2020-06-22 04:15:24 +00:00
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.\" Man page generated from reStructuredText.
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2020-07-22 05:45:19 +00:00
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.TH "SYNCTHING-DEVICE-IDS" "7" "Jul 16, 2020" "v1" "Syncthing"
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2020-06-22 04:15:24 +00:00
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.SH NAME
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syncthing-device-ids \- Understanding Device IDs
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.nr rst2man-indent-level 0
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level margin: \\n[rst2man-indent\\n[rst2man-indent-level]]
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..
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.de1 INDENT
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.\" .rstReportMargin pre:
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.\" .rstReportMargin post:
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..
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.de UNINDENT
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. RE
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.\" old: \\n[rst2man-indent\\n[rst2man-indent-level]]
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.\" new: \\n[rst2man-indent\\n[rst2man-indent-level]]
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.in \\n[rst2man-indent\\n[rst2man-indent-level]]u
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..
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.sp
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Every device is identified by a device ID. The device ID is used for address
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resolution, authentication and authorization. The term “device ID” could
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interchangeably have been “key ID” since the device ID is a direct property of
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the public key in use.
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.SH KEYS
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.sp
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To understand device IDs we need to look at the underlying mechanisms. At first
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startup, Syncthing will create a public/private keypair.
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.sp
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Currently this is a 384 bit ECDSA key (3072 bit RSA prior to v0.12.5,
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which is what is used as an example in this article). The keys are saved in
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the form of the private key (\fBkey.pem\fP) and a self signed certificate
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(\fBcert.pem\fP). The self signing part doesn’t actually add any security or
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functionality as far as Syncthing is concerned but it enables the use of the
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keys in a standard TLS exchange.
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.sp
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The typical certificate will look something like this, inspected with
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\fBopenssl x509\fP:
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.INDENT 0.0
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.INDENT 3.5
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.sp
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.nf
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.ft C
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Certificate:
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Data:
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Version: 3 (0x2)
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Serial Number: 0 (0x0)
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Signature Algorithm: sha1WithRSAEncryption
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Issuer: CN=syncthing
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Validity
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Not Before: Mar 30 21:10:52 2014 GMT
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Not After : Dec 31 23:59:59 2049 GMT
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Subject: CN=syncthing
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Subject Public Key Info:
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Public Key Algorithm: rsaEncryption
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RSA Public Key: (3072 bit)
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Modulus (3072 bit):
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00:da:83:8a:c0:95:af:0a:42:af:43:74:65:29:f2:
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30:e3:b9:12:d2:6b:70:93:da:0b:7b:8a:1e:e5:79:
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...
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99:09:4c:a9:7b:ba:4a:6a:8b:3b:e6:e7:c7:2c:00:
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90:aa:bc:ad:94:e7:80:95:d2:1b
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Exponent: 65537 (0x10001)
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X509v3 extensions:
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X509v3 Key Usage: critical
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Digital Signature, Key Encipherment
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X509v3 Extended Key Usage:
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TLS Web Server Authentication, TLS Web Client Authentication
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X509v3 Basic Constraints: critical
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CA:FALSE
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Signature Algorithm: sha1WithRSAEncryption
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68:72:43:8b:83:61:09:68:f0:ef:f0:43:b7:30:a6:73:1e:a8:
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d9:24:6c:2d:b4:bc:c9:e8:3e:0b:1e:3c:cc:7a:b2:c8:f1:1d:
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...
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88:7e:e2:61:aa:4c:02:e3:64:b0:da:70:3a:cd:1c:3d:86:db:
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df:54:b9:4e:be:1b
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.ft P
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.fi
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.UNINDENT
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.UNINDENT
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.sp
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We can see here that the certificate is little more than a container for the
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public key; the serial number is zero and the Issuer and Subject are both
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“syncthing” where a qualified name might otherwise be expected.
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.sp
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An advanced user could replace the \fBkey.pem\fP and \fBcert.pem\fP files with a
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keypair generated directly by the \fBopenssl\fP utility or other mechanism.
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.SH DEVICE IDS
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.sp
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To form a device ID the SHA\-256 hash of the certificate data in DER form is
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calculated. This means the hash covers all information under the
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\fBCertificate:\fP section above.
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.sp
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The hashing results in a 256 bit hash which we encode using base32. Base32
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encodes five bits per character so we need 256 / 5 = 51.2 characters to encode
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the device ID. This becomes 52 characters in practice, but 52 characters of
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base32 would decode to 260 bits which is not a whole number of bytes. The
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base32 encoding adds padding to 280 bits (the next multiple of both 5 and 8
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bits) so the resulting ID looks something like:
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.INDENT 0.0
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.INDENT 3.5
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.sp
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.nf
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.ft C
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MFZWI3DBONSGYYLTMRWGC43ENRQXGZDMMFZWI3DBONSGYYLTMRWA====
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.ft P
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.fi
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.UNINDENT
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.UNINDENT
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.sp
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The padding (\fB====\fP) is stripped away, the device ID split into four
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groups, and \fI\%check
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digits\fP <\fBhttps://forum.syncthing.net/t/v0-9-0-new-node-id-format/478\fP>
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are added for each group. For presentation purposes the device ID is
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grouped with dashes, resulting in the final value:
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.INDENT 0.0
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.INDENT 3.5
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.sp
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.nf
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.ft C
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MFZWI3D\-BONSGYC\-YLTMRWG\-C43ENR5\-QXGZDMM\-FZWI3DP\-BONSGYY\-LTMRWAD
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.ft P
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.fi
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.UNINDENT
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.UNINDENT
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.SS Connection Establishment
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.sp
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Now we know what device IDs are, here’s how they are used in Syncthing. When
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you add a device ID to the configuration, Syncthing will attempt to
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connect to that device. The first thing we need to do is figure out the IP and
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port to connect to. There are three possibilities here:
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.INDENT 0.0
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.IP \(bu 2
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The IP and port can be set statically in the configuration. The IP
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can equally well be a host name, so if you have a static IP or a
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dynamic DNS setup this might be a good option.
