209 lines
9.8 KiB
Plaintext
209 lines
9.8 KiB
Plaintext
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/**
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\page porting Porting to different target boards and operating systems
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%wpa_supplicant was designed to be easily portable to different
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hardware (board, CPU) and software (OS, drivers) targets. It is
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already used with number of operating systems and numerous wireless
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card models and drivers. The main %wpa_supplicant repository includes
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support for Linux, FreeBSD, and Windows. In addition, the code has been
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ported to number of other operating systems like VxWorks, PalmOS,
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Windows CE, and Windows Mobile. On the hardware
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side, %wpa_supplicant is used on various systems: desktops, laptops,
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PDAs, and embedded devices with CPUs including x86, PowerPC,
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arm/xscale, and MIPS. Both big and little endian configurations are
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supported.
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\section ansi_c_extra Extra functions on top of ANSI C
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%wpa_supplicant is mostly using ANSI C functions that are available on
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most targets. However, couple of additional functions that are common
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on modern UNIX systems are used. Number of these are listed with
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prototypes in common.h (the \verbatim #ifdef CONFIG_ANSI_C_EXTRA \endverbatim
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block). These functions may need to be implemented or at least defined
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as macros to native functions in the target OS or C library.
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Many of the common ANSI C functions are used through a wrapper
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definitions in os.h to allow these to be replaced easily with a
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platform specific version in case standard C libraries are not
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available. In addition, os.h defines couple of common platform
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specific functions that are implemented in os_unix.c for UNIX like
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targets and in os_win32.c for Win32 API. If the target platform does
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not support either of these examples, a new os_*.c file may need to be
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added.
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Unless OS_NO_C_LIB_DEFINES is defined, the standard ANSI C and POSIX
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functions are used by defining the os_*() wrappers to use them
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directly in order to avoid extra cost in size and speed. If the target
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platform needs different versions of the functions, os.h can be
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modified to define the suitable macros or alternatively,
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OS_NO_C_LIB_DEFINES may be defined for the build and the wrapper
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functions can then be implemented in a new os_*.c wrapper file.
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common.h defines number of helper macros for handling integers of
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different size and byte order. Suitable version of these definitions
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may need to be added for the target platform.
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\section configuration_backend Configuration backend
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%wpa_supplicant implements a configuration interface that allows the
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backend to be easily replaced in order to read configuration data from
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a suitable source depending on the target platform. config.c
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implements the generic code that can be shared with all configuration
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backends. Each backend is implemented in its own config_*.c file.
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The included config_file.c backend uses a text file for configuration
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and config_winreg.c uses Windows registry. These files can be used as
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an example for a new configuration backend if the target platform uses
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different mechanism for configuration parameters. In addition,
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config_none.c can be used as an empty starting point for building a
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new configuration backend.
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\section driver_iface_porting Driver interface
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Unless the target OS and driver is already supported, most porting
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projects have to implement a driver wrapper. This may be done by
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adding a new driver interface module or modifying an existing module
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(driver_*.c) if the new target is similar to one of them. \ref
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driver_wrapper "Driver wrapper implementation" describes the details
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of the driver interface and discusses the tasks involved in porting
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this part of %wpa_supplicant.
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\section l2_packet_porting l2_packet (link layer access)
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%wpa_supplicant needs to have access to sending and receiving layer 2
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(link layer) packets with two Ethertypes: EAP-over-LAN (EAPOL) 0x888e
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and RSN pre-authentication 0x88c7. l2_packet.h defines the interfaces
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used for this in the core %wpa_supplicant implementation.
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If the target operating system supports a generic mechanism for link
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layer access, that is likely the best mechanism for providing the
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needed functionality for %wpa_supplicant. Linux packet socket is an
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example of such a generic mechanism. If this is not available, a
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separate interface may need to be implemented to the network stack or
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driver. This is usually an intermediate or protocol driver that is
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operating between the device driver and the OS network stack. If such
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a mechanism is not feasible, the interface can also be implemented
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directly in the device driver.
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The main %wpa_supplicant repository includes l2_packet implementations
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for Linux using packet sockets (l2_packet_linux.c), more portable
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version using libpcap/libdnet libraries (l2_packet_pcap.c; this
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supports WinPcap, too), and FreeBSD specific version of libpcap
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interface (l2_packet_freebsd.c).
