Documentation ¶
Index ¶
- type BlockProducer
- type BlockSignatureData
- type BlockSignerDecoder
- type CommunicatorConsumer
- type Consumer
- type DKG
- type DynamicCommittee
- type EventHandler
- type EventLoop
- type FinalityProof
- type FinalizationConsumer
- type FollowerConsumer
- type FollowerLoop
- type Forks
- type LivenessData
- type OnQCCreated
- type PaceMaker
- type Packer
- type PartialTcCreated
- type ParticipantConsumer
- type Persister
- type ProposalDurationProvider
- type ProposalViolationConsumer
- type RandomBeaconInspector
- type RandomBeaconReconstructor
- type Replicas
- type SafetyData
- type SafetyRules
- type Signer
- type TimeoutAggregationConsumer
- type TimeoutAggregationViolationConsumer
- type TimeoutAggregator
- type TimeoutCollector
- type TimeoutCollectorConsumer
- type TimeoutCollectorFactory
- type TimeoutCollectors
- type TimeoutProcessor
- type TimeoutProcessorFactory
- type TimeoutSignatureAggregator
- type TimeoutSignerInfo
- type Validator
- type Verifier
- type VerifyingVoteProcessor
- type VoteAggregationConsumer
- type VoteAggregationViolationConsumer
- type VoteAggregator
- type VoteCollector
- type VoteCollectorConsumer
- type VoteCollectorStatus
- type VoteCollectors
- type VoteConsumer
- type VoteProcessor
- type VoteProcessorFactory
- type WeightedSignatureAggregator
- type Workerpool
- type Workers
Constants ¶
This section is empty.
Variables ¶
This section is empty.
Functions ¶
This section is empty.
Types ¶
type BlockProducer ¶
type BlockProducer interface { // MakeBlockProposal builds a new HotStuff block proposal using the given view, // the given quorum certificate for its parent and [optionally] a timeout certificate for last view(could be nil). // No errors are expected during normal operation. MakeBlockProposal(view uint64, qc *flow.QuorumCertificate, lastViewTC *flow.TimeoutCertificate) (*flow.Header, error) }
BlockProducer builds a new block proposal by building a new block payload with the builder module, and uses VoteCollectorFactory to create a disposable VoteCollector for producing the proposal vote. BlockProducer assembles the new block proposal using the block payload, block header and the proposal vote.
type BlockSignatureData ¶ added in v0.23.9
type BlockSignatureData struct { StakingSigners flow.IdentifierList RandomBeaconSigners flow.IdentifierList AggregatedStakingSig []byte // if BLS is used, this is equivalent to crypto.Signature AggregatedRandomBeaconSig []byte // if BLS is used, this is equivalent to crypto.Signature ReconstructedRandomBeaconSig crypto.Signature }
BlockSignatureData is an intermediate struct for Packer to pack the aggregated signature data into raw bytes or unpack from raw bytes.
type BlockSignerDecoder ¶ added in v0.26.17
type BlockSignerDecoder interface { // DecodeSignerIDs decodes the signer indices from the given block header into full node IDs. // Note: A block header contains a quorum certificate for its parent, which proves that the // consensus committee has reached agreement on validity of parent block. Consequently, the // returned IdentifierList contains the consensus participants that signed the parent block. // Expected Error returns during normal operations: // - signature.InvalidSignerIndicesError if signer indices included in the header do // not encode a valid subset of the consensus committee DecodeSignerIDs(header *flow.Header) (flow.IdentifierList, error) }
BlockSignerDecoder defines how to convert the ParentSignerIndices field within a particular block header to the identifiers of the nodes which signed the block.
type CommunicatorConsumer ¶ added in v0.29.0
type CommunicatorConsumer interface { // OnOwnVote notifies about intent to send a vote for the given parameters to the specified recipient. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnOwnVote(blockID flow.Identifier, view uint64, sigData []byte, recipientID flow.Identifier) // OnOwnTimeout notifies about intent to broadcast the given timeout object(TO) to all actors of the consensus process. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnOwnTimeout(timeout *model.TimeoutObject) // OnOwnProposal notifies about intent to broadcast the given block proposal to all actors of // the consensus process. // delay is to hold the proposal before broadcasting it. Useful to control the block production rate. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnOwnProposal(proposal *flow.Header, targetPublicationTime time.Time) }
CommunicatorConsumer consumes outbound notifications produced by HotStuff and it's components. Notifications allow the HotStuff core algorithm to communicate with the other actors of the consensus process. Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type Consumer ¶
type Consumer interface { FollowerConsumer CommunicatorConsumer ParticipantConsumer }
Consumer consumes outbound notifications produced by consensus participants. Notifications are consensus-internal state changes which are potentially relevant to the larger node in which HotStuff is running. The notifications are emitted in the order in which the HotStuff algorithm makes the respective steps.
Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type DynamicCommittee ¶ added in v0.29.0
type DynamicCommittee interface { Replicas // IdentitiesByBlock returns a list of the legitimate HotStuff participants for the given block. // The returned list of HotStuff participants: // - contains nodes that are allowed to submit proposals, votes, and timeouts // (un-ejected, non-zero weight at current block) // - is ordered in the canonical order // - contains no duplicates. // // ERROR conditions: // - state.ErrUnknownSnapshotReference if the blockID is for an unknown block IdentitiesByBlock(blockID flow.Identifier) (flow.IdentityList, error) // IdentityByBlock returns the full Identity for specified HotStuff participant. // The node must be a legitimate HotStuff participant with NON-ZERO WEIGHT at the specified block. // ERROR conditions: // - model.InvalidSignerError if participantID does NOT correspond to an authorized HotStuff participant at the specified block. // - state.ErrUnknownSnapshotReference if the blockID is for an unknown block IdentityByBlock(blockID flow.Identifier, participantID flow.Identifier) (*flow.Identity, error) }
DynamicCommittee extends Replicas to provide the consensus committee for the purposes of validating proposals. The proposer committee reflects block-to-block changes in the identity table to support immediately rejecting proposals from nodes after they are ejected. For validating proposals, we use *ByBlock methods.
Since the proposer committee can change at any block:
- we query by block ID
- we must have incorporated the full block ancestry prior to validating messages
type EventHandler ¶
type EventHandler interface { // OnReceiveQc processes a valid qc constructed by internal vote aggregator or discovered in TimeoutObject. // All inputs should be validated before feeding into this function. Assuming trusted data. // No errors are expected during normal operation. OnReceiveQc(qc *flow.QuorumCertificate) error // OnReceiveTc processes a valid tc constructed by internal timeout aggregator, discovered in TimeoutObject or // broadcast over the network. // All inputs should be validated before feeding into this function. Assuming trusted data. // No errors are expected during normal operation. OnReceiveTc(tc *flow.TimeoutCertificate) error // OnReceiveProposal processes a block proposal received from another HotStuff // consensus participant. // All inputs should be validated before feeding into this function. Assuming trusted data. // No errors are expected during normal operation. OnReceiveProposal(proposal *model.Proposal) error // OnLocalTimeout handles a local timeout event by creating a model.TimeoutObject and broadcasting it. // No errors are expected during normal operation. OnLocalTimeout() error // OnPartialTcCreated handles notification produces by the internal timeout aggregator. If the notification is for the current view, // a corresponding model.TimeoutObject is broadcast to the consensus committee. // No errors are expected during normal operation. OnPartialTcCreated(partialTC *PartialTcCreated) error // TimeoutChannel returns a channel that sends a signal on timeout. TimeoutChannel() <-chan time.Time // Start starts the event handler. // No errors are expected during normal operation. // CAUTION: EventHandler is not concurrency safe. The Start method must // be executed by the same goroutine that also calls the other business logic // methods, or concurrency safety has to be implemented externally. Start(ctx context.Context) error }
EventHandler runs a state machine to process proposals, QC and local timeouts. Not concurrency safe.
type EventLoop ¶
type EventLoop interface { module.HotStuff TimeoutCollectorConsumer VoteCollectorConsumer }
EventLoop performs buffer and processing of incoming proposals and QCs.
type FinalityProof ¶ added in v0.31.0
type FinalityProof struct { Block *model.Block CertifiedChild model.CertifiedBlock }
FinalityProof represents a finality proof for a Block. By convention, a FinalityProof is immutable. Finality in Jolteon/HotStuff is determined by the 2-chain rule:
There exists a _certified_ block C, such that Block.View + 1 = C.View
type FinalizationConsumer ¶
type FinalizationConsumer interface { // OnBlockIncorporated notifications are produced by the Finalization Logic // whenever a block is incorporated into the consensus state. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnBlockIncorporated(*model.Block) // OnFinalizedBlock notifications are produced by the Finalization Logic whenever // a block has been finalized. They are emitted in the order the blocks are finalized. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnFinalizedBlock(*model.Block) }
FinalizationConsumer consumes outbound notifications produced by the logic tracking forks and finalization. Such notifications are produced by the active consensus participants, and generally potentially relevant to the larger node. The notifications are emitted in the order in which the finalization algorithm makes the respective steps.
Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type FollowerConsumer ¶ added in v0.31.0
type FollowerConsumer interface { ProposalViolationConsumer FinalizationConsumer }
FollowerConsumer consumes outbound notifications produced by consensus followers. It is a subset of the notifications produced by consensus participants. Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type FollowerLoop ¶
type FollowerLoop struct { *component.ComponentManager // contains filtered or unexported fields }
FollowerLoop implements interface module.HotStuffFollower. FollowerLoop buffers all incoming events to the hotstuff FollowerLogic, and feeds FollowerLogic one event at a time using a worker thread. Concurrency safe.
func NewFollowerLoop ¶
func NewFollowerLoop(log zerolog.Logger, mempoolMetrics module.MempoolMetrics, forks Forks) (*FollowerLoop, error)
NewFollowerLoop creates an instance of HotStuffFollower
func (*FollowerLoop) AddCertifiedBlock ¶ added in v0.31.0
func (fl *FollowerLoop) AddCertifiedBlock(certifiedBlock *model.CertifiedBlock)
AddCertifiedBlock appends the given certified block to the tree of pending blocks and updates the latest finalized block (if finalization progressed). Unless the parent is below the pruning threshold (latest finalized view), we require that the parent has previously been added.
Notes:
- Under normal operations, this method is non-blocking. The follower internally queues incoming blocks and processes them in its own worker routine. However, when the inbound queue is, we block until there is space in the queue. This behavior is intentional, because we cannot drop blocks (otherwise, we would cause disconnected blocks). Instead, we simply block the compliance layer to avoid any pathological edge cases.
- Blocks whose views are below the latest finalized view are dropped.
- Inputs are idempotent (repetitions are no-ops).
type Forks ¶
type Forks interface { // GetBlocksForView returns all known blocks for the given view GetBlocksForView(view uint64) []*model.Block // GetBlock returns (BlockProposal, true) if the block with the specified // id was found and (nil, false) otherwise. GetBlock(blockID flow.Identifier) (*model.Block, bool) // FinalizedView returns the largest view number where a finalized block is known FinalizedView() uint64 // FinalizedBlock returns the finalized block with the largest view number FinalizedBlock() *model.Block // FinalityProof returns the latest finalized block and a certified child from // the subsequent view, which proves finality. // CAUTION: method returns (nil, false), when Forks has not yet finalized any // blocks beyond the finalized root block it was initialized with. FinalityProof() (*FinalityProof, bool) // AddValidatedBlock appends the validated block to the tree of pending // blocks and updates the latest finalized block (if applicable). Unless the parent is // below the pruning threshold (latest finalized view), we require that the parent is // already stored in Forks. Calling this method with previously processed blocks // leaves the consensus state invariant (though, it will potentially cause some // duplicate processing). // Notes: // - Method `AddCertifiedBlock(..)` should be used preferably, if a QC certifying // `block` is already known. This is generally the case for the consensus follower. // Method `AddValidatedBlock` is intended for active consensus participants, which fully // validate blocks (incl. payload), i.e. QCs are processed as part of validated proposals. // // Possible error returns: // - model.MissingBlockError if the parent does not exist in the forest (but is above // the pruned view). From the perspective of Forks, this error is benign (no-op). // - model.InvalidBlockError if the block is invalid (see `Forks.EnsureBlockIsValidExtension` // for details). From the perspective of Forks, this error is benign (no-op). However, we // assume all blocks are fully verified, i.e. they should satisfy all consistency // requirements. Hence, this error is likely an indicator of a bug in the compliance layer. // - model.ByzantineThresholdExceededError if conflicting QCs or conflicting finalized // blocks have been detected (violating a foundational consensus guarantees). This // indicates that there are 1/3+ Byzantine nodes (weighted by stake) in the network, // breaking the safety guarantees of HotStuff (or there is a critical bug / data // corruption). Forks cannot recover from this exception. // - All other errors are potential symptoms of bugs or state corruption. AddValidatedBlock(proposal *model.Block) error // AddCertifiedBlock appends the given certified block to the tree of pending // blocks and updates the latest finalized block (if finalization progressed). // Unless the parent is below the pruning threshold (latest finalized view), we // require that the parent is already stored in Forks. Calling this method with // previously processed blocks leaves the consensus state invariant (though, // it will potentially cause some duplicate processing). // // Possible error returns: // - model.MissingBlockError if the parent does not exist in the forest (but is above // the pruned view). From the perspective of Forks, this error is benign (no-op). // - model.InvalidBlockError if the block is invalid (see `Forks.EnsureBlockIsValidExtension` // for details). From the perspective of Forks, this error is benign (no-op). However, we // assume all blocks are fully verified, i.e. they should satisfy all consistency // requirements. Hence, this error is likely an indicator of a bug in the compliance layer. // - model.ByzantineThresholdExceededError if conflicting QCs or conflicting finalized // blocks have been detected (violating a foundational consensus guarantees). This // indicates that there are 1/3+ Byzantine nodes (weighted by stake) in the network, // breaking the safety guarantees of HotStuff (or there is a critical bug / data // corruption). Forks cannot recover from this exception. // - All other errors are potential symptoms of bugs or state corruption. AddCertifiedBlock(certifiedBlock *model.CertifiedBlock) error }
Forks maintains an in-memory data-structure of all blocks whose view-number is larger or equal to the latest finalized block. The latest finalized block is defined as the finalized block with the largest view number. When adding blocks, Forks automatically updates its internal state (including finalized blocks). Furthermore, blocks whose view number is smaller than the latest finalized block are pruned automatically.
PREREQUISITES: Forks expects that only blocks are added that can be connected to its latest finalized block (without missing interim ancestors). If this condition is violated, Forks will raise an error and ignore the block.
type LivenessData ¶ added in v0.29.0
type LivenessData struct { // CurrentView is the currently active view tracked by the PaceMaker. It is updated // whenever the PaceMaker sees evidence (QC or TC) for advancing to next view. CurrentView uint64 // NewestQC is the newest QC (by view) observed by the PaceMaker. The QC can be observed on its own or as a part of TC. NewestQC *flow.QuorumCertificate // LastViewTC is the TC for the prior view (CurrentView-1), if this view timed out. If the previous round // ended with a QC, this QC is stored in NewestQC and LastViewTC is nil. LastViewTC *flow.TimeoutCertificate }
type OnQCCreated ¶ added in v0.23.9
type OnQCCreated func(*flow.QuorumCertificate)
OnQCCreated is a callback which will be used by VoteCollector to submit a QC when it's able to create it
type PaceMaker ¶
type PaceMaker interface { ProposalDurationProvider // CurView returns the current view. CurView() uint64 // NewestQC returns QC with the highest view discovered by PaceMaker. NewestQC() *flow.QuorumCertificate // LastViewTC returns TC for last view, this could be nil if previous round // has entered with a QC. LastViewTC() *flow.TimeoutCertificate // ProcessQC will check if the given QC will allow PaceMaker to fast-forward to QC.view+1. // If PaceMaker incremented the current View, a NewViewEvent will be returned. // No errors are expected during normal operation. ProcessQC(qc *flow.QuorumCertificate) (*model.NewViewEvent, error) // ProcessTC will check if the given TC will allow PaceMaker to fast-forward to TC.view+1. // If PaceMaker incremented the current View, a NewViewEvent will be returned. // A nil TC is an expected valid input. // No errors are expected during normal operation. ProcessTC(tc *flow.TimeoutCertificate) (*model.NewViewEvent, error) // TimeoutChannel returns the timeout channel for the CURRENTLY ACTIVE timeout. // Each time the pacemaker starts a new timeout, this channel is replaced. TimeoutChannel() <-chan time.Time // Start starts the PaceMaker (i.e. the timeout for the configured starting value for view). // CAUTION: EventHandler is not concurrency safe. The Start method must // be executed by the same goroutine that also calls the other business logic // methods, or concurrency safety has to be implemented externally. Start(ctx context.Context) }
PaceMaker for HotStuff. The component is passive in that it only reacts to method calls. The PaceMaker does not perform state transitions on its own. Timeouts are emitted through channels. Each timeout has its own dedicated channel, which is garbage collected after the respective state has been passed. It is the EventHandler's responsibility to pick up timeouts from the currently active TimeoutChannel process them first and subsequently inform the PaceMaker about processing the timeout. Specifically, the intended usage pattern for the TimeoutChannels is as follows:
• Each time the PaceMaker starts a new timeout, it created a new TimeoutChannel
• The channel for the CURRENTLY ACTIVE timeout is returned by PaceMaker.TimeoutChannel()
Each time the EventHandler processes an event, the EventHandler might call into PaceMaker potentially resulting in a state transition and the PaceMaker starting a new timeout
Hence, after processing any event, EventHandler should retrieve the current TimeoutChannel from the PaceMaker.
