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222 lines
8.7 KiB
222 lines
8.7 KiB
/**
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* @file
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* @copyright defined in aergo/LICENSE.txt
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*/
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package trie
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import (
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"bytes"
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)
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// MerkleProof generates a Merke proof of inclusion or non-inclusion
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// for the current trie root
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// returns the audit path, bool (key included), key, value, error
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// (key,value) can be 1- (nil, value), value of the included key, 2- the kv of a LeafNode
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// on the path of the non-included key, 3- (nil, nil) for a non-included key
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// with a DefaultLeaf on the path
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func (s *Trie) MerkleProof(key []byte) ([][]byte, bool, []byte, []byte, error) {
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s.lock.RLock()
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defer s.lock.RUnlock()
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s.atomicUpdate = false // so loadChildren doesnt return a copy
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return s.merkleProof(s.Root, key, nil, s.TrieHeight, 0)
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}
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// MerkleProofPast generates a Merke proof of inclusion or non-inclusion
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// for a given past trie root
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// returns the audit path, bool (key included), key, value, error
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// (key,value) can be 1- (nil, value), value of the included key, 2- the kv of a LeafNode
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// on the path of the non-included key, 3- (nil, nil) for a non-included key
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// with a DefaultLeaf on the path
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func (s *Trie) MerkleProofR(key, root []byte) ([][]byte, bool, []byte, []byte, error) {
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s.lock.RLock()
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defer s.lock.RUnlock()
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s.atomicUpdate = false // so loadChildren doesnt return a copy
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return s.merkleProof(root, key, nil, s.TrieHeight, 0)
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}
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// MerkleProofCompressed returns a compressed merkle proof in the given trie
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func (s *Trie) MerkleProofCompressedR(key, root []byte) ([]byte, [][]byte, int, bool, []byte, []byte, error) {
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return s.merkleProofCompressed(key, root)
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}
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// MerkleProofCompressed returns a compressed merkle proof
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func (s *Trie) MerkleProofCompressed(key []byte) ([]byte, [][]byte, int, bool, []byte, []byte, error) {
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return s.merkleProofCompressed(key, s.Root)
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}
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func (s *Trie) merkleProofCompressed(key, root []byte) ([]byte, [][]byte, int, bool, []byte, []byte, error) {
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s.lock.RLock()
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defer s.lock.RUnlock()
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s.atomicUpdate = false // so loadChildren doesnt return a copy
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// create a regular merkle proof and then compress it
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mpFull, included, proofKey, proofVal, err := s.merkleProof(root, key, nil, s.TrieHeight, 0)
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if err != nil {
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return nil, nil, 0, true, nil, nil, err
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}
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// the height of the shortcut in the tree will be needed for the proof verification
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height := len(mpFull)
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var mp [][]byte
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bitmap := make([]byte, len(mpFull)/8+1)
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for i, node := range mpFull {
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if !bytes.Equal(node, DefaultLeaf) {
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bitSet(bitmap, i)
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mp = append(mp, node)
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}
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}
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return bitmap, mp, height, included, proofKey, proofVal, nil
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}
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// merkleProof generates a Merke proof of inclusion or non-inclusion
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// for a given trie root.
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// returns the audit path, bool (key included), key, value, error
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// (key,value) can be 1- (nil, value), value of the included key, 2- the kv of a LeafNode
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// on the path of the non-included key, 3- (nil, nil) for a non-included key
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// with a DefaultLeaf on the path
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func (s *Trie) merkleProof(root, key []byte, batch [][]byte, height, iBatch int) ([][]byte, bool, []byte, []byte, error) {
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if len(root) == 0 {
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// proove that an empty subtree is on the path of the key
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return nil, false, nil, nil, nil
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}
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// Fetch the children of the node
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batch, iBatch, lnode, rnode, isShortcut, err := s.loadChildren(root, height, iBatch, batch)
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if err != nil {
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return nil, false, nil, nil, err
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}
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if isShortcut || height == 0 {
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if bytes.Equal(lnode[:HashLength], key) {
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// return the value so a call to trie.Get() is not needed.
