I have a very concrete question about degree $d$ curves in $\mathbb{P}^2$.
Let $$\mathcal{D} \approx \mathbb{P}^{\delta_d}$$
be the space of homogeneous degree $d$ polynomials in three variables upto
scaling, where $\delta_d = \frac{d(d+3)}{2}$. Furthermore, let
$$ \mathcal{D}(r) \approx \mathbb{P}^r \subset \mathcal{D}$$
be the space of degree $d$ polynomials passing through $\delta_dr$
points in $\textit{general}$ position. Note that the dimension of this
space is $r$. The question I have is as follows......let
$$f\in \mathcal{D}(7),$$
i.e. let $f$ be a degree $d$ polynomial
passing through $\delta_d 7$ points in general position.
Is it correct that the only possible singularities that $f$ can have are
$A_k$ for $k= 1$ to $7$, $D_k$ for $k=4$ to $7$ and $E_6$ and
$E_7$. The reason I have in mind is that upto codimension $7$
the only possible singularities are the ADE singularities.
Any other singularity I want to rule out by
saying that the points are in ``general position''.
Is this argument correct?



Nonreduced curves in $\mathcal{O}(d)$ occur in codimension $2d1$, so you will want $d > 4$ to get rid of them. Fix a topological singularity type, and let $s$ be the codimension of its equisingular family inside its versal deformation. Then in $\mathcal{O}(d)$, singularities of this kind will occur in codimension at least $\mathrm{min}(d+1, s)$ because any length $d+1$ subscheme imposes indepedent conditions on $\mathcal{O}(d)$, and so the former can be shown to be transverse to a general $d+1$ codimensional subspace of the versal deformation of a singularity. Thus once $d \ge 7$, any singularity with $s > 8$ will not appear. This certainly limits the ADE singularities which may appear to the ones you listed. And if you have a handy table saying the only singularities with $s \le 7$ are ADE, then you could conclude. Because I don't have such a table (and because I'm trying to stay awake long enough to get over my jetlag), let's show it. Certainly $s \ge \delta$, and equality holds only for a node. So you only have to worry about singularities which have $\delta < 7$. In fact there's a better estimate coming from considering the 'equiclassical locus': $s \ge \kappa = \delta + \sum(m_i 1)$ where $m_i$ are the multiplicities of the components. Recall that $\delta$ is the sum over all infinitely near points of $m(m1)/2$, where $m$ is the multiplicity of the curve at that point. In particular, if $\delta \le 6$, then certainly $m \le 4$, and moreover if the multiplicity is $4$ then all branches must be smoothed and made disjoint after one blowup. Now I list topological types of singularities with $\delta < 7$, by number of branches:
How did I make this list? Unibranch singularities are classified by sub semigroups of $\mathbb{N}$, so I listed the ones corresponding to semigroups with at most 6 gaps; then I tried gluing them together. Most of the above list were ADE singularities. The ones that weren't: (a) $x^3 = y^7$ (b) $x^4 = y^5$, (c) two ordinary cusps with different tangents, (d) an ordinary cusp with two transverse lines, (e) $y(y+ax^2)(y+bx^2)$, and (f) four mutually transverse lines. The items (a), (b), (c), are ruled out by the constraint $\kappa < 8$. In the other cases, there is a obvious $\delta$constant deformation (move a smooth branch) which on the one hand changes the topological type of the singularity, and on the other does not reduce it to all nodes, so the equisingular locus must be of codimension at least 2 in the $\delta$constant locus. One reference for this kind of stuff is Diaz and Harris's ``Ideals associated to deformations of singular plane curves''. 

