Python

Here are some stories on how you can go wrong with naming, especially in open source software.

Easy

Don't use the name "easy" or "simple" in your software as it won't be and people will make fun of it.

Background

People tend to want to use the word 'easy' or 'simple' when things really are not, to describe a facade. They want to paper over immense complexity. Inevitably the facade will be a leaky abstraction, and developers using the software are exposed to it. And now you named it 'easy', when it's anything but not. Just don't give in to the temptation in the first place, and people won't make fun of it.

Examples

easy_install is a Python tool to easily and automatically install Python packages, similar to JavaScript npm or Ruby gems. pip is a more popular tool these days that does the same. easy_install hides, among many other complicated things, a full-fledged web scraper that follows links onto arbitrary websites to find packages. It's "easy" until it fails, and it will fail at one point or another.

SimpleItem is an infamous base class in Zope 2 that pulls in just about every aspect of Zope 2 as mixin classes. It's supposed to make it easy to create a new content type for Zope. The amount of methods made available is truly intimidating and anything but simple.

Demo

Don't use the word "demo" or "sample" in your main codebase or people will depend on it and you will be stuck with it forever.

Background

It's tempting in some library or framework consisting of many parts to want to expose an integrated set of pieces, just as an example, within that codebase itself. Real use of it will of course have the developers integrating those pieces themselves. Except they won't, and now you have people using Sample stuff in real world code.

The word Sample or Demo is fine if the entire codebase is a demo, but it's not fine as part of a larger codebase.

Examples

SampleContainer was a part of Zope 3 that serves as the base class of most actual container subclasses in real world code. It was just supposed to demonstrate how to do the integration.

Rewrite

Don't reuse the name of software for an incompatible rewrite, unless you want people to be confused about it.

Background

Your software has a big installed base. But it's not perfect. You decide to create a new, incompatible version, without a clear upgrade path. Perhaps you handwave the upgrade path "until later", but that then never happens.

Just name the new version something else. Because the clear upgrade path may never materialize, and people will be confused anyway. They will find documentation and examples for the old system if they search for the new one, and vice versa. Spare your user base that confusion.

The temptation to do this is great; you want to benefit from popularity of the name of the old system and this way attract users to the shiny new system. But that's exactly the situation where doing this is most confusing.

Examples

Zope 3: there was already a very popular Zope 2 around, and then we decide to completely rewrite it and named it "Zope 3". Some kind of upgrade path was promised but conveniently handwaved. Immense confusion arose. We then landed pieces of Zope 3 in the old Zope 2 codebase, and it took years to resolve all the confusion.

Company name

If you want a open source community, don't name the software after your company, or your company after the software.

Background

If you have a piece of open source software and you want an open source community of developers for it, then don't name it after your company. You may love your company, but outside developers get a clear indication that "the Acme Platform" is something that is developed by Acme. They know that as outside developers, they will never gain as much influence on the development of that software as developers working at Acme. So they just don't contribute. They go to other open source software that isn't so clearly allied to a single business and contribute there. And you are left to wonder why developers are not attracted to work on your software.

Similarly, you may have great success with an open source project and now want to name your own company after it. That sends a powerful signal of ownership to other stakeholders, and may deter them from contributing.

Of course naming is only a part of what makes an open source project look like something a developer can safely contribute to. But if you get the naming bit wrong, it's hard to get the rest right.

Add the potential entanglement into trademark politics on top of it, and just decide not to do it.

Examples

Examples omitted so I won't get into trouble with anyone.

29 Jul 2014 2:37pm GMT

Here are some stories on how you can go wrong with naming, especially in open source software.

Easy

Don't use the name "easy" or "simple" in your software as it won't be and people will make fun of it.

Background

People tend to want to use the word 'easy' or 'simple' when things really are not, to describe a facade. They want to paper over immense complexity. Inevitably the facade will be a leaky abstraction, and developers using the software are exposed to it. And now you named it 'easy', when it's anything but not. Just don't give in to the temptation in the first place, and people won't make fun of it.

Examples

easy_install is a Python tool to easily and automatically install Python packages, similar to JavaScript npm or Ruby gems. pip is a more popular tool these days that does the same. easy_install hides, among many other complicated things, a full-fledged web scraper that follows links onto arbitrary websites to find packages. It's "easy" until it fails, and it will fail at one point or another.

SimpleItem is an infamous base class in Zope 2 that pulls in just about every aspect of Zope 2 as mixin classes. It's supposed to make it easy to create a new content type for Zope. The amount of methods made available is truly intimidating and anything but simple.

Demo

Don't use the word "demo" or "sample" in your main codebase or people will depend on it and you will be stuck with it forever.

Background

It's tempting in some library or framework consisting of many parts to want to expose an integrated set of pieces, just as an example, within that codebase itself. Real use of it will of course have the developers integrating those pieces themselves. Except they won't, and now you have people using Sample stuff in real world code.

The word Sample or Demo is fine if the entire codebase is a demo, but it's not fine as part of a larger codebase.

Examples

SampleContainer was a part of Zope 3 that serves as the base class of most actual container subclasses in real world code. It was just supposed to demonstrate how to do the integration.

Rewrite

Don't reuse the name of software for an incompatible rewrite, unless you want people to be confused about it.

Background

Your software has a big installed base. But it's not perfect. You decide to create a new, incompatible version, without a clear upgrade path. Perhaps you handwave the upgrade path "until later", but that then never happens.

Just name the new version something else. Because the clear upgrade path may never materialize, and people will be confused anyway. They will find documentation and examples for the old system if they search for the new one, and vice versa. Spare your user base that confusion.

The temptation to do this is great; you want to benefit from popularity of the name of the old system and this way attract users to the shiny new system. But that's exactly the situation where doing this is most confusing.

Examples

Zope 3: there was already a very popular Zope 2 around, and then we decide to completely rewrite it and named it "Zope 3". Some kind of upgrade path was promised but conveniently handwaved. Immense confusion arose. We then landed pieces of Zope 3 in the old Zope 2 codebase, and it took years to resolve all the confusion.

Company name

If you want a open source community, don't name the software after your company, or your company after the software.

Background

If you have a piece of open source software and you want an open source community of developers for it, then don't name it after your company. You may love your company, but outside developers get a clear indication that "the Acme Platform" is something that is developed by Acme. They know that as outside developers, they will never gain as much influence on the development of that software as developers working at Acme. So they just don't contribute. They go to other open source software that isn't so clearly allied to a single business and contribute there. And you are left to wonder why developers are not attracted to work on your software.

Similarly, you may have great success with an open source project and now want to name your own company after it. That sends a powerful signal of ownership to other stakeholders, and may deter them from contributing.

Of course naming is only a part of what makes an open source project look like something a developer can safely contribute to. But if you get the naming bit wrong, it's hard to get the rest right.

Add the potential entanglement into trademark politics on top of it, and just decide not to do it.

Examples

Examples omitted so I won't get into trouble with anyone.

29 Jul 2014 2:37pm GMT

When working with shell scripts written in bash/csh/etc. one of the primary tools you have to rely on is a simple method of piping output and input from subprocesses called by the script to create complex logic to accomplish the goal of the script. When working with python, this same method of calling subprocesses to redirect the input/output is available, but the overhead of using this method in python would be so cumbersome as to make python a less desirable scripting language. In effect you were implementing large parts of the I/O facilities, and potentially even writing replacements for the existing shell utilities that would perform the same work. Recently, python developers attempted to solve this problem, by updating an existing python subprocess wrapper library called pbs, into an easier to use library called sh.

Sh can be installed using pip, and the author has posted some documentation for the library here: http://amoffat.github.io/sh/

Using the sh library

After installing the library into your version of python, there will be two ways to call any existing shell command available to the system, firstly you can import the command as though it was itself a python library:

from sh import hostname
print(hostname())

In addition, you can also call the command directly by just referencing the sh namespace prior to the command name:

import sh
print(sh.hostname())

When running this command on my linux workstation (hostname atlas) it will return the expected results:

Python 2.7.6 (default, Mar 22 2014, 22:59:56)
[GCC 4.8.2] on linux2
Type "help", "copyright", "credits" or "license" for more information.
>>> import sh
>>> print(sh.hostname())
atlas

However at this point, we are merely replacing a single shell command which prints output to the screen, the real benefit of the shell scripts was that you could chain together commands in order to create complex logic to help you do work.

Advanced Gymnastics

A common use of shell scripts is to provide administrators the ability to quickly filter log file output and to potentially search for specific conditions within those logs, to alert in the event that an application starts throwing errors. With python piping in sh we can create a simple log watcher, which would be capable of calling anything we desire in python when the log file contains any of the conditions we are looking for.

