I have embedded project using cross compiler. I would like to introduce Google test, compiled with native GCC compiler. Additionally build some unit test targets with CTC compiler.
Briefly:
I have 3 different targets and compile them with 3 different compilers. How to express it in CMakeLists.txt? I Tried SET_TARGET_PROPERTIES;
but it seems impossible to set CXX variable with this command!
I just had the same issue right now, but the other answer didn't help me. I'm also cross-compiling, and I need some utility programs to be compiled with GCC, but my core code to be compiled with avr-gcc.
Basically, if you have a CMakeLists.txt, and you want all targets in this file to be compiled with another compiler, you can just set the variables by hand.
Define these macros somewhere:
macro(use_host_compiler)
if (${CURRENT_COMPILER} STREQUAL "NATIVE")
# Save current native flags
set(NATIVE_C_FLAGS ${CMAKE_C_FLAGS} CACHE STRING "GCC flags for the native compiler." FORCE)
# Change compiler
set(CMAKE_SYSTEM_NAME ${CMAKE_HOST_SYSTEM_NAME})
set(CMAKE_SYSTEM_PROCESSOR ${CMAKE_HOST_SYSTEM_PROCESSOR})
set(CMAKE_C_COMPILER ${HOST_C_COMPILER})
set(CMAKE_C_FLAGS ${HOST_C_FLAGS})
set(CURRENT_COMPILER "HOST" CACHE STRING "Which compiler we are using." FORCE)
endif()
endmacro()
macro(use_native_compiler)
if (CMAKE_CROSSCOMPILING AND ${CURRENT_COMPILER} STREQUAL "HOST")
# Save current host flags
set(HOST_C_FLAGS ${CMAKE_C_FLAGS} CACHE STRING "GCC flags for the host compiler." FORCE)
# Change compiler
set(CMAKE_SYSTEM_NAME ${NATIVE_SYSTEM_NAME})
set(CMAKE_SYSTEM_PROCESSOR ${NATIVE_SYSTEM_PROCESSOR})
set(CMAKE_C_COMPILER ${NATIVE_C_COMPILER})
set(CMAKE_C_FLAGS ${NATIVE_C_FLAGS})
set(CURRENT_COMPILER "NATIVE" CACHE STRING "Which compiler we are using." FORCE)
endif()
endmacro()
At the very beginning of your CMakeLists.txt script (or in a toolchain file), set the following variables according to what you need:
CURRENT_COMPILER
HOST_C_COMPILER
HOST_C_FLAGS
NATIVE_SYSTEM_NAME
NATIVE_C_COMPILER
NATIVE_C_FLAGS
The idea is that CMAKE_C_COMPILER (and company) is a variable like any other, so setting it inside a certain scope will only leave it changed within that scope.
Example usage:
use_host_compiler()
add_executable(foo foo.c) # Compiled with your host (computer)'s compiler.
use_native_compiler()
add_executable(bar bar.c) # Compiled with your native compiler (e.g. `avr-gcc`).
There is no proper way to change compiler for individual target.
According to cmake manual "Once set, you can not change this variable". This is about CMAKE_<LANG>_COMPILER.
The solution suggested by AnthonyD973 does not seem to work, which is sad of course. The ability to use several compilers in a project without custom_command things is very useful.
One solution (that I haven't tried yet) is to use
set_target_properties(your_target CXX_COMPILER_LAUNCHER foo_wrapper)
Then make foo_wrapper a script that just drops the first argument (which will be the default compiler, e.g. c++) and then calls the compiler you want.
There's also CXX_LINKER_LAUNCHER and the same for C_....
CMake is a make file generator. It generates a file that you can then use to build. If you want to more than one target platform, you need to run CMake multiple times with different generators.
So what you want to do is not possible in CMake, but with CMake: You can create a shell script that invokes CMake multiple times.
Related
I would like to use the IAR compiler. I noticed CMake has already have a bunch of files about this compiler:
https://github.com/jevinskie/cmake/blob/master/Modules/Compiler/IAR.cmake
From what I read the common solution is to specify manually ALL the toolchain in my CMakeLists.txt:
set(CMAKE_C_COMPILER iccarm)
set(CMAKE_CPP_COMPILER iccarm)
How CMake can link these definitions with `Modules/Compiler/IAR.cmake"?
