dahdi-linux/drivers/dahdi/wcte12xp/base.c
Shaun Ruffell eff796fd8f wcte12xp, wctdm24xxp: Add compile-time option to disable ASPM for PCIe devices.
Certain BIOSes appear to enable ASPM even though it is not fully supported by
the platform. Also, since the PCIe links for TDM cards are always in use it
does not make sense to allow them to transition to the disabled state.

Just turn off power management on the PCIe links completely. For more
information see http://lwn.net/Articles/449448/.

Internal-Issue-ID: DAHLIN-283
Signed-off-by: Shaun Ruffell <sruffell@digium.com>

Origin: http://svnview.digium.com/svn/dahdi?view=rev&rev=10557

git-svn-id: http://svn.asterisk.org/svn/dahdi/linux/branches/2.6@10567 a0bf4364-ded3-4de4-8d8a-66a801d63aff
2012-03-21 19:11:57 +00:00

2987 lines
77 KiB
C

/*
* Digium, Inc. Wildcard TE12xP T1/E1 card Driver
*
* Written by Michael Spiceland <mspiceland@digium.com>
*
* Adapted from the wctdm24xxp and wcte11xp drivers originally
* written by Mark Spencer <markster@digium.com>
* Matthew Fredrickson <creslin@digium.com>
* William Meadows <wmeadows@digium.com>
*
* Copyright (C) 2007-2011, Digium, Inc.
*
* All rights reserved.
*
*/
/*
* See http://www.asterisk.org for more information about
* the Asterisk project. Please do not directly contact
* any of the maintainers of this project for assistance;
* the project provides a web site, mailing lists and IRC
* channels for your use.
*
* This program is free software, distributed under the terms of
* the GNU General Public License Version 2 as published by the
* Free Software Foundation. See the LICENSE file included with
* this program for more details.
*/
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/module.h>
#include <linux/init.h>
#include <linux/pci.h>
#include <linux/proc_fs.h>
#include <linux/moduleparam.h>
#include <linux/interrupt.h>
#include <linux/workqueue.h>
#include <linux/delay.h>
#include <linux/sched.h>
#include <stdbool.h>
#include <dahdi/kernel.h>
#include "wct4xxp/wct4xxp.h" /* For certain definitions */
#include "voicebus/voicebus.h"
#include "voicebus/vpmoct.h"
#include "wcte12xp.h"
#include "voicebus/GpakCust.h"
#include "voicebus/GpakApi.h"
#if VOICEBUS_SFRAME_SIZE != SFRAME_SIZE
#error VOICEBUS_SFRAME_SIZE != SFRAME_SIZE
#endif
#ifndef pr_fmt
#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
#endif
static int debug;
static int j1mode = 0;
static int alarmdebounce = 2500; /* LOF/LFA def to 2.5s AT&T TR54016*/
static int losalarmdebounce = 2500; /* LOS def to 2.5s AT&T TR54016*/
static int aisalarmdebounce = 2500; /* AIS(blue) def to 2.5s AT&T TR54016*/
static int yelalarmdebounce = 500; /* RAI(yellow) def to 0.5s AT&T devguide */
static int t1e1override = -1; /* deprecated */
static char *default_linemode = "auto"; /* 'auto', 'e1', or 't1' */
static int latency = VOICEBUS_DEFAULT_LATENCY;
static unsigned int max_latency = VOICEBUS_DEFAULT_MAXLATENCY;
static int vpmsupport = 1;
static int vpmtsisupport = 0;
static int vpmnlptype = DEFAULT_NLPTYPE;
static int vpmnlpthresh = DEFAULT_NLPTHRESH;
static int vpmnlpmaxsupp = DEFAULT_NLPMAXSUPP;
static void echocan_free(struct dahdi_chan *chan, struct dahdi_echocan_state *ec);
static int t1xxp_clear_maint(struct dahdi_span *span);
static const struct dahdi_echocan_features vpm150m_ec_features = {
.NLP_automatic = 1,
.CED_tx_detect = 1,
.CED_rx_detect = 1,
};
static const struct dahdi_echocan_ops vpm150m_ec_ops = {
.echocan_free = echocan_free,
};
static struct t1 *ifaces[WC_MAX_IFACES];
struct t1_desc {
const char *name;
};
static const struct t1_desc te120p = {"Wildcard TE120P"};
static const struct t1_desc te122 = {"Wildcard TE122"};
static const struct t1_desc te121 = {"Wildcard TE121"};
static inline bool is_pcie(const struct t1 *t1)
{
return (0 == strcmp(t1->variety, te121.name));
}
/* names of HWEC modules */
static const char *vpmadt032_name = "VPMADT032";
static const char *vpmoct_name = "VPMOCT032";
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
static kmem_cache_t *cmd_cache;
#else
static struct kmem_cache *cmd_cache;
#endif
static struct command *get_free_cmd(struct t1 *wc)
{
struct command *cmd;
cmd = kmem_cache_alloc(cmd_cache, GFP_ATOMIC);
if (cmd) {
memset(cmd, 0, sizeof(*cmd));
init_completion(&cmd->complete);
INIT_LIST_HEAD(&cmd->node);
}
return cmd;
}
static void free_cmd(struct t1 *wc, struct command *cmd)
{
kmem_cache_free(cmd_cache, cmd);
}
static struct command *_get_pending_cmd(struct t1 *wc)
{
struct command *cmd = NULL;
if (!list_empty(&wc->pending_cmds)) {
cmd = list_entry(wc->pending_cmds.next, struct command, node);
list_move_tail(&cmd->node, &wc->active_cmds);
}
return cmd;
}
static void submit_cmd(struct t1 *wc, struct command *cmd)
{
unsigned long flags;
spin_lock_irqsave(&wc->reglock, flags);
list_add_tail(&cmd->node, &wc->pending_cmds);
spin_unlock_irqrestore(&wc->reglock, flags);
}
static void _resend_cmds(struct t1 *wc)
{
list_splice_init(&wc->active_cmds, &wc->pending_cmds);
if (wc->vpmadt032)
vpmadt032_resend(wc->vpmadt032);
}
static inline void cmd_dequeue_vpmoct(struct t1 *wc, u8 *eframe)
{
struct vpmoct *vpm = wc->vpmoct;
struct vpmoct_cmd *cmd;
u8 i;
/* Pop a command off pending list */
spin_lock(&vpm->list_lock);
if (list_empty(&vpm->pending_list)) {
spin_unlock(&vpm->list_lock);
return;
}
cmd = list_entry(vpm->pending_list.next, struct vpmoct_cmd, node);
/* Push the command onto active list, if it's a syncronous cmd */
if (is_vpmoct_cmd_read(cmd))
list_move_tail(&cmd->node, &vpm->active_list);
else
list_del_init(&cmd->node);
/* Skip audio */
eframe += 66;
/* Save ident so we can match the return eframe */
cmd->txident = wc->txident;
/* We have four timeslots to work with for a regular spi packet */
/* TODO: Create debug flag for this in dev */
eframe[CMD_BYTE(0, 0, 1)] = 0x12;
eframe[CMD_BYTE(0, 1, 1)] = 0x34;
eframe[CMD_BYTE(0, 2, 1)] = 0x56;
eframe[CMD_BYTE(1, 0, 1)] = cmd->command;
eframe[CMD_BYTE(1, 1, 1)] = cmd->address;
eframe[CMD_BYTE(1, 2, 1)] = cmd->data[0];
for (i = 1; i < cmd->chunksize; i++) {
/* Every time slot is filled with chunk data
* ignoring command/address/data structure */
eframe[CMD_BYTE(1, 2, 1) + 2*i] = cmd->data[i];
}
/* Clean up fire-and-forget messages from memory */
if (list_empty(&cmd->node))
kfree(cmd);
spin_unlock(&vpm->list_lock);
#if 0
dev_info(&wc->vb.pdev->dev, "Wrote: ");
for (i = 0; i < 7; i++) {
dev_info(&wc->vb.pdev->dev, "|%x %x %x|",
eframe[CMD_BYTE(i, 0, 1)],
eframe[CMD_BYTE(i, 1, 1)],
eframe[CMD_BYTE(i, 2, 1)]);
}
#endif
}
static void cmd_dequeue(struct t1 *wc, unsigned char *eframe, int frame_num, int slot)
{
struct command *curcmd=NULL;
u16 address;
u8 data;
u32 flags;
/* Skip audio */
eframe += 66;
/* Search for something waiting to transmit */
if ((slot < 6) && (frame_num) && (frame_num < DAHDI_CHUNKSIZE - 1)) {
/* only 6 useable cs slots per */
/* framer */
curcmd = _get_pending_cmd(wc);
if (curcmd) {
curcmd->cs_slot = slot;
curcmd->ident = wc->txident;
address = curcmd->address;
data = curcmd->data;
flags = curcmd->flags;
} else {
/* If nothing else, use filler */
address = 0x4a;
data = 0;
flags = __CMD_RD;
}
if (flags & __CMD_WR)
eframe[CMD_BYTE(slot, 0, 0)] = 0x0c; /* 0c write command */
else if (flags & __CMD_LEDS)
eframe[CMD_BYTE(slot, 0, 0)] = 0x10 | ((address) & 0x0E); /* led set command */
else if (flags & __CMD_PINS)
eframe[CMD_BYTE(slot, 0, 0)] = 0x30; /* CPLD2 pin state */
else
eframe[CMD_BYTE(slot, 0, 0)] = 0x0a; /* read command */
eframe[CMD_BYTE(slot, 1, 0)] = address;
eframe[CMD_BYTE(slot, 2, 0)] = data;
}
}
static inline void cmd_decipher(struct t1 *wc, const u8 *eframe)
{
struct command *cmd = NULL;
const int IS_VPM = 0;
/* Skip audio */
eframe += 66;
while (!list_empty(&wc->active_cmds)) {
cmd = list_entry(wc->active_cmds.next, struct command, node);
if (cmd->ident != wc->rxident)
break;
if (cmd->flags & (__CMD_WR | __CMD_LEDS)) {
/* Nobody is waiting on writes...so let's just
* free them here. */
list_del_init(&cmd->node);
free_cmd(wc, cmd);
} else {
cmd->data |= eframe[CMD_BYTE(cmd->cs_slot, 2, IS_VPM)];
list_del_init(&cmd->node);
complete(&cmd->complete);
}
}
}
inline void cmd_decipher_vpmoct(struct t1 *wc, const u8 *eframe)
{
int i;
struct vpmoct *vpm = wc->vpmoct;
struct vpmoct_cmd *cmd;
/* Skip audio and first 6 timeslots */
eframe += 66;
spin_lock(&vpm->list_lock);
/* No command to handle, just exit */
if (list_empty(&vpm->active_list)) {
spin_unlock(&vpm->list_lock);
return;
}
cmd = list_entry(vpm->active_list.next, struct vpmoct_cmd, node);
if (wc->rxident == cmd->txident)
list_del_init(&cmd->node);
else
cmd = NULL;
spin_unlock(&vpm->list_lock);
if (!cmd)
return;
#if 0
/* Store result */
dev_info(&wc->vb.pdev->dev, "Read: ");
for (i = 0; i < 7; i++) {
dev_info(&wc->vb.pdev->dev, "|%x %x %x|",
eframe[CMD_BYTE(i, 0, 1)],
eframe[CMD_BYTE(i, 1, 1)],
eframe[CMD_BYTE(i, 2, 1)]);
}
dev_info(&wc->vb.pdev->dev, "\n");
#endif
cmd->command = eframe[CMD_BYTE(1, 0, 1)];
cmd->address = eframe[CMD_BYTE(1, 1, 1)];
for (i = 0; i < cmd->chunksize; ++i)
cmd->data[i] = eframe[CMD_BYTE(1, 2, 1) + 2*i];
complete(&cmd->complete);
}
inline void cmd_decipher_vpmadt032(struct t1 *wc, const u8 *eframe)
{
struct vpmadt032 *vpm = wc->vpmadt032;
struct vpmadt032_cmd *cmd;
BUG_ON(!vpm);
/* If the hardware is not processing any commands currently, then
* there is nothing for us to do here. */
if (list_empty(&vpm->active_cmds)) {
return;
}
spin_lock(&vpm->list_lock);
cmd = list_entry(vpm->active_cmds.next, struct vpmadt032_cmd, node);
if (wc->rxident == cmd->txident) {
list_del_init(&cmd->node);
} else {
cmd = NULL;
}
spin_unlock(&vpm->list_lock);
if (!cmd) {
return;
}
/* Skip audio */
eframe += 66;
/* Store result */
