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So, I like vectors a lot. They're nifty and fast. But I know this thing called a valarray exists. Why would I use a valarray instead of a vector? I know valarrays have some syntactic sugar, but other than that, when are they useful?

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Just was pondering this the other day, too. As far as I know, it's really just as specialized math vector. – GManNickG Oct 21 '09 at 18:02
Doesn't valarray do expression templates? – Mooing Duck Mar 27 '13 at 23:23
Physicist Ulrich Mutze provides a use-case for valarray here and here – lifebalance Nov 12 '14 at 15:30
up vote 47 down vote accepted

Valarrays (value arrays) are intended to bring some of the speed of Fortran to C++. You wouldn't make a valarray of pointers so the compiler can make assumptions about the code and optimise it better. (The main reason that Fortran is so fast is that there is no pointer type so there can be no pointer aliasing.)

Valarrays also have classes which allow you to slice them up in a reasonably easy way although that part of the standard could use a bit more work. Resizing them is destructive and they lack iterators.

So, if it's numbers you are working with and convenience isn't all that important use valarrays. Otherwise, vectors are just a lot more convenient.

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Fortran has had pointers since Fortran 90. – user2023370 Oct 18 '11 at 14:29
They are not designed to avoid pointers. C++11 defines begin() and end() in valarray that return iterators to them – Muhammad Annaqeeb Feb 8 '14 at 2:50
@user2023370: that's why so many Fortran users prefer Fortran 77. :) – Michael Sep 26 '14 at 23:21

valarray is kind of an orphan that was born in the wrong place at the wrong time. It's an attempt at optimization, fairly specifically for the machines that were used for heavy-duty math when it was written -- specifically, vector processors like the Crays.

For a vector processor, what you generally wanted to do was apply a single operation to an entire array, then apply the next operation to the entire array, and so on until you'd done everything you needed to do.

Unless you're dealing with fairly small arrays, however, that tends to work poorly with caching. On most modern machines, what you'd generally prefer (to the extent possible) would be to load part of the array, do all the operations on it you're going to, then move on to the next part of the array.

valarray is also supposed to eliminate any possibility of aliasing, which (at least theoretically) lets the compiler improve speed because it's more free to store values in registers. In reality, however, I'm not at all sure that any real implementation takes advantage of this to any significant degree. I suspect it's rather a chicken-and-egg sort of problem -- without compiler support it didn't become popular, and as long as it's not popular, nobody's going to go to the trouble of working on their compiler to support it.

There's also a bewildering (literally) array of ancillary classes to use with valarray. You get slice, slice_array, gslice and gslice_array to play with pieces of a valarray, and make it act like a multi-dimensional array. You also get mask_array to "mask" an operation (e.g. add items in x to y, but only at the positions where z is non-zero). To make more than trivial use of valarray, you have to learn a lot about these ancillary classes, some of which are pretty complex and none of which seems (at least to me) very well documented.

Bottom line: while it has moments of brilliance, and can do some things pretty neatly, there are also some very good reasons that it is (and will almost certainly remain) obscure.

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Is it specifically disallowed to store arbitrary object types inside valarray? – Mehrdad Dec 9 '12 at 2:31
@Mehrdad: Yes -- there's a (rather long) list of restrictions at [Numeric.Requirements]. For just a couple examples, all abstract classes and exceptions are prohibited. It also requires equivalence between (for example) copy construction and a sequence of default construction followed by assignment. – Jerry Coffin Dec 9 '12 at 13:15
@JerryCoffin sheesh that's scary. we promise that we wont use it. – Hani Goc Dec 10 '15 at 14:29
I wouldn't decide that based on fear. I'd decide it based on whether you need to store elements that use features it prohibits. – Jerry Coffin Dec 10 '15 at 20:53

During the standardization of C++98, valarray was designed to allow some sort of fast mathematical computations. However, around that time Todd Veldhuizen invented expression templates and created blitz++, and similar template-meta techniques were invented, which made valarrays pretty much obsolete before the standard was even released. IIRC, the original proposer(s) of valarray abandoned it halfway into the standardization, which (if true) didn't help it either.

ISTR that the main reason it wasn't removed from the standard is that nobody took the time to evaluate the issue thoroughly and write a proposal to remove it.

Please keep in mind, however, that all this is vaguely remembered hearsay. Take this with a grain of salt and hope someone corrects or confirms this.

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expression templates can be equally credited to Vandevoorde too, right ? – Nikos Athanasiou May 12 '14 at 15:32
@Nikos: Not that I know of. I could be wrong, though. What do you have in favor of that reading? – sbi May 12 '14 at 20:11
it's mentioned in the book "C++ Templates - The complete guide", I think it's generally accepted that they both invented them independently. – Nikos Athanasiou May 12 '14 at 20:30

valarray was supposed to let some FORTRAN vector-processing goodness rub off on C++. Somehow the necessary compiler support never really happened.

The Josuttis books contains some interesting (somewhat disparaging) commentary on valarray (here and here).

However, Intel now seem to be revisiting valarray in their recent compiler releases (e.g see slide 9); this is an interesting development given that their 4-way SIMD SSE instruction set is about to be joined by 8-way AVX and 16-way Larrabee instructions and in the interests of portability it'll likely be much better to code with an abstraction like valarray than (say) intrinsics.

