android_kernel_xiaomi_sm8350/drivers/net/wireless/zd1211rw/zd_chip.c
Tejun Heo 5a0e3ad6af include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h
percpu.h is included by sched.h and module.h and thus ends up being
included when building most .c files.  percpu.h includes slab.h which
in turn includes gfp.h making everything defined by the two files
universally available and complicating inclusion dependencies.

percpu.h -> slab.h dependency is about to be removed.  Prepare for
this change by updating users of gfp and slab facilities include those
headers directly instead of assuming availability.  As this conversion
needs to touch large number of source files, the following script is
used as the basis of conversion.

  http://userweb.kernel.org/~tj/misc/slabh-sweep.py

The script does the followings.

* Scan files for gfp and slab usages and update includes such that
  only the necessary includes are there.  ie. if only gfp is used,
  gfp.h, if slab is used, slab.h.

* When the script inserts a new include, it looks at the include
  blocks and try to put the new include such that its order conforms
  to its surrounding.  It's put in the include block which contains
  core kernel includes, in the same order that the rest are ordered -
  alphabetical, Christmas tree, rev-Xmas-tree or at the end if there
  doesn't seem to be any matching order.

* If the script can't find a place to put a new include (mostly
  because the file doesn't have fitting include block), it prints out
  an error message indicating which .h file needs to be added to the
  file.

The conversion was done in the following steps.

1. The initial automatic conversion of all .c files updated slightly
   over 4000 files, deleting around 700 includes and adding ~480 gfp.h
   and ~3000 slab.h inclusions.  The script emitted errors for ~400
   files.

2. Each error was manually checked.  Some didn't need the inclusion,
   some needed manual addition while adding it to implementation .h or
   embedding .c file was more appropriate for others.  This step added
   inclusions to around 150 files.

3. The script was run again and the output was compared to the edits
   from #2 to make sure no file was left behind.

4. Several build tests were done and a couple of problems were fixed.
   e.g. lib/decompress_*.c used malloc/free() wrappers around slab
   APIs requiring slab.h to be added manually.

5. The script was run on all .h files but without automatically
   editing them as sprinkling gfp.h and slab.h inclusions around .h
   files could easily lead to inclusion dependency hell.  Most gfp.h
   inclusion directives were ignored as stuff from gfp.h was usually
   wildly available and often used in preprocessor macros.  Each
   slab.h inclusion directive was examined and added manually as
   necessary.

6. percpu.h was updated not to include slab.h.

7. Build test were done on the following configurations and failures
   were fixed.  CONFIG_GCOV_KERNEL was turned off for all tests (as my
   distributed build env didn't work with gcov compiles) and a few
   more options had to be turned off depending on archs to make things
   build (like ipr on powerpc/64 which failed due to missing writeq).

   * x86 and x86_64 UP and SMP allmodconfig and a custom test config.
   * powerpc and powerpc64 SMP allmodconfig
   * sparc and sparc64 SMP allmodconfig
   * ia64 SMP allmodconfig
   * s390 SMP allmodconfig
   * alpha SMP allmodconfig
   * um on x86_64 SMP allmodconfig

8. percpu.h modifications were reverted so that it could be applied as
   a separate patch and serve as bisection point.

Given the fact that I had only a couple of failures from tests on step
6, I'm fairly confident about the coverage of this conversion patch.
If there is a breakage, it's likely to be something in one of the arch
headers which should be easily discoverable easily on most builds of
the specific arch.

Signed-off-by: Tejun Heo <tj@kernel.org>
Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org>
Cc: Ingo Molnar <mingo@redhat.com>
Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-30 22:02:32 +09:00

