kopia lustrzana https://github.com/NanoVNA-Saver/nanovna-saver
730 wiersze
29 KiB
Python
730 wiersze
29 KiB
Python
# NanoVNASaver
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#
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# A python program to view and export Touchstone data from a NanoVNA
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# Copyright (C) 2019, 2020 Rune B. Broberg
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# Copyright (C) 2020ff NanoVNA-Saver Authors
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#
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# This program is free software: you can redistribute it and/or modify
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# it under the terms of the GNU General Public License as published by
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# the Free Software Foundation, either version 3 of the License, or
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# (at your option) any later version.
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#
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# This program is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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# GNU General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with this program. If not, see <https://www.gnu.org/licenses/>.
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import math
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import logging
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from typing import List, Tuple
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import numpy as np
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from PyQt5 import QtWidgets, QtGui, QtCore
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from NanoVNASaver.Charts.Chart import Chart
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from NanoVNASaver.Formatting import (
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parse_frequency, parse_value,
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format_frequency_chart, format_frequency_chart_2,
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format_y_axis)
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from NanoVNASaver.RFTools import Datapoint
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from NanoVNASaver.SITools import Format, Value
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logger = logging.getLogger(__name__)
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class FrequencyChart(Chart):
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def __init__(self, name):
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super().__init__(name)
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self.maxFrequency = 100000000
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self.minFrequency = 1000000
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self.fixedSpan = False
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self.fixedValues = False
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self.logarithmicX = False
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self.logarithmicY = False
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self.leftMargin = 30
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self.rightMargin = 20
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self.bottomMargin = 20
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self.topMargin = 30
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self.dim.width = 250
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self.dim.height = 250
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self.fstart = 0
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self.fstop = 0
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self.name_unit = ""
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self.value_function = lambda x: 0.0
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# TODO: use unscaled values instead of unit dependend ones
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self.minDisplayValue = -1
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self.maxDisplayValue = 1
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self.minValue = -1
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self.maxValue = 1
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self.span = 1
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self.setContextMenuPolicy(QtCore.Qt.DefaultContextMenu)
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mode_group = QtWidgets.QActionGroup(self)
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self.menu = QtWidgets.QMenu()
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self.reset = QtWidgets.QAction("Reset")
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self.reset.triggered.connect(self.resetDisplayLimits)
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self.menu.addAction(self.reset)
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self.x_menu = QtWidgets.QMenu("Frequency axis")
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self.action_automatic = QtWidgets.QAction("Automatic")
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self.action_automatic.setCheckable(True)
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self.action_automatic.setChecked(True)
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self.action_automatic.changed.connect(
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lambda: self.setFixedSpan(self.action_fixed_span.isChecked()))
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self.action_fixed_span = QtWidgets.QAction("Fixed span")
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self.action_fixed_span.setCheckable(True)
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self.action_fixed_span.changed.connect(
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lambda: self.setFixedSpan(self.action_fixed_span.isChecked()))
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mode_group.addAction(self.action_automatic)
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mode_group.addAction(self.action_fixed_span)
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self.x_menu.addAction(self.action_automatic)
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self.x_menu.addAction(self.action_fixed_span)
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self.x_menu.addSeparator()
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self.action_set_fixed_start = QtWidgets.QAction(
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f"Start ({format_frequency_chart(self.minFrequency)})")
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self.action_set_fixed_start.triggered.connect(self.setMinimumFrequency)
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self.action_set_fixed_stop = QtWidgets.QAction(
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f"Stop ({format_frequency_chart(self.maxFrequency)})")
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self.action_set_fixed_stop.triggered.connect(self.setMaximumFrequency)
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self.x_menu.addAction(self.action_set_fixed_start)
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self.x_menu.addAction(self.action_set_fixed_stop)
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self.x_menu.addSeparator()
