linux_dsm_epyc7002/drivers/net/wireless/zd1211rw/zd_mac.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

1216 lines
32 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>
* Copyright (C) 2006-2007 Michael Wu <flamingice@sourmilk.net>
* Copyright (C) 2007-2008 Luis R. Rodriguez <mcgrof@winlab.rutgers.edu>
*
* 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
*/
#include <linux/netdevice.h>
#include <linux/etherdevice.h>
#include <linux/slab.h>
#include <linux/usb.h>
#include <linux/jiffies.h>
#include <net/ieee80211_radiotap.h>
#include "zd_def.h"
#include "zd_chip.h"
#include "zd_mac.h"
#include "zd_rf.h"
struct zd_reg_alpha2_map {
u32 reg;
char alpha2[2];
};
static struct zd_reg_alpha2_map reg_alpha2_map[] = {
{ ZD_REGDOMAIN_FCC, "US" },
{ ZD_REGDOMAIN_IC, "CA" },
{ ZD_REGDOMAIN_ETSI, "DE" }, /* Generic ETSI, use most restrictive */
{ ZD_REGDOMAIN_JAPAN, "JP" },
{ ZD_REGDOMAIN_JAPAN_ADD, "JP" },
{ ZD_REGDOMAIN_SPAIN, "ES" },
{ ZD_REGDOMAIN_FRANCE, "FR" },
};
/* This table contains the hardware specific values for the modulation rates. */
static const struct ieee80211_rate zd_rates[] = {
{ .bitrate = 10,
.hw_value = ZD_CCK_RATE_1M, },
{ .bitrate = 20,
.hw_value = ZD_CCK_RATE_2M,
.hw_value_short = ZD_CCK_RATE_2M | ZD_CCK_PREA_SHORT,
.flags = IEEE80211_RATE_SHORT_PREAMBLE },
{ .bitrate = 55,
.hw_value = ZD_CCK_RATE_5_5M,
.hw_value_short = ZD_CCK_RATE_5_5M | ZD_CCK_PREA_SHORT,
.flags = IEEE80211_RATE_SHORT_PREAMBLE },
{ .bitrate = 110,
.hw_value = ZD_CCK_RATE_11M,
.hw_value_short = ZD_CCK_RATE_11M | ZD_CCK_PREA_SHORT,
.flags = IEEE80211_RATE_SHORT_PREAMBLE },
{ .bitrate = 60,
.hw_value = ZD_OFDM_RATE_6M,
.flags = 0 },
{ .bitrate = 90,
.hw_value = ZD_OFDM_RATE_9M,
.flags = 0 },
{ .bitrate = 120,
.hw_value = ZD_OFDM_RATE_12M,
.flags = 0 },
{ .bitrate = 180,
.hw_value = ZD_OFDM_RATE_18M,
.flags = 0 },
{ .bitrate = 240,
.hw_value = ZD_OFDM_RATE_24M,
.flags = 0 },
{ .bitrate = 360,
.hw_value = ZD_OFDM_RATE_36M,
.flags = 0 },
{ .bitrate = 480,
.hw_value = ZD_OFDM_RATE_48M,
.flags = 0 },
{ .bitrate = 540,
.hw_value = ZD_OFDM_RATE_54M,
.flags = 0 },
};
/*
* Zydas retry rates table. Each line is listed in the same order as
* in zd_rates[] and contains all the rate used when a packet is sent
* starting with a given rates. Let's consider an example :
*
* "11 Mbits : 4, 3, 2, 1, 0" means :
* - packet is sent using 4 different rates
* - 1st rate is index 3 (ie 11 Mbits)
* - 2nd rate is index 2 (ie 5.5 Mbits)
* - 3rd rate is index 1 (ie 2 Mbits)
* - 4th rate is index 0 (ie 1 Mbits)
*/
static const struct tx_retry_rate zd_retry_rates[] = {
{ /* 1 Mbits */ 1, { 0 }},
{ /* 2 Mbits */ 2, { 1, 0 }},
{ /* 5.5 Mbits */ 3, { 2, 1, 0 }},
{ /* 11 Mbits */ 4, { 3, 2, 1, 0 }},
{ /* 6 Mbits */ 5, { 4, 3, 2, 1, 0 }},
{ /* 9 Mbits */ 6, { 5, 4, 3, 2, 1, 0}},
{ /* 12 Mbits */ 5, { 6, 3, 2, 1, 0 }},
{ /* 18 Mbits */ 6, { 7, 6, 3, 2, 1, 0 }},
{ /* 24 Mbits */ 6, { 8, 6, 3, 2, 1, 0 }},
{ /* 36 Mbits */ 7, { 9, 8, 6, 3, 2, 1, 0 }},
{ /* 48 Mbits */ 8, {10, 9, 8, 6, 3, 2, 1, 0 }},
{ /* 54 Mbits */ 9, {11, 10, 9, 8, 6, 3, 2, 1, 0 }}
};
static const struct ieee80211_channel zd_channels[] = {
{ .center_freq = 2412, .hw_value = 1 },
{ .center_freq = 2417, .hw_value = 2 },
{ .center_freq = 2422, .hw_value = 3 },
{ .center_freq = 2427, .hw_value = 4 },
{ .center_freq = 2432, .hw_value = 5 },
{ .center_freq = 2437, .hw_value = 6 },
{ .center_freq = 2442, .hw_value = 7 },
{ .center_freq = 2447, .hw_value = 8 },
{ .center_freq = 2452, .hw_value = 9 },
{ .center_freq = 2457, .hw_value = 10 },
