designers	Ron Rivest, Adi Shamir, and Leonard Adleman
publish date	1978
type	Public-Key
cryptanalysis	}}

In cryptography, RSA (which stands for Rivest, Shamir and Adleman who first publicly described it) is an algorithm for public-key cryptography. It is the first algorithm known to be suitable for signing as well as encryption, and was one of the first great advances in public key cryptography. RSA is widely used in electronic commerce protocols, and is believed to be sufficiently secure given sufficiently long keys and the use of up-to-date implementations.

History

Clifford Cocks, a British mathematician working for the UK intelligence agency GCHQ, described an equivalent system in an internal document in 1973, but given the relatively expensive computers needed to implement it at the time, it was mostly considered a curiosity and, as far as is publicly known, was never deployed. His discovery, however, was not revealed until 1998 due to its top-secret classification, and Rivest, Shamir, and Adleman devised RSA independently of Cocks' work. The RSA algorithm was publicly described in 1978 by Ron Rivest, Adi Shamir, and Leonard Adleman at MIT; the letters RSA are the initials of their surnames, listed in the same order as on the paper.

MIT was granted for a "Cryptographic communications system and method" that used the algorithm in 1983. The patent would have expired on September 21, 2000 (the term of patent was 17 years at the time), but the algorithm was released to the public domain by RSA Security on 6 September 2000, two weeks earlier. Since a paper describing the algorithm had been published in August 1977, prior to the December 1977 filing date of the patent application, regulations in much of the rest of the world precluded patents elsewhere and only the US patent was granted. Had Cocks' work been publicly known, a patent in the US might not have been possible.

From the DWPI's abstract of the patent,

The system includes a communications channel coupled to at least one terminal having an encoding device and to at least one terminal having a decoding device. A message-to-be-transferred is enciphered to ciphertext at the encoding terminal by encoding the message as a number M in a predetermined set. That number is then raised to a first predetermined power (associated with the intended receiver) and finally computed. The remainder or residue, C, is... computed when the exponentiated number is divided by the product of two predetermined prime numbers (associated with the intended receiver).

Operation

The RSA algorithm involves three steps: key generation, encryption and decryption.

Key generation

RSA involves a public key and a private key. The public key can be known to everyone and is used for encrypting messages. Messages encrypted with the public key can only be decrypted using the private key. The keys for the RSA algorithm are generated the following way: #Choose two distinct prime numbers ''p'' and ''q''. #*For security purposes, the integers ''p'' and ''q'' should be chosen at random, and should be of similar bit-length. Prime integers can be efficiently found using a primality test. #Compute #*''n'' is used as the modulus for both the public and private keys #Compute , where φ is Euler's totient function. #Choose an integer ''e'' such that and , i.e. ''e'' and φ(''n'') are coprime. #*''e'' is released as the public key exponent. #*''e'' having a short bit-length and small Hamming weight results in more efficient encryption - most commonly 0x10001 = 65537. However, small values of ''e'' (such as 3) have been shown to be less secure in some settings. #Determine ; i.e. ''d'' is the multiplicative inverse of . #*This is more clearly stated as solve for d given (d*e)mod φ(''n'') = 1 #*This is often computed using the extended Euclidean algorithm. #*''d'' is kept as the private key exponent.

The public key consists of the modulus ''n'' and the public (or encryption) exponent ''e''. The private key consists of the private (or decryption) exponent ''d'' which must be kept secret.

Notes: An alternative, used by PKCS#1, is to choose ''d'' matching with , where lcm is the least common multiple. Using λ instead of φ(''n'') allows more choices for ''d''. λ can also be defined using the Carmichael function, λ(''n'').

The ANSI X9.31 standard prescribes, IEEE 1363 describes, and PKCS#1 allows, that ''p'' and ''q'' match additional requirements: be strong primes, and be different enough that Fermat factorization fails.

Encryption

Alice transmits her public key $(n,e)$ to Bob and keeps the private key secret. Bob then wishes to send message M to Alice.

He first turns M into an integer m, such that by using an agreed-upon reversible protocol known as a padding scheme. He then computes the ciphertext $c$ corresponding to

: $c\; =\; m^e\backslash text\{\; (mod\; \}n\backslash text\{)\}$.

This can be done quickly using the method of exponentiation by squaring. Bob then transmits $c$ to Alice.

Note that at least nine values of m will yield a ciphertext c equal to m, but this is very unlikely to occur in practice.

