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Linux Kernel的Makefile与Kconfig文件的语法

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https://www.kernel.org/doc/Documentation/kbuild/kconfig-language.txt

Introduction
------------

The configuration database is a collection of configuration options
organized in a tree structure:

    +- Code maturity level options
    |  +- Prompt for development and/or incomplete code/drivers
    +- General setup
    |  +- Networking support
    |  +- System V IPC
    |  +- BSD Process Accounting
    |  +- Sysctl support
    +- Loadable module support
    |  +- Enable loadable module support
    |     +- Set version information on all module symbols
    |     +- Kernel module loader
    +- ...

Every entry has its own dependencies. These dependencies are used
to determine the visibility of an entry. Any child entry is only
visible if its parent entry is also visible.

Menu entries
------------

Most entries define a config option; all other entries help to organize
them. A single configuration option is defined like this:

config MODVERSIONS
    bool "Set version information on all module symbols"
    depends on MODULES
    help
      Usually, modules have to be recompiled whenever you switch to a new
      kernel.  ...

Every line starts with a key word and can be followed by multiple
arguments.  "config" starts a new config entry. The following lines
define attributes for this config option. Attributes can be the type of
the config option, input prompt, dependencies, help text and default
values. A config option can be defined multiple times with the same
name, but every definition can have only a single input prompt and the
type must not conflict.

Menu attributes
---------------

A menu entry can have a number of attributes. Not all of them are
applicable everywhere (see syntax).

- type definition: "bool"/"tristate"/"string"/"hex"/"int"
  Every config option must have a type. There are only two basic types:
  tristate and string; the other types are based on these two. The type
  definition optionally accepts an input prompt, so these two examples
  are equivalent:

    bool "Networking support"
  and
    bool
    prompt "Networking support"

- input prompt: "prompt" <prompt> ["if" <expr>]
  Every menu entry can have at most one prompt, which is used to display
  to the user. Optionally dependencies only for this prompt can be added
  with "if".

- default value: "default" <expr> ["if" <expr>]
  A config option can have any number of default values. If multiple
  default values are visible, only the first defined one is active.
  Default values are not limited to the menu entry where they are
  defined. This means the default can be defined somewhere else or be
  overridden by an earlier definition.
  The default value is only assigned to the config symbol if no other
  value was set by the user (via the input prompt above). If an input
  prompt is visible the default value is presented to the user and can
  be overridden by him.
  Optionally, dependencies only for this default value can be added with
  "if".

- type definition + default value:
    "def_bool"/"def_tristate" <expr> ["if" <expr>]
  This is a shorthand notation for a type definition plus a value.
  Optionally dependencies for this default value can be added with "if".

- dependencies: "depends on" <expr>
  This defines a dependency for this menu entry. If multiple
  dependencies are defined, they are connected with ‘&&‘. Dependencies
  are applied to all other options within this menu entry (which also
  accept an "if" expression), so these two examples are equivalent:

    bool "foo" if BAR
    default y if BAR
  and
    depends on BAR
    bool "foo"
    default y

- reverse dependencies: "select" <symbol> ["if" <expr>]
  While normal dependencies reduce the upper limit of a symbol (see
  below), reverse dependencies can be used to force a lower limit of
  another symbol. The value of the current menu symbol is used as the
  minimal value <symbol> can be set to. If <symbol> is selected multiple
  times, the limit is set to the largest selection.
  Reverse dependencies can only be used with boolean or tristate
  symbols.
  Note:
    select should be used with care. select will force
    a symbol to a value without visiting the dependencies.
    By abusing select you are able to select a symbol FOO even
    if FOO depends on BAR that is not set.
    In general use select only for non-visible symbols
    (no prompts anywhere) and for symbols with no dependencies.
    That will limit the usefulness but on the other hand avoid
    the illegal configurations all over.

- limiting menu display: "visible if" <expr>
  This attribute is only applicable to menu blocks, if the condition is
  false, the menu block is not displayed to the user (the symbols
  contained there can still be selected by other symbols, though). It is
  similar to a conditional "prompt" attribute for individual menu
  entries. Default value of "visible" is true.

- numerical ranges: "range" <symbol> <symbol> ["if" <expr>]
  This allows to limit the range of possible input values for int
  and hex symbols. The user can only input a value which is larger than
  or equal to the first symbol and smaller than or equal to the second
  symbol.

- help text: "help" or "---help---"
  This defines a help text. The end of the help text is determined by
  the indentation level, this means it ends at the first line which has
  a smaller indentation than the first line of the help text.
  "---help---" and "help" do not differ in behaviour, "---help---" is
  used to help visually separate configuration logic from help within
  the file as an aid to developers.

- misc options: "option" <symbol>[=<value>]
  Various less common options can be defined via this option syntax,
  which can modify the behaviour of the menu entry and its config
  symbol. These options are currently possible:

  - "defconfig_list"
    This declares a list of default entries which can be used when
    looking for the default configuration (which is used when the main
    .config doesn‘t exists yet.)

  - "modules"
    This declares the symbol to be used as the MODULES symbol, which
    enables the third modular state for all config symbols.
    At most one symbol may have the "modules" option set.

  - "env"=<value>
    This imports the environment variable into Kconfig. It behaves like
    a default, except that the value comes from the environment, this
    also means that the behaviour when mixing it with normal defaults is
    undefined at this point. The symbol is currently not exported back
    to the build environment (if this is desired, it can be done via
    another symbol).

  - "allnoconfig_y"
    This declares the symbol as one that should have the value y when
    using "allnoconfig". Used for symbols that hide other symbols.

Menu dependencies
-----------------

Dependencies define the visibility of a menu entry and can also reduce
the input range of tristate symbols. The tristate logic used in the
expressions uses one more state than normal boolean logic to express the
module state. Dependency expressions have the following syntax:

<expr> ::= <symbol>                             (1)
           <symbol> ‘=‘ <symbol>                (2)
           <symbol> ‘!=‘ <symbol>               (3)
           ‘(‘ <expr> ‘)‘                       (4)
           ‘!‘ <expr>                           (5)
           <expr> ‘&&‘ <expr>                   (6)
           <expr> ‘||‘ <expr>                   (7)

Expressions are listed in decreasing order of precedence. 

(1) Convert the symbol into an expression. Boolean and tristate symbols
    are simply converted into the respective expression values. All
    other symbol types result in ‘n‘.
(2) If the values of both symbols are equal, it returns ‘y‘,
    otherwise ‘n‘.
(3) If the values of both symbols are equal, it returns ‘n‘,
    otherwise ‘y‘.
(4) Returns the value of the expression. Used to override precedence.
(5) Returns the result of (2-/expr/).
(6) Returns the result of min(/expr/, /expr/).
(7) Returns the result of max(/expr/, /expr/).

An expression can have a value of ‘n‘, ‘m‘ or ‘y‘ (or 0, 1, 2
respectively for calculations). A menu entry becomes visible when its
expression evaluates to ‘m‘ or ‘y‘.

There are two types of symbols: constant and non-constant symbols.
Non-constant symbols are the most common ones and are defined with the
‘config‘ statement. Non-constant symbols consist entirely of alphanumeric
characters or underscores.
Constant symbols are only part of expressions. Constant symbols are
always surrounded by single or double quotes. Within the quote, any
other character is allowed and the quotes can be escaped using ‘\‘.

Menu structure
--------------

The position of a menu entry in the tree is determined in two ways. First
it can be specified explicitly:

menu "Network device support"
    depends on NET

config NETDEVICES
    ...

endmenu

All entries within the "menu" ... "endmenu" block become a submenu of
"Network device support". All subentries inherit the dependencies from
the menu entry, e.g. this means the dependency "NET" is added to the
dependency list of the config option NETDEVICES.

