mirror of https://github.com/status-im/op-geth.git
691 lines
22 KiB
Go
691 lines
22 KiB
Go
// Copyright 2018 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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// Package bmt provides a binary merkle tree implementation used for swarm chunk hash
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package bmt
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import (
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"fmt"
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"hash"
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"strings"
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"sync"
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"sync/atomic"
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)
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/*
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Binary Merkle Tree Hash is a hash function over arbitrary datachunks of limited size.
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It is defined as the root hash of the binary merkle tree built over fixed size segments
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of the underlying chunk using any base hash function (e.g., keccak 256 SHA3).
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Chunks with data shorter than the fixed size are hashed as if they had zero padding.
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BMT hash is used as the chunk hash function in swarm which in turn is the basis for the
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128 branching swarm hash http://swarm-guide.readthedocs.io/en/latest/architecture.html#swarm-hash
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The BMT is optimal for providing compact inclusion proofs, i.e. prove that a
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segment is a substring of a chunk starting at a particular offset.
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The size of the underlying segments is fixed to the size of the base hash (called the resolution
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of the BMT hash), Using Keccak256 SHA3 hash is 32 bytes, the EVM word size to optimize for on-chain BMT verification
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as well as the hash size optimal for inclusion proofs in the merkle tree of the swarm hash.
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Two implementations are provided:
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* RefHasher is optimized for code simplicity and meant as a reference implementation
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that is simple to understand
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* Hasher is optimized for speed taking advantage of concurrency with minimalistic
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control structure to coordinate the concurrent routines
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BMT Hasher implements the following interfaces
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* standard golang hash.Hash - synchronous, reusable
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* SwarmHash - SumWithSpan provided
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* io.Writer - synchronous left-to-right datawriter
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* AsyncWriter - concurrent section writes and asynchronous Sum call
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*/
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const (
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// PoolSize is the maximum number of bmt trees used by the hashers, i.e,
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// the maximum number of concurrent BMT hashing operations performed by the same hasher
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PoolSize = 8
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)
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// BaseHasherFunc is a hash.Hash constructor function used for the base hash of the BMT.
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// implemented by Keccak256 SHA3 sha3.NewKeccak256
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type BaseHasherFunc func() hash.Hash
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// Hasher a reusable hasher for fixed maximum size chunks representing a BMT
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// - implements the hash.Hash interface
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// - reuses a pool of trees for amortised memory allocation and resource control
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// - supports order-agnostic concurrent segment writes and section (double segment) writes
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// as well as sequential read and write
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// - the same hasher instance must not be called concurrently on more than one chunk
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// - the same hasher instance is synchronously reuseable
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// - Sum gives back the tree to the pool and guaranteed to leave
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// the tree and itself in a state reusable for hashing a new chunk
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// - generates and verifies segment inclusion proofs (TODO:)
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type Hasher struct {
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pool *TreePool // BMT resource pool
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bmt *tree // prebuilt BMT resource for flowcontrol and proofs
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}
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// New creates a reusable BMT Hasher that
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// pulls a new tree from a resource pool for hashing each chunk
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func New(p *TreePool) *Hasher {
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return &Hasher{
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pool: p,
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}
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}
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// TreePool provides a pool of trees used as resources by the BMT Hasher.
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// A tree popped from the pool is guaranteed to have a clean state ready
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// for hashing a new chunk.
