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proof_ipa.go
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proof_ipa.go
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// This is free and unencumbered software released into the public domain.
//
// Anyone is free to copy, modify, publish, use, compile, sell, or
// distribute this software, either in source code form or as a compiled
// binary, for any purpose, commercial or non-commercial, and by any
// means.
//
// In jurisdictions that recognize copyright laws, the author or authors
// of this software dedicate any and all copyright interest in the
// software to the public domain. We make this dedication for the benefit
// of the public at large and to the detriment of our heirs and
// successors. We intend this dedication to be an overt act of
// relinquishment in perpetuity of all present and future rights to this
// software under copyright law.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
// IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR
// OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
// ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
// OTHER DEALINGS IN THE SOFTWARE.
//
// For more information, please refer to <https://unlicense.org>
package verkle
import (
"bytes"
"errors"
"fmt"
"sort"
"unsafe"
ipa "github.com/crate-crypto/go-ipa"
"github.com/crate-crypto/go-ipa/common"
)
const IPA_PROOF_DEPTH = 8
type IPAProof struct {
CL [IPA_PROOF_DEPTH][32]byte `json:"cl"`
CR [IPA_PROOF_DEPTH][32]byte `json:"cr"`
FinalEvaluation [32]byte `json:"finalEvaluation"`
}
type VerkleProof struct {
OtherStems [][31]byte `json:"otherStems"`
DepthExtensionPresent []byte `json:"depthExtensionPresent"`
CommitmentsByPath [][32]byte `json:"commitmentsByPath"`
D [32]byte `json:"d"`
IPAProof *IPAProof `json:"ipa_proof"`
}
func (vp *VerkleProof) Copy() *VerkleProof {
ret := &VerkleProof{
OtherStems: make([][31]byte, len(vp.OtherStems)),
DepthExtensionPresent: make([]byte, len(vp.DepthExtensionPresent)),
CommitmentsByPath: make([][32]byte, len(vp.CommitmentsByPath)),
IPAProof: &IPAProof{},
}
copy(ret.OtherStems, vp.OtherStems)
copy(ret.DepthExtensionPresent, vp.DepthExtensionPresent)
copy(ret.CommitmentsByPath, vp.CommitmentsByPath)
ret.D = vp.D
if vp.IPAProof != nil {
ret.IPAProof = vp.IPAProof
}
return ret
}
type Proof struct {
Multipoint *ipa.MultiProof // multipoint argument
ExtStatus []byte // the extension status of each stem
Cs []*Point // commitments, sorted by their path in the tree
PoaStems [][]byte // stems proving another stem is absent
Keys [][]byte
PreValues [][]byte
PostValues [][]byte
}
type SuffixStateDiff struct {
Suffix byte `json:"suffix"`
CurrentValue *[32]byte `json:"currentValue"`
NewValue *[32]byte `json:"newValue"`
}
type SuffixStateDiffs []SuffixStateDiff
type StemStateDiff struct {
Stem [31]byte `json:"stem"`
SuffixDiffs SuffixStateDiffs `json:"suffixDiffs"`
}
type StateDiff []StemStateDiff
func (sd StateDiff) Copy() StateDiff {
ret := make(StateDiff, len(sd))
for i := range sd {
copy(ret[i].Stem[:], sd[i].Stem[:])
ret[i].SuffixDiffs = make([]SuffixStateDiff, len(sd[i].SuffixDiffs))
for j := range sd[i].SuffixDiffs {
ret[i].SuffixDiffs[j].Suffix = sd[i].SuffixDiffs[j].Suffix
if sd[i].SuffixDiffs[j].CurrentValue != nil {
ret[i].SuffixDiffs[j].CurrentValue = &[32]byte{}
copy((*ret[i].SuffixDiffs[j].CurrentValue)[:], (*sd[i].SuffixDiffs[j].CurrentValue)[:])
}
if sd[i].SuffixDiffs[j].NewValue != nil {
ret[i].SuffixDiffs[j].NewValue = &[32]byte{}
copy((*ret[i].SuffixDiffs[j].NewValue)[:], (*sd[i].SuffixDiffs[j].NewValue)[:])
}
}
}
return ret
}
func GetCommitmentsForMultiproof(root VerkleNode, keys [][]byte, resolver NodeResolverFn) (*ProofElements, []byte, [][]byte, error) {
sort.Sort(keylist(keys))
return root.GetProofItems(keylist(keys), resolver)
}
// getProofElementsFromTree factors the logic that is used both in the proving and verification methods. It takes a pre-state
// tree and an optional post-state tree, extracts the proof data from them and returns all the items required to build/verify
// a proof.