Decryption

Alice can recover $m$ from $c$ by using her private key exponent $d$ via computing

: $m\; =\; c^d\backslash text\{\; (mod\; \}n\backslash text\{)\}$.

Given $m$, she can recover the original message M by reversing the padding scheme.

(In practice, there are more efficient methods of calculating $c^d$ using the pre computed values below.)

Using the Chinese remainder algorithm

For efficiency many popular crypto libraries (like OpenSSL, Java and .NET) use the following optimization for decryption and signing: The following values are precomputed and stored as part of the private key:

$p$ and $q$: the primes from the key generation,

$d\_P\; =\; d\backslash text\{\; (mod\; \}p-1\backslash text\{)\}$,

$d\_Q\; =\; d\backslash text\{\; (mod\; \}q-1\backslash text\{)\}$ and

$q\_\{Inv\}\; =\; q^\{-1\}\backslash text\{\; (mod\; \}p\backslash text\{)\}$.

These values allow the recipient to compute the exponentiation $m\; =\; c^d\backslash text\{\; (mod\; \}pq\backslash text\{)\}$ more efficiently as follows:

$m\_1\; =\; c^\{d\_P\}\backslash text\{\; (mod\; \}p\backslash text\{)\}$

$m\_2\; =\; c^\{d\_Q\}\backslash text\{\; (mod\; \}q\backslash text\{)\}$

$h\; =\; q\_\{Inv\}*(m\_1-m\_2)\backslash text\{\; (mod\; \}p\backslash text\{)\}$ (if then some libraries compute h as $q\_\{Inv\}*(m\_1+p-m\_2)\backslash text\{\; (mod\; \}p\backslash text\{)\}$)

$m\; =\; m\_2\; +\; (h*q)\backslash ,$

This is more efficient than computing $m\; =\; c^d\backslash text\{\; (mod\; \}pq\backslash text\{)\}$ even though two modular exponentiations have to be computed. The reason is that these two modular exponentiations both use a smaller exponent and a smaller modulus.

A working example

Here is an example of RSA encryption and decryption. The parameters used here are artificially small, but one can also use OpenSSL to generate and examine a real keypair.

#Choose two distinct prime numbers, such as #:$p\; =\; 61$ and $q=53$. #Compute $n\; =\; p\; q$ giving #:n = 61 · 53 = 3233. #Compute the totient of the product as $\backslash phi(n)\; =\; (p-1)(q-1)$ giving #:$\backslash phi(3233)\; =\; (61\; -\; 1)(53\; -\; 1)\; =\; 3120$. #Choose any number that is coprime to 3120. Choosing a prime number for $e$ leaves us only to check that $e$ is not a divisor of 3120. #:Let $e=17$. #Compute $d$, the modular multiplicative inverse of $e\backslash text\{\; (mod\; \}\backslash varphi(n)\backslash text\{)\}$ yielding #:$d=2753$.

The public key is ($n=3233$, $e=17$). For a padded plaintext message $m$, the encryption function is $m^\{17\}\backslash text\{\; (mod\; \}3233\backslash text\{)\}$.

The private key is ($n=3233$, $d=2753$). For an encrypted ciphertext $c$, the decryption function is $c^\{2753\}\backslash text\{\; (mod\; \}3233\backslash text\{)\}$.

For instance, in order to encrypt $m=65$, we calculate

:$c\; =\; 65^\{17\}\backslash text\{\; (mod\; \}3233\backslash text\{)\}\; =\; 2790$.

To decrypt $c\; =\; 2790$, we calculate

:$m\; =\; 2790^\{2753\}\backslash text\{\; (mod\; \}3233\backslash text\{)\}\; =\; 65$.

Both of these calculations can be computed efficiently using the square-and-multiply algorithm for modular exponentiation. In real life situations the primes selected would be much larger; in our example it would be relatively trivial to factor $n$, 3233, obtained from the freely available public key back to the primes $p$ and $q$. Given $e$, also from the public key, we could then compute $d$ and so acquire the private key.

Practical implementations use Chinese Remainder theorem to speed up the calculation using modulus of factors (mod p*q using mod p and mod q).

