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signer.go
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signer.go
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// Copyright (C) 2019-2022, Ava Labs, Inc. All rights reserved.
// See the file LICENSE for licensing terms.
package x
import (
"errors"
"fmt"
stdcontext "context"
"github.com/ava-labs/avalanchego/database"
"github.com/ava-labs/avalanchego/ids"
"github.com/ava-labs/avalanchego/utils/crypto"
"github.com/ava-labs/avalanchego/utils/crypto/keychain"
"github.com/ava-labs/avalanchego/utils/hashing"
"github.com/ava-labs/avalanchego/vms/avm/fxs"
"github.com/ava-labs/avalanchego/vms/avm/txs"
"github.com/ava-labs/avalanchego/vms/components/avax"
"github.com/ava-labs/avalanchego/vms/components/verify"
"github.com/ava-labs/avalanchego/vms/nftfx"
"github.com/ava-labs/avalanchego/vms/propertyfx"
"github.com/ava-labs/avalanchego/vms/secp256k1fx"
)
var (
errUnknownTxType = errors.New("unknown tx type")
errUnknownInputType = errors.New("unknown input type")
errUnknownOpType = errors.New("unknown operation type")
errInvalidNumUTXOsInOp = errors.New("invalid number of UTXOs in operation")
errUnknownCredentialType = errors.New("unknown credential type")
errUnknownOutputType = errors.New("unknown output type")
errInvalidUTXOSigIndex = errors.New("invalid UTXO signature index")
emptySig [crypto.SECP256K1RSigLen]byte
_ Signer = (*signer)(nil)
)
type Signer interface {
SignUnsigned(ctx stdcontext.Context, tx txs.UnsignedTx) (*txs.Tx, error)
Sign(ctx stdcontext.Context, tx *txs.Tx) error
}
type SignerBackend interface {
GetUTXO(ctx stdcontext.Context, chainID, utxoID ids.ID) (*avax.UTXO, error)
}
type signer struct {
kc keychain.Keychain
backend SignerBackend
}
func NewSigner(kc keychain.Keychain, backend SignerBackend) Signer {
return &signer{
kc: kc,
backend: backend,
}
}
func (s *signer) SignUnsigned(ctx stdcontext.Context, utx txs.UnsignedTx) (*txs.Tx, error) {
tx := &txs.Tx{Unsigned: utx}
return tx, s.Sign(ctx, tx)
}
// TODO: implement txs.Visitor here
func (s *signer) Sign(ctx stdcontext.Context, tx *txs.Tx) error {
switch utx := tx.Unsigned.(type) {
case *txs.BaseTx:
return s.signBaseTx(ctx, tx, utx)
case *txs.CreateAssetTx:
return s.signCreateAssetTx(ctx, tx, utx)
case *txs.OperationTx:
return s.signOperationTx(ctx, tx, utx)
case *txs.ImportTx:
return s.signImportTx(ctx, tx, utx)
case *txs.ExportTx:
return s.signExportTx(ctx, tx, utx)
default:
return fmt.Errorf("%w: %T", errUnknownTxType, tx.Unsigned)
}
}
func (s *signer) signBaseTx(ctx stdcontext.Context, tx *txs.Tx, utx *txs.BaseTx) error {
txCreds, txSigners, err := s.getSigners(ctx, utx.BlockchainID, utx.Ins)
if err != nil {
return err
}
return sign(tx, txCreds, txSigners)
}
func (s *signer) signCreateAssetTx(ctx stdcontext.Context, tx *txs.Tx, utx *txs.CreateAssetTx) error {
txCreds, txSigners, err := s.getSigners(ctx, utx.BlockchainID, utx.Ins)
if err != nil {
return err
}
return sign(tx, txCreds, txSigners)
}
func (s *signer) signOperationTx(ctx stdcontext.Context, tx *txs.Tx, utx *txs.OperationTx) error {
txCreds, txSigners, err := s.getSigners(ctx, utx.BlockchainID, utx.Ins)
if err != nil {
return err
}
txOpsCreds, txOpsSigners, err := s.getOpsSigners(ctx, utx.BlockchainID, utx.Ops)
if err != nil {
return err
}
txCreds = append(txCreds, txOpsCreds...)
