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|
/*
* Low-level hardware driver -- IEEE 802.11 driver (80211.o) interface
* Copyright 2002-2005, Devicescape Software, Inc.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*/
#ifndef IEEE80211_H
#define IEEE80211_H
#include "ieee80211_shared.h"
/* Note! Only ieee80211_tx_status_irqsafe() and ieee80211_rx_irqsave() can be
* called in hardware interrupt context. The low-level driver must not call any
* other functions in hardware interrupt context. If there is a need for such
* call, the low-level driver should first ACK the interrupt and perform the
* IEEE 802.11 code call after this, e.g., from a scheduled tasklet (in
* software interrupt context).
*/
/*
* Frame format used when passing frame between low-level hardware drivers
* and IEEE 802.11 driver the same as used in the wireless media, i.e.,
* buffers start with IEEE 802.11 header and include the same octets that
* are sent over air.
*
* If hardware uses IEEE 802.3 headers (and perform 802.3 <-> 802.11
* conversion in firmware), upper layer 802.11 code needs to be changed to
* support this.
*
* If the receive frame format is not the same as the real frame sent
* on the wireless media (e.g., due to padding etc.), upper layer 802.11 code
* could be updated to provide support for such format assuming this would
* optimize the performance, e.g., by removing need to re-allocation and
* copying of the data.
*/
/* Interface version (used for compatibility verification) */
#define IEEE80211_VERSION 2
/* Channel information structure. Low-level driver is expected to fill in chan,
* freq, and val fields. Other fields will be filled in by 80211.o based on
* hostapd information and low-level driver does not need to use them. The
* limits for each channel will be provided in 'struct ieee80211_conf' when
* configuring the low-level driver with hw->config callback. */
struct ieee80211_channel {
short chan; /* channel number (IEEE 802.11) */
short freq; /* frequency in MHz */
int val; /* hw specific value for the channel */
int flag; /* flag for hostapd use (IEEE80211_CHAN_*) */
unsigned char power_level;
unsigned char antenna_max;
};
struct ieee80211_rate {
int rate; /* rate in 100 kbps */
int val; /* hw specific value for the rate */
int flags; /* IEEE80211_RATE_ flags */
int val2; /* hw specific value for the rate when using short preamble
* (only when IEEE80211_RATE_PREAMBLE2 flag is set, i.e., for
* 2, 5.5, and 11 Mbps) */
signed char min_rssi_ack;
unsigned char min_rssi_ack_delta;
/* following fields are set by 80211.o and need not be filled by the
* low-level driver */
int rate_inv; /* inverse of the rate (LCM(all rates) / rate) for
* optimizing channel utilization estimates */
};
struct ieee80211_hw_modes {
int mode;
int num_channels;
struct ieee80211_channel *channels;
int num_rates;
struct ieee80211_rate *rates;
int xr_end; /* only used with Atheros XR */
};
struct ieee80211_tx_queue_params {
int aifs; /* 0 .. 255; -1 = use default */
int cw_min; /* 2^n-1: 1, 3, 7, .. , 1023; 0 = use default */
int cw_max; /* 2^n-1: 1, 3, 7, .. , 1023; 0 = use default */
int burst_time; /* maximum burst time in 0.1 ms (i.e., 10 = 1 ms);
* 0 = disabled */
};
#define NUM_TX_DATA_QUEUES 6
struct ieee80211_tx_queue_stats_data {
unsigned int len; /* num packets in queue */
unsigned int limit; /* queue len (soft) limit */
unsigned int count; /* total num frames sent */
};
struct ieee80211_tx_queue_stats {
struct ieee80211_tx_queue_stats_data data[NUM_TX_DATA_QUEUES];
};
#ifndef IEEE80211_TX_QUEUE_NUMS
#define IEEE80211_TX_QUEUE_NUMS
