include/linux/atmdev.h


1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317

/* atmdev.h - ATM device driver declarations and various related items */
#ifndef LINUX_ATMDEV_H
#define LINUX_ATMDEV_H


#include <linux/wait.h> /* wait_queue_head_t */
#include <linux/time.h> /* struct timeval */
#include <linux/net.h>
#include <linux/bug.h>
#include <linux/skbuff.h> /* struct sk_buff */
#include <linux/uio.h>
#include <net/sock.h>
#include <linux/atomic.h>
#include <uapi/linux/atmdev.h>

#ifdef CONFIG_PROC_FS
#include <linux/proc_fs.h>

extern struct proc_dir_entry *atm_proc_root;
#endif

#ifdef CONFIG_COMPAT
#include <linux/compat.h>
struct compat_atm_iobuf {
	int length;
	compat_uptr_t buffer;
};
#endif

struct k_atm_aal_stats {
#define __HANDLE_ITEM(i) atomic_t i
	__AAL_STAT_ITEMS
#undef __HANDLE_ITEM
};


struct k_atm_dev_stats {
	struct k_atm_aal_stats aal0;
	struct k_atm_aal_stats aal34;
	struct k_atm_aal_stats aal5;
};

struct device;

enum {
	ATM_VF_ADDR,		/* Address is in use. Set by anybody, cleared
				   by device driver. */
	ATM_VF_READY,		/* VC is ready to transfer data. Set by device
				   driver, cleared by anybody. */
	ATM_VF_PARTIAL,		/* resources are bound to PVC (partial PVC
				   setup), controlled by socket layer */
	ATM_VF_REGIS,		/* registered with demon, controlled by SVC
				   socket layer */
	ATM_VF_BOUND,		/* local SAP is set, controlled by SVC socket
				   layer */
	ATM_VF_RELEASED,	/* demon has indicated/requested release,
				   controlled by SVC socket layer */
	ATM_VF_HASQOS,		/* QOS parameters have been set */
	ATM_VF_LISTEN,		/* socket is used for listening */
	ATM_VF_META,		/* SVC socket isn't used for normal data
				   traffic and doesn't depend on signaling
				   to be available */
	ATM_VF_SESSION,		/* VCC is p2mp session control descriptor */
	ATM_VF_HASSAP,		/* SAP has been set */
	ATM_VF_CLOSE,		/* asynchronous close - treat like VF_RELEASED*/
	ATM_VF_WAITING,		/* waiting for reply from sigd */
	ATM_VF_IS_CLIP,		/* in use by CLIP protocol */
};


#define ATM_VF2VS(flags) \
    (test_bit(ATM_VF_READY,&(flags)) ? ATM_VS_CONNECTED : \
     test_bit(ATM_VF_RELEASED,&(flags)) ? ATM_VS_CLOSING : \
     test_bit(ATM_VF_LISTEN,&(flags)) ? ATM_VS_LISTEN : \
     test_bit(ATM_VF_REGIS,&(flags)) ? ATM_VS_INUSE : \
     test_bit(ATM_VF_BOUND,&(flags)) ? ATM_VS_BOUND : ATM_VS_IDLE)


enum {
	ATM_DF_REMOVED,		/* device was removed from atm_devs list */
};


#define ATM_PHY_SIG_LOST    0	/* no carrier/light */
#define ATM_PHY_SIG_UNKNOWN 1	/* carrier/light status is unknown */
#define ATM_PHY_SIG_FOUND   2	/* carrier/light okay */

#define ATM_ATMOPT_CLP	1	/* set CLP bit */

struct atm_vcc {
	/* struct sock has to be the first member of atm_vcc */
	struct sock	sk;
	unsigned long	flags;		/* VCC flags (ATM_VF_*) */
	short		vpi;		/* VPI and VCI (types must be equal */
					/* with sockaddr) */
	int 		vci;
	unsigned long	aal_options;	/* AAL layer options */
	unsigned long	atm_options;	/* ATM layer options */
	struct atm_dev	*dev;		/* device back pointer */
	struct atm_qos	qos;		/* QOS */
	struct atm_sap	sap;		/* SAP */
	void (*release_cb)(struct atm_vcc *vcc); /* release_sock callback */
	void (*push)(struct atm_vcc *vcc,struct sk_buff *skb);
	void (*pop)(struct atm_vcc *vcc,struct sk_buff *skb); /* optional */
	int (*push_oam)(struct atm_vcc *vcc,void *cell);
	int (*send)(struct atm_vcc *vcc,struct sk_buff *skb);
	void		*dev_data;	/* per-device data */
	void		*proto_data;	/* per-protocol data */
	struct k_atm_aal_stats *stats;	/* pointer to AAL stats group */
	struct module *owner;		/* owner of ->push function */
	/* SVC part --- may move later ------------------------------------- */
	short		itf;		/* interface number */
	struct sockaddr_atmsvc local;
	struct sockaddr_atmsvc remote;
	/* Multipoint part ------------------------------------------------- */
	struct atm_vcc	*session;	/* session VCC descriptor */
	/* Other stuff ----------------------------------------------------- */
	void		*user_back;	/* user backlink - not touched by */
					/* native ATM stack. Currently used */
					/* by CLIP and sch_atm. */
};

static inline struct atm_vcc *atm_sk(struct sock *sk)
{
	return (struct atm_vcc *)sk;
}

static inline struct atm_vcc *ATM_SD(struct socket *sock)
{
	return atm_sk(sock->sk);
}

static inline struct sock *sk_atm(struct atm_vcc *vcc)
{
	return (struct sock *)vcc;
}

struct atm_dev_addr {
	struct sockaddr_atmsvc addr;	/* ATM address */
	struct list_head entry;		/* next address */
};

enum atm_addr_type_t { ATM_ADDR_LOCAL, ATM_ADDR_LECS };

struct atm_dev {
	const struct atmdev_ops *ops;	/* device operations; NULL if unused */
	const struct atmphy_ops *phy;	/* PHY operations, may be undefined */
					/* (NULL) */
	const char	*type;		/* device type name */
	int		number;		/* device index */
	void		*dev_data;	/* per-device data */
	void		*phy_data;	/* private PHY date */
	unsigned long	flags;		/* device flags (ATM_DF_*) */
	struct list_head local;		/* local ATM addresses */
	struct list_head lecs;		/* LECS ATM addresses learned via ILMI */
	unsigned char	esi[ESI_LEN];	/* ESI ("MAC" addr) */
	struct atm_cirange ci_range;	/* VPI/VCI range */
	struct k_atm_dev_stats stats;	/* statistics */
	char		signal;		/* signal status (ATM_PHY_SIG_*) */
	int		link_rate;	/* link rate (default: OC3) */
	atomic_t	refcnt;		/* reference count */
	spinlock_t	lock;		/* protect internal members */
#ifdef CONFIG_PROC_FS
	struct proc_dir_entry *proc_entry; /* proc entry */
	char *proc_name;		/* proc entry name */
#endif
	struct device class_dev;	/* sysfs device */
	struct list_head dev_list;	/* linkage */
};

