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yes* Chapter 1: Introduction
:PROPERTIES:
:CUSTOM_ID: chapter-1-introduction
:END:
** Abstract
:PROPERTIES:
:CUSTOM_ID: abstract
:END:
This project focuses on creating a framework on running heavy tasks that
a regular computer cannot run easily such as graphically demanding video
games, rendering 3D animations , protein folding simulations. In this
project the major focus will not be on the financial incentive part. A
peer to peer network will be created to help run tasks decentrally,
increasing bandwidth for running tasks. To ensure the tasks in the peer
to peer network do not corrupt the server 0S (Operating System), they
will be executed in a virtual environment in the server.
The main aim of this project was to create a custom peer to peer
network. The user acting as the client has total flexibility on how to
batch the tasks and the user acting as the server has complete
flexibility on tracking the container's usages and killing the
containers at any point of time.
** Motivation
:PROPERTIES:
:CUSTOM_ID: motivation
:END:
Many of the users rely on our PC / Laptop or servers that belong to a
server farm to run heavy tasks and with the demand of high creativity
requires higher computing power. Buying a powerful computer every few
years to run a bunch of heavy tasks which are not executed as frequently
to reap the benefits can be inefficient utilization of hardware. On the
other end, renting servers to run these heavy tasks can be really
useful. Ethically speaking this is leading to monopolisation of
computing power similar to what is happening in the web server area. By
using peer to peer principles it is possible to remove the
monopolisation factor and increase the bandwidth between the client and
server.
* Installation
:PROPERTIES:
:CUSTOM_ID: installation
:END:
Over here we will cover the basic steps to get the server and client
side running.
** Latest release install
:PROPERTIES:
:CUSTOM_ID: latest-release-install
:END:
https://github.com/Akilan1999/p2p-rendering-computation/releases
** Install from Github master branch
:PROPERTIES:
:CUSTOM_ID: install-from-github-master-branch
:END:
*** Install Go lang
:PROPERTIES:
:CUSTOM_ID: install-go-lang
:END:
The entire the implementation of this project is done using Go lang.
Thus, we need go lang to compile to code to a binary file.
[[https://golang.org/doc/install][Instructions to install Go lang]]
*** Install Docker
:PROPERTIES:
:CUSTOM_ID: install-docker
:END:
In this project the choice of virtualization is Docker due to it's wide
usage in the developer community. In the server module we use the Docker
Go API to create and interact with the containers.
[[https://docs.docker.com/get-docker/][Instructions to install docker]]
[[https://docs.nvidia.com/datacenter/cloud-native/container-toolkit/install-guide.html#docker][Instructions
to install docker GPU]]
#+begin_example
// Do ensure that the docker command does not need sudo to run
sudo chmod 666 /var/run/docker.sock
#+end_example
*** Build Project and install project
:PROPERTIES:
:CUSTOM_ID: build-project-and-install-project
:END:
To set up the internal dependencies and build the entire go code into a
single binary
#+begin_example
make install
#+end_example
**** For Windows
:PROPERTIES:
:CUSTOM_ID: for-windows
:END:
To set up P2PRC on Windows, simply run this batch file. *Make sure you
are not in admin mode when running this.*
#+begin_example
.\install.bat
#+end_example
*** Add appropriate paths to =.bashrc=
:PROPERTIES:
:CUSTOM_ID: add-appropriate-paths-to-.bashrc
:END:
#+begin_example
export P2PRC=/<PATH>/p2p-rendering-computation
export PATH=/<PATH>/p2p-rendering-computation:${PATH}
#+end_example
*** Set up configuration file
:PROPERTIES:
:CUSTOM_ID: set-up-configuration-file
:END:
#+begin_example
make configfile
#+end_example
Open the config file =config.json= and add the IPv6 address if you have
one.
*** Test if binary works
:PROPERTIES:
:CUSTOM_ID: test-if-binary-works
:END:
#+begin_example
p2prc --help
#+end_example
**** Output:
:PROPERTIES:
:CUSTOM_ID: output
:END:
#+begin_example
NAME:
p2p-rendering-computation - p2p cli application to create and access VMs in other servers
USAGE:
p2prc [global options] command [command options] [arguments...]
