dahdi-linux/drivers/dahdi/xpp/card_fxs.c

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/*
* Written by Oron Peled <oron@actcom.co.il>
* Copyright (C) 2004-2006, Xorcom
*
* All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*
*/
#include <linux/init.h>
#include <linux/module.h>
#include <linux/fs.h>
#include <linux/delay.h>
#include <linux/seq_file.h>
#include "xpd.h"
#include "xproto.h"
#include "xpp_dahdi.h"
#include "card_fxs.h"
#include "dahdi_debug.h"
#include "xbus-core.h"
static const char rcsid[] = "$Id$";
/* must be before dahdi_debug.h */
static DEF_PARM(int, debug, 0, 0644, "Print DBG statements");
static DEF_PARM_BOOL(reversepolarity, 0, 0644, "Reverse Line Polarity");
static DEF_PARM_BOOL(dtmf_detection, 1, 0644, "Do DTMF detection in hardware");
#ifdef POLL_DIGITAL_INPUTS
static DEF_PARM(uint, poll_digital_inputs, 1000, 0644, "Poll Digital Inputs");
#endif
static DEF_PARM(uint, poll_chan_linefeed, 30000, 0644, "Poll Channel Linefeed");
static DEF_PARM_BOOL(vmwi_ioctl, 1, 0644,
"Asterisk support VMWI notification via ioctl");
static DEF_PARM_BOOL(ring_trapez, 0, 0664, "Use trapezoid ring type");
static DEF_PARM_BOOL(lower_ringing_noise, 0, 0664,
"Lower ringing noise (may loose CallerID)");
/* Signaling is opposite (fxo signalling for fxs card) */
#if 1
#define FXS_DEFAULT_SIGCAP \
(DAHDI_SIG_FXOKS | DAHDI_SIG_FXOLS | DAHDI_SIG_FXOGS)
#else
#define FXS_DEFAULT_SIGCAP \
(DAHDI_SIG_SF | DAHDI_SIG_EM)
#endif
#define VMWI_TYPE(priv, pos, type) \
((priv)->vmwisetting[pos].vmwi_type & DAHDI_VMWI_ ## type)
#define VMWI_NEON(priv, pos) VMWI_TYPE(priv, pos, HVAC)
#define LINES_DIGI_OUT 2
#define LINES_DIGI_INP 4
enum fxs_leds {
LED_GREEN,
LED_RED,
OUTPUT_RELAY,
};
#define NUM_LEDS 2
/* Shortcuts */
#define SLIC_WRITE 1
#define SLIC_READ 0
#define SLIC_DIRECT_REQUEST(xbus, xpd, port, writing, reg, dL) \
xpp_register_request((xbus), (xpd), (port), \
(writing), (reg), 0, 0, (dL), 0, 0, 0, 0)
#define SLIC_INDIRECT_REQUEST(xbus, xpd, port, writing, reg, dL, dH) \
xpp_register_request((xbus), (xpd), (port), \
(writing), 0x1E, 1, (reg), (dL), 1, (dH), 0, 0)
#define EXP_REQUEST(xbus, xpd, writing, reg, dL, dH) \
xpp_register_request((xbus), (xpd), 0, \
(writing), (reg), 1, 0, (dL), 1, (dH), 0, 1)
#define RAM_REQUEST(xbus, xpd, port, writing, addr, data) \
xpp_ram_request((xbus), (xpd), (port), \
(writing), (__u8)(addr), (__u8)((addr) >> 8), (__u8)(data), (__u8)((data) >> 8), (__u8)((data) >> 16), (__u8)((data) >> 24), 0)
#define VALID_PORT(port) \
(((port) >= 0 && (port) <= 7) || (port) == PORT_BROADCAST)
#define REG_TYPE1_DIGITAL_IOCTRL 0x06 /* LED and RELAY control */
/* Values of SLIC linefeed control register (0x40) */
enum fxs_state {
FXS_LINE_OPEN = 0x00, /* Open */
FXS_LINE_ACTIVE = 0x01, /* Forward active */
FXS_LINE_OHTRANS = 0x02, /* Forward on-hook transmission */
FXS_LINE_TIPOPEN = 0x03, /* TIP open */
FXS_LINE_RING = 0x04, /* Ringing */
FXS_LINE_REV_ACTIVE = 0x05, /* Reverse active */
FXS_LINE_REV_OHTRANS = 0x06, /* Reverse on-hook transmission */
FXS_LINE_RING_OPEN = 0x07 /* RING open */
};
enum neon_state {
END_NEON = 0,
INIT_NEON = 1,
};
#define FXS_LINE_POL_ACTIVE \
((reversepolarity) ? FXS_LINE_REV_ACTIVE : FXS_LINE_ACTIVE)
#define FXS_LINE_POL_OHTRANS \
((reversepolarity) ? FXS_LINE_REV_OHTRANS : FXS_LINE_OHTRANS)
/* FXS type 1 registers */
#define REG_TYPE1_RINGCON 0x22 /* 34 - Ringing Oscillator Control */
/*
* DTMF detection
*/
#define REG_TYPE1_DTMF_DECODE 0x18 /* 24 - DTMF Decode Status */
#define REG_TYPE1_BATTERY 0x42 /* 66 - Battery Feed Control */
#define REG_TYPE1_BATTERY_BATSL BIT(1) /* Battery Feed Select */
/* 68 - Loop Closure/Ring Trip Detect Status */
#define REG_TYPE1_LOOPCLOSURE 0x44
#define REG_TYPE1_LOOPCLOSURE_ZERO 0xF8 /* Loop Closure zero bits. */
#define REG_TYPE1_LOOPCLOSURE_LCR BIT(0) /* Loop Closure Detect Indicator. */
/* FXS type 6 registers */
#define REG_TYPE6_RINGCON 0x26 /* 38 - Ringing Oscillator Control */
/* 34 - Loop Closure/Ring Trip Detect Status */
#define REG_TYPE6_LCRRTP 0x22
#define REG_TYPE6_LCRRTP_ZERO 0xF0 /* Loop Closure zero bits. */
#define REG_TYPE6_LCRRTP_LCR BIT(1) /* Loop Closure Detect Indicator. */
#define REG_TYPE6_TONEN 0x3E /* 62 - Hardware DTMF detection */
#define REG_TYPE6_TONEN_DTMF_DIS BIT(2) /* DTMF Disable */
#define REG_TYPE6_LINEFEED 0x1E /* 30 - Linefeed */
#define REG_TYPE6_TONDTMF 0x3C /* 60 - DTMF Decode Status */
#define REG_TYPE6_EXP_GPIOA 0x12 /* I/O Expander GPIOA */
#define REG_TYPE6_EXP_GPIOB 0x13 /* I/O Expander GPIOB */
#define REG_TYPE6_ENHANCE 0x2F /* 47 - Enhance */
#define REG_TYPE6_USERSTAT 0x42 /* 66 - Userstat */
#define REG_TYPE6_DIAG1 0x47 /* 71 - Diag1 */
#define RAM_TYPE6_SLOPE_VLIM 634
#define SLOPE_VLIM_DFLT 0x1E655196L
#define SLOPE_VLIM_MWI 0x8000000L
#define RAM_TYPE6_VBATH_EXPECT 767
#define VBATH_EXPECT_DFLT 0x2B10A20L
#define VBATH_EXPECT_MWI 0x6147AB2L
/*---------------- FXS Protocol Commands ----------------------------------*/
static bool fxs_packet_is_valid(xpacket_t *pack);
static void fxs_packet_dump(const char *msg, xpacket_t *pack);
#ifdef CONFIG_PROC_FS
static const struct file_operations proc_fxs_info_ops;
#ifdef WITH_METERING
static const struct file_operations proc_xpd_metering_ops;
#endif
#endif
static void start_stop_vm_led(xbus_t *xbus, xpd_t *xpd, lineno_t pos);
#define PROC_FXS_INFO_FNAME "fxs_info"
#ifdef WITH_METERING
#define PROC_METERING_FNAME "metering_gen"
#endif
struct FXS_priv_data {
#ifdef WITH_METERING
struct proc_dir_entry *meteringfile;
#endif
struct proc_dir_entry *fxs_info;
xpp_line_t ledstate[NUM_LEDS]; /* 0 - OFF, 1 - ON */
xpp_line_t ledcontrol[NUM_LEDS]; /* 0 - OFF, 1 - ON */
xpp_line_t search_fsk_pattern;
xpp_line_t found_fsk_pattern;
xpp_line_t update_offhook_state;
xpp_line_t want_dtmf_events; /* what dahdi want */
xpp_line_t want_dtmf_mute; /* what dahdi want */
xpp_line_t prev_key_down; /* DTMF down sets the bit */
xpp_line_t neon_blinking;
xpp_line_t neonstate;
xpp_line_t vbat_h; /* High voltage */
ktime_t prev_key_time[CHANNELS_PERXPD];
int led_counter[NUM_LEDS][CHANNELS_PERXPD];
int overheat_reset_counter[CHANNELS_PERXPD];
int ohttimer[CHANNELS_PERXPD];
#define OHT_TIMER 6000 /* How long after RING to retain OHT */
/* IDLE changing hook state */
enum fxs_state idletxhookstate[CHANNELS_PERXPD];
enum fxs_state lasttxhook[CHANNELS_PERXPD];
enum fxs_state polledhook[CHANNELS_PERXPD];
struct dahdi_vmwi_info vmwisetting[CHANNELS_PERXPD];
};
/*
* LED counter values:
* n>1 : BLINK every n'th tick
*/
#define LED_COUNTER(priv, pos, color) ((priv)->led_counter[color][pos])
#define IS_BLINKING(priv, pos, color) (LED_COUNTER(priv, pos, color) > 0)
#define MARK_BLINK(priv, pos, color, t) \
((priv)->led_counter[color][pos] = (t))
#define MARK_OFF(priv, pos, color) \
do { \
BIT_CLR((priv)->ledcontrol[color], (pos)); \
MARK_BLINK((priv), (pos), (color), 0); \
} while (0)
#define MARK_ON(priv, pos, color) \
do { \
BIT_SET((priv)->ledcontrol[color], (pos)); \
MARK_BLINK((priv), (pos), (color), 0); \
} while (0)
#define LED_BLINK_RING (1000/8) /* in ticks */
/*---------------- FXS: Static functions ----------------------------------*/
static int set_vm_led_mode(xbus_t *xbus, xpd_t *xpd, int pos,
unsigned int msg_waiting);
static int do_chan_power(xbus_t *xbus, xpd_t *xpd, lineno_t chan, bool on)
{
struct FXS_priv_data *priv;
unsigned long *p;
int was;
BUG_ON(!xbus);
BUG_ON(!xpd);
if (XPD_HW(xpd).type == 6) {
LINE_DBG(SIGNAL, xpd, chan, "is ignored in Si32260\n");
return 0;
}
priv = xpd->priv;
p = (unsigned long *)&priv->vbat_h;
if (on)
was = test_and_set_bit(chan, p) != 0;
else
was = test_and_clear_bit(chan, p) != 0;
if (was == on) {
LINE_DBG(SIGNAL, xpd, chan,
"%s (same, ignored)\n", (on) ? "up" : "down");
return 0;
}
LINE_DBG(SIGNAL, xpd, chan, "%s\n", (on) ? "up" : "down");
return SLIC_DIRECT_REQUEST(xbus, xpd, chan, SLIC_WRITE, REG_TYPE1_BATTERY,
(on) ? (int)REG_TYPE1_BATTERY_BATSL : 0x00);
}
static int linefeed_control(xbus_t *xbus, xpd_t *xpd, lineno_t chan,
enum fxs_state value)
{
struct FXS_priv_data *priv;
bool want_vbat_h;
priv = xpd->priv;
/*
* Should we drop vbat_h only during actuall ring?
