This document is the recommended first read if you are interested in using Nuitka, understand its use cases, check what you can expect, license, requirements, credits, etc.
Nuitka is the Python compiler. It is written in Python. It is a seamless replacement or extension to the Python interpreter and compiles every construct that CPython 2.6, 2.7, 3.3, 3.4, 3.5, 3.6, 3.7, 3.8, 3.9, 3.10, 3.11 have, when itself run with that Python version.
It then executes uncompiled code and compiled code together in an extremely compatible manner.
You can use all Python library modules and all extension modules freely.
Nuitka translates the Python modules into a C level program that then
uses libpython
and static C files of its own to execute in the same
way as CPython does.
All optimization is aimed at avoiding overhead, where it's unnecessary. None is aimed at removing compatibility, although slight improvements will occasionally be done, where not every bug of standard Python is emulated, e.g. more complete error messages are given, but there is a full compatibility mode to disable even that.
C Compiler: You need a compiler with support for C11 or alternatively for C++03 [1]
Currently this means, you need to use one of these compilers:
- The MinGW64 C11 compiler on Windows, must be based on gcc 11.2 or higher. It will be automatically downloaded if no usable C compiler is found, which is the recommended way of installing it, as Nuitka will also upgrade it for you.
- Visual Studio 2022 or higher on Windows [2], older versions will work but only supported for commercial users. Configure to use the English language pack for best results (Nuitka filters away garbage outputs, but only for English language). It will be used by default if installed.
- On all other platforms, the
gcc
compiler of at least version 5.1, and below that theg++
compiler of at least version 4.4 as an alternative. - The
clang
compiler on macOS X and most FreeBSD architectures. - On Windows the
clang-cl
compiler on Windows can be used if provided by the Visual Studio installer.
Python: Version 2.6, 2.7 or 3.3, 3.4, 3.5, 3.6, 3.7, 3.8, 3.9, 3.10, 3.11
Important
For Python 3.3/3.4 and only those, we need other Python version as a compile time dependency.
Nuitka itself is fully compatible with all listed versions, but Scons as an internally used tool is not.
For these versions, you need a Python2 or Python 3.5 or higher installed as well, but only during the compile time only. That is for use with Scons (which orchestrates the C compilation), which does not support the same Python versions as Nuitka.
In addition, on Windows, Python2 cannot be used because
clcache
does not work with it, there a Python 3.5 or higher needs to be installed.Nuitka finds these needed Python versions (e.g. on Windows via registry) and you shouldn't notice it as long as they are installed.
Increasingly, other functionality is available when another Python has a certain package installed. For example, onefile compression will work for a Python 2.x when another Python is found that has the
zstandard
package installed.Moving binaries to other machines
The created binaries can be made executable independent of the Python installation, with
--standalone
and--onefile
options.Binary filename suffix
The created binaries have an
.exe
suffix on Windows. On other platforms they have no suffix for standalone mode, or.bin
suffix, that you are free to remove or change, or specify with the-o
option.The suffix for acceleration mode is added just to be sure that the original script name and the binary name do not ever collide, so we can safely do an overwrite without destroying the original source file.
It has to be CPython, Anaconda Python, or Homebrew
You need the standard Python implementation, called "CPython", to execute Nuitka, because it is closely tied to implementation details of it.
It cannot be from Windows app store
It is known that Windows app store Python definitely does not work, it's checked against.
It cannot be pyenv on macOS
It is know that macOS "pyenv" does not work. Use Homebrew instead for self compiled Python installations. But note that standalone mode will be worse on these platforms and not be as backward compatible with older macOS versions.
Operating System: Linux, FreeBSD, NetBSD, macOS X, and Windows (32bits/64 bits/ARM).
Others may work as well. The portability is expected to be generally good, but the e.g. Scons usage may have to be adapted. Make sure to match Windows Python and C compiler architecture, or else you will get cryptic error messages.
Architectures: x86, x86_64 (amd64), and arm, likely many more
Other architectures are expected to also work, out of the box, as Nuitka is generally not using any hardware specifics. These are just the ones tested and known to be good. Feedback is welcome. Generally, the architectures that Debian supports can be considered good and tested too.
[1] | Support for this C11 is a given with gcc 5.x or higher or any clang version. The MSVC compiler doesn't do it yet. But as a workaround, as the C++03 language standard is very overlapping with C11, it is then used instead where the C compiler is too old. Nuitka used to require a C++ compiler in the past, but it changed. |
[2] | Download for free from https://www.visualstudio.com/en-us/downloads/download-visual-studio-vs.aspx (the community editions work just fine). The latest version is recommended but not required. On the other hand, there is no need to except to support pre-Windows 10 versions, and they might work for you, but support of these configurations is only available to commercial users. |
The recommended way of executing Nuitka is <the_right_python> -m
nuitka
to be absolutely certain which Python interpreter you are
using, so it is easier to match with what Nuitka has.
The next best way of executing Nuitka bare that is from a source
checkout or archive, with no environment variable changes, most
noteworthy, you do not have to mess with PYTHONPATH
at all for
Nuitka. You just execute the nuitka
and nuitka-run
scripts
directly without any changes to the environment. You may want to add the
bin
directory to your PATH
for your convenience, but that step
is optional.
Moreover, if you want to execute with the right interpreter, in that
case, be sure to execute <the_right_python> bin/nuitka
and be good.
Pick the right Interpreter
If you encounter a SyntaxError
you absolutely most certainly have
picked the wrong interpreter for the program you are compiling.
Nuitka has a --help
option to output what it can do:
nuitka --help
The nuitka-run
command is the same as nuitka
, but with a
different default. It tries to compile and directly execute a Python
script:
nuitka-run --help
This option that is different is --run
, and passing on arguments
after the first non-option to the created binary, so it is somewhat more
similar to what plain python
will do.
For most systems, there will be packages on the download page of Nuitka. But you can also
install it from source code as described above, but also like any other
Python program it can be installed via the normal python setup.py
install
routine.
Nuitka is licensed under the Apache License, Version 2.0; you may not use it except in compliance with the License.
You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.
This is basic steps if you have nothing installed, of course if you have any of the parts, just skip it.
- Download and install Python from https://www.python.org/downloads/windows
- Select one of
Windows x86-64 web-based installer
(64 bits Python, recommended) orx86 executable
(32 bits Python) installer. - Verify it's working using command
python --version
.
python -m pip install nuitka
- Verify using command
python -m nuitka --version
mkdir
HelloWorld- make a python file named hello.py
def talk(message):
return "Talk " + message
def main():
print(talk("Hello World"))
if __name__ == "__main__":
main()
Do as you normally would. Running Nuitka on code that works incorrectly is not easier to debug.
python hello.py
python -m nuitka hello.py
Note
This will prompt you to download a C caching tool (to speed up
repeated compilation of generated C code) and a MinGW64 based C
compiler unless you have a suitable MSVC installed. Say yes
to
both those questions.
