mirror_zfs/lib/libspl/include/sys/kstat.h
Brian Behlendorf a26baf285f Add linux libspl support
All changes needed for the libspl layer.  This includes modifications
to files directly copied from OpenSolaris and the addition of new
files needed to fill in the gaps.

Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov>
2010-08-31 13:41:59 -07:00

821 lines
29 KiB
C

/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2006 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
#ifndef _SYS_KSTAT_H
#define _SYS_KSTAT_H
/*
* Definition of general kernel statistics structures and /dev/kstat ioctls
*/
#include <sys/types.h>
#include <sys/time.h>
#ifdef __cplusplus
extern "C" {
#endif
typedef int kid_t; /* unique kstat id */
/*
* Kernel statistics driver (/dev/kstat) ioctls
*/
#define KSTAT_IOC_BASE ('K' << 8)
#define KSTAT_IOC_CHAIN_ID KSTAT_IOC_BASE | 0x01
#define KSTAT_IOC_READ KSTAT_IOC_BASE | 0x02
#define KSTAT_IOC_WRITE KSTAT_IOC_BASE | 0x03
/*
* /dev/kstat ioctl usage (kd denotes /dev/kstat descriptor):
*
* kcid = ioctl(kd, KSTAT_IOC_CHAIN_ID, NULL);
* kcid = ioctl(kd, KSTAT_IOC_READ, kstat_t *);
* kcid = ioctl(kd, KSTAT_IOC_WRITE, kstat_t *);
*/
#define KSTAT_STRLEN 31 /* 30 chars + NULL; must be 16 * n - 1 */
/*
* The generic kstat header
*/
typedef struct kstat {
/*
* Fields relevant to both kernel and user
*/
hrtime_t ks_crtime; /* creation time (from gethrtime()) */
struct kstat *ks_next; /* kstat chain linkage */
kid_t ks_kid; /* unique kstat ID */
char ks_module[KSTAT_STRLEN]; /* provider module name */
uchar_t ks_resv; /* reserved, currently just padding */
int ks_instance; /* provider module's instance */
char ks_name[KSTAT_STRLEN]; /* kstat name */
uchar_t ks_type; /* kstat data type */
char ks_class[KSTAT_STRLEN]; /* kstat class */
uchar_t ks_flags; /* kstat flags */
void *ks_data; /* kstat type-specific data */
uint_t ks_ndata; /* # of type-specific data records */
size_t ks_data_size; /* total size of kstat data section */
hrtime_t ks_snaptime; /* time of last data shapshot */
/*
* Fields relevant to kernel only
*/
int (*ks_update)(struct kstat *, int); /* dynamic update */
void *ks_private; /* arbitrary provider-private data */
int (*ks_snapshot)(struct kstat *, void *, int);
void *ks_lock; /* protects this kstat's data */
} kstat_t;
#ifdef _SYSCALL32
typedef int32_t kid32_t;
typedef struct kstat32 {
/*
* Fields relevant to both kernel and user
*/
hrtime_t ks_crtime;
caddr32_t ks_next; /* struct kstat pointer */
kid32_t ks_kid;
char ks_module[KSTAT_STRLEN];
uint8_t ks_resv;
int32_t ks_instance;
char ks_name[KSTAT_STRLEN];
uint8_t ks_type;
char ks_class[KSTAT_STRLEN];
uint8_t ks_flags;
caddr32_t ks_data; /* type-specific data */
uint32_t ks_ndata;
size32_t ks_data_size;
hrtime_t ks_snaptime;
/*
* Fields relevant to kernel only (only needed here for padding)
*/
int32_t _ks_update;
caddr32_t _ks_private;
int32_t _ks_snapshot;
caddr32_t _ks_lock;
} kstat32_t;
#endif /* _SYSCALL32 */
/*
* kstat structure and locking strategy
*
* Each kstat consists of a header section (a kstat_t) and a data section.
* The system maintains a set of kstats, protected by kstat_chain_lock.
* kstat_chain_lock protects all additions to/deletions from this set,
* as well as all changes to kstat headers. kstat data sections are
* *optionally* protected by the per-kstat ks_lock. If ks_lock is non-NULL,
* kstat clients (e.g. /dev/kstat) will acquire this lock for all of their
* operations on that kstat. It is up to the kstat provider to decide whether
* guaranteeing consistent data to kstat clients is sufficiently important
* to justify the locking cost. Note, however, that most statistic updates
* already occur under one of the provider's mutexes, so if the provider sets
* ks_lock to point to that mutex, then kstat data locking is free.
