docs/devel/build-system.txt - qemu - Git at Google

     The QEMU build system architecture
     ==================================

 This document aims to help developers understand the architecture of the
 QEMU build system. As with projects using GNU autotools, the QEMU build
 system has two stages, first the developer runs the "configure" script
 to determine the local build environment characteristics, then they run
 "make" to build the project. There is about where the similarities with
 GNU autotools end, so try to forget what you know about them.


 Stage 1: configure
 ==================

 The QEMU configure script is written directly in shell, and should be
 compatible with any POSIX shell, hence it uses #!/bin/sh. An important
 implication of this is that it is important to avoid using bash-isms on
 development platforms where bash is the primary host.

 In contrast to autoconf scripts, QEMU's configure is expected to be
 silent while it is checking for features. It will only display output
 when an error occurs, or to show the final feature enablement summary
 on completion.

 Adding new checks to the configure script usually comprises the
 following tasks:

  - Initialize one or more variables with the default feature state.

    Ideally features should auto-detect whether they are present,
    so try to avoid hardcoding the initial state to either enabled
    or disabled, as that forces the user to pass a --enable-XXX
    / --disable-XXX flag on every invocation of configure.

  - Add support to the command line arg parser to handle any new
    --enable-XXX / --disable-XXX flags required by the feature XXX.

  - Add information to the help output message to report on the new
    feature flag.

  - Add code to perform the actual feature check. As noted above, try to
    be fully dynamic in checking enablement/disablement.

  - Add code to print out the feature status in the configure summary
    upon completion.

  - Add any new makefile variables to $config_host_mak on completion.


 Taking (a simplified version of) the probe for gnutls from configure,
 we have the following pieces:

   # Initial variable state
   gnutls=""

   ..snip..

   # Configure flag processing
   --disable-gnutls) gnutls="no"
   ;;
   --enable-gnutls) gnutls="yes"
   ;;

   ..snip..

   # Help output feature message
   gnutls          GNUTLS cryptography support

   ..snip..

   # Test for gnutls
   if test "$gnutls" != "no"; then
      if ! $pkg_config --exists "gnutls"; then
         gnutls_cflags=`$pkg_config --cflags gnutls`
         gnutls_libs=`$pkg_config --libs gnutls`
         libs_softmmu="$gnutls_libs $libs_softmmu"
         libs_tools="$gnutls_libs $libs_tools"
         QEMU_CFLAGS="$QEMU_CFLAGS $gnutls_cflags"
         gnutls="yes"
      elif test "$gnutls" = "yes"; then
         feature_not_found "gnutls" "Install gnutls devel"
      else
         gnutls="no"
      fi
   fi

   ..snip..

   # Completion feature summary
   echo "GNUTLS support    $gnutls"

   ..snip..

   # Define make variables
   if test "$gnutls" = "yes" ; then
      echo "CONFIG_GNUTLS=y" >> $config_host_mak
   fi


 Helper functions
 ----------------

 The configure script provides a variety of helper functions to assist
 developers in checking for system features:

  - do_cc $ARGS...

    Attempt to run the system C compiler passing it $ARGS...

  - do_cxx $ARGS...

    Attempt to run the system C++ compiler passing it $ARGS...

  - compile_object $CFLAGS

    Attempt to compile a test program with the system C compiler using
    $CFLAGS. The test program must have been previously written to a file
    called $TMPC.

  - compile_prog $CFLAGS $LDFLAGS

    Attempt to compile a test program with the system C compiler using
    $CFLAGS and link it with the system linker using $LDFLAGS. The test
    program must have been previously written to a file called $TMPC.

  - has $COMMAND

    Determine if $COMMAND exists in the current environment, either as a
    shell builtin, or executable binary, returning 0 on success.

  - path_of $COMMAND

    Return the fully qualified path of $COMMAND, printing it to stdout,
    and returning 0 on success.

  - check_define $NAME

    Determine if the macro $NAME is defined by the system C compiler

  - check_include $NAME

    Determine if the include $NAME file is available to the system C
    compiler

  - write_c_skeleton

    Write a minimal C program main() function to the temporary file
    indicated by $TMPC

  - feature_not_found $NAME $REMEDY

    Print a message to stderr that the feature $NAME was not available
    on the system, suggesting the user try $REMEDY to address the
    problem.

