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RFC2437 - PKCS #1: RSA Cryptography Specifications Version 2.0

王朝other·作者佚名  2008-05-31
窄屏简体版  字體: |||超大  

Network Working Group B. Kaliski

Request for Comments: 2437 J. Staddon

Obsoletes: 2313 RSA Laboratories

Category: Informational October 1998

PKCS #1: RSA Cryptography Specifications

Version 2.0

Status of this Memo

This memo provides information for the Internet community. It does

not specify an Internet standard of any kind. Distribution of this

memo is unlimited.

Copyright Notice

Copyright (C) The Internet Society (1998). All Rights Reserved.

Table of Contents

1. IntrodUCtion.....................................2

1.1 Overview.........................................3

2. Notation.........................................3

3. Key types........................................5

3.1 RSA public key...................................5

3.2 RSA private key..................................5

4. Data conversion primitives.......................6

4.1 I2OSP............................................6

4.2 OS2IP............................................7

5. Cryptographic primitives.........................8

5.1 Encryption and decryption primitives.............8

5.1.1 RSAEP............................................8

5.1.2 RSADP............................................9

5.2 Signature and verification primitives...........10

5.2.1 RSASP1..........................................10

5.2.2 RSAVP1..........................................11

6. Overview of schemes.............................11

7. Encryption schemes..............................12

7.1 RSAES-OAEP......................................13

7.1.1 Encryption operation............................13

7.1.2 Decryption operation............................14

7.2 RSAES-PKCS1-v1_5................................15

7.2.1 Encryption operation............................17

7.2.2 Decryption operation............................17

8. Signature schemes with appendix.................18

8.1 RSASSA-PKCS1-v1_5...............................19

8.1.1 Signature generation operation..................20

8.1.2 Signature verification operation................21

9. Encoding methods................................22

9.1 Encoding methods for encryption.................22

9.1.1 EME-OAEP........................................22

9.1.2 EME-PKCS1-v1_5..................................24

9.2 Encoding methods for signatures with appendix...26

9.2.1 EMSA-PKCS1-v1_5.................................26

10. Auxiliary Functions.............................27

10.1 Hash Functions..................................27

10.2 Mask Generation Functions.......................28

10.2.1 MGF1............................................28

11. ASN.1 syntax....................................29

11.1 Key representation..............................29

11.1.1 Public-key syntax...............................30

11.1.2 Private-key syntax..............................30

11.2 Scheme identification...........................31

11.2.1 Syntax for RSAES-OAEP...........................31

11.2.2 Syntax for RSAES-PKCS1-v1_5.....................32

11.2.3 Syntax for RSASSA-PKCS1-v1_5....................33

12 Patent Statement................................33

12.1 Patent statement for the RSA algorithm..........34

13. Revision history................................35

14. References......................................35

Security Considerations.........................37

Acknowledgements................................37

Authors' Addresses..............................38

Full Copyright Statement........................39

1. Introduction

This memo is the successor to RFC2313. This document provides

recommendations for the implementation of public-key cryptography

based on the RSA algorithm [18], covering the following aspects:

-cryptographic primitives

-encryption schemes

-signature schemes with appendix

-ASN.1 syntax for representing keys and for identifying the

schemes

The recommendations are intended for general application within

computer and communications systems, and as such include a fair

amount of flexibility. It is eXPected that application standards

based on these specifications may include additional constraints. The

recommendations are intended to be compatible with draft standards

currently being developed by the ANSI X9F1 [1] and IEEE P1363 working

groups [14]. This document supersedes PKCS #1 version 1.5 [20].

Editor's note. It is expected that subsequent versions of PKCS #1 may

cover other aspects of the RSA algorithm such as key size, key

generation, key validation, and signature schemes with message

recovery.

1.1 Overview

The organization of this document is as follows:

-Section 1 is an introduction.

-Section 2 defines some notation used in this document.

-Section 3 defines the RSA public and private key types.

-Sections 4 and 5 define several primitives, or basic mathematical

operations. Data conversion primitives are in Section 4, and

cryptographic primitives (encryption-decryption,

signature-verification) are in Section 5.

-Section 6, 7 and 8 deal with the encryption and signature schemes

in this document. Section 6 gives an overview. Section 7 defines

an OAEP-based [2] encryption scheme along with the method found

in PKCS #1 v1.5. Section 8 defines a signature scheme with

appendix; the method is identical to that of PKCS #1 v1.5.

-Section 9 defines the encoding methods for the encryption and

signature schemes in Sections 7 and 8.

-Section 10 defines the hash functions and the mask generation

function used in this document.

-Section 11 defines the ASN.1 syntax for the keys defined in

Section 3 and the schemes gives in Sections 7 and 8.

-Section 12 outlines the revision history of PKCS #1.

-Section 13 contains references to other publications and

standards.

2. Notation

(n, e) RSA public key

c ciphertext representative, an integer between 0 and n-1

C ciphertext, an octet string

d private exponent

dP p's exponent, a positive integer such that:

e(dP)\equiv 1 (mod(p-1))

dQ q's exponent, a positive integer such that:

e(dQ)\equiv 1 (mod(q-1))

e public exponent

EM encoded message, an octet string

emLen intended length in octets of an encoded message

H hash value, an output of Hash

Hash hash function

hLen output length in octets of hash function Hash

K RSA private key

k length in octets of the modulus

l intended length of octet string

lcm(.,.) least common multiple of two

nonnegative integers

m message representative, an integer between

0 and n-1

M message, an octet string

MGF mask generation function

n modulus

P encoding parameters, an octet string

p,q prime factors of the modulus

qInv CRT coefficient, a positive integer less

than p such: q(qInv)\equiv 1 (mod p)

s signature representative, an integer

between 0 and n-1

S signature, an octet string

x a nonnegative integer

X an octet string corresponding to x

\xor bitwise exclusive-or of two octet strings

\lambda(n) lcm(p-1, q-1), where n = pq

concatenation operator

. octet length operator

3. Key types

Two key types are employed in the primitives and schemes defined in

this document: RSA public key and RSA private key. Together, an RSA

public key and an RSA private key form an RSA key pair.

3.1 RSA public key

For the purposes of this document, an RSA public key consists of two

components:

n, the modulus, a nonnegative integer

e, the public exponent, a nonnegative integer

In a valid RSA public key, the modulus n is a product of two odd

primes p and q, and the public exponent e is an integer between 3 and

n-1 satisfying gcd (e, \lambda(n)) = 1, where \lambda(n) = lcm (p-

1,q-1). A recommended syntax for interchanging RSA public keys

between implementations is given in Section 11.1.1; an

implementation's internal representation may differ.

3.2 RSA private key

For the purposes of this document, an RSA private key may have either

of two representations.

