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[tor-commits] [torspec/master] Add my proposal-280 draft (privcount in tor)
commit ce09d266b817e4466f823f821a9ff8fbe0740b96
Author: Nick Mathewson <nickm@xxxxxxxxxxxxxx>
Date: Mon Aug 7 13:39:27 2017 -0400
Add my proposal-280 draft (privcount in tor)
---
proposals/000-index.txt | 2 +
proposals/280-privcount-in-tor.txt | 332 +++++++++++++++++++++++++++++++++++++
2 files changed, 334 insertions(+)
diff --git a/proposals/000-index.txt b/proposals/000-index.txt
index 5dc4395..54d5bc4 100644
--- a/proposals/000-index.txt
+++ b/proposals/000-index.txt
@@ -200,6 +200,7 @@ Proposals by number:
277 Detect multiple relay instances running with same ID [OPEN]
278 Directory Compression Scheme Negotiation [FINISHED]
279 A Name System API for Tor Onion Services [DRAFT]
+280 Privacy-Preseving Statistics with Privcount in Tor [DRAFT]
Proposals by status:
@@ -223,6 +224,7 @@ Proposals by status:
270 RebelAlliance: A Post-Quantum Secure Hybrid Handshake Based on NewHope
273 Exit relay pinning for web services [for n/a]
279 A Name System API for Tor Onion Services
+ 280 Privacy-Preseving Statistics with Privcount in Tor
NEEDS-REVISION:
190 Bridge Client Authorization Based on a Shared Secret
NEEDS-RESEARCH:
diff --git a/proposals/280-privcount-in-tor.txt b/proposals/280-privcount-in-tor.txt
new file mode 100644
index 0000000..c51eb33
--- /dev/null
+++ b/proposals/280-privcount-in-tor.txt
@@ -0,0 +1,332 @@
+Filename: 280-privcount-in-tor.txt
+Title: Privacy-Preseving Statistics with Privcount in Tor
+Author: Nick Mathewson, Tim Wilson-Brown
+Created: 02-Aug-2017
+Status: Draft
+
+0. Acknowledgments
+
+ Tariq Elahi, George Danezis, and Ian Goldberg designed and implemented
+ the PrivEx blinding scheme. Rob Jansen and Aaron Johnson extended
+ PrivEx's differential privacy guarantees to multiple counters in
+ PrivCount:
+
+ https://github.com/privcount/privcount/blob/master/README.markdown#research-background
+
+ Rob Jansen and Tim Wilson-Brown wrote the majority of the experimental
+ PrivCount code, based on the PrivEx secret-sharing variant. This
+ implementation includes contributions from the PrivEx authors, and
+ others:
+
+ https://github.com/privcount/privcount/blob/master/CONTRIBUTORS.markdown
+
+1. Introduction and scope
+
+ PrivCount is a privacy-preserving way to collect aggregate statistics
+ about the Tor network without exposing the statistics from any single
+ Tor relay.
+
+ This document describes the behavior of the in-Tor portion of the
+ PrivCount system. It DOES NOT describe the counter configurations,
+ or any other parts of the system. (These will be covered in separate
+ proposals.)
+
+2. PrivCount overview
+
+ Here follows an oversimplified summary of PrivCount, with enough
+ information to explain the Tor side of things. The actual operation
+ of the non-Tor components is trickier than described below.
+
+ All values in the scheme below are 64-bit unsigned integers; addition
+ and subtraction are modulo 2^64.
+
+ In PrivCount, a Data Collector (in this case a Tor relay) shares
+ numeric data with N different Tally Reporters. (A Tally Reporter
+ performs the summing and unblinding roles of the Tally Server and Share
+ Keeper from experimental PrivCount.)
+
+ All N Tally Reporters together can reconstruct the original data, but
+ no (N-1)-sized subset of the Tally Reporters can learn anything about
+ the data.
+
+ (In reality, the Tally Reporters don't reconstruct the original data
+ at all! Instead, they will reconstruct a _sum_ of the original data
+ across all participating relays.)
+
+ To share data, for each value X to be shared, the relay generates
+ random values B_1 though B_n, and shares each B_i secretly with a
+ single Tally Reporter. The relay then publishes Y = X + SUM(B_i) + Z,
+ where Z is a noise value taken at random from a gaussian distribution.
+ The Tally Reporters can reconstruct X+Z by securely computing SUM(B_i)
+ across all contributing Data Collectors. (Tally Reporters MUST NOT
+ share individual B_i values: that would expose the underlying relay
+ totals.)
