package octez-libs
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sha256=aa2f5bc99cc4ca2217c52a1af2a2cdfd3b383208cb859ca2e79ca0903396ca1d
sha512=d68bb3eb615e3dcccc845fddfc9901c95b3c6dc8e105e39522ce97637b1308a7fa7aa1d271351d5933febd7476b2819e1694f31198f1f0919681f1f9cc97cb3a
doc/tezos_context_disk/Tezos_context_disk/Context/Proof/Stream/index.html
Module Proof.Stream
Stream proofs represent an explicit traversal of a Merle tree proof. Every element (a node, a value, or a shallow pointer) met is first "compressed" by shallowing its children and then recorded in the proof.
As stream proofs directly encode the recursive construction of the Merkle root hash is slightly simpler to implement: verifier simply need to hash the compressed elements lazily, without any memory or choice.
Moreover, the minimality of stream proofs is trivial to check. Once the computation has consumed the compressed elements required, it is sufficient to check that no more compressed elements remain in the proof.
However, as the compressed elements contain all the hashes of their shallow children, the size of stream proofs is larger (at least double in size in practice) than tree proofs, which only contains the hash for intermediate shallow pointers.
type elt = | Value of bytes| Node of (string * [ `Value of Tezos_base.TzPervasives.Context_hash.t | `Node of Tezos_base.TzPervasives.Context_hash.t ]) list| Inode of Tezos_base.TzPervasives.Context_hash.t Tezos_context_sigs__Context.Proof_types.inode| Inode_extender of Tezos_base.TzPervasives.Context_hash.t Tezos_context_sigs__Context.Proof_types.inode_extender
The type for elements of stream proofs.
Value v is a proof that the next element read in the store is the value v.
Node n is a proof that the next element read in the store is the node n.
Inode i is a proof that the next element read in the store is the inode i.
Inode_extender e is a proof that the next element read in the store is the node extender e.
type t = unit -> elt Tezos_base.TzPervasives.Seq.nodeThe type for stream proofs.
The sequence e_1 ... e_n proves that the e_1, ..., e_n are read in the store in sequence.