/* TODO: these need to be synchronized with hostapd_ioctl.h; make a shared
* header file that can be included into low-level drivers, 80211.o, and
* hostapd */
enum {
IEEE80211_TX_QUEUE_DATA0 = 0,
IEEE80211_TX_QUEUE_DATA1 = 1,
IEEE80211_TX_QUEUE_DATA2 = 2,
IEEE80211_TX_QUEUE_DATA3 = 3,
IEEE80211_TX_QUEUE_DATA4 = 4,
IEEE80211_TX_QUEUE_SVP = 5,
IEEE80211_TX_QUEUE_AFTER_BEACON = 6,
IEEE80211_TX_QUEUE_BEACON = 7
};
#endif /* IEEE80211_TX_QUEUE_NUMS */
struct ieee80211_low_level_stats {
unsigned int dot11ACKFailureCount;
unsigned int dot11RTSFailureCount;
unsigned int dot11FCSErrorCount;
unsigned int dot11RTSSuccessCount;
};
/* Transmit control fields. This data structure is passed to low-level driver
* with each TX frame. The low-level driver is responsible of configuring
* hardware to use given values (depending on what is supported). */
#define HW_KEY_IDX_INVALID -1
struct ieee80211_tx_control {
enum { PKT_NORMAL = 0, PKT_PROBE_RESP } pkt_type;
int tx_rate; /* Transmit rate, given as the hw specific value for the
* rate (from struct ieee80211_rate) */
int rts_cts_rate; /* Transmit rate for RTS/CTS frame, given as the hw
* specific value for the rate (from
* struct ieee80211_rate) */
/* 1 = only first attempt, 2 = one retry, .. */
unsigned int retry_limit:8;
/* duration field for RTS/CTS frame */
unsigned int rts_cts_duration:16;
/* TODO: change these bit flags to use one unsigned int variable and
* defines with BIT(n). These are copied to TX status structure and
* this will make the code faster and smaller. */
unsigned int req_tx_status:1; /* request TX status callback for this
* frame */
unsigned int do_not_encrypt:1; /* send this frame without encryption;
* e.g., for EAPOL frames */
unsigned int use_rts_cts:1; /* Use RTS-CTS before sending frame. */
unsigned int use_cts_protect:1; /* Use CTS protection for the frame
* (e.g., for combined 802.11g /
* 802.11b networks) */
unsigned int no_ack:1; /* Tell the low level not to wait for an ack */
unsigned int rate_ctrl_probe:1;
unsigned int clear_dst_mask:1;
unsigned int requeue:1;
/* following three flags are only used with Atheros Super A/G */
unsigned int compress:1;
unsigned int turbo_prime_notify:1; /* notify HostaAPd after frame
* transmission */
unsigned int fast_frame:1;
unsigned int atheros_xr:1; /* only used with Atheros XR */
unsigned int power_level:8; /* per-packet transmit power level, in dBm
*/
unsigned int antenna_sel:4; /* 0 = default/diversity,
* 1 = Ant0, 2 = Ant1 */
int key_idx:8; /* -1 = do not encrypt, >= 0 keyidx from hw->set_key()
*/
int icv_len:8; /* Length of the ICV/MIC field in octets */
int iv_len:8; /* Length of the IV field in octets */
unsigned int queue:4; /* hardware queue to use for this frame;
* 0 = highest, hw->queues-1 = lowest */
unsigned int sw_retry_attempt:4; /* no. of times hw has tried to
* transmit frame (not incl. hw retries) */
#if 0
int rateidx; /* internal 80211.o rateidx, to be copied to tx_status */
int alt_retry_rate; /* retry rate for the last retries, given as the
* hw specific value for the rate (from
* struct ieee80211_rate). To be used to limit
* packet dropping when probing higher rates, if hw
* supports multiple retry rates. -1 = not used */
#endif
};
#define IEEE80211_CB_MAGIC 0xAAB80211
struct ieee80211_tx_packet_data {
unsigned int magic;
struct ieee80211_tx_control control;
unsigned long jiffies;
struct ieee80211_sub_if_data *sdata;
};
#define RX_FLAG_MMIC_ERROR 0x1
#define RX_FLAG_DECRYPTED 0x2
#define RX_FLAG_XR_DOUBLE_CHIRP 0x4
/* Receive status. The low-level driver should provide this information
* (the subset supported by hardware) to the 802.11 code with each received
* frame.
