OpenCloudOS-Kernel/drivers/net/wireless/ath/ath9k/hw.c

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/*
* Copyright (c) 2008-2010 Atheros Communications Inc.
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include <linux/io.h>
#include <asm/unaligned.h>
#include "hw.h"
#include "hw-ops.h"
#include "rc.h"
#include "ar9003_mac.h"
#define ATH9K_CLOCK_RATE_CCK 22
#define ATH9K_CLOCK_RATE_5GHZ_OFDM 40
#define ATH9K_CLOCK_RATE_2GHZ_OFDM 44
#define ATH9K_CLOCK_FAST_RATE_5GHZ_OFDM 44
static bool ath9k_hw_set_reset_reg(struct ath_hw *ah, u32 type);
MODULE_AUTHOR("Atheros Communications");
MODULE_DESCRIPTION("Support for Atheros 802.11n wireless LAN cards.");
MODULE_SUPPORTED_DEVICE("Atheros 802.11n WLAN cards");
MODULE_LICENSE("Dual BSD/GPL");
static int __init ath9k_init(void)
{
return 0;
}
module_init(ath9k_init);
static void __exit ath9k_exit(void)
{
return;
}
module_exit(ath9k_exit);
/* Private hardware callbacks */
static void ath9k_hw_init_cal_settings(struct ath_hw *ah)
{
ath9k_hw_private_ops(ah)->init_cal_settings(ah);
}
static void ath9k_hw_init_mode_regs(struct ath_hw *ah)
{
ath9k_hw_private_ops(ah)->init_mode_regs(ah);
}
static bool ath9k_hw_macversion_supported(struct ath_hw *ah)
{
struct ath_hw_private_ops *priv_ops = ath9k_hw_private_ops(ah);
return priv_ops->macversion_supported(ah->hw_version.macVersion);
}
static u32 ath9k_hw_compute_pll_control(struct ath_hw *ah,
struct ath9k_channel *chan)
{
return ath9k_hw_private_ops(ah)->compute_pll_control(ah, chan);
}
static void ath9k_hw_init_mode_gain_regs(struct ath_hw *ah)
{
if (!ath9k_hw_private_ops(ah)->init_mode_gain_regs)
return;
ath9k_hw_private_ops(ah)->init_mode_gain_regs(ah);
}
/********************/
/* Helper Functions */
/********************/
static u32 ath9k_hw_mac_clks(struct ath_hw *ah, u32 usecs)
{
struct ieee80211_conf *conf = &ath9k_hw_common(ah)->hw->conf;
if (!ah->curchan) /* should really check for CCK instead */
return usecs *ATH9K_CLOCK_RATE_CCK;
if (conf->channel->band == IEEE80211_BAND_2GHZ)
return usecs *ATH9K_CLOCK_RATE_2GHZ_OFDM;
if (ah->caps.hw_caps & ATH9K_HW_CAP_FASTCLOCK)
return usecs * ATH9K_CLOCK_FAST_RATE_5GHZ_OFDM;
else
return usecs * ATH9K_CLOCK_RATE_5GHZ_OFDM;
}
static u32 ath9k_hw_mac_to_clks(struct ath_hw *ah, u32 usecs)
{
struct ieee80211_conf *conf = &ath9k_hw_common(ah)->hw->conf;
if (conf_is_ht40(conf))
return ath9k_hw_mac_clks(ah, usecs) * 2;
else
return ath9k_hw_mac_clks(ah, usecs);
}
bool ath9k_hw_wait(struct ath_hw *ah, u32 reg, u32 mask, u32 val, u32 timeout)
{
int i;
BUG_ON(timeout < AH_TIME_QUANTUM);
for (i = 0; i < (timeout / AH_TIME_QUANTUM); i++) {
if ((REG_READ(ah, reg) & mask) == val)
return true;
udelay(AH_TIME_QUANTUM);
}
ath_print(ath9k_hw_common(ah), ATH_DBG_ANY,
"timeout (%d us) on reg 0x%x: 0x%08x & 0x%08x != 0x%08x\n",
timeout, reg, REG_READ(ah, reg), mask, val);
return false;
}
EXPORT_SYMBOL(ath9k_hw_wait);
u32 ath9k_hw_reverse_bits(u32 val, u32 n)
{
u32 retval;
int i;
for (i = 0, retval = 0; i < n; i++) {
retval = (retval << 1) | (val & 1);
val >>= 1;
}
return retval;
}
bool ath9k_get_channel_edges(struct ath_hw *ah,
u16 flags, u16 *low,
u16 *high)
{
struct ath9k_hw_capabilities *pCap = &ah->caps;
if (flags & CHANNEL_5GHZ) {
*low = pCap->low_5ghz_chan;
*high = pCap->high_5ghz_chan;
return true;
}
if ((flags & CHANNEL_2GHZ)) {
*low = pCap->low_2ghz_chan;
*high = pCap->high_2ghz_chan;
return true;
}
return false;
}
u16 ath9k_hw_computetxtime(struct ath_hw *ah,
u8 phy, int kbps,
u32 frameLen, u16 rateix,
bool shortPreamble)
{
u32 bitsPerSymbol, numBits, numSymbols, phyTime, txTime;
if (kbps == 0)
return 0;
switch (phy) {
case WLAN_RC_PHY_CCK:
phyTime = CCK_PREAMBLE_BITS + CCK_PLCP_BITS;
if (shortPreamble)
phyTime >>= 1;
numBits = frameLen << 3;
txTime = CCK_SIFS_TIME + phyTime + ((numBits * 1000) / kbps);
break;
case WLAN_RC_PHY_OFDM:
if (ah->curchan && IS_CHAN_QUARTER_RATE(ah->curchan)) {
bitsPerSymbol = (kbps * OFDM_SYMBOL_TIME_QUARTER) / 1000;
numBits = OFDM_PLCP_BITS + (frameLen << 3);
numSymbols = DIV_ROUND_UP(numBits, bitsPerSymbol);
txTime = OFDM_SIFS_TIME_QUARTER
+ OFDM_PREAMBLE_TIME_QUARTER
+ (numSymbols * OFDM_SYMBOL_TIME_QUARTER);
} else if (ah->curchan &&
IS_CHAN_HALF_RATE(ah->curchan)) {
bitsPerSymbol = (kbps * OFDM_SYMBOL_TIME_HALF) / 1000;
numBits = OFDM_PLCP_BITS + (frameLen << 3);
numSymbols = DIV_ROUND_UP(numBits, bitsPerSymbol);
txTime = OFDM_SIFS_TIME_HALF +
OFDM_PREAMBLE_TIME_HALF
+ (numSymbols * OFDM_SYMBOL_TIME_HALF);
} else {
bitsPerSymbol = (kbps * OFDM_SYMBOL_TIME) / 1000;
numBits = OFDM_PLCP_BITS + (frameLen << 3);
numSymbols = DIV_ROUND_UP(numBits, bitsPerSymbol);
txTime = OFDM_SIFS_TIME + OFDM_PREAMBLE_TIME
+ (numSymbols * OFDM_SYMBOL_TIME);
}
break;
default:
ath_print(ath9k_hw_common(ah), ATH_DBG_FATAL,
"Unknown phy %u (rate ix %u)\n", phy, rateix);
txTime = 0;
break;
}
return txTime;
}
EXPORT_SYMBOL(ath9k_hw_computetxtime);
void ath9k_hw_get_channel_centers(struct ath_hw *ah,
struct ath9k_channel *chan,
struct chan_centers *centers)
{
int8_t extoff;
if (!IS_CHAN_HT40(chan)) {
centers->ctl_center = centers->ext_center =
centers->synth_center = chan->channel;
return;
}
if ((chan->chanmode == CHANNEL_A_HT40PLUS) ||
(chan->chanmode == CHANNEL_G_HT40PLUS)) {
centers->synth_center =
chan->channel + HT40_CHANNEL_CENTER_SHIFT;
extoff = 1;
} else {
centers->synth_center =
chan->channel - HT40_CHANNEL_CENTER_SHIFT;
extoff = -1;
}
centers->ctl_center =
centers->synth_center - (extoff * HT40_CHANNEL_CENTER_SHIFT);
/* 25 MHz spacing is supported by hw but not on upper layers */
centers->ext_center =
centers->synth_center + (extoff * HT40_CHANNEL_CENTER_SHIFT);
}
/******************/
/* Chip Revisions */
/******************/
static void ath9k_hw_read_revisions(struct ath_hw *ah)
{
u32 val;
val = REG_READ(ah, AR_SREV) & AR_SREV_ID;
if (val == 0xFF) {
val = REG_READ(ah, AR_SREV);
ah->hw_version.macVersion =
(val & AR_SREV_VERSION2) >> AR_SREV_TYPE2_S;
ah->hw_version.macRev = MS(val, AR_SREV_REVISION2);
ah->is_pciexpress = (val & AR_SREV_TYPE2_HOST_MODE) ? 0 : 1;
} else {
if (!AR_SREV_9100(ah))
ah->hw_version.macVersion = MS(val, AR_SREV_VERSION);
ah->hw_version.macRev = val & AR_SREV_REVISION;
if (ah->hw_version.macVersion == AR_SREV_VERSION_5416_PCIE)
ah->is_pciexpress = true;
}
}
/************************************/
/* HW Attach, Detach, Init Routines */
/************************************/
static void ath9k_hw_disablepcie(struct ath_hw *ah)
{
if (AR_SREV_9100(ah))
return;
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_PCIE_SERDES, 0x9248fc00);
REG_WRITE(ah, AR_PCIE_SERDES, 0x24924924);
REG_WRITE(ah, AR_PCIE_SERDES, 0x28000029);
REG_WRITE(ah, AR_PCIE_SERDES, 0x57160824);
REG_WRITE(ah, AR_PCIE_SERDES, 0x25980579);
REG_WRITE(ah, AR_PCIE_SERDES, 0x00000000);
REG_WRITE(ah, AR_PCIE_SERDES, 0x1aaabe40);
REG_WRITE(ah, AR_PCIE_SERDES, 0xbe105554);
REG_WRITE(ah, AR_PCIE_SERDES, 0x000e1007);
REG_WRITE(ah, AR_PCIE_SERDES2, 0x00000000);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
}
/* This should work for all families including legacy */
static bool ath9k_hw_chip_test(struct ath_hw *ah)
{
struct ath_common *common = ath9k_hw_common(ah);
u32 regAddr[2] = { AR_STA_ID0 };
u32 regHold[2];
u32 patternData[4] = { 0x55555555,
0xaaaaaaaa,
0x66666666,
0x99999999 };
int i, j, loop_max;
if (!AR_SREV_9300_20_OR_LATER(ah)) {
loop_max = 2;
regAddr[1] = AR_PHY_BASE + (8 << 2);
} else
loop_max = 1;
for (i = 0; i < loop_max; i++) {
u32 addr = regAddr[i];
u32 wrData, rdData;
regHold[i] = REG_READ(ah, addr);
for (j = 0; j < 0x100; j++) {
wrData = (j << 16) | j;
REG_WRITE(ah, addr, wrData);
rdData = REG_READ(ah, addr);
if (rdData != wrData) {
ath_print(common, ATH_DBG_FATAL,
"address test failed "
"addr: 0x%08x - wr:0x%08x != "
"rd:0x%08x\n",
addr, wrData, rdData);
return false;
}
}
for (j = 0; j < 4; j++) {
wrData = patternData[j];
REG_WRITE(ah, addr, wrData);
rdData = REG_READ(ah, addr);
if (wrData != rdData) {
ath_print(common, ATH_DBG_FATAL,
"address test failed "
"addr: 0x%08x - wr:0x%08x != "
"rd:0x%08x\n",
addr, wrData, rdData);
return false;
}
}
REG_WRITE(ah, regAddr[i], regHold[i]);
}
udelay(100);
return true;
}
static void ath9k_hw_init_config(struct ath_hw *ah)
{
int i;
ah->config.dma_beacon_response_time = 2;
ah->config.sw_beacon_response_time = 10;
ah->config.additional_swba_backoff = 0;
ah->config.ack_6mb = 0x0;
ah->config.cwm_ignore_extcca = 0;
ah->config.pcie_powersave_enable = 0;
ah->config.pcie_clock_req = 0;
ah->config.pcie_waen = 0;
ah->config.analog_shiftreg = 1;
ah->config.ofdm_trig_low = 200;
ah->config.ofdm_trig_high = 500;
ah->config.cck_trig_high = 200;
ah->config.cck_trig_low = 100;
/*
* For now ANI is disabled for AR9003, it is still
* being tested.
*/
if (!AR_SREV_9300_20_OR_LATER(ah))
ah->config.enable_ani = 1;
for (i = 0; i < AR_EEPROM_MODAL_SPURS; i++) {
ah->config.spurchans[i][0] = AR_NO_SPUR;
ah->config.spurchans[i][1] = AR_NO_SPUR;
}
if (ah->hw_version.devid != AR2427_DEVID_PCIE)
ah->config.ht_enable = 1;
else
ah->config.ht_enable = 0;
ah->config.rx_intr_mitigation = true;
/*
* Tx IQ Calibration (ah->config.tx_iq_calibration) is only
* used by AR9003, but it is showing reliability issues.
* It will take a while to fix so this is currently disabled.
*/
/*
* We need this for PCI devices only (Cardbus, PCI, miniPCI)
* _and_ if on non-uniprocessor systems (Multiprocessor/HT).
* This means we use it for all AR5416 devices, and the few
* minor PCI AR9280 devices out there.
*
* Serialization is required because these devices do not handle
* well the case of two concurrent reads/writes due to the latency
* involved. During one read/write another read/write can be issued
* on another CPU while the previous read/write may still be working
* on our hardware, if we hit this case the hardware poops in a loop.
* We prevent this by serializing reads and writes.
*
* This issue is not present on PCI-Express devices or pre-AR5416
* devices (legacy, 802.11abg).
