WSL2-Linux-Kernel/drivers/isdn/hardware/mISDN/hfcsusb.c

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/* hfcsusb.c
* mISDN driver for Colognechip HFC-S USB chip
*
* Copyright 2001 by Peter Sprenger (sprenger@moving-bytes.de)
* Copyright 2008 by Martin Bachem (info@bachem-it.com)
*
* 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, 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., 675 Mass Ave, Cambridge, MA 02139, USA.
*
*
* module params
* debug=<n>, default=0, with n=0xHHHHGGGG
* H - l1 driver flags described in hfcsusb.h
* G - common mISDN debug flags described at mISDNhw.h
*
* poll=<n>, default 128
* n : burst size of PH_DATA_IND at transparent rx data
*
* Revision: 0.3.3 (socket), 2008-11-05
*/
#include <linux/module.h>
#include <linux/delay.h>
#include <linux/usb.h>
#include <linux/mISDNhw.h>
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>
2010-03-24 11:04:11 +03:00
#include <linux/slab.h>
#include "hfcsusb.h"
static unsigned int debug;
static int poll = DEFAULT_TRANSP_BURST_SZ;
static LIST_HEAD(HFClist);
static DEFINE_RWLOCK(HFClock);
MODULE_AUTHOR("Martin Bachem");
MODULE_LICENSE("GPL");
module_param(debug, uint, S_IRUGO | S_IWUSR);
module_param(poll, int, 0);
static int hfcsusb_cnt;
/* some function prototypes */
static void hfcsusb_ph_command(struct hfcsusb *hw, u_char command);
static void release_hw(struct hfcsusb *hw);
static void reset_hfcsusb(struct hfcsusb *hw);
static void setPortMode(struct hfcsusb *hw);
static void hfcsusb_start_endpoint(struct hfcsusb *hw, int channel);
static void hfcsusb_stop_endpoint(struct hfcsusb *hw, int channel);
static int hfcsusb_setup_bch(struct bchannel *bch, int protocol);
static void deactivate_bchannel(struct bchannel *bch);
static void hfcsusb_ph_info(struct hfcsusb *hw);
/* start next background transfer for control channel */
static void
ctrl_start_transfer(struct hfcsusb *hw)
{
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s\n", hw->name, __func__);
if (hw->ctrl_cnt) {
hw->ctrl_urb->pipe = hw->ctrl_out_pipe;
hw->ctrl_urb->setup_packet = (u_char *)&hw->ctrl_write;
hw->ctrl_urb->transfer_buffer = NULL;
hw->ctrl_urb->transfer_buffer_length = 0;
hw->ctrl_write.wIndex =
cpu_to_le16(hw->ctrl_buff[hw->ctrl_out_idx].hfcs_reg);
hw->ctrl_write.wValue =
cpu_to_le16(hw->ctrl_buff[hw->ctrl_out_idx].reg_val);
usb_submit_urb(hw->ctrl_urb, GFP_ATOMIC);
}
}
/*
* queue a control transfer request to write HFC-S USB
* chip register using CTRL resuest queue
*/
static int write_reg(struct hfcsusb *hw, __u8 reg, __u8 val)
{
struct ctrl_buf *buf;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s reg(0x%02x) val(0x%02x)\n",
hw->name, __func__, reg, val);
spin_lock(&hw->ctrl_lock);
if (hw->ctrl_cnt >= HFC_CTRL_BUFSIZE) {
spin_unlock(&hw->ctrl_lock);
return 1;
}
buf = &hw->ctrl_buff[hw->ctrl_in_idx];
buf->hfcs_reg = reg;
buf->reg_val = val;
if (++hw->ctrl_in_idx >= HFC_CTRL_BUFSIZE)
hw->ctrl_in_idx = 0;
if (++hw->ctrl_cnt == 1)
ctrl_start_transfer(hw);
spin_unlock(&hw->ctrl_lock);
return 0;
}
/* control completion routine handling background control cmds */
static void
ctrl_complete(struct urb *urb)
{
struct hfcsusb *hw = (struct hfcsusb *) urb->context;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s\n", hw->name, __func__);
urb->dev = hw->dev;
if (hw->ctrl_cnt) {
hw->ctrl_cnt--; /* decrement actual count */
if (++hw->ctrl_out_idx >= HFC_CTRL_BUFSIZE)
hw->ctrl_out_idx = 0; /* pointer wrap */
ctrl_start_transfer(hw); /* start next transfer */
}
}
/* handle LED bits */
static void
set_led_bit(struct hfcsusb *hw, signed short led_bits, int set_on)
{
if (set_on) {
if (led_bits < 0)
hw->led_state &= ~abs(led_bits);
else
hw->led_state |= led_bits;
} else {
if (led_bits < 0)
hw->led_state |= abs(led_bits);
else
hw->led_state &= ~led_bits;
}
}
/* handle LED requests */
static void
handle_led(struct hfcsusb *hw, int event)
{
struct hfcsusb_vdata *driver_info = (struct hfcsusb_vdata *)
hfcsusb_idtab[hw->vend_idx].driver_info;
__u8 tmpled;
if (driver_info->led_scheme == LED_OFF)
return;
tmpled = hw->led_state;
switch (event) {
case LED_POWER_ON:
set_led_bit(hw, driver_info->led_bits[0], 1);
set_led_bit(hw, driver_info->led_bits[1], 0);
set_led_bit(hw, driver_info->led_bits[2], 0);
set_led_bit(hw, driver_info->led_bits[3], 0);
break;
case LED_POWER_OFF:
set_led_bit(hw, driver_info->led_bits[0], 0);
set_led_bit(hw, driver_info->led_bits[1], 0);
set_led_bit(hw, driver_info->led_bits[2], 0);
set_led_bit(hw, driver_info->led_bits[3], 0);
break;
case LED_S0_ON:
set_led_bit(hw, driver_info->led_bits[1], 1);
break;
case LED_S0_OFF:
set_led_bit(hw, driver_info->led_bits[1], 0);
break;
case LED_B1_ON:
set_led_bit(hw, driver_info->led_bits[2], 1);
break;
case LED_B1_OFF:
set_led_bit(hw, driver_info->led_bits[2], 0);
break;
case LED_B2_ON:
set_led_bit(hw, driver_info->led_bits[3], 1);
break;
case LED_B2_OFF:
set_led_bit(hw, driver_info->led_bits[3], 0);
break;
}
if (hw->led_state != tmpled) {
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s reg(0x%02x) val(x%02x)\n",
hw->name, __func__,
HFCUSB_P_DATA, hw->led_state);
write_reg(hw, HFCUSB_P_DATA, hw->led_state);
}
}
/*
* Layer2 -> Layer 1 Bchannel data
*/
static int
hfcusb_l2l1B(struct mISDNchannel *ch, struct sk_buff *skb)
{
struct bchannel *bch = container_of(ch, struct bchannel, ch);
struct hfcsusb *hw = bch->hw;
int ret = -EINVAL;
struct mISDNhead *hh = mISDN_HEAD_P(skb);
u_long flags;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s\n", hw->name, __func__);
switch (hh->prim) {
case PH_DATA_REQ:
spin_lock_irqsave(&hw->lock, flags);
ret = bchannel_senddata(bch, skb);
spin_unlock_irqrestore(&hw->lock, flags);
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s PH_DATA_REQ ret(%i)\n",
hw->name, __func__, ret);
if (ret > 0)
ret = 0;
return ret;
case PH_ACTIVATE_REQ:
if (!test_and_set_bit(FLG_ACTIVE, &bch->Flags)) {
hfcsusb_start_endpoint(hw, bch->nr - 1);
ret = hfcsusb_setup_bch(bch, ch->protocol);
} else