{ .center_freq = 2462, .hw_value = 11 },
{ .center_freq = 2467, .hw_value = 12 },
{ .center_freq = 2472, .hw_value = 13 },
{ .center_freq = 2484, .hw_value = 14 },
};
static void housekeeping_init(struct zd_mac *mac);
static void housekeeping_enable(struct zd_mac *mac);
static void housekeeping_disable(struct zd_mac *mac);
static int zd_reg2alpha2(u8 regdomain, char *alpha2)
{
unsigned int i;
struct zd_reg_alpha2_map *reg_map;
for (i = 0; i < ARRAY_SIZE(reg_alpha2_map); i++) {
reg_map = &reg_alpha2_map[i];
if (regdomain == reg_map->reg) {
alpha2[0] = reg_map->alpha2[0];
alpha2[1] = reg_map->alpha2[1];
return 0;
}
}
return 1;
}
int zd_mac_preinit_hw(struct ieee80211_hw *hw)
{
int r;
u8 addr[ETH_ALEN];
struct zd_mac *mac = zd_hw_mac(hw);
r = zd_chip_read_mac_addr_fw(&mac->chip, addr);
if (r)
return r;
SET_IEEE80211_PERM_ADDR(hw, addr);
return 0;
}
int zd_mac_init_hw(struct ieee80211_hw *hw)
{
int r;
struct zd_mac *mac = zd_hw_mac(hw);
struct zd_chip *chip = &mac->chip;
char alpha2[2];
u8 default_regdomain;
r = zd_chip_enable_int(chip);
if (r)
goto out;
r = zd_chip_init_hw(chip);
if (r)
goto disable_int;
ZD_ASSERT(!irqs_disabled());
r = zd_read_regdomain(chip, &default_regdomain);
if (r)
goto disable_int;
spin_lock_irq(&mac->lock);
mac->regdomain = mac->default_regdomain = default_regdomain;
spin_unlock_irq(&mac->lock);
/* We must inform the device that we are doing encryption/decryption in
* software at the moment. */
r = zd_set_encryption_type(chip, ENC_SNIFFER);
if (r)
goto disable_int;
r = zd_reg2alpha2(mac->regdomain, alpha2);
if (r)
goto disable_int;
r = regulatory_hint(hw->wiphy, alpha2);
disable_int:
zd_chip_disable_int(chip);
out:
return r;
}
void zd_mac_clear(struct zd_mac *mac)
{
flush_workqueue(zd_workqueue);
zd_chip_clear(&mac->chip);
ZD_ASSERT(!spin_is_locked(&mac->lock));
ZD_MEMCLEAR(mac, sizeof(struct zd_mac));
}
static int set_rx_filter(struct zd_mac *mac)
{
unsigned long flags;
u32 filter = STA_RX_FILTER;
spin_lock_irqsave(&mac->lock, flags);
if (mac->pass_ctrl)
filter |= RX_FILTER_CTRL;
spin_unlock_irqrestore(&mac->lock, flags);
return zd_iowrite32(&mac->chip, CR_RX_FILTER, filter);
}
static int set_mc_hash(struct zd_mac *mac)
{
struct zd_mc_hash hash;
zd_mc_clear(&hash);
return zd_chip_set_multicast_hash(&mac->chip, &hash);
}
static int zd_op_start(struct ieee80211_hw *hw)
{
struct zd_mac *mac = zd_hw_mac(hw);
struct zd_chip *chip = &mac->chip;
struct zd_usb *usb = &chip->usb;
int r;
if (!usb->initialized) {
r = zd_usb_init_hw(usb);
if (r)
goto out;
}
r = zd_chip_enable_int(chip);
if (r < 0)
goto out;
r = zd_chip_set_basic_rates(chip, CR_RATES_80211B | CR_RATES_80211G);
if (r < 0)
goto disable_int;
r = set_rx_filter(mac);
if (r)
goto disable_int;
r = set_mc_hash(mac);
if (r)
goto disable_int;
r = zd_chip_switch_radio_on(chip);
if (r < 0)
goto disable_int;
r = zd_chip_enable_rxtx(chip);
if (r < 0)
goto disable_radio;
r = zd_chip_enable_hwint(chip);
if (r < 0)
goto disable_rxtx;
housekeeping_enable(mac);
return 0;
disable_rxtx:
zd_chip_disable_rxtx(chip);
disable_radio:
zd_chip_switch_radio_off(chip);
disable_int:
zd_chip_disable_int(chip);
out:
return r;
}
static void zd_op_stop(struct ieee80211_hw *hw)
{
struct zd_mac *mac = zd_hw_mac(hw);
struct zd_chip *chip = &mac->chip;
struct sk_buff *skb;
struct sk_buff_head *ack_wait_queue = &mac->ack_wait_queue;
/* The order here deliberately is a little different from the open()
* method, since we need to make sure there is no opportunity for RX
* frames to be processed by mac80211 after we have stopped it.