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type TreePool struct {
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lock sync.Mutex
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c chan *tree // the channel to obtain a resource from the pool
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hasher BaseHasherFunc // base hasher to use for the BMT levels
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SegmentSize int // size of leaf segments, stipulated to be = hash size
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SegmentCount int // the number of segments on the base level of the BMT
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Capacity int // pool capacity, controls concurrency
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Depth int // depth of the bmt trees = int(log2(segmentCount))+1
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Size int // the total length of the data (count * size)
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count int // current count of (ever) allocated resources
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zerohashes [][]byte // lookup table for predictable padding subtrees for all levels
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}
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// NewTreePool creates a tree pool with hasher, segment size, segment count and capacity
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// on Hasher.getTree it reuses free trees or creates a new one if capacity is not reached
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func NewTreePool(hasher BaseHasherFunc, segmentCount, capacity int) *TreePool {
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// initialises the zerohashes lookup table
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depth := calculateDepthFor(segmentCount)
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segmentSize := hasher().Size()
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zerohashes := make([][]byte, depth+1)
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zeros := make([]byte, segmentSize)
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zerohashes[0] = zeros
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h := hasher()
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for i := 1; i < depth+1; i++ {
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zeros = doSum(h, nil, zeros, zeros)
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zerohashes[i] = zeros
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}
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return &TreePool{
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c: make(chan *tree, capacity),
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hasher: hasher,
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SegmentSize: segmentSize,
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SegmentCount: segmentCount,
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Capacity: capacity,
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Size: segmentCount * segmentSize,
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Depth: depth,
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zerohashes: zerohashes,
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}
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}
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// Drain drains the pool until it has no more than n resources
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func (p *TreePool) Drain(n int) {
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p.lock.Lock()
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defer p.lock.Unlock()
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for len(p.c) > n {
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<-p.c
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p.count--
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}
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}
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// Reserve is blocking until it returns an available tree
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// it reuses free trees or creates a new one if size is not reached
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// TODO: should use a context here
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func (p *TreePool) reserve() *tree {
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p.lock.Lock()
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defer p.lock.Unlock()
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var t *tree
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if p.count == p.Capacity {
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return <-p.c
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}
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select {
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case t = <-p.c:
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default:
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t = newTree(p.SegmentSize, p.Depth, p.hasher)
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p.count++
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}
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return t
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}
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// release gives back a tree to the pool.
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// this tree is guaranteed to be in reusable state
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func (p *TreePool) release(t *tree) {
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p.c <- t // can never fail ...
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}
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// tree is a reusable control structure representing a BMT
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// organised in a binary tree
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// Hasher uses a TreePool to obtain a tree for each chunk hash
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// the tree is 'locked' while not in the pool
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type tree struct {
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leaves []*node // leaf nodes of the tree, other nodes accessible via parent links
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cursor int // index of rightmost currently open segment
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offset int // offset (cursor position) within currently open segment
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section []byte // the rightmost open section (double segment)
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result chan []byte // result channel
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span []byte // The span of the data subsumed under the chunk
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}
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// node is a reuseable segment hasher representing a node in a BMT
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type node struct {
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isLeft bool // whether it is left side of the parent double segment
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parent *node // pointer to parent node in the BMT
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state int32 // atomic increment impl concurrent boolean toggle
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left, right []byte // this is where the two children sections are written
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hasher hash.Hash // preconstructed hasher on nodes
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}
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// newNode constructs a segment hasher node in the BMT (used by newTree)
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func newNode(index int, parent *node, hasher hash.Hash) *node {
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return &node{
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parent: parent,
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isLeft: index%2 == 0,
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hasher: hasher,
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}
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}
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// Draw draws the BMT (badly)
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func (t *tree) draw(hash []byte) string {
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var left, right []string
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var anc []*node
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for i, n := range t.leaves {
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left = append(left, fmt.Sprintf("%v", hashstr(n.left)))
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if i%2 == 0 {
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anc = append(anc, n.parent)
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}
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right = append(right, fmt.Sprintf("%v", hashstr(n.right)))
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}
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anc = t.leaves
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var hashes [][]string
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for l := 0; len(anc) > 0; l++ {
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var nodes []*node
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hash := []string{""}
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for i, n := range anc {
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hash = append(hash, fmt.Sprintf("%v|%v", hashstr(n.left), hashstr(n.right)))
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if i%2 == 0 && n.parent != nil {
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nodes = append(nodes, n.parent)
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}
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}
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hash = append(hash, "")
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hashes = append(hashes, hash)
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anc = nodes
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}
