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.\" Copyright (c) 1983, 1986, 1993
.\" The Regents of the University of California. All rights reserved.
.\"
.\" Redistribution and use in source and binary forms, with or without
.\" modification, are permitted provided that the following conditions
.\" are met:
.\" 1. Redistributions of source code must retain the above copyright
.\" notice, this list of conditions and the following disclaimer.
.\" 2. Redistributions in binary form must reproduce the above copyright
.\" notice, this list of conditions and the following disclaimer in the
.\" documentation and/or other materials provided with the distribution.
.\" 3. All advertising materials mentioning features or use of this software
.\" must display the following acknowledgement:
.\" This product includes software developed by the University of
.\" California, Berkeley and its contributors.
.\" 4. Neither the name of the University nor the names of its contributors
.\" may be used to endorse or promote products derived from this software
.\" without specific prior written permission.
.\"
.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
.\" ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
.\" SUCH DAMAGE.
.\"
.\" @(#)5.t 8.1 (Berkeley) 6/8/93
.\"
.nr H2 1
.\".ds RH "Memory management
.br
.ne 2i
.NH
\s+2Memory management\s0
.PP
A single mechanism is used for data storage: memory buffers, or
\fImbuf\fP's. An mbuf is a structure of the form:
.DS
._f
struct mbuf {
struct mbuf *m_next; /* next buffer in chain */
u_long m_off; /* offset of data */
short m_len; /* amount of data in this mbuf */
short m_type; /* mbuf type (accounting) */
u_char m_dat[MLEN]; /* data storage */
struct mbuf *m_act; /* link in higher-level mbuf list */
};
.DE
The \fIm_next\fP field is used to chain mbufs together on linked
lists, while the \fIm_act\fP field allows lists of mbuf chains to be
accumulated. By convention, the mbufs common to a single object
(for example, a packet) are chained together with the \fIm_next\fP
field, while groups of objects are linked via the \fIm_act\fP
field (possibly when in a queue).
.PP
Each mbuf has a small data area for storing information, \fIm_dat\fP.
The \fIm_len\fP field indicates the amount of data, while the \fIm_off\fP
field is an offset to the beginning of the data from the base of the
mbuf. Thus, for example, the macro \fImtod\fP, which converts a pointer
to an mbuf to a pointer to the data stored in the mbuf, has the form
.DS
._d
#define mtod(\fIx\fP,\fIt\fP) ((\fIt\fP)((int)(\fIx\fP) + (\fIx\fP)->m_off))
.DE
(note the \fIt\fP parameter, a C type cast, which is used to cast
the resultant pointer for proper assignment).
.PP
In addition to storing data directly in the mbuf's data area, data
of page size may be also be stored in a separate area of memory.
The mbuf utility routines maintain
a pool of pages for this purpose and manipulate a private page map
for such pages.
An mbuf with an external data area may be recognized by the larger
offset to the data area;
this is formalized by the macro M_HASCL(\fIm\fP), which is true
if the mbuf whose address is \fIm\fP has an external page cluster.
An array of reference counts on pages is also maintained
so that copies of pages may be made without core to core
copying (copies are created simply by duplicating the reference to the data
and incrementing the associated reference counts for the pages).
Separate data pages are currently used only
when copying data from a user process into the kernel,
and when bringing data in at the hardware level. Routines which
manipulate mbufs are not normally aware whether data is stored directly in
the mbuf data array, or if it is kept in separate pages.
.PP
The following may be used to allocate and free mbufs:
.LP
m = m_get(wait, type);
.br
MGET(m, wait, type);
.IP
The subroutine \fIm_get\fP and the macro \fIMGET\fP
each allocate an mbuf, placing its address in \fIm\fP.
The argument \fIwait\fP is either M_WAIT or M_DONTWAIT according
to whether allocation should block or fail if no mbuf is available.
The \fItype\fP is one of the predefined mbuf types for use in accounting
of mbuf allocation.
.IP "MCLGET(m);"
This macro attempts to allocate an mbuf page cluster
to associate with the mbuf \fIm\fP.
If successful, the length of the mbuf is set to CLSIZE,
the size of the page cluster.
.LP
n = m_free(m);
.br
MFREE(m,n);
.IP
The routine \fIm_free\fP and the macro \fIMFREE\fP
each free a single mbuf, \fIm\fP, and any associated external storage area,
placing a pointer to its successor in the chain it heads, if any, in \fIn\fP.
.IP "m_freem(m);"
This routine frees an mbuf chain headed by \fIm\fP.
.PP
The following utility routines are available for manipulating mbuf
chains:
.IP "m = m_copy(m0, off, len);"
.br
The \fIm_copy\fP routine create a copy of all, or part, of a
list of the mbufs in \fIm0\fP. \fILen\fP bytes of data, starting
\fIoff\fP bytes from the front of the chain, are copied.
Where possible, reference counts on pages are used instead
of core to core copies. The original mbuf chain must have at
least \fIoff\fP + \fIlen\fP bytes of data. If \fIlen\fP is
specified as M_COPYALL, all the data present, offset
as before, is copied.
.IP "m_cat(m, n);"
.br
The mbuf chain, \fIn\fP, is appended to the end of \fIm\fP.
Where possible, compaction is performed.
.IP "m_adj(m, diff);"
.br
The mbuf chain, \fIm\fP is adjusted in size by \fIdiff\fP
bytes. If \fIdiff\fP is non-negative, \fIdiff\fP bytes
are shaved off the front of the mbuf chain. If \fIdiff\fP
is negative, the alteration is performed from back to front.
No space is reclaimed in this operation; alterations are
accomplished by changing the \fIm_len\fP and \fIm_off\fP
fields of mbufs.
.IP "m = m_pullup(m0, size);"
.br
After a successful call to \fIm_pullup\fP, the mbuf at
the head of the returned list, \fIm\fP, is guaranteed
to have at least \fIsize\fP
bytes of data in contiguous memory within the data area of the mbuf
(allowing access via a pointer, obtained using the \fImtod\fP macro,
and allowing the mbuf to be located from a pointer to the data area
using \fIdtom\fP, defined below).
If the original data was less than \fIsize\fP bytes long,
\fIlen\fP was greater than the size of an mbuf data
area (112 bytes), or required resources were unavailable,
\fIm\fP is 0 and the original mbuf chain is deallocated.
.IP
This routine is particularly useful when verifying packet
header lengths on reception. For example, if a packet is
received and only 8 of the necessary 16 bytes required
for a valid packet header are present at the head of the list
of mbufs representing the packet, the remaining 8 bytes
may be ``pulled up'' with a single \fIm_pullup\fP call.
If the call fails the invalid packet will have been discarded.
.PP
By insuring that mbufs always reside on 128 byte boundaries,
it is always possible to locate the mbuf associated with a data
area by masking off the low bits of the virtual address.
This allows modules to store data structures in mbufs and
pass them around without concern for locating the original
mbuf when it comes time to free the structure.
Note that this works only with objects stored in the internal data
buffer of the mbuf.
The \fIdtom\fP macro is used to convert a pointer into an mbuf's
data area to a pointer to the mbuf,
.DS
#define dtom(x) ((struct mbuf *)((int)x & ~(MSIZE-1)))
.DE
.PP
Mbufs are used for dynamically allocated data structures such as
sockets as well as memory allocated for packets and headers. Statistics are
maintained on mbuf usage and can be viewed by users using the
\fInetstat\fP\|(1) program.
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