*/
if (num_possible_cpus() > 1)
ah->config.serialize_regmode = SER_REG_MODE_AUTO;
}
static void ath9k_hw_init_defaults(struct ath_hw *ah)
{
struct ath_regulatory *regulatory = ath9k_hw_regulatory(ah);
regulatory->country_code = CTRY_DEFAULT;
regulatory->power_limit = MAX_RATE_POWER;
regulatory->tp_scale = ATH9K_TP_SCALE_MAX;
ah->hw_version.magic = AR5416_MAGIC;
ah->hw_version.subvendorid = 0;
ah->ah_flags = 0;
if (!AR_SREV_9100(ah))
ah->ah_flags = AH_USE_EEPROM;
ah->atim_window = 0;
ah->sta_id1_defaults = AR_STA_ID1_CRPT_MIC_ENABLE;
ah->beacon_interval = 100;
ah->enable_32kHz_clock = DONT_USE_32KHZ;
ah->slottime = (u32) -1;
ah->globaltxtimeout = (u32) -1;
ah->power_mode = ATH9K_PM_UNDEFINED;
}
static int ath9k_hw_init_macaddr(struct ath_hw *ah)
{
struct ath_common *common = ath9k_hw_common(ah);
u32 sum;
int i;
u16 eeval;
u32 EEP_MAC[] = { EEP_MAC_LSW, EEP_MAC_MID, EEP_MAC_MSW };
sum = 0;
for (i = 0; i < 3; i++) {
eeval = ah->eep_ops->get_eeprom(ah, EEP_MAC[i]);
sum += eeval;
common->macaddr[2 * i] = eeval >> 8;
common->macaddr[2 * i + 1] = eeval & 0xff;
}
if (sum == 0 || sum == 0xffff * 3)
return -EADDRNOTAVAIL;
return 0;
}
static int ath9k_hw_post_init(struct ath_hw *ah)
{
int ecode;
if (!AR_SREV_9271(ah)) {
if (!ath9k_hw_chip_test(ah))
return -ENODEV;
}
if (!AR_SREV_9300_20_OR_LATER(ah)) {
ecode = ar9002_hw_rf_claim(ah);
if (ecode != 0)
return ecode;
}
ecode = ath9k_hw_eeprom_init(ah);
if (ecode != 0)
return ecode;
ath_print(ath9k_hw_common(ah), ATH_DBG_CONFIG,
"Eeprom VER: %d, REV: %d\n",
ah->eep_ops->get_eeprom_ver(ah),
ah->eep_ops->get_eeprom_rev(ah));
ecode = ath9k_hw_rf_alloc_ext_banks(ah);
if (ecode) {
ath_print(ath9k_hw_common(ah), ATH_DBG_FATAL,
"Failed allocating banks for "
"external radio\n");
return ecode;
}
if (!AR_SREV_9100(ah)) {
ath9k_hw_ani_setup(ah);
ath9k_hw_ani_init(ah);
}
return 0;
}
static void ath9k_hw_attach_ops(struct ath_hw *ah)
{
if (AR_SREV_9300_20_OR_LATER(ah))
ar9003_hw_attach_ops(ah);
else
ar9002_hw_attach_ops(ah);
}
/* Called for all hardware families */
static int __ath9k_hw_init(struct ath_hw *ah)
{
struct ath_common *common = ath9k_hw_common(ah);
int r = 0;
if (ah->hw_version.devid == AR5416_AR9100_DEVID)
ah->hw_version.macVersion = AR_SREV_VERSION_9100;
if (!ath9k_hw_set_reset_reg(ah, ATH9K_RESET_POWER_ON)) {
ath_print(common, ATH_DBG_FATAL,
"Couldn't reset chip\n");
return -EIO;
}
ath9k_hw_init_defaults(ah);
ath9k_hw_init_config(ah);
ath9k_hw_attach_ops(ah);
if (!ath9k_hw_setpower(ah, ATH9K_PM_AWAKE)) {
ath_print(common, ATH_DBG_FATAL, "Couldn't wakeup chip\n");
return -EIO;
}
if (ah->config.serialize_regmode == SER_REG_MODE_AUTO) {
if (ah->hw_version.macVersion == AR_SREV_VERSION_5416_PCI ||
(AR_SREV_9280(ah) && !ah->is_pciexpress)) {
ah->config.serialize_regmode =
SER_REG_MODE_ON;
} else {
ah->config.serialize_regmode =
SER_REG_MODE_OFF;
}
}
ath_print(common, ATH_DBG_RESET, "serialize_regmode is %d\n",
ah->config.serialize_regmode);
ath9k: Fix maximum tx fifo settings for single stream devices Atheros single stream AR9285 and AR9271 have half the PCU TX FIFO buffer size of that of dual stream devices. Dual stream devices have a max PCU TX FIFO size of 8 KB while single stream devices have 4 KB. Single stream devices have an issue though and require hardware only to use half of the amount of its capable PCU TX FIFO size, 2 KB and this requires a change in software. Technically a change would not have been required (except for frame burst considerations of 128 bytes) if these devices would have been able to use the full 4 KB of the PCU TX FIFO size but our systems engineers recommend 2 KB to be used only. We enforce this through software by reducing the max frame triggger level to 2 KB. Fixing the max frame trigger level should then have a few benefits: * The PER will now be adjusted as designed for underruns when the max trigger level is reached. This should help alleviate the bus as the rate control algorithm chooses a slower rate which should ensure frames are transmitted properly under high system bus load. * The poll we use on our TX queues should now trigger and work as designed for single stream devices. The hardware passes data from each TX queue on the PCU TX FIFO queue respecting each queue's priority. The new trigger level ensures this seeding of the PCU TX FIFO queue occurs as designed which could mean avoiding false resets and actually reseting hw correctly when a TX queue is indeed stuck. * Some undocumented / unsupported behaviour could have been triggered when the max trigger level level was being set to 4 KB on single stream devices. Its not clear what this issue was to me yet. Cc: Kyungwan Nam <kyungwan.nam@atheros.com> Cc: Bennyam Malavazi <bennyam.malavazi@atheros.com> Cc: Stephen Chen <stephen.chen@atheros.com> Cc: Shan Palanisamy <shan.palanisamy@atheros.com> Cc: Paul Shaw <paul.shaw@atheros.com> Signed-off-by: Vasanthakumar Thiagarajan <vasanth@atheros.com> Signed-off-by: Luis R. Rodriguez <lrodriguez@atheros.com> Signed-off-by: John W. Linville <linville@tuxdriver.com>
2009-11-25 10:37:57 +08:00
if (AR_SREV_9285(ah) || AR_SREV_9271(ah))
ah->config.max_txtrig_level = MAX_TX_FIFO_THRESHOLD >> 1;
else
ah->config.max_txtrig_level = MAX_TX_FIFO_THRESHOLD;
if (!ath9k_hw_macversion_supported(ah)) {
ath_print(common, ATH_DBG_FATAL,
"Mac Chip Rev 0x%02x.%x is not supported by "
"this driver\n", ah->hw_version.macVersion,
ah->hw_version.macRev);
return -EOPNOTSUPP;
}
if (AR_SREV_9271(ah) || AR_SREV_9100(ah))
ah->is_pciexpress = false;
ah->hw_version.phyRev = REG_READ(ah, AR_PHY_CHIP_ID);
ath9k_hw_init_cal_settings(ah);
ah->ani_function = ATH9K_ANI_ALL;
if (AR_SREV_9280_10_OR_LATER(ah) && !AR_SREV_9300_20_OR_LATER(ah))
ah->ani_function &= ~ATH9K_ANI_NOISE_IMMUNITY_LEVEL;
ath9k_hw_init_mode_regs(ah);
if (ah->is_pciexpress)
ath9k_hw_configpcipowersave(ah, 0, 0);
else
ath9k_hw_disablepcie(ah);
if (!AR_SREV_9300_20_OR_LATER(ah))
ar9002_hw_cck_chan14_spread(ah);
r = ath9k_hw_post_init(ah);
if (r)
return r;
ath9k_hw_init_mode_gain_regs(ah);
r = ath9k_hw_fill_cap_info(ah);
if (r)
return r;
r = ath9k_hw_init_macaddr(ah);
if (r) {
ath_print(common, ATH_DBG_FATAL,
"Failed to initialize MAC address\n");
return r;
}
if (AR_SREV_9285(ah) || AR_SREV_9271(ah))
ah->tx_trig_level = (AR_FTRIG_256B >> AR_FTRIG_S);
else
ah->tx_trig_level = (AR_FTRIG_512B >> AR_FTRIG_S);
if (AR_SREV_9300_20_OR_LATER(ah))
ar9003_hw_set_nf_limits(ah);
ath9k_init_nfcal_hist_buffer(ah);
common->state = ATH_HW_INITIALIZED;
return 0;
}
int ath9k_hw_init(struct ath_hw *ah)
{
int ret;
struct ath_common *common = ath9k_hw_common(ah);
/* These are all the AR5008/AR9001/AR9002 hardware family of chipsets */
switch (ah->hw_version.devid) {
case AR5416_DEVID_PCI:
case AR5416_DEVID_PCIE:
case AR5416_AR9100_DEVID:
case AR9160_DEVID_PCI:
case AR9280_DEVID_PCI:
case AR9280_DEVID_PCIE:
case AR9285_DEVID_PCIE:
case AR9287_DEVID_PCI:
case AR9287_DEVID_PCIE:
case AR2427_DEVID_PCIE:
case AR9300_DEVID_PCIE:
break;
default:
if (common->bus_ops->ath_bus_type == ATH_USB)
break;
ath_print(common, ATH_DBG_FATAL,
"Hardware device ID 0x%04x not supported\n",
ah->hw_version.devid);
return -EOPNOTSUPP;
}
ret = __ath9k_hw_init(ah);
if (ret) {
ath_print(common, ATH_DBG_FATAL,
"Unable to initialize hardware; "
"initialization status: %d\n", ret);
return ret;
}
return 0;
}
EXPORT_SYMBOL(ath9k_hw_init);
static void ath9k_hw_init_qos(struct ath_hw *ah)
{
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_MIC_QOS_CONTROL, 0x100aa);
REG_WRITE(ah, AR_MIC_QOS_SELECT, 0x3210);
REG_WRITE(ah, AR_QOS_NO_ACK,
SM(2, AR_QOS_NO_ACK_TWO_BIT) |
SM(5, AR_QOS_NO_ACK_BIT_OFF) |
SM(0, AR_QOS_NO_ACK_BYTE_OFF));
REG_WRITE(ah, AR_TXOP_X, AR_TXOP_X_VAL);
REG_WRITE(ah, AR_TXOP_0_3, 0xFFFFFFFF);
REG_WRITE(ah, AR_TXOP_4_7, 0xFFFFFFFF);
REG_WRITE(ah, AR_TXOP_8_11, 0xFFFFFFFF);
REG_WRITE(ah, AR_TXOP_12_15, 0xFFFFFFFF);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
}
static void ath9k_hw_init_pll(struct ath_hw *ah,
struct ath9k_channel *chan)
{
u32 pll = ath9k_hw_compute_pll_control(ah, chan);
REG_WRITE(ah, AR_RTC_PLL_CONTROL, pll);
/* Switch the core clock for ar9271 to 117Mhz */
if (AR_SREV_9271(ah)) {
udelay(500);
REG_WRITE(ah, 0x50040, 0x304);
}
udelay(RTC_PLL_SETTLE_DELAY);
REG_WRITE(ah, AR_RTC_SLEEP_CLK, AR_RTC_FORCE_DERIVED_CLK);
}
static void ath9k_hw_init_interrupt_masks(struct ath_hw *ah,
enum nl80211_iftype opmode)
{
u32 imr_reg = AR_IMR_TXERR |
AR_IMR_TXURN |
AR_IMR_RXERR |
AR_IMR_RXORN |
AR_IMR_BCNMISC;
if (AR_SREV_9300_20_OR_LATER(ah)) {
imr_reg |= AR_IMR_RXOK_HP;
if (ah->config.rx_intr_mitigation)
imr_reg |= AR_IMR_RXINTM | AR_IMR_RXMINTR;
else
imr_reg |= AR_IMR_RXOK_LP;
} else {
if (ah->config.rx_intr_mitigation)
imr_reg |= AR_IMR_RXINTM | AR_IMR_RXMINTR;
else
imr_reg |= AR_IMR_RXOK;
}
if (ah->config.tx_intr_mitigation)
imr_reg |= AR_IMR_TXINTM | AR_IMR_TXMINTR;
else
imr_reg |= AR_IMR_TXOK;
if (opmode == NL80211_IFTYPE_AP)
imr_reg |= AR_IMR_MIB;
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_IMR, imr_reg);
ah->imrs2_reg |= AR_IMR_S2_GTT;
REG_WRITE(ah, AR_IMR_S2, ah->imrs2_reg);
if (!AR_SREV_9100(ah)) {
REG_WRITE(ah, AR_INTR_SYNC_CAUSE, 0xFFFFFFFF);
REG_WRITE(ah, AR_INTR_SYNC_ENABLE, AR_INTR_SYNC_DEFAULT);
REG_WRITE(ah, AR_INTR_SYNC_MASK, 0);
}
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
if (AR_SREV_9300_20_OR_LATER(ah)) {
REG_WRITE(ah, AR_INTR_PRIO_ASYNC_ENABLE, 0);
REG_WRITE(ah, AR_INTR_PRIO_ASYNC_MASK, 0);
REG_WRITE(ah, AR_INTR_PRIO_SYNC_ENABLE, 0);
REG_WRITE(ah, AR_INTR_PRIO_SYNC_MASK, 0);
}
}
static void ath9k_hw_setslottime(struct ath_hw *ah, u32 us)
{
u32 val = ath9k_hw_mac_to_clks(ah, us);
val = min(val, (u32) 0xFFFF);
REG_WRITE(ah, AR_D_GBL_IFS_SLOT, val);
}
static void ath9k_hw_set_ack_timeout(struct ath_hw *ah, u32 us)
{
u32 val = ath9k_hw_mac_to_clks(ah, us);
val = min(val, (u32) MS(0xFFFFFFFF, AR_TIME_OUT_ACK));
REG_RMW_FIELD(ah, AR_TIME_OUT, AR_TIME_OUT_ACK, val);
}
static void ath9k_hw_set_cts_timeout(struct ath_hw *ah, u32 us)
{
u32 val = ath9k_hw_mac_to_clks(ah, us);
val = min(val, (u32) MS(0xFFFFFFFF, AR_TIME_OUT_CTS));
REG_RMW_FIELD(ah, AR_TIME_OUT, AR_TIME_OUT_CTS, val);
}
static bool ath9k_hw_set_global_txtimeout(struct ath_hw *ah, u32 tu)
{
if (tu > 0xFFFF) {
ath_print(ath9k_hw_common(ah), ATH_DBG_XMIT,
"bad global tx timeout %u\n", tu);
ah->globaltxtimeout = (u32) -1;
return false;
} else {
REG_RMW_FIELD(ah, AR_GTXTO, AR_GTXTO_TIMEOUT_LIMIT, tu);
ah->globaltxtimeout = tu;
return true;
}
}
void ath9k_hw_init_global_settings(struct ath_hw *ah)
{
struct ieee80211_conf *conf = &ath9k_hw_common(ah)->hw->conf;
int acktimeout;
int slottime;
int sifstime;
ath_print(ath9k_hw_common(ah), ATH_DBG_RESET, "ah->misc_mode 0x%x\n",
ah->misc_mode);
if (ah->misc_mode != 0)
REG_WRITE(ah, AR_PCU_MISC,
REG_READ(ah, AR_PCU_MISC) | ah->misc_mode);
if (conf->channel && conf->channel->band == IEEE80211_BAND_5GHZ)
sifstime = 16;
else
sifstime = 10;
/* As defined by IEEE 802.11-2007 17.3.8.6 */
slottime = ah->slottime + 3 * ah->coverage_class;
acktimeout = slottime + sifstime;
/*
* Workaround for early ACK timeouts, add an offset to match the
* initval's 64us ack timeout value.
