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346 lines
13 KiB
Plaintext
<chapter id="concepts" xreflabel="2">
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<docinfo>
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<date>
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$Id$
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</date>
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</docinfo>
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<title>
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Concepts
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</title>
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<para>
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&Gnupg; makes uses of several cryptographic concepts including
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<firstterm>symmetric ciphers</firstterm>,
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<firstterm>public-key ciphers</firstterm>, and
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<firstterm>one-way hashing</firstterm>.
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You can make basic use &gnupg; without fully understanding these concepts,
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but in order to use it wisely some understanding of them is necessary.
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</para>
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<para>
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This chapter introduces the basic cryptographic concepts used in GnuPG.
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Other books cover these topics in much more detail.
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A good book with which to pursue further study is
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<ulink url="http://www.counterpane.com/schneier.html">Bruce
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Schneier</ulink>'s
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<ulink url="http://www.counterpane.com/applied.html">"Applied
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Cryptography"</ulink>.
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</para>
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<sect1>
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<title>
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Symmetric ciphers
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</title>
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<para>
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A symmetric cipher is a cipher that uses the same key for both encryption
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and decryption.
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Two parties communicating using a symmetric cipher must agree on the
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key beforehand.
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Once they agree, the sender encrypts a message using the key, sends it
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to the receiver, and the receiver decrypts the message using the key.
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As an example, the German Enigma is a symmetric cipher, and daily keys
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were distributed as code books.
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Each day, a sending or receiving radio operator would consult his copy
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of the code book to find the day's key.
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Radio traffic for that day was then encrypted and decrypted using the
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day's key.
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Modern examples of symmetric ciphers include 3DES, Blowfish, and IDEA.
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</para>
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<para>
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A good cipher puts all the security in the key and none in the algorithm.
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In other words, it should be no help to an attacker if he knows which
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cipher is being used.
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Only if he obtains the key would knowledge of the algorithm be needed.
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The ciphers used in &gnupg; have this property.
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</para>
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<para>
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Since all the security is in the key, then it is important that it be
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very difficult to guess the key.
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In other words, the set of possible keys, &ie;, the <emphasis>key
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space</emphasis>, needs
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to be large.
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While at Los Alamos, Richard Feynman was famous for his ability to
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crack safes.
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To encourage the mystique he even carried around a set of tools
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including an old stethoscope.
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In reality, he used a variety of tricks to reduce the number of
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combinations he had to try to a small number and then simply guessed
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until he found the right combination.
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In other words, he reduced the size of the key space.
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</para>
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<para>
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Britain used machines to guess keys during World War 2.
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The German Enigma had a very large key space, but the British built
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speciailzed computing engines, the Bombes, to mechanically try
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keys until the day's key was found.
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This meant that sometimes they found the day's key within hours of
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the new key's use, but it also meant that on some days they never
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did find the right key.
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The Bombes were not general-purpose computers but were precursors
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to modern-day computers.
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</para>
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<para>
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Today, computers can guess keys very quickly, and this is why key
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size is important in modern cryptosystems.
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The cipher DES uses a 56-bit key, which means that there are
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<!-- inlineequation -->
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2<superscript>56</superscript> possible keys.
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<!-- inlineequation -->
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2<superscript>56</superscript> is 72,057,594,037,927,936 keys.
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This is a lot of keys, but a general-purpose computer can check the
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entire key space in a matter of days.
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A specialized computer can check it in hours.
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On the other hand, more recently designed ciphers such as 3DES,
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Blowfish, and IDEA
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<!-- inlineequation -->
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all use 128-bit keys, which means there are 2<superscript>128</superscript>
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possible keys.
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This is many, many more keys, and even if all the computers on the
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planet cooperated, it could still take more time than the age of
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the universe to find the key.
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</para>
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</sect1>
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<sect1>
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<title>
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Public-key ciphers
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</title>
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<para>
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The primary problem with symmetric ciphers is not their security but
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with key exchange.
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Once the sender and receiver have exchanged keys, that key can be
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used to securely communicate, but what secure communication channel
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was used to communicate the key itself?
