A flexible distributed key-value datastore that is optimized for caching and other realtime workloads.
This project was forked from the open source Redis project right before the transition to their new source available licenses.
This README is just a fast quick start document. More details can be found under valkey.io
Valkey is a high-performance data structure server that primarily serves key/value workloads.
It supports a wide range of native structures and an extensible plugin system for adding new data structures and access patterns.
Makefile
Valkey can be compiled and used on Linux, OSX, OpenBSD, NetBSD, FreeBSD.
We support big endian and little endian architectures, and both 32 bit
and 64 bit systems.
It may compile on Solaris derived systems (for instance SmartOS) but our
support for this platform is best effort and Valkey is not guaranteed to
work as well as in Linux, OSX, and *BSD.
It is as simple as:
% make
To build with TLS support, you’ll need OpenSSL development libraries (e.g.
libssl-dev on Debian/Ubuntu).
To build TLS support as Valkey built-in:
% make BUILD_TLS=yes
To build TLS as Valkey module:
% make BUILD_TLS=module
Note that sentinel mode does not support TLS module.
To build with experimental RDMA support you’ll need RDMA development libraries
(e.g. librdmacm-dev and libibverbs-dev on Debian/Ubuntu). For now, Valkey only
supports RDMA as connection module mode. Run:
% make BUILD_RDMA=module
To build with systemd support, you’ll need systemd development libraries (such
as libsystemd-dev on Debian/Ubuntu or systemd-devel on CentOS) and run:
% make USE_SYSTEMD=yes
To append a suffix to Valkey program names, use:
% make PROG_SUFFIX="-alt"
You can build a 32 bit Valkey binary using:
% make 32bit
After building Valkey, it is a good idea to test it using:
% make test
The above runs the main integration tests. Additional tests are started using:
% make test-unit # Unit tests
% make test-modules # Tests of the module API
% make test-sentinel # Valkey Sentinel integration tests
% make test-cluster # Valkey Cluster integration tests
More about running the integration tests can be found in
tests/README.md and for unit tests, see
src/unit/README.md.
Valkey has some dependencies which are included in the deps
directory.
make
does not automatically rebuild dependencies even if something in
the source code of dependencies changes.
When you update the source code with git pull
or when code inside the
dependencies tree is modified in any other way, make sure to use the following
command in order to really clean everything and rebuild from scratch:
% make distclean
This will clean: jemalloc, lua, hiredis, linenoise and other dependencies.
Also if you force certain build options like 32bit target, no C compiler
optimizations (for debugging purposes), and other similar build time options,
those options are cached indefinitely until you issue a make distclean
command.
If after building Valkey with a 32 bit target you need to rebuild it
with a 64 bit target, or the other way around, you need to perform a
make distclean
in the root directory of the Valkey distribution.
In case of build errors when trying to build a 32 bit binary of Valkey, try
the following steps:
make 32bit
:make CFLAGS="-m32 -march=native" LDFLAGS="-m32"
Selecting a non-default memory allocator when building Valkey is done by setting
the MALLOC
environment variable. Valkey is compiled and linked against libc
malloc by default, with the exception of jemalloc being the default on Linux
systems. This default was picked because jemalloc has proven to have fewer
fragmentation problems than libc malloc.
To force compiling against libc malloc, use:
% make MALLOC=libc
To compile against jemalloc on Mac OS X systems, use:
% make MALLOC=jemalloc
By default, Valkey will build using the POSIX clock_gettime function as the
monotonic clock source. On most modern systems, the internal processor clock
can be used to improve performance. Cautions can be found here:
http://oliveryang.net/2015/09/pitfalls-of-TSC-usage/
To build with support for the processor’s internal instruction clock, use:
% make CFLAGS="-DUSE_PROCESSOR_CLOCK"
Valkey will build with a user-friendly colorized output by default.
If you want to see a more verbose output, use the following:
% make V=1
To run Valkey with the default configuration, just type:
% cd src
% ./valkey-server
If you want to provide your valkey.conf, you have to run it using an additional
parameter (the path of the configuration file):
% cd src
% ./valkey-server /path/to/valkey.conf
It is possible to alter the Valkey configuration by passing parameters directly
as options using the command line. Examples:
% ./valkey-server --port 9999 --replicaof 127.0.0.1 6379
% ./valkey-server /etc/valkey/6379.conf --loglevel debug
All the options in valkey.conf are also supported as options using the command
line, with exactly the same name.
To manually run a Valkey server with TLS mode (assuming ./gen-test-certs.sh
was invoked so sample certificates/keys are available):
TLS built-in mode:
./src/valkey-server --tls-port 6379 --port 0 \
--tls-cert-file ./tests/tls/valkey.crt \
--tls-key-file ./tests/tls/valkey.key \
--tls-ca-cert-file ./tests/tls/ca.crt
TLS module mode:
./src/valkey-server --tls-port 6379 --port 0 \
--tls-cert-file ./tests/tls/valkey.crt \
--tls-key-file ./tests/tls/valkey.key \
--tls-ca-cert-file ./tests/tls/ca.crt \
--loadmodule src/valkey-tls.so
Note that you can disable TCP by specifying --port 0
explicitly.
It’s also possible to have both TCP and TLS available at the same time,
but you’ll have to assign different ports.