cmd->data = (0xff & eframe[CMD_BYTE(2, 1, 1)]) << 8;
cmd->data |= eframe[CMD_BYTE(2, 2, 1)];
if (cmd->desc & __VPM150M_WR) {
kfree(cmd);
} else {
cmd->desc |= __VPM150M_FIN;
complete(&cmd->complete);
}
}
static int config_vpmadt032(struct vpmadt032 *vpm, struct t1 *wc)
{
int res, channel;
GpakPortConfig_t portconfig = {0};
gpakConfigPortStatus_t configportstatus;
GPAK_PortConfigStat_t pstatus;
GpakChannelConfig_t chanconfig;
GPAK_ChannelConfigStat_t cstatus;
GPAK_AlgControlStat_t algstatus;
/* First Serial Port config */
portconfig.SlotsSelect1 = SlotCfgNone;
portconfig.FirstBlockNum1 = 0;
portconfig.FirstSlotMask1 = 0x0000;
portconfig.SecBlockNum1 = 1;
portconfig.SecSlotMask1 = 0x0000;
portconfig.SerialWordSize1 = SerWordSize8;
portconfig.CompandingMode1 = cmpNone;
portconfig.TxFrameSyncPolarity1 = FrameSyncActHigh;
portconfig.RxFrameSyncPolarity1 = FrameSyncActHigh;
portconfig.TxClockPolarity1 = SerClockActHigh;
portconfig.RxClockPolarity1 = SerClockActHigh;
portconfig.TxDataDelay1 = DataDelay0;
portconfig.RxDataDelay1 = DataDelay0;
portconfig.DxDelay1 = Disabled;
portconfig.ThirdSlotMask1 = 0x0000;
portconfig.FouthSlotMask1 = 0x0000;
portconfig.FifthSlotMask1 = 0x0000;
portconfig.SixthSlotMask1 = 0x0000;
portconfig.SevenSlotMask1 = 0x0000;
portconfig.EightSlotMask1 = 0x0000;
/* Second Serial Port config */
portconfig.SlotsSelect2 = SlotCfg8Groups;
portconfig.FirstBlockNum2 = 0;
portconfig.FirstSlotMask2 = 0x5554;
portconfig.SecBlockNum2 = 1;
portconfig.SecSlotMask2 = 0x5555;
portconfig.ThirdSlotMask2 = 0x5555;
portconfig.FouthSlotMask2 = 0x5555;
portconfig.SerialWordSize2 = SerWordSize8;
portconfig.CompandingMode2 = cmpNone;
portconfig.TxFrameSyncPolarity2 = FrameSyncActHigh;
portconfig.RxFrameSyncPolarity2 = FrameSyncActHigh;
portconfig.TxClockPolarity2 = SerClockActHigh;
portconfig.RxClockPolarity2 = SerClockActHigh;
portconfig.TxDataDelay2 = DataDelay0;
portconfig.RxDataDelay2 = DataDelay0;
portconfig.DxDelay2 = Disabled;
portconfig.FifthSlotMask2 = 0x0001;
portconfig.SixthSlotMask2 = 0x0000;
portconfig.SevenSlotMask2 = 0x0000;
portconfig.EightSlotMask2 = 0x0000;
/* Third Serial Port Config */
portconfig.SlotsSelect3 = SlotCfg8Groups;
portconfig.FirstBlockNum3 = 0;
portconfig.FirstSlotMask3 = 0x5554;
portconfig.SecBlockNum3 = 1;
portconfig.SecSlotMask3 = 0x5555;
portconfig.SerialWordSize3 = SerWordSize8;
portconfig.CompandingMode3 = cmpNone;
portconfig.TxFrameSyncPolarity3 = FrameSyncActHigh;
portconfig.RxFrameSyncPolarity3 = FrameSyncActHigh;
portconfig.TxClockPolarity3 = SerClockActHigh;
portconfig.RxClockPolarity3 = SerClockActLow;
portconfig.TxDataDelay3 = DataDelay0;
portconfig.RxDataDelay3 = DataDelay0;
portconfig.DxDelay3 = Disabled;
portconfig.ThirdSlotMask3 = 0x5555;
portconfig.FouthSlotMask3 = 0x5555;
portconfig.FifthSlotMask3 = 0x0001;
portconfig.SixthSlotMask3 = 0x0000;
portconfig.SevenSlotMask3 = 0x0000;
portconfig.EightSlotMask3 = 0x0000;
if ((configportstatus = gpakConfigurePorts(vpm->dspid, &portconfig, &pstatus))) {
t1_info(wc, "Configuration of ports failed (%d)!\n",
configportstatus);
return -1;
} else {
if (vpm->options.debug & DEBUG_VPMADT032_ECHOCAN)
t1_info(wc, "Configured McBSP ports successfully\n");
}
if ((res = gpakPingDsp(vpm->dspid, &vpm->version))) {
t1_info(wc, "Error pinging DSP (%d)\n", res);
return -1;
}
for (channel = 0; channel < ARRAY_SIZE(vpm->curecstate); ++channel) {
vpm->curecstate[channel].tap_length = 0;
vpm->curecstate[channel].nlp_type = vpm->options.vpmnlptype;
vpm->curecstate[channel].nlp_threshold = vpm->options.vpmnlpthresh;
vpm->curecstate[channel].nlp_max_suppress = vpm->options.vpmnlpmaxsupp;
vpm->setchanconfig_from_state(vpm, channel, &chanconfig);
if ((res = gpakConfigureChannel(vpm->dspid, channel, tdmToTdm, &chanconfig, &cstatus))) {
t1_info(wc, "Unable to configure channel #%d (%d)",
channel, res);
if (res == 1) {
printk(KERN_CONT ", reason %d", cstatus);
}
printk(KERN_CONT "\n");
return -1;
}
if ((res = gpakAlgControl(vpm->dspid, channel, BypassEcanA, &algstatus))) {
t1_info(wc, "Unable to disable echo can on channel %d "
"(reason %d:%d)\n", channel + 1, res,
algstatus);
return -1;
}
}
if ((res = gpakPingDsp(vpm->dspid, &vpm->version))) {
t1_info(wc, "Error pinging DSP (%d)\n", res);
return -1;
}
set_bit(VPM150M_ACTIVE, &vpm->control);
return 0;
}
#define debug_printk(wc, lvl, fmt, args...) if (debug >= (lvl)) do { \
t1_info((wc), fmt , ## args); } while (0)
static void cmd_dequeue_vpmadt032(struct t1 *wc, unsigned char *eframe)
{
struct vpmadt032_cmd *cmd;
struct vpmadt032 *vpm = wc->vpmadt032;
int x;
unsigned char leds = ~((atomic_read(&wc->txints) / 1000) % 8) & 0x7;
/* Skip audio */
eframe += 66;
if (test_bit(VPM150M_HPIRESET, &vpm->control)) {
debug_printk(wc, 1, "HW Resetting VPMADT032 ...\n");
for (x = 0; x < 4; x++) {
if (!x) {
if (test_and_clear_bit(VPM150M_HPIRESET,
&vpm->control)) {
eframe[CMD_BYTE(x, 0, 1)] = 0x0b;
} else {
eframe[CMD_BYTE(x, 0, 1)] = leds;
}
} else {
eframe[CMD_BYTE(x, 0, 1)] = 0x00 | leds;
}
eframe[CMD_BYTE(x, 1, 1)] = 0;
eframe[CMD_BYTE(x, 2, 1)] = 0x00;
}
return;
}
if ((cmd = vpmadt032_get_ready_cmd(vpm))) {
cmd->txident = wc->txident;
#if 0
printk(KERN_DEBUG "Found command txident = %d, desc = 0x%x, addr = 0x%x, data = 0x%x\n", cmd->txident, cmd->desc, cmd->address, cmd->data);
#endif
if (cmd->desc & __VPM150M_RWPAGE) {
/* Set CTRL access to page*/
eframe[CMD_BYTE(0, 0, 1)] = (0x8 << 4);
eframe[CMD_BYTE(0, 1, 1)] = 0;
eframe[CMD_BYTE(0, 2, 1)] = 0x20;
/* Do a page write */
if (cmd->desc & __VPM150M_WR) {
eframe[CMD_BYTE(1, 0, 1)] = ((0x8 | 0x4) << 4);
} else {
eframe[CMD_BYTE(1, 0, 1)] = ((0x8 | 0x4 | 0x1) << 4);
}
eframe[CMD_BYTE(1, 1, 1)] = 0;
if (cmd->desc & __VPM150M_WR) {
eframe[CMD_BYTE(1, 2, 1)] = cmd->data & 0xf;
} else {
eframe[CMD_BYTE(1, 2, 1)] = 0;
}
if (cmd->desc & __VPM150M_WR) {
/* Fill in buffer to size */
eframe[CMD_BYTE(2, 0, 1)] = 0;
eframe[CMD_BYTE(2, 1, 1)] = 0;
eframe[CMD_BYTE(2, 2, 1)] = 0;
} else {
/* Do reads twice b/c of vpmadt032 bug */
eframe[CMD_BYTE(2, 0, 1)] = ((0x8 | 0x4 | 0x1) << 4);
eframe[CMD_BYTE(2, 1, 1)] = 0;
eframe[CMD_BYTE(2, 2, 1)] = 0;
}
/* Clear XADD */
eframe[CMD_BYTE(3, 0, 1)] = (0x8 << 4);
eframe[CMD_BYTE(3, 1, 1)] = 0;
eframe[CMD_BYTE(3, 2, 1)] = 0;
/* Fill in buffer to size */
eframe[CMD_BYTE(4, 0, 1)] = 0;
eframe[CMD_BYTE(4, 1, 1)] = 0;
eframe[CMD_BYTE(4, 2, 1)] = 0;
} else {
/* Set address */
eframe[CMD_BYTE(0, 0, 1)] = ((0x8 | 0x4) << 4);
eframe[CMD_BYTE(0, 1, 1)] = (cmd->address >> 8) & 0xff;
eframe[CMD_BYTE(0, 2, 1)] = cmd->address & 0xff;
/* Send/Get our data */
if (cmd->desc & __VPM150M_WR) {
eframe[CMD_BYTE(1, 0, 1)] = ((0x8 | (0x3 << 1)) << 4);
} else {
eframe[CMD_BYTE(1, 0, 1)] = ((0x8 | (0x3 << 1) | 0x1) << 4);
}
eframe[CMD_BYTE(1, 1, 1)] = (cmd->data >> 8) & 0xff;
eframe[CMD_BYTE(1, 2, 1)] = cmd->data & 0xff;
if (cmd->desc & __VPM150M_WR) {
/* Fill in */
eframe[CMD_BYTE(2, 0, 1)] = 0;
eframe[CMD_BYTE(2, 1, 1)] = 0;
eframe[CMD_BYTE(2, 2, 1)] = 0;
} else {
/* Do this again for reads b/c of the bug in vpmadt032 */
eframe[CMD_BYTE(2, 0, 1)] = ((0x8 | (0x3 << 1) | 0x1) << 4);
eframe[CMD_BYTE(2, 1, 1)] = (cmd->data >> 8) & 0xff;
eframe[CMD_BYTE(2, 2, 1)] = cmd->data & 0xff;
}
/* Fill in the rest */
eframe[CMD_BYTE(3, 0, 1)] = 0;
eframe[CMD_BYTE(3, 1, 1)] = 0;
eframe[CMD_BYTE(3, 2, 1)] = 0;
/* Fill in the rest */
eframe[CMD_BYTE(4, 0, 1)] = 0;
eframe[CMD_BYTE(4, 1, 1)] = 0;
eframe[CMD_BYTE(4, 2, 1)] = 0;
}
} else if (test_and_clear_bit(VPM150M_SWRESET, &vpm->control)) {
for (x = 0; x < 7; x++) {
if (0 == x) {
eframe[CMD_BYTE(x, 0, 1)] = (0x8 << 4);
} else {
eframe[CMD_BYTE(x, 0, 1)] = 0x00;
}
eframe[CMD_BYTE(x, 1, 1)] = 0;
if (0 == x) {
eframe[CMD_BYTE(x, 2, 1)] = 0x01;
} else {
eframe[CMD_BYTE(x, 2, 1)] = 0x00;
}
}
} else {
for (x = 0; x < 7; x++) {
eframe[CMD_BYTE(x, 0, 1)] = 0x00;
eframe[CMD_BYTE(x, 1, 1)] = 0x00;
eframe[CMD_BYTE(x, 2, 1)] = 0x00;
}
}
/* Add our leds in */
for (x = 0; x < 7; x++)
eframe[CMD_BYTE(x, 0, 1)] |= leds;
}
static inline int t1_setreg(struct t1 *wc, int addr, int val)
{
struct command *cmd;
cmd = get_free_cmd(wc);
if (!cmd) {
WARN_ON(1);
return -ENOMEM;
}
cmd->address = addr;
cmd->data = val;
cmd->flags |= __CMD_WR;
submit_cmd(wc, cmd);
return 0;
}
static int t1_getreg(struct t1 *wc, int addr)
{
struct command *cmd = NULL;
unsigned long ret;
unsigned long flags;
might_sleep();
cmd = get_free_cmd(wc);
if (!cmd)
return -ENOMEM;
cmd->address = addr;
cmd->data = 0x00;
cmd->flags = __CMD_RD;
submit_cmd(wc, cmd);
ret = wait_for_completion_interruptible_timeout(&cmd->complete, HZ*10);
if (unlikely(!ret)) {
spin_lock_irqsave(&wc->reglock, flags);
if (!list_empty(&cmd->node)) {
/* Since we've removed this command from the list, we
* can go ahead and free it right away. */
list_del_init(&cmd->node);
spin_unlock_irqrestore(&wc->reglock, flags);
free_cmd(wc, cmd);
if (-ERESTARTSYS != ret) {
if (printk_ratelimit()) {
dev_warn(&wc->vb.pdev->dev,
"Timeout in %s\n", __func__);
}
ret = -EIO;
}
return ret;
} else {
/* Looks like this command was removed from the list by
* someone else already. Let's wait for them to complete
* it so that we don't free up the memory. */
spin_unlock_irqrestore(&wc->reglock, flags);
ret = wait_for_completion_timeout(&cmd->complete, HZ*2);
WARN_ON(!ret);
ret = cmd->data;
free_cmd(wc, cmd);
return ret;
}
}
ret = cmd->data;
free_cmd(wc, cmd);
return ret;
}
static void t1_setleds(struct t1 *wc, int leds)
{
struct command *cmd;
leds = (~leds) & 0x0E; /* invert the LED bits (3 downto 1)*/
cmd = get_free_cmd(wc);
if (!cmd)
return;
cmd->flags |= __CMD_LEDS;
cmd->address = leds;
submit_cmd(wc, cmd);
}
/**
* t1_getpins - Returns the value of the jumpers on the card.
