ITK/Cross Compiling: Difference between revisions
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* Target System = Windows | * Target System = Windows | ||
* Build System = Linux | * Build System = Linux | ||
''Note:'' the [http://mxe.cc/ MXE] project has an ITK package! Just | |||
cd mxe | |||
make itk | |||
== Major steps == | == Major steps == | ||
Line 101: | Line 109: | ||
=== Building the ToolChain for Windows === | === Building the ToolChain for Windows === | ||
The | The [http://mxe.cc/ MXE] project will build the toolchain nicely, and it even creates a CMake toolchain file. | ||
The following is a script developed by Johannes Schindelin (originally intended for [http://pacific.mpi-cbg.de/wiki/index.php/Fiji FIJI]). | |||
[[Media:Build-windows-cross-compiler.sh.gz|Script for Building the Windows (MinGW) Toolchain in Linux]] | [[Media:Build-windows-cross-compiler.sh.gz|Script for Building the Windows (MinGW) Toolchain in Linux]] | ||
=== Gathering Configuration settings in the target system === | |||
Following the advice of the CMake Wiki [http://www.cmake.org/Wiki/CMake_Cross_Compiling], put the following in a file called ToolChain.cmake | |||
# this one is important | |||
SET(CMAKE_SYSTEM_NAME Linux) | |||
#this one not so much | |||
SET(CMAKE_SYSTEM_VERSION 1) | |||
# specify the cross compiler | |||
SET(CMAKE_C_COMPILER /usr/bin/gcc) | |||
SET(CMAKE_CXX_COMPILER /usr/bin/g++) | |||
# where is the target environment | |||
SET(CMAKE_FIND_ROOT_PATH /usr) | |||
# search for programs in the build host directories | |||
SET(CMAKE_FIND_ROOT_PATH_MODE_PROGRAM NEVER) | |||
# for libraries and headers in the target directories | |||
SET(CMAKE_FIND_ROOT_PATH_MODE_LIBRARY ONLY) | |||
SET(CMAKE_FIND_ROOT_PATH_MODE_INCLUDE ONLY) | |||
Note that if you are using MXE, it already comes with a toolchain file at | |||
mxe/usr/i686-pc-mingw32/share/cmake/mxe-conf.cmake | |||
Run CMake using the command (in an empty directory) | |||
cmake -DCMAKE_TOOLCHAIN_FILE=./ToolChain.cmake ~/src/ITK | |||
This will generate (among many other things) a File called | |||
TryRunResults.cmake | |||
The values to be put in this file can be taken from the CMakeCache.txt file of a native build in Windows. The CMakeCache.txt can be created by manually running a CMake configuration on Windows. Use [https://gist.github.com/thewtex/5931775 this script] to populate the TryRun results with the Windows CMakeCache.txt contents. | |||
=== Using the Configuration in the Host === | |||
Now that you have copied the TryRunResuls.cmake file to the host system, you can use it as an initial cache for configuring the build. | |||
Do the command in the build system. | |||
cmake -C ~/TryRunResults.cmake ~/src/ITK | |||
once the configuration is completed you can proceed to build ITK by simply typing | |||
make | |||
The build process will fail when trying to create the HDF5 library. | |||
[ 73%] Building C object Modules/ThirdParty/HDF5/src/itkhdf5/src/CMakeFiles/H5make_libsettings.dir/H5make_libsettings.c.obj | |||
Linking C executable ../../../../../../bin/H5make_libsettings.exe | |||
[ 73%] Built target H5make_libsettings | |||
Scanning dependencies of target H5detect | |||
[ 73%] Building C object Modules/ThirdParty/HDF5/src/itkhdf5/src/CMakeFiles/H5detect.dir/H5detect.c.obj | |||
Linking C executable ../../../../../../bin/H5detect.exe | |||
[ 73%] Built target H5detect | |||
[ 73%] Generating ../H5lib_settings.c | |||
/bin/sh: ../../../../../../bin/H5make_libsettings.exe: cannot execute binary file | |||
make[2]: *** [Modules/ThirdParty/HDF5/src/itkhdf5/H5lib_settings.c] Error 126 | |||
make[1]: *** [Modules/ThirdParty/HDF5/src/itkhdf5/src/CMakeFiles/itkhdf5.dir/all] Error 2 | |||
make: *** [all] Error 2 | |||
