dahdi-linux/drivers/dahdi/wcfxo.c
Shaun Ruffell 64a98af676 Remove DAHDI_IRQF_[SHARED|DISABLED] flags.
These flags are direct mappings to the IRQF_[SHARED|DISABLED] flags and no
longer need to be kept separate.

Signed-off-by: Shaun Ruffell <sruffell@digium.com>
Signed-off-by: Russ Meyerriecks <rmeyerriecks@digium.com>
2015-05-13 14:45:01 -05:00

1105 lines
29 KiB
C

/*
* Wildcard X100P FXO Interface Driver for DAHDI Telephony interface
*
* Written by Mark Spencer <markster@digium.com>
* Matthew Fredrickson <creslin@digium.com>
*
* Copyright (C) 2001-2008, 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/usb.h>
#include <linux/pci.h>
#include <asm/io.h>
#include <linux/moduleparam.h>
#include <linux/slab.h>
#include <dahdi/kernel.h>
/* Uncomment to enable tasklet handling in the FXO driver. Not recommended
in general, but may improve interactive performance */
/* #define ENABLE_TASKLETS */
/* Un-comment the following for POTS line support for Japan */
/* #define JAPAN */
/* Un-comment for lines (eg from and ISDN TA) that remove */
/* phone power during ringing */
/* #define ZERO_BATT_RING */
#define WC_MAX_IFACES 128
#define WC_CNTL 0x00
#define WC_OPER 0x01
#define WC_AUXC 0x02
#define WC_AUXD 0x03
#define WC_MASK0 0x04
#define WC_MASK1 0x05
#define WC_INTSTAT 0x06
#define WC_DMAWS 0x08
#define WC_DMAWI 0x0c
#define WC_DMAWE 0x10
#define WC_DMARS 0x18
#define WC_DMARI 0x1c
#define WC_DMARE 0x20
#define WC_AUXFUNC 0x2b
#define WC_SERCTL 0x2d
#define WC_FSCDELAY 0x2f
/* DAA registers */
#define WC_DAA_CTL1 1
#define WC_DAA_CTL2 2
#define WC_DAA_DCTL1 5
#define WC_DAA_DCTL2 6
#define WC_DAA_PLL1_N1 7
#define WC_DAA_PLL1_M1 8
#define WC_DAA_PLL2_N2_M2 9
#define WC_DAA_PLL_CTL 10
#define WC_DAA_CHIPA_REV 11
#define WC_DAA_LINE_STAT 12
#define WC_DAA_CHIPB_REV 13
#define WC_DAA_DAISY_CTL 14
#define WC_DAA_TXRX_GCTL 15
#define WC_DAA_INT_CTL1 16
#define WC_DAA_INT_CTL2 17
#define WC_DAA_INT_CTL3 18
#define WC_DAA_INT_CTL4 19
#define FLAG_EMPTY 0
#define FLAG_WRITE 1
#define FLAG_READ 2
#ifdef ZERO_BATT_RING /* Need to debounce Off/On hook too */
#define JAPAN
#endif
#define RING_DEBOUNCE 64 /* Ringer Debounce (in ms) */
#ifdef JAPAN
#define BATT_DEBOUNCE 30 /* Battery debounce (in ms) */
#define OH_DEBOUNCE 350 /* Off/On hook debounce (in ms) */
#else
#define BATT_DEBOUNCE 80 /* Battery debounce (in ms) */
#endif
#define MINPEGTIME 10 * 8 /* 30 ms peak to peak gets us no more than 100 Hz */
#define PEGTIME 50 * 8 /* 50ms peak to peak gets us rings of 10 Hz or more */
#define PEGCOUNT 5 /* 5 cycles of pegging means RING */
#define wcfxo_printk(level, span, fmt, ...) \
printk(KERN_ ## level "%s-%s: %s: " fmt, #level, \
THIS_MODULE->name, (span).name, ## __VA_ARGS__)
#define wcfxo_notice(span, fmt, ...) \
wcfxo_printk(NOTICE, span, fmt, ## __VA_ARGS__)
#define wcfxo_dbg(span, fmt, ...) \
((void)((debug) && wcfxo_printk(DEBUG, span, "%s: " fmt, \
__FUNCTION__, ## __VA_ARGS__) ) )
struct reg {
unsigned long flags;
unsigned char index;
unsigned char reg;
unsigned char value;
};
static int wecareregs[] =
{
WC_DAA_DCTL1, WC_DAA_DCTL2, WC_DAA_PLL2_N2_M2, WC_DAA_CHIPA_REV,
WC_DAA_LINE_STAT, WC_DAA_CHIPB_REV, WC_DAA_INT_CTL2, WC_DAA_INT_CTL4,
};
struct wcfxo {
struct pci_dev *dev;
char *variety;
struct dahdi_device *ddev;
struct dahdi_span span;
struct dahdi_chan _chan;
struct dahdi_chan *chan;
int usecount;
int dead;
int pos;
unsigned long flags;
int freeregion;
int ring;
