hadoop-hdfs-project/hadoop-hdfs/src/site/markdown/HdfsImageViewer.md - hadoop - Git at Google

 <!---
   Licensed under the Apache License, Version 2.0 (the "License");
   you may not use this file except in compliance with the License.
   You may obtain a copy of the License at

    http://www.apache.org/licenses/LICENSE-2.0

   Unless required by applicable law or agreed to in writing, software
   distributed under the License is distributed on an "AS IS" BASIS,
   WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
   See the License for the specific language governing permissions and
   limitations under the License. See accompanying LICENSE file.
 -->

 Offline Image Viewer Guide
 ==========================

 <!-- MACRO{toc|fromDepth=0|toDepth=3} -->

 Overview
 --------

 The Offline Image Viewer is a tool to dump the contents of hdfs fsimage files to a human-readable format and provide read-only WebHDFS API in order to allow offline analysis and examination of an Hadoop cluster's namespace. The tool is able to process very large image files relatively quickly. The tool handles the layout formats that were included with Hadoop versions 2.4 and up. If you want to handle older layout formats, you can use the Offline Image Viewer of Hadoop 2.3 or [oiv\_legacy Command](#oiv_legacy_Command). If the tool is not able to process an image file, it will exit cleanly. The Offline Image Viewer does not require a Hadoop cluster to be running; it is entirely offline in its operation.

 The Offline Image Viewer provides several output processors:

 1.  Web is the default output processor. It launches a HTTP server
     that exposes read-only WebHDFS API. Users can investigate the namespace
     interactively by using HTTP REST API. It does not support secure mode, nor
     HTTPS.

 2.  XML creates an XML document of the fsimage and includes all of the
     information within the fsimage. The
     output of this processor is amenable to automated processing and
     analysis with XML tools. Due to the verbosity of the XML syntax,
     this processor will also generate the largest amount of output.

 3.  FileDistribution is the tool for analyzing file sizes in the
     namespace image. In order to run the tool one should define a range
     of integers [0, maxSize] by specifying maxSize and a step. The
     range of integers is divided into segments of size step: [0, s[1],
     ..., s[n-1], maxSize], and the processor calculates how many files
     in the system fall into each segment [s[i-1], s[i]). Note that
     files larger than maxSize always fall into the very last segment.
     By default, the output file is formatted as a tab separated two column
     table: Size and NumFiles. Where Size represents the start of the segment,
     and numFiles is the number of files form the image which size falls
     in this segment. By specifying the option -format, the output file will be
     formatted in a human-readable fashion rather than a number of bytes that
     showed in Size column. In addition, the Size column will be changed to the
     Size Range column.

 4. Delimited (experimental): Generate a text file with all of the elements
    common to both inodes and inodes-under-construction, separated by a
    delimiter. The default delimiter is \t, though this may be changed via
    the -delimiter argument.

 5. DetectCorruption (experimental): Detect potential corruption of the image
    by selectively loading parts of it and actively searching for
    inconsistencies. Outputs a summary of the found corruptions
    in a delimited format. Note that the check is not exhaustive,
    and only catches missing nodes during the namespace reconstruction.

 6. ReverseXML (experimental): This is the opposite of the XML processor;
    it reconstructs an fsimage from an XML file. This processor makes it easy to
    create fsimages for testing, and manually edit fsimages when there is
    corruption.

 Usage
 -----

 ### Web Processor

 Web processor launches a HTTP server which exposes read-only WebHDFS API. Users can specify the address to listen by -addr option (default by localhost:5978).

        bash$ bin/hdfs oiv -i fsimage
        14/04/07 13:25:14 INFO offlineImageViewer.WebImageViewer: WebImageViewer
        started. Listening on /127.0.0.1:5978. Press Ctrl+C to stop the viewer.

