How is the rectangle represented? Three points? Four points? Point, sides and angle? Two points and a side? Something else? Without knowing that, any attempts to answer your question will have only purely academic value.

In any case, for any *convex* polygon (including rectangle) the test is very simple: check each edge of the polygon, assuming each edge is oriented in counterclockwise direction, and test whether the point lies *to the left* of the edge (in the left-hand half-plane). If all edges pass the test - the point is inside. If at least one fails - the point is outside.

In order to test whether the point `(xp, yp)`

lies on the left-hand side of the edge `(x1, y1) - (x2, y2)`

, you just need to calculate

```
D = (x2 - x1) * (yp - y1) - (xp - x1) * (y2 - y1)
```

If `D > 0`

, the point is on the left-hand side. If `D < 0`

, the point is on the right-hand side. If `D = 0`

, the point is on the line.

The previous version of this answer described a seemingly different version of left-hand side test (see below). But it can be easily shown that it calculates the same value.

... In order to test whether the point `(xp, yp)`

lies on the left-hand side of the edge `(x1, y1) - (x2, y2)`

, you need to build the line equation for the line containing the edge. The equation is as follows

```
A * x + B * y + C = 0
```

where

```
A = -(y2 - y1)
B = x2 - x1
C = -(A * x1 + B * y1)
```

Now all you need to do is to calculate

```
D = A * xp + B * yp + C
```

If `D > 0`

, the point is on the left-hand side. If `D < 0`

, the point is on the right-hand side. If `D = 0`

, the point is on the line.

However, this test, again, works for any convex polygon, meaning that it might be too generic for a rectangle. A rectangle might allow a simpler test... For example, in a rectangle (or in any other parallelogram) the values of `A`

and `B`

have the same magnitude but different signs for opposing (i.e. parallel) edges, which can be exploited to simplify the test.