* This was initially only meant to work around an issue with delayed
* BA frames in some implementations, but it has been found to fix ACK
* timeout issues in other cases as well.
*/
if (conf->channel && conf->channel->band == IEEE80211_BAND_2GHZ)
acktimeout += 64 - sifstime - ah->slottime;
ath9k_hw_setslottime(ah, slottime);
ath9k_hw_set_ack_timeout(ah, acktimeout);
ath9k_hw_set_cts_timeout(ah, acktimeout);
if (ah->globaltxtimeout != (u32) -1)
ath9k_hw_set_global_txtimeout(ah, ah->globaltxtimeout);
}
EXPORT_SYMBOL(ath9k_hw_init_global_settings);
void ath9k_hw_deinit(struct ath_hw *ah)
{
struct ath_common *common = ath9k_hw_common(ah);
if (common->state < ATH_HW_INITIALIZED)
goto free_hw;
ath9k_hw_setpower(ah, ATH9K_PM_FULL_SLEEP);
free_hw:
ath9k_hw_rf_free_ext_banks(ah);
}
EXPORT_SYMBOL(ath9k_hw_deinit);
/*******/
/* INI */
/*******/
u32 ath9k_regd_get_ctl(struct ath_regulatory *reg, struct ath9k_channel *chan)
{
u32 ctl = ath_regd_get_band_ctl(reg, chan->chan->band);
if (IS_CHAN_B(chan))
ctl |= CTL_11B;
else if (IS_CHAN_G(chan))
ctl |= CTL_11G;
else
ctl |= CTL_11A;
return ctl;
}
/****************************************/
/* Reset and Channel Switching Routines */
/****************************************/
static inline void ath9k_hw_set_dma(struct ath_hw *ah)
{
struct ath_common *common = ath9k_hw_common(ah);
u32 regval;
ENABLE_REGWRITE_BUFFER(ah);
/*
* set AHB_MODE not to do cacheline prefetches
*/
if (!AR_SREV_9300_20_OR_LATER(ah)) {
regval = REG_READ(ah, AR_AHB_MODE);
REG_WRITE(ah, AR_AHB_MODE, regval | AR_AHB_PREFETCH_RD_EN);
}
/*
* let mac dma reads be in 128 byte chunks
*/
regval = REG_READ(ah, AR_TXCFG) & ~AR_TXCFG_DMASZ_MASK;
REG_WRITE(ah, AR_TXCFG, regval | AR_TXCFG_DMASZ_128B);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
/*
* Restore TX Trigger Level to its pre-reset value.
* The initial value depends on whether aggregation is enabled, and is
* adjusted whenever underruns are detected.
*/
if (!AR_SREV_9300_20_OR_LATER(ah))
REG_RMW_FIELD(ah, AR_TXCFG, AR_FTRIG, ah->tx_trig_level);
ENABLE_REGWRITE_BUFFER(ah);
/*
* let mac dma writes be in 128 byte chunks
*/
regval = REG_READ(ah, AR_RXCFG) & ~AR_RXCFG_DMASZ_MASK;
REG_WRITE(ah, AR_RXCFG, regval | AR_RXCFG_DMASZ_128B);
/*
* Setup receive FIFO threshold to hold off TX activities
*/
REG_WRITE(ah, AR_RXFIFO_CFG, 0x200);
if (AR_SREV_9300_20_OR_LATER(ah)) {
REG_RMW_FIELD(ah, AR_RXBP_THRESH, AR_RXBP_THRESH_HP, 0x1);
REG_RMW_FIELD(ah, AR_RXBP_THRESH, AR_RXBP_THRESH_LP, 0x1);
ath9k_hw_set_rx_bufsize(ah, common->rx_bufsize -
ah->caps.rx_status_len);
}
/*
* reduce the number of usable entries in PCU TXBUF to avoid
* wrap around issues.
*/
if (AR_SREV_9285(ah)) {
/* For AR9285 the number of Fifos are reduced to half.
* So set the usable tx buf size also to half to
* avoid data/delimiter underruns
*/
REG_WRITE(ah, AR_PCU_TXBUF_CTRL,
AR_9285_PCU_TXBUF_CTRL_USABLE_SIZE);
} else if (!AR_SREV_9271(ah)) {
REG_WRITE(ah, AR_PCU_TXBUF_CTRL,
AR_PCU_TXBUF_CTRL_USABLE_SIZE);
}
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
if (AR_SREV_9300_20_OR_LATER(ah))
ath9k_hw_reset_txstatus_ring(ah);
}
static void ath9k_hw_set_operating_mode(struct ath_hw *ah, int opmode)
{
u32 val;
val = REG_READ(ah, AR_STA_ID1);
val &= ~(AR_STA_ID1_STA_AP | AR_STA_ID1_ADHOC);
switch (opmode) {
case NL80211_IFTYPE_AP:
REG_WRITE(ah, AR_STA_ID1, val | AR_STA_ID1_STA_AP
| AR_STA_ID1_KSRCH_MODE);
REG_CLR_BIT(ah, AR_CFG, AR_CFG_AP_ADHOC_INDICATION);
break;
case NL80211_IFTYPE_ADHOC:
case NL80211_IFTYPE_MESH_POINT:
REG_WRITE(ah, AR_STA_ID1, val | AR_STA_ID1_ADHOC
| AR_STA_ID1_KSRCH_MODE);
REG_SET_BIT(ah, AR_CFG, AR_CFG_AP_ADHOC_INDICATION);
break;
case NL80211_IFTYPE_STATION:
case NL80211_IFTYPE_MONITOR:
REG_WRITE(ah, AR_STA_ID1, val | AR_STA_ID1_KSRCH_MODE);
break;
}
}
void ath9k_hw_get_delta_slope_vals(struct ath_hw *ah, u32 coef_scaled,
u32 *coef_mantissa, u32 *coef_exponent)
{
u32 coef_exp, coef_man;
for (coef_exp = 31; coef_exp > 0; coef_exp--)
if ((coef_scaled >> coef_exp) & 0x1)
break;
coef_exp = 14 - (coef_exp - COEF_SCALE_S);
coef_man = coef_scaled + (1 << (COEF_SCALE_S - coef_exp - 1));
*coef_mantissa = coef_man >> (COEF_SCALE_S - coef_exp);
*coef_exponent = coef_exp - 16;
}
static bool ath9k_hw_set_reset(struct ath_hw *ah, int type)
{
u32 rst_flags;
u32 tmpReg;
if (AR_SREV_9100(ah)) {
u32 val = REG_READ(ah, AR_RTC_DERIVED_CLK);
val &= ~AR_RTC_DERIVED_CLK_PERIOD;
val |= SM(1, AR_RTC_DERIVED_CLK_PERIOD);
REG_WRITE(ah, AR_RTC_DERIVED_CLK, val);
(void)REG_READ(ah, AR_RTC_DERIVED_CLK);
}
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_RTC_FORCE_WAKE, AR_RTC_FORCE_WAKE_EN |
AR_RTC_FORCE_WAKE_ON_INT);
if (AR_SREV_9100(ah)) {
rst_flags = AR_RTC_RC_MAC_WARM | AR_RTC_RC_MAC_COLD |
AR_RTC_RC_COLD_RESET | AR_RTC_RC_WARM_RESET;
} else {
tmpReg = REG_READ(ah, AR_INTR_SYNC_CAUSE);
if (tmpReg &
(AR_INTR_SYNC_LOCAL_TIMEOUT |
AR_INTR_SYNC_RADM_CPL_TIMEOUT)) {
u32 val;
REG_WRITE(ah, AR_INTR_SYNC_ENABLE, 0);
val = AR_RC_HOSTIF;
if (!AR_SREV_9300_20_OR_LATER(ah))
val |= AR_RC_AHB;
REG_WRITE(ah, AR_RC, val);
} else if (!AR_SREV_9300_20_OR_LATER(ah))
REG_WRITE(ah, AR_RC, AR_RC_AHB);
rst_flags = AR_RTC_RC_MAC_WARM;
if (type == ATH9K_RESET_COLD)
rst_flags |= AR_RTC_RC_MAC_COLD;
}
REG_WRITE(ah, AR_RTC_RC, rst_flags);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
udelay(50);
REG_WRITE(ah, AR_RTC_RC, 0);
if (!ath9k_hw_wait(ah, AR_RTC_RC, AR_RTC_RC_M, 0, AH_WAIT_TIMEOUT)) {
ath_print(ath9k_hw_common(ah), ATH_DBG_RESET,
"RTC stuck in MAC reset\n");
return false;
}
if (!AR_SREV_9100(ah))
REG_WRITE(ah, AR_RC, 0);
if (AR_SREV_9100(ah))
udelay(50);
return true;
}
static bool ath9k_hw_set_reset_power_on(struct ath_hw *ah)
{
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_RTC_FORCE_WAKE, AR_RTC_FORCE_WAKE_EN |
AR_RTC_FORCE_WAKE_ON_INT);
if (!AR_SREV_9100(ah) && !AR_SREV_9300_20_OR_LATER(ah))
REG_WRITE(ah, AR_RC, AR_RC_AHB);
REG_WRITE(ah, AR_RTC_RESET, 0);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
if (!AR_SREV_9300_20_OR_LATER(ah))
udelay(2);
if (!AR_SREV_9100(ah) && !AR_SREV_9300_20_OR_LATER(ah))
REG_WRITE(ah, AR_RC, 0);
REG_WRITE(ah, AR_RTC_RESET, 1);
if (!ath9k_hw_wait(ah,
AR_RTC_STATUS,
AR_RTC_STATUS_M,
AR_RTC_STATUS_ON,
AH_WAIT_TIMEOUT)) {
ath_print(ath9k_hw_common(ah), ATH_DBG_RESET,
"RTC not waking up\n");
return false;
}
ath9k_hw_read_revisions(ah);
return ath9k_hw_set_reset(ah, ATH9K_RESET_WARM);
}
static bool ath9k_hw_set_reset_reg(struct ath_hw *ah, u32 type)
{
REG_WRITE(ah, AR_RTC_FORCE_WAKE,
AR_RTC_FORCE_WAKE_EN | AR_RTC_FORCE_WAKE_ON_INT);
switch (type) {
case ATH9K_RESET_POWER_ON:
return ath9k_hw_set_reset_power_on(ah);
case ATH9K_RESET_WARM:
case ATH9K_RESET_COLD:
return ath9k_hw_set_reset(ah, type);
default:
return false;
}
}
static bool ath9k_hw_chip_reset(struct ath_hw *ah,
struct ath9k_channel *chan)
{
if (AR_SREV_9280(ah) && ah->eep_ops->get_eeprom(ah, EEP_OL_PWRCTRL)) {
if (!ath9k_hw_set_reset_reg(ah, ATH9K_RESET_POWER_ON))
return false;
} else if (!ath9k_hw_set_reset_reg(ah, ATH9K_RESET_WARM))
return false;
if (!ath9k_hw_setpower(ah, ATH9K_PM_AWAKE))
return false;
ah->chip_fullsleep = false;
ath9k_hw_init_pll(ah, chan);
ath9k_hw_set_rfmode(ah, chan);
return true;
}
static bool ath9k_hw_channel_change(struct ath_hw *ah,
struct ath9k_channel *chan)
{
struct ath_regulatory *regulatory = ath9k_hw_regulatory(ah);
struct ath_common *common = ath9k_hw_common(ah);
struct ieee80211_channel *channel = chan->chan;
u32 qnum;
int r;
for (qnum = 0; qnum < AR_NUM_QCU; qnum++) {
if (ath9k_hw_numtxpending(ah, qnum)) {
ath_print(common, ATH_DBG_QUEUE,
"Transmit frames pending on "
"queue %d\n", qnum);
return false;
}
}
if (!ath9k_hw_rfbus_req(ah)) {
ath_print(common, ATH_DBG_FATAL,
"Could not kill baseband RX\n");
return false;
}
ath9k_hw_set_channel_regs(ah, chan);
r = ath9k_hw_rf_set_freq(ah, chan);
if (r) {
ath_print(common, ATH_DBG_FATAL,
"Failed to set channel\n");
return false;
}
ah->eep_ops->set_txpower(ah, chan,
ath9k_regd_get_ctl(regulatory, chan),
channel->max_antenna_gain * 2,
channel->max_power * 2,
min((u32) MAX_RATE_POWER,
(u32) regulatory->power_limit));
ath9k_hw_rfbus_done(ah);
if (IS_CHAN_OFDM(chan) || IS_CHAN_HT(chan))
ath9k_hw_set_delta_slope(ah, chan);
ath9k_hw_spur_mitigate_freq(ah, chan);
if (!chan->oneTimeCalsDone)
chan->oneTimeCalsDone = true;
return true;
}
bool ath9k_hw_check_alive(struct ath_hw *ah)
{
int count = 50;
u32 reg;
if (AR_SREV_9285_10_OR_LATER(ah))
return true;
do {
reg = REG_READ(ah, AR_OBS_BUS_1);
if ((reg & 0x7E7FFFEF) == 0x00702400)
continue;
switch (reg & 0x7E000B00) {
case 0x1E000000:
case 0x52000B00:
case 0x18000B00:
continue;
default:
return true;
}
} while (count-- > 0);
return false;
}
EXPORT_SYMBOL(ath9k_hw_check_alive);
int ath9k_hw_reset(struct ath_hw *ah, struct ath9k_channel *chan,
bool bChannelChange)
{
struct ath_common *common = ath9k_hw_common(ah);
u32 saveLedState;
struct ath9k_channel *curchan = ah->curchan;
u32 saveDefAntenna;
u32 macStaId1;
u64 tsf = 0;
int i, r;