* @wc: The card to read from.
* @pins: Pointer to u8 character to hold the pins value.
*
* Returns 0 on success, otherwise an error code.
*
*/
static int t1_getpins(struct t1 *wc, u8 *pins)
{
struct command *cmd;
unsigned long flags;
unsigned long ret;
*pins = 0;
cmd = get_free_cmd(wc);
BUG_ON(!cmd);
cmd->address = 0x00;
cmd->data = 0x00;
cmd->flags = __CMD_PINS;
submit_cmd(wc, cmd);
ret = wait_for_completion_interruptible_timeout(&cmd->complete, HZ*2);
if (unlikely(!ret)) {
spin_lock_irqsave(&wc->reglock, flags);
list_del_init(&cmd->node);
spin_unlock_irqrestore(&wc->reglock, flags);
free_cmd(wc, cmd);
if (-ERESTARTSYS != ret) {
if (printk_ratelimit()) {
dev_warn(&wc->vb.pdev->dev,
"Timeout in %s\n", __func__);
}
ret = -EIO;
}
return ret;
}
*pins = cmd->data;
free_cmd(wc, cmd);
return 0;
}
static void __t1xxp_set_clear(struct t1 *wc)
{
int i, offset;
int ret;
unsigned short reg[3] = {0, 0, 0};
/* Calculate all states on all 24 channels using the channel
flags, then write all 3 clear channel registers at once */
for (i = 0; i < wc->span.channels; i++) {
offset = i/8;
if (wc->span.chans[i]->flags & DAHDI_FLAG_CLEAR)
reg[offset] |= 1 << (7 - (i % 8));
else
reg[offset] &= ~(1 << (7 - (i % 8)));
}
ret = t1_setreg(wc, CCB1, reg[0]);
if (ret < 0)
t1_info(wc, "Unable to set clear/rbs mode!\n");
ret = t1_setreg(wc, CCB2, reg[1]);
if (ret < 0)
t1_info(wc, "Unable to set clear/rbs mode!\n");
ret = t1_setreg(wc, CCB3, reg[2]);
if (ret < 0)
t1_info(wc, "Unable to set clear/rbs mode!\n");
}
/**
* _t1_free_channels - Free the memory allocated for the channels.
*
* Must be called with wc->reglock held.
*
*/
static void _t1_free_channels(struct t1 *wc)
{
int x;
for (x = 0; x < ARRAY_SIZE(wc->chans); x++) {
kfree(wc->chans[x]);
kfree(wc->ec[x]);
wc->chans[x] = NULL;
wc->ec[x] = NULL;
}
}
static void free_wc(struct t1 *wc)
{
unsigned long flags;
struct command *cmd;
LIST_HEAD(list);
spin_lock_irqsave(&wc->reglock, flags);
_t1_free_channels(wc);
list_splice_init(&wc->active_cmds, &list);
list_splice_init(&wc->pending_cmds, &list);
spin_unlock_irqrestore(&wc->reglock, flags);
while (!list_empty(&list)) {
cmd = list_entry(list.next, struct command, node);
list_del_init(&cmd->node);
free_cmd(wc, cmd);
}
if (wc->wq)
destroy_workqueue(wc->wq);
#ifdef CONFIG_VOICEBUS_ECREFERENCE
for (x = 0; x < ARRAY_SIZE(wc->ec_reference); ++x) {
if (wc->ec_reference[x])
dahdi_fifo_free(wc->ec_reference[x]);
}
#endif
kfree(wc->ddev->location);
kfree(wc->ddev->devicetype);
dahdi_free_device(wc->ddev);
kfree(wc);
}
static void t4_serial_setup(struct t1 *wc)
{
t1_setreg(wc, 0x85, 0xe0); /* GPC1: Multiplex mode enabled, FSC is output, active low, RCLK from channel 0 */
t1_setreg(wc, 0x08, 0x05); /* IPC: Interrupt push/pull active low */
/* Global clocks (8.192 Mhz CLK) */
t1_setreg(wc, 0x92, 0x00);
t1_setreg(wc, 0x93, 0x18);
t1_setreg(wc, 0x94, 0xfb);
t1_setreg(wc, 0x95, 0x0b);
t1_setreg(wc, 0x96, 0x00);
t1_setreg(wc, 0x97, 0x0b);
t1_setreg(wc, 0x98, 0xdb);
t1_setreg(wc, 0x99, 0xdf);
/* Configure interrupts */
t1_setreg(wc, 0x46, 0xc0); /* GCR: Interrupt on Activation/Deactivation of AIX, LOS */
/* Configure system interface */
t1_setreg(wc, 0x3e, 0x0a /* 0x02 */); /* SIC1: 4.096 Mhz clock/bus, double buffer receive / transmit, byte interleaved */
t1_setreg(wc, 0x3f, 0x00); /* SIC2: No FFS, no center receive eliastic buffer, phase 0 */
t1_setreg(wc, 0x40, 0x04); /* SIC3: Edges for capture */
t1_setreg(wc, 0x44, 0x30); /* CMR1: RCLK is at 8.192 Mhz dejittered */
t1_setreg(wc, 0x45, 0x00); /* CMR2: We provide sync and clock for tx and rx. */
t1_setreg(wc, 0x22, 0x00); /* XC0: Normal operation of Sa-bits */
t1_setreg(wc, 0x23, 0x04); /* XC1: 0 offset */
t1_setreg(wc, 0x24, 0x00); /* RC0: Just shy of 255 */
t1_setreg(wc, 0x25, 0x05); /* RC1: The rest of RC0 */
/* Configure ports */
t1_setreg(wc, 0x80, 0x00); /* PC1: SPYR/SPYX input on RPA/XPA */
t1_setreg(wc, 0x81, 0x22); /* PC2: RMFB/XSIG output/input on RPB/XPB */
t1_setreg(wc, 0x82, 0x65); /* PC3: Some unused stuff */
t1_setreg(wc, 0x83, 0x35); /* PC4: Some more unused stuff */
t1_setreg(wc, 0x84, 0x31); /* PC5: XMFS active low, SCLKR is input, RCLK is output */
t1_setreg(wc, 0x86, 0x03); /* PC6: CLK1 is Tx Clock output, CLK2 is 8.192 Mhz from DCO-R */
t1_setreg(wc, 0x3b, 0x00); /* Clear LCR1 */
}
static void t1_configure_t1(struct t1 *wc, int lineconfig, int txlevel)
{
unsigned int fmr4, fmr2, fmr1, fmr0, lim2;
char *framing, *line;
int mytxlevel;
if ((txlevel > 7) || (txlevel < 4))
mytxlevel = 0;
else
mytxlevel = txlevel - 4;
fmr1 = 0x9e; /* FMR1: Mode 0, T1 mode, CRC on for ESF, 2.048 Mhz system data rate, no XAIS */
fmr2 = 0x20; /* FMR2: no payload loopback, don't auto yellow alarm */
if (j1mode)
fmr4 = 0x1c;
else
fmr4 = 0x0c; /* FMR4: Lose sync on 2 out of 5 framing bits, auto resync */
lim2 = 0x21; /* LIM2: 50% peak is a "1", Advanced Loss recovery */
lim2 |= (mytxlevel << 6); /* LIM2: Add line buildout */
t1_setreg(wc, 0x1d, fmr1);
t1_setreg(wc, 0x1e, fmr2);
/* Configure line interface */
if (lineconfig & DAHDI_CONFIG_AMI) {
line = "AMI";
fmr0 = 0xa0;
} else {
line = "B8ZS";
fmr0 = 0xf0;
}
if (lineconfig & DAHDI_CONFIG_D4) {
framing = "D4";
} else {
framing = "ESF";
fmr4 |= 0x2;
fmr2 |= 0xc0;
}
t1_setreg(wc, 0x1c, fmr0);
t1_setreg(wc, 0x20, fmr4);
t1_setreg(wc, 0x21, 0x40); /* FMR5: Enable RBS mode */
t1_setreg(wc, 0x37, 0xf8); /* LIM1: Clear data in case of LOS, Set receiver threshold (0.5V), No remote loop, no DRS */
t1_setreg(wc, 0x36, 0x08); /* LIM0: Enable auto long haul mode, no local loop (must be after LIM1) */
t1_setreg(wc, 0x02, 0x50); /* CMDR: Reset the receiver and transmitter line interface */
t1_setreg(wc, 0x02, 0x00); /* CMDR: Reset the receiver and transmitter line interface */
t1_setreg(wc, 0x3a, lim2); /* LIM2: 50% peak amplitude is a "1" */
t1_setreg(wc, 0x38, 0x0a); /* PCD: LOS after 176 consecutive "zeros" */
t1_setreg(wc, 0x39, 0x15); /* PCR: 22 "ones" clear LOS */
if (j1mode)
t1_setreg(wc, 0x24, 0x80); /* J1 overide */
/* Generate pulse mask for T1 */
switch (mytxlevel) {
case 3:
t1_setreg(wc, 0x26, 0x07); /* XPM0 */
t1_setreg(wc, 0x27, 0x01); /* XPM1 */
t1_setreg(wc, 0x28, 0x00); /* XPM2 */
break;
case 2:
t1_setreg(wc, 0x26, 0x8c); /* XPM0 */
t1_setreg(wc, 0x27, 0x11); /* XPM1 */
t1_setreg(wc, 0x28, 0x01); /* XPM2 */
break;
case 1:
t1_setreg(wc, 0x26, 0x8c); /* XPM0 */
t1_setreg(wc, 0x27, 0x01); /* XPM1 */
t1_setreg(wc, 0x28, 0x00); /* XPM2 */
break;
case 0:
default:
t1_setreg(wc, 0x26, 0xd7); /* XPM0 */
t1_setreg(wc, 0x27, 0x22); /* XPM1 */
t1_setreg(wc, 0x28, 0x01); /* XPM2 */
break;
}
if (debug)
t1_info(wc, "Span configured for %s/%s\n", framing, line);
}
static void t1_configure_e1(struct t1 *wc, int lineconfig)
{
unsigned int fmr2, fmr1, fmr0;
unsigned int cas = 0;
char *crc4 = "";
char *framing, *line;
fmr1 = 0x46; /* FMR1: E1 mode, Automatic force resync, PCM30 mode, 8.192 Mhz backplane, no XAIS */
fmr2 = 0x03; /* FMR2: Auto transmit remote alarm, auto loss of multiframe recovery, no payload loopback */
if (lineconfig & DAHDI_CONFIG_CRC4) {
fmr1 |= 0x08; /* CRC4 transmit */
fmr2 |= 0xc0; /* CRC4 receive */
crc4 = "/CRC4";
}
t1_setreg(wc, 0x1d, fmr1);
t1_setreg(wc, 0x1e, fmr2);
/* Configure line interface */
if (lineconfig & DAHDI_CONFIG_AMI) {
line = "AMI";
fmr0 = 0xa0;
} else {
line = "HDB3";
fmr0 = 0xf0;
}
if (lineconfig & DAHDI_CONFIG_CCS) {
framing = "CCS";
} else {
framing = "CAS";
cas = 0x40;
}
t1_setreg(wc, 0x1c, fmr0);
t1_setreg(wc, 0x37, 0xf0 /*| 0x6 */ ); /* LIM1: Clear data in case of LOS, Set receiver threshold (0.5V), No remote loop, no DRS */
t1_setreg(wc, 0x36, 0x08); /* LIM0: Enable auto long haul mode, no local loop (must be after LIM1) */
t1_setreg(wc, 0x02, 0x50); /* CMDR: Reset the receiver and transmitter line interface */
t1_setreg(wc, 0x02, 0x00); /* CMDR: Reset the receiver and transmitter line interface */
/* Condition receive line interface for E1 after reset */
t1_setreg(wc, 0xbb, 0x17);
t1_setreg(wc, 0xbc, 0x55);
t1_setreg(wc, 0xbb, 0x97);
t1_setreg(wc, 0xbb, 0x11);
t1_setreg(wc, 0xbc, 0xaa);
t1_setreg(wc, 0xbb, 0x91);
t1_setreg(wc, 0xbb, 0x12);
t1_setreg(wc, 0xbc, 0x55);
t1_setreg(wc, 0xbb, 0x92);
t1_setreg(wc, 0xbb, 0x0c);
t1_setreg(wc, 0xbb, 0x00);
t1_setreg(wc, 0xbb, 0x8c);
t1_setreg(wc, 0x3a, 0x20); /* LIM2: 50% peak amplitude is a "1" */
t1_setreg(wc, 0x38, 0x0a); /* PCD: LOS after 176 consecutive "zeros" */
t1_setreg(wc, 0x39, 0x15); /* PCR: 22 "ones" clear LOS */
t1_setreg(wc, 0x20, 0x9f); /* XSW: Spare bits all to 1 */
t1_setreg(wc, 0x21, 0x1c|cas); /* XSP: E-bit set when async. AXS
auto, XSIF to 1 */
/* Generate pulse mask for E1 */
t1_setreg(wc, 0x26, 0x54); /* XPM0 */
t1_setreg(wc, 0x27, 0x02); /* XPM1 */
t1_setreg(wc, 0x28, 0x00); /* XPM2 */
t1_info(wc, "Span configured for %s/%s%s\n", framing, line, crc4);
}
static void t1xxp_framer_start(struct t1 *wc)
{
if (dahdi_is_e1_span(&wc->span)) {
t1_configure_e1(wc, wc->span.lineconfig);
} else { /* is a T1 card */
t1_configure_t1(wc, wc->span.lineconfig, wc->span.txlevel);
__t1xxp_set_clear(wc);
}
set_bit(DAHDI_FLAGBIT_RUNNING, &wc->span.flags);
}
static void set_span_devicetype(struct t1 *wc)
{
const char *olddevicetype;
olddevicetype = wc->ddev->devicetype;
#if defined(VPM_SUPPORT)
if (wc->vpmadt032) {
wc->ddev->devicetype = kasprintf(GFP_KERNEL,
"%s (VPMADT032)", wc->variety);
} else if (wc->vpmoct) {
wc->ddev->devicetype = kasprintf(GFP_KERNEL,
"%s (VPMOCT032)", wc->variety);
} else {
wc->ddev->devicetype = kasprintf(GFP_KERNEL, "%s", wc->variety);
}
#else
wc->ddev->devicetype = kasprintf(GFP_KERNEL, "%s", wc->variety);
#endif
/* On the off chance that we were able to allocate it previously. */
if (!wc->ddev->devicetype)
wc->ddev->devicetype = olddevicetype;
else
kfree(olddevicetype);
}
static int t1xxp_startup(struct file *file, struct dahdi_span *span)
{
struct t1 *wc = container_of(span, struct t1, span);
#ifndef CONFIG_VOICEBUS_ECREFERENCE
unsigned int i;
#endif
set_span_devicetype(wc);
#ifndef CONFIG_VOICEBUS_ECREFERENCE
/* initialize the start value for the entire chunk of last ec buffer */
for (i = 0; i < span->channels; i++) {
memset(wc->ec_chunk1[i], DAHDI_LIN2X(0, span->chans[i]), DAHDI_CHUNKSIZE);
memset(wc->ec_chunk2[i], DAHDI_LIN2X(0, span->chans[i]), DAHDI_CHUNKSIZE);
}
#endif
/* Reset framer with proper parameters and start */
t1xxp_framer_start(wc);
debug_printk(wc, 1, "Calling startup (flags is %lu)\n", span->flags);
return 0;
}
static inline bool is_initialized(struct t1 *wc)
{
WARN_ON(wc->not_ready < 0);
return (wc->not_ready == 0);
}
/**
* t1_wait_for_ready
*
* Check if the board has finished any setup and is ready to start processing
* calls.