* Current implementation copies this into skb->cb, so it must be less than
* 48 bytes. */
struct ieee80211_rx_status {
#if 0
u64 hosttime;
u64 mactime;
#endif
int freq; /* receive frequency in Mhz */
int channel;
int phymode;
int ssi;
int antenna;
int rate;
int flag;
};
/* Transmit status. The low-level driver should provide this information
* (the subset supported by hardware) to the 802.11 code for each transmit
* frame. */
struct ieee80211_tx_status {
/* flags copied from struct ieee80211_tx_control) */
unsigned int req_tx_status:1; /* whether TX status was explicitly
* requested */
unsigned int rate_ctrl_probe:1; /* whether this was a probe packet from
* rate control */
unsigned int tx_filtered:1;
/* following three fields are only used with Atheros Super A/G */
unsigned int turbo_prime_notify:1; /* notify HostAPd - CTS for Turbo
* Prime is sent */
int queue_length; /* information about TX queue */
int queue_number;
int ack; /* whether the TX frame was ACKed */
int ack_signal; /* measured signal strength of the ACK frame */
int excessive_retries;
int retry_count;
int rateidx; /* internal 80211.o rateidx, to be copied to tx_status */
};
struct ieee80211_conf {
int channel; /* IEEE 802.11 channel number */
int freq; /* MHz */
int channel_val; /* hw specific value for the channel */
int mode; /* IW_MODE_ */
int phymode; /* MODE_IEEE80211A, .. */
unsigned int regulatory_domain;
int adm_status;
int beacon_int;
/* Bitfields, grouped together */
int sw_encrypt:1;
int sw_decrypt:1;
int short_slot_time:1; /* use IEEE 802.11g Short Slot Time */
int ssid_hidden:1; /* do not broadcast the ssid */
/* these fields are used by low level drivers for hardware
* that generate beacons independently */
u8 *ssid;
size_t ssid_len;
u8 *generic_elem;
size_t generic_elem_len;
u8 power_level; /* transmit power limit for current
* regulatory domain; in dBm */
u8 antenna_max; /* maximum antenna gain */
short tx_power_reduction; /* in 0.1 dBm */
int antenna_sel; /* default antenna conf:
* 0 = default/diversity,
* 1 = Ant0,
* 2 = Ant1 */
int calib_int; /* hw/radio calibration interval in
* seconds */
int antenna_def;
int antenna_mode;
u8 bssid_mask[ETH_ALEN]; /* ff:ff:ff:ff:ff:ff = 1 BSSID */
int bss_count;
int atheros_super_ag_compression;
int atheros_super_ag_fast_frame;
int atheros_super_ag_burst;
int atheros_super_ag_wme_ele;
int atheros_super_ag_turbo_g;
int atheros_super_ag_turbo_prime;
int atheros_xr;
u8 client_bssid[ETH_ALEN];
/* Following five fields are used for IEEE 802.11H */
unsigned int radar_detect;
unsigned int spect_mgmt;
unsigned int quiet_duration; /* duration of quiet period */
unsigned int quiet_offset; /* how far into the beacon is the quiet
* period */
unsigned int quiet_period;
};
typedef enum { ALG_NONE, ALG_WEP, ALG_TKIP, ALG_CCMP, ALG_NULL }
ieee80211_key_alg;
struct ieee80211_key_conf {
int hw_key_idx; /* filled + used by low-level driver */
ieee80211_key_alg alg;
int keylen;
int force_sw_encrypt:1; /* to be cleared by low-level driver */
int keyidx:8; /* WEP key index */
int default_tx_key:1; /* This key is the new default TX key
* (used only for broadcast keys). */
int default_wep_only:1; /* static WEP is the only configured security
* policy; this allows some low-level drivers
* to determine when hwaccel can be used */
u8 key[0];
};
#define IEEE80211_SCAN_START 1
#define IEEE80211_SCAN_END 2
struct ieee80211_scan_conf {
int scan_channel; /* IEEE 802.11 channel number to do passive scan
* on */
