HADOOP-10954. Adding site documents of hadoop-tools (Masatake Iwasaki via aw)

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Allen Wittenauer 2014-09-26 12:01:41 -07:00
parent fe8222998f
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@ -212,6 +212,9 @@ Release 2.6.0 - UNRELEASED
HADOOP-8808. Update FsShell documentation to mention deprecation of some
of the commands, and mention alternatives (Akira AJISAKA via aw)
HADOOP-10954. Adding site documents of hadoop-tools (Masatake Iwasaki
via aw)
OPTIMIZATIONS
HADOOP-10838. Byte array native checksumming. (James Thomas via todd)

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<!---
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Gridmix
=======
---
- [Overview](#Overview)
- [Usage](#Usage)
- [General Configuration Parameters](#General_Configuration_Parameters)
- [Job Types](#Job_Types)
- [Job Submission Policies](#Job_Submission_Policies)
- [Emulating Users and Queues](#Emulating_Users_and_Queues)
- [Emulating Distributed Cache Load](#Emulating_Distributed_Cache_Load)
- [Configuration of Simulated Jobs](#Configuration_of_Simulated_Jobs)
- [Emulating Compression/Decompression](#Emulating_CompressionDecompression)
- [Emulating High-Ram jobs](#Emulating_High-Ram_jobs)
- [Emulating resource usages](#Emulating_resource_usages)
- [Simplifying Assumptions](#Simplifying_Assumptions)
- [Appendix](#Appendix)
---
Overview
--------
GridMix is a benchmark for Hadoop clusters. It submits a mix of
synthetic jobs, modeling a profile mined from production loads.
There exist three versions of the GridMix tool. This document
discusses the third (checked into `src/contrib` ), distinct
from the two checked into the `src/benchmarks` sub-directory.
While the first two versions of the tool included stripped-down versions
of common jobs, both were principally saturation tools for stressing the
framework at scale. In support of a broader range of deployments and
finer-tuned job mixes, this version of the tool will attempt to model
the resource profiles of production jobs to identify bottlenecks, guide
development, and serve as a replacement for the existing GridMix
benchmarks.
To run GridMix, you need a MapReduce job trace describing the job mix
for a given cluster. Such traces are typically generated by Rumen (see
Rumen documentation). GridMix also requires input data from which the
synthetic jobs will be reading bytes. The input data need not be in any
particular format, as the synthetic jobs are currently binary readers.
If you are running on a new cluster, an optional step generating input
data may precede the run.
In order to emulate the load of production jobs from a given cluster
on the same or another cluster, follow these steps:
1. Locate the job history files on the production cluster. This
location is specified by the
`mapred.job.tracker.history.completed.location`
configuration property of the cluster.
2. Run Rumen to build a job trace in JSON format for all or select jobs.
3. Use GridMix with the job trace on the benchmark cluster.
Jobs submitted by GridMix have names of the form
"`GRIDMIXnnnnnn`", where
"`nnnnnn`" is a sequence number padded with leading zeroes.
Usage
-----
Basic command-line usage without configuration parameters:
org.apache.hadoop.mapred.gridmix.Gridmix [-generate <size>] [-users <users-list>] <iopath> <trace>
Basic command-line usage with configuration parameters:
org.apache.hadoop.mapred.gridmix.Gridmix \
-Dgridmix.client.submit.threads=10 -Dgridmix.output.directory=foo \
[-generate <size>] [-users <users-list>] <iopath> <trace>
> Configuration parameters like
> `-Dgridmix.client.submit.threads=10` and
> `-Dgridmix.output.directory=foo` as given above should
> be used *before* other GridMix parameters.
The `<iopath>` parameter is the working directory for
GridMix. Note that this can either be on the local file-system
or on HDFS, but it is highly recommended that it be the same as that for
the original job mix so that GridMix puts the same load on the local
file-system and HDFS respectively.
The `-generate` option is used to generate input data and
Distributed Cache files for the synthetic jobs. It accepts standard units
of size suffixes, e.g. `100g` will generate
100 * 2<sup>30</sup> bytes as input data.
`<iopath>/input` is the destination directory for
generated input data and/or the directory from which input data will be
read. HDFS-based Distributed Cache files are generated under the
distributed cache directory `<iopath>/distributedCache`.
If some of the needed Distributed Cache files are already existing in the
distributed cache directory, then only the remaining non-existing
Distributed Cache files are generated when `-generate` option
is specified.
The `-users` option is used to point to a users-list
file (see <a href="#usersqueues">Emulating Users and Queues</a>).
The `<trace>` parameter is a path to a job trace
generated by Rumen. This trace can be compressed (it must be readable
using one of the compression codecs supported by the cluster) or
uncompressed. Use "-" as the value of this parameter if you
want to pass an *uncompressed* trace via the standard
input-stream of GridMix.
The class `org.apache.hadoop.mapred.gridmix.Gridmix` can
be found in the JAR
`contrib/gridmix/hadoop-gridmix-$VERSION.jar` inside your
Hadoop installation, where `$VERSION` corresponds to the
version of Hadoop installed. A simple way of ensuring that this class
and all its dependencies are loaded correctly is to use the
`hadoop` wrapper script in Hadoop:
hadoop jar <gridmix-jar> org.apache.hadoop.mapred.gridmix.Gridmix \
[-generate <size>] [-users <users-list>] <iopath> <trace>
The supported configuration parameters are explained in the
following sections.