1. The first representation consists of the pair (n, d), where the

components have the following meanings:

n, the modulus, a nonnegative integer

d, the private exponent, a nonnegative integer

2. The second representation consists of a quintuple (p, q, dP, dQ,

qInv), where the components have the following meanings:

p, the first factor, a nonnegative integer

q, the second factor, a nonnegative integer

dP, the first factor's exponent, a nonnegative integer

dQ, the second factor's exponent, a nonnegative integer

qInv, the CRT coefficient, a nonnegative integer

In a valid RSA private key with the first representation, the modulus

n is the same as in the corresponding public key and is the product

of two odd primes p and q, and the private exponent d is a positive

integer less than n satisfying:

ed \equiv 1 (mod \lambda(n))

where e is the corresponding public exponent and \lambda(n) is as

defined above.

In a valid RSA private key with the second representation, the two

factors p and q are the prime factors of the modulus n, the exponents

dP and dQ are positive integers less than p and q respectively

satisfying

e(dP)\equiv 1(mod(p-1))

e(dQ)\equiv 1(mod(q-1)),

and the CRT coefficient qInv is a positive integer less than p

satisfying:

q(qInv)\equiv 1 (mod p).

A recommended syntax for interchanging RSA private keys between

implementations, which includes components from both representations,

is given in Section 11.1.2; an implementation's internal

representation may differ.

4. Data conversion primitives

Two data conversion primitives are employed in the schemes defined in

this document:

I2OSP: Integer-to-Octet-String primitive

OS2IP: Octet-String-to-Integer primitive

For the purposes of this document, and consistent with ASN.1 syntax, an

octet string is an ordered sequence of octets (eight-bit bytes). The

sequence is indexed from first (conventionally, leftmost) to last

(rightmost). For purposes of conversion to and from integers, the first

octet is considered the most significant in the following conversion

primitives

4.1 I2OSP

I2OSP converts a nonnegative integer to an octet string of a specified

length.

I2OSP (x, l)

Input:

x nonnegative integer to be converted

l intended length of the resulting octet string

Output:

X corresponding octet string of length l; or

"integer too large"

Steps:

1. If x>=256^l, output "integer too large" and stop.

2. Write the integer x in its unique l-digit representation base 256:

x = x_{l-1}256^{l-1} + x_{l-2}256^{l-2} +... + x_1 256 + x_0

where 0 <= x_i < 256 (note that one or more leading digits will be

zero if x < 256^{l-1}).

3. Let the octet X_i have the value x_{l-i} for 1 <= i <= l. Output

the octet string:

X = X_1 X_2 ... X_l.

4.2 OS2IP

OS2IP converts an octet string to a nonnegative integer.

OS2IP (X)

Input:

X octet string to be converted

Output:

x corresponding nonnegative integer

Steps:

1. Let X_1 X_2 ... X_l be the octets of X from first to last, and

let x{l-i} have value X_i for 1<= i <= l.

2. Let x = x{l-1} 256^{l-1} + x_{l-2} 256^{l-2} +...+ x_1 256 + x_0.

3. Output x.

5. Cryptographic primitives

Cryptographic primitives are basic mathematical operations on which

cryptographic schemes can be built. They are intended for

implementation in hardware or as software modules, and are not

intended to provide security apart from a scheme.

Four types of primitive are specified in this document, organized in

pairs: encryption and decryption; and signature and verification.

The specifications of the primitives assume that certain conditions

are met by the inputs, in particular that public and private keys are

valid.

5.1 Encryption and decryption primitives

An encryption primitive produces a ciphertext representative from a

message representative under the control of a public key, and a

decryption primitive recovers the message representative from the

ciphertext representative under the control of the corresponding

private key.

One pair of encryption and decryption primitives is employed in the

encryption schemes defined in this document and is specified here:

RSAEP/RSADP. RSAEP and RSADP involve the same mathematical operation,

with different keys as input.

The primitives defined here are the same as in the draft IEEE P1363

and are compatible with PKCS #1 v1.5.

The main mathematical operation in each primitive is exponentiation.

5.1.1 RSAEP

RSAEP((n, e), m)

Input:

(n, e) RSA public key

m message representative, an integer between 0 and n-1

Output:

c ciphertext representative, an integer between 0 and n-1;

or "message representative out of range"

Assumptions: public key (n, e) is valid

Steps:

1. If the message representative m is not between 0 and n-1, output

message representative out of range and stop.

2. Let c = m^e mod n.

3. Output c.

5.1.2 RSADP

RSADP (K, c)

Input:

K RSA private key, where K has one of the following forms

-a pair (n, d)

-a quintuple (p, q, dP, dQ, qInv)

c ciphertext representative, an integer between 0 and n-1

Output:

m message representative, an integer between 0 and n-1; or

"ciphertext representative out of range"

Assumptions: private key K is valid

Steps:

1. If the ciphertext representative c is not between 0 and n-1,

output "ciphertext representative out of range" and stop.

2. If the first form (n, d) of K is used:

2.1 Let m = c^d mod n. Else, if the second form (p, q, dP,

dQ, qInv) of K is used:

2.2 Let m_1 = c^dP mod p.

2.3 Let m_2 = c^dQ mod q.

2.4 Let h = qInv ( m_1 - m_2 ) mod p.

2.5 Let m = m_2 + hq.

3. Output m.

5.2 Signature and verification primitives

A signature primitive produces a signature representative from a

message representative under the control of a private key, and a

verification primitive recovers the message representative from the

signature representative under the control of the corresponding

public key. One pair of signature and verification primitives is

employed in the signature schemes defined in this document and is

specified here: RSASP1/RSAVP1.

The primitives defined here are the same as in the draft IEEE P1363

and are compatible with PKCS #1 v1.5.

The main mathematical operation in each primitive is exponentiation,

as in the encryption and decryption primitives of Section 5.1. RSASP1

and RSAVP1 are the same as RSADP and RSAEP except for the names of

their input and output arguments; they are distinguished as they are

intended for different purposes.

5.2.1 RSASP1

RSASP1 (K, m)

Input:

K RSA private key, where K has one of the following

forms:

-a pair (n, d)

-a quintuple (p, q, dP, dQ, qInv)

m message representative, an integer between 0 and n-1

Output:

s signature representative, an integer between 0 and

n-1, or "message representative out of range"

Assumptions:

private key K is valid

Steps:

1. If the message representative m is not between 0 and n-1, output

"message representative out of range" and stop.

2. If the first form (n, d) of K is used:

2.1 Let s = m^d mod n. Else, if the second form (p, q, dP,

dQ, qInv) of K is used:

2.2 Let s_1 = m^dP mod p.

2.3 Let s_2 = m^dQ mod q.

2.4 Let h = qInv ( s_1 - s_2 ) mod p.

2.5 Let s = s_2 + hq.

3. Output S.

5.2.2 RSAVP1

RSAVP1 ((n, e), s)

Input:

(n, e) RSA public key

s signature representative, an integer between 0 and n-1

Output:

m message representative, an integer between 0 and n-1;

or "invalid"

Assumptions:

public key (n, e) is valid

Steps:

1. If the signature representative s is not between 0 and n-1, output

"invalid" and stop.

