If you only want degree distributions, you likely don't need a graph package at all. I recommend the bigtablulate package so that

- your R objects are file backed so that you aren't limited by RAM
- you can parallelize the degree computation using
`foreach`

Check out their website for more details. To give a quick example of this approach, let's first create an example with an edgelist involving 1 million edges among 1 million nodes.

```
set.seed(1)
N <- 1e6
M <- 1e6
edgelist <- cbind(sample(1:N,M,replace=TRUE),
sample(1:N,M,replace=TRUE))
colnames(edgelist) <- c("sender","receiver")
write.table(edgelist,file="edgelist-small.csv",sep=",",
row.names=FALSE,col.names=FALSE)
```

I next concatenate this file 10 times to make the example a bit bigger.

```
system("
for i in $(seq 1 10)
do
cat edgelist-small.csv >> edgelist.csv
done")
```

Next we load the `bigtabulate`

package and read in the text file with our edgelist. The command `read.big.matrix()`

creates a file-backed object in R.

```
library(bigtabulate)
x <- read.big.matrix("edgelist.csv", header = FALSE,
type = "integer",sep = ",",
backingfile = "edgelist.bin",
descriptor = "edgelist.desc")
nrow(x) # 1e7 as expected
```

We can compute the outdegrees by using `bigtable()`

on the first column.

```
outdegree <- bigtable(x,1)
head(outdegree)
```

Quick sanity check to make sure table is working as expected:

```
# Check table worked as expected for first "node"
j <- as.numeric(names(outdegree[1])) # get name of first node
all.equal(as.numeric(outdegree[1]), # outdegree's answer
sum(x[,1]==j)) # manual outdegree count
```

To get indegree, just do `bigtable(x,2)`

.