* - It would lower the noise caused to other channels by
* group ringing
* - But it may also stop CallerID from passing through the SLIC
*/
want_vbat_h = value == FXS_LINE_RING;
if (lower_ringing_noise || want_vbat_h)
do_chan_power(xbus, xpd, chan, want_vbat_h);
LINE_DBG(SIGNAL, xpd, chan, "value=0x%02X\n", value);
priv->lasttxhook[chan] = value;
if (XPD_HW(xpd).type == 6) {
int ret;
/* Make sure NEON state is off for */
if (value == FXS_LINE_POL_OHTRANS && IS_SET(priv->neon_blinking, chan))
set_vm_led_mode(xpd->xbus, xpd, chan, 0);
ret = SLIC_DIRECT_REQUEST(xbus, xpd, chan, SLIC_WRITE, REG_TYPE6_LINEFEED, value);
if (value == FXS_LINE_POL_ACTIVE && PHONEDEV(xpd).msg_waiting[chan])
set_vm_led_mode(xpd->xbus, xpd, chan, PHONEDEV(xpd).msg_waiting[chan]);
return ret;
} else {
return SLIC_DIRECT_REQUEST(xbus, xpd, chan, SLIC_WRITE, 0x40, value);
}
return 0;
}
static void vmwi_search(xpd_t *xpd, lineno_t pos, bool on)
{
struct FXS_priv_data *priv;
priv = xpd->priv;
BUG_ON(!xpd);
if (VMWI_NEON(priv, pos) && on) {
LINE_DBG(SIGNAL, xpd, pos, "START\n");
BIT_SET(priv->search_fsk_pattern, pos);
} else {
LINE_DBG(SIGNAL, xpd, pos, "STOP\n");
BIT_CLR(priv->search_fsk_pattern, pos);
}
}
/*
* LED and RELAY control is done via SLIC register 0x06:
* 7 6 5 4 3 2 1 0
* +-----+-----+-----+-----+-----+-----+-----+-----+
* | M2 | M1 | M3 | C2 | O1 | O3 | C1 | C3 |
* +-----+-----+-----+-----+-----+-----+-----+-----+
*
* Cn - Control bit (control one digital line)
* On - Output bit (program a digital line for output)
* Mn - Mask bit (only the matching output control bit is affected)
*
* C3 - OUTPUT RELAY (0 - OFF, 1 - ON)
* C1 - GREEN LED (0 - OFF, 1 - ON)
* O3 - Output RELAY (this line is output)
* O1 - Output GREEN (this line is output)
* C2 - RED LED (0 - OFF, 1 - ON)
* M3 - Mask RELAY. (1 - C3 effect the OUTPUT RELAY)
* M2 - Mask RED. (1 - C2 effect the RED LED)
* M1 - Mask GREEN. (1 - C1 effect the GREEN LED)
*
* The OUTPUT RELAY (actually a relay out) is connected to line 0 and 4 only.
*/
// GREEN RED OUTPUT RELAY
static const int led_register_mask[] = { BIT(7), BIT(6), BIT(5) };
static const int led_register_vals[] = { BIT(4), BIT(1), BIT(0) };
/*
* pos can be:
* - A line number
* - ALL_LINES. This is not valid anymore since 8-Jan-2007.
*/
static int do_led(xpd_t *xpd, lineno_t chan, __u8 which, bool on)
{
int ret = 0;
struct FXS_priv_data *priv;
int value;
xbus_t *xbus;
BUG_ON(!xpd);
BUG_ON(chan == ALL_LINES);
xbus = xpd->xbus;
priv = xpd->priv;
which = which % NUM_LEDS;
if (IS_SET(PHONEDEV(xpd).digital_outputs, chan)
|| IS_SET(PHONEDEV(xpd).digital_inputs, chan))
goto out;
if (chan == PORT_BROADCAST) {
priv->ledstate[which] = (on) ? ~0 : 0;
} else {
if (on)
BIT_SET(priv->ledstate[which], chan);
else
BIT_CLR(priv->ledstate[which], chan);
}
LINE_DBG(LEDS, xpd, chan, "LED: (type=%d) which=%d -- %s\n", XPD_HW(xpd).type, which,
(on) ? "on" : "off");
if (XPD_HW(xpd).type == 6) {
int mask = 1 << chan;
value = (on) << chan;
XPD_DBG(LEDS, xpd, "LED(%d): 0x%0X (mask: 0x%0X)\n", chan,
value, mask);
if (which == LED_GREEN) { /* other leds ignored */
ret = EXP_REQUEST(xbus, xpd, SLIC_WRITE,
REG_TYPE6_EXP_GPIOA, value, mask);
}
} else {
value = BIT(2) | BIT(3);
value |= ((BIT(5) | BIT(6) | BIT(7)) & ~led_register_mask[which]);
if (on)
value |= led_register_vals[which];
ret = SLIC_DIRECT_REQUEST(xbus, xpd, chan, SLIC_WRITE,
REG_TYPE1_DIGITAL_IOCTRL, value);
}
return 0;
out:
return ret;
}
static inline void set_mwi_led(xpd_t *xpd, int pos, int on)
{
struct FXS_priv_data *priv;
BUG_ON(!xpd);
priv = xpd->priv;
if (XPD_HW(xpd).type != 6)
return;
if (on) {
if (! IS_SET(priv->neonstate, pos)) {
SLIC_DIRECT_REQUEST(xpd->xbus, xpd, pos, SLIC_WRITE, REG_TYPE6_ENHANCE, 0x00);
SLIC_DIRECT_REQUEST(xpd->xbus, xpd, pos, SLIC_WRITE, REG_TYPE6_USERSTAT, 0x04);
SLIC_DIRECT_REQUEST(xpd->xbus, xpd, pos, SLIC_WRITE, REG_TYPE6_DIAG1, 0x0F);
BIT_SET(priv->neonstate, pos);
}
} else {
if (IS_SET(priv->neonstate, pos)) {
SLIC_DIRECT_REQUEST(xpd->xbus, xpd, pos, SLIC_WRITE, REG_TYPE6_DIAG1, 0x00);
BIT_CLR(priv->neonstate, pos);
}
}
}
static void blink_mwi(xpd_t *xpd)
{
struct FXS_priv_data *priv;
unsigned int timer_count;
int i;
BUG_ON(!xpd);
priv = xpd->priv;
timer_count = xpd->timer_count;
for_each_line(xpd, i) {
unsigned int msgs = PHONEDEV(xpd).msg_waiting[i];
/* LED duty cycle: 300ms on, 700ms off */
unsigned int in_range = (timer_count % 1000) >= 0 && (timer_count % 1000) <= 300;
if (!IS_OFFHOOK(xpd, i) && msgs && in_range &&
IS_SET(priv->neon_blinking,i) && priv->ohttimer[i] == 0)
set_mwi_led(xpd, i, 1);
else
set_mwi_led(xpd, i, 0);
}
}
static void handle_fxs_leds(xpd_t *xpd)
{
int i;
const enum fxs_leds colors[] = { LED_GREEN, LED_RED };
enum fxs_leds color;
unsigned int timer_count;
struct FXS_priv_data *priv;
BUG_ON(!xpd);
priv = xpd->priv;
timer_count = xpd->timer_count;
for (color = 0; color < ARRAY_SIZE(colors); color++) {
for_each_line(xpd, i) {
if (IS_SET
(PHONEDEV(xpd).digital_outputs | PHONEDEV(xpd).
digital_inputs, i))
continue;
/* Blinking? */
if ((xpd->blink_mode & BIT(i)) || IS_BLINKING(priv, i, color)) {
int mod_value = LED_COUNTER(priv, i, color);
if (!mod_value)
/* safety value */
mod_value = DEFAULT_LED_PERIOD;
/* led state is toggled */
if ((timer_count % mod_value) == 0) {
LINE_DBG(LEDS, xpd, i, "ledstate=%s\n",
(IS_SET
(priv->ledstate[color],
i)) ? "ON" : "OFF");
if (!IS_SET(priv->ledstate[color], i))
do_led(xpd, i, color, 1);
else
do_led(xpd, i, color, 0);
}
} else
if (IS_SET
(priv->ledcontrol[color] & ~priv->
ledstate[color], i)) {
do_led(xpd, i, color, 1);
} else
if (IS_SET
(~priv->ledcontrol[color] & priv->
ledstate[color], i)) {
do_led(xpd, i, color, 0);
}
}
}
}
static void restore_leds(xpd_t *xpd)
{
struct FXS_priv_data *priv;
int i;
priv = xpd->priv;
for_each_line(xpd, i) {
if (IS_OFFHOOK(xpd, i))
MARK_ON(priv, i, LED_GREEN);
else
MARK_OFF(priv, i, LED_GREEN);
}
}
#ifdef WITH_METERING
static int metering_gen(xpd_t *xpd, lineno_t chan, bool on)
{
__u8 value = (on) ? 0x94 : 0x00;
if (XPD_HW(xpd).type == 6) {
XBUS_NOTICE("Metering not supported with FXS type 6");
return 0;
}
LINE_DBG(SIGNAL, xpd, chan, "METERING Generate: %s\n",
(on) ? "ON" : "OFF");
return SLIC_DIRECT_REQUEST(xpd->xbus, xpd, chan, SLIC_WRITE, 0x23,
value);
}
#endif
/*---------------- FXS: Methods -------------------------------------------*/
static void fxs_proc_remove(xbus_t *xbus, xpd_t *xpd)
{
struct FXS_priv_data *priv;
BUG_ON(!xpd);
priv = xpd->priv;
#ifdef CONFIG_PROC_FS
#ifdef WITH_METERING
if (priv->meteringfile) {
XPD_DBG(PROC, xpd, "Removing xpd metering tone file\n");
remove_proc_entry(PROC_METERING_FNAME, xpd->proc_xpd_dir);
priv->meteringfile = NULL;
}
#endif
if (priv->fxs_info) {
XPD_DBG(PROC, xpd, "Removing xpd FXS_INFO file\n");
remove_proc_entry(PROC_FXS_INFO_FNAME, xpd->proc_xpd_dir);
