xref: /freebsd/share/man/man9/buf.9 (revision aa1a8ff2d6dbc51ef058f46f3db5a8bb77967145)
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28.Dd December 22, 1998
29.Dt BUF 9
30.Os
31.Sh NAME
32.Nm buf
33.Nd "kernel buffer I/O scheme used in FreeBSD VM system"
34.Sh DESCRIPTION
35The kernel implements a KVM abstraction of the buffer cache which allows it
36to map potentially disparate vm_page's into contiguous KVM for use by
37(mainly file system) devices and device I/O.
38This abstraction supports
39block sizes from DEV_BSIZE (usually 512) to upwards of several pages or more.
40It also supports a relatively primitive byte-granular valid range and dirty
41range currently hardcoded for use by NFS.
42The code implementing the
43VM Buffer abstraction is mostly concentrated in
44.Pa /usr/src/sys/kern/vfs_bio.c .
45.Pp
46One of the most important things to remember when dealing with buffer pointers
47(struct buf) is that the underlying pages are mapped directly from the buffer
48cache.
49No data copying occurs in the scheme proper, though some file systems
50such as UFS do have to copy a little when dealing with file fragments.
51The second most important thing to remember is that due to the underlying page
52mapping, the b_data base pointer in a buf is always *page* aligned, not
53*block* aligned.
54When you have a VM buffer representing some b_offset and
55b_size, the actual start of the buffer is (b_data + (b_offset & PAGE_MASK))
56and not just b_data.
57Finally, the VM system's core buffer cache supports
58valid and dirty bits (m->valid, m->dirty) for pages in DEV_BSIZE chunks.
59Thus
60a platform with a hardware page size of 4096 bytes has 8 valid and 8 dirty
61bits.
62These bits are generally set and cleared in groups based on the device
63block size of the device backing the page.
64Complete page's worth are often
65referred to using the VM_PAGE_BITS_ALL bitmask (i.e., 0xFF if the hardware page
66size is 4096).
67.Pp
68VM buffers also keep track of a byte-granular dirty range and valid range.
69This feature is normally only used by the NFS subsystem.
70I am not sure why it
71is used at all, actually, since we have DEV_BSIZE valid/dirty granularity
72within the VM buffer.
73If a buffer dirty operation creates a 'hole',
74the dirty range will extend to cover the hole.
75If a buffer validation
76operation creates a 'hole' the byte-granular valid range is left alone and
77will not take into account the new extension.
78Thus the whole byte-granular
79abstraction is considered a bad hack and it would be nice if we could get rid
80of it completely.
81.Pp
82A VM buffer is capable of mapping the underlying VM cache pages into KVM in
83order to allow the kernel to directly manipulate the data associated with
84the (vnode,b_offset,b_size).
85The kernel typically unmaps VM buffers the moment
86they are no longer needed but often keeps the 'struct buf' structure
87instantiated and even bp->b_pages array instantiated despite having unmapped
88them from KVM.
89If a page making up a VM buffer is about to undergo I/O, the
90system typically unmaps it from KVM and replaces the page in the b_pages[]
91array with a place-marker called bogus_page.
92The place-marker forces any kernel
93subsystems referencing the associated struct buf to re-lookup the associated
94page.
95I believe the place-marker hack is used to allow sophisticated devices
96such as file system devices to remap underlying pages in order to deal with,
97for example, re-mapping a file fragment into a file block.
98.Pp
99VM buffers are used to track I/O operations within the kernel.
100Unfortunately,
101the I/O implementation is also somewhat of a hack because the kernel wants
102to clear the dirty bit on the underlying pages the moment it queues the I/O
103to the VFS device, not when the physical I/O is actually initiated.
104This
105can create confusion within file system devices that use delayed-writes because
106you wind up with pages marked clean that are actually still dirty.
107If not
108treated carefully, these pages could be thrown away!
109Indeed, a number of
110serious bugs related to this hack were not fixed until the 2.2.8/3.0 release.
111The kernel uses an instantiated VM buffer (i.e., struct buf) to place-mark pages
112in this special state.
113The buffer is typically flagged B_DELWRI.
114When a
115device no longer needs a buffer it typically flags it as B_RELBUF.
116Due to
117the underlying pages being marked clean, the B_DELWRI|B_RELBUF combination must
118be interpreted to mean that the buffer is still actually dirty and must be
119written to its backing store before it can actually be released.
120In the case
121where B_DELWRI is not set, the underlying dirty pages are still properly
122marked as dirty and the buffer can be completely freed without losing that
123clean/dirty state information.
124(XXX do we have to check other flags in
125regards to this situation ???)
126.Pp
127The kernel reserves a portion of its KVM space to hold VM Buffer's data
128maps.
129Even though this is virtual space (since the buffers are mapped
130from the buffer cache), we cannot make it arbitrarily large because
131instantiated VM Buffers (struct buf's) prevent their underlying pages in the
132buffer cache from being freed.
133This can complicate the life of the paging
134system.
135.Sh HISTORY
136The
137.Nm
138manual page was originally written by
139.An Matthew Dillon
140and first appeared in
141.Fx 3.1 ,
142December 1998.
143