In this article we will continue with our previous pygame project by creating an exit button on the main game menu scene which when the user clicks on it the program will close the game. We will create the score scene in the next chapter as I have promised in the previous article but in this article we will create the exit button which is also very important for this project. This button will only...

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Related posts:

Open a text file then write the game level onto it with python Create the pause scene for the game Create the third level for this pygame project Lets move on to the next game level! Create a pool object for player missile Create an explosion manager and explosion class for pygame project Pygame loads image and background graphic on game scene The game state engine is ready! Playing background music with Pygame Draw lines with Pygame

13 Dec 2018 10:58am GMT

In this article we will continue with our previous pygame project by creating an exit button on the main game menu scene which when the user clicks on it the program will close the game. We will create the score scene in the next chapter as I have promised in the previous article but in this article we will create the exit button which is also very important for this project. This button will only...

Source

Related posts:

Open a text file then write the game level onto it with python Create the pause scene for the game Create the third level for this pygame project Lets move on to the next game level! Create a pool object for player missile Create an explosion manager and explosion class for pygame project Pygame loads image and background graphic on game scene The game state engine is ready! Playing background music with Pygame Draw lines with Pygame

13 Dec 2018 10:58am GMT

Python's list is one of the built-in sequence types (i.e. "it holds a sequence of things") is a wonderfully useful tool. I figured I'd try to determine what people are most often trying to do with lists (by analyzing Google's query data on the topic) and just bang out examples of "How do I do X with a list in Python?"

Reverse/Sort A List In Python

There are two ways to reverse a list in Python, and which one you use depends on what you want to do with the resulting reversed data. If you're only going iterate over the items in the reversed list (say, to print them out), use the Python built-in function reversed(seq). Here's an example of reversed in action:

original_list = [1, 2, 3, 4, 5]
for element in reversed(original_list):
    print(element)

If you need the reversed list itself, use the Python built-in function sorted(iterable, *, key=None, reverse=False). Let's see some examples:

In [10]: original_list = [3, 1, 2, 5, 4]

In [11]: sorted(original_list)
Out[11]: [1, 2, 3, 4, 5]

In [15]: sorted(original_list, reverse=True)
Out[15]: [5, 4, 3, 2, 1]

But what if your list contains more than just simple integers? How does one sort, say, a list of temperature readings over a given time if those daily readings are each stored as a tuples of the form (<date>, <daily high>, <daily low>)? Look at the following example:

readings = [('1202', 45.0, 28.1), ('1201', 44.0, 33.0), ('1130', 45.0, 32.6)]

Calling sorted(readings) will give us a new list with the elements ordered by the <date> portion of the tuple (the 0-th element, since Python compares tuples lexicographically; each item is compared in order, starting with the first elements). But what if we wanted to sort by <daily high> or <daily low>? Simple! Just pass the key parameter a function that takes a single argument and returns the key for sorted() to use for comparisons. For example, I could sort by daily low temperatures like so:

In [25]: sorted(readings, key=lambda reading: reading[2])
Out[25]: [('1202', 45.0, 28.1), ('1130', 45.0, 32.6), ('1201', 44.0, 33.0)]

In that example, we passed the key parameter a lambda function which accepted one argument and returned a value, in our case the third part of our temperature recording tuple (the reading[2] part). If we had wanted to sort by the daily high in reverse order, we would just change the call like so:

In [26]: sorted(readings, key=lambda reading: reading[1], reverse=True)
Out[26]: [('1202', 45.0, 28.1), ('1130', 45.0, 32.6), ('1201', 44.0, 33.0)]

Accessing elements of a tuple or class is such a common task that Python provides a set of convenience functions in the operator built-in module. To access a specific field in the tuple (as we did above for daily high as reading[1] and daily low as reading[2]), use the field's index in the tuple as an argument to operator.itemgetter:

In [29]: sorted(readings, key=itemgetter(1), reverse=True)
Out[29]: [('1202', 45.0, 28.1), ('1130', 45.0, 32.6), ('1201', 44.0, 33.0)]

But notice that the first two entries have the same high temp recordings (45.0). What if we wanted to first sort by high temp and then by low temp? itemgetter allows for multiple levels of sorting by simply passing in multiple index values. So let's sort by high temp first, then low temp:

In [31]: sorted(readings, key=itemgetter(1,2), reverse=True)
Out[31]: [('1130', 45.0, 32.6), ('1202', 45.0, 28.1), ('1201', 44.0, 33.0)]

Notice that the ('1130', 45.0, 32.6) tuple is now first, as it had an equal high temp and a greater low temp than ('1202', 45.0, 28.1).

Split A Python List Into Chunks

Splitting a list into equally sized sub-lists (for processing data in parallel, perhaps) is a common task. It's so common, in fact, that the itertools module (a module practically begging to be used in these kinds of tasks, by the way) gives actual code for how to accomplish this in Python in the itertools recpipes section of the docs. Here is the relevant code:

def grouper(iterable, n, fillvalue=None):
    "Collect data into fixed-length chunks or blocks"
    # grouper('ABCDEFG', 3, 'x') --> ABC DEF Gxx"
    args = [iter(iterable)] * n
    return zip_longest(*args, fillvalue=fillvalue)

The code may look confusing at first, but it's simply creating n (or 3 in the example in the comments) separate iterators over the iterable argument and then cleverly zipping them back together using zip_longest from the itertools module, to collect the elements of iterable in a series of n-sized chunks.

Flatten A Python List Of Lists Into One List

itertools recipes FTW again! Straight out of the section of the Python docs that gave us grouper above, the recipe for "flatten" is:

def flatten(list_of_lists):
    "Flatten one level of nesting."
    return chain.from_iterable(list_of_lists)

It simply calls itertools.chain.from_iterable() on the list_of_lists. A call to flatten([[1, 2, 3], [4, 5], [6, 7, 8]]) will give us an iterator that yields each element individually. We can say flattened_list = list(flatten([[1, 2, 3], [4, 5], [6, 7, 8]])) if what we need is an actual list and not just an iterator.

Insert Into A List In Python

The word "insert" here is vague (insert where?), but let's roll with it. Here are some of the flavors of list assignment mentioned in the Python docs about operations on "Mutable Sequence Types":

Operation   Result

s[i] = x    item i of s is replaced by x     
s[i:j] = t  slice of s from i to j is replaced by the contents of the iterable t     
s[i:j:k] = t    the elements of s[i:j:k] are replaced by those of t (as long as t is the same length as the slice it's replacing)
s.append(x) appends x to the end of the sequence (same as s[len(s):len(s)] = [x])
s.extend(t) or s += t   extends s with the contents of t (for the most part the same as s[len(s):len(s)] = t)    
s.insert(i, x)  inserts x into s at the index given by i (same as s[i:i] = [x])

So six different ways to insert into a list in Python. That doesn't seem very Pythonic!? Let's see which we might use on a case by case basis:

Insert Into The Beginning Of A List In Python

s.insert(0, value)

Insert Into The End Of A List In Python

s.append(value)

Insert Into An Existing Index Of A Python List

s[index] = value

Concatenating Two Python Lists

s += t  # Where s and t are both lists

Python "List Index Out Of Range" Error Message

This entry is less a "how-to" and more of a "what to do when things go wrong" type of entry, but it's nonetheless searched for very often in conjunction with Python lists (for obvious reasons). The message "list index out of range" is brought to you by a specific type of built-in Exception, namely the IndexError. It is simply saying that you tried to access a list, perhaps using code like the following:

def my_function(some_list):
    """Return something really interesting..."""
    third_value = some_list[2]
    # ... possibly more code following

2 is not a valid index to use because some_list does not have three values (we don't know how many it does have, just less than 3 in this case).

Want to know how many values some_list has? The Python built-in len(s) function will give you exactly that.

A simple debugging exercise of the "list index out of range" message might look like this:

def my_function(some_list):
    try:
        third_value = some_list[2]
    except IndexError:
        print(f'some_list only has {len(some_list)} entries')
        raise

Here we put our code in a try...except block and catch any IndexError exceptions that are raised. When we see one, we just print out the length of some_list and re-raise the exception (since we can't exactly handle that in any useful way). That gives me the following output:

In [50]: def my_function(some_list):
    ...:         try:
    ...:             third_value = some_list[2]
    ...:         except IndexError:
    ...:             print(f'some_list only has {len(some_list)} entries')
    ...:             raise
    ...:

In [51]: my_function([1,2])
some_list only has 2 entries
---------------------------------------------------------------------------
IndexError                                Traceback (most recent call last)
<ipython-input-51-3f735c70ddb9> in <module>
----> 1 my_function([1,2])

<ipython-input-50-137ffeaa7c70> in my_function(some_list)
    1 def my_function(some_list):
    2         try:
----> 3             third_value = some_list[2]
    4         except IndexError:
    5             print(f'some_list only has {len(some_list)} entries')

IndexError: list index out of range

How To Make A List In Python

The section topic is taken directly from search query volume, so rest assured this isn't me just throwing random facts about Python lists at you. There are a few ways to create a list in Python, but the two you'll use the most is using the "square-brace" syntax:

• x = [] sets x to an empty list
• x = [1, 2, 3] sets x to a list with the values 1, 2, 3
• x = [x for x in iterable] is the simplest example of list comprehension syntax (list comprehensions can be thought of syntactic sugar when creating a new list from an existing sequence and are very powerful tools, but probably outside the scope of this article).
• x = list() or x = list((1,2,3)) to use the list type constructor

Generally speaking, prefer the use of the first two methods unless you can think of a very good reason not to.

Apply A Function To A List In Python

Remember when I said list comprehensions were out of scope for this article. I lied. Even though they're a little trickier to grasp, they're very powerful and applying a function to each element in a list in Python is basically their bread and butter. Imagine we have a list of the numbers one through five and want to create a second list whose elements exactly each element in the original list multiplied by two. To construct such a list using a for loop, we'd need the following code:

original_list = [1,2,3,4,5]
double_list = []
for element in original_list:
    double_list.append(element * 2)

The need to do this occurs so frequently that (especially for performance-sensitive applications) a highly optimized general form of the above as part of the Python language in list comprehensions. Rather than go over the topic in great detail here, I'll simply link to the Python documentation on list comprehensions and note that we could achieve the same as code above using a list comprehension, like so:

original_list = [1,2,3,4,5]
double_list = [element * 2 for element in original_list]

I've grown to appreciate the precision of the grammar when reading it aloud, but it definitely takes some getting used to (and this is only the simplest use of a list comprehension).

Of course, there's always the Python built-in function map(), which will do much the same thing in a slightly easier to grok way, but there is an important difference between the two: map() yields the values back one-at-a-time (it's a generator) whereas a list comprehension will always create a new list from the existing list given as an argument.

It may seem difficult, but try to get to a place where you're using list comprehensions rather than map() as the former are both more powerful and more Pythonic.

Summary

This article was a quick hit, but it's good to go back to basics occasionally and see if there's anything you might have missed your first time through (I'll wager that very few Python developers know and use the itertools module as well and often as they should). I tentatively plan on adding to this article over time (a change log would be provided). Let me know if you think there's a common "Python list" Google query I missed or with suggestions on the other parts of Python lists that often trip up newcomers.

13 Dec 2018 8:02am GMT

Python's list is one of the built-in sequence types (i.e. "it holds a sequence of things") is a wonderfully useful tool. I figured I'd try to determine what people are most often trying to do with lists (by analyzing Google's query data on the topic) and just bang out examples of "How do I do X with a list in Python?"

Reverse/Sort A List In Python

There are two ways to reverse a list in Python, and which one you use depends on what you want to do with the resulting reversed data. If you're only going iterate over the items in the reversed list (say, to print them out), use the Python built-in function reversed(seq). Here's an example of reversed in action:

original_list = [1, 2, 3, 4, 5]
for element in reversed(original_list):
    print(element)

If you need the reversed list itself, use the Python built-in function sorted(iterable, *, key=None, reverse=False). Let's see some examples:

In [10]: original_list = [3, 1, 2, 5, 4]

In [11]: sorted(original_list)
Out[11]: [1, 2, 3, 4, 5]

In [15]: sorted(original_list, reverse=True)
Out[15]: [5, 4, 3, 2, 1]

But what if your list contains more than just simple integers? How does one sort, say, a list of temperature readings over a given time if those daily readings are each stored as a tuples of the form (<date>, <daily high>, <daily low>)? Look at the following example:

readings = [('1202', 45.0, 28.1), ('1201', 44.0, 33.0), ('1130', 45.0, 32.6)]

Calling sorted(readings) will give us a new list with the elements ordered by the <date> portion of the tuple (the 0-th element, since Python compares tuples lexicographically; each item is compared in order, starting with the first elements). But what if we wanted to sort by <daily high> or <daily low>? Simple! Just pass the key parameter a function that takes a single argument and returns the key for sorted() to use for comparisons. For example, I could sort by daily low temperatures like so:

In [25]: sorted(readings, key=lambda reading: reading[2])
Out[25]: [('1202', 45.0, 28.1), ('1130', 45.0, 32.6), ('1201', 44.0, 33.0)]

In that example, we passed the key parameter a lambda function which accepted one argument and returned a value, in our case the third part of our temperature recording tuple (the reading[2] part). If we had wanted to sort by the daily high in reverse order, we would just change the call like so:

In [26]: sorted(readings, key=lambda reading: reading[1], reverse=True)
Out[26]: [('1202', 45.0, 28.1), ('1130', 45.0, 32.6), ('1201', 44.0, 33.0)]

Accessing elements of a tuple or class is such a common task that Python provides a set of convenience functions in the operator built-in module. To access a specific field in the tuple (as we did above for daily high as reading[1] and daily low as reading[2]), use the field's index in the tuple as an argument to operator.itemgetter:

In [29]: sorted(readings, key=itemgetter(1), reverse=True)
Out[29]: [('1202', 45.0, 28.1), ('1130', 45.0, 32.6), ('1201', 44.0, 33.0)]

But notice that the first two entries have the same high temp recordings (45.0). What if we wanted to first sort by high temp and then by low temp? itemgetter allows for multiple levels of sorting by simply passing in multiple index values. So let's sort by high temp first, then low temp:

In [31]: sorted(readings, key=itemgetter(1,2), reverse=True)
Out[31]: [('1130', 45.0, 32.6), ('1202', 45.0, 28.1), ('1201', 44.0, 33.0)]

Notice that the ('1130', 45.0, 32.6) tuple is now first, as it had an equal high temp and a greater low temp than ('1202', 45.0, 28.1).

