The problem is NP-Hard, thus the backtracking solution [or other exponential solution as suggested by @vhallac] will be your best shot, since there is not known [and if P!=NP, there is no existing] polynomial solution for this kind of problem.

**NP-Hardness proof:**

First, we know that a rectangle consists of 4 edges, that are equal in pairs [e1=e2,e3=e4].

We will show that if there is a polynomial algorithm `A`

to this problem, we can also solve the Partition Problem, by the following algorithm:

```
input: a group of numbers S=a1,a2,...,an
output: true if and only if the numbers can be partitioned
algorithm:
sum <- a1 + a2 + .. + an
lengths <- a1, a2 , ... , an , (sum*5), (sum*5)
activate A with lengths.
if A answered there is any rectangle [solution is not 0], answer True
else answer False
```

**Correctness:**

(1) if there is a partition to S, let it be S1,S2, there is also a rectangle with edges: `(sum*5),(sum*5),S1,S2`

, and the algorithm will yield True.

(2) if the algorithm yields True, there is a rectangle available in lengths, since a1 + a2 + ... + an < sum*5, there are 2 edges with length sum*5, since the 2 other edges must be made using all remaining lengths [as the question specified], each other edge is actually of length `(a1 + a2 + ... + an)/2`

, and thus there is a legal partition to the problem.

**Conclusion:** There is a reduction `PARTITION<=(p) this problem`

, and thus, this problem is NP-Hard

**EDIT:**

the **backtracking solution** is pretty simple, get all possible rectangles, and check each of them to see which is the best.

backtracking solution: pseudo-code:

```
getAllRectangles(S,e1,e2,e3,e4,sol):
if S == {}:
if legalRectangle(e1,e2,e3,e4):
sol.add((e1,e2,e3,e4))
else: //S is not empty
elem <- S[0]
getAllRectangles(S-elem,e1+elem,e2,e3,e4,sol)
getAllRectangles(S-elem,e1,e2+elem,e3,e4,sol)
getAllRectangles(S-elem,e1,e2,e3+elem,e4,sol)
getAllRectangles(S-elem,e1,e2,e3,e4+elem,sol)
getRectangle(S):
RECS <- new Set
getAllRectangles(S,{},{},{},{},RECS)
getBest(RECS)
```

**EDIT2:**

As discussed in the comments, this answer shows not only this is hard to find the *BEST* rectangle, it is also hard to find *ANY* rectangle, making this problem hard for heuristic solutions as well.