lbcd/integration/bip0009_test.go

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// Copyright (c) 2016 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
// This file is ignored during the regular tests due to the following build tag.
// +build rpctest
package integration
import (
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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"fmt"
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"runtime"
"testing"
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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"time"
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integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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"github.com/btcsuite/btcd/blockchain"
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"github.com/btcsuite/btcd/chaincfg"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/integration/rpctest"
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)
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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const (
// vbLegacyBlockVersion is the highest legacy block version before the
// version bits scheme became active.
vbLegacyBlockVersion = 4
// vbTopBits defines the bits to set in the version to signal that the
// version bits scheme is being used.
vbTopBits = 0x20000000
)
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// assertVersionBit gets the passed block hash from the given test harness and
// ensures its version either has the provided bit set or unset per the set
// flag.
func assertVersionBit(r *rpctest.Harness, t *testing.T, hash *chainhash.Hash, bit uint8, set bool) {
block, err := r.Node.GetBlock(hash)
if err != nil {
t.Fatalf("failed to retrieve block %v: %v", hash, err)
}
switch {
case set && block.Header.Version&(1<<bit) == 0:
_, _, line, _ := runtime.Caller(1)
t.Fatalf("assertion failed at line %d: block %s, version 0x%x "+
"does not have bit %d set", line, hash,
block.Header.Version, bit)
case !set && block.Header.Version&(1<<bit) != 0:
_, _, line, _ := runtime.Caller(1)
t.Fatalf("assertion failed at line %d: block %s, version 0x%x "+
"has bit %d set", line, hash, block.Header.Version, bit)
}
}
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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// assertChainHeight retrieves the current chain height from the given test
// harness and ensures it matches the provided expected height.
func assertChainHeight(r *rpctest.Harness, t *testing.T, expectedHeight uint32) {
height, err := r.Node.GetBlockCount()
if err != nil {
t.Fatalf("failed to retrieve block height: %v", err)
}
if uint32(height) != expectedHeight {
_, _, line, _ := runtime.Caller(1)
t.Fatalf("assertion failed at line %d: block height of %d "+
"is not the expected %d", line, height, expectedHeight)
}
}
// thresholdStateToStatus converts the passed threshold state to the equivalent
// status string returned in the getblockchaininfo RPC.
func thresholdStateToStatus(state blockchain.ThresholdState) (string, error) {
switch state {
case blockchain.ThresholdDefined:
return "defined", nil
case blockchain.ThresholdStarted:
return "started", nil
case blockchain.ThresholdLockedIn:
return "lockedin", nil
case blockchain.ThresholdActive:
return "active", nil
case blockchain.ThresholdFailed:
return "failed", nil
}
return "", fmt.Errorf("unrecognized threshold state: %v", state)
}
// assertSoftForkStatus retrieves the current blockchain info from the given
// test harness and ensures the provided soft fork key is both available and its
// status is the equivalent of the passed state.
func assertSoftForkStatus(r *rpctest.Harness, t *testing.T, forkKey string, state blockchain.ThresholdState) {
// Convert the expected threshold state into the equivalent
// getblockchaininfo RPC status string.
status, err := thresholdStateToStatus(state)
if err != nil {
_, _, line, _ := runtime.Caller(1)
t.Fatalf("assertion failed at line %d: unable to convert "+
"threshold state %v to string", line, state)
}
info, err := r.Node.GetBlockChainInfo()
if err != nil {
t.Fatalf("failed to retrieve chain info: %v", err)
}
// Ensure the key is available.
desc, ok := info.Bip9SoftForks[forkKey]
if !ok {
_, _, line, _ := runtime.Caller(1)
t.Fatalf("assertion failed at line %d: softfork status for %q "+
"is not in getblockchaininfo results", line, forkKey)
}
// Ensure the status it the expected value.
if desc.Status != status {
_, _, line, _ := runtime.Caller(1)
t.Fatalf("assertion failed at line %d: softfork status for %q "+
"is %v instead of expected %v", line, forkKey,
desc.Status, status)
}
}
// testBIP0009 ensures the BIP0009 soft fork mechanism follows the state
// transition rules set forth by the BIP for the provided soft fork key. It
// uses the regression test network to signal support and advance through the
// various threshold states including failure to achieve locked in status.