VERSION:
<version no>
COMMANDS:
help, h Shows a list of commands or help for one command
GLOBAL OPTIONS:
--Server, -s Starts server (default: false) [$SERVER]
--UpdateServerList, --us Update List of Server available based on servers iptables (default: false) [$UPDATE_SERVER_LIST]
--ListServers, --ls List servers which can render tasks (default: false) [$LIST_SERVERS]
--AddServer value, --as value Adds server IP address to iptables [$ADD_SERVER]
--ViewImages value, --vi value View images available on the server IP address [$VIEW_IMAGES]
--CreateVM value, --touch value Creates Docker container on the selected server [$CREATE_VM]
--ContainerName value, --cn value Specifying the container run on the server side [$CONTAINER_NAME]
--RemoveVM value, --rm value Stop and Remove Docker container (IP:port) accompanied by container ID via --ID or --id [$REMOVE_VM]
--ID value, --id value Docker Container ID [$ID]
--Ports value, -p value Number of ports to open for the Docker Container [$NUM_PORTS]
--GPU, --gpu Create Docker Containers to access GPU (default: false) [$USE_GPU]
--Specification value, --specs value Specs of the server node [$SPECS]
--SetDefaultConfig, --dc Sets a default configuration file (default: false) [$SET_DEFAULT_CONFIG]
--NetworkInterfaces, --ni Shows the network interface in your computer (default: false) [$NETWORK_INTERFACE]
--ViewPlugins, --vp Shows plugins available to be executed (default: false) [$VIEW_PLUGIN]
--TrackedContainers, --tc View (currently running) containers which have been created from the client side (default: false) [$TRACKED_CONTAINERS]
--ExecutePlugin value, --plugin value Plugin which needs to be executed [$EXECUTE_PLUGIN]
--CreateGroup, --cgroup Creates a new group (default: false) [$CREATE_GROUP]
--Group value, --group value group flag with argument group ID [$GROUP]
--Groups, --groups View all groups (default: false) [$GROUPS]
--RemoveContainerGroup, --rmcgroup Remove specific container in the group (default: false) [$REMOVE_CONTAINER_GROUP]
--RemoveGroup value, --rmgroup value Removes the entire group [$REMOVE_GROUP]
--Generate value, --gen value Generates a new copy of P2PRC which can be modified based on your needs [$GENERATE]
--ModuleName value, --mod value New go project module name [$MODULENAME]
--PullPlugin value, --pp value Pulls plugin from git repos [$PULLPLUGIN]
--RemovePlugin value, --rp value Removes plugin [$REMOVEPLUGIN]
--help, -h show help (default: false)
--version, -v print the version (default: false)
#+end_example
--------------
* Using basic commands
:PROPERTIES:
:CUSTOM_ID: using-basic-commands
:END:
*** Start as a server
:PROPERTIES:
:CUSTOM_ID: start-as-a-server
:END:
Do ensure you have Docker installed for this
#+begin_example
p2prc -s
#+end_example
*** View server Specification
:PROPERTIES:
:CUSTOM_ID: view-server-specification
:END:
#+begin_example
p2prc --specs=<ip address>
#+end_example
*** Run container
:PROPERTIES:
:CUSTOM_ID: run-container
:END:
use the =--gpu= if you know the other machine has a gpu.