priv->fxs_info = NULL;
}
#endif
}
static int fxs_proc_create(xbus_t *xbus, xpd_t *xpd)
{
struct FXS_priv_data *priv;
BUG_ON(!xpd);
priv = xpd->priv;
#ifdef CONFIG_PROC_FS
XPD_DBG(PROC, xpd, "Creating FXS_INFO file\n");
priv->fxs_info = proc_create_data(PROC_FXS_INFO_FNAME, 0444,
xpd->proc_xpd_dir,
&proc_fxs_info_ops, xpd);
if (!priv->fxs_info) {
XPD_ERR(xpd, "Failed to create proc file '%s'\n",
PROC_FXS_INFO_FNAME);
fxs_proc_remove(xbus, xpd);
return -EINVAL;
}
SET_PROC_DIRENTRY_OWNER(priv->fxs_info);
#ifdef WITH_METERING
XPD_DBG(PROC, xpd, "Creating Metering tone file\n");
priv->meteringfile = proc_create_data(PROC_METERING_FNAME, 0200,
xpd->proc_xpd_dir,
&proc_xpd_metering_ops, xpd);
if (!priv->meteringfile) {
XPD_ERR(xpd, "Failed to create proc file '%s'\n",
PROC_METERING_FNAME);
fxs_proc_remove(xbus, xpd);
return -EINVAL;
}
#endif
#endif
return 0;
}
static xpd_t *FXS_card_new(xbus_t *xbus, int unit, int subunit,
const xproto_table_t *proto_table,
const struct unit_descriptor *unit_descriptor,
bool to_phone)
{
xpd_t *xpd = NULL;
int channels;
int subunit_ports;
int regular_channels;
struct FXS_priv_data *priv;
int i;
int d_inputs = 0;
int d_outputs = 0;
if (!to_phone) {
XBUS_NOTICE(xbus,
"XPD=%d%d: try to instanciate FXS with reverse direction\n",
unit, subunit);
return NULL;
}
subunit_ports = unit_descriptor->numchips * unit_descriptor->ports_per_chip;
if (unit_descriptor->subtype == 2)
regular_channels = min(6, subunit_ports);
else
regular_channels = min(8, subunit_ports);
channels = regular_channels;
/* Calculate digital inputs/outputs */
if (unit == 0 && unit_descriptor->subtype != 4 && unit_descriptor->numchips != 4) {
channels += 6; /* 2 DIGITAL OUTPUTS, 4 DIGITAL INPUTS */
d_inputs = LINES_DIGI_INP;
d_outputs = LINES_DIGI_OUT;
}
xpd =
xpd_alloc(xbus, unit, subunit,
sizeof(struct FXS_priv_data), proto_table, unit_descriptor, channels);
if (!xpd)
return NULL;
/* Initialize digital inputs/outputs */
if (d_inputs) {
XBUS_DBG(GENERAL, xbus, "Initialize %d digital inputs\n",
d_inputs);
PHONEDEV(xpd).digital_inputs =
BITMASK(d_inputs) << (regular_channels + d_outputs);
} else
XBUS_DBG(GENERAL, xbus, "No digital inputs\n");
if (d_outputs) {
XBUS_DBG(GENERAL, xbus, "Initialize %d digital outputs\n",
d_outputs);
PHONEDEV(xpd).digital_outputs =
BITMASK(d_outputs) << regular_channels;
} else
XBUS_DBG(GENERAL, xbus, "No digital outputs\n");
PHONEDEV(xpd).direction = TO_PHONE;
xpd->type_name = "FXS";
if (fxs_proc_create(xbus, xpd) < 0)
goto err;
priv = xpd->priv;
for_each_line(xpd, i) {
priv->idletxhookstate[i] = FXS_LINE_POL_ACTIVE;
}
return xpd;
err:
xpd_free(xpd);
return NULL;
}
static int FXS_card_init(xbus_t *xbus, xpd_t *xpd)
{
struct FXS_priv_data *priv;
int ret = 0;
int i;
BUG_ON(!xpd);
priv = xpd->priv;
/*
* Setup ring timers
*/
/* Software controled ringing (for CID) */
/* Ringing Oscilator Control */
if (XPD_HW(xpd).type == 6) {
ret = SLIC_DIRECT_REQUEST(xbus, xpd, PORT_BROADCAST, SLIC_WRITE,
REG_TYPE6_RINGCON, 0x00);
} else {
ret = SLIC_DIRECT_REQUEST(xbus, xpd, PORT_BROADCAST, SLIC_WRITE,
REG_TYPE1_RINGCON, 0x00);
}
if (ret < 0)
goto err;
for_each_line(xpd, i) {
if (XPD_HW(xpd).type == 6)
/* An arbitrary value that is not FXS_LINE_OPEN */
priv->polledhook[i] = FXS_LINE_ACTIVE;
linefeed_control(xbus, xpd, i, FXS_LINE_POL_ACTIVE);
}
XPD_DBG(GENERAL, xpd, "done\n");
for_each_line(xpd, i) {
do_led(xpd, i, LED_GREEN, 0);
do_led(xpd, i, LED_RED, 0);
}
for_each_line(xpd, i) {
do_led(xpd, i, LED_GREEN, 1);
msleep(50);
}
for_each_line(xpd, i) {
do_led(xpd, i, LED_GREEN, 0);
msleep(50);
}
restore_leds(xpd);
CALL_PHONE_METHOD(card_pcm_recompute, xpd, 0);
/*
* We should query our offhook state long enough time after we
* set the linefeed_control()
* So we do this after the LEDs
*/
for_each_line(xpd, i) {
if (IS_SET
(PHONEDEV(xpd).digital_outputs | PHONEDEV(xpd).
digital_inputs, i))
continue;
if (XPD_HW(xpd).type == 6) {
SLIC_DIRECT_REQUEST(xbus, xpd, i, SLIC_READ, REG_TYPE6_LCRRTP,
0);
} else {
SLIC_DIRECT_REQUEST(xbus, xpd, i, SLIC_READ, REG_TYPE1_LOOPCLOSURE,
0);
}
}
return 0;
err:
fxs_proc_remove(xbus, xpd);
XPD_ERR(xpd, "Failed initializing registers (%d)\n", ret);
return ret;
}
static int FXS_card_remove(xbus_t *xbus, xpd_t *xpd)
{
BUG_ON(!xpd);
XPD_DBG(GENERAL, xpd, "\n");
fxs_proc_remove(xbus, xpd);
return 0;
}
static int FXS_card_dahdi_preregistration(xpd_t *xpd, bool on)
{
xbus_t *xbus;
struct FXS_priv_data *priv;
int i;
BUG_ON(!xpd);
xbus = xpd->xbus;
BUG_ON(!xbus);
priv = xpd->priv;
BUG_ON(!priv);
XPD_DBG(GENERAL, xpd, "%s\n", (on) ? "on" : "off");
PHONEDEV(xpd).span.spantype = SPANTYPE_ANALOG_FXS;
for_each_line(xpd, i) {
struct dahdi_chan *cur_chan = XPD_CHAN(xpd, i);
XPD_DBG(GENERAL, xpd, "setting FXS channel %d\n", i);
if (IS_SET(PHONEDEV(xpd).digital_outputs, i)) {
snprintf(cur_chan->name, MAX_CHANNAME,
"XPP_OUT/%02d/%1d%1d/%d", xbus->num,
xpd->addr.unit, xpd->addr.subunit, i);
} else if (IS_SET(PHONEDEV(xpd).digital_inputs, i)) {
snprintf(cur_chan->name, MAX_CHANNAME,
"XPP_IN/%02d/%1d%1d/%d", xbus->num,
xpd->addr.unit, xpd->addr.subunit, i);
} else {
snprintf(cur_chan->name, MAX_CHANNAME,
"XPP_FXS/%02d/%1d%1d/%d", xbus->num,
xpd->addr.unit, xpd->addr.subunit, i);
}
cur_chan->chanpos = i + 1;
cur_chan->pvt = xpd;
cur_chan->sigcap = FXS_DEFAULT_SIGCAP;
if (!vmwi_ioctl) {
/* Old asterisk, assume default VMWI type */
priv->vmwisetting[i].vmwi_type = DAHDI_VMWI_HVAC;
}
}
for_each_line(xpd, i) {
MARK_ON(priv, i, LED_GREEN);
msleep(4);
MARK_ON(priv, i, LED_RED);
}
return 0;
}
static int FXS_card_dahdi_postregistration(xpd_t *xpd, bool on)
{
xbus_t *xbus;
struct FXS_priv_data *priv;
int i;
BUG_ON(!xpd);
xbus = xpd->xbus;
BUG_ON(!xbus);
priv = xpd->priv;
BUG_ON(!priv);
XPD_DBG(GENERAL, xpd, "%s\n", (on) ? "on" : "off");
for_each_line(xpd, i) {
MARK_OFF(priv, i, LED_GREEN);
msleep(2);
MARK_OFF(priv, i, LED_RED);
msleep(2);
}
restore_leds(xpd);
return 0;
}
/*
* Called with XPD spinlocked
*/
static void __do_mute_dtmf(xpd_t *xpd, int pos, bool muteit)
{
struct FXS_priv_data *priv;
priv = xpd->priv;
LINE_DBG(SIGNAL, xpd, pos, "%s\n", (muteit) ? "MUTE" : "UNMUTE");
if (muteit)
BIT_SET(PHONEDEV(xpd).mute_dtmf, pos);
else
BIT_CLR(PHONEDEV(xpd).mute_dtmf, pos);
/* already spinlocked */
CALL_PHONE_METHOD(card_pcm_recompute, xpd, priv->search_fsk_pattern);
}
struct ring_reg_param {
int is_indirect;
int regno;
uint8_t h_val;
uint8_t l_val;
};
enum ring_types {
RING_TYPE_NEON = 0,
RING_TYPE_TRAPEZ,
RING_TYPE_NORMAL,
};
struct byte_pair {
uint8_t h_val;
uint8_t l_val;
};
struct ring_reg_params {
const int is_indirect;
const int regno;
struct byte_pair values[1 + RING_TYPE_NORMAL - RING_TYPE_NEON];
};
#define REG_ENTRY(di, reg, vh1, vl1, vh2, vl2, vh3, vl3) \
{ (di), (reg), .values = { \
