lotus/chain/vm/syscalls.go

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package vm
import (
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"bytes"
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"context"
"fmt"
goruntime "runtime"
"sync"
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"github.com/filecoin-project/go-address"
"github.com/ipfs/go-cid"
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cbor "github.com/ipfs/go-ipld-cbor"
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"github.com/minio/blake2b-simd"
mh "github.com/multiformats/go-multihash"
"golang.org/x/xerrors"
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"github.com/filecoin-project/lotus/chain/state"
"github.com/filecoin-project/lotus/chain/types"
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"github.com/filecoin-project/lotus/lib/adtutil"
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"github.com/filecoin-project/lotus/lib/sigs"
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"github.com/filecoin-project/specs-actors/actors/abi"
"github.com/filecoin-project/specs-actors/actors/builtin/miner"
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"github.com/filecoin-project/specs-actors/actors/crypto"
"github.com/filecoin-project/specs-actors/actors/runtime"
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"github.com/filecoin-project/sector-storage/ffiwrapper"
)
func init() {
mh.Codes[0xf104] = "filecoin"
}
// Actual type is defined in chain/types/vmcontext.go because the VMContext interface is there
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func Syscalls(verifier ffiwrapper.Verifier) runtime.Syscalls {
return &syscallShim{verifier: verifier}
}
type syscallShim struct {
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ctx context.Context
cstate *state.StateTree
cst *cbor.BasicIpldStore
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verifier ffiwrapper.Verifier
}
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func (ss *syscallShim) ComputeUnsealedSectorCID(st abi.RegisteredSealProof, pieces []abi.PieceInfo) (cid.Cid, error) {
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var sum abi.PaddedPieceSize
for _, p := range pieces {
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sum += p.Size
}
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commd, err := ffiwrapper.GenerateUnsealedCID(st, pieces)
if err != nil {
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log.Errorf("generate data commitment failed: %s", err)
return cid.Undef, err
}
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return commd, nil
}
func (ss *syscallShim) HashBlake2b(data []byte) [32]byte {
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return blake2b.Sum256(data)
}
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// Checks validity of the submitted consensus fault with the two block headers needed to prove the fault
// and an optional extra one to check common ancestry (as needed).
// Note that the blocks are ordered: the method requires a.Epoch() <= b.Epoch().
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func (ss *syscallShim) VerifyConsensusFault(a, b, extra []byte) (*runtime.ConsensusFault, error) {
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// Note that block syntax is not validated. Any validly signed block will be accepted pursuant to the below conditions.
// Whether or not it could ever have been accepted in a chain is not checked/does not matter here.
// for that reason when checking block parent relationships, rather than instantiating a Tipset to do so
// (which runs a syntactic check), we do it directly on the CIDs.
// (0) cheap preliminary checks
// can blocks be decoded properly?
var blockA, blockB types.BlockHeader
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if decodeErr := blockA.UnmarshalCBOR(bytes.NewReader(a)); decodeErr != nil {
return nil, xerrors.Errorf("cannot decode first block header: %w", decodeErr)
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}
if decodeErr := blockB.UnmarshalCBOR(bytes.NewReader(b)); decodeErr != nil {
return nil, xerrors.Errorf("cannot decode second block header: %f", decodeErr)
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}
// are blocks the same?
if blockA.Cid().Equals(blockB.Cid()) {
return nil, fmt.Errorf("no consensus fault: submitted blocks are the same")
}
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// (1) check conditions necessary to any consensus fault
// were blocks mined by same miner?
if blockA.Miner != blockB.Miner {
return nil, fmt.Errorf("no consensus fault: blocks not mined by same miner")
}
// block a must be earlier or equal to block b, epoch wise (ie at least as early in the chain).
if blockB.Height < blockA.Height {
return nil, fmt.Errorf("first block must not be of higher height than second")
}
// (2) check for the consensus faults themselves
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var consensusFault *runtime.ConsensusFault
// (a) double-fork mining fault
if blockA.Height == blockB.Height {
consensusFault = &runtime.ConsensusFault{
Target: blockA.Miner,
Epoch: blockB.Height,
Type: runtime.ConsensusFaultDoubleForkMining,
}
}
// (b) time-offset mining fault
// strictly speaking no need to compare heights based on double fork mining check above,
// but at same height this would be a different fault.
if types.CidArrsEqual(blockA.Parents, blockB.Parents) && blockA.Height != blockB.Height {
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consensusFault = &runtime.ConsensusFault{
Target: blockA.Miner,
Epoch: blockB.Height,
Type: runtime.ConsensusFaultTimeOffsetMining,
}
}
// (c) parent-grinding fault
// Here extra is the "witness", a third block that shows the connection between A and B as
// A's sibling and B's parent.