The other way to generate the menu structure is done by analyzing the
dependencies. If a menu entry somehow depends on the previous entry, it
can be made a submenu of it. First, the previous (parent) symbol must
be part of the dependency list and then one of these two conditions
must be true:
- the child entry must become invisible, if the parent is set to ‘n‘
- the child entry must only be visible, if the parent is visible

config MODULES
    bool "Enable loadable module support"

config MODVERSIONS
    bool "Set version information on all module symbols"
    depends on MODULES

comment "module support disabled"
    depends on !MODULES

MODVERSIONS directly depends on MODULES, this means it‘s only visible if
MODULES is different from ‘n‘. The comment on the other hand is always
visible when MODULES is visible (the (empty) dependency of MODULES is
also part of the comment dependencies).


Kconfig syntax
--------------

The configuration file describes a series of menu entries, where every
line starts with a keyword (except help texts). The following keywords
end a menu entry:
- config
- menuconfig
- choice/endchoice
- comment
- menu/endmenu
- if/endif
- source
The first five also start the definition of a menu entry.

config:

    "config" <symbol>
    <config options>

This defines a config symbol <symbol> and accepts any of above
attributes as options.

menuconfig:
    "menuconfig" <symbol>
    <config options>

This is similar to the simple config entry above, but it also gives a
hint to front ends, that all suboptions should be displayed as a
separate list of options.

choices:

    "choice" [symbol]
    <choice options>
    <choice block>
    "endchoice"

This defines a choice group and accepts any of the above attributes as
options. A choice can only be of type bool or tristate, while a boolean
choice only allows a single config entry to be selected, a tristate
choice also allows any number of config entries to be set to ‘m‘. This
can be used if multiple drivers for a single hardware exists and only a
single driver can be compiled/loaded into the kernel, but all drivers
can be compiled as modules.
A choice accepts another option "optional", which allows to set the
choice to ‘n‘ and no entry needs to be selected.
If no [symbol] is associated with a choice, then you can not have multiple
definitions of that choice. If a [symbol] is associated to the choice,
then you may define the same choice (ie. with the same entries) in another
place.

comment:

    "comment" <prompt>
    <comment options>

This defines a comment which is displayed to the user during the
configuration process and is also echoed to the output files. The only
possible options are dependencies.

menu:

    "menu" <prompt>
    <menu options>
    <menu block>
    "endmenu"

This defines a menu block, see "Menu structure" above for more
information. The only possible options are dependencies and "visible"
attributes.

if:

    "if" <expr>
    <if block>
    "endif"

This defines an if block. The dependency expression <expr> is appended
to all enclosed menu entries.

source:

    "source" <prompt>

This reads the specified configuration file. This file is always parsed.

mainmenu:

    "mainmenu" <prompt>

This sets the config program‘s title bar if the config program chooses
to use it. It should be placed at the top of the configuration, before any
other statement.


Kconfig hints
-------------
This is a collection of Kconfig tips, most of which aren‘t obvious at
first glance and most of which have become idioms in several Kconfig
files.

Adding common features and make the usage configurable
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
It is a common idiom to implement a feature/functionality that are
relevant for some architectures but not all.
The recommended way to do so is to use a config variable named HAVE_*
that is defined in a common Kconfig file and selected by the relevant
architectures.
An example is the generic IOMAP functionality.

We would in lib/Kconfig see:

# Generic IOMAP is used to ...
config HAVE_GENERIC_IOMAP

config GENERIC_IOMAP
    depends on HAVE_GENERIC_IOMAP && FOO

And in lib/Makefile we would see:
obj-$(CONFIG_GENERIC_IOMAP) += iomap.o

For each architecture using the generic IOMAP functionality we would see:

config X86
    select ...
    select HAVE_GENERIC_IOMAP
    select ...

Note: we use the existing config option and avoid creating a new
config variable to select HAVE_GENERIC_IOMAP.

Note: the use of the internal config variable HAVE_GENERIC_IOMAP, it is
introduced to overcome the limitation of select which will force a
config option to ‘y‘ no matter the dependencies.
The dependencies are moved to the symbol GENERIC_IOMAP and we avoid the
situation where select forces a symbol equals to ‘y‘.

