Patch #3064: Port new turtle module and demos to 3.0.
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========================================================
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A new turtle module for Python
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========================================================
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Turtle graphics is a popular way for introducing programming to
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kids. It was part of the original Logo programming language developed
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by Wally Feurzig and Seymour Papert in 1966.
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Imagine a robotic turtle starting at (0, 0) in the x-y plane. Give it
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the command turtle.forward(15), and it moves (on-screen!) 15 pixels in
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the direction it is facing, drawing a line as it moves. Give it the
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command turtle.left(25), and it rotates in-place 25 degrees clockwise.
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By combining together these and similar commands, intricate shapes and
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pictures can easily be drawn.
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----- turtle.py
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This module is an extended reimplementation of turtle.py from the
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Python standard distribution up to Python 2.5. (See: http:\\www.python.org)
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It tries to keep the merits of turtle.py and to be (nearly) 100%
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compatible with it. This means in the first place to enable the
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learning programmer to use all the commands, classes and methods
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interactively when using the module from within IDLE run with
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the -n switch.
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Roughly it has the following features added:
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- Better animation of the turtle movements, especially of turning the
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turtle. So the turtles can more easily be used as a visual feedback
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instrument by the (beginning) programmer.
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- Different turtle shapes, gif-images as turtle shapes, user defined
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and user controllable turtle shapes, among them compound
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(multicolored) shapes. Turtle shapes can be stgretched and tilted, which
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makes turtles zu very versatile geometrical objects.
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- Fine control over turtle movement and screen updates via delay(),
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and enhanced tracer() and speed() methods.
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- Aliases for the most commonly used commands, like fd for forward etc.,
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following the early Logo traditions. This reduces the boring work of
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typing long sequences of commands, which often occur in a natural way
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when kids try to program fancy pictures on their first encounter with
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turtle graphcis.
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- Turtles now have an undo()-method with configurable undo-buffer.
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- Some simple commands/methods for creating event driven programs
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(mouse-, key-, timer-events). Especially useful for programming games.
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- A scrollable Canvas class. The default scrollable Canvas can be
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extended interactively as needed while playing around with the turtle(s).
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- A TurtleScreen class with methods controlling background color or
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background image, window and canvas size and other properties of the
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TurtleScreen.
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- There is a method, setworldcoordinates(), to install a user defined
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coordinate-system for the TurtleScreen.
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- The implementation uses a 2-vector class named Vec2D, derived from tuple.
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This class is public, so it can be imported by the application programmer,
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which makes certain types of computations very natural and compact.
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- Appearance of the TurtleScreen and the Turtles at startup/import can be
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configured by means of a turtle.cfg configuration file.
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The default configuration mimics the appearance of the old turtle module.
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- If configured appropriately the module reads in docstrings from a docstring
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dictionary in some different language, supplied separately and replaces
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the english ones by those read in. There is a utility function
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write_docstringdict() to write a dictionary with the original (english)
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docstrings to disc, so it can serve as a template for translations.
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--------------------------------------
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About turtleDemo.py
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--------------------------------------
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Tiny demo Viewer to view turtle graphics example scripts.
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Quickly and dirtyly assembled by Gregor Lingl.
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June, 2006
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For more information see: turtleDemo - Help
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Have fun!
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----------------------------------------------
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turtleDemo - Help
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----------------------------------------------
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This document has two sections:
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(1) How to use the demo viewer
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(2) How to add your own demos to the demo repository
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(1) How to use the demo viewer.
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Select a demoscript from the example menu.
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The (syntax coloured) source code appears in the left
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source code window. IT CANNOT BE EDITED, but ONLY VIEWED!
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- Press START button to start the demo.
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- Stop execution by pressing the STOP button.
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- Clear screen by pressing the CLEAR button.
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- Restart by pressing the START button again.
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SPECIAL demos are those which run EVENTDRIVEN.
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(For example clock.py - or oldTurtleDemo.py which
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in the end expects a mouse click.):
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Press START button to start the demo.
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- Until the EVENTLOOP is entered everything works
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as in an ordinary demo script.
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- When the EVENTLOOP is entered, you control the
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application by using the mouse and/or keys (or it's
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controlled by some timer events)
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To stop it you can and must press the STOP button.
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While the EVENTLOOP is running, the examples menu is disabled.
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- Only after having pressed the STOP button, you may
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restart it or choose another example script.
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* * * * * * * *
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In some rare situations there may occur interferences/conflicts
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between events concerning the demo script and those concerning the
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demo-viewer. (They run in the same process.) Strange behaviour may be
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the consequence and in the worst case you must close and restart the
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viewer.
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* * * * * * * *
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(2) How to add your own demos to the demo repository
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- scriptname: must begin with tdemo_ ,
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so it must have the form tdemo_<your-script-name>.py
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- place: same directory as turtleDemo.py or some
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subdirectory, the name of which must also begin with
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tdemo_.....
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- requirements on source code:
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code must contain a main() function which will
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be executed by the viewer (see provided example scripts)
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main() may return a string which will be displayed
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in the Label below the source code window (when execution
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has finished.)
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!! For programs, which are EVENT DRIVEN, main must return
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!! the string "EVENTLOOP". This informs the viewer, that the
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!! script is still running and must be stopped by the user!
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#!/usr/bin/python
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""" turtle-example-suite:
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tdemo-I_dont_like_tiltdemo.py
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Demostrates
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(a) use of a tilted ellipse as
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turtle shape
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(b) stamping that shape
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We can remove it, if you don't like it.
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Without using reset() ;-)
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---------------------------------------
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"""
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from tkinter.turtle import *
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import time
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def main():
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reset()
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shape("circle")
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resizemode("user")
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pu(); bk(24*18/6.283); rt(90); pd()
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tilt(45)
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pu()
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turtlesize(16,10,5)
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color("red", "violet")
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for i in range(18):
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fd(24)
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lt(20)
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stamp()
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color("red", "")
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for i in range(18):
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fd(24)
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lt(20)
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stamp()
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tilt(-15)
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turtlesize(3, 1, 4)
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color("blue", "yellow")
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for i in range(17):
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fd(24)
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lt(20)
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if i%2 == 0:
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stamp()
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time.sleep(1)
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while undobufferentries():
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undo()
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ht()
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write("OK, OVER!", align="center", font=("Courier", 18, "bold"))
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return "Done!"
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if __name__=="__main__":
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msg = main()
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print(msg)
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# mainloop()
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#!/usr/bin/python
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""" turtle-example-suite:
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tdemo_bytedesign.py
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An example adapted from the example-suite
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of PythonCard's turtle graphcis.
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It's based on an article in BYTE magazine
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Problem Solving with Logo: Using Turtle
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Graphics to Redraw a Design
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November 1982, p. 118 - 134
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-------------------------------------------
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Due to the statement
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t.delay(0)
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in line 152, which sets the animation delay
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to 0, this animation runs in "line per line"
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mode as fast as possible.