 Users can access the viewer and get the information of the fsimage by the following shell command:

        bash$ bin/hdfs dfs -ls webhdfs://127.0.0.1:5978/
        Found 2 items
        drwxrwx--* - root supergroup          0 2014-03-26 20:16 webhdfs://127.0.0.1:5978/tmp
        drwxr-xr-x   - root supergroup          0 2014-03-31 14:08 webhdfs://127.0.0.1:5978/user

 To get the information of all the files and directories, you can simply use the following command:

        bash$ bin/hdfs dfs -ls -R webhdfs://127.0.0.1:5978/

 Users can also get JSON formatted FileStatuses via HTTP REST API.

        bash$ curl -i http://127.0.0.1:5978/webhdfs/v1/?op=liststatus
        HTTP/1.1 200 OK
        Content-Type: application/json
        Content-Length: 252

        {"FileStatuses":{"FileStatus":[
        {"fileId":16386,"accessTime":0,"replication":0,"owner":"theuser","length":0,"permission":"755","blockSize":0,"modificationTime":1392772497282,"type":"DIRECTORY","group":"supergroup","childrenNum":1,"pathSuffix":"user"}
        ]}}

 The Web processor now supports the following operations:

 * [LISTSTATUS](./WebHDFS.html#List_a_Directory)
 * [GETFILESTATUS](./WebHDFS.html#Status_of_a_FileDirectory)
 * [GETACLSTATUS](./WebHDFS.html#Get_ACL_Status)
 * [GETXATTRS](./WebHDFS.html#Get_an_XAttr)
 * [LISTXATTRS](./WebHDFS.html#List_all_XAttrs)
 * [CONTENTSUMMARY](./WebHDFS.html#Get_Content_Summary_of_a_Directory)

 ### XML Processor

 XML Processor is used to dump all the contents in the fsimage. Users can specify input and output file via -i and -o command-line.

        bash$ bin/hdfs oiv -p XML -i fsimage -o fsimage.xml

 This will create a file named fsimage.xml contains all the information in the fsimage. For very large image files, this process may take several minutes.

 Applying the Offline Image Viewer with XML processor would result in the following output:

        <?xml version="1.0"?>
        <fsimage>
        <NameSection>
          <genstampV1>1000</genstampV1>
          <genstampV2>1002</genstampV2>
          <genstampV1Limit>0</genstampV1Limit>
          <lastAllocatedBlockId>1073741826</lastAllocatedBlockId>
          <txid>37</txid>
        </NameSection>
        <INodeSection>
          <lastInodeId>16400</lastInodeId>
          <inode>
            <id>16385</id>
            <type>DIRECTORY</type>
            <name></name>
            <mtime>1392772497282</mtime>
            <permission>theuser:supergroup:rwxr-xr-x</permission>
            <nsquota>9223372036854775807</nsquota>
            <dsquota>-1</dsquota>
          </inode>
        ...remaining output omitted...

 ### ReverseXML Processor

 ReverseXML processor is the opposite of the XML processor. Users can specify input XML file and output fsimage file via -i and -o command-line.

        bash$ bin/hdfs oiv -p ReverseXML -i fsimage.xml -o fsimage

 This will reconstruct an fsimage from an XML file.

 ### FileDistribution Processor

 FileDistribution processor can analyze file sizes in the namespace image. Users can specify maxSize (128GB by default) and step (2MB by default) in bytes via -maxSize and -step command-line.

        bash$ bin/hdfs oiv -p FileDistribution -maxSize maxSize -step size -i fsimage -o output

 The processor will calculate how many files in the system fall into each segment. The output file is formatted as a tab separated two column table showed as the following output:

        Size	NumFiles
        4	1
        12	1
        16	1
        20	1
        totalFiles = 4
        totalDirectories = 2
        totalBlocks = 4
        totalSpace = 48
        maxFileSize = 21

 To make the output result look more readable, users can specify -format option in addition.

        bash$ bin/hdfs oiv -p FileDistribution -maxSize maxSize -step size -format -i fsimage -o output

 This would result in the following output:

        Size Range	NumFiles
        (0 B, 4 B]	1
        (8 B, 12 B]	1
        (12 B, 16 B]	1
        (16 B, 21 B]	1
        totalFiles = 4
        totalDirectories = 2
        totalBlocks = 4
        totalSpace = 48
        maxFileSize = 21

 ### Delimited Processor

 Delimited processor generates a text representation of the fsimage, with each element separated by a delimiter string (\t by default). Users can specify a new delimiter string by -delimiter option.

        bash$ bin/hdfs oiv -p Delimited -delimiter delimiterString -i fsimage -o output

 In addition, users can specify a temporary dir to cache intermediate result by the following command:

        bash$ bin/hdfs oiv -p Delimited -delimiter delimiterString -t temporaryDir -i fsimage -o output