Build as module only
~~~~~~~~~~~~~~~~~~~~
To restrict a component build to module-only, qualify its config symbol
with "depends on m".  E.g.:

config FOO
    depends on BAR && m

limits FOO to module (=m) or disabled (=n).

 

https://www.kernel.org/doc/Documentation/kbuild/makefiles.txt

Linux Kernel Makefiles

This document describes the Linux kernel Makefiles.

=== Table of Contents

    === 1 Overview
    === 2 Who does what
    === 3 The kbuild files
       --- 3.1 Goal definitions
       --- 3.2 Built-in object goals - obj-y
       --- 3.3 Loadable module goals - obj-m
       --- 3.4 Objects which export symbols
       --- 3.5 Library file goals - lib-y
       --- 3.6 Descending down in directories
       --- 3.7 Compilation flags
       --- 3.8 Command line dependency
       --- 3.9 Dependency tracking
       --- 3.10 Special Rules
       --- 3.11 $(CC) support functions
       --- 3.12 $(LD) support functions

    === 4 Host Program support
       --- 4.1 Simple Host Program
       --- 4.2 Composite Host Programs
       --- 4.3 Defining shared libraries
       --- 4.4 Using C++ for host programs
       --- 4.5 Controlling compiler options for host programs
       --- 4.6 When host programs are actually built
       --- 4.7 Using hostprogs-$(CONFIG_FOO)

    === 5 Kbuild clean infrastructure

    === 6 Architecture Makefiles
       --- 6.1 Set variables to tweak the build to the architecture
       --- 6.2 Add prerequisites to archheaders:
       --- 6.3 Add prerequisites to archprepare:
       --- 6.4 List directories to visit when descending
       --- 6.5 Architecture-specific boot images
       --- 6.6 Building non-kbuild targets
       --- 6.7 Commands useful for building a boot image
       --- 6.8 Custom kbuild commands
       --- 6.9 Preprocessing linker scripts
       --- 6.10 Generic header files

    === 7 Kbuild syntax for exported headers
        --- 7.1 header-y
        --- 7.2 genhdr-y
        --- 7.3 destination-y
        --- 7.4 generic-y

    === 8 Kbuild Variables
    === 9 Makefile language
    === 10 Credits
    === 11 TODO

=== 1 Overview

The Makefiles have five parts:

    Makefile        the top Makefile.
    .config            the kernel configuration file.
    arch/$(ARCH)/Makefile    the arch Makefile.
    scripts/Makefile.*    common rules etc. for all kbuild Makefiles.
    kbuild Makefiles    there are about 500 of these.

The top Makefile reads the .config file, which comes from the kernel
configuration process.

The top Makefile is responsible for building two major products: vmlinux
(the resident kernel image) and modules (any module files).
It builds these goals by recursively descending into the subdirectories of
the kernel source tree.
The list of subdirectories which are visited depends upon the kernel
configuration. The top Makefile textually includes an arch Makefile
with the name arch/$(ARCH)/Makefile. The arch Makefile supplies
architecture-specific information to the top Makefile.

Each subdirectory has a kbuild Makefile which carries out the commands
passed down from above. The kbuild Makefile uses information from the
.config file to construct various file lists used by kbuild to build
any built-in or modular targets.

scripts/Makefile.* contains all the definitions/rules etc. that
are used to build the kernel based on the kbuild makefiles.


=== 2 Who does what

People have four different relationships with the kernel Makefiles.

*Users* are people who build kernels.  These people type commands such as
"make menuconfig" or "make".  They usually do not read or edit
any kernel Makefiles (or any other source files).

*Normal developers* are people who work on features such as device
drivers, file systems, and network protocols.  These people need to
maintain the kbuild Makefiles for the subsystem they are
working on.  In order to do this effectively, they need some overall
knowledge about the kernel Makefiles, plus detailed knowledge about the
public interface for kbuild.

*Arch developers* are people who work on an entire architecture, such
as sparc or ia64.  Arch developers need to know about the arch Makefile
as well as kbuild Makefiles.

*Kbuild developers* are people who work on the kernel build system itself.
These people need to know about all aspects of the kernel Makefiles.

This document is aimed towards normal developers and arch developers.


=== 3 The kbuild files

Most Makefiles within the kernel are kbuild Makefiles that use the
kbuild infrastructure. This chapter introduces the syntax used in the
kbuild makefiles.
The preferred name for the kbuild files are ‘Makefile‘ but ‘Kbuild‘ can
be used and if both a ‘Makefile‘ and a ‘Kbuild‘ file exists, then the ‘Kbuild‘
file will be used.

Section 3.1 "Goal definitions" is a quick intro, further chapters provide
more details, with real examples.

--- 3.1 Goal definitions

    Goal definitions are the main part (heart) of the kbuild Makefile.
    These lines define the files to be built, any special compilation
    options, and any subdirectories to be entered recursively.

    The most simple kbuild makefile contains one line:

    Example:
        obj-y += foo.o

    This tells kbuild that there is one object in that directory, named
    foo.o. foo.o will be built from foo.c or foo.S.

    If foo.o shall be built as a module, the variable obj-m is used.
    Therefore the following pattern is often used:

    Example:
        obj-$(CONFIG_FOO) += foo.o

    $(CONFIG_FOO) evaluates to either y (for built-in) or m (for module).
    If CONFIG_FOO is neither y nor m, then the file will not be compiled
    nor linked.

--- 3.2 Built-in object goals - obj-y

    The kbuild Makefile specifies object files for vmlinux
    in the $(obj-y) lists.  These lists depend on the kernel
    configuration.

    Kbuild compiles all the $(obj-y) files.  It then calls
    "$(LD) -r" to merge these files into one built-in.o file.
    built-in.o is later linked into vmlinux by the parent Makefile.

    The order of files in $(obj-y) is significant.  Duplicates in
    the lists are allowed: the first instance will be linked into
    built-in.o and succeeding instances will be ignored.

    Link order is significant, because certain functions
    (module_init() / __initcall) will be called during boot in the
    order they appear. So keep in mind that changing the link
    order may e.g. change the order in which your SCSI
    controllers are detected, and thus your disks are renumbered.

    Example:
        #drivers/isdn/i4l/Makefile
        # Makefile for the kernel ISDN subsystem and device drivers.
        # Each configuration option enables a list of files.
        obj-$(CONFIG_ISDN_I4L)         += isdn.o
        obj-$(CONFIG_ISDN_PPP_BSDCOMP) += isdn_bsdcomp.o

--- 3.3 Loadable module goals - obj-m

    $(obj-m) specify object files which are built as loadable
    kernel modules.

    A module may be built from one source file or several source
    files. In the case of one source file, the kbuild makefile
    simply adds the file to $(obj-m).

    Example:
        #drivers/isdn/i4l/Makefile
        obj-$(CONFIG_ISDN_PPP_BSDCOMP) += isdn_bsdcomp.o

    Note: In this example $(CONFIG_ISDN_PPP_BSDCOMP) evaluates to ‘m‘

    If a kernel module is built from several source files, you specify
    that you want to build a module in the same way as above; however,
    kbuild needs to know which object files you want to build your
    module from, so you have to tell it by setting a $(<module_name>-y)
    variable.

    Example:
        #drivers/isdn/i4l/Makefile
        obj-$(CONFIG_ISDN_I4L) += isdn.o
        isdn-y := isdn_net_lib.o isdn_v110.o isdn_common.o

    In this example, the module name will be isdn.o. Kbuild will
    compile the objects listed in $(isdn-y) and then run
    "$(LD) -r" on the list of these files to generate isdn.o.

    Due to kbuild recognizing $(<module_name>-y) for composite objects,
    you can use the value of a CONFIG_ symbol to optionally include an
    object file as part of a composite object.

    Example:
        #fs/ext2/Makefile
            obj-$(CONFIG_EXT2_FS) += ext2.o
        ext2-y := balloc.o dir.o file.o ialloc.o inode.o ioctl.o               namei.o super.o symlink.o
            ext2-$(CONFIG_EXT2_FS_XATTR) += xattr.o xattr_user.o                         xattr_trusted.o

    In this example, xattr.o, xattr_user.o and xattr_trusted.o are only
    part of the composite object ext2.o if $(CONFIG_EXT2_FS_XATTR)
    evaluates to ‘y‘.

    Note: Of course, when you are building objects into the kernel,
    the syntax above will also work. So, if you have CONFIG_EXT2_FS=y,
    kbuild will build an ext2.o file for you out of the individual
    parts and then link this into built-in.o, as you would expect.

--- 3.4 Objects which export symbols

    No special notation is required in the makefiles for