Execute the hello.exe
created near hello.py
.
To distribute, build with --standalone
option, which will not output
a single executable, but a whole folder. Copy the resulting
hello.dist
folder to the other machine and run it.
You may also try --onefile
which does create a single file, but make
sure that the mere standalone is working, before turning to it, as it
will make the debugging only harder, e.g. in case of missing data files.
If you want to compile a whole program recursively, and not only the single file that is the main program, do it like this:
python -m nuitka --follow-imports program.py
Note
There are more fine grained controls than --follow-imports
available. Consider the output of nuitka --help
. Including less
modules into the compilation, but instead using normal Python for it
will make it faster to compile.
In case you have a source directory with dynamically loaded files, i.e.
one which cannot be found by recursing after normal import statements
via the PYTHONPATH
(which would be the recommended way), you can
always require that a given directory shall also be included in the
executable:
python -m nuitka --follow-imports --include-plugin-directory=plugin_dir program.py
Note
If you don't do any dynamic imports, simply setting your
PYTHONPATH
at compilation time is what you should do.
Use --include-plugin-directory
only if you make __import__()
calls that Nuitka cannot predict, because they e.g. depend on command
line parameters. Nuitka also warns about these, and point to the
option.
Note
The resulting filename will be program.exe
on Windows,
program.bin
on other platforms.
Note
The resulting binary still depend on CPython and used C extension modules being installed.
If you want to be able to copy it to another machine, use
--standalone
and copy the created program.dist
directory and
execute the program.exe
(Windows) or program
(other
platforms) put inside.
If you want to compile a single extension module, all you have to do is this:
python -m nuitka --module some_module.py
The resulting file some_module.so
can then be used instead of
some_module.py
.
Important
The filename of the produced extension module must not be changed as
Python insists on a module name derived function as an entry point,
in this case PyInit_some_module
and renaming the file will not
change that. Match the filename of the source code what the binary
name should be.
Note
If both the extension module and the source code of it are in the same directory, the extension module is loaded. Changes to the source code only have effect once you recompile.
Note
The option --follow-import-to
and work as well, but the included
modules will only become importable after you imported the
some_module
name. If these kinds of imports are invisible to
Nuitka, e.g. dynamically created, you can use --include-module
or
--include-package
in that case, but for static imports it should
not be needed.
Note
An extension module can never include other extension modules. You will have to create a wheel for this to be doable.
Note
The resulting extension module can only be loaded into a CPython of the same version and doesn't include other extension modules.
If you need to compile a whole package and embed all modules, that is also feasible, use Nuitka like this:
python -m nuitka --module some_package --include-package=some_package
Note
The inclusion of the package contents needs to be provided manually,
otherwise, the package is mostly empty. You can be more specific if
you want, and only include part of it, or exclude part of it, e.g.
with --nofollow-import-to='*.tests'
you would not include the
unused test part of your code.
Note
Data files located inside the package will not be embedded by this process, you need to copy them yourself with this approach. Alternatively you can use the file embedding of Nuitka commercial.
For distribution to other systems, there is the standalone mode which
produces a folder for which you can specify --standalone
.
python -m nuitka --standalone program.py
Following all imports is default in this mode. You can selectively
exclude modules by specifically saying --nofollow-import-to
, but
then an ImportError
will be raised when import of it is attempted at
program run time. This may cause different behavior, but it may also
improve your compile time if done wisely.
For data files to be included, use the option
--include-data-files=<source>=<target>
where the source is a file
system path, but target has to be specified relative. For standalone you
can also copy them manually, but this can do extra checks, and for
onefile mode, there is no manual copying possible.
To copy some or all file in a directory, use the option
--include-data-files=/etc/*.txt=etc/
where you get to specify shell
patterns for the files, and a subdirectory where to put them, indicated
by the trailing slash.
To copy a whole folder with all files, you can use
--include-data-dir=/path/to/images=images
which will copy all files
including a potential subdirectory structure. You cannot filter here,
i.e. if you want only a partial copy, remove the files beforehand.
For package data, there is a better way, using
--include-package-data
which detects data files of packages
automatically and copies them over. It even accepts patterns in shell
style. It spares you the need to find the package directory yourself and
should be preferred whenever available.
With data files, you are largely on your own. Nuitka keeps track of ones that are needed by popular packages, but it might be incomplete. Raise issues if you encounter something in these.
When that is working, you can use the onefile mode if you so desire.
python -m nuitka --onefile program.py
This will create a single binary, that extracts itself on the target, before running the program. But notice, that accessing files relative to your program is impacted, make sure to read the section Onefile: Finding files as well.
# Create a binary that unpacks into a temporary folder
python -m nuitka --onefile program.py
Note
There are more platform specific options, e.g. related to icons,
splash screen, and version information, consider the --help
output for the details of these and check the section Tweaks_.
For the unpacking, by default a unique user temporary path one is used,
and then deleted, however this default
--onefile-tempdir-spec="%TEMP%/onefile_%PID%_%TIME%"
can be
overridden with a path specification that is using then using a cached
path, avoiding repeated unpacking, e.g. with
--onefile-tempdir-spec="%CACHE_DIR%/%COMPANY%/%PRODUCT%/%VERSION%"
which uses version information, and user specific cache directory.
Note
Using cached paths will e.g. be relevant too, when Windows Firewall comes into play, because otherwise, the binary will be a different one to it each time it is run.
Currently these expanded tokens are available:
Token | What this Expands to | Example |
---|---|---|
%TEMP% | User temporary file directory | C:\Users\...\AppData\Locals\Temp |
%PID% | Process ID | 2772 |
%TIME% | Time in seconds since the epoch. | 1299852985 |
%PROGRAM% | Full program run-time filename of executable. | C:\SomeWhere\YourOnefile.exe |
%PROGRAM_BASE% | No-suffix of run-time filename of executable. | C:\SomeWhere\YourOnefile |
%CACHE_DIR% | Cache directory for the user. | C:\Users\SomeBody\AppData\Local |
%COMPANY% | Value given as --company-name |
YourCompanyName |
%PRODUCT% | Value given as --product-name |
YourProductName |
%VERSION% | Combination of --file-version & --product-version |
3.0.0.0-1.0.0.0 |
%HOME% | Home directory for the user. | /home/somebody |
%NONE% | When provided for file outputs, None is used |
see notice below |
%NULL% | When provided for file outputs, os.devnull is used |
see notice below |
Important
It is your responsibility to make the path provided unique, on Windows a running program will be locked, and while using a fixed folder name is possible, it can cause locking issues in that case, where the program gets restarted.