*/
zd_chip_disable_rxtx(chip);
housekeeping_disable(mac);
flush_workqueue(zd_workqueue);
zd_chip_disable_hwint(chip);
zd_chip_switch_radio_off(chip);
zd_chip_disable_int(chip);
while ((skb = skb_dequeue(ack_wait_queue)))
dev_kfree_skb_any(skb);
}
/**
* zd_mac_tx_status - reports tx status of a packet if required
* @hw - a &struct ieee80211_hw pointer
* @skb - a sk-buffer
* @flags: extra flags to set in the TX status info
* @ackssi: ACK signal strength
* @success - True for successful transmission of the frame
*
* This information calls ieee80211_tx_status_irqsafe() if required by the
* control information. It copies the control information into the status
* information.
*
* If no status information has been requested, the skb is freed.
*/
static void zd_mac_tx_status(struct ieee80211_hw *hw, struct sk_buff *skb,
int ackssi, struct tx_status *tx_status)
{
struct ieee80211_tx_info *info = IEEE80211_SKB_CB(skb);
int i;
int success = 1, retry = 1;
int first_idx;
const struct tx_retry_rate *retries;
ieee80211_tx_info_clear_status(info);
if (tx_status) {
success = !tx_status->failure;
retry = tx_status->retry + success;
}
if (success) {
/* success */
info->flags |= IEEE80211_TX_STAT_ACK;
} else {
/* failure */
info->flags &= ~IEEE80211_TX_STAT_ACK;
}
first_idx = info->status.rates[0].idx;
ZD_ASSERT(0<=first_idx && first_idx<ARRAY_SIZE(zd_retry_rates));
retries = &zd_retry_rates[first_idx];
ZD_ASSERT(1 <= retry && retry <= retries->count);
info->status.rates[0].idx = retries->rate[0];
info->status.rates[0].count = 1; // (retry > 1 ? 2 : 1);
for (i=1; i<IEEE80211_TX_MAX_RATES-1 && i<retry; i++) {
info->status.rates[i].idx = retries->rate[i];
info->status.rates[i].count = 1; // ((i==retry-1) && success ? 1:2);
}
for (; i<IEEE80211_TX_MAX_RATES && i<retry; i++) {
info->status.rates[i].idx = retries->rate[retry - 1];
info->status.rates[i].count = 1; // (success ? 1:2);
}
if (i<IEEE80211_TX_MAX_RATES)
info->status.rates[i].idx = -1; /* terminate */
info->status.ack_signal = ackssi;
ieee80211_tx_status_irqsafe(hw, skb);
}
/**
* zd_mac_tx_failed - callback for failed frames
* @dev: the mac80211 wireless device
*
* This function is called if a frame couldn't be successfully
* transferred. The first frame from the tx queue, will be selected and
* reported as error to the upper layers.
*/
void zd_mac_tx_failed(struct urb *urb)
{
struct ieee80211_hw * hw = zd_usb_to_hw(urb->context);
struct zd_mac *mac = zd_hw_mac(hw);
struct sk_buff_head *q = &mac->ack_wait_queue;
struct sk_buff *skb;
struct tx_status *tx_status = (struct tx_status *)urb->transfer_buffer;
unsigned long flags;
int success = !tx_status->failure;
int retry = tx_status->retry + success;
int found = 0;
int i, position = 0;
q = &mac->ack_wait_queue;
spin_lock_irqsave(&q->lock, flags);
skb_queue_walk(q, skb) {
struct ieee80211_hdr *tx_hdr;
struct ieee80211_tx_info *info;
int first_idx, final_idx;
const struct tx_retry_rate *retries;
u8 final_rate;
position ++;
/* if the hardware reports a failure and we had a 802.11 ACK
* pending, then we skip the first skb when searching for a
* matching frame */
if (tx_status->failure && mac->ack_pending &&
skb_queue_is_first(q, skb)) {
continue;
}
tx_hdr = (struct ieee80211_hdr *)skb->data;
/* we skip all frames not matching the reported destination */
if (unlikely(memcmp(tx_hdr->addr1, tx_status->mac, ETH_ALEN))) {
continue;
}
/* we skip all frames not matching the reported final rate */
info = IEEE80211_SKB_CB(skb);
first_idx = info->status.rates[0].idx;
ZD_ASSERT(0<=first_idx && first_idx<ARRAY_SIZE(zd_retry_rates));
retries = &zd_retry_rates[first_idx];
if (retry <= 0 || retry > retries->count)
continue;
final_idx = retries->rate[retry - 1];
final_rate = zd_rates[final_idx].hw_value;
if (final_rate != tx_status->rate) {
continue;
}
found = 1;
break;
}
if (found) {
for (i=1; i<=position; i++) {
skb = __skb_dequeue(q);
zd_mac_tx_status(hw, skb,
mac->ack_pending ? mac->ack_signal : 0,
i == position ? tx_status : NULL);
mac->ack_pending = 0;
}
}
spin_unlock_irqrestore(&q->lock, flags);
}
/**
* zd_mac_tx_to_dev - callback for USB layer
* @skb: a &sk_buff pointer
* @error: error value, 0 if transmission successful
*
* Informs the MAC layer that the frame has successfully transferred to the
* device. If an ACK is required and the transfer to the device has been
* successful, the packets are put on the @ack_wait_queue with
* the control set removed.