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frequency_mode_group = QtWidgets.QActionGroup(self.x_menu)
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self.action_set_linear_x = QtWidgets.QAction("Linear")
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self.action_set_linear_x.setCheckable(True)
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self.action_set_logarithmic_x = QtWidgets.QAction("Logarithmic")
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self.action_set_logarithmic_x.setCheckable(True)
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frequency_mode_group.addAction(self.action_set_linear_x)
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frequency_mode_group.addAction(self.action_set_logarithmic_x)
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self.action_set_linear_x.triggered.connect(
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lambda: self.setLogarithmicX(False))
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self.action_set_logarithmic_x.triggered.connect(
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lambda: self.setLogarithmicX(True))
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self.action_set_linear_x.setChecked(True)
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self.x_menu.addAction(self.action_set_linear_x)
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self.x_menu.addAction(self.action_set_logarithmic_x)
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self.y_menu = QtWidgets.QMenu("Data axis")
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self.y_action_automatic = QtWidgets.QAction("Automatic")
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self.y_action_automatic.setCheckable(True)
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self.y_action_automatic.setChecked(True)
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self.y_action_automatic.changed.connect(
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lambda: self.setFixedValues(self.y_action_fixed_span.isChecked()))
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self.y_action_fixed_span = QtWidgets.QAction("Fixed span")
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self.y_action_fixed_span.setCheckable(True)
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self.y_action_fixed_span.changed.connect(
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lambda: self.setFixedValues(self.y_action_fixed_span.isChecked()))
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mode_group = QtWidgets.QActionGroup(self)
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mode_group.addAction(self.y_action_automatic)
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mode_group.addAction(self.y_action_fixed_span)
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self.y_menu.addAction(self.y_action_automatic)
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self.y_menu.addAction(self.y_action_fixed_span)
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self.y_menu.addSeparator()
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self.action_set_fixed_minimum = QtWidgets.QAction(
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f"Minimum ({self.minDisplayValue})")
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self.action_set_fixed_minimum.triggered.connect(self.setMinimumValue)
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self.action_set_fixed_maximum = QtWidgets.QAction(
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f"Maximum ({self.maxDisplayValue})")
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self.action_set_fixed_maximum.triggered.connect(self.setMaximumValue)
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self.y_menu.addAction(self.action_set_fixed_maximum)
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self.y_menu.addAction(self.action_set_fixed_minimum)
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if self.logarithmicYAllowed(): # This only works for some plot types
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self.y_menu.addSeparator()
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vertical_mode_group = QtWidgets.QActionGroup(self.y_menu)
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self.action_set_linear_y = QtWidgets.QAction("Linear")
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self.action_set_linear_y.setCheckable(True)
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self.action_set_logarithmic_y = QtWidgets.QAction("Logarithmic")
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self.action_set_logarithmic_y.setCheckable(True)
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vertical_mode_group.addAction(self.action_set_linear_y)
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vertical_mode_group.addAction(self.action_set_logarithmic_y)
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self.action_set_linear_y.triggered.connect(
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lambda: self.setLogarithmicY(False))
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self.action_set_logarithmic_y.triggered.connect(
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lambda: self.setLogarithmicY(True))
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self.action_set_linear_y.setChecked(True)
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self.y_menu.addAction(self.action_set_linear_y)
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self.y_menu.addAction(self.action_set_logarithmic_y)
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self.menu.addMenu(self.x_menu)
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self.menu.addMenu(self.y_menu)
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self.menu.addSeparator()
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self.menu.addAction(self.action_save_screenshot)
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self.action_popout = QtWidgets.QAction("Popout chart")
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self.action_popout.triggered.connect(
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lambda: self.popoutRequested.emit(self))
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self.menu.addAction(self.action_popout)
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self.setFocusPolicy(QtCore.Qt.ClickFocus)
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self.setMinimumSize(self.dim.width + self.rightMargin + self.leftMargin,
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self.dim.height + self.topMargin + self.bottomMargin)
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self.setSizePolicy(
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QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding,
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QtWidgets.QSizePolicy.MinimumExpanding))
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pal = QtGui.QPalette()
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pal.setColor(QtGui.QPalette.Background, Chart.color.background)
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self.setPalette(pal)
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self.setAutoFillBackground(True)
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def _set_start_stop(self):
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if self.fixedSpan:
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self.fstart = self.minFrequency
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self.fstop = self.maxFrequency
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return
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if self.data:
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self.fstart = self.data[0].freq
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self.fstop = self.data[len(self.data) - 1].freq
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return
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self.fstart = self.reference[0].freq
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self.fstop = self.reference[len(self.reference) - 1].freq
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def contextMenuEvent(self, event):
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self.action_set_fixed_start.setText(
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f"Start ({format_frequency_chart(self.minFrequency)})")
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self.action_set_fixed_stop.setText(
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f"Stop ({format_frequency_chart(self.maxFrequency)})")
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self.action_set_fixed_minimum.setText(
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f"Minimum ({self.minDisplayValue})")
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self.action_set_fixed_maximum.setText(
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f"Maximum ({self.maxDisplayValue})")
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if self.fixedSpan:
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self.action_fixed_span.setChecked(True)
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else:
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self.action_automatic.setChecked(True)
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if self.fixedValues:
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self.y_action_fixed_span.setChecked(True)
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else:
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self.y_action_automatic.setChecked(True)
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self.menu.exec_(event.globalPos())
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def setFixedSpan(self, fixed_span: bool):
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self.fixedSpan = fixed_span
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if fixed_span and self.minFrequency >= self.maxFrequency:
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self.fixedSpan = False
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self.action_automatic.setChecked(True)
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self.action_fixed_span.setChecked(False)
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self.update()
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def setFixedValues(self, fixed_values: bool):
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self.fixedValues = fixed_values
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self.update()
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def setLogarithmicX(self, logarithmic: bool):
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self.logarithmicX = logarithmic
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self.update()
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def setLogarithmicY(self, logarithmic: bool):
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self.logarithmicY = logarithmic and self.logarithmicYAllowed()
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self.update()
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@staticmethod
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def logarithmicYAllowed() -> bool:
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return False
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def setMinimumFrequency(self):
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min_freq_str, selected = QtWidgets.QInputDialog.getText(
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self, "Start frequency",
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"Set start frequency", text=str(self.minFrequency))
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if not selected:
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return
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span = abs(self.maxFrequency - self.minFrequency)
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min_freq = parse_frequency(min_freq_str)
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if min_freq < 0:
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return
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self.minFrequency = min_freq
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if self.minFrequency >= self.maxFrequency:
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self.maxFrequency = self.minFrequency + span
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self.fixedSpan = True
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self.update()
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def setMaximumFrequency(self):
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max_freq_str, selected = QtWidgets.QInputDialog.getText(
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self, "Stop frequency",
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"Set stop frequency", text=str(self.maxFrequency))
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if not selected:
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return
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span = abs(self.maxFrequency - self.minFrequency)
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max_freq = parse_frequency(max_freq_str)
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if max_freq < 0:
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return
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self.maxFrequency = max_freq
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if self.maxFrequency <= self.minFrequency:
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self.minFrequency = max(self.maxFrequency - span, 0)
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self.fixedSpan = True
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self.update()
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def setMinimumValue(self):
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text, selected = QtWidgets.QInputDialog.getText(
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self, "Minimum value",
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"Set minimum value",
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text=format_y_axis(self.minDisplayValue, self.name_unit))
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if not selected:
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return
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min_val = parse_value(text)
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yspan = abs(self.maxDisplayValue - self.minDisplayValue)
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self.minDisplayValue = min_val
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if self.minDisplayValue >= self.maxDisplayValue:
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self.maxDisplayValue = self.minDisplayValue + yspan
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# TODO: negativ logarythmical scale
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if self.logarithmicY and min_val <= 0:
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self.minDisplayValue = 0.01
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self.fixedValues = True
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self.update()
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def setMaximumValue(self):
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text, selected = QtWidgets.QInputDialog.getText(
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self, "Maximum value",
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"Set maximum value",
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text=format_y_axis(self.maxDisplayValue, self.name_unit))
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if not selected:
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return
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max_val = parse_value(text)
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yspan = abs(self.maxDisplayValue - self.minDisplayValue)
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self.maxDisplayValue = max_val
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if self.maxDisplayValue <= self.minDisplayValue:
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self.minDisplayValue = self.maxDisplayValue - yspan
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self.fixedValues = True
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self.update()
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def resetDisplayLimits(self):
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self.fixedValues = False
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self.y_action_automatic.setChecked(True)
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self.fixedSpan = False
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self.action_automatic.setChecked(True)
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self.logarithmicX = False
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self.action_set_linear_x.setChecked(True)
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self.logarithmicY = False
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if self.logarithmicYAllowed():
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self.action_set_linear_y.setChecked(True)
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self.update()
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def getXPosition(self, d: Datapoint) -> int:
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span = self.fstop - self.fstart
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if span > 0:
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if self.logarithmicX:
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span = math.log(self.fstop) - math.log(self.fstart)
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return self.leftMargin + round(
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self.dim.width * (math.log(d.freq) -
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math.log(self.fstart)) / span)
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return self.leftMargin + round(
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self.dim.width * (d.freq - self.fstart) / span)
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return math.floor(self.width() / 2)
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def getYPosition(self, d: Datapoint) -> int:
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try:
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return (
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self.topMargin +
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round((self.maxValue - self.value_function(d) /
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self.span * self.dim.height)))
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except ValueError:
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return self.topMargin
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def frequencyAtPosition(self, x, limit=True) -> int:
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"""
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Calculates the frequency at a given X-position
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:param limit: Determines whether frequencies outside the
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currently displayed span can be returned.
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:param x: The X position to calculate for.
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:return: The frequency at the given position, if one
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exists or -1 otherwise. If limit is True,
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and the value is before or after the chart,
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returns minimum or maximum frequencies.
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"""
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if self.fstop - self.fstart <= 0:
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return -1
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absx = x - self.leftMargin
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if limit:
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if absx < 0:
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return self.fstart
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if absx > self.dim.width:
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return self.fstop
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if self.logarithmicX:
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span = math.log(self.fstop) - math.log(self.fstart)
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step = span / self.dim.width
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return round(math.exp(math.log(self.fstart) + absx * step))
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span = self.fstop - self.fstart
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step = span / self.dim.width
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return round(self.fstart + absx * step)
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def valueAtPosition(self, y) -> List[float]:
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"""
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Returns the chart-specific value(s) at the specified Y-position
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:param y: The Y position to calculate for.
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:return: A list of the values at the Y-position, either
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containing a single value, or the two values for the
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chart from left to right Y-axis. If no value can be
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found, returns the empty list. If the frequency
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is above or below the chart, returns maximum
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or minimum values.
