# A Walk Through a Slice of Combinatorics in R*

Below, we examine packages equipped with the capabilities of generating combinations & permutations. If I have left out any package, please forgive me and please leave a comment or better yet, edit this post.

Outline of analysis:

- Introduction
- Setup
- Combinations
- Permutations
- Multisets
- Summary
- Memory

Before we begin, we note that combinations/permutations **with** replacement of distinct vs. non-distint items chosen *m* at a time are equivalent. This is so, because when we have replacement, it is not specific. Thus, no matter how many times a particular element originally occurs, the output will have an instance(s) of that element repeated 1 to *m* times.

## 1. Introduction

### Packages:

`gtools`

`combinat`

`multicool`

`partitions`

`RcppAlgos`

`arrangements`

`utils`

I did not include `permute`

or `permutations`

as they are not really meant to attack these types of problems. I also did not include the updated `gRbase`

as certain cases crashed my computer.

#### |————————————— **OVERVIEW** —————————————-|

```
|_________________| gtools | combinat | multicool | partitions |
| comb rep | Yes | | | |
| comb NO rep | Yes | Yes | | |
| perm rep | Yes | | | |
| perm NO rep | Yes | Yes | Yes | Yes |
| perm multiset | | | Yes | Yes |
| comb multiset | | | | |
| accepts factors | | Yes | | |
| m at a time | Yes | Yes/No | | |
| general vector | Yes | Yes | Yes | |
| iterable | | | Yes | |
| parallelizable | | | | |
| multi-threaded | | | | |
| big integer | | | | |
|_________________| arrangements | RcppAlgos | utils |
| comb rep | Yes | Yes | |
| comb NO rep | Yes | Yes | Yes |
| perm rep | Yes | Yes | |
| perm NO rep | Yes | Yes | |
| perm multiset | Yes | Yes | |
| comb multiset | Yes | Yes | |
| accepts factors | Yes | Yes | Yes |
| m at a time | Yes | Yes | Yes |
| general vector | Yes | Yes | Yes |
| iterable | Yes | Yes | |
| parallelizable | Yes | Yes | |
| big integer | Yes | Yes | |
| multi-threaded | | Yes | |
```

The tasks, `m at a time`

and `general vector`

, refer to the capability of generating results “*m* at a time” and rearranging a “general vector” as opposed to `1:n`

. In practice, we are generally concerned with finding rearrangements of a general vector, therefore all examinations below will reflect this when possible.

## 2. Setup

All benchmarks were ran on 3 different set-ups.

- 2022 Macbook Air Apple M2 24 GB
- 2020 Macbook Pro i7 16 GB
- 2022 Windows Surface i5 16 GB

```
library(microbenchmark)
## print up to 4 digits to keep microbenchmark output tidy
options(digits = 4)
options(width = 90)
numThreads <- min(as.integer(RcppAlgos::stdThreadMax() / 2), 6)
numThreads
#> [1] 4
pkgs <- c("gtools", "combinat", "multicool", "partitions",
"RcppAlgos", "arrangements", "utils", "microbenchmark")
sapply(pkgs, packageVersion, simplify = FALSE)
#> $gtools
#> [1] '3.9.3'
#>
#> $combinat
#> [1] '0.0.8'
#>
#> $multicool
#> [1] '0.1.12'
#>
#> $partitions
#> [1] '1.10.7'
#>
#> $RcppAlgos
#> [1] '2.6.0'
#>
#> $arrangements
#> [1] '1.1.9'
#>
#> $utils
#> [1] '4.2.1'
#>
#> $microbenchmark
#> [1] '1.4.7'
```

The listed results were obtained from setup #1 (i.e. Macbook Air M2). The results on the Macbook Pro were similar, however with the Windows setup, multi-threading was less effective. In some cases on the Windows setup, the serial execution was faster. We will call all functions with the pattern `package::function`

so no `library`

calls are needed.

## 3. Combinations

First, we examine combinations without replacement chosen *m* at a time.

