This is the implementation that I came up with:

```
import numpy as np
class NoBroadcastArray(np.ndarray):
def __new__(cls, input_array):
return np.asarray(input_array).view(cls)
def __setitem__(self, args, value):
value = np.asarray(value, dtype=self.dtype)
expected_size = self._compute_expected_size(args)
if expected_size != value.size:
raise ValueError(("assigned value size {} does not match expected size {} "
"in non-broadcasting assignment".format(value.size, expected_size)))
return super(NoBroadcastArray, self).__setitem__(args, value)
def _compute_expected_size(self, args):
if not isinstance(args, tuple):
args = (args,)
# Iterate through indexing arguments
arr_dim = 0
ellipsis_dim = len(args)
i_arg = 0
size = 1
adv_idx_shapes = []
for i_arg, arg in enumerate(args):
if isinstance(arg, slice):
size *= self._compute_slice_size(arg, arr_dim)
arr_dim += 1
elif arg is Ellipsis:
ellipsis_dim = arr_dim
break
elif arg is np.newaxis:
pass
else:
adv_idx_shapes.append(np.shape(arg))
arr_dim += 1
# Go backwards from end after ellipsis if necessary
arr_dim = -1
for arg in args[:i_arg:-1]:
if isinstance(arg, slice):
size *= self._compute_slice_size(arg, arr_dim)
arr_dim -= 1
elif arg is Ellipsis:
raise IndexError("an index can only have a single ellipsis ('...')")
elif arg is np.newaxis:
pass
else:
adv_idx_shapes.append(np.shape(arg))
arr_dim -= 1
# Include dimensions under ellipsis
ellipsis_end_dim = arr_dim + self.ndim + 1
if ellipsis_dim > ellipsis_end_dim:
raise IndexError("too many indices for array")
for i_dim in range(ellipsis_dim, ellipsis_end_dim):
size *= self.shape[i_dim]
size *= NoBroadcastArray._advanced_index_size(adv_idx_shapes)
return size
def _compute_slice_size(self, slice, axis):
if axis >= self.ndim or axis < -self.ndim:
raise IndexError("too many indices for array")
size = self.shape[axis]
start = slice.start
stop = slice.stop
step = slice.step if slice.step is not None else 1
if step == 0:
raise ValueError("slice step cannot be zero")
if start is not None:
start = start if start >= 0 else start + size
start = min(max(start, 0), size - 1)
else:
start = 0 if step > 0 else size - 1
if stop is not None:
stop = stop if stop >= 0 else stop + size
stop = min(max(stop, 0), size)
else:
stop = size if step > 0 else -1
slice_size = stop - start
if step < 0:
slice_size = -slice_size
step = -step
slice_size = ((slice_size - 1) // step + 1 if slice_size > 0 else 0)
return slice_size
@staticmethod
def _advanced_index_size(shapes):
size = 1
if not shapes:
return size
dims = max(len(s) for s in shapes)
for dim_sizes in zip(*(s[::-1] + (1,) * (dims - len(s)) for s in shapes)):
d = 1
for dim_size in dim_sizes:
if dim_size != 1:
if d != 1 and dim_size != d:
raise IndexError("shape mismatch: indexing arrays could not be "
"broadcast together with shapes " + " ".join(map(str, shapes)))
d = dim_size
size *= d
return size
```

You would use it like this:

```
import numpy as np
a = NoBroadcastArray(np.arange(24).reshape(4, 3, 2, 1))
a[:] = 1
# ValueError: assigned value size 1 does not match expected size 24 in non-broadcasting assignment
a[:, ..., [0, 1], :] = 1
# ValueError: assigned value size 1 does not match expected size 16 in non-broadcasting assignment
a[[[0, 1], [2, 3]], :, [1, 0]] = 1
# ValueError: assigned value size 1 does not match expected size 12 in non-broadcasting assignment
```

This only checks that the size of the given value matches the index, but it does not do any reshaping of the value, so that still works as usual with NumPy (i.e. additional outer dimensions can be added).