NAME
rt_dptbl − real-time dispatcher parameter table
DESCRIPTION
The process scheduler (or dispatcher) is the portion of the kernel that controls allocation of the CPU to processes. The scheduler supports the notion of scheduling classes where each class defines a scheduling policy, used to schedule processes within that class. Associated with each scheduling class is a set of priority queues on which ready to run processes are linked. These priority queues are mapped by the system configuration into a set of global scheduling priorities which are available to processes within the class. The dispatcher always selects for execution the process with the highest global scheduling priority in the system. The priority queues associated with a given class are viewed by that class as a contiguous set of priority levels numbered from 0 (lowest priority) to n (highest priority—a configuration dependent value). The set of global scheduling priorities that the queues for a given class are mapped into might not start at zero and might not be contiguous, depending on the configuration.
The real-time class maintains an in-core table, with an entry for each priority level, giving the properties of that level. This table is called the real-time dispatcher parameter table (rt_dptbl). The rt_dptbl consists of an array (config_rt_dptbl[]) of parameter structures (struct rtdpent_t), one for each of the n priority levels. The structure are accessed via a pointer, (rt_dptbl), to the array. The properties of a given priority level i are specified by the ith parameter structure in this array ( rt_dptbl[i] ).
A parameter
structure consists of the following members. These are also
described in the /usr/include/sys/rt.h header file.
rt_globpri
The global scheduling priority associated with this priority level. The rt_globpri values cannot be changed with dispadmin(1M).
rt_quantum
The length of the time quantum allocated to processes at this level in ticks (Hz). The time quantum value is only a default or starting value for processes at a particular level as the time quantum of a real-time process can be changed by the user with the priocntl command or the priocntl system call.
An administrator can affect the behavior of the real-time portion of the scheduler by reconfiguring the rt_dptbl. There are two methods available for doing this: reconfigure with a loadable module at boot-time or by using dispadmin(1M) at run-time.
rt_dptbl
Loadable Module
The rt_dptbl can be reconfigured with a loadable
module which contains a new real time dispatch table. The
module containing the dispatch table is separate from the RT
loadable module which contains the rest of the real time
software. This is the only method that can be used to change
the number of real time priority levels or the set of global
scheduling priorities used by the real time class. The
relevant procedure and source code is described in the
EXAMPLES section.
dispadmin
Configuration File
The rt_quantum values in the rt_dptbl can be
examined and modified on a running system using the
dispadmin(1M) command. Invoking dispadmin for
the real-time class allows the administrator to retrieve the
current rt_dptbl configuration from the
kernel’s in-core table, or overwrite the in-core table
with values from a configuration file. The configuration
file used for input to dispadmin must conform to the
specific format described below.
Blank lines are ignored and any part of a line to the right of a # symbol is treated as a comment. The first non-blank, non-comment line must indicate the resolution to be used for interpreting the time quantum values. The resolution is specified as
RES=res
where res is a positive integer between 1 and 1,000,000,000 inclusive and the resolution used is the reciprocal of res in seconds. (For example, RES=1000 specifies millisecond resolution.) Although very fine (nanosecond) resolution may be specified, the time quantum lengths are rounded up to the next integral multiple of the system clock’s resolution.
The remaining lines in the file are used to specify the rt_quantum values for each of the real-time priority levels. The first line specifies the quantum for real-time level 0, the second line specifies the quantum for real-time level 1. There must be exactly one line for each configured real-time priority level. Each rt_quantum entry must be either a positive integer specifying the desired time quantum (in the resolution given by res), or the value -2 indicating an infinite time quantum for that level.
EXAMPLES
Example 1: A Sample dispadmin Configuration File
The following excerpt from a dispadmin configuration file illustrates the format. Note that for each line specifying a time quantum there is a comment indicating the corresponding priority level. These level numbers indicate priority within the real-time class, and the mapping between these real-time priorities and the corresponding global scheduling priorities is determined by the configuration specified in the RT_DPTBL loadable module. The level numbers are strictly for the convenience of the administrator reading the file and, as with any comment, they are ignored by dispadmin on input. dispadmin assumes that the lines in the file are ordered by consecutive, increasing priority level (from 0 to the maximum configured real-time priority). The level numbers in the comments should normally agree with this ordering; if for some reason they don’t, however, dispadmin is unaffected.
# Real-Time Dispatcher Configuration File RES=1000 # TIME QUANTUM PRIORITY # (rt_quantum)LEVEL 100# 0 100# 1 100# 2 100# 3 100# 4 100# 5 90 # 6 90 # 7 .. . .. . .. . 10# 58 10# 59
Example 2: Replacing The rt_dptbl Loadable Module
In order to change the size of the real time dispatch table, the loadable module which contains the dispatch table information will have to be built. It is recommended that you save the existing module before using the following procedure.
1. |
Place the dispatch table code shown below in a file called rt_dptbl.c An example of an rt_dptbl.c file follows. | ||
2. |
Compile the code using the given compilation and link lines supplied. |
cc -c -0
-D_KERNEL rt_dptbl.c
ld -r -o RT_DPTBL rt_dptbl.o
3. |
Copy the current dispatch table in /usr/kernel/sched to RT_DPTBL.bak. | ||
4. |
Replace the current RT_DPTBL in /usr/kernel/sched. | ||
5. |
You will have to make changes in the /etc/system file to reflect the changes to the sizes of the tables. See system(4). The rt_maxpri variable may need changing. The syntax for setting this is: |
set RT:rt_maxpri=(class-specific value for maximum real-time priority)
6. |
Reboot the system to use the new dispatch table. |
Great care should be used in replacing the dispatch table using this method. If you don’t get it right, the system may not behave properly.
The following is an example of a rt_dptbl.c file used for building the new rt_dptbl.
/* BEGIN rt_dptbl.c */ #include <sys/proc.h> #include <sys/priocntl.h> #include <sys/class.h> #include <sys/disp.h> #include <sys/rt.h> #include <sys/rtpriocntl.h> /* * This is the loadable module wrapper. */ #include <sys/modctl.h> extern struct mod_ops mod_miscops; /* * Module linkage information for the kernel. */ static struct modlmisc modlmisc = { &mod_miscops, "realtime dispatch table" }; static struct modlinkage modlinkage = { MODREV_1, &modlmisc, 0 }; _init() { return (mod_install(&modlinkage)); } _info (struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } rtdpent_t config_rt_dptbl[] = { /* prilevel Time quantum */ 100,100, 101,100, 102,100, 103,100, 104,100, 105,100, 106,100, 107,100, 108,100, 109,100, 110,80, 111,80, 112,80, 113,80, 114,80, 115,80, 116,80, 117,80, 118,80, 119,80, 120,60, 121,60, 122,60, 123,60, 124,60, 125,60, 126,60, 127,60, 128,60, 129,60, 130,40, 131,40, 132,40, 133,40, 134,40, 135,40, 136,40, 137,40, 138,40, 139,40, 140,20, 141,20, 142,20, 143,20, 144,20, 145,20, 146,20, 147,20, 148,20, 149,20, 150,10, 151,10, 152,10, 153,10, 154,10, 155,10, 156,10, 157,10, 158,10, 159,10, }; /* * Return the address of config_rt_dptbl */ rtdpent_t * rt_getdptbl() { return (config_rt_dptbl); }
SEE ALSO
priocntl(1), dispadmin(1M), priocntl(2), system(4)
System Administration Guide: Basic Administration
Programming Interfaces Guide