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Problem Set 1

This is an introduction assignment to:

  • allow you to setup local Python environment
  • get you started with GradeScope

See GradeScope for exact due-date of this assignment.

Cheating

All the code you submit must be written by you. Submitting code written by anyone else is cheating in the official sense. Please don't do that.

It's ok (and encouraged!) for students to work together by discussing problems without sharing code. It's also ok to have someone look at your code to help you debug a specific issue. But it's not ok to look at someone else's code to copy it or to have anyone write code for you. Please don't explore the gray area between these things.

For common operations like "open a file", "parse a JSON string", or "call a library function", it's ok to copy two or three lines of code from documentation, Stack Overflow, etc. But copying more than two or three lines of code is probably not ok. If you do, you must clearly cite your source in an inline comment that begins with COPIED. Citing your source doesn't automatically make copying ok, but failing to cite your source turns one violation into two violations. Please don't explore the gray area of what counts as a "line of code".

Problems

This assignment consists of 7 problems:

  1. Manipulate unicode from bytes
  2. Generating a list of random integers of given length
  3. Generating random bytes of given length
  4. Manipulating given bytes with some basic arithmetic
  5. XORing set of bytes
  6. Decode hex string to bytes
  7. Inverse of previous to encode bytes as hex

Submission

You may submit this assignment in multiple ways described below.

Note that you can submit partial assignment without solving all of the problems first. We actually encourage you to submit early and often as GradeScope will help you testing your solutions.

Gradescope

GradeScope uses pytest for the test runner. It usually shows pretty good error messages. You can see some examples here. If youll need any help with gradescope output, please ask in slack.

Note that we reserve the right to update GradeScope test suite as we come across issues/bugs or find submissions which abuse things.

Python Submission

This is the simplest approach and we recommend that most students take this option. You simply need to submit a file named ps1.py. Note filename is important. Its not problems.py or anything else. Its literally filename == 'ps1.py'. This file should have these 7 functions defined:

  • example - solution is already provided for you and so this function is checked in Gradescope but is worth 0 points
  • problem1
  • problem2
  • problem3
  • problem4
  • problem5
  • problem6

Yes we know this is very creative naming but it keeps things simple :D

Below you will find type-annotated stubs of the functions you need to implement. You can copy-paste these stubs into ps1.py to get you started. Note that parameter names are important. GradeScope will call these functions with the same parameter names as defined in the stubs. Also some of the functions have doctests defined which provide example output functions should produce.

GradeScope will run this code on Python3.10 so we recommend you use the same Python version locally for development. pyenv might be of use here if you need to manage multiple Python versions.

import typing


def example(data: bytes) -> bytes:
    """
    Convert utf-8 encoded bytes to uppercase and return modified utf-8 encoded bytes

    >>> example(b'hello')
    b'HELLO'
    >>> example(b'hello').decode()
    'HELLO'
    >>> example('привіт'.encode())
    b'\xd0\x9f\xd0\xa0\xd0\x98\xd0\x92\xd0\x86\xd0\xa2'
    >>> example('привіт'.encode()).decode()
    'ПРИВІТ'
    """
    return data.decode("utf-8").upper().encode("utf-8")


def problem1(n: int) -> typing.List[int]:
    """
    Generate a list of `n` random numbers in range [0,256)

    Please use cryptographically-secure entropy source
    see secrets module in python

    # not doctest as output is random
    > problem1(5)
    [140, 7, 218, 46, 104]
    """


def problem2(n: int) -> bytes:
    """
    Generate random `n` bytes

    Please use cryptographically-secure entropy source
    see secrets module in python

    # not doctest as output is random
    > problem2(5)
    b'\x18s\x0b8B'
    """


def problem3(data: bytes) -> bytes:
    """
    Manipulate given data bytes where each byte is multiplied * 2 % 256

    In other words, input is a collection of bytes
    You should multiply each of those bytes by 2 mod 256
    (not to overflow)
    and then return resulting bytes

    >>> problem3(b'hello')
    b'\xd0\xca\xd8\xd8\xde'
    """


def problem4(data: typing.List[bytes]) -> bytes:
    """
    XOR all given bytes and output resulting XORed bytes

    All inputs will be of same length

    >>> problem4([
    ...     b'hello',
    ...     b'world',
    ...     b'hello',
    ... ])
    b'world'
    """


def problem5(data: str) -> bytes:
    """
    Decode given hex-encoded string to bytes

    >>> problem5('d0cad8d8de')
    b'\xd0\xca\xd8\xd8\xde'
    """


def problem6(data: bytes) -> str:
    """
    Encode given bytes to hex-encoded string

    >>> problem6(b'hello')
    '68656c6c6f'
    """

Binary Submission

If you feel adventurous, you can submit this assignment as an executable file therefore allowing you to solve it in any other language. Rust, C, C++, Java, JavaScript, even bash, etc can be used. Note that GradeScope runs Ubuntu22.04 so the executable needs to be POSIX-compatible and therefore no Windows executables.

To do that, you will need to submit either:

  • script file with valid shebang. For example ps1, ps1.sh, ps1.js, etc. By script file we mean here the file is plain text file (not binary).
  • compile an actual binary executable named ps1 from submitted source code via setup.sh (see below). Note that you CANNOT submit binary file directly as its source-code will not be accessible. The binary needs to be compiled in GradeScope from submitted source code.

In either case the executable will have to do the following:

  • accept bson input via stdin
  • produce bson output to stdout

BSON is used to explicitly allow binary data in both input and output without any additional steps like hex encoding.

BSON input will be of the following structure:

  • keys are the same as python function names described above
  • for each key, value is a dictionary with parameters for the function as defined above.

For example for a single function defined as:

def foo(a: int, b: str): pass

then the BSON input will be something like (represented as json here for clarity):

{
  "foo": {
    "a": 1,
    "b": "test"
  }
}

BSON output will be of the following structure:

  • keys are the same as python function names described above
  • for each key, value is the return value of the function as described above

In other words, for each function described above bson input via stdin will provide the function parameters and bson output to stdout should provide function return values.

This way the data-structures between Python submission and binary submission are interchangeable. As a matter of fact you can even generate bson input/output in python via simple_bson:

import sys
import simple_bson

# problem functions defined here

if __name__ == "__main__":
    inputs = simple_bson.loads(sys.stdin.buffer.read())
    solutions = {k: globals()[k](**v) for k, v in inputs.items()}
    sys.stdout.buffer.write(simple_bson.dumps(solutions))

Also see provided example bson files:

  • bson.in
  • bson.out

setup.sh

If you submit setup.sh along with your submission, this is a hook script which should allow you to:

  • install additional dependencies if you need to although this assignment should not require any external libraries and standard library should be sufficient.
  • install necessary system dependencies in order to compile binary solution from submitted source code

This should just be a simple bash script:

#!/usr/bin/env bash
# do things here