1501 lines
36 KiB
C

/* ZD1211 USB-WLAN driver for Linux
*
* Copyright (C) 2005-2007 Ulrich Kunitz <kune@deine-taler.de>
* Copyright (C) 2006-2007 Daniel Drake <dsd@gentoo.org>
*
* 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; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
/* This file implements all the hardware specific functions for the ZD1211
* and ZD1211B chips. Support for the ZD1211B was possible after Timothy
* Legge sent me a ZD1211B device. Thank you Tim. -- Uli
*/
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/slab.h>
#include "zd_def.h"
#include "zd_chip.h"
#include "zd_mac.h"
#include "zd_rf.h"
void zd_chip_init(struct zd_chip *chip,
struct ieee80211_hw *hw,
struct usb_interface *intf)
{
memset(chip, 0, sizeof(*chip));
mutex_init(&chip->mutex);
zd_usb_init(&chip->usb, hw, intf);
zd_rf_init(&chip->rf);
}
void zd_chip_clear(struct zd_chip *chip)
{
ZD_ASSERT(!mutex_is_locked(&chip->mutex));
zd_usb_clear(&chip->usb);
zd_rf_clear(&chip->rf);
mutex_destroy(&chip->mutex);
ZD_MEMCLEAR(chip, sizeof(*chip));
}
static int scnprint_mac_oui(struct zd_chip *chip, char *buffer, size_t size)
{
u8 *addr = zd_mac_get_perm_addr(zd_chip_to_mac(chip));
return scnprintf(buffer, size, "%02x-%02x-%02x",
addr[0], addr[1], addr[2]);
}
/* Prints an identifier line, which will support debugging. */
static int scnprint_id(struct zd_chip *chip, char *buffer, size_t size)
{
int i = 0;
i = scnprintf(buffer, size, "zd1211%s chip ",
zd_chip_is_zd1211b(chip) ? "b" : "");
i += zd_usb_scnprint_id(&chip->usb, buffer+i, size-i);
i += scnprintf(buffer+i, size-i, " ");
i += scnprint_mac_oui(chip, buffer+i, size-i);
i += scnprintf(buffer+i, size-i, " ");
i += zd_rf_scnprint_id(&chip->rf, buffer+i, size-i);
i += scnprintf(buffer+i, size-i, " pa%1x %c%c%c%c%c", chip->pa_type,
chip->patch_cck_gain ? 'g' : '-',
chip->patch_cr157 ? '7' : '-',
chip->patch_6m_band_edge ? '6' : '-',
chip->new_phy_layout ? 'N' : '-',
chip->al2230s_bit ? 'S' : '-');
return i;
}
static void print_id(struct zd_chip *chip)
{
char buffer[80];
scnprint_id(chip, buffer, sizeof(buffer));
buffer[sizeof(buffer)-1] = 0;
dev_info(zd_chip_dev(chip), "%s\n", buffer);
}
static zd_addr_t inc_addr(zd_addr_t addr)
{
u16 a = (u16)addr;
/* Control registers use byte addressing, but everything else uses word
* addressing. */
if ((a & 0xf000) == CR_START)
a += 2;
else
a += 1;
return (zd_addr_t)a;
}
/* Read a variable number of 32-bit values. Parameter count is not allowed to
* exceed USB_MAX_IOREAD32_COUNT.
*/
int zd_ioread32v_locked(struct zd_chip *chip, u32 *values, const zd_addr_t *addr,
unsigned int count)
{
int r;
int i;
zd_addr_t *a16;
u16 *v16;
unsigned int count16;
if (count > USB_MAX_IOREAD32_COUNT)
return -EINVAL;
/* Allocate a single memory block for values and addresses. */
count16 = 2*count;
a16 = (zd_addr_t *) kmalloc(count16 * (sizeof(zd_addr_t) + sizeof(u16)),
GFP_KERNEL);
if (!a16) {
dev_dbg_f(zd_chip_dev(chip),
"error ENOMEM in allocation of a16\n");
r = -ENOMEM;
goto out;
}
v16 = (u16 *)(a16 + count16);
for (i = 0; i < count; i++) {
int j = 2*i;
/* We read the high word always first. */
a16[j] = inc_addr(addr[i]);
a16[j+1] = addr[i];
}
r = zd_ioread16v_locked(chip, v16, a16, count16);
if (r) {
dev_dbg_f(zd_chip_dev(chip),
"error: zd_ioread16v_locked. Error number %d\n", r);
goto out;
}
for (i = 0; i < count; i++) {
int j = 2*i;
values[i] = (v16[j] << 16) | v16[j+1];
}
out:
kfree((void *)a16);
return r;
}
int _zd_iowrite32v_locked(struct zd_chip *chip, const struct zd_ioreq32 *ioreqs,
unsigned int count)
{
int i, j, r;
struct zd_ioreq16 *ioreqs16;
unsigned int count16;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
if (count == 0)
return 0;
if (count > USB_MAX_IOWRITE32_COUNT)
return -EINVAL;
/* Allocate a single memory block for values and addresses. */
count16 = 2*count;
ioreqs16 = kmalloc(count16 * sizeof(struct zd_ioreq16), GFP_KERNEL);
if (!ioreqs16) {
r = -ENOMEM;
dev_dbg_f(zd_chip_dev(chip),
"error %d in ioreqs16 allocation\n", r);
goto out;
}
for (i = 0; i < count; i++) {
j = 2*i;
/* We write the high word always first. */
ioreqs16[j].value = ioreqs[i].value >> 16;
ioreqs16[j].addr = inc_addr(ioreqs[i].addr);
ioreqs16[j+1].value = ioreqs[i].value;
ioreqs16[j+1].addr = ioreqs[i].addr;
}
r = zd_usb_iowrite16v(&chip->usb, ioreqs16, count16);
#ifdef DEBUG
if (r) {
dev_dbg_f(zd_chip_dev(chip),
"error %d in zd_usb_write16v\n", r);
}
#endif /* DEBUG */
out:
kfree(ioreqs16);
return r;
}
int zd_iowrite16a_locked(struct zd_chip *chip,
const struct zd_ioreq16 *ioreqs, unsigned int count)
{
int r;
unsigned int i, j, t, max;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
for (i = 0; i < count; i += j + t) {
t = 0;
max = count-i;
if (max > USB_MAX_IOWRITE16_COUNT)
max = USB_MAX_IOWRITE16_COUNT;
for (j = 0; j < max; j++) {
if (!ioreqs[i+j].addr) {
t = 1;
break;
}
}
r = zd_usb_iowrite16v(&chip->usb, &ioreqs[i], j);
if (r) {
dev_dbg_f(zd_chip_dev(chip),
"error zd_usb_iowrite16v. Error number %d\n",
