@ -5,6 +5,7 @@
@@ -5,6 +5,7 @@
# include "coins.h"
# include "script/standard.h"
# include "uint256.h"
# include "undo.h"
# include "utilstrencodings.h"
# include "test/test_bitcoin.h"
# include "test/test_random.h"
@ -16,6 +17,9 @@
@@ -16,6 +17,9 @@
# include <boost/test/unit_test.hpp>
bool ApplyTxInUndo ( const CTxInUndo & undo , CCoinsViewCache & view , const COutPoint & out ) ;
void UpdateCoins ( const CTransaction & tx , CCoinsViewCache & inputs , CTxUndo & txundo , int nHeight ) ;
namespace
{
class CCoinsViewTest : public CCoinsView
@ -213,6 +217,22 @@ BOOST_AUTO_TEST_CASE(coins_cache_simulation_test)
@@ -213,6 +217,22 @@ BOOST_AUTO_TEST_CASE(coins_cache_simulation_test)
BOOST_CHECK ( missed_an_entry ) ;
}
typedef std : : tuple < CTransaction , CTxUndo , CCoins > TxData ;
// Store of all necessary tx and undo data for next test
std : : map < uint256 , TxData > alltxs ;
TxData & FindRandomFrom ( const std : : set < uint256 > & txidset ) {
assert ( txidset . size ( ) ) ;
std : : set < uint256 > : : iterator txIt = txidset . lower_bound ( GetRandHash ( ) ) ;
if ( txIt = = txidset . end ( ) ) {
txIt = txidset . begin ( ) ;
}
std : : map < uint256 , TxData > : : iterator txdit = alltxs . find ( * txIt ) ;
assert ( txdit ! = alltxs . end ( ) ) ;
return txdit - > second ;
}
// This test is similar to the previous test
// except the emphasis is on testing the functionality of UpdateCoins
// random txs are created and UpdateCoins is used to update the cache stack
@ -229,77 +249,139 @@ BOOST_AUTO_TEST_CASE(updatecoins_simulation_test)
@@ -229,77 +249,139 @@ BOOST_AUTO_TEST_CASE(updatecoins_simulation_test)
std : : vector < CCoinsViewCacheTest * > stack ; // A stack of CCoinsViewCaches on top.
stack . push_back ( new CCoinsViewCacheTest ( & base ) ) ; // Start with one cache.
// Track the txids we've used and whether they have been spent or not
std : : map < uint256 , CAmount > coinbaseids ;
std : : set < uint256 > alltx ids;
// Track the txids we've used in various sets
std : : set < uint256 > coinbaseids ;
std : : set < uint256 > disconnected ids;
std : : set < uint256 > duplicateids ;
std : : set < uint256 > utxoset ;
for ( unsigned int i = 0 ; i < NUM_SIMULATION_ITERATIONS ; i + + ) {
{
uint32_t randiter = insecure_rand ( ) ;
// 19/20 txs add a new transaction
if ( randiter % 20 < 19 ) {
CMutableTransaction tx ;
tx . vin . resize ( 1 ) ;
tx . vout . resize ( 1 ) ;
tx . vout [ 0 ] . nValue = i ; //Keep txs unique unless intended to duplicate
unsigned int height = insecure_rand ( ) ;
CCoins oldcoins ;
// 1/10 times create a coinbase
if ( insecure_rand ( ) % 10 = = 0 | | coinbaseids . size ( ) < 10 ) {
// 1/100 times create a duplicate coinbase
// 2/20 times create a new coinbase
if ( randiter % 20 < 2 | | coinbaseids . size ( ) < 10 ) {
// 1/10 of those times create a duplicate coinbase
if ( insecure_rand ( ) % 10 = = 0 & & coinbaseids . size ( ) ) {
std : : map < uint256 , CAmount > : : iterator coinbaseIt = coinbaseids . lower_bound ( GetRandHash ( ) ) ;
if ( coinbaseIt = = coinbaseids . end ( ) ) {
coinbaseIt = coinbaseids . begin ( ) ;
}
//Use same random value to have same hash and be a true duplicate
tx . vout [ 0 ] . nValue = coinbaseIt - > second ;
assert ( tx . GetHash ( ) = = coinbaseIt - > first ) ;
duplicateids . insert ( coinbaseIt - > first ) ;
TxData & txd = FindRandomFrom ( coinbaseids ) ;
// Reuse the exact same coinbase
tx = std : : get < 0 > ( txd ) ;
// shouldn't be available for reconnection if its been duplicated
disconnectedids . erase ( tx . GetHash ( ) ) ;
duplicateids . insert ( tx . GetHash ( ) ) ;
}
else {
coinbaseids [ tx . GetHash ( ) ] = tx . vout [ 0 ] . nValue ;
coinbaseids . insert ( tx . GetHash ( ) ) ;
}
assert ( CTransaction ( tx ) . IsCoinBase ( ) ) ;
}
// 9/10 times create a regular tx
// 17/20 times reconnect previous or add a regular tx
else {
uint256 prevouthash ;
// equally likely to spend coinbase or non coinbase
std : : set < uint256 > : : iterator txIt = alltxids . lower_bound ( GetRandHash ( ) ) ;
