/*
 * Stuff used by all variants of the driver
 *
 * Copyright (c) 2001 by Stefan Eilers,
 *                       Hansjoerg Lipp <hjlipp@web.de>,
 *                       Tilman Schmidt <tilman@imap.cc>.
 *
 * =====================================================================
 *	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.
 * =====================================================================
 */

#include "gigaset.h"

/* ========================================================== */
/* bit masks for pending commands */
#define PC_DIAL		0x001
#define PC_HUP		0x002
#define PC_INIT		0x004
#define PC_DLE0		0x008
#define PC_DLE1		0x010
#define PC_SHUTDOWN	0x020
#define PC_ACCEPT	0x040
#define PC_CID		0x080
#define PC_NOCID	0x100
#define PC_CIDMODE	0x200
#define PC_UMMODE	0x400

/* types of modem responses */
#define RT_NOTHING	0
#define RT_ZSAU		1
#define RT_RING		2
#define RT_NUMBER	3
#define RT_STRING	4
#define RT_ZCAU		6

/* Possible ASCII responses */
#define RSP_OK		0
#define RSP_ERROR	1
#define RSP_ZGCI	3
#define RSP_RING	4
#define RSP_ZVLS	5
#define RSP_ZCAU	6

/* responses with values to store in at_state */
/* - numeric */
#define RSP_VAR		100
#define RSP_ZSAU	(RSP_VAR + VAR_ZSAU)
#define RSP_ZDLE	(RSP_VAR + VAR_ZDLE)
#define RSP_ZCTP	(RSP_VAR + VAR_ZCTP)
/* - string */
#define RSP_STR		(RSP_VAR + VAR_NUM)
#define RSP_NMBR	(RSP_STR + STR_NMBR)
#define RSP_ZCPN	(RSP_STR + STR_ZCPN)
#define RSP_ZCON	(RSP_STR + STR_ZCON)
#define RSP_ZBC		(RSP_STR + STR_ZBC)
#define RSP_ZHLC	(RSP_STR + STR_ZHLC)

#define RSP_WRONG_CID	-2	/* unknown cid in cmd */
#define RSP_INVAL	-6	/* invalid response   */
#define RSP_NODEV	-9	/* device not connected */

#define RSP_NONE	-19
#define RSP_STRING	-20
#define RSP_NULL	-21
#define RSP_INIT	-27
#define RSP_ANY		-26
#define RSP_LAST	-28

/* actions for process_response */
#define ACT_NOTHING		0
#define ACT_SETDLE1		1
#define ACT_SETDLE0		2
#define ACT_FAILINIT		3
#define ACT_HUPMODEM		4
#define ACT_CONFIGMODE		5
#define ACT_INIT		6
#define ACT_DLE0		7
#define ACT_DLE1		8
#define ACT_FAILDLE0		9
#define ACT_FAILDLE1		10
#define ACT_RING		11
#define ACT_CID			12
#define ACT_FAILCID		13
#define ACT_SDOWN		14
#define ACT_FAILSDOWN		15
#define ACT_DEBUG		16
#define ACT_WARN		17
#define ACT_DIALING		18
#define ACT_ABORTDIAL		19
#define ACT_DISCONNECT		20
#define ACT_CONNECT		21
#define ACT_REMOTEREJECT	22
#define ACT_CONNTIMEOUT		23
#define ACT_REMOTEHUP		24
#define ACT_ABORTHUP		25
#define ACT_ICALL		26
#define ACT_ACCEPTED		27
#define ACT_ABORTACCEPT		28
#define ACT_TIMEOUT		29
#define ACT_GETSTRING		30
#define ACT_SETVER		31
#define ACT_FAILVER		32
#define ACT_GOTVER		33
#define ACT_TEST		34
#define ACT_ERROR		35
#define ACT_ABORTCID		36
#define ACT_ZCAU		37
#define ACT_NOTIFY_BC_DOWN	38
#define ACT_NOTIFY_BC_UP	39
#define ACT_DIAL		40
#define ACT_ACCEPT		41
#define ACT_HUP			43
#define ACT_IF_LOCK		44
#define ACT_START		45
#define ACT_STOP		46
#define ACT_FAKEDLE0		47
#define ACT_FAKEHUP		48
#define ACT_FAKESDOWN		49
#define ACT_SHUTDOWN		50
#define ACT_PROC_CIDMODE	51
#define ACT_UMODESET		52
#define ACT_FAILUMODE		53
#define ACT_CMODESET		54
#define ACT_FAILCMODE		55
#define ACT_IF_VER		56
#define ACT_CMD			100

/* at command sequences */
#define SEQ_NONE	0
#define SEQ_INIT	100
#define SEQ_DLE0	200
#define SEQ_DLE1	250
#define SEQ_CID		300
#define SEQ_NOCID	350
#define SEQ_HUP		400
#define SEQ_DIAL	600
#define SEQ_ACCEPT	720
#define SEQ_SHUTDOWN	500
#define SEQ_CIDMODE	10
#define SEQ_UMMODE	11


/* 100: init, 200: dle0, 250:dle1, 300: get cid (dial), 350: "hup" (no cid),
 * 400: hup, 500: reset, 600: dial, 700: ring */
struct reply_t gigaset_tab_nocid[] =
{
/* resp_code, min_ConState, max_ConState, parameter, new_ConState, timeout,
 * action, command */

/* initialize device, set cid mode if possible */
{RSP_INIT,	 -1,  -1, SEQ_INIT,		100,  1, {ACT_TIMEOUT} },

{EV_TIMEOUT,	100, 100, -1,			101,  3, {0},	"Z\r"},
{RSP_OK,	101, 103, -1,			120,  5, {ACT_GETSTRING},
								"+GMR\r"},

{EV_TIMEOUT,	101, 101, -1,			102,  5, {0},	"Z\r"},
{RSP_ERROR,	101, 101, -1,			102,  5, {0},	"Z\r"},

{EV_TIMEOUT,	102, 102, -1,			108,  5, {ACT_SETDLE1},
								"^SDLE=0\r"},
{RSP_OK,	108, 108, -1,			104, -1},
{RSP_ZDLE,	104, 104,  0,			103,  5, {0},	"Z\r"},
{EV_TIMEOUT,	104, 104, -1,			  0,  0, {ACT_FAILINIT} },
{RSP_ERROR,	108, 108, -1,			  0,  0, {ACT_FAILINIT} },

{EV_TIMEOUT,	108, 108, -1,			105,  2, {ACT_SETDLE0,
							  ACT_HUPMODEM,
							  ACT_TIMEOUT} },
{EV_TIMEOUT,	105, 105, -1,			103,  5, {0},	"Z\r"},

{RSP_ERROR,	102, 102, -1,			107,  5, {0},	"^GETPRE\r"},
{RSP_OK,	107, 107, -1,			  0,  0, {ACT_CONFIGMODE} },
{RSP_ERROR,	107, 107, -1,			  0,  0, {ACT_FAILINIT} },
{EV_TIMEOUT,	107, 107, -1,			  0,  0, {ACT_FAILINIT} },

{RSP_ERROR,	103, 103, -1,			  0,  0, {ACT_FAILINIT} },
{EV_TIMEOUT,	103, 103, -1,			  0,  0, {ACT_FAILINIT} },

{RSP_STRING,	120, 120, -1,			121, -1, {ACT_SETVER} },

{EV_TIMEOUT,	120, 121, -1,			  0,  0, {ACT_FAILVER,
							  ACT_INIT} },
{RSP_ERROR,	120, 121, -1,			  0,  0, {ACT_FAILVER,
							  ACT_INIT} },
{RSP_OK,	121, 121, -1,			  0,  0, {ACT_GOTVER,
							  ACT_INIT} },

/* leave dle mode */
{RSP_INIT,	  0,   0, SEQ_DLE0,		201,  5, {0},	"^SDLE=0\r"},
{RSP_OK,	201, 201, -1,			202, -1},
{RSP_ZDLE,	202, 202,  0,			  0,  0, {ACT_DLE0} },
{RSP_NODEV,	200, 249, -1,			  0,  0, {ACT_FAKEDLE0} },
{RSP_ERROR,	200, 249, -1,			  0,  0, {ACT_FAILDLE0} },
{EV_TIMEOUT,	200, 249, -1,			  0,  0, {ACT_FAILDLE0} },

/* enter dle mode */
{RSP_INIT,	  0,   0, SEQ_DLE1,		251,  5, {0},	"^SDLE=1\r"},
{RSP_OK,	251, 251, -1,			252, -1},
{RSP_ZDLE,	252, 252,  1,			  0,  0, {ACT_DLE1} },
{RSP_ERROR,	250, 299, -1,			  0,  0, {ACT_FAILDLE1} },
{EV_TIMEOUT,	250, 299, -1,			  0,  0, {ACT_FAILDLE1} },

