Provided by: murasaki_1.68.6-4build1_amd64 bug

NAME

       murasaki - compute anchors between multiple sequences

SYNOPSIS

        murasaki [OPTIONS] -p[pattern] seq1.fa seq2.gbk [seq3.raw ...] #compute anchors between seq1.fa and seq2.gbk using [pattern]
        mpirun murasaki [OPTIONS] -p[pattern] seq1.fa seq2.gbk [seq3.raw ...] #compute anchors between seq1.fa and seq2.gbk using [pattern] in parallel via MPI

DESCRIPTION

       Murasaki generates anchors based on all supplied sequences based on the user supplied
       pattern and hash tables. Essentially each base of each sequence is masked by the pattern,
       forming a seed that is used to generate a hash. The location of the seed is stored in the
       hash table. Once all seeds have been hashed and stored, Murasaki scans the hash table,
       generating anchors for all matching seeds. An anchor refers to a set intervals across a
       subset of the input sequences. These are stored in name.anchors files, and described in
       "FILE FORMATS". By default anchors are maximally extended until their minimum pairwise
       ungapped alignment score drops below a threshold in the same fashion the X-drop parameter
       in BLAST and BLAST-like searches.

   PATTERNS
       Murasaki uses spaced seed patterns to in considering seeds. A spaced seed pattern is
       typically expressed as a string of 1s and 0s necessarily starting and ending with a 1. 1s
       indicate that this base is considered part of the seed, while bases at 0 positions are
       not. For example with a pattern "1011" the sequence "ACGT" would match sequences "AGGT"
       and "ATGT" but not "ACTT". The number of 1s in the pattern is known as the "weight" of the
       pattern, and the number of 1s and 0s combined is the "length" of the pattern. Murasaki
       allows the use of any arbitrary pattern expressed as a string of 1s and 0s, and also
       interprets patterns of the form "x:y" to mean a "random pattern of weight x and length y."

       The choice of pattern obviously has an impact on sensitivity and specificity, but whether
       one pattern is "better" than another depends on the application and the input sequences
       under consideration. Calcuating "maximally sensitive spaced seed patterns" is a
       computationally difficult problem and there are a number of research papers describing
       various methods for approximation ("RELATED READING"). In general, however, "heavier"
       spaced seed patterns are less sensitive, but more specific, than lighter seeds.
       Anecdotally we find that seeds with weights approximately 60% to 75% (with lengths around
       24 for bacteria, and 36 to 48 for mammals) are good for most applications. Extremely
       similar species (for example human and chimp) benefit from longer, heavier, seeds.

   HASH FUNCTIONS
       Hash functions (as well as hash parameters) are generated automatically based the system
       environment and input sequences. There are essentially two types of hash functions
       available in Murasaki: adaptive and cryptoraphic hashes. The adaptive hashes are XOR
       combinations of various bitwise shifts of the seed designed by analyzing the spaced seed
       pattern to maximize the entropy of the resulting hash. Cryptographic hashes are available
       via the CryptoPP library and use the entire spaced seed pattern to generate a hash using
       one of the common cryptographic hashes like MD5 or SHA-1. The adaptive hash functions are
       almost always faster and more efficient than MD5 and SHA-1, but the cryptographic
       functions are available for reference and may be useful as an alternative in the unlikely
       event you're dealing with an environment where the adaptive hasher is unsuitable (for
       example a sequence consisting of only A and T (leaving 1 out of every 2 bits unitilized)).

   MEMORY SCALING
       Murasaki can take a lot of memory. Storing the location of each seed in the hash table is
       the most costly part of the operation, requiring approximately "ceil(log_2(N))" bits per
       seed where "N" is the total sequence length. Locations are, by default, stored in a
       bitpacked format to approach theoretical minimum. The second most costly element is the
       hash table structure, where each bucket carries a small overhead and unused are simply
       wasted space. More hash table buckets (i.e. a longer hash table) decreases the expected
       number of collisions, leading to faster executation time. Therefore Murasaki tries to use
       as many buckets as possible by inspecting the available system memory and using as much as
       it can while still storing all the seed locations. If this automatic scaling is
       ineffective, setting the hash table size directly via the --hashbits|-b options can force
       a specific hash table size. If the memory of one computer is insufficient to store the
       desired hash table, PARALLELIZATION can be used to distribute the hash table across
       multiple computers.