Split A Python List Into Chunks

Splitting a list into equally sized sub-lists (for processing data in parallel, perhaps) is a common task. It's so common, in fact, that the itertools module (a module practically begging to be used in these kinds of tasks, by the way) gives actual code for how to accomplish this in Python in the itertools recpipes section of the docs. Here is the relevant code:

def grouper(iterable, n, fillvalue=None):
    "Collect data into fixed-length chunks or blocks"
    # grouper('ABCDEFG', 3, 'x') --> ABC DEF Gxx"
    args = [iter(iterable)] * n
    return zip_longest(*args, fillvalue=fillvalue)

The code may look confusing at first, but it's simply creating n (or 3 in the example in the comments) separate iterators over the iterable argument and then cleverly zipping them back together using zip_longest from the itertools module, to collect the elements of iterable in a series of n-sized chunks.

Flatten A Python List Of Lists Into One List

itertools recipes FTW again! Straight out of the section of the Python docs that gave us grouper above, the recipe for "flatten" is:

def flatten(list_of_lists):
    "Flatten one level of nesting."
    return chain.from_iterable(list_of_lists)

It simply calls itertools.chain.from_iterable() on the list_of_lists. A call to flatten([[1, 2, 3], [4, 5], [6, 7, 8]]) will give us an iterator that yields each element individually. We can say flattened_list = list(flatten([[1, 2, 3], [4, 5], [6, 7, 8]])) if what we need is an actual list and not just an iterator.

Insert Into A List In Python

The word "insert" here is vague (insert where?), but let's roll with it. Here are some of the flavors of list assignment mentioned in the Python docs about operations on "Mutable Sequence Types":

Operation   Result

s[i] = x    item i of s is replaced by x     
s[i:j] = t  slice of s from i to j is replaced by the contents of the iterable t     
s[i:j:k] = t    the elements of s[i:j:k] are replaced by those of t (as long as t is the same length as the slice it's replacing)
s.append(x) appends x to the end of the sequence (same as s[len(s):len(s)] = [x])
s.extend(t) or s += t   extends s with the contents of t (for the most part the same as s[len(s):len(s)] = t)    
s.insert(i, x)  inserts x into s at the index given by i (same as s[i:i] = [x])

So six different ways to insert into a list in Python. That doesn't seem very Pythonic!? Let's see which we might use on a case by case basis:

Insert Into The Beginning Of A List In Python

s.insert(0, value)

Insert Into The End Of A List In Python

s.append(value)

Insert Into An Existing Index Of A Python List

s[index] = value

Concatenating Two Python Lists

s += t  # Where s and t are both lists

Python "List Index Out Of Range" Error Message

This entry is less a "how-to" and more of a "what to do when things go wrong" type of entry, but it's nonetheless searched for very often in conjunction with Python lists (for obvious reasons). The message "list index out of range" is brought to you by a specific type of built-in Exception, namely the IndexError. It is simply saying that you tried to access a list, perhaps using code like the following:

def my_function(some_list):
    """Return something really interesting..."""
    third_value = some_list[2]
    # ... possibly more code following

2 is not a valid index to use because some_list does not have three values (we don't know how many it does have, just less than 3 in this case).

Want to know how many values some_list has? The Python built-in len(s) function will give you exactly that.

A simple debugging exercise of the "list index out of range" message might look like this:

def my_function(some_list):
    try:
        third_value = some_list[2]
    except IndexError:
        print(f'some_list only has {len(some_list)} entries')
        raise

Here we put our code in a try...except block and catch any IndexError exceptions that are raised. When we see one, we just print out the length of some_list and re-raise the exception (since we can't exactly handle that in any useful way). That gives me the following output:

In [50]: def my_function(some_list):
    ...:         try:
    ...:             third_value = some_list[2]
    ...:         except IndexError:
    ...:             print(f'some_list only has {len(some_list)} entries')
    ...:             raise
    ...:

In [51]: my_function([1,2])
some_list only has 2 entries
---------------------------------------------------------------------------
IndexError                                Traceback (most recent call last)
<ipython-input-51-3f735c70ddb9> in <module>
----> 1 my_function([1,2])

<ipython-input-50-137ffeaa7c70> in my_function(some_list)
    1 def my_function(some_list):
    2         try:
----> 3             third_value = some_list[2]
    4         except IndexError:
    5             print(f'some_list only has {len(some_list)} entries')

IndexError: list index out of range

How To Make A List In Python

The section topic is taken directly from search query volume, so rest assured this isn't me just throwing random facts about Python lists at you. There are a few ways to create a list in Python, but the two you'll use the most is using the "square-brace" syntax:

• x = [] sets x to an empty list
• x = [1, 2, 3] sets x to a list with the values 1, 2, 3
• x = [x for x in iterable] is the simplest example of list comprehension syntax (list comprehensions can be thought of syntactic sugar when creating a new list from an existing sequence and are very powerful tools, but probably outside the scope of this article).
• x = list() or x = list((1,2,3)) to use the list type constructor

Generally speaking, prefer the use of the first two methods unless you can think of a very good reason not to.

Apply A Function To A List In Python

Remember when I said list comprehensions were out of scope for this article. I lied. Even though they're a little trickier to grasp, they're very powerful and applying a function to each element in a list in Python is basically their bread and butter. Imagine we have a list of the numbers one through five and want to create a second list whose elements exactly each element in the original list multiplied by two. To construct such a list using a for loop, we'd need the following code:

original_list = [1,2,3,4,5]
double_list = []
for element in original_list:
    double_list.append(element * 2)

The need to do this occurs so frequently that (especially for performance-sensitive applications) a highly optimized general form of the above as part of the Python language in list comprehensions. Rather than go over the topic in great detail here, I'll simply link to the Python documentation on list comprehensions and note that we could achieve the same as code above using a list comprehension, like so:

original_list = [1,2,3,4,5]
double_list = [element * 2 for element in original_list]

I've grown to appreciate the precision of the grammar when reading it aloud, but it definitely takes some getting used to (and this is only the simplest use of a list comprehension).

Of course, there's always the Python built-in function map(), which will do much the same thing in a slightly easier to grok way, but there is an important difference between the two: map() yields the values back one-at-a-time (it's a generator) whereas a list comprehension will always create a new list from the existing list given as an argument.

It may seem difficult, but try to get to a place where you're using list comprehensions rather than map() as the former are both more powerful and more Pythonic.

Summary

This article was a quick hit, but it's good to go back to basics occasionally and see if there's anything you might have missed your first time through (I'll wager that very few Python developers know and use the itertools module as well and often as they should). I tentatively plan on adding to this article over time (a change log would be provided). Let me know if you think there's a common "Python list" Google query I missed or with suggestions on the other parts of Python lists that often trip up newcomers.

13 Dec 2018 8:02am GMT

Hi everyone! If you have been following my blog for a while you will know that I did research at Colgate University over the summers. My research was on Wi-Fi and how I can do some interesting stuff using it. The university just published its annual catalogue of all the research projects which happened over the summer. My research was done under the mentorship of Aaron Gember-Jacobson. I could not have asked for a better advisor. Here is the writeup of my project:

According to RAINN (Rape, Abuse & Incest National Network), 23.1% of female and 5.4% of male undergraduate students experience rape or sexual assault, with only a minute percentage reporting their assault to law enforcement¹. In certain cases, survivors can forget who the perpetrator was due to trauma and/or intoxication. I want to use technology to counter this problem. My hope is to reduce the number of potential culprits when such an incident occurs to make it easier for the survivor to identify the perpetrator.

This can be made possible by using a device that most people carry at all times - a smartphone. The idea is to save the device identifier and the distance between your phone and that of each person who comes near you in a searchable database. This allows you, the user, to search for which device was near you at a particular time. The research is further divided into two parts. The first involved finding a way to effectively calculate the relative distance between two smartphones and the second involved information storage and querying. I focused mainly on the first part, which turned out to be more difficult and involved than I anticipated.

The cornerstone of this idea is Wi-Fi and the information your smartphone emits when the Wi-Fi is turned on, though not necessarily connected to an access point. The formal requirements of this system are as follows: it should be passive so you don't have to actively monitor it; it shouldn't require other people's smartphones to run any specific application; the error in distance estimation should be less than 1 meter so the algorithm can accurately identify a human interaction; the system needs to work in NLOS (Non-line-of-sight) scenarios since people often have their smartphones in their pockets; finally, it should not require more than three devices, including your smartphone, a nearby smartphone, and a Wi-Fi Access Point to which both phones are connected, because the system should be portable.

Previous research in relative distance estimation offers varying levels of precision. One method involves using RSSI (Received Signal Strength Indication) readings from multiple access points (4+ for accuracy) and triangulating smartphone position based on that. We cannot use this method because 4+ devices are required. Another method involves using Time-of-Flight (ToF) measurements. There are multiple variations of this method, but the basic idea is to send data from your device to the device being localized, and recording the time taken for the data to travel from one device to another and for an acknowledgment to be received. Based on this timing measurement and the required time delay (known as SIFS, or Short Interframe Space) between a device receiving data and sending an acknowledgement, we can estimate the distance between two devices. This gives the best accuracy but is not directly applicable to this situation, because it requires a direct connection between the two smartphones.

I sought to develop a modified version of the ToF method, because it offers the best precision and requires the least number of devices to work effectively. The method I developed was to send unsolicited control packets (a special type of data frame) to the target mobile device and force it to send an acknowledgement (see figure). The major research question is: how do we force the target device to send an acknowledgement even if we are not directly connected to it?

I set up a testbed with three desktops equipped with Wi-Fi cards and running Ubuntu Linux. I used Scapy (a Python program for generating network packets) to generate and send control packets from one desktop to another and tcpdump on the third desktop to monitor and analyze the wireless communication taking place. I was able to send the control packets and solicit an acknowledgment from the target mobile (Ubuntu desktop) without being directly connected to it.

However, there was a bug in the networking drivers of Ubuntu that generated acknowledgments even in cases where no acknowledgment was supposed to be sent by the target device. Currently, I am investigating the bug and trying to figure out the most suitable way forward. Through this research, I found that the process of distance estimation is more complicated than it seems. There are several variables and timing issues that need to be taken into account. In the future, I plan on finding a workaround for this bug, with the eventual goal of making this system usable in everyday life.

If you have any questions about my research or anything in general please write them in the comments below. Looking forward to hearing your views! Have a great day/night!

13 Dec 2018 5:54am GMT

Hi everyone! If you have been following my blog for a while you will know that I did research at Colgate University over the summers. My research was on Wi-Fi and how I can do some interesting stuff using it. The university just published its annual catalogue of all the research projects which happened over the summer. My research was done under the mentorship of Aaron Gember-Jacobson. I could not have asked for a better advisor. Here is the writeup of my project:

According to RAINN (Rape, Abuse & Incest National Network), 23.1% of female and 5.4% of male undergraduate students experience rape or sexual assault, with only a minute percentage reporting their assault to law enforcement¹. In certain cases, survivors can forget who the perpetrator was due to trauma and/or intoxication. I want to use technology to counter this problem. My hope is to reduce the number of potential culprits when such an incident occurs to make it easier for the survivor to identify the perpetrator.

This can be made possible by using a device that most people carry at all times - a smartphone. The idea is to save the device identifier and the distance between your phone and that of each person who comes near you in a searchable database. This allows you, the user, to search for which device was near you at a particular time. The research is further divided into two parts. The first involved finding a way to effectively calculate the relative distance between two smartphones and the second involved information storage and querying. I focused mainly on the first part, which turned out to be more difficult and involved than I anticipated.

The cornerstone of this idea is Wi-Fi and the information your smartphone emits when the Wi-Fi is turned on, though not necessarily connected to an access point. The formal requirements of this system are as follows: it should be passive so you don't have to actively monitor it; it shouldn't require other people's smartphones to run any specific application; the error in distance estimation should be less than 1 meter so the algorithm can accurately identify a human interaction; the system needs to work in NLOS (Non-line-of-sight) scenarios since people often have their smartphones in their pockets; finally, it should not require more than three devices, including your smartphone, a nearby smartphone, and a Wi-Fi Access Point to which both phones are connected, because the system should be portable.

Previous research in relative distance estimation offers varying levels of precision. One method involves using RSSI (Received Signal Strength Indication) readings from multiple access points (4+ for accuracy) and triangulating smartphone position based on that. We cannot use this method because 4+ devices are required. Another method involves using Time-of-Flight (ToF) measurements. There are multiple variations of this method, but the basic idea is to send data from your device to the device being localized, and recording the time taken for the data to travel from one device to another and for an acknowledgment to be received. Based on this timing measurement and the required time delay (known as SIFS, or Short Interframe Space) between a device receiving data and sending an acknowledgement, we can estimate the distance between two devices. This gives the best accuracy but is not directly applicable to this situation, because it requires a direct connection between the two smartphones.

