// Copyright (c) 2017, The Monero Project
//
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#include <boost/uuid/uuid.hpp>
#include "gtest/gtest.h"
#include "crypto/crypto.h"
#include "cryptonote_protocol/cryptonote_protocol_defs.h"
#include "cryptonote_protocol/block_queue.h"
static const boost::uuids::uuid &uuid1()
{
static const boost::uuids::uuid uuid = crypto::rand<boost::uuids::uuid>();
return uuid;
}
static const boost::uuids::uuid &uuid2()
{
static const boost::uuids::uuid uuid = crypto::rand<boost::uuids::uuid>();
return uuid;
}
TEST(block_queue, empty)
{
cryptonote::block_queue bq;
ASSERT_EQ(bq.get_max_block_height(), 0);
}
TEST(block_queue, add_stepwise)
{
cryptonote::block_queue bq;
bq.add_blocks(0, 200, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 199);
bq.add_blocks(200, 200, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 399);
bq.add_blocks(401, 200, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 600);
bq.add_blocks(400, 10, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 600);
}
TEST(block_queue, flush_uuid)
{
cryptonote::block_queue bq;
bq.add_blocks(0, 200, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 199);
bq.add_blocks(200, 200, uuid2());
ASSERT_EQ(bq.get_max_block_height(), 399);
bq.flush_spans(uuid2());
ASSERT_EQ(bq.get_max_block_height(), 199);
bq.flush_spans(uuid1());
ASSERT_EQ(bq.get_max_block_height(), 0);
bq.add_blocks(0, 200, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 199);
bq.add_blocks(200, 200, uuid2());
ASSERT_EQ(bq.get_max_block_height(), 399);
bq.flush_spans(uuid1());
ASSERT_EQ(bq.get_max_block_height(), 399);
bq.add_blocks(0, 200, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 399);
}
TEST(block_queue, reserve_overlaps_both)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(0, 100, uuid1());
bq.add_blocks(200, 100, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 299);
span = bq.reserve_span(50, 250, 250, uuid2());
ASSERT_EQ(span.first, 100);
ASSERT_EQ(span.second, 100);
}
TEST(block_queue, reserve_overlaps_none)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(0, 100, uuid1());
bq.add_blocks(200, 100, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 299);
span = bq.reserve_span(120, 180, 250, uuid2());
ASSERT_EQ(span.first, 120);
ASSERT_EQ(span.second, 61);
}
TEST(block_queue, reserve_overlaps_none_max_hit)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(0, 100, uuid1());
bq.add_blocks(200, 100, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 299);
span = bq.reserve_span(120, 500, 50, uuid2());
ASSERT_EQ(span.first, 120);
ASSERT_EQ(span.second, 50);
}
TEST(block_queue, reserve_overlaps_start)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(0, 100, uuid1());
bq.add_blocks(200, 100, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 299);
span = bq.reserve_span(50, 150, 250, uuid2());
ASSERT_EQ(span.first, 100);
ASSERT_EQ(span.second, 51);
}
TEST(block_queue, reserve_overlaps_start_max_hit)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(0, 100, uuid1());
bq.add_blocks(200, 100, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 299);
span = bq.reserve_span(50, 300, 75, uuid2());
ASSERT_EQ(span.first, 100);
ASSERT_EQ(span.second, 75);
}
TEST(block_queue, reserve_overlaps_stop)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(0, 100, uuid1());
bq.add_blocks(200, 100, uuid1());
ASSERT_EQ(bq.get_max_block_height(), 299);
span = bq.reserve_span(150, 300, 250, uuid2());
ASSERT_EQ(span.first, 150);
ASSERT_EQ(span.second, 50);
}
TEST(block_queue, reserve_start_is_empty_after)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(100, 100, uuid1());
span = bq.reserve_span(150, 250, 100, uuid1());
ASSERT_EQ(span.first, 200);
ASSERT_EQ(span.second, 51);
}
TEST(block_queue, reserve_start_is_empty_start_fits)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(100, 100, uuid1());
span = bq.reserve_span(0, 250, 50, uuid1());
ASSERT_EQ(span.first, 0);
ASSERT_EQ(span.second, 50);
}
TEST(block_queue, reserve_start_is_empty_start_overflows)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(100, 100, uuid1());
span = bq.reserve_span(0, 250, 150, uuid1());
ASSERT_EQ(span.first, 0);
ASSERT_EQ(span.second, 100);
}
TEST(block_queue, flush_spans)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
bq.add_blocks(100, 100, uuid2());
bq.add_blocks(200, 100, uuid1());
bq.add_blocks(300, 100, uuid2());
ASSERT_EQ(bq.get_max_block_height(), 399);
bq.flush_spans(uuid2());
ASSERT_EQ(bq.get_max_block_height(), 299);
span = bq.reserve_span(0, 500, 500, uuid1());
ASSERT_EQ(span.first, 0);
ASSERT_EQ(span.second, 200);
bq.flush_spans(uuid1());
ASSERT_EQ(bq.get_max_block_height(), 0);
}
TEST(block_queue, get_next_span)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
uint64_t height;
std::list<cryptonote::block_complete_entry> blocks;
boost::uuids::uuid uuid;
bq.add_blocks(100, std::list<cryptonote::block_complete_entry>(100), uuid2(), 0, 0);
bq.add_blocks(200, std::list<cryptonote::block_complete_entry>(101), uuid1(), 0, 0);
bq.add_blocks(300, std::list<cryptonote::block_complete_entry>(102), uuid2(), 0, 0);
ASSERT_TRUE(bq.get_next_span(height, blocks, uuid));
ASSERT_EQ(height, 100);
ASSERT_EQ(blocks.size(), 100);
ASSERT_EQ(uuid, uuid2());
bq.remove_span(height);
ASSERT_TRUE(bq.get_next_span(height, blocks, uuid));
ASSERT_EQ(height, 200);
ASSERT_EQ(blocks.size(), 101);
ASSERT_EQ(uuid, uuid1());
bq.remove_span(height);
ASSERT_TRUE(bq.get_next_span(height, blocks, uuid));
ASSERT_EQ(height, 300);
ASSERT_EQ(blocks.size(), 102);
ASSERT_EQ(uuid, uuid2());
bq.remove_span(height);
ASSERT_FALSE(bq.get_next_span(height, blocks, uuid));
}
TEST(block_queue, get_next_span_if_scheduled)
{
cryptonote::block_queue bq;
std::pair<uint64_t, uint64_t> span;
uint64_t height;
std::list<cryptonote::block_complete_entry> blocks;
boost::uuids::uuid uuid;
std::list<crypto::hash> hashes;
boost::posix_time::ptime time;
bq.reserve_span(0, 100, 100, uuid1());
span = bq.get_next_span_if_scheduled(hashes, uuid, time);
ASSERT_EQ(span.first, 0);
ASSERT_EQ(span.second, 100);
ASSERT_EQ(uuid, uuid1());
bq.add_blocks(0, std::list<cryptonote::block_complete_entry>(100), uuid1(), 0, 0);
span = bq.get_next_span_if_scheduled(hashes, uuid, time);
ASSERT_EQ(span.second, 0);
}
