/*
** ioctl utilites
*/
-static int32 wl_dev_bufvar_get(struct net_device *dev, int8 *name, int8 *buf,
+static int32 wl_dev_bufvar_get(struct net_device *dev, s8 *name, s8 *buf,
int32 buf_len);
-static __used int32 wl_dev_bufvar_set(struct net_device *dev, int8 *name,
- int8 *buf, int32 len);
-static int32 wl_dev_intvar_set(struct net_device *dev, int8 *name, int32 val);
-static int32 wl_dev_intvar_get(struct net_device *dev, int8 *name,
+static __used int32 wl_dev_bufvar_set(struct net_device *dev, s8 *name,
+ s8 *buf, int32 len);
+static int32 wl_dev_intvar_set(struct net_device *dev, s8 *name, int32 val);
+static int32 wl_dev_intvar_get(struct net_device *dev, s8 *name,
int32 *retval);
static int32 wl_dev_ioctl(struct net_device *dev, uint32 cmd, void *arg,
uint32 len);
int32 scan_unassoc_time);
static int32 wl_dongle_offload(struct net_device *ndev, int32 arpoe,
int32 arp_ol);
-static int32 wl_pattern_atoh(int8 *src, int8 *dst);
+static int32 wl_pattern_atoh(s8 *src, s8 *dst);
static int32 wl_dongle_filter(struct net_device *ndev, uint32 filter_mode);
static int32 wl_update_wiphybands(struct wl_priv *wl);
#endif /* !EMBEDDED_PLATFORM */
static void wl_term_iscan(struct wl_priv *wl);
static int32 wl_init_iscan(struct wl_priv *wl);
static int32 wl_iscan_thread(void *data);
-static int32 wl_dev_iovar_setbuf(struct net_device *dev, int8 *iovar,
+static int32 wl_dev_iovar_setbuf(struct net_device *dev, s8 *iovar,
void *param, int32 paramlen, void *bufptr,
int32 buflen);
-static int32 wl_dev_iovar_getbuf(struct net_device *dev, int8 *iovar,
+static int32 wl_dev_iovar_getbuf(struct net_device *dev, s8 *iovar,
void *param, int32 paramlen, void *bufptr,
int32 buflen);
static int32 wl_run_iscan(struct wl_iscan_ctrl *iscan, struct wlc_ssid *ssid,
#if (WL_DBG_LEVEL > 0)
#define WL_DBG_ESTR_MAX 32
-static int8 wl_dbg_estr[][WL_DBG_ESTR_MAX] = {
+static s8 wl_dbg_estr[][WL_DBG_ESTR_MAX] = {
"SET_SSID", "JOIN", "START", "AUTH", "AUTH_IND",
"DEAUTH", "DEAUTH_IND", "ASSOC", "ASSOC_IND", "REASSOC",
"REASSOC_IND", "DISASSOC", "DISASSOC_IND", "QUIET_START", "QUIET_END",
}
static int32
-wl_dev_iovar_setbuf(struct net_device *dev, int8 * iovar, void *param,
+wl_dev_iovar_setbuf(struct net_device *dev, s8 * iovar, void *param,
int32 paramlen, void *bufptr, int32 buflen)
{
int32 iolen;
}
static int32
-wl_dev_iovar_getbuf(struct net_device *dev, int8 * iovar, void *param,
+wl_dev_iovar_getbuf(struct net_device *dev, s8 * iovar, void *param,
int32 paramlen, void *bufptr, int32 buflen)
{
int32 iolen;
return err;
}
-static int32 wl_dev_intvar_set(struct net_device *dev, int8 *name, int32 val)
+static int32 wl_dev_intvar_set(struct net_device *dev, s8 *name, int32 val)
{
- int8 buf[WLC_IOCTL_SMLEN];
+ s8 buf[WLC_IOCTL_SMLEN];
uint32 len;
int32 err = 0;
}
static int32
-wl_dev_intvar_get(struct net_device *dev, int8 *name, int32 *retval)
+wl_dev_intvar_get(struct net_device *dev, s8 *name, int32 *retval)
{
union {
- int8 buf[WLC_IOCTL_SMLEN];
+ s8 buf[WLC_IOCTL_SMLEN];
int32 val;
} var;
uint32 len;
wl_update_pmklist(struct net_device *dev, struct wl_pmk_list *pmk_list,
int32 err)
{
- int8 eabuf[ETHER_ADDR_STR_LEN];
+ s8 eabuf[ETHER_ADDR_STR_LEN];
int i, j;
memset(eabuf, 0, ETHER_ADDR_STR_LEN);
struct cfg80211_pmksa *pmksa)
{
struct wl_priv *wl = wiphy_to_wl(wiphy);
- int8 eabuf[ETHER_ADDR_STR_LEN];
+ s8 eabuf[ETHER_ADDR_STR_LEN];
int32 err = 0;
int i;
struct cfg80211_pmksa *pmksa)
{
struct wl_priv *wl = wiphy_to_wl(wiphy);
- int8 eabuf[ETHER_ADDR_STR_LEN];
+ s8 eabuf[ETHER_ADDR_STR_LEN];
struct _pmkid_list pmkid;
int32 err = 0;
int i;
if (wl_is_linkup(wl, e)) {
wl_link_up(wl);
if (wl_is_ibssmode(wl)) {
- cfg80211_ibss_joined(ndev, (int8 *)&e->addr,
+ cfg80211_ibss_joined(ndev, (s8 *)&e->addr,
GFP_KERNEL);
WL_DBG(("joined in IBSS network\n"));
} else {
}
static __used int32
-wl_dev_bufvar_set(struct net_device *dev, int8 *name, int8 *buf, int32 len)
+wl_dev_bufvar_set(struct net_device *dev, s8 *name, s8 *buf, int32 len)
{
struct wl_priv *wl = ndev_to_wl(dev);
uint32 buflen;
}
static int32
-wl_dev_bufvar_get(struct net_device *dev, int8 *name, int8 *buf,
+wl_dev_bufvar_get(struct net_device *dev, s8 *name, s8 *buf,
int32 buf_len)
{
struct wl_priv *wl = ndev_to_wl(dev);
ssid = (struct wlc_ssid *)wl_read_prof(wl, WL_PROF_SSID);
bss =
- cfg80211_get_bss(wl_to_wiphy(wl), NULL, (int8 *)&wl->bssid,
+ cfg80211_get_bss(wl_to_wiphy(wl), NULL, (s8 *)&wl->bssid,
ssid->SSID, ssid->SSID_len, WLAN_CAPABILITY_ESS,
WLAN_CAPABILITY_ESS);
uint32 event_type = ntoh32(e->event_type);
struct wl_priv *wl = ndev_to_wl(ndev);
#if (WL_DBG_LEVEL > 0)
- int8 *estr = (event_type <= sizeof(wl_dbg_estr) / WL_DBG_ESTR_MAX - 1) ?
- wl_dbg_estr[event_type] : (int8 *) "Unknown";
+ s8 *estr = (event_type <= sizeof(wl_dbg_estr) / WL_DBG_ESTR_MAX - 1) ?
+ wl_dbg_estr[event_type] : (s8 *) "Unknown";
#endif /* (WL_DBG_LEVEL > 0) */
WL_DBG(("event_type (%d):" "WLC_E_" "%s\n", event_type, estr));
if (likely(!wl_enq_event(wl, event_type, e, data)))
static int32
wl_dongle_glom(struct net_device *ndev, uint32 glom, uint32 dongle_align)
{
- int8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
+ s8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
'\0' + bitvec */
int32 err = 0;
static int32
wl_dongle_roam(struct net_device *ndev, uint32 roamvar, uint32 bcn_timeout)
{
- int8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
+ s8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
'\0' + bitvec */
int32 err = 0;
static int32 wl_dongle_eventmsg(struct net_device *ndev)
{
- int8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
+ s8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
'\0' + bitvec */
- int8 eventmask[WL_EVENTING_MASK_LEN];
+ s8 eventmask[WL_EVENTING_MASK_LEN];
int32 err = 0;
/* Setup event_msgs */
static int32
wl_dongle_offload(struct net_device *ndev, int32 arpoe, int32 arp_ol)
{
- int8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
+ s8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
'\0' + bitvec */
int32 err = 0;
return err;
}
-static int32 wl_pattern_atoh(int8 *src, int8 *dst)
+static int32 wl_pattern_atoh(s8 *src, s8 *dst)
{
#define strtoul(nptr, endptr, base) bcm_strtoul((nptr), (endptr), (base))
int i;
static int32 wl_dongle_filter(struct net_device *ndev, uint32 filter_mode)
{
- int8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
+ s8 iovbuf[WL_EVENTING_MASK_LEN + 12]; /* Room for "event_msgs" +
'\0' + bitvec */
- const int8 *str;
+ const s8 *str;
struct wl_pkt_filter pkt_filter;
struct wl_pkt_filter *pkt_filterp;
int32 buf_len;
int32 str_len;
uint32 mask_size;
uint32 pattern_size;
- int8 buf[256];
+ s8 buf[256];
int32 err = 0;
/* add a default packet filter pattern */
{
struct wiphy *wiphy;
int32 phy_list;
- int8 phy;
+ s8 phy;
int32 err = 0;
if (unlikely
return dev->driver_data;
}
-int32 wl_cfg80211_read_fw(int8 *buf, uint32 size)
+int32 wl_cfg80211_read_fw(s8 *buf, uint32 size)
{
const struct firmware *fw_entry;
struct wl_priv *wl;
wl->fw->ptr = 0;
}
-void *wl_cfg80211_request_fw(int8 *file_name)
+void *wl_cfg80211_request_fw(s8 *file_name)
{
struct wl_priv *wl;
const struct firmware *fw_entry = NULL;
return (void *)fw_entry->data;
}
-int8 *wl_cfg80211_get_fwname(void)
+s8 *wl_cfg80211_get_fwname(void)
{
struct wl_priv *wl;
return wl->fw->fw_name;
}
-int8 *wl_cfg80211_get_nvramname(void)
+s8 *wl_cfg80211_get_nvramname(void)
{
struct wl_priv *wl;
struct list_head eq_list;
uint32 etype;
wl_event_msg_t emsg;
- int8 edata[1];
+ s8 edata[1];
};
/* security information with currently associated ap */
struct wl_ibss {
u8 beacon_interval; /* in millisecond */
u8 atim; /* in millisecond */
- int8 join_only;
+ s8 join_only;
u8 band;
u8 channel;
};
struct completion exited;
struct wl_iscan_eloop el;
void *data;
- int8 ioctl_buf[WLC_IOCTL_SMLEN];
- int8 scan_buf[WL_ISCAN_BUF_MAX];
+ s8 ioctl_buf[WLC_IOCTL_SMLEN];
+ s8 scan_buf[WL_ISCAN_BUF_MAX];
};
/* association inform */
const struct firmware *fw_entry;
ulong status;
uint32 ptr;
- int8 fw_name[WL_FILE_NAME_MAX];
- int8 nvram_name[WL_FILE_NAME_MAX];
+ s8 fw_name[WL_FILE_NAME_MAX];
+ s8 nvram_name[WL_FILE_NAME_MAX];
};
/* assoc ie length */
extern int32 wl_cfg80211_down(void); /* dongle down */
extern void wl_cfg80211_dbg_level(uint32 level); /* set dongle
debugging level */
-extern void *wl_cfg80211_request_fw(int8 *file_name); /* request fw /nvram
+extern void *wl_cfg80211_request_fw(s8 *file_name); /* request fw /nvram
downloading */
-extern int32 wl_cfg80211_read_fw(int8 *buf, uint32 size); /* read fw
+extern int32 wl_cfg80211_read_fw(s8 *buf, uint32 size); /* read fw
image */
extern void wl_cfg80211_release_fw(void); /* release fw */
-extern int8 *wl_cfg80211_get_fwname(void); /* get firmware name for
+extern s8 *wl_cfg80211_get_fwname(void); /* get firmware name for
the dongle */
-extern int8 *wl_cfg80211_get_nvramname(void); /* get nvram name for
+extern s8 *wl_cfg80211_get_nvramname(void); /* get nvram name for
the dongle */
#endif /* _wl_cfg80211_h_ */
