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// Copyright (c) 2022 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include <chainparams.h>
#include <clientversion.h>
#include <node/blockstorage.h>
#include <node/context.h>
#include <node/kernel_notifications.h>
#include <script/solver.h>
#include <primitives/block.h>
#include <util/chaintype.h>
#include <validation.h>
#include <boost/test/unit_test.hpp>
#include <test/util/logging.h>
#include <test/util/setup_common.h>
using node::BLOCK_SERIALIZATION_HEADER_SIZE;
using node::BlockManager;
using node::KernelNotifications;
using node::MAX_BLOCKFILE_SIZE;
// use BasicTestingSetup here for the data directory configuration, setup, and cleanup
BOOST_FIXTURE_TEST_SUITE(blockmanager_tests, BasicTestingSetup)
BOOST_AUTO_TEST_CASE(blockmanager_find_block_pos)
{
const auto params {CreateChainParams(ArgsManager{}, ChainType::MAIN)};
KernelNotifications notifications{m_node.exit_status};
const BlockManager::Options blockman_opts{
.chainparams = *params,
.blocks_dir = m_args.GetBlocksDirPath(),
.notifications = notifications,
};
BlockManager blockman{m_node.kernel->interrupt, blockman_opts};
// simulate adding a genesis block normally
BOOST_CHECK_EQUAL(blockman.SaveBlockToDisk(params->GenesisBlock(), 0, nullptr).nPos, BLOCK_SERIALIZATION_HEADER_SIZE);
// simulate what happens during reindex
// simulate a well-formed genesis block being found at offset 8 in the blk00000.dat file
// the block is found at offset 8 because there is an 8 byte serialization header
// consisting of 4 magic bytes + 4 length bytes before each block in a well-formed blk file.
FlatFilePos pos{0, BLOCK_SERIALIZATION_HEADER_SIZE};
BOOST_CHECK_EQUAL(blockman.SaveBlockToDisk(params->GenesisBlock(), 0, &pos).nPos, BLOCK_SERIALIZATION_HEADER_SIZE);
// now simulate what happens after reindex for the first new block processed
// the actual block contents don't matter, just that it's a block.
// verify that the write position is at offset 0x12d.
// this is a check to make sure that https://github.com/bitcoin/bitcoin/issues/21379 does not recur
// 8 bytes (for serialization header) + 285 (for serialized genesis block) = 293
// add another 8 bytes for the second block's serialization header and we get 293 + 8 = 301
FlatFilePos actual{blockman.SaveBlockToDisk(params->GenesisBlock(), 1, nullptr)};
BOOST_CHECK_EQUAL(actual.nPos, BLOCK_SERIALIZATION_HEADER_SIZE + ::GetSerializeSize(params->GenesisBlock(), CLIENT_VERSION) + BLOCK_SERIALIZATION_HEADER_SIZE);
}
BOOST_FIXTURE_TEST_CASE(blockmanager_scan_unlink_already_pruned_files, TestChain100Setup)
{
// Cap last block file size, and mine new block in a new block file.
const auto& chainman = Assert(m_node.chainman);
auto& blockman = chainman->m_blockman;
const CBlockIndex* old_tip{WITH_LOCK(chainman->GetMutex(), return chainman->ActiveChain().Tip())};
WITH_LOCK(chainman->GetMutex(), blockman.GetBlockFileInfo(old_tip->GetBlockPos().nFile)->nSize = MAX_BLOCKFILE_SIZE);
CreateAndProcessBlock({}, GetScriptForRawPubKey(coinbaseKey.GetPubKey()));
// Prune the older block file, but don't unlink it
int file_number;
{
LOCK(chainman->GetMutex());
file_number = old_tip->GetBlockPos().nFile;
blockman.PruneOneBlockFile(file_number);
}
const FlatFilePos pos(file_number, 0);
// Check that the file is not unlinked after ScanAndUnlinkAlreadyPrunedFiles
// if m_have_pruned is not yet set
WITH_LOCK(chainman->GetMutex(), blockman.ScanAndUnlinkAlreadyPrunedFiles());
BOOST_CHECK(!AutoFile(blockman.OpenBlockFile(pos, true)).IsNull());
// Check that the file is unlinked after ScanAndUnlinkAlreadyPrunedFiles
// once m_have_pruned is set
blockman.m_have_pruned = true;
WITH_LOCK(chainman->GetMutex(), blockman.ScanAndUnlinkAlreadyPrunedFiles());
BOOST_CHECK(AutoFile(blockman.OpenBlockFile(pos, true)).IsNull());
// Check that calling with already pruned files doesn't cause an error
WITH_LOCK(chainman->GetMutex(), blockman.ScanAndUnlinkAlreadyPrunedFiles());
// Check that the new tip file has not been removed
const CBlockIndex* new_tip{WITH_LOCK(chainman->GetMutex(), return chainman->ActiveChain().Tip())};
BOOST_CHECK_NE(old_tip, new_tip);
const int new_file_number{WITH_LOCK(chainman->GetMutex(), return new_tip->GetBlockPos().nFile)};
const FlatFilePos new_pos(new_file_number, 0);
BOOST_CHECK(!AutoFile(blockman.OpenBlockFile(new_pos, true)).IsNull());
}
BOOST_FIXTURE_TEST_CASE(blockmanager_block_data_availability, TestChain100Setup)
{
// The goal of the function is to return the first not pruned block in the range [upper_block, lower_block].
