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(use-modules (skribilo lib)
             (ccwl skribilo))

(document :title [Concise Common Workflow Language]
  (chapter :title [Introduction]
    (p [,(abbr :short "CWL" :long "Common Workflow
Language") is an open standard for describing analysis workflows and
tools in a way that makes them portable and scalable across a variety
of software and hardware environments.])
    (p [,(abbr :short "ccwl" :long "Concise Common
Workflow Language") is a concise syntax to express CWL workflows. It
is implemented as an ,(abbr :short "EDSL" :long "Embedded Domain
Specific Language") in the Scheme programming language, a minimalist
dialect of the Lisp family of programming languages.])
    (p [ccwl is a compiler to generate CWL workflows
from concise descriptions in ccwl. In the future, ccwl will also have
a runtime whereby users can interactively execute workflows while
developing them.]))
  (chapter :title [Tutorial]
    (p [This tutorial will introduce you to writing
workflows in ccwl. Some knowledge of CWL is assumed. To learn about
CWL, please see the ,(ref :url "https://www.commonwl.org/user_guide/"
:text "Common Workflow Language User Guide")])

    (section :title [Important concepts]
      (p [The CWL and ccwl workflow languages
are statically typed programming languages where functions accept
multiple named inputs and return multiple named outputs. Let 's break
down what that means.])
      (subsection :title [Static typing]
        (p [In CWL ,the type of arguments accepted by a function and
the type of outputs returned by that function are specified explicitly
by the programmer ,and are known at compile time even before the code
has been run. Hence ,we say that it is statically typed.]))
      (subsection :title [Positional arguments and named arguments]
        (p [In many languages ,the order of arguments passed to a
function is significant. The position of each argument determines
which formal argument it gets mapped to. For example ,passing
positional arguments in Scheme looks like])
        (prog :line #f [(foo 1 2)])
        (p [In a language that supports named arguments ,the order of
arguments is not significant. Each argument explicitly names the
formal argument it gets mapped to. For example , in Scheme ,passing
named arguments may look like]
           (prog :line #f [(foo #:bar 1 #:baz 2)])))
      (subsection :title [Multiple function arguments and return values]
        (p [In most languages, functions accept multiple input
arguments but only return a single output value. However, in CWL, a
function can return multiple output values as well. These multiple
outputs are unordered and are each addressed by a unique name.])))

    (section :title [First example]
      (p [As is tradition, let us start with a simple "Hello World"
workflow in ccwl. This workflow accepts a string input and prints that
string.])

      (scheme-source "doc/hello-world.scm")

      (p [The first form in this code defines the ,(code "print")
command. This form is the equivalent of defining a
,(code "CommandLineTool") class workflow in CWL. All arguments after
,(code "#:run") specify the command that will be run. One of those
arguments ,(code "(input 'message #:type 'string)") refers to a
,(code "string") type input named ,(code "message"). Notice how the
command definition is very close to a shell command, only that it is
slightly annotated with inputs and their types.])

      (p [The second form describes the actual workflow and is the
equivalent of defining a ,(code "Workflow") class workflow in CWL. The
form ,(code "((message #:type string))") specifies the inputs of the
workflow. In this case, there is only one input---,(code "message") of
type ,(code "string"). The body of the workflow specifies the commands
that will be executed. The body of this workflow executes only a
single command---the ,(code "print") command---passing the
,(code "message") input of the workflow as the ,(code "message") input
to the ,(code "print") command.])

      (p [If this workflow is written to a file
,(file "hello-world.scm"), we may compile it to CWL by running])

      (prog :line #f [$ ccwl compile hello-world.scm])

      (p [This prints a big chunk of generated CWL to standard
output. We have achieved quite a lot of concision already! We write
the generated CWL to a file and execute it using (command "cwltool")
as follows. The expected output is also shown.])

      (prog :line #f (source :file "doc/hello-world.out")))

    (section :title [Capturing the standard output stream of a command]
      (p [Let us return to the “Hello World” example in the previous
section. But now ,let us capture the standard output of the
,(code "print") command in an output object. The ccwl code is the same
as earlier with only the addition of an ,(code "stdout") type output
object to the command definition.])