 
/* OF: send_Oam Flags */

#define ATM_OF_IMMED  1		/* Attempt immediate delivery */
#define ATM_OF_INRATE 2		/* Attempt in-rate delivery */


/*
 * ioctl, getsockopt, and setsockopt are optional and can be set to NULL.
 */

struct atmdev_ops { /* only send is required */
	void (*dev_close)(struct atm_dev *dev);
	int (*open)(struct atm_vcc *vcc);
	void (*close)(struct atm_vcc *vcc);
	int (*ioctl)(struct atm_dev *dev,unsigned int cmd,void __user *arg);
#ifdef CONFIG_COMPAT
	int (*compat_ioctl)(struct atm_dev *dev,unsigned int cmd,
			    void __user *arg);
#endif
	int (*getsockopt)(struct atm_vcc *vcc,int level,int optname,
	    void __user *optval,int optlen);
	int (*setsockopt)(struct atm_vcc *vcc,int level,int optname,
	    void __user *optval,unsigned int optlen);
	int (*send)(struct atm_vcc *vcc,struct sk_buff *skb);
	int (*send_oam)(struct atm_vcc *vcc,void *cell,int flags);
	void (*phy_put)(struct atm_dev *dev,unsigned char value,
	    unsigned long addr);
	unsigned char (*phy_get)(struct atm_dev *dev,unsigned long addr);
	int (*change_qos)(struct atm_vcc *vcc,struct atm_qos *qos,int flags);
	int (*proc_read)(struct atm_dev *dev,loff_t *pos,char *page);
	struct module *owner;
};

struct atmphy_ops {
	int (*start)(struct atm_dev *dev);
	int (*ioctl)(struct atm_dev *dev,unsigned int cmd,void __user *arg);
	void (*interrupt)(struct atm_dev *dev);
	int (*stop)(struct atm_dev *dev);
};

struct atm_skb_data {
	struct atm_vcc	*vcc;		/* ATM VCC */
	unsigned long	atm_options;	/* ATM layer options */
};

#define VCC_HTABLE_SIZE 32

extern struct hlist_head vcc_hash[VCC_HTABLE_SIZE];
extern rwlock_t vcc_sklist_lock;

#define ATM_SKB(skb) (((struct atm_skb_data *) (skb)->cb))

struct atm_dev *atm_dev_register(const char *type, struct device *parent,
				 const struct atmdev_ops *ops,
				 int number, /* -1 == pick first available */
				 unsigned long *flags);
struct atm_dev *atm_dev_lookup(int number);
void atm_dev_deregister(struct atm_dev *dev);

/* atm_dev_signal_change
 *
 * Propagate lower layer signal change in atm_dev->signal to netdevice.
 * The event will be sent via a notifier call chain.
 */
void atm_dev_signal_change(struct atm_dev *dev, char signal);

void vcc_insert_socket(struct sock *sk);

void atm_dev_release_vccs(struct atm_dev *dev);


static inline void atm_force_charge(struct atm_vcc *vcc,int truesize)
{
	atomic_add(truesize, &sk_atm(vcc)->sk_rmem_alloc);
}


static inline void atm_return(struct atm_vcc *vcc,int truesize)
{
	atomic_sub(truesize, &sk_atm(vcc)->sk_rmem_alloc);
}


static inline int atm_may_send(struct atm_vcc *vcc,unsigned int size)
{
	return (size + atomic_read(&sk_atm(vcc)->sk_wmem_alloc)) <
	       sk_atm(vcc)->sk_sndbuf;
}


static inline void atm_dev_hold(struct atm_dev *dev)
{
	atomic_inc(&dev->refcnt);
}


static inline void atm_dev_put(struct atm_dev *dev)
{
	if (atomic_dec_and_test(&dev->refcnt)) {
		BUG_ON(!test_bit(ATM_DF_REMOVED, &dev->flags));
		if (dev->ops->dev_close)
			dev->ops->dev_close(dev);
		put_device(&dev->class_dev);
	}
}


int atm_charge(struct atm_vcc *vcc,int truesize);
struct sk_buff *atm_alloc_charge(struct atm_vcc *vcc,int pdu_size,
    gfp_t gfp_flags);
int atm_pcr_goal(const struct atm_trafprm *tp);

void vcc_release_async(struct atm_vcc *vcc, int reply);

struct atm_ioctl {
	struct module *owner;
	/* A module reference is kept if appropriate over this call.
	 * Return -ENOIOCTLCMD if you don't handle it. */
	int (*ioctl)(struct socket *, unsigned int cmd, unsigned long arg);
	struct list_head list;
};

/**
 * register_atm_ioctl - register handler for ioctl operations
 *
 * Special (non-device) handlers of ioctl's should
 * register here. If you're a normal device, you should
 * set .ioctl in your atmdev_ops instead.
 */
void register_atm_ioctl(struct atm_ioctl *);

/**
 * deregister_atm_ioctl - remove the ioctl handler
 */
void deregister_atm_ioctl(struct atm_ioctl *);


/* register_atmdevice_notifier - register atm_dev notify events
 *
 * Clients like br2684 will register notify events
 * Currently we notify of signal found/lost
 */
int register_atmdevice_notifier(struct notifier_block *nb);
void unregister_atmdevice_notifier(struct notifier_block *nb);

