Which GCP service(s) is the best for my use case? - docker

I have an image in Artifact Registry that does a unit of work:
it expects input files inside a certain directory (let's call it main_input)
runs them, does some sequences of computation, and outputs results into an output folder in Google Storage
The run time of each does not exceed 30 minutes, but I have thousands of such runs to perform.
Inside a single VM, I can create various containers from this image by mounting the main_input directory inside the container to the correct ones on the host, and run.
However, I wonder if Cloud Run is a more scalable solution for this? or shall I look at other services/strategies?

Managing thousands of runs is not an easy task, you can use a scheduler like airflow or argo worfkflows to run the tasks and restart them if needed.
For the containers environment, I propose Kubernetes (GKE) over Cloud Run, for some reason:
you have more permissions than Cloud Run
to be agnostic from GCP (your code can work on other platforms like AWS)
better management for apps configurations and secrets, and supported with all the CI/CD tools
less expensive: you can create scalable preemptible node pools to reduce the cost and add a lot of resources when needed
you can use the same cluster to run other applications for your company
you can use open source tools for log collections, monitoring, HTTP reverse proxy, ...

Related

Fixing security vulnerabilities in Cloud Function container

The containers that result from the standard Cloud Function build/deploy process sometimes contain security vulnerabilities, and I'm not sure how to resolve these since Cloud Functions don't (as far as I know) offer much control of the execution environment by design. What's the best practice for resolving security vulnerabilities in Google Cloud Functions?
If I can figure out how to extend the build process I think I'll be in good shape, but am not sure how to do that for Cloud Functions in particular.
Situation:
I'm building my functions using the standard gcloud functions deploy command (docs). The deployment is successful and I can successfully run the function - it creates a container in the Container Registry (process overview -- sounds like its built off of the base Ubuntu Docker image).
I'm using Google's container vulnerability scanning, and it detects security issues in these containers, presumably because some of the packages in the Ubuntu base image have released security updates. In other container environments, its straightforward enough to update these packages via apt or similar, but I'm not aware of how to perform the equivalent in a Cloud Function environment since you don't really customize the environment (Dockerfile, etc).
Short answer: you can't. Cloud Functions seeks to be as easy to use as possible by being opinionated about how to build the container. You just provide the code.
If you want control over a serverless container, you should switch to Cloud Run, which lets you deploy the full container. It also gives you a greater degree of control over the amount of concurrent requests it can handle, potentially saving you money by utilizing the virtual machine more fully.

Why multi-container docker apps are built?

