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MUGQIC Pipelines

This repository holds several bioinformatics pipelines developed at McGill University and Génome Québec Innovation Centre (MUGQIC), as part of the GenAP project.

MUGQIC pipelines consist of Python scripts which create a list of jobs running Bash commands. Those scripts support dependencies between jobs and smart restart mechanism if some jobs fail during pipeline execution. Jobs can be submitted in different ways: by being sent to a PBS scheduler like Torque or by being run as a series of commands in batch through a Bash script. Job commands and parameters can be modified through several configuration files.

On this page:

[TOC]

Software requirement

MUGQIC pipelines have been tested with Python 2.7.

Quick setup for abacus, guillimin and mammouth users

Genomes and modules used by the pipelines are already installed on a CVMFS partition mounted on all those clusters in /cvmfs/soft.mugqic/CentOS6. To access them, add the following lines to your $HOME/.bash_profile:

#!bash
umask 0002

## MUGQIC genomes and modules 

export MUGQIC_INSTALL_HOME=/cvmfs/soft.mugqic/CentOS6

module use $MUGQIC_INSTALL_HOME/modulefiles

For MUGQIC analysts, add the following lines to your $HOME/.bash_profile:

#!bash
umask 0002
     
## MUGQIC genomes and modules for MUGQIC analysts
    
HOST=`hostname`;
    
DNSDOMAIN=`dnsdomainname`;

export MUGQIC_INSTALL_HOME=/cvmfs/soft.mugqic/CentOS6
    
if [[ $HOST == abacus* || $DNSDOMAIN == ferrier.genome.mcgill.ca ]]; then

  export MUGQIC_INSTALL_HOME_DEV=/lb/project/mugqic/analyste_dev

elif [[ $HOST == lg-* || $DNSDOMAIN == guillimin.clumeq.ca ]]; then

  export MUGQIC_INSTALL_HOME_DEV=/gs/project/mugqic/analyste_dev/phase2

elif [[ $BQMAMMOUTH == "mp2" ]]; then

  export MUGQIC_INSTALL_HOME_DEV=$(share_nobackup bourque)/mugqic_dev

fi
    
module use $MUGQIC_INSTALL_HOME/modulefiles $MUGQIC_INSTALL_HOME_DEV/modulefiles

Also, set JOB_MAIL in your $HOME/.bash_profile to receive PBS job logs:

#!bash
export JOB_MAIL=<my.name@my.email.ca>

MUGQIC pipelines and compatible Python version are already installed as modules on those clusters. To use them by default, add in your $HOME/.bash_profile:

#!bash
module load mugqic/python/2.7.8
module load mugqic/mugqic_pipelines/<latest_version>

(find out the latest version with: "module avail 2>&1 | grep mugqic/mugqic_pipelines").

For guillimin and mammouth users

Set your RAP_ID (Resource Allocation Project ID from Compute Canada) in your $HOME/.bash_profile:

#!bash
export RAP_ID=<my-rap-id>

Download and setup for external users

Download

Visit our Download page to get the latest stable release.

If you want to use the most recent development version:

#!bash
git clone git@bitbucket.org:mugqic/mugqic_pipelines.git

Setup

Set MUGQIC_PIPELINES_HOME to your local copy path, in your $HOME/.bash_profile:

#!bash
export MUGQIC_PIPELINES_HOME=/path/to/your/local/mugqic_pipelines

MUGQIC Pipelines require genomes and modules resources to run properly. First, set MUGQIC_INSTALL_HOME to the directory where you want to install those resources, in your $HOME/.bash_profile:

#!bash
## MUGQIC genomes and modules
    
export MUGQIC_INSTALL_HOME=/path/to/your/local/mugqic_resources
    
module use $MUGQIC_INSTALL_HOME/modulefiles

Genomes

Reference genomes and annotations must be installed in $MUGQIC_INSTALL_HOME/genomes/. Default genome installation scripts are already available in $MUGQIC_PIPELINES_HOME/resources/genomes/. To install all of them at once, use the script $MUGQIC_PIPELINES_HOME/resources/genomes/install_all_genomes.sh.