ret = 0;
if (!ret)
_queue_data(ch, PH_ACTIVATE_IND, MISDN_ID_ANY,
0, NULL, GFP_KERNEL);
break;
case PH_DEACTIVATE_REQ:
deactivate_bchannel(bch);
_queue_data(ch, PH_DEACTIVATE_IND, MISDN_ID_ANY,
0, NULL, GFP_KERNEL);
ret = 0;
break;
}
if (!ret)
dev_kfree_skb(skb);
return ret;
}
/*
* send full D/B channel status information
* as MPH_INFORMATION_IND
*/
static void
hfcsusb_ph_info(struct hfcsusb *hw)
{
struct ph_info *phi;
struct dchannel *dch = &hw->dch;
int i;
phi = kzalloc(sizeof(struct ph_info) +
dch->dev.nrbchan * sizeof(struct ph_info_ch), GFP_ATOMIC);
phi->dch.ch.protocol = hw->protocol;
phi->dch.ch.Flags = dch->Flags;
phi->dch.state = dch->state;
phi->dch.num_bch = dch->dev.nrbchan;
for (i = 0; i < dch->dev.nrbchan; i++) {
phi->bch[i].protocol = hw->bch[i].ch.protocol;
phi->bch[i].Flags = hw->bch[i].Flags;
}
_queue_data(&dch->dev.D, MPH_INFORMATION_IND, MISDN_ID_ANY,
sizeof(struct ph_info_dch) + dch->dev.nrbchan *
sizeof(struct ph_info_ch), phi, GFP_ATOMIC);
kfree(phi);
}
/*
* Layer2 -> Layer 1 Dchannel data
*/
static int
hfcusb_l2l1D(struct mISDNchannel *ch, struct sk_buff *skb)
{
struct mISDNdevice *dev = container_of(ch, struct mISDNdevice, D);
struct dchannel *dch = container_of(dev, struct dchannel, dev);
struct mISDNhead *hh = mISDN_HEAD_P(skb);
struct hfcsusb *hw = dch->hw;
int ret = -EINVAL;
u_long flags;
switch (hh->prim) {
case PH_DATA_REQ:
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s: PH_DATA_REQ\n",
hw->name, __func__);
spin_lock_irqsave(&hw->lock, flags);
ret = dchannel_senddata(dch, skb);
spin_unlock_irqrestore(&hw->lock, flags);
if (ret > 0) {
ret = 0;
queue_ch_frame(ch, PH_DATA_CNF, hh->id, NULL);
}
break;
case PH_ACTIVATE_REQ:
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s: PH_ACTIVATE_REQ %s\n",
hw->name, __func__,
(hw->protocol == ISDN_P_NT_S0) ? "NT" : "TE");
if (hw->protocol == ISDN_P_NT_S0) {
ret = 0;
if (test_bit(FLG_ACTIVE, &dch->Flags)) {
_queue_data(&dch->dev.D,
PH_ACTIVATE_IND, MISDN_ID_ANY, 0,
NULL, GFP_ATOMIC);
} else {
hfcsusb_ph_command(hw,
HFC_L1_ACTIVATE_NT);
test_and_set_bit(FLG_L2_ACTIVATED,
&dch->Flags);
}
} else {
hfcsusb_ph_command(hw, HFC_L1_ACTIVATE_TE);
ret = l1_event(dch->l1, hh->prim);
}
break;
case PH_DEACTIVATE_REQ:
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s: PH_DEACTIVATE_REQ\n",
hw->name, __func__);
test_and_clear_bit(FLG_L2_ACTIVATED, &dch->Flags);
if (hw->protocol == ISDN_P_NT_S0) {
hfcsusb_ph_command(hw, HFC_L1_DEACTIVATE_NT);
spin_lock_irqsave(&hw->lock, flags);
skb_queue_purge(&dch->squeue);
if (dch->tx_skb) {
dev_kfree_skb(dch->tx_skb);
dch->tx_skb = NULL;
}
dch->tx_idx = 0;
if (dch->rx_skb) {
dev_kfree_skb(dch->rx_skb);
dch->rx_skb = NULL;
}
test_and_clear_bit(FLG_TX_BUSY, &dch->Flags);
spin_unlock_irqrestore(&hw->lock, flags);
#ifdef FIXME
if (test_and_clear_bit(FLG_L1_BUSY, &dch->Flags))
dchannel_sched_event(&hc->dch, D_CLEARBUSY);
#endif
ret = 0;
} else
ret = l1_event(dch->l1, hh->prim);
break;
case MPH_INFORMATION_REQ:
hfcsusb_ph_info(hw);
ret = 0;
break;
}
return ret;
}
/*
* Layer 1 callback function
*/
static int
hfc_l1callback(struct dchannel *dch, u_int cmd)
{
struct hfcsusb *hw = dch->hw;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s cmd 0x%x\n",
hw->name, __func__, cmd);
switch (cmd) {
case INFO3_P8:
case INFO3_P10:
case HW_RESET_REQ:
case HW_POWERUP_REQ:
break;
case HW_DEACT_REQ:
skb_queue_purge(&dch->squeue);
if (dch->tx_skb) {
dev_kfree_skb(dch->tx_skb);
dch->tx_skb = NULL;
}
dch->tx_idx = 0;
if (dch->rx_skb) {
dev_kfree_skb(dch->rx_skb);
dch->rx_skb = NULL;
}
test_and_clear_bit(FLG_TX_BUSY, &dch->Flags);
break;
case PH_ACTIVATE_IND:
test_and_set_bit(FLG_ACTIVE, &dch->Flags);
_queue_data(&dch->dev.D, cmd, MISDN_ID_ANY, 0, NULL,
GFP_ATOMIC);
break;
case PH_DEACTIVATE_IND:
test_and_clear_bit(FLG_ACTIVE, &dch->Flags);
_queue_data(&dch->dev.D, cmd, MISDN_ID_ANY, 0, NULL,
GFP_ATOMIC);
break;
default:
if (dch->debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: unknown cmd %x\n",
hw->name, __func__, cmd);
return -1;
}
hfcsusb_ph_info(hw);
return 0;
}
static int
open_dchannel(struct hfcsusb *hw, struct mISDNchannel *ch,
struct channel_req *rq)
{
int err = 0;
if (debug & DEBUG_HW_OPEN)
printk(KERN_DEBUG "%s: %s: dev(%d) open addr(%i) from %p\n",
hw->name, __func__, hw->dch.dev.id, rq->adr.channel,
__builtin_return_address(0));
if (rq->protocol == ISDN_P_NONE)
return -EINVAL;
test_and_clear_bit(FLG_ACTIVE, &hw->dch.Flags);
test_and_clear_bit(FLG_ACTIVE, &hw->ech.Flags);
hfcsusb_start_endpoint(hw, HFC_CHAN_D);
/* E-Channel logging */
if (rq->adr.channel == 1) {
if (hw->fifos[HFCUSB_PCM_RX].pipe) {
hfcsusb_start_endpoint(hw, HFC_CHAN_E);
set_bit(FLG_ACTIVE, &hw->ech.Flags);
_queue_data(&hw->ech.dev.D, PH_ACTIVATE_IND,
MISDN_ID_ANY, 0, NULL, GFP_ATOMIC);
} else
return -EINVAL;
}
if (!hw->initdone) {
hw->protocol = rq->protocol;
if (rq->protocol == ISDN_P_TE_S0) {
err = create_l1(&hw->dch, hfc_l1callback);
if (err)
return err;
}
setPortMode(hw);
ch->protocol = rq->protocol;
hw->initdone = 1;
} else {
if (rq->protocol != ch->protocol)
return -EPROTONOSUPPORT;
}
if (((ch->protocol == ISDN_P_NT_S0) && (hw->dch.state == 3)) ||
((ch->protocol == ISDN_P_TE_S0) && (hw->dch.state == 7)))
_queue_data(ch, PH_ACTIVATE_IND, MISDN_ID_ANY,
0, NULL, GFP_KERNEL);
rq->ch = ch;
if (!try_module_get(THIS_MODULE))
printk(KERN_WARNING "%s: %s: cannot get module\n",
hw->name, __func__);
return 0;
}
static int
open_bchannel(struct hfcsusb *hw, struct channel_req *rq)
{
struct bchannel *bch;
if (rq->adr.channel == 0 || rq->adr.channel > 2)
return -EINVAL;
if (rq->protocol == ISDN_P_NONE)
return -EINVAL;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s B%i\n",
hw->name, __func__, rq->adr.channel);
bch = &hw->bch[rq->adr.channel - 1];
if (test_and_set_bit(FLG_OPEN, &bch->Flags))
return -EBUSY; /* b-channel can be only open once */
bch->ch.protocol = rq->protocol;
rq->ch = &bch->ch;
if (!try_module_get(THIS_MODULE))
printk(KERN_WARNING "%s: %s:cannot get module\n",
