Here is a slightly verbose method that returns the intersection intervals between an (infinite) line and a rectangle using only basic math:

```
// Line2 - 2D line with origin (= offset from 0,0) and direction
// Rectangle2 - 2D rectangle by min and max points
// Contacts - Stores entry and exit times of a line through a convex shape
Contacts findContacts(const Line2 &line, const Rectangle2 &rect) {
Contacts contacts;
// If the line is not parallel to the Y axis, find out when it will cross
// the limits of the rectangle horizontally
if(line.Direction.X != 0.0f) {
float leftTouch = (rect.Min.X - line.Origin.X) / line.Direction.X;
float rightTouch = (rect.Max.X - line.Origin.X) / line.Direction.X;
contacts.Entry = std::fmin(leftTouch, rightTouch);
contacts.Exit = std::fmax(leftTouch, rightTouch);
} else if((line.Offset.X < rect.Min.X) || (line.Offset.X >= rect.Max.X)) {
return Contacts::None; // Rectangle missed by vertical line
}
// If the line is not parallel to the X axis, find out when it will cross
// the limits of the rectangle vertically
if(line.Direction.Y != 0.0f) {
float topTouch = (rectangle.Min.Y - line.Offset.Y) / line.Direction.Y;
float bottomTouch = (rectangle.Max.Y - line.Offset.Y) / line.Direction.Y;
// If the line is parallel to the Y axis (and it goes through
// the rectangle), only the Y axis needs to be taken into account.
if(line.Direction.X == 0.0f) {
contacts.Entry = std::fmin(topTouch, bottomTouch);
contacts.Exit = std::fmax(topTouch, bottomTouch);
} else {
float verticalEntry = std::fmin(topTouch, bottomTouch);
float verticalExit = std::fmax(topTouch, bottomTouch);
// If the line already left the rectangle on one axis before entering it
// on the other, it has missed the rectangle.
if((verticalExit < contacts.Entry) || (contacts.Exit < verticalEntry)) {
return Contacts::None;
}
// Restrict the intervals from the X axis of the rectangle to where
// the line is also within the limits of the rectangle on the Y axis
contacts.Entry = std::fmax(verticalEntry, contacts.Entry);
contacts.Exit = std::fmin(verticalExit, contacts.Exit);
}
} else if((line.Offset.Y < rect.Min.Y) || (line.Offset.Y > rect.Max.Y)) {
return Contacts::None; // Rectangle missed by horizontal line
}
return contacts;
}
```

This approach offers a high degree of numerical stability (the intervals are, in all cases, the result of a single subtraction and division) but involves some branching.

For a line segment (with start and end points), you'd need to provide the segment's start point as the origin and for the direction, `end - start`

. Calculating the coordinates of the two intersections is a simple as `entryPoint = origin + direction * contacts.Entry`

and `exitPoint = origin + direction * contacts.Exit`

.