Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/dtrace/dtrace_test/@/dev/an/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/dtrace/dtrace_test/@/dev/an/if_aironet_ieee.h |
/*- * Copyright (c) 1997, 1998, 1999 * Bill Paul <wpaul@ctr.columbia.edu>. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Bill Paul. * 4. Neither the name of the author nor the names of any co-contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY Bill Paul AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL Bill Paul OR THE VOICES IN HIS HEAD * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. * * $FreeBSD: release/9.1.0/sys/dev/an/if_aironet_ieee.h 139749 2005-01-06 01:43:34Z imp $ */ #ifndef _IF_AIRONET_IEEE_H #define _IF_AIRONET_IEEE_H /* * This header defines a simple command interface to the FreeBSD * Aironet driver (an) driver, which is used to set certain * device-specific parameters which can't be easily managed through * ifconfig(8). No, sysctl(2) is not the answer. I said a _simple_ * interface, didn't I. */ #ifndef SIOCSAIRONET #define SIOCSAIRONET SIOCSIFGENERIC #endif #ifndef SIOCGAIRONET #define SIOCGAIRONET SIOCGIFGENERIC #endif /* * This is a make-predend RID value used only by the driver * to allow the user to set the speed. */ #define AN_RID_TX_SPEED 0x1234 /* * Technically I don't think there's a limit to a record * length. The largest record is the one that contains the CIS * data, which is 240 words long, so 256 should be a safe * value. */ #define AN_MAX_DATALEN 4096 struct an_req { u_int16_t an_len; u_int16_t an_type; u_int16_t an_val[AN_MAX_DATALEN]; }; /* * Private LTV records (interpreted only by the driver). This is * a minor kludge to allow reading the interface statistics from * the driver. */ #define AN_RID_IFACE_STATS 0x0100 #define AN_RID_MGMT_XMIT 0x0200 #ifdef ANCACHE #define AN_RID_ZERO_CACHE 0x0300 #define AN_RID_READ_CACHE 0x0400 #endif #define AN_FCTL_VERS 0x0002 #define AN_FCTL_FTYPE 0x000C #define AN_FCTL_STYPE 0x00F0 #define AN_FCTL_TODS 0x0100 #define AN_FCTL_FROMDS 0x0200 #define AN_FCTL_MOREFRAGS 0x0400 #define AN_FCTL_RETRY 0x0800 #define AN_FCTL_PM 0x1000 #define AN_FCTL_MOREDATA 0x2000 #define AN_FCTL_WEP 0x4000 #define AN_FCTL_ORDER 0x8000 #define AN_FTYPE_MGMT 0x0000 #define AN_FTYPE_CTL 0x0004 #define AN_FTYPE_DATA 0x0008 #define AN_STYPE_MGMT_ASREQ 0x0000 /* association request */ #define AN_STYPE_MGMT_ASRESP 0x0010 /* association response */ #define AN_STYPE_MGMT_REASREQ 0x0020 /* reassociation request */ #define AN_STYPE_MGMT_REASRESP 0x0030 /* reassociation response */ #define AN_STYPE_MGMT_PROBEREQ 0x0040 /* probe request */ #define AN_STYPE_MGMT_PROBERESP 0x0050 /* probe response */ #define AN_STYPE_MGMT_BEACON 0x0080 /* beacon */ #define AN_STYPE_MGMT_ATIM 0x0090 /* announcement traffic ind msg */ #define AN_STYPE_MGMT_DISAS 0x00A0 /* disassociation */ #define