package accounting import ( "crypto/ecdsa" "crypto/rand" "encoding/binary" "reflect" "github.com/mr-tron/base58" "github.com/nspcc-dev/neofs-api-go/chain" "github.com/nspcc-dev/neofs-api-go/decimal" "github.com/nspcc-dev/neofs-api-go/internal" "github.com/nspcc-dev/neofs-api-go/refs" crypto "github.com/nspcc-dev/neofs-crypto" "github.com/pkg/errors" ) type ( // Cheque structure that describes a user request for withdrawal of funds. Cheque struct { ID ChequeID Owner refs.OwnerID Amount *decimal.Decimal Height uint64 Signatures []ChequeSignature } // BalanceReceiver interface that is used to retrieve user balance by address. BalanceReceiver interface { Balance(accountAddress string) (*Account, error) } // ChequeID is identifier of user request for withdrawal of funds. ChequeID string // CID type alias. CID = refs.CID // SGID type alias. SGID = refs.SGID // ChequeSignature contains public key and hash, and is used to verify signatures. ChequeSignature struct { Key *ecdsa.PublicKey Hash []byte } ) const ( // ErrWrongSignature is raised when wrong signature is passed. ErrWrongSignature = internal.Error("wrong signature") // ErrWrongPublicKey is raised when wrong public key is passed. ErrWrongPublicKey = internal.Error("wrong public key") // ErrWrongChequeData is raised when passed bytes cannot not be parsed as valid Cheque. ErrWrongChequeData = internal.Error("wrong cheque data") // ErrInvalidLength is raised when passed bytes cannot not be parsed as valid ChequeID. ErrInvalidLength = internal.Error("invalid length") u16size = 2 u64size = 8 signaturesOffset = chain.AddressLength + refs.OwnerIDSize + u64size + u64size ) // NewChequeID generates valid random ChequeID using crypto/rand.Reader. func NewChequeID() (ChequeID, error) { d := make([]byte, chain.AddressLength) if _, err := rand.Read(d); err != nil { return "", err } id := base58.Encode(d) return ChequeID(id), nil } // String returns string representation of ChequeID. func (b ChequeID) String() string { return string(b) } // Empty returns true, if ChequeID is empty. func (b ChequeID) Empty() bool { return len(b) == 0 } // Valid validates ChequeID. func (b ChequeID) Valid() bool { d, err := base58.Decode(string(b)) return err == nil && len(d) == chain.AddressLength } // Bytes returns bytes representation of ChequeID. func (b ChequeID) Bytes() []byte { d, err := base58.Decode(string(b)) if err != nil { return make([]byte, chain.AddressLength) } return d } // Equal checks that current ChequeID is equal to passed ChequeID. func (b ChequeID) Equal(b2 ChequeID) bool { return b.Valid() && b2.Valid() && string(b) == string(b2) } // Unmarshal tries to parse []byte into valid ChequeID. func (b *ChequeID) Unmarshal(data []byte) error { *b = ChequeID(base58.Encode(data)) if !b.Valid() { return ErrInvalidLength } return nil } // Size returns size (chain.AddressLength). func (b ChequeID) Size() int { return chain.AddressLength } // MarshalTo tries to marshal ChequeID into passed bytes and returns // count of copied bytes or error, if bytes len is not enough to contain ChequeID. func (b ChequeID) MarshalTo(data []byte) (int, error) { if len(data) < chain.AddressLength { return 0, ErrInvalidLength } return copy(data, b.Bytes()), nil } // Equals checks that m and tx are valid and equal Tx values. func (m Tx) Equals(tx Tx) bool { return m.From == tx.From && m.To == tx.To && m.Type == tx.Type && m.Amount == tx.Amount } // Verify validates current Cheque and Signatures that are generated for current Cheque. func (b Cheque) Verify() error { data := b.marshalBody() for i, sign := range b.Signatures { if err := crypto.VerifyRFC6979(sign.Key, data, sign.Hash); err != nil { return errors.Wrapf(ErrWrongSignature, "item #%d: %s", i, err.Error()) } } return nil } // Sign is used to sign current Cheque and stores result inside b.Signatures. func (b *Cheque) Sign(key *ecdsa.PrivateKey) error { hash, err := crypto.SignRFC6979(key, b.marshalBody()) if err != nil { return err } b.Signatures = append(b.Signatures, ChequeSignature{ Key: &key.PublicKey, Hash: hash, }) return nil } func (b *Cheque) marshalBody() []byte { buf := make([]byte, signaturesOffset) var offset int offset += copy(buf, b.ID.Bytes()) offset += copy(buf[offset:], b.Owner.Bytes()) binary.LittleEndian.PutUint64(buf[offset:], uint64(b.Amount.Value)) offset += u64size binary.LittleEndian.PutUint64(buf[offset:], b.Height) return buf } func (b *Cheque) unmarshalBody(buf []byte) error { var offset int if len(buf) < signaturesOffset { return ErrWrongChequeData } { // unmarshal UUID if err := b.ID.Unmarshal(buf[offset : offset+chain.AddressLength]); err != nil { return err } offset += chain.AddressLength } { // unmarshal OwnerID if err := b.Owner.Unmarshal(buf[offset : offset+refs.OwnerIDSize]); err != nil { return err } offset += refs.OwnerIDSize } { // unmarshal amount