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gfiber / kernel / windcharger / d95f9bd73fd3a4ebabf7c524941f6b6095388c55 / . / drivers / net / wireless / b43 / phy_lp.c
blob: ea0d3a3a6a647036222b6160a9f1ae91de4e9493 [file] [log] [blame]
/*
Broadcom B43 wireless driver
IEEE 802.11g LP-PHY driver
Copyright (c) 2008-2009 Michael Buesch <mb@bu3sch.de>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; see the file COPYING. If not, write to
the Free Software Foundation, Inc., 51 Franklin Steet, Fifth Floor,
Boston, MA 02110-1301, USA.
*/
#include "b43.h"
#include "main.h"
#include "phy_lp.h"
#include "phy_common.h"
#include "tables_lpphy.h"
static int b43_lpphy_op_allocate(struct b43_wldev *dev)
{
struct b43_phy_lp *lpphy;
lpphy = kzalloc(sizeof(*lpphy), GFP_KERNEL);
if (!lpphy)
return -ENOMEM;
dev->phy.lp = lpphy;
return 0;
}
static void b43_lpphy_op_prepare_structs(struct b43_wldev *dev)
{
struct b43_phy *phy = &dev->phy;
struct b43_phy_lp *lpphy = phy->lp;
memset(lpphy, 0, sizeof(*lpphy));
//TODO
}
static void b43_lpphy_op_free(struct b43_wldev *dev)
{
struct b43_phy_lp *lpphy = dev->phy.lp;
kfree(lpphy);
dev->phy.lp = NULL;
}
static void lpphy_table_init(struct b43_wldev *dev)
{
//TODO
}
static void lpphy_baseband_rev0_1_init(struct b43_wldev *dev)
{
B43_WARN_ON(1);//TODO rev < 2 not supported, yet.
}
static void lpphy_baseband_rev2plus_init(struct b43_wldev *dev)
{
struct ssb_bus *bus = dev->dev->bus;
struct b43_phy_lp *lpphy = dev->phy.lp;
b43_phy_write(dev, B43_LPPHY_AFE_DAC_CTL, 0x50);
b43_phy_write(dev, B43_LPPHY_AFE_CTL, 0x8800);
b43_phy_write(dev, B43_LPPHY_AFE_CTL_OVR, 0);
b43_phy_write(dev, B43_LPPHY_AFE_CTL_OVRVAL, 0);
b43_phy_write(dev, B43_LPPHY_RF_OVERRIDE_0, 0);
b43_phy_write(dev, B43_LPPHY_RF_OVERRIDE_2, 0);
b43_phy_write(dev, B43_PHY_OFDM(0xF9), 0);
b43_phy_write(dev, B43_LPPHY_TR_LOOKUP_1, 0);
b43_phy_set(dev, B43_LPPHY_ADC_COMPENSATION_CTL, 0x10);
b43_phy_maskset(dev, B43_LPPHY_OFDMSYNCTHRESH0, 0xFF00, 0x78);
b43_phy_maskset(dev, B43_LPPHY_DCOFFSETTRANSIENT, 0xF8FF, 0x200);
b43_phy_maskset(dev, B43_LPPHY_DCOFFSETTRANSIENT, 0xFF00, 0x7F);
b43_phy_maskset(dev, B43_LPPHY_GAINDIRECTMISMATCH, 0xFF0F, 0x40);
b43_phy_maskset(dev, B43_LPPHY_PREAMBLECONFIRMTO, 0xFF00, 0x2);
b43_phy_mask(dev, B43_LPPHY_CRSGAIN_CTL, ~0x4000);
b43_phy_mask(dev, B43_LPPHY_CRSGAIN_CTL, ~0x2000);
b43_phy_set(dev, B43_PHY_OFDM(0x10A), 0x1);
b43_phy_maskset(dev, B43_PHY_OFDM(0x10A), 0xFF01, 0x10);
b43_phy_maskset(dev, B43_PHY_OFDM(0xDF), 0xFF00, 0xF4);
b43_phy_maskset(dev, B43_PHY_OFDM(0xDF), 0x00FF, 0xF100);
