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bitcoin-bitcoin-core/src/bench/coin_selection.cpp

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scripted-diff: Bump copyright headers -BEGIN VERIFY SCRIPT- ./contrib/devtools/copyright_header.py update ./ -END VERIFY SCRIPT- Commits of previous years: - 2021: f47dda2c58b5d8d623e0e7ff4e74bc352dfa83d7 - 2020: fa0074e2d82928016a43ca408717154a1c70a4db - 2019: aaaaad6ac95b402fe18d019d67897ced6b316ee0
2022-12-24 23:49:50 +00:00
// Copyright (c) 2012-2022 The Bitcoin Core developers
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
scripted-diff: Replace #include "" with #include <> (ryanofsky) -BEGIN VERIFY SCRIPT- for f in \ src/*.cpp \ src/*.h \ src/bench/*.cpp \ src/bench/*.h \ src/compat/*.cpp \ src/compat/*.h \ src/consensus/*.cpp \ src/consensus/*.h \ src/crypto/*.cpp \ src/crypto/*.h \ src/crypto/ctaes/*.h \ src/policy/*.cpp \ src/policy/*.h \ src/primitives/*.cpp \ src/primitives/*.h \ src/qt/*.cpp \ src/qt/*.h \ src/qt/test/*.cpp \ src/qt/test/*.h \ src/rpc/*.cpp \ src/rpc/*.h \ src/script/*.cpp \ src/script/*.h \ src/support/*.cpp \ src/support/*.h \ src/support/allocators/*.h \ src/test/*.cpp \ src/test/*.h \ src/wallet/*.cpp \ src/wallet/*.h \ src/wallet/test/*.cpp \ src/wallet/test/*.h \ src/zmq/*.cpp \ src/zmq/*.h do base=${f%/*}/ relbase=${base#src/} sed -i "s:#include \"\(.*\)\"\(.*\):if test -e \$base'\\1'; then echo \"#include <\"\$relbase\"\\1>\\2\"; else echo \"#include <\\1>\\2\"; fi:e" $f done -END VERIFY SCRIPT-
2017-11-10 13:57:53 +13:00
#include <bench/bench.h>
Pass chain and client variables where needed This commit does not change behavior. All it does is pass new function parameters. It is easiest to review this change with: git log -p -n1 -U0 --word-diff-regex=.
2017-05-30 15:55:17 -04:00
#include <interfaces/chain.h>
Pass NodeContext, ConnMan, BanMan references more places So g_connman and g_banman globals can be removed next commit.
2019-09-17 18:28:03 -04:00
#include <node/context.h>
coin selection: BnB, don't return selection if exceeds max allowed tx weight
2022-12-18 20:16:19 -03:00
#include <policy/policy.h>
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
#include <wallet/coinselection.h>
refactor: Detach wallet transaction methods (followup for move-only) Followup to commit "MOVEONLY: CWallet transaction code out of wallet.cpp/.h" that detaches and renames some CWalletTx methods, making into them into standalone functions or CWallet methods instead. There are no changes in behavior and no code changes that aren't purely mechanical. It just gives spend and receive functions more consistent names and removes the circular dependencies added by the earlier MOVEONLY commit. There are also no comment or documentation changes. Removed comments from transaction.h are just migrated to spend.h, receive.h, and wallet.h.
2021-02-12 18:01:22 -05:00
#include <wallet/spend.h>
bench: Destroy wallet txs instead of leaking their memory
2018-11-27 16:53:49 -05:00
#include <wallet/wallet.h>
wallet, tests: Replace usage of dummy db with mockable db
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#include <wallet/test/util.h>
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
#include <set>
Add src/node/* code to node:: namespace
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using node::NodeContext;
Add src/wallet/* code to wallet:: namespace
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using wallet::AttemptSelection;
[wallet] remove MIN_CHANGE
2022-03-10 10:38:31 +00:00
using wallet::CHANGE_LOWER;
Add src/wallet/* code to wallet:: namespace
2021-11-12 11:13:29 -05:00
using wallet::COutput;
using wallet::CWallet;
using wallet::CWalletTx;
using wallet::CoinEligibilityFilter;
using wallet::CoinSelectionParams;
wallet, tests: Replace usage of dummy db with mockable db
2022-12-12 15:40:48 -05:00
using wallet::CreateMockableWalletDatabase;
Add src/wallet/* code to wallet:: namespace
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using wallet::OutputGroup;
using wallet::SelectCoinsBnB;
using wallet::TxStateInactive;
Add src/node/* code to node:: namespace
2021-11-12 10:06:00 -05:00
bench: Destroy wallet txs instead of leaking their memory
2018-11-27 16:53:49 -05:00
static void addCoin(const CAmount& nValue, const CWallet& wallet, std::vector<std::unique_ptr<CWalletTx>>& wtxs)
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
{
static int nextLockTime = 0;
CMutableTransaction tx;
tx.nLockTime = nextLockTime++; // so all transactions get different hashes
bench: Destroy wallet txs instead of leaking their memory
2018-11-27 16:53:49 -05:00
tx.vout.resize(1);
tx.vout[0].nValue = nValue;
refactor: Make CWalletTx sync state type-safe Current CWalletTx state representation makes it possible to set inconsistent states that won't be handled correctly by wallet sync code or serialized & deserialized back into the same form. For example, it is possible to call setConflicted without setting a conflicting block hash, or setConfirmed with no transaction index. And it's possible update individual m_confirm and fInMempool data fields without setting an overall consistent state that can be serialized and handled correctly. Fix this without changing behavior by using std::variant, instead of an enum and collection of fields, to represent sync state, so state tracking code is safer and more legible. This is a first step to fixing state tracking bugs https://github.com/bitcoin-core/bitcoin-devwiki/wiki/Wallet-Transaction-Conflict-Tracking, by adding an extra margin of safety that can prevent new bugs from being introduced as existing bugs are fixed.
