Introduction to EVAL
EVAL
and EVALSHA
are used to evaluate scripts using the Lua interpreter
built into Redis starting from version 2.6.0.
The first argument of EVAL
is a Lua 5.1 script.
The script does not need to define a Lua function (and should not).
It is just a Lua program that will run in the context of the Redis server.
The second argument of EVAL
is the number of arguments that follows the script
(starting from the third argument) that represent Redis key names.
The arguments can be accessed by Lua using the !KEYS
global variable in the
form of a one-based array (so KEYS[1]
, KEYS[2]
, …).
All the additional arguments should not represent key names and can be accessed
by Lua using the ARGV
global variable, very similarly to what happens with
keys (so ARGV[1]
, ARGV[2]
, …).
The following example should clarify what stated above:
> eval "return {KEYS[1],KEYS[2],ARGV[1],ARGV[2]}" 2 key1 key2 first second
1) "key1"
2) "key2"
3) "first"
4) "second"
Note: as you can see Lua arrays are returned as Redis multi bulk replies, that is a Redis return type that your client library will likely convert into an Array type in your programming language.
It is possible to call Redis commands from a Lua script using two different Lua functions:
redis.call()
redis.pcall()
redis.call()
is similar to redis.pcall()
, the only difference is that if a
Redis command call will result in an error, redis.call()
will raise a Lua
error that in turn will force EVAL
to return an error to the command caller,
while redis.pcall
will trap the error and return a Lua table representing the
error.
The arguments of the redis.call()
and redis.pcall()
functions are all
the arguments of a well formed Redis command:
> eval "return redis.call('set','foo','bar')" 0
OK
The above script sets the key foo
to the string bar
.
However it violates the EVAL
command semantics as all the keys that the script
uses should be passed using the !KEYS
array:
> eval "return redis.call('set',KEYS[1],'bar')" 1 foo
OK
All Redis commands must be analyzed before execution to determine which
keys the command will operate on. In order for this to be true for EVAL
, keys must be passed explicitly.
This is useful in many ways, but especially to make sure Redis Cluster
can forward your request to the appropriate cluster node.
Note this rule is not enforced in order to provide the user with opportunities to abuse the Redis single instance configuration, at the cost of writing scripts not compatible with Redis Cluster.
Lua scripts can return a value that is converted from the Lua type to the Redis protocol using a set of conversion rules.
Conversion between Lua and Redis data types
Redis return values are converted into Lua data types when Lua calls a Redis
command using call() or pcall().
Similarly Lua data types are converted into the Redis protocol when a Lua script
returns a value, so that scripts can control what EVAL
will return to the
client.
This conversion between data types is designed in a way that if a Redis type is converted into a Lua type, and then the result is converted back into a Redis type, the result is the same as the initial value.
In other words there is a one-to-one conversion between Lua and Redis types. The following table shows you all the conversions rules:
Redis to Lua conversion table.
- Redis integer reply -> Lua number
- Redis bulk reply -> Lua string
- Redis multi bulk reply -> Lua table (may have other Redis data types nested)
- Redis status reply -> Lua table with a single
ok
field containing the status - Redis error reply -> Lua table with a single
err
field containing the error - Redis Nil bulk reply and Nil multi bulk reply -> Lua false boolean type
Lua to Redis conversion table.
- Lua number -> Redis integer reply (the number is converted into an integer)
- Lua string -> Redis bulk reply
- Lua table (array) -> Redis multi bulk reply (truncated to the first nil inside the Lua array if any)
- Lua table with a single
ok
field -> Redis status reply - Lua table with a single
err
field -> Redis error reply - Lua boolean false -> Redis Nil bulk reply.
There is an additional Lua-to-Redis conversion rule that has no corresponding Redis to Lua conversion rule:
- Lua boolean true -> Redis integer reply with value of 1.
Also there are two important rules to note:
- Lua has a single numerical type, Lua numbers. There is no distinction between integers and floats. So we always convert Lua numbers into integer replies, removing the decimal part of the number if any. If you want to return a float from Lua you should return it as a string, exactly like Redis itself does (see for instance the
ZSCORE
command). - There is no simple way to have nils inside Lua arrays, this is a result of Lua table semantics, so when Redis converts a Lua array into Redis protocol the conversion is stopped if a nil is encountered.