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// Specifically, since A is of lower height, it must be that B was mined omitting A from its tipset
var blockC types.BlockHeader
if len(extra) > 0 {
if decodeErr := blockC.UnmarshalCBOR(bytes.NewReader(extra)); decodeErr != nil {
return nil, xerrors.Errorf("cannot decode extra: %w", decodeErr)
}
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if types.CidArrsEqual(blockA.Parents, blockC.Parents) && blockA.Height == blockC.Height &&
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types.CidArrsContains(blockB.Parents, blockC.Cid()) && !types.CidArrsContains(blockB.Parents, blockA.Cid()) {
consensusFault = &runtime.ConsensusFault{
Target: blockA.Miner,
Epoch: blockB.Height,
Type: runtime.ConsensusFaultParentGrinding,
}
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}
}
// (3) return if no consensus fault by now
if consensusFault == nil {
return nil, xerrors.Errorf("no consensus fault detected")
}
// else
// (4) expensive final checks
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// check blocks are properly signed by their respective miner
// note we do not need to check extra's: it is a parent to block b
// which itself is signed, so it was willingly included by the miner
if sigErr := ss.VerifyBlockSig(&blockA); sigErr != nil {
return nil, xerrors.Errorf("cannot verify first block sig: %w", sigErr)
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}
if sigErr := ss.VerifyBlockSig(&blockB); sigErr != nil {
return nil, xerrors.Errorf("cannot verify second block sig: %w", sigErr)
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}
return consensusFault, nil
}
func (ss *syscallShim) VerifyBlockSig(blk *types.BlockHeader) error {
// get appropriate miner actor
act, err := ss.cstate.GetActor(blk.Miner)
if err != nil {
return err
}
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// use that to get the miner state
var mas miner.State
if err = ss.cst.Get(ss.ctx, act.Head, &mas); err != nil {
return err
}
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info, err := mas.GetInfo(adtutil.NewStore(ss.ctx, ss.cst))
if err != nil {
return err
}
// and use to get resolved workerKey
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waddr, err := ResolveToKeyAddr(ss.cstate, ss.cst, info.Worker)
if err != nil {
return err
}
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if err := sigs.CheckBlockSignature(ss.ctx, blk, waddr); err != nil {
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return err
}
return nil
}
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func (ss *syscallShim) VerifyPoSt(proof abi.WindowPoStVerifyInfo) error {
ok, err := ss.verifier.VerifyWindowPoSt(context.TODO(), proof)
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if err != nil {
return err
}
if !ok {
return fmt.Errorf("proof was invalid")
}
return nil
}
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func (ss *syscallShim) VerifySeal(info abi.SealVerifyInfo) error {
//_, span := trace.StartSpan(ctx, "ValidatePoRep")
//defer span.End()
miner, err := address.NewIDAddress(uint64(info.Miner))
if err != nil {
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return xerrors.Errorf("weirdly failed to construct address: %w", err)
}
ticket := []byte(info.Randomness)
proof := info.Proof
seed := []byte(info.InteractiveRandomness)
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log.Debugf("Verif r:%x; d:%x; m:%s; t:%x; s:%x; N:%d; p:%x", info.SealedCID, info.UnsealedCID, miner, ticket, seed, info.SectorID.Number, proof)
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//func(ctx context.Context, maddr address.Address, ssize abi.SectorSize, commD, commR, ticket, proof, seed []byte, sectorID abi.SectorNumber)
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ok, err := ss.verifier.VerifySeal(info)
if err != nil {
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return xerrors.Errorf("failed to validate PoRep: %w", err)
}
if !ok {
return fmt.Errorf("invalid proof")
}
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return nil
}
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func (ss *syscallShim) VerifySignature(sig crypto.Signature, addr address.Address, input []byte) error {
// TODO: in genesis setup, we are currently faking signatures
kaddr, err := ResolveToKeyAddr(ss.cstate, ss.cst, addr)
if err != nil {
return err
}
return sigs.Verify(&sig, kaddr, input)
}
var BatchSealVerifyParallelism = goruntime.NumCPU()
func (ss *syscallShim) BatchVerifySeals(inp map[address.Address][]abi.SealVerifyInfo) (map[address.Address][]bool, error) {
out := make(map[address.Address][]bool)
sema := make(chan struct{}, BatchSealVerifyParallelism)
var wg sync.WaitGroup
for addr, seals := range inp {
results := make([]bool, len(seals))
out[addr] = results
for i, s := range seals {
wg.Add(1)
go func(ma address.Address, ix int, svi abi.SealVerifyInfo, res []bool) {
defer wg.Done()
sema <- struct{}{}
if err := ss.VerifySeal(svi); err != nil {
log.Warnw("seal verify in batch failed", "miner", ma, "index", ix, "err", err)
res[ix] = false
} else {
res[ix] = true
}
<-sema
}(addr, i, s, results)
}
}
wg.Wait()
return out, nil
}