struct iw_range *range = (struct iw_range *)extra;
wl_uint32_list_t *list;
wl_rateset_t rateset;
- int8 *channels;
+ s8 *channels;
int error, i, k;
uint sf, ch;
int bcm_xdr_unpack_uint32(bcm_xdr_buf_t *b, uint32 *pval);
int bcm_xdr_pack_int32(bcm_xdr_buf_t *b, int32 val);
int bcm_xdr_unpack_int32(bcm_xdr_buf_t *b, int32 *pval);
-int bcm_xdr_pack_int8(bcm_xdr_buf_t *b, int8 val);
-int bcm_xdr_unpack_int8(bcm_xdr_buf_t *b, int8 *pval);
+int bcm_xdr_pack_s8(bcm_xdr_buf_t *b, s8 val);
+int bcm_xdr_unpack_s8(bcm_xdr_buf_t *b, s8 *pval);
int bcm_xdr_pack_opaque(bcm_xdr_buf_t *b, uint len, void *data);
int bcm_xdr_unpack_opaque(bcm_xdr_buf_t *b, uint len, void **pdata);
int bcm_xdr_unpack_opaque_cpy(bcm_xdr_buf_t *b, uint len, void *data);
#define BCM_IOV_TYPE_INIT { \
"void", \
"bool", \
- "int8", \
+ "s8", \
"u8", \
"int16", \
"uint16", \
BWL_PRE_PACKED_STRUCT struct wlc_d11rxhdr {
d11rxhdr_t rxhdr;
uint32 tsf_l; /* TSF_L reading */
- int8 rssi; /* computed instanteneous rssi in BMAC */
- int8 rxpwr0; /* obsoleted, place holder for legacy ROM code. use rxpwr[] */
- int8 rxpwr1; /* obsoleted, place holder for legacy ROM code. use rxpwr[] */
- int8 do_rssi_ma; /* do per-pkt sampling for per-antenna ma in HIGH */
- int8 rxpwr[WL_RSSI_ANT_MAX]; /* rssi for supported antennas */
+ s8 rssi; /* computed instanteneous rssi in BMAC */
+ s8 rxpwr0; /* obsoleted, place holder for legacy ROM code. use rxpwr[] */
+ s8 rxpwr1; /* obsoleted, place holder for legacy ROM code. use rxpwr[] */
+ s8 do_rssi_ma; /* do per-pkt sampling for per-antenna ma in HIGH */
+ s8 rxpwr[WL_RSSI_ANT_MAX]; /* rssi for supported antennas */
} BWL_POST_PACKED_STRUCT;
/* PhyRxStatus_0: */
typedef unsigned long ulong;
#endif
-/* define [u]int8/16/32/64, uintptr */
+/* define [u]int16/32/64, uintptr */
#ifndef TYPEDEF_UINT16
typedef unsigned short uint16;
typedef unsigned int uintptr;
#endif
-#ifndef TYPEDEF_INT8
-typedef signed char int8;
-#endif
-
#ifndef TYPEDEF_INT16
typedef signed short int16;
#endif
#undef TYPEDEF_UINT16
#undef TYPEDEF_UINT32
#undef TYPEDEF_UINTPTR
-#undef TYPEDEF_INT8
#undef TYPEDEF_INT16
#undef TYPEDEF_INT32
#undef TYPEDEF_FLOAT32
uint16 atim_window; /* units are Kusec */
u8 dtim_period; /* DTIM period */
int16 RSSI; /* receive signal strength (in dBm) */
- int8 phy_noise; /* noise (in dBm) */
+ s8 phy_noise; /* noise (in dBm) */
uint32 ie_length; /* byte length of Information Elements */
/* variable length Information Elements */
} wl_bss_info_107_t;
uint16 atim_window; /* units are Kusec */
u8 dtim_period; /* DTIM period */
int16 RSSI; /* receive signal strength (in dBm) */
- int8 phy_noise; /* noise (in dBm) */
+ s8 phy_noise; /* noise (in dBm) */
u8 n_cap; /* BSS is 802.11N Capable */
uint32 nbss_cap; /* 802.11N BSS Capabilities (based on HT_CAP_*) */
uint16 atim_window; /* units are Kusec */
u8 dtim_period; /* DTIM period */
int16 RSSI; /* receive signal strength (in dBm) */
- int8 phy_noise; /* noise (in dBm) */
+ s8 phy_noise; /* noise (in dBm) */
u8 n_cap; /* BSS is 802.11N Capable */
uint32 nbss_cap; /* 802.11N BSS Capabilities (based on HT_CAP_*) */
#define WL_BSS_FLAGS_RSSI_ONCHANNEL 0x04 /* rssi info was received on channel (vs offchannel) */
typedef struct wl_extdscan_params {
- int8 nprobes; /* 0, passive, otherwise active */
- int8 split_scan; /* split scan */
- int8 band; /* band */
- int8 pad;
+ s8 nprobes; /* 0, passive, otherwise active */
+ s8 split_scan; /* split scan */
+ s8 band; /* band */
+ s8 pad;
wlc_ssid_t ssid[WLC_EXTDSCAN_MAX_SSID]; /* ssid list */
uint32 tx_rate; /* in 500ksec units */
wl_scan_type_t scan_type; /* enum */
typedef struct wl_scan_params {
wlc_ssid_t ssid; /* default: {0, ""} */
struct ether_addr bssid; /* default: bcast */
- int8 bss_type; /* default: any,
+ s8 bss_type; /* default: any,
* DOT11_BSSTYPE_ANY/INFRASTRUCTURE/INDEPENDENT
*/
u8 scan_type; /* flags, 0 use default */
#define WL_RM_FLAG_REFUSED (1<<3)
typedef struct wl_rm_req_elt {
- int8 type;
- int8 flags;
+ s8 type;
+ s8 flags;
chanspec_t chanspec;
uint32 token; /* token for this measurement */
uint32 tsf_h; /* TSF high 32-bits of Measurement start time */
#define WL_RM_REQ_FIXED_LEN OFFSETOF(wl_rm_req_t, req)
typedef struct wl_rm_rep_elt {
- int8 type;
- int8 flags;
+ s8 type;
+ s8 flags;
chanspec_t chanspec;
uint32 token; /* token for this measurement */
uint32 tsf_h; /* TSF high 32-bits of Measurement start time */
#define WL_RPI_REP_BIN_NUM 8
typedef struct wl_rm_rpi_rep {
u8 rpi[WL_RPI_REP_BIN_NUM];
- int8 rpi_max[WL_RPI_REP_BIN_NUM];
+ s8 rpi_max[WL_RPI_REP_BIN_NUM];
} wl_rm_rpi_rep_t;
typedef struct wl_rm_rep {
} wl_po_t;
/* a large TX Power as an init value to factor out of MIN() calculations,
- * keep low enough to fit in an int8, units are .25 dBm
+ * keep low enough to fit in an s8, units are .25 dBm
*/
#define WLC_TXPWR_MAX (127) /* ~32 dBm = 1,500 mW */
typedef struct {
uint32 version; /* version field */
uint32 count; /* number of valid antenna rssi */
- int8 rssi_ant[WL_RSSI_ANT_MAX]; /* rssi per antenna */
+ s8 rssi_ant[WL_RSSI_ANT_MAX]; /* rssi per antenna */
} wl_rssi_ant_t;
#define NUM_PWRCTRL_RATES 12
u8 txpwr_bphy_cck_max[NUM_PWRCTRL_RATES]; /* Max CCK power for this band (SROM) */
u8 txpwr_bphy_ofdm_max; /* Max OFDM power for this band (SROM) */
u8 txpwr_aphy_max[NUM_PWRCTRL_RATES]; /* Max power for A band (SROM) */
- int8 txpwr_antgain[2]; /* Ant gain for each band - from SROM */
+ s8 txpwr_antgain[2]; /* Ant gain for each band - from SROM */
u8 txpwr_est_Pout_gofdm; /* Pwr estimate for 2.4 OFDM */
} tx_power_legacy_t;
chanspec_t local_chanspec; /* channel on which we are associated */
u8 local_max; /* local max according to the AP */
u8 local_constraint; /* local constraint according to the AP */
- int8 antgain[2]; /* Ant gain for each band - from SROM */
+ s8 antgain[2]; /* Ant gain for each band - from SROM */
u8 rf_cores; /* count of RF Cores being reported */
u8 est_Pout[4]; /* Latest tx power out estimate per RF
* chain without adjustment
chanspec_t local_chanspec; /* channel on which we are associated */
u8 local_max; /* local max according to the AP */
u8 local_constraint; /* local constraint according to the AP */
- int8 antgain[2]; /* Ant gain for each band - from SROM */
+ s8 antgain[2]; /* Ant gain for each band - from SROM */
u8 rf_cores; /* count of RF Cores being reported */
u8 est_Pout[4]; /* Latest tx power out estimate per RF chain */
u8 est_Pout_act[4]; /* Latest tx power out estimate per RF chain
static void wlc_phy_timercb_phycal(void *arg);
static bool wlc_phy_noise_calc_phy(phy_info_t *pi, uint32 *cmplx_pwr,
- int8 *pwr_ant);
+ s8 *pwr_ant);
static void wlc_phy_cal_perical_mphase_schedule(phy_info_t *pi, uint delay);
-static void wlc_phy_noise_cb(phy_info_t *pi, u8 channel, int8 noise_dbm);
+static void wlc_phy_noise_cb(phy_info_t *pi, u8 channel, s8 noise_dbm);
static void wlc_phy_noise_sample_request(wlc_phy_t *pih, u8 reason,
u8 ch);
struct txpwr_limits *tp, chanspec_t);
static bool wlc_phy_cal_txpower_recalc_sw(phy_info_t *pi);
-static int8 wlc_user_txpwr_antport_to_rfport(phy_info_t *pi, uint chan,
+static s8 wlc_user_txpwr_antport_to_rfport(phy_info_t *pi, uint chan,
uint32 band, u8 rate);
static void wlc_phy_upd_env_txpwr_rate_limits(phy_info_t *pi, uint32 band);
-static int8 wlc_phy_env_measure_vbat(phy_info_t *pi);
-static int8 wlc_phy_env_measure_temperature(phy_info_t *pi);
+static s8 wlc_phy_env_measure_vbat(phy_info_t *pi);
+static s8 wlc_phy_env_measure_temperature(phy_info_t *pi);
char *phy_getvar(phy_info_t *pi, const char *name)
{
power->flags &=
~(WL_TX_POWER_F_HW | WL_TX_POWER_F_ENABLED);
- wlc_lcnphy_get_tssi(pi, (int8 *) &power->est_Pout[0],
- (int8 *) &power->est_Pout_cck);
+ wlc_lcnphy_get_tssi(pi, (s8 *) &power->est_Pout[0],
+ (s8 *) &power->est_Pout_cck);
}
wlc_phyreg_exit(ppi);
}
}
static bool
-wlc_phy_noise_calc_phy(phy_info_t *pi, uint32 *cmplx_pwr, int8 *pwr_ant)
+wlc_phy_noise_calc_phy(phy_info_t *pi, uint32 *cmplx_pwr, s8 *pwr_ant)
{
- int8 cmplx_pwr_dbm[PHY_CORE_MAX];
+ s8 cmplx_pwr_dbm[PHY_CORE_MAX];
u8 i;
bzero((u8 *) cmplx_pwr_dbm, sizeof(cmplx_pwr_dbm));
for (i = 0; i < pi->pubpi.phy_corenum; i++) {
if (NREV_GE(pi->pubpi.phy_rev, 3))
- cmplx_pwr_dbm[i] += (int8) PHY_NOISE_OFFSETFACT_4322;
+ cmplx_pwr_dbm[i] += (s8) PHY_NOISE_OFFSETFACT_4322;
else
- cmplx_pwr_dbm[i] += (int8) (16 - (15) * 3 - 70);
+ cmplx_pwr_dbm[i] += (s8) (16 - (15) * 3 - 70);
}
for (i = 0; i < pi->pubpi.phy_corenum; i++) {
wlc_phy_noise_sample_request(wlc_phy_t *pih, u8 reason, u8 ch)
{
phy_info_t *pi = (phy_info_t *) pih;
- int8 noise_dbm = PHY_NOISE_FIXED_VAL_NPHY;
+ s8 noise_dbm = PHY_NOISE_FIXED_VAL_NPHY;
bool sampling_in_progress = (pi->phynoise_state != 0);
bool wait_for_intr = TRUE;
} else {
wlapi_suspend_mac_and_wait(pi->sh->physhim);
wlc_lcnphy_deaf_mode(pi, (bool) 0);
- noise_dbm = (int8) wlc_lcnphy_rx_signal_power(pi, 20);
+ noise_dbm = (s8) wlc_lcnphy_rx_signal_power(pi, 20);
wlc_lcnphy_deaf_mode(pi, (bool) 1);
wlapi_enable_mac(pi->sh->physhim);
