Let's start with what you asked for.
On pretty much no hardware that exists currently will
attribute float weights; compile. While shaders can have arrays of attributes, each array index represents a new attribute index. And on all hardware the currently exists, the maximum number of attribute indices is... 16. You'd need 25, and that's just for the weights.
Now, you can mitigate this easily enough by remembering that you can use
vec4 attributes. Thus, you store every four array elements in a single attribute. Your array would be
attribute vec4 weights; which is doable. Your weight-fetching logic will have to change of course.
Even so, you don't seem to be taking in the ramifications of what this would actually mean for your vertex data. Each attribute represents a component of a vertex's data. Each vertex for a rendering call will have the same amount of data; the contents of that data will differ, but not how much data.
In order to do what you're suggesting, every vertex in your mesh would need 25 floats describing the weight. Even if this was stored as normalized unsigned bytes, that's still 25 extra bytes worth of data at a minimum. That's a lot. Especially considering that for the vast majority of vertices, most of these values will be 0. Even in the worst case, you'd be looking at maybe 6-7 bones affecting an single vertex.
The way skinning is generally done in vertex shaders is to limit the number of bones that affects a single vertex to four. This way, you don't use an array of attributes; you just use a
vec4 attribute for the weights. Of course, you also now need to say which bone is associated with which weight. So you have a second
vec4 attribute that specifies the bone index for that weight.
This strikes a good balance. You only take up 2 extra attributes (which can be unsigned bytes in terms of size). And for the vast majority of vertices, you'll never even notice, because most vertices are only influenced by 1-3 bones. A few uses 4, and fewer still use 5+. In those cases, you just cut off the lowest weights and recompute the weights of the others proportionately.