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redict/tests/unit/maxmemory.tcl
Wang Yuan c1718f9d86
Replication backlog and replicas use one global shared replication buffer (#9166) 
## Background
For redis master, one replica uses one copy of replication buffer, that is a big waste of memory,
more replicas more waste, and allocate/free memory for every reply list also cost much.
If we set client-output-buffer-limit small and write traffic is heavy, master may disconnect with
replicas and can't finish synchronization with replica. If we set  client-output-buffer-limit big,
master may be OOM when there are many replicas that separately keep much memory.
Because replication buffers of different replica client are the same, one simple idea is that
all replicas only use one replication buffer, that will effectively save memory.

Since replication backlog content is the same as replicas' output buffer, now we
can discard replication backlog memory and use global shared replication buffer
to implement replication backlog mechanism.

## Implementation
I create one global "replication buffer" which contains content of replication stream.
The structure of "replication buffer" is similar to the reply list that exists in every client.
But the node of list is `replBufBlock`, which has `id, repl_offset, refcount` fields.
```c
/* Replication buffer blocks is the list of replBufBlock.
 *
 * +--------------+       +--------------+       +--------------+
 * | refcount = 1 |  ...  | refcount = 0 |  ...  | refcount = 2 |
 * +--------------+       +--------------+       +--------------+
 *      |                                            /       \
 *      |                                           /         \
 *      |                                          /           \
 *  Repl Backlog                               Replia_A      Replia_B
 * 
 * Each replica or replication backlog increments only the refcount of the
 * 'ref_repl_buf_node' which it points to. So when replica walks to the next
 * node, it should first increase the next node's refcount, and when we trim
 * the replication buffer nodes, we remove node always from the head node which
 * refcount is 0. If the refcount of the head node is not 0, we must stop
 * trimming and never iterate the next node. */

/* Similar with 'clientReplyBlock', it is used for shared buffers between
 * all replica clients and replication backlog. */
typedef struct replBufBlock {
    int refcount;           /* Number of replicas or repl backlog using. */
    long long id;           /* The unique incremental number. */
    long long repl_offset;  /* Start replication offset of the block. */
    size_t size, used;
    char buf[];
} replBufBlock;
```
So now when we feed replication stream into replication backlog and all replicas, we only need
to feed stream into replication buffer `feedReplicationBuffer`. In this function, we set some fields of
replication backlog and replicas to references of the global replication buffer blocks. And we also
need to check replicas' output buffer limit to free if exceeding `client-output-buffer-limit`, and trim
replication backlog if exceeding `repl-backlog-size`.

When sending reply to replicas, we also need to iterate replication buffer blocks and send its
content, when totally sending one block for replica, we decrease current node count and
increase the next current node count, and then free the block which reference is 0 from the
head of replication buffer blocks.

Since now we use linked list to manage replication backlog, it may cost much time for iterating
all linked list nodes to find corresponding replication buffer node. So we create a rax tree to
store some nodes  for index, but to avoid rax tree occupying too much memory, i record
one per 64 nodes for index.

Currently, to make partial resynchronization as possible as much, we always let replication
backlog as the last reference of replication buffer blocks, backlog size may exceeds our setting
if slow replicas that reference vast replication buffer blocks, and this method doesn't increase
memory usage since they share replication buffer. To avoid freezing server for freeing unreferenced
replication buffer blocks when we need to trim backlog for exceeding backlog size setting,
we trim backlog incrementally (free 64 blocks per call now), and make it faster in
`beforeSleep` (free 640 blocks).