int offhook;
int battery;
int wregcount;
int readpos;
int rreadpos;
unsigned int pegtimer;
int pegcount;
int peg;
int battdebounce;
int nobatttimer;
int ringdebounce;
#ifdef JAPAN
int ohdebounce;
#endif
int allread;
int regoffset; /* How far off our registers are from what we expect */
int alt;
int ignoreread;
int reset;
/* Up to 6 register can be written at a time */
struct reg regs[DAHDI_CHUNKSIZE];
struct reg oldregs[DAHDI_CHUNKSIZE];
unsigned char lasttx[DAHDI_CHUNKSIZE];
/* Up to 32 registers of whatever we most recently read */
unsigned char readregs[32];
unsigned long ioaddr;
dma_addr_t readdma;
dma_addr_t writedma;
volatile int *writechunk; /* Double-word aligned write memory */
volatile int *readchunk; /* Double-word aligned read memory */
#ifdef ZERO_BATT_RING
int onhook;
#endif
#ifdef ENABLE_TASKLETS
int taskletrun;
int taskletsched;
int taskletpending;
int taskletexec;
int txerrors;
int ints;
struct tasklet_struct wcfxo_tlet;
#endif
};
#define FLAG_INVERTSER (1 << 0)
#define FLAG_USE_XTAL (1 << 1)
#define FLAG_DOUBLE_CLOCK (1 << 2)
#define FLAG_RESET_ON_AUX5 (1 << 3)
#define FLAG_NO_I18N_REGS (1 << 4) /*!< Uses si3035, rather si3034 */
struct wcfxo_desc {
char *name;
unsigned long flags;
};
static struct wcfxo_desc wcx100p = { "Wildcard X100P",
FLAG_INVERTSER | FLAG_USE_XTAL | FLAG_DOUBLE_CLOCK };
static struct wcfxo_desc wcx101p = { "Wildcard X101P",
FLAG_USE_XTAL | FLAG_DOUBLE_CLOCK };
static struct wcfxo_desc generic = { "Generic Clone",
FLAG_USE_XTAL | FLAG_DOUBLE_CLOCK };
static struct wcfxo *ifaces[WC_MAX_IFACES];
static void wcfxo_release(struct wcfxo *wc);
static int debug = 0;
static int monitor = 0;
static int quiet = 0;
static int boost = 0;
static int opermode = 0;
static struct fxo_mode {
char *name;
int ohs;
int act;
int dct;
int rz;
int rt;
int lim;
int vol;
} fxo_modes[] =
{
{ "FCC", 0, 0, 2, 0, 0, 0, 0 }, /* US */
{ "CTR21", 0, 0, 3, 0, 0, 3, 0 }, /* Austria, Belgium, Denmark, Finland, France, Germany,
Greece, Iceland, Ireland, Italy, Luxembourg, Netherlands,
Norway, Portugal, Spain, Sweden, Switzerland, and UK */
};
static inline void wcfxo_transmitprep(struct wcfxo *wc, unsigned char ints)
{
volatile int *writechunk;
int x;
int written=0;
unsigned short cmd;
/* if nothing to transmit, have to do the dahdi_transmit() anyway */
if (!(ints & 3)) {
/* Calculate Transmission */
dahdi_transmit(&wc->span);
return;
}
/* Remember what it was we just sent */
memcpy(wc->lasttx, wc->chan->writechunk, DAHDI_CHUNKSIZE);
if (ints & 0x01) {
/* Write is at interrupt address. Start writing from normal offset */
writechunk = wc->writechunk;
} else {
writechunk = wc->writechunk + DAHDI_CHUNKSIZE * 2;
}
dahdi_transmit(&wc->span);
for (x=0;x<DAHDI_CHUNKSIZE;x++) {
/* Send a sample, as a 32-bit word, and be sure to indicate that a command follows */
if (wc->flags & FLAG_INVERTSER)
writechunk[x << 1] = cpu_to_le32(
~((unsigned short)(DAHDI_XLAW(wc->chan->writechunk[x], wc->chan))| 0x1) << 16
);
else
writechunk[x << 1] = cpu_to_le32(
((unsigned short)(DAHDI_XLAW(wc->chan->writechunk[x], wc->chan))| 0x1) << 16
);
/* We always have a command to follow our signal */
if (!wc->regs[x].flags) {
/* Fill in an empty register command with a read for a potentially useful register */
wc->regs[x].flags = FLAG_READ;
wc->regs[x].reg = wecareregs[wc->readpos];
wc->regs[x].index = wc->readpos;
wc->readpos++;
if (wc->readpos >= (sizeof(wecareregs) / sizeof(wecareregs[0]))) {
