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NumPy seems to lack built-in support for 3-byte and 6-byte types, aka uint24 and uint48. I have a large data set using these types and want to feed it to numpy. What I currently do (for uint24):

import numpy as np
dt = np.dtype([('head', '<u2'), ('data', '<u2', (3,))])
# I would like to be able to write
#  dt = np.dtype([('head', '<u2'), ('data', '<u3', (2,))])
#  dt = np.dtype([('head', '<u2'), ('data', '<u6')])
a = np.memmap("filename", mode='r', dtype=dt)
# convert 3 x 2byte data to 2 x 3byte
# w1 is LSB, w3 is MSB
w1, w2, w3 = a['data'].swapaxes(0,1)
a2 = np.ndarray((2,a.size), dtype='u4')
# 3 LSB
a2[0] = w2 % 256
a2[0] <<= 16
a2[0] += w1
# 3 MSB
a2[1] = w3
a2[1] <<=8
a2[1] += w2 >> 8
# now a2 contains "uint24" matrix

While it works for 100MB input, it looks inefficient (think of 100s GBs of data). Is there a more efficient way? For example, creating a special kind of read-only view which masks part of the data would be useful (kind of "uint64 with two MSBs always zero" type). I only need read-only access to the data.

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2 Answers 2

I don't believe there's a way to do what you're asking (it would require unaligned access, which is highly inefficient on some architectures). My solution from Reading and storing arbitrary byte length integers from a file might be more efficient at transferring the data to an in-process array:

a = np.memmap("filename", mode='r', dtype=np.dtype('>u1'))
e = np.zeros(a.size / 6, np.dtype('>u8'))
for i in range(3):
    e.view(dtype='>u2')[i + 1::4] = a.view(dtype='>u2')[i::3]

You can get unaligned access using the strides constructor parameter:

e = np.ndarray((a.size - 2) // 6, np.dtype('<u8'), buf, strides=(6,))

However with this each element will overlap with the next, so to actually use it you'd have to mask out the high bytes on access.

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+1 for alignment issues. Probs not worth it. –  Joe Aug 15 '12 at 10:15
While your method looks nicer, it still incurs reading the whole input several times and storing a modified copy in the memory. Both your and my original solution won't work for 100GB input. –  Ilia K. Aug 16 '12 at 7:49

Using the code below you can read integers of any size coded as big or little endian:

def readBigEndian(filename, bytesize):
    with (open(filename,"rb")) as f:
         str = f.read(bytesize)
         while len(str)==bytesize:
             int = 0;
             for byte in map(ord,str):
                 print byte
                 int = (int << 8) | byte
             str = f.read(bytesize)

def readLittleEndian(filename, bytesize):
    with (open(filename,"rb")) as f:
         str = f.read(bytesize)
         while len(str)==bytesize:
             int = 0;
             shift = 0
             for byte in map(ord,str):
                 print byte
                 int |= byte << shift
                 shift += 8
             str = f.read(bytesize)

for i in readLittleEndian("readint.py",3):
    print i
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