lotus/itests/kit/ensemble.go
zenground0 33f2d24f54 Snap Deals Integration
- FSM handles the actual cc upgrade process including error states
- PoSting (winning and window) works over upgraded and upgrading sectors
- Integration test and changes to itest framework to reduce flakes
- Update CLI to handle new upgrade
- Update dependencies
2022-01-10 15:39:38 +05:30

773 lines
23 KiB
Go

package kit
import (
"bytes"
"context"
"crypto/rand"
"fmt"
"io/ioutil"
"net"
"sync"
"testing"
"time"
"github.com/filecoin-project/go-address"
"github.com/filecoin-project/go-state-types/abi"
"github.com/filecoin-project/go-state-types/big"
"github.com/filecoin-project/go-state-types/exitcode"
"github.com/filecoin-project/go-state-types/network"
"github.com/filecoin-project/go-storedcounter"
"github.com/filecoin-project/lotus/api"
"github.com/filecoin-project/lotus/api/v1api"
"github.com/filecoin-project/lotus/build"
"github.com/filecoin-project/lotus/chain"
"github.com/filecoin-project/lotus/chain/actors"
"github.com/filecoin-project/lotus/chain/actors/builtin/miner"
"github.com/filecoin-project/lotus/chain/actors/builtin/power"
"github.com/filecoin-project/lotus/chain/gen"
genesis2 "github.com/filecoin-project/lotus/chain/gen/genesis"
"github.com/filecoin-project/lotus/chain/messagepool"
"github.com/filecoin-project/lotus/chain/stmgr"
"github.com/filecoin-project/lotus/chain/types"
"github.com/filecoin-project/lotus/chain/wallet"
"github.com/filecoin-project/lotus/cmd/lotus-seed/seed"
sectorstorage "github.com/filecoin-project/lotus/extern/sector-storage"
"github.com/filecoin-project/lotus/extern/sector-storage/ffiwrapper"
"github.com/filecoin-project/lotus/extern/sector-storage/mock"
"github.com/filecoin-project/lotus/genesis"
lotusminer "github.com/filecoin-project/lotus/miner"
"github.com/filecoin-project/lotus/node"
"github.com/filecoin-project/lotus/node/config"
"github.com/filecoin-project/lotus/node/modules"
"github.com/filecoin-project/lotus/node/modules/dtypes"
testing2 "github.com/filecoin-project/lotus/node/modules/testing"
"github.com/filecoin-project/lotus/node/repo"
"github.com/filecoin-project/lotus/storage/mockstorage"
miner2 "github.com/filecoin-project/specs-actors/v2/actors/builtin/miner"
power2 "github.com/filecoin-project/specs-actors/v2/actors/builtin/power"
"github.com/ipfs/go-datastore"
libp2pcrypto "github.com/libp2p/go-libp2p-core/crypto"
"github.com/libp2p/go-libp2p-core/peer"
mocknet "github.com/libp2p/go-libp2p/p2p/net/mock"
"github.com/stretchr/testify/require"
)
func init() {
chain.BootstrapPeerThreshold = 1
messagepool.HeadChangeCoalesceMinDelay = time.Microsecond
messagepool.HeadChangeCoalesceMaxDelay = 2 * time.Microsecond
messagepool.HeadChangeCoalesceMergeInterval = 100 * time.Nanosecond
}
// Ensemble is a collection of nodes instantiated within a test.
//
// Create a new ensemble with:
//
// ens := kit.NewEnsemble()
//
// Create full nodes and miners:
//
// var full TestFullNode
// var miner TestMiner
// ens.FullNode(&full, opts...) // populates a full node
// ens.Miner(&miner, &full, opts...) // populates a miner, using the full node as its chain daemon
//
// It is possible to pass functional options to set initial balances,
// presealed sectors, owner keys, etc.
//
// After the initial nodes are added, call `ens.Start()` to forge genesis
// and start the network. Mining will NOT be started automatically. It needs
// to be started explicitly by calling `BeginMining`.
//
// Nodes also need to be connected with one another, either via `ens.Connect()`
// or `ens.InterconnectAll()`. A common inchantation for simple tests is to do:
//
// ens.InterconnectAll().BeginMining(blocktime)
//
// You can continue to add more nodes, but you must always follow with
// `ens.Start()` to activate the new nodes.