Here are a few conversion examples:
> eval "return 10" 0
(integer) 10
> eval "return {1,2,{3,'Hello World!'}}" 0
1) (integer) 1
2) (integer) 2
3) 1) (integer) 3
2) "Hello World!"
> eval "return redis.call('get','foo')" 0
"bar"
The last example shows how it is possible to receive the exact return value of
redis.call()
or redis.pcall()
from Lua that would be returned if the command
was called directly.
In the following example we can see how floats and arrays with nils are handled:
> eval "return {1,2,3.3333,'foo',nil,'bar'}" 0
1) (integer) 1
2) (integer) 2
3) (integer) 3
4) "foo"
As you can see 3.333 is converted into 3, and the bar string is never returned as there is a nil before.
Helper functions to return Redis types
There are two helper functions to return Redis types from Lua.
redis.error_reply(error_string)
returns an error reply. This function simply returns a single field table with theerr
field set to the specified string for you.redis.status_reply(status_string)
returns a status reply. This function simply returns a single field table with theok
field set to the specified string for you.
There is no difference between using the helper functions or directly returning the table with the specified format, so the following two forms are equivalent:
return {err="My Error"}
return redis.error_reply("My Error")
Atomicity of scripts
Redis uses the same Lua interpreter to run all the commands.
Also Redis guarantees that a script is executed in an atomic way: no other
script or Redis command will be executed while a script is being executed.
This semantic is similar to the one of MULTI
/ EXEC
.
From the point of view of all the other clients the effects of a script are
either still not visible or already completed.
However this also means that executing slow scripts is not a good idea. It is not hard to create fast scripts, as the script overhead is very low, but if you are going to use slow scripts you should be aware that while the script is running no other client can execute commands.
Error handling
As already stated, calls to redis.call()
resulting in a Redis command error
will stop the execution of the script and return an error, in a way that
makes it obvious that the error was generated by a script:
> del foo
(integer) 1
> lpush foo a
(integer) 1
> eval "return redis.call('get','foo')" 0
(error) ERR Error running script (call to f_6b1bf486c81ceb7edf3c093f4c48582e38c0e791): ERR Operation against a key holding the wrong kind of value
Using redis.pcall()
no error is raised, but an error object is
returned in the format specified above (as a Lua table with an err
field).
The script can pass the exact error to the user by returning the error object
returned by redis.pcall()
.
Bandwidth and EVALSHA
The EVAL
command forces you to send the script body again and again.
Redis does not need to recompile the script every time as it uses an internal
caching mechanism, however paying the cost of the additional bandwidth may not
be optimal in many contexts.
On the other hand, defining commands using a special command or via redis.conf
would be a problem for a few reasons:
Different instances may have different implementations of a command.
Deployment is hard if we have to make sure all instances contain a given command, especially in a distributed environment.
Reading application code, the complete semantics might not be clear since the application calls commands defined server side.
In order to avoid these problems while avoiding the bandwidth penalty, Redis
implements the EVALSHA
command.
EVALSHA
works exactly like EVAL
, but instead of having a script as the first
argument it has the SHA1 digest of a script.
The behavior is the following:
If the server still remembers a script with a matching SHA1 digest, the script is executed.
If the server does not remember a script with this SHA1 digest, a special error is returned telling the client to use
EVAL
instead.
Example:
> set foo bar
OK
> eval "return redis.call('get','foo')" 0
"bar"
> evalsha 6b1bf486c81ceb7edf3c093f4c48582e38c0e791 0
"bar"
> evalsha ffffffffffffffffffffffffffffffffffffffff 0
(error) `NOSCRIPT` No matching script. Please use `EVAL`.
The client library implementation can always optimistically send EVALSHA
under
the hood even when the client actually calls EVAL
, in the hope the script was
already seen by the server.
If the NOSCRIPT
error is returned EVAL
will be used instead.
Passing keys and arguments as additional EVAL
arguments is also very useful in
this context as the script string remains constant and can be efficiently cached
by Redis.
Script cache semantics
Executed scripts are guaranteed to be in the script cache of a given execution
of a Redis instance forever. This means that if an EVAL
is performed against a Redis instance all the subsequent EVALSHA
calls will succeed.
The reason why scripts can be cached for long time is that it is unlikely for a well written application to have enough different scripts to cause memory problems. Every script is conceptually like the implementation of a new command, and even a large application will likely have just a few hundred of them. Even if the application is modified many times and scripts will change, the memory used is negligible.