r);
return r;
}
}
return 0;
}
/* Writes a variable number of 32 bit registers. The functions will split
* that in several USB requests. A split can be forced by inserting an IO
* request with an zero address field.
*/
int zd_iowrite32a_locked(struct zd_chip *chip,
const struct zd_ioreq32 *ioreqs, unsigned int count)
{
int r;
unsigned int i, j, t, max;
for (i = 0; i < count; i += j + t) {
t = 0;
max = count-i;
if (max > USB_MAX_IOWRITE32_COUNT)
max = USB_MAX_IOWRITE32_COUNT;
for (j = 0; j < max; j++) {
if (!ioreqs[i+j].addr) {
t = 1;
break;
}
}
r = _zd_iowrite32v_locked(chip, &ioreqs[i], j);
if (r) {
dev_dbg_f(zd_chip_dev(chip),
"error _zd_iowrite32v_locked."
" Error number %d\n", r);
return r;
}
}
return 0;
}
int zd_ioread16(struct zd_chip *chip, zd_addr_t addr, u16 *value)
{
int r;
mutex_lock(&chip->mutex);
r = zd_ioread16_locked(chip, value, addr);
mutex_unlock(&chip->mutex);
return r;
}
int zd_ioread32(struct zd_chip *chip, zd_addr_t addr, u32 *value)
{
int r;
mutex_lock(&chip->mutex);
r = zd_ioread32_locked(chip, value, addr);
mutex_unlock(&chip->mutex);
return r;
}
int zd_iowrite16(struct zd_chip *chip, zd_addr_t addr, u16 value)
{
int r;
mutex_lock(&chip->mutex);
r = zd_iowrite16_locked(chip, value, addr);
mutex_unlock(&chip->mutex);
return r;
}
int zd_iowrite32(struct zd_chip *chip, zd_addr_t addr, u32 value)
{
int r;
mutex_lock(&chip->mutex);
r = zd_iowrite32_locked(chip, value, addr);
mutex_unlock(&chip->mutex);
return r;
}
int zd_ioread32v(struct zd_chip *chip, const zd_addr_t *addresses,
u32 *values, unsigned int count)
{
int r;
mutex_lock(&chip->mutex);
r = zd_ioread32v_locked(chip, values, addresses, count);
mutex_unlock(&chip->mutex);
return r;
}
int zd_iowrite32a(struct zd_chip *chip, const struct zd_ioreq32 *ioreqs,
unsigned int count)
{
int r;
mutex_lock(&chip->mutex);
r = zd_iowrite32a_locked(chip, ioreqs, count);
mutex_unlock(&chip->mutex);
return r;
}
static int read_pod(struct zd_chip *chip, u8 *rf_type)
{
int r;
u32 value;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = zd_ioread32_locked(chip, &value, E2P_POD);
if (r)
goto error;
dev_dbg_f(zd_chip_dev(chip), "E2P_POD %#010x\n", value);
/* FIXME: AL2230 handling (Bit 7 in POD) */
*rf_type = value & 0x0f;
chip->pa_type = (value >> 16) & 0x0f;
chip->patch_cck_gain = (value >> 8) & 0x1;
chip->patch_cr157 = (value >> 13) & 0x1;
chip->patch_6m_band_edge = (value >> 21) & 0x1;
chip->new_phy_layout = (value >> 31) & 0x1;
chip->al2230s_bit = (value >> 7) & 0x1;
chip->link_led = ((value >> 4) & 1) ? LED1 : LED2;
chip->supports_tx_led = 1;
if (value & (1 << 24)) { /* LED scenario */
if (value & (1 << 29))
chip->supports_tx_led = 0;
}
dev_dbg_f(zd_chip_dev(chip),
"RF %s %#01x PA type %#01x patch CCK %d patch CR157 %d "
"patch 6M %d new PHY %d link LED%d tx led %d\n",
zd_rf_name(*rf_type), *rf_type,
chip->pa_type, chip->patch_cck_gain,
chip->patch_cr157, chip->patch_6m_band_edge,
chip->new_phy_layout,
chip->link_led == LED1 ? 1 : 2,
chip->supports_tx_led);
return 0;
error:
*rf_type = 0;
chip->pa_type = 0;
chip->patch_cck_gain = 0;
chip->patch_cr157 = 0;
chip->patch_6m_band_edge = 0;
chip->new_phy_layout = 0;
return r;
}
/* MAC address: if custom mac addresses are to be used CR_MAC_ADDR_P1 and
* CR_MAC_ADDR_P2 must be overwritten
*/
int zd_write_mac_addr(struct zd_chip *chip, const u8 *mac_addr)
{
int r;
struct zd_ioreq32 reqs[2] = {
[0] = { .addr = CR_MAC_ADDR_P1 },
[1] = { .addr = CR_MAC_ADDR_P2 },
};
if (mac_addr) {
reqs[0].value = (mac_addr[3] << 24)
| (mac_addr[2] << 16)
| (mac_addr[1] << 8)
| mac_addr[0];
reqs[1].value = (mac_addr[5] << 8)
| mac_addr[4];
dev_dbg_f(zd_chip_dev(chip), "mac addr %pM\n", mac_addr);
} else {
dev_dbg_f(zd_chip_dev(chip), "set NULL mac\n");
}
mutex_lock(&chip->mutex);
r = zd_iowrite32a_locked(chip, reqs, ARRAY_SIZE(reqs));
mutex_unlock(&chip->mutex);
return r;
}
int zd_read_regdomain(struct zd_chip *chip, u8 *regdomain)
{
int r;
u32 value;
mutex_lock(&chip->mutex);
r = zd_ioread32_locked(chip, &value, E2P_SUBID);
mutex_unlock(&chip->mutex);
if (r)
return r;
*regdomain = value >> 16;
dev_dbg_f(zd_chip_dev(chip), "regdomain: %#04x\n", *regdomain);
return 0;
}
static int read_values(struct zd_chip *chip, u8 *values, size_t count,
zd_addr_t e2p_addr, u32 guard)
{
int r;
int i;
u32 v;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
for (i = 0;;) {
r = zd_ioread32_locked(chip, &v,
(zd_addr_t)((u16)e2p_addr+i/2));
if (r)
return r;
v -= guard;
if (i+4 < count) {
values[i++] = v;
values[i++] = v >> 8;
values[i++] = v >> 16;
values[i++] = v >> 24;
continue;
}
for (;i < count; i++)
values[i] = v >> (8*(i%3));
return 0;
}
}
static int read_pwr_cal_values(struct zd_chip *chip)
{
return read_values(chip, chip->pwr_cal_values,
E2P_CHANNEL_COUNT, E2P_PWR_CAL_VALUE1,
0);
}
static int read_pwr_int_values(struct zd_chip *chip)
{
return read_values(chip, chip->pwr_int_values,
E2P_CHANNEL_COUNT, E2P_PWR_INT_VALUE1,
E2P_PWR_INT_GUARD);
}
static int read_ofdm_cal_values(struct zd_chip *chip)