AN_STYPE_MGMT_AUTH 0x00B0 /* authentication */ #define AN_STYPE_MGMT_DEAUTH 0x00C0 /* deauthentication */ /* * Aironet IEEE signal strength cache * * driver keeps cache of last * MAXANCACHE packets to arrive including signal strength info. * daemons may read this via ioctl * * Each entry in the wi_sigcache has a unique macsrc. */ #ifdef ANCACHE #define MAXANCACHE 10 struct an_sigcache { char macsrc[6]; /* unique MAC address for entry */ int ipsrc; /* ip address associated with packet */ int signal; /* signal strength of the packet */ int noise; /* noise value */ int quality; /* quality of the packet */ }; #endif /* * The card provides an 8-bit signal strength value (RSSI), which can * be converted to a dBm power value (or a percent) using a table in * the card's firmware (when available). The tables are slightly * different in individual cards, even of the same model. If the * table is not available, the mapping can be approximated by dBm = * RSSI - 100. This approximation can be seen by plotting a few * tables, and also matches some info on the Intersil web site (I * think they make the RF front end for the cards. However, the linux * driver uses the approximation dBm = RSSI/2 - 95. I think that is * just wrong. */ struct an_rssi_entry { u_int8_t an_rss_pct; u_int8_t an_rss_dbm; }; struct an_ltv_key { u_int16_t an_len; u_int16_t an_type; u_int16_t kindex; u_int8_t mac[6]; u_int16_t klen; u_int8_t key[16]; /* 128-bit keys */ }; struct an_ltv_stats { u_int16_t an_fudge; u_int16_t an_len; /* 0x00 */ u_int16_t an_type; /* 0xXX */ u_int16_t an_spacer; /* 0x02 */ u_int32_t an_rx_overruns; /* 0x04 */ u_int32_t an_rx_plcp_csum_errs; /* 0x08 */ u_int32_t an_rx_plcp_format_errs; /* 0x0C */ u_int32_t an_rx_plcp_len_errs; /* 0x10 */ u_int32_t an_rx_mac_crc_errs; /* 0x14 */ u_int32_t an_rx_mac_crc_ok; /* 0x18 */ u_int32_t an_rx_wep_errs; /* 0x1C */ u_int32_t an_rx_wep_ok; /* 0x20 */ u_int32_t an_retry_long; /* 0x24 */ u_int32_t an_retry_short; /* 0x28 */ u_int32_t an_retry_max; /* 0x2C */ u_int32_t an_no_ack; /* 0x30 */ u_int32_t an_no_cts; /* 0x34 */ u_int32_t an_rx_ack_ok; /* 0x38 */ u_int32_t an_rx_cts_ok; /* 0x3C */ u_int32_t an_tx_ack_ok; /* 0x40 */ u_int32_t an_tx_rts_ok; /* 0x44 */ u_int32_t an_tx_cts_ok; /* 0x48 */ u_int32_t an_tx_lmac_mcasts; /* 0x4C */ u_int32_t an_tx_lmac_bcasts; /* 0x50 */ u_int32_t an_tx_lmac_ucast_frags; /* 0x54 */ u_int32_t an_tx_lmac_ucasts; /* 0x58 */ u_int32_t an_tx_beacons; /* 0x5C */ u_int32_t an_rx_beacons; /* 0x60 */ u_int32_t an_tx_single_cols; /* 0x64 */ u_int32_t an_tx_multi_cols; /* 0x68 */ u_int32_t an_tx_defers_no; /* 0x6C */ u_int32_t an_tx_defers_prot; /* 0x70 */ u_int32_t an_tx_defers_energy; /* 0x74 */ u_int32_t an_rx_dups; /* 0x78 */ u_int32_t an_rx_partial; /* 0x7C */ u_int32_t an_tx_too_old; /* 0x80 */ u_int32_t an_rx_too_old; /* 0x84 */ u_int32_t an_lostsync_max_retries;/* 0x88 */ u_int32_t