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hashes = append(hashes, []string{"", fmt.Sprintf("%v", hashstr(hash)), ""})
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total := 60
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del := " "
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var rows []string
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for i := len(hashes) - 1; i >= 0; i-- {
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var textlen int
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hash := hashes[i]
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for _, s := range hash {
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textlen += len(s)
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}
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if total < textlen {
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total = textlen + len(hash)
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}
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delsize := (total - textlen) / (len(hash) - 1)
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if delsize > len(del) {
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delsize = len(del)
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}
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row := fmt.Sprintf("%v: %v", len(hashes)-i-1, strings.Join(hash, del[:delsize]))
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rows = append(rows, row)
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}
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rows = append(rows, strings.Join(left, " "))
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rows = append(rows, strings.Join(right, " "))
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return strings.Join(rows, "\n") + "\n"
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}
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// newTree initialises a tree by building up the nodes of a BMT
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// - segment size is stipulated to be the size of the hash
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func newTree(segmentSize, depth int, hashfunc func() hash.Hash) *tree {
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n := newNode(0, nil, hashfunc())
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prevlevel := []*node{n}
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// iterate over levels and creates 2^(depth-level) nodes
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// the 0 level is on double segment sections so we start at depth - 2 since
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count := 2
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for level := depth - 2; level >= 0; level-- {
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nodes := make([]*node, count)
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for i := 0; i < count; i++ {
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parent := prevlevel[i/2]
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var hasher hash.Hash
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if level == 0 {
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hasher = hashfunc()
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}
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nodes[i] = newNode(i, parent, hasher)
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}
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prevlevel = nodes
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count *= 2
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}
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// the datanode level is the nodes on the last level
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return &tree{
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leaves: prevlevel,
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result: make(chan []byte),
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section: make([]byte, 2*segmentSize),
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}
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}
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// methods needed to implement hash.Hash
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// Size returns the size
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func (h *Hasher) Size() int {
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return h.pool.SegmentSize
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}
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// BlockSize returns the block size
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func (h *Hasher) BlockSize() int {
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return 2 * h.pool.SegmentSize
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}
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// Sum returns the BMT root hash of the buffer
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// using Sum presupposes sequential synchronous writes (io.Writer interface)
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// hash.Hash interface Sum method appends the byte slice to the underlying
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// data before it calculates and returns the hash of the chunk
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// caller must make sure Sum is not called concurrently with Write, writeSection
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func (h *Hasher) Sum(b []byte) (s []byte) {
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t := h.getTree()
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// write the last section with final flag set to true
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go h.writeSection(t.cursor, t.section, true, true)
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// wait for the result
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s = <-t.result
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span := t.span
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// release the tree resource back to the pool
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h.releaseTree()
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// b + sha3(span + BMT(pure_chunk))
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if len(span) == 0 {
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return append(b, s...)
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}
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return doSum(h.pool.hasher(), b, span, s)
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}
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// methods needed to implement the SwarmHash and the io.Writer interfaces
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// Write calls sequentially add to the buffer to be hashed,
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// with every full segment calls writeSection in a go routine
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func (h *Hasher) Write(b []byte) (int, error) {
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l := len(b)
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if l == 0 || l > h.pool.Size {
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return 0, nil
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}
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t := h.getTree()
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secsize := 2 * h.pool.SegmentSize
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// calculate length of missing bit to complete current open section
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smax := secsize - t.offset
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// if at the beginning of chunk or middle of the section
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if t.offset < secsize {
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// fill up current segment from buffer
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copy(t.section[t.offset:], b)
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// if input buffer consumed and open section not complete, then
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// advance offset and return
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if smax == 0 {
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smax = secsize
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}
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if l <= smax {
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t.offset += l
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return l, nil
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}
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} else {
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// if end of a section
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if t.cursor == h.pool.SegmentCount*2 {
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return 0, nil
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}
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}
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// read full sections and the last possibly partial section from the input buffer
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for smax < l {
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// section complete; push to tree asynchronously
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go h.writeSection(t.cursor, t.section, true, false)
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// reset section
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t.section = make([]byte, secsize)
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// copy from input buffer at smax to right half of section
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copy(t.section, b[smax:])
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// advance cursor
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t.cursor++
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// smax here represents successive offsets in the input buffer
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smax += secsize
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}
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t.offset = l - smax + secsize
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return l, nil
