Redis CLI
The redis-cli
(Redis command line interface) is a terminal program used to send commands to and read replies from the Redis server. It has two main modes: an interactive REPL (Read Eval Print Loop) mode where the user types Redis commands and receives replies, and a command mode where redis-cli
is executed with additional arguments and the reply is printed to the standard output.
In interactive mode, redis-cli
has basic line editing capabilities to provide a familiar tyPING experience.
There are several options you can use to launch the program in special modes. You can simulate a replica and print the replication stream it receives from the primary, check the latency of a Redis server and display statistics, or request ASCII-art spectrogram of latency samples and frequencies, among many other things.
This guide will cover the different aspects of redis-cli
, starting from the simplest and ending with the more advanced features.
Command line usage
To run a Redis command and receive its reply as standard output to the terminal, include the command to execute as separate arguments of redis-cli
:
$ redis-cli INCR mycounter
(integer) 7
The reply of the command is “7”. Since Redis replies are typed (strings, arrays, integers, nil, errors, etc.), you see the type of the reply between praenthesis. This additional information may not be ideal when the output of redis-cli
must be used as input of another command or redirected into a file.
redis-cli
only shows additional information for human readibility when it detects the standard output is a tty, or terminal. For all other outputs it will auto-enable the raw output mode, as in the following example:
$ redis-cli INCR mycounter > /tmp/output.txt
$ cat /tmp/output.txt
8
Notice that (integer)
was omitted from the output since redis-cli
detected
the output was no longer written to the terminal. You can force raw output
even on the terminal with the --raw
option:
$ redis-cli --raw INCR mycounter
9
You can force human readable output when writing to a file or in
pipe to other commands by using --no-raw
.
Host, port, password and database
By default redis-cli
connects to the server at the address 127.0.0.1 with port 6379.
You can change this using several command line options. To specify a different host name or an IP address, use the -h
option. In order to set a different port, use -p
.
$ redis-cli -h redis15.localnet.org -p 6390 PING
PONG
If your instance is password protected, the -a <password>
option will
preform authentication saving the need of explicitly using the AUTH
command:
$ redis-cli -a myUnguessablePazzzzzword123 PING
PONG
For safety it is strongly advised to provide the password to redis-cli
automatically via the
REDISCLI_AUTH
environment variable.
Finally, it’s possible to send a command that operates on a database number
other than the default number zero by using the -n <dbnum>
option:
$ redis-cli FLUSHALL
OK
$ redis-cli -n 1 INCR a
(integer) 1
$ redis-cli -n 1 INCR a
(integer) 2
$ redis-cli -n 2 INCR a
(integer) 1
Some or all of this information can also be provided by using the -u <uri>
option and the URI pattern redis://user:password@host:port/dbnum
:
$ redis-cli -u redis://LJenkins:p%40ssw0rd@redis-16379.hosted.com:16379/0 PING
PONG
SSL/TLS
By default, redis-cli
uses a plain TCP connection to connect to Redis.
You may enable SSL/TLS using the --tls
option, along with --cacert
or
--cacertdir
to configure a trusted root certificate bundle or directory.
If the target server requires authentication using a client side certificate,
you can specify a certificate and a corresponding private key using --cert
and
--key
.
Getting input from other programs
There are two ways you can use redis-cli
in order to receive input from other
commands via the standard input. One is to use the target payload as the last argument
from stdin. For example, in order to set the Redis key net_services
to the content of the file /etc/services
from a local file system, use the -x
option:
$ redis-cli -x SET net_services < /etc/services
OK
$ redis-cli GETRANGE net_services 0 50
"#\n# Network services, Internet style\n#\n# Note that "
In the first line of the above session, redis-cli
was executed with the -x
option and a file was redirected to the CLI’s
standard input as the value to satisfy the SET net_services
command phrase. This is useful for scripting.