*
* NOTE: variable-size kstats MUST employ kstat data locking, to prevent
* data-size races with kstat clients.
*
* NOTE: ks_lock is really of type (kmutex_t *); it is declared as (void *)
* in the kstat header so that users don't have to be exposed to all of the
* kernel's lock-related data structures.
*/
#if defined(_KERNEL)
#define KSTAT_ENTER(k) \
{ kmutex_t *lp = (k)->ks_lock; if (lp) mutex_enter(lp); }
#define KSTAT_EXIT(k) \
{ kmutex_t *lp = (k)->ks_lock; if (lp) mutex_exit(lp); }
#define KSTAT_UPDATE(k, rw) (*(k)->ks_update)((k), (rw))
#define KSTAT_SNAPSHOT(k, buf, rw) (*(k)->ks_snapshot)((k), (buf), (rw))
#endif /* defined(_KERNEL) */
/*
* kstat time
*
* All times associated with kstats (e.g. creation time, snapshot time,
* kstat_timer_t and kstat_io_t timestamps, etc.) are 64-bit nanosecond values,
* as returned by gethrtime(). The accuracy of these timestamps is machine
* dependent, but the precision (units) is the same across all platforms.
*/
/*
* kstat identity (KID)
*
* Each kstat is assigned a unique KID (kstat ID) when it is added to the
* global kstat chain. The KID is used as a cookie by /dev/kstat to
* request information about the corresponding kstat. There is also
* an identity associated with the entire kstat chain, kstat_chain_id,
* which is bumped each time a kstat is added or deleted. /dev/kstat uses
* the chain ID to detect changes in the kstat chain (e.g., a new disk
* coming online) between ioctl()s.
*/
/*
* kstat module, kstat instance
*
* ks_module and ks_instance contain the name and instance of the module
* that created the kstat. In cases where there can only be one instance,
* ks_instance is 0. The kernel proper (/kernel/unix) uses "unix" as its
* module name.
*/
/*
* kstat name
*
* ks_name gives a meaningful name to a kstat. The full kstat namespace
* is module.instance.name, so the name only need be unique within a
* module. kstat_create() will fail if you try to create a kstat with
* an already-used (ks_module, ks_instance, ks_name) triplet. Spaces are
* allowed in kstat names, but strongly discouraged, since they hinder
* awk-style processing at user level.
*/
/*
* kstat type
*
* The kstat mechanism provides several flavors of kstat data, defined
* below. The "raw" kstat type is just treated as an array of bytes; you
* can use this to export any kind of data you want.
*
* Some kstat types allow multiple data structures per kstat, e.g.
* KSTAT_TYPE_NAMED; others do not. This is part of the spec for each
* kstat data type.
*
* User-level tools should *not* rely on the #define KSTAT_NUM_TYPES. To
* get this information, read out the standard system kstat "kstat_types".
*/
#define KSTAT_TYPE_RAW 0 /* can be anything */
/* ks_ndata >= 1 */
#define KSTAT_TYPE_NAMED 1 /* name/value pair */
/* ks_ndata >= 1 */
#define KSTAT_TYPE_INTR 2 /* interrupt statistics */
/* ks_ndata == 1 */
#define KSTAT_TYPE_IO 3 /* I/O statistics */
/* ks_ndata == 1 */
#define KSTAT_TYPE_TIMER 4 /* event timer */
/* ks_ndata >= 1 */
#define KSTAT_NUM_TYPES 5
/*
* kstat class
*
* Each kstat can be characterized as belonging to some broad class
* of statistics, e.g. disk, tape, net, vm, streams, etc. This field
* can be used as a filter to extract related kstats. The following
* values are currently in use: disk, tape, net, controller, vm, kvm,
* hat, streams, kstat, and misc. (The kstat class encompasses things
* like kstat_types.)
*/
/*
* kstat flags
*
* Any of the following flags may be passed to kstat_create(). They are
* all zero by default.
*
* KSTAT_FLAG_VIRTUAL:
*
* Tells kstat_create() not to allocate memory for the
* kstat data section; instead, you will set the ks_data
* field to point to the data you wish to export. This
* provides a convenient way to export existing data
* structures.