#endif
/*
 * cistpl.c -- 16-bit PCMCIA Card Information Structure parser
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License version 2 as
 * published by the Free Software Foundation.
 *
 * The initial developer of the original code is David A. Hinds
 * <dahinds@users.sourceforge.net>.  Portions created by David A. Hinds
 * are Copyright (C) 1999 David A. Hinds.  All Rights Reserved.
 *
 * (C) 1999		David A. Hinds
 */

#include <linux/config.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/kernel.h>
#include <linux/string.h>
#include <linux/major.h>
#include <linux/errno.h>
#include <linux/timer.h>
#include <linux/slab.h>
#include <linux/mm.h>
#include <linux/sched.h>
#include <linux/pci.h>
#include <linux/ioport.h>
#include <asm/io.h>
#include <asm/byteorder.h>

#include <pcmcia/cs_types.h>
#include <pcmcia/ss.h>
#include <pcmcia/cs.h>
#include <pcmcia/bulkmem.h>
#include <pcmcia/cisreg.h>
#include <pcmcia/cistpl.h>
#include "cs_internal.h"

static const u_char mantissa[] = {
    10, 12, 13, 15, 20, 25, 30, 35,
    40, 45, 50, 55, 60, 70, 80, 90
};

static const u_int exponent[] = {
    1, 10, 100, 1000, 10000, 100000, 1000000, 10000000
};

/* Convert an extended speed byte to a time in nanoseconds */
#define SPEED_CVT(v) \
    (mantissa[(((v)>>3)&15)-1] * exponent[(v)&7] / 10)
/* Convert a power byte to a current in 0.1 microamps */
#define POWER_CVT(v) \
    (mantissa[((v)>>3)&15] * exponent[(v)&7] / 10)
#define POWER_SCALE(v)		(exponent[(v)&7])

/* Upper limit on reasonable # of tuples */
#define MAX_TUPLES		200

/*====================================================================*/

/* Parameters that can be set with 'insmod' */

#define INT_MODULE_PARM(n, v) static int n = v; module_param(n, int, 0444)

INT_MODULE_PARM(cis_width,	0);		/* 16-bit CIS? */

void release_cis_mem(struct pcmcia_socket *s)
{
    if (s->cis_mem.flags & MAP_ACTIVE) {
	s->cis_mem.flags &= ~MAP_ACTIVE;
	s->ops->set_mem_map(s, &s->cis_mem);
	if (s->cis_mem.res) {
	    release_resource(s->cis_mem.res);
	    kfree(s->cis_mem.res);
	    s->cis_mem.res = NULL;
	}
	iounmap(s->cis_virt);
	s->cis_virt = NULL;
    }
}
EXPORT_SYMBOL(release_cis_mem);

/*
 * Map the card memory at "card_offset" into virtual space.
 * If flags & MAP_ATTRIB, map the attribute space, otherwise
 * map the memory space.
 */
static void __iomem *
set_cis_map(struct pcmcia_socket *s, unsigned int card_offset, unsigned int flags)
{
	pccard_mem_map *mem = &s->cis_mem;
	int ret;

	if (!(s->features & SS_CAP_STATIC_MAP) && (mem->res == NULL)) {
		mem->res = pcmcia_find_mem_region(0, s->map_size, s->map_size, 0, s);
		if (mem->res == NULL) {
			printk(KERN_NOTICE "cs: unable to map card memory!\n");
			return NULL;
		}
		s->cis_virt = NULL;
	}

	if (!(s->features & SS_CAP_STATIC_MAP) && (!s->cis_virt))
		s->cis_virt = ioremap(mem->res->start, s->map_size);

	mem->card_start = card_offset;
	mem->flags = flags;

	ret = s->ops->set_mem_map(s, mem);
	if (ret) {
		iounmap(s->cis_virt);
		s->cis_virt = NULL;
		return NULL;
	}

	if (s->features & SS_CAP_STATIC_MAP) {
		if (s->cis_virt)
			iounmap(s->cis_virt);
		s->cis_virt = ioremap(mem->static_start, s->map_size);
	}

	return s->cis_virt;
}

/*======================================================================

    Low-level functions to read and write CIS memory.  I think the
    write routine is only useful for writing one-byte registers.
    
======================================================================*/

/* Bits in attr field */
#define IS_ATTR		1
#define IS_INDIRECT	8

int pcmcia_read_cis_mem(struct pcmcia_socket *s, int attr, u_int addr,
		 u_int len, void *ptr)
{
    void __iomem *sys, *end;
    unsigned char *buf = ptr;
    
    cs_dbg(s, 3, "pcmcia_read_cis_mem(%d, %#x, %u)\n", attr, addr, len);

    if (attr & IS_INDIRECT) {
	/* Indirect accesses use a bunch of special registers at fixed
	   locations in common memory */
	u_char flags = ICTRL0_COMMON|ICTRL0_AUTOINC|ICTRL0_BYTEGRAN;
	if (attr & IS_ATTR) {
	    addr *= 2;
	    flags = ICTRL0_AUTOINC;
	}

	sys = set_cis_map(s, 0, MAP_ACTIVE | ((cis_width) ? MAP_16BIT : 0));
	if (!sys) {
	    memset(ptr, 0xff, len);
	    return -1;
	}

	writeb(flags, sys+CISREG_ICTRL0);
	writeb(addr & 0xff, sys+CISREG_IADDR0);
	writeb((addr>>8) & 0xff, sys+CISREG_IADDR1);
	writeb((addr>>16) & 0xff, sys+CISREG_IADDR2);
	writeb((addr>>24) & 0xff, sys+CISREG_IADDR3);
	for ( ; len > 0; len--, buf++)
	    *buf = readb(sys+CISREG_IDATA0);
    } else {
	u_int inc = 1, card_offset, flags;

	flags = MAP_ACTIVE | ((cis_width) ? MAP_16BIT : 0);
	if (attr) {
	    flags |= MAP_ATTRIB;
	    inc++;
	    addr *= 2;
	}

	card_offset = addr & ~(s->map_size-1);
	while (len) {
	    sys = set_cis_map(s, card_offset, flags);
	    if (!sys) {
		memset(ptr, 0xff, len);
		return -1;
	    }
	    end = sys + s->map_size;
	    sys = sys + (addr & (s->map_size-1));
	    for ( ; len > 0; len--, buf++, sys += inc) {
		if (sys == end)
		    break;
		*buf = readb(sys);
	    }
	    card_offset += s->map_size;
	    addr = 0;
	}
    }
    cs_dbg(s, 3, "  %#2.2x %#2.2x %#2.2x %#2.2x ...\n",
	  *(u_char *)(ptr+0), *(u_char *)(ptr+1),
	  *(u_char *)(ptr+2), *(u_char *)(ptr+3));
    return 0;
}
EXPORT_SYMBOL(pcmcia_read_cis_mem);