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"""
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import math
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from tkinter.turtle import Turtle, mainloop
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from time import clock
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# wrapper for any additional drawing routines
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# that need to know about each other
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class Designer(Turtle):
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def design(self, homePos, scale):
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self.up()
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for i in range(5):
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self.forward(64.65 * scale)
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self.down()
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self.wheel(self.position(), scale)
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self.up()
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self.backward(64.65 * scale)
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self.right(72)
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self.up()
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self.goto(homePos)
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self.right(36)
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self.forward(24.5 * scale)
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self.right(198)
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self.down()
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self.centerpiece(46 * scale, 143.4, scale)
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self.getscreen().tracer(True)
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def wheel(self, initpos, scale):
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self.right(54)
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for i in range(4):
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self.pentpiece(initpos, scale)
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self.down()
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self.left(36)
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for i in range(5):
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self.tripiece(initpos, scale)
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self.left(36)
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for i in range(5):
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self.down()
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self.right(72)
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self.forward(28 * scale)
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self.up()
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self.backward(28 * scale)
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self.left(54)
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self.getscreen().update()
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def tripiece(self, initpos, scale):
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oldh = self.heading()
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self.down()
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self.backward(2.5 * scale)
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self.tripolyr(31.5 * scale, scale)
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self.up()
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self.goto(initpos)
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self.setheading(oldh)
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self.down()
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self.backward(2.5 * scale)
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self.tripolyl(31.5 * scale, scale)
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self.up()
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self.goto(initpos)
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self.setheading(oldh)
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self.left(72)
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self.getscreen().update()
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def pentpiece(self, initpos, scale):
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oldh = self.heading()
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self.up()
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self.forward(29 * scale)
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self.down()
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for i in range(5):
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self.forward(18 * scale)
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self.right(72)
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self.pentr(18 * scale, 75, scale)
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self.up()
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self.goto(initpos)
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self.setheading(oldh)
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self.forward(29 * scale)
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self.down()
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for i in range(5):
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self.forward(18 * scale)
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self.right(72)
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self.pentl(18 * scale, 75, scale)
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self.up()
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self.goto(initpos)
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self.setheading(oldh)
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self.left(72)
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self.getscreen().update()
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def pentl(self, side, ang, scale):
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if side < (2 * scale): return
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self.forward(side)
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self.left(ang)
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self.pentl(side - (.38 * scale), ang, scale)
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def pentr(self, side, ang, scale):
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if side < (2 * scale): return
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self.forward(side)
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self.right(ang)
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self.pentr(side - (.38 * scale), ang, scale)
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def tripolyr(self, side, scale):
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if side < (4 * scale): return
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self.forward(side)
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self.right(111)
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self.forward(side / 1.78)
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self.right(111)
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self.forward(side / 1.3)
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self.right(146)
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self.tripolyr(side * .75, scale)
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def tripolyl(self, side, scale):
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if side < (4 * scale): return
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self.forward(side)
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self.left(111)
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self.forward(side / 1.78)
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self.left(111)
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self.forward(side / 1.3)
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self.left(146)
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self.tripolyl(side * .75, scale)
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def centerpiece(self, s, a, scale):
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self.forward(s); self.left(a)
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if s < (7.5 * scale):
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return
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self.centerpiece(s - (1.2 * scale), a, scale)
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def main():
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t = Designer()
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t.speed(0)
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t.hideturtle()
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t.getscreen().delay(0)
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t.getscreen().tracer(0)
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at = clock()
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t.design(t.position(), 2)
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et = clock()
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return "runtime: %.2f sec." % (et-at)
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if __name__ == '__main__':
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msg = main()
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print(msg)
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mainloop()
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# Datei: chaosplotter.py
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# Autor: Gregor Lingl
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# Datum: 31. 5. 2008
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# Ein einfaches Programm zur Demonstration von "chaotischem Verhalten".
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from tkinter.turtle import *
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def f(x):
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return 3.9*x*(1-x)
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def g(x):
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return 3.9*(x-x**2)
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def h(x):
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return 3.9*x-3.9*x*x
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def coosys():
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penup()
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goto(-1,0)
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pendown()
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goto(n+1,0)
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penup()
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goto(0, -0.1)
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pendown()
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goto(-0.1, 1.1)
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def plot(fun, start, farbe):
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x = start
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pencolor(farbe)
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penup()
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goto(0, x)
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pendown()
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dot(5)
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for i in range(n):
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x=fun(x)
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goto(i+1,x)
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dot(5)
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def main():
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global n
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n = 80
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ox=-250.0
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oy=-150.0
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ex= -2.0*ox / n
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ey=300.0
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reset()
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setworldcoordinates(-1.0,-0.1, n+1, 1.1)
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speed(0)
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hideturtle()
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coosys()
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plot(f, 0.35, "blue")
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plot(g, 0.35, "green")
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plot(h, 0.35, "red")
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for s in range(100):
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setworldcoordinates(0.5*s,-0.1, n+1, 1.1)
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return "Done!"
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if __name__ == "__main__":
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main()
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mainloop()
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#!/usr/bin/python
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# -*- coding: cp1252 -*-
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""" turtle-example-suite:
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tdemo_clock.py
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Enhanced clock-program, showing date
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and time
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------------------------------------
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Press STOP to exit the program!
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------------------------------------
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"""
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from tkinter.turtle import *
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from datetime import datetime
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mode("logo")
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def jump(distanz, winkel=0):
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penup()
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right(winkel)
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forward(distanz)
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left(winkel)
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pendown()
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def hand(laenge, spitze):
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fd(laenge*1.15)
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rt(90)
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fd(spitze/2.0)
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lt(120)
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fd(spitze)
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lt(120)
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fd(spitze)
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lt(120)
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fd(spitze/2.0)
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def make_hand_shape(name, laenge, spitze):
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reset()
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jump(-laenge*0.15)
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begin_poly()
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hand(laenge, spitze)
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end_poly()
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hand_form = get_poly()
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register_shape(name, hand_form)
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def clockface(radius):
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reset()
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pensize(7)
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for i in range(60):
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jump(radius)
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if i % 5 == 0:
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fd(25)
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jump(-radius-25)
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else:
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dot(3)
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jump(-radius)
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rt(6)
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def setup():
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global second_hand, minute_hand, hour_hand, writer
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mode("logo")
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make_hand_shape("second_hand", 125, 25)
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make_hand_shape("minute_hand", 130, 25)
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make_hand_shape("hour_hand", 90, 25)
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clockface(160)
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second_hand = Turtle()
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second_hand.shape("second_hand")
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second_hand.color("gray20", "gray80")
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minute_hand = Turtle()
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minute_hand.shape("minute_hand")
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minute_hand.color("blue1", "red1")
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hour_hand = Turtle()
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hour_hand.shape("hour_hand")
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hour_hand.color("blue3", "red3")
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for hand in second_hand, minute_hand, hour_hand:
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hand.resizemode("user")
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hand.shapesize(1, 1, 3)
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hand.speed(0)
|
||||
ht()
|
||||
writer = Turtle()
|
||||
#writer.mode("logo")
|
||||
writer.ht()
|
||||
writer.pu()
|
||||
writer.bk(85)
|
||||
|
||||
|
||||
def wochentag(t):
|
||||
wochentag = ["Monday", "Tuesday", "Wednesday",
|
||||
"Thursday", "Friday", "Saturday", "Sunday"]
|
||||
return wochentag[t.weekday()]
|
||||
|
||||
def datum(z):
|
||||
monat = ["Jan.", "Feb.", "Mar.", "Apr.", "May", "June",
|
||||
"July", "Aug.", "Sep.", "Oct.", "Nov.", "Dec."]
|
||||
j = z.year
|
||||
m = monat[z.month - 1]
|
||||
t = z.day
|
||||
return "%s %d %d" % (m, t, j)
|
||||
|
||||
def tick():
|
||||
t = datetime.today()
|
||||
sekunde = t.second + t.microsecond*0.000001
|
||||
minute = t.minute + sekunde/60.0
|
||||
stunde = t.hour + minute/60.0
|
||||
tracer(False)
|
||||
writer.clear()
|
||||
writer.home()
|
||||
writer.forward(65)
|
||||
writer.write(wochentag(t),
|
||||
align="center", font=("Courier", 14, "bold"))
|
||||
writer.back(150)
|
||||
writer.write(datum(t),
|
||||
align="center", font=("Courier", 14, "bold"))
|
||||
writer.forward(85)
|
||||
tracer(True)
|
||||
second_hand.setheading(6*sekunde)
|
||||
minute_hand.setheading(6*minute)
|
||||
hour_hand.setheading(30*stunde)
|
||||
tracer(True)
|
||||
ontimer(tick, 100)
|
||||
|
||||
def main():
|
||||
tracer(False)
|
||||
setup()
|
||||
tracer(True)
|
||||
tick()
|
||||
return "EVENTLOOP"
|
||||
|
||||
if __name__ == "__main__":
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,60 @@
|
|||
# colormixer
|
||||
|
||||
from tkinter.turtle import Screen, Turtle, mainloop
|
||||
import sys
|
||||
sys.setrecursionlimit(20000) # overcomes, for now, an instability of Python 3.0
|
||||
|
||||
class ColorTurtle(Turtle):
|
||||
|
||||
def __init__(self, x, y):
|
||||
Turtle.__init__(self)
|
||||
self.shape("turtle")
|
||||
self.resizemode("user")
|
||||
self.shapesize(3,3,5)
|
||||
self.pensize(10)
|
||||
self._color = [0,0,0]
|
||||
self.x = x
|
||||
self._color[x] = y
|
||||
self.color(self._color)
|
||||
self.speed(0)
|
||||
self.left(90)
|
||||
self.pu()
|
||||
self.goto(x,0)
|
||||
self.pd()
|
||||
self.sety(1)
|
||||
self.pu()
|
||||
self.sety(y)
|
||||
self.pencolor("gray25")
|
||||
self.ondrag(self.shift)
|
||||
|
||||
def shift(self, x, y):
|
||||
self.sety(max(0,min(y,1)))
|
||||
self._color[self.x] = self.ycor()
|
||||
self.fillcolor(self._color)
|
||||
setbgcolor()
|
||||
|
||||
def setbgcolor():
|
||||
screen.bgcolor(red.ycor(), green.ycor(), blue.ycor())
|
||||
|
||||
def main():
|
||||
global screen, red, green, blue
|
||||
screen = Screen()
|
||||
screen.delay(0)
|
||||
screen.setworldcoordinates(-1, -0.3, 3, 1.3)
|
||||
|
||||
red = ColorTurtle(0, .5)
|
||||
green = ColorTurtle(1, .5)
|
||||
blue = ColorTurtle(2, .5)
|
||||
setbgcolor()
|
||||
|
||||
writer = Turtle()
|
||||
writer.ht()
|
||||
writer.pu()
|
||||
writer.goto(1,1.15)
|
||||
writer.write("DRAG!",align="center",font=("Arial",30,("bold","italic")))
|
||||
return "EVENTLOOP"
|
||||
|
||||
if __name__ == "__main__":
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,109 @@
|
|||
#!/usr/bin/python
|
||||
""" turtlegraphics-example-suite:
|
||||
|
||||
tdemo_forest.py
|
||||
|
||||
Displays a 'forest' of 3 'breadth-first-trees'
|
||||
similar to the one from example tree.