ah->txchainmask = common->tx_chainmask;
ah->rxchainmask = common->rx_chainmask;
if (!ah->chip_fullsleep) {
ath9k_hw_abortpcurecv(ah);
if (!ath9k_hw_stopdmarecv(ah))
ath_print(common, ATH_DBG_XMIT,
"Failed to stop receive dma\n");
}
if (!ath9k_hw_setpower(ah, ATH9K_PM_AWAKE))
return -EIO;
if (curchan && !ah->chip_fullsleep)
ath9k_hw_getnf(ah, curchan);
if (bChannelChange &&
(ah->chip_fullsleep != true) &&
(ah->curchan != NULL) &&
(chan->channel != ah->curchan->channel) &&
((chan->channelFlags & CHANNEL_ALL) ==
(ah->curchan->channelFlags & CHANNEL_ALL)) &&
!(AR_SREV_9280(ah) || IS_CHAN_A_5MHZ_SPACED(chan) ||
IS_CHAN_A_5MHZ_SPACED(ah->curchan))) {
if (ath9k_hw_channel_change(ah, chan)) {
ath9k_hw_loadnf(ah, ah->curchan);
ath9k_hw_start_nfcal(ah);
return 0;
}
}
saveDefAntenna = REG_READ(ah, AR_DEF_ANTENNA);
if (saveDefAntenna == 0)
saveDefAntenna = 1;
macStaId1 = REG_READ(ah, AR_STA_ID1) & AR_STA_ID1_BASE_RATE_11B;
/* For chips on which RTC reset is done, save TSF before it gets cleared */
if (AR_SREV_9280(ah) && ah->eep_ops->get_eeprom(ah, EEP_OL_PWRCTRL))
tsf = ath9k_hw_gettsf64(ah);
saveLedState = REG_READ(ah, AR_CFG_LED) &
(AR_CFG_LED_ASSOC_CTL | AR_CFG_LED_MODE_SEL |
AR_CFG_LED_BLINK_THRESH_SEL | AR_CFG_LED_BLINK_SLOW);
ath9k_hw_mark_phy_inactive(ah);
/* Only required on the first reset */
if (AR_SREV_9271(ah) && ah->htc_reset_init) {
REG_WRITE(ah,
AR9271_RESET_POWER_DOWN_CONTROL,
AR9271_RADIO_RF_RST);
udelay(50);
}
if (!ath9k_hw_chip_reset(ah, chan)) {
ath_print(common, ATH_DBG_FATAL, "Chip reset failed\n");
return -EINVAL;
}
/* Only required on the first reset */
if (AR_SREV_9271(ah) && ah->htc_reset_init) {
ah->htc_reset_init = false;
REG_WRITE(ah,
AR9271_RESET_POWER_DOWN_CONTROL,
AR9271_GATE_MAC_CTL);
udelay(50);
}
/* Restore TSF */
if (tsf && AR_SREV_9280(ah) && ah->eep_ops->get_eeprom(ah, EEP_OL_PWRCTRL))
ath9k_hw_settsf64(ah, tsf);
if (AR_SREV_9280_10_OR_LATER(ah))
REG_SET_BIT(ah, AR_GPIO_INPUT_EN_VAL, AR_GPIO_JTAG_DISABLE);
r = ath9k_hw_process_ini(ah, chan);
if (r)
return r;
/* Setup MFP options for CCMP */
if (AR_SREV_9280_20_OR_LATER(ah)) {
/* Mask Retry(b11), PwrMgt(b12), MoreData(b13) to 0 in mgmt
* frames when constructing CCMP AAD. */
REG_RMW_FIELD(ah, AR_AES_MUTE_MASK1, AR_AES_MUTE_MASK1_FC_MGMT,
0xc7ff);
ah->sw_mgmt_crypto = false;
} else if (AR_SREV_9160_10_OR_LATER(ah)) {
/* Disable hardware crypto for management frames */
REG_CLR_BIT(ah, AR_PCU_MISC_MODE2,
AR_PCU_MISC_MODE2_MGMT_CRYPTO_ENABLE);
REG_SET_BIT(ah, AR_PCU_MISC_MODE2,
AR_PCU_MISC_MODE2_NO_CRYPTO_FOR_NON_DATA_PKT);
ah->sw_mgmt_crypto = true;
} else
ah->sw_mgmt_crypto = true;
if (IS_CHAN_OFDM(chan) || IS_CHAN_HT(chan))
ath9k_hw_set_delta_slope(ah, chan);
ath9k_hw_spur_mitigate_freq(ah, chan);
ah->eep_ops->set_board_values(ah, chan);
ath9k_hw_set_operating_mode(ah, ah->opmode);
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_STA_ID0, get_unaligned_le32(common->macaddr));
REG_WRITE(ah, AR_STA_ID1, get_unaligned_le16(common->macaddr + 4)
| macStaId1
| AR_STA_ID1_RTS_USE_DEF
| (ah->config.
ack_6mb ? AR_STA_ID1_ACKCTS_6MB : 0)
| ah->sta_id1_defaults);
ath_hw_setbssidmask(common);
REG_WRITE(ah, AR_DEF_ANTENNA, saveDefAntenna);
ath9k_hw_write_associd(ah);
REG_WRITE(ah, AR_ISR, ~0);
REG_WRITE(ah, AR_RSSI_THR, INIT_RSSI_THR);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
r = ath9k_hw_rf_set_freq(ah, chan);
if (r)
return r;
ENABLE_REGWRITE_BUFFER(ah);
for (i = 0; i < AR_NUM_DCU; i++)
REG_WRITE(ah, AR_DQCUMASK(i), 1 << i);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
ah->intr_txqs = 0;
for (i = 0; i < ah->caps.total_queues; i++)
ath9k_hw_resettxqueue(ah, i);
ath9k_hw_init_interrupt_masks(ah, ah->opmode);
ath9k_hw_init_qos(ah);
if (ah->caps.hw_caps & ATH9K_HW_CAP_RFSILENT)
ath9k_enable_rfkill(ah);
ath9k_hw_init_global_settings(ah);
if (!AR_SREV_9300_20_OR_LATER(ah)) {
ar9002_hw_enable_async_fifo(ah);
ar9002_hw_enable_wep_aggregation(ah);
}
REG_WRITE(ah, AR_STA_ID1,
REG_READ(ah, AR_STA_ID1) | AR_STA_ID1_PRESERVE_SEQNUM);
ath9k_hw_set_dma(ah);
REG_WRITE(ah, AR_OBS, 8);
if (ah->config.rx_intr_mitigation) {
REG_RMW_FIELD(ah, AR_RIMT, AR_RIMT_LAST, 500);
REG_RMW_FIELD(ah, AR_RIMT, AR_RIMT_FIRST, 2000);
}
if (ah->config.tx_intr_mitigation) {
REG_RMW_FIELD(ah, AR_TIMT, AR_TIMT_LAST, 300);
REG_RMW_FIELD(ah, AR_TIMT, AR_TIMT_FIRST, 750);
}
ath9k_hw_init_bb(ah, chan);
if (!ath9k_hw_init_cal(ah, chan))
return -EIO;
ENABLE_REGWRITE_BUFFER(ah);
ath9k_hw_restore_chainmask(ah);
REG_WRITE(ah, AR_CFG_LED, saveLedState | AR_CFG_SCLK_32KHZ);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
/*
* For big endian systems turn on swapping for descriptors
*/
if (AR_SREV_9100(ah)) {
u32 mask;
mask = REG_READ(ah, AR_CFG);
if (mask & (AR_CFG_SWRB | AR_CFG_SWTB | AR_CFG_SWRG)) {
ath_print(common, ATH_DBG_RESET,
"CFG Byte Swap Set 0x%x\n", mask);
} else {
mask =
INIT_CONFIG_STATUS | AR_CFG_SWRB | AR_CFG_SWTB;
REG_WRITE(ah, AR_CFG, mask);
ath_print(common, ATH_DBG_RESET,
"Setting CFG 0x%x\n", REG_READ(ah, AR_CFG));
}
} else {
/* Configure AR9271 target WLAN */
if (AR_SREV_9271(ah))
REG_WRITE(ah, AR_CFG, AR_CFG_SWRB | AR_CFG_SWTB);
#ifdef __BIG_ENDIAN
else
REG_WRITE(ah, AR_CFG, AR_CFG_SWTD | AR_CFG_SWRD);
#endif
}
if (ah->btcoex_hw.enabled)
ath9k_hw_btcoex_enable(ah);
if (AR_SREV_9300_20_OR_LATER(ah)) {
ath9k_hw_loadnf(ah, curchan);
ath9k_hw_start_nfcal(ah);
}
return 0;
}
EXPORT_SYMBOL(ath9k_hw_reset);
/************************/
/* Key Cache Management */
/************************/
bool ath9k_hw_keyreset(struct ath_hw *ah, u16 entry)
{
u32 keyType;
if (entry >= ah->caps.keycache_size) {
ath_print(ath9k_hw_common(ah), ATH_DBG_FATAL,
"keychache entry %u out of range\n", entry);
return false;
}
keyType = REG_READ(ah, AR_KEYTABLE_TYPE(entry));
REG_WRITE(ah, AR_KEYTABLE_KEY0(entry), 0);
REG_WRITE(ah, AR_KEYTABLE_KEY1(entry), 0);
REG_WRITE(ah, AR_KEYTABLE_KEY2(entry), 0);
REG_WRITE(ah, AR_KEYTABLE_KEY3(entry), 0);
REG_WRITE(ah, AR_KEYTABLE_KEY4(entry), 0);
REG_WRITE(ah, AR_KEYTABLE_TYPE(entry), AR_KEYTABLE_TYPE_CLR);
REG_WRITE(ah, AR_KEYTABLE_MAC0(entry), 0);
REG_WRITE(ah, AR_KEYTABLE_MAC1(entry), 0);
if (keyType == AR_KEYTABLE_TYPE_TKIP && ATH9K_IS_MIC_ENABLED(ah)) {
u16 micentry = entry + 64;
REG_WRITE(ah, AR_KEYTABLE_KEY0(micentry), 0);
REG_WRITE(ah, AR_KEYTABLE_KEY1(micentry), 0);
REG_WRITE(ah, AR_KEYTABLE_KEY2(micentry), 0);
REG_WRITE(ah, AR_KEYTABLE_KEY3(micentry), 0);
}
return true;
}
EXPORT_SYMBOL(ath9k_hw_keyreset);
bool ath9k_hw_keysetmac(struct ath_hw *ah, u16 entry, const u8 *mac)
{
u32 macHi, macLo;
if (entry >= ah->caps.keycache_size) {
ath_print(ath9k_hw_common(ah), ATH_DBG_FATAL,
"keychache entry %u out of range\n", entry);
return false;
}
if (mac != NULL) {
macHi = (mac[5] << 8) | mac[4];
macLo = (mac[3] << 24) |
(mac[2] << 16) |
(mac[1] << 8) |
mac[0];
macLo >>= 1;
macLo |= (macHi & 1) << 31;
macHi >>= 1;
} else {
macLo = macHi = 0;
}
REG_WRITE(ah, AR_KEYTABLE_MAC0(entry), macLo);
REG_WRITE(ah, AR_KEYTABLE_MAC1(entry), macHi | AR_KEYTABLE_VALID);
return true;
}
EXPORT_SYMBOL(ath9k_hw_keysetmac);
bool ath9k_hw_set_keycache_entry(struct ath_hw *ah, u16 entry,
const struct ath9k_keyval *k,
const u8 *mac)
{
const struct ath9k_hw_capabilities *pCap = &ah->caps;
struct ath_common *common = ath9k_hw_common(ah);
u32 key0, key1, key2, key3, key4;
u32 keyType;
if (entry >= pCap->keycache_size) {
ath_print(common, ATH_DBG_FATAL,
"keycache entry %u out of range\n", entry);
return false;
}
switch (k->kv_type) {
case ATH9K_CIPHER_AES_OCB:
keyType = AR_KEYTABLE_TYPE_AES;
break;
case ATH9K_CIPHER_AES_CCM:
if (!(pCap->hw_caps & ATH9K_HW_CAP_CIPHER_AESCCM)) {
ath_print(common, ATH_DBG_ANY,
"AES-CCM not supported by mac rev 0x%x\n",
ah->hw_version.macRev);
return false;
}
keyType = AR_KEYTABLE_TYPE_CCM;
break;
case ATH9K_CIPHER_TKIP:
keyType = AR_KEYTABLE_TYPE_TKIP;
if (ATH9K_IS_MIC_ENABLED(ah)
&& entry + 64 >= pCap->keycache_size) {
ath_print(common, ATH_DBG_ANY,
"entry %u inappropriate for TKIP\n", entry);
return false;
}
break;
case ATH9K_CIPHER_WEP:
if (k->kv_len < WLAN_KEY_LEN_WEP40) {
ath_print(common, ATH_DBG_ANY,
"WEP key length %u too small\n", k->kv_len);
return false;
}
if (k->kv_len <= WLAN_KEY_LEN_WEP40)
keyType = AR_KEYTABLE_TYPE_40;
else if (k->kv_len <= WLAN_KEY_LEN_WEP104)
keyType = AR_KEYTABLE_TYPE_104;
else
keyType = AR_KEYTABLE_TYPE_128;
break;
case ATH9K_CIPHER_CLR:
keyType = AR_KEYTABLE_TYPE_CLR;
break;
default:
ath_print(common, ATH_DBG_FATAL,
"cipher %u not supported\n", k->kv_type);
return false;
}
key0 = get_unaligned_le32(k->kv_val + 0);
key1 = get_unaligned_le16(k->kv_val + 4);
key2 = get_unaligned_le32(k->kv_val + 6);
key3 = get_unaligned_le16(k->kv_val + 10);
key4 = get_unaligned_le32(k->kv_val + 12);
if (k->kv_len <= WLAN_KEY_LEN_WEP104)
key4 &= 0xff;
/*
* Note: Key cache registers access special memory area that requires
* two 32-bit writes to actually update the values in the internal
* memory. Consequently, the exact order and pairs used here must be
* maintained.