General Configuration Parameters
--------------------------------
<table>
<tr>
<th>Parameter</th>
<th>Description</th>
</tr>
<tr>
<td>
<code>gridmix.output.directory</code>
</td>
<td>The directory into which output will be written. If specified,
<code>iopath</code> will be relative to this parameter. The
submitting user must have read/write access to this directory. The
user should also be mindful of any quota issues that may arise
during a run. The default is "<code>gridmix</code>".</td>
</tr>
<tr>
<td>
<code>gridmix.client.submit.threads</code>
</td>
<td>The number of threads submitting jobs to the cluster. This
also controls how many splits will be loaded into memory at a given
time, pending the submit time in the trace. Splits are pre-generated
to hit submission deadlines, so particularly dense traces may want
more submitting threads. However, storing splits in memory is
reasonably expensive, so you should raise this cautiously. The
default is 1 for the SERIAL job-submission policy (see
<a href="#policies">Job Submission Policies</a>) and one more than
the number of processors on the client machine for the other
policies.</td>
</tr>
<tr>
<td>
<code>gridmix.submit.multiplier</code>
</td>
<td>The multiplier to accelerate or decelerate the submission of
jobs. The time separating two jobs is multiplied by this factor.
The default value is 1.0. This is a crude mechanism to size
a job trace to a cluster.</td>
</tr>
<tr>
<td>
<code>gridmix.client.pending.queue.depth</code>
</td>
<td>The depth of the queue of job descriptions awaiting split
generation. The jobs read from the trace occupy a queue of this
depth before being processed by the submission threads. It is
unusual to configure this. The default is 5.</td>
</tr>
<tr>
<td>
<code>gridmix.gen.blocksize</code>
</td>
<td>The block-size of generated data. The default value is 256
MiB.</td>
</tr>
<tr>
<td>
<code>gridmix.gen.bytes.per.file</code>
</td>
<td>The maximum bytes written per file. The default value is 1
GiB.</td>
</tr>
<tr>
<td>
<code>gridmix.min.file.size</code>
</td>
<td>The minimum size of the input files. The default limit is 128
MiB. Tweak this parameter if you see an error-message like
"Found no satisfactory file" while testing GridMix with
a relatively-small input data-set.</td>
</tr>
<tr>
<td>
<code>gridmix.max.total.scan</code>
</td>
<td>The maximum size of the input files. The default limit is 100
TiB.</td>
</tr>
<tr>
<td>
<code>gridmix.task.jvm-options.enable</code>
</td>
<td>Enables Gridmix to configure the simulated task's max heap
options using the values obtained from the original task (i.e via
trace).
</td>
</tr>
</table>
Job Types
---------
GridMix takes as input a job trace, essentially a stream of
JSON-encoded job descriptions. For each job description, the submission
client obtains the original job submission time and for each task in
that job, the byte and record counts read and written. Given this data,
it constructs a synthetic job with the same byte and record patterns as
recorded in the trace. It constructs jobs of two types:
<table>
<tr>
<th>Job Type</th>
<th>Description</th>
</tr>
<tr>
<td>
<code>LOADJOB</code>
</td>
<td>A synthetic job that emulates the workload mentioned in Rumen
trace. In the current version we are supporting I/O. It reproduces
the I/O workload on the benchmark cluster. It does so by embedding
the detailed I/O information for every map and reduce task, such as
the number of bytes and records read and written, into each
job's input splits. The map tasks further relay the I/O patterns of
reduce tasks through the intermediate map output data.</td>
</tr>
<tr>
<td>
<code>SLEEPJOB</code>
</td>
<td>A synthetic job where each task does *nothing* but sleep
for a certain duration as observed in the production trace. The
scalability of the Job Tracker is often limited by how many
heartbeats it can handle every second. (Heartbeats are periodic
messages sent from Task Trackers to update their status and grab new
tasks from the Job Tracker.) Since a benchmark cluster is typically
a fraction in size of a production cluster, the heartbeat traffic
generated by the slave nodes is well below the level of the
production cluster. One possible solution is to run multiple Task
Trackers on each slave node. This leads to the obvious problem that
the I/O workload generated by the synthetic jobs would thrash the
slave nodes. Hence the need for such a job.</td>
</tr>
</table>
The following configuration parameters affect the job type:
<table>
<tr>
<th>Parameter</th>
<th>Description</th>
</tr>
<tr>
<td>
<code>gridmix.job.type</code>
</td>
<td>The value for this key can be one of LOADJOB or SLEEPJOB. The
default value is LOADJOB.</td>
</tr>
<tr>
<td>
<code>gridmix.key.fraction</code>
</td>
<td>For a LOADJOB type of job, the fraction of a record used for
the data for the key. The default value is 0.1.</td>
</tr>
<tr>
<td>
<code>gridmix.sleep.maptask-only</code>
</td>
<td>For a SLEEPJOB type of job, whether to ignore the reduce
tasks for the job. The default is <code>false</code>.</td>
</tr>
<tr>
<td>
<code>gridmix.sleep.fake-locations</code>
</td>
<td>For a SLEEPJOB type of job, the number of fake locations
for map tasks for the job. The default is 0.</td>
</tr>
<tr>
<td>
<code>gridmix.sleep.max-map-time</code>
</td>
<td>For a SLEEPJOB type of job, the maximum runtime for map
tasks for the job in milliseconds. The default is unlimited.</td>
</tr>
<tr>
<td>
<code>gridmix.sleep.max-reduce-time</code>
</td>
<td>For a SLEEPJOB type of job, the maximum runtime for reduce
tasks for the job in milliseconds. The default is unlimited.</td>
</tr>
</table>
<a name="policies"></a>
Job Submission Policies
-----------------------
GridMix controls the rate of job submission. This control can be
based on the trace information or can be based on statistics it gathers
from the Job Tracker. Based on the submission policies users define,
GridMix uses the respective algorithm to control the job submission.