b43_phy_write(dev, B43_LPPHY_CLIPTHRESH, 0x48);
b43_phy_maskset(dev, B43_LPPHY_HIGAINDB, 0xFF00, 0x46);
b43_phy_maskset(dev, B43_PHY_OFDM(0xE4), 0xFF00, 0x10);
b43_phy_maskset(dev, B43_LPPHY_PWR_THRESH1, 0xFFF0, 0x9);
b43_phy_mask(dev, B43_LPPHY_GAINDIRECTMISMATCH, ~0xF);
b43_phy_maskset(dev, B43_LPPHY_VERYLOWGAINDB, 0x00FF, 0x5500);
b43_phy_maskset(dev, B43_LPPHY_CLIPCTRTHRESH, 0xF81F, 0xA0);
b43_phy_maskset(dev, B43_LPPHY_GAINDIRECTMISMATCH, 0xE0FF, 0x300);
b43_phy_maskset(dev, B43_LPPHY_HIGAINDB, 0x00FF, 0x2A00);
if ((bus->chip_id == 0x4325) && (bus->chip_rev == 0)) {
b43_phy_maskset(dev, B43_LPPHY_LOWGAINDB, 0x00FF, 0x2100);
b43_phy_maskset(dev, B43_LPPHY_VERYLOWGAINDB, 0xFF00, 0xA);
} else {
b43_phy_maskset(dev, B43_LPPHY_LOWGAINDB, 0x00FF, 0x1E00);
b43_phy_maskset(dev, B43_LPPHY_VERYLOWGAINDB, 0xFF00, 0xD);
}
b43_phy_maskset(dev, B43_PHY_OFDM(0xFE), 0xFFE0, 0x1F);
b43_phy_maskset(dev, B43_PHY_OFDM(0xFF), 0xFFE0, 0xC);
b43_phy_maskset(dev, B43_PHY_OFDM(0x100), 0xFF00, 0x19);
b43_phy_maskset(dev, B43_PHY_OFDM(0xFF), 0x03FF, 0x3C00);
b43_phy_maskset(dev, B43_PHY_OFDM(0xFE), 0xFC1F, 0x3E0);
b43_phy_maskset(dev, B43_PHY_OFDM(0xFF), 0xFFE0, 0xC);
b43_phy_maskset(dev, B43_PHY_OFDM(0x100), 0x00FF, 0x1900);
b43_phy_maskset(dev, B43_LPPHY_CLIPCTRTHRESH, 0x83FF, 0x5800);
b43_phy_maskset(dev, B43_LPPHY_CLIPCTRTHRESH, 0xFFE0, 0x12);
b43_phy_maskset(dev, B43_LPPHY_GAINMISMATCH, 0x0FFF, 0x9000);
b43_lptab_write(dev, B43_LPTAB16(0x08, 0x14), 0);
b43_lptab_write(dev, B43_LPTAB16(0x08, 0x12), 0x40);
if (b43_current_band(dev->wl) == IEEE80211_BAND_2GHZ) {
b43_phy_set(dev, B43_LPPHY_CRSGAIN_CTL, 0x40);
b43_phy_maskset(dev, B43_LPPHY_CRSGAIN_CTL, 0xF0FF, 0xB00);
b43_phy_maskset(dev, B43_LPPHY_SYNCPEAKCNT, 0xFFF8, 0x6);
b43_phy_maskset(dev, B43_LPPHY_MINPWR_LEVEL, 0x00FF, 0x9D00);
b43_phy_maskset(dev, B43_LPPHY_MINPWR_LEVEL, 0xFF00, 0xA1);
} else /* 5GHz */
b43_phy_mask(dev, B43_LPPHY_CRSGAIN_CTL, ~0x40);
b43_phy_maskset(dev, B43_LPPHY_CRS_ED_THRESH, 0xFF00, 0xB3);
b43_phy_maskset(dev, B43_LPPHY_CRS_ED_THRESH, 0x00FF, 0xAD00);
b43_phy_maskset(dev, B43_LPPHY_INPUT_PWRDB, 0xFF00, lpphy->rx_pwr_offset);
b43_phy_set(dev, B43_LPPHY_RESET_CTL, 0x44);
b43_phy_write(dev, B43_LPPHY_RESET_CTL, 0x80);
b43_phy_write(dev, B43_LPPHY_AFE_RSSI_CTL_0, 0xA954);
b43_phy_write(dev, B43_LPPHY_AFE_RSSI_CTL_1,
0x2000 | ((u16)lpphy->rssi_gs << 10) |
((u16)lpphy->rssi_vc << 4) | lpphy->rssi_vf);
}
static void lpphy_baseband_init(struct b43_wldev *dev)
{
lpphy_table_init(dev);
if (dev->phy.rev >= 2)
lpphy_baseband_rev2plus_init(dev);
else
lpphy_baseband_rev0_1_init(dev);