wc->allread = 1;
wc->readpos = 0;
}
}
/* Prepare the command to follow it */
switch(wc->regs[x].flags) {
case FLAG_READ:
cmd = (wc->regs[x].reg | 0x20) << 8;
break;
case FLAG_WRITE:
cmd = (wc->regs[x].reg << 8) | (wc->regs[x].value & 0xff);
written = 1;
/* Wait at least four samples before reading */
wc->ignoreread = 4;
break;
default:
printk(KERN_DEBUG "wcfxo: Huh? No read or write??\n");
cmd = 0;
}
/* Setup the write chunk */
if (wc->flags & FLAG_INVERTSER)
writechunk[(x << 1) + 1] = cpu_to_le32(~(cmd << 16));
else
writechunk[(x << 1) + 1] = cpu_to_le32(cmd << 16);
}
if (written)
wc->readpos = 0;
wc->wregcount = 0;
for (x=0;x<DAHDI_CHUNKSIZE;x++) {
/* Rotate through registers */
wc->oldregs[x] = wc->regs[x];
wc->regs[x].flags = FLAG_EMPTY;
}
}
static inline void wcfxo_receiveprep(struct wcfxo *wc, unsigned char ints)
{
volatile int *readchunk;
int x;
int realreg;
int realval;
int sample;
if (ints & 0x04)
/* Read is at interrupt address. Valid data is available at normal offset */
readchunk = wc->readchunk;
else
readchunk = wc->readchunk + DAHDI_CHUNKSIZE * 2;
/* Keep track of how quickly our peg alternates */
wc->pegtimer+=DAHDI_CHUNKSIZE;
for (x=0;x<DAHDI_CHUNKSIZE;x++) {
/* We always have a command to follow our signal. */
if (wc->oldregs[x].flags == FLAG_READ && !wc->ignoreread) {
realreg = wecareregs[(wc->regs[x].index + wc->regoffset) %
(sizeof(wecareregs) / sizeof(wecareregs[0]))];
realval = (le32_to_cpu(readchunk[(x << 1) +wc->alt]) >> 16) & 0xff;
if ((realval == 0x89) && (realreg != WC_DAA_PLL2_N2_M2)) {
/* Some sort of slippage, correct for it */
while(realreg != WC_DAA_PLL2_N2_M2) {
/* Find register 9 */
realreg = wecareregs[(wc->regs[x].index + ++wc->regoffset) %
(sizeof(wecareregs) / sizeof(wecareregs[0]))];
wc->regoffset = wc->regoffset % (sizeof(wecareregs) / sizeof(wecareregs[0]));
}
if (debug)
printk(KERN_DEBUG "New regoffset: %d\n", wc->regoffset);
}
/* Receive into the proper register */
wc->readregs[realreg] = realval;
}
/* Look for pegging to indicate ringing */
sample = (short)(le32_to_cpu(readchunk[(x << 1) + (1 - wc->alt)]) >> 16);
if ((sample > 32000) && (wc->peg != 1)) {
if ((wc->pegtimer < PEGTIME) && (wc->pegtimer > MINPEGTIME))
wc->pegcount++;
wc->pegtimer = 0;
wc->peg = 1;
} else if ((sample < -32000) && (wc->peg != -1)) {
if ((wc->pegtimer < PEGTIME) && (wc->pegtimer > MINPEGTIME))
wc->pegcount++;
wc->pegtimer = 0;
wc->peg = -1;
}
wc->chan->readchunk[x] = DAHDI_LIN2X((sample), (wc->chan));
}
if (wc->pegtimer > PEGTIME) {
/* Reset pegcount if our timer expires */
wc->pegcount = 0;
}
/* Decrement debouncer if appropriate */
if (wc->ringdebounce)
wc->ringdebounce--;
if (!wc->offhook && !wc->ringdebounce) {
if (!wc->ring && (wc->pegcount > PEGCOUNT)) {
/* It's ringing */
if (debug)
printk(KERN_DEBUG "RING!\n");
dahdi_hooksig(wc->chan, DAHDI_RXSIG_RING);
wc->ring = 1;
}
if (wc->ring && !wc->pegcount) {
/* No more ring */
if (debug)
printk(KERN_DEBUG "NO RING!\n");
dahdi_hooksig(wc->chan, DAHDI_RXSIG_OFFHOOK);
wc->ring = 0;
}
}
if (wc->ignoreread)
wc->ignoreread--;
/* Do the echo cancellation... We are echo cancelling against
what we sent two chunks ago*/
dahdi_ec_chunk(wc->chan, wc->chan->readchunk, wc->lasttx);
/* Receive the result */
dahdi_receive(&wc->span);
}
#ifdef ENABLE_TASKLETS
static void wcfxo_tasklet(unsigned long data)
{
struct wcfxo *wc = (struct wcfxo *)data;
wc->taskletrun++;
/* Run tasklet */
