**note: this answer assumes your shape is a proper polygon.**

For our purposes, we'll define an equilibrium position as one where **the Center of Mass is directly above a point that is between the leftmost and rightmost ground-contact points of the object** (assuming the ground is a flat surface perpendicular to the force of gravity). This will work in all cases, for all shapes.

Note that, this is actually the *physical definition* of rotational equilibrium, as a consequence of Newtonian Rotational Kinematics.

For a proper polygon, if we eliminate cases where they stand on a sole vertex, this definition is equivalent to a stable position.

So, if you have a straight downward gravity, first find the left-most and right-most parts of it that are touching the ground.

Then, calculate your Center of Mass. For a polygon with known vertices and **uniform density**, this problem is reduced to finding the Centroid (relevant section).

Afterwards, drop a line from your CoM; if the intersection of the CoM and the ground is between those two x values, it's at equilibrium.

If your leftmost point and rightmost point match (ie, in a round object), this will still hold; just remember to be careful with your floating point comparisms.

Note that this can also be used to measure "how stable" an object is -- this measure is the maximum y-distance the Center of Mass can move before it is no longer within the range of the two contact points.

EDIT: nifty diagram made hastily

So, how can you use this to find all the ways it can sit on a table? See:

**EDIT**

# The programmable approach

Instead of the computationally expensive task of rotating the shape, try this instead.

Your shape's representation in your program should probably have a list of all vertices.

Find the vertices of your shape's convex hull (basically, your shape, but with all concave vertices -- vertices that are "pushed in" -- eliminated).

Then Iterate through each of pair of adjacent vertices on your convex hull (ie, if I had vertices A, B, C, D, I'd iterate through AB, BC, CD, DA)

Do this test:

- Draw a line
**A** through the two vertices being tested
- Draw a line perpendicular to
**A**, going through CoM **C**.
- Find the intersection of the two lines (simple algebra)
- If the intersection's y value is in between the y value of the two vertices, it stable. If the y values are all equal, compare the x values.

That should do the trick.

Here is an example of the test being running on one pair of vertices:

If your shape is not represented by its vertices in your data structure, then you should try to convert them. If it's something like a circle or an ellipse, you may use heuristics to guess the answer (a circle has infinite equilibrium positions; an ellipse 4, albeit only two "stable" points). If it's a curved wobbly irregular shape, you're going to have to supply your data structure for me be able to help in a program-related way, instead of just providing case-by-case heuristics.