To pipe together commands using the sh library, you would encapsulate each command in series to create a similar syntax to bash piping:

>>> print(sh.wc(sh.ls("-l", "/etc"), "-l"))
199

This command would have been equivalent to the bash pipe of "ls -l /etc | wc -l" indicating that the long listing of /etc on my workstation contained 199 lines of output. Each piped command is encapsulated inside the parenthesis of the command the precedes it.

For our log listener we will use the tail command along with a python iterator to watch for a potential error condition, which I will represent with the string "ERROR":

>>> for line in sh.tail("-f", "/tmp/test_log", _iter=True):
...     if "ERROR" in line:
...         print line

In this example, once executed, python will call the tail command to follow a particular log file. It will iterate over each line of output produced by tail and if any of the lines contain the string we are watching for python will print that line to standard output. At this point, this would be similar to using the tail command and piping the output to a string search command, like grep. However, you could replace the third line of the python with a more complex action, emailing the error condition out to a developer or administrator for review, or perhaps initiating a procedure to recover from the error automatically.

Conclusions

In this manner with just a few lines of python, much like with bash, one could create a relatively complex process without recreating all the shell commands which already perform this work, or create a convoluted wrapping process of passing output from command to command. This combination of the existing shell commands and the power of python; you get all the functions available to any python environment, with the ease of using the shell commands to do some of the work. In the future I will definitely be using this python library for my own shell scripting needs, as I have generally preferred the syntax and ease of use of python over that of bash, but now I will be able to enjoy both at the same time.

29 Jul 2014 12:35pm GMT

When working with shell scripts written in bash/csh/etc. one of the primary tools you have to rely on is a simple method of piping output and input from subprocesses called by the script to create complex logic to accomplish the goal of the script. When working with python, this same method of calling subprocesses to redirect the input/output is available, but the overhead of using this method in python would be so cumbersome as to make python a less desirable scripting language. In effect you were implementing large parts of the I/O facilities, and potentially even writing replacements for the existing shell utilities that would perform the same work. Recently, python developers attempted to solve this problem, by updating an existing python subprocess wrapper library called pbs, into an easier to use library called sh.

Sh can be installed using pip, and the author has posted some documentation for the library here: http://amoffat.github.io/sh/

Using the sh library

After installing the library into your version of python, there will be two ways to call any existing shell command available to the system, firstly you can import the command as though it was itself a python library:

from sh import hostname
print(hostname())

In addition, you can also call the command directly by just referencing the sh namespace prior to the command name:

import sh
print(sh.hostname())

When running this command on my linux workstation (hostname atlas) it will return the expected results:

Python 2.7.6 (default, Mar 22 2014, 22:59:56)
[GCC 4.8.2] on linux2
Type "help", "copyright", "credits" or "license" for more information.
>>> import sh
>>> print(sh.hostname())
atlas

However at this point, we are merely replacing a single shell command which prints output to the screen, the real benefit of the shell scripts was that you could chain together commands in order to create complex logic to help you do work.

Advanced Gymnastics

A common use of shell scripts is to provide administrators the ability to quickly filter log file output and to potentially search for specific conditions within those logs, to alert in the event that an application starts throwing errors. With python piping in sh we can create a simple log watcher, which would be capable of calling anything we desire in python when the log file contains any of the conditions we are looking for.

To pipe together commands using the sh library, you would encapsulate each command in series to create a similar syntax to bash piping:

>>> print(sh.wc(sh.ls("-l", "/etc"), "-l"))
199

This command would have been equivalent to the bash pipe of "ls -l /etc | wc -l" indicating that the long listing of /etc on my workstation contained 199 lines of output. Each piped command is encapsulated inside the parenthesis of the command the precedes it.

For our log listener we will use the tail command along with a python iterator to watch for a potential error condition, which I will represent with the string "ERROR":

>>> for line in sh.tail("-f", "/tmp/test_log", _iter=True):
...     if "ERROR" in line:
...         print line

In this example, once executed, python will call the tail command to follow a particular log file. It will iterate over each line of output produced by tail and if any of the lines contain the string we are watching for python will print that line to standard output. At this point, this would be similar to using the tail command and piping the output to a string search command, like grep. However, you could replace the third line of the python with a more complex action, emailing the error condition out to a developer or administrator for review, or perhaps initiating a procedure to recover from the error automatically.

Conclusions

In this manner with just a few lines of python, much like with bash, one could create a relatively complex process without recreating all the shell commands which already perform this work, or create a convoluted wrapping process of passing output from command to command. This combination of the existing shell commands and the power of python; you get all the functions available to any python environment, with the ease of using the shell commands to do some of the work. In the future I will definitely be using this python library for my own shell scripting needs, as I have generally preferred the syntax and ease of use of python over that of bash, but now I will be able to enjoy both at the same time.

29 Jul 2014 12:35pm GMT

On Part 1 we discussed the basics of embedding JavaScript code into an IPython Notebook, and saw how to use this feature to integrate D3.js charts. On this part we'll show you how to do the same with Chart.js.

IPython Notebook

This post is also available as an IPython Notebook on github.com

Part 2 - Embedding ChartJS

First we need to declare the requirement using RequireJS:

%%javascript
require.config({
    paths: {
        chartjs: '//cdnjs.cloudflare.com/ajax/libs/Chart.js/0.2.0/Chart.min'
    }
});

The procedure is the same as before, we define a template that will contain the rendered JavaScript code, and we use display to embed the code into the running page.

Chart.js is an HTML5 charting library capable of producing beautiful graphics with very little code. Now we want to plot the male and female population by region, division an state. We'll use interact with a new callback function called display_chart_chartjs, but this time we don't need custom widgets as we're only selecting a single item (we'll use a DropdownWidget). We've also included the show_javascript checkbox.

i = interact(
    display_chart_chartjs,
    sc_est2012_sex=widgets.fixed(sc_est2012_sex),
    region=widgets.fixed(region),
    division=widgets.fixed(division),
    show_javascript=widgets.CheckboxWidget(value=False),
    show=widgets.DropdownWidget(
        values={'By Region':'by_region', 'By Division': 'by_division', 'By State': 'by_state'},
        value='by_region'
    ),
    div=widgets.HTMLWidget(value='<canvas width=800 height=400 id="chart_chartjs"></canvas>')
)

/static/media/uploads/uploads/javascript_charts_3.png

As you can see, the library generates an beautiful and simple animated column chart. There's not much in terms of customization of Chart.js charts, but that makes it very easy to use.

On the last part (soon), we'll show you how to embed HighCharts charts.

29 Jul 2014 12:01pm GMT

On Part 1 we discussed the basics of embedding JavaScript code into an IPython Notebook, and saw how to use this feature to integrate D3.js charts. On this part we'll show you how to do the same with Chart.js.

IPython Notebook

This post is also available as an IPython Notebook on github.com

Part 2 - Embedding ChartJS

First we need to declare the requirement using RequireJS:

%%javascript
require.config({
    paths: {
        chartjs: '//cdnjs.cloudflare.com/ajax/libs/Chart.js/0.2.0/Chart.min'
    }
});

The procedure is the same as before, we define a template that will contain the rendered JavaScript code, and we use display to embed the code into the running page.

Chart.js is an HTML5 charting library capable of producing beautiful graphics with very little code. Now we want to plot the male and female population by region, division an state. We'll use interact with a new callback function called display_chart_chartjs, but this time we don't need custom widgets as we're only selecting a single item (we'll use a DropdownWidget). We've also included the show_javascript checkbox.

i = interact(
    display_chart_chartjs,
    sc_est2012_sex=widgets.fixed(sc_est2012_sex),
    region=widgets.fixed(region),
    division=widgets.fixed(division),
    show_javascript=widgets.CheckboxWidget(value=False),
    show=widgets.DropdownWidget(
        values={'By Region':'by_region', 'By Division': 'by_division', 'By State': 'by_state'},
        value='by_region'
    ),
    div=widgets.HTMLWidget(value='<canvas width=800 height=400 id="chart_chartjs"></canvas>')
)

As you can see, the library generates an beautiful and simple animated column chart. There's not much in terms of customization of Chart.js charts, but that makes it very easy to use.

On the last part (soon), we'll show you how to embed HighCharts charts.

29 Jul 2014 12:01pm GMT

PEP-396 suggests that all python packages should provide a __version__ attribute. This should contain a string in the form x.y.z which gives you the package's version number. That seems simple enough, except that Python does not provide an obvious way to set this attribute. It would be a tremendous waste of time to set this […]

29 Jul 2014 12:07am GMT

PEP-396 suggests that all python packages should provide a __version__ attribute. This should contain a string in the form x.y.z which gives you the package's version number. That seems simple enough, except that Python does not provide an obvious way to set this attribute. It would be a tremendous waste of time to set this […]

29 Jul 2014 12:07am GMT

If you are using Homebrew on OSX and Python and there is a small virtualenv then this article is for you.