if ( txIt = = alltxids . end ( ) ) {
txIt = alltxids . begin ( ) ;
// 1/20 times reconnect a previously disconnected tx
if ( randiter % 20 = = 2 & & disconnectedids . size ( ) ) {
TxData & txd = FindRandomFrom ( disconnectedids ) ;
tx = std : : get < 0 > ( txd ) ;
prevouthash = tx . vin [ 0 ] . prevout . hash ;
if ( ! CTransaction ( tx ) . IsCoinBase ( ) & & ! utxoset . count ( prevouthash ) ) {
disconnectedids . erase ( tx . GetHash ( ) ) ;
continue ;
}
// If this tx is already IN the UTXO, then it must be a coinbase, and it must be a duplicate
if ( utxoset . count ( tx . GetHash ( ) ) ) {
assert ( CTransaction ( tx ) . IsCoinBase ( ) ) ;
assert ( duplicateids . count ( tx . GetHash ( ) ) ) ;
}
prevouthash = * txIt ;
disconnectedids . erase ( tx . GetHash ( ) ) ;
}
// 16/20 times create a regular tx
else {
TxData & txd = FindRandomFrom ( utxoset ) ;
prevouthash = std : : get < 0 > ( txd ) . GetHash ( ) ;
// Construct the tx to spend the coins of prevouthash
tx . vin [ 0 ] . prevout . hash = prevouthash ;
tx . vin [ 0 ] . prevout . n = 0 ;
assert ( ! CTransaction ( tx ) . IsCoinBase ( ) ) ;
}
// In this simple test coins only have two states, spent or unspent, save the unspent state to restore
oldcoins = result [ prevouthash ] ;
// Update the expected result of prevouthash to know these coins are spent
CCoins & oldcoins = result [ prevouthash ] ;
oldcoins . Clear ( ) ;
result [ prevouthash ] . Clear ( ) ;
// It is of particular importance here that once we spend a coinbase tx hash
// it is no longer available to be duplicated (or spent again)
// BIP 34 in conjunction with enforcing BIP 30 (at least until BIP 34 was active)
// results in the fact that no coinbases were duplicated after they were already spent
alltxids . erase ( prevouthash ) ;
coinbaseids . erase ( prevouthash ) ;
utxoset . erase ( prevouthash ) ;
// The test is designed to ensure spending a duplicate coinbase will work properly
// if that ever happens and not resurrect the previously overwritten coinbase
if ( duplicateids . count ( prevouthash ) )
spent_a_duplicate_coinbase = true ;
assert ( ! CTransaction ( tx ) . IsCoinBase ( ) ) ;
}
// Track this tx to possibly spend later
alltxids . insert ( tx . GetHash ( ) ) ;
// Update the expected result to know about the new output coins
CCoins & coins = result [ tx . GetHash ( ) ] ;
coins . FromTx ( tx , height ) ;
result [ tx . GetHash ( ) ] . FromTx ( tx , height ) ;
// Call UpdateCoins on the top cache
CTxUndo undo ;
UpdateCoins ( tx , * ( stack . back ( ) ) , undo , height ) ;
// Update the utxo set for future spends
utxoset . insert ( tx . GetHash ( ) ) ;
// Track this tx and undo info to use later
alltxs . insert ( std : : make_pair ( tx . GetHash ( ) , std : : make_tuple ( tx , undo , oldcoins ) ) ) ;
}
UpdateCoins ( tx , * ( stack . back ( ) ) , height ) ;
//1/20 times undo a previous transaction
else if ( utxoset . size ( ) ) {
TxData & txd = FindRandomFrom ( utxoset ) ;
CTransaction & tx = std : : get < 0 > ( txd ) ;
CTxUndo & undo = std : : get < 1 > ( txd ) ;
CCoins & origcoins = std : : get < 2 > ( txd ) ;
uint256 undohash = tx . GetHash ( ) ;
// Update the expected result
// Remove new outputs
result [ undohash ] . Clear ( ) ;
// If not coinbase restore prevout
if ( ! tx . IsCoinBase ( ) ) {
result [ tx . vin [ 0 ] . prevout . hash ] = origcoins ;
}
// Disconnect the tx from the current UTXO
// See code in DisconnectBlock
// remove outputs
{
CCoinsModifier outs = stack . back ( ) - > ModifyCoins ( undohash ) ;
outs - > Clear ( ) ;
}
// restore inputs
if ( ! tx . IsCoinBase ( ) ) {
const COutPoint & out = tx . vin [ 0 ] . prevout ;
const CTxInUndo & undoin = undo . vprevout [ 0 ] ;
ApplyTxInUndo ( undoin , * ( stack . back ( ) ) , out ) ;
}
// Store as a candidate for reconnection
disconnectedids . insert ( undohash ) ;
// Update the utxoset
utxoset . erase ( undohash ) ;
if ( ! tx . IsCoinBase ( ) )
utxoset . insert ( tx . vin [ 0 ] . prevout . hash ) ;
}
// Once every 1000 iterations and at the end, verify the full cache.
