func number_divide(x, y Obj) Obj {
xfx := (uintptr(unsafe.Pointer(x)) & fixnum_mask) == fixnum_tag
yfx := (uintptr(unsafe.Pointer(y)) & fixnum_mask) == fixnum_tag
if xfx && yfx {
i1 := int(uintptr(unsafe.Pointer(x))) >> fixnum_shift
i2 := int(uintptr(unsafe.Pointer(y))) >> fixnum_shift
// A good optimizer will combine the div and mod into
// one instruction.
r, m := i1/i2, i1%i2
if m == 0 && r > fixnum_min && r < fixnum_max {
return Make_fixnum(r)
} else {
return wrap(big.NewRat(int64(i1), int64(i2)))
}
}
if (!xfx && (uintptr(unsafe.Pointer(x))&heap_mask) != heap_tag) ||
(!yfx && (uintptr(unsafe.Pointer(y))&heap_mask) != heap_tag) {
panic("bad type")
}
if xfx {
x = wrap(big.NewInt(int64(fixnum_to_int(x))))
}
if yfx {
y = wrap(big.NewInt(int64(fixnum_to_int(y))))
//return wrap(z.Div(vx,vy))
}
switch vx := (*x).(type) {
case *big.Int:
var z *big.Int = big.NewInt(0)
switch vy := (*y).(type) {
case *big.Int:
return simpBig(z.Div(vx, vy))
case *big.Rat:
z := big.NewRat(1, 1)
z.SetInt(vx)
return simpRat(z.Quo(z, vy))
default:
panic("bad type")
}
case *big.Rat:
z := big.NewRat(1, 1)
switch vy := (*y).(type) {
case *big.Int:
z.SetInt(vy)
return simpRat(z.Quo(vx, z))
case *big.Rat:
return simpRat(z.Quo(vx, vy))
}
}
panic("bad type")
}
func number_multiply(x, y Obj) Obj {
xfx := (uintptr(unsafe.Pointer(x)) & fixnum_mask) == fixnum_tag
yfx := (uintptr(unsafe.Pointer(y)) & fixnum_mask) == fixnum_tag
if xfx && yfx {
i1 := int64(int(uintptr(unsafe.Pointer(x))))
i2 := int64(int(uintptr(unsafe.Pointer(y))))
r := (i1 >> fixnum_shift) * (i2 >> fixnum_shift)
if r > int64(fixnum_min) && r < int64(fixnum_max) {
return Make_fixnum(int(r))
} else {
return wrap(big.NewInt(r))
}
}
if (!xfx && (uintptr(unsafe.Pointer(x))&heap_mask) != heap_tag) ||
(!yfx && (uintptr(unsafe.Pointer(y))&heap_mask) != heap_tag) {
panic("bad type")
}
if xfx {
x = wrap(big.NewInt(int64(fixnum_to_int(x))))
}
if yfx {
y = wrap(big.NewInt(int64(fixnum_to_int(y))))
}
switch vx := (*x).(type) {
case *big.Int:
var z *big.Int = big.NewInt(0)
switch vy := (*y).(type) {
case *big.Int:
return simpBig(z.Mul(vx, vy))
case *big.Rat:
z := big.NewRat(1, 1)
z.SetInt(vx)
return simpRat(z.Mul(z, vy))
default:
panic("bad type")
}
case *big.Rat:
z := big.NewRat(1, 1)
switch vy := (*y).(type) {
case *big.Int:
z.SetInt(vy)
return simpRat(z.Mul(vx, z))
case *big.Rat:
return simpRat(z.Mul(vx, vy))
}
}
panic("bad type")
}