|
||||
For further remarks see xtx_tree.py
|
||||
|
||||
This example is a 'breadth-first'-rewrite of
|
||||
a Logo program written by Erich Neuwirth. See:
|
||||
http://homepage.univie.ac.at/erich.neuwirth/
|
||||
"""
|
||||
from tkinter.turtle import Turtle, colormode, tracer, mainloop
|
||||
from random import randrange
|
||||
from time import clock
|
||||
|
||||
def symRandom(n):
|
||||
return randrange(-n,n+1)
|
||||
|
||||
def randomize( branchlist, angledist, sizedist ):
|
||||
return [ (angle+symRandom(angledist),
|
||||
sizefactor*1.01**symRandom(sizedist))
|
||||
for angle, sizefactor in branchlist ]
|
||||
|
||||
def randomfd( t, distance, parts, angledist ):
|
||||
for i in range(parts):
|
||||
t.left(symRandom(angledist))
|
||||
t.forward( (1.0 * distance)/parts )
|
||||
|
||||
def tree(tlist, size, level, widthfactor, branchlists, angledist=10, sizedist=5):
|
||||
# benutzt Liste von turtles und Liste von Zweiglisten,
|
||||
# fuer jede turtle eine!
|
||||
if level > 0:
|
||||
lst = []
|
||||
brs = []
|
||||
for t, branchlist in list(zip(tlist,branchlists)):
|
||||
t.pensize( size * widthfactor )
|
||||
t.pencolor( 255 - (180 - 11 * level + symRandom(15)),
|
||||
180 - 11 * level + symRandom(15),
|
||||
0 )
|
||||
t.pendown()
|
||||
randomfd(t, size, level, angledist )
|
||||
yield 1
|
||||
for angle, sizefactor in branchlist:
|
||||
t.left(angle)
|
||||
lst.append(t.clone())
|
||||
brs.append(randomize(branchlist, angledist, sizedist))
|
||||
t.right(angle)
|
||||
for x in tree(lst, size*sizefactor, level-1, widthfactor, brs,
|
||||
angledist, sizedist):
|
||||
yield None
|
||||
|
||||
|
||||
def start(t,x,y):
|
||||
colormode(255)
|
||||
t.reset()
|
||||
t.speed(0)
|
||||
t.hideturtle()
|
||||
t.left(90)
|
||||
t.penup()
|
||||
t.setpos(x,y)
|
||||
t.pendown()
|
||||
|
||||
def doit1(level, pen):
|
||||
pen.hideturtle()
|
||||
start(pen, 20, -208)
|
||||
t = tree( [pen], 80, level, 0.1, [[ (45,0.69), (0,0.65), (-45,0.71) ]] )
|
||||
return t
|
||||
|
||||
def doit2(level, pen):
|
||||
pen.hideturtle()
|
||||
start(pen, -135, -130)
|
||||
t = tree( [pen], 120, level, 0.1, [[ (45,0.69), (-45,0.71) ]] )
|
||||
return t
|
||||
|
||||
def doit3(level, pen):
|
||||
pen.hideturtle()
|
||||
start(pen, 190, -90)
|
||||
t = tree( [pen], 100, level, 0.1, [[ (45,0.7), (0,0.72), (-45,0.65) ]] )
|
||||
return t
|
||||
|
||||
# Hier 3 Baumgeneratoren:
|
||||
def main():
|
||||
p = Turtle()
|
||||
p.ht()
|
||||
tracer(75,0)
|
||||
u = doit1(6, Turtle(undobuffersize=1))
|
||||
s = doit2(7, Turtle(undobuffersize=1))
|
||||
t = doit3(5, Turtle(undobuffersize=1))
|
||||
a = clock()
|
||||
while True:
|
||||
done = 0
|
||||
for b in u,s,t:
|
||||
try:
|
||||
b.__next__()
|
||||
except:
|
||||
done += 1
|
||||
if done == 3:
|
||||
break
|
||||
|
||||
tracer(1,10)
|
||||
b = clock()
|
||||
return "runtime: %.2f sec." % (b-a)
|
||||
|
||||
if __name__ == '__main__':
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,138 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
tdemo_fractalCurves.py
|
||||
|
||||
This program draws two fractal-curve-designs:
|
||||
(1) A hilbert curve (in a box)
|
||||
(2) A combination of Koch-curves.
|
||||
|
||||
The CurvesTurtle class and the fractal-curve-
|
||||
methods are taken from the PythonCard example
|
||||
scripts for turtle-graphics.
|
||||
"""
|
||||
from tkinter.turtle import *
|
||||
from time import sleep, clock
|
||||
|
||||
class CurvesTurtle(Pen):
|
||||
# example derived from
|
||||
# Turtle Geometry: The Computer as a Medium for Exploring Mathematics
|
||||
# by Harold Abelson and Andrea diSessa
|
||||
# p. 96-98
|
||||
def hilbert(self, size, level, parity):
|
||||
if level == 0:
|
||||
return
|
||||
# rotate and draw first subcurve with opposite parity to big curve
|
||||
self.left(parity * 90)
|
||||
self.hilbert(size, level - 1, -parity)
|
||||
# interface to and draw second subcurve with same parity as big curve
|
||||
self.forward(size)
|
||||
self.right(parity * 90)
|
||||
self.hilbert(size, level - 1, parity)
|
||||
# third subcurve
|
||||
self.forward(size)
|
||||
self.hilbert(size, level - 1, parity)
|
||||
# fourth subcurve
|
||||
self.right(parity * 90)
|
||||
self.forward(size)
|
||||
self.hilbert(size, level - 1, -parity)
|
||||
# a final turn is needed to make the turtle
|
||||
# end up facing outward from the large square
|
||||
self.left(parity * 90)
|
||||
|
||||
# Visual Modeling with Logo: A Structural Approach to Seeing
|
||||
# by James Clayson
|
||||
# Koch curve, after Helge von Koch who introduced this geometric figure in 1904
|
||||
# p. 146
|
||||
def fractalgon(self, n, rad, lev, dir):
|
||||
import math
|
||||
|
||||
# if dir = 1 turn outward
|
||||
# if dir = -1 turn inward
|
||||
edge = 2 * rad * math.sin(math.pi / n)
|
||||
self.pu()
|
||||
self.fd(rad)
|
||||
self.pd()
|
||||
self.rt(180 - (90 * (n - 2) / n))
|
||||
for i in range(n):
|
||||
self.fractal(edge, lev, dir)
|
||||
self.rt(360 / n)
|
||||
self.lt(180 - (90 * (n - 2) / n))
|
||||
self.pu()
|
||||
self.bk(rad)
|
||||
self.pd()
|
||||
|
||||
# p. 146
|
||||
def fractal(self, dist, depth, dir):
|
||||
if depth < 1:
|
||||
self.fd(dist)
|
||||
return
|
||||
self.fractal(dist / 3, depth - 1, dir)
|
||||
self.lt(60 * dir)
|
||||
self.fractal(dist / 3, depth - 1, dir)
|
||||
self.rt(120 * dir)
|
||||
self.fractal(dist / 3, depth - 1, dir)
|
||||
self.lt(60 * dir)
|
||||
self.fractal(dist / 3, depth - 1, dir)
|
||||
|
||||
def main():
|
||||
ft = CurvesTurtle()
|
||||
|
||||
ft.reset()
|
||||
ft.speed(0)
|
||||
ft.ht()
|
||||
ft.getscreen().tracer(1,0)
|
||||
ft.pu()
|
||||
|
||||
size = 6
|
||||
ft.setpos(-33*size, -32*size)
|
||||
ft.pd()
|
||||
|
||||
ta=clock()
|
||||
ft.fillcolor("red")
|
||||
ft.begin_fill()
|
||||
ft.fd(size)
|
||||
|
||||
ft.hilbert(size, 6, 1)
|
||||
|
||||
# frame
|
||||
ft.fd(size)
|
||||
for i in range(3):
|
||||
ft.lt(90)
|
||||
ft.fd(size*(64+i%2))
|
||||
ft.pu()
|
||||
for i in range(2):
|
||||
ft.fd(size)
|
||||
ft.rt(90)
|
||||
ft.pd()
|
||||
for i in range(4):
|
||||
ft.fd(size*(66+i%2))
|
||||
ft.rt(90)
|
||||
ft.end_fill()
|
||||
tb=clock()
|
||||
res = "Hilbert: %.2fsec. " % (tb-ta)
|
||||
|
||||
sleep(3)
|
||||
|
||||
ft.reset()
|
||||
ft.speed(0)
|
||||
ft.ht()
|
||||
ft.getscreen().tracer(1,0)
|
||||
|
||||
ta=clock()
|
||||
ft.color("black", "blue")
|
||||
ft.begin_fill()
|
||||
ft.fractalgon(3, 250, 4, 1)
|
||||
ft.end_fill()
|
||||
ft.begin_fill()
|
||||
ft.color("red")
|
||||
ft.fractalgon(3, 200, 4, -1)
|
||||
ft.end_fill()
|
||||
tb=clock()
|
||||
res += "Koch: %.2fsec." % (tb-ta)
|
||||
return res
|
||||
|
||||
if __name__ == '__main__':
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,119 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
xtx_lindenmayer_indian.py
|
||||
|
||||
Each morning women in Tamil Nadu, in southern
|
||||
India, place designs, created by using rice
|
||||
flour and known as kolam on the thresholds of
|
||||
their homes.
