On some platforms (e.g. embedded), modulo operation is expensive, so `% 13`

is better avoided. But `AND`

operation of low-order bits is cheap, and equivalent to modulo of a power-of-2.

I tried writing a simple program (in Python) to search for a perfect hash of your 11 data points, using simple forms such as `((x << a) ^ (x << b)) & 0xF`

(where `& 0xF`

is equivalent to `% 16`

, giving a result in the range 0..15, for example). I was able to find the following collision-free hash which gives an index in the range 0..15 (expressed as a C macro):

```
#define HASH(x) ((((x) << 2) ^ ((x) >> 2)) & 0xF)
```

Here is the Python program I used:

```
data = [ 10, 100, 32, 45, 58, 126, 3, 29, 200, 400, 0 ]
def shift_right(value, shift_value):
"""Shift right that allows for negative values, which shift left
(Python shift operator doesn't allow negative shift values)"""
if shift_value == None:
return 0
if shift_value < 0:
return value << (-shift_value)
else:
return value >> shift_value
def find_hash():
def hashf(val, i, j = None, k = None):
return (shift_right(val, i) ^ shift_right(val, j) ^ shift_right(val, k)) & 0xF
for i in xrange(-7, 8):
for j in xrange(i, 8):
#for k in xrange(j, 8):
#j = None
k = None
outputs = set()
for val in data:
hash_val = hashf(val, i, j, k)
if hash_val >= 13:
pass
#break
if hash_val in outputs:
break
else:
outputs.add(hash_val)
else:
print i, j, k, outputs
if __name__ == '__main__':
find_hash()
```