.\"t .\" Automatically generated by Pandoc 1.16.0.2 .\" .TH "mergerfs" "1" "2017\-05\-26" "mergerfs user manual" "" .hy .SH NAME .PP mergerfs \- a featureful union filesystem .SH SYNOPSIS .PP mergerfs \-o .SH DESCRIPTION .PP \f[B]mergerfs\f[] is a union filesystem geared towards simplifying storage and management of files across numerous commodity storage devices. It is similar to \f[B]mhddfs\f[], \f[B]unionfs\f[], and \f[B]aufs\f[]. .SH FEATURES .IP \[bu] 2 Runs in userspace (FUSE) .IP \[bu] 2 Configurable behaviors .IP \[bu] 2 Support for extended attributes (xattrs) .IP \[bu] 2 Support for file attributes (chattr) .IP \[bu] 2 Runtime configurable (via xattrs) .IP \[bu] 2 Safe to run as root .IP \[bu] 2 Opportunistic credential caching .IP \[bu] 2 Works with heterogeneous filesystem types .IP \[bu] 2 Handling of writes to full drives (transparently move file to drive with capacity) .IP \[bu] 2 Handles pool of readonly and read/write drives .IP \[bu] 2 Turn read\-only files into symlinks to increase read performance .SH OPTIONS .SS mount options .IP \[bu] 2 \f[B]defaults\f[]: a shortcut for FUSE\[aq]s \f[B]atomic_o_trunc\f[], \f[B]auto_cache\f[], \f[B]big_writes\f[], \f[B]default_permissions\f[], \f[B]splice_move\f[], \f[B]splice_read\f[], and \f[B]splice_write\f[]. These options seem to provide the best performance. .IP \[bu] 2 \f[B]direct_io\f[]: causes FUSE to bypass caching which can increase write speeds at the detriment of reads. Note that not enabling \f[C]direct_io\f[] will cause double caching of files and therefore less memory for caching generally. However, \f[C]mmap\f[] does not work when \f[C]direct_io\f[] is enabled. .IP \[bu] 2 \f[B]minfreespace\f[]: the minimum space value used for creation policies. Understands \[aq]K\[aq], \[aq]M\[aq], and \[aq]G\[aq] to represent kilobyte, megabyte, and gigabyte respectively. (default: 4G) .IP \[bu] 2 \f[B]moveonenospc\f[]: when enabled (set to \f[B]true\f[]) if a \f[B]write\f[] fails with \f[B]ENOSPC\f[] or \f[B]EDQUOT\f[] a scan of all drives will be done looking for the drive with most free space which is at least the size of the file plus the amount which failed to write. An attempt to move the file to that drive will occur (keeping all metadata possible) and if successful the original is unlinked and the write retried. (default: false) .IP \[bu] 2 \f[B]use_ino\f[]: causes mergerfs to supply file/directory inodes rather than libfuse. While not a default it is generally recommended it be enabled so that hard linked files share the same inode value. .IP \[bu] 2 \f[B]dropcacheonclose\f[]: when a file is requested to be closed call \f[C]posix_fadvise\f[] on it first to instruct the kernel that we no longer need the data and it can drop its cache. Recommended when \f[B]direct_io\f[] is not enabled to limit double caching. (default: false) .IP \[bu] 2 \f[B]symlinkify\f[]: when enabled (set to \f[B]true\f[]) and a file is not writable and its mtime or ctime is older than \f[B]symlinkify_timeout\f[] files will be reported as symlinks to the original files. Please read more below before using. (default: false) .IP \[bu] 2 \f[B]symlinkify_timeout\f[]: time to wait, in seconds, to activate the \f[B]symlinkify\f[] behavior. (default: 3600) .IP \[bu] 2 \f[B]nullrw\f[]: turns reads and writes into no\-ops. The request will succeed but do nothing. Useful for benchmarking mergerfs. (default: false) .IP \[bu] 2 \f[B]ignorepponrename\f[]: ignore path preserving on rename. Typically rename and link act differently depending on the policy of \f[C]create\f[] (read below). Enabling this will cause rename and link to always use the non\-path preserving behavior. This means files, when renamed or linked, will stay on the same drive. .IP \[bu] 2 \f[B]fsname\f[]: sets the name of the filesystem as seen in \f[B]mount\f[], \f[B]df\f[], etc. Defaults to a list of the source paths concatenated together with the longest common prefix removed. .IP \[bu] 2 \f[B]func.=\f[]: sets the specific FUSE function\[aq]s policy. See below for the list of value types. Example: \f[B]func.getattr=newest\f[] .IP \[bu] 2 \f[B]category.