  - error_exit $MESSAGE $MORE...

    Print $MESSAGE to stderr, followed by $MORE... and then exit from the
    configure script with non-zero status

  - query_pkg_config $ARGS...

    Run pkg-config passing it $ARGS. If QEMU is doing a static build,
    then --static will be automatically added to $ARGS


 Stage 2: makefiles
 ==================

 The use of GNU make is required with the QEMU build system.

 Although the source code is spread across multiple subdirectories, the
 build system should be considered largely non-recursive in nature, in
 contrast to common practices seen with automake. There is some recursive
 invocation of make, but this is related to the things being built,
 rather than the source directory structure.

 QEMU currently supports both VPATH and non-VPATH builds, so there are
 three general ways to invoke configure & perform a build.

  - VPATH, build artifacts outside of QEMU source tree entirely

      cd ../
      mkdir build
      cd build
      ../qemu/configure
      make

  - VPATH, build artifacts in a subdir of QEMU source tree

      mkdir build
      cd build
      ../configure
      make

  - non-VPATH, build artifacts everywhere

      ./configure
      make

 The QEMU maintainers generally recommend that a VPATH build is used by
 developers. Patches to QEMU are expected to ensure VPATH build still
 works.


 Module structure
 ----------------

 There are a number of key outputs of the QEMU build system:

  - Tools - qemu-img, qemu-nbd, qga (guest agent), etc
  - System emulators - qemu-system-$ARCH
  - Userspace emulators - qemu-$ARCH
  - Unit tests

 The source code is highly modularized, split across many files to
 facilitate building of all of these components with as little duplicated
 compilation as possible. There can be considered to be two distinct
 groups of files, those which are independent of the QEMU emulation
 target and those which are dependent on the QEMU emulation target.

 In the target-independent set lives various general purpose helper code,
 such as error handling infrastructure, standard data structures,
 platform portability wrapper functions, etc. This code can be compiled
 once only and the .o files linked into all output binaries.

 In the target-dependent set lives CPU emulation, device emulation and
 much glue code. This sometimes also has to be compiled multiple times,
 once for each target being built.

 The utility code that is used by all binaries is built into a
 static archive called libqemuutil.a, which is then linked to all the
 binaries. In order to provide hooks that are only needed by some of the
 binaries, code in libqemuutil.a may depend on other functions that are
 not fully implemented by all QEMU binaries.  Dummy stubs for all these
 functions are also provided by this library, and will only be linked
 into the binary if the real implementation is not present.  In a way,
 the stubs can be thought of as a portable implementation of the weak
 symbols concept.

 All binaries should link to libqemuutil.a, e.g.:

  qemu-img$(EXESUF): qemu-img.o ..snip.. libqemuutil.a


 Windows platform portability
 ----------------------------

 On Windows, all binaries have the suffix '.exe', so all Makefile rules
 which create binaries must include the $(EXESUF) variable on the binary
 name. e.g.

  qemu-img$(EXESUF): qemu-img.o ..snip..

 This expands to '.exe' on Windows, or '' on other platforms.

 A further complication for the system emulator binaries is that
 two separate binaries need to be generated.

 The main binary (e.g. qemu-system-x86_64.exe) is linked against the
 Windows console runtime subsystem. These are expected to be run from a
 command prompt window, and so will print stderr to the console that
 launched them.

 The second binary generated has a 'w' on the end of its name (e.g.
 qemu-system-x86_64w.exe) and is linked against the Windows graphical
 runtime subsystem. These are expected to be run directly from the
 desktop and will open up a dedicated console window for stderr output.

 The Makefile.target will generate the binary for the graphical subsystem
 first, and then use objcopy to relink it against the console subsystem
 to generate the second binary.