if (wc->taskletpending) {
wc->taskletexec++;
wcfxo_receiveprep(wc, wc->ints);
wcfxo_transmitprep(wc, wc->ints);
}
wc->taskletpending = 0;
}
#endif
static void wcfxo_stop_dma(struct wcfxo *wc);
static void wcfxo_restart_dma(struct wcfxo *wc);
DAHDI_IRQ_HANDLER(wcfxo_interrupt)
{
struct wcfxo *wc = dev_id;
unsigned char ints;
unsigned char b;
#ifdef DEBUG_RING
static int oldb = 0;
static int oldcnt = 0;
#endif
ints = inb(wc->ioaddr + WC_INTSTAT);
if (!ints)
return IRQ_NONE;
outb(ints, wc->ioaddr + WC_INTSTAT);
if (ints & 0x0c) { /* if there is a rx interrupt pending */
#ifdef ENABLE_TASKLETS
wc->ints = ints;
if (!wc->taskletpending) {
wc->taskletpending = 1;
wc->taskletsched++;
tasklet_hi_schedule(&wc->wcfxo_tlet);
} else
wc->txerrors++;
#else
wcfxo_receiveprep(wc, ints);
/* transmitprep looks to see if there is anything to transmit
and returns by itself if there is nothing */
wcfxo_transmitprep(wc, ints);
#endif
}
if (ints & 0x10) {
printk(KERN_INFO "FXO PCI Master abort\n");
/* Stop DMA andlet the watchdog start it again */
wcfxo_stop_dma(wc);
return IRQ_RETVAL(1);
}
if (ints & 0x20) {
printk(KERN_INFO "PCI Target abort\n");
return IRQ_RETVAL(1);
}
if (1 /* !(wc->report % 0xf) */) {
/* Check for BATTERY from register and debounce for 8 ms */
b = wc->readregs[WC_DAA_LINE_STAT] & 0xf;
if (!b) {
wc->nobatttimer++;
#if 0
if (wc->battery)
printk(KERN_DEBUG "Battery loss: %d (%d debounce)\n", b, wc->battdebounce);
#endif
if (wc->battery && !wc->battdebounce) {
if (debug)
printk(KERN_DEBUG "NO BATTERY!\n");
wc->battery = 0;
#ifdef JAPAN
if ((!wc->ohdebounce) && wc->offhook) {
dahdi_hooksig(wc->chan, DAHDI_RXSIG_ONHOOK);
if (debug)
printk(KERN_DEBUG "Signalled On Hook\n");
#ifdef ZERO_BATT_RING
wc->onhook++;
#endif
}
#else
dahdi_hooksig(wc->chan, DAHDI_RXSIG_ONHOOK);
#endif
wc->battdebounce = BATT_DEBOUNCE;
} else if (!wc->battery)
wc->battdebounce = BATT_DEBOUNCE;
if ((wc->nobatttimer > 5000) &&
#ifdef ZERO_BATT_RING
!(wc->readregs[WC_DAA_DCTL1] & 0x04) &&
#endif
(!wc->span.alarms)) {
wc->span.alarms = DAHDI_ALARM_RED;
dahdi_alarm_notify(&wc->span);
}
} else if (b == 0xf) {
if (!wc->battery && !wc->battdebounce) {
if (debug)
printk(KERN_DEBUG "BATTERY!\n");
#ifdef ZERO_BATT_RING
if (wc->onhook) {
wc->onhook = 0;
dahdi_hooksig(wc->chan, DAHDI_RXSIG_OFFHOOK);
if (debug)
printk(KERN_DEBUG "Signalled Off Hook\n");
}
#else
dahdi_hooksig(wc->chan, DAHDI_RXSIG_OFFHOOK);
#endif
wc->battery = 1;
wc->nobatttimer = 0;
wc->battdebounce = BATT_DEBOUNCE;
if (wc->span.alarms) {
wc->span.alarms = 0;
dahdi_alarm_notify(&wc->span);
}
} else if (wc->battery)
wc->battdebounce = BATT_DEBOUNCE;
} else {
/* It's something else... */
wc->battdebounce = BATT_DEBOUNCE;
}
if (wc->battdebounce)
wc->battdebounce--;
#ifdef JAPAN
if (wc->ohdebounce)
wc->ohdebounce--;
#endif
}
return IRQ_RETVAL(1);
}
static int wcfxo_setreg(struct wcfxo *wc, unsigned char reg, unsigned char value)
{
int x;
if (wc->wregcount < DAHDI_CHUNKSIZE) {
x = wc->wregcount;
wc->regs[x].reg = reg;
wc->regs[x].value = value;
wc->regs[x].flags = FLAG_WRITE;
wc->wregcount++;
return 0;
}
printk(KERN_NOTICE "wcfxo: Out of space to write register %02x with %02x\n", reg, value);
return -1;
}
static inline struct wcfxo *wcfxo_from_span(struct dahdi_span *span)
{
return container_of(span, struct wcfxo, span);
}
static int _wcfxo_open(struct dahdi_chan *chan)
{
struct wcfxo *wc = chan->pvt;
if (wc->dead)
return -ENODEV;
wc->usecount++;
