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rng.h
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rng.h
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#ifndef RNG_H_
#define RNG_H_
#define __STDC_FORMAT_MACROS 1
#include <stdlib.h>
#include <stddef.h>
#include <inttypes.h>
///=============================================================================
/// Compiler and Platform Features
///=============================================================================
typedef int8_t i8;
typedef uint8_t u8;
typedef int16_t i16;
typedef uint16_t u16;
typedef int32_t i32;
typedef uint32_t u32;
typedef int64_t i64;
typedef uint64_t u64;
typedef float f32;
typedef double f64;
#define STRUCT(S) typedef struct S S; struct S
#if __GNUC__
#define IABS(X) __builtin_abs(X)
#define PREFETCH(PTR,RW,LOC) __builtin_prefetch(PTR,RW,LOC)
#define likely(COND) (__builtin_expect(!!(COND),1))
#define unlikely(COND) (__builtin_expect((COND),0))
#define ATTR(...) __attribute__((__VA_ARGS__))
#define BSWAP32(X) __builtin_bswap32(X)
#define UNREACHABLE() __builtin_unreachable()
#else
#define IABS(X) ((int)abs(X))
#define PREFETCH(PTR,RW,LOC)
#define likely(COND) (COND)
#define unlikely(COND) (COND)
#define ATTR(...)
static inline uint32_t BSWAP32(uint32_t x) {
x = ((x & 0x000000ff) << 24) | ((x & 0x0000ff00) << 8) |
((x & 0x00ff0000) >> 8) | ((x & 0xff000000) >> 24);
return x;
}
#if _MSC_VER
#define UNREACHABLE() __assume(0)
#else
#define UNREACHABLE() exit(1) // [[noreturn]]
#endif
#endif
/// imitate amd64/x64 rotate instructions
static inline ATTR(const, always_inline, artificial)
uint64_t rotl64(uint64_t x, uint8_t b)
{
return (x << b) | (x >> (64-b));
}
static inline ATTR(const, always_inline, artificial)
uint32_t rotr32(uint32_t a, uint8_t b)
{
return (a >> b) | (a << (32-b));
}
/// integer floor divide
static inline ATTR(const, always_inline)
int32_t floordiv(int32_t a, int32_t b)
{
int32_t q = a / b;
int32_t r = a % b;
return q - ((a ^ b) < 0 && !!r);
}
///=============================================================================
/// C implementation of Java Random
///=============================================================================
static inline void setSeed(uint64_t *seed, uint64_t value)
{
*seed = (value ^ 0x5deece66d) & ((1ULL << 48) - 1);
}
static inline int next(uint64_t *seed, const int bits)
{
*seed = (*seed * 0x5deece66d + 0xb) & ((1ULL << 48) - 1);
return (int) ((int64_t)*seed >> (48 - bits));
}
static inline int nextInt(uint64_t *seed, const int n)
{
int bits, val;
const int m = n - 1;
if ((m & n) == 0) {
uint64_t x = n * (uint64_t)next(seed, 31);
return (int) ((int64_t) x >> 31);
}
do {
bits = next(seed, 31);
val = bits % n;
}
while ((int32_t)((uint32_t)bits - val + m) < 0);
return val;
}
static inline uint64_t nextLong(uint64_t *seed)
{
return ((uint64_t) next(seed, 32) << 32) + next(seed, 32);
}
static inline float nextFloat(uint64_t *seed)
{
return next(seed, 24) / (float) (1 << 24);
}
static inline double nextDouble(uint64_t *seed)
{
uint64_t x = (uint64_t)next(seed, 26);
x <<= 27;
x += next(seed, 27);
return (int64_t) x / (double) (1ULL << 53);
}
/* A macro to generate the ideal assembly for X = nextInt(*S, 24)
* This is a macro and not an inline function, as many compilers can make use
* of the additional optimisation passes for the surrounding code.
*/
#define JAVA_NEXT_INT24(S,X) \
do { \
uint64_t a = (1ULL << 48) - 1; \
uint64_t c = 0x5deece66dULL * (S); \
c += 11; a &= c; \
(S) = a; \
a = (uint64_t) ((int64_t)a >> 17); \
c = 0xaaaaaaab * a; \
c = (uint64_t) ((int64_t)c >> 36); \
(X) = (int)a - (int)(c << 3) * 3; \
} while (0)
/* Jumps forwards in the random number sequence by simulating 'n' calls to next.