*
* KSTAT_FLAG_VAR_SIZE:
*
* The size of the kstat you are creating will vary over time.
* For example, you may want to use the kstat mechanism to
* export a linked list. NOTE: The kstat framework does not
* manage the data section, so all variable-size kstats must be
* virtual kstats. Moreover, variable-size kstats MUST employ
* kstat data locking to prevent data-size races with kstat
* clients. See the section on "kstat snapshot" for details.
*
* KSTAT_FLAG_WRITABLE:
*
* Makes the kstat's data section writable by root.
* The ks_snapshot routine (see below) does not need to check for
* this; permission checking is handled in the kstat driver.
*
* KSTAT_FLAG_PERSISTENT:
*
* Indicates that this kstat is to be persistent over time.
* For persistent kstats, kstat_delete() simply marks the
* kstat as dormant; a subsequent kstat_create() reactivates
* the kstat. This feature is provided so that statistics
* are not lost across driver close/open (e.g., raw disk I/O
* on a disk with no mounted partitions.)
* NOTE: Persistent kstats cannot be virtual, since ks_data
* points to garbage as soon as the driver goes away.
*
* The following flags are maintained by the kstat framework:
*
* KSTAT_FLAG_DORMANT:
*
* For persistent kstats, indicates that the kstat is in the
* dormant state (e.g., the corresponding device is closed).
*
* KSTAT_FLAG_INVALID:
*
* This flag is set when a kstat is in a transitional state,
* e.g. between kstat_create() and kstat_install().
* kstat clients must not attempt to access the kstat's data
* if this flag is set.
*/
#define KSTAT_FLAG_VIRTUAL 0x01
#define KSTAT_FLAG_VAR_SIZE 0x02
#define KSTAT_FLAG_WRITABLE 0x04
#define KSTAT_FLAG_PERSISTENT 0x08
#define KSTAT_FLAG_DORMANT 0x10
#define KSTAT_FLAG_INVALID 0x20
/*
* Dynamic update support
*
* The kstat mechanism allows for an optional ks_update function to update
* kstat data. This is useful for drivers where the underlying device
* keeps cheap hardware stats, but extraction is expensive. Instead of
* constantly keeping the kstat data section up to date, you can supply a
* ks_update function which updates the kstat's data section on demand.
* To take advantage of this feature, simply set the ks_update field before
* calling kstat_install().
*
* The ks_update function, if supplied, must have the following structure:
*
* int
* foo_kstat_update(kstat_t *ksp, int rw)
* {
* if (rw == KSTAT_WRITE) {
* ... update the native stats from ksp->ks_data;
* return EACCES if you don't support this
* } else {
* ... update ksp->ks_data from the native stats
* }
* }
*
* The ks_update return codes are: 0 for success, EACCES if you don't allow
* KSTAT_WRITE, and EIO for any other type of error.
*
* In general, the ks_update function may need to refer to provider-private
* data; for example, it may need a pointer to the provider's raw statistics.
* The ks_private field is available for this purpose. Its use is entirely
* at the provider's discretion.
*
* All variable-size kstats MUST supply a ks_update routine, which computes
* and sets ks_data_size (and ks_ndata if that is meaningful), since these
* are needed to perform kstat snapshots (see below).
*
* No kstat locking should be done inside the ks_update routine. The caller
* will already be holding the kstat's ks_lock (to ensure consistent data).
*/
#define KSTAT_READ 0
#define KSTAT_WRITE 1
/*
* Kstat snapshot
*
* In order to get a consistent view of a kstat's data, clients must obey
* the kstat's locking strategy. However, these clients may need to perform
* operations on the data which could cause a fault (e.g. copyout()), or
* operations which are simply expensive. Doing so could cause deadlock
* (e.g. if you're holding a disk's kstat lock which is ultimately required
* to resolve a copyout() fault), performance degradation (since the providers'
* activity is serialized at the kstat lock), device timing problems, etc.
*
* To avoid these problems, kstat data is provided via snapshots. Taking
* a snapshot is a simple process: allocate a wired-down kernel buffer,
* acquire the kstat's data lock, copy the data into the buffer ("take the
* snapshot"), and release the lock. This ensures that the kstat's data lock
* will be held as briefly as possible, and that no faults will occur while
* the lock is held.
*
* Normally, the snapshot is taken by default_kstat_snapshot(), which
* timestamps the data (sets ks_snaptime), copies it, and does a little
* massaging to deal with incomplete transactions on i/o kstats. However,
* this routine only works for kstats with contiguous data (the typical case).
