erigon-pulse/turbo/trie/structural_test.go
Alex Sharov e1dec529d4
Generic sort of slices (no allocs, inlinable) (#4161)
* save

* save

* save

* save

* save
2022-05-16 08:24:12 +01:00

731 lines
27 KiB
Go

// Copyright 2019 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty off
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
package trie
// Experimental code for separating data and structural information
import (
"bytes"
"encoding/binary"
"fmt"
"testing"
"github.com/ledgerwatch/erigon/common"
"github.com/ledgerwatch/erigon/crypto"
"github.com/ledgerwatch/erigon/turbo/rlphacks"
"github.com/stretchr/testify/require"
"golang.org/x/exp/slices"
)
func TestV2HashBuilding(t *testing.T) {
var keys []string
for b := uint32(0); b < 100000; b++ {
var preimage [4]byte
binary.BigEndian.PutUint32(preimage[:], b)
key := crypto.Keccak256(preimage[:])[:8]
keys = append(keys, string(key))
}
slices.Sort(keys)
for i, key := range keys {
if i > 0 && keys[i-1] == key {
fmt.Printf("Duplicate!\n")
}
}
tr := New(common.Hash{})
valueLong := []byte("VALUE123985903485903489043859043859043859048590485904385903485940385439058934058439058439058439058940385904358904385438809348908345")
valueShort := []byte("VAL")
for i, key := range keys {
if i%2 == 0 {
tr.Update([]byte(key), valueNode(valueLong))
} else {
tr.Update([]byte(key), valueNode(valueShort))
}
}
trieHash := tr.Hash()
hb := NewHashBuilder(false)
var succ bytes.Buffer
var curr bytes.Buffer
var valueTape bytes.Buffer
var groups, hasTree, hasHash []uint16
for i, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
keyBytes := []byte(key)
for _, b := range keyBytes {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
succ.WriteByte(16)
if curr.Len() > 0 {
var err error
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(valueTape.Bytes())}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
valueTape.Reset()
if i%2 == 0 {
valueTape.Write(valueLong)
} else {
valueTape.Write(valueShort)
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
if _, _, _, err := GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(valueTape.Bytes())}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
builtHash := hb.rootHash()
if trieHash != builtHash {
t.Errorf("Expected hash %x, got %x", trieHash, builtHash)
}
}
func TestV2Resolution(t *testing.T) {
var keys []string
for b := uint32(0); b < 100000; b++ {
var preimage [4]byte
binary.BigEndian.PutUint32(preimage[:], b)
key := crypto.Keccak256(preimage[:])[:8]
keys = append(keys, string(key))
}
slices.Sort(keys)
tr := New(common.Hash{})
value := []byte("VALUE123985903485903489043859043859043859048590485904385903485940385439058934058439058439058439058940385904358904385438809348908345")
for _, key := range keys {
tr.Update([]byte(key), valueNode(value))
}
trieHash := tr.Hash()
// Choose some keys to be resolved
var rl RetainList
// First, existing keys
for i := 0; i < 1000; i += 200 {
rl.AddKey([]byte(keys[i]))
}
// Next, some non-existing keys
for i := 0; i < 1000; i++ {
rl.AddKey(crypto.Keccak256([]byte(keys[i]))[:8])
}
hb := NewHashBuilder(false)
var succ bytes.Buffer
var curr bytes.Buffer
var valueTape bytes.Buffer
var groups, hasTree, hasHash []uint16
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
keyBytes := []byte(key)
for _, b := range keyBytes {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
succ.WriteByte(16)
if curr.Len() > 0 {
var err error
groups, hasTree, hasHash, err = GenStructStep(rl.Retain, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(valueTape.Bytes())}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
valueTape.Reset()
valueTape.Write(value)
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
if _, _, _, err := GenStructStep(rl.Retain, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(valueTape.Bytes())}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
tr1 := New(common.Hash{})
tr1.root = hb.root()
builtHash := hb.rootHash()
if trieHash != builtHash {
t.Errorf("Expected hash %x, got %x", trieHash, builtHash)
}
// Check the availability of the resolved keys
for _, hex := range rl.hexes {
key := hexToKeybytes(hex)
_, found := tr1.Get(key)
if !found {
t.Errorf("Key %x was not resolved", hex)
}
}
}
// In this test, we try to combine both accounts and their storage items in the single
// hash builder by tricking the GenStructStep slightly.