return 0;
}
static int wcfxo_open(struct dahdi_chan *chan)
{
int res;
unsigned long flags;
spin_lock_irqsave(&chan->lock, flags);
res = _wcfxo_open(chan);
spin_unlock_irqrestore(&chan->lock, flags);
return res;
}
static int wcfxo_watchdog(struct dahdi_span *span, int event)
{
printk(KERN_INFO "FXO: Restarting DMA\n");
wcfxo_restart_dma(wcfxo_from_span(span));
return 0;
}
static int wcfxo_close(struct dahdi_chan *chan)
{
struct wcfxo *wc = chan->pvt;
wc->usecount--;
/* If we're dead, release us now */
if (!wc->usecount && wc->dead)
wcfxo_release(wc);
return 0;
}
static int wcfxo_hooksig(struct dahdi_chan *chan, enum dahdi_txsig txsig)
{
struct wcfxo *wc = chan->pvt;
int reg=0;
switch(txsig) {
case DAHDI_TXSIG_START:
case DAHDI_TXSIG_OFFHOOK:
/* Take off hook and enable normal mode reception. This must
be done in two steps because of a hardware bug. */
reg = wc->readregs[WC_DAA_DCTL1] & ~0x08;
wcfxo_setreg(wc, WC_DAA_DCTL1, reg);
reg = reg | 0x1;
wcfxo_setreg(wc, WC_DAA_DCTL1, reg);
wc->offhook = 1;
#ifdef JAPAN
wc->battery = 1;
wc->battdebounce = BATT_DEBOUNCE;
wc->ohdebounce = OH_DEBOUNCE;
#endif
break;
case DAHDI_TXSIG_ONHOOK:
/* Put on hook and enable on hook line monitor */
reg = wc->readregs[WC_DAA_DCTL1] & 0xfe;
wcfxo_setreg(wc, WC_DAA_DCTL1, reg);
reg = reg | 0x08;
wcfxo_setreg(wc, WC_DAA_DCTL1, reg);
wc->offhook = 0;
/* Don't accept a ring for another 1000 ms */
wc->ringdebounce = 1000;
#ifdef JAPAN
wc->ohdebounce = OH_DEBOUNCE;
#endif
break;
default:
printk(KERN_NOTICE "wcfxo: Can't set tx state to %d\n", txsig);
}
if (debug)
printk(KERN_DEBUG "Setting hook state to %d (%02x)\n", txsig, reg);
return 0;
}
static const struct dahdi_span_ops wcfxo_span_ops = {
.owner = THIS_MODULE,
.hooksig = wcfxo_hooksig,
.open = wcfxo_open,
.close = wcfxo_close,
.watchdog = wcfxo_watchdog,
};
static int wcfxo_initialize(struct wcfxo *wc)
{
wc->ddev = dahdi_create_device();
/* DAHDI stuff */
sprintf(wc->span.name, "WCFXO/%d", wc->pos);
snprintf(wc->span.desc, sizeof(wc->span.desc) - 1, "%s Board %d", wc->variety, wc->pos + 1);
sprintf(wc->chan->name, "WCFXO/%d/%d", wc->pos, 0);
wc->ddev->location = kasprintf(GFP_KERNEL, "PCI Bus %02d Slot %02d",
wc->dev->bus->number,
PCI_SLOT(wc->dev->devfn) + 1);
if (!wc->ddev->location)
return -ENOMEM;
wc->ddev->manufacturer = "Digium";
wc->ddev->devicetype = wc->variety;
wc->chan->sigcap = DAHDI_SIG_FXSKS | DAHDI_SIG_FXSLS | DAHDI_SIG_SF;
wc->chan->chanpos = 1;
wc->span.chans = &wc->chan;
wc->span.channels = 1;
wc->span.flags = DAHDI_FLAG_RBS;
wc->span.deflaw = DAHDI_LAW_MULAW;
#ifdef ENABLE_TASKLETS
tasklet_init(&wc->wcfxo_tlet, wcfxo_tasklet, (unsigned long)wc);
#endif
wc->chan->pvt = wc;
wc->span.ops = &wcfxo_span_ops;
list_add_tail(&wc->span.device_node, &wc->ddev->spans);
if (dahdi_register_device(wc->ddev, &wc->dev->dev)) {
printk(KERN_NOTICE "Unable to register span with DAHDI\n");
return -1;
}
return 0;
}
static int wcfxo_hardware_init(struct wcfxo *wc)
{
/* Hardware stuff */
/* Reset PCI Interface chip and registers */
outb(0x0e, wc->ioaddr + WC_CNTL);
/* Set all to outputs except AUX 4, which is an input */
outb(0xef, wc->ioaddr + WC_AUXC);
/* Reset the DAA (DAA uses AUX5 for reset) */
outb(0x00, wc->ioaddr + WC_AUXD);
set_current_state(TASK_INTERRUPTIBLE);
schedule_timeout(1 + HZ / 800);
/* Set hook state to on hook & un-reset the DAA */
if (wc->flags & FLAG_RESET_ON_AUX5) {
/* Set hook state to on hook for when we switch.
