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// Copyright (c) 2014-2015 The Bitcoin Core developers
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// Distributed under the MIT software license, see the accompanying
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// file COPYING or http://www.opensource.org/licenses/mit-license.php.
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#include "chain.h"
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#include "random.h"
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#include "versionbits.h"
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#include "test/test_bitcoin.h"
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#include "chainparams.h"
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#include "main.h"
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#include "consensus/params.h"
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#include <boost/test/unit_test.hpp>
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/* Define a virtual block time, one block per 10 minutes after Nov 14 2014, 0:55:36am */
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int32_t TestTime(int nHeight) { return 1415926536 + 600 * nHeight; }
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static const Consensus::Params paramsDummy = Consensus::Params();
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class TestConditionChecker : public AbstractThresholdConditionChecker
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{
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private:
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mutable ThresholdConditionCache cache;
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public:
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int64_t BeginTime(const Consensus::Params& params) const { return TestTime(10000); }
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int64_t EndTime(const Consensus::Params& params) const { return TestTime(20000); }
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int Period(const Consensus::Params& params) const { return 1000; }
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int Threshold(const Consensus::Params& params) const { return 900; }
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bool Condition(const CBlockIndex* pindex, const Consensus::Params& params) const { return (pindex->nVersion & 0x100); }
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ThresholdState GetStateFor(const CBlockIndex* pindexPrev) const { return AbstractThresholdConditionChecker::GetStateFor(pindexPrev, paramsDummy, cache); }
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};
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#define CHECKERS 6
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class VersionBitsTester
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{
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// A fake blockchain
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std::vector<CBlockIndex*> vpblock;
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// 6 independent checkers for the same bit.
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// The first one performs all checks, the second only 50%, the third only 25%, etc...
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// This is to test whether lack of cached information leads to the same results.
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TestConditionChecker checker[CHECKERS];
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// Test counter (to identify failures)
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int num;
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public:
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VersionBitsTester() : num(0) {}
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VersionBitsTester& Reset() {
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for (unsigned int i = 0; i < vpblock.size(); i++) {
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delete vpblock[i];
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}
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for (unsigned int i = 0; i < CHECKERS; i++) {
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checker[i] = TestConditionChecker();
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}
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vpblock.clear();
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return *this;
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}
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~VersionBitsTester() {
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Reset();
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}
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VersionBitsTester& Mine(unsigned int height, int32_t nTime, int32_t nVersion) {
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while (vpblock.size() < height) {
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CBlockIndex* pindex = new CBlockIndex();
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pindex->nHeight = vpblock.size();
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pindex->pprev = vpblock.size() > 0 ? vpblock.back() : NULL;
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pindex->nTime = nTime;
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pindex->nVersion = nVersion;
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pindex->BuildSkip();
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vpblock.push_back(pindex);
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}
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return *this;
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}
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VersionBitsTester& TestDefined() {
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for (int i = 0; i < CHECKERS; i++) {
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if ((insecure_rand() & ((1 << i) - 1)) == 0) {
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BOOST_CHECK_MESSAGE(checker[i].GetStateFor(vpblock.empty() ? NULL : vpblock.back()) == THRESHOLD_DEFINED, strprintf("Test %i for DEFINED", num));
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}
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}
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num++;
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return *this;
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}
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VersionBitsTester& TestStarted() {
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for (int i = 0; i < CHECKERS; i++) {
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if ((insecure_rand() & ((1 << i) - 1)) == 0) {
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BOOST_CHECK_MESSAGE(checker[i].GetStateFor(vpblock.empty() ? NULL : vpblock.back()) == THRESHOLD_STARTED, strprintf("Test %i for STARTED", num));
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}
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}
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num++;
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return *this;
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}
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VersionBitsTester& TestLockedIn() {
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for (int i = 0; i < CHECKERS; i++) {
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if ((insecure_rand() & ((1 << i) - 1)) == 0) {
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BOOST_CHECK_MESSAGE(checker[i].GetStateFor(vpblock.empty() ? NULL : vpblock.back()) == THRESHOLD_LOCKED_IN, strprintf("Test %i for LOCKED_IN", num));
