1
/*-
2
 * SPDX-License-Identifier: BSD-2-Clause
3
 *
4
 * Copyright (c) 2015 Dmitry Chagin <[email protected]>
5
 *
6
 * Redistribution and use in source and binary forms, with or without
7
 * modification, are permitted provided that the following conditions
8
 * are met:
9
 * 1. Redistributions of source code must retain the above copyright
10
 *    notice, this list of conditions and the following disclaimer.
11
 * 2. Redistributions in binary form must reproduce the above copyright
12
 *    notice, this list of conditions and the following disclaimer in the
13
 *    documentation and/or other materials provided with the distribution.
14
 *
15
 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
16
 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
17
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
18
 * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
19
 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
20
 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
21
 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
22
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
23
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
24
 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
25
 * SUCH DAMAGE.
26
 */
27

28
#ifndef _LINUX_MI_H_
29
#define _LINUX_MI_H_
30

31
/*
32
 * Machine independent set of types for the Linux types.
33
 */
34
typedef uint32_t	l_dev_t;
35

36
/*
37
 * Linux dev_t conversion routines.
38
 *
39
 * As of version 2.6.0 of the Linux kernel, dev_t is a 32-bit quantity
40
 * with 12 bits set asaid for the major number and 20 for the minor number.
41
 * The in-kernel dev_t encoded as MMMmmmmm, where M is a hex digit of the
42
 * major number and m is a hex digit of the minor number.
43
 * The user-space dev_t encoded as mmmM MMmm, where M and m is the major
44
 * and minor numbers accordingly. This is downward compatible with legacy
45
 * systems where dev_t is 16 bits wide, encoded as MMmm.
46
 * In glibc dev_t is a 64-bit quantity, with 32-bit major and minor numbers,
47
 * encoded as MMMM Mmmm mmmM MMmm. This is downward compatible with the Linux
48
 * kernel and with legacy systems where dev_t is 16 bits wide.
49
 *
50
 * In the FreeBSD dev_t is a 64-bit quantity. The major and minor numbers
51
 * are encoded as MMMmmmMm, therefore conversion of the device numbers between
52
 * Linux user-space and FreeBSD kernel required.
53
 */
54
static __inline l_dev_t
55
linux_encode_dev(int _major, int _minor)
56
{
57

58
	return ((_minor & 0xff) | ((_major & 0xfff) << 8) |
59
	    (((_minor & ~0xff) << 12) & 0xfff00000));
60
}
61

62
static __inline l_dev_t
63
linux_new_encode_dev(dev_t _dev)
64
{
65

66
	return (_dev == NODEV ? 0 : linux_encode_dev(major(_dev), minor(_dev)));
67
}
68

69
static __inline int
70
linux_encode_major(dev_t _dev)
71
{
72

73
	return (_dev == NODEV ? 0 : major(_dev) & 0xfff);
74
}
75

76
static __inline int
77
linux_encode_minor(dev_t _dev)
78
{
79

80
	return (_dev == NODEV ? 0 : minor(_dev) & 0xfffff);
81
}
82

83
static __inline int
84
linux_decode_major(l_dev_t _dev)
85
{
86

87
	return ((_dev & 0xfff00) >> 8);
88
}
89

90
static __inline int
91
linux_decode_minor(l_dev_t _dev)
92
{
93

94
	return ((_dev & 0xff) | ((_dev & 0xfff00000) >> 12));
95
}
96

97
static __inline dev_t
98
linux_decode_dev(l_dev_t _dev)
99
{
100

101
	return (makedev(linux_decode_major(_dev), linux_decode_minor(_dev)));
102
}
103

104
/*
105
 * Private Brandinfo flags
106
 */
107
#define	LINUX_BI_FUTEX_REQUEUE	0x01000000
108