*/
static int t1_wait_for_ready(struct t1 *wc)
{
while (!is_initialized(wc)) {
if (fatal_signal_pending(current))
return -EIO;
msleep_interruptible(250);
}
return 0;
}
static int t1xxp_chanconfig(struct file *file,
struct dahdi_chan *chan, int sigtype)
{
struct t1 *wc = chan->pvt;
if (file->f_flags & O_NONBLOCK && !is_initialized(wc)) {
return -EAGAIN;
} else {
t1_wait_for_ready(wc);
}
if (test_bit(DAHDI_FLAGBIT_RUNNING, &chan->span->flags) &&
dahdi_is_t1_span(&wc->span)) {
__t1xxp_set_clear(wc);
}
return 0;
}
static int t1xxp_rbsbits(struct dahdi_chan *chan, int bits)
{
u_char m,c;
int n,b;
struct t1 *wc = chan->pvt;
unsigned long flags;
debug_printk(wc, 2, "Setting bits to %d on channel %s\n",
bits, chan->name);
if (dahdi_is_e1_span(&wc->span)) { /* do it E1 way */
if (chan->chanpos == 16)
return 0;
n = chan->chanpos - 1;
if (chan->chanpos > 15) n--;
b = (n % 15);
spin_lock_irqsave(&wc->reglock, flags);
c = wc->txsigs[b];
m = (n / 15) << 2; /* nibble selector */
c &= (0xf << m); /* keep the other nibble */
c |= (bits & 0xf) << (4 - m); /* put our new nibble here */
wc->txsigs[b] = c;
spin_unlock_irqrestore(&wc->reglock, flags);
/* output them to the chip */
t1_setreg(wc, 0x71 + b, c);
} else if (wc->span.lineconfig & DAHDI_CONFIG_D4) {
n = chan->chanpos - 1;
b = (n / 4);
spin_lock_irqsave(&wc->reglock, flags);
c = wc->txsigs[b];
m = ((3 - (n % 4)) << 1); /* nibble selector */
c &= ~(0x3 << m); /* keep the other nibble */
c |= ((bits >> 2) & 0x3) << m; /* put our new nibble here */
wc->txsigs[b] = c;
spin_unlock_irqrestore(&wc->reglock, flags);
/* output them to the chip */
t1_setreg(wc, 0x70 + b, c);
t1_setreg(wc, 0x70 + b + 6, c);
} else if (wc->span.lineconfig & DAHDI_CONFIG_ESF) {
n = chan->chanpos - 1;
b = (n / 2);
spin_lock_irqsave(&wc->reglock, flags);
c = wc->txsigs[b];
m = ((n % 2) << 2); /* nibble selector */
c &= (0xf << m); /* keep the other nibble */
c |= (bits & 0xf) << (4 - m); /* put our new nibble here */
wc->txsigs[b] = c;
spin_unlock_irqrestore(&wc->reglock, flags);
/* output them to the chip */
t1_setreg(wc, 0x70 + b, c);
}
debug_printk(wc, 2, "Finished setting RBS bits\n");
return 0;
}
static inline void t1_check_sigbits(struct t1 *wc)
{
int a,i,rxs;
if (!(test_bit(DAHDI_FLAGBIT_RUNNING, &wc->span.flags)))
return;
if (dahdi_is_e1_span(&wc->span)) {
for (i = 0; i < 15; i++) {
a = t1_getreg(wc, 0x71 + i);
if (a > -1) {
/* Get high channel in low bits */
rxs = (a & 0xf);
if (!(wc->span.chans[i+16]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i+16]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i+16], rxs);
}
}
rxs = (a >> 4) & 0xf;
if (!(wc->span.chans[i]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i], rxs);
}
}
}
}
} else if (wc->span.lineconfig & DAHDI_CONFIG_D4) {
for (i = 0; i < 24; i+=4) {
a = t1_getreg(wc, 0x70 + (i>>2));
if (a > -1) {
/* Get high channel in low bits */
rxs = (a & 0x3) << 2;
if (!(wc->span.chans[i+3]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i+3]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i+3], rxs);
}
}
rxs = (a & 0xc);
if (!(wc->span.chans[i+2]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i+2]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i+2], rxs);
}
}
rxs = (a >> 2) & 0xc;
if (!(wc->span.chans[i+1]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i+1]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i+1], rxs);
}
}
rxs = (a >> 4) & 0xc;
if (!(wc->span.chans[i]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i], rxs);
}
}
}
}
} else {
for (i = 0; i < 24; i+=2) {
a = t1_getreg(wc, 0x70 + (i>>1));
if (a > -1) {
/* Get high channel in low bits */
rxs = (a & 0xf);
if (!(wc->span.chans[i+1]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i+1]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i+1], rxs);
}
}
rxs = (a >> 4) & 0xf;
if (!(wc->span.chans[i]->sig & DAHDI_SIG_CLEAR)) {
if (wc->span.chans[i]->rxsig != rxs) {
dahdi_rbsbits(wc->span.chans[i], rxs);
}
}
}
}
}
}
struct maint_work_struct {
struct work_struct work;
struct t1 *wc;
int cmd;
struct dahdi_span *span;
};
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
static void t1xxp_maint_work(void *data)
{
struct maint_work_struct *w = data;
#else
static void t1xxp_maint_work(struct work_struct *work)
{
struct maint_work_struct *w = container_of(work,
struct maint_work_struct, work);
#endif
struct t1 *wc = w->wc;
struct dahdi_span *span = w->span;
int reg = 0;
int cmd = w->cmd;
if (dahdi_is_e1_span(&wc->span)) {
switch (cmd) {
case DAHDI_MAINT_NONE:
t1_info(wc, "Clearing all maint modes\n");
t1xxp_clear_maint(span);
break;
case DAHDI_MAINT_LOCALLOOP:
t1xxp_clear_maint(span);
reg = t1_getreg(wc, LIM0);
if (reg < 0)
goto cleanup;
t1_setreg(wc, LIM0, reg | LIM0_LL);
break;
case DAHDI_MAINT_REMOTELOOP:
case DAHDI_MAINT_LOOPUP:
case DAHDI_MAINT_LOOPDOWN:
t1_info(wc, "Only local loop supported in E1 mode\n");
goto cleanup;
default:
t1_info(wc, "Unknown E1 maint command: %d\n", cmd);
goto cleanup;
}
} else {
switch (cmd) {
case DAHDI_MAINT_NONE:
t1xxp_clear_maint(span);
break;
case DAHDI_MAINT_LOCALLOOP:
t1xxp_clear_maint(span);
reg = t1_getreg(wc, LIM0);
if (reg < 0)
goto cleanup;
t1_setreg(wc, LIM0, reg | LIM0_LL);
break;
case DAHDI_MAINT_NETWORKLINELOOP:
t1xxp_clear_maint(span);
reg = t1_getreg(wc, LIM1);
if (reg < 0)
goto cleanup;
t1_setreg(wc, LIM1, reg | LIM1_RL);
break;
case DAHDI_MAINT_NETWORKPAYLOADLOOP:
t1xxp_clear_maint(span);
reg = t1_getreg(wc, LIM1);
if (reg < 0)
goto cleanup;
t1_setreg(wc, LIM1, reg | (LIM1_RL | LIM1_JATT));
break;
case DAHDI_MAINT_LOOPUP:
t1xxp_clear_maint(span);
t1_setreg(wc, 0x21, 0x50);
break;
case DAHDI_MAINT_LOOPDOWN:
t1xxp_clear_maint(span);
t1_setreg(wc, 0x21, 0x60);
break;
default:
t1_info(wc, "Unknown T1 maint command: %d\n", cmd);
return;
}
}
cleanup:
kfree(w);
return;
}
static int t1xxp_maint(struct dahdi_span *span, int cmd)
{
struct maint_work_struct *work;
struct t1 *wc = container_of(span, struct t1, span);
if (dahdi_is_e1_span(&wc->span)) {
switch (cmd) {
case DAHDI_MAINT_NONE:
case DAHDI_MAINT_LOCALLOOP:
break;
case DAHDI_MAINT_REMOTELOOP:
case DAHDI_MAINT_LOOPUP:
case DAHDI_MAINT_LOOPDOWN:
t1_info(wc, "Only local loop supported in E1 mode\n");
return -ENOSYS;
default:
t1_info(wc, "Unknown E1 maint command: %d\n", cmd);
return -ENOSYS;
}
} else {
switch (cmd) {
case DAHDI_MAINT_NONE:
case DAHDI_MAINT_LOCALLOOP:
case DAHDI_MAINT_NETWORKLINELOOP:
case DAHDI_MAINT_NETWORKPAYLOADLOOP:
case DAHDI_MAINT_LOOPUP:
case DAHDI_MAINT_LOOPDOWN:
break;
default:
t1_info(wc, "Unknown T1 maint command: %d\n", cmd);
return -ENOSYS;
}
}
work = kmalloc(sizeof(*work), GFP_ATOMIC);
if (!work) {
t1_info(wc, "Failed to allocate memory for workqueue\n");
return -ENOMEM;
}
work->span = span;
work->wc = wc;
work->cmd = cmd;
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
INIT_WORK(&work->work, t1xxp_maint_work, work);
#else
INIT_WORK(&work->work, t1xxp_maint_work);
#endif
queue_work(wc->wq, &work->work);
return 0;
}
static int t1xxp_clear_maint(struct dahdi_span *span)
{
struct t1 *wc = container_of(span, struct t1, span);
int reg = 0;
/* Turn off local loop */
reg = t1_getreg(wc, LIM0);
if (reg < 0)
return -EIO;
t1_setreg(wc, LIM0, reg & ~LIM0_LL);
/* Turn off remote loop & jitter attenuator */
reg = t1_getreg(wc, LIM1);
if (reg < 0)
return -EIO;
t1_setreg(wc, LIM1, reg & ~(LIM1_RL | LIM1_JATT));
/* Clear loopup/loopdown signals on the line */
t1_setreg(wc, 0x21, 0x40);
return 0;
}
static int t1xxp_ioctl(struct dahdi_chan *chan, unsigned int cmd, unsigned long data)
{
struct t4_regs regs;
unsigned int x;
struct t1 *wc;
switch (cmd) {
case WCT4_GET_REGS:
wc = chan->pvt;
for (x = 0; x < sizeof(regs.regs) / sizeof(regs.regs[0]); x++)
regs.regs[x] = t1_getreg(wc, x);
if (copy_to_user((void __user *) data, &regs, sizeof(regs)))
return -EFAULT;
break;
default:
return -ENOTTY;
}
return 0;
}
static const char *t1xxp_echocan_name(const struct dahdi_chan *chan)
{
struct t1 *wc = chan->pvt;
if (wc->vpmadt032)
return vpmadt032_name;
else if (wc->vpmoct)
return vpmoct_name;
return NULL;
}
static int t1xxp_echocan_create(struct dahdi_chan *chan,
struct dahdi_echocanparams *ecp,
struct dahdi_echocanparam *p,
struct dahdi_echocan_state **ec)
{
struct t1 *wc = chan->pvt;
enum adt_companding comp;
if (!vpmsupport || !test_bit(VPM150M_ACTIVE, &wc->ctlreg))
return -ENODEV;
if (wc->vpmadt032) {
*ec = wc->ec[chan->chanpos - 1];
(*ec)->ops = &vpm150m_ec_ops;
(*ec)->features = vpm150m_ec_features;
comp = (DAHDI_LAW_ALAW == chan->span->deflaw) ?
