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359 lines
12 KiB
Plaintext
359 lines
12 KiB
Plaintext
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* For packet version 3 we calculate the keyids this way:
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RSA := low 64 bits of n
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ELGAMAL := build a v3 pubkey packet (with CTB 0x99) and calculate
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a rmd160 hash value from it. This is used as the
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fingerprint and the low 64 bits are the keyid.
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* Revocation certificates consist only of the signature packet;
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"import" knows how to handle this. The rationale behind it is
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to keep them small.
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Key generation shows progress by printing different characters to
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stderr:
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"." Last 10 Miller-Rabin tests failed
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"+" Miller-Rabin test succeeded
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"!" Reloading the pool with fresh prime numbers
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"^" Checking a new value for the generator
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"<" Size of one factor decreased
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">" Size of one factor increased
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The prime number for ElGamal is generated this way:
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1) Make a prime number q of 160, 200, 240 bits (depending on the keysize)
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2) Select the length of the other prime factors to be at least the size
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of q and calculate the number of prime factors needed
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3) Make a pool of prime numbers, each of the length determined in step 2
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4) Get a new permutation out of the pool or continue with step 3
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if we have tested all permutations.
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5) Calculate a candidate prime p = 2 * q * p[1] * ... * p[n] + 1
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6) Check that this prime has the correct length (this may change q if
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it seems not to be possible to make a prime of the desired length)
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7) Check whether this is a prime using trial divisions and the
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Miller-Rabin test.
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8) Continue with step 4 if we did not find a prime in step 7.
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9) Find a generator for that prime.
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Layout of the TrustDB
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=====================
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FIXME: use a directory record as top node instead of the pubkey record
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The TrustDB is built from fixed length records, where the first byte
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describes the record type. All numeric values are stored in network
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byte order. The length of each record is 40 bytes. The first record of
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the DB is always of type 1 and this is the only record of this type.
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Record type 0:
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--------------
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Unused record, can be reused for any purpose.
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Record type 1:
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--------------
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Version information for this TrustDB. This is always the first
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record of the DB and the only one with type 1.
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1 byte value 1
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3 bytes 'gpg' magic value
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1 byte Version of the TrustDB
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3 byte reserved
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1 u32 locked flags
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1 u32 timestamp of trustdb creation
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1 u32 timestamp of last modification
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1 u32 timestamp of last validation
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(Used to keep track of the time, when this TrustDB was checked
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against the pubring)
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1 u32 record number of keyhashtable
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12 bytes reserved
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Record type 2: (directory record)
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--------------
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Informations about a public key certificate.
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These are static values which are never changed without user interaction.
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1 byte value 2
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1 byte reserved
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1 u32 LID . (This is simply the record number of this record.)
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1 u32 List of key-records (the first one is the primary key)
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1 u32 List of uid-records
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1 u32 cache record
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1 byte ownertrust
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1 byte sigflag
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20 byte reserved
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Record type 3: (key record)
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--------------
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Informations about a primary public key.
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(This is mainly used to lookup a trust record)
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1 byte value 3
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1 byte reserved
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1 u32 LID
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1 u32 next - next key record
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7 bytes reserved
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1 byte keyflags
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1 byte pubkey algorithm
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1 byte length of the fingerprint (in bytes)
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20 bytes fingerprint of the public key
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(This is the value we use to identify a key)
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Record type 4: (uid record)
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--------------
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Informations about a userid
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We do not store the userid but the hash value of the userid because that
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is sufficient.
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1 byte value 4
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1 byte reserved
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1 u32 LID points to the directory record.
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1 u32 next next userid
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1 u32 pointer to preference record
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1 u32 siglist list of valid signatures
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1 byte uidflags
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1 byte reserved
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20 bytes ripemd160 hash of the username.
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Record type 5: (pref record)
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--------------
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Informations about preferences
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1 byte value 5
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1 byte reserved
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1 u32 LID; points to the directory record (and not to the uid record!).
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(or 0 for standard preference record)
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1 u32 next
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Record type 6 (sigrec)
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-------------
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Used to keep track of valid key signatures. Self-signatures are not
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stored.
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1 byte value 6
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1 byte reserved
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1 u32 LID points back to the dir record
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1 u32 next next sigrec of this owner or 0 to indicate the
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last sigrec.
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6 times
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1 u32 Local_id of signators dir record
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1 byte reserved
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Record type 9: (cache record)
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--------------
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Used to bind the trustDB to the concrete instance of keyblock in
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a pubring. This is used to cache information.
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1 byte value 9
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1 byte reserved
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1 u32 Local-Id.
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8 bytes keyid of the primary key (needed?)
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1 byte cache-is-valid the following stuff is only
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valid if this is set.
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1 byte reserved
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20 bytes rmd160 hash value over the complete keyblock
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This is used to detect any changes of the keyblock with all
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CTBs and lengths headers. Calculation is easy if the keyblock
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is optained from a keyserver: simply create the hash from all
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received data bytes.
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1 byte number of untrusted signatures.
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1 byte number of marginal trusted signatures.
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1 byte number of fully trusted signatures.
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(255 is stored for all values greater than 254)
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1 byte Trustlevel
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0 = undefined (not calculated)
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1 = unknown
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2 = not trusted
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3 = marginally trusted
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4 = fully trusted
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5 = ultimately trusted (have secret key too).
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Record Type 10 (hash table)
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--------------
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Due to the fact that we use fingerprints to lookup keys, we can
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implement quick access by some simple hash methods, and avoid
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the overhead of gdbm. A property of fingerprints is that they can be
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used directly as hash values. (They can be considered as strong
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random numbers.)