I sought to develop a modified version of the ToF method, because it offers the best precision and requires the least number of devices to work effectively. The method I developed was to send unsolicited control packets (a special type of data frame) to the target mobile device and force it to send an acknowledgement (see figure). The major research question is: how do we force the target device to send an acknowledgement even if we are not directly connected to it?

I set up a testbed with three desktops equipped with Wi-Fi cards and running Ubuntu Linux. I used Scapy (a Python program for generating network packets) to generate and send control packets from one desktop to another and tcpdump on the third desktop to monitor and analyze the wireless communication taking place. I was able to send the control packets and solicit an acknowledgment from the target mobile (Ubuntu desktop) without being directly connected to it.

However, there was a bug in the networking drivers of Ubuntu that generated acknowledgments even in cases where no acknowledgment was supposed to be sent by the target device. Currently, I am investigating the bug and trying to figure out the most suitable way forward. Through this research, I found that the process of distance estimation is more complicated than it seems. There are several variables and timing issues that need to be taken into account. In the future, I plan on finding a workaround for this bug, with the eventual goal of making this system usable in everyday life.

If you have any questions about my research or anything in general please write them in the comments below. Looking forward to hearing your views! Have a great day/night!

13 Dec 2018 5:54am GMT

pandas is a powerful, open source Python library for data analysis, manipulation, and visualization. I've been teaching data scientists to use pandas since 2014, and in the years since, it has grown in popularity to an estimated 5 to 10 million users and become a "must-use" tool in the Python data science toolkit.

I started using pandas around version 0.14.0, and I've followed the library as it has significantly matured to its current version, 0.23.4. But numerous data scientists have asked me questions like these over the years:

• "Is pandas reliable?"
• "Will it keep working in the future?"
• "Is it buggy? They haven't even released version 1.0!"

Version numbers can be used to signal the maturity of a product, and so I understand why someone might be hesitant to rely on "pre-1.0" software. But in the world of open source, version numbers don't necessarily tell you anything about the maturity or reliability of a library. (Yes, pandas is both mature and reliable!) Rather, version numbers communicate the stability of the API.

In particular, version 1.0 signals to the user: "We've figured out what the API should look like, and so API-breaking changes will only occur with major releases (2.0, 3.0, etc.)" In other words, version 1.0 marks the point at which your code should never break just by upgrading to the next minor release.

So the question remains: What's coming in pandas 1.0, and when is it coming?

Towards pandas 1.0

I recently watched a talk from PyData London called Towards pandas 1.0, given by pandas core developer Marc Garcia. It was an enlightening talk about the future of pandas, and so I wanted to highlight and comment on a few of the items that were mentioned:

• Method chaining 👍
• inplace 👎
• Apache Arrow 👍
• Extension Arrays 👍
• Other deprecations 👎
• Roadmap

If you want to follow along with the full talk slides, they can be found in this Jupyter notebook.

Method chaining 👍

The pandas core team now encourages the use of "method chaining". This is a style of programming in which you chain together multiple method calls into a single statement. This allows you to pass intermediate results from one method to the next rather than storing the intermediate results using variables.

Here's the example Marc used that does not use method chaining:

import pandas  
df = pandas.read_csv('data/titanic.csv.gz')  
df = df[df.Age < df.Age.quantile(.99)]  
df['Age'].fillna(df.Age.median(), inplace=True)  
df['Age'] = pandas.cut(df['Age'],  
                       bins=[df.Age.min(), 18, 40, df.Age.max()],
                       labels=['Underage', 'Young', 'Experienced'])
df['Sex'] = df['Sex'].replace({'female': 1, 'male': 0})  
df = df.pivot_table(values='Sex', columns='Pclass', index='Age', aggfunc='mean')  
df = df.rename_axis('', axis='columns')  
df = df.rename('Class {}'.format, axis='columns')  
df.style.format('{:.2%}')  

Here is the equivalent code that uses method chaining:

import pandas  
(pandas.read_csv('data/titanic.csv.gz')
       .query('Age < Age.quantile(.99)')
       .assign(Sex=lambda df: df['Sex'].replace({'female': 1, 'male': 0}),
               Age=lambda df: pandas.cut(df['Age'].fillna(df.Age.median()),
                                         bins=[df.Age.min(), 18, 40, df.Age.max()],
                                         labels=['Underage', 'Young', 'Experienced']))
       .pivot_table(values='Sex', columns='Pclass', index='Age', aggfunc='mean')
       .rename_axis('', axis='columns')
       .rename('Class {}'.format, axis='columns')
       .style.format('{:.2%}'))

Their primary reasons for preferring method chains are:

• readability: In their opinion, method chains are more readable.
• performance: Since the method chain tells pandas everything you want to do ahead of time, pandas can plan its operations more efficiently.

Here are my thoughts:

• I've been writing short method chains for years, and I find them to be more readable than the alternative. For example, I would never break df.isnull().sum() or ser.value_counts().sort_index() into multiple lines of code by using intermediate variables.
• However, I actually find long method chains (Marc's second example) to be less readable than the alternative, but maybe that's because I'm not used to writing them. Specifically, it's hard for me to follow the lambda functions inside the assign() method.

Tom Augspurger, another pandas core developer, also noted:

"One drawback to excessively long chains is that debugging can be harder. If something looks wrong at the end, you don't have intermediate values to inspect."

To be clear, method chaining has always been available in pandas, but support for chaining has increased through the addition of new "chain-able" methods. For example, the query() method (used in the chain above) was previously tagged as "experimental" in the documentation, which is why I haven't been using it or teaching it. That tag was removed in pandas 0.23, which may indicate that the core team is now encouraging the use of query().

I don't think you will ever be required to use method chains, but I presume that the documentation may eventually migrate to using that style.

For a longer discussion of this topic, see Tom Augspurger's Method Chaining post, which was part 2 of his Modern pandas series.

inplace 👎

The pandas core team discourages the use of the inplace parameter, and eventually it will be deprecated (which means "scheduled for removal from the library"). Here's why:

• inplace won't work within a method chain.
• The use of inplace often doesn't prevent copies from being created, contrary to what the name implies.
• Removing the inplace option would reduce the complexity of the pandas codebase.

Personally, I'm a fan of inplace and I happen to prefer writing df.reset_index(inplace=True) instead of df = df.reset_index(), for example. That being said, lots of beginners do get confused by inplace, and it's nice to have one clear way to do things in pandas, so ultimately I'd be fine with deprecation.

If you'd like to learn more about how memory is managed in pandas, I recommend watching this 5-minute section of Marc's talk.

Apache Arrow 👍

Apache Arrow is a "work in progress" to become the pandas back-end. Arrow was created in 2015 by Wes McKinney, the founder of pandas, to resolve many of the underlying limitations of the pandas DataFrame (as well as similar data structures in other languages).

The goal of Arrow is to create an open standard for representing tabular data that natively supports complex data formats and is highly optimized for performance. Although Arrow was inspired by pandas, it's designed to be a shared computational infrastructure for data science work across multiple languages.

Because Arrow is an infrastructure layer, its eventual use as the pandas back-end (likely coming after pandas 1.0) will ideally be transparent to pandas end users. However, it should result in much better performance as well as support for working with "larger-than-RAM" datasets in pandas.

For more details about Arrow, I recommend reading Wes McKinney's 2017 blog post, Apache Arrow and the "10 Things I Hate About pandas", as well as watching his talk (with slides) from SciPy 2018. For details about how Arrow will be integrated into pandas, I recommend watching Jeff Reback's talk (with slides) from PyData NYC 2017.

Extension Arrays 👍

Extension Arrays allow you to create custom data types for use with pandas. The documentation provides a nice summary:

Pandas now supports storing array-like objects that aren't necessarily 1-D NumPy arrays as columns in a DataFrame or values in a Series. This allows third-party libraries to implement extensions to NumPy's types, similar to how pandas implemented categoricals, datetimes with timezones, periods, and intervals.

In other words, previously the pandas team had to write a lot of custom code to implement data types that were not natively supported by NumPy (such as categoricals). With the release of Extension Arrays, there is now a generalized interface for creating custom types that anyone can use.

The pandas team has already used this interface to write an integer data type that supports missing values, also known as "NA" or "NaN" values. Previously, integer columns would be converted to floats if you marked any values as missing. The development documentation indicates that the "Integer NA" type will be available in the next release (version 0.24).

Another compelling use for this interface would be a native string type, since strings in pandas are currently represented using NumPy's "object" data type. The fletcher library has already used the interface to enable a native string type in pandas, though the pandas team may eventually build its own string type directly into pandas.

For a deeper look into this topic, check out the following resources:

• Extension Arrays for pandas: Blog post about the development of cyberpandas using Extension Arrays.
• Extending pandas with Custom Types: Video (with slides) about the development of the "Integer NA" type.
• Extending pandas using Apache Arrow and Numba: Video (with slides) about the development of a string type via fletcher, using Arrow for storage and Numba for better performance (as described here).

Other deprecations 👎

Here are a few other deprecations which were discussed in the talk:

• The ix accessor was already deprecated in version 0.20, in favor of loc (label-based access) and iloc (position-based access). Learn how to use loc and iloc in my video tutorial.
• The Panel data structure for 3-dimensional data was also deprecated in version 0.20, in favor of a DataFrame with a MultiIndex. Learn how to use the MultiIndex in my video tutorial.
• The SparseDataFrame, useful when a DataFrame mostly contains missing values, will be deprecated in an upcoming release.
• Python 2 support will be dropped from pandas in January 2019!

Roadmap

According to the talk, here's the roadmap to pandas 1.0:

• 0.23.4 was the most recent pandas release (August 2018).
• 0.24 is targeted for the end of 2018, according to the GitHub milestone.
• 0.25 is targeted for early 2019, and it will warn about all of the deprecations coming in 1.0.
• 1.0 will be the same as 0.25, except all the deprecated features will be removed.

More details about the roadmap are available in the pandas sprint notes from July 2018, though all of these plans are subject to change.

Learning pandas?

If you're new to pandas, I recommend watching my video tutorial series, Easier data analysis in Python with pandas.

If you're an intermediate pandas user, I recommend watching my tutorial from PyCon 2018, Best practices with pandas.

Want to know when I release new pandas tutorials? Subscribe to my email newsletter.

Let me know your thoughts or questions in the comments section below!

P.S. There is also a discussion of this post on Reddit.

12 Dec 2018 3:51pm GMT

pandas is a powerful, open source Python library for data analysis, manipulation, and visualization. I've been teaching data scientists to use pandas since 2014, and in the years since, it has grown in popularity to an estimated 5 to 10 million users and become a "must-use" tool in the Python data science toolkit.

I started using pandas around version 0.14.0, and I've followed the library as it has significantly matured to its current version, 0.23.4. But numerous data scientists have asked me questions like these over the years:

• "Is pandas reliable?"
• "Will it keep working in the future?"
• "Is it buggy? They haven't even released version 1.0!"

Version numbers can be used to signal the maturity of a product, and so I understand why someone might be hesitant to rely on "pre-1.0" software. But in the world of open source, version numbers don't necessarily tell you anything about the maturity or reliability of a library. (Yes, pandas is both mature and reliable!) Rather, version numbers communicate the stability of the API.

In particular, version 1.0 signals to the user: "We've figured out what the API should look like, and so API-breaking changes will only occur with major releases (2.0, 3.0, etc.)" In other words, version 1.0 marks the point at which your code should never break just by upgrading to the next minor release.

So the question remains: What's coming in pandas 1.0, and when is it coming?

Towards pandas 1.0

I recently watched a talk from PyData London called Towards pandas 1.0, given by pandas core developer Marc Garcia. It was an enlightening talk about the future of pandas, and so I wanted to highlight and comment on a few of the items that were mentioned:

• Method chaining 👍
• inplace 👎
• Apache Arrow 👍
• Extension Arrays 👍
• Other deprecations 👎
• Roadmap

If you want to follow along with the full talk slides, they can be found in this Jupyter notebook.

Method chaining 👍

The pandas core team now encourages the use of "method chaining". This is a style of programming in which you chain together multiple method calls into a single statement. This allows you to pass intermediate results from one method to the next rather than storing the intermediate results using variables.

Here's the example Marc used that does not use method chaining:

import pandas  
df = pandas.read_csv('data/titanic.csv.gz')  
df = df[df.Age < df.Age.quantile(.99)]  
df['Age'].fillna(df.Age.median(), inplace=True)  
df['Age'] = pandas.cut(df['Age'],  
                       bins=[df.Age.min(), 18, 40, df.Age.max()],
                       labels=['Underage', 'Young', 'Experienced'])
df['Sex'] = df['Sex'].replace({'female': 1, 'male': 0})  
df = df.pivot_table(values='Sex', columns='Pclass', index='Age', aggfunc='mean')  
df = df.rename_axis('', axis='columns')  
df = df.rename('Class {}'.format, axis='columns')  
df.style.format('{:.2%}')  

Here is the equivalent code that uses method chaining:

import pandas  
(pandas.read_csv('data/titanic.csv.gz')
       .query('Age < Age.quantile(.99)')
       .assign(Sex=lambda df: df['Sex'].replace({'female': 1, 'male': 0}),
               Age=lambda df: pandas.cut(df['Age'].fillna(df.Age.median()),
                                         bins=[df.Age.min(), 18, 40, df.Age.max()],
                                         labels=['Underage', 'Young', 'Experienced']))
       .pivot_table(values='Sex', columns='Pclass', index='Age', aggfunc='mean')
       .rename_axis('', axis='columns')
       .rename('Class {}'.format, axis='columns')
       .style.format('{:.2%}'))

Their primary reasons for preferring method chains are:

• readability: In their opinion, method chains are more readable.
• performance: Since the method chain tells pandas everything you want to do ahead of time, pandas can plan its operations more efficiently.