2. Let m = s^e mod n.

3. Output m.

6. Overview of schemes

A scheme combines cryptographic primitives and other techniques to

achieve a particular security goal. Two types of scheme are specified

in this document: encryption schemes and signature schemes with

appendix.

The schemes specified in this document are limited in scope in that

their operations consist only of steps to process data with a key,

and do not include steps for oBTaining or validating the key. Thus,

in addition to the scheme operations, an application will typically

include key management operations by which parties may select public

and private keys for a scheme operation. The specific additional

operations and other details are outside the scope of this document.

As was the case for the cryptographic primitives (Section 5), the

specifications of scheme operations assume that certain conditions

are met by the inputs, in particular that public and private keys are

valid. The behavior of an implementation is thus unspecified when a

key is invalid. The impact of such unspecified behavior depends on

the application. Possible means of addressing key validation include

explicit key validation by the application; key validation within the

public-key infrastructure; and assignment of liability for operations

performed with an invalid key to the party who generated the key.

7. Encryption schemes

An encryption scheme consists of an encryption operation and a

decryption operation, where the encryption operation produces a

ciphertext from a message with a recipient's public key, and the

decryption operation recovers the message from the ciphertext with

the recipient's corresponding private key.

An encryption scheme can be employed in a variety of applications. A

typical application is a key establishment protocol, where the

message contains key material to be delivered confidentially from one

party to another. For instance, PKCS #7 [21] employs such a protocol

to deliver a content-encryption key from a sender to a recipient; the

encryption schemes defined here would be suitable key-encryption

algorithms in that context.

Two encryption schemes are specified in this document: RSAES-OAEP and

RSAES-PKCS1-v1_5. RSAES-OAEP is recommended for new applications;

RSAES-PKCS1-v1_5 is included only for compatibility with existing

applications, and is not recommended for new applications.

The encryption schemes given here follow a general model similar to

that employed in IEEE P1363, by combining encryption and decryption

primitives with an encoding method for encryption. The encryption

operations apply a message encoding operation to a message to produce

an encoded message, which is then converted to an integer message

representative. An encryption primitive is applied to the message

representative to produce the ciphertext. Reversing this, the

decryption operations apply a decryption primitive to the ciphertext

to recover a message representative, which is then converted to an

octet string encoded message. A message decoding operation is applied

to the encoded message to recover the message and verify the

correctness of the decryption.

7.1 RSAES-OAEP

RSAES-OAEP combines the RSAEP and RSADP primitives (Sections 5.1.1

and 5.1.2) with the EME-OAEP encoding method (Section 9.1.1) EME-OAEP

is based on the method found in [2]. It is compatible with the IFES

scheme defined in the draft P1363 where the encryption and decryption

primitives are IFEP-RSA and IFDP-RSA and the message encoding method

is EME-OAEP. RSAES-OAEP can operate on messages of length up to k-2-

2hLen octets, where hLen is the length of the hash function output

for EME-OAEP and k is the length in octets of the recipient's RSA

modulus. Assuming that the hash function in EME-OAEP has appropriate

properties, and the key size is sufficiently large, RSAEP-OAEP

provides "plaintext-aware encryption," meaning that it is

computationally infeasible to obtain full or partial information

about a message from a ciphertext, and computationally infeasible to

generate a valid ciphertext without knowing the corresponding

message. Therefore, a chosen-ciphertext attack is ineffective

against a plaintext-aware encryption scheme such as RSAES-OAEP.

Both the encryption and the decryption operations of RSAES-OAEP take

the value of the parameter string P as input. In this version of PKCS

#1, P is an octet string that is specified explicitly. See Section

11.2.1 for the relevant ASN.1 syntax. We briefly note that to receive

the full security benefit of RSAES-OAEP, it should not be used in a

protocol involving RSAES-PKCS1-v1_5. It is possible that in a

protocol on which both encryption schemes are present, an adaptive

chosen ciphertext attack such as [4] would be useful.

Both the encryption and the decryption operations of RSAES-OAEP take

the value of the parameter string P as input. In this version of PKCS

#1, P is an octet string that is specified explicitly. See Section

11.2.1 for the relevant ASN.1 syntax.

7.1.1 Encryption operation

RSAES-OAEP-ENCRYPT ((n, e), M, P)

Input:

(n, e) recipient's RSA public key

M message to be encrypted, an octet string of length at

most k-2-2hLen, where k is the length in octets of the

modulus n and hLen is the length in octets of the hash

function output for EME-OAEP

P encoding parameters, an octet string that may be empty

Output:

C ciphertext, an octet string of length k; or "message too

long"

Assumptions: public key (n, e) is valid

Steps:

1. Apply the EME-OAEP encoding operation (Section 9.1.1.2) to the

message M and the encoding parameters P to produce an encoded message

EM of length k-1 octets:

EM = EME-OAEP-ENCODE (M, P, k-1)

If the encoding operation outputs "message too long," then output

"message too long" and stop.

2. Convert the encoded message EM to an integer message

representative m: m = OS2IP (EM)

3. Apply the RSAEP encryption primitive (Section 5.1.1) to the public

key (n, e) and the message representative m to produce an integer

ciphertext representative c:

c = RSAEP ((n, e), m)

4. Convert the ciphertext representative c to a ciphertext C of

length k octets: C = I2OSP (c, k)

5. Output the ciphertext C.

7.1.2 Decryption operation

RSAES-OAEP-DECRYPT (K, C, P)

Input:

K recipient's RSA private key

C ciphertext to be decrypted, an octet string of length

k, where k is the length in octets of the modulus n

P encoding parameters, an octet string that may be empty

Output:

M message, an octet string of length at most k-2-2hLen,

where hLen is the length in octets of the hash

function output for EME-OAEP; or "decryption error"

Steps:

1. If the length of the ciphertext C is not k octets, output

"decryption error" and stop.

2. Convert the ciphertext C to an integer ciphertext representative

c: c = OS2IP (C).

3. Apply the RSADP decryption primitive (Section 5.1.2) to the

private key K and the ciphertext representative c to produce an

integer message representative m:

m = RSADP (K, c)

If RSADP outputs "ciphertext out of range," then output "decryption

error" and stop.

4. Convert the message representative m to an encoded message EM of

length k-1 octets: EM = I2OSP (m, k-1)

If I2OSP outputs "integer too large," then output "decryption error"

and stop.

5. Apply the EME-OAEP decoding operation to the encoded message EM

and the encoding parameters P to recover a message M:

M = EME-OAEP-DECODE (EM, P)

If the decoding operation outputs "decoding error," then output

"decryption error" and stop.

