I believe this can be solved with `igraph`

in a similar way as in “recursive” self join in data.table but without the calculation.

The difficulty here is that there are separate graphs for each `Item`

. My approach is to split the data frame into a list of graphs. There might be more concise solutions which use the `type`

vertex attribute.

However, the code below creates the expected result:

```
library(igraph)
library(data.table)
library(magrittr)
lapply(
lapply(split(lctolc, lctolc$Item), function(x) graph.data.frame(x[, 2:3])),
function(x) lapply(
V(x)[degree(x, mode = "in") == 0],
function(s) all_simple_paths(x, from = s,
to = V(x)[degree(x, mode = "out") == 0]) %>%
lapply(
function(y) as.data.table(t(names(y))) %>% setnames(paste0("LC", seq_along(.)))
) %>%
rbindlist(fill = TRUE)
) %>% rbindlist(fill = TRUE)
) %>% rbindlist(fill = TRUE, idcol = "Item")
```

```
Item LC1 LC2 LC3 LC4
1: 8T4121 MN12 AB12 BC34 <NA>
2: 8T4121 MW92 WK14 RS11 OY01
3: 8T4121 MW92 WK14 RM11 <NA>
4: AB7651 MW92 RS11 OY01 <NA>
```

### Explanation

The `igraph`

package is a good choice for questions like this.

However, we need to treat the graph of each `Item`

separately. This is achieved by splitting the data.frame and creating a list of graphs by

```
lg <- lapply(split(lctolc, lctolc$Item), function(x) graph.data.frame(x[, 2:3]))
```

which returns

```
lg
```

```
$`8T4121`
IGRAPH 8eb2bcc DN-- 8 6 --
+ attr: name (v/c)
+ edges from 8eb2bcc (vertex names):
[1] AB12->BC34 MN12->AB12 MW92->WK14 WK14->RM11 WK14->RS11 RS11->OY01
$AB7651
IGRAPH 7cd75e7 DN-- 3 2 --
+ attr: name (v/c)
+ edges from 7cd75e7 (vertex names):
[1] MW92->RS11 RS11->OY01
```

or, visualised by two separate plots.

```
lapply(seq_along(lg), function(i) plot(lg[[i]], main = names(lg)[i]))
```

Now, the function `all_simple_paths()`

lists simple paths from one source vertex to another vertex or vertices where a path is simple if the vertices are visited once at most. To use the function we need to determine the start nodes and all end nodes. This is achieved by

```
V(x)[degree(x, mode = "in") == 0] # start nodes
V(x)[degree(x, mode = "out") == 0] # end nodes
```

The `degree()`

function returns the number of in-coming or out-going edges, resp.

For our example dataset we get

```
lapply(lg, function(x) V(x)[degree(x, mode = "in") == 0]) # start nodes
```

```
$`8T4121`
+ 2/8 vertices, named, from 8eb2bcc:
[1] MN12 MW92
$AB7651
+ 1/3 vertex, named, from 7cd75e7:
[1] MW92
```

```
lapply(lg, function(x) V(x)[degree(x, mode = "out") == 0]) # end nodes
```

```
$`8T4121`
+ 3/8 vertices, named, from 8eb2bcc:
[1] BC34 RM11 OY01
$AB7651
+ 1/3 vertex, named, from 7cd75e7:
[1] OY01
```

Now, we loop through all start nodes of each graph and determine all simple paths. The result is a list, again. For each list item, the node names are extracted and reshaped to a data.table in wide format. The columns are renamed to `LC1`

, `LC2`

, etc.

In each step, we get a list of data.tables which are combined by `rbindlist()`

. The `fill`

parameter is required as the number of columns may vary. The final call to rbindlist() uses the `idcol`

parameter to mark the rows which are associated with `Item`

.

### Data

The sample dataset has been amended to include the cases from OP's comments here and here.

```
library(data.table)
lctolc <- fread("
Item LC ToLC
8T4121 AB12 BC34
8T4121 MN12 AB12
8T4121 MW92 WK14
8T4121 WK14 RM11
8T4121 WK14 RS11
8T4121 RS11 OY01
AB7651 MW92 RS11
AB7651 RS11 OY01",
data.table = FALSE)
```