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NetBSD/sys/contrib/dev/ath/ah.h
gdamore b38b3d39ad Import new HAL 0.9.17.2. Approved by sam@ 
New HAL includes some driver changes to register accesses.
Adds support for WLAN devices on AR5312 family devices.
Adds support 32-bit SPARC ath devices (untested).
ath enabled in SPARC64 GENERIC builds.
This HAL is tested and known to work for i386 PCI devices, SPARC64 PCI devices,
and AR5312 WiSoC devices.  MIPS PCI devices appear to be busted (possibly only
on Alchemy hardware, unconfirmed), and cardbus support is untested due to
lack of test hardware.

Please report any new problems with this import to garrett@.
2006-06-05 05:14:37 +00:00

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/*-
* Copyright (c) 2002-2006 Sam Leffler, Errno Consulting, Atheros
* Communications, Inc. All rights reserved.
*
* Redistribution and use in source and binary forms are permitted
* provided that the following conditions are met:
* 1. The materials contained herein are unmodified and are used
* unmodified.
* 2. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following NO
* ''WARRANTY'' disclaimer below (''Disclaimer''), without
* modification.
* 3. Redistributions in binary form must reproduce at minimum a
* disclaimer similar to the Disclaimer below and any redistribution
* must be conditioned upon including a substantially similar
* Disclaimer requirement for further binary redistribution.
* 4. Neither the names of the above-listed copyright holders nor the
* names of any contributors may be used to endorse or promote
* product derived from this software without specific prior written
* permission.
*
* NO WARRANTY
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* ''AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF NONINFRINGEMENT,
* MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE
* FOR 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 DAMAGES.
*
* $Id: ah.h,v 1.4 2006/06/05 05:14:38 gdamore Exp $
*/
#ifndef _ATH_AH_H_
#define _ATH_AH_H_
/*
* Atheros Hardware Access Layer
*
* Clients of the HAL call ath_hal_attach to obtain a reference to an ath_hal
* structure for use with the device. Hardware-related operations that
* follow must call back into the HAL through interface, supplying the
* reference as the first parameter.
*/
/*
* Bus i/o type definitions. We define a platform-independent
* set of types that are mapped to platform-dependent data for
* register read/write operations. We use types that are large
* enough to hold a pointer; smaller data should fit and only
* require type coercion to work. Larger data can be stored
* elsewhere and a reference passed for the bus tag and/or handle.
*/
typedef void* HAL_SOFTC; /* pointer to driver/OS state */
typedef void* HAL_BUS_TAG; /* opaque bus i/o id tag */
typedef void* HAL_BUS_HANDLE; /* opaque bus i/o handle */
#include "ah_osdep.h"
/*
* __ahdecl is analogous to _cdecl; it defines the calling
* convention used within the HAL. For most systems this
* can just default to be empty and the compiler will (should)
* use _cdecl. For systems where _cdecl is not compatible this
* must be defined. See linux/ah_osdep.h for an example.
*/
#ifndef __ahdecl
#define __ahdecl
#endif
/*
* Status codes that may be returned by the HAL. Note that
* interfaces that return a status code set it only when an
* error occurs--i.e. you cannot check it for success.
*/
typedef enum {
HAL_OK = 0, /* No error */
HAL_ENXIO = 1, /* No hardware present */
HAL_ENOMEM = 2, /* Memory allocation failed */
HAL_EIO = 3, /* Hardware didn't respond as expected */
HAL_EEMAGIC = 4, /* EEPROM magic number invalid */
HAL_EEVERSION = 5, /* EEPROM version invalid */
HAL_EELOCKED = 6, /* EEPROM unreadable */
HAL_EEBADSUM = 7, /* EEPROM checksum invalid */
HAL_EEREAD = 8, /* EEPROM read problem */
HAL_EEBADMAC = 9, /* EEPROM mac address invalid */
HAL_EESIZE = 10, /* EEPROM size not supported */
HAL_EEWRITE = 11, /* Attempt to change write-locked EEPROM */
HAL_EINVAL = 12, /* Invalid parameter to function */
HAL_ENOTSUPP = 13, /* Hardware revision not supported */
HAL_ESELFTEST = 14, /* Hardware self-test failed */
HAL_EINPROGRESS = 15, /* Operation incomplete */
} HAL_STATUS;
typedef enum {
AH_FALSE = 0, /* NB: lots of code assumes false is zero */
AH_TRUE = 1,
} HAL_BOOL;
typedef enum {
HAL_CAP_REG_DMN = 0, /* current regulatory domain */
HAL_CAP_CIPHER = 1, /* hardware supports cipher */
HAL_CAP_TKIP_MIC = 2, /* handle TKIP MIC in hardware */
HAL_CAP_TKIP_SPLIT = 3, /* hardware TKIP uses split keys */
HAL_CAP_PHYCOUNTERS = 4, /* hardware PHY error counters */
HAL_CAP_DIVERSITY = 5, /* hardware supports fast diversity */
HAL_CAP_KEYCACHE_SIZE = 6, /* number of entries in key cache */
HAL_CAP_NUM_TXQUEUES = 7, /* number of hardware xmit queues */
HAL_CAP_VEOL = 9, /* hardware supports virtual EOL */
HAL_CAP_PSPOLL = 10, /* hardware has working PS-Poll support */
HAL_CAP_DIAG = 11, /* hardware diagnostic support */
HAL_CAP_COMPRESSION = 12, /* hardware supports compression */
HAL_CAP_BURST = 13, /* hardware supports packet bursting */
HAL_CAP_FASTFRAME = 14, /* hardware supoprts fast frames */
HAL_CAP_TXPOW = 15, /* global tx power limit */
HAL_CAP_TPC = 16, /* per-packet tx power control */
HAL_CAP_PHYDIAG = 17, /* hardware phy error diagnostic */
HAL_CAP_BSSIDMASK = 18, /* hardware supports bssid mask */
HAL_CAP_MCAST_KEYSRCH = 19, /* hardware has multicast key search */
HAL_CAP_TSF_ADJUST = 20, /* hardware has beacon tsf adjust */
HAL_CAP_XR = 21, /* hardware has XR support */
HAL_CAP_WME_TKIPMIC = 22, /* hardware can support TKIP MIC when WMM is turned on */
HAL_CAP_CHAN_HALFRATE = 23, /* hardware can support half rate channels */
HAL_CAP_CHAN_QUARTERRATE = 24, /* hardware can support quarter rate channels */
HAL_CAP_RFSILENT = 25, /* hardware has rfsilent support */
HAL_CAP_TPC_ACK = 26, /* ack txpower with per-packet tpc */
HAL_CAP_TPC_CTS = 27, /* cts txpower with per-packet tpc */
HAL_CAP_11D = 28, /* 11d beacon support for changing cc */
HAL_CAP_INTMIT = 29, /* interference mitigation */
} HAL_CAPABILITY_TYPE;
/*
* "States" for setting the LED. These correspond to
* the possible 802.11 operational states and there may
* be a many-to-one mapping between these states and the
* actual hardware state for the LED's (i.e. the hardware
* may have fewer states).