6. Output the message M.

Note. It is important that the error messages output in steps 4 and 5

be the same, otherwise an adversary may be able to extract useful

information from the type of error message received. Error message

information is used to mount a chosen-ciphertext attack on PKCS #1

v1.5 encrypted messages in [4].

7.2 RSAES-PKCS1-v1_5

RSAES-PKCS1-v1_5 combines the RSAEP and RSADP primitives with the

EME-PKCS1-v1_5 encoding method. It is the same as the encryption

scheme in PKCS #1 v1.5. RSAES-PKCS1-v1_5 can operate on messages of

length up to k-11 octets, although care should be taken to avoid

certain attacks on low-exponent RSA due to Coppersmith, et al. when

long messages are encrypted (see the third bullet in the notes below

and [7]).

RSAES-PKCS1-v1_5 does not provide "plaintext aware" encryption. In

particular, it is possible to generate valid ciphertexts without

knowing the corresponding plaintexts, with a reasonable probability

of success. This ability can be exploited in a chosen ciphertext

attack as shown in [4]. Therefore, if RSAES-PKCS1-v1_5 is to be used,

certain easily implemented countermeasures should be taken to thwart

the attack found in [4]. The addition of structure to the data to be

encoded, rigorous checking of PKCS #1 v1.5 conformance and other

redundancy in decrypted messages, and the consolidation of error

messages in a client-server protocol based on PKCS #1 v1.5 can all be

effective countermeasures and don't involve changes to a PKCS #1

v1.5-based protocol. These and other countermeasures are discussed in

[5].

Notes. The following passages describe some security recommendations

pertaining to the use of RSAES-PKCS1-v1_5. Recommendations from

version 1.5 of this document are included as well as new

recommendations motivated by cryptanalytic advances made in the

intervening years.

-It is recommended that the pseudorandom octets in EME-PKCS1-v1_5 be

generated independently for each encryption process, especially if

the same data is input to more than one encryption process. Hastad's

results [13] are one motivation for this recommendation.

-The padding string PS in EME-PKCS1-v1_5 is at least eight octets

long, which is a security condition for public-key operations that

prevents an attacker from recovering data by trying all possible

encryption blocks.

-The pseudorandom octets can also help thwart an attack due to

Coppersmith et al. [7] when the size of the message to be encrypted

is kept small. The attack works on low-exponent RSA when similar

messages are encrypted with the same public key. More specifically,

in one flavor of the attack, when two inputs to RSAEP agree on a

large fraction of bits (8/9) and low-exponent RSA (e = 3) is used to

encrypt both of them, it may be possible to recover both inputs with

the attack. Another flavor of the attack is successful in decrypting

a single ciphertext when a large fraction (2/3) of the input to RSAEP

is already known. For typical applications, the message to be

encrypted is short (e.g., a 128-bit symmetric key) so not enough

information will be known or common between two messages to enable

the attack. However, if a long message is encrypted, or if part of a

message is known, then the attack may be a concern. In any case, the

RSAEP-OAEP scheme overcomes the attack.

7.2.1 Encryption operation

RSAES-PKCS1-V1_5-ENCRYPT ((n, e), M)

Input:

(n, e) recipient's RSA public key

M message to be encrypted, an octet string of length at

most k-11 octets, where k is the length in octets of the

modulus n

Output:

C ciphertext, an octet string of length k; or "message too

long"

Steps:

1. Apply the EME-PKCS1-v1_5 encoding operation (Section 9.1.2.1) to

the message M to produce an encoded message EM of length k-1 octets:

EM = EME-PKCS1-V1_5-ENCODE (M, k-1)

If the encoding operation outputs "message too long," then output

"message too long" and stop.

2. Convert the encoded message EM to an integer message

representative m: m = OS2IP (EM)

3. Apply the RSAEP encryption primitive (Section 5.1.1) to the public

key (n, e) and the message representative m to produce an integer

ciphertext representative c: c = RSAEP ((n, e), m)

4. Convert the ciphertext representative c to a ciphertext C of

length k octets: C = I2OSP (c, k)

5. Output the ciphertext C.

7.2.2 Decryption operation

RSAES-PKCS1-V1_5-DECRYPT (K, C)

Input:

K recipient's RSA private key

C ciphertext to be decrypted, an octet string of length k,

where k is the length in octets of the modulus n

Output:

M message, an octet string of length at most k-11; or

"decryption error"

Steps:

1. If the length of the ciphertext C is not k octets, output

"decryption error" and stop.

2. Convert the ciphertext C to an integer ciphertext representative

c: c = OS2IP (C).

3. Apply the RSADP decryption primitive to the private key (n, d) and

the ciphertext representative c to produce an integer message

representative m: m = RSADP ((n, d), c).

If RSADP outputs "ciphertext out of range," then output "decryption

error" and stop.

4. Convert the message representative m to an encoded message EM of

length k-1 octets: EM = I2OSP (m, k-1)

If I2OSP outputs "integer too large," then output "decryption error"

and stop.

5. Apply the EME-PKCS1-v1_5 decoding operation to the encoded message

EM to recover a message M: M = EME-PKCS1-V1_5-DECODE (EM).

If the decoding operation outputs "decoding error," then output

"decryption error" and stop.

6. Output the message M.

Note. It is important that only one type of error message is output

by EME-PKCS1-v1_5, as ensured by steps 4 and 5. If this is not done,

then an adversary may be able to use information extracted form the

type of error message received to mount a chosen-ciphertext attack

such as the one found in [4].

8. Signature schemes with appendix

A signature scheme with appendix consists of a signature generation

operation and a signature verification operation, where the signature

generation operation produces a signature from a message with a

signer's private key, and the signature verification operation

verifies the signature on the message with the signer's corresponding

public key. To verify a signature constructed with this type of

scheme it is necessary to have the message itself. In this way,

signature schemes with appendix are distinguished from signature

schemes with message recovery, which are not supported in this

document.

A signature scheme with appendix can be employed in a variety of

applications. For instance, X.509 [6] employs such a scheme to

authenticate the content of a certificate; the signature scheme with

appendix defined here would be a suitable signature algorithm in that

context. A related signature scheme could be employed in PKCS #7

[21], although for technical reasons, the current version of PKCS #7

separates a hash function from a signature scheme, which is different

than what is done here.

One signature scheme with appendix is specified in this document:

RSASSA-PKCS1-v1_5.

The signature scheme with appendix given here follows a general model

similar to that employed in IEEE P1363, by combining signature and

verification primitives with an encoding method for signatures. The

signature generation operations apply a message encoding operation to

a message to produce an encoded message, which is then converted to

an integer message representative. A signature primitive is then

applied to the message representative to produce the signature. The

signature verification operations apply a signature verification

primitive to the signature to recover a message representative, which

is then converted to an octet string. The message encoding operation

is again applied to the message, and the result is compared to the

recovered octet string. If there is a match, the signature is

considered valid. (Note that this approach assumes that the signature

and verification primitives have the message-recovery form and the

encoding method is deterministic, as is the case for RSASP1/RSAVP1

and EMSA-PKCS1-v1_5. The signature generation and verification

operations have a different form in P1363 for other primitives and

encoding methods.)

