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1ccaf2ef06
* Add ibc swagger fetch in Makefile proto-update-deps * Update third_party proto files * Update swagger to include all Kava modules and IBC * Add api url to swagger config * Remove old swagger-ui directory * Add cleaned legacy-swagger.yml * Remove cosmos endpoints from legacy swagger * Remove invalid values, add legacy-swagger to merge config * Remove unused definitions * Fix legacy swagger type errors * Clean up mismatch names, deprecate legacy endpoints * Remove separate incentive-legacy-swagger.yml * Update title * Include legacy in title * Re-build swagger conf with updated title
235 lines
7.7 KiB
Protocol Buffer
235 lines
7.7 KiB
Protocol Buffer
syntax = "proto3";
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package ics23;
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option go_package = "github.com/confio/ics23/go";
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enum HashOp {
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// NO_HASH is the default if no data passed. Note this is an illegal argument some places.
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NO_HASH = 0;
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SHA256 = 1;
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SHA512 = 2;
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KECCAK = 3;
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RIPEMD160 = 4;
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BITCOIN = 5; // ripemd160(sha256(x))
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}
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/**
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LengthOp defines how to process the key and value of the LeafOp
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to include length information. After encoding the length with the given
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algorithm, the length will be prepended to the key and value bytes.
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(Each one with it's own encoded length)
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*/
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enum LengthOp {
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// NO_PREFIX don't include any length info
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NO_PREFIX = 0;
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// VAR_PROTO uses protobuf (and go-amino) varint encoding of the length
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VAR_PROTO = 1;
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// VAR_RLP uses rlp int encoding of the length
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VAR_RLP = 2;
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// FIXED32_BIG uses big-endian encoding of the length as a 32 bit integer
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FIXED32_BIG = 3;
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// FIXED32_LITTLE uses little-endian encoding of the length as a 32 bit integer
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FIXED32_LITTLE = 4;
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// FIXED64_BIG uses big-endian encoding of the length as a 64 bit integer
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FIXED64_BIG = 5;
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// FIXED64_LITTLE uses little-endian encoding of the length as a 64 bit integer
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FIXED64_LITTLE = 6;
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// REQUIRE_32_BYTES is like NONE, but will fail if the input is not exactly 32 bytes (sha256 output)
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REQUIRE_32_BYTES = 7;
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// REQUIRE_64_BYTES is like NONE, but will fail if the input is not exactly 64 bytes (sha512 output)
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REQUIRE_64_BYTES = 8;
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}
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/**
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ExistenceProof takes a key and a value and a set of steps to perform on it.
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The result of peforming all these steps will provide a "root hash", which can
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be compared to the value in a header.
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Since it is computationally infeasible to produce a hash collission for any of the used
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cryptographic hash functions, if someone can provide a series of operations to transform
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a given key and value into a root hash that matches some trusted root, these key and values
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must be in the referenced merkle tree.
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The only possible issue is maliablity in LeafOp, such as providing extra prefix data,
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which should be controlled by a spec. Eg. with lengthOp as NONE,
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prefix = FOO, key = BAR, value = CHOICE
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and
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prefix = F, key = OOBAR, value = CHOICE
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would produce the same value.
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With LengthOp this is tricker but not impossible. Which is why the "leafPrefixEqual" field
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in the ProofSpec is valuable to prevent this mutability. And why all trees should
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length-prefix the data before hashing it.
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*/
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message ExistenceProof {
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bytes key = 1;
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bytes value = 2;
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LeafOp leaf = 3;
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repeated InnerOp path = 4;
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}
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/*
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NonExistenceProof takes a proof of two neighbors, one left of the desired key,
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one right of the desired key. If both proofs are valid AND they are neighbors,
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then there is no valid proof for the given key.
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*/
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message NonExistenceProof {
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bytes key = 1; // TODO: remove this as unnecessary??? we prove a range
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ExistenceProof left = 2;
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ExistenceProof right = 3;
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}
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/*
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CommitmentProof is either an ExistenceProof or a NonExistenceProof, or a Batch of such messages
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*/
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message CommitmentProof {
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oneof proof {
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ExistenceProof exist = 1;
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NonExistenceProof nonexist = 2;
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BatchProof batch = 3;
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CompressedBatchProof compressed = 4;
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}
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}
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/**
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LeafOp represents the raw key-value data we wish to prove, and
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must be flexible to represent the internal transformation from
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the original key-value pairs into the basis hash, for many existing
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merkle trees.
