# *DOCUMENTATION* # # Note that this is *NOT* the top-level CMakeLists.txt. That's in the # application. See the Application Development Primer documentation # for details. # # To see a list of typical targets execute "make usage" # More info can be located in ./README.rst # Comments in this file are targeted only to the developer, do not # expect to learn how to build the kernel reading this file. if(NOT DEFINED ZEPHYR_BINARY_DIR) message(FATAL_ERROR "A user error has occured. cmake was invoked with '${CMAKE_CURRENT_LIST_DIR}' specified as the source directory, but it must be invoked with an application source directory, such as '${CMAKE_CURRENT_LIST_DIR}/samples/hello_world'. Debug variables: CMAKE_CACHEFILE_DIR: ${CMAKE_CACHEFILE_DIR} ") endif() project(Zephyr-Kernel VERSION ${PROJECT_VERSION}) enable_language(C CXX ASM) # Verify that the toolchain can compile a dummy file, if it is not we # won't be able to test for compatiblity with certain C flags. check_c_compiler_flag("" toolchain_is_ok) assert(toolchain_is_ok "The toolchain is unable to build a dummy C file. See CMakeError.log.") set(CMAKE_EXECUTABLE_SUFFIX .elf) if(NOT PROPERTY_LINKER_SCRIPT_DEFINES) set_property(GLOBAL PROPERTY PROPERTY_LINKER_SCRIPT_DEFINES -D__GCC_LINKER_CMD__) endif() define_property(GLOBAL PROPERTY PROPERTY_OUTPUT_FORMAT BRIEF_DOCS " " FULL_DOCS " ") set_property( GLOBAL PROPERTY PROPERTY_OUTPUT_FORMAT elf32-little${ARCH}) # BFD format # "zephyr_interface" is a source-less library that encapsulates all the global # compiler options needed by all source files. All zephyr libraries, # including the library named "zephyr" link with this library to # obtain these flags. # https://cmake.org/cmake/help/latest/manual/cmake-buildsystem.7.html#interface-libraries add_library(zephyr_interface INTERFACE) # "zephyr" is a catch-all CMake library for source files that can be # built purely with the include paths, defines, and other compiler # flags that come with zephyr_interface. zephyr_library_named(zephyr) zephyr_include_directories( kernel/include arch/${ARCH}/include ${SOC_DIR}/${ARCH}/${SOC_PATH} ${SOC_DIR}/${ARCH}/${SOC_PATH}/include ${SOC_DIR}/${ARCH}/${SOC_FAMILY}/include include include/drivers ${PROJECT_BINARY_DIR}/include/generated ${USERINCLUDE} ${STDINCLUDE} ) zephyr_compile_definitions( KERNEL __ZEPHYR__=1 ) if(NOT CONFIG_NO_OPTIMIZATIONS) zephyr_compile_definitions( _FORTIFY_SOURCE=2 ) endif() if(BUILD_VERSION) zephyr_compile_definitions( BUILD_VERSION=${BUILD_VERSION} ) endif() # We need to set an optimization level. # Default to -Os # unless CONFIG_NO_OPTIMIZATIONS is set, then it is -O0 # or unless CONFIG_DEBUG is set, then it is -Og # # also, some toolchain's break with -Os, and some toolchain's break # with -Og so allow them to override what flag to use # # Finally, the user can use Kconfig to add compiler options that will # come after these options and override them set_ifndef(OPTIMIZE_FOR_NO_OPTIMIZATIONS_FLAG "-O0") set_ifndef(OPTIMIZE_FOR_DEBUG_FLAG "-Og") set_ifndef(OPTIMIZE_FOR_SIZE_FLAG "-Os") set_ifndef(OPTIMIZE_FOR_SPEED_FLAG "-O2") if(CONFIG_NO_OPTIMIZATIONS) set(OPTIMIZATION_FLAG ${OPTIMIZE_FOR_NO_OPTIMIZATIONS_FLAG}) elseif(CONFIG_DEBUG_OPTIMIZATIONS) set(OPTIMIZATION_FLAG ${OPTIMIZE_FOR_DEBUG_FLAG}) elseif(CONFIG_SPEED_OPTIMIZATIONS) set(OPTIMIZATION_FLAG ${OPTIMIZE_FOR_SPEED_FLAG}) elseif(CONFIG_SIZE_OPTIMIZATIONS) set(OPTIMIZATION_FLAG ${OPTIMIZE_FOR_SIZE_FLAG}) # Default else() assert(0 "Unreachable code. Expected optimization level to have been chosen. See misc/Kconfig.") endif() # Dialects of C++, corresponding to the multiple published ISO standards. # Which standard it implements can be selected using the -std= command-line option. set_ifndef(DIALECT_STD_CPP98 "c++98") set_ifndef(DIALECT_STD_CPP11 "c++11") set_ifndef(DIALECT_STD_CPP14 "c++14") set_ifndef(DIALECT_STD_CPP17 "c++17") set_ifndef(DIALECT_STD_CPP2A "c++2a") if(CONFIG_STD_CPP98) set(STD_CPP_DIALECT ${DIALECT_STD_CPP98}) elseif(CONFIG_STD_CPP11) set(STD_CPP_DIALECT ${DIALECT_STD_CPP11}) # Default elseif(CONFIG_STD_CPP14) set(STD_CPP_DIALECT ${DIALECT_STD_CPP14}) elseif(CONFIG_STD_CPP17) set(STD_CPP_DIALECT ${DIALECT_STD_CPP17}) elseif(CONFIG_STD_CPP2A) set(STD_CPP_DIALECT ${DIALECT_STD_CPP2A}) else() assert(0 "Unreachable code. Expected C++ standard to have been chosen. See misc/Kconfig.") endif() zephyr_compile_options( ${OPTIMIZATION_FLAG} # Usually -Os -g # TODO: build configuration enough? -Wall -Wformat -Wformat-security -Wno-format-zero-length -imacros ${AUTOCONF_H} -ffreestanding -Wno-main -fno-common ${NOSTDINC_F} ${TOOLCHAIN_C_FLAGS} ) zephyr_compile_options( $<$:-std=${STD_CPP_DIALECT}> $<$:-fcheck-new> $<$:-ffunction-sections> $<$:-fdata-sections> $<$:-xassembler-with-cpp> $<$:-D_ASMLANGUAGE> ) if(NOT CONFIG_RTTI) zephyr_compile_options( $<$:-fno-rtti> ) endif() if(NOT CONFIG_EXCEPTIONS) zephyr_compile_options( $<$:-fno-exceptions> ) endif() zephyr_ld_options( ${TOOLCHAIN_LD_FLAGS} ) if(NOT CONFIG_NATIVE_APPLICATION) zephyr_ld_options( -nostdlib -static -no-pie ) endif() if(CONFIG_LIB_CPLUSPLUS) zephyr_ld_options( -lstdc++ ) endif() # ========================================================================== # # cmake -DW=... settings # # W=1 - warnings that may be relevant and does not occur too often # W=2 - warnings that occur quite often but may still be relevant # W=3 - the more obscure warnings, can most likely be ignored # ========================================================================== if(W MATCHES "1") zephyr_compile_options( -Wextra -Wunused -Wno-unused-parameter -Wmissing-declarations -Wmissing-format-attribute -Wold-style-definition ) zephyr_cc_option( -Wmissing-prototypes -Wmissing-include-dirs -Wunused-but-set-variable -Wno-missing-field-initializers ) endif() if(W MATCHES "2") zephyr_compile_options( -Waggregate-return -Wcast-align -Wdisabled-optimization -Wnested-externs -Wshadow ) zephyr_cc_option( -Wlogical-op -Wmissing-field-initializers ) endif() if(W MATCHES "3") zephyr_compile_options( -Wbad-function-cast -Wcast-qual -Wconversion -Wpacked -Wpadded -Wpointer-arith -Wredundant-decls -Wswitch-default ) zephyr_cc_option( -Wpacked-bitfield-compat -Wvla ) endif() # Allow the user to inject options when calling cmake, e.g. # 'cmake -DEXTRA_CFLAGS="-Werror -Wno-deprecated-declarations" ..' include(cmake/extra_flags.cmake) if(CONFIG_READABLE_ASM) zephyr_cc_option(-fno-reorder-blocks) zephyr_cc_option(-fno-ipa-cp-clone) zephyr_cc_option(-fno-partial-inlining) endif() zephyr_cc_option(-fno-asynchronous-unwind-tables) zephyr_cc_option(-fno-pie) zephyr_cc_option(-fno-pic) zephyr_cc_option(-fno-strict-overflow) zephyr_cc_option(-Wno-pointer-sign) if(CONFIG_STACK_CANARIES) zephyr_cc_option(-fstack-protector-all) # Only a valid option with GCC 7.x and above check_c_compiler_flag(-mstack-protector-guard=global MSTACK_PROTECTOR_GUARD) if(MSTACK_PROTECTOR_GUARD) zephyr_cc_option(-mstack-protector-guard=global) endif() endif() if(CONFIG_OVERRIDE_FRAME_POINTER_DEFAULT) if(CONFIG_OMIT_FRAME_POINTER) zephyr_cc_option(-fomit-frame-pointer) else() zephyr_cc_option(-fno-omit-frame-pointer) endif() endif() separate_arguments(CONFIG_COMPILER_OPT_AS_LIST UNIX_COMMAND ${CONFIG_COMPILER_OPT}) zephyr_compile_options(${CONFIG_COMPILER_OPT_AS_LIST}) # TODO: Include arch compiler options at this point. if(CMAKE_C_COMPILER_ID STREQUAL "Clang") zephyr_cc_option( #FIXME: need to fix all of those -Wno-sometimes-uninitialized -Wno-shift-overflow -Wno-missing-braces -Wno-self-assign -Wno-address-of-packed-member -Wno-unused-function -Wno-initializer-overrides -Wno-section -Wno-unknown-warning-option -Wno-unused-variable -Wno-format-invalid-specifier -Wno-gnu # comparison of unsigned expression < 0 is always false -Wno-tautological-compare ) else() # GCC assumed zephyr_cc_option( -Wno-unused-but-set-variable -fno-reorder-functions ) if(NOT ${ZEPHYR_TOOLCHAIN_VARIANT} STREQUAL "xcc") zephyr_cc_option(-fno-defer-pop) endif() endif() zephyr_cc_option_ifdef(CONFIG_STACK_USAGE -fstack-usage) zephyr_system_include_directories(${NOSTDINC}) # Force an error when things like SYS_INIT(foo, ...) occur with a missing header. zephyr_cc_option(-Werror=implicit-int) # Prohibit void pointer arithmetic. Illegal in C99 zephyr_cc_option(-Wpointer-arith) # Prohibit date/time macros, which would make the build non-deterministic # cc-option(-Werror=date-time) # TODO: Archiver arguments # ar_option(D) # Declare MPU userspace dependencies before the linker scripts to make # sure the order of dependencies are met if(CONFIG_CPU_HAS_MPU AND CONFIG_USERSPACE) if(CONFIG_MPU_REQUIRES_POWER_OF_TWO_ALIGNMENT AND CONFIG_APP_SHARED_MEM ) set(APP_SMEM_DEP app_smem_linker) endif() if(CONFIG_MPU_REQUIRES_POWER_OF_TWO_ALIGNMENT AND CONFIG_ARC AND CONFIG_APPLICATION_MEMORY) set(ALIGN_SIZING_DEP app_sizing_prebuilt linker_app_sizing_script) endif() if(CONFIG_ARM) set(PRIV_STACK_DEP priv_stacks_prebuilt) endif() endif() set_ifndef(LINKERFLAGPREFIX -Wl) if(NOT CONFIG_NATIVE_APPLICATION) zephyr_ld_options( ${LINKERFLAGPREFIX},-X ${LINKERFLAGPREFIX},-N ) endif() zephyr_ld_options( ${LINKERFLAGPREFIX},--gc-sections ${LINKERFLAGPREFIX},--build-id=none ) if(NOT CONFIG_NATIVE_APPLICATION) set(NOSTDINC_F -nostdinc) endif() get_property(TOPT GLOBAL PROPERTY TOPT) set_ifndef( TOPT -T) if(NOT CONFIG_NATIVE_APPLICATION) # Funny thing is if this is set to =error, some architectures will # skip this flag even though the compiler flag check passes # (e.g. ARC and Xtensa). So warning should be the default for now. # # Skip this for native application as Zephyr only provides # additions to the host toolchain linker script. The relocation # sections (.rel*) requires us to override those provided # by host toolchain. As we can't account for all possible # combination of compiler and linker on all machines used # for development, it is better to turn this off. # # CONFIG_LINKER_ORPHAN_SECTION_PLACE is to place the orphan sections # without any warnings or errors, which is the default behavior. # So there is no need to explicity set a linker flag. if(CONFIG_LINKER_ORPHAN_SECTION_WARN) zephyr_ld_options( ${LINKERFLAGPREFIX},--orphan-handling=warn ) elseif(CONFIG_LINKER_ORPHAN_SECTION_ERROR) zephyr_ld_options( ${LINKERFLAGPREFIX},--orphan-handling=error ) endif() endif() if(CONFIG_HAVE_CUSTOM_LINKER_SCRIPT) set(LINKER_SCRIPT ${APPLICATION_SOURCE_DIR}/${CONFIG_CUSTOM_LINKER_SCRIPT}) if(NOT EXISTS ${LINKER_SCRIPT}) set(LINKER_SCRIPT ${CONFIG_CUSTOM_LINKER_SCRIPT}) assert_exists(CONFIG_CUSTOM_LINKER_SCRIPT) endif() else() # Try a board specific linker file set(LINKER_SCRIPT ${BOARD_DIR}/linker.ld) if(NOT EXISTS ${LINKER_SCRIPT}) # If not available, try an SoC specific linker file set(LINKER_SCRIPT ${SOC_DIR}/${ARCH}/${SOC_PATH}/linker.ld) endif() endif() if(NOT EXISTS ${LINKER_SCRIPT}) message(FATAL_ERROR "Could not find linker script: '${LINKER_SCRIPT}'. Corrupted configuration?") endif() # Custom section support in linker scripts requires that the application source # directory is in the preprocessor search path, in order to find the custom # linker script fragments. if(CONFIG_CUSTOM_RODATA_LD OR CONFIG_CUSTOM_RWDATA_LD