Here are my thoughts:

• I've been writing short method chains for years, and I find them to be more readable than the alternative. For example, I would never break df.isnull().sum() or ser.value_counts().sort_index() into multiple lines of code by using intermediate variables.
• However, I actually find long method chains (Marc's second example) to be less readable than the alternative, but maybe that's because I'm not used to writing them. Specifically, it's hard for me to follow the lambda functions inside the assign() method.

Tom Augspurger, another pandas core developer, also noted:

"One drawback to excessively long chains is that debugging can be harder. If something looks wrong at the end, you don't have intermediate values to inspect."

To be clear, method chaining has always been available in pandas, but support for chaining has increased through the addition of new "chain-able" methods. For example, the query() method (used in the chain above) was previously tagged as "experimental" in the documentation, which is why I haven't been using it or teaching it. That tag was removed in pandas 0.23, which may indicate that the core team is now encouraging the use of query().

I don't think you will ever be required to use method chains, but I presume that the documentation may eventually migrate to using that style.

For a longer discussion of this topic, see Tom Augspurger's Method Chaining post, which was part 2 of his Modern pandas series.

inplace 👎

The pandas core team discourages the use of the inplace parameter, and eventually it will be deprecated (which means "scheduled for removal from the library"). Here's why:

• inplace won't work within a method chain.
• The use of inplace often doesn't prevent copies from being created, contrary to what the name implies.
• Removing the inplace option would reduce the complexity of the pandas codebase.

Personally, I'm a fan of inplace and I happen to prefer writing df.reset_index(inplace=True) instead of df = df.reset_index(), for example. That being said, lots of beginners do get confused by inplace, and it's nice to have one clear way to do things in pandas, so ultimately I'd be fine with deprecation.

If you'd like to learn more about how memory is managed in pandas, I recommend watching this 5-minute section of Marc's talk.

Apache Arrow 👍

Apache Arrow is a "work in progress" to become the pandas back-end. Arrow was created in 2015 by Wes McKinney, the founder of pandas, to resolve many of the underlying limitations of the pandas DataFrame (as well as similar data structures in other languages).

The goal of Arrow is to create an open standard for representing tabular data that natively supports complex data formats and is highly optimized for performance. Although Arrow was inspired by pandas, it's designed to be a shared computational infrastructure for data science work across multiple languages.

Because Arrow is an infrastructure layer, its eventual use as the pandas back-end (likely coming after pandas 1.0) will ideally be transparent to pandas end users. However, it should result in much better performance as well as support for working with "larger-than-RAM" datasets in pandas.

For more details about Arrow, I recommend reading Wes McKinney's 2017 blog post, Apache Arrow and the "10 Things I Hate About pandas", as well as watching his talk (with slides) from SciPy 2018. For details about how Arrow will be integrated into pandas, I recommend watching Jeff Reback's talk (with slides) from PyData NYC 2017.

Extension Arrays 👍

Extension Arrays allow you to create custom data types for use with pandas. The documentation provides a nice summary:

Pandas now supports storing array-like objects that aren't necessarily 1-D NumPy arrays as columns in a DataFrame or values in a Series. This allows third-party libraries to implement extensions to NumPy's types, similar to how pandas implemented categoricals, datetimes with timezones, periods, and intervals.

In other words, previously the pandas team had to write a lot of custom code to implement data types that were not natively supported by NumPy (such as categoricals). With the release of Extension Arrays, there is now a generalized interface for creating custom types that anyone can use.

The pandas team has already used this interface to write an integer data type that supports missing values, also known as "NA" or "NaN" values. Previously, integer columns would be converted to floats if you marked any values as missing. The development documentation indicates that the "Integer NA" type will be available in the next release (version 0.24).

Another compelling use for this interface would be a native string type, since strings in pandas are currently represented using NumPy's "object" data type. The fletcher library has already used the interface to enable a native string type in pandas, though the pandas team may eventually build its own string type directly into pandas.

For a deeper look into this topic, check out the following resources:

• Extension Arrays for pandas: Blog post about the development of cyberpandas using Extension Arrays.
• Extending pandas with Custom Types: Video (with slides) about the development of the "Integer NA" type.
• Extending pandas using Apache Arrow and Numba: Video (with slides) about the development of a string type via fletcher, using Arrow for storage and Numba for better performance (as described here).

Other deprecations 👎

Here are a few other deprecations which were discussed in the talk:

• The ix accessor was already deprecated in version 0.20, in favor of loc (label-based access) and iloc (position-based access). Learn how to use loc and iloc in my video tutorial.
• The Panel data structure for 3-dimensional data was also deprecated in version 0.20, in favor of a DataFrame with a MultiIndex. Learn how to use the MultiIndex in my video tutorial.
• The SparseDataFrame, useful when a DataFrame mostly contains missing values, will be deprecated in an upcoming release.
• Python 2 support will be dropped from pandas in January 2019!

Roadmap

According to the talk, here's the roadmap to pandas 1.0:

• 0.23.4 was the most recent pandas release (August 2018).
• 0.24 is targeted for the end of 2018, according to the GitHub milestone.
• 0.25 is targeted for early 2019, and it will warn about all of the deprecations coming in 1.0.
• 1.0 will be the same as 0.25, except all the deprecated features will be removed.

More details about the roadmap are available in the pandas sprint notes from July 2018, though all of these plans are subject to change.

Learning pandas?

If you're new to pandas, I recommend watching my video tutorial series, Easier data analysis in Python with pandas.

If you're an intermediate pandas user, I recommend watching my tutorial from PyCon 2018, Best practices with pandas.

Want to know when I release new pandas tutorials? Subscribe to my email newsletter.

Let me know your thoughts or questions in the comments section below!

P.S. There is also a discussion of this post on Reddit.

12 Dec 2018 3:51pm GMT

Are you a Python beginner looking for a tool that can support your learning? This article is for you! Every programmer needs a place to write their code. This article will discuss an awesome tool called Thonny that will enable you to start working with Python in a beginner-friendly environment.

In this article, you'll learn:

• How to install Thonny on your computer
• How to navigate Thonny's user interface to use its built-in features
• How to use Thonny to write and run your code
• How to use Thonny to debug your code

By the end of this article, you'll be comfortable with the development workflow in Thonny and ready to use it for your Python learning.

So what is Thonny? Great question!

Thonny is a free Python Integrated Development Environment (IDE) that was especially designed with the beginner Pythonista in mind. Specifically, it has a built-in debugger that can help when you run into nasty bugs, and it offers the ability to do step through expression evaluation, among other really awesome features.

Installing Thonny

This article assumes that you have Python 3 installed on your computer. If not, please review Python 3 Installation & Setup.

Web Download

The web download can be accessed via a web browser by visiting the Thonny website. Once on the page, you will see a light gray box in the top right corner like this:

Once you've found the gray box, click the appropriate link for your operating system. This tutorial assumes you've downloaded version 3.0.1.

Command Line Download

You can also install Thonny via your system's command line. On Windows, you can do this by starting a program called Command Prompt, while on macOS and Linux you start a program called Terminal. Once you've done that, enter the following command:

$ pip install thonny

The User Interface

Let's make sure you understand what Thonny has to offer. Think of Thonny as the workroom in which you will create amazing Python projects. Your workroom contains a toolbox containing many tools that will enable you to be a rock star Pythonista. In this section, you'll learn about each of the features of the UI that'll help you use each of the tools in your Thonny toolbox.

The Code Editor and Shell

Now that you have Thonny installed, open the application. You should see a window with several icons across the top, and two white areas:

Notice the two main sections of the window. The top section is your code editor, where you will write all of your code. The bottom half is your Shell, where you will see outputs from your code.

The Icons

Across the top you'll see several icons. Let's explore what each of them does. You'll see an image of the icons below, with a letter above each one. We will use these letters to talk about each of the icons:

Working our way from left to right, below is a description of each of the icons in the image.

A: The paper icon allows you to create a new file. Typically in Python you want to separate your programs into separate files. You'll use this button later in the tutorial to create your first program in Thonny!

B: The open folder icon allows you to open a file that already exists on your computer. This might be useful if you come back to a program that you worked on previously.

C: The floppy disk icon allows you to save your code. Press this early and often. You'll use this later to save your first Thonny Python program.

D: The play icon allows you to run your code. Remember that the code you write is meant to be executed. Running your code means you're telling Python, "Do what I told you to do!" (In other words, "Read through my code and execute what I wrote.")

E: The bug icon allows you to debug your code. It's inevitable that you will encounter bugs when you're writing code. A bug is another word for a problem. Bugs can come in many forms, sometimes appearing when you use inappropriate syntax and sometimes when your logic is incorrect.

Thonny's bug button is typically used to spot and investigate bugs. You'll work with this later in the tutorial. By the way, if you're wondering why they're called bugs, there's also a fun story of how it came about!

F-H: The arrow icons allow you to run your programs step by step. This can be very useful when you're debugging or, in other words, trying to find those nasty bugs in your code. These icons are used after you press the bug icon. You'll notice as you hit each arrow, a yellow highlighted bar will indicate which line or section Python is currently evaluating:

• The F arrow tells Python to take a big step, meaning jumping to the next line or block of code.
• The G arrow tells Python to take a small step, meaning diving deep into each component of an expression.
• The H arrow tells Python to exit out of the debugger.

I: The resume icon allows you to return to play mode from debug mode. This is useful in the instance when you no longer want to go step by step through the code, and instead want your program to finish running.

J: The stop icon allows you to stop running your code. This can be particularly useful if, let's say, your code runs a program that opens a new window, and you want to stop that program. You'll use the stop icon later in the tutorial.

Let's Try It!

Get ready to write your first official Python program in Thonny:

1. Enter the following code into the code editor:

   print("Hello World")
   

2. Click the play button to run your program.

3. See the output in the Shell window.

4. Click the play button again to see that it says hello one more time.

Congratulations! You've now completed your first program in Thonny! You should see Hello world! printed inside the Shell, also known as the console. This is because your program told Python to print this phrase, and the console is where you see the output of this execution.

Other UI Features

To see more of the other features that Thonny has to offer, navigate to the menu bar and select the View dropdown. You should see that Shell has a check mark next to it, which is why you see the Shell section in Thonny's application window:

Let's explore some of the other offerings, specifically those that will be useful to a beginning Pythonista:

1. Help: You'll select the Help view if you want more information about working with Thonny. Currently this section offers more reading on the following topics: Running Programs Step-wise, how to install 3rd Party Packages, or using Scientific Python Packages.

2. Variables: This feature can be very valuable. A variable in Python is a value that you define in code. Variables can be numbers, strings, or other complex data structures. This section allows you to see the values assigned to all of the variables in your program.

3. Assistant: The Assistant is there to give you helpful hints when you hit Exceptions or other types of errors.

The other features will become useful as you advance your skills. Check them out once you get more comfortable with Thonny!

The Code Editor

Now that you have an understanding of the UI, let's use Thonny to write another little program. In this section, you'll go through the features of Thonny that will help guide you through your development workflow.

Write Some Code

In the code editor (top portion of the UI), add the following function:

def factorial(num):
    if num == 1:
        return 1
    else:
        return num * factorial(num - 1)

print(factorial(3))

Save Your Code

Before we move on, let's save your program. Last time, you were prompted to do this after pressing the play button. You can also do this by clicking the blue floppy disk icon or by going to the menu bar and selecting File > Save. Let's call the program factorial.py.

Run Your Code

In order to run your code, find and press the play icon. The output should look like this:

Debug Your Code

To truly understand what this function is doing, try the step feature. Take a few large and small steps through the function to see what is happening. Remember you can do this by pressing the arrow icons:

As you can see, the steps will show how the computer is evaluating each part of the code. Each pop up window is like a piece of scratch paper that the computer is using to compute each portion of the code. Without this awesome feature, this may have been hard to conceptualize-but now you've got it!

Stop Running Your Code

So far, there hasn't been a need to hit the stop icon for this program, particularly because it exits as soon as it has executed print(). Try increasing the number being passed to the factorial function to 100:

def factorial(num):
    if num == 1:
        return 1
    else:
        return num * factorial(num - 1)

print(factorial(100))

Then step through the function. After a while, you will notice that you will be clicking for a long time to reach the end. This is a good time to use the stop button. The stop button can be really useful to stop a program that is either intentionally or unintentionally running continuously.

Find Syntax Errors in Your Code

Now that you have a simple program that works, let's break it! By intentionally creating an error in your factorial program, you'll be able to see how Thonny handles these types of issues.

We will be creating what is called a syntax error. A syntax error is an error that indicates that your code is syntactically incorrect. In other words, your code does not follow the proper way to write Python. When Python notices the error, it will display a syntax error to complain about your invalid code.

Above the print statement, let's add another print statement that says print("The factorial of 100 is:"). Now let's go ahead and create syntax errors. In the first print statement, remove the second quotation mark, and in the other remove the second parenthesis.

As you do this, you should see that Thonny will highlight your SyntaxErrors. Missing quotations are highlighted in green, and missing parenthesis are in gray:

For beginners, this is a great resource that will allow you to help spot any typos while you're writing. Some of the most common and frustrating errors when you start programming are missing quotes and mismatched parentheses.

If you have your Assistant View turned on, you will also notice that it will give you a helpful message to guide you in the right direction when you are debugging:

As you get more comfortable with Thonny, the Assistant can be a useful tool to help you get unstuck!