Usually you need to use %TIME%
or at least %PID%
to make a
path unique, and this is mainly intended for use cases, where e.g.
you want things to reside in a place you choose or abide your naming
conventions.
Important
For disabling output and stderr with --force-stdout-spec
and
--force-stderr-spec
the values %NONE%
and %NULL%
achieve
it, but with different effect. With %NONE%``the corresponding
handle becomes ``None
. As a result e.g. sys.stdout
will be
None
which is different from %NULL%
where it will be backed
by a file pointing to os.devnull
, i.e. you can write to it.
With %NONE%
you may get RuntimeError: lost sys.stdout
in case
it does get used, with %NULL%
that never happens. However, some
libraries handle this as input for their logging mechanism, and on
Windows this is how you are compatible with pythonw.exe
which is
behaving like %NONE%
.
If you have a setup.py
, setup.cfg
or pyproject.toml
driven
creation of wheels for your software in place, putting Nuitka to use is
extremely easy.
Lets start with the most common setuptools
approach, you can -
having Nuitka installed of course, simply execute the target
bdist_nuitka
rather than the bdist_wheel
. It takes all the
options and allows you to specify some more, that are specific to
Nuitka.
# For setup.py if not you't use other build systems:
setup(
# Data files are to be handled by setuptools and not Nuitka
package_data={"some_package": ["some_file.txt"]},
...,
# This is to pass Nuitka options.
command_options={
'nuitka': {
# boolean option, e.g. if you cared for C compilation commands
'--show-scons': True,
# options without value, e.g. enforce using Clang
'--clang': None,
# options with single values, e.g. enable a plugin of Nuitka
'--enable-plugin': "pyside2",
# options with several values, e.g. avoiding including modules
'--nofollow-import-to' : ["*.tests", "*.distutils"],
},
},
)
# For setup.py with other build systems:
# The tuple nature of the arguments is required by the dark nature of
# "setuptools" and plugins to it, that insist on full compatibility,
# e.g. "setuptools_rust"
setup(
# Data files are to be handled by setuptools and not Nuitka
package_data={"some_package": ["some_file.txt"]},
...,
# This is to pass Nuitka options.
...,
command_options={
'nuitka': {
# boolean option, e.g. if you cared for C compilation commands
'--show-scons': ("setup.py", True),
# options without value, e.g. enforce using Clang
'--clang': ("setup.py", None),
# options with single values, e.g. enable a plugin of Nuitka
'--enable-plugin': ("setup.py", "pyside2"),
# options with several values, e.g. avoiding including modules
'--nofollow-import-to' : ("setup.py", ["*.tests", "*.distutils"]),
}
},
)
If for some reason, you cannot or do not what to change the target, you
can add this to your setup.py
.
# For setup.py
setup(
...,
build_with_nuitka=True
)
Note
To temporarily disable the compilation, you could remove above line,
or edit the value to False
by or take its value from an
environment variable if you so choose, e.g.
bool(os.environ.get("USE_NUITKA", "True"))
. This is up to you.
Or you could put it in your setup.cfg
[metadata]
build_with_nuitka = True
And last, but not least, Nuitka also supports the new build
meta, so
when you have a pyproject.toml
already, simple replace or add this
value:
[build-system]
requires = ["setuptools>=42", "wheel", "nuitka", "toml"]
build-backend = "nuitka.distutils.Build"
# Data files are to be handled by setuptools and not Nuitka
[tool.setuptools.package-data]
some_package = ['data_file.txt']
[nuitka]
# These are not recommended, but they make it obvious to have effect.
# boolean option, e.g. if you cared for C compilation commands, leading
# dashes are omitted
show-scons = true
# options with single values, e.g. enable a plugin of Nuitka
enable-plugin = pyside2
# options with several values, e.g. avoiding including modules, accepts
# list argument.
nofollow-import-to = ["*.tests", "*.distutils"]
Note
For the nuitka
requirement above absolute paths like
C:\Users\...\Nuitka
will also work on Linux, use an absolute path
with two leading slashes, e.g. //home/.../Nuitka
.
Note
Whatever approach you take, data files in these wheels are not handled by Nuitka at all, but by setuptools. You can however use the data file embedding of Nuitka commercial. In that case you actually would embed the files inside the extension module itself, and not as a file in the wheel.
If you have multiple programs, that each should be executable, in the past you had to compile multiple times, and deploy all of these. With standalone mode, this of course meant that you were fairly wasteful, as sharing the folders could be done, but wasn't really supported by Nuitka.
Enter Multidist
. There is an option --main
that replaces or adds
to the positional argument given. And it can be given multiple times.
When given multiple times, Nuitka will create a binary that contains the
code of all the programs given, but sharing modules used in them. They
therefore do not have to be distributed multiple times.
Lets call the basename of the main path, and entry point. The names of
these must of course be different. Then the created binary can execute
either entry point, and will react to what sys.argv[0]
appears to
it. So if executed in the right way (with something like subprocess
or OS API you can control this name), or by renaming or copying the
binary, or symlinking to it, you can then achieve the miracle.
This allows to combine very different programs into one.
Note
This feature is still experimental. Use with care and report your findings should you encounter anything that is undesirable behavior
This mode works with standalone, onefile, and mere acceleration. It does not work with module mode.
For good looks, you may specify icons. On Windows, you can provide an icon file, a template executable, or a PNG file. All of these will work and may even be combined:
# These create binaries with icons on Windows
python -m nuitka --onefile --windows-icon-from-ico=your-icon.png program.py
python -m nuitka --onefile --windows-icon-from-ico=your-icon.ico program.py
python -m nuitka --onefile --windows-icon-template-exe=your-icon.ico program.py
# These create application bundles with icons on macOS
python -m nuitka --macos-create-app-bundle --macos-app-icon=your-icon.png program.py
python -m nuitka --macos-create-app-bundle --macos-app-icon=your-icon.icns program.py
Note
With Nuitka, you do not have to create platform specific icons, but instead it will convert e.g. PNG, but also other format on the fly during the build.
Entitlements for an macOS application bundle can be added with the
option, --macos-app-protected-resource
, all values are listed on
this page from Apple
An example value would be
--macos-app-protected-resource=NSMicrophoneUsageDescription:Microphone
access
for requesting access to a Microphone. After the colon, the
descriptive text is to be given.
