'\" t
.TH samtools 1 "2 September 2022" "samtools-1.16.1" "Bioinformatics tools"
.SH NAME
samtools \- Utilities for the Sequence Alignment/Map (SAM) format
.\"
.\" Copyright (C) 2008-2011, 2013-2022 Genome Research Ltd.
.\" Portions copyright (C) 2010, 2011 Broad Institute.
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.\" Author: Heng Li <lh3@sanger.ac.uk>
.\" Author: Joshua C. Randall <jcrandall@alum.mit.edu>
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.SH SYNOPSIS
.PP
samtools addreplacerg -r 'ID:fish' -r 'LB:1334' -r 'SM:alpha' -o output.bam input.bam
.PP
samtools ampliconclip -b bed.file input.bam
.PP
samtools ampliconstats primers.bed in.bam
.PP
samtools bedcov aln.sorted.bam
.PP
samtools calmd in.sorted.bam ref.fasta
.PP
samtools cat out.bam in1.bam in2.bam in3.bam
.PP
samtools collate -o aln.name_collated.bam aln.sorted.bam
.PP
samtools consensus -o out.fasta in.bam
.PP
samtools coverage aln.sorted.bam
.PP
samtools depad input.bam
.PP
samtools depth aln.sorted.bam
.PP
samtools dict -a GRCh38 -s "Homo sapiens" ref.fasta
.PP
samtools faidx ref.fasta
.PP
samtools fasta input.bam > output.fasta
.PP
samtools fastq input.bam > output.fastq
.PP
samtools fixmate in.namesorted.sam out.bam
.PP
samtools flags PAIRED,UNMAP,MUNMAP
.PP
samtools flagstat aln.sorted.bam
.PP
samtools fqidx ref.fastq
.PP
samtools head in.bam
.PP
samtools idxstats aln.sorted.bam
.PP
samtools import input.fastq > output.bam
.PP
samtools index aln.sorted.bam
.PP
samtools markdup in.algnsorted.bam out.bam
.PP
samtools merge out.bam in1.bam in2.bam in3.bam
.PP
samtools mpileup -C50 -f ref.fasta -r chr3:1,000-2,000 in1.bam in2.bam
.PP
samtools phase input.bam
.PP
samtools quickcheck in1.bam in2.cram
.PP
samtools reference -o ref.fa in.cram
.PP
samtools reheader in.header.sam in.bam > out.bam
.PP
samtools samples input.bam
.PP
samtools sort -T /tmp/aln.sorted -o aln.sorted.bam aln.bam
.PP
samtools split merged.bam
.PP
samtools stats aln.sorted.bam
.PP
samtools targetcut input.bam
.PP
samtools tview aln.sorted.bam ref.fasta
.PP
samtools view -bt ref_list.txt -o aln.bam aln.sam.gz

.SH DESCRIPTION
.PP
Samtools is a set of utilities that manipulate alignments in the SAM
(Sequence Alignment/Map), BAM, and CRAM formats.
It converts between the formats, does sorting, merging and indexing,
and can retrieve reads in any regions swiftly.

Samtools is designed to work on a stream. It regards an input file `-'
as the standard input (stdin) and an output file `-' as the standard
output (stdout). Several commands can thus be combined with Unix
pipes. Samtools always output warning and error messages to the standard
error output (stderr).

Samtools is also able to open files on remote FTP or
HTTP(S) servers if the file name starts with `ftp://', `http://', etc.
Samtools checks the current working directory for the index file and
will download the index upon absence. Samtools does not retrieve the
entire alignment file unless it is asked to do so.

If an index is needed, samtools looks for the index suffix
appended to the filename, and if that isn't found it tries again
without the filename suffix (for example \fBin.bam.bai\fR followed by
\fBin.bai\fR).  However if an index is in a completely different
location or has a different name, both the main data filename and
index filename can be pasted together with \fB##idx##\fR.  For
example \fB/data/in.bam##idx##/indices/in.bam.bai\fR may be used to
explicitly indicate where the data and index files reside.

.SH COMMANDS

Each command has its own man page which can be viewed using
e.g. \fBman samtools-view\fR or with a recent GNU man using
\fBman samtools view\fR.  Below we have a brief summary of syntax
and sub-command description.

Options common to all sub-commands are documented below in the GLOBAL
COMMAND OPTIONS section.

.TP 10 \"-------- view
.B view
samtools view
.RI [ options ]
.IR in.sam | in.bam | in.cram
.RI [ region ...]

With no options or regions specified, prints all alignments in the specified
input alignment file (in SAM, BAM, or CRAM format) to standard output
in SAM format (with no header by default).

You may specify one or more space-separated region specifications after the
input filename to restrict output to only those alignments which overlap the
specified region(s). Use of region specifications requires a coordinate-sorted
and indexed input file.

Options exist to change the output format from SAM to BAM or CRAM, so
this command also acts as a file format conversion utility.

.TP \"-------- tview
.B tview
samtools tview
.RB [ -p
.IR chr:pos ]
.RB [ -s
.IR STR ]
.RB [ -d
.IR display ]
.RI <in.sorted.bam>
.RI [ref.fasta]

Text alignment viewer (based on the ncurses library). In the viewer,
press `?' for help and press `g' to check the alignment start from a
region in the format like `chr10:10,000,000' or `=10,000,000' when
viewing the same reference sequence.

.TP \"-------- quickcheck
.B quickcheck
samtools quickcheck
.RI [ options ]
.IR in.sam | in.bam | in.cram
[ ... ]

Quickly check that input files appear to be intact. Checks that beginning of the
file contains a valid header (all formats) containing at least one target
sequence and then seeks to the end of the file and checks that an end-of-file
(EOF) is present and intact (BAM only).

