path: root/core/lattice_test.go

// Copyright 2018 The dexon-consensus-core Authors
// This file is part of the dexon-consensus-core library.
//
// The dexon-consensus-core library is free software: you can redistribute it
// and/or modify it under the terms of the GNU Lesser General Public License as
// published by the Free Software Foundation, either version 3 of the License,
// or (at your option) any later version.
//
// The dexon-consensus-core library is distributed in the hope that it will be
// useful, but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser
// General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the dexon-consensus-core library. If not, see
// <http://www.gnu.org/licenses/>.

package core

import (
    "math/rand"
    "testing"
    "time"

    "github.com/dexon-foundation/dexon-consensus-core/common"
    "github.com/dexon-foundation/dexon-consensus-core/core/blockdb"
    "github.com/dexon-foundation/dexon-consensus-core/core/crypto/ecdsa"
    "github.com/dexon-foundation/dexon-consensus-core/core/test"
    "github.com/dexon-foundation/dexon-consensus-core/core/types"
    "github.com/stretchr/testify/suite"
)

// testLatticeMgr wraps compaction chain and lattice.
type testLatticeMgr struct {
    lattice  *Lattice
    ccModule *compactionChain
    app      *test.App
    db       blockdb.BlockDatabase
}

func (mgr *testLatticeMgr) prepareBlock(
    chainID uint32) (b *types.Block, err error) {

    b = &types.Block{
        Position: types.Position{
            ChainID: chainID,
        }}
    err = mgr.lattice.PrepareBlock(b, time.Now().UTC())
    return
}

// Process describes the usage of Lattice.ProcessBlock.
func (mgr *testLatticeMgr) processBlock(b *types.Block) (err error) {
    var (
        delivered []*types.Block
        verified  []*types.Block
        pendings  = []*types.Block{b}
    )
    if err = mgr.lattice.SanityCheck(b); err != nil {
        if err == ErrAckingBlockNotExists {
            err = nil
        }
        return
    }
    for {
        if len(pendings) == 0 {
            break
        }
        b, pendings = pendings[0], pendings[1:]
        if verified, delivered, err = mgr.lattice.ProcessBlock(b); err != nil {
            return
        }
        // Deliver blocks.
        for _, b = range delivered {
            if err = mgr.ccModule.processBlock(b); err != nil {
                return
            }
            if err = mgr.db.Put(*b); err != nil {
                return
            }
            mgr.app.BlockDelivered(*b)
        }
        if err = mgr.lattice.PurgeBlocks(delivered); err != nil {
            return
        }
        // Update pending blocks for verified block (pass sanity check).
        pendings = append(pendings, verified...)
    }
    return
}

type LatticeTestSuite struct {
    suite.Suite
}

func (s *LatticeTestSuite) newTestLatticeMgr(
    cfg *types.Config) *testLatticeMgr {
    var (
        req   = s.Require()
        round uint64
    )
    // Setup private key.
    prvKey, err := ecdsa.NewPrivateKey()
    req.Nil(err)
    // Setup blockdb.
    db, err := blockdb.NewMemBackedBlockDB()
    req.Nil(err)
    // Setup application.
    app := test.NewApp()
    // Setup lattice.
    return &testLatticeMgr{
        ccModule: newCompactionChain(db),
        app:      app,
        db:       db,
        lattice: NewLattice(
            round,
            cfg,
            NewAuthenticator(prvKey),
            app,
            app,
            db)}
}