*/
typedef enum {
HAL_LED_INIT = 0,
HAL_LED_SCAN = 1,
HAL_LED_AUTH = 2,
HAL_LED_ASSOC = 3,
HAL_LED_RUN = 4
} HAL_LED_STATE;
/*
* Transmit queue types/numbers. These are used to tag
* each transmit queue in the hardware and to identify a set
* of transmit queues for operations such as start/stop dma.
*/
typedef enum {
HAL_TX_QUEUE_INACTIVE = 0, /* queue is inactive/unused */
HAL_TX_QUEUE_DATA = 1, /* data xmit q's */
HAL_TX_QUEUE_BEACON = 2, /* beacon xmit q */
HAL_TX_QUEUE_CAB = 3, /* "crap after beacon" xmit q */
HAL_TX_QUEUE_UAPSD = 4, /* u-apsd power save xmit q */
} HAL_TX_QUEUE;
#define HAL_NUM_TX_QUEUES 10 /* max possible # of queues */
/*
* Transmit queue subtype. These map directly to
* WME Access Categories (except for UPSD). Refer
* to Table 5 of the WME spec.
*/
typedef enum {
HAL_WME_AC_BK = 0, /* background access category */
HAL_WME_AC_BE = 1, /* best effort access category*/
HAL_WME_AC_VI = 2, /* video access category */
HAL_WME_AC_VO = 3, /* voice access category */
HAL_WME_UPSD = 4, /* uplink power save */
HAL_XR_DATA = 5, /* uplink power save */
} HAL_TX_QUEUE_SUBTYPE;
/*
* Transmit queue flags that control various
* operational parameters.
*/
typedef enum {
/*
* Per queue interrupt enables. When set the associated
* interrupt may be delivered for packets sent through
* the queue. Without these enabled no interrupts will
* be delivered for transmits through the queue.
*/
HAL_TXQ_TXOKINT_ENABLE = 0x0001, /* enable TXOK interrupt */
HAL_TXQ_TXERRINT_ENABLE = 0x0001, /* enable TXERR interrupt */
HAL_TXQ_TXDESCINT_ENABLE = 0x0002, /* enable TXDESC interrupt */
HAL_TXQ_TXEOLINT_ENABLE = 0x0004, /* enable TXEOL interrupt */
HAL_TXQ_TXURNINT_ENABLE = 0x0008, /* enable TXURN interrupt */
/*
* Enable hardware compression for packets sent through
* the queue. The compression buffer must be setup and
* packets must have a key entry marked in the tx descriptor.
*/
HAL_TXQ_COMPRESSION_ENABLE = 0x0010, /* enable h/w compression */
/*
* Disable queue when veol is hit or ready time expires.
* By default the queue is disabled only on reaching the
* physical end of queue (i.e. a null link ptr in the
* descriptor chain).
*/
HAL_TXQ_RDYTIME_EXP_POLICY_ENABLE = 0x0020,
/*
* Schedule frames on delivery of a DBA (DMA Beacon Alert)
* event. Frames will be transmitted only when this timer
* fires, e.g to transmit a beacon in ap or adhoc modes.
*/
HAL_TXQ_DBA_GATED = 0x0040, /* schedule based on DBA */
/*
* Each transmit queue has a counter that is incremented
* each time the queue is enabled and decremented when
* the list of frames to transmit is traversed (or when
* the ready time for the queue expires). This counter
* must be non-zero for frames to be scheduled for
* transmission. The following controls disable bumping
* this counter under certain conditions. Typically this
* is used to gate frames based on the contents of another
* queue (e.g. CAB traffic may only follow a beacon frame).
* These are meaningful only when frames are scheduled
* with a non-ASAP policy (e.g. DBA-gated).
*/
HAL_TXQ_CBR_DIS_QEMPTY = 0x0080, /* disable on this q empty */
HAL_TXQ_CBR_DIS_BEMPTY = 0x0100, /* disable on beacon q empty */
/*
* Fragment burst backoff policy. Normally the no backoff
* is done after a successful transmission, the next fragment
* is sent at SIFS. If this flag is set backoff is done
* after each fragment, regardless whether it was ack'd or
* not, after the backoff count reaches zero a normal channel
* access procedure is done before the next transmit (i.e.