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In particular, it would probably be much easier for an attacker to work
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to intercept the key than it is to try all the keys in the key space.
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Another problem is the number of keys needed.
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<!-- inlineequation -->
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If there are <emphasis>n</emphasis> people who need to communicate, then
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<!-- inlineequation -->
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<emphasis>n(n-1)/2</emphasis> keys
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are needed for each pair of people to communicate privately.
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This may be ok for a small number of people but quickly becomes unwieldly
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for large groups of people.
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</para>
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<para>
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Public-key ciphers were invented to avoid the key-exchange problem
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entirely.
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A public-key cipher uses a pair of keys for sending messages.
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The two keys belong to the person receiving the message.
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One key is a <emphasis>public key</emphasis> and may be given to anybody.
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The other key is a <emphasis>private key</emphasis> and is kept
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secret by the owner.
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A sender encrypts a message using the public key and once encrypted,
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only the private key may be used to decrypt it.
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</para>
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<para>
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This protocol solves the key-exchange problem inherent with symmetric
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ciphers.
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There is no need for the sender and receiver to agree
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upon a key.
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All that is required is that some time before secret communication the
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sender gets a copy of the receiver's public key.
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Furthermore, the one public key can be used by anybody wishing to
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communicate with the receiver.
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<!-- inlineequation -->
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So only <emphasis>n</emphasis> keypairs are needed for <emphasis>n</emphasis>
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people to communicate secretly
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with one another,
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</para>
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<para>
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Public-key ciphers are based on one-way trapdoor functions.
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A one-way function is a function that is easy to compute,
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but the inverse is hard to compute.
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For example, it is easy to multiply two prime numbers together to get
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a composite, but it is difficult to factor a composite into its prime
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components.a
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A one-way trapdoor function is similar, but it has a trapdoor.
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That is, if some piece of information is known, it becomes easy
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to compute the inverse.
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For example, if you have a number made of two prime factors, then knowing
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one of the factors makes it easy to compute the second.
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Given a public-key cipher based on prime factorization, the public
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key contains a composite number made from two large prime factors, and
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the encryption algorithm uses that composite to encrypt the
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message.
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The algorithm to decrypt the message requires knowing the prime factors,
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so decryption is easy if you have the private key containing one of the
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factors but extremely difficult if you do not have it.
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</para>
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<para>
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As with good symmetric ciphers, with a good public-key cipher all of the
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security rests with the key.
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Therefore, key size is a measure of the system's security, but
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one cannot compare the size of a symmetric cipher key and a public-key
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cipher key as a measure of their relative security.
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In a brute-force attack on a symmetric cipher with a key size of 80 bits,
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<!-- inlineequation -->
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the attacker must enumerate up to 2<superscript>81</superscript>-1 keys to
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find the right key.
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In a brute-force attack on a public-key cipher with a key size of 512 bits,
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the attacker must factor a composite number encoded in 512 bits (up to
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155 decimal digits).
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The workload for the attacker is fundamentally different depending on
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the cipher he is attacking.
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While 128 bits is sufficient for symmetric ciphers, given today's factoring
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technology public keys with 1024 bits are recommended for most purposes.
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</para>
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</sect1>
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<sect1>
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<title>
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Hybrid ciphers
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</title>
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<para>
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Public-key ciphers are no panacea.
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Many symmetric ciphers are stronger from a security standpoint,
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and public-key encryption and decryption are more expensive than the
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corresponding operations in symmetric systems.
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Public-key ciphers are nevertheless an effective tool for distributing
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symmetric cipher keys, and that is how they are used in hybrid cipher
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systems.
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</para>
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<para>
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A hybrid cipher uses both a symmetric cipher and a public-key cipher.
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It works by using a public-key cipher to share a key for the symmetric
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cipher.
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The actual message being sent is then encrypted using the key and sent
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to the recipient.
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Since symmetric key sharing is secure, the symmetric key used is different
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for each message sent.
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Hence it is sometimes called a session key.
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</para>
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<para>
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Both PGP and &gnupg; use hybrid ciphers.
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The session key, encrypted using the public-key cipher, and the message
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being sent, encrypted with the symmetric cipher, are automatically
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combined in one package.