=\f[]: Sets policy of all FUSE functions in the provided category. Example: \f[B]category.create=mfs\f[] .PP \f[B]NOTE:\f[] Options are evaluated in the order listed so if the options are \f[B]func.rmdir=rand,category.action=ff\f[] the \f[B]action\f[] category setting will override the \f[B]rmdir\f[] setting. .SS srcmounts .PP The srcmounts (source mounts) argument is a colon (\[aq]:\[aq]) delimited list of paths to be included in the pool. It does not matter if the paths are on the same or different drives nor does it matter the filesystem. Used and available space will not be duplicated for paths on the same device and any features which aren\[aq]t supported by the underlying filesystem (such as file attributes or extended attributes) will return the appropriate errors. .PP To make it easier to include multiple source mounts mergerfs supports globbing (http://linux.die.net/man/7/glob). \f[B]The globbing tokens MUST be escaped when using via the shell else the shell itself will expand it.\f[] .IP .nf \f[C] $\ mergerfs\ \-o\ defaults,allow_other,use_ino\ /mnt/disk\\*:/mnt/cdrom\ /media/drives \f[] .fi .PP The above line will use all mount points in /mnt prefixed with \f[B]disk\f[] and the \f[B]cdrom\f[]. .PP To have the pool mounted at boot or otherwise accessable from related tools use \f[B]/etc/fstab\f[]. .IP .nf \f[C] #\ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ /mnt/disk*:/mnt/cdrom\ \ /media/drives\ \ fuse.mergerfs\ \ defaults,allow_other,use_ino\ \ 0\ \ \ \ \ \ \ 0 \f[] .fi .PP \f[B]NOTE:\f[] the globbing is done at mount or xattr update time (see below). If a new directory is added matching the glob after the fact it will not be automatically included. .PP \f[B]NOTE:\f[] for mounting via \f[B]fstab\f[] to work you must have \f[B]mount.fuse\f[] installed. For Ubuntu/Debian it is included in the \f[B]fuse\f[] package. .SS symlinkify .PP Due to the levels of indirection introduced by mergerfs and the underlying technology FUSE there can be varying levels of performance degredation. This feature will turn non\-directories which are not writable into symlinks to the original file found by the \f[C]readlink\f[] policy after the mtime and ctime are older than the timeout. .PP \f[B]WARNING:\f[] The current implementation has a known issue in which if the file is open and being used when the file is converted to a symlink then the application which has that file open will receive an error when using it. This is unlikely to occur in practice but is something to keep in mind. .PP \f[B]WARNING:\f[] Some backup solutions, such as CrashPlan, do not backup the target of a symlink. If using this feature it will be necessary to point any backup software to the original drives or configure the software to follow symlinks if such an option is available. Alternatively create two mounts. One for backup and one for general consumption. .SS nullrw .PP Due to how FUSE works there is an overhead to all requests made to a FUSE filesystem. Meaning that even a simple passthrough will have some slowdown. However, generally the overhead is minimal in comparison to the cost of the underlying I/O. By disabling the underlying I/O we can test the theoretical performance boundries. .PP By enabling \f[C]nullrw\f[] mergerfs will work as it always does \f[B]except\f[] that all reads and writes will be no\-ops. A write will succeed (the size of the write will be returned as if it were successful) but mergerfs does nothing with the data it was given. Similarly a read will return the size requested but won\[aq]t touch the buffer. .PP Example: .IP .nf \f[C] $\ dd\ if=/dev/zero\ of=/path/to/mergerfs/mount/benchmark\ ibs=1M\ obs=512\ count=1024 1024+0\ records\ in 2097152+0\ records\ out 1073741824\ bytes\ (1.1\ GB,\ 1.0\ GiB)\ copied,\ 15.4067\ s,\ 69.7\ MB/s $\ dd\ if=/dev/zero\ of=/path/to/mergerfs/mount/benchmark\ ibs=1M\ obs=1M\ count=1024 1024+0\ records\ in 1024+0\ records\ out 1073741824\ bytes\ (1.1\ GB,\ 1.0\ GiB)\ copied,\ 0.219585\ s,\ 4.9\ GB/s $\ dd\ if=/path/to/mergerfs/mount/benchmark\ of=/dev/null\ bs=512\ count=102400 102400+0\ records\ in 102400+0\ records\ out 52428800\ bytes\ (52\ MB,\ 50\ MiB)\ copied,\ 0.757991\ s,\ 69.2\ MB/s $\ dd\ if=/path/to/mergerfs/mount/benchmark\ of=/dev/null\ bs=1M\ count=1024 1024+0\ records\ in 1024+0\ records\ out 1073741824\ bytes\ (1.1\ GB,\ 1.0\ GiB)\ copied,\ 0.18405\ s,\ 5.8\ GB/s \f[] .fi .PP It\[aq]s important to test with