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The video link is broken. – musiphil Mar 27 '13 at 0:08
Ta. Replaced it with something else (although I think might be a copy). It's over 3 years on from when I posted this and the 16-way Larrabee is finally coming to market in the form of the Xeon Phi, and the valarray optimisations do seem to be supported on it. – timday Mar 27 '13 at 8:42
Thank you for the updated links! – musiphil Mar 27 '13 at 23:31

I know valarrays have some syntactic sugar

I have to say that I don't think std::valarrays have much in way of syntactic sugar. The syntax is different, but I wouldn't call the difference "sugar." The API is weird. The section on std::valarrays in The C++ Programming Language mentions this unusual API and the fact that since std::valarrays are expected to be highly optimized, any error messages you get while using them will probably be non-intuitive.

Out of curiosity, about a year ago I pitted std::valarray against std::vector. I no longer have the code or the precise results (although it shouldn't be hard to write your own). Using GCC I did get a little performance benefit when using std::valarray for simple math, but not for my implementations to calculate standard deviation (and, of course, standard deviation isn't that complex, as far as math goes). I suspect that operations on each item in a large std::vector play better with caches than operations on std::valarrays. (NOTE, following advice from musiphil, I've managed to get almost identical performance from vector and valarray).

In the end, I decided to use std::vector while paying close attention to things like memory allocation and temporary object creation.

Both std::vector and std::valarray store the data in a contiguous block. However, they access that data using different patterns, and more importantly, the API for std::valarray encourages different access patterns than the API for std::vector.

For the standard deviation example, at a particular step I needed to find the collection's mean and the difference between each element's value and the mean.

For the std::valarray, I did something like:

std::valarray<double> original_values = ... // obviously I put something here
double mean = original_values.sum() / original_values.size();
std::valarray<double> temp(mean, original_values.size());
std::valarray<double> differences_from_mean = original_values - temp;

I may have been more clever with std::slice or std::gslice. It's been over five years now.

For std::vector, I did something along the lines of:

std::vector<double> original_values = ... // obviously, I put something here
double mean = std::accumulate(original_values.begin(), original_values.end(), 0.0) / original_values.size();

std::vector<double> differences_from_mean;
std::transform(original_values.begin(), original_values.end(), std::back_inserter(differences_from_mean), std::bind1st(std::minus<double>(), mean));

Today I would certainly write that differently. If nothing else, I would take advantage of C++11 lambdas.

It's obvious that these two snippets of code do different things. For one, the std::vector example doesn't make an intermediate collection like the std::valarray example does. However, I think it's fair to compare them because the differences are tied to the differences between std::vector and std::valarray.

When I wrote this answer, I suspected that subtracting the value of elements from two std::valarrays (last line in the std::valarray example) would be less cache-friendly than the corresponding line in the std::vector example (which happens to also be the last line).

It turns out, however, that

std::valarray<double> original_values = ... // obviously I put something here
double mean = original_values.sum() / original_values.size();
std::valarray<double> differences_from_mean = original_values - mean;

Does the same thing as the std::vector example, and has almost identical performance. In the end, the question is which API you prefer.

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I cannot think of any reason why a std::vector would play better with caches than a std::valarray; they both allocate a single contiguous block of memory for their elements. – musiphil Mar 27 '13 at 0:11
@musiphil My response got too long for a comment, so I've updated the answer. – Max Lybbert Mar 27 '13 at 23:08
Thank you for your updated answer. – musiphil Mar 27 '13 at 23:10
For your valarray example above, you didn't have to construct a temp valarray object, but you could have just done std::valarray<double> differences_from_mean = original_values - mean;, and then the cache behavior should be similar to that of the vector example. (By the way, if mean is really int, not double, you may need static_cast<double>(mean).) – musiphil Mar 27 '13 at 23:12
Thanks for the suggestion to clean up the valarray. I'll need to see if that improves the performance. As for mean being int: that was a mistake. I originally wrote the example up using ints, and then realized that the mean would then be very far from the real mean because of truncation. But I missed a few needed changes on my first round of edits. – Max Lybbert Mar 27 '13 at 23:20

The C++11 standard says:

The valarray array classes are defined to be free of certain forms of aliasing, thus allowing operations on these classes to be optimized.

See C++11 26.6.1-2.

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Since I assume the Standard does define which forms, can you quote them? Also, are these implemented using coding tricks, or are they compiler-based exceptions to aliasing rules elsewhere in the language? – underscore_d Apr 29 at 12:40

Since C++98, the C++ standard library provides class valarray<> for processing arrays of numeric values. A valarray is a representation of the mathematical concept of a linear sequence of values. It has one dimension, but you can get the illusion of higher dimensionality by special techniques of computed indices and powerful subsetting capabilities. Therefore, a valarray can be used as a base both for vector and matrix operations and for processing mathematical systems of polynomial equations with good performance. The valarray classes enable some tricky optimizations to get good performance for the processing of value arrays. However, it is not clear how important this component of the C++ standard library will be in the future, because other interesting developments perform even better. One of the most interesting examples is the Blitz system. If you are interested in numeric processing, you should look at it. The valarray classes were not designed very well. In fact, nobody tried to determine whether the final specification worked. This happened because nobody felt “responsible” for these classes. The people who introduced valarrays to the C++ standard library left the committee long before the first C++ standard was finished. For example, to use valarrays, you often need some inconvenient and time-consuming type conversions.

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You should mention that you have copied the text in your answer from the supplementary chapter of The C++ Standard Library. A Tutorial and Reference. – 0xbadf00d Feb 25 at 13:00

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