 If not set, Delimited processor will construct the namespace in memory before outputting text. The output result of this processor should be like the following output:

        Path	Replication	ModificationTime	AccessTime	PreferredBlockSize	BlocksCount	FileSize	NSQUOTA	DSQUOTA	Permission	UserName	GroupName
        /	0	2017-02-13 10:39	1970-01-01 08:00	0	0	0	9223372036854775807	-1	drwxr-xr-x	root	supergroup
        /dir0	0	2017-02-13 10:39	1970-01-01 08:00	0	0	0	-1	-1	drwxr-xr-x	root	supergroup
        /dir0/file0	1	2017-02-13 10:39	2017-02-13 10:39	134217728	1	1	0	0	-rw-r--r--	root	supergroup
        /dir0/file1	1	2017-02-13 10:39	2017-02-13 10:39	134217728	1	1	0	0	-rw-r--r--	root	supergroup
        /dir0/file2	1	2017-02-13 10:39	2017-02-13 10:39	134217728	1	1	0	0	-rw-r--r--	root	supergroup

 ### DetectCorruption Processor

 DetectCorruption processor generates a text representation of the errors of the fsimage, if there's any. It displays the following cases:

 1.  an inode is mentioned in the fsimage but no associated metadata is found (CorruptNode)

 2.  an inode has at least one corrupt children (MissingChildren)

 The delimiter string can be provided with the -delimiter option, and the processor can cache intermediate result using the -t option.

         bash$ bin/hdfs oiv -p DetectCorruption -delimiter delimiterString -t temporaryDir -i fsimage -o output

 The output result of this processor is empty if no corruption is found, otherwise the found entries in the following format:

         CorruptionType	Id	IsSnapshot	ParentPath	ParentId	Name	NodeType	CorruptChildren
         MissingChild	16385	false	/	Missing		Node	1
         MissingChild	16386	false	/	16385	dir0	Node	2
         CorruptNode	16388	true		16386		Unknown	0
         CorruptNode	16389	true		16386		Unknown	0
         CorruptNodeWithMissingChild	16391	true		16385		Unknown	1
         CorruptNode	16394	true		16391		Unknown	0

 The column CorruptionType can be MissingChild, CorruptNode or the combination of these two. IsSnapshot shows whether the node is kept in a snapshot or not. To the NodeType column either Node, Ref or Unknown can be written depending whether the node is an inode, a reference, or is corrupted and thus unknown. CorruptChildren contains the number of the corrupt children the inode may have.

 Options
 -------

 | **Flag** | **Description** |
 |:---- |:---- |
 | `-i`\|`--inputFile` *input file* | Specify the input fsimage file (or XML file, if ReverseXML processor is used) to process. Required. |
 | `-o`\|`--outputFile` *output file* | Specify the output filename, if the specified output processor generates one. If the specified file already exists, it is silently overwritten. (output to stdout by default) If the input file is an XML file, it also creates an &lt;outputFile&gt;.md5. |
 | `-p`\|`--processor` *processor* | Specify the image processor to apply against the image file. Currently valid options are `Web` (default), `XML`, `Delimited`, `DetectCorruption`, `FileDistribution` and `ReverseXML`. |
 | `-addr` *address* | Specify the address(host:port) to listen. (localhost:5978 by default). This option is used with Web processor. |
 | `-maxSize` *size* | Specify the range [0, maxSize] of file sizes to be analyzed in bytes (128GB by default). This option is used with FileDistribution processor. |
 | `-step` *size* | Specify the granularity of the distribution in bytes (2MB by default). This option is used with FileDistribution processor. |
 | `-format` | Format the output result in a human-readable fashion rather than a number of bytes. (false by default). This option is used with FileDistribution processor. |
 | `-delimiter` *arg* | Delimiting string to use with Delimited or DetectCorruption processor. |
 | `-t`\|`--temp` *temporary dir* | Use temporary dir to cache intermediate result to generate Delimited outputs. If not set, Delimited processor constructs the namespace in memory before outputting text. |
 | `-h`\|`--help` | Display the tool usage and help information and exit. |

 Analyzing Results
 -----------------

 The Offline Image Viewer makes it easy to gather large amounts of data about the hdfs namespace. This information can then be used to explore file system usage patterns or find specific files that match arbitrary criteria, along with other types of namespace analysis.

 oiv\_legacy Command
 -------------------

 Due to the internal layout changes introduced by the ProtocolBuffer-based fsimage ([HDFS-5698](https://issues.apache.org/jira/browse/HDFS-5698)), OfflineImageViewer consumes excessive amount of memory and loses some functions such as Indented processor. If you want to process without large amount of memory or use these processors, you can use `oiv_legacy` command (same as `oiv` in Hadoop 2.3).