ADT_COMP_ALAW : ADT_COMP_ULAW;
return vpmadt032_echocan_create(wc->vpmadt032, chan->chanpos-1,
comp, ecp, p);
} else if (wc->vpmoct) {
/* Hookup legacy callbacks */
*ec = wc->ec[chan->chanpos - 1];
(*ec)->ops = &vpm150m_ec_ops;
(*ec)->features = vpm150m_ec_features;
return vpmoct_echocan_create(wc->vpmoct, chan->chanpos-1,
chan->span->deflaw);
} else {
return -ENODEV;
}
}
static void echocan_free(struct dahdi_chan *chan, struct dahdi_echocan_state *ec)
{
struct t1 *wc = chan->pvt;
if (wc->vpmadt032)
vpmadt032_echocan_free(wc->vpmadt032, chan->chanpos - 1, ec);
else if (wc->vpmoct)
vpmoct_echocan_free(wc->vpmoct, chan->chanpos - 1);
}
static void
setchanconfig_from_state(struct vpmadt032 *vpm, int channel,
GpakChannelConfig_t *chanconfig)
{
GpakEcanParms_t *p;
BUG_ON(!vpm);
chanconfig->PcmInPortA = 3;
chanconfig->PcmInSlotA = (channel + 1) * 2;
chanconfig->PcmOutPortA = SerialPortNull;
chanconfig->PcmOutSlotA = (channel + 1) * 2;
chanconfig->PcmInPortB = 2;
chanconfig->PcmInSlotB = (channel + 1) * 2;
chanconfig->PcmOutPortB = 3;
chanconfig->PcmOutSlotB = (channel + 1) * 2;
chanconfig->ToneTypesA = Null_tone;
chanconfig->MuteToneA = Disabled;
chanconfig->FaxCngDetA = Disabled;
chanconfig->ToneTypesB = Null_tone;
chanconfig->EcanEnableA = Enabled;
chanconfig->EcanEnableB = Disabled;
chanconfig->MuteToneB = Disabled;
chanconfig->FaxCngDetB = Disabled;
chanconfig->SoftwareCompand = cmpNone;
chanconfig->FrameRate = rate10ms;
p = &chanconfig->EcanParametersA;
vpmadt032_get_default_parameters(p);
p->EcanNlpType = vpm->curecstate[channel].nlp_type;
p->EcanNlpThreshold = vpm->curecstate[channel].nlp_threshold;
p->EcanNlpMaxSuppress = vpm->curecstate[channel].nlp_max_suppress;
memcpy(&chanconfig->EcanParametersB,
&chanconfig->EcanParametersA,
sizeof(chanconfig->EcanParametersB));
}
#ifdef VPM_SUPPORT
struct vpm_load_work {
struct work_struct work;
struct t1 *wc;
};
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
static void vpm_load_func(void *data)
{
struct maint_work_struct *w = data;
#else
static void vpm_load_func(struct work_struct *work)
{
struct vpm_load_work *w = container_of(work,
struct vpm_load_work, work);
#endif
struct t1 *wc = w->wc;
int res;
res = vpmadt032_init(wc->vpmadt032);
if (res) {
/* There was some problem during initialization, but it passed
* the address test, let's try again in a bit. */
wc->vpm_check = jiffies + HZ/2;
return;
}
if (config_vpmadt032(wc->vpmadt032, wc)) {
clear_bit(VPM150M_ACTIVE, &wc->ctlreg);
wc->vpm_check = jiffies + HZ/2;
return;
}
/* turn on vpm (RX audio from vpm module) */
set_bit(VPM150M_ACTIVE, &wc->ctlreg);
wc->vpm_check = jiffies + HZ*5;
if (vpmtsisupport) {
debug_printk(wc, 1, "enabling VPM TSI pin\n");
/* turn on vpm timeslot interchange pin */
set_bit(0, &wc->ctlreg);
}
wc->not_ready--;
kfree(w);
}
static int vpm_start_load(struct t1 *wc)
{
struct vpm_load_work *work;
work = kzalloc(sizeof(*work), GFP_KERNEL);
if (!work)
return -ENOMEM;
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
INIT_WORK(&work->work, vpm_load_func, work);
#else
INIT_WORK(&work->work, vpm_load_func);
#endif
work->wc = wc;
queue_work(wc->wq, &work->work);
wc->not_ready++;
return 0;
}
static void t1_vpm_load_complete(struct device *dev, bool operational)
{
unsigned long flags;
struct pci_dev *pdev = container_of(dev, struct pci_dev, dev);
struct t1 *wc = pci_get_drvdata(pdev);
struct vpmoct *vpm = NULL;
if (!wc || is_initialized(wc)) {
WARN_ON(!wc);
return;
}
spin_lock_irqsave(&wc->reglock, flags);
wc->not_ready--;
if (operational) {
set_bit(VPM150M_ACTIVE, &wc->ctlreg);
} else {
clear_bit(VPM150M_ACTIVE, &wc->ctlreg);
vpm = wc->vpmoct;
wc->vpmoct = NULL;
}
spin_unlock_irqrestore(&wc->reglock, flags);
if (vpm)
vpmoct_free(vpm);
}
static void check_and_load_vpm(struct t1 *wc)
{
unsigned long flags;
struct vpmadt032_options options;
struct vpmadt032 *vpmadt = NULL;
if (!vpmsupport) {
t1_info(wc, "VPM Support Disabled via module parameter\n");
return;
}
memset(&options, 0, sizeof(options));
options.debug = debug;
options.vpmnlptype = vpmnlptype;
options.vpmnlpthresh = vpmnlpthresh;
options.vpmnlpmaxsupp = vpmnlpmaxsupp;
options.channels = dahdi_is_t1_span(&wc->span) ? 24 : 32;
/* We do not want to check that the VPM is alive until after we're
* done setting it up here, an hour should cover it... */
wc->vpm_check = jiffies + HZ*3600;
/* If there was one already allocated, let's free it. */
if (wc->vpmadt032) {
vpmadt = wc->vpmadt032;
clear_bit(VPM150M_ACTIVE, &vpmadt->control);
flush_workqueue(vpmadt->wq);
spin_lock_irqsave(&wc->reglock, flags);
wc->vpmadt032 = NULL;
spin_unlock_irqrestore(&wc->reglock, flags);
vpmadt032_free(vpmadt);
}
vpmadt = vpmadt032_alloc(&options);
if (!vpmadt)
return;
vpmadt->setchanconfig_from_state = setchanconfig_from_state;
spin_lock_irqsave(&wc->reglock, flags);
wc->vpmadt032 = vpmadt;
spin_unlock_irqrestore(&wc->reglock, flags);
/* Probe for and attempt to load a vpmadt032 module */
if (vpmadt032_test(vpmadt, &wc->vb) || vpm_start_load(wc)) {
/* There does not appear to be a VPMADT032 installed. */
clear_bit(VPM150M_ACTIVE, &wc->ctlreg);
spin_lock_irqsave(&wc->reglock, flags);
wc->vpmadt032 = NULL;
spin_unlock_irqrestore(&wc->reglock, flags);
vpmadt032_free(vpmadt);
}
/* Probe for and attempt to load a vpmoct032 module */
if (NULL == wc->vpmadt032) {
struct vpmoct *vpmoct;
/* Check for vpmoct */
vpmoct = vpmoct_alloc();
if (!vpmoct)
return;
vpmoct->dev = &wc->vb.pdev->dev;
spin_lock_irqsave(&wc->reglock, flags);
wc->vpmoct = vpmoct;
wc->not_ready++;
spin_unlock_irqrestore(&wc->reglock, flags);
vpmoct_init(vpmoct, t1_vpm_load_complete);
}
set_span_devicetype(wc);
}
#else
static inline void check_and_load_vpm(const struct t1 *wc)
{
return;
}
#endif
static void t1_chan_set_sigcap(struct dahdi_span *span, int x)
{
struct t1 *wc = container_of(span, struct t1, span);
struct dahdi_chan *chan = wc->chans[x];
chan->sigcap = DAHDI_SIG_CLEAR;
/* E&M variant supported depends on span type */
if (dahdi_is_e1_span(&wc->span)) {
/* E1 sigcap setup */
if (span->lineconfig & DAHDI_CONFIG_CCS) {
/* CCS setup */
chan->sigcap |= DAHDI_SIG_MTP2 | DAHDI_SIG_SF;
return;
}
/* clear out sig and sigcap for channel 16 on E1 CAS
* lines, otherwise, set it correctly */
if (x == 15) {
/* CAS signaling channel setup */
wc->chans[15]->sigcap = 0;
wc->chans[15]->sig = 0;
return;
}
/* normal CAS setup */
chan->sigcap |= DAHDI_SIG_EM_E1 | DAHDI_SIG_FXSLS |
DAHDI_SIG_FXSGS | DAHDI_SIG_FXSKS | DAHDI_SIG_SF |
DAHDI_SIG_FXOLS | DAHDI_SIG_FXOGS | DAHDI_SIG_FXOKS |
DAHDI_SIG_CAS | DAHDI_SIG_DACS_RBS;
} else {
/* T1 sigcap setup */
chan->sigcap |= DAHDI_SIG_EM | DAHDI_SIG_FXSLS |
DAHDI_SIG_FXSGS | DAHDI_SIG_FXSKS | DAHDI_SIG_MTP2 |
DAHDI_SIG_SF | DAHDI_SIG_FXOLS | DAHDI_SIG_FXOGS |
DAHDI_SIG_FXOKS | DAHDI_SIG_CAS | DAHDI_SIG_DACS_RBS;
}
}
static int
t1xxp_spanconfig(struct file *file, struct dahdi_span *span,
struct dahdi_lineconfig *lc)
{
struct t1 *wc = container_of(span, struct t1, span);
int i;
if (file->f_flags & O_NONBLOCK) {
if (!is_initialized(wc))
return -EAGAIN;
} else {
t1_wait_for_ready(wc);
}
/* Do we want to SYNC on receive or not */
if (lc->sync) {
set_bit(7, &wc->ctlreg);
span->syncsrc = span->spanno;
} else {
clear_bit(7, &wc->ctlreg);
span->syncsrc = 0;
}
/* make sure that sigcaps gets updated if necessary */
for (i = 0; i < wc->span.channels; i++)
t1_chan_set_sigcap(span, i);
/* If already running, apply changes immediately */
if (test_bit(DAHDI_FLAGBIT_RUNNING, &span->flags))
return t1xxp_startup(file, span);
return 0;
}
static int t1xxp_enable_hw_preechocan(struct dahdi_chan *chan)
{
struct t1 *wc = chan->pvt;
if (!wc->vpmoct)
return 0;
return vpmoct_preecho_enable(wc->vpmoct, chan->chanpos - 1);
}
static void t1xxp_disable_hw_preechocan(struct dahdi_chan *chan)
{
struct t1 *wc = chan->pvt;
if (!wc->vpmoct)
return;
vpmoct_preecho_disable(wc->vpmoct, chan->chanpos - 1);
}
/**
* t1_software_init - Initialize the board for the given type.
