Documentation/filesystems/nfs/pnfs.rst
Source file repositories/reference/linux-study-clean/Documentation/filesystems/nfs/pnfs.rst
File Facts
- System
- Linux kernel
- Corpus path
Documentation/filesystems/nfs/pnfs.rst- Extension
.rst- Size
- 3021 bytes
- Lines
- 79
- Domain
- Support Tooling And Documentation
- Bucket
- Documentation
- Inferred role
- Support Tooling And Documentation: documentation
- Status
- atlas-only
Why This File Exists
Repository support layer: documentation, build tooling, samples, user-space helper tools, generated initramfs support, licenses, and validation utilities.
- Repository support layer: documentation, build tooling, samples, user-space helper tools, generated initramfs support, licenses, and validation utilities.
- Defines or uses C structs; map object ownership, embedded links, reference counts, and lock ownership.
Dependency Surface
- No C-style include directives detected by the generator.
Detected Declarations
- No top-level syscall, struct, function, initcall, or export declaration detected by the generator.
Annotated Snippet
==========================
Reference counting in pnfs
==========================
The are several inter-related caches. We have layouts which can
reference multiple devices, each of which can reference multiple data servers.
Each data server can be referenced by multiple devices. Each device
can be referenced by multiple layouts. To keep all of this straight,
we need to reference count.
struct pnfs_layout_hdr
======================
The on-the-wire command LAYOUTGET corresponds to struct
pnfs_layout_segment, usually referred to by the variable name lseg.
Each nfs_inode may hold a pointer to a cache of these layout
segments in nfsi->layout, of type struct pnfs_layout_hdr.
We reference the header for the inode pointing to it, across each
outstanding RPC call that references it (LAYOUTGET, LAYOUTRETURN,
LAYOUTCOMMIT), and for each lseg held within.
Each header is also (when non-empty) put on a list associated with
struct nfs_client (cl_layouts). Being put on this list does not bump
the reference count, as the layout is kept around by the lseg that
keeps it in the list.
deviceid_cache
==============
lsegs reference device ids, which are resolved per nfs_client and
layout driver type. The device ids are held in a RCU cache (struct
nfs4_deviceid_cache). The cache itself is referenced across each
mount. The entries (struct nfs4_deviceid) themselves are held across
the lifetime of each lseg referencing them.
RCU is used because the deviceid is basically a write once, read many
data structure. The hlist size of 32 buckets needs better
justification, but seems reasonable given that we can have multiple
deviceid's per filesystem, and multiple filesystems per nfs_client.
The hash code is copied from the nfsd code base. A discussion of
hashing and variations of this algorithm can be found `here.
<http://groups.google.com/group/comp.lang.c/browse_thread/thread/9522965e2b8d3809>`_
data server cache
=================
file driver devices refer to data servers, which are kept in a module
level cache. Its reference is held over the lifetime of the deviceid
pointing to it.
lseg
====
lseg maintains an extra reference corresponding to the NFS_LSEG_VALID
bit which holds it in the pnfs_layout_hdr's list. When the final lseg
is removed from the pnfs_layout_hdr's list, the NFS_LAYOUT_DESTROYED
bit is set, preventing any new lsegs from being added.
layout drivers
==============
PNFS utilizes what is called layout drivers. The STD defines 4 basic
layout types: "files", "objects", "blocks", and "flexfiles". For each
of these types there is a layout-driver with a common function-vectors
table which are called by the nfs-client pnfs-core to implement the
different layout types.
Annotation
- Atlas domain: Support Tooling And Documentation / Documentation.
- Implementation status: atlas-only.
Implementation Notes
- This generated page is the file-by-file coverage layer; curated subsystem chapters should link here when they synthesize a multi-file control flow.
- Core OS pages should be promoted from atlas-only to deep-reviewed when they explain data structures, invariants, locking, lifecycle, and C implementation snippets.
- Driver-family pages are intentionally pattern-oriented unless they are part of the selected PCIe/NVMe representative device path.