/* incoming call */
{RSP_RING,	 -1,  -1, -1,			 -1, -1, {ACT_RING} },

/* get cid */
{RSP_INIT,	  0,   0, SEQ_CID,		301,  5, {0},	"^SGCI?\r"},
{RSP_OK,	301, 301, -1,			302, -1},
{RSP_ZGCI,	302, 302, -1,			  0,  0, {ACT_CID} },
{RSP_ERROR,	301, 349, -1,			  0,  0, {ACT_FAILCID} },
{EV_TIMEOUT,	301, 349, -1,			  0,  0, {ACT_FAILCID} },

/* enter cid mode */
{RSP_INIT,	  0,   0, SEQ_CIDMODE,		150,  5, {0},	"^SGCI=1\r"},
{RSP_OK,	150, 150, -1,			  0,  0, {ACT_CMODESET} },
{RSP_ERROR,	150, 150, -1,			  0,  0, {ACT_FAILCMODE} },
{EV_TIMEOUT,	150, 150, -1,			  0,  0, {ACT_FAILCMODE} },

/* leave cid mode */
{RSP_INIT,	  0,   0, SEQ_UMMODE,		160,  5, {0},	"Z\r"},
{RSP_OK,	160, 160, -1,			  0,  0, {ACT_UMODESET} },
{RSP_ERROR,	160, 160, -1,			  0,  0, {ACT_FAILUMODE} },
{EV_TIMEOUT,	160, 160, -1,			  0,  0, {ACT_FAILUMODE} },

/* abort getting cid */
{RSP_INIT,	  0,   0, SEQ_NOCID,		  0,  0, {ACT_ABORTCID} },

/* reset */
{RSP_INIT,	  0,   0, SEQ_SHUTDOWN,		504,  5, {0},	"Z\r"},
{RSP_OK,	504, 504, -1,			  0,  0, {ACT_SDOWN} },
{RSP_ERROR,	501, 599, -1,			  0,  0, {ACT_FAILSDOWN} },
{EV_TIMEOUT,	501, 599, -1,			  0,  0, {ACT_FAILSDOWN} },
{RSP_NODEV,	501, 599, -1,			  0,  0, {ACT_FAKESDOWN} },

{EV_PROC_CIDMODE, -1, -1, -1,			 -1, -1, {ACT_PROC_CIDMODE} },
{EV_IF_LOCK,	 -1,  -1, -1,			 -1, -1, {ACT_IF_LOCK} },
{EV_IF_VER,	 -1,  -1, -1,			 -1, -1, {ACT_IF_VER} },
{EV_START,	 -1,  -1, -1,			 -1, -1, {ACT_START} },
{EV_STOP,	 -1,  -1, -1,			 -1, -1, {ACT_STOP} },
{EV_SHUTDOWN,	 -1,  -1, -1,			 -1, -1, {ACT_SHUTDOWN} },

/* misc. */
{RSP_ERROR,	 -1,  -1, -1,			 -1, -1, {ACT_ERROR} },
{RSP_ZCAU,	 -1,  -1, -1,			 -1, -1, {ACT_ZCAU} },
{RSP_NONE,	 -1,  -1, -1,			 -1, -1, {ACT_DEBUG} },
{RSP_ANY,	 -1,  -1, -1,			 -1, -1, {ACT_WARN} },
{RSP_LAST}
};

/* 600: start dialing, 650: dial in progress, 800: connection is up, 700: ring,
 * 400: hup, 750: accepted icall */
struct reply_t gigaset_tab_cid[] =
{
/* resp_code, min_ConState, max_ConState, parameter, new_ConState, timeout,
 * action, command */

/* dial */
{EV_DIAL,	 -1,  -1, -1,			 -1, -1, {ACT_DIAL} },
{RSP_INIT,	  0,   0, SEQ_DIAL,		601,  5, {ACT_CMD+AT_BC} },
{RSP_OK,	601, 601, -1,			603,  5, {ACT_CMD+AT_PROTO} },
{RSP_OK,	603, 603, -1,			604,  5, {ACT_CMD+AT_TYPE} },
{RSP_OK,	604, 604, -1,			605,  5, {ACT_CMD+AT_MSN} },
{RSP_NULL,	605, 605, -1,			606,  5, {ACT_CMD+AT_CLIP} },
{RSP_OK,	605, 605, -1,			606,  5, {ACT_CMD+AT_CLIP} },
{RSP_NULL,	606, 606, -1,			607,  5, {ACT_CMD+AT_ISO} },
{RSP_OK,	606, 606, -1,			607,  5, {ACT_CMD+AT_ISO} },
{RSP_OK,	607, 607, -1,			608,  5, {0},	"+VLS=17\r"},
{RSP_OK,	608, 608, -1,			609, -1},
{RSP_ZSAU,	609, 609, ZSAU_PROCEEDING,	610,  5, {ACT_CMD+AT_DIAL} },
{RSP_OK,	610, 610, -1,			650,  0, {ACT_DIALING} },

{RSP_ERROR,	601, 610, -1,			  0,  0, {ACT_ABORTDIAL} },
{EV_TIMEOUT,	601, 610, -1,			  0,  0, {ACT_ABORTDIAL} },

/* optional dialing responses */
{EV_BC_OPEN,	650, 650, -1,			651, -1},
{RSP_ZVLS,	609, 651, 17,			 -1, -1, {ACT_DEBUG} },
{RSP_ZCTP,	610, 651, -1,			 -1, -1, {ACT_DEBUG} },
{RSP_ZCPN,	610, 651, -1,			 -1, -1, {ACT_DEBUG} },
{RSP_ZSAU,	650, 651, ZSAU_CALL_DELIVERED,	 -1, -1, {ACT_DEBUG} },

/* connect */
{RSP_ZSAU,	650, 650, ZSAU_ACTIVE,		800, -1, {ACT_CONNECT} },
{RSP_ZSAU,	651, 651, ZSAU_ACTIVE,		800, -1, {ACT_CONNECT,
							  ACT_NOTIFY_BC_UP} },
{RSP_ZSAU,	750, 750, ZSAU_ACTIVE,		800, -1, {ACT_CONNECT} },
{RSP_ZSAU,	751, 751, ZSAU_ACTIVE,		800, -1, {ACT_CONNECT,
							  ACT_NOTIFY_BC_UP} },
{EV_BC_OPEN,	800, 800, -1,			800, -1, {ACT_NOTIFY_BC_UP} },

/* remote hangup */
{RSP_ZSAU,	650, 651, ZSAU_DISCONNECT_IND,	  0,  0, {ACT_REMOTEREJECT} },
{RSP_ZSAU,	750, 751, ZSAU_DISCONNECT_IND,	  0,  0, {ACT_REMOTEHUP} },
{RSP_ZSAU,	800, 800, ZSAU_DISCONNECT_IND,	  0,  0, {ACT_REMOTEHUP} },

/* hangup */
{EV_HUP,	 -1,  -1, -1,			 -1, -1, {ACT_HUP} },
{RSP_INIT,	 -1,  -1, SEQ_HUP,		401,  5, {0},	"+VLS=0\r"},
{RSP_OK,	401, 401, -1,			402,  5},
{RSP_ZVLS,	402, 402,  0,			403,  5},
{RSP_ZSAU,	403, 403, ZSAU_DISCONNECT_REQ,	 -1, -1, {ACT_DEBUG} },
{RSP_ZSAU,	403, 403, ZSAU_NULL,		  0,  0, {ACT_DISCONNECT} },
{RSP_NODEV,	401, 403, -1,			  0,  0, {ACT_FAKEHUP} },
{RSP_ERROR,	401, 401, -1,			  0,  0, {ACT_ABORTHUP} },
{EV_TIMEOUT,	401, 403, -1,			  0,  0, {ACT_ABORTHUP} },

{EV_BC_CLOSED,	  0,   0, -1,			  0, -1, {ACT_NOTIFY_BC_DOWN} },

/* ring */
{RSP_ZBC,	700, 700, -1,			 -1, -1, {0} },
{RSP_ZHLC,	700, 700, -1,			 -1, -1, {0} },
{RSP_NMBR,	700, 700, -1,			 -1, -1, {0} },
{RSP_ZCPN,	700, 700, -1,			 -1, -1, {0} },
{RSP_ZCTP,	700, 700, -1,			 -1, -1, {0} },
{EV_TIMEOUT,	700, 700, -1,			720, 720, {ACT_ICALL} },
{EV_BC_CLOSED,	720, 720, -1,			  0, -1, {ACT_NOTIFY_BC_DOWN} },

