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How do I loop over the inodes in the superblock of a FUSE filesystem? The documentation specifies nothing about this.

  • What do you mean to loop over the inodes? – kamae Jul 25 '11 at 16:38
  • What I mean is that I want to be able to have a pointer to each inode - possibly some kind of struct. – atx Jul 25 '11 at 23:36
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    FUSE is an interface, not a filesystem. The virtual filesystem represented by the FUSE backend may not have inodes or a superblock, and it may not represent files in an enumerable fashion at all. (For instance, it's easy to write a FUSE filesystem which contains every possible filename, with each file containing its name.) – duskwuff -inactive- Jul 30 '11 at 2:51
  • Is it possible to fake having an inode for each file and directory? That would be sufficient also. – atx Jul 30 '11 at 3:53
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    FUSE can do things which are very dangerous and cause the host to behave in dangerous ways. In particular, to be POSIX conformant, each file must have a unique dev_t, ino_t pair. This is key to being able to identify if 2 names or file descriptors refer to the same file. A filesystem where every possible filename exists has more files than possible ino_t values and thus there's a big problem. Sadly, it seems fashionable among Linux kernel folks to give people enough rope to blow up the universe... – R.. GitHub STOP HELPING ICE Aug 3 '11 at 2:34
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You can iterate over the visible ones (those with entries), by calling nftw() at the mount point of an active FUSE instance. The callback you provide will be given the path and struct stat for each entry in the filesystem. You can interact with the corresponding inodes via systems calls to the returned paths.

  • Make that nftw. It's slightly more flexible and meant to obsolete plain ftw, I believe. – R.. GitHub STOP HELPING ICE Aug 4 '11 at 0:49
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FUSE is not a file system, and does not contain traditional inodes. It is better to think of it as implementing the reverse of what the UNIX file system API provides. For instance, when you open a file, you generate a file open system call. The kernel then takes that system call and returns a file.

What FUSE does is from the kernel it redirects that system call to the FUSE application which is back in user space. The application then decides how to respond to that system call and returns something to the kernel. The kernel then passes that response back to the original calling application.

In many cases, when you mount something with FUSE, you are not mounting a physical medium. When you open a file in a FUSE file system, it is probably going to create a temporary file on a real file system somewhere, copy data to that file, and then redirect most file operation calls on the FUSE file to the temporary file it created.

Most FUSE application implement stat, and provide most of the information that a real INODE structure would have, however, that information would not in general have a pointer aspect to it.

From a technical standpoint, you could implement something like EXT3 in FUSE, where it would take as a mount argument the EXT3 file system to mount. In that case, you could imagine real INODES, potentially with actual INODE pointers. However, that implementation of EXT3 would probably be fairly unpopular as every file system call would involve going from userspace to kernel to FUSE userspace to kernel to FUSE userspace to kernel and then finally back to your application. FUSE makes a lot more sense for file systems where performance is not important.

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