2 In this document you will find information about:
3 - how to build external modules
4 - how to make your module use the kbuild infrastructure
5 - how kbuild will install a kernel
6 - how to install modules in a non-standard location
11 === 2 How to build external modules
12 --- 2.1 Building external modules
13 --- 2.2 Available targets
14 --- 2.3 Available options
15 --- 2.4 Preparing the kernel tree for module build
16 --- 2.5 Building separate files for a module
17 === 3. Example commands
18 === 4. Creating a kbuild file for an external module
20 --- 5.1 How to include files from the kernel include dir
21 --- 5.2 External modules using an include/ dir
22 --- 5.3 External modules using several directories
23 === 6. Module installation
24 --- 6.1 INSTALL_MOD_PATH
25 --- 6.2 INSTALL_MOD_DIR
26 === 7. Module versioning & Module.symvers
27 --- 7.1 Symbols from the kernel (vmlinux + modules)
28 --- 7.2 Symbols and external modules
29 --- 7.3 Symbols from another external module
31 --- 8.1 Testing for CONFIG_FOO_BAR
37 kbuild includes functionality for building modules both
38 within the kernel source tree and outside the kernel source tree.
39 The latter is usually referred to as external or "out-of-tree"
40 modules and is used both during development and for modules that
41 are not planned to be included in the kernel tree.
43 What is covered within this file is mainly information to authors
44 of modules. The author of an external module should supply
45 a makefile that hides most of the complexity, so one only has to type
46 'make' to build the module. A complete example will be presented in
47 chapter 4, "Creating a kbuild file for an external module".
50 === 2. How to build external modules
52 kbuild offers functionality to build external modules, with the
53 prerequisite that there is a pre-built kernel available with full source.
54 A subset of the targets available when building the kernel is available
55 when building an external module.
57 --- 2.1 Building external modules
59 Use the following command to build an external module:
61 make -C <path-to-kernel> M=`pwd`
63 For the running kernel use:
65 make -C /lib/modules/`uname -r`/build M=`pwd`
67 For the above command to succeed, the kernel must have been
68 built with modules enabled.
70 To install the modules that were just built:
72 make -C <path-to-kernel> M=`pwd` modules_install
74 More complex examples will be shown later, the above should
75 be enough to get you started.
77 --- 2.2 Available targets
79 $KDIR refers to the path to the kernel source top-level directory
82 Will build the module(s) located in current directory.
83 All output files will be located in the same directory
85 No attempts are made to update the kernel source, and it is
86 a precondition that a successful make has been executed
89 make -C $KDIR M=`pwd` modules
90 The modules target is implied when no target is given.
91 Same functionality as if no target was specified.
92 See description above.
94 make -C $KDIR M=`pwd` modules_install
95 Install the external module(s).
96 Installation default is in /lib/modules/<kernel-version>/extra,
97 but may be prefixed with INSTALL_MOD_PATH - see separate
100 make -C $KDIR M=`pwd` clean
101 Remove all generated files for the module - the kernel
102 source directory is not modified.
104 make -C $KDIR M=`pwd` help
105 help will list the available target when building external
108 --- 2.3 Available options:
110 $KDIR refers to the path to the kernel source top-level directory
113 Used to specify where to find the kernel source.
114 '$KDIR' represent the directory where the kernel source is.
115 Make will actually change directory to the specified directory
116 when executed but change back when finished.
118 make -C $KDIR M=`pwd`
119 M= is used to tell kbuild that an external module is
121 The option given to M= is the directory where the external
122 module (kbuild file) is located.
123 When an external module is being built only a subset of the
124 usual targets are available.
126 make -C $KDIR SUBDIRS=`pwd`
127 Same as M=. The SUBDIRS= syntax is kept for backwards
130 --- 2.4 Preparing the kernel tree for module build
132 To make sure the kernel contains the information required to
133 build external modules the target 'modules_prepare' must be used.
134 'modules_prepare' exists solely as a simple way to prepare
135 a kernel source tree for building external modules.
136 Note: modules_prepare will not build Module.symvers even if
137 CONFIG_MODVERSIONS is set. Therefore a full kernel build
138 needs to be executed to make module versioning work.