|
||||
|
||||
These can be described by Lindenmayer systems,
|
||||
which can easily be implemented with turtle
|
||||
graphics and Python.
|
||||
|
||||
Two examples are shown here:
|
||||
(1) the snake kolam
|
||||
(2) anklets of Krishna
|
||||
|
||||
Taken from Marcia Ascher: Mathematics
|
||||
Elsewhere, An Exploration of Ideas Across
|
||||
Cultures
|
||||
|
||||
"""
|
||||
################################
|
||||
# Mini Lindenmayer tool
|
||||
###############################
|
||||
|
||||
from tkinter.turtle import *
|
||||
|
||||
def replace( seq, replacementRules, n ):
|
||||
for i in range(n):
|
||||
newseq = ""
|
||||
for element in seq:
|
||||
newseq = newseq + replacementRules.get(element,element)
|
||||
seq = newseq
|
||||
return seq
|
||||
|
||||
def draw( commands, rules ):
|
||||
for b in commands:
|
||||
try:
|
||||
rules[b]()
|
||||
except TypeError:
|
||||
try:
|
||||
draw(rules[b], rules)
|
||||
except:
|
||||
pass
|
||||
|
||||
|
||||
def main():
|
||||
################################
|
||||
# Example 1: Snake kolam
|
||||
################################
|
||||
|
||||
|
||||
def r():
|
||||
right(45)
|
||||
|
||||
def l():
|
||||
left(45)
|
||||
|
||||
def f():
|
||||
forward(7.5)
|
||||
|
||||
snake_rules = {"-":r, "+":l, "f":f, "b":"f+f+f--f--f+f+f"}
|
||||
snake_replacementRules = {"b": "b+f+b--f--b+f+b"}
|
||||
snake_start = "b--f--b--f"
|
||||
|
||||
drawing = replace(snake_start, snake_replacementRules, 3)
|
||||
|
||||
reset()
|
||||
speed(3)
|
||||
tracer(1,0)
|
||||
ht()
|
||||
up()
|
||||
backward(195)
|
||||
down()
|
||||
draw(drawing, snake_rules)
|
||||
|
||||
from time import sleep
|
||||
sleep(3)
|
||||
|
||||
################################
|
||||
# Example 2: Anklets of Krishna
|
||||
################################
|
||||
|
||||
def A():
|
||||
color("red")
|
||||
circle(10,90)
|
||||
|
||||
def B():
|
||||
from math import sqrt
|
||||
color("black")
|
||||
l = 5/sqrt(2)
|
||||
forward(l)
|
||||
circle(l, 270)
|
||||
forward(l)
|
||||
|
||||
def F():
|
||||
color("green")
|
||||
forward(10)
|
||||
|
||||
krishna_rules = {"a":A, "b":B, "f":F}
|
||||
krishna_replacementRules = {"a" : "afbfa", "b" : "afbfbfbfa" }
|
||||
krishna_start = "fbfbfbfb"
|
||||
|
||||
reset()
|
||||
speed(0)
|
||||
tracer(3,0)
|
||||
ht()
|
||||
left(45)
|
||||
drawing = replace(krishna_start, krishna_replacementRules, 3)
|
||||
draw(drawing, krishna_rules)
|
||||
tracer(1)
|
||||
return "Done!"
|
||||
|
||||
if __name__=='__main__':
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,76 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
tdemo_minimal_hanoi.py
|
||||
|
||||
A minimal 'Towers of Hanoi' animation:
|
||||
A tower of 6 discs is transferred from the
|
||||
left to the right peg.
|
||||
|
||||
An imho quite elegant and concise
|
||||
implementation using a tower class, which
|
||||
is derived from the built-in type list.
|
||||
|
||||
Discs are turtles with shape "square", but
|
||||
stretched to rectangles by shapesize()
|
||||
---------------------------------------
|
||||
To exit press STOP button
|
||||
---------------------------------------
|
||||
"""
|
||||
from tkinter.turtle import *
|
||||
|
||||
class Disc(Turtle):
|
||||
def __init__(self, n):
|
||||
Turtle.__init__(self, shape="square", visible=False)
|
||||
self.pu()
|
||||
self.shapesize(1.5, n*1.5, 2) # square-->rectangle
|
||||
self.fillcolor(n/6., 0, 1-n/6.)
|
||||
self.st()
|
||||
|
||||
class Tower(list):
|
||||
"Hanoi tower, a subclass of built-in type list"
|
||||
def __init__(self, x):
|
||||
"create an empty tower. x is x-position of peg"
|
||||
self.x = x
|
||||
def push(self, d):
|
||||
d.setx(self.x)
|
||||
d.sety(-150+34*len(self))
|
||||
self.append(d)
|
||||
def pop(self):
|
||||
d = list.pop(self)
|
||||
d.sety(150)
|
||||
return d
|
||||
|
||||
def hanoi(n, from_, with_, to_):
|
||||
if n > 0:
|
||||
hanoi(n-1, from_, to_, with_)
|
||||
to_.push(from_.pop())
|
||||
hanoi(n-1, with_, from_, to_)
|
||||
|
||||
def play():
|
||||
onkey(None,"space")
|
||||
clear()
|
||||
hanoi(6, t1, t2, t3)
|
||||
write("press STOP button to exit",
|
||||
align="center", font=("Courier", 16, "bold"))
|
||||
|
||||
def main():
|
||||
global t1, t2, t3
|
||||
ht(); penup(); goto(0, -225) # writer turtle
|
||||
t1 = Tower(-250)
|
||||
t2 = Tower(0)
|
||||
t3 = Tower(250)
|
||||
# make tower of 6 discs
|
||||
for i in range(6,0,-1):
|
||||
t1.push(Disc(i))
|
||||
# prepare spartanic user interface ;-)
|
||||
write("press spacebar to start game",
|
||||
align="center", font=("Courier", 16, "bold"))
|
||||
onkey(play, "space")
|
||||
listen()
|
||||
return "EVENTLOOP"
|
||||
|
||||
if __name__=="__main__":
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,50 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
tdemo_paint.py
|
||||
|
||||
A simple eventdriven paint program
|
||||
|
||||
- use left mouse button to move turtle
|
||||
- middle mouse button to change color
|
||||
- right mouse button do turn filling on/off
|
||||
-------------------------------------------
|
||||
Play around by clicking into the canvas
|
||||
using all three mouse buttons.
