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7. Fault Tolerance Through Dynamic (or Standby) Redundancy

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7. Fault Tolerance Through Dynamic (or Standby) Redundancy The lowest-cost fault-tolerance technique in multiprocessors. Steps performed: When a fault is detected, a ... – PowerPoint PPT presentation

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Title: 7. Fault Tolerance Through Dynamic (or Standby) Redundancy


1
7. Fault Tolerance Through Dynamic (or Standby)
Redundancy
  • The lowest-cost fault-tolerance technique in
    multiprocessors.
  • Steps performed
  • When a fault is detected, a fault location or
    diagnosis procedure is triggered.
  • The faulty processor is then replaced by a spare
    processor or spare processing capability through
    reconfiguration.
  • Finally, error recovery is performed, whereby the
    spare processor, using typically checkpointed
    information, takes over the computations of the
    faulty processor from where it left off.

2
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • In summary, Dynamic Redundancy is performed in 3
    steps
  • I. Fault detection and location
  • II. Reconfiguration of the system around the
  • faulty processor
  • III. Error recovery

3
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • Several approaches perform fault detection in
    multiprocessors
  • Scheduled off-line testing for permanent faults
  • Duplication and comparison
  • Diagnostics and coding techniques

Described next ...
4
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.1 Fault Detection in Multiprocessors
  • 7.1.1 Fault Detection Through Duplication and
    Comparison
  • A) Each processor of the multiprocessor can be
    duplicated, and the results compared before
    communicating to the processor pairs.

5
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.1 Fault Detection in Multiprocessors
  • 7.1.1 Fault Detection Through Duplication and
    Comparison
  • B) Another approach is dividing the P processors
    of a multiprocessor into P/2 pairs. The global
    memory which consists of M memory modules can
    either be divided into M/2 pairs. Comparators
    can be kept inside each processor and memory
    module, and results of both computations must
    match for an operation to be executed. If an
    error is detected by a processor pair, both
    processors of the pair are powered off, and the
    computations are able to proceed on the P- 2
    remaining processors, configured as (P-2)/2 pairs
    of processors.

6
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.1 Fault Detection in Multiprocessors
  • 7.1.1 Fault Detection Through Duplication and
    Comparison
  • C) Alternatively, the comparison operation can
    also be performed in software, by means of
    checkpoint comparison techniques.

7
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.1 Fault Detection in Multiprocessors
  • 7.1.1 Fault Detection Through Duplication and
    Comparison
  • D) Finally, the duplication and comparison
    operation can be performed by means of time
    redundancy. This is useful when one cannot afford
    the redundancy of duplication for cost, weight,
    power, and space constraints (e.g., embarked,
    battery-powered electronics).
  • In the presence of task dependencies (see
    example), one often finds processors that are
    idle, since there are no ready tasks. In such
    situations, one can map the original task graph
    on P/2 processors, get better processor
    utilization, and use the remaining P/2 processors
    to perform the duplicate computation of the task
    graph. Hence, in real task graphs, one can
    observe less than 100 time overhead.

8
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.1 Fault Detection in Multiprocessors
  • 7.1.1 Fault Detection Through Duplication and
    Comparison
  • Tasks

1
2
3
4
a) Original task graph mapping
6
1
2
3
4
5
6
7
-
5
  • Processors

7
b) Example of mapping duplicated task graphs on
disjoint sets of processors
1
2
3
4
2d
3d
4d
1d
6
5
6d
5d
7
7d
1
2,5
3,7
4,6
1d
2d,5d
3d,7d
4d,6d
9
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.1 Fault Detection in Multiprocessors
  • 7.1.2 Fault Detection Using Diagnostics and
    Coding
  • Techniques
  • See 2.2 Information Redundancy

10
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.2 Recovery Strategies for Multiprocessor
    Systems
  • Since most faults are transient or intermittent,
    s simple recovery procedure may be merely to
    reexcute the computation.
  • Recovery issues are more complex in distributed
    systems (communicating processes) one has to
    ensure that the correct execution of one process
    is not affected by the faulty execution of a
    communicating process.
  • Recovery techniques are different for
    distributed- and shared-memory multiprocessors
    multiple processes can access memory and have
    different or erroneous copies of the same
    variables, creating an inconsistent state when
    the error is detected.
  • Therefore, some scheme must be devised that will
    be able to store enough error-free processor
    state information at a reliable place from where
    it can be retrieved and used to restart the
    program (rollback recovery) from a consistent
    state, in the event of a transient failure in one
    or more processors during program execution.

11
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.2 Recovery Strategies for Multiprocessor
    Systems
  • The most popular scheme Checkpointing !
  • It involves storing as much information about the
    processor state as necessary at discreet points
    (checkpoints, or rollback points) in the program
    to ensure that the program can be rolled back to
    those points in the event of a node failure, and
    restarted from there, as though no fault had
    occurred.
  • Processor states varies from one system to
    another. Generally it involves the register set
    of the processor, the program counter, the state
    of cache, and even memory as well, or at least
    those parts of it that have been altered by the
    processor since the last checkpoint.
  • This information is stored in reliable storage,
    that is, memory assumed not to fail. Such a
    memory could be a disk, or memory protected by
    using error-correcting codes, or duplicated
    memory and/or registers.

12
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.3 Rollback Recovery Using Checkpoints
  • Rollback recovery using checkpoints is a very
    cost-effective method of providing fault
    tolerance against transient and intermittent
    faults.
  • Various implementations and overhead issues are
    illustrated in the following.

