@JoeKington's numpy solution is very clever, but it relies on `A[:,1]`

being in sorted order. Here is a fix for the general case:

```
import numpy as np
np.random.seed(1)
N=5
A = np.arange(2*N).reshape((-1,2))+100
np.random.shuffle(A)
print(A)
```

If `A`

looks like this:

```
[[104 105]
[102 103]
[108 109]
[100 101]
[106 107]]
```

and `V`

```
V = A[:,1].copy()
np.random.shuffle(V)
print(V)
```

looks like this:

```
[105 109 107 101 103]
```

then we use Joe's solution:

```
vals, order = np.unique(np.hstack((A[:,1],V)), return_inverse=True)
```

but save both the order of `A[:,1]`

and `V`

:

```
a_order = order[:V.size]
v_order = order[-V.size:]
```

and sort `A`

(by forming `A[np.argsort(a_order)]`

) before reordering with `v_order`

:

```
print A[np.argsort(a_order)][v_order]
[[104 105]
[108 109]
[106 107]
[100 101]
[102 103]]
```

(`A[np.argsort(a_order)]`

is `A`

sorted according to its second column.)

Note that np.unique always returns the array in sorted order. The documentation guarantees with `return_inverse=True`

that the returned indices are the indices of the unique array that reconstructs the original array. That is, if you call `np.unique`

like this:

```
uniq_arr, indices = np.unique(arr, return_inverse=True)
```

you are guaranteed that

```
unique_arr[indices] = arr
```

Because you can rely on this relationship, Joe's method does not depend on a mere implementation detail -- `unique`

will always behave this way. (Famous last words -- considering what happened to the order of output arguments returned by `np.unique1d`

... but never mind that :))