{
int r;
int i;
static const zd_addr_t addresses[] = {
E2P_36M_CAL_VALUE1,
E2P_48M_CAL_VALUE1,
E2P_54M_CAL_VALUE1,
};
for (i = 0; i < 3; i++) {
r = read_values(chip, chip->ofdm_cal_values[i],
E2P_CHANNEL_COUNT, addresses[i], 0);
if (r)
return r;
}
return 0;
}
static int read_cal_int_tables(struct zd_chip *chip)
{
int r;
r = read_pwr_cal_values(chip);
if (r)
return r;
r = read_pwr_int_values(chip);
if (r)
return r;
r = read_ofdm_cal_values(chip);
if (r)
return r;
return 0;
}
/* phy means physical registers */
int zd_chip_lock_phy_regs(struct zd_chip *chip)
{
int r;
u32 tmp;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = zd_ioread32_locked(chip, &tmp, CR_REG1);
if (r) {
dev_err(zd_chip_dev(chip), "error ioread32(CR_REG1): %d\n", r);
return r;
}
tmp &= ~UNLOCK_PHY_REGS;
r = zd_iowrite32_locked(chip, tmp, CR_REG1);
if (r)
dev_err(zd_chip_dev(chip), "error iowrite32(CR_REG1): %d\n", r);
return r;
}
int zd_chip_unlock_phy_regs(struct zd_chip *chip)
{
int r;
u32 tmp;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = zd_ioread32_locked(chip, &tmp, CR_REG1);
if (r) {
dev_err(zd_chip_dev(chip),
"error ioread32(CR_REG1): %d\n", r);
return r;
}
tmp |= UNLOCK_PHY_REGS;
r = zd_iowrite32_locked(chip, tmp, CR_REG1);
if (r)
dev_err(zd_chip_dev(chip), "error iowrite32(CR_REG1): %d\n", r);
return r;
}
/* CR157 can be optionally patched by the EEPROM for original ZD1211 */
static int patch_cr157(struct zd_chip *chip)
{
int r;
u16 value;
if (!chip->patch_cr157)
return 0;
r = zd_ioread16_locked(chip, &value, E2P_PHY_REG);
if (r)
return r;
dev_dbg_f(zd_chip_dev(chip), "patching value %x\n", value >> 8);
return zd_iowrite32_locked(chip, value >> 8, CR157);
}
/*
* 6M band edge can be optionally overwritten for certain RF's
* Vendor driver says: for FCC regulation, enabled per HWFeature 6M band edge
* bit (for AL2230, AL2230S)
*/
static int patch_6m_band_edge(struct zd_chip *chip, u8 channel)
{
ZD_ASSERT(mutex_is_locked(&chip->mutex));
if (!chip->patch_6m_band_edge)
return 0;
return zd_rf_patch_6m_band_edge(&chip->rf, channel);
}
/* Generic implementation of 6M band edge patching, used by most RFs via
* zd_rf_generic_patch_6m() */
int zd_chip_generic_patch_6m_band(struct zd_chip *chip, int channel)
{
struct zd_ioreq16 ioreqs[] = {
{ CR128, 0x14 }, { CR129, 0x12 }, { CR130, 0x10 },
{ CR47, 0x1e },
};
/* FIXME: Channel 11 is not the edge for all regulatory domains. */
if (channel == 1 || channel == 11)
ioreqs[0].value = 0x12;
dev_dbg_f(zd_chip_dev(chip), "patching for channel %d\n", channel);
return zd_iowrite16a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
}
static int zd1211_hw_reset_phy(struct zd_chip *chip)
{
static const struct zd_ioreq16 ioreqs[] = {
{ CR0, 0x0a }, { CR1, 0x06 }, { CR2, 0x26 },
{ CR3, 0x38 }, { CR4, 0x80 }, { CR9, 0xa0 },
{ CR10, 0x81 }, { CR11, 0x00 }, { CR12, 0x7f },
{ CR13, 0x8c }, { CR14, 0x80 }, { CR15, 0x3d },
{ CR16, 0x20 }, { CR17, 0x1e }, { CR18, 0x0a },
{ CR19, 0x48 }, { CR20, 0x0c }, { CR21, 0x0c },
{ CR22, 0x23 }, { CR23, 0x90 }, { CR24, 0x14 },
{ CR25, 0x40 }, { CR26, 0x10 }, { CR27, 0x19 },
{ CR28, 0x7f }, { CR29, 0x80 }, { CR30, 0x4b },
{ CR31, 0x60 }, { CR32, 0x43 }, { CR33, 0x08 },
{ CR34, 0x06 }, { CR35, 0x0a }, { CR36, 0x00 },
{ CR37, 0x00 }, { CR38, 0x38 }, { CR39, 0x0c },
{ CR40, 0x84 }, { CR41, 0x2a }, { CR42, 0x80 },
{ CR43, 0x10 }, { CR44, 0x12 }, { CR46, 0xff },
{ CR47, 0x1E }, { CR48, 0x26 }, { CR49, 0x5b },
{ CR64, 0xd0 }, { CR65, 0x04 }, { CR66, 0x58 },
{ CR67, 0xc9 }, { CR68, 0x88 }, { CR69, 0x41 },
{ CR70, 0x23 }, { CR71, 0x10 }, { CR72, 0xff },
{ CR73, 0x32 }, { CR74, 0x30 }, { CR75, 0x65 },
{ CR76, 0x41 }, { CR77, 0x1b }, { CR78, 0x30 },
{ CR79, 0x68 }, { CR80, 0x64 }, { CR81, 0x64 },
{ CR82, 0x00 }, { CR83, 0x00 }, { CR84, 0x00 },
{ CR85, 0x02 }, { CR86, 0x00 }, { CR87, 0x00 },
{ CR88, 0xff }, { CR89, 0xfc }, { CR90, 0x00 },
{ CR91, 0x00 }, { CR92, 0x00 }, { CR93, 0x08 },
{ CR94, 0x00 }, { CR95, 0x00 }, { CR96, 0xff },
{ CR97, 0xe7 }, { CR98, 0x00 }, { CR99, 0x00 },
{ CR100, 0x00 }, { CR101, 0xae }, { CR102, 0x02 },
{ CR103, 0x00 }, { CR104, 0x03 }, { CR105, 0x65 },
{ CR106, 0x04 }, { CR107, 0x00 }, { CR108, 0x0a },
{ CR109, 0xaa }, { CR110, 0xaa }, { CR111, 0x25 },
{ CR112, 0x25 }, { CR113, 0x00 }, { CR119, 0x1e },
{ CR125, 0x90 }, { CR126, 0x00 }, { CR127, 0x00 },
{ },
{ CR5, 0x00 }, { CR6, 0x00 }, { CR7, 0x00 },
{ CR8, 0x00 }, { CR9, 0x20 }, { CR12, 0xf0 },
{ CR20, 0x0e }, { CR21, 0x0e }, { CR27, 0x10 },
{ CR44, 0x33 }, { CR47, 0x1E }, { CR83, 0x24 },
{ CR84, 0x04 }, { CR85, 0x00 }, { CR86, 0x0C },
{ CR87, 0x12 }, { CR88, 0x0C }, { CR89, 0x00 },
{ CR90, 0x10 }, { CR91, 0x08 }, { CR93, 0x00 },
{ CR94, 0x01 }, { CR95, 0x00 }, { CR96, 0x50 },
{ CR97, 0x37 }, { CR98, 0x35 }, { CR101, 0x13 },
{ CR102, 0x27 }, { CR103, 0x27 }, { CR104, 0x18 },
{ CR105, 0x12 }, { CR109, 0x27 }, { CR110, 0x27 },
{ CR111, 0x27 }, { CR112, 0x27 }, { CR113, 0x27 },
{ CR114, 0x27 }, { CR115, 0x26 }, { CR116, 0x24 },