2021-02-16 22:36:26 -05:00
wtxs.push_back(std::make_unique<CWalletTx>(MakeTransactionRef(std::move(tx)), TxStateInactive{}));
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
}
// Simple benchmark for wallet coin selection. Note that it maybe be necessary
// to build up more complicated scenarios in order to get meaningful
// measurements of performance. From laanwj, "Wallet coin selection is probably
// the hardest, as you need a wider selection of scenarios, just testing the
// same one over and over isn't too useful. Generating random isn't useful
// either for measurements."
// (https://github.com/bitcoin/bitcoin/issues/7883#issuecomment-224807484)
Replace current benchmarking framework with nanobench This replaces the current benchmarking framework with nanobench [1], an MIT licensed single-header benchmarking library, of which I am the autor. This has in my opinion several advantages, especially on Linux: * fast: Running all benchmarks takes ~6 seconds instead of 4m13s on an Intel i7-8700 CPU @ 3.20GHz. * accurate: I ran e.g. the benchmark for SipHash_32b 10 times and calculate standard deviation / mean = coefficient of variation: * 0.57% CV for old benchmarking framework * 0.20% CV for nanobench So the benchmark results with nanobench seem to vary less than with the old framework. * It automatically determines runtime based on clock precision, no need to specify number of evaluations. * measure instructions, cycles, branches, instructions per cycle, branch misses (only Linux, when performance counters are available) * output in markdown table format. * Warn about unstable environment (frequency scaling, turbo, ...) * For better profiling, it is possible to set the environment variable NANOBENCH_ENDLESS to force endless running of a particular benchmark without the need to recompile. This makes it to e.g. run "perf top" and look at hotspots. Here is an example copy & pasted from the terminal output: | ns/byte | byte/s | err% | ins/byte | cyc/byte | IPC | bra/byte | miss% | total | benchmark |--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|---------------:|--------:|----------:|:---------- | 2.52 | 396,529,415.94 | 0.6% | 25.42 | 8.02 | 3.169 | 0.06 | 0.0% | 0.03 | `bench/crypto_hash.cpp RIPEMD160` | 1.87 | 535,161,444.83 | 0.3% | 21.36 | 5.95 | 3.589 | 0.06 | 0.0% | 0.02 | `bench/crypto_hash.cpp SHA1` | 3.22 | 310,344,174.79 | 1.1% | 36.80 | 10.22 | 3.601 | 0.09 | 0.0% | 0.04 | `bench/crypto_hash.cpp SHA256` | 2.01 | 496,375,796.23 | 0.0% | 18.72 | 6.43 | 2.911 | 0.01 | 1.0% | 0.00 | `bench/crypto_hash.cpp SHA256D64_1024` | 7.23 | 138,263,519.35 | 0.1% | 82.66 | 23.11 | 3.577 | 1.63 | 0.1% | 0.00 | `bench/crypto_hash.cpp SHA256_32b` | 3.04 | 328,780,166.40 | 0.3% | 35.82 | 9.69 | 3.696 | 0.03 | 0.0% | 0.03 | `bench/crypto_hash.cpp SHA512` [1] https://github.com/martinus/nanobench * Adds support for asymptotes This adds support to calculate asymptotic complexity of a benchmark. This is similar to #17375, but currently only one asymptote is supported, and I have added support in the benchmark `ComplexMemPool` as an example. Usage is e.g. like this: ``` ./bench_bitcoin -filter=ComplexMemPool -asymptote=25,50,100,200,400,600,800 ``` This runs the benchmark `ComplexMemPool` several times but with different complexityN settings. The benchmark can extract that number and use it accordingly. Here, it's used for `childTxs`. The output is this: | complexityN | ns/op | op/s | err% | ins/op | cyc/op | IPC | total | benchmark |------------:|--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|----------:|:---------- | 25 | 1,064,241.00 | 939.64 | 1.4% | 3,960,279.00 | 2,829,708.00 | 1.400 | 0.01 | `ComplexMemPool` | 50 | 1,579,530.00 | 633.10 | 1.0% | 6,231,810.00 | 4,412,674.00 | 1.412 | 0.02 | `ComplexMemPool` | 100 | 4,022,774.00 | 248.58 | 0.6% | 16,544,406.00 | 11,889,535.00 | 1.392 | 0.04 | `ComplexMemPool` | 200 | 15,390,986.00 | 64.97 | 0.2% | 63,904,254.00 | 47,731,705.00 | 1.339 | 0.17 | `ComplexMemPool` | 400 | 69,394,711.00 | 14.41 | 0.1% | 272,602,461.00 | 219,014,691.00 | 1.245 | 0.76 | `ComplexMemPool` | 600 | 168,977,165.00 | 5.92 | 0.1% | 639,108,082.00 | 535,316,887.00 | 1.194 | 1.86 | `ComplexMemPool` | 800 | 310,109,077.00 | 3.22 | 0.1% |1,149,134,246.00 | 984,620,812.00 | 1.167 | 3.41 | `ComplexMemPool` | coefficient | err% | complexity |--------------:|-------:|------------ | 4.78486e-07 | 4.5% | O(n^2) | 6.38557e-10 | 21.7% | O(n^3) | 3.42338e-05 | 38.0% | O(n log n) | 0.000313914 | 46.9% | O(n) | 0.0129823 | 114.4% | O(log n) | 0.0815055 | 133.8% | O(1) The best fitting curve is O(n^2), so the algorithm seems to scale quadratic with `childTxs` in the range 25 to 800.
