start_server {tags {"maxmemory"}} {
test "Without maxmemory small integers are shared" {
r config set maxmemory 0
r set a 1
assert {[r object refcount a] > 1}
}
test "With maxmemory and non-LRU policy integers are still shared" {
r config set maxmemory 1073741824
r config set maxmemory-policy allkeys-random
r set a 1
assert {[r object refcount a] > 1}
}
test "With maxmemory and LRU policy integers are not shared" {
r config set maxmemory 1073741824
r config set maxmemory-policy allkeys-lru
r set a 1
r config set maxmemory-policy volatile-lru
r set b 1
assert {[r object refcount a] == 1}
assert {[r object refcount b] == 1}
r config set maxmemory 0
}
foreach policy {
allkeys-random allkeys-lru volatile-lru volatile-random volatile-ttl
} {
test "maxmemory - is the memory limit honoured? (policy $policy)" {
# make sure to start with a blank instance
r flushall
# Get the current memory limit and calculate a new limit.
# We just add 100k to the current memory size so that it is
# fast for us to reach that limit.
set used [s used_memory]
set limit [expr {$used+100*1024}]
r config set maxmemory $limit
r config set maxmemory-policy $policy
# Now add keys until the limit is almost reached.
set numkeys 0
while 1 {
r setex [randomKey] 10000 x
incr numkeys
if {[s used_memory]+4096 > $limit} {
assert {$numkeys > 10}
break
}
}
# If we add the same number of keys already added again, we
# should still be under the limit.
for {set j 0} {$j < $numkeys} {incr j} {
r setex [randomKey] 10000 x
}
assert {[s used_memory] < ($limit+4096)}
}
}
foreach policy {
allkeys-random allkeys-lru volatile-lru volatile-random volatile-ttl
} {
test "maxmemory - only allkeys-* should remove non-volatile keys ($policy)" {
# make sure to start with a blank instance
r flushall
# Get the current memory limit and calculate a new limit.
# We just add 100k to the current memory size so that it is
# fast for us to reach that limit.
set used [s used_memory]
set limit [expr {$used+100*1024}]
r config set maxmemory $limit
r config set maxmemory-policy $policy
# Now add keys until the limit is almost reached.
set numkeys 0
while 1 {
r set [randomKey] x
incr numkeys
if {[s used_memory]+4096 > $limit} {
assert {$numkeys > 10}
break
}
}
# If we add the same number of keys already added again and
# the policy is allkeys-* we should still be under the limit.
# Otherwise we should see an error reported by Redis.
set err 0
for {set j 0} {$j < $numkeys} {incr j} {
if {[catch {r set [randomKey] x} e]} {
if {[string match {*used memory*} $e]} {
set err 1
}
}
}
if {[string match allkeys-* $policy]} {
assert {[s used_memory] < ($limit+4096)}
} else {
assert {$err == 1}
}
}
}
foreach policy {
volatile-lru volatile-random volatile-ttl
} {
test "maxmemory - policy $policy should only remove volatile keys." {
# make sure to start with a blank instance
r flushall
# Get the current memory limit and calculate a new limit.
# We just add 100k to the current memory size so that it is
# fast for us to reach that limit.
set used [s used_memory]
set limit [expr {$used+100*1024}]
r config set maxmemory $limit
r config set maxmemory-policy $policy
# Now add keys until the limit is almost reached.
set numkeys 0
while 1 {
# Odd keys are volatile
# Even keys are non volatile
if {$numkeys % 2} {
r setex "key:$numkeys" 10000 x
} else {
r set "key:$numkeys" x
}
if {[s used_memory]+4096 > $limit} {
assert {$numkeys > 10}
break
}
incr numkeys
}
# Now we add the same number of volatile keys already added.
# We expect Redis to evict only volatile keys in order to make
# space.
set err 0
for {set j 0} {$j < $numkeys} {incr j} {
catch {r setex "foo:$j" 10000 x}
}
# We should still be under the limit.
assert {[s used_memory] < ($limit+4096)}
# However all our non volatile keys should be here.
for {set j 0} {$j < $numkeys} {incr j 2} {
assert {[r exists "key:$j"]}
}
}
}
}