* @wc: The board to initialize.
* @type: The type of board we are, T1 / E1
*
* This function is called at startup and when the type of the span is changed
* via the dahdi_device before the span is assigned a number.
*
*/
static int t1_software_init(struct t1 *wc, enum linemode type)
{
int x;
struct dahdi_chan *chans[32] = {NULL,};
struct dahdi_echocan_state *ec[32] = {NULL,};
unsigned long flags;
int res = 0;
/* We may already be setup properly. */
if (wc->span.channels == ((E1 == type) ? 31 : 24))
return 0;
for (x = 0; x < ((E1 == type) ? 31 : 24); x++) {
chans[x] = kzalloc(sizeof(*chans[x]), GFP_KERNEL);
ec[x] = kzalloc(sizeof(*ec[x]), GFP_KERNEL);
if (!chans[x] || !ec[x])
goto error_exit;
}
set_span_devicetype(wc);
/* Because the interrupt handler is running, we need to atomically
* swap the channel arrays. */
spin_lock_irqsave(&wc->reglock, flags);
_t1_free_channels(wc);
memcpy(wc->chans, chans, sizeof(wc->chans));
memcpy(wc->ec, ec, sizeof(wc->ec));
memset(chans, 0, sizeof(chans));
memset(ec, 0, sizeof(ec));
if (type == E1) {
wc->span.channels = 31;
wc->span.spantype = "E1";
wc->span.linecompat = DAHDI_CONFIG_AMI | DAHDI_CONFIG_HDB3 |
DAHDI_CONFIG_CCS | DAHDI_CONFIG_CRC4;
wc->span.deflaw = DAHDI_LAW_ALAW;
} else {
wc->span.channels = 24;
wc->span.spantype = "T1";
wc->span.linecompat = DAHDI_CONFIG_AMI | DAHDI_CONFIG_B8ZS |
DAHDI_CONFIG_D4 | DAHDI_CONFIG_ESF;
wc->span.deflaw = DAHDI_LAW_MULAW;
}
spin_unlock_irqrestore(&wc->reglock, flags);
if (!wc->ddev->location)
return -ENOMEM;
t1_info(wc, "Setting up global serial parameters for %s\n",
(dahdi_is_e1_span(&wc->span) ? "E1" : "T1"));
t4_serial_setup(wc);
set_bit(DAHDI_FLAGBIT_RBS, &wc->span.flags);
for (x = 0; x < wc->span.channels; x++) {
sprintf(wc->chans[x]->name, "%s/%d", wc->span.name, x + 1);
t1_chan_set_sigcap(&wc->span, x);
wc->chans[x]->pvt = wc;
wc->chans[x]->chanpos = x + 1;
}
check_and_load_vpm(wc);
set_span_devicetype(wc);
return 0;
error_exit:
for (x = 0; x < ARRAY_SIZE(chans); ++x) {
kfree(chans[x]);
kfree(ec[x]);
}
return res;
}
/**
* t1xx_set_linemode - Change the type of span before assignment.
* @span: The span to change.
* @linemode: Text string for the line mode.
*
* This function may be called after the dahdi_device is registered but
* before the spans are assigned numbers (and are visible to the rest of
* DAHDI).
*
*/
static int t1xxp_set_linemode(struct dahdi_span *span, const char *linemode)
{
int res;
struct t1 *wc = container_of(span, struct t1, span);
/* We may already be set to the requested type. */
if (!strcasecmp(span->spantype, linemode))
return 0;
res = t1_wait_for_ready(wc);
if (res)
return res;
/* Stop the processing of the channels since we're going to change
* them. */
clear_bit(INITIALIZED, &wc->bit_flags);
smp_mb__after_clear_bit();
del_timer_sync(&wc->timer);
flush_workqueue(wc->wq);
if (!strcasecmp(linemode, "t1")) {
dev_info(&wc->vb.pdev->dev,
"Changing from E1 to T1 line mode.\n");
res = t1_software_init(wc, T1);
} else if (!strcasecmp(linemode, "e1")) {
dev_info(&wc->vb.pdev->dev,
"Changing from T1 to E1 line mode.\n");
res = t1_software_init(wc, E1);
} else {
dev_err(&wc->vb.pdev->dev,
"'%s' is an unknown linemode.\n", linemode);
res = -EINVAL;
}
/* Since we probably reallocated the channels we need to make
* sure they are configured before setting INITIALIZED again. */
if (!res) {
dahdi_init_span(span);
set_bit(INITIALIZED, &wc->bit_flags);
mod_timer(&wc->timer, jiffies + HZ/5);
}
return res;
}
#if 0
#ifdef VPM_SUPPORT
static inline unsigned char t1_vpm_in(struct t1 *wc, int unit, const unsigned int addr)
{
return t1_getreg_full(wc, addr, unit);
}
static inline unsigned char t1_vpm_out(struct t1 *wc, int unit, const unsigned int addr, const unsigned char val)
{
return t1_setreg(wc, addr, val, unit);
}
#endif
#endif
static int t1_hardware_post_init(struct t1 *wc, enum linemode *type)
{
int res;
int reg;
int x;
/* T1 or E1 */
if (-1 != t1e1override) {
pr_info("t1e1override is deprecated. Please use 'default_linemode'.\n");
*type = (t1e1override) ? E1 : T1;
} else {
if (!strcasecmp(default_linemode, "e1")) {
*type = E1;
} else if (!strcasecmp(default_linemode, "t1")) {
*type = T1;
} else {
u8 pins;
res = t1_getpins(wc, &pins);
if (res)
return res;
*type = (pins & 0x01) ? T1 : E1;
}
}
debug_printk(wc, 1, "linemode: %s\n", (*type == T1) ? "T1" : "E1");
/* what version of the FALC are we using? */
reg = t1_setreg(wc, 0x4a, 0xaa);
reg = t1_getreg(wc, 0x4a);
if (reg < 0) {
t1_info(wc, "Failed to read FALC version (%d)\n", reg);
return -EIO;
}
debug_printk(wc, 1, "FALC version: %08x\n", reg);
/* make sure reads and writes work */
for (x = 0; x < 256; x++) {
t1_setreg(wc, 0x14, x);
reg = t1_getreg(wc, 0x14);
if (reg < 0) {
t1_info(wc, "Failed register read (%d)\n", reg);
return -EIO;
}
if (reg != x) {
t1_info(wc, "Register test failed. "
"Wrote '%x' but read '%x'\n", x, reg);
return -EIO;
}
}
t1_setleds(wc, wc->ledstate);
return 0;
}
static inline void t1_check_alarms(struct t1 *wc)
{
unsigned char c,d;
int alarms;
int x,j;
unsigned char fmr4; /* must read this always */
if (!(test_bit(DAHDI_FLAGBIT_RUNNING, &wc->span.flags)))
return;
c = t1_getreg(wc, 0x4c);
fmr4 = t1_getreg(wc, 0x20); /* must read this even if we don't use it */
d = t1_getreg(wc, 0x4d);
/* Assume no alarms */
alarms = 0;
/* And consider only carrier alarms */
wc->span.alarms &= (DAHDI_ALARM_RED | DAHDI_ALARM_BLUE | DAHDI_ALARM_NOTOPEN);
if (dahdi_is_e1_span(&wc->span)) {
if (c & 0x04) {
/* No multiframe found, force RAI high after 400ms only if
we haven't found a multiframe since last loss
of frame */
if (!wc->flags.nmf) {
t1_setreg(wc, 0x20, 0x9f | 0x20); /* LIM0: Force RAI High */
wc->flags.nmf = 1;
t1_info(wc, "NMF workaround on!\n");
}
t1_setreg(wc, 0x1e, 0xc3); /* Reset to CRC4 mode */
t1_setreg(wc, 0x1c, 0xf2); /* Force Resync */
t1_setreg(wc, 0x1c, 0xf0); /* Force Resync */
} else if (!(c & 0x02)) {
if (wc->flags.nmf) {
t1_setreg(wc, 0x20, 0x9f); /* LIM0: Clear forced RAI */
wc->flags.nmf = 0;
t1_info(wc, "NMF workaround off!\n");
}
}
} else {
/* Detect loopup code if we're not sending one */
if ((!wc->span.mainttimer) && (d & 0x08)) {
/* Loop-up code detected */
if ((wc->span.maintstat != DAHDI_MAINT_REMOTELOOP)) {
t1_notice(wc, "Loopup detected,"\
" enabling remote loop\n");
t1_setreg(wc, 0x36, 0x08); /* LIM0: Disable any local loop */
t1_setreg(wc, 0x37, 0xf6); /* LIM1: Enable remote loop */
wc->span.maintstat = DAHDI_MAINT_REMOTELOOP;
}
} else
wc->loopupcnt = 0;
/* Same for loopdown code */
if ((!wc->span.mainttimer) && (d & 0x10)) {
/* Loop-down code detected */
if ((wc->span.maintstat == DAHDI_MAINT_REMOTELOOP)) {
t1_notice(wc, "Loopdown detected,"\
" disabling remote loop\n");
t1_setreg(wc, 0x36, 0x08); /* LIM0: Disable any local loop */
t1_setreg(wc, 0x37, 0xf0); /* LIM1: Disable remote loop */
wc->span.maintstat = DAHDI_MAINT_NONE;
}
} else
wc->loopdowncnt = 0;
}
if (wc->span.lineconfig & DAHDI_CONFIG_NOTOPEN) {
for (x=0,j=0;x < wc->span.channels;x++)
if ((wc->span.chans[x]->flags & DAHDI_FLAG_OPEN) ||
dahdi_have_netdev(wc->span.chans[x]))
j++;
if (!j)
alarms |= DAHDI_ALARM_NOTOPEN;
}
if (c & 0x20) { /* LOF/LFA */
if (wc->alarmcount >= (alarmdebounce/100))
alarms |= DAHDI_ALARM_RED;
else {
if (unlikely(debug && !wc->alarmcount)) {
/* starting to debounce LOF/LFA */
t1_info(wc, "LOF/LFA detected but "
"debouncing for %d ms\n",
alarmdebounce);
}
wc->alarmcount++;
}
} else
wc->alarmcount = 0;
if (c & 0x80) { /* LOS */
if (wc->losalarmcount >= (losalarmdebounce/100))
alarms |= DAHDI_ALARM_RED;
else {
if (unlikely(debug && !wc->losalarmcount)) {
/* starting to debounce LOS */
t1_info(wc, "LOS detected but debouncing "
"for %d ms\n", losalarmdebounce);
}
wc->losalarmcount++;
}
} else
wc->losalarmcount = 0;
if (c & 0x40) { /* AIS */
if (wc->aisalarmcount >= (aisalarmdebounce/100))
alarms |= DAHDI_ALARM_BLUE;
else {
if (unlikely(debug && !wc->aisalarmcount)) {
/* starting to debounce AIS */
t1_info(wc, "AIS detected but debouncing "
"for %d ms\n", aisalarmdebounce);
}
wc->aisalarmcount++;
}
} else
wc->aisalarmcount = 0;
/* Keep track of recovering */
if ((!alarms) && wc->span.alarms)
wc->alarmtimer = jiffies + 5*HZ;
if (wc->alarmtimer)
alarms |= DAHDI_ALARM_RECOVER;
/* If receiving alarms, go into Yellow alarm state */
if (alarms && !wc->flags.sendingyellow) {
t1_info(wc, "Setting yellow alarm\n");
/* We manually do yellow alarm to handle RECOVER and NOTOPEN, otherwise it's auto anyway */
t1_setreg(wc, 0x20, fmr4 | 0x20);
wc->flags.sendingyellow = 1;
} else if (!alarms && wc->flags.sendingyellow) {
t1_info(wc, "Clearing yellow alarm\n");
/* We manually do yellow alarm to handle RECOVER */
t1_setreg(wc, 0x20, fmr4 & ~0x20);
wc->flags.sendingyellow = 0;
}
/*
if ((c & 0x10))
alarms |= DAHDI_ALARM_YELLOW;
*/
if (c & 0x10) { /* receiving yellow (RAI) */
if (wc->yelalarmcount >= (yelalarmdebounce/100))
alarms |= DAHDI_ALARM_YELLOW;
else {
if (unlikely(debug && !wc->yelalarmcount)) {
/* starting to debounce AIS */
t1_info(wc, "yelllow (RAI) detected but "
"debouncing for %d ms\n",
yelalarmdebounce);
}
wc->yelalarmcount++;
}
} else
wc->yelalarmcount = 0;
if (wc->span.mainttimer || wc->span.maintstat)
alarms |= DAHDI_ALARM_LOOPBACK;
wc->span.alarms = alarms;
dahdi_alarm_notify(&wc->span);
}
static void handle_leds(struct t1 *wc)
{
unsigned char led;
unsigned long flags;
led = wc->ledstate;
if ((wc->span.alarms & (DAHDI_ALARM_RED | DAHDI_ALARM_BLUE))
|| wc->losalarmcount) {
/* When we're in red alarm, blink the led once a second. */
if (time_after(jiffies, wc->blinktimer)) {
led = (led & __LED_GREEN) ? SET_LED_RED(led) : UNSET_LED_REDGREEN(led);
}
} else if (wc->span.alarms & DAHDI_ALARM_YELLOW) {
led = (led & __LED_RED) ? SET_LED_GREEN(led) : SET_LED_RED(led);
} else {
if (wc->span.maintstat != DAHDI_MAINT_NONE)
led = SET_LED_ORANGE(led);
else
led = UNSET_LED_ORANGE(led);
if (test_bit(DAHDI_FLAGBIT_RUNNING, &wc->span.flags))
led = SET_LED_GREEN(led);
else
led = UNSET_LED_REDGREEN(led);
}
if (led != wc->ledstate) {
struct command *cmd;
cmd = get_free_cmd(wc);
if (cmd) {
wc->blinktimer = jiffies + HZ/2;
cmd->flags |= __CMD_LEDS;
cmd->address = ~led & 0x0E;
submit_cmd(wc, cmd);
spin_lock_irqsave(&wc->reglock, flags);
wc->ledstate = led;
spin_unlock_irqrestore(&wc->reglock, flags);
}
}
}
static void t1_do_counters(struct t1 *wc)
{
if (wc->alarmtimer && time_after(jiffies, wc->alarmtimer)) {
wc->span.alarms &= ~(DAHDI_ALARM_RECOVER);
wc->alarmtimer = 0;
dahdi_alarm_notify(&wc->span);
}
}
static void insert_tdm_data(const struct t1 *wc, u8 *sframe)
{
int i;
register u8 *chanchunk;
const int channels = wc->span.channels;
for (i = 0; i < channels; ++i) {
chanchunk = &wc->chans[i]->writechunk[0];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*0] = chanchunk[0];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*1] = chanchunk[1];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*2] = chanchunk[2];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*3] = chanchunk[3];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*4] = chanchunk[4];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*5] = chanchunk[5];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*6] = chanchunk[6];
sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*7] = chanchunk[7];
}
}
static inline void t1_transmitprep(struct t1 *wc, u8 *sframe)
{
int x;
int y;
u8 *eframe = sframe;
/* Calculate Transmission */
if (likely(test_bit(INITIALIZED, &wc->bit_flags)))
_dahdi_transmit(&wc->span);
#ifdef CONFIG_VOICEBUS_ECREFERENCE
for (chan = 0; chan < wc->span.channels; chan++) {
__dahdi_fifo_put(wc->ec_reference[chan],
wc->chans[chan]->writechunk, DAHDI_CHUNKSIZE);
}
#endif
if (likely(test_bit(INITIALIZED, &wc->bit_flags)))
insert_tdm_data(wc, sframe);
spin_lock(&wc->reglock);
for (x = 0; x < DAHDI_CHUNKSIZE; x++) {
/* process the command queue */
for (y = 0; y < 7; y++)
cmd_dequeue(wc, eframe, x, y);
#ifdef VPM_SUPPORT
if (wc->vpmadt032) {
cmd_dequeue_vpmadt032(wc, eframe);
} else if (wc->vpmoct) {
cmd_dequeue_vpmoct(wc, eframe);
}
#endif
if (x < DAHDI_CHUNKSIZE - 1) {
eframe[EFRAME_SIZE] = wc->ctlreg;
eframe[EFRAME_SIZE + 1] = wc->txident++;
}
eframe += (EFRAME_SIZE + EFRAME_GAP);
}
spin_unlock(&wc->reglock);
}
/**
* is_good_frame() - Whether the SFRAME received was one sent.
