asn1_value_editor.py 33.9 KB
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#!/usr/bin/python

'''
ASN.1 Variable editor
'''

__author__ = "Maxime Perrotin"
__license__ = "ESA Licence for open source software"
__version__ = "1.0"
__url__ = "http://taste.tuxfamily.org"

import sys

try:
    from PySide import *
    from PySide.QtCore import *
    from PySide.QtGui import *
    from PySide.QtUiTools import *
except ImportError:
    print 'Pyside not found (package python-pyside missing)...'

import vn

MIN_RANGE = Qt.UserRole + 1
MAX_RANGE = Qt.UserRole + 2
CHOICE_LIST = Qt.UserRole + 1
PLOTTERS = Qt.UserRole + 4
ASN1TYPE = Qt.UserRole


class myTextEdit(QTextEdit):
    ''' Customized text editor that contains a context menu for loading data from a file '''
    def __init__(self, parent=None):
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        super(myTextEdit, self).__init__(parent)
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    def contextMenuEvent(self, event):
        ''' When the context menu is open, add the Load from file action and open the menu '''
        myMenu = self.createStandardContextMenu()
        myAction = 'Load data from file'
        myMenu.addAction(myAction)
        action = myMenu.exec_(event.globalPos())
        if action is not None and action.text() == myAction:
            filename = QFileDialog.getOpenFileName(self, "Load string from file", ".", "All (*)")[0]
            if len(filename) == 0:
                return
            stringFile = QFile(filename)
            stringFile.open(QIODevice.ReadOnly)
            stringData = str(stringFile.readData(stringFile.size()))
            self.setText(stringData)
            stringFile.close()


class TreeDelegate(QStyledItemDelegate):
    '''Tree Delegate allows to define specific editors for each cell of the
tree view. This way, e.g. ASN.1 ENUMERATED values can be selected using a
combo box, while INTEGERS values can be set using a spin box.
Three functions have been redefined:
(1) createEditor, which  sets an editor to a cell, using the cell attributes
to learn about the ASN.1 basic type (stored in Qt.UserRole)
(2) SetEditorData, which is used at runtime to put the value in the given
editor when the user clicks on the cell
(3) SetModelData, which is called when the user is done with the editing: it
reads the value from the editor and place it back in the model '''
    seqof = Signal(QModelIndex, int, int)
    choice = Signal(QModelIndex, int, int)

    def __init__(self, oParent=None):
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        super(TreeDelegate, self).__init__(oParent)
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    def createEditor(self, parent, option, index):
        ''' Define the delegate (editor) to use for a given cell.
index.data() returns the actual value, and index.data(role) points to
some user data when role >= 32. 32 is Qt.UserRole. '''
        # Check the (user-defined) type associated with the cell
        asnType = index.data(ASN1TYPE)
        if asnType == 'INTEGER':
            editor = QSpinBox(parent)
            # Qt's int is 32-bits signed, so we may get overflows
            try:
                editor.setMinimum(index.data(MIN_RANGE))
            except OverflowError:
                editor.setMinimum(sys.maxint)
            try:
                editor.setMaximum(index.data(MAX_RANGE))
            except OverflowError:
                editor.setMaximum(sys.maxint)
        elif asnType == 'SEQOF':
            editor = QSpinBox(parent)
            minVal = index.data(MIN_RANGE)
            maxVal = index.data(MAX_RANGE)
            editor.setRange(minVal, maxVal)
        elif asnType == 'ENUMERATED' or asnType == 'CHOICE':
            editor = QComboBox(parent)
            enumVal = index.data(CHOICE_LIST)
            for val in enumVal:
                editor.addItem(val)
        elif asnType == 'REAL':
            editor = QDoubleSpinBox(parent)
            minVal = index.data(MIN_RANGE)
            maxVal = index.data(MAX_RANGE)
            editor.setRange(float(minVal), float(maxVal))
        elif asnType == 'STRING':
            editor = myTextEdit(parent)
            # maxLen = index.data(MAX_RANGE)
            # editor.setMaxLength(maxLen) (not supported by QTextEdit, only QLineEdit)
        elif asnType == 'BOOLEAN':
            editor = QComboBox(parent)
            boolVal = index.data(CHOICE_LIST)
            for val in boolVal:
                editor.addItem(val)
            # I do not use QCheckBox because the position of the box changes when
            # the cell is edited, which is not good-looking
            #editor = QCheckBox(parent)
            #defState =  index.data(Qt.CheckStateRole)
            #editor.setCheckState(Qt.CheckState(defState))
        else:
            return  # Non-editable cells
        return editor

