/* @(#)z_powf.c 1.0 98/08/13 */ #include #include "fdlibm.h" #include "zmath.h" float powf (float x, float y) { float d, k, t, r = 1.0; int n, sign, exponent_is_even_int = 0; __int32_t px; GET_FLOAT_WORD (px, x); k = modff (y, &d); if (k == 0.0) { /* Exponent y is an integer. */ if (modff (ldexpf (y, -1), &t)) { /* y is odd. */ exponent_is_even_int = 0; } else { /* y is even. */ exponent_is_even_int = 1; } } if (x == 0.0) { if (y <= 0.0) errno = EDOM; } else if ((t = y * log (fabsf (x))) >= BIGX) { errno = ERANGE; if (px & 0x80000000) { /* x is negative. */ if (k) { /* y is not an integer. */ errno = EDOM; x = 0.0; } else if (exponent_is_even_int) x = z_infinity_f.f; else x = -z_infinity_f.f; } else { x = z_infinity_f.f; } } else if (t < SMALLX) { errno = ERANGE; x = 0.0; } else { if ( !k && fabsf (d) <= 32767 ) { n = (int) d; if ((sign = (n < 0))) n = -n; while ( n > 0 ) { if ((unsigned int) n % 2) r *= x; x *= x; n = (unsigned int) n / 2; } if (sign) r = 1.0 / r; return r; } else { if ( px & 0x80000000 ) { /* x is negative. */ if (k) { /* y is not an integer. */ errno = EDOM; return 0.0; } } x = exp (t); if (!exponent_is_even_int) { if (px & 0x80000000) { /* y is an odd integer, and x is negative, so the result is negative. */ GET_FLOAT_WORD (px, x); px |= 0x80000000; SET_FLOAT_WORD (x, px); } } } } return x; } #ifdef _DOUBLE_IS_32BITS double pow (double x, double y) { return (double) powf ((float) x, (float) y); } #endif /* defined(_DOUBLE_IS_32BITS) */