I thought I would just have to do
include("Modules/Compiler/IAR.cmake")
What is the correct way to specify my IAR compiler?
When I do
cmake .
It still tries to use gcc instead of my IAR compiler. Why?
To select a specific compiler, you have several solutions, as exaplained in CMake wiki:
Method 1: use environment variables
For C and C++, set the CC and CXX environment variables. This method is not guaranteed to work for all generators. (Specifically, if you are trying to set Xcode's GCC_VERSION, this method confuses Xcode.)
For example:
CC=gcc-4.2 CXX=/usr/bin/g++-4.2 cmake -G "Your Generator" path/to/your/source
Method 2: use cmake -D
Set the appropriate CMAKE_FOO_COMPILER variable(s) to a valid compiler name or full path on the command-line using cmake -D.
For example:
cmake -G "Your Generator" -D CMAKE_C_COMPILER=gcc-4.2 -D CMAKE_CXX_COMPILER=g++-4.2 path/to/your/source
Method 3 (avoid): use set()
Set the appropriate CMAKE_FOO_COMPILER variable(s) to a valid compiler name or full path in a list file using set(). This must be done before any language is set (ie: before any project() or enable_language() command).
For example:
set(CMAKE_C_COMPILER "gcc-4.2")
set(CMAKE_CXX_COMPILER "/usr/bin/g++-4.2")
project("YourProjectName")
The wiki doesn't provide reason why 3rd method should be avoided...
I see more and more people who set CMAKE_C_COMPILER and other compiler-related variables in the CMakeLists.txt after the project call and wonder why this approach breaks sometimes.
What happens actually
When CMake executes the project() call, it looks for a default compiler executable and determines the way for use it: default compiler flags, default linker flags, compile features, etc.
And CMake stores path to that default compiler executable in the CMAKE_C_COMPILER variable.
When one sets CMAKE_C_COMPILER variable after the project() call, this only changes the compiler executable: default flags, features all remains set for the default compiler.
AS RESULT: When the project is built, a build system calls the project-specified compiler executable but with parameters suitable for the default compiler.
As one could guess, this approach would work only when one replaces a default compiler with a highly compatible one. E.g. replacement of gcc with clang could work sometimes.
This approach will never work for replacement of cl compiler (used in Visual Studio) with gcc one. Nor this will work when replacing a native compiler with a cross-compiler.
What to do
Never set a compiler in CMakeLists.txt.
If you want, e.g., to use clang instead of defaulted gcc, then either:
Pass -DCMAKE_C_COMPILER=<compiler> to cmake when configure the project. That way CMake will use this compiler instead of default one and on the project() call it will adjust all flags for the specified compiler.
Set CC environment variable (CXX for C++ compiler). CMake checks this variable when selects a default compiler.
(Only in rare cases) Set CMAKE_C_COMPILER variable before the project() call. This approach is similar to the first one, but makes the project less flexible.
If the ways above do not work
If on setting CMAKE_C_COMPILER in the command line CMake errors that a compiler cannot "compile a simple project", then something wrong in your environment.. or you specify a compiler incompatible for chosen generator or platform.
Examples:
Visual Studio generators work with cl compiler but cannot work with gcc.
A MinGW compiler usually requires MinGW Makefiles generator.
Incompatible generator cannot be fixed in CMakeLists.txt. One need to pass the proper -G option to the cmake executable (or select the proper generator in CMake GUI).
Cross-compiling
Cross-compiling usually requires setting CMAKE_SYSTEM_NAME variable, and this setting should normally be done in the toolchain file. That toolchain file is also responsible for set a compiler.
Setting CMAKE_SYSTEM_NAME in the CMakeLists.txt is almost always an error.
You need to create a toolchain file, and use the CmakeForceCompiler module.