*/
void zd_mac_tx_to_dev(struct sk_buff *skb, int error)
{
struct ieee80211_tx_info *info = IEEE80211_SKB_CB(skb);
struct ieee80211_hw *hw = info->rate_driver_data[0];
struct zd_mac *mac = zd_hw_mac(hw);
ieee80211_tx_info_clear_status(info);
skb_pull(skb, sizeof(struct zd_ctrlset));
if (unlikely(error ||
(info->flags & IEEE80211_TX_CTL_NO_ACK))) {
/*
* FIXME : do we need to fill in anything ?
*/
ieee80211_tx_status_irqsafe(hw, skb);
} else {
struct sk_buff_head *q = &mac->ack_wait_queue;
skb_queue_tail(q, skb);
while (skb_queue_len(q) > ZD_MAC_MAX_ACK_WAITERS) {
zd_mac_tx_status(hw, skb_dequeue(q),
mac->ack_pending ? mac->ack_signal : 0,
NULL);
mac->ack_pending = 0;
}
}
}
static int zd_calc_tx_length_us(u8 *service, u8 zd_rate, u16 tx_length)
{
/* ZD_PURE_RATE() must be used to remove the modulation type flag of
* the zd-rate values.
*/
static const u8 rate_divisor[] = {
[ZD_PURE_RATE(ZD_CCK_RATE_1M)] = 1,
[ZD_PURE_RATE(ZD_CCK_RATE_2M)] = 2,
/* Bits must be doubled. */
[ZD_PURE_RATE(ZD_CCK_RATE_5_5M)] = 11,
[ZD_PURE_RATE(ZD_CCK_RATE_11M)] = 11,
[ZD_PURE_RATE(ZD_OFDM_RATE_6M)] = 6,
[ZD_PURE_RATE(ZD_OFDM_RATE_9M)] = 9,
[ZD_PURE_RATE(ZD_OFDM_RATE_12M)] = 12,
[ZD_PURE_RATE(ZD_OFDM_RATE_18M)] = 18,
[ZD_PURE_RATE(ZD_OFDM_RATE_24M)] = 24,
[ZD_PURE_RATE(ZD_OFDM_RATE_36M)] = 36,
[ZD_PURE_RATE(ZD_OFDM_RATE_48M)] = 48,
[ZD_PURE_RATE(ZD_OFDM_RATE_54M)] = 54,
};
u32 bits = (u32)tx_length * 8;
u32 divisor;
divisor = rate_divisor[ZD_PURE_RATE(zd_rate)];
if (divisor == 0)
return -EINVAL;
switch (zd_rate) {
case ZD_CCK_RATE_5_5M:
bits = (2*bits) + 10; /* round up to the next integer */
break;
case ZD_CCK_RATE_11M:
if (service) {
u32 t = bits % 11;
*service &= ~ZD_PLCP_SERVICE_LENGTH_EXTENSION;
if (0 < t && t <= 3) {
*service |= ZD_PLCP_SERVICE_LENGTH_EXTENSION;
}
}
bits += 10; /* round up to the next integer */
break;
}
return bits/divisor;
}
static void cs_set_control(struct zd_mac *mac, struct zd_ctrlset *cs,
struct ieee80211_hdr *header,
struct ieee80211_tx_info *info)
{
/*
* CONTROL TODO:
* - if backoff needed, enable bit 0
* - if burst (backoff not needed) disable bit 0
*/
cs->control = 0;
/* First fragment */
if (info->flags & IEEE80211_TX_CTL_FIRST_FRAGMENT)
cs->control |= ZD_CS_NEED_RANDOM_BACKOFF;
/* No ACK expected (multicast, etc.) */
if (info->flags & IEEE80211_TX_CTL_NO_ACK)
cs->control |= ZD_CS_NO_ACK;
/* PS-POLL */
if (ieee80211_is_pspoll(header->frame_control))
cs->control |= ZD_CS_PS_POLL_FRAME;
if (info->control.rates[0].flags & IEEE80211_TX_RC_USE_RTS_CTS)
cs->control |= ZD_CS_RTS;
if (info->control.rates[0].flags & IEEE80211_TX_RC_USE_CTS_PROTECT)
cs->control |= ZD_CS_SELF_CTS;
/* FIXME: Management frame? */
}
static int zd_mac_config_beacon(struct ieee80211_hw *hw, struct sk_buff *beacon)
{
struct zd_mac *mac = zd_hw_mac(hw);
int r;
u32 tmp, j = 0;
/* 4 more bytes for tail CRC */
u32 full_len = beacon->len + 4;
r = zd_iowrite32(&mac->chip, CR_BCN_FIFO_SEMAPHORE, 0);
if (r < 0)
return r;
r = zd_ioread32(&mac->chip, CR_BCN_FIFO_SEMAPHORE, &tmp);
if (r < 0)
return r;
while (tmp & 0x2) {
r = zd_ioread32(&mac->chip, CR_BCN_FIFO_SEMAPHORE, &tmp);
if (r < 0)
return r;
if ((++j % 100) == 0) {
printk(KERN_ERR "CR_BCN_FIFO_SEMAPHORE not ready\n");
if (j >= 500) {
printk(KERN_ERR "Giving up beacon config.\n");
return -ETIMEDOUT;
}
}
msleep(1);
}
r = zd_iowrite32(&mac->chip, CR_BCN_FIFO, full_len - 1);
if (r < 0)
return r;
if (zd_chip_is_zd1211b(&mac->chip)) {