   PARALLELIZATION
       Murasaki is designed to run in parallel using MPI. Consult the documentation for the
       specific variations of your MPI implementation, however in general the executation method
       looks like:

        mpirun [MPI options] murasaki [murasaki options] -p[pattern] [seq1 ...]

       Murasaki in parallel divides the number of processors available (NP) into two groups:
       hasher nodes and storage nodes. The storage nodes divide the hash table between each
       themselves, each being responsible for a different part of the table. Hasher nodes divide
       the input sequence in between themselves, each hashing a separate portion of the input
       sequence, and passing the seed location to the appropriate storage node for storage.  When
       all the hasher nodes are finished hashing, the storage nodes scan their portion of hash
       table and pass matching sets of seeds to a hasher node where they are assembled into
       anchors and extended. Finally all the hasher nodes combine their independent anchor sets
       into one final set in "ceil(log_2(H))" iterations (where "H" is the number of hasher
       nodes), with each hasher node number 2h passing its anchors to hasher number 2h-1 at each
       iteration.

       Because almost none of the parallelization steps require communication between all nodes,
       and each seed and each anchor can be processed in parallel, Murasaki scales very well in
       parallel, running approximately twice as fast when twice as many nodes are available.
       Furthermore, the hash table is automatically grown to take advantage of the combined
       memory from multiple machines.

OPTIONS

       Most options can be specified in their long form (e.g. "--directory out" or
       "--directory=out") or short form (e.g. "-dout"). Options marked by <S> expect a string,
       <D> an integer, <F> a float, and <B> a boolean value ("yes/on/true/1" for true,
       "no/off/false/0" for false). Most booleans can omit the value, toggling the value from
       whatever it was to the opposite.

       Murasaki has a lot of options. Here we've separated them into categories to help
       distinguish the scope of the various options, however in certain situations certain option
       choices may have onforseen consequences, and of course ultimately if the specified output
       is huge, the required runtime will necessarily be long.  It is a mistake to think that
       everything outside of the "tuning options" in Performance section has no bearing on
       performance.

   Anchor parameter related options
       These options shape what is considered an "anchor".

       --pattern|-p <S>
            specifies the seed pattern (eg. 11101001010011011). using the format
            C<[<w>:<l>]> automatically generates a random pattern of weight <w>
            and length <l>

       --repeatmask|-r <B>
           Skip repeat masked data (ie: lowercase atgc). Be aware that some sequence files are
           distributed purely in lower case.

       --seedfilter|-f <D>
           Skip seeds that occur more than N times. Exceptionally slow. See --hashfilter for a
           faster approximation.

       --hashfilter|-m <D>
           Like --seedfilter but works on hash keys instead of seeds. May cause some collateral
           damage to otherwise unique seeds, but it's faster.

       --skipfwd|-F <B>
           Don't hash/match the forward strands.

       --skiprev|-R <B>
           Don't hash/match the reverse complement strands.

       --skip1to1|-1 <B>
           Skip matches along the 1:1 line (good for comparing to self).

       --hashonly|-Q <B>
           Hash Only. No anchor output, just statistics.

       --hashskip|-S <D>
           Hashes every n bases. Default is 1 (i.e. hashing all positions). Not supplying any
           argument increments the skip amount by 1.

       --join|-j <D>
           Join anchors within n bases of eachother (default: 0). Specifying a negative D implies
           -D*patternLength.

       --bitscore|-B <B>
           toggles compututation of a bitscore for all anchors (default is on).