/*accept icall*/
{EV_ACCEPT,	 -1,  -1, -1,			 -1, -1, {ACT_ACCEPT} },
{RSP_INIT,	720, 720, SEQ_ACCEPT,		721,  5, {ACT_CMD+AT_PROTO} },
{RSP_OK,	721, 721, -1,			722,  5, {ACT_CMD+AT_ISO} },
{RSP_OK,	722, 722, -1,			723,  5, {0},	"+VLS=17\r"},
{RSP_OK,	723, 723, -1,			724,  5, {0} },
{RSP_ZVLS,	724, 724, 17,			750, 50, {ACT_ACCEPTED} },
{RSP_ERROR,	721, 729, -1,			  0,  0, {ACT_ABORTACCEPT} },
{EV_TIMEOUT,	721, 729, -1,			  0,  0, {ACT_ABORTACCEPT} },
{RSP_ZSAU,	700, 729, ZSAU_NULL,		  0,  0, {ACT_ABORTACCEPT} },
{RSP_ZSAU,	700, 729, ZSAU_ACTIVE,		  0,  0, {ACT_ABORTACCEPT} },
{RSP_ZSAU,	700, 729, ZSAU_DISCONNECT_IND,	  0,  0, {ACT_ABORTACCEPT} },

{EV_BC_OPEN,	750, 750, -1,			751, -1},
{EV_TIMEOUT,	750, 751, -1,			  0,  0, {ACT_CONNTIMEOUT} },

/* B channel closed (general case) */
{EV_BC_CLOSED,	 -1,  -1, -1,			 -1, -1, {ACT_NOTIFY_BC_DOWN} },

/* misc. */
{RSP_ZCON,	 -1,  -1, -1,			 -1, -1, {ACT_DEBUG} },
{RSP_ZCAU,	 -1,  -1, -1,			 -1, -1, {ACT_ZCAU} },
{RSP_NONE,	 -1,  -1, -1,			 -1, -1, {ACT_DEBUG} },
{RSP_ANY,	 -1,  -1, -1,			 -1, -1, {ACT_WARN} },
{RSP_LAST}
};


static const struct resp_type_t {
	unsigned char	*response;
	int		resp_code;
	int		type;
} resp_type[] =
{
	{"OK",		RSP_OK,		RT_NOTHING},
	{"ERROR",	RSP_ERROR,	RT_NOTHING},
	{"ZSAU",	RSP_ZSAU,	RT_ZSAU},
	{"ZCAU",	RSP_ZCAU,	RT_ZCAU},
	{"RING",	RSP_RING,	RT_RING},
	{"ZGCI",	RSP_ZGCI,	RT_NUMBER},
	{"ZVLS",	RSP_ZVLS,	RT_NUMBER},
	{"ZCTP",	RSP_ZCTP,	RT_NUMBER},
	{"ZDLE",	RSP_ZDLE,	RT_NUMBER},
	{"ZHLC",	RSP_ZHLC,	RT_STRING},
	{"ZBC",		RSP_ZBC,	RT_STRING},
	{"NMBR",	RSP_NMBR,	RT_STRING},
	{"ZCPN",	RSP_ZCPN,	RT_STRING},
	{"ZCON",	RSP_ZCON,	RT_STRING},
	{NULL,		0,		0}
};

static const struct zsau_resp_t {
	unsigned char	*str;
	int		code;
} zsau_resp[] =
{
	{"OUTGOING_CALL_PROCEEDING",	ZSAU_OUTGOING_CALL_PROCEEDING},
	{"CALL_DELIVERED",		ZSAU_CALL_DELIVERED},
	{"ACTIVE",			ZSAU_ACTIVE},
	{"DISCONNECT_IND",		ZSAU_DISCONNECT_IND},
	{"NULL",			ZSAU_NULL},
	{"DISCONNECT_REQ",		ZSAU_DISCONNECT_REQ},
	{NULL,				ZSAU_UNKNOWN}
};

/* retrieve CID from parsed response
 * returns 0 if no CID, -1 if invalid CID, or CID value 1..65535
 */
static int cid_of_response(char *s)
{
	int cid;
	int rc;

	if (s[-1] != ';')
		return 0;	/* no CID separator */
	rc = kstrtoint(s, 10, &cid);
	if (rc)
		return 0;	/* CID not numeric */
	if (cid < 1 || cid > 65535)
		return -1;	/* CID out of range */
	return cid;
}

/**
 * gigaset_handle_modem_response() - process received modem response
 * @cs:		device descriptor structure.
 *
 * Called by asyncdata/isocdata if a block of data received from the
 * device must be processed as a modem command response. The data is
 * already in the cs structure.
 */
void gigaset_handle_modem_response(struct cardstate *cs)
{
	unsigned char *argv[MAX_REC_PARAMS + 1];
	int params;
	int i, j;
	const struct resp_type_t *rt;
	const struct zsau_resp_t *zr;
	int curarg;
	unsigned long flags;
	unsigned next, tail, head;
	struct event_t *event;
	int resp_code;
	int param_type;
	int abort;
	size_t len;
	int cid;
	int rawstring;

	len = cs->cbytes;
	if (!len) {
		/* ignore additional LFs/CRs (M10x config mode or cx100) */
		gig_dbg(DEBUG_MCMD, "skipped EOL [%02X]", cs->respdata[len]);
		return;
	}
	cs->respdata[len] = 0;
	argv[0] = cs->respdata;
	params = 1;
	if (cs->at_state.getstring) {
		/* getstring only allowed without cid at the moment */
		cs->at_state.getstring = 0;
		rawstring = 1;
		cid = 0;
	} else {
		/* parse line */
		for (i = 0; i < len; i++)
			switch (cs->respdata[i]) {
			case ';':
			case ',':
			case '=':
				if (params > MAX_REC_PARAMS) {
					dev_warn(cs->dev,
					   "too many parameters in response\n");
					/* need last parameter (might be CID) */
					params--;
				}
				argv[params++] = cs->respdata + i + 1;
			}

		rawstring = 0;
		cid = params > 1 ? cid_of_response(argv[params-1]) : 0;
		if (cid < 0) {
			gigaset_add_event(cs, &cs->at_state, RSP_INVAL,
					  NULL, 0, NULL);
			return;
		}

		for (j = 1; j < params; ++j)
			argv[j][-1] = 0;

		gig_dbg(DEBUG_EVENT, "CMD received: %s", argv[0]);
		if (cid) {
			--params;
			gig_dbg(DEBUG_EVENT, "CID: %s", argv[params]);
		}
		gig_dbg(DEBUG_EVENT, "available params: %d", params - 1);
		for (j = 1; j < params; j++)
			gig_dbg(DEBUG_EVENT, "param %d: %s", j, argv[j]);
	}

	spin_lock_irqsave(&cs->ev_lock, flags);
	head = cs->ev_head;
	tail = cs->ev_tail;

	abort = 1;
	curarg = 0;
	while (curarg < params) {
		next = (tail + 1) % MAX_EVENTS;
		if (unlikely(next == head)) {
			dev_err(cs->dev, "event queue full\n");
			break;
		}

		event = cs->events + tail;
		event->at_state = NULL;
		event->cid = cid;
		event->ptr = NULL;
		event->arg = NULL;
		tail = next;

		if (rawstring) {
			resp_code = RSP_STRING;
			param_type = RT_STRING;
		} else {
			for (rt = resp_type; rt->response; ++rt)
				if (!strcmp(argv[curarg], rt->response))
					break;

			if (!rt->response) {
				event->type = RSP_NONE;
				gig_dbg(DEBUG_EVENT,
					"unknown modem response: '%s'\n",
					argv[curarg]);
				break;
			}

			resp_code = rt->resp_code;
			param_type = rt->type;
			++curarg;
		}

		event->type = resp_code;

		switch (param_type) {
		case RT_NOTHING:
			break;
		case RT_RING:
			if (!cid) {
				dev_err(cs->dev,
					"received RING without CID!\n");
				event->type = RSP_INVAL;
				abort = 1;
			} else {
				event->cid = 0;
				event->parameter = cid;
				abort = 0;
			}
			break;
		case RT_ZSAU:
			if (curarg >= params) {
				event->parameter = ZSAU_NONE;
				break;
			}
			for (zr = zsau_resp; zr->str; ++zr)
				if (!strcmp(argv[curarg], zr->str))
					break;
			event->parameter = zr->code;
			if (!zr->str)
				dev_warn(cs->dev,
					"%s: unknown parameter %s after ZSAU\n",
					 __func__, argv[curarg]);
			++curarg;
			break;
		case RT_STRING:
			if (curarg < params) {
				event->ptr = kstrdup(argv[curarg], GFP_ATOMIC);
				if (!event->ptr)
					dev_err(cs->dev, "out of memory\n");
				++curarg;
			}
			gig_dbg(DEBUG_EVENT, "string==%s",
				event->ptr ? (char *) event->ptr : "NULL");
			break;
		case RT_ZCAU:
			event->parameter = -1;
			if (curarg + 1 < params) {
				u8 type, value;