int scan_freq; /* new freq in MHz to switch to for passive scan
*/
int scan_channel_val; /* hw specific value for the channel */
int scan_phymode; /* MODE_IEEE80211A, .. */
unsigned char scan_power_level;
unsigned char scan_antenna_max;
int running_channel; /* IEEE 802.11 channel number we operate on
* normally */
int running_freq; /* freq in MHz we're operating on normally */
int running_channel_val; /* hw specific value for the channel */
int running_phymode;
unsigned char running_power_level;
unsigned char running_antenna_max;
int scan_time; /* time a scan will take in us */
int tries;
struct sk_buff *skb; /* skb to transmit before changing channels, maybe
* NULL for none */
struct ieee80211_tx_control *tx_control;
};
#ifndef IW_MODE_ADHOC
#define IW_MODE_ADHOC 1
#endif
#ifndef IW_MODE_INFRA
#define IW_MODE_INFRA 2
#endif
#ifndef IW_MODE_MASTER
#define IW_MODE_MASTER 3
#endif
#ifndef IW_MODE_MONITOR
#define IW_MODE_MONITOR 6
#endif
#define IEEE80211_SEQ_COUNTER_RX 0
#define IEEE80211_SEQ_COUNTER_TX 1
typedef enum {
SET_KEY, DISABLE_KEY, REMOVE_ALL_KEYS,
ENABLE_COMPRESSION, DISABLE_COMPRESSION
} set_key_cmd;
/* Configuration block used by the low-level driver to tell 802.11 code about
* supported hardware features and to pass function pointers for callback
* functions. */
struct ieee80211_hw {
int version; /* IEEE80211_VERSION */
/* Driver name */
char *name;
/* TODO: frame_type 802.11/802.3, sw_encryption requirements */
/* Some wireless LAN chipsets generate beacons in the hardware/firmware
* and others rely on host generated beacons. This option is used to
* configure upper layer IEEE 802.11 module to generate beacons. The
* low-level driver can use ieee80211_beacon_get() to fetch next
* beacon frame. */
int host_gen_beacon:1;
/* Some devices handle decryption internally and do not
* indicate whether the frame was encrypted (unencrypted frames
* will be dropped by the hardware, unless specifically allowed
* through) */
int device_hides_wep:1;
/* Whether RX frames passed to ieee80211_rx() include FCS in the end
*/
int rx_includes_fcs:1;
/* Some wireless LAN chipsets buffer broadcast/multicast frames for
* power saving stations in the hardware/firmware and others rely on
* the host system for such buffering. This option is used to
* configure upper layer IEEE 802.11 to buffer broadcast/multicast
* frames when there are power saving stations so that low-level driver
* can fetch them with ieee80211_get_buffered_bc(). */
int host_broadcast_ps_buffering:1;
int wep_include_iv:1;
int data_nullfunc_ack:1; /* will data nullfunc frames get proper
* TX status callback */
/* Force sw version of encryption for TKIP packets if WMM is enabled.
*/
int no_tkip_wmm_hwaccel:1;
/* 1 if the payload needs to be padded at even boundaries after the
* header */
unsigned int extra_hdr_room:1;
/* Some devices handle Michael MIC internally and do not include MIC in
* the received packets given to 80211.o. device_strips_mic must be set
* for such devices. ISWEP bit is still expected to be set in the IEEE
* 802.11 header with this option unlike with device_hides_wep option.
*/
unsigned int device_strips_mic:1;
/* 1 = low-level driver supports skb fraglist (NETIF_F_FRAGLIST), i.e.,
* more than one skb per frame */
unsigned int fraglist;
/* This is the time in us to change channels
*/
int channel_change_time;
int num_modes;
struct ieee80211_hw_modes *modes;
/* Handler that 802.11 module calls for each transmitted frame.
* skb contains the buffer starting from the IEEE 802.11 header.
