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
|
/*
Unix SMB/CIFS implementation.
SMB Byte handling
Copyright (C) Andrew Tridgell 1992-1998
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 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef _BYTEORDER_H
#define _BYTEORDER_H
/*
This file implements macros for machine independent short and
int manipulation
Here is a description of this file that I emailed to the samba list once:
> I am confused about the way that byteorder.h works in Samba. I have
> looked at it, and I would have thought that you might make a distinction
> between LE and BE machines, but you only seem to distinguish between 386
> and all other architectures.
>
> Can you give me a clue?
sure.
Ok, now to the macros themselves. I'll take a simple example, say we
want to extract a 2 byte integer from a SMB packet and put it into a
type called uint16_t that is in the local machines byte order, and you
want to do it with only the assumption that uint16_t is _at_least_ 16
bits long (this last condition is very important for architectures
that don't have any int types that are 2 bytes long)
You do this:
#define CVAL(buf,pos) (((uint8_t *)(buf))[pos])
#define PVAL(buf,pos) ((unsigned int)CVAL(buf,pos))
#define SVAL(buf,pos) (PVAL(buf,pos)|PVAL(buf,(pos)+1)<<8)
then to extract a uint16_t value at offset 25 in a buffer you do this:
char *buffer = foo_bar();
uint16_t xx = SVAL(buffer,25);
We are using the byteoder independence of the ANSI C bitshifts to do
the work. A good optimising compiler should turn this into efficient
code, especially if it happens to have the right byteorder :-)
I know these macros can be made a bit tidier by removing some of the
casts, but you need to look at byteorder.h as a whole to see the
reasoning behind them. byteorder.h defines the following macros:
SVAL(buf,pos) - extract a 2 byte SMB value
IVAL(buf,pos) - extract a 4 byte SMB value
BVAL(buf,pos) - extract a 8 byte SMB value
SVALS(buf,pos) - signed version of SVAL()
IVALS(buf,pos) - signed version of IVAL()
BVALS(buf,pos) - signed version of BVAL()
SSVAL(buf,pos,val) - put a 2 byte SMB value into a buffer
SIVAL(buf,pos,val) - put a 4 byte SMB value into a buffer
SBVAL(buf,pos,val) - put a 8 byte SMB value into a buffer
SSVALS(buf,pos,val) - signed version of SSVAL()
SIVALS(buf,pos,val) - signed version of SIVAL()
SBVALS(buf,pos,val) - signed version of SBVAL()
RSVAL(buf,pos) - like SVAL() but for NMB byte ordering
RSVALS(buf,pos) - like SVALS() but for NMB byte ordering
RIVAL(buf,pos) - like IVAL() but for NMB byte ordering
RIVALS(buf,pos) - like IVALS() but for NMB byte ordering
RSSVAL(buf,pos,val) - like SSVAL() but for NMB ordering
RSIVAL(buf,pos,val) - like SIVAL() but for NMB ordering
RSIVALS(buf,pos,val) - like SIVALS() but for NMB ordering
it also defines lots of intermediate macros, just ignore those :-)
*/
/*
* On powerpc we can use the magic instructions to load/store in little endian.
* The instructions are reverse-indexing, so assume a big endian Power
* processor. Power8 can be big or little endian, so we need to explicitly
* check.
