# Efficiently merging two data frames on a non-trivial criteria

Answering this question last night, I spent a good hour trying to find a solution that didn't grow a `data.frame` in a for loop, without any success, so I'm curious if there's a better way to go about this problem.

The general case of the problem boils down to this:

• Merge two `data.frames`
• Entries in either `data.frame` can have 0 or more matching entries in the other.
• We only care about entries that have 1 or more matches across both.
• The match function is complex involving multiple columns in both `data.frame`s

For a concrete example I will use similar data to the linked question:

``````genes <- data.frame(gene       = letters[1:5],
chromosome = c(2,1,2,1,3),
start      = c(100, 100, 500, 350, 321),
end        = c(200, 200, 600, 400, 567))
markers <- data.frame(marker = 1:10,
chromosome = c(1, 1, 2, 2, 1, 3, 4, 3, 1, 2),
position   = c(105, 300, 96, 206, 150, 400, 25, 300, 120, 700))
``````

And our complex matching function:

``````# matching criteria, applies to a single entry from each data.frame
isMatch <- function(marker, gene) {
return(
marker\$chromosome == gene\$chromosome &
marker\$postion >= (gene\$start - 10) &
marker\$postion <= (gene\$end + 10)
)
}
``````

The output should look like an `sql` `INNER JOIN` of the two data.frames, for entries where `isMatch` is `TRUE`. I've tried to construct the two `data.frames` so that there can be 0 or more matches in the other `data.frame`.

The solution I came up with is as follows:

``````joined <- data.frame()
for (i in 1:nrow(genes)) {
# This repeated subsetting returns the same results as `isMatch` applied across
# the `markers` data.frame for each entry in `genes`.
matches <- markers[which(markers\$chromosome == genes[i, "chromosome"]),]
matches <- matches[which(matches\$pos >= (genes[i, "start"] - 10)),]
matches <- matches[which(matches\$pos <= (genes[i, "end"] + 10)),]
# matches may now be 0 or more rows, which we want to repeat the gene for:
if(nrow(matches) != 0) {
joined <- rbind(joined, cbind(genes[i,], matches[,c("marker", "position")]))
}
}
``````

Giving the results:

``````   gene chromosome start end marker position
1     a          2   100 200      3       96
2     a          2   100 200      4      206
3     b          1   100 200      1      105
4     b          1   100 200      5      150
5     b          1   100 200      9      120
51    e          3   321 567      6      400
``````

This is quite an ugly and clungy solution, but anything else I tried was met with failure:

• use of `apply`, gave me a `list` where each element was a matrix, with no way to `rbind` them.
• I can't specify the dimensions of `joined` first, because I don't know how many rows I will need in the end.

I'm sure I will come up with a problem of this general form in the future. So what's the correct way to solve this kind of problem?

-
When i run your code I get output (`joined`) that doesn't really make sense, can you show what you're expecting for the output from your demo? – alexwhan Sep 17 '13 at 2:55
Whoops! There was a bug (`>=` should have been `<=` in one instance). Fixed and updated with the output I get. – Scott Ritchie Sep 17 '13 at 3:05

A data table solution: a rolling join to fulfill the first inequality, followed by a vector scan to satisfy the second inequality. The join-on-first-inequality will have more rows than the final result (and therefore may run into memory issues), but it will be smaller than a straight-up merge in this answer.

``````require(data.table)

genes_start <- as.data.table(genes)
## create the start bound as a separate column to join to
genes_start[,`:=`(start_bound = start - 10)]
setkey(genes_start, chromosome, start_bound)

markers <- as.data.table(markers)
setkey(markers, chromosome, position)

new <- genes_start[
##join genes to markers
markers,
##rolling the last key column of genes_start (start_bound) forward
##to match the last key column of markers (position)
roll = Inf,
##inner join
nomatch = 0
##rolling join leaves positions column from markers
##with the column name from genes_start (start_bound)
##now vector scan to fulfill the other criterion
][start_bound <= end + 10]
##change names and column order to match desired result in question
setnames(new,"start_bound","position")
setcolorder(new,c("chromosome","gene","start","end","marker","position"))
# chromosome gene start end marker position
# 1:          1    b   100 200      1      105
# 2:          1    b   100 200      9      120
# 3:          1    b   100 200      5      150
# 4:          2    a   100 200      3       96
# 5:          2    a   100 200      4      206
# 6:          3    e   321 567      6      400
``````