OR CONFIG_CUSTOM_SECTIONS_LD) zephyr_include_directories(${APPLICATION_SOURCE_DIR}) endif() configure_file(version.h.in ${PROJECT_BINARY_DIR}/include/generated/version.h) function(construct_add_custom_command_for_linker_pass linker_output_name output_variable) set(linker_cmd_file_name ${linker_output_name}.cmd) if (${linker_output_name} MATCHES "^linker_pass_final$") set(linker_pass_define -DLINKER_PASS2) else() set(linker_pass_define "") endif() # Different generators deal with depfiles differently. if(CMAKE_GENERATOR STREQUAL "Unix Makefiles") # Note that the IMPLICIT_DEPENDS option is currently supported only # for Makefile generators and will be ignored by other generators. set(linker_script_dep IMPLICIT_DEPENDS C ${LINKER_SCRIPT}) elseif(CMAKE_GENERATOR STREQUAL "Ninja") # Using DEPFILE with other generators than Ninja is an error. set(linker_script_dep DEPFILE ${PROJECT_BINARY_DIR}/${linker_cmd_file_name}.dep) else() # TODO: How would the linker script dependencies work for non-linker # script generators. message(STATUS "Warning; this generator is not well supported. The Linker script may not be regenerated when it should.") set(linker_script_dep "") endif() zephyr_get_include_directories_for_lang(C current_includes) get_filename_component(base_name ${CMAKE_CURRENT_BINARY_DIR} NAME) get_property(current_defines GLOBAL PROPERTY PROPERTY_LINKER_SCRIPT_DEFINES) set(${output_variable} OUTPUT ${linker_cmd_file_name} DEPENDS ${LINKER_SCRIPT} ${linker_script_dep} COMMAND ${CMAKE_C_COMPILER} -x assembler-with-cpp ${NOSTDINC_F} ${NOSYSDEF_CFLAG} -MD -MF ${linker_cmd_file_name}.dep -MT ${base_name}/${linker_cmd_file_name} ${current_includes} ${current_defines} ${linker_pass_define} -E ${LINKER_SCRIPT} -P # Prevent generation of debug `#line' directives. -o ${linker_cmd_file_name} VERBATIM WORKING_DIRECTORY ${PROJECT_BINARY_DIR} PARENT_SCOPE ) endfunction() # Unfortunately, the order in which CMakeLists.txt code is processed # matters so we need to be careful about how we order the processing # of subdirectories. One example is "Compiler flags added late in the # build are not exported to external build systems #5605"; when we # integrate with an external build system we read out all compiler # flags when the external project is created. So an external project # defined in subsys or ext will not get global flags added by drivers/ # or tests/ as the subdirectories are ordered now. # # Another example of when the order matters is the reading and writing # of global properties such as ZEPHYR_LIBS or # GENERATED_KERNEL_OBJECT_FILES. # # Arch is placed early because it defines important compiler flags # that must be exported to external build systems defined in # e.g. subsys/. add_subdirectory(arch) add_subdirectory(lib) add_subdirectory(misc) # We use include instead of add_subdirectory to avoid creating a new directory scope. # This is because source file properties are directory scoped, including the GENERATED # property which is set implicitly for custom command outputs include(misc/generated/CMakeLists.txt) if(EXISTS ${SOC_DIR}/${ARCH}/CMakeLists.txt) add_subdirectory(${SOC_DIR}/${ARCH} soc/${ARCH}) else() add_subdirectory(${SOC_DIR}/${ARCH}/${SOC_PATH} soc/${ARCH}/${SOC_PATH}) endif() add_subdirectory(boards) add_subdirectory(ext) add_subdirectory(subsys) add_subdirectory(drivers) add_subdirectory(tests) set(syscall_macros_h ${ZEPHYR_BINARY_DIR}/include/generated/syscall_macros.h) add_custom_target(syscall_macros_h_target DEPENDS ${syscall_macros_h}) add_custom_command( OUTPUT ${syscall_macros_h} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/gen_syscall_header.py > ${syscall_macros_h} DEPENDS ${ZEPHYR_BASE}/scripts/gen_syscall_header.py ) set(syscall_list_h ${CMAKE_CURRENT_BINARY_DIR}/include/generated/syscall_list.h) set(syscalls_json ${CMAKE_CURRENT_BINARY_DIR}/misc/generated/syscalls.json) # The syscalls subdirs txt file is constructed by python containing a list of folders to use for # dependency handling, including empty folders. # Windows: The list is used to specify DIRECTORY list with CMAKE_CONFIGURE_DEPENDS attribute. # Other OS: The list will update whenever a file is added/removed/modified and ensure a re-build. set(syscalls_subdirs_txt ${CMAKE_CURRENT_BINARY_DIR}/misc/generated/syscalls_subdirs.txt) # As syscalls_subdirs_txt is updated whenever a file is modified, this file can not be used for # monitoring of added / removed folders. A trigger file is thus used for correct dependency # handling. The trigger file will update when a folder is added / removed. set(syscalls_subdirs_trigger ${CMAKE_CURRENT_BINARY_DIR}/misc/generated/syscalls_subdirs.trigger) if(NOT (${CMAKE_HOST_SYSTEM_NAME} STREQUAL Windows)) set(syscalls_links --create-links ${CMAKE_CURRENT_BINARY_DIR}/misc/generated/syscalls_links) endif() # When running CMake it must be ensured that all dependencies are correctly acquired. execute_process( COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/subfolder_list.py --directory ${ZEPHYR_BASE}/include # Walk this directory --out-file ${syscalls_subdirs_txt} # Write file with discovered folder --trigger ${syscalls_subdirs_trigger} # Trigger file that is used for json generation ${syscalls_links} # If defined, create symlinks for dependencies ) file(STRINGS ${syscalls_subdirs_txt} PARSE_SYSCALLS_PATHS_DEPENDS) if(${CMAKE_HOST_SYSTEM_NAME} STREQUAL Windows) # On windows only adding/removing files or folders will be reflected in depends. # Hence adding a file requires CMake to re-run to add this file to the file list. set_property(DIRECTORY