func getProofElementsFromTree(preroot, postroot VerkleNode, keys [][]byte, resolver NodeResolverFn) (*ProofElements, []byte, [][]byte, [][]byte, error) {
// go-ipa won't accept no key as an input, catch this corner case
// and return an empty result.
if len(keys) == 0 {
return nil, nil, nil, nil, errors.New("no key provided for proof")
}
pe, es, poas, err := GetCommitmentsForMultiproof(preroot, keys, resolver)
if err != nil {
return nil, nil, nil, nil, fmt.Errorf("error getting pre-state proof data: %w", err)
}
// if a post-state tree is present, merge its proof elements with
// those of the pre-state tree, so that they can be proved together.
postvals := make([][]byte, len(keys))
if postroot != nil {
// keys were sorted already in the above GetcommitmentsForMultiproof.
// Set the post values, if they are untouched, leave them `nil`
for i := range keys {
val, err := postroot.Get(keys[i], resolver)
if err != nil {
return nil, nil, nil, nil, fmt.Errorf("error getting post-state value for key %x: %w", keys[i], err)
}
if !bytes.Equal(pe.Vals[i], val) {
postvals[i] = val
}
}
}
// [0:3]: proof elements of the pre-state trie for serialization,
// 3: values to be inserted in the post-state trie for serialization
return pe, es, poas, postvals, nil
}
func MakeVerkleMultiProof(preroot, postroot VerkleNode, keys [][]byte, resolver NodeResolverFn) (*Proof, []*Point, []byte, []*Fr, error) {
pe, es, poas, postvals, err := getProofElementsFromTree(preroot, postroot, keys, resolver)
if err != nil {
return nil, nil, nil, nil, fmt.Errorf("get commitments for multiproof: %s", err)
}
cfg := GetConfig()
tr := common.NewTranscript("vt")
mpArg, err := ipa.CreateMultiProof(tr, cfg.conf, pe.Cis, pe.Fis, pe.Zis)
if err != nil {
return nil, nil, nil, nil, fmt.Errorf("creating multiproof: %w", err)
}
// It's wheel-reinvention time again 🎉: reimplement a basic
// feature that should be part of the stdlib.
// "But golang is a high-productivity language!!!" 🤪
// len()-1, because the root is already present in the
// parent block, so we don't keep it in the proof.
paths := make([]string, 0, len(pe.ByPath)-1)
for path := range pe.ByPath {
if len(path) > 0 {
paths = append(paths, path)
}
}
sort.Strings(paths)
cis := make([]*Point, len(pe.ByPath)-1)
for i, path := range paths {
cis[i] = pe.ByPath[path]
}
proof := &Proof{
Multipoint: mpArg,
Cs: cis,
ExtStatus: es,
PoaStems: poas,
Keys: keys,
PreValues: pe.Vals,
PostValues: postvals,
}
return proof, pe.Cis, pe.Zis, pe.Yis, nil
}
// VerifyVerkleProofWithPreState takes a proof and a trusted tree root and verifies that the proof is valid.
