This is what I would do:

# Code

```
Eigen::Matrix3Xf A(3, 2); // 3x2
A << 1, 2, 2, 2, 3, 5;
Eigen::Vector3f V = Eigen::Vector3f(1, 2, 3);
const Eigen::Matrix3Xf C = A.array().colwise() * V.array();
std::cout << C << std::endl;
```

Example output:

```
1 2
4 4
9 15
```

# Explanation

You were close, the trick is to use `.array()`

to do broadcasting multiplications.

`colwiseReturnType`

doesn't have a `.array()`

method, so we have to do our colwise shenanigans on the array view of A.

If you want to compute the element-wise product of two vectors (The coolest of cool cats call this the Hadamard Product), you can do

```
Eigen::Vector3f a = ...;
Eigen::Vector3f b = ...;
Eigen::Vector3f elementwise_product = a.array() * b.array();
```

Which is what the above code is doing, in a columnwise fashion.

**Edit:**

To address the row case, you can use `.rowwise()`

, and you'll need an extra `transpose()`

to make things fit

```
Eigen::Matrix<float, 3, 2> A; // 3x2
A << 1, 2, 2, 2, 3, 5;
Eigen::Vector2f V = Eigen::Vector2f(2, 3);
// Expected result
Eigen::Matrix<float, 3, 2> C = A.array().rowwise() * V.transpose().array();
std::cout << C << std::endl;
```

Example output:

```
2 6
4 6
6 15
```