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Important note: This is a work-in-progress project to update the sevenbridges2 package. Accordingly, this vignette will also change as new features are implemented.

1 Introduction

sevenbridges2 is an R package that provides an interface for the Seven Bridges public API. The supported platforms include the Seven Bridges Platform, Cancer Genomics Cloud (CGC), BioData Catalyst (BDC) and CAVATICA.

Learn more from our documentation on the Seven Bridges Platform, Cancer Genomics Cloud (CGC), BioData Catalyst (BDC) and CAVATICA.

Unlike the current sevenbridges package that is built on top of Reference classes, the sevenbridges2 package is based on more modern and lightweight R6 classes. However, the basic idea and way of constructing API requests is largely preserved.

1.1 R Client for the Seven Bridges API

In order to use the sevenbridges2 package users must authenticate themselves first by creating an Auth object and providing necessary credentials. You can read more about the authentication types in our next chapters.

The sevenbridges2 package only supports v2+ versions of the API, since versions prior to v2 are not compatible with the Common Workflow Language (CWL). This package provides a simple interface for accessing and trying out various methods.

1.2 Installation

The sevenbridges2 package is available on CRAN and Seven Bridges Github repository.

To install it from CRAN, use simply:

# Install package from CRAN
install.packages("sevenbridges2")

To install the development version from the develop branch on our Github, use the remotes package:

# Install package from github
remotes::install_github(
  "sbg/sevenbridges2",
  build_vignettes = TRUE, dependencies = TRUE
)

If you have trouble with pandoc and do not want to install it, set build_vignettes = FALSE to avoid the vignettes build.

1.3 API General Information

There are two ways of constructing API calls. For instance, you can use low-level API calls which use arguments like path, query, and body. These are documented in the API reference libraries for the Seven Bridges Platform and the CGC. An example of a low-level request to “list all projects” is shown below. In this request, you can also pass query and body as a list.

# Load the package
library("sevenbridges2")

# Authenticate
a <- Auth$new(token = "<your_token>", platform = "aws-us")

# List all projects with raw api() function
a$api(path = "projects", method = "GET")

(Advanced user option) The second way of constructing an API request is to directly use the httr2 package to make your API calls.

The sevenbridges2 package is organized by main resources from the Seven Bridges API reference. There we have groups of endpoints to work with projects, files, apps, tasks, invoices, volumes, etc. For each group of resources, there is a set of operations such as query(), get() and delete() which are common, as well as other custom operations.

Before we start, keep in mind the following:

offset and limit

Almost every API call accepts two arguments named offset and limit.

  • Offset defines where the retrieved items start.
  • Limit defines the number of items you want to get.

By default, offset is set to 0 and limit is set to 50. As such, your API request returns the first 50 items when you list items or search for items by name. To search and list all items, use complete = TRUE if you are using the core api() function in your API request, or the all() operation within the Collection object you’ve received as the result.

Collection

Every API call that returns a list of items (usually the output from query() operations), operations), like fetching projects, files, apps etc, wraps the results into a general Collection class object containing the items field from which users may access the items returned. Additional options that the Collection class offers are to navigate between pages of results, for example, to load next or previous page of results by calling next_page() and prev_page() methods.

Moreover, users can fetch all results using Collection’s all() method which is a shortcut to send multiple API calls for each next page and collect all results. Keep in mind the limit used, as well as the API rate limit.

# Create a collection of files
public_files <- a$files$query(project = "admin/sbg-public-data")

# Load next 50 results
public_files$next_page()

# Load previous 50 results
public_files$prev_page()

# Load all results
public_files$all()

Lastly, printing Collection objects will print the first 10 items (if there are more than 10 items in the results) by default, but this can be changed with the n parameter in its print() function:

# Create a collection of files
public_files <- a$files$query(project = "admin/sbg-public-data")

# Default print
public_files

# Print 20 items
public_files$print(n = 20)

Search by ID

When searching by ID (usually it’s the resource’s get() operation), your request will return your exact resource as it is unique. Therefore, you do not have to set offset and limit manually. It is good practice to find your resources by their ID and pass this ID as an input to your task. You can find a resource’s ID in the final part of the URL in the visual interface or via API requests to list resources or get a resource’s details.

