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acs.go
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acs.go
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package hbbft
import (
"fmt"
)
// ACSMessage represents a message sent between nodes in the ACS protocol.
type ACSMessage struct {
// Unique identifier of the "proposing" node.
ProposerID uint64
// Actual payload beeing sent.
Payload interface{}
}
// ACS implements the Asynchronous Common Subset protocol.
// ACS assumes a network of N nodes that send signed messages to each other.
// There can be f faulty nodes where (3 * f < N).
// Each participating node proposes an element for inlcusion. The protocol
// guarantees that all of the good nodes output the same set, consisting of
// at least (N -f) of the proposed values.
//
// Algorithm:
// ACS creates a Broadcast algorithm for each of the participating nodes.
// At least (N -f) of these will eventually output the element proposed by that
// node. ACS will also create and BBA instance for each participating node, to
// decide whether that node's proposed element should be inlcuded in common set.
// Whenever an element is received via broadcast, we imput "true" into the
// corresponding BBA instance. When (N-f) BBA instances have decided true we
// input false into the remaining ones, where we haven't provided input yet.
// Once all BBA instances have decided, ACS returns the set of all proposed
// values for which the decision was truthy.
type ACS struct {
// Config holds the ACS configuration.
Config
// Mapping of node ids and their rbc instance.
rbcInstances map[uint64]*RBC
// Mapping of node ids and their bba instance.
bbaInstances map[uint64]*BBA
// Results of the Reliable Broadcast.
rbcResults map[uint64][]byte
// Results of the Binary Byzantine Agreement.
bbaResults map[uint64]bool
// Final output of the ACS.
output map[uint64][]byte
// Que of ACSMessages that need to be broadcasted after each received
// and processed a message.
messageQue *messageQue
// Whether this ACS instance has already has decided output or not.
decided bool
// control flow tuples for internal channel communication.
closeCh chan struct{}
inputCh chan acsInputTuple
messageCh chan acsMessageTuple
}
// Control flow structure for internal channel communication. Allowing us to
// avoid the use of mutexes and eliminates race conditions.
type (
acsMessageTuple struct {
senderID uint64
msg *ACSMessage
err chan error
}
acsInputResponse struct {
rbcMessages []*BroadcastMessage
acsMessages []*ACSMessage
err error
}
acsInputTuple struct {
value []byte
response chan acsInputResponse
}
)
// NewACS returns a new ACS instance configured with the given Config and node
// ids.
func NewACS(cfg Config) *ACS {
if cfg.F == 0 {
cfg.F = (cfg.N - 1) / 3
}
acs := &ACS{
Config: cfg,
rbcInstances: make(map[uint64]*RBC),
bbaInstances: make(map[uint64]*BBA),
rbcResults: make(map[uint64][]byte),
bbaResults: make(map[uint64]bool),
messageQue: newMessageQue(),
closeCh: make(chan struct{}),
inputCh: make(chan acsInputTuple),
messageCh: make(chan acsMessageTuple),
}
// Create all the instances for the participating nodes
for _, id := range cfg.Nodes {
acs.rbcInstances[id] = NewRBC(cfg, id)
acs.bbaInstances[id] = NewBBA(cfg)
}
go acs.run()
return acs
}
// InputValue sets the input value for broadcast and returns an initial set of
// Broadcast and ACS Messages to be broadcasted in the network.
func (a *ACS) InputValue(val []byte) error {
t := acsInputTuple{
value: val,
response: make(chan acsInputResponse),
}
a.inputCh <- t
resp := <-t.response
return resp.err
}
// HandleMessage handles incoming messages to ACS and redirects them to the
// appropriate sub(protocol) instance.
func (a *ACS) HandleMessage(senderID uint64, msg *ACSMessage) error {
t := acsMessageTuple{
senderID: senderID,
msg: msg,
err: make(chan error),
}
a.messageCh <- t
return <-t.err
}
// handleMessage handles incoming messages to ACS and redirects them to the
// appropriate sub(protocol) instance.
func (a *ACS) handleMessage(senderID uint64, msg *ACSMessage) error {
switch t := msg.Payload.(type) {
case *AgreementMessage:
return a.handleAgreement(senderID, msg.ProposerID, t)
case *BroadcastMessage:
return a.handleBroadcast(senderID, msg.ProposerID, t)
default:
return fmt.Errorf("received unknown message (%v)", t)
}
}
// Output will return the output of the ACS instance. If the output was not nil
// then it will return the output else nil. Note that after consuming the output
// its will be set to nil forever.
func (a *ACS) Output() map[uint64][]byte {
if a.output != nil {
out := a.output
a.output = nil
return out
}
return nil
}
// Done returns true whether ACS has completed its agreements and cleared its
// messageQue.
func (a *ACS) Done() bool {
agreementsDone := true
for _, bba := range a.bbaInstances {
if !bba.done {
agreementsDone = false
}
}
return agreementsDone && a.messageQue.len() == 0
}
// inputValue sets the input value for broadcast and returns an initial set of
// Broadcast and ACS Messages to be broadcasted in the network.
