TiFlash is a columnar storage component of TiDB and TiDB Cloud, the fully-managed service of TiDB. It mainly plays the role of Analytical Processing (AP) in the Hybrid Transactional/Analytical Processing (HTAP) architecture of TiDB.
TiFlash stores data in columnar format and synchronizes data updates in real-time from TiKV by Raft logs with sub-second latency. Reads in TiFlash are guaranteed transactionally consistent with Snapshot Isolation level. TiFlash utilizes Massively Parallel Processing (MPP) computing architecture to accelerate the analytical workloads.
TiFlash repository is based on ClickHouse. We appreciate the excellent work of the ClickHouse team.
Quickly explore TiFlash with a free trial of TiDB Cloud.
See TiDB Cloud Quick Start Guide.
See Quick Start with HTAP and Use TiFlash.
TiFlash can be built on the following hardware architectures:
- x86-64 / amd64
- aarch64
And the following operating systems:
- Linux
- MacOS
The following packages are required:
- CMake 3.23.0+
- Clang 17.0.0+ under Linux or AppleClang 14.0.0+ under MacOS
- Rust
- Python 3.0+
- Ninja-Build or GNU Make
- Ccache (not necessary but highly recommended to reduce rebuild time)
Detailed steps for each platform are listed below.
Ubuntu / Debian
sudo apt update
# Install Rust toolchain, see https://rustup.rs for details
curl https://sh.rustup.rs -sSf | sh -s -- --default-toolchain none
source $HOME/.cargo/env
# Install LLVM, see https://apt.llvm.org for details
# Clang will be available as /usr/bin/clang++-17
wget https://apt.llvm.org/llvm.sh
chmod +x llvm.sh
sudo ./llvm.sh 17 all
# Install other dependencies
sudo apt install -y cmake ninja-build zlib1g-dev libcurl4-openssl-dev ccache
Note for Ubuntu 18.04 and Ubuntu 20.04:
The default installed cmake may be not recent enough. You can install a newer cmake from the Kitware APT Repository:
sudo apt install -y software-properties-common lsb-release
wget -O - https://apt.kitware.com/keys/kitware-archive-latest.asc 2>/dev/null | gpg --dearmor - | sudo tee /etc/apt/trusted.gpg.d/kitware.gpg >/dev/null
sudo apt-add-repository "deb https://apt.kitware.com/ubuntu/ $(lsb_release -cs) main"
sudo apt update
sudo apt install -y cmake
If you are facing "ld.lld: error: duplicate symbol: ssl3_cbc_digest_record":
It is likely because you have a pre-installed libssl3 where TiFlash prefers libssl1. TiFlash has vendored libssl1, so that you can simply remove the one in the system to make compiling work:
sudo apt remove libssl-dev
If this doesn't work, please file an issue.
Archlinux
# Install Rust toolchain, see https://rustup.rs for details
curl https://sh.rustup.rs -sSf | sh -s -- --default-toolchain none
source $HOME/.cargo/env
# Install compilers and dependencies
sudo pacman -S clang lld libc++ libc++abi compiler-rt openmp lcov cmake ninja curl openssl zlib llvm ccache
CentOS 7
Please refer to release-centos7-llvm/env/prepare-sysroot.sh
MacOS
# Install Rust toolchain, see https://rustup.rs for details
curl https://sh.rustup.rs -sSf | sh -s -- --default-toolchain none
source $HOME/.cargo/env
# Install compilers
xcode-select --install
# Install other dependencies
brew install ninja cmake openssl@1.1 ccache
If your MacOS is higher or equal to 13.0 (Ventura), it should work out of the box because by default Xcode 14.3 provides Apple clang 14.0.0. But if your MacOS is lower than 13.0, you should install llvm clang manually.
brew install llvm@17
# check llvm version
clang --version # should be 17.0.0 or higher
git clone https://github.com/pingcap/tiflash.git --recursive -j 20
cd tiflash
To build TiFlash for development:
# In the TiFlash repository root:
cmake --workflow --preset dev
Note: In Linux, usually you need to explicitly specify to use LLVM.
export CC="/usr/bin/clang-17"
export CXX="/usr/bin/clang++-17"
In MacOS, if you install llvm clang, you need to explicitly specify to use llvm clang.
Add the following lines to your shell environment, e.g. ~/.bash_profile
.
export PATH="/opt/homebrew/opt/llvm/bin:$PATH"
export CC="/opt/homebrew/opt/llvm/bin/clang"
export CXX="/opt/homebrew/opt/llvm/bin/clang++"
Or use CMAKE_C_COMPILER
and CMAKE_CXX_COMPILER
to specify the compiler, like this:
mkdir cmake-build-debug
cd cmake-build-debug
cmake .. -GNinja -DCMAKE_BUILD_TYPE=DEBUG -DCMAKE_C_COMPILER=/opt/homebrew/opt/llvm/bin/clang -DCMAKE_CXX_COMPILER=/opt/homebrew/opt/llvm/bin/clang++
ninja tiflash
After building, you can get TiFlash binary in dbms/src/Server/tiflash
in the cmake-build-debug
directory.
TiFlash has several CMake build options to tweak for development purposes. These options SHOULD NOT be changed for production usage, as they may introduce unexpected build errors and unpredictable runtime behaviors.
