.TH minimap2 1 "12 March 2024" "minimap2-2.28 (r1209)" "Bioinformatics tools" .SH NAME .PP minimap2 - mapping and alignment between collections of DNA sequences .SH SYNOPSIS * Indexing the target sequences (optional): .RS 4 minimap2 .RB [ -x .IR preset ] .B -d .I target.mmi .I target.fa .br minimap2 .RB [ -H ] .RB [ -k .IR kmer ] .RB [ -w .IR miniWinSize ] .RB [ -I .IR batchSize ] .B -d .I target.mmi .I target.fa .RE * Long-read alignment with CIGAR: .RS 4 minimap2 .B -a .RB [ -x .IR preset ] .I target.mmi .I query.fa > .I output.sam .br minimap2 .B -c .RB [ -H ] .RB [ -k .IR kmer ] .RB [ -w .IR miniWinSize ] .RB [ ... ] .I target.fa .I query.fa > .I output.paf .RE * Long-read overlap without CIGAR: .RS 4 minimap2 .B -x ava-ont .RB [ -t .IR nThreads ] .I target.fa .I query.fa > .I output.paf .RE .SH DESCRIPTION .PP Minimap2 is a fast sequence mapping and alignment program that can find overlaps between long noisy reads, or map long reads or their assemblies to a reference genome optionally with detailed alignment (i.e. CIGAR). At present, it works efficiently with query sequences from a few kilobases to ~100 megabases in length at a error rate ~15%. Minimap2 outputs in the PAF or the SAM format. .SH OPTIONS .SS Indexing options .TP 10 .BI -k \ INT Minimizer k-mer length [15] .TP .BI -w \ INT Minimizer window size [10]. A minimizer is the smallest k-mer in a window of w consecutive k-mers. .TP .BI -j \ INT Syncmer submer size [10]. Option .B -j and .B -w will override each: if .B -w is applied after .BR -j , .B -j will have no effect, and vice versa. .TP .B -H Use homopolymer-compressed (HPC) minimizers. An HPC sequence is constructed by contracting homopolymer runs to a single base. An HPC minimizer is a minimizer on the HPC sequence. .TP .BI -I \ NUM Load at most .I NUM target bases into RAM for indexing [8G]. If there are more than .I NUM bases in .IR target.fa , minimap2 needs to read .I query.fa multiple times to map it against each batch of target sequences. This would create a multi-part index. .I NUM may be ending with k/K/m/M/g/G. NB: mapping quality is incorrect given a multi-part index. See also option .BR --split-prefix . .TP .B --idx-no-seq Don't store target sequences in the index. It saves disk space and memory but the index generated with this option will not work with .B -a or .BR -c . When base-level alignment is not requested, this option is automatically applied. .TP .BI -d \ FILE Save the minimizer index of .I target.fa to .I FILE [no dump]. Minimap2 indexing is fast. It can index the human genome in a couple of minutes. If even shorter startup time is desired, use this option to save the index. Indexing options are fixed in the index file. When an index file is provided as the target sequences, options .BR -H , .BR -k , .BR -w , .B -I will be effectively overridden by the options stored in the index file. .TP .BI --alt \ FILE List of ALT contigs [null] .TP .BI --alt-drop \ FLOAT Drop ALT hits by .I FLOAT fraction when ranking and computing mapping quality [0.15] .SS Mapping options .TP 10 .BI -f \ FLOAT | INT1 [, INT2 ] If fraction, ignore top .I FLOAT fraction of most frequent minimizers [0.0002]. If integer, ignore minimizers occuring more than .I INT1 times. .I INT2 is only effective in the .B --sr or .B -xsr mode, which sets the threshold for a second round of seeding. .TP .BI -U \ INT1 [, INT2 ] Lower and upper bounds of k-mer occurrences [10,1000000]. The final k-mer occurrence threshold is .RI max{ INT1 ,\ min{ INT2 , .BR -f }}. This option prevents excessively small or large .B -f estimated from the input reference. Available since r1034 and deprecating .B --min-occ-floor in earlier versions of minimap2. .TP .BI --q-occ-frac \ FLOAT Discard a query minimizer if its occurrence is higher than .I FLOAT fraction of query minimizers and than the reference occurrence threshold [0.01]. Set 0 to disable. Available since r1105. .TP .BI -e \ INT Sample a high-frequency minimizer every .I INT basepairs [500]. .TP .BI -g \ NUM Stop chain enlongation if there are no