Explicitly include a boost "windows" folder even on linux
[supercollider.git] / include / plugin_interface / SC_RGen.h
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1 /*
2 SuperCollider real time audio synthesis system
3 Copyright (c) 2002 James McCartney. All rights reserved.
4 http://www.audiosynth.com
6 This program is free software; you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 2 of the License, or
9 (at your option) any later version.
11 This program is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
16 You should have received a copy of the GNU General Public License
17 along with this program; if not, write to the Free Software
18 Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
21 //----------------------------------------------------------------------------//
22 // Ran088: L'Ecuyer's 1996 three-component Tausworthe generator "taus88"
23 //----------------------------------------------------------------------------//
25 // Returns an integer random number uniformly distributed within [0,4294967295]
27 // The period length is approximately 2^88 (which is 3*10^26).
28 // This generator is very fast and passes all standard statistical tests.
30 // Reference:
31 // (1) P. L'Ecuyer, Maximally equidistributed combined Tausworthe generators,
32 // Mathematics of Computation, 65, 203-213 (1996), see Figure 4.
33 // (2) recommended in:
34 // P. L'Ecuyer, Random number generation, chapter 4 of the
35 // Handbook on Simulation, Ed. Jerry Banks, Wiley, 1997.
37 //----------------------------------------------------------------------------//
39 //----------------------------------------------------------------------------//
40 // I chose this random number generator for the following reasons:
41 // fast.
42 // easier and faster to seed than other high quality rng's such as Mersenne Twister.
43 // the internal state is only 12 bytes.
44 // the period is long enough for music/audio.
45 // possible to code in altivec in future if needed.
46 // - James McCartney
47 //----------------------------------------------------------------------------//
49 #ifndef _SC_RGen_
50 #define _SC_RGen_
52 #include "SC_Endian.h"
53 #include "SC_Types.h"
54 #include "SC_BoundsMacros.h"
55 #include "Hash.h"
56 #include <math.h>
58 struct RGen
60 void init(uint32 seed);
62 uint32 trand();
64 int32 irand(int32 scale);
65 int32 irand2(int32 scale);
66 int32 ilinrand(int32 scale);
67 int32 ibilinrand(int32 scale);
69 float fcoin();
70 float frand();
71 float frand2();
72 float frand0();
73 float frand8();
74 double drand();
75 double drand2(double scale);
76 double linrand(double scale);
77 double bilinrand(double scale);
78 double exprandrng(double lo, double hi);
79 double exprand(double scale);
80 double biexprand(double scale);
81 double sum3rand(double scale);
83 uint32 s1, s2, s3; // random generator state
86 inline void RGen::init(uint32 seed)
88 // humans tend to use small seeds - mess up the bits
89 seed = (uint32)Hash((int)seed);
91 // initialize seeds using the given seed value taking care of
92 // the requirements. The constants below are arbitrary otherwise
93 s1 = 1243598713U ^ seed; if (s1 < 2) s1 = 1243598713U;
94 s2 = 3093459404U ^ seed; if (s2 < 8) s2 = 3093459404U;
95 s3 = 1821928721U ^ seed; if (s3 < 16) s3 = 1821928721U;
98 inline uint32 trand( uint32& s1, uint32& s2, uint32& s3 )
100 // This function is provided for speed in inner loops where the
101 // state variables are loaded into registers.
102 // Thus updating the instance variables can
103 // be postponed until the end of the loop.
104 s1 = ((s1 & (uint32)-2) << 12) ^ (((s1 << 13) ^ s1) >> 19);
105 s2 = ((s2 & (uint32)-8) << 4) ^ (((s2 << 2) ^ s2) >> 25);
106 s3 = ((s3 & (uint32)-16) << 17) ^ (((s3 << 3) ^ s3) >> 11);
107 return s1 ^ s2 ^ s3;
110 inline uint32 RGen::trand()
112 // generate a random 32 bit number
113 return ::trand(s1, s2, s3);
116 inline double RGen::drand()
118 // return a double from 0.0 to 0.999...
119 #if BYTE_ORDER == BIG_ENDIAN
120 union { struct { uint32 hi, lo; } i; double f; } du;
121 #else
122 union { struct { uint32 lo, hi; } i; double f; } du;
123 #endif
124 du.i.hi = 0x41300000;
125 du.i.lo = trand();
126 return du.f - 1048576.;
129 inline float RGen::frand()
131 // return a float from 0.0 to 0.999...