Can somebody explain it with some examples? Why multi-container docker apps are built? while you can contain your app in a single docker container.
When you make a multi-container app you have to do networking. Is not it easy to run a single image of a single container rather than two images of two containers?
There are several good reasons for this:
It's easier to reuse prebuilt images. If you need MySQL, or Redis, or an Nginx reverse proxy, these all exist as standard images on Docker Hub, and you can just include them in a multi-container Docker Compose setup. If you tried to put them into a single image, you'd have to install and configure them yourself.
The Docker tooling is built for single-purpose containers. If you want the logs of a multi-process container, docker logs will generally print out the supervisord logs, which aren't what you want; if you want to restart one of those containers, the docker stop; docker rm; docker run sequence will delete the whole thing. Instead with a multi-process container you need to use debugging tools like docker exec to do anything, which is harder to manage.
You can upgrade one part without affecting the rest. Upgrading the code in a container usually involves building a new image, stopping and deleting the old container, and running a new container from the new image. The "deleting the old container" part is important, and routine; if you need to delete your database to upgrade your application, you risk losing data.
You can scale one part without affecting the rest. More applicable in a cluster environment like Docker Swarm or Kubernetes. If your application is overloaded (especially in production) you'd like to run multiple copies of it, but it's hard to run multiple copies of a standard relational database. That essentially requires you to run these separately, so you can run one proxy, five application servers, and one database.
Setting up a multi-container application shouldn't be especially difficult; the easiest way is to use Docker Compose, which will deal with things like creating a network for you.
For the sake of simplification, I would say you can run only one application with a public entry point (like API) in a single container. Actually, this approach is recommended by Docker official documentation.
Microservices
Because of this single constraint, you cannot run microservices that require their own entry points in a single docker container.
It could be more a discussion on the advantages of Monolith application vs Microservices.
Database
Even if you decide to run the Monolith application only, still you need to connect some database there. As you noticed, Docker has an additional network-configuration layer, so if you want to run Database and application locally, the easiest way is to use docker-compose to run both images (Database and your Application) inside one, automatically configured network.
# Application definition
application: <your app definition>
# Database definition
database:
image: mysql:5.7
In my example, you can just connect to your DB via https://database:<port> URL from your main app (plus credentials eventually) and it will work.
Scalability
However, why we should split images for the database from the application? One word - scalability. For development purposes, you want to have your local DB, maybe with docker because it is handy. For production purposes, you will put the application image to run somewhere (Kubernetes, Docker-Swarm, Azure App Services, etc.). To handle multiple requests at the same time, you want to run multiple instances of your application. However what about the database? You cannot connect to the internal instance of DB hosted in the same container, because other instances of your app in other containers will have a completely different set of data (without synchronization).
Most often you are electing to use a separate Database server - no matter if running it on the container or fully manged databases (like Azure CosmosDB or Mongo Atlas), but with your own configuration, scaling, and synchronization dedicated for DB only. Your app just needs to worry about the proper URL to that. Most cloud providers are exposing such services out of the box, so you are not worrying about the configuration by yourself.
Easy to change
Last but not least argument is about changing the initial setup overtime. You might change the database provider, or upgrade the version of the image in the future (such things are required from time to time). When you separate images, you can modify one without touching others. It is decreasing the cost of maintenance significantly.
Also, you can add additional services very easy - different logging aggregator? No Problem, additional microservice running out-of-the-box? Easy.

Can you run a sandbox container within a Cloud Run container?

Let's say I would to let the user upload some python or bash script, execute it in the cloud run and get the result back. To do this I would create a Cloud Run service with a service account that has no permissions to access project resources. I would as well run the script within the nested container so the user cannot interfere with the server code and manipulate consecutive requests from other users.
How would I make gvisor runsc or some other sandbox runtime available within the container running on Cloud Run?
I found some resources mentioning using the privileged flag on the original container, but that is not possible with Cloud Run. Also, I cannot find any information on how to run rootless containers with runsc. Let me know if I am on the right track or if this is even possible with cloud run or should I use another service?
Thank you.
Currently Cloud Run (fully managed) itself runs on a gVisor sandbox itself, so its support for low-level Linux APIs for creating further container environments using cgroups or Linux namespace APIs are probably not going to be possible.
However, since gVisor is technically an user-space sandboxing technology (though I'm not sure what level of privileges it requires), you might be able to run a gVisor sandbox inside gVisor, though I would not hold my hopes high as it's probably not designed for that. I'm guessing that gVisor sandbox does not provide ptrace capabilities for nested sandboxes to work, though you can probably ask this on gVisor’s own GitHub repository.
For a use case like this, I recommend checking out Cloud Run for Anthos on GKE, it's a similar developer experience to Cloud Run, but runs your applications on GKE nodes (which are GCE VMs) which have full Linux system call suite available to them. Since Kubernetes podspec is available there, you can actually create privileged containers, and run VMs inside them etc.
Usually containers themselves are supposed to be the sandbox, so attempting to create further sandboxes (like you asked earlier) is going to be a lot of platform-dependent work, even if you can get it running somehow.