 ### Usage

 1. Set `dfs.namenode.legacy-oiv-image.dir` to an appropriate directory
    to make standby NameNode or SecondaryNameNode save its namespace in the
    old fsimage format during checkpointing.

 2. Use `oiv_legacy` command to the old format fsimage.

         bash$ bin/hdfs oiv_legacy -i fsimage_old -o output

 ### Options

 | **Flag** | **Description** |
 |:---- |:---- |
 | `-i`\|`--inputFile` *input file* | Specify the input fsimage file to process. Required. |
 | `-o`\|`--outputFile` *output file* | Specify the output filename, if the specified output processor generates one. If the specified file already exists, it is silently overwritten. Required. |
 | `-p`\|`--processor` *processor* | Specify the image processor to apply against the image file. Valid options are Ls (default), XML, Delimited, Indented, FileDistribution and NameDistribution. |
 | `-maxSize` *size* | Specify the range [0, maxSize] of file sizes to be analyzed in bytes (128GB by default). This option is used with FileDistribution processor. |
 | `-step` *size* | Specify the granularity of the distribution in bytes (2MB by default). This option is used with FileDistribution processor. |
 | `-format` | Format the output result in a human-readable fashion rather than a number of bytes. (false by default). This option is used with FileDistribution processor. |
 | `-skipBlocks` | Do not enumerate individual blocks within files. This may save processing time and outfile file space on namespaces with very large files. The Ls processor reads the blocks to correctly determine file sizes and ignores this option. |
 | `-printToScreen` | Pipe output of processor to console as well as specified file. On extremely large namespaces, this may increase processing time by an order of magnitude. |
 | `-delimiter` *arg* | When used in conjunction with the Delimited processor, replaces the default tab delimiter with the string specified by *arg*. |
 | `-h`\|`--help` | Display the tool usage and help information and exit. |
	<!---
	Licensed under the Apache License, Version 2.0 (the "License");
	you may not use this file except in compliance with the License.
	You may obtain a copy of the License at

	http://www.apache.org/licenses/LICENSE-2.0

	Unless required by applicable law or agreed to in writing, software
	distributed under the License is distributed on an "AS IS" BASIS,
	WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	See the License for the specific language governing permissions and
	limitations under the License. See accompanying LICENSE file.
	-->

	Offline Image Viewer Guide
	==========================

	<!-- MACRO{toc\|fromDepth=0\|toDepth=3} -->

	Overview
	--------

	The Offline Image Viewer is a tool to dump the contents of hdfs fsimage files to a human-readable format and provide read-only WebHDFS API in order to allow offline analysis and examination of an Hadoop cluster's namespace. The tool is able to process very large image files relatively quickly. The tool handles the layout formats that were included with Hadoop versions 2.4 and up. If you want to handle older layout formats, you can use the Offline Image Viewer of Hadoop 2.3 or [oiv\_legacy Command](#oiv_legacy_Command). If the tool is not able to process an image file, it will exit cleanly. The Offline Image Viewer does not require a Hadoop cluster to be running; it is entirely offline in its operation.

	The Offline Image Viewer provides several output processors:

	1. Web is the default output processor. It launches a HTTP server
	that exposes read-only WebHDFS API. Users can investigate the namespace
	interactively by using HTTP REST API. It does not support secure mode, nor
	HTTPS.

	2. XML creates an XML document of the fsimage and includes all of the
	information within the fsimage. The
	output of this processor is amenable to automated processing and
	analysis with XML tools. Due to the verbosity of the XML syntax,
	this processor will also generate the largest amount of output.

