# Python interface to some of the commands of the 2.4 version of the
# BLT extension to tcl.
#
# $User:$
#
# $Date: 2006/02/03 13:19:45 $
#
# $Revision: 1.1.1.1 $
#
# $Header: /home/saturne/CVS/ICS/ics/Base/Blt.py,v 1.1.1.1 2006/02/03 13:19:45 douce Exp $
#
#------------------------------------------------------------------
"""
$Log: Blt.py,v $
Revision 1.1.1.1 2006/02/03 13:19:45 douce
First ics import
Revision 1.2 2003/05/28 12:33:43 alexmiro
added some code for making serialisation possible.
Added a properties-editor menu to GraphView
Revision 0.2 99/11/08 12:34:03 12:34:03 rey (Vicente Rey-Bakaikoa)
Working version without maths. On 7/Nov/99.
It implements graphelement class but not yet selection of
different sources.
Revision 0.1 99/10/29 09:13:18 09:13:18 rey (Vicente Rey-Bakaikoa)
prebeta version... not completed but working.
before big changes on classes
"""
import string
import types
import Tkinter
# Supported commands:
_busyCommand = '::blt::busy'
_vectorCommand = '::blt::vector'
_graphCommand = '::blt::graph'
_testCommand = '::blt::*'
_chartCommand = '::blt::stripchart'
_tabsetCommand = '::blt::tabset'
_haveBlt = None
_haveBltBusy = None
def _checkForBlt(window):
global _haveBlt
global _haveBltBusy
# Blt may be a package which has not yet been loaded. Try to load it.
try:
window.tk.call('package', 'require', 'BLT')
except Tkinter.TclError:
# Another way to try to dynamically load blt:
try:
window.tk.call('load', '', 'Blt')
except Tkinter.TclError:
pass
_haveBlt= (window.tk.call('info', 'commands', _testCommand) != '')
_haveBltBusy = (window.tk.call('info', 'commands', _busyCommand) != '')
def haveblt(window):
if _haveBlt is None:
_checkForBlt(window)
return _haveBlt
def havebltbusy(window):
if _haveBlt is None:
_checkForBlt(window)
return _haveBltBusy
def _loadBlt(window):
if _haveBlt is None:
if window is None:
window = Tkinter._default_root
if window is None:
window = Tkinter.Tk()
_checkForBlt(window)
def busy_hold(window, cursor = None):
_loadBlt(window)
if cursor is None:
window.tk.call(_busyCommand, 'hold', window._w)
else:
window.tk.call(_busyCommand, 'hold', window._w, '-cursor', cursor)
def busy_release(window):
_loadBlt(window)
window.tk.call(_busyCommand, 'release', window._w)
def busy_forget(window):
_loadBlt(window)
window.tk.call(_busyCommand, 'forget', window._w)
#=============================================================================
# Interface to the blt vector command which makes it look like the
# builtin python list type.
# The -variable, -command, -watchunset creation options are not supported.
# The dup, merge, notify, offset, populate, seq and variable methods
# and the +, -, * and / operations are not supported.
# Blt vector functions:
def vector_expr(expression):
tk = Tkinter._default_root.tk
strList = tk.splitlist(tk.call(_vectorCommand, 'expr', expression))
return tuple(map(string.atof, strList))
def vector_names(pattern = None):
tk = Tkinter._default_root.tk
return tk.splitlist(tk.call(_vectorCommand, 'names', pattern))
class Vector:
_varnum = 0
def __init__(self, size=None, master=None):