2020-06-13 09:37:27 +02:00
static void CoinSelection(benchmark::Bench& bench)
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
{
Pass NodeContext, ConnMan, BanMan references more places So g_connman and g_banman globals can be removed next commit.
2019-09-17 18:28:03 -04:00
NodeContext node;
auto chain = interfaces::MakeChain(node);
wallet, tests: Replace usage of dummy db with mockable db
2022-12-12 15:40:48 -05:00
CWallet wallet(chain.get(), "", CreateMockableWalletDatabase());
bench: Destroy wallet txs instead of leaking their memory
2018-11-27 16:53:49 -05:00
std::vector<std::unique_ptr<CWalletTx>> wtxs;
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
LOCK(wallet.cs_wallet);
bench: Simplify CoinSelection
2018-06-28 11:48:27 +01:00
// Add coins.
for (int i = 0; i < 1000; ++i) {
bench: Destroy wallet txs instead of leaking their memory
2018-11-27 16:53:49 -05:00
addCoin(1000 * COIN, wallet, wtxs);
}
addCoin(3 * COIN, wallet, wtxs);
Move GroupOutputs into SelectCoinsMinConf
2020-08-31 15:30:51 -04:00
// Create coins
refactor: use CoinsResult struct in SelectCoins Pass the whole CoinsResult struct to SelectCoins instead of only a vector. This means we now have to remove preselected coins from each OutputType vector and shuffle each vector individually. Pass the whole CoinsResult struct to AttemptSelection. This involves moving the logic in AttemptSelection to a newly named function, ChooseSelectionResult. This will allow us to run ChooseSelectionResult over each OutputType in a later commit. This ensures the backoffs work properly. Update unit and bench tests to use CoinResult.
2022-04-20 13:37:18 +02:00
wallet::CoinsResult available_coins;
bench: Destroy wallet txs instead of leaking their memory
2018-11-27 16:53:49 -05:00
for (const auto& wtx : wtxs) {
wallet: replace GetTxSpendSize with CalculateMaximumSignedInputSize
2022-06-27 09:09:09 +02:00
const auto txout = wtx->tx->vout.at(0);
wallet: switch to new shuffle, erase, push_back switch to new methods, remove old code. this also updates the Size, All, and Clear methods to now use the coins map. this commit is not strictly a refactor because previously coin selection was never run over the UNKNOWN type until the last step when being run over all. now that we are iterating over each, it is run over UNKNOWN but this is expected to be empty most of the time. Co-authored-by: furszy <matiasfurszyfer@protonmail.com>
2022-07-29 10:35:50 +02:00
available_coins.coins[OutputType::BECH32].emplace_back(COutPoint(wtx->GetHash(), 0), txout, /*depth=*/6 * 24, CalculateMaximumSignedInputSize(txout, &wallet, /*coin_control=*/nullptr), /*spendable=*/true, /*solvable=*/true, /*safe=*/true, wtx->GetTxTime(), /*from_me=*/true, /*fees=*/ 0);
bench: Simplify CoinSelection
2018-06-28 11:48:27 +01:00
}
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
bench: Simplify CoinSelection
2018-06-28 11:48:27 +01:00
const CoinEligibilityFilter filter_standard(1, 6, 0);
wallet: Pass FastRandomContext& to coin selection
2022-03-14 15:22:42 +01:00
FastRandomContext rand{};
const CoinSelectionParams coin_selection_params{
rand,
bench: fix incorrect named args in coin_selection bench
2022-03-22 13:54:08 +00:00
/*change_output_size=*/ 34,
/*change_spend_size=*/ 148,
[wallet] remove MIN_CHANGE
2022-03-10 10:38:31 +00:00
/*min_change_target=*/ CHANGE_LOWER,
bench: fix incorrect named args in coin_selection bench
2022-03-22 13:54:08 +00:00
/*effective_feerate=*/ CFeeRate(0),
/*long_term_feerate=*/ CFeeRate(0),
/*discard_feerate=*/ CFeeRate(0),
/*tx_noinputs_size=*/ 0,
/*avoid_partial=*/ false,
wallet: Pass FastRandomContext& to coin selection
2022-03-14 15:22:42 +01:00
};
wallet: single output groups filtering and grouping process Optimizes coin selection by performing the "group outputs" procedure only once, outside the "attempt selection" process. Avoiding the repeated execution of the 'GroupOutputs' operation that occurs on each coin eligibility filters (up to 8 of them); then for every coin vector type plus one for all the coins together. This also let us not perform coin selection over coin eligibility filtered groups that don't add new elements. (because, if the previous round failed, and the subsequent one has the same coins, then this new round will fail again).
