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// Copyright 2023 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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package legacypool
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import (
"crypto/ecdsa"
"math/big"
"testing"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/rawdb"
"github.com/ethereum/go-ethereum/core/state"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/event"
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"github.com/holiman/uint256"
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)
func pricedValuedTransaction ( nonce uint64 , value int64 , gaslimit uint64 , gasprice * big . Int , key * ecdsa . PrivateKey ) * types . Transaction {
tx , _ := types . SignTx ( types . NewTransaction ( nonce , common . Address { } , big . NewInt ( value ) , gaslimit , gasprice , nil ) , types . HomesteadSigner { } , key )
return tx
}
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func count ( t * testing . T , pool * LegacyPool ) ( pending int , queued int ) {
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t . Helper ( )
pending , queued = pool . stats ( )
if err := validatePoolInternals ( pool ) ; err != nil {
t . Fatalf ( "pool internal state corrupted: %v" , err )
}
return pending , queued
}
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func fillPool ( t testing . TB , pool * LegacyPool ) {
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t . Helper ( )
// Create a number of test accounts, fund them and make transactions
executableTxs := types . Transactions { }
nonExecutableTxs := types . Transactions { }
for i := 0 ; i < 384 ; i ++ {
key , _ := crypto . GenerateKey ( )
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pool . currentState . AddBalance ( crypto . PubkeyToAddress ( key . PublicKey ) , uint256 . NewInt ( 10000000000 ) )
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// Add executable ones
for j := 0 ; j < int ( pool . config . AccountSlots ) ; j ++ {
executableTxs = append ( executableTxs , pricedTransaction ( uint64 ( j ) , 100000 , big . NewInt ( 300 ) , key ) )
}
}
// Import the batch and verify that limits have been enforced
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pool . addRemotesSync ( executableTxs )
pool . addRemotesSync ( nonExecutableTxs )
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pending , queued := pool . Stats ( )
slots := pool . all . Slots ( )
// sanity-check that the test prerequisites are ok (pending full)
if have , want := pending , slots ; have != want {
t . Fatalf ( "have %d, want %d" , have , want )
}
if have , want := queued , 0 ; have != want {
t . Fatalf ( "have %d, want %d" , have , want )
}
t . Logf ( "pool.config: GlobalSlots=%d, GlobalQueue=%d\n" , pool . config . GlobalSlots , pool . config . GlobalQueue )
t . Logf ( "pending: %d queued: %d, all: %d\n" , pending , queued , slots )
}
// Tests that if a batch high-priced of non-executables arrive, they do not kick out
// executable transactions
func TestTransactionFutureAttack ( t * testing . T ) {
t . Parallel ( )
// Create the pool to test the limit enforcement with
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statedb , _ := state . New ( types . EmptyRootHash , state . NewDatabase ( rawdb . NewMemoryDatabase ( ) ) , nil )
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blockchain := newTestBlockChain ( eip1559Config , 1000000 , statedb , new ( event . Feed ) )
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config := testTxPoolConfig
config . GlobalQueue = 100
config . GlobalSlots = 100
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pool := New ( config , blockchain )
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pool . Init ( config . PriceLimit , blockchain . CurrentBlock ( ) , makeAddressReserver ( ) )
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defer pool . Close ( )
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fillPool ( t , pool )
pending , _ := pool . Stats ( )
// Now, future transaction attack starts, let's add a bunch of expensive non-executables, and see if the pending-count drops
{
key , _ := crypto . GenerateKey ( )
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pool . currentState . AddBalance ( crypto . PubkeyToAddress ( key . PublicKey ) , uint256 . NewInt ( 100000000000 ) )
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futureTxs := types . Transactions { }
for j := 0 ; j < int ( pool . config . GlobalSlots + pool . config . GlobalQueue ) ; j ++ {
futureTxs = append ( futureTxs , pricedTransaction ( 1000 + uint64 ( j ) , 100000 , big . NewInt ( 500 ) , key ) )
}
for i := 0 ; i < 5 ; i ++ {
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pool . addRemotesSync ( futureTxs )
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newPending , newQueued := count ( t , pool )
t . Logf ( "pending: %d queued: %d, all: %d\n" , newPending , newQueued , pool . all . Slots ( ) )
}
}
newPending , _ := pool . Stats ( )
// Pending should not have been touched
if have , want := newPending , pending ; have < want {
t . Errorf ( "wrong pending-count, have %d, want %d (GlobalSlots: %d)" ,
have , want , pool . config . GlobalSlots )
}
}
// Tests that if a batch high-priced of non-executables arrive, they do not kick out
// executable transactions
func TestTransactionFuture1559 ( t * testing . T ) {
t . Parallel ( )
// Create the pool to test the pricing enforcement with
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statedb , _ := state . New ( types . EmptyRootHash , state . NewDatabase ( rawdb . NewMemoryDatabase ( ) ) , nil )
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blockchain := newTestBlockChain ( eip1559Config , 1000000 , statedb , new ( event . Feed ) )
pool := New ( testTxPoolConfig , blockchain )
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pool . Init ( testTxPoolConfig . PriceLimit , blockchain . CurrentBlock ( ) , makeAddressReserver ( ) )
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defer pool . Close ( )
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// Create a number of test accounts, fund them and make transactions
fillPool ( t , pool )
pending , _ := pool . Stats ( )
// Now, future transaction attack starts, let's add a bunch of expensive non-executables, and see if the pending-count drops
{
key , _ := crypto . GenerateKey ( )
