libmemstat(3)

NAME

libmemstat - library interface to retrieve kernel memory al

locator
statistics

LIBRARY

library ``libmemstat''

SYNOPSIS

#include <sys/types.h>
#include <memstat.h>
General Functions
const char *
memstat_strerror(int error);
Memory Type List Management Functions
struct memoryt_ypel_ist *
memstat_mtl_alloc(void);
struct memoryt_ype *
memstat_mtl_first(struct memoryt_ypel_ist *list);
struct memoryt_ype *
memstat_mtl_next(struct memoryt_ype *mtp);
struct memoryt_ype *
memstat_mtl_find(struct memoryt_ypel_ist *list, int allocator,
        const char *name);
void
memstat_mtl_free(struct memoryt_ypel_ist *list);
int
memstat_mtl_geterror(struct memoryt_ypel_ist *list);
Allocator Query Functions
int
memstat_kvm_all(struct memoryt_ypel_ist *list, void *kvmh_andle);
int
memstat_kvm_malloc(struct     memoryt_ypel_ist    *list,    void
*kvmh_andle);
int
memstat_kvm_uma(struct memoryt_ypel_ist *list, void *kvmh_andle);
int
memstat_sysctl_all(struct memoryt_ypel_ist *list, int flags);
int
memstat_sysctl_malloc(struct memoryt_ypel_ist *list, int flags);
int
memstat_sysctl_uma(struct memoryt_ypel_ist *list, int flags);
Memory Type Accessor Methods
const char *
memstat_get_name(const struct memoryt_ype *mtp);
int
memstat_get_allocator(const struct memoryt_ype *mtp);
uint64t_
memstat_get_countlimit(const struct memoryt_ype *mtp);
uint64t_
memstat_get_byteslimit(const struct memoryt_ype *mtp);
uint64t_
memstat_get_sizemask(const struct memoryt_ype *mtp);
uint64t_
memstat_get_size(const struct memoryt_ype *mtp);
uint64t_
memstat_get_memalloced(const struct memoryt_ype *mtp);
uint64t_
memstat_get_memfreed(const struct memoryt_ype *mtp);
uint64t_
memstat_get_numallocs(const struct memoryt_ype *mtp);
uint64t_
memstat_get_numfrees(const struct memoryt_ype *mtp);
uint64t_
memstat_get_bytes(const struct memoryt_ype *mtp);
uint64t_
memstat_get_count(const struct memoryt_ype *mtp);
uint64t_
memstat_get_free(const struct memoryt_ype *mtp);
uint64t_
memstat_get_failures(const struct memoryt_ype *mtp);
void *
memstat_get_caller_pointer(const  struct memoryt_ype *mtp, int
index);
void
memstat_set_caller_pointer(struct memoryt_ype *mtp, int index,
        void *value);
uint64t_
memstat_get_caller_uint64(const  struct  memoryt_ype *mtp, int
index);
void
memstat_set_caller_uint64(struct memoryt_ype *mtp, int index,
        uint64t_value);
uint64t_
memstat_get_zonefree(const struct memoryt_ype *mtp);
uint64t_
memstat_get_kegfree(const struct memoryt_ype *mtp);
uint64t_
memstat_get_percpu_memalloced(const struct  memoryt_ype  *mtp,
int cpu);
uint64t_
memstat_get_percpu_memfreed(const struct memoryt_ype *mtp, int
cpu);
uint64t_
memstat_get_percpu_numallocs(const  struct  memoryt_ype  *mtp,
int cpu);
uint64t_
memstat_get_percpu_numfrees(const struct memoryt_ype *mtp, int
cpu);
uint64t_
memstat_get_percpu_sizemask(const struct memoryt_ype *mtp, int
cpu);
void *
memstat_get_percpu_caller_pointer(const   struct   memoryt_ype
*mtp, int cpu,
        int index);
void
memstat_set_percpu_caller_pointer(struct memoryt_ype *mtp, int
cpu,
        int index, void *value);
uint64t_
memstat_get_percpu_caller_uint64(const    struct   memoryt_ype
*mtp, int cpu,
        int index);
void
memstat_set_percpu_caller_uint64(struct memoryt_ype *mtp,  int
cpu,
        int index, uint64t_value);
uint64t_
memstat_get_percpu_free(const  struct  memoryt_ype  *mtp,  int
cpu);

