f90322a8ca
https://github.com/milvus-io/milvus/pull/35215 Signed-off-by: Yellow Shine <sammy.huang@zilliz.com> |
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ci/jenkins | ||
config | ||
deb | ||
docker | ||
rpm | ||
build_image_gpu.sh | ||
build_image.sh | ||
builder_gpu.sh | ||
builder.sh | ||
kind_provisioner.sh | ||
lib.sh | ||
OWNERS | ||
README.md | ||
set_docker_mirror.sh |
Building Milvus with Docker
Building Milvus is easy if you take advantage of the containerized build environment. This document will guide you through this build process.
- Docker, using one of the following configurations:
- macOS Install Docker for Mac. See installation instructions here. Note: You will want to set the Docker VM to have at least 2 vCPU and 8GB of initial memory or building will likely fail.
- Linux with local Docker Install Docker according to the instructions for your OS.
- Windows with Docker Desktop WSL2 backend Install Docker according to the instructions. Be sure to store your sources in the local Linux file system, not the Windows remote mount at
/mnt/c
.
- Optional Google Cloud SDK
You must install and configure Google Cloud SDK if you want to upload your release to Google Cloud Storage and may safely omit this otherwise.
Overview
While it is possible to build Milvus using a local golang installation, we have a build process that runs in a Docker container. This simplifies initial set up and provides a very consistent build and test environment.
Before You Begin
Before building Milvus, you must check the eligibility of Docker, Docker Compose, and hardware in line with Milvus' requirements.
Check Docker and Docker Compose version
Check whether your CPU supports SIMD extension instruction set
Milvus' computing operations depend on CPU’s support for SIMD (Single Instruction, Multiple Data) extension instruction set. Whether your CPU supports SIMD extension instruction set is crucial to index building and vector similarity search within Milvus. Ensure that your CPU supports at least one of the following SIMD instruction sets:
- SSE4.2
- AVX
- AVX2
- AVX512
Run the lscpu command to check if your CPU supports the SIMD instruction sets mentioned above:
lscpu | grep -e sse4_2 -e avx -e avx2 -e avx512
Check Wikipedia CPU with AVX for more details.
Key scripts
The following scripts are found in the build/
directory. Note that all scripts must be run from the Milvus root directory.
build/builder.sh
: Run a command in a build docker container. Common invocations are:build/builder.sh make
: Build just linux binary in the container. Pass options and packages as necessary.build/builder.sh make verifiers
: Run all pre-submission verification check.build/builder.sh make unittest
: Run all unit tests.build/builder.sh make clean
: Clean up all the generated files.
You can specify different OS for builder by setting OS_NAME
which defaults to ubuntu20.04
. Valid OS are ubuntu20.04
, amazonlinux2023
.
To specify amazonlinux2023
builder, use these commands:
export OS_NAME=amazonlinux2023
build/builder.sh make
Dev Containers
You can also get into the dev containers for development.
Enter root path of Milvus project on your host machine, execute the following commands:
$ ./scripts/devcontainer.sh up
Creating network "milvus-dev" with the default driver
Creating milvus_jaeger_1 ... done
Creating milvus_minio_1 ... done
Creating milvus_pulsar_1 ... done
Creating milvus_etcd_1 ... done
Creating milvus_builder_1 ... done
Check running state of Dev Container:
$ docker-compose -f docker-compose-devcontainer.yml ps
Name Command State Ports
---------------------------------------------------------------------------------------------------------------------------------------
milvus_builder_1 /tini -- autouseradd --use ... Up
milvus_etcd_1 etcd -advertise-client-url ... Up 2379/tcp, 2380/tcp
milvus_jaeger_1 /go/bin/all-in-one-linux Up 14250/tcp, 14268/tcp, 16686/tcp, 5775/udp, 5778/tcp, 6831/udp,
6832/udp
milvus_minio_1 /usr/bin/docker-entrypoint ... Up (healthy) 9000/tcp
milvus_pulsar_1 bin/pulsar standalone --no ... Up
milvus_builder_1
is the docker of milvus dev, other containers are used as unit test dependencies. you can run compilation and unit test inside the container, enter it:
docker exec -ti milvus_builder_1 bash
Compile the project and run unit test, see details at the DEVELOPMENT.md
make milvus
make unittest
Stop Dev Container
./scripts/devcontainer.sh down
E2E Tests
Milvus uses Python SDK to write test cases to verify the correctness of Milvus functions. Before running E2E tests, you need a running Milvus:
cd deployments/docker/dev
docker-compose up -d
cd ../../../
build/builder.sh /bin/bash -c "export ROCKSMQ_PATH='/tmp/milvus/rdb_data' && ./scripts/start_standalone.sh && cat"
or
build/builder.sh /bin/bash -c "./scripts/start_cluster.sh && cat"
To run E2E tests, use these commands:
MILVUS_SERVICE_IP=$(docker inspect -f '{{range .NetworkSettings.Networks}}{{.IPAddress}}{{end}}' $(docker-compose ps -q builder))
cd tests/docker
docker-compose run --rm pytest /bin/bash -c "pytest --host ${MILVUS_SERVICE_IP}"
Basic Flow
The scripts under build/
are used to build and test. They will ensure that the builder
Docker image is built (based on [build/docker/builder
] ) and then execute the appropriate command in that container. These scripts will both ensure that the right data is cached from run to run for incremental builds and will copy the results back out of the container. You can specify a different registry/name for builder
by setting IMAGE_REPO
which defaults to milvusdb
.
The builder.sh
is executed by first creating a “docker volume“ directory in .docker/
. The .docker/
directory is used to cache the third-party package and compiler cache data. It speeds up recompilation by caching previous compilations and detecting when the same compilation is being done again.
Debug on Host Machine
Integrate vscode with docker
-
Install Visual Studio Code
-
Integrate with VS Code
The working principle is as follows: mount the local file system to the workspace inside the container, or copy it to the container. The extension of vs code is installed inside the container and runs in it, so that the vs Code of the host can fully access the tools, platforms and file systems inside the container. This means that you just need to connect to different containers to switch the entire development environment seamlessly.
Taking the Milvus project as an example, there is a file named .devcontainer.json in the root directory of the project. This file describes how vs code accesses (or creates) a development container environment, and defines the container environment, working directory, extension tool set, etc.
- The steps to configure the development environment are as follows:
Start VS Code,in the command panel ( F1 ) input “Remote-Containers: Open Folder in Container” , then select the project folder which contains devcontainer.json file.
or click right-bottom corner button > < , choose “Remote-Containers: Open Folder in Container”,then select the project folder which contains devcontainer.json file.
VS Code begin load and construct Devcontainer, the progress bar display the construction state.
After Construction, VS Code automatically connects to the container. Now you can code and debug in VS Code, just like developing in your host machine.
You can also use terminal of VS Code to enter the Dev container to do something. Choose Terminal >> New Terminal in the navigation bar, then you can enter the container:
Modify vscode go setups if necessary, the setting path is code -> preference -> settings
"go.testFlags": ["-v"] //if you want say detailed output when running unit test
"go.coverOnSave": true //if you want to show coverage
"go.lintOnSave": true //if you want to auto golint and check code style
Integrate goland with docker
TBD