frostfs-contract/container/container_contract.go

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package container
import (
"git.frostfs.info/TrueCloudLab/frostfs-contract/common"
"github.com/nspcc-dev/neo-go/pkg/interop"
"github.com/nspcc-dev/neo-go/pkg/interop/contract"
"github.com/nspcc-dev/neo-go/pkg/interop/convert"
"github.com/nspcc-dev/neo-go/pkg/interop/iterator"
"github.com/nspcc-dev/neo-go/pkg/interop/native/crypto"
"github.com/nspcc-dev/neo-go/pkg/interop/native/management"
"github.com/nspcc-dev/neo-go/pkg/interop/native/std"
"github.com/nspcc-dev/neo-go/pkg/interop/runtime"
"github.com/nspcc-dev/neo-go/pkg/interop/storage"
)
type (
storageNode struct {
info []byte
}
Container struct {
value []byte
sig interop.Signature
pub interop.PublicKey
token []byte
}
ExtendedACL struct {
value []byte
sig interop.Signature
pub interop.PublicKey
token []byte
}
estimation struct {
from interop.PublicKey
size int
}
containerSizes struct {
cid []byte
estimations []estimation
}
)
const (
frostfsIDContractKey = "identityScriptHash"
balanceContractKey = "balanceScriptHash"
netmapContractKey = "netmapScriptHash"
nnsContractKey = "nnsScriptHash"
nnsRootKey = "nnsRoot"
nnsHasAliasKey = "nnsHasAlias"
// RegistrationFeeKey is a key in netmap config which contains fee for container registration.
RegistrationFeeKey = "ContainerFee"
// AliasFeeKey is a key in netmap config which contains fee for nice-name registration.
AliasFeeKey = "ContainerAliasFee"
// V2 format
containerIDSize = 32 // SHA256 size
singleEstimatePrefix = "est"
estimateKeyPrefix = "cnr"
containerKeyPrefix = 'x'
ownerKeyPrefix = 'o'
graveKeyPrefix = 'g'
estimatePostfixSize = 10
// CleanupDelta contains the number of the last epochs for which container estimations are present.
CleanupDelta = 3
// TotalCleanupDelta contains the number of the epochs after which estimation
// will be removed by epoch tick cleanup if any of the nodes hasn't updated
// container size and/or container has been removed. It must be greater than CleanupDelta.
TotalCleanupDelta = CleanupDelta + 1
// NotFoundError is returned if container is missing.
NotFoundError = "container does not exist"
// default SOA record field values
defaultRefresh = 3600 // 1 hour
defaultRetry = 600 // 10 min
defaultExpire = 3600 * 24 * 365 * 10 // 10 years
defaultTTL = 3600 // 1 hour
)
var eACLPrefix = []byte("eACL")
// OnNEP11Payment is needed for registration with contract as the owner to work.
func OnNEP11Payment(a interop.Hash160, b int, c []byte, d any) {
}
func _deploy(data any, isUpdate bool) {
ctx := storage.GetContext()
if isUpdate {
args := data.([]any)
common.CheckVersion(args[len(args)-1].(int))
return
}
args := data.(struct {
addrNetmap interop.Hash160
addrBalance interop.Hash160
addrID interop.Hash160
addrNNS interop.Hash160
nnsRoot string
})
if len(args.addrNetmap) != interop.Hash160Len ||
len(args.addrBalance) != interop.Hash160Len ||
len(args.addrID) != interop.Hash160Len {
panic("incorrect length of contract script hash")
}
storage.Put(ctx, netmapContractKey, args.addrNetmap)
storage.Put(ctx, balanceContractKey, args.addrBalance)
storage.Put(ctx, frostfsIDContractKey, args.addrID)
storage.Put(ctx, nnsContractKey, args.addrNNS)
storage.Put(ctx, nnsRootKey, args.nnsRoot)
// add NNS root for container alias domains
registerNiceNameTLD(args.addrNNS, args.nnsRoot)
runtime.Log("container contract initialized")
}
func registerNiceNameTLD(addrNNS interop.Hash160, nnsRoot string) {
isAvail := contract.Call(addrNNS, "isAvailable", contract.AllowCall|contract.ReadStates,
"container").(bool)
if !isAvail {
return
}
res := contract.Call(addrNNS, "register", contract.All,
nnsRoot, runtime.GetExecutingScriptHash(), "ops@frostfs.info",
defaultRefresh, defaultRetry, defaultExpire, defaultTTL).(bool)
if !res {
panic("can't register NNS TLD")
}
}
// Update method updates contract source code and manifest. It can be invoked
// by committee only.