*/
if (keyType == AR_KEYTABLE_TYPE_TKIP && ATH9K_IS_MIC_ENABLED(ah)) {
u16 micentry = entry + 64;
/*
* Write inverted key[47:0] first to avoid Michael MIC errors
* on frames that could be sent or received at the same time.
* The correct key will be written in the end once everything
* else is ready.
*/
REG_WRITE(ah, AR_KEYTABLE_KEY0(entry), ~key0);
REG_WRITE(ah, AR_KEYTABLE_KEY1(entry), ~key1);
/* Write key[95:48] */
REG_WRITE(ah, AR_KEYTABLE_KEY2(entry), key2);
REG_WRITE(ah, AR_KEYTABLE_KEY3(entry), key3);
/* Write key[127:96] and key type */
REG_WRITE(ah, AR_KEYTABLE_KEY4(entry), key4);
REG_WRITE(ah, AR_KEYTABLE_TYPE(entry), keyType);
/* Write MAC address for the entry */
(void) ath9k_hw_keysetmac(ah, entry, mac);
if (ah->misc_mode & AR_PCU_MIC_NEW_LOC_ENA) {
/*
* TKIP uses two key cache entries:
* Michael MIC TX/RX keys in the same key cache entry
* (idx = main index + 64):
* key0 [31:0] = RX key [31:0]
* key1 [15:0] = TX key [31:16]
* key1 [31:16] = reserved
* key2 [31:0] = RX key [63:32]
* key3 [15:0] = TX key [15:0]
* key3 [31:16] = reserved
* key4 [31:0] = TX key [63:32]
*/
u32 mic0, mic1, mic2, mic3, mic4;
mic0 = get_unaligned_le32(k->kv_mic + 0);
mic2 = get_unaligned_le32(k->kv_mic + 4);
mic1 = get_unaligned_le16(k->kv_txmic + 2) & 0xffff;
mic3 = get_unaligned_le16(k->kv_txmic + 0) & 0xffff;
mic4 = get_unaligned_le32(k->kv_txmic + 4);
/* Write RX[31:0] and TX[31:16] */
REG_WRITE(ah, AR_KEYTABLE_KEY0(micentry), mic0);
REG_WRITE(ah, AR_KEYTABLE_KEY1(micentry), mic1);
/* Write RX[63:32] and TX[15:0] */
REG_WRITE(ah, AR_KEYTABLE_KEY2(micentry), mic2);
REG_WRITE(ah, AR_KEYTABLE_KEY3(micentry), mic3);
/* Write TX[63:32] and keyType(reserved) */
REG_WRITE(ah, AR_KEYTABLE_KEY4(micentry), mic4);
REG_WRITE(ah, AR_KEYTABLE_TYPE(micentry),
AR_KEYTABLE_TYPE_CLR);
} else {
/*
* TKIP uses four key cache entries (two for group
* keys):
* Michael MIC TX/RX keys are in different key cache
* entries (idx = main index + 64 for TX and
* main index + 32 + 96 for RX):
* key0 [31:0] = TX/RX MIC key [31:0]
* key1 [31:0] = reserved
* key2 [31:0] = TX/RX MIC key [63:32]
* key3 [31:0] = reserved
* key4 [31:0] = reserved
*
* Upper layer code will call this function separately
* for TX and RX keys when these registers offsets are
* used.
*/
u32 mic0, mic2;
mic0 = get_unaligned_le32(k->kv_mic + 0);
mic2 = get_unaligned_le32(k->kv_mic + 4);
/* Write MIC key[31:0] */
REG_WRITE(ah, AR_KEYTABLE_KEY0(micentry), mic0);
REG_WRITE(ah, AR_KEYTABLE_KEY1(micentry), 0);
/* Write MIC key[63:32] */
REG_WRITE(ah, AR_KEYTABLE_KEY2(micentry), mic2);
REG_WRITE(ah, AR_KEYTABLE_KEY3(micentry), 0);
/* Write TX[63:32] and keyType(reserved) */
REG_WRITE(ah, AR_KEYTABLE_KEY4(micentry), 0);
REG_WRITE(ah, AR_KEYTABLE_TYPE(micentry),
AR_KEYTABLE_TYPE_CLR);
}
/* MAC address registers are reserved for the MIC entry */
REG_WRITE(ah, AR_KEYTABLE_MAC0(micentry), 0);
REG_WRITE(ah, AR_KEYTABLE_MAC1(micentry), 0);
/*
* Write the correct (un-inverted) key[47:0] last to enable
* TKIP now that all other registers are set with correct
* values.
*/
REG_WRITE(ah, AR_KEYTABLE_KEY0(entry), key0);
REG_WRITE(ah, AR_KEYTABLE_KEY1(entry), key1);
} else {
/* Write key[47:0] */
REG_WRITE(ah, AR_KEYTABLE_KEY0(entry), key0);
REG_WRITE(ah, AR_KEYTABLE_KEY1(entry), key1);
/* Write key[95:48] */
REG_WRITE(ah, AR_KEYTABLE_KEY2(entry), key2);
REG_WRITE(ah, AR_KEYTABLE_KEY3(entry), key3);
/* Write key[127:96] and key type */
REG_WRITE(ah, AR_KEYTABLE_KEY4(entry), key4);
REG_WRITE(ah, AR_KEYTABLE_TYPE(entry), keyType);
/* Write MAC address for the entry */
(void) ath9k_hw_keysetmac(ah, entry, mac);
}
return true;
}
EXPORT_SYMBOL(ath9k_hw_set_keycache_entry);
bool ath9k_hw_keyisvalid(struct ath_hw *ah, u16 entry)
{
if (entry < ah->caps.keycache_size) {
u32 val = REG_READ(ah, AR_KEYTABLE_MAC1(entry));
if (val & AR_KEYTABLE_VALID)
return true;
}
return false;
}
EXPORT_SYMBOL(ath9k_hw_keyisvalid);
/******************************/
/* Power Management (Chipset) */
/******************************/
/*
* Notify Power Mgt is disabled in self-generated frames.
* If requested, force chip to sleep.
*/
static void ath9k_set_power_sleep(struct ath_hw *ah, int setChip)
{
REG_SET_BIT(ah, AR_STA_ID1, AR_STA_ID1_PWR_SAV);
if (setChip) {
/*
* Clear the RTC force wake bit to allow the
* mac to go to sleep.
*/
REG_CLR_BIT(ah, AR_RTC_FORCE_WAKE,
AR_RTC_FORCE_WAKE_EN);
if (!AR_SREV_9100(ah) && !AR_SREV_9300_20_OR_LATER(ah))
REG_WRITE(ah, AR_RC, AR_RC_AHB | AR_RC_HOSTIF);
/* Shutdown chip. Active low */
if (!AR_SREV_5416(ah) && !AR_SREV_9271(ah))
REG_CLR_BIT(ah, (AR_RTC_RESET),
AR_RTC_RESET_EN);
}
}
/*
* Notify Power Management is enabled in self-generating
* frames. If request, set power mode of chip to
* auto/normal. Duration in units of 128us (1/8 TU).
*/
static void ath9k_set_power_network_sleep(struct ath_hw *ah, int setChip)
{
REG_SET_BIT(ah, AR_STA_ID1, AR_STA_ID1_PWR_SAV);
if (setChip) {
struct ath9k_hw_capabilities *pCap = &ah->caps;
if (!(pCap->hw_caps & ATH9K_HW_CAP_AUTOSLEEP)) {
/* Set WakeOnInterrupt bit; clear ForceWake bit */
REG_WRITE(ah, AR_RTC_FORCE_WAKE,
AR_RTC_FORCE_WAKE_ON_INT);
} else {
/*
* Clear the RTC force wake bit to allow the
* mac to go to sleep.
*/
REG_CLR_BIT(ah, AR_RTC_FORCE_WAKE,
AR_RTC_FORCE_WAKE_EN);
}
}
}
static bool ath9k_hw_set_power_awake(struct ath_hw *ah, int setChip)
{
u32 val;
int i;
if (setChip) {
if ((REG_READ(ah, AR_RTC_STATUS) &
AR_RTC_STATUS_M) == AR_RTC_STATUS_SHUTDOWN) {
if (ath9k_hw_set_reset_reg(ah,
ATH9K_RESET_POWER_ON) != true) {
return false;
}
if (!AR_SREV_9300_20_OR_LATER(ah))
ath9k_hw_init_pll(ah, NULL);
}
if (AR_SREV_9100(ah))
REG_SET_BIT(ah, AR_RTC_RESET,
AR_RTC_RESET_EN);
REG_SET_BIT(ah, AR_RTC_FORCE_WAKE,
AR_RTC_FORCE_WAKE_EN);
udelay(50);
for (i = POWER_UP_TIME / 50; i > 0; i--) {
val = REG_READ(ah, AR_RTC_STATUS) & AR_RTC_STATUS_M;
if (val == AR_RTC_STATUS_ON)
break;
udelay(50);
REG_SET_BIT(ah, AR_RTC_FORCE_WAKE,
AR_RTC_FORCE_WAKE_EN);
}
if (i == 0) {
ath_print(ath9k_hw_common(ah), ATH_DBG_FATAL,
"Failed to wakeup in %uus\n",
POWER_UP_TIME / 20);
return false;
}
}
REG_CLR_BIT(ah, AR_STA_ID1, AR_STA_ID1_PWR_SAV);
return true;
}
bool ath9k_hw_setpower(struct ath_hw *ah, enum ath9k_power_mode mode)
{
struct ath_common *common = ath9k_hw_common(ah);
int status = true, setChip = true;
static const char *modes[] = {
"AWAKE",
"FULL-SLEEP",
"NETWORK SLEEP",
"UNDEFINED"
};
if (ah->power_mode == mode)
return status;
ath_print(common, ATH_DBG_RESET, "%s -> %s\n",
modes[ah->power_mode], modes[mode]);
switch (mode) {
case ATH9K_PM_AWAKE:
status = ath9k_hw_set_power_awake(ah, setChip);
break;
case ATH9K_PM_FULL_SLEEP:
ath9k_set_power_sleep(ah, setChip);
ah->chip_fullsleep = true;
break;
case ATH9K_PM_NETWORK_SLEEP:
ath9k_set_power_network_sleep(ah, setChip);
break;
default:
ath_print(common, ATH_DBG_FATAL,
"Unknown power mode %u\n", mode);
return false;
}
ah->power_mode = mode;
return status;
}
EXPORT_SYMBOL(ath9k_hw_setpower);
/*******************/
/* Beacon Handling */
/*******************/
void ath9k_hw_beaconinit(struct ath_hw *ah, u32 next_beacon, u32 beacon_period)
{
int flags = 0;
ah->beacon_interval = beacon_period;
ENABLE_REGWRITE_BUFFER(ah);
switch (ah->opmode) {
case NL80211_IFTYPE_STATION:
case NL80211_IFTYPE_MONITOR:
REG_WRITE(ah, AR_NEXT_TBTT_TIMER, TU_TO_USEC(next_beacon));
REG_WRITE(ah, AR_NEXT_DMA_BEACON_ALERT, 0xffff);
REG_WRITE(ah, AR_NEXT_SWBA, 0x7ffff);
flags |= AR_TBTT_TIMER_EN;
break;
case NL80211_IFTYPE_ADHOC:
case NL80211_IFTYPE_MESH_POINT:
REG_SET_BIT(ah, AR_TXCFG,
AR_TXCFG_ADHOC_BEACON_ATIM_TX_POLICY);
REG_WRITE(ah, AR_NEXT_NDP_TIMER,
TU_TO_USEC(next_beacon +
(ah->atim_window ? ah->
atim_window : 1)));
flags |= AR_NDP_TIMER_EN;
case NL80211_IFTYPE_AP:
REG_WRITE(ah, AR_NEXT_TBTT_TIMER, TU_TO_USEC(next_beacon));
REG_WRITE(ah, AR_NEXT_DMA_BEACON_ALERT,
TU_TO_USEC(next_beacon -
ah->config.