Note
Beware that in the likely case of using spaces in the description part, you need to quote it for your shell to get through to Nuitka and not be interpreted as Nuitka arguments.
On Windows, the console is opened by programs unless you say so. Nuitka
defaults to this, effectively being only good for terminal programs, or
programs where the output is requested to be seen. There is a difference
in pythonw.exe
and python.exe
along those lines. This is
replicated in Nuitka with the option --disable-console
. Nuitka
recommends you to consider this in case you are using PySide6
e.g.
and other GUI packages, e.g. wx
, but it leaves the decision up to
you. In case, you know your program is console application, just using
--enable-console
which will get rid of these kinds of outputs from
Nuitka.
Note
The pythonw.exe
is never good to be used with Nuitka, as you
cannot see its output.
Splash screens are useful when program startup is slow. Onefile startup itself is not slow, but your program may be, and you cannot really know how fast the computer used will be, so it might be a good idea to have them. Luckily with Nuitka, they are easy to add for Windows.
For splash screen, you need to specify it as an PNG file, and then make sure to disable the splash screen when your program is ready, e.g. has complete the imports, prepared the window, connected to the database, and wants the splash screen to go away. Here we are using the project syntax to combine the code with the creation, compile this:
# nuitka-project: --onefile
# nuitka-project: --onefile-windows-splash-screen-image={MAIN_DIRECTORY}/Splash-Screen.png
# Whatever this is obviously
print("Delaying startup by 10s...")
import time, tempfile, os
time.sleep(10)
# Use this code to signal the splash screen removal.
if "NUITKA_ONEFILE_PARENT" in os.environ:
splash_filename = os.path.join(
tempfile.gettempdir(),
"onefile_%d_splash_feedback.tmp" % int(os.environ["NUITKA_ONEFILE_PARENT"]),
)
if os.path.exists(splash_filename):
os.unlink(splash_filename)
print("Done... splash should be gone.")
...
# Rest of your program goes here.
For analysis of your program and Nuitka packaging, there is the Compilation Report available. You can also make custom reports providing your own template, with a few of them built-in to Nuitka. These reports carry all the detail information, e.g. when a module was attempted to be imported, but not found, you can see where that happens. For bug reporting, it is very much recommended to provide the report.
You can attach copyright and trademark information, company name, product name, and so on to your compilation. This is then used in version information for the created binary on Windows, or application bundle on macOS. If you find something that it's lacking, let us know.
Binaries compiled on Windows with default settings of Nuitka and no further actions taken might be recognized by some AV vendors as malware. This is avoidable, but only in Nuitka commercial there is actual support and instructions for how to do it, seeing this as a typical commercial only need. https://nuitka.net/doc/commercial.html
Sometimes the C compilers will crash saying they cannot allocate memory or that some input was truncated, or similar error messages, clearly from it. There are several options you can explore here:
There is a dedicated option --low-memory
which influences decisions
of Nuitka, such that it avoids high usage of memory during compilation
at the cost of increased compile time.
Do not use a 32 bits compiler, but a 64 bit one. If you are using Python with 32 bits on Windows, you most definitely ought to use MSVC as the C compiler, and not MinGW64. The MSVC is a cross compiler, and can use more memory than gcc on that platform. If you are not on Windows, that is not an option of course. Also using the 64 bits Python will work.
When you compile from a living installation, that may well have many optional dependencies of your software installed. Some software, will then have imports on these, and Nuitka will compile them as well. Not only may these be just the trouble makers, they also require more memory, so get rid of that. Of course you do have to check that your program has all needed dependencies before you attempt to compile, or else the compiled program will equally not run.
With --lto=yes
or --lto=no
you can switch the C compilation to
only produce bytecode, and not assembler code and machine code directly,
but make a whole program optimization at the end. This will change the
memory usage pretty dramatically, and if you error is coming from the
assembler, using LTO will most definitely avoid that.
People have reported that programs that fail to compile with gcc due to its bugs or memory usage work fine with clang on Linux. On Windows, this could still be an option, but it needs to be implemented first for the automatic downloaded gcc, that would contain it. Since MSVC is known to be more memory effective anyway, you should go there, and if you want to use Clang, there is support for the one contained in MSVC.
On systems with not enough RAM, you need to use swap space. Running out of it is possibly a cause, and adding more swap space, or one at all, might solve the issue, but beware that it will make things extremely slow when the compilers swap back and forth, so consider the next tip first or on top of it.
With the --jobs
option of Nuitka, it will not start many C compiler
instances at once, each competing for the scarce resource of RAM. By
picking a value of one, only one C compiler instance will be running,
and on a 8 core system, that reduces the amount of memory by factor 8,
so that's a natural choice right there.
If your script modifies sys.path
to e.g. insert directories with
source code relative to it, Nuitka will not be able to see those.
However, if you set the PYTHONPATH
to the resulting value, it will
be able to compile it and find the used modules from these paths as
well.
A very frequent pattern with private code is that it scans plugin
directories of some kind, and e.g. uses os.listdir
, then considers
Python filenames, and then opens a file and does exec
on them. This
approach is working for Python code, but for compiled code, you should
use this much cleaner approach, that works for pure Python code and is a
lot less vulnerable.
# Using a package name, to locate the plugins. This is also a sane
# way to organize them into a directory.
scan_path = scan_package.__path__
for item in pkgutil.iter_modules(scan_path):
importlib.import_module(scan_package.__name__ + "." + item.name)
# You may want to do it recursively, but we don't do this here in
# this example. If you want to, handle that in this kind of branch.
if item.ispkg:
...
If your program fails to file data, it can cause all kinds of different
behaviors, e.g. a package might complain it is not the right version,
because a VERSION
file check defaulted to unknown. The absence of
icon files or help texts, may raise strange errors.
Often the error paths for files not being present are even buggy and will reveal programming errors like unbound local variables. Please look carefully at these exceptions keeping in mind that this can be the cause. If you program works without standalone, chances are data files might be cause.
The most common error indicating file absence is of course an uncaught
FileNotFoundError
with a filename. You should figure out what
package is missing files and then use --include-package-data
(preferably), or --include-data-dir
/--include-data-files
to
include them.
Nuitka has plugins that deal with copying DLLs. For NumPy, SciPy, Tkinter, etc.
These need special treatment to be able to run on other systems. Manually copying them is not enough and will given strange errors. Sometimes newer version of packages, esp. NumPy can be unsupported. In this case you will have to raise an issue, and use the older one.
If you want to manually add a DLL or an EXE, because it is your project only, you will have to use user Yaml files describing where they can be found. This is described in detail with examples in the Nuitka Package Configuration page.