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key and value are passed in. So that the signature of this operation is:
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leafOp(key, value) -> output
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To process this, first prehash the keys and values if needed (ANY means no hash in this case):
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hkey = prehashKey(key)
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hvalue = prehashValue(value)
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Then combine the bytes, and hash it
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output = hash(prefix || length(hkey) || hkey || length(hvalue) || hvalue)
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*/
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message LeafOp {
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HashOp hash = 1;
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HashOp prehash_key = 2;
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HashOp prehash_value = 3;
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LengthOp length = 4;
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// prefix is a fixed bytes that may optionally be included at the beginning to differentiate
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// a leaf node from an inner node.
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bytes prefix = 5;
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}
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/**
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InnerOp represents a merkle-proof step that is not a leaf.
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It represents concatenating two children and hashing them to provide the next result.
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The result of the previous step is passed in, so the signature of this op is:
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innerOp(child) -> output
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The result of applying InnerOp should be:
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output = op.hash(op.prefix || child || op.suffix)
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where the || operator is concatenation of binary data,
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and child is the result of hashing all the tree below this step.
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Any special data, like prepending child with the length, or prepending the entire operation with
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some value to differentiate from leaf nodes, should be included in prefix and suffix.
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If either of prefix or suffix is empty, we just treat it as an empty string
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*/
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message InnerOp {
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HashOp hash = 1;
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bytes prefix = 2;
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bytes suffix = 3;
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}
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/**
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ProofSpec defines what the expected parameters are for a given proof type.
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This can be stored in the client and used to validate any incoming proofs.
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verify(ProofSpec, Proof) -> Proof | Error
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As demonstrated in tests, if we don't fix the algorithm used to calculate the
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LeafHash for a given tree, there are many possible key-value pairs that can
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generate a given hash (by interpretting the preimage differently).
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We need this for proper security, requires client knows a priori what
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tree format server uses. But not in code, rather a configuration object.
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*/
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message ProofSpec {
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// any field in the ExistenceProof must be the same as in this spec.
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// except Prefix, which is just the first bytes of prefix (spec can be longer)
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LeafOp leaf_spec = 1;
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InnerSpec inner_spec = 2;
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// max_depth (if > 0) is the maximum number of InnerOps allowed (mainly for fixed-depth tries)
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int32 max_depth = 3;
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// min_depth (if > 0) is the minimum number of InnerOps allowed (mainly for fixed-depth tries)
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int32 min_depth = 4;
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}
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/*
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InnerSpec contains all store-specific structure info to determine if two proofs from a
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given store are neighbors.
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This enables:
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isLeftMost(spec: InnerSpec, op: InnerOp)
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isRightMost(spec: InnerSpec, op: InnerOp)
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isLeftNeighbor(spec: InnerSpec, left: InnerOp, right: InnerOp)
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*/
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message InnerSpec {
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// Child order is the ordering of the children node, must count from 0
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// iavl tree is [0, 1] (left then right)
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// merk is [0, 2, 1] (left, right, here)
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repeated int32 child_order = 1;
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int32 child_size = 2;
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int32 min_prefix_length = 3;
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int32 max_prefix_length = 4;
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// empty child is the prehash image that is used when one child is nil (eg. 20 bytes of 0)
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bytes empty_child = 5;
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// hash is the algorithm that must be used for each InnerOp
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HashOp hash = 6;
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}
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/*
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BatchProof is a group of multiple proof types than can be compressed
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*/
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message BatchProof {
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repeated BatchEntry entries = 1;
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}
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// Use BatchEntry not CommitmentProof, to avoid recursion
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message BatchEntry {
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oneof proof {
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ExistenceProof exist = 1;
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NonExistenceProof nonexist = 2;
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}
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}
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/****** all items here are compressed forms *******/
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message CompressedBatchProof {
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repeated CompressedBatchEntry entries = 1;
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repeated InnerOp lookup_inners = 2;
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}
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// Use BatchEntry not CommitmentProof, to avoid recursion
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message CompressedBatchEntry {
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oneof proof {
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CompressedExistenceProof exist = 1;
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CompressedNonExistenceProof nonexist = 2;
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}
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}
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message CompressedExistenceProof {
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bytes key = 1;
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bytes value = 2;
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LeafOp leaf = 3;
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// these are indexes into the lookup_inners table in CompressedBatchProof
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repeated int32 path = 4;
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}
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message CompressedNonExistenceProof {
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bytes key = 1; // TODO: remove this as unnecessary??? we prove a range
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CompressedExistenceProof left = 2;
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CompressedExistenceProof right = 3;
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}
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