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DEVSTAT(3) Library Functions Manual DEVSTAT(3)

devstat, devstat_getnumdevs, devstat_getgeneration, devstat_getversion, devstat_checkversion, devstat_getdevs, devstat_selectdevs, devstat_buildmatch, devstat_compute_statistics, devstat_compute_etimedevice statistics utility library

library “libdevstat”

#include <devstat.h>

int
devstat_getnumdevs(kvm_t *kd);

long
devstat_getgeneration(kvm_t *kd);

int
devstat_getversion(kvm_t *kd);

int
devstat_checkversion(kvm_t *kd);

int
devstat_getdevs(kvm_t *kd, struct statinfo *stats);

int
devstat_selectdevs(struct device_selection **dev_select, int *num_selected, int *num_selections, long *select_generation, long current_generation, struct devstat *devices, int numdevs, struct devstat_match *matches, int num_matches, char **dev_selections, int num_dev_selections, devstat_select_mode select_mode, int maxshowdevs, int perf_select);

int
devstat_buildmatch(char *match_str, struct devstat_match **matches, int *num_matches);

int
devstat_compute_statistics(struct devstat *current, struct devstat *previous, long double etime, ...);

long double
devstat_compute_etime(struct bintime *cur_time, struct bintime *prev_time);

The devstat library is a library of helper functions for dealing with the kernel devstat(9) interface, which is accessible to users via sysctl(3) and kvm(3). All functions that take a kvm_t * as first argument can be passed NULL instead of a kvm handle as this argument, which causes the data to be read via sysctl(3). Otherwise, it is read via kvm(3) using the supplied handle. The () function should be called with each kvm handle that is going to be used (or with NULL if sysctl(3) is going to be used).

The () function returns the number of devices registered with the devstat subsystem in the kernel.

The () function returns the current generation of the devstat list of devices in the kernel.

The () function returns the current kernel devstat version.

The () function checks the userland devstat version against the kernel devstat version. If the two are identical, it returns zero. Otherwise, it prints an appropriate error in devstat_errbuf and returns -1.

The () function fetches the current list of devices and statistics into the supplied statinfo structure. The statinfo structure can be found in <devstat.h>:

struct statinfo {
	long            cp_time[CPUSTATES];
	long            tk_nin;
	long            tk_nout;
	struct devinfo  *dinfo;
	long double     snap_time;
};

The () function expects the statinfo structure to be allocated, and it also expects the dinfo subelement to be allocated and zeroed prior to the first invocation of devstat_getdevs(). The dinfo subelement is used to store state between calls, and should not be modified after the first call to devstat_getdevs(). The dinfo subelement contains the following elements:

struct devinfo {
	struct devstat	*devices;
	uint8_t		*mem_ptr;
	long		generation;
	int		numdevs;
};

The kern.devstat.all sysctl(8) variable contains an array of devstat structures, but at the head of the array is the current devstat generation. The reason the generation is at the head of the buffer is so that userland software accessing the devstat statistics information can atomically get both the statistics information and the corresponding generation number. If client software were forced to get the generation number via a separate sysctl(8) variable (which is available for convenience), the list of devices could change between the time the client gets the generation and the time the client gets the device list.

The mem_ptr subelement of the devinfo structure is a pointer to memory that is allocated, and resized if necessary, by (). The devices subelement of the devinfo structure is basically a pointer to the beginning of the array of devstat structures from the kern.devstat.all sysctl(8) variable (or the corresponding values read via kvm(3)). The generation subelement of the devinfo structure contains the corresponding generation number. The numdevs subelement of the devinfo structure contains the current number of devices registered with the kernel devstat subsystem.