Here is an example toolchain file for bare-metal ARM development with IAR:
include(CMakeForceCompiler)
set(CMAKE_SYSTEM_NAME Generic) # Or name of your OS if you have one
set(CMAKE_SYSTEM_PROCESSOR arm) # Or whatever
set(CMAKE_CROSSCOMPILING 1)
set(CMAKE_C_COMPILER iccarm) # Change the arm suffix if appropriate
set(CMAKE_TRY_COMPILE_TARGET_TYPE STATIC_LIBRARY) # Required to make the previous line work for a target that requires a custom linker file
The last line is necessary because CMake will try to compile a test program with the compiler to make sure it works and to get some version information from preprocessor defines. Without this line, CMake will use add_executable() for the test program, and you will get the error "The C compiler "XXX" is not able to compile a simple test program." This is because the test program fails to link, as it doesn't have your custom linker file (I'm assuming bare-metal development since this is what IAR is usually used for). This line tells CMake to use add_library() instead, which makes the test succeed without the linker file. Source of this workaround: this CMake mailing list post.
Then, assuming that your toolchain file is named iar-toolchain.cmake, invoke CMake like this:
cmake -DCMAKE_TOOLCHAIN_FILE=iar-toolchain.cmake .
You can call cmake like this:
cmake -DCMAKE_C_COMPILER=iccarm ...
or
cmake -DCMAKE_CXX_COMPILER=...
If you don't want to use your PC's standard compiler, you have to give CMake the path to the compiler. You do this via environment variables, a toolchain file or direct definitions in the CMake command line (see e.g. CMake Error at CMakeLists.txt:30 (project): No CMAKE_C_COMPILER could be found).
Putting the compiler's name/path into your CMakeLists.txt would stop your project from being cross-platform.
CMake does check for the compiler ids by compiling special C/C++ files. So no need to manually include from Module/Compiler or Module/Platform.
This will be automatically done by CMake based on its compiler and platform checks.
References
CMake: In which Order are Files parsed (Cache, Toolchain, …)?
CMake GitLab Commit: Add support files for C, C++ and ASM for the IAR toolchain.
IAR Systems recently published a basic CMake tutorial with examples under their GitHub profile.
I like the the idea of a generic toolchain file which works seamlessly for both Windows and Linux compilers using find_program().
The following snippet will be used for when using C and can be used similarly for CXX:
# IAR C Compiler
find_program(CMAKE_C_COMPILER
NAMES icc${CMAKE_SYSTEM_PROCESSOR}
PATHS ${TOOLKIT}
"$ENV{ProgramFiles}/IAR Systems/*"
"$ENV{ProgramFiles\(x86\)}/IAR Systems/*"
/opt/iarsystems/bx${CMAKE_SYSTEM_PROCESSOR}
PATH_SUFFIXES bin ${CMAKE_SYSTEM_PROCESSOR}/bin
REQUIRED )
For ASM, I initially got puzzled with the NAMES but then I realized that the toolchain file was made that way for working with old Assemblers shipped with XLINK:
find_program(CMAKE_ASM_COMPILER
NAMES iasm${CMAKE_SYSTEM_PROCESSOR} a${CMAKE_SYSTEM_PROCESSOR}
PATHS ${TOOLKIT}
"$ENV{PROGRAMFILES}/IAR Systems/*"
"$ENV{ProgramFiles\(x86\)}/IAR Systems/*"
/opt/iarsystems/bx${CMAKE_SYSTEM_PROCESSOR}
PATH_SUFFIXES bin ${CMAKE_SYSTEM_PROCESSOR}/bin
REQUIRED )
Also, take a look at the full toolchain file. It will work automatically for "Arm" when the tools are installed on their default locations, otherwise it is just about updating the TOOLKIT variable and the compilers for all the supported languages should adjust automatically.
If your wanting to specify a compiler in cmake then just do ...
cmake_minimum_required(VERSION 3.22)
set(CMAKE_C_COMPILER "clang")
set(CMAKE_CXX_COMPILER "clang++")
Options 1 is only used if you want to specify what compiler you want to use as default for everything that you might compile on your computer. And I don't even think it would work on windows.
Option 2 would be used if you only want to use a different temporarily.
Option 3 is used if that's the compiler that should be used for that particular project. Also option 3 would be the most cross compatible.
I would like to use the IAR compiler. I noticed CMake has already have a bunch of files about this compiler:
https://github.com/jevinskie/cmake/blob/master/Modules/Compiler/IAR.cmake
From what I read the common solution is to specify manually ALL the toolchain in my CMakeLists.txt:
set(CMAKE_C_COMPILER iccarm)
set(CMAKE_CPP_COMPILER iccarm)
How CMake can link these definitions with `Modules/Compiler/IAR.cmake"?