func Update(script []byte, manifest []byte, data any) {
if !common.HasUpdateAccess() {
panic("only committee can update contract")
}
management.UpdateWithData(script, manifest, common.AppendVersion(data))
runtime.Log("container contract updated")
}
// Put method creates a new container if it has been invoked by Alphabet nodes
// of the Inner Ring.
//
// Container should be a stable marshaled Container structure from API.
// Signature is a RFC6979 signature of the Container.
// PublicKey contains the public key of the signer.
// Token is optional and should be a stable marshaled SessionToken structure from
// API.
func Put(container []byte, signature interop.Signature, publicKey interop.PublicKey, token []byte) {
PutNamed(container, signature, publicKey, token, "", "")
}
// PutNamed is similar to put but also sets a TXT record in nns contract.
// Note that zone must exist.
func PutNamed(container []byte, signature interop.Signature,
publicKey interop.PublicKey, token []byte,
name, zone string,
) {
ctx := storage.GetContext()
ownerID := ownerFromBinaryContainer(container)
containerID := crypto.Sha256(container)
cnr := Container{
value: container,
sig: signature,
pub: publicKey,
token: token,
}
var (
needRegister bool
nnsContractAddr interop.Hash160
domain string
)
if name != "" {
if zone == "" {
zone = storage.Get(ctx, nnsRootKey).(string)
}
nnsContractAddr = storage.Get(ctx, nnsContractKey).(interop.Hash160)
domain = name + "." + zone
needRegister = checkNiceNameAvailable(nnsContractAddr, domain)
}
alphabet := common.AlphabetNodes()
from := common.WalletToScriptHash(ownerID)
netmapContractAddr := storage.Get(ctx, netmapContractKey).(interop.Hash160)
balanceContractAddr := storage.Get(ctx, balanceContractKey).(interop.Hash160)
containerFee := contract.Call(netmapContractAddr, "config", contract.ReadOnly, RegistrationFeeKey).(int)
balance := contract.Call(balanceContractAddr, "balanceOf", contract.ReadOnly, from).(int)
if name != "" {
aliasFee := contract.Call(netmapContractAddr, "config", contract.ReadOnly, AliasFeeKey).(int)
containerFee += aliasFee
}
if balance < containerFee*len(alphabet) {
panic("insufficient balance to create container")
}
common.CheckAlphabetWitness()
// todo: check if new container with unique container id
details := common.ContainerFeeTransferDetails(containerID)
for i := 0; i < len(alphabet); i++ {
node := alphabet[i]
to := contract.CreateStandardAccount(node)
contract.Call(balanceContractAddr, "transferX",
contract.All,
from,
to,
containerFee,
details,
)
}
addContainer(ctx, containerID, ownerID, cnr)
if name != "" {
if needRegister {
res := contract.Call(nnsContractAddr, "register", contract.All,
domain, runtime.GetExecutingScriptHash(), "ops@frostfs.info",
defaultRefresh, defaultRetry, defaultExpire, defaultTTL).(bool)
if !res {
panic("can't register the domain " + domain)
}
}
contract.Call(nnsContractAddr, "addRecord", contract.All,
domain, 16 /* TXT */, std.Base58Encode(containerID))
key := append([]byte(nnsHasAliasKey), containerID...)
storage.Put(ctx, key, domain)
}
runtime.Log("added new container")
runtime.Notify("PutSuccess", containerID, publicKey)
}
// checkNiceNameAvailable checks if the nice name is available for the container.
