#!/bin/bash # Copyright 2014 The Kubernetes Authors All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # Common utilities, variables and checks for all build scripts. set -o errexit set -o nounset set -o pipefail DOCKER_OPTS=${DOCKER_OPTS:-""} DOCKER_NATIVE=${DOCKER_NATIVE:-""} DOCKER=(docker ${DOCKER_OPTS}) DOCKER_HOST=${DOCKER_HOST:-""} KUBE_ROOT=$(dirname "${BASH_SOURCE}")/.. cd "${KUBE_ROOT}" # This'll canonicalize the path KUBE_ROOT=$PWD source hack/lib/init.sh # Incoming options # readonly KUBE_SKIP_CONFIRMATIONS="${KUBE_SKIP_CONFIRMATIONS:-n}" readonly KUBE_GCS_UPLOAD_RELEASE="${KUBE_GCS_UPLOAD_RELEASE:-n}" readonly KUBE_GCS_NO_CACHING="${KUBE_GCS_NO_CACHING:-y}" readonly KUBE_GCS_MAKE_PUBLIC="${KUBE_GCS_MAKE_PUBLIC:-y}" # KUBE_GCS_RELEASE_BUCKET default: kubernetes-releases-${project_hash} readonly KUBE_GCS_RELEASE_PREFIX=${KUBE_GCS_RELEASE_PREFIX-devel}/ readonly KUBE_GCS_DOCKER_REG_PREFIX=${KUBE_GCS_DOCKER_REG_PREFIX-docker-reg}/ readonly KUBE_GCS_LATEST_FILE=${KUBE_GCS_LATEST_FILE:-} readonly KUBE_GCS_LATEST_CONTENTS=${KUBE_GCS_LATEST_CONTENTS:-} readonly KUBE_GCS_DELETE_EXISTING="${KUBE_GCS_DELETE_EXISTING:-n}" # Constants readonly KUBE_BUILD_IMAGE_REPO=kube-build # These get set in verify_prereqs with a unique hash based on KUBE_ROOT # KUBE_BUILD_IMAGE_TAG= # KUBE_BUILD_IMAGE="${KUBE_BUILD_IMAGE_REPO}:${KUBE_BUILD_IMAGE_TAG}" # KUBE_BUILD_CONTAINER_NAME=kube-build- readonly KUBE_BUILD_IMAGE_CROSS_TAG=cross readonly KUBE_BUILD_IMAGE_CROSS="${KUBE_BUILD_IMAGE_REPO}:${KUBE_BUILD_IMAGE_CROSS_TAG}" readonly KUBE_BUILD_GOLANG_VERSION=1.4 # KUBE_BUILD_DATA_CONTAINER_NAME=kube-build-data- # Here we map the output directories across both the local and remote _output # directories: # # *_OUTPUT_ROOT - the base of all output in that environment. # *_OUTPUT_SUBPATH - location where golang stuff is built/cached. Also # persisted across docker runs with a volume mount. # *_OUTPUT_BINPATH - location where final binaries are placed. If the remote # is really remote, this is the stuff that has to be copied # back. readonly LOCAL_OUTPUT_ROOT="${KUBE_ROOT}/_output" readonly LOCAL_OUTPUT_SUBPATH="${LOCAL_OUTPUT_ROOT}/dockerized" readonly LOCAL_OUTPUT_BINPATH="${LOCAL_OUTPUT_SUBPATH}/bin" readonly LOCAL_OUTPUT_IMAGE_STAGING="${LOCAL_OUTPUT_ROOT}/images" readonly OUTPUT_BINPATH="${CUSTOM_OUTPUT_BINPATH:-$LOCAL_OUTPUT_BINPATH}" readonly REMOTE_OUTPUT_ROOT="/go/src/${KUBE_GO_PACKAGE}/_output" readonly REMOTE_OUTPUT_SUBPATH="${REMOTE_OUTPUT_ROOT}/dockerized" readonly REMOTE_OUTPUT_BINPATH="${REMOTE_OUTPUT_SUBPATH}/bin" readonly DOCKER_MOUNT_ARGS_BASE=(--volume "${OUTPUT_BINPATH}:${REMOTE_OUTPUT_BINPATH}") # DOCKER_MOUNT_ARGS=("${DOCKER_MOUNT_ARGS_BASE[@]}" --volumes-from "${KUBE_BUILD_DATA_CONTAINER_NAME}") # We create a Docker data container to cache incremental build artifacts. We # need to cache both the go tree in _output and the go tree under Godeps. readonly REMOTE_OUTPUT_GOPATH="${REMOTE_OUTPUT_SUBPATH}/go" readonly REMOTE_GODEP_GOPATH="/go/src/${KUBE_GO_PACKAGE}/Godeps/_workspace/pkg" readonly DOCKER_DATA_MOUNT_ARGS=( --volume "${REMOTE_OUTPUT_GOPATH}" --volume "${REMOTE_GODEP_GOPATH}" ) # This is where the final release artifacts are created locally readonly RELEASE_STAGE="${LOCAL_OUTPUT_ROOT}/release-stage" readonly RELEASE_DIR="${LOCAL_OUTPUT_ROOT}/release-tars" readonly GCS_STAGE="${LOCAL_OUTPUT_ROOT}/gcs-stage" # The set of master binaries that run in Docker (on Linux) readonly KUBE_DOCKER_WRAPPED_BINARIES=( kube-apiserver kube-controller-manager kube-scheduler ) # The set of addons images that should be prepopulated readonly KUBE_ADDON_PATHS=( gcr.io/google_containers/pause:0.8.0 gcr.io/google_containers/kube-registry-proxy:0.3 ) # --------------------------------------------------------------------------- # Basic setup functions # Verify that the right utilities and such are installed for building Kube. Set # up some dynamic constants. # # Args: # $1 The type of operation to verify for. Only 'clean' is supported in which # case we don't verify docker. # # Vars set: # KUBE_ROOT_HASH # KUBE_BUILD_IMAGE_TAG # KUBE_BUILD_IMAGE # KUBE_BUILD_CONTAINER_NAME # KUBE_BUILD_DATA_CONTAINER_NAME # DOCKER_MOUNT_ARGS function kube::build::verify_prereqs() { kube::log::status "Verifying Prerequisites...." kube::build::ensure_tar || return 1 kube::build::ensure_docker_in_path || return 1 if kube::build::is_osx; then kube::build::docker_available_on_osx || return 1 fi kube::build::ensure_docker_daemon_connectivity || return 1 KUBE_ROOT_HASH=$(kube::build::short_hash "$KUBE_ROOT") KUBE_BUILD_IMAGE_TAG="build-${KUBE_ROOT_HASH}" KUBE_BUILD_IMAGE="${KUBE_BUILD_IMAGE_REPO}:${KUBE_BUILD_IMAGE_TAG}" KUBE_BUILD_CONTAINER_NAME="kube-build-${KUBE_ROOT_HASH}" KUBE_BUILD_DATA_CONTAINER_NAME="kube-build-data-${KUBE_ROOT_HASH}" DOCKER_MOUNT_ARGS=("${DOCKER_MOUNT_ARGS_BASE[@]}" --volumes-from "${KUBE_BUILD_DATA_CONTAINER_NAME}") } # --------------------------------------------------------------------------- # Utility functions function kube::build::docker_available_on_osx() { if [[ -z "${DOCKER_HOST}" ]]; then kube::log::status "No docker host is set. Checking options for setting one..." if [[ -z "$(which docker-machine)" && -z "$(which boot2docker)" ]]; then kube::log::status "It looks like you're running Mac OS X, and neither docker-machine or boot2docker are nowhere to be found." kube::log::status "See: https://docs.docker.com/machine/ for installation instructions." return 1 elif [[ -n "$(which docker-machine)" ]]; then kube::build::prepare_docker_machine elif [[ -n "$(which boot2docker)" ]]; then kube::build::prepare_boot2docker fi fi } function kube::build::prepare_docker_machine() { kube::log::status "docker-machine was found." docker-machine inspect kube-dev >/dev/null || { kube::log::status "Creating a machine to build Kubernetes" docker-machine create -d virtualbox kube-dev > /dev/null || { kube::log::error "Something went wrong creating a machine." kube::log::error "Try the following: " kube::log::error "docker-machine create -d kube-dev" return 1 } } docker-machine start kube-dev > /dev/null eval $(docker-machine env kube-dev) kube::log::status "A Docker host using docker-machine named kube-dev is ready to go!" return 0 } function kube::build::prepare_boot2docker() { kube::log::status "boot2docker cli has been deprecated in favor of docker-machine." kube::log::status "See: https://github.com/boot2docker/boot2docker-cli for more details." if [[ $(boot2docker status) != "running" ]]; then kube::log::status "boot2docker isn't running. We'll try to start it." boot2docker up || { kube::log::error "Can't start boot2docker." kube::log::error "You may need to 'boot2docker init' to create your VM." return 1 } fi # Reach over and set the clock. After sleep/resume the clock will skew. kube::log::status "Setting boot2docker clock" boot2docker ssh sudo date -u -D "%Y%m%d%H%M.%S" --set "$(date -u +%Y%m%d%H%M.%S)" >/dev/null kube::log::status "Setting boot2docker env variables" $(boot2docker shellinit) kube::log::status "boot2docker-vm has been successfully started." return 0 } function kube::build::is_osx() { [[ "$(uname)" == "Darwin" ]] } function kube::build::ensure_docker_in_path() { if [[ -z "$(which docker)" ]]; then kube::log::error "Can't find 'docker' in PATH, please fix and retry." kube::log::error "See https://docs.docker.com/installation/#installation for installation instructions." return 1 fi } function kube::build::ensure_docker_daemon_connectivity { if ! "${DOCKER[@]}" info > /dev/null 2>&1 ; then { echo "Can't connect to 'docker' daemon. please fix and retry." echo echo "Possible causes:" echo " - On Mac OS X, DOCKER_HOST hasn't been set. You may need to: " echo " - Create and start your VM using docker-machine or boot2docker: " echo " - docker-machine create -d kube-dev" echo " - boot2docker init && boot2docker start" echo " - Set your environment variables using: " echo " - eval \$(docker-machine env kube-dev)" echo " - \$(boot2docker shellinit)" echo " - On Linux, user isn't in 'docker' group. Add and relogin." echo " - Something like 'sudo usermod -a -G docker ${USER-user}'" echo " - RHEL7 bug and workaround: https://bugzilla.redhat.com/show_bug.cgi?id=1119282#c8" echo " - On Linux, Docker daemon hasn't been started or has crashed." } >&2 return 1 fi } function kube::build::ensure_tar() { if [[ -n "${TAR:-}" ]]; then return fi # Find gnu tar if it is available, bomb out if not. TAR=tar if which gtar &>/dev/null; then TAR=gtar else if which gnutar &>/dev/null; then TAR=gnutar fi fi if ! "${TAR}" --version | grep -q GNU; then echo " !!! Cannot find GNU tar. Build on Linux or install GNU tar" echo " on Mac OS X (brew install gnu-tar)." return 1 fi } function kube::build::clean_output() { # Clean out the output directory if it exists. if kube::build::has_docker ; then if kube::build::build_image_built ; then kube::log::status "Cleaning out _output/dockerized/bin/ via docker build image" kube::build::run_build_command bash -c "rm -rf '${REMOTE_OUTPUT_BINPATH}'/*" else kube::log::error "Build image