[RING_TYPE_NEON] = { .h_val = (vh1), .l_val = (vl1) }, \
[RING_TYPE_TRAPEZ] = { .h_val = (vh2), .l_val = (vl2) }, \
[RING_TYPE_NORMAL] = { .h_val = (vh3), .l_val = (vl3) }, \
}, \
}
static struct ring_reg_params ring_parameters[] = {
/* INDIR REG NEON TRAPEZ NORMAL */
REG_ENTRY(1, 0x16, 0xE8, 0x03, 0xC8, 0x00, 0x00, 0x00),
REG_ENTRY(1, 0x15, 0xEF, 0x7B, 0xAB, 0x5E, 0x77, 0x01),
REG_ENTRY(1, 0x14, 0x9F, 0x00, 0x8C, 0x01, 0xFD, 0x7E),
REG_ENTRY(0, 0x22, 0x00, 0x19, 0x00, 0x01, 0x00, 0x00),
REG_ENTRY(0, 0x30, 0x00, 0xE0, 0x00, 0x00, 0x00, 0x00),
REG_ENTRY(0, 0x31, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00),
REG_ENTRY(0, 0x32, 0x00, 0xF0, 0x00, 0x00, 0x00, 0x00),
REG_ENTRY(0, 0x33, 0x00, 0x05, 0x00, 0x00, 0x00, 0x00),
REG_ENTRY(1, 0x1D, 0x00, 0x46, 0x00, 0x36, 0x00, 0x36),
};
static void set_neon_state(xbus_t *xbus, xpd_t *xpd, int pos,
enum neon_state ns)
{
struct FXS_priv_data *priv;
LINE_DBG(SIGNAL, xpd, pos, "set NEON -> %d\n", ns);
priv = xpd->priv;
if (ns == INIT_NEON)
BIT_SET(priv->neon_blinking, pos);
else
BIT_CLR(priv->neon_blinking, pos);
if (XPD_HW(xpd).type == 6) {
switch (ns) {
case INIT_NEON:
RAM_REQUEST(xbus, xpd, pos, SLIC_WRITE, RAM_TYPE6_VBATH_EXPECT, VBATH_EXPECT_MWI << 3);
//RAM_REQUEST(xbus, xpd, pos, SLIC_WRITE, RAM_TYPE6_SLOPE_VLIM, SLOPE_VLIM_MWI << 3);
break;
default:
LINE_DBG(REGS, xpd, pos, "0x%04X: R 0x\n", RAM_TYPE6_SLOPE_VLIM);
set_mwi_led(xpd, pos, 0); /* Cannot have NEON LED during OHT (type == 6) */
SLIC_DIRECT_REQUEST(xbus, xpd, pos, SLIC_WRITE, REG_TYPE6_USERSTAT, 0x00);
SLIC_DIRECT_REQUEST(xbus, xpd, pos, SLIC_WRITE, REG_TYPE6_ENHANCE, 0x10);
RAM_REQUEST(xbus, xpd, pos, SLIC_WRITE, RAM_TYPE6_VBATH_EXPECT, VBATH_EXPECT_DFLT << 3);
RAM_REQUEST(xbus, xpd, pos, SLIC_WRITE, RAM_TYPE6_SLOPE_VLIM, SLOPE_VLIM_DFLT << 3);
break;
}
}
}
static int send_ring_parameters(xbus_t *xbus, xpd_t *xpd, int pos,
enum ring_types rtype)
{
const struct ring_reg_params *p;
const struct byte_pair *v;
int ret = 0;
int i;
if (XPD_HW(xpd).type == 6)
return 0;
if (rtype < RING_TYPE_NEON || rtype > RING_TYPE_NORMAL)
return -EINVAL;
for (i = 0; i < ARRAY_SIZE(ring_parameters); i++) {
p = &ring_parameters[i];
v = &(p->values[rtype]);
if (p->is_indirect) {
LINE_DBG(REGS, xpd, pos,
"[%d] 0x%02X: I 0x%02X 0x%02X\n",
i, p->regno, v->h_val, v->l_val);
ret = SLIC_INDIRECT_REQUEST(xbus, xpd, pos, SLIC_WRITE,
p->regno, v->h_val, v->l_val);
if (ret < 0) {
LINE_ERR(xpd, pos,
"Failed: 0x%02X: I 0x%02X, 0x%02X\n",
p->regno, v->h_val, v->l_val);
break;
}
} else {
LINE_DBG(REGS, xpd, pos, "[%d] 0x%02X: D 0x%02X\n",
i, p->regno, v->l_val);
ret = SLIC_DIRECT_REQUEST(xbus, xpd, pos, SLIC_WRITE,
p->regno, v->l_val);
if (ret < 0) {
LINE_ERR(xpd, pos,
"Failed: 0x%02X: D 0x%02X\n",
p->regno, v->l_val);
break;
}
}
}
return ret;
}
static int set_vm_led_mode(xbus_t *xbus, xpd_t *xpd, int pos,
unsigned int msg_waiting)
{
int ret = 0;
struct FXS_priv_data *priv;
BUG_ON(!xbus);
BUG_ON(!xpd);
priv = xpd->priv;
if (VMWI_NEON(priv, pos) && msg_waiting) {
/* A write to register 0x40 will now turn on/off the VM led */
LINE_DBG(SIGNAL, xpd, pos, "NEON\n");
set_neon_state(xbus, xpd, pos, INIT_NEON);
ret = send_ring_parameters(xbus, xpd, pos, RING_TYPE_NEON);
} else if (ring_trapez) {
LINE_DBG(SIGNAL, xpd, pos, "RINGER: Trapez ring\n");
set_neon_state(xbus, xpd, pos, END_NEON);
ret = send_ring_parameters(xbus, xpd, pos, RING_TYPE_TRAPEZ);
} else {
/* A write to register 0x40 will now turn on/off the ringer */
LINE_DBG(SIGNAL, xpd, pos, "RINGER\n");
set_neon_state(xbus, xpd, pos, END_NEON);
ret = send_ring_parameters(xbus, xpd, pos, RING_TYPE_NORMAL);
}
return (ret ? -EPROTO : 0);
}
static void start_stop_vm_led(xbus_t *xbus, xpd_t *xpd, lineno_t pos)
{
struct FXS_priv_data *priv;
unsigned int msgs;
BUG_ON(!xpd);
if (IS_SET
(PHONEDEV(xpd).digital_outputs | PHONEDEV(xpd).digital_inputs, pos))
return;
priv = xpd->priv;
msgs = PHONEDEV(xpd).msg_waiting[pos];
LINE_DBG(SIGNAL, xpd, pos, "%s\n", (msgs) ? "ON" : "OFF");
set_vm_led_mode(xbus, xpd, pos, msgs);
if (XPD_HW(xpd).type == 1) {
do_chan_power(xbus, xpd, pos, msgs > 0);
linefeed_control(xbus, xpd, pos,
(msgs > 0) ? FXS_LINE_RING : priv->idletxhookstate[pos]);
}
}
static int relay_out(xpd_t *xpd, int pos, bool on)
{
int ret = 0;
int value = 0;
int which = pos;
BUG_ON(!xpd);
/* map logical position to output port number (0/1) */
which -= (XPD_HW(xpd).subtype == 2) ? 6 : 8;
LINE_DBG(SIGNAL, xpd, pos, "which=%d -- %s\n", which,
(on) ? "on" : "off");
if (XPD_HW(xpd).type == 6) {
int relay_values_type6[] = { 0x01, 0x40 };
which = which % ARRAY_SIZE(relay_values_type6);
if (on)
value |= relay_values_type6[which];
ret = EXP_REQUEST(xpd->xbus, xpd, SLIC_WRITE,
REG_TYPE6_EXP_GPIOB, value, relay_values_type6[which]);
} else {
int relay_channels_type1[] = { 0, 4 };
which = which % ARRAY_SIZE(relay_channels_type1);
value = BIT(2) | BIT(3);
value |=
((BIT(5) | BIT(6) | BIT(7)) & ~led_register_mask[OUTPUT_RELAY]);
if (on)
value |= led_register_vals[OUTPUT_RELAY];
ret = SLIC_DIRECT_REQUEST(xpd->xbus, xpd, relay_channels_type1[which],
SLIC_WRITE, REG_TYPE1_DIGITAL_IOCTRL, value);
}
return ret;
}
static int send_ring(xpd_t *xpd, lineno_t chan, bool on)
{
int ret = 0;
xbus_t *xbus;
struct FXS_priv_data *priv;
enum fxs_state value = (on) ? FXS_LINE_RING : FXS_LINE_POL_ACTIVE;
BUG_ON(!xpd);
xbus = xpd->xbus;
BUG_ON(!xbus);
LINE_DBG(SIGNAL, xpd, chan, "%s\n", (on) ? "on" : "off");
priv = xpd->priv;
set_vm_led_mode(xbus, xpd, chan, 0);
do_chan_power(xbus, xpd, chan, on); /* Power up (for ring) */
ret = linefeed_control(xbus, xpd, chan, value);
if (on) {
MARK_BLINK(priv, chan, LED_GREEN, LED_BLINK_RING);
} else {
if (IS_BLINKING(priv, chan, LED_GREEN))
MARK_BLINK(priv, chan, LED_GREEN, 0);
}
return ret;
}
static int FXS_card_hooksig(xpd_t *xpd, int pos, enum dahdi_txsig txsig)
{
struct FXS_priv_data *priv;
int ret = 0;
struct dahdi_chan *chan = NULL;
enum fxs_state txhook;
unsigned long flags;
LINE_DBG(SIGNAL, xpd, pos, "%s\n", txsig2str(txsig));
priv = xpd->priv;
BUG_ON(PHONEDEV(xpd).direction != TO_PHONE);
if (IS_SET(PHONEDEV(xpd).digital_inputs, pos)) {
LINE_DBG(SIGNAL, xpd, pos,
"Ignoring signal sent to digital input line\n");
return 0;
}
if (SPAN_REGISTERED(xpd))
chan = XPD_CHAN(xpd, pos);
switch (txsig) {
case DAHDI_TXSIG_ONHOOK:
spin_lock_irqsave(&xpd->lock, flags);
PHONEDEV(xpd).ringing[pos] = 0;
oht_pcm(xpd, pos, 0);
vmwi_search(xpd, pos, 0);
BIT_CLR(priv->want_dtmf_events, pos);
BIT_CLR(priv->want_dtmf_mute, pos);
__do_mute_dtmf(xpd, pos, 0);
spin_unlock_irqrestore(&xpd->lock, flags);
if (IS_SET(PHONEDEV(xpd).digital_outputs, pos)) {
LINE_DBG(SIGNAL, xpd, pos, "%s -> digital output OFF\n",
txsig2str(txsig));
ret = relay_out(xpd, pos, 0);
return ret;
}
if (priv->lasttxhook[pos] == FXS_LINE_OPEN) {
/*
* Restore state after KEWL hangup.