# <size> can be either an integer size, or a string "first:last".
_loadBlt(master)
if master:
self._master = master
else:
self._master = Tkinter._default_root
self.tk = self._master.tk
self._name = 'PY_VEC' + str(Vector._varnum)
Vector._varnum = Vector._varnum + 1
if size is None:
self.tk.call(_vectorCommand, 'create', self._name)
else:
self.tk.call(_vectorCommand, 'create', '%s(%s)' % (self._name, size))
def __del__(self):
self.tk.call(_vectorCommand, 'destroy', self._name)
def __str__(self):
return self._name
def __repr__(self):
return '[' + string.join(map(str, self), ', ') + ']'
def __cmp__(self, list):
return cmp(self[:], list)
def __len__(self):
return self.tk.getint(self.tk.call(self._name, 'length'))
def __getitem__(self, key):
oldkey = key
if key < 0:
key = key + len(self)
try:
return self.tk.getdouble(self.tk.globalgetvar(self._name, str(key)))
except Tkinter.TclError:
raise IndexError, oldkey
def __setitem__(self, key, value):
if key < 0:
key = key + len(self)
return self.tk.globalsetvar(self._name, str(key), float(value))
def __delitem__(self, key):
if key < 0:
key = key + len(self)
return self.tk.globalunsetvar(self._name, str(key))
def __getslice__(self, start, end):
length = len(self)
if start < 0:
start = 0
if end > length:
end = length
if start >= end:
return []
end = end - 1 # Blt vector slices include end point.
text = self.tk.globalgetvar(self._name, str(start) + ':' + str(end))
return map(self.tk.getdouble, self.tk.splitlist(text))
def __setslice__(self, start, end, list):
if start > end:
end = start
self.set(self[:start] + list + self[end:])
def __delslice__(self, start, end):
if start < end:
self.set(self[:start] + self[end:])
def __add__(self, list):
return self[:] + list
def __radd__(self, list):
return list + self[:]
def __mul__(self, n):
return self[:] * n
__rmul__ = __mul__
# Python builtin list methods:
def append(self, *args):
self.tk.call(self._name, 'append', args)
def count(self, obj):
return self[:].count(obj)
def index(self, value):
return self[:].index(value)
def insert(self, index, value):
self[index:index] = [value]
def remove(self, value):
del self[self.index(value)]
def reverse(self):
s = self[:]
s.reverse()
self.set(s)
def sort(self, *args):
s = self[:]
s.sort()
self.set(s)
# Blt vector instance methods:
# append - same as list method above
def clear(self):
self.tk.call(self._name, 'clear')
def delete(self, *args):
self.tk.call((self._name, 'delete') + args)
def expr(self, expression):
self.tk.call(self._name, 'expr', expression)
def length(self, newSize=None):
return self.tk.getint(self.tk.call(self._name, 'length', newSize))
def range(self, first, last=None):
# Note that, unlike self[first:last], this includes the last
# item in the returned range.
text = self.tk.call(self._name, 'range', first, last)
return map(self.tk.getdouble, self.tk.splitlist(text))
def search(self, start, end=None):
return self._master._getints(self.tk.call(
self._name, 'search', start, end))
def set(self, list):
if type(list) != types.TupleType:
list = tuple(list)
self.tk.call(self._name, 'set', list)
# The blt vector sort method has different semantics to the python
# list sort method. Call these blt_sort:
def blt_sort(self, *args):
self.tk.call((self._name, 'sort') + args)
def blt_sort_reverse(self, *args):
self.tk.call((self._name, 'sort', '-reverse') + args)
# Special blt vector indexes:
def min(self):
return self.tk.getdouble(self.tk.globalgetvar(self._name, 'min'))
def max(self):
return self.tk.getdouble(self.tk.globalgetvar(self._name, 'max'))
# Method borrowed from Tkinter.Var class:
def get(self):
return self[:]
#=============================================================================
# This is a general purpose configure routine which can handle the
# configuration of widgets, items within widgets, etc. Supports the
# forms configure() and configure('font') for querying and
# configure(font = 'fixed', text = 'hello') for setting.
def _doConfigure(widget, subcommand, option, kw):
if not option and not kw:
# Return a description of all options.
ret = {}
options = widget.tk.splitlist(widget.tk.call(subcommand))
for optionString in options:
optionInfo = widget.tk.splitlist(optionString)
option = optionInfo[0][1:]
ret[option] = (option,) + optionInfo[1:]
return ret
if option:
# Return a description of the option given by <option>.
if kw:
# Having keywords implies setting configuration options.
# Can't set and get in one command!
raise ValueError, 'cannot have option argument with keywords'
option = '-' + option
optionInfo = widget.tk.splitlist(widget.tk.call(subcommand + (option,)))
return (optionInfo[0][1:],) + optionInfo[1:]
# Otherwise, set the given configuration options.
widget.tk.call(subcommand + widget._options(kw))
#=============================================================================
class Graph(Tkinter.Widget):
# Wrapper for the blt graph widget, version 2.4.
def __init__(self, master=None, cnf={}, **kw):
_loadBlt(master)
Tkinter.Widget.__init__(self, master, _graphCommand, cnf, kw)
def bar_create(self, name, **kw):
self.tk.call((self._w, 'bar', 'create', name) + self._options(kw))
def line_create(self, name, **kw):
self.tk.call((self._w, 'line', 'create', name) + self._options(kw))
def extents(self, item):
return self.tk.getint(self.tk.call(self._w, 'extents', item))
def invtransform(self, winX, winY):
return self._getdoubles(
self.tk.call(self._w, 'invtransform', winX, winY))
def inside(self, x, y):
return self.tk.getint(self.tk.call(self._w, 'inside', x, y))
def snap(self, photoName):
self.tk.call(self._w, 'snap', photoName)
def transform(self, x, y):
return self._getdoubles(self.tk.call(self._w, 'transform', x, y))
def axis_cget(self, axisName, key):
return self.tk.call(self._w, 'axis', 'cget', axisName, '-' + key)
def axis_configure(self, axes, option=None, **kw):
# <axes> may be a list of axisNames.
if type(axes) == types.StringType:
axes = [axes]
subcommand = (self._w, 'axis', 'configure') + tuple(axes)
return _doConfigure(self, subcommand, option, kw)
def axis_create(self, axisName, **kw):
self.tk.call((self._w, 'axis', 'create', axisName) + self._options(kw))
def axis_delete(self, *args):
self.tk.call((self._w, 'axis', 'delete') + args)
def axis_invtransform(self, axisName, value):
return self.tk.getdouble(self.tk.call(
self._w, 'axis', 'invtransform', axisName, value))
def axis_limits(self, axisName):
return self._getdoubles(self.tk.call(
self._w, 'axis', 'limits', axisName))
def axis_names(self, *args):
return self.tk.splitlist(
self.tk.call((self._w, 'axis', 'names') + args))
def axis_transform(self, axisName, value):
return self.tk.getint(self.tk.call(
self._w, 'axis', 'transform', axisName, value))
def xaxis_cget(self, key):
return self.tk.call(self._w, 'xaxis', 'cget', '-' + key)
def xaxis_configure(self, option=None, **kw):
subcommand = (self._w, 'xaxis', 'configure')
return _doConfigure(self, subcommand, option, kw)
def xaxis_invtransform(self, value):
return self.tk.getdouble(self.tk.call(
self._w, 'xaxis', 'invtransform', value))
def xaxis_limits(self):
return self._getdoubles(self.tk.call(self._w, 'xaxis', 'limits'))
def xaxis_transform(self, value):
return self.tk.getint(self.tk.call(
self._w, 'xaxis', 'transform', value))
def xaxis_use(self, axisName = None):
return self.tk.call(self._w, 'xaxis', 'use', axisName)
def x2axis_cget(self, key):
return self.tk.call(self._w, 'x2axis', 'cget', '-' + key)
def x2axis_configure(self, option=None, **kw):
subcommand = (self._w, 'x2axis', 'configure')
return _doConfigure(self, subcommand, option, kw)
def x2axis_invtransform(self, value):
return self.tk.getdouble(self.tk.call(
