frostfs-contract/container/container_contract.go

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package containercontract
import (
"github.com/nspcc-dev/neo-go/pkg/interop"
"github.com/nspcc-dev/neo-go/pkg/interop/binary"
"github.com/nspcc-dev/neo-go/pkg/interop/contract"
"github.com/nspcc-dev/neo-go/pkg/interop/crypto"
"github.com/nspcc-dev/neo-go/pkg/interop/iterator"
"github.com/nspcc-dev/neo-go/pkg/interop/runtime"
"github.com/nspcc-dev/neo-go/pkg/interop/storage"
"github.com/nspcc-dev/neofs-contract/common"
)
type (
storageNode struct {
info []byte
}
extendedACL struct {
val []byte
sig []byte
pub interop.PublicKey
}
estimation struct {
from interop.PublicKey
size int
}
containerSizes struct {
cid []byte
estimations []estimation
}
)
const (
version = 1
ownersKey = "ownersList"
neofsIDContractKey = "identityScriptHash"
balanceContractKey = "balanceScriptHash"
netmapContractKey = "netmapScriptHash"
containerFeeKey = "ContainerFee"
containerIDSize = 32 // SHA256 size
estimateKeyPrefix = "cnr"
cleanupDelta = 3
)
var (
containerFeeTransferMsg = []byte("container creation fee")
eACLPrefix = []byte("eACL")
ctx storage.Context
)
func init() {
ctx = storage.GetContext()
}
func Init(addrNetmap, addrBalance, addrID []byte) {
if storage.Get(ctx, netmapContractKey) != nil &&
storage.Get(ctx, balanceContractKey) != nil &&
storage.Get(ctx, neofsIDContractKey) != nil {
panic("init: contract already deployed")
}
if len(addrNetmap) != 20 || len(addrBalance) != 20 || len(addrID) != 20 {
panic("init: incorrect length of contract script hash")
}
storage.Put(ctx, netmapContractKey, addrNetmap)
storage.Put(ctx, balanceContractKey, addrBalance)
storage.Put(ctx, neofsIDContractKey, addrID)
runtime.Log("container contract initialized")
}
func Put(container, signature, publicKey []byte) bool {
netmapContractAddr := storage.Get(ctx, netmapContractKey).([]byte)
innerRing := common.InnerRingList(netmapContractAddr)
threshold := len(innerRing)/3*2 + 1
offset := int(container[1])
offset = 2 + offset + 4 // version prefix + version size + owner prefix
ownerID := container[offset : offset+25] // offset + size of owner
containerID := crypto.SHA256(container)
neofsIDContractAddr := storage.Get(ctx, neofsIDContractKey).([]byte)
// If invoked from storage node, ignore it.
// Inner ring will find tx, validate it and send it again.
irKey := common.InnerRingInvoker(innerRing)
if len(irKey) == 0 {
// check provided key
if !isSignedByOwnerKey(container, signature, ownerID, publicKey) {
// check keys from NeoFSID
keys := contract.Call(neofsIDContractAddr, "key", contract.ReadOnly, ownerID).([][]byte)
if !verifySignature(container, signature, keys) {
panic("put: invalid owner signature")
}
}
runtime.Notify("containerPut", container, signature, publicKey)
return true
}
from := walletToScripHash(ownerID)
balanceContractAddr := storage.Get(ctx, balanceContractKey).([]byte)
containerFee := contract.Call(netmapContractAddr, "config", contract.ReadOnly, containerFeeKey).(int)
hashCandidate := common.InvokeID([]interface{}{container, signature, publicKey}, []byte("put"))
n := common.Vote(ctx, hashCandidate, irKey)
if n >= threshold {
common.RemoveVotes(ctx, hashCandidate)
// todo: check if new container with unique container id
for i := 0; i < len(innerRing); i++ {
node := innerRing[i]
to := contract.CreateStandardAccount(node.PublicKey)
tx := contract.Call(balanceContractAddr, "transferX",
contract.All,
from,
to,
containerFee,
containerFeeTransferMsg, // consider add container id to the message
)
if !tx.(bool) {
// todo: consider using `return false` to remove votes
panic("put: can't transfer assets for container creation")
}
}
addContainer(ctx, containerID, ownerID, container)
// try to remove underscore at v0.92.0
_ = contract.Call(neofsIDContractAddr, "addKey", contract.All, ownerID, [][]byte{publicKey})
runtime.Log("put: added new container")
} else {
runtime.Log("put: processed invoke from inner ring")
}
return true
}
func Delete(containerID, signature []byte) bool {
innerRing := irList()
threshold := len(innerRing)/3*2 + 1
ownerID := getOwnerByID(ctx, containerID)
if len(ownerID) == 0 {
panic("delete: container does not exist")
}
// If invoked from storage node, ignore it.
