Scientific Computing

C / C++ tell source file location

C has long had the __FILE__ macro, which expands to a string literal containing the name or path to the current source file. C++ provides a much more powerful mechanism to programmatically determine the source file location via source_location in the <source_location> header introduced in C++20. This capability is particularly powerful for logging and debugging, as shown in the example linked above that a function’s caller can be located by source file and line number without the caller needing to explicitly pass that information.

Matlab Command Window restore

Sometimes when opening the Matlab Desktop, the Command Window where one types commands might not be visible. This can be restored from the “Home” tab on the top ribbon, click the “Layout” button on the Environment section, and click “Two Column (default)”. Notice that one can also “Save Layout” to store the current layout for future use and easily select between layout suitable for different tasks.

QEMU RISC-V Ubuntu quickstart

At the the writing, UTM didn’t have a known way to work with RISC-V, so we use QEMU directly on macOS (or Linux). Obtain QEMU - on macOS via brew install qemu or on Linux via the package manager (e.g. apt install qemu). We need a uboot.elf. One way to get it is from a Linux machine or VM if on macOS by apt install u-boot-qemu and then copy the file from /usr/lib/u-boot/qemu/riscv64/uboot.elf to the machine where you want to run QEMU.

cp /usr/lib/u-boot/qemu-riscv64_smode/uboot.elf ~/uboot.elf

Then obtain the Ubuntu LTS RISCV image.

Extract the image like:

unxz ubuntu-24.04.4-preinstalled-server-riscv64.img.xz

It’s important to increase the disk size, otherwise the image will run of space quickly when installing compilers etc. Add say 10 GB of virtual HD space by:

qemu-img resize -f raw ubuntu-*-preinstalled-server-riscv64.img +10G

Then run QEMU like (perhaps make a little script):

img=$HOME/riscv_vm/ubuntu-24.04.4-preinstalled-server-riscv64.img
uboot=$HOME/riscv_vm/uboot.elf

qemu-system-riscv64 \
-machine virt -nographic -m 2048 -smp 4 \
-kernel ${uboot} \
-device virtio-net-device,netdev=eth0 -netdev user,id=eth0 \
-device virtio-rng-pci \
-drive file=${img},format=raw,if=virtio

This should boot the Ubuntu image and in a few minutes get to the login prompt. The default username is ubuntu and the password is ubuntu.

pre-commit exclude files

When using Git pre-commit hooks with the wide range of files typical of scientific computing, it may occur that the hooks modify files that should be excluded, such as FITS files that have a text header and a binary data part. Exclude such files by using case-insensitive regex patterns in the .pre-commit-config.yaml file by top level exclude key, for example to case-insensitively exclude files with the .fit or .fits extension, use:

exclude: (?i)\.fits?$

Because it’s considered an anti-pattern to have a global pre-commit config, such exclusions and all other pre-commit configuration on a per-repo basis.

Fortran compiler flags for legacy code

To compile legacy Fortran code, certain compiler flags can be used to enable non-standard Fortran syntax that was common before the Fortran 95 standard became widely adopted. It’s hard to pin an exact year for when developers transitioned to more standard Fortran code, but the mid-2000s is a reasonable estimate for when Fortran codebases started to modernize in significant numbers. Gfortran took over from g77 as the default Fortran compiler circa 2005 and was the first widely used free Fortran compiler capable of the Fortran 95 standard. Here are legacy-enabling flags for currently maintained Fortran compilers.

In addition to the flags below, it may be necessary to provide default real and / or integer precision flags to compile old code that relies on the default precision being different than the modern default of 4 bytes for real and 4 bytes for integer.

GNU GFortran

  • -std=legacy enables pre-Fortran 77 arbitrary length arrays, where A(1) was declared instead of A(*) in Fortran 77 or A(:) in modern Fortran.
  • -fdec- options enable various non-standard extensions in the DEC Fortran style.
  • see also Gfortran runtime options for issues reading binary files.

LLVM Flang

Flang compiler flags have a “-std” option that might be checked to see if the project sets it too restrictively.

Intel oneAPI

  • -nostand does not change compiler behavior–it disables standard-based warnings.
  • -f66 apples Fortran 66 semantic rules, including Do loops that always run at least once.

IBM OpenXL

Cray Fortran

The ftn compiler can disable some checks with flags like -d C

Git config files

Git uses per-user ~/.gitconfig, per-repository .git/config configuration files, and environment variables to customize Git behavior. The system gitconfig file is not covered here. A common pattern is a developer makes most of their settings in the per-user Git config file, occasionally overriding them in the per-repository config file.

We have several articles on Git configuration, leading to a per-user Git config file with sections like:

pull HTTPS for speed, push SSH for security

[url "ssh://github.com/"]
	pushInsteadOf = https://github.com/
[url "ssh://gitlab.com/"]
	pushInsteadOf = https://gitlab.com/
[url "ssh://gist.github.com/"]
	pushInsteadOf = https://gist.github.com/scivision/
[url "ssh://gitlab.kitware.com/"]
    pushInsteadOf = https://gitlab.kitware.com/

Use Meld for diff and merge

[diff]
	tool = meld
[merge]
	tool = meld

Maintain linear Git history with fast-forward only by default with pull.ff only

[pull]
    ff = only

Check upon “git push” if all Git submodules have first been “git push” before the consuming repository, to avoid broken builds for others with push.recurseSubmodules check

[push]
	recurseSubmodules = check

For any Git operation (except “git clone”) that changs references to Git submodules commit hashes, automatically update the Git submodules to match the new commit hashes with option submodules.recurse true

[submodule]
	recurse = true

CMake version recommendations and install

Downloading the latest release of CMake is usually easy. Admin / sudo is not required.