				i = kstrtou8(argv[curarg++], 16, &type);
				j = kstrtou8(argv[curarg++], 16, &value);
				if (i == 0 && j == 0)
					event->parameter = (type << 8) | value;
			} else
				curarg = params - 1;
			break;
		case RT_NUMBER:
			if (curarg >= params ||
			    kstrtoint(argv[curarg++], 10, &event->parameter))
				event->parameter = -1;
			gig_dbg(DEBUG_EVENT, "parameter==%d", event->parameter);
			break;
		}

		if (resp_code == RSP_ZDLE)
			cs->dle = event->parameter;

		if (abort)
			break;
	}

	cs->ev_tail = tail;
	spin_unlock_irqrestore(&cs->ev_lock, flags);

	if (curarg != params)
		gig_dbg(DEBUG_EVENT,
			"invalid number of processed parameters: %d/%d",
			curarg, params);
}
EXPORT_SYMBOL_GPL(gigaset_handle_modem_response);

/* disconnect
 * process closing of connection associated with given AT state structure
 */
static void disconnect(struct at_state_t **at_state_p)
{
	unsigned long flags;
	struct bc_state *bcs = (*at_state_p)->bcs;
	struct cardstate *cs = (*at_state_p)->cs;

	spin_lock_irqsave(&cs->lock, flags);
	++(*at_state_p)->seq_index;

	/* revert to selected idle mode */
	if (!cs->cidmode) {
		cs->at_state.pending_commands |= PC_UMMODE;
		gig_dbg(DEBUG_EVENT, "Scheduling PC_UMMODE");
		cs->commands_pending = 1;
	}
	spin_unlock_irqrestore(&cs->lock, flags);

	if (bcs) {
		/* B channel assigned: invoke hardware specific handler */
		cs->ops->close_bchannel(bcs);
		/* notify LL */
		if (bcs->chstate & (CHS_D_UP | CHS_NOTIFY_LL)) {
			bcs->chstate &= ~(CHS_D_UP | CHS_NOTIFY_LL);
			gigaset_isdn_hupD(bcs);
		}
	} else {
		/* no B channel assigned: just deallocate */
		spin_lock_irqsave(&cs->lock, flags);
		list_del(&(*at_state_p)->list);
		kfree(*at_state_p);
		*at_state_p = NULL;
		spin_unlock_irqrestore(&cs->lock, flags);
	}
}

/* get_free_channel
 * get a free AT state structure: either one of those associated with the
 * B channels of the Gigaset device, or if none of those is available,
 * a newly allocated one with bcs=NULL
 * The structure should be freed by calling disconnect() after use.
 */
static inline struct at_state_t *get_free_channel(struct cardstate *cs,
						  int cid)
/* cids: >0: siemens-cid
	  0: without cid
	 -1: no cid assigned yet
*/
{
	unsigned long flags;
	int i;
	struct at_state_t *ret;

	for (i = 0; i < cs->channels; ++i)
		if (gigaset_get_channel(cs->bcs + i)) {
			ret = &cs->bcs[i].at_state;
			ret->cid = cid;
			return ret;
		}

	spin_lock_irqsave(&cs->lock, flags);
	ret = kmalloc(sizeof(struct at_state_t), GFP_ATOMIC);
	if (ret) {
		gigaset_at_init(ret, NULL, cs, cid);
		list_add(&ret->list, &cs->temp_at_states);
	}
	spin_unlock_irqrestore(&cs->lock, flags);
	return ret;
}

static void init_failed(struct cardstate *cs, int mode)
{
	int i;
	struct at_state_t *at_state;

	cs->at_state.pending_commands &= ~PC_INIT;
	cs->mode = mode;
	cs->mstate = MS_UNINITIALIZED;
	gigaset_free_channels(cs);
	for (i = 0; i < cs->channels; ++i) {
		at_state = &cs->bcs[i].at_state;
		if (at_state->pending_commands & PC_CID) {
			at_state->pending_commands &= ~PC_CID;
			at_state->pending_commands |= PC_NOCID;
			cs->commands_pending = 1;
		}
	}
}

static void schedule_init(struct cardstate *cs, int state)
{
	if (cs->at_state.pending_commands & PC_INIT) {
		gig_dbg(DEBUG_EVENT, "not scheduling PC_INIT again");
		return;
	}
	cs->mstate = state;
	cs->mode = M_UNKNOWN;
	gigaset_block_channels(cs);
	cs->at_state.pending_commands |= PC_INIT;
	gig_dbg(DEBUG_EVENT, "Scheduling PC_INIT");
	cs->commands_pending = 1;
}

/* Add "AT" to a command, add the cid, dle encode it, send the result to the
   hardware. */
static void send_command(struct cardstate *cs, const char *cmd, int cid,
			 int dle, gfp_t kmallocflags)
{
	struct cmdbuf_t *cb;
	size_t buflen;

	buflen = strlen(cmd) + 12; /* DLE ( A T 1 2 3 4 5 <cmd> DLE ) \0 */
	cb = kmalloc(sizeof(struct cmdbuf_t) + buflen, kmallocflags);
	if (!cb) {
		dev_err(cs->dev, "%s: out of memory\n", __func__);
		return;
	}
	if (cid > 0 && cid <= 65535)
		cb->len = snprintf(cb->buf, buflen,
				  dle ? "\020(AT%d%s\020)" : "AT%d%s",
				  cid, cmd);
	else
		cb->len = snprintf(cb->buf, buflen,
				  dle ? "\020(AT%s\020)" : "AT%s",
				  cmd);
	cb->offset = 0;
	cb->next = NULL;
	cb->wake_tasklet = NULL;
	cs->ops->write_cmd(cs, cb);
}

static struct at_state_t *at_state_from_cid(struct cardstate *cs, int cid)
{
	struct at_state_t *at_state;
	int i;
	unsigned long flags;

	if (cid == 0)
		return &cs->at_state;

	for (i = 0; i < cs->channels; ++i)
		if (cid == cs->bcs[i].at_state.cid)
			return &cs->bcs[i].at_state;

	spin_lock_irqsave(&cs->lock, flags);

	list_for_each_entry(at_state, &cs->temp_at_states, list)
		if (cid == at_state->cid) {
			spin_unlock_irqrestore(&cs->lock, flags);
			return at_state;
		}

	spin_unlock_irqrestore(&cs->lock, flags);

	return NULL;
}

static void bchannel_down(struct bc_state *bcs)
{
	if (bcs->chstate & CHS_B_UP) {
		bcs->chstate &= ~CHS_B_UP;
		gigaset_isdn_hupB(bcs);
	}

	if (bcs->chstate & (CHS_D_UP | CHS_NOTIFY_LL)) {
		bcs->chstate &= ~(CHS_D_UP | CHS_NOTIFY_LL);
		gigaset_isdn_hupD(bcs);
	}

	gigaset_free_channel(bcs);

	gigaset_bcs_reinit(bcs);
}

static void bchannel_up(struct bc_state *bcs)
{
	if (bcs->chstate & CHS_B_UP) {
		dev_notice(bcs->cs->dev, "%s: B channel already up\n",
			   __func__);
		return;
	}

	bcs->chstate |= CHS_B_UP;
	gigaset_isdn_connB(bcs);
}

static void start_dial(struct at_state_t *at_state, void *data,
			unsigned seq_index)
{
	struct bc_state *bcs = at_state->bcs;
	struct cardstate *cs = at_state->cs;
	char **commands = data;
	unsigned long flags;
	int i;

	bcs->chstate |= CHS_NOTIFY_LL;

	spin_lock_irqsave(&cs->lock, flags);
	if (at_state->seq_index != seq_index) {
		spin_unlock_irqrestore(&cs->lock, flags);
		goto error;
	}
	spin_unlock_irqrestore(&cs->lock, flags);

	for (i = 0; i < AT_NUM; ++i) {
		kfree(bcs->commands[i]);
		bcs->commands[i] = commands[i];
	}

	at_state->pending_commands |= PC_CID;
	gig_dbg(DEBUG_EVENT, "Scheduling PC_CID");
	cs->commands_pending = 1;
	return;

