FAQ: MongoDB Diagnostics
On this page
- Where can I find information about a
mongod
process that stopped running unexpectedly? - Does TCP
keepalive
time affect MongoDB Deployments? - Do TCP Retransmission Timeouts affect MongoDB Deployments?
- Why does MongoDB log so many "Connection Accepted" events?
- What tools are available for monitoring MongoDB?
- Memory Diagnostics for the WiredTiger Storage Engine
- Sharded Cluster Diagnostics
This document provides answers to common diagnostic questions and issues.
If you don't find the answer you're looking for, check the complete list of FAQs or post your question to the MongoDB Community.
Where can I find information about a mongod
process that stopped running unexpectedly?
If mongod
shuts down unexpectedly on a UNIX or UNIX-based
platform, and if mongod
fails to log a shutdown or error
message, then check your system logs for messages pertaining to MongoDB.
For example, for logs located in /var/log/messages
, use the
following commands:
sudo grep mongod /var/log/messages sudo grep score /var/log/messages
Does TCP keepalive
time affect MongoDB Deployments?
If you experience network timeouts or socket errors in communication between clients and servers, or between members of a sharded cluster or replica set, check the TCP keepalive value for the affected systems.
Many operating systems set this value to 7200
seconds (two hours) by
default. For MongoDB, you will generally experience better results with
a shorter keepalive value, on the order of 120
seconds (two
minutes).
If your MongoDB deployment experiences keepalive-related issues, you
must alter the keepalive value on all affected systems. This includes
all machines running mongod
or mongos
processes and all machines hosting client processes that connect to
MongoDB.
Adjusting the TCP keepalive value:
To view the keepalive setting on Linux, use one of the following commands:
sysctl net.ipv4.tcp_keepalive_time Or:
cat /proc/sys/net/ipv4/tcp_keepalive_time The value is measured in seconds.
Note
Although the setting name includes
ipv4
, thetcp_keepalive_time
value applies to both IPv4 and IPv6.To change the
tcp_keepalive_time
value, you can use one of the following commands, supplying a <value> in seconds:sudo sysctl -w net.ipv4.tcp_keepalive_time=<value> Or:
echo <value> | sudo tee /proc/sys/net/ipv4/tcp_keepalive_time These operations do not persist across system reboots. To persist the setting, add the following line to
/etc/sysctl.conf
, supplying a <value> in seconds, and reboot the machine:net.ipv4.tcp_keepalive_time = <value> Keepalive values greater than
300
seconds, (5 minutes) will be overridden onmongod
andmongos
sockets and set to300
seconds.
To view the keepalive setting on Windows, issue the following command:
reg query HKLM\SYSTEM\CurrentControlSet\Services\Tcpip\Parameters /v KeepAliveTime The registry value is not present by default. The system default, used if the value is absent, is
7200000
milliseconds or0x6ddd00
in hexadecimal.To change the
KeepAliveTime
value, use the following command in an Administrator Command Prompt, where<value>
is expressed in hexadecimal (e.g.120000
is0x1d4c0
):reg add HKLM\SYSTEM\CurrentControlSet\Services\Tcpip\Parameters\ /t REG_DWORD /v KeepAliveTime /d <value> Windows users should consider the Windows Server Technet Article on KeepAliveTime for more information on setting keepalive for MongoDB deployments on Windows systems. Keepalive values greater than or equal to 600000 milliseconds (10 minutes) will be ignored by
mongod
andmongos
.
To view the keepalive setting on macOS, issue the following command:
sysctl net.inet.tcp.keepidle The value is measured in milliseconds.
To change the
net.inet.tcp.keepidle
value, you can use the following command, supplying a <value> in milliseconds:sudo sysctl net.inet.tcp.keepidle=<value> This operation does not persist across system reboots, and must be set each time your system reboots. See your operating system's documentation for instructions on setting this value persistently. Keepalive values greater than or equal to
600000
milliseconds (10 minutes) will be ignored bymongod
andmongos
.Note
In macOS 10.15 Catalina, Apple no longer allows for configuration of the
net.inet.tcp.keepidle
option.
You will need to restart mongod
and mongos
processes for new system-wide keepalive settings to take effect.