 Object variable naming
 ----------------------

 The QEMU convention is to define variables to list different groups of
 object files. These are named with the convention $PREFIX-obj-y. For
 example the libqemuutil.a file will be linked with all objects listed
 in a variable 'util-obj-y'. So, for example, util/Makefile.obj will
 contain a set of definitions looking like

   util-obj-y += bitmap.o bitops.o hbitmap.o
   util-obj-y += fifo8.o
   util-obj-y += acl.o
   util-obj-y += error.o qemu-error.o

 When there is an object file which needs to be conditionally built based
 on some characteristic of the host system, the configure script will
 define a variable for the conditional. For example, on Windows it will
 define $(CONFIG_POSIX) with a value of 'n' and $(CONFIG_WIN32) with a
 value of 'y'. It is now possible to use the config variables when
 listing object files. For example,

   util-obj-$(CONFIG_WIN32) += oslib-win32.o qemu-thread-win32.o
   util-obj-$(CONFIG_POSIX) += oslib-posix.o qemu-thread-posix.o

 On Windows this expands to

   util-obj-y += oslib-win32.o qemu-thread-win32.o
   util-obj-n += oslib-posix.o qemu-thread-posix.o

 Since libqemutil.a links in $(util-obj-y), the POSIX specific files
 listed against $(util-obj-n) are ignored on the Windows platform builds.


 CFLAGS / LDFLAGS / LIBS handling
 --------------------------------

 There are many different binaries being built with differing purposes,
 and some of them might even be 3rd party libraries pulled in via git
 submodules. As such the use of the global CFLAGS variable is generally
 avoided in QEMU, since it would apply to too many build targets.

 Flags that are needed by any QEMU code (i.e. everything *except* GIT
 submodule projects) are put in $(QEMU_CFLAGS) variable. For linker
 flags the $(LIBS) variable is sometimes used, but a couple of more
 targeted variables are preferred. $(libs_softmmu) is used for
 libraries that must be linked to system emulator targets, $(LIBS_TOOLS)
 is used for tools like qemu-img, qemu-nbd, etc and $(LIBS_QGA) is used
 for the QEMU guest agent. There is currently no specific variable for
 the userspace emulator targets as the global $(LIBS), or more targeted
 variables shown below, are sufficient.

 In addition to these variables, it is possible to provide cflags and
 libs against individual source code files, by defining variables of the
 form $FILENAME-cflags and $FILENAME-libs. For example, the curl block
 driver needs to link to the libcurl library, so block/Makefile defines
 some variables:

   curl.o-cflags      := $(CURL_CFLAGS)
   curl.o-libs        := $(CURL_LIBS)

 The scope is a little different between the two variables. The libs get
 used when linking any target binary that includes the curl.o object
 file, while the cflags get used when compiling the curl.c file only.


 Statically defined files
 ------------------------

 The following key files are statically defined in the source tree, with
 the rules needed to build QEMU. Their behaviour is influenced by a
 number of dynamically created files listed later.

 - Makefile

 The main entry point used when invoking make to build all the components
 of QEMU. The default 'all' target will naturally result in the build of
 every component. The various tools and helper binaries are built
 directly via a non-recursive set of rules.

 Each system/userspace emulation target needs to have a slightly
 different set of make rules / variables. Thus, make will be recursively
 invoked for each of the emulation targets.

 The recursive invocation will end up processing the toplevel
 Makefile.target file (more on that later).


 - */Makefile.objs

 Since the source code is spread across multiple directories, the rules
 for each file are similarly modularized. Thus each subdirectory
 containing .c files will usually also contain a Makefile.objs file.
 These files are not directly invoked by a recursive make, but instead
 they are imported by the top level Makefile and/or Makefile.target

 Each Makefile.objs usually just declares a set of variables listing the
 .o files that need building from the source files in the directory. They
 will also define any custom linker or compiler flags. For example in
 block/Makefile.objs

   block-obj-$(CONFIG_LIBISCSI) += iscsi.o
   block-obj-$(CONFIG_CURL) += curl.o

   ..snip...

   iscsi.o-cflags     := $(LIBISCSI_CFLAGS)
   iscsi.o-libs       := $(LIBISCSI_LIBS)
   curl.o-cflags      := $(CURL_CFLAGS)
   curl.o-libs        := $(CURL_LIBS)

 If there are any rules defined in the Makefile.objs file, they should
 all use $(obj) as a prefix to the target, e.g.