All species-related files are in: $MUGQIC_INSTALL_HOME/genomes/species/<species_scientific_name>.<assembly>/ e.g. for Homo sapiens assembly GRCh37, the directory has the following (incomplete) hierarchy:

#!text
$MUGQIC_INSTALL_HOME/genomes/species/Homo_sapiens.GRCh37/
├── annotations/
│   ├── gtf_tophat_index/
│   ├── Homo_sapiens.GRCh37.dbSNP142.vcf.gz
│   ├── Homo_sapiens.GRCh37.dbSNP142.vcf.gz.tbi
│   ├── Homo_sapiens.GRCh37.Ensembl75.geneid2Symbol.tsv
│   ├── Homo_sapiens.GRCh37.Ensembl75.genes.length.tsv
│   ├── Homo_sapiens.GRCh37.Ensembl75.genes.tsv
│   ├── Homo_sapiens.GRCh37.Ensembl75.GO.tsv
│   ├── Homo_sapiens.GRCh37.Ensembl75.gtf
│   ├── Homo_sapiens.GRCh37.Ensembl75.ncrna.fa
│   ├── Homo_sapiens.GRCh37.Ensembl75.rrna.fa
│   ├── Homo_sapiens.GRCh37.Ensembl75.transcript_id.gtf
│   ├── Homo_sapiens.GRCh37.Ensembl75.vcf.gz
│   ├── ncrna_bwa_index/
│   └── rrna_bwa_index/
├── downloads/
│   ├── ftp.1000genomes.ebi.ac.uk/
│   ├── ftp.ensembl.org/
│   └── ftp.ncbi.nih.gov/
├── genome/
│   ├── bowtie2_index/
│   ├── bwa_index/
│   ├── Homo_sapiens.GRCh37.dict
│   ├── Homo_sapiens.GRCh37.fa
│   ├── Homo_sapiens.GRCh37.fa.fai
│   └── star_index/
├── Homo_sapiens.GRCh37.ini
└── log/

The assembly name is the one used by the download source e.g. "GRCh37" for Ensembl. Each species directory contains a <scientific_name>.<assembly>.ini file which lists among other things, the assembly synonyms e.g. "hg19":

Homo_sapiens.GRCh37.ini

#!ini
[DEFAULT]
scientific_name=Homo_sapiens
common_name=Human
assembly=GRCh37
assembly_synonyms=hg19
source=Ensembl
version=75
dbsnp_version=142
Install a new Genome

New genomes and annotations can be installed semi-automatically from Ensembl (vertebrate species), EnsemblGenomes (other species) or UCSC (genome and indexes only; no annotations).

Example for Chimpanzee:

  • Retrieve the species scientific name on Ensembl or UCSC: "Pan troglodytes"

  • Retrieve the assembly name:

    • Ensembl: "CHIMP2.1.4"
    • UCSC: "panTro4"
  • Retrieve the source version:

    • Ensembl: "78"
    • UCSC: unfortunately, UCSC does not have version numbers. Use panTro4.2bit date formatted as "YYYY-MM-DD": "2012-01-09"
  • cp $MUGQIC_PIPELINES_HOME/resources/genomes/GENOME_INSTALL_TEMPLATE.sh $MUGQIC_PIPELINES_HOME/resources/genomes/<scientific_name>.<assembly>.sh e.g.:

    • Ensembl:

        cp $MUGQIC_PIPELINES_HOME/resources/genomes/GENOME_INSTALL_TEMPLATE.sh $MUGQIC_PIPELINES_HOME/resources/genomes/Pan_troglodytes.CHIMP2.1.4.sh
      
    • UCSC:

        cp $MUGQIC_PIPELINES_HOME/resources/genomes/GENOME_INSTALL_TEMPLATE.sh $MUGQIC_PIPELINES_HOME/resources/genomes/Pan_troglodytes.panTro4.sh
      
  • Modify $MUGQIC_PIPELINES_HOME/resources/genomes/<scientific_name>.<assembly>.sh (ASSEMBLY_SYNONYMS can be left empty but if you know that 2 assemblies are identical apart from chr sequence prefixes, document it):

    • Ensembl:

        SPECIES=Pan_troglodytes   # With "_"; no space!
        COMMON_NAME=Chimpanzee
        ASSEMBLY=CHIMP2.1.4
        ASSEMBLY_SYNONYMS=panTro4
        SOURCE=Ensembl
        VERSION=78
      
    • UCSC:

        SPECIES=Pan_troglodytes   # With "_"; no space!
        COMMON_NAME=Chimpanzee
        ASSEMBLY=panTro4
        ASSEMBLY_SYNONYMS=CHIMP2.1.4
        SOURCE=UCSC
        VERSION=2012-01-09
      
  • If necessary, update $MUGQIC_PIPELINES_HOME/resources/genomes/install_genome.sh with INSTALL_HOME=$MUGQIC_INSTALL_HOME (otherwise $MUGQIC_INSTALL_HOME_DEV will be used by default).