hw->name, __func__);
return 0;
}
static int
channel_ctrl(struct hfcsusb *hw, struct mISDN_ctrl_req *cq)
{
int ret = 0;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s op(0x%x) channel(0x%x)\n",
hw->name, __func__, (cq->op), (cq->channel));
switch (cq->op) {
case MISDN_CTRL_GETOP:
cq->op = MISDN_CTRL_LOOP | MISDN_CTRL_CONNECT |
MISDN_CTRL_DISCONNECT;
break;
default:
printk(KERN_WARNING "%s: %s: unknown Op %x\n",
hw->name, __func__, cq->op);
ret = -EINVAL;
break;
}
return ret;
}
/*
* device control function
*/
static int
hfc_dctrl(struct mISDNchannel *ch, u_int cmd, void *arg)
{
struct mISDNdevice *dev = container_of(ch, struct mISDNdevice, D);
struct dchannel *dch = container_of(dev, struct dchannel, dev);
struct hfcsusb *hw = dch->hw;
struct channel_req *rq;
int err = 0;
if (dch->debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: cmd:%x %p\n",
hw->name, __func__, cmd, arg);
switch (cmd) {
case OPEN_CHANNEL:
rq = arg;
if ((rq->protocol == ISDN_P_TE_S0) ||
(rq->protocol == ISDN_P_NT_S0))
err = open_dchannel(hw, ch, rq);
else
err = open_bchannel(hw, rq);
if (!err)
hw->open++;
break;
case CLOSE_CHANNEL:
hw->open--;
if (debug & DEBUG_HW_OPEN)
printk(KERN_DEBUG
"%s: %s: dev(%d) close from %p (open %d)\n",
hw->name, __func__, hw->dch.dev.id,
__builtin_return_address(0), hw->open);
if (!hw->open) {
hfcsusb_stop_endpoint(hw, HFC_CHAN_D);
if (hw->fifos[HFCUSB_PCM_RX].pipe)
hfcsusb_stop_endpoint(hw, HFC_CHAN_E);
handle_led(hw, LED_POWER_ON);
}
module_put(THIS_MODULE);
break;
case CONTROL_CHANNEL:
err = channel_ctrl(hw, arg);
break;
default:
if (dch->debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: unknown command %x\n",
hw->name, __func__, cmd);
return -EINVAL;
}
return err;
}
/*
* S0 TE state change event handler
*/
static void
ph_state_te(struct dchannel *dch)
{
struct hfcsusb *hw = dch->hw;
if (debug & DEBUG_HW) {
if (dch->state <= HFC_MAX_TE_LAYER1_STATE)
printk(KERN_DEBUG "%s: %s: %s\n", hw->name, __func__,
HFC_TE_LAYER1_STATES[dch->state]);
else
printk(KERN_DEBUG "%s: %s: TE F%d\n",
hw->name, __func__, dch->state);
}
switch (dch->state) {
case 0:
l1_event(dch->l1, HW_RESET_IND);
break;
case 3:
l1_event(dch->l1, HW_DEACT_IND);
break;
case 5:
case 8:
l1_event(dch->l1, ANYSIGNAL);
break;
case 6:
l1_event(dch->l1, INFO2);
break;
case 7:
l1_event(dch->l1, INFO4_P8);
break;
}
if (dch->state == 7)
handle_led(hw, LED_S0_ON);
else
handle_led(hw, LED_S0_OFF);
}
/*
* S0 NT state change event handler
*/
static void
ph_state_nt(struct dchannel *dch)
{
struct hfcsusb *hw = dch->hw;
if (debug & DEBUG_HW) {
if (dch->state <= HFC_MAX_NT_LAYER1_STATE)
printk(KERN_DEBUG "%s: %s: %s\n",
hw->name, __func__,
HFC_NT_LAYER1_STATES[dch->state]);
else
printk(KERN_INFO DRIVER_NAME "%s: %s: NT G%d\n",
hw->name, __func__, dch->state);
}
switch (dch->state) {
case (1):
test_and_clear_bit(FLG_ACTIVE, &dch->Flags);
test_and_clear_bit(FLG_L2_ACTIVATED, &dch->Flags);
hw->nt_timer = 0;
hw->timers &= ~NT_ACTIVATION_TIMER;
handle_led(hw, LED_S0_OFF);
break;
case (2):
if (hw->nt_timer < 0) {
hw->nt_timer = 0;
hw->timers &= ~NT_ACTIVATION_TIMER;
hfcsusb_ph_command(dch->hw, HFC_L1_DEACTIVATE_NT);
} else {
hw->timers |= NT_ACTIVATION_TIMER;
hw->nt_timer = NT_T1_COUNT;
/* allow G2 -> G3 transition */
write_reg(hw, HFCUSB_STATES, 2 | HFCUSB_NT_G2_G3);
}
break;
case (3):
hw->nt_timer = 0;
hw->timers &= ~NT_ACTIVATION_TIMER;
test_and_set_bit(FLG_ACTIVE, &dch->Flags);
_queue_data(&dch->dev.D, PH_ACTIVATE_IND,
MISDN_ID_ANY, 0, NULL, GFP_ATOMIC);
handle_led(hw, LED_S0_ON);
break;
case (4):
hw->nt_timer = 0;
hw->timers &= ~NT_ACTIVATION_TIMER;
break;
default:
break;
}
hfcsusb_ph_info(hw);
}
static void
ph_state(struct dchannel *dch)
{
struct hfcsusb *hw = dch->hw;
if (hw->protocol == ISDN_P_NT_S0)
ph_state_nt(dch);
else if (hw->protocol == ISDN_P_TE_S0)
ph_state_te(dch);
}
/*
* disable/enable BChannel for desired protocoll
*/
static int
hfcsusb_setup_bch(struct bchannel *bch, int protocol)
{
struct hfcsusb *hw = bch->hw;
__u8 conhdlc, sctrl, sctrl_r;
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: protocol %x-->%x B%d\n",
hw->name, __func__, bch->state, protocol,
bch->nr);
/* setup val for CON_HDLC */
conhdlc = 0;
if (protocol > ISDN_P_NONE)
conhdlc = 8; /* enable FIFO */
switch (protocol) {
case (-1): /* used for init */
bch->state = -1;
/* fall through */
case (ISDN_P_NONE):
if (bch->state == ISDN_P_NONE)
return 0; /* already in idle state */
bch->state = ISDN_P_NONE;
clear_bit(FLG_HDLC, &bch->Flags);
clear_bit(FLG_TRANSPARENT, &bch->Flags);
break;
case (ISDN_P_B_RAW):
conhdlc |= 2;
bch->state = protocol;
set_bit(FLG_TRANSPARENT, &bch->Flags);
break;
case (ISDN_P_B_HDLC):
bch->state = protocol;
set_bit(FLG_HDLC, &bch->Flags);
break;
default:
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: prot not known %x\n",
hw->name, __func__, protocol);
return -ENOPROTOOPT;
}
if (protocol >= ISDN_P_NONE) {
write_reg(hw, HFCUSB_FIFO, (bch->nr == 1) ? 0 : 2);
write_reg(hw, HFCUSB_CON_HDLC, conhdlc);
write_reg(hw, HFCUSB_INC_RES_F, 2);
write_reg(hw, HFCUSB_FIFO, (bch->nr == 1) ? 1 : 3);
write_reg(hw, HFCUSB_CON_HDLC, conhdlc);
write_reg(hw, HFCUSB_INC_RES_F, 2);
sctrl = 0x40 + ((hw->protocol == ISDN_P_TE_S0) ? 0x00 : 0x04);
sctrl_r = 0x0;
if (test_bit(FLG_ACTIVE, &hw->bch[0].Flags)) {
sctrl |= 1;
sctrl_r |= 1;
}
if (test_bit(FLG_ACTIVE, &hw->bch[1].Flags)) {
sctrl |= 2;
sctrl_r |= 2;
}
write_reg(hw, HFCUSB_SCTRL, sctrl);
write_reg(hw, HFCUSB_SCTRL_R, sctrl_r);
if (protocol > ISDN_P_NONE)
handle_led(hw, (bch->nr == 1) ? LED_B1_ON : LED_B2_ON);
else
handle_led(hw, (bch->nr == 1) ? LED_B1_OFF :
LED_B2_OFF);
}
hfcsusb_ph_info(hw);
return 0;
}
static void
hfcsusb_ph_command(struct hfcsusb *hw, u_char command)
{
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: %x\n",
hw->name, __func__, command);
switch (command) {
case HFC_L1_ACTIVATE_TE:
/* force sending sending INFO1 */
write_reg(hw, HFCUSB_STATES, 0x14);
/* start l1 activation */