The Package Manager

As you continue to learn Python, it can be quite useful to download a Python package to use inside of your code. This allows you to use code that someone else has written inside of your program.

Consider an example where you want to do some calculations in your code. Instead of writing your own calculator, you might want to use a third-party package called simplecalculator. In order to do this, you'll use Thonny's package manager.

The package manager will allow you to install packages that you will need to use with your program. Specifically, it allows you to add more tools to your toolbox. Thonny has the built-in benefit of handling any conflicts with other Python interpreters.

To access the package manager, go to the menu bar and select Tools > Manage Packages… This should pop open a new window with a search field. Type simplecalculator into that field and click the Search button.

The output should look similar to this:

Go ahead and click Install to install this package. You will see a small window pop up showing the system's logs while it installs the package. Once it completes, you are ready to use simplecalculator in your code!

In the next section, you will use the simplecalculator package along with some of the other skills you've learned in this tutorial to create a simple calculator program.

Check Your Understanding

You've learned so much about Thonny so far! Here's what you've learned:

• Where to write your code
• How to save your code
• How to run your code
• How to stop your code from running
• Where to see your code execute
• How to spot SyntaxErrors
• How to install third party packages

Let's check your understanding of these concepts.

Now that you have simplecalculator installed, let's create a simple program that will use this package. You'll also use this as an opportunity to check that you understand some of the UI and development features that you've learned thus far in the tutorial.

Part 1: Create a File, Add Some Code, and Understand the Code

In Part 1, you will create a file, and add some code to it! Do your best to try to dig into what the code is actually doing. If you get stuck, check out the Take a Deeper Look window. Let's get started:

1. Start a new file.
2. Add the following code into your Thonny code editor:

 1 from calculator.simple import SimpleCalculator
 2 
 3 my_calculator = SimpleCalculator()  
 4 my_calculator.run('2 * 2')
 5 print(my_calculator.lcd)

This code will print out the result of 2 * 2 to the Thonny Shell in the main UI. To understand what each part of the code is doing, check out the Take a Deeper Look section below.

Great! Now that you know exactly what your calculator code is doing, let's move on to running this code!

Part 2: Save the File, View the Variables, and Run Your Code

Now it's time to save and run your code. In this section, you'll make use of two of the icons we reviewed earlier:

1. Save your new file as calculations.py.
2. Open the Variables window and make note of the two variables listed. You should see SimpleCalculator and my_calculator. This section also gives you insight into the value that each variable is pointing to.
3. Run your code! You should see 4.0 in the output:

Great job! Next you'll explore how Thonny's debugger can help you to better understand this code.

Other Great Beginner Features

As you get more comfortable with Thonny, the features in this section will come in quite handy.

Debugging

Using your calculations.py script, you're going to use the debugger to investigate what is happening. Update your code in calculations.py to the following:

from calculator.simple import SimpleCalculator

def create_add_string(x, y):
    '''Returns a string containing an addition expression.'''
    return 'x + y'

my_calculator = SimpleCalculator()  
my_calculator.run(create_add_string(2, 2))
print(my_calculator.lcd)

Hit the save icon to save this version.

You'll notice the code has a new function called create_add_string(). If you're unfamiliar with Python functions, learn more in this awesome Real Python course!

As you inspect the function, you may notice why this script will not work as expected. If not, that's okay! Thonny is going to help you see exactly what is going on, and squash that bug! Go ahead and run your program and see what happens. The Shell output should be the following:

>>> %Run calculations.py
0

Oh no! Now you can see there is a bug in your program. The answer should be 4! Next, you'll use Thonny's debugger to find the bug.

Let's Try It!

Now that we have a bug in our program, this is a great chance to use Thonny's debugging features:

1. Click the bug icon at the top of the window. This enters debugger mode.

2. You should see the import statements highlighted. Click the small step arrow icon, the yellow arrow in the middle. Keep pressing this to see how the debugger works. You should notice that it highlights each step that Python takes to evaluate your program. Once it hits create_add_string(), you should see a new window pop up.

3. Examine the pop up window carefully. You should see that it shows the values for x and y. Keep pressing the small step icon until you see the value that Python will return to your program. It will be enclosed in a light-blue box: Oh no! There's the bug! It looks like Python will return a string containing the letters x and y (meaning 'x + y' and not a string containing the values of those variables, like '2 + 2', which is what the calculator is expecting.) Each time you see a light-blue box, you can think of this as Python replacing subexpressions with their values, step by step. The pop up window can be thought of as a piece of scratch paper that Python uses to figure out those values. Continue to step through the program to see how this bug results in a calculation of 0.

4. The bug here has to do with string formatting. If you are unfamiliar with string formatting, check out this article on Python String Formatting Best Practices. Inside create_add_string(), the f-string formatting method should be used. Update this function to the following:

   def create_add_string(x, y):
       '''Returns a string containing an addition expression.'''
       return f'{x} + {y}'
   

5. Run your program again. You should see the following output:

   >>> %Run calculations.py
   4.0
   

Success! You have just demonstrated how the step-by-step debugger can help you find a problem in your code! Next you'll learn about some other fun Thonny features.

Variable Scope Highlighting

Thonny offers variable highlighting to remind you that the same name doesn't always mean the same variable. In order for this feature to work, on the menu bar, go to Thonny > Preferences and ensure that Highlight matching names is checked.

Notice in the code snippet below, that create_add_string() now has a new variable called my_calculator, though this is not the same as the my_calculator on lines 10 and 11. You should be able to tell because Thonny highlights the variables that reference the same thing. This my_calculator inside the function only exists within the scope of that function, which is why it is not highlighted when the cursor is on the other my_calculator variable on line 10:

This feature can really help you avoid typos and understand the scope of your variables.

Code Completion

Thonny also offers code completion for APIs. Notice in the snapshot below how pressing the Tab key shows the methods available from the random library:

This can be very useful when you're working with libraries and don't want to look at the documentation to find a method or attribute name.

Working on a Pre-Existing Project

Now that you've learned the basic features of Thonny, let's explore how you can use it to work on a pre-existing project.

Find a File on Your Computer

Opening a file on your computer is as easy as going to the menu bar, selecting File > Open, and using your browser to navigate to the file. You can also use the open folder icon at the top of the screen to do this as well.

If you have a requirements.txt file and pip locally installed, you can pip install these from the Thonny system Shell. If you don't have pip installed, remember you can use the Package Manager to install it:

$ pip install -r requirements.txt

Work on a Project From Github

Now that you are a Thonny expert, you can use it to work on the exercises from Real Python Course 1: Introduction to Python:

1. Navigate to the Real Python GitHub repo called book1-exercises.

2. Click the green button labeled Clone or download and select Download Zip.

3. Click the opening folder icon to navigate and find the downloaded files. You should find a folder called book1-exercises1.

4. Open one of the files and start working!

This is useful because there are tons of cool projects available on GitHub!

Conclusion

Awesome job getting through this tutorial on Thonny!

You can now start using Thonny to write, debug, and run Python code! If you like Thonny, you might also like some of the other IDEs we've listed in Python IDEs and Code Editors (Guide).

Thonny is actively maintained, and new features are being added all the time. There are several awesome new features that are currently in beta that can be found on the Thonny Blog. Thonny's main development takes place at the Institute of Computer Science of the University of Tartu, Estonia, as well as by contributors around the world.

[ Improve Your Python With 🐍 Python Tricks 💌 - Get a short & sweet Python Trick delivered to your inbox every couple of days. >> Click here to learn more and see examples ]

12 Dec 2018 2:00pm GMT

Are you a Python beginner looking for a tool that can support your learning? This article is for you! Every programmer needs a place to write their code. This article will discuss an awesome tool called Thonny that will enable you to start working with Python in a beginner-friendly environment.

In this article, you'll learn:

• How to install Thonny on your computer
• How to navigate Thonny's user interface to use its built-in features
• How to use Thonny to write and run your code
• How to use Thonny to debug your code

By the end of this article, you'll be comfortable with the development workflow in Thonny and ready to use it for your Python learning.

So what is Thonny? Great question!

Thonny is a free Python Integrated Development Environment (IDE) that was especially designed with the beginner Pythonista in mind. Specifically, it has a built-in debugger that can help when you run into nasty bugs, and it offers the ability to do step through expression evaluation, among other really awesome features.

Installing Thonny

This article assumes that you have Python 3 installed on your computer. If not, please review Python 3 Installation & Setup.

Web Download

The web download can be accessed via a web browser by visiting the Thonny website. Once on the page, you will see a light gray box in the top right corner like this:

Once you've found the gray box, click the appropriate link for your operating system. This tutorial assumes you've downloaded version 3.0.1.

Command Line Download

You can also install Thonny via your system's command line. On Windows, you can do this by starting a program called Command Prompt, while on macOS and Linux you start a program called Terminal. Once you've done that, enter the following command:

$ pip install thonny

The User Interface

Let's make sure you understand what Thonny has to offer. Think of Thonny as the workroom in which you will create amazing Python projects. Your workroom contains a toolbox containing many tools that will enable you to be a rock star Pythonista. In this section, you'll learn about each of the features of the UI that'll help you use each of the tools in your Thonny toolbox.

The Code Editor and Shell

Now that you have Thonny installed, open the application. You should see a window with several icons across the top, and two white areas:

Notice the two main sections of the window. The top section is your code editor, where you will write all of your code. The bottom half is your Shell, where you will see outputs from your code.

The Icons

Across the top you'll see several icons. Let's explore what each of them does. You'll see an image of the icons below, with a letter above each one. We will use these letters to talk about each of the icons:

Working our way from left to right, below is a description of each of the icons in the image.

A: The paper icon allows you to create a new file. Typically in Python you want to separate your programs into separate files. You'll use this button later in the tutorial to create your first program in Thonny!

B: The open folder icon allows you to open a file that already exists on your computer. This might be useful if you come back to a program that you worked on previously.

C: The floppy disk icon allows you to save your code. Press this early and often. You'll use this later to save your first Thonny Python program.

D: The play icon allows you to run your code. Remember that the code you write is meant to be executed. Running your code means you're telling Python, "Do what I told you to do!" (In other words, "Read through my code and execute what I wrote.")

E: The bug icon allows you to debug your code. It's inevitable that you will encounter bugs when you're writing code. A bug is another word for a problem. Bugs can come in many forms, sometimes appearing when you use inappropriate syntax and sometimes when your logic is incorrect.

Thonny's bug button is typically used to spot and investigate bugs. You'll work with this later in the tutorial. By the way, if you're wondering why they're called bugs, there's also a fun story of how it came about!

F-H: The arrow icons allow you to run your programs step by step. This can be very useful when you're debugging or, in other words, trying to find those nasty bugs in your code. These icons are used after you press the bug icon. You'll notice as you hit each arrow, a yellow highlighted bar will indicate which line or section Python is currently evaluating:

• The F arrow tells Python to take a big step, meaning jumping to the next line or block of code.
• The G arrow tells Python to take a small step, meaning diving deep into each component of an expression.
• The H arrow tells Python to exit out of the debugger.

I: The resume icon allows you to return to play mode from debug mode. This is useful in the instance when you no longer want to go step by step through the code, and instead want your program to finish running.

J: The stop icon allows you to stop running your code. This can be particularly useful if, let's say, your code runs a program that opens a new window, and you want to stop that program. You'll use the stop icon later in the tutorial.

Let's Try It!

Get ready to write your first official Python program in Thonny:

1. Enter the following code into the code editor:

   print("Hello World")
   

2. Click the play button to run your program.

3. See the output in the Shell window.

4. Click the play button again to see that it says hello one more time.

Congratulations! You've now completed your first program in Thonny! You should see Hello world! printed inside the Shell, also known as the console. This is because your program told Python to print this phrase, and the console is where you see the output of this execution.

Other UI Features

To see more of the other features that Thonny has to offer, navigate to the menu bar and select the View dropdown. You should see that Shell has a check mark next to it, which is why you see the Shell section in Thonny's application window:

Let's explore some of the other offerings, specifically those that will be useful to a beginning Pythonista:

1. Help: You'll select the Help view if you want more information about working with Thonny. Currently this section offers more reading on the following topics: Running Programs Step-wise, how to install 3rd Party Packages, or using Scientific Python Packages.

2. Variables: This feature can be very valuable. A variable in Python is a value that you define in code. Variables can be numbers, strings, or other complex data structures. This section allows you to see the values assigned to all of the variables in your program.

3. Assistant: The Assistant is there to give you helpful hints when you hit Exceptions or other types of errors.

The other features will become useful as you advance your skills. Check them out once you get more comfortable with Thonny!

The Code Editor

Now that you have an understanding of the UI, let's use Thonny to write another little program. In this section, you'll go through the features of Thonny that will help guide you through your development workflow.

Write Some Code

In the code editor (top portion of the UI), add the following function:

def factorial(num):
    if num == 1:
        return 1
    else:
        return num * factorial(num - 1)

print(factorial(3))

Save Your Code

Before we move on, let's save your program. Last time, you were prompted to do this after pressing the play button. You can also do this by clicking the blue floppy disk icon or by going to the menu bar and selecting File > Save. Let's call the program factorial.py.

Run Your Code

In order to run your code, find and press the play icon. The output should look like this:

Debug Your Code

To truly understand what this function is doing, try the step feature. Take a few large and small steps through the function to see what is happening. Remember you can do this by pressing the arrow icons:

As you can see, the steps will show how the computer is evaluating each part of the code. Each pop up window is like a piece of scratch paper that the computer is using to compute each portion of the code. Without this awesome feature, this may have been hard to conceptualize-but now you've got it!