DESCRIPTION

libmemstat provides an interface to retrieve kernel memory

allocator
statistics, for the purposes of debugging and system moni

toring, insulating applications from implementation details of the alloca

tors, and
allowing a tool to transparently support multiple alloca

tors. libmemstat
supports both retrieving a single statistics snapshot, as

well as incrementally updating statistics for long-term monitoring.

libmemstat describes each memory type using a struct

memoryt_ype, an
opaque memory type accessed by the application using acces

sor functions
in the library. libmemstat returns and updates chains of

struct
memoryt_ype via a struct memoryt_ypel_ist, which will be allocated

by
calling memstat_mtl_alloc(), and freed on completion using memstat_mtl_free(). Lists of memory types are populated via

calls that
query the kernel for statistics information; currently:
memstat_kvm_all(), memstat_kvm_malloc(), memstat_kvm_uma(), memstat_sysctl_all(), memstat_sysctl_uma(), and

memstat_sysctl_malloc().
Repeated calls will incrementally update the list of memory

types, permitting tracking over time without recreating all list

state. If an
error is detected during a query call, error condition in

formation may be
retrieved using memstat_mtl_geterror(), and converted to a

user-readable
string using memstat_strerror().

Freeing the list will free all memory type data in the list,

and so
invalidates any outstanding pointers to entries in the list.

struct
memoryt_ype entries in the list may be iterated over using memstat_mtl_first() and memstat_mtl_next(), which respec

tively return the
first entry in a list, and the next entry in a list.

memstat_mtl_find(),
which will return a pointer to the first entry matching the

passed parameters.

A series of accessor methods is provided to access fields of

the structure, including retrieving statistics and properties, as

well as setting
of caller owned fields. Direct application access to the

data structure
fields is not supported.

Library memoryt_ype Fields

Each struct memoryt_ype holds a description of the memory

type, including
its name and the allocator it is managed by, as well as cur

rent statistics on use. Some statistics are directly measured, others

are derived
from directly measured statistics. Certain high level

statistics are
present across all available allocators, such as the number

of allocation
and free operations; other measurements, such as the quanti

ty of free
items in per-CPU caches, or administrative limit on the num

ber of allocations, is available only for specific allocators.

Caller memoryt_ype Fields

struct memoryt_ype includes fields to allow the application to

store
data, in the form of pointers and 64-bit integers, with mem

ory types.
For example, the application author might make use of one of

the caller
pointers to reference a more complex data structure tracking

long-term
behavior of the memory type, or a window system object that

is used to
render the state of the memory type. General and per-CPU

storage is provided with each struct memoryt_ype in the form of an array of

pointers
and integers. The array entries are accessed via the index

argument to
the get and set accessor methods. Possible values of index

range between
0 and MEMSTAT_MAXCALLER.

Caller-owned fields are initialized to 0 or NULL when a new

struct
memoryt_ype is allocated and attached to a memory type list;

these fields
retain their values across queries that update library-owned

fields.

Allocator Types

Currently, libmemstat supports two kernel allocators: ALLO

CATOR_UMA for
uma(9), and ALLOCATOR_MALLOC for malloc(9). These values

may be passed
to memstat_mtl_find(), and will be returned by

memstat_get_allocator().
Two additional constants in the allocator name space are de

fined:
ALLOCATOR_UNKNOWN, which will only be returned as a result

of a library
error, and ALLOCATOR_ANY, which can be used to specify that

returning
types matching any allocator is permittible from

memstat_mtl_find().