Automated deployment of a dockerized application on a single machine

I have a web application consisting of a few services - web, DB and a job queue/worker. I host everything on a single Google VM and my deployment process is very simple and naive:
I manually install all services like the database on the VM
a bash script scheduled by crontab polls a remote git repository for changes every N minutes
if there were changes, it would simply restart all services using supervisord (job queue, web, etc)
Now, I am starting a new web project where I enjoy using docker-compose for local development. However, I seem to suck in analysis paralysis deciding between available options for production deployment - I looked at Kubernetes, Swarm, docker-compose, container registries and etc.
I am looking for a recipe that will keep me productive with a single machine deployment. Ideally, I should be able to scale it to multiple machines when the time comes, but simplicity and staying frugal (one machine) is more important for now. I want to consider 2 options - when the VM already exists and when a new bare VM can be allocated specifically for this application.
I wonder if docker-compose is a reasonable choice for a simple web application. Do people use it in production and if so, how does the entire process look like from bare VM to rolling out an updated application? Do people use Kubernetes or Swarm for a simple single-machine deployment or is it an overkill?
I wonder if docker-compose is a reasonable choice for a simple web application.
It can be, sure, if the development time is best spent focused on the web application and less on the non-web stuff such as the job queue and database. The other asterisk is whether the development environment works ok with hot-reloads or port-forwarding and that kind of jazz. I say it's a reasonable choice because 99% of the work of creating an application suitable for use in a clustered environment is the work of containerizing the application. So if the app already works under docker-compose, then it is with high likelihood that you can take the docker image that is constructed on behalf of docker-compose and roll it out to the cluster.
Do people use it in production
I hope not; I am sure there are people who use docker-compose to run in production, just like there are people that use Windows batch files to deploy, but don't be that person.
Do people use Kubernetes or Swarm for a simple single-machine deployment or is it an overkill?
Similarly, don't be a person that deploys the entire application on a single virtual machine or be mentally prepared for one failure to wipe out everything that you value. That's part of what clustering technologies are designed to protect against: one mistake taking down the entirety of the application, web, queuing, and persistence all in one fell swoop.
Now whether deploying kubernetes for your situation is "overkill" or not depends on whether you get benefit from the other things that kubernetes brings aside from mere scaling. We get benefit from developer empowerment, log aggregation, CPU and resource limits, the ability to take down one Node without introducing any drama, secrets management, configuration management, using a small number of Nodes for a large number of hosted applications (unlike creating a single virtual machine per deployed application because the deployments have no discipline over the placement of config file or ports or whatever). I can keep going, because kubernetes is truly magical; but, as many people will point out, it is not zero human cost to successfully run a cluster.
Many companies I have worked with are shifting their entire production environment towards Kubernetes. That makes sense because all cloud providers are currently pushing Kubernetes and we can be quite positive about Kubernetes being the future of cloud-based deployment. If your application is meant to run in any private or public cloud, I would personally choose Kubernetes as operating platform for it. If you plan to add additional services, you will be easily able to connect them and scale your infrastructure with a growing number of requests to your application. However, if you already know that you do not expect to scale your application, it may be over-powered to use a Kubernetes cluster to run it although Google Cloud etc. make it fairly easy to setup such a cluster with a few clicks.
Regarding an automated development workflow for Kubernetes, you can take a look at my answer to this question: How to best utilize Kubernetes/minikube DNS for local development