Use valkey-cli
to connect to the Valkey server:
./src/valkey-cli --tls \
--cert ./tests/tls/valkey.crt \
--key ./tests/tls/valkey.key \
--cacert ./tests/tls/ca.crt
Specifying --tls-replication yes
makes a replica connect to the primary.
Using --tls-cluster yes
makes Valkey Cluster use TLS across nodes.
Note that Valkey Over RDMA is an experimental feature.
It may be changed or removed in any minor or major version.
Currently, it is only supported on Linux.
To manually run a Valkey server with RDMA mode:
% ./src/valkey-server --protected-mode no \
--loadmodule src/valkey-rdma.so bind=192.168.122.100 port=6379
It’s possible to change bind address/port of RDMA by runtime command:
192.168.122.100:6379> CONFIG SET rdma.port 6380
It’s also possible to have both RDMA and TCP available, and there is no
conflict of TCP(6379) and RDMA(6379), Ex:
% ./src/valkey-server --protected-mode no \
--loadmodule src/valkey-rdma.so bind=192.168.122.100 port=6379 \
--port 6379
Note that the network card (192.168.122.100 of this example) should support
RDMA. To test a server supports RDMA or not:
% rdma res show (a new version iproute2 package)
Or:
% ibv_devices
You can use valkey-cli to play with Valkey. Start a valkey-server instance,
then in another terminal try the following:
% cd src
% ./valkey-cli
valkey> ping
PONG
valkey> set foo bar
OK
valkey> get foo
"bar"
valkey> incr mycounter
(integer) 1
valkey> incr mycounter
(integer) 2
valkey>
In order to install Valkey binaries into /usr/local/bin, just use:
% make install
You can use make PREFIX=/some/other/directory install
if you wish to use a
different destination.
Note: For compatibility with Redis, we create symlinks from the Redis names (redis-server
, redis-cli
, etc.) to the Valkey binaries installed by make install
.
The symlinks are created in same directory as the Valkey binaries.
The symlinks are removed when using make uninstall
.
The creation of the symlinks can be skipped by setting the makefile variable USE_REDIS_SYMLINKS=no
.
make install
will just install binaries in your system, but will not configure
init scripts and configuration files in the appropriate place. This is not
needed if you just want to play a bit with Valkey, but if you are installing
it the proper way for a production system, we have a script that does this
for Ubuntu and Debian systems:
% cd utils
% ./install_server.sh
Note: install_server.sh
will not work on Mac OSX; it is built for Linux only.
The script will ask you a few questions and will setup everything you need
to run Valkey properly as a background daemon that will start again on
system reboots.
You’ll be able to stop and start Valkey using the script named
/etc/init.d/valkey_<portnumber>
, for instance /etc/init.d/valkey_6379
.
CMake
In addition to the traditional Makefile
build, Valkey supports an alternative, experimental, build system using CMake
.
To build and install Valkey
, in Release
mode (an optimized build), type this into your terminal:
mkdir build-release
cd $_
cmake .. -DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=/opt/valkey
sudo make install
# Valkey is now installed under /opt/valkey
Other options supported by Valkey’s CMake
build system:
-DBUILD_TLS=<on|off|module>
enable TLS build for Valkey-DBUILD_RDMA=<off|module>
enable RDMA module build (only module mode supported)-DBUILD_MALLOC=<libc|jemalloc|tcmalloc|tcmalloc_minimal>
choose the allocator to use. Default on Linux: jemalloc
, for other OS: libc
-DBUILD_SANITIZER=<address|thread|undefined>
build with address sanitizer enabled-DBUILD_UNIT_TESTS=[1|0]
when set, the build will produce the executable valkey-unit-tests
-DBUILD_TEST_MODULES=[1|0]
when set, the build will include the modules located under the tests/modules
folder-DBUILD_EXAMPLE_MODULES=[1|0]
when set, the build will include the example modules located under the src/modules
folder-DCMAKE_BUILD_TYPE=<Debug|Release...>
define the build type, see CMake manual for more details-DCMAKE_INSTALL_PREFIX=/installation/path
override this value to define a custom install prefix. Default: /usr/local
-G<Generator Name>
generate build files for “Generator Name”. By default, CMake will generate Makefile
s.CMake
generates a user-friendly colorized output by default.
If you want to see a more verbose output, use the following:
make VERBOSE=1
During the CMake
stage, CMake
caches variables in a local file named CMakeCache.txt
. All variables generated by Valkey
are removed from the cache once consumed (this is done by calling to unset(VAR-NAME CACHE)
). However, some variables,
like the compiler path, are kept in cache. To start a fresh build either remove the cache file CMakeCache.txt
from the
build folder, or delete the build folder completely.
It is important to re-run CMake
when adding new source files.
During the CMake
stage of the build, CMake
generates a JSON file named compile_commands.json
and places it under the
build folder. This file is used by many IDEs and text editors for providing code completion (via clangd
).
A small caveat is that these tools will look for compile_commands.json
under the Valkey’s top folder.
A common workaround is to create a symbolic link to it:
cd /path/to/valkey/
# We assume here that your build folder is `build-release`
ln -sf $(pwd)/build-release/compile_commands.json $(pwd)/compile_commands.json
Restart your IDE and voila
Please see the CONTRIBUTING.md. For security bugs and vulnerabilities, please see SECURITY.md.
Valkey a Series of LF Projects, LLC
2810 N Church St, PMB 57274
Wilmington, Delaware 19802-4447