Search by name

Search by name as criteria in the query() operations of Resources, returns all exact or partial matches depending on the resource.

For example, to list all public files, use the admin/sbg-public-data project query parameter, while if you want to find an exact file by name, set its name parameter to the exact value (partial search by name is not possible for files).

# Search all public files
public_files <- a$files$query(project = "admin/sbg-public-data")

# Search files by name
file_1000G_omni <- a$files$query(
  project = "admin/sbg-public-data",
  name = "1000G_omni2.5.b37.vcf"
)

On the other hand, partial search by name works for Projects and Apps resources. You can set the corresponding name or query_terms parameters for this use case. In order to query public apps, set the visibility parameter to ‘public’.

# Search all public apps containing the STAR term
public_star_apps <- a$apps$query(
  visibility = "public",
  query_terms = list("STAR")
)

# Search all projects that contain "demo" in the name
demo_projs <- a$projects$query(name = "demo")
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2 Quickstart

2.1 Create Auth Object

Before you can access your account via the API, you have to provide your credentials. You can obtain your credentials in the form of an “authentication token” from the Developer Tab under Account Settings in the visual interface. Once you’ve obtained this, create an Auth object, so it remembers your authentication token and the path for the API. All subsequent requests will use these two pieces of information.

Let’s load the package first:

# Load package
library("sevenbridges2")

You have three different ways to provide your token. Choose from one of the methods below:

  1. Direct authentication. Here you should provide your developer token and a base URL for the platform of interest (alternatively, you can provide the name of the platform - these are the available options cgc, aws-us, aws-eu, ali-cn, cavatica, f4c - the default platform is aws-us) as function call arguments to Auth$new(). This will create the platform authentication object and temporarily set up your token and platform base URL as environment variables SB_AUTH_TOKEN and SB_API_ENDPOINT. This way, your token will not be directly stored in the Auth object, but you will still be able to access it by calling the get_token() method. Keep in mind that these environment variables are session-specific and are deleted when the session ends.

  2. Authentication via system environment variables. By default this will read the credential information from two existing system environment variables: SB_API_ENDPOINT and SB_AUTH_TOKEN. Of course, assuming that you have previously set these environment variables. Alternatively, you can specify the names of the system environment variables you want to be loaded using the sysenv_token and sysenv_url arguments.

  3. Authentication via the user configuration file. This file, by default $HOME/.sevenbridges/credentials, provides an organized way to collect and manage all your API authentication information for Seven Bridges platforms.

If you need to be logged into multiple accounts at the same time (which can also be for different platforms), please use either the second or the third method.

Method 1: Direct authentication

This is the most common method to construct the Auth object. For example:

# Authenticate with direct method
a <- Auth$new(platform = "aws-us", token = "<your-token>")

Method 2: Environment variables

To set the two environment variables in your system, you could use the function sbg_set_env(). For example:

# Set environment variables
sevenbridges2:::sbg_set_env(
  url = "https://api.sbgenomics.com/v2/",
  token = "<your_token>"
)

Note that these environment variables are session-specific.

Create an Auth object:

# Authenticate using environment variables
a <- Auth$new(from = "env")

Method 3: User configuration file

Assume we have already created the configuration file named credentials under the directory $HOME/.sevenbridges/:

[aws-us-<username>]
api_endpoint = https://api.sbgenomics.com/v2
auth_token = token_for_this_user

# another user on the same platform
[aws-us-rosalind-franklin]
api_endpoint = https://api.sbgenomics.com/v2
auth_token = token_for_this_user

[cgc]
api_endpoint = https://cgc-api.sbgenomics.com/v2
auth_token = token_for_this_user

[bdc]
api_endpoint = https://api.sb.biodatacatalyst.nhlbi.nih.gov/v2/
auth_token = token_for_this_user

To load the user profile aws-us-<username> from this configuration file, simply use:

# Load aws-us-<username> profile for authentication
a <- Auth$new(
  from = "file",
  profile_name = "aws-us-<username>"
)

If profile_name is not specified, we will try to load the profile named [default]:

# Load default profile
a <- Auth$new(from = "file")

The option based on the use of a configuration file also enables simultaneous authentication from multiple accounts. Assuming that we have a configuration file like the one listed above, and that we want to create authentication objects for two profiles (default and aws-us-<username>), we can achieve this in the following way:

# Create Auth object with 'default' account
a <- Auth$new(from = "file", profile_name = "default")

# Create Auth object with 'aws-us-<username>' account
b <- Auth$new(from = "file", profile_name = "aws-us-<username>")

Note: API paths (base URLs) differ for each Seven Bridges environment. Be sure to provide the correct path for the environment you are using. API paths for some of the environments are:

Platform Name API Base URL Short Name
Seven Bridges Platform (US) https://api.sbgenomics.com/v2 "aws-us"
Seven Bridges Platform (EU) https://eu-api.sbgenomics.com/v2 "aws-eu"
Seven Bridges Platform (China) https://api.sevenbridges.cn/v2 "ali-cn"
Cancer Genomics Cloud (CGC) https://cgc-api.sbgenomics.com/v2 "cgc"
Cavatica https://cavatica-api.sbgenomics.com/v2 "cavatica"
BioData Catalyst Powered by Seven Bridges https://api.sb.biodatacatalyst.nhlbi.nih.gov/v2 "f4c"
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Please check vignette("Authentication_and_Billing", package = "sevenbridges2") for more technical details about all available authentication methods.

2.2 Get User Information

Get your own information

This call returns information about your account.

# Get currently authenticated user info
a$user()
── User ────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
• country: United States
• affiliation: SBG
• last_name: Test
• first_name: User
• email: <user>@sbgenomics.com
• username: <username>
• href: https://api.sbgenomics.com/v2/users/<user>
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Get information about a user

This call returns information about the specified user. Note that currently you can view only your own user information, so this call is equivalent to the call to get information about your account.

# Get user info
a$user(username = "<username>")
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Please check vignette("Authentication_and_Billing", package = "sevenbridges2") for more technical details about getting user information.

2.3 Rate Limit

This call returns information about your current rate limit. This is the number of API calls you can make in five minutes. This call also returns information about your current instance limit.

# Get rate limit info
a$rate_limit()
── Rate Limit ────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
• rate
  • limit: 1000
  • remaining: 1000
  • reset: 2022-12-26 11:31:01 CET
• instance
  • limit: 25
  • remaining: 25
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Please check vignette("Authentication_and_Billing", package = "sevenbridges2") for more technical details about rate limit information.

2.4 Show Billing Information

Each project must have a Billing Group associated with it. This Billing Group pays for the storage and computation in the project.

For example, your first project(s) were created with the free funds from the Pilot Funds Billing Group assigned to each user at sign-up.

To get information about your billing groups:

# Check your billing info
a$billing_groups$query()

This call lists all your billing groups, including groups that are pending or have been disabled.

To get information about your invoices:

# Check your invoices
a$invoices$query()

The call returns information about all your available invoices, unless you use the billing_group_id query parameter to specify the ID of a particular billing group, in which case it will return the invoice incurred by that billing group only.

To get detailed information for a specific billing group, please use the billing_group method with the billing group ID. The information returned includes the billing group owner, the total balance, and the status of the billing group (pending, disabled,…).

# Get a single billing group
a$billing_groups$get(id = "<billing_group_id>")
── Billing group info ────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
• disabled: FALSE
• pending: FALSE
• type: regular
• name: My billing group
• owner: <bg_owner's_username>
• id: <billing_group_id>
• href: https://api.sbgenomics.com/v2/billing/groups/<billing_group_id>
• balance
  • currency: USD
  • amount: 221
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Please check vignette("Authentication_and_Billing", package = "sevenbridges2") for more technical details about billing informations.

2.5 List and query projects

Projects are the core building blocks of the platform. Each project corresponds to a distinct scientific investigation, serving as a container for its data, analysis tools, results, and collaborators.

In order to query and explore all projects, use the projects resource path and the query() method. One can also filter the projects by several criteria, like project’s name and tags. The search by name is partial and case-insensitive.