`RcppAlgos`

`combinat`

`gtools`

`arrangements`

`utils`

How to:

```
set.seed(13)
tVec1 <- sort(sample(100, 20))
m <- 10
t1 <- RcppAlgos::comboGeneral(tVec1, m) ## returns matrix with m columns
t3 <- combinat::combn(tVec1, m) ## returns matrix with m rows
t4 <- gtools::combinations(20, m, tVec1) ## returns matrix with m columns
identical(t(t3), t4) ## must transpose to compare
#> [1] TRUE
t5 <- arrangements::combinations(tVec1, m)
identical(t1, t5)
#> [1] TRUE
t6 <- utils::combn(tVec1, m) ## returns matrix with m rows
identical(t(t6), t4) ## must transpose to compare
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::comboGeneral(tVec1, m,
nThreads = numThreads),
cbRcppAlgosSer = RcppAlgos::comboGeneral(tVec1, m),
cbGtools = gtools::combinations(20, m, tVec1),
cbCombinat = combinat::combn(tVec1, m),
cbUtils = utils::combn(tVec1, m),
cbArrangements = arrangements::combinations(tVec1, m),
unit = "relative"
)
#> Warning in microbenchmark(cbRcppAlgosPar = RcppAlgos::comboGeneral(tVec1, : less accurate
#> nanosecond times to avoid potential integer overflows
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.0000 100
#> cbRcppAlgosSer 2.712 2.599 1.280 2.497 2.477 0.2666 100
#> cbGtools 739.325 686.803 271.623 679.894 661.560 11.7178 100
#> cbCombinat 173.836 166.265 76.735 176.052 191.945 4.9075 100
#> cbUtils 179.895 170.345 71.639 169.661 178.385 3.8900 100
#> cbArrangements 2.717 2.995 1.975 2.835 2.935 0.8195 100
```

Now, we examine combinations with replacement chosen *m* at a time.

`RcppAlgos`

`gtools`

`arrangements`

How to:

```
set.seed(97)
tVec2 <- sort(rnorm(12))
m <- 9
t1 <- RcppAlgos::comboGeneral(tVec2, m, repetition = TRUE)
t3 <- gtools::combinations(12, m, tVec2, repeats.allowed = TRUE)
identical(t1, t3)
#> [1] TRUE
t4 <- arrangements::combinations(tVec2, m, replace = TRUE)
identical(t1, t4)
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::comboGeneral(tVec2, m, TRUE,
nThreads = numThreads),
cbRcppAlgosSer = RcppAlgos::comboGeneral(tVec2, m, TRUE),
cbGtools = gtools::combinations(12, m, tVec2, repeats.allowed = TRUE),
cbArrangements = arrangements::combinations(tVec2, m, replace = TRUE),
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.0000 1.000 1.0000 1.0000 100
#> cbRcppAlgosSer 1.987 2.382 0.9173 2.347 1.2776 0.9733 100
#> cbGtools 670.126 517.561 103.8726 523.135 177.0940 12.0440 100
#> cbArrangements 2.300 2.582 0.8294 2.542 0.9212 1.0089 100
```

## 4. Permutations

First, we examine permutations without replacement chosen *m* at a time.

`RcppAlgos`

`gtools`

`arrangements`

How to:

```
tVec3 <- as.integer(c(2, 3, 5, 7, 11, 13, 17, 19, 23, 29))
t1 <- RcppAlgos::permuteGeneral(tVec3, 6)
t3 <- gtools::permutations(10, 6, tVec3)
identical(t1, t3)
#> [1] TRUE
t4 <- arrangements::permutations(tVec3, 6)
identical(t1, t4)
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::permuteGeneral(tVec3, 6,
nThreads = numThreads),
cbRcppAlgosSer = RcppAlgos::permuteGeneral(tVec3, 6),
cbGtools = gtools::permutations(10, 6, tVec3),
cbArrangements = arrangements::permutations(tVec3, 6),
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.0000 100
#> cbRcppAlgosSer 1.204 1.553 1.522 1.523 1.509 0.5722 100
#> cbGtools 357.078 308.978 288.396 301.611 292.862 64.8564 100
#> cbArrangements 2.356 2.361 2.183 2.292 2.224 0.4605 100
```

Next, we examine permutations without replacement with a general vector (returning all permutations).