The only way to flush the script cache is by explicitly calling the SCRIPT FLUSH
command, which will completely flush the scripts cache removing all the
scripts executed so far.
This is usually needed only when the instance is going to be instantiated for another customer or application in a cloud environment.
Also, as already mentioned, restarting a Redis instance flushes the script cache, which is not persistent. However from the point of view of the client there are only two ways to make sure a Redis instance was not restarted between two different commands.
- The connection we have with the server is persistent and was never closed so far.
- The client explicitly checks the
runid
field in theINFO
command in order to make sure the server was not restarted and is still the same process.
Practically speaking, for the client it is much better to simply assume that in the context of a given connection, cached scripts are guaranteed to be there
unless an administrator explicitly called the SCRIPT FLUSH
command.
The fact that the user can count on Redis not removing scripts is semantically useful in the context of pipelining.
For instance an application with a persistent connection to Redis can be sure that if a script was sent once it is still in memory, so EVALSHA can be used against those scripts in a pipeline without the chance of an error being generated due to an unknown script (we’ll see this problem in detail later).
A common pattern is to call SCRIPT LOAD
to load all the scripts that will
appear in a pipeline, then use EVALSHA
directly inside the pipeline without
any need to check for errors resulting from the script hash not being
recognized.
The SCRIPT command
Redis offers a SCRIPT command that can be used in order to control the scripting subsystem. SCRIPT currently accepts three different commands:
SCRIPT FLUSH
This command is the only way to force Redis to flush the scripts cache. It is most useful in a cloud environment where the same instance can be reassigned to a different user. It is also useful for testing client libraries’ implementations of the scripting feature.
SCRIPT EXISTS sha1 sha2 ... shaN
Given a list of SHA1 digests as arguments this command returns an array of 1 or 0, where 1 means the specific SHA1 is recognized as a script already present in the scripting cache, while 0 means that a script with this SHA1 was never seen before (or at least never seen after the latest SCRIPT FLUSH command).
SCRIPT LOAD script
This command registers the specified script in the Redis script cache. The command is useful in all the contexts where we want to make sure that
EVALSHA
will not fail (for instance during a pipeline or MULTI/EXEC operation), without the need to actually execute the script.SCRIPT KILL
This command is the only way to interrupt a long-running script that reaches the configured maximum execution time for scripts. The SCRIPT KILL command can only be used with scripts that did not modify the dataset during their execution (since stopping a read-only script does not violate the scripting engine’s guaranteed atomicity). See the next sections for more information about long running scripts.
Scripts as pure functions
A very important part of scripting is writing scripts that are pure functions. Scripts executed in a Redis instance are, by default, replicated on slaves and into the AOF file by sending the script itself — not the resulting commands.
The reason is that sending a script to another Redis instance is often much faster than sending the multiple commands the script generates, so if the client is sending many scripts to the master, converting the scripts into individual commands for the slave / AOF would result in too much bandwidth for the replication link or the Append Only File (and also too much CPU since dispatching a command received via network is a lot more work for Redis compared to dispatching a command invoked by Lua scripts).
Normally replicating scripts instead of the effects of the scripts makes sense, however not in all the cases. So starting with Redis 3.2 (currently not stable), the scripting engine is able to, alternatively, replicate the sequence of write commands resulting from the script execution, instead of replication the script itself. See the next section for more information. In this section we’ll assume that scripts are replicated by sending the whole script. Let’s call this replication mode whole scripts replication.
The main drawback with the whole scripts replication approach is that scripts are required to have the following property:
- The script must always evaluates the same Redis write commands with the same arguments given the same input data set. Operations performed by the script cannot depend on any hidden (non-explicit) information or state that may change as script execution proceeds or between different executions of the script, nor can it depend on any external input from I/O devices.
Things like using the system time, calling Redis random commands like
RANDOMKEY
, or using Lua random number generator, could result into scripts
that will not always evaluate in the same way.
In order to enforce this behavior in scripts Redis does the following:
- Lua does not export commands to access the system time or other external state.
