#define m_zero 0 #define m_one 1 #define m_from_double(x) (x) #define m_from_real(x) (x) #define m_add(x,y) ((x)+(y)) #define m_sub(x,y) ((x)-(y)) #define m_mul(x,y) ((x)*(y)) #define m_div(x,y) ((x)/(y)) #define m_mod(x,y) ((x)%(y)) #define m_divmod(x,y,a,b) {a=(x)/(y); b=m_mod(x,y);} #define m_pow(x,y) pow_int(x,y) #define m_pow_int(x,y) pow_int(x,y) #define m_bit_and(x,y) ((x)&(y)) #define m_bit_or(x,y) ((x)|(y)) #define m_bit_xor(x,y) ((x)^(y)) #define m_bit_not(x) (~(x)) #define m_minus(x) (-(x)) #define m_reciprocal(x) int_reciprocal(x) #define m_square(x) ((x)*(x)) #define m_eq(x,y) ((x)==(y)) #define m_ne(x,y) ((x)!=(y)) #define m_gt(x,y) ((x)>(y)) #define m_ge(x,y) ((x)>=(y)) #define m_lt(x,y) ((x)<(y)) #define m_le(x,y) ((x)<=(y)) #define m_isnan(x) 0 #define m_mulsum(x,y,z) {z += x*y;} #define m_mulsum_init INT2FIX(0) #define cmp(a,b) \ ((qsort_cast(a)==qsort_cast(b)) ? 0 : \ (qsort_cast(a) > qsort_cast(b)) ? 1 : -1) #define cmpgt(a,b) \ (qsort_cast(a) > qsort_cast(b)) static inline dtype f_sum(size_t n, char *p, ssize_t stride) { dtype x,y=0; size_t i=n; for (; i--;) { x = *(dtype*)p; y += x; p += stride; } return y; } static inline dtype f_prod(size_t n, char *p, ssize_t stride) { dtype x,y=1; size_t i=n; for (; i--;) { x = *(dtype*)p; y *= x; p += stride; } return y; } static inline dtype f_min(size_t n, char *p, ssize_t stride) { dtype x,y; size_t i=n; y = *(dtype*)p; p += stride; i--; for (; i--;) { x = *(dtype*)p; if (x < y) { y = x; } p += stride; } return y; } static inline dtype f_max(size_t n, char *p, ssize_t stride) { dtype x,y; size_t i=n; y = *(dtype*)p; p += stride; i--; for (; i--;) { x = *(dtype*)p; if (x > y) { y = x; } p += stride; } return y; } static inline size_t f_min_index(size_t n, char *p, ssize_t stride) { dtype x, y; size_t i, j=0; y = *(dtype*)p; for (i=1; i y) { y = x; j = i; } } return j; } static inline double f_seq(double x, double y, double c) { return x + y * c; }