Make sure reset is high */
outb(0x34, wc->ioaddr + WC_AUXD);
} else {
/* Set hook state to on hook for when we switch */
outb(0x24, wc->ioaddr + WC_AUXD);
}
/* Back to normal, with automatic DMA wrap around */
outb(0x01, wc->ioaddr + WC_CNTL);
/* Make sure serial port and DMA are out of reset */
outb(inb(wc->ioaddr + WC_CNTL) & 0xf9, wc->ioaddr + WC_CNTL);
/* Configure serial port for MSB->LSB operation */
if (wc->flags & FLAG_DOUBLE_CLOCK)
outb(0xc1, wc->ioaddr + WC_SERCTL);
else
outb(0xc0, wc->ioaddr + WC_SERCTL);
if (wc->flags & FLAG_USE_XTAL) {
/* Use the crystal oscillator */
outb(0x04, wc->ioaddr + WC_AUXFUNC);
}
/* Delay FSC by 2 so it's properly aligned */
outb(0x2, wc->ioaddr + WC_FSCDELAY);
/* Setup DMA Addresses */
outl(wc->writedma, wc->ioaddr + WC_DMAWS); /* Write start */
outl(wc->writedma + DAHDI_CHUNKSIZE * 8 - 4, wc->ioaddr + WC_DMAWI); /* Middle (interrupt) */
outl(wc->writedma + DAHDI_CHUNKSIZE * 16 - 4, wc->ioaddr + WC_DMAWE); /* End */
outl(wc->readdma, wc->ioaddr + WC_DMARS); /* Read start */
outl(wc->readdma + DAHDI_CHUNKSIZE * 8 - 4, wc->ioaddr + WC_DMARI); /* Middle (interrupt) */
outl(wc->readdma + DAHDI_CHUNKSIZE * 16 - 4, wc->ioaddr + WC_DMARE); /* End */
/* Clear interrupts */
outb(0xff, wc->ioaddr + WC_INTSTAT);
return 0;
}
static void wcfxo_enable_interrupts(struct wcfxo *wc)
{
/* Enable interrupts (we care about all of them) */
outb(0x3f, wc->ioaddr + WC_MASK0);
/* No external interrupts */
outb(0x00, wc->ioaddr + WC_MASK1);
}
static void wcfxo_start_dma(struct wcfxo *wc)
{
/* Reset Master and TDM */
outb(0x0f, wc->ioaddr + WC_CNTL);
set_current_state(TASK_INTERRUPTIBLE);
schedule_timeout(1);
outb(0x01, wc->ioaddr + WC_CNTL);
outb(0x01, wc->ioaddr + WC_OPER);
}
static void wcfxo_restart_dma(struct wcfxo *wc)
{
/* Reset Master and TDM */
outb(0x01, wc->ioaddr + WC_CNTL);
outb(0x01, wc->ioaddr + WC_OPER);
}
static void wcfxo_stop_dma(struct wcfxo *wc)
{
outb(0x00, wc->ioaddr + WC_OPER);
}
static void wcfxo_reset_tdm(struct wcfxo *wc)
{
/* Reset TDM */
outb(0x0f, wc->ioaddr + WC_CNTL);
}
static void wcfxo_disable_interrupts(struct wcfxo *wc)
{
outb(0x00, wc->ioaddr + WC_MASK0);
outb(0x00, wc->ioaddr + WC_MASK1);
}
static void wcfxo_set_daa_mode(struct wcfxo *wc)
{
/* Set country specific parameters (OHS, ACT, DCT, RZ, RT, LIM, VOL) */
int reg16 = ((fxo_modes[opermode].ohs & 0x1) << 6) |
((fxo_modes[opermode].act & 0x1) << 5) |
((fxo_modes[opermode].dct & 0x3) << 2) |
((fxo_modes[opermode].rz & 0x1) << 1) |
((fxo_modes[opermode].rt & 0x1) << 0);
int reg17 = ((fxo_modes[opermode].lim & 0x3) << 3);
int reg18 = ((fxo_modes[opermode].vol & 0x3) << 3);
if (wc->flags & FLAG_NO_I18N_REGS) {
wcfxo_dbg(wc->span, "This card does not support international settings.\n");
return;
}
wcfxo_setreg(wc, WC_DAA_INT_CTL1, reg16);
wcfxo_setreg(wc, WC_DAA_INT_CTL2, reg17);
wcfxo_setreg(wc, WC_DAA_INT_CTL3, reg18);
/* Wait a couple of jiffies for our writes to finish */
set_current_state(TASK_INTERRUPTIBLE);
schedule_timeout(1 + (DAHDI_CHUNKSIZE * HZ) / 800);
printk(KERN_INFO "wcfxo: DAA mode is '%s'\n", fxo_modes[opermode].name);
}
static int wcfxo_init_daa(struct wcfxo *wc)
{
/* This must not be called in an interrupt */
/* We let things settle for a bit */
unsigned char reg15;
int chip_revb;
// set_current_state(TASK_INTERRUPTIBLE);
// schedule_timeout(10);
/* Soft-reset it */
wcfxo_setreg(wc, WC_DAA_CTL1, 0x80);
/* Let the reset go */
set_current_state(TASK_UNINTERRUPTIBLE);
schedule_timeout(1 + (DAHDI_CHUNKSIZE * HZ) / 800);
/* We have a clock at 18.432 Mhz, so N1=1, M1=2, CGM=0 */