    modules exporting symbols.

--- 3.5 Library file goals - lib-y

    Objects listed with obj-* are used for modules, or
    combined in a built-in.o for that specific directory.
    There is also the possibility to list objects that will
    be included in a library, lib.a.
    All objects listed with lib-y are combined in a single
    library for that directory.
    Objects that are listed in obj-y and additionally listed in
    lib-y will not be included in the library, since they will
    be accessible anyway.
    For consistency, objects listed in lib-m will be included in lib.a.

    Note that the same kbuild makefile may list files to be built-in
    and to be part of a library. Therefore the same directory
    may contain both a built-in.o and a lib.a file.

    Example:
        #arch/x86/lib/Makefile
        lib-y    := delay.o

    This will create a library lib.a based on delay.o. For kbuild to
    actually recognize that there is a lib.a being built, the directory
    shall be listed in libs-y.
    See also "6.4 List directories to visit when descending".

    Use of lib-y is normally restricted to lib/ and arch/*/lib.

--- 3.6 Descending down in directories

    A Makefile is only responsible for building objects in its own
    directory. Files in subdirectories should be taken care of by
    Makefiles in these subdirs. The build system will automatically
    invoke make recursively in subdirectories, provided you let it know of
    them.

    To do so, obj-y and obj-m are used.
    ext2 lives in a separate directory, and the Makefile present in fs/
    tells kbuild to descend down using the following assignment.

    Example:
        #fs/Makefile
        obj-$(CONFIG_EXT2_FS) += ext2/

    If CONFIG_EXT2_FS is set to either ‘y‘ (built-in) or ‘m‘ (modular)
    the corresponding obj- variable will be set, and kbuild will descend
    down in the ext2 directory.
    Kbuild only uses this information to decide that it needs to visit
    the directory, it is the Makefile in the subdirectory that
    specifies what is modules and what is built-in.

    It is good practice to use a CONFIG_ variable when assigning directory
    names. This allows kbuild to totally skip the directory if the
    corresponding CONFIG_ option is neither ‘y‘ nor ‘m‘.

--- 3.7 Compilation flags

    ccflags-y, asflags-y and ldflags-y
    These three flags apply only to the kbuild makefile in which they
    are assigned. They are used for all the normal cc, as and ld
    invocations happening during a recursive build.
    Note: Flags with the same behaviour were previously named:
    EXTRA_CFLAGS, EXTRA_AFLAGS and EXTRA_LDFLAGS.
    They are still supported but their usage is deprecated.

    ccflags-y specifies options for compiling with $(CC).

    Example:
        # drivers/acpi/Makefile
        ccflags-y := -Os
        ccflags-$(CONFIG_ACPI_DEBUG) += -DACPI_DEBUG_OUTPUT

    This variable is necessary because the top Makefile owns the
    variable $(KBUILD_CFLAGS) and uses it for compilation flags for the
    entire tree.

    asflags-y specifies options for assembling with $(AS).

    Example:
        #arch/sparc/kernel/Makefile
        asflags-y := -ansi

    ldflags-y specifies options for linking with $(LD).

    Example:
        #arch/cris/boot/compressed/Makefile
        ldflags-y += -T $(srctree)/$(src)/decompress_$(arch-y).lds

    subdir-ccflags-y, subdir-asflags-y
    The two flags listed above are similar to ccflags-y and asflags-y.
    The difference is that the subdir- variants have effect for the kbuild
    file where they are present and all subdirectories.
    Options specified using subdir-* are added to the commandline before
    the options specified using the non-subdir variants.

    Example:
        subdir-ccflags-y := -Werror

    CFLAGS_$@, AFLAGS_$@

    CFLAGS_$@ and AFLAGS_$@ only apply to commands in current
    kbuild makefile.

    $(CFLAGS_$@) specifies per-file options for $(CC).  The $@
    part has a literal value which specifies the file that it is for.

    Example:
        # drivers/scsi/Makefile
        CFLAGS_aha152x.o =   -DAHA152X_STAT -DAUTOCONF
        CFLAGS_gdth.o    = # -DDEBUG_GDTH=2 -D__SERIAL__ -D__COM2__                      -DGDTH_STATISTICS

    These two lines specify compilation flags for aha152x.o and gdth.o.

    $(AFLAGS_$@) is a similar feature for source files in assembly
    languages.

    Example:
        # arch/arm/kernel/Makefile
        AFLAGS_head.o        := -DTEXT_OFFSET=$(TEXT_OFFSET)
        AFLAGS_crunch-bits.o := -Wa,-mcpu=ep9312
        AFLAGS_iwmmxt.o      := -Wa,-mcpu=iwmmxt


--- 3.9 Dependency tracking

    Kbuild tracks dependencies on the following:
    1) All prerequisite files (both *.c and *.h)
    2) CONFIG_ options used in all prerequisite files
    3) Command-line used to compile target

    Thus, if you change an option to $(CC) all affected files will
    be re-compiled.

--- 3.10 Special Rules

    Special rules are used when the kbuild infrastructure does
    not provide the required support. A typical example is
    header files generated during the build process.
    Another example are the architecture-specific Makefiles which
    need special rules to prepare boot images etc.

    Special rules are written as normal Make rules.
    Kbuild is not executing in the directory where the Makefile is
    located, so all special rules shall provide a relative
    path to prerequisite files and target files.

    Two variables are used when defining special rules:

    $(src)
    $(src) is a relative path which points to the directory
    where the Makefile is located. Always use $(src) when
    referring to files located in the src tree.

    $(obj)
    $(obj) is a relative path which points to the directory
    where the target is saved. Always use $(obj) when
    referring to generated files.

    Example:
        #drivers/scsi/Makefile
        $(obj)/53c8xx_d.h: $(src)/53c7,8xx.scr $(src)/script_asm.pl
            $(CPP) -DCHIP=810 - < $< | ... $(src)/script_asm.pl

    This is a special rule, following the normal syntax
    required by make.
    The target file depends on two prerequisite files. References
    to the target file are prefixed with $(obj), references
    to prerequisites are referenced with $(src) (because they are not
    generated files).

    $(kecho)
    echoing information to user in a rule is often a good practice
    but when execution "make -s" one does not expect to see any output
    except for warnings/errors.
    To support this kbuild define $(kecho) which will echo out the
    text following $(kecho) to stdout except if "make -s" is used.

    Example:
        #arch/blackfin/boot/Makefile
        $(obj)/vmImage: $(obj)/vmlinux.gz
            $(call if_changed,uimage)
            @$(kecho) ‘Kernel: $@ is ready‘


--- 3.11 $(CC) support functions

    The kernel may be built with several different versions of
    $(CC), each supporting a unique set of features and options.
    kbuild provide basic support to check for valid options for $(CC).
    $(CC) is usually the gcc compiler, but other alternatives are
    available.

    as-option
    as-option is used to check if $(CC) -- when used to compile
    assembler (*.S) files -- supports the given option. An optional
    second option may be specified if the first option is not supported.

    Example:
        #arch/sh/Makefile
        cflags-y += $(call as-option,-Wa$(comma)-isa=$(isa-y),)

    In the above example, cflags-y will be assigned the option
    -Wa$(comma)-isa=$(isa-y) if it is supported by $(CC).
    The second argument is optional, and if supplied will be used
    if first argument is not supported.

    cc-ldoption
    cc-ldoption is used to check if $(CC) when used to link object files
    supports the given option.  An optional second option may be
    specified if first option are not supported.

    Example:
        #arch/x86/kernel/Makefile
        vsyscall-flags += $(call cc-ldoption, -Wl$(comma)--hash-style=sysv)

    In the above example, vsyscall-flags will be assigned the option
    -Wl$(comma)--hash-style=sysv if it is supported by $(CC).
    The second argument is optional, and if supplied will be used
    if first argument is not supported.

    as-instr
    as-instr checks if the assembler reports a specific instruction
    and then outputs either option1 or option2
    C escapes are supported in the test instruction
    Note: as-instr-option uses KBUILD_AFLAGS for $(AS) options

    cc-option
    cc-option is used to check if $(CC) supports a given option, and not
    supported to use an optional second option.

    Example:
        #arch/x86/Makefile
        cflags-y += $(call cc-option,-march=pentium-mmx,-march=i586)

    In the above example, cflags-y will be assigned the option
    -march=pentium-mmx if supported by $(CC), otherwise -march=i586.