# List first 5 projects
my_projects <- a$projects$query(limit = 5)
my_projects

# Load next page of results
my_projects$next_page()

# Return all projects that contain the term "demo"
demo_projects <- a$projects$query(name = "demo")

# Return all projects tagged with "demo"
tagged_projects <- a$projects$query(tags = list("demo"))

Note that the output is the Collection object and the results (list of Project objects) can be found within the items field.

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Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about projects.

2.6 Create a new project

Create a new project called “API testing” with the billing group id obtained above.

# List all available billing groups for currently logged in user
a$billing_groups$query()

# Set the billing group for the new project
bid <- "<billing_group_id>"

# Create a new project
p <- a$projects$create(
  name = "API testing", billing_group = bid,
  description = "This project has been created using the sevenbridges2 R API
  library."
)
── Project ───────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
• category: PRIVATE
• root_folder: <root_folder_id>
• type: v2
• description: This project has been created using the sevenbridges2 R API library.
• billing_group: <billing_group_id>
• name: API testing
• id: <your_username_or_division>/api-testing
• href: https://api.sbgenomics.com/v2/projects/<your_username_or_division>/api-testing
• settings
  • locked: FALSE
  • controlled: FALSE
  • location: aws:us-east-1
  • use_interruptible_instances: TRUE
  • use_memoization: FALSE
  • intermediate_files: list(duration = 24, retention = "LIMITED")
  • allow_network_access: TRUE
  • use_elastic_disk: FALSE
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The new project is created on the platform. Notice also that the variable p is an R6 object with fields that contain information about the platform project. The facility also has several methods that allow you to perform basic platform operations on the project.

Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about projects.

2.7 Get details of a specified project

Use the get() method and provide the full ID of the project you would like to fetch.

# Get a single project by ID
a$projects$get(id = "<your_username_or_division>/api-testing")
── Project ───────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
• category: PRIVATE
• root_folder: <root_folder_id>
• type: v2
• description: This project has been created using the sevenbridges2 R API library.
• billing_group: <billing_group_id>
• name: API testing
• id: <your_username_or_division>/api-testing
• href: https://api.sbgenomics.com/v2/projects/<your_username_or_division>/api-testing
• settings
  • locked: FALSE
  • controlled: FALSE
  • location: aws:us-east-1
  • use_interruptible_instances: TRUE
  • use_memoization: FALSE
  • intermediate_files: list(duration = 24, retention = "LIMITED")
  • allow_network_access: TRUE
  • use_elastic_disk: FALSE

Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about apps.

2.8 Copy app into the project

Seven Bridges maintains workflows and tools available to all of its users in the Public Apps repository.

To find out more about public apps, you can do the following:

  • Browse them online. Check out the tutorial in the “Find apps” section.
  • You can use the sevenbridges2 package to find it, as shown below.
# Search by name matching, with limit 10
public_apps <- a$apps$query(
  visibility = "public",
  limit = 10,
  query_terms = list("STAR")
)

# Search by ID
star_app <- a$apps$get(
  id = "admin/sbg-public-data/rna-seq-alignment-star/0"
)

Now, copy the App your project with a new name, following this logic.

# Copy app into the project
a$apps$copy(
  app = star_app,
  project = "<username_or_division>/api-testing",
  name = "New copy of STAR"
)

# Check if it is copied
p <- a$projects$get(id = "<username_or_division>/api-testing")

# List the apps you have in your project
p$list_apps()

The short name is changed to newcopyofstar.

== App ==
id : <username_or_division>/api-testing/newcopyofstar/0
name : RNA-seq Alignment - STAR
project : <username_or_division>/api-testing
revision : 0

Alternatively, you can copy it from the App object.

# Get public app RNA Sequencing alignment - STAR
star_app <- a$apps$get(
  id = "admin/sbg-public-data/rna-seq-alignment-star/0"
)

# Copy it into a project
star_app$copy(
  project = "<username_or_division>/api-testing",
  name = "Copy of STAR"
)
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Next, we would like to run a task with this app. Let’s see what is required.

Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about tasks.

2.9 Execute a new task

2.9.1 Find your app inputs

Once you have copied the public app admin/sbg-public-data/rna-seq-alignment-star/0 into your project, <username>/api-testing, the app id in your current project is <username>/api-testing/newcopyofstar. Alternatively, you can use another app you already have in your project for this Quickstart.