self._w, 'x2axis', 'invtransform', value))
def x2axis_limits(self):
return self._getdoubles(self.tk.call(self._w, 'x2axis', 'limits'))
def x2axis_transform(self, value):
return self.tk.getint(self.tk.call(
self._w, 'x2axis', 'transform', value))
def x2axis_use(self, axisName = None):
return self.tk.call(self._w, 'x2axis', 'use', axisName)
def yaxis_cget(self, key):
return self.tk.call(self._w, 'yaxis', 'cget', '-' + key)
def yaxis_configure(self, option=None, **kw):
subcommand = (self._w, 'yaxis', 'configure')
return _doConfigure(self, subcommand, option, kw)
def yaxis_invtransform(self, value):
return self.tk.getdouble(self.tk.call(
self._w, 'yaxis', 'invtransform', value))
def yaxis_limits(self):
return self._getdoubles(self.tk.call(self._w, 'yaxis', 'limits'))
def yaxis_transform(self, value):
return self.tk.getint(self.tk.call(
self._w, 'yaxis', 'transform', value))
def yaxis_use(self, axisName = None):
return self.tk.call(self._w, 'yaxis', 'use', axisName)
def y2axis_cget(self, key):
return self.tk.call(self._w, 'y2axis', 'cget', '-' + key)
def y2axis_configure(self, option=None, **kw):
subcommand = (self._w, 'y2axis', 'configure')
return _doConfigure(self, subcommand, option, kw)
def y2axis_invtransform(self, value):
return self.tk.getdouble(self.tk.call(
self._w, 'y2axis', 'invtransform', value))
def y2axis_limits(self):
return self._getdoubles(self.tk.call(self._w, 'y2axis', 'limits'))
def y2axis_transform(self, value):
return self.tk.getint(self.tk.call(
self._w, 'y2axis', 'transform', value))
def y2axis_use(self, axisName = None):
return self.tk.call(self._w, 'y2axis', 'use', axisName)
def crosshairs_cget(self, key):
return self.tk.call(self._w, 'crosshairs', 'cget', '-' + key)
def crosshairs_configure(self, option=None, **kw):
subcommand = (self._w, 'crosshairs', 'configure')
return _doConfigure(self, subcommand, option, kw)
def crosshairs_off(self):
self.tk.call(self._w, 'crosshairs', 'off')
def crosshairs_on(self):
self.tk.call(self._w, 'crosshairs', 'on')
def crosshairs_toggle(self):
self.tk.call(self._w, 'crosshairs', 'toggle')
def element_create(self, name, **kw):
self.tk.call((self._w, 'element', 'create', name) + self._options(kw))
def element_activate(self, name, *args):
self.tk.call((self._w, 'element', 'activate', name) + args)
def element_bind(self, tagName, sequence=None, func=None, add=None):
return self._bind((self._w, 'element', 'bind', tagName),
sequence, func, add)
def element_unbind(self, tagName, sequence, funcid=None):
self.tk.call(self._w, 'element', 'bind', tagName, sequence, '')
if funcid:
self.deletecommand(funcid)
def element_cget(self, name, key):
return self.tk.call(self._w, 'element', 'cget', name, '-' + key)
def element_closest(self, x, y, *args, **kw):
var = 'python_private_1'
success = self.tk.getint(self.tk.call(
(self._w, 'element', 'closest', x, y, var) +
args + self._options(kw)))
if success:
rtn = {}
rtn['dist'] = self.tk.getdouble(self.tk.globalgetvar(var, 'dist'))
rtn['x'] = self.tk.getdouble(self.tk.globalgetvar(var, 'x'))
rtn['y'] = self.tk.getdouble(self.tk.globalgetvar(var, 'y'))
rtn['index'] = self.tk.getint(self.tk.globalgetvar(var, 'index'))
rtn['name'] = self.tk.globalgetvar(var, 'name')
return rtn
else:
return None
def element_configure(self, names, option=None, **kw):
