genode/repos/os/run/cpu_quota.run

#
# Check platform
#
# HW is the only kernel that provides appliance of quota to the scheduling.
#
assert_spec hw

#
# Build
#

build "core init drivers/timer test/cpu_quota"

#
# Boot image
#

create_boot_directory

install_config {
<config prio_levels="4">
	<parent-provides>
		<service name="ROM"/>
		<service name="RAM"/>
		<service name="IRQ"/>
		<service name="IO_MEM"/>
		<service name="IO_PORT"/>
		<service name="CAP"/>
		<service name="PD"/>
		<service name="RM"/>
		<service name="CPU"/>
		<service name="LOG"/>
		<service name="SIGNAL"/>
	</parent-provides>
	<default-route>
		<any-service><parent/><any-child/></any-service>
	</default-route>

	<start name="test-sync">
		<resource name="RAM" quantum="10M"/>
		<provides><service name="Sync"/></provides>
	</start>

	<start name="init_1" priority="-1">
		<binary name="init"/>
		<resource name="RAM" quantum="20M"/>
		<resource name="CPU" quantum="10"/>
		<config>
			<parent-provides>
				<service name="ROM"/>
				<service name="RAM"/>
				<service name="IRQ"/>
				<service name="IO_MEM"/>
				<service name="IO_PORT"/>
				<service name="CAP"/>
				<service name="PD"/>
				<service name="RM"/>
				<service name="CPU"/>
				<service name="LOG"/>
				<service name="SIGNAL"/>
				<service name="Timer"/>
				<service name="Sync"/>
			</parent-provides>
			<default-route>
				<any-service><parent/><any-child/></any-service>
			</default-route>

			<start name="test_slow">
				<binary name="test-cpu_quota"/>
				<resource name="RAM" quantum="10M"/>
				<resource name="CPU" quantum="50"/>
			</start>

		</config>
	</start>

	<start name="init_2" priority="-2">
		<binary name="init"/>
		<resource name="RAM" quantum="30M"/>
		<resource name="CPU" quantum="80"/>
		<config prio_levels="2">
			<parent-provides>
				<service name="ROM"/>
				<service name="RAM"/>
				<service name="IRQ"/>
				<service name="IO_MEM"/>
				<service name="IO_PORT"/>
				<service name="CAP"/>
				<service name="PD"/>
				<service name="RM"/>
				<service name="CPU"/>
				<service name="LOG"/>
				<service name="SIGNAL"/>
				<service name="Timer"/>
				<service name="Sync"/>
			</parent-provides>
			<default-route>
				<any-service><parent/></any-service>
			</default-route>

			<start name="test_midl" priority="0">
				<binary name="test-cpu_quota"/>
				<resource name="RAM" quantum="10M"/>
				<resource name="CPU" quantum="25"/>
			</start>

			<start name="test_fast" priority="-1">
				<binary name="test-cpu_quota"/>
				<resource name="RAM" quantum="10M"/>
				<resource name="CPU" quantum="75"/>
			</start>

		</config>
	</start>

	<start name="timer" priority="0">
		<resource name="RAM" quantum="10M"/>
		<resource name="CPU" quantum="10"/>
		<provides><service name="Timer"/></provides>
	</start>

</config>
}

build_boot_image "core init timer test-cpu_quota test-sync"

#
# Execution
#

append qemu_args "-nographic -m 128"

run_genode_until ".*done.*\n.*done.*\n.*done.*\n" 100

#
# Conclusion
#
set err_cnt 0

proc check_counter { name opt cnt total_cnt } {

	global err_cnt
	set    bad   0
	set    class "Good: "
	set    tol   0.01
	set    is    0

	#
	# On X86, the timer driver uses the PIT with a maximum timeout of 54 ms.
	# Thus, the driver frequently interrupts the counters with highest
	# priority to update the timer. This is why we need a higher error
	# tolerance as for ARM where the driver, once configured, can sleep for
	# the whole test timeout.
	#
	if {[have_spec x86]} { set tol 0.02 }

	#
	# Zynq is currently tested merely in Qemu and most likely because of
	# that, the results are less precise.
	#
	if {[have_spec zynq_qemu]} { set tol 0.03 }

	#
	# FIXME: There is no reasonable explanation by now why the test results
	# are less stable on these platforms. We have tried several things that
	# did not lead to an explanation or improvement:
	#
	#   * changing the timing parameters of the scheduler
	#   * switching off SMP
	#   * double-checking the speed of userland and kernel timers
	#
	if {[have_spec hw_odroid_xu]} { set tol 0.04 }
	if {[have_spec hw_arndale]}   { set tol 0.04 }

	if {[expr $total_cnt != 0]} { set is [expr double($cnt) / $total_cnt ] }

	set err      [expr $is - $opt]
	set is_fmt   [format {%0.3f} [expr $is  * 100]]
	set opt_fmt  [format {%0.3f} [expr $opt * 100]]
	set err_fmt  [format {%0.3f} [expr $err * 100]]
	set tol_fmt  [format {%0.3f} [expr $tol * 100]]

	if {[expr abs($err) > $tol]} {

		set class   "Bad:  "
		set err_cnt [expr $err_cnt + 1]
	}
	puts "$class$name received $is_fmt% CPU (goal $opt_fmt% tol $tol_fmt% err $err_fmt%)"
}

proc check_quota { name opt_sp quota_sp opt quota } {

	global err_cnt
	if {[expr $quota != $opt]} {
		puts "Bad:  $name has quota $quota us (goal $opt us)"
		set err_cnt [expr $err_cnt + 1]
	}
	if {[expr $quota_sp != $opt_sp]} {
		puts "Bad:  $name has super period $quota_sp us (goal $opt_sp us)"
		set err_cnt [expr $err_cnt + 1]
	}
}