### Other changes
- `mem_total_replication_buffers`: we add this field in INFO command, it means the total
  memory of replication buffers used.
- `mem_clients_slaves`:  now even replica is slow to replicate, and its output buffer memory
  is not 0, but it still may be 0, since replication backlog and replicas share one global replication
  buffer, only if replication buffer memory is more than the repl backlog setting size, we consider
  the excess as replicas' memory. Otherwise, we think replication buffer memory is the consumption
  of repl backlog.
- Key eviction
  Since all replicas and replication backlog share global replication buffer, we think only the
  part of exceeding backlog size the extra separate consumption of replicas.
  Because we trim backlog incrementally in the background, backlog size may exceeds our
  setting if slow replicas that reference vast replication buffer blocks disconnect.
  To avoid massive eviction loop, we don't count the delayed freed replication backlog into
  used memory even if there are no replicas, i.e. we also regard this memory as replicas's memory.
- `client-output-buffer-limit` check for replica clients
  It doesn't make sense to set the replica clients output buffer limit lower than the repl-backlog-size
  config (partial sync will succeed and then replica will get disconnected). Such a configuration is
  ignored (the size of repl-backlog-size will be used). This doesn't have memory consumption
  implications since the replica client will share the backlog buffers memory.
- Drop replication backlog after loading data if needed
  We always create replication backlog if server is a master, we need it because we put DELs in
  it when loading expired keys in RDB, but if RDB doesn't have replication info or there is no rdb,
  it is not possible to support partial resynchronization, to avoid extra memory of replication backlog,
  we drop it.
- Multi IO threads
 Since all replicas and replication backlog use global replication buffer,  if I/O threads are enabled,
  to guarantee data accessing thread safe, we must let main thread handle sending the output buffer
  to all replicas. But before, other IO threads could handle sending output buffer of all replicas.

## Other optimizations
This solution resolve some other problem:
- When replicas disconnect with master since of out of output buffer limit, releasing the output
  buffer of replicas may freeze server if we set big `client-output-buffer-limit` for replicas, but now,
  it doesn't cause freezing.
- This implementation may mitigate reply list copy cost time(also freezes server) when one replication
  has huge reply buffer and another replica can copy buffer for full synchronization. now, we just copy
  reference info, it is very light.
- If we set replication backlog size big, it also may cost much time to copy replication backlog into
  replica's output buffer. But this commit eliminates this problem.
- Resizing replication backlog size doesn't empty current replication backlog content.
2021-10-25 09:24:31 +03:00