After a small upgrade of Python via Brew, you risk to get this error when you want to use the virtualenv.

In my case, the directory where I store the virtualenvs is ~/.virtualenvs

$HOME/.virtualenvs/
    pelican/

Loads the virtualenv.

$HOME/.virtualenvs (0) > source ~/.virtualenvs/pelican/bin/activate.sh

$HOME/.virtualenvs (0) > (pelican) pelican
dyld: Library not loaded: @executable_path/../.Python
  Referenced from: $HOME/.virtualenvs/pelican/bin/python
  Reason: image not found
fish: Job 1, 'pelican' terminated by signal SIGTRAP (Trace or breakpoint trap)

$HOME/.virtualenvs (0) > (pelican) deactivate

In fact, there is a problem with the library, you need to regenerate the links of the Python interpreter. In this case, this is just to remove the existing links and re-execute the virtualenv command.

$HOME/.virtualenvs (0) > find pelican/ -type l
pelican/.Python
pelican/bin/python
pelican/bin/python2
pelican/include/python2.7
pelican/lib/python2.7/_abcoll.py
pelican/lib/python2.7/_weakrefset.py
pelican/lib/python2.7/abc.py
pelican/lib/python2.7/codecs.py
pelican/lib/python2.7/config
pelican/lib/python2.7/copy_reg.py
pelican/lib/python2.7/encodings
pelican/lib/python2.7/fnmatch.py
pelican/lib/python2.7/genericpath.py
pelican/lib/python2.7/lib-dynload
pelican/lib/python2.7/linecache.py
pelican/lib/python2.7/locale.py
pelican/lib/python2.7/ntpath.py
pelican/lib/python2.7/os.py
pelican/lib/python2.7/posixpath.py
pelican/lib/python2.7/re.py
pelican/lib/python2.7/sre.py
pelican/lib/python2.7/sre_compile.py
pelican/lib/python2.7/sre_constants.py
pelican/lib/python2.7/sre_parse.py
pelican/lib/python2.7/stat.py
pelican/lib/python2.7/types.py
pelican/lib/python2.7/UserDict.py
pelican/lib/python2.7/warnings.py

All the symlinks are wrong, and we need to remove them and re-execute the virtualenv command.

$HOME/.virtualenvs (0) > find pelican/ -type l -delete

$HOME/.virtualenvs (0) > virtualenv pelican
Overwriting pelican/lib/python2.7/site.py with new content
Overwriting pelican/lib/python2.7/orig-prefix.txt with new content
New python executable in pelican/bin/python2.7
Also creating executable in pelican/bin/python
Installing setuptools, pip...done.
Overwriting pelican/bin/activate_this.py with new content

Loads the virtualenv ;-)

$HOME/.virtualenvs (0) > source ~/.virtualenvs/pelican/bin/activate.sh

$HOME/.virtualenvs > (pelican) pelican --version
3.5.dev

And now, you have a working virtualenv.

28 Jul 2014 10:00pm GMT

If you are using Homebrew on OSX and Python and there is a small virtualenv then this article is for you.

After a small upgrade of Python via Brew, you risk to get this error when you want to use the virtualenv.

In my case, the directory where I store the virtualenvs is ~/.virtualenvs

$HOME/.virtualenvs/
    pelican/

Loads the virtualenv.

$HOME/.virtualenvs (0) > source ~/.virtualenvs/pelican/bin/activate.sh

$HOME/.virtualenvs (0) > (pelican) pelican
dyld: Library not loaded: @executable_path/../.Python
  Referenced from: $HOME/.virtualenvs/pelican/bin/python
  Reason: image not found
fish: Job 1, 'pelican' terminated by signal SIGTRAP (Trace or breakpoint trap)

$HOME/.virtualenvs (0) > (pelican) deactivate

In fact, there is a problem with the library, you need to regenerate the links of the Python interpreter. In this case, this is just to remove the existing links and re-execute the virtualenv command.

$HOME/.virtualenvs (0) > find pelican/ -type l
pelican/.Python
pelican/bin/python
pelican/bin/python2
pelican/include/python2.7
pelican/lib/python2.7/_abcoll.py
pelican/lib/python2.7/_weakrefset.py
pelican/lib/python2.7/abc.py
pelican/lib/python2.7/codecs.py
pelican/lib/python2.7/config
pelican/lib/python2.7/copy_reg.py
pelican/lib/python2.7/encodings
pelican/lib/python2.7/fnmatch.py
pelican/lib/python2.7/genericpath.py
pelican/lib/python2.7/lib-dynload
pelican/lib/python2.7/linecache.py
pelican/lib/python2.7/locale.py
pelican/lib/python2.7/ntpath.py
pelican/lib/python2.7/os.py
pelican/lib/python2.7/posixpath.py
pelican/lib/python2.7/re.py
pelican/lib/python2.7/sre.py
pelican/lib/python2.7/sre_compile.py
pelican/lib/python2.7/sre_constants.py
pelican/lib/python2.7/sre_parse.py
pelican/lib/python2.7/stat.py
pelican/lib/python2.7/types.py
pelican/lib/python2.7/UserDict.py
pelican/lib/python2.7/warnings.py

All the symlinks are wrong, and we need to remove them and re-execute the virtualenv command.

$HOME/.virtualenvs (0) > find pelican/ -type l -delete

$HOME/.virtualenvs (0) > virtualenv pelican
Overwriting pelican/lib/python2.7/site.py with new content
Overwriting pelican/lib/python2.7/orig-prefix.txt with new content
New python executable in pelican/bin/python2.7
Also creating executable in pelican/bin/python
Installing setuptools, pip...done.
Overwriting pelican/bin/activate_this.py with new content

Loads the virtualenv ;-)

$HOME/.virtualenvs (0) > source ~/.virtualenvs/pelican/bin/activate.sh

$HOME/.virtualenvs > (pelican) pelican --version
3.5.dev

And now, you have a working virtualenv.

28 Jul 2014 10:00pm GMT

So you have an audio stream where you'd like to get a human-friendly readout of the current audio level. You add a level component, but how do you actually get the level messages it generates?

            bus.add_signal_watch()
            bus.connect( 'message', self.on_level )

It really seems that you *should* be able to use element.connect(), but there doesn't seem to be an available event to which to connect on the level. So, you wind up having to process all of the events and look for your level event...

    def on_level( self, bus, message ):
        """Level message was received"""
        if message.src == self.monitor and message.type==gst.MESSAGE_ELEMENT:
            self.send( {
                'type':'level',
                'level': message.structure['rms'][0],
            })

Next problem, the "level" is not particularly human friendly. It appears to be a decibel attenuation (from 0 negative), where e.g. -17 seems to be a pretty loud voice and ~-40 is background noise... but that's just what *my* setup produces. Still trying to figure out if there's a formal "what pocketsphinx wants for dictation" definition somewhere. The "vader" element has a value of 0.0078125 as the default for volume cut-off, but no idea what that means.

28 Jul 2014 7:33pm GMT

So you have an audio stream where you'd like to get a human-friendly readout of the current audio level. You add a level component, but how do you actually get the level messages it generates?

            bus.add_signal_watch()
            bus.connect( 'message', self.on_level )

It really seems that you *should* be able to use element.connect(), but there doesn't seem to be an available event to which to connect on the level. So, you wind up having to process all of the events and look for your level event...

    def on_level( self, bus, message ):
        """Level message was received"""
        if message.src == self.monitor and message.type==gst.MESSAGE_ELEMENT:
            self.send( {
                'type':'level',
                'level': message.structure['rms'][0],
            })

Next problem, the "level" is not particularly human friendly. It appears to be a decibel attenuation (from 0 negative), where e.g. -17 seems to be a pretty loud voice and ~-40 is background noise... but that's just what *my* setup produces. Still trying to figure out if there's a formal "what pocketsphinx wants for dictation" definition somewhere. The "vader" element has a value of 0.0078125 as the default for volume cut-off, but no idea what that means.

28 Jul 2014 7:33pm GMT

PyOhio gave my lightning talk on ddlgenerator a warm reception, and Brandon Lorenz got me thinking, and PyOhio sprints filled my with py-drenaline, and now ddlgenerator can inspect your data and spit out SQLAlchemy model definitions for you:


$ cat merovingians.yaml 
-
  name: Clovis I
  reign:
    from: 486
    to: 511
-
  name: Childebert I
  reign:
    from: 511
    to: 558
$ ddlgenerator --inserts sqlalchemy merovingians.yaml 

from sqlalchemy import create_engine, Column, Integer, Table, Unicode
engine = create_engine(r'sqlite:///:memory:')
metadata = MetaData(bind=engine)

merovingians = Table('merovingians', metadata, 
  Column('name', Unicode(length=12), nullable=False), 
  Column('reign_from', Integer(), nullable=False), 
  Column('reign_to', Integer(), nullable=False), 
  schema=None)

metadata.create_all()
conn = engine.connect()
inserter = merovingians.insert()
conn.execute(inserter, **{'name': 'Clovis I', 'reign_from': 486, 'reign_to': 511})
conn.execute(inserter, **{'name': 'Childebert I', 'reign_from': 511, 'reign_to': 558})
conn.connection.commit()

Brandon's working on a pull request to provide similar functionality for Django models!