    def setEditorData(self, editor, index):
        ''' Set the curent value of the editor (when cell is clicked)
            in principle, take it from the model (index.data() = value) '''
        asnType = index.data(ASN1TYPE)
        if asnType in ('INTEGER', 'SEQOF'):
            editor. setValue(int(index.data()))
        elif asnType in ('ENUMERATED', 'CHOICE'):
            idx = editor.findText(index.data())
            editor.setCurrentIndex(idx)
            #editor. setEditText(index.data())
        elif asnType == 'REAL':
            editor.setValue(float(index.data()))
        elif asnType == 'STRING':
            editor.setText(index.data())
        elif asnType == 'BOOLEAN':
            idx = editor.findText(index.data())
            editor.setCurrentIndex(idx)
            #isChecked = index.model().data(index,  Qt.CheckStateRole)
            #editor.setCheckState(Qt.CheckState(isChecked))
        else:
            pass

    def setModelData(self, editor, model, index):
        '''  Once a choice has been made (by the user) take the value from
             the corresponding editor, and set it back in the model '''
        asnType = index.data(ASN1TYPE)
        if asnType == 'INTEGER':
            val = editor.value()
            model.setData(index, val)
        elif asnType == 'SEQOF':
            val = editor.value()
            model.setData(index, val)
            # Sequence of: display only the corresponding number of elements
            self.seqof.emit(index.sibling(index.row(), 0), val, index.data(MAX_RANGE))
        elif asnType == 'ENUMERATED':
            val = editor.currentText()
            model.setData(index, val)
        elif asnType == 'CHOICE':
            val = editor.currentText()
            model.setData(index, val)
            # display only the corresponding choice definition
            self.choice.emit(index.sibling(index.row(), 0), len(index.data(CHOICE_LIST)), editor.currentIndex())
        elif asnType == 'REAL':
            val = editor.value()
            model.setData(index, val)
        elif asnType == 'STRING':
            val = editor.toPlainText()
            model.setData(index, val)
        elif asnType == 'BOOLEAN':
            val = editor.currentText()
            model.setData(index, val)
            #if editor.isChecked(): model.setData (index, 'True')
            #else: model.setData (index,  'False')
            #model.setData (index, editor.checkState(),Qt.CheckStateRole)
        else:
            pass

    def updateEditorGeometry(self, editor, option, index):
        ''' Set editor geometry (bigger box for string types) '''
        asnType = index.data(ASN1TYPE)
        if asnType == 'STRING':
            r = QRect(option.rect.x(), option.rect.y(), option.rect.width(), max(option.rect.height(), 100))
        else:
            r = option.rect
        editor.setGeometry(r)


class asn1Editor(QTreeView):
    ''' ASN.1 Fields editor to define, load, save and/or send TC '''
    expandTree = Signal()
    expandBranch = Signal(QModelIndex)
    statusBarMessage = Signal(str)
    msc = Signal(unicode, unicode)

    def __init__(self, parent=None):
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        super(asn1Editor, self).__init__(parent)
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        self.model = QStandardItemModel(1, 4)
        self.model.setHorizontalHeaderLabels(['Field', 'Type', 'Constraints', 'Value'])
        self.delegate = TreeDelegate()
        self.setItemDelegate(self.delegate)
        # Set selection mode and behavior to allow multiple rows to be selected with Ctrl/Shift keys
        self.setSelectionBehavior(QAbstractItemView.SelectRows)
        self.setSelectionMode(QAbstractItemView.ExtendedSelection)