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"""
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absy = y - self.topMargin
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val = -1 * ((absy / self.dim.height * self.span) - self.maxValue)
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return [val * 10e11]
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def zoomTo(self, x1, y1, x2, y2):
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val1 = self.valueAtPosition(y1)
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val2 = self.valueAtPosition(y2)
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if len(val1) == len(val2) == 1 and val1[0] != val2[0]:
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self.minDisplayValue = round(min(val1[0], val2[0]), 3)
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self.maxDisplayValue = round(max(val1[0], val2[0]), 3)
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self.setFixedValues(True)
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freq1 = max(1, self.frequencyAtPosition(x1, limit=False))
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freq2 = max(1, self.frequencyAtPosition(x2, limit=False))
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if freq1 > 0 and freq2 > 0 and freq1 != freq2:
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self.minFrequency = min(freq1, freq2)
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self.maxFrequency = max(freq1, freq2)
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self.setFixedSpan(True)
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self.update()
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def mouseMoveEvent(self, a0: QtGui.QMouseEvent):
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if a0.buttons() == QtCore.Qt.RightButton:
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a0.ignore()
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return
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if a0.buttons() == QtCore.Qt.MiddleButton:
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# Drag the display
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a0.accept()
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if self.dragbox.move_x != -1 and self.dragbox.move_y != -1:
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dx = self.dragbox.move_x - a0.x()
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dy = self.dragbox.move_y - a0.y()
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self.zoomTo(self.leftMargin + dx, self.topMargin + dy,
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self.leftMargin + self.dim.width + dx,
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self.topMargin + self.dim.height + dy)
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self.dragbox.move_x = a0.x()
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self.dragbox.move_y = a0.y()
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return
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if a0.modifiers() == QtCore.Qt.ControlModifier:
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# Dragging a box
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if not self.dragbox.state:
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self.dragbox.pos_start = (a0.x(), a0.y())
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self.dragbox.pos = (a0.x(), a0.y())
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self.update()
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a0.accept()
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return
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x = a0.x()
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f = self.frequencyAtPosition(x)
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if x == -1:
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a0.ignore()
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return