Access Method List

The following accessor methods are defined, of which some

will be valid
for a given memory type:

memstat_get_name()

Return a pointer to the name of the memory type.

Memory for the
name is owned by libmemstat and will be valid

through a call to
memstat_mtl_free(). Note that names will be unique

with respect
to a single allocator, but that the same name might

be used by
different memory types owned by different memory al

locators.

memstat_get_allocator()

Return an integer identifier for the memory alloca

tor that owns
the memory type.

memstat_get_countlimit()

If the memory type has an administrative limit on

the number of
simultaneous allocations, return it.

memstat_get_byteslimit()

If the memory type has an administrative limit on

the number of
bytes of memory that may be simultaenously allocated

for the memory type, return it.

memstat_get_sizemask()

If the memory type supports variable allocation

sizes, return a
bitmask of sizes allocated for the memory type.

memstat_get_size()

If the memory type supports a fixed allocation size,

return that
size.

memstat_get_memalloced()

Return the total number of bytes allocated for the

memory type
over its lifetime.

memstat_get_memfreed()

Return the total number of bytes freed for the memo

ry type over
its lifetime.

memstat_get_numallocs()

Return the total number of allocations for the memo

ry type over
its lifetime.

memstat_get_numfrees()

Return the total number of frees for the memory type

over its
lifetime.

memstat_get_bytes()

Return the current number of bytes allocated to the

memory type.

memstat_get_count()

Return the current number of allocations for the

memory type.

memstat_get_free()

If the memory allocator supports a cache, return the

number of
items in the cache.

memstat_get_failures()

If the memory allocator and type permit allocation

failures,
return the number of allocation failures measured.

memstat_get_caller_pointer()

Return a caller-owned pointer for the memory type.

memstat_set_caller_pointer()

Set a caller-owned pointer for the memory type.

memstat_get_caller_uint64()

Return a caller-owned integer for the memory type.

memstat_set_caller_uint64()

Set a caller-owned integer for the memory type.

memstat_get_zonefree()

If the memory allocator supports a multi-level allo

cation structure, return the number of cached items in the zone.

These items
will be in a fully constructed state available for

immediate use.

memstat_get_kegfree()

If the memory allocator supports a multi-level allo

cation structure, return the number of cached items in the keg.

These items
may be in a partially constructed state, and may re

quire further
processing before they can be made available for

use.

memstat_get_percpu_memalloced()

If the memory allocator supports per-CPU statistics,

return the
number of bytes of memory allocated for the memory

type on the
CPU over its lifetime.

memstat_get_percpu_memfreed()

If the memory allocator supports per-CPU statistics,

return the
number of bytes of memory freed from the memory type

on the CPU
over its lifetime.

memstat_get_percpu_numallocs()

If the memory allocator supports per-CPU statistics,

return the
number of allocations for the memory type on the CPU

over its
lifetime.

memstat_get_percpu_numfrees()

If the memory allocator supports per-CPU statistics,

return the
number of frees for the memory type on the CPU over

its lifetime.

memstat_get_percpu_sizemask()

If the memory allocator supports variable size memo

ry allocation
and per-CPU statistics, return the size bitmask for

the memory
type on the CPU.

memstat_get_percpu_caller_pointer()

Return a caller-owned per-CPU pointer for the memory

type.

memstat_set_percpu_caller_pointer()

Set a caller-owned per-CPU pointer for the memory

type.

memstat_get_percpu_caller_uint64()

Return a caller-owned per-CPU integer for the memory

type.

memsttat_set_percpu_caller_uint64()

Set a caller-owned per-CPU integer for the memory

type.

memstat_get_percpu_free()

If the memory allocator supports a per-CPU cache,

return the number of free items in the per-CPU cache of the desig

nated CPU.

RETURN VALUES

libmemstat functions fall into three categories: functions

returning a
pointer to an object, functions returning an integer return

value, and
functions implementing accessor methods returning data from

a struct
memoryt_ype.

