@noindent where @var{recent_cpu} is an estimate of the CPU time the
thread has used recently (see below) and @var{nice} is the thread's
-@var{nice} value. The coefficients @math{1/4} and 2 on @var{recent_cpu}
+@var{nice} value. The result should be rounded down to the nearest
+integer (truncated).
+The coefficients @math{1/4} and 2 on @var{recent_cpu}
and @var{nice}, respectively, have been found to work well in practice
but lack deeper meaning. The calculated @var{priority} is always
adjusted to lie in the valid range @code{PRI_MIN} to @code{PRI_MAX}.
received ``recently,'' with the rate of decay inversely proportional to
the number of threads competing for the CPU.
-Assumptions made by some of the tests require that updates to
+Assumptions made by some of the tests require that these recalculations of
@var{recent_cpu} be made exactly when the system tick counter reaches a
multiple of a second, that is, when @code{timer_ticks () % TIMER_FREQ ==
0}, and not at any other time.
2^q, f = 2**q}. By the definition above, we can convert an integer or
real number into @m{p.q} format by multiplying with @m{f}. For example,
in 17.14 format the fraction 59/60 used in the calculation of
-@var{load_avg}, above, is @am{(59/60)2^{14}, 59/60*(2**14)} = 16,111
-(rounded to nearest). To convert a fixed-point value back to an
+@var{load_avg}, above, is @am{(59/60)2^{14}, 59/60*(2**14)} = 16,110.
+To convert a fixed-point value back to an
integer, divide by @m{f}. (The normal @samp{/} operator in C rounds
toward zero, that is, it rounds positive numbers down and negative
numbers up. To round to nearest, add @m{f / 2} to a positive number, or
projects / pintos-anon / blobdiff