* The low-level driver should send the frame out based on
* configuration in the TX control data. */
int (*tx)(struct net_device *dev, struct sk_buff *skb,
struct ieee80211_tx_control *control);
/* Handler for performing hardware reset. */
int (*reset)(struct net_device *dev);
/* Handler that is called when any netdevice attached to the hardware
* device is set UP for the first time. This can be used, e.g., to
* enable interrupts and beacon sending. */
int (*open)(struct net_device *dev);
/* Handler that is called when the last netdevice attached to the
* hardware device is set DOWN. This can be used, e.g., to disable
* interrupts and beacon sending. */
int (*stop)(struct net_device *dev);
/* Handler for configuration requests. IEEE 802.11 code calls this
* function to change hardware configuration, e.g., channel. */
int (*config)(struct net_device *dev, struct ieee80211_conf *conf);
/* Set TIM bit handler. If the hardware/firmware takes care of beacon
* generation, IEEE 802.11 code uses this function to tell the
* low-level to set (or clear if set==0) TIM bit for the given aid. If
* host system is used to generate beacons, this handler is not used
* and low-level driver should set it to NULL. */
int (*set_tim)(struct net_device *dev, int aid, int set);
/* Set encryption key. IEEE 802.11 module calls this function to set
* encryption keys. addr is ff:ff:ff:ff:ff:ff for default keys and
* station hwaddr for individual keys. aid of the station is given
* to help low-level driver in selecting which key->hw_key_idx to use
* for this key. TX control data will use the hw_key_idx selected by
* the low-level driver. */
int (*set_key)(struct net_device *dev, set_key_cmd cmd, u8 *addr,
struct ieee80211_key_conf *key, int aid);
/* Set TX key index for default/broadcast keys. This is needed in cases
* where wlan card is doing full WEP/TKIP encapsulation (wep_include_iv
* is not set), in other cases, this function pointer can be set to
* NULL since 80211.o takes care of selecting the key index for each
* TX frame. */
int (*set_key_idx)(struct net_device *dev, int idx);
/* Enable/disable IEEE 802.1X. This item requests wlan card to pass
* unencrypted EAPOL-Key frames even when encryption is configured.
* If the wlan card does not require such a configuration, this
* function pointer can be set to NULL. 80211.o */
int (*set_ieee8021x)(struct net_device *dev, int use_ieee8021x);
/* Set port authorization state (IEEE 802.1X PAE) to be authorized
* (authorized=1) or unauthorized (authorized=0). This function can be
* used if the wlan hardware or low-level driver implements PAE.
* 80211.o module will anyway filter frames based on authorization
* state, so this function pointer can be NULL if low-level driver does
* not require event notification about port state changes. */
int (*set_port_auth)(struct net_device *dev, u8 *addr, int authorized);
/* Ask the hardware to do a passive scan on a new channel. The hardware
* will do what ever is required to nicely leave the current channel
* including transmit any CTS packets, etc. */
int (*passive_scan)(struct net_device *dev, int state,
struct ieee80211_scan_conf *conf);
/* return low-level statistics */
int (*get_stats)(struct net_device *dev,
struct ieee80211_low_level_stats *stats);
/* Enable/disable test modes; mode = IEEE80211_TEST_* */
int (*test_mode)(struct net_device *dev, int mode);
/* Configuration of test parameters */
int (*test_param)(struct net_device *dev, int param, int value);
/* Change MAC address. addr is pointer to struct sockaddr. */
int (*set_mac_address)(struct net_device *dev, void *addr);
/* For devices that generate their own beacons and probe response
* or association responses this updates the state of privacy_invoked
* returns 0 for success or an error number */
int (*set_privacy_invoked)(struct net_device *dev,
int privacy_invoked);
/* For devices that have internal sequence counters, allow 802.11
* code to access the current value of a counter */
int (*get_sequence_counter)(struct net_device *dev,
u8* addr, u8 keyidx, u8 txrx,
u32* iv32, u16* iv16);
/* Configuration of RTS threshold (if device needs it) */
int (*set_rts_threshold)(struct net_device *dev, u32 value);
/* Configuration of fragmentation threshold (if device needs it) */
int (*set_frag_threshold)(struct net_device *dev, u32 value);
/* Configuration of retry limits (if device needs it) */
int (*set_retry_limit)(struct net_device *dev, u32 short_retry,
u32 long_retr);
/* Number of STAs in STA table notification (NULL = disabled) */
void (*sta_table_notification)(struct net_device *dev, int num_sta);
/* Configure TX queue parameters (EDCF (aifs, cw_min, cw_max),
* bursting) for a hardware TX queue.
* queue = IEEE80211_TX_QUEUE_*. */
int (*conf_tx)(struct net_device *dev, int queue,
const struct ieee80211_tx_queue_params *params);
/* Get statistics of the current TX queue status. This is used to get
* number of currently queued packets (queue length), maximum queue
* size (limit), and total number of packets sent using each TX queue
* (count). This information is used for WMM to find out which TX
* queues have room for more packets and by hostapd to provide
* statistics about the current queueing state to external programs. */
int (*get_tx_stats)(struct net_device *dev,
struct ieee80211_tx_queue_stats *stats);
/* Number of available hardware TX queues for data packets.
