############################################################################ # tools/Makefile.win # # Licensed to the Apache Software Foundation (ASF) under one or more # contributor license agreements. See the NOTICE file distributed with # this work for additional information regarding copyright ownership. The # ASF licenses this file to you under the Apache License, Version 2.0 (the # "License"); you may not use this file except in compliance with the # License. You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, WITHOUT # WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the # License for the specific language governing permissions and limitations # under the License. # ############################################################################ export SHELL=cmd export TOPDIR := ${shell echo %CD%} include $(TOPDIR)\Make.defs -include $(TOPDIR)\.version # In case .version file does not exist CONFIG_VERSION_STRING ?= "0.0.0" CONFIG_VERSION_MAJOR ?= 0 CONFIG_VERSION_MINOR ?= 0 CONFIG_VERSION_PATCH ?= 0 CONFIG_VERSION_BUILD ?= "0" # Process architecture and board-specific directories ARCH_DIR = arch\$(CONFIG_ARCH) ARCH_SRC = $(ARCH_DIR)\src ARCH_INC = $(ARCH_DIR)\include # CONFIG_APPS_DIR can be over-ridden from the command line or in the .config file. # The default value of CONFIG_APPS_DIR is ..\apps. Ultimately, the application # will be built if APPDIR is defined. APPDIR will be defined if a directory containing # a Makefile is found at the path provided by CONFIG_APPS_DIR ifeq ($(CONFIG_APPS_DIR),) CONFIG_APPS_DIR = ..\apps endif APPDIR := $(realpath ${shell if exist "$(CONFIG_APPS_DIR)\Makefile" echo $(CONFIG_APPS_DIR)}) # External code support # If external/ contains a Kconfig, we define the EXTERNALDIR variable to 'external' # so that main Kconfig can find it. Otherwise, we redirect it to a dummy Kconfig # This is due to kconfig inability to do conditional inclusion. EXTERNALDIR := $(shell if [ -r $(TOPDIR)\external\Kconfig ]; then echo 'external'; else echo '.external-dummy'; fi) # CONTEXTDIRS include directories that have special, one-time pre-build # requirements. Normally this includes things like auto-generation of # configuration specific files or creation of configurable symbolic links # CLEANDIRS are the directories that the clean target will executed in. # These are all directories that we know about. # CCLEANDIRS are directories that the clean_context target will execute in. # The clean_context target "undoes" the actions of the context target. # Only directories known to require cleaning are included. # KERNDEPDIRS are the directories in which we will build target dependencies. # If NuttX and applications are built separately (CONFIG_BUILD_PROTECTED or # CONFIG_BUILD_KERNEL), then this holds only the directories containing # kernel files. # USERDEPDIRS. If NuttX and applications are built separately (CONFIG_BUILD_PROTECTED), # then this holds only the directories containing user files. If # CONFIG_BUILD_KERNEL is selected, then applications are not build at all. include tools\Directories.mk # # Extra objects used in the final link. # # Pass 1 Incremental (relative) link objects should be put into the # processor-specific source directory (where other link objects will # be created). If the pass1 object is an archive, it could go anywhere. ifeq ($(CONFIG_BUILD_2PASS),y) EXTRA_OBJS += $(CONFIG_PASS1_OBJECT) endif # Library build selections # # NUTTXLIBS is the list of NuttX libraries that is passed to the # processor-specific Makefile to build the final NuttX target. # USERLIBS is the list of libraries used to build the final user-space # application # EXPORTLIBS is the list of libraries that should be exported by # 'make export' is ifeq ($(CONFIG_BUILD_PROTECTED),y) include tools\ProtectedLibs.mk else ifeq ($(CONFIG_BUILD_KERNEL),y) include tools\KernelLibs.mk else include tools\FlatLibs.mk endif # LINKLIBS derives from NUTTXLIBS and is simply the same list with the # subdirectory removed LINKLIBS = $(patsubst staging\\%,%,$(NUTTXLIBS)) # Export tool definitions MKEXPORT = tools\mkexport.bat MKEXPORT_ARGS = -t "$(TOPDIR)" ifneq ($(CONFIG_BUILD_FLAT),y) MKEXPORT_ARGS += -u endif ifneq ($(APPDIR),) ifneq ($(shell [ -e $(APPDIR)/Makefile ] && echo yes),) MKEXPORT_ARGS += -a "$(APPDIR)" MKEXPORT_ARGS += -m "$(MAKE)" endif endif ifeq ($(V),2) MKEXPORT_ARGS += -d endif # This is the name of the final target (relative to the top level directory) NUTTXNAME = nuttx BIN = $(NUTTXNAME)$(EXEEXT) all: $(BIN) .PHONY: dirlinks context clean_context configenv config oldconfig menuconfig nconfig export subdir_clean clean subdir_distclean distclean apps_clean apps_distclean .PHONY: pass1 pass1dep .PHONY: pass2 pass2dep # Target used to copy include\nuttx\math.h. If CONFIG_ARCH_MATH_H is # defined, then there is an architecture specific math.h header file # that will be included indirectly from include\math.h. But first, we # have to copy math.h from include\nuttx\. to include\. Logic within # include\nuttx\math.h will hand the redirection to the architecture- # specific math.h header file. # # If the CONFIG_LIBM is defined, the Rhombus libm will be built at libc\math. # Definitions and prototypes for the Rhombus libm are also contained in # include\nuttx\math.h and so the file must also be copied in that case. # # If neither CONFIG_ARCH_MATH_H nor CONFIG_LIBM is defined, then no math.h # header file will be provided. You would want that behavior if (1) you # don't use libm, or (2) you want to use the math.h and libm provided # within your toolchain. ifeq ($(CONFIG_ARCH_MATH_H),y) NEED_MATH_H = y else ifeq ($(CONFIG_LIBM),y) NEED_MATH_H = y endif ifeq ($(NEED_MATH_H),y) include\math.h: include\nuttx\math.h .clean_context $(Q) cp -f include\nuttx\math.h include\math.h else include\math.h: endif # The float.h header file defines the properties of your floating point # implementation. It would always be best to use your toolchain's float.h # header file but if none is available, a default float.h header file will # provided if this option is selected. However there is no assurance that # the settings in this float.h are actually correct for your platform! ifeq ($(CONFIG_ARCH_FLOAT_H),y) include\float.h: include\nuttx\float.h .clean_context $(Q) cp -f include\nuttx\float.h include\float.h else include\float.h: endif # Target used to copy include\nuttx\stdarg.h. If CONFIG_ARCH_STDARG_H is # defined, then there is an architecture specific stdarg.h header file # that will be included indirectly from include\stdarg.h. But first, we # have to copy stdarg.h from include\nuttx\. to include\. ifeq ($(CONFIG_ARCH_STDARG_H),y) include\stdarg.h: include\nuttx\stdarg.h .clean_context $(Q) cp -f