amount := int64(binary.LittleEndian.Uint64(buf[offset:])) b.Amount = decimal.New(amount) offset += u64size } { // unmarshal height b.Height = binary.LittleEndian.Uint64(buf[offset:]) offset += u64size } return nil } // MarshalBinary is used to marshal Cheque into bytes. func (b Cheque) MarshalBinary() ([]byte, error) { var ( count = len(b.Signatures) buf = make([]byte, b.Size()) offset = copy(buf, b.marshalBody()) ) binary.LittleEndian.PutUint16(buf[offset:], uint16(count)) offset += u16size for _, sign := range b.Signatures { key := crypto.MarshalPublicKey(sign.Key) offset += copy(buf[offset:], key) offset += copy(buf[offset:], sign.Hash) } return buf, nil } // Size returns size of Cheque (count of bytes needs to store it). func (b Cheque) Size() int { return signaturesOffset + u16size + len(b.Signatures)*(crypto.PublicKeyCompressedSize+crypto.RFC6979SignatureSize) } // UnmarshalBinary tries to parse []byte into valid Cheque. func (b *Cheque) UnmarshalBinary(buf []byte) error { if err := b.unmarshalBody(buf); err != nil { return err } body := buf[:signaturesOffset] count := int64(binary.LittleEndian.Uint16(buf[signaturesOffset:])) offset := signaturesOffset + u16size if ln := count * int64(crypto.PublicKeyCompressedSize+crypto.RFC6979SignatureSize); ln > int64(len(buf[offset:])) { return ErrWrongChequeData } for i := int64(0); i < count; i++ { sign := ChequeSignature{ Key: crypto.UnmarshalPublicKey(buf[offset : offset+crypto.PublicKeyCompressedSize]), Hash: make([]byte, crypto.RFC6979SignatureSize), } offset += crypto.PublicKeyCompressedSize if sign.Key == nil { return errors.Wrapf(ErrWrongPublicKey, "item #%d", i) } offset += copy(sign.Hash, buf[offset:offset+crypto.RFC6979SignatureSize]) if err := crypto.VerifyRFC6979(sign.Key, body, sign.Hash); err != nil { return errors.Wrapf(ErrWrongSignature, "item #%d: %s (offset=%d, len=%d)", i, err.Error(), offset, len(sign.Hash)) } b.Signatures = append(b.Signatures, sign) } return nil } // ErrNotEnoughFunds generates error using address and amounts. func ErrNotEnoughFunds(addr string, needed, residue *decimal.Decimal) error { return errors.Errorf("not enough funds (requested=%s, residue=%s, addr=%s", needed, residue, addr) } func (m *Account) hasLockAcc(addr string) bool { for i := range m.LockAccounts { if m.LockAccounts[i].Address == addr { return true } } return false } // ValidateLock checks that account can be locked. func (m *Account) ValidateLock() error { switch { case m.Address == "": return ErrEmptyAddress case m.ParentAddress == "": return ErrEmptyParentAddress case m.LockTarget == nil: return ErrEmptyLockTarget } switch v := m.LockTarget.Target.(type) { case *LockTarget_WithdrawTarget: if v.WithdrawTarget.Cheque != m.Address { return errors.Errorf("wrong cheque ID: expected %s, has %s", m.Address, v.WithdrawTarget.Cheque) } case *LockTarget_ContainerCreateTarget: switch { case v.ContainerCreateTarget.CID.Empty(): return ErrEmptyContainerID } } return nil } // CanLock checks possibility to lock funds. func (m *Account) CanLock(lockAcc *Account) error { switch { case m.ActiveFunds.LT(lockAcc.ActiveFunds): return ErrNotEnoughFunds(lockAcc.ParentAddress, lockAcc.ActiveFunds, m.ActiveFunds) case m.hasLockAcc(lockAcc.Address): return errors.Errorf("could not lock account(%s) funds: duplicating lock(%s)", m.Address, lockAcc.Address) default: return nil } } // LockForWithdraw checks that account contains locked funds by passed ChequeID. func (m *Account) LockForWithdraw(chequeID string) bool { switch v := m.LockTarget.Target.(type) { case *LockTarget_WithdrawTarget: return v.WithdrawTarget.Cheque == chequeID } return false } // LockForContainerCreate checks that account contains locked funds for container creation. func (m *Account) LockForContainerCreate(cid refs.CID) bool { switch v := m.LockTarget.Target.(type) { case *LockTarget_ContainerCreateTarget: return v.ContainerCreateTarget.CID.Equal(cid) } return false } // Equal checks that current Settlement is equal to passed Settlement. func (m *Settlement) Equal(s *Settlement) bool { if s == nil || m.Epoch != s.Epoch || len(m.Transactions) != len(s.Transactions) { return false } return len(m.Transactions) == 0 || reflect.DeepEqual(m.Transactions, s.Transactions) } // GetOwnerID is an OwnerID field getter. func (m BalanceRequest) GetOwnerID() OwnerID { return m.OwnerID } // SetOwnerID is an OwnerID field setter. func (m *BalanceRequest) SetOwnerID(owner OwnerID) { m.OwnerID = owner } // GetID is an ID field getter. func (m GetRequest) GetID() ChequeID { return m.ID } // SetID is an ID field setter. func (m *GetRequest) SetID(id ChequeID) { m.ID = id } // GetOwnerID is an OwnerID field getter. func (m GetRequest) GetOwnerID() OwnerID { return m.OwnerID } // SetOwnerID is an OwnerID field setter. func (m *GetRequest) SetOwnerID(id OwnerID) { m.OwnerID = id }