For Example:
for { timeoutChannel := el.eventHandler.TimeoutChannel() select { case <-timeoutChannel: el.eventHandler.OnLocalTimeout() case <other events> } }
Not concurrency safe.
type Packer ¶ added in v0.23.9
type Packer interface { // Pack serializes the provided BlockSignatureData into a precursor format of a QC. // view is the view of the block that the aggregated signature is for. // sig is the aggregated signature data. // Expected error returns during normal operations: // * none; all errors are symptoms of inconsistent input data or corrupted internal state. Pack(view uint64, sig *BlockSignatureData) (signerIndices []byte, sigData []byte, err error) // Unpack de-serializes the provided signature data. // sig is the aggregated signature data // It returns: // - (sigData, nil) if successfully unpacked the signature data // - (nil, model.InvalidFormatError) if failed to unpack the signature data Unpack(signerIdentities flow.IdentitySkeletonList, sigData []byte) (*BlockSignatureData, error) }
Packer packs aggregated signature data into raw bytes to be used in block header.
type PartialTcCreated ¶ added in v0.29.0
type PartialTcCreated struct { View uint64 NewestQC *flow.QuorumCertificate LastViewTC *flow.TimeoutCertificate }
PartialTcCreated represents a notification emitted by the TimeoutProcessor component, whenever it has collected TimeoutObjects from a superminority of consensus participants for a specific view. Along with the view, it reports the newest QC and TC (for previous view) discovered during timeout collection. Per convention, the newest QC is never nil, while the TC for the previous view might be nil.
type ParticipantConsumer ¶ added in v0.31.0
type ParticipantConsumer interface { // OnEventProcessed notifications are produced by the EventHandler when it is done processing // and hands control back to the EventLoop to wait for the next event. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnEventProcessed() // OnStart notifications are produced by the EventHandler when it starts blocks recovery and // prepares for handling incoming events from EventLoop. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnStart(currentView uint64) // OnReceiveProposal notifications are produced by the EventHandler when it starts processing a block. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnReceiveProposal(currentView uint64, proposal *model.Proposal) // OnReceiveQc notifications are produced by the EventHandler when it starts processing a // QuorumCertificate [QC] constructed by the node's internal vote aggregator. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnReceiveQc(currentView uint64, qc *flow.QuorumCertificate) // OnReceiveTc notifications are produced by the EventHandler when it starts processing a // TimeoutCertificate [TC] constructed by the node's internal timeout aggregator. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnReceiveTc(currentView uint64, tc *flow.TimeoutCertificate) // OnPartialTc notifications are produced by the EventHandler when it starts processing partial TC // constructed by local timeout aggregator. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnPartialTc(currentView uint64, partialTc *PartialTcCreated) // OnLocalTimeout notifications are produced by the EventHandler when it reacts to expiry of round duration timer. // Such a notification indicates that the PaceMaker's timeout was processed by the system. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnLocalTimeout(currentView uint64) // OnViewChange notifications are produced by PaceMaker when it transitions to a new view // based on processing a QC or TC. The arguments specify the oldView (first argument), // and the newView to which the PaceMaker transitioned (second argument). // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnViewChange(oldView, newView uint64) // OnQcTriggeredViewChange notifications are produced by PaceMaker when it moves to a new view // based on processing a QC. The arguments specify the qc (first argument), which triggered // the view change, and the newView to which the PaceMaker transitioned (second argument). // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnQcTriggeredViewChange(oldView uint64, newView uint64, qc *flow.QuorumCertificate) // OnTcTriggeredViewChange notifications are produced by PaceMaker when it moves to a new view // based on processing a TC. The arguments specify the tc (first argument), which triggered // the view change, and the newView to which the PaceMaker transitioned (second argument). // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnTcTriggeredViewChange(oldView uint64, newView uint64, tc *flow.TimeoutCertificate) // OnStartingTimeout notifications are produced by PaceMaker. Such a notification indicates that the // PaceMaker is now waiting for the system to (receive and) process blocks or votes. // The specific timeout type is contained in the TimerInfo. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnStartingTimeout(model.TimerInfo) // OnCurrentViewDetails notifications are produced by the EventHandler during the course of a view with auxiliary information. // These notifications are generally not produced for all views (for example skipped views). // These notifications are guaranteed to be produced for all views we enter after fully processing a message. // Example 1: // - We are in view 8. We process a QC with view 10, causing us to enter view 11. // - Then this notification will be produced for view 11. // Example 2: // - We are in view 8. We process a proposal with view 10, which contains a TC for view 9 and TC.NewestQC for view 8. // - The QC would allow us to enter view 9 and the TC would allow us to enter view 10, // so after fully processing the message we are in view 10. // - Then this notification will be produced for view 10, but not view 9 // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnCurrentViewDetails(currentView, finalizedView uint64, currentLeader flow.Identifier) }
ParticipantConsumer consumes outbound notifications produced by consensus participants actively proposing blocks, voting, collecting & aggregating votes to QCs, and participating in the pacemaker (sending timeouts, collecting & aggregating timeouts to TCs). Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type Persister ¶
type Persister interface { // GetSafetyData will retrieve last persisted safety data. // During normal operations, no errors are expected. GetSafetyData() (*SafetyData, error) // PutSafetyData persists the last safety data. // This method blocks until `safetyData` was successfully persisted. // During normal operations, no errors are expected. PutSafetyData(safetyData *SafetyData) error // GetLivenessData will retrieve last persisted liveness data. // During normal operations, no errors are expected. GetLivenessData() (*LivenessData, error) // PutLivenessData persists the last liveness data. // This method blocks until `safetyData` was successfully persisted. // During normal operations, no errors are expected. PutLivenessData(livenessData *LivenessData) error }
Persister is responsible for persisting state we need to bootstrap after a restart or crash.
type ProposalDurationProvider ¶ added in v0.31.0
type ProposalDurationProvider interface { // TargetPublicationTime is intended to be called by the EventHandler, whenever it // wants to publish a new proposal. The event handler inputs // - proposalView: the view it is proposing for, // - timeViewEntered: the time when the EventHandler entered this view // - parentBlockId: the ID of the parent block, which the EventHandler is building on // TargetPublicationTime returns the time stamp when the new proposal should be broadcasted. // For a given view where we are the primary, suppose the actual time we are done building our proposal is P: // - if P < TargetPublicationTime(..), then the EventHandler should wait until // `TargetPublicationTime` to broadcast the proposal // - if P >= TargetPublicationTime(..), then the EventHandler should immediately broadcast the proposal // // Note: Technically, our metrics capture the publication delay relative to this function's _latest_ call. // Currently, the EventHandler is the only caller of this function, and only calls it once. // // Concurrency safe. TargetPublicationTime(proposalView uint64, timeViewEntered time.Time, parentBlockId flow.Identifier) time.Time }
ProposalDurationProvider generates the target publication time for block proposals.
type ProposalViolationConsumer ¶ added in v0.31.0
type ProposalViolationConsumer interface { // OnInvalidBlockDetected notifications are produced by components that have detected // that a block proposal is invalid and need to report it. // Most of the time such block can be detected by calling Validator.ValidateProposal. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnInvalidBlockDetected(err flow.Slashable[model.InvalidProposalError]) // OnDoubleProposeDetected notifications are produced by the Finalization Logic // whenever a double block proposal (equivocation) was detected. // Equivocation occurs when the same leader proposes two different blocks for the same view. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnDoubleProposeDetected(*model.Block, *model.Block) }
ProposalViolationConsumer consumes outbound notifications about HotStuff-protocol violations. Such notifications are produced by the active consensus participants and consensus follower.
Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type RandomBeaconInspector ¶ added in v0.23.9
type RandomBeaconInspector interface { // Verify verifies the signature share under the signer's public key and the message agreed upon. // The function is thread-safe and wait-free (i.e. allowing arbitrary many routines to // execute the business logic, without interfering with each other). // It allows concurrent verification of the given signature. // Returns : // - model.InvalidSignerError if signerIndex is invalid // - model.ErrInvalidSignature if signerIndex is valid but signature is cryptographically invalid // - other error if there is an unexpected exception. Verify(signerIndex int, share crypto.Signature) error // TrustedAdd adds a share to the internal signature shares store. // There is no pre-check of the signature's validity _before_ adding it. // It is the caller's responsibility to make sure the signature was previously verified. // Nevertheless, the implementation guarantees safety (only correct threshold signatures // are returned) through a post-check (verifying the threshold signature // _after_ reconstruction before returning it). // The function is thread-safe but locks its internal state, thereby permitting only // one routine at a time to add a signature. // Returns: // - (true, nil) if the signature has been added, and enough shares have been collected. // - (false, nil) if the signature has been added, but not enough shares were collected. // - (false, error) if there is any exception adding the signature share. // - model.InvalidSignerError if signerIndex is invalid (out of the valid range) // - model.DuplicatedSignerError if the signer has been already added // - other error if there is an unexpected exception. TrustedAdd(signerIndex int, share crypto.Signature) (enoughshares bool, exception error) // a group signature. The function is thread-safe. EnoughShares() bool // Reconstruct reconstructs the group signature. The function is thread-safe but locks // its internal state, thereby permitting only one routine at a time. // // Returns: // - (signature, nil) if no error occurred // - (nil, model.InsufficientSignaturesError) if not enough shares were collected // - (nil, model.InvalidSignatureIncluded) if at least one collected share does not serialize to a valid BLS signature, // or if the constructed signature failed to verify against the group public key and stored message. This post-verification // is required for safety, as `TrustedAdd` allows adding invalid signatures. // - (nil, error) for any other unexpected error. Reconstruct() (crypto.Signature, error) }
RandomBeaconInspector encapsulates all methods needed by a Hotstuff leader to validate the beacon votes and reconstruct a beacon signature. The random beacon methods are based on a threshold signature scheme.
type RandomBeaconReconstructor ¶ added in v0.23.9
type RandomBeaconReconstructor interface { // Verify verifies the signature share under the signer's public key and the message agreed upon. // The function is thread-safe and wait-free (i.e. allowing arbitrary many routines to // execute the business logic, without interfering with each other). // It allows concurrent verification of the given signature. // Returns : // - model.InvalidSignerError if signerIndex is invalid // - model.ErrInvalidSignature if signerID is valid but signature is cryptographically invalid // - other error if there is an unexpected exception. Verify(signerID flow.Identifier, sig crypto.Signature) error // TrustedAdd adds a share to the internal signature shares store. // There is no pre-check of the signature's validity _before_ adding it. // It is the caller's responsibility to make sure the signature was previously verified. // Nevertheless, the implementation guarantees safety (only correct threshold signatures // are returned) through a post-check (verifying the threshold signature // _after_ reconstruction before returning it). // The function is thread-safe but locks its internal state, thereby permitting only // one routine at a time to add a signature. // Returns: // - (true, nil) if the signature has been added, and enough shares have been collected. // - (false, nil) if the signature has been added, but not enough shares were collected. // - (false, error) if there is any exception adding the signature share. // - model.InvalidSignerError if signerIndex is invalid (out of the valid range) // - model.DuplicatedSignerError if the signer has been already added // - other error if there is an unexpected exception. TrustedAdd(signerID flow.Identifier, sig crypto.Signature) (EnoughShares bool, err error) // a group signature. The function is thread-safe. EnoughShares() bool // Reconstruct reconstructs the group signature. The function is thread-safe but locks // its internal state, thereby permitting only one routine at a time. // // Returns: // - (signature, nil) if no error occurred // - (nil, model.InsufficientSignaturesError) if not enough shares were collected // - (nil, model.InvalidSignatureIncluded) if at least one collected share does not serialize to a valid BLS signature, // or if the constructed signature failed to verify against the group public key and stored message. This post-verification // is required for safety, as `TrustedAdd` allows adding invalid signatures. // - (nil, error) for any other unexpected error. Reconstruct() (crypto.Signature, error) }
RandomBeaconReconstructor encapsulates all methods needed by a Hotstuff leader to validate the beacon votes and reconstruct a beacon signature. The random beacon methods are based on a threshold signature scheme.
type Replicas ¶ added in v0.29.0
type Replicas interface { // LeaderForView returns the identity of the leader for a given view. // CAUTION: per liveness requirement of HotStuff, the leader must be fork-independent. // Therefore, a node retains its proposer view slots even if it is slashed. // Its proposal is simply considered invalid, as it is not from a legitimate participant. // Returns the following expected errors for invalid inputs: // - model.ErrViewForUnknownEpoch if no epoch containing the given view is known LeaderForView(view uint64) (flow.Identifier, error) // QuorumThresholdForView returns the minimum total weight for a supermajority // at the given view. This weight threshold is computed using the total weight // of the initial committee and is static over the course of an epoch. // Returns the following expected errors for invalid inputs: // - model.ErrViewForUnknownEpoch if no epoch containing the given view is known QuorumThresholdForView(view uint64) (uint64, error) // TimeoutThresholdForView returns the minimum total weight of observed timeout objects // required to safely timeout for the given view. This weight threshold is computed // using the total weight of the initial committee and is static over the course of // an epoch. // Returns the following expected errors for invalid inputs: // - model.ErrViewForUnknownEpoch if no epoch containing the given view is known TimeoutThresholdForView(view uint64) (uint64, error) // Self returns our own node identifier. // TODO: ultimately, the own identity of the node is necessary for signing. // Ideally, we would move the method for checking whether an Identifier refers to this node to the signer. // This would require some refactoring of EventHandler (postponed to later) Self() flow.Identifier // DKG returns the DKG info for epoch given by the input view. // Returns the following expected errors for invalid inputs: // - model.ErrViewForUnknownEpoch if no epoch containing the given view is known DKG(view uint64) (DKG, error) // IdentitiesByEpoch returns a list of the legitimate HotStuff participants for the epoch // given by the input view. // The returned list of HotStuff participants: // - contains nodes that are allowed to submit votes or timeouts within the given epoch // (un-ejected, non-zero weight at the beginning of the epoch) // - is ordered in the canonical order // - contains no duplicates. // // CAUTION: DO NOT use this method for validating block proposals. // CAUTION: This method considers epochs outside of Previous, Current, Next, w.r.t. the // finalized block, to be unknown. https://github.com/onflow/flow-go/issues/4085 // // Returns the following expected errors for invalid inputs: // - model.ErrViewForUnknownEpoch if no epoch containing the given view is known // IdentitiesByEpoch(view uint64) (flow.IdentitySkeletonList, error) // IdentityByEpoch returns the full Identity for specified HotStuff participant. // The node must be a legitimate HotStuff participant with NON-ZERO WEIGHT at the specified block. // CAUTION: This method considers epochs outside of Previous, Current, Next, w.r.t. the // finalized block, to be unknown. https://github.com/onflow/flow-go/issues/4085 // // ERROR conditions: // - model.InvalidSignerError if participantID does NOT correspond to an authorized HotStuff participant at the specified block. // // Returns the following expected errors for invalid inputs: // - model.ErrViewForUnknownEpoch if no epoch containing the given view is known // IdentityByEpoch(view uint64, participantID flow.Identifier) (*flow.IdentitySkeleton, error) }
Replicas defines the consensus committee for the purposes of validating votes, timeouts, quorum certificates, and timeout certificates. Any consensus committee member who was authorized to contribute to consensus AT THE BEGINNING of the epoch may produce valid votes and timeouts for the entire epoch, even if they are later ejected. So for validating votes/timeouts we use *ByEpoch methods.