Some packages are a single import, but to Nuitka mean that more than a thousand packages (literally) are to be included. The prime example of Pandas, which does want to plug and use just about everything you can imagine. Multiple frameworks for syntax highlighting everything imaginable take time.
Nuitka will have to learn effective caching to deal with this in the future. Right now, you will have to deal with huge compilation times for these.
A major weapon in fighting dependency creep should be applied, namely
the anti-bloat
plugin, which offers interesting abilities, that can
be put to use and block unneeded imports, giving an error for where they
occur. Use it e.g. like this --noinclude-pytest-mode=nofollow
--noinclude-setuptools-mode=nofollow
and e.g. also
--noinclude-custom-mode=setuptools:error
to get the compiler to
error out for a specific package. Make sure to check its help output. It
can take for each module of your choice, e.g. forcing also that e.g.
PyQt5
is considered uninstalled for standalone mode.
It's also driven by a configuration file, anti-bloat.yml
that you
can contribute to, removing typical bloat from packages. Feel free to
enhance it and make PRs towards Nuitka with it.
The standard code that normally works, also works, you should refer to
os.path.dirname(__file__)
or use all the packages like pkgutil
,
pkg_resources
, importlib.resources
to locate data files near the
standalone binary.
Important
What you should not do, is use the current directory
os.getcwd
, or assume that this is the script directory, e.g. with
paths like data/
.
If you did that, it was never good code. Links, to a program, launching from another directory, etc. will all fail in bad ways. Do not make assumptions about the directory your program is started from.
There is a difference between sys.argv[0]
and __file__
of the
main module for onefile mode, that is caused by using a bootstrap to a
temporary location. The first one will be the original executable path,
where as the second one will be the temporary or permanent path the
bootstrap executable unpacks to. Data files will be in the later
location, your original environment files will be in the former
location.
Given 2 files, one which you expect to be near your executable, and one which you expect to be inside the onefile binary, access them like this.
# This will find a file *near* your onefile.exe
open(os.path.join(os.path.dirname(sys.argv[0]), "user-provided-file.txt"))
# This will find a file *inside* your onefile.exe
open(os.path.join(os.path.dirname(__file__), "user-provided-file.txt"))
For debugging purposes, remove --disable-console
or use the options
--force-stdout-spec
and --force-stderr-spec
with paths as
documented for --onefile-tempdir-spec
above. These can be relative
to the program or absolute, so you can see the outputs given.
Sometimes people use this kind of code, which for packages on PyPI, we deal with by doing source code patches on the fly. If this is in your own code, here is what you can do:
def binder(func, name):
result = types.FunctionType(func.__code__, func.__globals__, name=func.__name__, argdefs=func.__defaults__, closure=func.__closure__)
result = functools.update_wrapper(result, func)
result.__kwdefaults__ = func.__kwdefaults__
result.__name__ = name
return result
Compiled functions cannot be used to create uncompiled ones from, so the
above code will not work. However, there is a dedicated clone
method, that is specific to them, so use this instead.
def binder(func, name):
try:
result = func.clone()
except AttributeError:
result = types.FunctionType(func.__code__, func.__globals__, name=func.__name__, argdefs=func.__defaults__, closure=func.__closure__)
result = functools.update_wrapper(result, func)
result.__kwdefaults__ = func.__kwdefaults__
result.__name__ = name
return result
A package can be compiled with Nuitka, no problem, but when it comes to
executing it, python -m compiled_module
is not going to work and
give the error No code object available for AssertsTest
because the
compiled module is not source code, and Python will not just load it.
The closest would be python -c "import compile_module"
and you might
have to call the main function yourself.
To support this, the CPython runpy
and/or ExtensionFileLoader
would need improving such that Nuitka could supply its compiled module
object for Python to use.
There is support for conditional options, and options using pre-defined variables, this is an example:
# Compilation mode, support OS specific.
# nuitka-project-if: {OS} in ("Windows", "Linux", "Darwin", "FreeBSD"):
# nuitka-project: --onefile
# nuitka-project-if: {OS} not in ("Windows", "Linux", "Darwin", "FreeBSD"):
# nuitka-project: --standalone
# The PySide2 plugin covers qt-plugins
# nuitka-project: --enable-plugin=pyside2
# nuitka-project: --include-qt-plugins=sensible,qml
The comments must be a start of line, and indentation is to be used, to end a conditional block, much like in Python. There are currently no other keywords than the used ones demonstrated above.
You can put arbitrary Python expressions there, and if you wanted to
e.g. access a version information of a package, you could simply use
__import__("module_name").__version__
if that would be required to
e.g. enable or disable certain Nuitka settings. The only thing Nuitka
does that makes this not Python expressions, is expanding {variable}
for a pre-defined set of variables:
Table with supported variables:
Variable | What this Expands to | Example |
---|---|---|
{OS} | Name of the OS used | Linux, Windows, Darwin, FreeBSD, OpenBSD |
{Version} | Version of Nuitka | e.g. (1, 6, 0) |
{Commercial} | Version of Nuitka Commercial | e.g. (2, 1, 0) |
{Arch} | Architecture used | x86_64, arm64, etc. |
{MAIN_DIRECTORY} | Directory of the compiled file | some_dir/maybe_relative |
{Flavor} | Variant of Python | e.g. Debian Python, Anaconda Python |
The use of {MAIN_DIRECTORY}
is recommended when you want to specify
a filename relative to the main script, e.g. for use in data file
options or user package configuration yaml files,
# nuitka-project: --include-data-files={MAIN_DIRECTORY}/my_icon.png=my_icon.png
# nuitka-project: --user-package-configuration-file={MAIN_DIRECTORY}/user.nuitka-package.config.yml
For passing things like -O
or -S
to Python, to your compiled
program, there is a command line option name --python-flag=
which
makes Nuitka emulate these options.
The most important ones are supported, more can certainly be added.
The C compiler, when invoked with the same input files, will take a long
time and much CPU to compile over and over. Make sure you are having
ccache
installed and configured when using gcc (even on Windows). It
will make repeated compilations much faster, even if things are not yet
not perfect, i.e. changes to the program can cause many C files to
change, requiring a new compilation instead of using the cached result.
On Windows, with gcc Nuitka supports using ccache.exe
which it will
offer to download from an official source and it automatically. This is
the recommended way of using it on Windows, as other versions can e.g.
hang.
Nuitka will pick up ccache
if it's in found in system PATH
, and
it will also be possible to provide if by setting
NUITKA_CCACHE_BINARY
to the full path of the binary, this is for use
in CI systems where things might be non-standard.