+
+ In order to prevent bogus data from corrupting the tally, the Tor
+ relays and the Tally Reporters perform multiple "instances" of this
+ algorithm, randomly sampling in each relays. The relay sends multiple
+ Y values for each measurement, built with different sets of B_i.
+ These "instances" are numbered in order from 1 to R.
+
+ So that the system will still produce results in the event of a single
+ Tally Reporter failure, these instances are distributed across multiple
+ subsets of Tally Reporters.
+
+ Below we describe a data format for this.
+
+3. The document format
+
+ This document format builds on the line-based directory format used
+ for other tor documents, described in Tor's dir-spec.txt.
+
+ Using this format, we describe two kinds of documents here: a
+ "counters" document that publishes all the Y values, and a "blinding"
+ document that describes the B_i values. But see "An optimized
+ alternative" below.
+
+ The "counters" document has these elements:
+
+ "privctr-dump-format" SP VERSION SP SigningKey
+
+ [At start, exactly once]
+
+ Describes the version of the dump format, and provides an ed25519
+ signing key to identify the relay. The signing key is encoded in
+ base64 with padding stripped. VERSION is "alpha" now, but should
+ be "1" once this document is finalized.
+
+ [[[TODO: Do we need a counter version as well?
+
+ Noise is distributed across a particular set of counters,
+ to provide differential privacy guarantees for those counters.
+ Reducing noise requires a break in the collection.
+ Adding counters is ok if the noise on each counter
+ monotonically increases. (Removing counters always reduces
+ noise.)
+
+ We also need to work out how to handle instances with mixed
+ Tor versions, where some Data Collectors report different
+ counters to other Data Collectors. (The blinding works if we
+ substitute zeroes for missing counters on Tally Reporters.
+ But we also need to add noise in this case.)
+
+ -teor
+ ]]]
+
+ "starting-at" SP IsoTime
+
+ [Exactly once]
+
+ The start of the time period when the statistics here were
+ collected.
+
+ "ending-at" SP IsoTime
+
+ [Exactly once]
+
+ The end of the time period when the statistics here were
+ collected.
+
+ "num-instances" SP Number
+
+ [Exactly once]
+
+ The number of "instances" that the relay used (see above.)
+
+ "tally-reporter" SP Identifier SP Key SP InstanceNumbers
+
+ [At least twice]
+
+ The curve25519 public key of each Tally Reporter that the relay
+ believes in. (If the list does not match the list of
+ participating tally reporters, they won't be able to find the
+ relay's values correctly.) The identifiers are non-space,
+ non-nul character sequences. The Key values are encoded in
+ base64 with padding stripped; they must be unique within each
+ counters document. The InstanceNumbers are comma-separated lists
+ of decimal integers from 0 to (num-instances - 1), in ascending
+ order.
+
+ Keyword ":" SP Int SP Int SP Int ...
+
+ [Any number of times]
+
+ The Y values for a single measurement. There are num-instances
+ such Y values for each measurement. They are 64-bit unsigned
+ integers, expressed in decimal.
+
+ The "Keyword" denotes which measurement is being shared. Keyword
+ MAY be any sequence of characters other than colon, nul, space,
+ and newline, though implementators SHOULD avoid getting too
+ creative here. Keywords MUST be unique within a single document.
+ Tally Reporters MUST handle unrecognized keywords. Keywords MAY
+ appear in any order.
+
+ It is safe to send the blinded totals for each instance to every
+ Tally Reporter. To unblind the totals, a Tally Reporter needs:
+ * a blinding document from each relay in the instance, and
+ * the per-counter blinding sums from the other Tally Reporters
+ in their instance.
+
+ [[[TODO: But is it safer to create a per-instance counters
+ document? -- teor]]]
+
+ The semantics of individual measurements are not specified here.
+
+ "signature" SP Signature
+
+ [At end, exactly once]
+
+ The Ed25519 signature of all the fields in the document, from the
+ first byte, up to but not including the "signature" keyword here.
+ The signature is encoded in base64 with padding stripped.
+
+
+ The "blinding" document has these elements:
+
+ "privctr-secret-offsets" SP VERSION SP SigningKey
+
+ [At start, exactly once.]
+
+ The VERSION and SigningKey parameters are the same as for
+ "privctr-dump-format".
+
+ "instances" SP Numbers
+
+ [Exactly once]
+
+ The instances that this Tally Reporter handles.
+ They are given as comma-separated decimal integers, as in the
+ "tally-reporter" entry in the counters document. They MUST
+ match the instances listed in the counters document.
+
+ [[[TODO: this is redundant. Specify the constraint instead? --teor]]]
+
+ "num-counters" SP Number
+
+ [Exactly once]
+
+ The number of counters that the relay used in its counters
+ document. This MUST be equal to the number of keywords in the
+ counters document.