Since the voter committee is considered static over an epoch:
- we can query identities by view
- we don't need the full block ancestry prior to validating messages
type SafetyData ¶ added in v0.29.0
type SafetyData struct { // LockedOneChainView is the head block's view of the newest 1-chain this replica has voted for. // The 1-chain can be indirect. // <·· <QC>[B0] <- <QC_B0>[B1] <- [my vote for B1] // In the depicted scenario, the replica voted for block B1, which forms a (potentially indirect) // 1-chain on top of B0. The replica updated LockedOneChainView to the max of the current value and // QC_B0.View = B0.View. Thereby, the safety module guarantees that the replica will not sign // a TimeoutObject that would allow a malicious leader to fork below the latest finalized block. LockedOneChainView uint64 // HighestAcknowledgedView is the highest view where we have voted or triggered a timeout HighestAcknowledgedView uint64 // LastTimeout is the last timeout that was produced by this node (may be nil if no timeout occurred yet) LastTimeout *model.TimeoutObject }
type SafetyRules ¶ added in v0.29.0
type SafetyRules interface { // ProduceVote takes a block proposal and current view, and decides whether to vote for the block. // Voting is deterministic meaning voting for same proposal will always result in the same vote. // Returns: // * (vote, nil): On the _first_ block for the current view that is safe to vote for. // Subsequently, voter does _not_ vote for any _other_ block with the same (or lower) view. // SafetyRules internally caches and persists its latest vote. As long as the SafetyRules' internal // state remains unchanged, ProduceVote will return its cached for identical inputs. // * (nil, model.NoVoteError): If the safety module decides that it is not safe to vote for the given block. // This is a sentinel error and _expected_ during normal operation. // All other errors are unexpected and potential symptoms of uncovered edge cases or corrupted internal state (fatal). ProduceVote(proposal *model.Proposal, curView uint64) (*model.Vote, error) // ProduceTimeout takes current view, highest locally known QC and TC (optional, must be nil if and // only if QC is for previous view) and decides whether to produce timeout for current view. // Returns: // * (timeout, nil): It is safe to timeout for current view using newestQC and lastViewTC. // * (nil, model.NoTimeoutError): If replica is not part of the authorized consensus committee (anymore) and // therefore is not authorized to produce a valid timeout object. This sentinel error is _expected_ during // normal operation, e.g. during the grace-period after Epoch switchover or after the replica self-ejected. // All other errors are unexpected and potential symptoms of uncovered edge cases or corrupted internal state (fatal). ProduceTimeout(curView uint64, newestQC *flow.QuorumCertificate, lastViewTC *flow.TimeoutCertificate) (*model.TimeoutObject, error) }
SafetyRules enforces all consensus rules that guarantee safety. It produces votes for the given blocks or TimeoutObject for the given views, only if all safety rules are satisfied. In particular, SafetyRules guarantees a foundational security theorem for HotStuff (incl. the DiemBFT / Jolteon variant), which we utilize also outside of consensus (e.g. queuing pending blocks for execution, verification, sealing etc):
THEOREM: For each view, there can be at most 1 certified block.
Implementations are generally *not* concurrency safe.
type Signer ¶
type Signer interface { // CreateProposal creates a proposal for the given block. No error returns // are expected during normal operations (incl. presence of byz. actors). CreateProposal(block *model.Block) (*model.Proposal, error) // CreateVote creates a vote for the given block. No error returns are // expected during normal operations (incl. presence of byz. actors). CreateVote(block *model.Block) (*model.Vote, error) // CreateTimeout creates a timeout for given view. No errors return are // expected during normal operations(incl presence of byz. actors). CreateTimeout(curView uint64, newestQC *flow.QuorumCertificate, lastViewTC *flow.TimeoutCertificate) (*model.TimeoutObject, error) }
Signer is responsible for creating votes, proposals for a given block.
type TimeoutAggregationConsumer ¶ added in v0.31.0
type TimeoutAggregationConsumer interface { TimeoutAggregationViolationConsumer TimeoutCollectorConsumer }
TimeoutAggregationConsumer consumes outbound notifications produced by Vote Aggregation logic. It is a subset of the notifications produced by consensus participants. Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type TimeoutAggregationViolationConsumer ¶ added in v0.31.0
type TimeoutAggregationViolationConsumer interface { // OnDoubleTimeoutDetected notifications are produced by the Timeout Aggregation logic // whenever a double timeout (same replica producing two different timeouts at the same view) was detected. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnDoubleTimeoutDetected(*model.TimeoutObject, *model.TimeoutObject) // OnInvalidTimeoutDetected notifications are produced by the Timeout Aggregation logic // whenever an invalid timeout was detected. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnInvalidTimeoutDetected(err model.InvalidTimeoutError) }
TimeoutAggregationViolationConsumer consumes outbound notifications about Active Pacemaker violations specifically invalid timeouts during processing. Such notifications are produced by the Timeout Aggregation logic.
Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type TimeoutAggregator ¶ added in v0.29.0
type TimeoutAggregator interface { module.ReadyDoneAware module.Startable // AddTimeout verifies and aggregates a timeout object. // This method can be called concurrently, timeouts will be queued and processed asynchronously. AddTimeout(timeoutObject *model.TimeoutObject) // PruneUpToView deletes all `TimeoutCollector`s _below_ to the given view, as well as // related indices. We only retain and process `TimeoutCollector`s, whose view is equal or larger // than `lowestRetainedView`. If `lowestRetainedView` is smaller than the // previous value, the previous value is kept and the method call is a NoOp. // This value should be set to the latest active view maintained by `Pacemaker`. PruneUpToView(lowestRetainedView uint64) }
TimeoutAggregator verifies and aggregates timeout objects to build timeout certificates [TCs]. When enough timeout objects are collected, it builds a TC and sends it to the EventLoop TimeoutAggregator also detects protocol violation, including invalid timeouts, double timeout, etc and notifies a HotStuff consumer for slashing.
type TimeoutCollector ¶ added in v0.29.0
type TimeoutCollector interface { // AddTimeout adds a Timeout Object [TO] to the collector. // When TOs from strictly more than 1/3 of consensus participants (measured by weight) // were collected, the callback for partial TC will be triggered. // After collecting TOs from a supermajority, a TC will be created and passed to the EventLoop. // Expected error returns during normal operations: // * timeoutcollector.ErrTimeoutForIncompatibleView - submitted timeout for incompatible view // All other exceptions are symptoms of potential state corruption. AddTimeout(timeoutObject *model.TimeoutObject) error // View returns the view that this instance is collecting timeouts for. // This method is useful when adding the newly created timeout collector to timeout collectors map. View() uint64 }
TimeoutCollector collects all timeout objects for a specified view. On the happy path, it generates a TimeoutCertificate when enough timeouts have been collected. The TimeoutCollector is a higher-level structure that orchestrates deduplication, caching and processing of timeouts, delegating those tasks to underlying modules (such as TimeoutProcessor). Implementations of TimeoutCollector must be concurrency safe.
type TimeoutCollectorConsumer ¶ added in v0.29.0
type TimeoutCollectorConsumer interface { // OnTcConstructedFromTimeouts notifications are produced by the TimeoutProcessor // component, whenever it constructs a TC based on TimeoutObjects from a // supermajority of consensus participants. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnTcConstructedFromTimeouts(certificate *flow.TimeoutCertificate) // OnPartialTcCreated notifications are produced by the TimeoutProcessor // component, whenever it collected TimeoutObjects from a superminority // of consensus participants for a specific view. Along with the view, it // reports the newest QC and TC (for previous view) discovered in process of // timeout collection. Per convention, the newest QC is never nil, while // the TC for the previous view might be nil. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnPartialTcCreated(view uint64, newestQC *flow.QuorumCertificate, lastViewTC *flow.TimeoutCertificate) // OnNewQcDiscovered notifications are produced by the TimeoutCollector // component, whenever it discovers new QC included in timeout object. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnNewQcDiscovered(certificate *flow.QuorumCertificate) // OnNewTcDiscovered notifications are produced by the TimeoutCollector // component, whenever it discovers new TC included in timeout object. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnNewTcDiscovered(certificate *flow.TimeoutCertificate) // OnTimeoutProcessed notifications are produced by the Timeout Aggregation logic, // each time we successfully ingest a valid timeout. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnTimeoutProcessed(timeout *model.TimeoutObject) }
TimeoutCollectorConsumer consumes outbound notifications produced by HotStuff's timeout aggregation component. These events are primarily intended for the HotStuff-internal state machine (EventHandler), but might also be relevant to the larger node in which HotStuff is running.