dma_beacon_response_time));
REG_WRITE(ah, AR_NEXT_SWBA,
TU_TO_USEC(next_beacon -
ah->config.
sw_beacon_response_time));
flags |=
AR_TBTT_TIMER_EN | AR_DBA_TIMER_EN | AR_SWBA_TIMER_EN;
break;
default:
ath_print(ath9k_hw_common(ah), ATH_DBG_BEACON,
"%s: unsupported opmode: %d\n",
__func__, ah->opmode);
return;
break;
}
REG_WRITE(ah, AR_BEACON_PERIOD, TU_TO_USEC(beacon_period));
REG_WRITE(ah, AR_DMA_BEACON_PERIOD, TU_TO_USEC(beacon_period));
REG_WRITE(ah, AR_SWBA_PERIOD, TU_TO_USEC(beacon_period));
REG_WRITE(ah, AR_NDP_PERIOD, TU_TO_USEC(beacon_period));
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
beacon_period &= ~ATH9K_BEACON_ENA;
if (beacon_period & ATH9K_BEACON_RESET_TSF) {
ath9k_hw_reset_tsf(ah);
}
REG_SET_BIT(ah, AR_TIMER_MODE, flags);
}
EXPORT_SYMBOL(ath9k_hw_beaconinit);
void ath9k_hw_set_sta_beacon_timers(struct ath_hw *ah,
const struct ath9k_beacon_state *bs)
{
u32 nextTbtt, beaconintval, dtimperiod, beacontimeout;
struct ath9k_hw_capabilities *pCap = &ah->caps;
struct ath_common *common = ath9k_hw_common(ah);
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_NEXT_TBTT_TIMER, TU_TO_USEC(bs->bs_nexttbtt));
REG_WRITE(ah, AR_BEACON_PERIOD,
TU_TO_USEC(bs->bs_intval & ATH9K_BEACON_PERIOD));
REG_WRITE(ah, AR_DMA_BEACON_PERIOD,
TU_TO_USEC(bs->bs_intval & ATH9K_BEACON_PERIOD));
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
REG_RMW_FIELD(ah, AR_RSSI_THR,
AR_RSSI_THR_BM_THR, bs->bs_bmissthreshold);
beaconintval = bs->bs_intval & ATH9K_BEACON_PERIOD;
if (bs->bs_sleepduration > beaconintval)
beaconintval = bs->bs_sleepduration;
dtimperiod = bs->bs_dtimperiod;
if (bs->bs_sleepduration > dtimperiod)
dtimperiod = bs->bs_sleepduration;
if (beaconintval == dtimperiod)
nextTbtt = bs->bs_nextdtim;
else
nextTbtt = bs->bs_nexttbtt;
ath_print(common, ATH_DBG_BEACON, "next DTIM %d\n", bs->bs_nextdtim);
ath_print(common, ATH_DBG_BEACON, "next beacon %d\n", nextTbtt);
ath_print(common, ATH_DBG_BEACON, "beacon period %d\n", beaconintval);
ath_print(common, ATH_DBG_BEACON, "DTIM period %d\n", dtimperiod);
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_NEXT_DTIM,
TU_TO_USEC(bs->bs_nextdtim - SLEEP_SLOP));
REG_WRITE(ah, AR_NEXT_TIM, TU_TO_USEC(nextTbtt - SLEEP_SLOP));
REG_WRITE(ah, AR_SLEEP1,
SM((CAB_TIMEOUT_VAL << 3), AR_SLEEP1_CAB_TIMEOUT)
| AR_SLEEP1_ASSUME_DTIM);
if (pCap->hw_caps & ATH9K_HW_CAP_AUTOSLEEP)
beacontimeout = (BEACON_TIMEOUT_VAL << 3);
else
beacontimeout = MIN_BEACON_TIMEOUT_VAL;
REG_WRITE(ah, AR_SLEEP2,
SM(beacontimeout, AR_SLEEP2_BEACON_TIMEOUT));
REG_WRITE(ah, AR_TIM_PERIOD, TU_TO_USEC(beaconintval));
REG_WRITE(ah, AR_DTIM_PERIOD, TU_TO_USEC(dtimperiod));
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
REG_SET_BIT(ah, AR_TIMER_MODE,
AR_TBTT_TIMER_EN | AR_TIM_TIMER_EN |
AR_DTIM_TIMER_EN);
/* TSF Out of Range Threshold */
REG_WRITE(ah, AR_TSFOOR_THRESHOLD, bs->bs_tsfoor_threshold);
}
EXPORT_SYMBOL(ath9k_hw_set_sta_beacon_timers);
/*******************/
/* HW Capabilities */
/*******************/
int ath9k_hw_fill_cap_info(struct ath_hw *ah)
{
struct ath9k_hw_capabilities *pCap = &ah->caps;
struct ath_regulatory *regulatory = ath9k_hw_regulatory(ah);
struct ath_common *common = ath9k_hw_common(ah);
struct ath_btcoex_hw *btcoex_hw = &ah->btcoex_hw;
u16 capField = 0, eeval;
eeval = ah->eep_ops->get_eeprom(ah, EEP_REG_0);
regulatory->current_rd = eeval;
eeval = ah->eep_ops->get_eeprom(ah, EEP_REG_1);
if (AR_SREV_9285_10_OR_LATER(ah))
eeval |= AR9285_RDEXT_DEFAULT;
regulatory->current_rd_ext = eeval;
capField = ah->eep_ops->get_eeprom(ah, EEP_OP_CAP);
if (ah->opmode != NL80211_IFTYPE_AP &&
ah->hw_version.subvendorid == AR_SUBVENDOR_ID_NEW_A) {
if (regulatory->current_rd == 0x64 ||
regulatory->current_rd == 0x65)
regulatory->current_rd += 5;
else if (regulatory->current_rd == 0x41)
regulatory->current_rd = 0x43;
ath_print(common, ATH_DBG_REGULATORY,
"regdomain mapped to 0x%x\n", regulatory->current_rd);
}
eeval = ah->eep_ops->get_eeprom(ah, EEP_OP_MODE);
if ((eeval & (AR5416_OPFLAGS_11G | AR5416_OPFLAGS_11A)) == 0) {
ath_print(common, ATH_DBG_FATAL,
"no band has been marked as supported in EEPROM.\n");
return -EINVAL;
}
bitmap_zero(pCap->wireless_modes, ATH9K_MODE_MAX);
if (eeval & AR5416_OPFLAGS_11A) {
set_bit(ATH9K_MODE_11A, pCap->wireless_modes);
if (ah->config.ht_enable) {
if (!(eeval & AR5416_OPFLAGS_N_5G_HT20))
set_bit(ATH9K_MODE_11NA_HT20,
pCap->wireless_modes);
if (!(eeval & AR5416_OPFLAGS_N_5G_HT40)) {
set_bit(ATH9K_MODE_11NA_HT40PLUS,
pCap->wireless_modes);
set_bit(ATH9K_MODE_11NA_HT40MINUS,
pCap->wireless_modes);
}
}
}
if (eeval & AR5416_OPFLAGS_11G) {
set_bit(ATH9K_MODE_11G, pCap->wireless_modes);
if (ah->config.ht_enable) {
if (!(eeval & AR5416_OPFLAGS_N_2G_HT20))
set_bit(ATH9K_MODE_11NG_HT20,
pCap->wireless_modes);
if (!(eeval & AR5416_OPFLAGS_N_2G_HT40)) {
set_bit(ATH9K_MODE_11NG_HT40PLUS,
pCap->wireless_modes);
set_bit(ATH9K_MODE_11NG_HT40MINUS,
pCap->wireless_modes);
}
}
}
pCap->tx_chainmask = ah->eep_ops->get_eeprom(ah, EEP_TX_MASK);
/*
* For AR9271 we will temporarilly uses the rx chainmax as read from
* the EEPROM.
*/
if ((ah->hw_version.devid == AR5416_DEVID_PCI) &&
!(eeval & AR5416_OPFLAGS_11A) &&
!(AR_SREV_9271(ah)))
/* CB71: GPIO 0 is pulled down to indicate 3 rx chains */
pCap->rx_chainmask = ath9k_hw_gpio_get(ah, 0) ? 0x5 : 0x7;
else
/* Use rx_chainmask from EEPROM. */
pCap->rx_chainmask = ah->eep_ops->get_eeprom(ah, EEP_RX_MASK);
if (!(AR_SREV_9280(ah) && (ah->hw_version.macRev == 0)))
ah->misc_mode |= AR_PCU_MIC_NEW_LOC_ENA;
pCap->low_2ghz_chan = 2312;
pCap->high_2ghz_chan = 2732;
pCap->low_5ghz_chan = 4920;
pCap->high_5ghz_chan = 6100;
pCap->hw_caps &= ~ATH9K_HW_CAP_CIPHER_CKIP;
pCap->hw_caps |= ATH9K_HW_CAP_CIPHER_TKIP;
pCap->hw_caps |= ATH9K_HW_CAP_CIPHER_AESCCM;
pCap->hw_caps &= ~ATH9K_HW_CAP_MIC_CKIP;
pCap->hw_caps |= ATH9K_HW_CAP_MIC_TKIP;
pCap->hw_caps |= ATH9K_HW_CAP_MIC_AESCCM;
if (ah->config.ht_enable)
pCap->hw_caps |= ATH9K_HW_CAP_HT;
else
pCap->hw_caps &= ~ATH9K_HW_CAP_HT;
pCap->hw_caps |= ATH9K_HW_CAP_GTT;
pCap->hw_caps |= ATH9K_HW_CAP_VEOL;
pCap->hw_caps |= ATH9K_HW_CAP_BSSIDMASK;
pCap->hw_caps &= ~ATH9K_HW_CAP_MCAST_KEYSEARCH;
if (capField & AR_EEPROM_EEPCAP_MAXQCU)
pCap->total_queues =
MS(capField, AR_EEPROM_EEPCAP_MAXQCU);
else
pCap->total_queues = ATH9K_NUM_TX_QUEUES;
if (capField & AR_EEPROM_EEPCAP_KC_ENTRIES)
pCap->keycache_size =
1 << MS(capField, AR_EEPROM_EEPCAP_KC_ENTRIES);
else
pCap->keycache_size = AR_KEYTABLE_SIZE;
pCap->hw_caps |= ATH9K_HW_CAP_FASTCC;
ath9k: Fix maximum tx fifo settings for single stream devices Atheros single stream AR9285 and AR9271 have half the PCU TX FIFO buffer size of that of dual stream devices. Dual stream devices have a max PCU TX FIFO size of 8 KB while single stream devices have 4 KB. Single stream devices have an issue though and require hardware only to use half of the amount of its capable PCU TX FIFO size, 2 KB and this requires a change in software. Technically a change would not have been required (except for frame burst considerations of 128 bytes) if these devices would have been able to use the full 4 KB of the PCU TX FIFO size but our systems engineers recommend 2 KB to be used only. We enforce this through software by reducing the max frame triggger level to 2 KB. Fixing the max frame trigger level should then have a few benefits: * The PER will now be adjusted as designed for underruns when the max trigger level is reached. This should help alleviate the bus as the rate control algorithm chooses a slower rate which should ensure frames are transmitted properly under high system bus load. * The poll we use on our TX queues should now trigger and work as designed for single stream devices. The hardware passes data from each TX queue on the PCU TX FIFO queue respecting each queue's priority. The new trigger level ensures this seeding of the PCU TX FIFO queue occurs as designed which could mean avoiding false resets and actually reseting hw correctly when a TX queue is indeed stuck. * Some undocumented / unsupported behaviour could have been triggered when the max trigger level level was being set to 4 KB on single stream devices. Its not clear what this issue was to me yet. Cc: Kyungwan Nam <kyungwan.nam@atheros.com> Cc: Bennyam Malavazi <bennyam.malavazi@atheros.com> Cc: Stephen Chen <stephen.chen@atheros.com> Cc: Shan Palanisamy <shan.palanisamy@atheros.com> Cc: Paul Shaw <paul.shaw@atheros.com> Signed-off-by: Vasanthakumar Thiagarajan <vasanth@atheros.com> Signed-off-by: Luis R. Rodriguez <lrodriguez@atheros.com> Signed-off-by: John W. Linville <linville@tuxdriver.com>
2009-11-25 10:37:57 +08:00
if (AR_SREV_9285(ah) || AR_SREV_9271(ah))
pCap->tx_triglevel_max = MAX_TX_FIFO_THRESHOLD >> 1;
else
pCap->tx_triglevel_max = MAX_TX_FIFO_THRESHOLD;
if (AR_SREV_9271(ah))
pCap->num_gpio_pins = AR9271_NUM_GPIO;
else if (AR_SREV_9285_10_OR_LATER(ah))
pCap->num_gpio_pins = AR9285_NUM_GPIO;
else if (AR_SREV_9280_10_OR_LATER(ah))
pCap->num_gpio_pins = AR928X_NUM_GPIO;
else
pCap->num_gpio_pins = AR_NUM_GPIO;
if (AR_SREV_9160_10_OR_LATER(ah) || AR_SREV_9100(ah)) {
pCap->hw_caps |= ATH9K_HW_CAP_CST;
pCap->rts_aggr_limit = ATH_AMPDU_LIMIT_MAX;
} else {
pCap->rts_aggr_limit = (8 * 1024);
}
pCap->hw_caps |= ATH9K_HW_CAP_ENHANCEDPM;
#if defined(CONFIG_RFKILL) || defined(CONFIG_RFKILL_MODULE)
ah->rfsilent = ah->eep_ops->get_eeprom(ah, EEP_RF_SILENT);
if (ah->rfsilent & EEP_RFSILENT_ENABLED) {
ah->rfkill_gpio =
MS(ah->rfsilent, EEP_RFSILENT_GPIO_SEL);
ah->rfkill_polarity =
MS(ah->rfsilent, EEP_RFSILENT_POLARITY);
pCap->hw_caps |= ATH9K_HW_CAP_RFSILENT;
}
#endif
if (AR_SREV_9271(ah))
pCap->hw_caps |= ATH9K_HW_CAP_AUTOSLEEP;
else
pCap->hw_caps &= ~ATH9K_HW_CAP_AUTOSLEEP;
if (AR_SREV_9280(ah) || AR_SREV_9285(ah))
pCap->hw_caps &= ~ATH9K_HW_CAP_4KB_SPLITTRANS;
else
pCap->hw_caps |= ATH9K_HW_CAP_4KB_SPLITTRANS;