        self.setModel(self.model)
        self.setAlternatingRowColors(True)
        # Set Editing triggers so that a single click in a cell opens the editor
        self.setEditTriggers(QAbstractItemView.AllEditTriggers)
        # If we later want to drag & drop values (to plot, meter..):
        self.setDragEnabled(False)
        # When the number of elements for a sequence of is changed, signal "seqof"
        # is triggered by the delegate. Same for choice.
        self.delegate.seqof.connect(self.seqofDisplay)
        self.delegate.choice.connect(self.choiceDisplay)
        self.expandTree.connect(self.expandAll)
        self.expandBranch.connect(self.expand)
        self.plotterBackend = None
        self.backend = None
        self.plottedIdxs = []
        self.log = None
        self.pendingTM = None

    def hideExtraColumns(self):
        ''' Hide the columns containing the type and constraint '''
        self.setColumnHidden(1, True)
        self.setColumnHidden(2, True)

    def showExtraColumns(self):
        ''' Show the columns containing the type and constraint '''
        self.setColumnHidden(1, False)
        self.setColumnHidden(2, False)

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    def setAsn1Model(self, dataview, row=0):
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        self.item = dataview
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        rootItem = self.addItem(self.item)
        self.treeItem = rootItem["item"]
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        self.model.setItem(row, 1, QStandardItem(rootItem["type"]))
        self.model.setItem(row, 2, QStandardItem(rootItem["constraint"]))
        self.model.setItem(row, 3, QStandardItem(rootItem["value"]))
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        # Add the item to the actual tree. 0,0 = 1st row, 1st column
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        self.model.setItem(row, 0, self.treeItem)
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        self.setWindowTitle('ASN.1 Variable editor')
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        self.hideUnusedFields(self.treeItem, start=True, row=row)
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        self.setColumnWidth(0, 200)
        self.setColumnWidth(1, 150)
        self.expandAll()
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        return rootItem["item"]
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    def hideUnusedFields(self, root, start=False, row=0):
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        ''' Hide CHOICE unselected fields and SEQUENCE OF out-of-range fields '''
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        rootType = self.model.item(row, 1).text()
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        if rootType == 'CHOICE' and start:
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            choices = self.model.item(row, 3).data(CHOICE_LIST)
            currValue = self.model.item(row, 3).text()
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            for j in range(len(choices)):
                if currValue == choices[j]:
                    break
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            rowIndex = self.model.item(row).index()
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            self.choiceDisplay(rowIndex, len(choices), j)
        elif rootType == 'SEQOF' and start:
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            maxValue = self.model.item(row, 3).data(MAX_RANGE)
            currValue = self.model.item(row, 3).text()
            rowIndex = self.model.item(row).index()
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            self.seqofDisplay(rowIndex, currValue, maxValue)

        if root.hasChildren():
            for i in range(root.rowCount()):  # for each row
                self.hideUnusedFields(root.child(i))  # check recursively
                asnType = root.child(i, 1).text()
                if asnType == 'SEQOF':
                    maxValue = root.child(i, 3).data(MAX_RANGE)
                    currValue = root.child(i, 3).text()
                    rowIndex = root.child(i).index()
                    self.seqofDisplay(rowIndex, currValue, maxValue)
                elif asnType == 'CHOICE':
                    choices = root.child(i, 3).data(CHOICE_LIST)
                    currValue = root.child(i, 3).text()
                    for j in range(len(choices)):
                        if currValue == choices[j]:
                            break
                    rowIndex = root.child(i).index()
                    self.choiceDisplay(rowIndex, len(choices), j)