109
/*
110
 * poll()
111
 */
112
#define	LINUX_POLLIN		0x0001
113
#define	LINUX_POLLPRI		0x0002
114
#define	LINUX_POLLOUT		0x0004
115
#define	LINUX_POLLERR		0x0008
116
#define	LINUX_POLLHUP		0x0010
117
#define	LINUX_POLLNVAL		0x0020
118
#define	LINUX_POLLRDNORM	0x0040
119
#define	LINUX_POLLRDBAND	0x0080
120
#define	LINUX_POLLWRNORM	0x0100
121
#define	LINUX_POLLWRBAND	0x0200
122
#define	LINUX_POLLMSG		0x0400
123
#define	LINUX_POLLREMOVE	0x1000
124
#define	LINUX_POLLRDHUP		0x2000
125

126
#define	LINUX_IFHWADDRLEN	6
127
#define	LINUX_IFNAMSIZ		16
128

129
struct l_sockaddr {
130
	unsigned short	sa_family;
131
	char		sa_data[14];
132
};
133

134
#define	LINUX_ARPHRD_ETHER	1
135
#define	LINUX_ARPHRD_LOOPBACK	772
136

137
/*
138
 * Supported address families
139
 */
140
#define	LINUX_AF_UNSPEC		0
141
#define	LINUX_AF_UNIX		1
142
#define	LINUX_AF_INET		2
143
#define	LINUX_AF_AX25		3
144
#define	LINUX_AF_IPX		4
145
#define	LINUX_AF_APPLETALK	5
146
#define	LINUX_AF_INET6		10
147
#define	LINUX_AF_NETLINK	16
148

149
#define	LINUX_NETLINK_ROUTE		0
150
#define	LINUX_NETLINK_SOCK_DIAG		4
151
#define	LINUX_NETLINK_NFLOG		5
152
#define	LINUX_NETLINK_SELINUX		7
153
#define	LINUX_NETLINK_AUDIT		9
154
#define	LINUX_NETLINK_FIB_LOOKUP	10
155
#define	LINUX_NETLINK_NETFILTER		12
156
#define	LINUX_NETLINK_KOBJECT_UEVENT	15
157

158
/*
159
 * net device flags
160
 */
161
#define	LINUX_IFF_UP		0x0001
162
#define	LINUX_IFF_BROADCAST	0x0002
163
#define	LINUX_IFF_DEBUG		0x0004
164
#define	LINUX_IFF_LOOPBACK	0x0008
165
#define	LINUX_IFF_POINTOPOINT	0x0010
166
#define	LINUX_IFF_NOTRAILERS	0x0020
167
#define	LINUX_IFF_RUNNING	0x0040
168
#define	LINUX_IFF_NOARP		0x0080
169
#define	LINUX_IFF_PROMISC	0x0100
170
#define	LINUX_IFF_ALLMULTI	0x0200
171
#define	LINUX_IFF_MASTER	0x0400
172
#define	LINUX_IFF_SLAVE		0x0800
173
#define	LINUX_IFF_MULTICAST	0x1000
174
#define	LINUX_IFF_PORTSEL	0x2000
175
#define	LINUX_IFF_AUTOMEDIA	0x4000
176
#define	LINUX_IFF_DYNAMIC	0x8000
177

178
/* sigaltstack */
179
#define	LINUX_SS_ONSTACK	1
180
#define	LINUX_SS_DISABLE	2
181

182
int linux_to_bsd_sigaltstack(int lsa);
183
int bsd_to_linux_sigaltstack(int bsa);
184

185
/* sigset */
186
typedef struct {
187
	uint64_t	__mask;
188
} l_sigset_t;
189

190
/* primitives to manipulate sigset_t */
191
#define	LINUX_SIGEMPTYSET(set)		(set).__mask = 0
192
#define	LINUX_SIGISMEMBER(set, sig)	(1ULL & ((set).__mask >> _SIG_IDX(sig)))
193
#define	LINUX_SIGADDSET(set, sig)	(set).__mask |= 1ULL << _SIG_IDX(sig)
194

195
void linux_to_bsd_sigset(l_sigset_t *, sigset_t *);
196
void bsd_to_linux_sigset(sigset_t *, l_sigset_t *);
197