error:
	for (i = 0; i < AT_NUM; ++i) {
		kfree(commands[i]);
		commands[i] = NULL;
	}
	at_state->pending_commands |= PC_NOCID;
	gig_dbg(DEBUG_EVENT, "Scheduling PC_NOCID");
	cs->commands_pending = 1;
	return;
}

static void start_accept(struct at_state_t *at_state)
{
	struct cardstate *cs = at_state->cs;
	struct bc_state *bcs = at_state->bcs;
	int i;

	for (i = 0; i < AT_NUM; ++i) {
		kfree(bcs->commands[i]);
		bcs->commands[i] = NULL;
	}

	bcs->commands[AT_PROTO] = kmalloc(9, GFP_ATOMIC);
	bcs->commands[AT_ISO] = kmalloc(9, GFP_ATOMIC);
	if (!bcs->commands[AT_PROTO] || !bcs->commands[AT_ISO]) {
		dev_err(at_state->cs->dev, "out of memory\n");
		/* error reset */
		at_state->pending_commands |= PC_HUP;
		gig_dbg(DEBUG_EVENT, "Scheduling PC_HUP");
		cs->commands_pending = 1;
		return;
	}

	snprintf(bcs->commands[AT_PROTO], 9, "^SBPR=%u\r", bcs->proto2);
	snprintf(bcs->commands[AT_ISO], 9, "^SISO=%u\r", bcs->channel + 1);

	at_state->pending_commands |= PC_ACCEPT;
	gig_dbg(DEBUG_EVENT, "Scheduling PC_ACCEPT");
	cs->commands_pending = 1;
}

static void do_start(struct cardstate *cs)
{
	gigaset_free_channels(cs);

	if (cs->mstate != MS_LOCKED)
		schedule_init(cs, MS_INIT);

	cs->isdn_up = 1;
	gigaset_isdn_start(cs);

	cs->waiting = 0;
	wake_up(&cs->waitqueue);
}

static void finish_shutdown(struct cardstate *cs)
{
	if (cs->mstate != MS_LOCKED) {
		cs->mstate = MS_UNINITIALIZED;
		cs->mode = M_UNKNOWN;
	}

	/* Tell the LL that the device is not available .. */
	if (cs->isdn_up) {
		cs->isdn_up = 0;
		gigaset_isdn_stop(cs);
	}

	/* The rest is done by cleanup_cs () in user mode. */

	cs->cmd_result = -ENODEV;
	cs->waiting = 0;
	wake_up(&cs->waitqueue);
}

static void do_shutdown(struct cardstate *cs)
{
	gigaset_block_channels(cs);

	if (cs->mstate == MS_READY) {
		cs->mstate = MS_SHUTDOWN;
		cs->at_state.pending_commands |= PC_SHUTDOWN;
		gig_dbg(DEBUG_EVENT, "Scheduling PC_SHUTDOWN");
		cs->commands_pending = 1;
	} else
		finish_shutdown(cs);
}

static void do_stop(struct cardstate *cs)
{
	unsigned long flags;

	spin_lock_irqsave(&cs->lock, flags);
	cs->connected = 0;
	spin_unlock_irqrestore(&cs->lock, flags);

	do_shutdown(cs);
}

/* Entering cid mode or getting a cid failed:
 * try to initialize the device and try again.
 *
 * channel >= 0: getting cid for the channel failed
 * channel < 0:  entering cid mode failed
 *
 * returns 0 on failure
 */
static int reinit_and_retry(struct cardstate *cs, int channel)
{
	int i;

	if (--cs->retry_count <= 0)
		return 0;

	for (i = 0; i < cs->channels; ++i)
		if (cs->bcs[i].at_state.cid > 0)
			return 0;

	if (channel < 0)
		dev_warn(cs->dev,
		    "Could not enter cid mode. Reinit device and try again.\n");
	else {
		dev_warn(cs->dev,
		    "Could not get a call id. Reinit device and try again.\n");
		cs->bcs[channel].at_state.pending_commands |= PC_CID;
	}
	schedule_init(cs, MS_INIT);
	return 1;
}

static int at_state_invalid(struct cardstate *cs,
			    struct at_state_t *test_ptr)
{
	unsigned long flags;
	unsigned channel;
	struct at_state_t *at_state;
	int retval = 0;

	spin_lock_irqsave(&cs->lock, flags);

	if (test_ptr == &cs->at_state)
		goto exit;

	list_for_each_entry(at_state, &cs->temp_at_states, list)
		if (at_state == test_ptr)
			goto exit;

	for (channel = 0; channel < cs->channels; ++channel)
		if (&cs->bcs[channel].at_state == test_ptr)
			goto exit;

	retval = 1;
exit:
	spin_unlock_irqrestore(&cs->lock, flags);
	return retval;
}

static void handle_icall(struct cardstate *cs, struct bc_state *bcs,
			 struct at_state_t **p_at_state)
{
	int retval;
	struct at_state_t *at_state = *p_at_state;

	retval = gigaset_isdn_icall(at_state);
	switch (retval) {
	case ICALL_ACCEPT:
		break;
	default:
		dev_err(cs->dev, "internal error: disposition=%d\n", retval);
		/* --v-- fall through --v-- */
	case ICALL_IGNORE:
	case ICALL_REJECT:
		/* hang up actively
		 * Device doc says that would reject the call.
		 * In fact it doesn't.
		 */
		at_state->pending_commands |= PC_HUP;
		cs->commands_pending = 1;
		break;
	}
}

static int do_lock(struct cardstate *cs)
{
	int mode;
	int i;

	switch (cs->mstate) {
	case MS_UNINITIALIZED:
	case MS_READY:
		if (cs->cur_at_seq || !list_empty(&cs->temp_at_states) ||
		    cs->at_state.pending_commands)
			return -EBUSY;

		for (i = 0; i < cs->channels; ++i)
			if (cs->bcs[i].at_state.pending_commands)
				return -EBUSY;

		if (!gigaset_get_channels(cs))
			return -EBUSY;

		break;
	case MS_LOCKED:
		break;
	default:
		return -EBUSY;
	}

	mode = cs->mode;
	cs->mstate = MS_LOCKED;
	cs->mode = M_UNKNOWN;

	return mode;
}

static int do_unlock(struct cardstate *cs)
{
	if (cs->mstate != MS_LOCKED)
		return -EINVAL;

	cs->mstate = MS_UNINITIALIZED;
	cs->mode = M_UNKNOWN;
	gigaset_free_channels(cs);
	if (cs->connected)
		schedule_init(cs, MS_INIT);

	return 0;
}

static void do_action(int action, struct cardstate *cs,
		      struct bc_state *bcs,
		      struct at_state_t **p_at_state, char **pp_command,
		      int *p_genresp, int *p_resp_code,
		      struct event_t *ev)
{
	struct at_state_t *at_state = *p_at_state;
	struct at_state_t *at_state2;
	unsigned long flags;

	int channel;

	unsigned char *s, *e;
	int i;
	unsigned long val;

	switch (action) {
	case ACT_NOTHING:
		break;
	case ACT_TIMEOUT:
		at_state->waiting = 1;
		break;
	case ACT_INIT:
		cs->at_state.pending_commands &= ~PC_INIT;
		cs->cur_at_seq = SEQ_NONE;
		cs->mode = M_UNIMODEM;
		spin_lock_irqsave(&cs->lock, flags);
		if (!cs->cidmode) {
			spin_unlock_irqrestore(&cs->lock, flags);
			gigaset_free_channels(cs);
			cs->mstate = MS_READY;
			break;
		}
		spin_unlock_irqrestore(&cs->lock, flags);
		cs->at_state.pending_commands |= PC_CIDMODE;
		gig_dbg(DEBUG_EVENT, "Scheduling PC_CIDMODE");
		cs->commands_pending = 1;
		break;
	case ACT_FAILINIT:
		dev_warn(cs->dev, "Could not initialize the device.\n");
		cs->dle = 0;
		init_failed(cs, M_UNKNOWN);
		cs->cur_at_seq = SEQ_NONE;
		break;
	case ACT_CONFIGMODE:
		init_failed(cs, M_CONFIG);
		cs->cur_at_seq = SEQ_NONE;
		break;
	case ACT_SETDLE1:
		cs->dle = 1;
		/* cs->inbuf[0].inputstate |= INS_command | INS_DLE_command; */
		cs->inbuf[0].inputstate &=
			~(INS_command | INS_DLE_command);
		break;
	case ACT_SETDLE0:
		cs->dle = 0;
		cs->inbuf[0].inputstate =
			(cs->inbuf[0].inputstate & ~INS_DLE_command)
			| INS_command;
		break;
	case ACT_CMODESET:
		if (cs->mstate == MS_INIT || cs->mstate == MS_RECOVER) {
			gigaset_free_channels(cs);
			cs->mstate = MS_READY;
		}
		cs->mode = M_CID;
		cs->cur_at_seq = SEQ_NONE;
		break;
	case ACT_UMODESET:
		cs->mode = M_UNIMODEM;
		cs->cur_at_seq = SEQ_NONE;
		break;
	case ACT_FAILCMODE:
		cs->cur_at_seq = SEQ_NONE;
		if (cs->mstate == MS_INIT || cs->mstate == MS_RECOVER) {
			init_failed(cs, M_UNKNOWN);
			break;
		}
		if (!reinit_and_retry(cs, -1))
			schedule_init(cs, MS_RECOVER);
		break;
	case ACT_FAILUMODE:
		cs->cur_at_seq = SEQ_NONE;
		schedule_init(cs, MS_RECOVER);
		break;
	case ACT_HUPMODEM:
		/* send "+++" (hangup in unimodem mode) */
		if (cs->connected) {
			struct cmdbuf_t *cb;