include\nuttx\stdarg.h include\stdarg.h else include\stdarg.h: endif # Target used to copy include\nuttx\setjmp.h. If CONFIG_ARCH_SETJMP_H is # defined, then there is an architecture specific setjmp.h header file # that will be included indirectly from include\setjmp.h. But first, we # have to copy setjmp.h from include\nuttx\. to include\. ifeq ($(CONFIG_ARCH_SETJMP_H),y) include\setjmp.h: include\nuttx\setjmp.h .clean_context $(Q) cp -f include\nuttx\setjmp.h include\setjmp.h else include\setjmp.h: endif # Targets used to build include\nuttx\version.h. Creation of version.h is # part of the overall NuttX configuration sequence. Notice that the # tools\mkversion tool is built and used to create include\nuttx\version.h tools\mkversion$(HOSTEXEEXT): $(Q) $(MAKE) -C tools -f Makefile.host mkversion$(HOSTEXEEXT) $(TOPDIR)\.version: $(Q) echo CONFIG_VERSION_STRING="0" > .version $(Q) echo CONFIG_VERSION_MAJOR=0 >> .version $(Q) echo CONFIG_VERSION_MINOR=0 >> .version $(Q) echo CONFIG_VERSION_PATCH=0 >> .version $(Q) echo CONFIG_VERSION_BUILD="0" >> .version include\nuttx\version.h: $(TOPDIR)\.version tools\mkversion$(HOSTEXEEXT) .clean_context $(Q) tools\mkversion$(HOSTEXEEXT) $(TOPDIR) > include\nuttx\version.h # Targets used to build include\nuttx\config.h. Creation of config.h is # part of the overall NuttX configuration sequence. Notice that the # tools\mkconfig tool is built and used to create include\nuttx\config.h tools\mkconfig$(HOSTEXEEXT): $(Q) $(MAKE) -C tools -f Makefile.host mkconfig$(HOSTEXEEXT) include\nuttx\config.h: $(TOPDIR)\.config tools\mkconfig$(HOSTEXEEXT) .clean_context $(Q) tools\mkconfig$(HOSTEXEEXT) $(TOPDIR) > include\nuttx\config.h # Targets used to create dependencies tools\mkdeps$(HOSTEXEEXT): $(Q) $(MAKE) -C tools -f Makefile.host mkdeps$(HOSTEXEEXT) # dirlinks, and helpers # # Directories links. Most of establishing the NuttX configuration involves # setting up symbolic links with 'generic' directory names to specific, # configured directories. # Link the arch\\include directory to include\arch include\arch: .clean_context @echo LN: include\arch to $(ARCH_DIR)\include $(Q) $(DIRLINK) $(TOPDIR)\$(ARCH_DIR)\include include\arch $(Q) touch $@ # Link the boards\\\\include directory to include\arch\board include\arch\board: include\arch @echo LN: include\arch\board to $(BOARD_DIR)\include $(Q) $(DIRLINK) $(BOARD_DIR)\include include\arch\board $(Q) touch $@ ifneq ($(BOARD_COMMON_DIR),) # Link the boards\\\common dir to arch\\src\board # Link the boards\\\\src dir to arch\\src\board\board $(ARCH_SRC)\board: .clean_context @echo "LN: $(ARCH_SRC)\board to $(BOARD_COMMON_DIR)" $(Q) $(DIRLINK) $(BOARD_COMMON_DIR) $(ARCH_SRC)\board @echo "LN: $(ARCH_SRC)\board\board to $(BOARD_DIR)\src" $(Q) $(DIRLINK) $(BOARD_DIR)\src $(ARCH_SRC)\board\board $(Q) touch $@ else # Link the boards\\\\src dir to arch\\src\board $(ARCH_SRC)\board: .clean_context @echo LN: $(ARCH_SRC)\board to $(BOARD_DIR)\src $(Q) $(DIRLINK) $(BOARD_DIR)\src $(ARCH_SRC)\board $(Q) touch $@ endif # Link the boards\\\drivers dir to drivers\platform drivers\platform: .clean_context @echo LN: $(TOPDIR)\drivers\platform to $(BOARD_DRIVERS_DIR) $(Q) $(DIRLINK) $(BOARD_DRIVERS_DIR) $(TOPDIR)\drivers\platform $(Q) touch $@ # Link arch\\src\ to arch\\src\chip $(ARCH_SRC)\chip: .clean_context ifneq ($(CONFIG_ARCH_CHIP),) @echo