198
/* signaling */
199
#define	LINUX_SIGHUP		1
200
#define	LINUX_SIGINT		2
201
#define	LINUX_SIGQUIT		3
202
#define	LINUX_SIGILL		4
203
#define	LINUX_SIGTRAP		5
204
#define	LINUX_SIGABRT		6
205
#define	LINUX_SIGIOT		LINUX_SIGABRT
206
#define	LINUX_SIGBUS		7
207
#define	LINUX_SIGFPE		8
208
#define	LINUX_SIGKILL		9
209
#define	LINUX_SIGUSR1		10
210
#define	LINUX_SIGSEGV		11
211
#define	LINUX_SIGUSR2		12
212
#define	LINUX_SIGPIPE		13
213
#define	LINUX_SIGALRM		14
214
#define	LINUX_SIGTERM		15
215
#define	LINUX_SIGSTKFLT		16
216
#define	LINUX_SIGCHLD		17
217
#define	LINUX_SIGCONT		18
218
#define	LINUX_SIGSTOP		19
219
#define	LINUX_SIGTSTP		20
220
#define	LINUX_SIGTTIN		21
221
#define	LINUX_SIGTTOU		22
222
#define	LINUX_SIGURG		23
223
#define	LINUX_SIGXCPU		24
224
#define	LINUX_SIGXFSZ		25
225
#define	LINUX_SIGVTALRM		26
226
#define	LINUX_SIGPROF		27
227
#define	LINUX_SIGWINCH		28
228
#define	LINUX_SIGIO		29
229
#define	LINUX_SIGPOLL		LINUX_SIGIO
230
#define	LINUX_SIGPWR		30
231
#define	LINUX_SIGSYS		31
232
#define	LINUX_SIGTBLSZ		31
233
#define	LINUX_SIGRTMIN		32
234
#define	LINUX_SIGRTMAX		64
235

236
#define LINUX_SIG_VALID(sig)	((sig) <= LINUX_SIGRTMAX && (sig) > 0)
237

238
int linux_to_bsd_signal(int sig);
239
int bsd_to_linux_signal(int sig);
240

241
/* sigprocmask actions */
242
#define	LINUX_SIG_BLOCK		0
243
#define	LINUX_SIG_UNBLOCK	1
244
#define	LINUX_SIG_SETMASK	2
245

246
void linux_dev_shm_create(void);
247
void linux_dev_shm_destroy(void);
248

249
/*
250
 * mask=0 is not sensible for this application, so it will be taken to mean
251
 * a mask equivalent to the value.  Otherwise, (word & mask) == value maps to
252
 * (word & ~mask) | value in a bitfield for the platform we're converting to.
253
 */
254
struct bsd_to_linux_bitmap {
255
	int	bsd_mask;
256
	int	bsd_value;
257
	int	linux_mask;
258
	int	linux_value;
259
};
260

261
int bsd_to_linux_bits_(int value, struct bsd_to_linux_bitmap *bitmap,
262
    size_t mapcnt, int no_value);
263
int linux_to_bsd_bits_(int value, struct bsd_to_linux_bitmap *bitmap,
264
    size_t mapcnt, int no_value);
265

266
/*
267
 * These functions are used for simplification of BSD <-> Linux bit conversions.
268
 * Given `value`, a bit field, these functions will walk the given bitmap table
269
 * and set the appropriate bits for the target platform.  If any bits were
270
 * successfully converted, then the return value is the equivalent of value
271
 * represented with the bit values appropriate for the target platform.
272
 * Otherwise, the value supplied as `no_value` is returned.
273
 */
274
#define	bsd_to_linux_bits(_val, _bmap, _noval) \
275
    bsd_to_linux_bits_((_val), (_bmap), nitems((_bmap)), (_noval))
276
#define	linux_to_bsd_bits(_val, _bmap, _noval) \
277
    linux_to_bsd_bits_((_val), (_bmap), nitems((_bmap)), (_noval))
278