// It panics if the name is taken. Returned value specifies if new domain registration is needed.
func checkNiceNameAvailable(nnsContractAddr interop.Hash160, domain string) bool {
isAvail := contract.Call(nnsContractAddr, "isAvailable",
contract.ReadStates|contract.AllowCall, domain).(bool)
if isAvail {
return true
}
owner := contract.Call(nnsContractAddr, "ownerOf",
contract.ReadStates|contract.AllowCall, domain).(string)
if owner != string(common.CommitteeAddress()) && owner != string(runtime.GetExecutingScriptHash()) {
panic("committee or container contract must own registered domain")
}
res := contract.Call(nnsContractAddr, "getRecords",
contract.ReadStates|contract.AllowCall, domain, 16 /* TXT */)
if res != nil {
panic("name is already taken")
}
return false
}
// Delete method removes a container from the contract storage if it has been
// invoked by Alphabet nodes of the Inner Ring.
//
// Signature is a RFC6979 signature of the container ID.
// Token is optional and should be a stable marshaled SessionToken structure from
// API.
//
// If the container doesn't exist, it panics with NotFoundError.
func Delete(containerID interop.Hash256, signature interop.Signature, publicKey interop.PublicKey, token []byte) {
ctx := storage.GetContext()
ownerID := getOwnerByID(ctx, containerID)
if ownerID == nil {
return
}
common.CheckAlphabetWitness()
key := append([]byte(nnsHasAliasKey), containerID...)
domain := storage.Get(ctx, key).(string)
if len(domain) != 0 {
storage.Delete(ctx, key)
// We should do `getRecord` first because NNS record could be deleted
// by other means (expiration, manual), thus leading to failing `deleteRecord`
// and inability to delete a container. We should also check if we own the record in case.
nnsContractAddr := storage.Get(ctx, nnsContractKey).(interop.Hash160)
res := contract.Call(nnsContractAddr, "getRecords", contract.ReadStates|contract.AllowCall, domain, 16 /* TXT */)
if res != nil && std.Base58Encode(containerID) == string(res.([]any)[0].(string)) {
contract.Call(nnsContractAddr, "deleteRecords", contract.All, domain, 16 /* TXT */)
}
}
removeContainer(ctx, containerID, ownerID)
runtime.Log("remove container")
runtime.Notify("DeleteSuccess", containerID)
}
type DelInfo struct {
Owner []byte
Epoch int
}
type delInfo struct {
Owner []byte
Epoch []byte
}
// DeletionInfo method returns container deletion info.
// If the container had never existed, NotFoundError is throwed.
// It can be used to check whether non-existing container was indeed deleted
// or does not yet exist at some height.
func DeletionInfo(containerID []byte) DelInfo {
ctx := storage.GetReadOnlyContext()
graveKey := append([]byte{graveKeyPrefix}, containerID...)
data := storage.Get(ctx, graveKey).([]byte)
if data == nil {
panic(NotFoundError)
}
d := std.Deserialize(data).(delInfo)
return DelInfo{
Owner: d.Owner,
Epoch: common.FromFixedWidth64(d.Epoch),
}
}
// Get method returns a structure that contains a stable marshaled Container structure,
// the signature, the public key of the container creator and a stable marshaled SessionToken
// structure if it was provided.
//
// If the container doesn't exist, it panics with NotFoundError.
func Get(containerID []byte) Container {
ctx := storage.GetReadOnlyContext()
cnt := getContainer(ctx, containerID)
if len(cnt.value) == 0 {
panic(NotFoundError)
}
return cnt
}
// Owner method returns a 25 byte Owner ID of the container.