	3. FileDistribution is the tool for analyzing file sizes in the
	namespace image. In order to run the tool one should define a range
	of integers [0, maxSize] by specifying maxSize and a step. The
	range of integers is divided into segments of size step: [0, s[1],
	..., s[n-1], maxSize], and the processor calculates how many files
	in the system fall into each segment [s[i-1], s[i]). Note that
	files larger than maxSize always fall into the very last segment.
	By default, the output file is formatted as a tab separated two column
	table: Size and NumFiles. Where Size represents the start of the segment,
	and numFiles is the number of files form the image which size falls
	in this segment. By specifying the option -format, the output file will be
	formatted in a human-readable fashion rather than a number of bytes that
	showed in Size column. In addition, the Size column will be changed to the
	Size Range column.

	4. Delimited (experimental): Generate a text file with all of the elements
	common to both inodes and inodes-under-construction, separated by a
	delimiter. The default delimiter is \t, though this may be changed via
	the -delimiter argument.

	5. DetectCorruption (experimental): Detect potential corruption of the image
	by selectively loading parts of it and actively searching for
	inconsistencies. Outputs a summary of the found corruptions
	in a delimited format. Note that the check is not exhaustive,
	and only catches missing nodes during the namespace reconstruction.

	6. ReverseXML (experimental): This is the opposite of the XML processor;
	it reconstructs an fsimage from an XML file. This processor makes it easy to
	create fsimages for testing, and manually edit fsimages when there is
	corruption.

	Usage
	-----

	### Web Processor

	Web processor launches a HTTP server which exposes read-only WebHDFS API. Users can specify the address to listen by -addr option (default by localhost:5978).

	bash$ bin/hdfs oiv -i fsimage
	14/04/07 13:25:14 INFO offlineImageViewer.WebImageViewer: WebImageViewer
	started. Listening on /127.0.0.1:5978. Press Ctrl+C to stop the viewer.

	Users can access the viewer and get the information of the fsimage by the following shell command:

	bash$ bin/hdfs dfs -ls webhdfs://127.0.0.1:5978/
	Found 2 items
	drwxrwx--* - root supergroup 0 2014-03-26 20:16 webhdfs://127.0.0.1:5978/tmp
	drwxr-xr-x - root supergroup 0 2014-03-31 14:08 webhdfs://127.0.0.1:5978/user

	To get the information of all the files and directories, you can simply use the following command:

	bash$ bin/hdfs dfs -ls -R webhdfs://127.0.0.1:5978/

	Users can also get JSON formatted FileStatuses via HTTP REST API.

	bash$ curl -i http://127.0.0.1:5978/webhdfs/v1/?op=liststatus
	HTTP/1.1 200 OK
	Content-Type: application/json
	Content-Length: 252

	{"FileStatuses":{"FileStatus":[
	{"fileId":16386,"accessTime":0,"replication":0,"owner":"theuser","length":0,"permission":"755","blockSize":0,"modificationTime":1392772497282,"type":"DIRECTORY","group":"supergroup","childrenNum":1,"pathSuffix":"user"}
	]}}

	The Web processor now supports the following operations:

	* [LISTSTATUS](./WebHDFS.html#List_a_Directory)
	* [GETFILESTATUS](./WebHDFS.html#Status_of_a_FileDirectory)
	* [GETACLSTATUS](./WebHDFS.html#Get_ACL_Status)
	* [GETXATTRS](./WebHDFS.html#Get_an_XAttr)
	* [LISTXATTRS](./WebHDFS.html#List_all_XAttrs)
	* [CONTENTSUMMARY](./WebHDFS.html#Get_Content_Summary_of_a_Directory)

	### XML Processor

	XML Processor is used to dump all the contents in the fsimage. Users can specify input and output file via -i and -o command-line.

	bash$ bin/hdfs oiv -p XML -i fsimage -o fsimage.xml

	This will create a file named fsimage.xml contains all the information in the fsimage. For very large image files, this process may take several minutes.

	Applying the Offline Image Viewer with XML processor would result in the following output:

	<?xml version="1.0"?>
	<fsimage>
	<NameSection>
	<genstampV1>1000</genstampV1>
	<genstampV2>1002</genstampV2>
	<genstampV1Limit>0</genstampV1Limit>
	<lastAllocatedBlockId>1073741826</lastAllocatedBlockId>
	<txid>37</txid>
	</NameSection>
	<INodeSection>
	<lastInodeId>16400</lastInodeId>
	<inode>
	<id>16385</id>
	<type>DIRECTORY</type>
	<name></name>
	<mtime>1392772497282</mtime>
	<permission>theuser:supergroup:rwxr-xr-x</permission>
	<nsquota>9223372036854775807</nsquota>
	<dsquota>-1</dsquota>
	</inode>
	...remaining output omitted...

