程序代写代做代考 algorithm graph go dns 2019 CSEE 4119: Computer Networks

2019 CSEE 4119: Computer Networks
Project 1: Video CDN
Preliminary Stage Due: October 14, 2020, at 11pm Updates:
2020/10/06: none yet
1. Overview 2
1.1 In the Real World 2 1.2 Your System 2 1.3 Groups and collaboration policy 3
2. Preliminary stage 4
2.1 Get your connections right. 4 2.2 Forwarding protocol. 5 2.3 Running the proxy 6 2.4 Test it out! 6 2.5 Final result 7 2.6 What to Submit for preliminary stage 7 2.7 Where to Submit 8
3. Final stage: Video Bitrate Adaptation 8
4 Development Environment 8
4.1 Virtual Box 8 4.5 Programming Language and Packages 9 [4.6] (Optional) CUIT Workstations 10
7 Grading 10 Academic integrity: Zero tolerance on plagiarism 11

1. Overview
In this project, you will explore aspects of how streaming video works, as well as socket programming and HTTP. In particular, you will implement adaptive bitrate selection. ​The programming languages and packages are specified in the development environment section​.
1.1 In the Real World
Figure 1 depicts (at a high level) what this system looks like in the real world. Clients trying to stream a video first issue a DNS query to resolve the service’s domain name to an IP address for one of the content servers operated by a content delivery network (CDN). The CDN’s authoritative DNS server selects the “best” content server for each particular client based on (1) the client’s IP address (from which it learns the client’s geographic or network location) and (2) current load on the content servers (which the servers periodically report to the DNS server).
Once the client has the IP address for one of the content servers, it begins requesting chunks of the video the user requested. The video is encoded at multiple bitrates. As the client player receives video data, it calculates the throughput of the transfer and monitors how much video it has buffered to play, and it requests the highest bitrate the connection can support without running out of video in the playback buffer.
1.2 Your System
Implementing an entire CDN is clearly a tall order, so let’s simplify things. First, your entire system will run on one host; we’re providing a network simulator (described in Development Environment​) that will allow you to run several processes with arbitrary IP addresses on one machine. Our simulator also allows you to assign arbitrary link characteristics (bandwidth and latency) to the path between each pair of “end hosts” (processes). For this project, you will do your development and testing using a virtual machine ​(VM)​ we provide.

Browser​. You’ll use an off-the-shelf web browser (e.g. Firefox) to play videos served by your CDN (via your proxy). This is not necessary for the preliminary stage.
Proxy​. Rather than modify the video player itself, you will implement adaptive bitrate selection in an HTTP proxy. The player requests chunks with standard HTTP GET requests. Your proxy will intercept these and modify them to retrieve whichever bitrate your algorithm deems appropriate. To simulate multiple clients, you will launch multiple instances of your proxy. More details when the final stage assignment is released.
Web Server. ​Video content will be served from an off-the-shelf web server (Apache). More details when the final stage assignment is released.
The project is broken up into two stages:
● In the ​preliminary stage​, you will implement a simple proxy that sequentially
handles clients and passes messages back and forth between client and server
without modifying the messages.
● In the final stage (to be released later), you will extend the proxy to implement
the full functionality described above, with the proxy modifying HTTP requests to perform bitrate adaptation.
1.3 Groups and collaboration policy
This is an individual project, but you can discuss it at a conceptual level with other students or consult Internet material (excluding implementations of Python proxies), as long as the final code and configuration you submit is completely yours and as long as

you do not share code or configuration. Before starting the project, be sure to read the collaboration policy​ at the end of this document.
2. Preliminary stage
You will be implementing a simple proxy that accepts client connections sequentially (i.e. handles a client, and, once it disconnects, takes care of the next client). In later stages, your proxy will be required to handle client connections concurrently.
In this preliminary stage, the proxy does NOT need to modify any messages it receives, as it will just relay the messages back and forth. In later stages, you will enhance your proxy to modify messages in order to perform adaptive bitrate selection.
2.1 Get your connections right.
Your proxy should accept connections from clients and then open up another connection with a server (​see How to run the proxy​). Once both connections are established, the proxy should forward messages between the client and server.
You should implement this in two steps:
a. Establish a connection with a client:
Your proxy should listen for connections from a client on any IP address on the port specified as a command line argument (​see How to run the proxy​). Your proxy should accept multiple connections from clients. It ​is not​ required to handle them concurrently for now. Simply handling them one by one, ​sequentially​, will be enough.
b. Establish a connection with a server:
Once the proxy gets connected to the client, it should then connect to the server. The server IP is provided as a command line argument. As for the port number, use 8080. Make sure to close connections to the client and server when either of them disconnects.