Copy the executables that were created on the host system, ''bin/H5detect.exe'' and ''bin/H5make_libsettings.exe'' to the Windows target and run them, | |||
H5detect > H5Tinit.c | |||
H5make_libsettings.exe > H5lib_settings.c | |||
Then copy the results *.c files to ''Modules/ThirdParty/HDF5/src/itkhdf5/'' in the host build tree. Restart the build, | |||
make | |||
= In Linux Host for ARM Target = | |||
In this particular case we illustrate | |||
* Target System = Raspberry Pi (ARMv6) | |||
* Build System = Linux (Ubuntu 12.10) | |||
== Major steps == | |||
# Build your tool chain in the build system | |||
#* This is the set of compiler and linker that must be build in the '''build''' system, but will know how to generate code for the Target system. | |||
#* In this case we use crosstool-ng to build the tool chain | |||
# Create a TryRun ... file in the '''native''' system | |||
#* This could be generated (as a skeleton) with the following commands | |||
=== Building the ToolChain for ARM === | |||
* The process is described in detail here: | |||
** http://www.kitware.com/blog/home/post/426 | |||
* based on the instructions from: | |||
** http://www.bootc.net/archives/2012/05/26/how-to-build-a-cross-compiler-for-your-raspberry-pi/ | |||
=== Gathering Configuration settings in the target system === | |||
Following the advice of the CMake Wiki [http://www.cmake.org/Wiki/CMake_Cross_Compiling] | |||
Put the following in a file called ToolChain.cmake | |||
# this one is important | |||
SET(CMAKE_SYSTEM_NAME Linux) | |||
#this one not so much | |||
SET(CMAKE_SYSTEM_VERSION 1) | |||
# specify the cross compiler | |||
SET(CMAKE_C_COMPILER | |||
/home/ibanez/local/x-tools/arm-unknown-linux-gnueabi/bin/arm-unknown-linux-gnueabi-gcc) | |||
SET(CMAKE_CXX_COMPILER | |||
/home/ibanez/local/x-tools/arm-unknown-linux-gnueabi/bin/arm-unknown-linux-gnueabi-g++) | |||
# where is the target environment | |||
SET(CMAKE_FIND_ROOT_PATH | |||
/home/ibanez/local/x-tools/arm-unknown-linux-gnueabi) | |||
# search for programs in the build host directories | |||
SET(CMAKE_FIND_ROOT_PATH_MODE_PROGRAM NEVER) | |||
# for libraries and headers in the target directories | |||
SET(CMAKE_FIND_ROOT_PATH_MODE_LIBRARY ONLY) | |||
SET(CMAKE_FIND_ROOT_PATH_MODE_INCLUDE ONLY) | |||
and run it with CMake using the command (in an empty directory) | |||
cmake -DCMAKE_TOOLCHAIN_FILE=./ToolChain.cmake ~/src/ITK | |||
This will generate (among many other things) a File called | |||
TryRunResults.cmake | |||
Then, manually populate, the values of each one of the fields. | |||
The values to be put in this file can be taken from the CMakeCache.txt file of a native build in the Raspberry Pi. | |||
For reference, | |||
* Here is a [[Media:CMakeCache_ITK_RaspberryPi.txt|CMakeCache.txt file]] from a native configuration in the Raspberry Pi. | |||
* Here is the corresponding [[Media:TryRunResults_ITK_RaspberryPi.cmake|TryRunResults.cmake file]] after updating values from the Raspberry Pi. | |||
=== Using the Configuration in the Host === | |||
Now that you have copied the TryRunResuls.cmake file to the host system, you can use it as an initial cache for configuring the build. | |||
Do the command in the build system. | |||
cmake -C ~/TryRunResults.cmake -DCMAKE_TOOLCHAIN_FILE=./ToolChain.cmake ~/src/ITK | |||
once the configuration is completed you can proceed to build ITK by simply typing | |||
make | |||
=== Dealing with TIFF bootstrapping === | |||
The build process of the TIFF library requires to first build an executable file called: | |||
* mkg3states (renamed as itkmkg3states in ITK) | |||
in order to generate a file called: | |||
* tif_fax2sm.c | |||
Since, during the cross-compilation process we generate executables that are for a different target architecture, the itkmkg3states file that we built, can't be run in the host to generate the tif_fax2sm.c file. | |||
