I think one could provide a vectorised solution using `stepfun`

and combining with `pmin`

and `pmax`

all of which are vectorised. Its a bit of twisted/complicated logic, but its worth all the effort.

Advantages of using `stepfun`

+ `pmin`

+ `pmax`

:

- blazing fast (see benchmarking below)
- not limited by the size of the matrix (see the error on a huge vector while running Jonathan's code)

First, the idea is inspired from `Jonathan Chang's`

post **here**. Here the small variation is that you need the index rather than the difference. Also, I *assume* that all values are *positive* (from your `runif`

input). You could extend this to vectors with negative inputs, but I leave that task to you if need be. Before I go to the code and benchmarking, let me explain what's the idea behind `stepfun`

.

Assume you have two vectors `x`

(equivalent to `v[,1]`

) and `y`

(equivalent to `t[,1]`

). Now, let us sort `y`

and create a `stepfun`

on the `sorted y`

in this manner:

```
y_sort <- sort(y)
step <- stepfun(y_sort, 0:length(y))
```

This helps us how exactly? Querying `step(a)`

gives you the index of the largest value in `y_sort`

that is `< a`

. This might take a while to sink in. In other words, the value `a`

lies in the position between `step(a)`

and `step(a) + 1`

in the `sorted y (y_sort)`

. Now, the first thing we'll have to figure out is, which one of these two values is closest to `a`

. This is achieved by extracting the indices `step(a)`

and `step(a)+1`

and the values in `y_sort`

corresponding to these indices and asking if the `abs(a-y_sort[step(a)]) > abs(a - y_sort[step(a)+1])`

. If its false, then, `step(a)`

is your index, and vice-versa. Second, getting back the original index from `y`

from `y_sort`

and this can be achieved by obtaining the corresponding sorted indices with the option `index.return = TRUE`

in `sort`

.

I agree this might be quite complicated to follow in this manner. But check the code and run it step by step and use the text above to follow it along (if necessary). The best part is that `a`

can be a vector, so it is extremely fast! Now on to the code.

```
# vectorised solution using stepfun
vectorise_fun1 <- function(x, y) {
y_sort <- sort(abs(y), index.return = TRUE)
y_sval <- y_sort$x
y_sidx <- y_sort$ix
# stepfun
step_fun <- stepfun(y_sval, 0:length(y))
ix1 <- pmax(1, step_fun(x))
ix2 <- pmin(length(y), 1 + ix1)
iy <- abs(x - y_sval[ix1]) > abs(x - y_sval[ix2])
# construct output
res <- rep(0, length(x))
res[iy] <- y_sidx[ix2[iy]]
res[!iy] <- y_sidx[ix1[!iy]]
res
}
# obtaining result
out_arun <- vectorise_fun1(v[,1], t[,1])
# (or) v[,2] <- vectorise_fun1(v[,1], t[,1])
# Are the results identical?
# Matthew's solution
vectorise_fun2 <- function(x, y) {
res <- Vectorize(function(r) which.min(abs(x[r] - y)))(seq(length(x)))
}
out_matthew <- vectorise_fun2(v[,1], t[,1])
# Jonathan's solution
vectorise_fun3 <- function(x, y) {
V <- matrix(rep.int(x, length(y)), ncol = length(y))
TT <- matrix(rep.int(y, length(x)), ncol = length(y), byrow = T)
max.col(-abs(V-TT))
}
out_jonathan <- vectorise_fun3(v[,1], t[,1])
# Are the results identical?
> all(out_arun == out_matthew)
[1] TRUE
> all(out_arun == out_jonathan)
[1] TRUE
```

So, what's the point? All results are identical and the function with `stepfun`

is huge and tricky to follow. Let's take a huge vector.

```
x <- runif(1e4)
y <- runif(1e3)
```

Now, let's benchmark to see the advantage:

```
require(rbenchmark)
> benchmark( out_arun <- vectorise_fun1(x,y),
out_matthew <- vectorise_fun2(x,y),
out_jonathan <- vectorise_fun3(x,y),
replications=1, order = "elapsed")
# test replications elapsed relative user.self
# 1 out_arun <- vectorise_fun1(x, y) 1 0.004 1.00 0.005
# 2 out_matthew <- vectorise_fun2(x, y) 1 0.221 55.25 0.169
# 3 out_jonathan <- vectorise_fun3(x, y) 1 1.381 345.25 0.873
# Are the results identical?
> all(out_arun == out_matthew)
[1] TRUE
> all(out_arun == out_jonathan)
[1] TRUE
```

So, using `step_fun`

is faster by a min of 55 times and a max of 345 times! Now, let's go for even bigger vectors.

```
x <- runif(1e5)
y <- runif(1e4)
require(rbenchmark)
> benchmark( out_arun <- vectorise_fun1(x,y),
out_matthew <- vectorise_fun2(x,y),
replications=1, order = "elapsed")
# test replications elapsed relative user.self
# 1 out_arun <- vectorise_fun1(x, y) 1 0.052 1.000 0.043
# 2 out_matthew <- vectorise_fun2(x, y) 1 16.668 320.538 11.849
```

Jonathan's function resulted in allocation error:

```
Error in rep.int(x, length(y)) :
cannot allocate vector of length 1000000000
```

And the speed up is 320 times here.