# <names> may be a list of elemNames.
if type(names) == types.StringType:
names = [names]
subcommand = (self._w, 'element', 'configure') + tuple(names)
return _doConfigure(self, subcommand, option, kw)
def element_deactivate(self, *args):
self.tk.call((self._w, 'element', 'deactivate') + args)
def element_delete(self, *args):
self.tk.call((self._w, 'element', 'delete') + args)
def element_exists(self, name):
return self.tk.getboolean(
self.tk.call(self._w, 'element', 'exists', name))
def element_names(self, *args):
return self.tk.splitlist(
self.tk.call((self._w, 'element', 'names') + args))
def element_show(self, nameList=None):
if nameList is not None:
nameList = tuple(nameList)
return self.tk.splitlist(
self.tk.call(self._w, 'element', 'show', nameList))
def element_type(self, name):
return self.tk.call(self._w, 'element', 'type', name)
def grid_cget(self, key):
return self.tk.call(self._w, 'grid', 'cget', '-' + key)
def grid_configure(self, option=None, **kw):
subcommand = (self._w, 'grid', 'configure')
return _doConfigure(self, subcommand, option, kw)
def grid_off(self):
self.tk.call(self._w, 'grid', 'off')
def grid_on(self):
self.tk.call(self._w, 'grid', 'on')
def grid_toggle(self):
self.tk.call(self._w, 'grid', 'toggle')
def legend_activate(self, *args):
self.tk.call((self._w, 'legend', 'activate') + args)
def legend_bind(self, tagName, sequence=None, func=None, add=None):
return self._bind((self._w, 'legend', 'bind', tagName),
sequence, func, add)
def legend_unbind(self, tagName, sequence, funcid=None):
self.tk.call(self._w, 'legend', 'bind', tagName, sequence, '')
if funcid:
self.deletecommand(funcid)
def legend_cget(self, key):
return self.tk.call(self._w, 'legend', 'cget', '-' + key)
def legend_configure(self, option=None, **kw):
subcommand = (self._w, 'legend', 'configure')
return _doConfigure(self, subcommand, option, kw)
def legend_deactivate(self, *args):
self.tk.call((self._w, 'legend', 'deactivate') + args)
def legend_get(self, pos):
return self.tk.call(self._w, 'legend', 'get', pos)
def pen_cget(self, name, key):
return self.tk.call(self._w, 'pen', 'cget', name, '-' + key)
def pen_configure(self, names, option=None, **kw):
# <names> may be a list of penNames.
if type(names) == types.StringType:
names = [names]
subcommand = (self._w, 'pen', 'configure') + tuple(names)
return _doConfigure(self, subcommand, option, kw)
def pen_create(self, name, **kw):
self.tk.call((self._w, 'pen', 'create', name) + self._options(kw))
def pen_delete(self, *args):
self.tk.call((self._w, 'pen', 'delete') + args)
def pen_names(self, *args):
return self.tk.splitlist(self.tk.call((self._w, 'pen', 'names') + args))
def postscript_cget(self, key):
return self.tk.call(self._w, 'postscript', 'cget', '-' + key)
def postscript_configure(self, option=None, **kw):
subcommand = (self._w, 'postscript', 'configure')
return _doConfigure(self, subcommand, option, kw)
def postscript_output(self, fileName=None, **kw):
prefix = (self._w, 'postscript', 'output')
if fileName is None:
return self.tk.call(prefix + self._options(kw))
else:
self.tk.call(prefix + (fileName,) + self._options(kw))
def marker_after(self, first, second=None):
self.tk.call(self._w, 'marker', 'after', first, second)
def marker_before(self, first, second=None):
self.tk.call(self._w, 'marker', 'before', first, second)
def marker_bind(self, tagName, sequence=None, func=None, add=None):
return self._bind((self._w, 'marker', 'bind', tagName),
sequence, func, add)
def marker_unbind(self, tagName, sequence, funcid=None):
self.tk.call(self._w, 'marker', 'bind', tagName, sequence, '')
if funcid:
self.deletecommand(funcid)
def marker_cget(self, name, key):
return self.tk.call(self._w, 'marker', 'cget', name, '-' + key)
def marker_configure(self, names, option=None, **kw):
# <names> may be a list of markerIds.
if type(names) == types.StringType:
names = [names]
subcommand = (self._w, 'marker', 'configure') + tuple(names)
return _doConfigure(self, subcommand, option, kw)
def marker_create(self, type, **kw):
return self.tk.call(
(self._w, 'marker', 'create', type) + self._options(kw))
def marker_delete(self, *args):
self.tk.call((self._w, 'marker', 'delete') + args)
def marker_exists(self, name):
return self.tk.getboolean(
self.tk.call(self._w, 'marker', 'exists', name))
def marker_names(self, *args):
return self.tk.splitlist(
self.tk.call((self._w, 'marker', 'names') + args))
def marker_type(self, name):
type = self.tk.call(self._w, 'marker', 'type', name)
if type == '':
type = None
return type
#=============================================================================
class Stripchart(Graph):
