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Are there any C++ (or C) libs that have NumPy-like arrays with support for slicing, vectorized operations, adding and subtracting contents element-by-element, etc.?

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Armadillo? – Oliver Charlesworth Jun 23 '12 at 12:17
As far as I know numpy uses LAPACK. While that is written in Fortran, there are c++ bindings available. Never used either of those though. – Voo Jun 23 '12 at 12:54
There is a recent C++ interface to NumPy, called ArmaNpy. – mtall May 8 '13 at 7:21
I can't see Boost.MultiArray in the comments yet – Dmitry Ledentsov Apr 16 '14 at 13:42
You could try embedding Python and actually using numpy which would have the advantage of not needing to learn a new library, though it'd be slower than using a C/C++ library. – Kevin Jun 13 at 6:28

8 Answers 8

up vote 15 down vote accepted

Here is several free softwares that would suits your needs.

1) The GNU Scientific Library is a GPL software written in C. It thus have a C-like allocation and way of programming (pointers, etc.). With the GSLwrap, you can have a C++ way of programming, while still using the GSL. GSL has a BLAS implementation, but you can use ATLAS instead of the default CBLAS, if you want even more performances.

2) The boost/uBLAS library is a BSL library, written in C++ and distributed as a boost package. It is a C++-way of implementing the BLAS standard. uBLAS comes with a few linear algebra functions, and there is an experimental binding to ATLAS.

3) eigen is a linear-algebra library, written in C++, distributed under the LGPL3 (or GPL2). It's a C++ way of programming, but more integrated than the two others (more algorithms and data structures are available). Eigen claim to be faster than the BLAS implementations above, while not following the de-facto standard BLAS API. Eigen does not seems to put a lot of effort on parallel implementation.

4) Armadillo is LGPL3 library, in C++. It has binding for LAPACK (the library used by numpy). It uses recursive templates and template meta-programming, which is a good point (I don't know if other libraries are doing it also?).

These alternatives are really good if you just want to get data structures and basic linear algebra. Depending on your taste about style, license or sysadmin challenges (installing big libraries like LAPACK may be difficult), you may choose the one that best suits your needs.

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-1 Taking the everybody else's answers in the thread and grouping them together as your 'answer' is pretty lame. Should have just answered with boost/uBLAS, that's new. – Matt Phillips Jun 23 '12 at 17:20
Believe it or not, my answer is the result of my own search, some month ago. I was believing that gathering the informations that helped me make my choice would be of some interest. I'm not sure wether it is better to have several informations spread across answers. You can still upvote everyone if you feel more concerned by ethic than efficiency. – nojhan Jun 23 '12 at 23:03
Sadly, none of these provide anything as general and convenient as numpy arrays. Numpy arrays are arbitrary-dimensional and support things like a[:4,::-1,:,19] = b[None,-5:,None] or a[a>5]=0 and similar, as well as having a huge set of array and index manipulation functions available. I really hope somebody makes something like that for C++ some day. – amaurea Mar 1 '14 at 11:56

All of these things are possible using the Standard Template Library (STL) which is available as a part of most compiler implementations. Have you looked at STL?

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Yes, if you're prepared to write all of the maths-like operations yourself. – Oliver Charlesworth Jun 23 '12 at 12:18
And after you've debugged the dozens of bugs you'll probably introduce in the process of writing it, you'll find out that numpy is a factor 5 more efficient, which then means rewriting all your code, thereby introducing most certainly hundreds of bugs in the process.. No really not a good idea. – Voo Jun 23 '12 at 12:53

Eigen is a good linear algebra library.

It is quite easy to install since it's a header-only library. It relies on template in order to to generate well optimized code. It vectorizes automatically the matrix operations.

It also fully support coefficient wise operations, such as the "per element multiplication" between two matrices for instance. It is what you need?

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Eigen is a template library for linear algebra (matrices, vectors…). It is header only and free to use (LGPL).

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The GSL is great, it does all of what you're asking and much more. It is licensed under the GPL though.

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Blitz++ supports arrays with an arbitrary number of axes, whereas Armadillo only supports up to three (vectors, matrices, and cubes). Eigen only supports vectors and matrices (not cubes). The downside is that Blitz++ doesn't have linear algebra functions beyond the basic entrywise operations and tensor contractions. Development seems to have slowed down quite some time ago, but perhaps that's just because the library does what it does and not many changes need to be made.

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VIGRA contains a good N-dimensional array implementation:

I use it extensively, and find it very simple and effective. It's also header only, so very easy to integrate into your development environment. It's the closest thing I've come across to using NumPy in terms of it's API.

The main downside is that it isn't so widely used as the others, so you won't find much help online. That, and it's awkwardly named (try searching for it!)

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While GLM is designed to mesh easily with OpenGL and GLSL, it is a fully functional header only math library for C++ with a very intuitive set of interfaces.

It declares vector & matrix types as well as various operations on them.

Multiplying two matrices is a simple as (M1 * M2). Subtracting two vectors (V1- V2).

Accessing values contained in vectors or matrices is equally simple. After declaring a vec3 vector for example, one can access its first element with vector.x. Check it out.

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