**Approach #1: No bad entries in **`d`

Here's one NumPy based method -

```
def assign_val(df, d, newval=1):
# Get d-rows,cols as arrays for efficient usage latet on
di,dc = np.array([j[0] for j in d]), np.array([j[1] for j in d])
# Get col and index data
i,c = df.index.values.astype(di.dtype),df.columns.values.astype(dc.dtype)
# Locate row indexes from d back to df
sidx_i = i.argsort()
I = sidx_i[np.searchsorted(i,di,sorter=sidx_i)]
# Locate column indexes from d back to df
sidx_c = c.argsort()
C = sidx_c[np.searchsorted(c,dc,sorter=sidx_c)]
# Assign into array data with new values
df.values[I,C] = newval
# Use df.to_numpy(copy=False)[I,C] = newval on newer pandas versions
return df
```

Sample run -

```
In [21]: df = pd.DataFrame(np.zeros((2,2)), columns=['y','x'], index=['b','a'])
In [22]: d = [("a", "x"), ("b", "y"), ('a','y')]
In [23]: assign_val(df, d, newval=1)
Out[23]:
y x
b 1.0 0.0
a 1.0 1.0
```

**Approach #2: Generic one**

If there are any *bad* entries in `d, we need to filter out those. So, a modified one for that generic case would be -

```
def ssidx(i,di):
sidx_i = i.argsort()
idx_i = np.searchsorted(i,di,sorter=sidx_i)
invalid_mask = idx_i==len(sidx_i)
idx_i[invalid_mask] = 0
I = sidx_i[idx_i]
invalid_mask |= i[I]!=di
return I,invalid_mask
# Get d-rows,cols as arrays for efficient usage latet on
di,dc = np.array([j[0] for j in d]), np.array([j[1] for j in d])
# Get col and index data
i,c = df.index.values.astype(di.dtype),df.columns.values.astype(dc.dtype)
# Locate row indexes from d back to df
I,badmask_I = ssidx(i,di)
# Locate column indexes from d back to df
C,badmask_C = ssidx(c,dc)
badmask = badmask_I | badmask_C
goodmask = ~badmask
df.values[I[goodmask],C[goodmask]] = newval
```