Python Bindings for the Parasail C Library
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PyPI Package:
Author: Jeff Daily (jeffrey.daily@gmail.com)
- Installation
- Quick Example
- Standard Function Naming Convention
- Profile Function Naming Convention
- Substitution Matrices
- SSW Library Emulation
- Banded Global Alignment
- File Input
- Tracebacks
- Citing parasail
- License: Battelle BSD-style
This package contains Python bindings for parasail. Parasail is a SIMD C (C99) library containing implementations of the Smith-Waterman (local), Needleman-Wunsch (global), and semi-global pairwise sequence alignment algorithms.
The recommended way of installing is to use the latest version available via pip.
pip install parasail
Binaries for Windows and OSX should be available via pip. Using pip on a Linux platform will first download the latest version of the parasail C library sources and then compile them automatically into a shared library. For an installation from sources, or to learn how the pip installation works on Linux, please read on.
To run the testsuite use the unittest runner.
python -m unittest discover tests
The parasail python bindings are based on ctypes. Unfortunately, best practices are not firmly established for providing cross-platform and user-friendly python bindings based on ctypes. The approach with parasail-python is to install the parasail shared library as "package data" and use a relative path from the parasail/__init__.py in order to locate the shared library.
There are two approaches currently supported. First, you can compile your own parasail shared library using one of the recommended build processes described in the parasail C library README.md, then copy the parasail.dll (Windows), libparasail.so (Linux), or libparasail.dylib (OSX) shared library to parasail-python/parasail -- the same folder location as parasasail-python/parasail/__init__.py.
The second approach is to let the setup.py script attempt to download and compile the parasail C library for you using the configure script that comes with it. This happens as a side effect of the bdist_wheel target.
python setup.py bdist_wheel
The bdist_wheel target will first look for the shared library. If it exists, it will happily install it as package data. Otherwise, the latest parasail master branch from github will be downloaded, unzipped, configured, made, and the shared library will be copied into the appropriate location for package data installation.
The downloading and building of the parasail C library can be skipped if you set the environment variable PARASAIL_SKIP_BUILD to any value prior to running setup.py or pip install. At runtime during import, the parasail bindings will search for the parasail C library first in the package data location, then in standard system locations, and lastly by searching through the environment variables PARASAIL_LIBPATH, LD_LIBRARY_PATH, DYLD_LIBRARY_PATH, and PATH.. For verbose output during this search, set PARASAIL_VERBOSE=1.
The Python interface only includes bindings for the dispatching functions, not the low-level instruction set-specific function calls. The Python interface also includes wrappers for the various PAM and BLOSUM matrices included in the distribution.
Gap open and extension penalties are specified as positive integers. When any of the algorithms open a gap, only the gap open penalty alone is applied.
import parasail
result = parasail.sw_scan_16("asdf", "asdf", 11, 1, parasail.blosum62)
result = parasail.sw_stats_striped_8("asdf", "asdf", 11, 1, parasail.pam100)
Be careful using the attributes of the Result object - especially on Result instances constructed on the fly. For example, calling parasail.sw_trace("asdf", "asdf", 11, 1, parasail.blosum62).cigar.seq returns a numpy.ndarray that wraps a pointer to memory that is invalid because the Cigar is deallocated before the seq statement. You can avoid this problem by assigning Result instances to variables as in the example above.
There are many functions within the parasail library, but most are variations of the familiar main algorithms. The following table describes the main algorithms and the shorthand name used for the function.
Algorithm | Function Name |
---|---|
Smith-Waterman local alignment | sw |
Needleman-Wunsch global alignment | nw |
Semi-Global, do not penalize gaps at beginning of s1/query | sg_qb |
Semi-Global, do not penalize gaps at end of s1/query | sg_qe |
Semi-Global, do not penalize gaps at beginning and end of s1/query | sg_qx |
Semi-Global, do not penalize gaps at beginning of s2/database | sg_db |
Semi-Global, do not penalize gaps at end of s2/database | sg_de |
Semi-Global, do not penalize gaps at beginning and end of s2/database | sg_dx |
Semi-Global, do not penalize gaps at beginning of s1/query and end of s2/database | sg_qb_de |
Semi-Global, do not penalize gaps at beginning of s2/database and end of s1/query | sg_qe_db |
Semi-Global, do not penalize gaps at beginning of s1/query and beginning of s2/database | sg_qb_db |
Semi-Global, do not penalize gaps at end of s2/database and end of s1/query | sg_qe_de |
Semi-Global, do not penalize gaps at beginning and end of both sequences | sg |
A good summary of the various alignment algorithms can be found courtesy of Dr. Dannie Durand's course on computational genomics here. The same document was copied locally to the C library repo in case this link ever breaks (link).
To make it easier to find the function you're looking for, the function names follow a naming convention. The following will use set notation {} to indicate a selection must be made and brackets [] to indicate an optional part of the name.
- Non-vectorized, reference implementations.
- Required, select algorithm from table above.
- Optional return alignment statistics.
- Optional return DP table or last row/col.
