I'm trying to implement direct collocation from scratch in a MathematicalProgram such that each constraint is a Python function, meaning that I can get the gradient of each constraint and cost with respect to their inputs. My goal is to use these gradients for a downstream task.

I'm converting the "Direct Collocation for the Pendulum" part of this notebook: https://github.com/RussTedrake/underactuated/blob/master/trajopt.ipynb to a MathematicalProgram. I've been able to convert the cost and constraints to lambdas instead of Formulas. For instance:

```
torque_limit = 3.0 # N*m.
u = dircol.input()
dircol.AddConstraintToAllKnotPoints(-torque_limit <= u[0])
dircol.AddConstraintToAllKnotPoints(u[0] <= torque_limit)
```

becomes

```
torque_limit = 3.0 # N*m.
for n in range(N-1):
constraint = prog.AddConstraint(lambda u: u, [-torque_limit], [torque_limit], [u[n][0]])
```

This means I can use ExtractGradient with that constraint:

```
ExtractGradient(constraint.evaluator().Eval(InitializeAutoDiff(arbitrary_u_vector)))
```

The one constraint I have not been able to turn into a Python lambda/function is the constraint for Pendulum's dynamics, since that is implemented inside the black box of DirectCollocation. I've read the C++ for DirectCollocation, but I haven't been able to figure it out.

What would it take to either reimplement trajectory optimization's dynamics constraint in Python as a function/lambda or access the dynamics constraint's gradient in Python in some other way? I would like to be able to do this for an arbitrary MultibodyPlant, say Quadrotor or Acrobot, not just Pendulum.