void pcmcia_write_cis_mem(struct pcmcia_socket *s, int attr, u_int addr,
		   u_int len, void *ptr)
{
    void __iomem *sys, *end;
    unsigned char *buf = ptr;
    
    cs_dbg(s, 3, "pcmcia_write_cis_mem(%d, %#x, %u)\n", attr, addr, len);

    if (attr & IS_INDIRECT) {
	/* Indirect accesses use a bunch of special registers at fixed
	   locations in common memory */
	u_char flags = ICTRL0_COMMON|ICTRL0_AUTOINC|ICTRL0_BYTEGRAN;
	if (attr & IS_ATTR) {
	    addr *= 2;
	    flags = ICTRL0_AUTOINC;
	}

	sys = set_cis_map(s, 0, MAP_ACTIVE | ((cis_width) ? MAP_16BIT : 0));
	if (!sys)
		return; /* FIXME: Error */

	writeb(flags, sys+CISREG_ICTRL0);
	writeb(addr & 0xff, sys+CISREG_IADDR0);
	writeb((addr>>8) & 0xff, sys+CISREG_IADDR1);
	writeb((addr>>16) & 0xff, sys+CISREG_IADDR2);
	writeb((addr>>24) & 0xff, sys+CISREG_IADDR3);
	for ( ; len > 0; len--, buf++)
	    writeb(*buf, sys+CISREG_IDATA0);
    } else {
	u_int inc = 1, card_offset, flags;

	flags = MAP_ACTIVE | ((cis_width) ? MAP_16BIT : 0);
	if (attr & IS_ATTR) {
	    flags |= MAP_ATTRIB;
	    inc++;
	    addr *= 2;
	}

	card_offset = addr & ~(s->map_size-1);
	while (len) {
	    sys = set_cis_map(s, card_offset, flags);
	    if (!sys)
		return; /* FIXME: error */

	    end = sys + s->map_size;
	    sys = sys + (addr & (s->map_size-1));
	    for ( ; len > 0; len--, buf++, sys += inc) {
		if (sys == end)
		    break;
		writeb(*buf, sys);
	    }
	    card_offset += s->map_size;
	    addr = 0;
	}
    }
}
EXPORT_SYMBOL(pcmcia_write_cis_mem);


/*======================================================================

    This is a wrapper around read_cis_mem, with the same interface,
    but which caches information, for cards whose CIS may not be
    readable all the time.
    
======================================================================*/

static void read_cis_cache(struct pcmcia_socket *s, int attr, u_int addr,
			   u_int len, void *ptr)
{
    struct cis_cache_entry *cis;
    int ret;

    if (s->fake_cis) {
	if (s->fake_cis_len > addr+len)
	    memcpy(ptr, s->fake_cis+addr, len);
	else
	    memset(ptr, 0xff, len);
	return;
    }

    list_for_each_entry(cis, &s->cis_cache, node) {
	if (cis->addr == addr && cis->len == len && cis->attr == attr) {
	    memcpy(ptr, cis->cache, len);
	    return;
	}
    }

#ifdef CONFIG_CARDBUS
    if (s->state & SOCKET_CARDBUS)
	ret = read_cb_mem(s, attr, addr, len, ptr);
    else
#endif
	ret = pcmcia_read_cis_mem(s, attr, addr, len, ptr);

	if (ret == 0) {
		/* Copy data into the cache */
		cis = kmalloc(sizeof(struct cis_cache_entry) + len, GFP_KERNEL);
		if (cis) {
			cis->addr = addr;
			cis->len = len;
			cis->attr = attr;
			memcpy(cis->cache, ptr, len);
			list_add(&cis->node, &s->cis_cache);
		}
	}
}

static void
remove_cis_cache(struct pcmcia_socket *s, int attr, u_int addr, u_int len)
{
	struct cis_cache_entry *cis;

	list_for_each_entry(cis, &s->cis_cache, node)
		if (cis->addr == addr && cis->len == len && cis->attr == attr) {
			list_del(&cis->node);
			kfree(cis);
			break;
		}
}

void destroy_cis_cache(struct pcmcia_socket *s)
{
	struct list_head *l, *n;

	list_for_each_safe(l, n, &s->cis_cache) {
		struct cis_cache_entry *cis = list_entry(l, struct cis_cache_entry, node);

		list_del(&cis->node);
		kfree(cis);
	}

	/*
	 * If there was a fake CIS, destroy that as well.
	 */
	if (s->fake_cis) {
		kfree(s->fake_cis);
		s->fake_cis = NULL;
	}
}
EXPORT_SYMBOL(destroy_cis_cache);

/*======================================================================

    This verifies if the CIS of a card matches what is in the CIS
    cache.
    
======================================================================*/

int verify_cis_cache(struct pcmcia_socket *s)
{
	struct cis_cache_entry *cis;
	char *buf;

	buf = kmalloc(256, GFP_KERNEL);
	if (buf == NULL)
		return -1;
	list_for_each_entry(cis, &s->cis_cache, node) {
		int len = cis->len;

		if (len > 256)
			len = 256;
#ifdef CONFIG_CARDBUS
		if (s->state & SOCKET_CARDBUS)
			read_cb_mem(s, cis->attr, cis->addr, len, buf);
		else
#endif
			pcmcia_read_cis_mem(s, cis->attr, cis->addr, len, buf);

		if (memcmp(buf, cis->cache, len) != 0) {
			kfree(buf);
			return -1;
		}
	}
	kfree(buf);
	return 0;
}

/*======================================================================

    For really bad cards, we provide a facility for uploading a
    replacement CIS.
    