different \f[C]obs\f[] (output block size) values since the relative overhead is greater with smaller values. As you can see above the size of a read or write can massively impact theoretical performance. If an application performs much worse through mergerfs it could very well be that it doesn\[aq]t optimally size its read and write requests. .SH FUNCTIONS / POLICIES / CATEGORIES .PP The POSIX filesystem API has a number of functions. \f[B]creat\f[], \f[B]stat\f[], \f[B]chown\f[], etc. In mergerfs these functions are grouped into 3 categories: \f[B]action\f[], \f[B]create\f[], and \f[B]search\f[]. Functions and categories can be assigned a policy which dictates how \f[B]mergerfs\f[] behaves. Any policy can be assigned to a function or category though some may not be very useful in practice. For instance: \f[B]rand\f[] (random) may be useful for file creation (create) but could lead to very odd behavior if used for \f[C]chmod\f[] (though only if there were more than one copy of the file). .PP Policies, when called to create, will ignore drives which are readonly. This allows for readonly and read/write drives to be mixed together. Note that the drive must be explicitly mounted with the \f[B]ro\f[] mount option for this to work. .SS Function / Category classifications .PP .TS tab(@); lw(7.9n) lw(62.1n). T{ Category T}@T{ FUSE Functions T} _ T{ action T}@T{ chmod, chown, link, removexattr, rename, rmdir, setxattr, truncate, unlink, utimens T} T{ create T}@T{ create, mkdir, mknod, symlink T} T{ search T}@T{ access, getattr, getxattr, ioctl, listxattr, open, readlink T} T{ N/A T}@T{ fallocate, fgetattr, fsync, ftruncate, ioctl, read, readdir, release, statfs, write T} .TE .PP Due to FUSE limitations \f[B]ioctl\f[] behaves differently if its acting on a directory. It\[aq]ll use the \f[B]getattr\f[] policy to find and open the directory before issuing the \f[B]ioctl\f[]. In other cases where something may be searched (to confirm a directory exists across all source mounts) \f[B]getattr\f[] will also be used. .SS Path Preservation .PP Policies, as described below, are of two core types. \f[C]path\ preserving\f[] and \f[C]non\-path\ preserving\f[]. .PP All policies which start with \f[C]ep\f[] (\f[B]epff\f[], \f[B]eplfs\f[], \f[B]eplus\f[], \f[B]epmfs\f[], \f[B]eprand\f[]) are \f[C]path\ preserving\[aq].\f[]ep\f[C]stands\ for\ \[aq]existing\ path\f[]. .PP As the descriptions explain a path preserving policy will only consider drives where the relative path being accessed already exists. .PP When using non\-path preserving policies where something is created paths will be copied to target drives as necessary. .SS Policy descriptions .PP .TS tab(@); lw(16.6n) lw(53.4n). T{ Policy T}@T{ Description T} _ T{ all T}@T{ Search category: acts like \f[B]ff\f[]. Action category: apply to all found. Create category: for \f[B]mkdir\f[], \f[B]mknod\f[], and \f[B]symlink\f[] it will apply to all found. \f[B]create\f[] works like \f[B]ff\f[]. It will exclude readonly drives and those with free space less than \f[B]minfreespace\f[]. T} T{ epall (existing path, all) T}@T{ Search category: acts like \f[B]epff\f[]. Action category: apply to all found. Create category: for \f[B]mkdir\f[], \f[B]mknod\f[], and \f[B]symlink\f[] it will apply to all existing paths found. \f[B]create\f[] works like \f[B]epff\f[]. Excludes readonly drives and those with free space less than \f[B]minfreespace\f[]. T} T{ epff (existing path, first found) T}@T{ Given the order of the drives, as defined at mount time or configured at runtime, act on the first one found where the relative path already exists. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[] (unless there is no other option). Falls back to \f[B]ff\f[]. T} T{ eplfs (existing path, least free space) T}@T{ Of all the drives on which the relative path exists choose the drive with the least free space. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[]. Falls back to \f[B]lfs\f[]. T} T{ eplus (existing path, least used space) T}@T{ Of all the drives on which the relative path exists choose the drive with the least used space. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[]. Falls back to \f[B]lus\f[]. T} T{ epmfs (existing path, most free space) T}@T{ Of all the drives on which the relative path exists choose the drive with the most free space. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[]. Falls back to \f[B]mfs\f[]. T} T{ eprand (existing path, random) T}@T{ Calls \f[B]epall\f[] and then randomizes. Otherwise behaves the same as \f[B]epall\f[]. T} T{ erofs T}@T{ Exclusively return \f[B]\-1\f[] with \f[B]errno\f[] set to \f[B]EROFS\f[] (Read\-only filesystem). By setting \f[B]create\f[] functions to this you can in effect turn the filesystem mostly readonly. T} T{ ff (first found) T}@T{ Given the order of the drives, as defined at mount time or configured at runtime, act on the first one found. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[] (unless there is no other option). T} T{ lfs (least free space) T}@T{ Pick the drive with the least available free space. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[]. Falls back to \f[B]mfs\f[]. T} T{ lus (least used space) T}@T{ Pick the drive with the least used space. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[]. Falls back to \f[B]mfs\f[]. T} T{ mfs (most free space) T}@T{ Pick the drive with the most available free space. For \f[B]create\f[] category functions it will exclude readonly drives. Falls back to \f[B]ff\f[]. T} T{ newest T}@T{ Pick the file / directory with the largest mtime. For \f[B]create\f[] category functions it will exclude readonly drives and those with free space less than \f[B]minfreespace\f[] (unless there is no other option). T} T{ rand (random) T}@T{ Calls \f[B]all\f[] and then randomizes. T} .TE .SS Defaults .PP .TS tab(@); l l. T{ Category T}@T{ Policy T} _ T{ action T}@T{ all T} T{ create T}@T{ epmfs T} T{ search T}@T{ ff T} .TE .SS rename & link .PP \f[B]NOTE:\f[] If you\[aq]re receiving errors from software when files are moved / renamed then you should consider changing the create policy to one which is \f[B]not\f[] path preserving, enabling \f[C]ignorepponrename\f[], or contacting the author of the offending software and requesting that \f[C]EXDEV\f[] be properly handled. .PP rename (http://man7.org/linux/man-pages/man2/rename.2.html) is a tricky function in a merged system. Under normal situations rename only works within a single filesystem or device. If a rename can\[aq]t be done atomically due to the source and destination paths existing on different mount points it will return \f[B]\-1\f[] with \f[B]errno = EXDEV\f[] (cross device). .PP Originally mergerfs would return EXDEV whenever a rename was requested which was cross directory in any way. This made the code simple and was technically complient with POSIX requirements. However, many applications fail to handle EXDEV at all and treat it as a normal error or otherwise handle it poorly. Such apps include: gvfsd\-fuse v1.20.3 and prior, Finder / CIFS/SMB client in Apple OSX 10.9+, NZBGet, Samba\[aq]s recycling bin feature. .PP As a result a compromise was made in order to get most software to work while still obeying mergerfs\[aq] policies. Below is the rather complicated logic. .IP \[bu] 2 If using a \f[B]create\f[] policy which tries to preserve directory paths (epff,eplfs,eplus,epmfs) .IP \[bu] 2 Using the \f[B]rename\f[] policy get the list of files to rename .IP \[bu] 2 For each file attempt rename: .RS 2 .IP \[bu] 2 If failure with ENOENT run \f[B]create\f[] policy .IP \[bu] 2 If create policy returns the same drive as currently evaluating then clone the path .IP \[bu] 2 Re\-attempt rename .RE .IP \[bu] 2 If \f[B]any\f[] of the renames succeed the higher level rename is considered a success .IP \[bu] 2 If \f[B]no\f[] renames succeed the first error encountered will be returned .IP \[bu] 2 On success: .RS 2 .IP \[bu] 2 Remove the target from all drives with no source file .IP \[bu] 2 Remove the source from all drives which failed to rename .RE .IP \[bu] 2 If using a \f[B]create\f[] policy which does \f[B]not\f[] try to preserve directory paths .IP \[bu] 2 Using the \f[B]rename\f[] policy get the list of files to rename .IP \[bu] 2 Using the \f[B]getattr\f[] policy get the target path .IP \[bu] 2 For each file attempt rename: .RS 2 .IP \[bu] 2 If the source drive != target drive: .IP \[bu] 2 Clone target path from target drive to source drive .IP \[bu] 2 Rename .RE .IP \[bu] 2 If \f[B]any\f[] of the renames