Miscellaneous Kernel Services
This chapter contains information about miscellaneous services provided by the OS X kernel. For most projects, you will probably never need to use most of these services, but if you do, you will find it hard to do without them.
This chapter contains these sections: Using Kernel Time Abstractions , Boot Option Handling, Queues, and Installing Shutdown Hooks.
Using Kernel Time Abstractions
There are two basic groups of time abstractions in the kernel. One group includes functions that provide delays and timed wake-ups. The other group includes functions and variables that provide the current wall clock time, the time used by a given process, and other similar information. This section describes both aspects of time from the perspective of the kernel.
Obtaining Time Information
There are a number of ways to get basic time information from within the kernel. The officially approved methods are those that Mach exports in kern/clock.h
. These include the following:
void clock_get_uptime(uint64_t *result); |
void clock_get_system_microtime( uint32_t *secs, |
uint32_t *microsecs); |
void clock_get_system_nanotime( uint32_t *secs, |
uint32_t *nanosecs); |
void clock_get_calendar_microtime( uint32_t *secs, |
uint32_t *microsecs); |
void clock_get_calendar_nanotime( uint32_t *secs, |
uint32_t *nanosecs); |
The function clock_get_uptime
returns a value in AbsoluteTime
units. For more information on using AbsoluteTime
, see Using Mach Absolute Time Functions.
The functions clock_get_system_microtime
and clock_get_system_nanotime
return 32-bit integers containing seconds and microseconds or nanoseconds, respectively, representing the system uptime.
The functions clock_get_calendar_microtime
and clock_get_calendar_nanotime
return 32-bit integers containing seconds and microseconds or nanoseconds, respectively, representing the current calendar date and time since the epoch (January 1, 1970).
In some parts of the kernel, you may find other functions that return type mach_timespec_t
. This type is similar to the traditional BSD struct timespec
, except that fractions of a second are measured in nanoseconds instead of microseconds:
struct mach_timespec { |
unsigned int tv_sec; |
clock_res_t tv_nsec; |
}; |
typedef struct mach_timespec *mach_timespec_t; |
In addition to the traditional Mach functions, if you are writing code in BSD portions of the kernel you can also get the current calendar (wall clock) time as a BSD timeval
, as well as find out the calendar time when the system was booted by doing the following:
#include <sys/kernel.h> |
struct timeval tv=time; /* calendar time */ |
struct timeval tv_boot=boottime; /* calendar time when booting occurred */ |
For other information, you should use the Mach functions listed previously.
Event and Timer Waits
Each part of the OS X kernel has a distinct API for waiting a certain period of time. In most cases, you can call these functions from other parts of the kernel. The I/O Kit provides IODelay
and IOSleep
. Mach provides functions based on AbsoluteTime
, as well as a few based on microseconds. BSD provides msleep
.
Using IODelay
and IOSleep
IODelay
, provided by the I/O Kit, abstracts a timed spin. If you are delaying for a short period of time, and if you need to be guaranteed that your wait will not be stopped prematurely by delivery of asynchronous events, this is probably the best choice. If you need to delay for several seconds, however, this is a bad choice, because the CPU that executes the wait will spin until the time has elapsed, unable to handle any other processing.
IOSleep
puts the currently executing thread to sleep for a certain period of time. There is no guarantee that your thread will execute after that period of time, nor is there a guarantee that your thread will not be awakened by some other event before the time has expired. It is roughly equivalent to the sleep
call from user space in this regard.
The use of IODelay
and IOSleep
are straightforward. Their prototypes are:
IODelay(unsigned microseconds); |
IOSleep(unsigned milliseconds); |
Note the differing units. It is not practical to put a thread to sleep for periods measured in microseconds, and spinning for several milliseconds is also inappropriate.
Using Mach Absolute Time Functions
The following Mach time functions are commonly used. Several others are described in osfmk/kern/clock.h
.
void delay(uint64_t microseconds); |
void clock_delay_until(uint64_t deadline); |
void clock_absolutetime_interval_to_deadline(uint64_t abstime, |
uint64_t *result); |
void nanoseconds_to_absolutetime(uint64_t nanoseconds, uint64_t *result); |
void absolutetime_to_nanoseconds(uint64_t abstime, uint64_t *result); |
These functions are generally straightforward. However, a few points deserve explanation. Unless specifically stated, all times, deadlines, and so on, are measured in abstime
units. The abstime
unit is equal to the length of one bus cycle, so the duration is dependent on the bus speed of the computer. For this reason, Mach provides conversion routines between abstime
units and nanoseconds.
Many time functions, however, provide time in seconds with nanosecond remainder. In this case, some conversion is necessary. For example, to obtain the current time as a mach abstime value, you might do the following:
uint32_t secpart; |
uint32_t nsecpart; |
uint64_t nsec, abstime; |
clock_get_calendar_nanotime(&secpart, &nsecpart); |
nsec = nsecpart + (1000000000ULL * secpart); //convert seconds to nanoseconds. |
nanoseconds_to_absolutetime(nsec, &abstime); |
The abstime value is now stored in the variable abstime
.
Using msleep
In addition to Mach and I/O Kit routines, BSD provides msleep
, which is the recommended way to delay in the BSD portions of the kernel. In other parts of the kernel, you should either use wait_queue
functions or use assert_wait
and thread_wakeup
functions, both of which are closely tied to the Mach scheduler, and are described in Kernel Thread APIs. Because this function is more commonly used for waiting on events, it is described further in Condition Variables.
Handling Version Dependencies
Many time-related functions such as clock_get_uptime
changed as a result of the transition to KPIs in OS X v.10.4. While these changes result in a cleaner interface, this can prove challenging if you need to make a kernel extension that needs to obtain time information across multiple versions of OS X in a kernel extension that would otherwise have no version dependencies (such as an I/O Kit KEXT).