* wait AIFS instead of SIFS).
*/
HAL_TXQ_FRAG_BURST_BACKOFF_ENABLE = 0x00800000,
/*
* Disable post-tx backoff following each frame.
*/
HAL_TXQ_BACKOFF_DISABLE = 0x00010000, /* disable post backoff */
/*
* DCU arbiter lockout control. This controls how
* lower priority tx queues are handled with respect to
* to a specific queue when multiple queues have frames
* to send. No lockout means lower priority queues arbitrate
* concurrently with this queue. Intra-frame lockout
* means lower priority queues are locked out until the
* current frame transmits (e.g. including backoffs and bursting).
* Global lockout means nothing lower can arbitrary so
* long as there is traffic activity on this queue (frames,
* backoff, etc).
*/
HAL_TXQ_ARB_LOCKOUT_INTRA = 0x00020000, /* intra-frame lockout */
HAL_TXQ_ARB_LOCKOUT_GLOBAL = 0x00040000, /* full lockout s */
HAL_TXQ_IGNORE_VIRTCOL = 0x00080000, /* ignore virt collisions */
HAL_TXQ_SEQNUM_INC_DIS = 0x00100000, /* disable seqnum increment */
} HAL_TX_QUEUE_FLAGS;
typedef struct {
u_int32_t tqi_ver; /* hal TXQ version */
HAL_TX_QUEUE_SUBTYPE tqi_subtype; /* subtype if applicable */
HAL_TX_QUEUE_FLAGS tqi_qflags; /* flags (see above) */
u_int32_t tqi_priority; /* (not used) */
u_int32_t tqi_aifs; /* aifs */
u_int32_t tqi_cwmin; /* cwMin */
u_int32_t tqi_cwmax; /* cwMax */
u_int16_t tqi_shretry; /* rts retry limit */
u_int16_t tqi_lgretry; /* long retry limit (not used)*/
u_int32_t tqi_cbrPeriod; /* CBR period (us) */
u_int32_t tqi_cbrOverflowLimit; /* threshold for CBROVF int */
u_int32_t tqi_burstTime; /* max burst duration (us) */
u_int32_t tqi_readyTime; /* frame schedule time (us) */
u_int32_t tqi_compBuf; /* comp buffer phys addr */
} HAL_TXQ_INFO;
#define HAL_TQI_NONVAL 0xffff
/* token to use for aifs, cwmin, cwmax */
#define HAL_TXQ_USEDEFAULT ((u_int32_t) -1)
/* compression definitions */
#define HAL_COMP_BUF_MAX_SIZE 9216 /* 9K */
#define HAL_COMP_BUF_ALIGN_SIZE 512
#define HAL_DECOMP_MASK_SIZE 128
/*
* Transmit packet types. This belongs in ah_desc.h, but
* is here so we can give a proper type to various parameters
* (and not require everyone include the file).
*
* NB: These values are intentionally assigned for
* direct use when setting up h/w descriptors.
*/
typedef enum {
HAL_PKT_TYPE_NORMAL = 0,
HAL_PKT_TYPE_ATIM = 1,
HAL_PKT_TYPE_PSPOLL = 2,
HAL_PKT_TYPE_BEACON = 3,
HAL_PKT_TYPE_PROBE_RESP = 4,
HAL_PKT_TYPE_CHIRP = 5,
HAL_PKT_TYPE_GRP_POLL = 6,
} HAL_PKT_TYPE;
/* Rx Filter Frame Types */
typedef enum {
HAL_RX_FILTER_UCAST = 0x00000001, /* Allow unicast frames */
HAL_RX_FILTER_MCAST = 0x00000002, /* Allow multicast frames */
HAL_RX_FILTER_BCAST = 0x00000004, /* Allow broadcast frames */
HAL_RX_FILTER_CONTROL = 0x00000008, /* Allow control frames */
HAL_RX_FILTER_BEACON = 0x00000010, /* Allow beacon frames */
HAL_RX_FILTER_PROM = 0x00000020, /* Promiscuous mode */
HAL_RX_FILTER_XRPOLL = 0x00000040, /* Allow XR poll frmae */
HAL_RX_FILTER_PROBEREQ = 0x00000080, /* Allow probe request frames */
HAL_RX_FILTER_PHYERR = 0x00000100, /* Allow phy errors */
HAL_RX_FILTER_PHYRADAR = 0x00000200, /* Allow phy radar errors*/
} HAL_RX_FILTER;
typedef enum {
HAL_PM_AWAKE = 0,
HAL_PM_FULL_SLEEP = 1,
HAL_PM_NETWORK_SLEEP = 2,
HAL_PM_UNDEFINED = 3
} HAL_POWER_MODE;
/*
* NOTE WELL:
* These are mapped to take advantage of the common locations for many of
* the bits on all of the currently supported MAC chips. This is to make
* the ISR as efficient as possible, while still abstracting HW differences.
* When new hardware breaks this commonality this enumerated type, as well
* as the HAL functions using it, must be modified. All values are directly
* mapped unless commented otherwise.