}
struct b2062_freqdata {
u16 freq;
u8 data[6];
};
/* Initialize the 2062 radio. */
static void lpphy_2062_init(struct b43_wldev *dev)
{
struct ssb_bus *bus = dev->dev->bus;
u32 crystalfreq, pdiv, tmp, ref;
unsigned int i;
const struct b2062_freqdata *fd = NULL;
static const struct b2062_freqdata freqdata_tab[] = {
{ .freq = 12000, .data[0] = 6, .data[1] = 6, .data[2] = 6,
.data[3] = 6, .data[4] = 10, .data[5] = 6, },
{ .freq = 13000, .data[0] = 4, .data[1] = 4, .data[2] = 4,
.data[3] = 4, .data[4] = 11, .data[5] = 7, },
{ .freq = 14400, .data[0] = 3, .data[1] = 3, .data[2] = 3,
.data[3] = 3, .data[4] = 12, .data[5] = 7, },
{ .freq = 16200, .data[0] = 3, .data[1] = 3, .data[2] = 3,
.data[3] = 3, .data[4] = 13, .data[5] = 8, },
{ .freq = 18000, .data[0] = 2, .data[1] = 2, .data[2] = 2,
.data[3] = 2, .data[4] = 14, .data[5] = 8, },
{ .freq = 19200, .data[0] = 1, .data[1] = 1, .data[2] = 1,
.data[3] = 1, .data[4] = 14, .data[5] = 9, },
};
b2062_upload_init_table(dev);
b43_radio_write(dev, B2062_N_TX_CTL3, 0);
b43_radio_write(dev, B2062_N_TX_CTL4, 0);
b43_radio_write(dev, B2062_N_TX_CTL5, 0);
b43_radio_write(dev, B2062_N_PDN_CTL0, 0x40);
b43_radio_write(dev, B2062_N_PDN_CTL0, 0);
b43_radio_write(dev, B2062_N_CALIB_TS, 0x10);
b43_radio_write(dev, B2062_N_CALIB_TS, 0);
if (b43_current_band(dev->wl) == IEEE80211_BAND_2GHZ)
b43_radio_set(dev, B2062_N_TSSI_CTL0, 0x1);
else
b43_radio_mask(dev, B2062_N_TSSI_CTL0, ~0x1);
/* Get the crystal freq, in Hz. */
crystalfreq = bus->chipco.pmu.crystalfreq * 1000;
B43_WARN_ON(!(bus->chipco.capabilities & SSB_CHIPCO_CAP_PMU));
B43_WARN_ON(crystalfreq == 0);
if (crystalfreq >= 30000000) {
pdiv = 1;
b43_radio_mask(dev, B2062_S_RFPLL_CTL1, 0xFFFB);
} else {
pdiv = 2;
b43_radio_set(dev, B2062_S_RFPLL_CTL1, 0x4);
}
tmp = (800000000 * pdiv + crystalfreq) / (32000000 * pdiv);
tmp = (tmp - 1) & 0xFF;
b43_radio_write(dev, B2062_S_RFPLL_CTL18, tmp);
tmp = (2 * crystalfreq + 1000000 * pdiv) / (2000000 * pdiv);
tmp = ((tmp & 0xFF) - 1) & 0xFFFF;
b43_radio_write(dev, B2062_S_RFPLL_CTL19, tmp);
ref = (1000 * pdiv + 2 * crystalfreq) / (2000 * pdiv);
ref &= 0xFFFF;
for (i = 0; i < ARRAY_SIZE(freqdata_tab); i++) {
if (ref < freqdata_tab[i].freq) {
fd = &freqdata_tab[i];
break;
}
}
if (!fd)
fd = &freqdata_tab[ARRAY_SIZE(freqdata_tab) - 1];
b43dbg(dev->wl, "b2062: Using crystal tab entry %u kHz.\n",
fd->freq); /* FIXME: Keep this printk until the code is fully debugged. */
b43_radio_write(dev, B2062_S_RFPLL_CTL8,
((u16)(fd->data[1]) << 4) | fd->data[0]);
b43_radio_write(dev, B2062_S_RFPLL_CTL9,