@ -420,6 +502,7 @@ BOOST_AUTO_TEST_CASE(ccoins_serialization)
@@ -420,6 +502,7 @@ BOOST_AUTO_TEST_CASE(ccoins_serialization)
const static uint256 TXID ;
const static CAmount PRUNED = - 1 ;
const static CAmount ABSENT = - 2 ;
const static CAmount FAIL = - 3 ;
const static CAmount VALUE1 = 100 ;
const static CAmount VALUE2 = 200 ;
const static CAmount VALUE3 = 300 ;
@ -630,11 +713,17 @@ BOOST_AUTO_TEST_CASE(ccoins_modify)
@@ -630,11 +713,17 @@ BOOST_AUTO_TEST_CASE(ccoins_modify)
void CheckModifyNewCoinsBase ( CAmount base_value , CAmount cache_value , CAmount modify_value , CAmount expected_value , char cache_flags , char expected_flags , bool coinbase )
{
SingleEntryCacheTest test ( base_value , cache_value , cache_flags ) ;
SetCoinsValue ( modify_value , * test . cache . ModifyNewCoins ( TXID , coinbase ) ) ;
CAmount result_value ;
char result_flags ;
try {
SetCoinsValue ( modify_value , * test . cache . ModifyNewCoins ( TXID , coinbase ) ) ;
GetCoinsMapEntry ( test . cache . map ( ) , result_value , result_flags ) ;
} catch ( std : : logic_error & e ) {
result_value = FAIL ;
result_flags = NO_ENTRY ;
}
BOOST_CHECK_EQUAL ( result_value , expected_value ) ;
BOOST_CHECK_EQUAL ( result_flags , expected_flags ) ;
}
@ -669,7 +758,7 @@ BOOST_AUTO_TEST_CASE(ccoins_modify_new)
@@ -669,7 +758,7 @@ BOOST_AUTO_TEST_CASE(ccoins_modify_new)
CheckModifyNewCoins ( PRUNED , PRUNED , PRUNED , 0 , DIRTY , true ) ;
CheckModifyNewCoins ( PRUNED , PRUNED , ABSENT , FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( PRUNED , PRUNED , ABSENT , FRESH , NO_ENTRY , true ) ;
CheckModifyNewCoins ( PRUNED , PRUNED , ABSENT , DIRTY , NO_ENTRY , false ) ;
CheckModifyNewCoins ( PRUNED , PRUNED , PRUNED , DIRTY , DIRTY , false ) ;
CheckModifyNewCoins ( PRUNED , PRUNED , PRUNED , DIRTY , DIRTY , true ) ;
CheckModifyNewCoins ( PRUNED , PRUNED , ABSENT , DIRTY | FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( PRUNED , PRUNED , ABSENT , DIRTY | FRESH , NO_ENTRY , true ) ;
@ -677,25 +766,25 @@ BOOST_AUTO_TEST_CASE(ccoins_modify_new)
@@ -677,25 +766,25 @@ BOOST_AUTO_TEST_CASE(ccoins_modify_new)
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , 0 , DIRTY , true ) ;
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , FRESH , DIRTY | FRESH , false ) ;
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , FRESH , DIRTY | FRESH , true ) ;
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , DIRTY , DIRTY | FRESH , false ) ;
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , DIRTY , DIRTY , false ) ;
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , DIRTY , DIRTY , true ) ;
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , DIRTY | FRESH , DIRTY | FRESH , false ) ;
CheckModifyNewCoins ( PRUNED , VALUE3 , VALUE3 , DIRTY | FRESH , DIRTY | FRESH , true ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , ABSENT , 0 , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , FAIL , 0 , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , PRUNED , 0 , DIRTY , true ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , ABSENT , FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , FAIL , FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , ABSENT , FRESH , NO_ENTRY , true ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , ABSENT , DIRTY , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , FAIL , DIRTY , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , PRUNED , DIRTY , DIRTY , true ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , ABSENT , DIRTY | FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , FAIL , DIRTY | FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , PRUNED , ABSENT , DIRTY | FRESH , NO_ENTRY , true ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , 0 , DIRTY | FRESH , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , FAIL , 0 , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , 0 , DIRTY , true ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , FRESH , DIRTY | FRESH , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , FAIL , FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , FRESH , DIRTY | FRESH , true ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , DIRTY , DIRTY | FRESH , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , FAIL , DIRTY , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , DIRTY , DIRTY , true ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , DIRTY | FRESH , DIRTY | FRESH , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , FAIL , DIRTY | FRESH , NO_ENTRY , false ) ;
CheckModifyNewCoins ( VALUE2 , VALUE3 , VALUE3 , DIRTY | FRESH , DIRTY | FRESH , true ) ;
}