//
// The API is chainable, so it's possible to do a lot in a very succinct way:
//
// kit.NewEnsemble().FullNode(&full).Miner(&miner, &full).Start().InterconnectAll().BeginMining()
//
// You can also find convenient fullnode:miner presets, such as 1:1, 1:2,
// and 2:1, e.g.:
//
// kit.EnsembleMinimal()
// kit.EnsembleOneTwo()
// kit.EnsembleTwoOne()
//
type Ensemble struct {
t *testing.T
bootstrapped bool
genesisBlock bytes.Buffer
mn mocknet.Mocknet
options *ensembleOpts
inactive struct {
fullnodes []*TestFullNode
miners []*TestMiner
}
active struct {
fullnodes []*TestFullNode
miners []*TestMiner
bms map[*TestMiner]*BlockMiner
}
genesis struct {
version network.Version
miners []genesis.Miner
accounts []genesis.Actor
}
}
// NewEnsemble instantiates a new blank Ensemble.
func NewEnsemble(t *testing.T, opts ...EnsembleOpt) *Ensemble {
options := DefaultEnsembleOpts
for _, o := range opts {
err := o(&options)
require.NoError(t, err)
}
n := &Ensemble{t: t, options: &options}
n.active.bms = make(map[*TestMiner]*BlockMiner)
for _, up := range options.upgradeSchedule {
if up.Height < 0 {
n.genesis.version = up.Network
}
}
// add accounts from ensemble options to genesis.
for _, acc := range options.accounts {
n.genesis.accounts = append(n.genesis.accounts, genesis.Actor{
Type: genesis.TAccount,
Balance: acc.initialBalance,
Meta: (&genesis.AccountMeta{Owner: acc.key.Address}).ActorMeta(),
})
}
return n
}
// FullNode enrolls a new full node.
func (n *Ensemble) FullNode(full *TestFullNode, opts ...NodeOpt) *Ensemble {
options := DefaultNodeOpts
for _, o := range opts {
err := o(&options)
require.NoError(n.t, err)
}
key, err := wallet.GenerateKey(types.KTBLS)
require.NoError(n.t, err)
if !n.bootstrapped && !options.balance.IsZero() {
// if we still haven't forged genesis, create a key+address, and assign
// it some FIL; this will be set as the default wallet when the node is
// started.
genacc := genesis.Actor{
Type: genesis.TAccount,
Balance: options.balance,
Meta: (&genesis.AccountMeta{Owner: key.Address}).ActorMeta(),
}
n.genesis.accounts = append(n.genesis.accounts, genacc)
}
*full = TestFullNode{t: n.t, options: options, DefaultKey: key}
n.inactive.fullnodes = append(n.inactive.fullnodes, full)
return n
}
// Miner enrolls a new miner, using the provided full node for chain
// interactions.
func (n *Ensemble) Miner(minerNode *TestMiner, full *TestFullNode, opts ...NodeOpt) *Ensemble {
require.NotNil(n.t, full, "full node required when instantiating miner")
options := DefaultNodeOpts
for _, o := range opts {
err := o(&options)
require.NoError(n.t, err)
}
privkey, _, err := libp2pcrypto.GenerateEd25519Key(rand.Reader)
require.NoError(n.t, err)
peerId, err := peer.IDFromPrivateKey(privkey)
require.NoError(n.t, err)
tdir, err := ioutil.TempDir("", "preseal-memgen")
require.NoError(n.t, err)
minerCnt := len(n.inactive.miners) + len(n.active.miners)
actorAddr, err := address.NewIDAddress(genesis2.MinerStart + uint64(minerCnt))
require.NoError(n.t, err)
if options.mainMiner != nil {
actorAddr = options.mainMiner.ActorAddr
}
ownerKey := options.ownerKey
if !n.bootstrapped {
var (
sectors = options.sectors
k *types.KeyInfo
genm *genesis.Miner
)
// Will use 2KiB sectors by default (default value of sectorSize).
proofType, err := miner.SealProofTypeFromSectorSize(options.sectorSize, n.genesis.version)
require.NoError(n.t, err)
// Create the preseal commitment.
if n.options.mockProofs {
genm, k, err = mockstorage.PreSeal(proofType, actorAddr, sectors)
} else {
genm, k, err = seed.PreSeal(actorAddr, proofType, 0, sectors, tdir, []byte("make genesis mem random"), nil, true)
}
require.NoError(n.t, err)
genm.PeerId = peerId
// create an owner key, and assign it some FIL.