r = zd_iowrite32(&mac->chip, CR_BCN_LENGTH, full_len - 1);
if (r < 0)
return r;
}
for (j = 0 ; j < beacon->len; j++) {
r = zd_iowrite32(&mac->chip, CR_BCN_FIFO,
*((u8 *)(beacon->data + j)));
if (r < 0)
return r;
}
for (j = 0; j < 4; j++) {
r = zd_iowrite32(&mac->chip, CR_BCN_FIFO, 0x0);
if (r < 0)
return r;
}
r = zd_iowrite32(&mac->chip, CR_BCN_FIFO_SEMAPHORE, 1);
if (r < 0)
return r;
/* 802.11b/g 2.4G CCK 1Mb
* 802.11a, not yet implemented, uses different values (see GPL vendor
* driver)
*/
return zd_iowrite32(&mac->chip, CR_BCN_PLCP_CFG, 0x00000400 |
(full_len << 19));
}
static int fill_ctrlset(struct zd_mac *mac,
struct sk_buff *skb)
{
int r;
struct ieee80211_hdr *hdr = (struct ieee80211_hdr *) skb->data;
unsigned int frag_len = skb->len + FCS_LEN;
unsigned int packet_length;
struct ieee80211_rate *txrate;
struct zd_ctrlset *cs = (struct zd_ctrlset *)
skb_push(skb, sizeof(struct zd_ctrlset));
struct ieee80211_tx_info *info = IEEE80211_SKB_CB(skb);
ZD_ASSERT(frag_len <= 0xffff);
txrate = ieee80211_get_tx_rate(mac->hw, info);
cs->modulation = txrate->hw_value;
if (info->control.rates[0].flags & IEEE80211_TX_RC_USE_SHORT_PREAMBLE)
cs->modulation = txrate->hw_value_short;
cs->tx_length = cpu_to_le16(frag_len);
cs_set_control(mac, cs, hdr, info);
packet_length = frag_len + sizeof(struct zd_ctrlset) + 10;
ZD_ASSERT(packet_length <= 0xffff);
/* ZD1211B: Computing the length difference this way, gives us
* flexibility to compute the packet length.
*/
cs->packet_length = cpu_to_le16(zd_chip_is_zd1211b(&mac->chip) ?
packet_length - frag_len : packet_length);
/*
* CURRENT LENGTH:
* - transmit frame length in microseconds
* - seems to be derived from frame length
* - see Cal_Us_Service() in zdinlinef.h
* - if macp->bTxBurstEnable is enabled, then multiply by 4
* - bTxBurstEnable is never set in the vendor driver
*
* SERVICE:
* - "for PLCP configuration"
* - always 0 except in some situations at 802.11b 11M
* - see line 53 of zdinlinef.h
*/
cs->service = 0;
r = zd_calc_tx_length_us(&cs->service, ZD_RATE(cs->modulation),
le16_to_cpu(cs->tx_length));
if (r < 0)
return r;
cs->current_length = cpu_to_le16(r);
cs->next_frame_length = 0;
return 0;
}
/**
* zd_op_tx - transmits a network frame to the device
*
* @dev: mac80211 hardware device
* @skb: socket buffer
* @control: the control structure
*
* This function transmit an IEEE 802.11 network frame to the device. The
* control block of the skbuff will be initialized. If necessary the incoming
* mac80211 queues will be stopped.
*/
static int zd_op_tx(struct ieee80211_hw *hw, struct sk_buff *skb)
{
struct zd_mac *mac = zd_hw_mac(hw);
struct ieee80211_tx_info *info = IEEE80211_SKB_CB(skb);
int r;
r = fill_ctrlset(mac, skb);
if (r)
goto fail;
info->rate_driver_data[0] = hw;
r = zd_usb_tx(&mac->chip.usb, skb);
if (r)
goto fail;
return 0;
fail:
dev_kfree_skb(skb);
return 0;
}
/**
* filter_ack - filters incoming packets for acknowledgements
* @dev: the mac80211 device
* @rx_hdr: received header
* @stats: the status for the received packet
*
* This functions looks for ACK packets and tries to match them with the
* frames in the tx queue. If a match is found the frame will be dequeued and
* the upper layers is informed about the successful transmission. If
* mac80211 queues have been stopped and the number of frames still to be
* transmitted is low the queues will be opened again.
*
* Returns 1 if the frame was an ACK, 0 if it was ignored.
