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Distributed Snapshot. -- How many messages are in transit on the internet? --What is the global state of a distributed system of N processes? How do we compute these?. Think about these. One-dollar bank. - PowerPoint PPT Presentation
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Distributed Snapshot
Think about these
-- How many messages are in transit
on the internet?
-- What is the global state of a distributed
system of N processes?
How do we compute these?
One-dollar bank
0
1
2
(0,1)
(1,2)(2,0)
Let a $1 coin circulate in a network of a million banks.
How can someone count the total $ in circulation? If
not counted “properly,” then one may think the total $
in circulation to be one million.
Importance of snapshots
Major uses in
- deadlock detection
- termination detection
- rollback recovery
- global predicate
computation
Consistent cut
(a ∈ C) ⋀ (b a) ≺ ⇒ b ∈ C
If this is not true, then the cut C is inconsistent
A cut is a set of events. If a cut C is consistent then
time
Consistent snapshot
The set of states immediately following the events
(actions) in a consistent cut forms a consistent
snapshot of a distributed system.
• A snapshot that is of practical interest is the most
recent one. Let C1 and C2 be two consistent cuts
and C1 ⊂ C2. Then C2 is more recent than C1.
• Analyze why certain cuts in the one-dollar bank are
inconsistent.
Consistent snapshot
How to record a consistent snapshot? Note that
1. The recording must be non-invasive.
2. Recording must be done on-the-fly.
You cannot stop the system.
Chandy-Lamport Algorithm
Works on a
(1) strongly connected graph
(2) each channel is FIFO.
An initiator initiates the
algorithm by sending out a
marker ( )
White and red processes
Initially every process is white.
When a process receives a marker,
it turns red if it has not already done so.
Every action by a process, and every
message sent by a process gets the
color of that process.
Two steps
Step 1. In one atomic action, the initiator (a) Turns red (b) Records its own state (c) sends a marker along all outgoing channels
Step 2. Every other process, upon receiving a marker for the first time (and before doing anything else) (a) Turns red (b) Records its own state (c) sends markers along all outgoing channels
The algorithm terminates when (1) every process turns red, and (2) Every process has received a marker through each incoming channel.
Why does it work?
Lemma 1. No red message is received in a white action.
Why does it work?
Theorem. The global state recorded by Chandy-Lamport algorithm is equivalent to the ideal snapshot state SSS.
Hint. A pair of actions (a, b) can be scheduled in any order, if there is no causal order between them, so (a; b) is equivalent to (b; a)
SSSEasy conceptualization of the snapshot state
All white All red
Why does it work?
Let an observer observe the following actions:
w[i] w[k] r[k] w[j] r[i] w[l] r[j] r[l] … w[i] w[k] w[j] r[k] r[i] w[l] r[j] r[l] … [Lemma 1]w[i] w[k] w[j] r[k] w[l] r[i] r[j] r[l] … [Lemma 1]w[i] w[k] w[j] w[l] r[k] r[i] r[j] r[l] … [done!]
Recorded state
Example 1: Count the tokens
Let us verify that Chandy-Lamport snapshot algorithm correctly counts
the tokens circulating in the system
A
B
C
How to account for the channel states? Use sent and received variables for each process.
token no token
token
token
no token
no token
A
B
C
no token
no token
token
Are these consistent cuts?
1
2
3
Example 2: Communicating State Machines
ch1
ch2
i j
up
down
up
state machine
i
state machine
j
send
M
send
M'
down
global state i ch1 j ch2
S0 down φ down φ
1 S up M down φ
2 S up M up M'
3 S down M up φ
receive
M'
receive
M
Something unusual
Let machine i start Chandy-Lamport snapshot before it
has sent M along ch1. Also, let machine j receive the
marker after it sends out M’ along ch2. Observe that
the snapshot state is
down ∅ up M’
Doesn’t this appear strange? This state was never
reached during the computation!
Understanding snapshot
S0
S1
i sends M
j sends M'
j receives M
j sends M'i receives M'
S1'
S2
S2'
i sends M
j receives M
i receives M'
i receives M' j receives M
S3
S0
S3'
recorded
state SSS
Understanding snapshot
The observed state is a feasible state that is reachable
from the initial configuration. It may not actually be visited
during a specific execution.
The final state of the original computation is always
reachable from the observed state.
Discussions
What good is a snapshot if that state has never been visited by the system?
- It is relevant for the detection of stable predicates.
- Useful for checkpointing.
Discussions
What if the channels are not FIFO?
Study how Lai-Yang algorithm works. It does not use any marker
LY1. The initiator records its own state. When it needs to send a
message m to another process, it sends a message (m, red).
LY2. When a process receives a message (m, red), it records its state
if it has not already done so, and then accepts the message m.
Question 1. Why will it work?
Question 1 Are there any limitations of this approach?
Food for thought
Distributed snapshot = distributed read.
Distributed reset = distributed write
How difficult is distributed reset?
Distributed debugging(Marzullo and Neiger, 1991)
observer
Distributed system
e, VC(e)
Distributed debugging
Distributed debugging
Possibly ϕ: At least one consistent global state S is reachable from the initial global state, such that φ(S) = true.
Definitely ϕ: All computations pass through some consistent global state S such that φ(S) = true.
Never ϕ: No computation passes through some consistent global state S such that φ(S) = true.
Definitely ϕ Possibly ϕ ⇒
Examples
ϕ = x+y =12 (true at S21) Possibly ϕ
ϕ = x+y > 15 (true at S32) Definitely ϕ
ϕ = x=y=5 (true at S40 and S22) Never ϕ
*Neither S40 and S22 is a consistent state*
Global State Collection
Global state collection
Some applications
- computing network topology
- termination detection
- deadlock detection
Chandy-Lamport algorithm does a partial job. Each process
generates a fragment of the global state, but these pieces have
to be “stitched together” to form a global state.
A simple exercise
Once the pieces of a consistent
global state become available,
consider collecting the global state via
all-to-all broadcast
At the end, each process
will compute a set V, where
V= {s(i): 0 ≤ i ≤ N-1 }
i
k
j
l
s(i) s(j)
s(k) s(l)
All-to-all broadcast
V.iW.i
V.kW.k
(i,k)
Acts like a “pump”
Assume that the topology is a strongly connected graph
V.jW.j
(j,i)