If you don't want the combo names in the resulting object, then we can combine elements of @DWin's and @Owen's Answers to provide a truly vectorised approach to the problem. (You can add the combination names as row names with one extra step at the end.)

First, the data:

```
dat <- read.table(con <- textConnection(" A B C D
w 0 0 1 1
x 0 1 0 1
y 0 0 1 1
z 0 0 0 1
"), header=TRUE)
close(con)
```

Take the `combn()`

idea from @DWin's Answer but use it on the *row indices* of `dat`

:

```
combs <- combn(seq_len(nrow(dat)), 2)
```

The rows of `combs`

now index the rows of `dat`

that we want to multiply together:

```
> combs
[,1] [,2] [,3] [,4] [,5] [,6]
[1,] 1 1 1 2 2 3
[2,] 2 3 4 3 4 4
```

Now we take the idea @Owen showed, namely `dat[i, ] * dat[j, ]`

with `i`

and `j`

being the first and second rows of `combs`

respectively. We convert to a matrix with `data.matrix()`

as this will be more efficient for large objects, but the code will work with `dat`

as a data frame too.

```
mat <- data.matrix(dat)
mat[combs[1,], ] * mat[combs[2,], ]
```

which produces:

```
> mat[combs[1,], ] * mat[combs[2,], ]
A B C D
w 0 0 0 1
w 0 0 1 1
w 0 0 0 1
x 0 0 0 1
x 0 0 0 1
y 0 0 0 1
```

To see how this works, note that `mat[combs[k,], ]`

produces a matrix with various rows repeated in the order specified by the combinations:

```
> mat[combs[1,], ]
A B C D
w 0 0 1 1
w 0 0 1 1
w 0 0 1 1
x 0 1 0 1
x 0 1 0 1
y 0 0 1 1
> mat[combs[2,], ]
A B C D
x 0 1 0 1
y 0 0 1 1
z 0 0 0 1
y 0 0 1 1
z 0 0 0 1
z 0 0 0 1
```

To get exactly what the OP posted, we can modify the rownames using a second `combn()`

call:

```
> out <- mat[combs[1,], ] * mat[combs[2,], ]
> rownames(out) <- apply(combn(rownames(dat), 2), 2, paste, collapse = "")
> out
A B C D
wx 0 0 0 1
wy 0 0 1 1
wz 0 0 0 1
xy 0 0 0 1
xz 0 0 0 1
yz 0 0 0 1
```