- Redis will block the script with an error if a script calls a Redis
command able to alter the data set after a Redis random command like
RANDOMKEY
,SRANDMEMBER
,TIME
. This means that if a script is read-only and does not modify the data set it is free to call those commands. Note that a random command does not necessarily mean a command that uses random numbers: any non-deterministic command is considered a random command (the best example in this regard is theTIME
command). - Redis commands that may return elements in random order, like
SMEMBERS
(because Redis Sets are unordered) have a different behavior when called from Lua, and undergo a silent lexicographical sorting filter before returning data to Lua scripts. Soredis.call("smembers",KEYS[1])
will always return the Set elements in the same order, while the same command invoked from normal clients may return different results even if the key contains exactly the same elements. - Lua pseudo random number generation functions
math.random
andmath.randomseed
are modified in order to always have the same seed every time a new script is executed. This means that callingmath.random
will always generate the same sequence of numbers every time a script is executed ifmath.randomseed
is not used.
However the user is still able to write commands with random behavior using the following simple trick. Imagine I want to write a Redis script that will populate a list with N random integers.
I can start with this small Ruby program:
require 'rubygems'
require 'redis'
r = Redis.new
RandomPushScript = <<EOF
local i = tonumber(ARGV[1])
local res
while (i > 0) do
res = redis.call('lpush',KEYS[1],math.random())
i = i-1
end
return res
EOF
r.del(:mylist)
puts r.eval(RandomPushScript,[:mylist],[10,rand(2**32)])
Every time this script executed the resulting list will have exactly the following elements:
> lrange mylist 0 -1
1) "0.74509509873814"
2) "0.87390407681181"
3) "0.36876626981831"
4) "0.6921941534114"
5) "0.7857992587545"
6) "0.57730350670279"
7) "0.87046522734243"
8) "0.09637165539729"
9) "0.74990198051087"
10) "0.17082803611217"
In order to make it a pure function, but still be sure that every invocation of the script will result in different random elements, we can simply add an additional argument to the script that will be used in order to seed the Lua pseudo-random number generator. The new script is as follows:
RandomPushScript = <<EOF
local i = tonumber(ARGV[1])
local res
math.randomseed(tonumber(ARGV[2]))
while (i > 0) do
res = redis.call('lpush',KEYS[1],math.random())
i = i-1
end
return res
EOF
r.del(:mylist)
puts r.eval(RandomPushScript,1,:mylist,10,rand(2**32))
What we are doing here is sending the seed of the PRNG as one of the arguments. This way the script output will be the same given the same arguments, but we are changing one of the arguments in every invocation, generating the random seed client-side. The seed will be propagated as one of the arguments both in the replication link and in the Append Only File, guaranteeing that the same changes will be generated when the AOF is reloaded or when the slave processes the script.
Note: an important part of this behavior is that the PRNG that Redis implements
as math.random
and math.randomseed
is guaranteed to have the same output
regardless of the architecture of the system running Redis.
32-bit, 64-bit, big-endian and little-endian systems will all produce the same
output.
Replicating commands instead of scripts
Starting with Redis 3.2 (not yet stable) it is possible to select an alternative replication method. Instead of replication whole scripts, we can just replicate single write commands generated by the script. We call this script effects replication.
In this replication mode, while Lua scripts are executed, Redis collects all the commands executed by the Lua scripting engine that actually modify the dataset. When the script execution finishes, the sequence of commands that the script generated are wrapped into a MULTI / EXEC transaction and are sent to slaves and AOF.
This is useful in several ways depending on the use case:
- When the script is slow to compute, but the effects can be summarized by a few write commands, it is a shame to re-compute the script on the slaves or when reloading the AOF. In this case to replicate just the effect of the script is much better.
- When script effects replication is enabled, the controls about non
deterministic functions are disabled. You can, for example, use the
TIME
orSRANDMEMBER
commands inside your scripts freely at any place. - The Lua PRNG in this mode is seeded randomly at every call.
In order to enable script effects replication, you need to issue the following Lua command before any write operated by the script:
redis.replicate_commands()
The function returns true if the script effects replication was enabled, otherwise if the function was called after the script already called some write command, it returns false, and normal whole script replication is used.
Selective replication of commands
When script effects replication is selected (see the previous section), it is possible to have more control in the way commands are replicated to slaves and AOF. This is a very advanced feature since a misuse can do damage by breaking the contract that the master, slaves, and AOF, all must contain the same logical content.
However this is a useful feature since, sometimes, we need to execute certain commands only in the master in order to create, for example, intermediate values.
Think at a Lua script where we perform an intersection between two sets. Pick five random elements, and create a new set with this five random elements. Finally we delete the temporary key representing the intersection between the two original sets. What we want to replicate is only the creation of the new set with the five elements. It’s not useful to also replicate the commands creating the temporary key.