			cb = kmalloc(sizeof(struct cmdbuf_t) + 3, GFP_ATOMIC);
			if (!cb) {
				dev_err(cs->dev, "%s: out of memory\n",
					__func__);
				return;
			}
			memcpy(cb->buf, "+++", 3);
			cb->len = 3;
			cb->offset = 0;
			cb->next = NULL;
			cb->wake_tasklet = NULL;
			cs->ops->write_cmd(cs, cb);
		}
		break;
	case ACT_RING:
		/* get fresh AT state structure for new CID */
		at_state2 = get_free_channel(cs, ev->parameter);
		if (!at_state2) {
			dev_warn(cs->dev,
			"RING ignored: could not allocate channel structure\n");
			break;
		}

		/* initialize AT state structure
		 * note that bcs may be NULL if no B channel is free
		 */
		at_state2->ConState = 700;
		for (i = 0; i < STR_NUM; ++i) {
			kfree(at_state2->str_var[i]);
			at_state2->str_var[i] = NULL;
		}
		at_state2->int_var[VAR_ZCTP] = -1;

		spin_lock_irqsave(&cs->lock, flags);
		at_state2->timer_expires = RING_TIMEOUT;
		at_state2->timer_active = 1;
		spin_unlock_irqrestore(&cs->lock, flags);
		break;
	case ACT_ICALL:
		handle_icall(cs, bcs, p_at_state);
		break;
	case ACT_FAILSDOWN:
		dev_warn(cs->dev, "Could not shut down the device.\n");
		/* fall through */
	case ACT_FAKESDOWN:
	case ACT_SDOWN:
		cs->cur_at_seq = SEQ_NONE;
		finish_shutdown(cs);
		break;
	case ACT_CONNECT:
		if (cs->onechannel) {
			at_state->pending_commands |= PC_DLE1;
			cs->commands_pending = 1;
			break;
		}
		bcs->chstate |= CHS_D_UP;
		gigaset_isdn_connD(bcs);
		cs->ops->init_bchannel(bcs);
		break;
	case ACT_DLE1:
		cs->cur_at_seq = SEQ_NONE;
		bcs = cs->bcs + cs->curchannel;

		bcs->chstate |= CHS_D_UP;
		gigaset_isdn_connD(bcs);
		cs->ops->init_bchannel(bcs);
		break;
	case ACT_FAKEHUP:
		at_state->int_var[VAR_ZSAU] = ZSAU_NULL;
		/* fall through */
	case ACT_DISCONNECT:
		cs->cur_at_seq = SEQ_NONE;
		at_state->cid = -1;
		if (bcs && cs->onechannel && cs->dle) {
			/* Check for other open channels not needed:
			 * DLE only used for M10x with one B channel.
			 */
			at_state->pending_commands |= PC_DLE0;
			cs->commands_pending = 1;
		} else
			disconnect(p_at_state);
		break;
	case ACT_FAKEDLE0:
		at_state->int_var[VAR_ZDLE] = 0;
		cs->dle = 0;
		/* fall through */
	case ACT_DLE0:
		cs->cur_at_seq = SEQ_NONE;
		at_state2 = &cs->bcs[cs->curchannel].at_state;
		disconnect(&at_state2);
		break;
	case ACT_ABORTHUP:
		cs->cur_at_seq = SEQ_NONE;
		dev_warn(cs->dev, "Could not hang up.\n");
		at_state->cid = -1;
		if (bcs && cs->onechannel)
			at_state->pending_commands |= PC_DLE0;
		else
			disconnect(p_at_state);
		schedule_init(cs, MS_RECOVER);
		break;
	case ACT_FAILDLE0:
		cs->cur_at_seq = SEQ_NONE;
		dev_warn(cs->dev, "Could not leave DLE mode.\n");
		at_state2 = &cs->bcs[cs->curchannel].at_state;
		disconnect(&at_state2);
		schedule_init(cs, MS_RECOVER);
		break;
	case ACT_FAILDLE1:
		cs->cur_at_seq = SEQ_NONE;
		dev_warn(cs->dev,
			 "Could not enter DLE mode. Trying to hang up.\n");
		channel = cs->curchannel;
		cs->bcs[channel].at_state.pending_commands |= PC_HUP;
		cs->commands_pending = 1;
		break;

	case ACT_CID: /* got cid; start dialing */
		cs->cur_at_seq = SEQ_NONE;
		channel = cs->curchannel;
		if (ev->parameter > 0 && ev->parameter <= 65535) {
			cs->bcs[channel].at_state.cid = ev->parameter;
			cs->bcs[channel].at_state.pending_commands |=
				PC_DIAL;
			cs->commands_pending = 1;
			break;
		}
		/* fall through */
	case ACT_FAILCID:
		cs->cur_at_seq = SEQ_NONE;
		channel = cs->curchannel;
		if (!reinit_and_retry(cs, channel)) {
			dev_warn(cs->dev,
				 "Could not get a call ID. Cannot dial.\n");
			at_state2 = &cs->bcs[channel].at_state;
			disconnect(&at_state2);
		}
		break;
	case ACT_ABORTCID:
		cs->cur_at_seq = SEQ_NONE;
		at_state2 = &cs->bcs[cs->curchannel].at_state;
		disconnect(&at_state2);
		break;

	case ACT_DIALING:
	case ACT_ACCEPTED:
		cs->cur_at_seq = SEQ_NONE;
		break;

	case ACT_ABORTACCEPT:	/* hangup/error/timeout during ICALL procssng */
		disconnect(p_at_state);
		break;

	case ACT_ABORTDIAL:	/* error/timeout during dial preparation */
		cs->cur_at_seq = SEQ_NONE;
		at_state->pending_commands |= PC_HUP;
		cs->commands_pending = 1;
		break;

	case ACT_REMOTEREJECT:	/* DISCONNECT_IND after dialling */
	case ACT_CONNTIMEOUT:	/* timeout waiting for ZSAU=ACTIVE */
	case ACT_REMOTEHUP:	/* DISCONNECT_IND with established connection */
		at_state->pending_commands |= PC_HUP;
		cs->commands_pending = 1;
		break;
	case ACT_GETSTRING: /* warning: RING, ZDLE, ...
			       are not handled properly anymore */
		at_state->getstring = 1;
		break;
	case ACT_SETVER:
		if (!ev->ptr) {
			*p_genresp = 1;
			*p_resp_code = RSP_ERROR;
			break;
		}
		s = ev->ptr;

		if (!strcmp(s, "OK")) {
			*p_genresp = 1;
			*p_resp_code = RSP_ERROR;
			break;
		}

		for (i = 0; i < 4; ++i) {
			val = simple_strtoul(s, (char **) &e, 10);
			if (val > INT_MAX || e == s)
				break;
			if (i == 3) {
				if (*e)
					break;
			} else if (*e != '.')
				break;
			else
				s = e + 1;
			cs->fwver[i] = val;
		}
		if (i != 4) {
			*p_genresp = 1;
			*p_resp_code = RSP_ERROR;
			break;
		}
		/*at_state->getstring = 1;*/
		cs->gotfwver = 0;
		break;
	case ACT_GOTVER:
		if (cs->gotfwver == 0) {
			cs->gotfwver = 1;
			gig_dbg(DEBUG_EVENT,
				"firmware version %02d.%03d.%02d.%02d",
				cs->fwver[0], cs->fwver[1],
				cs->fwver[2], cs->fwver[3]);
			break;
		}
		/* fall through */
	case ACT_FAILVER:
		cs->gotfwver = -1;
		dev_err(cs->dev, "could not read firmware version.\n");
		break;
	case ACT_ERROR:
		gig_dbg(DEBUG_ANY, "%s: ERROR response in ConState %d",
			__func__, at_state->ConState);
		cs->cur_at_seq = SEQ_NONE;
		break;
	case ACT_DEBUG:
		gig_dbg(DEBUG_ANY, "%s: resp_code %d in ConState %d",
			__func__, ev->type, at_state->ConState);
		break;
	case ACT_WARN:
		dev_warn(cs->dev, "%s: resp_code %d in ConState %d!\n",
			 __func__, ev->type, at_state->ConState);
		break;
	case ACT_ZCAU:
		dev_warn(cs->dev, "cause code %04x in connection state %d.\n",
			 ev->parameter, at_state->ConState);
		break;