I thought I would just have to do
include("Modules/Compiler/IAR.cmake")
What is the correct way to specify my IAR compiler?
When I do
cmake .
It still tries to use gcc instead of my IAR compiler. Why?
To select a specific compiler, you have several solutions, as exaplained in CMake wiki:
Method 1: use environment variables
For C and C++, set the CC and CXX environment variables. This method is not guaranteed to work for all generators. (Specifically, if you are trying to set Xcode's GCC_VERSION, this method confuses Xcode.)
For example:
CC=gcc-4.2 CXX=/usr/bin/g++-4.2 cmake -G "Your Generator" path/to/your/source
Method 2: use cmake -D
Set the appropriate CMAKE_FOO_COMPILER variable(s) to a valid compiler name or full path on the command-line using cmake -D.
For example:
cmake -G "Your Generator" -D CMAKE_C_COMPILER=gcc-4.2 -D CMAKE_CXX_COMPILER=g++-4.2 path/to/your/source
Method 3 (avoid): use set()
Set the appropriate CMAKE_FOO_COMPILER variable(s) to a valid compiler name or full path in a list file using set(). This must be done before any language is set (ie: before any project() or enable_language() command).
For example:
set(CMAKE_C_COMPILER "gcc-4.2")
set(CMAKE_CXX_COMPILER "/usr/bin/g++-4.2")
project("YourProjectName")
The wiki doesn't provide reason why 3rd method should be avoided...
I see more and more people who set CMAKE_C_COMPILER and other compiler-related variables in the CMakeLists.txt after the project call and wonder why this approach breaks sometimes.
What happens actually
When CMake executes the project() call, it looks for a default compiler executable and determines the way for use it: default compiler flags, default linker flags, compile features, etc.
And CMake stores path to that default compiler executable in the CMAKE_C_COMPILER variable.
When one sets CMAKE_C_COMPILER variable after the project() call, this only changes the compiler executable: default flags, features all remains set for the default compiler.
AS RESULT: When the project is built, a build system calls the project-specified compiler executable but with parameters suitable for the default compiler.
As one could guess, this approach would work only when one replaces a default compiler with a highly compatible one. E.g. replacement of gcc with clang could work sometimes.
This approach will never work for replacement of cl compiler (used in Visual Studio) with gcc one. Nor this will work when replacing a native compiler with a cross-compiler.
What to do
Never set a compiler in CMakeLists.txt.
If you want, e.g., to use clang instead of defaulted gcc, then either:
Pass -DCMAKE_C_COMPILER=<compiler> to cmake when configure the project. That way CMake will use this compiler instead of default one and on the project() call it will adjust all flags for the specified compiler.
Set CC environment variable (CXX for C++ compiler). CMake checks this variable when selects a default compiler.
(Only in rare cases) Set CMAKE_C_COMPILER variable before the project() call. This approach is similar to the first one, but makes the project less flexible.
If the ways above do not work
If on setting CMAKE_C_COMPILER in the command line CMake errors that a compiler cannot "compile a simple project", then something wrong in your environment.. or you specify a compiler incompatible for chosen generator or platform.
Examples:
Visual Studio generators work with cl compiler but cannot work with gcc.
A MinGW compiler usually requires MinGW Makefiles generator.
Incompatible generator cannot be fixed in CMakeLists.txt. One need to pass the proper -G option to the cmake executable (or select the proper generator in CMake GUI).
Cross-compiling
Cross-compiling usually requires setting CMAKE_SYSTEM_NAME variable, and this setting should normally be done in the toolchain file. That toolchain file is also responsible for set a compiler.
Setting CMAKE_SYSTEM_NAME in the CMakeLists.txt is almost always an error.
You need to create a toolchain file, and use the CmakeForceCompiler module.
