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DockerSlim (docker-slim): Don't change anything in your Docker container image and minify it by up to 30x (and for compiled languages even more) making it secure too! (free and open source)

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Install SlimToolkit Get Examples

Try Slim.AI SaaS

Optimize Your Experience with Containers. Make Your Containers Better, Smaller, More Secure and Do Less to Get There (free and open source!)

Note that DockerSlim is now just Slim (SlimToolkit is the full name, so it's easier to find it online) to show its growing support for additional container tools and runtimes in the cloud native ecosystem.

Slim was created by Kyle Quest and it's been improved by many contributors. The project is supported by Slim.AI.

Overview

Slim is a tool for developers with a number of different commands (build, xray, lint, debug and others) to simplify and optimize your developer experience with containers. It makes your containers better, smaller and more secure while providing advanced visibility and improved usability working with the original and minified containers.

Don't change anything in your container image and minify it by up to 30x making it secure too! Optimizing images isn't the only thing it can do though. It can also help you understand and author better container images.

Keep doing what you are doing. No need to change anything. Use the base image you want. Use the package manager you want. Don't worry about hand optimizing your Dockerfile. You shouldn't have to throw away your tools and your workflow to have small container images.

Don't worry about manually creating Seccomp and AppArmor security profiles. You shouldn't have to become an expert in Linux syscalls, Seccomp and AppArmor to have secure containers. Even if you do know enough about it wasting time reverse engineering your application behavior can be time-consuming.

Slim will optimize and secure your containers by understanding your application and what it needs using various analysis techniques. It will throw away what you don't need, reducing the attack surface of your container. What if you need some of those extra things to debug your container? You can use dedicated debugging side-car containers for that (more details below).

Understand your container image before and after you optimize it using the xray command in the slim app or the Slim.AI SaaS where you can get even more powerful insights including how your container image changed.

Slim has been used with Node.js, Python, Ruby, Java, Go, Rust, Elixir and PHP (some app types) running on Ubuntu, Debian, CentOS, Alpine and even Distroless.

Note that some application stacks do require advanced container probing to make sure that all dynamically loaded components are detected. See the --http-probe* flags for more details to know how you can define custom probe commands. In some cases you might also need to use the --include-path flag to make sure everything your application needs is included (e.g., ubuntu.com python SPA app container image example where the client side template files are explicitly included).

It's also a good idea to use your app/environment tests when you run the Slim app. See the --continue-after flag for more details about integrating your tests with the temporary container Slim creates when it's doing its dynamic analysis. Running tests in the target container is also an option, but it does require you to specify a custom ENTRYPOINT/CMD with a custom wrapper to start your app and to execute your tests.

Slim How

Interactive CLI prompt screencast:

asciicast

Watch this screencast to see how an application image is minified by more than 30x.

asciicast

When you run the build or profile commands in Slim it gives you an opportunity to interact with the temporary container it creates. By default, it will pause and wait for your input before it continues its execution. You can change this behavior using the --continue-after flag.

If your application exposes any web interfaces (e.g., when you have a web server or an HTTP API), you'll see the port numbers on the host machine you will need to use to interact with your application (look for the port.list and target.port.info messages on the screen). For example, in the screencast above you'll see that the internal application port 8000 is mapped to port 32911 on your host.

Note that Slim will interact with your application for you when HTTP probing is enabled (enabled by default; see the --http-probe* flag docs for more details). Some web applications built with scripting languages like Python or Ruby require service interactions to load everything in the application. Enable HTTP probing unless it gets in your way.

You can also interact with the temporary container via a shell script or snippet using --exec-file or --exec. For example, you can create a container which is only capable of using curl.

>> docker pull archlinux:latest
...

>> slim build --target archlinux:latest --tag archlinux:curl --http-probe=false --exec "curl checkip.amazonaws.com"
...

>> docker run archlinux:curl curl checkip.amazonaws.com
...

>> docker images
archlinux                 curl                ...        ...         17.4MB
archlinux                 latest              ...        ...         467MB
...

Community

Feel free to join any of these channels or just open a new Github issue if you want to chat or if you need help.

Slim on the Internet

Books:

Minification Examples

You can find the examples in a separate repository: https://github.com/slimtoolkit/examples

Node.js application images:

  • from ubuntu:14.04 - 432MB => 14MB (minified by 30.85X)
  • from debian:jessie - 406MB => 25.1MB (minified by 16.21X)
  • from node:alpine - 66.7MB => 34.7MB (minified by 1.92X)
  • from node:distroless - 72.7MB => 39.7MB (minified by 1.83X)

Python application images:

  • from ubuntu:14.04 - 438MB => 16.8MB (minified by 25.99X)
  • from python:2.7-alpine - 84.3MB => 23.1MB (minified by 3.65X)
  • from python:2.7.15 - 916MB => 27.5MB (minified by 33.29X)
  • from centos:7 - 647MB => 23MB (minified by 28.57X)
  • from centos/python-27-centos7 - 700MB => 24MB (minified by 29.01X)
  • from python2.7:distroless - 60.7MB => 18.3MB (minified by 3.32X)

Ruby application images:

  • from ubuntu:14.04 - 433MB => 13.8MB (minified by 31.31X)
  • from ruby:2.2-alpine - 319MB => 27MB (minified by 11.88X)
  • from ruby:2.5.3 - 978MB => 30MB (minified by 32.74X)

Go application images:

  • from golang:latest - 700MB => 1.56MB (minified by 448.76X)
  • from ubuntu:14.04 - 531MB => 1.87MB (minified by 284.10X)
  • from golang:alpine - 258MB => 1.56MB (minified by 165.61X)
  • from centos:7 - 615MB => 1.87MB (minified by 329.14X)

Rust application images:

  • from rust:1.31 - 2GB => 14MB (minified by 147.16X)

Java application images:

  • from ubuntu:14.04 - 743.6 MB => 100.3 MB

PHP application images:

  • from php:7.0-cli - 368MB => 26.6MB (minified by 13.85X)

Haskell application images:

  • (Scotty service) from haskell:8 - 2.09GB => 16.6MB (minified by 125.32X)
  • (Scotty service) from haskell:7 - 1.5GB => 21MB (minified by 71X)

Elixir application images:

  • (Phoenix service) from elixir:1.6 - 1.1 GB => 37 MB (minified by 29.25X)

RECENT UPDATES

Latest version: 1.40.0 (1/15/2023)

The 1.37.x-1.40.x releases add an experimental docker-compose support and various improved application tracing capabilities for the build command.

For more info about the latest release see the CHANGELOG.