One could do a double join, but as it involves re-keying the data table before the second join, I don't think that it will be faster than the vector scan solution above.

``````##makes a copy of the genes object and keys it by end
genes_end <- as.data.table(genes)
genes_end[,`:=`(end_bound = end + 10, start = NULL, end = NULL)]
setkey(genes_end, chromosome, gene, end_bound)

## as before, wrapped in a similar join (but rolling backwards this time)
new_2 <- genes_end[
setkey(
genes_start[
markers,
roll = Inf,
nomatch = 0
], chromosome, gene, start_bound),
roll = -Inf,
nomatch = 0
]
setnames(new2, "end_bound", "position")
``````
-
You absolutely win this. What took 29 minutes with `sqldf` on my full dataset takes just under 2 seconds with `data.table`! And you're right about the second code block -- it's almost twice as slow at just under 4 seconds. – Scott Ritchie Sep 20 '13 at 1:33
Are the end results identical? I only checked on the test dataset, so I don't know whether it is good for your full dataset. – Blue Magister Sep 20 '13 at 2:17
I didn't check exactly, but the number of rows came out roughly the same, so I assume so. – Scott Ritchie Sep 20 '13 at 2:38
Although I may get a speed increase in `sqldf` if I create similar `start_bound` and `end_bound` columns. – Scott Ritchie Sep 20 '13 at 2:39
+1 I haven't fully followed but can't `roll` be set to `-10` and `+10` directly? – Matt Dowle Sep 20 '13 at 11:28

I dealt with a very similar problem myself by doing the merge, and sorting out which rows satisfy the condition afterwards. I don't claim that this is a universal solution, if you're dealing with large datasets where there will be few entries that match the condition, this will likely be inefficient. But to adapt it to your data:

``````joined.raw <- merge(genes, markers)
joined <- joined.raw[joined.raw\$position >= (joined.raw\$start -10) & joined.raw\$position <= (joined.raw\$end + 10),]
joined
#    chromosome gene start end marker position
# 1           1    b   100 200      1      105
# 2           1    b   100 200      5      150
# 4           1    b   100 200      9      120
# 10          2    a   100 200      4      206
# 11          2    a   100 200      3       96
# 16          3    e   321 567      6      400
``````
-
Much more elegant! But you're right, creating the whole merged `data.frame` is probably not ideal. – Scott Ritchie Sep 17 '13 at 5:16
Yes, I agree - this is only convenient depending on the data – alexwhan Sep 17 '13 at 6:31

Another answer I've come up with using the `sqldf` package.

``````sqldf("SELECT gene, genes.chromosome, start, end, marker, position
FROM genes JOIN markers ON genes.chromosome = markers.chromosome
WHERE position >= (start - 10) AND position <= (end + 10)")
``````

Using `microbenchmark` it performs comparably to @alexwhan's `merge` and `[` method.

``````> microbenchmark(alexwhan, sql)
Unit: nanoseconds
expr min    lq median  uq  max neval
alexwhan 435 462.5  468.0 485 2398   100
sql 422 456.5  466.5 498 1262   100
``````

I've also attempted to test both functions on some real data of the same format I have lying around (35,000 rows for `genes`, 2,000,000 rows for `markers`, with the `joined` output coming to 480,000 rows).

Unfortunately `merge` seems unable to handle this much data, falling over at `joined.raw <- merge(genes, markers)` with an error (which i don't get if reduce the number of rows):

``````Error in merge.data.frame(genes, markers) :
negative length vectors are not allowed
``````

While the `sqldf` method runs successfully in 29 minutes.

-
Well, someone clearly needs to run `microbenchmark` on this answer vs. @alexwhan 's `[<-` approach. :-) – Carl Witthoft Sep 17 '13 at 11:40
Looks like I'll need a bigger example `data.frame` to measure the three methods! – Scott Ritchie Sep 17 '13 at 21:59
Im running them both on a real dataset (35k rows in genes, 2mil in markers) of that format to see what happens – Scott Ritchie Sep 17 '13 at 22:41

After almost one year regarding to this problem you solved for me... now i spent some time to deal with this using another way by awk....

``````awk 'FNR==NR{a[NR]=\$0;next}{for (i in a){split(a[i],x," ");if (x[2]==\$2 && x[3]-10 <=\$3 && x[4]+10 >=\$3)print x[1],x[2],x[3],x[4],\$0}}' gene.txt makers.txt > genesnp.txt
``````

which produce the kind of same results:

``````b   1   100 200 1   1   105
a   2   100 200 3   2   96
a   2   100 200 4   2   206
b   1   100 200 5   1   150
e   3   321 567 6   3   400
b   1   100 200 9   1   120
``````
-