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What we use is a dynamic multilevel architecture, which combines
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hashtables, record lists, and linked lists.
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This record is a hashtable of 256 entries; a special property
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is that all these records are stored consecutively to make one
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big table. The hash value is simple the 1st, 2nd, ... byte of
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the fingerprint (depending on the indirection level).
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1 byte value 10
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1 byte reserved
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n u32 recnum; n depends on the record length:
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n = (reclen-2)/4 which yields 9 for the current record length
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of 40 bytes.
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the total number of surch record which makes up the table is:
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m = (256+n-1) / n
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which is 29 for a record length of 40.
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To look up a key we use the first byte of the fingerprint to get
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the recnum from this hashtable and look up the addressed record:
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- If this record is another hashtable, we use 2nd byte
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to index this hast table and so on.
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- if this record is a hashlist, we walk all entries
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until we found one a matching one.
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- if this record is a key record, we compare the
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fingerprint and to decide whether it is the requested key;
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Record type 11 (hash list)
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--------------
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see hash table for an explanation.
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1 byte value 11
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1 byte reserved
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1 u32 next next hash list record
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n times n = (reclen-5)/5
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1 u32 recnum
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For the current record length of 40, n is 7
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Packet Headers
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===============
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GNUPG uses PGP 2 packet headers and also understands OpenPGP packet header.
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There is one enhancement used with the old style packet headers:
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CTB bits 10, the "packet-length length bits", have values listed in
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the following table:
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00 - 1-byte packet-length field
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01 - 2-byte packet-length field
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10 - 4-byte packet-length field
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11 - no packet length supplied, unknown packet length
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As indicated in this table, depending on the packet-length length
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bits, the remaining 1, 2, 4, or 0 bytes of the packet structure field
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are a "packet-length field". The packet-length field is a whole
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number field. The value of the packet-length field is defined to be
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the value of the whole number field.
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A value of 11 is currently used in one place: on compressed data.
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That is, a compressed data block currently looks like <A3 01 . . .>,
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where <A3>, binary 10 1000 11, is an indefinite-length packet. The
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proper interpretation is "until the end of the enclosing structure",
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although it should never appear outermost (where the enclosing
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structure is a file).
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+ This will be changed with another version, where the new meaning of
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+ the value 11 (see below) will also take place.
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+
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+ A value of 11 for other packets enables a special length encoding,
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+ which is used in case, where the length of the following packet can
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+ not be determined prior to writing the packet; especially this will
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+ be used if large amounts of data are processed in filter mode.
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+
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+ It works like this: After the CTB (with a length field of 11) a
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+ marker field is used, which gives the length of the following datablock.
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+ This is a simple 2 byte field (MSB first) containig the amount of data
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+ following this field, not including this length field. After this datablock
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+ another length field follows, which gives the size of the next datablock.
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+ A value of 0 indicates the end of the packet. The maximum size of a
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+ data block is limited to 65534, thereby reserving a value of 0xffff for
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+ future extensions. These length markers must be insereted into the data
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+ stream just before writing the data out.
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+
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+ This 2 byte filed is large enough, because the application must buffer
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+ this amount of data to prepend the length marker before writing it out.
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+ Data block sizes larger than about 32k doesn't make any sense. Note
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+ that this may also be used for compressed data streams, but we must use
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+ another packet version to tell the application that it can not assume,
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+ that this is the last packet.
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Keyserver Message Format
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-------------------------
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The keyserver may be contacted by a Unix Domain socket or via TCP.
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The format of a request is:
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----
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command-tag
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"Content-length:" digits
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CRLF
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------
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Where command-tag is
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NOOP
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GET <user-name>
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PUT
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DELETE <user-name>
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The format of a response is:
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------
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"GNUPG/1.0" status-code status-text
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"Content-length:" digits
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CRLF
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------------
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followed by <digits> bytes of data
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Status codes are:
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o 1xx: Informational - Request received, continuing process
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o 2xx: Success - The action was successfully received, understood,
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and accepted
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o 4xx: Client Error - The request contains bad syntax or cannot be
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fulfilled
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o 5xx: Server Error - The server failed to fulfill an apparently
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valid request
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Ich werde jetzt doch das HKP Protokoll implementieren:
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Naja, die Doku ist so gut wie nichtexistent, da gebe ich Dir recht.
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In kurzen Worten:
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(Minimal-)HTTP-Server auf Port 11371, versteht ein GET auf /pks/lookup,
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wobei die Query-Parameter (Key-Value-Paare mit = zwischen Key und
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Value; die Paare sind hinter ? und durch & getrennt). G<>ltige
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Operationen sind:
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- - op (Operation) mit den M<>glichkeiten index (gleich wie -kv bei
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PGP), vindex (-kvv) und get (-kxa)
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- - search: Liste der Worte, die im Key vorkommen m<>ssen. Worte sind
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mit Worttrennzeichen wie Space, Punkt, @, ... getrennt, Worttrennzeichen
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werden nicht betrachtet, die Reihenfolge der Worte ist egal.
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- - exact: (on=aktiv, alles andere inaktiv) Nur die Schl<68>ssel
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zur<75>ckgeben, die auch den "search"-String beinhalten (d.h.
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Wortreihenfolge und Sonderzeichen sind wichtig)
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- - fingerprint (Bei [v]index auch den Fingerprint ausgeben), "on"
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f<>r aktiv, alles andere inaktiv
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Neu (wird von GNUPG benutzt):
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/pks/lookup/<gnupg_formatierte_user_id>?op=<operation>
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Zus<EFBFBD>tzlich versteht der Keyserver auch ein POST auf /pks/add, womit
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man Keys hochladen kann.
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