func (pn *paxosNode) GetNextProposalNumber(args *paxosrpc.ProposalNumberArgs, reply *paxosrpc.ProposalNumberReply) error {
pn.propNumLock.Lock()
defer pn.propNumLock.Unlock()
reply.N = pn.nodePropNum
pn.nodePropNum += pn.numNodes
return nil
}
func (pn *paxosNode) GetNextProposalNumber(args *paxosrpc.ProposalNumberArgs, reply *paxosrpc.ProposalNumberReply) error {
key := args.Key
var n int
if m, found := pn.highestSeen[key]; found {
n = (m/pn.numNodes+1)*pn.numNodes + pn.nodeID
} else {
n = pn.nodeID
}
pn.highestSeen[key] = n
reply.N = n
return nil
}
// GetNextProposalNumber generates a proposal number which will be passed to
// Propose. Proposal numbers should not repeat, and for a particular node
// they should be strictly increasing.
func (pn *paxosNode) GetNextProposalNumber(args *paxosrpc.ProposalNumberArgs, reply *paxosrpc.ProposalNumberReply) error {
// Will just give the Max([Nh/k]*k + id , )
key := args.Key
pxi := pn.getInstance(key)
pxi.mu.RLock()
defer pxi.mu.RUnlock()
replyN := (pxi.Nh/pn.numNodes+1)*pn.numNodes + pn.id
reply.N = replyN
return nil
}
// This function is used to generate the next proposal number given the user input
func (pn *paxosNode) GetNextProposalNumber(args *paxosrpc.ProposalNumberArgs, reply *paxosrpc.ProposalNumberReply) error {
fmt.Println("get number")
key := args.Key
pNumber, ok := pn.pNumberMap[key]
if !ok {
pNumber = -1
}
newNumber := pNumber + 1
reply.N = newNumber*pn.numNodes + pn.srvId
pn.pNumberMap[key] = newNumber
fmt.Println("getnumber: ", reply.N)
return nil
}
func (pn *paxosNode) GetNextProposalNumber(args *paxosrpc.ProposalNumberArgs, reply *paxosrpc.ProposalNumberReply) error {
// just increment the clock and calculate the proposal number
N_my, ok1 := pn.clockMap[args.Key]
N_h, ok2 := pn.maxpropMap[args.Key]
highest_time := 0
if ok1 && ok2 {
if N_my > N_h/pn.numNodes {
highest_time = N_my
} else {
highest_time = N_h / pn.numNodes
}
} else if ok1 {
highest_time = N_my
} else if ok2 {
highest_time = N_h / pn.numNodes
}
pn.clockMap[args.Key] = highest_time + 1
reply.N = pn.clockMap[args.Key]*pn.numNodes + pn.id
return nil
}
func (pn *paxosNode) GetNextProposalNumber(args *paxosrpc.ProposalNumberArgs, reply *paxosrpc.ProposalNumberReply) error {
reply.N = pn.logicTime*pn.timeFactor + pn.id
return nil
}
func (pn *paxosNode) GetNextProposalNumber(args *paxosrpc.ProposalNumberArgs, reply *paxosrpc.ProposalNumberReply) error {
key := args.Key
pn.mutex.Lock()
if pn.keyValueMutex[key] == nil {
pn.keyValueMutex[key] = &sync.Mutex{}
}
pn.mutex.Unlock()
// lock current key mutex
pn.keyValueMutex[key].Lock()
if pn.keyValue[key] == nil {
pn.keyValue[key] = &value{
Key: key,
Value: nil,
N_a: -1,
N_h: -1,
my_n: -1,
}
}
val := pn.keyValue[key]
my_n := val.my_n
N_h := val.N_h
// reply.N = math.Max(my_n, N_h) + 1
if my_n > N_h {
reply.N = my_n
} else {
reply.N = N_h
}
// fmt.Println("GetNextProposalNumber", reply.N, my_n, N_h)
reply.N = (reply.N+pn.numNodes-pn.nodeID)/pn.numNodes*pn.numNodes + pn.nodeID
pn.keyValueMutex[key].Unlock()
// fmt.Println("my_n", my_n, "N_h", N_h, "replyN", reply.N)
tempValue := pn.keyValue[args.Key]
tempValue.my_n = reply.N
pn.keyValue[args.Key] = tempValue
if pn.savedkeyValue[key] == nil {
pn.savedkeyValue[key] = &value{
Key: args.Key,
Value: nil,
N_a: -1,
N_h: -1,
my_n: -1,
}
}
retChan := make(chan int, 1)
// proposalNumberArgs := &paxosrpc.ProposalNumberArgs{
// Key: args.Key,
// }
// proposalNumberReply := &paxosrpc.ProposalNumberReply{}
// pn.GetNextProposalNumber(proposalNumberArgs, proposalNumberReply)
// fmt.Println("get new proposal number", proposalNumberReply.N)
newArgs := &paxosrpc.ProposeArgs{
Key: args.Key,
N: reply.N,
V: nil,
}
// fmt.Println("Prepare phase")
for nodeID, hostPort := range pn.hostMap {
pn.ProposeByNode(nodeID, hostPort, newArgs, retChan)
<-retChan
}
return nil
}