if (regulatory->current_rd_ext & (1 << REG_EXT_JAPAN_MIDBAND)) {
pCap->reg_cap =
AR_EEPROM_EEREGCAP_EN_KK_NEW_11A |
AR_EEPROM_EEREGCAP_EN_KK_U1_EVEN |
AR_EEPROM_EEREGCAP_EN_KK_U2 |
AR_EEPROM_EEREGCAP_EN_KK_MIDBAND;
} else {
pCap->reg_cap =
AR_EEPROM_EEREGCAP_EN_KK_NEW_11A |
AR_EEPROM_EEREGCAP_EN_KK_U1_EVEN;
}
/* Advertise midband for AR5416 with FCC midband set in eeprom */
if (regulatory->current_rd_ext & (1 << REG_EXT_FCC_MIDBAND) &&
AR_SREV_5416(ah))
pCap->reg_cap |= AR_EEPROM_EEREGCAP_EN_FCC_MIDBAND;
pCap->num_antcfg_5ghz =
ah->eep_ops->get_num_ant_config(ah, ATH9K_HAL_FREQ_BAND_5GHZ);
pCap->num_antcfg_2ghz =
ah->eep_ops->get_num_ant_config(ah, ATH9K_HAL_FREQ_BAND_2GHZ);
if (AR_SREV_9280_10_OR_LATER(ah) &&
ath9k_hw_btcoex_supported(ah)) {
btcoex_hw->btactive_gpio = ATH_BTACTIVE_GPIO;
btcoex_hw->wlanactive_gpio = ATH_WLANACTIVE_GPIO;
if (AR_SREV_9285(ah)) {
btcoex_hw->scheme = ATH_BTCOEX_CFG_3WIRE;
btcoex_hw->btpriority_gpio = ATH_BTPRIORITY_GPIO;
} else {
btcoex_hw->scheme = ATH_BTCOEX_CFG_2WIRE;
}
} else {
btcoex_hw->scheme = ATH_BTCOEX_CFG_NONE;
}
if (AR_SREV_9300_20_OR_LATER(ah)) {
pCap->hw_caps |= ATH9K_HW_CAP_EDMA | ATH9K_HW_CAP_LDPC |
ATH9K_HW_CAP_FASTCLOCK;
pCap->rx_hp_qdepth = ATH9K_HW_RX_HP_QDEPTH;
pCap->rx_lp_qdepth = ATH9K_HW_RX_LP_QDEPTH;
pCap->rx_status_len = sizeof(struct ar9003_rxs);
pCap->tx_desc_len = sizeof(struct ar9003_txc);
pCap->txs_len = sizeof(struct ar9003_txs);
} else {
pCap->tx_desc_len = sizeof(struct ath_desc);
}
if (AR_SREV_9300_20_OR_LATER(ah))
pCap->hw_caps |= ATH9K_HW_CAP_RAC_SUPPORTED;
return 0;
}
bool ath9k_hw_getcapability(struct ath_hw *ah, enum ath9k_capability_type type,
u32 capability, u32 *result)
{
struct ath_regulatory *regulatory = ath9k_hw_regulatory(ah);
switch (type) {
case ATH9K_CAP_CIPHER:
switch (capability) {
case ATH9K_CIPHER_AES_CCM:
case ATH9K_CIPHER_AES_OCB:
case ATH9K_CIPHER_TKIP:
case ATH9K_CIPHER_WEP:
case ATH9K_CIPHER_MIC:
case ATH9K_CIPHER_CLR:
return true;
default:
return false;
}
case ATH9K_CAP_TKIP_MIC:
switch (capability) {
case 0:
return true;
case 1:
return (ah->sta_id1_defaults &
AR_STA_ID1_CRPT_MIC_ENABLE) ? true :
false;
}
case ATH9K_CAP_TKIP_SPLIT:
return (ah->misc_mode & AR_PCU_MIC_NEW_LOC_ENA) ?
false : true;
case ATH9K_CAP_MCAST_KEYSRCH:
switch (capability) {
case 0:
return true;
case 1:
if (REG_READ(ah, AR_STA_ID1) & AR_STA_ID1_ADHOC) {
return false;
} else {
return (ah->sta_id1_defaults &
AR_STA_ID1_MCAST_KSRCH) ? true :
false;
}
}
return false;
case ATH9K_CAP_TXPOW:
switch (capability) {
case 0:
return 0;
case 1:
*result = regulatory->power_limit;
return 0;
case 2:
*result = regulatory->max_power_level;
return 0;
case 3:
*result = regulatory->tp_scale;
return 0;
}
return false;
case ATH9K_CAP_DS:
return (AR_SREV_9280_20_OR_LATER(ah) &&
(ah->eep_ops->get_eeprom(ah, EEP_RC_CHAIN_MASK) == 1))
? false : true;
default:
return false;
}
}
EXPORT_SYMBOL(ath9k_hw_getcapability);
bool ath9k_hw_setcapability(struct ath_hw *ah, enum ath9k_capability_type type,
u32 capability, u32 setting, int *status)
{
switch (type) {
case ATH9K_CAP_TKIP_MIC:
if (setting)
ah->sta_id1_defaults |=
AR_STA_ID1_CRPT_MIC_ENABLE;
else
ah->sta_id1_defaults &=
~AR_STA_ID1_CRPT_MIC_ENABLE;
return true;
case ATH9K_CAP_MCAST_KEYSRCH:
if (setting)
ah->sta_id1_defaults |= AR_STA_ID1_MCAST_KSRCH;
else
ah->sta_id1_defaults &= ~AR_STA_ID1_MCAST_KSRCH;
return true;
default:
return false;
}
}
EXPORT_SYMBOL(ath9k_hw_setcapability);
/****************************/
/* GPIO / RFKILL / Antennae */
/****************************/
static void ath9k_hw_gpio_cfg_output_mux(struct ath_hw *ah,
u32 gpio, u32 type)
{
int addr;
u32 gpio_shift, tmp;
if (gpio > 11)
addr = AR_GPIO_OUTPUT_MUX3;
else if (gpio > 5)
addr = AR_GPIO_OUTPUT_MUX2;
else
addr = AR_GPIO_OUTPUT_MUX1;
gpio_shift = (gpio % 6) * 5;
if (AR_SREV_9280_20_OR_LATER(ah)
|| (addr != AR_GPIO_OUTPUT_MUX1)) {
REG_RMW(ah, addr, (type << gpio_shift),
(0x1f << gpio_shift));
} else {
tmp = REG_READ(ah, addr);
tmp = ((tmp & 0x1F0) << 1) | (tmp & ~0x1F0);
tmp &= ~(0x1f << gpio_shift);
tmp |= (type << gpio_shift);
REG_WRITE(ah, addr, tmp);
}
}
void ath9k_hw_cfg_gpio_input(struct ath_hw *ah, u32 gpio)
{
u32 gpio_shift;
BUG_ON(gpio >= ah->caps.num_gpio_pins);
gpio_shift = gpio << 1;
REG_RMW(ah,
AR_GPIO_OE_OUT,
(AR_GPIO_OE_OUT_DRV_NO << gpio_shift),
(AR_GPIO_OE_OUT_DRV << gpio_shift));
}
EXPORT_SYMBOL(ath9k_hw_cfg_gpio_input);
u32 ath9k_hw_gpio_get(struct ath_hw *ah, u32 gpio)
{
#define MS_REG_READ(x, y) \
(MS(REG_READ(ah, AR_GPIO_IN_OUT), x##_GPIO_IN_VAL) & (AR_GPIO_BIT(y)))
if (gpio >= ah->caps.num_gpio_pins)
return 0xffffffff;
if (AR_SREV_9300_20_OR_LATER(ah))
return MS_REG_READ(AR9300, gpio) != 0;
else if (AR_SREV_9271(ah))
return MS_REG_READ(AR9271, gpio) != 0;
else if (AR_SREV_9287_10_OR_LATER(ah))
return MS_REG_READ(AR9287, gpio) != 0;
else if (AR_SREV_9285_10_OR_LATER(ah))
return MS_REG_READ(AR9285, gpio) != 0;
else if (AR_SREV_9280_10_OR_LATER(ah))
return MS_REG_READ(AR928X, gpio) != 0;
else
return MS_REG_READ(AR, gpio) != 0;
}
EXPORT_SYMBOL(ath9k_hw_gpio_get);
void ath9k_hw_cfg_output(struct ath_hw *ah, u32 gpio,
u32 ah_signal_type)
{
u32 gpio_shift;
ath9k_hw_gpio_cfg_output_mux(ah, gpio, ah_signal_type);
gpio_shift = 2 * gpio;
REG_RMW(ah,
AR_GPIO_OE_OUT,
(AR_GPIO_OE_OUT_DRV_ALL << gpio_shift),
(AR_GPIO_OE_OUT_DRV << gpio_shift));
}
EXPORT_SYMBOL(ath9k_hw_cfg_output);
void ath9k_hw_set_gpio(struct ath_hw *ah, u32 gpio, u32 val)
{
if (AR_SREV_9271(ah))
val = ~val;
REG_RMW(ah, AR_GPIO_IN_OUT, ((val & 1) << gpio),
AR_GPIO_BIT(gpio));
}
EXPORT_SYMBOL(ath9k_hw_set_gpio);
u32 ath9k_hw_getdefantenna(struct ath_hw *ah)
{
return REG_READ(ah, AR_DEF_ANTENNA) & 0x7;
}
EXPORT_SYMBOL(ath9k_hw_getdefantenna);
void ath9k_hw_setantenna(struct ath_hw *ah, u32 antenna)
{
REG_WRITE(ah, AR_DEF_ANTENNA, (antenna & 0x7));
}
EXPORT_SYMBOL(ath9k_hw_setantenna);
/*********************/
/* General Operation */
/*********************/
u32 ath9k_hw_getrxfilter(struct ath_hw *ah)
{
u32 bits = REG_READ(ah, AR_RX_FILTER);
u32 phybits = REG_READ(ah, AR_PHY_ERR);
if (phybits & AR_PHY_ERR_RADAR)
bits |= ATH9K_RX_FILTER_PHYRADAR;
if (phybits & (AR_PHY_ERR_OFDM_TIMING | AR_PHY_ERR_CCK_TIMING))
bits |= ATH9K_RX_FILTER_PHYERR;
return bits;
}
EXPORT_SYMBOL(ath9k_hw_getrxfilter);
void ath9k_hw_setrxfilter(struct ath_hw *ah, u32 bits)
{
u32 phybits;
ENABLE_REGWRITE_BUFFER(ah);
REG_WRITE(ah, AR_RX_FILTER, bits);
phybits = 0;
if (bits & ATH9K_RX_FILTER_PHYRADAR)
phybits |= AR_PHY_ERR_RADAR;
if (bits & ATH9K_RX_FILTER_PHYERR)
phybits |= AR_PHY_ERR_OFDM_TIMING | AR_PHY_ERR_CCK_TIMING;
REG_WRITE(ah, AR_PHY_ERR, phybits);
if (phybits)
REG_WRITE(ah, AR_RXCFG,
REG_READ(ah, AR_RXCFG) | AR_RXCFG_ZLFDMA);
else
REG_WRITE(ah, AR_RXCFG,
REG_READ(ah, AR_RXCFG) & ~AR_RXCFG_ZLFDMA);
REGWRITE_BUFFER_FLUSH(ah);
DISABLE_REGWRITE_BUFFER(ah);
}
EXPORT_SYMBOL(ath9k_hw_setrxfilter);
bool ath9k_hw_phy_disable(struct ath_hw *ah)
{
if (!ath9k_hw_set_reset_reg(ah, ATH9K_RESET_WARM))
return false;
ath9k_hw_init_pll(ah, NULL);
return true;
}
EXPORT_SYMBOL(ath9k_hw_phy_disable);
bool ath9k_hw_disable(struct ath_hw *ah)
{
if (!ath9k_hw_setpower(ah, ATH9K_PM_AWAKE))
return false;
if (!ath9k_hw_set_reset_reg(ah, ATH9K_RESET_COLD))
return false;
ath9k_hw_init_pll(ah, NULL);
return true;
}
EXPORT_SYMBOL(ath9k_hw_disable);
void ath9k_hw_set_txpowerlimit(struct ath_hw *ah, u32 limit)
{
struct ath_regulatory *regulatory = ath9k_hw_regulatory(ah);
struct ath9k_channel *chan = ah->curchan;
struct ieee80211_channel *channel = chan->chan;
regulatory->power_limit = min(limit, (u32) MAX_RATE_POWER);
ah->eep_ops->set_txpower(ah, chan,
ath9k_regd_get_ctl(regulatory, chan),
channel->max_antenna_gain * 2,
channel->max_power * 2,
min((u32) MAX_RATE_POWER,
(u32) regulatory->power_limit));
}
EXPORT_SYMBOL(ath9k_hw_set_txpowerlimit);
void ath9k_hw_setmac(struct ath_hw *ah, const u8 *mac)
{
memcpy(ath9k_hw_common(ah)->macaddr, mac, ETH_ALEN);
}
EXPORT_SYMBOL(ath9k_hw_setmac);
void ath9k_hw_setopmode(struct ath_hw *ah)
{
ath9k_hw_set_operating_mode(ah, ah->opmode);
}
EXPORT_SYMBOL(ath9k_hw_setopmode);
void ath9k_hw_setmcastfilter(struct ath_hw *ah, u32 filter0, u32 filter1)
{
REG_WRITE(ah, AR_MCAST_FIL0, filter0);
REG_WRITE(ah, AR_MCAST_FIL1, filter1);
}
EXPORT_SYMBOL(ath9k_hw_setmcastfilter);
void ath9k_hw_write_associd(struct ath_hw *ah)
{
struct ath_common *common = ath9k_hw_common(ah);
REG_WRITE(ah, AR_BSS_ID0, get_unaligned_le32(common->curbssid));
REG_WRITE(ah, AR_BSS_ID1, get_unaligned_le16(common->curbssid + 4) |
((common->curaid & 0x3fff) << AR_BSS_ID1_AID_S));
}
EXPORT_SYMBOL(ath9k_hw_write_associd);
#define ATH9K_MAX_TSF_READ 10
u64 ath9k_hw_gettsf64(struct ath_hw *ah)
{
u32 tsf_lower, tsf_upper1, tsf_upper2;
int i;
tsf_upper1 = REG_READ(ah, AR_TSF_U32);
for (i = 0; i < ATH9K_MAX_TSF_READ; i++) {
tsf_lower = REG_READ(ah, AR_TSF_L32);
tsf_upper2 = REG_READ(ah, AR_TSF_U32);
if (tsf_upper2 == tsf_upper1)
break;
tsf_upper1 = tsf_upper2;
}
WARN_ON( i == ATH9K_MAX_TSF_READ );
return (((u64)tsf_upper1 << 32) | tsf_lower);
}
EXPORT_SYMBOL(ath9k_hw_gettsf64);
void ath9k_hw_settsf64(struct ath_hw *ah, u64 tsf64)
{
REG_WRITE(ah, AR_TSF_L32, tsf64 & 0xffffffff);
REG_WRITE(ah, AR_TSF_U32, (tsf64 >> 32) & 0xffffffff);
}
EXPORT_SYMBOL(ath9k_hw_settsf64);
void ath9k_hw_reset_tsf(struct ath_hw *ah)
{
if (!ath9k_hw_wait(ah, AR_SLP32_MODE, AR_SLP32_TSF_WRITE_STATUS, 0,
AH_TSF_WRITE_TIMEOUT))
ath_print(ath9k_hw_common(ah), ATH_DBG_RESET,
"AR_SLP32_TSF_WRITE_STATUS limit exceeded\n");
REG_WRITE(ah, AR_RESET_TSF, AR_RESET_TSF_ONCE);
}
EXPORT_SYMBOL(ath9k_hw_reset_tsf);
void ath9k_hw_set_tsfadjust(struct ath_hw *ah, u32 setting)
{
if (setting)
ah->misc_mode |= AR_PCU_TX_ADD_TSF;
else
ah->misc_mode &= ~AR_PCU_TX_ADD_TSF;
}
EXPORT_SYMBOL(ath9k_hw_set_tsfadjust);
/*
* Extend 15-bit time stamp from rx descriptor to
* a full 64-bit TSF using the current h/w TSF.