A different approach is to feed redis-cli
a sequence of commands written in a
text file:
$ cat /tmp/commands.txt
SET item:3374 100
INCR item:3374
APPEND item:3374 xxx
GET item:3374
$ cat /tmp/commands.txt | redis-cli
OK
(integer) 101
(integer) 6
"101xxx"
All the commands in commands.txt
are executed consecutively by
redis-cli
as if they were typed by the user in interactive mode. Strings can be
quoted inside the file if needed, so that it’s possible to have single
arguments with spaces, newlines, or other special characters:
$ cat /tmp/commands.txt
SET arg_example "This is a single argument"
STRLEN arg_example
$ cat /tmp/commands.txt | redis-cli
OK
(integer) 25
Continuously run the same command
It is possible to execute a signle command a specified number of times
with a user-selected pause between executions. This is useful in
different contexts - for example when we want to continuously monitor some
key content or INFO
field output, or when we want to simulate some
recurring write event, such as pushing a new item into a list every 5 seconds.
This feature is controlled by two options: -r <count>
and -i <delay>
.
The -r
option states how many times to run a command and -i
sets
the delay between the different command calls in seconds (with the ability
to specify values such as 0.1 to represent 100 milliseconds).
By default the interval (or delay) is set to 0, so commands are just executed ASAP:
$ redis-cli -r 5 INCR counter_value
(integer) 1
(integer) 2
(integer) 3
(integer) 4
(integer) 5
To run the same command indefinitely, use -1
as the count value.
To monitor over time the RSS memory size it’s possible to use the following command:
$ redis-cli -r -1 -i 1 INFO | grep rss_human
used_memory_rss_human:2.71M
used_memory_rss_human:2.73M
used_memory_rss_human:2.73M
used_memory_rss_human:2.73M
... a new line will be printed each second ...
Mass insertion of data using redis-cli
Mass insertion using redis-cli
is covered in a separate page as it is a
worthwhile topic itself. Please refer to our mass insertion guide.
CSV output
A CSV (Comma Separated Values) output feature exists within redis-cli
to export data from Redis to an external program.
$ redis-cli LPUSH mylist a b c d
(integer) 4
$ redis-cli --csv LRANGE mylist 0 -1
"d","c","b","a"
Note that the --csv
flag will only work on a single command, not the entirety of a DB as an export.
Running Lua scripts
The redis-cli
has extensive support for using the debugging facility
of Lua scripting, available with Redis 3.2 onwards. For this feature, refer to the Redis Lua debugger documentation.
Even without using the debugger, redis-cli
can be used to
run scripts from a file as an argument:
$ cat /tmp/script.lua
return redis.call('SET',KEYS[1],ARGV[1])
$ redis-cli --eval /tmp/script.lua location:hastings:temp , 23
OK
The Redis EVAL
command takes the list of keys the script uses, and the
other non key arguments, as different arrays. When calling EVAL
you
provide the number of keys as a number.
When calling redis-cli
with the --eval
option above, there is no need to specify the number of keys
explicitly. Instead it uses the convention of separating keys and arguments
with a comma. This is why in the above call you see location:hastings:temp , 23
as arguments.
So location:hastings:temp
will populate the KEYS
array, and 23
the ARGV
array.
The --eval
option is useful when writing simple scripts. For more
complex work, the Lua debugger is recommended. It is possible to mix the two approaches, since the debugger can also execute scripts from an external file.
Interactive mode
We have explored how to use the Redis CLI as a command line program.
This is useful for scripts and certain types of testing, however most
people will spend the majority of time in redis-cli
using its interactive
mode.
In interactive mode the user types Redis commands at the prompt. The command is sent to the server, processed, and the reply is parsed back and rendered into a simpler form to read.
Nothing special is needed for running the redis-cli
in interactive mode -
just execute it without any arguments
$ redis-cli
127.0.0.1:6379> PING
PONG
The string 127.0.0.1:6379>
is the prompt. It displays the connected Redis server instance’s hostname and port.