ownerKey, err = wallet.NewKey(*k)
require.NoError(n.t, err)
genacc := genesis.Actor{
Type: genesis.TAccount,
Balance: options.balance,
Meta: (&genesis.AccountMeta{Owner: ownerKey.Address}).ActorMeta(),
}
n.genesis.miners = append(n.genesis.miners, *genm)
n.genesis.accounts = append(n.genesis.accounts, genacc)
} else {
require.NotNil(n.t, ownerKey, "worker key can't be null if initializing a miner after genesis")
}
rl, err := net.Listen("tcp", "127.0.0.1:")
require.NoError(n.t, err)
*minerNode = TestMiner{
t: n.t,
ActorAddr: actorAddr,
OwnerKey: ownerKey,
FullNode: full,
PresealDir: tdir,
options: options,
RemoteListener: rl,
}
minerNode.Libp2p.PeerID = peerId
minerNode.Libp2p.PrivKey = privkey
n.inactive.miners = append(n.inactive.miners, minerNode)
return n
}
// Start starts all enrolled nodes.
func (n *Ensemble) Start() *Ensemble {
ctx := context.Background()
var gtempl *genesis.Template
if !n.bootstrapped {
// We haven't been bootstrapped yet, we need to generate genesis and
// create the networking backbone.
gtempl = n.generateGenesis()
n.mn = mocknet.New(ctx)
}
// ---------------------
// FULL NODES
// ---------------------
// Create all inactive full nodes.
for i, full := range n.inactive.fullnodes {
r := repo.NewMemory(nil)
opts := []node.Option{
node.FullAPI(&full.FullNode, node.Lite(full.options.lite)),
node.Base(),
node.Repo(r),
node.MockHost(n.mn),
node.Test(),
// so that we subscribe to pubsub topics immediately
node.Override(new(dtypes.Bootstrapper), dtypes.Bootstrapper(true)),
// upgrades
node.Override(new(stmgr.UpgradeSchedule), n.options.upgradeSchedule),
}
// append any node builder options.
opts = append(opts, full.options.extraNodeOpts...)
// Either generate the genesis or inject it.
if i == 0 && !n.bootstrapped {
opts = append(opts, node.Override(new(modules.Genesis), testing2.MakeGenesisMem(&n.genesisBlock, *gtempl)))
} else {
opts = append(opts, node.Override(new(modules.Genesis), modules.LoadGenesis(n.genesisBlock.Bytes())))
}
// Are we mocking proofs?
if n.options.mockProofs {
opts = append(opts,
node.Override(new(ffiwrapper.Verifier), mock.MockVerifier),
node.Override(new(ffiwrapper.Prover), mock.MockProver),
)
}
// Call option builders, passing active nodes as the parameter
for _, bopt := range full.options.optBuilders {
opts = append(opts, bopt(n.active.fullnodes))
}
// Construct the full node.
stop, err := node.New(ctx, opts...)
require.NoError(n.t, err)
addr, err := full.WalletImport(context.Background(), &full.DefaultKey.KeyInfo)
require.NoError(n.t, err)
err = full.WalletSetDefault(context.Background(), addr)
require.NoError(n.t, err)
// Are we hitting this node through its RPC?
if full.options.rpc {
withRPC := fullRpc(n.t, full)
n.inactive.fullnodes[i] = withRPC
}
n.t.Cleanup(func() { _ = stop(context.Background()) })
n.active.fullnodes = append(n.active.fullnodes, full)
}
// If we are here, we have processed all inactive fullnodes and moved them
// to active, so clear the slice.
n.inactive.fullnodes = n.inactive.fullnodes[:0]
// Link all the nodes.
err := n.mn.LinkAll()
require.NoError(n.t, err)
// ---------------------
// MINERS
// ---------------------
// Create all inactive miners.
for i, m := range n.inactive.miners {
if n.bootstrapped {
if m.options.mainMiner == nil {
// this is a miner created after genesis, so it won't have a preseal.
// we need to create it on chain.
