For Boolean values, you can use the functions `is_true`

and `is_false`

. Numerical values can be integer, rational or algebraic. We can use the functions `is_int_value`

, `is_rational_value`

and `is_algebraic_value`

to test each case. The integer case is the simplest, we can use the method `as_long()`

to convert the Z3 integer value into a Python long. For rational values, we can use the methods `numerator()`

and `denominator()`

to obtain the Z3 integers representing the numerator and denominator. The methods `numerator_as_long()`

and `denominator_as_long()`

are shortcuts for `self.numerator().as_long()`

and `self.denominator().as_long()`

. Finally, algebraic numbers are used to represent irrational numbers. The `AlgebraicNumRef`

class has a method called `approx(self, precision)`

. It returns a Z3 rational number that approximates the algebraic number with precision `1/10^precision`

. Here is an example on how to use this methods. It is also available online at: http://rise4fun.com/Z3Py/Mkw

```
p = Bool('p')
x = Real('x')
s = Solver()
s.add(Or(x < 5, x > 10), Or(p, x**2 == 2), Not(p))
s.check()
m = s.model()
print m[p], m[x]
print "is_true(m[p]):", is_true(m[p])
print "is_false(m[p]):", is_false(m[p])
print "is_int_value(m[x]):", is_int_value(m[x])
print "is_rational_value(m[x]):", is_rational_value(m[x])
print "is_algebraic_value(m[x]):", is_algebraic_value(m[x])
r = m[x].approx(20) # r is an approximation of m[x] with precision 1/10^20
print "is_rational_value(r):", is_rational_value(r)
print r.numerator_as_long()
print r.denominator_as_long()
print float(r.numerator_as_long())/float(r.denominator_as_long())
```

`bool(s.model()[x])`

and`float(s.model()[p])`

?`bool(s.model()[p])`

gives`True`

, when it should be`False`

and`float(s.model()[x])`

throws an exception`AttributeError: AlgebraicNumRef instance has no attribute '__float__'`