### Approach #1

Going by the new-found information picked up off `OP's comments`

that states only `y`

is changing in real-time, we can pre-process lots of stuffs around `x`

and hence do much better. We will create a hashing array that will store stepped masks. For the part that involves `y`

, we will simply index into the hashing array with the indices obtained off `searchsorted`

which will approximate the final mask array. A final step of assigning the remaining bools could be offloaded to numba given its ragged nature. This should also be beneficial if we decide to scale up the lengths of `y`

.

Let's look at the implementation.

**Pre-processing with **`x`

:

```
sidx = x.argsort()
ssidx = x.argsort().argsort()
# Choose a scale factor.
# 1. A small one would store more mapping info, hence faster but occupy more mem
# 2. A big one would store less mapping info, hence slower, but memory efficient.
scale_factor = 100
mapar = np.arange(0,len(x),scale_factor)[:,None] > ssidx
```

**Remaining steps with **`y`

:

```
import numba as nb
@nb.njit(parallel=True,fastmath=True)
def array_masking3(out, starts, idx, sidx):
N = len(out)
for i in nb.prange(N):
for j in nb.prange(starts[i], idx[i]):
out[i,sidx[j]] = True
return out
idx = np.searchsorted(x,y,sorter=sidx)
s0 = idx//scale_factor
starts = s0*scale_factor
out = mapar[s0]
out = array_masking3(out, starts, idx, sidx)
```

**Benchmarking**

```
In [2]: x = np.random.rand(1000000)
...: y = np.random.rand(200)
In [3]: ## Pre-processing step with "x"
...: sidx = x.argsort()
...: ssidx = x.argsort().argsort()
...: scale_factor = 100
...: mapar = np.arange(0,len(x),scale_factor)[:,None] > ssidx
In [4]: %%timeit
...: idx = np.searchsorted(x,y,sorter=sidx)
...: s0 = idx//scale_factor
...: starts = s0*scale_factor
...: out = mapar[s0]
...: out = array_masking3(out, starts, idx, sidx)
41 ms ± 141 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
# A 1/10th smaller hashing array has similar timings
In [7]: scale_factor = 1000
...: mapar = np.arange(0,len(x),scale_factor)[:,None] > ssidx
In [8]: %%timeit
...: idx = np.searchsorted(x,y,sorter=sidx)
...: s0 = idx//scale_factor
...: starts = s0*scale_factor
...: out = mapar[s0]
...: out = array_masking3(out, starts, idx, sidx)
40.6 ms ± 196 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
# @silgon's soln
In [5]: %timeit x[np.newaxis,:] < y[:,np.newaxis]
138 ms ± 896 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
```

### Approach #2

This borrowed a good part from `OP's solution`

.

```
import numba as nb
@nb.njit(parallel=True)
def array_masking2(mask1D, mask_out, idx, pt):
n = len(idx)
for j in nb.prange(len(pt)):
if mask1D[j]:
for i in nb.prange(pt[j],n):
mask_out[j, idx[i]] = False
else:
for i in nb.prange(pt[j]):
mask_out[j, idx[i]] = True
return mask_out
def app2(idx, pt):
m,n = len(pt), len(idx)
mask1 = pt>len(x)//2
mask2 = np.broadcast_to(mask1[:,None], (m,n)).copy()
return array_masking2(mask1, mask2, idx, pt)
```

So, the idea is once, we have larger than half of indices to be set `True`

, we switch over to set `False`

instead after pre-assigning those rows as all `True`

. This results in lesser memory accesses and hence some noticeable performance boost.

### Benchmarking

OP's solution :

```
@nb.njit(parallel=True,fastmath=True)
def array_masking(mask, idx, pt):
for j in nb.prange(pt.shape[0]):
for i in nb.prange(pt[j]):
mask[j, idx[i]] = True
return mask
def app1(idx, pt):
m,n = len(pt), len(idx)
mask = np.zeros((m, n), dtype='bool')
return array_masking(mask, idx, pt)
```

Timings -

```
In [5]: np.random.seed(0)
...: x = np.random.rand(1000000)
...: y = np.random.rand(200)
In [6]: %timeit app1(idx, pt)
264 ms ± 8.91 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
In [7]: %timeit app2(idx, pt)
165 ms ± 3.43 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)
```