INSTALLATION

If you already have Slim installed use the update command to get the latest version:

slim update

Downloads

  1. Download the zip package for your platform.

    • Latest Mac binaries (curl -L -o ds.zip https://downloads.dockerslim.com/releases/1.40.0/dist_mac.zip)

    • Latest Mac M1 binaries (curl -L -o ds.zip https://downloads.dockerslim.com/releases/1.40.0/dist_mac_m1.zip)

    • Latest Linux binaries (curl -L -o ds.tar.gz https://downloads.dockerslim.com/releases/1.40.0/dist_linux.tar.gz)

    • Latest Linux ARM binaries (curl -L -o ds.tar.gz https://downloads.dockerslim.com/releases/1.40.0/dist_linux_arm.tar.gz)

    • Latest Linux ARM64 binaries (curl -L -o ds.tar.gz https://downloads.dockerslim.com/releases/1.40.0/dist_linux_arm64.tar.gz)

  2. Unzip the package and optionally move it to your bin directory.

Linux (for non-intel replace dist_linux with the platform-specific extracted path):

tar -xvf ds.tar.gz
mv  dist_linux/docker-slim /usr/local/bin/
mv  dist_linux/docker-slim-sensor /usr/local/bin/

Mac:

unzip ds.zip
mv  dist_mac/docker-slim /usr/local/bin/
mv  dist_mac/docker-slim-sensor /usr/local/bin/
  1. Add the location where you unzipped the package to your PATH environment variable (optional).

If the directory where you extracted the binaries is not in your PATH then you'll need to run your Slim app binary from that directory.

Scripted Install

You can also use this script to install the current release of Slim on Linux (x86 and ARM) and macOS (x86 and Apple Silicon)

curl -sL https://raw.githubusercontent.com/slimtoolkit/slim/master/scripts/install-slim.sh | sudo -E bash -

Homebrew

brew install docker-slim

The Homebrew installer: https://formulae.brew.sh/formula/docker-slim

Docker

docker pull dslim/slim

See the RUNNING CONTAINERIZED section for more usage info.

SaaS

Powered by Slim. It will help you understand and troubleshoot your application containers and a lot more. If you use the xray command you'll want to try the SaaS. Understanding image changes is easy with its container diff capabilities. Connect your own registry and you can do the same with your own containers. Try it here without installing anything locally.

BASIC USAGE INFO

slim [global flags] [lint|xray|build|profile|update|version|help] [command-specific flags] <IMAGE_ID_OR_NAME>

If you don't specify any command slim will start in the interactive prompt mode.

COMMANDS

  • xray - Performs static analysis for the target container image (including 'reverse engineering' the Dockerfile for the image). Use this command if you want to know what's inside of your container image and what makes it fat.
  • lint - Analyzes container instructions in Dockerfiles (Docker image support is WIP)
  • build - Analyzes, profiles and optimizes your container image generating the supported security profiles. This is the most popular command.
  • registry - Execute registry operations.
  • profile - Performs basic container image analysis and dynamic container analysis, but it doesn't generate an optimized image.
  • run - Runs one or more containers (for now runs a single container similar to docker run)
  • version - Shows the version information.
  • update - Updates Slim to the latest version.
  • help - Show the available commands and global flags

Example: slim build my/sample-app

See the USAGE DETAILS section for more details. Run slim help to get a high level overview of the available commands. Run slim COMMAND_NAME without any parameters and you'll get more information about that command (e.g., slim build).

If you run slim without any parameters you'll get an interactive prompt that will provide suggestions about the available commands and flags. Tabs are used to show the available options, to autocomplete the parameters and to navigate the option menu (which you can also do with Up and Down arrows). Spaces are used to move to the next parameter and Enter is used to run the command. For more info about the interactive prompt see go-prompt.

USAGE DETAILS

slim [global options] command [command options] <target image ID or name>

Commands:

  • xray - Show what's in the container image and reverse engineer its Dockerfile
  • lint - Lint the target Dockerfile (or image, in the future)
  • build - Analyze the target container image along with its application and build an optimized image from it
  • registry - Execute registry operations.
  • profile - Collect fat image information and generate a fat container report
  • version - Show app and docker version information
  • update - Update the app
  • help - Show help info

Global options:

  • --report - command report location (target location where to save the executed command results; slim.report.json by default; set it to off to disable)
  • --check-version - check if the current version is outdated
  • --version - print the version
  • --debug - enable debug logs
  • --verbose - enable info logs
  • --log-level - set the logging level ('debug', 'info', 'warn' (default), 'error', 'fatal', 'panic')
  • --log-format - set the format used by logs ('text' (default), or 'json')
  • --console-format - set the console output format to use ('text' (default), or 'json')
  • --log - log file to store logs
  • --host - Docker host address or socket (prefix with tcp:// or unix://)
  • --tls - use TLS connecting to Docker
  • --tls-verify - do TLS verification
  • --tls-cert-path - path to TLS cert files
  • --state-path value - Slim state base path (must set it if the Slim binaries are not in a writable directory!)
  • --archive-state - Archives Slim state to the selected Docker volume (default volume - slim-state). By default, enabled when Slim is running in a container (disabled otherwise). Set it to off to disable explicitly.
  • --in-container - Set it to true to explicitly indicate that Slim is running in a container (if it's not set Slim will try to analyze the environment where it's running to determine if it's containerized)

To disable the version checks set the global --check-version flag to false (e.g., --check-version=false) or you can use the DSLIM_CHECK_VERSION environment variable.

LINT COMMAND OPTIONS

  • --target - target Dockerfile path (or Docker image, in the future; if you don't use this flag you must specify the target as the argument to the command)
  • --target-type - explicitly specify the command target type (values: dockerfile, image)
  • --skip-build-context - don't try to analyze build context
  • --build-context-dir - explicitly specify the build context directory
  • --skip-dockerignore - don't try to analyze .dockerignore
  • --include-check-label - include checks with the selected label key:value
  • --exclude-check-label - exclude checks with the selected label key:value
  • --include-check-id - check ID to include
  • --include-check-id-file - file with check IDs to include
  • --exclude-check-id - check ID to exclude
  • --exclude-check-id-file - file with check IDs to exclude
  • --show-nohits - show checks with no matches
  • --show-snippet - show check match snippet (default value: true)
  • --list-checks - list available checks (don't need to specify the target flag if you just want to list the available checks)