* If you create a kstat whose data is, say, a linked list, you must provide
* your own ks_snapshot routine. The routine you supply must have the
* following prototype (replace "foo" with something appropriate):
*
* int foo_kstat_snapshot(kstat_t *ksp, void *buf, int rw);
*
* The minimal snapshot routine -- one which copies contiguous data that
* doesn't need any massaging -- would be this:
*
* ksp->ks_snaptime = gethrtime();
* if (rw == KSTAT_WRITE)
* bcopy(buf, ksp->ks_data, ksp->ks_data_size);
* else
* bcopy(ksp->ks_data, buf, ksp->ks_data_size);
* return (0);
*
* A more illuminating example is taking a snapshot of a linked list:
*
* ksp->ks_snaptime = gethrtime();
* if (rw == KSTAT_WRITE)
* return (EACCES); ... See below ...
* for (foo = first_foo; foo; foo = foo->next) {
* bcopy((char *) foo, (char *) buf, sizeof (struct foo));
* buf = ((struct foo *) buf) + 1;
* }
* return (0);
*
* In the example above, we have decided that we don't want to allow
* KSTAT_WRITE access, so we return EACCES if this is attempted.
*
* The key points are:
*
* (1) ks_snaptime must be set (via gethrtime()) to timestamp the data.
* (2) Data gets copied from the kstat to the buffer on KSTAT_READ,
* and from the buffer to the kstat on KSTAT_WRITE.
* (3) ks_snapshot return values are: 0 for success, EACCES if you
* don't allow KSTAT_WRITE, and EIO for any other type of error.
*
* Named kstats (see section on "Named statistics" below) containing long
* strings (KSTAT_DATA_STRING) need special handling. The kstat driver
* assumes that all strings are copied into the buffer after the array of
* named kstats, and the pointers (KSTAT_NAMED_STR_PTR()) are updated to point
* into the copy within the buffer. The default snapshot routine does this,
* but overriding routines should contain at least the following:
*
* if (rw == KSTAT_READ) {
* kstat_named_t *knp = buf;
* char *end = knp + ksp->ks_ndata;
* uint_t i;
*
* ... Do the regular copy ...
* bcopy(ksp->ks_data, buf, sizeof (kstat_named_t) * ksp->ks_ndata);
*
* for (i = 0; i < ksp->ks_ndata; i++, knp++) {
* if (knp[i].data_type == KSTAT_DATA_STRING &&
* KSTAT_NAMED_STR_PTR(knp) != NULL) {
* bcopy(KSTAT_NAMED_STR_PTR(knp), end,
* KSTAT_NAMED_STR_BUFLEN(knp));
* KSTAT_NAMED_STR_PTR(knp) = end;
* end += KSTAT_NAMED_STR_BUFLEN(knp);
* }
* }
*/
/*
* Named statistics.
*
* List of arbitrary name=value statistics.
*/
typedef struct kstat_named {
char name[KSTAT_STRLEN]; /* name of counter */
uchar_t data_type; /* data type */
union {
char c[16]; /* enough for 128-bit ints */
int32_t i32;
uint32_t ui32;
struct {
union {
char *ptr; /* NULL-term string */
#if defined(_KERNEL) && defined(_MULTI_DATAMODEL)
caddr32_t ptr32;
#endif
char __pad[8]; /* 64-bit padding */
} addr;
uint32_t len; /* # bytes for strlen + '\0' */
} str;
/*
* The int64_t and uint64_t types are not valid for a maximally conformant
* 32-bit compilation environment (cc -Xc) using compilers prior to the
* introduction of C99 conforming compiler (reference ISO/IEC 9899:1990).
* In these cases, the visibility of i64 and ui64 is only permitted for
* 64-bit compilation environments or 32-bit non-maximally conformant
* C89 or C90 ANSI C compilation environments (cc -Xt and cc -Xa). In the
* C99 ANSI C compilation environment, the long long type is supported.
* The _INT64_TYPE is defined by the implementation (see sys/int_types.h).