Editor's note. RSA Laboratories is investigating the possibility of

including a scheme based on the PSS encoding methods specified in

[3], which would be recommended for new applications.

8.1 RSASSA-PKCS1-v1_5

RSASSA-PKCS1-v1_5 combines the RSASP1 and RSAVP1 primitives with the

EME-PKCS1-v1_5 encoding method. It is compatible with the IFSSA

scheme defined in the draft P1363 where the signature and

verification primitives are IFSP-RSA1 and IFVP-RSA1 and the message

encoding method is EMSA-PKCS1-v1_5 (which is not defined in P1363).

The length of messages on which RSASSA-PKCS1-v1_5 can operate is

either unrestricted or constrained by a very large number, depending

on the hash function underlying the message encoding method.

Assuming that the hash function in EMSA-PKCS1-v1_5 has appropriate

properties and the key size is sufficiently large, RSASSA-PKCS1-v1_5

provides secure signatures, meaning that it is computationally

infeasible to generate a signature without knowing the private key,

and computationally infeasible to find a message with a given

signature or two messages with the same signature. Also, in the

encoding method EMSA-PKCS1-v1_5, a hash function identifier is

embedded in the encoding. Because of this feature, an adversary must

invert or find collisions of the particular hash function being used;

attacking a different hash function than the one selected by the

signer is not useful to the adversary.

8.1.1 Signature generation operation

RSASSA-PKCS1-V1_5-SIGN (K, M)

Input:

K signer's RSA private ke

M message to be signed, an octet string

Output:

S signature, an octet string of length k, where k is the

length in octets of the modulus n; "message too long" or

"modulus too short"

Steps:

1. Apply the EMSA-PKCS1-v1_5 encoding operation (Section 9.2.1) to

the message M to produce an encoded message EM of length k-1 octets:

EM = EMSA-PKCS1-V1_5-ENCODE (M, k-1)

If the encoding operation outputs "message too long," then output

"message too long" and stop. If the encoding operation outputs

"intended encoded message length too short" then output "modulus too

short".

2. Convert the encoded message EM to an integer message

representative m: m = OS2IP (EM)

3. Apply the RSASP1 signature primitive (Section 5.2.1) to the

private key K and the message representative m to produce an integer

signature representative s: s = RSASP1 (K, m)

4. Convert the signature representative s to a signature S of length

k octets: S = I2OSP (s, k)

5. Output the signature S.

8.1.2 Signature verification operation

RSASSA-PKCS1-V1_5-VERIFY ((n, e), M, S)

Input:

(n, e) signer's RSA public key

M message whose signature is to be verified, an octet string

S signature to be verified, an octet string of length k,

where k is the length in octets of the modulus n

Output: "valid signature," "invalid signature," or "message too

long", or "modulus too short"

Steps:

1. If the length of the signature S is not k octets, output "invalid

signature" and stop.

2. Convert the signature S to an integer signature representative s:

s = OS2IP (S)

3. Apply the RSAVP1 verification primitive (Section 5.2.2) to the

public key (n, e) and the signature representative s to produce an

integer message representative m:

m = RSAVP1 ((n, e), s) If RSAVP1 outputs "invalid"

then output "invalid signature" and stop.

4. Convert the message representative m to an encoded message EM of

length k-1 octets: EM = I2OSP (m, k-1)

If I2OSP outputs "integer too large," then output "invalid signature"

and stop.

5. Apply the EMSA-PKCS1-v1_5 encoding operation (Section 9.2.1) to

the message M to produce a second encoded message EM' of length k-1

octets:

EM' = EMSA-PKCS1-V1_5-ENCODE (M, k-1)

If the encoding operation outputs "message too long," then output

"message too long" and stop. If the encoding operation outputs

"intended encoded message length too short" then output "modulus too

short".

6. Compare the encoded message EM and the second encoded message EM'.

If they are the same, output "valid signature"; otherwise, output

"invalid signature."

9. Encoding methods

Encoding methods consist of operations that map between octet string

messages and integer message representatives.

Two types of encoding method are considered in this document:

encoding methods for encryption, encoding methods for signatures with

appendix.

9.1 Encoding methods for encryption

An encoding method for encryption consists of an encoding operation

and a decoding operation. An encoding operation maps a message M to a

message representative EM of a specified length; the decoding

operation maps a message representative EM back to a message. The

encoding and decoding operations are inverses.

The message representative EM will typically have some structure that

can be verified by the decoding operation; the decoding operation

will output "decoding error" if the structure is not present. The

encoding operation may also introduce some randomness, so that

different applications of the encoding operation to the same message

will produce different representatives.

Two encoding methods for encryption are employed in the encryption

schemes and are specified here: EME-OAEP and EME-PKCS1-v1_5.

9.1.1 EME-OAEP

This encoding method is parameterized by the choice of hash function

and mask generation function. Suggested hash and mask generation

functions are given in Section 10. This encoding method is based on

the method found in [2].

9.1.1.1 Encoding operation

EME-OAEP-ENCODE (M, P, emLen)

Options:

Hash hash function (hLen denotes the length in octet of the

hash function output)

MGF mask generation function

Input:

M message to be encoded, an octet string of length at most

emLen-1-2hLen

P encoding parameters, an octet string

emLen intended length in octets of the encoded message, at least

2hLen+1

Output:

EM encoded message, an octet string of length emLen;

"message too long" or "parameter string too long"

Steps:

1. If the length of P is greater than the input limitation for the

hash function (2^61-1 octets for SHA-1) then output "parameter string

too long" and stop.

2. If M > emLen-2hLen-1 then output "message too long" and stop.

3. Generate an octet string PS consisting of emLen-M-2hLen-1 zero

octets. The length of PS may be 0.

4. Let pHash = Hash(P), an octet string of length hLen.

5. Concatenate pHash, PS, the message M, and other padding to form a

data block DB as: DB = pHash PS 01 M

6. Generate a random octet string seed of length hLen.

7. Let dbMask = MGF(seed, emLen-hLen).

8. Let maskedDB = DB \xor dbMask.

9. Let seedMask = MGF(maskedDB, hLen).

10. Let maskedSeed = seed \xor seedMask.

11. Let EM = maskedSeed maskedDB.

12. Output EM.

9.1.1.2 Decoding operation EME-OAEP-DECODE (EM, P)

Options:

Hash hash function (hLen denotes the length in octet of the hash

function output)

MGF mask generation function

Input:

EM encoded message, an octet string of length at least 2hLen+1

P encoding parameters, an octet string

Output:

M recovered message, an octet string of length at most

EM-1-2hLen; or "decoding error"

Steps:

1. If the length of P is greater than the input limitation for the

hash function (2^61-1 octets for SHA-1) then output "parameter string

too long" and stop.