(Figure 4) Preliminary structure
2.2 Forwarding protocol.
The “messages” that the proxy forwards follow a particular structure (for example, in HTTP, you know that there is a header and a body). This structure is important, as the recipient of the message can know where to look to get a specific piece of information. For the preliminary stage, we keep our message structure very simple:
(Figure 5) Structure of a message
The message has a body, and an End Of Message (EOM) symbol that indicates the end of the message. In our case, we define our EOM as the the new line character ‘\n’. Please note that detecting ‘\n’ is different from detecting the slash character ‘\’ and the letter ‘n’..
A message has to be fully received by the proxy before being forwarded to the other side.
Here is how the forwarding protocol works in our case:
1. The proxy gets a message from the client and forwards it to the server
2. The proxy expects a response from the server, gets it, and forwards it to the
client
An important thing to notice here is that there is no asynchronous forwarding (i.e., the proxy doesn’t simply forward any message, it first waits for a message from the client,

and then waits for a response from a server). In other terms, the proxy shouldn’t forward a message coming from a server before getting one from the client.
2.3 Running the proxy
You should create an executable Python script called ​proxy​ inside the proxy directory (see ​below for a description of the development environment​), which should be invoked as follows:
cd ~/project1-starter/proxy
./proxy
listen-port​: The TCP port your proxy should listen on for accepting connections from the client.
fake-ip​: Your proxy should bind to this IP address for outbound connections to the server. You should not bind your proxy listen socket to this IP address— bind the listen socket to receive traffic to the specified port regardless of the IP address. (i.e. by calling mySocket.bind((“”, ))
Important note: ​The above is a pretty unusual thing to do.​ You might think “in lecture, we saw that the client socket doesn’t bind, and now, you are telling us to bind the proxy’s outbound socket when connecting to the server”. However, it is necessary for the Final Stage’s network simulator to work properly, and so we will add it in this stage.
server-ip​: The IP address of the server
See instructions for making your script executable in the section ​What to Submit for
preliminary stage.
2.4 Test it out!
You can test parts​ ​Get your connections right​ ​and​ ​Forwarding protocol​ ​of​ ​your proxy implementation by using the netcat tool (​nc ​or ​netcat​, which is installed in the ​VM​) presented in class, using both a netcat client and a netcat server. You should be able to send a message from the client and see it appear on the server side. Then, any response sent from your server should also appear on the client. For the fake-ip, you

can indicate 127.0.0.1 (localhost) when testing with netcat instances that are created on your machine.
2.5 Final result
Your proxy should be able to forward a message from a client to the server, and in turn, forward the response from the server back to the client. It should support back-and-forth messages until one side closes the connection. After the connection is closed, it should be able to accept a new connection from a client. You should be able to test the behavior of your application by creating netcat instances.
Note that this version simply forwards messages with the structure specified in Figure 2. The next stage will have a different message structure: the HTTP message structure, and you’ll have to adapt your proxy based on your knowledge of HTTP messages.
2.6 What to Submit for preliminary stage
PLEASE PAY ATTENTION TO THE HANDIN STRUCTURE, AS EVEN A TYPO WILL CAUSE THE GRADER TO BREAK, WHICH CAN MAKE YOU LOSE 10 POINTS. You will submit your project as a zipped file named <​yourUNI>.zip. ​Unzipping this file should give us a directory named ​handin​ which should ​only​ contain the following:
● proxy​ — A directory named ​proxy ​containing only your source code. The code that you want to execute should be an executable named ​proxy​, as described in 2.3 How to run the proxy​.​ To make the code executable, follow these steps:
1. Add ‘#!/usr/bin/env python3’ to the top of your ​proxy​ Python file
2. Run ‘chmod 755 proxy’ to ensure that the file has the correct permissions
to be executable by us.
(Figure 6) Preliminary stage submission file structure.

You may organize your code within the ​proxy​ directory as you see fit. Part of your grade may be based on how understandable/organized/well-explained your code is, but we do not require any particular organization as well as it is well-organized.
2.7 Where to Submit
You will submit your code to CourseWorks​. ​If you have any questions about it, please let us know ASAP.
3. Final stage: Video Bitrate Adaptation Details to be released later.
4 Development Environment
For the project, we are providing a virtual machine (VM) pre-configured with the software you will need. We strongly recommend that you do all development and testing in this VM; your code must run correctly on this image as we will be using it for grading. For example, some students in previous years decided to write their code on their Windows environment, which changed the control characters to ​CLRF (Unix uses LF, thus our grader could not run their code)​. Please make sure your code uses ​LF​. This section describes the VM and the starter code it contains.
4.1 Virtual Box
The virtual machine disk (VMDK) we provide was created using VirtualBox, though you may be able to use it with other virtualization software. VirtualBox is a free download for Windows, OSX, and Linux on ​https://www.virtualbox.org​. ​And please download the VM instance ​here​, and then import it to your own VirtualBox. Please set the number of processors according to your host machine (By selecting your imported VM image and go to ​Settings–>System–>Processor​).
We’ve already set up an admin account: Username: ​ece4119abr
Password: ​kuroseross

