Once you have your tree, then it is an arbitrary choice for how the 0 and 1 is assigned to the two branches at each fork in the road. So without a way to make that assignment canonical, there is no "right answer" to how to assign the bits to each symbol, e.g. that `r`

must be `011`

. `r`

could be any three-bit value. (Though it must be three bits in length for this set of frequencies.)

All that matters is that the decoder gets the same assignment of 0's and 1's as the encoder. Either you can send the codes directly, or you can send the lengths and assign the 0's and 1's in a canonical manner. As an example, the compression algorithm used in zip, gzip, png, etc. sends only the number of bits for each symbol. Then starting with the smallest length, all symbols of that length are assigned codes starting at 0. The symbols are assigned the codes in order with the symbols sorted by their representation integer. E.g. ASCII-sorted order for characters. For the next length, bits are added on the right and the code counting continues. This assures a proper prefix code, decoding from left to right.

So in this case, the code lengths are:

```
2: _
3: a, e, r
4: d, f, n
5: b, h, t
6: i, k, o, s, u, v
```

So we get (with symbols in alphabetic order within each length):

```
_: 00
a: 010
e: 011
r: 100
d: 1010
f: 1011
n: 1100
b: 11010
h: 11011
t: 11100
i: 111010
k: 111011
o: 111100
s: 111101
u: 111110
v: 111111
```

The bits assignments here are different than what's in your book for two of the three symbols. As examples of other perfectly good canonical prefix code choices, you could invert all of the bits, or you could invert any subsets of the columns of bits. E.g. you could invert the whole first column. You could change the order of symbols in each length. You can reverse the bit order. In fact, zip, etc. stores the bits shown above in reverse order, so decoding is done from the least significant bit first, i.e. right to left.