#include "ikarus.h" #include #include #include #include ikp ikrt_bytevector_to_flonum(ikp x, ikpcb* pcb){ double v = strtod((char*)x+off_bytevector_data, NULL); ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = v; return r; } ikp ikrt_fl_plus(ikp x, ikp y,ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = flonum_data(x) + flonum_data(y); return r; } ikp ikrt_fl_minus(ikp x, ikp y,ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = flonum_data(x) - flonum_data(y); return r; } ikp ikrt_fl_times(ikp x, ikp y,ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = flonum_data(x) * flonum_data(y); return r; } ikp ikrt_fl_div(ikp x, ikp y,ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = flonum_data(x) / flonum_data(y); return r; } ikp ikrt_fl_invert(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = 1.0 / flonum_data(x); return r; } ikp ikrt_fl_sin(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = sin(flonum_data(x)); return r; } ikp ikrt_fl_cos(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = cos(flonum_data(x)); return r; } ikp ikrt_fl_sqrt(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = sqrt(flonum_data(x)); return r; } ikp ikrt_fl_log(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = log(flonum_data(x)); return r; } ikp ikrt_fl_atan(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = atan(flonum_data(x)); return r; } ikp ikrt_fx_sin(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = sin(unfix(x)); return r; } ikp ikrt_fx_cos(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = cos(unfix(x)); return r; } ikp ikrt_fx_sqrt(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = sqrt(unfix(x)); return r; } ikp ikrt_fx_atan(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = atan(unfix(x)); return r; } ikp ikrt_fx_log(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = log(unfix(x)); return r; } ikp ikrt_fixnum_to_flonum(ikp x, ikpcb* pcb){ ikp r = ik_alloc(pcb, flonum_size) + vector_tag; ref(r, -vector_tag) = (ikp)flonum_tag; flonum_data(r) = unfix(x); return r; } ikp ikrt_fl_equal(ikp x, ikp y){ if(flonum_data(x) == flonum_data(y)){ return true_object; } else { return false_object; } } ikp ikrt_fl_less_or_equal(ikp x, ikp y){ if(flonum_data(x) <= flonum_data(y)){ return true_object; } else { return false_object; } } ikp ikrt_fl_less(ikp x, ikp y){ if(flonum_data(x) < flonum_data(y)){ return true_object; } else { return false_object; } }