APPEND PROPERTY CMAKE_CONFIGURE_DEPENDS ${PARSE_SYSCALLS_PATHS_DEPENDS}) # Also On Windows each header file must be monitored as file modifications are not reflected # on directory level. file(GLOB_RECURSE PARSE_SYSCALLS_HEADER_DEPENDS ${ZEPHYR_BASE}/include/*.h) else() # The syscall parsing depends on the folders in order to detect add/removed/modified files. # When a folder is removed, CMake will try to find a target that creates that dependency. # This command sets up the target for CMake to find. # Without this code, CMake will fail with the following error: # needed by '', missing and no known rule to make it # when a folder is removed. add_custom_command(OUTPUT ${PARSE_SYSCALLS_PATHS_DEPENDS} COMMAND ${CMAKE_COMMAND} -E echo "" COMMENT "Preparing syscall dependency handling" ) add_custom_command( OUTPUT ${syscalls_subdirs_trigger} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/subfolder_list.py --directory ${ZEPHYR_BASE}/include # Walk this directory --out-file ${syscalls_subdirs_txt} # Write file with discovered folder --trigger ${syscalls_subdirs_trigger} # Trigger file that is used for json generation ${syscalls_links} # If defined, create symlinks for dependencies DEPENDS ${PARSE_SYSCALLS_PATHS_DEPENDS} ) # Ensure subdir file always exists when specifying CMake dependency. if(NOT EXISTS ${syscalls_subdirs_txt}) file(WRITE ${syscalls_subdirs_txt} "") endif() # On other OS'es, modifying a file is reflected on the folder timestamp and hence detected # when using depend on directory level. # Thus CMake only needs to re-run when sub-directories are added / removed, which is indicated # using a trigger file. set_property(DIRECTORY APPEND PROPERTY CMAKE_CONFIGURE_DEPENDS ${syscalls_subdirs_txt}) endif() # SYSCALL_INCLUDE_DIRECTORY will include the directories that needs to be # searched for syscall declarations if CONFIG_APPLICATION_DEFINED_SYSCALL is set if(CONFIG_APPLICATION_DEFINED_SYSCALL) set(SYSCALL_INCLUDE_DIRECTORY --include ${APPLICATION_SOURCE_DIR}) endif() add_custom_command( OUTPUT ${syscalls_json} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/parse_syscalls.py --include ${ZEPHYR_BASE}/include # Read files from this dir ${SYSCALL_INCLUDE_DIRECTORY} --json-file ${syscalls_json} # Write this file DEPENDS ${syscalls_subdirs_trigger} ${PARSE_SYSCALLS_HEADER_DEPENDS} ) add_custom_target(syscall_list_h_target DEPENDS ${syscall_list_h}) add_custom_command(OUTPUT include/generated/syscall_dispatch.c ${syscall_list_h} # Also, some files are written to include/generated/syscalls/ COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/gen_syscalls.py --json-file ${syscalls_json} # Read this file --base-output include/generated/syscalls # Write to this dir --syscall-dispatch include/generated/syscall_dispatch.c # Write this file --syscall-list ${syscall_list_h} WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} DEPENDS ${syscalls_json} ) set(DRV_VALIDATION ${PROJECT_BINARY_DIR}/include/generated/driver-validation.h) add_custom_command( OUTPUT ${DRV_VALIDATION} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/gen_kobject_list.py --validation-output ${DRV_VALIDATION} $<$:--verbose> WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(driver_validation_h_target DEPENDS ${DRV_VALIDATION}) include($ENV{ZEPHYR_BASE}/cmake/kobj.cmake) gen_kobj(KOBJ_INCLUDE_PATH) # Generate offsets.c.obj from offsets.c # Generate offsets.h from offsets.c.obj set(OFFSETS_C_PATH ${ZEPHYR_BASE}/arch/${ARCH}/core/offsets/offsets.c) set(OFFSETS_O_PATH ${CMAKE_CURRENT_BINARY_DIR}/CMakeFiles/offsets.dir/arch/${ARCH}/core/offsets/offsets.c.obj) set(OFFSETS_H_PATH ${PROJECT_BINARY_DIR}/include/generated/offsets.h) add_library( offsets STATIC ${OFFSETS_C_PATH}) target_link_libraries(offsets zephyr_interface) add_dependencies( offsets syscall_list_h_target syscall_macros_h_target driver_validation_h_target kobj_types_h_target ) add_custom_command( OUTPUT ${OFFSETS_H_PATH} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/gen_offset_header.py -i ${OFFSETS_O_PATH} -o ${OFFSETS_H_PATH} DEPENDS offsets ) add_custom_target(offsets_h DEPENDS ${OFFSETS_H_PATH}) zephyr_include_directories(${TOOLCHAIN_INCLUDES}) zephyr_get_include_directories_for_lang(C ZEPHYR_INCLUDES) add_subdirectory(kernel) # Read list content get_property(ZEPHYR_LIBS_PROPERTY GLOBAL PROPERTY ZEPHYR_LIBS) foreach(zephyr_lib ${ZEPHYR_LIBS_PROPERTY}) # TODO: Could this become an INTERFACE property of zephyr_interface? add_dependencies(${zephyr_lib} offsets_h) # Verify that all (non-imported) libraries have source # files. Libraries without source files are not supported because # they are an indication that something has been misconfigured. get_target_property(lib_imported ${zephyr_lib} IMPORTED) get_target_property(lib_sources ${zephyr_lib} SOURCES) if(lib_sources STREQUAL lib_sources-NOTFOUND AND (NOT (${zephyr_lib} STREQUAL app)) AND (NOT lib_imported) ) # app is not checked because it's sources are added to it after # this CMakeLists.txt file has been processed message(FATAL_ERROR "\ The Zephyr library '${zephyr_lib}' was created without source files. \ Empty (non-imported) libraries are not supported. \ Either make sure that the library has the sources it should have, \ or make sure it is not created when it has no source files.") endif() endforeach() get_property(OUTPUT_FORMAT GLOBAL PROPERTY PROPERTY_OUTPUT_FORMAT) if(CONFIG_APPLICATION_MEMORY) # Objects default to being in kernel space, and then we exclude # certain items. set(kernel_object_file_list ${ZEPHYR_LIBS_PROPERTY} kernel ) list( REMOVE_ITEM kernel_object_file_list app ) # The zephyr libraries in zephyr/lib/ and zephyr/test/ belong in # userspace. # NB: The business logic for determing what source files are in # kernel space and what source files are in user space is # fragile. Fix ASAP. # # The intended design is that certain directories are designated as # containing userspace code and others for kernel space code. The # implementation we have however is not working on directories of # code, it is working on zephyr libraries. It is exploiting the fact # that zephyr libraries follow a naming scheme as described in # extensions.cmake:zephyr_library_get_current_dir_lib_name # # But code from test/ and lib/ that is placed in the "zephyr" # library (with zephyr_sources()) will not be in a library that is # prefixed with lib__ or test__ and will end up in the wrong address # space. set(application_space_dirs lib tests ) foreach(f ${kernel_object_file_list}) foreach(app_dir ${application_space_dirs}) if(${f} MATCHES "^${app_dir}__") # Begins with ${app_dir}__, e.g. lib__libc list( REMOVE_ITEM kernel_object_file_list ${f} ) endif() endforeach() endforeach() # Create a list ks, with relative paths to kernel space libs. foreach(f ${kernel_object_file_list}) get_target_property(target_name ${f} NAME) get_target_property(target_binary_dir ${f} BINARY_DIR) string(REPLACE ${PROJECT_BINARY_DIR} "" fixed_path ${target_binary_dir} ) # Append / if not empty if(fixed_path) set(fixed_path "${fixed_path}/") endif() # Cut off leading / if present if(fixed_path MATCHES "^/.+") string(SUBSTRING ${fixed_path} 1 -1 fixed_path) endif() set(fixed_path "${fixed_path}lib${target_name}.a") if(CMAKE_GENERATOR STREQUAL "Ninja") # Ninja invokes the linker from the root of the build directory # (APPLICATION_BINARY_DIR) instead of from the build/zephyr # directory (PROJECT_BINARY_DIR). So for linker-defs.h to get # the correct path we need to prefix with zephyr/. set(fixed_path "zephyr/${fixed_path}") endif() list(APPEND ks ${fixed_path}) endforeach() # We are done constructing kernel_object_file_list, now we inject # this list into the linker script through the define # KERNELSPACE_OBJECT_FILES set(def -DKERNELSPACE_OBJECT_FILES=) foreach(f ${ks}) set(def "${def} ${f}") endforeach() set_property(GLOBAL APPEND PROPERTY PROPERTY_LINKER_SCRIPT_DEFINES ${def} ) endif() # CONFIG_APPLICATION_MEMORY if (CONFIG_CODE_DATA_RELOCATION) set(CODE_RELOCATION_DEP code_relocation_source_lib) endif() # CONFIG_CODE_DATA_RELOCATION construct_add_custom_command_for_linker_pass(linker custom_command) add_custom_command( ${custom_command} ) add_custom_target( linker_script DEPENDS ${ALIGN_SIZING_DEP} ${PRIV_STACK_DEP} ${APP_SMEM_DEP} ${CODE_RELOCATION_DEP} linker.cmd offsets_h ) # Give the 'linker_script' target all of the include directories so # that cmake can successfully find the linker_script's header # dependencies. zephyr_get_include_directories_for_lang(C ZEPHYR_INCLUDE_DIRS STRIP_PREFIX # Don't use a -I prefix ) set_property(TARGET linker_script PROPERTY INCLUDE_DIRECTORIES ${ZEPHYR_INCLUDE_DIRS} ) set(zephyr_lnk ${LINKERFLAGPREFIX},-Map=${PROJECT_BINARY_DIR}/${KERNEL_MAP_NAME} -u_OffsetAbsSyms -u_ConfigAbsSyms ${LINKERFLAGPREFIX},--whole-archive ${ZEPHYR_LIBS_PROPERTY} ${LINKERFLAGPREFIX},--no-whole-archive kernel ${OFFSETS_O_PATH} ${LIB_INCLUDE_DIR} -L${PROJECT_BINARY_DIR} ${TOOLCHAIN_LIBS} ) if(CONFIG_GEN_ISR_TABLES) if(CONFIG_GEN_SW_ISR_TABLE) list(APPEND GEN_ISR_TABLE_EXTRA_ARG --sw-isr-table) endif() if(CONFIG_GEN_IRQ_VECTOR_TABLE) list(APPEND GEN_ISR_TABLE_EXTRA_ARG --vector-table) endif() # isr_tables.c is generated from zephyr_prebuilt by # gen_isr_tables.py add_custom_command( OUTPUT isr_tables.c COMMAND ${CMAKE_OBJCOPY} -I ${OUTPUT_FORMAT} -O binary --only-section=.intList $ isrList.bin COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/arch/common/gen_isr_tables.py --output-source isr_tables.c --kernel $ --intlist isrList.bin $<$:--big-endian> $<$:--debug> ${GEN_ISR_TABLE_EXTRA_ARG} DEPENDS zephyr_prebuilt ) set_property(GLOBAL APPEND PROPERTY GENERATED_KERNEL_SOURCE_FILES isr_tables.c) endif() if(CONFIG_CODE_DATA_RELOCATION) set(MEM_RELOCATAION_LD "${PROJECT_BINARY_DIR}/include/generated/linker_relocate.ld") set(MEM_RELOCATAION_CODE "${PROJECT_BINARY_DIR}/code_relocation.c") add_custom_command( OUTPUT ${MEM_RELOCATAION_CODE} ${MEM_RELOCATAION_LD} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/gen_relocate_app.py $<$:--verbose> -d ${APPLICATION_BINARY_DIR} -i '$' -o ${MEM_RELOCATAION_LD} -c ${MEM_RELOCATAION_CODE} DEPENDS app kernel ${ZEPHYR_LIBS_PROPERTY} ) add_library(code_relocation_source_lib STATIC ${MEM_RELOCATAION_CODE}) target_link_libraries(code_relocation_source_lib zephyr_interface) endif() if(CONFIG_ARM AND CONFIG_USERSPACE) set(GEN_PRIV_STACKS $ENV{ZEPHYR_BASE}/scripts/gen_priv_stacks.py) set(PROCESS_PRIV_STACKS_GPERF $ENV{ZEPHYR_BASE}/scripts/process_gperf.py) set(PRIV_STACKS priv_stacks_hash.gperf) set(PRIV_STACKS_OUTPUT_SRC_PRE priv_stacks_hash_preprocessed.c) set(PRIV_STACKS_OUTPUT_SRC priv_stacks_hash.c) set(PRIV_STACKS_OUTPUT_OBJ priv_stacks_hash.c.obj) set(PRIV_STACKS_OUTPUT_OBJ_RENAMED priv_stacks_hash_renamed.o) # Essentially what we are doing here is extracting some information # out of the nearly finished elf file, generating the source code # for a hash table based on that information, and then compiling and # linking the hash table back into a now even more nearly finished # elf file. # Use the script GEN_PRIV_STACKS to scan the kernel binary's # (zephyr_prebuilt) DWARF information