mirror of
https://gitlab.com/pulsechaincom/erigon-pulse.git
synced 2024-12-25 21:17:16 +00:00
0be3044b7e
* rename * rename "make grpc" * rename "abi bindings templates" * rename "abi bindings templates"
448 lines
12 KiB
Go
448 lines
12 KiB
Go
// Copyright 2019 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 off
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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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// Visualisation of Merkle Patricia Tries.
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package trie
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import (
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"bytes"
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"fmt"
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"io"
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"math/big"
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"github.com/ledgerwatch/erigon/common"
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"github.com/ledgerwatch/erigon/visual"
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)
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// VisualOpts contains various configuration options fo the Visual function
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// It has been introduced as a replacement for too many arguments with options
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type VisualOpts struct {
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Highlights [][]byte // Collection of keys, in the HEX encoding, that need to be highlighted with digits
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IndexColors []string // Array of colors for representing digits as colored boxes
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FontColors []string // Array of colors, the same length as indexColors, for the textual digits inside the coloured boxes
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CutTerminals int // Specifies how many digits to cut from the terminal short node keys for a more convinient display
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Values bool // Whether to display value nodes (as box with rounded corners)
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CodeCompressed bool // Whether to turn the code from a large rectangle to a small square for a more convinient display
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ValCompressed bool // Whether long values (over 10 characters) are shortened using ... in the middle
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ValHex bool // Whether values should be displayed as hex numbers (otherwise they are displayed as just strings)
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SameLevel bool // Whether the leaves (and hashes) need to be on the same horizontal level
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}
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// Visual creates visualisation of trie with highlighting
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func Visual(t *Trie, w io.Writer, opts *VisualOpts) {
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var leaves map[string]struct{}
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if opts.Values {
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leaves = make(map[string]struct{})
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}
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hashes := make(map[string]struct{})
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visualNode(t.root, []byte{}, w, opts.Highlights, opts, leaves, hashes)
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if opts.SameLevel {
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fmt.Fprintf(w, "{rank = same;")
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for leaf := range leaves {
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fmt.Fprintf(w, "n_%x;", leaf)
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}
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fmt.Fprintf(w, `};
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`)
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fmt.Fprintf(w, "{rank = same;")
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for hash := range hashes {
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fmt.Fprintf(w, "n_%x;", hash)
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}
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fmt.Fprintf(w, `};
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`)
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}
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}
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func visualNode(nd node, hex []byte, w io.Writer, highlights [][]byte, opts *VisualOpts,
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leaves map[string]struct{}, hashes map[string]struct{}) {
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switch n := nd.(type) {
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case nil:
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case *shortNode:
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var pLenMax int
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for _, h := range highlights {
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pLen := prefixLen(n.Key, h)
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if pLen > pLenMax {
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pLenMax = pLen
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}
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}
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visual.Vertical(w, n.Key, pLenMax, fmt.Sprintf("n_%x", hex), opts.IndexColors, opts.FontColors, opts.CutTerminals)
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if v, ok := n.Val.(valueNode); ok {
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if leaves != nil {
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leaves[string(hex)] = struct{}{}
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/*
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var valStr string
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if opts.ValHex {
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valStr = fmt.Sprintf("%x", []byte(v))
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} else {
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valStr = string(v)
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}
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if opts.ValCompressed && len(valStr) > 10 {
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valStr = fmt.Sprintf("%x..%x", []byte(v)[:2], []byte(v)[len(v)-2:])
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}
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*/
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valHex := keybytesToHex(v)
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valHex = valHex[:len(valHex)-1]
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visual.HexBox(w, fmt.Sprintf("e_%x", concat(hex, n.Key...)), valHex, 32, opts.ValCompressed, false)
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fmt.Fprintf(w,
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`n_%x -> e_%x;
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`, hex, concat(hex, n.Key...))
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}
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} else if a, ok := n.Val.(*accountNode); ok {
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balance := float64(big.NewInt(0).Div(a.Balance.ToBig(), big.NewInt(1000000000000000)).Uint64()) / 1000.0
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visual.Circle(w, fmt.Sprintf("e_%x", concat(hex, n.Key...)), fmt.Sprintf("%d \u039E%.3f", a.Nonce, balance), true)
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accountHex := concat(hex, n.Key...)
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fmt.Fprintf(w,
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`n_%x -> e_%x;
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`, hex, accountHex)
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if !a.IsEmptyCodeHash() {
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if code := a.code; code != nil {
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codeHex := keybytesToHex(code)
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codeHex = codeHex[:len(codeHex)-1]
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visual.HexBox(w, fmt.Sprintf("c_%x", accountHex), codeHex, 32, opts.CodeCompressed, false)
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} else {
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visual.Box(w, fmt.Sprintf("c_%x", accountHex), "codeHash")
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}
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fmt.Fprintf(w,
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`e_%x -> c_%x;
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`, accountHex, accountHex)
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}
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if !a.IsEmptyRoot() {
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if a.storage != nil {
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nKey := n.Key
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if nKey[len(nKey)-1] == 16 {
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nKey = nKey[:len(nKey)-1]
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}
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var newHighlights [][]byte
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for _, h := range highlights {
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if h != nil && bytes.HasPrefix(h, nKey) {
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newHighlights = append(newHighlights, h[len(nKey):])
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}
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}
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visualNode(a.storage, accountHex[:len(accountHex)-1], w, newHighlights, opts, leaves, hashes)
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} else {
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visual.Box(w, fmt.Sprintf("n_%x", accountHex[:len(accountHex)-1]), "storHash")
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}
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fmt.Fprintf(w,
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`e_%x -> n_%x;
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`, accountHex, accountHex[:len(accountHex)-1])
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}
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} else {
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fmt.Fprintf(w,
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`
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n_%x -> n_%x;
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`, hex, concat(hex, n.Key...))
