raze-gles/polymer/eduke32/build/include/pragmas.h

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// This file has been modified from Ken Silverman's original release
// by Jonathon Fowler (jf@jonof.id.au)
#ifndef pragmas_h_
#define pragmas_h_
#ifdef __cplusplus
extern "C" {
#endif
#include <limits.h>
#define EDUKE32_GENERATE_PRAGMAS \
EDUKE32_SCALER_PRAGMA(1) EDUKE32_SCALER_PRAGMA(2) EDUKE32_SCALER_PRAGMA(3) EDUKE32_SCALER_PRAGMA(4) \
EDUKE32_SCALER_PRAGMA(5) EDUKE32_SCALER_PRAGMA(6) EDUKE32_SCALER_PRAGMA(7) EDUKE32_SCALER_PRAGMA(8) \
EDUKE32_SCALER_PRAGMA(9) EDUKE32_SCALER_PRAGMA(10) EDUKE32_SCALER_PRAGMA(11) EDUKE32_SCALER_PRAGMA(12) \
EDUKE32_SCALER_PRAGMA(13) EDUKE32_SCALER_PRAGMA(14) EDUKE32_SCALER_PRAGMA(15) EDUKE32_SCALER_PRAGMA(16) \
EDUKE32_SCALER_PRAGMA(17) EDUKE32_SCALER_PRAGMA(18) EDUKE32_SCALER_PRAGMA(19) EDUKE32_SCALER_PRAGMA(20) \
EDUKE32_SCALER_PRAGMA(21) EDUKE32_SCALER_PRAGMA(22) EDUKE32_SCALER_PRAGMA(23) EDUKE32_SCALER_PRAGMA(24) \
EDUKE32_SCALER_PRAGMA(25) EDUKE32_SCALER_PRAGMA(26) EDUKE32_SCALER_PRAGMA(27) EDUKE32_SCALER_PRAGMA(28) \
EDUKE32_SCALER_PRAGMA(29) EDUKE32_SCALER_PRAGMA(30) EDUKE32_SCALER_PRAGMA(31)
extern int32_t dmval;
#if !defined(NOASM) && defined __cplusplus
extern "C" {
#endif
extern int32_t reciptable[2048], fpuasm;
#if !defined(NOASM) && defined __cplusplus
}
#endif
// break the C version of divscale out from the others
// because asm version overflows in drawmapview()
#define qw(x) ((int64_t)(x)) // quadword cast
#define dw(x) ((int32_t)(x)) // doubleword cast
#define wo(x) ((int16_t)(x)) // word cast
#define by(x) ((uint8_t)(x)) // byte cast
#define LIBDIVIDE_ALWAYS
#define DIVTABLESIZE 16384
extern libdivide_s64pad_t divtable64[DIVTABLESIZE];
extern libdivide_s32pad_t divtable32[DIVTABLESIZE];
extern void initdivtables(void);
#if defined(__arm__) || defined(LIBDIVIDE_ALWAYS)
static inline uint32_t divideu32(uint32_t n, uint32_t d)
{
static libdivide_u32_t udiv;
static uint32_t lastd;
if (d == lastd)
goto skip;
lastd = d;
udiv = libdivide_u32_gen(d);
skip:
return libdivide_u32_do(n, &udiv);
}
static inline int32_t tabledivide64(int64_t n, int32_t d)
{
static libdivide_s64_t sdiv;
static int32_t lastd;
libdivide_s64_t const * const dptr = ((unsigned)d < DIVTABLESIZE) ? (libdivide_s64_t *)&divtable64[d] : &sdiv;
if (d == lastd || dptr != &sdiv)
goto skip;
lastd = d;
sdiv = libdivide_s64_gen(d);
skip:
return libdivide_s64_do(n, dptr);
}
static inline int32_t tabledivide32(int32_t n, int32_t d)
{
static libdivide_s32_t sdiv;
static int32_t lastd;
libdivide_s32_t const * const dptr = ((unsigned)d < DIVTABLESIZE) ? (libdivide_s32_t *)&divtable32[d] : &sdiv;
if (d == lastd || dptr != &sdiv)
goto skip;
lastd = d;
sdiv = libdivide_s32_gen(d);
skip:
return libdivide_s32_do(n, dptr);
}
#else
FORCE_INLINE uint32_t divideu32(uint32_t n, uint32_t d) { return n / d; }
static inline int32_t tabledivide64(int64_t n, int32_t d)
{
return ((unsigned)d < DIVTABLESIZE) ? libdivide_s64_do(n, (libdivide_s64_t *)&divtable64[d]) : n / d;
}
static inline int32_t tabledivide32(int32_t n, int32_t d)
{
return ((unsigned)d < DIVTABLESIZE) ? libdivide_s32_do(n, (libdivide_s32_t *)&divtable32[d]) : n / d;
}
#endif
extern uint32_t divideu32_noinline(uint32_t n, uint32_t d);
extern int32_t tabledivide32_noinline(int32_t n, int32_t d);
extern int32_t tabledivide64_noinline(int64_t n, int32_t d);
#ifdef GEKKO
#include <math.h>
static inline int32_t divscale(int32_t eax, int32_t ebx, int32_t ecx) { return tabledivide64(ldexp(eax, ecx), ebx); }
#else
static inline int32_t divscale(int32_t eax, int32_t ebx, int32_t ecx)
{
const int64_t numer = qw(eax) << by(ecx);
return dw(tabledivide64(numer, ebx));
}
#endif
#define EDUKE32_SCALER_PRAGMA(a) \
FORCE_INLINE int32_t divscale##a(int32_t eax, int32_t ebx) { return divscale(eax, ebx, a); }