Stop Running Your Code

So far, there hasn't been a need to hit the stop icon for this program, particularly because it exits as soon as it has executed print(). Try increasing the number being passed to the factorial function to 100:

def factorial(num):
    if num == 1:
        return 1
    else:
        return num * factorial(num - 1)

print(factorial(100))

Then step through the function. After a while, you will notice that you will be clicking for a long time to reach the end. This is a good time to use the stop button. The stop button can be really useful to stop a program that is either intentionally or unintentionally running continuously.

Find Syntax Errors in Your Code

Now that you have a simple program that works, let's break it! By intentionally creating an error in your factorial program, you'll be able to see how Thonny handles these types of issues.

We will be creating what is called a syntax error. A syntax error is an error that indicates that your code is syntactically incorrect. In other words, your code does not follow the proper way to write Python. When Python notices the error, it will display a syntax error to complain about your invalid code.

Above the print statement, let's add another print statement that says print("The factorial of 100 is:"). Now let's go ahead and create syntax errors. In the first print statement, remove the second quotation mark, and in the other remove the second parenthesis.

As you do this, you should see that Thonny will highlight your SyntaxErrors. Missing quotations are highlighted in green, and missing parenthesis are in gray:

For beginners, this is a great resource that will allow you to help spot any typos while you're writing. Some of the most common and frustrating errors when you start programming are missing quotes and mismatched parentheses.

If you have your Assistant View turned on, you will also notice that it will give you a helpful message to guide you in the right direction when you are debugging:

As you get more comfortable with Thonny, the Assistant can be a useful tool to help you get unstuck!

The Package Manager

As you continue to learn Python, it can be quite useful to download a Python package to use inside of your code. This allows you to use code that someone else has written inside of your program.

Consider an example where you want to do some calculations in your code. Instead of writing your own calculator, you might want to use a third-party package called simplecalculator. In order to do this, you'll use Thonny's package manager.

The package manager will allow you to install packages that you will need to use with your program. Specifically, it allows you to add more tools to your toolbox. Thonny has the built-in benefit of handling any conflicts with other Python interpreters.

To access the package manager, go to the menu bar and select Tools > Manage Packages… This should pop open a new window with a search field. Type simplecalculator into that field and click the Search button.

The output should look similar to this:

Go ahead and click Install to install this package. You will see a small window pop up showing the system's logs while it installs the package. Once it completes, you are ready to use simplecalculator in your code!

In the next section, you will use the simplecalculator package along with some of the other skills you've learned in this tutorial to create a simple calculator program.

Check Your Understanding

You've learned so much about Thonny so far! Here's what you've learned:

• Where to write your code
• How to save your code
• How to run your code
• How to stop your code from running
• Where to see your code execute
• How to spot SyntaxErrors
• How to install third party packages

Let's check your understanding of these concepts.

Now that you have simplecalculator installed, let's create a simple program that will use this package. You'll also use this as an opportunity to check that you understand some of the UI and development features that you've learned thus far in the tutorial.

Part 1: Create a File, Add Some Code, and Understand the Code

In Part 1, you will create a file, and add some code to it! Do your best to try to dig into what the code is actually doing. If you get stuck, check out the Take a Deeper Look window. Let's get started:

1. Start a new file.
2. Add the following code into your Thonny code editor:

 1 from calculator.simple import SimpleCalculator
 2 
 3 my_calculator = SimpleCalculator()  
 4 my_calculator.run('2 * 2')
 5 print(my_calculator.lcd)

This code will print out the result of 2 * 2 to the Thonny Shell in the main UI. To understand what each part of the code is doing, check out the Take a Deeper Look section below.

Great! Now that you know exactly what your calculator code is doing, let's move on to running this code!

Part 2: Save the File, View the Variables, and Run Your Code

Now it's time to save and run your code. In this section, you'll make use of two of the icons we reviewed earlier:

1. Save your new file as calculations.py.
2. Open the Variables window and make note of the two variables listed. You should see SimpleCalculator and my_calculator. This section also gives you insight into the value that each variable is pointing to.
3. Run your code! You should see 4.0 in the output:

Great job! Next you'll explore how Thonny's debugger can help you to better understand this code.

Other Great Beginner Features

As you get more comfortable with Thonny, the features in this section will come in quite handy.

Debugging

Using your calculations.py script, you're going to use the debugger to investigate what is happening. Update your code in calculations.py to the following:

from calculator.simple import SimpleCalculator

def create_add_string(x, y):
    '''Returns a string containing an addition expression.'''
    return 'x + y'

my_calculator = SimpleCalculator()  
my_calculator.run(create_add_string(2, 2))
print(my_calculator.lcd)

Hit the save icon to save this version.

You'll notice the code has a new function called create_add_string(). If you're unfamiliar with Python functions, learn more in this awesome Real Python course!

As you inspect the function, you may notice why this script will not work as expected. If not, that's okay! Thonny is going to help you see exactly what is going on, and squash that bug! Go ahead and run your program and see what happens. The Shell output should be the following:

>>> %Run calculations.py
0

Oh no! Now you can see there is a bug in your program. The answer should be 4! Next, you'll use Thonny's debugger to find the bug.

Let's Try It!

Now that we have a bug in our program, this is a great chance to use Thonny's debugging features:

1. Click the bug icon at the top of the window. This enters debugger mode.

2. You should see the import statements highlighted. Click the small step arrow icon, the yellow arrow in the middle. Keep pressing this to see how the debugger works. You should notice that it highlights each step that Python takes to evaluate your program. Once it hits create_add_string(), you should see a new window pop up.

3. Examine the pop up window carefully. You should see that it shows the values for x and y. Keep pressing the small step icon until you see the value that Python will return to your program. It will be enclosed in a light-blue box: Oh no! There's the bug! It looks like Python will return a string containing the letters x and y (meaning 'x + y' and not a string containing the values of those variables, like '2 + 2', which is what the calculator is expecting.) Each time you see a light-blue box, you can think of this as Python replacing subexpressions with their values, step by step. The pop up window can be thought of as a piece of scratch paper that Python uses to figure out those values. Continue to step through the program to see how this bug results in a calculation of 0.

4. The bug here has to do with string formatting. If you are unfamiliar with string formatting, check out this article on Python String Formatting Best Practices. Inside create_add_string(), the f-string formatting method should be used. Update this function to the following:

   def create_add_string(x, y):
       '''Returns a string containing an addition expression.'''
       return f'{x} + {y}'
   

5. Run your program again. You should see the following output:

   >>> %Run calculations.py
   4.0
   

Success! You have just demonstrated how the step-by-step debugger can help you find a problem in your code! Next you'll learn about some other fun Thonny features.

Variable Scope Highlighting

Thonny offers variable highlighting to remind you that the same name doesn't always mean the same variable. In order for this feature to work, on the menu bar, go to Thonny > Preferences and ensure that Highlight matching names is checked.

Notice in the code snippet below, that create_add_string() now has a new variable called my_calculator, though this is not the same as the my_calculator on lines 10 and 11. You should be able to tell because Thonny highlights the variables that reference the same thing. This my_calculator inside the function only exists within the scope of that function, which is why it is not highlighted when the cursor is on the other my_calculator variable on line 10:

This feature can really help you avoid typos and understand the scope of your variables.

Code Completion

Thonny also offers code completion for APIs. Notice in the snapshot below how pressing the Tab key shows the methods available from the random library:

This can be very useful when you're working with libraries and don't want to look at the documentation to find a method or attribute name.

Working on a Pre-Existing Project

Now that you've learned the basic features of Thonny, let's explore how you can use it to work on a pre-existing project.

Find a File on Your Computer

Opening a file on your computer is as easy as going to the menu bar, selecting File > Open, and using your browser to navigate to the file. You can also use the open folder icon at the top of the screen to do this as well.

If you have a requirements.txt file and pip locally installed, you can pip install these from the Thonny system Shell. If you don't have pip installed, remember you can use the Package Manager to install it:

$ pip install -r requirements.txt

Work on a Project From Github

Now that you are a Thonny expert, you can use it to work on the exercises from Real Python Course 1: Introduction to Python:

1. Navigate to the Real Python GitHub repo called book1-exercises.

2. Click the green button labeled Clone or download and select Download Zip.

3. Click the opening folder icon to navigate and find the downloaded files. You should find a folder called book1-exercises1.

4. Open one of the files and start working!

This is useful because there are tons of cool projects available on GitHub!

Conclusion

Awesome job getting through this tutorial on Thonny!

You can now start using Thonny to write, debug, and run Python code! If you like Thonny, you might also like some of the other IDEs we've listed in Python IDEs and Code Editors (Guide).

Thonny is actively maintained, and new features are being added all the time. There are several awesome new features that are currently in beta that can be found on the Thonny Blog. Thonny's main development takes place at the Institute of Computer Science of the University of Tartu, Estonia, as well as by contributors around the world.

[ Improve Your Python With 🐍 Python Tricks 💌 - Get a short & sweet Python Trick delivered to your inbox every couple of days. >> Click here to learn more and see examples ]

12 Dec 2018 2:00pm GMT

I am glad to inform you all that the remove duplicate file project written with python has finally completed and now it will be uploaded to github for you all to enjoy. This is a free software and it will always remain free. Although I would really love to create a linux version of this remove duplicate file software but because I do not have a linux os's computer therefore at the moment this software is just for the windows user only. I have packed this software up where you can just click on it to open it up to search and destroy the duplicate files inside your computer. Here are the steps you need to do to search and destroy the duplicate files:

1. Open up the application on your windows desktop.
2. Click on the select file button to select a file or use shift and select many files at once.
   
3. Select the other folder which you want this program to search and destroy all the duplicate files from, then sit back and enjoy.
4. This program will search all the files within that selected folder but make sure you are not selecting the same folder which you have selected the original file from.
5. You can select multiple files at the same time and you can also select another file which you want to remove it's duplicate version from after you have selected the first batch of files but it is not advisable for you to do multiple times of file selection action at once if this program is running on a slow computer.
   

All right, now lets look at the images below for the step by step tutorial on how to use this python application.

Start the application then click on the select file button below Click shift and select all the files that you wish to search and destroy their duplicate versions from and click the open button Next is to select the folder which you wish to remove all the duplicate files from then click on the select folder button That is it, now just sit back and enjoy while watching the program doing it's job

If you spot any bug in this application you can leave a comment below this post and I will fix it as fast as possible. If you are not sure about how to use this program you can create a folder then copy and paste some files from one folder to this new folder and start to practice to delete the duplicate files based on the steps I have shown to you earlier. This program is not perfect and thus your feedback is very important for me to improve on the quality of this program.

The application has been uploaded to github and you can now download the Multitas.exe file through this link. After you have downloaded the file, click on the Multitas.exe file to open it up and use it.

This program is only for the windows os user and maybe you need to have python installed on your desktop before you can use it.

If you intend to compile and run the program by yourself, then you can download the entire package then open up the windows command prompt and type in 'python path/to/Multitas.py' to start the application on your windows os laptop, this application runs well with no problem at all!

12 Dec 2018 12:15pm GMT

I am glad to inform you all that the remove duplicate file project written with python has finally completed and now it will be uploaded to github for you all to enjoy. This is a free software and it will always remain free. Although I would really love to create a linux version of this remove duplicate file software but because I do not have a linux os's computer therefore at the moment this software is just for the windows user only. I have packed this software up where you can just click on it to open it up to search and destroy the duplicate files inside your computer. Here are the steps you need to do to search and destroy the duplicate files:

1. Open up the application on your windows desktop.
2. Click on the select file button to select a file or use shift and select many files at once.
   
3. Select the other folder which you want this program to search and destroy all the duplicate files from, then sit back and enjoy.
4. This program will search all the files within that selected folder but make sure you are not selecting the same folder which you have selected the original file from.
5. You can select multiple files at the same time and you can also select another file which you want to remove it's duplicate version from after you have selected the first batch of files but it is not advisable for you to do multiple times of file selection action at once if this program is running on a slow computer.
   

All right, now lets look at the images below for the step by step tutorial on how to use this python application.

Start the application then click on the select file button below Click shift and select all the files that you wish to search and destroy their duplicate versions from and click the open button Next is to select the folder which you wish to remove all the duplicate files from then click on the select folder button That is it, now just sit back and enjoy while watching the program doing it's job

If you spot any bug in this application you can leave a comment below this post and I will fix it as fast as possible. If you are not sure about how to use this program you can create a folder then copy and paste some files from one folder to this new folder and start to practice to delete the duplicate files based on the steps I have shown to you earlier. This program is not perfect and thus your feedback is very important for me to improve on the quality of this program.

The application has been uploaded to github and you can now download the Multitas.exe file through this link. After you have downloaded the file, click on the Multitas.exe file to open it up and use it.

This program is only for the windows os user and maybe you need to have python installed on your desktop before you can use it.

If you intend to compile and run the program by yourself, then you can download the entire package then open up the windows command prompt and type in 'python path/to/Multitas.py' to start the application on your windows os laptop, this application runs well with no problem at all!

12 Dec 2018 12:15pm GMT

Although this behavior is in line with what you'd expect from a text editor, wouldn't it be nice if PyCharm could help you a little further? So we've made sure that breaking up an F-string in PyCharm 2018.3.2 leaves you with a valid Python file:

12 Dec 2018 11:47am GMT

Although this behavior is in line with what you'd expect from a text editor, wouldn't it be nice if PyCharm could help you a little further? So we've made sure that breaking up an F-string in PyCharm 2018.3.2 leaves you with a valid Python file:

12 Dec 2018 11:47am GMT

In this screencast, we learn about the Python egg, which was one of Python's old formats for distributing code. In modern Python, we now use a wheel.

