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+# Foreword
+
+This document describes an on-going project to support FUSE filesystems within
+the sentry. This is intended to become the final documentation for this
+subsystem, and is therefore written in the past tense. However FUSE support is
+currently incomplete and the document will be updated as things progress.
+
+# FUSE: Filesystem in Userspace
+
+The sentry supports dispatching filesystem operations to a FUSE server,
+allowing FUSE filesystem to be used with a sandbox.
+
+## Overview
+
+FUSE has two main components:
+
+1. A client kernel driver (canonically `fuse.ko` in Linux), which forwards
+ filesystem operations (usually initiated by syscalls) to the server.
+
+2. A server, which is a userspace daemon that implements the actual filesystem.
+
+The sentry implements the client component, which allows a server daemon
+running within the sandbox to implement a filesystem within the sandbox.
+
+A FUSE filesystem is initialized with `mount(2)`, typically with the help of a
+utility like `fusermount(1)`. Various mount options exist for establishing
+ownership and access permissions on the filesystem, but the most important mount
+option is a file descriptor used to establish communication between the client
+and server.
+
+The FUSE device FD is obtained by opening `/dev/fuse`. During regular operation,
+the client and server use the FUSE protocol described in `fuse(4)` to service
+filesystem operations. See the "Protocol" section below for more
+information about this protocol. The core of the sentry support for FUSE is the
+client-side implementation of this protocol.
+
+## FUSE in the Sentry
+
+The sentry's FUSE client targets VFS2 and has the following components:
+
+- An implementation of `/dev/fuse`.
+
+- A VFS2 filesystem for mapping syscalls to FUSE ops. Since we're targeting
+ VFS2, one point of contention may be the lack of inodes in VFS2. We can
+ tentatively implement a kernfs-based filesystem to bridge the gap in APIs. The
+ kernfs base functionality can serve the role of the Linux inode cache and, the
+ filesystem can map VFS2 syscalls to kernfs inode operations; see the
+ `kernfs.Inode` interface.
+
+The FUSE protocol lends itself well to marshaling with `go_marshal`. The
+various request and response packets can be defined in the ABI package and
+converted to and from the wire format using `go_marshal`.
+
+### Design Goals
+
+- While filesystem performance is always important, the sentry's FUSE support is
+ primarily concerned with compatibility, with performance as a secondary
+ concern.
+
+- Avoiding deadlocks from a hung server daemon.
+
+- Consider the potential for denial of service from a malicious server
+ daemon. Protecting itself from userspace is already a design goal for the
+ sentry, but needs additional consideration for FUSE. Normally, an operating
+ system doesn't rely on userspace to make progress with filesystem
+ operations. Since this changes with FUSE, it opens up the possibility of
+ creating a chain of dependencies controlled by userspace, which could affect
+ an entire sandbox. For example: a FUSE op can block a syscall, which could be
+ holding a subsystem lock, which can then block another task goroutine.
+
+### Milestones
+
+Below are some broad goals to aim for while implementing FUSE in the sentry.
+Many FUSE ops can be grouped into broad categories of functionality, and most
+ops can be implemented in parallel.
+
+#### Minimal client that can mount a trivial FUSE filesystem.
+
+- Implement `/dev/fuse`.
+
+- Implement basic FUSE ops like `FUSE_INIT`, `FUSE_DESTROY`.
+
+#### Read-only mount with basic file operations
+
+- Implement the majority of file, directory and file descriptor FUSE ops. For
+ this milestone, we can skip uncommon or complex operations like mmap, mknod,
+ file locking, poll, and extended attributes. We can stub these out along with
+ any ops that modify the filesystem. The exact list of required ops are to be
+ determined, but the goal is to mount a real filesystem as read-only, and be
+ able to read contents from the filesystem in the sentry.
+
+#### Full read-write support
+
+- Implement the remaining FUSE ops and decide if we can omit rarely used
+ operations like ioctl.
+
+# Appendix
+
+## FUSE Protocol
+
+The FUSE protocol is a request-response protocol. All requests are initiated by
+the client. The wire-format for the protocol is raw c structs serialized to
+memory.
+
+All FUSE requests begin with the following request header:
+
+```c
+struct fuse_in_header {
+ uint32_t len; // Length of the request, including this header.
+ uint32_t opcode; // Requested operation.
+ uint64_t unique; // A unique identifier for this request.
+ uint64_t nodeid; // ID of the filesystem object being operated on.
+ uint32_t uid; // UID of the requesting process.
+ uint32_t gid; // GID of the requesting process.
+ uint32_t pid; // PID of the requesting process.
+ uint32_t padding;
+};
+```
+
+The request is then followed by a payload specific to the `opcode`.
+
+All responses begin with this response header:
+
+```c
+struct fuse_out_header {
+ uint32_t len; // Length of the response, including this header.
+ int32_t error; // Status of the request, 0 if success.
+ uint64_t unique; // The unique identifier from the corresponding request.
+};
+```
+
+The response payload also depends on the request `opcode`. If `error != 0`, the
+response payload must be empty.