* WMM requires at least four queues. */
int queues;
/* Get the current TSF timer value from firmware/hardware. Currently,
* this is only used for IBSS mode debugging and, as such, is not a
* required function. */
u64 (*get_tsf)(struct net_device *dev);
/* Reset the TSF timer and allow firmware/hardware to synchronize with
* other STAs in the IBSS. This is only used in IBSS mode. This
* function is optional if the firmware/hardware takes full care of
* TSF synchronization. */
void (*reset_tsf)(struct net_device *dev);
/* Setup beacon data for IBSS beacons. Unlike access point (Master),
* IBSS uses a fixed beacon frame which is configured using this
* function. This handler is required only for IBSS mode. */
int (*beacon_update)(struct net_device *dev, struct sk_buff *skb,
struct ieee80211_tx_control *control);
/* Determine whether the last IBSS beacon was sent by us. This is
* needed only for IBSS mode and the result of this function is used to
* determine whether to reply to Probe Requests. */
int (*tx_last_beacon)(struct net_device *dev);
/* Optional handler for XR-in-use notification. */
int (*atheros_xr_in_use)(struct net_device *dev, int in_use);
};
/* Allocate a new hardware device. This must be called once for each
* hardware device. The returned pointer must be used to refer to this
* device when calling other functions. 802.11 code allocates a private data
* area for the low-level driver. The size of this area is given as
* priv_data_len. ieee80211_dev_hw_data() is used to get a pointer to the
* private data area.
*
* Note: in this version of the interface the returned pointer is struct
* net_device *. This may change in the future and low-level driver should
* not refer the device data directly to remain compatible with the future
* versions of the interface. */
struct net_device *ieee80211_alloc_hw(size_t priv_data_len,
void (*setup)(struct net_device *));
/* Register hardware device to the IEEE 802.11 code and kernel. Low-level
* drivers must call this function before using any other IEEE 802.11
* function. */
int ieee80211_register_hw(struct net_device *dev, struct ieee80211_hw *hw);
/* This function is allowed to update hardware configuration (e.g., list of
* supported operation modes and rates). */
int ieee80211_update_hw(struct net_device *dev, struct ieee80211_hw *hw);
/* Unregister a hardware device. This function instructs 802.11 code to free
* allocated resources and unregister netdevices from the kernel. */
void ieee80211_unregister_hw(struct net_device *dev);
/* Free allocated net_device including private data of a driver. */
void ieee80211_free_hw(struct net_device *dev);
/* Receive frame callback function. The low-level driver uses this function to
* send received frames to the IEEE 802.11 code. Receive buffer (skb) must
* start with IEEE 802.11 header. */
void ieee80211_rx(struct net_device *dev, struct sk_buff *skb,
struct ieee80211_rx_status *status);
void ieee80211_rx_irqsafe(struct net_device *dev, struct sk_buff *skb,
struct ieee80211_rx_status *status);
/* Transmit status callback function. The low-level driver must call this
* function to report transmit status for all the TX frames that had
* req_tx_status set in the transmit control fields. In addition, this should
* be called at least for all unicast frames to provide information for TX rate
* control algorithm. In order to maintain all statistics, this function is
* recommended to be called after each frame, including multicast/broadcast, is
* sent. */
void ieee80211_tx_status(struct net_device *dev, struct sk_buff *skb,
struct ieee80211_tx_status *status);
void ieee80211_tx_status_irqsafe(struct net_device *dev, struct sk_buff *skb,
struct ieee80211_tx_status *status);
/* Beacon generation function. If the beacon frames are generated by the host
* system (i.e., not in hardware/firmware), the low-level driver uses this
* function to receive the next beacon frame from the 802.11 code. The
* low-level is responsible for calling this function before beacon data is
* needed (e.g., based on hardware interrupt). Returned skb is used only once
* and low-level driver is responsible of freeing it. */
struct sk_buff * ieee80211_beacon_get(struct net_device *dev, int bss_idx,
struct ieee80211_tx_control *control);
/* Function for accessing buffered broadcast and multicast frames. If
* hardware/firmware does not implement buffering of broadcast/multicast
* frames when power saving is used, 802.11 code buffers them in the host
* memory. The low-level driver uses this function to fetch next buffered
* frame. In most cases, this is used when generating beacon frame. This
* function returns a pointer to the next buffered skb or NULL if no more
* buffered frames are available.
