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Jython is an implementation of the high-level, dynamic, object-oriented
language Python written in 100% Pure Java, and seamlessly integrated with
the Java platform. It thus allows you to run Python on any Java platform.
"""Drag-and-drop support for Tkinter.
This is very preliminary. I currently only support dnd *within* one
application, between different windows (or within the same window).
I an trying to make this as generic as possible -- not dependent on
the use of a particular widget or icon type, etc. I also hope that
this will work with Pmw.
To enable an object to be dragged, you must create an event binding
for it that starts the drag-and-drop process. Typically, you should
bind to a callback function that you write. The function
should call Tkdnd.dnd_start(source, event), where 'source' is the
object to be dragged, and 'event' is the event that invoked the call
(the argument to your callback function). Even though this is a class
instantiation, the returned instance should not be stored -- it will
be kept alive automatically for the duration of the drag-and-drop.
When a drag-and-drop is already in process for the Tk interpreter, the
call is *ignored*; this normally averts starting multiple simultaneous
dnd processes, e.g. because different button callbacks all
dnd_start().
The object is *not* necessarily a widget -- it can be any
application-specific object that is meaningful to potential
drag-and-drop targets.
Potential drag-and-drop targets are discovered as follows. Whenever
the mouse moves, and at the start and end of a drag-and-drop move, the
Tk widget directly under the mouse is inspected. This is the target
widget (not to be confused with the target object, yet to be
determined). If there is no target widget, there is no dnd target
object. If there is a target widget, and it has an attribute
dnd_accept, this should be a function (or any callable object). The
function is called as dnd_accept(source, event), where 'source' is the
object being dragged (the object passed to dnd_start() above), and
'event' is the most recent event object (generally a event;
it can also be or ). If the dnd_accept()
function returns something other than None, this is the new dnd target
object. If dnd_accept() returns None, or if the target widget has no
dnd_accept attribute, the target widget's parent is considered as the
target widget, and the search for a target object is repeated from
there. If necessary, the search is repeated all the way up to the
root widget. If none of the target widgets can produce a target
object, there is no target object (the target object is None).
The target object thus produced, if any, is called the new target
object. It is compared with the old target object (or None, if there
was no old target widget). There are several cases ('source' is the
source object, and 'event' is the most recent event object):
- Both the old and new target objects are None. Nothing happens.
- The old and new target objects are the same object. Its method
dnd_motion(source, event) is called.
- The old target object was None, and the new target object is not
None. The new target object's method dnd_enter(source, event) is
called.
- The new target object is None, and the old target object is not
None. The old target object's method dnd_leave(source, event) is
called.
- The old and new target objects differ and neither is None. The old
target object's method dnd_leave(source, event), and then the new
target object's method dnd_enter(source, event) is called.
Once this is done, the new target object replaces the old one, and the
Tk mainloop proceeds. The return value of the methods mentioned above
is ignored; if they raise an exception, the normal exception handling
mechanisms take over.
The drag-and-drop processes can end in two ways: a final target object
is selected, or no final target object is selected. When a final
target object is selected, it will always have been notified of the
potential drop by a call to its dnd_enter() method, as described
above, and possibly one or more calls to its dnd_motion() method; its
dnd_leave() method has not been called since the last call to
dnd_enter(). The target is notified of the drop by a call to its
method dnd_commit(source, event).
If no final target object is selected, and there was an old target
object, its dnd_leave(source, event) method is called to complete the
dnd sequence.
Finally, the source object is notified that the drag-and-drop process
is over, by a call to source.dnd_end(target, event), specifying either
the selected target object, or None if no target object was selected.
The source object can use this to implement the commit action; this is
sometimes simpler than to do it in the target's dnd_commit(). The
target's dnd_commit() method could then simply be aliased to
dnd_leave().
At any time during a dnd sequence, the application can cancel the
sequence by calling the cancel() method on the object returned by
dnd_start(). This will call dnd_leave() if a target is currently
active; it will never call dnd_commit().