For the MSVC compilers and ClangCL setups, using the clcache
is
automatic and included in Nuitka.
On macOS and Intel, there is an automatic download of a ccache
binary from our site, for arm64 arches, it's recommended to use this
setup, which installs Homebrew and ccache in there. Nuitka picks that
one up automatically if it on that kind of machine. You need and should
not use Homebrew with Nuitka otherwise, it's not the best for standalone
deployments, but we can take ccache
from there.
export HOMEBREW_INSTALL_FROM_API=1
/bin/bash -c "$(curl -fsSL https://raw.githubusercontent.com/Homebrew/install/master/install.sh)"
eval $(/opt/homebrew/bin/brew shellenv)
brew install ccache
The storage for cache results of all kinds, downloads, cached
compilation results from C and Nuitka, is done in a platform dependent
directory as determined by the appdirs
package. However, you can
override it with setting the environment variable NUITKA_CACHE_DIR
to a base directory. This is for use in environments where the home
directory is not persisted, but other paths are.
Avoid running the nuitka
binary, doing python -m nuitka
will
make a 100% sure you are using what you think you are. Using the wrong
Python will make it give you SyntaxError
for good code or
ImportError
for installed modules. That is happening, when you run
Nuitka with Python2 on Python3 code and vice versa. By explicitly
calling the same Python interpreter binary, you avoid that issue
entirely.
The fastest binaries of pystone.exe
on Windows with 64 bits Python
proved to be significantly faster with MinGW64, roughly 20% better
score. So it is recommended for use over MSVC. Using clang-cl.exe
of
Clang7 was faster than MSVC, but still significantly slower than
MinGW64, and it will be harder to use, so it is not recommended.
On Linux for pystone.bin
the binary produced by clang6
was
faster than gcc-6.3
, but not by a significant margin. Since gcc is
more often already installed, that is recommended to use for now.
Differences in C compilation times have not yet been examined.
Using the Python DLL, like standard CPython does can lead to unexpected slowdowns, e.g. in uncompiled code that works with Unicode strings. This is because calling to the DLL rather than residing in the DLL causes overhead, and this even happens to the DLL with itself, being slower, than a Python all contained in one binary.
So if feasible, aim at static linking, which is currently only possible
with Anaconda Python on non-Windows, Debian Python2, self compiled
Pythons (do not activate --enable-shared
, not needed), and installs
created with pyenv
.
Note
On Anaconda, you may need to execute conda install
libpython-static
The process of making standalone executables for Windows traditionally involves using an external dependency walker in order to copy necessary libraries along with the compiled executables to the distribution folder.
There is plenty of ways to find that something is missing. Do not manually copy things into the folder, esp. not DLLs, as that's not going to work. Instead make bug reports to get these handled by Nuitka properly.
On Windows, the Windows Defender tool and the Windows Indexing Service both scan the freshly created binaries, while Nuitka wants to work with it, e.g. adding more resources, and then preventing operations randomly due to holding locks. Make sure to exclude your compilation stage from these services.
Whether compiling with MingW or MSVC, the standalone programs have external dependencies to Visual C Runtime libraries. Nuitka tries to ship those dependent DLLs by copying them from your system.
Beginning with Microsoft Windows 10, Microsoft ships ucrt.dll
(Universal C Runtime libraries) which handles calls to
api-ms-crt-*.dll
.
With earlier Windows platforms (and wine/ReactOS), you should consider installing Visual C runtime libraries before executing a Nuitka standalone compiled program.
Depending on the used C compiler, you'll need the following redist versions on the target machines. However notice that compilation using the 14.3 based version is recommended.
Visual C version | Redist Year | CPython |
---|---|---|
14.3 | 2022 | 3.11 |
14.2 | 2019 | 3.5, 3.6, 3.7, 3.8, 3.9, 3.10 |
14.1 | 2017 | 3.5, 3.6, 3.7, 3.8 |
14.0 | 2015 | 3.5, 3.6, 3.7, 3.8 |
10.0 | 2010 | 3.3, 3.4 |
9.0 | 2008 | 2.6, 2.7 |
When using MingGW64, you'll need the following redist versions:
MingGW64 version | Redist Year | CPython |
---|---|---|
8.1.0 | 2015 | 3.5, 3.6, 3.7, 3.8, 3.9, 3.10, 3.11 |
Once the corresponding runtime libraries are installed on the target
system, you may remove all api-ms-crt-*.dll
files from your Nuitka
compiled dist folder.
Nuitka does not sys.frozen
unlike other tools, because it usually
triggers inferior code for no reason. For Nuitka, we have the module
attribute __compiled__
to test if a specific module was compiled,
and the function attribute __compiled__
to test if a specific
function was compiled.
Nuitka will apply values from the environment variables CCFLAGS
,
LDFLAGS
during the compilation on top of what it determines to be
necessary. Beware of course, that is this is only useful if you know
what you are doing, so should this pose an issues, raise them only with
perfect information.
Nuitka will automatically target the architecture of the Python you are
using. If this is 64 bits, it will create a 64 bits binary, if it is 32
bits, it will create a 32 bits binary. You have the option to select the
bits when you download the Python. In the output of python -m nuitka
--version
there is a line for the architecture. It Arch: x86_64
for 64 bits, and just Arch: x86
for 32 bits.
The C compiler will be picked to match that more or less automatically. If you specify it explicitly and it mismatches, you will get a warning about the mismatch and informed that you compiler choice was rejected.
When you use --report=compilation-report.xml
Nuitka will create an
XML file with detailed information about the compilation and packaging
process. This is growing in completeness with very release and exposes
module usage attempts, timings of the compilation, plugin influences,
data file paths, DLLs, and reasons why things are included or not.
At this time, the report contains absolute paths in some places, with your private information. The goal is to make this blended out by default, because we also want to become able to compare compilation reports from different setups, e.g. with updated packages, and see the changes to Nuitka. The report is however recommended for your bug reporting.
Also, another form is available, where the report is free form and according to a Jinja2 template of yours, and one that is included in Nuitka. The same information as used to produce the XML file is accessible. However, right now this is not yet documented, but we plan to add a table with the data. For reader of the source code that is familiar with Jinja2, however, it will be easy to do it now already.
If you have a template, you can use it like this
--report-template=your_template.rst.j2:your_report.rst
and of
course, the usage of restructured text, is only an example. You can use
markdown, your own XML, or whatever you see fit. Nuitka will just expand
the template with the compilation report data.
Currently the follow reports are included in Nuitka. You just use the name as a filename, and Nuitka will pick that one instead.
