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87 lines
5.7 KiB
ReStructuredText
87 lines
5.7 KiB
ReStructuredText
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Transaction tear-offs
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=====================
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.. topic:: Summary
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* *Hide transaction components for privacy purposes*
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* *Oracles and non-validating notaries can only see their "related" transaction components, but not the full transaction details*
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Overview
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--------
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There are cases where some of the entities involved on the transaction could only have partial visibility on the
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transaction parts. For instance, when an oracle should sign a transaction, the only information it needs to see is their
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embedded, related to this oracle, command(s). Similarly, a non-validating notary only needs to see a transaction's input
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states. Providing any additional transaction data to the oracle would constitute a privacy leak.
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To combat this, we use the concept of filtered transactions, in which the transaction proposer(s) uses a nested Merkle
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tree approach to "tear off" any parts of the transaction that the oracle/notary doesn't need to see before presenting it
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to them for signing. A Merkle tree is a well-known cryptographic scheme that is commonly used to provide proofs of
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inclusion and data integrity. Merkle trees are widely used in peer-to-peer networks, blockchain systems and git.
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The advantage of a Merkle tree is that the parts of the transaction that were torn off when presenting the transaction
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to the oracle cannot later be changed without also invalidating the oracle's digital signature.
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Transaction Merkle trees
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^^^^^^^^^^^^^^^^^^^^^^^^
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A Merkle tree is constructed from a transaction by splitting the transaction into leaves, where each leaf contains
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either an input, an output, a command, or an attachment. The final nested tree structure also contains the
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other fields of the transaction, such as the time-window, the notary and the required signers. As shown in the picture
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below, the only component type that is requiring two trees instead of one is the command, which is split into
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command data and required signers for visibility purposes.
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Corda is using a patent-pending approach using nested Merkle trees per component type. Briefly, a component sub-tree
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is generated for each component type (i.e., inputs, outputs, attachments). Then, the roots of these sub-trees
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form the leaves of the top Merkle tree and finally the root of this tree represents the transaction id.
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Another important feature is that a nonce is deterministically generated for each component in a way that each nonce
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is independent. Then, we use the nonces along with their corresponding components to calculate the component hash,
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which is the actual Merkle tree leaf. Nonces are required to protect against brute force attacks that otherwise would
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reveal the content of low-entropy hashed values (i.e., a single-word text attachment).
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After computing the leaves, each Merkle tree is built in the normal way by hashing the concatenation of nodes’ hashes
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below the current one together. It’s visible on the example image below, where ``H`` denotes sha256 function, "+" - concatenation.
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.. image:: resources/merkleTreeFull.png
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:scale: 35%
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:align: center
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The transaction has three input states, two output states, two commands, one attachment, a notary and a time-window.
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Notice that if a tree is not a full binary tree, leaves are padded to the nearest
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power of 2 with zero hash (since finding a pre-image of sha256(x) == 0 is hard computational task) - marked light
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green above. Finally, the hash of the root is the identifier of the transaction, it's also used for signing and
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verification of data integrity. Every change in transaction on a leaf level will change its identifier.
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Hiding data
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^^^^^^^^^^^
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Hiding data and providing the proof that it formed a part of a transaction is done by constructing partial Merkle trees
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(or Merkle branches). A Merkle branch is a set of hashes, that given the leaves’ data, is used to calculate the
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root’s hash. Then, that hash is compared with the hash of a whole transaction and if they match it means that data we
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obtained belongs to that particular transaction. In the following we provide concrete examples on the data visible to a
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an oracle and a non-validating notary, respectively.
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Let's assume that only the first command should be visible to an Oracle. We should also provide guarantees that all of
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the commands requiring a signature from this oracle should be visible to the oracle entity, but not the rest. Here is how
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this filtered transaction will be represented in the Merkle tree structure.
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.. image:: resources/SubMerkleTree_Oracle.png
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:scale: 35%
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:align: center
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Blue nodes and ``H(c2)`` are provided to the Oracle service, while the black ones are omitted. ``H(c2)`` is required, so
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that the Oracle can compute ``H(commandData)`` without being to able to see the second command, but at the same time
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ensuring ``CommandData1`` is part of the transaction. It is highlighted that all signers are visible, so as to have a
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proof that no related command (that the Oracle should see) has been maliciously filtered out. Additionally, hashes of
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sub-trees (violet nodes) are also provided in the current Corda protocol. The latter is required for special cases, i.e.,
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when required to know if a component group is empty or not.
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Having all of the aforementioned data, one can calculate the root of the top tree and compare it with original
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transaction identifier - we have a proof that this command and time-window belong to this transaction.
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Along the same lines, if we want to send the same transaction to a non-validating notary we should hide all components
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apart from input states, time-window and the notary information. This data is enough for the notary to know which
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input states should be checked for double-spending, if the time-window is valid and if this transaction should be
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notarised by this notary.
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.. image:: resources/SubMerkleTree_Notary.png
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:scale: 35%
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:align: center
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