{ CR117, 0xfc }, { CR118, 0xfa }, { CR120, 0x4f },
{ CR125, 0xaa }, { CR127, 0x03 }, { CR128, 0x14 },
{ CR129, 0x12 }, { CR130, 0x10 }, { CR131, 0x0C },
{ CR136, 0xdf }, { CR137, 0x40 }, { CR138, 0xa0 },
{ CR139, 0xb0 }, { CR140, 0x99 }, { CR141, 0x82 },
{ CR142, 0x54 }, { CR143, 0x1c }, { CR144, 0x6c },
{ CR147, 0x07 }, { CR148, 0x4c }, { CR149, 0x50 },
{ CR150, 0x0e }, { CR151, 0x18 }, { CR160, 0xfe },
{ CR161, 0xee }, { CR162, 0xaa }, { CR163, 0xfa },
{ CR164, 0xfa }, { CR165, 0xea }, { CR166, 0xbe },
{ CR167, 0xbe }, { CR168, 0x6a }, { CR169, 0xba },
{ CR170, 0xba }, { CR171, 0xba },
/* Note: CR204 must lead the CR203 */
{ CR204, 0x7d },
{ },
{ CR203, 0x30 },
};
int r, t;
dev_dbg_f(zd_chip_dev(chip), "\n");
r = zd_chip_lock_phy_regs(chip);
if (r)
goto out;
r = zd_iowrite16a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
if (r)
goto unlock;
r = patch_cr157(chip);
unlock:
t = zd_chip_unlock_phy_regs(chip);
if (t && !r)
r = t;
out:
return r;
}
static int zd1211b_hw_reset_phy(struct zd_chip *chip)
{
static const struct zd_ioreq16 ioreqs[] = {
{ CR0, 0x14 }, { CR1, 0x06 }, { CR2, 0x26 },
{ CR3, 0x38 }, { CR4, 0x80 }, { CR9, 0xe0 },
{ CR10, 0x81 },
/* power control { { CR11, 1 << 6 }, */
{ CR11, 0x00 },
{ CR12, 0xf0 }, { CR13, 0x8c }, { CR14, 0x80 },
{ CR15, 0x3d }, { CR16, 0x20 }, { CR17, 0x1e },
{ CR18, 0x0a }, { CR19, 0x48 },
{ CR20, 0x10 }, /* Org:0x0E, ComTrend:RalLink AP */
{ CR21, 0x0e }, { CR22, 0x23 }, { CR23, 0x90 },
{ CR24, 0x14 }, { CR25, 0x40 }, { CR26, 0x10 },
{ CR27, 0x10 }, { CR28, 0x7f }, { CR29, 0x80 },
{ CR30, 0x4b }, /* ASIC/FWT, no jointly decoder */
{ CR31, 0x60 }, { CR32, 0x43 }, { CR33, 0x08 },
{ CR34, 0x06 }, { CR35, 0x0a }, { CR36, 0x00 },
{ CR37, 0x00 }, { CR38, 0x38 }, { CR39, 0x0c },
{ CR40, 0x84 }, { CR41, 0x2a }, { CR42, 0x80 },
{ CR43, 0x10 }, { CR44, 0x33 }, { CR46, 0xff },
{ CR47, 0x1E }, { CR48, 0x26 }, { CR49, 0x5b },
{ CR64, 0xd0 }, { CR65, 0x04 }, { CR66, 0x58 },
{ CR67, 0xc9 }, { CR68, 0x88 }, { CR69, 0x41 },
{ CR70, 0x23 }, { CR71, 0x10 }, { CR72, 0xff },
{ CR73, 0x32 }, { CR74, 0x30 }, { CR75, 0x65 },
{ CR76, 0x41 }, { CR77, 0x1b }, { CR78, 0x30 },
{ CR79, 0xf0 }, { CR80, 0x64 }, { CR81, 0x64 },
{ CR82, 0x00 }, { CR83, 0x24 }, { CR84, 0x04 },
{ CR85, 0x00 }, { CR86, 0x0c }, { CR87, 0x12 },
{ CR88, 0x0c }, { CR89, 0x00 }, { CR90, 0x58 },
{ CR91, 0x04 }, { CR92, 0x00 }, { CR93, 0x00 },
{ CR94, 0x01 },
{ CR95, 0x20 }, /* ZD1211B */
{ CR96, 0x50 }, { CR97, 0x37 }, { CR98, 0x35 },
{ CR99, 0x00 }, { CR100, 0x01 }, { CR101, 0x13 },
{ CR102, 0x27 }, { CR103, 0x27 }, { CR104, 0x18 },
{ CR105, 0x12 }, { CR106, 0x04 }, { CR107, 0x00 },
{ CR108, 0x0a }, { CR109, 0x27 }, { CR110, 0x27 },
{ CR111, 0x27 }, { CR112, 0x27 }, { CR113, 0x27 },
{ CR114, 0x27 }, { CR115, 0x26 }, { CR116, 0x24 },
{ CR117, 0xfc }, { CR118, 0xfa }, { CR119, 0x1e },
{ CR125, 0x90 }, { CR126, 0x00 }, { CR127, 0x00 },
{ CR128, 0x14 }, { CR129, 0x12 }, { CR130, 0x10 },
{ CR131, 0x0c }, { CR136, 0xdf }, { CR137, 0xa0 },
{ CR138, 0xa8 }, { CR139, 0xb4 }, { CR140, 0x98 },
{ CR141, 0x82 }, { CR142, 0x53 }, { CR143, 0x1c },
{ CR144, 0x6c }, { CR147, 0x07 }, { CR148, 0x40 },
{ CR149, 0x40 }, /* Org:0x50 ComTrend:RalLink AP */
{ CR150, 0x14 }, /* Org:0x0E ComTrend:RalLink AP */
{ CR151, 0x18 }, { CR159, 0x70 }, { CR160, 0xfe },
{ CR161, 0xee }, { CR162, 0xaa }, { CR163, 0xfa },
{ CR164, 0xfa }, { CR165, 0xea }, { CR166, 0xbe },
{ CR167, 0xbe }, { CR168, 0x6a }, { CR169, 0xba },
{ CR170, 0xba }, { CR171, 0xba },
/* Note: CR204 must lead the CR203 */
{ CR204, 0x7d },
{},
{ CR203, 0x30 },
};
int r, t;
dev_dbg_f(zd_chip_dev(chip), "\n");
r = zd_chip_lock_phy_regs(chip);
if (r)
goto out;
r = zd_iowrite16a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
t = zd_chip_unlock_phy_regs(chip);
if (t && !r)
r = t;
out:
return r;
}
static int hw_reset_phy(struct zd_chip *chip)
{
return zd_chip_is_zd1211b(chip) ? zd1211b_hw_reset_phy(chip) :
zd1211_hw_reset_phy(chip);
}
static int zd1211_hw_init_hmac(struct zd_chip *chip)
{
static const struct zd_ioreq32 ioreqs[] = {
{ CR_ZD1211_RETRY_MAX, ZD1211_RETRY_COUNT },
{ CR_RX_THRESHOLD, 0x000c0640 },
};
dev_dbg_f(zd_chip_dev(chip), "\n");
ZD_ASSERT(mutex_is_locked(&chip->mutex));
return zd_iowrite32a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
}
static int zd1211b_hw_init_hmac(struct zd_chip *chip)
{
static const struct zd_ioreq32 ioreqs[] = {
{ CR_ZD1211B_RETRY_MAX, ZD1211B_RETRY_COUNT },
{ CR_ZD1211B_CWIN_MAX_MIN_AC0, 0x007f003f },
{ CR_ZD1211B_CWIN_MAX_MIN_AC1, 0x007f003f },
{ CR_ZD1211B_CWIN_MAX_MIN_AC2, 0x003f001f },
{ CR_ZD1211B_CWIN_MAX_MIN_AC3, 0x001f000f },
{ CR_ZD1211B_AIFS_CTL1, 0x00280028 },
{ CR_ZD1211B_AIFS_CTL2, 0x008C003C },
{ CR_ZD1211B_TXOP, 0x01800824 },
{ CR_RX_THRESHOLD, 0x000c0eff, },
};
dev_dbg_f(zd_chip_dev(chip), "\n");
ZD_ASSERT(mutex_is_locked(&chip->mutex));
return zd_iowrite32a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
}
static int hw_init_hmac(struct zd_chip *chip)
{
int r;