// For storage items, we will be using the keys which are concatenation of the contract address hash,
// incarnation encoding, and the storage location hash.
// If we just allow it to be processed natually, then at the end of the processing of all storage
// items, we would have entension node which hasTree off at some point, but includes incarnation encoding
// in it, which we do not want. To cut it off, we will use the "trick". When we give the last
// storage item to the GenStructStep, instead of setting `succ` to the empty slice, indicating that
// nothing follows, we will set `succ` to a key which is the concatenation of the address hash,
// incarnation encoding, except that the last nibble of the incoding is arbitrarily modified
// This will cause the correct extension node to form.
// In order to prevent the branch node on top of the extension node, we will need to manipulate
// the `groups` array and truncate it to the level of the accounts
func TestEmbeddedStorage(t *testing.T) {
var accountAddress = common.Address{3, 4, 5, 6}
addrHash := crypto.Keccak256(accountAddress[:])
incarnation := make([]byte, 8)
binary.BigEndian.PutUint64(incarnation, uint64(2))
var location1 = common.Hash{1}
locationKey1 := append(append([]byte{}, addrHash...), crypto.Keccak256(location1[:])...)
var location2 = common.Hash{2}
locationKey2 := append(append([]byte{}, addrHash...), crypto.Keccak256(location2[:])...)
var location3 = common.Hash{3}
locationKey3 := append(append([]byte{}, addrHash...), crypto.Keccak256(location3[:])...)
var keys = []string{string(locationKey1), string(locationKey2), string(locationKey3)}
slices.Sort(keys)
tr := New(common.Hash{})
valueShort := []byte("VAL")
for _, key := range keys {
tr.Update([]byte(key)[common.HashLength:], valueNode(valueShort))
}
trieHash := tr.Hash()
hb := NewHashBuilder(true)
var succ bytes.Buffer
var curr bytes.Buffer
var groups, hasTree, hasHash []uint16
var err error
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
keyBytes := []byte(key)
for _, b := range keyBytes {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
succ.WriteByte(16)
if curr.Len() > 0 {
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return true }, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(valueShort)}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
// Produce the key which is specially modified version of `curr` (only different in the last nibble)
cutoff := 2 * common.HashLength
succ.Write(curr.Bytes()[:cutoff-1])
succ.WriteByte(curr.Bytes()[cutoff-1] + 1)
if _, _, _, err = GenStructStep(func(_ []byte) bool { return true }, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(valueShort)}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
builtHash := hb.rootHash()
if trieHash != builtHash {
fmt.Printf("Trie built: %s\n", hb.root().fstring(""))
fmt.Printf("Trie expected: %s\n", tr.root.fstring(""))
t.Errorf("Expected hash %x, got %x", trieHash, builtHash)
}
fmt.Printf("groups: %d\n", len(groups))
}
func TestEmbeddedStorage11(t *testing.T) {
keys := []struct {
k []byte
v []byte
}{
{
k: common.FromHex("fff9c1aa5884f1130301f60f98419b9d4217bc4ab65a2976b41e9a00bbceae9800000000000000010d2f4a412d2809e00f42a7f8cb0e659bddf0b4f201d24eb1b2946493cbae334c"),
v: common.FromHex("496e7374616e6365000000000000000000000000000000000000000000000000"),
},
{
k: common.FromHex("fff9c1aa5884f1130301f60f98419b9d4217bc4ab65a2976b41e9a00bbceae98000000000000000123a5384746519cbca71a22098063e5608768276f2dc212e71fd2c6c643c726c4"),
v: common.FromHex("65eea643e9a9d6f5f2f7e13ccdff36cf45b46aab"),
},
{
k: common.FromHex("fff9c1aa5884f1130301f60f98419b9d4217bc4ab65a2976b41e9a00bbceae980000000000000001387a79e493fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"),
v: common.FromHex("01"),
},
{
k: common.FromHex("fff9c1aa5884f1130301f60f98419b9d4217bc4ab65a2976b41e9a00bbceae980000000000000001a8dc6a21510692d70d47860a1bbd432c801d1860bfbbe6856756ad4c062ba601"),
v: common.FromHex("53706f7265000000000000000000000000000000000000000000000000000000"),
},
{
k: common.FromHex("fff9c1aa5884f1130301f60f98419b9d4217bc4ab65a2976b41e9a00bbceae980000000000000001dee260551c74e3b37ed31b6e5f482a3ff9342f863a5880c9090db0cc9e002750"),
v: common.FromHex("5067247f2214dca445bfb213277b5f19711e309f"),
},
{
k: common.FromHex("fff9c1aa5884f1130301f60f98419b9d4217bc4ab65a2976b41e9a00bbceae980000000000000001fe59747b95e3ddbc3fd7e47a8bdf2465d2d88a030c9bd19cc3c0b7a9860c0d5f"),
v: common.FromHex("01"),
},
}
hb := NewHashBuilder(true)
var succ bytes.Buffer
var curr bytes.Buffer
var groups, hasTree, hasHash []uint16
var err error
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
keyBytes := key.k