  • Run $MUGQIC_PIPELINES_HOME/resources/genomes/<scientific_name>.<assembly>.sh. It will download and install genomes, indexes and, for Ensembl only, annotations (GTF, VCF, etc.).

    If the genome is big, separate batch jobs will be submitted to the cluster for bwa, bowtie/tophat, star indexing. Check that jobs are completed OK.

  • If the new genome has been installed in $MUGQIC_INSTALL_HOME_DEV, to deploy in $MUGQIC_INSTALL_HOME:

      rsync -va $MUGQIC_INSTALL_HOME_DEV/genomes/species/<scientific_name>.<assembly>/ $MUGQIC_INSTALL_HOME/genomes/species/<scientific_name>.<assembly>/
    
  • Add the newly created INI file to the genome config files for further usage in pipeline command:

      cp $MUGQIC_INSTALL_HOME/genomes/species/<scientific_name>.<assembly>/<scientific_name>.<assembly>.ini $MUGQIC_PIPELINES_HOME/resources/genomes/config/
    

Modules

Software tools and associated modules must be installed in $MUGQIC_INSTALL_HOME/software/ and $MUGQIC_INSTALL_HOME/modulefiles/. Default software/module installation scripts are already available in $MUGQIC_PIPELINES_HOME/resources/modules/.

Install a new Module

New software tools and associated modules can be installed semi-automatically:

  • cp $MUGQIC_PIPELINES_HOME/resources/modules/MODULE_INSTALL_TEMPLATE.sh $MUGQIC_PIPELINES_HOME/resources/modules/<my_software>.sh

  • Modify $MUGQIC_PIPELINES_HOME/resources/modules/<my_software>.sh following the instructions inside.

  • Run $MUGQIC_PIPELINES_HOME/resources/modules/<my_software>.sh with no arguments. By default, it will download and extract the remote software archive, build the software and create the associated module, all in $MUGQIC_INSTALL_HOME_DEV if it is set.

  • If everything is OK, to install it in production, run:

      $MUGQIC_PIPELINES_HOME/resources/modules/<my_software>.sh MUGQIC_INSTALL_HOME
    

    (no $ before MUGQIC_INSTALL_HOME!).

  • Check if the module is available with: module avail 2>&1 | grep mugqic/<my_software>/<version>

Usage

For each pipeline, get help about usage, arguments and steps with:

  • if you use a mugqic/mugqic_pipelines/<version> module on our clusters, simply:
#!bash
<pipeline_name>.py --help
  • if you use your own local install:
#!bash
$MUGQIC_PIPELINES_HOME/pipelines/<pipeline_name>/<pipeline_name>.py --help

Pipelines require as input one Readset File, one or more Configuration File(s) and possibly one Design File, all described below.

For more information about a specific pipeline, visit:

Readset File

The Readset File is a TAB-separated values plain text file with one line per readset and the following columns in any order:

DNA-Seq, RNA-Seq, RNA-Seq De Novo Assembly, ChIP-Seq

  • Sample: must contain letters A-Z, numbers 0-9, hyphens (-) or underscores (_) only; BAM files will be merged into a file named after this value; mandatory;
  • Readset: a unique readset name with the same allowed characters as above; mandatory;
  • Library: optional;
  • RunType: PAIRED_END or SINGLE_END; mandatory;
  • Run: optional;
  • Lane: optional;
  • QualityOffset: quality score offset integer used for trimming; optional;
  • BED: relative or absolute path to BED file; optional;
  • FASTQ1: relative or absolute path to first FASTQ file for paired-end readset or single FASTQ file for single-end readset; mandatory if BAM value is missing;
  • FASTQ2: relative or absolute path to second FASTQ file for paired-end readset; mandatory if RunType value is "PAIRED_END";
  • BAM: relative or absolute path to BAM file which will be converted into FASTQ files if they are not available; mandatory if FASTQ1 value is missing, ignored otherwise.