// we get the proof type for the requested sector size, for
// the current network version.
nv, err := m.FullNode.FullNode.StateNetworkVersion(ctx, types.EmptyTSK)
require.NoError(n.t, err)
proofType, err := miner.SealProofTypeFromSectorSize(m.options.sectorSize, nv)
require.NoError(n.t, err)
params, aerr := actors.SerializeParams(&power2.CreateMinerParams{
Owner: m.OwnerKey.Address,
Worker: m.OwnerKey.Address,
SealProofType: proofType,
Peer: abi.PeerID(m.Libp2p.PeerID),
})
require.NoError(n.t, aerr)
createStorageMinerMsg := &types.Message{
From: m.OwnerKey.Address,
To: power.Address,
Value: big.Zero(),
Method: power.Methods.CreateMiner,
Params: params,
}
signed, err := m.FullNode.FullNode.MpoolPushMessage(ctx, createStorageMinerMsg, nil)
require.NoError(n.t, err)
mw, err := m.FullNode.FullNode.StateWaitMsg(ctx, signed.Cid(), build.MessageConfidence, api.LookbackNoLimit, true)
require.NoError(n.t, err)
require.Equal(n.t, exitcode.Ok, mw.Receipt.ExitCode)
var retval power2.CreateMinerReturn
err = retval.UnmarshalCBOR(bytes.NewReader(mw.Receipt.Return))
require.NoError(n.t, err, "failed to create miner")
m.ActorAddr = retval.IDAddress
} else {
params, err := actors.SerializeParams(&miner2.ChangePeerIDParams{NewID: abi.PeerID(m.Libp2p.PeerID)})
require.NoError(n.t, err)
msg := &types.Message{
To: m.options.mainMiner.ActorAddr,
From: m.options.mainMiner.OwnerKey.Address,
Method: miner.Methods.ChangePeerID,
Params: params,
Value: types.NewInt(0),
}
signed, err2 := m.FullNode.FullNode.MpoolPushMessage(ctx, msg, nil)
require.NoError(n.t, err2)
mw, err2 := m.FullNode.FullNode.StateWaitMsg(ctx, signed.Cid(), build.MessageConfidence, api.LookbackNoLimit, true)
require.NoError(n.t, err2)
require.Equal(n.t, exitcode.Ok, mw.Receipt.ExitCode)
}
}
has, err := m.FullNode.WalletHas(ctx, m.OwnerKey.Address)
require.NoError(n.t, err)
// Only import the owner's full key into our companion full node, if we
// don't have it still.
if !has {
_, err = m.FullNode.WalletImport(ctx, &m.OwnerKey.KeyInfo)
require.NoError(n.t, err)
}
// // Set it as the default address.
// err = m.FullNode.WalletSetDefault(ctx, m.OwnerAddr.Address)
// require.NoError(n.t, err)
r := repo.NewMemory(nil)
lr, err := r.Lock(repo.StorageMiner)
require.NoError(n.t, err)
c, err := lr.Config()
require.NoError(n.t, err)
cfg, ok := c.(*config.StorageMiner)
if !ok {
n.t.Fatalf("invalid config from repo, got: %T", c)
}
cfg.Common.API.RemoteListenAddress = m.RemoteListener.Addr().String()
cfg.Subsystems.EnableMarkets = m.options.subsystems.Has(SMarkets)
cfg.Subsystems.EnableMining = m.options.subsystems.Has(SMining)
cfg.Subsystems.EnableSealing = m.options.subsystems.Has(SSealing)
cfg.Subsystems.EnableSectorStorage = m.options.subsystems.Has(SSectorStorage)
cfg.Dealmaking.MaxStagingDealsBytes = m.options.maxStagingDealsBytes
if m.options.mainMiner != nil {
token, err := m.options.mainMiner.FullNode.AuthNew(ctx, api.AllPermissions)
require.NoError(n.t, err)
cfg.Subsystems.SectorIndexApiInfo = fmt.Sprintf("%s:%s", token, m.options.mainMiner.ListenAddr)
cfg.Subsystems.SealerApiInfo = fmt.Sprintf("%s:%s", token, m.options.mainMiner.ListenAddr)
fmt.Println("config for market node, setting SectorIndexApiInfo to: ", cfg.Subsystems.SectorIndexApiInfo)
fmt.Println("config for market node, setting SealerApiInfo to: ", cfg.Subsystems.SealerApiInfo)
}
err = lr.SetConfig(func(raw interface{}) {
rcfg := raw.(*config.StorageMiner)
*rcfg = *cfg
})
require.NoError(n.t, err)
ks, err := lr.KeyStore()
require.NoError(n.t, err)
pk, err := libp2pcrypto.MarshalPrivateKey(m.Libp2p.PrivKey)
