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Manof

The jew crane

Overview

What it is

Manof is a tool for building and running multi-container Docker applications, similar to Crane and Docker compose (if it supported build). Manof takes an imperative approach where configuration is expressed through Python code instead of static configuration files (json/yaml). Rather than have several mostly duplicated .yml files, users leverage everything in the Python arsenal to describe their environments in a single manofest.py python module.
Manof itself is Python-based (Twisted).

A short example

  1. Create a small manofest.py file (Or use the one in examples/basic/manofest.py):

    import manof
    
    
    class MobyBase(manof.Image):
    
        @property
        def detach(self):
            return False
    
        @property
        def rm_on_run(self):
            return True
    
        @property
        def labels(self):
            return {
                'manofest-class': self.name,
            }
    
        @property
        def env(self):
            return [
                {'VERSE': 'Plain talking. Take us so far.'},
            ]
    
        @property
        def command(self):
            return '{0} "echo \'{1}\'"'.format(self.shell_cmd, self.chorus_line)
    
        @property
        def shell_cmd(self):
            raise RuntimeError('Unknown shell')
    
        @property
        def chorus_line(self):
            return None
    
    
    class MobyUbuntu(MobyBase):
    
        @property
        def image_name(self):
            return 'ubuntu:16.04'
    
        @property
        def shell_cmd(self):
            return '/bin/bash -c'
    
        @property
        def chorus_line(self):
            return 'Lift me up, lift me up'
    
        @property
        def exposed_ports(self):
            return [
                8000,
            ]
    
        @property
        def env(self):
            return super(MobyUbuntu, self).env + [
                {'MY_CUSTOM_ENV': 'VALUE_A'},
            ]
    
    
    class MobyAlpine(MobyBase):
    
        @property
        def image_name(self):
            return 'alpine:3.7'
    
        @property
        def shell_cmd(self):
            return '/bin/sh -c'
    
        @property
        def chorus_line(self):
            return 'Higher now ama'
    
        @property
        def exposed_ports(self):
            return [
                {9000: 9001},
            ]
    
        @property
        def env(self):
            return super(MobyAlpine, self).env + [
                {'MY_CUSTOM_ENV': 'VALUE_B'},
            ]
  2. Now, Try running this from the same dir as the above manofest.py (or point to it using the appropriate argument), to get a feeling of what manof provides for you:

    > manof lift moby_ubuntu
    

    You'll be getting a log output to your stdout, stating the phases of building and running the image, ending with a log line similar to this one:

     07.07.18 22:12:09.918 manof.moby_ubuntu: (I) Command succeeded {"cwd": "None", "err": "", "out": "Lift me up, lift me up"}
    {"command":
       "docker run --rm --net host --label manofest-class=moby_ubuntu --publish
       8000:8000 --env VERSE='Plain talking. Take us so far.' --env
       MY_CUSTOM_ENV=VALUE_A --name moby_ubuntu ubuntu:16.04 /bin/bash -c "echo
       'Lift me up, lift me up'""}
    
  3. Now, try this one, and inspect its output:

    > manof lift moby_alpine
    
  4. Lifting both, consecutively:

    > manof lift moby_ubuntu moby_alpine
    
  5. If you'd like to separately provision (build) and run the images:

    > manof provision moby_ubuntu moby_alpine
    > manof run moby_ubuntu moby_alpine
    

As you can see, Your long and unreadable docker commands will turn into digestible, wieldly manof equivalents. Manof can manage almost all aspects of building/running docker images and volumes in a very friendly and flexible way. All is achieved by programming the behaviour of your project's images and volumes (groups supported) into a configuration-like python module (by convention called manofest.py), and reading this in runtime, the manof CLI will generate the necessary docker commands for the defined targets.

This approach provides a quantum leap in flexibility and re-usability of the different properties' logic definition. For example, maintaining a single manofest.py file per project, can answer the needs of many deployment scenarios - different host os's, environments (dev/integration and production), app versions, users, etc...

How it came to be

"Another docker orchestration tool?!" - a (longer) real-life example

A long time ago, we were using Crane in Iguazio. But shortly after we found ourselves with a plethora of different crane.yml variants for different scenarios - mac/ubuntu/centos, for dev/production and different integration scenarios. Each scenario had some (sometime different) subset of building/running docker options which would need to be tweaked.

Managing different configurations was just too cumbersome and did not allow for an elegant code-like config sharing between the different configurations.

We figured would be great if we could just define it in python code, inspecting machine properties or importing whatever we need as we go along to define a certain volume or port forwarding rule, and being able to decide which docker arguments are "locked in" for specific images (or volumes) and which should really be decided on runtime, for our use cases.
We wanted a smart grouping system, so we can run manof provision group_a and each image in the group will be built with its needed arguments and logic, and the build should consider the relations and dependencies between the images, building them in the right order.
We also would like to have a smart dependency system - image a should be able to be based off of image b, but still inherit some run/build behaviour (like environment variables or ports exposure) from image c, or even just some generic abstract class d. In other words, we want the power of object inheritance.

So, here we are then... introducing manof!