((u16)(fd->data[3]) << 4) | fd->data[2]);
b43_radio_write(dev, B2062_S_RFPLL_CTL10, fd->data[4]);
b43_radio_write(dev, B2062_S_RFPLL_CTL11, fd->data[5]);
}
/* Initialize the 2063 radio. */
static void lpphy_2063_init(struct b43_wldev *dev)
{
//TODO
}
static void lpphy_sync_stx(struct b43_wldev *dev)
{
//TODO
}
static void lpphy_radio_init(struct b43_wldev *dev)
{
/* The radio is attached through the 4wire bus. */
b43_phy_set(dev, B43_LPPHY_FOURWIRE_CTL, 0x2);
udelay(1);
b43_phy_mask(dev, B43_LPPHY_FOURWIRE_CTL, 0xFFFD);
udelay(1);
if (dev->phy.rev < 2) {
lpphy_2062_init(dev);
} else {
lpphy_2063_init(dev);
lpphy_sync_stx(dev);
b43_phy_write(dev, B43_PHY_OFDM(0xF0), 0x5F80);
b43_phy_write(dev, B43_PHY_OFDM(0xF1), 0);
//TODO Do something on the backplane
}
}
/* Read the TX power control mode from hardware. */
static void lpphy_read_tx_pctl_mode_from_hardware(struct b43_wldev *dev)
{
struct b43_phy_lp *lpphy = dev->phy.lp;
u16 ctl;
ctl = b43_phy_read(dev, B43_LPPHY_TX_PWR_CTL_CMD);
switch (ctl & B43_LPPHY_TX_PWR_CTL_CMD_MODE) {
case B43_LPPHY_TX_PWR_CTL_CMD_MODE_OFF:
lpphy->txpctl_mode = B43_LPPHY_TXPCTL_OFF;
break;
case B43_LPPHY_TX_PWR_CTL_CMD_MODE_SW:
lpphy->txpctl_mode = B43_LPPHY_TXPCTL_SW;
break;
case B43_LPPHY_TX_PWR_CTL_CMD_MODE_HW:
lpphy->txpctl_mode = B43_LPPHY_TXPCTL_HW;
break;
default:
lpphy->txpctl_mode = B43_LPPHY_TXPCTL_UNKNOWN;
B43_WARN_ON(1);
break;
}
}
/* Set the TX power control mode in hardware. */
static void lpphy_write_tx_pctl_mode_to_hardware(struct b43_wldev *dev)
{
struct b43_phy_lp *lpphy = dev->phy.lp;
u16 ctl;
switch (lpphy->txpctl_mode) {
case B43_LPPHY_TXPCTL_OFF:
ctl = B43_LPPHY_TX_PWR_CTL_CMD_MODE_OFF;
break;
case B43_LPPHY_TXPCTL_HW:
ctl = B43_LPPHY_TX_PWR_CTL_CMD_MODE_HW;
break;
case B43_LPPHY_TXPCTL_SW:
ctl = B43_LPPHY_TX_PWR_CTL_CMD_MODE_SW;
break;
default:
ctl = 0;
B43_WARN_ON(1);
}
b43_phy_maskset(dev, B43_LPPHY_TX_PWR_CTL_CMD,
(u16)~B43_LPPHY_TX_PWR_CTL_CMD_MODE, ctl);
}
static void lpphy_set_tx_power_control(struct b43_wldev *dev,
enum b43_lpphy_txpctl_mode mode)
{
struct b43_phy_lp *lpphy = dev->phy.lp;
enum b43_lpphy_txpctl_mode oldmode;
oldmode = lpphy->txpctl_mode;
lpphy_read_tx_pctl_mode_from_hardware(dev);
if (lpphy->txpctl_mode == mode)
return;
lpphy->txpctl_mode = mode;
if (oldmode == B43_LPPHY_TXPCTL_HW) {
//TODO Update TX Power NPT
//TODO Clear all TX Power offsets
} else {
if (mode == B43_LPPHY_TXPCTL_HW) {
//TODO Recalculate target TX power
b43_phy_maskset(dev, B43_LPPHY_TX_PWR_CTL_CMD,
0xFF80, lpphy->tssi_idx);
b43_phy_maskset(dev, B43_LPPHY_TX_PWR_CTL_NNUM,