*
* Note: buffered frames are returned only after DTIM beacon frame was
* generated with ieee80211_beacon_get() and the low-level driver must thus
* call ieee80211_beacon_get() first. ieee80211_get_buffered_bc() returns
* NULL if the previous generated beacon was not DTIM, so the low-level driver
* does not need to check for DTIM beacons separately and should be able to
* use common code for all beacons. */
struct sk_buff *
ieee80211_get_buffered_bc(struct net_device *dev, int bss_idx,
struct ieee80211_tx_control *control);
/* Low level drivers that have their own MLME and MAC indicate
* the aid for an associating station with this call */
int ieee80211_set_aid_for_sta(struct net_device *dev, u8 *peer_address,
u16 aid);
/* Given an sk_buff with a raw 802.11 header at the data pointer this function
* returns the 802.11 header length in bytes (not including encryption
* headers). If the data in the sk_buff is too short to contain a valid 802.11
* header the function returns 0.
*/
int ieee80211_get_hdrlen_from_skb(struct sk_buff *skb);
/* Like ieee80211_get_hdrlen_from_skb() but takes a FC in CPU order. */
int ieee80211_get_hdrlen(u16 fc);
/* Function for net interface operation. IEEE 802.11 may use multiple kernel
* netdevices for each hardware device. The low-level driver does not "see"
* these interfaces, so it should use this function to perform netif
* operations on all interface. */
typedef enum {
NETIF_ATTACH, NETIF_DETACH, NETIF_START, NETIF_STOP, NETIF_WAKE,
NETIF_IS_STOPPED, NETIF_UPDATE_TX_START
} Netif_Oper;
int ieee80211_netif_oper(struct net_device *dev, Netif_Oper op);
/*
* Function to get hardware configuration information
* by the low level driver should it need it.
*/
struct ieee80211_conf *
ieee80211_get_hw_conf(struct net_device *dev);
/* Return a pointer to the low-level private data area for the given device. */
void * ieee80211_dev_hw_data(struct net_device *dev);
/* Return a pointer to network statistics data area for the given device. */
void * ieee80211_dev_stats(struct net_device *dev);
/* Function to indicate Radar Detection. The low level driver must call this
* function to indicate the presence of radar in the current channel.
* Additionally the radar type also could be sent */
int ieee80211_radar_status(struct net_device *dev, int channel, int radar,
int radar_type);
/* Test modes */
enum {
IEEE80211_TEST_DISABLE = 0 /* terminate testing */,
IEEE80211_TEST_UNMASK_CHANNELS = 1 /* allow all channels to be used */,
IEEE80211_TEST_CONTINUOUS_TX = 2,
};
/* Test parameters */
enum {
/* TX power in hardware specific raw value */
IEEE80211_TEST_PARAM_TX_POWER_RAW = 0,
/* TX rate in hardware specific raw value */
IEEE80211_TEST_PARAM_TX_RATE_RAW = 1,
/* Continuous TX pattern (32-bit) */
IEEE80211_TEST_PARAM_TX_PATTERN = 2,
/* TX power in 0.1 dBm, 100 = 10 dBm */
IEEE80211_TEST_PARAM_TX_POWER = 3,
/* TX rate in 100 kbps, 540 = 54 Mbps */
IEEE80211_TEST_PARAM_TX_RATE = 4,
IEEE80211_TEST_PARAM_TX_ANT_SEL_RAW = 5,
};
/* ieee80211_tx_led called with state == 1 when the first frame is queued