for _, b := range keyBytes {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
succ.WriteByte(16)
if curr.Len() > 0 {
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(key.v)}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
// Produce the key which is specially modified version of `curr` (only different in the last nibble)
cutoff := 2 * (common.HashLength + common.IncarnationLength)
succ.Write(curr.Bytes()[:cutoff-1])
succ.WriteByte(curr.Bytes()[cutoff-1] + 1)
if _, _, _, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, nil /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(keys[len(keys)-1].v)}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
builtHash := hb.rootHash()
fmt.Printf("%d, %x, %d, %x\n", cutoff, builtHash, len(hb.hashStack), hb.hashStack)
//if trieHash != builtHash {
// fmt.Printf("Trie built: %s\n", hb.root().fstring(""))
// fmt.Printf("Trie expected: %s\n", tr.root.fstring(""))
// t.Errorf("Expected hash %x, got %x", trieHash, builtHash)
//}
fmt.Printf("groups: %d\n", len(groups))
}
func TestAccountsOnly(t *testing.T) {
keys := []struct {
k []byte
v []byte
}{
{k: common.FromHex("10002a312d2809e00f42a7f8cb0e659bddf0b4f201d24eb1b2946493cbae334c"), v: common.FromHex("01")},
{k: common.FromHex("10002a412d2809e00f42a7f8cb0e659bddf0b4f201d24eb1b2946493cbae334c"), v: common.FromHex("01")},
{k: common.FromHex("10002b412d2809e00f42a7f8cb0e659bddf0b4f201d24eb1b2946493cbae334c"), v: common.FromHex("01")},
{k: common.FromHex("10009384w46519cbc71a22098063e5608768276f2dc212e71fd2c6c643c726c4"), v: common.FromHex("01")},
{k: common.FromHex("10009484w46519cbc71a22098063e5608768276f2dc212e71fd2c6c643c726c4"), v: common.FromHex("01")},
{k: common.FromHex("1000a9e493fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"), v: common.FromHex("01")},
{k: common.FromHex("110006a1510692d70d47860a1bbd432c801d1860bfbbe6856756ad4c062ba601"), v: common.FromHex("01")},
{k: common.FromHex("120006a1510692d70d47860a1bbd432c801d1860bfbbe6856756ad4c062ba601"), v: common.FromHex("01")},
{k: common.FromHex("121006a1510692d70d47860a1bbd432c801d1860bfbbe6856756ad4c062ba601"), v: common.FromHex("01")},
{k: common.FromHex("200c6a21510692d70d47860a1bbd432c801d1860bfbbe6856756ad4c062ba601"), v: common.FromHex("01")},
}
hb := NewHashBuilder(false)
var succ bytes.Buffer
var curr bytes.Buffer
var groups, hasTree, hasHash []uint16
var err error
i := 0
hc := func(keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error {
if hasHash == 0 && hasTree == 0 {
return nil
}
i++
switch i {
case 1:
require.Equal(t, common.FromHex("0100000002"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b10000000000)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b000)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 2:
require.Equal(t, common.FromHex("01000000"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b1000000100)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b100)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 3:
require.Equal(t, common.FromHex("01"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b100)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b001)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 4:
require.Equal(t, common.FromHex(""), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b10)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b10)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
}
return nil
}
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
keyBytes := key.k
for _, b := range keyBytes {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
succ.WriteByte(16)
if curr.Len() > 0 {
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, hc /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(key.v)}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
// Produce the key which is specially modified version of `curr` (only different in the last nibble)
if _, _, _, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), []byte{}, hb, hc /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(keys[len(keys)-1].v)}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
require.Equal(t, 4, i)
}
func TestBranchesOnly(t *testing.T) {
keys := []struct {
k []byte
hasTree bool
}{
{k: common.FromHex("0100000002000a03"), hasTree: false},
{k: common.FromHex("0100000002000a04"), hasTree: true},
{k: common.FromHex("01000000020b"), hasTree: false},
{k: common.FromHex("010000000900000103"), hasTree: false},
//{k: common.FromHex("010000000900000104"), hasTree: false},
//{k: common.FromHex("010000000900000203"), hasTree: false},
//{k: common.FromHex("010000000900000204"), hasTree: false},
{k: common.FromHex("010000000901"), hasTree: false},
{k: common.FromHex("010000000a"), hasTree: false},
