**You can't push a rope.** No seriously, you can't because its weight is going to make it hang down in a catenary shape and you need to always pull to keep it in place.

The amount you need to pull is given by the catenary equations. Consider the hanging cable with dimensions shown below:

[![fig1][1]][1]

Actually given the pull force $H$, the remaining dimensions and values are derived from  the catenary equations. You need a measure of the weight of the rope, and it is given as $w = \frac{m g}{L}$ usually, that is $w$ is weight per unit length. Also you must know $S$, the span where the rope hangs from. 

I have summarized the catenary equations below, as well as their parabolic approximations

| Quantity | Catenary | Approximation |
| --- | --- | --- |
| Catenary Constant, $a$ | $ a = \frac{H}{w} $ |  |
| Hanging Length, $L$ | $L = 2 a \,\sinh \left( \frac{S}{2 a} \right)$ | $L = S + \frac{w^2 S^3}{24 H^2}$  |
| Maximum Sag, $D$ | $D = a \left( \cosh \left( \frac{S}{2 a} \right) -1 \right)$ | $D = \frac{w S^2}{8 H}$ |
| Support Force, $V$ | $V = H \sinh \left( \frac{S}{2 a} \right) $ | $V = \frac{w S}{2} + \frac{w^3 S^3}{48 H^2}$ |
| Total Force, $T=\sqrt{H^2+V^2}$  | $T  = H \cosh \left( \frac{S}{2 a} \right) $ | $T =H + \frac{w^2 S^2}{8 H}$ |

The above assume and inextensible rope.

So for example for a rope of length $L$ and mass $m$, you have $w= \frac{m g}{L}$ and using the parabolic approximation for $L$, you can solve for the pull force

$$ H = \sqrt{ \frac{  m^2 g^2 S^3 }{24 L^2 (L-S)} } $$

If you wanted to find the _exact_ answer, you would need a numerical method to solve the catenary equations. Usually bisection works the fastest, but you can employ single point iteration

$$ H \leftarrow \frac{w S}{2} {\rm asinh}\left( \frac{w L}{2 H} \right) $$

The convergence of the the above isn't great, as after 40 iterations the error was still over 0.5% in a test case I did.

  [1]: https://i.sstatic.net/SbiUo.png