wait_for_intr = FALSE;
} else {
phy_iq_est_t est[PHY_CORE_MAX];
uint32 cmplx_pwr[PHY_CORE_MAX];
- int8 noise_dbm_ant[PHY_CORE_MAX];
+ s8 noise_dbm_ant[PHY_CORE_MAX];
uint16 log_num_samps, num_samps, classif_state = 0;
u8 wait_time = 32;
u8 wait_crs = 0;
wlc_phy_noise_sample_request(pih, PHY_NOISE_SAMPLE_EXTERNAL, channel);
}
-static void wlc_phy_noise_cb(phy_info_t *pi, u8 channel, int8 noise_dbm)
+static void wlc_phy_noise_cb(phy_info_t *pi, u8 channel, s8 noise_dbm)
{
if (!pi->phynoise_state)
return;
}
-static int8 wlc_phy_noise_read_shmem(phy_info_t *pi)
+static s8 wlc_phy_noise_read_shmem(phy_info_t *pi)
{
uint32 cmplx_pwr[PHY_CORE_MAX];
- int8 noise_dbm_ant[PHY_CORE_MAX];
+ s8 noise_dbm_ant[PHY_CORE_MAX];
uint16 lo, hi;
uint32 cmplx_pwr_tot = 0;
- int8 noise_dbm = PHY_NOISE_FIXED_VAL_NPHY;
+ s8 noise_dbm = PHY_NOISE_FIXED_VAL_NPHY;
u8 idx, core;
ASSERT(pi->pubpi.phy_corenum <= PHY_CORE_MAX);
phy_info_t *pi = (phy_info_t *) pih;
uint16 jssi_aux;
u8 channel = 0;
- int8 noise_dbm = PHY_NOISE_FIXED_VAL_NPHY;
+ s8 noise_dbm = PHY_NOISE_FIXED_VAL_NPHY;
if (ISLCNPHY(pi)) {
uint32 cmplx_pwr, cmplx_pwr0, cmplx_pwr1;
if (pwr_offset_dB > 127)
pwr_offset_dB -= 256;
- noise_dbm += (int8) (pwr_offset_dB - 30);
+ noise_dbm += (s8) (pwr_offset_dB - 30);
gain_dB = (status_0 & 0x1ff);
- noise_dbm -= (int8) (gain_dB);
+ noise_dbm -= (s8) (gain_dB);
} else {
noise_dbm = PHY_NOISE_FIXED_VAL_LCNPHY;
}
}
-int8 lcnphy_gain_index_offset_for_pkt_rssi[] = {
+s8 lcnphy_gain_index_offset_for_pkt_rssi[] = {
8,
8,
8,
0
};
-void wlc_phy_compute_dB(uint32 *cmplx_pwr, int8 *p_cmplx_pwr_dB, u8 core)
+void wlc_phy_compute_dB(uint32 *cmplx_pwr, s8 *p_cmplx_pwr_dB, u8 core)
{
u8 shift_ct, lsb, msb, secondmsb, i;
uint32 tmp;
msb = shift_ct;
}
secondmsb = (u8) ((cmplx_pwr[i] >> (msb - 1)) & 1);
- p_cmplx_pwr_dB[i] = (int8) (3 * msb + 2 * secondmsb);
+ p_cmplx_pwr_dB[i] = (s8) (3 * msb + 2 * secondmsb);
}
}
}
end:
- wlc_rxhdr->rssi = (int8) rssi;
+ wlc_rxhdr->rssi = (s8) rssi;
}
void wlc_phy_freqtrack_start(wlc_phy_t *pih)
uint k;
for (i = 0; i < MA_WINDOW_SZ; i++) {
- pi->sh->phy_noise_window[i] = (int8) (rssi & 0xff);
+ pi->sh->phy_noise_window[i] = (s8) (rssi & 0xff);
}
if (ISLCNPHY(pi)) {
for (i = 0; i < MA_WINDOW_SZ; i++)
return active_bitmap;
}
-int8 wlc_phy_stf_ssmode_get(wlc_phy_t *pih, chanspec_t chanspec)
+s8 wlc_phy_stf_ssmode_get(wlc_phy_t *pih, chanspec_t chanspec)
{
phy_info_t *pi = (phy_info_t *) pih;
u8 siso_mcs_id, cdd_mcs_id;
}
}
-static int8
+static s8
wlc_user_txpwr_antport_to_rfport(phy_info_t *pi, uint chan, uint32 band,
u8 rate)
{
- int8 offset = 0;
+ s8 offset = 0;
if (!pi->user_txpwr_at_rfport)
return offset;
return offset;
}
-static int8 wlc_phy_env_measure_vbat(phy_info_t *pi)
+static s8 wlc_phy_env_measure_vbat(phy_info_t *pi)
{
if (ISLCNPHY(pi))
return wlc_lcnphy_vbatsense(pi, 0);
return 0;
}
-static int8 wlc_phy_env_measure_temperature(phy_info_t *pi)
+static s8 wlc_phy_env_measure_temperature(phy_info_t *pi)
{
if (ISLCNPHY(pi))
return wlc_lcnphy_tempsense_degree(pi, 0);
static void wlc_phy_upd_env_txpwr_rate_limits(phy_info_t *pi, uint32 band)
{
u8 i;
- int8 temp, vbat;
+ s8 temp, vbat;
for (i = 0; i < TXP_NUM_RATES; i++)
pi->txpwr_env_limit[i] = WLC_TXPWR_MAX;
}
void
-wlc_phy_get_pwrdet_offsets(phy_info_t *pi, int8 *cckoffset, int8 *ofdmoffset)
+wlc_phy_get_pwrdet_offsets(phy_info_t *pi, s8 *cckoffset, s8 *ofdmoffset)
{
*cckoffset = 0;
*ofdmoffset = 0;
return quotient;
}
-int8 wlc_phy_upd_rssi_offset(phy_info_t *pi, int8 rssi, chanspec_t chanspec)
+s8 wlc_phy_upd_rssi_offset(phy_info_t *pi, s8 rssi, chanspec_t chanspec)
{
return rssi;
extern void wlc_phy_stf_chain_get(wlc_phy_t *pih, u8 *txchain,
u8 *rxchain);
extern u8 wlc_phy_stf_chain_active_get(wlc_phy_t *pih);
-extern int8 wlc_phy_stf_ssmode_get(wlc_phy_t *pih, chanspec_t chanspec);
+extern s8 wlc_phy_stf_ssmode_get(wlc_phy_t *pih, chanspec_t chanspec);
extern void wlc_phy_ldpc_override_set(wlc_phy_t *ppi, bool val);
extern void wlc_phy_cal_perical(wlc_phy_t *ppi, u8 reason);
extern const u8 *wlc_phy_get_ofdm_rate_lookup(void);
-extern int8 wlc_phy_get_tx_power_offset_by_mcs(wlc_phy_t *ppi,
+extern s8 wlc_phy_get_tx_power_offset_by_mcs(wlc_phy_t *ppi,
u8 mcs_offset);
-extern int8 wlc_phy_get_tx_power_offset(wlc_phy_t *ppi, u8 tbl_offset);
+extern s8 wlc_phy_get_tx_power_offset(wlc_phy_t *ppi, u8 tbl_offset);
#endif /* _wlc_phy_h_ */
} aci_save_gphy_t;
typedef struct _lo_complex_t {
- int8 i;
- int8 q;
+ s8 i;
+ s8 q;
} lo_complex_abgphy_info_t;
typedef struct _nphy_iq_comp {
} nphy_iq_comp_t;
typedef struct _nphy_txpwrindex {
- int8 index;
- int8 index_internal;
- int8 index_internal_save;
+ s8 index;
+ s8 index_internal;
+ s8 index_internal_save;
uint16 AfectrlOverride;
uint16 AfeCtrlDacGain;
uint16 rad_gain;
} txiqcal_cache_t;
typedef struct _nphy_pwrctrl {
- int8 max_pwr_2g;
- int8 idle_targ_2g;
+ s8 max_pwr_2g;
+ s8 idle_targ_2g;
int16 pwrdet_2g_a1;
int16 pwrdet_2g_b0;
int16 pwrdet_2g_b1;
- int8 max_pwr_5gm;
- int8 idle_targ_5gm;
- int8 max_pwr_5gh;
- int8 max_pwr_5gl;
+ s8 max_pwr_5gm;
+ s8 idle_targ_5gm;
+ s8 max_pwr_5gh;
+ s8 max_pwr_5gl;
int16 pwrdet_5gm_a1;
int16 pwrdet_5gm_b0;
int16 pwrdet_5gm_b1;
int16 pwrdet_5gh_a1;
int16 pwrdet_5gh_b0;
int16 pwrdet_5gh_b1;
- int8 idle_targ_5gl;
- int8 idle_targ_5gh;
- int8 idle_tssi_2g;
- int8 idle_tssi_5g;
- int8 idle_tssi;
+ s8 idle_targ_5gl;
+ s8 idle_targ_5gh;
+ s8 idle_tssi_2g;
+ s8 idle_tssi_5g;
+ s8 idle_tssi;
int16 a1;
int16 b0;
int16 b1;
uint slow_timer;
uint glacial_timer;
u8 rx_antdiv;
- int8 phy_noise_window[MA_WINDOW_SZ];
+ s8 phy_noise_window[MA_WINDOW_SZ];
uint phy_noise_index;
u8 hw_phytxchain;
u8 hw_phyrxchain;
u8 tx_srom_max_rate_5g_mid[TXP_NUM_RATES];
u8 tx_srom_max_rate_5g_hi[TXP_NUM_RATES];
u8 tx_user_target[TXP_NUM_RATES];
- int8 tx_power_offset[TXP_NUM_RATES];
+ s8 tx_power_offset[TXP_NUM_RATES];
u8 tx_power_target[TXP_NUM_RATES];
srom_fem_t srom_fem2g;
u8 tx_power_max_rate_ind;
bool hwpwrctrl;
u8 nphy_txpwrctrl;
- int8 nphy_txrx_chain;
+ s8 nphy_txrx_chain;
bool phy_5g_pwrgain;
uint16 phy_wreg;
uint16 phy_wreg_limit;
- int8 n_preamble_override;
+ s8 n_preamble_override;
u8 antswitch;
u8 aa2g, aa5g;
- int8 idle_tssi[CH_5G_GROUP];
- int8 target_idle_tssi;
- int8 txpwr_est_Pout;
+ s8 idle_tssi[CH_5G_GROUP];
+ s8 target_idle_tssi;
+ s8 txpwr_est_Pout;
u8 tx_power_min;
u8 txpwr_limit[TXP_NUM_RATES];
u8 txpwr_env_limit[TXP_NUM_RATES];
bool phy_fixed_noise;
uint32 xtalfreq;
u8 pdiv;
- int8 carrier_suppr_disable;
+ s8 carrier_suppr_disable;
bool phy_bphy_evm;
bool phy_bphy_rfcs;
- int8 phy_scraminit;
+ s8 phy_scraminit;
u8 phy_gpiosel;
int16 phy_txcore_disable_temp;
int16 phy_txcore_enable_temp;
- int8 phy_tempsense_offset;
+ s8 phy_tempsense_offset;
bool phy_txcore_heatedup;
uint16 radiopwr;
uint16 mintxbias;
uint16 mintxmag;
lo_complex_abgphy_info_t gphy_locomp_iq[STATIC_NUM_RF][STATIC_NUM_BB];
- int8 stats_11b_txpower[STATIC_NUM_RF][STATIC_NUM_BB];
+ s8 stats_11b_txpower[STATIC_NUM_RF][STATIC_NUM_BB];
uint16 gain_table[TX_GAIN_TABLE_LENGTH];
bool loopback_gain;
int16 max_lpback_gain_hdB;
int min_rssi;
int max_rssi;
- int8 txpwridx;
+ s8 txpwridx;
u8 min_txpower;
u8 a_band_high_disable;
uint txmag_len;
bool txmag_enable;
- int8 *a_tssi_to_dbm;
- int8 *m_tssi_to_dbm;
- int8 *l_tssi_to_dbm;
- int8 *h_tssi_to_dbm;
+ s8 *a_tssi_to_dbm;
+ s8 *m_tssi_to_dbm;
+ s8 *l_tssi_to_dbm;
+ s8 *h_tssi_to_dbm;
u8 *hwtxpwr;
uint16 freqtrack_saved_regs[2];
u8 phy_aa2g;
bool nphy_tableloaded;
- int8 nphy_rssisel;
+ s8 nphy_rssisel;
uint32 nphy_bb_mult_save;
uint16 nphy_txiqlocal_bestc[11];
bool nphy_txiqlocal_coeffsvalid;
uint16 nphy_fineclockgatecontrol;
- int8 rx2tx_biasentry;
+ s8 rx2tx_biasentry;
uint16 crsminpwr0;
uint16 crsminpwrl0;
uint tbl_save_offset;
u8 txpwrctrl;
- int8 txpwrindex[PHY_CORE_MAX];
+ s8 txpwrindex[PHY_CORE_MAX];
u8 phycal_tempdelta;
uint32 mcs20_po;
extern void wlc_phy_cordic(fixed theta, cint32 *val);
extern u8 wlc_phy_nbits(int32 value);
extern uint32 wlc_phy_sqrt_int(uint32 value);
-extern void wlc_phy_compute_dB(uint32 *cmplx_pwr, int8 *p_dB, u8 core);
+extern void wlc_phy_compute_dB(uint32 *cmplx_pwr, s8 *p_dB, u8 core);
extern uint wlc_phy_init_radio_regs_allbands(phy_info_t *pi,
radio_20xx_regs_t *radioregs);
extern int wlc_phy_chanspec_bandrange_get(phy_info_t *, chanspec_t);
extern void wlc_lcnphy_set_tx_pwr_ctrl(phy_info_t *pi, uint16 mode);
-extern int8 wlc_lcnphy_get_current_tx_pwr_idx(phy_info_t *pi);
+extern s8 wlc_lcnphy_get_current_tx_pwr_idx(phy_info_t *pi);
extern void wlc_phy_txpower_recalc_target_nphy(phy_info_t *pi);
extern void wlc_lcnphy_txpower_recalc_target(phy_info_t *pi);
extern uint16 wlc_lcnphy_tempsense(phy_info_t *pi, bool mode);
extern int16 wlc_lcnphy_tempsense_new(phy_info_t *pi, bool mode);
-extern int8 wlc_lcnphy_tempsense_degree(phy_info_t *pi, bool mode);
-extern int8 wlc_lcnphy_vbatsense(phy_info_t *pi, bool mode);
+extern s8 wlc_lcnphy_tempsense_degree(phy_info_t *pi, bool mode);
+extern s8 wlc_lcnphy_vbatsense(phy_info_t *pi, bool mode);