#+begin_example
p2prc --touch=<server ip address> -p <number of ports> --gpu
#+end_example
*** Remove container
:PROPERTIES:
:CUSTOM_ID: remove-container
:END:
The docker id is present in the output where you create a container
#+begin_example
p2prc --rm=<server ip address> --id=<docker container id>
#+end_example
*** Adding servers to ip table
:PROPERTIES:
:CUSTOM_ID: adding-servers-to-ip-table
:END:
#+begin_example
p2prc --as=<server ip address you want to add>
#+end_example
*** Update ip table
:PROPERTIES:
:CUSTOM_ID: update-ip-table
:END:
#+begin_example
p2prc --us
#+end_example
*** List Servers
:PROPERTIES:
:CUSTOM_ID: list-servers
:END:
#+begin_example
p2prc --ls
#+end_example
*** View Network interfaces
:PROPERTIES:
:CUSTOM_ID: view-network-interfaces
:END:
#+begin_example
p2prc --ni
#+end_example
*** Viewing Containers created Client side
:PROPERTIES:
:CUSTOM_ID: viewing-containers-created-client-side
:END:
#+begin_example
p2prc --tc
#+end_example
[[file:ClientImplementation.md#tracking-containers][read more on
tracking containers]]
*** Running plugin
:PROPERTIES:
:CUSTOM_ID: running-plugin
:END:
#+begin_example
p2prc --plugin <plugin name> --id <container id or group id>
#+end_example
*** Create group
:PROPERTIES:
:CUSTOM_ID: create-group
:END:
#+begin_example
p2prc --cgroup
#+end_example
*** Add container to group
:PROPERTIES:
:CUSTOM_ID: add-container-to-group
:END:
#+begin_example
p2prc --group <group id> --id <container id>
#+end_example
*** View groups
:PROPERTIES:
:CUSTOM_ID: view-groups
:END:
#+begin_example
p2prc --groups
#+end_example
*** View specific group
:PROPERTIES:
:CUSTOM_ID: view-specific-group
:END:
#+begin_example
p2prc --group <group id>
#+end_example
*** Delete container from group
:PROPERTIES:
:CUSTOM_ID: delete-container-from-group
:END:
#+begin_example
p2prc --rmcgroup --group <group id> --id <container id>
#+end_example
*** Delete entire group
:PROPERTIES:
:CUSTOM_ID: delete-entire-group
:END:
#+begin_example
p2prc --rmgroup <group id>
#+end_example
[[file:ClientImplementation.md#Grouping-Containers][read more on
grouping containers]] ### Extending usecase of P2PRC (Requires a go
compiler to run)
#+begin_example
p2prc --gen <project name> --mod <go module name>
#+end_example
[[file:GenerateImplementation.md][read more about the generate module]]
*** Pulling plugin from a remote repo
:PROPERTIES:
:CUSTOM_ID: pulling-plugin-from-a-remote-repo
:END:
#+begin_example
p2prc --pp <repo link>
#+end_example
*** Deleting plugin from the plugin directory
:PROPERTIES:
:CUSTOM_ID: deleting-plugin-from-the-plugin-directory
:END:
#+begin_example
p2prc --rp <plugin name>
#+end_example
*** Added custom metadata about the current node
:PROPERTIES:
:CUSTOM_ID: added-custom-metadata-about-the-current-node
:END:
#+begin_example
p2prc --amd "custom metadata"
#+end_example
--------------
* Using Plugins
:PROPERTIES:
:CUSTOM_ID: using-plugins
:END:
This feature is still Under Development:
[[file:PluginImplementation.md][Read more on the implementation]]
**** Dependencies
:PROPERTIES:
:CUSTOM_ID: dependencies
:END:
- Ansible:
- Debian/ubuntu: =sudo apt install ansible=
- Others:
[[https://ansible-tips-and-tricks.readthedocs.io/en/latest/ansible/install/][Installation
link]]
**** Run Test Cases
:PROPERTIES:
:CUSTOM_ID: run-test-cases
:END:
- Generate Test Case Ansible file
- =make testcases=
- Enter inside plugin directory and run tests.
#+begin_quote
[!NOTE] That docker needs to installed and needs to run without sudo.
Refer the section [[#install-docker][Install Docker]]. - =cd plugin= -
=go test .=
#+end_quote
* P2P Module Implementation
:PROPERTIES:
:CUSTOM_ID: p2p-module-implementation
:END:
The P2P module (i.e Peer to Peer Module) is responsible for storing the
IP table and interacting with the IP table. In the following
implementation of the P2P module ,the IP table stores information about
servers available in the network. The other functionality the P2P module
takes care of is doing the appropriate speed tests to the servers in the
IP table. This is for informing the users about nodes which are close by
and nodes which have quicker uploads and downloads speeds. The module is
responsible to ensure that there are no duplicate server IPs in the IP
table and to remove all server IPs which are not pingable.