The values dp, dq and qInv, which are part of the private key are computed as follows:

$dp\; =\; d\backslash text\{\; mod\; \}(p-1)\; =\; 2753\; \backslash text\{\; mod\; \}\; (61-1)\; =\; 53$

$dq\; =\; d\backslash text\{\; mod\; \}(q-1)\; =\; 2753\; \backslash text\{\; mod\; \}\; (53-1)\; =\; 49$

$qInv\; =\; q^\{-1\}\; \backslash text\{\; mod\; \}\; p\; =\; 53^\{-1\}\; \backslash text\{\; mod\; \}\; 61\; =\; 38$ (Hence: $qInv*q\; \backslash text\{\; mod\; \}\; p\; =\; 38*53\; \backslash text\{\; mod\; \}\; 61\; =\; 1$ )

Here is how dp, dq and qInv are used for efficient decryption. (Encryption is efficient by choice of public exponent e)

$m1\; =\; c^\{dp\}\; \backslash text\{\; mod\; \}\; p\; =\; 2790^\{53\}\; \backslash text\{\; mod\; \}\; 61\; =\; 4$

$m2\; =\; c^\{dq\}\; \backslash text\{\; mod\; \}\; q\; =\; 2790^\{49\}\; \backslash text\{\; mod\; \}\; 53\; =\; 12$

$h\; =\; (qInv\; *\; (m1\; -\; m2))\; \backslash text\{\; mod\; \}\; p\; =\; (38\; *\; -8)\; \backslash text\{\; mod\; \}\; 61\; =\; 1$

$m\; =\; m2\; +\; h*q\; =\; 12\; +\; 1*53\; =\; 65$ (same as above but computed more efficiently)

Attacks against plain RSA

There are a number of attacks against plain RSA as described below.

When encrypting with low encryption exponents (e.g., $e\; =\; 3$) and small values of the $m$, (i.e.

If the same clear text message is sent to $e$ or more recipients in an encrypted way, and the receivers share the same exponent $e$, but different $p$, $q$, and therefore $n$, then it is easy to decrypt the original clear text message via the Chinese remainder theorem. Johan Håstad noticed that this attack is possible even if the cleartexts are not equal, but the attacker knows a linear relation between them. This attack was later improved by Don Coppersmith.

Because RSA encryption is a deterministic encryption algorithm – i.e., has no random component – an attacker can successfully launch a chosen plaintext attack against the cryptosystem, by encrypting likely plaintexts under the public key and test if they are equal to the ciphertext. A cryptosystem is called semantically secure if an attacker cannot distinguish two encryptions from each other even if the attacker knows (or has chosen) the corresponding plaintexts. As described above, RSA without padding is not semantically secure.

RSA has the property that the product of two ciphertexts is equal to the encryption of the product of the respective plaintexts. That is $m\_1^em\_2^e\backslash equiv\; (m\_1m\_2)^e\backslash text\{\; (mod\; \}n\backslash text\{)\}.$ Because of this multiplicative property a chosen-ciphertext attack is possible. E.g. an attacker, who wants to know the decryption of a ciphertext $c=m^e\backslash text\{\; (mod\; \}n\backslash text\{)\}$ may ask the holder of the private key to decrypt an unsuspicious-looking ciphertext $c\text{'}\; =\; c\; r^e\backslash text\{\; (mod\; \}n\backslash text\{)\}$ for some value $r$ chosen by the attacker. Because of the multiplicative property $c\text{'}$ is the encryption of $mr\backslash text\{\; (mod\; \}n\backslash text\{)\}$. Hence, if the attacker is successful with the attack, he will learn $mr\backslash text\{\; (mod\; \}n\backslash text\{)\}$ from which he can derive the message ''m'' by multiplying $mr$ with the modular inverse of $r$ modulo $n$.

Padding schemes

To avoid these problems, practical RSA implementations typically embed some form of structured, randomized padding into the value $m$ before encrypting it. This padding ensures that $m$ does not fall into the range of insecure plaintexts, and that a given message, once padded, will encrypt to one of a large number of different possible ciphertexts.

Standards such as PKCS#1 have been carefully designed to securely pad messages prior to RSA encryption. Because these schemes pad the plaintext $m$ with some number of additional bits, the size of the un-padded message M must be somewhat smaller. RSA padding schemes must be carefully designed so as to prevent sophisticated attacks which may be facilitated by a predictable message structure. Early versions of the PKCS#1 standard (up to version 1.5) used a construction that turned RSA into a semantically secure encryption scheme. This version was later found vulnerable to a practical adaptive chosen ciphertext attack. Later versions of the standard include Optimal Asymmetric Encryption Padding (OAEP), which prevents these attacks. The PKCS#1 standard also incorporates processing schemes designed to provide additional security for RSA signatures, e.g., the Probabilistic Signature Scheme for RSA (RSA-PSS).