28 Jul 2014 3:30pm GMT

PyOhio gave my lightning talk on ddlgenerator a warm reception, and Brandon Lorenz got me thinking, and PyOhio sprints filled my with py-drenaline, and now ddlgenerator can inspect your data and spit out SQLAlchemy model definitions for you:


$ cat merovingians.yaml 
-
  name: Clovis I
  reign:
    from: 486
    to: 511
-
  name: Childebert I
  reign:
    from: 511
    to: 558
$ ddlgenerator --inserts sqlalchemy merovingians.yaml 

from sqlalchemy import create_engine, Column, Integer, Table, Unicode
engine = create_engine(r'sqlite:///:memory:')
metadata = MetaData(bind=engine)

merovingians = Table('merovingians', metadata, 
  Column('name', Unicode(length=12), nullable=False), 
  Column('reign_from', Integer(), nullable=False), 
  Column('reign_to', Integer(), nullable=False), 
  schema=None)

metadata.create_all()
conn = engine.connect()
inserter = merovingians.insert()
conn.execute(inserter, **{'name': 'Clovis I', 'reign_from': 486, 'reign_to': 511})
conn.execute(inserter, **{'name': 'Childebert I', 'reign_from': 511, 'reign_to': 558})
conn.connection.commit()

Brandon's working on a pull request to provide similar functionality for Django models!

28 Jul 2014 3:30pm GMT

The EP14 Pylint sprint team (more on this here and there) is proud to announce they just released Pylint 1.3 together with its companion Astroid 1.2. As usual, this includes several new features as well and bug fixes. You'll find below some structured list of the changes.

Packages are uploaded to pypi, debian/ubuntu packages should be soon provided by Logilab, until they get into the standard packaging system of your favorite distribution.

Please notice Pylint 1.3 will be the last release branch support python 2.5 and 2.6. Starting from 1.4, we will only support python greater or equal to 2.7. This will be the occasion to do some great cleanup in the code base. Notice this is only about the Pylint's runtime, you should still be able to run Pylint on your Python 2.5 code, through using Python 2.7 at least.

New checks

Add multiple checks for PEP 3101 advanced string formatting: 'bad-format-string', 'missing-format-argument-key', 'unused-format-string-argument', 'format-combined-specification', 'missing-format-attribute' and 'invalid-format-index'
New 'invalid-slice-index' and 'invalid-sequence-index' for invalid sequence and slice indices
New 'assigning-non-slot' warning, which detects assignments to attributes not defined in slots

Improved checkers

Fixed 'fixme' false positive (#149)
Fixed 'unbalanced-iterable-unpacking' false positive when encountering starred nodes (#273)
Fixed 'bad-format-character' false positive when encountering the 'a' format on Python 3
Fixed 'unused-variable' false positive when the variable is assigned through an import (#196)
Fixed 'unused-variable' false positive when assigning to a nonlocal (#275)
Fixed 'pointless-string-statement' false positive for attribute docstrings (#193)
Emit 'undefined-variable' when using the Python 3 metaclass= argument. Also fix 'unused-import' false for that construction (#143)
Emit 'broad-except' and 'bare-except' even if the number of except handlers is different than 1. Fixes issue (#113)
Emit 'attribute-defined-outside-init' for all statements in the same module as the offended class, not just for the last assignment (#262, as well as a long standing output mangling problem in some edge cases)
Emit 'not-callable' when calling properties (#268)
Don't let ImportError propagate from the imports checker, leading to crash in some namespace package related cases (#203)
Don't emit 'no-name-in-module' for ignored modules (#223)
Don't emit 'unnecessary-lambda' if the body of the lambda call contains call chaining (#243)
Definition order is considered for classes, function arguments and annotations (#257)
Only emit 'attribute-defined-outside-init' for definition within the same module as the offended class, avoiding to mangle the output in some cases
Don't emit 'hidden-method' message when the attribute has been monkey-patched, you're on your own when you do that.

Others changes

Checkers are now properly ordered to respect priority(#229)
Use the proper mode for pickle when opening and writing the stats file (#148)

Astroid changes

Function nodes can detect decorator call chain and see if they are decorated with builtin descriptors (classmethod and staticmethod).
infer_call_result called on a subtype of the builtin type will now return a new Class rather than an Instance.
Class.metaclass() now handles module-level __metaclass__ declaration on python 2, and no longer looks at the __metaclass__ class attribute on python 3.
Add slots method to Class nodes, for retrieving the list of valid slots it defines.
Expose function annotation to astroid: Arguments node exposes 'varargannotation', 'kwargannotation' and 'annotations' attributes, while Function node has the 'returns' attribute.
Backported most of the logilab.common.modutils module there, as most things there are for pylint/astroid only and we want to be able to fix them without requiring a new logilab.common release
Fix names grabed using wildcard import in "absolute import mode" (i.e. with absolute_import activated from the __future__ or with python 3) (pylint issue #58)
Add support in brain for understanding enum classes.

28 Jul 2014 3:21pm GMT

The EP14 Pylint sprint team (more on this here and there) is proud to announce they just released Pylint 1.3 together with its companion Astroid 1.2. As usual, this includes several new features as well and bug fixes. You'll find below some structured list of the changes.

Packages are uploaded to pypi, debian/ubuntu packages should be soon provided by Logilab, until they get into the standard packaging system of your favorite distribution.

Please notice Pylint 1.3 will be the last release branch support python 2.5 and 2.6. Starting from 1.4, we will only support python greater or equal to 2.7. This will be the occasion to do some great cleanup in the code base. Notice this is only about the Pylint's runtime, you should still be able to run Pylint on your Python 2.5 code, through using Python 2.7 at least.

New checks

Add multiple checks for PEP 3101 advanced string formatting: 'bad-format-string', 'missing-format-argument-key', 'unused-format-string-argument', 'format-combined-specification', 'missing-format-attribute' and 'invalid-format-index'
New 'invalid-slice-index' and 'invalid-sequence-index' for invalid sequence and slice indices
New 'assigning-non-slot' warning, which detects assignments to attributes not defined in slots

Improved checkers

Fixed 'fixme' false positive (#149)
Fixed 'unbalanced-iterable-unpacking' false positive when encountering starred nodes (#273)
Fixed 'bad-format-character' false positive when encountering the 'a' format on Python 3
Fixed 'unused-variable' false positive when the variable is assigned through an import (#196)
Fixed 'unused-variable' false positive when assigning to a nonlocal (#275)
Fixed 'pointless-string-statement' false positive for attribute docstrings (#193)
Emit 'undefined-variable' when using the Python 3 metaclass= argument. Also fix 'unused-import' false for that construction (#143)
Emit 'broad-except' and 'bare-except' even if the number of except handlers is different than 1. Fixes issue (#113)
Emit 'attribute-defined-outside-init' for all statements in the same module as the offended class, not just for the last assignment (#262, as well as a long standing output mangling problem in some edge cases)
Emit 'not-callable' when calling properties (#268)
Don't let ImportError propagate from the imports checker, leading to crash in some namespace package related cases (#203)
Don't emit 'no-name-in-module' for ignored modules (#223)
Don't emit 'unnecessary-lambda' if the body of the lambda call contains call chaining (#243)
Definition order is considered for classes, function arguments and annotations (#257)
Only emit 'attribute-defined-outside-init' for definition within the same module as the offended class, avoiding to mangle the output in some cases
Don't emit 'hidden-method' message when the attribute has been monkey-patched, you're on your own when you do that.

Others changes

Checkers are now properly ordered to respect priority(#229)
Use the proper mode for pickle when opening and writing the stats file (#148)

Astroid changes

Function nodes can detect decorator call chain and see if they are decorated with builtin descriptors (classmethod and staticmethod).
infer_call_result called on a subtype of the builtin type will now return a new Class rather than an Instance.
Class.metaclass() now handles module-level __metaclass__ declaration on python 2, and no longer looks at the __metaclass__ class attribute on python 3.
Add slots method to Class nodes, for retrieving the list of valid slots it defines.
Expose function annotation to astroid: Arguments node exposes 'varargannotation', 'kwargannotation' and 'annotations' attributes, while Function node has the 'returns' attribute.
Backported most of the logilab.common.modutils module there, as most things there are for pylint/astroid only and we want to be able to fix them without requiring a new logilab.common release
Fix names grabed using wildcard import in "absolute import mode" (i.e. with absolute_import activated from the __future__ or with python 3) (pylint issue #58)
Add support in brain for understanding enum classes.