   $(obj)/generated-tcg-tracers.h: $(obj)/generated-tcg-tracers.h-timestamp


 - Makefile.target

 This file provides the entry point used to build each individual system
 or userspace emulator target. Each enabled target has its own
 subdirectory. For example if configure is run with the argument
 '--target-list=x86_64-softmmu', then a sub-directory 'x86_64-softmu'
 will be created, containing a 'Makefile' which symlinks back to
 Makefile.target

 So when the recursive '$(MAKE) -C x86_64-softmmu' is invoked, it ends up
 using Makefile.target for the build rules.


 - rules.mak

 This file provides the generic helper rules for invoking build tools, in
 particular the compiler and linker. This also contains the magic (hairy)
 'unnest-vars' function which is used to merge the variable definitions
 from all Makefile.objs in the source tree down into the main Makefile
 context.


 - default-configs/*.mak

 The files under default-configs/ control what emulated hardware is built
 into each QEMU system and userspace emulator targets. They merely
 contain a long list of config variable definitions. For example,
 default-configs/x86_64-softmmu.mak has:

   include pci.mak
   include sound.mak
   include usb.mak
   CONFIG_QXL=$(CONFIG_SPICE)
   CONFIG_VGA_ISA=y
   CONFIG_VGA_CIRRUS=y
   CONFIG_VMWARE_VGA=y
   CONFIG_VIRTIO_VGA=y
   ...snip...

 These files rarely need changing unless new devices / hardware need to
 be enabled for a particular system/userspace emulation target


 - tests/Makefile

 Rules for building the unit tests. This file is included directly by the
 top level Makefile, so anything defined in this file will influence the
 entire build system. Care needs to be taken when writing rules for tests
 to ensure they only apply to the unit test execution / build.

 - tests/docker/Makefile.include

 Rules for Docker tests. Like tests/Makefile, this file is included
 directly by the top level Makefile, anything defined in this file will
 influence the entire build system.

 - po/Makefile

 Rules for building and installing the binary message catalogs from the
 text .po file sources. This almost never needs changing for any reason.


 Dynamically created files
 -------------------------

 The following files are generated dynamically by configure in order to
 control the behaviour of the statically defined makefiles. This avoids
 the need for QEMU makefiles to go through any pre-processing as seen
 with autotools, where Makefile.am generates Makefile.in which generates
 Makefile.


 - config-host.mak

 When configure has determined the characteristics of the build host it
 will write a long list of variables to config-host.mak file. This
 provides the various install directories, compiler / linker flags and a
 variety of CONFIG_* variables related to optionally enabled features.
 This is imported by the top level Makefile in order to tailor the build
 output.

 The variables defined here are those which are applicable to all QEMU
 build outputs. Variables which are potentially different for each
 emulator target are defined by the next file...

 It is also used as a dependency checking mechanism. If make sees that
 the modification timestamp on configure is newer than that on
 config-host.mak, then configure will be re-run.


 - config-host.h

 The config-host.h file is used by source code to determine what features
 are enabled. It is generated from the contents of config-host.mak using
 the scripts/create_config program. This extracts all the CONFIG_* variables,
 most of the HOST_* variables and a few other misc variables from
 config-host.mak, formatting them as C preprocessor macros.


 - $TARGET-NAME/config-target.mak

 TARGET-NAME is the name of a system or userspace emulator, for example,
 x86_64-softmmu denotes the system emulator for the x86_64 architecture.
 This file contains the variables which need to vary on a per-target
 basis. For example, it will indicate whether KVM or Xen are enabled for
 the target and any other potential custom libraries needed for linking
 the target.


 - $TARGET-NAME/config-devices.mak

 TARGET-NAME is again the name of a system or userspace emulator. The
 config-devices.mak file is automatically generated by make using the
 scripts/make_device_config.sh program, feeding it the
 default-configs/$TARGET-NAME file as input.


 - $TARGET-NAME/Makefile

 This is the entrypoint used when make recurses to build a single system
 or userspace emulator target. It is merely a symlink back to the
 Makefile.target in the top level.


 Useful make targets
 ===================

 - help

   Print a help message for the most common build targets.

