Since the OS itself doesnot frequen

Since the OS itself does
not frequently reset the __access_bit, once set by the CPU,
JOB2 employs a loop to periodically clear __access_bit and
collects the access information during this period. JOB2
incurs slightly more overhead than JOB1, but the amortized
overhead over the sampling time window (also 3 s) is not
high since it switches to the sleep mode after iterating
200 times (the time cost is far less than 3 s). Based on the
page access counters, JOB2 records the numbers of pages by
grouping the counter values into five ranges: VH [150, 200],
H [100, 150], M [64, 100], L [10, 64] and VL [1, 10]. For example,
M denotes the number of pages with a counter value
large than or equal to 64 but smaller than 100. By doing this,
SysMon can gain a global view of the page-level memory access
frequency distribution. As illustrated in Fig. 8 (a darker color
indicates a larger number of pages), the distribution of pages
with a different access frequency varies over different sampling
intervals (horizontal axis). Due to the space constraint,
Fig. 8 shows only a small fraction of the sampling time
period, which is representative of the whole period. Based
on the above information, the WPD is computed as: WPD ¼
(2  VH þ 1.5  H þ 1  M þ 0.5  L þ 0.1  VL)/all_used_-
pages, where all_used_pages is the total number of pages
accessed during a JOB2’s sampling period (200 iterations).
Notably, the row-buffer locality of one particular application
can be estimated by WPD. Taking sjeng as an example,
although it touches as many pages as some LLCM/LLCH
applications, the per-page access frequency is relatively
lower than that of a LLCM/LLCH application such as mcf.
Correspondingly, the WPDvalue of sjeng is much lower than
that of mcf