Compilers define macros that can be used to identify a compiler and platform from within C, C++ and Fortran code.
This can be useful for many purposes where short bits of platform-specific or compiler-specific code is needed.
If a significant amount of code is needed, it may be better to swap in different code files using the build system instead of lengthly #if defined(foo) logic.
There are numerous examples for C and C++ so here we will focus on macros of Fortran compilers.
Gfortran
Gfortran compiler macro definitions are obtained in an OS-agnostic way by:
echo "" | gfortran -dM -E - > macros.txt
that creates a file “macros.txt” containing all the compiler macros.
commonly used macros to detect operating system / compiler configuration include:
_WIN32 1
__linux__ 1
__unix__ 1
__APPLE__ 1
Intel Fortran
Intel Fortran
compiler macros
include the Gfortran macros noted above and additionally:
__INTEL_COMPILER 1
PGI Fortran
PGI Fortran compiler macros are printed by:
pgfortran -dM
the PGI macros include the Gfortran macros above as well as:
Meson subproject and CMake ExternalProject keep project namespaces separate.
Meson subproject and CMake FetchContent download and configure all projects at configure time.
CMake FetchContent comingles the CMake project namespaces.
FetchContent can be easier to use than ExternalProject if you control both software projects’ CMake scripts.
If you don’t control the “child” project, it may be better to use ExternalProject instead of FetchContent.
For these examples, suppose we have a top-level project “parent” and a “child” project containing a library that is desired in parent.
Suppose the child project can be built standalone (by itself) but also may be used directly from other CMake projects.
project
CMAKE_SOURCE_DIR
CMAKE_BINARY_DIR
PROJECT_SOURCE_DIR
parent
~/foo
~/foo/build
~/foo
child: standalone
~/bar
~/bar/build
~/bar
child: CMake ExternalProject
~/foo/build/child-prefix/src/child
~/foo/build/child-prefix/src/child-build
~/foo/build/child-prefix/src/child
child: CMake FetchContent
~/foo
~/foo/build
~/foo/build/_deps/child-src
FetchContent
FetchContent populates content from the other project at configure time.
FetchContent populates the “child” project with default values from the “parent” project.
Varibles set in the “child” project generally do not affect the “parent” project unless specifically used from the “parent” project.
From “parent” project CMakeLists.txt:
cmake_minimum_required(VERSION3.14)project(parentFortran)include(FetchContent)FetchContent_Declare(childGIT_REPOSITORYhttps://github.invalid/username/child.gitGIT_TAGmaster# it's much better to use a specific Git revision or Git tag for reproducibility
)FetchContent_MakeAvailable(child)# your program
add_executable(myprogmain.f90)target_link_libraries(myprogmylib) # mylib is from "child"
FetchContent_MakeAvailable
make “child” code configure, populating variables and targets as if it were part of “parent” CMake project.
The child project CMAKE_BINARY_DIR and CMAKE_SOURCE_DIR will be those of parent project.
That is, if the parent project is in ~/foo and the build directory is ~/foo/build, then the child project in ~/childcode called by FetchContent will also have CMAKE_SOURCE_DIR of ~/foo and CMAKE_BINARY_DIR of ~/foo/build.
So be careful in the child project when using such variables that may be defined by parent projects.
This is why projects that aren’t specifically designed to work together may be better joined by ExternalProject.
A typical technique within the child project that can operate standalone is to refer to CMAKE_CURRENT_SOURCE_DIR instead of CMAKE_SOURCE_DIR as the latter will break when used from FetchContent.
ExternalProject
ExternalProject populates content from the other project at build time.
This means the other project’s libraries are not visible until the parent project is built.
Since ExternalProject does not combine the project namespaces, ExternalProject may be necessary if you don’t control the other projects.
ExternalProject will not download, configure or build without the add_dependencies() statement.
Upon cmake --build of the parent project, ExternalProject downloads, configures and builds.
From “parent” project CMakeLists.txt:
project(parentFortran)include(ExternalProject)ExternalProject_Add(child_projGIT_REPOSITORYhttps://github.com/scivision/cmake-externalprojectGIT_TAGmaster# it's much better to use a specific Git revision or Git tag for reproducability
INSTALL_COMMAND""# this disables the install step for the external project
)ExternalProject_Get_Property(child_projBINARY_DIR)file(MAKE_DIRECTORY${BINARY_DIR}/include) # avoid race condition
add_library(timestwoSTATICIMPORTEDGLOBAL)set_target_properties(timestwoPROPERTIESIMPORTED_LOCATION${BINARY_DIR}/${CMAKE_STATIC_LIBRARY_PREFIX}timestwo${CMAKE_STATIC_LIBRARY_SUFFIX}INTERFACE_INCLUDE_DIRECTORIES${BINARY_DIR}/include)add_executable(test_timestwotest_timestwo.f90) # your program
add_dependencies(test_timestwochild_proj) # externalproject won't download without this
target_link_libraries(test_timestwotimestwo)
Since the ExternalProject is built by itself and generally is unaware of the consuming “parent”, this does NOT work to detect use as an ExternalProject:
project(child...)# "is_fetched" is:
# * ExternalProject: false--does not detect
# * FetchContent: true
set(is_fetched (NOTCMAKE_SOURCE_DIRSTREQUALPROJECT_SOURCE_DIR))
Note that the
PARENT_DIRECTORY
property is NOT useful for detecting if the “child” is being used as an ExternalProject.
target_link_directories() is generally NOT preferred because library name collisions can occur, particularly with system libraries.
As a CMake project grows, the increasing complexity can make it hard to remember what tests are to be run.