func VerifyVerkleProofWithPreState(proof *Proof, preroot VerkleNode) error {
pe, _, _, _, err := getProofElementsFromTree(preroot, nil, proof.Keys, nil)
if err != nil {
return fmt.Errorf("error getting proof elements: %w", err)
}
if ok, err := VerifyVerkleProof(proof, pe.Cis, pe.Zis, pe.Yis, GetConfig()); !ok || err != nil {
return fmt.Errorf("error verifying proof: verifies=%v, error=%w", ok, err)
}
return nil
}
func VerifyVerkleProof(proof *Proof, Cs []*Point, indices []uint8, ys []*Fr, tc *Config) (bool, error) {
tr := common.NewTranscript("vt")
return ipa.CheckMultiProof(tr, tc.conf, proof.Multipoint, Cs, ys, indices)
}
// SerializeProof serializes the proof in the rust-verkle format:
// * len(Proof of absence stem) || Proof of absence stems
// * len(depths) || serialize(depth || ext statusi)
// * len(commitments) || serialize(commitment)
// * Multipoint proof
// it also returns the serialized keys and values
func SerializeProof(proof *Proof) (*VerkleProof, StateDiff, error) {
otherstems := make([][31]byte, len(proof.PoaStems))
for i, stem := range proof.PoaStems {
copy(otherstems[i][:], stem)
}
cbp := make([][32]byte, len(proof.Cs))
for i, C := range proof.Cs {
serialized := C.Bytes()
copy(cbp[i][:], serialized[:])
}
var cls, crs [IPA_PROOF_DEPTH][32]byte
for i := 0; i < IPA_PROOF_DEPTH; i++ {
l := proof.Multipoint.IPA.L[i].Bytes()
copy(cls[i][:], l[:])
r := proof.Multipoint.IPA.R[i].Bytes()
copy(crs[i][:], r[:])
}
var stemdiff *StemStateDiff
var statediff StateDiff
for i, key := range proof.Keys {
if stemdiff == nil || !bytes.Equal(stemdiff.Stem[:], key[:31]) {
statediff = append(statediff, StemStateDiff{})
stemdiff = &statediff[len(statediff)-1]
copy(stemdiff.Stem[:], key[:31])
}
stemdiff.SuffixDiffs = append(stemdiff.SuffixDiffs, SuffixStateDiff{Suffix: key[31]})
newsd := &stemdiff.SuffixDiffs[len(stemdiff.SuffixDiffs)-1]
var valueLen = len(proof.PreValues[i])
switch valueLen {
case 0:
// null value
case 32:
newsd.CurrentValue = (*[32]byte)(proof.PreValues[i])
default:
var aligned [32]byte
copy(aligned[:valueLen], proof.PreValues[i])
newsd.CurrentValue = (*[32]byte)(unsafe.Pointer(&aligned[0]))
}
valueLen = len(proof.PostValues[i])
switch valueLen {
case 0:
// null value
case 32:
newsd.NewValue = (*[32]byte)(proof.PostValues[i])
default:
// TODO remove usage of unsafe
var aligned [32]byte
copy(aligned[:valueLen], proof.PostValues[i])
newsd.NewValue = (*[32]byte)(unsafe.Pointer(&aligned[0]))
}
}
return &VerkleProof{
OtherStems: otherstems,
DepthExtensionPresent: proof.ExtStatus,
CommitmentsByPath: cbp,
D: proof.Multipoint.D.Bytes(),
IPAProof: &IPAProof{
CL: cls,
CR: crs,
FinalEvaluation: proof.Multipoint.IPA.A_scalar.Bytes(),
},
}, statediff, nil
}
// DeserializeProof deserializes the proof found in blocks, into a format that
// can be used to rebuild a stateless version of the tree.