minimizers within .IR NUM -bp [10k]. .TP .BI -r \ NUM1 [, NUM2 ] Bandwidth for chaining and base alignment [500,20k]. .I NUM1 is used for initial chaining and alignment extension; .I NUM2 for RMQ-based re-chaining and closing gaps in alignments. .TP .BI -n \ INT Discard chains consisting of .RI < INT number of minimizers [3] .TP .BI -m \ INT Discard chains with chaining score .RI < INT [40]. Chaining score equals the approximate number of matching bases minus a concave gap penalty. It is computed with dynamic programming. .TP .B -D If query sequence name/length are identical to the target name/length, ignore diagonal anchors. This option also reduces DP-based extension along the diagonal. .TP .B -P Retain all chains and don't attempt to set primary chains. Options .B -p and .B -N have no effect when this option is in use. .TP .BR --dual = yes | no If .BR no , skip query-target pairs wherein the query name is lexicographically greater than the target name [yes] .TP .B -X Equivalent to .RB ' -DP .BR --dual = no .BR --no-long-join '. Primarily used for all-vs-all read overlapping. .TP .BI -p \ FLOAT Minimal secondary-to-primary score ratio to output secondary mappings [0.8]. Between two chains overlaping over half of the shorter chain (controlled by .BR -M ), the chain with a lower score is secondary to the chain with a higher score. If the ratio of the scores is below .IR FLOAT , the secondary chain will not be outputted or extended with DP alignment later. This option has no effect when .B -X is applied. .TP .BI -N \ INT Output at most .I INT secondary alignments [5]. This option has no effect when .B -X is applied. .TP .BI -G \ NUM Maximum gap on the reference (effective with .BR -xsplice / --splice ). This option also changes the chaining and alignment band width to .IR NUM . Increasing this option slows down spliced alignment. [200k] .TP .BI -F \ NUM Maximum fragment length (aka insert size; effective with .BR -xsr / --frag = yes ) [800] .TP .BI -M \ FLOAT Mark as secondary a chain that overlaps with a better chain by .I FLOAT or more of the shorter chain [0.5] .TP .BR --rmq = no | yes Use the minigraph chaining algorithm [no]. The minigraph algorithm is better for aligning contigs through long INDELs. .TP .BI --rmq-inner \ NUM Apply full dynamic programming for anchors within distance .I NUM [1000]. .TP .B --hard-mask-level Honor option .B -M and disable a heurstic to save unmapped subsequences and disables .BR --mask-len . .TP .BI --mask-len \ NUM Keep an alignment if dropping it leaves an unaligned region on query longer than .IR INT [inf]. Effective without .BR --hard-mask-level . .TP .BI --max-chain-skip \ INT A heuristics that stops chaining early [25]. Minimap2 uses dynamic programming for chaining. The time complexity is quadratic in the number of seeds. This option makes minimap2 exits the inner loop if it repeatedly sees seeds already on chains. Set .I INT to a large number to switch off this heurstics. .TP .BI --max-chain-iter \ INT Check up to .I INT partial chains during chaining [5000]. This is a heuristic to avoid quadratic time complexity in the worst case. .TP .BI --chain-gap-scale \ FLOAT Scale of gap cost during chaining [1.0] .TP .B --no-long-join Disable the long gap patching heuristic. When this option is applied, the maximum alignment gap is mostly controlled by .BR -r . .TP .B --splice Enable the splice alignment mode. .TP .B --sr Enable short-read alignment heuristics. In the short-read mode, minimap2 applies a second round of chaining with a higher minimizer occurrence threshold if no good chain is found. In addition, minimap2 attempts to patch gaps between seeds with ungapped alignment. .TP .BI --split-prefix \ STR Prefix to create temporary files. Typically used for a multi-part index. .TP .BR --frag = no | yes Whether to enable the fragment mode [no] .TP .B --for-only Only map to the forward strand of the reference sequences. For paired-end reads in the forward-reverse orientation, the first read is mapped to forward strand of the reference and the second read