//
// See TestBIP0009 for an overview of what is tested.
//
// NOTE: This only differs from the exported version in that it accepts the
// specific soft fork deployment to test.
func testBIP0009(t *testing.T, forkKey string, deploymentID uint32) {
// Initialize the primary mining node with only the genesis block.
r, err := rpctest.New(&chaincfg.RegressionNetParams, nil, nil)
if err != nil {
t.Fatalf("unable to create primary harness: %v", err)
}
if err := r.SetUp(false, 0); err != nil {
t.Fatalf("unable to setup test chain: %v", err)
}
defer r.TearDown()
// *** ThresholdDefined ***
//
// Assert the chain height is the expected value and the soft fork
// status starts out as defined.
assertChainHeight(r, t, 0)
assertSoftForkStatus(r, t, forkKey, blockchain.ThresholdDefined)
// *** ThresholdDefined part 2 - 1 block prior to ThresholdStarted ***
//
// Generate enough blocks to reach the height just before the first
// state transition without signalling support since the state should
// move to started once the start time has been reached regardless of
// support signalling.
//
// NOTE: This is two blocks before the confirmation window because the
// getblockchaininfo RPC reports the status for the block AFTER the
// current one. All of the heights below are thus offset by one to
// compensate.
//
// Assert the chain height is the expected value and soft fork status is
// still defined and did NOT move to started.
confirmationWindow := r.ActiveNet.MinerConfirmationWindow
for i := uint32(0); i < confirmationWindow-2; i++ {
_, err := r.GenerateAndSubmitBlock(nil, vbLegacyBlockVersion,
time.Time{})
if err != nil {
t.Fatalf("failed to generated block %d: %v", i, err)
}
}
assertChainHeight(r, t, confirmationWindow-2)
assertSoftForkStatus(r, t, forkKey, blockchain.ThresholdDefined)
// *** ThresholdStarted ***
//
// Generate another block to reach the next window.
//
// Assert the chain height is the expected value and the soft fork
// status is started.
_, err = r.GenerateAndSubmitBlock(nil, vbLegacyBlockVersion, time.Time{})
if err != nil {
t.Fatalf("failed to generated block: %v", err)
}
assertChainHeight(r, t, confirmationWindow-1)
assertSoftForkStatus(r, t, forkKey, blockchain.ThresholdStarted)
// *** ThresholdStarted part 2 - Fail to achieve ThresholdLockedIn ***
//
// Generate enough blocks to reach the next window in such a way that
// the number blocks with the version bit set to signal support is 1
// less than required to achieve locked in status.
//
// Assert the chain height is the expected value and the soft fork
// status is still started and did NOT move to locked in.
if deploymentID > uint32(len(r.ActiveNet.Deployments)) {
t.Fatalf("deployment ID %d does not exist", deploymentID)
}
deployment := &r.ActiveNet.Deployments[deploymentID]
activationThreshold := r.ActiveNet.RuleChangeActivationThreshold
signalForkVersion := int32(1<<deployment.BitNumber) | vbTopBits
for i := uint32(0); i < activationThreshold-1; i++ {
_, err := r.GenerateAndSubmitBlock(nil, signalForkVersion,
time.Time{})
if err != nil {
t.Fatalf("failed to generated block %d: %v", i, err)
}
}
for i := uint32(0); i < confirmationWindow-(activationThreshold-1); i++ {
_, err := r.GenerateAndSubmitBlock(nil, vbLegacyBlockVersion,
time.Time{})
if err != nil {
t.Fatalf("failed to generated block %d: %v", i, err)
}
}
assertChainHeight(r, t, (confirmationWindow*2)-1)
assertSoftForkStatus(r, t, forkKey, blockchain.ThresholdStarted)
// *** ThresholdLockedIn ***
//
// Generate enough blocks to reach the next window in such a way that
// the number blocks with the version bit set to signal support is
// exactly the number required to achieve locked in status.
