insmod: Unknown symbol in module

insmod: Unknown symbol in module

If you have a kernel loadable module which uses functions provided by other loadable kernel modules, this could happen when you load the module.
To make the test simple, let's call these 2 modules as m1 and m2.
  • The m2 is exporting function void func_m2(void).
  • The m1 is calling this function.
  • Both modules properly compile.
You can use the following command to see if the function is registered to the kernel by checking the kernel symbol table:

cat /proc/kallsyms | grep 'func_m2'
The compiling is successful, but the loading of m1 failed with:

m1: no symbol version for func_m2
m1: Unknown symbol func_m2
Why?
To check the output of the compiling, you should see the WARNING:

WARNING:"func_m2" undefined!
To fix it,
  • Run-time sequence
  • You should run insmod on 'm2.ko' before issuing the insmod for 'm1.ko'.
  • Buil-time sequence
  • When you build m2, it creates a Module.symvers file. Copy this file to where you are building m1. Then make m1, and insmod it.

Debug Module's Version Symbol Issue

  • Get the version of running kernel
  • 
    $ uname -rv
    5.8.0-53-generic #60~20.04.1-Ubuntu SMP Thu May 6 09:52:46 UTC 2021    
        
  • Find the path of the problematic module
  • 
    $ find /lib/modules -name igc.ko -print                                              
    /lib/modules/5.11.0-1003-intel/kernel/drivers/net/ethernet/intel/igc/igc.ko
    /lib/modules/5.13.0-1002-oem/kernel/drivers/net/ethernet/intel/igc/igc.ko    
        
  • Get the vermagic of the problematic module
  • 
    $ modinfo /lib/modules/5.11.0-1003-intel/kernel/drivers/net/ethernet/intel/igc/igc.ko
    ...
    vermagic:       5.11.0-1003-intel SMP mod_unload modversions    
    ...
        
  • Find packages contian the problematic module
  • 
    $ sudo apt-file update
    $ sudo apt-file find igc
    linux-modules-5.10.0-*-oem: /lib/modules/5.10.0-*-oem/kernel/drivers/net/ethernet/intel/igc/igc.ko
    linux-modules-5.4.0-*-lowlatency: /lib/modules/5.4.0-*-lowlatency/kernel/drivers/net/ethernet/intel/igc/igc.ko
    linux-modules-5.6.0-*-oem: /lib/modules/5.6.0-*-oem/kernel/drivers/net/ethernet/intel/igc/igc.ko
    linux-modules-5.8.0-*-lowlatency: /lib/modules/5.8.0-*-lowlatency/kernel/drivers/net/ethernet/intel/igc/igc.ko
    linux-modules-extra-5.4.0-*-*: /lib/modules/5.4.0-*-*/kernel/drivers/net/ethernet/intel/igc/igc.ko
        
  • List the installed packages contain the problematic module
  • 
    $ dpkg -l | grep linux-modules
    ii  linux-modules-5.11.0-1003-intel       5.11.0-1003.3                         amd64        Linux kernel extra modules for version 5.11.0 on 64 bit x86 SMP
    ii  linux-modules-extra-5.11.0-1003-intel 5.11.0-1003.3                         amd64        Linux kernel extra modules for version 5.11.0 on 64 bit x86 SMP
        
  • Download packages then extract the modules
  • 
    $ dpkg-deb -R linux-modules-5.11.0-1003-intel_5.11.0-1003.3_amd64.deb linux-modules  
        

Building External Modules


This document describes how to build an out-of-tree kernel module.