XRAY COMMAND OPTIONS

  • --target - Target container image (name or ID)
  • --pull - Try pulling target if it's not available locally (default: false).
  • --docker-config-path - Set the docker config path used to fetch registry credentials (used with the --pull flag).
  • --registry-account - Account to be used when pulling images from private registries (used with the --pull flag).
  • --registry-secret - Account secret to be used when pulling images from private registries (used with the --pull and --registry-account flags).
  • --show-plogs - Show image pull logs (default: false).
  • --changes value - Show layer change details for the selected change type (values: none, all, delete, modify, add).
  • --changes-output value - Where to show the changes (values: all, report, console).
  • --layer value - Show details for the selected layer (using layer index or ID)
  • --add-image-manifest - Add raw image manifest to the command execution report file
  • --add-image-config - Add raw image config object to the command execution report file
  • --layer-changes-max - Maximum number of changes to show for each layer
  • --all-changes-max - Maximum number of changes to show for all layers
  • --add-changes-max - Maximum number of add changes to show for all layers
  • --modify-changes-max - Maximum number of modify changes to show for all layers
  • --delete-changes-max - Maximum number of delete changes to show for all layers
  • --change-path value - Include changes for the files that match the path pattern (Glob/Match in Go and **). Value formats: <path pattern> | dump:<output type>:<path pattern> | ::<path pattern> where output type is console or a directory name. If value starts with dump: the match will be 'dumped' to the selected output type. [can use this flag multiple times]
  • --change-data value - Include changes for the files that match the data pattern (regex). Value formats: <data regex> | dump:<output type>:<path pattern>:<data regex> | ::<path pattern>:<data regex> | :::<data regex> where output type is console or a directory name. If value starts with dump: the match will be 'dumped' to the selected output type. [can use this flag multiple times]
  • --change-data-hash value - Include changes for the files that match the provided data hashes (sha1). Value formats: <sha1 hash> | dump:<output type>:<sha1 hash> | ::<sha1 hash> where output type is console or a directory name. If value starts with dump: the match will be 'dumped' to the selected output type. [can use this flag multiple times]
  • --reuse-saved-image - Reuse saved container image (default: true).
  • --top-changes-max - Maximum number of top changes to track (defalt: 20).
  • --hash-data - Generate file data hashes (default: false).
  • --detect-duplicates - Detect duplicate files based on their hashes (default: true).
  • --show-duplicates - Show all discovered duplicate file paths (default: false).
  • --show-special-perms - Show files with special permissions (setuid,setgid,sticky) (default: true)
  • --detect-utf8 - Detect utf8 files and optionally extract the discovered utf8 file content (possible values: "true" or "dump" or "dump:output_target.tgz" or "dump:output_target.tgz::max_size_bytes" or "dump:output_target.tgz:::max_size_bytes").
  • --detect-all-certs - Detect all certifcate files
  • --detect-all-cert-pks - Detect all certifcate private key files
  • --change-match-layers-only - Show only layers with change matches (default: false).
  • --export-all-data-artifacts - TAR archive file path to export all text data artifacts (if value is set to . then the archive file path defaults to ./data-artifacts.tar)
  • --remove-file-artifacts - Remove file artifacts when command is done (note: you'll loose the reverse engineered Dockerfile)

Change Types:

  • none - Don't show any file system change details in image layers (the top changes from the corresponding layer are still shown)
  • all - Show all file system change details in image layers
  • delete - Show only delete file system change details in image layers
  • modify - Show only modify file system change details in image layers
  • add - Show only 'add' file system change details in image layers

In the interactive CLI prompt mode you must specify the target image using the --target flag while in the traditional CLI mode you can use the --target flag or you can specify the target image as the last value in the command.

BUILD COMMAND OPTIONS

  • --target - Target container image (name or ID). It's an alternative way to provide the target information. The standard way to provide the target information is by putting as the last value in the build command CLI call.

  • --pull - Try pulling target if it's not available locally (default: false).

  • --docker-config-path - Set the docker config path used to fetch registry credentials (used with the --pull flag).

  • --registry-account - Account to be used when pulling images from private registries (used with the --pull flag).

  • --registry-secret - Account secret to be used when pulling images from private registries (used with the --pull and --registry-account flags).

  • --show-plogs - Show image pull logs (default: false).

  • --compose-file - Load container info from selected compose file

  • --target-compose-svc - Target service from compose file

  • --target-compose-svc-image - Override the container image name and/or tag when targetting a compose service using the target-compose-svc parameter (format: tag_name or image_name:tag_name)

  • --target-compose-svc-no-ports - Do not publish ports for target service from compose file

  • --dep-exclude-compose-svc-all - Do not start any compose services as target dependencies

  • --dep-include-compose-svc - Include specific compose service as a target dependency (only selected services will be started)

  • --dep-exclude-compose-svc - Exclude specific service from the compose services that will be started as target dependencies

  • --dep-include-compose-svc-deps - Include all dependencies for the selected compose service (excluding the service itself) as target dependencies

  • --dep-include-target-compose-svc-deps - Include all dependencies for the target compose service (excluding the service itself) as target dependencies. This is a shortcut flag to avoid repeating the service name (it's a pretty long flag name though :-))

  • --compose-svc-start-wait - Number of seconds to wait before starting each compose service

  • --compose-net - Attach target to the selected compose network(s) otherwise all networks will be attached

  • --compose-env-nohost - Don't include the env vars from the host to compose

  • --compose-env-file - Load compose env vars from file (host env vars override the values loaded from this file)

  • --compose-workdir - Set custom work directory for compose

  • --compose-project-name - Use custom project name for compose

  • --container-probe-compose-svc - Container test/probe service from compose file

  • --prestart-compose-svc - placeholder for now

  • --poststart-compose-svc - placeholder for now

  • --http-probe - Enables/disables HTTP probing (ENABLED by default; you have to disable the probe if you don't need it by setting the flag to false: --http-probe=false)

  • --http-probe-off - Alternative way to disable HTTP probing

  • --http-probe-cmd - Additional HTTP probe command [can use this flag multiple times]

  • --http-probe-cmd-file - File with user defined HTTP probe commands

  • --http-probe-start-wait - Number of seconds to wait before starting HTTP probing

  • --http-probe-retry-count - Number of retries for each HTTP probe (default value: 5)

  • --http-probe-retry-wait - Number of seconds to wait before retrying HTTP probe (doubles when target is not ready; default value: 8)

  • --http-probe-ports - Explicit list of ports to probe (in the order you want them to be probed; excluded ports are not probed!)

  • --http-probe-full - Do full HTTP probe for all selected ports (if false, finish after first successful scan; default value: false)

  • --http-probe-exit-on-failure - Exit when all HTTP probe commands fail (default value: true)

  • --http-probe-crawl - Enable crawling for the default HTTP probe command (default value: true)

  • --http-crawl-max-depth - Max depth to use for the HTTP probe crawler (default value: 3)

  • --http-crawl-max-page-count - Max number of pages to visit for the HTTP probe crawler (default value: 1000)

  • --http-crawl-concurrency - Number of concurrent workers when crawling an HTTP target (default value: 10)

  • --http-max-concurrent-crawlers - Number of concurrent crawlers in the HTTP probe (default value: 1)

  • --http-probe-apispec - Run HTTP probes for API spec where the value represents the target path where the spec is available (supports Swagger 2.x and OpenAPI 3.x) [can use this flag multiple times]

  • --http-probe-apispec-file - Run HTTP probes for API spec from file (supports Swagger 2.x and OpenAPI 3.x) [can use this flag multiple times]

  • --http-probe-exec - App to execute when running HTTP probes. [can use this flag multiple times]

  • --http-probe-exec-file - Apps to execute when running HTTP probes loaded from file.