|
||||
-------------------------------------------
|
||||
To exit press STOP button
|
||||
-------------------------------------------
|
||||
"""
|
||||
from tkinter.turtle import *
|
||||
|
||||
def switchupdown(x=0, y=0):
|
||||
if pen()["pendown"]:
|
||||
end_fill()
|
||||
up()
|
||||
else:
|
||||
down()
|
||||
begin_fill()
|
||||
|
||||
def changecolor(x=0, y=0):
|
||||
global colors
|
||||
colors = colors[1:]+colors[:1]
|
||||
color(colors[0])
|
||||
|
||||
def main():
|
||||
global colors
|
||||
shape("circle")
|
||||
resizemode("user")
|
||||
shapesize(.5)
|
||||
width(3)
|
||||
colors=["red", "green", "blue", "yellow"]
|
||||
color(colors[0])
|
||||
switchupdown()
|
||||
onscreenclick(goto,1)
|
||||
onscreenclick(changecolor,2)
|
||||
onscreenclick(switchupdown,3)
|
||||
return "EVENTLOOP"
|
||||
|
||||
if __name__ == "__main__":
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,65 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
tdemo_peace.py
|
||||
|
||||
A very simple drawing suitable as a beginner's
|
||||
programming example.
|
||||
|
||||
Uses only commands, which are also available in
|
||||
old turtle.py.
|
||||
|
||||
Intentionally no variables are used except for the
|
||||
colorloop:
|
||||
"""
|
||||
|
||||
from tkinter.turtle import *
|
||||
|
||||
def main():
|
||||
peacecolors = ("red3", "orange", "yellow",
|
||||
"seagreen4", "orchid4",
|
||||
"royalblue1", "dodgerblue4")
|
||||
|
||||
reset()
|
||||
s = Screen()
|
||||
up()
|
||||
goto(-320,-195)
|
||||
width(70)
|
||||
|
||||
for pcolor in peacecolors:
|
||||
color(pcolor)
|
||||
down()
|
||||
forward(640)
|
||||
up()
|
||||
backward(640)
|
||||
left(90)
|
||||
forward(66)
|
||||
right(90)
|
||||
|
||||
width(25)
|
||||
color("white")
|
||||
goto(0,-170)
|
||||
down()
|
||||
|
||||
circle(170)
|
||||
left(90)
|
||||
forward(340)
|
||||
up()
|
||||
left(180)
|
||||
forward(170)
|
||||
right(45)
|
||||
down()
|
||||
forward(170)
|
||||
up()
|
||||
backward(170)
|
||||
left(90)
|
||||
down()
|
||||
forward(170)
|
||||
up()
|
||||
|
||||
goto(0,300) # vanish if hideturtle() is not available ;-)
|
||||
return "Done!!"
|
||||
|
||||
if __name__ == "__main__":
|
||||
main()
|
||||
mainloop()
|
|
@ -0,0 +1,181 @@
|
|||
#!/usr/bin/python
|
||||
""" xturtle-example-suite:
|
||||
|
||||
xtx_kites_and_darts.py
|
||||
|
||||
Constructs two aperiodic penrose-tilings,
|
||||
consisting of kites and darts, by the method
|
||||
of inflation in six steps.
|
||||
|
||||
Starting points are the patterns "sun"
|
||||
consisting of five kites and "star"
|
||||
consisting of five darts.
|
||||
|
||||
For more information see:
|
||||
http://en.wikipedia.org/wiki/Penrose_tiling
|
||||
-------------------------------------------
|
||||
"""
|
||||
from tkinter.turtle import *
|
||||
from math import cos, pi
|
||||
from time import clock, sleep
|
||||
|
||||
f = (5**0.5-1)/2.0 # (sqrt(5)-1)/2 -- golden ratio
|
||||
d = 2 * cos(3*pi/10)
|
||||
|
||||
def kite(l):
|
||||
fl = f * l
|
||||
lt(36)
|
||||
fd(l)
|
||||
rt(108)
|
||||
fd(fl)
|
||||
rt(36)
|
||||
fd(fl)
|
||||
rt(108)
|
||||
fd(l)
|
||||
rt(144)
|
||||
|
||||
def dart(l):
|
||||
fl = f * l
|
||||
lt(36)
|
||||
fd(l)
|
||||
rt(144)
|
||||
fd(fl)
|
||||
lt(36)
|
||||
fd(fl)
|
||||
rt(144)
|
||||
fd(l)
|
||||
rt(144)
|
||||
|
||||
def inflatekite(l, n):
|
||||
if n == 0:
|
||||
px, py = pos()
|
||||
h, x, y = int(heading()), round(px,3), round(py,3)
|
||||
tiledict[(h,x,y)] = True
|
||||
return
|
||||
fl = f * l
|
||||
lt(36)
|
||||
inflatedart(fl, n-1)
|
||||
fd(l)
|
||||
rt(144)
|
||||
inflatekite(fl, n-1)
|
||||
lt(18)
|
||||
fd(l*d)
|
||||
rt(162)
|
||||
inflatekite(fl, n-1)
|
||||
lt(36)
|
||||
fd(l)
|
||||
rt(180)
|
||||
inflatedart(fl, n-1)
|
||||
lt(36)
|
||||
|
||||
def inflatedart(l, n):
|
||||
if n == 0:
|
||||
px, py = pos()
|
||||
h, x, y = int(heading()), round(px,3), round(py,3)
|
||||
tiledict[(h,x,y)] = False
|
||||
return
|
||||
fl = f * l
|
||||
inflatekite(fl, n-1)
|
||||
lt(36)
|
||||
fd(l)
|
||||
rt(180)
|
||||
inflatedart(fl, n-1)
|
||||
lt(54)
|
||||
fd(l*d)
|
||||
rt(126)
|
||||
inflatedart(fl, n-1)
|
||||
fd(l)
|
||||
rt(144)
|
||||
|
||||
def draw(l, n, th=2):
|
||||
clear()
|
||||
l = l * f**n
|
||||
shapesize(l/100.0, l/100.0, th)
|
||||
for k in tiledict:
|
||||
h, x, y = k
|
||||
setpos(x, y)
|
||||
setheading(h)
|
||||
if tiledict[k]:
|
||||
shape("kite")
|
||||
color("black", (0, 0.75, 0))
|
||||
else:
|
||||
shape("dart")
|
||||
color("black", (0.75, 0, 0))
|
||||
stamp()
|
||||
|
||||
def sun(l, n):
|
||||
for i in range(5):
|
||||
inflatekite(l, n)
|
||||
lt(72)
|
||||
|
||||
def star(l,n):
|
||||
for i in range(5):
|
||||
inflatedart(l, n)
|
||||
lt(72)
|
||||
|
||||
def makeshapes():
|
||||
tracer(0)
|
||||
begin_poly()
|
||||
kite(100)
|
||||
end_poly()
|
||||
register_shape("kite", get_poly())
|
||||
begin_poly()
|
||||
dart(100)
|
||||
end_poly()
|
||||
register_shape("dart", get_poly())
|
||||
tracer(1)
|
||||
|
||||
def start():
|
||||
reset()
|
||||
ht()
|
||||
pu()
|
||||
makeshapes()
|
||||
resizemode("user")
|
||||
|
||||
def test(l=200, n=4, fun=sun, startpos=(0,0), th=2):
|
||||
global tiledict
|
||||
goto(startpos)
|
||||
setheading(0)
|
||||
tiledict = {}
|
||||
a = clock()
|
||||
tracer(0)
|
||||
fun(l, n)
|
||||
b = clock()
|
||||
draw(l, n, th)
|
||||
tracer(1)
|
||||
c = clock()
|
||||
print("Calculation: %7.4f s" % (b - a))
|
||||
print("Drawing: %7.4f s" % (c - b))
|
||||
print("Together: %7.4f s" % (c - a))
|
||||
nk = len([x for x in tiledict if tiledict[x]])
|
||||
nd = len([x for x in tiledict if not tiledict[x]])
|
||||
print("%d kites and %d darts = %d pieces." % (nk, nd, nk+nd))
|
||||
|
||||
def demo(fun=sun):
|
||||
start()
|
||||
for i in range(8):
|
||||
a = clock()
|
||||
test(300, i, fun)
|
||||
b = clock()
|
||||
t = b - a
|
||||
if t < 2:
|
||||
sleep(2 - t)
|
||||
|
||||
def main():
|
||||
#title("Penrose-tiling with kites and darts.")
|
||||
mode("logo")
|
||||
bgcolor(0.3, 0.3, 0)
|
||||
demo(sun)
|
||||
sleep(2)
|
||||
demo(star)
|
||||
pencolor("black")
|
||||
goto(0,-200)
|
||||
pencolor(0.7,0.7,1)
|
||||
write("Please wait...",
|
||||
align="center", font=('Arial Black', 36, 'bold'))
|
||||
test(600, 8, startpos=(70, 117))
|
||||
return "Done"
|
||||
|
||||
if __name__ == "__main__":
|
||||
msg = main()
|
||||
mainloop()
|
|
@ -0,0 +1,113 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
tdemo_planets_and_moon.py
|
||||
|
||||
Gravitational system simulation using the
|
||||
approximation method from Feynman-lectures,
|
||||
p.9-8, using turtlegraphics.