140 --- 2.5 Building separate files for a module
141 It is possible to build single files which are part of a module.
142 This works equally well for the kernel, a module and even for
144 Examples (module foo.ko, consist of bar.o, baz.o):
145 make -C $KDIR M=`pwd` bar.lst
146 make -C $KDIR M=`pwd` bar.o
147 make -C $KDIR M=`pwd` foo.ko
148 make -C $KDIR M=`pwd` /
151 === 3. Example commands
153 This example shows the actual commands to be executed when building
154 an external module for the currently running kernel.
155 In the example below, the distribution is supposed to use the
156 facility to locate output files for a kernel compile in a different
157 directory than the kernel source - but the examples will also work
158 when the source and the output files are mixed in the same directory.
161 /lib/modules/<kernel-version>/source -> /usr/src/linux-<version>
163 # Output from kernel compile
164 /lib/modules/<kernel-version>/build -> /usr/src/linux-<version>-up
166 Change to the directory where the kbuild file is located and execute
167 the following commands to build the module:
169 cd /home/user/src/module
170 make -C /usr/src/`uname -r`/source \
171 O=/lib/modules/`uname-r`/build \
174 Then, to install the module use the following command:
176 make -C /usr/src/`uname -r`/source \
177 O=/lib/modules/`uname-r`/build \
181 If you look closely you will see that this is the same command as
182 listed before - with the directories spelled out.
184 The above are rather long commands, and the following chapter
185 lists a few tricks to make it all easier.
188 === 4. Creating a kbuild file for an external module
190 kbuild is the build system for the kernel, and external modules
191 must use kbuild to stay compatible with changes in the build system
192 and to pick up the right flags to gcc etc.
194 The kbuild file used as input shall follow the syntax described
195 in Documentation/kbuild/makefiles.txt. This chapter will introduce a few
196 more tricks to be used when dealing with external modules.
198 In the following a Makefile will be created for a module with the
203 8123_bin.o_shipped <= Binary blob
205 --- 4.1 Shared Makefile for module and kernel
207 An external module always includes a wrapper Makefile supporting
208 building the module using 'make' with no arguments.
209 The Makefile provided will most likely include additional
210 functionality such as test targets etc. and this part shall
211 be filtered away from kbuild since it may impact kbuild if
215 --> filename: Makefile
216 ifneq ($(KERNELRELEASE),)
217 # kbuild part of makefile
219 8123-y := 8123_if.o 8123_pci.o 8123_bin.o
224 KERNELDIR := /lib/modules/`uname -r`/build
226 $(MAKE) -C $(KERNELDIR) M=`pwd` $@
228 # Module specific targets
230 echo "X" > 8123_bin.o_shipped
234 In example 1, the check for KERNELRELEASE is used to separate
235 the two parts of the Makefile. kbuild will only see the two
236 assignments whereas make will see everything except the two
239 In recent versions of the kernel, kbuild will look for a file named
240 Kbuild and as second option look for a file named Makefile.
241 Utilising the Kbuild file makes us split up the Makefile in example 1
242 into two files as shown in example 2:
247 8123-y := 8123_if.o 8123_pci.o 8123_bin.o
249 --> filename: Makefile
250 KERNELDIR := /lib/modules/`uname -r`/build
252 $(MAKE) -C $(KERNELDIR) M=`pwd` $@
254 # Module specific targets
256 echo "X" > 8123_bin.o_shipped
259 In example 2, we are down to two fairly simple files and for simple
260 files as used in this example the split is questionable. But some
261 external modules use Makefiles of several hundred lines and here it
262 really pays off to separate the kbuild part from the rest.
263 Example 3 shows a backward compatible version.
268 8123-y := 8123_if.o 8123_pci.o 8123_bin.o
270 --> filename: Makefile
271 ifneq ($(KERNELRELEASE),)
276 KERNELDIR := /lib/modules/`uname -r`/build
278 $(MAKE) -C $KERNELDIR M=`pwd` $@
280 # Module specific targets
282 echo "X" > 8123_bin.o_shipped
286 The trick here is to include the Kbuild file from Makefile, so
287 if an older version of kbuild picks up the Makefile, the Kbuild
288 file will be included.
290 --- 4.2 Binary blobs included in a module
292 Some external modules needs to include a .o as a blob. kbuild
293 has support for this, but requires the blob file to be named
294 <filename>_shipped. In our example the blob is named
295 8123_bin.o_shipped and when the kbuild rules kick in the file
296 8123_bin.o is created as a simple copy off the 8213_bin.o_shipped file
297 with the _shipped part stripped of the filename.