not built. Cannot clean via docker build image." fi kube::log::status "Removing data container" "${DOCKER[@]}" rm -v "${KUBE_BUILD_DATA_CONTAINER_NAME}" >/dev/null 2>&1 || true fi kube::log::status "Cleaning out local _output directory" rm -rf "${LOCAL_OUTPUT_ROOT}" } # Make sure the _output directory is created and mountable by docker function kube::build::prepare_output() { mkdir -p "${LOCAL_OUTPUT_SUBPATH}" # On RHEL/Fedora SELinux is enabled by default and currently breaks docker # volume mounts. We can work around this by explicitly adding a security # context to the _output directory. # Details: https://access.redhat.com/documentation/en-US/Red_Hat_Enterprise_Linux/7/html/Resource_Management_and_Linux_Containers_Guide/sec-Sharing_Data_Across_Containers.html#sec-Mounting_a_Host_Directory_to_a_Container if which selinuxenabled &>/dev/null && \ selinuxenabled && \ which chcon >/dev/null ; then if [[ ! $(ls -Zd "${LOCAL_OUTPUT_ROOT}") =~ svirt_sandbox_file_t ]] ; then kube::log::status "Applying SELinux policy to '_output' directory." if ! chcon -Rt svirt_sandbox_file_t "${LOCAL_OUTPUT_ROOT}"; then echo " ***Failed***. This may be because you have root owned files under _output." echo " Continuing, but this build may fail later if SELinux prevents access." fi fi fi } function kube::build::has_docker() { which docker &> /dev/null } # Detect if a specific image exists # # $1 - image repo name # #2 - image tag function kube::build::docker_image_exists() { [[ -n $1 && -n $2 ]] || { kube::log::error "Internal error. Image not specified in docker_image_exists." exit 2 } # We cannot just specify the IMAGE here as `docker images` doesn't behave as # expected. See: https://github.com/docker/docker/issues/8048 "${DOCKER[@]}" images | grep -Eq "^(\S+/)?${1}\s+${2}\s+" } # Takes $1 and computes a short has for it. Useful for unique tag generation function kube::build::short_hash() { [[ $# -eq 1 ]] || { kube::log::error "Internal error. No data based to short_hash." exit 2 } local short_hash if which md5 >/dev/null 2>&1; then short_hash=$(md5 -q -s "$1") else short_hash=$(echo -n "$1" | md5sum) fi echo ${short_hash:0:10} } # Pedantically kill, wait-on and remove a container. The -f -v options # to rm don't actually seem to get the job done, so force kill the # container, wait to ensure it's stopped, then try the remove. This is # a workaround for bug https://github.com/docker/docker/issues/3968. function kube::build::destroy_container() { "${DOCKER[@]}" kill "$1" >/dev/null 2>&1 || true "${DOCKER[@]}" wait "$1" >/dev/null 2>&1 || true "${DOCKER[@]}" rm -f -v "$1" >/dev/null 2>&1 || true } # --------------------------------------------------------------------------- # Building function kube::build::build_image_built() { kube::build::docker_image_exists "${KUBE_BUILD_IMAGE_REPO}" "${KUBE_BUILD_IMAGE_TAG}" } function kube::build::ensure_golang() { kube::build::docker_image_exists golang "${KUBE_BUILD_GOLANG_VERSION}" || { [[ ${KUBE_SKIP_CONFIRMATIONS} =~ ^[yY]$ ]] || { echo "You don't have a local copy of the golang docker image. This image is 450MB." read -p "Download it now? [y/n] " -r echo [[ $REPLY =~ ^[yY]$ ]] || { echo "Aborting." >&2 exit 1 } } kube::log::status "Pulling docker image: golang:${KUBE_BUILD_GOLANG_VERSION}" "${DOCKER[@]}" pull golang:${KUBE_BUILD_GOLANG_VERSION} } } # The set of source targets to include in the kube-build image function kube::build::source_targets() { local targets=( api build cmd docs examples Godeps/_workspace/src Godeps/Godeps.json hack LICENSE pkg plugin README.md test third_party ) if [ -n "${KUBERNETES_CONTRIB:-}" ]; then for contrib in "${KUBERNETES_CONTRIB}"; do targets+=($(eval "kube::contrib::${contrib}::source_targets")) done fi echo "${targets[@]}" } # Set up the context directory for the kube-build image and build it. function kube::build::build_image() { kube::build::ensure_tar local -r build_context_dir="${LOCAL_OUTPUT_IMAGE_STAGING}/${KUBE_BUILD_IMAGE}" kube::build::build_image_cross mkdir -p "${build_context_dir}" "${TAR}" czf "${build_context_dir}/kube-source.tar.gz" $(kube::build::source_targets) kube::version::get_version_vars kube::version::save_version_vars "${build_context_dir}/kube-version-defs" cp build/build-image/Dockerfile ${build_context_dir}/Dockerfile kube::build::docker_build "${KUBE_BUILD_IMAGE}" "${build_context_dir}" } # Build the kubernetes golang cross base image. function kube::build::build_image_cross() { kube::build::ensure_golang local -r build_context_dir="${LOCAL_OUTPUT_ROOT}/images/${KUBE_BUILD_IMAGE}/cross" mkdir -p "${build_context_dir}" cp build/build-image/cross/Dockerfile ${build_context_dir}/Dockerfile kube::build::docker_build "${KUBE_BUILD_IMAGE_CROSS}" "${build_context_dir}" } # Build a docker image from a Dockerfile. # $1 is the name of the image to build # $2 is the location of the "context" directory, with the Dockerfile at the root. function kube::build::docker_build() { local -r image=$1 local -r context_dir=$2 local -ra build_cmd=("${DOCKER[@]}" build -t "${image}" "${context_dir}") kube::log::status "Building Docker image ${image}." local docker_output docker_output=$("${build_cmd[@]}" 2>&1) || { cat <&2 +++ Docker build command failed for ${image} ${docker_output} To retry manually, run: ${build_cmd[*]} EOF return 1 } } function kube::build::clean_image() { local -r image=$1 kube::log::status "Deleting docker image ${image}" "${DOCKER[@]}" rmi ${image} 2> /dev/null || true } function kube::build::clean_images() { kube::build::has_docker || return 0 kube::build::clean_image "${KUBE_BUILD_IMAGE}" kube::log::status "Cleaning all other untagged docker images" "${DOCKER[@]}" rmi $("${DOCKER[@]}" images -q --filter 'dangling=true') 2> /dev/null || true } function kube::build::ensure_data_container() { if ! "${DOCKER[@]}" inspect "${KUBE_BUILD_DATA_CONTAINER_NAME}" >/dev/null 2>&1; then kube::log::status "Creating data container" local -ra docker_cmd=( "${DOCKER[@]}" run "${DOCKER_DATA_MOUNT_ARGS[@]}" --name "${KUBE_BUILD_DATA_CONTAINER_NAME}" "${KUBE_BUILD_IMAGE}" true ) "${docker_cmd[@]}" fi } # Run a command in the kube-build image. This assumes that the image has # already been built. This will sync out all output data from the build. function kube::build::run_build_command() { kube::log::status "Running build command...." [[ $# != 0 ]] || { echo "Invalid input." >&2; return 4; } kube::build::ensure_data_container kube::build::prepare_output local -a docker_run_opts=( "--name=${KUBE_BUILD_CONTAINER_NAME}" "${DOCKER_MOUNT_ARGS[@]}" ) if [ -n "${KUBERNETES_CONTRIB:-}" ]; then docker_run_opts+=(-e "KUBERNETES_CONTRIB=${KUBERNETES_CONTRIB}") fi # If we have stdin we can run interactive. This allows things like 'shell.sh' # to work. However, if we run this way and don't have stdin, then it ends up # running in a daemon-ish mode. So if we don't have a stdin, we explicitly # attach stderr/stdout but don't bother asking for a tty. if [[ -t 0 ]]; then docker_run_opts+=(--interactive --tty) else docker_run_opts+=(--attach=stdout --attach=stderr) fi local -ra docker_cmd=( "${DOCKER[@]}" run "${docker_run_opts[@]}" "${KUBE_BUILD_IMAGE}") # Clean up container from any previous run kube::build::destroy_container "${KUBE_BUILD_CONTAINER_NAME}" "${docker_cmd[@]}" "$@" kube::build::destroy_container "${KUBE_BUILD_CONTAINER_NAME}" } # Test if the output directory is remote (and can only be accessed through # docker) or if it is "local" and we can access the output without going through # docker. function kube::build::is_output_remote() { rm -f "${LOCAL_OUTPUT_SUBPATH}/test_for_remote" kube::build::run_build_command touch "${REMOTE_OUTPUT_BINPATH}/test_for_remote" [[ ! -e "${LOCAL_OUTPUT_BINPATH}/test_for_remote" ]] } # If the Docker server is remote, copy the results back out. function kube::build::copy_output() { if kube::build::is_output_remote; then # At time of this code, docker cp does not work when copying from a volume. # As a workaround, the binaries are first copied to a local filesystem, # /tmp, then docker cp'd to the local binaries output directory. # The fix for the volume bug has been accepted and once it's widely # deployed the code below should be simplified to a simple docker cp # Bug: https://github.com/docker/docker/pull/8509 local -a docker_run_opts=( "--name=${KUBE_BUILD_CONTAINER_NAME}" "${DOCKER_MOUNT_ARGS[@]}" -d ) local -ra docker_cmd=( "${DOCKER[@]}" run "${docker_run_opts[@]}" "${KUBE_BUILD_IMAGE}" ) kube::log::status "Syncing back _output/dockerized/bin directory from remote Docker" rm -rf "${LOCAL_OUTPUT_BINPATH}" mkdir -p "${LOCAL_OUTPUT_BINPATH}" kube::build::destroy_container "${KUBE_BUILD_CONTAINER_NAME}" "${docker_cmd[@]}" bash -c "cp -r ${REMOTE_OUTPUT_BINPATH} /tmp/bin;touch /tmp/finished;rm /tmp/bin/test_for_remote;/bin/sleep 600" > /dev/null 2>&1 # Wait until binaries have finished coppying count=0 while true;do if docker "${DOCKER_OPTS}" cp "${KUBE_BUILD_CONTAINER_NAME}:/tmp/finished" "${LOCAL_OUTPUT_BINPATH}" > /dev/null 2>&1;then docker "${DOCKER_OPTS}" cp "${KUBE_BUILD_CONTAINER_NAME}:/tmp/bin" "${LOCAL_OUTPUT_SUBPATH}" break; fi let count=count+1 if [[ $count -eq 60 ]]; then # break after 5m kube::log::error "Timed out waiting for binaries..." break fi sleep 5 done "${DOCKER[@]}" rm -f -v "${KUBE_BUILD_CONTAINER_NAME}" >/dev/null 2>&1 || true else kube::log::status "Output directory is local. No need to copy results out." fi } # --------------------------------------------------------------------------- # Build final release artifacts function kube::release::clean_cruft() { # Clean out cruft find ${RELEASE_STAGE} -name '*~' -exec rm {} \; find ${RELEASE_STAGE} -name '#*#' -exec rm {} \; find ${RELEASE_STAGE} -name '.DS*' -exec rm {} \; } function kube::release::package_tarballs() { # Clean out any old releases rm -rf "${RELEASE_DIR}" mkdir -p "${RELEASE_DIR}" kube::release::package_client_tarballs & kube::release::package_server_tarballs & kube::release::package_salt_tarball & kube::util::wait-for-jobs || { kube::log::error "previous tarball phase failed"; return 1; } kube::release::package_full_tarball & # _full depends on all the previous phases kube::release::package_test_tarball & # _test doesn't depend on anything kube::util::wait-for-jobs || { kube::log::error "previous tarball phase failed"; return 1; } } # Package up all of the cross compiled clients. Over time this should grow into # a full SDK function kube::release::package_client_tarballs() { # Find all of the built client binaries local platform platforms platforms=($(cd "${LOCAL_OUTPUT_BINPATH}" ; echo */*)) for platform in "${platforms[@]}"; do local platform_tag=${platform/\//-} # Replace a "/" for a "-" kube::log::status "Starting tarball: client $platform_tag" ( local release_stage="${RELEASE_STAGE}/client/${platform_tag}/kubernetes" rm -rf "${release_stage}" mkdir -p "${release_stage}/client/bin" local client_bins=("${KUBE_CLIENT_BINARIES[@]}") if [[ "${platform%/*}" == "windows" ]]; then client_bins=("${KUBE_CLIENT_BINARIES_WIN[@]}") fi # This fancy expression will expand to prepend a path # (${LOCAL_OUTPUT_BINPATH}/${platform}/) to every item in the # KUBE_CLIENT_BINARIES array. cp "${client_bins[@]/#/${LOCAL_OUTPUT_BINPATH}/${platform}/}" \ "${release_stage}/client/bin/" kube::release::clean_cruft local package_name="${RELEASE_DIR}/kubernetes-client-${platform_tag}.tar.gz" kube::release::create_tarball "${package_name}" "${release_stage}/.." ) & done kube::log::status "Waiting on tarballs" kube::util::wait-for-jobs || { kube::log::error "client tarball creation failed"; exit 1; } } # Package up all of the server binaries function kube::release::package_server_tarballs() { local platform for platform in "${KUBE_SERVER_PLATFORMS[@]}" ; do local platform_tag=${platform/\//-} # Replace a "/" for a "-" kube::log::status "Building tarball: server $platform_tag" local release_stage="${RELEASE_STAGE}/server/${platform_tag}/kubernetes" rm -rf "${release_stage}" mkdir -p "${release_stage}/server/bin" mkdir -p "${release_stage}/addons" # This fancy expression will expand to prepend a path # (${LOCAL_OUTPUT_BINPATH}/${platform}/) to every item in the # KUBE_SERVER_BINARIES array. cp "${KUBE_SERVER_BINARIES[@]/#/${LOCAL_OUTPUT_BINPATH}/${platform}/}" \ "${release_stage}/server/bin/" kube::release::create_docker_images_for_server "${release_stage}/server/bin"; kube::release::write_addon_docker_images_for_server "${release_stage}/addons" # Include the client binaries here too as they are useful debugging tools. local client_bins=("${KUBE_CLIENT_BINARIES[@]}") if [[ "${platform%/*}" == "windows" ]]; then client_bins=("${KUBE_CLIENT_BINARIES_WIN[@]}") fi cp "${client_bins[@]/#/${LOCAL_OUTPUT_BINPATH}/${platform}/}" \ "${release_stage}/server/bin/" kube::release::clean_cruft local package_name="${RELEASE_DIR}/kubernetes-server-${platform_tag}.tar.gz" kube::release::create_tarball "${package_name}" "${release_stage}/.." done } function kube::release::md5() { if which md5 >/dev/null 2>&1; then md5 -q "$1" else md5sum "$1" | awk '{ print $1 }' fi } function kube::release::sha1() { if which shasum >/dev/null 2>&1; then shasum -a1 "$1" | awk '{ print $1 }' else sha1sum "$1" | awk '{ print $1 }' fi } # This will take binaries that run on master and creates Docker images # that wrap the binary in them. (One docker image per binary) function kube::release::create_docker_images_for_server() { # Create a sub-shell so that we don't pollute the outer environment ( local binary_name for binary_name in "${KUBE_DOCKER_WRAPPED_BINARIES[@]}"; do kube::log::status "Starting Docker build