    def parseModel(self, root, nbRows=-1):
        ''' Parse the model to get all field values recursively (root type is QStandardItem) '''
        if root.hasChildren():
            resValue = {}
            seqofValue = []
            seqOf = False
            if nbRows == -1:
                nbRows = root.rowCount()
            else:
                seqOf = True
            for i in range(nbRows):  # for each child row
                name = root.child(i, 0).text()
                asnType = root.child(i, 1).text()
                value = root.child(i, 3).text()
                if asnType in ('SEQUENCE', 'SET'):
                    seqValue = self.parseModel(root.child(i))  # parse recursively
                    resValue[name] = seqValue
                    if seqOf:
                        seqofValue.append(seqValue)
                elif asnType == 'SEQOF':
                    seqOfValue = self.parseModel(root.child(i), nbRows=int(value))
                    resValue[name] = seqOfValue
                    if seqOf:
                        seqofValue.append(seqOfValue)
                elif asnType == 'CHOICE':
                    choiceValue = self.parseModel(root.child(i))  # parse recursively
                    resValue[name] = {"Choice": value, value: choiceValue[value]}
                    if seqOf:
                        seqofValue.append(resValue[name])
                elif asnType == 'INTEGER':
                    resValue[name] = int(value)
                    if seqOf:
                        seqofValue.append(int(value))
                elif asnType == 'REAL':
                    resValue[name] = float(value)
                    if seqOf:
                        seqofValue.append(float(value))
                elif asnType == 'BOOLEAN':
                    if value == 'True':
                        boolValue = True
                    else:
                        boolValue = False
                    resValue[name] = boolValue
                    if seqOf:
                        seqofValue.append(boolValue)
                elif asnType == 'ENUMERATED':
                    resValue[name] = {'Enum': value}
                    if seqOf:
                        seqofValue.append(resValue[name])
                else:  # Strings
                    resValue[name] = value
                    if seqOf:
                        seqofValue.append(value)
            if seqOf:
                return seqofValue
            else:
                return resValue
        else:  # single elements (all but SeqOF, Choice, Sequence)
            row = root.row()
            value = self.model.item(row, 3).text()
            asnType = self.model.item(row, 1).text()
            if asnType == 'INTEGER':
                value = int(value)
            elif asnType == 'REAL':
                value = float(value)
            elif asnType == 'BOOLEAN':
                value = True if value == 'True' else False
            elif asnType == 'ENUMERATED':
                value = {'Enum': value}
            else:
                pass
            return value

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    def getVariable(self, root=None):
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        ''' Read the ASN.1 variable from the tree editor '''
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        root = root or self.treeItem
        row = root.row()
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        name = root.text()
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        asnType = self.model.item(row, 1).text()
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        if asnType == 'SEQOF':
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            nbRows = int(self.model.item(row, 3).text())
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            value = self.parseModel(root, nbRows)
            return {name: value}
        elif asnType == 'CHOICE':
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            value = self.model.item(row, 3).text()
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            choiceValue = self.parseModel(root)
            return {name: {"Choice": value, value: choiceValue[value]}}
        else:
            value = self.parseModel(root)
            return {name: value}

    def updateModel(self, root, var, nbRows=-1):
        ''' Parse the model and update values '''
        if root.hasChildren():
            seqOf = False
            if nbRows == -1:
                nbRows = root.rowCount()
            else:
                seqOf = True
            for i in range(nbRows):
                name = root.child(i, 0).text()
                asnType = root.child(i, 1).text()
                child = root.child(i, 3)
                if seqOf:
                    value = var[i]
                else:
                    if name in var:
                        value = var[name]
                    else:
                        continue
                if asnType in ('INTEGER', 'REAL', 'SEQOF'):
                    plotters = root.child(i, 3).data(PLOTTERS)
                    if plotters is not None:
                        self.log.debug("updateModel - updatePlot call")
                        for plotter in plotters:
                            self.plotterBackend.updatePlot(plotter, value)
                        self.log.debug("updateModel - updatePlot end")
                if asnType in ('INTEGER', 'REAL', 'BOOLEAN', 'STRING'):
                    child.setText(str(value))
                elif asnType == 'ENUMERATED':
                    child.setText(value['Enum'])
                elif asnType in ('SEQUENCE', 'SET'):
                    self.updateModel(root.child(i), value)  # update recursively
                elif asnType == 'CHOICE':
                    child.setText(str(value['Choice']))
                    self.updateModel(root.child(i), value)  # update recursively
                elif asnType == 'SEQOF':
                    child.setText(str(len(value)))
                    self.updateModel(root.child(i), value, len(value))

