On Windows, Anaconda/Miniconda can install GCC libraries such as libstdc++ and libgfortran et al under miniconda3/Library/mingw-w64/bin.
This path is put by default by fresh Anaconda/Miniconda installation on Path by “conda activate”, but no files are installed there until certain packages are installed.
These libraries are for a particular GCC version, and are not necessarily ABI compatible with the GCC version on the system perhaps from MSYS2.
This problem can manifest as Windows error code 139 when running other executables that need say libstdc++ but Anaconda’s path is overriding the desired GCC lower on Path.
The solution to this problem could be either:
uninstall the conda Python package that installed those libraries
rename the Library/mingw-w64/bin e.g. to bin-backup and see if the needed Python packages still work
These functions use only Python standard library modules.
Detect if inside WSL
This function detects if Python is running in WSL.
from platform import uname
defin_wsl() -> bool:
return'microsoft-standard'in uname().release
Detect WSL from Windows (outside WSL)
import os
import shutil
defwsl_available() -> bool:
"""
heuristic to detect if Windows Subsystem for Linux is available.
Uses presence of /etc/os-release in the WSL image to say Linux is there.
This is a de facto file standard across Linux distros.
"""if os.name =="nt":
wsl = shutil.which("wsl")
ifnot wsl:
returnFalse# can't read this file or test with# pathlib.Path('//wsl$/Ubuntu/etc/os-release').# A Python limitation?
ret = subprocess.run(["wsl", "test", "-f", "/etc/os-release"])
return ret.returncode ==0returnFalse
We generally recommend using
Ninja with CMake,
especially for large projects.
Ninja speeds up rebuild times significantly and avoids erratic problems with slower GNU Make.
CMake also has the
Ninja Multi-Config
generator
cmake -G "Ninja Multi-Config"
that allows building multiple build configuration types e.g. Debug, Release without CMake regenerating build*.ninja files for each build type with totally distinct build root directories.
Ninja Multi-Config generator options may be used transparently with older CMake and different generators.
The default CMake generator can be set with environment variable:
CMAKE_GENERATOR="Ninja Multi-Config"
NOTE: CMAKE_CONFIGURATION_TYPES was broken in CMake 3.22.0, where it was introduced.
CMake ≥ 3.19 is strongly recommended for general users for more robust and easy syntax.
For project developers, we recommend CMake >= 3.22 as the new features make debugging CMake and setting up CI considerably easier.
Downloading the latest release of CMake is usually easy.
For Linux and Mac, admin/sudo is NOT required.
For platforms where CMake binaries aren’t easily available, use
build_cmake.cmake.
Key features added
The priority of these features is subjective–we write from the scientific computing perspective.
CMake 3.22 adds several CMake Environment Variables that are generally useful.
CMAKE_BUILD_TYPE default for single configuration build systems.
CMAKE_CONFIGURATION_TYPES defaults available configurations for multi-config build systems like Ninja Multi-Config–this is broken for initial CMake 3.22.0 release.
CMAKE_INSTALL_MODE makes symlinks with copy fallback a good choice for installing programs from CMake.
For CTest, the new ENVIRONMENT_MODIFICATION test property makes modifying environment variables for test(s) much easier.
CMake 3.21
adds more preset features, including making “generator” optional–the default CMake behavior will be used to determine generator.
The cmake --install-prefix option can be used instead of the cumbersome cmake -DCMAKE_INSTALL_PREFIX=.
PROJECT_IS_TOP_LEVEL and <PROJECT-NAME>_IS_TOP_LEVEL identify if a project is at the top of the project hierarchy.
ctest --output-junit gives test output in standard tooling format.
CMake 3.20
adds support for Intel NextGen LLVM compiler and NVIDIA HPC compiler.
ExternalProject_Add() learned CONFIGURE_HANDLED_BY_BUILD which avoids CMake commanding a reconfigure on each build.
try_compiler(WORKING_DIRECTORY) was added.
CMake presets in CMakePresets.json now covers configure, build and test, allowing many parameters to be declared with inheritance in JSON.
CMake presets are a key feature for CI, as well as user configurations.
ctest --test-dir build option avoids the need to manually cd build.
cmake_path
allows path manipulation and introspection without actually touching the filesystem.
CMake 3.19 added support for ISPC language.
string(JSON GET|SET) parsing is very useful to avoid hard-coding parameters.
FindPython/find_package accepts version ranges.
Intel oneAPI works with CMake >= 3.19.6.
Emits deprecation warning for cmake_minimum_required VERSION less than 2.8.12.
CMakePresets.json enables configure parameter declarations in JSON.
Adds REQUIRED parameter to find_program.
Adds file(ARCHIVE_CREATE) and file(ARCHIVE_EXTRACT)
CMake 3.17
adds
Ninja Multi-Config generator.
cmake
–debug-find
shows what find_*() is doing.
Eliminates Windows “sh.exe is on PATH” error.
Recognizes that Ninja 1.10 correctly works with Fortran.
CMake 3.15 adds CMAKE_GENERATOR environment variable that works like global -G option.
Enhances Python interpreter finding.
Adds cmake --install command instead of “cmake –build build –target install”.
Added Zstd compression.
CMake 3.14: I created check_fortran_source_runs().
FetchContent was enhanced with simpler syntax.
The transitive link resolution was considerably enhanced in CMake 3.14.
Projects just work in CMake >= 3.14 that fail at link-time with CMake < 3.14.
We don’t recommend use of the older CMake versions below as they take significantly more effort to support.
CMake 3.13
adds ctest --progress and better Matlab compiler support.