To tweak options, pass one or multiple -D...=...
args when invoking CMake, for example:
cd cmake-build-debug
cmake .. -GNinja -DCMAKE_BUILD_TYPE=DEBUG -DFOO=BAR
^^^^^^^^^
-
Build Type:
-
-DCMAKE_BUILD_TYPE=RELWITHDEBINFO
: Release build with debug info (default) -
-DCMAKE_BUILD_TYPE=DEBUG
: Debug build -
-DCMAKE_BUILD_TYPE=RELEASE
: Release build
Usually you may want to use different build directories for different build types, e.g. a new build directory named
cmake-build-release
for the release build, so that compile unit cache will not be invalidated when you switch between different build types. -
-
Build with Unit Tests:
-
-DENABLE_TESTS=ON
: Enable unit tests (enabled by default in debug profile) -
-DENABLE_TESTS=OFF
: Disable unit tests (default in release profile)
-
-
Build using GNU Make instead of ninja-build:
Click to expand instructions
To use GNU Make, simply don't pass
-GNinja
to cmake:cd cmake-build-debug cmake .. -DCMAKE_BUILD_TYPE=DEBUG make tiflash -j
NOTE: Option
-j
(defaults to your system CPU core count, otherwise you can optionally specify a number) is used to control the build parallelism. Higher parallelism consumes more memory. If you encounter compiler OOM or hang, try to lower the parallelism by specifying a reasonable number, e.g., half of your system CPU core count or even smaller, after-j
, depending on the available memory in your system. -
Build with System Libraries:
Click to expand instructions
For local development, it is sometimes handy to use pre-installed third-party libraries in the system, rather than to compile them from sources of the bundled (internal) submodules.
Options are supplied to control whether to use internal third-party libraries (bundled in TiFlash) or to try using the pre-installed system ones.
WARNING: It is NOT guaranteed that TiFlash would still build if any of the system libraries are used. Build errors are very likely to happen, almost all the time.
You can view these options along with their descriptions by running:
cd cmake-build-debug cmake -LH | grep "USE_INTERNAL" -A3
All of these options are default as
ON
, as the names tell, using the internal libraries and build from sources.There is another option to append extra paths for CMake to find system libraries:
PREBUILT_LIBS_ROOT
: Default as empty, can be specified with multiple values, separated by;
-
Build for AMD64 Architecture:
Click to expand instructions
To deploy TiFlash under the Linux AMD64 architecture, the CPU must support the
AVX2
instruction set. Ensure thatcat /proc/cpuinfo | grep avx2
has output.If need to build TiFlash for AMD64 architecture without such instruction set, please use cmake option
-DNO_AVX_OR_HIGHER=ON
.
Unit tests are automatically enabled in debug profile. To build these unit tests:
# In the TiFlash repository root:
cmake --workflow --preset unit-tests-all
Then, to run these unit tests:
cd cmake-build-debug
./dbms/gtests_dbms
./libs/libdaemon/src/tests/gtests_libdaemon
./libs/libcommon/src/tests/gtests_libcommon
More usages are available via ./dbms/gtests_dbms --help
.
TiFlash supports testing with thread sanitizer and address sanitizer.
To build unit test executables with sanitizer enabled:
# In the TiFlash repository root:
cmake --workflow --preset asan-tests-all # or tsan-tests-all
There are known false positives reported from leak sanitizer (which is included in address sanitizer). To suppress these errors, set the following environment variables before running the executables:
LSAN_OPTIONS="suppressions=tests/sanitize/asan.suppression" ./dbms/gtests_dbms ...
# or
TSAN_OPTIONS="suppressions=tests/sanitize/tsan.suppression" ./dbms/gtests_dbms ...
Check out the Integration Test Guide for more details.
To build micro benchmark tests, you need release profile and tests enabled:
# In the TiFlash repository root:
cmake --workflow --preset benchmarks
Then, to run these micro benchmarks:
cd cmake-build-release
./dbms/bench_dbms
# Or run with filter:
# ./dbms/bench_dbms --benchmark_filter=xxx
More usages are available via ./dbms/bench_dbms --help
.
To build coverage report, run the script under release-centos7-llvm
cd release-centos7-llvm
./gen_coverage.sh
# Or run with filter:
# FILTER='*DMFile*:*DeltaMerge*:*Segment*' ./gen_coverage.sh
# After the script finished, it will output the directory of code coverage report, you can check out the files by webbrowser
python3 -m http.server --directory "${REPORT_DIR}" "${REPORT_HTTP_PORT}"
Here is the overview of TiFlash architecture The architecture of TiFlash's distributed storage engine and transaction layer.
See TiFlash Development Guide and TiFlash Design documents.
Before submitting a pull request, please resolve clang-tidy errors and use format-diff.py to format source code, otherwise CI build may raise error.
NOTE: It is required to use clang-format 17.0.0+.
# In the TiFlash repository root:
merge_base=$(git merge-base upstream/master HEAD)
python3 release-centos7-llvm/scripts/run-clang-tidy.py -p cmake-build-debug -j 20 --files `git diff $merge_base --name-only`
# if there are too much errors, you can try to run the script again with `-fix`
python3 format-diff.py --diff_from $merge_base
TiFlash is under the Apache 2.0 license. See the LICENSE file for details.