Do TCP Retransmission Timeouts affect MongoDB Deployments?
If you experience long stalls (stalls greater than two minutes) followed
by network timeouts or socket errors between clients and server
or between members of a sharded cluster or replica set,
check the tcp_retries2
value for the affected systems.
Most Linux operating systems set this value to 15
by default, while
Windows sets it to 5
. For MongoDB, you experience better results
with a lower tcp_retries2
value, on the order of 5
(12 seconds)
or lower.
If your MongoDB deployment experiences TCP retransmission timeout-related
issues, change the tcp_retries2
value (TcpMaxDataRetransmission
on Windows) for all affected systems. This includes all machines running
mongod
or mongos
processes and
all machines hosting client processes that connect to MongoDB.
Adjust the TCP Retransmission Timeout
On most Linux operating systems, control the TCP retransmission
by adjusting the net.ipv4.tcp_retries2
sysctl setting.
Note
Although the setting name includes ipv4
, the tcp_retries2
setting
applies to both IPv4 and IPv6.
To view the current setting, use the
sysctl
command:sysctl net.ipv4.tcp_retries2 net.ipv4.tcp_retries = 15 To change the
tcp_retries2
setting at runtime, use thesysctl
command:sysctl -w net.ipv4.tcp_retries2=8 To make the change permanent, edit the configuration file:
Open
/etc/sysctl.conf
in your preferred text editor:vi /etc/sysctl.conf Configure the
net.ipv4.tcp_retries2
setting:net.ipv4.tcp_retries2 = 8 Restart the system.
Your system now uses the new
tcp_retries2
setting.
On Windows, control TCP Retransmission by adjusting the
TcpMaxDataRetransmissions
parameter.
To view the
TcpMaxDataRetransmissions
setting on Windows, issue the following command:reg query HKLM\SYSTEM\CurrentControlSet\Services\Tcpip\Parameters /v TcpMaxDataRetransmissions By default, the parameter is not set. The system default, used if the value is absent, is
5
retries.To change the
TcpMaxDataRetransmissions
value, use the following command in an Administrator Command Prompt, where<value>
is an integer:reg add HKLM\SYSTEM\CurrentControlSet\Services\Tcpip\Parameters\ /t REG_DWORD /v TcpMaxDataRetransmission /d <value>
Why does MongoDB log so many "Connection Accepted" events?
If you see a very large number of connection and re-connection messages in your MongoDB log, then clients are frequently connecting and disconnecting to the MongoDB server. This is normal behavior for applications that do not use request pooling, such as CGI. Consider using FastCGI, an Apache Module, or some other kind of persistent application server to decrease the connection overhead.
If these connections do not impact your performance you can use the
run-time quiet
option or the command-line option
--quiet
to suppress these messages from the
log.
What tools are available for monitoring MongoDB?
The MongoDB Cloud Manager and Ops Manager, an on-premise solution available in MongoDB Enterprise Advanced include monitoring functionality, which collects data from running MongoDB deployments and provides visualization and alerts based on that data.
For more information, see also the MongoDB Cloud Manager documentation and Ops Manager documentation.
A full list of third-party tools is available as part of the Monitoring for MongoDB documentation.
Memory Diagnostics for the WiredTiger Storage Engine
Must my working set size fit RAM?
No.
If the cache does not have enough space to load additional data, WiredTiger evicts pages from the cache to free up space.
Note
The storage.wiredTiger.engineConfig.cacheSizeGB
limits the size of the WiredTiger internal
cache. The operating system will use the available free memory
for filesystem cache, which allows the compressed MongoDB data
files to stay in memory. In addition, the operating system will
use any free RAM to buffer file system blocks and file system
cache.
To accommodate the additional consumers of RAM, you may have to decrease WiredTiger internal cache size.
The default WiredTiger internal cache size value assumes that there is a
single mongod
instance per machine. If a single machine
contains multiple MongoDB instances, then you should decrease the setting to
accommodate the other mongod
instances.
If you run mongod
in a container (e.g. lxc
,
cgroups
, Docker, etc.) that does not have access to all of the
RAM available in a system, you must set storage.wiredTiger.engineConfig.cacheSizeGB
to a value
less than the amount of RAM available in the container. The exact
amount depends on the other processes running in the container. See
memLimitMB
.