The prompt updates as the connected server changes or when operating on a database different from the database number zero:
127.0.0.1:6379> SELECT 2
OK
127.0.0.1:6379[2]> DBSIZE
(integer) 1
127.0.0.1:6379[2]> SELECT 0
OK
127.0.0.1:6379> DBSIZE
(integer) 503
Handling connections and reconnections
Using the CONNECT
command in interactive mode makes it possible to connect
to a different instance, by specifying the hostname and port we want
to connect to:
127.0.0.1:6379> CONNECT metal 6379
metal:6379> PING
PONG
As you can see the prompt changes accordingly when connecting to a different server instance.
If a connection is attempted to an instance that is unreachable, the redis-cli
goes into disconnected
mode and attempts to reconnect with each new command:
127.0.0.1:6379> CONNECT 127.0.0.1 9999
Could not connect to Redis at 127.0.0.1:9999: Connection refused
not connected> PING
Could not connect to Redis at 127.0.0.1:9999: Connection refused
not connected> PING
Could not connect to Redis at 127.0.0.1:9999: Connection refused
Generally after a disconnection is detected, redis-cli
always attempts to
reconnect transparently; if the attempt fails, it shows the error and
enters the disconnected state. The following is an example of disconnection
and reconnection:
127.0.0.1:6379> INFO SERVER
Could not connect to Redis at 127.0.0.1:6379: Connection refused
not connected> PING
PONG
127.0.0.1:6379>
(now we are connected again)
When a reconnection is performed, redis-cli
automatically re-selects the
last database number selected. However, all other states about the
connection is lost, such as within a MULTI/EXEC transaction:
$ redis-cli
127.0.0.1:6379> MULTI
OK
127.0.0.1:6379> PING
QUEUED
( here the server is manually restarted )
127.0.0.1:6379> EXEC
(error) ERR EXEC without MULTI
This is usually not an issue when using the redis-cli
in interactive mode for
testing, but this limitation should be known.
Editing, history, completion and hints
Because redis-cli
uses the
linenoise line editing library, it
always has line editing capabilities, without depending on libreadline
or
other optional libraries.
Command execution history can be accessed in order to avoid retyping commands by pressing the arrow keys (up and down).
The history is preserved between restarts of the CLI, in a file named
.rediscli_history
inside the user home directory, as specified
by the HOME
environment variable. It is possible to use a different
history filename by setting the REDISCLI_HISTFILE
environment variable,
and disable it by setting it to /dev/null
.
The redis-cli
is also able to perform command-name completion by pressing the TAB
key, as in the following example:
127.0.0.1:6379> Z<TAB>
127.0.0.1:6379> ZADD<TAB>
127.0.0.1:6379> ZCARD<TAB>
Once Redis command name has been entered at the prompt, the redis-cli
will display
syntax hints. Like command history, this behavior can be turned on and off via the redis-cli
preferences.
Preferences
There are two ways to customize redis-cli
behavior. The file .redisclirc
in the home directory is loaded by the CLI on startup. You can override the
file’s default location by setting the REDISCLI_RCFILE
environment variable to
an alternative path. Preferences can also be set during a CLI session, in which
case they will last only the duration of the session.
To set preferences, use the special :set
command. The following preferences
can be set, either by typing the command in the CLI or adding it to the
.redisclirc
file:
:set hints
- enables syntax hints:set nohints
- disables syntax hints
Running the same command N times
It is possible to run the same command multiple times in interactive mode by prefixing the command name by a number:
127.0.0.1:6379> 5 INCR mycounter
(integer) 1
(integer) 2
(integer) 3
(integer) 4
(integer) 5
Showing help about Redis commands
redis-cli
provides online help for most Redis commands, using the HELP
command. The command can be used
in two forms:
HELP @<category>
shows all the commands about a given category. The categories are:@generic
@string
@list
@set
@sorted_set
@hash
@pubsub
@transactions
@connection
@server
@scripting
@hyperloglog
@cluster
@geo
@stream
HELP <commandname>
shows specific help for the command given as argument.