=== Table of Contents

 === 1 Introduction
 === 2 How to Build External Modules
    --- 2.1 Command Syntax
    --- 2.2 Options
    --- 2.3 Targets
    --- 2.4 Building Separate Files
 === 3. Creating a Kbuild File for an External Module
    --- 3.1 Shared Makefile
    --- 3.2 Separate Kbuild file and Makefile
    --- 3.3 Binary Blobs
    --- 3.4 Building Multiple Modules
 === 4. Include Files
    --- 4.1 Kernel Includes
    --- 4.2 Single Subdirectory
    --- 4.3 Several Subdirectories
 === 5. Module Installation
    --- 5.1 INSTALL_MOD_PATH
    --- 5.2 INSTALL_MOD_DIR
 === 6. Module Versioning
    --- 6.1 Symbols From the Kernel (vmlinux + modules)
    --- 6.2 Symbols and External Modules
    --- 6.3 Symbols From Another External Module
 === 7. Tips & Tricks
    --- 7.1 Testing for CONFIG_FOO_BAR



=== 1. Introduction

"kbuild" is the build system used by the Linux kernel. Modules must use
kbuild to stay compatible with changes in the build infrastructure and
to pick up the right flags to "gcc." Functionality for building modules
both in-tree and out-of-tree is provided. The method for building
either is similar, and all modules are initially developed and built
out-of-tree.

Covered in this document is information aimed at developers interested
in building out-of-tree (or "external") modules. The author of an
external module should supply a makefile that hides most of the
complexity, so one only has to type "make" to build the module. This is
easily accomplished, and a complete example will be presented in
section 3.


=== 2. How to Build External Modules

To build external modules, you must have a prebuilt kernel available
that contains the configuration and header files used in the build.
Also, the kernel must have been built with modules enabled. If you are
using a distribution kernel, there will be a package for the kernel you
are running provided by your distribution.

An alternative is to use the "make" target "modules_prepare." This will
make sure the kernel contains the information required. The target
exists solely as a simple way to prepare a kernel source tree for
building external modules.

NOTE: "modules_prepare" will not build Module.symvers even if
CONFIG_MODVERSIONS is set; therefore, a full kernel build needs to be
executed to make module versioning work.

--- 2.1 Command Syntax

 The command to build an external module is:

  $ make -C  M=$PWD

 The kbuild system knows that an external module is being built
 due to the "M=" option given in the command.
 To build against the running kernel use:

  $ make -C /lib/modules/`uname -r`/build M=$PWD

 Then to install the module(s) just built, add the target
 "modules_install" to the command:

  $ make -C /lib/modules/`uname -r`/build M=$PWD modules_install

--- 2.2 Options

 ($KDIR refers to the path of the kernel source directory.)

 make -C $KDIR M=$PWD

 -C $KDIR
  The directory where the kernel source is located.
  "make" will actually change to the specified directory
  when executing and will change back when finished.

 M=$PWD
  Informs kbuild that an external module is being built.
  The value given to "M" is the absolute path of the
  directory where the external module (kbuild file) is
  located.

--- 2.3 Targets

 When building an external module, only a subset of the "make"
 targets are available.

 make -C $KDIR M=$PWD [target]

 The default will build the module(s) located in the current
 directory, so a target does not need to be specified. All
 output files will also be generated in this directory. No
 attempts are made to update the kernel source, and it is a
 precondition that a successful "make" has been executed for the
 kernel.

 modules
  The default target for external modules. It has the
  same functionality as if no target was specified. See
  description above.

 modules_install
  Install the external module(s). The default location is
  /lib/modules//extra/, but a prefix may
  be added with INSTALL_MOD_PATH (discussed in section 5).

 clean
  Remove all generated files in the module directory only.

 help
  List the available targets for external modules.

--- 2.4 Building Separate Files

 It is possible to build single files that are part of a module.
 This works equally well for the kernel, a module, and even for
 external modules.

 Example (The module foo.ko, consist of bar.o and baz.o):
  make -C $KDIR M=$PWD bar.lst
  make -C $KDIR M=$PWD baz.o
  make -C $KDIR M=$PWD foo.ko
  make -C $KDIR M=$PWD /


=== 3. Creating a Kbuild File for an External Module

In the last section we saw the command to build a module for the
running kernel. The module is not actually built, however, because a
build file is required. Contained in this file will be the name of
the module(s) being built, along with the list of requisite source
files. The file may be as simple as a single line:

 obj-m := module_name.o

The kbuild system will build .o from .c,
and, after linking, will result in the kernel module .ko.
The above line can be put in either a "Kbuild" file or a "Makefile."
When the module is built from multiple sources, an additional line is
needed listing the files:

 module_name-y := obj1.o obj2.o ...