*/
u64 ath9k_hw_extend_tsf(struct ath_hw *ah, u32 rstamp)
{
u64 tsf;
tsf = ath9k_hw_gettsf64(ah);
if ((tsf & 0x7fff) < rstamp)
tsf -= 0x8000;
return (tsf & ~0x7fff) | rstamp;
}
EXPORT_SYMBOL(ath9k_hw_extend_tsf);
void ath9k_hw_set11nmac2040(struct ath_hw *ah)
{
struct ieee80211_conf *conf = &ath9k_hw_common(ah)->hw->conf;
u32 macmode;
if (conf_is_ht40(conf) && !ah->config.cwm_ignore_extcca)
macmode = AR_2040_JOINED_RX_CLEAR;
else
macmode = 0;
REG_WRITE(ah, AR_2040_MODE, macmode);
}
/* HW Generic timers configuration */
static const struct ath_gen_timer_configuration gen_tmr_configuration[] =
{
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP_TIMER, AR_NDP_PERIOD, AR_TIMER_MODE, 0x0080},
{AR_NEXT_NDP2_TIMER, AR_NDP2_PERIOD, AR_NDP2_TIMER_MODE, 0x0001},
{AR_NEXT_NDP2_TIMER + 1*4, AR_NDP2_PERIOD + 1*4,
AR_NDP2_TIMER_MODE, 0x0002},
{AR_NEXT_NDP2_TIMER + 2*4, AR_NDP2_PERIOD + 2*4,
AR_NDP2_TIMER_MODE, 0x0004},
{AR_NEXT_NDP2_TIMER + 3*4, AR_NDP2_PERIOD + 3*4,
AR_NDP2_TIMER_MODE, 0x0008},
{AR_NEXT_NDP2_TIMER + 4*4, AR_NDP2_PERIOD + 4*4,
AR_NDP2_TIMER_MODE, 0x0010},
{AR_NEXT_NDP2_TIMER + 5*4, AR_NDP2_PERIOD + 5*4,
AR_NDP2_TIMER_MODE, 0x0020},
{AR_NEXT_NDP2_TIMER + 6*4, AR_NDP2_PERIOD + 6*4,
AR_NDP2_TIMER_MODE, 0x0040},
{AR_NEXT_NDP2_TIMER + 7*4, AR_NDP2_PERIOD + 7*4,
AR_NDP2_TIMER_MODE, 0x0080}
};
/* HW generic timer primitives */
/* compute and clear index of rightmost 1 */
static u32 rightmost_index(struct ath_gen_timer_table *timer_table, u32 *mask)
{
u32 b;
b = *mask;
b &= (0-b);
*mask &= ~b;
b *= debruijn32;
b >>= 27;
return timer_table->gen_timer_index[b];
}
u32 ath9k_hw_gettsf32(struct ath_hw *ah)
{
return REG_READ(ah, AR_TSF_L32);
}
EXPORT_SYMBOL(ath9k_hw_gettsf32);
struct ath_gen_timer *ath_gen_timer_alloc(struct ath_hw *ah,
void (*trigger)(void *),
void (*overflow)(void *),
void *arg,
u8 timer_index)
{
struct ath_gen_timer_table *timer_table = &ah->hw_gen_timers;
struct ath_gen_timer *timer;
timer = kzalloc(sizeof(struct ath_gen_timer), GFP_KERNEL);
if (timer == NULL) {
ath_print(ath9k_hw_common(ah), ATH_DBG_FATAL,
"Failed to allocate memory"
"for hw timer[%d]\n", timer_index);
return NULL;
}
/* allocate a hardware generic timer slot */
timer_table->timers[timer_index] = timer;
timer->index = timer_index;
timer->trigger = trigger;
timer->overflow = overflow;
timer->arg = arg;
return timer;
}
EXPORT_SYMBOL(ath_gen_timer_alloc);
void ath9k_hw_gen_timer_start(struct ath_hw *ah,
struct ath_gen_timer *timer,
u32 timer_next,
u32 timer_period)
{
struct ath_gen_timer_table *timer_table = &ah->hw_gen_timers;
u32 tsf;
BUG_ON(!timer_period);
set_bit(timer->index, &timer_table->timer_mask.timer_bits);
tsf = ath9k_hw_gettsf32(ah);
ath_print(ath9k_hw_common(ah), ATH_DBG_HWTIMER,
"curent tsf %x period %x"
"timer_next %x\n", tsf, timer_period, timer_next);
/*
* Pull timer_next forward if the current TSF already passed it
* because of software latency
*/
if (timer_next < tsf)
timer_next = tsf + timer_period;
/*
* Program generic timer registers
*/
REG_WRITE(ah, gen_tmr_configuration[timer->index].next_addr,
timer_next);
REG_WRITE(ah, gen_tmr_configuration[timer->index].period_addr,
timer_period);
REG_SET_BIT(ah, gen_tmr_configuration[timer->index].mode_addr,
gen_tmr_configuration[timer->index].mode_mask);
/* Enable both trigger and thresh interrupt masks */
REG_SET_BIT(ah, AR_IMR_S5,
(SM(AR_GENTMR_BIT(timer->index), AR_IMR_S5_GENTIMER_THRESH) |
SM(AR_GENTMR_BIT(timer->index), AR_IMR_S5_GENTIMER_TRIG)));
}
EXPORT_SYMBOL(ath9k_hw_gen_timer_start);
void ath9k_hw_gen_timer_stop(struct ath_hw *ah, struct ath_gen_timer *timer)
{
struct ath_gen_timer_table *timer_table = &ah->hw_gen_timers;
if ((timer->index < AR_FIRST_NDP_TIMER) ||
(timer->index >= ATH_MAX_GEN_TIMER)) {
return;
}
/* Clear generic timer enable bits. */
REG_CLR_BIT(ah, gen_tmr_configuration[timer->index].mode_addr,
gen_tmr_configuration[timer->index].mode_mask);
/* Disable both trigger and thresh interrupt masks */
REG_CLR_BIT(ah, AR_IMR_S5,
(SM(AR_GENTMR_BIT(timer->index), AR_IMR_S5_GENTIMER_THRESH) |
SM(AR_GENTMR_BIT(timer->index), AR_IMR_S5_GENTIMER_TRIG)));
clear_bit(timer->index, &timer_table->timer_mask.timer_bits);
}
EXPORT_SYMBOL(ath9k_hw_gen_timer_stop);
void ath_gen_timer_free(struct ath_hw *ah, struct ath_gen_timer *timer)
{
struct ath_gen_timer_table *timer_table = &ah->hw_gen_timers;
/* free the hardware generic timer slot */
timer_table->timers[timer->index] = NULL;
kfree(timer);
}
EXPORT_SYMBOL(ath_gen_timer_free);
/*
* Generic Timer Interrupts handling
*/
void ath_gen_timer_isr(struct ath_hw *ah)
{
struct ath_gen_timer_table *timer_table = &ah->hw_gen_timers;
struct ath_gen_timer *timer;
struct ath_common *common = ath9k_hw_common(ah);
u32 trigger_mask, thresh_mask, index;
/* get hardware generic timer interrupt status */
trigger_mask = ah->intr_gen_timer_trigger;
thresh_mask = ah->intr_gen_timer_thresh;
trigger_mask &= timer_table->timer_mask.val;
thresh_mask &= timer_table->timer_mask.val;
trigger_mask &= ~thresh_mask;
while (thresh_mask) {
index = rightmost_index(timer_table, &thresh_mask);
timer = timer_table->timers[index];
BUG_ON(!timer);
ath_print(common, ATH_DBG_HWTIMER,
"TSF overflow for Gen timer %d\n", index);
timer->overflow(timer->arg);
}
while (trigger_mask) {
index = rightmost_index(timer_table, &trigger_mask);
timer = timer_table->timers[index];
BUG_ON(!timer);
ath_print(common, ATH_DBG_HWTIMER,
"Gen timer[%d] trigger\n", index);
timer->trigger(timer->arg);
}
}
EXPORT_SYMBOL(ath_gen_timer_isr);
/********/
/* HTC */
/********/
void ath9k_hw_htc_resetinit(struct ath_hw *ah)
{
ah->htc_reset_init = true;
}
EXPORT_SYMBOL(ath9k_hw_htc_resetinit);
static struct {
u32 version;
const char * name;
} ath_mac_bb_names[] = {
/* Devices with external radios */
{ AR_SREV_VERSION_5416_PCI, "5416" },
{ AR_SREV_VERSION_5416_PCIE, "5418" },
{ AR_SREV_VERSION_9100, "9100" },
{ AR_SREV_VERSION_9160, "9160" },
/* Single-chip solutions */
{ AR_SREV_VERSION_9280, "9280" },
{ AR_SREV_VERSION_9285, "9285" },
{ AR_SREV_VERSION_9287, "9287" },
{ AR_SREV_VERSION_9271, "9271" },
{ AR_SREV_VERSION_9300, "9300" },
};
/* For devices with external radios */
static struct {
u16 version;
const char * name;
} ath_rf_names[] = {
{ 0, "5133" },
{ AR_RAD5133_SREV_MAJOR, "5133" },
{ AR_RAD5122_SREV_MAJOR, "5122" },
{ AR_RAD2133_SREV_MAJOR, "2133" },
{ AR_RAD2122_SREV_MAJOR, "2122" }
};
/*
* Return the MAC/BB name. "????" is returned if the MAC/BB is unknown.
*/
static const char *ath9k_hw_mac_bb_name(u32 mac_bb_version)
{
int i;
for (i=0; i<ARRAY_SIZE(ath_mac_bb_names); i++) {
if (ath_mac_bb_names[i].version == mac_bb_version) {
return ath_mac_bb_names[i].name;
}
}
return "????";
}
/*
* Return the RF name. "????" is returned if the RF is unknown.
* Used for devices with external radios.
*/
static const char *ath9k_hw_rf_name(u16 rf_version)
{
int i;
for (i=0; i<ARRAY_SIZE(ath_rf_names); i++) {
if (ath_rf_names[i].version == rf_version) {
return ath_rf_names[i].name;
}
}
return "????";
}
void ath9k_hw_name(struct ath_hw *ah, char *hw_name, size_t len)
{
int used;
/* chipsets >= AR9280 are single-chip */
if (AR_SREV_9280_10_OR_LATER(ah)) {
used = snprintf(hw_name, len,
"Atheros AR%s Rev:%x",
ath9k_hw_mac_bb_name(ah->hw_version.macVersion),
ah->hw_version.macRev);
}
else {
used = snprintf(hw_name, len,
"Atheros AR%s MAC/BB Rev:%x AR%s RF Rev:%x",
ath9k_hw_mac_bb_name(ah->hw_version.macVersion),
ah->hw_version.macRev,
ath9k_hw_rf_name((ah->hw_version.analog5GhzRev &
AR_RADIO_SREV_MAJOR)),
ah->hw_version.phyRev);
}
hw_name[used] = '\0';
}
EXPORT_SYMBOL(ath9k_hw_name);