* with state == 0 when the last frame is transmitted and tx queue is empty
*/
void ieee80211_tx_led(int state, struct net_device *dev);
/* ieee80211_rx_led is called each time frame is received, state is not used
* (== 2)
*/
void ieee80211_rx_led(int state, struct net_device *dev);
/* IEEE 802.11 defines */
#define FCS_LEN 4
#define WLAN_FC_PVER 0x0003
#define WLAN_FC_TODS 0x0100
#define WLAN_FC_FROMDS 0x0200
#define WLAN_FC_MOREFRAG 0x0400
#define WLAN_FC_RETRY 0x0800
#define WLAN_FC_PWRMGT 0x1000
#define WLAN_FC_MOREDATA 0x2000
#define WLAN_FC_ISWEP 0x4000
#define WLAN_FC_ORDER 0x8000
#define WLAN_FC_GET_TYPE(fc) (((fc) & 0x000c) >> 2)
#define WLAN_FC_GET_STYPE(fc) (((fc) & 0x00f0) >> 4)
#define WLAN_GET_SEQ_FRAG(seq) ((seq) & 0x000f)
#define WLAN_GET_SEQ_SEQ(seq) ((seq) >> 4)
#define WLAN_FC_DATA_PRESENT(fc) (((fc) & 0x4c) == 0x08)
#define WLAN_FC_TYPE_MGMT 0
#define WLAN_FC_TYPE_CTRL 1
#define WLAN_FC_TYPE_DATA 2
/* management */
#define WLAN_FC_STYPE_ASSOC_REQ 0
#define WLAN_FC_STYPE_ASSOC_RESP 1
#define WLAN_FC_STYPE_REASSOC_REQ 2
#define WLAN_FC_STYPE_REASSOC_RESP 3
#define WLAN_FC_STYPE_PROBE_REQ 4
#define WLAN_FC_STYPE_PROBE_RESP 5
#define WLAN_FC_STYPE_BEACON 8
#define WLAN_FC_STYPE_ATIM 9
#define WLAN_FC_STYPE_DISASSOC 10
#define WLAN_FC_STYPE_AUTH 11
#define WLAN_FC_STYPE_DEAUTH 12
#define WLAN_FC_STYPE_ACTION 13
/* control */
#define WLAN_FC_STYPE_PSPOLL 10
#define WLAN_FC_STYPE_RTS 11
#define WLAN_FC_STYPE_CTS 12
#define WLAN_FC_STYPE_ACK 13
#define WLAN_FC_STYPE_CFEND 14
#define WLAN_FC_STYPE_CFENDACK 15
/* data */
#define WLAN_FC_STYPE_DATA 0
#define WLAN_FC_STYPE_DATA_CFACK 1
#define WLAN_FC_STYPE_DATA_CFPOLL 2
#define WLAN_FC_STYPE_DATA_CFACKPOLL 3
#define WLAN_FC_STYPE_NULLFUNC 4
#define WLAN_FC_STYPE_CFACK 5
#define WLAN_FC_STYPE_CFPOLL 6
#define WLAN_FC_STYPE_CFACKPOLL 7
#define WLAN_FC_STYPE_QOS_DATA 8
#define WLAN_FC_STYPE_QOS_DATA_CFACK 9
#define WLAN_FC_STYPE_QOS_DATA_CFPOLL 10
#define WLAN_FC_STYPE_QOS_DATA_CFACKPOLL 11
#define WLAN_FC_STYPE_QOS_NULLFUNC 12
#define WLAN_FC_STYPE_QOS_CFACK 13
#define WLAN_FC_STYPE_QOS_CFPOLL 14
#define WLAN_FC_STYPE_QOS_CFACKPOLL 15
#define IEEE80211_MAX_FRAG_THRESHOLD 2346
#define IEEE80211_MAX_RTS_THRESHOLD 2347
struct ieee80211_hdr {
u16 frame_control;
u16 duration_id;
u8 addr1[6];
u8 addr2[6];
u8 addr3[6];
u16 seq_ctrl;
u8 addr4[6];
} __attribute__ ((packed));
/* return a pointer to the source address (SA) */
static inline u8 *ieee80211_get_SA(struct ieee80211_hdr *hdr)
{
u8 *raw = (u8 *) hdr;
u8 tofrom = (*(raw+1)) & 3; /* get the TODS and FROMDS bits */
switch (tofrom) {
case 2:
return hdr->addr3;
case 3:
return hdr->addr4;
}
return hdr->addr2;
}
/* return a pointer to the destination address (DA) */
static inline u8 *ieee80211_get_DA(struct ieee80211_hdr *hdr)
{
u8 *raw = (u8 *) hdr;
u8 to_ds = (*(raw+1)) & 1; /* get the TODS bit */
if (to_ds)
return hdr->addr3;
return hdr->addr1;
}
static inline int ieee80211_get_morefrag(struct ieee80211_hdr *hdr)
{
return (le16_to_cpu(hdr->frame_control) & WLAN_FC_MOREFRAG) != 0;
}
#endif /* IEEE80211_H */
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