Functions returning a pointer to an object will generally

return NULL on
failure. memstat_mtl_alloc() will return an error value via

errno, which
will consist of the value ENOMEM. Functions

memstat_mtl_first(),
memstat_mtl_next(), and memstat_mtl_find() will return NULL

when there is
no entry or match in the list; however, this is not consid

ered a failure
mode and no error value is available.

Functions returning an integer success value will return 0

on success, or
-1 on failure. If a failure is returned, the list error ac

cess method,
memstat_mtl_geterror(), may be used to retrieve the error

state. The
string representation of the error may be retrieved using
memstat_strerror(). Possible error values are:

MEMSTAT_ERROR_UNDEFINED Undefined error. Occurs if

memstat_mtl_geterror() is

called on a
list before an error asso

ciated with the
list has occurred.

MEMSTAT_ERROR_NOMEMORY Insufficient memory. Oc

curs if library

calls to malloc(3) fail, or

if a system
call to retrieve kernel

statistics fails
with ENOMEM.

MEMSTAT_ERROR_VERSION Returned if the current

version of

libmemstat is unable to in

terpret the
statistics data returned by

the kernel
due to an explicit version

mismatch, or
to differences in data

structures that
cannot be reconciled.

MEMSTAT_ERROR_PERMISSION Returned if a statistics

source returns

errno values of EACCES or

EPERM.

MEMSTAT_ERROR_TOOMANYCPUS Returned if the compile

time limit on

the number of CPUs in

libmemstat is
lower than the number of

CPUs returned
by a statistics data

source.

MEMSTAT_ERROR_DATAERROR Returned if libmemstat is

unable to

interpret statistics data

returned by
the data source, even

though there does
not appear to be a version

problem.

MEMSTAT_ERROR_KVM Returned if libmemstat ex

periences an

error while using kvm(3)

interfaces to
query statistics data. Use
kvm_geterr(3) to retrieve

the error.

MEMSTAT_ERROR_KVM_NOSYMBOL Returned if libmemstat is

unable to read

a required symbol from the

kernel being
operated on.

MEMSTAT_ERROR_KVM_SHORTREAD Returned if libmemstat at

tempts to read

data from a live memory im

age or kernel
core dump and insufficient

data is
returned.

Finally, functions returning data from a struct memoryt_ype

pointer are
not permitted to fail, and directly return either a statis

tic or pointer
to a string.

EXAMPLES

Create a memory type list, query the uma(9) memory allocator

for available statistics, and print out the number of allocations

performed by the
mbuf zone.

struct memory_type_list *mtlp;
struct memory_type *mtp;
uint64_t mbuf_count;

mtlp = memstat_mtl_alloc();
if (mtlp == NULL)

err(-1, "memstat_mtl_alloc");

if (memstat_sysctl_uma(mtlp, 0) < 0)

err(-1, "memstat_sysctl_uma");

mtp = memstat_mtl_find(mtlp, ALLOCATOR_UMA, "mbuf");
if (mtp == NULL)

errx(-1, "memstat_mtl_find: mbuf not found");

mbuf_count = memstat_get_count(mtp);
memstat_mtl_free(mtlp);

printf("mbufs: %llu0, (unsigned long long)mbuf_count);

SEE ALSO

malloc(9), uma(9)

HISTORY

The libmemstat library appeared in FreeBSD 6.0.

AUTHORS

The kernel memory allocator changes necessary to support a

general purpose monitoring library, along with the library, were writ

ten by Robert
Watson <rwatson@FreeBSD.org>.

BUGS

There are memory allocators in the kernel, such as the VM

page allocator
and sf_buf allocator, which are not currently supported by

libmemstat.

Once a memory type is present on a memory type list, it will

not be
removed even if the kernel no longer presents information on

the type via
its monitoring interfaces. In order to flush removed memory

types, it is
necessary to free the entire list and allocate a new one.

BSD June 27, 2005

BSD