//
// If the container doesn't exist, it panics with NotFoundError.
func Owner(containerID []byte) []byte {
ctx := storage.GetReadOnlyContext()
owner := getOwnerByID(ctx, containerID)
if owner == nil {
panic(NotFoundError)
}
return owner
}
// Count method returns the number of registered containers.
func Count() int {
count := 0
ctx := storage.GetReadOnlyContext()
it := storage.Find(ctx, []byte{containerKeyPrefix}, storage.KeysOnly)
for iterator.Next(it) {
count++
}
return count
}
// ContainersOf iterates over all container IDs owned by the specified owner.
// If owner is nil, it iterates over all containers.
func ContainersOf(owner []byte) iterator.Iterator {
ctx := storage.GetReadOnlyContext()
key := []byte{ownerKeyPrefix}
if len(owner) != 0 {
key = append(key, owner...)
}
return storage.Find(ctx, key, storage.ValuesOnly)
}
// List method returns a list of all container IDs owned by the specified owner.
func List(owner []byte) [][]byte {
ctx := storage.GetReadOnlyContext()
if len(owner) == 0 {
return getAllContainers(ctx)
}
var list [][]byte
it := storage.Find(ctx, append([]byte{ownerKeyPrefix}, owner...), storage.ValuesOnly)
for iterator.Next(it) {
id := iterator.Value(it).([]byte)
list = append(list, id)
}
return list
}
// SetEACL method sets a new extended ACL table related to the contract
// if it was invoked by Alphabet nodes of the Inner Ring.
//
// EACL should be a stable marshaled EACLTable structure from API.
// Signature is a RFC6979 signature of the Container.
// PublicKey contains the public key of the signer.
// Token is optional and should be a stable marshaled SessionToken structure from
// API.
//
// If the container doesn't exist, it panics with NotFoundError.
func SetEACL(eACL []byte, signature interop.Signature, publicKey interop.PublicKey, token []byte) {
ctx := storage.GetContext()
// V2 format
// get container ID
offset := int(eACL[1])
offset = 2 + offset + 4
containerID := eACL[offset : offset+32]
ownerID := getOwnerByID(ctx, containerID)
if ownerID == nil {
panic(NotFoundError)
}
common.CheckAlphabetWitness()
rule := ExtendedACL{
value: eACL,
sig: signature,
pub: publicKey,
token: token,
}
key := append(eACLPrefix, containerID...)
common.SetSerialized(ctx, key, rule)
runtime.Log("success")
runtime.Notify("SetEACLSuccess", containerID, publicKey)
}
// EACL method returns a structure that contains a stable marshaled EACLTable structure,
// the signature, the public key of the extended ACL setter and a stable marshaled SessionToken
// structure if it was provided.
//
// If the container doesn't exist, it panics with NotFoundError.
func EACL(containerID []byte) ExtendedACL {
ctx := storage.GetReadOnlyContext()
ownerID := getOwnerByID(ctx, containerID)
if ownerID == nil {
panic(NotFoundError)
}
return getEACL(ctx, containerID)
}
// PutContainerSize method saves container size estimation in contract
// memory. It can be invoked only by Storage nodes from the network map. This method
// checks witness based on the provided public key of the Storage node.
//
// If the container doesn't exist, it panics with NotFoundError.
func PutContainerSize(epoch int, cid []byte, usedSize int, pubKey interop.PublicKey) {
ctx := storage.GetContext()
if getOwnerByID(ctx, cid) == nil {
panic(NotFoundError)
}
common.CheckWitness(pubKey)
if !isStorageNode(ctx, pubKey) {
panic("method must be invoked by storage node from network map")
}
key := estimationKey(epoch, cid, pubKey)
s := estimation{
from: pubKey,
size: usedSize,
}
storage.Put(ctx, key, std.Serialize(s))
updateEstimations(ctx, epoch, cid, pubKey, false)
runtime.Log("saved container size estimation")
}
// GetContainerSize method returns the container ID and a slice of container
// estimations. Container estimation includes the public key of the Storage Node
// that registered estimation and value of estimation.