In the common case where RSA is used to exchange symmetric keys, key encapsulation provides a simpler alternative to padding. Instead of generating a random symmetric key, padding it and then encrypting the padded version with RSA, a random integer ''m'' between 1 and ''n''-1 is generated and encrypted directly using RSA. Both the sender and receiver generate identical symmetric keys by applying the same key derivation function to ''m.''

Signing messages

Suppose Alice uses Bob's public key to send him an encrypted message. In the message, she can claim to be Alice but Bob has no way of verifying that the message was actually from Alice since anyone can use Bob's public key to send him encrypted messages. In order to verify the origin of a message, RSA can also be used to sign a message.

Suppose Alice wishes to send a signed message to Bob. She can use her own private key to do so. She produces a hash value of the message, raises it to the power of $d\backslash text\{\; mod\; \}n$ (as she does when decrypting a message), and attaches it as a "signature" to the message. When Bob receives the signed message, he uses the same hash algorithm in conjunction with Alice's public key. He raises the signature to the power of $e\backslash text\{\; mod\; \}n$ (as he does when encrypting a message), and compares the resulting hash value with the message's actual hash value. If the two agree, he knows that the author of the message was in possession of Alice's private key, and that the message has not been tampered with since.

Secure padding schemes such as RSA-PSS are as essential for the security of message signing as they are for message encryption. The same key should never be used for both encryption and signing.

Security and practical considerations

Integer factorization and RSA problem

The security of the RSA cryptosystem is based on two mathematical problems: the problem of factoring large numbers and the RSA problem. Full decryption of an RSA ciphertext is thought to be infeasible on the assumption that both of these problems are hard, i.e., no efficient algorithm exists for solving them. Providing security against ''partial'' decryption may require the addition of a secure padding scheme.

The RSA problem is defined as the task of taking $e$th roots modulo a composite $n$: recovering a value $m$ such that $c\backslash equiv\; m^e\backslash text\{\; (mod\; \}n\backslash text\{)\}$, where $(n,\; e)$ is an RSA public key and $c$ is an RSA ciphertext. Currently the most promising approach to solving the RSA problem is to factor the modulus $n$. With the ability to recover prime factors, an attacker can compute the secret exponent $d$ from a public key $(n,\; e)$, then decrypt $c$ using the standard procedure. To accomplish this, an attacker factors $n$ into $p$ and $q$, and computes $(p-1)(q-1)$ which allows the determination of $d$ from $e$. No polynomial-time method for factoring large integers on a classical computer has yet been found, but it has not been proven that none exists. See integer factorization for a discussion of this problem. Rivest, Shamir and Adleman have shown that finding ''d'' from ''n'' and ''e'' is equally hard as factoring ''n'' into ''p'' and ''q''. However, this proof does not imply that inverting RSA is equally hard as factoring.

, the largest (known) number factored by a general-purpose factoring algorithm was 768 bits long (see RSA-768), using a state-of-the-art distributed implementation. RSA keys are typically 1024–2048 bits long. Some experts believe that 1024-bit keys may become breakable in the near future (though this is disputed); few see any way that 4096-bit keys could be broken in the foreseeable future. Therefore, it is generally presumed that RSA is secure if $n$ is sufficiently large. If $n$ is 300 bits or shorter, it can be factored in a few hours on a personal computer, using software already freely available. Keys of 512 bits have been shown to be practically breakable in 1999 when RSA-155 was factored by using several hundred computers and are now factored in a few weeks using common hardware. A theoretical hardware device named TWIRL and described by Shamir and Tromer in 2003 called into question the security of 1024 bit keys. It is currently recommended that $n$ be at least 2048 bits long.

In 1994, Peter Shor showed that a quantum computer (if one could ever be practically created for the purpose) would be able to factor in polynomial time, breaking RSA.

Key generation

Finding the large primes ''p'' and ''q'' is usually done by testing random numbers of the right size with probabilistic primality tests which quickly eliminate virtually all non-primes.