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return nil, true, nil, rnode[:HashLength], nil
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}
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// Return the proof of the leaf key that is on the path of the non included key
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return nil, false, lnode[:HashLength], rnode[:HashLength], nil
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}
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// append the left or right node to the proof
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if bitIsSet(key, s.TrieHeight-height) {
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mp, included, proofKey, proofValue, err := s.merkleProof(rnode, key, batch, height-1, 2*iBatch+2)
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if err != nil {
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return nil, false, nil, nil, err
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}
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if len(lnode) != 0 {
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return append(mp, lnode[:HashLength]), included, proofKey, proofValue, nil
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} else {
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return append(mp, DefaultLeaf), included, proofKey, proofValue, nil
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}
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}
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mp, included, proofKey, proofValue, err := s.merkleProof(lnode, key, batch, height-1, 2*iBatch+1)
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if err != nil {
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return nil, false, nil, nil, err
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}
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if len(rnode) != 0 {
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return append(mp, rnode[:HashLength]), included, proofKey, proofValue, nil
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} else {
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return append(mp, DefaultLeaf), included, proofKey, proofValue, nil
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}
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}
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// VerifyInclusion verifies that key/value is included in the trie with latest root
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func (s *Trie) VerifyInclusion(ap [][]byte, key, value []byte) bool {
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leafHash := s.hash(key, value, []byte{byte(s.TrieHeight - len(ap))})
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return bytes.Equal(s.Root, s.verifyInclusion(ap, 0, key, leafHash))
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}
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// VerifyInclusionWithRoot verifies that key/value is included in the trie with provided root
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func (s *Trie) VerifyInclusionWithRoot(root []byte, ap [][]byte, key, value []byte) bool {
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leafHash := s.hash(key, value, []byte{byte(s.TrieHeight - len(ap))})
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return bytes.Equal(root, s.verifyInclusion(ap, 0, key, leafHash))
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}
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// verifyInclusion returns the merkle root by hashing the merkle proof items
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func (s *Trie) verifyInclusion(ap [][]byte, keyIndex int, key, leafHash []byte) []byte {
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if keyIndex == len(ap) {
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return leafHash
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}
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if bitIsSet(key, keyIndex) {
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return s.hash(ap[len(ap)-keyIndex-1], s.verifyInclusion(ap, keyIndex+1, key, leafHash))
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}
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return s.hash(s.verifyInclusion(ap, keyIndex+1, key, leafHash), ap[len(ap)-keyIndex-1])
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}
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// VerifyNonInclusion verifies a proof of non inclusion,
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// Returns true if the non-inclusion is verified
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func (s *Trie) VerifyNonInclusion(ap [][]byte, key, value, proofKey []byte) bool {
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// Check if an empty subtree is on the key path
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if len(proofKey) == 0 {
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// return true if a DefaultLeaf in the key path is included in the trie
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return bytes.Equal(s.Root, s.verifyInclusion(ap, 0, key, DefaultLeaf))
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}
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// Check if another kv leaf is on the key path in 2 steps
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// 1- Check the proof leaf exists
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if !s.VerifyInclusion(ap, proofKey, value) {
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// the proof leaf is not included in the trie
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return false
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}
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// 2- Check the proof leaf is on the key path
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var b int
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for b = 0; b < len(ap); b++ {
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if bitIsSet(key, b) != bitIsSet(proofKey, b) {
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// the proofKey leaf node is not on the path of the key
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return false
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}
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}
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// return true because we verified another leaf is on the key path
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return true
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}
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// VerifyInclusionC verifies that key/value is included in the trie with latest root
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func (s *Trie) VerifyInclusionC(bitmap, key, value []byte, ap [][]byte, length int) bool {
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leafHash := s.hash(key, value, []byte{byte(s.TrieHeight - length)})
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return bytes.Equal(s.Root, s.verifyInclusionC(bitmap, key, leafHash, ap, length, 0, 0))
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}
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// VerifyInclusionWithRootC verifies that key/value is included in the trie with latest root
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func (s *Trie) VerifyInclusionWithRootC(root, bitmap, key, value []byte, ap [][]byte, length int) bool {
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leafHash := s.hash(key, value, []byte{byte(s.TrieHeight - length)})
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return bytes.Equal(root, s.verifyInclusionC(bitmap, key, leafHash, ap, length, 0, 0))
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}
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// verifyInclusionC returns the merkle root by hashing the merkle proof items
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func (s *Trie) verifyInclusionC(bitmap, key, leafHash []byte, ap [][]byte, length, keyIndex, apIndex int) []byte {
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if keyIndex == length {
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return leafHash
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}
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if bitIsSet(key, keyIndex) {
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if bitIsSet(bitmap, length-keyIndex-1) {
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return s.hash(ap[len(ap)-apIndex-1], s.verifyInclusionC(bitmap, key, leafHash, ap, length, keyIndex+1, apIndex+1))
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}
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return s.hash(DefaultLeaf, s.verifyInclusionC(bitmap, key, leafHash, ap, length, keyIndex+1, apIndex))
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}
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if bitIsSet(bitmap, length-keyIndex-1) {
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return s.hash(s.verifyInclusionC(bitmap, key, leafHash, ap, length, keyIndex+1, apIndex+1), ap[len(ap)-apIndex-1])
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}
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return s.hash(s.verifyInclusionC(bitmap, key, leafHash, ap, length, keyIndex+1, apIndex), DefaultLeaf)
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}
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// VerifyNonInclusionC verifies a proof of non inclusion,
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// Returns true if the non-inclusion is verified
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func (s *Trie) VerifyNonInclusionC(ap [][]byte, length int, bitmap, key, value, proofKey []byte) bool {
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// Check if an empty subtree is on the key path
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if len(proofKey) == 0 {
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// return true if a DefaultLeaf in the key path is included in the trie
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return bytes.Equal(s.Root, s.verifyInclusionC(bitmap, key, DefaultLeaf, ap, length, 0, 0))
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}
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// Check if another kv leaf is on the key path in 2 steps
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// 1- Check the proof leaf exists
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if !s.VerifyInclusionC(bitmap, proofKey, value, ap, length) {
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// the proof leaf is not included in the trie
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return false
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}
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// 2- Check the proof leaf is on the key path
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var b int
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for b = 0; b < length; b++ {
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if bitIsSet(key, b) != bitIsSet(proofKey, b) {
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// the proofKey leaf node is not on the path of the key
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return false
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}
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}
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// return true because we verified another leaf is on the key path
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return true
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}
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