Report Name | Status | Purpose |
---|---|---|
LicenseReport | experimental | Distributions used in a compilation with license texts |
Note
The community can and should contribute more report types and help enhancing the existing ones for good looks.
This chapter gives an overview, of what to currently expect in terms of performance from Nuitka. It's a work in progress and is updated as we go. The current focus for performance measurements is Python 2.7, but 3.x is going to follow later.
The results are the top value from this kind of output, running pystone 1000 times and taking the minimal value. The idea is that the fastest run is most meaningful, and eliminates usage spikes.
echo "Uncompiled Python2"
for i in {1..100}; do BENCH=1 python2 tests/benchmarks/pystone.py ; done | sort -rn | head -n 1
python2 -m nuitka --lto=yes --pgo tests/benchmarks/pystone.py
echo "Compiled Python2"
for i in {1..100}; do BENCH=1 ./pystone.bin ; done | sort -n | head -rn 1
echo "Uncompiled Python3"
for i in {1..100}; do BENCH=1 python3 tests/benchmarks/pystone3.py ; done | sort -rn | head -n 1
python3 -m nuitka --lto=yes --pgo tests/benchmarks/pystone3.py
echo "Compiled Python3"
for i in {1..100}; do BENCH=1 ./pystone3.bin ; done | sort -rn | head -n 1
Python | Uncompiled | Compiled LTO | Compiled PGO |
---|---|---|---|
Debian Python 2.7 | 137497.87 (1.000) | 460995.20 (3.353) | 503681.91 (3.663) |
Nuitka Python 2.7 | 144074.78 (1.048) | 479271.51 (3.486) | 511247.44 (3.718) |
Remember, this project needs constant work. Although the Python compatibility is insanely high, and test suite works near perfectly, there is still more work needed, esp. to make it do more optimization. Try it out, and when popular packages do not work, please make reports on GitHub.
Nuitka announcements and interesting stuff is pointed to on both the Mastodon and Twitter accounts, but obviously with not too many details, usually pointing to the website, but sometimes I also ask questions there.
@KayHayen on Mastodon. @KayHayen on Twitter.
Should you encounter any issues, bugs, or ideas, please visit the Nuitka bug tracker and report them.
Best practices for reporting bugs:
Please always include the following information in your report, for the underlying Python version. You can easily copy&paste this into your report. It does contain more information that you think. Do not write something manually. You may always add of course.
python -m nuitka --version
Try to make your example minimal. That is, try to remove code that does not contribute to the issue as much as possible. Ideally come up with a small reproducing program that illustrates the issue, using
print
with different results when that programs runs compiled or native.If the problem occurs spuriously (i.e. not each time), try to set the environment variable
PYTHONHASHSEED
to0
, disabling hash randomization. If that makes the problem go away, try increasing in steps of 1 to a hash seed value that makes it happen every time, include it in your report.Do not include the created code in your report. Given proper input, it's redundant, and it's not likely that I will look at it without the ability to change the Python or Nuitka source and re-run it.
Do not send screenshots of text, that is bad and lazy. Instead, capture text outputs from the console.
Consider using this software with caution. Even though many tests are applied before releases, things are potentially breaking. Your feedback and patches to Nuitka are very welcome.
You are more than welcome to join Nuitka development and help to complete the project in all minor and major ways.
The development of Nuitka occurs in git. We currently have these 3 branches:
main
This branch contains the stable release to which only hotfixes for bugs will be done. It is supposed to work at all times and is supported.
develop
This branch contains the ongoing development. It may at times contain little regressions, but also new features. On this branch, the integration work is done, whereas new features might be developed on feature branches.
factory
This branch contains unfinished and incomplete work. It is very frequently subject to
git rebase
and the public staging ground, where my work for develop branch lives first. It is intended for testing only and recommended to base any of your own development on. When updating it, you very often will get merge conflicts. Simply resolve those by doinggit fetch && git reset --hard origin/factory
and switch to the latest version.
Note
The Developer Manual explains the coding rules, branching model used, with feature branches and hotfix releases, the Nuitka design and much more. Consider reading it to become a contributor. This document is intended for Nuitka users.
Should you feel that you cannot help Nuitka directly, but still want to support, please consider making a donation and help this way.
The code objects are empty for native compiled functions. There is no bytecode with Nuitka's compiled function objects, so there is no way to provide it.
There is no tracing of compiled functions to attach a debugger to.
The most important form of optimization is the constant folding. This is when an operation can be fully predicted at compile time. Currently, Nuitka does these for some built-ins (but not all yet, somebody to look at this more closely will be very welcome!), and it does it e.g. for binary/unary operations and comparisons.
Constants currently recognized:
5 + 6 # binary operations
not 7 # unary operations
5 < 6 # comparisons
range(3) # built-ins
Literals are the one obvious source of constants, but also most likely other optimization steps like constant propagation or function inlining will be. So this one should not be underestimated and a very important step of successful optimizations. Every option to produce a constant may impact the generated code quality a lot.
Status
The folding of constants is considered implemented, but it might be incomplete in that not all possible cases are caught. Please report it as a bug when you find an operation in Nuitka that has only constants as input and is not folded.
At the core of optimizations, there is an attempt to determine the values of variables at run time and predictions of assignments. It determines if their inputs are constants or of similar values. An expression, e.g. a module variable access, an expensive operation, may be constant across the module of the function scope and then there needs to be none or no repeated module variable look-up.
Consider e.g. the module attribute __name__
which likely is only
ever read, so its value could be predicted to a constant string known at
compile time. This can then be used as input to the constant folding.
if __name__ == "__main__":
# Your test code might be here
use_something_not_use_by_program()
Status
From modules attributes, only __name__
is currently actually
optimized. Also possible would be at least __doc__
. In the
future, this may improve as SSA is expanded to module variables.
Also, built-in exception name references are optimized if they are used as a module level read-only variables:
try:
something()
except ValueError: # The ValueError is a slow global name lookup normally.
pass
Status
This works for all built-in names. When an assignment is done to such a name, or it's even local, then, of course, it is not done.
For built-in calls like type
, len
, or range
it is often
possible to predict the result at compile time, esp. for constant inputs
the resulting value often can be precomputed by Nuitka. It can simply
determine the result or the raised exception and replace the built-in
call with that value, allowing for more constant folding or code path
reduction.
type("string") # predictable result, builtin type str.
len([1, 2]) # predictable result
range(3, 9, 2) # predictable result
range(3, 9, 0) # predictable exception, range raises due to 0.
Status
The built-in call prediction is considered implemented. We can simply during compile time emulate the call and use its result or raised exception. But we may not cover all the built-ins there are yet.