  • --publish-port - Map container port to host port analyzing image at runtime to make it easier to integrate external tests (format => port | hostPort:containerPort | hostIP:hostPort:containerPort | hostIP::containerPort )[can use this flag multiple times]

  • --publish-exposed-ports - Map all exposed ports to the same host ports analyzing image at runtime (default value: false)

  • --show-clogs - Show container logs (from the container used to perform dynamic inspection)

  • --show-blogs - Show build logs (when the minified container is built)

  • --copy-meta-artifacts - Copy meta artifacts to the provided location

  • --remove-file-artifacts - Remove file artifacts when command is done (note: you'll loose autogenerated Seccomp and Apparmor profiles unless you copy them with the copy-meta-artifacts flag or if you archive the state)

  • --tag - Use a custom tag for the generated image (instead of the default value: <original_image_name>.slim) [can use this flag multiple times if you need to create additional tags for the optimized image]

  • --entrypoint - Override ENTRYPOINT analyzing image at runtime

  • --cmd - Override CMD analyzing image at runtime

  • --mount - Mount volume analyzing image (the mount parameter format is identical to the -v mount command in Docker) [can use this flag multiple times]

  • --include-path - Include directory or file from image [can use this flag multiple times] (optionally overwriting the artifact's permissions, user and group information; format: target:octalPermFlags#uid#gid ; see the non-default USER FAQ section for more details)

  • --include-path-file - Load directory or file includes from a file (optionally overwriting the artifact's permissions, user and group information; format: target:octalPermFlags#uid#gid ; see the non-default USER FAQ section for more details)

  • --include-bin value - Include binary from image (executable or shared object using its absolute path)

  • --include-bin-file - Load shared binary file includes from a file (similar to --include-path-file)

  • --include-exe value - Include executable from image (by executable name)

  • --include-exe-file - Load executable file includes from a file (similar to --include-path-file)

  • --include-shell - Include basic shell functionality (default value: false)

  • --include-cert-all - Keep all discovered cert files (default: true)

  • --include-cert-bundles-only - Keep only cert bundles

  • --include-cert-dirs - Keep known cert directories and all files in them

  • --include-cert-pk-all - Keep all discovered cert private keys

  • --include-cert-pk-dirs - Keep known cert private key directories and all files in them

  • --include-new - Keep new files created by target during dynamic analysis (default value: true)

  • --include-oslibs-net - Keep the common networking OS libraries (default value: true)

  • --include-app-nuxt-dir - Keep the root Nuxt.js app directory (default value: false)

  • --include-app-nuxt-build-dir - Keep the build Nuxt.js app directory (default value: false)

  • --include-app-nuxt-dist-dir - Keep the dist Nuxt.js app directory (default value: false)

  • --include-app-nuxt-static-dir - Keep the static asset directory for Nuxt.js apps (default value: false)

  • --include-app-nuxt-nodemodules-dir - Keep the node modules directory for Nuxt.js apps (default value: false)

  • --include-app-next-dir - Keep the root Next.js app directory (default value: false)

  • --include-app-next-build-dir - Keep the build directory for Next.js app (default value: false)

  • --include-app-next-dist-dir - Keep the static SPA directory for Next.js apps (default value: false)

  • --include-app-next-static-dir - Keep the static public asset directory for Next.js apps (default value: false)

  • --include-app-next-nodemodules-dir - Keep the node modules directory for Next.js apps (default value: false)

  • --include-node-package - Keep node.js package by name [can use this flag multiple times]

  • --preserve-path - Keep path from orignal image in its initial state (changes to the selected container image files when it runs will be discarded). [can use this flag multiple times]

  • --preserve-path-file - File with paths to keep from original image in their original state (changes to the selected container image files when it runs will be discarded).

  • --path-perms - Set path permissions/user/group in optimized image (format: target:octalPermFlags#uid#gid ; see the non-default USER FAQ section for more details)

  • --path-perms-file - File with path permissions to set (format: target:octalPermFlags#uid#gid ; see the non-default USER FAQ section for more details)

  • --exclude-pattern - Exclude path pattern (Glob/Match in Go and **) from image

  • --exclude-mounts - Exclude mounted volumes from image (default value: true)

  • --label - Override or add LABEL analyzing image at runtime [can use this flag multiple times]

  • --volume - Add VOLUME analyzing image at runtime [can use this flag multiple times]

  • --env - Override ENV analyzing image at runtime [can use this flag multiple times]

  • --workdir - Override WORKDIR analyzing image at runtime

  • --network - Override default container network settings analyzing image at runtime

  • --expose - Use additional EXPOSE instructions analyzing image at runtime [can use this flag multiple times]

  • --link - Add link to another container analyzing image at runtime [can use this flag multiple times]

  • --hostname - Override default container hostname analyzing image at runtime

  • --etc-hosts-map - Add a host to IP mapping to /etc/hosts analyzing image at runtime [can use this flag multiple times]

  • --container-dns - Add a dns server analyzing image at runtime [can use this flag multiple times]

  • --container-dns-search - Add a dns search domain for unqualified hostnames analyzing image at runtime [can use this flag multiple times]

  • --image-overrides - Save runtime overrides in generated image (values is all or a comma delimited list of override types: entrypoint, cmd, workdir, env, expose, volume, label). Use this flag if you need to set a runtime value and you want to persist it in the optimized image. If you only want to add, edit or delete an image value in the optimized image use one of the --new-* or --remove-* flags (define below).

  • --continue-after - Select continue mode: enter | signal | probe | exec | timeout-number-in-seconds | container.probe (default value if http probes are disabled: enter). You can also select probe and exec together: 'probe&exec' (make sure to use quotes around the two modes or the & will break the shell command).

  • --dockerfile - The source Dockerfile name to build the fat image before it's optimized.

  • --tag-fat - Custom tag for the fat image built from Dockerfile.

  • --cbo-add-host - Add an extra host-to-IP mapping in /etc/hosts to use when building an image (Container Build Option).

  • --cbo-build-arg - Add a build-time variable (Container Build Option).

  • --cbo-label - Add a label when building from Dockerfiles (Container Build Option).

  • --cbo-target - Target stage to build for multi-stage Dockerfiles (Container Build Option).

  • --cbo-network - Networking mode to use for the RUN instructions at build-time (Container Build Option).

  • --cbo-cache-from - Add an image to the build cache (Container Build Option).

  • --cro-runtime - Runtime to use with the created containers (Container Runtime Option).

  • --cro-host-config-file - File to load the Docker host configuration data (JSON format) to use when running the container. See the HostConfig struct definition from the go-dockerclient package for configuration details. Note that Slim will automatically add SYS_ADMIN to the list of capabilities and run the container in privileged mode, which are required to generate the seccomp profiles. The host config parameters specified using their standalone build or profile command flags overwrite the values in the host config file (volume binds are merged).

  • --cro-sysctl - Set namespaced kernel parameters in the created container (Container Runtime Option).

  • --cro-shm-size - Shared memory size for /dev/shm in the created container (Container Runtime Option).