    The second argument to cc-option is optional, and if omitted,
    cflags-y will be assigned no value if first option is not supported.
    Note: cc-option uses KBUILD_CFLAGS for $(CC) options

   cc-option-yn
    cc-option-yn is used to check if gcc supports a given option
    and return ‘y‘ if supported, otherwise ‘n‘.

    Example:
        #arch/ppc/Makefile
        biarch := $(call cc-option-yn, -m32)
        aflags-$(biarch) += -a32
        cflags-$(biarch) += -m32

    In the above example, $(biarch) is set to y if $(CC) supports the -m32
    option. When $(biarch) equals ‘y‘, the expanded variables $(aflags-y)
    and $(cflags-y) will be assigned the values -a32 and -m32,
    respectively.
    Note: cc-option-yn uses KBUILD_CFLAGS for $(CC) options

    cc-option-align
    gcc versions >= 3.0 changed the type of options used to specify
    alignment of functions, loops etc. $(cc-option-align), when used
    as prefix to the align options, will select the right prefix:
    gcc < 3.00
        cc-option-align = -malign
    gcc >= 3.00
        cc-option-align = -falign

    Example:
        KBUILD_CFLAGS += $(cc-option-align)-functions=4

    In the above example, the option -falign-functions=4 is used for
    gcc >= 3.00. For gcc < 3.00, -malign-functions=4 is used.
    Note: cc-option-align uses KBUILD_CFLAGS for $(CC) options

    cc-disable-warning
    cc-disable-warning checks if gcc supports a given warning and returns
    the commandline switch to disable it. This special function is needed,
    because gcc 4.4 and later accept any unknown -Wno-* option and only
    warn about it if there is another warning in the source file.

    Example:
        KBUILD_CFLAGS += $(call cc-disable-warning, unused-but-set-variable)

    In the above example, -Wno-unused-but-set-variable will be added to
    KBUILD_CFLAGS only if gcc really accepts it.

    cc-version
    cc-version returns a numerical version of the $(CC) compiler version.
    The format is <major><minor> where both are two digits. So for example
    gcc 3.41 would return 0341.
    cc-version is useful when a specific $(CC) version is faulty in one
    area, for example -mregparm=3 was broken in some gcc versions
    even though the option was accepted by gcc.

    Example:
        #arch/x86/Makefile
        cflags-y += $(shell         if [ $(call cc-version) -ge 0300 ] ; then \
            echo "-mregparm=3"; fi ;)

    In the above example, -mregparm=3 is only used for gcc version greater
    than or equal to gcc 3.0.

    cc-ifversion
    cc-ifversion tests the version of $(CC) and equals last argument if
    version expression is true.

    Example:
        #fs/reiserfs/Makefile
        ccflags-y := $(call cc-ifversion, -lt, 0402, -O1)

    In this example, ccflags-y will be assigned the value -O1 if the
    $(CC) version is less than 4.2.
    cc-ifversion takes all the shell operators:
    -eq, -ne, -lt, -le, -gt, and -ge
    The third parameter may be a text as in this example, but it may also
    be an expanded variable or a macro.

    cc-fullversion
    cc-fullversion is useful when the exact version of gcc is needed.
    One typical use-case is when a specific GCC version is broken.
    cc-fullversion points out a more specific version than cc-version does.

    Example:
        #arch/powerpc/Makefile
        $(Q)if test "$(call cc-fullversion)" = "040200" ; then \
            echo -n ‘*** GCC-4.2.0 cannot compile the 64-bit powerpc ‘ ; \
            false ; \
        fi

    In this example for a specific GCC version the build will error out explaining
    to the user why it stops.

    cc-cross-prefix
    cc-cross-prefix is used to check if there exists a $(CC) in path with
    one of the listed prefixes. The first prefix where there exist a
    prefix$(CC) in the PATH is returned - and if no prefix$(CC) is found
    then nothing is returned.
    Additional prefixes are separated by a single space in the
    call of cc-cross-prefix.
    This functionality is useful for architecture Makefiles that try
    to set CROSS_COMPILE to well-known values but may have several
    values to select between.
    It is recommended only to try to set CROSS_COMPILE if it is a cross
    build (host arch is different from target arch). And if CROSS_COMPILE
    is already set then leave it with the old value.

    Example:
        #arch/m68k/Makefile
        ifneq ($(SUBARCH),$(ARCH))
                ifeq ($(CROSS_COMPILE),)
                       CROSS_COMPILE := $(call cc-cross-prefix, m68k-linux-gnu-)
            endif
        endif

--- 3.12 $(LD) support functions

    ld-option
    ld-option is used to check if $(LD) supports the supplied option.
    ld-option takes two options as arguments.
    The second argument is an optional option that can be used if the
    first option is not supported by $(LD).

    Example:
        #Makefile
        LDFLAGS_vmlinux += $(call ld-option, -X)


=== 4 Host Program support

Kbuild supports building executables on the host for use during the
compilation stage.
Two steps are required in order to use a host executable.

The first step is to tell kbuild that a host program exists. This is
done utilising the variable hostprogs-y.

The second step is to add an explicit dependency to the executable.
This can be done in two ways. Either add the dependency in a rule,
or utilise the variable $(always).
Both possibilities are described in the following.

--- 4.1 Simple Host Program

    In some cases there is a need to compile and run a program on the
    computer where the build is running.
    The following line tells kbuild that the program bin2hex shall be
    built on the build host.

    Example:
        hostprogs-y := bin2hex

    Kbuild assumes in the above example that bin2hex is made from a single
    c-source file named bin2hex.c located in the same directory as
    the Makefile.

--- 4.2 Composite Host Programs

    Host programs can be made up based on composite objects.
    The syntax used to define composite objects for host programs is
    similar to the syntax used for kernel objects.
    $(<executable>-objs) lists all objects used to link the final
    executable.

    Example:
        #scripts/lxdialog/Makefile
        hostprogs-y   := lxdialog
        lxdialog-objs := checklist.o lxdialog.o

    Objects with extension .o are compiled from the corresponding .c
    files. In the above example, checklist.c is compiled to checklist.o
    and lxdialog.c is compiled to lxdialog.o.
    Finally, the two .o files are linked to the executable, lxdialog.
    Note: The syntax <executable>-y is not permitted for host-programs.

--- 4.3 Defining shared libraries

    Objects with extension .so are considered shared libraries, and
    will be compiled as position independent objects.
    Kbuild provides support for shared libraries, but the usage
    shall be restricted.
    In the following example the libkconfig.so shared library is used
    to link the executable conf.

    Example:
        #scripts/kconfig/Makefile
        hostprogs-y     := conf
        conf-objs       := conf.o libkconfig.so
        libkconfig-objs := expr.o type.o

    Shared libraries always require a corresponding -objs line, and
    in the example above the shared library libkconfig is composed by
    the two objects expr.o and type.o.
    expr.o and type.o will be built as position independent code and
    linked as a shared library libkconfig.so. C++ is not supported for
    shared libraries.

--- 4.4 Using C++ for host programs

    kbuild offers support for host programs written in C++. This was
    introduced solely to support kconfig, and is not recommended
    for general use.

    Example:
        #scripts/kconfig/Makefile
        hostprogs-y   := qconf
        qconf-cxxobjs := qconf.o

    In the example above the executable is composed of the C++ file
    qconf.cc - identified by $(qconf-cxxobjs).

    If qconf is composed by a mixture of .c and .cc files, then an
    additional line can be used to identify this.

    Example:
        #scripts/kconfig/Makefile
        hostprogs-y   := qconf
        qconf-cxxobjs := qconf.o
        qconf-objs    := check.o

--- 4.5 Controlling compiler options for host programs

    When compiling host programs, it is possible to set specific flags.
    The programs will always be compiled utilising $(HOSTCC) passed
    the options specified in $(HOSTCFLAGS).
    To set flags that will take effect for all host programs created
    in that Makefile, use the variable HOST_EXTRACFLAGS.

    Example:
        #scripts/lxdialog/Makefile
        HOST_EXTRACFLAGS += -I/usr/include/ncurses

    To set specific flags for a single file the following construction
    is used:

    Example:
        #arch/ppc64/boot/Makefile
        HOSTCFLAGS_piggyback.o := -DKERNELBASE=$(KERNELBASE)

    It is also possible to specify additional options to the linker.