  • Let's look at a very obvious example. I present you this horrible docker command, which is a slightly treated version of a real world use case:

      docker run --detach --net bridge --log-driver none --label
      services=igz8.identity.7 --label igz-project=platform --label
      service_group=standalone --health-cmd=<our shell healthcheck cmd>
      --health-interval=15s --health-retries=3 --health-timeout=5s --publish 3345:2345
      --volume host_path_1:container_path_1
      --volume host_path_2:container_path_2
      ...
      (more volume args)
      ...
      --env IGZ_CLUSTER_NAME=igzc0 --env IGZ_NODE_NAME=igz8 --env
      IGZ_SERVICE_NAME=identity --env IGZ_SERVICE_INSTANCE=7 --env
      IGZ_SOME_IP=11.22.34.55 --env IGZ_SOME_PORT=8001
      IGZ_SOME_ENV_1=value_1 --env IGZ_SOME_ENV_2=value_2
      --env IGZ_SOME_ENV_3=value_3
      ...
      (soooo many more env vars)
      ...
      --name igz8.identity.7 iguazio/identity
    

Instead of the above, you can run this compact and equivalent manof command, given the identity image is properly configured in our (internal, of course) manofest.py file.

    manof run --node-name=igz8 --service-instance=7 -po=1000 identity

Now, that's much more friendly to run now, isn't it?! ☺️ The resulting docker command will be exactly the same.

Manof core principles

  • Declare images, volumes, and groups of the images/volumes using the strength of a full-fledged programming language (python) - including inheritance, conditions, flow control, code re-usability etc... This will give each its own custom behaviour for building/running/removing and so on.

  • Define whichever image specific argument you want these images to have on the manof CLI, because some things should be overridable at run time! (like --service-instance in the example above).

  • Now, you can run common docker commands in a compact manner, which will generate a rich docker command in a smart manner, giving you 100% control over everything with either the manofest.py module, or a combination of the manofest.py and run time arguments to the manof tool.

  • Of course, it is possible to create and maintain as many manofest.py files as you'd like, if you are so inclined, even though, from our experience, we recommend keeping it to 1 per repo/project, for a seamless day-to-day experience. In a multiple manofest files scenario, don't forget to point your manof to the correct manofest.py file when invoking it, using the -mp/--manofest-path cli switch.

  • Similarly and consistently with crane:

    • Building/pulling target images and volumes is referred to by the verb provision
    • Provisioning and then running an image in a single command is referred to by verb lift

Command structure

manof [manof args ...] {operation} [operation-specific-args ...] [target-specific args ...] targets [targets ...]
  • Currently supported operations: {update,provision,run,stop,rm,lift,serialize,push,pull}

  • Commonly used manof args:

    • --manofest-path MANOFEST_FILEPATH - Explicitly provide the full path to the manofest.py file, otherwise a manofest.py will be expected to reside in CWD.

    • --log-severity {verbose,debug,info,warn,warning,error,V,D,I,W,E} - Setting the log severity of both console logging, and file logging (if such is configured). Accepts both full and abbreviation notation. Can be controlled separately via --log-console-severity and --log-file-severity.

    • --parallel NUM - How many docker commands should be launch simultaneously (default is 1).

    • --dry-run - Tells manof to not run any docker command, just log. Can be useful for debugging.

    • We are continuously updating and improving manof. Support for new options is being added constantly. Please type manof --help for a full list of possible arguments and options.

    • Update your manof using manof update which will pull latest code from github.

Pre-requisites

  • python 3.7
  • pip
  • virtualenv
  • docker (well, duh) - Any docker-CE/EE version would do. Older version are partially supported (some flags/properties may not work)

Installation

> git clone [email protected]:v3io/manof.git
> cd manof && ./install

More Examples

Basic Usage

Here we provide some examples of basic manof usage, to show you the ropes of defining and manipulating images, volumes and groups thereof. The manofest code for the below examples, in its entirety, can be found in examples/basic/manofest.py. Here we will focus on specific code snippets to demonstrate key manof building blocks.

  • Using manof to provision and run an image:

    • Manof commands:
    manof lift image_a
    
    • Example manofest.py code. Here we threw in some basic properties for the image:
      import manof
      
      
      class ImageA(manof.Image):
      
          @property
          def image_name(self):
              return 'ubuntu:16.04'
      
          @property
          def detach(self):
              return False
      
          @property
          def labels(self):
              return {
                  'my-project': 'custom_image_1',
              }
          
          @property
          def exposed_ports(self):
              return [
                  8000,
                  {9000: 9001},
              ]
          @property      
          def env(self):
              return [
                'MY_ENV_1',
                {'MY_ENV_2': 'TARGET_VALUE_1'},
              ] 
      
          @property
          def command(self):
              return '/bin/bash -c "echo \'hello manof user\'"'
  • Using manof to provision and run a group of images:

    • Manof commands:
    manof lift my_images
    
    • Example manofest.py code:

      import manof
      
      
      class MyImages(manof.Group):
      
          @property
          def members(self):
              return [
                  'ImageA',
                  'ImageB',
              ]
  • Using manof to create a named volume:

    • Manof commands:
    manof provision --node-name=node3 volume_a
    
    • Example manofest.py code. Here we also define a volume specific argument:

      import datetime
      import pytz
      
      import manof
      
      class VolumeA(manof.NamedVolume):
      
          def register_args(self, parser):
              parser.add_argument('--node-name', type=str, default='node0')
      
          @property
          def prefix(self):
              """
              Here we use the argument --node-name to affect a prefix. This will prefix the actual named-volume name
                  as can be seen using 'docker volume ls'
              """
              return 'proj_a_{0}_'.format(self._args.node_name)
      
          @property
          def labels(self):
              return {
                  'creation_datetime': datetime.datetime.now(pytz.utc).isoformat(),
                  'volume_image': self.name,
              }
  • Using manof to create a group of named volumes:

    • Manof commands:
    manof provision my_volumes
    
    • A basic volume group example in manofest.py:

      import manof
      
      class MyVolumes(manof.Group):
      
          @property
          def members(self):
              return [
                  'VolumeA',
                  'VolumeB',
              ]

Advanced usage

More example manofest files showing off some common use patterns will be added soon to the repository

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