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If the target operating system is supported by libpcap (receiving) and
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libdnet (sending), l2_packet_pcap.c can likely be used with minimal or
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no changes. If this is not a case or a proprietary interface for link
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layer is required, a new l2_packet module may need to be
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added. Alternatively, struct wpa_driver_ops::send_eapol() handler can
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be used to override the l2_packet library if the link layer access is
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integrated with the driver interface implementation.
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\section eloop_porting Event loop
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%wpa_supplicant uses a single process/thread model and an event loop
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to provide callbacks on events (registered timeout, received packet,
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signal). eloop.h defines the event loop interface. eloop.c is an
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implementation of such an event loop using select() and sockets. This
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is suitable for most UNIX/POSIX systems. When porting to other
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operating systems, it may be necessary to replace that implementation
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with OS specific mechanisms that provide similar functionality.
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\section ctrl_iface_porting Control interface
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%wpa_supplicant uses a \ref ctrl_iface_page "control interface"
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to allow external processed
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to get status information and to control the operations. Currently,
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this is implemented with socket based communication; both UNIX domain
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sockets and UDP sockets are supported. If the target OS does not
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support sockets, this interface will likely need to be modified to use
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another mechanism like message queues. The control interface is
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optional component, so it is also possible to run %wpa_supplicant
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without porting this part.
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The %wpa_supplicant side of the control interface is implemented in
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ctrl_iface.c. Matching client side is implemented as a control
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interface library in wpa_ctrl.c.
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\section entry_point Program entry point
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%wpa_supplicant defines a set of functions that can be used to
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initialize main supplicant processing. Each operating system has a
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mechanism for starting new processing or threads. This is usually a
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function with a specific set of arguments and calling convention. This
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function is responsible on initializing %wpa_supplicant.
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main.c includes an entry point for UNIX-like operating system, i.e.,
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main() function that uses command line arguments for setting
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parameters for %wpa_supplicant. When porting to other operating
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systems, similar OS-specific entry point implementation is needed. It
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can be implemented in a new file that is then linked with
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%wpa_supplicant instead of main.o. main.c is also a good example on
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how the initialization process should be done.
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The supplicant initialization functions are defined in
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wpa_supplicant_i.h. In most cases, the entry point function should
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start by fetching configuration parameters. After this, a global
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%wpa_supplicant context is initialized with a call to
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wpa_supplicant_init(). After this, existing network interfaces can be
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added with wpa_supplicant_add_iface(). wpa_supplicant_run() is then
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used to start the main event loop. Once this returns at program
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termination time, wpa_supplicant_deinit() is used to release global
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context data.
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wpa_supplicant_add_iface() and wpa_supplicant_remove_iface() can be
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used dynamically to add and remove interfaces based on when
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%wpa_supplicant processing is needed for them. This can be done, e.g.,
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when hotplug network adapters are being inserted and ejected. It is
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also possible to do this when a network interface is being
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enabled/disabled if it is desirable that %wpa_supplicant processing
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for the interface is fully enabled/disabled at the same time.
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\section simple_build Simple build example
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One way to start a porting project is to begin with a very simple
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build of %wpa_supplicant with WPA-PSK support and once that is
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building correctly, start adding features.
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Following command can be used to build very simple version of
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%wpa_supplicant:
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\verbatim
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cc -o wpa_supplicant config.c eloop.c common.c md5.c rc4.c sha1.c \
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config_none.c l2_packet_none.c tls_none.c wpa.c preauth.c \
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aes_wrap.c wpa_supplicant.c events.c main_none.c drivers.c
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\endverbatim
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The end result is not really very useful since it uses empty functions
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for configuration parsing and layer 2 packet access and does not
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include a driver interface. However, this is a good starting point
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since the build is complete in the sense that all functions are
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present and this is easy to configure to a build system by just
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including the listed C files.
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Once this version can be build successfully, the end result can be
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made functional by adding a proper program entry point (main*.c),
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driver interface (driver_*.c and matching CONFIG_DRIVER_* define for
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registration in drivers.c), configuration parser/writer (config_*.c),
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and layer 2 packet access implementation (l2_packet_*.c). After these
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components have been added, the end result should be a working
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WPA/WPA2-PSK enabled supplicant.
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After the basic functionality has been verified to work, more features
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can be added by linking in more files and defining C pre-processor
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defines. Currently, the best source of information for what options
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are available and which files needs to be included is in the Makefile
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used for building the supplicant with make. Similar configuration will
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be needed for build systems that either use different type of make
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tool or a GUI-based project configuration.
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*/
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