To see statistics on the cache and eviction, use the
serverStatus
command. The
wiredTiger.cache
field holds the information on
the cache and eviction.
... "wiredTiger" : { ... "cache" : { "tracked dirty bytes in the cache" : <num>, "bytes currently in the cache" : <num>, "maximum bytes configured" : <num>, "bytes read into cache" :<num>, "bytes written from cache" : <num>, "pages evicted by application threads" : <num>, "checkpoint blocked page eviction" : <num>, "unmodified pages evicted" : <num>, "page split during eviction deepened the tree" : <num>, "modified pages evicted" : <num>, "pages selected for eviction unable to be evicted" : <num>, "pages evicted because they exceeded the in-memory maximum" : <num>,, "pages evicted because they had chains of deleted items" : <num>, "failed eviction of pages that exceeded the in-memory maximum" : <num>, "hazard pointer blocked page eviction" : <num>, "internal pages evicted" : <num>, "maximum page size at eviction" : <num>, "eviction server candidate queue empty when topping up" : <num>, "eviction server candidate queue not empty when topping up" : <num>, "eviction server evicting pages" : <num>, "eviction server populating queue, but not evicting pages" : <num>, "eviction server unable to reach eviction goal" : <num>, "pages split during eviction" : <num>, "pages walked for eviction" : <num>, "eviction worker thread evicting pages" : <num>, "in-memory page splits" : <num>, "percentage overhead" : <num>, "tracked dirty pages in the cache" : <num>, "pages currently held in the cache" : <num>, "pages read into cache" : <num>, "pages written from cache" : <num>, }, ...
For an explanation of some key cache and eviction statistics, such
as wiredTiger.cache.bytes currently in the cache
and wiredTiger.cache.tracked dirty bytes in the cache
, see wiredTiger.cache
.
To adjust the size of the WiredTiger internal cache, see
storage.wiredTiger.engineConfig.cacheSizeGB
and
--wiredTigerCacheSizeGB
. Avoid increasing the WiredTiger
internal cache size above its default value.
How do I calculate how much RAM I need for my application?
With WiredTiger, MongoDB utilizes both the WiredTiger internal cache and the filesystem cache.
Starting in MongoDB 3.4, the default WiredTiger internal cache size is the larger of either:
50% of (RAM - 1 GB), or
256 MB.
For example, on a system with a total of 4GB of RAM the WiredTiger
cache will use 1.5GB of RAM (0.5 * (4 GB - 1 GB) = 1.5 GB
).
Conversely, a system with a total of 1.25 GB of RAM will allocate 256
MB to the WiredTiger cache because that is more than half of the
total RAM minus one gigabyte (0.5 * (1.25 GB - 1 GB) = 128 MB < 256 MB
).
Note
In some instances, such as when running in a container, the database can have memory constraints that are lower than the total system memory. In such instances, this memory limit, rather than the total system memory, is used as the maximum RAM available.
To see the memory limit, see hostInfo.system.memLimitMB
.
By default, WiredTiger uses Snappy block compression for all collections and prefix compression for all indexes. Compression defaults are configurable at a global level and can also be set on a per-collection and per-index basis during collection and index creation.
Different representations are used for data in the WiredTiger internal cache versus the on-disk format:
Data in the filesystem cache is the same as the on-disk format, including benefits of any compression for data files. The filesystem cache is used by the operating system to reduce disk I/O.
Indexes loaded in the WiredTiger internal cache have a different data representation to the on-disk format, but can still take advantage of index prefix compression to reduce RAM usage. Index prefix compression deduplicates common prefixes from indexed fields.
Collection data in the WiredTiger internal cache is uncompressed and uses a different representation from the on-disk format. Block compression can provide significant on-disk storage savings, but data must be uncompressed to be manipulated by the server.
Via the filesystem cache, MongoDB automatically uses all free memory that is not used by the WiredTiger cache or by other processes.
To adjust the size of the WiredTiger internal cache, see
storage.wiredTiger.engineConfig.cacheSizeGB
and
--wiredTigerCacheSizeGB
. Avoid increasing the WiredTiger
internal cache size above its default value.