28 Jul 2014 3:21pm GMT

Here are the list of things we managed to achieve during those last two days at EuroPython.

After several attempts, Michal managed to have pylint running analysis on several files in parallel. This is still in a pull request (https://bitbucket.org/logilab/pylint/pull-request/82/added-support-for-checking-files-in) because of some limitations, so we decided it won't be part of the 1.3 release.

Claudiu killed maybe 10 bugs or so and did some heavy issues cleanup in the trackers. He also demonstrated some experimental support of python 3 style annotation to drive a better inference. Pretty exciting! Torsten also killed several bugs, restored python 2.5 compat (though that will need a logilab-common release as well), introduced a new functional test framework that will replace the old one once all the existing tests will be backported. On wednesday, he did show us a near future feature they already have at Google: some kind of confidence level associated to messages so that you can filter out based on that. Sylvain fixed a couple of bugs (including https://bitbucket.org/logilab/pylint/issue/58/ which was annoying all the numpy community), started some refactoring of the PyLinter class so it does a little bit fewer things (still way too many though) and attempted to improve the pylint note on both pylint and astroid, which went down recently "thanks" to the new checks like 'bad-continuation'.

Also, we merged the pylint-brain project into astroid to simplify things, so you should now submit your brain plugins directly to the astroid project. Hopefuly you'll be redirected there on attempt to use the old (removed) pylint-brain project on bitbucket.

And, the good news is that now both Torsten and Claudiu have new powers: they should be able to do some releases of pylint and astroid. To celebrate that and the end of the sprint, we published Pylint 1.3 together with Astroid 1.2. More on this here.

28 Jul 2014 3:21pm GMT

Here are the list of things we managed to achieve during those last two days at EuroPython.

After several attempts, Michal managed to have pylint running analysis on several files in parallel. This is still in a pull request (https://bitbucket.org/logilab/pylint/pull-request/82/added-support-for-checking-files-in) because of some limitations, so we decided it won't be part of the 1.3 release.

Claudiu killed maybe 10 bugs or so and did some heavy issues cleanup in the trackers. He also demonstrated some experimental support of python 3 style annotation to drive a better inference. Pretty exciting! Torsten also killed several bugs, restored python 2.5 compat (though that will need a logilab-common release as well), introduced a new functional test framework that will replace the old one once all the existing tests will be backported. On wednesday, he did show us a near future feature they already have at Google: some kind of confidence level associated to messages so that you can filter out based on that. Sylvain fixed a couple of bugs (including https://bitbucket.org/logilab/pylint/issue/58/ which was annoying all the numpy community), started some refactoring of the PyLinter class so it does a little bit fewer things (still way too many though) and attempted to improve the pylint note on both pylint and astroid, which went down recently "thanks" to the new checks like 'bad-continuation'.

Also, we merged the pylint-brain project into astroid to simplify things, so you should now submit your brain plugins directly to the astroid project. Hopefuly you'll be redirected there on attempt to use the old (removed) pylint-brain project on bitbucket.

And, the good news is that now both Torsten and Claudiu have new powers: they should be able to do some releases of pylint and astroid. To celebrate that and the end of the sprint, we published Pylint 1.3 together with Astroid 1.2. More on this here.

28 Jul 2014 3:21pm GMT

My book, Practical Maya Programming with Python has been finally published! Please check it out and tell me what you think. I hope you will find it sufficiently-but-not-overly opinionated :) It is about as personal as a technical book can get, being distilled from years of mentoring many technical artists and programmers, which is a very intimate experience. It also grows from my belief and observation that becoming a better programmer will, due to all sorts of indirect benefits, help make you a better person.

If you are using Python as a scripting language in a larger application- a game engine, productivity software, 3D software, even a monolithic codebase that no longer feels like Python- there's a lot of relevant material here about turning those environments into more standard and traditional Python development environments, which give you better tools and velocity. The Maya knowledge required is minimal for much of the book. Wrapping a procedural undo system with context managers or decorators is universal. A short quote from the Preface:

This book is not a reference. It is not a cookbook, and it is not a comprehensive guide to Maya's Python API. It is a book that will teach you how to write better Python code for use inside of Maya. It will unearth interesting ways of using Maya and Python to create amazing things that wouldn't be possible otherwise. While there is plenty of code in this book that I encourage you to copy and adapt, this book is not about providing recipes. It is a book to teach skills and enable.

Finally, to those who pre-ordered, I'm truly sorry for all the delays. They're unacceptable. I hope you'll buy and enjoy the book anyway. At least I now have a real-world education on the perils of working with the wrong publisher, and won't be making that same mistake again.

Thanks and happy reading!
Rob Galanakis

28 Jul 2014 2:38pm GMT

My book, Practical Maya Programming with Python has been finally published! Please check it out and tell me what you think. I hope you will find it sufficiently-but-not-overly opinionated :) It is about as personal as a technical book can get, being distilled from years of mentoring many technical artists and programmers, which is a very intimate experience. It also grows from my belief and observation that becoming a better programmer will, due to all sorts of indirect benefits, help make you a better person.

If you are using Python as a scripting language in a larger application- a game engine, productivity software, 3D software, even a monolithic codebase that no longer feels like Python- there's a lot of relevant material here about turning those environments into more standard and traditional Python development environments, which give you better tools and velocity. The Maya knowledge required is minimal for much of the book. Wrapping a procedural undo system with context managers or decorators is universal. A short quote from the Preface:

This book is not a reference. It is not a cookbook, and it is not a comprehensive guide to Maya's Python API. It is a book that will teach you how to write better Python code for use inside of Maya. It will unearth interesting ways of using Maya and Python to create amazing things that wouldn't be possible otherwise. While there is plenty of code in this book that I encourage you to copy and adapt, this book is not about providing recipes. It is a book to teach skills and enable.

Finally, to those who pre-ordered, I'm truly sorry for all the delays. They're unacceptable. I hope you'll buy and enjoy the book anyway. At least I now have a real-world education on the perils of working with the wrong publisher, and won't be making that same mistake again.

Thanks and happy reading!
Rob Galanakis

28 Jul 2014 2:38pm GMT

This year we're trying something new, introductory workshops designed for beginners not attending the conference. It's an attempt by the Python community to reach out to the wider community. All of these workshops are being held at our venue partner, The Edge, part of the State Library of Queensland at South Brisbane.

DjangoGirls workshop (Monday 4th August, 9am-12pm)
Introduction to Programming in Python (Friday 1st August, 10am-4pm)
Introduction to Electronics in Python (Friday 1st August, 10am-4pm)

The full details of the workshops can be found at http://2014.pycon-au.org/programme/workshops

All of our workshops need mentors, please consider signing up as a mentor.

28 Jul 2014 1:41pm GMT

This year we're trying something new, introductory workshops designed for beginners not attending the conference. It's an attempt by the Python community to reach out to the wider community. All of these workshops are being held at our venue partner, The Edge, part of the State Library of Queensland at South Brisbane.

DjangoGirls workshop (Monday 4th August, 9am-12pm)
Introduction to Programming in Python (Friday 1st August, 10am-4pm)
Introduction to Electronics in Python (Friday 1st August, 10am-4pm)

The full details of the workshops can be found at http://2014.pycon-au.org/programme/workshops

All of our workshops need mentors, please consider signing up as a mentor.

28 Jul 2014 1:41pm GMT

I had a fun time at EuroPython 2014 in Berlin last week. It was a very well organized conference and I enjoyed meeting old friends again as well as meeting new people. Before I went I was a bit worried with the amount of attendees it'd feel too massive; I had that experience at a PyCon in the US a few years ago. But I was pleasantly surprised it didn't -- it felt like a smaller conference, and I liked it.

Another positive thing that stood out was a larger diversity; there seemed to be more people from central and eastern Europe there than before, and most of all, there were more women. It was underscored by a 13 year old girl giving a lightning talk -- that was just not going to happen at EuroPython 5 years ago.

This is a very positive trend and I hope it continues. I know it takes a lot of work on the part of the organizers to get this far.

I gave a talk at EuroPython myself this year, and I think it went well:

28 Jul 2014 12:00pm GMT

I had a fun time at EuroPython 2014 in Berlin last week. It was a very well organized conference and I enjoyed meeting old friends again as well as meeting new people. Before I went I was a bit worried with the amount of attendees it'd feel too massive; I had that experience at a PyCon in the US a few years ago. But I was pleasantly surprised it didn't -- it felt like a smaller conference, and I liked it.

Another positive thing that stood out was a larger diversity; there seemed to be more people from central and eastern Europe there than before, and most of all, there were more women. It was underscored by a 13 year old girl giving a lightning talk -- that was just not going to happen at EuroPython 5 years ago.

This is a very positive trend and I hope it continues. I know it takes a lot of work on the part of the organizers to get this far.