Data in the middle of the file is not read since that would be much more time
consuming, so please note that this command will not detect internal corruption,
but is useful for testing that files are not truncated before performing more
intensive tasks on them.

This command will exit with a non-zero exit code if any input files don't have a
valid header or are missing an EOF block. Otherwise it will exit successfully
(with a zero exit code).

.TP \"-------- head
.B head
samtools head
.RI [ options ]
.IR in.sam | in.bam | in.cram

Prints the input file's headers and optionally also its first few alignment
records. This command always displays the headers as they are in the file,
never adding an extra @PG header itself.

.TP \"-------- index
.B index
samtools index
.RB [ -bc ]
.RB [ -m
.IR INT ]
.IR aln.sam.gz | aln.bam | aln.cram
.RI [ out.index ]

Index a coordinate-sorted SAM, BAM or CRAM file for fast random access.
Note for SAM this only works if the file has been BGZF compressed first.
(Starting from Samtools 1.16, this command can also be given several
alignment filenames, which are indexed individually.)

This index is needed when
.I region
arguments are used to limit
.B samtools view
and similar commands to particular regions of interest.

If an output filename is given, the index file will be written to
.IR out.index .
Otherwise, for a CRAM file
.IR aln.cram ,
index file
.IB aln.cram .crai
will be created; for a BAM or SAM file
.IR aln.bam ,
either
.IB aln.bam .bai
or
.IB aln.bam .csi
will be created, depending on the index format selected.

.TP \"-------- sort
.B sort
.na
samtools sort
.RB [ -l
.IR level ]
.RB [ -m
.IR maxMem ]
.RB [ -o
.IR out.bam ]
.RB [ -O
.IR format ]
.RB [ -n ]
.RB [ -t
.IR tag ]
.RB [ -T
.IR tmpprefix ]
.RB [ -@
.IR threads "] [" in.sam | in.bam | in.cram ]
.ad

Sort alignments by leftmost coordinates, or by read name when
.B -n
is used.
An appropriate
.B @HD-SO
sort order header tag will be added or an existing one updated if necessary.

The sorted output is written to standard output by default, or to the
specified file
.RI ( out.bam )
when
.B -o
is used.
This command will also create temporary files
.IB tmpprefix . %d .bam
as needed when the entire alignment data cannot fit into memory
(as controlled via the
.B -m
option).

Consider using
.B samtools collate
instead if you need name collated data without a full lexicographical sort.

Note that if the sorted output file is to be indexed with
.BR "samtools index" ,
the default coordinate sort must be used.
Thus the
.B -n
and
.B -t
options are incompatible with
.BR "samtools index" .

.TP \"-------- collate
.B collate
samtools collate
.RI [ options ]
.IR in.sam | in.bam | in.cram " [" <prefix> "]"

Shuffles and groups reads together by their names.
A faster alternative to a full query name sort,
.B collate
ensures that reads of the same name are grouped together in contiguous groups,
but doesn't make any guarantees about the order of read names between groups.

The output from this command should be suitable for any operation that
requires all reads from the same template to be grouped together.

.TP \"-------- idxstats
.B idxstats
samtools idxstats
.IR in.sam | in.bam | in.cram

Retrieve and print stats in the index file corresponding to the input file.
Before calling idxstats, the input BAM file should be indexed by samtools index.

If run on a SAM or CRAM file or an unindexed BAM file, this command
will still produce the same summary statistics, but does so by reading
through the entire file.  This is far slower than using the BAM
indices.

The output is TAB-delimited with each line consisting of reference sequence
name, sequence length, # mapped reads and # unmapped reads. It is written to
stdout.

.TP \"-------- flagstat
.B flagstat
samtools flagstat
.IR in.sam | in.bam | in.cram

Does a full pass through the input file to calculate and print statistics
to stdout.

Provides counts for each of 13 categories based primarily on bit flags in
the FLAG field. Each category in the output is broken down into QC pass and
QC fail, which is presented as "#PASS + #FAIL" followed by a description of
the category.

.TP \"-------- flags
.B flags
samtools flags
.IR INT | STR [,...]

Convert between textual and numeric flag representation.

.B FLAGS:
.TS
rb l l .
0x1	PAIRED	paired-end (or multiple-segment) sequencing technology
0x2	PROPER_PAIR	each segment properly aligned according to the aligner
0x4	UNMAP	segment unmapped
0x8	MUNMAP	next segment in the template unmapped
0x10	REVERSE	SEQ is reverse complemented
0x20	MREVERSE	SEQ of the next segment in the template is reverse complemented
0x40	READ1	the first segment in the template
0x80	READ2	the last segment in the template
0x100	SECONDARY	secondary alignment
0x200	QCFAIL	not passing quality controls
0x400	DUP	PCR or optical duplicate
0x800	SUPPLEMENTARY	supplementary alignment
.TE

.TP \"-------- stats
.B stats
samtools stats
.RI [ options ]
.IR in.sam | in.bam | in.cram
.RI [ region ...]

samtools stats collects statistics from BAM files and outputs in a text format.
The output can be visualized graphically using plot-bamstats.


.TP \"-------- bedcov
.B bedcov
samtools bedcov
.RI [ options ]
.IR region.bed " " in1.sam | in1.bam | in1.cram "[...]"

Reports the total read base count (i.e. the sum of per base read depths)
for each genomic region specified in the supplied BED file. The regions
are output as they appear in the BED file and are 0-based.
Counts for each alignment file supplied are reported in separate columns.