2. If EM < 2hLen+1, then output "decoding error" and stop.

3. Let maskedSeed be the first hLen octets of EM and let maskedDB be

the remaining EM - hLen octets.

4. Let seedMask = MGF(maskedDB, hLen).

5. Let seed = maskedSeed \xor seedMask.

6. Let dbMask = MGF(seed, EM - hLen).

7. Let DB = maskedDB \xor dbMask.

8. Let pHash = Hash(P), an octet string of length hLen.

9. Separate DB into an octet string pHash' consisting of the first

hLen octets of DB, a (possibly empty) octet string PS consisting of

consecutive zero octets following pHash', and a message M as:

DB = pHash' PS 01 M

If there is no 01 octet to separate PS from M, output "decoding

error" and stop.

10. If pHash' does not equal pHash, output "decoding error" and stop.

11. Output M.

9.1.2 EME-PKCS1-v1_5

This encoding method is the same as in PKCS #1 v1.5, Section 8:

Encryption Process.

9.1.2.1 Encoding operation

EME-PKCS1-V1_5-ENCODE (M, emLen)

Input:

M message to be encoded, an octet string of length at most

emLen-10

emLen intended length in octets of the encoded message

Output:

EM encoded message, an octet string of length emLen; or

"message too long"

Steps:

1. If the length of the message M is greater than emLen - 10 octets,

output "message too long" and stop.

2. Generate an octet string PS of length emLen-M-2 consisting of

pseudorandomly generated nonzero octets. The length of PS will be at

least 8 octets.

3. Concatenate PS, the message M, and other padding to form the

encoded message EM as:

EM = 02 PS 00 M

4. Output EM.

9.1.2.2 Decoding operation

EME-PKCS1-V1_5-DECODE (EM)

Input:

EM encoded message, an octet string of length at least 10

Output:

M recovered message, an octet string of length at most

EM-10; or "decoding error"

Steps:

1. If the length of the encoded message EM is less than 10, output

"decoding error" and stop.

2. Separate the encoded message EM into an octet string PS consisting

of nonzero octets and a message M as: EM = 02 PS 00 M.

If the first octet of EM is not 02, or if there is no 00 octet to

separate PS from M, output "decoding error" and stop.

3. If the length of PS is less than 8 octets, output "decoding error"

and stop.

4. Output M.

9.2 Encoding methods for signatures with appendix

An encoding method for signatures with appendix, for the purposes of

this document, consists of an encoding operation. An encoding

operation maps a message M to a message representative EM of a

specified length. (In future versions of this document, encoding

methods may be added that also include a decoding operation.)

One encoding method for signatures with appendix is employed in the

encryption schemes and is specified here: EMSA-PKCS1-v1_5.

9.2.1 EMSA-PKCS1-v1_5

This encoding method only has an encoding operation.

EMSA-PKCS1-v1_5-ENCODE (M, emLen)

Option:

Hash hash function (hLen denotes the length in octet of the hash

function output)

Input:

M message to be encoded

emLen intended length in octets of the encoded message, at least

T + 10, where T is the DER encoding of a certain value

computed during the encoding operation

Output:

EM encoded message, an octet string of length emLen; or "message

too long" or "intended encoded message length too short"

Steps:

1. Apply the hash function to the message M to produce a hash value

H:

H = Hash(M).

If the hash function outputs "message too long," then output "message

too long".

2. Encode the algorithm ID for the hash function and the hash value

into an ASN.1 value of type DigestInfo (see Section 11) with the

Distinguished Encoding Rules (DER), where the type DigestInfo has the

syntax

DigestInfo::=SEQUENCE{

digestAlgorithm AlgorithmIdentifier,

digest OCTET STRING }

The first field identifies the hash function and the second contains

the hash value. Let T be the DER encoding.

3. If emLen is less than T + 10 then output "intended encoded

message length too short".

4. Generate an octet string PS consisting of emLen-T-2 octets

with value FF (hexadecimal). The length of PS will be at least 8

octets.

5. Concatenate PS, the DER encoding T, and other padding to form the

encoded message EM as: EM = 01 PS 00 T

6. Output EM.

10. Auxiliary Functions

This section specifies the hash functions and the mask generation

functions that are mentioned in the encoding methods (Section 9).

10.1 Hash Functions

Hash functions are used in the operations contained in Sections 7, 8

and 9. Hash functions are deterministic, meaning that the output is

completely determined by the input. Hash functions take octet strings

of variable length, and generate fixed length octet strings. The hash

functions used in the operations contained in Sections 7, 8 and 9

should be collision resistant. This means that it is infeasible to

find two distinct inputs to the hash function that produce the same

output. A collision resistant hash function also has the desirable

property of being one-way; this means that given an output, it is

infeasible to find an input whose hash is the specified output. The

property of collision resistance is especially desirable for RSASSA-

PKCS1-v1_5, as it makes it infeasible to forge signatures. In

addition to the requirements, the hash function should yield a mask

generation function (Section 10.2) with pseudorandom output.

Three hash functions are recommended for the encoding methods in this

document: MD2 [15], MD5 [17], and SHA-1 [16]. For the EME-OAEP

encoding method, only SHA-1 is recommended. For the EMSA-PKCS1-v1_5

encoding method, SHA-1 is recommended for new applications. MD2 and

MD5 are recommended only for compatibility with existing applications

based on PKCS #1 v1.5.

The hash functions themselves are not defined here; readers are

referred to the appropriate references ([15], [17] and [16]).

Note. Version 1.5 of this document also allowed for the use of MD4 in

signature schemes. The cryptanalysis of MD4 has progressed

significantly in the intervening years. For example, Dobbertin [10]

demonstrated how to find collisions for MD4 and that the first two

rounds of MD4 are not one-way [11]. Because of these results and

others (e.g. [9]), MD4 is no longer recommended. There have also been

advances in the cryptanalysis of MD2 and MD5, although not enough to

warrant removal from existing applications. Rogier and Chauvaud [19]

demonstrated how to find collisions in a modified version of MD2. No

one has demonstrated how to find collisions for the full MD5

algorithm, although partial results have been found (e.g. [8]). For

new applications, to address these concerns, SHA-1 is preferred.

10.2 Mask Generation Functions

A mask generation function takes an octet string of variable length

and a desired output length as input, and outputs an octet string of

the desired length. There may be restrictions on the length of the

input and output octet strings, but such bounds are generally very

large. Mask generation functions are deterministic; the octet string

output is completely determined by the input octet string. The output

of a mask generation function should be pseudorandom, that is, if the

seed to the function is unknown, it should be infeasible to

distinguish the output from a truly random string. The plaintext-

awareness of RSAES-OAEP relies on the random nature of the output of

the mask generation function, which in turn relies on the random

nature of the underlying hash.