|
||||
|
||||
Example: heavy central body, light planet,
|
||||
very light moon!
|
||||
Planet has a circular orbit, moon a stable
|
||||
orbit around the planet.
|
||||
|
||||
You can hold the movement temporarily by pressing
|
||||
the left mouse button with mouse over the
|
||||
scrollbar of the canvas.
|
||||
|
||||
"""
|
||||
from tkinter.turtle import Shape, Turtle, mainloop, Vec2D as Vec
|
||||
from time import sleep
|
||||
|
||||
G = 8
|
||||
|
||||
class GravSys(object):
|
||||
def __init__(self):
|
||||
self.planets = []
|
||||
self.t = 0
|
||||
self.dt = 0.01
|
||||
def init(self):
|
||||
for p in self.planets:
|
||||
p.init()
|
||||
def start(self):
|
||||
for i in range(10000):
|
||||
self.t += self.dt
|
||||
for p in self.planets:
|
||||
p.step()
|
||||
|
||||
class Star(Turtle):
|
||||
def __init__(self, m, x, v, gravSys, shape):
|
||||
Turtle.__init__(self, shape=shape)
|
||||
self.penup()
|
||||
self.m = m
|
||||
self.setpos(x)
|
||||
self.v = v
|
||||
gravSys.planets.append(self)
|
||||
self.gravSys = gravSys
|
||||
self.resizemode("user")
|
||||
self.pendown()
|
||||
def init(self):
|
||||
dt = self.gravSys.dt
|
||||
self.a = self.acc()
|
||||
self.v = self.v + 0.5*dt*self.a
|
||||
def acc(self):
|
||||
a = Vec(0,0)
|
||||
for planet in self.gravSys.planets:
|
||||
if planet != self:
|
||||
v = planet.pos()-self.pos()
|
||||
a += (G*planet.m/abs(v)**3)*v
|
||||
return a
|
||||
def step(self):
|
||||
dt = self.gravSys.dt
|
||||
self.setpos(self.pos() + dt*self.v)
|
||||
if self.gravSys.planets.index(self) != 0:
|
||||
self.setheading(self.towards(self.gravSys.planets[0]))
|
||||
self.a = self.acc()
|
||||
self.v = self.v + dt*self.a
|
||||
|
||||
## create compound yellow/blue turtleshape for planets
|
||||
|
||||
def main():
|
||||
s = Turtle()
|
||||
s.reset()
|
||||
s.getscreen().tracer(0,0)
|
||||
s.ht()
|
||||
s.pu()
|
||||
s.fd(6)
|
||||
s.lt(90)
|
||||
s.begin_poly()
|
||||
s.circle(6, 180)
|
||||
s.end_poly()
|
||||
m1 = s.get_poly()
|
||||
s.begin_poly()
|
||||
s.circle(6,180)
|
||||
s.end_poly()
|
||||
m2 = s.get_poly()
|
||||
|
||||
planetshape = Shape("compound")
|
||||
planetshape.addcomponent(m1,"orange")
|
||||
planetshape.addcomponent(m2,"blue")
|
||||
s.getscreen().register_shape("planet", planetshape)
|
||||
s.getscreen().tracer(1,0)
|
||||
|
||||
## setup gravitational system
|
||||
gs = GravSys()
|
||||
sun = Star(1000000, Vec(0,0), Vec(0,-2.5), gs, "circle")
|
||||
sun.color("yellow")
|
||||
sun.shapesize(1.8)
|
||||
sun.pu()
|
||||
earth = Star(12500, Vec(210,0), Vec(0,195), gs, "planet")
|
||||
earth.pencolor("green")
|
||||
earth.shapesize(0.8)
|
||||
moon = Star(1, Vec(220,0), Vec(0,295), gs, "planet")
|
||||
moon.pencolor("blue")
|
||||
moon.shapesize(0.5)
|
||||
gs.init()
|
||||
gs.start()
|
||||
return "Done!"
|
||||
|
||||
if __name__ == '__main__':
|
||||
msg = main()
|
||||
print(msg)
|
||||
#mainloop()
|
|
@ -0,0 +1,63 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
tdemo_tree.py
|
||||
|
||||
Displays a 'breadth-first-tree' - in contrast
|
||||
to the classical Logo tree drawing programs,
|
||||
which use a depth-first-algorithm.
|
||||
|
||||
Uses:
|
||||
(1) a tree-generator, where the drawing is
|
||||
quasi the side-effect, whereas the generator
|
||||
always yields None.
|
||||
(2) Turtle-cloning: At each branching point the
|
||||
current pen is cloned. So in the end there
|
||||
are 1024 turtles.
|
||||
"""
|
||||
from tkinter.turtle import Turtle, mainloop
|
||||
from time import clock
|
||||
|
||||
def tree(plist, l, a, f):
|
||||
""" plist is list of pens
|
||||
l is length of branch
|
||||
a is half of the angle between 2 branches
|
||||
f is factor by which branch is shortened
|
||||
from level to level."""
|
||||
if l > 3:
|
||||
lst = []
|
||||
for p in plist:
|
||||
p.forward(l)
|
||||
q = p.clone()
|
||||
p.left(a)
|
||||
q.right(a)
|
||||
lst.append(p)
|
||||
lst.append(q)
|
||||
for x in tree(lst, l*f, a, f):
|
||||
yield None
|
||||
|
||||
def maketree():
|
||||
p = Turtle()
|
||||
p.setundobuffer(None)
|
||||
p.hideturtle()
|
||||
p.speed(0)
|
||||
p.getscreen().tracer(30,0)
|
||||
p.left(90)
|
||||
p.penup()
|
||||
p.forward(-210)
|
||||
p.pendown()
|
||||
t = tree([p], 200, 65, 0.6375)
|
||||
for x in t:
|
||||
pass
|
||||
print(len(p.getscreen().turtles()))
|
||||
|
||||
def main():
|
||||
a=clock()
|
||||
maketree()
|
||||
b=clock()
|
||||
return "done: %.2f sec." % (b-a)
|
||||
|
||||
if __name__ == "__main__":
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,65 @@
|
|||
""" turtle-example-suite:
|
||||
|
||||
tdemo_wikipedia3.py
|
||||
|
||||
This example is
|
||||
inspired by the Wikipedia article on turtle
|
||||
graphics. (See example wikipedia1 for URLs)
|
||||
|
||||
First we create (ne-1) (i.e. 35 in this
|
||||
example) copies of our first turtle p.
|
||||
Then we let them perform their steps in
|
||||
parallel.
|
||||
|
||||
Followed by a complete undo().
|
||||
"""
|
||||
from tkinter.turtle import Screen, Turtle, mainloop
|
||||
from time import clock, sleep
|
||||
|
||||
def mn_eck(p, ne,sz):
|
||||
turtlelist = [p]
|
||||
#create ne-1 additional turtles
|
||||
for i in range(1,ne):
|
||||
q = p.clone()
|
||||
q.rt(360.0/ne)
|
||||
turtlelist.append(q)
|
||||
p = q
|
||||
for i in range(ne):
|
||||
c = abs(ne/2.0-i)/(ne*.7)
|
||||
# let those ne turtles make a step
|
||||
# in parallel:
|
||||
for t in turtlelist:
|
||||
t.rt(360./ne)
|
||||
t.pencolor(1-c,0,c)
|
||||
t.fd(sz)
|
||||
|
||||
def main():
|
||||
s = Screen()
|
||||
s.bgcolor("black")
|
||||
p=Turtle()
|
||||
p.speed(0)
|
||||
p.hideturtle()
|
||||
p.pencolor("red")
|
||||
p.pensize(3)
|
||||
|
||||
s.tracer(36,0)
|
||||
|
||||
at = clock()
|
||||
mn_eck(p, 36, 19)
|
||||
et = clock()
|
||||
z1 = et-at
|
||||
|
||||
sleep(1)
|
||||
|
||||
at = clock()
|
||||
while any([t.undobufferentries() for t in s.turtles()]):
|
||||
for t in s.turtles():
|
||||
t.undo()
|
||||
et = clock()
|
||||
return "Laufzeit: %.3f sec" % (z1+et-at)
|
||||
|
||||
|
||||
if __name__ == '__main__':
|
||||
msg = main()
|
||||
print(msg)
|
||||
mainloop()
|
|
@ -0,0 +1,49 @@
|
|||
#!/usr/bin/python
|
||||
""" turtle-example-suite:
|
||||
|
||||
tdemo_yinyang.py
|
||||
|
||||
Another drawing suitable as a beginner's
|
||||
programming example.
|
||||
|
||||
The small circles are drawn by the circle
|
||||
command.