.TP \"-------- depth
.B depth
samtools depth
.RI [ options ]
.RI "[" in1.sam | in1.bam | in1.cram " [" in2.sam | in2.bam | in2.cram "] [...]]"

Computes the read depth at each position or region.

.TP \"-------- ampliconstats
.B ampliconstats
samtools ampliconstats
.RI [ options ]
.IR primers.bed
.IR in.sam | in.bam | in.cram [...]

samtools ampliconstats collects statistics from one or more input
alignment files and produces tables in text format.  The output can be
visualized graphically using plot-ampliconstats.

The alignment files should have previously been clipped of primer
sequence, for example by \fBsamtools ampliconclip\fR and the sites of
these primers should be specified as a bed file in the arguments.

.TP \"-------- mpileup
.B mpileup
samtools mpileup
.RB [ -EB ]
.RB [ -C
.IR capQcoef ]
.RB [ -r
.IR reg ]
.RB [ -f
.IR in.fa ]
.RB [ -l
.IR list ]
.RB [ -Q
.IR minBaseQ ]
.RB [ -q
.IR minMapQ ]
.I in.bam
.RI [ in2.bam
.RI [ ... ]]

Generate textual pileup for one or multiple BAM files.  For VCF and
BCF output, please use the
.B bcftools mpileup
command instead.
Alignment records are grouped by sample (SM) identifiers in @RG header lines.
If sample identifiers are absent, each input file is regarded as one sample.

See the samtools-mpileup man page for a description of the pileup format and options.

.TP \"-------- consensus
.B consensus
samtools consensus
.RB [ options ]
.I in.bam

Generate consensus from a SAM, BAM or CRAM file based on the contents
of the alignment records.  The consensus is written either as FASTA, 
FASTQ, or a pileup oriented format.

The default output for FASTA and FASTQ formats include one base per
non-gap consensus.  Hence insertions with respect to the aligned
reference will be included and deletions removed.  This behaviour can
be adjusted.

Two consensus calling algorithms are offered.  The default computes a
heterozygous consensus in a Bayesian manner, derived from the "Gap5"
consensus algorithm.  A simpler base frequency counting method is also
available.


.TP \"-------- reference
.B reference
samtools reference
.RB [ options ]
.I in.bam

Generate a reference from a SAM, BAM or CRAM file based on the
contents of the SEQuence field and the MD:Z: auxiliary tags, or from
the embedded reference blocks within a CRAM file (provided it was
constructed using the \fBembed_ref=1\fR option).

.TP \"-------- coverage
.B coverage
samtools coverage
.RI [ options ]
.RI "[" in1.sam | in1.bam | in1.cram " [" in2.sam | in2.bam | in2.cram "] [...]]"

Produces a histogram or table of coverage per chromosome.

.TP \"-------- merge
.B merge
samtools merge
.RB [ -nur1f ]
.RB [ -h
.IR inh.sam ]
.RB [ -t
.IR tag ]
.RB [ -R
.IR reg ]
.RB [ -b
.IR list "] " out.bam " " in1.bam " [" in2.bam " " in3.bam " ... " inN.bam ]

Merge multiple sorted alignment files, producing a single sorted output file
that contains all the input records and maintains the existing sort order.

If
.BR -h
is specified the @SQ headers of input files will be merged into the specified header, otherwise they will be merged
into a composite header created from the input headers.
If the @SQ headers differ in order this may require the output file to be re-sorted after merge.

The ordering of the records in the input files must match the usage of the
\fB-n\fP and \fB-t\fP command-line options.  If they do not, the output
order will be undefined.  See
.B sort
for information about record ordering.

.TP \"-------- split
.B split
samtools split
.RI [ options ]
.IR merged.sam | merged.bam | merged.cram

Splits a file by read group, producing one or more output files
matching a common prefix (by default based on the input filename)
each containing one read-group.

.TP \"-------- cat
.B cat
samtools cat
.RB [ -b
.IR list ]
.RB [ -h
.IR header.sam ]
.RB [ -o
.IR out.bam "] " in1.bam " " in2.bam " [ ... ]"

Concatenate BAMs or CRAMs. Although this works on either BAM or CRAM,
all input files must be the same format as each other. The sequence
dictionary of each input file must be identical, although this command
does not check this. This command uses a similar trick to
.B reheader
which enables fast BAM concatenation.

.TP \"-------- import
.B import
samtools import
.RI [ options ]
.IR in.fastq " [ ... ]"

Converts one or more FASTQ files to unaligned SAM, BAM or CRAM.  These
formats offer a richer capability of tracking sample meta-data via the
SAM header and per-read meta-data via the auxiliary tags.  The
.B fastq
command may be used to reverse this conversion.

.TP \"-------- fastq fasta
.B fastq/a
samtools fastq
.RI [ options ]
.I in.bam
.br
samtools fasta
.RI [ options ]
.I in.bam

Converts a BAM or CRAM into either FASTQ or FASTA format depending on the
command invoked. The files will be automatically compressed if the
file names have a .gz or .bgzf extension.

The input to this program must be collated by name.
Use
.B samtools collate
or
.B samtools sort -n
to ensure this.

.TP \"-------- faidx
.B faidx
samtools faidx <ref.fasta> [region1 [...]]

Index reference sequence in the FASTA format or extract subsequence from
indexed reference sequence. If no region is specified,
.B faidx
will index the file and create
.I <ref.fasta>.fai
on the disk. If regions are specified, the subsequences will be
retrieved and printed to stdout in the FASTA format.

The input file can be compressed in the
.B BGZF
format.

FASTQ files can be read and indexed by this command.  Without using
.B --fastq
any extracted subsequence will be in FASTA format.