  • --use-local-mounts - Mount local paths for target container artifact input and output (off, by default)

  • --use-sensor-volume - Sensor volume name to use (set it to your Docker volume name if you manage your own Slim sensor volume).

  • --keep-tmp-artifacts - Keep temporary artifacts when command is done (off, by default).

  • --keep-perms - Keep artifact permissions as-is (default: true)

  • --run-target-as-user - Run target app (in the temporary container) as USER from Dockerfile (true, by default)

  • --new-entrypoint - New ENTRYPOINT instruction for the optimized image

  • --new-cmd - New CMD instruction for the optimized image

  • --new-expose - New EXPOSE instructions for the optimized image

  • --new-workdir - New WORKDIR instruction for the optimized image

  • --new-env - New ENV instructions for the optimized image

  • --new-label - New LABEL instructions for the optimized image

  • --new-volume - New VOLUME instructions for the optimized image

  • --remove-volume - Remove VOLUME instructions for the optimized image

  • --remove-env - Remove ENV instructions for the optimized image

  • --remove-label - Remove LABEL instructions for the optimized image

  • --remove-expose - Remove EXPOSE instructions for the optimized image

  • --exec - A shell script snippet to run via Docker exec

  • --exec-file - A shell script file to run via Docker exec

  • --sensor-ipc-mode - Select sensor IPC mode: proxy | direct (useful for containerized CI/CD environments)

  • --sensor-ipc-endpoint - Override sensor IPC endpoint

  • --rta-onbuild-base-image - Enable runtime analysis for onbuild base images (default: false)

  • --rta-source-ptrace - Enable PTRACE runtime analysis source (default: true)

In the interactive CLI prompt mode you must specify the target image using the --target flag while in the traditional CLI mode you can use the --target flag or you can specify the target image as the last value in the command.

The --include-path option is useful if you want to customize your minified image adding extra files and directories. The --include-path-file option allows you to load multiple includes from a newline delimited file. Use this option if you have a lot of includes. The includes from --include-path and --include-path-file are combined together. You can also use the --exclude-pattern flag to control what shouldn't be included.

The --continue-after option is useful if you need to script the Slim app. If you pick the probe option then Slim will continue executing the build command after the HTTP probe is done executing. If you pick the exec options then Slim will continue executing the build command after the container exec shell commands (specified using the --exec-file or --exec flags) are done executing. If you pick the timeout option Slim will allow the target container to run for 60 seconds before it will attempt to collect the artifacts. You can specify a custom timeout value by passing a number of seconds you need instead of the timeout string. If you pick the signal option you'll need to send a USR1 signal to the Slim app process. The signal option is useful when you want to run your own tests against the temporary container Slim creates. Your test automation / CI/CD pipeline will be able to notify the Slim app that it's done running its test by sending the USR1 to it.

You can also combine multiple continue-after modes. For now only combining probe and exec is supported (using either probe&exec or exec&probe as the --continue-after flag value). Other combinations may work too. Combining probe and signal is not supported.

The --include-shell option provides a simple way to keep a basic shell in the minified container. Not all shell commands are included. To get additional shell commands or other command line utilities use the --include-exe and/or --include-bin options. Note that the extra apps and binaries might missed some of the non-binary dependencies (which don't get picked up during static analysis). For those additional dependencies use the --include-path and --include-path-file options.

The --dockerfile option makes it possible to build a new minified image directly from source Dockerfile. Pass the Dockerfile name as the value for this flag and pass the build context directory or URL instead of the docker image name as the last parameter for the build command: slim build --dockerfile Dockerfile --tag my/custom_minified_image_name . If you want to see the console output from the build stages (when the fat and slim images are built) add the --show-blogs build flag. Note that the build console output is not interactive and it's printed only after the corresponding build step is done. The fat image created during the build process has the .fat suffix in its name. If you specify a custom image tag (with the --tag flag) the .fat suffix is added to the name part of the tag. If you don't provide a custom tag the generated fat image name will have the following format: slim-tmp-fat-image.<pid_of_slim>.<current_timestamp>. The minified image name will have the .slim suffix added to that auto-generated container image name (slim-tmp-fat-image.<pid_of_slim>.<current_timestamp>.slim). Take a look at this python examples to see how it's using the --dockerfile flag.

The --use-local-mounts option is used to choose how the Slim sensor is added to the target container and how the sensor artifacts are delivered back to the master. If you enable this option you'll get the original Slim app behavior where it uses local file system volume mounts to add the sensor executable and to extract the artifacts from the target container. This option doesn't always work as expected in the dockerized environment where Slim itself is running in a Docker container. When this option is disabled (default behavior) then a separate Docker volume is used to mount the sensor and the sensor artifacts are explicitly copied from the target container.

REGISTRY COMMAND OPTIONS

PULL SUBCOMMAND OPTIONS

USAGE: slim registry pull [IMAGE]

  • --target value - Target container image (name or ID) [$DSLIM_TARGET]
  • --save-to-docker- Save pulled image to docker (default: true) [$DSLIM_REG_PULL_SAVE_TO_DOCKER]

PUSH SUBCOMMAND OPTIONS

USAGE: slim registry push [IMAGE]

COPY SUBCOMMAND OPTIONS

USAGE: slim registry copy [SRC_IMAGE] [DST_IMAGE]

RUNNING CONTAINERIZED

The current version of Slim is able to run in containers. It will try to detect if it's running in a containerized environment, but you can also tell Slim explicitly using the --in-container global flag.

You can run Slim in your container directly or you can use the Slim container image in your containerized environment. If you are using the Slim container image make sure you run it configured with the Docker IPC information, so it can communicate with the Docker daemon. The most common way to do it is by mounting the Docker unix socket to the Slim app container. Some containerized environments (like Gitlab and their dind service) might not expose the Docker unix socket to you, so you'll need to make sure the environment variables used to communicate with Docker (e.g., DOCKER_HOST) are passed to the Slim app container. Note that if those environment variables reference any kind of local host names those names need to be replaced or you need to tell the Slim app about them using the --etc-hosts-map flag. If those environment variables reference local files those local files (e.g., files for TLS cert validation) will need to be copied to a temporary container, so that temporary container can be used as a data container to make those files accessible by the Slim app container.

When Slim app runs in a container it will attempt to save its execution state in a separate Docker volume. If the volume doesn't exist it will try to create it (slim-state, by default). You can pick a different state volume or disable this behavior completely by using the global --archive-state flag. If you do want to persist the Slim app execution state (which includes the seccomp and AppArmor profiles) without using the state archiving feature you can mount your own volume that maps to the /bin/.slim-state directory in the Slim app container.

By default, the Slim app will try to create a Docker volume for its sensor unless one already exists. If this behavior is not supported by your containerized environment you can create a volume separately and pass its name to the Slim app using the --use-sensor-volume flag.