txSigners = append(txSigners, txOpsSigners...)
return sign(tx, txCreds, txSigners)
}
func (s *signer) signImportTx(ctx stdcontext.Context, tx *txs.Tx, utx *txs.ImportTx) error {
txCreds, txSigners, err := s.getSigners(ctx, utx.BlockchainID, utx.Ins)
if err != nil {
return err
}
txImportCreds, txImportSigners, err := s.getSigners(ctx, utx.SourceChain, utx.ImportedIns)
if err != nil {
return err
}
txCreds = append(txCreds, txImportCreds...)
txSigners = append(txSigners, txImportSigners...)
return sign(tx, txCreds, txSigners)
}
func (s *signer) signExportTx(ctx stdcontext.Context, tx *txs.Tx, utx *txs.ExportTx) error {
txCreds, txSigners, err := s.getSigners(ctx, utx.BlockchainID, utx.Ins)
if err != nil {
return err
}
return sign(tx, txCreds, txSigners)
}
func (s *signer) getSigners(ctx stdcontext.Context, sourceChainID ids.ID, ins []*avax.TransferableInput) ([]verify.Verifiable, [][]keychain.Signer, error) {
txCreds := make([]verify.Verifiable, len(ins))
txSigners := make([][]keychain.Signer, len(ins))
for credIndex, transferInput := range ins {
txCreds[credIndex] = &secp256k1fx.Credential{}
input, ok := transferInput.In.(*secp256k1fx.TransferInput)
if !ok {
return nil, nil, errUnknownInputType
}
inputSigners := make([]keychain.Signer, len(input.SigIndices))
txSigners[credIndex] = inputSigners
utxoID := transferInput.InputID()
utxo, err := s.backend.GetUTXO(ctx, sourceChainID, utxoID)
if err == database.ErrNotFound {
// If we don't have access to the UTXO, then we can't sign this
// transaction. However, we can attempt to partially sign it.
continue
}
if err != nil {
return nil, nil, err
}
out, ok := utxo.Out.(*secp256k1fx.TransferOutput)
if !ok {
return nil, nil, errUnknownOutputType
}
for sigIndex, addrIndex := range input.SigIndices {
if addrIndex >= uint32(len(out.Addrs)) {
return nil, nil, errInvalidUTXOSigIndex
}
addr := out.Addrs[addrIndex]
key, ok := s.kc.Get(addr)
if !ok {
// If we don't have access to the key, then we can't sign this
// transaction. However, we can attempt to partially sign it.
continue
}
inputSigners[sigIndex] = key
}
}
return txCreds, txSigners, nil
}
func (s *signer) getOpsSigners(ctx stdcontext.Context, sourceChainID ids.ID, ops []*txs.Operation) ([]verify.Verifiable, [][]keychain.Signer, error) {
txCreds := make([]verify.Verifiable, len(ops))
txSigners := make([][]keychain.Signer, len(ops))
for credIndex, op := range ops {
var input *secp256k1fx.Input
switch op := op.Op.(type) {
case *secp256k1fx.MintOperation:
txCreds[credIndex] = &secp256k1fx.Credential{}
input = &op.MintInput
case *nftfx.MintOperation:
txCreds[credIndex] = &nftfx.Credential{}
input = &op.MintInput
case *nftfx.TransferOperation:
txCreds[credIndex] = &nftfx.Credential{}
input = &op.Input
case *propertyfx.MintOperation:
txCreds[credIndex] = &propertyfx.Credential{}
input = &op.MintInput
case *propertyfx.BurnOperation:
txCreds[credIndex] = &propertyfx.Credential{}
input = &op.Input
default:
return nil, nil, errUnknownOpType
}
inputSigners := make([]keychain.Signer, len(input.SigIndices))
txSigners[credIndex] = inputSigners
if len(op.UTXOIDs) != 1 {
return nil, nil, errInvalidNumUTXOsInOp
}
utxoID := op.UTXOIDs[0].InputID()
utxo, err := s.backend.GetUTXO(ctx, sourceChainID, utxoID)
if err == database.ErrNotFound {
// If we don't have access to the UTXO, then we can't sign this
// transaction. However, we can attempt to partially sign it.