       --seedterms|-T <B>
           toggles retention of seed terms (defaults to off). These are necessary for computing
           TF-IDF scores).

       --sectime|-e <B>
           Always display times in seconds as opposed to human readable "1d 3h 45m 5s" style
           times.

       --mergefilter|-Y <D>
           Filter out matches which would would cause more than D many anchors to be generated
           from 1 seed (default -Y100).  Use -Y0 to disable.

       --scorefilter <D>
           Set a minimum ungapped score for seeds.

       --rifts|-/ <D>
           Allow anchors to skip D sequences (default 0).

       --islands|-% <D>
           Same as --rifts=S-D (where S is number of input seqs).

       --fuzzyextend|-z <B>
           Enable (default) or disable fuzzy extension (i.e. ungapped alignment) of anchors.

       --fuzzyextendlosslimit|-Z <D>
           Set the cutoff at which to stop extending fuzzy hits (ie. the BLAST X parameter).

       --gappedanchors <B>
           Use gapped (true) or ungapped (false (default)) anchors.

       --scorebyminimumpair <B>
           Do anchor scoring by minimum pair when appropriate (default). Alternative is
           arithmatic mean (seldom useful, but theoretically faster).  =item --rifts|-/ <D>

           Allow anchors to skip D sequences (default 0).

       --islands|-% <D>
           Same as --rifts=S-D (where S is number of input seqs).

       --fuzzyextend|-z <B>
           Enable (default) or disable fuzzy extension (i.e. ungapped alignment) of anchors.

       --fuzzyextendlosslimit|-Z <D>
           Set the cutoff at which to stop extending fuzzy hits (ie. the BLAST X parameter).

       --gappedanchors <B>
           Use gapped (true) or ungapped (false (default)) anchors.

       --scorebyminimumpair <B>
           Do anchor scoring by minimum pair when appropriate (default). Alternative is
           arithmatic mean (seldom useful, but theoretically faster).

   Output options
       These options primarily affect what data is output where.

       --directory|-d <S>
            output directory (default: output)

       --name|-n <S>
            alignment name (default: test)

       --repeatmap|-i <B>
           Toggles keeping of a repeat map when --mergefilter is used (defaults to yes).

       --histogram|-H <D>
           Histogram computation level: (-H alone implies -H1)

           0 - no histogram (default)
           1 - basic bucketsize/bucketcount histogram data
           2 - bucket-based scores to anchors.detils
           3 - perbucket count data
           4 - perbucket + perpattern count data

           Any values above 2 are purely explorartory and can result in massive output files.

       --tfidf|-k <B>
           Perform accurate tfidf scoring from within murasaki (requires extra memory at anchor
           generation time). Default is no.

   Performance/tuning options
       These options primarily affect performance, and don't (in general) impact output.

       --quickhash|-q <D>
            specify a hashing function:

           0 - adaptive with S-boxes (default when there's plenty of hash table to spare)
           1 - don't pack bits to make hash (use first word only)
           2 - naively use the first hashbits worth of pattern
           3 - adaptivevely find a good hash (default)
           **experimental CryptoPP hashes**
           4 - MD5
           5 - SHA1
           6 - Whirlpool
           7 - CRC-32
           8 - Adler-32

           Note: 3 and 0 are the only "recommended" hash functions, and the only ones
           automatically selected. The others are provided merely for reference. 1, 7, and 8
           aren't even expected to utilize the entire hash space.

       --hashbits|-b <D>
           use D bit hashes (for n's of 1 to WORDSIZE. default 26)

       --hashtype|-t <S>
           select hash table data structure to use:

           OpenHash  - open sub-word packing of hashbits (default when there's plenty of hash
           table to spare)
           EcoHash   - chained sub-word packing of hashbits (default)
           ArrayHash - malloc/realloc (fast but fragmentation-prone)
           MSetHash  - memory exorbanant, almost pointless.
       --probing <D>
           0 - linear, 1 - quadratic (default). Only applicable for --hashtype=OpenHash.