func (a *ACS) inputValue(data []byte) error {
rbc, ok := a.rbcInstances[a.ID]
if !ok {
return fmt.Errorf("could not find rbc instance (%d)", a.ID)
}
reqs, err := rbc.InputValue(data)
if err != nil {
return err
}
if len(reqs) != a.N-1 {
return fmt.Errorf("expecting (%d) proof messages got (%d)", a.N, len(reqs))
}
for i, id := range uint64sWithout(a.Nodes, a.ID) {
a.messageQue.addMessage(&ACSMessage{a.ID, reqs[i]}, id)
}
for _, msg := range rbc.Messages() {
a.addMessage(a.ID, msg)
}
if output := rbc.Output(); output != nil {
a.rbcResults[a.ID] = output
a.processAgreement(a.ID, func(bba *BBA) error {
if bba.AcceptInput() {
return bba.InputValue(true)
}
return nil
})
}
return nil
}
func (a *ACS) stop() {
close(a.closeCh)
}
func (a *ACS) run() {
for {
select {
case <-a.closeCh:
return
case t := <-a.inputCh:
err := a.inputValue(t.value)
t.response <- acsInputResponse{err: err}
case t := <-a.messageCh:
t.err <- a.handleMessage(t.senderID, t.msg)
}
}
}
// handleAgreement processes the received AgreementMessage from sender (sid)
// for a value proposed by the proposing node (pid).
func (a *ACS) handleAgreement(sid, pid uint64, msg *AgreementMessage) error {
return a.processAgreement(pid, func(bba *BBA) error {
return bba.HandleMessage(sid, msg)
})
}
// handleBroadcast processes the received BroadcastMessage.
func (a *ACS) handleBroadcast(sid, pid uint64, msg *BroadcastMessage) error {
return a.processBroadcast(pid, func(rbc *RBC) error {
return rbc.HandleMessage(sid, msg)
})
}
func (a *ACS) processBroadcast(pid uint64, fun func(rbc *RBC) error) error {
rbc, ok := a.rbcInstances[pid]
if !ok {
return fmt.Errorf("could not find rbc instance for (%d)", pid)
}
if err := fun(rbc); err != nil {
return err
}
for _, msg := range rbc.Messages() {
a.addMessage(pid, msg)
}
if output := rbc.Output(); output != nil {
a.rbcResults[pid] = output
return a.processAgreement(pid, func(bba *BBA) error {
if bba.AcceptInput() {
return bba.InputValue(true)
}
return nil
})
}
return nil
}
func (a *ACS) processAgreement(pid uint64, fun func(bba *BBA) error) error {
bba, ok := a.bbaInstances[pid]
if !ok {
return fmt.Errorf("could not find bba instance for (%d)", pid)
}
if bba.done {
return nil
}
if err := fun(bba); err != nil {
return err
}
for _, msg := range bba.Messages() {
a.addMessage(pid, msg)
}
// Check if we got an output.
if output := bba.Output(); output != nil {
if _, ok := a.bbaResults[pid]; ok {
return fmt.Errorf("multiple bba results for (%d)", pid)
}
a.bbaResults[pid] = output.(bool)
// When received 1 from at least (N - f) instances of BA, provide input 0.
// to each other instance of BBA that has not provided his input yet.
if output.(bool) && a.countTruthyAgreements() == a.N-a.F {
for id, bba := range a.bbaInstances {
if bba.AcceptInput() {
if err := bba.InputValue(false); err != nil {
return err
}
for _, msg := range bba.Messages() {
a.addMessage(id, msg)
}
if output := bba.Output(); output != nil {
a.bbaResults[id] = output.(bool)
}
}
}
}
a.tryCompleteAgreement()
}
return nil
}
func (a *ACS) tryCompleteAgreement() {
if a.decided || a.countTruthyAgreements() < a.N-a.F {
return
}
if len(a.bbaResults) < a.N {
return
}
// At this point all bba instances have provided their output.
nodesThatProvidedTrue := []uint64{}
for id, ok := range a.bbaResults {
if ok {
nodesThatProvidedTrue = append(nodesThatProvidedTrue, id)
}
}
bcResults := make(map[uint64][]byte)
for _, id := range nodesThatProvidedTrue {
val, _ := a.rbcResults[id]
bcResults[id] = val
}
if len(nodesThatProvidedTrue) == len(bcResults) {
a.output = bcResults
a.decided = true
}
}
func (a *ACS) addMessage(from uint64, msg interface{}) {
for _, id := range uint64sWithout(a.Nodes, a.ID) {
a.messageQue.addMessage(&ACSMessage{from, msg}, id)
}
}
// countTruthyAgreements returns the number of truthy received agreement messages.
func (a *ACS) countTruthyAgreements() int {
n := 0
for _, ok := range a.bbaResults {
if ok {
n++
}
}
return n
}
func uint64sWithout(s []uint64, val uint64) []uint64 {
dest := []uint64{}
for i := 0; i < len(s); i++ {
if s[i] != val {
dest = append(dest, s[i])
}
}
return dest
}