I have never worked with CMake before, so please forgive any rookie mistakes. Most of the following working frame has been given to me by my project group.
The goal is to build GoogleTest into a .dll, to be used in different, indepentent parts of our project. I'm having troubles setting up CMake the right way.
The work-flow so far has been:
Clone gtest from git --> also downloads a CMake List file
Alter variables in CMakeCache.txt to have it produce a Code::Blocks project file
Compile the project file in Code::Blocks
So far, it produces a static library (.a files) that can be used in our project. I'm having troubles genereating .dll files.
Variables I have tried changing:
BUILD_SHARED_LIBS:BOOL=ON --> the files generated by Code::Blocks now have a .dll.a double extension
CMAKE_C_FLAGS and all the corresponding C++ flags where set to -DGTEST_CREATE_SHARED_LIBRARY=1 as given here
CMAKE_EXE_LINKER_FLAGS has been set to -shared to make the linker produce .dll files
I have worked my way through the GoogleTest documentation here and here but in both, building it into a .dll is merely a 2-sentence-topic.
As #Tsyvarev pointed out, the .dll files were created in a (very) different folder.
This question already has answers here:
How to detect if current scope has a parent in CMake?
(3 answers)
How can I tell, within a CMakeLists.txt, whether it's used with add_subdirectory()? [duplicate]
(1 answer)
Closed 4 months ago.
I have a small CMake project that encapsulate a small C++ library. For this library, I want to enable almost all available warnings by default while developing it. However, if someone wants to make use of my library and therefore uses add_subdirectory to include my project, I would like to disable warnings for my library.
I know how to disable warnings, but I would like to know how one would go about detecting whether the CMake project is currently processed stand-alone or embedded in another CMake project.
CMake >= v3.21
There's a boolean flag PROJECT_IS_TOP_LEVEL, which seems to indicate exactly this.
For more general querying (not only the current project), there's also <PROJECT-NAME>_IS_TOP_LEVEL.
CMake pre < v3.21
Disclaimer: This answer assumes that project calls always happen in the first processed CMakeLists.txt file that is processed for every project.
The best way to check for this (to my knowledge) would be to test whether the variables CMAKE_SOURCE_DIR and PROJECT_SOURCE_DIR (note: no CMAKE_ prefix) refer to the same path.
From the docs 1, 2:
CMAKE_SOURCE_DIR
The path to the top level of the source tree.
This is the full path to the top level of the current CMake source tree.
PROJECT_SOURCE_DIR
This is the source directory of the last call to the project() command made in the current directory scope or one of its parents. Note, it is not affected by calls to project() made within a child directory scope (i.e. from within a call to add_subdirectory() from the current scope).
So the gist of it is that if the project is built stand-alone, top-level source directory, is the one that contains your own CMakeLists.txt file, which (as is normally the case) contains the project call of your own project. Assuming you don't have multiple project calls in your project (again: as is usually the case), that means that the directory in which the last project call happened (and which does not lie in a sun directory of your current directory, which according to the docs don't count) is the same as the top-level source directory. Therefore, the mentioned variables will refer to the same path.
If, however, your project is embedded in someone else's CMake project, their CMakeLists.txt location will define the top-level source directory. At some point, they will include your project, which starts by its own project call, updating PROJECT_SOURCE_DIR to the path to the directory in which your CMakeLists.txt file lies. Therefore, CMAKE_SOURCE_DIR != PROJECT_SOURCE_DIR.
TL;DR: This is the necessary check
if (CMAKE_SOURCE_DIR STREQUAL PROJECT_SOURCE_DIR)
message(STATUS "Your project is standalone")
else()
message(STATUS "Your project is embedded")
endif()
This question already has an answer here:
CMake globbing generated files
(1 answer)
Closed last year.