2022-08-03 19:04:36 -03:00
auto group = wallet::GroupOutputs(wallet, available_coins, coin_selection_params, {{filter_standard}})[filter_standard];
Replace current benchmarking framework with nanobench This replaces the current benchmarking framework with nanobench [1], an MIT licensed single-header benchmarking library, of which I am the autor. This has in my opinion several advantages, especially on Linux: * fast: Running all benchmarks takes ~6 seconds instead of 4m13s on an Intel i7-8700 CPU @ 3.20GHz. * accurate: I ran e.g. the benchmark for SipHash_32b 10 times and calculate standard deviation / mean = coefficient of variation: * 0.57% CV for old benchmarking framework * 0.20% CV for nanobench So the benchmark results with nanobench seem to vary less than with the old framework. * It automatically determines runtime based on clock precision, no need to specify number of evaluations. * measure instructions, cycles, branches, instructions per cycle, branch misses (only Linux, when performance counters are available) * output in markdown table format. * Warn about unstable environment (frequency scaling, turbo, ...) * For better profiling, it is possible to set the environment variable NANOBENCH_ENDLESS to force endless running of a particular benchmark without the need to recompile. This makes it to e.g. run "perf top" and look at hotspots. Here is an example copy & pasted from the terminal output: | ns/byte | byte/s | err% | ins/byte | cyc/byte | IPC | bra/byte | miss% | total | benchmark |--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|---------------:|--------:|----------:|:---------- | 2.52 | 396,529,415.94 | 0.6% | 25.42 | 8.02 | 3.169 | 0.06 | 0.0% | 0.03 | `bench/crypto_hash.cpp RIPEMD160` | 1.87 | 535,161,444.83 | 0.3% | 21.36 | 5.95 | 3.589 | 0.06 | 0.0% | 0.02 | `bench/crypto_hash.cpp SHA1` | 3.22 | 310,344,174.79 | 1.1% | 36.80 | 10.22 | 3.601 | 0.09 | 0.0% | 0.04 | `bench/crypto_hash.cpp SHA256` | 2.01 | 496,375,796.23 | 0.0% | 18.72 | 6.43 | 2.911 | 0.01 | 1.0% | 0.00 | `bench/crypto_hash.cpp SHA256D64_1024` | 7.23 | 138,263,519.35 | 0.1% | 82.66 | 23.11 | 3.577 | 1.63 | 0.1% | 0.00 | `bench/crypto_hash.cpp SHA256_32b` | 3.04 | 328,780,166.40 | 0.3% | 35.82 | 9.69 | 3.696 | 0.03 | 0.0% | 0.03 | `bench/crypto_hash.cpp SHA512` [1] https://github.com/martinus/nanobench * Adds support for asymptotes This adds support to calculate asymptotic complexity of a benchmark. This is similar to #17375, but currently only one asymptote is supported, and I have added support in the benchmark `ComplexMemPool` as an example. Usage is e.g. like this: ``` ./bench_bitcoin -filter=ComplexMemPool -asymptote=25,50,100,200,400,600,800 ``` This runs the benchmark `ComplexMemPool` several times but with different complexityN settings. The benchmark can extract that number and use it accordingly. Here, it's used for `childTxs`. The output is this: | complexityN | ns/op | op/s | err% | ins/op | cyc/op | IPC | total | benchmark |------------:|--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|----------:|:---------- | 25 | 1,064,241.00 | 939.64 | 1.4% | 3,960,279.00 | 2,829,708.00 | 1.400 | 0.01 | `ComplexMemPool` | 50 | 1,579,530.00 | 633.10 | 1.0% | 6,231,810.00 | 4,412,674.00 | 1.412 | 0.02 | `ComplexMemPool` | 100 | 4,022,774.00 | 248.58 | 0.6% | 16,544,406.00 | 11,889,535.00 | 1.392 | 0.04 | `ComplexMemPool` | 200 | 15,390,986.00 | 64.97 | 0.2% | 63,904,254.00 | 47,731,705.00 | 1.339 | 0.17 | `ComplexMemPool` | 400 | 69,394,711.00 | 14.41 | 0.1% | 272,602,461.00 | 219,014,691.00 | 1.245 | 0.76 | `ComplexMemPool` | 600 | 168,977,165.00 | 5.92 | 0.1% | 639,108,082.00 | 535,316,887.00 | 1.194 | 1.86 | `ComplexMemPool` | 800 | 310,109,077.00 | 3.22 | 0.1% |1,149,134,246.00 | 984,620,812.00 | 1.167 | 3.41 | `ComplexMemPool` | coefficient | err% | complexity |--------------:|-------:|------------ | 4.78486e-07 | 4.5% | O(n^2) | 6.38557e-10 | 21.7% | O(n^3) | 3.42338e-05 | 38.0% | O(n log n) | 0.000313914 | 46.9% | O(n) | 0.0129823 | 114.4% | O(log n) | 0.0815055 | 133.8% | O(1) The best fitting curve is O(n^2), so the algorithm seems to scale quadratic with `childTxs` in the range 25 to 800.
2020-06-13 09:37:27 +02:00
bench.run([&] {
Amend bumpfee for inputs with overlapping ancestry At the end of coin selection reduce the fees by the difference between the individual bump fee estimates and the collective bump fee estimate.