       --hitfilter|-h <D>
           Minimum number of hits to be outputted as an anchor (default 1). In PatternHunter this
           is 2.

       --rseed|-s <D>
           Random number seed for non-deterministic algorithms (ie: adative hash function
           generation). If you're doing any performance comparisons, it's probably imperative
           that you use the same seed for each run of the same settings.  Default is obtained
           from time() (ie: seconds since 1970).

       --memory|-M [<F>|<S>]
           Set the target amount of total memory (either in gb or as % total memory).

       --reverseotf|-o <B>
           Generate reverse complement on the fly (defaults to on). Turning this off precomputes
           the all reverse complement strands and stores them in memory, which rarely provides a
           measurable performance improvement.

       --binaryseq <B>
           Enable (default) or disable binary sequence read/write

       Adaptive hash function related:

       Performance options related to adaptive hash function generation.

       --hasherFairEntropy <B>
           Use more balanced entropy estimation (default: yes).

       --hasherCorrelationAdjust <B>
           Adjust entropy estimates for nearby sources assuming some correlation (default: yes).

       --hasherTargetGACycles <D>
           Adaptive hash function generation genetic algorithm cycle cutoff.

       --hasherEntropyAgro <F>
           How aggressive to be about pursuing maximum entropy hash functions (takes a real.
           default is 1).

   MPI Specific:
       --hashers|-A [<F>|<D>]
           Specify the number of processes to be used as hashers (only applies to MPI. If a
           number between 0 and 1 it refers to a ratio of np).

       --localhash|-K <B>
           Perform hashing locally on each storage node rather than sending it over the network
           (helpful for slow networks).

       --mpidistro|-L <B>
           Toggles use of MPI to distribute sequence data over (if the sequence is available on
           local disk on each node then turning this off may potentially accerlate the initial
           sequence loading).

       --waittoanchor|-w <B>
           Postpone actual anchor computation until all location sets have been received (as
           opposed to trying to work between receiving seed packets).

       --buffers|-u <D>
           Maximum number of unfinished buffers to allow while message passing (0 means
           unlimited). Default is set based on the number of nodes participating. MPI can crash
           or perform very poorly if this value is too high.

       --nobuffers|-U <B>
           Same as --buffers=1.

       --bigfirst|-I <B>
           Assign hashers to large memory nodes first.

       --hostbalance|-l <B>
           If yes (default): spread out hashers evenly among all nodes.
           If no: ignore host name when assigning jobs.
       --memorybalance|-a <B>
           If yes (default): balance hash storage between nodes based on the amount of available
           ram.
           If no: distribute storage evently. This more likely to achieve optimal run times, but
           might not utilize memory as efficiently.
       --distmerge|-< <B>
           if yes (default): during the merge step, storage nodes send seeds to any available
           hasher.
           if no: send all seeds to one node only.
       --distcollect|-> <B>
           if yes (default): collect anchor data from all hashers.
           if no: send all seeds to the final assembly node only.
       --mpiredirectoutput <B>
           if yes (default): each rank redirects its stdout/stderr to a separate file
           (murasaki-mpiout-N).
           if no: do what comes naturally (ie: managed by mpirun (for OpenMPI see
           --output-filename and --tag-output in mpirun(1))).
       --keepstdoe <B>
           Don't erase the murasaki-mpiout files on success.

       --sysvipc|-V <B>
           Use System V IPC to negotiate shared memory regions (saves memory when one host runs
           multiple nodes). Default is true.

   Universal options:
       --verbose|-v
           Increases verbosity.

       --version|-V
           Prints version information and quits.

       --help|-?
           Prints a help message and quits.

FILE FORMATS

       Murasaki has a wide array of output files, the formats of most of which are intended to be
       intuitive. All output files are prefixed by the value of the --name parameter. The primary
       output file formats are described here. Files are line based and tab delimited unless
       otherwise specified.