Here is an example toolchain file for bare-metal ARM development with IAR:
include(CMakeForceCompiler)
set(CMAKE_SYSTEM_NAME Generic) # Or name of your OS if you have one
set(CMAKE_SYSTEM_PROCESSOR arm) # Or whatever
set(CMAKE_CROSSCOMPILING 1)
set(CMAKE_C_COMPILER iccarm) # Change the arm suffix if appropriate
set(CMAKE_TRY_COMPILE_TARGET_TYPE STATIC_LIBRARY) # Required to make the previous line work for a target that requires a custom linker file
The last line is necessary because CMake will try to compile a test program with the compiler to make sure it works and to get some version information from preprocessor defines. Without this line, CMake will use add_executable() for the test program, and you will get the error "The C compiler "XXX" is not able to compile a simple test program." This is because the test program fails to link, as it doesn't have your custom linker file (I'm assuming bare-metal development since this is what IAR is usually used for). This line tells CMake to use add_library() instead, which makes the test succeed without the linker file. Source of this workaround: this CMake mailing list post.
Then, assuming that your toolchain file is named iar-toolchain.cmake, invoke CMake like this:
cmake -DCMAKE_TOOLCHAIN_FILE=iar-toolchain.cmake .
You can call cmake like this:
cmake -DCMAKE_C_COMPILER=iccarm ...
or
cmake -DCMAKE_CXX_COMPILER=...
If you don't want to use your PC's standard compiler, you have to give CMake the path to the compiler. You do this via environment variables, a toolchain file or direct definitions in the CMake command line (see e.g. CMake Error at CMakeLists.txt:30 (project): No CMAKE_C_COMPILER could be found).
Putting the compiler's name/path into your CMakeLists.txt would stop your project from being cross-platform.
CMake does check for the compiler ids by compiling special C/C++ files. So no need to manually include from Module/Compiler or Module/Platform.
This will be automatically done by CMake based on its compiler and platform checks.
References
CMake: In which Order are Files parsed (Cache, Toolchain, …)?
CMake GitLab Commit: Add support files for C, C++ and ASM for the IAR toolchain.
IAR Systems recently published a basic CMake tutorial with examples under their GitHub profile.
I like the the idea of a generic toolchain file which works seamlessly for both Windows and Linux compilers using find_program().
The following snippet will be used for when using C and can be used similarly for CXX:
# IAR C Compiler
find_program(CMAKE_C_COMPILER
NAMES icc${CMAKE_SYSTEM_PROCESSOR}
PATHS ${TOOLKIT}
"$ENV{ProgramFiles}/IAR Systems/*"
"$ENV{ProgramFiles\(x86\)}/IAR Systems/*"
/opt/iarsystems/bx${CMAKE_SYSTEM_PROCESSOR}
PATH_SUFFIXES bin ${CMAKE_SYSTEM_PROCESSOR}/bin
REQUIRED )
For ASM, I initially got puzzled with the NAMES but then I realized that the toolchain file was made that way for working with old Assemblers shipped with XLINK:
find_program(CMAKE_ASM_COMPILER
NAMES iasm${CMAKE_SYSTEM_PROCESSOR} a${CMAKE_SYSTEM_PROCESSOR}
PATHS ${TOOLKIT}
"$ENV{PROGRAMFILES}/IAR Systems/*"
"$ENV{ProgramFiles\(x86\)}/IAR Systems/*"
/opt/iarsystems/bx${CMAKE_SYSTEM_PROCESSOR}
PATH_SUFFIXES bin ${CMAKE_SYSTEM_PROCESSOR}/bin
REQUIRED )
Also, take a look at the full toolchain file. It will work automatically for "Arm" when the tools are installed on their default locations, otherwise it is just about updating the TOOLKIT variable and the compilers for all the supported languages should adjust automatically.
If your wanting to specify a compiler in cmake then just do ...
cmake_minimum_required(VERSION 3.22)
set(CMAKE_C_COMPILER "clang")
set(CMAKE_CXX_COMPILER "clang++")
Options 1 is only used if you want to specify what compiler you want to use as default for everything that you might compile on your computer. And I don't even think it would work on windows.
Option 2 would be used if you only want to use a different temporarily.
Option 3 is used if that's the compiler that should be used for that particular project. Also option 3 would be the most cross compatible.
The Cmake FAQ
and
other
places
recommend to check CMAKE_CONFIGURATION_TYPES to recognize a multi-configuration generator. I have found several questions where this did not work (for example this one). The issue seems to be that the variable is not set the first time cmake is called.