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start_server {tags {"maxmemory" "external:skip"}} {
r config set maxmemory 11mb
r config set maxmemory-policy allkeys-lru
set server_pid [s process_id]
proc init_test {client_eviction} {
r flushdb
set prev_maxmemory_clients [r config get maxmemory-clients]
if $client_eviction {
r config set maxmemory-clients 3mb
r client no-evict on
} else {
r config set maxmemory-clients 0
}
r config resetstat
# fill 5mb using 50 keys of 100kb
for {set j 0} {$j < 50} {incr j} {
r setrange $j 100000 x
}
assert_equal [r dbsize] 50
}
# Return true if the eviction occurred (client or key) based on argument
proc check_eviction_test {client_eviction} {
set evicted_keys [s evicted_keys]
set evicted_clients [s evicted_clients]
set dbsize [r dbsize]
if $client_eviction {
return [expr $evicted_clients > 0 && $evicted_keys == 0 && $dbsize == 50]
} else {
return [expr $evicted_clients == 0 && $evicted_keys > 0 && $dbsize < 50]
}
}
# Assert the eviction test passed (and prints some debug info on verbose)
proc verify_eviction_test {client_eviction} {
set evicted_keys [s evicted_keys]
set evicted_clients [s evicted_clients]
set dbsize [r dbsize]
if $::verbose {
puts "evicted keys: $evicted_keys"
puts "evicted clients: $evicted_clients"
puts "dbsize: $dbsize"
}
assert [check_eviction_test $client_eviction]
}
foreach {client_eviction} {false true} {
set clients {}
test "eviction due to output buffers of many MGET clients, client eviction: $client_eviction" {
init_test $client_eviction
for {set j 0} {$j < 20} {incr j} {
set rr [redis_deferring_client]
lappend clients $rr
}
# Generate client output buffers via MGET until we can observe some effect on
# keys / client eviction, or we time out.
set t [clock seconds]
while {![check_eviction_test $client_eviction] && [expr [clock seconds] - $t] < 20} {
foreach rr $clients {
if {[catch {
$rr mget 1
$rr flush
} err]} {
lremove clients $rr
}
}
}
verify_eviction_test $client_eviction
}
foreach rr $clients {
$rr close
}
set clients {}
test "eviction due to input buffer of a dead client, client eviction: $client_eviction" {
init_test $client_eviction
for {set j 0} {$j < 30} {incr j} {
set rr [redis_deferring_client]
lappend clients $rr
}
foreach rr $clients {
if {[catch {
$rr write "*250\r\n"
for {set j 0} {$j < 249} {incr j} {
$rr write "\$1000\r\n"
$rr write [string repeat x 1000]
$rr write "\r\n"
$rr flush
}
}]} {
lremove clients $rr
}
}
verify_eviction_test $client_eviction
}
foreach rr $clients {
$rr close
}
set clients {}
test "eviction due to output buffers of pubsub, client eviction: $client_eviction" {
init_test $client_eviction
for {set j 0} {$j < 20} {incr j} {
set rr [redis_client]
lappend clients $rr
}
foreach rr $clients {
$rr subscribe bla
}
# Generate client output buffers via PUBLISH until we can observe some effect on
# keys / client eviction, or we time out.
set bigstr [string repeat x 100000]
set t [clock seconds]
while {![check_eviction_test $client_eviction] && [expr [clock seconds] - $t] < 20} {
if {[catch { r publish bla $bigstr } err]} {
if $::verbose {
puts "Error publishing: $err"
}
}
}
verify_eviction_test $client_eviction
}
foreach rr $clients {
$rr close
}
}
}
start_server {tags {"maxmemory external:skip"}} {
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 allkeys-lfu volatile-lru volatile-lfu 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-lfu 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"]}
}
}
}
}
# Calculate query buffer memory of slave
proc slave_query_buffer {srv} {
set clients [split [$srv client list] "\r\n"]
set c [lsearch -inline $clients *flags=S*]
if {[string length $c] > 0} {
assert {[regexp {qbuf=([0-9]+)} $c - qbuf]}
assert {[regexp {qbuf-free=([0-9]+)} $c - qbuf_free]}
return [expr $qbuf + $qbuf_free]
}
return 0
}
proc test_slave_buffers {test_name cmd_count payload_len limit_memory pipeline} {
start_server {tags {"maxmemory external:skip"}} {
start_server {} {
set slave_pid [s process_id]
test "$test_name" {
set slave [srv 0 client]
set slave_host [srv 0 host]
set slave_port [srv 0 port]
set master [srv -1 client]
set master_host [srv -1 host]
set master_port [srv -1 port]
# Disable slow log for master to avoid memory growth in slow env.
$master config set slowlog-log-slower-than -1
# add 100 keys of 100k (10MB total)
for {set j 0} {$j < 100} {incr j} {
$master setrange "key:$j" 100000 asdf
}
# make sure master doesn't disconnect slave because of timeout
$master config set repl-timeout 1200 ;# 20 minutes (for valgrind and slow machines)
$master config set maxmemory-policy allkeys-random
$master config set client-output-buffer-limit "replica 100000000 100000000 300"
$master config set repl-backlog-size [expr {10*1024}]
$slave slaveof $master_host $master_port
wait_for_condition 50 100 {
[s 0 master_link_status] eq {up}
} else {
fail "Replication not started."
}
# measure used memory after the slave connected and set maxmemory
set orig_used [s -1 used_memory]
set orig_client_buf [s -1 mem_clients_normal]
set orig_mem_not_counted_for_evict [s -1 mem_not_counted_for_evict]
set orig_used_no_repl [expr {$orig_used - $orig_mem_not_counted_for_evict}]
set limit [expr {$orig_used - $orig_mem_not_counted_for_evict + 32*1024}]
if {$limit_memory==1} {
$master config set maxmemory $limit
}
# put the slave to sleep
set rd_slave [redis_deferring_client]