.TP \"-------- fqidx
.B fqidx
samtools fqidx <ref.fastq> [region1 [...]]

Index reference sequence in the FASTQ format or extract subsequence from
indexed reference sequence. If no region is specified,
.B fqidx
will index the file and create
.I <ref.fastq>.fai
on the disk. If regions are specified, the subsequences will be
retrieved and printed to stdout in the FASTQ format.

The input file can be compressed in the
.B BGZF
format.

.B samtools fqidx
should only be used on fastq files with a small number of entries.
Trying to use it on a file containing millions of short sequencing reads
will produce an index that is almost as big as the original file, and
searches using the index will be very slow and use a lot of memory.

.TP \"-------- dict
.B dict
samtools dict
.IR ref.fasta | ref.fasta.gz

Create a sequence dictionary file from a fasta file.

.TP \"-------- calmd
.B calmd
samtools calmd
.RB [ -Eeubr ]
.RB [ -C
.IR capQcoef "] " aln.bam " " ref.fasta

Generate the MD tag. If the MD tag is already present, this command will
give a warning if the MD tag generated is different from the existing
tag. Output SAM by default.

Calmd can also read and write CRAM files although in most cases it is
pointless as CRAM recalculates MD and NM tags on the fly.  The one
exception to this case is where both input and output CRAM files
have been / are being created with the \fIno_ref\fR option.

.TP \"-------- fixmate
.B fixmate
.na
samtools fixmate
.RB [ -rpcm ]
.RB [ -O
.IR format ]
.I in.nameSrt.bam out.bam
.ad

Fill in mate coordinates, ISIZE and mate related flags from a
name-sorted alignment.

.TP \"-------- markdup
.B markdup
.na
samtools markdup
.RB [ -l
.IR length ]
.RB [ -r ]
.RB [ -s ]
.RB [ -T ]
.RB [ -S ]
.I in.algsort.bam out.bam
.ad

Mark duplicate alignments from a coordinate sorted file that
has been run through \fBsamtools fixmate\fR with the \fB-m\fR option.  This program
relies on the MC and ms tags that fixmate provides.

.TP \"-------- rmdup
.B rmdup
samtools rmdup [-sS] <input.srt.bam> <out.bam>

.B This command is obsolete.  Use markdup instead.

.TP \"-------- addreplacerg
.B addreplacerg
samtools addreplacerg
.RB [ -r
.I rg-line
|
.B -R
.IR rg-ID ]
.RB [ -m
.IR mode ]
.RB [ -l
.IR level ]
.RB [ -o
.IR out.bam ]
.I in.bam

Adds or replaces read group tags in a file.

.TP \"-------- reheader
.B reheader
samtools reheader
.RB [ -iP ]
.I in.header.sam in.bam

Replace the header in
.I in.bam
with the header in
.IR in.header.sam .
This command is much faster than replacing the header with a
BAM\(->SAM\(->BAM conversion.

By default this command outputs the BAM or CRAM file to standard
output (stdout), but for CRAM format files it has the option to
perform an in-place edit, both reading and writing to the same file.
No validity checking is performed on the header, nor that it is suitable
to use with the sequence data itself.

.TP \"-------- targetcut
.B targetcut
samtools targetcut
.RB [ -Q
.IR minBaseQ ]
.RB [ -i
.IR inPenalty ]
.RB [ -0
.IR em0 ]
.RB [ -1
.IR em1 ]
.RB [ -2
.IR em2 ]
.RB [ -f
.IR ref "] " in.bam

This command identifies target regions by examining the continuity of read depth, computes
haploid consensus sequences of targets and outputs a SAM with each sequence corresponding
to a target. When option
.B -f
is in use, BAQ will be applied. This command is
.B only
designed for cutting fosmid clones from fosmid pool sequencing [Ref. Kitzman et al. (2010)].

.TP \"-------- phase
.B phase
samtools phase
.RB [ -AF ]
.RB [ -k
.IR len ]
.RB [ -b
.IR prefix ]
.RB [ -q
.IR minLOD ]
.RB [ -Q
.IR minBaseQ "] " in.bam

Call and phase heterozygous SNPs.

.TP \"-------- depad
.B depad
samtools depad
.RB [ -SsCu1 ]
.RB [ -T
.IR ref.fa ]
.RB [ -o
.IR output "] " in.bam

Converts a BAM aligned against a padded reference to a BAM aligned
against the depadded reference.  The padded reference may contain
verbatim "*" bases in it, but "*" bases are also counted in the
reference numbering.  This means that a sequence base-call aligned
against a reference "*" is considered to be a cigar match ("M" or "X")
operator (if the base-call is "A", "C", "G" or "T").  After depadding
the reference "*" bases are deleted and such aligned sequence
base-calls become insertions.  Similarly transformations apply for
deletions and padding cigar operations.

.TP \"-------- ampliconclip
.B ampliconclip
samtools ampliconclip
.RB [ -o
.IR out.file ]
.RB [ -f
.IR stat.file ]
.RB [ --soft-clip ]
.RB [ --hard-clip ]
.RB [ --both-ends ]
.RB [ --strand ]
.RB [ --clipped ]
.RB [ --fail ]
.RB [ --no-PG ]
.B -b
.I bed.file in.file

Clip reads in a SAM compatible file based on data from a BED file.