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a0.accept()
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m = self.getActiveMarker()
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if m is not None:
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m.setFrequency(str(f))
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m.frequencyInput.setText(str(f))
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def resizeEvent(self, a0: QtGui.QResizeEvent) -> None:
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self.dim.width = a0.size().width() - self.rightMargin - self.leftMargin
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self.dim.height = a0.size().height() - self.bottomMargin - self.topMargin
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self.update()
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def paintEvent(self, _: QtGui.QPaintEvent) -> None:
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qp = QtGui.QPainter(self)
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self.drawChart(qp)
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self.drawValues(qp)
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self._check_frequency_boundaries(qp)
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if self.dragbox.state and self.dragbox.pos[0] != -1:
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self.drawDragbog(qp)
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qp.end()
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def _data_oob(self, data: list[Datapoint]) -> bool:
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return (data[0].freq > self.fstop or self.data[-1].freq < self.fstart)
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def _check_frequency_boundaries(self, qp: QtGui.QPainter):
|
|
if (self.data and self._data_oob(self.data) and
|
|
(not self.reference or self._data_oob(self.reference))):
|
|
# Data outside frequency range
|
|
qp.setBackgroundMode(QtCore.Qt.OpaqueMode)
|
|
qp.setBackground(Chart.color.background)
|
|
qp.setPen(Chart.color.text)
|
|
qp.drawText(self.leftMargin + self.dim.width / 2 - 70,
|
|
self.topMargin + self.dim.height / 2 - 20,
|
|
"Data outside frequency span")
|
|
|
|
def drawDragbog(self, qp: QtGui.QPainter):
|
|
dashed_pen = QtGui.QPen(Chart.color.foreground, 1, QtCore.Qt.DashLine)
|
|
qp.setPen(dashed_pen)
|
|
top_left = QtCore.QPoint(
|
|
self.dragbox.pos_start[0], self.dragbox.pos_start[1])
|
|
bottom_right = QtCore.QPoint(self.dragbox.pos[0], self.dragbox.pos[1])
|
|
rect = QtCore.QRect(top_left, bottom_right)
|
|
qp.drawRect(rect)
|
|
|
|
def drawChart(self, qp: QtGui.QPainter):
|
|
qp.setPen(QtGui.QPen(Chart.color.text))
|
|
headline = self.name
|
|
if self.name_unit:
|
|
headline += f" ({self.name_unit})"
|
|
qp.drawText(3, 15, headline)
|
|
qp.setPen(QtGui.QPen(Chart.color.foreground))
|
|
qp.drawLine(self.leftMargin, 20,
|
|
self.leftMargin, self.topMargin + self.dim.height + 5)
|
|
qp.drawLine(self.leftMargin - 5, self.topMargin + self.dim.height,
|
|
self.leftMargin + self.dim.width, self.topMargin + self.dim.height)
|
|
self.drawTitle(qp)
|
|
|
|
def drawValues(self, qp: QtGui.QPainter):
|
|
if len(self.data) == 0 and len(self.reference) == 0:
|
|
return
|
|
pen = QtGui.QPen(Chart.color.sweep)
|
|
pen.setWidth(self.dim.point)
|
|
line_pen = QtGui.QPen(Chart.color.sweep)
|
|
line_pen.setWidth(self.dim.line)
|
|
highlighter = QtGui.QPen(QtGui.QColor(20, 0, 255))
|
|
highlighter.setWidth(1)
|
|
|
|
self._set_start_stop()
|
|
|
|
# Draw bands if required
|
|
if self.bands.enabled:
|
|
self.drawBands(qp, self.fstart, self.fstop)
|
|
|
|
min_value, max_value = self._find_scaling()
|
|
self.maxValue = max_value
|
|
self.minValue = min_value
|
|
span = max_value - min_value
|
|
if span == 0:
|
|
logger.info(
|
|
"Span is zero for %s-Chart, setting to a small value.", self.name)
|
|
span = 1e-15
|
|
self.span = span