*/
static int filter_ack(struct ieee80211_hw *hw, struct ieee80211_hdr *rx_hdr,
struct ieee80211_rx_status *stats)
{
struct zd_mac *mac = zd_hw_mac(hw);
struct sk_buff *skb;
struct sk_buff_head *q;
unsigned long flags;
int found = 0;
int i, position = 0;
if (!ieee80211_is_ack(rx_hdr->frame_control))
return 0;
q = &mac->ack_wait_queue;
spin_lock_irqsave(&q->lock, flags);
skb_queue_walk(q, skb) {
struct ieee80211_hdr *tx_hdr;
position ++;
if (mac->ack_pending && skb_queue_is_first(q, skb))
continue;
tx_hdr = (struct ieee80211_hdr *)skb->data;
if (likely(!memcmp(tx_hdr->addr2, rx_hdr->addr1, ETH_ALEN)))
{
found = 1;
break;
}
}
if (found) {
for (i=1; i<position; i++) {
skb = __skb_dequeue(q);
zd_mac_tx_status(hw, skb,
mac->ack_pending ? mac->ack_signal : 0,
NULL);
mac->ack_pending = 0;
}
mac->ack_pending = 1;
mac->ack_signal = stats->signal;
}
spin_unlock_irqrestore(&q->lock, flags);
return 1;
}
int zd_mac_rx(struct ieee80211_hw *hw, const u8 *buffer, unsigned int length)
{
struct zd_mac *mac = zd_hw_mac(hw);
struct ieee80211_rx_status stats;
const struct rx_status *status;
struct sk_buff *skb;
int bad_frame = 0;
__le16 fc;
int need_padding;
int i;
u8 rate;
if (length < ZD_PLCP_HEADER_SIZE + 10 /* IEEE80211_1ADDR_LEN */ +
FCS_LEN + sizeof(struct rx_status))
return -EINVAL;
memset(&stats, 0, sizeof(stats));
/* Note about pass_failed_fcs and pass_ctrl access below:
* mac locking intentionally omitted here, as this is the only unlocked
* reader and the only writer is configure_filter. Plus, if there were
* any races accessing these variables, it wouldn't really matter.
* If mac80211 ever provides a way for us to access filter flags
* from outside configure_filter, we could improve on this. Also, this
* situation may change once we implement some kind of DMA-into-skb
* RX path. */
/* Caller has to ensure that length >= sizeof(struct rx_status). */
status = (struct rx_status *)
(buffer + (length - sizeof(struct rx_status)));
if (status->frame_status & ZD_RX_ERROR) {
if (mac->pass_failed_fcs &&
(status->frame_status & ZD_RX_CRC32_ERROR)) {
stats.flag |= RX_FLAG_FAILED_FCS_CRC;
bad_frame = 1;
} else {
return -EINVAL;
}
}
stats.freq = zd_channels[_zd_chip_get_channel(&mac->chip) - 1].center_freq;
stats.band = IEEE80211_BAND_2GHZ;
stats.signal = status->signal_strength;
rate = zd_rx_rate(buffer, status);
/* todo: return index in the big switches in zd_rx_rate instead */
for (i = 0; i < mac->band.n_bitrates; i++)
if (rate == mac->band.bitrates[i].hw_value)
stats.rate_idx = i;
length -= ZD_PLCP_HEADER_SIZE + sizeof(struct rx_status);
buffer += ZD_PLCP_HEADER_SIZE;
/* Except for bad frames, filter each frame to see if it is an ACK, in
* which case our internal TX tracking is updated. Normally we then
* bail here as there's no need to pass ACKs on up to the stack, but
* there is also the case where the stack has requested us to pass
* control frames on up (pass_ctrl) which we must consider. */
if (!bad_frame &&
filter_ack(hw, (struct ieee80211_hdr *)buffer, &stats)
&& !mac->pass_ctrl)
return 0;
fc = get_unaligned((__le16*)buffer);
need_padding = ieee80211_is_data_qos(fc) ^ ieee80211_has_a4(fc);
skb = dev_alloc_skb(length + (need_padding ? 2 : 0));
if (skb == NULL)
return -ENOMEM;
if (need_padding) {
/* Make sure the the payload data is 4 byte aligned. */
skb_reserve(skb, 2);
}
/* FIXME : could we avoid this big memcpy ? */
memcpy(skb_put(skb, length), buffer, length);
memcpy(IEEE80211_SKB_RXCB(skb), &stats, sizeof(stats));
ieee80211_rx_irqsafe(hw, skb);
return 0;
}
static int zd_op_add_interface(struct ieee80211_hw *hw,
struct ieee80211_vif *vif)
{
struct zd_mac *mac = zd_hw_mac(hw);
/* using NL80211_IFTYPE_UNSPECIFIED to indicate no mode selected */
if (mac->type != NL80211_IFTYPE_UNSPECIFIED)
return -EOPNOTSUPP;
switch (vif->type) {
case NL80211_IFTYPE_MONITOR:
case NL80211_IFTYPE_MESH_POINT:
case NL80211_IFTYPE_STATION:
case NL80211_IFTYPE_ADHOC:
mac->type = vif->type;
break;
default:
return -EOPNOTSUPP;
}
return zd_write_mac_addr(&mac->chip, vif->addr);
}
static void zd_op_remove_interface(struct ieee80211_hw *hw,
struct ieee80211_vif *vif)
{
struct zd_mac *mac = zd_hw_mac(hw);