.TP \"-------- samples
.B samples
samtools samples
.RB [ -o
.IR out.file ]
.RB [ -i ]
.RB [ -T
.IR TAG ]
.RB [ -f
.IR refs.fasta ]
.RB [ -F
.IR refs_list ]
.RB [ -X ]

Prints the samples from alignment files

.SH SAMTOOLS OPTIONS
These are options that are passed after the \fBsamtools\fR command,
before any sub-command is specified.
.EE
.TP \"-------- help etc
.BR help ,\  --help
Display a brief usage message listing the samtools commands available.
If the name of a command is also given, e.g.,
.BR samtools\ help\ view ,
the detailed usage message for that particular command is displayed.

.TP
.B --version
Display the version numbers and copyright information for samtools and
the important libraries used by samtools.

.TP
.B --version-only
Display the full samtools version number in a machine-readable format.
.PP
.SH GLOBAL COMMAND OPTIONS
.PP
Several long-options are shared between multiple samtools sub-commands:
\fB--input-fmt\fR, \fB--input-fmt-option\fR, \fB--output-fmt\fR,
\fB--output-fmt-option\fR, \fB--reference\fR, \fB--write-index\fR,
and \fB--verbosity\fR.
The input format is typically auto-detected so specifying the format
is usually unnecessary and the option is included for completeness.
Note that not all subcommands have all options.  Consult the subcommand
help for more details.
.PP
Format strings recognised are "sam", "sam.gz", "bam" and "cram".  They may be
followed by a comma separated list of options as \fIkey\fR or
\fIkey\fR=\fIvalue\fR. See below for examples.
.PP
The \fBfmt-option\fR arguments accept either a single \fIoption\fR or
\fIoption\fR=\fIvalue\fR.  Note that some options only work on some
file formats and only on read or write streams.  If value is
unspecified for a boolean option, the value is assumed to be 1.  The
valid options are as follows.
.RS 0
.\" General purpose
.TP 4
.BI level= INT
Output only. Specifies the compression level from 1 to 9, or 0 for
uncompressed.  If the output format is SAM, this also enables BGZF
compression, otherwise SAM defaults to uncompressed.
.TP
.BI nthreads= INT
Specifies the number of threads to use during encoding and/or
decoding.  For BAM this will be encoding only.  In CRAM the threads
are dynamically shared between encoder and decoder.
.TP
.BI filter= STRING
Apply filter STRING to all incoming records, rejecting any that do not
satisfy the expression.  See the FILTER EXPRESSIONS section below for
specifics.
.\" CRAM specific
.TP
.BI reference= fasta_file
Specifies a FASTA reference file for use in CRAM encoding or decoding.
It usually is not required for decoding except in the situation of the
MD5 not being obtainable via the REF_PATH or REF_CACHE environment variables.
.TP
.BI decode_md= 0|1
CRAM input only; defaults to 1 (on).  CRAM does not typically store
MD and NM tags, preferring to generate them on the fly.  When this
option is 0 missing MD, NM tags will not be generated.  It can be
particularly useful when combined with a file encoded using store_md=1
and store_nm=1.
.TP
.BI store_md= 0|1
CRAM output only; defaults to 0 (off).  CRAM normally only stores MD
tags when the reference is unknown and lets the decoder generate these
values on-the-fly (see decode_md).
.TP
.BI store_nm= 0|1
CRAM output only; defaults to 0 (off).  CRAM normally only stores NM
tags when the reference is unknown and lets the decoder generate these
values on-the-fly (see decode_md).
.TP
.BI ignore_md5= 0|1
CRAM input only; defaults to 0 (off).  When enabled, md5 checksum
errors on the reference sequence and block checksum errors within CRAM
are ignored.  Use of this option is strongly discouraged.
.TP
.BI required_fields= bit-field
CRAM input only; specifies which SAM columns need to be populated.
By default all fields are used.  Limiting the decode to specific
columns can have significant performance gains.  The bit-field is a
numerical value constructed from the following table.
.TS
rb l .
0x1	SAM_QNAME
0x2	SAM_FLAG
0x4	SAM_RNAME
0x8	SAM_POS
0x10	SAM_MAPQ
0x20	SAM_CIGAR
0x40	SAM_RNEXT
0x80	SAM_PNEXT
0x100	SAM_TLEN
0x200	SAM_SEQ
0x400	SAM_QUAL
0x800	SAM_AUX
0x1000	SAM_RGAUX
.TE
.TP
.BI name_prefix= string
CRAM input only; defaults to output filename.  Any sequences with
auto-generated read names will use \fIstring\fR as the name prefix.
.TP
.BI multi_seq_per_slice= 0|1
CRAM output only; defaults to 0 (off).  By default CRAM generates one
container per reference sequence, except in the case of many small
references (such as a fragmented assembly).
.TP
.BI version= major.minor
CRAM output only.  Specifies the CRAM version number.  Acceptable
values are "2.1" and "3.0".
.TP
.BI seqs_per_slice= INT
CRAM output only; defaults to 10000.
.TP
.BI slices_per_container= INT
CRAM output only; defaults to 1.  The effect of having multiple slices
per container is to share the compression header block between
multiple slices.  This is unlikely to have any significant impact
unless the number of sequences per slice is reduced.  (Together these
two options control the granularity of random access.)
.TP
.BI embed_ref= 0|1
CRAM output only; defaults to 0 (off).  If 1, this will store portions
of the reference sequence in each slice, permitting decode without
having requiring an external copy of the reference sequence.
.TP
.BI no_ref= 0|1
CRAM output only; defaults to 0 (off).  If 1, sequences will be stored
verbatim with no reference encoding.  This can be useful if no
reference is available for the file.
.TP
.BI use_bzip2= 0|1
CRAM output only; defaults to 0 (off).  Permits use of bzip2 in CRAM
block compression.
.TP
.BI use_lzma= 0|1
CRAM output only; defaults to 0 (off).  Permits use of lzma in CRAM
block compression.
.TP
.BI use_fqz= 0|1
CRAM \(>= 3.1 output only; enables and disables the fqzcomp quality
compression method.  This is on by default for version 3.1 and above
only when the small and archive profiles are in use.
.TP
.BI use_tok= 0|1
CRAM \(>= 3.1 output only; enables and disables the namne tokeniser
compression method.  This is on by default for version 3.1 and above.
.TP
.BI lossy_names= 0|1
CRAM output only; defaults to 0 (off).  If 1, templates with all
members within the same CRAM slice will have their read names
removed.  New names will be automatically generated during decoding.
Also see the \fBname_prefix\fR option.
.TP
.B fast, normal, small, archive
CRAM output only.  Set the CRAM compression profile.  This is a
simplified way of setting many output options at once.  It changes the
following options according to the profile in use.  The "normal"
profile is the default.