write_reg(hw, HFCUSB_STATES, 0x04);
break;
case HFC_L1_FORCE_DEACTIVATE_TE:
write_reg(hw, HFCUSB_STATES, 0x10);
write_reg(hw, HFCUSB_STATES, 0x03);
break;
case HFC_L1_ACTIVATE_NT:
if (hw->dch.state == 3)
_queue_data(&hw->dch.dev.D, PH_ACTIVATE_IND,
MISDN_ID_ANY, 0, NULL, GFP_ATOMIC);
else
write_reg(hw, HFCUSB_STATES, HFCUSB_ACTIVATE |
HFCUSB_DO_ACTION | HFCUSB_NT_G2_G3);
break;
case HFC_L1_DEACTIVATE_NT:
write_reg(hw, HFCUSB_STATES,
HFCUSB_DO_ACTION);
break;
}
}
/*
* Layer 1 B-channel hardware access
*/
static int
channel_bctrl(struct bchannel *bch, struct mISDN_ctrl_req *cq)
{
return mISDN_ctrl_bchannel(bch, cq);
}
/* collect data from incoming interrupt or isochron USB data */
static void
hfcsusb_rx_frame(struct usb_fifo *fifo, __u8 *data, unsigned int len,
int finish)
{
struct hfcsusb *hw = fifo->hw;
struct sk_buff *rx_skb = NULL;
int maxlen = 0;
int fifon = fifo->fifonum;
int i;
int hdlc = 0;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s: fifo(%i) len(%i) "
"dch(%p) bch(%p) ech(%p)\n",
hw->name, __func__, fifon, len,
fifo->dch, fifo->bch, fifo->ech);
if (!len)
return;
if ((!!fifo->dch + !!fifo->bch + !!fifo->ech) != 1) {
printk(KERN_DEBUG "%s: %s: undefined channel\n",
hw->name, __func__);
return;
}
spin_lock(&hw->lock);
if (fifo->dch) {
rx_skb = fifo->dch->rx_skb;
maxlen = fifo->dch->maxlen;
hdlc = 1;
}
if (fifo->bch) {
maxlen = bchannel_get_rxbuf(fifo->bch, len);
rx_skb = fifo->bch->rx_skb;
if (maxlen < 0) {
if (rx_skb)
skb_trim(rx_skb, 0);
pr_warning("%s.B%d: No bufferspace for %d bytes\n",
hw->name, fifo->bch->nr, len);
spin_unlock(&hw->lock);
return;
}
maxlen = fifo->bch->maxlen;
hdlc = test_bit(FLG_HDLC, &fifo->bch->Flags);
}
if (fifo->ech) {
rx_skb = fifo->ech->rx_skb;
maxlen = fifo->ech->maxlen;
hdlc = 1;
}
if (fifo->dch || fifo->ech) {
if (!rx_skb) {
rx_skb = mI_alloc_skb(maxlen, GFP_ATOMIC);
if (rx_skb) {
if (fifo->dch)
fifo->dch->rx_skb = rx_skb;
if (fifo->ech)
fifo->ech->rx_skb = rx_skb;
skb_trim(rx_skb, 0);
} else {
printk(KERN_DEBUG "%s: %s: No mem for rx_skb\n",
hw->name, __func__);
spin_unlock(&hw->lock);
return;
}
}
/* D/E-Channel SKB range check */
if ((rx_skb->len + len) >= MAX_DFRAME_LEN_L1) {
printk(KERN_DEBUG "%s: %s: sbk mem exceeded "
"for fifo(%d) HFCUSB_D_RX\n",
hw->name, __func__, fifon);
skb_trim(rx_skb, 0);
spin_unlock(&hw->lock);
return;
}
}
memcpy(skb_put(rx_skb, len), data, len);
if (hdlc) {
/* we have a complete hdlc packet */
if (finish) {
if ((rx_skb->len > 3) &&
(!(rx_skb->data[rx_skb->len - 1]))) {
if (debug & DBG_HFC_FIFO_VERBOSE) {
printk(KERN_DEBUG "%s: %s: fifon(%i)"
" new RX len(%i): ",
hw->name, __func__, fifon,
rx_skb->len);
i = 0;
while (i < rx_skb->len)
printk("%02x ",
rx_skb->data[i++]);
printk("\n");
}
/* remove CRC & status */
skb_trim(rx_skb, rx_skb->len - 3);
if (fifo->dch)
recv_Dchannel(fifo->dch);
if (fifo->bch)
recv_Bchannel(fifo->bch, MISDN_ID_ANY,
0);
if (fifo->ech)
recv_Echannel(fifo->ech,
&hw->dch);
} else {
if (debug & DBG_HFC_FIFO_VERBOSE) {
printk(KERN_DEBUG
"%s: CRC or minlen ERROR fifon(%i) "
"RX len(%i): ",
hw->name, fifon, rx_skb->len);
i = 0;
while (i < rx_skb->len)
printk("%02x ",
rx_skb->data[i++]);
printk("\n");
}
skb_trim(rx_skb, 0);
}
}
} else {
/* deliver transparent data to layer2 */
recv_Bchannel(fifo->bch, MISDN_ID_ANY, false);
}
spin_unlock(&hw->lock);
}
static void
fill_isoc_urb(struct urb *urb, struct usb_device *dev, unsigned int pipe,
void *buf, int num_packets, int packet_size, int interval,
usb_complete_t complete, void *context)
{
int k;
usb_fill_bulk_urb(urb, dev, pipe, buf, packet_size * num_packets,
complete, context);
urb->number_of_packets = num_packets;
urb->transfer_flags = URB_ISO_ASAP;
urb->actual_length = 0;
urb->interval = interval;
for (k = 0; k < num_packets; k++) {
urb->iso_frame_desc[k].offset = packet_size * k;
urb->iso_frame_desc[k].length = packet_size;
urb->iso_frame_desc[k].actual_length = 0;
}
}
/* receive completion routine for all ISO tx fifos */
static void
rx_iso_complete(struct urb *urb)
{
struct iso_urb *context_iso_urb = (struct iso_urb *) urb->context;
struct usb_fifo *fifo = context_iso_urb->owner_fifo;
struct hfcsusb *hw = fifo->hw;
int k, len, errcode, offset, num_isoc_packets, fifon, maxlen,
status, iso_status, i;
__u8 *buf;
static __u8 eof[8];
__u8 s0_state;
fifon = fifo->fifonum;
status = urb->status;
spin_lock(&hw->lock);
if (fifo->stop_gracefull) {
fifo->stop_gracefull = 0;
fifo->active = 0;
spin_unlock(&hw->lock);
return;
}
spin_unlock(&hw->lock);
/*
* ISO transfer only partially completed,
* look at individual frame status for details
*/
if (status == -EXDEV) {
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: with -EXDEV "
"urb->status %d, fifonum %d\n",
hw->name, __func__, status, fifon);
/* clear status, so go on with ISO transfers */
status = 0;
}
s0_state = 0;
if (fifo->active && !status) {
num_isoc_packets = iso_packets[fifon];
maxlen = fifo->usb_packet_maxlen;
for (k = 0; k < num_isoc_packets; ++k) {
len = urb->iso_frame_desc[k].actual_length;
offset = urb->iso_frame_desc[k].offset;
buf = context_iso_urb->buffer + offset;
iso_status = urb->iso_frame_desc[k].status;
if (iso_status && (debug & DBG_HFC_FIFO_VERBOSE)) {
printk(KERN_DEBUG "%s: %s: "
"ISO packet %i, status: %i\n",
hw->name, __func__, k, iso_status);
}
/* USB data log for every D ISO in */
if ((fifon == HFCUSB_D_RX) &&
(debug & DBG_HFC_USB_VERBOSE)) {
printk(KERN_DEBUG
"%s: %s: %d (%d/%d) len(%d) ",
hw->name, __func__, urb->start_frame,
k, num_isoc_packets - 1,
len);
for (i = 0; i < len; i++)
printk("%x ", buf[i]);
printk("\n");
}
if (!iso_status) {
if (fifo->last_urblen != maxlen) {
/*
* save fifo fill-level threshold bits
* to use them later in TX ISO URB
* completions
*/
hw->threshold_mask = buf[1];
if (fifon == HFCUSB_D_RX)
s0_state = (buf[0] >> 4);
eof[fifon] = buf[0] & 1;
if (len > 2)
hfcsusb_rx_frame(fifo, buf + 2,
len - 2, (len < maxlen)
? eof[fifon] : 0);
} else
hfcsusb_rx_frame(fifo, buf, len,
(len < maxlen) ?
