386 lines
8.6 KiB
C++
386 lines
8.6 KiB
C++
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// File: crn_rand.cpp
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// See Copyright Notice and license at the end of inc/crnlib.h
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// See:
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// http://www.ciphersbyritter.com/NEWS4/RANDC.HTM
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// http://burtleburtle.net/bob/rand/smallprng.html
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// http://www.cs.ucl.ac.uk/staff/d.jones/GoodPracticeRNG.pdf
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// See GPG7, page 120, or http://www.lomont.org/Math/Papers/2008/Lomont_PRNG_2008.pdf
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#include "crn_core.h"
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#include "crn_rand.h"
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#include "crn_hash.h"
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#define znew (z=36969*(z&65535)+(z>>16))
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#define wnew (w=18000*(w&65535)+(w>>16))
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#define MWC ((znew<<16)+wnew )
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#define SHR3 (jsr^=(jsr<<17), jsr^=(jsr>>13), jsr^=(jsr<<5))
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#define CONG (jcong=69069*jcong+1234567)
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#define FIB ((b=a+b),(a=b-a))
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#define KISS ((MWC^CONG)+SHR3)
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#define LFIB4 (c++,t[c]=t[c]+t[UC(c+58)]+t[UC(c+119)]+t[UC(c+178)])
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#define SWB (c++,bro=(x<y),t[c]=(x=t[UC(c+34)])-(y=t[UC(c+19)]+bro))
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#define UNI (KISS*2.328306e-10)
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#define VNI ((long) KISS)*4.656613e-10
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#define UC (unsigned char) /*a cast operation*/
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//#define rot(x,k) (((x)<<(k))|((x)>>(32-(k))))
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#define rot(x,k) CRNLIB_ROTATE_LEFT(x,k)
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namespace crnlib
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{
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static const double cNorm = 1.0 / (double)0x100000000ULL;
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kiss99::kiss99()
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{
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x = 123456789;
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y = 362436000;
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z = 521288629;
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c = 7654321;
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}
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void kiss99::seed(uint32 i, uint32 j, uint32 k)
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{
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x = i;
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y = j;
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z = k;
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c = 7654321;
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}
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inline uint32 kiss99::next()
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{
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x = 69069*x+12345;
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y ^= (y<<13);
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y ^= (y>>17);
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y ^= (y<<5);
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uint64 t = c;
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t += (698769069ULL*z);
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c = static_cast<uint32>(t >> 32);
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z = static_cast<uint32>(t);
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return (x+y+z);
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}
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inline uint32 ranctx::next()
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{
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uint32 e = a - rot(b, 27);
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a = b ^ rot(c, 17);
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b = c + d;
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c = d + e;
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d = e + a;
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return d;
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}
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void ranctx::seed(uint32 seed)
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{
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a = 0xf1ea5eed, b = c = d = seed;
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for (uint32 i=0; i<20; ++i)
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next();
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}
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well512::well512()
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{
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seed(0xDEADBE3F);
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}
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void well512::seed(uint32 seed[well512::cStateSize])
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{
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memcpy(m_state, seed, sizeof(m_state));
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m_index = 0;
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}
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void well512::seed(uint32 seed)
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{
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uint32 jsr = utils::swap32(seed) ^ 0xAAC29377;
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for (uint i = 0; i < cStateSize; i++)
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{
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SHR3;
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seed = bitmix32c(seed);
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m_state[i] = seed ^ jsr;
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}
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m_index = 0;
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}
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void well512::seed(uint32 seed1, uint32 seed2, uint32 seed3)
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{
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uint32 jsr = seed2;
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uint32 jcong = seed3;
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for (uint i = 0; i < cStateSize; i++)
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{
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SHR3;
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seed1 = bitmix32c(seed1);
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CONG;
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m_state[i] = seed1 ^ jsr ^ jcong;
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}
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m_index = 0;
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}
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inline uint32 well512::next()
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{
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uint32 a, b, c, d;
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a = m_state[m_index];
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c = m_state[(m_index+13)&15];
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b = a^c^(a<<16)^(c<<15);
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c = m_state[(m_index+9)&15];
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c ^= (c>>11);
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a = m_state[m_index] = b^c;
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d = a^((a<<5)&0xDA442D20UL);
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m_index = (m_index + 15)&15;
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a = m_state[m_index];
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m_state[m_index] = a^b^d^(a<<2)^(b<<18)^(c<<28);
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return m_state[m_index];
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}
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random::random()
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{
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seed(12345,65435,34221);
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}
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random::random(uint32 i)
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{
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seed(i);
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}
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void random::seed(uint32 i1, uint32 i2, uint32 i3)
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{
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m_ranctx.seed(i1^i2^i3);
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m_kiss99.seed(i1, i2, i3);
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m_well512.seed(i1, i2, i3);
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for (uint i = 0; i < 100; i++)
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urand32();
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}
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void random::seed(uint32 i)
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{
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uint32 jsr = i;
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SHR3; SHR3;
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uint32 jcong = utils::swap32(~jsr);
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CONG; CONG;
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uint32 i1 = SHR3 ^ CONG;
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uint32 i2 = SHR3 ^ CONG;
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uint32 i3 = SHR3 + CONG;
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seed(i1, i2, i3);
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}
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uint32 random::urand32()
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{
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return m_kiss99.next() ^ (m_ranctx.next() + m_well512.next());
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}
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uint64 random::urand64()
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{
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uint64 result = urand32();
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result <<= 32ULL;
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result |= urand32();
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return result;
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}
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uint32 random::fast_urand32()
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{
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return m_well512.next();
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}
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uint32 random::bit()
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{
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uint32 k = urand32();
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return (k ^ (k >> 6) ^ (k >> 10) ^ (k >> 30)) & 1;
