AROS Application Development Manual -- The AROS Build SystemAvis This guide has its last major revision begin November 2006. Changes to the build system after this date will not be reflected in this guide. IntroductionPurpose of the AROS build systemOne may wonder why AROS needs a build system. The answer is that it simplifies the building of more complex binaries and takes away a lot of the manual work otherwise needed to compile, link and copy the files. Additionally this system builds a dependency tree over a big source code tree and will build the binaries in the right order so that all dependencies are fulfilled when a certain binary is built. The build system also makes the source code tree modular: you can add or remove certain directories and the build system will adapt to these changes. (Of course, one always has to take care not to delete code other parts still depend upon). Components of the build systemAROS uses several development tools in its build system. A short list of the most important components is:
To illustrate how these tools interact which each other we will explain what happens under the hood when you compile the HelloWorld program given in the previous chapter. If you followed the tutorial for building the program with the build system you first added the local/helloworld directory with some source files; afterwards you called make local/helloworld in the top make directory. During the execution of this command the following steps were taken:
Build system tutorialIn this section a description is given of the most important macros for AROS application development. The purpose is not to give an in-depth discussion but enough information to be able to perform most of the application development needs. An in-depth discussion of the build tools is given in the reference section in this manual. Basic file syntax and set-upAs was seen in the helloworld example above you use the build system by putting a mmakefile.src file in the directory containing your source files. For the AROS build system to notice your file the directory containing it has to be within the AROS main source directory (the name of this top directory is most likely AROS). So for the moment you need to get hold of the AROS source code to be able to use the build system which is discussed in another chapter. A good place to put your own source code is in the AROS/local directory, as was done for the helloworld example. An AROS mmakefile has to start with the following line: include $(SRCDIR)/config/aros.cfg ... The start line will set the environment in the makefile for AROS compilation. It has to be included because this environment is used by the MetaMake macros. After this first line, most of the time one or more calls to a genmf macro will follow. Such a macro has the following syntax: %macro param1=... param2=... ... When the mmakefile.src file is translated into a mmakefile file the line above will be replaced with make commands defined by the macro. A macro is called by it's name followed by zero or more parameters with an optional value assigned to the parameter. The order of the parameters is not important and not all parameters defined by a macro have to get values; a default value will be used when a parameter is not provided. Some parameters may be mandatory and an error message will be generated when it is left out. One macro call can be spread over several lines by ending a line with a backslash and continue the macro on the next line. So the example macro call could have been written also as:
%macro \
param1=... \
param2=... \
...
Normally no spaces are allowed in the values given to a parameter, if that is needed one has to enclose the list by double quotes ("). The following chapters will discuss the more important high level commands. Only the most important parameters for the macros will be treated there; a list and description of all parameters of a macro will be given in the reference section. Building an AROS programYou can build a program by using the following macro in your mmakefile.src file: %build_prog mmake=MetaTarget progname=Prog files=SourceFiles This will build a program named Prog from the list of SourceFiles. By giving the mmake argument the MetaMake program will see that this program can be built by MetaTarget; e.g. doing make MetaTarget in the top AROS source directory will build the program. When typing this command also the dependencies will be built every time you want to recompile this module. Additionally a MetaTarget-quick meta-target will be defined that allows to build the program without the dependencies being rebuilt. This can save time when you are changing the source code of a program and want to rebuild it often. The list of files SourceFiles are the name of the C input files without the .c suffix. As explained above this list has to be enclosed by double quotes if it contains more than one file. By default, the program will have the same file path in the AROS binary tree as its source files had in the source tree. This can be changed by specifying the targetdir=... argument. The latter argument has to contain a full path, so most of the time it will start with $(AROSDIR)/, to put the program somewhere in the binary AROS tree. So, to put the program in the Extras directory you use this: %build_prog ... targetdir=$(AROSDIR)/Extras As explained above the argument to a macro has to be enclosed in quotation marks if it contains more then one file. Currently the list can't be split over more then one line and often make variables are used to pass the list of files to build. The next three examples do the same only with different syntax. First: the in-line list version:
%build_prog \
mmake=myprog progname=MyProg \
files="file1 file2 file3"