//
// Use the ID obtained from ListContainerSizes method. Estimations are removed
// from contract storage every epoch, see NewEpoch method; therefore, this method
// can return different results during different epochs.
func GetContainerSize(id []byte) containerSizes {
ctx := storage.GetReadOnlyContext()
// V2 format
// this `id` expected to be from `ListContainerSizes`
// therefore it is not contains postfix, we ignore it in the cut.
ln := len(id)
cid := id[ln-containerIDSize : ln]
return getContainerSizeEstimation(ctx, id, cid)
}
// ListContainerSizes method returns the IDs of container size estimations
// that have been registered for the specified epoch.
func ListContainerSizes(epoch int) [][]byte {
ctx := storage.GetReadOnlyContext()
var buf any = epoch
key := []byte(estimateKeyPrefix)
key = append(key, buf.([]byte)...)
it := storage.Find(ctx, key, storage.KeysOnly)
uniq := map[string]struct{}{}
for iterator.Next(it) {
storageKey := iterator.Value(it).([]byte)
ln := len(storageKey)
storageKey = storageKey[:ln-estimatePostfixSize]
uniq[string(storageKey)] = struct{}{}
}
var result [][]byte
for k := range uniq {
result = append(result, []byte(k))
}
return result
}
// IterateContainerSizes method returns iterator over container size estimations
// that have been registered for the specified epoch.
func IterateContainerSizes(epoch int) iterator.Iterator {
ctx := storage.GetReadOnlyContext()
var buf any = epoch
key := []byte(estimateKeyPrefix)
key = append(key, buf.([]byte)...)
return storage.Find(ctx, key, storage.DeserializeValues)
}
// NewEpoch method removes all container size estimations from epoch older than
// epochNum + 3. It can be invoked only by NewEpoch method of the Netmap contract.
func NewEpoch(epochNum int) {
ctx := storage.GetContext()
common.CheckAlphabetWitness()
cleanupContainers(ctx, epochNum)
}
// StartContainerEstimation method produces StartEstimation notification.
// It can be invoked only by Alphabet nodes of the Inner Ring.
func StartContainerEstimation(epoch int) {
common.CheckAlphabetWitness()
runtime.Notify("StartEstimation", epoch)
runtime.Log("notification has been produced")
}
// StopContainerEstimation method produces StopEstimation notification.
// It can be invoked only by Alphabet nodes of the Inner Ring.
func StopContainerEstimation(epoch int) {
common.CheckAlphabetWitness()
runtime.Notify("StopEstimation", epoch)
runtime.Log("notification has been produced")
}
// Version returns the version of the contract.
func Version() int {
return common.Version
}
func addContainer(ctx storage.Context, id, owner []byte, container Container) {
containerListKey := append([]byte{ownerKeyPrefix}, owner...)
containerListKey = append(containerListKey, id...)
storage.Put(ctx, containerListKey, id)
idKey := append([]byte{containerKeyPrefix}, id...)
common.SetSerialized(ctx, idKey, container)
graveKey := append([]byte{graveKeyPrefix}, id...)
storage.Delete(ctx, graveKey)
}
func removeContainer(ctx storage.Context, id []byte, owner []byte) {
containerListKey := append([]byte{ownerKeyPrefix}, owner...)
containerListKey = append(containerListKey, id...)
storage.Delete(ctx, containerListKey)
storage.Delete(ctx, append([]byte{containerKeyPrefix}, id...))
graveKey := append([]byte{graveKeyPrefix}, id...)