For example in order to show help for the PFADD
command, use:
127.0.0.1:6379> HELP PFADD
PFADD key element [element ...]
summary: Adds the specified elements to the specified HyperLogLog.
since: 2.8.9
Note that HELP
supports TAB completion as well.
Clearing the terminal screen
Using the CLEAR
command in interactive mode clears the terminal’s screen.
Special modes of operation
So far we saw two main modes of redis-cli
.
- Command line execution of Redis commands.
- Interactive “REPL” usage.
The CLI performs other auxiliary tasks related to Redis that are explained in the next sections:
- Monitoring tool to show continuous stats about a Redis server.
- Scanning a Redis database for very large keys.
- Key space scanner with pattern matching.
- Acting as a Pub/Sub client to subscribe to channels.
- Monitoring the commands executed into a Redis instance.
- Checking the latency of a Redis server in different ways.
- Checking the scheduler latency of the local computer.
- Transferring RDB backups from a remote Redis server locally.
- Acting as a Redis replica for showing what a replica receives.
- Simulating LRU workloads for showing stats about keys hits.
- A client for the Lua debugger.
Continuous stats mode
Continuous stats mode is probably one of the lesser known yet very useful features of redis-cli
to monitor Redis instances in real time. To enable this mode, the --stat
option is used.
The output is very clear about the behavior of the CLI in this mode:
$ redis-cli --stat
------- data ------ --------------------- load -------------------- - child -
keys mem clients blocked requests connections
506 1015.00K 1 0 24 (+0) 7
506 1015.00K 1 0 25 (+1) 7
506 3.40M 51 0 60461 (+60436) 57
506 3.40M 51 0 146425 (+85964) 107
507 3.40M 51 0 233844 (+87419) 157
507 3.40M 51 0 321715 (+87871) 207
508 3.40M 51 0 408642 (+86927) 257
508 3.40M 51 0 497038 (+88396) 257
In this mode a new line is printed every second with useful information and differences of request values between old data points. Memory usage, client connection counts, and various other statistics about the connected Redis database can be easily understood with this auxiliary redis-cli
tool.
The -i <interval>
option in this case works as a modifier in order to
change the frequency at which new lines are emitted. The default is one
second.
Scanning for big keys
In this special mode, redis-cli
works as a key space analyzer. It scans the
dataset for big keys, but also provides information about the data types
that the data set consists of. This mode is enabled with the --bigkeys
option,
and produces verbose output:
$ redis-cli --bigkeys
# Scanning the entire keyspace to find biggest keys as well as
# average sizes per key type. You can use -i 0.01 to sleep 0.01 sec
# per SCAN command (not usually needed).
[00.00%] Biggest string found so far 'key-419' with 3 bytes
[05.14%] Biggest list found so far 'mylist' with 100004 items
[35.77%] Biggest string found so far 'counter:__rand_int__' with 6 bytes
[73.91%] Biggest hash found so far 'myobject' with 3 fields
-------- summary -------
Sampled 506 keys in the keyspace!
Total key length in bytes is 3452 (avg len 6.82)
Biggest string found 'counter:__rand_int__' has 6 bytes
Biggest list found 'mylist' has 100004 items
Biggest hash found 'myobject' has 3 fields
504 strings with 1403 bytes (99.60% of keys, avg size 2.78)
1 lists with 100004 items (00.20% of keys, avg size 100004.00)
0 sets with 0 members (00.00% of keys, avg size 0.00)
1 hashs with 3 fields (00.20% of keys, avg size 3.00)
0 zsets with 0 members (00.00% of keys, avg size 0.00)
In the first part of the output, each new key larger than the previous larger key (of the same type) encountered is reported. The summary section provides general stats about the data inside the Redis instance.
The program uses the SCAN
command, so it can be executed against a busy
server without impacting the operations, however the -i
option can be
used in order to throttle the scanning process of the specified fraction
of second for each SCAN
command.