The () function selects devices to display based upon a number of criteria:

specified devices
Specified devices are the first selection priority. These are generally devices specified by name by the user e.g. da0, da1, cd0.
match patterns
These are pattern matching expressions generated by devstat_buildmatch() from user input.
performance
If performance mode is enabled, devices will be sorted based on the bytes field in the device_selection structure passed in to devstat_selectdevs(). The bytes value currently must be maintained by the user. In the future, this may be done for him in a devstat library routine. If no devices have been selected by name or by pattern, the performance tracking code will select every device in the system, and sort them by performance. If devices have been selected by name or pattern, the performance tracking code will honor those selections and will only sort among the selected devices.
order in the devstat list
If the selection mode is set to DS_SELECT_ADD, and if there are still less than maxshowdevs devices selected, devstat_selectdevs() will automatically select up to maxshowdevs devices.

The () function performs selections in four different modes:

In “add” mode, devstat_selectdevs() will select any unselected devices specified by name or matching pattern. It will also select more devices, in devstat list order, until the number of selected devices is equal to maxshowdevs or until all devices are selected.
In “only” mode, devstat_selectdevs() will clear all current selections, and will only select devices specified by name or by matching pattern.
In “remove” mode, devstat_selectdevs() will remove devices specified by name or by matching pattern. It will not select any additional devices.
In “add only” mode, devstat_selectdevs() will select any unselected devices specified by name or matching pattern. In this respect it is identical to “add” mode. It will not, however, select any devices other than those specified.

In all selection modes, () will not select any more than maxshowdevs devices. One exception to this is when you are in “top” mode and no devices have been selected. In this case, devstat_selectdevs() will select every device in the system. Client programs must pay attention to selection order when deciding whether to pay attention to a particular device. This may be the wrong behavior, and probably requires additional thought.

The () function handles allocation and resizing of the dev_select structure passed in by the client. The devstat_selectdevs() function uses the numdevs and current_generation fields to track the current devstat generation and number of devices. If num_selections is not the same as numdevs or if select_generation is not the same as current_generation, devstat_selectdevs() will resize the selection list as necessary, and re-initialize the selection array.

The () function takes a comma separated match string and compiles it into a devstat_match structure that is understood by devstat_selectdevs(). Match strings have the following format:

device,type,if

The () function takes care of allocating and reallocating the match list as necessary. Currently known match types include:

device type:
Direct Access devices
Sequential Access devices
Printers
Processor devices
Write Once Read Multiple devices
CD devices
Scanner devices
Optical Memory devices
Medium Changer devices
Communication devices
Storage Array devices
Enclosure Services devices
Floppy devices
interface:
Integrated Drive Electronics devices
Small Computer System Interface devices
Any other device interface
passthrough:
Passthrough devices

The () function provides complete statistics calculation. There are four arguments for which values must be supplied: current, previous, etime, and the terminating argument for the varargs list, DSM_NONE. For most applications, the user will want to supply valid devstat structures for both current and previous. In some instances, for instance when calculating statistics since system boot, the user may pass in a NULL pointer for the previous argument. In that case, devstat_compute_statistics() will use the total stats in the current structure to calculate statistics over etime. For each statistics to be calculated, the user should supply the proper enumerated type (listed below), and a variable of the indicated type. All statistics are either integer values, for which a uint64_t is used, or floating point, for which a long double is used. The statistics that may be calculated are:

type: N/A

This must be the last argument passed to (). It is an argument list terminator.

type: uint64_t *

The total number of bytes transferred between the acquisition of previous and current.

 
 
type: uint64_t *

The total number of bytes in transactions of the specified type between the acquisition of previous and current.

type: uint64_t *

The total number of transfers between the acquisition of previous and current.

 
 
 
type: uint64_t *

The total number of transactions of the specified type between the acquisition of previous and current.

type: long double *

The total duration of transactions, in seconds, between the acquisition of previous and current.

 
 
 
type: long double *

The total duration of transactions of the specified type between the acquisition of previous and current.

type: long double *

Total time the device had one or more transactions outstanding between the acquisition of previous and current.

type: uint64_t *

The total number of blocks transferred between the acquisition of previous and current. This number is in terms of the blocksize reported by the device. If no blocksize has been reported (i.e., the block size is 0), a default blocksize of 512 bytes will be used in the calculation.