*/
#if defined(_INT64_TYPE)
int64_t i64;
uint64_t ui64;
#endif
long l;
ulong_t ul;
/* These structure members are obsolete */
longlong_t ll;
u_longlong_t ull;
float f;
double d;
} value; /* value of counter */
} kstat_named_t;
#define KSTAT_DATA_CHAR 0
#define KSTAT_DATA_INT32 1
#define KSTAT_DATA_UINT32 2
#define KSTAT_DATA_INT64 3
#define KSTAT_DATA_UINT64 4
#if !defined(_LP64)
#define KSTAT_DATA_LONG KSTAT_DATA_INT32
#define KSTAT_DATA_ULONG KSTAT_DATA_UINT32
#else
#if !defined(_KERNEL)
#define KSTAT_DATA_LONG KSTAT_DATA_INT64
#define KSTAT_DATA_ULONG KSTAT_DATA_UINT64
#else
#define KSTAT_DATA_LONG 7 /* only visible to the kernel */
#define KSTAT_DATA_ULONG 8 /* only visible to the kernel */
#endif /* !_KERNEL */
#endif /* !_LP64 */
/*
* Statistics exporting named kstats with long strings (KSTAT_DATA_STRING)
* may not make the assumption that ks_data_size is equal to (ks_ndata * sizeof
* (kstat_named_t)). ks_data_size in these cases is equal to the sum of the
* amount of space required to store the strings (ie, the sum of
* KSTAT_NAMED_STR_BUFLEN() for all KSTAT_DATA_STRING statistics) plus the
* space required to store the kstat_named_t's.
*
* The default update routine will update ks_data_size automatically for
* variable-length kstats containing long strings (using the default update
* routine only makes sense if the string is the only thing that is changing
* in size, and ks_ndata is constant). Fixed-length kstats containing long
* strings must explicitly change ks_data_size (after creation but before
* initialization) to reflect the correct amount of space required for the
* long strings and the kstat_named_t's.
*/
#define KSTAT_DATA_STRING 9
/* These types are obsolete */
#define KSTAT_DATA_LONGLONG KSTAT_DATA_INT64
#define KSTAT_DATA_ULONGLONG KSTAT_DATA_UINT64
#define KSTAT_DATA_FLOAT 5
#define KSTAT_DATA_DOUBLE 6
#define KSTAT_NAMED_PTR(kptr) ((kstat_named_t *)(kptr)->ks_data)
/*
* Retrieve the pointer of the string contained in the given named kstat.
*/
#define KSTAT_NAMED_STR_PTR(knptr) ((knptr)->value.str.addr.ptr)
/*
* Retrieve the length of the buffer required to store the string in the given
* named kstat.
*/
#define KSTAT_NAMED_STR_BUFLEN(knptr) ((knptr)->value.str.len)
/*
* Interrupt statistics.
*
* An interrupt is a hard interrupt (sourced from the hardware device
* itself), a soft interrupt (induced by the system via the use of
* some system interrupt source), a watchdog interrupt (induced by
* a periodic timer call), spurious (an interrupt entry point was
* entered but there was no interrupt condition to service),
* or multiple service (an interrupt condition was detected and
* serviced just prior to returning from any of the other types).
*
* Measurement of the spurious class of interrupts is useful for
* autovectored devices in order to pinpoint any interrupt latency
* problems in a particular system configuration.
*
* Devices that have more than one interrupt of the same
* type should use multiple structures.
*/
#define KSTAT_INTR_HARD 0
#define KSTAT_INTR_SOFT 1
#define KSTAT_INTR_WATCHDOG 2
#define KSTAT_INTR_SPURIOUS 3
#define KSTAT_INTR_MULTSVC 4
#define KSTAT_NUM_INTRS 5
typedef struct kstat_intr {
uint_t intrs[KSTAT_NUM_INTRS]; /* interrupt counters */
} kstat_intr_t;
#define KSTAT_INTR_PTR(kptr) ((kstat_intr_t *)(kptr)->ks_data)
/*
* I/O statistics.
*/
typedef struct kstat_io {
/*
* Basic counters.
*
* The counters should be updated at the end of service
* (e.g., just prior to calling biodone()).
*/
u_longlong_t nread; /* number of bytes read */
u_longlong_t nwritten; /* number of bytes written */
uint_t reads; /* number of read operations */
uint_t writes; /* number of write operations */
/*
* Accumulated time and queue length statistics.
*
* Accumulated time statistics are kept as a running sum
* of "active" time. Queue length statistics are kept as a
* running sum of the product of queue length and elapsed time
* at that length -- i.e., a Riemann sum for queue length
* integrated against time. (You can also think of the active time
* as a Riemann sum, for the boolean function (queue_length > 0)
* integrated against time, or you can think of it as the
* Lebesgue measure of the set on which queue_length > 0.)
