tools/wrk/deps/luajit/src/lib_math.c
/*
** Math library.
** Copyright (C) 2005-2013 Mike Pall. See Copyright Notice in luajit.h
*/
#include <math.h>
#define lib_math_c
#define LUA_LIB
#include "lua.h"
#include "lauxlib.h"
#include "lualib.h"
#include "lj_obj.h"
#include "lj_lib.h"
#include "lj_vm.h"
/* ------------------------------------------------------------------------ */
#define LJLIB_MODULE_math
LJLIB_ASM(math_abs) LJLIB_REC(.)
{
lj_lib_checknumber(L, 1);
return FFH_RETRY;
}
LJLIB_ASM_(math_floor) LJLIB_REC(math_round IRFPM_FLOOR)
LJLIB_ASM_(math_ceil) LJLIB_REC(math_round IRFPM_CEIL)
LJLIB_ASM(math_sqrt) LJLIB_REC(math_unary IRFPM_SQRT)
{
lj_lib_checknum(L, 1);
return FFH_RETRY;
}
LJLIB_ASM_(math_log10) LJLIB_REC(math_unary IRFPM_LOG10)
LJLIB_ASM_(math_exp) LJLIB_REC(math_unary IRFPM_EXP)
LJLIB_ASM_(math_sin) LJLIB_REC(math_unary IRFPM_SIN)
LJLIB_ASM_(math_cos) LJLIB_REC(math_unary IRFPM_COS)
LJLIB_ASM_(math_tan) LJLIB_REC(math_unary IRFPM_TAN)
LJLIB_ASM_(math_asin) LJLIB_REC(math_atrig FF_math_asin)
LJLIB_ASM_(math_acos) LJLIB_REC(math_atrig FF_math_acos)
LJLIB_ASM_(math_atan) LJLIB_REC(math_atrig FF_math_atan)
LJLIB_ASM_(math_sinh) LJLIB_REC(math_htrig IRCALL_sinh)
LJLIB_ASM_(math_cosh) LJLIB_REC(math_htrig IRCALL_cosh)
LJLIB_ASM_(math_tanh) LJLIB_REC(math_htrig IRCALL_tanh)
LJLIB_ASM_(math_frexp)
LJLIB_ASM_(math_modf) LJLIB_REC(.)
LJLIB_ASM(math_log) LJLIB_REC(math_log)
{
double x = lj_lib_checknum(L, 1);
if (L->base+1 < L->top) {
double y = lj_lib_checknum(L, 2);
#ifdef LUAJIT_NO_LOG2
x = log(x); y = 1.0 / log(y);
#else
x = lj_vm_log2(x); y = 1.0 / lj_vm_log2(y);
#endif
setnumV(L->base-1, x*y); /* Do NOT join the expression to x / y. */
return FFH_RES(1);
}
return FFH_RETRY;
}
LJLIB_PUSH(57.29577951308232)
LJLIB_ASM_(math_deg) LJLIB_REC(math_degrad)
LJLIB_PUSH(0.017453292519943295)
LJLIB_ASM_(math_rad) LJLIB_REC(math_degrad)
LJLIB_ASM(math_atan2) LJLIB_REC(.)
{
lj_lib_checknum(L, 1);
lj_lib_checknum(L, 2);
return FFH_RETRY;
}
LJLIB_ASM_(math_pow) LJLIB_REC(.)
LJLIB_ASM_(math_fmod)
LJLIB_ASM(math_ldexp) LJLIB_REC(.)
{
lj_lib_checknum(L, 1);
#if LJ_DUALNUM && !LJ_TARGET_X86ORX64
lj_lib_checkint(L, 2);
#else
lj_lib_checknum(L, 2);
#endif
return FFH_RETRY;
}
LJLIB_ASM(math_min) LJLIB_REC(math_minmax IR_MIN)
{
int i = 0;
do { lj_lib_checknumber(L, ++i); } while (L->base+i < L->top);
return FFH_RETRY;
}
LJLIB_ASM_(math_max) LJLIB_REC(math_minmax IR_MAX)
LJLIB_PUSH(3.14159265358979323846) LJLIB_SET(pi)
LJLIB_PUSH(1e310) LJLIB_SET(huge)
/* ------------------------------------------------------------------------ */
/* This implements a Tausworthe PRNG with period 2^223. Based on:
** Tables of maximally-equidistributed combined LFSR generators,
** Pierre L'Ecuyer, 1991, table 3, 1st entry.
** Full-period ME-CF generator with L=64, J=4, k=223, N1=49.
*/
/* PRNG state. */
struct RandomState {
uint64_t gen[4]; /* State of the 4 LFSR generators. */
int valid; /* State is valid. */
};
/* Union needed for bit-pattern conversion between uint64_t and double. */
typedef union { uint64_t u64; double d; } U64double;
/* Update generator i and compute a running xor of all states. */
#define TW223_GEN(i, k, q, s) \
z = rs->gen[i]; \
z = (((z<<q)^z) >> (k-s)) ^ ((z&((uint64_t)(int64_t)-1 << (64-k)))<<s); \
r ^= z; rs->gen[i] = z;
/* PRNG step function. Returns a double in the range 1.0 <= d < 2.0. */
LJ_NOINLINE uint64_t LJ_FASTCALL lj_math_random_step(RandomState *rs)
{
uint64_t z, r = 0;
TW223_GEN(0, 63, 31, 18)
TW223_GEN(1, 58, 19, 28)
TW223_GEN(2, 55, 24, 7)
TW223_GEN(3, 47, 21, 8)
return (r & U64x(000fffff,ffffffff)) | U64x(3ff00000,00000000);
}
/* PRNG initialization function. */
static void random_init(RandomState *rs, double d)
{
uint32_t r = 0x11090601; /* 64-k[i] as four 8 bit constants. */
int i;
for (i = 0; i < 4; i++) {
U64double u;
uint32_t m = 1u << (r&255);
r >>= 8;
u.d = d = d * 3.14159265358979323846 + 2.7182818284590452354;
if (u.u64 < m) u.u64 += m; /* Ensure k[i] MSB of gen[i] are non-zero. */
rs->gen[i] = u.u64;
}
rs->valid = 1;
for (i = 0; i < 10; i++)
lj_math_random_step(rs);
}
/* PRNG extract function. */
LJLIB_PUSH(top-2) /* Upvalue holds userdata with RandomState. */
LJLIB_CF(math_random) LJLIB_REC(.)
{
int n = (int)(L->top - L->base);
RandomState *rs = (RandomState *)(uddata(udataV(lj_lib_upvalue(L, 1))));
U64double u;
double d;
if (LJ_UNLIKELY(!rs->valid)) random_init(rs, 0.0);
u.u64 = lj_math_random_step(rs);
d = u.d - 1.0;
if (n > 0) {
#if LJ_DUALNUM
int isint = 1;
double r1;
lj_lib_checknumber(L, 1);
if (tvisint(L->base)) {
r1 = (lua_Number)intV(L->base);
} else {
isint = 0;
r1 = numV(L->base);
}
#else
double r1 = lj_lib_checknum(L, 1);
#endif
if (n == 1) {
d = lj_vm_floor(d*r1) + 1.0; /* d is an int in range [1, r1] */
} else {
#if LJ_DUALNUM
double r2;
lj_lib_checknumber(L, 2);
if (tvisint(L->base+1)) {
r2 = (lua_Number)intV(L->base+1);
} else {
isint = 0;
r2 = numV(L->base+1);
}
#else
double r2 = lj_lib_checknum(L, 2);
#endif
d = lj_vm_floor(d*(r2-r1+1.0)) + r1; /* d is an int in range [r1, r2] */
}
#if LJ_DUALNUM
if (isint) {
setintV(L->top-1, lj_num2int(d));
return 1;
}
#endif
} /* else: d is a double in range [0, 1] */
setnumV(L->top++, d);
return 1;
}
/* PRNG seed function. */
LJLIB_PUSH(top-2) /* Upvalue holds userdata with RandomState. */
LJLIB_CF(math_randomseed)
{
RandomState *rs = (RandomState *)(uddata(udataV(lj_lib_upvalue(L, 1))));
random_init(rs, lj_lib_checknum(L, 1));
return 0;
}
/* ------------------------------------------------------------------------ */
#include "lj_libdef.h"
LUALIB_API int luaopen_math(lua_State *L)
{
RandomState *rs;
rs = (RandomState *)lua_newuserdata(L, sizeof(RandomState));
rs->valid = 0; /* Use lazy initialization to save some time on startup. */
LJ_LIB_REG(L, LUA_MATHLIBNAME, math);
#if defined(LUA_COMPAT_MOD) && !LJ_52
lua_getfield(L, -1, "fmod");
lua_setfield(L, -2, "mod");
#endif
return 1;
}