The idea of using a number to order the modifications is taken from Dukeling's post.

We will need 2 maps and 4 binary indexed tree (BIT, a.k.a. Fenwick Tree): 1 map and 2 BITs for rows, and 1 map and 2 BITs for columns. Let us call them `m_row`

, `f_row[0]`

, and `f_row[1]`

; `m_col`

, `f_col[0]`

and `f_col[1]`

respectively.

Map may be implemented with array, or tree like structure, or hashing. The 2 maps are used to store the last modification to a row/column. Since there can be at most 10^{5} modification, you may use that fact to save space from simple array implementation.

BIT has 2 operations:

`adjust(value, delta_freq)`

, which adjusts the frequency of the `value`

by `delta_freq`

amount.
`rsq(from_value, to_value)`

, (rsq stands for range sum query) which finds the sum of the all the frequencies from `from_value`

to `to_value`

inclusive.

Let us declare global variable: `version`

Let us define `numRow`

to be the number of rows in the 2D boolean matrix, and `numCol`

to be the number of columns in the 2D boolean matrix.

The BITs should have size of at least MAX_QUERY + 1, since it is used to count the number of changes to the rows and columns, which can be as many as the number of queries.

Initialization:

```
version = 1
# Map should return <0, 0> for rows or cols not yet
# directly updated by query
m_row = m_col = empty map
f_row[0] = f_row[1] = f_col[0] = f_col[1] = empty BIT
```

Update algorithm:

```
update(isRow, value, idx):
if (isRow):
# Since setting a row/column to a new value will reset
# everything done to it, we need to erase earlier
# modification to it.
# For example, turn on/off on a row a few times, then
# query some column
<prevValue, prevVersion> = m_row.get(idx)
if ( prevVersion > 0 ):
f_row[prevValue].adjust( prevVersion, -1 )
m_row.map( idx, <value, version> )
f_row[value].adjust( version, 1 )
else:
<prevValue, prevVersion> = m_col.get(idx)
if ( prevVersion > 0 ):
f_col[prevValue].adjust( prevVersion, -1 )
m_col.map( idx, <value, version> )
f_col[value].adjust( version, 1 )
version = version + 1
```

Count algorithm:

```
count(isRow, idx):
if (isRow):
# If this is row, we want to find number of reverse modifications
# done by updating the columns
<value, row_version> = m_row.get(idx)
count = f_col[1 - value].rsq(row_version + 1, version)
else:
# If this is column, we want to find number of reverse modifications
# done by updating the rows
<value, col_version> = m_col.get(idx)
count = f_row[1 - value].rsq(col_version + 1, version)
if (isRow):
if (value == 1):
return numRow - count
else:
return count
else:
if (value == 1):
return numCol - count
else:
return count
```

The complexity is logarithmic in worst case for both update and count.