Caution: the events are not strictly ordered by increasing views! The notifications are emitted by concurrent processing logic. Over larger time scales, the emitted events are for statistically increasing views. However, on short time scales there are _no_ monotonicity guarantees w.r.t. the events' views.
Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type TimeoutCollectorFactory ¶ added in v0.29.0
type TimeoutCollectorFactory interface { // Create is a factory method to generate a TimeoutCollector for a given view // Expected error returns during normal operations: // * model.ErrViewForUnknownEpoch no epoch containing the given view is known // All other errors should be treated as exceptions. Create(view uint64) (TimeoutCollector, error) }
TimeoutCollectorFactory performs creation of TimeoutCollector for a given view
type TimeoutCollectors ¶ added in v0.29.0
type TimeoutCollectors interface { // GetOrCreateCollector retrieves the TimeoutCollector for the specified // view or creates one if none exists. When creating a timeout collector, // the view is used to query the consensus committee for the respective // Epoch the view belongs to. // It returns: // - (collector, true, nil) if no collector can be found by the view, and a new collector was created. // - (collector, false, nil) if the collector can be found by the view. // - (nil, false, error) if running into any exception creating the timeout collector. // Expected error returns during normal operations: // * mempool.BelowPrunedThresholdError if view is below the pruning threshold // * model.ErrViewForUnknownEpoch if view is not yet pruned but no epoch containing the given view is known GetOrCreateCollector(view uint64) (collector TimeoutCollector, created bool, err error) // PruneUpToView prunes the timeout collectors with views _below_ the given value, i.e. // we only retain and process timeout collectors, whose views are equal or larger than `lowestRetainedView`. // If `lowestRetainedView` is smaller than the previous value, the previous value is // kept and the method call is a NoOp. PruneUpToView(lowestRetainedView uint64) }
TimeoutCollectors encapsulates the functionality to generate, store and prune `TimeoutCollector` instances (one per view). Its main purpose is to provide a higher-level API to `TimeoutAggregator` for managing and interacting with the view-specific `TimeoutCollector` instances. Implementations are concurrency safe.
type TimeoutProcessor ¶ added in v0.29.0
type TimeoutProcessor interface { // Process performs processing of single timeout object. This function is safe to call from multiple goroutines. // Expected error returns during normal operations: // * timeoutcollector.ErrTimeoutForIncompatibleView - submitted timeout for incompatible view // * model.InvalidTimeoutError - submitted invalid timeout(invalid structure or invalid signature) // * model.DuplicatedSignerError if a timeout from the same signer was previously already added // It does _not necessarily_ imply that the timeout is invalid or the sender is equivocating. // All other errors should be treated as exceptions. Process(timeout *model.TimeoutObject) error }
TimeoutProcessor ingests Timeout Objects [TO] for a particular view. It implements the algorithms for validating TOs, orchestrates their low-level aggregation and emits `OnPartialTcCreated` and `OnTcConstructedFromTimeouts` notifications. TimeoutProcessor cannot deduplicate TOs (this should be handled by the higher-level TimeoutCollector) and errors instead. Depending on their implementation, a TimeoutProcessor might drop timeouts or attempt to construct a TC.
type TimeoutProcessorFactory ¶ added in v0.29.0
type TimeoutProcessorFactory interface { // Create is a factory method to generate a TimeoutProcessor for a given view // Expected error returns during normal operations: // * model.ErrViewForUnknownEpoch no epoch containing the given view is known // All other errors should be treated as exceptions. Create(view uint64) (TimeoutProcessor, error) }
TimeoutProcessorFactory performs creation of TimeoutProcessor for a given view
type TimeoutSignatureAggregator ¶ added in v0.29.0
type TimeoutSignatureAggregator interface { // VerifyAndAdd verifies the signature under the stored public keys and adds the signature and the corresponding // highest QC to the internal set. Internal set and collected weight is modified iff signature _is_ valid. // The total weight of all collected signatures (excluding duplicates) is returned regardless // of any returned error. // Expected errors during normal operations: // - model.InvalidSignerError if signerID is invalid (not a consensus participant) // - model.DuplicatedSignerError if the signer has been already added // - model.ErrInvalidSignature if signerID is valid but signature is cryptographically invalid VerifyAndAdd(signerID flow.Identifier, sig crypto.Signature, newestQCView uint64) (totalWeight uint64, exception error) // TotalWeight returns the total weight presented by the collected signatures. TotalWeight() uint64 // View returns the view that this instance is aggregating signatures for. View() uint64 // Aggregate aggregates the signatures and returns with additional data. // Aggregated signature will be returned as SigData of timeout certificate. // Caller can be sure that resulting signature is valid. // Expected errors during normal operations: // - model.InsufficientSignaturesError if no signatures have been added yet Aggregate() (signersInfo []TimeoutSignerInfo, aggregatedSig crypto.Signature, exception error) }
TimeoutSignatureAggregator aggregates timeout signatures for one particular view. When instantiating a TimeoutSignatureAggregator, the following information is supplied:
- The view for which the aggregator collects timeouts.
- For each replicas that is authorized to send a timeout at this particular view: the node ID, public staking keys, and weight
Timeouts for other views or from non-authorized replicas are rejected. In their TimeoutObjects, replicas include a signature over the pair (view, newestQCView), where `view` is the view number the timeout is for and `newestQCView` is the view of the newest QC known to the replica. TimeoutSignatureAggregator collects these signatures, internally tracks the total weight of all collected signatures. Note that in general the signed messages are different, which makes the aggregation a comparatively expensive operation. Upon calling `Aggregate`, the TimeoutSignatureAggregator aggregates all valid signatures collected up to this point. The aggregate signature is guaranteed to be correct, as only valid signatures are excepted as inputs. TimeoutSignatureAggregator internally tracks the total weight of all collected signatures. Implementations must be concurrency safe.
type TimeoutSignerInfo ¶ added in v0.29.0
type TimeoutSignerInfo struct { NewestQCView uint64 Signer flow.Identifier }
TimeoutSignerInfo is a helper structure that stores the QC views that each signer contributed to a TC. Used as result of TimeoutSignatureAggregator.Aggregate()
type Validator ¶
type Validator interface { // ValidateQC checks the validity of a QC. // During normal operations, the following error returns are expected: // * model.InvalidQCError if the QC is invalid // * model.ErrViewForUnknownEpoch if the QC refers unknown epoch ValidateQC(qc *flow.QuorumCertificate) error // ValidateTC checks the validity of a TC. // During normal operations, the following error returns are expected: // * model.InvalidTCError if the TC is invalid // * model.ErrViewForUnknownEpoch if the TC refers unknown epoch ValidateTC(tc *flow.TimeoutCertificate) error // ValidateProposal checks the validity of a proposal. // During normal operations, the following error returns are expected: // * model.InvalidProposalError if the block is invalid // * model.ErrViewForUnknownEpoch if the proposal refers unknown epoch ValidateProposal(proposal *model.Proposal) error // ValidateVote checks the validity of a vote. // Returns the full entity for the voter. During normal operations, // the following errors are expected: // * model.InvalidVoteError for invalid votes // * model.ErrViewForUnknownEpoch if the vote refers unknown epoch ValidateVote(vote *model.Vote) (*flow.IdentitySkeleton, error) }
Validator provides functions to validate QC, proposals and votes.
