Write a program (FeistelEncryption.asm) in HACK assembly, that implements the described Feistel encryption system. The initial key, Ko, will be stored in RAM[1], and the plaintext to be encrypted will be represented by a 16-bit value stored in RAM[2]. The result of the encryption should be stored in RAM[0]. The Feistel cipher is a symmetric block cipher encryption framework which is the basis of many modern day encryption algorithms. In this coursework you will implement a Feistel cipher system as a software implementation in Hack Assembly. In a Feistel cipher the plaintext, P, to be encrypted is split into two equal size parts Lo and Ro such that P = LoRo. A function F is applied to one half of the plaintext, combined with a key, and the result is XOR'd with the other half of the plaintext. Feistel ciphers often employ multiple rounds of this scheme. In general the scheme works as follows, for all i=0,...,N, Li+1 = Ri Ri+1 = L; F(R₁, K₁) To decrypt an encrypted message using this cipher we can apply the same procedure. in reverse. For in,n 1,..., 0, R₁ = Li+1 L₁ = Ri+1 F(Li+1, Ki) For this coursework we are interested in the 16-bit Feistel cipher which uses 4 rounds. The function F(A, B) = A + ¬B. The keys are derived from a single 8-bit key Ko such that, Ko=b7b6b5b4b3b₂b₁bo K1b6b5b4b3b2b1b0b7 K₂ = b5b4b3b2b1bb7b6 K3=b4b3b2b1b0b7b6b5

Please give me a step by step solution for this question, using only the regular c-instructions offered with hack assembly language.

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Write a program (FeistelEncryption.asm) in HACK assembly, that implements the described Feistel encryption system. The initial key, Ko, will be stored in RAM[1], and the plaintext to be encrypted will be represented by a 16-bit value stored in RAM[2]. The result of the encryption should be stored in RAM[0].

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The Feistel cipher is a symmetric block cipher encryption framework which is the basis of many modern day encryption algorithms. In this coursework you will implement a Feistel cipher system as a software implementation in Hack Assembly. In a Feistel cipher the plaintext, P, to be encrypted is split into two equal size parts Lo and Ro such that P = LoRo. A function F is applied to one half of the plaintext, combined with a key, and the result is XOR'd with the other half of the plaintext. Feistel ciphers often employ multiple rounds of this scheme. In general the scheme works as follows, for all i=0,...,N, Li+1 = Ri Ri+1 = L; F(R₁, K₁) To decrypt an encrypted message using this cipher we can apply the same procedure. in reverse. For in,n 1,..., 0, R₁ = Li+1 L₁ = Ri+1 F(Li+1, Ki) For this coursework we are interested in the 16-bit Feistel cipher which uses 4 rounds. The function F(A, B) = A + ¬B. The keys are derived from a single 8-bit key Ko such that, Ko=b7b6b5b4b3b₂b₁bo K1b6b5b4b3b2b1b0b7 K₂ = b5b4b3b2b1bb7b6 K3=b4b3b2b1b0b7b6b5