Here's a basic example of how to use the containerized version of the Slim app: docker run -it --rm -v /var/run/docker.sock:/var/run/docker.sock dslim/slim build your-docker-image-name

Here's a GitLab example for their dind .gitlab-ci.yml config file: docker run -e DOCKER_HOST=tcp://$(grep docker /etc/hosts | cut -f1):2375 dslim/slim build your-docker-image-name

Here's a CircleCI example for their remote docker .circleci/config.yml config file (used after the setup_remote_docker step):

docker create -v /dcert_path --name dcert alpine:latest /bin/true
docker cp $DOCKER_CERT_PATH/. dcert:/dcert_path
docker run --volumes-from dcert -e DOCKER_HOST=$DOCKER_HOST -e DOCKER_TLS_VERIFY=$DOCKER_TLS_VERIFY -e DOCKER_CERT_PATH=/dcert_path dslim/slim build your-docker-image-name

DOCKER CONNECT OPTIONS

If you don't specify any Docker connect options the Slim app expects to find the following environment variables: DOCKER_HOST, DOCKER_TLS_VERIFY (optional), DOCKER_CERT_PATH (required if DOCKER_TLS_VERIFY is set to "1")

If the Docker environment variables are configured to use TLS and to verify the Docker cert (default behavior), but you want to disable the TLS verification you can override the TLS verification behavior by setting the --tls-verify to false:

slim --tls-verify=false build my/sample-node-app-multi

You can override all Docker connection options using these flags: --host, --tls, --tls-verify, --tls-cert-path. These flags correspond to the standard Docker options (and the environment variables).

If you want to use TLS with verification:

slim --host=tcp://192.168.99.100:2376 --tls-cert-path=/Users/youruser/.docker/machine/machines/default --tls=true --tls-verify=true build my/sample-node-app-multi

If you want to use TLS without verification:

slim --host=tcp://192.168.99.100:2376 --tls-cert-path=/Users/youruser/.docker/machine/machines/default --tls=true --tls-verify=false build my/sample-node-app-multi

If the Docker environment variables are not set and if you don't specify any Docker connect options Slim will try to use the default unix socket.

HTTP PROBE COMMANDS

If the HTTP probe is enabled (note: it is enabled by default) it will default to running GET / with HTTP and then HTTPS on every exposed port. You can add additional commands using the --http-probe-cmd and --http-probe-cmd-file options.

If you want to disable HTTP probing set the --http-probe flag to false (e.g., --http-probe=false). You can also use the --http-probe-off flag to do the same (simply use the flag without any parameters).

The --http-probe-cmd option is good when you want to specify a small number of simple commands where you select some or all of these HTTP command options: crawling (defaults to false), protocol, method (defaults to GET), resource (path and query string).

If you only want to use custom HTTP probe command and you don't want the default GET / command added to the command list you explicitly provided you'll need to set --http-probe to false when you specify your custom HTTP probe command. Note that this inconsistency will be addressed in the future releases to make it less confusing.

Possible field combinations:

  • /path - runs GET /path
  • crawl:/path - runs GET /path and then crawls the pages referenced by the target page
  • post:/path - runs POST /path
  • crawl:get:/path - runs GET /path and then crawls the pages referenced by the target page
  • https:get:/path runs GET /path only on https
  • crawl:http:get:/path - runs GET /path and then crawls the pages referenced by the target page

Here are a couple of examples:

Adds two extra probe commands: GET /api/info and POST /submit (tries http first, then tries https): slim build --show-clogs --http-probe-cmd /api/info --http-probe-cmd POST:/submit my/sample-node-app-multi

Adds one extra probe command: POST /submit (using only http): slim build --show-clogs --http-probe-cmd http:POST:/submit my/sample-node-app-multi

The --http-probe-cmd-file option is good when you have a lot of commands and/or you want to select additional HTTP command options.

Available HTTP command options:

  • method - HTTP method to use
  • resource - target resource URL
  • port - port number
  • protocol - http, https, http2, http2c (cleartext version of http2), ws, wss (secure websocket)
  • headers - array of strings with column delimited key/value pairs (e.g., "Content-Type: application/json")
  • body - request body as a string
  • body_file - request body loaded from the provided file
  • username - username to use for basic auth
  • password - password to use for basic auth
  • crawl - boolean to indicate if you want to crawl the target (to visit all referenced resources)

Here's a probe command file example:

slim build --show-clogs --http-probe-cmd-file probeCmds.json my/sample-node-app-multi

Commands in probeCmds.json:

{
  "commands":
  [
   {
     "resource": "/api/info"
   },
   {
     "method": "POST",
     "resource": "/submit"
   },
   {
     "procotol": "http",
     "resource": "/api/call?arg=one"
   },
   {
     "protocol": "http",
     "method": "POST",
     "resource": "/submit2",
     "body": "key=value"
   },
   {
     "protocol": "http",
     "method": "POST",
     "resource": "/submit3",
     "body_file": "mydata.json",
     "headers": ["Content-Type: application/json"]
   }
  ]
}

The HTTP probe command file path can be a relative path (relative to the current working directory) or it can be an absolute path.

For each HTTP probe call Slim will print the call status. Example: info=http.probe.call status=200 method=GET target=http://127.0.0.1:32899/ attempt=1 error=none.

You can execute your own external HTTP requests using the target.port.list field in the container info message Slim prints when it starts its test container: slim[build]: info=container name=<your_container_name> id=<your_container_id> target.port.list=[<comma_separated_list_of_port_numbers_to_use>] target.port.info=[<comma_separated_list_of_port_mapping_records>]. Example: slim[build]: info=container name=slimk_42861_20190203084955 id=aa44c43bcf4dd0dae78e2a8b3ac011e7beb6f098a65b09c8bce4a91dc2ff8427 target.port.list=[32899] target.port.info=[9000/tcp => 0.0.0.0:32899]. With this information you can run curl or other HTTP request generating tools: curl http://localhost:32899.

The current version also includes an experimental crawling capability. To enable it for the default HTTP probe use the --http-probe-crawl flag. You can also enable it for the HTTP probe commands in your command file using the crawl boolean field.

When crawling is enabled the HTTP probe will act like a web crawler following the links it finds in the target endpoint.

Probing based on the Swagger/OpenAPI spec is another experimental capability. This feature introduces two new flags:

  • http-probe-apispec - value: <path_to_fetch_spec>:<api_endpoint_prefix>
  • http-probe-apispec-file - value: <local_file_path_to_spec>

You can use the --http-probe-exec and --http-probe-exec-file options to run the user provided commands when the http probes are executed. This example shows how you can run curl against the temporary container created by Slim when the http probes are executed.

slim build --http-probe-exec 'curl http://localhost:YOUR_CONTAINER_PORT_NUM/some/path' --publish-port YOUR_CONTAINER_PORT_NUM your-container-image-name

DEBUGGING MINIFIED CONTAINERS

You can create dedicated debugging side-car container images loaded with the tools you need for debugging target containers. This allows you to keep your production container images small. The debugging side-car containers attach to the running target containers.