// Inner ring will find tx, validate it and send it again.
irKey := common.InnerRingInvoker(innerRing)
if len(irKey) == 0 {
// check provided key
neofsIDContractAddr := storage.Get(ctx, neofsIDContractKey).([]byte)
keys := contract.Call(neofsIDContractAddr, "key", contract.ReadOnly, ownerID).([][]byte)
if !verifySignature(containerID, signature, keys) {
panic("delete: invalid owner signature")
}
runtime.Notify("containerDelete", containerID, signature)
return true
}
hashCandidate := common.InvokeID([]interface{}{containerID, signature}, []byte("delete"))
n := common.Vote(ctx, hashCandidate, irKey)
if n >= threshold {
common.RemoveVotes(ctx, hashCandidate)
removeContainer(ctx, containerID, ownerID)
runtime.Log("delete: remove container")
} else {
runtime.Log("delete: processed invoke from inner ring")
}
return true
}
func Get(containerID []byte) []byte {
return storage.Get(ctx, containerID).([]byte)
}
func Owner(containerID []byte) []byte {
return getOwnerByID(ctx, containerID)
}
func List(owner []byte) [][]byte {
if len(owner) == 0 {
return getAllContainers(ctx)
}
var list [][]byte
owners := common.GetList(ctx, ownersKey)
for i := 0; i < len(owners); i++ {
ownerID := owners[i]
if len(owner) != 0 && !common.BytesEqual(owner, ownerID) {
continue
}
containers := common.GetList(ctx, ownerID)
for j := 0; j < len(containers); j++ {
container := containers[j]
list = append(list, container)
}
}
return list
}
func SetEACL(eACL, signature []byte) bool {
// get container ID
offset := int(eACL[1])
offset = 2 + offset + 4
containerID := eACL[offset : offset+32]
ownerID := getOwnerByID(ctx, containerID)
if len(ownerID) == 0 {
panic("setEACL: container does not exists")
}
neofsIDContractAddr := storage.Get(ctx, neofsIDContractKey).([]byte)
keys := contract.Call(neofsIDContractAddr, "key", contract.ReadOnly, ownerID).([][]byte)
if !verifySignature(eACL, signature, keys) {
panic("setEACL: invalid eACL signature")
}
rule := extendedACL{
val: eACL,
sig: signature,
}
key := append(eACLPrefix, containerID...)