298 This allows the 8123_bin.o filename to be used in the assignment to
303 8123-y := 8123_if.o 8123_pci.o 8123_bin.o
305 In example 4, there is no distinction between the ordinary .c/.h files
306 and the binary file. But kbuild will pick up different rules to create
312 Include files are a necessity when a .c file uses something from other .c
313 files (not strictly in the sense of C, but if good programming practice is
314 used). Any module that consists of more than one .c file will have a .h file
315 for one of the .c files.
317 - If the .h file only describes a module internal interface, then the .h file
318 shall be placed in the same directory as the .c files.
319 - If the .h files describe an interface used by other parts of the kernel
320 located in different directories, the .h files shall be located in
321 include/linux/ or other include/ directories as appropriate.
323 One exception for this rule is larger subsystems that have their own directory
324 under include/ such as include/scsi. Another exception is arch-specific
325 .h files which are located under include/asm-$(ARCH)/*.
327 External modules have a tendency to locate include files in a separate include/
328 directory and therefore need to deal with this in their kbuild file.
330 --- 5.1 How to include files from the kernel include dir
332 When a module needs to include a file from include/linux/, then one
335 #include <linux/modules.h>
337 kbuild will make sure to add options to gcc so the relevant
338 directories are searched.
339 Likewise for .h files placed in the same directory as the .c file.
345 --- 5.2 External modules using an include/ dir
347 External modules often locate their .h files in a separate include/
348 directory although this is not usual kernel style. When an external
349 module uses an include/ dir then kbuild needs to be told so.
350 The trick here is to use either EXTRA_CFLAGS (take effect for all .c
351 files) or CFLAGS_$F.o (take effect only for a single file).
353 In our example, if we move 8123_if.h to a subdirectory named include/
354 the resulting Kbuild file would look like:
359 EXTRA_CFLAGS := -Iinclude
360 8123-y := 8123_if.o 8123_pci.o 8123_bin.o
362 Note that in the assignment there is no space between -I and the path.
363 This is a kbuild limitation: there must be no space present.
365 --- 5.3 External modules using several directories
367 If an external module does not follow the usual kernel style, but
368 decides to spread files over several directories, then kbuild can
371 Consider the following example:
374 +- src/complex_main.c
375 | +- hal/hardwareif.c
376 | +- hal/include/hardwareif.h
379 To build a single module named complex.ko, we then need the following
384 complex-y := src/complex_main.o
385 complex-y += src/hal/hardwareif.o
387 EXTRA_CFLAGS := -I$(src)/include
388 EXTRA_CFLAGS += -I$(src)src/hal/include
391 kbuild knows how to handle .o files located in another directory -
392 although this is NOT recommended practice. The syntax is to specify
393 the directory relative to the directory where the Kbuild file is
396 To find the .h files, we have to explicitly tell kbuild where to look
397 for the .h files. When kbuild executes, the current directory is always
398 the root of the kernel tree (argument to -C) and therefore we have to
399 tell kbuild how to find the .h files using absolute paths.
400 $(src) will specify the absolute path to the directory where the
401 Kbuild file are located when being build as an external module.
402 Therefore -I$(src)/ is used to point out the directory of the Kbuild
403 file and any additional path are just appended.
405 === 6. Module installation
407 Modules which are included in the kernel are installed in the directory:
409 /lib/modules/$(KERNELRELEASE)/kernel
411 External modules are installed in the directory:
413 /lib/modules/$(KERNELRELEASE)/extra
415 --- 6.1 INSTALL_MOD_PATH
417 Above are the default directories, but as always, some level of
418 customization is possible. One can prefix the path using the variable
421 $ make INSTALL_MOD_PATH=/frodo modules_install
422 => Install dir: /frodo/lib/modules/$(KERNELRELEASE)/kernel
424 INSTALL_MOD_PATH may be set as an ordinary shell variable or as in the
425 example above, can be specified on the command line when calling make.
426 INSTALL_MOD_PATH has effect both when installing modules included in
427 the kernel as well as when installing external modules.
429 --- 6.2 INSTALL_MOD_DIR
431 When installing external modules they are by default installed to a
432 directory under /lib/modules/$(KERNELRELEASE)/extra, but one may wish
433 to locate modules for a specific functionality in a separate
434 directory. For this purpose, one can use INSTALL_MOD_DIR to specify an
435 alternative name to 'extra'.