NOTE: Further documentation describing the syntax used by kbuild is
located in Documentation/kbuild/makefiles.txt.

The examples below demonstrate how to create a build file for the
module 8123.ko, which is built from the following files:

 8123_if.c
 8123_if.h
 8123_pci.c
 8123_bin.o_shipped <= Binary blob

--- 3.1 Shared Makefile

 An external module always includes a wrapper makefile that
 supports building the module using "make" with no arguments.
 This target is not used by kbuild; it is only for convenience.
 Additional functionality, such as test targets, can be included
 but should be filtered out from kbuild due to possible name
 clashes.

 Example 1:
  --> filename: Makefile
  ifneq ($(KERNELRELEASE),)
  # kbuild part of makefile
  obj-m  := 8123.o
  8123-y := 8123_if.o 8123_pci.o 8123_bin.o

  else
  # normal makefile
  KDIR ?= /lib/modules/`uname -r`/build

  default:
   $(MAKE) -C $(KDIR) M=$$PWD

  # Module specific targets
  genbin:
   echo "X" > 8123_bin.o_shipped

  endif

 The check for KERNELRELEASE is used to separate the two parts
 of the makefile. In the example, kbuild will only see the two
 assignments, whereas "make" will see everything except these
 two assignments. This is due to two passes made on the file:
 the first pass is by the "make" instance run on the command
 line; the second pass is by the kbuild system, which is
 initiated by the parameterized "make" in the default target.

--- 3.2 Separate Kbuild File and Makefile

 In newer versions of the kernel, kbuild will first look for a
 file named "Kbuild," and only if that is not found, will it
 then look for a makefile. Utilizing a "Kbuild" file allows us
 to split up the makefile from example 1 into two files:

 Example 2:
  --> filename: Kbuild
  obj-m  := 8123.o
  8123-y := 8123_if.o 8123_pci.o 8123_bin.o

  --> filename: Makefile
  KDIR ?= /lib/modules/`uname -r`/build

  default:
   $(MAKE) -C $(KDIR) M=$$PWD

  # Module specific targets
  genbin:
   echo "X" > 8123_bin.o_shipped

 The split in example 2 is questionable due to the simplicity of
 each file; however, some external modules use makefiles
 consisting of several hundred lines, and here it really pays
 off to separate the kbuild part from the rest.

 The next example shows a backward compatible version.

 Example 3:
  --> filename: Kbuild
  obj-m  := 8123.o
  8123-y := 8123_if.o 8123_pci.o 8123_bin.o

  --> filename: Makefile
  ifneq ($(KERNELRELEASE),)
  # kbuild part of makefile
  include Kbuild

  else
  # normal makefile
  KDIR ?= /lib/modules/`uname -r`/build

  default:
   $(MAKE) -C $(KDIR) M=$$PWD

  # Module specific targets
  genbin:
   echo "X" > 8123_bin.o_shipped

  endif

 Here the "Kbuild" file is included from the makefile. This
 allows an older version of kbuild, which only knows of
 makefiles, to be used when the "make" and kbuild parts are
 split into separate files.

--- 3.3 Binary Blobs

 Some external modules need to include an object file as a blob.
 kbuild has support for this, but requires the blob file to be
 named _shipped. When the kbuild rules kick in, a copy
 of _shipped is created with _shipped stripped off,
 giving us . This shortened filename can be used in
 the assignment to the module.

 Throughout this section, 8123_bin.o_shipped has been used to
 build the kernel module 8123.ko; it has been included as
 8123_bin.o.

  8123-y := 8123_if.o 8123_pci.o 8123_bin.o

 Although there is no distinction between the ordinary source
 files and the binary file, kbuild will pick up different rules
 when creating the object file for the module.