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}
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}
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num++;
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return *this;
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}
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VersionBitsTester& TestActive() {
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for (int i = 0; i < CHECKERS; i++) {
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if ((insecure_rand() & ((1 << i) - 1)) == 0) {
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BOOST_CHECK_MESSAGE(checker[i].GetStateFor(vpblock.empty() ? NULL : vpblock.back()) == THRESHOLD_ACTIVE, strprintf("Test %i for ACTIVE", num));
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}
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}
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num++;
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return *this;
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}
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VersionBitsTester& TestFailed() {
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for (int i = 0; i < CHECKERS; i++) {
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if ((insecure_rand() & ((1 << i) - 1)) == 0) {
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BOOST_CHECK_MESSAGE(checker[i].GetStateFor(vpblock.empty() ? NULL : vpblock.back()) == THRESHOLD_FAILED, strprintf("Test %i for FAILED", num));
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}
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}
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num++;
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return *this;
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}
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CBlockIndex * Tip() { return vpblock.size() ? vpblock.back() : NULL; }
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};
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BOOST_FIXTURE_TEST_SUITE(versionbits_tests, TestingSetup)
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BOOST_AUTO_TEST_CASE(versionbits_test)
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{
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for (int i = 0; i < 64; i++) {
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// DEFINED -> FAILED
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VersionBitsTester().TestDefined()
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.Mine(1, TestTime(1), 0x100).TestDefined()
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.Mine(11, TestTime(11), 0x100).TestDefined()
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.Mine(989, TestTime(989), 0x100).TestDefined()
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.Mine(999, TestTime(20000), 0x100).TestDefined()
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.Mine(1000, TestTime(20000), 0x100).TestFailed()
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.Mine(1999, TestTime(30001), 0x100).TestFailed()
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.Mine(2000, TestTime(30002), 0x100).TestFailed()
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.Mine(2001, TestTime(30003), 0x100).TestFailed()
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.Mine(2999, TestTime(30004), 0x100).TestFailed()
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.Mine(3000, TestTime(30005), 0x100).TestFailed()
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// DEFINED -> STARTED -> FAILED
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.Reset().TestDefined()
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.Mine(1, TestTime(1), 0).TestDefined()
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.Mine(1000, TestTime(10000) - 1, 0x100).TestDefined() // One second more and it would be defined
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.Mine(2000, TestTime(10000), 0x100).TestStarted() // So that's what happens the next period
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.Mine(2051, TestTime(10010), 0).TestStarted() // 51 old blocks
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.Mine(2950, TestTime(10020), 0x100).TestStarted() // 899 new blocks
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.Mine(3000, TestTime(20000), 0).TestFailed() // 50 old blocks (so 899 out of the past 1000)
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.Mine(4000, TestTime(20010), 0x100).TestFailed()
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// DEFINED -> STARTED -> FAILED while threshold reached
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.Reset().TestDefined()
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.Mine(1, TestTime(1), 0).TestDefined()
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.Mine(1000, TestTime(10000) - 1, 0x101).TestDefined() // One second more and it would be defined
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.Mine(2000, TestTime(10000), 0x101).TestStarted() // So that's what happens the next period
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.Mine(2999, TestTime(30000), 0x100).TestStarted() // 999 new blocks
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.Mine(3000, TestTime(30000), 0x100).TestFailed() // 1 new block (so 1000 out of the past 1000 are new)
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.Mine(3999, TestTime(30001), 0).TestFailed()
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.Mine(4000, TestTime(30002), 0).TestFailed()
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.Mine(14333, TestTime(30003), 0).TestFailed()
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.Mine(24000, TestTime(40000), 0).TestFailed()
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// DEFINED -> STARTED -> LOCKEDIN at the last minute -> ACTIVE
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.Reset().TestDefined()
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.Mine(1, TestTime(1), 0).TestDefined()
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.Mine(1000, TestTime(10000) - 1, 0x101).TestDefined() // One second more and it would be defined
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.Mine(2000, TestTime(10000), 0x101).TestStarted() // So that's what happens the next period
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.Mine(2050, TestTime(10010), 0x200).TestStarted() // 50 old blocks
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.Mine(2950, TestTime(10020), 0x100).TestStarted() // 900 new blocks
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.Mine(2999, TestTime(19999), 0x200).TestStarted() // 49 old blocks
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.Mine(3000, TestTime(29999), 0x200).TestLockedIn() // 1 old block (so 900 out of the past 1000)
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.Mine(3999, TestTime(30001), 0).TestLockedIn()
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.Mine(4000, TestTime(30002), 0).TestActive()
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.Mine(14333, TestTime(30003), 0).TestActive()
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.Mine(24000, TestTime(40000), 0).TestActive();
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}
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}
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BOOST_AUTO_TEST_CASE(versionbits_computeblockversion)
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{
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// Check that ComputeBlockVersion will set the appropriate bit correctly
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// on mainnet.