.TS
lb l l l l .
Option	\fBfast\fR	\fBnormal\fR	\fBsmall\fR	\fBarchive\fR
level	1	5	6	7
use_bzip2	off	off	on	on
use_lzma	off	off	off	on if level>7
use_tok(*)	off	on	on	on
use_fqz(*)	off	off	on	on
use_arith(*)	off	off	off	on
seqs_per_slice	10000	10000	25000	100000
.TE

(*) \fBuse_tok\fR, \fBuse_fqz\fR and \fBuse_arith\fR are only
enabled for CRAM version 3.1 and above.

The \fBlevel\fR listed is only the default value, and will not be set
if it has been explicitly changed already.  Additionally
\fBbases_per_slice\fR is set to \fB500*seqs_per_slice\fR unless previously
explicitly set.

.RE
.PP
For example:
.EX 4
samtools view --input-fmt-option decode_md=0
    --output-fmt cram,version=3.0 --output-fmt-option embed_ref
    --output-fmt-option seqs_per_slice=2000 -o foo.cram foo.bam

samtools view -O cram,small -o bar.cram bar.bam
.EE
.PP
The \fB--write-index\fR option enables automatic index creation while
writing out BAM, CRAM or bgzf SAM files.  Note to get compressed SAM
as the output format you need to manually request a compression level,
otherwise all SAM files are uncompressed.  By default SAM and BAM will
use CSI indices while CRAM will use CRAI indices.  If you need to
create BAI indices note that it is possible to specify the name of
the index being written to, and hence the format, by using the
\fBfilename##idx##indexname\fR notation.
.PP
For example: to convert a BAM to a compressed SAM with CSI indexing:
.EX 4
samtools view -h -O sam,level=6 --write-index in.bam -o out.sam.gz
.EE
.PP
To convert a SAM to a compressed BAM using BAI indexing:
.EX 4
samtools view --write-index in.sam -o out.bam##idx##out.bam.bai
.EE
.PP
The \fB--verbosity \fIINT\fR option sets the verbosity level for samtools
and HTSlib.  The default is 3 (HTS_LOG_WARNING); 2 reduces warning messages
and 0 or 1 also reduces some error messages, while values greater than 3
produce increasing numbers of additional warnings and logging messages.

.PP
.SH REFERENCE SEQUENCES
.PP
The CRAM format requires use of a reference sequence for both reading
and writing.
.PP
When reading a CRAM the \fB@SQ\fR headers are interrogated to identify
the reference sequence MD5sum (\fBM5:\fR tag) and the local reference
sequence filename (\fBUR:\fR tag).  Note that \fIhttp://\fR and
\fIftp://\fR based URLs in the UR: field are not used, but local fasta
filenames (with or without \fIfile://\fR) can be used.
.PP
To create a CRAM the \fB@SQ\fR headers will also be read to identify
the reference sequences, but M5: and UR: tags may not be present. In
this case the \fB-T\fR and \fB-t\fR options of samtools view may be
used to specify the fasta or fasta.fai filenames respectively
(provided the .fasta.fai file is also backed up by a .fasta file).
.PP
The search order to obtain a reference is:
.IP 1. 3
Use any local file specified by the command line options (eg -T).
.IP 2. 3
Look for MD5 via REF_CACHE environment variable.
.IP 3. 3
Look for MD5 in each element of the REF_PATH environment variable.
.IP 4. 3
Look for a local file listed in the UR: header tag.

.PP
.SH FILTER EXPRESSIONS
.PP
Filter expressions are used as an on-the-fly checking of incoming SAM,
BAM or CRAM records, discarding records that do not match the
specified expression.

The language used is primarily C style, but with a few differences in
the precedence rules for bit operators and the inclusion of regular
expression matching.

The operator precedence, from strongest binding to weakest, is:

.TS
l lb l .
Grouping	(, )	E.g. "(1+2)*3"
Values:	literals, vars	Numbers, strings and variables
Unary ops:	+, -, !, ~ 	E.g. -10 +10, !10 (not), ~5 (bit not)
Math ops:	*, /, %	Multiply, division and (integer) modulo
Math ops:	+, -	Addition / subtraction
Bit-wise:	&	Integer AND
Bit-wise	^	Integer XOR
Bit-wise	|	Integer OR
Conditionals:	>, >=, <, <=
Equality:	==, !=, =~, !~	=~ and !~ match regular expressions
Boolean:	&&, ||	Logical AND / OR
.TE

Expressions are computed using floating point mathematics, so "10 / 4"
evaluates to 2.5 rather than 2.  They may be written as integers in
decimal or "0x" plus hexadecimal, and floating point with or without
exponents.However operations that require integers first do an
implicit type conversion, so "7.9 % 5" is 2 and "7.9 & 4.1" is
equivalent to "7 & 4", which is 4.  Strings are always specified using
double quotes.  To get a double quote in a string, use backslash.
Similarly a double backslash is used to get a literal backslash.  For
example \fBab\\"c\\\\d\fR is the string \fBab"c\\d\fR.