  • Linux: snap install cmake
  • macOS: brew install cmake
  • Windows: winget install Kitware.CMake
  • PyPI CMake package: python -m pip install cmake

For platforms where CMake binaries aren’t easily available, build CMake using scripts/build_cmake.cmake.

To see the merge requests for a certain release, use a URL like: https://gitlab.kitware.com/cmake/cmake/-/merge_requests?milestone_title=3.32.0&scope=all&state=all

CMake 4.3 additions include:

  • Common Package Specification (CPS) officially supported. This provides a solution for the long-standing program of build system-agnostic JSON package configuration files, which can be generated by CMake’s install(EXPORT) and consumable by other build systems.
  • cmake --version=json-v1 tells details of the libraries vendored into CMake, which is useful for debugging and reporting issues with CMake’s bundled dependencies. This is complementary to cmake -E capabilities which reports specific capabilities of the CMake.
  • CMake command line and archive create commands can specify compression level and algorithm in more detail
  • numerous generator string expressions were added

CMake 4.2 additions include:

  • Visual Studio 18 2026 generator.
  • FASTBuild generator has impressive benchmarks. FASTBuild supports more modern platforms including Windows, versus ccache or distcc.
  • ExternalProject added options to modify environment variables at each step by CONFIGURE_ENVIRONMENT_MODIFICATION, BUILD_ENVIRONMENT_MODIFICATION, INSTALL_ENVIRONMENT_MODIFICATION, TEST_ENVIRONMENT_MODIFICATION
  • Target property SPDX_LICENSE

CMake 4.1 additions include:

  • project() added COMPAT_VERSION that propagates to subdirectories and can be queried for the top-level COMPAT_VERSION.

CMake 4.0 additions include:

CMake 3.31 additions include:

  • CMake warns if cmake_minimum_required() is < 3.10.
  • TLS ≥ 1.2 is required by default for internet operations e.g. file(DOWNLOAD), ExternalProject, FetchContent, and similar.
  • file(ARCHIVE_CREATE) gained a long-needed WORKING_DIRECTORY parameter that is essentially necessary to avoid machine-specific paths being embedded in the archive.
  • CMAKE_LINK_LIBRARIES_STRATEGY allows specifying a strategy for ordering target direct link dependencies.

CMake 3.30 additions include:

  • C++26 support.
  • CMAKE_TLS_VERIFY environment variable was added to set TLS verification (true, false).
  • defaults CMAKE_TLS_VERIFY to on, where previously it was off.

CMake 3.29 additions include:

  • cmake_language(EXIT code) to exit CMake script mode with a specific return code. This is useful when using CMake as a platform-agnostic scripting language instead of shell script.
  • Environment variable CMAKE_INSTALL_PREFIX is used to set the default install prefix across projects–it can be overridden as typical by cmake -DCMAKE_INSTALL_PREFIX= option.
  • Target property TEST_LAUNCHER allows specifying a test launcher. For MPI program this allows deduplicating or making more programmatic test runner scripts.
  • Linker information variables including CMAKE__COMPILER_LINKER_ID have been added to allow programmatic logic like setting target_link_options() based on the particular linker.
  • ctest --parallel without a number or 0 will use unbounded test run parallelism.

CMake 3.28 additions include:

  • changes PATH behavior for Windows find_{library,path,file}() to no longer search PATH. This may break some projects that rely on PATH for finding libraries. MSYS2-distributed CMake is patched to include PATH like earlier CMake, which can be confusing for CI etc. not using MSYS CMake with that patch. Windows CI/user may need to specify CMAKE_PREFIX_PATH like

    cmake -DCMAKE_PREFIX_PATH=$Env:SYSTEMDRIVE/msys64/ucrt64/lib -B build

  • Support for C++20 modules is considerably improved and most users will want at least CMake 3.28 to make C++ modules usable.

  • Generator expressions $<IF> $<AND> $<OR> now short circuit.

  • Test properties now have a DIRECTORY parameter, useful for setting test parameters from the project’s top level CMakeLists.txt.

  • CMake 3.28.4 fixed a long-standing bug in Ninja Fortran targets that use include statements.

CMake 3.27 additions include:

ℹ️ Note

Fortran + Ninja was broken for OBJECT libraries in CMake 3.27.0..3.27.8 and fixed in 3.27.9.

Older CMake changelog

Get Matlab version from Python reading VersionInfo.xml

The Matlab version can be obtained “brute force” by running Matlab, but this can take tens of seconds on a network drive system such as HPC.

matlab -batch "disp(version)"

A much faster way to get the Matlab version is to read the VersionInfo.xml file that is included in the Matlab installation directory. This file contains the version information in XML format, as is available at least back to Matlab R2016a.

This Python script quickly parses the VersionInfo.xml file to extract the Matlab version information without needing to run Matlab itself.

macOS DYLD_LIBRARY_PATH security blocking

Environment variables that start with DYLD_ are restricted by macOS, and are not passed to child processes by default for security reasons. A workaround for this is to use a dummy environment variable that does not start with DYLD_, and then use a wrapper script to read that variable and set the DYLD_LIBRARY_PATH environment variable accordingly. This is necessary because DYLD_LIBRARY_PATH is read at program startup, and setting it within a program will not have any effect on the dynamic linker used by that program. The wrapper script can be used to set the DYLD_LIBRARY_PATH environment variable before executing the desired program, allowing it to find the necessary libraries without being blocked by macOS security restrictions.