# SPARK Integer overflow check

I have the following program:

``````procedure Main with SPARK_Mode is
F : array (0 .. 10) of Integer := (0, 1, others => 0);
begin
for I in 2 .. F'Last loop
F (I) := F (I - 1) + F (I - 2);
end loop;
end Main;
``````

If I run `gnatprove`, I get the following result, pointing to the `+` sign:

medium: overflow check might fail

Does this mean that `F (I - 1)` could be equal to `Integer'Last`, and adding anything to that would overflow? If so, then is it not clear from the flow of the program that this is impossible? Or do I need to specify this with a contract? If not, then what does it mean?

A counterexample shows that indeed `gnatprove` in this case worries about the edges of `Integer`:

medium: overflow check might fail (e.g. when `F = (1 => -1, others => -2147483648)` and `I = 2`)

• Could one claim that `F (I) <= 2 * I` for all `I`? – Jacob Sparre Andersen Nov 10 '17 at 20:19
• @JacobSparreAndersen, I think that would be true as long as `I <= 7`, and would be false otherwise. – rid Nov 10 '17 at 20:54
• Ahh. Yes. I can't remember the convergence limit for this series, but I'm sure it is possible to look it up somewhere. The trick is to convince your provers that it is correct. The easy solution would be to have `gnatprove` unroll the loop before passing it to the provers. – Jacob Sparre Andersen Nov 11 '17 at 13:09
• @JacobSparreAndersen, how can I do that? Also, wouldn't that present a problem if the upper limit of `F` would come from user input instead of being the constant `10`? – rid Nov 11 '17 at 15:00
• I think loop-unrolling is controlled by some command line parameter. And no, loop-unrolling wouldn't work if the range is dynamic. Then you have to know your math. – Jacob Sparre Andersen Nov 11 '17 at 15:44

Consider adding a loop invariant to your code. The following is an example from the book "Building High Integrity Applications with Spark".

``````procedure Copy_Into(Buffer : out Buffer_Type;
Source : in String) is
Characters_To_Copy : Buffer.Count_Type := Maximum_Buffer_Size;
begin
Buffer := (Others => ' '); -- Initialize to all blanks
if Source'Length < Characters_To_Copy then
Characters_To_Copy := Source'Length;
end if;
for Index in Buffer.Count_Type range 1..Characters_To_Copy loop
pragma Loop_Invariant
(Characters_To_Copy <= Source'Length and
Characters_To_Copy = Characters_To_Copy'Loop_Entry);
Buffer (Index) := Source(Source'First + (Index - 1));
end loop;
end Copy_Into;
``````
• I'm not sure I understand how I could use a `Loop_Invariant` for this. Can you please post an example? – rid Nov 10 '17 at 19:04
• Every trip around the loop, you change the contents of `F`. You have to help the tools, but telling them something which doesn't change about `F` by taking one more trip around the loop. (Newer versions of the SPARK tools can be told to unroll short loops, thus avoiding having to think about loop invariants.) – Jacob Sparre Andersen Nov 10 '17 at 20:16
• @JacobSparreAndersen, hmm, I'm thinking that the only thing that changes is the value of `F (I)`, everything else remains the same. Still, I'm not sure what I could express in a loop invariant to help the tool. – rid Nov 10 '17 at 20:59

This loop invariant should work - since 2^(n-1) + 2^(n-2) < 2^n - but I can't convince the provers:

``````procedure Fibonacci with SPARK_Mode is
F : array (0 .. 10) of Natural := (0      => 0,
1      => 1,
others => 0);
begin
for I in 2 .. F'Last loop
pragma Loop_Invariant
(for all J in F'Range => F (J) < 2 ** J);

F (I) := F (I - 1) + F (I - 2);
end loop;
end Fibonacci;
``````

You can probably convince the provers with a bit of manual assistance (showing how 2^(n-1) + 2^(n-2) = 2^(n-2) * (2 + 1) = 3/4 * 2^n < 2^n).