One mask generation function is recommended for the encoding methods

in this document, and is defined here: MGF1, which is based on a hash

function. Future versions of this document may define other mask

generation functions.

10.2.1 MGF1

MGF1 is a Mask Generation Function based on a hash function.

MGF1 (Z, l)

Options:

Hash hash function (hLen denotes the length in octets of the hash

function output)

Input:

Z seed from which mask is generated, an octet string

l intended length in octets of the mask, at most 2^32(hLen)

Output:

mask mask, an octet string of length l; or "mask too long"

Steps:

1.If l > 2^32(hLen), output "mask too long" and stop.

2.Let T be the empty octet string.

3.For counter from 0 to \lceil{l / hLen}\rceil-1, do the following:

a.Convert counter to an octet string C of length 4 with the primitive

I2OSP: C = I2OSP (counter, 4)

b.Concatenate the hash of the seed Z and C to the octet string T: T =

T Hash (Z C)

4.Output the leading l octets of T as the octet string mask.

11. ASN.1 syntax

11.1 Key representation

This section defines ASN.1 object identifiers for RSA public and

private keys, and defines the types RSAPublicKey and RSAPrivateKey.

The intended application of these definitions includes X.509

certificates, PKCS #8 [22], and PKCS #12 [23].

The object identifier rsaEncryption identifies RSA public and private

keys as defined in Sections 11.1.1 and 11.1.2. The parameters field

associated with this OID in an AlgorithmIdentifier shall have type

NULL.

rsaEncryption OBJECT IDENTIFIER ::= {pkcs-1 1}

All of the definitions in this section are the same as in PKCS #1

v1.5.

11.1.1 Public-key syntax

An RSA public key should be represented with the ASN.1 type

RSAPublicKey:

RSAPublicKey::=SEQUENCE{

modulus INTEGER, -- n

publicExponent INTEGER -- e }

(This type is specified in X.509 and is retained here for

compatibility.)

The fields of type RSAPublicKey have the following meanings:

-modulus is the modulus n.

-publicExponent is the public exponent e.

11.1.2 Private-key syntax

An RSA private key should be represented with ASN.1 type

RSAPrivateKey:

RSAPrivateKey ::= SEQUENCE {

version Version,

modulus INTEGER, -- n

publicExponent INTEGER, -- e

privateExponent INTEGER, -- d

prime1 INTEGER, -- p

prime2 INTEGER, -- q

exponent1 INTEGER, -- d mod (p-1)

exponent2 INTEGER, -- d mod (q-1)

coefficient INTEGER -- (inverse of q) mod p }

Version ::= INTEGER

The fields of type RSAPrivateKey have the following meanings:

-version is the version number, for compatibility with future

revisions of this document. It shall be 0 for this version of the

document.

-modulus is the modulus n.

-publicExponent is the public exponent e.

-privateExponent is the private exponent d.

-prime1 is the prime factor p of n.

-prime2 is the prime factor q of n.

-exponent1 is d mod (p-1).

-exponent2 is d mod (q-1).

-coefficient is the Chinese Remainder Theorem coefficient q-1 mod p.

11.2 Scheme identification

This section defines object identifiers for the encryption and

signature schemes. The schemes compatible with PKCS #1 v1.5 have the

same definitions as in PKCS #1 v1.5. The intended application of

these definitions includes X.509 certificates and PKCS #7.

11.2.1 Syntax for RSAES-OAEP

The object identifier id-RSAES-OAEP identifies the RSAES-OAEP

encryption scheme.

id-RSAES-OAEP OBJECT IDENTIFIER ::= {pkcs-1 7}

The parameters field associated with this OID in an

AlgorithmIdentifier shall have type RSAEP-OAEP-params:

RSAES-OAEP-params ::= SEQUENCE {

hashFunc [0] AlgorithmIdentifier {{oaepDigestAlgorithms}}

DEFAULT sha1Identifier,

maskGenFunc [1] AlgorithmIdentifier {{pkcs1MGFAlgorithms}}

DEFAULT mgf1SHA1Identifier,

pSourceFunc [2] AlgorithmIdentifier

{{pkcs1pSourceAlgorithms}}

DEFAULT pSpecifiedEmptyIdentifier }

The fields of type RSAES-OAEP-params have the following meanings:

-hashFunc identifies the hash function. It shall be an algorithm ID

with an OID in the set oaepDigestAlgorithms, which for this version

shall consist of id-sha1, identifying the SHA-1 hash function. The

parameters field for id-sha1 shall have type NULL.

oaepDigestAlgorithms ALGORITHM-IDENTIFIER ::= {

{NULL IDENTIFIED BY id-sha1} }

id-sha1 OBJECT IDENTIFIER ::=

{iso(1) identified-organization(3) oiw(14) secsig(3)

algorithms(2) 26}

The default hash function is SHA-1:

sha1Identifier ::= AlgorithmIdentifier {id-sha1, NULL}

-maskGenFunc identifies the mask generation function. It shall be an

algorithm ID with an OID in the set pkcs1MGFAlgorithms, which for

this version shall consist of id-mgf1, identifying the MGF1 mask

generation function (see Section 10.2.1). The parameters field for

id-mgf1 shall have type AlgorithmIdentifier, identifying the hash

function on which MGF1 is based, where the OID for the hash function

shall be in the set oaepDigestAlgorithms.

pkcs1MGFAlgorithms ALGORITHM-IDENTIFIER ::= {

{AlgorithmIdentifier {{oaepDigestAlgorithms}} IDENTIFIED

BY id-mgf1} }

id-mgf1 OBJECT IDENTIFIER ::= {pkcs-1 8}

The default mask generation function is MGF1 with SHA-1:

mgf1SHA1Identifier ::= AlgorithmIdentifier {

id-mgf1, sha1Identifier }

-pSourceFunc identifies the source (and possibly the value) of the

encoding parameters P. It shall be an algorithm ID with an OID in the

set pkcs1pSourceAlgorithms, which for this version shall consist of

id-pSpecified, indicating that the encoding parameters are specified

explicitly. The parameters field for id-pSpecified shall have type

OCTET STRING, containing the encoding parameters.

pkcs1pSourceAlgorithms ALGORITHM-IDENTIFIER ::= {

{OCTET STRING IDENTIFIED BY id-pSpecified} }

id-pSpecified OBJECT IDENTIFIER ::= {pkcs-1 9}

The default encoding parameters is an empty string (so that pHash in

EME-OAEP will contain the hash of the empty string):

pSpecifiedEmptyIdentifier ::= AlgorithmIdentifier {

id-pSpecified, OCTET STRING SIZE (0) }

If all of the default values of the fields in RSAES-OAEP-params are

used, then the algorithm identifier will have the following value:

RSAES-OAEP-Default-Identifier ::= AlgorithmIdentifier {

id-RSAES-OAEP,

{sha1Identifier,

mgf1SHA1Identifier,

pSpecifiedEmptyIdentifier } }

11.2.2 Syntax for RSAES-PKCS1-v1_5

The object identifier rsaEncryption (Section 11.1) identifies the

RSAES-PKCS1-v1_5 encryption scheme. The parameters field associated

with this OID in an AlgorithmIdentifier shall have type NULL. This is

the same as in PKCS #1 v1.5.