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}
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// Reset needs to be called before writing to the hasher
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func (h *Hasher) Reset() {
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h.releaseTree()
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}
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// methods needed to implement the SwarmHash interface
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// ResetWithLength needs to be called before writing to the hasher
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// the argument is supposed to be the byte slice binary representation of
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// the length of the data subsumed under the hash, i.e., span
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func (h *Hasher) ResetWithLength(span []byte) {
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h.Reset()
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h.getTree().span = span
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}
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// releaseTree gives back the Tree to the pool whereby it unlocks
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// it resets tree, segment and index
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func (h *Hasher) releaseTree() {
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t := h.bmt
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if t == nil {
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return
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}
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h.bmt = nil
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go func() {
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t.cursor = 0
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t.offset = 0
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t.span = nil
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t.section = make([]byte, h.pool.SegmentSize*2)
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select {
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case <-t.result:
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default:
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}
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h.pool.release(t)
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}()
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}
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// NewAsyncWriter extends Hasher with an interface for concurrent segment/section writes
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func (h *Hasher) NewAsyncWriter(double bool) *AsyncHasher {
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secsize := h.pool.SegmentSize
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if double {
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secsize *= 2
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}
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write := func(i int, section []byte, final bool) {
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h.writeSection(i, section, double, final)
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}
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return &AsyncHasher{
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Hasher: h,
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double: double,
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secsize: secsize,
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write: write,
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}
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}
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// SectionWriter is an asynchronous segment/section writer interface
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type SectionWriter interface {
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Reset() // standard init to be called before reuse
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Write(index int, data []byte) // write into section of index
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Sum(b []byte, length int, span []byte) []byte // returns the hash of the buffer
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SectionSize() int // size of the async section unit to use
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}
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// AsyncHasher extends BMT Hasher with an asynchronous segment/section writer interface
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// AsyncHasher is unsafe and does not check indexes and section data lengths
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// it must be used with the right indexes and length and the right number of sections
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//
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// behaviour is undefined if
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// * non-final sections are shorter or longer than secsize
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// * if final section does not match length
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// * write a section with index that is higher than length/secsize
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// * set length in Sum call when length/secsize < maxsec
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//
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// * if Sum() is not called on a Hasher that is fully written
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// a process will block, can be terminated with Reset
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// * it will not leak processes if not all sections are written but it blocks
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// and keeps the resource which can be released calling Reset()
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type AsyncHasher struct {
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*Hasher // extends the Hasher
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mtx sync.Mutex // to lock the cursor access
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double bool // whether to use double segments (call Hasher.writeSection)
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secsize int // size of base section (size of hash or double)
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write func(i int, section []byte, final bool)
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}
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// methods needed to implement AsyncWriter
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// SectionSize returns the size of async section unit to use
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func (sw *AsyncHasher) SectionSize() int {
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return sw.secsize
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}
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// Write writes the i-th section of the BMT base
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// this function can and is meant to be called concurrently
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// it sets max segment threadsafely
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func (sw *AsyncHasher) Write(i int, section []byte) {
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sw.mtx.Lock()
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defer sw.mtx.Unlock()
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t := sw.getTree()
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// cursor keeps track of the rightmost section written so far
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// if index is lower than cursor then just write non-final section as is
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if i < t.cursor {
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// if index is not the rightmost, safe to write section
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go sw.write(i, section, false)
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return
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}
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// if there is a previous rightmost section safe to write section
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if t.offset > 0 {
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if i == t.cursor {
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// i==cursor implies cursor was set by Hash call so we can write section as final one
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// since it can be shorter, first we copy it to the padded buffer
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t.section = make([]byte, sw.secsize)
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copy(t.section, section)
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go sw.write(i, t.section, true)
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return
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}
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// the rightmost section just changed, so we write the previous one as non-final
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go sw.write(t.cursor, t.section, false)
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}
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// set i as the index of the righmost section written so far
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// set t.offset to cursor*secsize+1
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t.cursor = i
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t.offset = i*sw.secsize + 1
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t.section = make([]byte, sw.secsize)
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copy(t.section, section)
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}
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// Sum can be called any time once the length and the span is known
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// potentially even before all segments have been written
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// in such cases Sum will block until all segments are present and
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// the hash for the length can be calculated.