|
|
|
|
target_ticks = math.floor(self.dim.height / 60)
|
|
fmt = Format(max_nr_digits=1)
|
|
for i in range(target_ticks):
|
|
val = min_value + (i / target_ticks) * span
|
|
y = self.topMargin + \
|
|
round((self.maxValue - val) / self.span * self.dim.height)
|
|
qp.setPen(Chart.color.text)
|
|
if val != min_value:
|
|
valstr = str(Value(val, fmt=fmt))
|
|
qp.drawText(3, y + 3, valstr)
|
|
qp.setPen(QtGui.QPen(Chart.color.foreground))
|
|
qp.drawLine(self.leftMargin - 5, y,
|
|
self.leftMargin + self.dim.width, y)
|
|
|
|
qp.setPen(QtGui.QPen(Chart.color.foreground))
|
|
qp.drawLine(self.leftMargin - 5, self.topMargin,
|
|
self.leftMargin + self.dim.width, self.topMargin)
|
|
qp.setPen(Chart.color.text)
|
|
qp.drawText(3, self.topMargin + 4, str(Value(max_value, fmt=fmt)))
|
|
qp.drawText(3, self.dim.height + self.topMargin,
|
|
str(Value(min_value, fmt=fmt)))
|
|
self.drawFrequencyTicks(qp)
|
|
|
|
self.drawData(qp, self.data, Chart.color.sweep)
|
|
self.drawData(qp, self.reference, Chart.color.reference)
|
|
self.drawMarkers(qp)
|
|
|
|
def _find_scaling(self) -> Tuple[float, float]:
|
|
min_value = self.minDisplayValue / 10e11
|
|
max_value = self.maxDisplayValue / 10e11
|
|
if self.fixedValues:
|
|
return (min_value, max_value)
|
|
for d in self.data:
|
|
val = self.value_function(d)
|
|
min_value = min(min_value, val)
|
|
max_value = max(max_value, val)
|
|
for d in self.reference: # Also check min/max for the reference sweep
|
|
if d.freq < self.fstart or d.freq > self.fstop:
|
|
continue
|
|
val = self.value_function(d)
|
|
min_value = min(min_value, val)
|
|
max_value = max(max_value, val)
|
|
return (min_value, max_value)
|
|
|
|
def drawFrequencyTicks(self, qp):
|
|
fspan = self.fstop - self.fstart
|
|
qp.setPen(Chart.color.text)
|
|
# Number of ticks does not include the origin
|
|
ticks = math.floor(self.dim.width / 100)
|
|
|
|
# try to adapt format to span
|
|
if int(fspan / ticks / self.fstart * 10000) > 2:
|
|
my_format_frequency = format_frequency_chart
|
|
else:
|
|
my_format_frequency = format_frequency_chart_2
|
|
|
|
qp.drawText(self.leftMargin - 20,
|
|
self.topMargin + self.dim.height + 15,
|
|
my_format_frequency(self.fstart))
|
|
|
|
for i in range(ticks):
|
|
x = self.leftMargin + round((i + 1) * self.dim.width / ticks)
|
|
if self.logarithmicX:
|
|
fspan = math.log(self.fstop) - math.log(self.fstart)
|
|
freq = round(
|
|
math.exp(((i + 1) * fspan / ticks) + math.log(self.fstart)))
|
|
else:
|
|
freq = round(fspan / ticks * (i + 1) + self.fstart)
|
|
qp.setPen(QtGui.QPen(Chart.color.foreground))
|
|
qp.drawLine(x, self.topMargin, x,
|
|
self.topMargin + self.dim.height + 5)
|
|
qp.setPen(Chart.color.text)
|
|
qp.drawText(x - 20,
|
|
self.topMargin + self.dim.height + 15,
|
|
my_format_frequency(freq))
|
|
|
|
def drawBands(self, qp, fstart, fstop):
|
|
qp.setBrush(self.bands.color)
|
|
qp.setPen(QtGui.QColor(128, 128, 128, 0)) # Don't outline the bands
|
|
for _, start, end in self.bands.bands:
|
|
try:
|
|
start = int(start)
|
|
end = int(end)
|
|
except ValueError:
|
|
continue
|
|
# don't draw if either band not in chart or completely in band
|
|
if start < fstart < fstop < end or end < fstart or start > fstop:
|
|
continue
|
|
x_start = max(self.leftMargin + 1,
|
|
self.getXPosition(Datapoint(start, 0, 0)))
|
|
x_stop = min(self.leftMargin + self.dim.width,
|
|
self.getXPosition(Datapoint(end, 0, 0)))
|
|
qp.drawRect(x_start,
|
|
self.topMargin,
|
|
x_stop - x_start,
|
|
self.dim.height)
|
|
|
|
def drawData(self, qp: QtGui.QPainter, data: List[Datapoint],
|
|
color: QtGui.QColor, y_function=None):
|
|
if y_function is None:
|
|
y_function = self.getYPosition
|
|
pen = QtGui.QPen(color)
|
|
pen.setWidth(self.dim.point)
|
|
line_pen = QtGui.QPen(color)
|
|
line_pen.setWidth(self.dim.line)
|
|
qp.setPen(pen)
|
|
for i, d in enumerate(data):
|
|
x = self.getXPosition(d)
|
|
y = y_function(d)
|
|
if y is None:
|
|
continue
|
|
