5affed38fc
This commit makes a large number of minor changes concerning API usage within the deamon to match the latest version on the upstream btcsuite libraries. The major changes are the switch from wire.ShaHash to chainhash.Hash, and that wire.NewMsgTx() now takes a paramter indicating the version of the transaction to be created.
152 lines
4.8 KiB
Go
152 lines
4.8 KiB
Go
package elkrem
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import (
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"fmt"
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"github.com/roasbeef/btcd/chaincfg/chainhash"
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)
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/* elkrem is a simpler alternative to the 64 dimensional sha-chain.
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it's basically a reverse merkle tree. If we want to provide 2**64 possible
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hashes, this requires a worst case computation of 63 hashes for the
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sender, and worst-case storage of 64 hashes for the receiver.
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The operations are left hash L() and right hash R(), which are
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hash(parent) and hash(parent, 1) respectively. (concatenate one byte)
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Here is a shorter example of a tree with 8 leaves and 15 total nodes.
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The sender first computes the bottom left leaf 0b0000. This is
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L(L(L(L(root)))). The receiver stores leaf 0.
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Next the sender computes 0b0001. R(L(L(L(root)))). Receiver stores.
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Next sender computes 0b1000 (8). L(L(L(root))). Receiver stores this, and
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discards leaves 0b0000 and 0b0001, as they have the parent node 8.
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For total hashes (2**h)-1 requires a tree of height h.
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Sender:
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as state, must store 1 hash (root) and that's all
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generate any index, compute at most h hashes.
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Receiver:
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as state, must store at most h+1 hashes and the index of each hash (h*(h+1)) bits
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to compute a previous index, compute at most h hashes.
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*/
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const maxIndex = uint64(281474976710654) // 2^48 - 2
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const maxHeight = uint8(47)
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// You can calculate h from i but I can't figure out how without taking
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// O(i) ops. Feels like there should be a clever O(h) way. 1 byte, whatever.
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type ElkremNode struct {
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h uint8 // height of this node
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i uint64 // index (i'th node)
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sha *chainhash.Hash // hash
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}
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type ElkremSender struct {
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root *chainhash.Hash // root hash of the tree
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}
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type ElkremReceiver struct {
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s []ElkremNode // store of received hashes
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}
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func LeftSha(in chainhash.Hash) chainhash.Hash {
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return chainhash.DoubleHashH(in[:]) // left is sha(sha(in))
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}
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func RightSha(in chainhash.Hash) chainhash.Hash {
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return chainhash.DoubleHashH(append(in[:], 0x01)) // sha(sha(in, 1))
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}
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// iterative descent of sub-tree. w = hash number you want. i = input index
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// h = height of input index. sha = input hash
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func descend(w, i uint64, h uint8, sha chainhash.Hash) (chainhash.Hash, error) {
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for w < i {
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if w <= i-(1<<h) { // left
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sha = LeftSha(sha)
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i = i - (1 << h) // left descent reduces index by 2**h
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} else { // right
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sha = RightSha(sha)
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i-- // right descent reduces index by 1
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}
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if h == 0 { // avoid underflowing h
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break
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}
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h-- // either descent reduces height by 1
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}
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if w != i { // somehow couldn't / didn't end up where we wanted to go
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return sha, fmt.Errorf("can't generate index %d from %d", w, i)
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}
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return sha, nil
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}
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// Creates an Elkrem Sender from a root hash.
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func NewElkremSender(r chainhash.Hash) *ElkremSender {
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var e ElkremSender
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e.root = &r
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return &e
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}
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// AtIndex skips to the requested index
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// should never error; remove error..?
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func (e *ElkremSender) AtIndex(w uint64) (*chainhash.Hash, error) {
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out, err := descend(w, maxIndex, maxHeight, *e.root)
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return &out, err
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}
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// AddNext inserts the next hash in the tree. Returns an error if
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// the incoming hash doesn't fit.
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func (e *ElkremReceiver) AddNext(sha *chainhash.Hash) error {
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// note: careful about atomicity / disk writes here
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var n ElkremNode
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n.sha = sha
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t := len(e.s) - 1 // top of stack
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if t >= 0 { // if this is not the first hash (>= because we -1'd)
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n.i = e.s[t].i + 1 // incoming index is tip of stack index + 1
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}
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if t > 0 && e.s[t-1].h == e.s[t].h { // top 2 elements are equal height
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// next node must be parent; verify and remove children
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n.h = e.s[t].h + 1 // assign height
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l := LeftSha(*sha) // calc l child
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r := RightSha(*sha) // calc r child
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if !e.s[t-1].sha.IsEqual(&l) { // test l child
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return fmt.Errorf("left child doesn't match, expect %s got %s",
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e.s[t-1].sha.String(), l.String())
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}
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if !e.s[t].sha.IsEqual(&r) { // test r child
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return fmt.Errorf("right child doesn't match, expect %s got %s",
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e.s[t].sha.String(), r.String())
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}
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e.s = e.s[:len(e.s)-2] // l and r children OK, remove them
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} // if that didn't happen, height defaults to 0
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e.s = append(e.s, n) // append new node to stack
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return nil
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}
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// AtIndex returns the w'th hash in the receiver.
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func (e *ElkremReceiver) AtIndex(w uint64) (*chainhash.Hash, error) {
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if e == nil || e.s == nil {
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return nil, fmt.Errorf("nil elkrem receiver")
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}
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var out ElkremNode // node we will eventually return
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for _, n := range e.s { // go through stack
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if w <= n.i { // found one bigger than or equal to what we want
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out = n
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break
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}
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}
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if out.sha == nil { // didn't find anything
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return nil, fmt.Errorf("receiver has max %d, less than requested %d",
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e.s[len(e.s)-1].i, w)
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}
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sha, err := descend(w, out.i, out.h, *out.sha)
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return &sha, err
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}
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// UpTo tells you what the receiver can go up to.
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func (e *ElkremReceiver) UpTo() uint64 {
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if len(e.s) < 1 {
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return 0
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}
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return e.s[len(e.s)-1].i
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}
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