Can't the heat equation be inverted?

I have heard people say that the heat equation isn’t invertible because it smooths out irregularities that can not be recovered by backwards time evolution. But is this so? I will now argue that it can be inverted assuming that its Fourier modes decay quickly enough.

For a function $f(t, x)$, the heat equation is
$$ frac{partial}{partial t} f = frac{partial^2}{partial x^2} f.$$

We may now write
$$
f(0, x) = int_{- infty}^infty d k ; tilde{f}(k) e^{i k x }
$$
and using the linearity of the heat equation, solve
$$
f(t, x) = int_{- infty}^infty d k ; tilde{f}(k) e^{i k x – k^2 t}.
$$
One might be concerned that the above integral might not converge for negative $t$. However, if we demand that $tilde{f}(k)$ decays fast enough, namely faster than $e^{- k^2 t}$ for all $t$, then this isn’t a problem.

Assuming the above argument is correct, let’s ask if it’s possible to construct two functions $f(0, x)$ and $g(0, x)$ which aren’t equal, but are exactly equal by some finite time $t$? (Such functions would violate the aforementioned fall off condition.) Wouldn’t this violate the linearity of the heat equation? The function $f(0, x) – g(0, x)$ would evolve from being non-zero to exactly $0$.

So I guess my general question is, can the heat equation be inverted or not?