func (s *LatticeTestSuite) TestBasicUsage() {
    // One Lattice prepare blocks on chains randomly selected each time
    // and process it. Those generated blocks and kept into a buffer, and
    // process by other Lattice instances with random order.
    var (
        blockNum        = 100
        chainNum        = uint32(19)
        otherLatticeNum = 20
        req             = s.Require()
        err             error
        cfg             = types.Config{
            NumChains:        chainNum,
            PhiRatio:         float32(2) / float32(3),
            K:                0,
            MinBlockInterval: 0,
            MaxBlockInterval: 3000 * time.Second,
        }
        master    = s.newTestLatticeMgr(&cfg)
        apps      = []*test.App{master.app}
        revealSeq = map[string]struct{}{}
    )
    // Master-lattice generates blocks.
    for i := uint32(0); i < chainNum; i++ {
        // Produce genesis blocks should be delivered before all other blocks,
        // or the consensus time would be wrong.
        b, err := master.prepareBlock(i)
        req.NotNil(b)
        req.Nil(err)
        // We've ignored the error for "acking blocks don't exist".
        req.Nil(master.processBlock(b))
    }
    for i := 0; i < (blockNum - int(chainNum)); i++ {
        b, err := master.prepareBlock(uint32(rand.Intn(int(chainNum))))
        req.NotNil(b)
        req.Nil(err)
        // We've ignored the error for "acking blocks don't exist".
        req.Nil(master.processBlock(b))
    }
    // Now we have some blocks, replay them on different lattices.
    iter, err := master.db.GetAll()
    req.Nil(err)
    revealer, err := test.NewRandomRevealer(iter)
    req.Nil(err)
    for i := 0; i < otherLatticeNum; i++ {
        revealer.Reset()
        revealed := ""
        other := s.newTestLatticeMgr(&cfg)
        for {
            b, err := revealer.Next()
            if err != nil {
                if err == blockdb.ErrIterationFinished {
                    err = nil
                    break
                }
            }
            req.Nil(err)
            req.Nil(other.processBlock(&b))
            revealed += b.Hash.String() + ","
            revealSeq[revealed] = struct{}{}
        }
        apps = append(apps, other.app)
    }
    // Make sure not only one revealing sequence.
    req.True(len(revealSeq) > 1)
    // Make sure nothing goes wrong.
    for i, app := range apps {
        req.Nil(app.Verify())
        for j, otherApp := range apps {
            if i >= j {
                continue
            }
            req.Nil(app.Compare(otherApp))
        }
    }
}

func (s *LatticeTestSuite) TestSanityCheck() {
    // This sanity check focuses on hash/signature part.
    var (
        chainNum = uint32(19)
        cfg      = types.Config{
            NumChains:        chainNum,
            PhiRatio:         float32(2) / float32(3),
            K:                0,
            MinBlockInterval: 0,
            MaxBlockInterval: 3000 * time.Second,
        }
        lattice = s.newTestLatticeMgr(&cfg).lattice
        auth    = lattice.authModule // Steal auth module from lattice, :(
        req     = s.Require()
        err     error
    )
    // A block properly signed should pass sanity check.
    b := &types.Block{
        Position: types.Position{ChainID: 0},
    }
    req.NoError(auth.SignBlock(b))
    req.NoError(lattice.SanityCheck(b))
    // A block with incorrect signature should not pass sanity check.
    b.Signature, err = auth.prvKey.Sign(common.NewRandomHash())
    req.NoError(err)
    req.Equal(lattice.SanityCheck(b), ErrIncorrectSignature)
    // A block with un-sorted acks should not pass sanity check.
    b.Acks = common.NewSortedHashes(common.Hashes{
        common.NewRandomHash(),
        common.NewRandomHash(),
        common.NewRandomHash(),
        common.NewRandomHash(),
        common.NewRandomHash(),
    })
    b.Acks[0], b.Acks[1] = b.Acks[1], b.Acks[0]
    req.NoError(auth.SignBlock(b))
    req.Equal(lattice.SanityCheck(b), ErrAcksNotSorted)
    // A block with incorrect hash should not pass sanity check.
    b.Hash = common.NewRandomHash()
    req.Equal(lattice.SanityCheck(b), ErrIncorrectHash)
}

func TestLattice(t *testing.T) {
    suite.Run(t, new(LatticeTestSuite))
}