to the reverse stand. .TP .B --rev-only Only map to the reverse complement strand of the reference sequences. .TP .BR --heap-sort = no | yes If yes, sort anchors with heap merge, instead of radix sort. Heap merge is faster for short reads, but slower for long reads. [no] .TP .B --no-pairing Treat two reads in a pair as independent reads. The mate related fields in SAM are still properly populated. .TP .B --no-hash-name Produce the same alignment for identical sequences regardless of their sequence names. .SS Alignment options .TP 10 .BI -A \ INT Matching score [2] .TP .BI -B \ INT Mismatching penalty [4] .TP .BI -b \ INT Mismatching penalty for transitions [same as .BR -B ]. .TP .BI -O \ INT1[,INT2] Gap open penalty [4,24]. If .I INT2 is not specified, it is set to .IR INT1 . .TP .BI -E \ INT1[,INT2] Gap extension penalty [2,1]. A gap of length .I k costs .RI min{ O1 + k * E1 , O2 + k * E2 }. In the splice mode, the second gap penalties are not used. .TP .BI -J \ INT Splice model [1]. 0 for the original minimap2 splice model that always penalizes non-GT-AG splicing; 1 for the miniprot model that considers non-GT-AG. Option .B -C has no effect with the default .BR -J1 . .BR -J0 . .TP .BI -C \ INT Cost for a non-canonical GT-AG splicing (effective with .B --splice .BR -J0 ) [0]. .TP .BI -z \ INT1[,INT2] Truncate an alignment if the running alignment score drops too quickly along the diagonal of the DP matrix (diagonal X-drop, or Z-drop) [400,200]. If the drop of score is above .IR INT2 , minimap2 will reverse complement the query in the related region and align again to test small inversions. Minimap2 truncates alignment if there is an inversion or the drop of score is greater than .IR INT1 . Decrease .I INT2 to find small inversions at the cost of performance and false positives. Increase .I INT1 to improves the contiguity of alignment at the cost of poor alignment in the middle. .TP .BI -s \ INT Minimal peak DP alignment score to output [40]. The peak score is computed from the final CIGAR. It is the score of the max scoring segment in the alignment and may be different from the total alignment score. .TP .BI -u \ CHAR How to find canonical splicing sites GT-AG - .BR f : transcript strand; .BR b : both strands; .BR n : no attempt to match GT-AG [n] .TP .BI --end-bonus \ INT Score bonus when alignment extends to the end of the query sequence [0]. .TP .BI --score-N \ INT Score of a mismatch involving ambiguous bases [1]. .TP .BR --splice-flank = yes | no Assume the next base to a .B GT donor site tends to be A/G (91% in human and 92% in mouse) and the preceding base to a .B AG acceptor tends to be C/T [no]. This trend is evolutionarily conservative, all the way to S. cerevisiae (PMID:18688272). Specifying this option generally leads to higher junction accuracy by several percents, so it is applied by default with .BR --splice . However, the SIRV control does not honor this trend (only ~60%). This option reduces accuracy. If you are benchmarking minimap2 on SIRV data, please add .B --splice-flank=no to the command line. .TP .BR --junc-bed \ FILE Gene annotations in the BED12 format (aka 12-column BED), or intron positions in 5-column BED. With this option, minimap2 prefers splicing in annotations. BED12 file can be converted from GTF/GFF3 with `paftools.js gff2bed anno.gtf' []. .TP .BR --junc-bonus \ INT Score bonus for a splice donor or acceptor found in annotation (effective with .BR --junc-bed ) [9]. .TP .BI --end-seed-pen \ INT Drop a terminal anchor if .IR s 65535 operators at the CG tag. Older tools are unable to convert alignments with >65535 CIGAR ops to BAM. This option makes minimap2 SAM compatible with older tools. Newer tools recognizes this tag and reconstruct the real CIGAR in memory. .TP .BI -R \ STR SAM read group line in a format like .B @RG\\\\tID:foo\\\\tSM:bar []. .TP .B -y Copy input FASTA/Q comments to output. .TP .B -c Generate CIGAR. In PAF, the CIGAR is written to the `cg' custom tag. .TP .BI --cs[= STR ] Output the .B cs tag. .I STR can be either .I short or .IR