I tested with the following file
cmake_minimum_required(VERSION 2.6)
if(CMAKE_CONFIGURATION_TYPES)
message("Multi-configuration generator")
else()
message("Single-configuration generator")
endif()
project(foo)
and called it like this
mkdir build
cd build
cmake -G "Visual Studio 12 2013" ..
and got Single-configuration generator.
How should I distinguish whether the current generator supports multiple configurations?
EDITED: Added information on checking and changing CMAKE_CONFIGURATION_TYPES
Check and Changing CMAKE_CONFIGURATION_TYPES
Taking the suggestions from this question you could check and change CMAKE_CONFIGURATION_TYPES, but be aware that there was a bug 0015577: The 'project' command overwrites CMAKE_CONFIGURATION_TYPES in CMake 3.2.2 that did break this behaviour for the initial VS solution generation (fixed with CMake 3.3.0):
cmake_minimum_required(VERSION 3.3)
project(foo NONE)
if(CMAKE_CONFIGURATION_TYPES)
message("Multi-configuration generator")
set(CMAKE_CONFIGURATION_TYPES "Debug;Release" CACHE STRING "My multi config types" FORCE)
else()
message("Single-configuration generator")
endif()
enable_language(C CXX)
Preset CMAKE_CONFIGURATION_TYPES
If you just need a certain set of configurations for multi-configuration environments you can do (thanks to #Tsyvarev for the suggestion):
cmake_minimum_required(VERSION 2.8)
# NOTE: Only used in multi-configuration environments
set(CMAKE_CONFIGURATION_TYPES "Debug;Release" CACHE STRING "My multi config types" FORCE)
project(foo)
None multi-configuration environments will just ignore it. But be aware that other CMake modules like findBoost.cmake, findCUDA.cmake may rely on CMAKE_CONFIGURATION_TYPES being empty for single-configuration environments (thanks again #Tsyvarev for the hint).
So a better solution would be adding toolchain files for all your supported generators. They are generally useful, because there you can handle all the toolchain/generator specific parts.
Here is an extract of my VSToolchain.txt:
# Reduce the config types to only Debug and Release
SET(CMAKE_CONFIGURATION_TYPES "Debug;Release" CACHE STRING "" FORCE)
# Standard is a console app. If you need a windows app, use WIN32 define in add_executable
set(CMAKE_WIN32_EXECUTABLE 0 CACHE INTERNAL "")
CMAKE_WIN32_EXECUTABLE is just there to show what kind of settings I have put in my Visual Studio toolchain file.
Another CMake command line solution is suggested here: How to create cmake build configuration without debug symbols and without optimizations?
Only Checking CMAKE_CONFIGURATION_TYPES
If you only want do check what CMake does set in CMAKE_CONFIGURATION_TYPES:
I just tested your above code with Visual Studio 2013 and MinGW/GCC (both with empty build directories). You just need one small change and move the check after the project() command:
project(foo)
message("CMAKE_CONFIGURATION_TYPES ${CMAKE_CONFIGURATION_TYPES}")
if(CMAKE_CONFIGURATION_TYPES)
message("Multi-configuration generator")
else()
message("Single-configuration generator")
endif()
And I get for VS2013:
CMAKE_CONFIGURATION_TYPES Debug;Release;MinSizeRel;RelWithDebInfo
Multi-configuration generator
And for GCC:
CMAKE_CONFIGURATION_TYPES
Single-configuration generator
For more details about what CMake does see:
CMAKE_CONFIGURATION_TYPES set by EnableLanguage() in cmGlobalVisualStudio7Generator.cxx
CMake: In which Order are Files parsed (Cache, Toolchain, …)?
I see you are on CMake v2.6, but for anyone who is on v3.9+, v3.9 introduced the global property called GENERATOR_IS_MULTI_CONFIG:
Read-only property that is true on multi-configuration generators.
You can load the value into a CMake variable like so:
get_property(is_multi_config GLOBAL PROPERTY GENERATOR_IS_MULTI_CONFIG)
This very approach is recommended in "Professional CMake" by Craig Scott, along with explanations of the shortcomings of other approaches- especially those involving CMAKE_CONFIGURATION_TYPES. The book is $30 but the section I'm referring to is in the sample chapters.