2023-09-13 14:10:47 -04:00
auto result = AttemptSelection(wallet.chain(), 1003 * COIN, group, coin_selection_params, /*allow_mixed_output_types=*/true);
Use SelectionResult in AttemptSelection Replace setCoinsRet and nValueRet with a SelectionResult in AttemptSelection
2021-05-21 18:39:41 -04:00
assert(result);
assert(result->GetSelectedValue() == 1003 * COIN);
assert(result->GetInputSet().size() == 2);
Replace current benchmarking framework with nanobench This replaces the current benchmarking framework with nanobench [1], an MIT licensed single-header benchmarking library, of which I am the autor. This has in my opinion several advantages, especially on Linux: * fast: Running all benchmarks takes ~6 seconds instead of 4m13s on an Intel i7-8700 CPU @ 3.20GHz. * accurate: I ran e.g. the benchmark for SipHash_32b 10 times and calculate standard deviation / mean = coefficient of variation: * 0.57% CV for old benchmarking framework * 0.20% CV for nanobench So the benchmark results with nanobench seem to vary less than with the old framework. * It automatically determines runtime based on clock precision, no need to specify number of evaluations. * measure instructions, cycles, branches, instructions per cycle, branch misses (only Linux, when performance counters are available) * output in markdown table format. * Warn about unstable environment (frequency scaling, turbo, ...) * For better profiling, it is possible to set the environment variable NANOBENCH_ENDLESS to force endless running of a particular benchmark without the need to recompile. This makes it to e.g. run "perf top" and look at hotspots. Here is an example copy & pasted from the terminal output: | ns/byte | byte/s | err% | ins/byte | cyc/byte | IPC | bra/byte | miss% | total | benchmark |--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|---------------:|--------:|----------:|:---------- | 2.52 | 396,529,415.94 | 0.6% | 25.42 | 8.02 | 3.169 | 0.06 | 0.0% | 0.03 | `bench/crypto_hash.cpp RIPEMD160` | 1.87 | 535,161,444.83 | 0.3% | 21.36 | 5.95 | 3.589 | 0.06 | 0.0% | 0.02 | `bench/crypto_hash.cpp SHA1` | 3.22 | 310,344,174.79 | 1.1% | 36.80 | 10.22 | 3.601 | 0.09 | 0.0% | 0.04 | `bench/crypto_hash.cpp SHA256` | 2.01 | 496,375,796.23 | 0.0% | 18.72 | 6.43 | 2.911 | 0.01 | 1.0% | 0.00 | `bench/crypto_hash.cpp SHA256D64_1024` | 7.23 | 138,263,519.35 | 0.1% | 82.66 | 23.11 | 3.577 | 1.63 | 0.1% | 0.00 | `bench/crypto_hash.cpp SHA256_32b` | 3.04 | 328,780,166.40 | 0.3% | 35.82 | 9.69 | 3.696 | 0.03 | 0.0% | 0.03 | `bench/crypto_hash.cpp SHA512` [1] https://github.com/martinus/nanobench * Adds support for asymptotes This adds support to calculate asymptotic complexity of a benchmark. This is similar to #17375, but currently only one asymptote is supported, and I have added support in the benchmark `ComplexMemPool` as an example. Usage is e.g. like this: ``` ./bench_bitcoin -filter=ComplexMemPool -asymptote=25,50,100,200,400,600,800 ``` This runs the benchmark `ComplexMemPool` several times but with different complexityN settings. The benchmark can extract that number and use it accordingly. Here, it's used for `childTxs`. The output is this: | complexityN | ns/op | op/s | err% | ins/op | cyc/op | IPC | total | benchmark |------------:|--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|----------:|:---------- | 25 | 1,064,241.00 | 939.64 | 1.4% | 3,960,279.00 | 2,829,708.00 | 1.400 | 0.01 | `ComplexMemPool` | 50 | 1,579,530.00 | 633.10 | 1.0% | 6,231,810.00 | 4,412,674.00 | 1.412 | 0.02 | `ComplexMemPool` | 100 | 4,022,774.00 | 248.58 | 0.6% | 16,544,406.00 | 11,889,535.00 | 1.392 | 0.04 | `ComplexMemPool` | 200 | 15,390,986.00 | 64.97 | 0.2% | 63,904,254.00 | 47,731,705.00 | 1.339 | 0.17 | `ComplexMemPool` | 400 | 69,394,711.00 | 14.41 | 0.1% | 272,602,461.00 | 219,014,691.00 | 1.245 | 0.76 | `ComplexMemPool` | 600 | 168,977,165.00 | 5.92 | 0.1% | 639,108,082.00 | 535,316,887.00 | 1.194 | 1.86 | `ComplexMemPool` | 800 | 310,109,077.00 | 3.22 | 0.1% |1,149,134,246.00 | 984,620,812.00 | 1.167 | 3.41 | `ComplexMemPool` | coefficient | err% | complexity |--------------:|-------:|------------ | 4.78486e-07 | 4.5% | O(n^2) | 6.38557e-10 | 21.7% | O(n^3) | 3.42338e-05 | 38.0% | O(n log n) | 0.000313914 | 46.9% | O(n) | 0.0129823 | 114.4% | O(log n) | 0.0815055 | 133.8% | O(1) The best fitting curve is O(n^2), so the algorithm seems to scale quadratic with `childTxs` in the range 25 to 800.
2020-06-13 09:37:27 +02:00
});
Add microbenchmarks to profile more code paths. The new benchmarks exercise script validation, CCoinsDBView caching, mempool eviction, and wallet coin selection code. All of the benchmarks added here are extremely simple and don't necessarily mirror common real world conditions or interesting performance edge cases. Details about how specific benchmarks can be improved are noted in comments. Github-Issue: #7883
2016-10-02 17:38:48 -04:00
}
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
// Copied from src/wallet/test/coinselector_tests.cpp
wallet: Switch to using output groups instead of coins in coin selection
2018-07-19 11:45:26 +09:00
static void add_coin(const CAmount& nValue, int nInput, std::vector<OutputGroup>& set)
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
{
CMutableTransaction tx;
tx.vout.resize(nInput + 1);
tx.vout[nInput].nValue = nValue;
Set effective_value when initializing a COutput Previously in COutput, effective_value was initialized as the absolute value of the txout, and fee as 0. effective_value along with fee were calculated outside of the COutput constructor and set after the object had been initialized. These changes will allow either the fee or the feerate to be passed in a COutput constructor. If either are provided, fee and effective_value are calculated and set in the constructor. As a result, AvailableCoins also needs to be passed the feerate when utxos are being spent. When balance is calculated or the coins are being listed and feerate is neither available nor required, AvailableCoinsListUnspent is used instead, which runs AvailableCoins while providing the default value for feerate. Unit tests for the calculation of effective value have also been added.
2022-04-24 18:01:58 -04:00
COutput output(COutPoint(tx.GetHash(), nInput), tx.vout.at(nInput), /*depth=*/ 0, /*input_bytes=*/ -1, /*spendable=*/ true, /*solvable=*/ true, /*safe=*/ true, /*time=*/ 0, /*from_me=*/ true, /*fees=*/ 0);
Remove OutputGroup non-default constructors
2020-08-31 15:10:49 -04:00
set.emplace_back();
refactor: make OutputGroup::m_outputs field a vector of shared_ptr Initial steps towards sharing COutput instances across all possible OutputGroups (instead of copying them time after time).
