { d->xMax = 0.1; d->xMin = -0.1; } } else { double offset = (d->xMax - d->xMin)*d->autoScaleOffsetFactor; d->xMin -= offset; d->xMax += offset; } setAutoScaleX(true); d->retransformScales(); } return update; } bool CartesianPlot::scaleAutoY() { Q_D(CartesianPlot); if (d->curvesYMinMaxIsDirty) { calculateCurvesYMinMax(); d->curvesYMinMaxIsDirty = false; } bool update = false; if (d->curvesYMin != d->yMin && d->curvesYMin != INFINITY) { d->yMin = d->curvesYMin; update = true; } if (d->curvesYMax != d->yMax && d->curvesYMax != -INFINITY) { d->yMax = d->curvesYMax; update = true; } if (update) { if (d->yMax == d->yMin) { //in case min and max are equal (e.g. if we plot a single point), subtract/add 10% of the value if (d->yMax != 0) { d->yMax = d->yMax*1.1; d->yMin = d->yMin*0.9; } else { d->yMax = 0.1; d->yMin = -0.1; } } else { double offset = (d->yMax - d->yMin)*d->autoScaleOffsetFactor; d->yMin -= offset; d->yMax += offset; } setAutoScaleY(true); d->retransformScales(); } return update; } bool CartesianPlot::scaleAuto() { DEBUG("CartesianPlot::scaleAuto()"); Q_D(CartesianPlot); if (d->curvesXMinMaxIsDirty) { calculateCurvesXMinMax(); d->curvesXMinMaxIsDirty = false; } if (d->curvesYMinMaxIsDirty) { calculateCurvesYMinMax(); d->curvesYMinMaxIsDirty = false; } bool updateX = false; bool updateY = false; if (d->curvesXMin != d->xMin && d->curvesXMin != INFINITY) { d->xMin = d->curvesXMin; updateX = true; } if (d->curvesXMax != d->xMax && d->curvesXMax != -INFINITY) { d->xMax = d->curvesXMax; updateX = true; } if (d->curvesYMin != d->yMin && d->curvesYMin != INFINITY) { d->yMin = d->curvesYMin; updateY = true; } if (d->curvesYMax != d->yMax && d->curvesYMax != -INFINITY) { d->yMax = d->curvesYMax; updateY = true; } DEBUG(" xmin/xmax = " << d->xMin << '/' << d->xMax << ", ymin/ymax = " << d->yMin << '/' << d->yMax); if (updateX || updateY) { if (updateX) { if (d->xMax == d->xMin) { //in case min and max are equal (e.g. if we plot a single point), subtract/add 10% of the value if (d->xMax != 0) { d->xMax = d->xMax*1.1; d->xMin = d->xMin*0.9; } else { d->xMax = 0.1; d->xMin = -0.1; } } else { double offset = (d->xMax - d->xMin)*d->autoScaleOffsetFactor; d->xMin -= offset; d->xMax += offset; } setAutoScaleX(true); } if (updateY) { if (d->yMax == d->yMin) { //in case min and max are equal (e.g. if we plot a single point), subtract/add 10% of the value if (d->yMax != 0) { d->yMax = d->yMax*1.1; d->yMin = d->yMin*0.9; } else { d->yMax = 0.1; d->yMin = -0.1; } } else { double offset = (d->yMax - d->yMin)*d->autoScaleOffsetFactor; d->yMin -= offset; d->yMax += offset; } setAutoScaleY(true); } d->retransformScales(); } return (updateX || updateY); } void CartesianPlot::calculateCurvesXMinMax() { Q_D(CartesianPlot); int count = 0; switch (d->rangeType) { case CartesianPlot::RangeFree: count = 0; break; case CartesianPlot::RangeLast: count = -d->rangeLastValues; break; case CartesianPlot::RangeFirst: count = d->rangeFirstValues; break; } d->curvesXMin = INFINITY; d->curvesXMax = -INFINITY; //loop over all xy-curves and determine the maximum and minimum x-values for (const auto* curve : this->children()) { if (!curve->isVisible()) continue; auto* xColumn = curve->xColumn(); if (!xColumn) continue; double min = xColumn->minimum(count); if (min < d->curvesXMin) d->curvesXMin = min; double max = xColumn->maximum(count); if (max > d->curvesXMax) d->curvesXMax = max; //take error bars into account auto xErrorType = curve->xErrorType(); if (xErrorType != XYCurve::NoError) { //consider error bars only if error columns are set auto* xErrorPlusColumn = curve->xErrorPlusColumn(); auto* xErrorMinusColumn = curve->xErrorMinusColumn(); if ( (xErrorType == XYCurve::SymmetricError && xErrorPlusColumn) || (xErrorType == XYCurve::AsymmetricError && (xErrorPlusColumn || xErrorMinusColumn)) ) { int start =0; int end = 0; switch (d->rangeType) { case CartesianPlot::RangeFree: start = 0; end = xColumn->rowCount(); break; case CartesianPlot::RangeLast: start = xColumn->rowCount() - d->rangeLastValues; end = xColumn->rowCount(); break; case CartesianPlot::RangeFirst: start = 0; end = d->rangeFirstValues; break; } for (int i = start; i < end; ++i) { if (!xColumn->isValid(i) || xColumn->isMasked(i)) continue; if ( (xErrorPlusColumn && i >= xErrorPlusColumn->rowCount()) || (xErrorMinusColumn && i >= xErrorMinusColumn->rowCount()) ) continue; //determine the values for the errors double errorPlus, errorMinus; if (xErrorPlusColumn && xErrorPlusColumn->isValid(i) && !xErrorPlusColumn->isMasked(i)) errorPlus = xErrorPlusColumn->valueAt(i); else errorPlus = 0; if (xErrorType == XYCurve::SymmetricError) errorMinus = errorPlus; else { if (xErrorMinusColumn && xErrorMinusColumn->isValid(i) && !xErrorMinusColumn->isMasked(i)) errorMinus = xErrorMinusColumn->valueAt(i); else errorMinus = 0; } min = xColumn->valueAt(i) - errorMinus; if (min < d->curvesXMin) d->curvesXMin = min; max = xColumn->valueAt(i) + errorPlus; if (max > d->curvesXMax) d->curvesXMax = max; } } } } //loop over all histograms and determine the maximum and minimum x-values for (const auto* curve : this->children()) { if (!curve->isVisible()) continue; if (!curve->dataColumn()) continue; const double min = curve->getXMinimum(); if (d->curvesXMin > min) d->curvesXMin = min; const double max = curve->getXMaximum(); if (max > d->curvesXMax) d->curvesXMax = max; } } void CartesianPlot::calculateCurvesYMinMax() { Q_D(CartesianPlot); int count = 0; switch (d->rangeType) { case CartesianPlot::RangeFree: count = 0; break; case CartesianPlot::RangeLast: count = -d->rangeLastValues; break; case CartesianPlot::RangeFirst: count = d->rangeFirstValues; break; } d->curvesYMin = INFINITY; d->curvesYMax = -INFINITY; //loop over all xy-curves and determine the maximum and minimum y-values for (const auto* curve : this->children()) { if (!curve->isVisible()) continue; auto* yColumn = curve->yColumn(); if (!yColumn) continue; double min = curve->yColumn()->minimum(count); if (min < d->curvesYMin) d->curvesYMin = min; double max = curve->yColumn()->maximum(count); if (max > d->curvesYMax) d->curvesYMax = max; //take error bars into account auto yErrorType = curve->yErrorType(); if (yErrorType != XYCurve::NoError) { //consider error bars only if error columns are set auto* yErrorPlusColumn = curve->yErrorPlusColumn(); auto* yErrorMinusColumn = curve->yErrorMinusColumn(); if ( (yErrorType == XYCurve::SymmetricError && yErrorPlusColumn) || (yErrorType == XYCurve::AsymmetricError && (yErrorPlusColumn || yErrorMinusColumn)) ) { int start =0; int end = 0; switch (d->rangeType) { case CartesianPlot::RangeFree: start = 0; end = yColumn->rowCount(); break; case CartesianPlot::RangeLast: start = yColumn->rowCount() - d->rangeLastValues; end = yColumn->rowCount(); break; case CartesianPlot::RangeFirst: start = 0; end = d->rangeFirstValues; break; } for (int i = start; i < end; ++i) { if (!yColumn->isValid(i) || yColumn->isMasked(i)) continue; if ( (yErrorPlusColumn && i >= yErrorPlusColumn->rowCount()) || (yErrorMinusColumn && i >= yErrorMinusColumn->rowCount()) ) continue; //determine the values for the errors double errorPlus, errorMinus; if (yErrorPlusColumn && yErrorPlusColumn->isValid(i) && !yErrorPlusColumn->isMasked(i)) errorPlus = yErrorPlusColumn->valueAt(i); else errorPlus = 0; if (yErrorType == XYCurve::SymmetricError) errorMinus = errorPlus; else { if (yErrorMinusColumn && yErrorMinusColumn->isValid(i) && !yErrorMinusColumn->isMasked(i)) errorMinus = yErrorMinusColumn->valueAt(i); else errorMinus = 0; } min = yColumn->valueAt(i) - errorMinus; if (min < d->curvesYMin) d->curvesYMin = min; max = yColumn->valueAt(i) + errorPlus; if (max > d->curvesYMax) d->curvesYMax = max; } } } } //loop over all histograms and determine the maximum y-value for (const auto* curve : this->children()) { if (!curve->isVisible()) continue; const double min = curve->getYMinimum(); if (d->curvesYMin > min) d->curvesYMin = min; const double max = curve->getYMaximum(); if (max > d->curvesYMax) d->curvesYMax = max; } } void CartesianPlot::zoomIn() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleX(false); setAutoScaleY(false); setUndoAware(true); double oldRange = (d->xMax - d->xMin); double newRange = (d->xMax - d->xMin) / m_zoomFactor; d->xMax = d->xMax + (newRange - oldRange) / 2; d->xMin = d->xMin - (newRange - oldRange) / 2; oldRange = (d->yMax - d->yMin); newRange = (d->yMax - d->yMin) / m_zoomFactor; d->yMax = d->yMax + (newRange - oldRange) / 2; d->yMin = d->yMin - (newRange - oldRange) / 2; d->retransformScales(); } void CartesianPlot::zoomOut() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleX(false); setAutoScaleY(false); setUndoAware(true); double oldRange = (d->xMax-d->xMin); double newRange = (d->xMax-d->xMin)*m_zoomFactor; d->xMax = d->xMax + (newRange-oldRange)/2; d->xMin = d->xMin - (newRange-oldRange)/2; oldRange = (d->yMax-d->yMin); newRange = (d->yMax-d->yMin)*m_zoomFactor; d->yMax = d->yMax + (newRange-oldRange)/2; d->yMin = d->yMin - (newRange-oldRange)/2; d->retransformScales(); } void CartesianPlot::zoomInX() { Q_D(CartesianPlot); setAutoScaleX(false); double oldRange = (d->xMax-d->xMin); double newRange = (d->xMax-d->xMin)/m_zoomFactor; d->xMax = d->xMax + (newRange-oldRange)/2; d->xMin = d->xMin - (newRange-oldRange)/2; d->retransformScales(); } void CartesianPlot::zoomOutX() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleX(false); setUndoAware(true); double oldRange = (d->xMax-d->xMin); double newRange = (d->xMax-d->xMin)*m_zoomFactor; d->xMax = d->xMax + (newRange-oldRange)/2; d->xMin = d->xMin - (newRange-oldRange)/2; d->retransformScales(); } void CartesianPlot::zoomInY() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleY(false); setUndoAware(true); double oldRange = (d->yMax-d->yMin); double newRange = (d->yMax-d->yMin)/m_zoomFactor; d->yMax = d->yMax + (newRange-oldRange)/2; d->yMin = d->yMin - (newRange-oldRange)/2; d->retransformScales(); } void CartesianPlot::zoomOutY() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleY(false); setUndoAware(true); double oldRange = (d->yMax-d->yMin); double newRange = (d->yMax-d->yMin)*m_zoomFactor; d->yMax = d->yMax + (newRange-oldRange)/2; d->yMin = d->yMin - (newRange-oldRange)/2; d->retransformScales(); } void CartesianPlot::shiftLeftX() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleX(false); setUndoAware(true); double offsetX = (d->xMax-d->xMin)*0.1; d->xMax -= offsetX; d->xMin -= offsetX; d->retransformScales(); } void CartesianPlot::shiftRightX() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleX(false); setUndoAware(true); double offsetX = (d->xMax-d->xMin)*0.1; d->xMax += offsetX; d->xMin += offsetX; d->retransformScales(); } void CartesianPlot::shiftUpY() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleY(false); setUndoAware(true); double offsetY = (d->yMax-d->yMin)*0.1; d->yMax += offsetY; d->yMin += offsetY; d->retransformScales(); } void CartesianPlot::shiftDownY() { Q_D(CartesianPlot); setUndoAware(false); setAutoScaleY(false); setUndoAware(true); double offsetY = (d->yMax-d->yMin)*0.1; d->yMax -= offsetY; d->yMin -= offsetY; d->retransformScales(); } void CartesianPlot::cursor() { Q_D(CartesianPlot); d->retransformScales(); } void CartesianPlot::mousePressZoomSelectionMode(QPointF logicPos) { Q_D(CartesianPlot); d->mousePressZoomSelectionMode(logicPos); } void CartesianPlot::mousePressCursorMode(int cursorNumber, QPointF logicPos) { Q_D(CartesianPlot); d->mousePressCursorMode(cursorNumber, logicPos); } void CartesianPlot::mouseMoveZoomSelectionMode(QPointF logicPos) { Q_D(CartesianPlot); d->mouseMoveZoomSelectionMode(logicPos); } void CartesianPlot::mouseMoveCursorMode(int cursorNumber, QPointF logicPos) { Q_D(CartesianPlot); d->mouseMoveCursorMode(cursorNumber, logicPos); } void CartesianPlot::mouseReleaseZoomSelectionMode() { Q_D(CartesianPlot); d->mouseReleaseZoomSelectionMode(); } void CartesianPlot::mouseHoverZoomSelectionMode(QPointF logicPos) { Q_D(CartesianPlot); d->mouseHoverZoomSelectionMode(logicPos); } //############################################################################## //###### SLOTs for changes triggered via QActions in the context menu ######## //############################################################################## void CartesianPlot::visibilityChanged() { Q_D(CartesianPlot); this->setVisible(!d->isVisible()); } void CartesianPlot::deselected() { setMouseMode(MouseMode::SelectionMode); } //##################################################################### //################### Private implementation ########################## //##################################################################### CartesianPlotPrivate::CartesianPlotPrivate(CartesianPlot* plot) : AbstractPlotPrivate(plot), q(plot) { setData(0, WorksheetElement::NameCartesianPlot); m_cursor0Text.prepare(); m_cursor1Text.prepare(); } /*! updates the position of plot rectangular in scene coordinates to \c r and recalculates the scales. The size of the plot corresponds to the size of the plot area, the area which is filled with the background color etc. and which can pose the parent item for several sub-items (like TextLabel). Note, the size of the area used to define the coordinate system doesn't need to be equal to this plot area. Also, the size (=bounding box) of CartesianPlot can be greater than the size of the plot area. */ void CartesianPlotPrivate::retransform() { if (suppressRetransform) return; PERFTRACE("CartesianPlotPrivate::retransform()"); prepareGeometryChange(); setPos( rect.x()+rect.width()/2, rect.y()+rect.height()/2); updateDataRect(); retransformScales(); //plotArea position is always (0, 0) in parent's coordinates, don't need to update here q->plotArea()->setRect(rect); //call retransform() for the title and the legend (if available) //when a predefined position relative to the (Left, Centered etc.) is used, //the actual position needs to be updated on plot's geometry changes. if (q->title()) q->title()->retransform(); if (q->m_legend) q->m_legend->retransform(); WorksheetElementContainerPrivate::recalcShapeAndBoundingRect(); } void CartesianPlotPrivate::retransformScales() { DEBUG("CartesianPlotPrivate::retransformScales()"); DEBUG(" xmin/xmax = " << xMin << '/'<< xMax << ", ymin/ymax = " << yMin << '/' << yMax); PERFTRACE("CartesianPlotPrivate::retransformScales()"); auto* plot = dynamic_cast(q); QVector scales; //check ranges for log-scales if (xScale != CartesianPlot::ScaleLinear) checkXRange(); //check whether we have x-range breaks - the first break, if available, should be valid bool hasValidBreak = (xRangeBreakingEnabled && !xRangeBreaks.list.isEmpty() && xRangeBreaks.list.first().isValid()); static const int breakGap = 20; double sceneStart, sceneEnd, logicalStart, logicalEnd; //create x-scales int plotSceneStart = dataRect.x(); int plotSceneEnd = dataRect.x() + dataRect.width(); if (!hasValidBreak) { //no breaks available -> range goes from the plot beginning to the end of the plot sceneStart = plotSceneStart; sceneEnd = plotSceneEnd; logicalStart = xMin; logicalEnd = xMax; //TODO: how should we handle the case sceneStart == sceneEnd? //(to reproduce, create plots and adjust the spacing/pading to get zero size for the plots) if (sceneStart != sceneEnd) scales << this->createScale(xScale, sceneStart, sceneEnd, logicalStart, logicalEnd); } else { int sceneEndLast = plotSceneStart; int logicalEndLast = xMin; for (const auto& rb : xRangeBreaks.list) { if (!rb.isValid()) break; //current range goes from the end of the previous one (or from the plot beginning) to curBreak.start sceneStart = sceneEndLast; if (&rb == &xRangeBreaks.list.first()) sceneStart += breakGap; sceneEnd = plotSceneStart + (plotSceneEnd-plotSceneStart) * rb.position; logicalStart = logicalEndLast; logicalEnd = rb.start; if (sceneStart != sceneEnd) scales << this->createScale(xScale, sceneStart, sceneEnd, logicalStart, logicalEnd); sceneEndLast = sceneEnd; logicalEndLast = rb.end; } //add the remaining range going from the last available range break to the end of the plot (=end of the x-data range) sceneStart = sceneEndLast+breakGap; sceneEnd = plotSceneEnd; logicalStart = logicalEndLast; logicalEnd = xMax; if (sceneStart != sceneEnd) scales << this->createScale(xScale, sceneStart, sceneEnd, logicalStart, logicalEnd); } cSystem->setXScales(scales); //check ranges for log-scales if (yScale != CartesianPlot::ScaleLinear) checkYRange(); //check whether we have y-range breaks - the first break, if available, should be valid hasValidBreak = (yRangeBreakingEnabled && !yRangeBreaks.list.isEmpty() && yRangeBreaks.list.first().isValid()); //create y-scales scales.clear(); plotSceneStart = dataRect.y() + dataRect.height(); plotSceneEnd = dataRect.y(); if (!hasValidBreak) { //no breaks available -> range goes from the plot beginning to the end of the plot sceneStart = plotSceneStart; sceneEnd = plotSceneEnd; logicalStart = yMin; logicalEnd = yMax; if (sceneStart != sceneEnd) scales << this->createScale(yScale, sceneStart, sceneEnd, logicalStart, logicalEnd); } else { int sceneEndLast = plotSceneStart; int logicalEndLast = yMin; for (const auto& rb : yRangeBreaks.list) { if (!rb.isValid()) break; //current range goes from the end of the previous one (or from the plot beginning) to curBreak.start sceneStart = sceneEndLast; if (&rb == &yRangeBreaks.list.first()) sceneStart -= breakGap; sceneEnd = plotSceneStart + (plotSceneEnd-plotSceneStart) * rb.position; logicalStart = logicalEndLast; logicalEnd = rb.start; if (sceneStart != sceneEnd) scales << this->createScale(yScale, sceneStart, sceneEnd, logicalStart, logicalEnd); sceneEndLast = sceneEnd; logicalEndLast = rb.end; } //add the remaining range going from the last available range break to the end of the plot (=end of the y-data range) sceneStart = sceneEndLast-breakGap; sceneEnd = plotSceneEnd; logicalStart = logicalEndLast; logicalEnd = yMax; if (sceneStart != sceneEnd) scales << this->createScale(yScale, sceneStart, sceneEnd, logicalStart, logicalEnd); } cSystem->setYScales(scales); //calculate the changes in x and y and save the current values for xMin, xMax, yMin, yMax double deltaXMin = 0; double deltaXMax = 0; double deltaYMin = 0; double deltaYMax = 0; if (xMin != xMinPrev) { deltaXMin = xMin - xMinPrev; emit plot->xMinChanged(xMin); } if (xMax != xMaxPrev) { deltaXMax = xMax - xMaxPrev; emit plot->xMaxChanged(xMax); } if (yMin != yMinPrev) { deltaYMin = yMin - yMinPrev; emit plot->yMinChanged(yMin); } if (yMax != yMaxPrev) { deltaYMax = yMax - yMaxPrev; emit plot->yMaxChanged(yMax); } xMinPrev = xMin; xMaxPrev = xMax; yMinPrev = yMin; yMaxPrev = yMax; //adjust auto-scale axes for (auto* axis : q->children()) { if (!axis->autoScale()) continue; if (axis->orientation() == Axis::AxisHorizontal) { if (deltaXMax != 0) { axis->setUndoAware(false); axis->setSuppressRetransform(true); axis->setEnd(xMax); axis->setUndoAware(true); axis->setSuppressRetransform(false); } if (deltaXMin != 0) { axis->setUndoAware(false); axis->setSuppressRetransform(true); axis->setStart(xMin); axis->setUndoAware(true); axis->setSuppressRetransform(false); } //TODO; // if (axis->position() == Axis::AxisCustom && deltaYMin != 0) { // axis->setOffset(axis->offset() + deltaYMin, false); // } } else { if (deltaYMax != 0) { axis->setUndoAware(false); axis->setSuppressRetransform(true); axis->setEnd(yMax); axis->setUndoAware(true); axis->setSuppressRetransform(false); } if (deltaYMin != 0) { axis->setUndoAware(false); axis->setSuppressRetransform(true); axis->setStart(yMin); axis->setUndoAware(true); axis->setSuppressRetransform(false); } //TODO; // if (axis->position() == Axis::AxisCustom && deltaXMin != 0) { // axis->setOffset(axis->offset() + deltaXMin, false); // } } } // call retransform() on the parent to trigger the update of all axes and curvesю //no need to do this on load since all plots are retransformed again after the project is loaded. if (!q->isLoading()) q->retransform(); } /* * calculates the rectangular of the are showing the actual data (plot's rect minus padding), * in plot's coordinates. */ void CartesianPlotPrivate::updateDataRect() { dataRect = mapRectFromScene(rect); double paddingLeft = horizontalPadding; double paddingRight = rightPadding; double paddingTop = verticalPadding; double paddingBottom = bottomPadding; if (symmetricPadding) { paddingRight = horizontalPadding; paddingBottom = verticalPadding; } dataRect.setX(dataRect.x() + paddingLeft); dataRect.setY(dataRect.y() + paddingTop); double newHeight = dataRect.height() - paddingBottom; if (newHeight < 0) newHeight = 0; dataRect.setHeight(newHeight); double newWidth = dataRect.width() - paddingRight; if (newWidth < 0) newWidth = 0; dataRect.setWidth(newWidth); } void CartesianPlotPrivate::rangeChanged() { curvesXMinMaxIsDirty = true; curvesYMinMaxIsDirty = true; if (autoScaleX && autoScaleY) q->scaleAuto(); else if (autoScaleX) q->scaleAutoX(); else if (autoScaleY) q->scaleAutoY(); } void CartesianPlotPrivate::xRangeFormatChanged() { for (auto* axis : q->children()) { if (axis->orientation() == Axis::AxisHorizontal) axis->retransformTickLabelStrings(); } } void CartesianPlotPrivate::yRangeFormatChanged() { for (auto* axis : q->children()) { if (axis->orientation() == Axis::AxisVertical) axis->retransformTickLabelStrings(); } } /*! * don't allow any negative values for the x range when log or sqrt scalings are used */ void CartesianPlotPrivate::checkXRange() { double min = 0.01; if (xMin <= 0.0) { (min < xMax*min) ? xMin = min : xMin = xMax*min; emit q->xMinChanged(xMin); } else if (xMax <= 0.0) { (-min > xMin*min) ? xMax = -min : xMax = xMin*min; emit q->xMaxChanged(xMax); } } /*! * don't allow any