	/* events from the LL */
	case ACT_DIAL:
		start_dial(at_state, ev->ptr, ev->parameter);
		break;
	case ACT_ACCEPT:
		start_accept(at_state);
		break;
	case ACT_HUP:
		at_state->pending_commands |= PC_HUP;
		gig_dbg(DEBUG_EVENT, "Scheduling PC_HUP");
		cs->commands_pending = 1;
		break;

	/* hotplug events */
	case ACT_STOP:
		do_stop(cs);
		break;
	case ACT_START:
		do_start(cs);
		break;

	/* events from the interface */
	case ACT_IF_LOCK:
		cs->cmd_result = ev->parameter ? do_lock(cs) : do_unlock(cs);
		cs->waiting = 0;
		wake_up(&cs->waitqueue);
		break;
	case ACT_IF_VER:
		if (ev->parameter != 0)
			cs->cmd_result = -EINVAL;
		else if (cs->gotfwver != 1) {
			cs->cmd_result = -ENOENT;
		} else {
			memcpy(ev->arg, cs->fwver, sizeof cs->fwver);
			cs->cmd_result = 0;
		}
		cs->waiting = 0;
		wake_up(&cs->waitqueue);
		break;

	/* events from the proc file system */
	case ACT_PROC_CIDMODE:
		spin_lock_irqsave(&cs->lock, flags);
		if (ev->parameter != cs->cidmode) {
			cs->cidmode = ev->parameter;
			if (ev->parameter) {
				cs->at_state.pending_commands |= PC_CIDMODE;
				gig_dbg(DEBUG_EVENT, "Scheduling PC_CIDMODE");
			} else {
				cs->at_state.pending_commands |= PC_UMMODE;
				gig_dbg(DEBUG_EVENT, "Scheduling PC_UMMODE");
			}
			cs->commands_pending = 1;
		}
		spin_unlock_irqrestore(&cs->lock, flags);
		cs->waiting = 0;
		wake_up(&cs->waitqueue);
		break;

	/* events from the hardware drivers */
	case ACT_NOTIFY_BC_DOWN:
		bchannel_down(bcs);
		break;
	case ACT_NOTIFY_BC_UP:
		bchannel_up(bcs);
		break;
	case ACT_SHUTDOWN:
		do_shutdown(cs);
		break;


	default:
		if (action >= ACT_CMD && action < ACT_CMD + AT_NUM) {
			*pp_command = at_state->bcs->commands[action - ACT_CMD];
			if (!*pp_command) {
				*p_genresp = 1;
				*p_resp_code = RSP_NULL;
			}
		} else
			dev_err(cs->dev, "%s: action==%d!\n", __func__, action);
	}
}

/* State machine to do the calling and hangup procedure */
static void process_event(struct cardstate *cs, struct event_t *ev)
{
	struct bc_state *bcs;
	char *p_command = NULL;
	struct reply_t *rep;
	int rcode;
	int genresp = 0;
	int resp_code = RSP_ERROR;
	int sendcid;
	struct at_state_t *at_state;
	int index;
	int curact;
	unsigned long flags;

	if (ev->cid >= 0) {
		at_state = at_state_from_cid(cs, ev->cid);
		if (!at_state) {
			gig_dbg(DEBUG_EVENT, "event %d for invalid cid %d",
				ev->type, ev->cid);
			gigaset_add_event(cs, &cs->at_state, RSP_WRONG_CID,
					  NULL, 0, NULL);
			return;
		}
	} else {
		at_state = ev->at_state;
		if (at_state_invalid(cs, at_state)) {
			gig_dbg(DEBUG_EVENT, "event for invalid at_state %p",
				at_state);
			return;
		}
	}

	gig_dbg(DEBUG_EVENT, "connection state %d, event %d",
		at_state->ConState, ev->type);

	bcs = at_state->bcs;
	sendcid = at_state->cid;

	/* Setting the pointer to the dial array */
	rep = at_state->replystruct;

	spin_lock_irqsave(&cs->lock, flags);
	if (ev->type == EV_TIMEOUT) {
		if (ev->parameter != at_state->timer_index
		    || !at_state->timer_active) {
			ev->type = RSP_NONE; /* old timeout */
			gig_dbg(DEBUG_EVENT, "old timeout");
		} else if (!at_state->waiting)
			gig_dbg(DEBUG_EVENT, "timeout occurred");
		else
			gig_dbg(DEBUG_EVENT, "stopped waiting");
	}
	spin_unlock_irqrestore(&cs->lock, flags);

	/* if the response belongs to a variable in at_state->int_var[VAR_XXXX]
	   or at_state->str_var[STR_XXXX], set it */
	if (ev->type >= RSP_VAR && ev->type < RSP_VAR + VAR_NUM) {
		index = ev->type - RSP_VAR;
		at_state->int_var[index] = ev->parameter;
	} else if (ev->type >= RSP_STR && ev->type < RSP_STR + STR_NUM) {
		index = ev->type - RSP_STR;
		kfree(at_state->str_var[index]);
		at_state->str_var[index] = ev->ptr;
		ev->ptr = NULL; /* prevent process_events() from
				   deallocating ptr */
	}

	if (ev->type == EV_TIMEOUT || ev->type == RSP_STRING)
		at_state->getstring = 0;

	/* Search row in dial array which matches modem response and current
	   constate */
	for (;; rep++) {
		rcode = rep->resp_code;
		if (rcode == RSP_LAST) {
			/* found nothing...*/
			dev_warn(cs->dev, "%s: rcode=RSP_LAST: "
					"resp_code %d in ConState %d!\n",
				 __func__, ev->type, at_state->ConState);
			return;
		}
		if ((rcode == RSP_ANY || rcode == ev->type)
		  && ((int) at_state->ConState >= rep->min_ConState)
		  && (rep->max_ConState < 0
		      || (int) at_state->ConState <= rep->max_ConState)
		  && (rep->parameter < 0 || rep->parameter == ev->parameter))
			break;
	}

	p_command = rep->command;

	at_state->waiting = 0;
	for (curact = 0; curact < MAXACT; ++curact) {
		/* The row tells us what we should do  ..
		 */
		do_action(rep->action[curact], cs, bcs, &at_state, &p_command,
			  &genresp, &resp_code, ev);
		if (!at_state)
			break; /* may be freed after disconnect */
	}

	if (at_state) {
		/* Jump to the next con-state regarding the array */
		if (rep->new_ConState >= 0)
			at_state->ConState = rep->new_ConState;

		if (genresp) {
			spin_lock_irqsave(&cs->lock, flags);
			at_state->timer_expires = 0;
			at_state->timer_active = 0;
			spin_unlock_irqrestore(&cs->lock, flags);
			gigaset_add_event(cs, at_state, resp_code,
					  NULL, 0, NULL);
		} else {
			/* Send command to modem if not NULL... */
			if (p_command) {
				if (cs->connected)
					send_command(cs, p_command,
						     sendcid, cs->dle,
						     GFP_ATOMIC);
				else
					gigaset_add_event(cs, at_state,
							  RSP_NODEV,
							  NULL, 0, NULL);
			}

			spin_lock_irqsave(&cs->lock, flags);
			if (!rep->timeout) {
				at_state->timer_expires = 0;
				at_state->timer_active = 0;
			} else if (rep->timeout > 0) { /* new timeout */
				at_state->timer_expires = rep->timeout * 10;
				at_state->timer_active = 1;
				++at_state->timer_index;
			}
			spin_unlock_irqrestore(&cs->lock, flags);
		}
	}
}

static void schedule_sequence(struct cardstate *cs,
			      struct at_state_t *at_state, int sequence)
{
	cs->cur_at_seq = sequence;
	gigaset_add_event(cs, at_state, RSP_INIT, NULL, sequence, NULL);
}

static void process_command_flags(struct cardstate *cs)
{
	struct at_state_t *at_state = NULL;
	struct bc_state *bcs;
	int i;
	int sequence;
	unsigned long flags;

	cs->commands_pending = 0;

	if (cs->cur_at_seq) {
		gig_dbg(DEBUG_EVENT, "not searching scheduled commands: busy");
		return;
	}

	gig_dbg(DEBUG_EVENT, "searching scheduled commands");

	sequence = SEQ_NONE;

