/*
* Ikarus Scheme -- A compiler for R6RS Scheme.
* Copyright (C) 2006,2007,2008 Abdulaziz Ghuloum
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 3 as
* published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#include "ikarus-data.h"
#include
#include
#include
#include
ikptr
ikrt_fl_round(ikptr x, ikptr y){
flonum_data(y) = round(flonum_data(x));
return y;
}
ikptr
ikrt_fl_exp(ikptr x, ikptr y){
flonum_data(y) = exp(flonum_data(x));
return y;
}
ikptr
ikrt_flfl_expt(ikptr a, ikptr b, ikptr z){
flonum_data(z) = exp(flonum_data(b) * log(flonum_data(a)));
return z;
}
ikptr
ikrt_bytevector_to_flonum(ikptr x, ikpcb* pcb){
double v = strtod((char*)(long)x+off_bytevector_data, NULL);
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = v;
return r;
}
ikptr
ikrt_fl_plus(ikptr x, ikptr y,ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = flonum_data(x) + flonum_data(y);
return r;
}
ikptr
ikrt_fl_minus(ikptr x, ikptr y,ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = flonum_data(x) - flonum_data(y);
return r;
}
ikptr
ikrt_fl_times(ikptr x, ikptr y,ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = flonum_data(x) * flonum_data(y);
return r;
}
ikptr
ikrt_fl_div(ikptr x, ikptr y,ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = flonum_data(x) / flonum_data(y);
return r;
}
ikptr
ikrt_fl_invert(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = 1.0 / flonum_data(x);
return r;
}
ikptr
ikrt_fl_sin(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = sin(flonum_data(x));
return r;
}
ikptr
ikrt_fl_cos(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = cos(flonum_data(x));
return r;
}
ikptr
ikrt_fl_tan(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = tan(flonum_data(x));
return r;
}
ikptr
ikrt_fl_asin(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = asin(flonum_data(x));
return r;
}
ikptr
ikrt_fl_acos(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = acos(flonum_data(x));
return r;
}
ikptr
ikrt_fl_atan(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = atan(flonum_data(x));
return r;
}
ikptr
ikrt_atan2(ikptr y, ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = atan2(flonum_data(y), flonum_data(x));
return r;
}
ikptr
ikrt_fl_sqrt(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = sqrt(flonum_data(x));
return r;
}
ikptr
ikrt_fl_log(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = log(flonum_data(x));
return r;
}
ikptr
ikrt_fx_sin(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = sin(unfix(x));
return r;
}
ikptr
ikrt_fx_cos(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = cos(unfix(x));
return r;
}
ikptr
ikrt_fx_tan(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = tan(unfix(x));
return r;
}
ikptr
ikrt_fx_asin(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = asin(unfix(x));
return r;
}
ikptr
ikrt_fx_acos(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = acos(unfix(x));
return r;
}
ikptr
ikrt_fx_atan(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = atan(unfix(x));
return r;
}
ikptr
ikrt_fl_sinh(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = sinh(flonum_data(x));
return r;
}
ikptr
ikrt_fl_cosh(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = cosh(flonum_data(x));
return r;
}
ikptr
ikrt_fl_tanh(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = tanh(flonum_data(x));
return r;
}
ikptr
ikrt_fl_asinh(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = asinh(flonum_data(x));
return r;
}
ikptr
ikrt_fl_acosh(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = acosh(flonum_data(x));
return r;
}
ikptr
ikrt_fl_atanh(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = atanh(flonum_data(x));
return r;
}
ikptr
ikrt_fx_sqrt(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = sqrt(unfix(x));
return r;
}
ikptr
ikrt_fx_log(ikptr x, ikpcb* pcb){
ikptr r = ik_unsafe_alloc(pcb, flonum_size) + vector_tag;
ref(r, -vector_tag) = (ikptr)flonum_tag;
flonum_data(r) = log(unfix(x));
return r;
}
ikptr
ikrt_fixnum_to_flonum(ikptr x, ikptr r, ikpcb* pcb){
flonum_data(r) = unfix(x);
return r;
}
ikptr
ikrt_fl_equal(ikptr x, ikptr y){
if(flonum_data(x) == flonum_data(y)){
return true_object;
} else {
return false_object;
}
}
ikptr
ikrt_fl_less_or_equal(ikptr x, ikptr y){
if(flonum_data(x) <= flonum_data(y)){
return true_object;
} else {
return false_object;
}
}
ikptr
ikrt_fl_less(ikptr x, ikptr y){
if(flonum_data(x) < flonum_data(y)){
return true_object;
} else {
return false_object;
}
}