*/
static inline void skipNextN(uint64_t *seed, uint64_t n)
{
uint64_t m = 1;
uint64_t a = 0;
uint64_t im = 0x5deece66dULL;
uint64_t ia = 0xb;
uint64_t k;
for (k = n; k; k >>= 1)
{
if (k & 1)
{
m *= im;
a = im * a + ia;
}
ia = (im + 1) * ia;
im *= im;
}
*seed = *seed * m + a;
*seed &= 0xffffffffffffULL;
}
///=============================================================================
/// Xoroshiro 128
///=============================================================================
STRUCT(Xoroshiro)
{
uint64_t lo, hi;
};
static inline void xSetSeed(Xoroshiro *xr, uint64_t value)
{
const uint64_t XL = 0x9e3779b97f4a7c15ULL;
const uint64_t XH = 0x6a09e667f3bcc909ULL;
const uint64_t A = 0xbf58476d1ce4e5b9ULL;
const uint64_t B = 0x94d049bb133111ebULL;
uint64_t l = value ^ XH;
uint64_t h = l + XL;
l = (l ^ (l >> 30)) * A;
h = (h ^ (h >> 30)) * A;
l = (l ^ (l >> 27)) * B;
h = (h ^ (h >> 27)) * B;
l = l ^ (l >> 31);
h = h ^ (h >> 31);
xr->lo = l;
xr->hi = h;
}
static inline uint64_t xNextLong(Xoroshiro *xr)
{
uint64_t l = xr->lo;
uint64_t h = xr->hi;
uint64_t n = rotl64(l + h, 17) + l;
h ^= l;
xr->lo = rotl64(l, 49) ^ h ^ (h << 21);
xr->hi = rotl64(h, 28);
return n;
}
static inline int xNextInt(Xoroshiro *xr, uint32_t n)
{
uint64_t r = (xNextLong(xr) & 0xFFFFFFFF) * n;
if ((uint32_t)r < n)
{
while ((uint32_t)r < (~n + 1) % n)
{
r = (xNextLong(xr) & 0xFFFFFFFF) * n;
}
}
return r >> 32;
}
static inline double xNextDouble(Xoroshiro *xr)
{
return (xNextLong(xr) >> (64-53)) * 1.1102230246251565E-16;
}
static inline float xNextFloat(Xoroshiro *xr)
{
return (xNextLong(xr) >> (64-24)) * 5.9604645E-8F;
}
static inline void xSkipN(Xoroshiro *xr, int count)
{
while (count --> 0)
xNextLong(xr);
}
static inline uint64_t xNextLongJ(Xoroshiro *xr)
{
int32_t a = xNextLong(xr) >> 32;
int32_t b = xNextLong(xr) >> 32;
return ((uint64_t)a << 32) + b;
}
static inline int xNextIntJ(Xoroshiro *xr, uint32_t n)
{
int bits, val;
const int m = n - 1;
if ((m & n) == 0) {
uint64_t x = n * (xNextLong(xr) >> 33);
return (int) ((int64_t) x >> 31);
}
do {
bits = (xNextLong(xr) >> 33);
val = bits % n;
}
while ((int32_t)((uint32_t)bits - val + m) < 0);
return val;
}
//==============================================================================
// MC Seed Helpers
//==============================================================================
/**
* The seed pipeline:
*
* getLayerSalt(n) -> layerSalt (ls)
* layerSalt (ls), worldSeed (ws) -> startSalt (st), startSeed (ss)
* startSeed (ss), coords (x,z) -> chunkSeed (cs)
*
* The chunkSeed alone is enough to generate the first PRNG integer with:
* mcFirstInt(cs, mod)
* subsequent PRNG integers are generated by stepping the chunkSeed forwards,
* salted with startSalt:
* cs_next = mcStepSeed(cs, st)
*/
static inline uint64_t mcStepSeed(uint64_t s, uint64_t salt)
{
return s * (s * 6364136223846793005ULL + 1442695040888963407ULL) + salt;
}
static inline int mcFirstInt(uint64_t s, int mod)
{
int ret = (int)(((int64_t)s >> 24) % mod);
if (ret < 0)
ret += mod;
return ret;
}
static inline int mcFirstIsZero(uint64_t s, int mod)
{
return (int)(((int64_t)s >> 24) % mod) == 0;
}
static inline uint64_t getChunkSeed(uint64_t ss, int x, int z)
{
uint64_t cs = ss + x;
cs = mcStepSeed(cs, z);
cs = mcStepSeed(cs, x);
cs = mcStepSeed(cs, z);
return cs;
}
static inline uint64_t getLayerSalt(uint64_t salt)
{
uint64_t ls = mcStepSeed(salt, salt);
ls = mcStepSeed(ls, salt);
ls = mcStepSeed(ls, salt);
return ls;
}
static inline uint64_t getStartSalt(uint64_t ws, uint64_t ls)
{
uint64_t st = ws;
st = mcStepSeed(st, ls);
st = mcStepSeed(st, ls);
st = mcStepSeed(st, ls);
return st;
}
static inline uint64_t getStartSeed(uint64_t ws, uint64_t ls)
{
uint64_t ss = ws;
ss = getStartSalt(ss, ls);
ss = mcStepSeed(ss, 0);
return ss;
}
///============================================================================
/// Arithmatic
///============================================================================
/* Linear interpolations
*/
static inline double lerp(double part, double from, double to)
{
return from + part * (to - from);
}
static inline double lerp2(
double dx, double dy, double v00, double v10, double v01, double v11)
{
return lerp(dy, lerp(dx, v00, v10), lerp(dx, v01, v11));
}
static inline double lerp3(
double dx, double dy, double dz,
double v000, double v100, double v010, double v110,
double v001, double v101, double v011, double v111)
{
v000 = lerp2(dx, dy, v000, v100, v010, v110);
v001 = lerp2(dx, dy, v001, v101, v011, v111);
return lerp(dz, v000, v001);
}
static inline double clampedLerp(double part, double from, double to)
{
if (part <= 0) return from;
if (part >= 1) return to;
return lerp(part, from, to);
}
/* Find the modular inverse: (1/x) | mod m.
* Assumes x and m are positive (less than 2^63), co-prime.
*/
static inline ATTR(const)
uint64_t mulInv(uint64_t x, uint64_t m)
{
uint64_t t, q, a, b, n;
if ((int64_t)m <= 1)
return 0; // no solution
n = m;
a = 0; b = 1;
while ((int64_t)x > 1)
{
if (m == 0)
return 0; // x and m are co-prime
q = x / m;
t = m; m = x % m; x = t;
t = a; a = b - q * a; b = t;
}
if ((int64_t)b < 0)
b += n;
return b;
}
#endif /* RNG_H_ */