132 union { uint32 i; float f; } u; // union for floating point conversion of result
133 u.i = 0x3F800000 | (trand() >> 9);
134 return u.f - 1.f;
137 inline float RGen::frand0()
139 // return a float from +1.0 to +1.999...
140 union { uint32 i; float f; } u; // union for floating point conversion of result
141 u.i = 0x3F800000 | (trand() >> 9);
142 return u.f;
145 inline float RGen::frand2()
147 // return a float from -1.0 to +0.999...
148 union { uint32 i; float f; } u; // union for floating point conversion of result
149 u.i = 0x40000000 | (trand() >> 9);
150 return u.f - 3.f;
153 inline float RGen::frand8()
155 // return a float from -0.125 to +0.124999...
156 union { uint32 i; float f; } u; // union for floating point conversion of result
157 u.i = 0x3E800000 | (trand() >> 9);
158 return u.f - 0.375f;
161 inline float RGen::fcoin()
163 // only return one of the two values -1.0 or +1.0
164 union { uint32 i; float f; } u; // union for floating point conversion of result
165 u.i = 0x3F800000 | (0x80000000 & trand());
166 return u.f;
169 inline int32 RGen::irand(int32 scale)
171 // return an int from 0 to scale - 1
172 return (int32)floor(scale * drand());
175 inline int32 RGen::irand2(int32 scale)
177 // return a int from -scale to +scale
178 return (int32)floor((2. * scale + 1.) * drand() - scale);
181 inline int32 RGen::ilinrand(int32 scale)
183 int32 a = irand(scale);
184 int32 b = irand(scale);
185 return sc_min(a,b);
188 inline double RGen::linrand(double scale)
190 double a = drand();
191 double b = drand();
192 return sc_min(a,b) * scale;
195 inline int32 RGen::ibilinrand(int32 scale)
197 int32 a = irand(scale);
198 int32 b = irand(scale);
199 return a - b;
202 inline double RGen::bilinrand(double scale)
204 double a = drand();
205 double b = drand();
206 return (a - b) * scale;
209 inline double RGen::exprandrng(double lo, double hi)
211 return lo * exp(log(hi / lo) * drand());
214 inline double RGen::exprand(double scale)
216 double z;
217 while ((z = drand()) == 0.0) {}
218 return -log(z) * scale;
221 inline double RGen::biexprand(double scale)
223 double z;
224 while ((z = drand2(1.)) == 0.0 || z == -1.0) {}
225 if (z > 0.0) z = log(z);
226 else z = -log(-z);
227 return z * scale;
230 inline double RGen::sum3rand(double scale)
232 // larry polansky's poor man's gaussian generator
233 return (drand() + drand() + drand() - 1.5) * 0.666666667 * scale;
236 inline double drand( uint32& s1, uint32& s2, uint32& s3 )
238 union { struct { uint32 hi, lo; } i; double f; } u;
239 u.i.hi = 0x41300000;
240 u.i.lo = trand(s1,s2,s3);
241 return u.f - 1048576.;
244 inline float frand( uint32& s1, uint32& s2, uint32& s3 )
246 // return a float from 0.0 to 0.999...
247 union { uint32 i; float f; } u;
248 u.i = 0x3F800000 | (trand(s1,s2,s3) >> 9);
249 return u.f - 1.f;
252 inline float frand0( uint32& s1, uint32& s2, uint32& s3 )
254 // return a float from +1.0 to +1.999...
255 union { uint32 i; float f; } u;
256 u.i = 0x3F800000 | (trand(s1,s2,s3) >> 9);
257 return u.f;
260 inline float frand2( uint32& s1, uint32& s2, uint32& s3 )
262 // return a float from -1.0 to +0.999...
263 union { uint32 i; float f; } u;
264 u.i = 0x40000000 | (trand(s1,s2,s3) >> 9);
265 return u.f - 3.f;
268 inline float frand8( uint32& s1, uint32& s2, uint32& s3 )
270 // return a float from -0.125 to +0.124999...
271 union { uint32 i; float f; } u;
272 u.i = 0x3E800000 | (trand(s1,s2,s3) >> 9);
273 return u.f - 0.375f;
276 inline float fcoin( uint32& s1, uint32& s2, uint32& s3 )
278 // only return one of the two values -1.0 or +1.0
279 union { uint32 i; float f; } u;
280 u.i = 0x3F800000 | (0x80000000 & trand(s1,s2,s3));
281 return u.f;
284 #endif