Example:

Sample	Readset	Library	RunType	Run	Lane	QualityOffset	BED	FASTQ1	FASTQ2	BAM
sampleA	readset1	lib0001	PAIRED_END	run100	1	33	path/to/file.bed	path/to/readset1.paired1.fastq.gz	path/to/readset1.paired2.fastq.gz	path/to/readset1.bam
sampleA	readset2	lib0001	PAIRED_END	run100	2	33	path/to/file.bed	path/to/readset2.paired1.fastq.gz	path/to/readset2.paired2.fastq.gz	path/to/readset2.bam
sampleB	readset3	lib0002	PAIRED_END	run200	5	33	path/to/file.bed	path/to/readset3.paired1.fastq.gz	path/to/readset3.paired2.fastq.gz	path/to/readset3.bam
sampleB	readset4	lib0002	PAIRED_END	run200	6	33	path/to/file.bed	path/to/readset4.paired1.fastq.gz	path/to/readset4.paired2.fastq.gz	path/to/readset4.bam

PacBio Assembly

  • Sample: must contain letters A-Z, numbers 0-9, hyphens (-) or underscores (_) only; mandatory;
  • Readset: a unique readset name with the same allowed characters as above; mandatory;
  • Smartcell: mandatory;
  • NbBasePairs: total number of base pairs for this readset; mandatory;
  • EstimatedGenomeSize: estimated genome size in number of base pairs used to compute seeding read length cutoff; mandatory;
  • BAS: comma-separated list of relative or absolute paths to BAS files (old PacBio format); mandatory if BAX value is missing, ignored otherwise;
  • BAX: comma-separated list of relative or absolute paths to BAX files; BAX file list is used first if both BAX/BAS lists are present; mandatory if BAS value is missing.

Example:

Sample	Readset	Smartcell	NbBasePairs	EstimatedGenomeSize	BAS	BAX
sampleA	readset1	F_01_1	122169744	150000	path/to/readset1.bas.h5	path/to/readset1.1.bax.h5,path/to/readset1.2.bax.h5,path/to/readset1.3.bax.h5
sampleA	readset2	F_01_2	105503472	150000	path/to/readset2.bas.h5	path/to/readset2.1.bax.h5,path/to/readset2.2.bax.h5,path/to/readset2.3.bax.h5
sampleB	readset3	G_01_1	118603200	150000	path/to/readset3.bas.h5	path/to/readset3.1.bax.h5,path/to/readset3.2.bax.h5,path/to/readset3.3.bax.h5
sampleB	readset4	G_01_2	104239488	150000	path/to/readset4.bas.h5	path/to/readset4.1.bax.h5,path/to/readset4.2.bax.h5,path/to/readset4.3.bax.h5

For abacus users with Nanuq readsets

If your readsets belong to a Nanuq project, use $MUGQIC_PIPELINES_HOME/utils/nanuq2mugqic_pipelines.py script to automatically create a Readset File and symlinks to your readsets on abacus.

Configuration Files

Pipeline command parameters and cluster settings can be customized using Configuration Files (.ini extension). Those files have a structure similar to Microsoft Windows INI files e.g.:

#!ini
[DEFAULT]
module_trimmomatic=mugqic/trimmomatic/0.32

[trimmomatic]
min_length=50

A parameter value is first searched in its specific section, then, if not found, in the special DEFAULT section. The example above would resolve parameter module_trimmomatic value from section trimmomatic to mugqic/trimmomatic/0.32.

Configuration files support interpolation. For example:

#!ini
scientific_name=Homo_sapiens
assembly=GRCh37
assembly_dir=$MUGQIC_INSTALL_HOME/genomes/species/%(scientific_name)s.%(assembly)s
genome_fasta=%(assembly_dir)s/genome/%(scientific_name)s.%(assembly)s.fa

would resolve genome_fasta value to $MUGQIC_INSTALL_HOME/genomes/species/Homo_sapiens.GRCh37/genome/Homo_sapiens.GRCh37.fa.

Each pipeline has several configuration files in:

#!bash
$MUGQIC_PIPELINES_HOME/pipelines/<pipeline_name>/<pipeline_name>.*.ini

A default configuration file (.base.ini extension) is set for running on abacus cluster using Homo sapiens reference genome and must always be passed first to the --config option.

You can also add a list of other configuration files to --config. Files are read in the list order and each parameter value is overwritten if redefined in the next file.

This is useful to customize settings for a specific cluster or genome. Each pipeline has a special configuration file for guillimin and mammouth clusters (.guillimin.ini and .mammouth.ini extensions respectively) in the same directory. And various genome settings are available in $MUGQIC_PIPELINES_HOME/resources/genomes/config/.