extern void wlc_phy_carrier_suppress_lcnphy(phy_info_t *pi);
extern void wlc_lcnphy_crsuprs(phy_info_t *pi, int channel);
extern void wlc_lcnphy_epa_switch(phy_info_t *pi, bool mode);
extern bool wlc_phy_tpc_isenabled_lcnphy(phy_info_t *pi);
extern void wlc_lcnphy_tx_pwr_update_npt(phy_info_t *pi);
extern int32 wlc_lcnphy_tssi2dbm(int32 tssi, int32 a1, int32 b0, int32 b1);
-extern void wlc_lcnphy_get_tssi(phy_info_t *pi, int8 *ofdm_pwr,
- int8 *cck_pwr);
+extern void wlc_lcnphy_get_tssi(phy_info_t *pi, s8 *ofdm_pwr,
+ s8 *cck_pwr);
extern void wlc_lcnphy_tx_power_adjustment(wlc_phy_t *ppi);
extern int32 wlc_lcnphy_rx_signal_power(phy_info_t *pi, int32 gain_index);
extern int wlc_phy_cal_rxiq_nphy(phy_info_t *pi, nphy_txgains_t target_gain,
u8 type, bool d);
extern void wlc_phy_txpwr_index_nphy(phy_info_t *pi, u8 core_mask,
- int8 txpwrindex, bool res);
+ s8 txpwrindex, bool res);
extern void wlc_phy_rssisel_nphy(phy_info_t *pi, u8 core, u8 rssi_type);
extern int wlc_phy_poll_rssi_nphy(phy_info_t *pi, u8 rssi_type,
int32 *rssi_buf, u8 nsamps);
extern void wlc_phy_nphy_tkip_rifs_war(phy_info_t *pi, u8 rifs);
-void wlc_phy_get_pwrdet_offsets(phy_info_t *pi, int8 *cckoffset,
- int8 *ofdmoffset);
-extern int8 wlc_phy_upd_rssi_offset(phy_info_t *pi, int8 rssi,
+void wlc_phy_get_pwrdet_offsets(phy_info_t *pi, s8 *cckoffset,
+ s8 *ofdmoffset);
+extern s8 wlc_phy_upd_rssi_offset(phy_info_t *pi, s8 rssi,
chanspec_t chanspec);
extern bool wlc_phy_n_txpower_ipa_ison(phy_info_t *pih);
0x04464f,
};
-static const int8 lcnphy_gain_table[] = {
+static const s8 lcnphy_gain_table[] = {
-16,
-13,
10,
92,
};
-static const int8 lcnphy_gain_index_offset_for_rssi[] = {
+static const s8 lcnphy_gain_index_offset_for_rssi[] = {
7,
7,
7,
#define wlc_radio_2064_rcal_done(pi) (0 != (read_radio_reg(pi, RADIO_2064_REG05C) & 0x20))
#define tempsense_done(pi) (0x8000 == (read_phy_reg(pi, 0x476) & 0x8000))
-#define LCNPHY_IQLOCC_READ(val) ((u8)(-(int8)(((val) & 0xf0) >> 4) + (int8)((val) & 0x0f)))
+#define LCNPHY_IQLOCC_READ(val) ((u8)(-(s8)(((val) & 0xf0) >> 4) + (s8)((val) & 0x0f)))
#define FIXED_TXPWR 78
#define LCNPHY_TEMPSENSE(val) ((int16)((val > 255) ? (val - 512) : val))
return k;
}
-int8 wlc_lcnphy_get_current_tx_pwr_idx(phy_info_t *pi)
+s8 wlc_lcnphy_get_current_tx_pwr_idx(phy_info_t *pi)
{
- int8 index;
+ s8 index;
phy_info_lcnphy_t *pi_lcn = pi->u.pi_lcnphy;
if (txpwrctrl_off(pi))
index = pi_lcn->lcnphy_current_index;
else if (wlc_lcnphy_tssi_based_pwr_ctrl_enabled(pi))
index =
- (int8) (wlc_lcnphy_get_current_tx_pwr_idx_if_pwrctrl_on(pi)
+ (s8) (wlc_lcnphy_get_current_tx_pwr_idx_if_pwrctrl_on(pi)
/ 2);
else
index = pi_lcn->lcnphy_current_index;
}
}
-static void wlc_lcnphy_set_tx_pwr_soft_ctrl(phy_info_t *pi, int8 index)
+static void wlc_lcnphy_set_tx_pwr_soft_ctrl(phy_info_t *pi, s8 index)
{
uint32 cck_offset[4] = { 22, 22, 22, 22 };
uint32 ofdm_offset, reg_offset_cck;
}
-static int8 wlc_lcnphy_tempcompensated_txpwrctrl(phy_info_t *pi)
+static s8 wlc_lcnphy_tempcompensated_txpwrctrl(phy_info_t *pi)
{
- int8 index, delta_brd, delta_temp, new_index, tempcorrx;
+ s8 index, delta_brd, delta_temp, new_index, tempcorrx;
int16 manp, meas_temp, temp_diff;
bool neg = 0;
uint16 temp;
temp_diff = -temp_diff;
}
- delta_temp = (int8) wlc_lcnphy_qdiv_roundup((uint32) (temp_diff * 192),
+ delta_temp = (s8) wlc_lcnphy_qdiv_roundup((uint32) (temp_diff * 192),
(uint32) (pi_lcn->
lcnphy_tempsense_slope
* 10), 0);
&& LCNREV_IS(pi->pubpi.phy_rev, 0))
delta_temp = 0;
if (pi_lcn->lcnphy_tempcorrx > 31)
- tempcorrx = (int8) (pi_lcn->lcnphy_tempcorrx - 64);
+ tempcorrx = (s8) (pi_lcn->lcnphy_tempcorrx - 64);
else
- tempcorrx = (int8) pi_lcn->lcnphy_tempcorrx;
+ tempcorrx = (s8) pi_lcn->lcnphy_tempcorrx;
if (LCNREV_IS(pi->pubpi.phy_rev, 1))
tempcorrx = 4;
new_index =
void wlc_lcnphy_set_tx_pwr_ctrl(phy_info_t *pi, uint16 mode)
{
uint16 old_mode = wlc_lcnphy_get_tx_pwr_ctrl(pi);
- int8 index;
+ s8 index;
phy_info_lcnphy_t *pi_lcn = pi->u.pi_lcnphy;
ASSERT((LCNPHY_TX_PWR_CTRL_OFF == mode) ||
if (mode == LCNPHY_TX_PWR_CTRL_TEMPBASED) {
index = wlc_lcnphy_tempcompensated_txpwrctrl(pi);
wlc_lcnphy_set_tx_pwr_soft_ctrl(pi, index);
- pi_lcn->lcnphy_current_index = (int8)
+ pi_lcn->lcnphy_current_index = (s8)
((read_phy_reg(pi, 0x4a9) & 0xFF) / 2);
}
}
u8 save_reg007, save_reg0FF, save_reg11F, save_reg005, save_reg025,
save_reg112;
uint16 values_to_save[14];
- int8 index;
+ s8 index;
int i;
phy_info_lcnphy_t *pi_lcn = pi->u.pi_lcnphy;
OSL_DELAY(999);
ASSERT(index <= LCNPHY_MAX_TX_POWER_INDEX);
- pi_lcn->lcnphy_tx_power_idx_override = (int8) index;
+ pi_lcn->lcnphy_tx_power_idx_override = (s8) index;
pi_lcn->lcnphy_current_index = (u8) index;
tab.tbl_id = LCNPHY_TBL_ID_TXPWRCTL;
}
wlc_lcnphy_get_radio_loft(pi, &ei0, &eq0, &fi0, &fq0);
- if ((ABS((int8) fi0) == 15) && (ABS((int8) fq0) == 15)) {
+ if ((ABS((s8) fi0) == 15) && (ABS((s8) fq0) == 15)) {
if (CHSPEC_IS5G(pi->radio_chanspec)) {
target_gains.gm_gain = 255;
target_gains.pga_gain = 255;
return (uint16) avg;
}
-int8 wlc_lcnphy_tempsense_degree(phy_info_t *pi, bool mode)
+s8 wlc_lcnphy_tempsense_degree(phy_info_t *pi, bool mode)
{
int32 degree = wlc_lcnphy_tempsense_new(pi, mode);
degree =
((degree << 10) + LCN_TEMPSENSE_OFFSET + (LCN_TEMPSENSE_DEN >> 1))
/ LCN_TEMPSENSE_DEN;
- return (int8) degree;
+ return (s8) degree;
}
-int8 wlc_lcnphy_vbatsense(phy_info_t *pi, bool mode)
+s8 wlc_lcnphy_vbatsense(phy_info_t *pi, bool mode)
{
uint16 vbatsenseval;
int32 avg = 0;
if (!suspend)
wlapi_enable_mac(pi->sh->physhim);
}
- return (int8) avg;
+ return (s8) avg;
}
static void wlc_lcnphy_afe_clk_init(phy_info_t *pi, u8 mode)
static void wlc_lcnphy_glacial_timer_based_cal(phy_info_t *pi)
{
bool suspend;
- int8 index;
+ s8 index;
uint16 SAVE_pwrctrl = wlc_lcnphy_get_tx_pwr_ctrl(pi);
phy_info_lcnphy_t *pi_lcn = pi->u.pi_lcnphy;
suspend =
const lcnphy_rx_iqcomp_t *rx_iqcomp;
int rx_iqcomp_sz;
uint16 SAVE_pwrctrl = wlc_lcnphy_get_tx_pwr_ctrl(pi);
- int8 index;
+ s8 index;
phytbl_info_t tab;
int32 a1, b0, b1;
int32 tssi, pwr, maxtargetpwr, mintargetpwr;
}
}
-void wlc_lcnphy_get_tssi(phy_info_t *pi, int8 *ofdm_pwr, int8 *cck_pwr)
+void wlc_lcnphy_get_tssi(phy_info_t *pi, s8 *ofdm_pwr, s8 *cck_pwr)
{
- int8 cck_offset;
+ s8 cck_offset;
uint16 status;
status = (read_phy_reg(pi, 0x4ab));
if (wlc_lcnphy_tssi_based_pwr_ctrl_enabled(pi) &&
(status & (0x1 << 15))) {
- *ofdm_pwr = (int8) (((read_phy_reg(pi, 0x4ab) & (0x1ff << 0))
+ *ofdm_pwr = (s8) (((read_phy_reg(pi, 0x4ab) & (0x1ff << 0))
>> 0) >> 1);
if (wlc_phy_tpc_isenabled_lcnphy(pi))
void wlc_lcnphy_tx_power_adjustment(wlc_phy_t *ppi)
{
- int8 index;
+ s8 index;
uint16 index2;
phy_info_t *pi = (phy_info_t *) ppi;
phy_info_lcnphy_t *pi_lcn = pi->u.pi_lcnphy;
index2 = (uint16) (index * 2);
mod_phy_reg(pi, 0x4a9, (0x1ff << 0), (index2) << 0);
- pi_lcn->lcnphy_current_index = (int8)
+ pi_lcn->lcnphy_current_index = (s8)
((read_phy_reg(pi, 0x4a9) & 0xFF) / 2);
}
}
& (0xff << 0));
if (temp > 127)
temp -= 256;
- pi_lcn->lcnphy_input_pwr_offset_db = (int8) temp;
+ pi_lcn->lcnphy_input_pwr_offset_db = (s8) temp;
pi_lcn->lcnphy_Med_Low_Gain_db = (read_phy_reg(pi, 0x424)
& (0xff << 8))
static bool BCMATTACHFN(wlc_phy_txpwr_srom_read_lcnphy) (phy_info_t *pi)
{
- int8 txpwr = 0;
+ s8 txpwr = 0;
int i;
phy_info_lcnphy_t *pi_lcn = pi->u.pi_lcnphy;
pi_lcn->lcnphy_rssi_gs;
}
- txpwr = (int8) PHY_GETINTVAR(pi, "maxp2ga0");
+ txpwr = (s8) PHY_GETINTVAR(pi, "maxp2ga0");
pi->tx_srom_max_2g = txpwr;
for (i = 0; i < PWRTBL_NUM_COEFF; i++) {
uint16 lcnphy_tssi_npt;
uint16 lcnphy_target_tx_freq;
- int8 lcnphy_tx_power_idx_override;
+ s8 lcnphy_tx_power_idx_override;
uint16 lcnphy_noise_samples;
uint32 lcnphy_papdRxGnIdx;
int16 lcnphy_dsssgainidxtableoffset;
uint32 lcnphy_tr_R_gain_val;
uint32 lcnphy_tr_T_gain_val;
- int8 lcnphy_input_pwr_offset_db;
+ s8 lcnphy_input_pwr_offset_db;
uint16 lcnphy_Med_Low_Gain_db;
uint16 lcnphy_Very_Low_Gain_db;
- int8 lcnphy_lastsensed_temperature;
- int8 lcnphy_pkteng_rssi_slope;
+ s8 lcnphy_lastsensed_temperature;
+ s8 lcnphy_pkteng_rssi_slope;
u8 lcnphy_saved_tx_user_target[TXP_NUM_RATES];
u8 lcnphy_volt_winner;
u8 lcnphy_volt_low;
u8 lcnphy_cck;
u8 lcnphy_psat_2pt3_detected;
int32 lcnphy_lowest_Re_div_Im;
- int8 lcnphy_final_papd_cal_idx;
+ s8 lcnphy_final_papd_cal_idx;
uint16 lcnphy_extstxctrl4;
uint16 lcnphy_extstxctrl0;
uint16 lcnphy_extstxctrl1;
u8 lcnphy_aci_stat;
uint lcnphy_aci_start_time;
- int8 lcnphy_tx_power_offset[TXP_NUM_RATES];
+ s8 lcnphy_tx_power_offset[TXP_NUM_RATES];
};
#endif /* _wlc_phy_lcn_h_ */
#define NPHY_CALSANITY_RSSI_W1_MAX_NEG (NPHY_RSSICAL_W1_TARGET - NPHY_RSSICAL_MAXREAD)
#define NPHY_CALSANITY_RSSI_W2_MAX_POS NPHY_CALSANITY_RSSI_W1_MAX_POS
#define NPHY_CALSANITY_RSSI_W2_MAX_NEG (NPHY_RSSICAL_W2_TARGET - NPHY_RSSICAL_MAXREAD)
-#define NPHY_RSSI_SXT(x) ((int8) (-((x) & 0x20) + ((x) & 0x1f)))
+#define NPHY_RSSI_SXT(x) ((s8) (-((x) & 0x20) + ((x) & 0x1f)))
#define NPHY_RSSI_NB_VIOL(x) (((x) > NPHY_CALSANITY_RSSI_NB_MAX_POS) || \