*/
LINE_DBG(SIGNAL, xpd, pos, "KEWL STOP\n");
linefeed_control(xpd->xbus, xpd, pos,
FXS_LINE_POL_ACTIVE);
if (IS_OFFHOOK(xpd, pos))
MARK_ON(priv, pos, LED_GREEN);
}
ret = send_ring(xpd, pos, 0); // RING off
if (!IS_OFFHOOK(xpd, pos))
start_stop_vm_led(xpd->xbus, xpd, pos);
txhook = priv->lasttxhook[pos];
if (chan) {
switch (chan->sig) {
case DAHDI_SIG_EM:
case DAHDI_SIG_FXOKS:
case DAHDI_SIG_FXOLS:
txhook = priv->idletxhookstate[pos];
break;
case DAHDI_SIG_FXOGS:
txhook = FXS_LINE_TIPOPEN;
break;
}
}
ret = linefeed_control(xpd->xbus, xpd, pos, txhook);
break;
case DAHDI_TXSIG_OFFHOOK:
if (IS_SET(PHONEDEV(xpd).digital_outputs, pos)) {
LINE_NOTICE(xpd, pos,
"%s -> Is digital output. Ignored\n",
txsig2str(txsig));
return -EINVAL;
}
txhook = priv->lasttxhook[pos];
if (PHONEDEV(xpd).ringing[pos]) {
oht_pcm(xpd, pos, 1);
txhook = FXS_LINE_OHTRANS;
}
PHONEDEV(xpd).ringing[pos] = 0;
if (chan) {
switch (chan->sig) {
case DAHDI_SIG_EM:
txhook = FXS_LINE_POL_ACTIVE;
break;
default:
txhook = priv->idletxhookstate[pos];
break;
}
}
ret = linefeed_control(xpd->xbus, xpd, pos, txhook);
break;
case DAHDI_TXSIG_START:
PHONEDEV(xpd).ringing[pos] = 1;
oht_pcm(xpd, pos, 0);
vmwi_search(xpd, pos, 0);
if (IS_SET(PHONEDEV(xpd).digital_outputs, pos)) {
LINE_DBG(SIGNAL, xpd, pos, "%s -> digital output ON\n",
txsig2str(txsig));
ret = relay_out(xpd, pos, 1);
return ret;
}
ret = send_ring(xpd, pos, 1); // RING on
break;
case DAHDI_TXSIG_KEWL:
if (IS_SET(PHONEDEV(xpd).digital_outputs, pos)) {
LINE_DBG(SIGNAL, xpd, pos,
"%s -> Is digital output. Ignored\n",
txsig2str(txsig));
return -EINVAL;
}
linefeed_control(xpd->xbus, xpd, pos, FXS_LINE_OPEN);
MARK_OFF(priv, pos, LED_GREEN);
break;
default:
XPD_NOTICE(xpd, "%s: Can't set tx state to %s (%d)\n", __func__,
txsig2str(txsig), txsig);
ret = -EINVAL;
}
return ret;
}
static int set_vmwi(xpd_t *xpd, int pos, unsigned long arg)
{
struct FXS_priv_data *priv;
struct dahdi_vmwi_info vmwisetting;
const int vmwi_flags =
DAHDI_VMWI_LREV | DAHDI_VMWI_HVDC | DAHDI_VMWI_HVAC;
priv = xpd->priv;
BUG_ON(!priv);
if (copy_from_user
(&vmwisetting, (__user void *)arg, sizeof(vmwisetting)))
return -EFAULT;
if ((vmwisetting.vmwi_type & ~vmwi_flags) != 0) {
LINE_NOTICE(xpd, pos, "Bad DAHDI_VMWI_CONFIG: 0x%X\n",
vmwisetting.vmwi_type);
return -EINVAL;
}
LINE_DBG(SIGNAL, xpd, pos, "DAHDI_VMWI_CONFIG: 0x%X\n",
vmwisetting.vmwi_type);
if (VMWI_TYPE(priv, pos, LREV)) {
LINE_NOTICE(xpd, pos,
"%s: VMWI(lrev) is not implemented yet. Ignored.\n",
__func__);
}
if (VMWI_TYPE(priv, pos, HVDC)) {
LINE_NOTICE(xpd, pos,
"%s: VMWI(hvdc) is not implemented yet. Ignored.\n",
__func__);
}
if (VMWI_TYPE(priv, pos, HVAC))
; /* VMWI_NEON */
if (priv->vmwisetting[pos].vmwi_type == 0)
; /* Disable VMWI */
priv->vmwisetting[pos] = vmwisetting;
set_vm_led_mode(xpd->xbus, xpd, pos, PHONEDEV(xpd).msg_waiting[pos]);
return 0;
}
static int hardware_dtmf_control(xpd_t *xpd, int pos, bool on)
{
int ret = 0;
LINE_DBG(SIGNAL, xpd, pos, "%s: %s\n", __func__, (on) ? "on" : "off");
if (XPD_HW(xpd).type == 6) {
int value = (on) ? 0xE0 : REG_TYPE6_TONEN_DTMF_DIS;
ret = SLIC_DIRECT_REQUEST(xpd->xbus, xpd, pos, SLIC_WRITE,
REG_TYPE6_TONEN, value);
} else {
ret = SLIC_DIRECT_REQUEST(xpd->xbus, xpd, pos, SLIC_WRITE, 0x17, on);
}
return ret;
}
/*
* Private ioctl()
* We don't need it now, since we detect vmwi via FSK patterns
*/
static int FXS_card_ioctl(xpd_t *xpd, int pos, unsigned int cmd,
unsigned long arg)
{
struct FXS_priv_data *priv;
xbus_t *xbus;
int val;
unsigned long flags;
BUG_ON(!xpd);
priv = xpd->priv;
BUG_ON(!priv);
xbus = xpd->xbus;
BUG_ON(!xbus);
if (!XBUS_IS(xbus, READY))
return -ENODEV;
if (pos < 0 || pos >= PHONEDEV(xpd).channels) {
XPD_NOTICE(xpd, "Bad channel number %d in %s(), cmd=%u\n", pos,
__func__, cmd);
return -EINVAL;
}
switch (cmd) {
case DAHDI_ONHOOKTRANSFER:
if (get_user(val, (int __user *)arg))
return -EFAULT;
LINE_DBG(SIGNAL, xpd, pos, "DAHDI_ONHOOKTRANSFER (%d millis)\n",
val);
if (IS_SET
(PHONEDEV(xpd).digital_inputs | PHONEDEV(xpd).
digital_outputs, pos))
return 0; /* Nothing to do */
oht_pcm(xpd, pos, 1); /* Get ready of VMWI FSK tones */
if (priv->lasttxhook[pos] == FXS_LINE_POL_ACTIVE
|| IS_SET(priv->neon_blinking, pos)) {
priv->ohttimer[pos] = val;
priv->idletxhookstate[pos] = FXS_LINE_POL_OHTRANS;
vmwi_search(xpd, pos, 1);
CALL_PHONE_METHOD(card_pcm_recompute, xpd,
priv->search_fsk_pattern);
LINE_DBG(SIGNAL, xpd, pos,
"Start OHT_TIMER. wanted_pcm_mask=0x%X\n",
PHONEDEV(xpd).wanted_pcm_mask);
}
if (VMWI_NEON(priv, pos) && !IS_OFFHOOK(xpd, pos))
start_stop_vm_led(xbus, xpd, pos);
return 0;
case DAHDI_TONEDETECT:
if (get_user(val, (int __user *)arg))
return -EFAULT;
LINE_DBG(SIGNAL, xpd, pos,
"DAHDI_TONEDETECT: %s %s (dtmf_detection=%s)\n",
(val & DAHDI_TONEDETECT_ON) ? "ON" : "OFF",
(val & DAHDI_TONEDETECT_MUTE) ? "MUTE" : "NO-MUTE",
(dtmf_detection ? "YES" : "NO"));
if (!dtmf_detection) {
spin_lock_irqsave(&xpd->lock, flags);
if (IS_SET(priv->want_dtmf_events, pos)) {
/*
* Detection mode changed:
* Disable DTMF interrupts
*/
}
hardware_dtmf_control(xpd, pos, 0);
BIT_CLR(priv->want_dtmf_events, pos);
BIT_CLR(priv->want_dtmf_mute, pos);
__do_mute_dtmf(xpd, pos, 0);
spin_unlock_irqrestore(&xpd->lock, flags);
return -ENOTTY;
}
/*
* During natively bridged calls, Asterisk
* will request one of the sides to stop sending
* dtmf events. Check the requested state.
*/
spin_lock_irqsave(&xpd->lock, flags);
if (val & DAHDI_TONEDETECT_ON) {
if (!IS_SET(priv->want_dtmf_events, pos)) {
/*
* Detection mode changed:
* Enable DTMF interrupts
*/
LINE_DBG(SIGNAL, xpd, pos,
"DAHDI_TONEDETECT: "
"Enable Hardware DTMF\n");
hardware_dtmf_control(xpd, pos, 1);
}
BIT_SET(priv->want_dtmf_events, pos);
} else {
if (IS_SET(priv->want_dtmf_events, pos)) {
/*
* Detection mode changed:
* Disable DTMF interrupts
*/
LINE_DBG(SIGNAL, xpd, pos,
"DAHDI_TONEDETECT: "
"Disable Hardware DTMF\n");
hardware_dtmf_control(xpd, pos, 0);
}
BIT_CLR(priv->want_dtmf_events, pos);
}
if (val & DAHDI_TONEDETECT_MUTE) {
BIT_SET(priv->want_dtmf_mute, pos);
} else {
BIT_CLR(priv->want_dtmf_mute, pos);
__do_mute_dtmf(xpd, pos, 0);
}
spin_unlock_irqrestore(&xpd->lock, flags);
return 0;
case DAHDI_SETPOLARITY:
if (get_user(val, (int __user *)arg))
return -EFAULT;
/*
* Asterisk may send us this if chan_dahdi config
* has "hanguponpolarityswitch=yes" to notify
* that the other side has hanged up.
*
* This has no effect on normal phone (but we may
* be connected to another FXO equipment).
* note that this chan_dahdi settings has different
* meaning for FXO, where it signals polarity
* reversal *detection* logic.
*
* It seems that sometimes we get this from
* asterisk in wrong state (e.g: while ringing).
* In these cases, silently ignore it.
*/
if (priv->lasttxhook[pos] == FXS_LINE_RING
|| priv->lasttxhook[pos] == FXS_LINE_OPEN) {
LINE_DBG(SIGNAL, xpd, pos,
"DAHDI_SETPOLARITY: %s Cannot change "
"when lasttxhook=0x%X\n",
(val) ? "ON" : "OFF", priv->lasttxhook[pos]);
return -EINVAL;
}
LINE_DBG(SIGNAL, xpd, pos, "DAHDI_SETPOLARITY: %s\n",
(val) ? "ON" : "OFF");
if ((val && !reversepolarity) || (!val && reversepolarity))
priv->lasttxhook[pos] |= FXS_LINE_RING;
else
priv->lasttxhook[pos] &= ~FXS_LINE_RING;
linefeed_control(xbus, xpd, pos, priv->lasttxhook[pos]);
return 0;
case DAHDI_VMWI_CONFIG:
if (set_vmwi(xpd, pos, arg) < 0)
return -EINVAL;
return 0;
case DAHDI_VMWI: /* message-waiting led control */
if (get_user(val, (int __user *)arg))
return -EFAULT;
if (!vmwi_ioctl) {
static bool notified;
if (!notified) {
notified = true;
LINE_NOTICE(xpd, pos,
"Got DAHDI_VMWI notification "
"but vmwi_ioctl parameter is off. "
"Ignoring.\n");
}
return 0;
}
/* Digital inputs/outputs don't have VM leds */
if (IS_SET
(PHONEDEV(xpd).digital_inputs | PHONEDEV(xpd).
digital_outputs, pos))
return 0;
PHONEDEV(xpd).msg_waiting[pos] = val;
LINE_DBG(SIGNAL, xpd, pos, "DAHDI_VMWI: %s\n",
(val) ? "yes" : "no");
return 0;
default:
report_bad_ioctl(THIS_MODULE->name, xpd, pos, cmd);
}
return -ENOTTY;
}
static int FXS_card_open(xpd_t *xpd, lineno_t chan)
{
struct FXS_priv_data *priv;
BUG_ON(!xpd);
priv = xpd->priv;
if (IS_OFFHOOK(xpd, chan))
LINE_NOTICE(xpd, chan, "Already offhook during open. OK.\n");
else
LINE_DBG(SIGNAL, xpd, chan, "is onhook\n");
/*
* Delegate updating dahdi to FXS_card_tick():
* The problem is that dahdi_hooksig() is spinlocking the channel and
* we are called by dahdi with the spinlock already held on the
* same channel.