--- 3.4 Building Multiple Modules

 kbuild supports building multiple modules with a single build
 file. For example, if you wanted to build two modules, foo.ko
 and bar.ko, the kbuild lines would be:

  obj-m := foo.o bar.o
  foo-y := 
  bar-y := 

 It is that simple!


=== 4. Include Files

Within the kernel, header files are kept in standard locations
according to the following rule:

 * If the header file only describes the internal interface of a
   module, then the file is placed in the same directory as the
   source files.
 * If the header file describes an interface used by other parts
   of the kernel that are located in different directories, then
   the file is placed in include/linux/.

   NOTE: There are two notable exceptions to this rule: larger
   subsystems have their own directory under include/, such as
   include/scsi; and architecture specific headers are located
   under arch/$(ARCH)/include/.

--- 4.1 Kernel Includes

 To include a header file located under include/linux/, simply
 use:

  #include 

 kbuild will add options to "gcc" so the relevant directories
 are searched.

--- 4.2 Single Subdirectory

 External modules tend to place header files in a separate
 include/ directory where their source is located, although this
 is not the usual kernel style. To inform kbuild of the
 directory, use either ccflags-y or CFLAGS_.o.

 Using the example from section 3, if we moved 8123_if.h to a
 subdirectory named include, the resulting kbuild file would
 look like:

  --> filename: Kbuild
  obj-m := 8123.o

  ccflags-y := -Iinclude
  8123-y := 8123_if.o 8123_pci.o 8123_bin.o

 Note that in the assignment there is no space between -I and
 the path. This is a limitation of kbuild: there must be no
 space present.

--- 4.3 Several Subdirectories

 kbuild can handle files that are spread over several directories.
 Consider the following example:

 .
 |__ src
 |   |__ complex_main.c
 |   |__ hal
 | |__ hardwareif.c
 | |__ include
 |     |__ hardwareif.h
 |__ include
     |__ complex.h

 To build the module complex.ko, we then need the following
 kbuild file:

  --> filename: Kbuild
  obj-m := complex.o
  complex-y := src/complex_main.o
  complex-y += src/hal/hardwareif.o

  ccflags-y := -I$(src)/include
  ccflags-y += -I$(src)/src/hal/include

 As you can see, kbuild knows how to handle object files located
 in other directories. The trick is to specify the directory
 relative to the kbuild file's location. That being said, this
 is NOT recommended practice.

 For the header files, kbuild must be explicitly told where to
 look. When kbuild executes, the current directory is always the
 root of the kernel tree (the argument to "-C") and therefore an
 absolute path is needed. $(src) provides the absolute path by
 pointing to the directory where the currently executing kbuild
 file is located.


=== 5. Module Installation

Modules which are included in the kernel are installed in the
directory:

 /lib/modules/$(KERNELRELEASE)/kernel/

And external modules are installed in:

 /lib/modules/$(KERNELRELEASE)/extra/

--- 5.1 INSTALL_MOD_PATH

 Above are the default directories but as always some level of
 customization is possible. A prefix can be added to the
 installation path using the variable INSTALL_MOD_PATH:

  $ make INSTALL_MOD_PATH=/frodo modules_install
  => Install dir: /frodo/lib/modules/$(KERNELRELEASE)/kernel/

 INSTALL_MOD_PATH may be set as an ordinary shell variable or,
 as shown above, can be specified on the command line when
 calling "make." This has effect when installing both in-tree
 and out-of-tree modules.

--- 5.2 INSTALL_MOD_DIR

 External modules are by default installed to a directory under
 /lib/modules/$(KERNELRELEASE)/extra/, but you may wish to
 locate modules for a specific functionality in a separate
 directory. For this purpose, use INSTALL_MOD_DIR to specify an
 alternative name to "extra."