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pool . currentState . AddBalance ( crypto . PubkeyToAddress ( key . PublicKey ) , uint256 . NewInt ( 100000000000 ) )
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futureTxs := types . Transactions { }
for j := 0 ; j < int ( pool . config . GlobalSlots + pool . config . GlobalQueue ) ; j ++ {
futureTxs = append ( futureTxs , dynamicFeeTx ( 1000 + uint64 ( j ) , 100000 , big . NewInt ( 200 ) , big . NewInt ( 101 ) , key ) )
}
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pool . addRemotesSync ( futureTxs )
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}
newPending , _ := pool . Stats ( )
// Pending should not have been touched
if have , want := newPending , pending ; have != want {
t . Errorf ( "Wrong pending-count, have %d, want %d (GlobalSlots: %d)" ,
have , want , pool . config . GlobalSlots )
}
}
// Tests that if a batch of balance-overdraft txs arrive, they do not kick out
// executable transactions
func TestTransactionZAttack ( t * testing . T ) {
t . Parallel ( )
// Create the pool to test the pricing enforcement with
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statedb , _ := state . New ( types . EmptyRootHash , state . NewDatabase ( rawdb . NewMemoryDatabase ( ) ) , nil )
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blockchain := newTestBlockChain ( eip1559Config , 1000000 , statedb , new ( event . Feed ) )
pool := New ( testTxPoolConfig , blockchain )
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pool . Init ( testTxPoolConfig . PriceLimit , blockchain . CurrentBlock ( ) , makeAddressReserver ( ) )
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defer pool . Close ( )
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// Create a number of test accounts, fund them and make transactions
fillPool ( t , pool )
countInvalidPending := func ( ) int {
t . Helper ( )
var ivpendingNum int
pendingtxs , _ := pool . Content ( )
for account , txs := range pendingtxs {
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cur_balance := new ( big . Int ) . Set ( pool . currentState . GetBalance ( account ) . ToBig ( ) )
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for _ , tx := range txs {
if cur_balance . Cmp ( tx . Value ( ) ) <= 0 {
ivpendingNum ++
} else {
cur_balance . Sub ( cur_balance , tx . Value ( ) )
}
}
}
if err := validatePoolInternals ( pool ) ; err != nil {
t . Fatalf ( "pool internal state corrupted: %v" , err )
}
return ivpendingNum
}
ivPending := countInvalidPending ( )
t . Logf ( "invalid pending: %d\n" , ivPending )
// Now, DETER-Z attack starts, let's add a bunch of expensive non-executables (from N accounts) along with balance-overdraft txs (from one account), and see if the pending-count drops
for j := 0 ; j < int ( pool . config . GlobalQueue ) ; j ++ {
futureTxs := types . Transactions { }
key , _ := crypto . GenerateKey ( )
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pool . currentState . AddBalance ( crypto . PubkeyToAddress ( key . PublicKey ) , uint256 . NewInt ( 100000000000 ) )
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futureTxs = append ( futureTxs , pricedTransaction ( 1000 + uint64 ( j ) , 21000 , big . NewInt ( 500 ) , key ) )
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pool . addRemotesSync ( futureTxs )
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}
overDraftTxs := types . Transactions { }
{
key , _ := crypto . GenerateKey ( )
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pool . currentState . AddBalance ( crypto . PubkeyToAddress ( key . PublicKey ) , uint256 . NewInt ( 100000000000 ) )
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for j := 0 ; j < int ( pool . config . GlobalSlots ) ; j ++ {
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overDraftTxs = append ( overDraftTxs , pricedValuedTransaction ( uint64 ( j ) , 600000000000 , 21000 , big . NewInt ( 500 ) , key ) )
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}
}
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pool . addRemotesSync ( overDraftTxs )
pool . addRemotesSync ( overDraftTxs )
pool . addRemotesSync ( overDraftTxs )
pool . addRemotesSync ( overDraftTxs )
pool . addRemotesSync ( overDraftTxs )
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newPending , newQueued := count ( t , pool )
newIvPending := countInvalidPending ( )
t . Logf ( "pool.all.Slots(): %d\n" , pool . all . Slots ( ) )
t . Logf ( "pending: %d queued: %d, all: %d\n" , newPending , newQueued , pool . all . Slots ( ) )
t . Logf ( "invalid pending: %d\n" , newIvPending )
// Pending should not have been touched
if newIvPending != ivPending {
t . Errorf ( "Wrong invalid pending-count, have %d, want %d (GlobalSlots: %d, queued: %d)" ,
newIvPending , ivPending , pool . config . GlobalSlots , newQueued )
}
}
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func BenchmarkFutureAttack ( b * testing . B ) {
// Create the pool to test the limit enforcement with
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statedb , _ := state . New ( types . EmptyRootHash , state . NewDatabase ( rawdb . NewMemoryDatabase ( ) ) , nil )
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blockchain := newTestBlockChain ( eip1559Config , 1000000 , statedb , new ( event . Feed ) )
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config := testTxPoolConfig
config . GlobalQueue = 100
config . GlobalSlots = 100
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pool := New ( config , blockchain )
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pool . Init ( testTxPoolConfig . PriceLimit , blockchain . CurrentBlock ( ) , makeAddressReserver ( ) )
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defer pool . Close ( )
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fillPool ( b , pool )
key , _ := crypto . GenerateKey ( )
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pool . currentState . AddBalance ( crypto . PubkeyToAddress ( key . PublicKey ) , uint256 . NewInt ( 100000000000 ) )
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futureTxs := types . Transactions { }
for n := 0 ; n < b . N ; n ++ {
futureTxs = append ( futureTxs , pricedTransaction ( 1000 + uint64 ( n ) , 100000 , big . NewInt ( 500 ) , key ) )
}
b . ResetTimer ( )
for i := 0 ; i < 5 ; i ++ {
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pool . addRemotesSync ( futureTxs )
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}
}