# This is a multi-stage Dockerfile, with a selectable first stage. With this # approach we get: # # 1. Separation of dependencies needed to build our app in the 'build' stage # and those needed to run our app in the 'final' stage, as we don't want # the build-time dependencies to be included in the final Docker image. # # 2. Support for either building our app for the architecture of the base # image using MODE=build (the default) or for externally built app # binaries (e.g. cross-compiled) using MODE=copy. # # In total there are four stages consisting of: # - Two possible first stages: 'build' or 'copy'. # - A special 'source' stage which selects either 'build' or 'copy' as the # source of binaries to be used by ... # - The 'final' stage. ### ### ARG DEFINITIONS ########################################################### ### # This section defines arguments that can be overriden on the command line # when invoking `docker build` using the argument form: # # `--build-arg =`. # MODE # ==== # Supported values: build (default), copy # # By default this Dockerfile will build our app from sources. If the sources # have already been (cross) compiled by some external process and you wish to # use the resulting binaries from that process, then: # # 1. Create a directory on the host called 'dockerbin/$TARGETPLATFORM' # containing the already compiled app binaries (where $TARGETPLATFORM # is a special variable set by Docker BuiltKit). # 2. Supply arguments `--build-arg MODE=copy` to `docker build`. ARG MODE=build # BASE_IMG # ======== # # Only used when MODE=build. ARG BASE_IMG=alpine:edge # CARGO_ARGS # ========== # # Only used when MODE=build. # # This ARG can be used to control the features enabled when compiling the app # or other compilation settings as necessary. ARG CARGO_ARGS ### ### BUILD STAGES ############################################################## ### # ----------------------------------------------------------------------------- # Docker stage: build # ----------------------------------------------------------------------------- # # Builds our app binaries from sources. FROM ${BASE_IMG} AS build ARG CARGO_ARGS RUN apk add --no-cache rust cargo WORKDIR /tmp/build COPY . . # `CARGO_HTTP_MULTIPLEXING` forces Cargo to use HTTP/1.1 without pipelining # instead of HTTP/2 with multiplexing. This seems to help with various # "spurious network error" warnings when Cargo attempts to fetch from crates.io # when building this image on Docker Hub and GitHub Actions build machines. # # `cargo install` is used instead of `cargo build` because it places just the # binaries we need into a predictable output directory. We can't control this # with arguments to cargo build as `--out-dir` is unstable and contentious and # `--target-dir` still requires us to know which profile and target the # binaries were built for. By using `cargo install` we can also avoid needing # to hard-code the set of binary names to copy so that if we add or remove # built binaries in future this will "just work". Note that `--root /tmp/out` # actually causes the binaries to be placed in `/tmp/out/bin/`. `cargo install` # will create the output directory for us. RUN CARGO_HTTP_MULTIPLEXING=false cargo install \ --locked \ --path . \ --root /tmp/out/ \ ${CARGO_ARGS} # ----------------------------------------------------------------------------- # Docker stage: copy # ----------------------------------------------------------------------------- # Only used when MODE=copy. # # Copy binaries from the host directory 'dockerbin/$TARGETPLATFORM' directory # into this build stage to the same predictable location that binaries would be # in if MODE were 'build'. # # Requires that `docker build` be invoked with variable `DOCKER_BUILDKIT=1` set # in the environment. This is necessary so that Docker will skip the unused # 'build' stage and so that the magic $TARGETPLATFORM ARG will be set for us. FROM ${BASE_IMG} AS copy ARG TARGETPLATFORM ONBUILD COPY dockerbin/$TARGETPLATFORM /tmp/out/bin/ # ----------------------------------------------------------------------------- # Docker stage: source # ----------------------------------------------------------------------------- # This is a "magic" build stage that "labels" a chosen prior build stage as the # one that the build stage after this one should copy application binaries # from. It also causes the ONBUILD COPY command from the 'copy' stage to be run # if needed. Finally, we ensure binaries have the executable flag set because # when copied in from outside they may not have the flag set, especially if # they were uploaded as a GH actions artifact then downloaded again which # causes file permissions to be lost. # See: https://github.com/actions/upload-artifact#permission-loss FROM ${MODE} AS source RUN chmod a+x /tmp/out/bin/* # ----------------------------------------------------------------------------- # Docker stage: final # ----------------------------------------------------------------------------- # Create an image containing just the binaries, configs & scripts needed to run # our app, and not the things needed to build it. # # The previous build stage from which binaries are copied is controlled by the # MODE ARG (see above). FROM ${BASE_IMG} AS final # Copy binaries from the 'source' build stage into the image we are building COPY --from=source /tmp/out/bin/* /usr/local/bin/ # Build variables for uid and guid of user to run container ARG RUN_USER=routinator ARG RUN_USER_UID=1012 ARG RUN_USER_GID=1012 # Install required runtime dependencies RUN apk add --no-cache libgcc rsync tini RUN addgroup -g ${RUN_USER_GID} ${RUN_USER} && \ adduser -D -u ${RUN_USER_UID} -G ${RUN_USER} ${RUN_USER} # Switch to our applications user USER $RUN_USER_UID # Hint to operators the TCP port that the application in this image listens on # (by default). The default Rotonda configuration configures Rotonda to listen # for HTTP requests on port 8080, incoming BGP connections on port 11179 and # incoming BMP connections on port 11019. For consistency we do the same. EXPOSE 8080/tcp EXPOSE 11019/tcp EXPOSE 11179/tcp # Use Tini to ensure that our application responds to CTRL-C when run in the # foreground without the Docker argument "--init" (which is actually another # way of activating Tini, but cannot be enabled from inside the Docker image). ENTRYPOINT ["/sbin/tini", "--", "rotonda"]