One way around this is to build the executable for the architecture of the host (e.g. taking it from any other local build of ITK in the host), and use it to replace the itkmkg3states file. Then using it to generate the .c file. | |||
This can be done with the following commands: | |||
* cd ITK_CROSS_COMPILED_BINARY_DIR/Modules/ThirdParty/TIFF/src/itktiff | |||
* cp ITK_NATIVE_BINARY_DIR/Modules/ThirdParty/TIFF/src/itktiff/itkmkg3states . | |||
* ./itkmkg3states -c const ITK_CROSS_COMPILED_BINARY_DIR/Modules/ThirdParty/TIFF/src/itktiff/tif_fax3sm.c | |||
Then it is possible to continue with the "make" process. | |||
=== Packaging === | |||
Once the build finishes, we can package ITK with the command: | |||
* make package | |||
this will produce three files (that are independent of each other) | |||
* ITK-4.4.0-Linux.sh | |||
* ITK-4.4.0-Linux.tar.gz | |||
* ITK-4.4.0-Linux.tar.Z | |||
For example, copying the ITK-4.4.0-Linux.tar.gz file to the target, and expanding it there will provide a local installation of ITK against which it is possible to build ITK applications. | |||
=== Extra Links === | |||
* http://www.kitware.com/blog/home/post/422 | |||
* http://www.kitware.com/blog/home/post/426 | |||
* http://www.kitware.com/blog/home/post/428 |
Latest revision as of 20:45, 5 February 2018
This page is currently inactive and is retained for historical reference. Either the page is no longer relevant or consensus on its purpose has become unclear. To revive discussion, seek broader input via a forum such as the village pump. |
This page describes the procedure to follow when cross compiling ITK for another system.
In this page, we will refer to the system as:
- Target System: The system where the executables are intended to run.
- Build System: The system where the executables are built.
In Linux Host for Mac Target
In this particular case we illustrate
- Target System = Mac
- Build System = Linux
Major steps
- Build your tool chain in the build system
- This is the set of compiler and linker that must be build in the build system, but will know how to generate code for the Target system.
- Create a TryRun ... file in the native system
- This could be generated (as a skeleton) with the following commands
Building the ToolChain for Darwin
The following is a script developed by Johannes Schindelin (originally intended for FIJI)
Script for Building the Darwing Toolchain in Linux
Gathering Configuration settings in the target system
Following the advice of the CMake Wiki [1]
Put the following in a file called ToolChain.cmake
# this one is important SET(CMAKE_SYSTEM_NAME Linux) #this one not so much SET(CMAKE_SYSTEM_VERSION 1) # specify the cross compiler SET(CMAKE_C_COMPILER /usr/bin/gcc) SET(CMAKE_CXX_COMPILER /usr/bin/g++) # where is the target environment SET(CMAKE_FIND_ROOT_PATH /usr) # search for programs in the build host directories SET(CMAKE_FIND_ROOT_PATH_MODE_PROGRAM NEVER) # for libraries and headers in the target directories SET(CMAKE_FIND_ROOT_PATH_MODE_LIBRARY ONLY) SET(CMAKE_FIND_ROOT_PATH_MODE_INCLUDE ONLY)
and run it with CMake using the command (in an empty directory)
cmake -DCMAKE_TOOLCHAIN_FILE=./ToolChain.cmake ~/src/ITK
This will generate (among many other things) a File called
TryRunResults.cmake
Then, manually populate, the values of each one of the fields.
The values to be put in this file can be taken from the CMakeCache.txt file of a native build in Darwin.
Finally, copy this file to the build system.
Using the Configuration in the Host
Now that you have copied the TryRunResuls.cmake file to the host system, you can use it as an initial cache for configuring the build.