eof[fifon] : 0);
fifo->last_urblen = len;
}
}
/* signal S0 layer1 state change */
if ((s0_state) && (hw->initdone) &&
(s0_state != hw->dch.state)) {
hw->dch.state = s0_state;
schedule_event(&hw->dch, FLG_PHCHANGE);
}
fill_isoc_urb(urb, fifo->hw->dev, fifo->pipe,
context_iso_urb->buffer, num_isoc_packets,
fifo->usb_packet_maxlen, fifo->intervall,
(usb_complete_t)rx_iso_complete, urb->context);
errcode = usb_submit_urb(urb, GFP_ATOMIC);
if (errcode < 0) {
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: error submitting "
"ISO URB: %d\n",
hw->name, __func__, errcode);
}
} else {
if (status && (debug & DBG_HFC_URB_INFO))
printk(KERN_DEBUG "%s: %s: rx_iso_complete : "
"urb->status %d, fifonum %d\n",
hw->name, __func__, status, fifon);
}
}
/* receive completion routine for all interrupt rx fifos */
static void
rx_int_complete(struct urb *urb)
{
int len, status, i;
__u8 *buf, maxlen, fifon;
struct usb_fifo *fifo = (struct usb_fifo *) urb->context;
struct hfcsusb *hw = fifo->hw;
static __u8 eof[8];
spin_lock(&hw->lock);
if (fifo->stop_gracefull) {
fifo->stop_gracefull = 0;
fifo->active = 0;
spin_unlock(&hw->lock);
return;
}
spin_unlock(&hw->lock);
fifon = fifo->fifonum;
if ((!fifo->active) || (urb->status)) {
if (debug & DBG_HFC_URB_ERROR)
printk(KERN_DEBUG
"%s: %s: RX-Fifo %i is going down (%i)\n",
hw->name, __func__, fifon, urb->status);
fifo->urb->interval = 0; /* cancel automatic rescheduling */
return;
}
len = urb->actual_length;
buf = fifo->buffer;
maxlen = fifo->usb_packet_maxlen;
/* USB data log for every D INT in */
if ((fifon == HFCUSB_D_RX) && (debug & DBG_HFC_USB_VERBOSE)) {
printk(KERN_DEBUG "%s: %s: D RX INT len(%d) ",
hw->name, __func__, len);
for (i = 0; i < len; i++)
printk("%02x ", buf[i]);
printk("\n");
}
if (fifo->last_urblen != fifo->usb_packet_maxlen) {
/* the threshold mask is in the 2nd status byte */
hw->threshold_mask = buf[1];
/* signal S0 layer1 state change */
if (hw->initdone && ((buf[0] >> 4) != hw->dch.state)) {
hw->dch.state = (buf[0] >> 4);
schedule_event(&hw->dch, FLG_PHCHANGE);
}
eof[fifon] = buf[0] & 1;
/* if we have more than the 2 status bytes -> collect data */
if (len > 2)
hfcsusb_rx_frame(fifo, buf + 2,
urb->actual_length - 2,
(len < maxlen) ? eof[fifon] : 0);
} else {
hfcsusb_rx_frame(fifo, buf, urb->actual_length,
(len < maxlen) ? eof[fifon] : 0);
}
fifo->last_urblen = urb->actual_length;
status = usb_submit_urb(urb, GFP_ATOMIC);
if (status) {
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: error resubmitting USB\n",
hw->name, __func__);
}
}
/* transmit completion routine for all ISO tx fifos */
static void
tx_iso_complete(struct urb *urb)
{
struct iso_urb *context_iso_urb = (struct iso_urb *) urb->context;
struct usb_fifo *fifo = context_iso_urb->owner_fifo;
struct hfcsusb *hw = fifo->hw;
struct sk_buff *tx_skb;
int k, tx_offset, num_isoc_packets, sink, remain, current_len,
errcode, hdlc, i;
int *tx_idx;
int frame_complete, fifon, status, fillempty = 0;
__u8 threshbit, *p;
spin_lock(&hw->lock);
if (fifo->stop_gracefull) {
fifo->stop_gracefull = 0;
fifo->active = 0;
spin_unlock(&hw->lock);
return;
}
if (fifo->dch) {
tx_skb = fifo->dch->tx_skb;
tx_idx = &fifo->dch->tx_idx;
hdlc = 1;
} else if (fifo->bch) {
tx_skb = fifo->bch->tx_skb;
tx_idx = &fifo->bch->tx_idx;
hdlc = test_bit(FLG_HDLC, &fifo->bch->Flags);
if (!tx_skb && !hdlc &&
test_bit(FLG_FILLEMPTY, &fifo->bch->Flags))
fillempty = 1;
} else {
printk(KERN_DEBUG "%s: %s: neither BCH nor DCH\n",
hw->name, __func__);
spin_unlock(&hw->lock);
return;
}
fifon = fifo->fifonum;
status = urb->status;
tx_offset = 0;
/*
* ISO transfer only partially completed,
* look at individual frame status for details
*/
if (status == -EXDEV) {
if (debug & DBG_HFC_URB_ERROR)
printk(KERN_DEBUG "%s: %s: "
"-EXDEV (%i) fifon (%d)\n",
hw->name, __func__, status, fifon);
/* clear status, so go on with ISO transfers */
status = 0;
}
if (fifo->active && !status) {
/* is FifoFull-threshold set for our channel? */
threshbit = (hw->threshold_mask & (1 << fifon));
num_isoc_packets = iso_packets[fifon];
/* predict dataflow to avoid fifo overflow */
if (fifon >= HFCUSB_D_TX)
sink = (threshbit) ? SINK_DMIN : SINK_DMAX;
else
sink = (threshbit) ? SINK_MIN : SINK_MAX;
fill_isoc_urb(urb, fifo->hw->dev, fifo->pipe,
context_iso_urb->buffer, num_isoc_packets,
fifo->usb_packet_maxlen, fifo->intervall,
(usb_complete_t)tx_iso_complete, urb->context);
memset(context_iso_urb->buffer, 0,
sizeof(context_iso_urb->buffer));
frame_complete = 0;
for (k = 0; k < num_isoc_packets; ++k) {
/* analyze tx success of previous ISO packets */
if (debug & DBG_HFC_URB_ERROR) {
errcode = urb->iso_frame_desc[k].status;
if (errcode) {
printk(KERN_DEBUG "%s: %s: "
"ISO packet %i, status: %i\n",
hw->name, __func__, k, errcode);
}
}
/* Generate next ISO Packets */
if (tx_skb)
remain = tx_skb->len - *tx_idx;
else if (fillempty)
remain = 15; /* > not complete */
else
remain = 0;
if (remain > 0) {
fifo->bit_line -= sink;
current_len = (0 - fifo->bit_line) / 8;
if (current_len > 14)
current_len = 14;
if (current_len < 0)
current_len = 0;
if (remain < current_len)
current_len = remain;
/* how much bit do we put on the line? */
fifo->bit_line += current_len * 8;
context_iso_urb->buffer[tx_offset] = 0;
if (current_len == remain) {
if (hdlc) {
/* signal frame completion */
context_iso_urb->
buffer[tx_offset] = 1;
/* add 2 byte flags and 16bit
* CRC at end of ISDN frame */
fifo->bit_line += 32;
}
frame_complete = 1;
}
/* copy tx data to iso-urb buffer */
p = context_iso_urb->buffer + tx_offset + 1;
if (fillempty) {
memset(p, fifo->bch->fill[0],
current_len);
} else {
memcpy(p, (tx_skb->data + *tx_idx),
current_len);
*tx_idx += current_len;
}
urb->iso_frame_desc[k].offset = tx_offset;
urb->iso_frame_desc[k].length = current_len + 1;
/* USB data log for every D ISO out */
if ((fifon == HFCUSB_D_RX) && !fillempty &&
(debug & DBG_HFC_USB_VERBOSE)) {
printk(KERN_DEBUG
"%s: %s (%d/%d) offs(%d) len(%d) ",
hw->name, __func__,
k, num_isoc_packets - 1,
urb->iso_frame_desc[k].offset,
urb->iso_frame_desc[k].length);
for (i = urb->iso_frame_desc[k].offset;
i < (urb->iso_frame_desc[k].offset
+ urb->iso_frame_desc[k].length);
i++)
printk("%x ",
context_iso_urb->buffer[i]);
printk(" skb->len(%i) tx-idx(%d)\n",
tx_skb->len, *tx_idx);
}
tx_offset += (current_len + 1);
} else {
urb->iso_frame_desc[k].offset = tx_offset++;
urb->iso_frame_desc[k].length = 1;
/* we lower data margin every msec */
fifo->bit_line -= sink;
if (fifo->bit_line < BITLINE_INF)
fifo->bit_line = BITLINE_INF;
}
if (frame_complete) {