I have embedded project using cross compiler. I would like to introduce Google test, compiled with native GCC compiler. Additionally build some unit test targets with CTC compiler.
Briefly:
I have 3 different targets and compile them with 3 different compilers. How to express it in CMakeLists.txt? I Tried SET_TARGET_PROPERTIES;
but it seems impossible to set CXX variable with this command!
I just had the same issue right now, but the other answer didn't help me. I'm also cross-compiling, and I need some utility programs to be compiled with GCC, but my core code to be compiled with avr-gcc.
Basically, if you have a CMakeLists.txt, and you want all targets in this file to be compiled with another compiler, you can just set the variables by hand.
Define these macros somewhere:
macro(use_host_compiler)
if (${CURRENT_COMPILER} STREQUAL "NATIVE")
# Save current native flags
set(NATIVE_C_FLAGS ${CMAKE_C_FLAGS} CACHE STRING "GCC flags for the native compiler." FORCE)
# Change compiler
set(CMAKE_SYSTEM_NAME ${CMAKE_HOST_SYSTEM_NAME})
set(CMAKE_SYSTEM_PROCESSOR ${CMAKE_HOST_SYSTEM_PROCESSOR})
set(CMAKE_C_COMPILER ${HOST_C_COMPILER})
set(CMAKE_C_FLAGS ${HOST_C_FLAGS})
set(CURRENT_COMPILER "HOST" CACHE STRING "Which compiler we are using." FORCE)
endif()
endmacro()
macro(use_native_compiler)
if (CMAKE_CROSSCOMPILING AND ${CURRENT_COMPILER} STREQUAL "HOST")
# Save current host flags
set(HOST_C_FLAGS ${CMAKE_C_FLAGS} CACHE STRING "GCC flags for the host compiler." FORCE)
# Change compiler
set(CMAKE_SYSTEM_NAME ${NATIVE_SYSTEM_NAME})
set(CMAKE_SYSTEM_PROCESSOR ${NATIVE_SYSTEM_PROCESSOR})
set(CMAKE_C_COMPILER ${NATIVE_C_COMPILER})
set(CMAKE_C_FLAGS ${NATIVE_C_FLAGS})
set(CURRENT_COMPILER "NATIVE" CACHE STRING "Which compiler we are using." FORCE)
endif()
endmacro()
At the very beginning of your CMakeLists.txt script (or in a toolchain file), set the following variables according to what you need:
CURRENT_COMPILER
HOST_C_COMPILER
HOST_C_FLAGS
NATIVE_SYSTEM_NAME
NATIVE_C_COMPILER
NATIVE_C_FLAGS
The idea is that CMAKE_C_COMPILER (and company) is a variable like any other, so setting it inside a certain scope will only leave it changed within that scope.
Example usage:
use_host_compiler()
add_executable(foo foo.c) # Compiled with your host (computer)'s compiler.
use_native_compiler()
add_executable(bar bar.c) # Compiled with your native compiler (e.g. `avr-gcc`).
There is no proper way to change compiler for individual target.
According to cmake manual "Once set, you can not change this variable". This is about CMAKE_<LANG>_COMPILER.
The solution suggested by AnthonyD973 does not seem to work, which is sad of course. The ability to use several compilers in a project without custom_command things is very useful.
One solution (that I haven't tried yet) is to use
set_target_properties(your_target CXX_COMPILER_LAUNCHER foo_wrapper)
Then make foo_wrapper a script that just drops the first argument (which will be the default compiler, e.g. c++) and then calls the compiler you want.
There's also CXX_LINKER_LAUNCHER and the same for C_....
CMake is a make file generator. It generates a file that you can then use to build. If you want to more than one target platform, you need to run CMake multiple times with different generators.
So what you want to do is not possible in CMake, but with CMake: You can create a shell script that invokes CMake multiple times.
Visual Studio C++ 2008 / GCC 4.4.2
I have written a program to run on Linux and now I have to port my code to run on Windows. I have decided to use CMake as I want to keep the same build system for both platforms.
