# Numpy.GetBuffer and Numpy.FromBuffer

I am trying to wrap my head around the numpy implementation of PEP3118. How exactly does buffer access work in numpy.

``````>>> p = numpy.getbuffer(numpy.arange(10))
>>> p
<read-write buffer for 0x1003e5b10, size -1, offset 0 at 0x1016ab4b0>
>>> numpy.frombuffer(p)
array([  0.00000000e+000,   4.94065646e-324,   9.88131292e-324,
1.48219694e-323,   1.97626258e-323,   2.47032823e-323,
2.96439388e-323,   3.45845952e-323,   3.95252517e-323,
4.44659081e-323])
``````

So I am getting unexpected returns. I would expect to see an array with 10 elements from 0-9. I can get into the array and read/write though.

``````>>> j = numpy.frombuffer(p)
>>> j
array([  0.00000000e+000,   4.94065646e-324,   9.88131292e-324,
1.48219694e-323,   1.97626258e-323,   2.47032823e-323,
2.96439388e-323,   3.45845952e-323,   3.95252517e-323,
4.44659081e-323])
>>> j += 1
>>> j
array([ 1.,  1.,  1.,  1.,  1.,  1.,  1.,  1.,  1.,  1.])
``````

So it looks like the buffer is initializing to all zeros, which I can then write to. The functionality that I am expecting is to be able to build the array (with arange or asarray) directly to the buffer with getbuffer. Is that not possible?

-

You have a simple `dtype` problem. The buffer you create with

``````np.getbuffer(np.arange(10))
``````

has a `dtype=int`, because `np.arange` uses `dtype=int` by default.

``````np.frombuffer(p)
``````

you're in fact using the `dtype=float` default of `np.frombuffer`. Instead, use

``````np.frombuffer(p, dtype=int)
``````

et voilà, you get

``````array([0, 1, 2, 3, 4, 5, 6, 7, 8, 9])
``````
-

Let me add some remarks to the excellent existing answer by Pierre.

You need `getbuffer` only if you have to slice an `ndarray`: you can retrieve the python buffer object associated with the whole array via the `data` attribute

``````>>> import numpy as np
>>> a = np.arange(10)
>>> a.data == np.getbuffer(a)
True
``````

On the contrary, you do not need to pass an actual buffer object to the `frombuffer` function, every object that exposes the `buffer` interface is good.

``````>>> np.frombuffer(a, a.dtype)
array([0, 1, 2, 3, 4, 5, 6, 7, 8, 9])
>>> np.frombuffer(a)
array([  0.00000000e+000,   4.94065646e-324,   9.88131292e-324,
1.48219694e-323,   1.97626258e-323,   2.47032823e-323,
2.96439388e-323,   3.45845952e-323,   3.95252517e-323,
4.44659081e-323])
>>> import array
>>> c = array.array('i', range(10))
>>> np.frombuffer(c, np.int32)
array([0, 1, 2, 3, 4, 5, 6, 7, 8, 9], dtype=int32)
>>> np.frombuffer(c)
array([  2.12199579e-314,   6.36598737e-314,   1.06099790e-313,
1.48539705e-313,   1.90979621e-313])
``````

When decoding a buffer object, you have to know the correct `dtype` as the examples above demonstrate. To be more precise, buffer objects do not have a `dtype`: they are just a stream of binary data. Instead `ndarray` objects have a `dtype` that dictates how the underlying binary data is interpreted.

To answer your question: every numpy `ndarray` exposes the buffer interface. You can access the buffer or a slice of it via the `data` descriptor or the `getbuffer` function. You can create `ndarray`'s from object exposing the buffer interface by means of the `frombuffer` function. Since buffer (as opposed to `ndarrays`) do not have `dtype` information, you should always explicitly specify how the buffer has to be interepreted via the `dtype` argument to `frombuffer`.

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What a wonderful addendum to Pierre's answer. The additional detail is quite appreciated. –  Jzl5325 Sep 18 '12 at 18:50