 
 
type: uint64_t *

The total number of blocks of the specified type between the acquisition of previous and current. This number is in terms of the blocksize reported by the device. If no blocksize has been reported (i.e., the block size is 0), a default blocksize of 512 bytes will be used in the calculation.

type: long double *

The average number of kilobytes per transfer between the acquisition of previous and current.

 
 
type: long double *

The average number of kilobytes in the specified type transaction between the acquisition of previous and current.

type: long double *

The average number of transfers per second between the acquisition of previous and current.

 
 
 
type: long double *

The average number of transactions of the specified type per second between the acquisition of previous and current.

type: long double *

The average number of megabytes transferred per second between the acquisition of previous and current.

 
 
type: long double *

The average number of megabytes per second in the specified type of transaction between the acquisition of previous and current.

type: long double *

The average number of blocks transferred per second between the acquisition of previous and current. This number is in terms of the blocksize reported by the device. If no blocksize has been reported (i.e., the block size is 0), a default blocksize of 512 bytes will be used in the calculation.

 
 
type: long double *

The average number of blocks per second in the specified type of transaction between the acquisition of previous and current. This number is in terms of the blocksize reported by the device. If no blocksize has been reported (i.e., the block size is 0), a default blocksize of 512 bytes will be used in the calculation.

type: long double *

The average duration of transactions between the acquisition of previous and current.

 
 
 
type: long double *

The average duration of transactions of the specified type between the acquisition of previous and current.

type: long double *

The percentage of time the device had one or more transactions outstanding between the acquisition of previous and current.

type: uint64_t *

The number of not yet completed transactions at the time when current was acquired.

type: N/A

If you do not need a result from (), just put DSM_SKIP as first (type) parameter and NULL as second parameter. This can be useful in scenarios where the statistics to be calculated are determined at run time.

The () function provides an easy way to find the difference in seconds between two bintime structures. This is most commonly used in conjunction with the time recorded by the devstat_getdevs() function (in struct statinfo) each time it fetches the current devstat list.

The devstat_getnumdevs(), devstat_getgeneration(), and devstat_getversion() function return the indicated sysctl variable, or -1 if there is an error fetching the variable.

The devstat_checkversion() function returns 0 if the kernel and userland devstat versions match. If they do not match, it returns -1.

The devstat_getdevs() and devstat_selectdevs() functions return -1 in case of an error, 0 if there is no error, and 1 if the device list or selected devices have changed. A return value of 1 from devstat_getdevs() is usually a hint to re-run devstat_selectdevs() because the device list has changed.

The devstat_buildmatch() function returns -1 for error, and 0 if there is no error.

The devstat_compute_etime() function returns the computed elapsed time.

The devstat_compute_statistics() function returns -1 for error, and 0 for success.

If an error is returned from one of the devstat library functions, the reason for the error is generally printed in the global string devstat_errbuf which is DEVSTAT_ERRBUF_SIZE characters long.

systat(1), kvm(3), sysctl(3), iostat(8), rpc.rstatd(8), sysctl(8), vmstat(8), devstat(9)

The devstat statistics system first appeared in FreeBSD 3.0. The new interface (the functions prefixed with devstat_) first appeared in FreeBSD 5.0.

Kenneth Merry <ken@FreeBSD.org>

There should probably be an interface to de-allocate memory allocated by devstat_getdevs(), devstat_selectdevs(), and devstat_buildmatch().

The devstat_selectdevs() function should probably not select more than maxshowdevs devices in “top” mode when no devices have been selected previously.

There should probably be functions to perform the statistics buffer swapping that goes on in most of the clients of this library.

The statinfo and devinfo structures should probably be cleaned up and thought out a little more.

December 15, 2012 FreeBSD-12.0