279
/*
280
 * Easy mapping helpers.  BITMAP_EASY_LINUX represents a single bit to be
281
 * translated, and the FreeBSD and Linux values are supplied.  BITMAP_1t1_LINUX
282
 * is the extreme version of this, where not only is it a single bit, but the
283
 * name of the macro used to represent the Linux version of a bit literally has
284
 * LINUX_ prepended to the normal name.
285
 */
286
#define	BITMAP_EASY_LINUX(_name, _linux_name)	\
287
	{					\
288
		.bsd_value = (_name),		\
289
		.linux_value = (_linux_name),	\
290
	}
291
#define	BITMAP_1t1_LINUX(_name)	BITMAP_EASY_LINUX(_name, LINUX_##_name)
292

293
int bsd_to_linux_errno(int error);
294
void linux_check_errtbl(void);
295

296
#define STATX_BASIC_STATS		0x07ff
297
#define STATX_BTIME			0x0800
298
#define STATX_ALL			0x0fff
299

300
#define STATX_ATTR_COMPRESSED		0x0004
301
#define STATX_ATTR_IMMUTABLE		0x0010
302
#define STATX_ATTR_APPEND		0x0020
303
#define STATX_ATTR_NODUMP		0x0040
304
#define STATX_ATTR_ENCRYPTED		0x0800
305
#define STATX_ATTR_AUTOMOUNT		0x1000
306

307
struct l_statx_timestamp {
308
	int64_t tv_sec;
309
	int32_t tv_nsec;
310
	int32_t __spare0;
311
};
312

313
struct l_statx {
314
	uint32_t stx_mask;
315
	uint32_t stx_blksize;
316
	uint64_t stx_attributes;
317
	uint32_t stx_nlink;
318
	uint32_t stx_uid;
319
	uint32_t stx_gid;
320
	uint16_t stx_mode;
321
	uint16_t __spare0[1];
322
	uint64_t stx_ino;
323
	uint64_t stx_size;
324
	uint64_t stx_blocks;
325
	uint64_t stx_attributes_mask;
326
	struct l_statx_timestamp stx_atime;
327
	struct l_statx_timestamp stx_btime;
328
	struct l_statx_timestamp stx_ctime;
329
	struct l_statx_timestamp stx_mtime;
330
	uint32_t stx_rdev_major;
331
	uint32_t stx_rdev_minor;
332
	uint32_t stx_dev_major;
333
	uint32_t stx_dev_minor;
334
	uint64_t stx_mnt_id;
335
	uint64_t __spare2[13];
336
};
337

338
/*
339
 * statfs f_flags
340
 */
341
#define	LINUX_ST_RDONLY			0x0001
342
#define	LINUX_ST_NOSUID			0x0002
343
#define	LINUX_ST_NODEV			0x0004	/* No native analogue */
344
#define	LINUX_ST_NOEXEC			0x0008
345
#define	LINUX_ST_SYNCHRONOUS		0x0010
346
#define	LINUX_ST_VALID			0x0020
347
#define	LINUX_ST_MANDLOCK		0x0040	/* No native analogue */
348
#define	LINUX_ST_NOATIME		0x0400
349
#define	LINUX_ST_NODIRATIME		0x0800	/* No native analogue */
350
#define	LINUX_ST_RELATIME		0x1000	/* No native analogue */
351
#define	LINUX_ST_NOSYMFOLLOW		0x2000
352

353
#ifndef lower_32_bits
354
#define	lower_32_bits(n)	((uint32_t)((n) & 0xffffffff))
355
#endif
356

357
#ifdef KTRACE
358
#define	linux_ktrsigset(s, l)	\
359
	ktrstruct("l_sigset_t", (s), l)
360
#endif
361

362
/*
363
 * Criteria for interface name translation
364
 */
365
#define	IFP_IS_ETH(ifp)		(if_gettype(ifp) == IFT_ETHER)
366
#define	IFP_IS_LOOP(ifp)	(if_gettype(ifp) == IFT_LOOP)
367

368
struct ifnet;
369

370
bool linux_use_real_ifname(const struct ifnet *);
371

372
void linux_netlink_register(void);
373
void linux_netlink_deregister(void);
374

375
#endif /* _LINUX_MI_H_ */
376

377