Evidence
Contents
Evidence#
Important
Terra’s evidence module inherits from Cosmos SDK’s evidence
module. This document is a stub and covers mainly important Terra-specific notes about how it is used.
The evidence module allows arbitrary evidence of misbehavior, such as equivocation and counterfactual signing, to be submitted and handled.
Typically, standard evidence handling expects the underlying consensus engine, Tendermint, to automatically submit evidence when it is discovered by allowing clients and foreign chains to submit more complex evidence directly. The evidence module operates differently.
All concrete evidence types must implement the Evidence
interface contract. First, submitted Evidence
is routed through the evidence module’s Router
, where it attempts to find a corresponding registered Handler
for that specific Evidence
type. Each Evidence
type must have a Handler
registered with the evidence module’s keeper for it to be successfully routed and executed.
Each corresponding handler must also fulfill the Handler
interface contract. The Handler
for a given Evidence
type can perform any arbitrary state transitions, such as slashing, jailing, and tombstoning.
Concepts#
Evidence#
Any concrete type of evidence submitted to the module must fulfill the following Evidence
contract. Not all concrete types of evidence will fulfill this contract in the same way, and some data might be entirely irrelevant to certain types of evidence. An additional ValidatorEvidence
, which extends Evidence
, has also been created to define a contract for evidence against malicious validators.
// Evidence defines the contract which concrete evidence types of misbehavior
// must implement.
type Evidence interface {
proto.Message
Route() string
Type() string
String() string
Hash() tmbytes.HexBytes
ValidateBasic() error
// Height at which the infraction occurred
GetHeight() int64
}
// ValidatorEvidence extends Evidence interface to define contract
// for evidence against malicious validators
type ValidatorEvidence interface {
Evidence
// The consensus address of the malicious validator at time of infraction
GetConsensusAddress() sdk.ConsAddress
// The total power of the malicious validator at time of infraction
GetValidatorPower() int64
// The total validator set power at time of infraction
GetTotalPower() int64
}
Registration and handling#
First, the evidence module must know about all the types of evidence it is expected to handle. Register the Route
method in the Evidence
contract with a Router
as defined below. The Router
accepts Evidence
and attempts to find the corresponding Handler
for the Evidence
via the Route
method.
type Router interface {
AddRoute(r string, h Handler) Router
HasRoute(r string) bool
GetRoute(path string) Handler
Seal()
Sealed() bool
}
As defined below, the Handler
is responsible for executing the entirety of the business logic for handling Evidence
. Doing so typically includes validating the evidence, both stateless checks via ValidateBasic
and stateful checks via any keepers provided to the Handler
. Additionally, the Handler
may also perform capabilities, such as slashing and jailing a validator. All Evidence
handled by the Handler
must be persisted.
// Handler defines an agnostic Evidence handler. The handler is responsible
// for executing all corresponding business logic necessary for verifying the
// evidence as valid. In addition, the Handler may execute any necessary
// slashing and potential jailing.
type Handler func(sdk.Context, Evidence) error
State#
The evidence module only stores valid submitted Evidence
in state. The evidence state is also stored and exported in the evidence module’s GenesisState
.
// GenesisState defines the evidence module's genesis state.
message GenesisState {
// evidence defines all the evidence at genesis.
repeated google.protobuf.Any evidence = 1;
}
Messages#
MsgSubmitEvidence#
Evidence is submitted through a MsgSubmitEvidence
message:
// MsgSubmitEvidence represents a message that supports submitting arbitrary
// Evidence of misbehavior such as equivocation or counterfactual signing.
message MsgSubmitEvidence {
string submitter = 1;
google.protobuf.Any evidence = 2;
}
The Evidence
of a MsgSubmitEvidence
message must have a corresponding Handler
registered with the evidence module’s Router
to be processed and routed correctly.
Given the Evidence
is registered with a corresponding Handler
, it is processed as follows:
func SubmitEvidence(ctx Context, evidence Evidence) error {
if _, ok := GetEvidence(ctx, evidence.Hash()); ok {
return sdkerrors.Wrap(types.ErrEvidenceExists, evidence.Hash().String())
}
if !router.HasRoute(evidence.Route()) {
return sdkerrors.Wrap(types.ErrNoEvidenceHandlerExists, evidence.Route())
}
handler := router.GetRoute(evidence.Route())
if err := handler(ctx, evidence); err != nil {
return sdkerrors.Wrap(types.ErrInvalidEvidence, err.Error())
}
ctx.EventManager().EmitEvent(
sdk.NewEvent(
types.EventTypeSubmitEvidence,
sdk.NewAttribute(types.AttributeKeyEvidenceHash, evidence.Hash().String()),
),
)
SetEvidence(ctx, evidence)
return nil
}
Valid submitted Evidence
of the same type must not already exist. The Evidence
is routed to the Handler
and executed. If no error in handling the Evidence occurs, an event is emitted, and it is persisted to state.
Events#
The evidence module emits the following handler events:
MsgSubmitEvidence#
Type |
Attribute Key |
Attribute Value |
---|---|---|
submit_evidence |
evidence_hash |
{evidenceHash} |
message |
module |
evidence |
message |
sender |
{senderAddress} |
message |
action |
submit_evidence |
BeginBlock#
Evidence handling#
Tendermint blocks can include
Evidence that indicates whether a validator acted maliciously. The relevant information is forwarded to the application as ABCI Evidence in abci.RequestBeginBlock
so that the validator can be punished accordingly.