mac->type = NL80211_IFTYPE_UNSPECIFIED;
zd_set_beacon_interval(&mac->chip, 0);
zd_write_mac_addr(&mac->chip, NULL);
}
static int zd_op_config(struct ieee80211_hw *hw, u32 changed)
{
struct zd_mac *mac = zd_hw_mac(hw);
struct ieee80211_conf *conf = &hw->conf;
return zd_chip_set_channel(&mac->chip, conf->channel->hw_value);
}
static void zd_process_intr(struct work_struct *work)
{
u16 int_status;
struct zd_mac *mac = container_of(work, struct zd_mac, process_intr);
int_status = le16_to_cpu(*(__le16 *)(mac->intr_buffer+4));
if (int_status & INT_CFG_NEXT_BCN)
dev_dbg_f_limit(zd_mac_dev(mac), "INT_CFG_NEXT_BCN\n");
else
dev_dbg_f(zd_mac_dev(mac), "Unsupported interrupt\n");
zd_chip_enable_hwint(&mac->chip);
}
static void set_multicast_hash_handler(struct work_struct *work)
{
struct zd_mac *mac =
container_of(work, struct zd_mac, set_multicast_hash_work);
struct zd_mc_hash hash;
spin_lock_irq(&mac->lock);
hash = mac->multicast_hash;
spin_unlock_irq(&mac->lock);
zd_chip_set_multicast_hash(&mac->chip, &hash);
}
static void set_rx_filter_handler(struct work_struct *work)
{
struct zd_mac *mac =
container_of(work, struct zd_mac, set_rx_filter_work);
int r;
dev_dbg_f(zd_mac_dev(mac), "\n");
r = set_rx_filter(mac);
if (r)
dev_err(zd_mac_dev(mac), "set_rx_filter_handler error %d\n", r);
}
static u64 zd_op_prepare_multicast(struct ieee80211_hw *hw,
int mc_count, struct dev_addr_list *mclist)
{
struct zd_mac *mac = zd_hw_mac(hw);
struct zd_mc_hash hash;
int i;
zd_mc_clear(&hash);
for (i = 0; i < mc_count; i++) {
if (!mclist)
break;
dev_dbg_f(zd_mac_dev(mac), "mc addr %pM\n", mclist->dmi_addr);
zd_mc_add_addr(&hash, mclist->dmi_addr);
mclist = mclist->next;
}
return hash.low | ((u64)hash.high << 32);
}
#define SUPPORTED_FIF_FLAGS \
(FIF_PROMISC_IN_BSS | FIF_ALLMULTI | FIF_FCSFAIL | FIF_CONTROL | \
FIF_OTHER_BSS | FIF_BCN_PRBRESP_PROMISC)
static void zd_op_configure_filter(struct ieee80211_hw *hw,
unsigned int changed_flags,
unsigned int *new_flags,
u64 multicast)
{
struct zd_mc_hash hash = {
.low = multicast,
.high = multicast >> 32,
};
struct zd_mac *mac = zd_hw_mac(hw);
unsigned long flags;
/* Only deal with supported flags */
changed_flags &= SUPPORTED_FIF_FLAGS;
*new_flags &= SUPPORTED_FIF_FLAGS;
/*
* If multicast parameter (as returned by zd_op_prepare_multicast)
* has changed, no bit in changed_flags is set. To handle this
* situation, we do not return if changed_flags is 0. If we do so,
* we will have some issue with IPv6 which uses multicast for link
* layer address resolution.
*/
if (*new_flags & (FIF_PROMISC_IN_BSS | FIF_ALLMULTI))
zd_mc_add_all(&hash);
spin_lock_irqsave(&mac->lock, flags);
mac->pass_failed_fcs = !!(*new_flags & FIF_FCSFAIL);
mac->pass_ctrl = !!(*new_flags & FIF_CONTROL);
mac->multicast_hash = hash;
spin_unlock_irqrestore(&mac->lock, flags);
/* XXX: these can be called here now, can sleep now! */
queue_work(zd_workqueue, &mac->set_multicast_hash_work);
if (changed_flags & FIF_CONTROL)
queue_work(zd_workqueue, &mac->set_rx_filter_work);
/* no handling required for FIF_OTHER_BSS as we don't currently
* do BSSID filtering */
/* FIXME: in future it would be nice to enable the probe response
* filter (so that the driver doesn't see them) until
* FIF_BCN_PRBRESP_PROMISC is set. however due to atomicity here, we'd
* have to schedule work to enable prbresp reception, which might
* happen too late. For now we'll just listen and forward them all the
* time. */
}
static void set_rts_cts_work(struct work_struct *work)
{
struct zd_mac *mac =
container_of(work, struct zd_mac, set_rts_cts_work);
unsigned long flags;
unsigned int short_preamble;
mutex_lock(&mac->chip.mutex);
spin_lock_irqsave(&mac->lock, flags);
mac->updating_rts_rate = 0;
short_preamble = mac->short_preamble;
spin_unlock_irqrestore(&mac->lock, flags);
zd_chip_set_rts_cts_rate_locked(&mac->chip, short_preamble);
mutex_unlock(&mac->chip.mutex);
}
static void zd_op_bss_info_changed(struct ieee80211_hw *hw,
struct ieee80211_vif *vif,
struct ieee80211_bss_conf *bss_conf,
u32 changes)
{
struct zd_mac *mac = zd_hw_mac(hw);
unsigned long flags;
int associated;
dev_dbg_f(zd_mac_dev(mac), "changes: %x\n", changes);