 - print-VAR

   Print the value of the variable VAR. Useful for debugging the build
   system.
	The QEMU build system architecture
	==================================

	This document aims to help developers understand the architecture of the
	QEMU build system. As with projects using GNU autotools, the QEMU build
	system has two stages, first the developer runs the "configure" script
	to determine the local build environment characteristics, then they run
	"make" to build the project. There is about where the similarities with
	GNU autotools end, so try to forget what you know about them.


	Stage 1: configure
	==================

	The QEMU configure script is written directly in shell, and should be
	compatible with any POSIX shell, hence it uses #!/bin/sh. An important
	implication of this is that it is important to avoid using bash-isms on
	development platforms where bash is the primary host.

	In contrast to autoconf scripts, QEMU's configure is expected to be
	silent while it is checking for features. It will only display output
	when an error occurs, or to show the final feature enablement summary
	on completion.

	Adding new checks to the configure script usually comprises the
	following tasks:

	- Initialize one or more variables with the default feature state.

	Ideally features should auto-detect whether they are present,
	so try to avoid hardcoding the initial state to either enabled
	or disabled, as that forces the user to pass a --enable-XXX
	/ --disable-XXX flag on every invocation of configure.

	- Add support to the command line arg parser to handle any new
	--enable-XXX / --disable-XXX flags required by the feature XXX.

	- Add information to the help output message to report on the new
	feature flag.

	- Add code to perform the actual feature check. As noted above, try to
	be fully dynamic in checking enablement/disablement.

	- Add code to print out the feature status in the configure summary
	upon completion.

	- Add any new makefile variables to $config_host_mak on completion.


	Taking (a simplified version of) the probe for gnutls from configure,
	we have the following pieces:

	# Initial variable state
	gnutls=""

	..snip..

	# Configure flag processing
	--disable-gnutls) gnutls="no"
	;;
	--enable-gnutls) gnutls="yes"
	;;

	..snip..

	# Help output feature message
	gnutls GNUTLS cryptography support

	..snip..

	# Test for gnutls
	if test "$gnutls" != "no"; then
	if ! $pkg_config --exists "gnutls"; then
	gnutls_cflags=`$pkg_config --cflags gnutls`
	gnutls_libs=`$pkg_config --libs gnutls`
	libs_softmmu="$gnutls_libs $libs_softmmu"
	libs_tools="$gnutls_libs $libs_tools"
	QEMU_CFLAGS="$QEMU_CFLAGS $gnutls_cflags"
	gnutls="yes"
	elif test "$gnutls" = "yes"; then
	feature_not_found "gnutls" "Install gnutls devel"
	else
	gnutls="no"
	fi
	fi

	..snip..

	# Completion feature summary
	echo "GNUTLS support $gnutls"

	..snip..

	# Define make variables
	if test "$gnutls" = "yes" ; then
	echo "CONFIG_GNUTLS=y" >> $config_host_mak
	fi


	Helper functions
	----------------

	The configure script provides a variety of helper functions to assist
	developers in checking for system features:

	- do_cc $ARGS...

	Attempt to run the system C compiler passing it $ARGS...

	- do_cxx $ARGS...

	Attempt to run the system C++ compiler passing it $ARGS...

	- compile_object $CFLAGS

	Attempt to compile a test program with the system C compiler using
	$CFLAGS. The test program must have been previously written to a file
	called $TMPC.

	- compile_prog $CFLAGS $LDFLAGS

	Attempt to compile a test program with the system C compiler using
	$CFLAGS and link it with the system linker using $LDFLAGS. The test
	program must have been previously written to a file called $TMPC.

	- has $COMMAND

	Determine if $COMMAND exists in the current environment, either as a
	shell builtin, or executable binary, returning 0 on success.

	- path_of $COMMAND

	Return the fully qualified path of $COMMAND, printing it to stdout,
	and returning 0 on success.

	- check_define $NAME

	Determine if the macro $NAME is defined by the system C compiler

	- check_include $NAME

	Determine if the include $NAME file is available to the system C
	compiler

	- write_c_skeleton

	Write a minimal C program main() function to the temporary file
	indicated by $TMPC

	- feature_not_found $NAME $REMEDY

	Print a message to stderr that the feature $NAME was not available
	on the system, suggesting the user try $REMEDY to address the
	problem.