frame_complete = 0;
if (debug & DBG_HFC_FIFO_VERBOSE) {
printk(KERN_DEBUG "%s: %s: "
"fifon(%i) new TX len(%i): ",
hw->name, __func__,
fifon, tx_skb->len);
i = 0;
while (i < tx_skb->len)
printk("%02x ",
tx_skb->data[i++]);
printk("\n");
}
dev_kfree_skb(tx_skb);
tx_skb = NULL;
if (fifo->dch && get_next_dframe(fifo->dch))
tx_skb = fifo->dch->tx_skb;
else if (fifo->bch &&
get_next_bframe(fifo->bch))
tx_skb = fifo->bch->tx_skb;
}
}
errcode = usb_submit_urb(urb, GFP_ATOMIC);
if (errcode < 0) {
if (debug & DEBUG_HW)
printk(KERN_DEBUG
"%s: %s: error submitting ISO URB: %d \n",
hw->name, __func__, errcode);
}
/*
* abuse DChannel tx iso completion to trigger NT mode state
* changes tx_iso_complete is assumed to be called every
* fifo->intervall (ms)
*/
if ((fifon == HFCUSB_D_TX) && (hw->protocol == ISDN_P_NT_S0)
&& (hw->timers & NT_ACTIVATION_TIMER)) {
if ((--hw->nt_timer) < 0)
schedule_event(&hw->dch, FLG_PHCHANGE);
}
} else {
if (status && (debug & DBG_HFC_URB_ERROR))
printk(KERN_DEBUG "%s: %s: urb->status %s (%i)"
"fifonum=%d\n",
hw->name, __func__,
symbolic(urb_errlist, status), status, fifon);
}
spin_unlock(&hw->lock);
}
/*
* allocs urbs and start isoc transfer with two pending urbs to avoid
* gaps in the transfer chain
*/
static int
start_isoc_chain(struct usb_fifo *fifo, int num_packets_per_urb,
usb_complete_t complete, int packet_size)
{
struct hfcsusb *hw = fifo->hw;
int i, k, errcode;
if (debug)
printk(KERN_DEBUG "%s: %s: fifo %i\n",
hw->name, __func__, fifo->fifonum);
/* allocate Memory for Iso out Urbs */
for (i = 0; i < 2; i++) {
if (!(fifo->iso[i].urb)) {
fifo->iso[i].urb =
usb_alloc_urb(num_packets_per_urb, GFP_KERNEL);
if (!(fifo->iso[i].urb)) {
printk(KERN_DEBUG
"%s: %s: alloc urb for fifo %i failed",
hw->name, __func__, fifo->fifonum);
}
fifo->iso[i].owner_fifo = (struct usb_fifo *) fifo;
fifo->iso[i].indx = i;
/* Init the first iso */
if (ISO_BUFFER_SIZE >=
(fifo->usb_packet_maxlen *
num_packets_per_urb)) {
fill_isoc_urb(fifo->iso[i].urb,
fifo->hw->dev, fifo->pipe,
fifo->iso[i].buffer,
num_packets_per_urb,
fifo->usb_packet_maxlen,
fifo->intervall, complete,
&fifo->iso[i]);
memset(fifo->iso[i].buffer, 0,
sizeof(fifo->iso[i].buffer));
for (k = 0; k < num_packets_per_urb; k++) {
fifo->iso[i].urb->
iso_frame_desc[k].offset =
k * packet_size;
fifo->iso[i].urb->
iso_frame_desc[k].length =
packet_size;
}
} else {
printk(KERN_DEBUG
"%s: %s: ISO Buffer size to small!\n",
hw->name, __func__);
}
}
fifo->bit_line = BITLINE_INF;
errcode = usb_submit_urb(fifo->iso[i].urb, GFP_KERNEL);
fifo->active = (errcode >= 0) ? 1 : 0;
fifo->stop_gracefull = 0;
if (errcode < 0) {
printk(KERN_DEBUG "%s: %s: %s URB nr:%d\n",
hw->name, __func__,
symbolic(urb_errlist, errcode), i);
}
}
return fifo->active;
}
static void
stop_iso_gracefull(struct usb_fifo *fifo)
{
struct hfcsusb *hw = fifo->hw;
int i, timeout;
u_long flags;
for (i = 0; i < 2; i++) {
spin_lock_irqsave(&hw->lock, flags);
if (debug)
printk(KERN_DEBUG "%s: %s for fifo %i.%i\n",
hw->name, __func__, fifo->fifonum, i);
fifo->stop_gracefull = 1;
spin_unlock_irqrestore(&hw->lock, flags);
}
for (i = 0; i < 2; i++) {
timeout = 3;
while (fifo->stop_gracefull && timeout--)
schedule_timeout_interruptible((HZ / 1000) * 16);
if (debug && fifo->stop_gracefull)
printk(KERN_DEBUG "%s: ERROR %s for fifo %i.%i\n",
hw->name, __func__, fifo->fifonum, i);
}
}
static void
stop_int_gracefull(struct usb_fifo *fifo)
{
struct hfcsusb *hw = fifo->hw;
int timeout;
u_long flags;
spin_lock_irqsave(&hw->lock, flags);
if (debug)
printk(KERN_DEBUG "%s: %s for fifo %i\n",
hw->name, __func__, fifo->fifonum);
fifo->stop_gracefull = 1;
spin_unlock_irqrestore(&hw->lock, flags);
timeout = 3;
while (fifo->stop_gracefull && timeout--)
schedule_timeout_interruptible((HZ / 1000) * 3);
if (debug && fifo->stop_gracefull)
printk(KERN_DEBUG "%s: ERROR %s for fifo %i\n",
hw->name, __func__, fifo->fifonum);
}
/* start the interrupt transfer for the given fifo */
static void
start_int_fifo(struct usb_fifo *fifo)
{
struct hfcsusb *hw = fifo->hw;
int errcode;
if (debug)
printk(KERN_DEBUG "%s: %s: INT IN fifo:%d\n",
hw->name, __func__, fifo->fifonum);
if (!fifo->urb) {
fifo->urb = usb_alloc_urb(0, GFP_KERNEL);
if (!fifo->urb)
return;
}
usb_fill_int_urb(fifo->urb, fifo->hw->dev, fifo->pipe,
fifo->buffer, fifo->usb_packet_maxlen,
(usb_complete_t)rx_int_complete, fifo, fifo->intervall);
fifo->active = 1;
fifo->stop_gracefull = 0;
errcode = usb_submit_urb(fifo->urb, GFP_KERNEL);
if (errcode) {
printk(KERN_DEBUG "%s: %s: submit URB: status:%i\n",
hw->name, __func__, errcode);
fifo->active = 0;
}
}
static void
setPortMode(struct hfcsusb *hw)
{
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s %s\n", hw->name, __func__,
(hw->protocol == ISDN_P_TE_S0) ? "TE" : "NT");
if (hw->protocol == ISDN_P_TE_S0) {
write_reg(hw, HFCUSB_SCTRL, 0x40);
write_reg(hw, HFCUSB_SCTRL_E, 0x00);
write_reg(hw, HFCUSB_CLKDEL, CLKDEL_TE);
write_reg(hw, HFCUSB_STATES, 3 | 0x10);
write_reg(hw, HFCUSB_STATES, 3);
} else {
write_reg(hw, HFCUSB_SCTRL, 0x44);
write_reg(hw, HFCUSB_SCTRL_E, 0x09);
write_reg(hw, HFCUSB_CLKDEL, CLKDEL_NT);
write_reg(hw, HFCUSB_STATES, 1 | 0x10);
write_reg(hw, HFCUSB_STATES, 1);
}
}
static void
reset_hfcsusb(struct hfcsusb *hw)
{
struct usb_fifo *fifo;
int i;
if (debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s\n", hw->name, __func__);
/* do Chip reset */
write_reg(hw, HFCUSB_CIRM, 8);
/* aux = output, reset off */
write_reg(hw, HFCUSB_CIRM, 0x10);
/* set USB_SIZE to match the wMaxPacketSize for INT or BULK transfers */
write_reg(hw, HFCUSB_USB_SIZE, (hw->packet_size / 8) |
((hw->packet_size / 8) << 4));
/* set USB_SIZE_I to match the the wMaxPacketSize for ISO transfers */
write_reg(hw, HFCUSB_USB_SIZE_I, hw->iso_packet_size);
/* enable PCM/GCI master mode */
write_reg(hw, HFCUSB_MST_MODE1, 0); /* set default values */
write_reg(hw, HFCUSB_MST_MODE0, 1); /* enable master mode */
/* init the fifos */
write_reg(hw, HFCUSB_F_THRES,
(HFCUSB_TX_THRESHOLD / 8) | ((HFCUSB_RX_THRESHOLD / 8) << 4));
fifo = hw->fifos;
for (i = 0; i < HFCUSB_NUM_FIFOS; i++) {
write_reg(hw, HFCUSB_FIFO, i); /* select the desired fifo */
fifo[i].max_size =
(i <= HFCUSB_B2_RX) ? MAX_BCH_SIZE : MAX_DFRAME_LEN;
fifo[i].last_urblen = 0;
/* set 2 bit for D- & E-channel */
write_reg(hw, HFCUSB_HDLC_PAR, ((i <= HFCUSB_B2_RX) ? 0 : 2));
/* enable all fifos */
if (i == HFCUSB_D_TX)
write_reg(hw, HFCUSB_CON_HDLC,
(hw->protocol == ISDN_P_NT_S0) ? 0x08 : 0x09);
else
write_reg(hw, HFCUSB_CON_HDLC, 0x08);
write_reg(hw, HFCUSB_INC_RES_F, 2); /* reset the fifo */
}