*
* ^
* | _________
* 8 | i4 |
* | | |
* Queue 6 | |
* Length | _________ | |
* 4 | i2 |_______| |
* | | i3 |
* 2_______| |
* | i1 |
* |_______________________________|
* Time-> t1 t2 t3 t4
*
* At each change of state (entry or exit from the queue),
* we add the elapsed time (since the previous state change)
* to the active time if the queue length was non-zero during
* that interval; and we add the product of the elapsed time
* times the queue length to the running length*time sum.
*
* This method is generalizable to measuring residency
* in any defined system: instead of queue lengths, think
* of "outstanding RPC calls to server X".
*
* A large number of I/O subsystems have at least two basic
* "lists" of transactions they manage: one for transactions
* that have been accepted for processing but for which processing
* has yet to begin, and one for transactions which are actively
* being processed (but not done). For this reason, two cumulative
* time statistics are defined here: wait (pre-service) time,
* and run (service) time.
*
* All times are 64-bit nanoseconds (hrtime_t), as returned by
* gethrtime().
*
* The units of cumulative busy time are accumulated nanoseconds.
* The units of cumulative length*time products are elapsed time
* times queue length.
*
* Updates to the fields below are performed implicitly by calls to
* these five functions:
*
* kstat_waitq_enter()
* kstat_waitq_exit()
* kstat_runq_enter()
* kstat_runq_exit()
*
* kstat_waitq_to_runq() (see below)
* kstat_runq_back_to_waitq() (see below)
*
* Since kstat_waitq_exit() is typically followed immediately
* by kstat_runq_enter(), there is a single kstat_waitq_to_runq()
* function which performs both operations. This is a performance
* win since only one timestamp is required.
*
* In some instances, it may be necessary to move a request from
* the run queue back to the wait queue, e.g. for write throttling.
* For these situations, call kstat_runq_back_to_waitq().
*
* These fields should never be updated by any other means.
*/
hrtime_t wtime; /* cumulative wait (pre-service) time */
hrtime_t wlentime; /* cumulative wait length*time product */
hrtime_t wlastupdate; /* last time wait queue changed */
hrtime_t rtime; /* cumulative run (service) time */
hrtime_t rlentime; /* cumulative run length*time product */
hrtime_t rlastupdate; /* last time run queue changed */
uint_t wcnt; /* count of elements in wait state */
uint_t rcnt; /* count of elements in run state */
} kstat_io_t;
#define KSTAT_IO_PTR(kptr) ((kstat_io_t *)(kptr)->ks_data)
/*
* Event timer statistics - cumulative elapsed time and number of events.
*
* Updates to these fields are performed implicitly by calls to
* kstat_timer_start() and kstat_timer_stop().
*/
typedef struct kstat_timer {
char name[KSTAT_STRLEN]; /* event name */
uchar_t resv; /* reserved */
u_longlong_t num_events; /* number of events */
hrtime_t elapsed_time; /* cumulative elapsed time */
hrtime_t min_time; /* shortest event duration */
hrtime_t max_time; /* longest event duration */
hrtime_t start_time; /* previous event start time */
hrtime_t stop_time; /* previous event stop time */
} kstat_timer_t;
#define KSTAT_TIMER_PTR(kptr) ((kstat_timer_t *)(kptr)->ks_data)
#if defined(_KERNEL)
#include <sys/t_lock.h>
extern kid_t kstat_chain_id; /* bumped at each state change */
extern void kstat_init(void); /* initialize kstat framework */
/*
* Adding and deleting kstats.
*
* The typical sequence to add a kstat is:
*
* ksp = kstat_create(module, instance, name, class, type, ndata, flags);
* if (ksp) {
* ... provider initialization, if necessary
* kstat_install(ksp);
* }
*
* There are three logically distinct steps here:
*
* Step 1: System Initialization (kstat_create)
*
* kstat_create() performs system initialization. kstat_create()
* allocates memory for the entire kstat (header plus data), initializes
* all header fields, initializes the data section to all zeroes, assigns
* a unique KID, and puts the kstat onto the system's kstat chain.
* The returned kstat is marked invalid (KSTAT_FLAG_INVALID is set),
* because the provider (caller) has not yet had a chance to initialize
* the data section.