- Optional use a prefix scan implementation.
parasail. {nw,sg,sg_qb,sg_qe,sg_qx,sg_db,sg_de,sg_dx,sg_qb_de,sg_qe_db,sg_qb_db,sg_qe_de,sw} [_stats] [{_table,_rowcol}] [_scan]
- Non-vectorized, traceback-capable reference implementations.
- Required, select algorithm from table above.
- Optional use a prefix scan implementation.
parasail. {nw,sg,sg_qb,sg_qe,sg_qx,sg_db,sg_de,sg_dx,sg_qb_de,sg_qe_db,sg_qb_db,sg_qe_de,sw} _trace [_scan]
- Vectorized.
- Required, select algorithm from table above.
- Optional return alignment statistics.
- Optional return DP table or last row/col.
- Required, select vectorization strategy -- striped is a good place to start, but scan is often faster for global alignment.
- Required, select solution width. 'sat' will attempt 8-bit solution but if overflow is detected it will then perform the 16-bit operation. Can be faster in some cases, though 16-bit is often sufficient.
parasail. {nw,sg,sg_qb,sg_qe,sg_qx,sg_db,sg_de,sg_dx,sg_qb_de,sg_qe_db,sg_qb_db,sg_qe_de,sw} [_stats] [{_table,_rowcol}] {_striped,_scan,_diag} {_8,_16,_32,_64,_sat}
- Vectorized, traceback-capable.
- Required, select algorithm from table above.
- Required, select vectorization strategy -- striped is a good place to start, but scan is often faster for global alignment.
- Required, select solution width. 'sat' will attempt 8-bit solution but if overflow is detected it will then perform the 16-bit operation. Can be faster in some cases, though 16-bit is often sufficient.
parasail. {nw,sg,sg_qb,sg_qe,sg_qx,sg_db,sg_de,sg_dx,sg_qb_de,sg_qe_db,sg_qb_db,sg_qe_de,sw} _trace {_striped,_scan,_diag} {_8,_16,_32,_64,_sat}
It has been noted in literature that some performance can be gained by reusing the query sequence when using striped [Farrar, 2007] or scan [Daily, 2015] vector strategies. There is a special subset of functions that enables this behavior. For the striped and scan vector implementations only, a query profile can be created and reused for subsequent alignments. This can noticeably speed up applications such as database search.
- Profile creation
- Optional, prepare query profile for a function that returns statistics. Stats require additional data structures to be allocated.
- Required, select solution width. 'sat' will allocate profiles for both 8- and 16-bit solutions.
parasail.profile_create [_stats] {_8,_16,_32,_64,_sat}
- Profile use
- Vectorized.
- Required, select algorithm from table above.
- Optional return alignment statistics.
- Optional return DP table or last row/col.
- Required, select vectorization strategy -- striped is a good place to start, but scan is often faster for global alignment.
- Required, select solution width. 'sat' will attempt 8-bit solution but if overflow is detected it will then perform the 16-bit operation. Can be faster in some cases, though 16-bit is often sufficient.
parasail. {nw,sg,sg_qb,sg_qe,sg_qx,sg_db,sg_de,sg_dx,sg_qb_de,sg_qe_db,sg_qb_db,sg_qe_de,sw} [_stats] [{_table,_rowcol}] {_striped,_scan} _profile {_8,_16,_32,_64,_sat}
- Vectorized, traceback-capable.
- Required, select algorithm from table above.
- Required, select vectorization strategy -- striped is a good place to start, but scan is often faster for global alignment.
- Required, select solution width. 'sat' will attempt 8-bit solution but if overflow is detected it will then perform the 16-bit operation. Can be faster in some cases, though 16-bit is often sufficient.
parasail. {nw,sg,sg_qb,sg_qe,sg_qx,sg_db,sg_de,sg_dx,sg_qb_de,sg_qe_db,sg_qb_db,sg_qe_de,sw} _trace {_striped,_scan} _profile {_8,_16,_32,_64,_sat}
- Vectorized.
Please note that the bit size you select for creating the profile must match the bit size of the function you call. The example below uses a 16-bit profile and a 16-bit function.