*/
typedef enum {
HAL_INT_RX = 0x00000001, /* Non-common mapping */
HAL_INT_RXDESC = 0x00000002,
HAL_INT_RXNOFRM = 0x00000008,
HAL_INT_RXEOL = 0x00000010,
HAL_INT_RXORN = 0x00000020,
HAL_INT_TX = 0x00000040, /* Non-common mapping */
HAL_INT_TXDESC = 0x00000080,
HAL_INT_TXURN = 0x00000800,
HAL_INT_MIB = 0x00001000,
HAL_INT_RXPHY = 0x00004000,
HAL_INT_RXKCM = 0x00008000,
HAL_INT_SWBA = 0x00010000,
HAL_INT_BMISS = 0x00040000,
HAL_INT_BNR = 0x00100000, /* Non-common mapping */
HAL_INT_TIM = 0x00200000, /* Non-common mapping */
HAL_INT_DTIM = 0x00400000, /* Non-common mapping */
HAL_INT_DTIMSYNC= 0x00800000, /* Non-common mapping */
HAL_INT_GPIO = 0x01000000,
HAL_INT_CABEND = 0x02000000, /* Non-common mapping */
HAL_INT_FATAL = 0x40000000, /* Non-common mapping */
HAL_INT_GLOBAL = 0x80000000, /* Set/clear IER */
HAL_INT_BMISC = HAL_INT_TIM
| HAL_INT_DTIM
| HAL_INT_DTIMSYNC
| HAL_INT_CABEND,
/* Interrupt bits that map directly to ISR/IMR bits */
HAL_INT_COMMON = HAL_INT_RXNOFRM
| HAL_INT_RXDESC
| HAL_INT_RXEOL
| HAL_INT_RXORN
| HAL_INT_TXURN
| HAL_INT_TXDESC
| HAL_INT_MIB
| HAL_INT_RXPHY
| HAL_INT_RXKCM
| HAL_INT_SWBA
| HAL_INT_BMISS
| HAL_INT_GPIO,
HAL_INT_NOCARD = 0xffffffff /* To signal the card was removed */
} HAL_INT;
typedef enum {
HAL_RFGAIN_INACTIVE = 0,
HAL_RFGAIN_READ_REQUESTED = 1,
HAL_RFGAIN_NEED_CHANGE = 2
} HAL_RFGAIN;
/*
* Channels are specified by frequency.
*/
typedef struct {
u_int16_t channel; /* setting in Mhz */
u_int16_t channelFlags; /* see below */
u_int8_t privFlags;
int8_t maxRegTxPower; /* max regulatory tx power in dBm */
int8_t maxTxPower; /* max true tx power in 0.5 dBm */
int8_t minTxPower; /* min true tx power in 0.5 dBm */
} HAL_CHANNEL;
/* channelFlags */
#define CHANNEL_CW_INT 0x0002 /* CW interference detected on channel */
#define CHANNEL_TURBO 0x0010 /* Turbo Channel */
#define CHANNEL_CCK 0x0020 /* CCK channel */
#define CHANNEL_OFDM 0x0040 /* OFDM channel */
#define CHANNEL_2GHZ 0x0080 /* 2 GHz spectrum channel. */
#define CHANNEL_5GHZ 0x0100 /* 5 GHz spectrum channel */
#define CHANNEL_PASSIVE 0x0200 /* Only passive scan allowed in the channel */
#define CHANNEL_DYN 0x0400 /* dynamic CCK-OFDM channel */
#define CHANNEL_XR 0x0800 /* XR channel */
#define CHANNEL_STURBO 0x2000 /* Static turbo, no 11a-only usage */
#define CHANNEL_HALF 0x4000 /* Half rate channel */
#define CHANNEL_QUARTER 0x8000 /* Quarter rate channel */
/* privFlags */
#define CHANNEL_INTERFERENCE 0x01 /* Software use: channel interference
used for as AR as well as RADAR
interference detection */
#define CHANNEL_DFS 0x02 /* DFS required on channel */
#define CHANNEL_4MS_LIMIT 0x04 /* 4msec packet limit on this channel */
#define CHANNEL_DFS_CLEAR 0x08 /* if channel has been checked for DFS */
#define CHANNEL_A (CHANNEL_5GHZ|CHANNEL_OFDM)
#define CHANNEL_B (CHANNEL_2GHZ|CHANNEL_CCK)
#define CHANNEL_PUREG (CHANNEL_2GHZ|CHANNEL_OFDM)
#ifdef notdef
#define CHANNEL_G (CHANNEL_2GHZ|CHANNEL_DYN)
#else
#define CHANNEL_G (CHANNEL_2GHZ|CHANNEL_OFDM)
#endif
#define CHANNEL_T (CHANNEL_5GHZ|CHANNEL_OFDM|CHANNEL_TURBO)
#define CHANNEL_ST (CHANNEL_T|CHANNEL_STURBO)
#define CHANNEL_108G (CHANNEL_2GHZ|CHANNEL_OFDM|CHANNEL_TURBO)
#define CHANNEL_108A CHANNEL_T
#define CHANNEL_X (CHANNEL_5GHZ|CHANNEL_OFDM|CHANNEL_XR)
#define CHANNEL_ALL \
(CHANNEL_OFDM|CHANNEL_CCK| CHANNEL_2GHZ | CHANNEL_5GHZ | CHANNEL_TURBO)
#define CHANNEL_ALL_NOTURBO (CHANNEL_ALL &~ CHANNEL_TURBO)
#define HAL_ANTENNA_MIN_MODE 0
#define HAL_ANTENNA_FIXED_A 1
#define HAL_ANTENNA_FIXED_B 2
#define HAL_ANTENNA_MAX_MODE 3
typedef struct {
u_int32_t ackrcv_bad;
u_int32_t rts_bad;
u_int32_t rts_good;
u_int32_t fcs_bad;
u_int32_t beacons;
} HAL_MIB_STATS;
typedef u_int16_t HAL_CTRY_CODE; /* country code */
typedef u_int16_t HAL_REG_DOMAIN; /* regulatory domain code */
enum {
CTRY_DEBUG = 0x1ff, /* debug country code */
CTRY_DEFAULT = 0 /* default country code */
};
enum {
HAL_MODE_11A = 0x001, /* 11a channels */