require.NoError(n.t, err)
err = ks.Put("libp2p-host", types.KeyInfo{
Type: "libp2p-host",
PrivateKey: pk,
})
require.NoError(n.t, err)
ds, err := lr.Datastore(context.TODO(), "/metadata")
require.NoError(n.t, err)
err = ds.Put(ctx, datastore.NewKey("miner-address"), m.ActorAddr.Bytes())
require.NoError(n.t, err)
nic := storedcounter.New(ds, datastore.NewKey(modules.StorageCounterDSPrefix))
for i := 0; i < m.options.sectors; i++ {
_, err := nic.Next()
require.NoError(n.t, err)
}
_, err = nic.Next()
require.NoError(n.t, err)
err = lr.Close()
require.NoError(n.t, err)
if m.options.mainMiner == nil {
enc, err := actors.SerializeParams(&miner2.ChangePeerIDParams{NewID: abi.PeerID(m.Libp2p.PeerID)})
require.NoError(n.t, err)
msg := &types.Message{
From: m.OwnerKey.Address,
To: m.ActorAddr,
Method: miner.Methods.ChangePeerID,
Params: enc,
Value: types.NewInt(0),
}
_, err2 := m.FullNode.MpoolPushMessage(ctx, msg, nil)
require.NoError(n.t, err2)
}
var mineBlock = make(chan lotusminer.MineReq)
opts := []node.Option{
node.StorageMiner(&m.StorageMiner, cfg.Subsystems),
node.Base(),
node.Repo(r),
node.Test(),
node.If(!m.options.disableLibp2p, node.MockHost(n.mn)),
node.Override(new(v1api.FullNode), m.FullNode.FullNode),
node.Override(new(*lotusminer.Miner), lotusminer.NewTestMiner(mineBlock, m.ActorAddr)),
// disable resource filtering so that local worker gets assigned tasks
// regardless of system pressure.
node.Override(new(sectorstorage.SealerConfig), func() sectorstorage.SealerConfig {
scfg := config.DefaultStorageMiner()
scfg.Storage.ResourceFiltering = sectorstorage.ResourceFilteringDisabled
return scfg.Storage
}),
// upgrades
node.Override(new(stmgr.UpgradeSchedule), n.options.upgradeSchedule),
}
// append any node builder options.
opts = append(opts, m.options.extraNodeOpts...)
idAddr, err := address.IDFromAddress(m.ActorAddr)
require.NoError(n.t, err)
// preload preseals if the network still hasn't bootstrapped.
var presealSectors []abi.SectorID
if !n.bootstrapped {
sectors := n.genesis.miners[i].Sectors
for _, sector := range sectors {
presealSectors = append(presealSectors, abi.SectorID{
Miner: abi.ActorID(idAddr),
Number: sector.SectorID,
})
}
}
if n.options.mockProofs {
opts = append(opts,
node.Override(new(*mock.SectorMgr), func() (*mock.SectorMgr, error) {
return mock.NewMockSectorMgr(presealSectors), nil
}),
node.Override(new(sectorstorage.SectorManager), node.From(new(*mock.SectorMgr))),
node.Override(new(sectorstorage.Unsealer), node.From(new(*mock.SectorMgr))),
node.Override(new(sectorstorage.PieceProvider), node.From(new(*mock.SectorMgr))),
node.Override(new(ffiwrapper.Verifier), mock.MockVerifier),
node.Override(new(ffiwrapper.Prover), mock.MockProver),
node.Unset(new(*sectorstorage.Manager)),
)
}
// start node
stop, err := node.New(ctx, opts...)
require.NoError(n.t, err)
// using real proofs, therefore need real sectors.
if !n.bootstrapped && !n.options.mockProofs {
err := m.StorageAddLocal(ctx, m.PresealDir)
require.NoError(n.t, err)
}
n.t.Cleanup(func() { _ = stop(context.Background()) })
// Are we hitting this node through its RPC?
if m.options.rpc {
withRPC := minerRpc(n.t, m)
n.inactive.miners[i] = withRPC
}
mineOne := func(ctx context.Context, req lotusminer.MineReq) error {
select {
case mineBlock <- req:
return nil
case <-ctx.Done():
return ctx.Err()
}
}
m.MineOne = mineOne
m.Stop = stop
n.active.miners = append(n.active.miners, m)
}
// If we are here, we have processed all inactive miners and moved them
// to active, so clear the slice.
n.inactive.miners = n.inactive.miners[:0]
// Link all the nodes.