Lots of new linking options are added, fixes to Fortran submodule bugs.
The very convenient cmake -B build incantation, target_sources() with absolute path are also added.
It’s significantly more difficult to use CMake older than 3.13 with medium to large projects.
CMake 3.12 adds transitive library specification (out of same directory) and full Fortran Submodule support.
get_property(_test_names DIRECTORY . TESTS) retrieves test names in current directory.
CMake 3.11 allows specify targets initially w/o sources.
FetchContent is added, allowing fast hierarchies of CMake and non-CMake projects.
The versions of CMake below have been deprecated as of CMake 3.19.
Patching files with
GNU Patch
has been a common task for decades.
Due to
technical issues
with potential patch library implementation, CMake does not include a native patch function.
We use CMake to detect if “patch” is available, which it virtually always is on Unix-like systems.
For Windows, we use
MSYS2
or
WSL.
CMake Patch file repository example
uses standard GNU Patch files across operating systems.
We put the patched file into the binary directory to avoid ambiguity.
The file patching occurs only if the source file changes using canonical CMake approach.
With slight modification, this patching can occur on files obtained via CMake FetchContent, header files, or other resources.
Select: Workloads → Desktop development with C++, then for Individual Components, select only:
Windows SDK
C++ x64/x86 build tools
The build tools allow using MSVC “cl.exe” C / C++ compiler from the command line.
Visual Studio
changed
the
Build Tools
from being C++ specific in late 2017.
Thus newer Visual Studio versions work in place of older versions.
Windows Python needs Visual C++ libraries installed via the SDK to build code, such as via setuptools.extension.Extension or numpy.distutils.core.Extension.
For example, building
f2py
modules in Windows with Python requires Visual C++ SDK as installed above.
On Linux and Mac, the C++ libraries are installed with the compiler.
Microsoft Visual C++ 10.0 is required (unable to find vcvarsall.bat)
was formerly fixed by installing Microsoft Visual C++ Compiler
for Python 2.7.
However, this download is NO LONGER AVAILABLE.
It’s recommended in general to use a recent Python 3 version instead.
Visual Studio is used for Python on Windows whenever C, C++, Fortran or other compiled language extension modules are used from Python.
For example, a C library may be used for better performance, seamlessly called from Python.
A downside of this prototyping method is reliance on an opaque proprietary toolchain.
If your prototype has a corner case Mathworks didn’t anticipate you may have to recode in another language such as Python that runs directly on the embedded computer.
Another alternative is running the Matlab script directly on the embedded system using GNU Octave.
We have achieved 30+ fps batch processing on video motion streams on the Raspberry Pi Zero with GNU Octave.
Popular Raspberry Pi operating systems can easily install a recent
GNU Octave.
We suggest installing Octave with
apt install --no-install-recommends octave
We suggest first installing Octave on your laptop to verify the particular Matlab script works with Octave.
If the script doesn’t work with Octave and it seems too difficult to do so, consider transitioning to Python.
MacOS
Frameworks
are linked with the -framework flag.
CMake has special handling for these flags, so target_link_libraries should be used for them.
The quoting in the example below is necessary to get CMake handling the flags correctly.
The optional “setup.py” for setuptools-based Python packages can be reduced to a one-line file for simple Python packages, by putting the project
metadata in setup.cfg.
The example setup.cfg file below is associated with a setup.py file containing merely:
from setuptools import setup; setup()
This is installed as usual like:
python -m pip install -e .
It can be most effective to put all project configuration, including Python package prerequisites in setup.cfg instead of setup.py.
setup.cfg is human-readable and machine-parseable without first installing the package.
Putting as many parameters as possible into setup.cfg instead of setup.py is
important
and beneficial
for reasons including:
reproducible results
security risk mitigation
getting package prerequisite tree list
This is an example of best practices (since 2016) of minimal setup.py using setup.cfg.
It does not use requirements.txt.
setup.cfg holds the machine-readable configuration, easy for humans too.
The “version” is contained in file “mypkg/init.py” as Python code:
__version__ ="1.2.3"
setup.cfg file contains:
[metadata]name=mypkgauthor=Joe Smithauthor_email=me@gmail.comdescription=My awesome program prints cool messagesversion=attr: mypkg.__version__url=https://github.com/joe/mypkgkeywords= cool printing
networkingclassifiers= Development Status :: 4 - Beta
Intended Audience :: Science/Research
Programming Language :: Python :: 3
Topic :: Scientific/Engineeringlicense_files= LICENSE.txt[options]python_requires=>= 3.8packages=find:zip_safe=Falseinstall_requires=# numpy[options.extras_require]tests= pytest
flake8
mypy[options.entry_points]console_scripts=# joesprog = mypkg:__main__:cli
“console_scripts” expects a file “mypkg/main.py” with the function “cli()” designed to accept command line input, perhaps using argparse.ArgumentParser
The companion to setup.cfg is pyproject.toml.
pyproject.toml is used in general for Python project settings, including ones not using setuptools.
The standard way to communicate that setuptools is used for a Python project is with pyproject.toml containing:
[build-system]
requires = ["setuptools", "wheel"]
PEP8 checking via flake8 is configured in .flake8:
python_requires parameter avoids user confusion if they have an old Python version.
Instead of them opening a GitHub issue or just not using your program at all, they’ll get a useful error message.
Python can easily
import Fortran code using f2py.
See this f2py example
setup.py.
setuptools 38.6
and
wheel 0.31
support Markdown README.
Pip 10 brought pyproject.toml support, necessary for clean handling of Python Extension Modules via Numpy as well as setup.cfg support.