HAL_MODE_TURBO = 0x002, /* 11a turbo-only channels */
HAL_MODE_11B = 0x004, /* 11b channels */
HAL_MODE_PUREG = 0x008, /* 11g channels (OFDM only) */
#ifdef notdef
HAL_MODE_11G = 0x010, /* 11g channels (OFDM/CCK) */
#else
HAL_MODE_11G = 0x008, /* XXX historical */
#endif
HAL_MODE_108G = 0x020, /* 11a+Turbo channels */
HAL_MODE_108A = 0x040, /* 11g+Turbo channels */
HAL_MODE_XR = 0x100, /* XR channels */
HAL_MODE_11A_HALF_RATE = 0x200, /* 11A half rate channels */
HAL_MODE_11A_QUARTER_RATE = 0x400, /* 11A quarter rate channels */
HAL_MODE_ALL = 0xfff
};
typedef struct {
int rateCount; /* NB: for proper padding */
u_int8_t rateCodeToIndex[32]; /* back mapping */
struct {
u_int8_t valid; /* valid for rate control use */
u_int8_t phy; /* CCK/OFDM/XR */
u_int16_t rateKbps; /* transfer rate in kbs */
u_int8_t rateCode; /* rate for h/w descriptors */
u_int8_t shortPreamble; /* mask for enabling short
* preamble in CCK rate code */
u_int8_t dot11Rate; /* value for supported rates
* info element of MLME */
u_int8_t controlRate; /* index of next lower basic
* rate; used for dur. calcs */
u_int16_t lpAckDuration; /* long preamble ACK duration */
u_int16_t spAckDuration; /* short preamble ACK duration*/
} info[32];
} HAL_RATE_TABLE;
typedef struct {
u_int rs_count; /* number of valid entries */
u_int8_t rs_rates[32]; /* rates */
} HAL_RATE_SET;
/*
* Antenna switch control. By default antenna selection
* enables multiple (2) antenna use. To force use of the
* A or B antenna only specify a fixed setting. Fixing
* the antenna will also disable any diversity support.
*/
typedef enum {
HAL_ANT_VARIABLE = 0, /* variable by programming */
HAL_ANT_FIXED_A = 1, /* fixed antenna A */
HAL_ANT_FIXED_B = 2, /* fixed antenna B */
} HAL_ANT_SETTING;
typedef enum {
HAL_M_STA = 1, /* infrastructure station */
HAL_M_IBSS = 0, /* IBSS (adhoc) station */
HAL_M_HOSTAP = 6, /* Software Access Point */
HAL_M_MONITOR = 8 /* Monitor mode */
} HAL_OPMODE;
typedef struct {
u_int8_t kv_type; /* one of HAL_CIPHER */
u_int8_t kv_pad;
u_int16_t kv_len; /* length in bits */
u_int8_t kv_val[16]; /* enough for 128-bit keys */
u_int8_t kv_mic[8]; /* TKIP MIC key */
} HAL_KEYVAL;
typedef enum {
HAL_CIPHER_WEP = 0,
HAL_CIPHER_AES_OCB = 1,
HAL_CIPHER_AES_CCM = 2,
HAL_CIPHER_CKIP = 3,
HAL_CIPHER_TKIP = 4,
HAL_CIPHER_CLR = 5, /* no encryption */
HAL_CIPHER_MIC = 127 /* TKIP-MIC, not a cipher */
} HAL_CIPHER;
enum {
HAL_SLOT_TIME_6 = 6, /* NB: for turbo mode */
HAL_SLOT_TIME_9 = 9,
HAL_SLOT_TIME_20 = 20,
};
/*
* Per-station beacon timer state. Note that the specified
* beacon interval (given in TU's) can also include flags
* to force a TSF reset and to enable the beacon xmit logic.
* If bs_cfpmaxduration is non-zero the hardware is setup to
* coexist with a PCF-capable AP.
*/
typedef struct {
u_int32_t bs_nexttbtt; /* next beacon in TU */
u_int32_t bs_nextdtim; /* next DTIM in TU */
u_int32_t bs_intval; /* beacon interval+flags */
#define HAL_BEACON_PERIOD 0x0000ffff /* beacon interval period */
#define HAL_BEACON_ENA 0x00800000 /* beacon xmit enable */
#define HAL_BEACON_RESET_TSF 0x01000000 /* clear TSF */
u_int32_t bs_dtimperiod;
u_int16_t bs_cfpperiod; /* CFP period in TU */
u_int16_t bs_cfpmaxduration; /* max CFP duration in TU */
u_int32_t bs_cfpnext; /* next CFP in TU */
u_int16_t bs_timoffset; /* byte offset to TIM bitmap */
u_int16_t bs_bmissthreshold; /* beacon miss threshold */
u_int32_t bs_sleepduration; /* max sleep duration */
} HAL_BEACON_STATE;
/*
* Like HAL_BEACON_STATE but for non-station mode setup.
* NB: see above flag definitions
*/
typedef struct {
u_int32_t bt_intval; /* beacon interval+flags */
u_int32_t bt_nexttbtt; /* next beacon in TU */
u_int32_t bt_nextatim; /* next ATIM in TU */
u_int32_t bt_nextdba; /* next DBA in 1/8th TU */
u_int32_t bt_nextswba; /* next SWBA in 1/8th TU */
} HAL_BEACON_TIMERS;
/*
* Per-node statistics maintained by the driver for use in
* optimizing signal quality and other operational aspects.