2022-08-01 16:15:36 -03:00
set.back().Insert(std::make_shared<COutput>(output), /*ancestors=*/ 0, /*descendants=*/ 0);
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
}
// Copied from src/wallet/test/coinselector_tests.cpp
wallet: Switch to using output groups instead of coins in coin selection
2018-07-19 11:45:26 +09:00
static CAmount make_hard_case(int utxos, std::vector<OutputGroup>& utxo_pool)
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
{
utxo_pool.clear();
CAmount target = 0;
for (int i = 0; i < utxos; ++i) {
refactor: use braced init for integer constants instead of c style casts
2021-12-18 12:50:58 -05:00
target += CAmount{1} << (utxos+i);
add_coin(CAmount{1} << (utxos+i), 2*i, utxo_pool);
add_coin((CAmount{1} << (utxos+i)) + (CAmount{1} << (utxos-1-i)), 2*i + 1, utxo_pool);
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
}
return target;
}
Replace current benchmarking framework with nanobench This replaces the current benchmarking framework with nanobench [1], an MIT licensed single-header benchmarking library, of which I am the autor. This has in my opinion several advantages, especially on Linux: * fast: Running all benchmarks takes ~6 seconds instead of 4m13s on an Intel i7-8700 CPU @ 3.20GHz. * accurate: I ran e.g. the benchmark for SipHash_32b 10 times and calculate standard deviation / mean = coefficient of variation: * 0.57% CV for old benchmarking framework * 0.20% CV for nanobench So the benchmark results with nanobench seem to vary less than with the old framework. * It automatically determines runtime based on clock precision, no need to specify number of evaluations. * measure instructions, cycles, branches, instructions per cycle, branch misses (only Linux, when performance counters are available) * output in markdown table format. * Warn about unstable environment (frequency scaling, turbo, ...) * For better profiling, it is possible to set the environment variable NANOBENCH_ENDLESS to force endless running of a particular benchmark without the need to recompile. This makes it to e.g. run "perf top" and look at hotspots. Here is an example copy & pasted from the terminal output: | ns/byte | byte/s | err% | ins/byte | cyc/byte | IPC | bra/byte | miss% | total | benchmark |--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|---------------:|--------:|----------:|:---------- | 2.52 | 396,529,415.94 | 0.6% | 25.42 | 8.02 | 3.169 | 0.06 | 0.0% | 0.03 | `bench/crypto_hash.cpp RIPEMD160` | 1.87 | 535,161,444.83 | 0.3% | 21.36 | 5.95 | 3.589 | 0.06 | 0.0% | 0.02 | `bench/crypto_hash.cpp SHA1` | 3.22 | 310,344,174.79 | 1.1% | 36.80 | 10.22 | 3.601 | 0.09 | 0.0% | 0.04 | `bench/crypto_hash.cpp SHA256` | 2.01 | 496,375,796.23 | 0.0% | 18.72 | 6.43 | 2.911 | 0.01 | 1.0% | 0.00 | `bench/crypto_hash.cpp SHA256D64_1024` | 7.23 | 138,263,519.35 | 0.1% | 82.66 | 23.11 | 3.577 | 1.63 | 0.1% | 0.00 | `bench/crypto_hash.cpp SHA256_32b` | 3.04 | 328,780,166.40 | 0.3% | 35.82 | 9.69 | 3.696 | 0.03 | 0.0% | 0.03 | `bench/crypto_hash.cpp SHA512` [1] https://github.com/martinus/nanobench * Adds support for asymptotes This adds support to calculate asymptotic complexity of a benchmark. This is similar to #17375, but currently only one asymptote is supported, and I have added support in the benchmark `ComplexMemPool` as an example. Usage is e.g. like this: ``` ./bench_bitcoin -filter=ComplexMemPool -asymptote=25,50,100,200,400,600,800 ``` This runs the benchmark `ComplexMemPool` several times but with different complexityN settings. The benchmark can extract that number and use it accordingly. Here, it's used for `childTxs`. The output is this: | complexityN | ns/op | op/s | err% | ins/op | cyc/op | IPC | total | benchmark |------------:|--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|----------:|:---------- | 25 | 1,064,241.00 | 939.64 | 1.4% | 3,960,279.00 | 2,829,708.00 | 1.400 | 0.01 | `ComplexMemPool` | 50 | 1,579,530.00 | 633.10 | 1.0% | 6,231,810.00 | 4,412,674.00 | 1.412 | 0.02 | `ComplexMemPool` | 100 | 4,022,774.00 | 248.58 | 0.6% | 16,544,406.00 | 11,889,535.00 | 1.392 | 0.04 | `ComplexMemPool` | 200 | 15,390,986.00 | 64.97 | 0.2% | 63,904,254.00 | 47,731,705.00 | 1.339 | 0.17 | `ComplexMemPool` | 400 | 69,394,711.00 | 14.41 | 0.1% | 272,602,461.00 | 219,014,691.00 | 1.245 | 0.76 | `ComplexMemPool` | 600 | 168,977,165.00 | 5.92 | 0.1% | 639,108,082.00 | 535,316,887.00 | 1.194 | 1.86 | `ComplexMemPool` | 800 | 310,109,077.00 | 3.22 | 0.1% |1,149,134,246.00 | 984,620,812.00 | 1.167 | 3.41 | `ComplexMemPool` | coefficient | err% | complexity |--------------:|-------:|------------ | 4.78486e-07 | 4.5% | O(n^2) | 6.38557e-10 | 21.7% | O(n^3) | 3.42338e-05 | 38.0% | O(n log n) | 0.000313914 | 46.9% | O(n) | 0.0129823 | 114.4% | O(log n) | 0.0815055 | 133.8% | O(1) The best fitting curve is O(n^2), so the algorithm seems to scale quadratic with `childTxs` in the range 25 to 800.
