diff options
author | Glenn Elliott <gelliott@cs.unc.edu> | 2012-08-20 17:28:55 -0400 |
---|---|---|
committer | Glenn Elliott <gelliott@cs.unc.edu> | 2012-08-27 14:36:41 -0400 |
commit | 88ae4ef95bafec936509d8f117bc04dda6cbdd88 (patch) | |
tree | c6da78e38718c65af4b1f90eac08e5340b7c2a4e /include/net/stp.h | |
parent | 9a19f35c9c287cb8abd5bcf276ae8d1a3e876907 (diff) |
EDF priority tie-breaks..
Instead of tie-breaking by PID (which is a static
priority tie-break), we can tie-break by other
job-level-unique parameters. This is desirable
because tasks are equaly affected by tardiness
since static priority tie-breaks cause tasks
with greater PID values to experience the most
tardiness.
There are four tie-break methods:
1) Lateness. If two jobs, J_{1,i} and J_{2,j} of
tasks T_1 and T_2, respectively, have equal
deadlines, we favor the job of the task that
had the worst lateness for jobs J_{1,i-1} and
J_{2,j-1}.
Note: Unlike tardiness, lateness may be less than
zero. This occurs when a job finishes before its
deadline.
2) Normalized Lateness. The same as #1, except
lateness is first normalized by each task's
relative deadline. This prevents tasks with short
relative deadlines and small execution requirements
from always losing tie-breaks.
3) Hash. The job tuple (PID, Job#) is used to
generate a hash. Hash values are then compared.
A job has ~50% chance of winning a tie-break
with respect to another job.
Note: Emperical testing shows that some jobs
can have +/- ~1.5% advantage in tie-breaks.
Linux's built-in hash function is not totally
a uniform hash.
4) PIDs. PID-based tie-break used in prior
versions of Litmus.
Diffstat (limited to 'include/net/stp.h')
0 files changed, 0 insertions, 0 deletions