wcfxo_setreg(wc, WC_DAA_PLL1_N1, 0x0); /* This value is N1 - 1 */
wcfxo_setreg(wc, WC_DAA_PLL1_M1, 0x1); /* This value is M1 - 1 */
/* We want to sample at 8khz, so N2 = 9, M2 = 10 (N2-1, M2-1) */
wcfxo_setreg(wc, WC_DAA_PLL2_N2_M2, 0x89);
/* Wait until the PLL's are locked. Time is between 100 uSec and 1 mSec */
set_current_state(TASK_INTERRUPTIBLE);
schedule_timeout(1 + HZ/1000 + (DAHDI_CHUNKSIZE * HZ) / 800);
/* No additional ration is applied to the PLL and faster lock times
* are possible */
wcfxo_setreg(wc, WC_DAA_PLL_CTL, 0x0);
/* Enable off hook pin */
wcfxo_setreg(wc, WC_DAA_DCTL1, 0x0a);
if (monitor) {
/* Enable ISOcap and external speaker and charge pump if present */
wcfxo_setreg(wc, WC_DAA_DCTL2, 0x80);
} else {
/* Enable ISOcap and charge pump if present (leave speaker disabled) */
wcfxo_setreg(wc, WC_DAA_DCTL2, 0xe0);
}
/* Wait a couple of jiffies for our writes to finish */
set_current_state(TASK_INTERRUPTIBLE);
schedule_timeout(1 + (DAHDI_CHUNKSIZE * HZ) / 800);
reg15 = 0x0;
/* Go ahead and attenuate transmit signal by 6 db */
if (quiet) {
printk(KERN_INFO "wcfxo: Attenuating transmit signal for quiet operation\n");
reg15 |= (quiet & 0x3) << 4;
}
if (boost) {
printk(KERN_INFO "wcfxo: Boosting receive signal\n");
reg15 |= (boost & 0x3);
}
wcfxo_setreg(wc, WC_DAA_TXRX_GCTL, reg15);
/* REVB: reg. 13, bits 5:2 */
chip_revb = (wc->readregs[WC_DAA_CHIPB_REV] >> 2) & 0xF;
wcfxo_dbg(wc->span, "DAA chip REVB is %x\n", chip_revb);
switch(chip_revb) {
case 1: case 2: case 3:
/* This is a si3034. Nothing to do */
break;
case 4: case 5: case 7:
/* This is 3035. Has no support for international registers */
wc->flags |= FLAG_NO_I18N_REGS;
break;
default:
wcfxo_notice(wc->span, "Unknown DAA chip revision: REVB=%d\n",
chip_revb);
}
/* Didn't get it right. Register 9 is still garbage */
if (wc->readregs[WC_DAA_PLL2_N2_M2] != 0x89)
return -1;
#if 0
{ int x;
int y;
for (y=0;y<100;y++) {
printk(KERN_DEBUG " reg dump ====== %d ======\n", y);
for (x=0;x<sizeof(wecareregs) / sizeof(wecareregs[0]);x++) {
printk(KERN_DEBUG "daa: Reg %d: %02x\n", wecareregs[x], wc->readregs[wecareregs[x]]);
}
set_current_state(TASK_INTERRUPTIBLE);
schedule_timeout(100);
} }
#endif
return 0;
}
static int __devinit wcfxo_init_one(struct pci_dev *pdev, const struct pci_device_id *ent)
{
struct wcfxo *wc;
struct wcfxo_desc *d = (struct wcfxo_desc *)ent->driver_data;
int x;
for (x=0;x<WC_MAX_IFACES;x++)
if (!ifaces[x]) break;
if (x >= WC_MAX_IFACES) {
printk(KERN_ERR "Too many interfaces: Found %d, can only handle %d.\n",
x, WC_MAX_IFACES - 1);
return -EIO;
}
if (pci_enable_device(pdev))
return -EIO;
wc = kmalloc(sizeof(struct wcfxo), GFP_KERNEL);
if (!wc) {
printk(KERN_ERR "wcfxo: Failed initializinf card. Not enough memory.");
return -ENOMEM;
}
ifaces[x] = wc;
memset(wc, 0, sizeof(struct wcfxo));
wc->chan = &wc->_chan;
wc->ioaddr = pci_resource_start(pdev, 0);
wc->dev = pdev;
wc->pos = x;
wc->variety = d->name;
wc->flags = d->flags;
/* Keep track of whether we need to free the region */
if (request_region(wc->ioaddr, 0xff, "wcfxo"))
wc->freeregion = 1;
/* Allocate enough memory for two zt chunks, receive and transmit. Each sample uses
32 bits. Allocate an extra set just for control too */
wc->writechunk = (int *)pci_alloc_consistent(pdev, DAHDI_MAX_CHUNKSIZE * 2 * 2 * 2 * 4, &wc->writedma);
if (!wc->writechunk) {
printk(KERN_NOTICE "wcfxo: Unable to allocate DMA-able memory\n");
if (wc->freeregion)
release_region(wc->ioaddr, 0xff);
return -ENOMEM;
}
wc->readchunk = wc->writechunk + DAHDI_MAX_CHUNKSIZE * 4; /* in doublewords */
wc->readdma = wc->writedma + DAHDI_MAX_CHUNKSIZE * 16; /* in bytes */