Comparison operators are evaluated as a match being 1 and a mismatch
being 0, thus "(2 > 1) + (3 < 5)" evaluates as 2.  All comparisons
involving undefined (null) values are deemed to be false.

The variables are where the file format specifics are accessed from
the expression.  The variables correspond to SAM fields, for example
to find paired alignments with high mapping quality and a very large
insert size, we may use the expression "\fBmapq >= 30 && (tlen >= 100000 || tlen <= -100000)\fR".
Valid variable names and their data types are:

.TS
lb l l .
endpos	int	Alignment end position (1-based)
flag	int	Combined FLAG field
flag.paired	int	Single bit, 0 or 1
flag.proper_pair	int	Single bit, 0 or 2
flag.unmap	int	Single bit, 0 or 4
flag.munmap	int	Single bit, 0 or 8
flag.reverse	int	Single bit, 0 or 16
flag.mreverse	int	Single bit, 0 or 32
flag.read1	int	Single bit, 0 or 64
flag.read2	int	Single bit, 0 or 128
flag.secondary	int	Single bit, 0 or 256
flag.qcfail	int	Single bit, 0 or 512
flag.dup	int	Single bit, 0 or 1024
flag.supplementary	int	Single bit, 0 or 2048
library	string	Library (LB header via RG)
mapq	int	Mapping quality
mpos	int	Synonym for pnext
mrefid	int	Mate reference number (0 based)
mrname	string	Synonym for rnext
ncigar	int	Number of cigar operations
pnext	int	Mate's alignment position (1-based)
pos	int	Alignment position (1-based)
qlen	int	Alignment length: no. query bases
qname	string	Query name
qual	string	Quality values (raw, 0 based)
refid	int	Integer reference number (0 based)
rlen	int	Alignment length: no. reference bases
rname	string	Reference name
rnext	string	Mate's reference name
sclen	int	Number of soft-clipped bases
seq	string	Sequence
tlen	int	Template length (insert size)
[XX]	int / string	XX tag value
.TE

Flags are returned either as the whole flag value or by checking for a
single bit.  Hence the filter expression \fBflag.dup\fR is
equivalent to \fBflag & 1024\fR.

"qlen" and "rlen" are measured using the CIGAR string to count the
number of query (sequence) and reference bases consumed.  Note "qlen"
may not exactly match the length of the "seq" field if the sequence is
"*".  "sclen" is the number of soft-clipped bases.  When combined in
"qlen-sclen" it can give the number of sequence bases used in the
alignment, distinguishing between global alignment and local alignment
length.

"endpos" is the (1-based inclusive) position of the rightmost mapped base
of the read, as measured using the CIGAR string, and for mapped reads
is equivalent to "pos+rlen-1". For unmapped reads, it is the same as
"pos".

Reference names may be matched either by their string forms ("rname"
and "mrname") or as the Nth \fB@SQ\fR line (counting from zero) as
stored in BAM using "tid" and "mtid" respectively.

Auxiliary tags are described in square brackets and these expand to
either integer or string as defined by the tag itself (\fBXX:Z:\fIstring\fR or
\fBXX:i:\fIint\fR).  For example \fB[NM]>=10\fR can be used to look
for alignments with many mismatches and \fB[RG]=~"grp[ABC]-"\fR will
match the read-group string.

If no comparison is used with an auxiliary tag it is taken simply to
be a test for the existence of that tag.  So \fB[NM]\fR will return any
record containing an NM tag, even if that tag is zero (\fBNM:i:0\fR).
In htslib <= 1.15 negating this with \fB![NM]\fR gave misleading
results as it was true if the tag did not exist or did exist but was
zero.  Now this is strictly does-not-exist.  An explicit
\fBexists([NM])\fR and \fB!exists([NM])\fR function has also been added
to make this intention clear.

Similarly in htslib <= 1.15 using \fB[NM]!=0\fR was true both when the
tag existed and was not zero as well as when the tag did not exist.
From 1.16 onwards all comparison operators are only true for tags that
exist, so \fB[NM]!=0\fR works as expected.

Some simple functions are available to operate on strings.  These
treat the strings as arrays of bytes, permitting their length,
minimum, maximum and average values to be computed.  These are useful
for processing Quality Scores.

.TS
lb l .
length(x)	Length of the string (excluding nul char)
min(x)	Minimum byte value in the string
max(x)	Maximum byte value in the string
avg(x)	Average byte value in the string
.TE

Note that "avg" is a floating point value and it may be NAN for empty
strings.  This means that "avg(qual)" does not produce an error for
records that have both seq and qual of "*".  NAN values will fail any
conditional checks, so e.g. "avg(qual) > 20" works and will not report
these records.  NAN also fails all equality, < and > comparisons, and
returns zero when given as an argument to the \fBexists\fR function.
It can be negated with \fB!x\fR in which case it becomes true.