In the below minimal example, if I know the name of the generated source file in advance (test1.txt), I could do the below
cmake_minimum_required(VERSION 3.20)
project(example)
add_executable(example main.cpp ${CMAKE_BINARY_DIR}/test1.txt)
set_source_files_properties(${CMAKE_BINARY_DIR}/test1.txt PROPERTIES GENERATED TRUE)
However, how can I achieve the same thing if I don't know the name of the generated files in advance? For my application, it will also work if the generated files are added to another target instead of the original one. Please see below of my failed attempt
cmake_minimum_required(VERSION 3.20)
project(example)
add_executable(example main.cpp)
add_custom_target(
example-generate
COMMAND $<TARGET_FILE:example>
COMMAND "using bash commands to glob the generated files but need to find a way to output the result to a cmake variable"
DEPENDS example)
add_library(example2 OBJECT) # the target with the generated unknown sources, but I can't find a way to add sources to it in build time
add_dependencies(example2 example-generate)
You can generate a dummy source file with a concrete name that #includes all the others.
You might need to write out a DEPFILE to get accurate incremental-build dependencies (if the list of files depends on something other than the example sources/binary or command-line invocation).
I have the following layout. It is basically a certain class, and within its directory there is a subdirectory containing unit tests:
The class being tested is built like this:
add_library(experimental_run PUBLIC ${PROJECT_SOURCE_DIR}/experiments/experimental_run/experimental_run.cpp)
target_link_libraries(experimental_run PUBLIC nlohmann_json::nlohmann_json)
(this is the outermost CMakeLists in the image).
The tests-directory's CMakeLists.txt's contents are as follows:
cmake_minimum_required(VERSION 3.13)
add_executable(test_experimental_run_obj ${CMAKE_CURRENT_SOURCE_DIR}/test_experimental_run.cpp)
target_compile_options(test_experimental_run_obj PUBLIC -pg -g -O2)
target_link_libraries(test_experimental_run_obj PUBLIC experimental_run GTest::GTest GTest::Main)
target_include_directories(
test_experimental_run_obj PUBLIC
${PROJECT_SOURCE_DIR}/experiments/experimental_run/)
Essentially, first I am building the class as a library,
and then try to build the unit tests linking them towards
the library and including the appropriate directory
with target_include_directories and ${PROJECT_SOURCE_DIR}, where the latter
stores the root directory of the project.
Now this looks like I am effectively telling CMake "Feel free to look into the included
directories for anything you find in my #includes." However, my unit-test file
has it in red:
and prompts me to include the files using "../"
Now, why then I bothered to have the target_include_directories in the first place,
if I am to explicitly show the location anyway? Isn't the main idea
to make the whole thing flexible, without code duplication?
What am I missing?
EDIT: now that I went ahead and did include the "../"-prefix, the unit tests fail to compile, since the linked library experimental_run is non-existent. No wonder, since CLion does not seem to recognize it as something it needs to build.
EDIT: I've figured out one thing for now. CMAKE_PROJECT_SOURCE_DIR refers to the directory of where this _very CMakeLists resides, i.e. referring to the project's argument. This way, I can load the outermost library as a CMake project, but however cannot link against it inside the tests still.
(final) UPDATE:
Let's say I found a "workaround" this by adding
set(SOURCES ./test_experimental_run.cpp ../experimental_run.cpp)
set(TARGET test_experimental_run_obj)
into the CMakeLists of the unit-tests directory, and to no surprise it
compiles and works fine. If I remove he second *.cpp file, however,
and add experimental_run to target_link_libraries, I get
[ 50%] Linking CXX executable test_experimental_run_obj
/usr/bin/ld: cannot find -lexperimental_run
collect2: error: ld returned 1 exit status
Essentially the question is how to test the library assuming it is compiled,
and without having to specify its source code inside the unit-testing code.
Appreciate your time, I am yet developing my modus operandi with CMake,
so even shaping the right question is challenging for me right now.
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It is notoriously difficult to get any useful information on CMake as a beginner. So far, I've seen a few tutorials on how to set up some very basic project or another. However, none of these explain the reasoning behind anything that is shown in them, always leaving many holes to fill.
What does calling CMake on a CMakeLists mean? Is it supposed to be called once per build tree or what? How do I use different settings for each build if they all use the same CMakeLists.txt file from the same source?
Why does each subdirectory need its own CMakeLists file? Would it make sense to use CMake on a CMakeLists.txt other than the one at the root of the project? If so, in what cases?
What's the difference between specifying how to build an executable or library from the CMakeLists file in their own subdirectory versus doing it in the CMakeLists file at the root of all source?