+
+ [[[TODO: this is redundant. Specify the constraint instead? --teor]]]
+
+ "tally-reporter-pubkey" SP Key
+
+ [Exactly once]
+
+ The curve25519 public key of the tally reporter who is intended
+ to receive an decrypt this document. The key is base64-encoded
+ with padding stripped.
+
+ "count-document-digest" SP "sha3" Digest NL
+ "-----BEGIN ENCRYPTED DATA-----" NL
+ Data
+ "-----END ENCRYPTED DATA-----" NL
+
+ [Exactly once]
+
+ The SHA3-256 digest of the count document corresponding to this
+ blinding document. The digest is base64-encoded with padding
+ stripped. The data encodes the blinding values (See "The
+ Blinding Values") below, and is encrypted to the tally reporter's
+ public key using the hybrid encryption algorithm described below.
+
+ "signature" SP Signature
+
+ [At end, exactly once]
+
+ The Ed25519 signature of all the fields in the document, from the
+ first byte, up to but not including the "signature" keyword here.
+ The signature is encoded in base64 with padding stripped.
+
+
+4. The Blinding Values
+
+ The "Data" field of the blinding documents above, when decrypted,
+ yields a sequence of 64-bit binary values, encoded in network
+ (big-endian) order. There are C * R such values, where C is the number
+ of keywords in the count document, and R is the number of instances
+ that the Tally Reporter participates in. The client generates all of
+ these values uniformly at random.
+
+ For each keyword in the count document, in the order specified by the
+ count document, the decrypted data holds R*8 bytes for the specified
+ instance of that keyword's blinded counter.
+
+ For example: if the count document lists the keywords "b", "x", "g",
+ and "a" (in that order), and lists instances "0", and "2", then the
+ decrypted data will hold the blinding values in this order:
+ b, instance 0
+ b, instance 2
+ x, instance 0
+ x, instance 2
+ g, instance 0
+ g, instance 2
+ a, instance 0
+ a, instance 2
+
+
+4. Implementation Notes
+
+ A relay should, when starting a new round, generate all the blinding
+ values and noise values in advance. The relay should then use these
+ values to compute Y_0 = SUM(B_i) + Z for each instance of each
+ counter. Having done this, the relay MUST encrypt the blinding values
+ to the public key of each tally reporter, and wipe them from memory.
+
+
+5. The hybrid encryption algorithm
+
+ We use a hybrid encryption scheme above, where items can be encrypted
+ to a public key. We instantiate it as follows, using curve25519
+ public keys.
+
+ To encrypt a plaintext M to a public key PK1
+ 1. the sender generates a new ephemeral keypair sk2, PK2.
+ 2. The sender computes the shared diffie hellman secret
+ SEED = (sk2 * PK1).
+
+ 3. The sender derives 64 bytes of key material as
+ SHAKE256(TEXT | SEED)[...64]
+ where "TEXT" is "Expand curve25519 for privcount encryption".
+
+ The first 32 bytes of this is an aes key K1;
+ the second 32 bytes are a mac key K2.
+
+ 4. The sender computes a ciphertext C as AES256_CTR(K1, M)
+
+ 5. The sender computes a MAC as
+ SHA3_256([00 00 00 00 00 00 00 20] | K2 | C)
+
+ 6. The hybrid-encrypted text is PK2 | MAC | C.
+
+
+6. An optimized alternative
+
+ As an alternative, the sequences of blinding values is NOT transmitted
+ to the tally reporters. Instead the client generates a single
+ ephemeral keypair sk_c, PK_c, and places the public key in its counts
+ document. It does this each time a new round begins.
+
+ For each tally reporter with public key PK_i, the client then does
+ the handshake sk_c * PK_i to compute SEED_i.
+
+ The client then generates the blinding values for that tally reporter
+ as SHAKE256(SEED_i)[...R*C*8].
+
+ After initializing the counters to Y_0, the client can discard the
+ blinding values and sk_c.
+
+ Later, the tally reporters can reconstruct the blinding values as
+ SHAKE256(sk_i * PK_c)[...]
+
+ This alternative allows the client to transmit only a single public
+ key, when previously it would need to transmit a complete set of
+ blinding factors for each tally reporter. Further, the alternative
+ does away with the need for blinding documents altogether. It is,
+ however, more sensitive to any defects in SHAKE256 than the design
+ above. Like the rest of this design, it would need rethinking if we
+ want to expand this scheme to work with anonymous data collectors,
+ such as Tor clients.
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