write_reg(hw, HFCUSB_SCTRL_R, 0); /* disable both B receivers */
handle_led(hw, LED_POWER_ON);
}
/* start USB data pipes dependand on device's endpoint configuration */
static void
hfcsusb_start_endpoint(struct hfcsusb *hw, int channel)
{
/* quick check if endpoint already running */
if ((channel == HFC_CHAN_D) && (hw->fifos[HFCUSB_D_RX].active))
return;
if ((channel == HFC_CHAN_B1) && (hw->fifos[HFCUSB_B1_RX].active))
return;
if ((channel == HFC_CHAN_B2) && (hw->fifos[HFCUSB_B2_RX].active))
return;
if ((channel == HFC_CHAN_E) && (hw->fifos[HFCUSB_PCM_RX].active))
return;
/* start rx endpoints using USB INT IN method */
if (hw->cfg_used == CNF_3INT3ISO || hw->cfg_used == CNF_4INT3ISO)
start_int_fifo(hw->fifos + channel * 2 + 1);
/* start rx endpoints using USB ISO IN method */
if (hw->cfg_used == CNF_3ISO3ISO || hw->cfg_used == CNF_4ISO3ISO) {
switch (channel) {
case HFC_CHAN_D:
start_isoc_chain(hw->fifos + HFCUSB_D_RX,
ISOC_PACKETS_D,
(usb_complete_t)rx_iso_complete,
16);
break;
case HFC_CHAN_E:
start_isoc_chain(hw->fifos + HFCUSB_PCM_RX,
ISOC_PACKETS_D,
(usb_complete_t)rx_iso_complete,
16);
break;
case HFC_CHAN_B1:
start_isoc_chain(hw->fifos + HFCUSB_B1_RX,
ISOC_PACKETS_B,
(usb_complete_t)rx_iso_complete,
16);
break;
case HFC_CHAN_B2:
start_isoc_chain(hw->fifos + HFCUSB_B2_RX,
ISOC_PACKETS_B,
(usb_complete_t)rx_iso_complete,
16);
break;
}
}
/* start tx endpoints using USB ISO OUT method */
switch (channel) {
case HFC_CHAN_D:
start_isoc_chain(hw->fifos + HFCUSB_D_TX,
ISOC_PACKETS_B,
(usb_complete_t)tx_iso_complete, 1);
break;
case HFC_CHAN_B1:
start_isoc_chain(hw->fifos + HFCUSB_B1_TX,
ISOC_PACKETS_D,
(usb_complete_t)tx_iso_complete, 1);
break;
case HFC_CHAN_B2:
start_isoc_chain(hw->fifos + HFCUSB_B2_TX,
ISOC_PACKETS_B,
(usb_complete_t)tx_iso_complete, 1);
break;
}
}
/* stop USB data pipes dependand on device's endpoint configuration */
static void
hfcsusb_stop_endpoint(struct hfcsusb *hw, int channel)
{
/* quick check if endpoint currently running */
if ((channel == HFC_CHAN_D) && (!hw->fifos[HFCUSB_D_RX].active))
return;
if ((channel == HFC_CHAN_B1) && (!hw->fifos[HFCUSB_B1_RX].active))
return;
if ((channel == HFC_CHAN_B2) && (!hw->fifos[HFCUSB_B2_RX].active))
return;
if ((channel == HFC_CHAN_E) && (!hw->fifos[HFCUSB_PCM_RX].active))
return;
/* rx endpoints using USB INT IN method */
if (hw->cfg_used == CNF_3INT3ISO || hw->cfg_used == CNF_4INT3ISO)
stop_int_gracefull(hw->fifos + channel * 2 + 1);
/* rx endpoints using USB ISO IN method */
if (hw->cfg_used == CNF_3ISO3ISO || hw->cfg_used == CNF_4ISO3ISO)
stop_iso_gracefull(hw->fifos + channel * 2 + 1);
/* tx endpoints using USB ISO OUT method */
if (channel != HFC_CHAN_E)
stop_iso_gracefull(hw->fifos + channel * 2);
}
/* Hardware Initialization */
static int
setup_hfcsusb(struct hfcsusb *hw)
{
u_char b;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s\n", hw->name, __func__);
/* check the chip id */
if (read_reg_atomic(hw, HFCUSB_CHIP_ID, &b) != 1) {
printk(KERN_DEBUG "%s: %s: cannot read chip id\n",
hw->name, __func__);
return 1;
}
if (b != HFCUSB_CHIPID) {
printk(KERN_DEBUG "%s: %s: Invalid chip id 0x%02x\n",
hw->name, __func__, b);
return 1;
}
/* first set the needed config, interface and alternate */
(void) usb_set_interface(hw->dev, hw->if_used, hw->alt_used);
hw->led_state = 0;
/* init the background machinery for control requests */
hw->ctrl_read.bRequestType = 0xc0;
hw->ctrl_read.bRequest = 1;
hw->ctrl_read.wLength = cpu_to_le16(1);
hw->ctrl_write.bRequestType = 0x40;
hw->ctrl_write.bRequest = 0;
hw->ctrl_write.wLength = 0;
usb_fill_control_urb(hw->ctrl_urb, hw->dev, hw->ctrl_out_pipe,
(u_char *)&hw->ctrl_write, NULL, 0,
(usb_complete_t)ctrl_complete, hw);
reset_hfcsusb(hw);
return 0;
}
static void
release_hw(struct hfcsusb *hw)
{
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s\n", hw->name, __func__);
/*
* stop all endpoints gracefully
* TODO: mISDN_core should generate CLOSE_CHANNEL
* signals after calling mISDN_unregister_device()
*/
hfcsusb_stop_endpoint(hw, HFC_CHAN_D);
hfcsusb_stop_endpoint(hw, HFC_CHAN_B1);
hfcsusb_stop_endpoint(hw, HFC_CHAN_B2);
if (hw->fifos[HFCUSB_PCM_RX].pipe)
hfcsusb_stop_endpoint(hw, HFC_CHAN_E);
if (hw->protocol == ISDN_P_TE_S0)
l1_event(hw->dch.l1, CLOSE_CHANNEL);
mISDN_unregister_device(&hw->dch.dev);
mISDN_freebchannel(&hw->bch[1]);
mISDN_freebchannel(&hw->bch[0]);
mISDN_freedchannel(&hw->dch);
if (hw->ctrl_urb) {
usb_kill_urb(hw->ctrl_urb);
usb_free_urb(hw->ctrl_urb);
hw->ctrl_urb = NULL;
}
if (hw->intf)
usb_set_intfdata(hw->intf, NULL);
list_del(&hw->list);
kfree(hw);
hw = NULL;
}
static void
deactivate_bchannel(struct bchannel *bch)
{
struct hfcsusb *hw = bch->hw;
u_long flags;
if (bch->debug & DEBUG_HW)
printk(KERN_DEBUG "%s: %s: bch->nr(%i)\n",
hw->name, __func__, bch->nr);
spin_lock_irqsave(&hw->lock, flags);
mISDN_clear_bchannel(bch);
spin_unlock_irqrestore(&hw->lock, flags);
hfcsusb_setup_bch(bch, ISDN_P_NONE);
hfcsusb_stop_endpoint(hw, bch->nr - 1);
}
/*
* Layer 1 B-channel hardware access
*/
static int
hfc_bctrl(struct mISDNchannel *ch, u_int cmd, void *arg)
{
struct bchannel *bch = container_of(ch, struct bchannel, ch);
int ret = -EINVAL;
if (bch->debug & DEBUG_HW)
printk(KERN_DEBUG "%s: cmd:%x %p\n", __func__, cmd, arg);
switch (cmd) {
case HW_TESTRX_RAW:
case HW_TESTRX_HDLC:
case HW_TESTRX_OFF:
ret = -EINVAL;
break;
case CLOSE_CHANNEL:
test_and_clear_bit(FLG_OPEN, &bch->Flags);
deactivate_bchannel(bch);
ch->protocol = ISDN_P_NONE;
ch->peer = NULL;
module_put(THIS_MODULE);
ret = 0;
break;
case CONTROL_CHANNEL:
ret = channel_bctrl(bch, arg);
break;
default:
printk(KERN_WARNING "%s: unknown prim(%x)\n",
__func__, cmd);
}
return ret;
}
static int
setup_instance(struct hfcsusb *hw, struct device *parent)
{
u_long flags;
int err, i;
if (debug & DBG_HFC_CALL_TRACE)
printk(KERN_DEBUG "%s: %s\n", hw->name, __func__);
spin_lock_init(&hw->ctrl_lock);
spin_lock_init(&hw->lock);
mISDN_initdchannel(&hw->dch, MAX_DFRAME_LEN_L1, ph_state);
hw->dch.debug = debug & 0xFFFF;
hw->dch.hw = hw;
hw->dch.dev.Dprotocols = (1 << ISDN_P_TE_S0) | (1 << ISDN_P_NT_S0);
hw->dch.dev.D.send = hfcusb_l2l1D;
hw->dch.dev.D.ctrl = hfc_dctrl;
/* enable E-Channel logging */
if (hw->fifos[HFCUSB_PCM_RX].pipe)
mISDN_initdchannel(&hw->ech, MAX_DFRAME_LEN_L1, NULL);
hw->dch.dev.Bprotocols = (1 << (ISDN_P_B_RAW & ISDN_P_B_MASK)) |
(1 << (ISDN_P_B_HDLC & ISDN_P_B_MASK));
hw->dch.dev.nrbchan = 2;
for (i = 0; i < 2; i++) {
hw->bch[i].nr = i + 1;
set_channelmap(i + 1, hw->dch.dev.channelmap);
hw->bch[i].debug = debug;
mISDN_initbchannel(&hw->bch[i], MAX_DATA_MEM, poll >> 1);