*
*/
static inline bool is_good_frame(const u8 *sframe)
{
const u8 a = sframe[0*(EFRAME_SIZE+EFRAME_GAP) + (EFRAME_SIZE+1)];
const u8 b = sframe[1*(EFRAME_SIZE+EFRAME_GAP) + (EFRAME_SIZE+1)];
return a != b;
}
/**
* extract_tdm_data() - Move TDM data from sframe to channels.
*
*/
static void extract_tdm_data(struct t1 *wc, const u8 *const sframe)
{
int i;
register u8 *chanchunk;
const int channels = wc->span.channels;
for (i = 0; i < channels; ++i) {
chanchunk = &wc->chans[i]->readchunk[0];
chanchunk[0] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*0];
chanchunk[1] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*1];
chanchunk[2] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*2];
chanchunk[3] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*3];
chanchunk[4] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*4];
chanchunk[5] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*5];
chanchunk[6] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*6];
chanchunk[7] = sframe[(i+1)*2 + (EFRAME_SIZE + EFRAME_GAP)*7];
}
/* Pre-echo with the vpmoct overwrites the 24th timeslot with the
* specified channel's pre-echo audio stream. This timeslot is unused
* by the te12xp */
if (wc->vpmoct && wc->vpmoct->preecho_enabled) {
chanchunk = &wc->vpmoct->preecho_buf[0];
chanchunk[0] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*0];
chanchunk[1] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*1];
chanchunk[2] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*2];
chanchunk[3] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*3];
chanchunk[4] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*4];
chanchunk[5] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*5];
chanchunk[6] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*6];
chanchunk[7] = sframe[23 + (EFRAME_SIZE + EFRAME_GAP)*7];
}
}
static inline void t1_receiveprep(struct t1 *wc, const u8* sframe)
{
int x;
unsigned char expected;
const u8 *eframe = sframe;
if (!is_good_frame(sframe))
return;
if (likely(test_bit(INITIALIZED, &wc->bit_flags)))
extract_tdm_data(wc, sframe);
spin_lock(&wc->reglock);
for (x = 0; x < DAHDI_CHUNKSIZE; x++) {
if (x < DAHDI_CHUNKSIZE - 1) {
expected = wc->rxident+1;
wc->rxident = eframe[EFRAME_SIZE + 1];
wc->statreg = eframe[EFRAME_SIZE + 2];
if (wc->rxident != expected) {
wc->ddev->irqmisses++;
_resend_cmds(wc);
if (unlikely(debug)) {
t1_info(wc, "oops: rxident=%d "
"expected=%d x=%d\n",
wc->rxident, expected, x);
}
}
}
cmd_decipher(wc, eframe);
#ifdef VPM_SUPPORT
if (wc->vpmadt032)
cmd_decipher_vpmadt032(wc, eframe);
else if (wc->vpmoct)
cmd_decipher_vpmoct(wc, eframe);
#endif
eframe += (EFRAME_SIZE + EFRAME_GAP);
}
spin_unlock(&wc->reglock);
/* echo cancel */
if (likely(test_bit(INITIALIZED, &wc->bit_flags))) {
for (x = 0; x < wc->span.channels; x++) {
struct dahdi_chan *const c = wc->chans[x];
#ifdef CONFIG_VOICEBUS_ECREFERENCE
unsigned char buffer[DAHDI_CHUNKSIZE];
__dahdi_fifo_get(wc->ec_reference[x], buffer,
ARRAY_SIZE(buffer));
_dahdi_ec_chunk(c, c->readchunk,
buffer);
#else
if ((wc->vpmoct) &&
(c->chanpos-1 == wc->vpmoct->preecho_timeslot) &&
(wc->vpmoct->preecho_enabled)) {
__dahdi_ec_chunk(c, c->readchunk,
wc->vpmoct->preecho_buf,
c->writechunk);
} else {
_dahdi_ec_chunk(c, c->readchunk,
wc->ec_chunk2[x]);
memcpy(wc->ec_chunk2[x], wc->ec_chunk1[x],
DAHDI_CHUNKSIZE);
memcpy(wc->ec_chunk1[x], c->writechunk,
DAHDI_CHUNKSIZE);
}
}
#endif
_dahdi_receive(&wc->span);
}
}
static void t1_handle_transmit(struct voicebus *vb, struct list_head *buffers)
{
struct t1 *wc = container_of(vb, struct t1, vb);
struct vbb *vbb;
list_for_each_entry(vbb, buffers, entry) {
memset(vbb->data, 0, sizeof(vbb->data));
atomic_inc(&wc->txints);
t1_transmitprep(wc, vbb->data);
handle_leds(wc);
}
}
static void t1_handle_receive(struct voicebus *vb, struct list_head *buffers)
{
struct t1 *wc = container_of(vb, struct t1, vb);
struct vbb *vbb;
list_for_each_entry(vbb, buffers, entry)
t1_receiveprep(wc, vbb->data);
}
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
static void timer_work_func(void *param)
{
struct t1 *wc = param;
#else
static void timer_work_func(struct work_struct *work)
{
struct t1 *wc = container_of(work, struct t1, timer_work);
#endif
t1_do_counters(wc);
t1_check_alarms(wc);
t1_check_sigbits(wc);
if (test_bit(INITIALIZED, &wc->bit_flags))
mod_timer(&wc->timer, jiffies + HZ/10);
}
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
static void vpm_check_func(void *data)
{
struct t1 *wc = data;
#else
static void vpm_check_func(struct work_struct *work)
{
struct t1 *wc = container_of(work, struct t1, vpm_check_work);
#endif
int res;
u16 version;
const int MAX_CHECKS = 5;
/* If there is a failed VPM module, do not block dahdi_cfg
* indefinitely. */
if (++wc->vpm_check_count > MAX_CHECKS) {
wc->not_ready--;
wc->vpm_check = MAX_JIFFY_OFFSET;
t1_info(wc, "Disabling VPMADT032 Checking.\n");
return;
}
if (!test_bit(INITIALIZED, &wc->bit_flags))
return;
if (test_bit(VPM150M_ACTIVE, &wc->ctlreg)) {
res = gpakPingDsp(wc->vpmadt032->dspid, &version);
if (!res) {
set_bit(VPM150M_ACTIVE, &wc->ctlreg);
wc->vpm_check = jiffies + HZ*5;
wc->vpm_check_count = 0;
return;
}
clear_bit(VPM150M_ACTIVE, &wc->ctlreg);
t1_info(wc, "VPMADT032 is non-responsive. Resetting.\n");
}
if (!test_bit(INITIALIZED, &wc->bit_flags))
return;
res = vpmadt032_reset(wc->vpmadt032);
if (res) {
t1_info(wc, "Failed VPMADT032 reset. VPMADT032 is disabled.\n");
wc->vpm_check = jiffies + HZ*5;
return;
}
if (!test_bit(INITIALIZED, &wc->bit_flags))
return;
res = config_vpmadt032(wc->vpmadt032, wc);
if (res) {
/* We failed the configuration, let's try again. */
t1_info(wc, "Failed to configure the ports. Retrying.\n");
if (!test_bit(INITIALIZED, &wc->bit_flags))
return;
queue_work(wc->vpmadt032->wq, &wc->vpm_check_work);
return;
}
if (!test_bit(INITIALIZED, &wc->bit_flags))
return;
/* Looks like the reset went ok so we can put the VPM module back in
* the TDM path. */
set_bit(VPM150M_ACTIVE, &wc->ctlreg);
t1_info(wc, "VPMADT032 is reenabled.\n");
wc->vpm_check = jiffies + HZ*5;
wc->not_ready--;
return;
}
static void te12xp_timer(unsigned long data)
{
unsigned long flags;
struct t1 *wc = (struct t1 *)data;
if (unlikely(!test_bit(INITIALIZED, &wc->bit_flags)))
return;
queue_work(wc->wq, &wc->timer_work);
spin_lock_irqsave(&wc->reglock, flags);
if (!wc->vpmadt032)
goto unlock_exit;
if (time_after(wc->vpm_check, jiffies))
goto unlock_exit;
queue_work(wc->vpmadt032->wq, &wc->vpm_check_work);
unlock_exit:
spin_unlock_irqrestore(&wc->reglock, flags);
return;
}
static void t1_handle_error(struct voicebus *vb)
{
unsigned long flags;
struct t1 *wc = container_of(vb, struct t1, vb);
spin_lock_irqsave(&wc->reglock, flags);
if (!wc->vpmadt032)
goto unlock_exit;
clear_bit(VPM150M_ACTIVE, &wc->ctlreg);
queue_work(wc->vpmadt032->wq, &wc->vpm_check_work);
unlock_exit:
spin_unlock_irqrestore(&wc->reglock, flags);
}
static const struct voicebus_operations voicebus_operations = {
.handle_receive = t1_handle_receive,
.handle_transmit = t1_handle_transmit,
.handle_error = t1_handle_error,
};
#ifdef CONFIG_VOICEBUS_SYSFS
static ssize_t voicebus_current_latency_show(struct device *dev,
struct device_attribute *attr,
char *buf)
{
unsigned long flags;
struct t1 *wc = dev_get_drvdata(dev);
unsigned int current_latency;
spin_lock_irqsave(&wc->vb.lock, flags);
current_latency = wc->vb.min_tx_buffer_count;
spin_unlock_irqrestore(&wc->vb.lock, flags);
return sprintf(buf, "%d\n", current_latency);
}
static DEVICE_ATTR(voicebus_current_latency, 0400,
voicebus_current_latency_show, NULL);
static ssize_t vpm_firmware_version_show(struct device *dev,
struct device_attribute *attr,
char *buf)
{
int res;
u16 version = 0;
struct t1 *wc = dev_get_drvdata(dev);
if (wc->vpmadt032) {
res = gpakPingDsp(wc->vpmadt032->dspid, &version);
if (res) {
t1_info(wc, "Failed gpakPingDsp %d\n", res);
version = -1;
}
}
return sprintf(buf, "%x.%02x\n", (version & 0xff00) >> 8, (version & 0xff));
}
static DEVICE_ATTR(vpm_firmware_version, 0400,
vpm_firmware_version_show, NULL);
static void create_sysfs_files(struct t1 *wc)
{
int ret;
ret = device_create_file(&wc->vb.pdev->dev,
&dev_attr_voicebus_current_latency);
if (ret) {
dev_info(&wc->vb.pdev->dev,
"Failed to create device attributes.\n");
}
ret = device_create_file(&wc->vb.pdev->dev,
&dev_attr_vpm_firmware_version);
if (ret) {
dev_info(&wc->vb.pdev->dev,
"Failed to create device attributes.\n");
}
}
static void remove_sysfs_files(struct t1 *wc)
{
device_remove_file(&wc->vb.pdev->dev,
&dev_attr_vpm_firmware_version);
device_remove_file(&wc->vb.pdev->dev,