2020-06-13 09:37:27 +02:00
static void BnBExhaustion(benchmark::Bench& bench)
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
{
// Setup
wallet: Switch to using output groups instead of coins in coin selection
2018-07-19 11:45:26 +09:00
std::vector<OutputGroup> utxo_pool;
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
Replace current benchmarking framework with nanobench This replaces the current benchmarking framework with nanobench [1], an MIT licensed single-header benchmarking library, of which I am the autor. This has in my opinion several advantages, especially on Linux: * fast: Running all benchmarks takes ~6 seconds instead of 4m13s on an Intel i7-8700 CPU @ 3.20GHz. * accurate: I ran e.g. the benchmark for SipHash_32b 10 times and calculate standard deviation / mean = coefficient of variation: * 0.57% CV for old benchmarking framework * 0.20% CV for nanobench So the benchmark results with nanobench seem to vary less than with the old framework. * It automatically determines runtime based on clock precision, no need to specify number of evaluations. * measure instructions, cycles, branches, instructions per cycle, branch misses (only Linux, when performance counters are available) * output in markdown table format. * Warn about unstable environment (frequency scaling, turbo, ...) * For better profiling, it is possible to set the environment variable NANOBENCH_ENDLESS to force endless running of a particular benchmark without the need to recompile. This makes it to e.g. run "perf top" and look at hotspots. Here is an example copy & pasted from the terminal output: | ns/byte | byte/s | err% | ins/byte | cyc/byte | IPC | bra/byte | miss% | total | benchmark |--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|---------------:|--------:|----------:|:---------- | 2.52 | 396,529,415.94 | 0.6% | 25.42 | 8.02 | 3.169 | 0.06 | 0.0% | 0.03 | `bench/crypto_hash.cpp RIPEMD160` | 1.87 | 535,161,444.83 | 0.3% | 21.36 | 5.95 | 3.589 | 0.06 | 0.0% | 0.02 | `bench/crypto_hash.cpp SHA1` | 3.22 | 310,344,174.79 | 1.1% | 36.80 | 10.22 | 3.601 | 0.09 | 0.0% | 0.04 | `bench/crypto_hash.cpp SHA256` | 2.01 | 496,375,796.23 | 0.0% | 18.72 | 6.43 | 2.911 | 0.01 | 1.0% | 0.00 | `bench/crypto_hash.cpp SHA256D64_1024` | 7.23 | 138,263,519.35 | 0.1% | 82.66 | 23.11 | 3.577 | 1.63 | 0.1% | 0.00 | `bench/crypto_hash.cpp SHA256_32b` | 3.04 | 328,780,166.40 | 0.3% | 35.82 | 9.69 | 3.696 | 0.03 | 0.0% | 0.03 | `bench/crypto_hash.cpp SHA512` [1] https://github.com/martinus/nanobench * Adds support for asymptotes This adds support to calculate asymptotic complexity of a benchmark. This is similar to #17375, but currently only one asymptote is supported, and I have added support in the benchmark `ComplexMemPool` as an example. Usage is e.g. like this: ``` ./bench_bitcoin -filter=ComplexMemPool -asymptote=25,50,100,200,400,600,800 ``` This runs the benchmark `ComplexMemPool` several times but with different complexityN settings. The benchmark can extract that number and use it accordingly. Here, it's used for `childTxs`. The output is this: | complexityN | ns/op | op/s | err% | ins/op | cyc/op | IPC | total | benchmark |------------:|--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|----------:|:---------- | 25 | 1,064,241.00 | 939.64 | 1.4% | 3,960,279.00 | 2,829,708.00 | 1.400 | 0.01 | `ComplexMemPool` | 50 | 1,579,530.00 | 633.10 | 1.0% | 6,231,810.00 | 4,412,674.00 | 1.412 | 0.02 | `ComplexMemPool` | 100 | 4,022,774.00 | 248.58 | 0.6% | 16,544,406.00 | 11,889,535.00 | 1.392 | 0.04 | `ComplexMemPool` | 200 | 15,390,986.00 | 64.97 | 0.2% | 63,904,254.00 | 47,731,705.00 | 1.339 | 0.17 | `ComplexMemPool` | 400 | 69,394,711.00 | 14.41 | 0.1% | 272,602,461.00 | 219,014,691.00 | 1.245 | 0.76 | `ComplexMemPool` | 600 | 168,977,165.00 | 5.92 | 0.1% | 639,108,082.00 | 535,316,887.00 | 1.194 | 1.86 | `ComplexMemPool` | 800 | 310,109,077.00 | 3.22 | 0.1% |1,149,134,246.00 | 984,620,812.00 | 1.167 | 3.41 | `ComplexMemPool` | coefficient | err% | complexity |--------------:|-------:|------------ | 4.78486e-07 | 4.5% | O(n^2) | 6.38557e-10 | 21.7% | O(n^3) | 3.42338e-05 | 38.0% | O(n log n) | 0.000313914 | 46.9% | O(n) | 0.0129823 | 114.4% | O(log n) | 0.0815055 | 133.8% | O(1) The best fitting curve is O(n^2), so the algorithm seems to scale quadratic with `childTxs` in the range 25 to 800.