======================================================================*/

int pcmcia_replace_cis(struct pcmcia_socket *s, cisdump_t *cis)
{
    if (s->fake_cis != NULL) {
	kfree(s->fake_cis);
	s->fake_cis = NULL;
    }
    if (cis->Length > CISTPL_MAX_CIS_SIZE)
	return CS_BAD_SIZE;
    s->fake_cis = kmalloc(cis->Length, GFP_KERNEL);
    if (s->fake_cis == NULL)
	return CS_OUT_OF_RESOURCE;
    s->fake_cis_len = cis->Length;
    memcpy(s->fake_cis, cis->Data, cis->Length);
    return CS_SUCCESS;
}
EXPORT_SYMBOL(pcmcia_replace_cis);

/*======================================================================

    The high-level CIS tuple services
    
======================================================================*/

typedef struct tuple_flags {
    u_int		link_space:4;
    u_int		has_link:1;
    u_int		mfc_fn:3;
    u_int		space:4;
} tuple_flags;

#define LINK_SPACE(f)	(((tuple_flags *)(&(f)))->link_space)
#define HAS_LINK(f)	(((tuple_flags *)(&(f)))->has_link)
#define MFC_FN(f)	(((tuple_flags *)(&(f)))->mfc_fn)
#define SPACE(f)	(((tuple_flags *)(&(f)))->space)

int pccard_get_next_tuple(struct pcmcia_socket *s, unsigned int func, tuple_t *tuple);

int pccard_get_first_tuple(struct pcmcia_socket *s, unsigned int function, tuple_t *tuple)
{
    if (!s)
	return CS_BAD_HANDLE;
    if (!(s->state & SOCKET_PRESENT))
	return CS_NO_CARD;
    tuple->TupleLink = tuple->Flags = 0;
#ifdef CONFIG_CARDBUS
    if (s->state & SOCKET_CARDBUS) {
	struct pci_dev *dev = s->cb_dev;
	u_int ptr;
	pci_bus_read_config_dword(dev->subordinate, 0, PCI_CARDBUS_CIS, &ptr);
	tuple->CISOffset = ptr & ~7;
	SPACE(tuple->Flags) = (ptr & 7);
    } else
#endif
    {
	/* Assume presence of a LONGLINK_C to address 0 */
	tuple->CISOffset = tuple->LinkOffset = 0;
	SPACE(tuple->Flags) = HAS_LINK(tuple->Flags) = 1;
    }
    if (!(s->state & SOCKET_CARDBUS) && (s->functions > 1) &&
	!(tuple->Attributes & TUPLE_RETURN_COMMON)) {
	cisdata_t req = tuple->DesiredTuple;
	tuple->DesiredTuple = CISTPL_LONGLINK_MFC;
	if (pccard_get_next_tuple(s, function, tuple) == CS_SUCCESS) {
	    tuple->DesiredTuple = CISTPL_LINKTARGET;
	    if (pccard_get_next_tuple(s, function, tuple) != CS_SUCCESS)
		return CS_NO_MORE_ITEMS;
	} else
	    tuple->CISOffset = tuple->TupleLink = 0;
	tuple->DesiredTuple = req;
    }
    return pccard_get_next_tuple(s, function, tuple);
}
EXPORT_SYMBOL(pccard_get_first_tuple);

static int follow_link(struct pcmcia_socket *s, tuple_t *tuple)
{
    u_char link[5];
    u_int ofs;

    if (MFC_FN(tuple->Flags)) {
	/* Get indirect link from the MFC tuple */
	read_cis_cache(s, LINK_SPACE(tuple->Flags),
		       tuple->LinkOffset, 5, link);
	ofs = le32_to_cpu(*(u_int *)(link+1));
	SPACE(tuple->Flags) = (link[0] == CISTPL_MFC_ATTR);
	/* Move to the next indirect link */
	tuple->LinkOffset += 5;
	MFC_FN(tuple->Flags)--;
    } else if (HAS_LINK(tuple->Flags)) {
	ofs = tuple->LinkOffset;
	SPACE(tuple->Flags) = LINK_SPACE(tuple->Flags);
	HAS_LINK(tuple->Flags) = 0;
    } else {
	return -1;
    }
    if (!(s->state & SOCKET_CARDBUS) && SPACE(tuple->Flags)) {
	/* This is ugly, but a common CIS error is to code the long
	   link offset incorrectly, so we check the right spot... */
	read_cis_cache(s, SPACE(tuple->Flags), ofs, 5, link);
	if ((link[0] == CISTPL_LINKTARGET) && (link[1] >= 3) &&
	    (strncmp(link+2, "CIS", 3) == 0))
	    return ofs;
	remove_cis_cache(s, SPACE(tuple->Flags), ofs, 5);
	/* Then, we try the wrong spot... */
	ofs = ofs >> 1;
    }
    read_cis_cache(s, SPACE(tuple->Flags), ofs, 5, link);
    if ((link[0] == CISTPL_LINKTARGET) && (link[1] >= 3) &&
	(strncmp(link+2, "CIS", 3) == 0))
	return ofs;
    remove_cis_cache(s, SPACE(tuple->Flags), ofs, 5);
    return -1;
}

int pccard_get_next_tuple(struct pcmcia_socket *s, unsigned int function, tuple_t *tuple)
{
    u_char link[2], tmp;
    int ofs, i, attr;

    if (!s)
	return CS_BAD_HANDLE;
    if (!(s->state & SOCKET_PRESENT))
	return CS_NO_CARD;

    link[1] = tuple->TupleLink;
    ofs = tuple->CISOffset + tuple->TupleLink;
    attr = SPACE(tuple->Flags);

    for (i = 0; i < MAX_TUPLES; i++) {
	if (link[1] == 0xff) {
	    link[0] = CISTPL_END;
	} else {
	    read_cis_cache(s, attr, ofs, 2, link);
	    if (link[0] == CISTPL_NULL) {
		ofs++; continue;
	    }
	}
	
	/* End of chain?  Follow long link if possible */
	if (link[0] == CISTPL_END) {
	    if ((ofs = follow_link(s, tuple)) < 0)
		return CS_NO_MORE_ITEMS;
	    attr = SPACE(tuple->Flags);
	    read_cis_cache(s, attr, ofs, 2, link);
	}