Docker, what is it and what is the purpose

I've heard about Docker some days ago and wanted to go across.
But in fact, I don't know what is the purpose of this "container"?
What is a container?
Can it replace a virtual machine dedicated to development?
What is the purpose, in simple words, of using Docker in companies? The main advantage?
VM: Using virtual machine (VM) software, for example, Ubuntu can be installed inside a Windows. And they would both run at the same time. It is like building a PC, with its core components like CPU, RAM, Disks, Network Cards etc, within an operating system and assemble them to work as if it was a real PC. This way, the virtual PC becomes a "guest" inside an actual PC which with its operating system, which is called a host.
Container: It's same as above but instead of using an entire operating system, it cut down the "unnecessary" components of the virtual OS to create a minimal version of it. This lead to the creation of LXC (Linux Containers). It therefore should be faster and more efficient than VMs.
Docker: A docker container, unlike a virtual machine and container, does not require or include a separate operating system. Instead, it relies on the Linux kernel's functionality and uses resource isolation.
Purpose of Docker: Its primary focus is to automate the deployment of applications inside software containers and the automation of operating system level virtualization on Linux. It's more lightweight than standard Containers and boots up in seconds.
(Notice that there's no Guest OS required in case of Docker)
[ Note, this answer focuses on Linux containers and may not fully apply to other operating systems. ]
What is a container ?
It's an App: A container is a way to run applications that are isolated from each other. Rather than virtualizing the hardware to run multiple operating systems, containers rely on virtualizing the operating system to run multiple applications. This means you can run more containers on the same hardware than VMs because you only have one copy of the OS running, and you do not need to preallocate the memory and CPU cores for each instance of your app. Just like any other app, when a container needs the CPU or Memory, it allocates them, and then frees them up when done, allowing other apps to use those same limited resources later.
They leverage kernel namespaces: Each container by default will receive an environment where the following are namespaced:
Mount: filesystems, / in the container will be different from / on the host.
PID: process id's, pid 1 in the container is your launched application, this pid will be different when viewed from the host.
Network: containers run with their own loopback interface (127.0.0.1) and a private IP by default. Docker uses technologies like Linux bridge networks to connect multiple containers together in their own private lan.
IPC: interprocess communication
UTS: this includes the hostname
User: you can optionally shift all the user id's to be offset from that of the host
Each of these namespaces also prevent a container from seeing things like the filesystem or processes on the host, or in other containers, unless you explicitly remove that isolation.
And other linux security tools: Containers also utilize other security features like SELinux, AppArmor, Capabilities, and Seccomp to limit users inside the container, including the root user, from being able to escape the container or negatively impact the host.
Package your apps with their dependencies for portability: Packaging an application into a container involves assembling not only the application itself, but all dependencies needed to run that application, into a portable image. This image is the base filesystem used to create a container. Because we are only isolating the application, this filesystem does not include the kernel and other OS utilities needed to virtualize an entire operating system. Therefore, an image for a container should be significantly smaller than an image for an equivalent virtual machine, making it faster to deploy to nodes across the network. As a result, containers have become a popular option for deploying applications into the cloud and remote data centers.
Can it replace a virtual machine dedicated to development ?
It depends: If your development environment is running Linux, and you either do not need access to hardware devices, or it is acceptable to have direct access to the physical hardware, then you'll find a migration to a Linux container fairly straight forward. The ideal target for a docker container are applications like web based API's (e.g. a REST app), which you access via the network.
What is the purpose, in simple words, of using Docker in companies ? The main advantage ?
Dev or Ops: Docker is typically brought into an environment in one of two paths. Developers looking for a way to more rapidly develop and locally test their application, and operations looking to run more workload on less hardware than would be possible with virtual machines.
Or Devops: One of the ideal targets is to leverage Docker immediately from the CI/CD deployment tool, compiling the application and immediately building an image that is deployed to development, CI, prod, etc. Containers often reduce the time to move the application from the code check-in until it's available for testing, making developers more efficient. And when designed properly, the same image that was tested and approved by the developers and CI tools can be deployed in production. Since that image includes all the application dependencies, the risk of something breaking in production that worked in development are significantly reduced.
Scalability: One last key benefit of containers that I'll mention is that they are designed for horizontal scalability in mind. When you have stateless apps under heavy load, containers are much easier and faster to scale out due to their smaller image size and reduced overhead. For this reason you see containers being used by many of the larger web based companies, like Google and Netflix.
Same questions were hitting my head some days ago and what i found after getting into it, let's understand in very simple words.