13
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.3 Rollback Recovery Using Checkpoints
  • 7.3.1 Processor Cache-Based Checkpoints

CPU
Register
Active State
Bank A
Bank B
Ta1
Tb1
1 Ta1
4 Tb1
Cache
data
data
2 Flush
5 Flush
CPU Register Save Area
Main Memory
Ta2
Tb2
3 Ta2
6 Tb2
Checkpoint State
Processor-based checkpoint and rollback recovery.
Fault-tolerant techniques to flush cache.
14
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.3 Rollback Recovery Using Checkpoints
  • 7.3.1 Processor Cache-Based Checkpoints

Condition Failure Action
Ta1 Ta2 Tb1 Tb2 None None
Ta1 gtTa2 Tb1 Tb2 Flush A Copy Bank B to A
Ta1 Ta2 gt Tb1 Tb2 Between Copy Bank A to B
Ta1 Ta2 Tb1 gt Tb2 Flush B Copy Bank A to B
Failure Conditions.
15
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.3 Rollback Recovery Using Checkpoints
  • 7.3.2 Virtual Checkpoints

k
Checkpoint (v lt V)
Active (v V)
j
Checkpoint
Paging Disk
Real Memory
Virtual Memory
Overview of Single Page Mapping.
Basic Concept.
16
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.3 Rollback Recovery Using Checkpoints
  • 7.3.2 Virtual Checkpoints

tc1
tc2
tc2
V 0
V 1
V 2
V 1
V 2
tr0 m0 checkpoint
tr1 m1 Active v 1
tr1 m1 checkpoint
tr2 m2 Active v 2
tr2
tr3
Case 1 First reference after checkpoint.
Case 2 Page previously referenced.
17
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.3 Rollback Recovery Using Checkpoints
  • 7.3.2 Virtual Checkpoints

I am alive
Checkpointed State
Pri
Pri
Primary Process
Backup Process
Primary Process
Backup Process
I am alive
Primary process checkpoints the state with the
backup process.
I am alive messages are used for fault
detection.
18
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.4 Rollback Recovery in Communicating
    ......Multiprocessors
  • 7.4.1 Shared-Memory Multiprocessors

Bus Line Set by Processor to Indicate ...
Shared sharing a block on the bus.
Establish Rollback Point that a rollback point is being established.
Rollback that it is backing up to the prior rollback point.
Bus lines.
19
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.4 Rollback Recovery in Communicating
    ......Multiprocessors
  • 7.4.2 Distributed-Memory Multiprocessors

P1
P2
Communication
Checkpoint
Domino effect in recovery of multiprocesses.
20
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.4 Rollback Recovery in Communicating
    ......Multiprocessors
  • 7.4.2 Distributed-Memory Multiprocessors

Consistent and inconsistent recovery lines.
21
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.4 Rollback Recovery in Communicating
    Multiprocessors
  • 7.4.3 Recovery in Distributed Shared-Memory
    Systems
  • Typically, distributed shared-memory (DSM)
    systems are loosely coupled, geographically
    distributed systems of processors, each processor
    with its own memory.
  • Implemented by using Virtual Memory programmers
    see a single shared memory, which in reality is
    made up of individual memories residing in
    different processors.
  • Pages are used as the basic blocks of memory
    transfer. Each node keeps in its own local memory
    a subset of the total number of pages from the
    shared virtual memory.
  • A page fault is generated whenever a node tries
    to access a nonresident page. A page request is
    then generated and sent to a distinguished owner
    node that has a copy of the page needed. Upon
    reception of the page request, the owner node
    transfers the new page to the requester, which
    then becomes the new owner.
  • An owner-node keeps a page-table with information
    on the nodes which have read-only copies of pages
    that are owned by the owner-node.

22
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.4 Rollback Recovery in Communicating
    Multiprocessors
  • 7.4.3 Recovery in Distributed Shared-Memory
    Systems
  • A local checkpoint for the mentioned system
    consists of (the important information that must
    be saved)
  • a) the contents of locally owned pages that have
    been modified since the last checkpoint on the
    local node.
  • b) the page-table entries for locally owned pages
    that have been modified since the last
    checkpoint.
  • This is in addition to the state information of
    the local processor, which is also stored with
    each checkpoint in reliable storage.
  • How the reliable storage is implemented depends
    upon the resources available, as well as on the
    level of reliability desired from the system.
  • A process on a recovering processor is expected
    to retrieve any clean pages that it might need
    from previous checkpoints stored on disk, in
    addition to any dirty pages that were stored in
    the last checkpoint before failure.

23
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.4 Rollback Recovery in Communicating
    ......Multiprocessors
  • 7.4.4 Recovery in Database Systems
  • Database systems employ atomic actions known as
    transactions to maintain consistency and
    integrity in the presence of concurrent
    activities.
  • Since transactions are atomic activities, in the
    event a transaction is aborted, its actions have
    to be undone to restore consistency to the
    system.
  • Because of the all-or-nothing property of
    atomic actions, an important amount of work might
    be abandoned needlessly when an internal error is
    encountered.

24
7. Fault Tolerance Through Dynamic or Standby
Redundancy
  • 7.4 Rollback Recovery in Communicating
    Multiprocessors
  • 7.4.4 Recovery in Database Systems
  • Shadowing is a typical implementation of
    recovery-oriented mechanism on database systems,
    which involves using a new disk page to write the
    modified version of a database page. When the
    transaction completes (or commits), the page to
    which it was writing becomes the permanent page,
    or it is discarded if the transaction aborts.
    Recovery is fast, since it only involves
    discarding the modified pages into which the
    transactions in the active list are writing.
  • Thus, a scheme for distributed systems has been
    considered which uses pages as the invisible unit
    of memory that is stored as part of a checkpoint
    and used for recovery.
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