if (mac->type == NL80211_IFTYPE_MESH_POINT ||
mac->type == NL80211_IFTYPE_ADHOC) {
associated = true;
if (changes & BSS_CHANGED_BEACON) {
struct sk_buff *beacon = ieee80211_beacon_get(hw, vif);
if (beacon) {
zd_mac_config_beacon(hw, beacon);
kfree_skb(beacon);
}
}
if (changes & BSS_CHANGED_BEACON_ENABLED) {
u32 interval;
if (bss_conf->enable_beacon)
interval = BCN_MODE_IBSS |
bss_conf->beacon_int;
else
interval = 0;
zd_set_beacon_interval(&mac->chip, interval);
}
} else
associated = is_valid_ether_addr(bss_conf->bssid);
spin_lock_irq(&mac->lock);
mac->associated = associated;
spin_unlock_irq(&mac->lock);
/* TODO: do hardware bssid filtering */
if (changes & BSS_CHANGED_ERP_PREAMBLE) {
spin_lock_irqsave(&mac->lock, flags);
mac->short_preamble = bss_conf->use_short_preamble;
if (!mac->updating_rts_rate) {
mac->updating_rts_rate = 1;
/* FIXME: should disable TX here, until work has
* completed and RTS_CTS reg is updated */
queue_work(zd_workqueue, &mac->set_rts_cts_work);
}
spin_unlock_irqrestore(&mac->lock, flags);
}
}
static u64 zd_op_get_tsf(struct ieee80211_hw *hw)
{
struct zd_mac *mac = zd_hw_mac(hw);
return zd_chip_get_tsf(&mac->chip);
}
static const struct ieee80211_ops zd_ops = {
.tx = zd_op_tx,
.start = zd_op_start,
.stop = zd_op_stop,
.add_interface = zd_op_add_interface,
.remove_interface = zd_op_remove_interface,
.config = zd_op_config,
.prepare_multicast = zd_op_prepare_multicast,
.configure_filter = zd_op_configure_filter,
.bss_info_changed = zd_op_bss_info_changed,
.get_tsf = zd_op_get_tsf,
};
struct ieee80211_hw *zd_mac_alloc_hw(struct usb_interface *intf)
{
struct zd_mac *mac;
struct ieee80211_hw *hw;
hw = ieee80211_alloc_hw(sizeof(struct zd_mac), &zd_ops);
if (!hw) {
dev_dbg_f(&intf->dev, "out of memory\n");
return NULL;
}
mac = zd_hw_mac(hw);
memset(mac, 0, sizeof(*mac));
spin_lock_init(&mac->lock);
mac->hw = hw;
mac->type = NL80211_IFTYPE_UNSPECIFIED;
memcpy(mac->channels, zd_channels, sizeof(zd_channels));
memcpy(mac->rates, zd_rates, sizeof(zd_rates));
mac->band.n_bitrates = ARRAY_SIZE(zd_rates);
mac->band.bitrates = mac->rates;
mac->band.n_channels = ARRAY_SIZE(zd_channels);
mac->band.channels = mac->channels;
hw->wiphy->bands[IEEE80211_BAND_2GHZ] = &mac->band;
hw->flags = IEEE80211_HW_RX_INCLUDES_FCS |
IEEE80211_HW_SIGNAL_UNSPEC;
hw->wiphy->interface_modes =
BIT(NL80211_IFTYPE_MESH_POINT) |
BIT(NL80211_IFTYPE_STATION) |
BIT(NL80211_IFTYPE_ADHOC);
hw->max_signal = 100;
hw->queues = 1;
hw->extra_tx_headroom = sizeof(struct zd_ctrlset);
/*
* Tell mac80211 that we support multi rate retries
*/
hw->max_rates = IEEE80211_TX_MAX_RATES;
hw->max_rate_tries = 18; /* 9 rates * 2 retries/rate */
skb_queue_head_init(&mac->ack_wait_queue);
mac->ack_pending = 0;
zd_chip_init(&mac->chip, hw, intf);
housekeeping_init(mac);
INIT_WORK(&mac->set_multicast_hash_work, set_multicast_hash_handler);
INIT_WORK(&mac->set_rts_cts_work, set_rts_cts_work);
INIT_WORK(&mac->set_rx_filter_work, set_rx_filter_handler);
INIT_WORK(&mac->process_intr, zd_process_intr);
SET_IEEE80211_DEV(hw, &intf->dev);
return hw;
}
#define LINK_LED_WORK_DELAY HZ
static void link_led_handler(struct work_struct *work)
{
struct zd_mac *mac =
container_of(work, struct zd_mac, housekeeping.link_led_work.work);
struct zd_chip *chip = &mac->chip;
int is_associated;
int r;
spin_lock_irq(&mac->lock);
is_associated = mac->associated;
spin_unlock_irq(&mac->lock);
r = zd_chip_control_leds(chip,
is_associated ? ZD_LED_ASSOCIATED : ZD_LED_SCANNING);
if (r)
dev_dbg_f(zd_mac_dev(mac), "zd_chip_control_leds error %d\n", r);
queue_delayed_work(zd_workqueue, &mac->housekeeping.link_led_work,
LINK_LED_WORK_DELAY);
}
static void housekeeping_init(struct zd_mac *mac)
{
INIT_DELAYED_WORK(&mac->housekeeping.link_led_work, link_led_handler);
}
static void housekeeping_enable(struct zd_mac *mac)
{
dev_dbg_f(zd_mac_dev(mac), "\n");
queue_delayed_work(zd_workqueue, &mac->housekeeping.link_led_work,
0);
}
static void housekeeping_disable(struct zd_mac *mac)
{
dev_dbg_f(zd_mac_dev(mac), "\n");
cancel_rearming_delayed_workqueue(zd_workqueue,
&mac->housekeeping.link_led_work);
zd_chip_control_leds(&mac->chip, ZD_LED_OFF);
}