Assuming you have a running container named node_app_alpine you can attach your debugging side-car with a command like this: docker run --rm -it --pid=container:node_app_alpine --net=container:node_app_alpine --cap-add sys_admin alpine sh. In this example, the debugging side-car is a regular alpine image. This is exactly what happens with the node_alpine app sample (located in the node_alpine directory of the examples repo) and the run_debug_sidecar.command helper script.

If you run the ps command in the side-car you'll see the application from the target container:

# ps
PID   USER     TIME   COMMAND
    1 root       0:00 node /opt/my/service/server.js
   13 root       0:00 sh
   38 root       0:00 ps

You can access the target container file system through /proc/<TARGET_PID>/root:

# ls -lh /proc/1/root/opt/my/service
total 8
drwxr-xr-x    3 root     root        4.0K Sep  2 15:51 node_modules
-rwxr-xr-x    1 root     root         415 Sep  8 00:52 server.js

Some of the useful debugging commands include cat /proc/<TARGET_PID>/cmdline, ls -l /proc/<TARGET_PID>/cwd, cat /proc/1/environ, cat /proc/<TARGET_PID>/limits, cat /proc/<TARGET_PID>/status and ls -l /proc/<TARGET_PID>/fd.

MINIFYING COMMAND LINE TOOLS

Unless the default CMD instruction in your Dockerfile is sufficient you'll have to specify command line parameters when you execute the build command in Slim. This can be done with the --cmd option.

Other useful command line parameters:

  • --show-clogs - use it if you want to see the output of your container.
  • --mount - use it to mount a volume when Slim inspects your image.
  • --entrypoint - use it if you want to override the ENTRYPOINT instruction when Slim inspects your image.

Note that the --entrypoint and --cmd options don't override the ENTRYPOINT and CMD instructions in the final minified image.

Here's a sample build command:

slim build --show-clogs=true --cmd docker-compose.yml --mount $(pwd)/data/:/data/ dslim/container-transform

It's used to minify the container-transform tool. You can get the minified image from Docker Hub.

QUICK SECCOMP EXAMPLE

If you want to auto-generate a Seccomp profile AND minify your image use the build command. If you only want to auto-generate a Seccomp profile (along with other interesting image metadata) use the profile command.

Step one: run Slim

slim build your-name/your-app

Step two: use the generated Seccomp profile

docker run --security-opt seccomp:<slim directory>/.images/<YOUR_APP_IMAGE_ID>/artifacts/your-name-your-app-seccomp.json <your other run params> your-name/your-app

Feel free to copy the generated profile :-)

You can use the generated Seccomp profile with your original image or with the minified image.

USING AUTO-GENERATED SECCOMP PROFILES

You can use the generated profile with your original image or with the minified image Slim created:

docker run -it --rm --security-opt seccomp:path_to/my-sample-node-app-seccomp.json -p 8000:8000 my/sample-node-app.slim

ORIGINAL DEMO VIDEO

DockerSlim demo

Demo video on YouTube

DEMO STEPS

The demo runs on Mac OS X, but you can build a linux version. Note that these steps are different from the steps in the demo video.

  1. Get the Slim app binaries:

Unzip them and optionally add their directory to your PATH environment variable if you want to use the app from other locations.

The extracted directory contains two binaries (and now it also contains a symlink for the old name):

  • slim <- the main Slim application binary
  • slim-sensor <- the sensor application used to collect information from running containers
  • docker-slim <- the symlink to slim, the new main app binary (useful if you are still using the old name in your scripts)
  1. Clone the examples repo to use the sample apps (note: the examples have been moved to a separate repo). You can skip this step if you have your own app.

git clone https://github.com/slimtoolkit/examples.git

  1. Create a Docker image for the sample node.js app in examples/node_ubuntu. You can skip this step if you have your own app.

cd examples/node_ubuntu

docker build -t my/sample-node-app .

  1. Run the Slim app:

./slim build my/sample-node-app <- run it from the location where you extraced the Slim app binaries (or update your PATH env var to include the directory where the Slim app binaries are located)

Slim creates a special container based on the target image you provided. It also creates a resource directory where it stores the information it discovers about your image: <slim directory>/.images/<TARGET_IMAGE_ID>.

By default, the Slim app will run its http probe against the temporary container. If you are minifying a command line tool that doesn't expose any web service interface you'll need to explicitly disable http probing (by setting --http-probe=false).

  1. Use curl (or other tools) to call the sample app (optional)

curl http://<YOUR_DOCKER_HOST_IP>:<PORT>

This is an optional step to make sure the target app container is doing something. Depending on the application it's an optional step. For some applications it's required if it loads new application resources dynamically based on the requests it's processing (e.g., Ruby or Python).

You'll see the mapped ports printed to the console when the Slim app starts the target container. You can also get the port number either from the docker ps or docker port <CONTAINER_ID> commands. The current version of DockerSlim doesn't allow you to map exposed network ports (it works like docker run … -P).

  1. Press and wait until the Slim app says it's done

By default or when http probing is enabled explicitly the Slim app will continue its execution once the http probe is done running. If you explicitly picked a different continue-after option follow the expected steps. For example, for the enter continue-after option you must press the enter button on your keyboard.

If http probing is enabled (when http-probe is set) and if continue-after is set to enter and you press the enter key before the built-in HTTP probe is done the probe might produce an EOF error because the Slim app will shut down the target container before all probe commands are done executing. It's ok to ignore it unless you really need the probe to finish.

  1. Once Slim is done check that the new minified image is there

docker images

You should see my/sample-node-app.slim in the list of images. Right now all generated images have .slim at the end of its name.

  1. Use the minified image

docker run -it --rm --name="slim_node_app" -p 8000:8000 my/sample-node-app.slim

FAQ

Is it safe for production use?

Yes! Either way, you should test your Docker images.

How can I contribute if I don't know Go?

You don't need to read the language spec and lots of books :-) Go through the Tour of Go and optionally read 50 Shades of Go and you'll be ready to contribute!

What's the best application for Slim?

Slim will work for any containerized application; however, Slim automates app interactions for applications with an HTTP API. You can use Slim even if your app doesn't have an HTTP API. You'll need to interact with your application manually to make sure Slim can observe your application behavior.

Can I use Slim with dockerized command line tools?

Yes. The --cmd, --entrypoint, and --mount options will help you minify your image. The container-transform tool is a good example.

Notes:

You can explore the artifacts Slim generates when it's creating a slim image. You'll find those in <slim directory>/.images/<TARGET_IMAGE_ID>/artifacts. One of the artifacts is a "reverse engineered" Dockerfile for the original image. It'll be called Dockerfile.fat.

If you'd like to see the artifacts without running the Slim app you can take a look at the examples/artifacts directory in this repo. It doesn't include any image files, but you'll find:

  • a reverse engineered Dockerfile (Dockerfile.fat)
  • a container report file (creport.json)
  • a sample AppArmor profile (which will be named based on your original image name)
  • and a sample Seccomp profile

If you don't want to create a minified image and only want to "reverse engineer" the Dockerfile you can use the info command.