Note
The storage.wiredTiger.engineConfig.cacheSizeGB
limits the size of the WiredTiger internal
cache. The operating system will use the available free memory
for filesystem cache, which allows the compressed MongoDB data
files to stay in memory. In addition, the operating system will
use any free RAM to buffer file system blocks and file system
cache.
To accommodate the additional consumers of RAM, you may have to decrease WiredTiger internal cache size.
The default WiredTiger internal cache size value assumes that there is a
single mongod
instance per machine. If a single machine
contains multiple MongoDB instances, then you should decrease the setting to
accommodate the other mongod
instances.
If you run mongod
in a container (e.g. lxc
,
cgroups
, Docker, etc.) that does not have access to all of the
RAM available in a system, you must set storage.wiredTiger.engineConfig.cacheSizeGB
to a value
less than the amount of RAM available in the container. The exact
amount depends on the other processes running in the container. See
memLimitMB
.
To view statistics on the cache and eviction rate, see the
wiredTiger.cache
field
returned from the serverStatus
command.
Sharded Cluster Diagnostics
The two most important factors in maintaining a successful sharded cluster are:
While you can change your shard key later, it is important to carefully consider your shard key choice to avoid scalability and performance issues. Continue reading for specific issues you may encounter in a production environment.
In a new sharded cluster, why does all data remain on one shard?
Your cluster must have sufficient data for sharding to make sense. Sharding works by migrating chunks between the shards until each shard has roughly the same number of chunks.
The default chunk size is 128 megabytes. MongoDB will not begin migrations until the imbalance of chunks in the cluster exceeds the migration threshold. This behavior helps prevent unnecessary chunk migrations, which can degrade the performance of your cluster as a whole.
If you have just deployed a sharded cluster, make sure that you have enough data to make sharding effective. If you do not have sufficient data to create more than eight 128 megabyte chunks, then all data will remain on one shard. Either lower the chunk size setting, or add more data to the cluster.
As a related problem, the system will split chunks only on inserts or updates, which means that if you configure sharding and do not continue to issue insert and update operations, the database will not create any chunks. You can either wait until your application inserts data or split chunks manually.
Finally, if your shard key has a low cardinality, MongoDB may not be able to create sufficient splits among the data.
Why would one shard receive a disproportionate amount of traffic in a sharded cluster?
In some situations, a single shard or a subset of the cluster will receive a disproportionate portion of the traffic and workload. In almost all cases this is the result of a shard key that does not effectively allow write scaling.
It's also possible that you have "hot chunks." In this case, you may be able to solve the problem by splitting and then migrating parts of these chunks.
You may have to consider resharding your collection with a different shard key to correct this pattern.
What can prevent a sharded cluster from balancing?
If you have just deployed your sharded cluster, you may want to consider the troubleshooting suggestions for a new cluster where data remains on a single shard.
If the cluster was initially balanced, but later developed an uneven distribution of data, consider the following possible causes:
You have deleted or removed a significant amount of data from the cluster. If you have added additional data, it may have a different distribution with regards to its shard key.
Your shard key has low cardinality and MongoDB cannot split the chunks any further.
Your data set is growing faster than the balancer can distribute data around the cluster. This is uncommon and typically is the result of:
a balancing window that is too short, given the rate of data growth.
an uneven distribution of write operations that requires more data migration. You may have to choose a different shard key to resolve this issue.
poor network connectivity between shards, which may lead to chunk migrations that take too long to complete. Investigate your network configuration and interconnections between shards.
Why do chunk migrations affect sharded cluster performance?
If migrations impact your cluster or application's performance, consider the following options, depending on the nature of the impact:
If migrations only interrupt your clusters sporadically, you can limit the balancing window to prevent balancing activity during peak hours. Ensure that there is enough time remaining to keep the data from becoming out of balance again.
If the balancer is always migrating chunks to the detriment of overall cluster performance:
You may want to attempt decreasing the chunk size to limit the size of the migration.
Your cluster may be over capacity, and you may want to attempt to add one or two shards to the cluster to distribute load.
It's also possible that your shard key causes your application to direct all writes to a single shard. This kind of activity pattern can require the balancer to migrate most data soon after writing it. You may have to consider resharding your collection with a different shard key that provides better write scaling.