common.SetSerialized(ctx, key, rule)
runtime.Log("setEACL: success")
return true
}
func EACL(containerID []byte) extendedACL {
ownerID := getOwnerByID(ctx, containerID)
if len(ownerID) == 0 {
panic("getEACL: container does not exists")
}
eacl := getEACL(ctx, containerID)
if len(eacl.sig) == 0 {
return eacl
}
// attach corresponding public key if it was not revoked from neofs id
neofsIDContractAddr := storage.Get(ctx, neofsIDContractKey).([]byte)
keys := contract.Call(neofsIDContractAddr, "key", contract.ReadOnly, ownerID).([][]byte)
for i := range keys {
key := keys[i]
if crypto.ECDsaSecp256r1Verify(eacl.val, key, eacl.sig) {
eacl.pub = key
break
}
}
return eacl
}
func PutContainerSize(epoch int, cid []byte, usedSize int, pubKey interop.PublicKey) bool {
if !runtime.CheckWitness(pubKey) {
panic("container: invalid witness for size estimation")
}
if !isStorageNode(pubKey) {
panic("container: only storage nodes can save size estimations")
}
key := estimationKey(epoch, cid)
s := getContainerSizeEstimation(key, cid)
// do not add estimation twice
for i := range s.estimations {
est := s.estimations[i]
if common.BytesEqual(est.from, pubKey) {
return false
}
}
s.estimations = append(s.estimations, estimation{
from: pubKey,
size: usedSize,
})
storage.Put(ctx, key, binary.Serialize(s))
runtime.Log("container: saved container size estimation")
return true
}
func GetContainerSize(id []byte) containerSizes {
return getContainerSizeEstimation(id, nil)
}
func ListContainerSizes(epoch int) [][]byte {
var buf interface{} = epoch
key := []byte(estimateKeyPrefix)
key = append(key, buf.([]byte)...)
it := storage.Find(ctx, key, storage.KeysOnly)
var result [][]byte
for iterator.Next(it) {
key := iterator.Value(it).([]byte) // it MUST BE `storage.KeysOnly`
result = append(result, key)
}
return result
}
func ProcessEpoch(epochNum int) {
innerRing := irList()
threshold := len(innerRing)/3*2 + 1
irKey := common.InnerRingInvoker(innerRing)
if len(irKey) == 0 {
panic("processEpoch: this method must be invoked from inner ring")
}
candidates := keysToDelete(epochNum)
epochID := common.InvokeID([]interface{}{epochNum}, []byte("epoch"))
n := common.Vote(ctx, epochID, irKey)
if n >= threshold {
common.RemoveVotes(ctx, epochID)
for i := range candidates {
candidate := candidates[i]
storage.Delete(ctx, candidate)
}
}
}
func StartContainerEstimation(epoch int) bool {
innerRing := irList()
threshold := len(innerRing)/3*2 + 1
irKey := common.InnerRingInvoker(innerRing)
if len(irKey) == 0 {
panic("startEstimation: only inner ring nodes can invoke this")
}
hashCandidate := common.InvokeID([]interface{}{epoch}, []byte("startEstimation"))
n := common.Vote(ctx, hashCandidate, irKey)
if n >= threshold {
common.RemoveVotes(ctx, hashCandidate)
runtime.Notify("StartEstimation", epoch)
runtime.Log("startEstimation: notification has been produced")
} else {
runtime.Log("startEstimation: processed invoke from inner ring")
}
return true
}
func StopContainerEstimation(epoch int) bool {
innerRing := irList()
threshold := len(innerRing)/3*2 + 1
irKey := common.InnerRingInvoker(innerRing)
if len(irKey) == 0 {
panic("stopEstimation: only inner ring nodes can invoke this")
}
hashCandidate := common.InvokeID([]interface{}{epoch}, []byte("stopEstimation"))
n := common.Vote(ctx, hashCandidate, irKey)
if n >= threshold {
common.RemoveVotes(ctx, hashCandidate)
runtime.Notify("StopEstimation", epoch)
runtime.Log("stopEstimation: notification has been produced")
} else {
runtime.Log("stopEstimation: processed invoke from inner ring")
}
return true
}
func Version() int {
return version
}
func addContainer(ctx storage.Context, id []byte, owner []byte, container []byte) {
addOrAppend(ctx, ownersKey, owner)
addOrAppend(ctx, owner, id)
storage.Put(ctx, id, container)
}
func removeContainer(ctx storage.Context, id []byte, owner []byte) {
n := remove(ctx, owner, id)
// if it was last container, remove owner from the list of owners
if n == 0 {
_ = remove(ctx, ownersKey, owner)
}
storage.Delete(ctx, id)
}
func addOrAppend(ctx storage.Context, key interface{}, value []byte) {
list := common.GetList(ctx, key)
for i := 0; i < len(list); i++ {
if common.BytesEqual(list[i], value) {
return
}
}
if len(list) == 0 {
list = [][]byte{value}
} else {
list = append(list, value)
}
common.SetSerialized(ctx, key, list)
}
// remove returns amount of left elements in the list
func remove(ctx storage.Context, key interface{}, value []byte) int {
var (
list = common.GetList(ctx, key)
newList = [][]byte{}
)
for i := 0; i < len(list); i++ {
if !common.BytesEqual(list[i], value) {
newList = append(newList, list[i])
}
}
ln := len(newList)
if ln == 0 {
storage.Delete(ctx, key)
} else {
common.SetSerialized(ctx, key, newList)
}
return ln
}
func getAllContainers(ctx storage.Context) [][]byte {
var list [][]byte
it := storage.Find(ctx, []byte{}, storage.KeysOnly)
for iterator.Next(it) {
key := iterator.Value(it).([]byte) // it MUST BE `storage.KeysOnly`
if len(key) == containerIDSize {
list = append(list, key)
}
}
return list
}
func getEACL(ctx storage.Context, cid []byte) extendedACL {
key := append(eACLPrefix, cid...)