Can I make a project for Eclipse and another for Visual Studio, just changing the -G option when calling CMake? Is that even how it's used?
None of the tutorials, documentation pages or questions/answers I've seen so far give any useful insight towards understanding how to use CMake. The examples are just not thorough. No matter what tutorials I read, I feel like I'm missing something important.
There are many questions asked by CMake newbies like me that don't ask this explicitly, but that make obvious the fact that, as newbs, we have no idea how to deal with CMake or what to make of it.
What is CMake for?
According to Wikipedia:
CMake is [...] software for managing the build process of software
using a compiler-independent method. It is designed to support
directory hierarchies and applications that depend on multiple
libraries. It is used in conjunction with native build environments
such as make, Apple's Xcode, and Microsoft Visual Studio.
With CMake, you no longer need to maintain separate settings specific to your compiler/build environment. You have one configuration, and that works for many environments.
CMake can generate a Microsoft Visual Studio solution, an Eclipse project or a Makefile maze from the same files without changing anything in them.
Given a bunch of directories with code in them, CMake manages all the dependencies, build orders and other tasks that your project needs done before it can be compiled. It does NOT actually compile anything. To use CMake, you must tell it (using configuration files called CMakeLists.txt) what executables you need compiled, what libraries they link to, what directories there are in your project and what is inside of them, as well as any details like flags or anything else you need (CMake is quite powerful).
If this is correctly set up, you then use CMake to create all of the files that your "native build environment" of choice needs to do its job. In Linux, by default, this means Makefiles. So once you run CMake, it will create a bunch of files for its own use plus some Makefiles. All you need to do thereafter is type "make" in the console from the root folder every time you're done editing your code, and bam, a compiled and linked executable is made.
How does CMake work? What does it do?
Here is an example project setup that I will use throughout:
simple/
CMakeLists.txt
src/
tutorial.cxx
CMakeLists.txt
lib/
TestLib.cxx
TestLib.h
CMakeLists.txt
build/
The contents of each file are shown and discussed later on.
CMake sets your project up according to the root CMakeLists.txt of your project, and does so in whatever directory you executed cmake from in the console. Doing this from a folder that isn't the root of your project produces what is called an out-of-source build, which means files created during compilation (obj files, lib files, executables, you know) will be placed in said folder, kept separate from the actual code. It helps reduce clutter and is preferred for other reasons as well, which I will not discuss.
I do not know what happens if you execute cmake on any other than the root CMakeLists.txt.
In this example, since I want it all placed inside the build/ folder, first I have to navigate there, then pass CMake the directory in which the root CMakeLists.txt resides.
cd build
cmake ..
By default, this sets everything up using Makefiles as I've said. Here is what the build folder should look like now:
simple/build/
CMakeCache.txt
cmake_install.cmake
Makefile
CMakeFiles/
(...)
src/
CMakeFiles/
(...)
cmake_install.cmake
Makefile
lib/
CMakeFiles/
(...)
cmake_install.cmake
Makefile
What are all of these files? The only thing you have to worry about is the Makefile and the project folders.
Notice the src/ and lib/ folders. These have been created because simple/CMakeLists.txt points to them using the command add_subdirectory(<folder>). This command tells CMake to look in said folder for another CMakeLists.txt file and execute that script, so every subdirectory added this way must have a CMakeLists.txt file within. In this project, simple/src/CMakeLists.txt describes how to build the actual executable and simple/lib/CMakeLists.txt describes how to build the library. Every target that a CMakeLists.txt describes will be placed by default in its subdirectory within the build tree. So, after a quick
make
in console done from build/, some files are added:
simple/build/
(...)
lib/
libTestLib.a
(...)
src/
Tutorial
(...)
The project is built, and the executable is ready to be executed. What do you do if you want the executables put in a specific folder? Set the appropriate CMake variable, or change the properties of a specific target. More on CMake variables later.
How do I tell CMake how to build my project?
Here are the contents, explained, of each file in the source directory:
simple/CMakeLists.txt:
cmake_minimum_required(VERSION 2.6)
project(Tutorial)
# Add all subdirectories in this project
add_subdirectory(lib)
add_subdirectory(src)
The minimum required version should always be set, according to the warning CMake throws when you don't. Use whatever your version of CMake is.