*/
typedef struct {
u_int32_t ns_avgbrssi; /* average beacon rssi */
u_int32_t ns_avgrssi; /* average data rssi */
u_int32_t ns_avgtxrssi; /* average tx rssi */
} HAL_NODE_STATS;
#define HAL_RSSI_EP_MULTIPLIER (1<<7) /* pow2 to optimize out * and / */
struct ath_desc;
/*
* Hardware Access Layer (HAL) API.
*
* Clients of the HAL call ath_hal_attach to obtain a reference to an
* ath_hal structure for use with the device. Hardware-related operations
* that follow must call back into the HAL through interface, supplying
* the reference as the first parameter. Note that before using the
* reference returned by ath_hal_attach the caller should verify the
* ABI version number.
*/
struct ath_hal {
u_int32_t ah_magic; /* consistency check magic number */
u_int32_t ah_abi; /* HAL ABI version */
#define HAL_ABI_VERSION 0x06052200 /* YYMMDDnn */
u_int16_t ah_devid; /* PCI device ID */
u_int16_t ah_subvendorid; /* PCI subvendor ID */
HAL_SOFTC ah_sc; /* back pointer to driver/os state */
HAL_BUS_TAG ah_st; /* params for register r+w */
HAL_BUS_HANDLE ah_sh;
HAL_CTRY_CODE ah_countryCode;
u_int32_t ah_macVersion; /* MAC version id */
u_int16_t ah_macRev; /* MAC revision */
u_int16_t ah_phyRev; /* PHY revision */
/* NB: when only one radio is present the rev is in 5Ghz */
u_int16_t ah_analog5GhzRev;/* 5GHz radio revision */
u_int16_t ah_analog2GhzRev;/* 2GHz radio revision */
u_int8_t ah_decompMask[HAL_DECOMP_MASK_SIZE]; /* decomp mask array */
const HAL_RATE_TABLE *__ahdecl(*ah_getRateTable)(struct ath_hal *,
u_int mode);
void __ahdecl(*ah_detach)(struct ath_hal*);
/* Reset functions */
HAL_BOOL __ahdecl(*ah_reset)(struct ath_hal *, HAL_OPMODE,
HAL_CHANNEL *, HAL_BOOL bChannelChange,
HAL_STATUS *status);
HAL_BOOL __ahdecl(*ah_phyDisable)(struct ath_hal *);
HAL_BOOL __ahdecl(*ah_disable)(struct ath_hal *);
void __ahdecl(*ah_setPCUConfig)(struct ath_hal *);
HAL_BOOL __ahdecl(*ah_perCalibration)(struct ath_hal*, HAL_CHANNEL *, HAL_BOOL *);
HAL_BOOL __ahdecl(*ah_setTxPowerLimit)(struct ath_hal *, u_int32_t);
void __ahdecl(*ah_arEnable)(struct ath_hal *);
void __ahdecl(*ah_arDisable)(struct ath_hal *);
void __ahdecl(*ah_arReset)(struct ath_hal *);
HAL_BOOL __ahdecl(*ah_radarHaveEvent)(struct ath_hal *);
HAL_BOOL __ahdecl(*ah_processDfs)(struct ath_hal *, HAL_CHANNEL *);
u_int32_t __ahdecl(*ah_dfsNolCheck)(struct ath_hal *, HAL_CHANNEL *, u_int32_t);
HAL_BOOL __ahdecl(*ah_radarWait)(struct ath_hal *, HAL_CHANNEL *);
/* Transmit functions */
HAL_BOOL __ahdecl(*ah_updateTxTrigLevel)(struct ath_hal*,
HAL_BOOL incTrigLevel);
int __ahdecl(*ah_setupTxQueue)(struct ath_hal *, HAL_TX_QUEUE,
const HAL_TXQ_INFO *qInfo);
HAL_BOOL __ahdecl(*ah_setTxQueueProps)(struct ath_hal *, int q,
const HAL_TXQ_INFO *qInfo);
HAL_BOOL __ahdecl(*ah_getTxQueueProps)(struct ath_hal *, int q,
HAL_TXQ_INFO *qInfo);
HAL_BOOL __ahdecl(*ah_releaseTxQueue)(struct ath_hal *ah, u_int q);
HAL_BOOL __ahdecl(*ah_resetTxQueue)(struct ath_hal *ah, u_int q);
u_int32_t __ahdecl(*ah_getTxDP)(struct ath_hal*, u_int);
HAL_BOOL __ahdecl(*ah_setTxDP)(struct ath_hal*, u_int, u_int32_t txdp);
u_int32_t __ahdecl(*ah_numTxPending)(struct ath_hal *, u_int q);
HAL_BOOL __ahdecl(*ah_startTxDma)(struct ath_hal*, u_int);
HAL_BOOL __ahdecl(*ah_stopTxDma)(struct ath_hal*, u_int);
HAL_BOOL __ahdecl(*ah_setupTxDesc)(struct ath_hal *, struct ath_desc *,
u_int pktLen, u_int hdrLen,
HAL_PKT_TYPE type, u_int txPower,
u_int txRate0, u_int txTries0,
u_int keyIx, u_int antMode, u_int flags,
u_int rtsctsRate, u_int rtsctsDuration,
u_int compicvLen, u_int compivLen,
u_int comp);
HAL_BOOL __ahdecl(*ah_setupXTxDesc)(struct ath_hal *, struct ath_desc*,
u_int txRate1, u_int txTries1,
u_int txRate2, u_int txTries2,
u_int txRate3, u_int txTries3);
HAL_BOOL __ahdecl(*ah_fillTxDesc)(struct ath_hal *, struct ath_desc *,
u_int segLen, HAL_BOOL firstSeg,
HAL_BOOL lastSeg, const struct ath_desc *);
HAL_STATUS __ahdecl(*ah_procTxDesc)(struct ath_hal *, struct ath_desc*);
void __ahdecl(*ah_getTxIntrQueue)(struct ath_hal *, u_int32_t *);
void __ahdecl(*ah_reqTxIntrDesc)(struct ath_hal *, struct ath_desc*);
/* Receive Functions */
u_int32_t __ahdecl(*ah_getRxDP)(struct ath_hal*);
void __ahdecl(*ah_setRxDP)(struct ath_hal*, u_int32_t rxdp);