I gave a talk at EuroPython myself this year, and I think it went well:

28 Jul 2014 12:00pm GMT

Hearing a talk about static analysis at EuroPython 2014 and meeting Christian Heimes there (CPython core dev and member of the security response team) got us talking about running Coverty Scan on Cython generated code. They provide a free service for Open Source projects, most likely because there is a clear benefit in terms of marketing visibility and distributed filtering work on a large amount of code.

The problem with a source code generator is that you can only run the analyser on the generated code, so you need a real world project that uses the generator. The obvious choice for us was lxml, as it has a rather large code base with more than 230000 lines of C code, generated from some 20000 lines of Cython code. The first run against the latest lxml release got us about 1200 findings, but a quick glance through them showed that the bulk of them were false positives for the way Cython generates code for some Python constructs. There was also a large set of "dead code" findings that I had already worked on in Cython a couple of months ago. It now generates substantially less dead code. So I gave it another run against the current developer versions of both lxml and Cython.

The net result is that the number of findings went down to 428. A large subset of those relates to constant macros in conditions, which is what I use in lxml to avoid a need for C level #ifdefs. The C compiler is happy to discard this code, so Coverty's dead code finding is ok but not relevant. Other large sets of "dead code" findings are due to Cython generating generic error handling code in cases where an underlying C macro actually cannot fail, e.g. when converting a C boolean value to Python's constant True/False objects. So that's ok, too.

There seems to be a bug in the current Coverty analysis that gets confused by repeated C boolean checks, e.g.

((x == NULL) != 0)

Cython generates this additional check at the end to make sure that the integer result of a C boolean test is always 1 or 0 and nothing else. Coverty Scan currently seems to read it as

x == NULL && NULL != 0

and assumes that the result is always false because NULL != 0 is a constant false value.

It's also a bit funny that the tool complains about a single "{" being dead code, although it's followed immediately by a (used) label. That's not really an amount of code that I'd consider relevant for reporting.

On the upside, the tool found another couple of cases in the try-except implementation where Cython was generating dead code, so I was able to eliminate them. The advantage here is that a goto statement can be eliminated, which may leave the target label unused and can thus eliminate further code under that label that would be generated later but now can also be suppressed. Well, and generating less code is generally a good thing anyway.

Overall, the results make a really convincing case for Cython. Nothing of importance was found, and the few minor issues where Cython still generated more code than necessary could easily be eliminated, so that all projects that use the next version can just benefit. Compare that to manually written C extension code, where reference counting is a large source of errors and the verbose C-API of CPython makes the code substantially harder to get right and to maintain than the straight forward Python syntax and semantics of Cython. When run against the CPython code base for the first time, Coverty Scan found several actual bugs and even security issues. This also nicely matches the findings by David Malcolm and his GCC based analysis tool, who ended up using Cython generated code for eliminating false positives, rather than finding actual bugs in it.

28 Jul 2014 9:04am GMT

Hearing a talk about static analysis at EuroPython 2014 and meeting Christian Heimes there (CPython core dev and member of the security response team) got us talking about running Coverty Scan on Cython generated code. They provide a free service for Open Source projects, most likely because there is a clear benefit in terms of marketing visibility and distributed filtering work on a large amount of code.

The problem with a source code generator is that you can only run the analyser on the generated code, so you need a real world project that uses the generator. The obvious choice for us was lxml, as it has a rather large code base with more than 230000 lines of C code, generated from some 20000 lines of Cython code. The first run against the latest lxml release got us about 1200 findings, but a quick glance through them showed that the bulk of them were false positives for the way Cython generates code for some Python constructs. There was also a large set of "dead code" findings that I had already worked on in Cython a couple of months ago. It now generates substantially less dead code. So I gave it another run against the current developer versions of both lxml and Cython.

The net result is that the number of findings went down to 428. A large subset of those relates to constant macros in conditions, which is what I use in lxml to avoid a need for C level #ifdefs. The C compiler is happy to discard this code, so Coverty's dead code finding is ok but not relevant. Other large sets of "dead code" findings are due to Cython generating generic error handling code in cases where an underlying C macro actually cannot fail, e.g. when converting a C boolean value to Python's constant True/False objects. So that's ok, too.

There seems to be a bug in the current Coverty analysis that gets confused by repeated C boolean checks, e.g.

((x == NULL) != 0)

Cython generates this additional check at the end to make sure that the integer result of a C boolean test is always 1 or 0 and nothing else. Coverty Scan currently seems to read it as

x == NULL && NULL != 0

and assumes that the result is always false because NULL != 0 is a constant false value.

It's also a bit funny that the tool complains about a single "{" being dead code, although it's followed immediately by a (used) label. That's not really an amount of code that I'd consider relevant for reporting.

On the upside, the tool found another couple of cases in the try-except implementation where Cython was generating dead code, so I was able to eliminate them. The advantage here is that a goto statement can be eliminated, which may leave the target label unused and can thus eliminate further code under that label that would be generated later but now can also be suppressed. Well, and generating less code is generally a good thing anyway.

Overall, the results make a really convincing case for Cython. Nothing of importance was found, and the few minor issues where Cython still generated more code than necessary could easily be eliminated, so that all projects that use the next version can just benefit. Compare that to manually written C extension code, where reference counting is a large source of errors and the verbose C-API of CPython makes the code substantially harder to get right and to maintain than the straight forward Python syntax and semantics of Cython. When run against the CPython code base for the first time, Coverty Scan found several actual bugs and even security issues. This also nicely matches the findings by David Malcolm and his GCC based analysis tool, who ended up using Cython generated code for eliminating false positives, rather than finding actual bugs in it.

28 Jul 2014 9:04am GMT

In this post, we're going to give you a user-friendly introduction to Python decorators. (The code works on both Python 2 [2.6 or 2.7 only] and 3 so don't be concerned with your version.) Before jumping into the topic du jour, consider the usefulness of the map() function. You've got a list with some data and want to apply some function [like times2() below] to all its elements and get a new list with the modified data:

def times2(x):
return x * 2

>>> list(map(times2, [0, 1, 2, 3, 4]))
[0, 2, 4, 6, 8]

Yeah yeah, I know that you can do the same thing with a list comprehension or generator expression, but my point was about an independent piece of logic [like times2()] and mapping that function across a data set ([0, 1, 2, 3, 4]) to generate a new data set ([0, 2, 4, 6, 8]). However, since mapping functions like times2()aren't tied to any particular chunk of data, you can reuse them elsewhere with other unrelated (or related) data.

Along similar lines, consider function calls. You have independent functions and methods in classes. Now, think about "mapped" execution across functions. What are things that you can do with functions that don't have much to do with the behavior of the functions themselves? How about logging function calls, timing them, or some other introspective, cross-cutting behavior. Sure you can implement that behavior in each of the functions that you care about such information, however since they're so generic, it would be nice to only write that logging code just once.

Introduced in 2.4, decorators modularize cross-cutting behavior so that developers don'thave to implement near duplicates of the same piece of code for each function. Rather, Python gives them the ability to put that logic in one place and use decorators with its at-sign ("@") syntax to "map" that behavior to any function (or method). This compartmentalization of cross-cutting functionality gives Python an aspect-oriented programming flavor.

How do you do this in Python? Let's take a look at a simple example, the logging of function calls. Create a decorator function that takes a function object as its sole argument, and implement the cross-cutting functionality. In logged() below, we're just going to log function calls by making a call to the print() function each time a logged function is called.

def logged(_func):

def _wrapped():
print('Function %r called at: %s' % (

_func.__name__, ctime()))

return _func()
return _wrapped

In logged(), we use the function's name (given by func.__name__) plus a timestamp from time.ctime() to build our output string. Make sure you get the right imports, time.ctime() for sure, and if using Python 2, the print() function:

from __future__ import print_function # 2.6 or 2.7 only
from time import ctime

Now that we have our logged() decorator, how do we use it? On the line above the function which you want to apply the decorator to, place an at-sign in front of the decorator name. That's followed immediately on the next line with the normal function declaration. Here's what it looks like, applied to a boring generic foo() function which just print()s it's been called.

@logged

def foo():

print('foo() called')

When you call foo(), you can see that the decorator logged()is called first, which then calls foo() on your behalf:

$ log_func.py

Function 'foo' called at: Sun Jul 27 04:09:37 2014

foo() called

If you take a closer look at logged() above, the way the decorator works is that the decorated function is "wrapped" so that it is passed as func to the decorator then the newly-wrapped function _wrapped()is (re)assigned as foo(). That's why it now behaves the way it does when you call it.