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var newHighlights [][]byte
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for _, h := range highlights {
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if h != nil && bytes.HasPrefix(h, n.Key) {
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newHighlights = append(newHighlights, h[len(n.Key):])
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}
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}
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visualNode(n.Val, concat(hex, n.Key...), w, newHighlights, opts, leaves, hashes)
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}
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case *duoNode:
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i1, i2 := n.childrenIdx()
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fmt.Fprintf(w,
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`
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n_%x [label=<
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<table border="0" color="#000000" cellborder="1" cellspacing="0">
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<tr>
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`, hex)
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var hOn1, hOn2 bool
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var highlights1, highlights2 [][]byte
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for _, h := range highlights {
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if len(h) > 0 && h[0] == i1 {
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highlights1 = append(highlights1, h[1:])
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hOn1 = true
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}
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if len(h) > 0 && h[0] == i2 {
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highlights2 = append(highlights2, h[1:])
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hOn2 = true
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}
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}
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if hOn1 {
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fmt.Fprintf(w,
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`
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<td bgcolor="%s" port="h%d"><font color="%s">%s</font></td>
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`, opts.IndexColors[i1], i1, opts.FontColors[i1], indices[i1])
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} else {
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fmt.Fprintf(w,
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`
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<td bgcolor="%s" port="h%d"></td>
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`, opts.IndexColors[i1], i1)
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}
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if hOn2 {
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fmt.Fprintf(w,
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`
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<td bgcolor="%s" port="h%d"><font color="%s">%s</font></td>
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`, opts.IndexColors[i2], i2, opts.FontColors[i2], indices[i2])
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} else {
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fmt.Fprintf(w,
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`
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<td bgcolor="%s" port="h%d"></td>
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`, opts.IndexColors[i2], i2)
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}
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fmt.Fprintf(w,
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`
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</tr>
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</table>
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>];
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n_%x:h%d -> n_%x;
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n_%x:h%d -> n_%x;
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`, hex, i1, concat(hex, i1), hex, i2, concat(hex, i2))
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visualNode(n.child1, concat(hex, i1), w, highlights1, opts, leaves, hashes)
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visualNode(n.child2, concat(hex, i2), w, highlights2, opts, leaves, hashes)
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case *fullNode:
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fmt.Fprintf(w,
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`
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n_%x [label=<
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<table border="0" color="#000000" cellborder="1" cellspacing="0">
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<tr>
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`, hex)
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hOn := make(map[byte]struct{})
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for _, h := range highlights {
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if len(h) > 0 {
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hOn[h[0]] = struct{}{}
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}
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}
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for i, child := range n.Children {
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if child == nil {
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continue
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}
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if _, ok := hOn[byte(i)]; ok {
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fmt.Fprintf(w,
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`
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<td bgcolor="%s" port="h%d"><font color="%s">%s</font></td>
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`, opts.IndexColors[i], i, opts.FontColors[i], indices[i])
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} else {
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fmt.Fprintf(w,
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`
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<td bgcolor="%s" port="h%d"></td>
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`, opts.IndexColors[i], i)
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}
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}
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fmt.Fprintf(w,
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`
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</tr>
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</table>
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>];
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`)
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for i, child := range n.Children {
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if child == nil {
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continue
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}
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fmt.Fprintf(w,
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` n_%x:h%d -> n_%x;
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`, hex, i, concat(hex, byte(i)))
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}
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for i, child := range n.Children {
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if child == nil {
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continue
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}
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var newHighlights [][]byte
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for _, h := range highlights {
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if len(h) > 0 && h[0] == byte(i) {
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newHighlights = append(newHighlights, h[1:])
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}
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}
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visualNode(child, concat(hex, byte(i)), w, newHighlights, opts, leaves, hashes)
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}
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case hashNode:
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hashes[string(hex)] = struct{}{}
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visual.Box(w, fmt.Sprintf("n_%x", hex), "hash")
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}
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}
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// Fold modifies the trie by folding the given set of keys, making sure that they are inaccessible
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// without resolution via DB
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func (t *Trie) Fold(keys [][]byte) {
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var hexes = make([][]byte, 0, len(keys))
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for _, key := range keys {
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hexes = append(hexes, keybytesToHex(key))
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}
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h := newHasher(false)
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defer returnHasherToPool(h)
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_, t.root = fold(t.root, hexes, h, true)
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}
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func fold(nd node, hexes [][]byte, h *hasher, isRoot bool) (bool, node) {
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switch n := nd.(type) {
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case *shortNode:
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var newHexes [][]byte
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for _, hex := range hexes {
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if bytes.Equal(n.Key, hex) {
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var hn common.Hash
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h.hash(n, isRoot, hn[:])
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return true, hashNode{hash: hn[:]}
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}
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pLen := prefixLen(n.Key, hex)
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if pLen > 0 {
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newHexes = append(newHexes, hex[pLen:])
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}
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}