{k: common.FromHex("0101"), hasTree: false},
{k: common.FromHex("010200000a"), hasTree: false},
{k: common.FromHex("010200000b"), hasTree: false},
{k: common.FromHex("0201"), hasTree: false},
}
hb := NewHashBuilder(false)
var succ, curr bytes.Buffer
var groups, hasTree, hasHash []uint16
var err error
i := 0
hc := func(keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error {
if hasHash == 0 && hasTree == 0 {
return nil
}
i++
switch i {
case 1:
require.Equal(t, common.FromHex("0100000002000a"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b11000)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b1000)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 2:
require.Equal(t, common.FromHex("0100000002"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b100000000000)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b1)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 3:
require.Equal(t, common.FromHex("0100000009"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b10)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b0)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 4:
require.Equal(t, common.FromHex("01000000"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b11000000100)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b01000000100)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 5:
require.Equal(t, common.FromHex("01020000"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b110000000000)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b0)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 6:
require.Equal(t, common.FromHex("01"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b10)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b101)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 7:
require.Equal(t, common.FromHex(""), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b10)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b10)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
}
return nil
}
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
succ.Write(key.k)
if curr.Len() > 0 {
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, hc /* hashCollector */, &GenStructStepHashData{common.Hash{}, key.hasTree}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
// Produce the key which is specially modified version of `curr` (only different in the last nibble)
if _, _, _, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), []byte{}, hb, hc /* hashCollector */, &GenStructStepHashData{common.Hash{}, false}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
require.Equal(t, 7, i)
}
func TestStorageOnly(t *testing.T) {
//acc := common.FromHex("fff9c1aa5884f1130301f60f98419b9d4217bc4ab65a2976b41e9a00bbceae980000000000000001")
keys := []struct {
k []byte
v []byte
}{
{
k: common.FromHex("500020e493fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"), v: common.FromHex("01"),
},
{
k: common.FromHex("500021e493fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"), v: common.FromHex("01"),
},
{
k: common.FromHex("500027e493fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"), v: common.FromHex("01"),
},
{
k: common.FromHex("5000979e93fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"), v: common.FromHex("01"),
},
{
k: common.FromHex("5000a7e493fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"), v: common.FromHex("01"),
},
{
k: common.FromHex("600a79e493fff57a9c96dc0a7efb356613eafd5c89ea9f2be54d8ecf96ce0d28"), v: common.FromHex("01"),
},
}
hb := NewHashBuilder(false)
var succ bytes.Buffer
var curr bytes.Buffer
var groups, hasHash, hasTree []uint16
var err error
i := 0
hc := func(keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error {
if hasHash == 0 && hasTree == 0 {
return nil
}
i++
switch i {
case 1:
require.Equal(t, common.FromHex("05000000"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b100)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b0)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 3:
require.Equal(t, common.FromHex("05000000"), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b100)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b000)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 4:
require.Equal(t, common.FromHex(""), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b0)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b100000)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 5:
require.NoError(t, fmt.Errorf("not expected"))
}
return nil
}
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
keyBytes := key.k
for _, b := range keyBytes {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
if len(key.k) == 32 || len(key.k) == 72 {
succ.WriteByte(16)
}
if curr.Len() > 0 {