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The recipient uses his private-key to decrypt the session key and the
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session key is then used to decrypt the message.
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</para>
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<para>
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A hybrid cipher is no stronger than the public-key cipher or symmetric
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cipher it uses, whichever is weaker.
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In PGP and &gnupg;, the public-key cipher is probably the weaker of
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the pair.
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Fortunately, however, if an attacker could decrypt a session key it
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would only be useful for reading the one message encrypted with that
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session key.
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The attacker would have to start over and decrypt another session
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key in order to read any other message.
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</para>
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</sect1>
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<sect1>
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<title>
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Digital signatures
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</title>
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<para>
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A hash function is a many-to-one function that maps its input to a
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value in a finite set.
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Typically this set is a range of natural numbers.
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<!-- inlineequation -->
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A simple ehash function is <emphasis>f</emphasis>(<emphasis>x</emphasis>) = 0
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for all integers <emphasis>x</emphasis>.
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A more interesting hash function is
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<emphasis>f</emphasis>(<emphasis>x</emphasis>) = <emphasis>x</emphasis>
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<emphasis>mod</emphasis> 37, which
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maps <emphasis>x</emphasis> to the remainder of dividing <emphasis>x</emphasis> by 37.
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</para>
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<para>
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A document's digital signature is the result of applying a hash
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function to the document.
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To be useful, however, the hash function needs to satisfy two
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important properties.
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First, it should be hard to find two documents that hash to the
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same value.
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Second, given a hash value it should be hard to recover the document
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that produced that value.
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</para>
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<para>
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Some public-key ciphers<footnote><para>
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The cipher must have the property that the actual public key or private
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key could be used by the encryption algorithm as the public key.
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RSA is an example of such an algorithm while ElGamal is not an example.
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</para>
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</footnote> could be used to sign documents.
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The signer encrypts the document with his <emphasis>private</emphasis> key.
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Anybody wishing to check the signature and see the document simply
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uses the signer's public key to decrypt the document.
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This algorithm does satisfy the two properties needed from a good hash
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function, but in practice, this algorithm is too slow to be useful.
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</para>
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<para>
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An alternative is to use hash functions designed to satisfy these
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two important properties.
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SHA and MD5 are examples of such algorithms.
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Using such an algorithm, a document is signed by hashing it, and
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the hash value is the signature.
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Another person can check the signature by also hashing their copy of the
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document and comparing the hash value they get with the hash value of
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the original document.
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If they match, it is almost certain that the documents are identical.
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</para>
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<para>
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Of course, the problem now is using a hash function for digital
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signatures without permitting an attacker to interfere with signature
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checking.
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If the document and signature are sent unencrypted, an attacker could
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modify the document and generate a corresponding signature without the
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recipient's knowledge.
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If only the document is encrypted, an attacker could tamper with the
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signature and cause a signature check to fail.
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A third option is to use a hybrid public-key encryption to encrypt both
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the signature and document.
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The signer uses his private key, and anybody can use his public key
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to check the signature and document.
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This sounds good but is actually nonsense.
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If this algorithm truly secured the document it would also
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secure it from tampering and there would be no need for the signature.
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The more serious problem, however, is that this does not protect either
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the signature or document from tampering.
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With this algorithm, only the session key for the symmetric cipher
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is encrypted using the signer's private key.
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Anybody can use the public key to recover the session key.
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Therefore, it is straightforward for an attacker to recover the session
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key and use it to encrypt substitute documents and signatures to send
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to others in the sender's name.
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</para>
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<para>
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An algorithm that does work is to use a public key algorithm to
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encrypt only the signature.
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In particular, the hash value is encrypted using the signer's private
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key, and anbody can check the signature using the public key.
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The signed document can be sent using any other encryption algorithm
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including none if it is a public document.
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If the document is modified the signature check will fail, but this
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is precisely what the signature check is supposed to catch.
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The Digital Signature Standard (DSA) is a public key signature
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algorithm that works as just described.
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DSA is the primary signing algorithm used in &Gnupg;.
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</para>
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</sect1>
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</chapter>
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