	/* clear pending_commands and hangup channels on shutdown */
	if (cs->at_state.pending_commands & PC_SHUTDOWN) {
		cs->at_state.pending_commands &= ~PC_CIDMODE;
		for (i = 0; i < cs->channels; ++i) {
			bcs = cs->bcs + i;
			at_state = &bcs->at_state;
			at_state->pending_commands &=
				~(PC_DLE1 | PC_ACCEPT | PC_DIAL);
			if (at_state->cid > 0)
				at_state->pending_commands |= PC_HUP;
			if (at_state->pending_commands & PC_CID) {
				at_state->pending_commands |= PC_NOCID;
				at_state->pending_commands &= ~PC_CID;
			}
		}
	}

	/* clear pending_commands and hangup channels on reset */
	if (cs->at_state.pending_commands & PC_INIT) {
		cs->at_state.pending_commands &= ~PC_CIDMODE;
		for (i = 0; i < cs->channels; ++i) {
			bcs = cs->bcs + i;
			at_state = &bcs->at_state;
			at_state->pending_commands &=
				~(PC_DLE1 | PC_ACCEPT | PC_DIAL);
			if (at_state->cid > 0)
				at_state->pending_commands |= PC_HUP;
			if (cs->mstate == MS_RECOVER) {
				if (at_state->pending_commands & PC_CID) {
					at_state->pending_commands |= PC_NOCID;
					at_state->pending_commands &= ~PC_CID;
				}
			}
		}
	}

	/* only switch back to unimodem mode if no commands are pending and
	 * no channels are up */
	spin_lock_irqsave(&cs->lock, flags);
	if (cs->at_state.pending_commands == PC_UMMODE
	    && !cs->cidmode
	    && list_empty(&cs->temp_at_states)
	    && cs->mode == M_CID) {
		sequence = SEQ_UMMODE;
		at_state = &cs->at_state;
		for (i = 0; i < cs->channels; ++i) {
			bcs = cs->bcs + i;
			if (bcs->at_state.pending_commands ||
			    bcs->at_state.cid > 0) {
				sequence = SEQ_NONE;
				break;
			}
		}
	}
	spin_unlock_irqrestore(&cs->lock, flags);
	cs->at_state.pending_commands &= ~PC_UMMODE;
	if (sequence != SEQ_NONE) {
		schedule_sequence(cs, at_state, sequence);
		return;
	}

	for (i = 0; i < cs->channels; ++i) {
		bcs = cs->bcs + i;
		if (bcs->at_state.pending_commands & PC_HUP) {
			bcs->at_state.pending_commands &= ~PC_HUP;
			if (bcs->at_state.pending_commands & PC_CID) {
				/* not yet dialing: PC_NOCID is sufficient */
				bcs->at_state.pending_commands |= PC_NOCID;
				bcs->at_state.pending_commands &= ~PC_CID;
			} else {
				schedule_sequence(cs, &bcs->at_state, SEQ_HUP);
				return;
			}
		}
		if (bcs->at_state.pending_commands & PC_NOCID) {
			bcs->at_state.pending_commands &= ~PC_NOCID;
			cs->curchannel = bcs->channel;
			schedule_sequence(cs, &cs->at_state, SEQ_NOCID);
			return;
		} else if (bcs->at_state.pending_commands & PC_DLE0) {
			bcs->at_state.pending_commands &= ~PC_DLE0;
			cs->curchannel = bcs->channel;
			schedule_sequence(cs, &cs->at_state, SEQ_DLE0);
			return;
		}
	}

	list_for_each_entry(at_state, &cs->temp_at_states, list)
		if (at_state->pending_commands & PC_HUP) {
			at_state->pending_commands &= ~PC_HUP;
			schedule_sequence(cs, at_state, SEQ_HUP);
			return;
		}

	if (cs->at_state.pending_commands & PC_INIT) {
		cs->at_state.pending_commands &= ~PC_INIT;
		cs->dle = 0;
		cs->inbuf->inputstate = INS_command;
		schedule_sequence(cs, &cs->at_state, SEQ_INIT);
		return;
	}
	if (cs->at_state.pending_commands & PC_SHUTDOWN) {
		cs->at_state.pending_commands &= ~PC_SHUTDOWN;
		schedule_sequence(cs, &cs->at_state, SEQ_SHUTDOWN);
		return;
	}
	if (cs->at_state.pending_commands & PC_CIDMODE) {
		cs->at_state.pending_commands &= ~PC_CIDMODE;
		if (cs->mode == M_UNIMODEM) {
			cs->retry_count = 1;
			schedule_sequence(cs, &cs->at_state, SEQ_CIDMODE);
			return;
		}
	}

	for (i = 0; i < cs->channels; ++i) {
		bcs = cs->bcs + i;
		if (bcs->at_state.pending_commands & PC_DLE1) {
			bcs->at_state.pending_commands &= ~PC_DLE1;
			cs->curchannel = bcs->channel;
			schedule_sequence(cs, &cs->at_state, SEQ_DLE1);
			return;
		}
		if (bcs->at_state.pending_commands & PC_ACCEPT) {
			bcs->at_state.pending_commands &= ~PC_ACCEPT;
			schedule_sequence(cs, &bcs->at_state, SEQ_ACCEPT);
			return;
		}
		if (bcs->at_state.pending_commands & PC_DIAL) {
			bcs->at_state.pending_commands &= ~PC_DIAL;
			schedule_sequence(cs, &bcs->at_state, SEQ_DIAL);
			return;
		}
		if (bcs->at_state.pending_commands & PC_CID) {
			switch (cs->mode) {
			case M_UNIMODEM:
				cs->at_state.pending_commands |= PC_CIDMODE;
				gig_dbg(DEBUG_EVENT, "Scheduling PC_CIDMODE");
				cs->commands_pending = 1;
				return;
			case M_UNKNOWN:
				schedule_init(cs, MS_INIT);
				return;
			}
			bcs->at_state.pending_commands &= ~PC_CID;
			cs->curchannel = bcs->channel;
			cs->retry_count = 2;
			schedule_sequence(cs, &cs->at_state, SEQ_CID);
			return;
		}
	}
}

static void process_events(struct cardstate *cs)
{
	struct event_t *ev;
	unsigned head, tail;
	int i;
	int check_flags = 0;
	int was_busy;
	unsigned long flags;

	spin_lock_irqsave(&cs->ev_lock, flags);
	head = cs->ev_head;

	for (i = 0; i < 2 * MAX_EVENTS; ++i) {
		tail = cs->ev_tail;
		if (tail == head) {
			if (!check_flags && !cs->commands_pending)
				break;
			check_flags = 0;
			spin_unlock_irqrestore(&cs->ev_lock, flags);
			process_command_flags(cs);
			spin_lock_irqsave(&cs->ev_lock, flags);
			tail = cs->ev_tail;
			if (tail == head) {
				if (!cs->commands_pending)
					break;
				continue;
			}
		}

		ev = cs->events + head;
		was_busy = cs->cur_at_seq != SEQ_NONE;
		spin_unlock_irqrestore(&cs->ev_lock, flags);
		process_event(cs, ev);
		spin_lock_irqsave(&cs->ev_lock, flags);
		kfree(ev->ptr);
		ev->ptr = NULL;
		if (was_busy && cs->cur_at_seq == SEQ_NONE)
			check_flags = 1;

		head = (head + 1) % MAX_EVENTS;
		cs->ev_head = head;
	}

	spin_unlock_irqrestore(&cs->ev_lock, flags);

	if (i == 2 * MAX_EVENTS) {
		dev_err(cs->dev,
			"infinite loop in process_events; aborting.\n");
	}
}

/* tasklet scheduled on any event received from the Gigaset device
 * parameter:
 *	data	ISDN controller state structure
 */
void gigaset_handle_event(unsigned long data)
{
	struct cardstate *cs = (struct cardstate *) data;

	/* handle incoming data on control/common channel */
	if (cs->inbuf->head != cs->inbuf->tail) {
		gig_dbg(DEBUG_INTR, "processing new data");
		cs->ops->handle_input(cs->inbuf);
	}

	process_events(cs);
}