There are currently three types of policies:
<table>
<tr>
<th>Job Submission Policy</th>
<th>Description</th>
</tr>
<tr>
<td>
<code>STRESS</code>
</td>
<td>Keep submitting jobs so that the cluster remains under stress.
In this mode we control the rate of job submission by monitoring
the real-time load of the cluster so that we can maintain a stable
stress level of workload on the cluster. Based on the statistics we
gather we define if a cluster is *underloaded* or
*overloaded* . We consider a cluster *underloaded* if
and only if the following three conditions are true:
<ol>
<li>the number of pending and running jobs are under a threshold
TJ</li>
<li>the number of pending and running maps are under threshold
TM</li>
<li>the number of pending and running reduces are under threshold
TR</li>
</ol>
The thresholds TJ, TM and TR are proportional to the size of the
cluster and map, reduce slots capacities respectively. In case of a
cluster being *overloaded* , we throttle the job submission.
In the actual calculation we also weigh each running task with its
remaining work - namely, a 90% complete task is only counted as 0.1
in calculation. Finally, to avoid a very large job blocking other
jobs, we limit the number of pending/waiting tasks each job can
contribute.</td>
</tr>
<tr>
<td>
<code>REPLAY</code>
</td>
<td>In this mode we replay the job traces faithfully. This mode
exactly follows the time-intervals given in the actual job
trace.</td>
</tr>
<tr>
<td>
<code>SERIAL</code>
</td>
<td>In this mode we submit the next job only once the job submitted
earlier is completed.</td>
</tr>
</table>
The following configuration parameters affect the job submission policy:
<table>
<tr>
<th>Parameter</th>
<th>Description</th>
</tr>
<tr>
<td>
<code>gridmix.job-submission.policy</code>
</td>
<td>The value for this key would be one of the three: STRESS, REPLAY
or SERIAL. In most of the cases the value of key would be STRESS or
REPLAY. The default value is STRESS.</td>
</tr>
<tr>
<td>
<code>gridmix.throttle.jobs-to-tracker-ratio</code>
</td>
<td>In STRESS mode, the minimum ratio of running jobs to Task
Trackers in a cluster for the cluster to be considered
*overloaded* . This is the threshold TJ referred to earlier.
The default is 1.0.</td>
</tr>
<tr>
<td>
<code>gridmix.throttle.maps.task-to-slot-ratio</code>
</td>
<td>In STRESS mode, the minimum ratio of pending and running map
tasks (i.e. incomplete map tasks) to the number of map slots for
a cluster for the cluster to be considered *overloaded* .
This is the threshold TM referred to earlier. Running map tasks are
counted partially. For example, a 40% complete map task is counted
as 0.6 map tasks. The default is 2.0.</td>
</tr>
<tr>
<td>
<code>gridmix.throttle.reduces.task-to-slot-ratio</code>
</td>
<td>In STRESS mode, the minimum ratio of pending and running reduce
tasks (i.e. incomplete reduce tasks) to the number of reduce slots
for a cluster for the cluster to be considered *overloaded* .
This is the threshold TR referred to earlier. Running reduce tasks
are counted partially. For example, a 30% complete reduce task is
counted as 0.7 reduce tasks. The default is 2.5.</td>
</tr>
<tr>
<td>
<code>gridmix.throttle.maps.max-slot-share-per-job</code>
</td>
<td>In STRESS mode, the maximum share of a cluster's map-slots
capacity that can be counted toward a job's incomplete map tasks in
overload calculation. The default is 0.1.</td>
</tr>
<tr>
<td>
<code>gridmix.throttle.reducess.max-slot-share-per-job</code>
</td>
<td>In STRESS mode, the maximum share of a cluster's reduce-slots
capacity that can be counted toward a job's incomplete reduce tasks
in overload calculation. The default is 0.1.</td>
</tr>
</table>
<a name="usersqueues"></a>
Emulating Users and Queues
--------------------------
Typical production clusters are often shared with different users and
the cluster capacity is divided among different departments through job
queues. Ensuring fairness among jobs from all users, honoring queue
capacity allocation policies and avoiding an ill-behaving job from
taking over the cluster adds significant complexity in Hadoop software.