static const struct zd_ioreq32 ioreqs[] = {
{ CR_ACK_TIMEOUT_EXT, 0x20 },
{ CR_ADDA_MBIAS_WARMTIME, 0x30000808 },
{ CR_SNIFFER_ON, 0 },
{ CR_RX_FILTER, STA_RX_FILTER },
{ CR_GROUP_HASH_P1, 0x00 },
{ CR_GROUP_HASH_P2, 0x80000000 },
{ CR_REG1, 0xa4 },
{ CR_ADDA_PWR_DWN, 0x7f },
{ CR_BCN_PLCP_CFG, 0x00f00401 },
{ CR_PHY_DELAY, 0x00 },
{ CR_ACK_TIMEOUT_EXT, 0x80 },
{ CR_ADDA_PWR_DWN, 0x00 },
{ CR_ACK_TIME_80211, 0x100 },
{ CR_RX_PE_DELAY, 0x70 },
{ CR_PS_CTRL, 0x10000000 },
{ CR_RTS_CTS_RATE, 0x02030203 },
{ CR_AFTER_PNP, 0x1 },
{ CR_WEP_PROTECT, 0x114 },
{ CR_IFS_VALUE, IFS_VALUE_DEFAULT },
{ CR_CAM_MODE, MODE_AP_WDS},
};
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = zd_iowrite32a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
if (r)
return r;
return zd_chip_is_zd1211b(chip) ?
zd1211b_hw_init_hmac(chip) : zd1211_hw_init_hmac(chip);
}
struct aw_pt_bi {
u32 atim_wnd_period;
u32 pre_tbtt;
u32 beacon_interval;
};
static int get_aw_pt_bi(struct zd_chip *chip, struct aw_pt_bi *s)
{
int r;
static const zd_addr_t aw_pt_bi_addr[] =
{ CR_ATIM_WND_PERIOD, CR_PRE_TBTT, CR_BCN_INTERVAL };
u32 values[3];
r = zd_ioread32v_locked(chip, values, (const zd_addr_t *)aw_pt_bi_addr,
ARRAY_SIZE(aw_pt_bi_addr));
if (r) {
memset(s, 0, sizeof(*s));
return r;
}
s->atim_wnd_period = values[0];
s->pre_tbtt = values[1];
s->beacon_interval = values[2];
return 0;
}
static int set_aw_pt_bi(struct zd_chip *chip, struct aw_pt_bi *s)
{
struct zd_ioreq32 reqs[3];
if (s->beacon_interval <= 5)
s->beacon_interval = 5;
if (s->pre_tbtt < 4 || s->pre_tbtt >= s->beacon_interval)
s->pre_tbtt = s->beacon_interval - 1;
if (s->atim_wnd_period >= s->pre_tbtt)
s->atim_wnd_period = s->pre_tbtt - 1;
reqs[0].addr = CR_ATIM_WND_PERIOD;
reqs[0].value = s->atim_wnd_period;
reqs[1].addr = CR_PRE_TBTT;
reqs[1].value = s->pre_tbtt;
reqs[2].addr = CR_BCN_INTERVAL;
reqs[2].value = s->beacon_interval;
return zd_iowrite32a_locked(chip, reqs, ARRAY_SIZE(reqs));
}
static int set_beacon_interval(struct zd_chip *chip, u32 interval)
{
int r;
struct aw_pt_bi s;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = get_aw_pt_bi(chip, &s);
if (r)
return r;
s.beacon_interval = interval;
return set_aw_pt_bi(chip, &s);
}
int zd_set_beacon_interval(struct zd_chip *chip, u32 interval)
{
int r;
mutex_lock(&chip->mutex);
r = set_beacon_interval(chip, interval);
mutex_unlock(&chip->mutex);
return r;
}
static int hw_init(struct zd_chip *chip)
{
int r;
dev_dbg_f(zd_chip_dev(chip), "\n");
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = hw_reset_phy(chip);
if (r)
return r;
r = hw_init_hmac(chip);
if (r)
return r;
return set_beacon_interval(chip, 100);
}
static zd_addr_t fw_reg_addr(struct zd_chip *chip, u16 offset)
{
return (zd_addr_t)((u16)chip->fw_regs_base + offset);
}
#ifdef DEBUG
static int dump_cr(struct zd_chip *chip, const zd_addr_t addr,
const char *addr_string)
{
int r;
u32 value;
r = zd_ioread32_locked(chip, &value, addr);
if (r) {
dev_dbg_f(zd_chip_dev(chip),
"error reading %s. Error number %d\n", addr_string, r);
return r;
}
dev_dbg_f(zd_chip_dev(chip), "%s %#010x\n",
addr_string, (unsigned int)value);
return 0;
}
static int test_init(struct zd_chip *chip)
{
int r;
r = dump_cr(chip, CR_AFTER_PNP, "CR_AFTER_PNP");
if (r)
return r;
r = dump_cr(chip, CR_GPI_EN, "CR_GPI_EN");
if (r)
return r;
return dump_cr(chip, CR_INTERRUPT, "CR_INTERRUPT");
}
static void dump_fw_registers(struct zd_chip *chip)
{
const zd_addr_t addr[4] = {
fw_reg_addr(chip, FW_REG_FIRMWARE_VER),
fw_reg_addr(chip, FW_REG_USB_SPEED),
fw_reg_addr(chip, FW_REG_FIX_TX_RATE),
fw_reg_addr(chip, FW_REG_LED_LINK_STATUS),
};
int r;
u16 values[4];
r = zd_ioread16v_locked(chip, values, (const zd_addr_t*)addr,
ARRAY_SIZE(addr));
if (r) {
dev_dbg_f(zd_chip_dev(chip), "error %d zd_ioread16v_locked\n",
r);
return;
}
dev_dbg_f(zd_chip_dev(chip), "FW_FIRMWARE_VER %#06hx\n", values[0]);
dev_dbg_f(zd_chip_dev(chip), "FW_USB_SPEED %#06hx\n", values[1]);
dev_dbg_f(zd_chip_dev(chip), "FW_FIX_TX_RATE %#06hx\n", values[2]);
dev_dbg_f(zd_chip_dev(chip), "FW_LINK_STATUS %#06hx\n", values[3]);
}
#endif /* DEBUG */
static int print_fw_version(struct zd_chip *chip)
{
int r;
u16 version;
r = zd_ioread16_locked(chip, &version,
fw_reg_addr(chip, FW_REG_FIRMWARE_VER));
if (r)
return r;
dev_info(zd_chip_dev(chip),"firmware version %04hx\n", version);
return 0;
}
static int set_mandatory_rates(struct zd_chip *chip, int gmode)
{
u32 rates;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
/* This sets the mandatory rates, which only depend from the standard
* that the device is supporting. Until further notice we should try
* to support 802.11g also for full speed USB.
*/
if (!gmode)
rates = CR_RATE_1M|CR_RATE_2M|CR_RATE_5_5M|CR_RATE_11M;
else
rates = CR_RATE_1M|CR_RATE_2M|CR_RATE_5_5M|CR_RATE_11M|
CR_RATE_6M|CR_RATE_12M|CR_RATE_24M;
return zd_iowrite32_locked(chip, rates, CR_MANDATORY_RATE_TBL);
}
int zd_chip_set_rts_cts_rate_locked(struct zd_chip *chip,
int preamble)
{