*/
BIT_SET(priv->update_offhook_state, chan);
return 0;
}
static int FXS_card_close(xpd_t *xpd, lineno_t chan)
{
struct FXS_priv_data *priv;
BUG_ON(!xpd);
LINE_DBG(GENERAL, xpd, chan, "\n");
priv = xpd->priv;
priv->idletxhookstate[chan] = FXS_LINE_POL_ACTIVE;
return 0;
}
#ifdef POLL_DIGITAL_INPUTS
/*
* INPUT polling is done via SLIC register 0x06 (same as LEDS):
* 7 6 5 4 3 2 1 0
* +-----+-----+-----+-----+-----+-----+-----+-----+
* | I1 | I3 | | | I2 | I4 | | |
* +-----+-----+-----+-----+-----+-----+-----+-----+
*
*/
static int input_ports_type1[] = {
/* slic = input_port */
[0] = -1,
[1] = -1,
[2] = 2,
[3] = 3,
[4] = -1,
[5] = -1,
[6] = 0,
[7] = 1,
};
static void poll_inputs(xpd_t *xpd)
{
int i;
BUG_ON(xpd->xbus_idx != 0); // Only unit #0 has digital inputs
if (XPD_HW(xpd).type == 6) {
EXP_REQUEST(xpd->xbus, xpd, SLIC_READ,
REG_TYPE6_EXP_GPIOB, 0, 0);
} else {
for (i = 0; i < ARRAY_SIZE(input_ports_type1); i++) {
int pos = input_ports_type1[i];
if (pos >= 0) {
SLIC_DIRECT_REQUEST(xpd->xbus, xpd, i, SLIC_READ, 0x06, 0);
}
}
}
}
#endif
static void poll_linefeed(xpd_t *xpd)
{
struct FXS_priv_data *priv;
int i;
if (XPD_HW(xpd).type != 6)
return;
if (xpd->xpd_state != XPD_STATE_READY)
return;
priv = xpd->priv;
BUG_ON(!priv);
BUG_ON(!xpd->xbus);
XPD_DBG(GENERAL, xpd, "periodic poll");
for_each_line(xpd, i) {
if (IS_SET(PHONEDEV(xpd).digital_outputs, i)
|| IS_SET(PHONEDEV(xpd).digital_inputs, i))
continue;
if (priv->polledhook[i] == FXS_LINE_OPEN &&
priv->lasttxhook[i] != FXS_LINE_OPEN) {
LINE_NOTICE(xpd, i, "Overheat detected, resetting.");
priv->overheat_reset_counter[i]++;
linefeed_control(xpd->xbus, xpd, i,
priv->lasttxhook[i]);
}
SLIC_DIRECT_REQUEST(xpd->xbus, xpd, i, SLIC_READ,
REG_TYPE6_LINEFEED, 0);
}
}
static void handle_linefeed(xpd_t *xpd)
{
struct FXS_priv_data *priv;
int i;
BUG_ON(!xpd);
priv = xpd->priv;
BUG_ON(!priv);
for_each_line(xpd, i) {
if (priv->lasttxhook[i] == FXS_LINE_RING
&& !IS_SET(priv->neon_blinking, i)) {
/* RINGing, prepare for OHT */
priv->ohttimer[i] = OHT_TIMER;
priv->idletxhookstate[i] = FXS_LINE_POL_OHTRANS;
} else {
if (priv->ohttimer[i]) {
priv->ohttimer[i]--;
if (!priv->ohttimer[i]) {
LINE_DBG(SIGNAL, xpd, i,
"ohttimer expired\n");
priv->idletxhookstate[i] =
FXS_LINE_POL_ACTIVE;
oht_pcm(xpd, i, 0);
vmwi_search(xpd, i, 0);
if (priv->lasttxhook[i] ==
FXS_LINE_POL_OHTRANS) {
/* Apply the change if appropriate */
linefeed_control(xpd->xbus, xpd,
i,
FXS_LINE_POL_ACTIVE);
}
}
}
}
}
}
/*
* Optimized memcmp() like function. Only test for equality (true/false).
* This optimization reduced the detect_vmwi() runtime by a factor of 3.
*/
static inline bool mem_equal(const char a[], const char b[], size_t len)
{
int i;
for (i = 0; i < len; i++)
if (a[i] != b[i])
return 0;
return 1;
}
/*
* Detect Voice Mail Waiting Indication
*/
static void detect_vmwi(xpd_t *xpd)
{
struct FXS_priv_data *priv;
xbus_t *xbus;
static const __u8 FSK_COMMON_PATTERN[] =
{ 0xA8, 0x49, 0x22, 0x3B, 0x9F, 0xFF, 0x1F, 0xBB };
static const __u8 FSK_ON_PATTERN[] =
{ 0xA2, 0x2C, 0x1F, 0x2C, 0xBB, 0xA1, 0xA5, 0xFF };
static const __u8 FSK_OFF_PATTERN[] =
{ 0xA2, 0x2C, 0x28, 0xA5, 0xB1, 0x21, 0x49, 0x9F };
int i;
xpp_line_t ignore_mask;
BUG_ON(!xpd);
xbus = xpd->xbus;
priv = xpd->priv;
BUG_ON(!priv);
ignore_mask =
PHONEDEV(xpd).offhook_state |
~(PHONEDEV(xpd).oht_pcm_pass) |
~(priv->search_fsk_pattern) |
PHONEDEV(xpd).digital_inputs |
PHONEDEV(xpd).digital_outputs;
for_each_line(xpd, i) {
struct dahdi_chan *chan = XPD_CHAN(xpd, i);
__u8 *writechunk = chan->writechunk;
if (IS_SET(ignore_mask, i))
continue;
#if 0
if (writechunk[0] != 0x7F && writechunk[0] != 0) {
int j;
LINE_DBG(GENERAL, xpd, i, "MSG:");
for (j = 0; j < DAHDI_CHUNKSIZE; j++) {
if (debug)
printk(" %02X", writechunk[j]);
}
if (debug)
printk("\n");
}
#endif
if (unlikely
(mem_equal
(writechunk, FSK_COMMON_PATTERN, DAHDI_CHUNKSIZE))) {
LINE_DBG(SIGNAL, xpd, i,
"Found common FSK pattern. "
"Start looking for ON/OFF patterns.\n");
BIT_SET(priv->found_fsk_pattern, i);
} else if (unlikely(IS_SET(priv->found_fsk_pattern, i))) {
BIT_CLR(priv->found_fsk_pattern, i);
oht_pcm(xpd, i, 0);
if (unlikely
(mem_equal
(writechunk, FSK_ON_PATTERN, DAHDI_CHUNKSIZE))) {
LINE_DBG(SIGNAL, xpd, i, "MSG WAITING ON\n");
PHONEDEV(xpd).msg_waiting[i] = 1;
start_stop_vm_led(xbus, xpd, i);
} else
if (unlikely
(mem_equal
(writechunk, FSK_OFF_PATTERN,
DAHDI_CHUNKSIZE))) {
LINE_DBG(SIGNAL, xpd, i, "MSG WAITING OFF\n");
PHONEDEV(xpd).msg_waiting[i] = 0;
start_stop_vm_led(xbus, xpd, i);
} else {
int j;
LINE_NOTICE(xpd, i, "MSG WAITING Unexpected:");
for (j = 0; j < DAHDI_CHUNKSIZE; j++)
printk(" %02X", writechunk[j]);
printk("\n");
}
}
}
}
static int FXS_card_tick(xbus_t *xbus, xpd_t *xpd)
{
struct FXS_priv_data *priv;
BUG_ON(!xpd);
priv = xpd->priv;
BUG_ON(!priv);
#ifdef POLL_DIGITAL_INPUTS
if (poll_digital_inputs && PHONEDEV(xpd).digital_inputs) {
if ((xpd->timer_count % poll_digital_inputs) == 0)
poll_inputs(xpd);
}
#endif
if ((xpd->timer_count % poll_chan_linefeed) == 0)
poll_linefeed(xpd);
handle_fxs_leds(xpd);
handle_linefeed(xpd);
if (XPD_HW(xpd).type == 6)
blink_mwi(xpd);
/*
* Hack alert (FIXME):
* Asterisk did FXS_card_open() and we wanted to report
* offhook state. However, the channel is spinlocked by dahdi
* so we marked it in the priv->update_offhook_state mask and
* now we take care of notification to dahdi and Asterisk
*/
if (priv->update_offhook_state) {
enum dahdi_rxsig rxsig;
int i;
for_each_line(xpd, i) {
if (!IS_SET(priv->update_offhook_state, i))
continue;
rxsig =
IS_OFFHOOK(xpd,
i) ? DAHDI_RXSIG_OFFHOOK :
DAHDI_RXSIG_ONHOOK;
/* Notify after open() */
notify_rxsig(xpd, i, rxsig);
BIT_CLR(priv->update_offhook_state, i);
}
}
if (SPAN_REGISTERED(xpd)) {
if (!vmwi_ioctl && priv->search_fsk_pattern)
detect_vmwi(xpd); /* Detect via FSK modulation */
}
return 0;
}
/*---------------- FXS: HOST COMMANDS -------------------------------------*/
/*---------------- FXS: Astribank Reply Handlers --------------------------*/
/*
* Should be called with spinlocked XPD
*/
static void process_hookstate(xpd_t *xpd, xpp_line_t offhook,
xpp_line_t change_mask)
{
xbus_t *xbus;
struct FXS_priv_data *priv;
int i;
BUG_ON(!xpd);
BUG_ON(PHONEDEV(xpd).direction != TO_PHONE);
xbus = xpd->xbus;
priv = xpd->priv;
XPD_DBG(SIGNAL, xpd, "offhook=0x%X change_mask=0x%X\n", offhook,
change_mask);
for_each_line(xpd, i) {
if (IS_SET(PHONEDEV(xpd).digital_outputs, i)
|| IS_SET(PHONEDEV(xpd).digital_inputs, i))
continue;
if (IS_SET(change_mask, i)) {
PHONEDEV(xpd).ringing[i] = 0; /* No more ringing... */
#ifdef WITH_METERING
metering_gen(xpd, i, 0); /* Stop metering... */
#endif
MARK_BLINK(priv, i, LED_GREEN, 0);
/*
* Reset our previous DTMF memories...
*/
BIT_CLR(priv->prev_key_down, i);
priv->prev_key_time[i] = ktime_set(0L, 0UL);
if (IS_SET(offhook, i)) {
LINE_DBG(SIGNAL, xpd, i, "OFFHOOK\n");
MARK_ON(priv, i, LED_GREEN);
hookstate_changed(xpd, i, 1);
} else {
LINE_DBG(SIGNAL, xpd, i, "ONHOOK\n");
MARK_OFF(priv, i, LED_GREEN);
hookstate_changed(xpd, i, 0);
}
/*
* Must switch to low power. In high power, an ONHOOK
* won't be detected.
*/
do_chan_power(xbus, xpd, i, 0);
}
}
}
HANDLER_DEF(FXS, SIG_CHANGED)
{
xpp_line_t sig_status =
RPACKET_FIELD(pack, FXS, SIG_CHANGED, sig_status);
xpp_line_t sig_toggles =
RPACKET_FIELD(pack, FXS, SIG_CHANGED, sig_toggles);
unsigned long flags;
BUG_ON(!xpd);
BUG_ON(PHONEDEV(xpd).direction != TO_PHONE);
XPD_DBG(SIGNAL, xpd, "(PHONE) sig_toggles=0x%04X sig_status=0x%04X\n",
sig_toggles, sig_status);
#if 0
Is this needed ? for_each_line(xpd, i) {
// Power down (prevent overheating!!!)
