#include <iostream>

#include <Eigen/Core>

namespace Eigen {

// float op double -> double
template <typename BinaryOp>
struct ScalarBinaryOpTraits<float, double, BinaryOp> {
  enum { Defined = 1 };
  typedef double ReturnType;

// double op float -> double
template <typename BinaryOp>
struct ScalarBinaryOpTraits<double, float, BinaryOp> {
  enum { Defined = 1 };
  typedef double ReturnType;


int main() {
    Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic> m1(2, 2);
    m1 << 1, 2, 3, 4;

    Eigen::Matrix<double, Eigen::Dynamic, Eigen::Dynamic> m2(2, 2);
    m2 << 1, 2, 3, 4;

    std::cerr << m1 * m2 <<std::endl;  // <- boom!!

I'd like to know why the above code does not compile. Here is the full error messages. Please note that if I define m1 and m2 to have fixed sizes, it works fine.

I'm using Eigen3.3.1. It's tested on a Mac running OSX-10.12 with Apple's clang-800.0.42.1.


This is because the general matrix-matrix product is highly optimized with aggressive manual vectorization, pipelining, multi-level caching, etc. This part does not support mixing float and double. You can bypass this heavily optimized implementation with m1.lazyProduct(m2) that corresponds to the implementations used fro small fixed-size matrices, but there is only disadvantages of doing so: the ALUs does not support mixing float and double, so float values have to be promoted to double anyway and you will loose vectorization. Better cast the float to double explicitly:

m1.cast<double>() * m2
  • 1
    Actually, my real problem is to define custom scalar types T1 and T2. I've found that using ScalarBinaryOpTraits works mostly but not for the multiplication of two dynamic-sized Eigen matrices of T1 and T2. I used double and float to make the example simpler. – Soonho Kong Jan 5 '17 at 22:09
  • I'm wondering if one of the followings looks a good solution to you: 1. Provide operator overloading operator* for Eigen matrices of T1 and T2 explicitly (probably using cast operation in it) 2. Provide a specialization of Eigen::internal::general_matrix_matrix_product for T1 and T2. If this is the way to go, is there a good example of doing this? – Soonho Kong Jan 5 '17 at 22:12
  • 3
    We should really bypass this heavy code for custom scalar types. This will be the case for 3.4 and probably backported to some 3.3.x release. Meanwhile, you can indeed specialize general_matrix_matrix_product as there, or also follow this piece of code. – ggael Jan 6 '17 at 9:27
  • @ggael the developers of Stan (and I) are discussing this matrix multiplication issue on their forum in the context of their implemention of std::complex math on their automatic differentiation types. Would appreciate any thoughts you might have (either there or here). – Chris Chiasson Dec 17 '19 at 20:44
  • @ggael not sure if I properly tagged you in the last comment, so I'm just making sure I tab completed it correctly. Sorry if it double notifies you. – Chris Chiasson Dec 17 '19 at 20:45

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.