negative values for the y range when log or sqrt scalings are used */ void CartesianPlotPrivate::checkYRange() { double min = 0.01; if (yMin <= 0.0) { (min < yMax*min) ? yMin = min : yMin = yMax*min; emit q->yMinChanged(yMin); } else if (yMax <= 0.0) { (-min > yMin*min) ? yMax = -min : yMax = yMin*min; emit q->yMaxChanged(yMax); } } CartesianScale* CartesianPlotPrivate::createScale(CartesianPlot::Scale type, double sceneStart, double sceneEnd, double logicalStart, double logicalEnd) { DEBUG("CartesianPlotPrivate::createScale() scene start/end = " << sceneStart << '/' << sceneEnd << ", logical start/end = " << logicalStart << '/' << logicalEnd); // Interval interval (logicalStart-0.01, logicalEnd+0.01); //TODO: move this to CartesianScale Interval interval (std::numeric_limits::lowest(), std::numeric_limits::max()); // Interval interval (logicalStart, logicalEnd); if (type == CartesianPlot::ScaleLinear) return CartesianScale::createLinearScale(interval, sceneStart, sceneEnd, logicalStart, logicalEnd); else return CartesianScale::createLogScale(interval, sceneStart, sceneEnd, logicalStart, logicalEnd, type); } /*! * Reimplemented from QGraphicsItem. */ QVariant CartesianPlotPrivate::itemChange(GraphicsItemChange change, const QVariant &value) { if (change == QGraphicsItem::ItemPositionChange) { const QPointF& itemPos = value.toPointF();//item's center point in parent's coordinates; const qreal x = itemPos.x(); const qreal y = itemPos.y(); //calculate the new rect and forward the changes to the frontend QRectF newRect; const qreal w = rect.width(); const qreal h = rect.height(); newRect.setX(x-w/2); newRect.setY(y-h/2); newRect.setWidth(w); newRect.setHeight(h); emit q->rectChanged(newRect); } else if (change == QGraphicsItem::ItemSelectedChange) { if (!value.toBool() || q->mouseMode() != CartesianPlot::MouseMode::SelectionMode) q->setMouseMode(CartesianPlot::MouseMode::SelectionMode); } return QGraphicsItem::itemChange(change, value); } //############################################################################## //################################## Events ################################## //############################################################################## void CartesianPlotPrivate::mousePressEvent(QGraphicsSceneMouseEvent *event) { if (mouseMode == CartesianPlot::ZoomSelectionMode || mouseMode == CartesianPlot::ZoomXSelectionMode || mouseMode == CartesianPlot::ZoomYSelectionMode) { emit q->mousePressZoomSelectionModeSignal(cSystem->mapSceneToLogical(event->pos())); if (mouseMode == CartesianPlot::ZoomSelectionMode) m_selectionStart = event->pos(); else if (mouseMode == CartesianPlot::ZoomXSelectionMode) { m_selectionStart.setX(event->pos().x()); m_selectionStart.setY(dataRect.y()); } else if (mouseMode == CartesianPlot::ZoomYSelectionMode) { m_selectionStart.setX(dataRect.x()); m_selectionStart.setY(event->pos().y()); } m_selectionEnd = m_selectionStart; m_selectionBandIsShown = true; } else if (mouseMode == CartesianPlot::Cursor) { setCursor(Qt::SizeHorCursor); QPointF logicalPos = cSystem->mapSceneToLogical(event->pos(), AbstractCoordinateSystem::MappingFlag::Limit); double cursorPenWidth2 = cursorPen.width()/2.; if (cursorPenWidth2 < 10.) cursorPenWidth2 = 10.; if (cursor0Enable && qAbs(event->pos().x()-cSystem->mapLogicalToScene(QPointF(cursor0Pos.x(),yMin)).x()) < cursorPenWidth2) { selectedCursor = 0; } else if (cursor1Enable && qAbs(event->pos().x()-cSystem->mapLogicalToScene(QPointF(cursor1Pos.x(),yMin)).x()) < cursorPenWidth2) { selectedCursor = 1; } else if (QApplication::keyboardModifiers() & Qt::ControlModifier){ cursor1Enable = true; selectedCursor = 1; emit q->cursor1EnableChanged(cursor1Enable); } else { cursor0Enable = true; selectedCursor = 0; emit q->cursor0EnableChanged(cursor0Enable); } emit q->mousePressCursorModeSignal(selectedCursor, logicalPos); } else { if (!locked && dataRect.contains(event->pos())) { panningStarted = true; m_panningStart = event->pos(); setCursor(Qt::ClosedHandCursor); } } QGraphicsItem::mousePressEvent(event); } void CartesianPlotPrivate::mousePressZoomSelectionMode(QPointF logicalPos) { if (mouseMode == CartesianPlot::ZoomSelectionMode) { if (logicalPos.x() < xMin) logicalPos.setX(xMin); if (logicalPos.x() > xMax) logicalPos.setX(xMax); if (logicalPos.y() < yMin) logicalPos.setY(yMin); if (logicalPos.y() > yMax) logicalPos.setY(yMax); m_selectionStart = cSystem->mapLogicalToScene(logicalPos, CartesianCoordinateSystem::SuppressPageClipping); } else if (mouseMode == CartesianPlot::ZoomXSelectionMode) { logicalPos.setY(yMin); // must be done, because the other plots can have other ranges, value must be in the scenes m_selectionStart.setX(cSystem->mapLogicalToScene(logicalPos, CartesianCoordinateSystem::SuppressPageClipping).x()); m_selectionStart.setY(dataRect.y()); } else if (mouseMode == CartesianPlot::ZoomYSelectionMode) { logicalPos.setX(xMin); // must be done, because the other plots can have other ranges, value must be in the scenes m_selectionStart.setX(dataRect.x()); m_selectionStart.setY(cSystem->mapLogicalToScene(logicalPos, CartesianCoordinateSystem::SuppressPageClipping).y()); } m_selectionEnd = m_selectionStart; m_selectionBandIsShown = true; } void CartesianPlotPrivate::mousePressCursorMode(int cursorNumber, QPointF logicalPos) { cursorNumber == 0 ? cursor0Enable = true : cursor1Enable = true; QPointF p1(logicalPos.x(), yMin); QPointF p2(logicalPos.x(), yMax); if (cursorNumber == 0) { cursor0Pos.setX(logicalPos.x()); cursor0Pos.setY(0); } else { cursor1Pos.setX(logicalPos.x()); cursor1Pos.setY(0); } update(); } void CartesianPlotPrivate::updateCursor() { update(); } void CartesianPlotPrivate::mouseMoveEvent(QGraphicsSceneMouseEvent* event) { if (mouseMode == CartesianPlot::SelectionMode) { if (panningStarted && dataRect.contains(event->pos()) ) { //don't retransform on small mouse movement deltas const int deltaXScene = (m_panningStart.x() - event->pos().x()); const int deltaYScene = (m_panningStart.y() - event->pos().y()); if (abs(deltaXScene) < 5 && abs(deltaYScene) < 5) return; const QPointF logicalEnd = cSystem->mapSceneToLogical(event->pos()); const QPointF logicalStart = cSystem->mapSceneToLogical(m_panningStart); const float deltaX = (logicalStart.x() - logicalEnd.x()); const float deltaY = (logicalStart.y() - logicalEnd.y()); xMax += deltaX; xMin += deltaX; yMax += deltaY; yMin += deltaY; q->setUndoAware(false); q->setAutoScaleX(false); q->setAutoScaleY(false); q->setUndoAware(true); retransformScales(); m_panningStart = event->pos(); } else QGraphicsItem::mouseMoveEvent(event); } else if (mouseMode == CartesianPlot::ZoomSelectionMode || mouseMode == CartesianPlot::ZoomXSelectionMode || mouseMode == CartesianPlot::ZoomYSelectionMode) { QGraphicsItem::mouseMoveEvent(event); if ( !boundingRect().contains(event->pos()) ) { q->info(QString()); return; } emit q->mouseMoveZoomSelectionModeSignal(cSystem->mapSceneToLogical(event->pos(), CartesianCoordinateSystem::MappingFlag::Limit)); } else if (mouseMode == CartesianPlot::Cursor) { QGraphicsItem::mouseMoveEvent(event); if (!boundingRect().contains(event->pos())) { q->info(i18n("Not inside of the bounding rect")); return; } QPointF logicalPos = cSystem->mapSceneToLogical(event->pos(), AbstractCoordinateSystem::MappingFlag::Limit); // updating treeview data and cursor position // updatign cursor position is done in Worksheet, because // multiple plots must be updated emit q->mouseMoveCursorModeSignal(selectedCursor, logicalPos); } } void CartesianPlotPrivate::mouseMoveZoomSelectionMode(QPointF logicalPos) { QString info; QPointF logicalStart = cSystem->mapSceneToLogical(m_selectionStart, CartesianCoordinateSystem::MappingFlag::SuppressPageClipping); if (mouseMode == CartesianPlot::ZoomSelectionMode) { m_selectionEnd = cSystem->mapLogicalToScene(logicalPos, CartesianCoordinateSystem::MappingFlag::SuppressPageClipping); QPointF logicalEnd = logicalPos; if (xRangeFormat == CartesianPlot::Numeric) info = QString::fromUtf8("Δx=") + QString::number(logicalEnd.x()-logicalStart.x()); else info = i18n("from x=%1 to x=%2", QDateTime::fromMSecsSinceEpoch(logicalStart.x()).toString(xRangeDateTimeFormat), QDateTime::fromMSecsSinceEpoch(logicalEnd.x()).toString(xRangeDateTimeFormat)); info += QLatin1String(", "); if (yRangeFormat == CartesianPlot::Numeric) info += QString::fromUtf8("Δy=") + QString::number(logicalEnd.y()-logicalStart.y()); else info += i18n("from y=%1 to y=%2", QDateTime::fromMSecsSinceEpoch(logicalStart.y()).toString(xRangeDateTimeFormat), QDateTime::fromMSecsSinceEpoch(logicalEnd.y()).toString(xRangeDateTimeFormat)); } else if (mouseMode == CartesianPlot::ZoomXSelectionMode) { logicalPos.setY(yMin); // must be done, because the other plots can have other ranges, value must be in the scenes m_selectionEnd.setX(cSystem->mapLogicalToScene(logicalPos, CartesianCoordinateSystem::MappingFlag::SuppressPageClipping).x());//event->pos().x()); m_selectionEnd.setY(dataRect.bottom()); QPointF logicalEnd = logicalPos; if (xRangeFormat == CartesianPlot::Numeric) info = QString::fromUtf8("Δx=") + QString::number(logicalEnd.x()-logicalStart.x()); else info = i18n("from x=%1 to x=%2", QDateTime::fromMSecsSinceEpoch(logicalStart.x()).toString(xRangeDateTimeFormat), QDateTime::fromMSecsSinceEpoch(logicalEnd.x()).toString(xRangeDateTimeFormat)); } else if (mouseMode == CartesianPlot::ZoomYSelectionMode) { m_selectionEnd.setX(dataRect.right()); logicalPos.setX(xMin); // must be done, because the other plots can have other ranges, value must be in the scenes m_selectionEnd.setY(cSystem->mapLogicalToScene(logicalPos, CartesianCoordinateSystem::MappingFlag::SuppressPageClipping).y());//event->pos().y()); QPointF logicalEnd = logicalPos; if (yRangeFormat == CartesianPlot::Numeric) info = QString::fromUtf8("Δy=") + QString::number(logicalEnd.y()-logicalStart.y()); else info = i18n("from y=%1 to y=%2", QDateTime::fromMSecsSinceEpoch(logicalStart.y()).toString(xRangeDateTimeFormat), QDateTime::fromMSecsSinceEpoch(logicalEnd.y()).toString(xRangeDateTimeFormat)); } q->info(info); update(); } void CartesianPlotPrivate::mouseMoveCursorMode(int cursorNumber, QPointF logicalPos) { QPointF p1(logicalPos.x(), 0); cursorNumber == 0 ? cursor0Pos = p1 : cursor1Pos = p1; QString info; if (xRangeFormat == CartesianPlot::Numeric) info = QString::fromUtf8("x=") + QString::number(logicalPos.x()); else info = i18n("x=%1", QDateTime::fromMSecsSinceEpoch(logicalPos.x()).toString(xRangeDateTimeFormat)); q->info(info); update(); } void CartesianPlotPrivate::mouseReleaseEvent(QGraphicsSceneMouseEvent* event) { setCursor(Qt::ArrowCursor); if (mouseMode == CartesianPlot::SelectionMode) { panningStarted = false; //TODO: why do we do this all the time?!?! const QPointF& itemPos = pos();//item's center point in parent's coordinates; const qreal x = itemPos.x(); const