&dev_attr_voicebus_current_latency);
}
#else
static inline void create_sysfs_files(struct t1 *wc) { return; }
static inline void remove_sysfs_files(struct t1 *wc) { return; }
#endif /* CONFIG_VOICEBUS_SYSFS */
static const struct dahdi_span_ops t1_span_ops = {
.owner = THIS_MODULE,
.spanconfig = t1xxp_spanconfig,
.chanconfig = t1xxp_chanconfig,
.startup = t1xxp_startup,
.rbsbits = t1xxp_rbsbits,
.maint = t1xxp_maint,
.ioctl = t1xxp_ioctl,
.set_spantype = t1xxp_set_linemode,
#ifdef VPM_SUPPORT
.enable_hw_preechocan = t1xxp_enable_hw_preechocan,
.disable_hw_preechocan = t1xxp_disable_hw_preechocan,
.echocan_create = t1xxp_echocan_create,
.echocan_name = t1xxp_echocan_name,
#endif
};
static int __devinit te12xp_init_one(struct pci_dev *pdev, const struct pci_device_id *ent)
{
struct t1 *wc;
const struct t1_desc *d = (struct t1_desc *) ent->driver_data;
unsigned int x;
int res;
unsigned int index = -1;
enum linemode type;
for (x = 0; x < ARRAY_SIZE(ifaces); x++) {
if (!ifaces[x]) {
index = x;
break;
}
}
if (-1 == index) {
printk(KERN_INFO "%s: Too many interfaces\n",
THIS_MODULE->name);
return -EIO;
}
wc = kzalloc(sizeof(*wc), GFP_KERNEL);
if (!wc)
return -ENOMEM;
/* Set the performance counters to -1 since this card currently does
* not support collecting them. */
memset(&wc->span.count, -1, sizeof(wc->span.count));
ifaces[index] = wc;
sprintf(wc->span.name, "WCT1/%d", index);
snprintf(wc->span.desc, sizeof(wc->span.desc) - 1, "%s Card %d",
d->name, index);
wc->not_ready = 1;
wc->ledstate = -1;
wc->variety = d->name;
wc->txident = 1;
spin_lock_init(&wc->reglock);
INIT_LIST_HEAD(&wc->active_cmds);
INIT_LIST_HEAD(&wc->pending_cmds);
# if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 18)
wc->timer.function = te12xp_timer;
wc->timer.data = (unsigned long)wc;
init_timer(&wc->timer);
# else
setup_timer(&wc->timer, te12xp_timer, (unsigned long)wc);
# endif
# if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
INIT_WORK(&wc->timer_work, timer_work_func, wc);
# else
INIT_WORK(&wc->timer_work, timer_work_func);
# endif
# if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 20)
INIT_WORK(&wc->vpm_check_work, vpm_check_func, wc);
# else
INIT_WORK(&wc->vpm_check_work, vpm_check_func);
# endif
wc->ddev = dahdi_create_device();
if (!wc->ddev) {
ifaces[index] = NULL;
kfree(wc);
return -ENOMEM;
}
wc->ddev->manufacturer = "Digium";
wc->ddev->location = kasprintf(GFP_KERNEL, "PCI Bus %02d Slot %02d",
pdev->bus->number,
PCI_SLOT(pdev->devfn) + 1);
if (!wc->ddev->location) {
ifaces[index] = NULL;
kfree(wc);
return -ENOMEM;
}
#ifdef CONFIG_VOICEBUS_ECREFERENCE
for (x = 0; x < ARRAY_SIZE(wc->ec_reference); ++x) {
/* 256 is used here since it is the largest power of two that
* will contain 8 * VOICBUS_DEFAULT_LATENCY */
wc->ec_reference[x] = dahdi_fifo_alloc(256, GFP_KERNEL);
if (IS_ERR(wc->ec_reference[x])) {
res = PTR_ERR(wc->ec_reference[x]);
wc->ec_reference[x] = NULL;
free_wc(wc);
return res;
}
}
#endif /* CONFIG_VOICEBUS_ECREFERENCE */
#ifdef CONFIG_VOICEBUS_DISABLE_ASPM
if (is_pcie(wc)) {
pci_disable_link_state(pdev->bus->self, PCIE_LINK_STATE_L0S |
PCIE_LINK_STATE_L1 | PCIE_LINK_STATE_CLKPM);
};
#endif
snprintf(wc->name, sizeof(wc->name)-1, "wcte12xp%d", index);
pci_set_drvdata(pdev, wc);
wc->vb.ops = &voicebus_operations;
wc->vb.pdev = pdev;
wc->vb.debug = &debug;
res = voicebus_init(&wc->vb, wc->name);
if (res) {
free_wc(wc);
ifaces[index] = NULL;
return res;
}
wc->wq = create_singlethread_workqueue(wc->name);
if (!wc->wq) {
kfree(wc);
ifaces[index] = NULL;
return -ENOMEM;
}
voicebus_set_minlatency(&wc->vb, latency);
voicebus_set_maxlatency(&wc->vb, max_latency);
max_latency = wc->vb.max_latency;
create_sysfs_files(wc);
voicebus_lock_latency(&wc->vb);
if (voicebus_start(&wc->vb)) {
voicebus_release(&wc->vb);
free_wc(wc);
ifaces[index] = NULL;
return -EIO;
}
res = t1_hardware_post_init(wc, &type);
if (res) {
voicebus_release(&wc->vb);
free_wc(wc);
ifaces[index] = NULL;
return res;
}
wc->span.chans = wc->chans;
res = t1_software_init(wc, type);
if (res) {
voicebus_release(&wc->vb);
free_wc(wc);
ifaces[index] = NULL;
return res;
}
wc->span.ops = &t1_span_ops;
list_add_tail(&wc->span.device_node, &wc->ddev->spans);
res = dahdi_register_device(wc->ddev, &wc->vb.pdev->dev);
if (res) {
t1_info(wc, "Unable to register with DAHDI\n");
return res;
}
set_bit(INITIALIZED, &wc->bit_flags);
mod_timer(&wc->timer, jiffies + HZ/5);
t1_info(wc, "Found a %s\n", wc->variety);
voicebus_unlock_latency(&wc->vb);
wc->not_ready--;
return 0;
}
static void __devexit te12xp_remove_one(struct pci_dev *pdev)
{
struct t1 *wc = pci_get_drvdata(pdev);
#ifdef VPM_SUPPORT
unsigned long flags;
struct vpmadt032 *vpmadt = wc->vpmadt032;
struct vpmoct *vpmoct = wc->vpmoct;
#endif
if (!wc)
return;
dahdi_unregister_device(wc->ddev);
remove_sysfs_files(wc);
clear_bit(INITIALIZED, &wc->bit_flags);
smp_mb__after_clear_bit();
del_timer_sync(&wc->timer);
flush_workqueue(wc->wq);
#ifdef VPM_SUPPORT
if (vpmadt) {
clear_bit(VPM150M_ACTIVE, &vpmadt->control);
flush_workqueue(vpmadt->wq);
} else if (vpmoct) {
while (t1_wait_for_ready(wc))
schedule();
}
#endif
del_timer_sync(&wc->timer);
voicebus_release(&wc->vb);
#ifdef VPM_SUPPORT
if (vpmadt) {
spin_lock_irqsave(&wc->reglock, flags);
wc->vpmadt032 = NULL;
spin_unlock_irqrestore(&wc->reglock, flags);
vpmadt032_free(vpmadt);
} else if (vpmoct) {
spin_lock_irqsave(&wc->reglock, flags);
wc->vpmoct = NULL;
spin_unlock_irqrestore(&wc->reglock, flags);
vpmoct_free(vpmoct);
}
#endif
t1_info(wc, "Freed a Wildcard TE12xP.\n");
free_wc(wc);
}
static DEFINE_PCI_DEVICE_TABLE(te12xp_pci_tbl) = {
{ 0xd161, 0x0120, PCI_ANY_ID, PCI_ANY_ID, 0, 0, (unsigned long) &te120p},
{ 0xd161, 0x8000, PCI_ANY_ID, PCI_ANY_ID, 0, 0, (unsigned long) &te121},
{ 0xd161, 0x8001, PCI_ANY_ID, PCI_ANY_ID, 0, 0, (unsigned long) &te122},
{ 0 }
};
#if LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 12)
static void te12xp_shutdown(struct pci_dev *pdev)
{
struct t1 *wc = pci_get_drvdata(pdev);
voicebus_quiesce(&wc->vb);
}
#endif
static int te12xp_suspend(struct pci_dev *pdev, pm_message_t state)
{
return -ENOSYS;
}
MODULE_DEVICE_TABLE(pci, te12xp_pci_tbl);
static struct pci_driver te12xp_driver = {
.name = "wcte12xp",
.probe = te12xp_init_one,
.remove = __devexit_p(te12xp_remove_one),
#if LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 12)
.shutdown = te12xp_shutdown,
#endif
.suspend = te12xp_suspend,
.id_table = te12xp_pci_tbl,
};
static int __init te12xp_init(void)
{
int res;
#if LINUX_VERSION_CODE < KERNEL_VERSION(2, 6, 23)
cmd_cache = kmem_cache_create(THIS_MODULE->name, sizeof(struct command), 0,
#if defined(CONFIG_SLUB) && (LINUX_VERSION_CODE == KERNEL_VERSION(2, 6, 22))
SLAB_HWCACHE_ALIGN | SLAB_STORE_USER, NULL, NULL);
#else
SLAB_HWCACHE_ALIGN, NULL, NULL);
#endif
#else
cmd_cache = kmem_cache_create(THIS_MODULE->name, sizeof(struct command), 0,
SLAB_HWCACHE_ALIGN, NULL);
#endif
if (!cmd_cache)
return -ENOMEM;
if (-1 != t1e1override) {
pr_info("'t1e1override' is deprecated. "
"Please use 'default_linemode' instead\n");
} else if (strcasecmp(default_linemode, "auto") &&
strcasecmp(default_linemode, "t1") &&
strcasecmp(default_linemode, "e1")) {
pr_err("'%s' is an unknown span type.", default_linemode);
default_linemode = "auto";
return -EINVAL;
}
res = dahdi_pci_module(&te12xp_driver);
if (res) {
kmem_cache_destroy(cmd_cache);
return -ENODEV;
}
return 0;
}
static void __exit te12xp_cleanup(void)
{
pci_unregister_driver(&te12xp_driver);
kmem_cache_destroy(cmd_cache);
}
module_param(debug, int, S_IRUGO | S_IWUSR);
module_param(t1e1override, int, S_IRUGO | S_IWUSR);
module_param(default_linemode, charp, S_IRUGO);
MODULE_PARM_DESC(default_linemode, "\"auto\"(default), \"e1\", or \"t1\". "
"\"auto\" will use the value from the hardware jumpers.");
module_param(j1mode, int, S_IRUGO | S_IWUSR);
module_param(alarmdebounce, int, S_IRUGO | S_IWUSR);
module_param(losalarmdebounce, int, S_IRUGO | S_IWUSR);
module_param(aisalarmdebounce, int, S_IRUGO | S_IWUSR);
module_param(yelalarmdebounce, int, S_IRUGO | S_IWUSR);
module_param(latency, int, S_IRUGO);
module_param(max_latency, int, S_IRUGO);
#ifdef VPM_SUPPORT
module_param(vpmsupport, int, S_IRUGO);
module_param(vpmtsisupport, int, S_IRUGO);
module_param(vpmnlptype, int, S_IRUGO);
module_param(vpmnlpthresh, int, S_IRUGO);
module_param(vpmnlpmaxsupp, int, S_IRUGO);
#endif
MODULE_DESCRIPTION("Wildcard VoiceBus Digital Card Driver");
MODULE_AUTHOR("Digium Incorporated <support@digium.com>");
MODULE_LICENSE("GPL v2");
module_init(te12xp_init);
module_exit(te12xp_cleanup);