You can also read the chapter this video is based on here or get the book on Leanpub

---

Previous Episodes

• Python 101: Episode #35 - The virtualenv Package
• Python 101: Episode #34 - The SQLAlchemy Package
• Python 101 - Episode #33: The requests Package
• Python 101: Episode #32 - Static Code Analysis

12 Dec 2018 6:05am GMT

In this screencast, we learn about the Python egg, which was one of Python's old formats for distributing code. In modern Python, we now use a wheel.

You can also read the chapter this video is based on here or get the book on Leanpub

---

Previous Episodes

• Python 101: Episode #35 - The virtualenv Package
• Python 101: Episode #34 - The SQLAlchemy Package
• Python 101 - Episode #33: The requests Package
• Python 101: Episode #32 - Static Code Analysis

12 Dec 2018 6:05am GMT

Welcome back, let us continue with our previous pygame project. In this article we will first create a text file which will be used to store the game level. This text file will be called level.txt which will be stored within the project folder. We need to create this text file by hand and type in 1 which is the first level of the game onto it, this level number will be rewritten each and every...

Source

Related posts:

Create the pause scene for the game Create the third level for this pygame project Lets move on to the next game level! Create a pool object for player missile Create Enemy Missile and Enemy Missile Manager Create player missile manager and player missile class in Pygame The cloud object has been introduced into Rock Sweeper The most advance sprites overlapping detection method from Pygame How to create a stand still sprite animation with Pygame How to draw circle with Pygame

12 Dec 2018 5:27am GMT

Welcome back, let us continue with our previous pygame project. In this article we will first create a text file which will be used to store the game level. This text file will be called level.txt which will be stored within the project folder. We need to create this text file by hand and type in 1 which is the first level of the game onto it, this level number will be rewritten each and every...

Source

Related posts:

Create the pause scene for the game Create the third level for this pygame project Lets move on to the next game level! Create a pool object for player missile Create Enemy Missile and Enemy Missile Manager Create player missile manager and player missile class in Pygame The cloud object has been introduced into Rock Sweeper The most advance sprites overlapping detection method from Pygame How to create a stand still sprite animation with Pygame How to draw circle with Pygame

12 Dec 2018 5:27am GMT

Welcome back again, in this chapter we will create a message box to tell the user how many duplicate files have been deleted from each selected file. The game plan here is simple, we will attach a message variable to the label widget and pass that widget to each remove thread instance so the program can modify the content of that message by adding in the selected file name as well as the total number of duplicate files that have been remove from the selected folder. That modify message will then be shown by the messagebox on the main thread at the end of each file deleting process. The first file we need to edit is the main file where we will pass in the tkinter's label object with the message variable to each new remove thread instance which the program has created, the remove thread instance will then modify the content of that same message which includes the total number of duplicate files that have been deleted together with the file name of the original selected file. We need not worry too much about whether those threads will compete with each other to modify the content of the message or not because one process will finish before another so therefore there is always a time gap in between the process in this case. Here is the new version of the main file.

from tkinter import *
from tkinter import filedialog
from Remove import Remove
import os
from tkinter import messagebox

win = Tk() # 1 Create instance
win.title("Multitas") # 2 Add a title
win.resizable(0, 0) # 3 Disable resizing the GUI
win.configure(background='black') # 4 change background color

# 5 Create a label
aLabel = Label(win, text="Remove duplicate", anchor="center")
aLabel.grid(column=0, row=1)
aLabel.configure(foreground="white")
aLabel.configure(background="black")
aLabel.message = ''

# 6 Create a selectFile function to be used by button
def selectFile():

    fullfilenames = filedialog.askopenfilenames(initialdir="/", title="Select a file") # select multiple files from the hard drive

    if(fullfilenames != ''):

        fullfilenamelist = win.tk.splitlist(fullfilenames)
        directory_path = os.path.dirname(os.path.abspath(fullfilenamelist[0]))

        os.chdir(directory_path)  # change the directory to the selected file directory

        folder = filedialog.askdirectory()  # 7 open a folder then create and start a new remove thread to delete the duplicate file
        folder = folder.replace('/', '\\')  # 8 this is for the windows separator only

        if(folder != '' and folder != os.getcwd()):

            for fullfilename in fullfilenamelist:

                if(fullfilename != ''):
                    filename = fullfilename.split('/')[-1]
                    remove = Remove(folder, filename, fullfilename, directory_path, aLabel)
                    remove.start()
                    remove.join()
                    messagebox.showinfo('Remove duplicate files', aLabel.message)

        else:
            messagebox.showinfo("Error", "Kindly select one folder and it must be a different one")
            return

    else:
        messagebox.showinfo("Select file", "You need to select a file!")
        return


# 9 Adding a Button
action = Button(win, text="Select File", command=selectFile)
action.grid(column=0, row=0)
action.configure(background='brown')
action.configure(foreground='white')

win.mainloop()  # 10 start GUI

And here is the edit version of the remove thread class.

import threading
import os
import filecmp
from tkinter import messagebox

class Remove(threading.Thread):

    def __init__(self, massage,  filename, fullfilename, directory_path, aLabel):

        threading.Thread.__init__(self)
        self.massage = massage
        self.filename, self.file_extension = os.path.splitext(filename)
        self.fullfilename = fullfilename
        self.directory_path = directory_path
        self.count = 0
        self.aLabel = aLabel

    def run(self):

        filepaths = os.listdir(self.massage)

        for filepath in list(filepaths):
            os.chdir(self.massage)
            if(os.getcwd() != self.directory_path): # make sure that we will not delete the same file in the selected file directory
                if(os.path.isfile(filepath)):
                    filename, file_extension = os.path.splitext(filepath)
                    self.remove_file(file_extension, filepath)
                else:
                    self.delete_duplicate(os.path.join(self.massage, filepath))
            else:
                continue

        self.aLabel.message = 'Removed ' + str(self.count) + ' duplicate : ' + self.filename # show this message box each time a set of duplicate files have been remove


    def delete_duplicate(self, folder): # sub method to pass folder to

        filepaths = os.listdir(folder)

        for filepath in list(filepaths):
            os.chdir(folder)
            if(os.getcwd() != self.directory_path):

                if(os.path.isfile(filepath)):
                    filename, file_extension = os.path.splitext(filepath)
                    self.remove_file(file_extension, filepath)
                else:
                    self.delete_duplicate(os.path.join(folder, filepath))

            else:
                continue

    def remove_file(self, file_extension, filepath):
        if (file_extension == self.file_extension):
            if filecmp.cmp(filepath, self.fullfilename, shallow=False):
                os.remove(filepath)
                self.count += 1

Now each remove thread will manage it's own business so there is no conflict with the count variable and the old message text will be replaced by the new one by the next process which changes it. That is basically it for this remove duplicate project, we are now fully ready to pack it up and use it on our windows' desktop.

12 Dec 2018 3:38am GMT

Welcome back again, in this chapter we will create a message box to tell the user how many duplicate files have been deleted from each selected file. The game plan here is simple, we will attach a message variable to the label widget and pass that widget to each remove thread instance so the program can modify the content of that message by adding in the selected file name as well as the total number of duplicate files that have been remove from the selected folder. That modify message will then be shown by the messagebox on the main thread at the end of each file deleting process. The first file we need to edit is the main file where we will pass in the tkinter's label object with the message variable to each new remove thread instance which the program has created, the remove thread instance will then modify the content of that same message which includes the total number of duplicate files that have been deleted together with the file name of the original selected file. We need not worry too much about whether those threads will compete with each other to modify the content of the message or not because one process will finish before another so therefore there is always a time gap in between the process in this case. Here is the new version of the main file.

from tkinter import *
from tkinter import filedialog
from Remove import Remove
import os
from tkinter import messagebox

win = Tk() # 1 Create instance
win.title("Multitas") # 2 Add a title
win.resizable(0, 0) # 3 Disable resizing the GUI
win.configure(background='black') # 4 change background color

# 5 Create a label
aLabel = Label(win, text="Remove duplicate", anchor="center")
aLabel.grid(column=0, row=1)
aLabel.configure(foreground="white")
aLabel.configure(background="black")
aLabel.message = ''

# 6 Create a selectFile function to be used by button
def selectFile():

    fullfilenames = filedialog.askopenfilenames(initialdir="/", title="Select a file") # select multiple files from the hard drive

    if(fullfilenames != ''):

        fullfilenamelist = win.tk.splitlist(fullfilenames)
        directory_path = os.path.dirname(os.path.abspath(fullfilenamelist[0]))

        os.chdir(directory_path)  # change the directory to the selected file directory

        folder = filedialog.askdirectory()  # 7 open a folder then create and start a new remove thread to delete the duplicate file
        folder = folder.replace('/', '\\')  # 8 this is for the windows separator only

        if(folder != '' and folder != os.getcwd()):

            for fullfilename in fullfilenamelist:

                if(fullfilename != ''):
                    filename = fullfilename.split('/')[-1]
                    remove = Remove(folder, filename, fullfilename, directory_path, aLabel)
                    remove.start()
                    remove.join()
                    messagebox.showinfo('Remove duplicate files', aLabel.message)

        else:
            messagebox.showinfo("Error", "Kindly select one folder and it must be a different one")
            return

    else:
        messagebox.showinfo("Select file", "You need to select a file!")
        return


# 9 Adding a Button
action = Button(win, text="Select File", command=selectFile)
action.grid(column=0, row=0)
action.configure(background='brown')
action.configure(foreground='white')

win.mainloop()  # 10 start GUI

And here is the edit version of the remove thread class.

import threading
import os
import filecmp
from tkinter import messagebox

class Remove(threading.Thread):

    def __init__(self, massage,  filename, fullfilename, directory_path, aLabel):

        threading.Thread.__init__(self)
        self.massage = massage
        self.filename, self.file_extension = os.path.splitext(filename)
        self.fullfilename = fullfilename
        self.directory_path = directory_path
        self.count = 0
        self.aLabel = aLabel

    def run(self):

        filepaths = os.listdir(self.massage)

        for filepath in list(filepaths):
            os.chdir(self.massage)
            if(os.getcwd() != self.directory_path): # make sure that we will not delete the same file in the selected file directory
                if(os.path.isfile(filepath)):
                    filename, file_extension = os.path.splitext(filepath)
                    self.remove_file(file_extension, filepath)
                else:
                    self.delete_duplicate(os.path.join(self.massage, filepath))
            else:
                continue

        self.aLabel.message = 'Removed ' + str(self.count) + ' duplicate : ' + self.filename # show this message box each time a set of duplicate files have been remove


    def delete_duplicate(self, folder): # sub method to pass folder to

        filepaths = os.listdir(folder)

        for filepath in list(filepaths):
            os.chdir(folder)
            if(os.getcwd() != self.directory_path):

                if(os.path.isfile(filepath)):
                    filename, file_extension = os.path.splitext(filepath)
                    self.remove_file(file_extension, filepath)
                else:
                    self.delete_duplicate(os.path.join(folder, filepath))

            else:
                continue

    def remove_file(self, file_extension, filepath):
        if (file_extension == self.file_extension):
            if filecmp.cmp(filepath, self.fullfilename, shallow=False):
                os.remove(filepath)
                self.count += 1

Now each remove thread will manage it's own business so there is no conflict with the count variable and the old message text will be replaced by the new one by the next process which changes it. That is basically it for this remove duplicate project, we are now fully ready to pack it up and use it on our windows' desktop.

12 Dec 2018 3:38am GMT

Message-passing for everyone.

I proudly announce libchirp. I believe queues, message-routers and patterns like pub-sub are the way message-passing should be done. However, I also believe they should be optional and tweak-able. libchirp does only one thing: message-passing with encryption. All other building-blocks should be implemented in upper-layer modules or daemons. libchirp is the basis for modular message-passing and actor-based programming.

I want to thank Adfinis-SyGroup who have supported me and allowed me to develop libchirp.

Here the mandatory echo-server example:

import asyncio
from libchirp.asyncio import Chirp, Config, Loop

class EchoChirp(Chirp):
    async def handler(self, msg):
        await self.send(msg)

loop = Loop(); config = Config()
config.DISABLE_ENCRYPTION = True
# Workers are usually asynchronous
config.SYNCHRONOUS = False
aio_loop = asyncio.get_event_loop()
try:
    chirp = EchoChirp(loop, config, aio_loop)
    try:
        aio_loop.run_forever()
    finally:
        chirp.stop()
finally:
    loop.stop()

There is also a ThreadPoolExecutor- and a Queue-based interface.

By the way libchirp for python are bindings to my C99-implementation. My secondary goal is to build a polyglot message-passing toolkit. Please be welcome to contribute bindings for your favorite language.

Project links

• python-chirp: https://github.com/concretecloud/python-chirp
• C99-chirp: https://github.com/concretecloud/chirp
• Other chirp related software: https://github.com/concretecloud

11 Dec 2018 11:00pm GMT

Message-passing for everyone.

I proudly announce libchirp. I believe queues, message-routers and patterns like pub-sub are the way message-passing should be done. However, I also believe they should be optional and tweak-able. libchirp does only one thing: message-passing with encryption. All other building-blocks should be implemented in upper-layer modules or daemons. libchirp is the basis for modular message-passing and actor-based programming.

I want to thank Adfinis-SyGroup who have supported me and allowed me to develop libchirp.