  $ make INSTALL_MOD_DIR=gandalf -C $KDIR \
         M=$PWD modules_install
  => Install dir: /lib/modules/$(KERNELRELEASE)/gandalf/


=== 6. Module Versioning

Module versioning is enabled by the CONFIG_MODVERSIONS tag, and is used
as a simple ABI consistency check. A CRC value of the full prototype
for an exported symbol is created. When a module is loaded/used, the
CRC values contained in the kernel are compared with similar values in
the module; if they are not equal, the kernel refuses to load the
module.

Module.symvers contains a list of all exported symbols from a kernel
build.

--- 6.1 Symbols From the Kernel (vmlinux + modules)

 During a kernel build, a file named Module.symvers will be
 generated. Module.symvers contains all exported symbols from
 the kernel and compiled modules. For each symbol, the
 corresponding CRC value is also stored.

 The syntax of the Module.symvers file is:
               

  0x2d036834  scsi_remove_host   drivers/scsi/scsi_mod

 For a kernel build without CONFIG_MODVERSIONS enabled, the CRC
 would read 0x00000000.

 Module.symvers serves two purposes:
 1) It lists all exported symbols from vmlinux and all modules.
 2) It lists the CRC if CONFIG_MODVERSIONS is enabled.

--- 6.2 Symbols and External Modules

 When building an external module, the build system needs access
 to the symbols from the kernel to check if all external symbols
 are defined. This is done in the MODPOST step. modpost obtains
 the symbols by reading Module.symvers from the kernel source
 tree. If a Module.symvers file is present in the directory
 where the external module is being built, this file will be
 read too. During the MODPOST step, a new Module.symvers file
 will be written containing all exported symbols that were not
 defined in the kernel.

--- 6.3 Symbols From Another External Module

 Sometimes, an external module uses exported symbols from
 another external module. kbuild needs to have full knowledge of
 all symbols to avoid spitting out warnings about undefined
 symbols. Three solutions exist for this situation.

 NOTE: The method with a top-level kbuild file is recommended
 but may be impractical in certain situations.

 Use a top-level kbuild file
  If you have two modules, foo.ko and bar.ko, where
  foo.ko needs symbols from bar.ko, you can use a
  common top-level kbuild file so both modules are
  compiled in the same build. Consider the following
  directory layout:

  ./foo/ <= contains foo.ko
  ./bar/ <= contains bar.ko

  The top-level kbuild file would then look like:

  #./Kbuild (or ./Makefile):
   obj-y := foo/ bar/

  And executing

   $ make -C $KDIR M=$PWD

  will then do the expected and compile both modules with
  full knowledge of symbols from either module.

 Use an extra Module.symvers file
  When an external module is built, a Module.symvers file
  is generated containing all exported symbols which are
  not defined in the kernel. To get access to symbols
  from bar.ko, copy the Module.symvers file from the
  compilation of bar.ko to the directory where foo.ko is
  built. During the module build, kbuild will read the
  Module.symvers file in the directory of the external
  module, and when the build is finished, a new
  Module.symvers file is created containing the sum of
  all symbols defined and not part of the kernel.

 Use "make" variable KBUILD_EXTRA_SYMBOLS
  If it is impractical to copy Module.symvers from
  another module, you can assign a space separated list
  of files to KBUILD_EXTRA_SYMBOLS in your build file.
  These files will be loaded by modpost during the
  initialization of its symbol tables.


=== 7. Tips & Tricks

--- 7.1 Testing for CONFIG_FOO_BAR

 Modules often need to check for certain CONFIG_ options to
 decide if a specific feature is included in the module. In
 kbuild this is done by referencing the CONFIG_ variable
 directly.

  #fs/ext2/Makefile
  obj-$(CONFIG_EXT2_FS) += ext2.o

  ext2-y := balloc.o bitmap.o dir.o
  ext2-$(CONFIG_EXT2_FS_XATTR) += xattr.o

 External modules have traditionally used "grep" to check for
 specific CONFIG_ settings directly in .config. This usage is
 broken. As introduced before, external modules should use
 kbuild for building and can therefore use the same methods as
 in-tree modules when testing for CONFIG_ definitions.




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