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if len(newHexes) > 0 {
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folded, nn := fold(n.Val, newHexes, h, false)
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n.Val = nn
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if folded {
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var hn common.Hash
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h.hash(n, isRoot, hn[:])
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return true, hashNode{hash: hn[:]}
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}
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return false, n
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}
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case *duoNode:
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i1, i2 := n.childrenIdx()
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var hexes1, hexes2 [][]byte
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for _, h := range hexes {
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if len(h) > 0 && h[0] == i1 {
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hexes1 = append(hexes1, h[1:])
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}
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if len(h) > 0 && h[0] == i2 {
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hexes2 = append(hexes2, h[1:])
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}
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}
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var folded1, folded2 bool
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var nn1, nn2 node
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if len(hexes1) > 0 {
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folded1, nn1 = fold(n.child1, hexes1, h, false)
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n.child1 = nn1
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}
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if len(hexes2) > 0 {
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folded2, nn2 = fold(n.child2, hexes2, h, false)
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n.child2 = nn2
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}
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if folded1 && folded2 {
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var hn common.Hash
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h.hash(n, isRoot, hn[:])
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return true, hashNode{hash: hn[:]}
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}
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return false, n
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case *fullNode:
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var unfolded bool
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for i, child := range n.Children {
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if child == nil {
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continue
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}
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var newHexes [][]byte
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for _, h := range hexes {
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if len(h) > 0 && h[0] == byte(i) {
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newHexes = append(newHexes, h[1:])
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}
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}
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if len(newHexes) > 0 {
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folded, nn := fold(child, newHexes, h, false)
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n.Children[i] = nn
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if !folded {
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unfolded = true
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}
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} else {
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unfolded = true
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}
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}
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if !unfolded {
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var hn common.Hash
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h.hash(n, isRoot, hn[:])
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return true, hashNode{hash: hn[:]}
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}
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return false, n
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}
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return false, nd
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}
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// HexToQuad converts hexary trie to quad trie with the same set of keys
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func HexToQuad(t *Trie) *Trie {
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newTrie := New(common.Hash{})
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transformSubTrie(t.root, []byte{}, newTrie, keyHexToQuad)
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return newTrie
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}
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// KeyToQuad converts a key in KEY encoding to QUAD encoding (similar to HEX encoding, but uses digits 0..3 instead of digits 0..15)
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func KeyToQuad(key []byte) []byte {
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l := len(key)*2 + 1
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var nibbles = make([]byte, l)
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for i, b := range key {
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nibbles[i*2] = b / 16
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nibbles[i*2+1] = b % 16
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}
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nibbles[l-1] = 16
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return keyHexToQuad(nibbles)
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}
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func keyHexToQuad(hex []byte) []byte {
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quadLen := len(hex) * 2
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if hex[len(hex)-1] == 16 {
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quadLen--
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}
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quad := make([]byte, quadLen)
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qi := 0
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for _, h := range hex {
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if h == 16 {
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quad[qi] = 16
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qi++
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} else {
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quad[qi] = h / 4
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qi++
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quad[qi] = h % 4
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qi++
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}
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}
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return quad
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}
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// FullKeys construct the list of full keys (i.e. keys that can be accessed without resolution via DB) that are present in
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// the given trie
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func FullKeys(t *Trie) []string {
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return fullKeys(t.root, nil, nil)
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}
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func fullKeys(nd node, hex []byte, fk []string) []string {
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switch n := nd.(type) {
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case nil:
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return fk
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case hashNode:
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return fk
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case valueNode:
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return append(fk, string(concat(hex, 16)))
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case *shortNode:
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h := n.Key
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// Remove terminator
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if h[len(h)-1] == 16 {
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h = h[:len(h)-1]
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}
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hexVal := concat(hex, h...)
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return fullKeys(n.Val, hexVal, fk)
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case *duoNode:
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i1, i2 := n.childrenIdx()
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hex1 := make([]byte, len(hex)+1)
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copy(hex1, hex)
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hex1[len(hex)] = i1
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hex2 := make([]byte, len(hex)+1)
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copy(hex2, hex)
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hex2[len(hex)] = i2
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return fullKeys(n.child2, hex2, fullKeys(n.child1, hex1, fk))
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case *fullNode:
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for i, child := range n.Children {
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if child != nil {
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fk = fullKeys(child, concat(hex, byte(i)), fk)
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}
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}
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return fk
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case *accountNode:
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return append(fullKeys(n.storage, hex, fk), string(concat(hex, 16)))
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default:
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panic(fmt.Sprintf("%T", nd))
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}
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}
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