# Numpy: Multiplying large arrays with dtype=int8 is SLOW

Consider the following piece of code, which generates some (potentially) huge, multi-dimensional array and performs numpy.tensordot with it (whether we multiply the same or two different arrays here, does not really matter).

import time
import numpy

L, N = 6, 4

shape = (2*L)*[N,]
A = numpy.arange(numpy.prod(shape)).reshape(shape)
A = A % 256 - 128   # [-127,+127]
axes=(range(1,2*L,2), range(0,2*L,2))

def run(dtype, repeat=1):
A_ = A.astype(dtype)
t = time.time()
for i in range(repeat):
numpy.tensordot(A_, A_, axes)
t = time.time() - t
print(dtype, '   \t%8.2f sec\t%8.2f MB' %(t, A_.nbytes/1e6))

Now we can compare the performance for different data types, e.g.:

run(numpy.float64)
run(numpy.int64)

Since the array only consists of small integer numbers, I would like to save some memory by using dtype=int8. However, this slows down the matrix multiplication A LOT.

## Here are some test cases

The first one, is the important one for my use case. The others are just for reference. Using Numpy 1.13.1 and Python 3.4.2

### Large array

L, N = 6, 4; A.size = 4**12 = 16777216
<class 'numpy.float64'>        59.58 sec      134.22 MB
<class 'numpy.float32'>        44.19 sec       67.11 MB
<class 'numpy.int16'>         711.16 sec       33.55 MB
<class 'numpy.int8'>          647.40 sec       16.78 MB

Same array with different data types. Memory decreases as expected. But why the large differences in the CPU time? If anything I would expect int to be faster than float.

### Large array with different shape

L, N = 1, 4**6; A.size = (4**6)**2 = 16777216
<class 'numpy.float64'>        57.95 sec      134.22 MB
<class 'numpy.float32'>        42.84 sec       67.11 MB

The shape doesn't seem to have a large effect.

### Not so large array

L, N = 5, 4
<class 'numpy.float128'>       10.91 sec       16.78 MB
<class 'numpy.float64'>         0.98 sec        8.39 MB
<class 'numpy.float32'>         0.90 sec        4.19 MB
<class 'numpy.float16'>         9.80 sec        2.10 MB
<class 'numpy.int64'>           8.84 sec        8.39 MB
<class 'numpy.int32'>           5.55 sec        4.19 MB
<class 'numpy.int16'>           2.23 sec        2.10 MB
<class 'numpy.int8'>            1.82 sec        1.05 MB

Smaller values, but same weird trend.

### small array, lots of repetitions

L, N = 2, 4; A.size = 4**4 = 256; repeat=1000000

<class 'numpy.float128'>       17.92 sec        4.10 KB
<class 'numpy.float64'>        14.20 sec        2.05 KB
<class 'numpy.float32'>        12.21 sec        1.02 KB
<class 'numpy.float16'>        41.72 sec        0.51 KB
<class 'numpy.int64'>          14.21 sec        2.05 KB
<class 'numpy.int32'>          14.26 sec        1.02 KB
<class 'numpy.int16'>          13.88 sec        0.51 KB
<class 'numpy.int8'>           13.03 sec        0.26 KB

Other than float16 being much slower, everything is fine here.

## Question

Why is int8 for very large arrays so much slower? Is there any way around this? Saving memory becomes increasingly important for larger arrays!

• Related - stackoverflow.com/questions/45373679 Commented Aug 3, 2017 at 8:55
• "BLAS, optimized over decades for different archs, cpus, instructions and cache-sizes has no integer-type!" Well, that explains why (Although it opens the question why there is no interger-type in BLAS). But is there a better way in numpy? Commented Aug 3, 2017 at 9:08
• I'd vote for using floats, even it it means to use excessive amounts of memory. A factor of 2 or 4 doesn't sound so harsh to be impractical.
– Alfe
Commented Aug 3, 2017 at 9:45
• Numpy is built on LAPACK (generally), which is built on BLAS. Expecting numpy to improve the efficiency of BLAS is sort of like expecting an auto mechanic to improve your engine by inventing a lighter type of steel. Commented Aug 3, 2017 at 10:02
• Everybody builds engines out of steel - in this case, that steel is BLAS. Someone could make a better "steel" someday, but it probably won't be someone who makes "engines" for a living. Commented Aug 3, 2017 at 10:32