# How to generate permutations or combinations of object in R?

How to generate sequences of `r` objects from `n` objects? I'm looking for a way to do either permutations or combinations, with/without replacement, with distinct and non-distinct items (aka multisets).

This is related to twelvefold way. The "distinct" solutions could be included in twelvefold way, while the "non-distinct" are not included.

• There are, arguably, twelve questions of this type. Mar 21, 2014 at 20:55
• Yeah, it's a really useful way to organize and think about all of those different combinatorial objects. FYI, most of Google's first page hits for "Twelvefold Way" include more readable tables/clearer explanations than does the Wikipedia page I linked. Mar 21, 2014 at 21:26
• Thanks for the information. I think what I am missing are the surjective cases. Right..? [update]: it seems to be wrong Mar 21, 2014 at 21:32
• You're right, that's wrong ;) The characteristics on which the 12-fold classification is based are +/- different than what you've picked. For me, by far the best way to think about it is as looking at n balls being placed into m urns. There are three possible restrictions on how they can be placed (no restriction, must be injective, or must be surjective), and 4 possible combinations of labeled/unlabeled balls and urns. Here and here are 2 sources that use that lens to view the problem. Mar 21, 2014 at 21:50
• Finally, I figure out the difference between the 8 questions here and twelvefold. Four of the questions here are in twelvefold (those "distinct" questions) while those "non-distinct" questions are not in twelvefold. Mar 21, 2014 at 22:38

# 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:

1. Introduction
2. Setup
3. Combinations
4. Permutations
5. Multisets
6. Summary
7. 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:

1. `gtools`
2. `combinat`
3. `multicool`
4. `partitions`
5. `RcppAlgos`
6. `arrangements`
7. `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.

1. 2022 Macbook Air Apple M2 24 GB
2. 2020 Macbook Pro i7 16 GB
3. 2022 Windows Surface i5 16 GB
``````library(microbenchmark)
## print up to 4 digits to keep microbenchmark output tidy
options(digits = 4)
options(width = 90)

#> [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.

1. `RcppAlgos`
2. `combinat`
3. `gtools`
4. `arrangements`
5. `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,
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.

1. `RcppAlgos`
2. `gtools`
3. `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,
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.

1. `RcppAlgos`
2. `gtools`
3. `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,
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).

1. `RcppAlgos`
2. `gtools`
3. `combinat`
4. `multicool`
5. `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,
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).

1. `RcppAlgos`
2. `gtools`
3. `combinat`
4. `multicool`
5. `partitions`
6. `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(
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.

1. `RcppAlgos`
2. `gtools`
3. `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(
),
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.

1. `RcppAlgos`
2. `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:

1. `RcppAlgos`
2. `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:

1. `RcppAlgos`
2. `multicool`
3. `partitions`
4. `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`

1. The output is in lexicographical order.
2. Allows the user to specify the format via the `layout` argument (“row : row-major”, “colmnn : column-major”, and “list : list”).
3. Offers convenient methods such as `collect` & `getnext` when working with iterators.
4. 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.
5. 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`

1. The output is in lexicographical order.
2. 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.).
3. GMP support allows for exploration of combinations/permutations of vectors with many results.
4. Produce results in parallel using the `Parallel` or `nThreads` arguments.
5. Similar to `combn`, there is a `FUN` argument for applying a function to each result (See also `FUN.VALUE`).
6. 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.

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

• Excellent review! I guess I understand why in some cases, iterpc is not performing as efficiently as RcppAlgos because of the nature of generator. iterpc needs to initialize a generator object before performing the actual algorithm. I am actually refactoring iterpc as a new package and paradoxically, I am trying to get rid of RCpp and to use R C api solely. Again, excellent package RcppAlgos! Dec 29, 2017 at 23:36
• @RandyLai, thanks for the kind words. I'm glad this review can help in some way. I've heard the C api in R can be tricky to say the least. I wish you the best in your goals. Dec 30, 2017 at 12:31
• @JosephWood I have a problem with permutation. I wonder if the `permuteGeneral()` function can be applied to a list in list to calculate all possible permutations.i.e `expand.grid(1:10,1:100,1:5)` gives different length of vector of permutations. And it is also applicable with list. Consider I have a list `mylist = list(list(c(1,2,3,3,4),c(10,20,30,30,40,40,40,55)),list(c(2,4,6,6),1:10,1:50))` and if a use `sapply(mylist,expand.grid)` it gives expected result. I wonder if this can be done with `permuteGeneral()` function since `expand.grid()` function takes a lot time with higher dimensions. Aug 13, 2019 at 9:15
• I am gobsmacked! What a thorough exploration of the topic! Thanks! May 24, 2021 at 11:32
• @jangorecki, the only base R solution I know of is `combn` which is included. Are there other base R solutions? I will happily add it. The only other base R solution i can think of that some may think should be include is `expand.grid`. The problem with this function is that it doesn’t give permutations or combinations, but rather the Cartesian product, which is fundamentally different. Oct 13, 2022 at 15:14

EDIT: I have updated the answer to use a more efficient package `arrangements`

## Getting start of using `arrangement`

arrangements contains some efficient generators and iterators for permutations and combinations. It has been demonstrated that `arrangements` outperforms most of the existing packages of similar kind. Some benchmarks could be found here.

Here are the answers to the above questions

``````# 1) combinations: without replacement: distinct items

combinations(5, 2)

[,1] [,2]
[1,]    1    2
[2,]    1    3
[3,]    1    4
[4,]    1    5
[5,]    2    3
[6,]    2    4
[7,]    2    5
[8,]    3    4
[9,]    3    5
[10,]    4    5

# 2) combinations: with replacement: distinct items

combinations(5, 2, replace=TRUE)