RsaEncryption OBJECT IDENTIFIER ::= {PKCS-1 1}

11.2.3 Syntax for RSASSA-PKCS1-v1_5

The object identifier for RSASSA-PKCS1-v1_5 shall be one of the

following. The choice of OID depends on the choice of hash algorithm:

MD2, MD5 or SHA-1. Note that if either MD2 or MD5 is used then the

OID is just as in PKCS #1 v1.5. For each OID, the parameters field

associated with this OID in an AlgorithmIdentifier shall have type

NULL.

If the hash function to be used is MD2, then the OID should be:

md2WithRSAEncryption ::= {PKCS-1 2}

If the hash function to be used is MD5, then the OID should be:

md5WithRSAEncryption ::= {PKCS-1 4}

If the hash function to be used is SHA-1, then the OID should be:

sha1WithRSAEncryption ::= {pkcs-1 5}

In the digestInfo type mentioned in Section 9.2.1 the OIDS for the

digest algorithm are the following:

id-SHA1 OBJECT IDENTIFIER ::=

{iso(1) identified-organization(3) oiw(14) secsig(3)

algorithms(2) 26 }

md2 OBJECT IDENTIFIER ::=

{iso(1) member-body(2) US(840) rsadsi(113549)

digestAlgorithm(2) 2}

md5 OBJECT IDENTIFIER ::=

{iso(1) member-body(2) US(840) rsadsi(113549)

digestAlgorithm(2) 5}

The parameters field of the digest algorithm has ASN.1 type NULL for

these OIDs.

12. Patent statement

The Internet Standards Process as defined in RFC1310 requires a

written statement from the Patent holder that a license will be made

available to applicants under reasonable terms and conditions prior

to approving a specification as a Proposed, Draft or Internet

Standard.

The Internet Society, Internet Architecture Board, Internet

Engineering Steering Group and the Corporation for National Research

Initiatives take no position on the validity or scope of the

following patents and patent applications, nor on the appropriateness

of the terms of the assurance. The Internet Society and other groups

mentioned above have not made any determination as to any other

intellectual property rights which may apply to the practice of this

standard. Any further consideration of these matters is the user's

responsibility.

12.1 Patent statement for the RSA algorithm

The Massachusetts Institute of Technology has granted RSA Data

Security, Inc., exclusive sub-licensing rights to the following

patent issued in the United States:

Cryptographic Communications System and Method ("RSA"), No. 4,405,829

RSA Data Security, Inc. has provided the following statement with

regard to this patent:

It is RSA's business practice to make licenses to its patents

available on reasonable and nondiscriminatory terms. Accordingly, RSA

is willing, upon request, to grant non-exclusive licenses to such

patent on reasonable and non-discriminatory terms and conditions to

those who respect RSA's intellectual property rights and subject to

RSA's then current royalty rate for the patent licensed. The royalty

rate for the RSA patent is presently set at 2% of the licensee's

selling price for each product covered by the patent. Any requests

for license information may be directed to:

Director of Licensing

RSA Data Security, Inc.

2955 Campus Drive

Suite 400

San Mateo, CA 94403

A license under RSA's patent(s) does not include any rights to know-

how or other technical information or license under other

intellectual property rights. Such license does not extend to any

activities which constitute infringement or inducement thereto. A

licensee must make his own determination as to whether a license is

necessary under patents of others.

13. Revision history

Versions 1.0-1.3

Versions 1.0-1.3 were distributed to participants in RSA Data

Security, Inc.'s Public-Key Cryptography Standards meetings in

February and March 1991.

Version 1.4

Version 1.4 was part of the June 3, 1991 initial public release of

PKCS. Version 1.4 was published as NIST/OSI Implementors' Workshop

document SEC-SIG-91-18.

Version 1.5

Version 1.5 incorporates several editorial changes, including updates

to the references and the addition of a revision history. The

following substantive changes were made: -Section 10: "MD4 with RSA"

signature and verification processes were added.

-Section 11: md4WithRSAEncryption object identifier was added.

Version 2.0 [DRAFT]

Version 2.0 incorporates major editorial changes in terms of the

document structure, and introduces the RSAEP-OAEP encryption scheme.

This version continues to support the encryption and signature

processes in version 1.5, although the hash algorithm MD4 is no

longer allowed due to cryptanalytic advances in the intervening

years.

14. References

[1] ANSI, ANSI X9.44: Key Management Using Reversible Public Key

Cryptography for the Financial Services Industry. Work in

Progress.

[2] M. Bellare and P. Rogaway. Optimal Asymmetric Encryption - How to

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[3] M. Bellare and P. Rogaway. The Exact Security of Digital

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[4] D. Bleichenbacher. Chosen Ciphertext Attacks against Protocols

Based on the RSA Encryption Standard PKCS #1. To appear in

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[5] D. Bleichenbacher, B. Kaliski and J. Staddon. Recent Results on

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Number 7, June 24, 1998.

[6] CCITT. Recommendation X.509: The Directory-Authentication

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293-304, Springer-Verlag, 1994.

[9] B. den Boer, and A. Bosselaers. An Attack on the Last Two Rounds

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[14] IEEE. IEEE P1363: Standard Specifications for Public Key

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[20] RSA Laboratories. PKCS #1: RSA Encryption Standard. Version 1.5,

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[21] RSA Laboratories. PKCS #7: Cryptographic Message Syntax

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[22] RSA Laboratories. PKCS #8: Private-Key Information Syntax

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[23] RSA Laboratories. PKCS #12: Personal Information Exchange Syntax

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Security Considerations

Security issues are discussed throughout this memo.

Acknowledgements

This document is based on a contribution of RSA Laboratories, a

division of RSA Data Security, Inc. Any substantial use of the text

from this document must acknowledge RSA Data Security, Inc. RSA Data

Security, Inc. requests that all material mentioning or referencing

this document identify this as "RSA Data Security, Inc. PKCS #1

v2.0".

Authors' Addresses

Burt Kaliski

RSA Laboratories East

20 Crosby Drive

Bedford, MA 01730

Phone: (617) 687-7000

EMail: burt@rsa.com

Jessica Staddon

RSA Laboratories West

2955 Campus Drive

Suite 400

San Mateo, CA 94403

Phone: (650) 295-7600

EMail: jstaddon@rsa.com

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included on all such copies and derivative works. However, this

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the copyright notice or references to the Internet Society or other

Internet organizations, except as needed for the purpose of

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