# Wrapper for the blt stripchart widget, version 2.4.
def __init__(self, master=None, cnf={}, **kw):
_loadBlt(master)
Tkinter.Widget.__init__(self, master, _chartCommand, cnf, kw)
#=============================================================================
class Tabset(Tkinter.Widget):
# Wrapper for the blt TabSet widget, version 2.4.
def __init__(self, master=None, cnf={}, **kw):
_loadBlt(master)
Tkinter.Widget.__init__(self, master, _tabsetCommand, cnf, kw)
def activate(self, tabIndex):
self.tk.call(self._w, 'activate', tabIndex)
# This is the 'bind' sub-command:
def tag_bind(self, tagName, sequence=None, func=None, add=None):
return self._bind((self._w, 'bind', tagName), sequence, func, add)
def tag_unbind(self, tagName, sequence, funcid=None):
self.tk.call(self._w, 'bind', tagName, sequence, '')
if funcid:
self.deletecommand(funcid)
def delete(self, first, last = None):
self.tk.call(self._w, 'delete', first, last)
# This is the 'focus' sub-command:
def tab_focus(self, tabIndex):
self.tk.call(self._w, 'focus', tabIndex)
def get(self, tabIndex):
return self.tk.call(self._w, 'get', tabIndex)
def index(self, tabIndex):
index = self.tk.call(self._w, 'index', tabIndex)
if index == '':
return None
else:
return self.tk.getint(self.tk.call(self._w, 'index', tabIndex))
def insert(self, position, name1, *names, **kw):
self.tk.call(
(self._w, 'insert', position, name1) + names + self._options(kw))
def invoke(self, tabIndex):
return self.tk.call(self._w, 'invoke', tabIndex)
def move(self, tabIndex1, beforeOrAfter, tabIndex2):
self.tk.call(self._w, 'move', tabIndex1, beforeOrAfter, tabIndex2)
def nearest(self, x, y):
return self.tk.call(self._w, 'nearest', x, y)
def scan_mark(self, x, y):
self.tk.call(self._w, 'scan', 'mark', x, y)
def scan_dragto(self, x, y):
self.tk.call(self._w, 'scan', 'dragto', x, y)
def see(self, index):
self.tk.call(self._w, 'see', index)
def see(self, tabIndex):
self.tk.call(self._w,'see',tabIndex)
def size(self):
return self.tk.getint(self.tk.call(self._w, 'size'))
def tab_cget(self, tabIndex, option):
if option[:1] != '-':
option = '-' + option
if option[-1:] == '_':
option = option[:-1]
return self.tk.call(self._w, 'tab', 'cget', tabIndex, option)
def tab_configure(self, tabIndexes, option=None, **kw):
# <tabIndexes> may be a list of tabs.
if type(tabIndexes) in (types.StringType, types.IntType):
tabIndexes = [tabIndexes]
subcommand = (self._w, 'tab', 'configure') + tuple(tabIndexes)
return _doConfigure(self, subcommand, option, kw)
def tab_names(self, *args):
return self.tk.splitlist(self.tk.call((self._w, 'tab', 'names') + args))
def tab_tearoff(self, tabIndex, newName = None):
if newName is None:
name = self.tk.call(self._w, 'tab', 'tearoff', tabIndex)
return self.nametowidget(name)
else:
self.tk.call(self._w, 'tab', 'tearoff', tabIndex, newName)
def view(self):
s = self.tk.call(self._w, 'view')
return tuple(map(self.tk.getint, self.tk.splitlist(s)))
def view_moveto(self, fraction):
self.tk.call(self._w, 'view', 'moveto', fraction)
def view_scroll(self, number, what):
self.tk.call(self._w, 'view', 'scroll', number, what)
#=============================================================================
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