exec kill -SIGSTOP $slave_pid
# send some 10mb worth of commands that don't increase the memory usage
if {$pipeline == 1} {
set rd_master [redis_deferring_client -1]
for {set k 0} {$k < $cmd_count} {incr k} {
$rd_master setrange key:0 0 [string repeat A $payload_len]
}
for {set k 0} {$k < $cmd_count} {incr k} {
$rd_master read
}
} else {
for {set k 0} {$k < $cmd_count} {incr k} {
$master setrange key:0 0 [string repeat A $payload_len]
}
}
set new_used [s -1 used_memory]
set slave_buf [s -1 mem_clients_slaves]
set client_buf [s -1 mem_clients_normal]
set mem_not_counted_for_evict [s -1 mem_not_counted_for_evict]
set used_no_repl [expr {$new_used - $mem_not_counted_for_evict - [slave_query_buffer $master]}]
# we need to exclude replies buffer and query buffer of replica from used memory.
# removing the replica (output) buffers is done so that we are able to measure any other
# changes to the used memory and see that they're insignificant (the test's purpose is to check that
# the replica buffers are counted correctly, so the used memory growth after deducting them
# should be nearly 0).
# we remove the query buffers because on slow test platforms, they can accumulate many ACKs.
set delta [expr {($used_no_repl - $client_buf) - ($orig_used_no_repl - $orig_client_buf)}]
assert {[$master dbsize] == 100}
assert {$slave_buf > 2*1024*1024} ;# some of the data may have been pushed to the OS buffers
set delta_max [expr {$cmd_count / 2}] ;# 1 byte unaccounted for, with 1M commands will consume some 1MB
assert {$delta < $delta_max && $delta > -$delta_max}
$master client kill type slave
set info_str [$master info memory]
set killed_used [getInfoProperty $info_str used_memory]
set killed_mem_not_counted_for_evict [getInfoProperty $info_str mem_not_counted_for_evict]
set killed_slave_buf [s -1 mem_clients_slaves]
# we need to exclude replies buffer and query buffer of slave from used memory after kill slave
set killed_used_no_repl [expr {$killed_used - $killed_mem_not_counted_for_evict - [slave_query_buffer $master]}]
set delta_no_repl [expr {$killed_used_no_repl - $used_no_repl}]
assert {[$master dbsize] == 100}
assert {$killed_slave_buf == 0}
assert {$delta_no_repl > -$delta_max && $delta_no_repl < $delta_max}
}
# unfreeze slave process (after the 'test' succeeded or failed, but before we attempt to terminate the server
exec kill -SIGCONT $slave_pid
}
}
}
# test that slave buffer are counted correctly
# we wanna use many small commands, and we don't wanna wait long
# so we need to use a pipeline (redis_deferring_client)
# that may cause query buffer to fill and induce eviction, so we disable it
test_slave_buffers {slave buffer are counted correctly} 1000000 10 0 1
# test that slave buffer don't induce eviction
# test again with fewer (and bigger) commands without pipeline, but with eviction
test_slave_buffers "replica buffer don't induce eviction" 100000 100 1 0
start_server {tags {"maxmemory external:skip"}} {
test {Don't rehash if used memory exceeds maxmemory after rehash} {
r config set maxmemory 0
r config set maxmemory-policy allkeys-random
# Next rehash size is 8192, that will eat 64k memory
populate 4096 "" 1
set used [s used_memory]
set limit [expr {$used + 10*1024}]
r config set maxmemory $limit
r set k1 v1
# Next writing command will trigger evicting some keys if last
# command trigger DB dict rehash
r set k2 v2
# There must be 4098 keys because redis doesn't evict keys.
r dbsize
} {4098}
}
start_server {tags {"maxmemory external:skip"}} {
test {client tracking don't cause eviction feedback loop} {
r config set maxmemory 0
r config set maxmemory-policy allkeys-lru
r config set maxmemory-eviction-tenacity 100
# 10 clients listening on tracking messages
set clients {}
for {set j 0} {$j < 10} {incr j} {
lappend clients [redis_deferring_client]
}
foreach rd $clients {
$rd HELLO 3
$rd read ; # Consume the HELLO reply
$rd CLIENT TRACKING on
$rd read ; # Consume the CLIENT reply
}
# populate 300 keys, with long key name and short value
for {set j 0} {$j < 300} {incr j} {
set key $j[string repeat x 1000]
r set $key x
# for each key, enable caching for this key
foreach rd $clients {
$rd get $key
$rd read
}
}
# we need to wait one second for the client querybuf excess memory to be
# trimmed by cron, otherwise the INFO used_memory and CONFIG maxmemory
# below (on slow machines) won't be "atomic" and won't trigger eviction.
after 1100
# set the memory limit which will cause a few keys to be evicted
# we need to make sure to evict keynames of a total size of more than
# 16kb since the (PROTO_REPLY_CHUNK_BYTES), only after that the
# invalidation messages have a chance to trigger further eviction.
set used [s used_memory]
set limit [expr {$used - 40000}]
r config set maxmemory $limit
# make sure some eviction happened
set evicted [s evicted_keys]
if {$::verbose} { puts "evicted: $evicted" }
# make sure we didn't drain the database
assert_range [r dbsize] 200 300
assert_range $evicted 10 50
foreach rd $clients {
$rd read ;# make sure we have some invalidation message waiting
$rd close
}
# eviction continues (known problem described in #8069)
# for now this test only make sures the eviction loop itself doesn't
# have feedback loop
set evicted [s evicted_keys]
if {$::verbose} { puts "evicted: $evicted" }
}
}
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