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    def updateVariable(self, var, root=None):
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        ''' Update the variable value - used when loading a TC or receiving a TM '''
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        root = root or self.treeItem
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        row = root.row()
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        name = root.text()
        value = var[name]
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        asnType = self.model.item(row, 1).text()
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        if asnType == 'SEQOF':
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            self.model.item(row, 3).setText(str(len(value)))
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            self.updateModel(root, var[name], len(value))
        elif asnType == 'CHOICE':
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            self.model.item(row, 3).setText(str(value['Choice']))
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            self.updateModel(root, value)
        elif asnType in ('INTEGER', 'REAL', 'STRING', 'BOOLEAN'):
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            self.model.item(row, 3).setText(str(value))
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        elif asnType == 'ENUMERATED':
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            self.model.item(row, 3).setText(value['Enum'])
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        else:  # SEQUENCE or SET
            self.updateModel(root, value)
        if asnType in ('INTEGER', 'REAL', 'SEQOF'):
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            plotters = self.model.item(row, 3).data(PLOTTERS)
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            if plotters != None:
                for plotter in plotters:
                    self.plotterBackend.updatePlot(plotter, value)
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        self.hideUnusedFields(root, True, row=row)
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        if self.plotterBackend is not None:
            self.plotterBackend.refresh()
        # Inform the thread to update the tree (expand all branches)
        self.expandTree.emit()

    def tmToEditor(self, pythonVar):
        ''' Check validity of a TM and update the viewer with the value '''
        self.log.debug("Entering tmToEditor")
        if pythonVar == {}:
            self.log.error('Error decoding ' + self.treeItem.text() + ' TM')
            self.statusBarMessage.emit('Error decoding ' + self.treeItem.text() + ' TM')
        else:
            self.updateVariable(pythonVar)
            for name in pythonVar:
                # Send value to the MSC recorder
                asnVN = vn.toASN1ValueNotation(pythonVar[name])
                msg = name + '(' + asnVN + ')'
                self.log.debug('Emitting input to MSC')  # + msg)
                self.msc.emit('in', msg)
        self.log.debug("Leaving tmToEditor")

    def ProcessTM(self, rawMsg):
        ''' Decode a TM received from the msgQ (not UDP) and update the model '''
        self.log.debug("Entering ProcessTM")
        native_tm = self.backend.decode_TM(rawMsg)
        pythonVar = self.backend.fromASN1ToPyside(native_tm)
        self.tmToEditor(pythonVar)
        self.log.debug("Leaving ProcessTM")

    @Slot()
    def receivedTM(self):
        ''' TM received from another thread (polling queue) '''
        if self.pendingTM:
            self.ProcessTM(self.pendingTM)
            self.pendingTM = None

    def ProcessUDPTM(self, uperMsg):
        ''' Decode an uPER-encoded TM (e.g. received from UDP sockets) and update the model '''
        native_tm = self.backend.decode_uPER(uperMsg)
        pythonVar = self.backend.fromASN1ToPyside(native_tm)
        self.tmToEditor(pythonVar)

    def saveTC(self):
        ''' Encode the data using GSER (ASN.1 Value Notation) and save it to a file'''
        data = self.getVariable()
        for name in data:
            asnVN = vn.toASN1ValueNotation(data[name]).replace('_', '-')
            self.log.debug('Saving ' + asnVN)
            #uPER_buffer = self.backend.encode_uPER(native_tc)
        filename = QFileDialog.getSaveFileName(self, "Save TC", ".", "ASN.1 Variable (*.tc)")[0]
        try:
            if filename.split('.')[-1] != 'tc':
                filename += ".tc"
            tcFile = QFile(filename)
            tcFile.open(QIODevice.WriteOnly | QIODevice.Text)
            #tcFile.write(uPER_buffer)
            tcFile.write(str(asnVN))
            tcFile.close()
        except:
            pass

    def sendTC(self):
        ''' Encode and send the TC to the main TASTE binary using message queue or UDP '''
        data = self.getVariable()
        for name in data:
            asnVN = vn.toASN1ValueNotation(data[name]).replace('_', '-').strip()
            msg = name + '(' + asnVN + ')'
            self.log.debug('out ' + msg)
            self.msc.emit('out', msg)
        asnVal = self.backend.fromPysideToASN1(data)
        self.backend.sendTC(asnVal)