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.IP \(bu 2
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Using local discovery, if enabled. Every Syncthing instance on a LAN
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periodically broadcasts information about itself (device ID, address,
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port number). If we’ve seen one of these broadcasts for a given
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device ID that’s where we try to connect.
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.IP \(bu 2
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Using global discovery, if enabled. Every Syncthing instance
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announces itself to the global discovery service (device ID and
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external port number \- the internal address is not announced to the
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global server). If we don’t have a static address and haven’t seen
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any local announcements the global discovery server will be queried
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for an address.
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.UNINDENT
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.sp
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Once we have an address and port a TCP connection is established and a TLS
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handshake performed. As part of the handshake both devices present their
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certificates. Once the handshake has completed and the peer certificate is
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known, the following steps are performed:
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.INDENT 0.0
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.IP 1. 3
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Calculate the remote device ID by processing the received certificate as above.
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.IP 2. 3
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Weed out a few possible misconfigurations \- i.e. if the device ID is
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that of the local device or of a device we already have an active
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connection to. Drop the connection in these cases.
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.IP 3. 3
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Verify the remote device ID against the configuration. If it is not a
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device ID we are expecting to talk to, drop the connection.
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.IP 4. 3
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Verify the certificate \fBCommonName\fP against the configuration. By
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default, we expect it to be \fBsyncthing\fP, but when using custom
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certificates this can be changed.
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.IP 5. 3
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If everything checks out so far, accept the connection.
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.UNINDENT
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.SH AN ASIDE ABOUT COLLISIONS
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.sp
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The SHA\-256 hash is cryptographically collision resistant. This means
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that there is no way that we know of to create two different messages
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with the same hash.
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.sp
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You can argue that of course there are collisions \- there’s an infinite
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amount of inputs and a finite amount of outputs \- so by definition there
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are infinitely many messages that result in the same hash.
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.sp
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I’m going to quote \fI\%stack
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overflow\fP <\fBhttps://stackoverflow.com/questions/4014090/is-it-safe-to-ignore-the-possibility-of-sha-collisions-in-practice\fP>
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here:
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.INDENT 0.0
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.INDENT 3.5
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The usual answer goes thus: what is the probability that a rogue
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asteroid crashes on Earth within the next second, obliterating
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civilization\-as\-we\- know\-it, and killing off a few billion people ?
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It can be argued that any unlucky event with a probability lower
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than that is not actually very important.
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.sp
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If we have a “perfect” hash function with output size n, and we have
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p messages to hash (individual message length is not important),
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then probability of collision is about p2/2n+1 (this is an
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approximation which is valid for “small” p, i.e. substantially
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smaller than 2n/2). For instance, with SHA\-256 (n=256) and one
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billion messages (p=10^9) then the probability is about 4.3*10^\-60.
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.sp
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A mass\-murderer space rock happens about once every 30 million years
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on average. This leads to a probability of such an event occurring
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in the next second to about 10^\-15. That’s 45 orders of magnitude
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more probable than the SHA\-256 collision. Briefly stated, if you
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find SHA\-256 collisions scary then your priorities are wrong.
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.UNINDENT
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.UNINDENT
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.sp
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It’s also worth noting that the property of SHA\-256 that we are using is not
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simply collision resistance but resistance to a preimage attack, i.e. even if
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you can find two messages that result in a hash collision that doesn’t help you
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attack Syncthing (or TLS in general). You need to create a message that hashes
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to exactly the hash that my certificate already has or you won’t get in.
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.sp
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Note also that it’s not good enough to find a random blob of bits that happen to
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have the same hash as my certificate. You need to create a valid DER\-encoded,
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signed certificate that has the same hash as mine. The difficulty of this is
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staggeringly far beyond the already staggering difficulty of finding a SHA\-256
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collision.
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.SH PROBLEMS AND VULNERABILITIES
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.sp
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As far as I know, these are the issues or potential issues with the
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above mechanism.
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.SS Discovery Spoofing
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.sp
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Currently, the local discovery mechanism isn’t protected by crypto. This
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means that any device can in theory announce itself for any device ID and
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potentially receive connections for that device from the local network.
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.SS Long Device IDs are Painful
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.sp
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It’s a mouthful to read over the phone, annoying to type into an SMS or even
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into a computer. And it needs to be done twice, once for each side.
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.sp
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This isn’t a vulnerability as such, but a user experience problem. There are
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various possible solutions:
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.INDENT 0.0
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.IP \(bu 2
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Use shorter device IDs with verification based on the full ID (“You
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entered MFZWI3; I found and connected to a device with the ID
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MFZWI3\-DBONSG\-YYLTMR\-WGC43E\-NRQXGZ\-DMMFZW\-I3DBON\-SGYYLT\-MRWA, please
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confirm that this is correct”).
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.IP \(bu 2
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Use shorter device IDs with an out of band authentication, a la
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Bluetooth pairing. You enter a one time PIN into Syncthing and give
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that PIN plus a short device ID to another user. On initial connect,
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both sides verify that the other knows the correct PIN before
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accepting the connection.
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.UNINDENT
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.SH AUTHOR
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The Syncthing Authors
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.SH COPYRIGHT
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2014-2019, The Syncthing Authors
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.\" Generated by docutils manpage writer.
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