Numbers ''p'' and ''q'' should not be 'too close', lest the Fermat factorization for ''n'' be successful, if ''p'' − ''q'', for instance is less than 2''n''^1/4 (which for even small 1024-bit values of ''n'' is 3×10⁷⁷) solving for ''p'' and ''q'' is trivial. Furthermore, if either ''p'' − 1 or ''q'' − 1 has only small prime factors, ''n'' can be factored quickly by Pollard's ''p'' − 1 algorithm, and these values of ''p'' or ''q'' should therefore be discarded as well.

It is important that the private key ''d'' be large enough. Michael J. Wiener showed that if ''p'' is between ''q'' and 2''q'' (which is quite typical) and ''d'' < ''n''^1/4/3, then ''d'' can be computed efficiently from ''n'' and ''e''.

There is no known attack against small public exponents such as ''e'' = 3, provided that proper padding is used. However, when no padding is used, or when the padding is improperly implemented, small public exponents have a greater risk of leading to an attack, such as the unpadded plaintext vulnerability listed above. 65537 is a commonly used value for ''e''. This value can be regarded as a compromise between avoiding potential small exponent attacks and still allowing efficient encryptions (or signature verification). The NIST Special Publication on Computer Security (SP 800-78 Rev 1 of August 2007) does not allow public exponents ''e'' smaller than 65537, but does not state a reason for this restriction.

This procedure raises additional security issues. For instance, it is of utmost importance to use a strong random number generator for the symmetric key, because otherwise Eve (an eavesdropper wanting to see what was sent) could bypass RSA by guessing the symmetric key.

Timing attacks

Kocher described a new attack on RSA in 1995: if the attacker Eve knows Alice's hardware in sufficient detail and is able to measure the decryption times for several known ciphertexts, she can deduce the decryption key $d$ quickly. This attack can also be applied against the RSA signature scheme. In 2003, Boneh and Brumley demonstrated a more practical attack capable of recovering RSA factorizations over a network connection (e.g., from a Secure Socket Layer (SSL)-enabled webserver). This attack takes advantage of information leaked by the Chinese remainder theorem optimization used by many RSA implementations.

One way to thwart these attacks is to ensure that the decryption operation takes a constant amount of time for every ciphertext. However, this approach can significantly reduce performance. Instead, most RSA implementations use an alternate technique known as cryptographic blinding. RSA blinding makes use of the multiplicative property of RSA. Instead of computing $c^d\backslash text\{\; (mod\; \}n\backslash text\{)\}$, Alice first chooses a secret random value $r$ and computes $(r^e\; c)^d\backslash text\{\; (mod\; \}n\backslash text\{)\}$. The result of this computation after applying Euler's Theorem is $r\; c^d\backslash text\{\; (mod\; \}n\backslash text\{)\}$ and so the effect of $r$ can be removed by multiplying by its inverse. A new value of $r$ is chosen for each ciphertext. With blinding applied, the decryption time is no longer correlated to the value of the input ciphertext and so the timing attack fails.

Adaptive chosen ciphertext attacks

In 1998, Daniel Bleichenbacher described the first practical adaptive chosen ciphertext attack, against RSA-encrypted messages using the PKCS #1 v1 padding scheme (a padding scheme randomizes and adds structure to an RSA-encrypted message, so it is possible to determine whether a decrypted message is valid.) Due to flaws with the PKCS #1 scheme, Bleichenbacher was able to mount a practical attack against RSA implementations of the Secure Socket Layer protocol, and to recover session keys. As a result of this work, cryptographers now recommend the use of provably secure padding schemes such as Optimal Asymmetric Encryption Padding, and RSA Laboratories has released new versions of PKCS #1 that are not vulnerable to these attacks.

Side-channel analysis attacks

A side-channel attack using branch prediction analysis (BPA) has been described. Many processors use a branch predictor to determine whether a conditional branch in the instruction flow of a program is likely to be taken or not. Often these processors also implement simultaneous multithreading (SMT). Branch prediction analysis attacks use a spy process to discover (statistically) the private key when processed with these processors.

Simple Branch Prediction Analysis (SBPA) claims to improve BPA in a non-statistical way. In their paper, "On the Power of Simple Branch Prediction Analysis", the authors of SBPA (Onur Aciicmez and Cetin Kaya Koc) claim to have discovered 508 out of 512 bits of an RSA key in 10 iterations.

A power fault attack on RSA implementations has been described in 2010. The authors recovered the key by varying the CPU power voltage outside limits; this caused multiple power faults on the server.