   .seqs
       The .seqs shows what sequences were used as input, 1 per line. This file gets used by
       various programs in conjunction with the .anchors file, so it's generally important that
       the contents reflect the correct sequence files. Moving anchor results between computers
       might result in a change of paths, requiring the user to update the .seqs file. As an
       alternative, always using relative paths can alleviate this problem.

   .anchors files
       These files are 1 anchor per line, with a 3-tuple per sequence. Each touple represents the
       start and stop coordinates and strand of the anchored interval on each sequence. The
       sequence order matches that of the order in the .seqs file. The coordinates are structured
       such that 1 refers to the first base in the sequence, 2 to the second, etc. Negative
       values refer to the reverse complement sequence where -1 is the last base of the reverse
       complement sequence (ie: the complement first base in the forward sequence). The "strand"
       element is a '+' or '-' that merely matches the sign of the coordinates (this is redundant
       information, but kept to make parsing or filtering simpler).

       For examle:

        1       18     +       -1      -18       -

       This line describes an anchor where the first 18 bases of the first sequence match the
       first 18 bases of the reverse complement of the second sequence.

   .anchors.details
       This is an antiquated file format, but used by GMV to calculate statistics like TF-IDF
       scores, and has been kept around for that reason. The .anchors.details file has the same
       format and information as the .anchors file, however after the anchor touples are two more
       terms: a score, and a comma (,) delimited list of term and count pairs (written
       "term:count"). The score and count data might be varied depending on the "--histogram"
       option choices.

   .anchors.bitscore
       The term "bitscore" here is a misnomer, but maintained for historical reasons. In reality,
       this file contains the mean number of matching bases and length of each anchor
       (corresponding line by line to the .anchors file).

   .stats.tfidf
       Contains anchor TF-IDF scores (corresponding line by line to the .anchors file).

   .histogram
       Contains a simple histogram of the hash table usage. The first field is the bucket size,
       and the second is the frequency. For example a .histogram file like this:

        1  24
        2  1

       Would indicate that there were 24 hash buckets that stored only 1 location (i.e. 24 unique
       seeds), and 1 hash bucket stored 2 locations (i.e. 1 seed that matched 2 locations (or 2
       non-matching seeds that resulted in a hash collision)).

   .options
       Maintains a record of the options used when running Murasaki.

   .repeats
       The .repeats file stores a record of "repeats" as defined by the --mergefilter option
       (i.e. seeds that would have have induced more anchors than permitted). In this file, each
       repeat record is separated by a blank line. A repeat record looks like this:

        R: G.GCCTTT.T.ACT.CACAA..AT
        0: 2145540494 -425039256 -113794380 1998323403
        1: 2480929222 -1874514626 2543723555 -2550045172

       The first line (always prefixed "R:") shows the repeating seed itself (where the . are the
       bases masked by the pattern). The subsequent lines show where these seeds occured in the
       input sequences (in the first (0) and second (1) sequences). Note that if there are no
       hits in a particular sequence, it doesn't include a blank line for that sequence. For
       example:

        R: G.GCCTTT.T.ACT.CACAA..AT
        0: 2145540494 -425039256 -113794380 1998323403
        2: 2480929222 -1874514626 2543723555 -2550045172

       is also a valid .repeats file.

LICENSE

       GNU General Public License, version 3 (GPLv3)

AVAILABILITY

       <http://murasaki.sourceforge.net>

AUTHOR

       Kris Popendorf <krisp@dna.bio.keio.ac.jp>

SEE ALSO

       mbfa(1), geneparse(1)

   RELATED READING
       M. Csuros and B. Ma, "Rapid Homology Search with Two-Stage Extension and Daughter Seeds"
       (2005).
       F. P. Preparata and L. Zhang and K. W. Choi, "Quick, practical selection of effective
       seeds for homology search" (2005).
       KP Choi, et. al., "Good spaced seeds for homology search" (2004).