Sometimes the result of a built-in should not be predicted when the
result is big. A range()
call e.g. may give too big values to
include the result in the binary. Then it is not done.
range(100000) # We do not want this one to be expanded
Status
This is considered mostly implemented. Please file bugs for built-ins that are pre-computed, but should not be computed by Nuitka at compile time with specific values.
For conditional statements, some branches may not ever be taken, because of the condition truth value being possible to predict. In these cases, the branch not taken and the condition check is removed.
This can typically predict code like this:
if __name__ == "__main__":
# Your test code might be here
use_something_not_use_by_program()
or
if False:
# Your deactivated code might be here
use_something_not_use_by_program()
It will also benefit from constant propagations, or enable them because once some branches have been removed, other things may become more predictable, so this can trigger other optimization to become possible.
Every branch removed makes optimization more likely. With some code branches removed, access patterns may be more friendly. Imagine e.g. that a function is only called in a removed branch. It may be possible to remove it entirely, and that may have other consequences too.
Status
This is considered implemented, but for the maximum benefit, more constants need to be determined at compile time.
For exceptions that are determined at compile time, there is an expression that will simply do raise the exception. These can be propagated upwards, collecting potentially "side effects", i.e. parts of expressions that were executed before it occurred, and still have to be executed.
Consider the following code:
print(side_effect_having() + (1 / 0))
print(something_else())
The (1 / 0)
can be predicted to raise a ZeroDivisionError
exception, which will be propagated through the +
operation. That
part is just Constant Propagation as normal.
The call side_effect_having()
will have to be retained though, but
the print
does not and can be turned into an explicit raise. The
statement sequence can then be aborted and as such the
something_else
call needs no code generation or consideration
anymore.
To that end, Nuitka works with a special node that raises an exception and is wrapped with a so-called "side_effects" expression, but yet can be used in the code as an expression having a value.
Status
The propagation of exceptions is mostly implemented but needs handling in every kind of operations, and not all of them might do it already. As work progresses or examples arise, the coverage will be extended. Feel free to generate bug reports with non-working examples.
Consider the following code:
try:
b = 8
print(range(3, b, 0))
print("Will not be executed")
except ValueError as e:
print(e)
The try
block is bigger than it needs to be. The statement b = 8
cannot cause a ValueError
to be raised. As such it can be moved to
outside the try without any risk.
b = 8
try:
print(range(3, b, 0))
print("Will not be executed")
except ValueError as e:
print(e)
Status
This is considered done. For every kind of operation, we trace if it
may raise an exception. We do however not track properly yet, what
can do a ValueError
and what cannot.
With the exception propagation, it then becomes possible to transform this code:
try:
b = 8
print(range(3, b, 0))
print("Will not be executed!")
except ValueError as e:
print(e)
try:
raise ValueError("range() step argument must not be zero")
except ValueError as e:
print(e)
Which then can be lowered in complexity by avoiding the raise and catch of the exception, making it:
e = ValueError("range() step argument must not be zero")
print(e)
Status
This is not implemented yet.
For loops and conditional statements that contain only code without effect, it should be possible to remove the whole construct:
for i in range(1000):
pass
The loop could be removed, at maximum, it should be considered an
assignment of variable i
to 999
and no more.
Status
This is not implemented yet, as it requires us to track iterators, and their side effects, as well as loop values, and exit conditions. Too much yet, but we will get there.
Another example:
if side_effect_free:
pass
The condition check should be removed in this case, as its evaluation is
not needed. It may be difficult to predict that side_effect_free
has
no side effects, but many times this might be possible.
Status
This is considered implemented. The conditional statement nature is removed if both branches are empty, only the condition is evaluated and checked for truth (in cases that could raise an exception).
When the length of the right-hand side of an assignment to a sequence can be predicted, the unpacking can be replaced with multiple assignments.
a, b, c = 1, side_effect_free(), 3
a = 1
b = side_effect_free()
c = 3
This is of course only really safe if the left-hand side cannot raise an exception while building the assignment targets.
We do this now, but only for constants, because we currently have no ability to predict if an expression can raise an exception or not.
Status
This is partially implemented. We are working on unpacking enhancements, that will recognize where index access is available. This faster access will then avoid tuples and iteration, then this will be perfect.
When a construct like in xrange()
or in range()
is used, it is
possible to know what the iteration does and represent that so that
iterator users can use that instead.
I consider that:
for i in xrange(1000):
something(i)
could translate xrange(1000)
into an object of a special class that
does the integer looping more efficiently. In case i
is only
assigned from there, this could be a nice case for a dedicated class.
Status
Future work, not even started.
Functions are structured so that their parameter parsing and tp_call
interface is separate from the actual function code. This way the call
can be optimized away. One problem is that the evaluation order can
differ.
def f(a, b, c):
return a, b, c
f(c=get1(), b=get2(), a=get3())
This will have to evaluate first get1()
, then get2()
and only
then get3()
and then make the function call with these values.
Therefore it will be necessary to have a staging of the parameters
before making the actual call, to avoid a re-ordering of the calls to
get1()
, get2()
, and get3()
.
Status
Not even started. A re-formulation that avoids the dictionary to call the function, and instead uses temporary variables appears to be relatively straight forward once we do that kind of parameter analysis.
In some cases, accesses to list
constants can become tuple
constants instead.
Consider that:
for x in [a, b, c]:
something(x)
Can be optimized into this:
for x in (a, b, c):
something(x)
This allows for simpler, faster code to be generated, and fewer checks
needed, because e.g. the tuple
is clearly immutable, whereas the
list
needs a check to assert that. This is also possible for sets.
Status
Implemented, even works for non-constants. Needs other optimization to become generally useful, and will itself help other optimization to become possible. This allows us to e.g. only treat iteration over tuples, and not care about sets.
In theory, something similar is also possible for dict
. For the
later, it will be non-trivial though to maintain the order of execution
without temporary values introduced. The same thing is done for pure
constants of these types, they change to tuple
values when iterated.
Nuitka does not include metadata in the distribution. It's rather large, and the goal is to use it at compile time. Therefore information about entry points, version checks, etc. are all done at compile time rather than at run time. Not only is that faster, it also recognized problems sooner.
pkg_resources.require("lxml")
importlib.metadata.version("lxml")
...
Status
This is considered complete. The coverage of the APIs is very good, but naturally this will always have to be code that uses compile time values, but that is nearly never an issue, and where it happens, we use "anti-bloat" patches to deal with these in 3rd party packages.
This document is written in REST. That is an ASCII format which is readable to human, but easily used to generate PDF or HTML documents.
You will find the current version at: https://nuitka.net/doc/user-manual.html