data := storage.Get(ctx, key)
if data != nil {
return binary.Deserialize(data.([]byte)).(extendedACL)
}
return extendedACL{val: []byte{}, sig: []byte{}, pub: []byte{}}
}
func walletToScripHash(wallet []byte) []byte {
return wallet[1 : len(wallet)-4]
}
func verifySignature(msg, sig []byte, keys [][]byte) bool {
for i := range keys {
key := keys[i]
if crypto.ECDsaSecp256r1Verify(msg, key, sig) {
return true
}
}
return false
}
func getOwnerByID(ctx storage.Context, id []byte) []byte {
owners := common.GetList(ctx, ownersKey)
for i := 0; i < len(owners); i++ {
ownerID := owners[i]
containers := common.GetList(ctx, ownerID)
for j := 0; j < len(containers); j++ {
container := containers[j]
if common.BytesEqual(container, id) {
return ownerID
}
}
}
return nil
}
func isSignedByOwnerKey(msg, sig, owner, key []byte) bool {
if !isOwnerFromKey(owner, key) {
return false
}
return crypto.ECDsaSecp256r1Verify(msg, key, sig)
}
func isOwnerFromKey(owner []byte, key []byte) bool {
ownerSH := walletToScripHash(owner)
keySH := contract.CreateStandardAccount(key)
return common.BytesEqual(ownerSH, keySH)
}
func estimationKey(epoch int, cid []byte) []byte {
var buf interface{} = epoch
result := []byte(estimateKeyPrefix)
result = append(result, buf.([]byte)...)
return append(result, cid...)
}
func getContainerSizeEstimation(key, cid []byte) containerSizes {
data := storage.Get(ctx, key)
if data != nil {
return binary.Deserialize(data.([]byte)).(containerSizes)
}
return containerSizes{
cid: cid,
estimations: []estimation{},
}
}
// isStorageNode looks into _previous_ epoch network map, because storage node
// announce container size estimation of previous epoch.
func isStorageNode(key interop.PublicKey) bool {
netmapContractAddr := storage.Get(ctx, netmapContractKey).([]byte)
snapshot := contract.Call(netmapContractAddr, "snapshot", contract.ReadOnly, 1).([]storageNode)
for i := range snapshot {
nodeInfo := snapshot[i].info
nodeKey := nodeInfo[2:35] // offset:2, len:33
if common.BytesEqual(key, nodeKey) {
return true
}
}
return false
}
func keysToDelete(epoch int) [][]byte {
results := [][]byte{}
it := storage.Find(ctx, []byte(estimateKeyPrefix), storage.KeysOnly)
for iterator.Next(it) {
k := iterator.Value(it).([]byte) // it MUST BE `storage.KeysOnly`
nbytes := k[len(estimateKeyPrefix) : len(k)-32]
var n interface{} = nbytes
if epoch-n.(int) > cleanupDelta {
results = append(results, k)
}
}
return results
}
func irList() []common.IRNode {
return common.InnerRingListViaStorage(ctx, netmapContractKey)
}