Why one would think about docker and containers when everything seems fine with current process of application architecture and development !!
Let's take an example that we are developing an application using nodeJs , MongoDB, Redis, RabbitMQ etc services [you can think of any other services].
Now we face these following things as problems in application development and shipping process if we forget about existence of docker or other alternatives of containerizing applications.
Compatibility of services(nodeJs, mongoDB, Redis, RabbitMQ etc.) with OS(even after finding compatible versions with OS, if something unexpected happens related to versions then we need to relook the compatibility again and fix that).
If two system components requires a library/dependency with different versions in application in OS(That need a relook every time in case of an unexpected behaviour of application due to library and dependency version issue).
Most importantly , If new person joins the team, we find it very difficult to setup the new environment, person has to follow large set of instructions and run hundreds of commands to finally setup the environment And it takes time and effort.
People have to make sure that they are using right version of OS and check compatibilities of services with OS.And each developer has to follow this each time while setting up.
We also have different environment like dev, test and production.If One developer is comfortable using one OS and other is comfortable with other OS And in this case, we can't guarantee that our application will behave in same way in these two different situations.
All of these make our life difficult in process of developing , testing and shipping the applications.
So we need something which handles compatibility issue and allows us to make changes and modifications in any system component without affecting other components.
Now we think about docker because it's purpose is to
containerise the applications and automate the deployment of applications and ship them very easily.
How docker solves above issues-
We can run each service component(nodeJs, MongoDB, Redis, RabbitMQ) in different containers with its own dependencies and libraries in the same OS but with different environments.
We have to just run docker configuration once then all our team developers can get started with simple docker run command, we have saved lot of time and efforts here:).
So containers are isolated environments with all dependencies and
libraries bundled together with their own process and networking
interfaces and mounts.
All containers use the same OS resources
therefore they take less time to boot up and utilise the CPU
efficiently with less hardware costs.
I hope this would be helpful.
Why use docker:
Docker makes it really easy to install and running software without worrying about setup or dependencies. Docker is really made it easy and really straight forward for you to install and run software on any given computer not just your computer but on web servers as well or any cloud based computing platform. For example when I went to install redis in my computer by using bellow command
wget http://download.redis.io/redis-stable.tar.gz
I got error,
Now I could definitely go and troubleshoot this install that program and then try installing redis again, and I kind of get into endless cycle of trying to do all bellow troubleshooting as you I am installing and running software.
Now let me show you how easy it is to run read as if you are making use of Docker instead. just run the command docker run -it redis, this command will install docker without any error.
What docker is:
To understand what is docker you have to know about docker Ecosystem.
Docker client, server, Machine, Images, Hub, Composes are all projects tools pieces of software that come together to form a platform where ecosystem around creating and running something called containers, now if you run the command docker run redis something called docker CLI reached out to something called the Docker Hub and it downloaded a single file called an image.
An image is a single file containing all the dependencies and all the configuration required to run a very specific program, for example redis this which is what the image that you just downloaded was supposed to run.
This is a single file that gets stored on your hard drive and at some point time you can use this image to create something called a container.
A container is an instance of an image and you can kind of think it as being like a running program with it's own isolated set of hardware resources so it kind of has its own little set or its own little space of memory has its own little space of networking technology and its own little space of hard drive space as well.
Now lets examine when you give bellow command:
sudo docker run hello-world
Above command will starts up the docker client or docker CLI, Docker CLI is in charge of taking commands from you kind of doing a little bit of processing on them and then communicating the commands over to something called the docker server, and docker server is in charge of the heavy lifting when we ran the command Docker run hello-world,
That meant that we wanted to start up a new container using the image with the name of hello world, the hello world image has a tiny tittle program inside of it whose sole purpose or sole job is to print out the message that you see in the terminal.
Now when we ran that command and it was issued over to the docker server a series of actions very quickly occurred in background. The Docker server saw that we were trying to start up a new container using an image called hello world.
The first thing that the docker server did was check to see if it already had a local copy like a copy on your personal machine of the hello world image or that hello world file.So the docker server looked into something called the image cache.
Now because you and I just installed Docker on our personal computers that image cache is currently empty, We have no images that have already been downloaded before.