Here the mandatory echo-server example:

import asyncio
from libchirp.asyncio import Chirp, Config, Loop

class EchoChirp(Chirp):
    async def handler(self, msg):
        await self.send(msg)

loop = Loop(); config = Config()
config.DISABLE_ENCRYPTION = True
# Workers are usually asynchronous
config.SYNCHRONOUS = False
aio_loop = asyncio.get_event_loop()
try:
    chirp = EchoChirp(loop, config, aio_loop)
    try:
        aio_loop.run_forever()
    finally:
        chirp.stop()
finally:
    loop.stop()

There is also a ThreadPoolExecutor- and a Queue-based interface.

By the way libchirp for python are bindings to my C99-implementation. My secondary goal is to build a polyglot message-passing toolkit. Please be welcome to contribute bindings for your favorite language.

Project links

• python-chirp: https://github.com/concretecloud/python-chirp
• C99-chirp: https://github.com/concretecloud/chirp
• Other chirp related software: https://github.com/concretecloud

11 Dec 2018 11:00pm GMT

Python 3.7.2rc1 and 3.6.8rc1 are now available. 3.7.2rc1 is the release preview of the next maintenance release of Python 3.7, the latest feature release of Python. 3.6.8rc1 is the release preview of the next and last maintenance release of Python 3.6, the previous feature release of Python. Assuming no critical problems are found prior to 2018-12-20, no code changes are planned between these release candidates and the final releases. These release candidates are intended to give you the opportunity to test the new security and bug fixes in 3.7.2 and 3.6.8. We strongly encourage you to test your projects and report issues found to bugs.python.org as soon as possible. Please keep in mind that these are preview releases and, thus, their use is not recommended for production environments.

You can find these releases and more information here:

11 Dec 2018 10:00pm GMT

Python 3.7.2rc1 and 3.6.8rc1 are now available. 3.7.2rc1 is the release preview of the next maintenance release of Python 3.7, the latest feature release of Python. 3.6.8rc1 is the release preview of the next and last maintenance release of Python 3.6, the previous feature release of Python. Assuming no critical problems are found prior to 2018-12-20, no code changes are planned between these release candidates and the final releases. These release candidates are intended to give you the opportunity to test the new security and bug fixes in 3.7.2 and 3.6.8. We strongly encourage you to test your projects and report issues found to bugs.python.org as soon as possible. Please keep in mind that these are preview releases and, thus, their use is not recommended for production environments.

You can find these releases and more information here:

11 Dec 2018 10:00pm GMT

#346 - DECEMBER 11, 2018
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Get a Data Science Job in 6 Months, Guaranteed

With 1-on-1 mentorship, career coaching, and personalized support, you'll gain the skills and experience you need to get hired in a new role with Springboard's Data Science Career Track. The average reported salary increase was $23k. Launch your new career with Springboard. Apply today →
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11 Dec 2018 8:30pm GMT

#346 - DECEMBER 11, 2018
View in Browser »

Get a Data Science Job in 6 Months, Guaranteed

With 1-on-1 mentorship, career coaching, and personalized support, you'll gain the skills and experience you need to get hired in a new role with Springboard's Data Science Career Track. The average reported salary increase was $23k. Launch your new career with Springboard. Apply today →
SPRINGBOARD sponsor

Discussions

Python Jobs

Software Engineer (Munich, Germany)

Stylight GmbH

Senior Software Engineer (Munich, Germany)

Stylight GmbH

Lead Engineer (Munich, Germany)

Stylight GmbH

Backend Software Engineer (Vancouver, BC)

Gasket Games Corp

Head of Engineering (Remote)

FindKeep.Love

Cybersecurity Firm Seeks Backend Lead (NY or LA)

Aon Cyber Solutions

Senior Software Engineer (Los Angeles, CA)

GoodRx

Senior Developer (Chicago, IL)

Panopta

More Python Jobs >>>

Articles & Tutorials

Love Python? Show It With Some Python Swag

Show your love for the best programming language in the world and make your day more Pythonic with Python mugs, t-shirts, mouse pads, and stickers. Get 20% off this week only with coupon code "PYCODERS" →
NERDLETTERING sponsor

Projects & Code

Happy Pythoning!
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11 Dec 2018 8:30pm GMT

11 Dec 2018 7:47pm GMT

11 Dec 2018 7:47pm GMT

Details

11 Dec 2018 7:32pm GMT

Details

11 Dec 2018 7:32pm GMT

In this episode, you will learn ye olde method of adding code to the Python Packaging Index. Note that while some of this video is still relevant, you should be using the twine package now for uploading to PyPI. See https://packaging.python.org/guides/using-testpypi/ for more information.

You can also read the chapter this video is based on here or get the book on Leanpub

---

Previous Episodes

• Python 101: Episode #35 - The virtualenv Package
• Python 101: Episode #34 - The SQLAlchemy Package
• Python 101 - Episode #33: The requests Package
• Python 101: Episode #32 - Static Code Analysis

11 Dec 2018 7:06pm GMT

In this episode, you will learn ye olde method of adding code to the Python Packaging Index. Note that while some of this video is still relevant, you should be using the twine package now for uploading to PyPI. See https://packaging.python.org/guides/using-testpypi/ for more information.

You can also read the chapter this video is based on here or get the book on Leanpub

---

Previous Episodes

• Python 101: Episode #35 - The virtualenv Package
• Python 101: Episode #34 - The SQLAlchemy Package
• Python 101 - Episode #33: The requests Package
• Python 101: Episode #32 - Static Code Analysis

11 Dec 2018 7:06pm GMT

Gestern musste ich morgens zur Station nach KWT um unsere Rerservierten Bustickets für die Weihnachtsferien in Capetown abzuholen. Der Bahnhof selber ist seit Dezember aus kostengründen ohne Zugverbindung - aber Translux und co - die langdistanzbusse haben dort ihre Büros.


Größere Kartenansicht

© benste CC NC SA

10 Nov 2011 10:57am GMT

Niemand ist besorgt um so was - mit dem Auto fährt man einfach durch, und in der City - nahe Gnobie- "ne das ist erst gefährlich wenn die Feuerwehr da ist" - 30min später auf dem Rückweg war die Feuerwehr da.

© benste CC NC SA

09 Nov 2011 8:25pm GMT

Brai = Grillabend o.ä.

Die möchte gern Techniker beim Flicken ihrer SpeakOn / Klinke Stecker Verzweigungen...

Die Damen "Mamas" der Siedlung bei der offiziellen Eröffnungsrede

Auch wenn weniger Leute da waren als erwartet, Laute Musik und viele Leute ...

Und natürlich ein Feuer mit echtem Holz zum Grillen.

© benste CC NC SA

08 Nov 2011 2:30pm GMT

One of our missions was bringing Katja's Linux Server back to her room. While doing that we saw her new decoration.

Björn, Simphiwe carried the PC to Katja's school

© benste CC NC SA

07 Nov 2011 2:00pm GMT

Today I went with Björn to Needs Camp to Visit Katja's guest family for a special Party. First of all we visited some friends of Nelisa - yeah the one I'm working with in Quigney - Katja's guest fathers sister - who did her a haircut.

African Women usually get their hair done by arranging extensions and not like Europeans just cutting some hair.

In between she looked like this...

And then she was done - looks amazing considering the amount of hair she had last week - doesn't it ?

© benste CC NC SA

06 Nov 2011 7:45pm GMT

Irgendwie viel mir heute auf das ich meine Blogposts mal ein bischen umstrukturieren muss - wenn ich immer nur von neuen Plätzen berichte, dann müsste ich ja eine Rundreise machen. Hier also mal ein paar Sachen aus meinem heutigen Alltag.

Erst einmal vorweg, Samstag zählt zumindest für uns Voluntäre zu den freien Tagen.

Dieses Wochenende sind nur Rommel und ich auf der Farm - Katja und Björn sind ja mittlerweile in ihren Einsatzstellen, und meine Mitbewohner Kyle und Jonathan sind zu Hause in Grahamstown - sowie auch Sipho der in Dimbaza wohnt.
Robin, die Frau von Rommel ist in Woodie Cape - schon seit Donnerstag um da ein paar Sachen zur erledigen.
Naja wie dem auch sei heute morgen haben wir uns erstmal ein gemeinsames Weetbix/Müsli Frühstück gegönnt und haben uns dann auf den Weg nach East London gemacht. 2 Sachen waren auf der Checkliste Vodacom, Ethienne (Imobilienmakler) außerdem auf dem Rückweg die fehlenden Dinge nach NeedsCamp bringen.

Nachdem wir gerade auf der Dirtroad losgefahren sind mussten wir feststellen das wir die Sachen für Needscamp und Ethienne nicht eingepackt hatten aber die Pumpe für die Wasserversorgung im Auto hatten.

Also sind wir in EastLondon ersteinmal nach Farmerama - nein nicht das onlinespiel farmville - sondern einen Laden mit ganz vielen Sachen für eine Farm - in Berea einem nördlichen Stadteil gefahren.

In Farmerama haben wir uns dann beraten lassen für einen Schnellverschluss der uns das leben mit der Pumpe leichter machen soll und außerdem eine leichtere Pumpe zur Reperatur gebracht, damit es nicht immer so ein großer Aufwand ist, wenn mal wieder das Wasser ausgegangen ist.

Fego Caffé ist in der Hemmingways Mall, dort mussten wir und PIN und PUK einer unserer Datensimcards geben lassen, da bei der PIN Abfrage leider ein zahlendreher unterlaufen ist. Naja auf jeden Fall speichern die Shops in Südafrika so sensible Daten wie eine PUK - die im Prinzip zugang zu einem gesperrten Phone verschafft.

Im Cafe hat Rommel dann ein paar online Transaktionen mit dem 3G Modem durchgeführt, welches ja jetzt wieder funktionierte - und übrigens mittlerweile in Ubuntu meinem Linuxsystem perfekt klappt.

Nebenbei bin ich nach 8ta gegangen um dort etwas über deren neue Deals zu erfahren, da wir in einigen von Hilltops Centern Internet anbieten wollen. Das Bild zeigt die Abdeckung UMTS in NeedsCamp Katjas Ort. 8ta ist ein neuer Telefonanbieter von Telkom, nachdem Vodafone sich Telkoms anteile an Vodacom gekauft hat müssen die komplett neu aufbauen.
Wir haben uns dazu entschieden mal eine kostenlose Prepaidkarte zu testen zu organisieren, denn wer weis wie genau die Karte oben ist ... Bevor man einen noch so billigen Deal für 24 Monate signed sollte man wissen obs geht.

Danach gings nach Checkers in Vincent, gesucht wurden zwei Hotplates für WoodyCape - R 129.00 eine - also ca. 12€ für eine zweigeteilte Kochplatte.
Wie man sieht im Hintergrund gibts schon Weihnachtsdeko - Anfang November und das in Südafrika bei sonnig warmen min- 25°C

Mittagessen haben wir uns bei einem Pakistanischen Curry Imbiss gegönnt - sehr empfehlenswert !
Naja und nachdem wir dann vor ner Stunde oder so zurück gekommen sind habe ich noch den Kühlschrank geputzt den ich heute morgen zum defrosten einfach nach draußen gestellt hatte. Jetzt ist der auch mal wieder sauber und ohne 3m dicke Eisschicht...

Morgen ... ja darüber werde ich gesondert berichten ... aber vermutlich erst am Montag, denn dann bin ich nochmal wieder in Quigney(East London) und habe kostenloses Internet.

© benste CC NC SA

05 Nov 2011 4:33pm GMT

Sterkspruit is one of Hilltops Computer Centres in the far north of Eastern Cape. On the trip to J'burg we've used the opportunity to take a look at the centre.

Pupils in the big classroom

The Trainer

School in Countryside

Adult Class in the Afternoon

"Town"

© benste CC NC SA

31 Oct 2011 4:58pm GMT

What are you doing in an internet cafe if your ADSL and Faxline has been discontinued before months end. Well my idea was sitting outside and eating some ice cream.
At least it's sunny and not as rainy as on the weekend.

© benste CC NC SA

31 Oct 2011 3:11pm GMT

For those who are traveling through Zastron - there is a very nice Restaurant which is serving delicious food at reasanable prices.
In addition they're selling home made juices jams and honey.

interior

home made specialities - the shop in the shop

the Bar

© benste CC NC SA

30 Oct 2011 4:47pm GMT

Having the 10 - 12h trip from J'burg back to ELS I was able to take a lot of pcitures including these different roadsides

Plain Street

Orange River in its beginngings (near Lesotho)

Zastron Anglican Church

The Bridge in Between "Free State" and Eastern Cape next to Zastron

my new Background ;)

If you listen to GoogleMaps you'll end up traveling 50km of gravel road - as it was just renewed we didn't have that many problems and saved 1h compared to going the official way with all it's constructions sites

Freeway

getting dark

© benste CC NC SA

29 Oct 2011 4:23pm GMT

Klar einiges mag anders sein, vieles aber gleich - aber ein in Deutschland täglich übliches Bild einer Straßenbaustelle - wie läuft das eigentlich in Südafrika ?

Ersteinmal vorweg - NEIN keine Ureinwohner die mit den Händen graben - auch wenn hier mehr Manpower genutzt wird - sind sie fleißig mit Technologie am arbeiten.

Eine ganz normale "Bundesstraße"

und wie sie erweitert wird

gaaaanz viele LKWs

denn hier wird eine Seite über einen langen Abschnitt komplett gesperrt, so das eine Ampelschaltung mit hier 45 Minuten Wartezeit entsteht

Aber wenigstens scheinen die ihren Spaß zu haben ;) - Wie auch wir denn gücklicher Weise mussten wir nie länger als 10 min. warten.

© benste CC NC SA

28 Oct 2011 4:20pm GMT