# Fastest way to find *the index* of the second (third…) highest/lowest value in vector or column

Fastest way to find the index of the second (third...) highest/lowest value in vector or column ?

i.e. what

``````sort(x,partial=n-1)[n-1]
``````

is to

``````max()
``````

but for

``````which.max()
``````

Best,

Fastest way to find second (third...) highest/lowest value in vector or column

-

EDIT 2 :

As Joshua pointed out, none of the given solutions actually performs correct when you have a tie on the maxima, so :

``````X <- c(11:19,19)

n <- length(unique(X))
which(X == sort(unique(X),partial=n-1)[n-1])
``````

fastest way of doing it correctly then. I deleted the order way, as that one doesn't work and is a lot slower, so not a good answer according to OP.

To point to the issue we ran into :

``````> X <- c(11:19,19)
> n <- length(X)
> which(X == sort(X,partial=n-1)[n-1])
[1]  9 10 #which is the indices of the double maximum 19

> n <- length(unique(X))
> which(X == sort(unique(X),partial=n-1)[n-1])
[1] 8 # which is the correct index of 18
``````

The timings of the valid solutions :

``````> x <- runif(1000000)

> ind <- 2

> n <- length(unique(x))

> system.time(which(x == sort(unique(x),partial=n-ind+1)[n-ind+1]))
user  system elapsed
0.11    0.00    0.11

> system.time(sapply(sort(unique(x), index.return=TRUE), `[`, n-ind+1))
user  system elapsed
0.69    0.00    0.69
``````
-
Speaking of ties, you may get an inaccurate answer if there are ties before the index you want. If there are 2 elements with the max value and you want the second highest value, none of the currently proposed solutions will give you that. They will all return the second highest sorted value, which is tied with the max value. You would need to `unique` your vector first. –  Joshua Ulrich Apr 6 '11 at 16:06
Are you sure this works? I'm might be loosing the plot, but consider my example data. Your solution doesn't give the right answer. Remember `order()` gives the permutation of the vector to get the vector in increasing/decreasing order. It works here because `x` is already sorted but if it isn't. `order(x, decreasing = TRUE)[i]` should be sufficient for the ith largest. Or am I so wrong it is embarrassing? –  Gavin Simpson Apr 6 '11 at 16:07
@Gavin : darn right... –  Joris Meys Apr 6 '11 at 16:16
and @Joshua : also very right. Goes for all solutions actually, and I showed it in my solution as well... –  Joris Meys Apr 6 '11 at 16:18

One possible route is to use the `index.return` argument to `sort`. I'm not sure if this is fastest though.

``````set.seed(21)
x <- rnorm(10)
ind <- 2
sapply(sort(x, index.return=TRUE), `[`, length(x)-ind+1)
#        x       ix
# 1.746222 3.000000
``````
-
why not just use order if you only need the indices? –  Joris Meys Apr 6 '11 at 15:53
@Joris: You're certainly correct if you only need the index. I guess I assumed they needed both the value and the index. –  Joshua Ulrich Apr 6 '11 at 15:55
@Joris, note that the original Q was also concerned with doing this fast. For large vectors, sorting is slow and order needs to sort the whole vector to work. This is the reason for the OP linking to the previous Q. –  Gavin Simpson Apr 6 '11 at 16:18
@Gavin : got it, corrected it as well. –  Joris Meys Apr 6 '11 at 16:26
To be fair, the OP never mentioned the ties handling, but you are quite - I knew when posting the solution it would fail with ties and was planning to show a ties-handling version although it does slow things down a bit. –  Gavin Simpson Apr 6 '11 at 16:49

No ties `which()` is probably your friend here. Combine the output from the `sort()` solution with `which()` to find the index that matches the output from the `sort()` step.

``````> set.seed(1)
> x <- sample(1000, 250)
> sort(x,partial=n-1)[n-1]
[1] 992
> which(x == sort(x,partial=n-1)[n-1])
[1] 145
``````

Ties handling The solution above doesn't work properly (and wasn't intended to) if there are ties and the ties are the values that are the ith largest or larger values. We need to take the unique values of the vector before sorting those values and then the above solution works:

``````> set.seed(1)
> x <- sample(1000, 1000, replace = TRUE)
> length(unique(x))
[1] 639
> n <- length(x)
> i <- which(x == sort(x,partial=n-1)[n-1])
> sum(x > x[i])
[1] 0
> x.uni <- unique(x)
> n.uni <- length(x.uni)
> i <- which(x == sort(x.uni, partial = n.uni-1)[n.uni-1])
> sum(x > x[i])
[1] 2
> tail(sort(x))
[1]  994  996  997  997 1000 1000
``````

`order()` is also very useful here:

``````> head(ord <- order(x, decreasing = TRUE))
[1] 220 145 209 202 211 163
``````

So the solution here is `ord[2]` for the index of the 2nd highest/largest element of `x`.

Some timings:

``````> set.seed(1)
> X <- sample(1e7, 1e7)
> system.time({n <- length(X); which(X == sort(X, partial = n-1)[n-1])})
user  system elapsed
0.319   0.058   0.378
> system.time({ord <- order(X, decreasing = TRUE); ord[2]})
user  system elapsed
14.578   0.084  14.708
> system.time({order(X, decreasing = TRUE)[2]})
user  system elapsed
14.647   0.084  14.779
``````

But as the linked post was getting at and the timings above show, `order()` is much slower, but both provide the same results:

``````> all.equal(which(X == sort(X, partial = n-1)[n-1]),
+           order(X, decreasing = TRUE)[2])
[1] TRUE
``````

And for the ties-handling version:

``````foo <- function(x, i) {
X <- unique(x)
N <- length(X)
i <- i-1
which(x == sort(X, partial = N-i)[N-i])
}

> system.time(foo(X, 2))
user  system elapsed
1.249   0.176   1.454
``````

So the extra steps slow this solution down a bit, but it is still very competitive with `order()`.

-

Method: Set all max values to `-Inf`, then find the indices of the max. No sorting required.

``````X <- runif(1e7)
system.time(
{
X[X == max(X)] <- -Inf
which(X == max(X))
})
``````

Works with ties and is very fast.

If you can guarantee no ties, then an even faster version is

``````system.time(
{
X[which.max(X)] <- -Inf
which.max(X)
})
``````

EDIT: As Joris mentioned, this method doesn't scale that well for finding third, fourth, etc., highest values.

``````which_nth_highest_richie <- function(x, n)
{
for(i in seq_len(n - 1L)) x[x == max(x)] <- -Inf
which(x == max(x))
}

which_nth_highest_joris <- function(x, n)
{
ux <- unique(x)
nux <- length(ux)
which(x == sort(ux, partial = nux - n + 1)[nux - n + 1])
}
``````

Using `x <- runif(1e7)` and `n = 2`, Richie wins

``````system.time(which_nth_highest_richie(x, 2))   #about half a second
For `n = 100`, Joris wins
``````system.time(which_nth_highest_richie(x, 100)) #about 20 seconds, ouch!
The balance point, where they take the same length of time, is about `n = 10`.