Do the command in the build system.
cmake -C ~/TryRunResults.cmake ~/src/ITK
once the configuration is completed you can proceed to build ITK by simply typing
make
The full process scripted
The process as a whole has been scripted in the file below
Script for configuring a cross-compilation build
Thanks to Johannes Schindelin for contributing the script.
In Linux Host for Windows Target
In this particular case we illustrate
- Target System = Windows
- Build System = Linux
Note: the MXE project has an ITK package! Just
cd mxe make itk
Major steps
- Build your tool chain in the build system
- This is the set of compiler and linker that must be build in the build system, but will know how to generate code for the Target system.
- In this case we use MinGW as the tool chain
- Create a TryRun ... file in the native system
- This could be generated (as a skeleton) with the following commands
Building the ToolChain for Windows
The MXE project will build the toolchain nicely, and it even creates a CMake toolchain file.
The following is a script developed by Johannes Schindelin (originally intended for FIJI). Script for Building the Windows (MinGW) Toolchain in Linux
Gathering Configuration settings in the target system
Following the advice of the CMake Wiki [2], put the following in a file called ToolChain.cmake
# this one is important SET(CMAKE_SYSTEM_NAME Linux) #this one not so much SET(CMAKE_SYSTEM_VERSION 1) # specify the cross compiler SET(CMAKE_C_COMPILER /usr/bin/gcc) SET(CMAKE_CXX_COMPILER /usr/bin/g++) # where is the target environment SET(CMAKE_FIND_ROOT_PATH /usr) # search for programs in the build host directories SET(CMAKE_FIND_ROOT_PATH_MODE_PROGRAM NEVER) # for libraries and headers in the target directories SET(CMAKE_FIND_ROOT_PATH_MODE_LIBRARY ONLY) SET(CMAKE_FIND_ROOT_PATH_MODE_INCLUDE ONLY)
Note that if you are using MXE, it already comes with a toolchain file at
mxe/usr/i686-pc-mingw32/share/cmake/mxe-conf.cmake
Run CMake using the command (in an empty directory)
cmake -DCMAKE_TOOLCHAIN_FILE=./ToolChain.cmake ~/src/ITK
This will generate (among many other things) a File called
TryRunResults.cmake
The values to be put in this file can be taken from the CMakeCache.txt file of a native build in Windows. The CMakeCache.txt can be created by manually running a CMake configuration on Windows. Use this script to populate the TryRun results with the Windows CMakeCache.txt contents.
Using the Configuration in the Host
Now that you have copied the TryRunResuls.cmake file to the host system, you can use it as an initial cache for configuring the build.
Do the command in the build system.
cmake -C ~/TryRunResults.cmake ~/src/ITK
once the configuration is completed you can proceed to build ITK by simply typing
make
The build process will fail when trying to create the HDF5 library.
[ 73%] Building C object Modules/ThirdParty/HDF5/src/itkhdf5/src/CMakeFiles/H5make_libsettings.dir/H5make_libsettings.c.obj Linking C executable ../../../../../../bin/H5make_libsettings.exe [ 73%] Built target H5make_libsettings Scanning dependencies of target H5detect [ 73%] Building C object Modules/ThirdParty/HDF5/src/itkhdf5/src/CMakeFiles/H5detect.dir/H5detect.c.obj Linking C executable ../../../../../../bin/H5detect.exe [ 73%] Built target H5detect [ 73%] Generating ../H5lib_settings.c /bin/sh: ../../../../../../bin/H5make_libsettings.exe: cannot execute binary file make[2]: *** [Modules/ThirdParty/HDF5/src/itkhdf5/H5lib_settings.c] Error 126 make[1]: *** [Modules/ThirdParty/HDF5/src/itkhdf5/src/CMakeFiles/itkhdf5.dir/all] Error 2 make: *** [all] Error 2
Copy the executables that were created on the host system, bin/H5detect.exe and bin/H5make_libsettings.exe to the Windows target and run them,
H5detect > H5Tinit.c H5make_libsettings.exe > H5lib_settings.c
Then copy the results *.c files to Modules/ThirdParty/HDF5/src/itkhdf5/ in the host build tree. Restart the build,
make
In Linux Host for ARM Target
In this particular case we illustrate
- Target System = Raspberry Pi (ARMv6)
- Build System = Linux (Ubuntu 12.10)
Major steps
- Build your tool chain in the build system
- This is the set of compiler and linker that must be build in the build system, but will know how to generate code for the Target system.