succeed the higher level rename is considered a success .IP \[bu] 2 If \f[B]no\f[] renames succeed the first error encountered will be returned .IP \[bu] 2 On success: .RS 2 .IP \[bu] 2 Remove the target from all drives with no source file .IP \[bu] 2 Remove the source from all drives which failed to rename .RE .PP The the removals are subject to normal entitlement checks. .PP The above behavior will help minimize the likelihood of EXDEV being returned but it will still be possible. .PP \f[B]link\f[] uses the same basic strategy. .SS readdir .PP readdir (http://linux.die.net/man/3/readdir) is different from all other filesystem functions. While it could have it\[aq]s own set of policies to tweak its behavior at this time it provides a simple union of files and directories found. Remember that any action or information queried about these files and directories come from the respective function. For instance: an \f[B]ls\f[] is a \f[B]readdir\f[] and for each file/directory returned \f[B]getattr\f[] is called. Meaning the policy of \f[B]getattr\f[] is responsible for choosing the file/directory which is the source of the metadata you see in an \f[B]ls\f[]. .SS statvfs .PP statvfs (http://linux.die.net/man/2/statvfs) normalizes the source drives based on the fragment size and sums the number of adjusted blocks and inodes. This means you will see the combined space of all sources. Total, used, and free. The sources however are dedupped based on the drive so multiple sources on the same drive will not result in double counting it\[aq]s space. .SH BUILDING .PP \f[B]NOTE:\f[] Prebuilt packages can be found at: https://github.com/trapexit/mergerfs/releases .PP First get the code from github (http://github.com/trapexit/mergerfs). .IP .nf \f[C] $\ git\ clone\ https://github.com/trapexit/mergerfs.git $\ #\ or $\ wget\ https://github.com/trapexit/mergerfs/releases/download//mergerfs\-.tar.gz \f[] .fi .SS Debian / Ubuntu .IP .nf \f[C] $\ sudo\ apt\-get\ \-y\ update $\ sudo\ apt\-get\ \-y\ install\ git\ make $\ cd\ mergerfs $\ make\ install\-build\-pkgs $\ make\ deb $\ sudo\ dpkg\ \-i\ ../mergerfs_version_arch.deb \f[] .fi .SS Fedora .IP .nf \f[C] $\ su\ \- #\ dnf\ \-y\ update #\ dnf\ \-y\ install\ git\ make #\ cd\ mergerfs #\ make\ install\-build\-pkgs #\ make\ rpm #\ rpm\ \-i\ rpmbuild/RPMS//mergerfs\-..rpm \f[] .fi .SS Generically .PP Have git, g++, make, python, libattr1, automake, libtool installed. .IP .nf \f[C] $\ cd\ mergerfs $\ make $\ sudo\ make\ install \f[] .fi .SH RUNTIME .SS \&.mergerfs pseudo file .IP .nf \f[C] /.mergerfs \f[] .fi .PP There is a pseudo file available at the mount point which allows for the runtime modification of certain \f[B]mergerfs\f[] options. The file will not show up in \f[B]readdir\f[] but can be \f[B]stat\f[]\[aq]ed and manipulated via {list,get,set}xattrs (http://linux.die.net/man/2/listxattr) calls. .PP Even if xattrs are disabled for mergerfs the {list,get,set}xattrs (http://linux.die.net/man/2/listxattr) calls against this pseudo file will still work. .PP Any changes made at runtime are \f[B]not\f[] persisted. If you wish for values to persist they must be included as options wherever you configure the mounting of mergerfs (fstab). .SS Keys .PP Use \f[C]xattr\ \-l\ /mount/point/.mergerfs\f[] to see all supported keys. Some are informational and therefore readonly. .SS user.mergerfs.srcmounts .PP Used to query or modify the list of source mounts. When modifying there are several shortcuts to easy manipulation of the list. .PP .TS tab(@); l l. T{ Value T}@T{ Description T} _ T{ [list] T}@T{ set T} T{ +<[list] T}@T{ prepend T} T{ +>[list] T}@T{ append T} T{ \-[list] T}@T{ remove all values provided T} T{ \-< T}@T{ remove first in list T} T{ \-> T}@T{ remove last in list T} .TE .SS minfreespace .PP Input: interger with an optional multiplier suffix. \f[B]K\f[], \f[B]M\f[], or \f[B]G\f[]. .PP Output: value in bytes .SS moveonenospc .PP Input: \f[B]true\f[] and \f[B]false\f[] .PP Ouput: \f[B]true\f[] or \f[B]false\f[] .SS categories / funcs .PP Input: short policy string as described elsewhere in this document .PP Output: the policy string except for categories where its funcs have multiple types. In that case it will be a comma separated list .SS Example .IP .nf \f[C] [trapexit:/tmp/mount]\ $\ xattr\ \-l\ .mergerfs user.mergerfs.srcmounts:\ /tmp/a:/tmp/b user.mergerfs.minfreespace:\ 4294967295 user.mergerfs.moveonenospc:\ false \&... [trapexit:/tmp/mount]\ $\ xattr\ \-p\ user.mergerfs.category.search\ .mergerfs ff [trapexit:/tmp/mount]\ $\ xattr\ \-w\ user.mergerfs.category.search\ newest\ .mergerfs [trapexit:/tmp/mount]\ $\ xattr\ \-p\ user.mergerfs.category.search\ .mergerfs newest [trapexit:/tmp/mount]\ $\ xattr\ \-w\ user.mergerfs.srcmounts\ +/tmp/c\ .mergerfs [trapexit:/tmp/mount]\ $\ xattr\ \-p\ user.mergerfs.srcmounts\ .mergerfs /tmp/a:/tmp/b:/tmp/c [trapexit:/tmp/mount]\ $\ xattr\ \-w\ user.mergerfs.srcmounts\ =/tmp/c\ .mergerfs [trapexit:/tmp/mount]\ $\ xattr\ \-p\ user.mergerfs.srcmounts\ .mergerfs /tmp/c [trapexit:/tmp/mount]\ $\ xattr\ \-w\ user.mergerfs.srcmounts\ \[aq]+= 2.6.3 allows upto 65535 groups per user but most other *nixs allow far less. NFS allowing only 16. The system does handle overflow gracefully. If the user has more than 32 supplemental groups only the first 32 will be used. If more than 256 users are using the system when an uncached user is found it will evict an existing user\[aq]s cache at random. So long as there aren\[aq]t more than 256 active users this should be fine. If either value is too low for your needs you will have to modify \f[C]gidcache.hpp\f[] to increase the values. Note that doing so will increase the memory needed by each thread. .SS mergerfs or libfuse crashing .PP \f[B]NOTE:\f[] as of mergerfs 2.22.0 it includes the most recent version of libfuse so any crash should be reported. For older releases continue reading... .PP If suddenly the mergerfs mount point disappears and \f[C]Transport\ endpoint\ is\ not\ connected\f[] is returned when attempting to perform actions within the mount directory \f[B]and\f[] the version of libfuse (use \f[C]mergerfs\ \-v\f[] to find the version) is older than \f[C]2.9.4\f[] its likely due to a bug in libfuse. Affected versions of libfuse can be found in Debian Wheezy, Ubuntu Precise and others. .PP In order to fix this please install newer versions of libfuse. If using a Debian based distro (Debian,Ubuntu,Mint) you can likely just install newer versions of libfuse (https://packages.debian.org/unstable/libfuse2) and fuse (https://packages.debian.org/unstable/fuse) from the repo of a newer release. .SS mergerfs appears to be crashing or exiting .PP There seems to be an issue with Linux version \f[C]4.9.0\f[] and above in which an invalid message appears to be transmitted to libfuse (used by mergerfs) causing it to exit. No messages will be printed in any logs as its not a proper crash. Debugging of the issue is still ongoing and can be followed via the fuse\-devel thread (https://sourceforge.net/p/fuse/mailman/message/35662577). .SS mergerfs under heavy load and memory preasure leads to kernel panic .PP https://lkml.org/lkml/2016/9/14/527 .IP .nf \f[C] [25192.515454]\ kernel\ BUG\ at\ /build/linux\-a2WvEb/linux\-4.4.0/mm/workingset.c:346! [25192.517521]\ invalid\ opcode:\ 0000\ [#1]\ SMP [25192.519602]\ Modules\ linked\ in:\ netconsole\ ip6t_REJECT\ nf_reject_ipv6\ ipt_REJECT\ nf_reject_ipv4\ configfs\ binfmt_misc\ veth\ bridge\ stp\ llc\ nf_conntrack_ipv6\ nf_defrag_ipv6\ xt_conntrack\ ip6table_filter\ ip6_tables\ xt_multiport\ iptable_filter\ ipt_MASQUERADE\ nf_nat_masquerade_ipv4\ xt_comment\ xt_nat\ iptable_nat\ nf_conntrack_ipv4\ nf_defrag_ipv4\ nf_nat_ipv4\ nf_nat\ nf_conntrack\ xt_CHECKSUM\ xt_tcpudp\ iptable_mangle\ ip_tables\ x_tables\ intel_rapl\ x86_pkg_temp_thermal\ intel_powerclamp\ eeepc_wmi\ asus_wmi\ coretemp\ sparse_keymap\ kvm_intel\ ppdev\ kvm\ irqbypass\ mei_me\ 8250_fintek\ input_leds\ serio_raw\ parport_pc\ tpm_infineon\ mei\ shpchp\ mac_hid\ parport\ lpc_ich\ autofs4\ drbg\ ansi_cprng\ dm_crypt\ algif_skcipher\ af_alg\ btrfs\ raid456\ async_raid6_recov\ async_memcpy\ async_pq\ async_xor\ async_tx\ xor\ raid6_pq\ libcrc32c\ raid0\ multipath\ linear\ raid10\ raid1\ i915\ crct10dif_pclmul\ crc32_pclmul\ aesni_intel\ i2c_algo_bit\ aes_x86_64\ drm_kms_helper\ lrw\ gf128mul\ glue_helper\ ablk_helper\ syscopyarea\ cryptd\ sysfillrect\ sysimgblt\ fb_sys_fops\ drm\ ahci\ r8169\ libahci\ mii\ wmi\ fjes\ video\ [last\ unloaded:\ netconsole] [25192.540910]\ CPU:\ 2\ PID:\ 63\ Comm:\ kswapd0\ Not\ tainted\ 4.4.0\-36\-generic\ #55\-Ubuntu [25192.543411]\ Hardware\ name:\ System\ manufacturer\ System\ Product\ Name/P8H67\-M\ PRO,\ BIOS\ 3904\ 04/27/2013 [25192.545840]\ task:\ ffff88040cae6040\ ti:\ ffff880407488000\ task.ti:\ ffff880407488000 [25192.548277]\ RIP:\ 0010:[]\ \ []\ shadow_lru_isolate+0x181/0x190 [25192.550706]\ RSP:\ 0018:ffff88040748bbe0\ \ EFLAGS:\ 00010002 [25192.553127]\ RAX:\ 0000000000001c81\ RBX:\ ffff8802f91ee928\ RCX:\ ffff8802f91eeb38 [25192.555544]\ RDX:\ ffff8802f91ee938\ RSI:\ ffff8802f91ee928\ RDI:\ ffff8804099ba2c0 [25192.557914]\ RBP:\ ffff88040748bc08\ R08:\ 000000000001a7b6\ R09:\ 000000000000003f [25192.560237]\ R10:\ 000000000001a750\ R11:\ 0000000000000000\ R12:\ ffff8804099ba2c0 [25192.562512]\ R13:\ ffff8803157e9680\ R14:\ ffff8803157e9668\ R15:\ ffff8804099ba2c8 [25192.564724]\ FS:\ \ 0000000000000000(0000)\ GS:ffff88041f280000(0000)\ knlGS:0000000000000000 [25192.566990]\ CS:\ \ 0010\ DS:\ 0000\ ES:\ 0000\ CR0:\ 0000000080050033 [25192.569201]\ CR2:\ 00007ffabb690000\ CR3:\ 0000000001e0a000\ CR4:\ 00000000000406e0 [25192.571419]\ Stack: [25192.573550]\ \ ffff8804099ba2c0\ ffff88039e4f86f0\ ffff8802f91ee928\ ffff8804099ba2c8 [25192.575695]\ \ ffff88040748bd08\ ffff88040748bc58\ ffffffff811b99bf\ 0000000000000052 [25192.577814]\ \ 0000000000000000\ ffffffff811ba380\ 000000000000008a\ 0000000000000080 [25192.579947]\ Call\ Trace: [25192.582022]\ \ []\ __list_lru_walk_one.isra.3+0x8f/0x130 [25192.584137]\ \ []\ ?\ memcg_drain_all_list_lrus+0x190/0x190 [25192.586165]\ \ []\ list_lru_walk_one+0x23/0x30 [25192.588145]\ \ []\ scan_shadow_nodes+0x34/0x50 [25192.590074]\ \ []\ shrink_slab.part.40+0x1ed/0x3d0 [25192.591985]\ \ []\ shrink_zone+0x2ca/0x2e0 [25192.593863]\ \ []\ kswapd+0x51e/0x990 [25192.595737]\ \ []\ ?\ mem_cgroup_shrink_node_zone+0x1c0/0x1c0 [25192.597613]\ \ []\ kthread+0xd8/0xf0 [25192.599495]\ \ []\ ?\ kthread_create_on_node+0x1e0/0x1e0 [25192.601335]\ \ []\ ret_from_fork+0x3f/0x70 [25192.603193]\ \ []\ ?\ kthread_create_on_node+0x1e0/0x1e0 \f[] .fi .PP There is a bug in the kernel. A work around appears to be turning off \f[C]splice\f[]. Add \f[C]no_splice_write,no_splice_move,no_splice_read\f[] to mergerfs\[aq] options. Should be placed after \f[C]defaults\f[] if it is used since it will turn them on. This however is not guaranteed to work. .SH FAQ .SS Why use mergerfs over mhddfs? .PP mhddfs is no longer maintained and has some known stability and security issues (see below). MergerFS provides a superset of mhddfs\[aq] features and should offer the same or maybe better performance. .PP If you wish to get similar behavior to mhddfs from mergerfs then set \f[C]category.create=ff\f[]. .SS Why use mergerfs over aufs? .PP While aufs can offer better peak performance mergerfs provides more configurability and is generally easier to use. mergerfs however does not offer the overlay / copy\-on\-write (COW) features which aufs and overlayfs have. .SS Why use mergerfs over LVM/ZFS/BTRFS/RAID0 drive concatenation / striping? .PP With simple JBOD / drive concatenation / stripping / RAID0 a single drive failure will result in full pool failure. mergerfs performs a similar behavior without the possibility of catastrophic failure and difficulties in recovery. Drives may fail however all other data will continue to be accessable. .PP When combined with something like SnapRaid (http://www.snapraid.it) and/or an offsite backup solution you can have the flexibilty of JBOD without the single point of failure. .SS Why use mergerfs over ZFS? .PP MergerFS is not intended to be a replacement for ZFS. MergerFS is intended to provide flexible pooling of arbitrary drives (local or remote), of arbitrary sizes, and arbitrary filesystems. For \f[C]write\ once,\ read\ many\f[] usecases such as bulk media storage. Where data integrity and backup is managed in other ways. In that situation ZFS can introduce major maintance and cost burdens as described here (http://louwrentius.com/the-hidden-cost-of-using-zfs-for-your-home-nas.html). .SS Can drives be written to directly? Outside of mergerfs while pooled? .PP Yes. It will be represented immediately in the pool as the policies perscribe. .SS Why do I get an "out of space" error even though the system says there\[aq]s