|
||||
|
||||
"""
|
||||
|
||||
from tkinter.turtle import *
|
||||
|
||||
def yin(radius, color1, color2):
|
||||
width(3)
|
||||
color("black", color1)
|
||||
begin_fill()
|
||||
circle(radius/2., 180)
|
||||
circle(radius, 180)
|
||||
left(180)
|
||||
circle(-radius/2., 180)
|
||||
end_fill()
|
||||
left(90)
|
||||
up()
|
||||
forward(radius*0.35)
|
||||
right(90)
|
||||
down()
|
||||
color(color1, color2)
|
||||
begin_fill()
|
||||
circle(radius*0.15)
|
||||
end_fill()
|
||||
left(90)
|
||||
up()
|
||||
backward(radius*0.35)
|
||||
down()
|
||||
left(90)
|
||||
|
||||
def main():
|
||||
reset()
|
||||
yin(200, "black", "white")
|
||||
yin(200, "white", "black")
|
||||
ht()
|
||||
return "Done!"
|
||||
|
||||
if __name__ == '__main__':
|
||||
main()
|
||||
mainloop()
|
|
@ -0,0 +1,10 @@
|
|||
width = 800
|
||||
height = 600
|
||||
canvwidth = 1200
|
||||
canvheight = 900
|
||||
shape = arrow
|
||||
mode = standard
|
||||
resizemode = auto
|
||||
fillcolor = ""
|
||||
title = Python turtle graphics demo.
|
||||
|
|
@ -0,0 +1,291 @@
|
|||
#!/usr/bin/python
|
||||
import sys
|
||||
import os
|
||||
|
||||
from tkinter import *
|
||||
from idlelib.Percolator import Percolator
|
||||
from idlelib.ColorDelegator import ColorDelegator
|
||||
from idlelib.textView import view_file # TextViewer
|
||||
from imp import reload
|
||||
|
||||
from tkinter import turtle
|
||||
import time
|
||||
|
||||
STARTUP = 1
|
||||
READY = 2
|
||||
RUNNING = 3
|
||||
DONE = 4
|
||||
EVENTDRIVEN = 5
|
||||
|
||||
menufont = ("Arial", 12, NORMAL)
|
||||
btnfont = ("Arial", 12, 'bold')
|
||||
txtfont = ('Lucida Console', 8, 'normal')
|
||||
|
||||
def getExampleEntries():
|
||||
cwd = os.getcwd()
|
||||
#print(cwd, os.listdir(cwd))
|
||||
if "turtleDemo.py" not in os.listdir(cwd):
|
||||
print("Directory of turtleDemo must be current working directory!")
|
||||
print("But in your case this is", cwd)
|
||||
sys.exit()
|
||||
entries1 = [entry for entry in os.listdir(cwd) if
|
||||
entry.startswith("tdemo_") and
|
||||
not entry.endswith(".pyc")]
|
||||
entries2 = []
|
||||
for entry in entries1:
|
||||
if entry.endswith(".py"):
|
||||
entries2.append(entry)
|
||||
else:
|
||||
path = os.path.join(cwd,entry)
|
||||
sys.path.append(path)
|
||||
subdir = [entry]
|
||||
scripts = [script for script in os.listdir(path) if
|
||||
script.startswith("tdemo_") and
|
||||
script.endswith(".py")]
|
||||
entries2.append(subdir+scripts)
|
||||
return entries2
|
||||
|
||||
def showDemoHelp():
|
||||
view_file(demo.root, "Help on turtleDemo", "demohelp.txt")
|
||||
|
||||
def showAboutDemo():
|
||||
view_file(demo.root, "About turtleDemo", "about_turtledemo.txt")
|
||||
|
||||
def showAboutTurtle():
|
||||
view_file(demo.root, "About the new turtle module.", "about_turtle.txt")
|
||||
|
||||
class DemoWindow(object):
|
||||
|
||||
def __init__(self, filename=None): #, root=None):
|
||||
self.root = root = turtle._root = Tk()
|
||||
root.wm_protocol("WM_DELETE_WINDOW", self._destroy)
|
||||
|
||||
#################
|
||||
self.mBar = Frame(root, relief=RAISED, borderwidth=2)
|
||||
self.mBar.pack(fill=X)
|
||||
|
||||
self.ExamplesBtn = self.makeLoadDemoMenu()
|
||||
self.OptionsBtn = self.makeHelpMenu()
|
||||
self.mBar.tk_menuBar(self.ExamplesBtn, self.OptionsBtn) #, QuitBtn)
|
||||
|
||||
root.title('Python turtle-graphics examples')
|
||||
#################
|
||||
self.left_frame = left_frame = Frame(root)
|
||||
self.text_frame = text_frame = Frame(left_frame)
|
||||
self.vbar = vbar =Scrollbar(text_frame, name='vbar')
|
||||
self.text = text = Text(text_frame,
|
||||
name='text', padx=5, wrap='none',
|
||||
width=45)
|
||||
vbar['command'] = text.yview
|
||||
vbar.pack(side=LEFT, fill=Y)
|
||||
#####################
|
||||
self.hbar = hbar =Scrollbar(text_frame, name='hbar', orient=HORIZONTAL)
|
||||
hbar['command'] = text.xview
|
||||
hbar.pack(side=BOTTOM, fill=X)
|
||||
#####################
|
||||
text['yscrollcommand'] = vbar.set
|
||||
text.config(font=txtfont)
|
||||
text.config(xscrollcommand=hbar.set)
|
||||
text.pack(side=LEFT, fill=Y, expand=1)
|
||||
#####################
|
||||
self.output_lbl = Label(left_frame, height= 1,text=" --- ", bg = "#ddf",
|
||||
font = ("Arial", 16, 'normal'))
|
||||
self.output_lbl.pack(side=BOTTOM, expand=0, fill=X)
|
||||
#####################
|
||||
text_frame.pack(side=LEFT, fill=BOTH, expand=0)
|
||||
left_frame.pack(side=LEFT, fill=BOTH, expand=0)
|
||||
self.graph_frame = g_frame = Frame(root)
|
||||
|
||||
turtle.Screen._root = g_frame
|
||||
turtle.Screen._canvas = turtle.ScrolledCanvas(g_frame, 800, 600, 1000, 800)
|
||||
#xturtle.Screen._canvas.pack(expand=1, fill="both")
|
||||
self.screen = _s_ = turtle.Screen()
|
||||
#####
|
||||
turtle.TurtleScreen.__init__(_s_, _s_._canvas)
|
||||
#####
|
||||
self.scanvas = _s_._canvas
|
||||
#xturtle.RawTurtle.canvases = [self.scanvas]
|
||||
turtle.RawTurtle.screens = [_s_]
|
||||
|
||||
self.scanvas.pack(side=TOP, fill=BOTH, expand=1)
|
||||
|
||||
self.btn_frame = btn_frame = Frame(g_frame, height=100)
|
||||
self.start_btn = Button(btn_frame, text=" START ", font=btnfont, fg = "white",
|
||||
disabledforeground = "#fed", command=self.startDemo)
|
||||
self.start_btn.pack(side=LEFT, fill=X, expand=1)
|
||||
self.stop_btn = Button(btn_frame, text=" STOP ", font=btnfont, fg = "white",
|
||||
disabledforeground = "#fed", command = self.stopIt)
|
||||
self.stop_btn.pack(side=LEFT, fill=X, expand=1)
|
||||
self.clear_btn = Button(btn_frame, text=" CLEAR ", font=btnfont, fg = "white",
|
||||
disabledforeground = "#fed", command = self.clearCanvas)
|
||||
self.clear_btn.pack(side=LEFT, fill=X, expand=1)
|
||||
|
||||
self.btn_frame.pack(side=TOP, fill=BOTH, expand=0)
|
||||
self.graph_frame.pack(side=TOP, fill=BOTH, expand=1)
|
||||
|
||||
Percolator(text).insertfilter(ColorDelegator())
|
||||
self.dirty = False
|
||||
self.exitflag = False
|
||||
if filename:
|
||||
self.loadfile(filename)
|
||||
self.configGUI(NORMAL, DISABLED, DISABLED, DISABLED,
|
||||
"Choose example from menu", "black")
|
||||
self.state = STARTUP
|
||||
|
||||
def _destroy(self):
|
||||
self.root.destroy()
|
||||
sys.exit()
|
||||
|
||||
def configGUI(self, menu, start, stop, clear, txt="", color="blue"):
|
||||
self.ExamplesBtn.config(state=menu)