for image: ${binary_name}" ( local md5_sum md5_sum=$(kube::release::md5 "$1/${binary_name}") local docker_build_path="$1/${binary_name}.dockerbuild" local docker_file_path="${docker_build_path}/Dockerfile" local binary_file_path="$1/${binary_name}" rm -rf ${docker_build_path} mkdir -p ${docker_build_path} ln $1/${binary_name} ${docker_build_path}/${binary_name} printf " FROM busybox \n ADD ${binary_name} /usr/local/bin/${binary_name}\n" > ${docker_file_path} local docker_image_tag=gcr.io/google_containers/$binary_name:$md5_sum docker build -q -t "${docker_image_tag}" ${docker_build_path} >/dev/null docker save ${docker_image_tag} > ${1}/${binary_name}.tar echo $md5_sum > ${1}/${binary_name}.docker_tag rm -rf ${docker_build_path} kube::log::status "Deleting docker image ${docker_image_tag}" "${DOCKER[@]}" rmi ${docker_image_tag} 2>/dev/null || true ) & done kube::util::wait-for-jobs || { kube::log::error "previous Docker build failed"; return 1; } kube::log::status "Docker builds done" ) } # This will pull and save docker images for addons which need to placed # on the nodes directly. function kube::release::write_addon_docker_images_for_server() { # Create a sub-shell so that we don't pollute the outer environment ( local addon_path for addon_path in "${KUBE_ADDON_PATHS[@]}"; do ( kube::log::status "Pulling and writing Docker image for addon: ${addon_path}" local dest_name="${addon_path//\//\~}" docker pull "${addon_path}" docker save "${addon_path}" > "${1}/${dest_name}.tar" ) & done kube::util::wait-for-jobs || { kube::log::error "unable to pull or write addon image"; return 1; } kube::log::status "Addon images done" ) } # Package up the salt configuration tree. This is an optional helper to getting # a cluster up and running. function kube::release::package_salt_tarball() { kube::log::status "Building tarball: salt" local release_stage="${RELEASE_STAGE}/salt/kubernetes" rm -rf "${release_stage}" mkdir -p "${release_stage}" cp -R "${KUBE_ROOT}/cluster/saltbase" "${release_stage}/" # TODO(#3579): This is a temporary hack. It gathers up the yaml, # yaml.in, json files in cluster/addons (minus any demos) and overlays # them into kube-addons, where we expect them. (This pipeline is a # fancy copy, stripping anything but the files we don't want.) local objects objects=$(cd "${KUBE_ROOT}/cluster/addons" && find . \( -name \*.yaml -or -name \*.yaml.in -or -name \*.json \) | grep -v demo) tar c -C "${KUBE_ROOT}/cluster/addons" ${objects} | tar x -C "${release_stage}/saltbase/salt/kube-addons" kube::release::clean_cruft local package_name="${RELEASE_DIR}/kubernetes-salt.tar.gz" kube::release::create_tarball "${package_name}" "${release_stage}/.." } # This is the stuff you need to run tests from the binary distribution. function kube::release::package_test_tarball() { kube::log::status "Building tarball: test" local release_stage="${RELEASE_STAGE}/test/kubernetes" rm -rf "${release_stage}" mkdir -p "${release_stage}" local platform for platform in "${KUBE_CLIENT_PLATFORMS[@]}"; do local test_bins=("${KUBE_TEST_BINARIES[@]}") if [[ "${platform%/*}" == "windows" ]]; then test_bins=("${KUBE_TEST_BINARIES_WIN[@]}") fi mkdir -p "${release_stage}/platforms/${platform}" cp "${test_bins[@]/#/${LOCAL_OUTPUT_BINPATH}/${platform}/}" \ "${release_stage}/platforms/${platform}" done tar c ${KUBE_TEST_PORTABLE[@]} | tar x -C ${release_stage} kube::release::clean_cruft local package_name="${RELEASE_DIR}/kubernetes-test.tar.gz" kube::release::create_tarball "${package_name}" "${release_stage}/.." } # This is all the stuff you need to run/install kubernetes. This includes: # - precompiled binaries for client # - Cluster spin up/down scripts and configs for various cloud providers # - tarballs for server binary and salt configs that are ready to be uploaded # to master by whatever means appropriate. function kube::release::package_full_tarball() { kube::log::status "Building tarball: full" local release_stage="${RELEASE_STAGE}/full/kubernetes" rm -rf "${release_stage}" mkdir -p "${release_stage}" # Copy all of the client binaries in here, but not test or server binaries. # The server binaries are included with the server binary tarball. local platform for platform in "${KUBE_CLIENT_PLATFORMS[@]}"; do local client_bins=("${KUBE_CLIENT_BINARIES[@]}") if [[ "${platform%/*}" == "windows" ]]; then client_bins=("${KUBE_CLIENT_BINARIES_WIN[@]}") fi mkdir -p "${release_stage}/platforms/${platform}" cp "${client_bins[@]/#/${LOCAL_OUTPUT_BINPATH}/${platform}/}" \ "${release_stage}/platforms/${platform}" done # We want everything in /cluster except saltbase. That is only needed on the # server. cp -R "${KUBE_ROOT}/cluster" "${release_stage}/" rm -rf "${release_stage}/cluster/saltbase" mkdir -p "${release_stage}/server" cp "${RELEASE_DIR}/kubernetes-salt.tar.gz" "${release_stage}/server/" cp "${RELEASE_DIR}"/kubernetes-server-*.tar.gz "${release_stage}/server/" mkdir -p "${release_stage}/third_party" cp -R "${KUBE_ROOT}/third_party/htpasswd" "${release_stage}/third_party/htpasswd" cp -R "${KUBE_ROOT}/examples" "${release_stage}/" cp -R "${KUBE_ROOT}/docs" "${release_stage}/" cp "${KUBE_ROOT}/README.md" "${release_stage}/" cp "${KUBE_ROOT}/LICENSE" "${release_stage}/" cp "${KUBE_ROOT}/Vagrantfile" "${release_stage}/" mkdir -p "${release_stage}/contrib/completions/bash" cp "${KUBE_ROOT}/contrib/completions/bash/kubectl" "${release_stage}/contrib/completions/bash" kube::release::clean_cruft local package_name="${RELEASE_DIR}/kubernetes.tar.gz" kube::release::create_tarball "${package_name}" "${release_stage}/.." } # Build a release tarball. $1 is the output tar name. $2 is the base directory # of the files to be packaged. This assumes that ${2}/kubernetes is what is # being packaged. function kube::release::create_tarball() { kube::build::ensure_tar local tarfile=$1 local stagingdir=$2 "${TAR}" czf "${tarfile}" -C "${stagingdir}" kubernetes --owner=0 --group=0 } # --------------------------------------------------------------------------- # GCS Release function kube::release::gcs::release() { [[ ${KUBE_GCS_UPLOAD_RELEASE} =~ ^[yY]$ ]] || return 0 kube::release::gcs::verify_prereqs || return 1 kube::release::gcs::ensure_release_bucket || return 1 kube::release::gcs::copy_release_artifacts || return 1 } # Verify things are set up for uploading to GCS function kube::release::gcs::verify_prereqs() { if [[ -z "$(which gsutil)" || -z "$(which gcloud)" ]]; then echo "Releasing Kubernetes requires gsutil and gcloud. Please download," echo "install and authorize through the Google Cloud SDK: " echo echo " https://developers.google.com/cloud/sdk/" return 1 fi if [[ -z "${GCLOUD_ACCOUNT-}" ]]; then GCLOUD_ACCOUNT=$(gcloud auth list 2>/dev/null | awk '/(active)/ { print $2 }') fi if [[ -z "${GCLOUD_ACCOUNT-}" ]]; then echo "No account authorized through gcloud. Please fix with:" echo echo " gcloud auth login" return 1 fi if [[ -z "${GCLOUD_PROJECT-}" ]]; then GCLOUD_PROJECT=$(gcloud config list project | awk '{project = $3} END {print project}') fi if [[ -z "${GCLOUD_PROJECT-}" ]]; then echo "No account authorized through gcloud. Please fix with:" echo echo " gcloud config set project " return 1 fi } # Create a unique bucket name for releasing Kube and make sure it exists. function kube::release::gcs::ensure_release_bucket() { local project_hash project_hash=$(kube::build::short_hash "$GCLOUD_PROJECT") KUBE_GCS_RELEASE_BUCKET=${KUBE_GCS_RELEASE_BUCKET-kubernetes-releases-${project_hash}} if ! gsutil ls "gs://${KUBE_GCS_RELEASE_BUCKET}" >/dev/null 2>&1 ; then echo "Creating Google Cloud Storage bucket: $KUBE_GCS_RELEASE_BUCKET" gsutil mb -p "${GCLOUD_PROJECT}" "gs://${KUBE_GCS_RELEASE_BUCKET}" || return 1 fi } function kube::release::gcs::stage_and_hash() { kube::build::ensure_tar || return 1 # Split the args into srcs... and dst local -r args=( "$@" ) local -r split=$((${#args[@]}-1)) # Split point for src/dst args local -r srcs=( "${args[@]::${split}}" ) local -r dst="${args[${split}]}" for src in ${srcs[@]}; do srcdir=$(dirname ${src}) srcthing=$(basename ${src}) mkdir -p ${GCS_STAGE}/${dst} || return 1 "${TAR}" c -C ${srcdir} ${srcthing} | "${TAR}" x -C ${GCS_STAGE}/${dst} || return 1 done } function kube::release::gcs::copy_release_artifacts() { # TODO: This isn't atomic. There will be points in time where there will be # no active release. Also, if something fails, the release could be half- # copied. The real way to do this would perhaps to have some sort of release # version so that we are never overwriting a destination. local -r gcs_destination="gs://${KUBE_GCS_RELEASE_BUCKET}/${KUBE_GCS_RELEASE_PREFIX}" kube::log::status "Staging release artifacts to ${GCS_STAGE}" rm -rf ${GCS_STAGE} || return 1 mkdir -p ${GCS_STAGE} || return 1 # Stage everything in release directory kube::release::gcs::stage_and_hash "${RELEASE_DIR}"/* . || return 1 # Having the configure-vm.sh and trusty/node.yaml scripts from the GCE cluster # deploy hosted with the release is useful for GKE. kube::release::gcs::stage_and_hash "${RELEASE_STAGE}/full/kubernetes/cluster/gce/configure-vm.sh" extra/gce || return 1 kube::release::gcs::stage_and_hash "${RELEASE_STAGE}/full/kubernetes/cluster/gce/trusty/node.yaml" extra/gce || return 1 # Upload the "naked" binaries to GCS. This is useful for install scripts that # download the binaries directly and don't need tars. local platform platforms platforms=($(cd "${RELEASE_STAGE}/client" ; echo *)) for platform in "${platforms[@]}"; do local src="${RELEASE_STAGE}/client/${platform}/kubernetes/client/bin/*" local dst="bin/${platform/-//}/" # We assume here the "server package" is a superset of the "client package" if [[ -d "${RELEASE_STAGE}/server/${platform}" ]]; then src="${RELEASE_STAGE}/server/${platform}/kubernetes/server/bin/*" fi kube::release::gcs::stage_and_hash "$src" "$dst" || return 1 done kube::log::status "Hashing files in ${GCS_STAGE}" find ${GCS_STAGE} -type f | while read path; do kube::release::md5 ${path} > "${path}.md5" || return 1 kube::release::sha1 ${path} > "${path}.sha1" || return 1 done kube::log::status "Copying release artifacts to ${gcs_destination}" # First delete all objects at the destination if gsutil ls "${gcs_destination}" >/dev/null 2>&1; then kube::log::error "${gcs_destination} not empty." [[ ${KUBE_GCS_DELETE_EXISTING} =~ ^[yY]$ ]] || { read -p "Delete everything under ${gcs_destination}? [y/n] " -r || { echo "EOF on prompt. Skipping upload" return } [[ $REPLY =~ ^[yY]$ ]] || { echo "Skipping upload" return } } gsutil -q -m rm -f -R "${gcs_destination}" || return 1 fi local gcs_options=() if [[ ${KUBE_GCS_NO_CACHING} =~ ^[yY]$ ]]; then gcs_options=("-h" "Cache-Control:private, max-age=0") fi gsutil -q -m "${gcs_options[@]+${gcs_options[@]}}" cp -r "${GCS_STAGE}"/* ${gcs_destination} || return 1 # TODO(jbeda): Generate an HTML page with links for this release so it is easy # to see it. For extra credit, generate a dynamic page that builds up the # release list using the GCS JSON API. Use Angular and Bootstrap for extra # extra credit. if [[ ${KUBE_GCS_MAKE_PUBLIC} =~ ^[yY]$ ]]; then kube::log::status "Marking all uploaded objects public" gsutil -q -m acl ch -R -g all:R "${gcs_destination}" >/dev/null 2>&1 || return 1 fi gsutil ls -lhr "${gcs_destination}" || return 1 } function kube::release::gcs::publish_latest() { local latest_file_dst="gs://${KUBE_GCS_RELEASE_BUCKET}/${KUBE_GCS_LATEST_FILE}" mkdir -p "${RELEASE_STAGE}/upload" || return 1 echo ${KUBE_GCS_LATEST_CONTENTS} > "${RELEASE_STAGE}/upload/latest" || return 1 gsutil -m cp "${RELEASE_STAGE}/upload/latest" "${latest_file_dst}" || return 1 if [[ ${KUBE_GCS_MAKE_PUBLIC} =~ ^[yY]$ ]]; then gsutil acl ch -R -g all:R "${latest_file_dst}" >/dev/null 2>&1 || return 1 fi kube::log::status "gsutil cat ${latest_file_dst}:" gsutil cat ${latest_file_dst} || return 1 } # Publish a new latest.txt, but only if the release we're dealing with # is newer than the contents in GCS. function kube::release::gcs::publish_latest_official() { local -r new_version=${KUBE_GCS_LATEST_CONTENTS} local -r latest_file_dst="gs://${KUBE_GCS_RELEASE_BUCKET}/${KUBE_GCS_LATEST_FILE}" local -r version_regex="^v(0|[1-9][0-9]*)\\.(0|[1-9][0-9]*)\\.(0|[1-9][0-9]*)$" [[ ${new_version} =~ ${version_regex} ]] || { kube::log::error "publish_latest_official passed bogus value: '${new_version}'" return 1 } local -r version_major="${BASH_REMATCH[1]}" local -r version_minor="${BASH_REMATCH[2]}" local -r version_patch="${BASH_REMATCH[3]}" local gcs_version gcs_version=$(gsutil cat "${latest_file_dst}") [[ ${gcs_version} =~ ${version_regex} ]] || { kube::log::error "${latest_file_dst} contains invalid release version, can't compare: '${gcs_version}'" return 1 } local -r gcs_version_major="${BASH_REMATCH[1]}" local -r gcs_version_minor="${BASH_REMATCH[2]}" local -r gcs_version_patch="${BASH_REMATCH[3]}" local greater=true if [[ "${gcs_version_major}" -gt "${version_major}" ]]; then greater=false elif [[ "${gcs_version_major}" -lt "${version_major}" ]]; then : # fall out elif [[ "${gcs_version_minor}" -gt "${version_minor}" ]]; then greater=false elif [[ "${gcs_version_minor}" -lt "${version_minor}" ]]; then : # fall out elif [[ "${gcs_version_patch}" -ge "${version_patch}" ]]; then greater=false fi if [[ "${greater}" != "true" ]]; then kube::log::status "${gcs_version} (latest on GCS) >= ${new_version} (just uploaded), not updating ${latest_file_dst}" return 0 fi kube::log::status "${new_version} (just uploaded) > ${gcs_version} (latest on GCS), updating ${latest_file_dst}" kube::release::gcs::publish_latest || return 1 }