*
* By default, kstats are exported to all zones on the system. A kstat may be
* created via kstat_create_zone() to specify a zone to which the statistics
* should be exported. kstat_zone_add() may be used to specify additional
* zones to which the statistics are to be exported.
*
* Step 2: Provider Initialization
*
* The provider performs any necessary initialization of the data section,
* e.g. setting the name fields in a KSTAT_TYPE_NAMED. Virtual kstats set
* the ks_data field at this time. The provider may also set the ks_update,
* ks_snapshot, ks_private, and ks_lock fields if necessary.
*
* Step 3: Installation (kstat_install)
*
* Once the kstat is completely initialized, kstat_install() clears the
* INVALID flag, thus making the kstat accessible to the outside world.
* kstat_install() also clears the DORMANT flag for persistent kstats.
*
* Removing a kstat from the system
*
* kstat_delete(ksp) removes ksp from the kstat chain and frees all
* associated system resources. NOTE: When you call kstat_delete(),
* you must NOT be holding that kstat's ks_lock. Otherwise, you may
* deadlock with a kstat reader.
*
* Persistent kstats
*
* From the provider's point of view, persistence is transparent. The only
* difference between ephemeral (normal) kstats and persistent kstats
* is that you pass KSTAT_FLAG_PERSISTENT to kstat_create(). Magically,
* this has the effect of making your data visible even when you're
* not home. Persistence is important to tools like iostat, which want
* to get a meaningful picture of disk activity. Without persistence,
* raw disk i/o statistics could never accumulate: they would come and
* go with each open/close of the raw device.
*
* The magic of persistence works by slightly altering the behavior of
* kstat_create() and kstat_delete(). The first call to kstat_create()
* creates a new kstat, as usual. However, kstat_delete() does not
* actually delete the kstat: it performs one final update of the data
* (i.e., calls the ks_update routine), marks the kstat as dormant, and
* sets the ks_lock, ks_update, ks_private, and ks_snapshot fields back
* to their default values (since they might otherwise point to garbage,
* e.g. if the provider is going away). kstat clients can still access
* the dormant kstat just like a live kstat; they just continue to see
* the final data values as long as the kstat remains dormant.
* All subsequent kstat_create() calls simply find the already-existing,
* dormant kstat and return a pointer to it, without altering any fields.
* The provider then performs its usual initialization sequence, and
* calls kstat_install(). kstat_install() uses the old data values to
* initialize the native data (i.e., ks_update is called with KSTAT_WRITE),
* thus making it seem like you were never gone.
*/
extern kstat_t *kstat_create(const char *, int, const char *, const char *,
uchar_t, uint_t, uchar_t);
extern kstat_t *kstat_create_zone(const char *, int, const char *,
const char *, uchar_t, uint_t, uchar_t, zoneid_t);
extern void kstat_install(kstat_t *);
extern void kstat_delete(kstat_t *);
extern void kstat_named_setstr(kstat_named_t *knp, const char *src);
extern void kstat_set_string(char *, const char *);
extern void kstat_delete_byname(const char *, int, const char *);
extern void kstat_delete_byname_zone(const char *, int, const char *, zoneid_t);
extern void kstat_named_init(kstat_named_t *, const char *, uchar_t);
extern void kstat_timer_init(kstat_timer_t *, const char *);
extern void kstat_waitq_enter(kstat_io_t *);
extern void kstat_waitq_exit(kstat_io_t *);
extern void kstat_runq_enter(kstat_io_t *);
extern void kstat_runq_exit(kstat_io_t *);
extern void kstat_waitq_to_runq(kstat_io_t *);
extern void kstat_runq_back_to_waitq(kstat_io_t *);
extern void kstat_timer_start(kstat_timer_t *);
extern void kstat_timer_stop(kstat_timer_t *);
extern void kstat_zone_add(kstat_t *, zoneid_t);
extern void kstat_zone_remove(kstat_t *, zoneid_t);
extern int kstat_zone_find(kstat_t *, zoneid_t);
extern kstat_t *kstat_hold_bykid(kid_t kid, zoneid_t);
extern kstat_t *kstat_hold_byname(const char *, int, const char *, zoneid_t);
extern void kstat_rele(kstat_t *);
#endif /* defined(_KERNEL) */
#ifdef __cplusplus
}
#endif
#endif /* _SYS_KSTAT_H */