|
||||
|
||||
self.start_btn.config(state=start)
|
||||
if start==NORMAL:
|
||||
self.start_btn.config(bg="#d00")
|
||||
else:
|
||||
self.start_btn.config(bg="#fca")
|
||||
|
||||
self.stop_btn.config(state=stop)
|
||||
if stop==NORMAL:
|
||||
self.stop_btn.config(bg="#d00")
|
||||
else:
|
||||
self.stop_btn.config(bg="#fca")
|
||||
self.clear_btn.config(state=clear)
|
||||
|
||||
self.clear_btn.config(state=clear)
|
||||
if clear==NORMAL:
|
||||
self.clear_btn.config(bg="#d00")
|
||||
else:
|
||||
self.clear_btn.config(bg="#fca")
|
||||
|
||||
self.output_lbl.config(text=txt, fg=color)
|
||||
|
||||
|
||||
def makeLoadDemoMenu(self):
|
||||
CmdBtn = Menubutton(self.mBar, text='Examples', underline=0, font=menufont)
|
||||
CmdBtn.pack(side=LEFT, padx="2m")
|
||||
CmdBtn.menu = Menu(CmdBtn)
|
||||
|
||||
for entry in getExampleEntries():
|
||||
def loadexample(x):
|
||||
def emit():
|
||||
self.loadfile(x)
|
||||
return emit
|
||||
if isinstance(entry,str):
|
||||
CmdBtn.menu.add_command(label=entry[6:-3], underline=0, font=menufont,
|
||||
command=loadexample(entry))
|
||||
else:
|
||||
_dir, entries = entry[0], entry[1:]
|
||||
CmdBtn.menu.choices = Menu(CmdBtn.menu)
|
||||
for e in entries:
|
||||
CmdBtn.menu.choices.add_command(label=e[6:-3], underline=0, font=menufont,
|
||||
command = loadexample(os.path.join(_dir,e)))
|
||||
|
||||
CmdBtn.menu.add_cascade(label=_dir[6:],
|
||||
menu = CmdBtn.menu.choices, font=menufont )
|
||||
|
||||
CmdBtn['menu'] = CmdBtn.menu
|
||||
return CmdBtn
|
||||
|
||||
|
||||
def makeHelpMenu(self):
|
||||
CmdBtn = Menubutton(self.mBar, text='Help', underline=0, font = menufont)
|
||||
CmdBtn.pack(side=LEFT, padx='2m')
|
||||
CmdBtn.menu = Menu(CmdBtn)
|
||||
|
||||
CmdBtn.menu.add_command(label='About turtle.py', font=menufont, command=showAboutTurtle)
|
||||
CmdBtn.menu.add_command(label='turtleDemo - Help', font=menufont, command=showDemoHelp)
|
||||
CmdBtn.menu.add_command(label='About turtleDemo', font=menufont, command=showAboutDemo)
|
||||
|
||||
CmdBtn['menu'] = CmdBtn.menu
|
||||
return CmdBtn
|
||||
|
||||
def refreshCanvas(self):
|
||||
if not self.dirty: return
|
||||
self.screen.clear()
|
||||
#self.screen.mode("standard")
|
||||
self.dirty=False
|
||||
|
||||
def loadfile(self,filename):
|
||||
self.refreshCanvas()
|
||||
if os.path.exists(filename) and not os.path.isdir(filename):
|
||||
# load and display file text
|
||||
f = open(filename,'r')
|
||||
chars = f.read()
|
||||
f.close()
|
||||
self.text.delete("1.0", "end")
|
||||
self.text.insert("1.0",chars)
|
||||
direc, fname = os.path.split(filename)
|
||||
self.root.title(fname[6:-3]+" - a Python turtle graphics example")
|
||||
self.module = __import__(fname[:-3])
|
||||
reload(self.module)
|
||||
self.configGUI(NORMAL, NORMAL, DISABLED, DISABLED,
|
||||
"Press start button", "red")
|
||||
self.state = READY
|
||||
|
||||
def startDemo(self):
|
||||
self.refreshCanvas()
|
||||
self.dirty = True
|
||||
turtle.TurtleScreen._RUNNING = True
|
||||
self.configGUI(DISABLED, DISABLED, NORMAL, DISABLED,
|
||||
"demo running...", "black")
|
||||
self.screen.clear()
|
||||
self.screen.mode("standard")
|
||||
self.state = RUNNING
|
||||
|
||||
try:
|
||||
result = self.module.main()
|
||||
if result == "EVENTLOOP":
|
||||
self.state = EVENTDRIVEN
|
||||
else:
|
||||
self.state = DONE
|
||||
except turtle.Terminator:
|
||||
self.state = DONE
|
||||
result = "stopped!"
|
||||
if self.state == DONE:
|
||||
self.configGUI(NORMAL, NORMAL, DISABLED, NORMAL,
|
||||
result)
|
||||
elif self.state == EVENTDRIVEN:
|
||||
self.exitflag = True
|
||||
self.configGUI(DISABLED, DISABLED, NORMAL, DISABLED,
|
||||
"use mouse/keys or STOP", "red")
|
||||
|
||||
def clearCanvas(self):
|
||||
self.refreshCanvas()
|
||||
self.screen._delete("all")
|
||||
self.scanvas.config(cursor="")
|
||||
self.configGUI(NORMAL, NORMAL, DISABLED, DISABLED)
|
||||
|
||||
def stopIt(self):
|
||||
if self.exitflag:
|
||||
self.clearCanvas()
|
||||
self.exitflag = False
|
||||
self.configGUI(NORMAL, NORMAL, DISABLED, DISABLED,
|
||||
"STOPPED!", "red")
|
||||
turtle.TurtleScreen._RUNNING = False
|
||||
#print "stopIT: exitflag = True"
|
||||
else:
|
||||
turtle.TurtleScreen._RUNNING = False
|
||||
#print "stopIt: exitflag = False"
|
||||
|
||||
if __name__ == '__main__':
|
||||
demo = DemoWindow()
|
||||
RUN = True
|
||||
while RUN:
|
||||
try:
|
||||
#print("ENTERING mainloop")
|
||||
demo.root.mainloop()
|
||||
except AttributeError:
|
||||
#print("AttributeError!- WAIT A MOMENT!")
|
||||
time.sleep(0.3)
|
||||
print("GOING ON ..")
|
||||
demo.ckearCanvas()
|
||||
except TypeError:
|
||||
demo.screen._delete("all")
|
||||
#print("CRASH!!!- WAIT A MOMENT!")
|
||||
time.sleep(0.3)
|
||||
#print("GOING ON ..")
|
||||
demo.clearCanvas()
|
||||
except:
|
||||
print("BYE!")
|
||||
RUN = False
|
|
@ -0,0 +1,52 @@
|
|||
#!/usr/bin/python
|
||||
## DEMONSTRATES USE OF 2 CANVASES, SO CANNOT BE RUN IN DEMOVIEWER!
|
||||
"""turtle example: Using TurtleScreen and RawTurtle
|
||||
for drawing on two distinct canvases.
|
||||
"""
|
||||
from tkinter.turtle import TurtleScreen, RawTurtle, TK
|
||||
|
||||
root = TK.Tk()
|
||||
cv1 = TK.Canvas(root, width=300, height=200, bg="#ddffff")
|
||||
cv2 = TK.Canvas(root, width=300, height=200, bg="#ffeeee")
|
||||
cv1.pack()
|
||||
cv2.pack()
|
||||
|
||||
s1 = TurtleScreen(cv1)
|
||||
s1.bgcolor(0.85, 0.85, 1)
|
||||
s2 = TurtleScreen(cv2)
|
||||
s2.bgcolor(1, 0.85, 0.85)
|
||||
|
||||
p = RawTurtle(s1)
|
||||
q = RawTurtle(s2)
|
||||
|
||||
p.color("red", (1, 0.85, 0.85))
|
||||
p.width(3)
|
||||
q.color("blue", (0.85, 0.85, 1))
|
||||
q.width(3)
|
||||
|
||||
for t in p,q:
|
||||
t.shape("turtle")
|
||||
t.lt(36)
|
||||
|
||||
q.lt(180)
|
||||
|
||||
for t in p, q:
|
||||
t.begin_fill()
|
||||
for i in range(5):
|
||||
for t in p, q:
|
||||
t.fd(50)
|
||||
t.lt(72)
|
||||
for t in p,q:
|
||||
t.end_fill()
|
||||
t.lt(54)
|
||||
t.pu()
|
||||
t.bk(50)
|
||||
|
||||
## Want to get some info?
|
||||
|
||||
print(s1, s2)
|
||||
print(p, q)
|
||||
print(s1.turtles())
|
||||
print(s2.turtles())
|
||||
|
||||
TK.mainloop()
|
File diff suppressed because it is too large
Load Diff
File diff suppressed because it is too large
Load Diff
Loading…
Reference in New Issue