# pre-define variables if regexp does not match
set slow_quota "";    set midl_quota "";    set fast_quota ""
set slow_quota_sp ""; set midl_quota_sp ""; set fast_quota_sp ""

regexp {[0-9]+} [regexp -inline {slow. quota [0-9]+} $output] slow_quota
regexp {[0-9]+} [regexp -inline {midl. quota [0-9]+} $output] midl_quota
regexp {[0-9]+} [regexp -inline {fast. quota [0-9]+} $output] fast_quota

regexp {[0-9]+} [regexp -inline {slow. quota super period [0-9]+} $output] slow_quota_sp
regexp {[0-9]+} [regexp -inline {midl. quota super period [0-9]+} $output] midl_quota_sp
regexp {[0-9]+} [regexp -inline {fast. quota super period [0-9]+} $output] fast_quota_sp

#
# We have to consider the rounding errors as the two translations from init to
# core and then from core to the user are distinct.
#
# Slow quota (1000000 * (0x8000 *  5 / 100)) / 0x8000 =  49987
# Slow quota (1000000 * (0x8000 * 20 / 100)) / 0x8000 = 199981
# Slow quota (1000000 * (0x8000 * 60 / 100)) / 0x8000 = 599975
#
check_quota "Slow test"   1000000 $slow_quota_sp  49987 $slow_quota
check_quota "Middle test" 1000000 $midl_quota_sp 199981 $midl_quota
check_quota "Fast test"   1000000 $fast_quota_sp 599975 $fast_quota

regexp {[0-9]+} [regexp -inline {slow. counter A [0-9]+} $output] slow_a_cnt
regexp {[0-9]+} [regexp -inline {midl. counter A [0-9]+} $output] midl_a_cnt
regexp {[0-9]+} [regexp -inline {fast. counter A [0-9]+} $output] fast_a_cnt
regexp {[0-9]+} [regexp -inline {slow. counter B [0-9]+} $output] slow_b_cnt
regexp {[0-9]+} [regexp -inline {midl. counter B [0-9]+} $output] midl_b_cnt
regexp {[0-9]+} [regexp -inline {fast. counter B [0-9]+} $output] fast_b_cnt

set total_cnt [expr $fast_a_cnt + $midl_a_cnt + $slow_a_cnt + $fast_b_cnt + $midl_b_cnt + $slow_b_cnt]

#
# Slow   5.0 % claim + 5.0 % fill = 10 %
#   Stage 1
#     A  0.5 % claim + 2.5 % fill =  3 %
#     B  4.5 % claim + 2.5 % fill =  7 %
#   Stage 2
#     A  5.0 % claim + 5.0 % fill = 10 %
#   Total
#     A  3/4 * 3 + 1/4 * 10 = 4.75 %
#     A  3/4 * 7 + 1/4 *  0 = 5.25 %
#
check_counter "Slow counter A"   0.0475 $slow_a_cnt $total_cnt
check_counter "Slow counter B"   0.0525 $slow_b_cnt $total_cnt

#
# Middle 20 % claim + 5.0 % fill = 25.0 %
#   Stage 1
#     A   2 % claim + 2.5 % fill =  4.5 %
#     B  18 % claim + 2.5 % fill = 20.5 %
#   Stage 2
#     A  20 % claim + 5.0 % fill = 25.0 %
#   Total
#     A  3/4 *  4.5 + 1/4 * 25 =  9.625 %
#     A  3/4 * 20.5 + 1/4 *  0 = 15.375 %
#
check_counter "Middle counter A" 0.09625 $midl_a_cnt $total_cnt
check_counter "Middle counter B" 0.15375 $midl_b_cnt $total_cnt

#
# Fast   60 % claim + 5.0 % fill = 65.0 %
#   Stage 1
#     A   6 % claim + 2.5 % fill =  8.5 %
#     B  54 % claim + 2.5 % fill = 56.5 %
#   Stage 2
#     A  60 % claim + 5.0 % fill = 65.0 %
#   Total
#     A  3/4 *  8.5 + 1/4 * 65 = 22.625 %
#     A  3/4 * 56.5 + 1/4 *  0 = 42.375 %
#
check_counter "Fast counter A" 0.22625 $fast_a_cnt $total_cnt
check_counter "Fast counter B" 0.42375 $fast_b_cnt $total_cnt

# final conclusion and return
if {[expr $err_cnt > 0]} {
	puts "Test failed because of $err_cnt errors"
	exit -1
}
puts "Test succeeded"