continue
}
if err != nil {
return nil, nil, err
}
var addrs []ids.ShortID
switch out := utxo.Out.(type) {
case *secp256k1fx.MintOutput:
addrs = out.Addrs
case *nftfx.MintOutput:
addrs = out.Addrs
case *nftfx.TransferOutput:
addrs = out.Addrs
case *propertyfx.MintOutput:
addrs = out.Addrs
case *propertyfx.OwnedOutput:
addrs = out.Addrs
default:
return nil, nil, errUnknownOutputType
}
for sigIndex, addrIndex := range input.SigIndices {
if addrIndex >= uint32(len(addrs)) {
return nil, nil, errInvalidUTXOSigIndex
}
addr := addrs[addrIndex]
key, ok := s.kc.Get(addr)
if !ok {
// If we don't have access to the key, then we can't sign this
// transaction. However, we can attempt to partially sign it.
continue
}
inputSigners[sigIndex] = key
}
}
return txCreds, txSigners, nil
}
func sign(tx *txs.Tx, creds []verify.Verifiable, txSigners [][]keychain.Signer) error {
codec := Parser.Codec()
unsignedBytes, err := codec.Marshal(txs.CodecVersion, &tx.Unsigned)
if err != nil {
return fmt.Errorf("couldn't marshal unsigned tx: %w", err)
}
unsignedHash := hashing.ComputeHash256(unsignedBytes)
if expectedLen := len(txSigners); expectedLen != len(tx.Creds) {
tx.Creds = make([]*fxs.FxCredential, expectedLen)
}
sigCache := make(map[ids.ShortID][crypto.SECP256K1RSigLen]byte)
for credIndex, inputSigners := range txSigners {
fxCred := tx.Creds[credIndex]
if fxCred == nil {
fxCred = &fxs.FxCredential{}
tx.Creds[credIndex] = fxCred
}
credIntf := fxCred.Verifiable
if credIntf == nil {
credIntf = creds[credIndex]
fxCred.Verifiable = credIntf
}
var cred *secp256k1fx.Credential
switch credImpl := credIntf.(type) {
case *secp256k1fx.Credential:
cred = credImpl
case *nftfx.Credential:
cred = &credImpl.Credential
case *propertyfx.Credential:
cred = &credImpl.Credential
default:
return errUnknownCredentialType
}
if expectedLen := len(inputSigners); expectedLen != len(cred.Sigs) {
cred.Sigs = make([][crypto.SECP256K1RSigLen]byte, expectedLen)
}
for sigIndex, signer := range inputSigners {
if signer == nil {
// If we don't have access to the key, then we can't sign this
// transaction. However, we can attempt to partially sign it.
continue
}
addr := signer.Address()
if sig := cred.Sigs[sigIndex]; sig != emptySig {
// If this signature has already been populated, we can just
// copy the needed signature for the future.
sigCache[addr] = sig
continue
}
if sig, exists := sigCache[addr]; exists {
// If this key has already produced a signature, we can just
// copy the previous signature.
cred.Sigs[sigIndex] = sig
continue
}
sig, err := signer.SignHash(unsignedHash)
if err != nil {
return fmt.Errorf("problem signing tx: %w", err)
}
copy(cred.Sigs[sigIndex][:], sig)
sigCache[addr] = cred.Sigs[sigIndex]
}
}
signedBytes, err := codec.Marshal(txs.CodecVersion, tx)
if err != nil {
return fmt.Errorf("couldn't marshal tx: %w", err)
}
tx.Initialize(unsignedBytes, signedBytes)
return nil
}