Proofs of correctness

Concise proof using Euler's Theorem

To show that a message encrypted with ''e'' can be decrypted with ''d'' we need to prove

:$m\; \backslash equiv\; (m^e)^d\backslash text\{\; (mod\; \}n\backslash text\{)\}$

i.e.

: $m\; \backslash equiv\; m^\{ed\}\backslash text\{\; (mod\; \}n\backslash text\{)\}.$

Now, since $ed\; =\; 1\; +\; k\backslash varphi(n)$,

: $m^\{ed\}\; \backslash equiv\; m^\{1\; +\; k\backslash varphi(n)\}\; \backslash equiv\; m\; (m^\{\backslash varphi(n)\})^\{k\}\; \backslash equiv\; m\backslash text\{\; (mod\; \}n\backslash text\{)\}.$

The last congruence directly follows from Euler's theorem when $m$ is relatively prime to $n$.

Proof using Fermat's Little Theorem and Chinese Remainder Theorem

Another way to prove the correctness of RSA is based on Fermat's little theorem. This theorem states that if ''p'' is prime and ''p'' does not divide ''a'' then : $a^\{(p-1)\}\; \backslash equiv\; 1\backslash text\{\; (mod\; \}p\backslash text\{)\}.$

In RSA, the modulus $n\; =\; p\; q$ is a product of two primes ''p'' and ''q''. The public key ''e'' and private key ''d'' satisfy : $e\; d\; \backslash equiv\; 1\backslash text\{\; (mod\; \}(p-1)(q-1)\backslash text\{)\}.$ Therefore, there exists an integer ''h'', such that : $e\; d\; -\; 1\; =\; h(p-1)(q-1).$

We can then continue to calculate : $\backslash left(m^e\backslash right)^d\; \backslash equiv\; m^\{e\; d\}\; \backslash equiv\; m^\{(e\; d\; -\; 1)\}m\; \backslash equiv\; m^\{h(p-1)(q-1)\}m\; \backslash equiv\; 1^\{h(q-1)\}m\backslash equiv\; m\backslash text\{\; (mod\; \}p\backslash text\{)\}.$

And likewise for ''q'' : $\backslash left(m^e\backslash right)^d\; \backslash equiv\; m^\{e\; d\}\; \backslash equiv\; m^\{(e\; d\; -\; 1)\}m\; \backslash equiv\; m^\{h(p-1)(q-1)\}m\; \backslash equiv\; 1^\{h(p-1)\}m\backslash equiv\; m\backslash text\{\; (mod\; \}q\backslash text\{)\}.$

If ''p'' and ''q'' are coprime, $a\backslash equiv\; b\backslash text\{\; (mod\; \}p\backslash text\{)\}$ and $a\backslash equiv\; b\backslash text\{\; (mod\; \}q\backslash text\{)\}$ then the Chinese remainder theorem implies $a\backslash equiv\; b\backslash text\{\; (mod\; \}pq\backslash text\{)\}$. Hence : $\backslash left(m^e\backslash right)^d\; \backslash equiv\; m\backslash text\{\; (mod\; \}pq\backslash text\{)\}.$

See also

Public-key cryptography

Encryption

Key exchange

Diffie-Hellman key exchange

Key management

Cryptographic key length

Computational complexity theory

Notes

References

External links

The Original RSA Patent as filed with the U.S. Patent Office by Rivest; Ronald L. (Belmont, MA), Shamir; Adi (Cambridge, MA), Adleman; Leonard M. (Arlington, MA), December 14, 1977, .

PKCS #1: RSA Cryptography Standard (RSA Laboratories website)

* The ''PKCS #1'' standard ''"provides recommendations for the implementation of public-key cryptography based on the RSA algorithm, covering the following aspects: cryptographic primitives; encryption schemes; signature schemes with appendix; ASN.1 syntax for representing keys and for identifying the schemes"''.

