Aegisub/vendor/luajit/src/lj_vmmath.c

153 lines
4.0 KiB
C

/*
** Math helper functions for assembler VM.
** Copyright (C) 2005-2017 Mike Pall. See Copyright Notice in luajit.h
*/
#define lj_vmmath_c
#define LUA_CORE
#include <errno.h>
#include <math.h>
#include "lj_obj.h"
#include "lj_ir.h"
#include "lj_vm.h"
/* -- Wrapper functions --------------------------------------------------- */
#if LJ_TARGET_X86 && __ELF__ && __PIC__
/* Wrapper functions to deal with the ELF/x86 PIC disaster. */
LJ_FUNCA double lj_wrap_log(double x) { return log(x); }
LJ_FUNCA double lj_wrap_log10(double x) { return log10(x); }
LJ_FUNCA double lj_wrap_exp(double x) { return exp(x); }
LJ_FUNCA double lj_wrap_sin(double x) { return sin(x); }
LJ_FUNCA double lj_wrap_cos(double x) { return cos(x); }
LJ_FUNCA double lj_wrap_tan(double x) { return tan(x); }
LJ_FUNCA double lj_wrap_asin(double x) { return asin(x); }
LJ_FUNCA double lj_wrap_acos(double x) { return acos(x); }
LJ_FUNCA double lj_wrap_atan(double x) { return atan(x); }
LJ_FUNCA double lj_wrap_sinh(double x) { return sinh(x); }
LJ_FUNCA double lj_wrap_cosh(double x) { return cosh(x); }
LJ_FUNCA double lj_wrap_tanh(double x) { return tanh(x); }
LJ_FUNCA double lj_wrap_atan2(double x, double y) { return atan2(x, y); }
LJ_FUNCA double lj_wrap_pow(double x, double y) { return pow(x, y); }
LJ_FUNCA double lj_wrap_fmod(double x, double y) { return fmod(x, y); }
#endif
/* -- Helper functions for generated machine code ------------------------- */
double lj_vm_foldarith(double x, double y, int op)
{
switch (op) {
case IR_ADD - IR_ADD: return x+y; break;
case IR_SUB - IR_ADD: return x-y; break;
case IR_MUL - IR_ADD: return x*y; break;
case IR_DIV - IR_ADD: return x/y; break;
case IR_MOD - IR_ADD: return x-lj_vm_floor(x/y)*y; break;
case IR_POW - IR_ADD: return pow(x, y); break;
case IR_NEG - IR_ADD: return -x; break;
case IR_ABS - IR_ADD: return fabs(x); break;
#if LJ_HASJIT
case IR_ATAN2 - IR_ADD: return atan2(x, y); break;
case IR_LDEXP - IR_ADD: return ldexp(x, (int)y); break;
case IR_MIN - IR_ADD: return x > y ? y : x; break;
case IR_MAX - IR_ADD: return x < y ? y : x; break;
#endif
default: return x;
}
}
#if (LJ_HASJIT && !(LJ_TARGET_ARM || LJ_TARGET_ARM64 || LJ_TARGET_PPC)) || LJ_TARGET_MIPS
int32_t LJ_FASTCALL lj_vm_modi(int32_t a, int32_t b)
{
uint32_t y, ua, ub;
lua_assert(b != 0); /* This must be checked before using this function. */
ua = a < 0 ? (uint32_t)-a : (uint32_t)a;
ub = b < 0 ? (uint32_t)-b : (uint32_t)b;
y = ua % ub;
if (y != 0 && (a^b) < 0) y = y - ub;
if (((int32_t)y^b) < 0) y = (uint32_t)-(int32_t)y;
return (int32_t)y;
}
#endif
#if LJ_HASJIT
#ifdef LUAJIT_NO_LOG2
double lj_vm_log2(double a)
{
return log(a) * 1.4426950408889634074;
}
#endif
#ifdef LUAJIT_NO_EXP2
double lj_vm_exp2(double a)
{
return exp(a * 0.6931471805599453);
}
#endif
#if !LJ_TARGET_X86ORX64
/* Unsigned x^k. */
static double lj_vm_powui(double x, uint32_t k)
{
double y;
lua_assert(k != 0);
for (; (k & 1) == 0; k >>= 1) x *= x;
y = x;
if ((k >>= 1) != 0) {
for (;;) {
x *= x;
if (k == 1) break;
if (k & 1) y *= x;
k >>= 1;
}
y *= x;
}
return y;
}
/* Signed x^k. */
double lj_vm_powi(double x, int32_t k)
{
if (k > 1)
return lj_vm_powui(x, (uint32_t)k);
else if (k == 1)
return x;
else if (k == 0)
return 1.0;
else
return 1.0 / lj_vm_powui(x, (uint32_t)-k);
}
#endif
/* Computes fpm(x) for extended math functions. */
double lj_vm_foldfpm(double x, int fpm)
{
switch (fpm) {
case IRFPM_FLOOR: return lj_vm_floor(x);
case IRFPM_CEIL: return lj_vm_ceil(x);
case IRFPM_TRUNC: return lj_vm_trunc(x);
case IRFPM_SQRT: return sqrt(x);
case IRFPM_EXP: return exp(x);
case IRFPM_EXP2: return lj_vm_exp2(x);
case IRFPM_LOG: return log(x);
case IRFPM_LOG2: return lj_vm_log2(x);
case IRFPM_LOG10: return log10(x);
case IRFPM_SIN: return sin(x);
case IRFPM_COS: return cos(x);
case IRFPM_TAN: return tan(x);
default: lua_assert(0);
}
return 0;
}
#if LJ_HASFFI
int lj_vm_errno(void)
{
return errno;
}
#endif
#endif