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https://gitlab.com/pulsechaincom/go-pulse.git
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b628d72766
This changes the CI / release builds to use the latest Go version. It also upgrades golangci-lint to a newer version compatible with Go 1.19. In Go 1.19, godoc has gained official support for links and lists. The syntax for code blocks in doc comments has changed and now requires a leading tab character. gofmt adapts comments to the new syntax automatically, so there are a lot of comment re-formatting changes in this PR. We need to apply the new format in order to pass the CI lint stage with Go 1.19. With the linter upgrade, I have decided to disable 'gosec' - it produces too many false-positive warnings. The 'deadcode' and 'varcheck' linters have also been removed because golangci-lint warns about them being unmaintained. 'unused' provides similar coverage and we already have it enabled, so we don't lose much with this change.
210 lines
6.3 KiB
Go
210 lines
6.3 KiB
Go
// Copyright 2016 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 trie
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import (
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"sync"
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"github.com/ethereum/go-ethereum/crypto"
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"github.com/ethereum/go-ethereum/rlp"
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"golang.org/x/crypto/sha3"
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)
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// hasher is a type used for the trie Hash operation. A hasher has some
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// internal preallocated temp space
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type hasher struct {
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sha crypto.KeccakState
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tmp []byte
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encbuf rlp.EncoderBuffer
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parallel bool // Whether to use parallel threads when hashing
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}
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// hasherPool holds pureHashers
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var hasherPool = sync.Pool{
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New: func() interface{} {
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return &hasher{
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tmp: make([]byte, 0, 550), // cap is as large as a full fullNode.
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sha: sha3.NewLegacyKeccak256().(crypto.KeccakState),
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encbuf: rlp.NewEncoderBuffer(nil),
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}
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},
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}
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func newHasher(parallel bool) *hasher {
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h := hasherPool.Get().(*hasher)
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h.parallel = parallel
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return h
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}
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func returnHasherToPool(h *hasher) {
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hasherPool.Put(h)
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}
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// hash collapses a node down into a hash node, also returning a copy of the
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// original node initialized with the computed hash to replace the original one.
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func (h *hasher) hash(n node, force bool) (hashed node, cached node) {
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// Return the cached hash if it's available
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if hash, _ := n.cache(); hash != nil {
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return hash, n
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}
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// Trie not processed yet, walk the children
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switch n := n.(type) {
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case *shortNode:
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collapsed, cached := h.hashShortNodeChildren(n)
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hashed := h.shortnodeToHash(collapsed, force)
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// We need to retain the possibly _not_ hashed node, in case it was too
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// small to be hashed
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if hn, ok := hashed.(hashNode); ok {
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cached.flags.hash = hn
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} else {
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cached.flags.hash = nil
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}
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return hashed, cached
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case *fullNode:
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collapsed, cached := h.hashFullNodeChildren(n)
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hashed = h.fullnodeToHash(collapsed, force)
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if hn, ok := hashed.(hashNode); ok {
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cached.flags.hash = hn
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} else {
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cached.flags.hash = nil
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}
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return hashed, cached
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default:
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// Value and hash nodes don't have children so they're left as were
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return n, n
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}
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}
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// hashShortNodeChildren collapses the short node. The returned collapsed node
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// holds a live reference to the Key, and must not be modified.
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// The cached
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func (h *hasher) hashShortNodeChildren(n *shortNode) (collapsed, cached *shortNode) {
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// Hash the short node's child, caching the newly hashed subtree
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collapsed, cached = n.copy(), n.copy()
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// Previously, we did copy this one. We don't seem to need to actually
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// do that, since we don't overwrite/reuse keys
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//cached.Key = common.CopyBytes(n.Key)
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collapsed.Key = hexToCompact(n.Key)
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// Unless the child is a valuenode or hashnode, hash it
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switch n.Val.(type) {
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case *fullNode, *shortNode:
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collapsed.Val, cached.Val = h.hash(n.Val, false)
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}
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return collapsed, cached
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}
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func (h *hasher) hashFullNodeChildren(n *fullNode) (collapsed *fullNode, cached *fullNode) {
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// Hash the full node's children, caching the newly hashed subtrees
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cached = n.copy()
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collapsed = n.copy()
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if h.parallel {
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var wg sync.WaitGroup
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wg.Add(16)
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for i := 0; i < 16; i++ {
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go func(i int) {
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hasher := newHasher(false)
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if child := n.Children[i]; child != nil {
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collapsed.Children[i], cached.Children[i] = hasher.hash(child, false)
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} else {
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collapsed.Children[i] = nilValueNode
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}
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returnHasherToPool(hasher)
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wg.Done()
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}(i)
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}
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wg.Wait()
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} else {
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for i := 0; i < 16; i++ {
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if child := n.Children[i]; child != nil {
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collapsed.Children[i], cached.Children[i] = h.hash(child, false)
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} else {
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collapsed.Children[i] = nilValueNode
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}
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}
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}
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return collapsed, cached
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}
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// shortnodeToHash creates a hashNode from a shortNode. The supplied shortnode
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// should have hex-type Key, which will be converted (without modification)
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// into compact form for RLP encoding.
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// If the rlp data is smaller than 32 bytes, `nil` is returned.
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func (h *hasher) shortnodeToHash(n *shortNode, force bool) node {
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n.encode(h.encbuf)
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enc := h.encodedBytes()
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if len(enc) < 32 && !force {
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return n // Nodes smaller than 32 bytes are stored inside their parent
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}
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return h.hashData(enc)
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}
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// shortnodeToHash is used to creates a hashNode from a set of hashNodes, (which
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// may contain nil values)
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func (h *hasher) fullnodeToHash(n *fullNode, force bool) node {
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n.encode(h.encbuf)
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enc := h.encodedBytes()
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if len(enc) < 32 && !force {
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return n // Nodes smaller than 32 bytes are stored inside their parent
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}
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return h.hashData(enc)
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}
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// encodedBytes returns the result of the last encoding operation on h.encbuf.
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// This also resets the encoder buffer.
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//
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// All node encoding must be done like this:
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//
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// node.encode(h.encbuf)
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// enc := h.encodedBytes()
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//
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// This convention exists because node.encode can only be inlined/escape-analyzed when
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// called on a concrete receiver type.
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func (h *hasher) encodedBytes() []byte {
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h.tmp = h.encbuf.AppendToBytes(h.tmp[:0])
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h.encbuf.Reset(nil)
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return h.tmp
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}
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// hashData hashes the provided data
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func (h *hasher) hashData(data []byte) hashNode {
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n := make(hashNode, 32)
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h.sha.Reset()
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h.sha.Write(data)
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h.sha.Read(n)
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return n
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}
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// proofHash is used to construct trie proofs, and returns the 'collapsed'
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// node (for later RLP encoding) as well as the hashed node -- unless the
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// node is smaller than 32 bytes, in which case it will be returned as is.
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// This method does not do anything on value- or hash-nodes.
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func (h *hasher) proofHash(original node) (collapsed, hashed node) {
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switch n := original.(type) {
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case *shortNode:
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sn, _ := h.hashShortNodeChildren(n)
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return sn, h.shortnodeToHash(sn, false)
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case *fullNode:
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fn, _ := h.hashFullNodeChildren(n)
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return fn, h.fullnodeToHash(fn, false)
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default:
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// Value and hash nodes don't have children so they're left as were
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return n, n
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}
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}
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