use a kd-tree

Unfortunately, in high dimensions this data structure suffers severely from the curse of dimensionality, which causes its search time to be comparable to the brute force search.

reduce the number of dimensions

Dimensionality reduction is a good approach, which offers a fair trade-off between accuracy and speed. You lose some information when you reduce your dimensions, but gain some speed.

By accuracy I mean finding the exact Nearest Neighbor (NN).

Principal Component Analysis(PCA) is a good idea when you want to reduce the dimensional space your data live on.

Is there some clever algorithm or data structure to solve this exactly in reasonable time?

Approximate nearest neighbor search (ANNS), where you are satisfied with finding a point that might not be the exact Nearest Neighbor, but rather a good approximation of it (that is the 4th for example NN to your query, while you are looking for the 1st NN).

That approach cost you accuracy, but increases performance significantly. Moreover, the probability of finding a good NN (close enough to the query) is relatively high.

You could read more about ANNS in the introduction our kd-GeRaF paper.

A good idea is to combine ANNS with dimensionality reduction.

Locality Sensitive Hashing (LSH) is a modern approach to solve the Nearest Neighbor problem in high dimensions. The key idea is that points that lie close to each other are hashed to the same bucket. So when a query arrives, it will be hashed to a bucket, where that bucket (and usually its neighboring ones) contain good NN candidates).

FALCONN is a good C++ implementation, which focuses in cosine similarity. Another good implementation is our DOLPHINN, which is a more general library.

Foundations of Multidimensional and Metric Data Structures. It has some chapters specifically on structures suited to high-dimensional data.1more comment