Functions that operate on both strings and numerics:

.TS
lb l .
exists(x)	True if the value exists (or is explicitly true).
default(x,d)	Value \fBx\fR if it exists or \fBd\fR if not.
.TE

Functions that apply only to numeric values:

.TS
lb l .
sqrt(x)	Square root of \fBx\fR
log(x)	Natural logarithm of \fBx\fR
pow(x, y)	Power function, \fBx\fR to the power of \fBy\fR
exp(x)	Base-e exponential, equivalent to \fBpow(e,x)\fR
.TE

.PP
.SH ENVIRONMENT VARIABLES
.PP
.TP
.B HTS_PATH
A colon-separated list of directories in which to search for HTSlib plugins.
If $HTS_PATH starts or ends with a colon or contains a double colon (\fB::\fP),
the built-in list of directories is searched at that point in the search.

If no HTS_PATH variable is defined, the built-in list of directories
specified when HTSlib was built is used, which typically includes
\fB/usr/local/libexec/htslib\fP and similar directories.

.TP
.B REF_PATH
A colon separated (semi-colon on Windows) list of locations in which
to look for sequences identified by their MD5sums.  This can be either
a list of directories or URLs. Note that if a URL is included then the
colon in http:// and ftp:// and the optional port number will be
treated as part of the URL and not a PATH field separator.
For URLs, the text \fB%s\fR will be replaced by the MD5sum being
read.

If no REF_PATH has been specified it will default to
\fBhttp://www.ebi.ac.uk/ena/cram/md5/%s\fR and if REF_CACHE is also unset,
it will be set to \fB$XDG_CACHE_HOME/hts-ref/%2s/%2s/%s\fR.
If \fB$XDG_CACHE_HOME\fR is unset, \fB$HOME/.cache\fR (or a local system
temporary directory if no home directory is found) will be used similarly.

.TP
.B REF_CACHE
This can be defined to a single location housing a local cache of
references.  Upon downloading a reference it will be stored in the
location pointed to by REF_CACHE.  REF_CACHE will be searched
before attempting to load via the REF_PATH search list.  If no
REF_PATH is defined, both REF_PATH and REF_CACHE will be automatically
set (see above), but if REF_PATH is defined and REF_CACHE not then no
local cache is used.

To avoid many files being stored in the same directory, REF_CACHE may
be defined as a pattern using \fB%\fR\fInum\fR\fBs\fR to consume \fInum\fR
characters of the MD5sum and \fB%s\fR to consume all remaining characters.
If REF_CACHE lacks \fB%s\fR then it will get an implicit \fB/%s\fR appended.

To aid population of the REF_CACHE directory a script
\fBmisc/seq_cache_populate.pl\fR is provided in the Samtools
distribution. This takes a fasta file or a directory of fasta files
and generates the MD5sum named files.

For example if you use \fBseq_cache_populate -subdirs 2 -root
/local/ref_cache\fR to create 2 nested subdirectories (the default),
each consuming 2 characters of the MD5sum, then REF_CACHE must be set
to \fB/local/ref_cache/%2s/%2s/%s\fR.
.PP
.SH EXAMPLES
.IP o 2
Import SAM to BAM when
.B @SQ
lines are present in the header:
.EX 2
samtools view -b aln.sam > aln.bam
.EE
If
.B @SQ
lines are absent:
.EX 2
samtools faidx ref.fa
samtools view -bt ref.fa.fai aln.sam > aln.bam
.EE
where
.I ref.fa.fai
is generated automatically by the
.B faidx
command.

.IP o 2
Convert a BAM file to a CRAM file using a local reference sequence.
.EX 2
samtools view -C -T ref.fa aln.bam > aln.cram
.EE

.SH AUTHOR
.PP
Heng Li from the Sanger Institute wrote the original C version of
samtools.  Bob Handsaker from the Broad Institute implemented the BGZF
library.  Petr Danecek and Heng Li wrote the VCF/BCF implementation.
James Bonfield from the Sanger Institute developed the CRAM
implementation.  Other large code contributions have been made by
John Marshall, Rob Davies, Martin Pollard, Andrew Whitwham, Valeriu Ohan
(all while primarily at the Sanger Institute), with numerous other
smaller but valuable contributions.  See the per-command manual pages
for further authorship.

.SH SEE ALSO
.IR samtools-addreplacerg (1),
.IR samtools-ampliconclip (1),
.IR samtools-ampliconstats (1),
.IR samtools-bedcov (1),
.IR samtools-calmd (1),
.IR samtools-cat (1),
.IR samtools-collate (1),
.IR samtools-consensus (1),
.IR samtools-coverage (1),
.IR samtools-depad (1),
.IR samtools-depth (1),
.IR samtools-dict (1),
.IR samtools-faidx (1),
.IR samtools-fasta (1),
.IR samtools-fastq (1),
.IR samtools-fixmate (1),
.IR samtools-flags (1),
.IR samtools-flagstat (1),
.IR samtools-fqidx (1),
.IR samtools-head (1),
.IR samtools-idxstats (1),
.IR samtools-import (1),
.IR samtools-index (1),
.IR samtools-markdup (1),
.IR samtools-merge (1),
.IR samtools-mpileup (1),
.IR samtools-phase (1),
.IR samtools-quickcheck (1),
.IR samtools-reference (1),
.IR samtools-reheader (1),
.IR samtools-rmdup (1),
.IR samtools-sort (1),
.IR samtools-split (1),
.IR samtools-stats (1),
.IR samtools-targetcut (1),
.IR samtools-tview (1),
.IR samtools-view (1),
.IR bcftools (1),
.IR sam (5),
.IR tabix (1)
.PP
Samtools website: <http://www.htslib.org/>
.br
File format specification of SAM/BAM,CRAM,VCF/BCF: <http://samtools.github.io/hts-specs>
.br
Samtools latest source: <https://github.com/samtools/samtools>
.br
HTSlib latest source: <https://github.com/samtools/htslib>
.br
Bcftools website: <http://samtools.github.io/bcftools>