*/
#if (defined(__powerpc__) && defined(__GNUC__) && HAVE_BIG_ENDIAN)
static __inline__ uint16_t ld_le16(const uint16_t *addr)
{
uint16_t val;
__asm__ ("lhbrx %0,0,%1" : "=r" (val) : "r" (addr), "m" (*addr));
return val;
}
static __inline__ void st_le16(uint16_t *addr, const uint16_t val)
{
__asm__ ("sthbrx %1,0,%2" : "=m" (*addr) : "r" (val), "r" (addr));
}
static __inline__ uint32_t ld_le32(const uint32_t *addr)
{
uint32_t val;
__asm__ ("lwbrx %0,0,%1" : "=r" (val) : "r" (addr), "m" (*addr));
return val;
}
static __inline__ void st_le32(uint32_t *addr, const uint32_t val)
{
__asm__ ("stwbrx %1,0,%2" : "=m" (*addr) : "r" (val), "r" (addr));
}
#define HAVE_ASM_BYTEORDER 1
#else
#define HAVE_ASM_BYTEORDER 0
#endif
#define CVAL(buf,pos) ((unsigned int)(((const uint8_t *)(buf))[pos]))
#define CVAL_NC(buf,pos) (((uint8_t *)(buf))[pos]) /* Non-const version of CVAL */
#define PVAL(buf,pos) (CVAL(buf,pos))
#define SCVAL(buf,pos,val) (CVAL_NC(buf,pos) = (val))
#if HAVE_ASM_BYTEORDER
#define _PTRPOS(buf,pos) (((const uint8_t *)(buf))+(pos))
#define SVAL(buf,pos) ld_le16((const uint16_t *)_PTRPOS(buf,pos))
#define IVAL(buf,pos) ld_le32((const uint32_t *)_PTRPOS(buf,pos))
#define SSVAL(buf,pos,val) st_le16((uint16_t *)_PTRPOS(buf,pos), val)
#define SIVAL(buf,pos,val) st_le32((uint32_t *)_PTRPOS(buf,pos), val)
#define SVALS(buf,pos) ((int16_t)SVAL(buf,pos))
#define IVALS(buf,pos) ((int32_t)IVAL(buf,pos))
#define SSVALS(buf,pos,val) SSVAL((buf),(pos),((int16_t)(val)))
#define SIVALS(buf,pos,val) SIVAL((buf),(pos),((int32_t)(val)))
#else /* not HAVE_ASM_BYTEORDER */
#define SVAL(buf,pos) (PVAL(buf,pos)|PVAL(buf,(pos)+1)<<8)
#define IVAL(buf,pos) (SVAL(buf,pos)|SVAL(buf,(pos)+2)<<16)
#define SSVALX(buf,pos,val) (CVAL_NC(buf,pos)=(uint8_t)((val)&0xFF),CVAL_NC(buf,pos+1)=(uint8_t)((val)>>8))
#define SIVALX(buf,pos,val) (SSVALX(buf,pos,val&0xFFFF),SSVALX(buf,pos+2,val>>16))
#define SVALS(buf,pos) ((int16_t)SVAL(buf,pos))
#define IVALS(buf,pos) ((int32_t)IVAL(buf,pos))
#define SSVAL(buf,pos,val) SSVALX((buf),(pos),((uint16_t)(val)))
#define SIVAL(buf,pos,val) SIVALX((buf),(pos),((uint32_t)(val)))
#define SSVALS(buf,pos,val) SSVALX((buf),(pos),((int16_t)(val)))
#define SIVALS(buf,pos,val) SIVALX((buf),(pos),((int32_t)(val)))
#endif /* not HAVE_ASM_BYTEORDER */
/* 64 bit macros */
#define BVAL(p, ofs) (IVAL(p,ofs) | (((uint64_t)IVAL(p,(ofs)+4)) << 32))
#define BVALS(p, ofs) ((int64_t)BVAL(p,ofs))
#define SBVAL(p, ofs, v) (SIVAL(p,ofs,(v)&0xFFFFFFFF), SIVAL(p,(ofs)+4,((uint64_t)(v))>>32))
#define SBVALS(p, ofs, v) (SBVAL(p,ofs,(uint64_t)v))
/* now the reverse routines - these are used in nmb packets (mostly) */
#define SREV(x) ((((x)&0xFF)<<8) | (((x)>>8)&0xFF))
#define IREV(x) ((SREV(x)<<16) | (SREV((x)>>16)))
#define BREV(x) ((IREV(x)<<32) | (IREV((x)>>32)))
#define RSVAL(buf,pos) SREV(SVAL(buf,pos))
#define RSVALS(buf,pos) SREV(SVALS(buf,pos))
#define RIVAL(buf,pos) IREV(IVAL(buf,pos))
#define RIVALS(buf,pos) IREV(IVALS(buf,pos))
#define RBVAL(buf,pos) BREV(BVAL(buf,pos))
#define RBVALS(buf,pos) BREV(BVALS(buf,pos))
#define RSSVAL(buf,pos,val) SSVAL(buf,pos,SREV(val))
#define RSSVALS(buf,pos,val) SSVALS(buf,pos,SREV(val))
#define RSIVAL(buf,pos,val) SIVAL(buf,pos,IREV(val))
#define RSIVALS(buf,pos,val) SIVALS(buf,pos,IREV(val))
#define RSBVAL(buf,pos,val) SBVAL(buf,pos,BREV(val))
#define RSBVALS(buf,pos,val) SBVALS(buf,pos,BREV(val))
/* Alignment macros. */
#define ALIGN4(p,base) ((p) + ((4 - (PTR_DIFF((p), (base)) & 3)) & 3))
#define ALIGN2(p,base) ((p) + ((2 - (PTR_DIFF((p), (base)) & 1)) & 1))
/* macros for accessing SMB protocol elements */
#define VWV(vwv) ((vwv)*2)
#endif /* _BYTEORDER_H */
|