How might I approach this problem? I am thinking I try to put tiles, then if I cant put any more, I need to backtrack ... but how do I know how much to backtrack? Also after putting a tile, how might I (the code) decide which next tile to fill and with which type of tile?

use this recurrence : Here, F(N) represents no of ways of tiling a 3XN grid with 3X1 or 1X3 tiles.
Take the sum, and you get the recurrence i mentioned above. 


The first thing to do in a computer science problem is to understand and reduce it. In this case, try to understand how the height of the rectangle relates to the problem. When placing a tile sideways, is there any option but placing two tiles horizontally under it? So, what tile options do you effectively have? Is it a 2D or a 1D problem? You should then be able to solve the problem via combinatorics. 

Consider building the 3 by N block from left to right. At any stage, there are essentially two cases to consider: you can place a vertical tile or you can place three horizontal tiles. You can capture these in a recursive function that tries both alternatives and calls itself to build the rest of the block. That is, the number of ways to build a 3 by N block is the number of ways to build a 3 by (N1) block plus the number of ways to build a 3 by (N3) block. As it's homework, I'll leave implementation to you. I'd expect that it could be solved exactly by hand, as well. 


I'd think this could be solved purely using integer division and modulus, and a bit of multiplication. no loops needed. 


c++ implementation using dynamic programming:
f(n)  solution for length n. f(n1)  when you put vertical. f(n3)  when you put 3 horizontal blocks 


Think about how the tiling must look  there are either vertical tiles or else 3x3 blocks of horizontal tiles. Imagine that these 3x3 blocks are glued together  no loss in doing this.If there are k 3x3 blocks then there are n  3k vertical blocks for k = 0, 1, . . .n/3 where j is the greatest integer less than or equal to j. There are C(n2k, k) arrangements possible where C(x,y) is "n choose y" i.e. (x!)/((y!)((xy)!)). So the answer is C(n,0) + C(n2,1) + C(n4,2) + . . .C(n  2, n/3). The same method works for the number of tilings of an nxk box with nx1 tiles. In fact, using a small provocative number like 3 could be considered a distraction for the problem. To solve this for boxes with a width bigger than n would require another recursion. . 