LN: $(ARCH_SRC)\chip to $(ARCH_SRC)\$(CONFIG_ARCH_CHIP) $(Q) $(DIRLINK) $(TOPDIR)\$(ARCH_SRC)\$(CONFIG_ARCH_CHIP) $(ARCH_SRC)\chip $(Q) touch $@ endif # Link arch\\include\ to arch\\include\chip include\arch\chip: include\arch ifneq ($(CONFIG_ARCH_CHIP),) @echo LN: include\arch\chip to $(ARCH_INC)\$(CONFIG_ARCH_CHIP) $(Q) $(DIRLINK) $(TOPDIR)\$(ARCH_INC)\$(CONFIG_ARCH_CHIP) include\arch\chip $(Q) touch $@ endif dirlinks: include\arch include\arch\board include\arch\chip $(ARCH_SRC)\board $(ARCH_SRC)\chip drivers\platform $(Q) $(MAKE) -C libs/libxx dirlinks $(Q) $(MAKE) -C boards dirlinks $(Q) $(MAKE) -C openamp dirlinks $(Q) $(MAKE) -C $(CONFIG_APPS_DIR) dirlinks # context # # The context target is invoked on each target build to assure that NuttX is # properly configured. The basic configuration steps include creation of the # the config.h and version.h header files in the include\nuttx directory and # the establishment of symbolic links to configured directories. context: include\nuttx\config.h include\nuttx\version.h include\math.h include\float.h include\stdarg.h include\setjmp.h dirlinks $(Q) mkdir -p staging $(Q) for %%G in ($(CONTEXTDIRS)) do ( $(MAKE) -C %%G context ) # clean_context # # This is part of the distclean target. It removes all of the header files # and symbolic links created by the context target. clean_context: $(Q) for %%G in ($(CCLEANDIRS)) do ( if exist %%G\Makefile $(MAKE) -C %%G clean_context ) $(call DELFILE, include\nuttx\config.h) $(call DELFILE, include\nuttx\version.h) $(call DELFILE, include\float.h) $(call DELFILE, include\math.h) $(call DELFILE, include\stdarg.h) $(call DELFILE, include\setjmp.h) .clean_context: .config +$(Q) $(MAKE) clean_context $(Q) touch $@ # Archive targets. The target build sequence will first create a series of # libraries, one per configured source file directory. The final NuttX # execution will then be built from those libraries. The following targets # build those libraries. # pass1 and pass2 # # If the 2 pass build option is selected, then this pass1 target is # configured to built before the pass2 target. This pass1 target may, as an # example, build an extra link object (CONFIG_PASS1_OBJECT) which may be an # incremental (relative) link object, but could be a static library (archive); # some modification to this Makefile would be required if CONFIG_PASS1_OBJECT # is an archive. Exactly what is performed during pass1 or what it generates # is unknown to this makefile unless CONFIG_PASS1_OBJECT is defined. pass1: $(USERLIBS) pass2: $(NUTTXLIBS) # $(BIN) # # Create the final NuttX executable in a two pass build process. In the # normal case, all pass1 and pass2 dependencies are created then pass1 # and pass2 targets are built. However, in some cases, you may need to build # pass1 dependencies and pass1 first, then build pass2 dependencies and pass2. # in that case, execute 'make pass1 pass2' from the command line. $(BIN): pass1 pass2 ifeq ($(CONFIG_BUILD_2PASS),y) $(Q) if [ -z "$(CONFIG_PASS1_BUILDIR)" ]; then \ echo "ERROR: CONFIG_PASS1_BUILDIR not defined"; \ exit 1; \ fi $(Q) if [ ! -d "$(CONFIG_PASS1_BUILDIR)" ]; then \ echo "ERROR: CONFIG_PASS1_BUILDIR does not exist"; \ exit 1; \ fi $(Q) if [ ! -f "$(CONFIG_PASS1_BUILDIR)\Makefile" ]; then \ echo "ERROR: No Makefile in CONFIG_PASS1_BUILDIR"; \ exit 1; \ fi $(Q) $(MAKE) -C $(CONFIG_PASS1_BUILDIR) LINKLIBS="$(LINKLIBS)" USERLIBS="$(USERLIBS)" "$(CONFIG_PASS1_TARGET)" endif $(Q) $(MAKE) -C $(ARCH_SRC) EXTRA_OBJS="$(EXTRA_OBJS)" LINKLIBS="$(LINKLIBS)" EXTRAFLAGS="$(KDEFINE) $(EXTRAFLAGS)" $(BIN) ifeq ($(CONFIG_INTELHEX_BINARY),y) @echo "CP: $(NUTTXNAME).hex" $(Q) $(OBJCOPY) $(OBJCOPYARGS) -O ihex $(BIN) $(NUTTXNAME).hex endif ifeq ($(CONFIG_MOTOROLA_SREC),y) @echo "CP: $(NUTTXNAME).srec" $(Q) $(OBJCOPY) $(OBJCOPYARGS) -O srec $(BIN) $(NUTTXNAME).srec endif ifeq ($(CONFIG_RAW_BINARY),y) @echo "CP: $(NUTTXNAME).bin" $(Q) $(OBJCOPY) $(OBJCOPYARGS) -O binary $(BIN) $(NUTTXNAME).bin endif $(call POSTBUILD, $(TOPDIR)) # download # # This is a helper target that will rebuild NuttX and download it to the target # system in one step. The operation of this target depends completely upon # implementation of the DOWNLOAD command in the user Make.defs file. It will # generate an error an error if the DOWNLOAD command is not defined. download: $(BIN) $(call DOWNLOAD, $<) # pass1dep: Create pass1 build dependencies # pass2dep: Create pass2 build dependencies pass1dep: context tools\mkdeps$(HOSTEXEEXT) $(Q) for %%G in ($(USERDEPDIRS)) do ( $(MAKE) -C %%G depend ) pass2dep: context tools\mkdeps$(HOSTEXEEXT) $(Q) for %%G in ($(KERNDEPDIRS)) do ( $(MAKE) -C %%G EXTRAFLAGS="$(KDEFINE) $(EXTRAFLAGS)" depend ) # Configuration targets # # These targets depend on the kconfig-frontends packages. To use these, you # must first download and install the kconfig-frontends package from this # location: https://bitbucket.org/nuttx/tools/downloads/. See # misc\tools\README.txt for additional information. config: apps_preconfig $(Q) set APPSDIR=$(patsubst "%",%,${CONFIG_APPS_DIR})& set EXTERNALDIR=$(EXTERNALDIR)& kconfig-conf Kconfig oldconfig: apps_preconfig $(Q) set APPSDIR=$(patsubst "%",%,${CONFIG_APPS_DIR})& set EXTERNALDIR=$(EXTERNALDIR)& kconfig-conf --oldconfig Kconfig olddefconfig: apps_preconfig $(Q) set APPSDIR=$(patsubst "%",%,${CONFIG_APPS_DIR})& set EXTERNALDIR=$(EXTERNALDIR)& kconfig-conf --olddefconfig Kconfig menuconfig: configenv apps_preconfig $(Q) set APPSDIR=$(patsubst "%",%,${CONFIG_APPS_DIR})& set EXTERNALDIR=$(EXTERNALDIR)& kconfig-mconf Kconfig nconfig: apps_preconfig $(Q) set APPSDIR=$(patsubst "%",%,${CONFIG_APPS_DIR})& set EXTERNALDIR=$(EXTERNALDIR)& kconfig-nconf Kconfig savedefconfig: apps_preconfig $(Q) set APPSDIR=$(patsubst "%",%,${CONFIG_APPS_DIR})& set EXTERNALDIR=$(EXTERNALDIR)& kconfig-conf --savedefconfig defconfig.tmp Kconfig $(Q) sed -i -e "/CONFIG_APPS_DIR=/d" defconfig.tmp $(Q) grep "CONFIG_ARCH=" .config >> defconfig.tmp -$(Q) grep "^CONFIG_ARCH_CHIP_" .config >> defconfig.tmp -$(Q) grep "CONFIG_ARCH_CHIP=" .config >> defconfig.tmp -$(Q) grep "CONFIG_ARCH_BOARD=" .config >> defconfig.tmp -$(Q) grep "^CONFIG_ARCH_CUSTOM" .config >> defconfig.tmp -$(Q) grep "^CONFIG_ARCH_BOARD_CUSTOM" .config >> defconfig.tmp $(Q) export LC_ALL=C; cat defconfig.tmp | sort | uniq > sortedconfig.tmp $(Q) echo "#" > warning.tmp $(Q) echo "# This file is autogenerated: PLEASE DO NOT EDIT IT." >> warning.tmp $(Q) echo "#" >> warning.tmp $(Q) echo "# You can use \"make menuconfig\" to make any modifications to the installed .config file." >> warning.tmp $(Q) echo "# You can then do \"make savedefconfig\" to generate a new defconfig file that includes your" >> warning.tmp $(Q) echo "# modifications." >> warning.tmp $(Q) echo "#" >> warning.tmp $(Q) cat warning.tmp sortedconfig.tmp > defconfig $(Q) rm -f warning.tmp $(Q) rm -f defconfig.tmp $(Q) rm -f sortedconfig.tmp # export # # The export target will package the NuttX libraries and header files into # an exportable package. Caveats: (1) These needs some extension for the KERNEL # build; it needs to receive USERLIBS and create a libuser.a). (2) The logic # in tools\mkexport.sh only supports GCC and, for example, explicitly assumes # that the archiver is 'ar' export: ${NUTTXLIBS} $(Q) $(MKEXPORT) $(MKEXPORT_ARGS) -l "$(EXPORTLIBS)" # General housekeeping targets: dependencies, cleaning, etc. # # depend: Create both PASS1 and PASS2 dependencies # clean: Removes derived object files, archives, executables, and # temporary files, but retains the configuration and context # files and directories. # distclean: Does 'clean' then also removes all configuration and context # files. This essentially restores the directory structure # to its original, unconfigured stated. depend: pass1dep pass2dep $(foreach SDIR, $(CLEANDIRS), $(eval $(call SDIR_template,$(SDIR),clean))) subdir_clean: $(foreach SDIR, $(CLEANDIRS), $(SDIR)_clean) ifeq ($(CONFIG_BUILD_2PASS),y) $(Q) $(MAKE) -C $(CONFIG_PASS1_BUILDIR) clean endif clean: subdir_clean $(call DELFILE, $(BIN)) $(call DELFILE, nuttx.*) $(call DELFILE, *.map) $(call DELFILE, _SAVED_APPS_config) $(call DELFILE, nuttx-export*) $(call DELFILE, nuttx_user*) $(call DELFILE, .gdbinit) $(call DELDIR, staging) $(call DELFILE, uImage) $(call CLEAN) $(foreach SDIR, $(CLEANDIRS), $(eval $(call SDIR_template,$(SDIR),distclean))) subdir_distclean: $(foreach SDIR, $(CLEANDIRS), $(SDIR)_distclean) distclean: clean subdir_distclean clean_context ifeq ($(CONFIG_BUILD_2PASS),y) $(Q) $(MAKE) -C $(CONFIG_PASS1_BUILDIR) distclean endif $(call DELFILE, Make.defs) $(call DELFILE, defconfig) $(call DELFILE, defconfig.tmp-e) $(call DELFILE, .config) $(call DELFILE, .config.old) $(call DELFILE, .config-e) $(call DELFILE, .clean_context) $(call DIRUNLINK, include\arch\board) $(call DIRUNLINK, include\arch\chip) $(call DIRUNLINK, include\arch) $(call DIRUNLINK, $(ARCH_SRC)\board\board) $(call DIRUNLINK, $(ARCH_SRC)\board) $(call DIRUNLINK, $(ARCH_SRC)\chip) $(call DIRUNLINK, $(TOPDIR)\drivers\platform) $(Q) $(MAKE) -C tools -f Makefile.host clean # Application housekeeping targets. The APPDIR variable refers to the user # application directory. A sample apps\ directory is included with NuttX, # however, this is not treated as part of NuttX and may be replaced with a # different application directory. For the most part, the application # directory is treated like any other build directory in this script. However, # as a convenience, the following targets are included to support housekeeping # functions in the user application directory from the NuttX build directory. # # apps_preconfig: Prepare applications to be configured # apps_clean: Perform the clean operation only in the user application # directory # apps_distclean: Perform the distclean operation only in the user application # directory. apps_preconfig: dirlinks ifneq ($(APPDIR),) $(Q) $(MAKE) -C "$(APPDIR)" preconfig endif apps_clean: ifneq ($(APPDIR),) $(Q) $(MAKE) -C "$(APPDIR)" clean endif apps_distclean: ifneq ($(APPDIR),) $(Q) $(MAKE) -C "$(APPDIR)" distclean endif