When Julius Caesar sent messages to his generals, he didn't trust his messengers. So he replaced every A in his messages with a D, every B with an E, and so on through the alphabet. Only someone who knew the “shift by 3” rule could decipher his messages.
And so we begin.
About Encryption and decryption
Data that can be read and understood without any special measures is called plaintext or cleartext. The method of disguising plaintext in such a way as to hide its substance is called encryption. Encrypting plaintext results in unreadable gibberish called ciphertext. You use encryption to make sure that information is hidden from anyone for whom it is not intended, even those who can see the encrypted data. The process of reverting ciphertext to its original plaintext is called decryption. just look this ilustrastion :
Plaintext --> encryption --> chipertext --> descryption --> plaintext
What is cryptography?
Cryptography is the science of using mathematics to encrypt and decrypt data. Cryptography enables you to store sensitive information or transmit it across insecure networks (like the Internet) so that it cannot be read by anyone except the intended recipient. While cryptography is the science of securing data, cryptanalysis is the science of analyzing and breaking secure communication. Classical cryptanalysis involves an interesting combination of analytical reasoning, application of mathematical tools, pattern finding, patience, determination, and luck. Cryptanalysts are also called attackers. Cryptology embraces both cryptography and cryptanalysis.
A related discipline is steganography, which is the science of hiding messages rather than making them unreadable. Steganography is not cryptography; it is a form of coding. It relies on the secrecy of the mechanism used to hide the message. If, for example, you encode a secret message by putting each letter as the first letter of the first word of every sentence, it’s secret until someone knows to look for it, and then it provides no security at all.
Strong cryptography
“There are two kinds of cryptography in this world: cryptography that will stop your kid sister from reading your files, and cryptography that will stop major governments from reading your files. This book is about the latter.”
—Bruce Schneier, Applied Cryptography: Protocols, Algorithms, and Source Code in C
PGP is also about the latter sort of cryptography.
Cryptography can be strong or weak, as explained above. Cryptographic strength is measured in the time and resources it would require to recover the plaintext. The result of strong cryptography is ciphertext that is very difficult to decipher without possession of the appropriate decoding tool. How difficult? Given all of today’s computing power and available time—even a billion computers doing a billion checks a second—it is not possible to decipher the result of strong cryptography before the end of the universe.
One would think, then, that strong cryptography would hold up rather well against even an extremely determined cryptanalyst. Who’s really to say? No one has proven that the strongest encryption obtainable today will hold up under tomorrow’s computing power. However, the strong cryptography employed by PGP is the best available today. Vigilance and conservatism will protect you better, however, than claims of impenetrability.
How does cryptography work?
A cryptographic algorithm, or cipher, is a mathematical function used in the encryption and decryption process. A cryptographic algorithm works in combination with a key—a word, number, or phrase—to encrypt the plaintext. The same plaintext encrypts to different ciphertext with different keys. The security of encrypted data is entirely dependent on two things: the strength of the cryptographic algorithm and the secrecy of the key.
A cryptographic algorithm, plus all possible keys and all the protocols that make it work, comprise a cryptosystem. PGP is a cryptosystem.
Conventional cryptography
In conventional cryptography, also called secret-key or symmetric-key encryption, one key is used both for encryption and decryption. The Data Encryption Standard (DES) in an example of a conventional cryptosystem that has been widely deployed by the U.S. Government and the banking industry. It is being replaced by the Advanced Encryption Standard (AES). The following figure is an illustration of the conventional encryption process.
Plaintext --> encryption --> chipertext --> descryption --> plaintext
| -------------------------------- KEY ------------------------------|
Caesar’s cipher
An extremely simple example of conventional cryptography is a substitution cipher. A substitution cipher substitutes one piece of information for another. This is most frequently done by offsetting letters of the alphabet. Two examples are Captain Midnight’s Secret Decoder Ring, which you may have owned when you were a kid, and Julius Caesar’s cipher. In both cases, the algorithm is to offset the alphabet and the key is the number of characters to offset it.
For example, if we encode the word “SECRET” using Caesar’s key value of 3, we offset the alphabet so that the 3rd letter down (D) begins the alphabet.
So starting with
ABCDEFGHIJKLMNOPQRSTUVWXYZ
and sliding everything up by 3, you get
DEFGHIJKLMNOPQRSTUVWXYZABC
where D=A, E=B, F=C, and so on.
Using this scheme, the plaintext, “SECRET” encrypts as “VHFUHW.” To allow someone else to read the ciphertext, you tell them that the key is 3. Obviously, this is exceedingly weak cryptography by today’s standards, but hey, it worked for Caesar, and it illustrates how conventional cryptography works.
Key management and conventional encryption
Conventional encryption has benefits. It is very fast. It is especially useful for encrypting data that is not going anywhere. However, conventional encryption alone as a means for transmitting secure data can be quite expensive simply due to the difficulty of secure key distribution.
Recall a character from your favorite spy movie: the person with a locked briefcase handcuffed to his or her wrist. What is in the briefcase, anyway? It’s probably not the secret plan itself. It’s the key that will decrypt the secret data. For a sender and recipient to communicate securely using conventional encryption, they must agree upon a key and keep it secret between themselves. If they are in different physical locations, they must trust a courier, the Bat Phone, or some other secure communications medium to prevent the disclosure of the secret key during transmission. Anyone who overhears or intercepts the key in transit can later read, modify, and forge all information encrypted or authenticated with that key. From DES to Captain
Midnight’s Secret Decoder Ring, the persistent problem with conventional encryption is key distribution: how do you get the key to the recipient without someone intercepting it?
Public-key cryptography The problems of key distribution are solved by public-key cryptography, the concept of which was introduced by Whitfield Diffie and Martin Hellman in 1975. (There is now evidence that the British Secret Service invented it a few years before Diffie and Hellman, but kept it a military secret—and did nothing with it.(1)
Public-key cryptography uses a pair of keys: a public key, which encrypts data, and a corresponding private key, for decryption. Because it uses two keys, it is sometimes called asymmetric cryptography. You publish your public key to the world while keeping your private key secret. Anyone with a copy of your public key can then encrypt information that only you can read, even people you have never met.
Source : PGP Readme, IntroToCrypto
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1) J H Ellis, The Possibility of Secure Non-Secret Digital Encryption, CESG Report, January 1970. [CESG is the UK’s National Authority for the official use of cryptography.]