long . If no .I STR is given, .I short is assumed. [none] .TP .B --MD Output the MD tag (see the SAM spec). .TP .B --eqx Output =/X CIGAR operators for sequence match/mismatch. .TP .B -Y In SAM output, use soft clipping for supplementary alignments. .TP .B --secondary-seq In SAM output, show query sequences for secondary alignments. .TP .BI --seed \ INT Integer seed for randomizing equally best hits. Minimap2 hashes .I INT and read name when choosing between equally best hits. [11] .TP .BI -t \ INT Number of threads [3]. Minimap2 uses at most three threads when indexing target sequences, and uses up to .IR INT +1 threads when mapping (the extra thread is for I/O, which is frequently idle and takes little CPU time). .TP .B -2 Use two I/O threads during mapping. By default, minimap2 uses one I/O thread. When I/O is slow (e.g. piping to gzip, or reading from a slow pipe), the I/O thread may become the bottleneck. Apply this option to use one thread for input and another thread for output, at the cost of increased peak RAM. .TP .BI -K \ NUM Number of bases loaded into memory to process in a mini-batch [500M]. Similar to option .BR -I , K/M/G/k/m/g suffix is accepted. A large .I NUM helps load balancing in the multi-threading mode, at the cost of increased memory. .TP .BR --secondary = yes | no Whether to output secondary alignments [yes] .TP .BI --max-qlen \ NUM Filter out query sequences longer than .IR NUM . .TP .B --paf-no-hit In PAF, output unmapped queries; the strand and the reference name fields are set to `*'. Warning: some paftools.js commands may not work with such output for the moment. .TP .B --sam-hit-only In SAM, don't output unmapped reads. .TP .B --version Print version number to stdout .SS Preset options .TP 10 .BI -x \ STR Preset []. This option applies multiple options at the same time. It should be applied before other options because options applied later will overwrite the values set by .BR -x . Available .I STR are: .RS .TP 10 .B map-ont Align noisy long reads of ~10% error rate to a reference genome. This is the default mode. .TP .B lr:hq Align accurate long reads (error rate <1%) to a reference genome .RB ( -k19 .B -w19 -U50,500 .BR -g10k ). This was recommended by ONT developers for recent Nanopore reads produced with chemistry v14 that can reach ~99% in accuracy. It was shown to work better for accurate Nanopore reads than .BR map-hifi . .TP .B map-hifi Align PacBio high-fidelity (HiFi) reads to a reference genome .RB ( -xlr:hq .B -A1 -B4 -O6,26 -E2,1 .BR -s200 ). It differs from .B lr:hq only in scoring. It has not been tested whether .B lr:hq would work better for PacBio HiFi reads. .TP .B map-pb Align older PacBio continuous long (CLR) reads to a reference genome .RB ( -Hk19 ). Note that this data type is effectively deprecated by HiFi. Unless you work on very old data, you probably want to use .B map-hifi or .BR lr:hq . .TP .B map-iclr Align Illumina Complete Long Reads (ICLR) to a reference genome .RB ( -k19 .B -B6 -b4 .BR -O10,50 ). This was recommended by Illumina developers. .TP .B asm5 Long assembly to reference mapping .RB ( -k19 .B -w19 -U50,500 --rmq -r1k,100k -g10k -A1 -B19 -O39,81 -E3,1 -s200 -z200 .BR -N50 ). Typically, the alignment will not extend to regions with 5% or higher sequence divergence. Use this preset if the average divergence is not much higher than 0.1%. .TP .B asm10 Long assembly to reference mapping .RB ( -k19 .B -w19 -U50,500 --rmq -r1k,100k -g10k -A1 -B9 -O16,41 -E2,1 -s200 -z200 .BR -N50 ). Use this if the average divergence is around 1%. .TP .B asm20 Long assembly to reference mapping .RB ( -k19 .B -w10 -U50,500 --rmq -r1k,100k -g10k -A1 -B4 -O6,26 -E2,1 -s200 -z200 .BR -N50 ). Use this if the average divergence is around several percent. .TP .B splice Long-read spliced alignment .RB ( -k15 .B -w5 --splice -g2k -G200k -A1 -B2 -O2,32 -E1,0 -C9 -z200 -ub --junc-bonus=9 --cap-sw-mem=0 .BR --splice-flank=yes ). In the splice mode, 1) long deletions are taken as introns and represented as the .RB ` N ' CIGAR operator; 2) long insertions