Second: Using a make variable:
FILES := file1 file2 file3
%build_prog \
mmake=myprog progname=MyProg \
files=$(FILES)
Third: Using the make line continuation:
FILES := \
file1 \
file2 \
file3
%build_prog \
mmake=myprog progname=MyProg \
files=$(FILES)
Build system referenceAvis This reference manual is out of date and things have changed considerably. Please consult config/make.tmpl in the source code tree to see the current implementation. If you want to help updating this section, please contact us. MetaMakeIntroductionMetaMake is a version of make which allows to recursively build targets in the various directories of a project or even another project. It searches a directory tree for makefiles and all makefiles it finds for "metatargets". Then it tries to build all metatargets. You can also specify a program which converts "source" makefiles into makefiles before MetaMake will invoke make. Syntax of the makefileMetaMake uses normal makefile syntax but gives a special meaning to a comment line that starts with #MM. This line is used to define so called metatargets. The name of the makefile itself is defined in the MetaMake config file that is discussed in one of the following sections. There exist three ways of defining a metatarget in a makefile:
The line for the definition of a metatarget can be spread over several lines if you end every line with the \ character and start the next line with #MM. You can define a metatarget with the same name in several files. The meta-prerequisites are then gathered as if they were in a single entry. If a metatarget is defined both with #MM and #MM- the #MM has priority. How MetaMake worksMetaMake is run by calling make in the root directory of the AROS source tree. At first MetaMake will build up a tree of all the makefiles present in a root directory and all subdirectories. At the same time it will also build a tree of all the metatargets and their dependencies. Next it will build all the meta-prerequisites needed for this metatarget and then finally the metatarget itself. Or viewed differently: every meta-prerequisite is handled as a metatarget when it needs to be build. For each of these metatargets a walk through of all the directories is done. In every makefile where the metatarget is defined by the first or third way from the previous section make is called with the name of the target as a make target. When MetaMake calls normal make also two variables are defined. $(TOP) has the value of the root directory and $(CURDIR) the path relative to this root directory. Metatargets which aren't a prerequisite of another target aren't build by default. If you want to build such a metatarget you have to type make metatarget in the root directory of the AROS source tree. Auto-generated makefilesAnother feature of MetaMake is automatic generating a makefile from a source makefile. When the directory tree is scanned for all the makefiles in every directory it is checked if a makefile is present with a .src suffix added. If it is there and is newer than the makefile present in that directory a script will be called to regenerate the makefile from the source makefile. What script has to be called is defined in the configuration file. ExamplesThe next few examples are taken from the AROS project. Example 1: Normal dependencies#MM contrib-regina-module : setup linklibs includes contrib-regina-includes This example says that in this makefile a contrib-regina-module is exists that has to be built. Before building this metatarget first the metatargets setup, linklibs, ... have to be built; this ensures that the includes, linklibs etc. will be present before this module will be built. Example 2: Metatarget consisting of submetatargets#MM- contrib-freetype : contrib-freetype-linklib \ #MM contrib-freetype-graph \ #MM contrib-freetype-fonts \ #MM contrib-freetype-demos Here, it actually says that the contrib-freetype metatarget requires the building of linklib, graph, fonts and demos of freetype. If some extra work needs to be done in the makefile where this metatarget is, the definition can start with #MM and then a normal make target contrib-freetype should be present in the makefile. Also, the use of the line continuation for the metatarget definition is demonstrated here. Example 3: Quick building of a target#MM workbench-utilities : includes linklibs setup-clock-catalogs #MM workbench-utilities-quick : workbench-utilities Normally, when a user executes MetaMake with as its argument workbench-utilities, make will be called in every the directories where the meta-prerequisites are included in the makefile. This can become quite annoying when debugging programs. If the second metatarget workbench-utilities-quick is defined as shown above, only that target will be build in this directory. Of course, the user has then to be sure that the metatargets on which workbench-utilities depend are up-to-date. Configuration fileThe MetaMake configuration file should have the path $(TOP)/mmake.config. A short explanation of its content:
GenmfIntroductionGenmf uses two files for generating a makefile. The first one is the macro definition file and the second the source makefile (mmakefile.src) where these macros can be used. The macros for AROS are in the file $(TOP)/config/make.tmpl. SyntaxIn general the % character is used as the special character for genmf source makefiles. Macro definitionA macro definition has the following syntax: %define macroname option1[=[default][\A][\M]] option2[=[default][\A][\M]] ... ... %end macroname is the name of the macro. option1, option2, ... are the arguments for the macro. These options can be used in the body of this template by typing %(option1). This will be replaced be the value of option1. The argument can be followed by a default value. If no default value is specified an empty string is taken. Normally no spaces are allowed in the default value of an argument. If this is needed this can be done by surrounding the value with double quotes ("). Also two switches can be added:
Macro instantiationThe instantiation of the macro is done by using the '%' character followed by the name of the macro to instantiate (without round brackets around it): %macro_name [option1=]value [option2=]value Two ways are possible to specify value for arguments to a macro:
When giving values to arguments, again double quotes are required to include spaces in the values of the arguments. Macro instantiation may be used inside the body of a macro, even macros that will only be defined later on in the macro definition file. Note In the definition of the genmf rules sometimes MetaMake variables are used as default variables for an argument (e.g. dflags=%(cflags)). This is not really possible in the definition file but is done by using text that has the same effect. AROS application development macros referenceHigh level mmakefile.src macrosAROS standard MetaMake targetsThe following metatargets are often used as prerequisite:
FIXME: complete Note These mega MetaMake targets were introduced in the beginning of the project. The usage of these metatargets is now considered as deprecated and should be avoided. One should try to use more specific targets for dependencies, e.g. if a certain program uses a certain library one should specify this library as a dependency of this program not all the linklibs by using the linklibs metatarget. Building programsThere are two macros for building programs. One macro %build_progs that will compile every input file to a separate executable and one macro %build_prog that will compile and link all the input files into one executable. Macro %build_progsThis macro will compile and link every input file into a separate executable and has the following definition:
%define build_progs mmake=/A files=/A \
objdir=$(GENDIR)/$(CURDIR) targetdir=$(AROSDIR)/$(CURDIR) \
cflags=$(CFLAGS) dflags=$(BD_CFLAGS$(BDID)) ldflags=$(LDFLAGS) \
uselibs= usehostlibs= usestartup=yes detach=no
With the following arguments:
Macro %build_progThis macro will compile and link the input files into an single executable and has the following definition:
%define build_prog mmake=/A progname=/A files=%(progname) asmfiles= \
objdir=$(GENDIR)/$(CURDIR) targetdir=$(AROSDIR)/$(CURDIR) \
cflags=$(CFLAGS) dflags=$(BD_CFLAGS$(BDID)) ldflags=$(LDFLAGS) \
aflags=$(AFLAFS) uselibs= usehostlibs= usestartup=yes detach=no
With the following arguments:
Common%define common This adds some common stuff to the makefile, like a clean target. The clean target only deletes generated makefiles. Building catalogsThe definition of the macro is as follows: %define build_catalogs mmake=/A name=/A subdir=/A \ catalogs="$(basename $(wildcard *.ct))" source="../strings.h" \ description="$(basename $(wildcard *.cd))" dir=$(AROS_CATALOGS) \ sourcedescription="$(TOOLDIR)/C_h_orig" With the meaning of the arguments as follows:
Example: %build_catalogs mmake=workbench-system-wanderer-tools-info-catalogs \ name=Info subdir=System/System/Wanderer/Tools Building iconsCreates icons. The images must be in PNG or ILBM format. The icon is configured from an additional text file with the name %(iconname).info.src. You can find the documentation of this file in $(TOP)/tools/ilbmtoicon/README The definition of the macro is as follows: %define build_icons mmake=/A icons=/A dir=/A With the meaning of the arguments as follows:
Example: %build_icons mmake=workbench-system-wanderer-tools-newdrawer-icons \ icons=newdrawer dir=$(AROS_WANDERER)/Tools The definition file has the name newdrawer.info.src. Building static link-librariesBuilding link-libraries is straight-forward. A list of files will be compiled or assembled and collected into a link library in a specified target directory. The definition of the macro is as follows: %define build_linklib mmake=/A libname=/A files="$(basename $(wildcard *.c)) \ asmfiles= objs= cflags=$(CFLAGS) dflags=%(cflags) aflags=$(AFLAGS) \ objdir=$(OBJDIR) libdir=$(LIBDIR) With the meaning of the arguments as follows:
Compiling arch- and/or CPU-specific filesIn the previous paragraph the method was explained how a module can be built with the AROS genmf macros. Sometimes someone wants to replace certain files in a module with an implementation only valid for a certain arch or a certain CPU. The macro definitionArch-specific files are handled by the macro called %build_archspecific and it has the following header: %define build_archspecific mainmmake=/A maindir=/A arch=/A files= asmfiles= \ cflags=$(CFLAGS) dflags=%(cflags) aflags=$(AFLAGS) compiler=target The explanation of the argument to this macro:
Code shared by different portsA second macro called %rule_archalias allows to create a virtual architecture. Any code for that virtual architecture can be shared between several other architectures. Most likely this is used for code that uses an API that is shared between several architecture but not all of them. The macro has the following header: %define rule_archalias mainmmake=/A arch=/A alias=/A With the following arguments
Examples
The file $(TOP)/config/make.tmpl contains more macros. See the comments in that file for their usage. AROS portable makefile variablesThe file $(TOP)/config/make.cfg is usually included in all makefiles. It contains a lot of variables which are often used in these makefiles. The most important are the absolute paths for standard directories (e.g. AROS_C) and names for tools (e.g. MMAKE, GENMF). Platform-dependent definitions can be found in:
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