	/* Is this a link tuple?  Make a note of it */
	if ((link[0] == CISTPL_LONGLINK_A) ||
	    (link[0] == CISTPL_LONGLINK_C) ||
	    (link[0] == CISTPL_LONGLINK_MFC) ||
	    (link[0] == CISTPL_LINKTARGET) ||
	    (link[0] == CISTPL_INDIRECT) ||
	    (link[0] == CISTPL_NO_LINK)) {
	    switch (link[0]) {
	    case CISTPL_LONGLINK_A:
		HAS_LINK(tuple->Flags) = 1;
		LINK_SPACE(tuple->Flags) = attr | IS_ATTR;
		read_cis_cache(s, attr, ofs+2, 4, &tuple->LinkOffset);
		break;
	    case CISTPL_LONGLINK_C:
		HAS_LINK(tuple->Flags) = 1;
		LINK_SPACE(tuple->Flags) = attr & ~IS_ATTR;
		read_cis_cache(s, attr, ofs+2, 4, &tuple->LinkOffset);
		break;
	    case CISTPL_INDIRECT:
		HAS_LINK(tuple->Flags) = 1;
		LINK_SPACE(tuple->Flags) = IS_ATTR | IS_INDIRECT;
		tuple->LinkOffset = 0;
		break;
	    case CISTPL_LONGLINK_MFC:
		tuple->LinkOffset = ofs + 3;
		LINK_SPACE(tuple->Flags) = attr;
		if (function == BIND_FN_ALL) {
		    /* Follow all the MFC links */
		    read_cis_cache(s, attr, ofs+2, 1, &tmp);
		    MFC_FN(tuple->Flags) = tmp;
		} else {
		    /* Follow exactly one of the links */
		    MFC_FN(tuple->Flags) = 1;
		    tuple->LinkOffset += function * 5;
		}
		break;
	    case CISTPL_NO_LINK:
		HAS_LINK(tuple->Flags) = 0;
		break;
	    }
	    if ((tuple->Attributes & TUPLE_RETURN_LINK) &&
		(tuple->DesiredTuple == RETURN_FIRST_TUPLE))
		break;
	} else
	    if (tuple->DesiredTuple == RETURN_FIRST_TUPLE)
		break;
	
	if (link[0] == tuple->DesiredTuple)
	    break;
	ofs += link[1] + 2;
    }
    if (i == MAX_TUPLES) {
	cs_dbg(s, 1, "cs: overrun in pcmcia_get_next_tuple\n");
	return CS_NO_MORE_ITEMS;
    }
    
    tuple->TupleCode = link[0];
    tuple->TupleLink = link[1];
    tuple->CISOffset = ofs + 2;
    return CS_SUCCESS;
}
EXPORT_SYMBOL(pccard_get_next_tuple);

/*====================================================================*/

#define _MIN(a, b)		(((a) < (b)) ? (a) : (b))

int pccard_get_tuple_data(struct pcmcia_socket *s, tuple_t *tuple)
{
    u_int len;

    if (!s)
	return CS_BAD_HANDLE;

    if (tuple->TupleLink < tuple->TupleOffset)
	return CS_NO_MORE_ITEMS;
    len = tuple->TupleLink - tuple->TupleOffset;
    tuple->TupleDataLen = tuple->TupleLink;
    if (len == 0)
	return CS_SUCCESS;
    read_cis_cache(s, SPACE(tuple->Flags),
		   tuple->CISOffset + tuple->TupleOffset,
		   _MIN(len, tuple->TupleDataMax), tuple->TupleData);
    return CS_SUCCESS;
}
EXPORT_SYMBOL(pccard_get_tuple_data);


/*======================================================================

    Parsing routines for individual tuples
    
======================================================================*/

static int parse_device(tuple_t *tuple, cistpl_device_t *device)
{
    int i;
    u_char scale;
    u_char *p, *q;

    p = (u_char *)tuple->TupleData;
    q = p + tuple->TupleDataLen;

    device->ndev = 0;
    for (i = 0; i < CISTPL_MAX_DEVICES; i++) {
	
	if (*p == 0xff) break;
	device->dev[i].type = (*p >> 4);
	device->dev[i].wp = (*p & 0x08) ? 1 : 0;
	switch (*p & 0x07) {
	case 0: device->dev[i].speed = 0;   break;
	case 1: device->dev[i].speed = 250; break;
	case 2: device->dev[i].speed = 200; break;
	case 3: device->dev[i].speed = 150; break;
	case 4: device->dev[i].speed = 100; break;
	case 7:
	    if (++p == q) return CS_BAD_TUPLE;
	    device->dev[i].speed = SPEED_CVT(*p);
	    while (*p & 0x80)
		if (++p == q) return CS_BAD_TUPLE;
	    break;
	default:
	    return CS_BAD_TUPLE;
	}

	if (++p == q) return CS_BAD_TUPLE;
	if (*p == 0xff) break;
	scale = *p & 7;
	if (scale == 7) return CS_BAD_TUPLE;
	device->dev[i].size = ((*p >> 3) + 1) * (512 << (scale*2));
	device->ndev++;
	if (++p == q) break;
    }
    
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_checksum(tuple_t *tuple, cistpl_checksum_t *csum)
{
    u_char *p;
    if (tuple->TupleDataLen < 5)
	return CS_BAD_TUPLE;
    p = (u_char *)tuple->TupleData;
    csum->addr = tuple->CISOffset+(short)le16_to_cpu(*(u_short *)p)-2;
    csum->len = le16_to_cpu(*(u_short *)(p + 2));
    csum->sum = *(p+4);
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_longlink(tuple_t *tuple, cistpl_longlink_t *link)
{
    if (tuple->TupleDataLen < 4)
	return CS_BAD_TUPLE;
    link->addr = le32_to_cpu(*(u_int *)tuple->TupleData);
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_longlink_mfc(tuple_t *tuple,
			      cistpl_longlink_mfc_t *link)
{
    u_char *p;
    int i;
    
    p = (u_char *)tuple->TupleData;
    
    link->nfn = *p; p++;
    if (tuple->TupleDataLen <= link->nfn*5)
	return CS_BAD_TUPLE;
    for (i = 0; i < link->nfn; i++) {
	link->fn[i].space = *p; p++;
	link->fn[i].addr = le32_to_cpu(*(u_int *)p); p += 4;
    }
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_strings(u_char *p, u_char *q, int max,
			 char *s, u_char *ofs, u_char *found)
{
    int i, j, ns;

    if (p == q) return CS_BAD_TUPLE;
    ns = 0; j = 0;
    for (i = 0; i < max; i++) {
	if (*p == 0xff) break;
	ofs[i] = j;
	ns++;
	for (;;) {
	    s[j++] = (*p == 0xff) ? '\0' : *p;
	    if ((*p == '\0') || (*p == 0xff)) break;
	    if (++p == q) return CS_BAD_TUPLE;
	}
	if ((*p == 0xff) || (++p == q)) break;
    }
    if (found) {
	*found = ns;
	return CS_SUCCESS;
    } else {
	return (ns == max) ? CS_SUCCESS : CS_BAD_TUPLE;
    }
}