Perhaps the project logic is unexpectedly omitting necessary tests.
The CI system or human can verify the list of tests is as expected by parsing the simple text output from:
ctest -N
before this, the project must be configured and built as usual:
If the Git commits have already been push to remote, this process will require other users of the repo to reset or reclone.
That’s true with any Git operation that edits history.
If the Git commits have not already been pushed, then this process will not require extra steps from other repo users.
show commit AuthorDate CommitDate
In general, show any commit’s AuthorDate and CommitDate by
git show <commit_hash> --pretty=fuller
for the most recent commit, simply:
git show --pretty=fuller
edit last commit only
To reset the author of the last commit to the current Git username and email, as well as setting AuthorDate and CommitDate to the current time:
Intel Fortran on Windows provides an easy way to use Fortran MPI on Windows.
The Intel Fortran compile and link commands on Windows are distinct from those on Linux / MacOS, perhaps reflecting the internal use of Visual Studio on Windows.
The HDF5 1.10.6 release changed the naming convention for the HDF5 Fortran library files on all operating systems.
old: hdf5hl_fortran.
new: hdf5_hl_fortran.
CMake’s FindHDF5.cmake did not have this change in CMake 3.16.2.
We created a CMake Issue for this.
Tentatively one can compile using HDF5 with Intel Fortran on Windows like:
The free open source SSH app
ConnectBot
allows connecting to SSH servers with port forwarding using public key authentication, including ED25519.
Problem
Sometimes it’s necessary to share SSH keypairs on multiple clients.
Perhaps the server owner isn’t willing to bother with more than one SSH client key, and you don’t have shell access on SSH login to add another key yourself.
ConnectBot has an
open issue
since it cannot import OpenSSH keys created on a PC.
Generally users should create unique SSH public/private keypairs for each device.
Sharing keys between devices means if a device is compromised, deleting its key from ~/.ssh/authorized_keys on the SSH server disables all other devices sharing that key.
Workaround
Create an SSH keypair in ConnectBot.
Copy the ConnectBot-created public/private keypair to the PC ~/.ssh directory.
The stem (filename without extension) of the public and private keys must match.
The public key should have a .pub suffix, while the private key has no suffix.
Thereby the same SSH keypair is used on your phone with ConnectBot and your PC with OpenSSH client.
Carriers in numerous countries worldwide have shutdown 2G networks to free spectrum for 3G, 4G and 5G services.
Embedded modems such as automotive (OnStar) and alarm systems may again be impacted by these shutdowns.
In developing regions we anticipate 2G networks will linger for several more years, due to cost-effective legacy devices.
Those designing IoT and other embedded devices with cellular modems should consider LPWA 4G LTE, particularly Cat M1 and NB1 to help ensure global functionality.
Each geopolitical region has unique LTE bands, but often OEM modules with the same pinout have region-specific models.
OEM LTE modules will incorporate at least some bands for each region, so that global LTE roaming for even inexpensive LTE modems will become increasingly common.
A local Git repo can become corrupted in rare circumstances, perhaps doing a git commit just as a computer crashes or loses power.
A common symptom of a corrupted local Git repo is any Git command except for perhaps git diff giving error:
fatal: your current branch appears to be broken
The changes are likely still present, as seen via git diff.
Previous commits that were not pushed to remote are likely present as well in the form of the modified files,
but the historical local Git commit deltas may not be recoverable.
This recovery will in effect “squash” the local commits that weren’t previously pushed to remote.
NOTE: work done on other branches that weren’t pushed to remote may not be retrievable.
Recovery
Copy the directory tree of the affected local Git repo, preferably on another hard drive or in the cloud.
git clone a fresh copy of the remote Git repo to a new directory
use a program like Meld to incrementally copy into the new directory the changes from the old corrupted directory.
If there are a large number of changes, consider making the changes via multiple Git commits.
On Jan 2, 2020 DraftSight Linux discontinuation was announced.
Consider
libre
free CAD programs that work on Linux, MacOS and Windows instead of DraftSight.
DraftSight is a non-free program available for Windows only, and in the future for cloud.
To our Linux users: thank you for your support. As communicated in 2019, all free versions of DraftSight ended 12/31 including Linux Beta. We look forward to releasing a more flexible, scalable solution this year, DraftSight Cloud, enabling DraftSight on your browser. Stay tuned! pic.twitter.com/364uqzbwYF
3DS DraftSight has 2-D and some 3-D functionality.
All no-cost DraftSight licenses were
terminated on 31 DEC 2019.
DraftSight was provided at no cost from 2010-2019 for Windows, MacOS and Linux.
DraftSight is natively compatible with AutoCAD DWG / DXF
formats
through R2018 (used by AutoCAD 2020).
Hi-DPI
If you have a high resolution screen and the DraftSight GUI icons look too small, try
Tools → Options → System Options → Display → Screen Options → Use Large Icons.
This article is for AutoCAD 2-D libre alternatives available for Linux, MacOS and Windows.
Other
free CAD programs
exist, but they generally require retraining for users coming from AutoCAD.
Libre 2-D AutoCAD-like
Libre 2-D AutoCAD-like choices include:
QCAD
LibreCAD
DWG for QCAD and LibreCAD is via the free ODA DWG ↔ DXF converter.
FreeCAD is 3-D parametric modeling akin to SolidWorks.
FreeCAD can
import DXF or DWG
using ODA DWG ↔ DXF converter.
Free, non-libre
ODA File Converter
supports through
R2020 DWG/DXF.
ODA File Converter may be used to convert from DXF to DWG en masse as a first/last step.
The OpenDesignAlliance is the same organization where QCad gets its non-free non-libre converter.