if (IS_SET(sig_toggles, i))
do_chan_power(xpd->xbus, xpd, BIT(i), 0);
}
#endif
spin_lock_irqsave(&xpd->lock, flags);
process_hookstate(xpd, sig_status, sig_toggles);
spin_unlock_irqrestore(&xpd->lock, flags);
return 0;
}
#ifdef POLL_DIGITAL_INPUTS
static inline void notify_digital_input(xpd_t *xpd, int input_port, int offhook)
{
int channo = PHONEDEV(xpd).channels - LINES_DIGI_INP + input_port;
/* Stop ringing. No leds for digital inputs. */
PHONEDEV(xpd).ringing[channo] = 0;
if (offhook && !IS_OFFHOOK(xpd, channo)) {
LINE_DBG(SIGNAL, xpd, channo, "OFFHOOK\n");
hookstate_changed(xpd, channo, 1);
} else if (!offhook && IS_OFFHOOK(xpd, channo)) {
LINE_DBG(SIGNAL, xpd, channo, "ONHOOK\n");
hookstate_changed(xpd, channo, 0);
}
}
static void process_digital_inputs(xpd_t *xpd, const reg_cmd_t *info)
{
bool offhook;
/* Sanity check */
if (!PHONEDEV(xpd).digital_inputs) {
XPD_NOTICE(xpd, "%s called without digital inputs. Ignored\n",
__func__);
return;
}
if (XPD_HW(xpd).type == 6) {
static int input_values_type6[] = { 0x80, 0x20, 0x08, 0x02 }; /* I/O Expander values of input relays */
int i;
/* Map I/O Expander GPIO into line number */
for (i = 0; i < ARRAY_SIZE(input_values_type6); i++) {
int chanmask = input_values_type6[i];
offhook = (REG_FIELD(info, data_low) & chanmask) == 0;
notify_digital_input(xpd, i, offhook);
}
} else {
int channo = info->h.portnum;
int input_port;
offhook = (REG_FIELD(info, data_low) & 0x1) == 0;
if (channo < 0 || channo >= ARRAY_SIZE(input_ports_type1)) {
XPD_ERR(xpd, "%s: got bad portnum=%d\n", __func__, channo);
return;
}
input_port = input_ports_type1[channo];
if (input_port < 0) {
XPD_ERR(xpd, "%s: portnum=%d is not input port\n", __func__, channo);
return;
}
notify_digital_input(xpd, input_port, offhook);
}
}
#endif
static const char dtmf_digits[] = {
'D', '1', '2', '3', '4', '5', '6', '7', '8', '9', '0', '*', '#',
'A', 'B', 'C'
};
/*
* This function is called with spinlocked XPD
*/
static void process_dtmf(xpd_t *xpd, uint portnum, __u8 val)
{
__u8 digit;
bool key_down = val & 0x10;
bool want_mute;
bool want_event;
struct FXS_priv_data *priv;
ktime_t now;
s64 msec = 0;
struct timespec64 ts;
if (!dtmf_detection)
return;
if (!SPAN_REGISTERED(xpd))
return;
priv = xpd->priv;
val &= 0xF;
digit = dtmf_digits[val];
want_mute = IS_SET(priv->want_dtmf_mute, portnum);
want_event = IS_SET(priv->want_dtmf_events, portnum);
if (!IS_SET(priv->prev_key_down, portnum) && !key_down)
LINE_NOTICE(xpd, portnum, "DTMF: duplicate UP (%c)\n", digit);
if (key_down)
BIT_SET(priv->prev_key_down, portnum);
else
BIT_CLR(priv->prev_key_down, portnum);
now = ktime_get();
if (!dahdi_ktime_equal(priv->prev_key_time[portnum], ktime_set(0, 0)))
msec = ktime_ms_delta(now, priv->prev_key_time[portnum]);
priv->prev_key_time[portnum] = now;
ts = ktime_to_timespec64(now);
LINE_DBG(SIGNAL, xpd, portnum,
"[%lld.%06ld] DTMF digit %-4s '%c' (val=%d, want_mute=%s want_event=%s, delta=%lld msec)\n",
(s64)ts.tv_sec, ts.tv_nsec * NSEC_PER_USEC,
(key_down) ? "DOWN" : "UP", digit, val,
(want_mute) ? "yes" : "no", (want_event) ? "yes" : "no", msec);
/*
* FIXME: we currently don't use the want_dtmf_mute until
* we are sure about the logic in Asterisk native bridging.
* Meanwhile, simply mute it on button press.
*/
if (key_down && want_mute)
__do_mute_dtmf(xpd, portnum, 1);
else
__do_mute_dtmf(xpd, portnum, 0);
if (want_event) {
int event =
(key_down) ? DAHDI_EVENT_DTMFDOWN : DAHDI_EVENT_DTMFUP;
dahdi_qevent_lock(XPD_CHAN(xpd, portnum), event | digit);
}
}
static int FXS_card_register_reply(xbus_t *xbus, xpd_t *xpd, reg_cmd_t *info)
{
unsigned long flags;
struct FXS_priv_data *priv;
__u8 regnum = 0;
bool indirect = 0;
spin_lock_irqsave(&xpd->lock, flags);
priv = xpd->priv;
BUG_ON(!priv);
if (info->h.bytes == REG_CMD_SIZE(REG)) {
if ((XPD_HW(xpd).type == 1) && (REG_FIELD(info, regnum) == 0x1E))
indirect = 1;
regnum = (indirect) ? REG_FIELD(info, subreg) : REG_FIELD(info, regnum);
XPD_DBG(REGS, xpd, "%s reg_num=0x%X, dataL=0x%X dataH=0x%X\n",
(indirect) ? "I" : "D", regnum, REG_FIELD(info, data_low),
REG_FIELD(info, data_high));
}
if (info->h.bytes == REG_CMD_SIZE(RAM)) {
uint addr;
unsigned long val;
XPD_DBG(REGS, xpd, "port=%d, addr_low=0x%X, addr_high=0x%X, data_0=0x%X data_1=0x%X data_2=0x%X data_3=0x%X\n",
info->h.portnum,
REG_FIELD_RAM(info, addr_low),
REG_FIELD_RAM(info, addr_high),
REG_FIELD_RAM(info, data_0),
REG_FIELD_RAM(info, data_1),
REG_FIELD_RAM(info, data_2),
REG_FIELD_RAM(info, data_3));
addr = (REG_FIELD_RAM(info, addr_high) << 8) | REG_FIELD_RAM(info, addr_low);
val = (REG_FIELD_RAM(info, data_3) << 24) |
(REG_FIELD_RAM(info, data_2) << 16) |
(REG_FIELD_RAM(info, data_1) << 8) |
REG_FIELD_RAM(info, data_0);
} else if ((XPD_HW(xpd).type == 1 && !indirect && regnum == REG_TYPE1_DTMF_DECODE) ||
(XPD_HW(xpd).type == 6 && !indirect && regnum == REG_TYPE6_TONDTMF)) {
__u8 val = REG_FIELD(info, data_low);
process_dtmf(xpd, info->h.portnum, val);
} else if ((XPD_HW(xpd).type == 6 && !indirect && regnum == REG_TYPE6_LINEFEED)) {
__u8 val = REG_FIELD(info, data_low);
LINE_DBG(SIGNAL, xpd, info->h.portnum,
"REG_TYPE6_LINEFEED: dataL=0x%X \n", val);
priv->polledhook[info->h.portnum] = val;
}
#ifdef POLL_DIGITAL_INPUTS
/*
* Process digital inputs polling results
*/
else if ( (XPD_HW(xpd).type == 1 && !indirect && regnum == REG_TYPE1_DIGITAL_IOCTRL) ||
(XPD_HW(xpd).type == 6 && !indirect && regnum == REG_TYPE6_EXP_GPIOB &&
REG_FIELD(info, do_expander)))
process_digital_inputs(xpd, info);
#endif
else if (XPD_HW(xpd).type == 1 && !indirect && regnum == REG_TYPE1_LOOPCLOSURE) { /* OFFHOOK ? */
__u8 val = REG_FIELD(info, data_low);
xpp_line_t mask = BIT(info->h.portnum);
xpp_line_t offhook;
/*
* Validate reply. Non-existing/disabled ports
* will reply with 0xFF. Ignore these.
*/
if ((val & REG_TYPE1_LOOPCLOSURE_ZERO) == 0) {
offhook = (val & REG_TYPE1_LOOPCLOSURE_LCR) ? mask : 0;
LINE_DBG(SIGNAL, xpd, info->h.portnum,
"REG_TYPE1_LOOPCLOSURE: dataL=0x%X "
"(offhook=0x%X mask=0x%X)\n",
val, offhook, mask);
process_hookstate(xpd, offhook, mask);
}
} else if (XPD_HW(xpd).type == 6 && !indirect && regnum == REG_TYPE6_LCRRTP) { /* OFFHOOK ? */
__u8 val = REG_FIELD(info, data_low);
xpp_line_t mask = BIT(info->h.portnum);
xpp_line_t offhook;
/*
* Validate reply. Non-existing/disabled ports
* will reply with 0xFF. Ignore these.
*/
if ((val & REG_TYPE6_LCRRTP_ZERO) == 0) {
offhook = (val & REG_TYPE6_LCRRTP_LCR) ? mask : 0;
LINE_DBG(SIGNAL, xpd, info->h.portnum,
"REG_TYPE6_LCRRTP: dataL=0x%X "
"(offhook=0x%X mask=0x%X)\n",
val, offhook, mask);
process_hookstate(xpd, offhook, mask);
}
} else {
#if 0
XPD_NOTICE(xpd,
"Spurious register reply(ignored): "
"%s reg_num=0x%X, dataL=0x%X dataH=0x%X\n",
(indirect) ? "I" : "D",
regnum, REG_FIELD(info, data_low),
REG_FIELD(info, data_high));
#endif
}
/*
* Update /proc info only if reply relate to the last slic
* read request
*/
if (REG_FIELD(&xpd->requested_reply, regnum) ==
REG_FIELD(info, regnum)
&& REG_FIELD(&xpd->requested_reply, do_subreg) ==
REG_FIELD(info, do_subreg)
&& REG_FIELD(&xpd->requested_reply, subreg) ==
REG_FIELD(info, subreg)) {
xpd->last_reply = *info;
}
spin_unlock_irqrestore(&xpd->lock, flags);
return 0;
}
static int FXS_card_state(xpd_t *xpd, bool on)
{
BUG_ON(!xpd);
XPD_DBG(GENERAL, xpd, "%s\n", (on) ? "on" : "off");
return 0;
}
static const struct xops fxs_xops = {
.card_new = FXS_card_new,
.card_init = FXS_card_init,
.card_remove = FXS_card_remove,
.card_tick = FXS_card_tick,
.card_register_reply = FXS_card_register_reply,
};
static const struct phoneops fxs_phoneops = {
.card_dahdi_preregistration = FXS_card_dahdi_preregistration,
.card_dahdi_postregistration = FXS_card_dahdi_postregistration,
.card_hooksig = FXS_card_hooksig,
.card_pcm_recompute = generic_card_pcm_recompute,
.card_pcm_fromspan = generic_card_pcm_fromspan,
.card_pcm_tospan = generic_card_pcm_tospan,
.card_timing_priority = generic_timing_priority,
.echocancel_timeslot = generic_echocancel_timeslot,
.echocancel_setmask = generic_echocancel_setmask,
.card_open = FXS_card_open,
.card_close = FXS_card_close,
.card_ioctl = FXS_card_ioctl,
.card_state = FXS_card_state,
};
static xproto_table_t PROTO_TABLE(FXS) = {
.owner = THIS_MODULE,
.entries = {
/* Prototable Card Opcode */
XENTRY( FXS, FXS, SIG_CHANGED ),
},
.name = "FXS", /* protocol name */
.ports_per_subunit = 8,
.type = XPD_TYPE_FXS,
.xops = &fxs_xops,
.phoneops = &fxs_phoneops,
.packet_is_valid = fxs_packet_is_valid,
.packet_dump = fxs_packet_dump,
};
static bool fxs_packet_is_valid(xpacket_t *pack)
{
const xproto_entry_t *xe;
// DBG(GENERAL, "\n");
xe = xproto_card_entry(&PROTO_TABLE(FXS), XPACKET_OP(pack));
return xe != NULL;
}