To be able to sufficiently test and discover bugs in these areas,
GridMix must emulate the contentions of jobs from different users and/or
submitted to different queues.
Emulating multiple queues is easy - we simply set up the benchmark
cluster with the same queue configuration as the production cluster and
we configure synthetic jobs so that they get submitted to the same queue
as recorded in the trace. However, not all users shown in the trace have
accounts on the benchmark cluster. Instead, we set up a number of testing
user accounts and associate each unique user in the trace to testing
users in a round-robin fashion.
The following configuration parameters affect the emulation of users
and queues:
<table>
<tr>
<th>Parameter</th>
<th>Description</th>
</tr>
<tr>
<td>
<code>gridmix.job-submission.use-queue-in-trace</code>
</td>
<td>When set to <code>true</code> it uses exactly the same set of
queues as those mentioned in the trace. The default value is
<code>false</code>.</td>
</tr>
<tr>
<td>
<code>gridmix.job-submission.default-queue</code>
</td>
<td>Specifies the default queue to which all the jobs would be
submitted. If this parameter is not specified, GridMix uses the
default queue defined for the submitting user on the cluster.</td>
</tr>
<tr>
<td>
<code>gridmix.user.resolve.class</code>
</td>
<td>Specifies which <code>UserResolver</code> implementation to use.
We currently have three implementations:
<ol>
<li><code>org.apache.hadoop.mapred.gridmix.EchoUserResolver</code>
- submits a job as the user who submitted the original job. All
the users of the production cluster identified in the job trace
must also have accounts on the benchmark cluster in this case.</li>
<li><code>org.apache.hadoop.mapred.gridmix.SubmitterUserResolver</code>
- submits all the jobs as current GridMix user. In this case we
simply map all the users in the trace to the current GridMix user
and submit the job.</li>
<li><code>org.apache.hadoop.mapred.gridmix.RoundRobinUserResolver</code>
- maps trace users to test users in a round-robin fashion. In
this case we set up a number of testing user accounts and
associate each unique user in the trace to testing users in a
round-robin fashion.</li>
</ol>
The default is
<code>org.apache.hadoop.mapred.gridmix.SubmitterUserResolver</code>.</td>
</tr>
</table>
If the parameter `gridmix.user.resolve.class` is set to
`org.apache.hadoop.mapred.gridmix.RoundRobinUserResolver`,
we need to define a users-list file with a list of test users.
This is specified using the `-users` option to GridMix.
<note>
Specifying a users-list file using the `-users` option is
mandatory when using the round-robin user-resolver. Other user-resolvers
ignore this option.
</note>
A users-list file has one user per line, each line of the format:
<username>
For example:
user1
user2
user3
In the above example we have defined three users `user1`, `user2` and `user3`.
Now we would associate each unique user in the trace to the above users
defined in round-robin fashion. For example, if trace's users are
`tuser1`, `tuser2`, `tuser3`, `tuser4` and `tuser5`, then the mappings would be:
tuser1 -> user1
tuser2 -> user2
tuser3 -> user3
tuser4 -> user1
tuser5 -> user2
For backward compatibility reasons, each line of users-list file can
contain username followed by groupnames in the form username[,group]*.
The groupnames will be ignored by Gridmix.
Emulating Distributed Cache Load
--------------------------------
Gridmix emulates Distributed Cache load by default for LOADJOB type of
jobs. This is done by precreating the needed Distributed Cache files for all
the simulated jobs as part of a separate MapReduce job.
Emulation of Distributed Cache load in gridmix simulated jobs can be
disabled by configuring the property
`gridmix.distributed-cache-emulation.enable` to
`false`.
But generation of Distributed Cache data by gridmix is driven by
`-generate` option and is independent of this configuration
property.
Both generation of Distributed Cache files and emulation of
Distributed Cache load are disabled if:
* input trace comes from the standard input-stream instead of file, or
* `<iopath>` specified is on local file-system, or
* any of the ascendant directories of the distributed cache directory
i.e. `<iopath>/distributedCache` (including the distributed
cache directory) doesn't have execute permission for others.
Configuration of Simulated Jobs
-------------------------------
Gridmix3 sets some configuration properties in the simulated Jobs
submitted by it so that they can be mapped back to the corresponding Job
in the input Job trace. These configuration parameters include:
<table>
<tr>
<th>Parameter</th>
<th>Description</th>
</tr>
<tr>
<td>
<code>gridmix.job.original-job-id</code>
</td>
<td> The job id of the original cluster's job corresponding to this
simulated job.
</td>
</tr>
<tr>
<td>
<code>gridmix.job.original-job-name</code>
</td>
<td> The job name of the original cluster's job corresponding to this
simulated job.
</td>
</tr>
</table>
Emulating Compression/Decompression
-----------------------------------
MapReduce supports data compression and decompression.
Input to a MapReduce job can be compressed. Similarly, output of Map
and Reduce tasks can also be compressed. Compression/Decompression
emulation in GridMix is important because emulating
compression/decompression will effect the CPU and Memory usage of the
task. A task emulating compression/decompression will affect other
tasks and daemons running on the same node.