LOCK(::cs_main);
auto& chainman = m_node.chainman;
auto& blockman = chainman->m_blockman;
const CBlockIndex& tip = *chainman->ActiveTip();
// Function to prune all blocks from 'last_pruned_block' down to the genesis block
const auto& func_prune_blocks = [&](CBlockIndex* last_pruned_block)
{
LOCK(::cs_main);
CBlockIndex* it = last_pruned_block;
while (it != nullptr && it->nStatus & BLOCK_HAVE_DATA) {
it->nStatus &= ~BLOCK_HAVE_DATA;
it = it->pprev;
}
};
// 1) Return genesis block when all blocks are available
BOOST_CHECK_EQUAL(blockman.GetFirstStoredBlock(tip), chainman->ActiveChain()[0]);
BOOST_CHECK(blockman.CheckBlockDataAvailability(tip, *chainman->ActiveChain()[0]));
// 2) Check lower_block when all blocks are available
CBlockIndex* lower_block = chainman->ActiveChain()[tip.nHeight / 2];
BOOST_CHECK(blockman.CheckBlockDataAvailability(tip, *lower_block));
// Prune half of the blocks
int height_to_prune = tip.nHeight / 2;
CBlockIndex* first_available_block = chainman->ActiveChain()[height_to_prune + 1];
CBlockIndex* last_pruned_block = first_available_block->pprev;
func_prune_blocks(last_pruned_block);
// 3) The last block not pruned is in-between upper-block and the genesis block
BOOST_CHECK_EQUAL(blockman.GetFirstStoredBlock(tip), first_available_block);
BOOST_CHECK(blockman.CheckBlockDataAvailability(tip, *first_available_block));
BOOST_CHECK(!blockman.CheckBlockDataAvailability(tip, *last_pruned_block));
}
BOOST_AUTO_TEST_CASE(blockmanager_flush_block_file)
{
KernelNotifications notifications{m_node.exit_status};
node::BlockManager::Options blockman_opts{
.chainparams = Params(),
.blocks_dir = m_args.GetBlocksDirPath(),
.notifications = notifications,
};
BlockManager blockman{m_node.kernel->interrupt, blockman_opts};
// Test blocks with no transactions, not even a coinbase
CBlock block1;
block1.nVersion = 1;
CBlock block2;
block2.nVersion = 2;
CBlock block3;
block3.nVersion = 3;
// They are 80 bytes header + 1 byte 0x00 for vtx length
constexpr int TEST_BLOCK_SIZE{81};
// Blockstore is empty
BOOST_CHECK_EQUAL(blockman.CalculateCurrentUsage(), 0);
// Write the first block; dbp=nullptr means this block doesn't already have a disk
// location, so allocate a free location and write it there.
FlatFilePos pos1{blockman.SaveBlockToDisk(block1, /*nHeight=*/1, /*dbp=*/nullptr)};
// Write second block
FlatFilePos pos2{blockman.SaveBlockToDisk(block2, /*nHeight=*/2, /*dbp=*/nullptr)};
// Two blocks in the file
BOOST_CHECK_EQUAL(blockman.CalculateCurrentUsage(), (TEST_BLOCK_SIZE + BLOCK_SERIALIZATION_HEADER_SIZE) * 2);
// First two blocks are written as expected
// Errors are expected because block data is junk, thrown AFTER successful read
CBlock read_block;
BOOST_CHECK_EQUAL(read_block.nVersion, 0);
{
ASSERT_DEBUG_LOG("ReadBlockFromDisk: Errors in block header");
BOOST_CHECK(!blockman.ReadBlockFromDisk(read_block, pos1));
BOOST_CHECK_EQUAL(read_block.nVersion, 1);
}
{
ASSERT_DEBUG_LOG("ReadBlockFromDisk: Errors in block header");
BOOST_CHECK(!blockman.ReadBlockFromDisk(read_block, pos2));
BOOST_CHECK_EQUAL(read_block.nVersion, 2);
}
// When FlatFilePos* dbp is given, SaveBlockToDisk() will not write or
// overwrite anything to the flat file block storage. It will, however,
// update the blockfile metadata. This is to facilitate reindexing
// when the user has the blocks on disk but the metadata is being rebuilt.
// Verify this behavior by attempting (and failing) to write block 3 data
// to block 2 location.
CBlockFileInfo* block_data = blockman.GetBlockFileInfo(0);
BOOST_CHECK_EQUAL(block_data->nBlocks, 2);
BOOST_CHECK(blockman.SaveBlockToDisk(block3, /*nHeight=*/3, /*dbp=*/&pos2) == pos2);
// Metadata is updated...
BOOST_CHECK_EQUAL(block_data->nBlocks, 3);
// ...but there are still only two blocks in the file
BOOST_CHECK_EQUAL(blockman.CalculateCurrentUsage(), (TEST_BLOCK_SIZE + BLOCK_SERIALIZATION_HEADER_SIZE) * 2);
// Block 2 was not overwritten:
// SaveBlockToDisk() did not call WriteBlockToDisk() because `FlatFilePos* dbp` was non-null
blockman.ReadBlockFromDisk(read_block, pos2);
BOOST_CHECK_EQUAL(read_block.nVersion, 2);
}
BOOST_AUTO_TEST_SUITE_END()
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