There is a function in the `exactci`

package that I'd like to pass arguments to as matrices and get back a matrix. As it is, all arguments can only be vectors of length 1. I dug into the source and found this piece, the function I actually use (here with arguments modified and reduced):

```
exact.binom.minlike <- function(d1, d2, e1, e2){
x <- round(d1)
n <- x + round(d2)
p <- e1 / (e1 + e2)
support <- 0:n
f <- dbinom(support, n, p)
d <- f[support == x]
sum(f[f <= d * relErr])
}
```

(this returns a p value for a two-sided test of equality for poisson rates using the `minlike`

method)

I see that the reason I can't pass in a matrix and get back a matrix is because of the vector `support`

that gets created inside. I stripped down the `dbinom()`

part to the following:

```
f <- exp( lfactorial(n) -
(lfactorial(support) + lfactorial(n - support)) +
support * log(p) +
(n - support) * log(1 - p)
)
```

This gives back the same vector, `f`

, fine and dandy, even a bit faster, but it doesn't appear to solve my problem- at least I don't see a way out of using `support`

as a vector. The length of support will vary based on whatever `d1+d2`

is, so I'm stuck making comparisons one at a time. The best I've been able to do is stick the whole thing inside `Vectorize()`

, which takes matrices just fine as argument, but returns back a vector instead of a matrix:

```
exact.binom.minlike.stripped <- Vectorize(compiler:::cmpfun(function(d1, d2, e1, e2, relErr = 1 + 10 ^ ( -7)){
x <- round(d1)
n <- x + round(d2)
p <- e1 / (e1 + e2)
support <- 0:n
# where dbinom() is the prob mass function:
# n choose k * p ^ k * (1 - p) ^ (n - k) # log it to strip down, then exp it
f <- exp( lfactorial(n) -
(lfactorial(support) + lfactorial(n - support)) +
support * log(p) +
(n - support) * log(1 - p)
)
#f <- dbinom(support,n,p)
d <- f[support == x]
sum(f[f <= d * relErr])
}))
```

Here's an example:

```
set.seed(1)
d1 <- matrix(rpois(36,lambda = 100), 6)
d2 <- matrix(rpois(36,lambda = 150), 6)
e1 <- matrix(rpois(36,lambda = 10000), 6)
e2 <- matrix(rpois(36,lambda = 25000), 6)
```

this output is a vector of length 36 instead of a 6x6 matrix. All four inputs were 6x6 matrices:

```
(p.vals <- exact.binom.minlike.stripped(d1, d2, e1, e2))
[1] 1.935277e-04 9.680425e-08 1.508232e-08 1.227176e-04 1.656111e-02
[6] 2.310620e-04 2.871150e-05 4.024025e-06 4.804943e-05 1.619866e-02
[11] 3.610596e-02 1.101247e-04 5.153746e-04 1.350891e-04 8.663191e-06
[16] 1.384378e-05 2.681715e-06 4.556092e-08 2.270317e-04 2.040001e-04
[21] 3.330344e-01 4.775055e-05 2.588667e-07 5.647732e-04 1.615861e-03
[26] 2.438345e-03 2.524692e-04 3.398664e-05 2.001322e-05 4.361194e-03
[31] 3.909116e-05 1.697943e-03 8.543677e-07 2.992653e-05 2.617216e-04
[36] 3.106748e-03
```

I gather I can add `dim()`

s to this and make it back into a matrix:

```
dim(p.vals) <- dim(d1)
```

but that seems second best. Can I make `Vectorize()`

give back a matrix of the same dimensions as the arguments passed to it? Even better, is there a way to properly vectorize what I'm doing here and avoid hidden for loops altogether (`Vectorize()`

uses `mapply()`

)?

[[Edit]] Thanks Pete for the great suggestions. Here's a comparison using data closer in dimension to what I'm actually doing:

```
set.seed(1)
N <-110
d1 <- matrix(rpois(N^2,lambda = 1000), N)
d2 <- matrix(rpois(N^2,lambda = 1500), N)
e1 <- matrix(rpois(N^2,lambda = 10000), N)
e2 <- matrix(rpois(N^2,lambda = 25000), N)
system.time(exact.binom.minlike.stripped.2(d1, d2, e1, e2))
user system elapsed
16.353 1.112 17.635
system.time(exact.binom.minlike.stripped.3(d1, d2, e1, e2))
user system elapsed
14.685 0.016 14.715
system.time({
(p.vals <- exact.binom.minlike.stripped(d1, d2, e1, e2))
(dim(p.vals) <- dim(d1))
})
user system elapsed
12.541 0.040 12.604
```

I watched my system monitor for memory usage during these, and only `exact.binom.minlike.stripped.2()`

is a memory hog. I see that if I were to use this on my real data, where `max(n)`

can get 10-20 times larger, that my computer would choke. (3) does not avthis problem, but for some reason it's not quite as fast as `exact.binom.minlike.stripped()`

. Compiling (3) did not make it run any faster on my system.

[[Edit 2]]: on the same data, Pete's new `exact.binom.minlike.stripped3()`

does the job in:

```
user system elapsed
6.468 0.032 6.513
```

Thus, the later stretegy, pre-calculating the log factorial of `max(n)`

, is a major time-saver. Many thanks Pete!

`outer`

may be helpful. Here's a post I did on talkstats.com you might modify to use matrices isntead: talkstats.com/showthread.php/… – Tyler Rinker Nov 17 '12 at 18:57`3`

is very slightly faster than the original on my computer, although given how close they are I can see them flipping on a different setup. I think your explicit calculation replacing`dbinom`

is the reason: I assume that`dbinom`

has sanity checks in place, which have to be run`N^2`

times. I got a small speed-up by replacing`dbinom`

in`3`

, then found (using`Rprof`

) that most of the time was spent in`lfactorial`

. Precomputing the`lfactorial`

results made`3`

about twice as fast. – pete Nov 18 '12 at 22:40