So because the image cache was empty the docker server decided to reach out to a free service called Docker hub. The Docker Hub is a repository of free public images that you can freely download and run on your personal computer. So Docker server reached out to Docker Hub and and downloaded the hello world file and stored it on your computer in the image-cache, where it can now be re-run at some point the future very quickly without having to re-downloading it from the docker hub.
After that the docker server will use it to create an instance of a container, and we know that a container is an instance of an image, its sole purpose is to run one very specific program. So the docker server then essentially took that image file from image cache and loaded it up into memory to created a container out of it and then ran a single program inside of it. And that single programs purpose was to print out the message that you see.
What a container is:
A container is a process or a set of processes that have a grouping of resource specifically assigned to it, in the bellow is a diagram that anytime that we think about a container we've got some running process that sends a system call to a kernel, the kernel is going to look at that incoming system call and direct it to a very specific portion of the hard drive, the RAM, CPU or what ever else it might need and a portion of each of these resources is made available to that singular process.
Let me try to provide as simple answers as possible:
But in fact, I don't know what is the purpose of this "container"?
What is a container?
Simply put: a package containing software. More specifically, an application and all its dependencies bundled together. A regular, non-dockerised application environment is hooked directly to the OS, whereas a Docker container is an OS abstraction layer.
And a container differs from an image in that a container is a runtime instance of an image - similar to how objects are runtime instances of classes in case you're familiar with OOP.
Can it replace a virtual machine dedicated to development?
Both VMs and Docker containers are virtualisation techniques, in that they provide abstraction on top of system infrastructure.
A VM runs a full “guest” operating system with virtual access to host resources through a hypervisor. This means that the VM often provides the environment with more resources than it actually needs In general, VMs provide an environment with more resources than most applications need. Therefore, containers are a lighter-weight technique. The two solve different problems.
What is the purpose, in simple words, of using Docker in companies?
The main advantage?
Containerisation goes hand-in-hand with microservices. The smaller services that make up the larger application are often tested and run in Docker containers. This makes continuous testing easier.
Also, because Docker containers are read-only they enforce a key DevOps principle: production services should remain unaltered
Some general benefits of using them:
Great isolation of services
Great manageability as containers contain everything the app needs
Encapsulation of implementation technology (in the containers)
Efficient resource utilisation (due to light-weight os virtualisation) in comparison to VMs
Fast deployment
If you don't have any prior experience with Docker this answer will cover the basics needed as a developer.
Docker has become a standard tool for DevOps as it is an effective application to improve operational efficiencies. When you look at why Docker was created and why it is very popular, it is mostly for its ability to reduce the amount of time it takes to set up the environments where applications run and are developed.
Just look at how long it takes to set up an environment where you have React as the frontend, a node and express API for backend, which also needs Mongo. And that's just to start. Then when your team grows and you have multiple developers working on the same front and backend and therefore they need to set up the same resources in their local environment for testing purposes, how can you guarantee every developer will run the same environment resources, let alone the same versions? All of these scenarios play well into Docker's strengths where it's value comes from setting containers with specific settings, environments and even versions of resources. Simply type a few commands to have Docker set up, install, and run your resources automatically.
Let's briefly go over the main components. A container is basically where your application or specific resource is located. For example, you could have the Mongo database in one container, then the frontend React application, and finally your node express server in the third container.
Then you have an image, which is from what the container is built. The images contains all the information that a container needs to build a container exactly the same way across any systems. It's like a recipe.
Then you have volumes, which holds the data of your containers. So if your applications are on containers, which are static and unchanging, the data that change is on the volumes.
And finally, the pieces that allow all these items to speak is networking. Yes, that sounds simple, but understand that each container in Docker have no idea of the existence of each container. They're fully isolated. So unless we set up networking in Docker, they won't have any idea how to connect to one and another.
There are really good answers above which I found really helpful.
Below I had drafted a simpler answer:
Reasons to dockerize my web application?
a. One OS for multiple applications ( Resources are shared )
b. Resource manangement ( CPU / RAM) is efficient.
c. Serverless Implementation made easier -Yes, AWS ECS with Fargate, But serverless can be achieved with Lamdba
d. Infra As Code - Agree, but IaC can be achieved via Terraforms
e. "It works in my machine" Issue
Still, below questions are open when choosing dockerization
A simple spring boot application
a. Jar file with size ~50MB
b. creates a Docker Image ~500MB
c. Cant I simply choose a small ec2 instance for my microservices.
Financial Benefits (reducing the individual instance cost) ?
a. No need to pay for individual OS subscription
b. Is there any monetary benefit like the below implementation?
c. let say select t3.2xlarge ( 8 core / 32 GB) and start 4-5 docker images ?

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