For this reason, Redis 3.2 introduces a new command that only works when
script effects replication is enabled, and is able to control the scripting
replication engine. The command is called redis.set_repl()
and fails raising
an error if called when script effects replication is disabled.
The command can be called with four different arguments:
redis.set_repl(redis.REPL_ALL) -- Replicte to AOF and slaves.
redis.set_repl(redis.REPL_AOF) -- Replicte only to AOF.
redis.set_repl(redis.REPL_SLAVE) -- Replicte only to slaves.
redis.set_repl(redis.REPL_NONE) -- Don't replicate at all.
By default the scripting engine is always set to REPL_ALL
. By calling
this function the user can switch on/off AOF and or slaves replication, and
turn them back later at her/his wish.
A simple example follows:
redis.replicate_commands() -- Enable effects replication.
redis.call('set','A','1')
redis.set_repl(redis.REPL_NONE)
redis.call('set','B','2')
redis.set_repl(redis.REPL_ALL)
redis.call('set','C','3')
After running the above script, the result is that only keys A and C will be created on slaves and AOF.
Global variables protection
Redis scripts are not allowed to create global variables, in order to avoid leaking data into the Lua state. If a script needs to maintain state between calls (a pretty uncommon need) it should use Redis keys instead.
When global variable access is attempted the script is terminated and EVAL returns with an error:
redis 127.0.0.1:6379> eval 'a=10' 0
(error) ERR Error running script (call to f_933044db579a2f8fd45d8065f04a8d0249383e57): user_script:1: Script attempted to create global variable 'a'
Accessing a non existing global variable generates a similar error.
Using Lua debugging functionality or other approaches like altering the meta table used to implement global protections in order to circumvent globals protection is not hard. However it is difficult to do it accidentally. If the user messes with the Lua global state, the consistency of AOF and replication is not guaranteed: don’t do it.
Note for Lua newbies: in order to avoid using global variables in your scripts simply declare every variable you are going to use using the local keyword.
Using SELECT inside scripts
It is possible to call SELECT
inside Lua scripts like with normal clients,
However one subtle aspect of the behavior changes between Redis 2.8.11 and
Redis 2.8.12. Before the 2.8.12 release the database selected by the Lua
script was transferred to the calling script as current database.
Starting from Redis 2.8.12 the database selected by the Lua script only
affects the execution of the script itself, but does not modify the database
selected by the client calling the script.
The semantic change between patch level releases was needed since the old behavior was inherently incompatible with the Redis replication layer and was the cause of bugs.
Available libraries
The Redis Lua interpreter loads the following Lua libraries:
base
lib.table
lib.string
lib.math
lib.struct
lib.cjson
lib.cmsgpack
lib.bitop
lib.redis.sha1hex
function.redis.breakpoint and redis.debug
function in the context of the Redis Lua debugger.
Every Redis instance is guaranteed to have all the above libraries so you can be sure that the environment for your Redis scripts is always the same.
struct, CJSON and cmsgpack are external libraries, all the other libraries are standard Lua libraries.
struct
struct is a library for packing/unpacking structures within Lua.
Valid formats:
> - big endian
< - little endian
![num] - alignment
x - pading
b/B - signed/unsigned byte
h/H - signed/unsigned short
l/L - signed/unsigned long
T - size_t
i/In - signed/unsigned integer with size `n' (default is size of int)
cn - sequence of `n' chars (from/to a string); when packing, n==0 means
the whole string; when unpacking, n==0 means use the previous
read number as the string length
s - zero-terminated string
f - float
d - double
' ' - ignored
Example:
127.0.0.1:6379> eval 'return struct.pack("HH", 1, 2)' 0
"\x01\x00\x02\x00"
127.0.0.1:6379> eval 'return {struct.unpack("HH", ARGV[1])}' 0 "\x01\x00\x02\x00"
1) (integer) 1
2) (integer) 2
3) (integer) 5
127.0.0.1:6379> eval 'return struct.size("HH")' 0
(integer) 4
CJSON
The CJSON library provides extremely fast JSON manipulation within Lua.
Example:
redis 127.0.0.1:6379> eval 'return cjson.encode({["foo"]= "bar"})' 0
"{\"foo\":\"bar\"}"
redis 127.0.0.1:6379> eval 'return cjson.decode(ARGV[1])["foo"]' 0 "{\"foo\":\"bar\"}"
"bar"
cmsgpack
The cmsgpack library provides simple and fast MessagePack manipulation within Lua.
