[SKB]: __skb_queue_after(prev) = __skb_insert(prev, prev->next)
[linux-2.6] / include / asm-mn10300 / div64.h
1 /* MN10300 64-bit division
2  *
3  * Copyright (C) 2007 Red Hat, Inc. All Rights Reserved.
4  * Written by David Howells (dhowells@redhat.com)
5  *
6  * This program is free software; you can redistribute it and/or
7  * modify it under the terms of the GNU General Public Licence
8  * as published by the Free Software Foundation; either version
9  * 2 of the Licence, or (at your option) any later version.
10  */
11 #ifndef _ASM_DIV64
12 #define _ASM_DIV64
13
14 #include <linux/types.h>
15
16 extern void ____unhandled_size_in_do_div___(void);
17
18 /*
19  * divide n by base, leaving the result in n and returning the remainder
20  * - we can do this quite efficiently on the MN10300 by cascading the divides
21  *   through the MDR register
22  */
23 #define do_div(n, base)                                                 \
24 ({                                                                      \
25         unsigned __rem = 0;                                             \
26         if (sizeof(n) <= 4) {                                           \
27                 asm("mov        %1,mdr  \n"                             \
28                     "divu       %2,%0   \n"                             \
29                     "mov        mdr,%1  \n"                             \
30                     : "+r"(n), "=d"(__rem)                              \
31                     : "r"(base), "1"(__rem)                             \
32                     : "cc"                                              \
33                     );                                                  \
34         } else if (sizeof(n) <= 8) {                                    \
35                 union {                                                 \
36                         unsigned long long l;                           \
37                         u32 w[2];                                       \
38                 } __quot;                                               \
39                 __quot.l = n;                                           \
40                 asm("mov        %0,mdr  \n"     /* MDR = 0 */           \
41                     "divu       %3,%1   \n"                             \
42                     /* __quot.MSL = __div.MSL / base, */                \
43                     /* MDR = MDR:__div.MSL % base */                    \
44                     "divu       %3,%2   \n"                             \
45                     /* __quot.LSL = MDR:__div.LSL / base, */            \
46                     /* MDR = MDR:__div.LSL % base */                    \
47                     "mov        mdr,%0  \n"                             \
48                     : "=d"(__rem), "=r"(__quot.w[1]), "=r"(__quot.w[0]) \
49                     : "r"(base), "0"(__rem), "1"(__quot.w[1]),          \
50                       "2"(__quot.w[0])                                  \
51                     : "cc"                                              \
52                     );                                                  \
53                 n = __quot.l;                                           \
54         } else {                                                        \
55                 ____unhandled_size_in_do_div___();                      \
56         }                                                               \
57         __rem;                                                          \
58 })
59
60 /*
61  * do an unsigned 32-bit multiply and divide with intermediate 64-bit product
62  * so as not to lose accuracy
63  * - we use the MDR register to hold the MSW of the product
64  */
65 static inline __attribute__((const))
66 unsigned __muldiv64u(unsigned val, unsigned mult, unsigned div)
67 {
68         unsigned result;
69
70         asm("mulu       %2,%0   \n"     /* MDR:val = val*mult */
71             "divu       %3,%0   \n"     /* val = MDR:val/div;
72                                          * MDR = MDR:val%div */
73             : "=r"(result)
74             : "0"(val), "ir"(mult), "r"(div)
75             );
76
77         return result;
78 }
79
80 /*
81  * do a signed 32-bit multiply and divide with intermediate 64-bit product so
82  * as not to lose accuracy
83  * - we use the MDR register to hold the MSW of the product
84  */
85 static inline __attribute__((const))
86 signed __muldiv64s(signed val, signed mult, signed div)
87 {
88         signed result;
89
90         asm("mul        %2,%0   \n"     /* MDR:val = val*mult */
91             "div        %3,%0   \n"     /* val = MDR:val/div;
92                                          * MDR = MDR:val%div */
93             : "=r"(result)
94             : "0"(val), "ir"(mult), "r"(div)
95             );
96
97         return result;
98 }
99
100 extern __attribute__((const))
101 uint64_t div64_64(uint64_t dividend, uint64_t divisor);
102
103 #endif /* _ASM_DIV64 */