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const Consensus::Params &mainnetParams = Params(CBaseChainParams::MAIN).GetConsensus();
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// Use the TESTDUMMY deployment for testing purposes.
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int64_t bit = mainnetParams.vDeployments[Consensus::DEPLOYMENT_TESTDUMMY].bit;
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int64_t nStartTime = mainnetParams.vDeployments[Consensus::DEPLOYMENT_TESTDUMMY].nStartTime;
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int64_t nTimeout = mainnetParams.vDeployments[Consensus::DEPLOYMENT_TESTDUMMY].nTimeout;
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assert(nStartTime < nTimeout);
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// In the first chain, test that the bit is set by CBV until it has failed.
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// In the second chain, test the bit is set by CBV while STARTED and
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// LOCKED-IN, and then no longer set while ACTIVE.
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VersionBitsTester firstChain, secondChain;
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// Start generating blocks before nStartTime
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int64_t nTime = nStartTime - 1;
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// Before MedianTimePast of the chain has crossed nStartTime, the bit
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// should not be set.
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CBlockIndex *lastBlock = NULL;
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lastBlock = firstChain.Mine(2016, nTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit), 0);
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// Mine 2011 more blocks at the old time, and check that CBV isn't setting the bit yet.
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for (int i=1; i<2012; i++) {
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lastBlock = firstChain.Mine(2016+i, nTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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// This works because VERSIONBITS_LAST_OLD_BLOCK_VERSION happens
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// to be 4, and the bit we're testing happens to be bit 28.
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BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit), 0);
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}
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// Now mine 5 more blocks at the start time -- MTP should not have passed yet, so
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// CBV should still not yet set the bit.
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nTime = nStartTime;
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for (int i=2012; i<=2016; i++) {
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lastBlock = firstChain.Mine(2016+i, nTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit), 0);
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}
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// Advance to the next period and transition to STARTED,
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lastBlock = firstChain.Mine(6048, nTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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// so ComputeBlockVersion should now set the bit,
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BOOST_CHECK((ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit)) != 0);
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// and should also be using the VERSIONBITS_TOP_BITS.
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BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & VERSIONBITS_TOP_MASK, VERSIONBITS_TOP_BITS);
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// Check that ComputeBlockVersion will set the bit until nTimeout
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nTime += 600;
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int blocksToMine = 4032; // test blocks for up to 2 time periods
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int nHeight = 6048;
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// These blocks are all before nTimeout is reached.
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while (nTime < nTimeout && blocksToMine > 0) {
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lastBlock = firstChain.Mine(nHeight+1, nTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK((ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit)) != 0);
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BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & VERSIONBITS_TOP_MASK, VERSIONBITS_TOP_BITS);
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blocksToMine--;
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nTime += 600;
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nHeight += 1;
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};
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nTime = nTimeout;
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// FAILED is only triggered at the end of a period, so CBV should be setting
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// the bit until the period transition.
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for (int i=0; i<2015; i++) {
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lastBlock = firstChain.Mine(nHeight+1, nTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK((ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit)) != 0);
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nHeight += 1;
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}
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// The next block should trigger no longer setting the bit.
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lastBlock = firstChain.Mine(nHeight+1, nTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit), 0);
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// On a new chain:
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// verify that the bit will be set after lock-in, and then stop being set
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// after activation.
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nTime = nStartTime;
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// Mine one period worth of blocks, and check that the bit will be on for the
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// next period.
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lastBlock = secondChain.Mine(2016, nStartTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK((ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit)) != 0);
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// Mine another period worth of blocks, signaling the new bit.
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lastBlock = secondChain.Mine(4032, nStartTime, VERSIONBITS_TOP_BITS | (1<<bit)).Tip();
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// After one period of setting the bit on each block, it should have locked in.
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// We keep setting the bit for one more period though, until activation.
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BOOST_CHECK((ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit)) != 0);
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// Now check that we keep mining the block until the end of this period, and
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// then stop at the beginning of the next period.
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lastBlock = secondChain.Mine(6047, nStartTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK((ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit)) != 0);
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lastBlock = secondChain.Mine(6048, nStartTime, VERSIONBITS_LAST_OLD_BLOCK_VERSION).Tip();
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BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & (1<<bit), 0);
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// Finally, verify that after a soft fork has activated, CBV no longer uses
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// VERSIONBITS_LAST_OLD_BLOCK_VERSION.
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//BOOST_CHECK_EQUAL(ComputeBlockVersion(lastBlock, mainnetParams) & VERSIONBITS_TOP_MASK, VERSIONBITS_TOP_BITS);
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}
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BOOST_AUTO_TEST_SUITE_END()
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