Leveraging @RichardScriven's insight that `adist`

could be used (it calculates "approximate string distance". I made a function to be more comprehensive. Please note `"trafos"`

stands for the "transformations" used to determine the "distance" between two strings (example at bottom)

**EDIT** This answer can produce wrong/unexpected results; as pointed out by @wdkrnls:

I ran your function against "apple" and "big apple bagels" and it returned "appl". I would have expected "apple".

See the explanation below for the wrong result. We start with a function to get the `longest_string`

in a list:

```
longest_string <- function(s){return(s[which.max(nchar(s))])}
```

Then we can use @RichardSriven's work and the `stringi`

library:

```
library(stringi)
lcsbstr <- function(a,b) {
sbstr_locations<- stri_locate_all_regex(drop(attr(adist(a, b, counts=TRUE), "trafos")), "M+")[[1]]
cmn_sbstr<-stri_sub(longest_string(c(a,b)), sbstr_locations)
longest_cmn_sbstr <- longest_string(cmn_sbstr)
return(longest_cmn_sbstr)
}
```

Or we can rewrite our code to *avoid the use of any external libraries* (still using R's native `adist`

function):

```
lcsbstr_no_lib <- function(a,b) {
matches <- gregexpr("M+", drop(attr(adist(a, b, counts=TRUE), "trafos")))[[1]];
lengths<- attr(matches, 'match.length')
which_longest <- which.max(lengths)
index_longest <- matches[which_longest]
length_longest <- lengths[which_longest]
longest_cmn_sbstr <- substring(longest_string(c(a,b)), index_longest , index_longest + length_longest - 1)
return(longest_cmn_sbstr )
}
```

Both above functions identify only `'hello '`

as the longest common substring, instead of '`hello r'`

(regardless of which argument is the longer of the two):

```
identical('hello',
lcsbstr_no_lib('hello', 'hello there'),
lcsbstr( 'hello', 'hello there'),
lcsbstr_no_lib('hello there', 'hello'),
lcsbstr( 'hello there', 'hello'))
```

**LAST EDIT**
*Note some odd behavior* with this result:

```
lcsbstr('hello world', 'hello')
#[1] 'hell'
```

I was expecting `'hello'`

, but since the transformation actually moves (via deletion) the "o" in w**o**rld to become the "o" in hell**o** -- only the *hell* part is considered a match according to the `M`

:

```
drop(attr(adist('hello world', 'hello', counts=TRUE), "trafos"))
#[1] "MMMMDDDMDDD"
#[1] vvvv v
#[1] "hello world"
```

This behavior is observed using this Levenstein tool -- it gives two possible solutions, equivalent to these two transformations

```
#[1] "MMMMDDDMDDD"
#[1] "MMMMMDDDDDD"
```

I don't know if we can configure `adist`

to prefer one solution over another? (the transformations have the same "weight" -- the same number of "M" and "D"'s -- don't know how to prefer the transformations with the greater number of **consecutive** `M`

)

Finally, don't forget adist allows you to pass in `ignore.case = TRUE`

(`FALSE`

is the default)

- Key to the
`"trafos"`

property of `adist`

; the "transformations" to get from one string to another:

the transformation sequences are returned as the "trafos" attribute of the return value, as character strings with elements `M`

, `I`

, `D`

and `S`

indicating a match, insertion, deletion and substitution

`LCS`

function doesn’t find the longest common substring, it finds the longest commonsubsequence– hence the result you are getting. That’s the definition of a subsequence. These problems are related but have quite different solutions, and the longest commonsubsequenceproblem is a more classical problem in computer science, and hence is the one more often implemented. – Konrad Rudolph Feb 1 '15 at 14:17