Maybe this algorithm suits your needs, I will explain it with 4 bits digits and you can later expand it to be used with 16 bits.

```
L = [0b1000,0b1100,0b1111,0b1001, 0b0000]
bits = 4 # total bits
next_bit = bits*len(L)-1 # next position to be calculated
res = 0
for i in range(bits-1,-1,-1): # iterate 3,2,1,0 (bits backwards)
for x in L: # iterate through every integer in L
res = res | (((x&1<<i)>>i)<<next_bit) # say what? o.O
next_bit-=1 # set next_bit to the next position to be calculated
>>> bin(res)
'0b11110011000010000110'
```

Basically, what it does is iterate through every bit position to be analize in each number, then iterate through each number to analyze that position, and once you know what position to analyze on what number, you perform this weird calculation: `(((x&1<<i)>>i)<<total_bits-1)`

.

The loop will accumulate on `res`

the result of that calculation which I explain:

`x&1<<i`

will test if the bit at position `i`

is on
`((x&1<<i)>>i)`

shifting backwards `i`

bits will make sure the result is `1`

or `0`

`(((x&1<<i)>>i)<<next_bit)`

shifting forward `next_bit`

will set the bit to `1`

or `0`

at position `next_bit`

.

You need this `next_bit`

integer to keep account of what's the next bit on the result you need to set. Since you have for example, 5 four bits digits, you know the result will have 5*4 bits.

I don't like much those two for loops. In C this is probably good but in Python they are not very efficient. I still thinking a way to remove them. I dare you to benchmark them with this simple oneliner:

```
>>>L = [0b1000,0b1100,0b1111,0b1001, 0b0000]
>>>int(''.join(['1' if x&1<<i else '0' for i in range(3,-1,-1) for x in L]),2)
995462
```

You'll be surprised about the performance.

Hope this helps!