are disabled; 3) deletion and insertion gap costs are different during chaining; 4) the computation of the .RB ` ms ' tag ignores introns to demote hits to pseudogenes. .TP .B splice:hq Spliced alignment for accurate long RNA-seq reads such as PacBio iso-seq .RB ( -xsplice .B -C5 -O6,24 .BR -B4 ). .TP .B sr Short-read alignment without splicing .RB ( -k21 .B -w11 --sr --frag=yes -A2 -B8 -O12,32 -E2,1 -b0 -r100 -p.5 -N20 -f1000,5000 -n2 -m25 .B -s40 -g100 -2K50m --heap-sort=yes .BR --secondary=no ). .TP .B ava-pb PacBio CLR all-vs-all overlap mapping .RB ( -Hk19 .B -Xw5 -e0 .BR -m100 ). .TP .B ava-ont Oxford Nanopore all-vs-all overlap mapping .RB ( -k15 .B -Xw5 -e0 -m100 .BR -r2k ). .RE .SS Miscellaneous options .TP 10 .B --no-kalloc Use the libc default allocator instead of the kalloc thread-local allocator. This debugging option is mostly used with Valgrind to detect invalid memory accesses. Minimap2 runs slower with this option, especially in the multi-threading mode. .TP .B --print-qname Print query names to stderr, mostly to see which query is crashing minimap2. .TP .B --print-seeds Print seed positions to stderr, for debugging only. .SH OUTPUT FORMAT .PP Minimap2 outputs mapping positions in the Pairwise mApping Format (PAF) by default. PAF is a TAB-delimited text format with each line consisting of at least 12 fields as are described in the following table: .TS center box; cb | cb | cb r | c | l . Col Type Description _ 1 string Query sequence name 2 int Query sequence length 3 int Query start coordinate (0-based) 4 int Query end coordinate (0-based) 5 char `+' if query/target on the same strand; `-' if opposite 6 string Target sequence name 7 int Target sequence length 8 int Target start coordinate on the original strand 9 int Target end coordinate on the original strand 10 int Number of matching bases in the mapping 11 int Number bases, including gaps, in the mapping 12 int Mapping quality (0-255 with 255 for missing) .TE .PP When alignment is available, column 11 gives the total number of sequence matches, mismatches and gaps in the alignment; column 10 divided by column 11 gives the BLAST-like alignment identity. When alignment is unavailable, these two columns are approximate. PAF may optionally have additional fields in the SAM-like typed key-value format. Minimap2 may output the following tags: .TS center box; cb | cb | cb r | c | l . Tag Type Description _ tp A Type of aln: P/primary, S/secondary and I,i/inversion cm i Number of minimizers on the chain s1 i Chaining score s2 i Chaining score of the best secondary chain NM i Total number of mismatches and gaps in the alignment MD Z To generate the ref sequence in the alignment AS i DP alignment score SA Z List of other supplementary alignments ms i DP score of the max scoring segment in the alignment nn i Number of ambiguous bases in the alignment ts A Transcript strand (splice mode only) cg Z CIGAR string (only in PAF) cs Z Difference string dv f Approximate per-base sequence divergence de f Gap-compressed per-base sequence divergence rl i Length of query regions harboring repetitive seeds .TE .PP The .B cs tag encodes difference sequences in the short form or the entire query .I AND reference sequences in the long form. It consists of a series of operations: .TS center box; cb | cb |cb r | l | l . Op Regex Description _ = [ACGTN]+ Identical sequence (long form) : [0-9]+ Identical sequence length * [acgtn][acgtn] Substitution: ref to query + [acgtn]+ Insertion to the reference - [acgtn]+ Deletion from the reference ~ [acgtn]{2}[0-9]+[acgtn]{2} Intron length and splice signal .TE .SH LIMITATIONS .TP 2 * Minimap2 may produce suboptimal alignments through long low-complexity regions where seed positions may be suboptimal. This should not be a big concern because even the optimal alignment may be wrong in such regions. .TP * Minimap2 requires SSE2 or NEON instructions to compile. It is possible to add non-SSE2/NEON support, but it would make minimap2 slower by several times. .SH SEE ALSO .PP miniasm(1), minimap(1), bwa(1).