"""
import Tkinter
# The factory function
def dnd_start(source, event):
h = DndHandler(source, event)
if h.root:
return h
else:
return None
# The class that does the work
class DndHandler:
root = None
def __init__(self, source, event):
if event.num > 5:
return
root = event.widget._root()
try:
root.__dnd
return # Don't start recursive dnd
except AttributeError:
root.__dnd = self
self.root = root
self.source = source
self.target = None
self.initial_button = button = event.num
self.initial_widget = widget = event.widget
self.release_pattern = "" % (button, button)
self.save_cursor = widget['cursor'] or ""
widget.bind(self.release_pattern, self.on_release)
widget.bind("", self.on_motion)
widget['cursor'] = "hand2"
def __del__(self):
root = self.root
self.root = None
if root:
try:
del root.__dnd
except AttributeError:
pass
def on_motion(self, event):
x, y = event.x_root, event.y_root
target_widget = self.initial_widget.winfo_containing(x, y)
source = self.source
new_target = None
while target_widget:
try:
attr = target_widget.dnd_accept
except AttributeError:
pass
else:
new_target = attr(source, event)
if new_target:
break
target_widget = target_widget.master
old_target = self.target
if old_target is new_target:
if old_target:
old_target.dnd_motion(source, event)
else:
if old_target:
self.target = None
old_target.dnd_leave(source, event)
if new_target:
new_target.dnd_enter(source, event)
self.target = new_target
def on_release(self, event):
self.finish(event, 1)
def cancel(self, event=None):
self.finish(event, 0)
def finish(self, event, commit=0):
target = self.target
source = self.source
widget = self.initial_widget
root = self.root
try:
del root.__dnd
self.initial_widget.unbind(self.release_pattern)
self.initial_widget.unbind("")
widget['cursor'] = self.save_cursor
self.target = self.source = self.initial_widget = self.root = None
if target:
if commit:
target.dnd_commit(source, event)
else:
target.dnd_leave(source, event)
finally:
source.dnd_end(target, event)
# ----------------------------------------------------------------------
# The rest is here for testing and demonstration purposes only!
class Icon:
def __init__(self, name):
self.name = name
self.canvas = self.label = self.id = None
def attach(self, canvas, x=10, y=10):
if canvas is self.canvas:
self.canvas.coords(self.id, x, y)
return
if self.canvas:
self.detach()
if not canvas:
return
label = Tkinter.Label(canvas, text=self.name,
borderwidth=2, relief="raised")
id = canvas.create_window(x, y, window=label, anchor="nw")
self.canvas = canvas
self.label = label
self.id = id
label.bind("", self.press)
def detach(self):
canvas = self.canvas
if not canvas:
return
id = self.id
label = self.label
self.canvas = self.label = self.id = None
canvas.delete(id)
label.destroy()
def press(self, event):
if dnd_start(self, event):
# where the pointer is relative to the label widget:
self.x_off = event.x
self.y_off = event.y
# where the widget is relative to the canvas:
self.x_orig, self.y_orig = self.canvas.coords(self.id)
def move(self, event):
x, y = self.where(self.canvas, event)
self.canvas.coords(self.id, x, y)
def putback(self):
self.canvas.coords(self.id, self.x_orig, self.y_orig)
def where(self, canvas, event):
# where the corner of the canvas is relative to the screen:
x_org = canvas.winfo_rootx()
y_org = canvas.winfo_rooty()
# where the pointer is relative to the canvas widget:
x = event.x_root - x_org
y = event.y_root - y_org
# compensate for initial pointer offset
return x - self.x_off, y - self.y_off
def dnd_end(self, target, event):
pass
class Tester:
def __init__(self, root):
self.top = Tkinter.Toplevel(root)
self.canvas = Tkinter.Canvas(self.top, width=100, height=100)
self.canvas.pack(fill="both", expand=1)
self.canvas.dnd_accept = self.dnd_accept
def dnd_accept(self, source, event):
return self
def dnd_enter(self, source, event):
self.canvas.focus_set() # Show highlight border
x, y = source.where(self.canvas, event)
x1, y1, x2, y2 = source.canvas.bbox(source.id)
dx, dy = x2-x1, y2-y1
self.dndid = self.canvas.create_rectangle(x, y, x+dx, y+dy)
self.dnd_motion(source, event)
def dnd_motion(self, source, event):
x, y = source.where(self.canvas, event)
x1, y1, x2, y2 = self.canvas.bbox(self.dndid)
self.canvas.move(self.dndid, x-x1, y-y1)
def dnd_leave(self, source, event):
self.top.focus_set() # Hide highlight border
self.canvas.delete(self.dndid)
self.dndid = None
def dnd_commit(self, source, event):
self.dnd_leave(source, event)
x, y = source.where(self.canvas, event)
source.attach(self.canvas, x, y)
def test():
root = Tkinter.Tk()
root.geometry("+1+1")
Tkinter.Button(command=root.quit, text="Quit").pack()
t1 = Tester(root)
t1.top.geometry("+1+60")
t2 = Tester(root)
t2.top.geometry("+120+60")
t3 = Tester(root)
t3.top.geometry("+240+60")
i1 = Icon("ICON1")
i2 = Icon("ICON2")
i3 = Icon("ICON3")
i1.attach(t1.canvas)
i2.attach(t2.canvas)
i3.attach(t3.canvas)
root.mainloop()
if __name__ == '__main__':
test()