netmapContractAddr := storage.Get(ctx, netmapContractKey).(interop.Hash160)
epoch := contract.Call(netmapContractAddr, "epoch", contract.ReadOnly).(int)
common.SetSerialized(ctx, graveKey, delInfo{
Owner: owner,
Epoch: common.ToFixedWidth64(epoch),
})
}
func getAllContainers(ctx storage.Context) [][]byte {
var list [][]byte
it := storage.Find(ctx, []byte{containerKeyPrefix}, storage.KeysOnly|storage.RemovePrefix)
for iterator.Next(it) {
key := iterator.Value(it).([]byte) // it MUST BE `storage.KeysOnly`
// V2 format
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 std.Deserialize(data.([]byte)).(ExtendedACL)
}
return ExtendedACL{value: []byte{}, sig: interop.Signature{}, pub: interop.PublicKey{}, token: []byte{}}
}
func getContainer(ctx storage.Context, cid []byte) Container {
data := storage.Get(ctx, append([]byte{containerKeyPrefix}, cid...))
if data != nil {
return std.Deserialize(data.([]byte)).(Container)
}
return Container{value: []byte{}, sig: interop.Signature{}, pub: interop.PublicKey{}, token: []byte{}}
}
func getOwnerByID(ctx storage.Context, cid []byte) []byte {
container := getContainer(ctx, cid)
if len(container.value) == 0 {
return nil
}
return ownerFromBinaryContainer(container.value)
}
func ownerFromBinaryContainer(container []byte) []byte {
// V2 format
offset := int(container[1])
offset = 2 + offset + 4 // version prefix + version size + owner prefix
return container[offset : offset+25] // offset + size of owner
}
func estimationKey(epoch int, cid []byte, key interop.PublicKey) []byte {
var buf any = epoch
hash := crypto.Ripemd160(key)
result := []byte(estimateKeyPrefix)
result = append(result, buf.([]byte)...)
result = append(result, cid...)
return append(result, hash[:estimatePostfixSize]...)
}
func getContainerSizeEstimation(ctx storage.Context, key, cid []byte) containerSizes {
var estimations []estimation
it := storage.Find(ctx, key, storage.ValuesOnly|storage.DeserializeValues)
for iterator.Next(it) {
est := iterator.Value(it).(estimation)
estimations = append(estimations, est)
}
return containerSizes{
cid: cid,
estimations: estimations,
}
}
// isStorageNode looks into _previous_ epoch network map, because storage node
// announces container size estimation of the previous epoch.
func isStorageNode(ctx storage.Context, key interop.PublicKey) bool {
netmapContractAddr := storage.Get(ctx, netmapContractKey).(interop.Hash160)
snapshot := contract.Call(netmapContractAddr, "snapshot", contract.ReadOnly, 1).([]storageNode)
for i := range snapshot {
// V2 format
nodeInfo := snapshot[i].info
nodeKey := nodeInfo[2:35] // offset:2, len:33
if common.BytesEqual(key, nodeKey) {
return true
}
}
return false
}
func updateEstimations(ctx storage.Context, epoch int, cid []byte, pub interop.PublicKey, isUpdate bool) {
h := crypto.Ripemd160(pub)
estKey := append([]byte(singleEstimatePrefix), cid...)
estKey = append(estKey, h...)
var newEpochs []int
rawList := storage.Get(ctx, estKey).([]byte)
if rawList != nil {
epochs := std.Deserialize(rawList).([]int)
for _, oldEpoch := range epochs {
if !isUpdate && epoch-oldEpoch > CleanupDelta {
key := append([]byte(estimateKeyPrefix), convert.ToBytes(oldEpoch)...)
key = append(key, cid...)
key = append(key, h[:estimatePostfixSize]...)
storage.Delete(ctx, key)
} else {
newEpochs = append(newEpochs, oldEpoch)
}
}
}
newEpochs = append(newEpochs, epoch)
common.SetSerialized(ctx, estKey, newEpochs)
}
func cleanupContainers(ctx storage.Context, epoch int) {
it := storage.Find(ctx, []byte(estimateKeyPrefix), storage.KeysOnly)
for iterator.Next(it) {
k := iterator.Value(it).([]byte)
// V2 format
nbytes := k[len(estimateKeyPrefix) : len(k)-containerIDSize-estimatePostfixSize]
var n any = nbytes
if epoch-n.(int) > TotalCleanupDelta {
storage.Delete(ctx, k)
}
}
}