Thorough walk through of RSA

Prime Number Hide-And-Seek: How the RSA Cipher Works

Menezes, Oorschot, Vanstone, Scott: ''Handbook of Applied Cryptography'' (free PDF downloads), see Chapter 8

Onur Aciicmez, Cetin Kaya Koc, Jean-Pierre Seifert: ''On the Power of Simple Branch Prediction Analysis''

A New Vulnerability In RSA Cryptography, CAcert NEWS Blog

Example of an RSA implementation with PKCS#1 padding (GPL source code)

Kocher's article about timing attacks

Online RSA encryption application

An animated explanation of RSA with its mathematical background by CrypTool

Category:Public-key cryptography Category:Asymmetric-key cryptosystems Category:Electronic commerce

ar:خوارزمية آر إس إيه bg:RSA ca:RSA cs:RSA da:RSA de:RSA-Kryptosystem et:RSA (algoritm) el:RSA es:RSA eo:RSA eu:RSA fa:آراس‌ای fr:Rivest Shamir Adleman gl:RSA ko:RSA 암호 hr:RSA id:RSA is:RSA it:RSA he:RSA ka:RSA ალგორითმი lv:RSA šifrēšanas algoritms lt:RSA hu:RSA-eljárás nl:RSA (cryptografie) ja:RSA暗号 no:RSA pl:RSA (kryptografia) pt:RSA ro:RSA ru:RSA simple:RSA sl:RSA sr:RSA fi:RSA sv:RSA th:RSA tr:RSA uk:RSA vi:RSA (mã hóa) zh:RSA加密演算法

:''For other persons named Christopher Young, see Christopher Young (disambiguation)''

name	Christopher Young
background	non_performing_personnel
birth name	Robert Gilchrist Ilsley Young
born	Red Bank, New Jersey, USA
occupation	Composer
genre	Film score
years active	1982–present
website	http://www.christopher-young.com/ }}

Christopher Young (born April 28, 1958) is an American music composer for both film and television.

Many of his music compositions are for horror films, including ''Hellraiser'', ''Tales from the Hood'', ''A Nightmare on Elm Street 2: Freddy's Revenge'', ''Urban Legend'', and ''Drag Me to Hell''. Other works include ''Lucky You'' and ''Spider-Man 3'', for which he received the Film & TV Music Award for Best Score for a Dramatic Feature Film. He also made three cameo appearances in ''Spider-Man 3''.

Christopher Young was honored with the prestigious Richard Kirk award at the 2008 BMI Film and TV Awards. The award is given annually to a composer who has made significant contributions to film and television music.

Life and career

Young was born in Red Bank, New Jersey, USA. He graduated from Hampshire College in Massachusetts with a Bachelor of Arts in music, and then completed his post-graduate work at North Texas State University. In 1980, he moved to Los Angeles. Originally a jazz drummer, when he heard some of Bernard Herrmann's works he decided to become a film composer. He studied at the UCLA Film School under the famous David Raksin. He later taught at the Thornton School of Music of the University of Southern California.

Filmography

Priest

When in Rome

Love Happens

Drag Me to Hell

The Vanishment

The Uninvited

Sleepwalking

Untraceable

Spider-Man 3

Lucky You

Ghost Rider

Entrapment

Dark Ride (Themes Only)

The Grudge 2

The Exorcism of Emily Rose

At the Dusk (Incomplete Score)

Unfinished Life (Partially Used Score)

Miss Congeniality 2: Armed and Fabulous

Beauty Shop

Bright Angel

The Grudge

Hide and Seek (Incomplete scores)

Something the Lord Made

Spider-Man 2 (Additional scores)

Something's Gotta Give

Runaway Jury

The Devil and Daniel Webster

The Core

Rounders

Hellbound: Hellraiser 2

Shade

Set It Off

The Tower

The Country Bears

Murder in the First

Madison (Themes only)

The Warden

The Shipping News

Dragonfly

Scenes of the Crime

Bandits

Rapid Fire

Copycat

The Glass House

Swordfish

Sweet November

The Gift

The Big Kahuna

Wonder Boys

Bless the Child

Virtuosity

The Fly II

Hellraiser

Hard Rain

Flowers in the Attic

A Nightmare on Elm Street 2: Freddy's Revenge

The Dark Half

Hider in the House

Creation

Deathstalker II

References

External links

Category:1957 births Category:American film score composers Category:American television composers Category:Hampshire College alumni Category:Living people Category:People from Red Bank, New Jersey Category:University of North Texas alumni Category:UCLA Film School alumni Category:Thornton School of Music faculty

ar:كريستوفر يونغ da:Christopher Young de:Christopher Young es:Christopher Young fr:Christopher Young id:Christopher Young it:Christopher Young nl:Christopher Young ja:クリストファー・ヤング pt:Christopher Young ru:Янг, Кристофер sv:Christopher Young