The name of your project can be used later on, and hints towards the fact you can manage more than one project from the same CMake files. I won't delve into that, though.
As mentioned before, add_subdirectory() adds a folder to the project, which means CMake expects it to have a CMakeLists.txt within, which it will then run before continuing. By the way, if you happen to have a CMake function defined you can use it from other CMakeLists.txts in subdirectories, but you have to define it before you use add_subdirectory() or it won't find it. CMake is smarter about libraries, though, so this is likely the only time you will run into this kind of problem.
simple/lib/CMakeLists.txt:
add_library(TestLib TestLib.cxx)
To make your very own library, you give it a name and then list all the files it's built from. Straightforward. If it needed another file, foo.cxx, to be compiled, you would instead write add_library(TestLib TestLib.cxx foo.cxx). This also works for files in other directories, for instance add_library(TestLib TestLib.cxx ${CMAKE_SOURCE_DIR}/foo.cxx). More on the CMAKE_SOURCE_DIR variable later.
Another thing you can do with this is specify that you want a shared library. The example: add_library(TestLib SHARED TestLib.cxx). Fear not, this is where CMake begins to make your life easier. Whether it's shared or not, now all you need to handle to use a library created in this way is the name you gave it here. The name of this library is now TestLib, and you can reference it from anywhere in the project. CMake will find it.
Is there a better way to list dependencies? Definitely yes. Check down below for more on this.
simple/lib/TestLib.cxx:
#include <stdio.h>
void test() {
printf("testing...\n");
}
simple/lib/TestLib.h:
#ifndef TestLib
#define TestLib
void test();
#endif
simple/src/CMakeLists.txt:
# Name the executable and all resources it depends on directly
add_executable(Tutorial tutorial.cxx)
# Link to needed libraries
target_link_libraries(Tutorial TestLib)
# Tell CMake where to look for the .h files
target_include_directories(Tutorial PUBLIC ${CMAKE_SOURCE_DIR}/lib)
The command add_executable() works exactly the same as add_library(), except, of course, it will generate an executable instead. This executable can now be referenced as a target for things like target_link_libraries(). Since tutorial.cxx uses code found in the TestLib library, you point this out to CMake as shown.
Similarly, any .h files #included by any sources in add_executable() that are not in the same directory as the source have to be added somehow. If not for the target_include_directories() command, lib/TestLib.h would not be found when compiling Tutorial, so the entire lib/ folder is added to the include directories to be searched for #includes. You might also see the command include_directories() which acts in a similar fashion, except that it does not need you to specify a target since it outright sets it globally, for all executables. Once again, I'll explain CMAKE_SOURCE_DIR later.
simple/src/tutorial.cxx:
#include <stdio.h>
#include "TestLib.h"
int main (int argc, char *argv[])
{
test();
fprintf(stdout, "Main\n");
return 0;
}
Notice how the "TestLib.h" file is included. No need to include the full path: CMake takes care of all that behind the scenes thanks to target_include_directories().
Technically speaking, in a simple source tree like this you can do without the CMakeLists.txts under lib/ and src/ and just adding something like add_executable(Tutorial src/tutorial.cxx) to simple/CMakeLists.txt. It's up to you and your project's needs.
What else should I know to properly use CMake?
(AKA topics relevant to your understanding)
Finding and using packages: The answer to this question explains it better than I ever could.
Declaring variables and functions, using control flow, etc.: check out this tutorial that explains the basics of what CMake has to offer, as well as being a good introduction in general.
CMake variables: there are plenty, so what follows is a crash course to get you on the right track. The CMake wiki is a good place to get more in-depth information on variables and ostensibly other things as well.
You may want to edit some variables without rebuilding the build tree. Use ccmake for this (it edits the CMakeCache.txt file). Remember to configure when done with the changes and then generate makefiles with the updated configuration.
Read the previously referenced tutorial to learn about using variables, but long story short:
set(<variable name> value) to change or create a variable.
${<variable name>} to use it.
