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// Copyright (c) 2020-2022 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 <addrman.h>
#include <bench/bench.h>
#include <netgroup.h>
#include <random.h>
#include <util/check.h>
#include <util/time.h>
#include <optional>
#include <vector>
/* A "source" is a source address from which we have received a bunch of other addresses. */
static constexpr size_t NUM_SOURCES = 64;
static constexpr size_t NUM_ADDRESSES_PER_SOURCE = 256;
static NetGroupManager EMPTY_NETGROUPMAN{std::vector<bool>()};
static constexpr uint32_t ADDRMAN_CONSISTENCY_CHECK_RATIO{0};
static std::vector<CAddress> g_sources;
static std::vector<std::vector<CAddress>> g_addresses;
static void CreateAddresses()
{
if (g_sources.size() > 0) { // already created
return;
}
FastRandomContext rng(uint256(std::vector<unsigned char>(32, 123)));
auto randAddr = [&rng]() {
in6_addr addr;
memcpy(&addr, rng.randbytes(sizeof(addr)).data(), sizeof(addr));
uint16_t port;
memcpy(&port, rng.randbytes(sizeof(port)).data(), sizeof(port));
if (port == 0) {
port = 1;
}
CAddress ret(CService(addr, port), NODE_NETWORK);
ret.nTime = Now<NodeSeconds>();
return ret;
};
for (size_t source_i = 0; source_i < NUM_SOURCES; ++source_i) {
g_sources.emplace_back(randAddr());
g_addresses.emplace_back();
for (size_t addr_i = 0; addr_i < NUM_ADDRESSES_PER_SOURCE; ++addr_i) {
g_addresses[source_i].emplace_back(randAddr());
}
}
}
static void AddAddressesToAddrMan(AddrMan& addrman)
{
for (size_t source_i = 0; source_i < NUM_SOURCES; ++source_i) {
addrman.Add(g_addresses[source_i], g_sources[source_i]);
}
}
static void FillAddrMan(AddrMan& addrman)
{
CreateAddresses();
AddAddressesToAddrMan(addrman);
}
/* Benchmarks */
static void AddrManAdd(benchmark::Bench& bench)
{
CreateAddresses();
bench.run([&] {
AddrMan addrman{EMPTY_NETGROUPMAN, /*deterministic=*/false, ADDRMAN_CONSISTENCY_CHECK_RATIO};
AddAddressesToAddrMan(addrman);
});
}
static void AddrManSelect(benchmark::Bench& bench)
{
AddrMan addrman{EMPTY_NETGROUPMAN, /*deterministic=*/false, ADDRMAN_CONSISTENCY_CHECK_RATIO};
FillAddrMan(addrman);
bench.run([&] {
const auto& address = addrman.Select();
assert(address.first.GetPort() > 0);
});
}
static void AddrManGetAddr(benchmark::Bench& bench)
{
AddrMan addrman{EMPTY_NETGROUPMAN, /*deterministic=*/false, ADDRMAN_CONSISTENCY_CHECK_RATIO};
FillAddrMan(addrman);
bench.run([&] {
const auto& addresses = addrman.GetAddr(/*max_addresses=*/2500, /*max_pct=*/23, /*network=*/std::nullopt);
assert(addresses.size() > 0);
});
}
static void AddrManAddThenGood(benchmark::Bench& bench)
{
auto markSomeAsGood = [](AddrMan& addrman) {
for (size_t source_i = 0; source_i < NUM_SOURCES; ++source_i) {
for (size_t addr_i = 0; addr_i < NUM_ADDRESSES_PER_SOURCE; ++addr_i) {
addrman.Good(g_addresses[source_i][addr_i]);
}
}
};
CreateAddresses();
bench.run([&] {
// To make the benchmark independent of the number of evaluations, we always prepare a new addrman.
// This is necessary because AddrMan::Good() method modifies the object, affecting the timing of subsequent calls
// to the same method and we want to do the same amount of work in every loop iteration.
//
// This has some overhead (exactly the result of AddrManAdd benchmark), but that overhead is constant so improvements in
// AddrMan::Good() will still be noticeable.
AddrMan addrman{EMPTY_NETGROUPMAN, /*deterministic=*/false, ADDRMAN_CONSISTENCY_CHECK_RATIO};
AddAddressesToAddrMan(addrman);
markSomeAsGood(addrman);
});
}
BENCHMARK(AddrManAdd, benchmark::PriorityLevel::HIGH);
BENCHMARK(AddrManSelect, benchmark::PriorityLevel::HIGH);
BENCHMARK(AddrManGetAddr, benchmark::PriorityLevel::HIGH);
BENCHMARK(AddrManAddThenGood, benchmark::PriorityLevel::HIGH);
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