func DeserializeProof(vp *VerkleProof, statediff StateDiff) (*Proof, error) {
var (
poaStems, keys [][]byte
prevalues, postvalues [][]byte
extStatus []byte
commitments []*Point
multipoint ipa.MultiProof
)
poaStems = make([][]byte, len(vp.OtherStems))
for i, poaStem := range vp.OtherStems {
poaStems[i] = make([]byte, len(poaStem))
copy(poaStems[i], poaStem[:])
}
extStatus = vp.DepthExtensionPresent
commitments = make([]*Point, len(vp.CommitmentsByPath))
for i, commitmentBytes := range vp.CommitmentsByPath {
var commitment Point
if err := commitment.SetBytes(commitmentBytes[:]); err != nil {
return nil, err
}
commitments[i] = &commitment
}
if err := multipoint.D.SetBytes(vp.D[:]); err != nil {
return nil, fmt.Errorf("setting D: %w", err)
}
multipoint.IPA.A_scalar.SetBytes(vp.IPAProof.FinalEvaluation[:])
multipoint.IPA.L = make([]Point, IPA_PROOF_DEPTH)
for i, b := range vp.IPAProof.CL {
if err := multipoint.IPA.L[i].SetBytes(b[:]); err != nil {
return nil, fmt.Errorf("setting L[%d]: %w", i, err)
}
}
multipoint.IPA.R = make([]Point, IPA_PROOF_DEPTH)
for i, b := range vp.IPAProof.CR {
if err := multipoint.IPA.R[i].SetBytes(b[:]); err != nil {
return nil, fmt.Errorf("setting R[%d]: %w", i, err)
}
}
// turn statediff into keys and values
for _, stemdiff := range statediff {
for _, suffixdiff := range stemdiff.SuffixDiffs {
var k [32]byte
copy(k[:31], stemdiff.Stem[:])
k[31] = suffixdiff.Suffix
keys = append(keys, k[:])
if suffixdiff.CurrentValue != nil {
prevalues = append(prevalues, suffixdiff.CurrentValue[:])
} else {
prevalues = append(prevalues, nil)
}
if suffixdiff.NewValue != nil {
postvalues = append(postvalues, suffixdiff.NewValue[:])
} else {
postvalues = append(postvalues, nil)
}
}
}
proof := Proof{
&multipoint,
extStatus,
commitments,
poaStems,
keys,
prevalues,
postvalues,
}
return &proof, nil
}
type stemInfo struct {
depth byte
stemType byte
has_c1, has_c2 bool
values map[byte][]byte
stem []byte
}
// PreStateTreeFromProof builds a stateless prestate tree from the proof.
func PreStateTreeFromProof(proof *Proof, rootC *Point) (VerkleNode, error) { // skipcq: GO-R1005
if len(proof.Keys) != len(proof.PreValues) {
return nil, fmt.Errorf("incompatible number of keys and pre-values: %d != %d", len(proof.Keys), len(proof.PreValues))
}
if len(proof.Keys) != len(proof.PostValues) {
return nil, fmt.Errorf("incompatible number of keys and post-values: %d != %d", len(proof.Keys), len(proof.PostValues))
}
stems := make([][]byte, 0, len(proof.Keys))
for _, k := range proof.Keys {
if len(stems) == 0 || !bytes.Equal(stems[len(stems)-1], k[:31]) {
stems = append(stems, k[:31])
}
}
if len(stems) != len(proof.ExtStatus) {
return nil, fmt.Errorf("invalid number of stems and extension statuses: %d != %d", len(stems), len(proof.ExtStatus))
}
var (
info = map[string]stemInfo{}
paths [][]byte
err error
poas = proof.PoaStems
)
// The proof of absence stems must be sorted. If that isn't the case, the proof is invalid.
if !sort.IsSorted(bytesSlice(proof.PoaStems)) {
return nil, fmt.Errorf("proof of absence stems are not sorted")
}
// We build a cache of paths that have a presence extension status.
pathsWithExtPresent := map[string]struct{}{}
i := 0
for _, es := range proof.ExtStatus {
if es&3 == extStatusPresent {
pathsWithExtPresent[string(stems[i][:es>>3])] = struct{}{}
}
i++
}
// assign one or more stem to each stem info
for i, es := range proof.ExtStatus {
si := stemInfo{
depth: es >> 3,
stemType: es & 3,
}
path := stems[i][:si.depth]
switch si.stemType {
case extStatusAbsentEmpty:
// All keys that are part of a proof of absence, must contain empty
// prestate values. If that isn't the case, the proof is invalid.
for j := range proof.Keys { // TODO: DoS risk, use map or binary search.
