# How to integrate a library that uses expression templates?

I would like to use the Eigen matrix library as the linear algebra engine in my program. Eigen uses expression templates to implement lazy evaluation and to simplify loops and calculations.

For example:

``````#include<Eigen/Core>

int main()
{
int size = 40;
// VectorXf is a vector of floats, with dynamic size.
Eigen::VectorXf u(size), v(size), w(size), z(size);
u = 2*v + w + 0.2*z;
}
``````

Since Eigen uses expression templates, code like

``````u = 2*v + w + 0.2*z;
``````

In the above mentioned sample reduces to a single loop of length 10 (not 40, the floats are put into regiser by chunks of 4) without creating a temporary. How cool is that?

But if I integrate the library like this:

``````class UsingEigen
{
public:
UsingEigen(const Eigen::VectorXf& data):
data_(data)
{}

UsingEigen operator + (const UsingEigen& adee)const
{
}

...
private:
Eigen::VectorXf data_;
}
``````

Then the expressions like:

``````UsingEigen a, b, c, d;
a = b + c + d;
``````

cannot take advantage of the way Eigen is implemented. And this is not the last of it. There are many other examples, where expression templates are used in Eigen.

The easy solution would be not to define the operators by myself, make `data_` public and just write expressions like:

``````UsingEigen a, b, c, d;
a.data_ = b.data_ + c.data_ + d.data_;
``````

This breaks encapsulation, but it preserves the efficiency of Eigen.

Other way could be to make my own operators, but let them return expression templates. But since I am a beginner in C++, I do not know if this is the right way to go.

I am sorry if the question is too general in nature. I am a beginner and have noone to ask. Up until now I was using `std::vector<float>` everywhere, but now I need to use matrices also. To switch from `std::vector<float>` to Eigen in my entire project is a big step and I am afraid of making a wrong call right in the start. Any advice is welcomed!

-
Interesting problem. The first thing, though, is: why do you want to encapsulate the Eigen library vectors in this way? What behaviour do your classes add? –  Konrad Rudolph Jun 11 '12 at 8:02
My classes do not add any functionality to the Eigen library classes themselves, but use them. For example one of my core classes stores two vectors. One as an input to a certain mathematical computation and the other as output. These objects need to interoperate in a similar fashion as I mentioned above. When you add two such objects, the inputs should be added. –  Martin Drozdik Jun 11 '12 at 8:06
I don't think this is possible without reproducting substantial part of expression template framework yourself. For instance, `(a+b)*c` will be something like `ExprCwiseAdd*UsingEigen` (the name is made up, don't recall it any longer), and there will have to be `ExprCwiseAdd*UsingEigen` defined somewhere, but also `ExprCwiseAdd*ExprCWiseAdd` and so on. In short, the addition will not have `UsingEigen` as return type. (You might have a look at boost::proto which is a framework for expression templates). Good luck. –  eudoxos Jun 11 '12 at 8:11
@Martin In that case I would try to model all parts of the workflow that do perform calculations purely in terms of `Eigen` classes, and only use your wrappers as the respective input and output. Intermediate steps then use the actual `Eigen` data. And you don’t need to expose variables, you can use functions that return (for instance) references to the classes. True, this still exposes data. I feel your pain. –  Konrad Rudolph Jun 11 '12 at 8:21
If you ever decide to use expression templates in your own code, do yourself a favor and take a look at Boost.Proto. –  Luc Touraille Jun 11 '12 at 8:49
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Why would exposing `data_` break encapsulation? Encapsulation means hiding the implementation details and only exposing the interface. If your wrapper class `UsingEigen` does not add any behavior or state to the native `Eigen` library, the interface does not change. In this case, you should drop this wrapper altogether and write your program using the `Eigen` data structures.

Exposing a matrix or a vector is not breaking encapsulation: only exposing the implementation of the matrix or vector would do that. The `Eigen` library exposes the arithmetic operators but not their implementation.

With expression template libraries, the most common way for users to extend the library functionality is by adding behavior, not adding by adding state. And for adding behavior you do not need to write wrapper classes: you can also add non-member functions that are implemented in terms of the `Eigen` class member functions. See this column "How Non-Member Functions Improve Encapsulation" by Scott Meyers.

As for your concern that the transformation of your current program to a version that explicitly uses the `Eigen` functionality: you can perform the change step-by-step, changing small parts of your program each time, making sure your unit tests (you do have unit tests, don't you?) do not break as you go along.

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Exposing data members breaks encapsulation. But adding the expression templates overloads for the Eigen classes would break it in the same way. –  Konrad Rudolph Jun 11 '12 at 8:28
@KonradRudolph It doesn't break encapsulation if `UsingEigen` has the exact same interface and with the exact same implementation (i.e. a literal wrapper class with pure forwarding and no logging/checking etc. added). You would be right if `UsingEigen` would define an extra layer of abstraction, but it doesn't appear to be the case (and it should not be called `UsingEigen` then at all because that exposes the implementation!) –  TemplateRex Jun 11 '12 at 8:41

In my opinion, this looks more of a object oriented design problem rather than a library usage problem. Whatever you read from the books are the right recommendations. i.e, do not expose member variables and shield the upper layers from the nuances of the 3rd party layer usage.

What you could look forward is right abstractions of mathematical functions that can be implemented using this library internally. i.e, you could expose a library of your own with high level functions than elementary vector and matrix operations. In this way you can utilize the peculiarities of the interactions among the library objects and at the same time you don't have to expose your member variables to upper layers.

For e.g you could abstract away my higher level APIs like computing the distance from a point to a plane, distance between two planes, computing the new coordinates of a point w.r.t another coordinate system using the transformation matrices etc. To implement these methods internally you can utilize the library objects. You can restrict to not to have any of the library classes used in the API signatures to avoid dependency for the upper layers on this library.

Upper layers of your program should be higher in the level of abstraction and need not bother about the elementary implementation details such as how the calculation of the distance from a point to the plane is implemented etc. Also, they even need not know if this lower layer is implemented using this library or something else. They would just use the interfaces of your library.

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I don't understand all your question I will try to answer you most of them. In this sentence:

`````` UsingEigen operator + (const UsingEigen& adee)const
{
}
``````

You have an overload operator ( sorry I don't know if this is the correct way to write in English), for this reason you can write:

``````a = b + c + d;
``````

``````a.data_ = b.data_ + c.data_ + d.data_;
``````

You won't have any problem, cost of your program will be the same. In addition you will have encapsulation and efficiency.

On the other way if you want define your own operator you can do it like the template do it. You can find information on the web searching "overload operator" but is similar to this:

``````UsingEigen operator + (const UsingEigen& adee)const
{
}
``````

Instead of "+" you can put the operator and do the operations you need.

If you want to create a matrix it is simple. You only need to create a array of array or vector of vector.

I think is something like this:

``````std::vector<vector<float>>
``````

I am not sure but it is easy, on the other hand you can use a simple matrix on this way:

float YourMatrix [size][size];