437 $ make INSTALL_MOD_DIR=gandalf -C KERNELDIR \
438 M=`pwd` modules_install
439 => Install dir: /lib/modules/$(KERNELRELEASE)/gandalf
442 === 7. Module versioning & Module.symvers
444 Module versioning is enabled by the CONFIG_MODVERSIONS tag.
446 Module versioning is used as a simple ABI consistency check. The Module
447 versioning creates a CRC value of the full prototype for an exported symbol and
448 when a module is loaded/used then the CRC values contained in the kernel are
449 compared with similar values in the module. If they are not equal, then the
450 kernel refuses to load the module.
452 Module.symvers contains a list of all exported symbols from a kernel build.
454 --- 7.1 Symbols from the kernel (vmlinux + modules)
456 During a kernel build, a file named Module.symvers will be generated.
457 Module.symvers contains all exported symbols from the kernel and
458 compiled modules. For each symbols, the corresponding CRC value
461 The syntax of the Module.symvers file is:
462 <CRC> <Symbol> <module>
464 0x2d036834 scsi_remove_host drivers/scsi/scsi_mod
466 For a kernel build without CONFIG_MODVERSIONS enabled, the crc
467 would read: 0x00000000
469 Module.symvers serves two purposes:
470 1) It lists all exported symbols both from vmlinux and all modules
471 2) It lists the CRC if CONFIG_MODVERSIONS is enabled
473 --- 7.2 Symbols and external modules
475 When building an external module, the build system needs access to
476 the symbols from the kernel to check if all external symbols are
477 defined. This is done in the MODPOST step and to obtain all
478 symbols, modpost reads Module.symvers from the kernel.
479 If a Module.symvers file is present in the directory where
480 the external module is being built, this file will be read too.
481 During the MODPOST step, a new Module.symvers file will be written
482 containing all exported symbols that were not defined in the kernel.
484 --- 7.3 Symbols from another external module
486 Sometimes, an external module uses exported symbols from another
487 external module. Kbuild needs to have full knowledge on all symbols
488 to avoid spitting out warnings about undefined symbols.
489 Three solutions exist to let kbuild know all symbols of more than
491 The method with a top-level kbuild file is recommended but may be
492 impractical in certain situations.
494 Use a top-level Kbuild file
495 If you have two modules: 'foo' and 'bar', and 'foo' needs
496 symbols from 'bar', then one can use a common top-level kbuild
497 file so both modules are compiled in same build.
499 Consider following directory layout:
500 ./foo/ <= contains the foo module
501 ./bar/ <= contains the bar module
502 The top-level Kbuild file would then look like:
504 #./Kbuild: (this file may also be named Makefile)
508 make -C $KDIR M=`pwd`
510 will then do the expected and compile both modules with full
511 knowledge on symbols from both modules.
513 Use an extra Module.symvers file
514 When an external module is built, a Module.symvers file is
515 generated containing all exported symbols which are not
516 defined in the kernel.
517 To get access to symbols from module 'bar', one can copy the
518 Module.symvers file from the compilation of the 'bar' module
519 to the directory where the 'foo' module is built.
520 During the module build, kbuild will read the Module.symvers
521 file in the directory of the external module and when the
522 build is finished, a new Module.symvers file is created
523 containing the sum of all symbols defined and not part of the
526 Use make variable KBUILD_EXTRA_SYMBOLS in the Makefile
527 If it is impractical to copy Module.symvers from another
528 module, you can assign a space separated list of files to
529 KBUILD_EXTRA_SYMBOLS in your Makfile. These files will be
530 loaded by modpost during the initialisation of its symbol
535 --- 8.1 Testing for CONFIG_FOO_BAR
537 Modules often need to check for certain CONFIG_ options to decide if
538 a specific feature shall be included in the module. When kbuild is used
539 this is done by referencing the CONFIG_ variable directly.
542 obj-$(CONFIG_EXT2_FS) += ext2.o
544 ext2-y := balloc.o bitmap.o dir.o
545 ext2-$(CONFIG_EXT2_FS_XATTR) += xattr.o
547 External modules have traditionally used grep to check for specific
548 CONFIG_ settings directly in .config. This usage is broken.
549 As introduced before, external modules shall use kbuild when building
550 and therefore can use the same methods as in-kernel modules when
551 testing for CONFIG_ definitions.