0x8FFF, ((u16)lpphy->tssi_npt << 16));
//TODO Set "TSSI Transmit Count" variable to total transmitted frame count
//TODO Disable TX gain override
lpphy->tx_pwr_idx_over = -1;
}
}
if (dev->phy.rev >= 2) {
if (mode == B43_LPPHY_TXPCTL_HW)
b43_phy_maskset(dev, B43_PHY_OFDM(0xD0), 0xFD, 0x2);
else
b43_phy_maskset(dev, B43_PHY_OFDM(0xD0), 0xFD, 0);
}
lpphy_write_tx_pctl_mode_to_hardware(dev);
}
static void lpphy_set_tx_power_by_index(struct b43_wldev *dev, u8 index)
{
struct b43_phy_lp *lpphy = dev->phy.lp;
lpphy->tx_pwr_idx_over = index;
if (lpphy->txpctl_mode != B43_LPPHY_TXPCTL_OFF)
lpphy_set_tx_power_control(dev, B43_LPPHY_TXPCTL_SW);
//TODO
}
static void lpphy_btcoex_override(struct b43_wldev *dev)
{
b43_write16(dev, B43_MMIO_BTCOEX_CTL, 0x3);
b43_write16(dev, B43_MMIO_BTCOEX_TXCTL, 0xFF);
}
static void lpphy_pr41573_workaround(struct b43_wldev *dev)
{
struct b43_phy_lp *lpphy = dev->phy.lp;
u32 *saved_tab;
const unsigned int saved_tab_size = 256;
enum b43_lpphy_txpctl_mode txpctl_mode;
s8 tx_pwr_idx_over;
u16 tssi_npt, tssi_idx;
saved_tab = kcalloc(saved_tab_size, sizeof(saved_tab[0]), GFP_KERNEL);
if (!saved_tab) {
b43err(dev->wl, "PR41573 failed. Out of memory!\n");
return;
}
lpphy_read_tx_pctl_mode_from_hardware(dev);
txpctl_mode = lpphy->txpctl_mode;
tx_pwr_idx_over = lpphy->tx_pwr_idx_over;
tssi_npt = lpphy->tssi_npt;
tssi_idx = lpphy->tssi_idx;
if (dev->phy.rev < 2) {
b43_lptab_read_bulk(dev, B43_LPTAB32(10, 0x140),
saved_tab_size, saved_tab);
} else {
b43_lptab_read_bulk(dev, B43_LPTAB32(7, 0x140),
saved_tab_size, saved_tab);
}
//TODO
kfree(saved_tab);
}
static void lpphy_calibration(struct b43_wldev *dev)
{
struct b43_phy_lp *lpphy = dev->phy.lp;
enum b43_lpphy_txpctl_mode saved_pctl_mode;
b43_mac_suspend(dev);
lpphy_btcoex_override(dev);
lpphy_read_tx_pctl_mode_from_hardware(dev);
saved_pctl_mode = lpphy->txpctl_mode;
lpphy_set_tx_power_control(dev, B43_LPPHY_TXPCTL_OFF);
//TODO Perform transmit power table I/Q LO calibration
if ((dev->phy.rev == 0) && (saved_pctl_mode != B43_LPPHY_TXPCTL_OFF))
lpphy_pr41573_workaround(dev);
//TODO If a full calibration has not been performed on this channel yet, perform PAPD TX-power calibration
lpphy_set_tx_power_control(dev, saved_pctl_mode);
//TODO Perform I/Q calibration with a single control value set
b43_mac_enable(dev);
}
/* Initialize TX power control */
static void lpphy_tx_pctl_init(struct b43_wldev *dev)
{
if (0/*FIXME HWPCTL capable */) {
//TODO
} else { /* This device is only software TX power control capable. */
if (b43_current_band(dev->wl) == IEEE80211_BAND_2GHZ) {