hw->bch[i].hw = hw;
hw->bch[i].ch.send = hfcusb_l2l1B;
hw->bch[i].ch.ctrl = hfc_bctrl;
hw->bch[i].ch.nr = i + 1;
list_add(&hw->bch[i].ch.list, &hw->dch.dev.bchannels);
}
hw->fifos[HFCUSB_B1_TX].bch = &hw->bch[0];
hw->fifos[HFCUSB_B1_RX].bch = &hw->bch[0];
hw->fifos[HFCUSB_B2_TX].bch = &hw->bch[1];
hw->fifos[HFCUSB_B2_RX].bch = &hw->bch[1];
hw->fifos[HFCUSB_D_TX].dch = &hw->dch;
hw->fifos[HFCUSB_D_RX].dch = &hw->dch;
hw->fifos[HFCUSB_PCM_RX].ech = &hw->ech;
hw->fifos[HFCUSB_PCM_TX].ech = &hw->ech;
err = setup_hfcsusb(hw);
if (err)
goto out;
snprintf(hw->name, MISDN_MAX_IDLEN - 1, "%s.%d", DRIVER_NAME,
hfcsusb_cnt + 1);
printk(KERN_INFO "%s: registered as '%s'\n",
DRIVER_NAME, hw->name);
err = mISDN_register_device(&hw->dch.dev, parent, hw->name);
if (err)
goto out;
hfcsusb_cnt++;
write_lock_irqsave(&HFClock, flags);
list_add_tail(&hw->list, &HFClist);
write_unlock_irqrestore(&HFClock, flags);
return 0;
out:
mISDN_freebchannel(&hw->bch[1]);
mISDN_freebchannel(&hw->bch[0]);
mISDN_freedchannel(&hw->dch);
kfree(hw);
return err;
}
static int
hfcsusb_probe(struct usb_interface *intf, const struct usb_device_id *id)
{
struct hfcsusb *hw;
struct usb_device *dev = interface_to_usbdev(intf);
struct usb_host_interface *iface = intf->cur_altsetting;
struct usb_host_interface *iface_used = NULL;
struct usb_host_endpoint *ep;
struct hfcsusb_vdata *driver_info;
int ifnum = iface->desc.bInterfaceNumber, i, idx, alt_idx,
probe_alt_setting, vend_idx, cfg_used, *vcf, attr, cfg_found,
ep_addr, cmptbl[16], small_match, iso_packet_size, packet_size,
alt_used = 0;
vend_idx = 0xffff;
for (i = 0; hfcsusb_idtab[i].idVendor; i++) {
if ((le16_to_cpu(dev->descriptor.idVendor)
== hfcsusb_idtab[i].idVendor) &&
(le16_to_cpu(dev->descriptor.idProduct)
== hfcsusb_idtab[i].idProduct)) {
vend_idx = i;
continue;
}
}
printk(KERN_DEBUG
"%s: interface(%d) actalt(%d) minor(%d) vend_idx(%d)\n",
__func__, ifnum, iface->desc.bAlternateSetting,
intf->minor, vend_idx);
if (vend_idx == 0xffff) {
printk(KERN_WARNING
"%s: no valid vendor found in USB descriptor\n",
__func__);
return -EIO;
}
/* if vendor and product ID is OK, start probing alternate settings */
alt_idx = 0;
small_match = -1;
/* default settings */
iso_packet_size = 16;
packet_size = 64;
while (alt_idx < intf->num_altsetting) {
iface = intf->altsetting + alt_idx;
probe_alt_setting = iface->desc.bAlternateSetting;
cfg_used = 0;
while (validconf[cfg_used][0]) {
cfg_found = 1;
vcf = validconf[cfg_used];
ep = iface->endpoint;
memcpy(cmptbl, vcf, 16 * sizeof(int));
/* check for all endpoints in this alternate setting */
for (i = 0; i < iface->desc.bNumEndpoints; i++) {
ep_addr = ep->desc.bEndpointAddress;
/* get endpoint base */
idx = ((ep_addr & 0x7f) - 1) * 2;
if (ep_addr & 0x80)
idx++;
attr = ep->desc.bmAttributes;
if (cmptbl[idx] != EP_NOP) {
if (cmptbl[idx] == EP_NUL)
cfg_found = 0;
if (attr == USB_ENDPOINT_XFER_INT
&& cmptbl[idx] == EP_INT)
cmptbl[idx] = EP_NUL;
if (attr == USB_ENDPOINT_XFER_BULK
&& cmptbl[idx] == EP_BLK)
cmptbl[idx] = EP_NUL;
if (attr == USB_ENDPOINT_XFER_ISOC
&& cmptbl[idx] == EP_ISO)
cmptbl[idx] = EP_NUL;
if (attr == USB_ENDPOINT_XFER_INT &&
ep->desc.bInterval < vcf[17]) {
cfg_found = 0;
}
}
ep++;
}
for (i = 0; i < 16; i++)
if (cmptbl[i] != EP_NOP && cmptbl[i] != EP_NUL)
cfg_found = 0;
if (cfg_found) {
if (small_match < cfg_used) {
small_match = cfg_used;
alt_used = probe_alt_setting;
iface_used = iface;
}
}
cfg_used++;
}
alt_idx++;
} /* (alt_idx < intf->num_altsetting) */
/* not found a valid USB Ta Endpoint config */
if (small_match == -1)
return -EIO;
iface = iface_used;
hw = kzalloc(sizeof(struct hfcsusb), GFP_KERNEL);
if (!hw)
return -ENOMEM; /* got no mem */
snprintf(hw->name, MISDN_MAX_IDLEN - 1, "%s", DRIVER_NAME);
ep = iface->endpoint;
vcf = validconf[small_match];
for (i = 0; i < iface->desc.bNumEndpoints; i++) {
struct usb_fifo *f;
ep_addr = ep->desc.bEndpointAddress;
/* get endpoint base */
idx = ((ep_addr & 0x7f) - 1) * 2;
if (ep_addr & 0x80)
idx++;
f = &hw->fifos[idx & 7];
/* init Endpoints */
if (vcf[idx] == EP_NOP || vcf[idx] == EP_NUL) {
ep++;
continue;
}
switch (ep->desc.bmAttributes) {
case USB_ENDPOINT_XFER_INT:
f->pipe = usb_rcvintpipe(dev,
ep->desc.bEndpointAddress);
f->usb_transfer_mode = USB_INT;
packet_size = le16_to_cpu(ep->desc.wMaxPacketSize);
break;
case USB_ENDPOINT_XFER_BULK:
if (ep_addr & 0x80)
f->pipe = usb_rcvbulkpipe(dev,
ep->desc.bEndpointAddress);
else
f->pipe = usb_sndbulkpipe(dev,
ep->desc.bEndpointAddress);
f->usb_transfer_mode = USB_BULK;
packet_size = le16_to_cpu(ep->desc.wMaxPacketSize);
break;
case USB_ENDPOINT_XFER_ISOC:
if (ep_addr & 0x80)
f->pipe = usb_rcvisocpipe(dev,
ep->desc.bEndpointAddress);
else
f->pipe = usb_sndisocpipe(dev,
ep->desc.bEndpointAddress);
f->usb_transfer_mode = USB_ISOC;
iso_packet_size = le16_to_cpu(ep->desc.wMaxPacketSize);
break;
default:
f->pipe = 0;
}
if (f->pipe) {
f->fifonum = idx & 7;
f->hw = hw;
f->usb_packet_maxlen =
le16_to_cpu(ep->desc.wMaxPacketSize);
f->intervall = ep->desc.bInterval;
}
ep++;
}
hw->dev = dev; /* save device */
hw->if_used = ifnum; /* save used interface */
hw->alt_used = alt_used; /* and alternate config */
hw->ctrl_paksize = dev->descriptor.bMaxPacketSize0; /* control size */
hw->cfg_used = vcf[16]; /* store used config */
hw->vend_idx = vend_idx; /* store found vendor */
hw->packet_size = packet_size;
hw->iso_packet_size = iso_packet_size;
/* create the control pipes needed for register access */
hw->ctrl_in_pipe = usb_rcvctrlpipe(hw->dev, 0);
hw->ctrl_out_pipe = usb_sndctrlpipe(hw->dev, 0);
hw->ctrl_urb = usb_alloc_urb(0, GFP_KERNEL);
driver_info =
(struct hfcsusb_vdata *)hfcsusb_idtab[vend_idx].driver_info;
printk(KERN_DEBUG "%s: %s: detected \"%s\" (%s, if=%d alt=%d)\n",
hw->name, __func__, driver_info->vend_name,
conf_str[small_match], ifnum, alt_used);
if (setup_instance(hw, dev->dev.parent))
return -EIO;
hw->intf = intf;
usb_set_intfdata(hw->intf, hw);
return 0;
}
/* function called when an active device is removed */
static void
hfcsusb_disconnect(struct usb_interface *intf)
{
struct hfcsusb *hw = usb_get_intfdata(intf);
struct hfcsusb *next;
int cnt = 0;
printk(KERN_INFO "%s: device disconnected\n", hw->name);
handle_led(hw, LED_POWER_OFF);
release_hw(hw);
list_for_each_entry_safe(hw, next, &HFClist, list)
cnt++;
if (!cnt)
hfcsusb_cnt = 0;
usb_set_intfdata(intf, NULL);
}
static struct usb_driver hfcsusb_drv = {
.name = DRIVER_NAME,
.id_table = hfcsusb_idtab,
.probe = hfcsusb_probe,
.disconnect = hfcsusb_disconnect,
};
module_usb_driver(hfcsusb_drv);