/*====================================================================*/

static int parse_vers_1(tuple_t *tuple, cistpl_vers_1_t *vers_1)
{
    u_char *p, *q;
    
    p = (u_char *)tuple->TupleData;
    q = p + tuple->TupleDataLen;
    
    vers_1->major = *p; p++;
    vers_1->minor = *p; p++;
    if (p >= q) return CS_BAD_TUPLE;

    return parse_strings(p, q, CISTPL_VERS_1_MAX_PROD_STRINGS,
			 vers_1->str, vers_1->ofs, &vers_1->ns);
}

/*====================================================================*/

static int parse_altstr(tuple_t *tuple, cistpl_altstr_t *altstr)
{
    u_char *p, *q;
    
    p = (u_char *)tuple->TupleData;
    q = p + tuple->TupleDataLen;
    
    return parse_strings(p, q, CISTPL_MAX_ALTSTR_STRINGS,
			 altstr->str, altstr->ofs, &altstr->ns);
}

/*====================================================================*/

static int parse_jedec(tuple_t *tuple, cistpl_jedec_t *jedec)
{
    u_char *p, *q;
    int nid;

    p = (u_char *)tuple->TupleData;
    q = p + tuple->TupleDataLen;

    for (nid = 0; nid < CISTPL_MAX_DEVICES; nid++) {
	if (p > q-2) break;
	jedec->id[nid].mfr = p[0];
	jedec->id[nid].info = p[1];
	p += 2;
    }
    jedec->nid = nid;
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_manfid(tuple_t *tuple, cistpl_manfid_t *m)
{
    u_short *p;
    if (tuple->TupleDataLen < 4)
	return CS_BAD_TUPLE;
    p = (u_short *)tuple->TupleData;
    m->manf = le16_to_cpu(p[0]);
    m->card = le16_to_cpu(p[1]);
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_funcid(tuple_t *tuple, cistpl_funcid_t *f)
{
    u_char *p;
    if (tuple->TupleDataLen < 2)
	return CS_BAD_TUPLE;
    p = (u_char *)tuple->TupleData;
    f->func = p[0];
    f->sysinit = p[1];
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_funce(tuple_t *tuple, cistpl_funce_t *f)
{
    u_char *p;
    int i;
    if (tuple->TupleDataLen < 1)
	return CS_BAD_TUPLE;
    p = (u_char *)tuple->TupleData;
    f->type = p[0];
    for (i = 1; i < tuple->TupleDataLen; i++)
	f->data[i-1] = p[i];
    return CS_SUCCESS;
}

/*====================================================================*/

static int parse_config(tuple_t *tuple, cistpl_config_t *config)
{
    int rasz, rmsz, i;
    u_char *p;

    p = (u_char *)tuple->TupleData;
    rasz = *p & 0x03;
    rmsz = (*p & 0x3c) >> 2;
    if (tuple->TupleDataLen < rasz+rmsz+4)
	return CS_BAD_TUPLE;
    config->last_idx = *(++p);
    p++;
    config->base = 0;
    for (i = 0; i <= rasz; i++)
	config->base += p[i] << (8*i);
    p += rasz+1;
    for (i = 0; i < 4; i++)
	config->rmask[i] = 0;
    for (i = 0; i <= rmsz; i++)
	config->rmask[i>>2] += p[i] << (8*(i%4));
    config->subtuples = tuple->TupleDataLen - (rasz+rmsz+4);
    return CS_SUCCESS;
}

/*======================================================================

    The following routines are all used to parse the nightmarish
    config table entries.
    
======================================================================*/

static u_char *parse_power(u_char *p, u_char *q,
			   cistpl_power_t *pwr)
{
    int i;
    u_int scale;

    if (p == q) return NULL;
    pwr->present = *p;
    pwr->flags = 0;
    p++;
    for (i = 0; i < 7; i++)
	if (pwr->present & (1<<i)) {
	    if (p == q) return NULL;
	    pwr->param[i] = POWER_CVT(*p);
	    scale = POWER_SCALE(*p);
	    while (*p & 0x80) {
		if (++p == q) return NULL;
		if ((*p & 0x7f) < 100)
		    pwr->param[i] += (*p & 0x7f) * scale / 100;
		else if (*p == 0x7d)
		    pwr->flags |= CISTPL_POWER_HIGHZ_OK;
		else if (*p == 0x7e)
		    pwr->param[i] = 0;
		else if (*p == 0x7f)
		    pwr->flags |= CISTPL_POWER_HIGHZ_REQ;
		else
		    return NULL;
	    }
	    p++;
	}
    return p;
}

/*====================================================================*/

static u_char *parse_timing(u_char *p, u_char *q,
			    cistpl_timing_t *timing)
{
    u_char scale;

    if (p == q) return NULL;
    scale = *p;
    if ((scale & 3) != 3) {
	if (++p == q) return NULL;
	timing->wait = SPEED_CVT(*p);
	timing->waitscale = exponent[scale & 3];
    } else
	timing->wait = 0;
    scale >>= 2;
    if ((scale & 7) != 7) {
	if (++p == q) return NULL;
	timing->ready = SPEED_CVT(*p);
	timing->rdyscale = exponent[scale & 7];
    } else
	timing->ready = 0;
    scale >>= 3;
    if (scale != 7) {
	if (++p == q) return NULL;
	timing->reserved = SPEED_CVT(*p);
	timing->rsvscale = exponent[scale];
    } else
	timing->reserved = 0;
    p++;
    return p;
}