Equivocation#
Currently, the SDK handles two types of evidence inside the ABCI BeginBlock
:
DuplicateVoteEvidence
,LightClientAttackEvidence
.
The evidence module handles these two evidence types the same way. First, the SDK converts the Tendermint concrete evidence type to a SDK Evidence
interface by using Equivocation
as the concrete type.
// Equivocation implements the Evidence interface.
message Equivocation {
int64 height = 1;
google.protobuf.Timestamp time = 2;
int64 power = 3;
string consensus_address = 4;
}
For an Equivocation
submitted in block
to be valid, it must meet the following requirement:
Evidence.Timestamp >= block.Timestamp - MaxEvidenceAge
where:
Evidence.Timestamp
is the timestamp in the block at heightEvidence.Height
.block.Timestamp
is the current block timestamp.
If valid Equivocation
evidence is included in a block, the validator’s stake is
reduced by SlashFractionDoubleSign
, as defined by the slashing module. The reduction is implemented at the point when the infraction occurred instead of when the evidence was discovered.
The stake that contributed to the infraction is slashed, even if it has been redelegated or started unbonding.
Additionally, the validator is permanently jailed and tombstoned so that the validator cannot re-enter the validator set again.
Equivocation
evidence handling code
func (k Keeper) HandleEquivocationEvidence(ctx sdk.Context, evidence *types.Equivocation) {
logger := k.Logger(ctx)
consAddr := evidence.GetConsensusAddress()
if _, err := k.slashingKeeper.GetPubkey(ctx, consAddr.Bytes()); err != nil {
// Ignore evidence that cannot be handled.
//
// NOTE: Developers used to panic with:
// `panic(fmt.Sprintf("Validator consensus-address %v not found", consAddr))`,
// but this couples the expectations of the app to both Tendermint and
// the simulator. Both are expected to provide the full range of
// allowable but none of the disallowed evidence types. Instead of
// getting this coordination right, it is easier to relax the
// constraints and ignore evidence that cannot be handled.
return
}
// calculate the age of the evidence
infractionHeight := evidence.GetHeight()
infractionTime := evidence.GetTime()
ageDuration := ctx.BlockHeader().Time.Sub(infractionTime)
ageBlocks := ctx.BlockHeader().Height - infractionHeight
// Reject evidence if the double-sign is too old. Evidence is considered stale
// if the difference in time and number of blocks is greater than the allowed
// parameters defined.
cp := ctx.ConsensusParams()
if cp != nil && cp.Evidence != nil {
if ageDuration > cp.Evidence.MaxAgeDuration && ageBlocks > cp.Evidence.MaxAgeNumBlocks {
logger.Info(
"ignored equivocation; evidence too old",
"validator", consAddr,
"infraction_height", infractionHeight,
"max_age_num_blocks", cp.Evidence.MaxAgeNumBlocks,
"infraction_time", infractionTime,
"max_age_duration", cp.Evidence.MaxAgeDuration,
)
return
}
}
validator := k.stakingKeeper.ValidatorByConsAddr(ctx, consAddr)
if validator == nil || validator.IsUnbonded() {
// Defensive: Simulation doesn't take unbonding periods into account, and
// Tendermint might break this assumption at some point.
return
}
if ok := k.slashingKeeper.HasValidatorSigningInfo(ctx, consAddr); !ok {
panic(fmt.Sprintf("expected signing info for validator %s but not found", consAddr))
}
// ignore if the validator is already tombstoned
if k.slashingKeeper.IsTombstoned(ctx, consAddr) {
logger.Info(
"ignored equivocation; validator already tombstoned",
"validator", consAddr,
"infraction_height", infractionHeight,
"infraction_time", infractionTime,
)
return
}
logger.Info(
"confirmed equivocation",
"validator", consAddr,
"infraction_height", infractionHeight,
"infraction_time", infractionTime,
)
// To retrieve the stake distribution which signed the block, subtract ValidatorUpdateDelay from the evidence height.
// Note, that this *can* result in a negative "distributionHeight", up to
// -ValidatorUpdateDelay, i.e. at the end of the
// pre-genesis block (none) = at the beginning of the genesis block.
// That's fine since this is just used to filter unbonding delegations & redelegations.
distributionHeight := infractionHeight - sdk.ValidatorUpdateDelay
// Slash validator. The `power` is the int64 power of the validator as provided
// to/by Tendermint. This value is validator.Tokens as sent to Tendermint via
// ABCI, and now received as evidence. The fraction is passed in to separately
// to slash unbonding and rebonding delegations.
k.slashingKeeper.Slash(
ctx,
consAddr,
k.slashingKeeper.SlashFractionDoubleSign(ctx),
evidence.GetValidatorPower(), distributionHeight,
)
// Jail the validator if not already jailed. This will begin unbonding the
// validator if not already unbonding (tombstoned).
if !validator.IsJailed() {
k.slashingKeeper.Jail(ctx, consAddr)
}
k.slashingKeeper.JailUntil(ctx, consAddr, types.DoubleSignJailEndTime)
k.slashingKeeper.Tombstone(ctx, consAddr)
}
The slashing, jailing, and tombstoning calls are delegated through the slashing module, which emits informative events and finally delegates calls to the staking module. For more information about slashing and jailing, see transitions.