    Example:
        #scripts/kconfig/Makefile
        HOSTLOADLIBES_qconf := -L$(QTDIR)/lib

    When linking qconf, it will be passed the extra option
    "-L$(QTDIR)/lib".

--- 4.6 When host programs are actually built

    Kbuild will only build host-programs when they are referenced
    as a prerequisite.
    This is possible in two ways:

    (1) List the prerequisite explicitly in a special rule.

    Example:
        #drivers/pci/Makefile
        hostprogs-y := gen-devlist
        $(obj)/devlist.h: $(src)/pci.ids $(obj)/gen-devlist
            ( cd $(obj); ./gen-devlist ) < $<

    The target $(obj)/devlist.h will not be built before
    $(obj)/gen-devlist is updated. Note that references to
    the host programs in special rules must be prefixed with $(obj).

    (2) Use $(always)
    When there is no suitable special rule, and the host program
    shall be built when a makefile is entered, the $(always)
    variable shall be used.

    Example:
        #scripts/lxdialog/Makefile
        hostprogs-y   := lxdialog
        always        := $(hostprogs-y)

    This will tell kbuild to build lxdialog even if not referenced in
    any rule.

--- 4.7 Using hostprogs-$(CONFIG_FOO)

    A typical pattern in a Kbuild file looks like this:

    Example:
        #scripts/Makefile
        hostprogs-$(CONFIG_KALLSYMS) += kallsyms

    Kbuild knows about both ‘y‘ for built-in and ‘m‘ for module.
    So if a config symbol evaluate to ‘m‘, kbuild will still build
    the binary. In other words, Kbuild handles hostprogs-m exactly
    like hostprogs-y. But only hostprogs-y is recommended to be used
    when no CONFIG symbols are involved.

=== 5 Kbuild clean infrastructure

"make clean" deletes most generated files in the obj tree where the kernel
is compiled. This includes generated files such as host programs.
Kbuild knows targets listed in $(hostprogs-y), $(hostprogs-m), $(always),
$(extra-y) and $(targets). They are all deleted during "make clean".
Files matching the patterns "*.[oas]", "*.ko", plus some additional files
generated by kbuild are deleted all over the kernel src tree when
"make clean" is executed.

Additional files can be specified in kbuild makefiles by use of $(clean-files).

    Example:
        #drivers/pci/Makefile
        clean-files := devlist.h classlist.h

When executing "make clean", the two files "devlist.h classlist.h" will
be deleted. Kbuild will assume files to be in same relative directory as the
Makefile except if an absolute path is specified (path starting with ‘/‘).

To delete a directory hierarchy use:

    Example:
        #scripts/package/Makefile
        clean-dirs := $(objtree)/debian/

This will delete the directory debian, including all subdirectories.
Kbuild will assume the directories to be in the same relative path as the
Makefile if no absolute path is specified (path does not start with ‘/‘).

To exclude certain files from make clean, use the $(no-clean-files) variable.
This is only a special case used in the top level Kbuild file:

    Example:
        #Kbuild
        no-clean-files := $(bounds-file) $(offsets-file)

Usually kbuild descends down in subdirectories due to "obj-* := dir/",
but in the architecture makefiles where the kbuild infrastructure
is not sufficient this sometimes needs to be explicit.

    Example:
        #arch/x86/boot/Makefile
        subdir- := compressed/

The above assignment instructs kbuild to descend down in the
directory compressed/ when "make clean" is executed.

To support the clean infrastructure in the Makefiles that builds the
final bootimage there is an optional target named archclean:

    Example:
        #arch/x86/Makefile
        archclean:
            $(Q)$(MAKE) $(clean)=arch/x86/boot

When "make clean" is executed, make will descend down in arch/x86/boot,
and clean as usual. The Makefile located in arch/x86/boot/ may use
the subdir- trick to descend further down.

Note 1: arch/$(ARCH)/Makefile cannot use "subdir-", because that file is
included in the top level makefile, and the kbuild infrastructure
is not operational at that point.

Note 2: All directories listed in core-y, libs-y, drivers-y and net-y will
be visited during "make clean".

=== 6 Architecture Makefiles

The top level Makefile sets up the environment and does the preparation,
before starting to descend down in the individual directories.
The top level makefile contains the generic part, whereas
arch/$(ARCH)/Makefile contains what is required to set up kbuild
for said architecture.
To do so, arch/$(ARCH)/Makefile sets up a number of variables and defines
a few targets.

When kbuild executes, the following steps are followed (roughly):
1) Configuration of the kernel => produce .config
2) Store kernel version in include/linux/version.h
3) Symlink include/asm to include/asm-$(ARCH)
4) Updating all other prerequisites to the target prepare:
   - Additional prerequisites are specified in arch/$(ARCH)/Makefile
5) Recursively descend down in all directories listed in
   init-* core* drivers-* net-* libs-* and build all targets.
   - The values of the above variables are expanded in arch/$(ARCH)/Makefile.
6) All object files are then linked and the resulting file vmlinux is
   located at the root of the obj tree.
   The very first objects linked are listed in head-y, assigned by
   arch/$(ARCH)/Makefile.
7) Finally, the architecture-specific part does any required post processing
   and builds the final bootimage.
   - This includes building boot records
   - Preparing initrd images and the like


--- 6.1 Set variables to tweak the build to the architecture

    LDFLAGS        Generic $(LD) options

    Flags used for all invocations of the linker.
    Often specifying the emulation is sufficient.

    Example:
        #arch/s390/Makefile
        LDFLAGS         := -m elf_s390
    Note: ldflags-y can be used to further customise
    the flags used. See chapter 3.7.

    LDFLAGS_MODULE    Options for $(LD) when linking modules

    LDFLAGS_MODULE is used to set specific flags for $(LD) when
    linking the .ko files used for modules.
    Default is "-r", for relocatable output.

    LDFLAGS_vmlinux    Options for $(LD) when linking vmlinux

    LDFLAGS_vmlinux is used to specify additional flags to pass to
    the linker when linking the final vmlinux image.
    LDFLAGS_vmlinux uses the LDFLAGS_$@ support.

    Example:
        #arch/x86/Makefile
        LDFLAGS_vmlinux := -e stext

    OBJCOPYFLAGS    objcopy flags

    When $(call if_changed,objcopy) is used to translate a .o file,
    the flags specified in OBJCOPYFLAGS will be used.
    $(call if_changed,objcopy) is often used to generate raw binaries on
    vmlinux.

    Example:
        #arch/s390/Makefile
        OBJCOPYFLAGS := -O binary

        #arch/s390/boot/Makefile
        $(obj)/image: vmlinux FORCE
            $(call if_changed,objcopy)

    In this example, the binary $(obj)/image is a binary version of
    vmlinux. The usage of $(call if_changed,xxx) will be described later.

    KBUILD_AFLAGS        $(AS) assembler flags

    Default value - see top level Makefile
    Append or modify as required per architecture.

    Example:
        #arch/sparc64/Makefile
        KBUILD_AFLAGS += -m64 -mcpu=ultrasparc

    KBUILD_CFLAGS        $(CC) compiler flags

    Default value - see top level Makefile
    Append or modify as required per architecture.

    Often, the KBUILD_CFLAGS variable depends on the configuration.

    Example:
        #arch/x86/boot/compressed/Makefile
        cflags-$(CONFIG_X86_32) := -march=i386
        cflags-$(CONFIG_X86_64) := -mcmodel=small
        KBUILD_CFLAGS += $(cflags-y)

    Many arch Makefiles dynamically run the target C compiler to
    probe supported options:

        #arch/x86/Makefile

        ...
        cflags-$(CONFIG_MPENTIUMII)     += $(call cc-option,                        -march=pentium2,-march=i686)
        ...
        # Disable unit-at-a-time mode ...
        KBUILD_CFLAGS += $(call cc-option,-fno-unit-at-a-time)
        ...


    The first example utilises the trick that a config option expands
    to ‘y‘ when selected.

    KBUILD_AFLAGS_KERNEL    $(AS) options specific for built-in

    $(KBUILD_AFLAGS_KERNEL) contains extra C compiler flags used to compile
    resident kernel code.

    KBUILD_AFLAGS_MODULE   Options for $(AS) when building modules

    $(KBUILD_AFLAGS_MODULE) is used to add arch specific options that
    are used for $(AS).
    From commandline AFLAGS_MODULE shall be used (see kbuild.txt).

    KBUILD_CFLAGS_KERNEL    $(CC) options specific for built-in

    $(KBUILD_CFLAGS_KERNEL) contains extra C compiler flags used to compile
    resident kernel code.

    KBUILD_CFLAGS_MODULE   Options for $(CC) when building modules

    $(KBUILD_CFLAGS_MODULE) is used to add arch specific options that
    are used for $(CC).
    From commandline CFLAGS_MODULE shall be used (see kbuild.txt).