+
+### Operations
+
+The following is a list of all FUSE operations used in `fuse_in_header.opcode`
+as of Linux v4.4, and a brief description of their purpose. These are defined in
+`uapi/linux/fuse.h`. Many of these have a corresponding request and response
+payload struct; `fuse(4)` has details for some of these. We also note how these
+operations map to the sentry virtual filesystem.
+
+#### FUSE meta-operations
+
+These operations are specific to FUSE and don't have a corresponding action in a
+generic filesystem.
+
+- `FUSE_INIT`: This operation initializes a new FUSE filesystem, and is the
+ first message sent by the client after mount. This is used for version and
+ feature negotiation. This is related to `mount(2)`.
+- `FUSE_DESTROY`: Teardown a FUSE filesystem, related to `unmount(2)`.
+- `FUSE_INTERRUPT`: Interrupts an in-flight operation, specified by the
+ `fuse_in_header.unique` value provided in the corresponding request
+ header. The client can send at most one of these per request, and will enter
+ an uninterruptible wait for a reply. The server is expected to reply promptly.
+- `FUSE_FORGET`: A hint to the server that server should evict the indicate node
+ from any caches. This is wired up to `(struct super_operations).evict_inode`
+ in Linux, which is in turned hooked as the inode cache shrinker which is
+ typically triggered by system memory pressure.
+- `FUSE_BATCH_FORGET`: Batch version of `FUSE_FORGET`.
+
+#### Filesystem Syscalls
+
+These FUSE ops map directly to an equivalent filesystem syscall, or family of
+syscalls. The relevant syscalls have a similar name to the operation, unless
+otherwise noted.
+
+Node creation:
+
+- `FUSE_MKNOD`
+- `FUSE_MKDIR`
+- `FUSE_CREATE`: This is equivalent to `open(2)` and `creat(2)`, which
+ atomically creates and opens a node.
+
+Node attributes and extended attributes:
+
+- `FUSE_GETATTR`
+- `FUSE_SETATTR`
+- `FUSE_SETXATTR`
+- `FUSE_GETXATTR`
+- `FUSE_LISTXATTR`
+- `FUSE_REMOVEXATTR`
+
+Node link manipulation:
+
+- `FUSE_READLINK`
+- `FUSE_LINK`
+- `FUSE_SYMLINK`
+- `FUSE_UNLINK`
+
+Directory operations:
+
+- `FUSE_RMDIR`
+- `FUSE_RENAME`
+- `FUSE_RENAME2`
+- `FUSE_OPENDIR`: `open(2)` for directories.
+- `FUSE_RELEASEDIR`: `close(2)` for directories.
+- `FUSE_READDIR`
+- `FUSE_READDIRPLUS`
+- `FUSE_FSYNCDIR`: `fsync(2)` for directories.
+- `FUSE_LOOKUP`: Establishes a unique identifier for a FS node. This is
+ reminiscent of `VirtualFilesystem.GetDentryAt` in that it resolves a path
+ component to a node. However the returned identifier is opaque to the
+ client. The server must remember this mapping, as this is how the client will
+ reference the node in the future.
+
+File operations:
+
+- `FUSE_OPEN`: `open(2)` for files.
+- `FUSE_RELEASE`: `close(2)` for files.
+- `FUSE_FSYNC`
+- `FUSE_FALLOCATE`
+- `FUSE_SETUPMAPPING`: Creates a memory map on a file for `mmap(2)`.
+- `FUSE_REMOVEMAPPING`: Removes a memory map for `munmap(2)`.
+
+File locking:
+
+- `FUSE_GETLK`
+- `FUSE_SETLK`
+- `FUSE_SETLKW`
+- `FUSE_COPY_FILE_RANGE`
+
+File descriptor operations:
+
+- `FUSE_IOCTL`
+- `FUSE_POLL`
+- `FUSE_LSEEK`
+
+Filesystem operations:
+
+- `FUSE_STATFS`
+
+#### Permissions
+
+- `FUSE_ACCESS` is used to check if a node is accessible, as part of many
+ syscall implementations. Maps to `vfs.FilesystemImpl.AccessAt`
+ in the sentry.
+
+#### I/O Operations
+
+These ops are used to read and write file pages. They're used to implement both
+I/O syscalls like `read(2)`, `write(2)` and `mmap(2)`.
+
+- `FUSE_READ`
+- `FUSE_WRITE`
+
+#### Miscellaneous
+
+- `FUSE_FLUSH`: Used by the client to indicate when a file descriptor is
+ closed. Distinct from `FUSE_FSYNC`, which corresponds to an `fsync(2)` syscall
+ from the user. Maps to `vfs.FileDescriptorImpl.Release` in the sentry.
+- `FUSE_BMAP`: Old address space API for block defrag. Probably not needed.
+- `FUSE_NOTIFY_REPLY`: [TODO: what does this do?]
+
+# References
+
+- `fuse(4)` manpage.
+- Linux kernel FUSE documentation: https://www.kernel.org/doc/html/latest/filesystems/fuse.html