an_lostsync_missed_beacons;/* 0x8C */ u_int32_t an_lostsync_arl_exceeded;/*0x90 */ u_int32_t an_lostsync_deauthed; /* 0x94 */ u_int32_t an_lostsync_disassociated;/*0x98 */ u_int32_t an_lostsync_tsf_timing; /* 0x9C */ u_int32_t an_tx_host_mcasts; /* 0xA0 */ u_int32_t an_tx_host_bcasts; /* 0xA4 */ u_int32_t an_tx_host_ucasts; /* 0xA8 */ u_int32_t an_tx_host_failed; /* 0xAC */ u_int32_t an_rx_host_mcasts; /* 0xB0 */ u_int32_t an_rx_host_bcasts; /* 0xB4 */ u_int32_t an_rx_host_ucasts; /* 0xB8 */ u_int32_t an_rx_host_discarded; /* 0xBC */ u_int32_t an_tx_hmac_mcasts; /* 0xC0 */ u_int32_t an_tx_hmac_bcasts; /* 0xC4 */ u_int32_t an_tx_hmac_ucasts; /* 0xC8 */ u_int32_t an_tx_hmac_failed; /* 0xCC */ u_int32_t an_rx_hmac_mcasts; /* 0xD0 */ u_int32_t an_rx_hmac_bcasts; /* 0xD4 */ u_int32_t an_rx_hmac_ucasts; /* 0xD8 */ u_int32_t an_rx_hmac_discarded; /* 0xDC */ u_int32_t an_tx_hmac_accepted; /* 0xE0 */ u_int32_t an_ssid_mismatches; /* 0xE4 */ u_int32_t an_ap_mismatches; /* 0xE8 */ u_int32_t an_rates_mismatches; /* 0xEC */ u_int32_t an_auth_rejects; /* 0xF0 */ u_int32_t an_auth_timeouts; /* 0xF4 */ u_int32_t an_assoc_rejects; /* 0xF8 */ u_int32_t an_assoc_timeouts; /* 0xFC */ u_int32_t an_reason_outside_table;/* 0x100 */ u_int32_t an_reason1; /* 0x104 */ u_int32_t an_reason2; /* 0x108 */ u_int32_t an_reason3; /* 0x10C */ u_int32_t an_reason4; /* 0x110 */ u_int32_t an_reason5; /* 0x114 */ u_int32_t an_reason6; /* 0x118 */ u_int32_t an_reason7; /* 0x11C */ u_int32_t an_reason8; /* 0x120 */ u_int32_t an_reason9; /* 0x124 */ u_int32_t an_reason10; /* 0x128 */ u_int32_t an_reason11; /* 0x12C */ u_int32_t an_reason12; /* 0x130 */ u_int32_t an_reason13; /* 0x134 */ u_int32_t an_reason14; /* 0x138 */ u_int32_t an_reason15; /* 0x13C */ u_int32_t an_reason16; /* 0x140 */ u_int32_t an_reason17; /* 0x144 */ u_int32_t an_reason18; /* 0x148 */ u_int32_t an_reason19; /* 0x14C */ u_int32_t an_rx_mgmt_pkts; /* 0x150 */ u_int32_t an_tx_mgmt_pkts; /* 0x154 */ u_int32_t an_rx_refresh_pkts; /* 0x158 */ u_int32_t an_tx_refresh_pkts; /* 0x15C */ u_int32_t an_rx_poll_pkts; /* 0x160 */ u_int32_t an_tx_poll_pkts; /* 0x164 */ u_int32_t an_host_retries; /* 0x168 */ u_int32_t an_lostsync_hostreq; /* 0x16C */ u_int32_t an_host_tx_bytes; /* 0x170 */ u_int32_t an_host_rx_bytes; /* 0x174 */ u_int32_t an_uptime_usecs; /* 0x178 */ u_int32_t an_uptime_secs; /* 0x17C */ u_int32_t an_lostsync_better_ap; /* 0x180 */ u_int32_t an_rsvd[15]; }; /* * General configuration information. */ struct an_ltv_genconfig { /* General configuration. */ u_int16_t an_len; /* 0x00 */ u_int16_t an_type; /* XXXX */ u_int16_t an_opmode; /* 0x02 */ u_int16_t an_rxmode; /* 0x04 */ u_int16_t an_fragthresh; /* 0x06 */ u_int16_t an_rtsthresh; /* 0x08 */ u_int8_t an_macaddr[6]; /* 0x0A */ u_int8_t an_rates[8]; /* 0x10 */ u_int16_t an_shortretry_limit; /* 0x18 */ u_int16_t an_longretry_limit; /* 0x1A */ u_int16_t an_tx_msdu_lifetime; /* 0x1C */ u_int16_t an_rx_msdu_lifetime; /* 0x1E */ u_int16_t an_stationary; /* 0x20 */ u_int16_t an_ordering; /* 0x22 */ u_int16_t an_devtype; /* 0x24 */ u_int16_t an_rsvd0[5]; /* 0x26 */ /* Scanning associating. */ u_int16_t an_scanmode; /* 0x30 */ u_int16_t an_probedelay; /* 0x32 */ u_int16_t an_probe_energy_timeout;/* 0x34 */ u_int16_t an_probe_response_timeout;/*0x36 */ u_int16_t an_beacon_listen_timeout;/*0x38 */ u_int16_t an_ibss_join_net_timeout;/*0x3A */ u_int16_t an_auth_timeout; /* 0x3C */ u_int16_t an_authtype; /* 0x3E */ u_int16_t an_assoc_timeout; /* 0x40 */ u_int16_t an_specified_ap_timeout;/* 0x42 */ u_int16_t an_offline_scan_interval;/*0x44 */ u_int16_t an_offline_scan_duration;/*0x46 */ u_int16_t an_link_loss_delay; /* 0x48 */ u_int16_t an_max_beacon_lost_time;/* 0x4A */ u_int16_t an_refresh_interval; /* 0x4C */ u_int16_t an_rsvd1; /* 0x4E */ /* Power save operation */ u_int16_t an_psave_mode; /* 0x50 */ u_int16_t an_sleep_for_dtims; /* 0x52 */ u_int16_t an_listen_interval; /* 0x54 */ u_int16_t an_fast_listen_interval;/* 0x56 */ u_int16_t an_listen_decay; /* 0x58 */ u_int16_t an_fast_listen_decay; /* 0x5A */ u_int16_t an_rsvd2[2]; /* 0x5C */ /* Ad-hoc (or AP) operation. */ u_int16_t an_beacon_period; /* 0x60 */ u_int16_t an_atim_duration; /* 0x62 */ u_int16_t an_rsvd3; /* 0x64 */ u_int16_t an_ds_channel; /* 0x66 */ u_int16_t an_rsvd4; /* 0x68 */ u_int16_t an_dtim_period; /* 0x6A */ u_int16_t an_rsvd5[2]; /* 0x6C */ /* Radio operation. */ u_int16_t an_radiotype; /* 0x70 */ u_int16_t an_diversity; /* 0x72 */ u_int16_t an_tx_power; /* 0x74 */ u_int16_t an_rss_thresh; /* 0x76 */ u_int16_t an_modulation_type; /* 0x78 */ u_int16_t an_short_preamble; /* 0x7A */ u_int16_t an_home_product; /* 0x7C */ u_int16_t an_rsvd6; /* 0x7E */ /* Aironet extensions. */ u_int8_t an_nodename[16]; /* 0x80 */ u_int16_t an_arl_thresh; /* 0x90 */ u_int16_t an_arl_decay; /* 0x92 */ u_int16_t an_arl_delay; /* 0x94 */ u_int8_t an_rsvd7; /* 0x96 */ u_int8_t an_rsvd8; /* 0x97 */ u_int8_t an_magic_packet_action; /* 0x98 */ u_int8_t an_magic_packet_ctl; /* 0x99 */ u_int16_t an_rsvd9; u_int16_t an_spare[19]; }; #define AN_OPMODE_IBSS_ADHOC 0x0000 #define AN_OPMODE_INFRASTRUCTURE_STATION 0x0001 #define AN_OPMODE_AP 0x0002 #define AN_OPMODE_AP_REPEATER 0x0003 #define AN_OPMODE_UNMODIFIED_PAYLOAD 0x0100 #define AN_OPMODE_AIRONET_EXTENSIONS 0x0200 #define AN_OPMODE_AP_EXTENSIONS 0x0400 #define AN_RXMODE_BC_MC_ADDR 0x0000 #define AN_RXMODE_BC_ADDR 0x0001 #define AN_RXMODE_ADDR 0x0002 #define AN_RXMODE_80211_MONITOR_CURBSS 0x0003 #define AN_RXMODE_80211_MONITOR_ANYBSS 0x0004 #define AN_RXMODE_LAN_MONITOR_CURBSS 0x0005 #define AN_RXMODE_NO_8023_HEADER 0x0100 #define AN_RXMODE_NORMALIZED_RSSI 0x0200 #define AN_RATE_1MBPS 0x0002 #define AN_RATE_2MBPS 0x0004 #define AN_RATE_5_5MBPS 0x000B #define AN_RATE_11MBPS 0x0016 #define AN_DEVTYPE_PC4500 0x0065 #define AN_DEVTYPE_PC4800 0x006D #define AN_SCANMODE_ACTIVE 0x0000 #define AN_SCANMODE_PASSIVE 0x0001 #define AN_SCANMODE_AIRONET_ACTIVE 0x0002 #define AN_AUTHTYPE_NONE 0x0000 #define AN_AUTHTYPE_OPEN 0x0001 #define AN_AUTHTYPE_SHAREDKEY 0x0002 #define AN_AUTHTYPE_MASK 0x00ff #define AN_AUTHTYPE_ENABLE 0x0100 #define AN_AUTHTYPE_PRIVACY_IN_USE 0x0100 #define AN_AUTHTYPE_ALLOW_UNENCRYPTED 0x0200 #define AN_AUTHTYPE_LEAP 0x1000 #define AN_PSAVE_NONE 0x0000 #define AN_PSAVE_CAM 0x0001 #define AN_PSAVE_PSP 0x0002 #define AN_PSAVE_PSP_CAM 0x0003 #define AN_RADIOTYPE_80211_FH 0x0001 #define AN_RADIOTYPE_80211_DS 0x0002 #define AN_RADIOTYPE_LM2000_DS 0x0004 #define AN_DIVERSITY_FACTORY_DEFAULT 0x0000 #define AN_DIVERSITY_ANTENNA_1_ONLY 0x0001 #define AN_DIVERSITY_ANTENNA_2_ONLY 0x0002 #define AN_DIVERSITY_ANTENNA_1_AND_2 0x0003 #define AN_TXPOWER_FACTORY_DEFAULT 0x0000 #define AN_TXPOWER_50MW 50 #define AN_TXPOWER_100MW 100 #define AN_TXPOWER_250MW 250 #define AN_HOME_NETWORK 0x0001 #define AN_HOME_INSTALL_AP 0x0002 /* * Valid SSID list. You can specify up to three SSIDs denoting * the service sets that you want to join. The first SSID always * defaults to "tsunami" which is a handy way to detect the * card. */ struct an_ltv_ssidlist { u_int16_t an_len; u_int16_t an_type; u_int16_t an_ssid1_len; char an_ssid1[32]; u_int16_t an_ssid2_len; char an_ssid2[32]; u_int16_t an_ssid3_len; char an_ssid3[32]; }; struct an_ltv_ssid_entry{ u_int16_t an_len; char an_ssid[32]; }; #define MAX_SSIDS 25 struct an_ltv_ssidlist_new { u_int16_t an_len; u_int16_t an_type; struct an_ltv_ssid_entry an_entry[MAX_SSIDS]; }; /* * Valid AP list. */ struct an_ltv_aplist { u_int16_t an_len; u_int16_t an_type; u_int8_t an_ap1[8]; u_int8_t an_ap2[8]; u_int8_t an_ap3[8]; u_int8_t an_ap4[8]; }; /* * Driver name. */ struct an_ltv_drvname { u_int16_t an_len; u_int16_t an_type; u_int8_t an_drvname[16]; }; /* * Frame encapsulation. */ struct an_rid_encap { u_int16_t an_len; u_int16_t an_type; u_int16_t an_ethertype_default; u_int16_t an_action_default; u_int16_t an_ethertype0; u_int16_t an_action0; u_int16_t an_ethertype1; u_int16_t an_action1; u_int16_t an_ethertype2; u_int16_t an_action2; u_int16_t an_ethertype3; u_int16_t an_action3; u_int16_t an_ethertype4; u_int16_t an_action4; u_int16_t an_ethertype5; u_int16_t an_action5; u_int16_t an_ethertype6; u_int16_t an_action6; }; #define AN_ENCAP_ACTION_RX 0x0001 #define AN_ENCAP_ACTION_TX 0x0002 #define AN_RXENCAP_NONE 0x0000 #define AN_RXENCAP_RFC1024 0x0001 #define AN_TXENCAP_RFC1024 0x0000 #define AN_TXENCAP_80211 0x0002 /* * Card capabilities (read only). */ struct an_ltv_caps { u_int16_t an_len; /* 0x00 */ u_int16_t an_type; /* XXXX */ u_int8_t an_oui[3]; /* 0x02 */ u_int8_t an_rsvd0; /* 0x05 */ u_int16_t an_prodnum; /* 0x06 */ u_int8_t an_manufname[32]; /* 0x08 */ u_int8_t