Compression emulation is enabled if
`gridmix.compression-emulation.enable` is set to
`true`. By default compression emulation is enabled for
jobs of type *LOADJOB* . With compression emulation enabled,
GridMix will now generate compressed text data with a constant
compression ratio. Hence a simulated GridMix job will now emulate
compression/decompression using compressible text data (having a
constant compression ratio), irrespective of the compression ratio
observed in the actual job.
A typical MapReduce Job deals with data compression/decompression in
the following phases
* `Job input data decompression: ` GridMix generates
compressible input data when compression emulation is enabled.
Based on the original job's configuration, a simulated GridMix job
will use a decompressor to read the compressed input data.
Currently, GridMix uses
`mapreduce.input.fileinputformat.inputdir` to determine
if the original job used compressed input data or
not. If the original job's input files are uncompressed then the
simulated job will read the compressed input file without using a
decompressor.
* `Intermediate data compression and decompression: `
If the original job has map output compression enabled then GridMix
too will enable map output compression for the simulated job.
Accordingly, the reducers will use a decompressor to read the map
output data.
* `Job output data compression: `
If the original job's output is compressed then GridMix
too will enable job output compression for the simulated job.
The following configuration parameters affect compression emulation
<table>
<tr>
<th>Parameter</th>
<th>Description</th>
</tr>
<tr>
<td>gridmix.compression-emulation.enable</td>
<td>Enables compression emulation in simulated GridMix jobs.
Default is true.</td>
</tr>
</table>
With compression emulation turned on, GridMix will generate compressed
input data. Hence the total size of the input
data will be lesser than the expected size. Set
`gridmix.min.file.size` to a smaller value (roughly 10% of
`gridmix.gen.bytes.per.file`) for enabling GridMix to
correctly emulate compression.
Emulating High-Ram jobs
-----------------------
MapReduce allows users to define a job as a High-Ram job. Tasks from a
High-Ram job can occupy multiple slots on the task-trackers.
Task-tracker assigns fixed virtual memory for each slot. Tasks from
High-Ram jobs can occupy multiple slots and thus can use up more
virtual memory as compared to a default task.
Emulating this behavior is important because of the following reasons
* Impact on scheduler: Scheduling of tasks from High-Ram jobs
impacts the scheduling behavior as it might result into slot
reservation and slot/resource utilization.
* Impact on the node : Since High-Ram tasks occupy multiple slots,
trackers do some bookkeeping for allocating extra resources for
these tasks. Thus this becomes a precursor for memory emulation
where tasks with high memory requirements needs to be considered
as a High-Ram task.
High-Ram feature emulation can be disabled by setting
`gridmix.highram-emulation.enable` to `false`.
Emulating resource usages
-------------------------
Usages of resources like CPU, physical memory, virtual memory, JVM heap
etc are recorded by MapReduce using its task counters. This information
is used by GridMix to emulate the resource usages in the simulated
tasks. Emulating resource usages will help GridMix exert similar load
on the test cluster as seen in the actual cluster.
MapReduce tasks use up resources during its entire lifetime. GridMix
also tries to mimic this behavior by spanning resource usage emulation
across the entire lifetime of the simulated task. Each resource to be
emulated should have an *emulator* associated with it.
Each such *emulator* should implement the
`org.apache.hadoop.mapred.gridmix.emulators.resourceusage
.ResourceUsageEmulatorPlugin` interface. Resource
*emulators* in GridMix are *plugins* that can be
configured (plugged in or out) before every run. GridMix users can
configure multiple emulator *plugins* by passing a comma
separated list of *emulators* as a value for the
`gridmix.emulators.resource-usage.plugins` parameter.
List of *emulators* shipped with GridMix:
* Cumulative CPU usage *emulator* :
GridMix uses the cumulative CPU usage value published by Rumen
and makes sure that the total cumulative CPU usage of the simulated
task is close to the value published by Rumen. GridMix can be
configured to emulate cumulative CPU usage by adding
`org.apache.hadoop.mapred.gridmix.emulators.resourceusage
.CumulativeCpuUsageEmulatorPlugin` to the list of emulator
*plugins* configured for the
`gridmix.emulators.resource-usage.plugins` parameter.
CPU usage emulator is designed in such a way that
it only emulates at specific progress boundaries of the task. This
interval can be configured using
`gridmix.emulators.resource-usage.cpu.emulation-interval`.
The default value for this parameter is `0.1` i.e
`10%`.
* Total heap usage *emulator* :
GridMix uses the total heap usage value published by Rumen
and makes sure that the total heap usage of the simulated
task is close to the value published by Rumen. GridMix can be
configured to emulate total heap usage by adding
`org.apache.hadoop.mapred.gridmix.emulators.resourceusage
.TotalHeapUsageEmulatorPlugin` to the list of emulator
*plugins* configured for the
`gridmix.emulators.resource-usage.plugins` parameter.
Heap usage emulator is designed in such a way that
it only emulates at specific progress boundaries of the task. This
interval can be configured using
`gridmix.emulators.resource-usage.heap.emulation-interval
`. The default value for this parameter is `0.1`
i.e `10%` progress interval.
Note that GridMix will emulate resource usages only for jobs of type *LOADJOB* .