In the event you need to move files between the VM and your computer (e.g., for submission), there are a few options.
1. (​recommended)​ Create a (private) Github repository with the relevant project files. You can push to your repository from the VM and access the files from anywhere.
2. Send the files via the Internet (email, Google Drive). Firefox is installed on the VM.
3. VirtualBox has ​‘shared folders’​, that let a host computer access files in a VM.
4.5 Programming Language and Packages
This project must be implemented in ​Python 3.8.2​. If this choice of language poses a significant problem for you (i.e., you have never used python before), please contact the instructors.
For this project, you are allowed to use the following python packages: sys, socket, threading, select, time, re, numpy
Using an unallowed package in your code may result in no credit being given. Other than the packages listed, you may only use the package if you ask on Piazza ​and​ a TA or the professor explicitly responds to your request approving the use. We will maintain a pinned Piazza post titled “​Project 1 List of Approved (and Disallowed) Packages​”, so please check that post before posting your request. If you would like to use a package not mentioned here and are unsure if it would be acceptable, please ​add a ​new followup discussion ​under the above mentioned pinned post on Piazza at least 3 days in advance of the project deadline.
In your followup discussion, you must mention the package name, the package version, and a link to the official repository of the package (e.g. ​http://pypi.python.org/pypi​). TAs will examine your request and determine if the package is allowed and add it to the list of allowed/disallowed packages.

[4.6] (Optional) CUIT Workstations
Most students may be most comfortable developing on their personal computers. If you do not have a workstation capable of running the provided VM on VirtualBox, CUIT has been kind enough to allot us workstations for you to develop on. Specifically, the following machines are available:
1. cadpc05.ee.columbia.ed​u 2. cadpc29.ee.columbia.edu 3. cadpc30.ee.columbia.edu 4. cadpc31.ee.columbia.edu 5. cadpc32.ee.columbia.edu 6. cadpc33.ee.columbia.edu 7. cadpc34.ee.columbia.edu 8. cadpc35.ee.columbia.edu 9. cadpc37.ee.columbia.edu 10. cadpc38.ee.columbia.edu 11. cadpc39.ee.columbia.edu 12. cadpc40.ee.columbia.edu 13. cadpc41.ee.columbia.edu 14. cadpc42.ee.columbia.edu
To access the machines, follow the instructions ​here​. You should have received an email from CUIT with an initial password for ssh (the username is your UNI). If you do not want to use the CUIT computers, you can log in once to change the password, or you can simply ignore the email.
If you notice your machine is running slow, that may be because other students are using the same machine at the same time (we are not the only ones allowed to use the machines). Consider switching to a different machine, in this case.
7 Grading
Your grade will consist of the following components: Proxy ​(70 points)
● 15 points: Preliminary stage proxying
● Final stage proxy implementation
● Code executes as instructed
Final Stage Writeup ​(20 points)
● Plots of utilization, fairness, and smoothness for α ∈ {0.1, 0.5, 0.9}

● Discussion of tradeoffs for varying α Style ​(10 points)
● Code thoroughly commented
● Code organized and modular
● README listing your files and what they contain
Please make sure your code runs as an executable and as described in Running the Proxy (​Preliminary Stage​) before submitting. Code that does not run may receive a zero on the assignment.
Academic integrity: Zero tolerance on plagiarism
The rules for ​Columbia University​, the C​ S Department​, and the EE Department (via SEAS: ​1 and ​2​) apply. It is your responsibility to carefully read these policies and ask the professor (via Piazza) if you have any questions about academic integrity. Please ask the professor before submitting the assignment, with enough time to resolve the issue before the deadline. A misunderstanding of university or class policies is not an excuse for violating a policy.
This class requires closely obeying the policy on academic integrity, and has zero tolerance on plagiarism for all assignments, including both projects/programming assignments and written assignments. By zero tolerance, we mean that the minimum punishment for plagiarism/cheating is a 0 for the assignment, and all cases will be referred to the Dean of Students.
This assignment must be completed individually. For programming assignments, in particular, you must write all the code you hand in yourself, except for code that we give you as part of the assignments. You are not allowed to look at anyone else’s solution (including solutions on the Internet, if there are any), and you are not allowed to look at code from previous years or ask people who took the class in previous years for help. You may discuss the assignments with other students at the conceptual level, but you may not write pseudocode together, or look at or copy each other’s code. ​Helping other students violate the policy (for example, letting them look at your code) is a violation, even if you completed the code yourself.​ Please do not publish your code or make it available to future students — for example, please do not make your code visible on Github. Uploading course materials to sites such as CourseHero, Chegg or Github is academic misconduct at Columbia (see ​pg 10​).
You may look at documentation from the tools’ websites. However, you may not use external libraries or any online code unless granted explicit permission by the professor or TA. ​For written (non-programming) answers, if you quote material from textbooks, journal articles, manuals, etc., you ​must​ include a citation that gives proper credit to the source to avoid suspicion of plagiarism. If you are unsure how to properly cite, you can use the web to find references on scientific citations, or ask fellow students and TAs on Piazza.

For each programming assignment, we will use software to check for plagiarized code.
Note​: You ​must​ set permissions on any homework assignments so that they are readable only by you. You may get reprimanded for facilitating cheating if you do not follow this rule.