`RcppAlgos`

`gtools`

`combinat`

`multicool`

`arrangements`

How to:

```
tVec3Prime <- tVec3[1:9]
## For RcppAlgos, arrangements, & gtools (see above)
t4 <- combinat::permn(tVec3Prime) ## returns a list of vectors
## convert to a matrix
t4 <- do.call(rbind, t4)
t5 <- multicool::allPerm(multicool::initMC(tVec3Prime)) ## returns a matrix with n columns
all.equal(t4[do.call(order,as.data.frame(t4)),],
t5[do.call(order,as.data.frame(t5)),])
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::permuteGeneral(tVec3Prime,
nThreads = numThreads),
cbRcppAlgosSer = RcppAlgos::permuteGeneral(tVec3Prime),
cbGtools = gtools::permutations(9, 9, tVec3Prime),
cbCombinat = combinat::permn(tVec3Prime),
cbMulticool = multicool::allPerm(multicool::initMC(tVec3Prime)),
cbArrangements = arrangements::permutations(tVec3Prime),
times = 25,
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.0 25
#> cbRcppAlgosSer 1.555 2.187 2.616 2.190 2.274 10.3 25
#> cbGtools 1913.125 1850.589 1893.918 1877.707 1915.601 2124.5 25
#> cbCombinat 508.360 512.182 562.042 532.123 595.722 715.3 25
#> cbMulticool 103.061 103.694 128.480 118.169 127.118 208.3 25
#> cbArrangements 3.216 3.583 13.566 3.544 3.561 139.2 25
```

Now, we examine permutations without replacement for `1:n`

(returning all permutations).

`RcppAlgos`

`gtools`

`combinat`

`multicool`

`partitions`

`arrangements`

How to:

```
t1 <- partitions::perms(9) ## returns an object of type 'partition' with n rows
identical(t(as.matrix(t1)), RcppAlgos::permuteGeneral(9))
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::permuteGeneral(9, nThreads = numThreads),
cbRcppAlgosSer = RcppAlgos::permuteGeneral(9),
cbGtools = gtools::permutations(9, 9),
cbCombinat = combinat::permn(9),
cbMulticool = multicool::allPerm(multicool::initMC(1:9)),
cbPartitions = partitions::perms(9),
cbArrangements = arrangements::permutations(9),
times = 25,
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.000 25
#> cbRcppAlgosSer 1.583 2.218 2.587 2.261 2.591 1.814 25
#> cbGtools 2010.303 1855.443 1266.853 1898.458 1903.055 217.422 25
#> cbCombinat 511.196 515.197 392.252 533.737 652.125 86.305 25
#> cbMulticool 108.152 103.188 80.469 108.227 120.804 23.504 25
#> cbPartitions 6.139 6.018 7.167 5.993 6.403 9.446 25
#> cbArrangements 4.089 3.797 3.135 3.791 3.760 1.858 25
```

Lastly, we examine permutations with replacement.

`RcppAlgos`

`gtools`

`arrangements`

How to:

```
t1 <- RcppAlgos::permuteGeneral(tVec3, 5, repetition = TRUE)
t3 <- gtools::permutations(10, 5, tVec3, repeats.allowed = TRUE)
t4 <- arrangements::permutations(x = tVec3, k = 5, replace = TRUE)
identical(t1, t3)
#> [1] TRUE
identical(t1, t4)
#> [1] TRUE
```

This next benchmark is a little surprising given the results up until now.

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::permuteGeneral(
tVec3, 5, TRUE, nThreads = numThreads
),
cbRcppAlgosSer = RcppAlgos::permuteGeneral(tVec3, 5, TRUE),
cbGtools = gtools::permutations(10, 5, tVec3, repeats.allowed = TRUE),
cbArrangements = arrangements::permutations(tVec3, 5, replace = TRUE),
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.000 100
#> cbRcppAlgosSer 1.307 1.669 1.465 1.561 1.513 1.015 100
#> cbGtools 6.364 6.188 5.448 5.762 5.434 1.625 100
#> cbArrangements 2.584 2.442 1.824 2.265 2.135 0.117 100
```

That is not a typo… `gtools::permutations`

is almost as fast as the other compiled functions. I encourage the reader to go check out the source code of `gtools::permutations`

as it is one of the most elegant displays of programming out there (`R`

or otherwise).

## 5. Multisets

First, we examine combinations of multisets.

`RcppAlgos`

`arrangements`

To find combinations/permutations of multisets, with `RcppAlgos`

use the `freqs`

arguments to specify how many times each element of the source vector, `v`

, is repeated.