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//
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// b: digest is appended to b
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// length: known length of the input (unsafe; undefined if out of range)
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// meta: metadata to hash together with BMT root for the final digest
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// e.g., span for protection against existential forgery
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func (sw *AsyncHasher) Sum(b []byte, length int, meta []byte) (s []byte) {
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sw.mtx.Lock()
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t := sw.getTree()
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if length == 0 {
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sw.mtx.Unlock()
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|
s = sw.pool.zerohashes[sw.pool.Depth]
|
|
} else {
|
|
// for non-zero input the rightmost section is written to the tree asynchronously
|
|
// if the actual last section has been written (t.cursor == length/t.secsize)
|
|
maxsec := (length - 1) / sw.secsize
|
|
if t.offset > 0 {
|
|
go sw.write(t.cursor, t.section, maxsec == t.cursor)
|
|
}
|
|
// set cursor to maxsec so final section is written when it arrives
|
|
t.cursor = maxsec
|
|
t.offset = length
|
|
result := t.result
|
|
sw.mtx.Unlock()
|
|
// wait for the result or reset
|
|
s = <-result
|
|
}
|
|
// relesase the tree back to the pool
|
|
sw.releaseTree()
|
|
// if no meta is given just append digest to b
|
|
if len(meta) == 0 {
|
|
return append(b, s...)
|
|
}
|
|
// hash together meta and BMT root hash using the pools
|
|
return doSum(sw.pool.hasher(), b, meta, s)
|
|
}
|
|
|
|
// writeSection writes the hash of i-th section into level 1 node of the BMT tree
|
|
func (h *Hasher) writeSection(i int, section []byte, double bool, final bool) {
|
|
// select the leaf node for the section
|
|
var n *node
|
|
var isLeft bool
|
|
var hasher hash.Hash
|
|
var level int
|
|
t := h.getTree()
|
|
if double {
|
|
level++
|
|
n = t.leaves[i]
|
|
hasher = n.hasher
|
|
isLeft = n.isLeft
|
|
n = n.parent
|
|
// hash the section
|
|
section = doSum(hasher, nil, section)
|
|
} else {
|
|
n = t.leaves[i/2]
|
|
hasher = n.hasher
|
|
isLeft = i%2 == 0
|
|
}
|
|
// write hash into parent node
|
|
if final {
|
|
// for the last segment use writeFinalNode
|
|
h.writeFinalNode(level, n, hasher, isLeft, section)
|
|
} else {
|
|
h.writeNode(n, hasher, isLeft, section)
|
|
}
|
|
}
|
|
|
|
// writeNode pushes the data to the node
|
|
// if it is the first of 2 sisters written, the routine terminates
|
|
// if it is the second, it calculates the hash and writes it
|
|
// to the parent node recursively
|
|
// since hashing the parent is synchronous the same hasher can be used
|
|
func (h *Hasher) writeNode(n *node, bh hash.Hash, isLeft bool, s []byte) {
|
|
level := 1
|
|
for {
|
|
// at the root of the bmt just write the result to the result channel
|
|
if n == nil {
|
|
h.getTree().result <- s
|
|
return
|
|
}
|
|
// otherwise assign child hash to left or right segment
|
|
if isLeft {
|
|
n.left = s
|
|
} else {
|
|
n.right = s
|
|
}
|
|
// the child-thread first arriving will terminate
|
|
if n.toggle() {
|
|
return
|
|
}
|
|
// the thread coming second now can be sure both left and right children are written
|
|
// so it calculates the hash of left|right and pushes it to the parent
|
|
s = doSum(bh, nil, n.left, n.right)
|
|
isLeft = n.isLeft
|
|
n = n.parent
|
|
level++
|
|
}
|
|
}
|
|
|
|
// writeFinalNode is following the path starting from the final datasegment to the
|
|
// BMT root via parents
|
|
// for unbalanced trees it fills in the missing right sister nodes using
|
|
// the pool's lookup table for BMT subtree root hashes for all-zero sections
|
|
// otherwise behaves like `writeNode`
|
|
func (h *Hasher) writeFinalNode(level int, n *node, bh hash.Hash, isLeft bool, s []byte) {
|
|
|
|
for {
|
|
// at the root of the bmt just write the result to the result channel
|
|
if n == nil {
|
|
if s != nil {
|
|
h.getTree().result <- s
|
|
}
|
|
return
|
|
}
|
|
var noHash bool
|
|
if isLeft {
|
|
// coming from left sister branch
|
|
// when the final section's path is going via left child node
|
|
// we include an all-zero subtree hash for the right level and toggle the node.