lots of space left? .PP First make sure you\[aq]ve read the sections above about policies, path preserving, and the \f[B]moveonenospc\f[] option. .PP Remember that mergerfs is simply presenting a logical merging of the contents of the pooled drives. The reported free space is the aggregate space available \f[B]not\f[] the contiguous space available. MergerFS does not split files across drives. If the writing of a file fills a drive and \f[B]moveonenospc\f[] is disabled it will return an ENOSPC error. .PP If \f[B]moveonenospc\f[] is enabled but there exists no drives with enough space for the file and the data to be written (or the drive happened to fill up as the file was being moved) it will error indicating there isn\[aq]t enough space. .PP It is also possible that the filesystem selected has run out of inodes. Use \f[C]df\ \-i\f[] to list the total and available inodes per filesystem. In the future it might be worth considering the number of inodes available when making placement decisions in order to minimize this situation. .SS Can mergerfs mounts be exported over NFS? .PP Yes. Some clients (Kodi) have issues in which the contents of the NFS mount will not be presented but users have found that enabling the \f[C]use_ino\f[] option often fixes that problem. .SS Can mergerfs mounts be exported over Samba / SMB? .PP Yes. .SS How are inodes calculated? .PP mergerfs\-inode = (original\-inode | (device\-id << 32)) .PP While \f[C]ino_t\f[] is 64 bits only a few filesystems use more than 32. Similarly, while \f[C]dev_t\f[] is also 64 bits it was traditionally 16 bits. Bitwise or\[aq]ing them together should work most of the time. While totally unique inodes are preferred the overhead which would be needed does not seem to outweighted by the benefits. .SS It\[aq]s mentioned that there are some security issues with mhddfs. What are they? How does mergerfs address them? .PP mhddfs (https://github.com/trapexit/mhddfs) manages running as \f[B]root\f[] by calling getuid() (https://github.com/trapexit/mhddfs/blob/cae96e6251dd91e2bdc24800b4a18a74044f6672/src/main.c#L319) and if it returns \f[B]0\f[] then it will chown (http://linux.die.net/man/1/chown) the file. Not only is that a race condition but it doesn\[aq]t handle many other situations. Rather than attempting to simulate POSIX ACL behavior the proper way to manage this is to use seteuid (http://linux.die.net/man/2/seteuid) and setegid (http://linux.die.net/man/2/setegid), in effect becoming the user making the original call, and perform the action as them. This is what mergerfs does. .PP In Linux setreuid syscalls apply only to the thread. GLIBC hides this away by using realtime signals to inform all threads to change credentials. Taking after \f[B]Samba\f[], mergerfs uses \f[B]syscall(SYS_setreuid,...)\f[] to set the callers credentials for that thread only. Jumping back to \f[B]root\f[] as necessary should escalated privileges be needed (for instance: to clone paths between drives). .PP For non\-Linux systems mergerfs uses a read\-write lock and changes credentials only when necessary. If multiple threads are to be user X then only the first one will need to change the processes credentials. So long as the other threads need to be user X they will take a readlock allowing multiple threads to share the credentials. Once a request comes in to run as user Y that thread will attempt a write lock and change to Y\[aq]s credentials when it can. If the ability to give writers priority is supported then that flag will be used so threads trying to change credentials don\[aq]t starve. This isn\[aq]t the best solution but should work reasonably well assuming there are few users. .SH SUPPORT .SS Issues with the software .IP \[bu] 2 github.com: https://github.com/trapexit/mergerfs/issues .IP \[bu] 2 email: trapexit\@spawn.link .IP \[bu] 2 twitter: https://twitter.com/_trapexit .SS Support development .IP \[bu] 2 Gratipay: https://gratipay.com/~trapexit .IP \[bu] 2 BitCoin: 12CdMhEPQVmjz3SSynkAEuD5q9JmhTDCZA .SH LINKS .IP \[bu] 2 http://github.com/trapexit/mergerfs .IP \[bu] 2 http://github.com/trapexit/mergerfs\-tools .IP \[bu] 2 http://github.com/trapexit/scorch .IP \[bu] 2 http://github.com/trapexit/backup\-and\-recovery\-howtos .SH AUTHORS Antonio SJ Musumeci .