    def loadTC(self):
        ''' Load/Decode a TC and populate the values in the model '''
        filename = QFileDialog.getOpenFileName(self, "Open TC", ".", "ASN.1 Variable (*.tc)")[0]
        if len(filename) == 0:
            return
        try:
            tcFile = QFile(filename)
            tcFile.open(QIODevice.ReadOnly | QIODevice.Text)
            asnVN = str(tcFile.readData(tcFile.size()))
            tcFile.close()
            pythonVar = vn.fromValueNotationToPySide(self.treeItem.text(), asnVN)
            self.updateVariable(pythonVar)
        except:
            pass

    def dataPath(self, idx):
        ''' Create a textual representation of a field path (e.g. myTM.myChoice.position.x) '''
        if not idx.isValid():
            return ''
        subpath = self.dataPath(idx.parent())
        if len(subpath)>0:
            subpath+='.'
        subpath += idx.data()
        return subpath

    def pathToIdx(self, path, root=None):
        ''' Find an index in the model based from a dot-splitted path representation '''
        if root is None:
            root = self.treeItem.index()
        if len(path) == 1:
            return QPersistentModelIndex(root) if root.data() == path[0] else None
        else:
            # Recursive call for each child
            for i in range(self.model.itemFromIndex(root).rowCount()):
                result = self.pathToIdx(path[1:], root.child(i, 0))
                if result is not None:
                    return result

    def newPlot(self, fifoId=-1, meter=False):
        ''' Add a set of data (based on selected lines) to a new plotter or speedometer '''
        selectedIdxs = self.selectedIndexes()
        # Count the number of eligible lines for plotting (discard non-numerical types)
        eligible=[]
        for idx in selectedIdxs:
            if idx.column() > 0:
                continue
            asntype = idx.sibling(idx.row(), 1).data()
            if asntype in ('INTEGER', 'REAL', 'SEQOF'):
                self.log.info('Candidate for plot: '+ self.dataPath(idx))
                discard = False
                if fifoId > 0:
                    currData=idx.sibling(idx.row(), 3).data(PLOTTERS)
                    if currData is not None:
                        for elem in currData:
                            if elem['fifoId'] == fifoId:
                                discard = True
                if not discard:
                    eligible.append(idx.sibling(idx.row(), 3))
                else:
                    self.log.info('(but discarding because already in current plot)')
            else:
                self.log.warning('Cannot plot {data} (type {asntype} is not numerical)'.format(data=idx.data(), asntype=asntype))
        if len(eligible) == 0:
            self.log.warning('No valid lines selected for the plot')
            self.statusBarMessage.emit('No valid lines selected for the plot')
            return
        if fifoId == -1 and not meter:
            fifoId = self.plotterBackend.newPlot()
        for idx in eligible:
            dataPath = self.dataPath(idx.sibling(idx.row(), 0))
            currData = idx.data(PLOTTERS)
            minRange = idx.data(MIN_RANGE)
            maxRange = idx.data(MAX_RANGE)
            if meter:
                fifoId = self.plotterBackend.newMeter(dataPath, minRange, maxRange)
            if currData is None:
                currData = []
            currData.append({'fifoId': int(fifoId), 'curveName': dataPath})
            idx.model().setData(idx, currData, PLOTTERS)
            # Keep track of all plotted values - used when saving the model state
            persistentIdx = QPersistentModelIndex(idx)
            if persistentIdx not in self.plottedIdxs:
                self.plottedIdxs.append(persistentIdx)

    def addToPlot(self):
        ''' Add a new curve to an existing plot window '''
        fifoId = self.sender().text().split()[-1]
        self.newPlot(int(fifoId))

    def setPlotterBackend(self, backend):
        ''' Set a "pointer" to the GnuPlot/Meter backend module '''
        self.plotterBackend = backend

    def meter(self):
        ''' Create speedometers for the selected values '''
        self.newPlot(meter=True)

    def displaytip(self, index):
        ''' Display a tip when the mouse moves above a cell '''
        asnType = index.sibling(index.row(), 1).data()
        constraint = index.sibling(index.row(), 2).data()
        self.statusBarMessage.emit(asnType + ' ' + (constraint if constraint is not None else ''))