if (wcfxo_initialize(wc)) {
printk(KERN_NOTICE "wcfxo: Unable to intialize modem\n");
if (wc->freeregion)
release_region(wc->ioaddr, 0xff);
kfree(wc);
return -EIO;
}
/* Enable bus mastering */
pci_set_master(pdev);
/* Keep track of which device we are */
pci_set_drvdata(pdev, wc);
if (request_irq(pdev->irq, wcfxo_interrupt, IRQF_SHARED, "wcfxo", wc)) {
printk(KERN_NOTICE "wcfxo: Unable to request IRQ %d\n", pdev->irq);
if (wc->freeregion)
release_region(wc->ioaddr, 0xff);
kfree(wc);
return -EIO;
}
wcfxo_hardware_init(wc);
/* Enable interrupts */
wcfxo_enable_interrupts(wc);
/* Initialize Write/Buffers to all blank data */
memset((void *)wc->writechunk,0,DAHDI_MAX_CHUNKSIZE * 2 * 2 * 2 * 4);
/* Start DMA */
wcfxo_start_dma(wc);
/* Initialize DAA (after it's started) */
if (wcfxo_init_daa(wc)) {
printk(KERN_NOTICE "Failed to initailize DAA, giving up...\n");
wcfxo_stop_dma(wc);
wcfxo_disable_interrupts(wc);
dahdi_unregister_device(wc->ddev);
free_irq(pdev->irq, wc);
/* Reset PCI chip and registers */
outb(0x0e, wc->ioaddr + WC_CNTL);
if (wc->freeregion)
release_region(wc->ioaddr, 0xff);
kfree(wc->ddev->location);
dahdi_free_device(wc->ddev);
kfree(wc);
return -EIO;
}
wcfxo_set_daa_mode(wc);
printk(KERN_INFO "Found a Wildcard FXO: %s\n", wc->variety);
return 0;
}
static void wcfxo_release(struct wcfxo *wc)
{
dahdi_unregister_device(wc->ddev);
if (wc->freeregion)
release_region(wc->ioaddr, 0xff);
kfree(wc->ddev->location);
dahdi_free_device(wc->ddev);
kfree(wc);
printk(KERN_INFO "Freed a Wildcard\n");
}
static void __devexit wcfxo_remove_one(struct pci_dev *pdev)
{
struct wcfxo *wc = pci_get_drvdata(pdev);
if (wc) {
/* Stop any DMA */
wcfxo_stop_dma(wc);
wcfxo_reset_tdm(wc);
/* In case hardware is still there */
wcfxo_disable_interrupts(wc);
/* Immediately free resources */
pci_free_consistent(pdev, DAHDI_MAX_CHUNKSIZE * 2 * 2 * 2 * 4, (void *)wc->writechunk, wc->writedma);
free_irq(pdev->irq, wc);
/* Reset PCI chip and registers */
outb(0x0e, wc->ioaddr + WC_CNTL);
/* Release span, possibly delayed */
if (!wc->usecount)
wcfxo_release(wc);
else
wc->dead = 1;
}
}
static DEFINE_PCI_DEVICE_TABLE(wcfxo_pci_tbl) = {
{ 0xe159, 0x0001, 0x8084, PCI_ANY_ID, 0, 0, (unsigned long) &generic },
{ 0xe159, 0x0001, 0x8085, PCI_ANY_ID, 0, 0, (unsigned long) &wcx101p },
{ 0xe159, 0x0001, 0x8086, PCI_ANY_ID, 0, 0, (unsigned long) &generic },
{ 0xe159, 0x0001, 0x8087, PCI_ANY_ID, 0, 0, (unsigned long) &generic },
{ 0x1057, 0x5608, PCI_ANY_ID, PCI_ANY_ID, 0, 0, (unsigned long) &wcx100p },
{ 0 }
};
MODULE_DEVICE_TABLE (pci, wcfxo_pci_tbl);
static struct pci_driver wcfxo_driver = {
.name = "wcfxo",
.probe = wcfxo_init_one,
.remove = __devexit_p(wcfxo_remove_one),
.id_table = wcfxo_pci_tbl,
};
static int __init wcfxo_init(void)
{
int res;
int x;
if ((opermode >= sizeof(fxo_modes) / sizeof(fxo_modes[0])) || (opermode < 0)) {
printk(KERN_NOTICE "Invalid/unknown operating mode specified. Please choose one of:\n");
for (x=0;x<sizeof(fxo_modes) / sizeof(fxo_modes[0]); x++)
printk(KERN_INFO "%d: %s\n", x, fxo_modes[x].name);
return -ENODEV;
}
res = dahdi_pci_module(&wcfxo_driver);
if (res)
return -ENODEV;
return 0;
}
static void __exit wcfxo_cleanup(void)
{
pci_unregister_driver(&wcfxo_driver);
}
module_param(debug, int, 0644);
module_param(quiet, int, 0444);
module_param(boost, int, 0444);
module_param(monitor, int, 0444);
module_param(opermode, int, 0444);
MODULE_DESCRIPTION("Wildcard X100P Driver");
MODULE_AUTHOR("Mark Spencer <markster@digium.com>");
MODULE_LICENSE("GPL v2");
module_init(wcfxo_init);
module_exit(wcfxo_cleanup);