For example, -i 0.01
will slow down the program execution considerably, but will also reduce the load on the server
to a negligible amount.
Note that the summary also reports in a cleaner form the biggest keys found for each time. The initial output is just to provide some interesting info ASAP if running against a very large data set.
Getting a list of keys
It is also possible to scan the key space, again in a way that does not
block the Redis server (which does happen when you use a command
like KEYS *
), and print all the key names, or filter them for specific
patterns. This mode, like the --bigkeys
option, uses the SCAN
command,
so keys may be reported multiple times if the dataset is changing, but no
key would ever be missing, if that key was present since the start of the
iteration. Because of the command that it uses this option is called --scan
.
$ redis-cli --scan | head -10
key-419
key-71
key-236
key-50
key-38
key-458
key-453
key-499
key-446
key-371
Note that head -10
is used in order to print only the first lines of the
output.
Scanning is able to use the underlying pattern matching capability of
the SCAN
command with the --pattern
option.
$ redis-cli --scan --pattern '*-11*'
key-114
key-117
key-118
key-113
key-115
key-112
key-119
key-11
key-111
key-110
key-116
Piping the output through the wc
command can be used to count specific
kind of objects, by key name:
$ redis-cli --scan --pattern 'user:*' | wc -l
3829433
You can use -i 0.01
to add a delay between calls to the SCAN
command.
This will make the command slower but will significantly reduce load on the server.
Pub/sub mode
The CLI is able to publish messages in Redis Pub/Sub channels using
the PUBLISH
command. Subscribing to channels in order to receive
messages is different - the terminal is blocked and waits for
messages, so this is implemented as a special mode in redis-cli
. Unlike
other special modes this mode is not enabled by using a special option,
but simply by using the SUBSCRIBE
or PSUBSCRIBE
command, which are available in
interactive or command mode:
$ redis-cli PSUBSCRIBE '*'
Reading messages... (press Ctrl-C to quit)
1) "PSUBSCRIBE"
2) "*"
3) (integer) 1
The reading messages message shows that we entered Pub/Sub mode.
When another client publishes some message in some channel, such as with the command redis-cli PUBLISH mychannel mymessage
, the CLI in Pub/Sub mode will show something such as:
1) "pmessage"
2) "*"
3) "mychannel"
4) "mymessage"
This is very useful for debugging Pub/Sub issues.
To exit the Pub/Sub mode just process CTRL-C
.
Monitoring commands executed in Redis
Similarly to the Pub/Sub mode, the monitoring mode is entered automatically
once you use the MONITOR
commnad. All commands received by the active Redis instance will be printed to the standard output:
$ redis-cli MONITOR
OK
1460100081.165665 [0 127.0.0.1:51706] "set" "shipment:8000736522714:status" "sorting"
1460100083.053365 [0 127.0.0.1:51707] "get" "shipment:8000736522714:status"
Note that it is possible to use to pipe the output, so you can monitor
for specific patterns using tools such as grep
.
Monitoring the latency of Redis instances
Redis is often used in contexts where latency is very critical. Latency involves multiple moving parts within the application, from the client library to the network stack, to the Redis instance itself.
The redis-cli
has multiple facilities for studying the latency of a Redis
instance and understanding the latency’s maximum, average and distribution.
The basic latency-checking tool is the --latency
option. Using this
option the CLI runs a loop where the PING
command is sent to the Redis
instance and the time to receive a reply is measured. This happens 100
times per second, and stats are updated in a real time in the console:
$ redis-cli --latency
min: 0, max: 1, avg: 0.19 (427 samples)
The stats are provided in milliseconds. Usually, the average latency of
a very fast instance tends to be overestimated a bit because of the
latency due to the kernel scheduler of the system running redis-cli
itself, so the average latency of 0.19 above may easily be 0.01 or less.
However this is usually not a big problem, since most developers are interested in
events of a few milliseconds or more.