to produce a table of kernel # objects (PRIV_STACKS) which we will then pass to gperf add_custom_command( OUTPUT ${PRIV_STACKS} COMMAND ${PYTHON_EXECUTABLE} ${GEN_PRIV_STACKS} --kernel $ --output ${PRIV_STACKS} $<$:--verbose> DEPENDS priv_stacks_prebuilt WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(priv_stacks DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${PRIV_STACKS}) # Use gperf to generate C code (PRIV_STACKS_OUTPUT_SRC_PRE) which implements a # perfect hashtable based on PRIV_STACKS add_custom_command( OUTPUT ${PRIV_STACKS_OUTPUT_SRC_PRE} COMMAND ${GPERF} -C --output-file ${PRIV_STACKS_OUTPUT_SRC_PRE} ${PRIV_STACKS} DEPENDS priv_stacks ${PRIV_STACKS} WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(priv_stacks_output_src_pre DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${PRIV_STACKS_OUTPUT_SRC_PRE}) # For our purposes the code/data generated by gperf is not optimal. # # The script PROCESS_GPERF creates a new c file OUTPUT_SRC based on # OUTPUT_SRC_PRE to greatly reduce the amount of code/data generated # since we know we are always working with pointer values add_custom_command( OUTPUT ${PRIV_STACKS_OUTPUT_SRC} COMMAND ${PYTHON_EXECUTABLE} ${PROCESS_PRIV_STACKS_GPERF} -i ${PRIV_STACKS_OUTPUT_SRC_PRE} -o ${PRIV_STACKS_OUTPUT_SRC} -p "struct _k_priv_stack_map" $<$:--verbose> DEPENDS priv_stacks_output_src_pre ${PRIV_STACKS_OUTPUT_SRC_PRE} WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(priv_stacks_output_src DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${PRIV_STACKS_OUTPUT_SRC}) # We need precise control of where generated text/data ends up in the final # kernel image. Disable function/data sections and use objcopy to move # generated data into special section names add_library(priv_stacks_output_lib STATIC ${CMAKE_CURRENT_BINARY_DIR}/${PRIV_STACKS_OUTPUT_SRC} ) target_link_libraries(priv_stacks_output_lib zephyr_interface) # Turn off -ffunction-sections, etc. # NB: Using a library instead of target_compile_options(priv_stacks_output_lib # [...]) because a library's options have precedence add_library(priv_stacks_output_lib_interface INTERFACE) target_compile_options(priv_stacks_output_lib_interface INTERFACE -fno-function-sections -fno-data-sections ) target_link_libraries(priv_stacks_output_lib priv_stacks_output_lib_interface) set(PRIV_STACKS_OUTPUT_OBJ_PATH ${CMAKE_CURRENT_BINARY_DIR}/CMakeFiles/priv_stacks_output_lib.dir/${PRIV_STACKS_OUTPUT_OBJ}) add_custom_command( OUTPUT ${CMAKE_CURRENT_BINARY_DIR}/${PRIV_STACKS_OUTPUT_OBJ_RENAMED} COMMAND ${CMAKE_OBJCOPY} --rename-section .bss=.priv_stacks.noinit --rename-section .data=.priv_stacks.data --rename-section .text=.priv_stacks.text --rename-section .rodata=.priv_stacks.rodata ${PRIV_STACKS_OUTPUT_OBJ_PATH} ${PRIV_STACKS_OUTPUT_OBJ_RENAMED} DEPENDS priv_stacks_output_lib WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(priv_stacks_output_obj_renamed DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${PRIV_STACKS_OUTPUT_OBJ_RENAMED}) add_library(priv_stacks_output_obj_renamed_lib STATIC IMPORTED GLOBAL) set_property( TARGET priv_stacks_output_obj_renamed_lib PROPERTY IMPORTED_LOCATION ${CMAKE_CURRENT_BINARY_DIR}/${PRIV_STACKS_OUTPUT_OBJ_RENAMED} ) add_dependencies( priv_stacks_output_obj_renamed_lib priv_stacks_output_obj_renamed ) set_property(GLOBAL APPEND PROPERTY GENERATED_KERNEL_OBJECT_FILES priv_stacks_output_obj_renamed_lib) endif() if(CONFIG_USERSPACE) set(GEN_KOBJ_LIST ${ZEPHYR_BASE}/scripts/gen_kobject_list.py) set(PROCESS_GPERF ${ZEPHYR_BASE}/scripts/process_gperf.py) set(OBJ_LIST kobject_hash.gperf) set(OUTPUT_SRC_PRE kobject_hash_preprocessed.c) set(OUTPUT_SRC kobject_hash.c) set(OUTPUT_OBJ kobject_hash.c.obj) set(OUTPUT_OBJ_RENAMED kobject_hash_renamed.o) # Essentially what we are doing here is extracting some information # out of the nearly finished elf file, generating the source code # for a hash table based on that information, and then compiling and # linking the hash table back into a now even more nearly finished # elf file. # Use the script GEN_KOBJ_LIST to scan the kernel binary's # (zephyr_prebuilt) DWARF information to produce a table of kernel # objects (OBJ_LIST) which we will then pass to gperf add_custom_command( OUTPUT ${OBJ_LIST} COMMAND ${PYTHON_EXECUTABLE} ${GEN_KOBJ_LIST} --kernel $ --gperf-output ${OBJ_LIST} $<$:--verbose> DEPENDS zephyr_prebuilt WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(obj_list DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${OBJ_LIST}) # Use gperf to generate C code (OUTPUT_SRC_PRE) which implements a # perfect hashtable based on OBJ_LIST add_custom_command( OUTPUT ${OUTPUT_SRC_PRE} COMMAND ${GPERF} --output-file ${OUTPUT_SRC_PRE} ${OBJ_LIST} DEPENDS obj_list ${OBJ_LIST} WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(output_src_pre DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${OUTPUT_SRC_PRE}) # For our purposes the code/data generated by gperf is not optimal. # # The script PROCESS_GPERF creates a new c file OUTPUT_SRC based on # OUTPUT_SRC_PRE to greatly reduce the amount of code/data generated # since we know we are always working with pointer values add_custom_command( OUTPUT ${OUTPUT_SRC} COMMAND ${PYTHON_EXECUTABLE} ${PROCESS_GPERF} -i ${OUTPUT_SRC_PRE} -o ${OUTPUT_SRC} -p "struct _k_object" $<$:--verbose> DEPENDS output_src_pre ${OUTPUT_SRC_PRE} WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(output_src DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${OUTPUT_SRC}) # We need precise control of where generated text/data ends up in the