# Algorithm to determine whether two periodic sequences of intervals have a nonempty intersection

I am looking for an algorithm that, given natural parameters l1, n1, m1, l2, n2, m2, and size, answers "true" if and only if there exists natural numbers k1, k2, r1, r2 such that:

l1 + k1*m1 + r1 = l2 + k2*m2 + r2

with the constraints k1 <= n1, k2 <= n2, r1 < size, r2 < size and r1 <> r2.

The obvious solution is linear in min(n1, n2). I am looking for something a little more efficient.

## Context

I am trying to implement in a static analyzer a check for C99 rule 6.5.16.1:3

If the value being stored in an object is read from another object that overlaps in any way the storage of the first object, then the overlap shall be exact [...] otherwise, the behavior is undefined.

When the analyzer encounters an assignment `*p1 = *p2;` where `p1` and `p2` may point into the same block, it must check that the zones pointed by `p1` and `p2` do not overlap in a way forbidden by the above rule. The parameter "size" above corresponds to the size of the type pointed by `p1` and `p2`. This size is statically known. The offsets that `p1` are known to point to inside the block are represented as a set l1 + k1*m1 with l1 and m1 fixed, known natural integers and k1 varying between 0 and n1 (n1 is also fixed and known). Similarly, the offsets `p2` is known to point to are of the form l2 + k2*m2 for some known l2, m2 and n2. The equation l1 + k1*m1 + r1 = l2 + k2*m2 + r2 corresponds to the existence of some overlapping offsets. The condition r1 <> r2 corresponds to the case where the overlap is not exact, when the analyzer must warn.

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Can you give an example set of parameters? –  vhallac Sep 3 '11 at 21:23
@vhallac l1=0, m1 = 512, n1 = 1000, l2=128, m2 = 760, n2 = 300, size = 128. –  Pascal Cuoq Sep 3 '11 at 21:27

It seems you are looking for the solution to a linear system of congruences. The Chinese remainder theorem should be applicable. It won't apply your bounds checking, but if it finds a solution you can then check bounds yourself trivially.

EDIT: Forget the CRT.

Assuming `size <= m1` and `size <= m2`, model the low (inclusive) and high (exclusive) edges of your memory regions as linear relations:

``````addr1low = l1 + k1*m1
``````

You want to know if there exist `k1, k2` in range such that `addr1low < addr2low < addr1high` or `addr1low < addr2high < addr1high`. Note the exclusive inequalities; this way we avoid exactly overlapping ranges.

Suppose `m1 = m2 = m`. Consider:

``````addr1low < addr2low
l1 + k1*m < l2 + k2*m
(k1 - k2) * m < l2 - l1
k1 - k2 < (l2 - l1) / m

l2 + k2*m < l1 + k1*m + size
l2 - l1 < (k1 - k2) * m + size
(l2 - l1 - size) < (k1 - k2) * m
(l2 - l1 - size) / m < k1 - k2
``````

The progression above is reversible. Assuming `k1, k2` may be 0, `-n2 <= k1 - k2 <= n1`. If there is an integer in range between `(l2 - l1 - size) / m` and `(l2 - l1) / m`, then the system holds and there is an overlap. That is, if `ceil(max((l2 - l1 - size) / m, -n2)) <= floor(min((l2 - l1) / m, n1))`. The other case (`addr1low < addr2high < addr1high`) proceeds similarly:

``````addr1low < addr2high
l1 + k1*m < l2 + k2*m + size
// ..
(l1 - l2 - size) / m < k2 - k1

// ..
k2 - k1 < (l1 - l2) / m
``````

Now the test becomes `ceil(max((l1 - l2 - size) / m, -n1)) <= floor(min((l1 - l2) / m, n2))`.

Now consider `m1 <> m1`, and without loss of generality take `m1 < m2`.

Treating the variables as continuous, solve the intersections:

``````addr1low < addr2low
l1 + k*m1 < l2 + k*m2
(l1 - l2) < k * (m2 - m1)
(l1 - l2) / (m2 - m1) < k

l2 + k*m2 < l1 + k*m1 + size
l2 - l1 - size < k * (m1 - m2)
(l2 - l1 - size) / (m1 - m2) > k  // m1 - m2 < 0
``````

Again, the steps are reversible, so any integer `k < min(n1, n2)` that satisfies the bounds will make the system hold. That is, it holds if `ceil(max((l1 - l2) / (m2 - m1), 0)) <= floor(min((l2 - l1 - size) / (m1 - m2), n1, n2))`. The other case:

``````addr1low < addr2high
l1 + k*m1 < l2 + k*m2 + size
l1 - l2 - size < k * (m2 - m1)
(l1 - l2 - size) / (m2 - m1) < k

l2 + k*m2 < l1 + k*m1
l2 - l1 < k * (m1 - m2)
(l2 - l1) / (m1 - m2) > k   // m1 - m2 < 0
``````

Here the test becomes `ceil(max((l1 - l2 - size) / (m2 - m1), 0)) <= floor(min((l2 - l1) / (m1 - m2), n1, n2))`.

The final pseudo code might look something like this:

``````intersectos?(l1, n1, m1, l2, n2, m2, size) {
if (m1 == m2) {
return ceil(max((l2 - l1 - size) / m, -n2)) <= floor(min((l2 - l1) / m, n1)) ||
ceil(max((l1 - l2 - size) / m, -n1)) <= floor(min((l1 - l2) / m, n2));
}

if (m1 > m2) {
swap the arguments
}

return ceil(max((l1 - l2) / (m2 - m1), 0)) <= floor(min((l2 - l1 - size) / (m1 - m2), n1, n2)) ||
ceil(max((l1 - l2 - size) / (m2 - m1), 0)) <= floor(min((l2 - l1) / (m1 - m2), n1, n2));
}
``````
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Yes, I'd check that the bounds make a nonempty intersection possible first, since that's the easy part. Could you perhaps expand your answer into an actual algorithm? The way I see it right now is still linear in size, which can be large (yes, I'm slow). –  Pascal Cuoq Sep 3 '11 at 21:45
The free term `r2-r1` makes it very difficult to convert to a CRT. But maybe O(size) would be better than O(min(n1, n2)). :) But still it hurts that `m1` and `m2` are not coprime - which is required for CRT. –  vhallac Sep 3 '11 at 21:52
+1 for nice and detailed derivation. One question, though: I don't get the `k` in the `m1 <> m2` case. If there is no such `k`, isn't it still possible that there may be some `k1`, `k2` where `k1 <> k2` that satisfy the inequalities? –  vhallac Sep 4 '11 at 10:28
Yea, you may be right. If m1 <> m2, then the addr(k) linears intersect, and do at most once (so, the common k exists and is unique.) However, it may be that the bounds check on the intersection fails and yet the regions overlap elsewhere.. –  phs Sep 4 '11 at 19:24