Simplifying Assumptions
-----------------------
GridMix will be developed in stages, incorporating feedback and
patches from the community. Currently its intent is to evaluate
MapReduce and HDFS performance and not the layers on top of them (i.e.
the extensive lib and sub-project space). Given these two limitations,
the following characteristics of job load are not currently captured in
job traces and cannot be accurately reproduced in GridMix:
* *Filesystem Properties* - No attempt is made to match block
sizes, namespace hierarchies, or any property of input, intermediate
or output data other than the bytes/records consumed and emitted from
a given task. This implies that some of the most heavily-used parts of
the system - text processing, streaming, etc. - cannot be meaningfully tested
with the current implementation.
* *I/O Rates* - The rate at which records are
consumed/emitted is assumed to be limited only by the speed of the
reader/writer and constant throughout the task.
* *Memory Profile* - No data on tasks' memory usage over time
is available, though the max heap-size is retained.
* *Skew* - The records consumed and emitted to/from a given
task are assumed to follow observed averages, i.e. records will be
more regular than may be seen in the wild. Each map also generates
a proportional percentage of data for each reduce, so a job with
unbalanced input will be flattened.
* *Job Failure* - User code is assumed to be correct.
* *Job Independence* - The output or outcome of one job does
not affect when or whether a subsequent job will run.
Appendix
--------
Issues tracking the original implementations of
<a href="https://issues.apache.org/jira/browse/HADOOP-2369">GridMix1</a>,
<a href="https://issues.apache.org/jira/browse/HADOOP-3770">GridMix2</a>,
and <a href="https://issues.apache.org/jira/browse/MAPREDUCE-776">GridMix3</a>
can be found on the Apache Hadoop MapReduce JIRA. Other issues tracking
the current development of GridMix can be found by searching
<a href="https://issues.apache.org/jira/browse/MAPREDUCE/component/12313086">
the Apache Hadoop MapReduce JIRA</a>

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#set ( $H3 = '###' )
#set ( $H4 = '####' )
#set ( $H5 = '#####' )
Rumen
=====
---
- [Overview](#Overview)
- [Motivation](#Motivation)
- [Components](#Components)
- [How to use Rumen?](#How_to_use_Rumen)
- [Trace Builder](#Trace_Builder)
- [Example](#Example)
- [Folder](#Folder)
- [Examples](#Examples)
- [Appendix](#Appendix)
- [Resources](#Resources)
- [Dependencies](#Dependencies)
---
Overview
--------
*Rumen* is a data extraction and analysis tool built for
*Apache Hadoop*. *Rumen* mines *JobHistory* logs to
extract meaningful data and stores it in an easily-parsed, condensed
format or *digest*. The raw trace data from MapReduce logs are
often insufficient for simulation, emulation, and benchmarking, as these
tools often attempt to measure conditions that did not occur in the
source data. For example, if a task ran locally in the raw trace data
but a simulation of the scheduler elects to run that task on a remote
rack, the simulator requires a runtime its input cannot provide.
To fill in these gaps, Rumen performs a statistical analysis of the
digest to estimate the variables the trace doesn't supply. Rumen traces
drive both Gridmix (a benchmark of Hadoop MapReduce clusters) and Mumak
(a simulator for the JobTracker).
$H3 Motivation
* Extracting meaningful data from *JobHistory* logs is a common
task for any tool built to work on *MapReduce*. It
is tedious to write a custom tool which is so tightly coupled with
the *MapReduce* framework. Hence there is a need for a
built-in tool for performing framework level task of log parsing and
analysis. Such a tool would insulate external systems depending on
job history against the changes made to the job history format.
* Performing statistical analysis of various attributes of a
*MapReduce Job* such as *task runtimes, task failures
etc* is another common task that the benchmarking
and simulation tools might need. *Rumen* generates
<a href="http://en.wikipedia.org/wiki/Cumulative_distribution_function">
*Cumulative Distribution Functions (CDF)*
</a> for the Map/Reduce task runtimes.
Runtime CDF can be used for extrapolating the task runtime of
incomplete, missing and synthetic tasks. Similarly CDF is also
computed for the total number of successful tasks for every attempt.
$H3 Components
*Rumen* consists of 2 components
* *Trace Builder* :
Converts *JobHistory* logs into an easily-parsed format.
Currently `TraceBuilder` outputs the trace in
<a href="http://www.json.org/">*JSON*</a>
format.
* *Folder *:
A utility to scale the input trace. A trace obtained from
*TraceBuilder* simply summarizes the jobs in the
input folders and files. The time-span within which all the jobs in
a given trace finish can be considered as the trace runtime.
*Folder* can be used to scale the runtime of a trace.
Decreasing the trace runtime might involve dropping some jobs from
the input trace and scaling down the runtime of remaining jobs.
Increasing the trace runtime might involve adding some dummy jobs to
the resulting trace and scaling up the runtime of individual jobs.
How to use Rumen?
-----------------
Converting *JobHistory* logs into a desired job-trace consists of 2 steps
1. Extracting information into an intermediate format
2. Adjusting the job-trace obtained from the intermediate trace to
have the desired properties.
