Line data Source code
1 : /* SPDX-License-Identifier: GPL-2.0-or-later */
2 : #ifndef _FIXP_ARITH_H
3 : #define _FIXP_ARITH_H
4 :
5 : #include <linux/bug.h>
6 : #include <linux/math64.h>
7 :
8 : /*
9 : * Simplistic fixed-point arithmetics.
10 : * Hmm, I'm probably duplicating some code :(
11 : *
12 : * Copyright (c) 2002 Johann Deneux
13 : */
14 :
15 : /*
16 : *
17 : * Should you need to contact me, the author, you can do so by
18 : * e-mail - mail your message to <johann.deneux@gmail.com>
19 : */
20 :
21 : #include <linux/types.h>
22 :
23 : static const s32 sin_table[] = {
24 : 0x00000000, 0x023be165, 0x04779632, 0x06b2f1d2, 0x08edc7b6, 0x0b27eb5c,
25 : 0x0d61304d, 0x0f996a26, 0x11d06c96, 0x14060b67, 0x163a1a7d, 0x186c6ddd,
26 : 0x1a9cd9ac, 0x1ccb3236, 0x1ef74bf2, 0x2120fb82, 0x234815ba, 0x256c6f9e,
27 : 0x278dde6e, 0x29ac379f, 0x2bc750e8, 0x2ddf003f, 0x2ff31bdd, 0x32037a44,
28 : 0x340ff241, 0x36185aee, 0x381c8bb5, 0x3a1c5c56, 0x3c17a4e7, 0x3e0e3ddb,
29 : 0x3fffffff, 0x41ecc483, 0x43d464fa, 0x45b6bb5d, 0x4793a20f, 0x496af3e1,
30 : 0x4b3c8c11, 0x4d084650, 0x4ecdfec6, 0x508d9210, 0x5246dd48, 0x53f9be04,
31 : 0x55a6125a, 0x574bb8e5, 0x58ea90c2, 0x5a827999, 0x5c135399, 0x5d9cff82,
32 : 0x5f1f5ea0, 0x609a52d1, 0x620dbe8a, 0x637984d3, 0x64dd894f, 0x6639b039,
33 : 0x678dde6d, 0x68d9f963, 0x6a1de735, 0x6b598ea1, 0x6c8cd70a, 0x6db7a879,
34 : 0x6ed9eba0, 0x6ff389de, 0x71046d3c, 0x720c8074, 0x730baeec, 0x7401e4bf,
35 : 0x74ef0ebb, 0x75d31a5f, 0x76adf5e5, 0x777f903b, 0x7847d908, 0x7906c0af,
36 : 0x79bc384c, 0x7a6831b8, 0x7b0a9f8c, 0x7ba3751c, 0x7c32a67c, 0x7cb82884,
37 : 0x7d33f0c8, 0x7da5f5a3, 0x7e0e2e31, 0x7e6c924f, 0x7ec11aa3, 0x7f0bc095,
38 : 0x7f4c7e52, 0x7f834ecf, 0x7fb02dc4, 0x7fd317b3, 0x7fec09e1, 0x7ffb025e,
39 : 0x7fffffff
40 : };
41 :
42 : /**
43 : * __fixp_sin32() returns the sin of an angle in degrees
44 : *
45 : * @degrees: angle, in degrees, from 0 to 360.
46 : *
47 : * The returned value ranges from -0x7fffffff to +0x7fffffff.
48 : */
49 : static inline s32 __fixp_sin32(int degrees)
50 : {
51 : s32 ret;
52 0 : bool negative = false;
53 :
54 0 : if (degrees > 180) {
55 0 : negative = true;
56 0 : degrees -= 180;
57 : }
58 0 : if (degrees > 90)
59 0 : degrees = 180 - degrees;
60 :
61 0 : ret = sin_table[degrees];
62 :
63 0 : return negative ? -ret : ret;
64 : }
65 :
66 : /**
67 : * fixp_sin32() returns the sin of an angle in degrees
68 : *
69 : * @degrees: angle, in degrees. The angle can be positive or negative
70 : *
71 : * The returned value ranges from -0x7fffffff to +0x7fffffff.
72 : */
73 : static inline s32 fixp_sin32(int degrees)
74 : {
75 0 : degrees = (degrees % 360 + 360) % 360;
76 :
77 0 : return __fixp_sin32(degrees);
78 : }
79 :
80 : /* cos(x) = sin(x + 90 degrees) */
81 : #define fixp_cos32(v) fixp_sin32((v) + 90)
82 :
83 : /*
84 : * 16 bits variants
85 : *
86 : * The returned value ranges from -0x7fff to 0x7fff
87 : */
88 :
89 : #define fixp_sin16(v) (fixp_sin32(v) >> 16)
90 : #define fixp_cos16(v) (fixp_cos32(v) >> 16)
91 :
92 : /**
93 : * fixp_sin32_rad() - calculates the sin of an angle in radians
94 : *
95 : * @radians: angle, in radians
96 : * @twopi: value to be used for 2*pi
97 : *
98 : * Provides a variant for the cases where just 360
99 : * values is not enough. This function uses linear
100 : * interpolation to a wider range of values given by
101 : * twopi var.
102 : *
103 : * Experimental tests gave a maximum difference of
104 : * 0.000038 between the value calculated by sin() and
105 : * the one produced by this function, when twopi is
106 : * equal to 360000. That seems to be enough precision
107 : * for practical purposes.
108 : *
109 : * Please notice that two high numbers for twopi could cause
110 : * overflows, so the routine will not allow values of twopi
111 : * bigger than 1^18.
112 : */
113 : static inline s32 fixp_sin32_rad(u32 radians, u32 twopi)
114 : {
115 : int degrees;
116 : s32 v1, v2, dx, dy;
117 : s64 tmp;
118 :
119 : /*
120 : * Avoid too large values for twopi, as we don't want overflows.
121 : */
122 : BUG_ON(twopi > 1 << 18);
123 :
124 : degrees = (radians * 360) / twopi;
125 : tmp = radians - (degrees * twopi) / 360;
126 :
127 : degrees = (degrees % 360 + 360) % 360;
128 : v1 = __fixp_sin32(degrees);
129 :
130 : v2 = fixp_sin32(degrees + 1);
131 :
132 : dx = twopi / 360;
133 : dy = v2 - v1;
134 :
135 : tmp *= dy;
136 :
137 : return v1 + div_s64(tmp, dx);
138 : }
139 :
140 : /* cos(x) = sin(x + pi/2 radians) */
141 :
142 : #define fixp_cos32_rad(rad, twopi) \
143 : fixp_sin32_rad(rad + twopi / 4, twopi)
144 :
145 : /**
146 : * fixp_linear_interpolate() - interpolates a value from two known points
147 : *
148 : * @x0: x value of point 0
149 : * @y0: y value of point 0
150 : * @x1: x value of point 1
151 : * @y1: y value of point 1
152 : * @x: the linear interpolant
153 : */
154 : static inline int fixp_linear_interpolate(int x0, int y0, int x1, int y1, int x)
155 : {
156 : if (y0 == y1 || x == x0)
157 : return y0;
158 : if (x1 == x0 || x == x1)
159 : return y1;
160 :
161 : return y0 + ((y1 - y0) * (x - x0) / (x1 - x0));
162 : }
163 :
164 : #endif
|