#+caption: UML diagram of P2P module
[[file:images/p2pmoduleArch.png]]
The peer to peer implementation was built from scratch. This is because
other peer to peer libraries were on the implementation of the
Distributed hash table. At the current moment all those heavy features
are not needed because the objective is to search and list all possible
servers available. The limitation being that to be a part of the network
the user has to know at least 1 server. The advantage of building from
scratch makes the module super light and possibility for custom
functions and structs. The sub topics below will mention the
implementations of each functionality in depth.
** IP Table
:PROPERTIES:
:CUSTOM_ID: ip-table
:END:
The ip table file is a json as the format with a list of servers ip
addresses, latencies, downloads and uploads speeds. The functions
implemented include read file, write file and remove duplicate IP
addresses. The remove duplicate IP address function exists because
sometimes servers IP tables can have the same ip addresses as what the
client has. The path of the IP table json file is received from the
configuration module.
#+begin_src json
{
"ip_address": [
{
"ipv4": "<ipv4 address>",
"latency": "<latency>",
"download": "<download>",
"upload": "<upload>"
"port no": "<server port no>",
}
]
}
#+end_src
*** Latency
:PROPERTIES:
:CUSTOM_ID: latency
:END:
The latency is measured in milliseconds. The route /server_info is
called from the server and time it takes to provide a json response is
recorded.
** NAT Traversal
:PROPERTIES:
:CUSTOM_ID: nat-traversal
:END:
P2PRC currently supports TURN for NAT traversal.
** TURN
:PROPERTIES:
:CUSTOM_ID: turn
:END:
The current TURN implementation used is FRP. The TURN server is also
required when a P2PRC node is acting as a Server. The TURN server is
determined based on the Node with the least amount of latency based on
the Nodes available on the IPTable. Once a TURN server is determined
there are 2 actions performed. The first one is =/FRPPort= to the TURN
server to receive a port which is used to generate the external port
from the TURN server. The flow below describes the workflow.
*** Client mode
:PROPERTIES:
:CUSTOM_ID: client-mode
:END:
- Call =/FRPPort=
#+begin_example
http://<turn server ip>:<server port no>/FRPport
#+end_example
- Call the TURN server in the following manner. The following is a
sample code snippet below.
#+begin_src go
import (
"github.com/Akilan1999/p2p-rendering-computation/p2p/frp"
)
func main() {
serverPort, err := frp.GetFRPServerPort("http://" + <lowestLatencyIpAddress.Ipv4> + ":" + lowestLatencyIpAddress.ServerPort)
if err != nil {
return nil, err
}
// Create 1 second delay to allow FRP server to start
time.Sleep(1 * time.Second)
// Starts FRP as a client with
proxyPort, err := frp.StartFRPClientForServer(<lowestLatencyIpAddress.Ipv4>, serverPort, <the port you want to expose externally>)
if err != nil {
return nil, err
}
}
#+end_src
* Language Bindings
:PROPERTIES:
:CUSTOM_ID: language-bindings
:END:
[[https://en.wikipedia.org/wiki/Language_binding][Language bindings]]
refers to wrappers to bridge 2 programming languages. This is used in
P2PRC to extend calling P2PRC functions in other programming languages.
Currently this is done by generating =.so= and =.h= from the Go
compiler.
** How to build shared object files
:PROPERTIES:
:CUSTOM_ID: how-to-build-shared-object-files
:END:
**** The easier way
:PROPERTIES:
:CUSTOM_ID: the-easier-way
:END:
#+begin_src sh
# Run
make sharedObjects
#+end_src
**** Or the direct way
:PROPERTIES:
:CUSTOM_ID: or-the-direct-way
:END:
#+begin_src sh
# Run
cd Bindings && go build -buildmode=c-shared -o p2prc.so
#+end_src
**** If successfully built:
:PROPERTIES:
:CUSTOM_ID: if-successfully-built
:END:
#+begin_src sh
# Enter into the Bindings directory
cd Bindings
# List files
ls
# Find files
p2prc.h p2prc.so
#+end_src
** Workings under the hood
:PROPERTIES:
:CUSTOM_ID: workings-under-the-hood
:END:
Below are a sample set of commands to open the bindings implementation.