CMAKE_SOURCE_DIR: The root directory of source. In the previous example, this is always equal to /simple
CMAKE_BINARY_DIR: The root directory of the build. In the previous example, this is equals to simple/build/, but if you ran cmake simple/ from a folder such as foo/bar/etc/, then all references to CMAKE_BINARY_DIR in that build tree would become /foo/bar/etc.
CMAKE_CURRENT_SOURCE_DIR: The directory in which the current CMakeLists.txt is in. This means it changes throughout: printing this from simple/CMakeLists.txt yields /simple, and printing it from simple/src/CMakeLists.txt yields /simple/src.
CMAKE_CURRENT_BINARY_DIR: You get the idea. This path would depend not only on the folder the build is in, but also on the current CMakeLists.txt script's location.
Why are these important? Source files will obviously not be in the build tree. If you try something like target_include_directories(Tutorial PUBLIC ../lib) in the previous example, that path will be relative to the build tree, that is to say it will be like writing ${CMAKE_BINARY_DIR}/lib, which will look inside simple/build/lib/. There are no .h files in there; at most you will find libTestLib.a. You want ${CMAKE_SOURCE_DIR}/lib instead.
CMAKE_CXX_FLAGS: Flags to pass on to the compiler, in this case the C++ compiler. Also worth noting is CMAKE_CXX_FLAGS_DEBUG which will be used instead if CMAKE_BUILD_TYPE is set to DEBUG. There are more like these; check out the CMake wiki.
CMAKE_RUNTIME_OUTPUT_DIRECTORY: Tell CMake where to put all executables when built. This is a global setting. You can, for instance, set it to bin/ and have everything neatly placed there. EXECUTABLE_OUTPUT_PATH is similar, but deprecated, in case you stumble upon it.
CMAKE_LIBRARY_OUTPUT_DIRECTORY: Likewise, a global setting to tell CMake where to put all library files.
Target properties: you can set properties that affect only one target, be it an executable or a library (or an archive... you get the idea). Here is a good example of how to use it (with set_target_properties().
Is there an easy way to add sources to a target automatically? Use GLOB to list everything in a given directory under the same variable. Example syntax is FILE(GLOB <variable name> <directory>/*.cxx).
Can you specify different build types? Yes, though I'm not sure about how this works or the limitations of this. It probably requires some if/then'ning, but CMake does offer some basic support without configuring anything, like defaults for the CMAKE_CXX_FLAGS_DEBUG, for instance.
You can either set your build type from within the CMakeLists.txt file via set(CMAKE_BUILD_TYPE <type>) or by calling CMake from console with the appropriate flags, for example cmake -DCMAKE_BUILD_TYPE=Debug.
Any good examples of projects that use CMake? Wikipedia has a list of open-source projects that use CMake, if you want to look into that. Online tutorials have been nothing but a letdown to me so far in this regard, however this Stack Overflow question has a pretty cool and easy-to-understand CMake setup. It's worth a look.
Using variables from CMake in your code: Here's a quick and dirty example (adapted from some other tutorial):
simple/CMakeLists.txt:
project (Tutorial)
# Setting variables
set (Tutorial_VERSION_MAJOR 1)
set (Tutorial_VERSION_MINOR 1)
# Configure_file(<input> <output>)
# Copies a file <input> to file <output> and substitutes variable values referenced in the file content.
# So you can pass some CMake variables to the source code (in this case version numbers)
configure_file (
"${PROJECT_SOURCE_DIR}/TutorialConfig.h.in"
"${PROJECT_SOURCE_DIR}/src/TutorialConfig.h"
)
simple/TutorialConfig.h.in:
// Configured options and settings
#define Tutorial_VERSION_MAJOR #Tutorial_VERSION_MAJOR#
#define Tutorial_VERSION_MINOR #Tutorial_VERSION_MINOR#
The resulting file generated by CMake, simple/src/TutorialConfig.h:
// Configured options and settings
#define Tutorial_VERSION_MAJOR 1
#define Tutorial_VERSION_MINOR 1
With clever use of these you can do cool things like turning off a library and such. I do recommend taking a look at that tutorial as there are some slightly more advanced things that are bound to be very useful on larger projects, sooner or later.
For everything else, Stack Overflow is brimming with specific questions and concise answers, which is great for everyone except the uninitiated.