	- error_exit $MESSAGE $MORE...

	Print $MESSAGE to stderr, followed by $MORE... and then exit from the
	configure script with non-zero status

	- query_pkg_config $ARGS...

	Run pkg-config passing it $ARGS. If QEMU is doing a static build,
	then --static will be automatically added to $ARGS


	Stage 2: makefiles
	==================

	The use of GNU make is required with the QEMU build system.

	Although the source code is spread across multiple subdirectories, the
	build system should be considered largely non-recursive in nature, in
	contrast to common practices seen with automake. There is some recursive
	invocation of make, but this is related to the things being built,
	rather than the source directory structure.

	QEMU currently supports both VPATH and non-VPATH builds, so there are
	three general ways to invoke configure & perform a build.

	- VPATH, build artifacts outside of QEMU source tree entirely

	cd ../
	mkdir build
	cd build
	../qemu/configure
	make

	- VPATH, build artifacts in a subdir of QEMU source tree

	mkdir build
	cd build
	../configure
	make

	- non-VPATH, build artifacts everywhere

	./configure
	make

	The QEMU maintainers generally recommend that a VPATH build is used by
	developers. Patches to QEMU are expected to ensure VPATH build still
	works.


	Module structure
	----------------

	There are a number of key outputs of the QEMU build system:

	- Tools - qemu-img, qemu-nbd, qga (guest agent), etc
	- System emulators - qemu-system-$ARCH
	- Userspace emulators - qemu-$ARCH
	- Unit tests

	The source code is highly modularized, split across many files to
	facilitate building of all of these components with as little duplicated
	compilation as possible. There can be considered to be two distinct
	groups of files, those which are independent of the QEMU emulation
	target and those which are dependent on the QEMU emulation target.

	In the target-independent set lives various general purpose helper code,
	such as error handling infrastructure, standard data structures,
	platform portability wrapper functions, etc. This code can be compiled
	once only and the .o files linked into all output binaries.

	In the target-dependent set lives CPU emulation, device emulation and
	much glue code. This sometimes also has to be compiled multiple times,
	once for each target being built.

	The utility code that is used by all binaries is built into a
	static archive called libqemuutil.a, which is then linked to all the
	binaries. In order to provide hooks that are only needed by some of the
	binaries, code in libqemuutil.a may depend on other functions that are
	not fully implemented by all QEMU binaries. Dummy stubs for all these
	functions are also provided by this library, and will only be linked
	into the binary if the real implementation is not present. In a way,
	the stubs can be thought of as a portable implementation of the weak
	symbols concept.

	All binaries should link to libqemuutil.a, e.g.:

	qemu-img$(EXESUF): qemu-img.o ..snip.. libqemuutil.a


	Windows platform portability
	----------------------------

	On Windows, all binaries have the suffix '.exe', so all Makefile rules
	which create binaries must include the $(EXESUF) variable on the binary
	name. e.g.

	qemu-img$(EXESUF): qemu-img.o ..snip..

	This expands to '.exe' on Windows, or '' on other platforms.

	A further complication for the system emulator binaries is that
	two separate binaries need to be generated.

	The main binary (e.g. qemu-system-x86_64.exe) is linked against the
	Windows console runtime subsystem. These are expected to be run from a
	command prompt window, and so will print stderr to the console that
	launched them.

	The second binary generated has a 'w' on the end of its name (e.g.
	qemu-system-x86_64w.exe) and is linked against the Windows graphical
	runtime subsystem. These are expected to be run directly from the
	desktop and will open up a dedicated console window for stderr output.

	The Makefile.target will generate the binary for the graphical subsystem
	first, and then use objcopy to relink it against the console subsystem
	to generate the second binary.