qreal y = itemPos.y(); //calculate the new rect and set it QRectF newRect; const qreal w = rect.width(); const qreal h = rect.height(); newRect.setX(x-w/2); newRect.setY(y-h/2); newRect.setWidth(w); newRect.setHeight(h); suppressRetransform = true; q->setRect(newRect); suppressRetransform = false; QGraphicsItem::mouseReleaseEvent(event); } else if (mouseMode == CartesianPlot::ZoomSelectionMode || mouseMode == CartesianPlot::ZoomXSelectionMode || mouseMode == CartesianPlot::ZoomYSelectionMode) { emit q->mouseReleaseZoomSelectionModeSignal(); } } void CartesianPlotPrivate::mouseReleaseZoomSelectionMode() { //don't zoom if very small region was selected, avoid occasional/unwanted zooming if ( qAbs(m_selectionEnd.x()-m_selectionStart.x()) < 20 || qAbs(m_selectionEnd.y()-m_selectionStart.y()) < 20 ) { m_selectionBandIsShown = false; return; } //determine the new plot ranges QPointF logicalZoomStart = cSystem->mapSceneToLogical(m_selectionStart, AbstractCoordinateSystem::SuppressPageClipping); QPointF logicalZoomEnd = cSystem->mapSceneToLogical(m_selectionEnd, AbstractCoordinateSystem::SuppressPageClipping); if (m_selectionEnd.x() > m_selectionStart.x()) { xMin = logicalZoomStart.x(); xMax = logicalZoomEnd.x(); } else { xMin = logicalZoomEnd.x(); xMax = logicalZoomStart.x(); } if (m_selectionEnd.y() > m_selectionStart.y()) { yMin = logicalZoomEnd.y(); yMax = logicalZoomStart.y(); } else { yMin = logicalZoomStart.y(); yMax = logicalZoomEnd.y(); } m_selectionBandIsShown = false; retransformScales(); } void CartesianPlotPrivate::wheelEvent(QGraphicsSceneWheelEvent* event) { if (locked) return; //determine first, which axes are selected and zoom only in the corresponding direction. //zoom the entire plot if no axes selected. bool zoomX = false; bool zoomY = false; for (auto* axis : q->children()) { if (!axis->graphicsItem()->isSelected()) continue; if (axis->orientation() == Axis::AxisHorizontal) zoomX = true; else zoomY = true; } if (event->delta() > 0) { if (!zoomX && !zoomY) { //no special axis selected -> zoom in everything q->zoomIn(); } else { if (zoomX) q->zoomInX(); if (zoomY) q->zoomInY(); } } else { if (!zoomX && !zoomY) { //no special axis selected -> zoom in everything q->zoomOut(); } else { if (zoomX) q->zoomOutX(); if (zoomY) q->zoomOutY(); } } } void CartesianPlotPrivate::keyPressEvent(QKeyEvent * event) { if (event->key() == Qt::Key_Escape) { setCursor(Qt::ArrowCursor); q->setMouseMode(CartesianPlot::MouseMode::SelectionMode); m_selectionBandIsShown = false; } QGraphicsItem::keyPressEvent(event); } void CartesianPlotPrivate::hoverMoveEvent(QGraphicsSceneHoverEvent* event) { QPointF point = event->pos(); QString info; if (dataRect.contains(point)) { m_insideDataRect = true; QPointF logicalPoint = cSystem->mapSceneToLogical(point); if ((mouseMode == CartesianPlot::ZoomSelectionMode) || mouseMode == CartesianPlot::SelectionMode) { info = "x="; if (xRangeFormat == CartesianPlot::Numeric) info += QString::number(logicalPoint.x()); else info += QDateTime::fromMSecsSinceEpoch(logicalPoint.x()).toString(xRangeDateTimeFormat); info += ", y="; if (yRangeFormat == CartesianPlot::Numeric) info += QString::number(logicalPoint.y()); else info += QDateTime::fromMSecsSinceEpoch(logicalPoint.y()).toString(yRangeDateTimeFormat); } if (mouseMode == CartesianPlot::ZoomSelectionMode && !m_selectionBandIsShown) { emit q->mouseHoverZoomSelectionModeSignal(logicalPoint); } else if (mouseMode == CartesianPlot::ZoomXSelectionMode && !m_selectionBandIsShown) { info = "x="; if (xRangeFormat == CartesianPlot::Numeric) info += QString::number(logicalPoint.x()); else info += QDateTime::fromMSecsSinceEpoch(logicalPoint.x()).toString(xRangeDateTimeFormat); emit q->mouseHoverZoomSelectionModeSignal(logicalPoint); } else if (mouseMode == CartesianPlot::ZoomYSelectionMode && !m_selectionBandIsShown) { info = "y="; if (yRangeFormat == CartesianPlot::Numeric) info += QString::number(logicalPoint.y()); else info += QDateTime::fromMSecsSinceEpoch(logicalPoint.y()).toString(yRangeDateTimeFormat); emit q->mouseHoverZoomSelectionModeSignal(logicalPoint); } else if (mouseMode == CartesianPlot::MouseMode::SelectionMode) { // hover the nearest curve to the mousepointer // hovering curves is implemented in the parent, because no ignoreEvent() exists // for it. Checking all curves and hover the first bool curve_hovered = false; QVector curves = q->children(); for (int i=curves.count() - 1; i >= 0; i--){ // because the last curve is above the other curves if (curve_hovered){ // if a curve is already hovered, disable hover for the rest curves[i]->setHover(false); continue; } if (curves[i]->activateCurve(event->pos())){ curves[i]->setHover(true); curve_hovered = true; continue; } curves[i]->setHover(false); } } else if (mouseMode == CartesianPlot::Cursor){ info = "x="; if (yRangeFormat == CartesianPlot::Numeric) info += QString::number(logicalPoint.x()); else info += QDateTime::fromMSecsSinceEpoch(logicalPoint.x()).toString(xRangeDateTimeFormat); double cursorPenWidth2 = cursorPen.width()/2.; if (cursorPenWidth2 < 10.) cursorPenWidth2 = 10.; if ((cursor0Enable && qAbs(point.x()-cSystem->mapLogicalToScene(QPointF(cursor0Pos.x(),yMin)).x()) < cursorPenWidth2) || (cursor1Enable && qAbs(point.x()-cSystem->mapLogicalToScene(QPointF(cursor1Pos.x(),yMin)).x()) < cursorPenWidth2)) setCursor(Qt::SizeHorCursor); else setCursor(Qt::ArrowCursor); update(); } } else { m_insideDataRect = false; update(); } q->info(info); QGraphicsItem::hoverMoveEvent(event); } void CartesianPlotPrivate::hoverLeaveEvent(QGraphicsSceneHoverEvent* event) { QVector curves = q->children(); for (auto* curve : curves) curve->setHover(false); m_hovered = false; QGraphicsItem::hoverLeaveEvent(event); } void CartesianPlotPrivate::mouseHoverZoomSelectionMode(QPointF logicPos) { if (!isSelected()) return; if (mouseMode == CartesianPlot::ZoomSelectionMode && !m_selectionBandIsShown) { } else if (mouseMode == CartesianPlot::ZoomXSelectionMode && !m_selectionBandIsShown) { QPointF p1(logicPos.x(), yMin); QPointF p2(logicPos.x(), yMax); m_selectionStartLine.setP1(cSystem->mapLogicalToScene(p1, CartesianCoordinateSystem::MappingFlag::Limit)); m_selectionStartLine.setP2(cSystem->mapLogicalToScene(p2, CartesianCoordinateSystem::MappingFlag::Limit)); } else if (mouseMode == CartesianPlot::ZoomYSelectionMode && !m_selectionBandIsShown) { QPointF p1(xMin, logicPos.y()); QPointF p2(xMax, logicPos.y()); m_selectionStartLine.setP1(cSystem->mapLogicalToScene(p1, CartesianCoordinateSystem::MappingFlag::Limit)); m_selectionStartLine.setP2(cSystem->mapLogicalToScene(p2, CartesianCoordinateSystem::MappingFlag::Limit)); } update(); // because if previous another selection mode was selected, the lines must be deleted } void CartesianPlotPrivate::paint(QPainter* painter, const QStyleOptionGraphicsItem* option, QWidget* widget) { Q_UNUSED(option) Q_UNUSED(widget) if (!isVisible()) return; if (!m_printing) { painter->save(); painter->setPen(cursorPen); QFont font = painter->font(); font.setPointSize(font.pointSize() * 4); painter->setFont(font); QPointF p1 = cSystem->mapLogicalToScene(QPointF(cursor0Pos.x(),yMin)); if (cursor0Enable && p1 != QPointF(0,0)){ QPointF p2 = cSystem->mapLogicalToScene(QPointF(cursor0Pos.x(),yMax)); painter->drawLine(p1,p2); QPointF textPos = p2; textPos.setX(p2.x() - m_cursor0Text.size().width()/2); textPos.setY(p2.y() - m_cursor0Text.size().height()); if (textPos.y() < boundingRect().y()) textPos.setY(boundingRect().y()); painter->drawStaticText(textPos, m_cursor0Text); } p1 = cSystem->mapLogicalToScene(QPointF(cursor1Pos.x(),yMin)); if (cursor1Enable && p1 != QPointF(0,0)){ QPointF p2 = cSystem->mapLogicalToScene(QPointF(cursor1Pos.x(),yMax)); painter->drawLine(p1,p2); QPointF textPos = p2; // TODO: Moving this stuff into other function to not calculate it every time textPos.setX(p2.x() - m_cursor1Text.size().width()/2); textPos.setY(p2.y() - m_cursor1Text.size().height()); if (textPos.y() < boundingRect().y()) textPos.setY(boundingRect().y()); painter->drawStaticText(textPos, m_cursor1Text); } painter->restore(); } painter->setPen(QPen(Qt::black, 3)); if ((mouseMode == CartesianPlot::ZoomXSelectionMode || mouseMode == CartesianPlot::ZoomYSelectionMode) && (!m_selectionBandIsShown) && m_insideDataRect) painter->drawLine(m_selectionStartLine); if (m_selectionBandIsShown) { QPointF selectionStart = m_selectionStart; if (m_selectionStart.x() > dataRect.right()) selectionStart.setX(dataRect.right()); if (m_selectionStart.x() < dataRect.left()) selectionStart.setX(dataRect.left()); if (m_selectionStart.y() > dataRect.bottom()) selectionStart.setY(dataRect.bottom()); if (m_selectionStart.y() < dataRect.top()) selectionStart.setY(dataRect.top()); QPointF selectionEnd = m_selectionEnd; if (m_selectionEnd.x() > dataRect.right()) selectionEnd.setX(dataRect.right()); if (m_selectionEnd.x() < dataRect.left()) selectionEnd.setX(dataRect.left()); if (m_selectionEnd.y() > dataRect.bottom()) selectionEnd.setY(dataRect.bottom()); if (m_selectionEnd.y() < dataRect.top()) selectionEnd.setY(dataRect.top()); painter->save(); painter->setPen(QPen(Qt::black, 5)); painter->drawRect(QRectF(selectionStart, selectionEnd)); painter->setBrush(Qt::blue); painter->setOpacity(0.2); painter->drawRect(QRectF(selectionStart, selectionEnd)); painter->restore(); } float penWidth = 6.; QRectF rect = q->m_plotArea->graphicsItem()->boundingRect(); rect = QRectF(-rect.width()/2 - penWidth / 2, -rect.height()/2 - penWidth / 2, rect.width() + penWidth, rect.height() + penWidth); if (m_hovered && !isSelected() && !m_printing) { painter->setPen(QPen(QApplication::palette().color(QPalette::Shadow), penWidth, Qt::SolidLine)); painter->drawRect(rect); } if (isSelected() && !m_printing) { painter->setPen(QPen(QApplication::palette().color(QPalette::Highlight), penWidth, Qt::SolidLine)); painter->drawRect(rect); } } //############################################################################## //################## Serialization/Deserialization ########################### //############################################################################## //! Save as XML void CartesianPlot::save(QXmlStreamWriter* writer) const { Q_D(const CartesianPlot); writer->writeStartElement( "cartesianPlot" ); writeBasicAttributes(writer); writeCommentElement(writer); //applied theme if (!d->theme.isEmpty()) { writer->writeStartElement( "theme" ); writer->writeAttribute("name", d->theme); writer->writeEndElement(); } //cursor writer->writeStartElement( "cursor" ); WRITE_QPEN(d->cursorPen); writer->writeEndElement(); //geometry writer->writeStartElement( "geometry" ); writer->writeAttribute( "x", QString::number(d->rect.x()) ); writer->writeAttribute( "y", QString::number(d->rect.y()) ); writer->writeAttribute( "width", QString::number(d->rect.width()) ); writer->writeAttribute( "height", QString::number(d->rect.height()) ); writer->writeAttribute( "visible", QString::number(d->isVisible()) ); writer->writeEndElement(); //coordinate