((x) < NPHY_CALSANITY_RSSI_NB_MAX_NEG))
#define NPHY_RSSI_W1_VIOL(x) (((x) > NPHY_CALSANITY_RSSI_W1_MAX_POS) || \
uint16 lpf_biq0;
uint16 lna2;
uint16 lna1;
- int8 txpwrindex;
+ s8 txpwrindex;
} nphy_ipa_txrxgain_t;
#define NPHY_IPA_RXCAL_MAXGAININDEX (6 - 1)
0x607f0001, 0x607f0001, 0x607f0001, 0x607f0001
};
-static int8 nphy_papd_pga_gain_delta_ipa_2g[] = {
+static s8 nphy_papd_pga_gain_delta_ipa_2g[] = {
-114, -108, -98, -91, -84, -78, -70, -62,
-54, -46, -39, -31, -23, -15, -8, 0
};
-static int8 nphy_papd_pga_gain_delta_ipa_5g[] = {
+static s8 nphy_papd_pga_gain_delta_ipa_5g[] = {
-100, -95, -89, -83, -77, -70, -63, -56,
-48, -41, -33, -25, -19, -12, -6, 0
};
-6, -5, -4, -3, -2, -1, -1, 0
};
-static int8 nphy_papd_pgagain_dlt_5g_2057[] = {
+static s8 nphy_papd_pgagain_dlt_5g_2057[] = {
-107, -101, -92, -85, -78, -71, -62, -55,
-47, -39, -32, -24, -19, -12, -6, 0
};
-static int8 nphy_papd_pgagain_dlt_5g_2057rev7[] = {
+static s8 nphy_papd_pgagain_dlt_5g_2057rev7[] = {
-110, -104, -95, -88, -81, -74, -66, -58,
-50, -44, -36, -28, -23, -15, -8, 0
};
NPHY_RFSEQ_CMD_SET_HPF_BW
};
u8 rfseq_updategainu_dlys[] = { 10, 30, 1 };
- int8 lna1G_gain_db[] = { 7, 11, 16, 23 };
- int8 lna1G_gain_db_rev4[] = { 8, 12, 17, 25 };
- int8 lna1G_gain_db_rev5[] = { 9, 13, 18, 26 };
- int8 lna1G_gain_db_rev6[] = { 8, 13, 18, 25 };
- int8 lna1G_gain_db_rev6_224B0[] = { 10, 14, 19, 27 };
- int8 lna1A_gain_db[] = { 7, 11, 17, 23 };
- int8 lna1A_gain_db_rev4[] = { 8, 12, 18, 23 };
- int8 lna1A_gain_db_rev5[] = { 6, 10, 16, 21 };
- int8 lna1A_gain_db_rev6[] = { 6, 10, 16, 21 };
- int8 *lna1_gain_db = NULL;
- int8 lna2G_gain_db[] = { -5, 6, 10, 14 };
- int8 lna2G_gain_db_rev5[] = { -3, 7, 11, 16 };
- int8 lna2G_gain_db_rev6[] = { -5, 6, 10, 14 };
- int8 lna2G_gain_db_rev6_224B0[] = { -5, 6, 10, 15 };
- int8 lna2A_gain_db[] = { -6, 2, 6, 10 };
- int8 lna2A_gain_db_rev4[] = { -5, 2, 6, 10 };
- int8 lna2A_gain_db_rev5[] = { -7, 0, 4, 8 };
- int8 lna2A_gain_db_rev6[] = { -7, 0, 4, 8 };
- int8 *lna2_gain_db = NULL;
- int8 tiaG_gain_db[] = {
+ s8 lna1G_gain_db[] = { 7, 11, 16, 23 };
+ s8 lna1G_gain_db_rev4[] = { 8, 12, 17, 25 };
+ s8 lna1G_gain_db_rev5[] = { 9, 13, 18, 26 };
+ s8 lna1G_gain_db_rev6[] = { 8, 13, 18, 25 };
+ s8 lna1G_gain_db_rev6_224B0[] = { 10, 14, 19, 27 };
+ s8 lna1A_gain_db[] = { 7, 11, 17, 23 };
+ s8 lna1A_gain_db_rev4[] = { 8, 12, 18, 23 };
+ s8 lna1A_gain_db_rev5[] = { 6, 10, 16, 21 };
+ s8 lna1A_gain_db_rev6[] = { 6, 10, 16, 21 };
+ s8 *lna1_gain_db = NULL;
+ s8 lna2G_gain_db[] = { -5, 6, 10, 14 };
+ s8 lna2G_gain_db_rev5[] = { -3, 7, 11, 16 };
+ s8 lna2G_gain_db_rev6[] = { -5, 6, 10, 14 };
+ s8 lna2G_gain_db_rev6_224B0[] = { -5, 6, 10, 15 };
+ s8 lna2A_gain_db[] = { -6, 2, 6, 10 };
+ s8 lna2A_gain_db_rev4[] = { -5, 2, 6, 10 };
+ s8 lna2A_gain_db_rev5[] = { -7, 0, 4, 8 };
+ s8 lna2A_gain_db_rev6[] = { -7, 0, 4, 8 };
+ s8 *lna2_gain_db = NULL;
+ s8 tiaG_gain_db[] = {
0x0A, 0x0A, 0x0A, 0x0A, 0x0A, 0x0A, 0x0A, 0x0A, 0x0A, 0x0A };
- int8 tiaA_gain_db[] = {
+ s8 tiaA_gain_db[] = {
0x13, 0x13, 0x13, 0x13, 0x13, 0x13, 0x13, 0x13, 0x13, 0x13 };
- int8 tiaA_gain_db_rev4[] = {
+ s8 tiaA_gain_db_rev4[] = {
0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d };
- int8 tiaA_gain_db_rev5[] = {
+ s8 tiaA_gain_db_rev5[] = {
0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d };
- int8 tiaA_gain_db_rev6[] = {
+ s8 tiaA_gain_db_rev6[] = {
0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d, 0x0d };
- int8 *tia_gain_db;
- int8 tiaG_gainbits[] = {
+ s8 *tia_gain_db;
+ s8 tiaG_gainbits[] = {
0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03 };
- int8 tiaA_gainbits[] = {
+ s8 tiaA_gainbits[] = {
0x06, 0x06, 0x06, 0x06, 0x06, 0x06, 0x06, 0x06, 0x06, 0x06 };
- int8 tiaA_gainbits_rev4[] = {
+ s8 tiaA_gainbits_rev4[] = {
0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04 };
- int8 tiaA_gainbits_rev5[] = {
+ s8 tiaA_gainbits_rev5[] = {
0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04 };
- int8 tiaA_gainbits_rev6[] = {
+ s8 tiaA_gainbits_rev6[] = {
0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04 };
- int8 *tia_gainbits;
- int8 lpf_gain_db[] = { 0x00, 0x06, 0x0c, 0x12, 0x12, 0x12 };
- int8 lpf_gainbits[] = { 0x00, 0x01, 0x02, 0x03, 0x03, 0x03 };
+ s8 *tia_gainbits;
+ s8 lpf_gain_db[] = { 0x00, 0x06, 0x0c, 0x12, 0x12, 0x12 };
+ s8 lpf_gainbits[] = { 0x00, 0x01, 0x02, 0x03, 0x03, 0x03 };
uint16 rfseqG_init_gain[] = { 0x613f, 0x613f, 0x613f, 0x613f };
uint16 rfseqG_init_gain_rev4[] = { 0x513f, 0x513f, 0x513f, 0x513f };
uint16 rfseqG_init_gain_rev5[] = { 0x413f, 0x413f, 0x413f, 0x413f };
static void wlc_phy_workarounds_nphy_gainctrl_2057_rev5(phy_info_t *pi)
{
- int8 lna1_gain_db[] = { 8, 13, 17, 22 };
- int8 lna2_gain_db[] = { -2, 7, 11, 15 };
- int8 tia_gain_db[] = { -4, -1, 2, 5, 5, 5, 5, 5, 5, 5 };
- int8 tia_gainbits[] = {
+ s8 lna1_gain_db[] = { 8, 13, 17, 22 };
+ s8 lna2_gain_db[] = { -2, 7, 11, 15 };
+ s8 tia_gain_db[] = { -4, -1, 2, 5, 5, 5, 5, 5, 5, 5 };
+ s8 tia_gainbits[] = {
0x0, 0x01, 0x02, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03 };
mod_phy_reg(pi, 0x1c, (0x1 << 13), (1 << 13));
static void wlc_phy_workarounds_nphy_gainctrl_2057_rev6(phy_info_t *pi)
{
uint16 currband;
- int8 lna1G_gain_db_rev7[] = { 9, 14, 19, 24 };
- int8 *lna1_gain_db = NULL;
- int8 *lna1_gain_db_2 = NULL;
- int8 *lna2_gain_db = NULL;
- int8 tiaA_gain_db_rev7[] = { -9, -6, -3, 0, 3, 3, 3, 3, 3, 3 };
- int8 *tia_gain_db;
- int8 tiaA_gainbits_rev7[] = { 0, 1, 2, 3, 4, 4, 4, 4, 4, 4 };
- int8 *tia_gainbits;
+ s8 lna1G_gain_db_rev7[] = { 9, 14, 19, 24 };
+ s8 *lna1_gain_db = NULL;
+ s8 *lna1_gain_db_2 = NULL;
+ s8 *lna2_gain_db = NULL;
+ s8 tiaA_gain_db_rev7[] = { -9, -6, -3, 0, 3, 3, 3, 3, 3, 3 };
+ s8 *tia_gain_db;
+ s8 tiaA_gainbits_rev7[] = { 0, 1, 2, 3, 4, 4, 4, 4, 4, 4 };
+ s8 *tia_gainbits;
uint16 rfseqA_init_gain_rev7[] = { 0x624f, 0x624f };
uint16 *rfseq_init_gain;
uint16 init_gaincode;
uint16 nbclip_th = 0;
u8 w1clip_th;
uint16 freq;
- int8 nvar_baseline_offset0 = 0, nvar_baseline_offset1 = 0;
+ s8 nvar_baseline_offset0 = 0, nvar_baseline_offset1 = 0;
u8 chg_nbclip_th = 0;
mod_phy_reg(pi, 0x1c, (0x1 << 13), (1 << 13));
if ((freq <= 5080) || (freq == 5825)) {
- int8 lna1A_gain_db_rev7[] = { 11, 16, 20, 24 };
- int8 lna1A_gain_db_2_rev7[] = {
+ s8 lna1A_gain_db_rev7[] = { 11, 16, 20, 24 };
+ s8 lna1A_gain_db_2_rev7[] = {
11, 17, 22, 25 };
- int8 lna2A_gain_db_rev7[] = { -1, 6, 10, 14 };
+ s8 lna2A_gain_db_rev7[] = { -1, 6, 10, 14 };
crsminu_th = 0x3e;
lna1_gain_db = lna1A_gain_db_rev7;
lna2_gain_db = lna2A_gain_db_rev7;
} else if ((freq >= 5500) && (freq <= 5700)) {
- int8 lna1A_gain_db_rev7[] = { 11, 17, 21, 25 };
- int8 lna1A_gain_db_2_rev7[] = {
+ s8 lna1A_gain_db_rev7[] = { 11, 17, 21, 25 };
+ s8 lna1A_gain_db_2_rev7[] = {
12, 18, 22, 26 };
- int8 lna2A_gain_db_rev7[] = { 1, 8, 12, 16 };
+ s8 lna2A_gain_db_rev7[] = { 1, 8, 12, 16 };
crsminu_th = 0x45;
clip1md_gaincode_B = 0x14;
lna2_gain_db = lna2A_gain_db_rev7;
} else {
- int8 lna1A_gain_db_rev7[] = { 12, 18, 22, 26 };
- int8 lna1A_gain_db_2_rev7[] = {
+ s8 lna1A_gain_db_rev7[] = { 12, 18, 22, 26 };
+ s8 lna1A_gain_db_2_rev7[] = {
12, 18, 22, 26 };
- int8 lna2A_gain_db_rev7[] = { -1, 6, 10, 14 };
+ s8 lna2A_gain_db_rev7[] = { -1, 6, 10, 14 };
crsminu_th = 0x41;
lna1_gain_db = lna1A_gain_db_rev7;
}
static void
-wlc_phy_scale_offset_rssi_nphy(phy_info_t *pi, uint16 scale, int8 offset,
+wlc_phy_scale_offset_rssi_nphy(phy_info_t *pi, uint16 scale, s8 offset,
u8 coresel, u8 rail, u8 rssi_type)
{
uint16 valuetostuff;
uint16 rfctrloverride_save = 0;
uint16 rfctrlrssiothers1_save = 0;
uint16 rfctrlrssiothers2_save = 0;
- int8 tmp_buf[4];
+ s8 tmp_buf[4];
u8 ctr = 0, samp = 0;
int32 rssi_out_val;
uint16 gpiosel_orig;
}
ctr = 0;
- tmp_buf[ctr++] = ((int8) ((rssi0 & 0x3f) << 2)) >> 2;
- tmp_buf[ctr++] = ((int8) (((rssi0 >> 8) & 0x3f) << 2)) >> 2;
- tmp_buf[ctr++] = ((int8) ((rssi1 & 0x3f) << 2)) >> 2;
- tmp_buf[ctr++] = ((int8) (((rssi1 >> 8) & 0x3f) << 2)) >> 2;
+ tmp_buf[ctr++] = ((s8) ((rssi0 & 0x3f) << 2)) >> 2;
+ tmp_buf[ctr++] = ((s8) (((rssi0 >> 8) & 0x3f) << 2)) >> 2;
+ tmp_buf[ctr++] = ((s8) ((rssi1 & 0x3f) << 2)) >> 2;
+ tmp_buf[ctr++] = ((s8) (((rssi1 >> 8) & 0x3f) << 2)) >> 2;
for (ctr = 0; ctr < 4; ctr++) {
rssi_buf[ctr] += tmp_buf[ctr];
}
wlc_phy_scale_offset_rssi_nphy(pi, 0x0,
- (int8)
+ (s8)
fine_digital_offset[result_idx],
(result_idx / 2 ==
0) ? RADIO_MIMO_CORESEL_CORE1 :
rxpwr1 = phyRx2_l;
}
- wlc_rxh->rxpwr[0] = (int8) rxpwr0;
- wlc_rxh->rxpwr[1] = (int8) rxpwr1;
+ wlc_rxh->rxpwr[0] = (s8) rxpwr0;
+ wlc_rxh->rxpwr[1] = (s8) rxpwr1;
wlc_rxh->do_rssi_ma = 0;
if (pi->sh->rssi_mode == RSSI_ANT_MERGE_MAX)
}
wlc_phy_scale_offset_rssi_nphy(pi, 0x0,
- (int8)
+ (s8)
fine_digital_offset
[result_idx],
(result_idx /
}
wlc_phy_scale_offset_rssi_nphy(pi, 0x0,
- (int8)
+ (s8)
fine_digital_offset
[core *
2],
pi->nphy_txpwrindex[1].index = -1;
} else {
wlc_phy_txpwr_index_nphy(pi, (1 << 0),
- (int8) (pi->
+ (s8) (pi->
nphy_txpwrindex
[0].