The entire script:

#!/usr/bin/env python
'log_func.py -- demo of decorators'

from __future__ import print_function # 2.6 or 2.7 only
from time import ctime

def logged(_func):
def _wrapped():
print('Function %r called at: %s' % (
_func.__name__, ctime()))
return _func()
return _wrapped

@logged
def foo():
print('foo() called')

foo()

That was just a simple example to give you an idea of what decorators are. If you dig a little deeper, you'll discover one caveat is that the wrapping isn't perfect. For example, the attributes of foo() are lost, i.e., its name and docstring. If you ask for either, you'll get _wrapped()'s info instead:

>>> print("My name:", foo.__name__) # should be 'foo'!
My name: _wrapped
>>> print("Docstring:", foo.__doc__) # _wrapped's docstring!
Docstring: None

In reality, the "@" syntax is just a shortcut. Here's what you really did, which should explain this behavior:

def foo():

print('foo() called')

foo = logged(foo) # returns _wrapped (and its attributes)

So as you can tell, it's not a complete wrap. A convenience function that ties up these loose ends is functools.wraps(). If you use it and run the same code, you will get foo()'s info. However, if you're not going to use a function's attributes while it's wrapped, it's less important to do this.

There's also support for additional features, such calling decorated functions with parameters, applying more complex decorators, applying multiple levels of decorators, and also class decorators. You can find out more about (function and method) decorators in Chapter 11 of Core Python Programming or live in my upcoming course which starts in just a few days near the San Francisco airport... there are still a few seats left!

27 Jul 2014 5:09pm GMT

In this post, we're going to give you a user-friendly introduction to Python decorators. (The code works on both Python 2 [2.6 or 2.7 only] and 3 so don't be concerned with your version.) Before jumping into the topic du jour, consider the usefulness of the map() function. You've got a list with some data and want to apply some function [like times2() below] to all its elements and get a new list with the modified data:

def times2(x):
return x * 2

>>> list(map(times2, [0, 1, 2, 3, 4]))
[0, 2, 4, 6, 8]

Yeah yeah, I know that you can do the same thing with a list comprehension or generator expression, but my point was about an independent piece of logic [like times2()] and mapping that function across a data set ([0, 1, 2, 3, 4]) to generate a new data set ([0, 2, 4, 6, 8]). However, since mapping functions like times2()aren't tied to any particular chunk of data, you can reuse them elsewhere with other unrelated (or related) data.

Along similar lines, consider function calls. You have independent functions and methods in classes. Now, think about "mapped" execution across functions. What are things that you can do with functions that don't have much to do with the behavior of the functions themselves? How about logging function calls, timing them, or some other introspective, cross-cutting behavior. Sure you can implement that behavior in each of the functions that you care about such information, however since they're so generic, it would be nice to only write that logging code just once.

Introduced in 2.4, decorators modularize cross-cutting behavior so that developers don'thave to implement near duplicates of the same piece of code for each function. Rather, Python gives them the ability to put that logic in one place and use decorators with its at-sign ("@") syntax to "map" that behavior to any function (or method). This compartmentalization of cross-cutting functionality gives Python an aspect-oriented programming flavor.

How do you do this in Python? Let's take a look at a simple example, the logging of function calls. Create a decorator function that takes a function object as its sole argument, and implement the cross-cutting functionality. In logged() below, we're just going to log function calls by making a call to the print() function each time a logged function is called.

def logged(_func):

def _wrapped():
print('Function %r called at: %s' % (

_func.__name__, ctime()))

return _func()
return _wrapped

In logged(), we use the function's name (given by func.__name__) plus a timestamp from time.ctime() to build our output string. Make sure you get the right imports, time.ctime() for sure, and if using Python 2, the print() function:

from __future__ import print_function # 2.6 or 2.7 only
from time import ctime

Now that we have our logged() decorator, how do we use it? On the line above the function which you want to apply the decorator to, place an at-sign in front of the decorator name. That's followed immediately on the next line with the normal function declaration. Here's what it looks like, applied to a boring generic foo() function which just print()s it's been called.

@logged

def foo():

print('foo() called')

When you call foo(), you can see that the decorator logged()is called first, which then calls foo() on your behalf:

$ log_func.py

Function 'foo' called at: Sun Jul 27 04:09:37 2014

foo() called

If you take a closer look at logged() above, the way the decorator works is that the decorated function is "wrapped" so that it is passed as func to the decorator then the newly-wrapped function _wrapped()is (re)assigned as foo(). That's why it now behaves the way it does when you call it.

The entire script:

#!/usr/bin/env python
'log_func.py -- demo of decorators'

from __future__ import print_function # 2.6 or 2.7 only
from time import ctime

def logged(_func):
def _wrapped():
print('Function %r called at: %s' % (
_func.__name__, ctime()))
return _func()
return _wrapped

@logged
def foo():
print('foo() called')

foo()

That was just a simple example to give you an idea of what decorators are. If you dig a little deeper, you'll discover one caveat is that the wrapping isn't perfect. For example, the attributes of foo() are lost, i.e., its name and docstring. If you ask for either, you'll get _wrapped()'s info instead:

>>> print("My name:", foo.__name__) # should be 'foo'!
My name: _wrapped
>>> print("Docstring:", foo.__doc__) # _wrapped's docstring!
Docstring: None

In reality, the "@" syntax is just a shortcut. Here's what you really did, which should explain this behavior:

def foo():

print('foo() called')

foo = logged(foo) # returns _wrapped (and its attributes)

So as you can tell, it's not a complete wrap. A convenience function that ties up these loose ends is functools.wraps(). If you use it and run the same code, you will get foo()'s info. However, if you're not going to use a function's attributes while it's wrapped, it's less important to do this.

There's also support for additional features, such calling decorated functions with parameters, applying more complex decorators, applying multiple levels of decorators, and also class decorators. You can find out more about (function and method) decorators in Chapter 11 of Core Python Programming or live in my upcoming course which starts in just a few days near the San Francisco airport... there are still a few seats left!

27 Jul 2014 5:09pm GMT

Thank you for your suggestion. In our General Assembly at EuroPython 2014 we have just voted on updating the bylaws to also use the "EPS" abbreviation.

We will update the website in the coming days.

Enjoy,
-
EuroPython Society

27 Jul 2014 11:30am GMT

Thank you for your suggestion. In our General Assembly at EuroPython 2014 we have just voted on updating the bylaws to also use the "EPS" abbreviation.

We will update the website in the coming days.

Enjoy,
-
EuroPython Society

27 Jul 2014 11:30am GMT

I am still looking for a good e-mail replacement that is more respectful of my privacy.

This will never happen with the existing e-mail system due to the way it works: when you send an e-mail to someone, even if you encrypt the body of your e-mail, the metadata will transit from server to server in clear, and the final destination will store it.

Every PGP UX I have tried is terrible anyways. It's just too painful to get things right for someone that has no knowledge (and no desire to have some) of how things work.

What I aiming for now is a separate system to send and receive mails with my close friends and my family. Something that my mother can use like regular e-mails, without any extra work.

I guess some kind of "Darknet for E-mails" where they are no intermediate servers between my mailbox and my mom's mailbox, and no way for a eavesdropper to get the content.

Ideally:

end-to-end encryption
direct network link between my mom's mail server and me
based on existing protocols (SMTP/IMAP/POP3) so my mom can use Thunderbird or I can set her up a Zimbra server.

Project Tox

The Tox Project is a project that aims to replace Skype with a more secured instant messaging system. You can send text, voice and even video messages to your friends.

It's based on NaCL for the crypto bits and in particular the crypto_box API which provides high-level functions to generate public/private key pairs and encrypt/decrypt messages with it.

The other main feature of Tox is its Distributed Hash Table that contains the list of nodes that are connected to the network with their Tox Id.

When you run a Tox-based application, you become part of the Tox network by registering to a few known public nodes.

To send a message to someone, you have to know their Tox Id and send a crypted message using the crypto_box api and the keypair magic.

Tox was created as an instant messaging system, so it has features to add/remove/invite friends, create groups etc. but its core capability is to let you reach out another node given its id, and communicate with it. And that can be any kind of communication.

So e-mails could transit through Tox nodes.

Toxmail experiment

Toxmail is my little experiment to build a secure e-mail system on the top of Tox.

It's a daemon that registers to the Tox network and runs an SMTP service that converts outgoing e-mails to text messages that are sent through Tox. It also converts incoming text messages back into e-mails and stores them in a local Maildir.

Toxmail also runs a simple POP3 server, so it's actually a full stack that can be used through an e-mail client like Thunderbird.

You can just create a new account in Thunderbird, point it to the Toxmail SMPT and POP3 local services, and use it like another e-mail account.

When you want to send someone an e-mail, you have to know their Tox Id, and use TOXID@tox as the recipient.

For example:

7F9C31FE850E97CEFD4C4591DF93FC757C7C12549DDD55F8EEAECC34FE76C029@tox

When the SMTP daemon sees this, it tries to send the e-mail to that Tox-ID. What I am planning to do is to have an automatic conversion of regular e-mails using a lookup table the user can maintain. A list of contacts where you provide for each entry an e-mail and a tox id.