#+begin_example
# run
cd Bindings/
# list files
ls
# search for file
Client.go
#+end_example
*** In Client go
:PROPERTIES:
:CUSTOM_ID: in-client-go
:END:
There a few things to notice which are different from your standard Go
programs:
**** 1. We import "C" which means [[https://pkg.go.dev/cmd/cgo][Cgo]] is required.
:PROPERTIES:
:CUSTOM_ID: we-import-c-which-means-cgo-is-required.
:END:
#+begin_src go
import "C"
#+end_src
**** 2. All functions which are required to be called from other programming languages have comment such as.
:PROPERTIES:
:CUSTOM_ID: all-functions-which-are-required-to-be-called-from-other-programming-languages-have-comment-such-as.
:END:
#+begin_src go
//export <function name>
// ------------ Example ----------------
// The function below allows to externally
// to call the P2PRC function to start containers
// in a specific node in the know list of nodes
// in the p2p network.
// Note: the comment "//export StartContainer".
//export StartContainer
func StartContainer(IP string) (output *C.char) {
container, err := client.StartContainer(IP, 0, false, "", "")
if err != nil {
return C.CString(err.Error())
}
return ConvertStructToJSONString(container)
}
#+end_src
**** 3. While looking through the file (If 2 files are compared it is pretty trivial to notice a common structure).
:PROPERTIES:
:CUSTOM_ID: while-looking-through-the-file-if-2-files-are-compared-it-is-pretty-trivial-to-notice-a-common-structure.
:END:
#+begin_src go
// --------- Example ------------
//export StartContainer
func StartContainer(IP string) (output *C.char) {
container, err := client.StartContainer(IP, 0, false, "", "")
if err != nil {
return C.CString(err.Error())
}
return ConvertStructToJSONString(container)
}
//export ViewPlugin
func ViewPlugin() (output *C.char) {
plugins, err := plugin.DetectPlugins()
if err != nil {
return C.CString(err.Error())
}
return ConvertStructToJSONString(plugins)
}
#+end_src
**** It is easy to notice that:
:PROPERTIES:
:CUSTOM_ID: it-is-easy-to-notice-that
:END:
- =ConvertStructToJSONString(<go object>)=: This is a helper function
that convert a go object to JSON string initially and converts it to
=CString=.
- =(output *C.char)=: This is the return type for most of the functions.
**** A Pseudo code to refer to the common function implementation shape could be represented as:
:PROPERTIES:
:CUSTOM_ID: a-pseudo-code-to-refer-to-the-common-function-implementation-shape-could-be-represented-as
:END:
#+begin_example
func <Function name> (output *C.char) {
<response>,<error> := <P2PRC function name>(<parameters if needed>)
if <error> != nil {
return C.CString(<error>.Error())
}
return ConvertStructToJSONString(<response>)
}
#+end_example
** Current languages supported
:PROPERTIES:
:CUSTOM_ID: current-languages-supported
:END:
- Python
*** Build sample python program
:PROPERTIES:
:CUSTOM_ID: build-sample-python-program
:END:
The easier way
#+begin_src sh
# Run
make python
# Expected ouput
Output is in the Directory Bindings/python/export/
# Run
cd Bindings/python/export/
# list files
ls
# Expected output
SharedObjects/ p2prc.py
#+end_src
Above shows a generated folder which consists of a folder called
"SharedObjects/" which consists of =p2prc.so= and =p2prc.h= files.
=p2prc.py= refers to a sample python script calling P2PRC go functions.
To start an any project to extend P2PRC with python, This generated
folder can copied and created as a new git repo for P2PRC extensions
scripted or used a reference point as proof of concept that P2PRC can be
called from other programming languages.
