LBP
/
corosync
réplica de https://github.com/corosync/corosync


			
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							***
All cryptographic software in this package is subject to the following legal
notice:
This package includes publicly available encryption source code which,
together with object code resulting from the compiling of publicly
available source code, may be exported from the United States under License
Exception TSU prsuant to 15 C.F.R Section 740.13(e).
***
Security Design of openais

The openais project intends to mitigate the following threats:

1. forged group messaging messages which are intended to fault the openais
   executive
2. forged group messaging messages which are intended to fault applications
   using openais apis
3. monitoring of network data to capture sensitive information

The openais project does not intend to mitigate the following threats:

1. physical access to the hardware which could expose the private key
2. privledged access to the operating system which could expose the private key
   or be used to inject errors into the ais executive.
3. library user creates requests which are intended to fault the openais
   executive

The openais project mitigates the threats using two mechanisms:

1. Authentication
2. Secrecy

Library Interface
-----------------
The openais executive authenticates every library user.  The library is only
allowed to access services if it's GID is ais or 0.  Unauthorized library
users are rejected.

The ais group is a trusted group.  If the administrator doesn't trust the
application, it should not be added to the group!  Any member of the ais group
could potentially send a malformed request to the executive and cause it to
fault.

Group Messaging Interface
-------------------------
Group messaging uses UDP/IP to communicate with other openais executives using
messages.  It is possible without authentication of every packet that an
attacker could forge messages.  These forged messages could fault the openais
executive distributed state machines.  It would also be possible to corrupt 
end applications by forging changes.

Since messages are sent using UDP/IP it would be possible to snoop those
messages and rebuild sensitive data.

To solve these problems, the group messaging interface uses two new interfaces
interal to it's implementation:
1. encrypt_and_sign - encrypts and signs a message securely
2. authenticate_and_decrypt - authenticates and decrypts a message securely

When the executive wants to send a message over the network, it uses
encrypt_and_sign to prepare the message to be sent.  When the executive
wants to receive a message from the network, it uses
authenticate_and_decrypt to verify the message is valid and decrypt it.

These two functions utilize the following algorithms:
sha1 - hash algorithm secure for using with hmac 
hmac - produces a 16 byte digest from any length input
sober - pseudo random number generator and stream cipher

The hmac algorithm requires a 16 byte key.
The sober algorithm requires a 16 byte private key.
The sober algorithm requires a 16 byte public initial vector.

The private key is read from disk and stored in memory for use with the
sober algorithm to generate the three required keys.

Every message starts with a
struct security {
	unsigned char digest[20]; A one way hash digest
	unsigned char salt[16]; A securely generated random number 
}

When a message is sent (encrypt_and_sign):
------------------------------------------
1. sober is used to create a 16 byte random number (salt) using the md4
   algorithm
2. sober is keyed with the private key and the initial vector is set to the
   salt.  Then a 48 byte key is read from the sober algorithm.  This 48 byte
   key is split into 3 16 byte keys.  The keys are the hmac key, the sober key
   and the sober initial vector.
3. A sober instance is keyed with the sober key and sober initial vector
   from step #2.
4. The data of the packet, except for the security header, is encrypted using
   the sober cipher that was initialized in step #3.
5. The salt is stored in the security header of the outgoing message.
6. The hmac is initialized with the hmac key generated in step #2.
7. The message, except for the security header, is hmaced to produce a digest
   using the sha1 algorithm.
8. The digest is stored in the outgoing message.
9. The message is transmitted. 


When a message is received (decrypt_and_authenticate):
------------------------------------------------------
1. sober is keyed with the private key and the initial vector is set to the
   salt in the received message.  Then a 48 byte key is read from the sober
   algorithm.  This 48 byte key is split into 3 16 byte keys.  The keys are the
   hmac key, the sober key and the sober initial vector.
2. The sober key and sober initial vector from step #1 are used to key a
   new sober instance.
3. The hmac is setup using the hmac key generated in step #1 using sha1.
5. The message is authenticated, except for the security header.
6. If the message was not authenticated, the caller is told of the result.
   The caller ignores the message.
7. The message is decrypted, except for the security header, using the sober
   algorithm in step #2.
8. The message is processed.

This does consume some resources.  It ensures the private key is never shared
openly, that messages are authenticated, that messages are encrypted, and that
any key exposure of the sober encryption key, sober initial vector, or hmac
key can only be used to attack one of the algorithms.  Finally every key used
is randomly unique (within the 2^128 search space of the input to sober) to
ensure that keys are never reused, nonce's are never reused, and hmac's are
never reused.

Comments welcome mailto:openais@lists.osdl.org