```
set.seed(496)
myFreqs <- sample(1:5, 12, replace = TRUE)
## This is how many times each element will be repeated
tVec4 <- as.integer(c(1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233))
t1 <- RcppAlgos::comboGeneral(tVec4, 12, freqs = myFreqs)
t3 <- arrangements::combinations(tVec4, 12, freq = myFreqs)
identical(t1, t3)
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::comboGeneral(
tVec4, 12, freqs = myFreqs, nThreads = numThreads
),
cbRcppAlgosSer = RcppAlgos::comboGeneral(tVec4, 12, freqs = myFreqs),
cbArrangements = arrangements::combinations(tVec4, 12, freq = myFreqs),
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.0000 100
#> cbRcppAlgosSer 3.197 3.012 2.003 2.831 2.681 0.1658 100
#> cbArrangements 9.391 7.830 4.901 7.252 6.731 0.3140 100
```

For permutations of multisets chosen *m* at a time, we have:

`RcppAlgos`

`arrangements`

How to:

```
set.seed(123)
tVec5 <- sort(runif(5))
t1 <- RcppAlgos::permuteGeneral(tVec5, 8, freqs = rep(4, 5))
t3 <- arrangements::permutations(tVec5, 8, freq = rep(4, 5))
identical(t1, t3)
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::permuteGeneral(
tVec5, 8, freqs = rep(4, 5), nThreads = numThreads
),
cbRcppAlgosSer = RcppAlgos::permuteGeneral(tVec5, 8, freqs = rep(4, 5)),
cbArrangements = arrangements::permutations(tVec5, 8, freq = rep(4, 5)),
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.000 100
#> cbRcppAlgosSer 3.336 3.326 2.990 3.330 3.517 2.106 100
#> cbArrangements 3.751 3.746 3.346 3.757 3.840 2.305 100
```

For permutations of multisets returning all permutations, we have:

`RcppAlgos`

`multicool`

`partitions`

`arrangements`

How to:

```
tVec6 <- (1:5)^3
## For multicool, you must have the elements explicitly repeated
tVec6Prime <- rep(tVec6, times = rep(2, 5))
## for comparison
t1 <- RcppAlgos::permuteGeneral(tVec6, freqs = rep(2, 5))
t2 <- partitions::multiset(tVec6Prime)
t3 <- multicool::allPerm(multicool::initMC(tVec6Prime))
t4 <- arrangements::permutations(tVec6, freq = rep(2, 5))
## the package partitions, returns class of integer
## whereas RcppAlgos preserves class of tVec6 (i.e. numeric)
all.equal(t1, t(as.matrix(t2)))
#> [1] TRUE
identical(t1[do.call(order,as.data.frame(t1)),],
t3[do.call(order,as.data.frame(t3)),])
#> [1] TRUE
identical(t1, t4)
#> [1] TRUE
```

Benchmark:

```
microbenchmark(
cbRcppAlgosPar = RcppAlgos::permuteGeneral(
tVec6, freqs = rep(2, 5), nThreads = numThreads
),
cbRcppAlgosSer = RcppAlgos::permuteGeneral(tVec6, freqs = rep(2, 5)),
cbMulticool = multicool::allPerm(multicool::initMC(tVec6Prime)),
cbPartitions = partitions::multiset(tVec6Prime),
cbArrangements = arrangements::permutations(tVec6, freq = rep(2, 5)),
unit = "relative"
)
#> Unit: relative
#> expr min lq mean median uq max neval
#> cbRcppAlgosPar 1.000 1.000 1.000 1.000 1.000 1.0000 100
#> cbRcppAlgosSer 2.485 2.141 2.289 2.584 2.511 1.0250 100
#> cbMulticool 80.195 66.237 45.540 64.971 66.057 3.5655 100
#> cbPartitions 5.731 4.786 3.925 4.719 4.953 0.4558 100
#> cbArrangements 2.999 2.907 3.270 2.966 2.906 3.1214 100
```

## 6. Summary

Both `gtools`

and `combinat`

are well established packages for rearranging elements of a vector. With `gtools`

there are a few more options (see the overview above) and with `combinat`

, you can rearrange `factors`

. With `multicool`

, one is able to rearrange multisets. Although `partitions`

is limited for the purposes of this question, it is a powerhouse packed with highly efficient functions for dealing with integer partitions.

`arrangements`

- The output is in lexicographical order.
- Allows the user to specify the format via the
`layout`

argument (“row : row-major”, “colmnn : column-major”, and “list : list”).
- Offers convenient methods such as
`collect`

& `getnext`

when working with iterators.
- Allows for the generation of more than
`2^31 - 1`

combinations/permutations via `getnext`

. N.B. `RcppAlgos`

(via `nextItem`

) and `multicool`

(via `nextPerm`

) are also capable of doing this.
- GMP support allows for exploration of combinations/permutations of vectors with many results.

Observe:

```
icomb <- arrangements::icombinations(1000, 7)
icomb$getnext()
#> [1] 1 2 3 4 5 6 7
icomb$getnext(d = 5)
#> [,1] [,2] [,3] [,4] [,5] [,6] [,7]
#> [1,] 1 2 3 4 5 6 8
#> [2,] 1 2 3 4 5 6 9
#> [3,] 1 2 3 4 5 6 10
#> [4,] 1 2 3 4 5 6 11
#> [5,] 1 2 3 4 5 6 12
```

This feature is really nice when you only want a few combinations/permutations. With traditional methods, you would have to generate all combinations/permutations and then subset. This would render the previous example impossible as there are more than `10^17`

results (i.e. `ncombinations(1000, 7, bigz = TRUE)`

= 194280608456793000).

This feature along with the improvements to the generators in `arrangements`

, allow it to be very efficient with respect to memory.

`RcppAlgos`

- The output is in lexicographical order.
- There are convenient constraint features that we will not discuss here as they are off-topic for this question. I will only note that the types of problems that can be solved by utilizing these features were the motivation for creating this package (partitions, subset-sum, etc.).
- GMP support allows for exploration of combinations/permutations of vectors with many results.
- Produce results in parallel using the
`Parallel`

or `nThreads`

arguments.
- Similar to
`combn`

, there is a `FUN`

argument for applying a function to each result (See also `FUN.VALUE`

).
- Provides flexible and merory efficient iterators that allow for bidirectional iteration as well as random access.
`nextItem`

|`nextNIter`

|`nextRemaining`

: Retrieve the *next* lexicographical result(s)
`prevItem`

|`prevNIter`

|`prevRemaining`

: Retrieve the *previous* lexicographical result(s)
`front`

|`back`

|`[[`

: Random access methods
- Allows for easy generation of more than
`2^31 - 1`

results from any starting place.

Observe:

```
iter <- RcppAlgos::comboIter(1000, 7)
# first combinations
iter@nextIter()
#> [1] 1 2 3 4 5 6 7
# next 5 combinations
iter@nextNIter(5)
#> [,1] [,2] [,3] [,4] [,5] [,6] [,7]
#> [1,] 1 2 3 4 5 6 8
#> [2,] 1 2 3 4 5 6 9
#> [3,] 1 2 3 4 5 6 10
#> [4,] 1 2 3 4 5 6 11
#> [5,] 1 2 3 4 5 6 12
# from the current state, the previous combination
iter@prevIter()
#> [1] 1 2 3 4 5 6 11
# the last combination
iter@back()
#> [1] 994 995 996 997 998 999 1000
# the 5th combination
iter[[5]]
#> [1] 1 2 3 4 5 6 11
# you can even pass a vector of indices
iter[[c(1, 3, 5)]]
#> [,1] [,2] [,3] [,4] [,5] [,6] [,7]
#> [1,] 1 2 3 4 5 6 7
#> [2,] 1 2 3 4 5 6 9
#> [3,] 1 2 3 4 5 6 11
# start iterating from any index
iter[[gmp::pow.bigz(2, 31)]]
#> [1] 1 2 3 17 138 928 954
# get useful info about the current state
iter@summary()
#> $description
#> [1] "Combinations of 1000 choose 7"
#>
#> $currentIndex
#> Big Integer ('bigz') :
#> [1] 2147483648
#>
#> $totalResults
#> Big Integer ('bigz') :
#> [1] 194280608456793000
#>
#> $totalRemaining
#> Big Integer ('bigz') :
#> [1] 194280606309309352
## get next ieteration
iter@nextIter()
#> [1] 1 2 3 17 138 928 955
```

In case you were wondering how each package scales, I will leave you with this final example that measures how fast `RcppAlgos`

and the `arrangements`

packages can generate over 100 million results. Note, `gtools::combinations`

is left out here as it will throw the error: `evaluation nested too deeply...`

. We also leave out `combn`

as it takes quite some time to execute. Curiously, the differences in memory usage between `utils::combn`

and `combinat::combn`

is quite bizarre given that they are only marginally different (see `?utils::combn`

under the “Authors” section).

Observe:

```
set.seed(2187)
tVec7 <- sort(sample(10^7, 10^3))
## 166,167,000 Combinations
system.time(RcppAlgos::comboGeneral(tVec7, 3))
#> user system elapsed
#> 0.386 0.105 0.490
system.time(arrangements::combinations(x = tVec7, k = 3))
#> user system elapsed
#> 0.439 0.105 0.545
## 124,251,000 Permuations
system.time(RcppAlgos::permuteGeneral(tVec7[1:500], 3))
#> user system elapsed
#> 0.141 0.076 0.218
system.time(arrangements::permutations(x = tVec7[1:500], k = 3))
#> user system elapsed
#> 0.386 0.077 0.463
```

## 7. Memory

When executing `comboGeneral`

as well as `arrangements::combinations`

, the memory will jump almost 2 Gbs before calling `gc`

. This seems about right as `#rows * #nols * bytesPerCell / 2^30 bytes = choose(1000,3) * 3 * 4 / 2^30 bytes = (166167000 * 3 * 4)/2^30 = 1.857 Gbs`

). However, when executing `combn`

, the memory behavior was eratic (e.g. sometimes it would use all 16 Gb of memory and other times it would only spike a couple of Gbs). When I tested this on the Windows set-up, it would often crash.

We can confirm this using `Rprof`

along with `summaryRporf`

. Observe:

```
Rprof("RcppAlgos.out", memory.profiling = TRUE)
t1 <- RcppAlgos::comboGeneral(tVec7, 3)
Rprof(NULL)
head(summaryRprof("RcppAlgos.out", memory = "both")$by.total, n = 1)
#> total.time total.pct mem.total self.time self.pct
#> "RcppAlgos::comboGeneral" 0.42 100 1902 0.42 100
Rprof("arrangements.out", memory.profiling = TRUE)
t3 <- arrangements::combinations(tVec7, 3)
Rprof(NULL)
head(summaryRprof("arrangements.out", memory = "both")$by.total, n = 1)
#> total.time total.pct mem.total self.time self.pct
#> "arrangements::combinations" 0.5 100 1902 0.5 100
```

With `RcppAlgos`

& `arrangements`

, `mem.total`

registers just over `1900 Mb`

.

And here is the memory profile on a smaller vector.

```
tVec7Prime <- tVec7[1:300]
Rprof("combinat.out", memory.profiling = TRUE)
t3 <- combinat::combn(tVec7Prime, 3)
Rprof(NULL)
head(summaryRprof("combinat.out", memory = "both")$by.total, n = 1)
#> total.time total.pct mem.total self.time self.pct
#> "combinat::combn" 2.1 100 1055 1.98 94.29
Rprof("utils.out", memory.profiling = TRUE)
t4 <- utils::combn(tVec7Prime, 3)
Rprof(NULL)
head(summaryRprof("utils.out", memory = "both")$by.total, n = 1)
#> total.time total.pct mem.total self.time self.pct
#> "utils::combn" 1.6 100 2059 1.6 100
Rprof("gtools.out", memory.profiling = TRUE)
t5 <- gtools::combinations(300, 3, tVec7Prime)
Rprof(NULL)
head(summaryRprof("gtools.out", memory = "both")$by.total, n = 1)
#> total.time total.pct mem.total self.time self.pct
#> "rbind" 1.62 100 6659 1.46 90.12
```

Interestingly, `utils::combn`

and `combinat::combn`

use different amounts of memory and take different amounts of time to execute. This does not hold up with smaller vectors:

```
microbenchmark(combinat::combn(2:13, 6), utils::combn(2:13, 6))
#> Unit: microseconds
#> expr min lq mean median uq max neval
#> combinat::combn(2:13, 6) 313.4 326.7 329.4 328.1 330.4 370.6 100
#> utils::combn(2:13, 6) 378.3 393.1 397.0 395.2 399.2 451.2 100
```

And with `gtools`

the total memory used is a little over 3x as much as `utils`

. It should be noted that for these 3 packages, I obtained different results every-time I ran them (e.g. for `combinat::combn`

sometimes I would get 9000 Mb and then I would get 13000 Mb).

Still, none can match `RcppAlgos`

**OR** `arrangements`

. Both only use 51 Mb when ran on the example above.

benchmark script: https://github.com/jwood000/RcppAlgos/blob/main/scripts/SO_Comb_Perm_in_R.R

_{*: An homage to A Walk through Combinatorics by Miklós Bóna }