To draft a new task, you need to specify the following:

  • The name of the task
  • An optional description
  • The App object or id of the workflow you are executing
  • The inputs for your workflow.

You can always check the App details on the visual interface for task input requirements. However, there is also a function on the App objects to get basic information about app’s inputs and outputs. To find the required inputs with R, you need to get an App object first.

Let’s check which inputs this app requires by calling the input_matrix() function and bring them into our project.

# Fetch copied app
copied_star_app <- a$apps$get(
  id = "<username_or_division>/api-testing/newcopyofstar/0"
)

# Preview its inputs
copied_star_app$input_matrix()

Locate the IDs of the required inputs. Note that task inputs need to match the expected data type and name. In the above example, we see two required fields:

  • fastq: This input takes a file array in the following formats: FASTA, FASTQ, FA, FQ etc.
  • genomeFastaFiles: This is a single reference file in the FASTA, FA, FNA or TAR format.

We also want to provide a gene feature file:

  • sjdbGTFfile: A file array that can be in the GTF, GFF, GFF2, or GFF3 format.

You can find a list of possible input types below:

  • number, character or integer: you can directly pass these to the input parameter as they are.
  • enum type: Pass this value to the input parameter.
  • file: This input is a file. However, while some inputs accept only a single file (File), other inputs take more than one file (File arrays, FilesList, or ‘File...’ ). This input requires you to pass a single File object (for a single file input) or list of File objects (for inputs which accept more than one file). You can search for your file by id or by name, as shown in the example below.
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2.9.2 Prepare your input files

# Get reads (fastq) files and and copy them into a project
reads_1 <- a$files$get(id = "641c48c425ed1842bd0bf799") # file id
reads_1$copy_to(project = p)

reads_2 <- a$files$get(id = "641c48c425ed1842bd0bf835") # file id
reads_2$copy_to(project = p)

# Get a single file reference file and copy into a project
fasta_in <- a$files$get(id = "641c48c525ed1842bd0bf86a") # file id
fasta_in$copy_to(project = p)

# Get gtf file and copy into a project
gtf_in <- a$files$get(id = "641c48c425ed1842bd0bf825") # file id
gtf_in$copy_to(project = p)

# Get copied files
input_files <- p$list_files()$items
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2.9.3 Create a new draft task

# Add new tasks
taskName <- paste0("STAR-alignment ", date())

tsk <- p$create_task(
  name = taskName,
  description = "STAR test",
  app = copied_star_app,
  inputs = list(
    "fastq" = c(input_files[[1]], input_files[[2]]),
    "genomeFastaFiles" = input_files[[3]],
    "sjdbGTFfile" = list(input_files[[4]])
  )
)

# Preview task
tsk$print()

2.9.4 Preview your app’s expected outputs

Similarly as with inputs, you can also preview the structure of the expected outputs of the task or workflow. You can get details about the output’s name, description and type using output_matrix(). This function can be called from the App object.

# Get app's outputs details
copied_star_app$output_matrix()
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Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about tasks.

2.10 Run a Task

Now, we are ready to run our task.

# Run your task
tsk$run()

Before you run your task, you can adjust your draft task if you have any final modifications.

# Update task
tsk$update(description = "New RNA SEQ Alignment - STAR task")

After you run a task, you can track its status by refreshing the object with reload() function.

# Reload task
tsk$reload()
tsk$status

You can also abort the task execution if needed:

# Abort your task
tsk$abort()

If you want to rerun your task without any modifications, you can use rerun() function which will clone the current task for you and start the execution immediately.

# Rerun your task
tsk$rerun()

On the other side, if you want to update your task first and then re-run it, you should clone the current task, update it and then run it, as demonstrated below:

# First clone existing task
cloned_task <- tsk$clone_task()

# Then, update GTF input file in the cloned task
cloned_task$update(inputs = list(sjdbGTFfile = "<some new file>"))
cloned_task$run()

Alternatively, you can delete the draft task if you no longer wish to run it.

# # not run
# tsk$delete()
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Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about running tasks.