index_internal),
FALSE);
wlc_phy_txpwr_index_nphy(pi, (1 << 1),
- (int8) (pi->
+ (s8) (pi->
nphy_txpwrindex
[1].
index_internal),
int16 desired_log2_pwr, actual_log2_pwr, delta_pwr;
bool gainctrl_done = FALSE;
u8 mix_tia_gain = 3;
- int8 optim_gaintbl_index = 0, prev_gaintbl_index = 0;
- int8 curr_gaintbl_index = 3;
+ s8 optim_gaintbl_index = 0, prev_gaintbl_index = 0;
+ s8 curr_gaintbl_index = 3;
u8 gainctrl_dirn = NPHY_RXCAL_GAIN_INIT;
nphy_ipa_txrxgain_t *nphy_rxcal_gaintbl;
uint16 hpvga, lpf_biq1, lpf_biq0, lna2, lna1;
int16 fine_gain_idx;
- int8 txpwrindex;
+ s8 txpwrindex;
uint16 nphy_rxcal_txgain[2];
if (NREV_GE(pi->pubpi.phy_rev, 7)) {
uint16 rx_lpf_bw, rx_lpf_bws[2] = { 2, 4 };
uint16 lpf_hpc = 7, hpvga_hpc = 7;
- int8 rccal_stepsize;
+ s8 rccal_stepsize;
uint16 rccal_val, last_rccal_val = 0, best_rccal_val = 0;
uint32 ref_iq_vals = 0, target_iq_vals = 0;
uint16 num_samps, log_num_samps = 10;
uint16 cal_gain[2];
nphy_iqcal_params_t cal_params[2];
u8 rxcore_state;
- int8 rxlpf_rccal_hpc, txlpf_rccal_lpc;
- int8 txlpf_idac;
+ s8 rxlpf_rccal_hpc, txlpf_rccal_lpc;
+ s8 txlpf_idac;
bool phyhang_avoid_state = FALSE;
bool skip_rxiqcal = FALSE;
wlc_phy_txpwrctrl_enable_nphy(pi, phy_b4);
if (phy_b4 == PHY_TPC_HW_OFF) {
wlc_phy_txpwr_index_nphy(pi, (1 << 0),
- (int8) (pi->nphy_txpwrindex[0].
+ (s8) (pi->nphy_txpwrindex[0].
index_internal), FALSE);
wlc_phy_txpwr_index_nphy(pi, (1 << 1),
- (int8) (pi->nphy_txpwrindex[1].
+ (s8) (pi->nphy_txpwrindex[1].
index_internal), FALSE);
}
pi->nphy_txpid2g[PHY_CORE_1] =
(u8) PHY_GETINTVAR(pi, "txpid2ga1");
pi->nphy_pwrctrl_info[PHY_CORE_0].max_pwr_2g =
- (int8) PHY_GETINTVAR(pi, "maxp2ga0");
+ (s8) PHY_GETINTVAR(pi, "maxp2ga0");
pi->nphy_pwrctrl_info[PHY_CORE_1].max_pwr_2g =
- (int8) PHY_GETINTVAR(pi, "maxp2ga1");
+ (s8) PHY_GETINTVAR(pi, "maxp2ga1");
pi->nphy_pwrctrl_info[PHY_CORE_0].pwrdet_2g_a1 =
(int16) PHY_GETINTVAR(pi, "pa2gw0a0");
pi->nphy_pwrctrl_info[PHY_CORE_1].pwrdet_2g_a1 =
pi->nphy_pwrctrl_info[PHY_CORE_1].pwrdet_2g_b1 =
(int16) PHY_GETINTVAR(pi, "pa2gw2a1");
pi->nphy_pwrctrl_info[PHY_CORE_0].idle_targ_2g =
- (int8) PHY_GETINTVAR(pi, "itt2ga0");
+ (s8) PHY_GETINTVAR(pi, "itt2ga0");
pi->nphy_pwrctrl_info[PHY_CORE_1].idle_targ_2g =
- (int8) PHY_GETINTVAR(pi, "itt2ga1");
+ (s8) PHY_GETINTVAR(pi, "itt2ga1");
pi->cck2gpo = (uint16) PHY_GETINTVAR(pi, "cck2gpo");
pi->nphy_txpid5g[PHY_CORE_1] =
(u8) PHY_GETINTVAR(pi, "txpid5ga1");
pi->nphy_pwrctrl_info[PHY_CORE_0].max_pwr_5gm =
- (int8) PHY_GETINTVAR(pi, "maxp5ga0");
+ (s8) PHY_GETINTVAR(pi, "maxp5ga0");
pi->nphy_pwrctrl_info[PHY_CORE_1].max_pwr_5gm =
- (int8) PHY_GETINTVAR(pi, "maxp5ga1");
+ (s8) PHY_GETINTVAR(pi, "maxp5ga1");
pi->nphy_pwrctrl_info[PHY_CORE_0].pwrdet_5gm_a1 =
(int16) PHY_GETINTVAR(pi, "pa5gw0a0");
pi->nphy_pwrctrl_info[PHY_CORE_1].pwrdet_5gm_a1 =
pi->nphy_pwrctrl_info[PHY_CORE_1].pwrdet_5gm_b1 =
(int16) PHY_GETINTVAR(pi, "pa5gw2a1");
pi->nphy_pwrctrl_info[PHY_CORE_0].idle_targ_5gm =
- (int8) PHY_GETINTVAR(pi, "itt5ga0");
+ (s8) PHY_GETINTVAR(pi, "itt5ga0");
pi->nphy_pwrctrl_info[PHY_CORE_1].idle_targ_5gm =
- (int8) PHY_GETINTVAR(pi, "itt5ga1");
+ (s8) PHY_GETINTVAR(pi, "itt5ga1");
pi->ofdm5gpo = (uint32) PHY_GETINTVAR(pi, "ofdm5gpo");
pi->nphy_txpid5gl[1] =
(u8) PHY_GETINTVAR(pi, "txpid5gla1");
pi->nphy_pwrctrl_info[0].max_pwr_5gl =
- (int8) PHY_GETINTVAR(pi, "maxp5gla0");
+ (s8) PHY_GETINTVAR(pi, "maxp5gla0");
pi->nphy_pwrctrl_info[1].max_pwr_5gl =
- (int8) PHY_GETINTVAR(pi, "maxp5gla1");
+ (s8) PHY_GETINTVAR(pi, "maxp5gla1");
pi->nphy_pwrctrl_info[0].pwrdet_5gl_a1 =
(int16) PHY_GETINTVAR(pi, "pa5glw0a0");
pi->nphy_pwrctrl_info[1].pwrdet_5gl_a1 =
pi->nphy_txpid5gh[1] =
(u8) PHY_GETINTVAR(pi, "txpid5gha1");
pi->nphy_pwrctrl_info[0].max_pwr_5gh =
- (int8) PHY_GETINTVAR(pi, "maxp5gha0");
+ (s8) PHY_GETINTVAR(pi, "maxp5gha0");
pi->nphy_pwrctrl_info[1].max_pwr_5gh =
- (int8) PHY_GETINTVAR(pi, "maxp5gha1");
+ (s8) PHY_GETINTVAR(pi, "maxp5gha1");
pi->nphy_pwrctrl_info[0].pwrdet_5gh_a1 =
(int16) PHY_GETINTVAR(pi, "pa5ghw0a0");
pi->nphy_pwrctrl_info[1].pwrdet_5gh_a1 =
pi->phy_txcore_disable_temp = PHY_CHAIN_TX_DISABLE_TEMP;
}
- pi->phy_tempsense_offset = (int8) PHY_GETINTVAR(pi, "tempoffset");
+ pi->phy_tempsense_offset = (s8) PHY_GETINTVAR(pi, "tempoffset");
if (pi->phy_tempsense_offset != 0) {
if (pi->phy_tempsense_offset >
(NPHY_SROM_TEMPSHIFT + NPHY_SROM_MAXTEMPOFFSET)) {
uint32 idx;
uint16 iqloCalbuf[7];
uint32 iqcomp, locomp, curr_locomp;
- int8 locomp_i, locomp_q;
- int8 curr_locomp_i, curr_locomp_q;
+ s8 locomp_i, locomp_q;
+ s8 curr_locomp_i, curr_locomp_q;
uint32 tbl_id, tbl_len, tbl_offset;
uint32 regval[128];
locomp =
(uint32) ((tbl_id == 26) ? iqloCalbuf[5] : iqloCalbuf[6]);
- locomp_i = (int8) ((locomp >> 8) & 0xff);
- locomp_q = (int8) ((locomp) & 0xff);
+ locomp_i = (s8) ((locomp >> 8) & 0xff);
+ locomp_q = (s8) ((locomp) & 0xff);
for (idx = 0; idx < tbl_len; idx++) {
if (NREV_GE(pi->pubpi.phy_rev, 3)) {
curr_locomp_i = locomp_i;
curr_locomp_q = locomp_q;
} else {
- curr_locomp_i = (int8) ((locomp_i *
+ curr_locomp_i = (s8) ((locomp_i *
nphy_tpc_loscale[idx] +
128) >> 8);
curr_locomp_q =
- (int8) ((locomp_q * nphy_tpc_loscale[idx] +
+ (s8) ((locomp_q * nphy_tpc_loscale[idx] +
128) >> 8);
}
curr_locomp = (uint32) ((curr_locomp_i & 0xff) << 8);
{
uint32 idx;
int16 a1[2], b0[2], b1[2];
- int8 target_pwr_qtrdbm[2];
+ s8 target_pwr_qtrdbm[2];
int32 num, den, pwr_est;
u8 chan_freq_range;
u8 idle_tssi[2];
}
}
- target_pwr_qtrdbm[0] = (int8) pi->tx_power_max;
- target_pwr_qtrdbm[1] = (int8) pi->tx_power_max;
+ target_pwr_qtrdbm[0] = (s8) pi->tx_power_max;
+ target_pwr_qtrdbm[1] = (s8) pi->tx_power_max;
if (NREV_GE(pi->pubpi.phy_rev, 3)) {
if (pi->srom_fem2g.tssipos) {
}
void
-wlc_phy_txpwr_index_nphy(phy_info_t *pi, u8 core_mask, int8 txpwrindex,
+wlc_phy_txpwr_index_nphy(phy_info_t *pi, u8 core_mask, s8 txpwrindex,
bool restore_cals)
{
u8 core, txpwrctl_tbl;
/* per-tid mpdu transmit retry limit at regular rate */
u8 rr_retry_limit_tid[AMPDU_MAX_SCB_TID];
u8 mpdu_density; /* min mpdu spacing (0-7) ==> 2^(x-1)/8 usec */
- int8 max_pdu; /* max pdus allowed in ampdu */
+ s8 max_pdu; /* max pdus allowed in ampdu */
u8 dur; /* max duration of an ampdu (in msec) */
u8 txpkt_weight; /* weight of ampdu in txfifo; reduces rate lag */
u8 rx_factor; /* maximum rx ampdu factor (0-3) ==> 2^(13+x) bytes */
uint *len);
extern void wlc_bmac_process_ps_switch(wlc_hw_info_t *wlc,
- struct ether_addr *ea, int8 ps_on);
+ struct ether_addr *ea, s8 ps_on);
extern void wlc_bmac_hw_etheraddr(wlc_hw_info_t *wlc_hw,
struct ether_addr *ea);
extern void wlc_bmac_set_hw_etheraddr(wlc_hw_info_t *wlc_hw,
bool _ap; /* is this configuration an AP */
struct wlc_if *wlcif; /* virtual interface, NULL for primary bsscfg */
void *sup; /* pointer to supplicant state */
- int8 sup_type; /* type of supplicant */
+ s8 sup_type; /* type of supplicant */
bool sup_enable_wpa; /* supplicant WPA on/off */
void *authenticator; /* pointer to authenticator state */
bool sup_auth_pending; /* flag for auth timeout */
u8 SSID_len; /* the length of SSID */
u8 SSID[DOT11_MAX_SSID_LEN]; /* SSID string */
struct scb *bcmc_scb[MAXBANDS]; /* one bcmc_scb per band */
- int8 _idx; /* the index of this bsscfg,
+ s8 _idx; /* the index of this bsscfg,
* assigned at wlc_bsscfg_alloc()
*/
/* MAC filter */
uint32 valid_channels;
u8 radar_channels; /* List of radar sensitive channels */
u8 restricted_channels; /* List of channels used only if APs are detected */
- int8 maxpwr[WLC_MAXPWR_TBL_SIZE]; /* Max tx pwr in qdBm for each sub-band */
- int8 pub_maxpwr[BAND_5G_PWR_LVLS]; /* Country IE advertised max tx pwr in dBm
+ s8 maxpwr[WLC_MAXPWR_TBL_SIZE]; /* Max tx pwr in qdBm for each sub-band */
+ s8 pub_maxpwr[BAND_5G_PWR_LVLS]; /* Country IE advertised max tx pwr in dBm
* per sub-band
*/
u8 flags;
* by sub-band for 5 GHz limits using CHANNEL_POWER_IDX_5G(channel)
*/
typedef struct {
- int8 maxpwr20[WLC_MAXPWR_MIMO_TBL_SIZE]; /* tx 20 MHz power limits, qdBm units */
- int8 maxpwr40[WLC_MAXPWR_MIMO_TBL_SIZE]; /* tx 40 MHz power limits, qdBm units */
+ s8 maxpwr20[WLC_MAXPWR_MIMO_TBL_SIZE]; /* tx 20 MHz power limits, qdBm units */
+ s8 maxpwr40[WLC_MAXPWR_MIMO_TBL_SIZE]; /* tx 40 MHz power limits, qdBm units */
u8 flags;
} locale_mimo_info_t;
uint16 flags; /* misc flags */
u8 algo_hw; /* cache for hw register */
u8 aes_mode; /* cache for hw register */
- int8 iv_len; /* IV length */
- int8 icv_len; /* ICV length */
+ s8 iv_len; /* IV length */
+ s8 icv_len; /* ICV length */
uint32 len; /* key length..don't move this var */
/* data is 4byte aligned */
u8 data[DOT11_MAX_KEY_SIZE]; /* key data */