system and padding writer->writeStartElement( "coordinateSystem" ); writer->writeAttribute( "autoScaleX", QString::number(d->autoScaleX) ); writer->writeAttribute( "autoScaleY", QString::number(d->autoScaleY) ); writer->writeAttribute( "xMin", QString::number(d->xMin, 'g', 16)); writer->writeAttribute( "xMax", QString::number(d->xMax, 'g', 16) ); writer->writeAttribute( "yMin", QString::number(d->yMin, 'g', 16) ); writer->writeAttribute( "yMax", QString::number(d->yMax, 'g', 16) ); writer->writeAttribute( "xScale", QString::number(d->xScale) ); writer->writeAttribute( "yScale", QString::number(d->yScale) ); writer->writeAttribute( "xRangeFormat", QString::number(d->xRangeFormat) ); writer->writeAttribute( "yRangeFormat", QString::number(d->yRangeFormat) ); writer->writeAttribute( "horizontalPadding", QString::number(d->horizontalPadding) ); writer->writeAttribute( "verticalPadding", QString::number(d->verticalPadding) ); writer->writeAttribute( "rightPadding", QString::number(d->rightPadding) ); writer->writeAttribute( "bottomPadding", QString::number(d->bottomPadding) ); writer->writeAttribute( "symmetricPadding", QString::number(d->symmetricPadding)); writer->writeEndElement(); //x-scale breaks if (d->xRangeBreakingEnabled || !d->xRangeBreaks.list.isEmpty()) { writer->writeStartElement("xRangeBreaks"); writer->writeAttribute( "enabled", QString::number(d->xRangeBreakingEnabled) ); for (const auto& rb : d->xRangeBreaks.list) { writer->writeStartElement("xRangeBreak"); writer->writeAttribute("start", QString::number(rb.start)); writer->writeAttribute("end", QString::number(rb.end)); writer->writeAttribute("position", QString::number(rb.position)); writer->writeAttribute("style", QString::number(rb.style)); writer->writeEndElement(); } writer->writeEndElement(); } //y-scale breaks if (d->yRangeBreakingEnabled || !d->yRangeBreaks.list.isEmpty()) { writer->writeStartElement("yRangeBreaks"); writer->writeAttribute( "enabled", QString::number(d->yRangeBreakingEnabled) ); for (const auto& rb : d->yRangeBreaks.list) { writer->writeStartElement("yRangeBreak"); writer->writeAttribute("start", QString::number(rb.start)); writer->writeAttribute("end", QString::number(rb.end)); writer->writeAttribute("position", QString::number(rb.position)); writer->writeAttribute("style", QString::number(rb.style)); writer->writeEndElement(); } writer->writeEndElement(); } //serialize all children (plot area, title text label, axes and curves) for (auto* elem : children(IncludeHidden)) elem->save(writer); writer->writeEndElement(); // close "cartesianPlot" section } //! Load from XML bool CartesianPlot::load(XmlStreamReader* reader, bool preview) { Q_D(CartesianPlot); if (!readBasicAttributes(reader)) return false; KLocalizedString attributeWarning = ki18n("Attribute '%1' missing or empty, default value is used"); QXmlStreamAttributes attribs; QString str; bool titleLabelRead = false; while (!reader->atEnd()) { reader->readNext(); if (reader->isEndElement() && reader->name() == "cartesianPlot") break; if (!reader->isStartElement()) continue; if (reader->name() == "comment") { if (!readCommentElement(reader)) return false; } else if (!preview && reader->name() == "theme") { attribs = reader->attributes(); d->theme = attribs.value("name").toString(); } else if (!preview && reader->name() == "cursor") { attribs = reader->attributes(); QPen pen; pen.setWidth(attribs.value("width").toInt()); pen.setStyle(static_cast(attribs.value("style").toInt())); QColor color; color.setRed(attribs.value("color_r").toInt()); color.setGreen(attribs.value("color_g").toInt()); color.setBlue(attribs.value("color_b").toInt()); pen.setColor(color); d->cursorPen = pen; } else if (!preview && reader->name() == "geometry") { attribs = reader->attributes(); str = attribs.value("x").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("x").toString()); else d->rect.setX( str.toDouble() ); str = attribs.value("y").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("y").toString()); else d->rect.setY( str.toDouble() ); str = attribs.value("width").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("width").toString()); else d->rect.setWidth( str.toDouble() ); str = attribs.value("height").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("height").toString()); else d->rect.setHeight( str.toDouble() ); str = attribs.value("visible").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("visible").toString()); else d->setVisible(str.toInt()); } else if (!preview && reader->name() == "coordinateSystem") { attribs = reader->attributes(); READ_INT_VALUE("autoScaleX", autoScaleX, bool); READ_INT_VALUE("autoScaleY", autoScaleY, bool); str = attribs.value("xMin").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("xMin").toString()); else { d->xMin = str.toDouble(); d->xMinPrev = d->xMin; } str = attribs.value("xMax").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("xMax").toString()); else { d->xMax = str.toDouble(); d->xMaxPrev = d->xMax; } str = attribs.value("yMin").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("yMin").toString()); else { d->yMin = str.toDouble(); d->yMinPrev = d->yMin; } str = attribs.value("yMax").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("yMax").toString()); else { d->yMax = str.toDouble(); d->yMaxPrev = d->yMax; } READ_INT_VALUE("xScale", xScale, CartesianPlot::Scale); READ_INT_VALUE("yScale", yScale, CartesianPlot::Scale); READ_INT_VALUE("xRangeFormat", xRangeFormat, CartesianPlot::RangeFormat); READ_INT_VALUE("yRangeFormat", yRangeFormat, CartesianPlot::RangeFormat); READ_DOUBLE_VALUE("horizontalPadding", horizontalPadding); READ_DOUBLE_VALUE("verticalPadding", verticalPadding); READ_DOUBLE_VALUE("rightPadding", rightPadding); READ_DOUBLE_VALUE("bottomPadding", bottomPadding); READ_INT_VALUE("symmetricPadding", symmetricPadding, bool); } else if (!preview && reader->name() == "xRangeBreaks") { //delete default rang break d->xRangeBreaks.list.clear(); attribs = reader->attributes(); READ_INT_VALUE("enabled", xRangeBreakingEnabled, bool); } else if (!preview && reader->name() == "xRangeBreak") { attribs = reader->attributes(); RangeBreak b; str = attribs.value("start").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("start").toString()); else b.start = str.toDouble(); str = attribs.value("end").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("end").toString()); else b.end = str.toDouble(); str = attribs.value("position").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("position").toString()); else b.position = str.toDouble(); str = attribs.value("style").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("style").toString()); else b.style = CartesianPlot::RangeBreakStyle(str.toInt()); d->xRangeBreaks.list << b; } else if (!preview && reader->name() == "yRangeBreaks") { //delete default rang break d->yRangeBreaks.list.clear(); attribs = reader->attributes(); READ_INT_VALUE("enabled", yRangeBreakingEnabled, bool); } else if (!preview && reader->name() == "yRangeBreak") { attribs = reader->attributes(); RangeBreak b; str = attribs.value("start").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("start").toString()); else b.start = str.toDouble(); str = attribs.value("end").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("end").toString()); else b.end = str.toDouble(); str = attribs.value("position").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("position").toString()); else b.position = str.toDouble(); str = attribs.value("style").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("style").toString()); else b.style = CartesianPlot::RangeBreakStyle(str.toInt()); d->yRangeBreaks.list << b; } else if (reader->name() == "textLabel") { if (!titleLabelRead) { //the first text label is always the title label m_title->load(reader, preview); titleLabelRead = true; //TODO: the name is read in m_title->load() but we overwrite it here //since the old projects don't have this " - Title" appendix yet that we add in init(). //can be removed in couple of releases m_title->setName(name() + QLatin1String(" - ") + i18n("Title")); } else { TextLabel* label = new TextLabel("text label"); if (label->load(reader, preview)) { addChildFast(label); label->setParentGraphicsItem(graphicsItem()); } else { delete label; return false; } } } else if (reader->name() == "plotArea") m_plotArea->load(reader, preview); else if (reader->name() == "axis") { Axis* axis = new Axis(QString()); if (axis->load(reader, preview)) addChildFast(axis); else { delete axis; return false; } } else if (reader->name() == "xyCurve") { XYCurve* curve = new XYCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyEquationCurve") { XYEquationCurve* curve = new XYEquationCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyDataReductionCurve") { XYDataReductionCurve* curve = new XYDataReductionCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyDifferentiationCurve") { XYDifferentiationCurve* curve = new XYDifferentiationCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyIntegrationCurve") { XYIntegrationCurve* curve = new XYIntegrationCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyInterpolationCurve") { XYInterpolationCurve* curve = new XYInterpolationCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xySmoothCurve") { XYSmoothCurve* curve = new XYSmoothCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyFitCurve") { XYFitCurve* curve = new XYFitCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyFourierFilterCurve") { XYFourierFilterCurve* curve = new XYFourierFilterCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyFourierTransformCurve") { XYFourierTransformCurve* curve = new XYFourierTransformCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyConvolutionCurve") { XYConvolutionCurve* curve = new XYConvolutionCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "xyCorrelationCurve") { XYCorrelationCurve* curve = new XYCorrelationCurve(QString()); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else if (reader->name() == "cartesianPlotLegend") { m_legend = new CartesianPlotLegend(this, QString()); if (m_legend->load(reader, preview)) addChildFast(m_legend); else { delete m_legend; return false; } } else if (reader->name() == "customPoint") { CustomPoint* point = new CustomPoint(this, QString()); if (point->load(reader, preview)) addChildFast(point); else { delete point; return false; } } else if (reader->name() == "Histogram") { Histogram* curve = new Histogram("Histogram"); if (curve->load(reader, preview)) addChildFast(curve); else { removeChild(curve); return false; } } else { // unknown element reader->raiseWarning(i18n("unknown cartesianPlot element '%1'", reader->name().toString())); if (!reader->skipToEndElement()) return false; } } if (preview) return true; d->retransform(); //if a theme was used, initialize the color palette if (!d->theme.isEmpty()) { //TODO: check whether the theme config really exists KConfig config( ThemeHandler::themeFilePath(d->theme), KConfig::SimpleConfig ); this->setColorPalette(config); } else { //initialize the color palette with default colors this->setColorPalette(KConfig()); } return true; } //############################################################################## //######################### Theme management ################################## //############################################################################## void CartesianPlot::loadTheme(const QString& theme) { KConfig config(ThemeHandler::themeFilePath(theme), KConfig::SimpleConfig); loadThemeConfig(config); } void CartesianPlot::loadThemeConfig(const KConfig& config) { QString str = config.name(); // theme path is saved with UNIX dir separator str = str.right(str.length() - str.lastIndexOf(QLatin1Char('/')) - 1); DEBUG(" set theme to " << str.toStdString()); this->setTheme(str); //load the color palettes for the curves this->setColorPalette(config); //load the theme for all the children for (auto* child : children(AbstractAspect::IncludeHidden)) child->loadThemeConfig(config); Q_D(CartesianPlot); d->update(this->rect()); } void CartesianPlot::saveTheme(KConfig &config) { const QVector& axisElements = children(AbstractAspect::IncludeHidden); const QVector& plotAreaElements = children(AbstractAspect::IncludeHidden); const QVector& textLabelElements = children(AbstractAspect::IncludeHidden); axisElements.at(0)->saveThemeConfig(config); plotAreaElements.at(0)->saveThemeConfig(config); textLabelElements.at(0)->saveThemeConfig(config); for (auto *child : children(AbstractAspect::IncludeHidden)) child->saveThemeConfig(config); } //Generating colors from 5-color theme palette void CartesianPlot::setColorPalette(const KConfig& config) { if (config.hasGroup(QLatin1String("Theme"))) { KConfigGroup group = config.group(QLatin1String("Theme")); //read the five colors defining the palette m_themeColorPalette.clear(); m_themeColorPalette.append(group.readEntry("ThemePaletteColor1", QColor())); m_themeColorPalette.append(group.readEntry("ThemePaletteColor2", QColor())); m_themeColorPalette.append(group.readEntry("ThemePaletteColor3", QColor())); m_themeColorPalette.append(group.readEntry("ThemePaletteColor4", QColor())); m_themeColorPalette.append(group.readEntry("ThemePaletteColor5", QColor())); } else { //no theme is available, provide 5 "default colors" m_themeColorPalette.clear(); m_themeColorPalette.append(QColor(25, 25, 25)); m_themeColorPalette.append(QColor(0, 0, 127)); m_themeColorPalette.append(QColor(127 ,0, 0)); m_themeColorPalette.append(QColor(0, 127, 0)); m_themeColorPalette.append(QColor(85, 0, 127)); } //generate 30 additional shades if the color palette contains more than one color if (m_themeColorPalette.at(0) != m_themeColorPalette.at(1)) { QColor c; //3 factors to create shades from theme's palette float fac[3] = {0.25f,0.45f,0.65f}; //Generate 15 lighter shades for (int i = 0; i < 5; i++) { for (int j = 1; j < 4; j++) { c.setRed( m_themeColorPalette.at(i).red()*(1-fac[j-1]) ); c.setGreen( m_themeColorPalette.at(i).green()*(1-fac[j-1]) ); c.setBlue( m_themeColorPalette.at(i).blue()*(1-fac[j-1]) ); m_themeColorPalette.append(c); } } //Generate 15 darker shades for (int i = 0; i < 5; i++) { for (int j = 4; j < 7; j++) { c.setRed( m_themeColorPalette.at(i).red()+((255-m_themeColorPalette.at(i).red())*fac[j-4]) ); c.setGreen( m_themeColorPalette.at(i).green()+((255-m_themeColorPalette.at(i).green())*fac[j-4]) ); c.setBlue( m_themeColorPalette.at(i).blue()+((255-m_themeColorPalette.at(i).blue())*fac[j-4]) ); m_themeColorPalette.append(c); } } } } const QList& CartesianPlot::themeColorPalette() const { return m_themeColorPalette; } diff --git a/src/commonfrontend/ProjectExplorer.cpp b/src/commonfrontend/ProjectExplorer.cpp index 4bfb3c2bb..8becf5534 100644 --- a/src/commonfrontend/ProjectExplorer.cpp +++ b/src/commonfrontend/ProjectExplorer.cpp @@ -1,888 +1,888 @@ /*************************************************************************** File : ProjectExplorer.cpp Project : LabPlot Description : A tree view for displaying and editing an AspectTreeModel. -------------------------------------------------------------------- Copyright : (C) 2007-2008 by Tilman Benkert (thzs@gmx.net) Copyright : (C) 2010-2018 Alexander Semke (alexander.semke@web.de) ***************************************************************************/ /*************************************************************************** * * * 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. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the Free Software * * Foundation, Inc., 51 Franklin Street, Fifth Floor, * * Boston, MA 02110-1301 USA * * * ***************************************************************************/ #include "ProjectExplorer.h" #include "backend/core/AspectTreeModel.h" #include "backend/core/AbstractPart.h" #include "backend/core/Project.h" #include "backend/lib/XmlStreamReader.h" #include "backend/worksheet/plots/cartesian/CartesianPlot.h" #include "commonfrontend/core/PartMdiView.h" #include #include #include #include #include #include #include #include #include #include #include #include /*! \class ProjectExplorer \brief A tree view for displaying and editing an AspectTreeModel. In addition to the functionality of QTreeView, ProjectExplorer allows the usage of the context menus provided by AspectTreeModel and propagates the item selection in the view to the model. Furthermore, features for searching and filtering in the model are provided. \ingroup commonfrontend */ ProjectExplorer::ProjectExplorer(QWidget* parent) : m_treeView(new QTreeView(parent)), m_frameFilter(new QFrame(this)) { auto* layout = new QVBoxLayout(this); layout->setSpacing(0); layout->setContentsMargins(0, 0, 0, 0); auto* layoutFilter = new QHBoxLayout(m_frameFilter); layoutFilter->setSpacing(0); layoutFilter->setContentsMargins(0, 0, 0, 0); QLabel* lFilter = new QLabel(i18n("Search/Filter:")); layoutFilter->addWidget(lFilter); m_leFilter = new QLineEdit(m_frameFilter); m_leFilter->setClearButtonEnabled(true); m_leFilter->setPlaceholderText(i18n("Search/Filter text")); layoutFilter->addWidget(m_leFilter); bFilterOptions = new QPushButton(m_frameFilter); bFilterOptions->setIcon(QIcon::fromTheme("configure")); bFilterOptions->setCheckable(true); layoutFilter->addWidget(bFilterOptions); layout->addWidget(m_frameFilter); m_treeView->setAnimated(true); m_treeView->setAlternatingRowColors(true); m_treeView->setSelectionBehavior(QAbstractItemView::SelectRows); m_treeView->setSelectionMode(QAbstractItemView::ExtendedSelection); m_treeView->setUniformRowHeights(true); m_treeView->viewport()->installEventFilter(this); m_treeView->header()->setStretchLastSection(true); m_treeView->header()->installEventFilter(this); m_treeView->setDragEnabled(true); m_treeView->setAcceptDrops(true); m_treeView->setDropIndicatorShown(true); m_treeView->setDragDropMode(QAbstractItemView::InternalMove); layout->addWidget(m_treeView); this->createActions(); connect(m_leFilter, &QLineEdit::textChanged, this, &ProjectExplorer::filterTextChanged); connect(bFilterOptions, &QPushButton::toggled, this, &ProjectExplorer::toggleFilterOptionsMenu); } void ProjectExplorer::createActions() { caseSensitiveAction = new QAction(i18n("Case Sensitive"), this); caseSensitiveAction->setCheckable(true); caseSensitiveAction->setChecked(false); connect(caseSensitiveAction, &QAction::triggered, this, &ProjectExplorer::toggleFilterCaseSensitivity); matchCompleteWordAction = new QAction(i18n("Match Complete Word"), this); matchCompleteWordAction->setCheckable(true); matchCompleteWordAction->setChecked(false); connect(matchCompleteWordAction, &QAction::triggered, this, &ProjectExplorer::toggleFilterMatchCompleteWord); expandTreeAction = new QAction(QIcon::fromTheme(QLatin1String("expand-all")), i18n("Expand All"), this); connect(expandTreeAction, &QAction::triggered, m_treeView, &QTreeView::expandAll); expandSelectedTreeAction = new QAction(QIcon::fromTheme(QLatin1String("expand-all")), i18n("Expand Selected"), this); connect(expandSelectedTreeAction, &QAction::triggered, this, &ProjectExplorer::expandSelected); collapseTreeAction = new QAction(QIcon::fromTheme(QLatin1String("collapse-all")), i18n("Collapse All"), this); connect(collapseTreeAction, &QAction::triggered, m_treeView, &QTreeView::collapseAll); collapseSelectedTreeAction = new QAction(QIcon::fromTheme(QLatin1String("collapse-all")), i18n("Collapse Selected"), this); connect(collapseSelectedTreeAction, &QAction::triggered, this, &ProjectExplorer::collapseSelected); deleteSelectedTreeAction = new QAction(QIcon::fromTheme("edit-delete"), i18n("Delete Selected"), this); connect(deleteSelectedTreeAction, &QAction::triggered, this, &ProjectExplorer::deleteSelected); toggleFilterAction = new QAction(QIcon::fromTheme(QLatin1String("view-filter")), i18n("Hide Search/Filter Options"), this); connect(toggleFilterAction, &QAction::triggered, this, &ProjectExplorer::toggleFilterWidgets); showAllColumnsAction = new QAction(i18n("Show All"),this); showAllColumnsAction->setCheckable(true); showAllColumnsAction->setChecked(true); showAllColumnsAction->setEnabled(false); connect(showAllColumnsAction, &QAction::triggered, this, &ProjectExplorer::showAllColumns); } /*! shows the context menu in the tree. In addition to the context menu of the currently selected aspect, treeview specific options are added. */ void ProjectExplorer::contextMenuEvent(QContextMenuEvent *event) { if (!m_treeView->model()) return; const QModelIndex& index = m_treeView->indexAt(m_treeView->viewport()->mapFrom(this, event->pos())); if (!index.isValid()) m_treeView->clearSelection(); const QModelIndexList& items = m_treeView->selectionModel()->selectedIndexes(); QMenu* menu = nullptr; if (items.size()/4 == 1) { auto* aspect = static_cast(index.internalPointer()); menu = aspect->createContextMenu(); } else { menu = new QMenu(); QMenu* projectMenu = m_project->createContextMenu(); projectMenu->setTitle(m_project->name()); menu->addMenu(projectMenu); menu->addSeparator(); if (items.size()/4 > 1) { menu->addAction(expandSelectedTreeAction); menu->addAction(collapseSelectedTreeAction); menu->addSeparator(); menu->addAction(deleteSelectedTreeAction); menu->addSeparator(); } else { menu->addAction(expandTreeAction); menu->addAction(collapseTreeAction); menu->addSeparator(); menu->addAction(toggleFilterAction); //Menu for showing/hiding the columns in the tree view QMenu* columnsMenu = menu->addMenu(i18n("Show/Hide columns")); columnsMenu->addAction(showAllColumnsAction); columnsMenu->addSeparator(); for (auto* action : list_showColumnActions) columnsMenu->addAction(action); //TODO //Menu for showing/hiding the top-level aspects (Worksheet, Spreadhsheet, etc) in the tree view // QMenu* objectsMenu = menu->addMenu(i18n("Show/Hide objects")); } } if (menu) menu->exec(event->globalPos()); delete menu; } void ProjectExplorer::setCurrentAspect(const AbstractAspect* aspect) { const AspectTreeModel* tree_model = qobject_cast(m_treeView->model()); if (tree_model) m_treeView->setCurrentIndex(tree_model->modelIndexOfAspect(aspect)); } /*! Sets the \c model for the tree view to present. */ void ProjectExplorer::setModel(AspectTreeModel* treeModel) { m_treeView->setModel(treeModel); connect(treeModel, &AspectTreeModel::renameRequested, m_treeView, static_cast(&QAbstractItemView::edit)); connect(treeModel, &AspectTreeModel::indexSelected, this, &ProjectExplorer::selectIndex); connect(treeModel, &AspectTreeModel::indexDeselected, this, &ProjectExplorer::deselectIndex); connect(treeModel, &AspectTreeModel::hiddenAspectSelected, this, &ProjectExplorer::hiddenAspectSelected); connect(m_treeView->selectionModel(), &QItemSelectionModel::currentChanged, this, &ProjectExplorer::currentChanged); connect(m_treeView->selectionModel(), &QItemSelectionModel::selectionChanged, this, &ProjectExplorer::selectionChanged); //create action for showing/hiding the columns in the tree. //this is done here since the number of columns is not available in createActions() yet. if (list_showColumnActions.size() == 0) { for (int i = 0; i < m_treeView->model()->columnCount(); i++) { QAction* showColumnAction = new QAction(treeModel->headerData(i, Qt::Horizontal).toString(), this); showColumnAction->setCheckable(true); showColumnAction->setChecked(true); list_showColumnActions.append(showColumnAction); connect(showColumnAction, &QAction::triggered, this, [=] { ProjectExplorer::toggleColumn(i); }); } } else { for (int i = 0; i < list_showColumnActions.size(); ++i) { if (!list_showColumnActions.at(i)->isChecked()) m_treeView->hideColumn(i); } } } void ProjectExplorer::setProject(Project* project) { connect(project, &Project::aspectAdded, this, &ProjectExplorer::aspectAdded); connect(project, &Project::requestSaveState, this, &ProjectExplorer::save); connect(project, &Project::requestLoadState, this, &ProjectExplorer::load); connect(project, &Project::requestNavigateTo, this, &ProjectExplorer::navigateTo); connect(project, &Project::loaded, this, &ProjectExplorer::resizeHeader); m_project = project; //for newly created projects, resize the header to fit the size of the header section names. //for projects loaded from a file, this function will be called laterto fit the sizes //of the content once the project is loaded resizeHeader(); } QModelIndex ProjectExplorer::currentIndex() const { return m_treeView->currentIndex(); } /*! handles the contextmenu-event of the horizontal header in the tree view. Provides a menu for selective showing and hiding of columns. */ bool ProjectExplorer::eventFilter(QObject* obj, QEvent* event) { if (obj == m_treeView->header() && event->type() == QEvent::ContextMenu) { //Menu for showing/hiding the columns in the tree view QMenu* columnsMenu = new QMenu(m_treeView->header()); columnsMenu->addSection(i18n("Columns")); columnsMenu->addAction(showAllColumnsAction); columnsMenu->addSeparator(); for (auto* action : list_showColumnActions) columnsMenu->addAction(action); auto* e = static_cast(event); columnsMenu->exec(e->globalPos()); delete columnsMenu; return true; } else if (obj == m_treeView->viewport()) { auto* e = static_cast(event); if (event->type() == QEvent::MouseButtonPress) { if (e->button() == Qt::LeftButton) { QModelIndex index = m_treeView->indexAt(e->pos()); if (!index.isValid()) return false; auto* aspect = static_cast(index.internalPointer()); if (aspect->isDraggable()) { m_dragStartPos = e->globalPos(); m_dragStarted = false; } } } else if (event->type() == QEvent::MouseMove) { if ( !m_dragStarted && m_treeView->selectionModel()->selectedIndexes().size() > 0 && (e->globalPos() - m_dragStartPos).manhattanLength() >= QApplication::startDragDistance()) { m_dragStarted = true; auto* drag = new QDrag(this); auto* mimeData = new QMimeData; //determine the selected objects and serialize the pointers to QMimeData QVector vec; QModelIndexList items = m_treeView->selectionModel()->selectedIndexes(); //there are four model indices in each row -> divide by 4 to obtain the number of selected rows (=aspects) for (int i = 0; i < items.size()/4; ++i) { const QModelIndex& index = items.at(i*4); auto* aspect = static_cast(index.internalPointer()); vec << (quintptr)aspect; } QByteArray data; QDataStream stream(&data, QIODevice::WriteOnly); stream << vec; mimeData->setData("labplot-dnd", data); drag->setMimeData(mimeData); drag->exec(); } } else if (event->type() == QEvent::DragEnter) { //ignore events not related to internal drags of columns etc., e.g. dropping of external files onto LabPlot auto* dragEnterEvent = static_cast(event); const QMimeData* mimeData = dragEnterEvent->mimeData(); if (!mimeData) { event->ignore(); return false; } if (mimeData->formats().at(0) != QLatin1String("labplot-dnd")) { event->ignore(); return false; } event->setAccepted(true); } else if (event->type() == QEvent::DragMove) { auto* dragMoveEvent = static_cast(event); const QMimeData* mimeData = dragMoveEvent->mimeData(); //determine the first aspect being dragged QByteArray data = mimeData->data(QLatin1String("labplot-dnd")); QVector vec; QDataStream stream(&data, QIODevice::ReadOnly); stream >> vec; AbstractAspect* sourceAspect{nullptr}; if (!vec.isEmpty()) sourceAspect = (AbstractAspect*)vec.at(0); if (!sourceAspect) return false; //determine the aspect under the cursor QModelIndex index = m_treeView->indexAt(dragMoveEvent->pos()); if (!index.isValid()) return false; //accept only the events when the aspect being dragged is dropable onto the aspect under the cursor //and the aspect under the cursor is not already the parent of the dragged aspect AbstractAspect* destinationAspect = static_cast(index.internalPointer()); bool accept = sourceAspect->dropableOn().indexOf(destinationAspect->type()) != -1 && sourceAspect->parentAspect() != destinationAspect; event->setAccepted(accept); } else if (event->type() == QEvent::Drop) { auto* dropEvent = static_cast(event); QModelIndex index = m_treeView->indexAt(dropEvent->pos()); if (!index.isValid()) return false; auto* aspect = static_cast(index.internalPointer()); aspect->processDropEvent(dropEvent); } } return QObject::eventFilter(obj, event); } //############################################################################## //################################# SLOTS #################################### //############################################################################## /*! expand the aspect \c aspect (the tree index corresponding to it) in the tree view and makes it visible and selected. Called when a new aspect is added to the project. */ void ProjectExplorer::aspectAdded(const AbstractAspect* aspect) { if (m_project->isLoading()) return; //don't do anything if hidden aspects were added if (aspect->hidden()) return; //don't do anything for newly added data spreadsheets of data picker curves if (aspect->inherits(AspectType::Spreadsheet) && aspect->parentAspect()->inherits(AspectType::DatapickerCurve)) return; const AspectTreeModel* tree_model = qobject_cast(m_treeView->model()); const QModelIndex& index = tree_model->modelIndexOfAspect(aspect); //expand and make the aspect visible m_treeView->setExpanded(index, true); // newly added columns are only expanded but not selected, return here if (aspect->inherits(AspectType::Column)) { m_treeView->setExpanded(tree_model->modelIndexOfAspect(aspect->parentAspect()), true); return; } m_treeView->scrollTo(index); m_treeView->setCurrentIndex(index); m_treeView->header()->resizeSections(QHeaderView::ResizeToContents); m_treeView->header()->resizeSection(0, m_treeView->header()->sectionSize(0)*1.2); } void ProjectExplorer::navigateTo(const QString& path) { const AspectTreeModel* tree_model = qobject_cast(m_treeView->model()); if (tree_model) m_treeView->setCurrentIndex(tree_model->modelIndexOfAspect(path)); } void ProjectExplorer::currentChanged(const QModelIndex & current, const QModelIndex & previous) { Q_UNUSED(previous); emit currentAspectChanged(static_cast(current.internalPointer())); } void ProjectExplorer::toggleColumn(int index) { //determine the total number of checked column actions int checked = 0; for (const auto* action : list_showColumnActions) { if (action->isChecked()) checked++; } if (list_showColumnActions.at(index)->isChecked()) { m_treeView->showColumn(index); m_treeView->header()->resizeSection(0,0 ); m_treeView->header()->resizeSections(QHeaderView::ResizeToContents); for (auto* action : list_showColumnActions) action->setEnabled(true); //deactivate the "show all column"-action, if all actions are checked if ( checked == list_showColumnActions.size() ) { showAllColumnsAction->setEnabled(false); showAllColumnsAction->setChecked(true); } } else { m_treeView->hideColumn(index); showAllColumnsAction->setEnabled(true); showAllColumnsAction->setChecked(false); //if there is only one checked column-action, deactivated it. //It should't be possible to hide all columns if ( checked == 1 ) { int i = 0; while ( !list_showColumnActions.at(i)->isChecked() ) i++; list_showColumnActions.at(i)->setEnabled(false); } } } void ProjectExplorer::showAllColumns() { for (int i = 0; i < m_treeView->model()->columnCount(); i++) { m_treeView->showColumn(i); m_treeView->header()->resizeSection(0,0 ); m_treeView->header()->resizeSections(QHeaderView::ResizeToContents); } showAllColumnsAction->setEnabled(false); for (auto* action : list_showColumnActions) { action->setEnabled(true); action->setChecked(true); } } /*! shows/hides the frame with the search/filter widgets */ void ProjectExplorer::toggleFilterWidgets() { if (m_frameFilter->isVisible()) { m_frameFilter->hide(); toggleFilterAction->setText(i18n("Show Search/Filter Options")); } else { m_frameFilter->show(); toggleFilterAction->setText(i18n("Hide Search/Filter Options")); } } /*! toggles the menu for the filter/search options */ void ProjectExplorer::toggleFilterOptionsMenu(bool checked) { if (checked) { QMenu menu; menu.addAction(caseSensitiveAction); menu.addAction(matchCompleteWordAction); connect(&menu, &QMenu::aboutToHide, bFilterOptions, &QPushButton::toggle); menu.exec(bFilterOptions->mapToGlobal(QPoint(0,bFilterOptions->height()))); } } void ProjectExplorer::resizeHeader() { m_treeView->header()->resizeSections(QHeaderView::ResizeToContents); m_treeView->header()->resizeSection(0, m_treeView->header()->sectionSize(0)*1.2); //make the column "Name" somewhat bigger } /*! called when the filter/search text was changend. */ void ProjectExplorer::filterTextChanged(const QString& text) { QModelIndex root = m_treeView->model()->index(0,0); filter(root, text); } bool ProjectExplorer::filter(const QModelIndex& index, const QString& text) { Qt::CaseSensitivity sensitivity = caseSensitiveAction->isChecked() ? Qt::CaseSensitive : Qt::CaseInsensitive; bool matchCompleteWord = matchCompleteWordAction->isChecked(); bool childVisible = false; const int rows = index.model()->rowCount(index); for (int i = 0; i < rows; i++) { QModelIndex child = index.model()->index(i, 0, index); auto* aspect = static_cast(child.internalPointer()); bool visible; if (text.isEmpty()) visible = true; else if (matchCompleteWord) visible = aspect->name().startsWith(text, sensitivity); else visible = aspect->name().contains(text, sensitivity); if (visible) { //current item is visible -> make all its children visible without applying the filter for (int j = 0; j < child.model()->rowCount(child); ++j) { m_treeView->setRowHidden(j, child, false); if (text.isEmpty()) filter(child, text); } childVisible = true; } else { //check children items. if one of the children is visible, make the parent (current) item visible too. visible = filter(child, text); if (visible) childVisible = true; } m_treeView->setRowHidden(i, index, !visible); } return childVisible; } void ProjectExplorer::toggleFilterCaseSensitivity() { filterTextChanged(m_leFilter->text()); } void ProjectExplorer::toggleFilterMatchCompleteWord() { filterTextChanged(m_leFilter->text()); } void ProjectExplorer::selectIndex(const QModelIndex& index) { if (m_project->isLoading()) return; if ( !m_treeView->selectionModel()->isSelected(index) ) { m_treeView->selectionModel()->select(index, QItemSelectionModel::Select | QItemSelectionModel::Rows); m_treeView->setExpanded(index, true); m_treeView->scrollTo(index); } } void ProjectExplorer::deselectIndex(const QModelIndex & index) { if (m_project->isLoading()) return; if ( m_treeView->selectionModel()->isSelected(index) ) m_treeView->selectionModel()->select(index, QItemSelectionModel::Deselect | QItemSelectionModel::Rows); } void ProjectExplorer::selectionChanged(const QItemSelection &selected, const QItemSelection &deselected) { QModelIndex index; QModelIndexList items; AbstractAspect* aspect = nullptr; //there are four model indices in each row //-> divide by 4 to obtain the number of selected rows (=aspects) items = selected.indexes(); for (int i = 0; i < items.size()/4; ++i) { index = items.at(i*4); aspect = static_cast(index.internalPointer()); aspect->setSelected(true); } items = deselected.indexes(); for (int i = 0; i < items.size()/4; ++i) { index = items.at(i*4); aspect = static_cast(index.internalPointer()); aspect->setSelected(false); } items = m_treeView->selectionModel()->selectedRows(); QList selectedAspects; for (const QModelIndex& index : items) { aspect = static_cast(index.internalPointer()); selectedAspects<selectionModel()->selectedRows(); QList selectedAspects; for (const QModelIndex& index : items) { selectedAspects << static_cast(index.internalPointer()); } emit selectedAspectsChanged(selectedAspects); } void ProjectExplorer::expandSelected() { const QModelIndexList items = m_treeView->selectionModel()->selectedIndexes(); for (const auto& index : items) m_treeView->setExpanded(index, true); } void ProjectExplorer::collapseSelected() { const QModelIndexList items = m_treeView->selectionModel()->selectedIndexes(); for (const auto& index : items) m_treeView->setExpanded(index, false); } void ProjectExplorer::deleteSelected() { const QModelIndexList items = m_treeView->selectionModel()->selectedIndexes(); if (!items.size()) return; int rc = KMessageBox::warningYesNo( this, i18np("Do you really want to delete the selected object?", "Do you really want to delete the selected %1 objects?", items.size()/4), i18np("Delete selected object", "Delete selected objects", items.size()/4)); if (rc == KMessageBox::No) return; m_project->beginMacro(i18np("Project Explorer: delete %1 selected object", "Project Explorer: delete %1 selected objects", items.size()/4)); for (int i = 0; i < items.size()/4; ++i) { const QModelIndex& index = items.at(i*4); auto* aspect = static_cast(index.internalPointer()); aspect->remove(); } m_project->endMacro(); } //############################################################################## //################## Serialization/Deserialization ########################### //############################################################################## struct ViewState { Qt::WindowStates state; QRect geometry; }; /** * \brief Save the current state of the tree view * (expanded items and the currently selected item) as XML */ void ProjectExplorer::save(QXmlStreamWriter* writer) const { auto* model = qobject_cast(m_treeView->model()); QList selected; QList expanded; QList withView; QVector viewStates; int currentRow = -1; //row corresponding to the current index in the tree view, -1 for the root element (=project) QModelIndexList selectedRows = m_treeView->selectionModel()->selectedRows(); //check whether the project node itself is expanded if (m_treeView->isExpanded(m_treeView->model()->index(0,0))) expanded.push_back(-1); int row = 0; for (const auto* aspect : m_project->children(AspectType::AbstractAspect, AbstractAspect::Recursive)) { const QModelIndex& index = model->modelIndexOfAspect(aspect); const auto* part = dynamic_cast(aspect); if (part && part->hasMdiSubWindow()) { withView.push_back(row); ViewState s = {part->view()->windowState(), part->view()->geometry()}; viewStates.push_back(s); } if (model->rowCount(index)>0 && m_treeView->isExpanded(index)) expanded.push_back(row); if (selectedRows.indexOf(index) != -1) selected.push_back(row); if (index == m_treeView->currentIndex()) currentRow = row; row++; } writer->writeStartElement("state"); writer->writeStartElement("expanded"); for (const auto e : expanded) writer->writeTextElement("row", QString::number(e)); writer->writeEndElement(); writer->writeStartElement("selected"); for (const auto s : selected) writer->writeTextElement("row", QString::number(s)); writer->writeEndElement(); writer->writeStartElement("view"); for (int i = 0; i < withView.size(); ++i) { writer->writeStartElement("row"); const ViewState& s = viewStates.at(i); writer->writeAttribute( "state", QString::number(s.state) ); writer->writeAttribute( "x", QString::number(s.geometry.x()) ); writer->writeAttribute( "y", QString::number(s.geometry.y()) ); writer->writeAttribute( "width", QString::number(s.geometry.width()) ); writer->writeAttribute( "height", QString::number(s.geometry.height()) ); writer->writeCharacters(QString::number(withView.at(i))); writer->writeEndElement(); } writer->writeEndElement(); writer->writeStartElement("current"); writer->writeTextElement("row", QString::number(currentRow)); writer->writeEndElement(); writer->writeEndElement(); } /** * \brief Load from XML */ bool ProjectExplorer::load(XmlStreamReader* reader) { const AspectTreeModel* model = qobject_cast(m_treeView->model()); const auto aspects = m_project->children(AspectType::AbstractAspect, AbstractAspect::Recursive); bool expandedItem = false; bool selectedItem = false; bool viewItem = false; (void)viewItem; // because of a strange g++-warning about unused viewItem bool currentItem = false; QModelIndex currentIndex; QString str; int row; QVector selected; QList expanded; QXmlStreamAttributes attribs; KLocalizedString attributeWarning = ki18n("Attribute '%1' missing or empty, default value is used"); while (!reader->atEnd()) { reader->readNext(); if (reader->isEndElement() && reader->name() == "state") break; if (!reader->isStartElement()) continue; if (reader->name() == "expanded") { expandedItem = true; selectedItem = false; viewItem = false; currentItem = false; } else if (reader->name() == "selected") { expandedItem = false; selectedItem = true; viewItem = false; currentItem = false; } else if (reader->name() == "view") { expandedItem = false; selectedItem = false; viewItem = true; currentItem = false; } else if (reader->name() == "current") { expandedItem = false; selectedItem = false; viewItem = false; currentItem = true; } else if (reader->name() == "row") { - attribs = reader->attributes(); row = reader->readElementText().toInt(); QModelIndex index; if (row == -1) index = model->modelIndexOfAspect(m_project); //-1 corresponds to the project-item (s.a. ProjectExplorer::save()) else if (row >= aspects.size() || row < 0 /* checking for <0 to protect against wrong values in the XML */) continue; else index = model->modelIndexOfAspect(aspects.at(row)); if (expandedItem) expanded.push_back(index); else if (selectedItem) selected.push_back(index); else if (currentItem) currentIndex = index; else if (viewItem) { auto* part = dynamic_cast(aspects.at(row)); if (!part) continue; //TODO: add error/warning message here? emit currentAspectChanged(part); + attribs = reader->attributes(); str = attribs.value("state").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("state").toString()); else { part->view()->setWindowState(Qt::WindowStates(str.toInt())); part->mdiSubWindow()->setWindowState(Qt::WindowStates(str.toInt())); } if (str != "0") continue; //no geometry settings required for maximized/minimized windows QRect geometry; str = attribs.value("x").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("x").toString()); else geometry.setX(str.toInt()); str = attribs.value("y").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("y").toString()); else geometry.setY(str.toInt()); str = attribs.value("width").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("width").toString()); else geometry.setWidth(str.toInt()); str = attribs.value("height").toString(); if (str.isEmpty()) reader->raiseWarning(attributeWarning.subs("height").toString()); else geometry.setHeight(str.toInt()); part->mdiSubWindow()->setGeometry(geometry); } } } for (const auto& index : expanded) { m_treeView->setExpanded(index, true); collapseParents(index, expanded);//collapse all parent indices if they are not expanded } for (const auto& index : selected) m_treeView->selectionModel()->select(index, QItemSelectionModel::Select | QItemSelectionModel::Rows); m_treeView->setCurrentIndex(currentIndex); m_treeView->scrollTo(currentIndex); //when setting the current index above it gets expanded, collapse all parent indices if they are were not expanded when saved collapseParents(currentIndex, expanded); return true; } void ProjectExplorer::collapseParents(const QModelIndex& index, const QList& expanded) { //root index doesn't have any parents - this case is not caught by the second if-statement below if (index.column() == 0 && index.row() == 0) return; const QModelIndex parent = index.parent(); if (parent == QModelIndex()) return; if (expanded.indexOf(parent) == -1) m_treeView->collapse(parent); }