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}
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double random::drand(double l, double h)
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{
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CRNLIB_ASSERT(l <= h);
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if (l >= h)
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return l;
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return math::clamp(l + (h - l) * (urand32() * cNorm), l, h);
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}
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float random::frand(float l, float h)
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{
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CRNLIB_ASSERT(l <= h);
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if (l >= h)
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return l;
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float r = static_cast<float>(l + (h - l) * (urand32() * cNorm));
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return math::clamp<float>(r, l, h);
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}
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int random::irand(int l, int h)
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{
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CRNLIB_ASSERT(l < h);
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if (l >= h)
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return l;
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uint32 range = static_cast<uint32>(h - l);
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uint32 rnd = urand32();
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#if defined(_M_IX86) && defined(_MSC_VER)
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//uint32 rnd_range = static_cast<uint32>(__emulu(range, rnd) >> 32U);
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uint32 x[2];
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*reinterpret_cast<uint64*>(x) = __emulu(range, rnd);
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uint32 rnd_range = x[1];
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#else
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uint32 rnd_range = static_cast<uint32>((((uint64)range) * ((uint64)rnd)) >> 32U);
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#endif
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int result = l + rnd_range;
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CRNLIB_ASSERT((result >= l) && (result < h));
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return result;
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}
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int random::irand_inclusive(int l, int h)
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{
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CRNLIB_ASSERT(h < cINT32_MAX);
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return irand(l, h + 1);
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}
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/*
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ALGORITHM 712, COLLECTED ALGORITHMS FROM ACM.
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THIS WORK PUBLISHED IN TRANSACTIONS ON MATHEMATICAL SOFTWARE,
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VOL. 18, NO. 4, DECEMBER, 1992, PP. 434-435.
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The function returns a normally distributed pseudo-random number
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with a given mean and standard devaiation. Calls are made to a
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function subprogram which must return independent random
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numbers uniform in the interval (0,1).
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The algorithm uses the ratio of uniforms method of A.J. Kinderman
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and J.F. Monahan augmented with quadratic bounding curves.
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*/
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double random::gaussian(double mean, double stddev)
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{
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double q,u,v,x,y;
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/*
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Generate P = (u,v) uniform in rect. enclosing acceptance region
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Make sure that any random numbers <= 0 are rejected, since
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gaussian() requires uniforms > 0, but RandomUniform() delivers >= 0.
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*/
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do {
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u = drand(0, 1);
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v = drand(0, 1);
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if (u <= 0.0 || v <= 0.0) {
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u = 1.0;
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v = 1.0;
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}
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v = 1.7156 * (v - 0.5);
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/* Evaluate the quadratic form */
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x = u - 0.449871;
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y = fabs(v) + 0.386595;
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q = x * x + y * (0.19600 * y - 0.25472 * x);
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/* Accept P if inside inner ellipse */
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if (q < 0.27597)
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break;
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/* Reject P if outside outer ellipse, or outside acceptance region */
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} while ((q > 0.27846) || (v * v > -4.0 * log(u) * u * u));
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/* Return ratio of P's coordinates as the normal deviate */
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return (mean + stddev * v / u);
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}
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void random::test()
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{
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}
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fast_random::fast_random() :
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jsr(0xABCD917A),
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jcong(0x17F3DEAD)
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{
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}
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fast_random::fast_random(const fast_random& other) :
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jsr(other.jsr), jcong(other.jcong)
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{
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}
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fast_random::fast_random(uint32 i)
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{
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seed(i);
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}
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fast_random& fast_random::operator=(const fast_random& other)
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{
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jsr = other.jsr;
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jcong = other.jcong;
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return *this;
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}
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void fast_random::seed(uint32 i)
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{
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jsr = i;
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SHR3;
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SHR3;
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jcong = (~i) ^ 0xDEADBEEF;
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SHR3;
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CONG;
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}
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uint32 fast_random::urand32()
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{
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return SHR3 ^ CONG;
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}
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uint64 fast_random::urand64()
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{
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uint64 result = urand32();
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result <<= 32ULL;
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result |= urand32();
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return result;
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}
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int fast_random::irand(int l, int h)
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{
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CRNLIB_ASSERT(l < h);
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if (l >= h)
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return l;
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uint32 range = static_cast<uint32>(h - l);
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uint32 rnd = urand32();
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#if defined(_M_IX86) && defined(_MSC_VER)
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//uint32 rnd_range = static_cast<uint32>(__emulu(range, rnd) >> 32U);
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uint32 x[2];
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*reinterpret_cast<uint64*>(x) = __emulu(range, rnd);
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uint32 rnd_range = x[1];
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#else
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uint32 rnd_range = static_cast<uint32>((((uint64)range) * ((uint64)rnd)) >> 32U);
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#endif
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int result = l + rnd_range;
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CRNLIB_ASSERT((result >= l) && (result < h));
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return result;
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}
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double fast_random::drand(double l, double h)
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{
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CRNLIB_ASSERT(l <= h);
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if (l >= h)
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return l;
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return math::clamp(l + (h - l) * (urand32() * cNorm), l, h);
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}
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float fast_random::frand(float l, float h)
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{
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CRNLIB_ASSERT(l <= h);
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if (l >= h)
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return l;
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float r = static_cast<float>(l + (h - l) * (urand32() * cNorm));
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return math::clamp<float>(r, l, h);
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}
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} // namespace crnlib
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