	Object variable naming
	----------------------

	The QEMU convention is to define variables to list different groups of
	object files. These are named with the convention $PREFIX-obj-y. For
	example the libqemuutil.a file will be linked with all objects listed
	in a variable 'util-obj-y'. So, for example, util/Makefile.obj will
	contain a set of definitions looking like

	util-obj-y += bitmap.o bitops.o hbitmap.o
	util-obj-y += fifo8.o
	util-obj-y += acl.o
	util-obj-y += error.o qemu-error.o

	When there is an object file which needs to be conditionally built based
	on some characteristic of the host system, the configure script will
	define a variable for the conditional. For example, on Windows it will
	define $(CONFIG_POSIX) with a value of 'n' and $(CONFIG_WIN32) with a
	value of 'y'. It is now possible to use the config variables when
	listing object files. For example,

	util-obj-$(CONFIG_WIN32) += oslib-win32.o qemu-thread-win32.o
	util-obj-$(CONFIG_POSIX) += oslib-posix.o qemu-thread-posix.o

	On Windows this expands to

	util-obj-y += oslib-win32.o qemu-thread-win32.o
	util-obj-n += oslib-posix.o qemu-thread-posix.o

	Since libqemutil.a links in $(util-obj-y), the POSIX specific files
	listed against $(util-obj-n) are ignored on the Windows platform builds.


	CFLAGS / LDFLAGS / LIBS handling
	--------------------------------

	There are many different binaries being built with differing purposes,
	and some of them might even be 3rd party libraries pulled in via git
	submodules. As such the use of the global CFLAGS variable is generally
	avoided in QEMU, since it would apply to too many build targets.

	Flags that are needed by any QEMU code (i.e. everything except GIT
	submodule projects) are put in $(QEMU_CFLAGS) variable. For linker
	flags the $(LIBS) variable is sometimes used, but a couple of more
	targeted variables are preferred. $(libs_softmmu) is used for
	libraries that must be linked to system emulator targets, $(LIBS_TOOLS)
	is used for tools like qemu-img, qemu-nbd, etc and $(LIBS_QGA) is used
	for the QEMU guest agent. There is currently no specific variable for
	the userspace emulator targets as the global $(LIBS), or more targeted
	variables shown below, are sufficient.

	In addition to these variables, it is possible to provide cflags and
	libs against individual source code files, by defining variables of the
	form $FILENAME-cflags and $FILENAME-libs. For example, the curl block
	driver needs to link to the libcurl library, so block/Makefile defines
	some variables:

	curl.o-cflags := $(CURL_CFLAGS)
	curl.o-libs := $(CURL_LIBS)

	The scope is a little different between the two variables. The libs get
	used when linking any target binary that includes the curl.o object
	file, while the cflags get used when compiling the curl.c file only.


	Statically defined files
	------------------------

	The following key files are statically defined in the source tree, with
	the rules needed to build QEMU. Their behaviour is influenced by a
	number of dynamically created files listed later.

	- Makefile

	The main entry point used when invoking make to build all the components
	of QEMU. The default 'all' target will naturally result in the build of
	every component. The various tools and helper binaries are built
	directly via a non-recursive set of rules.

	Each system/userspace emulation target needs to have a slightly
	different set of make rules / variables. Thus, make will be recursively
	invoked for each of the emulation targets.

	The recursive invocation will end up processing the toplevel
	Makefile.target file (more on that later).


	- */Makefile.objs

	Since the source code is spread across multiple directories, the rules
	for each file are similarly modularized. Thus each subdirectory
	containing .c files will usually also contain a Makefile.objs file.
	These files are not directly invoked by a recursive make, but instead
	they are imported by the top level Makefile and/or Makefile.target

	Each Makefile.objs usually just declares a set of variables listing the
	.o files that need building from the source files in the directory. They
	will also define any custom linker or compiler flags. For example in
	block/Makefile.objs

	block-obj-$(CONFIG_LIBISCSI) += iscsi.o
	block-obj-$(CONFIG_CURL) += curl.o

	..snip...

	iscsi.o-cflags := $(LIBISCSI_CFLAGS)
	iscsi.o-libs := $(LIBISCSI_LIBS)
	curl.o-cflags := $(CURL_CFLAGS)
	curl.o-libs := $(CURL_LIBS)

	If there are any rules defined in the Makefile.objs file, they should
	all use $(obj) as a prefix to the target, e.g.