2.11 Run tasks using spot instances

Running tasks with spot instances could potentially reduce a considerable amount of computational cost. This option can be controlled on the project level or the task level on Seven Bridges platforms. Our package follows the same logic as our platform’s web interface (the current default setting for spot instances is on).

For example, when we create a project using Projects resource’s method create(), we can set use_interruptible = FALSE to use on-demand instances (non-interruptible but more expensive) instead of the spot instances (interruptible but cheaper):

# Create project with disabled spot instances
p <- a$projects$create(
  name = "spot-disabled-project", bid, description = "spot disabled project",
  use_interruptible = FALSE
)

Then all the new tasks created under this project will use on-demand instances to run by default, unless an argument use_interruptible_instances is specifically set to TRUE when drafting the new task using Tasks resource method create().

For example, if p is the above spot disabled project, to draft a task that will use spot instances to run:

# Create task and set usage of interruptible instances to TRUE
tsk <- p$create_task(
  name = paste0("spot enabled task in a spot disabled project"),
  description = "spot enabled task",
  app = copied_star_app,
  inputs = list(
    "fastq" = c(input_files[[1]], input_files[[2]]),
    "genomeFastaFiles" = input_files[[3]],
    "sjdbGTFfile" = list(input_files[[4]])
  ),
  use_interruptible_instances = TRUE
)

Conversely, you can have a spot instance enabled project, but draft and run specific tasks using on-demand instances, by setting use_interruptible_instances = FALSE in create_task() explicitly.

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Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about running tasks using spot instances.

2.12 Execution hints per task run

During workflow development and benchmarking, sometimes we need to view and make adjustments to the computational resources needed for a task to run more efficiently. Also, if a task fails due to resource deficiency, we often want to define a larger instance for the task re-run without editing the app itself. This is particularly important in cases where there is not enough disk space.

The Seven Bridges API allows setting specific task execution parameters by using execution_settings. It includes the instance type (instance_type) and the maximum number of parallel instances (max_parallel_instances):

# Create task with setting instance type and number of parallel instances
tsk <- p$create_task(
  ...,
  execution_settings = list(
    instance_type = "c4.2xlarge;ebs-gp2;2000",
    max_parallel_instances = 2
  )
)

For details about execution_settings, please check create a new draft task.

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Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about execution hints.

2.13 Draft a batch task

Now let’s do a batch with 4 files in 2 groups, which is batched by metadata sample_id. We will assume each file has this metadata field entered. Since these files can be evenly grouped into 2, we will have a single parent batch task with 2 child tasks.

# Add two more fastq files that will be used in our task inputs
# and copy them into our API testing project
reads_3 <- a$files$get(id = "641c48c425ed1842bd0bf7b6") # file id
reads_3$copy_to(project = p)

reads_4 <- a$files$get(id = "641c48c425ed1842bd0bf7a5") # file id
reads_4$copy_to(project = p)

# Get all project files
input_files <- p$list_files()$items

taskName <- paste0("STAR-alignment ", date())

# Create task with batch criteria
tsk <- p$create_task(
  name = taskName,
  description = "Batch Star Test",
  app = copied_star_app,
  batch = TRUE,
  batch_input = "fastq",
  batch_by = list(
    type = "CRITERIA",
    criteria = list("metadata.sample_id")
  ),
  inputs = list(
    "fastq" = c(
      input_files[[1]],
      input_files[[2]],
      input_files[[3]],
      input_files[[4]]
    ),
    "genomeFastaFiles" = input_files[[5]],
    "sjdbGTFfile" = list(input_files[[6]])
  )
)

# Run batch task
tsk$run()

Now you have a draft batch task. Please check it out in the visual interface. Your response body should inform you of any errors or warnings.

You can also check the parent task’s children status with list_batch_children() method and then for each child execution details:

# List parent task children and their execution details
child_tasks <- tsk$list_batch_children()

child1_details <- child_tasks$items[[1]]$get_execution_details()
child2_details <- child_tasks$items[[2]]$get_execution_details()
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Please check vignette("Projects_and_Tasks_execution", package = "sevenbridges2") for more technical details about running batch tasks.

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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