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, hc /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(key.v)}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
// Produce the key which is specially modified version of `curr` (only different in the last nibble)
if _, _, _, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, hc /* hashCollector */, &GenStructStepLeafData{rlphacks.RlpSerializableBytes(keys[len(keys)-1].v)}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
require.Equal(t, 2, i)
}
func TestStorageWithoutBranchNodeInRoot(t *testing.T) {
trace := false
keys := []struct {
k []byte
hasTree bool
}{
{
k: common.FromHex("500020"),
hasTree: true,
},
{
k: common.FromHex("500021"),
hasTree: false,
},
{
k: common.FromHex("500027"),
hasTree: false,
},
}
var i int
hc := func(keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error {
if hasHash == 0 && hasTree == 0 {
return nil
}
i++
switch i {
case 1:
require.Equal(t, common.FromHex("0500000002"), keyHex)
//require.Equal(t, fmt.Sprintf("%b", uint16(0b10000011)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b10000011)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b1)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
case 2:
require.Equal(t, common.FromHex(""), keyHex)
require.Equal(t, fmt.Sprintf("%b", uint16(0b0)), fmt.Sprintf("%b", hasHash))
require.Equal(t, fmt.Sprintf("%b", uint16(0b100000)), fmt.Sprintf("%b", hasTree))
require.NotNil(t, hashes)
}
return nil
}
hb := NewHashBuilder(false)
var curr, succ bytes.Buffer
var currhasTree, succhasTree bool
var groups, hasTree, hasHash []uint16
var err error
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
for _, b := range key.k {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
currhasTree = succhasTree
succhasTree = key.hasTree
if curr.Len() > 0 {
v := &GenStructStepHashData{common.Hash{}, currhasTree}
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, hc /* hashCollector */, v, groups, hasTree, hasHash, trace)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
currhasTree = succhasTree
v := &GenStructStepHashData{common.Hash{}, currhasTree}
// Produce the key which is specially modified version of `curr` (only different in the last nibble)
if _, _, _, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), []byte{}, hb, hc /* hashCollector */, v, groups, hasTree, hasHash, trace); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
require.Equal(t, 2, i)
}
func Test2(t *testing.T) {
keys := []struct {
k []byte
v []byte
}{
{
k: common.FromHex("000000"),
v: common.FromHex("0100000000000000000000000000000000000000000000000000000000000000"),
},
{
k: common.FromHex("000001"),
v: common.FromHex("0100000000000000000000000000000000000000000000000000000000000000"),
},
{
k: common.FromHex("000009"),
v: common.FromHex("0100000000000000000000000000000000000000000000000000000000000000"),
},
//{
// k: common.FromHex("000010"),
// v: common.FromHex("0100000000000000000000000000000000000000000000000000000000000000"),
//},
//{
// k: common.FromHex("000020"),
// v: common.FromHex("0100000000000000000000000000000000000000000000000000000000000000"),
//},
{
k: common.FromHex("01"),
v: common.FromHex("0100000000000000000000000000000000000000000000000000000000000000"),
},
{
k: common.FromHex("02"),
v: common.FromHex("0100000000000000000000000000000000000000000000000000000000000000"),
},
}
hb := NewHashBuilder(false)
var succ bytes.Buffer
var curr bytes.Buffer
var groups, hasTree, hasHash []uint16
var err error
for _, key := range keys {
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
keyBytes := key.k
for _, b := range keyBytes {
succ.WriteByte(b / 16)
succ.WriteByte(b % 16)
}
//succ.WriteByte(16)
if curr.Len() > 0 {
fmt.Printf("send: %x\n", succ.Bytes())
groups, hasTree, hasHash, err = GenStructStep(func(_ []byte) bool { return false },
curr.Bytes(), succ.Bytes(), hb,
func(keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error {
return nil
}, /* hashCollector */ &GenStructStepHashData{Hash: common.BytesToHash(key.v)}, groups, hasTree, hasHash, false)
if err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}
}
curr.Reset()
curr.Write(succ.Bytes())
succ.Reset()
// Produce the key which is specially modified version of `curr` (only different in the last nibble)
if _, _, _, err = GenStructStep(func(_ []byte) bool { return false }, curr.Bytes(), succ.Bytes(), hb, func(keyHex []byte, hasState, hasTree, hasHash uint16, hashes, rootHash []byte) error {
return nil
}, /* hashCollector */ &GenStructStepHashData{Hash: common.BytesToHash(keys[len(keys)-1].v)}, groups, hasTree, hasHash, false); err != nil {
t.Errorf("Could not execute step of structGen algorithm: %v", err)
}
}