From 797a1404213173791a5f4126a77ad383ceb00064 Mon Sep 17 00:00:00 2001 From: Christian Cleberg Date: Mon, 4 Mar 2024 22:34:28 -0600 Subject: initial migration to test org-mode --- content/blog/2018-12-08-aes-encryption.md | 124 ------------------------------ 1 file changed, 124 deletions(-) delete mode 100644 content/blog/2018-12-08-aes-encryption.md (limited to 'content/blog/2018-12-08-aes-encryption.md') diff --git a/content/blog/2018-12-08-aes-encryption.md b/content/blog/2018-12-08-aes-encryption.md deleted file mode 100644 index 54a31a5..0000000 --- a/content/blog/2018-12-08-aes-encryption.md +++ /dev/null @@ -1,124 +0,0 @@ -+++ -date = 2018-12-08 -title = "AES Encryption" -description = "An exploration of the AES encryption standard." -+++ - -# Basic AES - -If you're not familiar with encryption techniques, -[AES](https://en.wikipedia.org/wiki/Advanced_Encryption_Standard) is the -**Advanced Encryption Standard**. This specification was established by -the National Institute of Standards and Technology, sub-selected from -the Rijndael family of ciphers (128, 192, and 256 bits) in 2001. -Furthering its popularity and status, the US government chose AES as -their default encryption method for top-secret data, removing the -previous standard which had been in place since 1977. - -AES has proven to be an extremely safe encryption method, with 7-round -and 8-round attacks making no material improvements since the release of -this encryption standard almost two decades ago. - -> Though many papers have been published on the cryptanalysis of AES, -> the fastest single-key attacks on round-reduced AES variants [20, -> 33] so far are only slightly more powerful than those proposed 10 -> years ago [23,24]. -> -> - [Bogdonav, et -> al.](http://research.microsoft.com/en-us/projects/cryptanalysis/aesbc.pdf) - -# How Secure is AES? - -In theory, AES-256 is non-crackable due to the massive number of -combinations that can be produced. However, AES-128 is no longer -recommended as a viable implementation to protect important data. - -A semi-short [comic -strip](http://www.moserware.com/2009/09/stick-figure-guide-to-advanced.html) -from Moserware quickly explains AES for the public to understand. -Basically AES encrypts the data by obscuring the relationship between -the data and the encrypted data. Additionally, this method spreads the -message out. Lastly, the key produced by AES is the secret to decrypting -it. Someone may know the method of AES, but without the key, they are -powerless. - -To obscure and spread the data out, AES creates a -substitution-permutation network. Wikipedia has a wonderful [example of -an SP -network](https://upload.wikimedia.org/wikipedia/commons/thumb/c/cd/SubstitutionPermutationNetwork2.png/468px-SubstitutionPermutationNetwork2.png) -available. This network sends the data through a set of S boxes (using -the unique key) to substitute the bits with another block of bits. Then, -a P box will permutate, or rearrange, the bits. This is done over and -over, with the key being derived from the last round. For AES, the key -size specifies the number of transformation rounds: 10, 12, and 14 -rounds for 128-bit, 192-bit, and 256-bit keys, respectively. - -# The Process - -1. \*KeyExpansion=: Using [Rijndael's key - schedule](https://en.m.wikipedia.org/wiki/Advanced_Encryption_Standard), - the keys are dynamically generated. -2. **AddRoundKey**: Each byte of the data is combined with this key - using bitwise xor. -3. **SubBytes**: This is followed by the substitution of each byte of - data. -4. **ShiftRows**: Then, the final three rows are shifted a certain - number of steps, dictated by the cipher. -5. **MixColumns**: After the rows have been shifted, the columns are - mixed and combined. - -This process does not necessarily stop after one full round. Steps 2 -through 5 will repeat for the number of rounds specified by the key. -However, the final round excludes the MixColumns step. As you can see, -this is a fairly complex process. One must have a solid understanding of -general mathematic principles to fully understand how the sequence works -(and to even attempt to find a weakness). - -According to research done by Bogdanov et al., it would take billions of -years to brute force a 126-bit key with current hardware. Additionally, -this brute force attack would require storing 2^88^ bits of data! -However, there are a few different attacks that have been used to show -vulnerabilities with the use of this technology. Side-channel attacks -use inadvertent leaks of data from the hardware or software, which can -allow attackers to obtain the key or run programs on a user's hardware. - -Please note that this is not something you should run out and try to -implement in your `Hello, World!` app after only a few hours of -research. While AES (basically all encryption methods) is extremely -efficient in what it does, it takes a lot of time and patience to -understand. If you're looking for something which currently implements -AES, check out the [Legion of the Bouncy -Castle](https://www.bouncycastle.org/documentation.html) for Java -implementations of cryptographic algorithms. - -# Why Does Encryption Matter? - -There are limitless reasons to enable encryption at-rest or in-transit -for various aspects of your digital life. You can research specific -examples, such as [Australia passes new law to thwart strong -encryption](https://arstechnica.com/tech-policy/2018/12/australia-passes-new-law-to-thwart-strong-encryption/). -However, I will simply list a few basic reasons to always enable -encryption, where feasible: - -1. Privacy is a human right and is recognized as a national right in - some countries (e.g., [US Fourth - Amendment](https://www.law.cornell.edu/wex/fourth_amendment)). -2. "Why not?" Encryption rarely affects performance or speed, so - there's usually not a reason to avoid it in the first place. -3. Your digital identity and activity (texts, emails, phone calls, - online accounts, etc.) are extremely valuable and can result in - terrible consequences, such as identity theft, if leaked to other - parties. Encrypting this data prevents such leaks from ruining - lives. -4. Wiping or factory-resetting does not actually wipe all data from the - storage device. There are methods to read data from the physical - disks/boards inside devices. -5. Corporations, governments, and other nefarious groups/individuals - are actively looking for ways to collect personal information about - anyone they can. If someone's data is unencrypted, that person may - become a target due to the ease of data collection. - -****Read More:**** - -- [Federal Information Processing Standards Publication - 197](http://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.197.pdf) -- cgit v1.2.3-70-g09d2