#ifndef UTILS_H #define UTILS_H #include #include #define STATIC_ASSERT(expr) typedef int STATIC_ASSERT_FAILED[(expr) ? 1 : -1] #define MIN(a,b) (((a) < (b)) ? (a) : (b)) #define MAX(a,b) (((a) > (b)) ? (a) : (b)) #define BOUND(x,a,b) ( MIN(b, MAX(a, x)) ) static inline void breakpoint(void); #pragma aux breakpoint = 0xcd 0x03; static inline __segment get_cs(void); #pragma aux get_cs = "mov ax, cs" value [ax] modify exact []; static inline __segment get_ds(void); #pragma aux get_ds = "mov ax, ds" value [ax] modify exact []; /** Converts a far pointer into equivalent linear address. * Note that under protected mode linear != physical (for that, need VDS). */ static inline uint32_t linear_addr(const void __far * ptr) { return ((uint32_t)(FP_SEG(ptr)) << 4) + FP_OFF(ptr); } /** Map x linearly from range [0, srcmax] to [0, dstmax]. * Equivalent of (x * dstmax) / srcmax but with 32-bit unsigned precision. */ static unsigned scaleu(unsigned x, unsigned srcmax, unsigned dstmax); #pragma aux scaleu = \ "mul cx" /* dx:ax = x * dstmax */\ "div bx" /* ax = dx:ax / srcmax */\ __parm [ax] [bx] [cx] \ __value [ax] \ __modify [ax dx] /** Map x linearly from range [0, srcmax] to [0, dstmax]. * Equivalent of (x * dstmax) / srcmax but with 32-bit signed precision. */ static int scalei(int x, int srcmax, int dstmax); #pragma aux scalei = \ "imul cx" /* dx:ax = x * dstmax */ \ "idiv bx" /* ax = dx:ax / srcmax */ \ __parm [ax] [bx] [cx] \ __value [ax] \ __modify [ax dx] /** Map x linearly from range [0, srcmax] to [0, dstmax]. * Equivalent of (x * dstmax) / srcmax but with 32-bit signed precision. * Division remainder is returned in rem, which should be reused * in future calls to reduce rounding error. */ static int scalei_rem(int x, int srcmax, int dstmax, short *rem); #pragma aux scalei_rem = \ "imul cx" /* dx:ax = x * dstmax */ \ "mov cx, [si]" /* cx = rem */ \ "test cx, cx" \ "setns cl" /* cl = 1 if rem positive, 0 if negative */ \ "movzx cx, cl" \ "dec cx" /* cx = 0 if rem positive, -1 if negative */ \ "add ax, [si]" /* ax += *rem */ \ "adc dx, cx" /* dx += 1 if carry and rem positive, 0 if carry and rem negative (aka. signed addition) */ \ "idiv bx" /* ax = dx:ax / srcmax, dx = new remainder */ \ "mov [si], dx" /* store the new remainder */ \ __parm [ax] [bx] [cx] [si] \ __value [ax] \ __modify [ax cx dx si] #endif