static void wlc_update_mimo_band_bwcap(wlc_info_t *wlc, u8 bwcap);
static void wlc_ht_update_sgi_rx(wlc_info_t *wlc, int val);
void wlc_ht_mimops_cap_update(wlc_info_t *wlc, u8 mimops_mode);
-static void wlc_ht_update_ldpc(wlc_info_t *wlc, int8 val);
+static void wlc_ht_update_ldpc(wlc_info_t *wlc, s8 val);
static void wlc_war16165(wlc_info_t *wlc, bool tx);
static void wlc_process_eventq(void *arg);
wlc->protection->_g = (bool) val;
break;
case WLC_PROT_G_OVR:
- wlc->protection->g_override = (int8) val;
+ wlc->protection->g_override = (s8) val;
break;
case WLC_PROT_G_USER:
wlc->protection->gmode_user = (u8) val;
break;
case WLC_PROT_OVERLAP:
- wlc->protection->overlap = (int8) val;
+ wlc->protection->overlap = (s8) val;
break;
case WLC_PROT_N_USER:
- wlc->protection->nmode_user = (int8) val;
+ wlc->protection->nmode_user = (s8) val;
break;
case WLC_PROT_N_CFG:
- wlc->protection->n_cfg = (int8) val;
+ wlc->protection->n_cfg = (s8) val;
break;
case WLC_PROT_N_CFG_OVR:
- wlc->protection->n_cfg_override = (int8) val;
+ wlc->protection->n_cfg_override = (s8) val;
break;
case WLC_PROT_N_NONGF:
wlc->protection->nongf = (bool) val;
break;
case WLC_PROT_N_NONGF_OVR:
- wlc->protection->nongf_override = (int8) val;
+ wlc->protection->nongf_override = (s8) val;
break;
case WLC_PROT_N_PAM_OVR:
- wlc->protection->n_pam_override = (int8) val;
+ wlc->protection->n_pam_override = (s8) val;
break;
case WLC_PROT_N_OBSS:
wlc->protection->n_obss = (bool) val;
}
}
-static void wlc_ht_update_ldpc(wlc_info_t *wlc, int8 val)
+static void wlc_ht_update_ldpc(wlc_info_t *wlc, s8 val)
{
wlc->stf->ldpc = val;
wlc->machwcap = state_bmac.machwcap;
wlc_protection_upd(wlc, WLC_PROT_N_PAM_OVR,
- (int8) state_bmac.preamble_ovr);
+ (s8) state_bmac.preamble_ovr);
return TRUE;
}
WL_ERROR(("wl%d: %s: Invalid antennas available in srom, using 2dB\n", unit, __func__));
wlc->band->antgain = 8;
} else {
- int8 gain, fract;
+ s8 gain, fract;
/* Older sroms specified gain in whole dbm only. In order
* be able to specify qdbm granularity and remain backward compatible
* the whole dbms are now encoded in only low 6 bits and remaining qdbms
bandtype = wlc->band->bandtype;
/* get antennas available */
- aa = (int8) getintvar(vars, (BAND_5G(bandtype) ? "aa5g" : "aa2g"));
+ aa = (s8) getintvar(vars, (BAND_5G(bandtype) ? "aa5g" : "aa2g"));
if (aa == 0)
- aa = (int8) getintvar(vars,
+ aa = (s8) getintvar(vars,
(BAND_5G(bandtype) ? "aa1" : "aa0"));
if ((aa < 1) || (aa > 15)) {
WL_ERROR(("wl%d: %s: Invalid antennas available in srom (0x%x), using 3.\n", unit, __func__, aa));
/* Compute Antenna Gain */
wlc->band->antgain =
- (int8) getintvar(vars, (BAND_5G(bandtype) ? "ag1" : "ag0"));
+ (s8) getintvar(vars, (BAND_5G(bandtype) ? "ag1" : "ag0"));
wlc_attach_antgain_init(wlc);
return TRUE;
uint i;
wlc_rateset_t rs;
/* Default to 54g Auto */
- int8 shortslot = WLC_SHORTSLOT_AUTO; /* Advertise and use shortslot (-1/0/1 Auto/Off/On) */
+ s8 shortslot = WLC_SHORTSLOT_AUTO; /* Advertise and use shortslot (-1/0/1 Auto/Off/On) */
bool shortslot_restrict = FALSE; /* Restrict association to stations that support shortslot
*/
bool ignore_bcns = TRUE; /* Ignore legacy beacons on the same channel */
break;
case WLC_SET_TXANT:
- bcmerror = wlc_stf_ant_txant_validate(wlc, (int8) val);
+ bcmerror = wlc_stf_ant_txant_validate(wlc, (s8) val);
if (bcmerror < 0)
break;
- wlc->stf->txant = (int8) val;
+ wlc->stf->txant = (s8) val;
/* if down, we are done */
if (!wlc->pub->up)
break;
}
- wlc->shortslot_override = (int8) val;
+ wlc->shortslot_override = (s8) val;
/* shortslot is an 11g feature, so no more work if we are
* currently on the 5G band
break;
}
- wlc_protection_upd(wlc, WLC_PROT_OVERLAP, (int8) val);
+ wlc_protection_upd(wlc, WLC_PROT_OVERLAP, (s8) val);
/* Current g_protection will sync up to the specified control alg in watchdog
* if the driver is up and associated.
break;
}
- wlc_protection_upd(wlc, WLC_PROT_G_OVR, (int8) val);
+ wlc_protection_upd(wlc, WLC_PROT_G_OVR, (s8) val);
break;
if (cmd == WLC_GET_VAR) {
bcmerror =
wlc_iovar_op(wlc, arg,
- (void *)((int8 *) arg + i),
+ (void *)((s8 *) arg + i),
len - i, arg, len, IOV_GET,
wlcif);
} else
bcmerror =
wlc_iovar_op(wlc, arg, NULL, 0,
- (void *)((int8 *) arg + i),
+ (void *)((s8 *) arg + i),
len - i, IOV_SET, wlcif);
break;
IOV_SET, NULL);
}
-/* simplified int8 get interface for common WLC_GET_VAR ioctl handler */
-int wlc_iovar_getint8(wlc_info_t *wlc, const char *name, int8 *arg)
+/* simplified s8 get interface for common WLC_GET_VAR ioctl handler */
+int wlc_iovar_gets8(wlc_info_t *wlc, const char *name, s8 *arg)
{
int iovar_int;
int err;
wlc_iovar_op(wlc, name, NULL, 0, &iovar_int, sizeof(iovar_int),
IOV_GET, NULL);
if (!err)
- *arg = (int8) iovar_int;
+ *arg = (s8) iovar_int;
return err;
}
}
void BCMFASTPATH
-wlc_txfifo(wlc_info_t *wlc, uint fifo, void *p, bool commit, int8 txpktpend)
+wlc_txfifo(wlc_info_t *wlc, uint fifo, void *p, bool commit, s8 txpktpend)
{
uint16 frameid = INVALIDFID;
d11txh_t *txh;
}
void BCMFASTPATH
-wlc_txfifo_complete(wlc_info_t *wlc, uint fifo, int8 txpktpend)
+wlc_txfifo_complete(wlc_info_t *wlc, uint fifo, s8 txpktpend)
{
TXPKTPENDDEC(wlc, fifo, txpktpend);
WL_TRACE(("wlc_txfifo_complete, pktpend dec %d to %d\n", txpktpend,
typedef struct wlc_protection {
bool _g; /* use g spec protection, driver internal */
- int8 g_override; /* override for use of g spec protection */
+ s8 g_override; /* override for use of g spec protection */
u8 gmode_user; /* user config gmode, operating band->gmode is different */
- int8 overlap; /* Overlap BSS/IBSS protection for both 11g and 11n */
- int8 nmode_user; /* user config nmode, operating pub->nmode is different */
- int8 n_cfg; /* use OFDM protection on MIMO frames */
- int8 n_cfg_override; /* override for use of N protection */
+ s8 overlap; /* Overlap BSS/IBSS protection for both 11g and 11n */
+ s8 nmode_user; /* user config nmode, operating pub->nmode is different */
+ s8 n_cfg; /* use OFDM protection on MIMO frames */
+ s8 n_cfg_override; /* override for use of N protection */
bool nongf; /* non-GF present protection */
- int8 nongf_override; /* override for use of GF protection */
- int8 n_pam_override; /* override for preamble: MM or GF */
+ s8 nongf_override; /* override for use of GF protection */
+ s8 n_pam_override; /* override for preamble: MM or GF */
bool n_obss; /* indicated OBSS Non-HT STA present */
uint longpre_detect_timeout; /* #sec until long preamble bcns gone */
u8 rxstreams; /* number of rxchains being used */
u8 ant_rx_ovr; /* rx antenna override */
- int8 txant; /* userTx antenna setting */
+ s8 txant; /* userTx antenna setting */
uint16 phytxant; /* phyTx antenna setting in txheader */
u8 ss_opmode; /* singlestream Operational mode, 0:siso; 1:cdd */
u8 rxchain_restore_delay; /* delay time to restore default rxchain */
- int8 ldpc; /* AUTO/ON/OFF ldpc cap supported */
+ s8 ldpc; /* AUTO/ON/OFF ldpc cap supported */
u8 txcore[MAX_STREAMS_SUPPORTED + 1]; /* bitmap of selected core for each Nsts */
- int8 spatial_policy;
+ s8 spatial_policy;
} wlc_stf_t;
#define WLC_STF_SS_STBC_TX(wlc, scb) \
ratespec_t rspec_override; /* 802.11 rate override */
ratespec_t mrspec_override; /* multicast rate override */
u8 band_stf_ss_mode; /* Configured STF type, 0:siso; 1:cdd */
- int8 band_stf_stbc_tx; /* STBC TX 0:off; 1:force on; -1:auto */
+ s8 band_stf_stbc_tx; /* STBC TX 0:off; 1:force on; -1:auto */
wlc_rateset_t hw_rateset; /* rates supported by chip (phy-specific) */
u8 basic_rate[WLC_MAXRATE + 1]; /* basic rates indexed by rate */
bool mimo_cap_40; /* 40 MHz cap enabled on this band */
- int8 antgain; /* antenna gain from srom */
+ s8 antgain; /* antenna gain from srom */
uint16 CWmin; /* The minimum size of contention window, in unit of aSlotTime */
uint16 CWmax; /* The maximum size of contention window, in unit of aSlotTime */
uint qvalid; /* DirFrmQValid and BcMcFrmQValid */
/* Regulatory power limits */
- int8 txpwr_local_max; /* regulatory local txpwr max */
+ s8 txpwr_local_max; /* regulatory local txpwr max */
u8 txpwr_local_constraint; /* local power contraint in dB */
#ifdef WLC_HIGH_ONLY
/* driver feature */
bool _rifs; /* enable per-packet rifs */
int32 rifs_advert; /* RIFS mode advertisement */
- int8 sgi_tx; /* sgi tx */
+ s8 sgi_tx; /* sgi tx */
bool wet; /* true if wireless ethernet bridging mode */
/* AP-STA synchronization, power save */
u8 mimoft; /* SIGN or 11N */
u8 mimo_band_bwcap; /* bw cap per band type */
- int8 txburst_limit_override; /* tx burst limit override */
+ s8 txburst_limit_override; /* tx burst limit override */
uint16 txburst_limit; /* tx burst limit value */
