This particular issue could be solved in most cases in a monolithic kernel. That it isn’t, is by design. But it’s a terrible design decision, because it can lead to situations where (for example) a zombie process locks a mount point and prevents unmounting because the kernel insists it’s still in use by the zombie process. Which the kernel provides no mechanism for terminating.
It is provable via experiment in Linux by use of fuse filesystems. Create a program that is guaranteed to become a zombie. Run it within a filesystem mounted by an in-kernel module, like a remote nfs mount. You now have a permanently mounted NFS mount point. Now, use mount something using fuse, say a WebDAV remote point. Run the same zombie process there. Again, the mount point is unmountable. Now, kill the fuse process itself. The mount point will be unmounted and disappear.
This is exactly how microkernels work. Every module is killable, crashable, upgradable - all without forcing a reboot or affecting any processes not using the module. And in a well-designed microkernel, even processes using the module can in many cases continue functioning as if the restarted kernel module never changed.
Fuse is really close to the capabilities of microkernels, except it’s only filesystems. In a microkernel, nearly everything is like fuse. A linux kernel compiled such that everything is a loadable module, and not hard linked into the kernel, is close to a microkernel, except without the benefits of actually being a microkernel.
Microkernels are better. Popularity does not prove superiority, except in the metric of popularity.
This particular issue could be solved in most cases in a monolithic kernel. That it isn’t, is by design. But it’s a terrible design decision, because it can lead to situations where (for example) a zombie process locks a mount point and prevents unmounting because the kernel insists it’s still in use by the zombie process. Which the kernel provides no mechanism for terminating.
It is provable via experiment in Linux by use of fuse filesystems. Create a program that is guaranteed to become a zombie. Run it within a filesystem mounted by an in-kernel module, like a remote nfs mount. You now have a permanently mounted NFS mount point. Now, use mount something using fuse, say a WebDAV remote point. Run the same zombie process there. Again, the mount point is unmountable. Now, kill the fuse process itself. The mount point will be unmounted and disappear.
This is exactly how microkernels work. Every module is killable, crashable, upgradable - all without forcing a reboot or affecting any processes not using the module. And in a well-designed microkernel, even processes using the module can in many cases continue functioning as if the restarted kernel module never changed.
Fuse is really close to the capabilities of microkernels, except it’s only filesystems. In a microkernel, nearly everything is like fuse. A linux kernel compiled such that everything is a loadable module, and not hard linked into the kernel, is close to a microkernel, except without the benefits of actually being a microkernel.
Microkernels are better. Popularity does not prove superiority, except in the metric of popularity.