For a planet of mass **m**, at a distance **r** from the ship, the ship will experience
an acceleration:

**a** = k **m** / **r**^2,

where k is some constant that depends on the units you're using. The acceleration will
be directed toward the planet. It might be convenient to break down the acceleration
into its components along the x and y axes (assuming you're working in 2 dimensions).
If the planet is at an angle **theta** in the x-y plane, relative to the ship,

**a**_{x} = **a** cos(**theta**)

**a**_{y} = **a** sin(**theta**)

For multiple planets, you can just add the accelerations component-wise.

If the ship has an initial velocity **v**_{x} at time **t**, then the velocity at
the next time step **t** + **delta_t** would be:

**v**_{x} + **a**_{x} * **delta_t**

If this ship is at initial position **p**_{x} at time t, then the position
at **t** + **delta_t** would be:

**p**_{x} + **v**_{x} **delta_t** + **a**_{x} **delta_t**^2 / 2

See: Equations of motion