- int8 cck_40txbw; /* 11N, cck tx b/w override when in 40MHZ mode */
- int8 ofdm_40txbw; /* 11N, ofdm tx b/w override when in 40MHZ mode */
- int8 mimo_40txbw; /* 11N, mimo tx b/w override when in 40MHZ mode */
+ s8 cck_40txbw; /* 11N, cck tx b/w override when in 40MHZ mode */
+ s8 ofdm_40txbw; /* 11N, ofdm tx b/w override when in 40MHZ mode */
+ s8 mimo_40txbw; /* 11N, mimo tx b/w override when in 40MHZ mode */
ht_cap_ie_t ht_cap; /* HT CAP IE being advertised by this node */
uint seckeys; /* 54 key table shm address */
/* network config */
bool shortpreamble; /* currently operating with CCK ShortPreambles */
bool shortslot; /* currently using 11g ShortSlot timing */
- int8 barker_preamble; /* current Barker Preamble Mode */
- int8 shortslot_override; /* 11g ShortSlot override */
+ s8 barker_preamble; /* current Barker Preamble Mode */
+ s8 shortslot_override; /* 11g ShortSlot override */
bool include_legacy_erp; /* include Legacy ERP info elt ID 47 as well as g ID 42 */
bool barker_overlap_control; /* TRUE: be aware of overlapping BSSs for barker */
bool ignore_bcns; /* override: ignore non shortslot bcns in a 11g network */
bool legacy_probe; /* restricts probe requests to CCK rates */
wlc_protection_t *protection;
- int8 PLCPHdr_override; /* 802.11b Preamble Type override */
+ s8 PLCPHdr_override; /* 802.11b Preamble Type override */
wlc_stf_t *stf;
extern void wlc_recv(wlc_info_t *wlc, void *p);
extern bool wlc_dotxstatus(wlc_info_t *wlc, tx_status_t *txs, uint32 frm_tx2);
extern void wlc_txfifo(wlc_info_t *wlc, uint fifo, void *p, bool commit,
- int8 txpktpend);
-extern void wlc_txfifo_complete(wlc_info_t *wlc, uint fifo, int8 txpktpend);
+ s8 txpktpend);
+extern void wlc_txfifo_complete(wlc_info_t *wlc, uint fifo, s8 txpktpend);
extern void wlc_info_init(wlc_info_t *wlc, int unit);
extern void wlc_print_txstatus(tx_status_t *txs);
extern int wlc_xmtfifo_sz_get(wlc_info_t *wlc, uint fifo, uint *blocks);
#define WLC_SNR_INVALID 0 /* invalid SNR value */
/* a large TX Power as an init value to factor out of MIN() calculations,
- * keep low enough to fit in an int8, units are .25 dBm
+ * keep low enough to fit in an s8, units are .25 dBm
*/
#define WLC_TXPWR_MAX (127) /* ~32 dBm = 1,500 mW */
uint16 beacon_period; /* units are Kusec */
uint16 atim_window; /* units are Kusec */
chanspec_t chanspec; /* Channel num, bw, ctrl_sb and band */
- int8 infra; /* 0=IBSS, 1=infrastructure, 2=unknown */
+ s8 infra; /* 0=IBSS, 1=infrastructure, 2=unknown */
wlc_rateset_t rateset; /* supported rates */
u8 dtim_period; /* DTIM period */
- int8 phy_noise; /* noise right after tx (in dBm) */
+ s8 phy_noise; /* noise right after tx (in dBm) */
uint16 capability; /* Capability information */
struct dot11_bcn_prb *bcn_prb; /* beacon/probe response frame (ioctl na) */
uint16 bcn_prb_len; /* beacon/probe response frame length (ioctl na) */
u8 _n_enab; /* bitmap of 11N + HT support */
bool _n_reqd; /* N support required for clients */
- int8 _coex; /* 20/40 MHz BSS Management AUTO, ENAB, DISABLE */
+ s8 _coex; /* 20/40 MHz BSS Management AUTO, ENAB, DISABLE */
bool _priofc; /* Priority-based flowcontrol */
struct ether_addr cur_etheraddr; /* our local ethernet address */
extern void wlc_scb_ratesel_init_all(struct wlc_info *wlc);
/* ioctl */
-extern int wlc_iovar_getint8(struct wlc_info *wlc, const char *name,
- int8 *arg);
+extern int wlc_iovar_gets8(struct wlc_info *wlc, const char *name,
+ s8 *arg);
extern int wlc_iovar_check(wlc_pub_t *pub, const bcm_iovar_t *vi, void *arg,
int len, bool set);
static inline int wlc_iovar_getu8(struct wlc_info *wlc, const char *name,
u8 *arg)
{
- return wlc_iovar_getint8(wlc, name, (int8 *) arg);
+ return wlc_iovar_gets8(wlc, name, (s8 *) arg);
}
static inline int wlc_iovar_setuint(struct wlc_info *wlc, const char *name,
#define WLC_STF_SS_STBC_RX(wlc) (WLCISNPHY(wlc->band) && \
NREV_GT(wlc->band->phyrev, 3) && NREV_LE(wlc->band->phyrev, 6))
-static int8 wlc_stf_stbc_rx_get(wlc_info_t *wlc);
+static s8 wlc_stf_stbc_rx_get(wlc_info_t *wlc);
static bool wlc_stf_stbc_tx_set(wlc_info_t *wlc, int32 int_val);
static int wlc_stf_txcore_set(wlc_info_t *wlc, u8 Nsts, u8 val);
static int wlc_stf_spatial_policy_set(wlc_info_t *wlc, int val);
setbit(ss_algo_channel, PHY_TXC1_MODE_STBC);
}
-static int8 wlc_stf_stbc_rx_get(wlc_info_t *wlc)
+static s8 wlc_stf_stbc_rx_get(wlc_info_t *wlc)
{
return (wlc->ht_cap.cap & HT_CAP_RX_STBC_MASK) >> HT_CAP_RX_STBC_SHIFT;
}
else
wlc->ht_cap.cap |= HT_CAP_TX_STBC;
- wlc->bandstate[BAND_2G_INDEX]->band_stf_stbc_tx = (int8) int_val;
- wlc->bandstate[BAND_5G_INDEX]->band_stf_stbc_tx = (int8) int_val;
+ wlc->bandstate[BAND_2G_INDEX]->band_stf_stbc_tx = (s8) int_val;
+ wlc->bandstate[BAND_5G_INDEX]->band_stf_stbc_tx = (s8) int_val;
return TRUE;
}
WL_TRACE(("wl%d: %s: val %x\n", wlc->pub->unit, __func__, val));
- wlc->stf->spatial_policy = (int8) val;
+ wlc->stf->spatial_policy = (s8) val;
for (i = 1; i <= MAX_STREAMS_SUPPORTED; i++) {
core_mask = (val == MAX_SPATIAL_EXPANSION) ?
wlc->stf->txchain : txcore_default[i];
{
}
-int wlc_stf_ant_txant_validate(wlc_info_t *wlc, int8 val)
+int wlc_stf_ant_txant_validate(wlc_info_t *wlc, s8 val)
{
int bcmerror = BCME_OK;
}
if (bcmerror == BCME_OK)
- wlc->stf->txant = (int8) val;
+ wlc->stf->txant = (s8) val;
return bcmerror;
*/
static void _wlc_stf_phy_txant_upd(wlc_info_t *wlc)
{
- int8 txant;
+ s8 txant;
- txant = (int8) wlc->stf->txant;
+ txant = (s8) wlc->stf->txant;
ASSERT(txant == ANT_TX_FORCE_0 || txant == ANT_TX_FORCE_1
|| txant == ANT_TX_LAST_RX);
extern int wlc_stf_rxchain_set(wlc_info_t *wlc, int32 int_val);
extern bool wlc_stf_stbc_rx_set(wlc_info_t *wlc, int32 int_val);
-extern int wlc_stf_ant_txant_validate(wlc_info_t *wlc, int8 val);
+extern int wlc_stf_ant_txant_validate(wlc_info_t *wlc, s8 val);
extern void wlc_stf_phy_txant_upd(wlc_info_t *wlc);
extern void wlc_stf_phy_chain_calc(wlc_info_t *wlc);
extern uint16 wlc_stf_phytxchain_sel(wlc_info_t *wlc, ratespec_t rspec);
if (DMA64_ENAB(di) && DMA64_MODE(di)) {
if (di->txd64)
DMA_FREE_CONSISTENT(di->osh,
- ((int8 *) (uintptr) di->txd64 -
+ ((s8 *) (uintptr) di->txd64 -
di->txdalign), di->txdalloc,
(di->txdpaorig), &di->tx_dmah);
if (di->rxd64)
DMA_FREE_CONSISTENT(di->osh,
- ((int8 *) (uintptr) di->rxd64 -
+ ((s8 *) (uintptr) di->rxd64 -
di->rxdalign), di->rxdalloc,
(di->rxdpaorig), &di->rx_dmah);
} else if (DMA32_ENAB(di)) {
if (di->txd32)
DMA_FREE_CONSISTENT(di->osh,
- ((int8 *) (uintptr) di->txd32 -
+ ((s8 *) (uintptr) di->txd32 -
di->txdalign), di->txdalloc,
(di->txdpaorig), &di->tx_dmah);
if (di->rxd32)
DMA_FREE_CONSISTENT(di->osh,
- ((int8 *) (uintptr) di->rxd32 -
+ ((s8 *) (uintptr) di->rxd32 -
di->rxdalign), di->rxdalloc,
(di->rxdpaorig), &di->rx_dmah);
} else
ASSERT(PHYSADDRHI(di->txdpaorig) == 0);
di->txd32 = (dma32dd_t *) ROUNDUP((uintptr) va, align);
di->txdalign =
- (uint) ((int8 *) (uintptr) di->txd32 - (int8 *) va);
+ (uint) ((s8 *) (uintptr) di->txd32 - (s8 *) va);
PHYSADDRLOSET(di->txdpa,
PHYSADDRLO(di->txdpaorig) + di->txdalign);
ASSERT(PHYSADDRHI(di->rxdpaorig) == 0);
di->rxd32 = (dma32dd_t *) ROUNDUP((uintptr) va, align);
di->rxdalign =
- (uint) ((int8 *) (uintptr) di->rxd32 - (int8 *) va);
+ (uint) ((s8 *) (uintptr) di->rxd32 - (s8 *) va);
PHYSADDRLOSET(di->rxdpa,
PHYSADDRLO(di->rxdpaorig) + di->rxdalign);
align = (1 << align_bits);
di->txd64 = (dma64dd_t *) ROUNDUP((uintptr) va, align);
di->txdalign =
- (uint) ((int8 *) (uintptr) di->txd64 - (int8 *) va);
+ (uint) ((s8 *) (uintptr) di->txd64 - (s8 *) va);
PHYSADDRLOSET(di->txdpa,
PHYSADDRLO(di->txdpaorig) + di->txdalign);
/* Make sure that alignment didn't overflow */
align = (1 << align_bits);
di->rxd64 = (dma64dd_t *) ROUNDUP((uintptr) va, align);
di->rxdalign =
- (uint) ((int8 *) (uintptr) di->rxd64 - (int8 *) va);
+ (uint) ((s8 *) (uintptr) di->rxd64 - (s8 *) va);
PHYSADDRLOSET(di->rxdpa,
PHYSADDRLO(di->rxdpaorig) + di->rxdalign);
/* Make sure that alignment didn't overflow */
/* Change resource dependancies masks */
typedef struct {
uint32 res_mask; /* resources (chip specific) */
- int8 action; /* action */
+ s8 action; /* action */
uint32 depend_mask; /* changes to the dependancies mask */
bool(*filter) (si_t *sih); /* action is taken when filter is NULL or return TRUE */
} pmu_res_depend_t;
#define SET_SBREG(sii, r, mask, val) \
W_SBREG((sii), (r), ((R_SBREG((sii), (r)) & ~(mask)) | (val)))
-#define REGS2SB(va) (sbconfig_t *) ((int8 *)(va) + SBCONFIGOFF)
+#define REGS2SB(va) (sbconfig_t *) ((s8 *)(va) + SBCONFIGOFF)
/* sonicsrev */
#define SONICS_2_2 (SBIDL_RV_2_2 >> SBIDL_RV_SHIFT)
projects / mv-sheeva.git / commitdiff