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/*
Computes a deterministic minimal height merkle tree hash.
If the number of items is not a power of two, some leaves
will be at different levels. Tries to keep both sides of
the tree the same size, but the left may be one greater.
Use this for short deterministic trees, such as the validator list.
For larger datasets, use IAVLTree.
*
/ \
/ \
/ \
/ \
* *
/ \ / \
/ \ / \
/ \ / \
* * * h6
/ \ / \ / \
h0 h1 h2 h3 h4 h5
*/
package merkle
import (
"bytes"
"crypto/sha256"
"fmt"
"github.com/tendermint/tendermint/binary"
)
func SimpleHashFromTwoHashes(left []byte, right []byte) []byte {
var n int64
var err error
var hasher = sha256.New()
binary.WriteByteSlice(left, hasher, &n, &err)
binary.WriteByteSlice(right, hasher, &n, &err)
if err != nil {
panic(err)
}
return hasher.Sum(nil)
}
func SimpleHashFromHashes(hashes [][]byte) []byte {
// Recursive impl.
switch len(hashes) {
case 0:
return nil
case 1:
return hashes[0]
default:
left := SimpleHashFromHashes(hashes[:(len(hashes)+1)/2])
right := SimpleHashFromHashes(hashes[(len(hashes)+1)/2:])
return SimpleHashFromTwoHashes(left, right)
}
}
// Convenience for SimpleHashFromHashes.
func SimpleHashFromBinaries(items []interface{}) []byte {
hashes := [][]byte{}
for _, item := range items {
hashes = append(hashes, SimpleHashFromBinary(item))
}
return SimpleHashFromHashes(hashes)
}
// General Convenience
func SimpleHashFromBinary(item interface{}) []byte {
hasher, n, err := sha256.New(), new(int64), new(error)
binary.WriteBinary(item, hasher, n, err)
if *err != nil {
panic(err)
}
return hasher.Sum(nil)
}
// Convenience for SimpleHashFromHashes.
func SimpleHashFromHashables(items []Hashable) []byte {
hashes := [][]byte{}
for _, item := range items {
hash := item.Hash()
hashes = append(hashes, hash)
}
return SimpleHashFromHashes(hashes)
}
//--------------------------------------------------------------------------------
type SimpleProof struct {
Index int `json:"index"`
Total int `json:"total"`
LeafHash []byte `json:"leaf_hash"`
InnerHashes [][]byte `json:"inner_hashes"` // Hashes from leaf's sibling to a root's child.
RootHash []byte `json:"root_hash"`
}
// proofs[0] is the proof for items[0].
func SimpleProofsFromHashables(items []Hashable) (proofs []*SimpleProof) {
trails, root := trailsFromHashables(items)
proofs = make([]*SimpleProof, len(items))
for i, trail := range trails {
proofs[i] = &SimpleProof{
Index: i,
Total: len(items),
LeafHash: trail.Hash,
InnerHashes: trail.FlattenInnerHashes(),
RootHash: root.Hash,
}
}
return
}
// Verify that leafHash is a leaf hash of the simple-merkle-tree
// which hashes to rootHash.
func (sp *SimpleProof) Verify(leafHash []byte, rootHash []byte) bool {
if !bytes.Equal(leafHash, sp.LeafHash) {
return false
}
if !bytes.Equal(rootHash, sp.RootHash) {
return false
}
computedHash := computeHashFromInnerHashes(sp.Index, sp.Total, sp.LeafHash, sp.InnerHashes)
if computedHash == nil {
return false
}
if !bytes.Equal(computedHash, rootHash) {
return false
}
return true
}
func (sp *SimpleProof) String() string {
return sp.StringIndented("")
}
func (sp *SimpleProof) StringIndented(indent string) string {
return fmt.Sprintf(`SimpleProof{
%s Index: %v
%s Total: %v
%s LeafHash: %X
%s InnerHashes: %X
%s RootHash: %X
%s}`,
indent, sp.Index,
indent, sp.Total,
indent, sp.LeafHash,
indent, sp.InnerHashes,
indent, sp.RootHash,
indent)
}
// Use the leafHash and innerHashes to get the root merkle hash.
// If the length of the innerHashes slice isn't exactly correct, the result is nil.
func computeHashFromInnerHashes(index int, total int, leafHash []byte, innerHashes [][]byte) []byte {
// Recursive impl.
if index >= total {
return nil
}
switch total {
case 0:
panic("Cannot call computeHashFromInnerHashes() with 0 total")
case 1:
if len(innerHashes) != 0 {
return nil
}
return leafHash
default:
if len(innerHashes) == 0 {
return nil
}
numLeft := (total + 1) / 2
if index < numLeft {
leftHash := computeHashFromInnerHashes(index, numLeft, leafHash, innerHashes[:len(innerHashes)-1])
if leftHash == nil {
return nil
}
return SimpleHashFromTwoHashes(leftHash, innerHashes[len(innerHashes)-1])
} else {
rightHash := computeHashFromInnerHashes(index-numLeft, total-numLeft, leafHash, innerHashes[:len(innerHashes)-1])
if rightHash == nil {
return nil
}
return SimpleHashFromTwoHashes(innerHashes[len(innerHashes)-1], rightHash)
}
}
}
// Helper structure to construct merkle proof.
// The node and the tree is thrown away afterwards.
// Exactly one of node.Left and node.Right is nil, unless node is the root, in which case both are nil.
// node.Parent.Hash = hash(node.Hash, node.Right.Hash) or
// hash(node.Left.Hash, node.Hash), depending on whether node is a left/right child.
type SimpleProofNode struct {
Hash []byte
Parent *SimpleProofNode
Left *SimpleProofNode // Left sibling (only one of Left,Right is set)
Right *SimpleProofNode // Right sibling (only one of Left,Right is set)
}
// Starting from a leaf SimpleProofNode, FlattenInnerHashes() will return
// the inner hashes for the item corresponding to the leaf.
func (spn *SimpleProofNode) FlattenInnerHashes() [][]byte {
// Nonrecursive impl.
innerHashes := [][]byte{}
for spn != nil {
if spn.Left != nil {
innerHashes = append(innerHashes, spn.Left.Hash)
} else if spn.Right != nil {
innerHashes = append(innerHashes, spn.Right.Hash)
} else {
break
}
spn = spn.Parent
}
return innerHashes
}
// trails[0].Hash is the leaf hash for items[0].
// trails[i].Parent.Parent....Parent == root for all i.
func trailsFromHashables(items []Hashable) (trails []*SimpleProofNode, root *SimpleProofNode) {
// Recursive impl.
switch len(items) {
case 0:
return nil, nil
case 1:
trail := &SimpleProofNode{items[0].Hash(), nil, nil, nil}
return []*SimpleProofNode{trail}, trail
default:
lefts, leftRoot := trailsFromHashables(items[:(len(items)+1)/2])
rights, rightRoot := trailsFromHashables(items[(len(items)+1)/2:])
rootHash := SimpleHashFromTwoHashes(leftRoot.Hash, rightRoot.Hash)
root := &SimpleProofNode{rootHash, nil, nil, nil}
leftRoot.Parent = root
leftRoot.Right = rightRoot
rightRoot.Parent = root
rightRoot.Left = leftRoot
return append(lefts, rights...), root
}
}