    KBUILD_LDFLAGS_MODULE   Options for $(LD) when linking modules

    $(KBUILD_LDFLAGS_MODULE) is used to add arch specific options
    used when linking modules. This is often a linker script.
    From commandline LDFLAGS_MODULE shall be used (see kbuild.txt).

    KBUILD_ARFLAGS   Options for $(AR) when creating archives

    $(KBUILD_ARFLAGS) set by the top level Makefile to "D" (deterministic
    mode) if this option is supported by $(AR).

--- 6.2 Add prerequisites to archheaders:

    The archheaders: rule is used to generate header files that
    may be installed into user space by "make header_install" or
    "make headers_install_all".  In order to support
    "make headers_install_all", this target has to be able to run
    on an unconfigured tree, or a tree configured for another
    architecture.

    It is run before "make archprepare" when run on the
    architecture itself.


--- 6.3 Add prerequisites to archprepare:

    The archprepare: rule is used to list prerequisites that need to be
    built before starting to descend down in the subdirectories.
    This is usually used for header files containing assembler constants.

        Example:
        #arch/arm/Makefile
        archprepare: maketools

    In this example, the file target maketools will be processed
    before descending down in the subdirectories.
    See also chapter XXX-TODO that describe how kbuild supports
    generating offset header files.


--- 6.4 List directories to visit when descending

    An arch Makefile cooperates with the top Makefile to define variables
    which specify how to build the vmlinux file.  Note that there is no
    corresponding arch-specific section for modules; the module-building
    machinery is all architecture-independent.


    head-y, init-y, core-y, libs-y, drivers-y, net-y

    $(head-y) lists objects to be linked first in vmlinux.
    $(libs-y) lists directories where a lib.a archive can be located.
    The rest list directories where a built-in.o object file can be
    located.

    $(init-y) objects will be located after $(head-y).
    Then the rest follows in this order:
    $(core-y), $(libs-y), $(drivers-y) and $(net-y).

    The top level Makefile defines values for all generic directories,
    and arch/$(ARCH)/Makefile only adds architecture-specific directories.

    Example:
        #arch/sparc64/Makefile
        core-y += arch/sparc64/kernel/
        libs-y += arch/sparc64/prom/ arch/sparc64/lib/
        drivers-$(CONFIG_OPROFILE)  += arch/sparc64/oprofile/


--- 6.5 Architecture-specific boot images

    An arch Makefile specifies goals that take the vmlinux file, compress
    it, wrap it in bootstrapping code, and copy the resulting files
    somewhere. This includes various kinds of installation commands.
    The actual goals are not standardized across architectures.

    It is common to locate any additional processing in a boot/
    directory below arch/$(ARCH)/.

    Kbuild does not provide any smart way to support building a
    target specified in boot/. Therefore arch/$(ARCH)/Makefile shall
    call make manually to build a target in boot/.

    The recommended approach is to include shortcuts in
    arch/$(ARCH)/Makefile, and use the full path when calling down
    into the arch/$(ARCH)/boot/Makefile.

    Example:
        #arch/x86/Makefile
        boot := arch/x86/boot
        bzImage: vmlinux
            $(Q)$(MAKE) $(build)=$(boot) $(boot)/$@

    "$(Q)$(MAKE) $(build)=<dir>" is the recommended way to invoke
    make in a subdirectory.

    There are no rules for naming architecture-specific targets,
    but executing "make help" will list all relevant targets.
    To support this, $(archhelp) must be defined.

    Example:
        #arch/x86/Makefile
        define archhelp
          echo  ‘* bzImage      - Image (arch/$(ARCH)/boot/bzImage)‘
        endif

    When make is executed without arguments, the first goal encountered
    will be built. In the top level Makefile the first goal present
    is all:.
    An architecture shall always, per default, build a bootable image.
    In "make help", the default goal is highlighted with a ‘*‘.
    Add a new prerequisite to all: to select a default goal different
    from vmlinux.

    Example:
        #arch/x86/Makefile
        all: bzImage

    When "make" is executed without arguments, bzImage will be built.

--- 6.6 Building non-kbuild targets

    extra-y

    extra-y specify additional targets created in the current
    directory, in addition to any targets specified by obj-*.

    Listing all targets in extra-y is required for two purposes:
    1) Enable kbuild to check changes in command lines
       - When $(call if_changed,xxx) is used
    2) kbuild knows what files to delete during "make clean"

    Example:
        #arch/x86/kernel/Makefile
        extra-y := head.o init_task.o

    In this example, extra-y is used to list object files that
    shall be built, but shall not be linked as part of built-in.o.


--- 6.7 Commands useful for building a boot image

    Kbuild provides a few macros that are useful when building a
    boot image.

    if_changed

    if_changed is the infrastructure used for the following commands.

    Usage:
        target: source(s) FORCE
            $(call if_changed,ld/objcopy/gzip)

    When the rule is evaluated, it is checked to see if any files
    need an update, or the command line has changed since the last
    invocation. The latter will force a rebuild if any options
    to the executable have changed.
    Any target that utilises if_changed must be listed in $(targets),
    otherwise the command line check will fail, and the target will
    always be built.
    Assignments to $(targets) are without $(obj)/ prefix.
    if_changed may be used in conjunction with custom commands as
    defined in 6.8 "Custom kbuild commands".

    Note: It is a typical mistake to forget the FORCE prerequisite.
    Another common pitfall is that whitespace is sometimes
    significant; for instance, the below will fail (note the extra space
    after the comma):
        target: source(s) FORCE
    #WRONG!#    $(call if_changed, ld/objcopy/gzip)

    ld
    Link target. Often, LDFLAGS_$@ is used to set specific options to ld.

    objcopy
    Copy binary. Uses OBJCOPYFLAGS usually specified in
    arch/$(ARCH)/Makefile.
    OBJCOPYFLAGS_$@ may be used to set additional options.

    gzip
    Compress target. Use maximum compression to compress target.

    Example:
        #arch/x86/boot/Makefile
        LDFLAGS_bootsect := -Ttext 0x0 -s --oformat binary
        LDFLAGS_setup    := -Ttext 0x0 -s --oformat binary -e begtext

        targets += setup setup.o bootsect bootsect.o
        $(obj)/setup $(obj)/bootsect: %: %.o FORCE
            $(call if_changed,ld)

    In this example, there are two possible targets, requiring different
    options to the linker. The linker options are specified using the
    LDFLAGS_$@ syntax - one for each potential target.
    $(targets) are assigned all potential targets, by which kbuild knows
    the targets and will:
        1) check for commandline changes
        2) delete target during make clean

    The ": %: %.o" part of the prerequisite is a shorthand that
    free us from listing the setup.o and bootsect.o files.
    Note: It is a common mistake to forget the "target :=" assignment,
          resulting in the target file being recompiled for no
          obvious reason.

    dtc
    Create flattend device tree blob object suitable for linking
    into vmlinux. Device tree blobs linked into vmlinux are placed
    in an init section in the image. Platform code *must* copy the
    blob to non-init memory prior to calling unflatten_device_tree().

    To use this command, simply add *.dtb into obj-y or targets, or make
    some other target depend on %.dtb

    A central rule exists to create $(obj)/%.dtb from $(src)/%.dts;
    architecture Makefiles do no need to explicitly write out that rule.

    Example:
        targets += $(dtb-y)
        clean-files += *.dtb
        DTC_FLAGS ?= -p 1024

    dtc_cpp
    This is just like dtc as describe above, except that the C pre-
    processor is invoked upon the .dtsp file before compiling the result
    with dtc.

    In order for build dependencies to work, all files compiled using
    dtc_cpp must use the C pre-processor‘s #include functionality and not
    dtc‘s /include/ functionality.

    Using the C pre-processor allows use of #define to create named
    constants. In turn, the #defines will typically appear in a header
    file, which may be shared with regular C code. Since the dtc language
    represents a data structure rather than code in C syntax, similar
    restrictions are placed on a header file included by a device tree
    file as for a header file included by an assembly language file.