End-to-end encryption, no intermediates between the user and the recipient. Ya!

Caveats & Limitations

For ToxMail to work, it needs to be registered to the Tox network all the time.

This limitation can be partially solved by adding in the SMTP daemon a retry feature: if the recipient's node is offline, the mail is stored and it tries to send it later.

But for the e-mail to go through, the two nodes have to be online at the same time at some point.

Maybe a good way to solve this would be to have Toxmail run into a Raspberry-PI plugged into the home internet box. That'd make sense actually: run your own little mail server for all your family/friends conversations.

One major problem though is what to do with e-mails that are to be sent to recipients that are part of your toxmail contact list, but also to recipients that are not using Toxmail. I guess the best thing to do is to fallback to the regular routing in that case, and let the user know.

Anyways, lots of fun playing with this on my spare time.

The prototype is being built here, using Python and the PyTox binding:

https://github.com/tarekziade/toxmail

It has reached a state where you can actually send and receive e-mails :)

I'd love to have feedback on this little project.

26 Jul 2014 11:22am GMT

I am still looking for a good e-mail replacement that is more respectful of my privacy.

This will never happen with the existing e-mail system due to the way it works: when you send an e-mail to someone, even if you encrypt the body of your e-mail, the metadata will transit from server to server in clear, and the final destination will store it.

Every PGP UX I have tried is terrible anyways. It's just too painful to get things right for someone that has no knowledge (and no desire to have some) of how things work.

What I aiming for now is a separate system to send and receive mails with my close friends and my family. Something that my mother can use like regular e-mails, without any extra work.

I guess some kind of "Darknet for E-mails" where they are no intermediate servers between my mailbox and my mom's mailbox, and no way for a eavesdropper to get the content.

Ideally:

end-to-end encryption
direct network link between my mom's mail server and me
based on existing protocols (SMTP/IMAP/POP3) so my mom can use Thunderbird or I can set her up a Zimbra server.

Project Tox

The Tox Project is a project that aims to replace Skype with a more secured instant messaging system. You can send text, voice and even video messages to your friends.

It's based on NaCL for the crypto bits and in particular the crypto_box API which provides high-level functions to generate public/private key pairs and encrypt/decrypt messages with it.

The other main feature of Tox is its Distributed Hash Table that contains the list of nodes that are connected to the network with their Tox Id.

When you run a Tox-based application, you become part of the Tox network by registering to a few known public nodes.

To send a message to someone, you have to know their Tox Id and send a crypted message using the crypto_box api and the keypair magic.

Tox was created as an instant messaging system, so it has features to add/remove/invite friends, create groups etc. but its core capability is to let you reach out another node given its id, and communicate with it. And that can be any kind of communication.

So e-mails could transit through Tox nodes.

Toxmail experiment

Toxmail is my little experiment to build a secure e-mail system on the top of Tox.

It's a daemon that registers to the Tox network and runs an SMTP service that converts outgoing e-mails to text messages that are sent through Tox. It also converts incoming text messages back into e-mails and stores them in a local Maildir.

Toxmail also runs a simple POP3 server, so it's actually a full stack that can be used through an e-mail client like Thunderbird.

You can just create a new account in Thunderbird, point it to the Toxmail SMPT and POP3 local services, and use it like another e-mail account.

When you want to send someone an e-mail, you have to know their Tox Id, and use TOXID@tox as the recipient.

For example:

7F9C31FE850E97CEFD4C4591DF93FC757C7C12549DDD55F8EEAECC34FE76C029@tox

When the SMTP daemon sees this, it tries to send the e-mail to that Tox-ID. What I am planning to do is to have an automatic conversion of regular e-mails using a lookup table the user can maintain. A list of contacts where you provide for each entry an e-mail and a tox id.

End-to-end encryption, no intermediates between the user and the recipient. Ya!

Caveats & Limitations

For ToxMail to work, it needs to be registered to the Tox network all the time.

This limitation can be partially solved by adding in the SMTP daemon a retry feature: if the recipient's node is offline, the mail is stored and it tries to send it later.

But for the e-mail to go through, the two nodes have to be online at the same time at some point.

Maybe a good way to solve this would be to have Toxmail run into a Raspberry-PI plugged into the home internet box. That'd make sense actually: run your own little mail server for all your family/friends conversations.

One major problem though is what to do with e-mails that are to be sent to recipients that are part of your toxmail contact list, but also to recipients that are not using Toxmail. I guess the best thing to do is to fallback to the regular routing in that case, and let the user know.

Anyways, lots of fun playing with this on my spare time.

The prototype is being built here, using Python and the PyTox binding:

https://github.com/tarekziade/toxmail

It has reached a state where you can actually send and receive e-mails :)

I'd love to have feedback on this little project.

26 Jul 2014 11:22am GMT

Zero to hero

What Prompted me??

I started my third year thinking I should do something that would put me different from the rest and one of my professors suggested me as to why don't I apply for GSoC. I don't know why but I took the suggestion rather seriously, thanks to the bet I had with one of my friend(who is about to complete his MBBS) that whoever earns first will buy the other a "RayBan shades". Well, that's it. I was determined. I started my research early, probably during the start of February(I knew I want to buy my friend, his shades and also buy mine too, in the process).

What experiences I had before??

I started looking at previous years' GSoC projects(having had little experience with Open Source) and started learning how to contribute. I was also very fascinated to the amount of knowledge one could gain just by googling and browsing web pages . I discovered very soon, as to what an immensely great tool , email, through which I could chat with anyone in the open source world and ask seemingly stupid questions and always expect to get a gentle reply back with an answer. Well, that held me spell bound and I knew I want to contribute to Open Source.

How did I begin??

About the middle of March, I discovered that my passion for Python as a programming language increased , after understanding how easy it is as a language. Added to that, my popularity among my fellow classmates increased when I started evangelizing Python(thanks to my seniors for introducing it, I guess I did a decent job popularizing the language). And I started contributing to PSF(Python Software Foundation) , started with a simple bug to fix documentation and slowly my interactivity in IRC increased and I started liking one of the project one of the community member proposed.

A twist in the story??

There I was, still a noob and not knowing how to convince my probable mentor that I could complete the project, given direction. About this juncture, a fellow student(from some university in France) mailed this particular mentor that he was interested in the project . Do, remember, I was part of the mailing list and follow the happenings of it. So, I was furious knowing that I had a competition(having put so much effort) and I was not willing to compromise my project (knowing that this is the one project I actually understood and started researching a little bit too). The other projects require me to have some domain knowledge. I went back to my teachers, seniors, friends and Google and started asking the question , "how would i solve the problem the mentor posted?" . I framed a couple of answers, though very noobish , but at least I could reply the email thread posting my understanding of the problem and how I would solve it and also ask various questions I had in my mind. Well, the mentor replied, immediately to my surprise, and responded back with comments as well as answers to the questions I posed. Again, my nemesis/competitor replied back(he having good knowledge about the problem domain). I knew it was not going to be easy. Hence, I went back again, through all my sources, made further understanding of the problem and posted back again. I guess, about 20 mails in the thread , till we(all three of us) decided we should catch up in IRC and discuss more.

The conclusion:

Well, at IRC , most of senior members from the community were present, and they suggested that they should probably extend the scope of the project(since two students were interested in one project and showed immense passion). Unsurprisingly, over multiple meetings, the project scope was expanded, both the students were given equal important but independent tasks and both the students got opportunity to say they are Google Summer of Code students. Thank goodness, we decided to built the project from scratch giving us more than enough work on our plate.

Movie titles:

1) In the open source world, there is no competition , it is only "COLLABORATION".

2) Why give up, when you can win??

3) From Zero to Hero!!

4) A prodigy in making

p.s. I still owe my friend his shades . *sshole, I am still waiting for him to visit me so that I can buy him his shades and buy mine too. Also, I know its been two years since the story happened, but it is never too late to share, don't you agree??

11 Oct 2013 5:39am GMT

fidzu : Python

29 Jul 2014

Easy

Background

Examples

Demo

Background

Examples

Rewrite

Background

Examples

Company name

Background

Examples

Easy

Background

Examples

Demo

Background

Examples

Rewrite

Background

Examples

Company name

Background

Examples

Using the sh library

Advanced Gymnastics

Conclusions

Using the sh library

Advanced Gymnastics

Conclusions

IPython Notebook

Part 2 - Embedding ChartJS

IPython Notebook

Part 2 - Embedding ChartJS

28 Jul 2014

27 Jul 2014

26 Jul 2014

Project Tox

Toxmail experiment

Caveats & Limitations

Project Tox

Toxmail experiment

Caveats & Limitations

11 Oct 2013

fidzu channels