if self.isPlotable(x, y):
|
|
qp.drawPoint(int(x), int(y))
|
|
if self.flag.draw_lines and i > 0:
|
|
prevx = self.getXPosition(data[i - 1])
|
|
prevy = y_function(data[i - 1])
|
|
if prevy is None:
|
|
continue
|
|
qp.setPen(line_pen)
|
|
if self.isPlotable(x, y) and self.isPlotable(prevx, prevy):
|
|
qp.drawLine(x, y, prevx, prevy)
|
|
elif self.isPlotable(x, y) and not self.isPlotable(prevx, prevy):
|
|
new_x, new_y = self.getPlotable(x, y, prevx, prevy)
|
|
qp.drawLine(x, y, new_x, new_y)
|
|
elif not self.isPlotable(x, y) and self.isPlotable(prevx, prevy):
|
|
new_x, new_y = self.getPlotable(prevx, prevy, x, y)
|
|
qp.drawLine(prevx, prevy, new_x, new_y)
|
|
qp.setPen(pen)
|
|
|
|
def drawMarkers(self, qp, data=None, y_function=None):
|
|
if data is None:
|
|
data = self.data
|
|
if y_function is None:
|
|
y_function = self.getYPosition
|
|
highlighter = QtGui.QPen(QtGui.QColor(20, 0, 255))
|
|
highlighter.setWidth(1)
|
|
for m in self.markers:
|
|
if m.location != -1 and m.location < len(data):
|
|
x = self.getXPosition(data[m.location])
|
|
y = y_function(data[m.location])
|
|
if self.isPlotable(x, y):
|
|
self.drawMarker(x, y, qp, m.color,
|
|
self.markers.index(m) + 1)
|
|
|
|
def isPlotable(self, x, y):
|
|
return y is not None and x is not None and \
|
|
self.leftMargin <= x <= self.leftMargin + self.dim.width and \
|
|
self.topMargin <= y <= self.topMargin + self.dim.height
|
|
|
|
def getPlotable(self, x, y, distantx, distanty):
|
|
p1 = np.array([x, y])
|
|
p2 = np.array([distantx, distanty])
|
|
# First check the top line
|
|
if distanty < self.topMargin:
|
|
p3 = np.array([self.leftMargin, self.topMargin])
|
|
p4 = np.array([self.leftMargin + self.dim.width, self.topMargin])
|
|
elif distanty > self.topMargin + self.dim.height:
|
|
p3 = np.array([self.leftMargin, self.topMargin + self.dim.height])
|
|
p4 = np.array([self.leftMargin + self.dim.width,
|
|
self.topMargin + self.dim.height])
|
|
else:
|
|
return x, y
|
|
|
|
da = p2 - p1
|
|
db = p4 - p3
|
|
dp = p1 - p3
|
|
dap = np.array([-da[1], da[0]])
|
|
denom = np.dot(dap, db)
|
|
|
|
if denom:
|
|
x, y = ((np.dot(dap, dp) / denom.astype(float)) * db + p3)[:2]
|
|
|
|
return int(x), int(y)
|
|
|
|
def copy(self):
|
|
new_chart = super().copy()
|
|
new_chart.fstart = self.fstart
|
|
new_chart.fstop = self.fstop
|
|
new_chart.maxFrequency = self.maxFrequency
|
|
new_chart.minFrequency = self.minFrequency
|
|
new_chart.span = self.span
|
|
new_chart.minDisplayValue = self.minDisplayValue
|
|
new_chart.maxDisplayValue = self.maxDisplayValue
|
|
new_chart.pointSize = self.dim.point
|
|
new_chart.lineThickness = self.dim.line
|
|
|
|
new_chart.setFixedSpan(self.fixedSpan)
|
|
new_chart.action_automatic.setChecked(not self.fixedSpan)
|
|
new_chart.action_fixed_span.setChecked(self.fixedSpan)
|
|
|
|
new_chart.setFixedValues(self.fixedValues)
|
|
new_chart.y_action_automatic.setChecked(not self.fixedValues)
|
|
new_chart.y_action_fixed_span.setChecked(self.fixedValues)
|
|
|
|
new_chart.setLogarithmicX(self.logarithmicX)
|
|
new_chart.action_set_logarithmic_x.setChecked(self.logarithmicX)
|
|
new_chart.action_set_linear_x.setChecked(not self.logarithmicX)
|
|
|
|
new_chart.setLogarithmicY(self.logarithmicY)
|
|
if self.logarithmicYAllowed():
|
|
new_chart.action_set_logarithmic_y.setChecked(self.logarithmicY)
|
|
new_chart.action_set_linear_y.setChecked(not self.logarithmicY)
|
|
return new_chart
|
|
|
|
def keyPressEvent(self, a0: QtGui.QKeyEvent) -> None:
|
|
m = self.getActiveMarker()
|
|
if m is not None and a0.modifiers() == QtCore.Qt.NoModifier:
|
|
if a0.key() in [QtCore.Qt.Key_Down, QtCore.Qt.Key_Left]:
|
|
m.frequencyInput.keyPressEvent(QtGui.QKeyEvent(
|
|
a0.type(), QtCore.Qt.Key_Down, a0.modifiers()))
|
|
elif a0.key() in [QtCore.Qt.Key_Up, QtCore.Qt.Key_Right]:
|
|
m.frequencyInput.keyPressEvent(QtGui.QKeyEvent(
|
|
a0.type(), QtCore.Qt.Key_Up, a0.modifiers()))
|
|
else:
|
|
super().keyPressEvent(a0)
|