You could scan the edge list, swapping indexes so that for each `(i, j)`

it is always true that `i < j`

. This you do in O(N).

You also need a sorted edge list, and this is O(N log N). Once you have the sorted edge list, you can store it in Symmetric-CSR format. When reading cell `(y,x)`

, if `y > x`

then you swap `y`

and `x`

. Then you read `row_pointer[y]`

and `row_pointer[y+1]`

, let them be `Pa`

and `Pb`

, and start scanning `CSR[i]`

for i between `Pa`

and `Pb`

; you exit if `x`

>= `CSR[i]`

(found or not found depending if = or >), or if `i == Pb`

(not found).

You could also generate a second edge list where `j > i`

, and sort it too. At this point, you can scan both edges at the same time, and generate a CSR list without need of symmetry.

```
j0 = j1 = N+1
# i-th row:
# we are scanning NodesIJ[ij] and NodesJI[ji].
If NodesIJ[ij][0] == i
j0 = NodesIJ[ij][1]
If NodesJI[ji][0] == i
j1 = NodesIJ[ji][1]
if (j0 < j1)
j = j0
j0 = N+1
ij++
else
if (j1 == N+1)
# Nothing more on this row, and j0 and j1 are both N+1.
i++;
continue
j = j1
j1 = N+1
ji++
# We may now store (i,j) in CSR
if (-1 == row_ind[i])
row_ind[i] = csr;
col_ind[csr++] = j
```

The algorithm above can be improved observing that for any given `i`

, if there exist `p`

and `q`

such that `NodesIJ[p] = i`

and `NodesJI[q] = i`

, it will always be `NodesIJ[p][1] > NodesJI[q][1]`

since the former list describes the upper right triangular and the latter describes the lower left. So we can scan NodesJI until `NodesJI[p][0]`

is i, and then go on to `NodesJI[q]`

.

We can also avoid always checking for `row_ind`

initialization noting that if `csr`

index does not change, then the row is empty and the corresponding value can be -1 (or N+1, or whatever "invalid" value we want), otherwise it has to be the previous value of `csr`

.

```
scsr = csr;
while NodesIJ[ij][0] == i
col_ind[csr++] = NodesIJ[ij++][1]
while NodesJI[ji][0] == i
col_ind[csr++] = NodesJI[ji++][1]
row_ind[i++] = (csr == scsr) ? -1 : scsr;
```

The above runs in O(N log N).

An alternative is to allocate the matrix, decode the edge list into the matrix and parse it into a CSR. This is O(N), but may require too much memory; for a list size of N, you may have up to N^2 (or (N/a)^2, a being the average number of connections) cells. A list of millions of edges might easily require tens of gigabytes of storage.