Sometimes it is useful to study how the maximum and average latencies
evolve during time. The --latency-history
option is used for that
purpose: it works exactly like --latency
, but every 15 seconds (by
default) a new sampling session is started from scratch:
$ redis-cli --latency-history
min: 0, max: 1, avg: 0.14 (1314 samples) -- 15.01 seconds range
min: 0, max: 1, avg: 0.18 (1299 samples) -- 15.00 seconds range
min: 0, max: 1, avg: 0.20 (113 samples)^C
Sampling sessions' length can be changed with the -i <interval>
option.
The most advanced latency study tool, but also the most complex to
interpret for non-experienced users, is the ability to use color terminals
to show a spectrum of latencies. You’ll see a colored output that indicates the
different percentages of samples, and different ASCII characters that indicate
different latency figures. This mode is enabled using the --latency-dist
option:
$ redis-cli --latency-dist
(output not displayed, requires a color terminal, try it!)
There is another pretty unusual latency tool implemented inside redis-cli
.
It does not check the latency of a Redis instance, but the latency of the
computer running redis-cli
. This latency is intrinsic to the kernel scheduler,
the hypervisor in case of virtualized instances, and so forth.
Redis calls it intrinsic latency because it’s mostly opaque to the programmer.
If the Redis instance has high latency regardless of all the obvious things
that may be the source cause, it’s worth to check what’s the best your system
can do by running redis-cli
in this special mode directly in the system you
are running Redis servers on.
By measuring the intrinsic latency, you know that this is the baseline,
and Redis cannot outdo your system. In order to run the CLI
in this mode, use the --intrinsic-latency <test-time>
. Note that the test time is in seconds and dictates how long the test should run.
$ ./redis-cli --intrinsic-latency 5
Max latency so far: 1 microseconds.
Max latency so far: 7 microseconds.
Max latency so far: 9 microseconds.
Max latency so far: 11 microseconds.
Max latency so far: 13 microseconds.
Max latency so far: 15 microseconds.
Max latency so far: 34 microseconds.
Max latency so far: 82 microseconds.
Max latency so far: 586 microseconds.
Max latency so far: 739 microseconds.
65433042 total runs (avg latency: 0.0764 microseconds / 764.14 nanoseconds per run).
Worst run took 9671x longer than the average latency.
IMPORTANT: this command must be executed on the computer that runs the Redis server instance, not on a different host. It does not connect to a Redis instance and performs the test locally.
In the above case, the system cannot do better than 739 microseconds of worst case latency, so one can expect certain queries to occasionally run less than 1 millisecond.
Remote backups of RDB files
During a Redis replication’s first synchronization, the primary and the replica
exchange the whole data set in the form of an RDB file. This feature is exploited
by redis-cli
in order to provide a remote backup facility that allows a
transfer of an RDB file from any Redis instance to the local computer running
redis-cli
. To use this mode, call the CLI with the --rdb <dest-filename>
option:
$ redis-cli --rdb /tmp/dump.rdb
SYNC sent to master, writing 13256 bytes to '/tmp/dump.rdb'
Transfer finished with success.
This is a simple but effective way to ensure disaster recovery
RDB backups exist of your Redis instance. When using this options in
scripts or cron
jobs, make sure to check the return value of the command.
If it is non zero, an error occurred as in the following example:
$ redis-cli --rdb /tmp/dump.rdb
SYNC with master failed: -ERR Can't SYNC while not connected with my master
$ echo $?
1
Replica mode
The replica mode of the CLI is an advanced feature useful for
Redis developers and for debugging operations.
It allows for the inspection of the content a primary sends to its replicas in the replication
stream in order to propagate the writes to its replicas. The option
name is simply --replica
. The following is a working example:
$ redis-cli --replica
SYNC with master, discarding 13256 bytes of bulk transfer...
SYNC done. Logging commands from master.
