# z3 const declaration

In Z3 Python, what's the diff between 1) `x = Const("x",IntSort())` vs 2) `x = Int("x")` ? is_const returns true for both and they are both ArithRef. I would thought 1) would be appropriate for defining a const, e.g., x is 3.14 and 2) is to making a variable.

Is there a correct way to create a const variable like x = 3.14 (other than generating a formula x == 3.14)

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There is no difference between `Const("x", IntSort())` and `Int("x")`. We should view `Int("x")` as syntax sugar for the former. The function `Const` is usually used to define constants of user defined sorts. Example:

``````S, (a, b, c) = EnumSort('S', ('a', 'b', 'c'))
x = Const("x", S)
``````

In Z3, we use the term "variable" for universal and existential variables. Quantifier free formulas do not contain variables, only constants. In the formula, `x + 1 > 0`, we say `x` and `1` are constants. We say `x` is a uninterpreted constant, and `1` is interpreted one. That is, the meaning of `1` is fixed, but Z3 is free to assign an interpretation for `x` in order to make a formula satisfiable. If you just want to create the interpreted constant `3.14`, you can use `RealVal('3.14')`. In the following example, `x` is not a Z3 expression, but a Python variable that points to the Z3 expression `3.14`. We can use `x` as shorthand for `3.14` when building Z3 expressions/formulas. The Python variable `z` is pointing to the Z3 expression `y`. Finally, `z > x` returns the Z3 expression `y > 3.14`. Z3Py beginners usually confuse Python variables with Z3 expressions. After the difference is clear, everything starts to make sense.

``````x = RealVal('3.14')
z = Real('y')
print z > x
``````
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Thanks, that makes sense .. Another one: does z3 or smtlib in general allow declaring variables with certain ranges ? e.g., `x = [0,100]` ,i.e. `x` can only have values from 0 to 100. I know I can declare `x` as an int and assert `0<=x <= 100` to force `x` to be within the range. – Vu Nguyen Sep 17 '12 at 18:39
No, we have to declare `x` as an integer (or Real), and assert that `0 <= x` and `x <= 100`. – Leonardo de Moura Sep 17 '12 at 20:52