void __ahdecl(*ah_enableReceive)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_stopDmaReceive)(struct ath_hal*);
void __ahdecl(*ah_startPcuReceive)(struct ath_hal*);
void __ahdecl(*ah_stopPcuReceive)(struct ath_hal*);
void __ahdecl(*ah_setMulticastFilter)(struct ath_hal*,
u_int32_t filter0, u_int32_t filter1);
HAL_BOOL __ahdecl(*ah_setMulticastFilterIndex)(struct ath_hal*,
u_int32_t index);
HAL_BOOL __ahdecl(*ah_clrMulticastFilterIndex)(struct ath_hal*,
u_int32_t index);
u_int32_t __ahdecl(*ah_getRxFilter)(struct ath_hal*);
void __ahdecl(*ah_setRxFilter)(struct ath_hal*, u_int32_t);
HAL_BOOL __ahdecl(*ah_setupRxDesc)(struct ath_hal *, struct ath_desc *,
u_int32_t size, u_int flags);
HAL_STATUS __ahdecl(*ah_procRxDesc)(struct ath_hal *, struct ath_desc *,
u_int32_t phyAddr, struct ath_desc *next,
u_int64_t tsf);
void __ahdecl(*ah_rxMonitor)(struct ath_hal *,
const HAL_NODE_STATS *, HAL_CHANNEL *);
void __ahdecl(*ah_procMibEvent)(struct ath_hal *,
const HAL_NODE_STATS *);
/* Misc Functions */
HAL_STATUS __ahdecl(*ah_getCapability)(struct ath_hal *,
HAL_CAPABILITY_TYPE, u_int32_t capability,
u_int32_t *result);
HAL_BOOL __ahdecl(*ah_setCapability)(struct ath_hal *,
HAL_CAPABILITY_TYPE, u_int32_t capability,
u_int32_t setting, HAL_STATUS *);
HAL_BOOL __ahdecl(*ah_getDiagState)(struct ath_hal *, int request,
const void *args, u_int32_t argsize,
void **result, u_int32_t *resultsize);
void __ahdecl(*ah_getMacAddress)(struct ath_hal *, u_int8_t *);
HAL_BOOL __ahdecl(*ah_setMacAddress)(struct ath_hal *, const u_int8_t*);
void __ahdecl(*ah_getBssIdMask)(struct ath_hal *, u_int8_t *);
HAL_BOOL __ahdecl(*ah_setBssIdMask)(struct ath_hal *, const u_int8_t*);
HAL_BOOL __ahdecl(*ah_setRegulatoryDomain)(struct ath_hal*,
u_int16_t, HAL_STATUS *);
void __ahdecl(*ah_setLedState)(struct ath_hal*, HAL_LED_STATE);
void __ahdecl(*ah_writeAssocid)(struct ath_hal*,
const u_int8_t *bssid, u_int16_t assocId);
HAL_BOOL __ahdecl(*ah_gpioCfgOutput)(struct ath_hal *, u_int32_t gpio);
HAL_BOOL __ahdecl(*ah_gpioCfgInput)(struct ath_hal *, u_int32_t gpio);
u_int32_t __ahdecl(*ah_gpioGet)(struct ath_hal *, u_int32_t gpio);
HAL_BOOL __ahdecl(*ah_gpioSet)(struct ath_hal *,
u_int32_t gpio, u_int32_t val);
void __ahdecl(*ah_gpioSetIntr)(struct ath_hal*, u_int, u_int32_t);
u_int32_t __ahdecl(*ah_getTsf32)(struct ath_hal*);
u_int64_t __ahdecl(*ah_getTsf64)(struct ath_hal*);
void __ahdecl(*ah_resetTsf)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_detectCardPresent)(struct ath_hal*);
void __ahdecl(*ah_updateMibCounters)(struct ath_hal*,
HAL_MIB_STATS*);
HAL_RFGAIN __ahdecl(*ah_getRfGain)(struct ath_hal*);
u_int __ahdecl(*ah_getDefAntenna)(struct ath_hal*);
void __ahdecl(*ah_setDefAntenna)(struct ath_hal*, u_int);
HAL_ANT_SETTING __ahdecl(*ah_getAntennaSwitch)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_setAntennaSwitch)(struct ath_hal*,
HAL_ANT_SETTING);
HAL_BOOL __ahdecl(*ah_setSlotTime)(struct ath_hal*, u_int);
u_int __ahdecl(*ah_getSlotTime)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_setAckTimeout)(struct ath_hal*, u_int);
u_int __ahdecl(*ah_getAckTimeout)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_setAckCTSRate)(struct ath_hal*, u_int);
u_int __ahdecl(*ah_getAckCTSRate)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_setCTSTimeout)(struct ath_hal*, u_int);
u_int __ahdecl(*ah_getCTSTimeout)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_setDecompMask)(struct ath_hal*, u_int16_t, int);
void __ahdecl(*ah_setCoverageClass)(struct ath_hal*, u_int8_t, int);
/* Key Cache Functions */
u_int32_t __ahdecl(*ah_getKeyCacheSize)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_resetKeyCacheEntry)(struct ath_hal*, u_int16_t);
HAL_BOOL __ahdecl(*ah_isKeyCacheEntryValid)(struct ath_hal *,
u_int16_t);
HAL_BOOL __ahdecl(*ah_setKeyCacheEntry)(struct ath_hal*,
u_int16_t, const HAL_KEYVAL *,
const u_int8_t *, int);
HAL_BOOL __ahdecl(*ah_setKeyCacheEntryMac)(struct ath_hal*,
u_int16_t, const u_int8_t *);
/* Power Management Functions */
HAL_BOOL __ahdecl(*ah_setPowerMode)(struct ath_hal*,
HAL_POWER_MODE mode, int setChip);
HAL_POWER_MODE __ahdecl(*ah_getPowerMode)(struct ath_hal*);