"PING"
"SELECT","0"
"SET","last_name","Enigk"
"PING"
"INCR","mycounter"
The command begins by discarding the RDB file of the first synchronization and then logs each command received in CSV format.
If you think some of the commands are not replicated correctly in your replicas this is a good way to check what’s happening, and also useful information in order to improve the bug report.
Performing an LRU simulation
Redis is often used as a cache with LRU eviction.
Depending on the number of keys and the amount of memory allocated for the
cache (specified via the maxmemory
directive), the amount of cache hits
and misses will change. Sometimes, simulating the rate of hits is very
useful to correctly provision your cache.
The redis-cli
has a special mode where it performs a simulation of GET and SET
operations, using an 80-20% power law distribution in the requests pattern.
This means that 20% of keys will be requested 80% of times, which is a
common distribution in caching scenarios.
Theoretically, given the distribution of the requests and the Redis memory overhead, it should be possible to compute the hit rate analytically with a mathematical formula. However, Redis can be configured with different LRU settings (number of samples) and LRU’s implementation, which is approximated in Redis, changes a lot between different versions. Similarly the amount of memory per key may change between versions. That is why this tool was built: its main motivation was for testing the quality of Redis' LRU implementation, but now is also useful for testing how a given version behaves with the settings originally intended for deployment.
To use this mode, specify the amount of keys in the test and configure a sensible maxmemory
setting as a first attempt.
IMPORTANT NOTE: Configuring the maxmemory
setting in the Redis configuration
is crucial: if there is no cap to the maximum memory usage, the hit will
eventually be 100% since all the keys can be stored in memory. If too many keys are specified with maximum memory, eventually all of the computer RAM will be used. It is also needed to configure an appropriate
maxmemory policy; most of the time allkeys-lru
is selected.
In the following example there is a configured a memory limit of 100MB and an LRU simulation using 10 million keys.
WARNING: the test uses pipelining and will stress the server, don’t use it with production instances.
$ ./redis-cli --lru-test 10000000
156000 Gets/sec | Hits: 4552 (2.92%) | Misses: 151448 (97.08%)
153750 Gets/sec | Hits: 12906 (8.39%) | Misses: 140844 (91.61%)
159250 Gets/sec | Hits: 21811 (13.70%) | Misses: 137439 (86.30%)
151000 Gets/sec | Hits: 27615 (18.29%) | Misses: 123385 (81.71%)
145000 Gets/sec | Hits: 32791 (22.61%) | Misses: 112209 (77.39%)
157750 Gets/sec | Hits: 42178 (26.74%) | Misses: 115572 (73.26%)
154500 Gets/sec | Hits: 47418 (30.69%) | Misses: 107082 (69.31%)
151250 Gets/sec | Hits: 51636 (34.14%) | Misses: 99614 (65.86%)
The program shows stats every second. In the first seconds the cache starts to be populated. The misses rate later stabilizes into the actual figure that can be expected:
120750 Gets/sec | Hits: 48774 (40.39%) | Misses: 71976 (59.61%)
122500 Gets/sec | Hits: 49052 (40.04%) | Misses: 73448 (59.96%)
127000 Gets/sec | Hits: 50870 (40.06%) | Misses: 76130 (59.94%)
124250 Gets/sec | Hits: 50147 (40.36%) | Misses: 74103 (59.64%)
A miss rate of 59% may not be acceptable for certain use cases therefor 100MB of memory is not enough. Observe an example using a half gigabyte of memory. After several minutes the output stabilizes to the following figures:
140000 Gets/sec | Hits: 135376 (96.70%) | Misses: 4624 (3.30%)
141250 Gets/sec | Hits: 136523 (96.65%) | Misses: 4727 (3.35%)
140250 Gets/sec | Hits: 135457 (96.58%) | Misses: 4793 (3.42%)
140500 Gets/sec | Hits: 135947 (96.76%) | Misses: 4553 (3.24%)
With 500MB there is sufficient space for the key quantity (10 million) and distribution (80-20 style).