(w/r/t the last sentence of the OP: i am *not* aware of such a numpy/scipy method but w/r/t the Question in the OP Title (i.e., improving NumPy dot performance) what's below should be of some help. In other words, my answer is directed to improving performance of most of the *steps comprising* your function for Y).

First, this should give you a noticeable boost over the vanilla NumPy *dot* method:

```
>>> from scipy.linalg import blas as FB
>>> vx = FB.dgemm(alpha=1., a=v1, b=v2, trans_b=True)
```

Note that the two arrays, v1, v2 are *both* in C_FORTRAN order

You can access the byte order of a NumPy array through an array's *flags* attribute like so:

```
>>> c = NP.ones((4, 3))
>>> c.flags
C_CONTIGUOUS : True # refers to C-contiguous order
F_CONTIGUOUS : False # fortran-contiguous
OWNDATA : True
MASKNA : False
OWNMASKNA : False
WRITEABLE : True
ALIGNED : True
UPDATEIFCOPY : False
```

to change the order of one of the arrays so both are aligned, just call the NumPy array constructor, pass in the array and set the appropriate *order* flag to True

```
>>> c = NP.array(c, order="F")
>>> c.flags
C_CONTIGUOUS : False
F_CONTIGUOUS : True
OWNDATA : True
MASKNA : False
OWNMASKNA : False
WRITEABLE : True
ALIGNED : True
UPDATEIFCOPY : False
```

You can further optimize by exploiting array-order alignment to *reduce excess memory consumption caused by ***copying** the original arrays.

But why are the arrays copied before being passed to *dot*?

The dot product relies on BLAS operations. These operations require arrays stored in C-contiguous order--it's this constraint that causes the arrays to be copied.

On the other hand, the *transpose* does *not* effect a copy, though unfortunately returns the result in *Fortran order*:

Therefore, to remove the performance bottleneck, you need to *eliminate the predicate array-copying step*; to do that just requires passing both arrays to *dot* in C-contiguous order*.

So to calculate **dot(A.T., A)** *without* making an extra copy:

```
>>> import scipy.linalg.blas as FB
>>> vx = FB.dgemm(alpha=1.0, a=A.T, b=A.T, trans_b=True)
```

In sum, the expression just above (along with the predicate import statement) can substitute for dot, to supply the same functionality but better performance

you can bind that expression to a function like so:

```
>>> super_dot = lambda v, w: FB.dgemm(alpha=1., a=v.T, b=w.T, trans_b=True)
```