if bytes.HasPrefix(proof.Keys[j], stems[i]) && proof.PreValues[j] != nil {
return nil, fmt.Errorf("proof of absence (empty) stem %x has a value", si.stem)
}
}
case extStatusAbsentOther:
// All keys that are part of a proof of absence, must contain empty
// prestate values. If that isn't the case, the proof is invalid.
for j := range proof.Keys { // TODO: DoS risk, use map or binary search.
if bytes.HasPrefix(proof.Keys[j], stems[i]) && proof.PreValues[j] != nil {
return nil, fmt.Errorf("proof of absence (other) stem %x has a value", si.stem)
}
}
// For this absent path, we must first check if this path contains a proof of presence.
// If that is the case, we don't have to do anything since the corresponding leaf will be
// constructed by that extension status (already processed or to be processed).
// In other case, we should get the stem from the list of proof of absence stems.
if _, ok := pathsWithExtPresent[string(path)]; ok {
continue
}
// Note that this path doesn't have proof of presence (previous if check above), but
// it can have multiple proof of absence. If a previous proof of absence had already
// created the stemInfo for this path, we don't have to do anything.
if _, ok := info[string(path)]; ok {
continue
}
si.stem = poas[0]
poas = poas[1:]
case extStatusPresent:
si.values = map[byte][]byte{}
si.stem = stems[i]
for j, k := range proof.Keys { // TODO: DoS risk, use map or binary search.
if bytes.Equal(k[:31], si.stem) {
si.values[k[31]] = proof.PreValues[j]
si.has_c1 = si.has_c1 || (k[31] < 128)
si.has_c2 = si.has_c2 || (k[31] >= 128)
}
}
default:
return nil, fmt.Errorf("invalid extension status: %d", si.stemType)
}
info[string(path)] = si
paths = append(paths, path)
}
if len(poas) != 0 {
return nil, fmt.Errorf("not all proof of absence stems were used: %d", len(poas))
}
root := NewStatelessInternal(0, rootC).(*InternalNode)
comms := proof.Cs
for _, p := range paths {
// NOTE: the reconstructed tree won't tell the
// difference between leaves missing from view
// and absent leaves. This is enough for verification
// but not for block validation.
values := make([][]byte, NodeWidth)
for i, k := range proof.Keys {
if len(proof.PreValues[i]) == 0 {
// Skip the nil keys, they are here to prove
// an absence.
continue
}
if bytes.Equal(k[:31], info[string(p)].stem) {
values[k[31]] = proof.PreValues[i]
}
}
comms, err = root.CreatePath(p, info[string(p)], comms, values)
if err != nil {
return nil, err
}
}
return root, nil
}
// PostStateTreeFromProof uses the pre-state trie and the list of updated values
// to produce the stateless post-state trie.
func PostStateTreeFromStateDiff(preroot VerkleNode, statediff StateDiff) (VerkleNode, error) {
postroot := preroot.Copy()
for _, stemstatediff := range statediff {
var (
values = make([][]byte, NodeWidth)
overwrites bool
)
for _, suffixdiff := range stemstatediff.SuffixDiffs {
if /* len(suffixdiff.NewValue) > 0 - this only works for a slice */ suffixdiff.NewValue != nil {
// if this value is non-nil, it means InsertValuesAtStem should be
// called, otherwise, skip updating the tree.
overwrites = true
values[suffixdiff.Suffix] = suffixdiff.NewValue[:]
}
}
if overwrites {
var stem [31]byte
copy(stem[:31], stemstatediff.Stem[:])
if err := postroot.(*InternalNode).InsertValuesAtStem(stem[:], values, nil); err != nil {
return nil, fmt.Errorf("error overwriting value in post state: %w", err)
}
}
}
postroot.Commit()
return postroot, nil
}
type bytesSlice [][]byte
func (x bytesSlice) Len() int { return len(x) }
func (x bytesSlice) Less(i, j int) bool { return bytes.Compare(x[i], x[j]) < 0 }
func (x bytesSlice) Swap(i, j int) { x[i], x[j] = x[j], x[i] }