> Extracting information from *JobHistory* logs is a one time
> operation. This so called *Gold Trace* can be reused to
> generate traces with desired values of properties such as
> `output-duration`, `concentration` etc.
*Rumen* provides 2 basic commands
* `TraceBuilder`
* `Folder`
Firstly, we need to generate the *Gold Trace*. Hence the first
step is to run `TraceBuilder` on a job-history folder.
The output of the `TraceBuilder` is a job-trace file (and an
optional cluster-topology file). In case we want to scale the output, we
can use the `Folder` utility to fold the current trace to the
desired length. The remaining part of this section explains these
utilities in detail.
> Examples in this section assumes that certain libraries are present
> in the java CLASSPATH. See <em>Section-3.2</em> for more details.
$H3 Trace Builder
`Command:`
java org.apache.hadoop.tools.rumen.TraceBuilder [options] <jobtrace-output> <topology-output> <inputs>
This command invokes the `TraceBuilder` utility of
*Rumen*. It converts the JobHistory files into a series of JSON
objects and writes them into the `<jobtrace-output>`
file. It also extracts the cluster layout (topology) and writes it in
the`<topology-output>` file.
`<inputs>` represents a space-separated list of
JobHistory files and folders.
> 1) Input and output to `TraceBuilder` is expected to
> be a fully qualified FileSystem path. So use file://
> to specify files on the `local` FileSystem and
> hdfs:// to specify files on HDFS. Since input files or
> folder are FileSystem paths, it means that they can be globbed.
> This can be useful while specifying multiple file paths using
> regular expressions.
> 2) By default, TraceBuilder does not recursively scan the input
> folder for job history files. Only the files that are directly
> placed under the input folder will be considered for generating
> the trace. To add all the files under the input directory by
> recursively scanning the input directory, use -recursive
> option.
Cluster topology is used as follows :
* To reconstruct the splits and make sure that the
distances/latencies seen in the actual run are modeled correctly.
* To extrapolate splits information for tasks with missing splits
details or synthetically generated tasks.
`Options :`
<table>
<tr>
<th> Parameter</th>
<th> Description</th>
<th> Notes </th>
</tr>
<tr>
<td><code>-demuxer</code></td>
<td>Used to read the jobhistory files. The default is
<code>DefaultInputDemuxer</code>.</td>
<td>Demuxer decides how the input file maps to jobhistory file(s).
Job history logs and job configuration files are typically small
files, and can be more effectively stored when embedded in some
container file format like SequenceFile or TFile. To support such
usage cases, one can specify a customized Demuxer class that can
extract individual job history logs and job configuration files
from the source files.
</td>
</tr>
<tr>
<td><code>-recursive</code></td>
<td>Recursively traverse input paths for job history logs.</td>
<td>This option should be used to inform the TraceBuilder to
recursively scan the input paths and process all the files under it.
Note that, by default, only the history logs that are directly under
the input folder are considered for generating the trace.
</td>
</tr>
</table>
$H4 Example
java org.apache.hadoop.tools.rumen.TraceBuilder file:///home/user/job-trace.json file:///home/user/topology.output file:///home/user/logs/history/done
This will analyze all the jobs in
`/home/user/logs/history/done` stored on the
`local` FileSystem and output the jobtraces in
`/home/user/job-trace.json` along with topology
information in `/home/user/topology.output`.
$H3 Folder
`Command`:
java org.apache.hadoop.tools.rumen.Folder [options] [input] [output]
> Input and output to `Folder` is expected to be a fully
> qualified FileSystem path. So use file:// to specify
> files on the `local` FileSystem and hdfs:// to
> specify files on HDFS.
This command invokes the `Folder` utility of
*Rumen*. Folding essentially means that the output duration of
the resulting trace is fixed and job timelines are adjusted
to respect the final output duration.
`Options :`
<table>
<tr>
<th> Parameter</th>
<th> Description</th>
<th> Notes </th>
</tr>
<tr>
<td><code>-input-cycle</code></td>
<td>Defines the basic unit of time for the folding operation. There is
no default value for <code>input-cycle</code>.
<strong>Input cycle must be provided</strong>.
</td>
<td>'<code>-input-cycle 10m</code>'
implies that the whole trace run will be now sliced at a 10min
interval. Basic operations will be done on the 10m chunks. Note
that *Rumen* understands various time units like
<em>m(min), h(hour), d(days) etc</em>.
</td>
</tr>
<tr>
<td><code>-output-duration</code></td>
<td>This parameter defines the final runtime of the trace.
Default value if <strong>1 hour</strong>.
</td>
<td>'<code>-output-duration 30m</code>'
implies that the resulting trace will have a max runtime of
30mins. All the jobs in the input trace file will be folded and
scaled to fit this window.
</td>
</tr>
<tr>
<td><code>-concentration</code></td>
<td>Set the concentration of the resulting trace. Default value is
<strong>1</strong>.
</td>
<td>If the total runtime of the resulting trace is less than the total
runtime of the input trace, then the resulting trace would contain
lesser number of jobs as compared to the input trace. This
essentially means that the output is diluted. To increase the
density of jobs, set the concentration to a higher value.</td>
</tr>
<tr>
<td><code>-debug</code></td>
<td>Run the Folder in debug mode. By default it is set to
<strong>false</strong>.</td>
<td>In debug mode, the Folder will print additional statements for
debugging. Also the intermediate files generated in the scratch
directory will not be cleaned up.