EDUKE32_GENERATE_PRAGMAS EDUKE32_SCALER_PRAGMA(32)
#undef EDUKE32_SCALER_PRAGMA
static inline int32_t scale(int32_t eax, int32_t edx, int32_t ecx)
{
const int64_t numer = qw(eax) * edx;
return dw(tabledivide64(numer, ecx));
}
FORCE_INLINE void swapptr(void *a, void *b)
{
intptr_t const t = *(intptr_t*) a;
*(intptr_t*) a = *(intptr_t*) b;
*(intptr_t*) b = t;
}
#if defined(__GNUC__) && defined(GEKKO)
// GCC Inline Assembler version (PowerPC)
#include "pragmas_ppc.h"
#elif defined(__GNUC__) && defined(__i386__) && !defined(NOASM)
// GCC Inline Assembler version (x86)
#include "pragmas_x86_gcc.h"
#elif defined(_MSC_VER) && !defined(NOASM) // __GNUC__
// Microsoft C inline assembler
#include "pragmas_x86_msvc.h"
#elif defined(__arm__) // _MSC_VER
// GCC Inline Assembler version (ARM)
#include "pragmas_arm.h"
#else
//
// Generic C
//
#define EDUKE32_SCALER_PRAGMA(a) \
FORCE_INLINE int32_t mulscale##a(int32_t eax, int32_t edx) { return dw((qw(eax) * qw(edx)) >> by(a)); } \
\
FORCE_INLINE int32_t dmulscale##a(int32_t eax, int32_t edx, int32_t esi, int32_t edi) \
{ \
return dw(((qw(eax) * qw(edx)) + (qw(esi) * qw(edi))) >> by(a)); \
}
EDUKE32_GENERATE_PRAGMAS EDUKE32_SCALER_PRAGMA(32)
#undef EDUKE32_SCALER_PRAGMA
FORCE_INLINE void swapchar(void *a, void *b)
{
char const t = *((char *)b);
*((char *)b) = *((char *)a);
*((char *)a) = t;
}
FORCE_INLINE void swapchar2(void *a, void *b, int32_t s)
{
swapchar(a, b);
swapchar((char *)a + 1, (char *)b + s);
}
FORCE_INLINE void swapshort(void *a, void *b)
{
int16_t const t = *((int16_t *)b);
*((int16_t *)b) = *((int16_t *)a);
*((int16_t *)a) = t;
}
FORCE_INLINE void swaplong(void *a, void *b)
{
int32_t const t = *((int32_t *)b);
*((int32_t *)b) = *((int32_t *)a);
*((int32_t *)a) = t;
}
FORCE_INLINE void swapfloat(void *a, void *b)
{
float const t = *((float *)b);
*((float *)b) = *((float *)a);
*((float *)a) = t;
}
FORCE_INLINE void swapdouble(void *a, void *b)
{
double const t = *((double *) b);
*((double *) b) = *((double *) a);
*((double *) a) = t;
}
FORCE_INLINE void swap64bit(void *a, void *b)
{
uint64_t const t = *((uint64_t *)b);
*((uint64_t *)b) = *((uint64_t *)a);
*((uint64_t *)a) = t;
}
FORCE_INLINE char readpixel(void *s) { return (*((char *)(s))); }
FORCE_INLINE void drawpixel(void *s, char a) { *((char *)(s)) = a; }
FORCE_INLINE int32_t klabs(int32_t a)
{
const uint32_t m = a >> (sizeof(uint32_t) * CHAR_BIT - 1);
return (a ^ m) - m;
}
FORCE_INLINE int32_t ksgn(int32_t a) { return (a > 0) - (a < 0); }
FORCE_INLINE int32_t mulscale(int32_t eax, int32_t edx, int32_t ecx) { return dw((qw(eax) * edx) >> by(ecx)); }
FORCE_INLINE int32_t dmulscale(int32_t eax, int32_t edx, int32_t esi, int32_t edi, int32_t ecx)
{
return dw(((qw(eax) * edx) + (qw(esi) * edi)) >> by(ecx));
}
void qinterpolatedown16(intptr_t bufptr, int32_t num, int32_t val, int32_t add);
void qinterpolatedown16short(intptr_t bufptr, int32_t num, int32_t val, int32_t add);
void clearbuf(void *d, int32_t c, int32_t a);
void copybuf(const void *s, void *d, int32_t c);
void swapbuf4(void *a, void *b, int32_t c);
void clearbufbyte(void *D, int32_t c, int32_t a);
void copybufbyte(const void *S, void *D, int32_t c);
void copybufreverse(const void *S, void *D, int32_t c);
static inline int32_t krecipasm(int32_t i)
{
// Ken did this
float const f = (float const)i;
i = *(int32_t const *)&f;
return ((reciptable[(i >> 12) & 2047] >> (((i - 0x3f800000) >> 23) & 31)) ^ (i >> 31));
}
#endif
#undef qw
#undef dw
#undef wo
#undef by
static inline void swapbufreverse(void *s, void *d, int32_t c)
{
uint8_t *src = (uint8_t *)s, *dst = (uint8_t *)d;
Bassert(c >= 4);
do
{
swapchar(dst, src);
swapchar(dst + 1, src - 1);
swapchar(dst + 2, src - 2);
swapchar(dst + 3, src - 3);
dst += 4, src -= 4;
} while ((c -= 4) > 4);
while (c--)
swapchar(dst++, src--);
}
#ifdef __cplusplus
}
#endif
#endif // pragmas_h_