u32 value = 0;
dev_dbg_f(zd_chip_dev(chip), "preamble=%x\n", preamble);
value |= preamble << RTSCTS_SH_RTS_PMB_TYPE;
value |= preamble << RTSCTS_SH_CTS_PMB_TYPE;
/* We always send 11M RTS/self-CTS messages, like the vendor driver. */
value |= ZD_PURE_RATE(ZD_CCK_RATE_11M) << RTSCTS_SH_RTS_RATE;
value |= ZD_RX_CCK << RTSCTS_SH_RTS_MOD_TYPE;
value |= ZD_PURE_RATE(ZD_CCK_RATE_11M) << RTSCTS_SH_CTS_RATE;
value |= ZD_RX_CCK << RTSCTS_SH_CTS_MOD_TYPE;
return zd_iowrite32_locked(chip, value, CR_RTS_CTS_RATE);
}
int zd_chip_enable_hwint(struct zd_chip *chip)
{
int r;
mutex_lock(&chip->mutex);
r = zd_iowrite32_locked(chip, HWINT_ENABLED, CR_INTERRUPT);
mutex_unlock(&chip->mutex);
return r;
}
static int disable_hwint(struct zd_chip *chip)
{
return zd_iowrite32_locked(chip, HWINT_DISABLED, CR_INTERRUPT);
}
int zd_chip_disable_hwint(struct zd_chip *chip)
{
int r;
mutex_lock(&chip->mutex);
r = disable_hwint(chip);
mutex_unlock(&chip->mutex);
return r;
}
static int read_fw_regs_offset(struct zd_chip *chip)
{
int r;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = zd_ioread16_locked(chip, (u16*)&chip->fw_regs_base,
FWRAW_REGS_ADDR);
if (r)
return r;
dev_dbg_f(zd_chip_dev(chip), "fw_regs_base: %#06hx\n",
(u16)chip->fw_regs_base);
return 0;
}
/* Read mac address using pre-firmware interface */
int zd_chip_read_mac_addr_fw(struct zd_chip *chip, u8 *addr)
{
dev_dbg_f(zd_chip_dev(chip), "\n");
return zd_usb_read_fw(&chip->usb, E2P_MAC_ADDR_P1, addr,
ETH_ALEN);
}
int zd_chip_init_hw(struct zd_chip *chip)
{
int r;
u8 rf_type;
dev_dbg_f(zd_chip_dev(chip), "\n");
mutex_lock(&chip->mutex);
#ifdef DEBUG
r = test_init(chip);
if (r)
goto out;
#endif
r = zd_iowrite32_locked(chip, 1, CR_AFTER_PNP);
if (r)
goto out;
r = read_fw_regs_offset(chip);
if (r)
goto out;
/* GPI is always disabled, also in the other driver.
*/
r = zd_iowrite32_locked(chip, 0, CR_GPI_EN);
if (r)
goto out;
r = zd_iowrite32_locked(chip, CWIN_SIZE, CR_CWMIN_CWMAX);
if (r)
goto out;
/* Currently we support IEEE 802.11g for full and high speed USB.
* It might be discussed, whether we should suppport pure b mode for
* full speed USB.
*/
r = set_mandatory_rates(chip, 1);
if (r)
goto out;
/* Disabling interrupts is certainly a smart thing here.
*/
r = disable_hwint(chip);
if (r)
goto out;
r = read_pod(chip, &rf_type);
if (r)
goto out;
r = hw_init(chip);
if (r)
goto out;
r = zd_rf_init_hw(&chip->rf, rf_type);
if (r)
goto out;
r = print_fw_version(chip);
if (r)
goto out;
#ifdef DEBUG
dump_fw_registers(chip);
r = test_init(chip);
if (r)
goto out;
#endif /* DEBUG */
r = read_cal_int_tables(chip);
if (r)
goto out;
print_id(chip);
out:
mutex_unlock(&chip->mutex);
return r;
}
static int update_pwr_int(struct zd_chip *chip, u8 channel)
{
u8 value = chip->pwr_int_values[channel - 1];
return zd_iowrite16_locked(chip, value, CR31);
}
static int update_pwr_cal(struct zd_chip *chip, u8 channel)
{
u8 value = chip->pwr_cal_values[channel-1];
return zd_iowrite16_locked(chip, value, CR68);
}
static int update_ofdm_cal(struct zd_chip *chip, u8 channel)
{
struct zd_ioreq16 ioreqs[3];
ioreqs[0].addr = CR67;
ioreqs[0].value = chip->ofdm_cal_values[OFDM_36M_INDEX][channel-1];
ioreqs[1].addr = CR66;
ioreqs[1].value = chip->ofdm_cal_values[OFDM_48M_INDEX][channel-1];
ioreqs[2].addr = CR65;
ioreqs[2].value = chip->ofdm_cal_values[OFDM_54M_INDEX][channel-1];
return zd_iowrite16a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
}
static int update_channel_integration_and_calibration(struct zd_chip *chip,
u8 channel)
{
int r;
if (!zd_rf_should_update_pwr_int(&chip->rf))
return 0;
r = update_pwr_int(chip, channel);
if (r)
return r;
if (zd_chip_is_zd1211b(chip)) {
static const struct zd_ioreq16 ioreqs[] = {
{ CR69, 0x28 },
{},
{ CR69, 0x2a },
};
r = update_ofdm_cal(chip, channel);
if (r)
return r;
r = update_pwr_cal(chip, channel);
if (r)
return r;
r = zd_iowrite16a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
if (r)
return r;
}
return 0;
}
/* The CCK baseband gain can be optionally patched by the EEPROM */
static int patch_cck_gain(struct zd_chip *chip)
{
int r;
u32 value;
if (!chip->patch_cck_gain || !zd_rf_should_patch_cck_gain(&chip->rf))
return 0;
ZD_ASSERT(mutex_is_locked(&chip->mutex));
r = zd_ioread32_locked(chip, &value, E2P_PHY_REG);
if (r)
return r;
dev_dbg_f(zd_chip_dev(chip), "patching value %x\n", value & 0xff);
return zd_iowrite16_locked(chip, value & 0xff, CR47);
}
int zd_chip_set_channel(struct zd_chip *chip, u8 channel)
{
int r, t;
mutex_lock(&chip->mutex);
r = zd_chip_lock_phy_regs(chip);
if (r)
goto out;
r = zd_rf_set_channel(&chip->rf, channel);
if (r)
goto unlock;
r = update_channel_integration_and_calibration(chip, channel);
if (r)
goto unlock;
r = patch_cck_gain(chip);
if (r)
goto unlock;
r = patch_6m_band_edge(chip, channel);
if (r)
goto unlock;
r = zd_iowrite32_locked(chip, 0, CR_CONFIG_PHILIPS);
unlock:
t = zd_chip_unlock_phy_regs(chip);
if (t && !r)
r = t;
out:
mutex_unlock(&chip->mutex);
return r;
}