    In particular, the C pre-processor is passed -x assembler-with-cpp,
    which sets macro __ASSEMBLY__. __DTS__ is also set. These allow header
    files to restrict their content to that compatible with device tree
    source.

    A central rule exists to create $(obj)/%.dtb from $(src)/%.dtsp;
    architecture Makefiles do no need to explicitly write out that rule.

--- 6.8 Custom kbuild commands

    When kbuild is executing with KBUILD_VERBOSE=0, then only a shorthand
    of a command is normally displayed.
    To enable this behaviour for custom commands kbuild requires
    two variables to be set:
    quiet_cmd_<command>    - what shall be echoed
          cmd_<command>    - the command to execute

    Example:
        #
        quiet_cmd_image = BUILD   $@
              cmd_image = $(obj)/tools/build $(BUILDFLAGS)                                              $(obj)/vmlinux.bin > $@

        targets += bzImage
        $(obj)/bzImage: $(obj)/vmlinux.bin $(obj)/tools/build FORCE
            $(call if_changed,image)
            @echo ‘Kernel: $@ is ready‘

    When updating the $(obj)/bzImage target, the line

    BUILD    arch/x86/boot/bzImage

    will be displayed with "make KBUILD_VERBOSE=0".


--- 6.9 Preprocessing linker scripts

    When the vmlinux image is built, the linker script
    arch/$(ARCH)/kernel/vmlinux.lds is used.
    The script is a preprocessed variant of the file vmlinux.lds.S
    located in the same directory.
    kbuild knows .lds files and includes a rule *lds.S -> *lds.

    Example:
        #arch/x86/kernel/Makefile
        always := vmlinux.lds

        #Makefile
        export CPPFLAGS_vmlinux.lds += -P -C -U$(ARCH)

    The assignment to $(always) is used to tell kbuild to build the
    target vmlinux.lds.
    The assignment to $(CPPFLAGS_vmlinux.lds) tells kbuild to use the
    specified options when building the target vmlinux.lds.

    When building the *.lds target, kbuild uses the variables:
    KBUILD_CPPFLAGS    : Set in top-level Makefile
    cppflags-y    : May be set in the kbuild makefile
    CPPFLAGS_$(@F)  : Target specific flags.
                      Note that the full filename is used in this
                      assignment.

    The kbuild infrastructure for *lds file are used in several
    architecture-specific files.

--- 6.10 Generic header files

    The directory include/asm-generic contains the header files
    that may be shared between individual architectures.
    The recommended approach how to use a generic header file is
    to list the file in the Kbuild file.
    See "7.4 generic-y" for further info on syntax etc.

=== 7 Kbuild syntax for exported headers

The kernel include a set of headers that is exported to userspace.
Many headers can be exported as-is but other headers require a
minimal pre-processing before they are ready for user-space.
The pre-processing does:
- drop kernel specific annotations
- drop include of compiler.h
- drop all sections that are kernel internal (guarded by ifdef __KERNEL__)

Each relevant directory contains a file name "Kbuild" which specifies the
headers to be exported.
See subsequent chapter for the syntax of the Kbuild file.

    --- 7.1 header-y

    header-y specify header files to be exported.

        Example:
            #include/linux/Kbuild
            header-y += usb/
            header-y += aio_abi.h

    The convention is to list one file per line and
    preferably in alphabetic order.

    header-y also specify which subdirectories to visit.
    A subdirectory is identified by a trailing ‘/‘ which
    can be seen in the example above for the usb subdirectory.

    Subdirectories are visited before their parent directories.

    --- 7.2 genhdr-y

    genhdr-y specifies generated files to be exported.
    Generated files are special as they need to be looked
    up in another directory when doing ‘make O=...‘ builds.

        Example:
            #include/linux/Kbuild
            genhdr-y += version.h

    --- 7.3 destination-y

    When an architecture have a set of exported headers that needs to be
    exported to a different directory destination-y is used.
    destination-y specify the destination directory for all exported
    headers in the file where it is present.

        Example:
            #arch/xtensa/platforms/s6105/include/platform/Kbuild
            destination-y := include/linux

    In the example above all exported headers in the Kbuild file
    will be located in the directory "include/linux" when exported.

    --- 7.4 generic-y

    If an architecture uses a verbatim copy of a header from
    include/asm-generic then this is listed in the file
    arch/$(ARCH)/include/asm/Kbuild like this:

        Example:
            #arch/x86/include/asm/Kbuild
            generic-y += termios.h
            generic-y += rtc.h

    During the prepare phase of the build a wrapper include
    file is generated in the directory:

        arch/$(ARCH)/include/generated/asm

    When a header is exported where the architecture uses
    the generic header a similar wrapper is generated as part
    of the set of exported headers in the directory:

        usr/include/asm

    The generated wrapper will in both cases look like the following:

        Example: termios.h
            #include <asm-generic/termios.h>

=== 8 Kbuild Variables

The top Makefile exports the following variables:

    VERSION, PATCHLEVEL, SUBLEVEL, EXTRAVERSION

    These variables define the current kernel version.  A few arch
    Makefiles actually use these values directly; they should use
    $(KERNELRELEASE) instead.

    $(VERSION), $(PATCHLEVEL), and $(SUBLEVEL) define the basic
    three-part version number, such as "2", "4", and "0".  These three
    values are always numeric.

    $(EXTRAVERSION) defines an even tinier sublevel for pre-patches
    or additional patches.    It is usually some non-numeric string
    such as "-pre4", and is often blank.

    KERNELRELEASE

    $(KERNELRELEASE) is a single string such as "2.4.0-pre4", suitable
    for constructing installation directory names or showing in
    version strings.  Some arch Makefiles use it for this purpose.

    ARCH

    This variable defines the target architecture, such as "i386",
    "arm", or "sparc". Some kbuild Makefiles test $(ARCH) to
    determine which files to compile.

    By default, the top Makefile sets $(ARCH) to be the same as the
    host system architecture.  For a cross build, a user may
    override the value of $(ARCH) on the command line:

        make ARCH=m68k ...


    INSTALL_PATH

    This variable defines a place for the arch Makefiles to install
    the resident kernel image and System.map file.
    Use this for architecture-specific install targets.

    INSTALL_MOD_PATH, MODLIB

    $(INSTALL_MOD_PATH) specifies a prefix to $(MODLIB) for module
    installation.  This variable is not defined in the Makefile but
    may be passed in by the user if desired.

    $(MODLIB) specifies the directory for module installation.
    The top Makefile defines $(MODLIB) to
    $(INSTALL_MOD_PATH)/lib/modules/$(KERNELRELEASE).  The user may
    override this value on the command line if desired.

    INSTALL_MOD_STRIP

    If this variable is specified, will cause modules to be stripped
    after they are installed.  If INSTALL_MOD_STRIP is ‘1‘, then the
    default option --strip-debug will be used.  Otherwise,
    INSTALL_MOD_STRIP value will be used as the option(s) to the strip
    command.


=== 9 Makefile language

The kernel Makefiles are designed to be run with GNU Make.  The Makefiles
use only the documented features of GNU Make, but they do use many
GNU extensions.

GNU Make supports elementary list-processing functions.  The kernel
Makefiles use a novel style of list building and manipulation with few
"if" statements.

GNU Make has two assignment operators, ":=" and "=".  ":=" performs
immediate evaluation of the right-hand side and stores an actual string
into the left-hand side.  "=" is like a formula definition; it stores the
right-hand side in an unevaluated form and then evaluates this form each
time the left-hand side is used.

There are some cases where "=" is appropriate.  Usually, though, ":="
is the right choice.

=== 10 Credits

Original version made by Michael Elizabeth Chastain, <mailto:mec@shout.net>
Updates by Kai Germaschewski <kai@tp1.ruhr-uni-bochum.de>
Updates by Sam Ravnborg <sam@ravnborg.org>
Language QA by Jan Engelhardt <jengelh@gmx.de>

=== 11 TODO

- Describe how kbuild supports shipped files with _shipped.
- Generating offset header files.
- Add more variables to section 7?

 

 

 

Linux Kernel的Makefile与Kconfig文件的语法,布布扣,bubuko.com

Linux Kernel的Makefile与Kconfig文件的语法

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原文地址:http://www.cnblogs.com/tfanalysis/p/3785186.html

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