</td>
</tr>
<tr>
<td><code>-seed</code></td>
<td>Initial seed to the Random Number Generator. By default, a Random
Number Generator is used to generate a seed and the seed value is
reported back to the user for future use.
</td>
<td>If an initial seed is passed, then the <code>Random Number
Generator</code> will generate the random numbers in the same
sequence i.e the sequence of random numbers remains same if the
same seed is used. Folder uses Random Number Generator to decide
whether or not to emit the job.
</td>
</tr>
<tr>
<td><code>-temp-directory</code></td>
<td>Temporary directory for the Folder. By default the <strong>output
folder's parent directory</strong> is used as the scratch space.
</td>
<td>This is the scratch space used by Folder. All the
temporary files are cleaned up in the end unless the Folder is run
in <code>debug</code> mode.</td>
</tr>
<tr>
<td><code>-skew-buffer-length</code></td>
<td>Enables <em>Folder</em> to tolerate skewed jobs.
The default buffer length is <strong>0</strong>.</td>
<td>'<code>-skew-buffer-length 100</code>'
indicates that if the jobs appear out of order within a window
size of 100, then they will be emitted in-order by the folder.
If a job appears out-of-order outside this window, then the Folder
will bail out provided <code>-allow-missorting</code> is not set.
<em>Folder</em> reports the maximum skew size seen in the
input trace for future use.
</td>
</tr>
<tr>
<td><code>-allow-missorting</code></td>
<td>Enables <em>Folder</em> to tolerate out-of-order jobs. By default
mis-sorting is not allowed.
</td>
<td>If mis-sorting is allowed, then the <em>Folder</em> will ignore
out-of-order jobs that cannot be deskewed using a skew buffer of
size specified using <code>-skew-buffer-length</code>. If
mis-sorting is not allowed, then the Folder will bail out if the
skew buffer is incapable of tolerating the skew.
</td>
</tr>
</table>
$H4 Examples
$H5 Folding an input trace with 10 hours of total runtime to generate an output trace with 1 hour of total runtime
java org.apache.hadoop.tools.rumen.Folder -output-duration 1h -input-cycle 20m file:///home/user/job-trace.json file:///home/user/job-trace-1hr.json
If the folded jobs are out of order then the command will bail out.
$H5 Folding an input trace with 10 hours of total runtime to generate an output trace with 1 hour of total runtime and tolerate some skewness
java org.apache.hadoop.tools.rumen.Folder -output-duration 1h -input-cycle 20m -allow-missorting -skew-buffer-length 100 file:///home/user/job-trace.json file:///home/user/job-trace-1hr.json
If the folded jobs are out of order, then atmost
100 jobs will be de-skewed. If the 101<sup>st</sup> job is
*out-of-order*, then the command will bail out.
$H5 Folding an input trace with 10 hours of total runtime to generate an output trace with 1 hour of total runtime in debug mode
java org.apache.hadoop.tools.rumen.Folder -output-duration 1h -input-cycle 20m -debug -temp-directory file:///tmp/debug file:///home/user/job-trace.json file:///home/user/job-trace-1hr.json
This will fold the 10hr job-trace file
`file:///home/user/job-trace.json` to finish within 1hr
and use `file:///tmp/debug` as the temporary directory.
The intermediate files in the temporary directory will not be cleaned
up.
$H5 Folding an input trace with 10 hours of total runtime to generate an output trace with 1 hour of total runtime with custom concentration.
java org.apache.hadoop.tools.rumen.Folder -output-duration 1h -input-cycle 20m -concentration 2 file:///home/user/job-trace.json file:///home/user/job-trace-1hr.json</source>
This will fold the 10hr job-trace file
`file:///home/user/job-trace.json` to finish within 1hr
with concentration of 2. `Example-2.3.2` will retain 10%
of the jobs. With *concentration* as 2, 20% of the total input
jobs will be retained.
Appendix
--------
$H3 Resources
<a href="https://issues.apache.org/jira/browse/MAPREDUCE-751">MAPREDUCE-751</a>
is the main JIRA that introduced *Rumen* to *MapReduce*.
Look at the MapReduce
<a href="https://issues.apache.org/jira/browse/MAPREDUCE/component/12313617">
rumen-component</a>for further details.
$H3 Dependencies
*Rumen* expects certain library *JARs* to be present in
the *CLASSPATH*. The required libraries are
* `Hadoop MapReduce Tools` (`hadoop-mapred-tools-{hadoop-version}.jar`)
* `Hadoop Common` (`hadoop-common-{hadoop-version}.jar`)
* `Apache Commons Logging` (`commons-logging-1.1.1.jar`)
* `Apache Commons CLI` (`commons-cli-1.2.jar`)
* `Jackson Mapper` (`jackson-mapper-asl-1.4.2.jar`)
* `Jackson Core` (`jackson-core-asl-1.4.2.jar`)
> One simple way to run Rumen is to use '$HADOOP_HOME/bin/hadoop jar'
> option to run it.