It sounds like you already know what the graph should look like, so I believe if you can use a depth-first search approach. Although breath-first search can be used to avoid recursion.
For example, if you have the nodes 1-5, and k=2, then you can build a graph by starting at node 1, and then simply randomly choosing an unvisited node. Like so:
1 [Start at 1]
1-2 [expand 2, add edge(1,2) to graph]
1-2-3 [expand 3, add edge(2,3) to graph]
1-2-3-4 [expand 4, add edge(3,4) to graph]
1-2-3-4-5 [expand 5, add edge(4,5) to graph]
1-2-3-4-5-1 [expand 1, add edge(5,1) to graph] (this step may or may not be done)
If an edge is never used twice, then p paths will lead to degree p*2 overall, with the degree of the start and end nodes dependent on if the paths are really a tour. To avoid duplicate work, it is probably easier to just label of the vertices as the integers 1 through N, then create edges such that each vertex, v, connects to the vertex numbered (v+j) mod (N+1) where j and (N+1) are co-prime < N-1. The last bit making things a bit problematic, as the number of co-primes from 1 to N can be limited if N is not prime. This means solutions don't exist for certain values, at least in the form of a new Hamiltonian path/tour. However, if you ignore the co-prime aspect and simply make j be integers from 1 thru p, then go through each vertex and create the edges (instead of using the path approach), you can make all the vertices have degree k, where k is an even number >= 2. This is achievable in O(N*k), although it may be pushed back as far as O(N^2) if co-prime method is used.
Thus the path for k=4 would look like this, if started at 1, with j=2:
1 [Start at 1]
1-3 [expand 3, add edge(1,3) to graph]
1-3-5 [expand 5, add edge(3,5) to graph]
1-3-5-2 [expand 2, add edge(5,2) to graph]
1-3-5-2-4 [expand 4, add edge(2,4) to graph]
1-3-5-2-4-1 [expand 1, add edge(4,1) to graph] (this step may or may not be done)
Since |V| = 5 and k = 4, the resulting edges form a complete graph, which is expected. It's also works out since 2 and 5 are co-prime.
Obtaining an odd degree is a bit more difficult. First obtain the degree k-1, then edges are added in such a way an odd degree is obtained overall. It seems fairly easy to get very close (with one or two exceptions) to all edges being an odd degree, but it seems impossible or at least very difficult with odd number of vertices, and requires a careful selection of edges with even number of vertices. The section of which, isn't easy to put into an algorithm. However, it can be approximated by simply picking two unused vertices and creating an edge between them such that the vertices are not used twice, and the edges are not used twice.