u8 zd_chip_get_channel(struct zd_chip *chip)
{
u8 channel;
mutex_lock(&chip->mutex);
channel = chip->rf.channel;
mutex_unlock(&chip->mutex);
return channel;
}
int zd_chip_control_leds(struct zd_chip *chip, enum led_status status)
{
const zd_addr_t a[] = {
fw_reg_addr(chip, FW_REG_LED_LINK_STATUS),
CR_LED,
};
int r;
u16 v[ARRAY_SIZE(a)];
struct zd_ioreq16 ioreqs[ARRAY_SIZE(a)] = {
[0] = { fw_reg_addr(chip, FW_REG_LED_LINK_STATUS) },
[1] = { CR_LED },
};
u16 other_led;
mutex_lock(&chip->mutex);
r = zd_ioread16v_locked(chip, v, (const zd_addr_t *)a, ARRAY_SIZE(a));
if (r)
goto out;
other_led = chip->link_led == LED1 ? LED2 : LED1;
switch (status) {
case ZD_LED_OFF:
ioreqs[0].value = FW_LINK_OFF;
ioreqs[1].value = v[1] & ~(LED1|LED2);
break;
case ZD_LED_SCANNING:
ioreqs[0].value = FW_LINK_OFF;
ioreqs[1].value = v[1] & ~other_led;
if (get_seconds() % 3 == 0) {
ioreqs[1].value &= ~chip->link_led;
} else {
ioreqs[1].value |= chip->link_led;
}
break;
case ZD_LED_ASSOCIATED:
ioreqs[0].value = FW_LINK_TX;
ioreqs[1].value = v[1] & ~other_led;
ioreqs[1].value |= chip->link_led;
break;
default:
r = -EINVAL;
goto out;
}
if (v[0] != ioreqs[0].value || v[1] != ioreqs[1].value) {
r = zd_iowrite16a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
if (r)
goto out;
}
r = 0;
out:
mutex_unlock(&chip->mutex);
return r;
}
int zd_chip_set_basic_rates(struct zd_chip *chip, u16 cr_rates)
{
int r;
if (cr_rates & ~(CR_RATES_80211B|CR_RATES_80211G))
return -EINVAL;
mutex_lock(&chip->mutex);
r = zd_iowrite32_locked(chip, cr_rates, CR_BASIC_RATE_TBL);
mutex_unlock(&chip->mutex);
return r;
}
static inline u8 zd_rate_from_ofdm_plcp_header(const void *rx_frame)
{
return ZD_OFDM | zd_ofdm_plcp_header_rate(rx_frame);
}
/**
* zd_rx_rate - report zd-rate
* @rx_frame - received frame
* @rx_status - rx_status as given by the device
*
* This function converts the rate as encoded in the received packet to the
* zd-rate, we are using on other places in the driver.
*/
u8 zd_rx_rate(const void *rx_frame, const struct rx_status *status)
{
u8 zd_rate;
if (status->frame_status & ZD_RX_OFDM) {
zd_rate = zd_rate_from_ofdm_plcp_header(rx_frame);
} else {
switch (zd_cck_plcp_header_signal(rx_frame)) {
case ZD_CCK_PLCP_SIGNAL_1M:
zd_rate = ZD_CCK_RATE_1M;
break;
case ZD_CCK_PLCP_SIGNAL_2M:
zd_rate = ZD_CCK_RATE_2M;
break;
case ZD_CCK_PLCP_SIGNAL_5M5:
zd_rate = ZD_CCK_RATE_5_5M;
break;
case ZD_CCK_PLCP_SIGNAL_11M:
zd_rate = ZD_CCK_RATE_11M;
break;
default:
zd_rate = 0;
}
}
return zd_rate;
}
int zd_chip_switch_radio_on(struct zd_chip *chip)
{
int r;
mutex_lock(&chip->mutex);
r = zd_switch_radio_on(&chip->rf);
mutex_unlock(&chip->mutex);
return r;
}
int zd_chip_switch_radio_off(struct zd_chip *chip)
{
int r;
mutex_lock(&chip->mutex);
r = zd_switch_radio_off(&chip->rf);
mutex_unlock(&chip->mutex);
return r;
}
int zd_chip_enable_int(struct zd_chip *chip)
{
int r;
mutex_lock(&chip->mutex);
r = zd_usb_enable_int(&chip->usb);
mutex_unlock(&chip->mutex);
return r;
}
void zd_chip_disable_int(struct zd_chip *chip)
{
mutex_lock(&chip->mutex);
zd_usb_disable_int(&chip->usb);
mutex_unlock(&chip->mutex);
}
int zd_chip_enable_rxtx(struct zd_chip *chip)
{
int r;
mutex_lock(&chip->mutex);
zd_usb_enable_tx(&chip->usb);
r = zd_usb_enable_rx(&chip->usb);
mutex_unlock(&chip->mutex);
return r;
}
void zd_chip_disable_rxtx(struct zd_chip *chip)
{
mutex_lock(&chip->mutex);
zd_usb_disable_rx(&chip->usb);
zd_usb_disable_tx(&chip->usb);
mutex_unlock(&chip->mutex);
}
int zd_rfwritev_locked(struct zd_chip *chip,
const u32* values, unsigned int count, u8 bits)
{
int r;
unsigned int i;
for (i = 0; i < count; i++) {
r = zd_rfwrite_locked(chip, values[i], bits);
if (r)
return r;
}
return 0;
}
/*
* We can optionally program the RF directly through CR regs, if supported by
* the hardware. This is much faster than the older method.
*/
int zd_rfwrite_cr_locked(struct zd_chip *chip, u32 value)
{
struct zd_ioreq16 ioreqs[] = {
{ CR244, (value >> 16) & 0xff },
{ CR243, (value >> 8) & 0xff },
{ CR242, value & 0xff },
};
ZD_ASSERT(mutex_is_locked(&chip->mutex));
return zd_iowrite16a_locked(chip, ioreqs, ARRAY_SIZE(ioreqs));
}
int zd_rfwritev_cr_locked(struct zd_chip *chip,
const u32 *values, unsigned int count)
{
int r;
unsigned int i;
for (i = 0; i < count; i++) {
r = zd_rfwrite_cr_locked(chip, values[i]);
if (r)
return r;
}
return 0;
}
int zd_chip_set_multicast_hash(struct zd_chip *chip,
struct zd_mc_hash *hash)
{
struct zd_ioreq32 ioreqs[] = {
{ CR_GROUP_HASH_P1, hash->low },
{ CR_GROUP_HASH_P2, hash->high },
};
return zd_iowrite32a(chip, ioreqs, ARRAY_SIZE(ioreqs));
}
u64 zd_chip_get_tsf(struct zd_chip *chip)
{
int r;
static const zd_addr_t aw_pt_bi_addr[] =
{ CR_TSF_LOW_PART, CR_TSF_HIGH_PART };
u32 values[2];
u64 tsf;
mutex_lock(&chip->mutex);
r = zd_ioread32v_locked(chip, values, (const zd_addr_t *)aw_pt_bi_addr,
ARRAY_SIZE(aw_pt_bi_addr));
mutex_unlock(&chip->mutex);
if (r)
return 0;
tsf = values[1];
tsf = (tsf << 32) | values[0];
return tsf;
}