//TODO
} else {
//TODO
}
//TODO set BB multiplier to 0x0096
}
}
static int b43_lpphy_op_init(struct b43_wldev *dev)
{
/* TODO: band SPROM */
lpphy_baseband_init(dev);
lpphy_radio_init(dev);
//TODO calibrate RC
//TODO set channel
lpphy_tx_pctl_init(dev);
//TODO full calib
return 0;
}
static u16 b43_lpphy_op_read(struct b43_wldev *dev, u16 reg)
{
b43_write16(dev, B43_MMIO_PHY_CONTROL, reg);
return b43_read16(dev, B43_MMIO_PHY_DATA);
}
static void b43_lpphy_op_write(struct b43_wldev *dev, u16 reg, u16 value)
{
b43_write16(dev, B43_MMIO_PHY_CONTROL, reg);
b43_write16(dev, B43_MMIO_PHY_DATA, value);
}
static u16 b43_lpphy_op_radio_read(struct b43_wldev *dev, u16 reg)
{
/* Register 1 is a 32-bit register. */
B43_WARN_ON(reg == 1);
/* LP-PHY needs a special bit set for read access */
if (dev->phy.rev < 2) {
if (reg != 0x4001)
reg |= 0x100;
} else
reg |= 0x200;
b43_write16(dev, B43_MMIO_RADIO_CONTROL, reg);
return b43_read16(dev, B43_MMIO_RADIO_DATA_LOW);
}
static void b43_lpphy_op_radio_write(struct b43_wldev *dev, u16 reg, u16 value)
{
/* Register 1 is a 32-bit register. */
B43_WARN_ON(reg == 1);
b43_write16(dev, B43_MMIO_RADIO_CONTROL, reg);
b43_write16(dev, B43_MMIO_RADIO_DATA_LOW, value);
}
static void b43_lpphy_op_software_rfkill(struct b43_wldev *dev,
bool blocked)
{
//TODO
}
static int b43_lpphy_op_switch_channel(struct b43_wldev *dev,
unsigned int new_channel)
{
//TODO
return 0;
}
static unsigned int b43_lpphy_op_get_default_chan(struct b43_wldev *dev)
{
if (b43_current_band(dev->wl) == IEEE80211_BAND_2GHZ)
return 1;
return 36;
}
static void b43_lpphy_op_set_rx_antenna(struct b43_wldev *dev, int antenna)
{
//TODO
}
static void b43_lpphy_op_adjust_txpower(struct b43_wldev *dev)
{
//TODO
}
static enum b43_txpwr_result b43_lpphy_op_recalc_txpower(struct b43_wldev *dev,
bool ignore_tssi)
{
//TODO
return B43_TXPWR_RES_DONE;
}
const struct b43_phy_operations b43_phyops_lp = {
.allocate = b43_lpphy_op_allocate,
.free = b43_lpphy_op_free,
.prepare_structs = b43_lpphy_op_prepare_structs,
.init = b43_lpphy_op_init,
.phy_read = b43_lpphy_op_read,
.phy_write = b43_lpphy_op_write,
.radio_read = b43_lpphy_op_radio_read,
.radio_write = b43_lpphy_op_radio_write,
.software_rfkill = b43_lpphy_op_software_rfkill,
.switch_analog = b43_phyop_switch_analog_generic,
.switch_channel = b43_lpphy_op_switch_channel,
.get_default_chan = b43_lpphy_op_get_default_chan,
.set_rx_antenna = b43_lpphy_op_set_rx_antenna,
.recalc_txpower = b43_lpphy_op_recalc_txpower,
.adjust_txpower = b43_lpphy_op_adjust_txpower,
};