2020-06-13 09:37:27 +02:00
bench.run([&] {
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
// Benchmark
CAmount target = make_hard_case(17, utxo_pool);
coin selection: BnB, don't return selection if exceeds max allowed tx weight
2022-12-18 20:16:19 -03:00
SelectCoinsBnB(utxo_pool, target, 0, MAX_STANDARD_TX_WEIGHT); // Should exhaust
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
// Cleanup
utxo_pool.clear();
Replace current benchmarking framework with nanobench This replaces the current benchmarking framework with nanobench [1], an MIT licensed single-header benchmarking library, of which I am the autor. This has in my opinion several advantages, especially on Linux: * fast: Running all benchmarks takes ~6 seconds instead of 4m13s on an Intel i7-8700 CPU @ 3.20GHz. * accurate: I ran e.g. the benchmark for SipHash_32b 10 times and calculate standard deviation / mean = coefficient of variation: * 0.57% CV for old benchmarking framework * 0.20% CV for nanobench So the benchmark results with nanobench seem to vary less than with the old framework. * It automatically determines runtime based on clock precision, no need to specify number of evaluations. * measure instructions, cycles, branches, instructions per cycle, branch misses (only Linux, when performance counters are available) * output in markdown table format. * Warn about unstable environment (frequency scaling, turbo, ...) * For better profiling, it is possible to set the environment variable NANOBENCH_ENDLESS to force endless running of a particular benchmark without the need to recompile. This makes it to e.g. run "perf top" and look at hotspots. Here is an example copy & pasted from the terminal output: | ns/byte | byte/s | err% | ins/byte | cyc/byte | IPC | bra/byte | miss% | total | benchmark |--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|---------------:|--------:|----------:|:---------- | 2.52 | 396,529,415.94 | 0.6% | 25.42 | 8.02 | 3.169 | 0.06 | 0.0% | 0.03 | `bench/crypto_hash.cpp RIPEMD160` | 1.87 | 535,161,444.83 | 0.3% | 21.36 | 5.95 | 3.589 | 0.06 | 0.0% | 0.02 | `bench/crypto_hash.cpp SHA1` | 3.22 | 310,344,174.79 | 1.1% | 36.80 | 10.22 | 3.601 | 0.09 | 0.0% | 0.04 | `bench/crypto_hash.cpp SHA256` | 2.01 | 496,375,796.23 | 0.0% | 18.72 | 6.43 | 2.911 | 0.01 | 1.0% | 0.00 | `bench/crypto_hash.cpp SHA256D64_1024` | 7.23 | 138,263,519.35 | 0.1% | 82.66 | 23.11 | 3.577 | 1.63 | 0.1% | 0.00 | `bench/crypto_hash.cpp SHA256_32b` | 3.04 | 328,780,166.40 | 0.3% | 35.82 | 9.69 | 3.696 | 0.03 | 0.0% | 0.03 | `bench/crypto_hash.cpp SHA512` [1] https://github.com/martinus/nanobench * Adds support for asymptotes This adds support to calculate asymptotic complexity of a benchmark. This is similar to #17375, but currently only one asymptote is supported, and I have added support in the benchmark `ComplexMemPool` as an example. Usage is e.g. like this: ``` ./bench_bitcoin -filter=ComplexMemPool -asymptote=25,50,100,200,400,600,800 ``` This runs the benchmark `ComplexMemPool` several times but with different complexityN settings. The benchmark can extract that number and use it accordingly. Here, it's used for `childTxs`. The output is this: | complexityN | ns/op | op/s | err% | ins/op | cyc/op | IPC | total | benchmark |------------:|--------------------:|--------------------:|--------:|----------------:|----------------:|-------:|----------:|:---------- | 25 | 1,064,241.00 | 939.64 | 1.4% | 3,960,279.00 | 2,829,708.00 | 1.400 | 0.01 | `ComplexMemPool` | 50 | 1,579,530.00 | 633.10 | 1.0% | 6,231,810.00 | 4,412,674.00 | 1.412 | 0.02 | `ComplexMemPool` | 100 | 4,022,774.00 | 248.58 | 0.6% | 16,544,406.00 | 11,889,535.00 | 1.392 | 0.04 | `ComplexMemPool` | 200 | 15,390,986.00 | 64.97 | 0.2% | 63,904,254.00 | 47,731,705.00 | 1.339 | 0.17 | `ComplexMemPool` | 400 | 69,394,711.00 | 14.41 | 0.1% | 272,602,461.00 | 219,014,691.00 | 1.245 | 0.76 | `ComplexMemPool` | 600 | 168,977,165.00 | 5.92 | 0.1% | 639,108,082.00 | 535,316,887.00 | 1.194 | 1.86 | `ComplexMemPool` | 800 | 310,109,077.00 | 3.22 | 0.1% |1,149,134,246.00 | 984,620,812.00 | 1.167 | 3.41 | `ComplexMemPool` | coefficient | err% | complexity |--------------:|-------:|------------ | 4.78486e-07 | 4.5% | O(n^2) | 6.38557e-10 | 21.7% | O(n^3) | 3.42338e-05 | 38.0% | O(n log n) | 0.000313914 | 46.9% | O(n) | 0.0129823 | 114.4% | O(log n) | 0.0815055 | 133.8% | O(1) The best fitting curve is O(n^2), so the algorithm seems to scale quadratic with `childTxs` in the range 25 to 800.
2020-06-13 09:37:27 +02:00
});
Benchmark BnB in the worst case where it exhausts
2018-03-06 14:24:15 -05:00
}
bench: explicitly make all current benchmarks "high" priority no-functional changes. Only have set the priority level explicitly on every BENCHMARK macro call.
2022-09-25 12:25:16 -03:00
BENCHMARK(CoinSelection, benchmark::PriorityLevel::HIGH);
BENCHMARK(BnBExhaustion, benchmark::PriorityLevel::HIGH);
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