[,1] [,2]
[1,]    1    1
[2,]    1    2
[3,]    1    3
[4,]    1    4
[5,]    1    5
[6,]    2    2
[7,]    2    3
[8,]    2    4
[9,]    2    5
[10,]    3    3
[11,]    3    4
[12,]    3    5
[13,]    4    4
[14,]    4    5
[15,]    5    5

# 3) combinations: without replacement: non distinct items

combinations(x = c("a", "b", "c"), freq = c(2, 1, 1), k = 2)

[,1] [,2]
[1,] "a"  "a"
[2,] "a"  "b"
[3,] "a"  "c"
[4,] "b"  "c"

# 4) combinations: with replacement: non distinct items

combinations(x = c("a", "b", "c"), k = 2, replace = TRUE)  # as `freq` does not matter

[,1] [,2]
[1,] "a"  "a"
[2,] "a"  "b"
[3,] "a"  "c"
[4,] "b"  "b"
[5,] "b"  "c"
[6,] "c"  "c"

# 5) permutations: without replacement: distinct items

permutations(5, 2)

[,1] [,2]
[1,]    1    2
[2,]    1    3
[3,]    1    4
[4,]    1    5
[5,]    2    1
[6,]    2    3
[7,]    2    4
[8,]    2    5
[9,]    3    1
[10,]    3    2
[11,]    3    4
[12,]    3    5
[13,]    4    1
[14,]    4    2
[15,]    4    3
[16,]    4    5
[17,]    5    1
[18,]    5    2
[19,]    5    3
[20,]    5    4

# 6) permutations: with replacement: distinct items

permutations(5, 2, replace = TRUE)

[,1] [,2]
[1,]    1    1
[2,]    1    2
[3,]    1    3
[4,]    1    4
[5,]    1    5
[6,]    2    1
[7,]    2    2
[8,]    2    3
[9,]    2    4
[10,]    2    5
[11,]    3    1
[12,]    3    2
[13,]    3    3
[14,]    3    4
[15,]    3    5
[16,]    4    1
[17,]    4    2
[18,]    4    3
[19,]    4    4
[20,]    4    5
[21,]    5    1
[22,]    5    2
[23,]    5    3
[24,]    5    4
[25,]    5    5

# 7) permutations: without replacement: non distinct items

permutations(x = c("a", "b", "c"), freq = c(2, 1, 1), k = 2)

[,1] [,2]
[1,] "a"  "a"
[2,] "a"  "b"
[3,] "a"  "c"
[4,] "b"  "a"
[5,] "b"  "c"
[6,] "c"  "a"
[7,] "c"  "b"

# 8) permutations: with replacement: non distinct items

permutations(x = c("a", "b", "c"), k = 2, replace = TRUE)  # as `freq` doesn't matter

[,1] [,2]
[1,] "a"  "a"
[2,] "a"  "b"
[3,] "a"  "c"
[4,] "b"  "a"
[5,] "b"  "b"
[6,] "b"  "c"
[7,] "c"  "a"
[8,] "c"  "b"
[9,] "c"  "c"
``````

## Compare to other packages

There are few advantages of using `arrangements` over the existing packages.

1. Integral framework: you don't have to use different packages for different methods.

2. It is very efficient. See https://randy3k.github.io/arrangements/articles/benchmark.html for some benchmarks.

3. It is memory efficient, it is able to generate all 13! permutation of 1 to 13, existing packages will fail to do so because of the limitation of matrix size. The `getnext()` method of the iterators allow users to get the arrangements one by one.

4. The generated arrangements are in dictionary order which may be desired for some users.

• I think this answer might be improved by showing some output that tells the story of each "question."
– Jota
Mar 21, 2014 at 20:57
• This answer is an advertisement for your package. If you're going to do that, please demonstrate the various capabilities and why they are superior to previous methods. As it is, in my opinion, this question and answer does not supplant all other questions about combinations/permutations (and it looks like this is your intent). Apr 7, 2014 at 5:14
• Hi Matthew, sorry to make you feel like it is an advertisement (indeed it is :)..) If you to go to see the editing history of my answer, you will see that the old answers are using other packages. In particularly, there is no package in doing k-permeation of multi set, see the home-brew function here. Since I was unsatisfied with the existing packages, so I decided to write my own package. Apr 7, 2014 at 5:34
• But I agree with you, I should compare my package with the existing packages. Apr 7, 2014 at 5:36
• I guess it is in general not an issue because the recommended way for a package to call a function in another package is `<package>::<function>`. Unless scripts are concerned, having similar names should not do much harm.....IMO. Jan 12, 2018 at 23:06

The package crossdes seems like a worthy addition to the list. Check this tutorial.

I will copy the text from the tutorial in case the information in that link gets lost.

For a BIBD there are v treatments repeated r times in b blocks of k observations. There is a fifth parameter lambda that records the number of blocks where every pair of treatment occurs in the design.

We first load the crossdes package in our sessions:

``````require(crossdes)
``````

The function find.BIB is used to generate a block design with specific number of treatments, blocks (rows of the design) and elements per block (columns of the design).

Consider an example with five treatments in four blocks of three elements. We can create a block design via:

``````> find. BIB(5, 4, 3)
[,1] [,2] [,3]
[1,]    1    3    4
[2,]    2    4    5
[3,]    2    3    5
[4,]    1    2    5
``````

This design is not a BIBD because the treatments are not all repeated the same number of times in the design and we can check this with the isGYD function. For this example:

``````> isGYD(find. BIB(5, 4, 3))

[1] The design is neither balanced w.r.t. rows nor w.r.t. columns.
``````

This confirms what we can see from the design.

The tutorial keeps going with seven treatments, seven blocks, and three elements but I won't include those.

• While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review Oct 10, 2022 at 15:35