What if my Docker images uses the USER command?

The current version of Slim does include support for non-default users (take a look at the non-default user examples (including the ElasticSearch example located in the 3rdparty directory) in the examples repo. Please open tickets if something doesn't work for you.

Everything should work as-is, but for the special cases where the current behavior don't work as expected you can adjust what Slim does using various build command parameters: --run-target-as-user, --keep-perms, --path-perms, --path-perms-file (along with the --include-* parameters).

The --run-target-as-user parameter is enabled by default and it controls if the application in the temporary container is started using the identity from the USER instruction in the container's Dockerfile.

The --keep-perms parameter is also enabled by default. It tells Slim to retain the permissions and the ownership information for the files and directories copied to the optimized container image.

The --path-perms and --path-perms-file parameters are similar to the --include-path and --include-path-file parameters. They are used to overwrite the permission and the user/group information for the target files and directories. Note that the target files/directories are expected to be in the optimized container image. If you don't know if the target files/directories will be in the optimized container you'll need to use one of the --include-* parameters (e.g., --include-path-file) to explicitly require those artifacts to be included. You can specify the permissions and the ownership information in the --include-* parameters too (so you don't need to have the --path-* parameters just to set the permissions).

The --path-* and --include-* params use the same format to communicate the permission/owernship info: TARGET_PATH_OR_NAME:PERMS_IN_OCTAL_FORMAT#USER_ID#GROUP_ID.

You don't have to specify the user and group IDs if you don't want to change them.

Here's an example using these parameters to minify the standard nginx image adding extra artifacts and changing their permissions: slim build --include-path='/opt:770#104#107' --include-path='/bin/uname:710' --path-perms='/tmp:700' nginx.

This is what you'll see in the optimized container image:

drwx------  0 0      0           0 Feb 28 22:15 tmp/
-rwx--x---  0 0      0       31240 Mar 14  2015 bin/uname
drwxrwx---  0 104    107         0 Feb 28 22:13 opt/

The uname binary isn't used by nginx, so the --include-path parameter is used to keep it in the optimized image changing its permissions to 710.

The /tmp directory will be included in the optimized image on its own, so the --path-perms parameter is used to change its permissions to 700.

When you set permissions/user/group on a directory the settings are only applied to that directory and not to the artifacts inside. The future versions will allow you to apply the same settings to everything inside the target directory too.

Also note that for now you have to use numeric user and group IDs. The future versions will allow you to use user and group names too.

Nginx fails in my minified image

If you see nginx: [emerg] mkdir() "/var/lib/nginx/body" failed it means your nginx setup uses a non-standard temporary directory. Nginx will fail if the base directory for its temporary folders doesn't exist (they won't create the missing intermediate directories). Normally it's /var/lib/nginx, but if you have a custom config that points to something else you'll need to add an --include-path flag as an extra flag when you run the Slim app.

Slim fails with a 'no permission to read from' error

This problem shouldn't happen anymore because the exported artifacts are saved in a tar file and the master app doesn't need to access the files directly anymore.

If you run older versions of Slim you can get around this problem by running Slim from a root shell. That way it will have access to all exported files.

Slim copies the relevant image artifacts trying to preserve their permissions. If the permissions are too restrictive the master app might not have sufficient priviledge to access these files when it's building the new minified image.

BUILD PROCESS

Build Options

Pick one of the build options that works best for you.

Containerized

Run make build_in_docker on linux or make build_m1_in_docker on Macs (or ./scripts/docker-builder.run.sh or click on ./scripts/mac/docker-builder.run.command on Macs) from the project directory (builds Slim in a Docker container; great if you don't want to install Go on your local machine and if you already have Docker).

Native

Run make build on linux or make build_m1 on Macs (or ./scripts/src.build.sh or click on ./scripts/mac/src.build.command on Macs) to build Slim natively (requires Go installed locally).

Note:

Try using the latest version of Go building the Slim app. The current version of Go used to build the Slim app is 1.19.

Gitpod

If you have a web browser, you can get a fully pre-configured development environment in one click:

Open in Gitpod

Additional Tools
  • license-bill-of-materials - Optional tool to track dependencies and their licenses.
  • golint - Optional tool for code analysis. See https://github.com/golang/lint for more details.

You can install these tools using the tools.get.sh shell script in the scripts directory.

Notes:

  • Make sure you have golint if you intend to run the src.inspect.sh or mac.src.inspect.command scripts.

CONTRIBUTING

If the project sounds interesting or if you found a bug see CONTRIBUTING.md and submit a PR!

DESIGN

To learn more about the code take a look at this interactive code diagram generated using CodeSee and watch the Slim Code videos on 'YouTube'.

CORE CONCEPTS

  1. Inspect container metadata (static analysis)
  2. Inspect container data (static analysis)
  3. Inspect running application (dynamic analysis)
  4. Build an application artifact graph
  5. Use the collected application data to build small images
  6. Use the collected application data to auto-generate various security framework configurations.

DYNAMIC ANALYSIS OPTIONS

  1. Instrument the container image (and replace the entrypoint/cmd) to collect application activity data
  2. Use kernel-level tools that provide visibility into running containers (without instrumenting the containers)
  3. Disable relevant namespaces in the target container to gain container visibility (can be done with runC)

SECURITY

The goal is to auto-generate Seccomp, AppArmor, (and potentially SELinux) profiles based on the collected information.

  • AppArmor profiles
  • Seccomp profiles

CHALLENGES

Some of the advanced analysis options require a number of Linux kernel features that are not always included. The kernel you get with Docker Machine / Boot2docker is a great example of that.

DEVELOPMENT PROGRESS

TODO

  • AppArmor profile improvements
  • Better support for command line applications (e.g., ability to specify multiple executions)
  • Discover HTTP endpoints to make the HTTP probe more intelligent.
  • Scripting language dependency discovery in the "scanner" app.
  • Explore additional dependency discovery methods.
  • "Live" image create mode - to create new images from containers where users install their applications interactively.

The WISHLIST doc includes even more potential improvements.

ORIGINS

DockerSlim was a Docker Global Hack Day #dockerhackday project. It barely worked at the time, but it did get a win in Seattle and it took the second place in the Plumbing category overall :-)

DHD3

Since then it's been improved and it works pretty well for its core use cases. It can be better though. That's why the project needs your help! You don't need to know much about the container internals, container runtimes and you don't need to know anything about Go. You can contribute in many different ways. For example, use Slim on your images and open Github issues documenting your experience even if it worked just fine :-)

MINIFIED IMAGES ON DOCKER HUB

LICENSE

Apache License v2, see LICENSE for details.


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DockerSlim (docker-slim): Don't change anything in your Docker container image and minify it by up to 30x (and for compiled languages even more) making it secure too! (free and open source)

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