- In this case we use crosstool-ng to build the tool chain
- Create a TryRun ... file in the native system
- This could be generated (as a skeleton) with the following commands
Building the ToolChain for ARM
- The process is described in detail here:
- based on the instructions from:
Gathering Configuration settings in the target system
Following the advice of the CMake Wiki [3]
Put the following in a file called ToolChain.cmake
# this one is important SET(CMAKE_SYSTEM_NAME Linux) #this one not so much SET(CMAKE_SYSTEM_VERSION 1) # specify the cross compiler SET(CMAKE_C_COMPILER /home/ibanez/local/x-tools/arm-unknown-linux-gnueabi/bin/arm-unknown-linux-gnueabi-gcc) SET(CMAKE_CXX_COMPILER /home/ibanez/local/x-tools/arm-unknown-linux-gnueabi/bin/arm-unknown-linux-gnueabi-g++) # where is the target environment SET(CMAKE_FIND_ROOT_PATH /home/ibanez/local/x-tools/arm-unknown-linux-gnueabi) # search for programs in the build host directories SET(CMAKE_FIND_ROOT_PATH_MODE_PROGRAM NEVER) # for libraries and headers in the target directories SET(CMAKE_FIND_ROOT_PATH_MODE_LIBRARY ONLY) SET(CMAKE_FIND_ROOT_PATH_MODE_INCLUDE ONLY)
and run it with CMake using the command (in an empty directory)
cmake -DCMAKE_TOOLCHAIN_FILE=./ToolChain.cmake ~/src/ITK
This will generate (among many other things) a File called
TryRunResults.cmake
Then, manually populate, the values of each one of the fields.
The values to be put in this file can be taken from the CMakeCache.txt file of a native build in the Raspberry Pi.
For reference,
- Here is a CMakeCache.txt file from a native configuration in the Raspberry Pi.
- Here is the corresponding TryRunResults.cmake file after updating values from the Raspberry Pi.
Using the Configuration in the Host
Now that you have copied the TryRunResuls.cmake file to the host system, you can use it as an initial cache for configuring the build.
Do the command in the build system.
cmake -C ~/TryRunResults.cmake -DCMAKE_TOOLCHAIN_FILE=./ToolChain.cmake ~/src/ITK
once the configuration is completed you can proceed to build ITK by simply typing
make
Dealing with TIFF bootstrapping
The build process of the TIFF library requires to first build an executable file called:
- mkg3states (renamed as itkmkg3states in ITK)
in order to generate a file called:
- tif_fax2sm.c
Since, during the cross-compilation process we generate executables that are for a different target architecture, the itkmkg3states file that we built, can't be run in the host to generate the tif_fax2sm.c file.
One way around this is to build the executable for the architecture of the host (e.g. taking it from any other local build of ITK in the host), and use it to replace the itkmkg3states file. Then using it to generate the .c file.
This can be done with the following commands:
- cd ITK_CROSS_COMPILED_BINARY_DIR/Modules/ThirdParty/TIFF/src/itktiff
- cp ITK_NATIVE_BINARY_DIR/Modules/ThirdParty/TIFF/src/itktiff/itkmkg3states .
- ./itkmkg3states -c const ITK_CROSS_COMPILED_BINARY_DIR/Modules/ThirdParty/TIFF/src/itktiff/tif_fax3sm.c
Then it is possible to continue with the "make" process.
Packaging
Once the build finishes, we can package ITK with the command:
- make package
this will produce three files (that are independent of each other)
- ITK-4.4.0-Linux.sh
- ITK-4.4.0-Linux.tar.gz
- ITK-4.4.0-Linux.tar.Z
For example, copying the ITK-4.4.0-Linux.tar.gz file to the target, and expanding it there will provide a local installation of ITK against which it is possible to build ITK applications.