Here is a list of time-related functions that are available in both pre-KPI and KPI versions of OS X:
uint64_t mach_absolute_time(void);
Declared In:
<mach/mach_time.h>
Dependency:
com.apple.kernel.mach
This function returns a Mach absolute time value for the current wall clock time in units of
uint64_t
.void microtime(struct timeval *tv);
Declared In:
<sys/time.h>
Dependency:
com.apple.kernel.bsd
This function returns a timeval struct containing the current wall clock time.
void microuptime(struct timeval *tv);
Declared In:
<sys/time.h>
Dependency:
com.apple.kernel.bsd
This function returns a timeval struct containing the current uptime.
void nanotime(struct timespec *ts);
Declared In:
<sys/time.h>
Dependency:
com.apple.kernel.bsd
This function returns a timespec struct containing the current wall clock time.
void nanouptime(struct timespec *ts);
Declared In:
<sys/time.h>
Dependency:
com.apple.kernel.bsd
This function returns a timespec struct containing the current uptime.
In addition to these APIs, the functionality marked __APPLE_API_UNSTABLE
in <mach/time_value.h>
was adopted as-is in OS X v.10.4 and is no longer marked unstable.
Boot Option Handling
OS X provides a simple parse routine, PE_parse_boot_arg
, for basic boot argument passing. It supports both flags and numerical value assignment. For obtaining values, you write code similar to the following:
unsigned int argval; |
if (PE_parse_boot_arg("argflag", &argval)) { |
/* check for reasonable value */ |
if (argval < 10 || argval > 37) |
argval = 37; |
} else { |
/* use default value */ |
argval = 37; |
} |
Since PE_parse_boot_arg
returns a nonzero value if the flag exists, you can check for the presence of a flag by using a flag that starts with a dash (-) and ignoring the value stored in argvalue
.
The PE_parse_boot_arg
function can also be used to get a string argument. To do this, you must pass in the address of an array of type char
as the second argument. The behavior of PE_parse_boot_arg
is undefined if a string is passed in for a numeric variable or vice versa. Its behavior is also undefined if a string exceeds the storage space allocated. Be sure to allow enough space for the largest reasonable string including a null delimiter. No attempt is made at bounds checking, since an overflow is generally a fatal error and should reasonably prevent booting.
Queues
As part of its BSD infrastructure, the OS X kernel provides a number of basic support macros to simplify handling of linked lists and queues. These are implemented as C macros, and assume a standard C struct
. As such, they are probably not suited for writing code in C++.
The basic types of lists and queues included are
SLIST
is ideal for creating stacks or for handling large sets of data with few or no removals. Arbitrary removal, however, requires an O(n)
traversal of the list.
STAILQ
is similar to SLIST
except that it maintains pointers to both ends of the queue. This makes it ideal for simple FIFO queues by adding entries at the tail and fetching entries from the head. Like SLIST
, it is inefficient to remove arbitrary elements.
LIST
is a doubly linked version of SLIST
. The extra pointers require additional space, but allow O(1)
(constant time) removal of arbitrary elements and bidirectional traversal.
TAILQ
is a doubly linked version of STAILQ
. Like LIST
, the extra pointers require additional space, but allow O(1)
(constant time) removal of arbitrary elements and bidirectional traversal.
Because their functionality is relatively simple, their use is equally straightforward. These macros can be found in xnu/bsd/sys/queue.h
.
Installing Shutdown Hooks
Although OS X does not have traditional BSD-style shutdown hooks, the I/O Kit provides equivalent functionality in recent versions. Since the I/O Kit provides this functionality, you must call it from C++ code.
To register for notification, you call registerSleepWakeInterest
(described in IOKit/RootDomain.h
) and register for sleep notification. If the system is about to be shut down, your handler is called with the message type kIOMessageSystemWillPowerOff
. If the system is about to reboot, your handler gets the message type kIOMessageSystemWillRestart
. If the system is about to reboot, your handler gets the message type kIOMessageSystemWillSleep
.
If you no longer need to receive notification (for example, if your KEXT gets unloaded), be certain to release the notifier with IONofitier::release
to avoid a kernel panic on shutdown.
For example, the following sample KEXT registers for sleep notifications, then logs a message with IOLog when a sleep notification occurs:
#include <IOKit/IOLib.h> |
#include <IOKit/pwr_mgt/RootDomain.h> |
#include <IOKit/pwr_mgt/IOPM.h> |
#include <IOKit/IOService.h> |
#include <IOKit/IONotifier.h> |
#define ALLOW_SLEEP 1 |
IONotifier *notifier; |
extern "C" { |
IOReturn mySleepHandler( void * target, void * refCon, |
UInt32 messageType, IOService * provider, |
void * messageArgument, vm_size_t argSize ) |
{ |
IOLog("Got sleep/wake notice. Message type was %d\n", messageType); |
#if ALLOW_SLEEP |
acknowledgeSleepWakeNotification(refCon); |
#else |
vetoSleepWakeNotification(refCon); |
#endif |
return 0; |
} |
kern_return_t sleepkext_start (kmod_info_t * ki, void * d) { |
void *myself = NULL; // Would pass the self pointer here if in a class instance |
notifier = registerPrioritySleepWakeInterest( |
&mySleepHandler, myself, NULL); |
return KERN_SUCCESS; |
} |
kern_return_t sleepkext_stop (kmod_info_t * ki, void * d) { |
notifier->remove(); |
return KERN_SUCCESS; |
} |
} // extern "C" |
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