Meraculous-Sapelo2: Difference between revisions
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run_meraculous.sh -c meraculous.standalone.config -dir output -cleanup_level 1 | run_meraculous.sh -c meraculous.standalone.config -dir output -cleanup_level 1 | ||
where parameters of the job, such as the maximum wall clock time (--time), maximum memory (--mem), CPU cores (--cpus-per-task), and the job name (--job-name) need to be modified appropriately. In this example, the standard output and | where the parameters of the job, such as the maximum wall clock time (--time), maximum memory (--mem), CPU cores (--cpus-per-task), and the job name (--job-name) need to be modified appropriately. In this example, the standard output and error of the run_meraculous.sh command will be saved into two files called "log.${SLURM_JOB_ID}.out" and "log.${SLURM_JOB_ID}.err", respectively, where ${SLURM_JOB_ID} will automatically be replaced by the jobid number. | ||
Revision as of 12:36, 14 December 2022
Category
Bioinformatics
Program On
Sapelo2
Version
2.2.6
Author / Distributor
Please see https://jgi.doe.gov/data-and-tools/software-tools/meraculous/: "Meraculous is a whole genome assembler for Next Generation Sequencing data geared for large genomes."
Description
From https://sourceforge.net/projects/meraculous20/, "Meraculous-2D is a whole genome assembler for NGS reads (Illumina) that is capable of assembling large, diploid genomes with modest computational requirements.
Features include:
- Efficient k-mer counting and deBruijn graph traversal
- Two modes of handling of diploid allelic variation
- Improved scaffolding that produces more complete assemblies without compromising scaffolding accuracy."
Running Program
Also refer to Running Jobs on Sapelo2
For more information on Environment Modules on Sapelo2 please see the Lmod page.
- Version 2.2.6, installed as Conda virtual environment in /apps/eb/Meraculous/2.2.6
To use this version of magma, please first load the module with
module load Meraculous/2.2.6
Please note:
- To run Meraculous, in your current job working folder, you need to prepare a configuration file that contains the parameters guiding the entire assembly process. This configuration file must be passed to the program with the -c <configuration file> argument.
- The assembly is driven by a perl pipeline which performs data fragmentation and load balancing, as well as submission and monitoring of multiple task arrays on a SLURM-type cluster (Sapelo2) or a standalone multi-core server.
Example of how to run Meraculous in a standalone multi-core server on batch
1. Create a configuration file in your current working folder. In the example below this file is called meraculous.standalone.config and its content is
#Describe the libraries ( one line per library ) lib_seq /scratch/zhuofei/meraculous/OT1_CKDN220054653-1A_HF33VDSX5_L1_R1_paired.fq,/scratch/zhuofei/meraculous/OT1_CKDN220054653-1A_HF33VDSX5_L1_R2_paired.fq GERMAC1 200 20 150 0 0 1 1 1 0 0 genome_size 2.15 mer_size 31 diploid_mode 2 num_prefix_blocks 4 min_depth_cutoff 3 use_cluster 0
2. Create a job submission script, called sub.sh in the example here, with the sample content
#!/bin/bash #SBATCH --job-name=meraculoue_standalone #SBATCH --partition=batch #SBATCH --nodes=1 #SBATCH --ntasks=1 #SBATCH --cpus-per-task=16 #SBATCH --mem=128gb #SBATCH --time=7-00:00:00 #SBATCH --output=log.%j.out #SBATCH --error=log.%j.err cd $SLURM_SUBMIT_DIR ml Meraculous/2.2.6 run_meraculous.sh -c meraculous.standalone.config -dir output -cleanup_level 1
where the parameters of the job, such as the maximum wall clock time (--time), maximum memory (--mem), CPU cores (--cpus-per-task), and the job name (--job-name) need to be modified appropriately. In this example, the standard output and error of the run_meraculous.sh command will be saved into two files called "log.${SLURM_JOB_ID}.out" and "log.${SLURM_JOB_ID}.err", respectively, where ${SLURM_JOB_ID} will automatically be replaced by the jobid number.
3. Submit the job to the queue with
sbatch sub.sh
Documentation
Tutorials and user guide are available at http://magma.maths.usyd.edu.au/magma/documentation/
Installation
- Binaries for Intel and AMD processors with AVX support downloaded from http://magma.maths.usyd.edu.au/magma/
System
64-bit Linux