|
|
n.right = h.pool.zerohashes[level]
|
|
if s != nil {
|
|
n.left = s
|
|
// if a left final node carries a hash, it must be the first (and only thread)
|
|
// so the toggle is already in passive state no need no call
|
|
// yet thread needs to carry on pushing hash to parent
|
|
noHash = false
|
|
} else {
|
|
// if again first thread then propagate nil and calculate no hash
|
|
noHash = n.toggle()
|
|
}
|
|
} else {
|
|
// right sister branch
|
|
if s != nil {
|
|
// if hash was pushed from right child node, write right segment change state
|
|
n.right = s
|
|
// if toggle is true, we arrived first so no hashing just push nil to parent
|
|
noHash = n.toggle()
|
|
|
|
} else {
|
|
// if s is nil, then thread arrived first at previous node and here there will be two,
|
|
// so no need to do anything and keep s = nil for parent
|
|
noHash = true
|
|
}
|
|
}
|
|
// the child-thread first arriving will just continue resetting s to nil
|
|
// the second thread now can be sure both left and right children are written
|
|
// it calculates the hash of left|right and pushes it to the parent
|
|
if noHash {
|
|
s = nil
|
|
} else {
|
|
s = doSum(bh, nil, n.left, n.right)
|
|
}
|
|
// iterate to parent
|
|
isLeft = n.isLeft
|
|
n = n.parent
|
|
level++
|
|
}
|
|
}
|
|
|
|
// getTree obtains a BMT resource by reserving one from the pool and assigns it to the bmt field
|
|
func (h *Hasher) getTree() *tree {
|
|
if h.bmt != nil {
|
|
return h.bmt
|
|
}
|
|
t := h.pool.reserve()
|
|
h.bmt = t
|
|
return t
|
|
}
|
|
|
|
// atomic bool toggle implementing a concurrent reusable 2-state object
|
|
// atomic addint with %2 implements atomic bool toggle
|
|
// it returns true if the toggler just put it in the active/waiting state
|
|
func (n *node) toggle() bool {
|
|
return atomic.AddInt32(&n.state, 1)%2 == 1
|
|
}
|
|
|
|
// calculates the hash of the data using hash.Hash
|
|
func doSum(h hash.Hash, b []byte, data ...[]byte) []byte {
|
|
h.Reset()
|
|
for _, v := range data {
|
|
h.Write(v)
|
|
}
|
|
return h.Sum(b)
|
|
}
|
|
|
|
// hashstr is a pretty printer for bytes used in tree.draw
|
|
func hashstr(b []byte) string {
|
|
end := len(b)
|
|
if end > 4 {
|
|
end = 4
|
|
}
|
|
return fmt.Sprintf("%x", b[:end])
|
|
}
|
|
|
|
// calculateDepthFor calculates the depth (number of levels) in the BMT tree
|
|
func calculateDepthFor(n int) (d int) {
|
|
c := 2
|
|
for ; c < n; c *= 2 {
|
|
d++
|
|
}
|
|
return d + 1
|
|
}
|