err = n.mn.LinkAll()
require.NoError(n.t, err)
if !n.bootstrapped && len(n.active.miners) > 0 {
// We have *just* bootstrapped, so mine 2 blocks to setup some CE stuff in some actors
var wait sync.Mutex
wait.Lock()
observer := n.active.fullnodes[0]
bm := NewBlockMiner(n.t, n.active.miners[0])
n.t.Cleanup(bm.Stop)
bm.MineUntilBlock(ctx, observer, func(epoch abi.ChainEpoch) {
wait.Unlock()
})
wait.Lock()
bm.MineUntilBlock(ctx, observer, func(epoch abi.ChainEpoch) {
wait.Unlock()
})
wait.Lock()
}
n.bootstrapped = true
return n
}
// InterconnectAll connects all miners and full nodes to one another.
func (n *Ensemble) InterconnectAll() *Ensemble {
// connect full nodes to miners.
for _, from := range n.active.fullnodes {
for _, to := range n.active.miners {
// []*TestMiner to []api.CommonAPI type coercion not possible
// so cannot use variadic form.
n.Connect(from, to)
}
}
// connect full nodes between each other, skipping ourselves.
last := len(n.active.fullnodes) - 1
for i, from := range n.active.fullnodes {
if i == last {
continue
}
for _, to := range n.active.fullnodes[i+1:] {
n.Connect(from, to)
}
}
return n
}
// Connect connects one full node to the provided full nodes.
func (n *Ensemble) Connect(from api.Net, to ...api.Net) *Ensemble {
addr, err := from.NetAddrsListen(context.Background())
require.NoError(n.t, err)
for _, other := range to {
err = other.NetConnect(context.Background(), addr)
require.NoError(n.t, err)
}
return n
}
func (n *Ensemble) BeginMiningMustPost(blocktime time.Duration, miners ...*TestMiner) []*BlockMiner {
ctx := context.Background()
// wait one second to make sure that nodes are connected and have handshaken.
// TODO make this deterministic by listening to identify events on the
// libp2p eventbus instead (or something else).
time.Sleep(1 * time.Second)
var bms []*BlockMiner
if len(miners) == 0 {
// no miners have been provided explicitly, instantiate block miners
// for all active miners that aren't still mining.
for _, m := range n.active.miners {
if _, ok := n.active.bms[m]; ok {
continue // skip, already have a block miner
}
miners = append(miners, m)
}
}
if len(miners) > 1 {
n.t.Fatalf("Only one active miner for MustPost, but have %d", len(miners))
}
for _, m := range miners {
bm := NewBlockMiner(n.t, m)
bm.MineBlocksMustPost(ctx, blocktime)
n.t.Cleanup(bm.Stop)
bms = append(bms, bm)
n.active.bms[m] = bm
}
return bms
}
// BeginMining kicks off mining for the specified miners. If nil or 0-length,
// it will kick off mining for all enrolled and active miners. It also adds a
// cleanup function to stop all mining operations on test teardown.
func (n *Ensemble) BeginMining(blocktime time.Duration, miners ...*TestMiner) []*BlockMiner {
ctx := context.Background()
// wait one second to make sure that nodes are connected and have handshaken.
// TODO make this deterministic by listening to identify events on the
// libp2p eventbus instead (or something else).
time.Sleep(1 * time.Second)
var bms []*BlockMiner
if len(miners) == 0 {
// no miners have been provided explicitly, instantiate block miners
// for all active miners that aren't still mining.
for _, m := range n.active.miners {
if _, ok := n.active.bms[m]; ok {
continue // skip, already have a block miner
}
miners = append(miners, m)
}
}
for _, m := range miners {
bm := NewBlockMiner(n.t, m)
bm.MineBlocks(ctx, blocktime)
n.t.Cleanup(bm.Stop)
bms = append(bms, bm)
n.active.bms[m] = bm
}
return bms
}
func (n *Ensemble) generateGenesis() *genesis.Template {
var verifRoot = gen.DefaultVerifregRootkeyActor
if k := n.options.verifiedRoot.key; k != nil {
verifRoot = genesis.Actor{
Type: genesis.TAccount,
Balance: n.options.verifiedRoot.initialBalance,
Meta: (&genesis.AccountMeta{Owner: k.Address}).ActorMeta(),
}
}
templ := &genesis.Template{
NetworkVersion: n.genesis.version,
Accounts: n.genesis.accounts,
Miners: n.genesis.miners,
NetworkName: "test",
Timestamp: uint64(time.Now().Unix() - int64(n.options.pastOffset.Seconds())),
VerifregRootKey: verifRoot,
RemainderAccount: gen.DefaultRemainderAccountActor,
}
return templ
}