int16_t __ahdecl(*ah_getChanNoise)(struct ath_hal *, HAL_CHANNEL *);
/* Beacon Management Functions */
void __ahdecl(*ah_setBeaconTimers)(struct ath_hal*,
const HAL_BEACON_TIMERS *);
/* NB: deprecated, use ah_setBeaconTimers instead */
void __ahdecl(*ah_beaconInit)(struct ath_hal *,
u_int32_t nexttbtt, u_int32_t intval);
void __ahdecl(*ah_setStationBeaconTimers)(struct ath_hal*,
const HAL_BEACON_STATE *);
void __ahdecl(*ah_resetStationBeaconTimers)(struct ath_hal*);
/* Interrupt functions */
HAL_BOOL __ahdecl(*ah_isInterruptPending)(struct ath_hal*);
HAL_BOOL __ahdecl(*ah_getPendingInterrupts)(struct ath_hal*, HAL_INT*);
HAL_INT __ahdecl(*ah_getInterrupts)(struct ath_hal*);
HAL_INT __ahdecl(*ah_setInterrupts)(struct ath_hal*, HAL_INT);
};
/*
* Check the PCI vendor ID and device ID against Atheros' values
* and return a printable description for any Atheros hardware.
* AH_NULL is returned if the ID's do not describe Atheros hardware.
*/
extern const char *__ahdecl ath_hal_probe(u_int16_t vendorid, u_int16_t devid);
/*
* Attach the HAL for use with the specified device. The device is
* defined by the PCI device ID. The caller provides an opaque pointer
* to an upper-layer data structure (HAL_SOFTC) that is stored in the
* HAL state block for later use. Hardware register accesses are done
* using the specified bus tag and handle. On successful return a
* reference to a state block is returned that must be supplied in all
* subsequent HAL calls. Storage associated with this reference is
* dynamically allocated and must be freed by calling the ah_detach
* method when the client is done. If the attach operation fails a
* null (AH_NULL) reference will be returned and a status code will
* be returned if the status parameter is non-zero.
*/
extern struct ath_hal * __ahdecl ath_hal_attach(u_int16_t devid, HAL_SOFTC,
HAL_BUS_TAG, HAL_BUS_HANDLE, HAL_STATUS* status);
/*
* Set the Vendor ID for Vendor SKU's which can modify the
* channel properties returned by ath_hal_init_channels.
* Return AH_TRUE if set succeeds
*/
extern HAL_BOOL __ahdecl ath_hal_setvendor(struct ath_hal *, u_int32_t );
/*
* Return a list of channels available for use with the hardware.
* The list is based on what the hardware is capable of, the specified
* country code, the modeSelect mask, and whether or not outdoor
* channels are to be permitted.
*
* The channel list is returned in the supplied array. maxchans
* defines the maximum size of this array. nchans contains the actual
* number of channels returned. If a problem occurred or there were
* no channels that met the criteria then AH_FALSE is returned.
*/
extern HAL_BOOL __ahdecl ath_hal_init_channels(struct ath_hal *,
HAL_CHANNEL *chans, u_int maxchans, u_int *nchans,
u_int8_t *regclassids, u_int maxregids, u_int *nregids,
HAL_CTRY_CODE cc, u_int16_t modeSelect,
HAL_BOOL enableOutdoor, HAL_BOOL enableExtendedChannels);
/*
* Calibrate noise floor data following a channel scan or similar.
* This must be called prior retrieving noise floor data.
*/
extern void __ahdecl ath_hal_process_noisefloor(struct ath_hal *ah);
/*
* Return bit mask of wireless modes supported by the hardware.
*/
extern u_int __ahdecl ath_hal_getwirelessmodes(struct ath_hal*, HAL_CTRY_CODE);
/*
* Return rate table for specified mode (11a, 11b, 11g, etc).
*/
extern const HAL_RATE_TABLE * __ahdecl ath_hal_getratetable(struct ath_hal *,
u_int mode);
/*
* Calculate the transmit duration of a frame.
*/
extern u_int16_t __ahdecl ath_hal_computetxtime(struct ath_hal *,
const HAL_RATE_TABLE *rates, u_int32_t frameLen,
u_int16_t rateix, HAL_BOOL shortPreamble);
/*
* Return if device is public safety.
*/
extern HAL_BOOL __ahdecl ath_hal_ispublicsafetysku(struct ath_hal *);
/*
* Convert between IEEE channel number and channel frequency
* using the specified channel flags; e.g. CHANNEL_2GHZ.
*/
extern int __ahdecl ath_hal_mhz2ieee(struct ath_hal *, u_int mhz, u_int flags);
/*
* Return a version string for the HAL release.
*/
extern char ath_hal_version[];
/*
* Return a NULL-terminated array of build/configuration options.
*/
extern const char* ath_hal_buildopts[];
#endif /* _ATH_AH_H_ */
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