    @Slot(QModelIndex, int, int)
    def seqofDisplay(self, parent, val, max):
        ''' Slot updating the number of SEQOF elements displayed '''
        for row in range(max):
            if int(row) < int(val):
                display = False
            else:
                display = True
            self.setRowHidden(row, parent, display)
        self.expandBranch.emit(parent)

    @Slot(QModelIndex, int, int)
    def choiceDisplay(self, parent, nbOfElem, choice):
        ''' Slot updating the current selected CHOICE element '''
        for row in range(nbOfElem):
            if int(choice) == int(row):
                display = False
            else:
                display = True
            self.setRowHidden(row, parent, display)
        self.expandBranch.emit(parent)

    def addInteger(self, elem):
        # Set default value (min range):
        val = QStandardItem('%d' % elem["minR"])
        # Define type attributes, later used to define the proper cell editor
        val.setData(elem["type"], ASN1TYPE)
        try:
            val.setData(elem["minR"], MIN_RANGE)
        except OverflowError:
            val.setData(-1000000, MIN_RANGE)
        try:
            val.setData(elem["maxR"], MAX_RANGE)
        except OverflowError:
            val.setData(1000000, MAX_RANGE)
        # Set the text for the constraint and add it to the 3rd column:
        constraint = QStandardItem('(%d..%d)' % (elem["minR"], elem["maxR"]))
        constraint.setData(QBrush(QColor("gray")), Qt.ForegroundRole)
        return {"value": val, "constraint": constraint}

    def addReal(self, elem):
        # Set default value (min range):
        val = QStandardItem('%.2f' % elem["minR"])
        # Define type attributes, later used to define the proper cell editor
        val.setData(elem["type"], ASN1TYPE)
        try:
            val.setData(elem["minR"], MIN_RANGE)
        except OverflowError:
            # Python cannot handle 64bit double - reducing the range in case of overflow
            val.setData(-10000000.0, MIN_RANGE)
        try:
            val.setData(elem["maxR"], MAX_RANGE)
        except OverflowError:
            val.setData(10000000.0, MAX_RANGE)
        # Set the text for the constraint and add it to the 3rd column:
        constraint = QStandardItem('(%.2f..%.2f)' % (elem["minR"], elem["maxR"]))
        constraint.setData(QBrush(QColor("gray")), Qt.ForegroundRole)
        return {"value": val, "constraint": constraint}

    def addEnum(self, elem):
        # Set default value (first enum value)
        val = QStandardItem(elem["values"][0])
        # Define type attributes, later used to define the proper cell editor
        val.setData(elem["type"], ASN1TYPE)  # type (ENUMERATED)
        val.setData(elem["values"], CHOICE_LIST)  # enum values
        constraint = QStandardItem()
        return {"value": val, "constraint": constraint}

    def addString(self, elem):
        # Set default value (empty string)
        if "default" in elem:
            defaultString = elem["default"]
        else:
            defaultString = ""
        val = QStandardItem(defaultString)
        # Define type attributes, later used to define the proper cell editor
        val.setData(elem["type"], ASN1TYPE)  # type (IA5String)
        val.setData(elem["minSize"], MIN_RANGE)  # size min
        val.setData(elem["maxSize"], MAX_RANGE)  # size max
        # Set the text for the constraint and add it to the 3rd column:
        if elem["minSize"] == elem["maxSize"]:
            constraintStr = 'SIZE(%d)' % elem["minSize"]
        else:
            constraintStr = 'SIZE(%d..%d)' % (elem["minSize"], elem["maxSize"])
        constraint = QStandardItem(constraintStr)
        constraint.setData(QBrush(QColor("gray")), Qt.ForegroundRole)
        return {"value": val, "constraint": constraint}

    def addBool(self, elem):
        # Set default value (True or False)
        val = QStandardItem(elem["default"])
        # Define type attributes, later used to define the proper cell editor
        val.setData(elem["type"], ASN1TYPE)  # type (BOOLEAN)
        val.setData(['True', 'False'], CHOICE_LIST)  # enum values
        constraint = QStandardItem()
        return {"value": val, "constraint": constraint}