However, I need to link with some libraries for both platforms. In my CMakeLists.txt I have the following:
# Compile with gcc c89 standard
IF(CMAKE_COMPILER_IS_GNUCXX)
MESSAGE(STATUS "GCC detected - Adding compiler flags")
SET(CMAKE_C_FLAGS "-pthread -ggdb -Wextra -Wall -pedantic -std=c89")
ENDIF(CMAKE_COMPILER_IS_GNUCXX)
IF(WIN32)
SET(CMAKE_C_FLAGS "ws2_32.lib")
ENDIF(WIN32)
However, when I compile on Visual Studio I get the following error:
fatal error C1083: Cannot open source file: 'ws2_32.lib': No such file or directory
What can I do to resolve this problem?
========= Edit
In the top level directory
# Project Client Server
CMAKE_MINIMUM_REQUIRED(VERSION 2.6)
# Name of project
PROJECT(CLIENT_SERVER)
# Compile with gcc c89 standard
IF(CMAKE_COMPILER_IS_GNUCXX)
MESSAGE(STATUS "GCC detected - Adding compiler flags")
SET(CMAKE_C_FLAGS "-pthread -ggdb -Wextra -Wall -pedantic -std=c89")
ENDIF(CMAKE_COMPILER_IS_GNUCXX)
IF(WIN32)
SET(CMAKE_C_FLAGS "ws2_32")
ENDIF(WIN32)
# Includes
INCLUDE_DIRECTORIES(${CLIENT_SERVER_SOURCE_DIR}/cltsvr_ults)
INCLUDE_DIRECTORIES(${CLIENT_SERVER_SOURCE_DIR}/server)
INCLUDE_DIRECTORIES(${CLIENT_SERVER_SOURCE_DIR}/client)
# libraries
LINK_DIRECTORIES($CLIENT_SERVER/cltsvr_ults)
# Add subdirectories
ADD_SUBDIRECTORY(client)
ADD_SUBDIRECTORY(server)
ADD_SUBDIRECTORY(cltsvr_ults)
ADD_SUBDIRECTORY(test_client)
ADD_SUBDIRECTORY(test_server)
In the subdirectory of client I have this CMakeLists.txt
# libray called client from client.c
ADD_LIBRARY(client client)
And in the subdirectory of test_clt where I create and link my executable.
# Test client add executable
INCLUDE_DIRECTORIES($CLIENT_SERVER_SOURCE_DIR/client)
INCLUDE_DIRECTORIES($CLIENT_SERVER_SOURCE_DIR/cltsvr_ults)
# Link the library
LINK_DIRECTORIES($CLIENT_SERVER/client)
# Add the executable
ADD_EXECUTABLE(clt test_clt)
# Link the executable to the client library
IF(WIN32)
TARGET_LINK_LIBRARIES(clt client ws2_32)
ENDIF(WIN32)
Disclaimer: My answer is of philosophical nature which should encourage you to avoid touching CMAKE_C_FLAGS directly. For the direct answer that just solves your problem look what Bill ( the lead architect of the CMake btw. ) wrote.
The thing about CMake is, that it lets you describe what you want to do without referring to a specific compiler or platform. What CMake does is building the compiler and linker flags from your usage of
include_directories
add_definitions
add_library
add_executable
target_link_libraries
If there are no external dependencies, other than the compiler itself, this is all you need. For external dependencies use
find_package
It defines a set of variables, like
find_package(SDL)
defines
SDL_INCLUDE_DIR
SDL_LIBRARY
for usage with respectively include_directories and target_link_libraries. CMake ships with a bunch of so called module files, like FindSDL.cmake and many others can be googled.
The next lower level is to use
find_path
find_library
which are used in the Find???.cmake modules itself.
The CMAKE_C_FLAGS variable is composed by CMake from these commands. Modifying it means you bypass CMake. There are cases, like for special optimization flags, you want to do this, but at this point all power and thus responsibility transfered from CMake to you.
By adding ws2_32.lib to the C_FLAGS, you are using it at compile time, and not link time. If you look at the error message, you can see it it treating the file as if it were a c++ source file: Cannot open source file: 'ws2_32.lib'. target_link_libraries(target ws2_32) should work.
You need to use the Target Link Libraries command. The target would be the executable you're building.
EDIT: You shouldn't specify the libs you're linking against in C_FLAGS. You can do something like TARGET_LINK_LIBRARIES(execName, ws_32, ...). I'm not 100% sure if you need the .lib. Been a while since I used CMake.