	$(obj)/generated-tcg-tracers.h: $(obj)/generated-tcg-tracers.h-timestamp


	- Makefile.target

	This file provides the entry point used to build each individual system
	or userspace emulator target. Each enabled target has its own
	subdirectory. For example if configure is run with the argument
	'--target-list=x86_64-softmmu', then a sub-directory 'x86_64-softmu'
	will be created, containing a 'Makefile' which symlinks back to
	Makefile.target

	So when the recursive '$(MAKE) -C x86_64-softmmu' is invoked, it ends up
	using Makefile.target for the build rules.


	- rules.mak

	This file provides the generic helper rules for invoking build tools, in
	particular the compiler and linker. This also contains the magic (hairy)
	'unnest-vars' function which is used to merge the variable definitions
	from all Makefile.objs in the source tree down into the main Makefile
	context.


	- default-configs/*.mak

	The files under default-configs/ control what emulated hardware is built
	into each QEMU system and userspace emulator targets. They merely
	contain a long list of config variable definitions. For example,
	default-configs/x86_64-softmmu.mak has:

	include pci.mak
	include sound.mak
	include usb.mak
	CONFIG_QXL=$(CONFIG_SPICE)
	CONFIG_VGA_ISA=y
	CONFIG_VGA_CIRRUS=y
	CONFIG_VMWARE_VGA=y
	CONFIG_VIRTIO_VGA=y
	...snip...

	These files rarely need changing unless new devices / hardware need to
	be enabled for a particular system/userspace emulation target


	- tests/Makefile

	Rules for building the unit tests. This file is included directly by the
	top level Makefile, so anything defined in this file will influence the
	entire build system. Care needs to be taken when writing rules for tests
	to ensure they only apply to the unit test execution / build.

	- tests/docker/Makefile.include

	Rules for Docker tests. Like tests/Makefile, this file is included
	directly by the top level Makefile, anything defined in this file will
	influence the entire build system.

	- po/Makefile

	Rules for building and installing the binary message catalogs from the
	text .po file sources. This almost never needs changing for any reason.


	Dynamically created files
	-------------------------

	The following files are generated dynamically by configure in order to
	control the behaviour of the statically defined makefiles. This avoids
	the need for QEMU makefiles to go through any pre-processing as seen
	with autotools, where Makefile.am generates Makefile.in which generates
	Makefile.


	- config-host.mak

	When configure has determined the characteristics of the build host it
	will write a long list of variables to config-host.mak file. This
	provides the various install directories, compiler / linker flags and a
	variety of CONFIG_* variables related to optionally enabled features.
	This is imported by the top level Makefile in order to tailor the build
	output.

	The variables defined here are those which are applicable to all QEMU
	build outputs. Variables which are potentially different for each
	emulator target are defined by the next file...

	It is also used as a dependency checking mechanism. If make sees that
	the modification timestamp on configure is newer than that on
	config-host.mak, then configure will be re-run.


	- config-host.h

	The config-host.h file is used by source code to determine what features
	are enabled. It is generated from the contents of config-host.mak using
	the scripts/create_config program. This extracts all the CONFIG_* variables,
	most of the HOST_* variables and a few other misc variables from
	config-host.mak, formatting them as C preprocessor macros.


	- $TARGET-NAME/config-target.mak

	TARGET-NAME is the name of a system or userspace emulator, for example,
	x86_64-softmmu denotes the system emulator for the x86_64 architecture.
	This file contains the variables which need to vary on a per-target
	basis. For example, it will indicate whether KVM or Xen are enabled for
	the target and any other potential custom libraries needed for linking
	the target.


	- $TARGET-NAME/config-devices.mak

	TARGET-NAME is again the name of a system or userspace emulator. The
	config-devices.mak file is automatically generated by make using the
	scripts/make_device_config.sh program, feeding it the
	default-configs/$TARGET-NAME file as input.


	- $TARGET-NAME/Makefile

	This is the entrypoint used when make recurses to build a single system
	or userspace emulator target. It is merely a symlink back to the
	Makefile.target in the top level.


	Useful make targets
	===================

	- help

	Print a help message for the most common build targets.

	- print-VAR

	Print the value of the variable VAR. Useful for debugging the build
	system.