    def addSequence(self, elem, parent):
        types = []
        values = []
        constraints = []

        for child in elem["children"]:
            field = self.addItem(child)
            parent.appendRow(field["item"])
            types.append(field["type"])
            values.append(field["value"])
            constraints.append(field["constraint"])

        parent.appendColumn(types)
        parent.appendColumn(constraints)
        parent.appendColumn(values)
        constraint = QStandardItem()
        val = QStandardItem()
        return {"value": val, "constraint": constraint}

    def addSeqOf(self, elem, parent):
        types = []
        values = []
        constraints = []
        for i in range(elem["maxSize"]):
            elem["seqoftype"]["id"] = "elem_%d" % i
            field = self.addItem(elem["seqoftype"])
            parent.appendRow(field["item"])
            types.append(field["type"])
            values.append(field["value"])
            constraints.append(field["constraint"])
        parent.appendColumn(types)
        parent.appendColumn(constraints)
        parent.appendColumn(values)
        if elem["minSize"] == elem["maxSize"]:
            constraintStr = 'SIZE(%d)' % elem["minSize"]
        else:
            constraintStr = 'SIZE(%d..%d)' % (elem["minSize"], elem["maxSize"])
        constraint = QStandardItem(constraintStr)
        constraint.setData(QBrush(QColor("gray")), Qt.ForegroundRole)
        val = QStandardItem('%d' % elem["minSize"])
        val.setData(elem["type"], ASN1TYPE)   # type (SEQOF)
        val.setData(elem["minSize"], MIN_RANGE)  # min number of elements
        val.setData(elem["maxSize"], MAX_RANGE)  # max number of elements
        return {"value": val, "constraint": constraint}

    def addChoice(self, elem, parent):
        types = []
        values = []
        constraints = []
        ids = []
        for choice in elem["choices"]:
            field = self.addItem(choice)
            ids.append(choice["id"])
            parent.appendRow(field["item"])
            types.append(field["type"])
            values.append(field["value"])
            constraints.append(field["constraint"])

        parent.appendColumn(types)
        parent.appendColumn(constraints)
        parent.appendColumn(values)

        val = QStandardItem(ids[0])  # default value: first choice
        # Define type attributes, later used to define the proper cell editor
        val.setData(elem["type"], ASN1TYPE)  # type (CHOICE)
        val.setData(ids, CHOICE_LIST)  # choice values
        constraint = QStandardItem()
        return {"value": val, "constraint": constraint}

    def addItem(self, elem):
        # Add field name on the first column:
        field = QStandardItem(elem["id"])
        # Add type on the second column in gray:
        asnType = QStandardItem(elem["type"])
        asnType.setData(QBrush(QColor("gray")), Qt.ForegroundRole)

        # get the Value and Contraints fields for the different types:
        if elem["type"] == 'INTEGER':
            data = self.addInteger(elem)
        elif elem["type"] == 'REAL':
            data = self.addReal(elem)
        elif elem["type"] == 'BOOLEAN':
            data = self.addBool(elem)
        elif elem["type"] == 'ENUMERATED':
            data = self.addEnum(elem)
        elif elem["type"] == 'STRING':
            data = self.addString(elem)
        elif elem["type"] in ('SEQUENCE', 'SET'):
            data = self.addSequence(elem, field)
        elif elem["type"] == 'SEQOF':
            data = self.addSeqOf(elem, field)
        elif elem["type"] == 'CHOICE':
            data = self.addChoice(elem, field)
        else:
            print 'You are using a non-supported type: ' + elem["type"]
            sys.exit(-1)
        return {"item": field, "type": asnType, "value": data["value"], "constraint": data["constraint"]}


class asn1Viewer(asn1Editor):
    ''' TM Viewing class. Fields are not editable '''
    def __init__(self, parent=None):
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        super(asn1Viewer, self).__init__(parent)
Maxime Perrotin's avatar
Maxime Perrotin committed
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        self.setEditTriggers(QAbstractItemView.NoEditTriggers)