	### ReverseXML Processor

	ReverseXML processor is the opposite of the XML processor. Users can specify input XML file and output fsimage file via -i and -o command-line.

	bash$ bin/hdfs oiv -p ReverseXML -i fsimage.xml -o fsimage

	This will reconstruct an fsimage from an XML file.

	### FileDistribution Processor

	FileDistribution processor can analyze file sizes in the namespace image. Users can specify maxSize (128GB by default) and step (2MB by default) in bytes via -maxSize and -step command-line.

	bash$ bin/hdfs oiv -p FileDistribution -maxSize maxSize -step size -i fsimage -o output

	The processor will calculate how many files in the system fall into each segment. The output file is formatted as a tab separated two column table showed as the following output:

	Size NumFiles
	4 1
	12 1
	16 1
	20 1
	totalFiles = 4
	totalDirectories = 2
	totalBlocks = 4
	totalSpace = 48
	maxFileSize = 21

	To make the output result look more readable, users can specify -format option in addition.

	bash$ bin/hdfs oiv -p FileDistribution -maxSize maxSize -step size -format -i fsimage -o output

	This would result in the following output:

	Size Range NumFiles
	(0 B, 4 B] 1
	(8 B, 12 B] 1
	(12 B, 16 B] 1
	(16 B, 21 B] 1
	totalFiles = 4
	totalDirectories = 2
	totalBlocks = 4
	totalSpace = 48
	maxFileSize = 21

	### Delimited Processor

	Delimited processor generates a text representation of the fsimage, with each element separated by a delimiter string (\t by default). Users can specify a new delimiter string by -delimiter option.

	bash$ bin/hdfs oiv -p Delimited -delimiter delimiterString -i fsimage -o output

	In addition, users can specify a temporary dir to cache intermediate result by the following command:

	bash$ bin/hdfs oiv -p Delimited -delimiter delimiterString -t temporaryDir -i fsimage -o output

	If not set, Delimited processor will construct the namespace in memory before outputting text. The output result of this processor should be like the following output:

	Path Replication ModificationTime AccessTime PreferredBlockSize BlocksCount FileSize NSQUOTA DSQUOTA Permission UserName GroupName
	/ 0 2017-02-13 10:39 1970-01-01 08:00 0 0 0 9223372036854775807 -1 drwxr-xr-x root supergroup
	/dir0 0 2017-02-13 10:39 1970-01-01 08:00 0 0 0 -1 -1 drwxr-xr-x root supergroup
	/dir0/file0 1 2017-02-13 10:39 2017-02-13 10:39 134217728 1 1 0 0 -rw-r--r-- root supergroup
	/dir0/file1 1 2017-02-13 10:39 2017-02-13 10:39 134217728 1 1 0 0 -rw-r--r-- root supergroup
	/dir0/file2 1 2017-02-13 10:39 2017-02-13 10:39 134217728 1 1 0 0 -rw-r--r-- root supergroup

	### DetectCorruption Processor

	DetectCorruption processor generates a text representation of the errors of the fsimage, if there's any. It displays the following cases:

	1. an inode is mentioned in the fsimage but no associated metadata is found (CorruptNode)

	2. an inode has at least one corrupt children (MissingChildren)

	The delimiter string can be provided with the -delimiter option, and the processor can cache intermediate result using the -t option.

	bash$ bin/hdfs oiv -p DetectCorruption -delimiter delimiterString -t temporaryDir -i fsimage -o output

	The output result of this processor is empty if no corruption is found, otherwise the found entries in the following format:

	CorruptionType Id IsSnapshot ParentPath ParentId Name NodeType CorruptChildren
	MissingChild 16385 false / Missing Node 1
	MissingChild 16386 false / 16385 dir0 Node 2
	CorruptNode 16388 true 16386 Unknown 0
	CorruptNode 16389 true 16386 Unknown 0
	CorruptNodeWithMissingChild 16391 true 16385 Unknown 1
	CorruptNode 16394 true 16391 Unknown 0

	The column CorruptionType can be MissingChild, CorruptNode or the combination of these two. IsSnapshot shows whether the node is kept in a snapshot or not. To the NodeType column either Node, Ref or Unknown can be written depending whether the node is an inode, a reference, or is corrupted and thus unknown. CorruptChildren contains the number of the corrupt children the inode may have.