profile = parasail.profile_create_16("asdf", parasail.blosum62)
result1 = parasail.sw_trace_striped_profile_16(profile, "asdf", 10, 1)
result2 = parasail.nw_scan_profile_16(profile, "asdf", 10, 1)
parasail bundles a number of substitution matrices including PAM and BLOSUM. To use them, look them up by name (useful for command-line parsing) or use directly. For example
print(parasail.blosum62)
matrix = parasail.Matrix("pam100")
You can also create your own matrices with simple match/mismatch values. For more complex matrices, you can start by copying a built-in matrix or start simple and modify values as needed. For example
# copy a built-in matrix, then modify like a numpy array
matrix = parasail.blosum62.copy()
matrix[2,4] = 200
matrix[3,:] = 100
user_matrix = parasail.matrix_create("ACGT", 2, -1)
You can also parse simple matrix files using the function if the file is in the following format:
# # Any line starting with '#' is a comment. # # Needs a row for the alphabet. First column is a repeat of the # alphabet and assumed to be identical in order to the first alphabet row. # # Last row and column *must* be a non-alphabet character to represent # any input sequence character that is outside of the alphabet. # A T G C S W R Y K M B V H D N U * A 5 -4 -4 -4 -4 1 1 -4 -4 1 -4 -1 -1 -1 -2 -4 -5 T -4 5 -4 -4 -4 1 -4 1 1 -4 -1 -4 -1 -1 -2 5 -5 G -4 -4 5 -4 1 -4 1 -4 1 -4 -1 -1 -4 -1 -2 -4 -5 C -4 -4 -4 5 1 -4 -4 1 -4 1 -1 -1 -1 -4 -2 -4 -5 S -4 -4 1 1 -1 -4 -2 -2 -2 -2 -1 -1 -3 -3 -1 -4 -5 W 1 1 -4 -4 -4 -1 -2 -2 -2 -2 -3 -3 -1 -1 -1 1 -5 R 1 -4 1 -4 -2 -2 -1 -4 -2 -2 -3 -1 -3 -1 -1 -4 -5 Y -4 1 -4 1 -2 -2 -4 -1 -2 -2 -1 -3 -1 -3 -1 1 -5 K -4 1 1 -4 -2 -2 -2 -2 -1 -4 -1 -3 -3 -1 -1 1 -5 M 1 -4 -4 1 -2 -2 -2 -2 -4 -1 -3 -1 -1 -3 -1 -4 -5 B -4 -1 -1 -1 -1 -3 -3 -1 -1 -3 -1 -2 -2 -2 -1 -1 -5 V -1 -4 -1 -1 -1 -3 -1 -3 -3 -1 -2 -1 -2 -2 -1 -4 -5 H -1 -1 -4 -1 -3 -1 -3 -1 -3 -1 -2 -2 -1 -2 -1 -1 -5 D -1 -1 -1 -4 -3 -1 -1 -3 -1 -3 -2 -2 -2 -1 -1 -1 -5 N -2 -2 -2 -2 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -2 -5 U -4 5 -4 -4 -4 1 -4 1 1 -4 -1 -4 -1 -1 -2 5 -5 * -5 -5 -5 -5 -5 -5 -5 -5 -5 -5 -5 -5 -5 -5 -5 -5 -5
matrix_from_filename = parasail.Matrix("filename.txt")
The SSW library (https://github.com/mengyao/Complete-Striped-Smith-Waterman-Library) performs Smith-Waterman local alignment using SSE2 instructions and a striped vector. Its result provides the primary score, a secondary score, beginning and ending locations of the alignment for both the query and reference sequences, as well as a SAM CIGAR. There are a few parasail functions that emulate this behavior, with the only exception being that parasail does not calculate a secondary score.
score_size = 1 # 0, use 8-bit align; 1, use 16-bit; 2, try both
profile = parasail.ssw_init("asdf", parasail.blosum62, score_size)
result = parasail.ssw_profile(profile, "asdf", 10, 1)
print(result.score1)
print(result.cigar)
print(result.ref_begin1)
print(result.ref_end1)
print(result.read_begin1)
print(result.read_end1)
# or skip profile creation
result = parasail.ssw("asdf", "asdf", 10, 1, parasail.blosum62)
There is one version of banded global alignment available. Though it is not vectorized, it might still be faster than using other parasail global alignment functions, especially for large sequences. The function signature is similar to the other parasail functions with the only exception being k
, the band width.
band_size = 3
result = parasail.nw_banded("asdf", "asdf", 10, 1, band_size, matrix):
Parasail can parse FASTA, FASTQ, and gzipped versions of such files if
zlib was found during the C library build. The
function parasail.sequences_from_file
will return a list-like object
containing Sequence instances. A parasail Sequence behaves like an
immutable string but also has extra attributes name
, comment
,
and qual
. These attributes will return an empty string if the input
file did not contain these fields.
Parasail supports accessing a SAM CIGAR string from a result. You must use a traceback-capable alignment function. Refer to the C interface description above for details on how to use a traceback-capable alignment function.
result = parasail.sw_trace("asdf", "asdf", 10, 1, parasail.blosum62)
cigar = result.cigar
# cigars have seq, len, beg_query, and beg_ref properties
# the seq property is encoded
print(cigar.seq)
# use decode attribute to return a decoded cigar string
print(cigar.decode)
If needed, please cite the following paper.
Daily, Jeff. (2016). Parasail: SIMD C library for global, semi-global, and local pairwise sequence alignments. BMC Bioinformatics, 17(1), 1-11. doi:10.1186/s12859-016-0930-z
http://dx.doi.org/10.1186/s12859-016-0930-z
Copyright (c) 2015, Battelle Memorial Institute
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- Redistributions of the software in any form, and publications based on work performed using the software should include the following citation as a reference:
Daily, Jeff. (2016). Parasail: SIMD C library for global, semi-global, and local pairwise sequence alignments. BMC Bioinformatics, 17(1), 1-11. doi:10.1186/s12859-016-0930-z
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