final # kernel image. Disable function/data sections and use objcopy to move # generated data into special section names add_library(output_lib STATIC ${CMAKE_CURRENT_BINARY_DIR}/${OUTPUT_SRC} ) # always compile kobject_hash.c at optimization -Os set_source_files_properties(${OUTPUT_SRC} PROPERTIES COMPILE_FLAGS -Os) target_link_libraries(output_lib zephyr_interface) # Turn off -ffunction-sections, etc. # NB: Using a library instead of target_compile_options(output_lib # [...]) because a library's options have precedence add_library(output_lib_interface INTERFACE) target_compile_options(output_lib_interface INTERFACE -fno-function-sections -fno-data-sections ) target_link_libraries(output_lib output_lib_interface) set(OUTPUT_OBJ_PATH ${CMAKE_CURRENT_BINARY_DIR}/CMakeFiles/output_lib.dir/${OUTPUT_OBJ}) add_custom_command( OUTPUT ${CMAKE_CURRENT_BINARY_DIR}/${OUTPUT_OBJ_RENAMED} COMMAND ${CMAKE_OBJCOPY} --rename-section .data=.kobject_data.data --rename-section .text=.kobject_data.text --rename-section .rodata=.kobject_data.rodata ${OUTPUT_OBJ_PATH} ${OUTPUT_OBJ_RENAMED} DEPENDS output_lib WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR} ) add_custom_target(output_obj_renamed DEPENDS ${CMAKE_CURRENT_BINARY_DIR}/${OUTPUT_OBJ_RENAMED}) add_library(output_obj_renamed_lib STATIC IMPORTED GLOBAL) set_property( TARGET output_obj_renamed_lib PROPERTY IMPORTED_LOCATION ${CMAKE_CURRENT_BINARY_DIR}/${OUTPUT_OBJ_RENAMED} ) add_dependencies( output_obj_renamed_lib output_obj_renamed ) set_property(GLOBAL APPEND PROPERTY GENERATED_KERNEL_OBJECT_FILES output_obj_renamed_lib) endif() # Read global variables into local variables get_property(GKOF GLOBAL PROPERTY GENERATED_KERNEL_OBJECT_FILES) get_property(GKSF GLOBAL PROPERTY GENERATED_KERNEL_SOURCE_FILES) get_property(CSTD GLOBAL PROPERTY CSTD) set_ifndef(CSTD c99) zephyr_compile_options( $<$:-std=${CSTD}> ) configure_file( $ENV{ZEPHYR_BASE}/include/arch/arc/v2/app_data_alignment.ld ${PROJECT_BINARY_DIR}/include/generated/app_data_alignment.ld) configure_file( $ENV{ZEPHYR_BASE}/include/arch/arm/cortex_m/scripts/app_smem.ld ${PROJECT_BINARY_DIR}/include/generated/app_smem.ld) if(CONFIG_CPU_HAS_MPU AND CONFIG_USERSPACE) if(CONFIG_MPU_REQUIRES_POWER_OF_TWO_ALIGNMENT AND CONFIG_APP_SHARED_MEM) set(APP_SMEM_LD "${PROJECT_BINARY_DIR}/include/generated/app_smem.ld") set(OBJ_FILE_DIR "${PROJECT_BINARY_DIR}/../") add_custom_target( ${APP_SMEM_DEP} ALL DEPENDS app kernel ) add_custom_command( TARGET ${APP_SMEM_DEP} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/gen_app_partitions.py -d ${OBJ_FILE_DIR} -o ${APP_SMEM_LD} $<$:--verbose> WORKING_DIRECTORY ${PROJECT_BINARY_DIR}/ COMMENT "Generating power of 2 aligned app_smem linker section" ) endif() if(CONFIG_MPU_REQUIRES_POWER_OF_TWO_ALIGNMENT AND CONFIG_ARC AND CONFIG_APPLICATION_MEMORY) construct_add_custom_command_for_linker_pass(linker_app_sizing custom_command) add_custom_command( ${custom_command} ) add_custom_target( linker_app_sizing_script DEPENDS linker_app_sizing.cmd offsets_h ${APP_SMEM_DEP} ${CODE_RELOCATION_DEP} ) set_property(TARGET linker_app_sizing_script PROPERTY INCLUDE_DIRECTORIES ${ZEPHYR_INCLUDE_DIRS} ) # For systems with MPUs, the size of the application data section must # be determined so that MPU alignment requirements can be met. # Create a app_sizing_prebuilt target so we can do this before the # other ELF files are built set(GEN_APP_ALIGN $ENV{ZEPHYR_BASE}/scripts/gen_alignment_script.py) add_executable( app_sizing_prebuilt misc/empty_file.c) target_link_libraries(app_sizing_prebuilt ${TOPT} ${PROJECT_BINARY_DIR}/linker_app_sizing.cmd ${zephyr_lnk} ${CODE_RELOCATION_DEP}) set_property(TARGET app_sizing_prebuilt PROPERTY LINK_DEPENDS ${PROJECT_BINARY_DIR}/linker_app_sizing.cmd) add_dependencies( app_sizing_prebuilt linker_app_sizing_script offsets ${CODE_RELOCATION_DEP} ) add_custom_command( TARGET app_sizing_prebuilt POST_BUILD COMMAND ${PYTHON_EXECUTABLE} ${GEN_APP_ALIGN} --output ./include/generated/app_data_alignment.ld --kernel $ VERBATIM WORKING_DIRECTORY ${PROJECT_BINARY_DIR}/ ) endif() if(CONFIG_ARM) construct_add_custom_command_for_linker_pass(linker_priv_stacks custom_command) add_custom_command( ${custom_command} ) add_custom_target( linker_priv_stacks_script DEPENDS ${ALIGN_SIZING_DEP} ${APP_SMEM_DEP} ${CODE_RELOCATION_DEP} linker_priv_stacks.cmd offsets_h ) set_property(TARGET linker_priv_stacks_script PROPERTY INCLUDE_DIRECTORIES ${ZEPHYR_INCLUDE_DIRS} ) set(PRIV_STACK_LIB priv_stacks_output_obj_renamed_lib) add_executable( priv_stacks_prebuilt misc/empty_file.c) target_link_libraries(priv_stacks_prebuilt ${TOPT} ${PROJECT_BINARY_DIR}/linker_priv_stacks.cmd ${zephyr_lnk} ${CODE_RELOCATION_DEP}) set_property(TARGET priv_stacks_prebuilt PROPERTY LINK_DEPENDS ${PROJECT_BINARY_DIR}/linker_priv_stacks.cmd) add_dependencies( priv_stacks_prebuilt ${ALIGN_SIZING_DEP} linker_priv_stacks_script offsets) endif() endif() # FIXME: Is there any way to get rid of empty_file.c? add_executable( zephyr_prebuilt misc/empty_file.c) target_link_libraries(zephyr_prebuilt ${TOPT} ${PROJECT_BINARY_DIR}/linker.cmd ${PRIV_STACK_LIB} ${zephyr_lnk} ${CODE_RELOCATION_DEP}) set_property(TARGET zephyr_prebuilt PROPERTY LINK_DEPENDS ${PROJECT_BINARY_DIR}/linker.cmd) add_dependencies( zephyr_prebuilt ${ALIGN_SIZING_DEP} ${PRIV_STACK_DEP} linker_script offsets) if(GKOF OR GKSF) set(logical_target_for_zephyr_elf kernel_elf) # The second linker pass uses the same source linker script of the # first pass (LINKER_SCRIPT), but this time with a different output # file and