/*====================================================================*/

static u_char *parse_io(u_char *p, u_char *q, cistpl_io_t *io)
{
    int i, j, bsz, lsz;

    if (p == q) return NULL;
    io->flags = *p;

    if (!(*p & 0x80)) {
	io->nwin = 1;
	io->win[0].base = 0;
	io->win[0].len = (1 << (io->flags & CISTPL_IO_LINES_MASK));
	return p+1;
    }
    
    if (++p == q) return NULL;
    io->nwin = (*p & 0x0f) + 1;
    bsz = (*p & 0x30) >> 4;
    if (bsz == 3) bsz++;
    lsz = (*p & 0xc0) >> 6;
    if (lsz == 3) lsz++;
    p++;
    
    for (i = 0; i < io->nwin; i++) {
	io->win[i].base = 0;
	io->win[i].len = 1;
	for (j = 0; j < bsz; j++, p++) {
	    if (p == q) return NULL;
	    io->win[i].base += *p << (j*8);
	}
	for (j = 0; j < lsz; j++, p++) {
	    if (p == q) return NULL;
	    io->win[i].len += *p << (j*8);
	}
    }
    return p;
}

/*====================================================================*/

static u_char *parse_mem(u_char *p, u_char *q, cistpl_mem_t *mem)
{
    int i, j, asz, lsz, has_ha;
    u_int len, ca, ha;

    if (p == q) return NULL;

    mem->nwin = (*p & 0x07) + 1;
    lsz = (*p & 0x18) >> 3;
    asz = (*p & 0x60) >> 5;
    has_ha = (*p & 0x80);
    if (++p == q) return NULL;
    
    for (i = 0; i < mem->nwin; i++) {
	len = ca = ha = 0;
	for (j = 0; j < lsz; j++, p++) {
	    if (p == q) return NULL;
	    len += *p << (j*8);
	}
	for (j = 0; j < asz; j++, p++) {
	    if (p == q) return NULL;
	    ca += *p << (j*8);
	}
	if (has_ha)
	    for (j = 0; j < asz; j++, p++) {
		if (p == q) return NULL;
		ha += *p << (j*8);
	    }
	mem->win[i].len = len << 8;
	mem->win[i].card_addr = ca << 8;
	mem->win[i].host_addr = ha << 8;
    }
    return p;
}

/*====================================================================*/

static u_char *parse_irq(u_char *p, u_char *q, cistpl_irq_t *irq)
{
    if (p == q) return NULL;
    irq->IRQInfo1 = *p; p++;
    if (irq->IRQInfo1 & IRQ_INFO2_VALID) {
	if (p+2 > q) return NULL;
	irq->IRQInfo2 = (p[1]<<8) + p[0];
	p += 2;
    }
    return p;
}

/*====================================================================*/

static int parse_cftable_entry(tuple_t *tuple,
			       cistpl_cftable_entry_t *entry)
{
    u_char *p, *q, features;

    p = tuple->TupleData;
    q = p + tuple->TupleDataLen;
    entry->index = *p & 0x3f;
    entry->flags = 0;
    if (*p & 0x40)
	entry->flags |= CISTPL_CFTABLE_DEFAULT;
    if (*p & 0x80) {
	if (++p == q) return CS_BAD_TUPLE;
	if (*p & 0x10)
	    entry->flags |= CISTPL_CFTABLE_BVDS;
	if (*p & 0x20)
	    entry->flags |= CISTPL_CFTABLE_WP;
	if (*p & 0x40)
	    entry->flags |= CISTPL_CFTABLE_RDYBSY;
	if (*p & 0x80)
	    entry->flags |= CISTPL_CFTABLE_MWAIT;
	entry->interface = *p & 0x0f;
    } else
	entry->interface = 0;

    /* Process optional features */
    if (++p == q) return CS_BAD_TUPLE;
    features = *p; p++;

    /* Power options */
    if ((features & 3) > 0) {
	p = parse_power(p, q, &entry->vcc);
	if (p == NULL) return CS_BAD_TUPLE;
    } else
	entry->vcc.present = 0;
    if ((features & 3) > 1) {
	p = parse_power(p, q, &entry->vpp1);
	if (p == NULL) return CS_BAD_TUPLE;
    } else
	entry->vpp1.present = 0;
    if ((features & 3) > 2) {
	p = parse_power(p, q, &entry->vpp2);
	if (p == NULL) return CS_BAD_TUPLE;
    } else
	entry->vpp2.present = 0;

    /* Timing options */
    if (features & 0x04) {
	p = parse_timing(p, q, &entry->timing);
	if (p == NULL) return CS_BAD_TUPLE;
    } else {
	entry->timing.wait = 0;
	entry->timing.ready = 0;
	entry->timing.reserved = 0;
    }
    
    /* I/O window options */
    if (features & 0x08) {
	p = parse_io(p, q, &entry->io);
	if (p == NULL) return CS_BAD_TUPLE;
    } else
	entry->io.nwin = 0;
    
    /* Interrupt options */
    if (features & 0x10) {
	p = parse_irq(p, q, &entry->irq);
	if (p == NULL) return CS_BAD_TUPLE;
    } else
	entry->irq.IRQInfo1 = 0;

    switch (features & 0x60) {
    case 0x00:
	entry->mem.nwin = 0;
	break;
    case 0x20:
	entry->mem.nwin = 1;
	entry->mem.win[0].len = le16_to_cpu(*(u_short *)p) << 8;
	entry->mem.win[0].card_addr = 0;
	entry->mem.win[0].host_addr = 0;
	p += 2;
	if (p > q) return CS_BAD_TUPLE;
	break;
    case 0x40:
	entry->mem.nwin = 1;
	entry->mem.win[0].len = le16_to_cpu(*(u_short *)p) << 8;
	entry->mem.win[0].card_addr =
	    le16_to_cpu(*(u_short *)(p+2)) << 8;
	entry->mem.win[0].host_addr = 0;
	p += 4;
	if (p > q) return CS_BAD_TUPLE;
	break;
    case 0x60:
	p = parse_mem(p, q, &entry->mem);
	if (p == NULL) return CS_BAD_TUPLE;
	break;
    }

    /* Misc features */
    if (features & 0x80) {
	if (p == q) return CS_BAD_TUPLE;
	entry->flags |= (*p << 8);
	while (*p & 0x80)
	    if (++p == q) return CS_BAD_TUPLE;
	p++;
    }

    entry->subtuples = q-p;