type Verifier ¶
type Verifier interface { // VerifyVote checks the cryptographic validity of a vote's `SigData` w.r.t. // the view and blockID. It is the responsibility of the calling code to ensure // that `voter` is authorized to vote. // Return values: // * nil if `sigData` is cryptographically valid // * model.InvalidFormatError if the signature has an incompatible format. // * model.ErrInvalidSignature is the signature is invalid // * model.InvalidSignerError is only relevant for extended signature schemes, // where special signing authority is only given to a _subset_ of consensus // participants (e.g. random beacon). In case a participant signed despite not // being authorized, an InvalidSignerError is returned. // * model.ErrViewForUnknownEpoch is only relevant for extended signature schemes, // where querying of DKG might fail if no epoch containing the given view is known. // * unexpected errors should be treated as symptoms of bugs or uncovered // edge cases in the logic (i.e. as fatal) VerifyVote(voter *flow.IdentitySkeleton, sigData []byte, view uint64, blockID flow.Identifier) error // VerifyQC checks the cryptographic validity of a QC's `SigData` w.r.t. the // given view and blockID. It is the responsibility of the calling code to ensure that // all `signers` are authorized, without duplicates. // Return values: // * nil if `sigData` is cryptographically valid // * model.InvalidFormatError if `sigData` has an incompatible format // * model.InsufficientSignaturesError if `signers is empty. // Depending on the order of checks in the higher-level logic this error might // be an indicator of a external byzantine input or an internal bug. // * model.ErrInvalidSignature if a signature is invalid // * model.InvalidSignerError is only relevant for extended signature schemes, // where special signing authority is only given to a _subset_ of consensus // participants (e.g. random beacon). In case a participant signed despite not // being authorized, an InvalidSignerError is returned. // * model.ErrViewForUnknownEpoch is only relevant for extended signature schemes, // where querying of DKG might fail if no epoch containing the given view is known. // * unexpected errors should be treated as symptoms of bugs or uncovered // edge cases in the logic (i.e. as fatal) VerifyQC(signers flow.IdentitySkeletonList, sigData []byte, view uint64, blockID flow.Identifier) error // VerifyTC checks cryptographic validity of the TC's `sigData` w.r.t. the // given view. It is the responsibility of the calling code to ensure // that all `signers` are authorized, without duplicates. Return values: // * nil if `sigData` is cryptographically valid // * model.InsufficientSignaturesError if `signers is empty. // * model.InvalidFormatError if `signers`/`highQCViews` have differing lengths // * model.ErrInvalidSignature if a signature is invalid // * unexpected errors should be treated as symptoms of bugs or uncovered // edge cases in the logic (i.e. as fatal) VerifyTC(signers flow.IdentitySkeletonList, sigData []byte, view uint64, highQCViews []uint64) error }
Verifier is the component responsible for the cryptographic integrity of votes, proposals and QC's against the block they are signing. Overall, there are two criteria for the validity of a vote and QC:
(1) the signer ID(s) must correspond to authorized consensus participants (2) the signature must be cryptographically valid.
Note that Verifier only implements (2). This API design allows to decouple
(i) the common logic for checking that a super-majority of the consensus committee voted (ii) the handling of combined staking+RandomBeacon votes (consensus nodes) vs only staking votes (collector nodes)
On the one hand, this API design makes code less concise, as the two checks are now distributed over API boundaries. On the other hand, we can avoid repeated Identity lookups in the implementation, which increases performance.
type VerifyingVoteProcessor ¶ added in v0.23.9
type VerifyingVoteProcessor interface { VoteProcessor // Block returns which block that will be used to collector votes for. Transition to VerifyingVoteCollector can occur only // when we have received block proposal so this information has to be available. Block() *model.Block }
VerifyingVoteProcessor is a VoteProcessor that attempts to construct a QC for the given block.
type VoteAggregationConsumer ¶ added in v0.31.0
type VoteAggregationConsumer interface { VoteAggregationViolationConsumer VoteCollectorConsumer }
VoteAggregationConsumer consumes outbound notifications produced by Vote Aggregation logic. It is a subset of the notifications produced by consensus participants. Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type VoteAggregationViolationConsumer ¶ added in v0.31.0
type VoteAggregationViolationConsumer interface { // OnDoubleVotingDetected notifications are produced by the Vote Aggregation logic // whenever a double voting (same voter voting for different blocks at the same view) was detected. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnDoubleVotingDetected(*model.Vote, *model.Vote) // OnInvalidVoteDetected notifications are produced by the Vote Aggregation logic // whenever an invalid vote was detected. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnInvalidVoteDetected(err model.InvalidVoteError) // OnVoteForInvalidBlockDetected notifications are produced by the Vote Aggregation logic // whenever vote for invalid proposal was detected. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnVoteForInvalidBlockDetected(vote *model.Vote, invalidProposal *model.Proposal) }
VoteAggregationViolationConsumer consumes outbound notifications about HotStuff-protocol violations specifically invalid votes during processing. Such notifications are produced by the Vote Aggregation logic.
Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type VoteAggregator ¶
type VoteAggregator interface { module.ReadyDoneAware module.Startable // AddVote verifies and aggregates a vote. // The voting block could either be known or unknown. // If the voting block is unknown, the vote won't be processed until AddBlock is called with the block. // This method can be called concurrently, votes will be queued and processed asynchronously. AddVote(vote *model.Vote) // AddBlock notifies the VoteAggregator that it should start processing votes for the given block. // The input block is queued internally within the `VoteAggregator` and processed _asynchronously_ // by the VoteAggregator's internal worker routines. // CAUTION: we expect that the input block's validity has been confirmed prior to calling AddBlock, // including the proposer's signature. Otherwise, VoteAggregator might crash or exhibit undefined // behaviour. AddBlock(block *model.Proposal) // InvalidBlock notifies the VoteAggregator about an invalid proposal, so that it // can process votes for the invalid block and slash the voters. // No errors are expected during normal operations InvalidBlock(block *model.Proposal) error // PruneUpToView deletes all votes _below_ to the given view, as well as // related indices. We only retain and process whose view is equal or larger // than `lowestRetainedView`. If `lowestRetainedView` is smaller than the // previous value, the previous value is kept and the method call is a NoOp. PruneUpToView(view uint64) }
VoteAggregator verifies and aggregates votes to build QC. When enough votes have been collected, it builds a QC and send it to the EventLoop VoteAggregator also detects protocol violation, including invalid votes, double voting etc, and notifies a HotStuff consumer for slashing.
type VoteCollector ¶ added in v0.23.9
type VoteCollector interface { // ProcessBlock performs validation of block signature and processes block with respected collector. // Calling this function will mark conflicting collector as stale and change state of valid collectors // It returns nil if the block is valid. // It returns model.InvalidProposalError if block is invalid. // It returns other error if there is exception processing the block. ProcessBlock(block *model.Proposal) error // AddVote adds a vote to the collector // When enough votes have been added to produce a QC, the QC will be created asynchronously, and // passed to EventLoop through a callback. // No errors are expected during normal operations. AddVote(vote *model.Vote) error // RegisterVoteConsumer registers a VoteConsumer. Upon registration, the collector // feeds all cached votes into the consumer in the order they arrived. // CAUTION, VoteConsumer implementations must be // * NON-BLOCKING and consume the votes without noteworthy delay, and // * CONCURRENCY SAFE RegisterVoteConsumer(consumer VoteConsumer) // View returns the view that this instance is collecting votes for. // This method is useful when adding the newly created vote collector to vote collectors map. View() uint64 // Status returns the status of the vote collector Status() VoteCollectorStatus }
VoteCollector collects all votes for a specified view. On the happy path, it generates a QC when enough votes have been collected. The VoteCollector internally delegates the vote-format specific processing to the VoteProcessor.
type VoteCollectorConsumer ¶ added in v0.31.0
type VoteCollectorConsumer interface { // OnQcConstructedFromVotes notifications are produced by the VoteAggregator // component, whenever it constructs a QC from votes. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnQcConstructedFromVotes(*flow.QuorumCertificate) // OnVoteProcessed notifications are produced by the Vote Aggregation logic, each time // we successfully ingest a valid vote. // Prerequisites: // Implementation must be concurrency safe; Non-blocking; // and must handle repetition of the same events (with some processing overhead). OnVoteProcessed(vote *model.Vote) }
VoteCollectorConsumer consumes outbound notifications produced by HotStuff's vote aggregation component. These events are primarily intended for the HotStuff-internal state machine (EventHandler), but might also be relevant to the larger node in which HotStuff is running.