* Config Implementation
:PROPERTIES:
:CUSTOM_ID: config-implementation
:END:
The configuration module is responsible to store basic information of
absolute paths of files being called in the Go code. In a full-fledged
Cli the configuration file can be found in the directory /etc/ and from
there points to location such as where the IP table file is located. In
the future implementation the config file will have information such as
number of hops and other parameters to tweak and to improve the
effectiveness of the peer to peer network. The configuration module was
implemented using the library Viper. The Viper library automates
features such as searching in default paths to find out if the
configuration file is present. If the configuration file is not present
in the default paths then it auto generates the configuration file. The
configurations file can be in any format. In this project the
configuration file was generated using JSON format.
#+begin_src json
{
"MachineName": "pc-74-120.customer.ask4.lan",
"IPTable": "/Users/akilan/Documents/p2p-rendering-computation/p2p/iptable/ip_table.json",
"DockerContainers": "/Users/akilan/Documents/p2p-rendering-computation/server/docker/containers/",
"DefaultDockerFile": "/Users/akilan/Documents/p2p-rendering-computation/server/docker/containers/docker-ubuntu-sshd/",
"SpeedTestFile": "/Users/akilan/Documents/p2p-rendering-computation/p2p/50.bin",
"IPV6Address": "",
"PluginPath": "/Users/akilan/Documents/p2p-rendering-computation/plugin/deploy",
"TrackContainersPath": "/Users/akilan/Documents/p2p-rendering-computation/client/trackcontainers/trackcontainers.json",
"ServerPort": "8088",
"GroupTrackContainersPath": "/Users/akilan/Documents/p2p-rendering-computation/client/trackcontainers/grouptrackcontainers.json",
"FRPServerPort": "True",
"BehindNAT": "True",
"CustomConfig": null
}
#+end_src
* Abstractions
:PROPERTIES:
:CUSTOM_ID: abstractions
:END:
The Abstractions package consists of black-boxed functions for P2PRC.
** Functions
:PROPERTIES:
:CUSTOM_ID: functions
:END:
- =Init(<Project name>)=: Initializes P2PRC with all the needed
configurations.
- =Start()=: Starts p2prc as a server and makes it possible to extend by
adding other routes and functionality to P2PRC.
- =MapPort(<port no>)=: On the local machine the port you want to export
to world.
- =StartContainer(<ip address>)=: The machine on the p2p network where
you want to spin up a docker container.
- =RemoveContainer(<ip address>,<container id>)=: Terminate container
based on the IP address and container name.
- =GetSpecs(<ip address>)=: Get specs of a machine on the network based
on the IP address.
- =ViewIPTable()=: View the IP table which about nodes in the network.
- =UpdateIPTable()=: Force update IP table to learn about new nodes
faster.
* NAT Traversal
:PROPERTIES:
:CUSTOM_ID: nat-traversal
:END:
P2PRC currently supports TURN for NAT traversal.
** TURN
:PROPERTIES:
:CUSTOM_ID: turn
:END:
The current TURN implementation used is FRP. The TURN server is also
required when a P2PRC node is acting as a Server. The TURN server is
determined based on the Node with the least amount of latency based on
the Nodes available on the IPTable. Once a TURN server is determined
there are 2 actions performed. The first one is =/FRPPort= to the TURN
server to receive a port which is used to generate the external port
from the TURN server. The flow below describes the workflow.
*** Client mode
:PROPERTIES:
:CUSTOM_ID: client-mode
:END:
- Call =/FRPPort=
#+begin_example
http://<turn server ip>:<server port no>/FRPport
#+end_example
- Call the TURN server in the following manner. The following is a
sample code snippet below.
#+begin_src go
import (
"github.com/Akilan1999/p2p-rendering-computation/p2p/frp"
)
func main() {
serverPort, err := frp.GetFRPServerPort("http://" + <lowestLatencyIpAddress.Ipv4> + ":" + lowestLatencyIpAddress.ServerPort)
if err != nil {
return nil, err
}
// Create 1 second delay to allow FRP server to start
time.Sleep(1 * time.Second)
// Starts FRP as a client with
proxyPort, err := frp.StartFRPClientForServer(<lowestLatencyIpAddress.Ipv4>, serverPort, <the port you want to expose externally>)
if err != nil {
return nil, err
}
}
#+end_src