an_prodname[16]; /* 0x28 */ u_int8_t an_prodvers[8]; /* 0x38 */ u_int8_t an_oemaddr[6]; /* 0x40 */ u_int8_t an_aironetaddr[6]; /* 0x46 */ u_int16_t an_radiotype; /* 0x4C */ u_int16_t an_regdomain; /* 0x4E */ u_int8_t an_callid[6]; /* 0x50 */ u_int8_t an_rates[8]; /* 0x56 */ u_int8_t an_rx_diversity; /* 0x5E */ u_int8_t an_tx_diversity; /* 0x5F */ u_int16_t an_tx_powerlevels[8]; /* 0x60 */ u_int16_t an_hwrev; /* 0x70 */ u_int16_t an_hwcaps; /* 0x72 */ u_int16_t an_temprange; /* 0x74 */ u_int16_t an_fwrev; /* 0x76 */ u_int16_t an_fwsubrev; /* 0x78 */ u_int16_t an_ifacerev; /* 0x7A */ u_int16_t an_softcaps; /* 0x7C */ u_int16_t an_bootblockrev; /* 0x7E */ u_int16_t an_req_hw_support; /* 0x80 */ u_int16_t an_unknown[31]; /* 0x82 */ }; /* * Access point (read only) */ struct an_ltv_apinfo { u_int16_t an_len; u_int16_t an_type; u_int16_t an_tim_addr; u_int16_t an_airo_addr; }; /* * Radio info (read only). */ struct an_ltv_radioinfo { u_int16_t an_len; u_int16_t an_type; /* ??? */ }; /* * RSSI map. If available in the card's firmware, this can be used to * convert the 8-bit RSSI values from the card into dBm. */ struct an_ltv_rssi_map { u_int16_t an_len; u_int16_t an_type; struct an_rssi_entry an_entries[256]; }; /* * Status (read only). Note: the manual claims this RID is 108 bytes * long (0x6A is the last datum, which is 2 bytes long) however when * this RID is read from the NIC, it returns a length of 110. To be * on the safe side, this structure is padded with an extra 16-bit * word. (There is a misprint in the manual which says the macaddr * field is 8 bytes long.) * * Also, the channel_set and current_channel fields appear to be * reversed. Either that, or the hop_period field is unused. */ struct an_ltv_status { u_int16_t an_len; /* 0x00 */ u_int16_t an_type; /* 0xXX */ u_int8_t an_macaddr[6]; /* 0x02 */ u_int16_t an_opmode; /* 0x08 */ u_int16_t an_errcode; /* 0x0A */ u_int16_t an_signal_quality; /* 0x0C */ u_int16_t an_ssidlen; /* 0x0E */ u_int8_t an_ssid[32]; /* 0x10 */ u_int8_t an_ap_name[16]; /* 0x30 */ u_int8_t an_cur_bssid[6]; /* 0x40 */ u_int8_t an_prev_bssid1[6]; /* 0x46 */ u_int8_t an_prev_bssid2[6]; /* 0x4C */ u_int8_t an_prev_bssid3[6]; /* 0x52 */ u_int16_t an_beacon_period; /* 0x58 */ u_int16_t an_dtim_period; /* 0x5A */ u_int16_t an_atim_duration; /* 0x5C */ u_int16_t an_hop_period; /* 0x5E */ u_int16_t an_cur_channel; /* 0x62 */ u_int16_t an_channel_set; /* 0x60 */ u_int16_t an_hops_to_backbone; /* 0x64 */ u_int16_t an_ap_total_load; /* 0x66 */ u_int16_t an_our_generated_load; /* 0x68 */ u_int16_t an_accumulated_arl; /* 0x6A */ u_int16_t an_cur_signal_quality; /* 0x6C */ u_int16_t an_current_tx_rate; /* 0x6E */ u_int16_t an_ap_device; /* 0x70 */ u_int16_t an_normalized_strength; /* 0x72 */ u_int16_t an_short_pre_in_use; /* 0x74 */ u_int8_t an_ap_ip_addr[4]; /* 0x76 */ u_int8_t an_noise_prev_sec_pc; /* 0x7A */ u_int8_t an_noise_prev_sec_db; /* 0x7B */ u_int8_t an_avg_noise_prev_min_pc; /* 0x7C */ u_int8_t an_avg_noise_prev_min_db; /* 0x7D */ u_int8_t an_max_noise_prev_min_pc; /* 0x7E */ u_int8_t an_max_noise_prev_min_db; /* 0x7F */ u_int16_t an_spare[18]; }; #define AN_STATUS_OPMODE_CONFIGURED 0x0001 #define AN_STATUS_OPMODE_MAC_ENABLED 0x0002 #define AN_STATUS_OPMODE_RX_ENABLED 0x0004 #define AN_STATUS_OPMODE_IN_SYNC 0x0010 #define AN_STATUS_OPMODE_ASSOCIATED 0x0020 #define AN_STATUS_OPMODE_LEAP 0x0040 #define AN_STATUS_OPMODE_ERROR 0x8000 /* * WEP Key */ struct an_ltv_wepkey { u_int16_t an_len; /* 0x00 */ u_int16_t an_type; /* 0xXX */ u_int16_t an_key_index; /* 0x02 */ u_int8_t an_mac_addr[6]; /* 0x04 */ u_int16_t an_key_len; /* 0x0A */ u_int8_t an_key[13]; /* 0x0C */ }; /* * Receive frame structure. */ struct an_rxframe { u_int32_t an_rx_time; /* 0x00 */ u_int16_t an_rx_status; /* 0x04 */ u_int16_t an_rx_payload_len; /* 0x06 */ u_int8_t an_rsvd0; /* 0x08 */ u_int8_t an_rx_signal_strength; /* 0x09 */ u_int8_t an_rx_rate; /* 0x0A */ u_int8_t an_rx_chan; /* 0x0B */ u_int8_t an_rx_assoc_cnt; /* 0x0C */ u_int8_t an_rsvd1[3]; /* 0x0D */ u_int8_t an_plcp_hdr[4]; /* 0x10 */ u_int16_t an_frame_ctl; /* 0x14 */ u_int16_t an_duration; /* 0x16 */ u_int8_t an_addr1[6]; /* 0x18 */ u_int8_t an_addr2[6]; /* 0x1E */ u_int8_t an_addr3[6]; /* 0x24 */ u_int16_t an_seq_ctl; /* 0x2A */ u_int8_t an_addr4[6]; /* 0x2C */ u_int8_t an_gaplen; /* 0x32 */ } __packed; /* Do not modify this unless you are modifying LEAP itself */ #define LEAP_USERNAME_MAX 32 #define LEAP_PASSWORD_MAX 32 /* * LEAP Username */ struct an_ltv_leap_username { u_int16_t an_len; /* 0x00 */ u_int16_t an_type; /* 0xXX */ u_int16_t an_username_len; /* 0x02 */ u_int8_t an_username[LEAP_USERNAME_MAX]; /* 0x04 */ }; /* * LEAP Password */ struct an_ltv_leap_password { u_int16_t an_len; /* 0x00 */ u_int16_t an_type; /* 0xXX */ u_int16_t an_password_len; /* 0x02 */ u_int8_t an_password[LEAP_PASSWORD_MAX]; /* 0x04 */ }; /* * These are all the LTV record types that we can read or write * from the Aironet. Not all of them are temendously useful, but I * list as many as I know about here for completeness. */ /* * Configuration (read/write) */ #define AN_RID_GENCONFIG 0xFF10 /* General configuration info */ #define AN_RID_SSIDLIST 0xFF11 /* Valid SSID list */ #define AN_RID_APLIST 0xFF12 /* Valid AP list */ #define AN_RID_DRVNAME 0xFF13 /* ID name of this node for diag */ #define AN_RID_ENCAPPROTO 0xFF14 /* Payload encapsulation type */ #define AN_RID_WEP_TEMP 0xFF15 /* Temporary Key */ #define AN_RID_WEP_PERM 0xFF16 /* Perminant Key */ #define AN_RID_ACTUALCFG 0xFF20 /* Current configuration settings */ /* * Reporting (read only) */ #define AN_RID_CAPABILITIES 0xFF00 /* PC 4500/4800 capabilities */ #define AN_RID_AP_INFO 0xFF01 /* Access point info */ #define AN_RID_RADIO_INFO 0xFF02 /* Radio info */ #define AN_RID_RSSI_MAP 0xFF04 /* RSSI <-> dBm table */ #define AN_RID_STATUS 0xFF50 /* Current status info */ #define AN_RID_BEACONS_HST 0xFF51 #define AN_RID_BUSY_HST 0xFF52 #define AN_RID_RETRIES_HST 0xFF53 /* * Statistics */ #define AN_RID_16BITS_CUM 0xFF60 /* Cumulative 16-bit stats counters */ #define AN_RID_16BITS_DELTA 0xFF61 /* 16-bit stats (since last clear) */ #define AN_RID_16BITS_DELTACLR 0xFF62 /* 16-bit stats, clear on read */ #define AN_RID_32BITS_CUM 0xFF68 /* Cumulative 32-bit stats counters */ #define AN_RID_32BITS_DELTA 0xFF69 /* 32-bit stats (since last clear) */ #define AN_RID_32BITS_DELTACLR 0xFF6A /* 32-bit stats, clear on read */ /* * LEAP */ #define AN_RID_LEAPUSERNAME 0xFF23 /* Username */ #define AN_RID_LEAPPASSWORD 0xFF24 /* Password */ /* * OTHER Unknonwn for now */ #define AN_RID_MOD 0xFF17 #define AN_RID_OPTIONS 0xFF18 #define AN_RID_FACTORY_CONFIG 0xFF18 /* * FreeBSD fake RID */ #define AN_RID_MONITOR_MODE 0x0001 /* Set monitor mode for driver */ #define AN_MONITOR 1 #define AN_MONITOR_ANY_BSS 2 #define AN_MONITOR_INCLUDE_BEACON 4 #define AN_MONITOR_AIRONET_HEADER 8 #define DLT_AIRONET_HEADER 120 /* Has been allocated at tcpdump.org */ /* * from the Linux driver from Cisco ... no copyright header. * Removed duplicated information that already existed in the FreeBSD driver * provides emulation of the Cisco extensions to the Linux Aironet driver. */ /* * Ioctl constants to be used in airo_ioctl.command */ #define AIROGCAP 0 /* Capability rid */ #define AIROGCFG 1 /* USED A LOT */ #define AIROGSLIST 2 /* System ID list */ #define AIROGVLIST 3 /* List of specified AP's */ #define AIROGDRVNAM 4 /* NOTUSED */ #define AIROGEHTENC 5 /* NOTUSED */ #define AIROGWEPKTMP 6 #define AIROGWEPKNV 7 #define AIROGSTAT 8 #define AIROGSTATSC32 9 #define AIROGSTATSD32 10 /* * Leave gap of 40 commands after AIROGSTATSD32 */ #define AIROPCAP AIROGSTATSD32 + 40 #define AIROPVLIST AIROPCAP + 1 #define AIROPSLIST AIROPVLIST + 1 #define AIROPCFG AIROPSLIST + 1 #define AIROPSIDS AIROPCFG + 1 #define AIROPAPLIST AIROPSIDS + 1 #define AIROPMACON AIROPAPLIST + 1 /* Enable mac */ #define AIROPMACOFF AIROPMACON + 1 /* Disable mac */ #define AIROPSTCLR AIROPMACOFF + 1 #define AIROPWEPKEY AIROPSTCLR + 1 #define AIROPWEPKEYNV AIROPWEPKEY + 1 #define AIROPLEAPPWD AIROPWEPKEYNV + 1 #define AIROPLEAPUSR AIROPLEAPPWD + 1 /* * Another gap of 40 commands before flash codes */ #define AIROFLSHRST AIROPWEPKEYNV + 40 #define AIROFLSHGCHR AIROFLSHRST + 1 #define AIROFLSHSTFL AIROFLSHGCHR + 1 #define AIROFLSHPCHR AIROFLSHSTFL + 1 #define AIROFLPUTBUF AIROFLSHPCHR + 1 #define AIRORESTART AIROFLPUTBUF + 1 /* * Struct to enable up to 65535 ioctl's */ #define AIROMAGIC 0xa55a typedef struct aironet_ioctl { unsigned short command; /* What to do */ unsigned short len; /* Len of data */ unsigned char *data; /* d-data */ } airo_ioctl; #endif