I have one big analytical function `myfunc.m`

for which I need to obtain the derivative in code format `d_myfunc_dx.m`

. The problem constraints is that I need to produce code that I can refactor, so I can meet some quality requirements, and that the function itself has a few particularities, which are reproduced by the minimal example below.

```
function[out] = myfunc(x,a, max_iterations)
count = 0;
theta = 0;
delta = 1;
while (count<max_iterations && abs(delta)<eps)
cout = count+1;
delta = theta - cos(theta*x);
theta = theta - delta;
end
if(theta<a)
out = theta+x
else
out = x
end
end
```

Ideally, the derivative function should look like this:

```
function[d_out_dx] = myfunc(x,a, max_iterations)
count = 0;
theta = 0;
delta = 1;
while (count<max_iterations && abs(delta)<eps)
cout = count+1;
delta = theta - cos(theta*x);
theta = theta - delta;
end
%assuming convergence: theta = cos(theta*x):
d_theta_dx = -theta*sin(theta*x);
if(theta>a)
d_out_dx = d_theta_dx+1
else
d_out_dx = 1
end
end
```

I.e. That's readable, so I can refactor it, it contains the branches which were present on the original function. The edge case `theta=a`

is ignored which is actually desirable.

But I'm not expecting any tool to assume the convergence of the iterative method and perform an implicit derivative. So I'd be satisfied if I got something like:

```
function[d_out_dx] = myfunc(x,a, max_iterations)
count = 0;
theta = 0;
delta = 1;
d_theta_dx = 0;
while (count<max_iterations && abs(delta) < eps)
cout = count+1;
delta = theta - cos(theta*x);
d_delta_dx = d_theta_dx + theta*sin(theta*x)
theta = theta - delta;
d_theta_dx = d_theta_dx - d_delta_dx
end
if(theta>a)
d_out_dx = d_theta_dx+1
else
d_out_dx = 1
end
end
```

Always nice if I could find some free tool for this job.

I'm also required to test the code checked independently, so I'll know if anything didn't went well. No concern about reliability of tool. Because of the standards employed during refactor, I won't worry about safety of the generated code (i.e. protection against zero division).

What I've tried so far:

**-Hand-Coding**: Because the functions I need to work with are very large, and the process being error prone, I simply can't get a correct code. Plus, I need to derivate with respect to several variables, which means the process would be too much time consuming.

**-ADiMat**: Introduced functions such as adimat_opdiff_mult(t_theta, theta, t_x, x), this causes me not to comply with my coding standards. And refactoring it would mean having almost the same work as hand-writing the derivatives.

**-ADiGator**: It cannot parse conditionals, so I'd need to remove branches from the target function and re-obtain the derivative for each case. It created lots of intermediate variables, for which the names aren't helpful, but at least are readable.

**-Casadi:** As far as I've experimented with it, it creates text rather than code, and within this text, the variables internal to the function lose their names and are replaced by `@1`

, `@2`

, `@3`

and so on. Would be a nightmare to recode by hand and difficult to rely on a custom script to refactor it.