static void fxs_packet_dump(const char *msg, xpacket_t *pack)
{
DBG(GENERAL, "%s\n", msg);
}
/*------------------------- SLIC Handling --------------------------*/
#ifdef CONFIG_PROC_FS
static int proc_fxs_info_show(struct seq_file *sfile, void *not_used)
{
unsigned long flags;
xpd_t *xpd = sfile->private;
struct FXS_priv_data *priv;
int i;
int led;
if (!xpd)
return -ENODEV;
spin_lock_irqsave(&xpd->lock, flags);
priv = xpd->priv;
BUG_ON(!priv);
seq_printf(sfile, "%-12s", "Channel:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d", i);
}
seq_printf(sfile, "\n%-12s", "");
for_each_line(xpd, i) {
char *chan_type;
if (IS_SET(PHONEDEV(xpd).digital_outputs, i))
chan_type = "out";
else if (IS_SET(PHONEDEV(xpd).digital_inputs, i))
chan_type = "in";
else
chan_type = "";
seq_printf(sfile, "%4s", chan_type);
}
seq_printf(sfile, "\n%-12s", "idletxhook:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d", priv->idletxhookstate[i]);
}
seq_printf(sfile, "\n%-12s", "lasttxhook:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d", priv->lasttxhook[i]);
}
seq_printf(sfile, "\n%-12s", "ohttimer:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d", priv->ohttimer[i]);
}
seq_printf(sfile, "\n%-12s", "neon_blink:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d",
IS_SET(priv->neon_blinking, i));
}
seq_printf(sfile, "\n%-12s", "search_fsk:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d",
IS_SET(priv->search_fsk_pattern, i));
}
seq_printf(sfile, "\n%-12s", "vbat_h:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d",
test_bit(i, (unsigned long *)&priv->vbat_h));
}
seq_printf(sfile, "\n");
for (led = 0; led < NUM_LEDS; led++) {
seq_printf(sfile, "\nLED #%d\t%-12s: ",
led, "ledstate");
for_each_line(xpd, i) {
if (!IS_SET(PHONEDEV(xpd).digital_outputs, i)
&& !IS_SET(PHONEDEV(xpd).digital_inputs, i))
seq_printf(sfile, "%d ",
IS_SET(priv->ledstate[led], i));
}
seq_printf(sfile, "\nLED #%d\t%-12s: ",
led, "ledcontrol");
for_each_line(xpd, i) {
if (!IS_SET(PHONEDEV(xpd).digital_outputs, i)
&& !IS_SET(PHONEDEV(xpd).digital_inputs, i))
seq_printf(sfile, "%d ",
IS_SET(priv->ledcontrol[led], i));
}
seq_printf(sfile, "\nLED #%d\t%-12s: ",
led, "led_counter");
for_each_line(xpd, i) {
if (!IS_SET(PHONEDEV(xpd).digital_outputs, i)
&& !IS_SET(PHONEDEV(xpd).digital_inputs, i))
seq_printf(sfile, "%d ",
LED_COUNTER(priv, i, led));
}
}
seq_printf(sfile, "\n%-12s", "overheats:");
for_each_line(xpd, i) {
seq_printf(sfile, "%4d", priv->overheat_reset_counter[i]);
}
seq_printf(sfile, "\n");
spin_unlock_irqrestore(&xpd->lock, flags);
return 0;
}
static int proc_fxs_info_open(struct inode *inode, struct file *file)
{
return single_open(file, proc_fxs_info_show, PDE_DATA(inode));
}
static const struct file_operations proc_fxs_info_ops = {
.owner = THIS_MODULE,
.open = proc_fxs_info_open,
.read = seq_read,
.llseek = seq_lseek,
.release = single_release,
};
#ifdef WITH_METERING
static ssize_t proc_xpd_metering_write(struct file *file,
const char __user *buffer, size_t count, loff_t *offset)
{
xpd_t *xpd = file->private_data;
char buf[MAX_PROC_WRITE];
lineno_t chan;
int num;
int ret;
if (!xpd)
return -ENODEV;
if (count >= MAX_PROC_WRITE - 1) {
XPD_ERR(xpd, "Metering string too long (%zu)\n", count);
return -EINVAL;
}
if (copy_from_user(&buf, buffer, count))
return -EFAULT;
buf[count] = '\0';
ret = sscanf(buf, "%d", &num);
if (ret != 1) {
XPD_ERR(xpd, "Metering value should be number. Got '%s'\n",
buf);
return -EINVAL;
}
chan = num;
if (chan != PORT_BROADCAST && chan > xpd->channels) {
XPD_ERR(xpd, "Metering tone: bad channel number %d\n", chan);
return -EINVAL;
}
if ((ret = metering_gen(xpd, chan, 1)) < 0) {
XPD_ERR(xpd, "Failed sending metering tone\n");
return ret;
}
return count;
}
static int proc_xpd_metering_open(struct inode *inode, struct file *file)
{
file->private_data = PDE_DATA(inode);
}
static const struct file_operations proc_xpd_metering_ops = {
.owner = THIS_MODULE,
.open = proc_xpd_metering_open,
.write = proc_xpd_metering_write,
.release = single_release,
};
#endif
#endif
static DEVICE_ATTR_READER(fxs_ring_registers_show, dev, buf)
{
xpd_t *xpd;
struct FXS_priv_data *priv;
unsigned long flags;
const struct ring_reg_params *p;
const struct byte_pair *v;
enum ring_types rtype;
int len = 0;
int i;
BUG_ON(!dev);
xpd = dev_to_xpd(dev);
if (!xpd)
return -ENODEV;
priv = xpd->priv;
BUG_ON(!priv);
spin_lock_irqsave(&xpd->lock, flags);
len += sprintf(buf + len, "# Reg#: D/I\tNEON \tTRAPEZ \tNORMAL \n");
for (i = 0; i < ARRAY_SIZE(ring_parameters); i++) {
p = &ring_parameters[i];
len += sprintf(buf + len, "[%d] 0x%02X: %c",
i, p->regno, (p->is_indirect) ? 'I' : 'D');
for (rtype = RING_TYPE_NEON; rtype <= RING_TYPE_NORMAL; rtype++) {
v = &(p->values[rtype]);
if (p->is_indirect)
len += sprintf(buf + len, "\t0x%02X 0x%02X",
v->h_val, v->l_val);
else
len += sprintf(buf + len, "\t0x%02X ----",
v->l_val);
}
len += sprintf(buf + len, "\n");
}
spin_unlock_irqrestore(&xpd->lock, flags);
return len;
}
static DEVICE_ATTR_WRITER(fxs_ring_registers_store, dev, buf, count)
{
xpd_t *xpd;
struct FXS_priv_data *priv;
unsigned long flags;
char rtype_name[MAX_PROC_WRITE];
enum ring_types rtype;
struct ring_reg_params *params;
struct byte_pair *v;
int regno;
int h_val;
int l_val;
int ret;
int i;
BUG_ON(!dev);
xpd = dev_to_xpd(dev);
if (!xpd)
return -ENODEV;
priv = xpd->priv;
BUG_ON(!priv);
ret = sscanf(buf, "%10s %X %X %X\n",
rtype_name, &regno, &h_val, &l_val);
if (ret < 3 || ret > 4) {
XPD_ERR(xpd, "Bad input: '%s'\n", buf);
XPD_ERR(xpd, "# Correct input\n");
XPD_ERR(xpd, "{NEON|TRAPEZ|NORMAL} <regno> <byte> [<byte>]\n");
goto invalid_input;
}
if (strcasecmp("NEON", rtype_name) == 0)
rtype = RING_TYPE_NEON;
else if (strcasecmp("TRAPEZ", rtype_name) == 0)
rtype = RING_TYPE_TRAPEZ;
else if (strcasecmp("NORMAL", rtype_name) == 0)
rtype = RING_TYPE_NORMAL;
else {
XPD_ERR(xpd, "Unknown ring type '%s' (NEON/TRAPEZ/NORMAL)\n",
rtype_name);
goto invalid_input;
}
params = NULL;
for (i = 0; i < ARRAY_SIZE(ring_parameters); i++) {
if (ring_parameters[i].regno == regno) {
params = &ring_parameters[i];
break;
}
}
if (!params) {
XPD_ERR(xpd, "Bad register 0x%X\n", regno);
goto invalid_input;
}
if (params->is_indirect) {
if (ret != 4) {
XPD_ERR(xpd,
"Missing low-byte (0x%X is indirect register)\n",
regno);
goto invalid_input;
}
XPD_DBG(SIGNAL, xpd, "%s Indirect 0x%X <=== 0x%X 0x%X\n",
rtype_name, regno, h_val, l_val);
} else {
if (ret != 3) {
XPD_ERR(xpd,
"Should give exactly one value (0x%X is direct register)\n",
regno);
goto invalid_input;
}
l_val = h_val;
h_val = 0;
XPD_DBG(SIGNAL, xpd, "%s Direct 0x%X <=== 0x%X\n",
rtype_name, regno, h_val);
}
spin_lock_irqsave(&xpd->lock, flags);
v = &(params->values[rtype]);
v->h_val = h_val;
v->l_val = l_val;
spin_unlock_irqrestore(&xpd->lock, flags);
return count;
invalid_input:
return -EINVAL;
}
static DEVICE_ATTR(fxs_ring_registers, S_IRUGO | S_IWUSR,
fxs_ring_registers_show,
fxs_ring_registers_store);
static int fxs_xpd_probe(struct device *dev)
{
xpd_t *xpd;
int ret;
xpd = dev_to_xpd(dev);
/* Is it our device? */
if (xpd->xpd_type != XPD_TYPE_FXS) {
XPD_ERR(xpd, "drop suggestion for %s (%d)\n", dev_name(dev),
xpd->xpd_type);
return -EINVAL;
}
XPD_DBG(DEVICES, xpd, "SYSFS\n");
ret = device_create_file(dev, &dev_attr_fxs_ring_registers);
if (ret) {
XPD_ERR(xpd, "%s: device_create_file(fxs_ring_registers) failed: %d\n",
__func__, ret);
goto fail_fxs_ring_registers;
}
return 0;
fail_fxs_ring_registers:
return ret;
}
static int fxs_xpd_remove(struct device *dev)
{
xpd_t *xpd;
xpd = dev_to_xpd(dev);
XPD_DBG(DEVICES, xpd, "SYSFS\n");
device_remove_file(dev, &dev_attr_fxs_ring_registers);
return 0;
}
static struct xpd_driver fxs_driver = {
.xpd_type = XPD_TYPE_FXS,
.driver = {
.name = "fxs",
.owner = THIS_MODULE,
.probe = fxs_xpd_probe,
.remove = fxs_xpd_remove}
};
static int __init card_fxs_startup(void)
{
int ret;
if ((ret = xpd_driver_register(&fxs_driver.driver)) < 0)
return ret;
#ifdef POLL_DIGITAL_INPUTS
INFO("FEATURE: with DIGITAL INPUTS support (polled every %d msec)\n",
poll_digital_inputs);
#else
INFO("FEATURE: without DIGITAL INPUTS support\n");
#endif
INFO("FEATURE: DAHDI_VMWI (HVAC only)\n");
#ifdef WITH_METERING
INFO("FEATURE: WITH METERING Generation\n");
#else
INFO("FEATURE: NO METERING Generation\n");
#endif
xproto_register(&PROTO_TABLE(FXS));
return 0;
}
static void __exit card_fxs_cleanup(void)
{
xproto_unregister(&PROTO_TABLE(FXS));
xpd_driver_unregister(&fxs_driver.driver);
}
MODULE_DESCRIPTION("XPP FXS Card Driver");
MODULE_AUTHOR("Oron Peled <oron@actcom.co.il>");
MODULE_LICENSE("GPL");
MODULE_ALIAS_XPD(XPD_TYPE_FXS);
module_init(card_fxs_startup);
module_exit(card_fxs_cleanup);