Example:
127.0.0.1:6379> eval 'return cmsgpack.pack({"foo", "bar", "baz"})' 0
"\x93\xa3foo\xa3bar\xa3baz"
127.0.0.1:6379> eval 'return cmsgpack.unpack(ARGV[1])' 0 "\x93\xa3foo\xa3bar\xa3baz"
1) "foo"
2) "bar"
3) "baz"
bitop
The Lua Bit Operations Module adds bitwise operations on numbers. It is available for scripting in Redis since version 2.8.18.
Example:
127.0.0.1:6379> eval 'return bit.tobit(1)' 0
(integer) 1
127.0.0.1:6379> eval 'return bit.bor(1,2,4,8,16,32,64,128)' 0
(integer) 255
127.0.0.1:6379> eval 'return bit.tohex(422342)' 0
"000671c6"
It supports several other functions:
bit.tobit
, bit.tohex
, bit.bnot
, bit.band
, bit.bor
, bit.bxor
,
bit.lshift
, bit.rshift
, bit.arshift
, bit.rol
, bit.ror
, bit.bswap
.
All available functions are documented in the Lua BitOp documentation
redis.sha1hex
Perform the SHA1 of the input string.
Example:
127.0.0.1:6379> eval 'return redis.sha1hex(ARGV[1])' 0 "foo"
"0beec7b5ea3f0fdbc95d0dd47f3c5bc275da8a33"
Emitting Redis logs from scripts
It is possible to write to the Redis log file from Lua scripts using the
redis.log
function.
redis.log(loglevel,message)
loglevel
is one of:
redis.LOG_DEBUG
redis.LOG_VERBOSE
redis.LOG_NOTICE
redis.LOG_WARNING
They correspond directly to the normal Redis log levels. Only logs emitted by scripting using a log level that is equal or greater than the currently configured Redis instance log level will be emitted.
The message
argument is simply a string.
Example:
redis.log(redis.LOG_WARNING,"Something is wrong with this script.")
Will generate the following:
[32343] 22 Mar 15:21:39 # Something is wrong with this script.
Sandbox and maximum execution time
Scripts should never try to access the external system, like the file system or any other system call. A script should only operate on Redis data and passed arguments.
Scripts are also subject to a maximum execution time (five seconds by default). This default timeout is huge since a script should usually run in under a millisecond. The limit is mostly to handle accidental infinite loops created during development.
It is possible to modify the maximum time a script can be executed with
millisecond precision, either via redis.conf
or using the CONFIG GET / CONFIG
SET command.
The configuration parameter affecting max execution time is called
lua-time-limit
.
When a script reaches the timeout it is not automatically terminated by Redis since this violates the contract Redis has with the scripting engine to ensure that scripts are atomic. Interrupting a script means potentially leaving the dataset with half-written data. For this reasons when a script executes for more than the specified time the following happens:
- Redis logs that a script is running too long.
- It starts accepting commands again from other clients, but will reply with a
BUSY error to all the clients sending normal commands.
The only allowed commands in this status are
SCRIPT KILL
andSHUTDOWN NOSAVE
. - It is possible to terminate a script that executes only read-only commands
using the
SCRIPT KILL
command. This does not violate the scripting semantic as no data was yet written to the dataset by the script. - If the script already called write commands the only allowed command becomes
SHUTDOWN NOSAVE
that stops the server without saving the current data set on disk (basically the server is aborted).
EVALSHA in the context of pipelining
Care should be taken when executing EVALSHA
in the context of a pipelined
request, since even in a pipeline the order of execution of commands must be
guaranteed.
If EVALSHA
will return a NOSCRIPT
error the command can not be reissued
later otherwise the order of execution is violated.
The client library implementation should take one of the following approaches:
Always use plain
EVAL
when in the context of a pipeline.Accumulate all the commands to send into the pipeline, then check for
EVAL
commands and use theSCRIPT EXISTS
command to check if all the scripts are already defined. If not, addSCRIPT LOAD
commands on top of the pipeline as required, and useEVALSHA
for all theEVAL
calls.
Debugging Lua scripts
Starting with Redis 3.2 (currently in beta), Redis has support for native
Lua debugging. The Redis Lua debugger is a remote debugger consisting of
a server, which is Redis itself, and a client, which is by default redis-cli
.
The Lua debugger is described in the Lua scripts debugging section of the Redis documentation.