//
// Assert the chain height is the expected value and the soft fork
// status moved to locked in.
for i := uint32(0); i < activationThreshold; i++ {
_, err := r.GenerateAndSubmitBlock(nil, signalForkVersion,
time.Time{})
if err != nil {
t.Fatalf("failed to generated block %d: %v", i, err)
}
}
for i := uint32(0); i < confirmationWindow-activationThreshold; i++ {
_, err := r.GenerateAndSubmitBlock(nil, vbLegacyBlockVersion,
time.Time{})
if err != nil {
t.Fatalf("failed to generated block %d: %v", i, err)
}
}
assertChainHeight(r, t, (confirmationWindow*3)-1)
assertSoftForkStatus(r, t, forkKey, blockchain.ThresholdLockedIn)
// *** ThresholdLockedIn part 2 -- 1 block prior to ThresholdActive ***
//
// Generate enough blocks to reach the height just before the next
// window without continuing to signal support since it is already
// locked in.
//
// Assert the chain height is the expected value and the soft fork
// status is still locked in and did NOT move to active.
for i := uint32(0); i < confirmationWindow-1; i++ {
_, err := r.GenerateAndSubmitBlock(nil, vbLegacyBlockVersion,
time.Time{})
if err != nil {
t.Fatalf("failed to generated block %d: %v", i, err)
}
}
assertChainHeight(r, t, (confirmationWindow*4)-2)
assertSoftForkStatus(r, t, forkKey, blockchain.ThresholdLockedIn)
// *** ThresholdActive ***
//
// Generate another block to reach the next window without continuing to
// signal support since it is already locked in.
//
// Assert the chain height is the expected value and the soft fork
// status moved to active.
_, err = r.GenerateAndSubmitBlock(nil, vbLegacyBlockVersion, time.Time{})
if err != nil {
t.Fatalf("failed to generated block: %v", err)
}
assertChainHeight(r, t, (confirmationWindow*4)-1)
assertSoftForkStatus(r, t, forkKey, blockchain.ThresholdActive)
}
// TestBIP0009 ensures the BIP0009 soft fork mechanism follows the state
// transition rules set forth by the BIP for all soft forks. It uses the
// regression test network to signal support and advance through the various
// threshold states including failure to achieve locked in status.
//
// Overview:
// - Assert the chain height is 0 and the state is ThresholdDefined
// - Generate 1 fewer blocks than needed to reach the first state transition
// - Assert chain height is expected and state is still ThresholdDefined
// - Generate 1 more block to reach the first state transition
// - Assert chain height is expected and state moved to ThresholdStarted
// - Generate enough blocks to reach the next state transition window, but only
// signal support in 1 fewer than the required number to achieve
// ThresholdLockedIn
// - Assert chain height is expected and state is still ThresholdStarted
// - Generate enough blocks to reach the next state transition window with only
// the exact number of blocks required to achieve locked in status signalling
// support.
// - Assert chain height is expected and state moved to ThresholdLockedIn
// - Generate 1 fewer blocks than needed to reach the next state transition
// - Assert chain height is expected and state is still ThresholdLockedIn
// - Generate 1 more block to reach the next state transition
// - Assert chain height is expected and state moved to ThresholdActive
func TestBIP0009(t *testing.T) {
t.Parallel()
testBIP0009(t, "dummy", chaincfg.DeploymentTestDummy)
}
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// TestBIP0009Mining ensures blocks built via btcd's CPU miner follow the rules
// set forth by BIP0009 by using the test dummy deployment.
//
// Overview:
// - Generate block 1
// - Assert bit is NOT set (ThresholdDefined)
// - Generate enough blocks to reach first state transition
// - Assert bit is NOT set for block prior to state transition
// - Assert bit is set for block at state transition (ThresholdStarted)
// - Generate enough blocks to reach second state transition
// - Assert bit is set for block at state transition (ThresholdLockedIn)
// - Generate enough blocks to reach third state transition
// - Assert bit is set for block prior to state transition (ThresholdLockedIn)
// - Assert bit is NOT set for block at state transition (ThresholdActive)
func TestBIP0009Mining(t *testing.T) {
t.Parallel()
// Initialize the primary mining node with only the genesis block.