Implementations must:
- be concurrency safe
- be non-blocking
- handle repetition of the same events (with some processing overhead).
type VoteCollectorStatus ¶ added in v0.23.9
type VoteCollectorStatus int
VoteCollectorStatus indicates the VoteCollector's status It has three different status.
const ( // VoteCollectorStatusCaching is for the status when the block has not been received. // The vote collector in this status will cache all the votes without verifying them VoteCollectorStatusCaching VoteCollectorStatus = iota // VoteCollectorStatusVerifying is for the status when the block has been received, // and is able to process all votes for it. VoteCollectorStatusVerifying // VoteCollectorStatusInvalid is for the status when the block has been verified and // is invalid. All votes to this block will be collected to slash the voter. VoteCollectorStatusInvalid )
func (VoteCollectorStatus) String ¶ added in v0.23.9
func (ps VoteCollectorStatus) String() string
type VoteCollectors ¶ added in v0.23.9
type VoteCollectors interface { module.ReadyDoneAware module.Startable // GetOrCreateCollector retrieves the hotstuff.VoteCollector for the specified // view or creates one if none exists. // When creating a vote collector, the view will be used to get epoch by view, then create the random beacon // signer object by epoch, because epoch determines DKG, which determines random beacon committee. // It returns: // - (collector, true, nil) if no collector can be found by the view, and a new collector was created. // - (collector, false, nil) if the collector can be found by the view // - (nil, false, error) if running into any exception creating the vote collector state machine // Expected error returns during normal operations: // * mempool.BelowPrunedThresholdError - in case view is lower than last pruned view GetOrCreateCollector(view uint64) (collector VoteCollector, created bool, err error) // PruneUpToView prunes the vote collectors with views _below_ the given value, i.e. // we only retain and process whose view is equal or larger than `lowestRetainedView`. // If `lowestRetainedView` is smaller than the previous value, the previous value is // kept and the method call is a NoOp. PruneUpToView(lowestRetainedView uint64) }
VoteCollectors is an interface which allows VoteAggregator to interact with collectors structured by view. Implementations of this interface are responsible for state transitions of `VoteCollector`s and pruning of stale and outdated collectors by view.
type VoteConsumer ¶ added in v0.23.9
VoteConsumer consumes all votes for one specific view. It is registered with the `VoteCollector` for the respective view. Upon registration, the `VoteCollector` feeds votes into the consumer in the order they are received (already cached votes as well as votes received in the future). Only votes that pass de-duplication and equivocation detection are passed on. CAUTION, VoteConsumer implementations must be
- NON-BLOCKING and consume the votes without noteworthy delay, and
- CONCURRENCY SAFE
type VoteProcessor ¶ added in v0.23.9
type VoteProcessor interface { // Process performs processing of single vote. This function is safe to call from multiple goroutines. // Expected error returns during normal operations: // * VoteForIncompatibleBlockError - submitted vote for incompatible block // * VoteForIncompatibleViewError - submitted vote for incompatible view // * model.InvalidVoteError - submitted vote with invalid signature // * model.DuplicatedSignerError - vote from a signer whose vote was previously already processed // All other errors should be treated as exceptions. Process(vote *model.Vote) error // Status returns the status of the vote processor Status() VoteCollectorStatus }
VoteProcessor processes votes. It implements the vote-format specific processing logic. Depending on their implementation, a VoteProcessor might drop votes or attempt to construct a QC.
type VoteProcessorFactory ¶ added in v0.23.9
type VoteProcessorFactory interface { // Create instantiates a VerifyingVoteProcessor for processing votes for a specific proposal. // Caller can be sure that proposal vote was successfully verified and processed. // Expected error returns during normal operations: // * model.InvalidProposalError - proposal has invalid proposer vote Create(log zerolog.Logger, proposal *model.Proposal) (VerifyingVoteProcessor, error) }
VoteProcessorFactory is a factory that can be used to create a verifying vote processors for a specific proposal. Depending on factory implementation it will return processors for consensus or collection clusters
type WeightedSignatureAggregator ¶ added in v0.23.9
type WeightedSignatureAggregator interface { // Verify verifies the signature under the stored public keys and message. // Expected errors during normal operations: // - model.InvalidSignerError if signerID is invalid (not a consensus participant) // - model.ErrInvalidSignature if signerID is valid but signature is cryptographically invalid Verify(signerID flow.Identifier, sig crypto.Signature) error // TrustedAdd adds a signature to the internal set of signatures and adds the signer's // weight to the total collected weight, iff the signature is _not_ a duplicate. The // total weight of all collected signatures (excluding duplicates) is returned regardless // of any returned error. // Expected errors during normal operations: // - model.InvalidSignerError if signerID is invalid (not a consensus participant) // - model.DuplicatedSignerError if the signer has been already added TrustedAdd(signerID flow.Identifier, sig crypto.Signature) (totalWeight uint64, exception error) // TotalWeight returns the total weight presented by the collected signatures. TotalWeight() uint64 // Aggregate aggregates the signatures and returns the aggregated signature. // The function performs a final verification and errors if the aggregated signature is invalid. This is // required for the function safety since `TrustedAdd` allows adding invalid signatures. // The function errors with: // - model.InsufficientSignaturesError if no signatures have been added yet // - model.InvalidSignatureIncludedError if: // -- some signature(s), included via TrustedAdd, fail to deserialize (regardless of the aggregated public key) // -- or all signatures deserialize correctly but some signature(s), included via TrustedAdd, are // invalid (while aggregated public key is valid) // - model.InvalidAggregatedKeyError if all signatures deserialize correctly but the signer's // staking public keys sum up to an invalid key (BLS identity public key). // Any aggregated signature would fail the cryptographic verification under the identity public // key and therefore such signature is considered invalid. Such scenario can only happen if // staking public keys of signers were forged to add up to the identity public key. // Under the assumption that all staking key PoPs are valid, this error case can only // happen if all signers are malicious and colluding. If there is at least one honest signer, // there is a negligible probability that the aggregated key is identity. // // The function is thread-safe. Aggregate() (flow.IdentifierList, []byte, error) }
WeightedSignatureAggregator aggregates signatures of the same signature scheme and the same message from different signers. The public keys and message are agreed upon upfront. It is also recommended to only aggregate signatures generated with keys representing equivalent security-bit level. Furthermore, a weight [unsigned int64] is assigned to each signer ID. The WeightedSignatureAggregator internally tracks the total weight of all collected signatures. Implementations must be concurrency safe.
type Workerpool ¶ added in v0.23.9
type Workerpool interface { Workers // StopWait stops the worker pool and waits for all queued tasks to // complete. No additional tasks may be submitted, but all pending tasks are // executed by workers before this function returns. StopWait() }
Workerpool adds the functionality to terminate the workers to the Workers interface.
type Workers ¶ added in v0.23.9
type Workers interface { // Submit enqueues a function for a worker to execute. Submit will not block // regardless of the number of tasks submitted. Each task is immediately // given to an available worker or queued otherwise. Tasks are processed in // FiFO order. Submit(task func()) }
Workers queues and processes submitted tasks. We explicitly do not expose any functionality to terminate the worker pool.
Source Files ¶
- block_producer.go
- committee.go
- consumer.go
- event_handler.go
- event_loop.go
- follower_loop.go
- forks.go
- pacemaker.go
- persister.go
- randombeacon_inspector.go
- safety_rules.go
- signature.go
- signer.go
- timeout_aggregator.go
- timeout_collector.go
- timeout_collectors.go
- validator.go
- verifier.go
- vote_aggregator.go
- vote_collector.go
- vote_collectors.go
Directories ¶
Path | Synopsis |
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Package cruisectl implements a "cruise control" system for Flow by adjusting nodes' latest ProposalTiming in response to changes in the measured view rate and target epoch switchover time.
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Package cruisectl implements a "cruise control" system for Flow by adjusting nodes' latest ProposalTiming in response to changes in the measured view rate and target epoch switchover time. |