	Options
	-------

	\| Flag \| Description \|
	\|:---- \|:---- \|
	\| `-i`\\|`--inputFile` input file \| Specify the input fsimage file (or XML file, if ReverseXML processor is used) to process. Required. \|
	\| `-o`\\|`--outputFile` output file \| Specify the output filename, if the specified output processor generates one. If the specified file already exists, it is silently overwritten. (output to stdout by default) If the input file is an XML file, it also creates an <outputFile>.md5. \|
	\| `-p`\\|`--processor` processor \| Specify the image processor to apply against the image file. Currently valid options are `Web` (default), `XML`, `Delimited`, `DetectCorruption`, `FileDistribution` and `ReverseXML`. \|
	\| `-addr` address \| Specify the address(host:port) to listen. (localhost:5978 by default). This option is used with Web processor. \|
	\| `-maxSize` size \| Specify the range [0, maxSize] of file sizes to be analyzed in bytes (128GB by default). This option is used with FileDistribution processor. \|
	\| `-step` size \| Specify the granularity of the distribution in bytes (2MB by default). This option is used with FileDistribution processor. \|
	\| `-format` \| Format the output result in a human-readable fashion rather than a number of bytes. (false by default). This option is used with FileDistribution processor. \|
	\| `-delimiter` arg \| Delimiting string to use with Delimited or DetectCorruption processor. \|
	\| `-t`\\|`--temp` temporary dir \| Use temporary dir to cache intermediate result to generate Delimited outputs. If not set, Delimited processor constructs the namespace in memory before outputting text. \|
	\| `-h`\\|`--help` \| Display the tool usage and help information and exit. \|

	Analyzing Results
	-----------------

	The Offline Image Viewer makes it easy to gather large amounts of data about the hdfs namespace. This information can then be used to explore file system usage patterns or find specific files that match arbitrary criteria, along with other types of namespace analysis.

	oiv\_legacy Command
	-------------------

	Due to the internal layout changes introduced by the ProtocolBuffer-based fsimage ([HDFS-5698](https://issues.apache.org/jira/browse/HDFS-5698)), OfflineImageViewer consumes excessive amount of memory and loses some functions such as Indented processor. If you want to process without large amount of memory or use these processors, you can use `oiv_legacy` command (same as `oiv` in Hadoop 2.3).

	### Usage

	1. Set `dfs.namenode.legacy-oiv-image.dir` to an appropriate directory
	to make standby NameNode or SecondaryNameNode save its namespace in the
	old fsimage format during checkpointing.

	2. Use `oiv_legacy` command to the old format fsimage.

	bash$ bin/hdfs oiv_legacy -i fsimage_old -o output

	### Options

	\| Flag \| Description \|
	\|:---- \|:---- \|
	\| `-i`\\|`--inputFile` input file \| Specify the input fsimage file to process. Required. \|
	\| `-o`\\|`--outputFile` output file \| Specify the output filename, if the specified output processor generates one. If the specified file already exists, it is silently overwritten. Required. \|
	\| `-p`\\|`--processor` processor \| Specify the image processor to apply against the image file. Valid options are Ls (default), XML, Delimited, Indented, FileDistribution and NameDistribution. \|
	\| `-maxSize` size \| Specify the range [0, maxSize] of file sizes to be analyzed in bytes (128GB by default). This option is used with FileDistribution processor. \|
	\| `-step` size \| Specify the granularity of the distribution in bytes (2MB by default). This option is used with FileDistribution processor. \|
	\| `-format` \| Format the output result in a human-readable fashion rather than a number of bytes. (false by default). This option is used with FileDistribution processor. \|
	\| `-skipBlocks` \| Do not enumerate individual blocks within files. This may save processing time and outfile file space on namespaces with very large files. The Ls processor reads the blocks to correctly determine file sizes and ignores this option. \|
	\| `-printToScreen` \| Pipe output of processor to console as well as specified file. On extremely large namespaces, this may increase processing time by an order of magnitude. \|
	\| `-delimiter` arg \| When used in conjunction with the Delimited processor, replaces the default tab delimiter with the string specified by arg. \|
	\| `-h`\\|`--help` \| Display the tool usage and help information and exit. \|