# Based on the Qt 5 processor detection code, so should be very accurate # http://code.qt.io/cgit/qt/qtbase.git/tree/src/corelib/global/qprocessordetection.h?h=5.8 # Currently handles arm (v5, v6, v7, v8), x86 (32/64), ia64, and ppc (32/64) # Regarding POWER/PowerPC, just as is noted in the Qt source, # "There are many more known variants/revisions that we do not handle/detect." set(archdetect_c_code " #if defined(__arm__) || defined(__TARGET_ARCH_ARM) || defined(_M_ARM) || defined(__aarch64__) # if defined(__ARM_ARCH) && __ARM_ARCH > 1 # define Q_PROCESSOR_ARM __ARM_ARCH # elif defined(__TARGET_ARCH_ARM) && __TARGET_ARCH_ARM > 1 # define Q_PROCESSOR_ARM __TARGET_ARCH_ARM # endif # if defined(__ARM64_ARCH_8__) || defined(__aarch64__) # define Q_PROCESSOR_ARM 8 # elif defined(__ARM_ARCH_7__) \\ || defined(__ARM_ARCH_7A__) \\ || defined(__ARM_ARCH_7R__) \\ || defined(__ARM_ARCH_7M__) \\ || (defined(__TARGET_ARCH_ARM) && __TARGET_ARCH_ARM-0 >= 7) # define Q_PROCESSOR_ARM 7 # elif defined(__ARM_ARCH_6__) \\ || defined(__ARM_ARCH_6J__) \\ || defined(__ARM_ARCH_6T2__) \\ || defined(__ARM_ARCH_6Z__) \\ || defined(__ARM_ARCH_6K__) \\ || defined(__ARM_ARCH_6ZK__) \\ || defined(__ARM_ARCH_6M__) \\ || (defined(__TARGET_ARCH_ARM) && __TARGET_ARCH_ARM-0 >= 6) # define Q_PROCESSOR_ARM 6 # elif defined(__ARM_ARCH_5TEJ__) \\ || (defined(__TARGET_ARCH_ARM) && __TARGET_ARCH_ARM-0 >= 5) # define define Q_PROCESSOR_ARM 5 # else # define Q_PROCESSOR_ARM 0 # endif # if Q_PROCESSOR_ARM == 8 # error cmake_ARCH armv8 # elif Q_PROCESSOR_ARM == 7 # error cmake_ARCH armv7 # elif Q_PROCESSOR_ARM == 6 # error cmake_ARCH armv6 # elif Q_PROCESSOR_ARM == 5 # error cmake_ARCH armv5 # else # error cmake_ARCH arm # endif #elif defined(__i386) || defined(__i386__) || defined(_M_IX86) # error cmake_ARCH i386 #elif defined(__x86_64) || defined(__x86_64__) || defined(__amd64) || defined(_M_X64) # error cmake_ARCH x86_64 #elif defined(__ia64) || defined(__ia64__) || defined(_M_IA64) # error cmake_ARCH ia64 #elif defined(__ppc__) || defined(__ppc) || defined(__powerpc__) \\ || defined(_ARCH_COM) || defined(_ARCH_PWR) || defined(_ARCH_PPC) \\ || defined(_M_MPPC) || defined(_M_PPC) # if defined(__ppc64__) || defined(__powerpc64__) || defined(__64BIT__) # error cmake_ARCH ppc64 # else # error cmake_ARCH ppc # endif #endif #error cmake_ARCH unknown ") # Set ppc_support to TRUE before including this file or ppc and ppc64 # will be treated as invalid architectures since they are no longer supported by Apple function(target_architecture output_var) if(APPLE AND CMAKE_OSX_ARCHITECTURES) # On OS X we use CMAKE_OSX_ARCHITECTURES *if* it was set # First let's normalize the order of the values # Note that it's not possible to compile PowerPC applications if you are using # the OS X SDK version 10.6 or later - you'll need 10.4/10.5 for that, so we # disable it by default # See this page for more information: # http://stackoverflow.com/questions/5333490/how-can-we-restore-ppc-ppc64-as-well-as-full-10-4-10-5-sdk-support-to-xcode-4 # Architecture defaults to i386 or ppc on OS X 10.5 and earlier, depending on the CPU type detected at runtime. # On OS X 10.6+ the default is x86_64 if the CPU supports it, i386 otherwise. foreach(osx_arch ${CMAKE_OSX_ARCHITECTURES}) if("${osx_arch}" STREQUAL "ppc" AND ppc_support) set(osx_arch_ppc TRUE) elseif("${osx_arch}" STREQUAL "i386") set(osx_arch_i386 TRUE) elseif("${osx_arch}" STREQUAL "x86_64") set(osx_arch_x86_64 TRUE) elseif("${osx_arch}" STREQUAL "ppc64" AND ppc_support) set(osx_arch_ppc64 TRUE) else() message(FATAL_ERROR "Invalid OS X arch name: ${osx_arch}") endif() endforeach() # Now add all the architectures in our normalized order if(osx_arch_ppc) list(APPEND ARCH ppc) endif() if(osx_arch_i386) list(APPEND ARCH i386) endif() if(osx_arch_x86_64) list(APPEND ARCH x86_64) endif() if(osx_arch_ppc64) list(APPEND ARCH ppc64) endif() else() file(WRITE "${CMAKE_BINARY_DIR}/arch.c" "${archdetect_c_code}") enable_language(C) # Detect the architecture in a rather creative way... # This compiles a small C program which is a series of ifdefs that selects a # particular #error preprocessor directive whose message string contains the # target architecture. The program will always fail to compile (both because # file is not a valid C program, and obviously because of the presence of the # #error preprocessor directives... but by exploiting the preprocessor in this # way, we can detect the correct target architecture even when cross-compiling, # since the program itself never needs to be run (only the compiler/preprocessor) try_run( run_result_unused compile_result_unused "${CMAKE_BINARY_DIR}" "${CMAKE_BINARY_DIR}/arch.c" COMPILE_OUTPUT_VARIABLE ARCH CMAKE_FLAGS CMAKE_OSX_ARCHITECTURES=${CMAKE_OSX_ARCHITECTURES} ) # Parse the architecture name from the compiler output string(REGEX MATCH "cmake_ARCH ([a-zA-Z0-9_]+)" ARCH "${ARCH}") # Get rid of the value marker leaving just the architecture name string(REPLACE "cmake_ARCH " "" ARCH "${ARCH}") # If we are compiling with an unknown architecture this variable should # already be set to "unknown" but in the case that it's empty (i.e. due # to a typo in the code), then set it to unknown if (NOT ARCH) set(ARCH unknown) endif() endif() set(${output_var} "${ARCH}" PARENT_SCOPE) endfunction()