For example, to run the DNA-Seq pipeline on guillimin cluster with Mus musculus reference genome:

#!bash
$MUGQIC_PIPELINES_HOME/pipelines/dnaseq/dnaseq.py --config $MUGQIC_PIPELINES_HOME/pipelines/dnaseq/dnaseq.base.ini $MUGQIC_PIPELINES_HOME/pipelines/dnaseq/dnaseq.guillimin.ini $MUGQIC_PIPELINES_HOME/resources/genomes/config/Mus_musculus.GRCm38.ini ...

Design File

RNA-Seq, RNA-Seq De Novo Assembly and ChIP-Seq pipelines can perform differential expression analysis if they are provided with an input Design File.

The Design File is a TAB-separated values plain text file with one line per sample and the following columns:

  • Sample: first column; must contain letters A-Z, numbers 0-9, hyphens (-) or underscores (_) only; the sample name must match a sample name in the readset file; mandatory;
  • : each of the following columns defines an experimental design contrast; the column name defines the contrast name, and the following values represent the sample group membership for this contrast:
    • '0' or '': the sample does not belong to any group;
    • '1': the sample belongs to the control group;
    • '2': the sample belongs to the treatment test case group.

Example:

Sample	Contrast1	Contrast2	Contrast3
sampleA	1	1	1
sampleB	2	0	1
sampleC	0	2	0
sampleD	0	0	2

For ChIP-Seq pipeline users

Peak calling type must be specified by adding to the contrast name either ,N for Narrow peak calling, or ,B for Broad peak calling.

Example:

Sample	Contrast1,N	Contrast2,B
sampleA	1	1
sampleB	2	0
sampleC	0	2

Warning for ChIP-Seq pipeline users: the values '1' for control and '2' for treatment are reversed compared to the old Perl version.

HTML Analysis Report

While pipelines are run, some jobs create a partial analysis report in Markdown format in <output_dir>/report/<pipeline_name>.<step_name>.md e.g. <output_dir>/report/DnaSeq.bwa_mem_picard_sort_sam.md.

At any time during the pipeline processing, you can run the same pipeline command and add the option --report. This will create a bash script calling the Pandoc converter to aggregate all partial Markdown reports already created into one single HTML document, which you can view in <output_dir>/report/index.html.

Thus, if the last pipeline steps fail, you will still get an HTML report containing sections for the first steps only.

The report title value can be overwritten in your copy of $MUGQIC_PIPELINES_HOME/pipelines/<pipeline_name>/<pipeline_name>.base.ini in section [report]. You can also edit the partial Markdown reports before running the pandoc script, to add custom comments in your HTML report.

For developers: if you want to modify the Markdown report templates, they are all located in $MUGQIC_PIPELINES_HOME/bfx/report/.

PBS Job Logs

When pipelines are run in PBS (Portable Batch System) job scheduler mode (default), a job list file is created in <output_dir>/job_output/<PipelineName>_job_list_<timestamp> and subsequent job log files are placed in <output_dir>/job_output/<step_name>/<job_name>_<timestamp>.o e.g.:

#!text
my_output_dir/job_output/
├── RnaSeqDeNovoAssembly_job_list_2014-09-30T19.52.29
├── trimmomatic
│   ├── trimmomatic.readset1_2014-09-30T19.52.29.o
│   └── trimmomatic.readset2_2014-09-30T19.52.29.o
├── trinity
│   └── trinity_2014-10-01T14.17.02.o
└── trinotate
    └── trinotate_2014-10-22T14.05.58.o

To view a TAB-separated values log report, use $MUGQIC_PIPELINES_HOME/utils/log_report.pl script by typing:

#!bash
$MUGQIC_PIPELINES_HOME/utils/log_report.pl <output_dir>/job_output/<PipelineName>_job_list_<timestamp>

which will output e.g.:

#!text
# Number of jobs: 41
#
# Number of successful jobs: 4
# Number of active jobs: 0
# Number of inactive jobs: 36
# Number of failed jobs: 1
#
# Execution time: 2014-09-30T19:52:58 - 2014-09-30T22:38:04 (2 h 45 min 6 s)
#
# Shortest job: merge_trimmomatic_stats (1 s)
# Longest job: insilico_read_normalization_readsets.readset2 (1 h 33 min 53 s)
#
# Lowest memory job: merge_trimmomatic_stats (0.00 GiB)
# Highest memory job: insilico_read_normalization_readsets.readset2 (31.32 GiB)
#
#JOB_ID JOB_FULL_ID    JOB_NAME    JOB_DEPENDENCIES    STATUS    JOB_EXIT_CODE    CMD_EXIT_CODE    REAL_TIME    START_DATE    END_DATE    CPU_TIME    CPU_REAL_TIME_RATIO    PHYSICAL_MEM    VIRTUAL_MEM    EXTRA_VIRTUAL_MEM_PCT    LIMITS    QUEUE    USERNAME    GROUP    SESSION    ACCOUNT    NODES    PATH
2100213.abacus2.ferrier.genome.mcgill.ca    2100213.abacus2.ferrier.genome.mcgill.ca    trimmomatic.readset1    SUCCESS    N/A    0    01:08:45 (1 h 8 min 45 s)    2014-09-30T19:52:58    2014-09-30T21:01:48    02:39:34 (2 h 39 min 34 s)    2.32    1.71 GiB    3.73 GiB    118.2 %    neednodes=1:ppn=6,nodes=1:ppn=6,walltime=24:00:00    sw    jfillon analyste    2465764    N/A    f3c10    /path/to/output_dir/job_output/trimmomatic/trimmomatic.readset1_2014-09-30T19.52.29.o
2100214.abacus2.ferrier.genome.mcgill.ca    2100214.abacus2.ferrier.genome.mcgill.ca    trimmomatic.readset2    SUCCESS    N/A    0    01:08:59 (1 h 8 min 59 s)    2014-09-30T19:52:58    2014-09-30T21:02:01    02:40:05 (2 h 40 min 5 s)    2.32    1.41 GiB    3.73 GiB    164.0 %    neednodes=1:ppn=6,nodes=1:ppn=6,walltime=24:00:00    sw    jfillon analyste    2465669    N/A    f3c10    /path/to/output_dir/job_output/trimmomatic/trimmomatic.readset2_2014-09-30T19.52.29.o
2100215.abacus2.ferrier.genome.mcgill.ca    2100215.abacus2.ferrier.genome.mcgill.ca    merge_trimmomatic_stats    2100213.abacus2.ferrier.genome.mcgill.ca:2100214.abacus2.ferrier.genome.mcgill.ca    SUCCESS    N/A    0    00:00:01 (1 s)    2014-09-30T21:04:06    2014-09-30T21:04:12    00:00:00 (0 s)    0.00    0.00 GiB    0.00 GiB    N/A    neednodes=1:ppn=1,nodes=1:ppn=1,walltime=120:00:00    sw    jfillon    analyste    3343994    N/A    f3c11    /path/to/output_dir/job_output/merge_trimmomatic_stats/merge_trimmomatic_stats_2014-09-30T19.52.29.o
2100216.abacus2.ferrier.genome.mcgill.ca    2100216.abacus2.ferrier.genome.mcgill.ca    insilico_read_normalization_readsets.readset1    2100213.abacus2.ferrier.genome.mcgill.ca    FAILED    N/A    N/A    00:38:16 (38 min 16 s)    2014-09-30T21:02:02    2014-09-30T21:40:23    04:50:10 (4 h 50 min 10 s)    7.58    30.71 GiB    32.32 GiB    5.3 %    neednodes=1:ppn=6,nodes=1:ppn=6,walltime=120:00:00    sw    jfillon    analyste    3343745    N/A    f3c11    /path/to/output_dir/job_output/insilico_read_normalization_readsets/insilico_read_normalization_readsets.readset1_2014-09-30T19.52.29.o
...

Call home

When pipeline jobs are submitted, a call home feature is invoked to collect some usage data. Those data are used to compute statistics and justify grant applications for funding support.

Data collected:

  • Date and time
  • Host and IP address
  • Pipeline name
  • Number of samples
  • Pipeline steps

Contact us

Please visit our mailing list to find questions and answers about MUGQIC Pipelines.

To subscribe to the mailing list and receive other people's messages, send an e-mail at mugqic_pipelines+subscribe@googlegroups.com. You will receive an invitation which you must accept.

To use it, send us an e-mail at mugqic_pipelines@googlegroups.com.

You can also report bugs at pipelines@computationalgenomics.ca.

  • Messages should not be sent directly to our team members. The generic e-mail addresses above are viewable by all of us and facilitate the follow-up of your request.
  • Choose a meaningful subject for your message.
  • Include the pipeline version number in your message (and the commit number if applicable).
  • Provide the following information relevant to the problem encountered: the python command, the bash submission script, the output (job_outputs//.o) file,
  • An error message or code snippet illustrating your request is normally very useful.

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