r, err := rpctest.New(&chaincfg.SimNetParams, nil, nil)
if err != nil {
t.Fatalf("unable to create primary harness: %v", err)
}
if err := r.SetUp(true, 0); err != nil {
t.Fatalf("unable to setup test chain: %v", err)
}
defer r.TearDown()
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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// Assert the chain only consists of the gensis block.
assertChainHeight(r, t, 0)
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// *** ThresholdDefined ***
//
// Generate a block that extends the genesis block. It should not have
// the test dummy bit set in the version since the first window is
// in the defined threshold state.
deployment := &r.ActiveNet.Deployments[chaincfg.DeploymentTestDummy]
testDummyBitNum := deployment.BitNumber
hashes, err := r.Node.Generate(1)
if err != nil {
t.Fatalf("unable to generate blocks: %v", err)
}
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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assertChainHeight(r, t, 1)
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assertVersionBit(r, t, hashes[0], testDummyBitNum, false)
// *** ThresholdStarted ***
//
// Generate enough blocks to reach the first state transition.
//
// The second to last generated block should not have the test bit set
// in the version.
//
// The last generated block should now have the test bit set in the
// version since the btcd mining code will have recognized the test
// dummy deployment as started.
confirmationWindow := r.ActiveNet.MinerConfirmationWindow
numNeeded := confirmationWindow - 1
hashes, err = r.Node.Generate(numNeeded)
if err != nil {
t.Fatalf("failed to generated %d blocks: %v", numNeeded, err)
}
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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assertChainHeight(r, t, confirmationWindow)
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assertVersionBit(r, t, hashes[len(hashes)-2], testDummyBitNum, false)
assertVersionBit(r, t, hashes[len(hashes)-1], testDummyBitNum, true)
// *** ThresholdLockedIn ***
//
// Generate enough blocks to reach the next state transition.
//
// The last generated block should still have the test bit set in the
// version since the btcd mining code will have recognized the test
// dummy deployment as locked in.
hashes, err = r.Node.Generate(confirmationWindow)
if err != nil {
t.Fatalf("failed to generated %d blocks: %v", confirmationWindow,
err)
}
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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assertChainHeight(r, t, confirmationWindow*2)
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assertVersionBit(r, t, hashes[len(hashes)-1], testDummyBitNum, true)
// *** ThresholdActivated ***
//
// Generate enough blocks to reach the next state transition.
//
// The second to last generated block should still have the test bit set
// in the version since it is still locked in.
//
// The last generated block should NOT have the test bit set in the
// version since the btcd mining code will have recognized the test
// dummy deployment as activated and thus there is no longer any need
// to set the bit.
hashes, err = r.Node.Generate(confirmationWindow)
if err != nil {
t.Fatalf("failed to generated %d blocks: %v", confirmationWindow,
err)
}
integration: Add BIP0009 state transition tests This adds tests which exercise the BIP0009 state transitions using the newly available soft fork status information in the getblockchaininfo RPC. The following is an overview of the tests added: - Assert the chain height is 0 and the state is ThresholdDefined - Generate 1 fewer blocks than needed to reach the first state transition - Assert chain height is expected and state is still ThresholdDefined - Generate 1 more block to reach the first state transition - Assert chain height is expected and state moved to ThresholdStarted - Generate enough blocks to reach the next state transition window, but only signal support in 1 fewer than the required number to achieve ThresholdLockedIn - Assert chain height is expected and state is still ThresholdStarted - Generate enough blocks to reach the next state transition window with only the exact number of blocks required to achieve locked in status signalling support - Assert chain height is expected and state moved to ThresholdLockedIn - Generate 1 fewer blocks than needed to reach the next state transition - Assert chain height is expected and state is still ThresholdLockedIn - Generate 1 more block to reach the next state transition - Assert chain height is expected and state moved to ThresholdActive In addition, it updates the existing BIP0009 mining tests to include extra assertions that the chain height is at the expected height in addition to checking that the bits are correctly set according to the expected state.
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assertChainHeight(r, t, confirmationWindow*3)
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assertVersionBit(r, t, hashes[len(hashes)-2], testDummyBitNum, true)
assertVersionBit(r, t, hashes[len(hashes)-1], testDummyBitNum, false)
}