preprocessed with the define LINKER_PASS2. construct_add_custom_command_for_linker_pass(linker_pass_final custom_command) add_custom_command( ${custom_command} ) add_custom_target( linker_pass_final_script DEPENDS ${ALIGN_SIZING_DEP} ${PRIV_STACK_DEP} ${CODE_RELOCATION_DEP} zephyr_prebuilt linker_pass_final.cmd offsets_h ) set_property(TARGET linker_pass_final_script PROPERTY INCLUDE_DIRECTORIES ${ZEPHYR_INCLUDE_DIRS} ) add_executable( kernel_elf misc/empty_file.c ${GKSF}) target_link_libraries(kernel_elf ${GKOF} ${TOPT} ${PROJECT_BINARY_DIR}/linker_pass_final.cmd ${zephyr_lnk} ${CODE_RELOCATION_DEP}) set_property(TARGET kernel_elf PROPERTY LINK_DEPENDS ${PROJECT_BINARY_DIR}/linker_pass_final.cmd) add_dependencies( kernel_elf ${ALIGN_SIZING_DEP} ${PRIV_STACK_DEP} linker_pass_final_script) else() set(logical_target_for_zephyr_elf zephyr_prebuilt) # Use the prebuilt elf as the final elf since we don't have a # generation stage. endif() # Export the variable to the application's scope to allow the # application to know what the name of the final elf target is. set(logical_target_for_zephyr_elf ${logical_target_for_zephyr_elf} PARENT_SCOPE) # To avoid having the same logical target name for the zephyr lib and # the zephyr elf, we set the kernel_elf file name to zephyr.elf. set_target_properties(${logical_target_for_zephyr_elf} PROPERTIES OUTPUT_NAME ${KERNEL_NAME}) set(post_build_commands "") list_append_ifdef(CONFIG_CHECK_LINK_MAP post_build_commands COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/check_link_map.py ${KERNEL_MAP_NAME} ) if(NOT CONFIG_BUILD_NO_GAP_FILL) # Use ';' as separator to get proper space in resulting command. set(GAP_FILL "--gap-fill;0xff") endif() list_append_ifdef( CONFIG_BUILD_OUTPUT_HEX post_build_commands COMMAND ${CMAKE_OBJCOPY} -S -Oihex ${GAP_FILL} -R .comment -R COMMON -R .eh_frame ${KERNEL_ELF_NAME} ${KERNEL_HEX_NAME} ) list_append_ifdef( CONFIG_BUILD_OUTPUT_BIN post_build_commands COMMAND ${CMAKE_OBJCOPY} -S -Obinary ${GAP_FILL} -R .comment -R COMMON -R .eh_frame ${KERNEL_ELF_NAME} ${KERNEL_BIN_NAME} ) list_append_ifdef( CONFIG_BUILD_OUTPUT_S19 post_build_commands COMMAND ${CMAKE_OBJCOPY} ${GAP_FILL} --srec-len 1 --output-target=srec ${KERNEL_ELF_NAME} ${KERNEL_S19_NAME} ) list_append_ifdef( CONFIG_OUTPUT_DISASSEMBLY post_build_commands COMMAND ${CMAKE_OBJDUMP} -S ${KERNEL_ELF_NAME} > ${KERNEL_LST_NAME} ) list_append_ifdef( CONFIG_OUTPUT_STAT post_build_commands COMMAND ${CMAKE_READELF} -e ${KERNEL_ELF_NAME} > ${KERNEL_STAT_NAME} ) list_append_ifdef( CONFIG_BUILD_OUTPUT_STRIPPED post_build_commands COMMAND ${CMAKE_STRIP} --strip-all ${KERNEL_ELF_NAME} -o ${KERNEL_STRIP_NAME} ) list_append_ifdef( CONFIG_BUILD_OUTPUT_EXE post_build_commands COMMAND ${CMAKE_COMMAND} -E copy ${KERNEL_ELF_NAME} ${KERNEL_EXE_NAME} ) add_custom_command( TARGET ${logical_target_for_zephyr_elf} POST_BUILD ${post_build_commands} COMMENT "Generating files from zephyr.elf for board: ${BOARD}" # NB: COMMENT only works for some CMake-Generators ) # To populate with hex files to merge, do the following: # set_property(GLOBAL APPEND PROPERTY HEX_FILES_TO_MERGE ${my_local_list}) # Note that the zephyr.hex file will not be included automatically. get_property(HEX_FILES_TO_MERGE GLOBAL PROPERTY HEX_FILES_TO_MERGE) if(HEX_FILES_TO_MERGE) # Merge in out-of-tree hex files. set(MERGED_HEX_NAME merged.hex) add_custom_command( OUTPUT ${MERGED_HEX_NAME} COMMAND ${PYTHON_EXECUTABLE} ${ZEPHYR_BASE}/scripts/mergehex.py -o ${MERGED_HEX_NAME} ${HEX_FILES_TO_MERGE} DEPENDS ${HEX_FILES_TO_MERGE} ${logical_target_for_zephyr_elf} ) add_custom_target(mergehex ALL DEPENDS ${MERGED_HEX_NAME}) list(APPEND FLASH_DEPS mergehex) endif() if(CONFIG_OUTPUT_PRINT_MEMORY_USAGE) # Use --print-memory-usage with the first link. # # Don't use this option with the second link because seeing it twice # could confuse users and using it on the second link would suppress # it when the first link has a ram/flash-usage issue. set(option ${LINKERFLAGPREFIX},--print-memory-usage) string(MAKE_C_IDENTIFIER check${option} check) set(SAVED_CMAKE_REQUIRED_FLAGS ${CMAKE_REQUIRED_FLAGS}) set(CMAKE_REQUIRED_FLAGS "${CMAKE_REQUIRED_FLAGS} ${option}") zephyr_check_compiler_flag(C "" ${check}) set(CMAKE_REQUIRED_FLAGS ${SAVED_CMAKE_REQUIRED_FLAGS}) target_link_libraries_ifdef(${check} zephyr_prebuilt ${option}) endif() if(EMU_PLATFORM) include(${ZEPHYR_BASE}/cmake/emu/${EMU_PLATFORM}.cmake) else() add_custom_target(run COMMAND ${CMAKE_COMMAND} -E echo "===================================================" "Emulation/Simulation not supported with this board." "===================================================" ) endif() add_subdirectory(cmake/flash) add_subdirectory(cmake/usage) add_subdirectory(cmake/reports) if(CONFIG_ASSERT AND (NOT CONFIG_FORCE_NO_ASSERT)) message(WARNING " ------------------------------------------------------------ --- WARNING: __ASSERT() statements are globally ENABLED --- --- The kernel will run more slowly and use more memory --- ------------------------------------------------------------" ) endif() if(CONFIG_BOARD_DEPRECATED) message(WARNING " WARNING: The board '${BOARD}' is deprecated and will be removed in version ${CONFIG_BOARD_DEPRECATED}" ) endif() if(CONFIG_X86 AND CONFIG_USERSPACE AND NOT CONFIG_X86_NO_MELTDOWN) message(WARNING " WARNING: You have enabled CONFIG_USERSPACE on an x86-based target. If your CPU is vulnerable to the Meltdown CPU bug, security of supervisor-only memory pages is not guaranteed. This version of Zephyr does not contain a fix for this issue." ) endif()