      (scheme-source "doc/capture-stdout.scm")

      (p [Let's write this code to a file
,(file "capture-stdout.scm"), generate CWL, write the generated CWL to
,(file "capture-stdout.cwl"), and run it using ,(code "cwltool"). We
might expect something like the output below. Notice how the standard
output of the ,(code "print") command has been captured in the file
,(file "51fe79d15e7790a9ded795304220d7a44aa84b48").])

      (prog :line #f (source :file "doc/capture-stdout.out")))

    (section :title [Capturing output files]
      (p [In the previous section ,we captured the standard output
stream of a command. But ,how do we capture any output files created
by a command?  Let us see.])

      (p [Consider a tar archive ,(file "hello.tar") containing a file
,(file "hello.txt").])

      (prog :line #f (source :file "doc/hello.tar.out"))

      (p [Let us write a workflow to extract the file
,(file "hello.txt") from the archive. Everything in the following
workflow except the ,(code "#:binding") parameter will already be
familiar to you. The ,(code "#:binding") parameter sets the
,(code "outputBinding") field in the generated CWL. In the example
below, we set the ,(code "glob") field to look for a file named
,(file "hello.txt").])

      (scheme-source "doc/capture-output-file.scm")

      (p [Writing this workflow to ,(file "capture-output-file.scm"),
compiling and running it gives us the following output. Notice that
the file ,(file "hello.txt") has been captured and is now present in
our current working directory.])

      (prog :line #f (source :file "doc/capture-output-file.out"))

      (p [The above workflow is not awfully flexible. The name of the
file to extract is hardcoded into the workflow. Let us modify the
workflow to accept the name of the file to extract. We introduce
,(code "extractfile"), a ,(code "string") type input that is passed to
,(command "tar") and is referenced in the ,(code "glob") field.])

      (scheme-source "doc/capture-output-file-with-parameter-reference.scm")

      (p [Compiling and running this workflow gives us the following
output.])

      (prog :line #f (source :file "doc/capture-output-file-with-parameter-reference.out")))

    (section :title [Workflow with multiple steps]
      (p [Till now, we have only written trivial workflows with a
single command. If we were only interested in executing single
commands, we would hardly need a workflow language! So, in this
section, let us write our first multi-step workflow and learn how to
connect steps together in an arbitrary topology.])

      (subsection :title [pipe]
        (p [First ,the simplest of topologies---a linear chain
representing sequential execution of steps. The following workflow
decompresses a compressed C source file ,compiles and then executes
it.])

        (scheme-source "doc/decompress-compile-run.scm")

        (p [Notice the ,(code "pipe") form in the body of the
workflow. The ,(code "pipe") form specifies a list of steps to be
executed sequentially. The workflow inputs coming into ,(code "pipe")
are passed into the first step. Thereafter, the outputs of each step
are passed as inputs into the next. Note that this has nothing to do
with the Unix pipe. The inputs/outputs passed between steps are
general CWL inputs/outputs. They need not be the standard stdin and
stdout streams.])

        ;; TODO: Add workflow graph

        (p [Writing this worklow to
,(file "decompress-compile-run.scm"), compiling and running it with
the compressed C source file ,(file "hello.c.gz") gives us the
following output.])

        (prog :line #f (source :file "doc/decompress-compile-run.out"))

        (p [The steps run in succession, and the stdout of the
compiled executable is in
,(file "c32c587f7afbdf87cf991c14a43edecf09cd93bf"). Success!]))

      (subsection :title [tee]
        (p [Next, the tee topology. The following workflow computes
three different checksums of a given input file.])

        (scheme-source "doc/checksum.scm")

        (p [Notice the ,(code "tee") form in the body of the
workflow. The ,(code "tee") form specifies a list of steps that are
independent of each other. The workflow inputs coming into
,(code "tee") are passed into every step contained in the body of the
,(code "tee"). The outputs of each step are collected together and
unioned as the output of the ,(code "tee").])

        ;; TODO: Add workflow graph

        (p [Writing this workflow to ,(file "checksum.scm"), compiling
and running it with some file ,(file "hello.txt") gives us the
following output.])

        (prog :line #f (source :file "doc/checksum.out"))

        (p [The MD5, SHA1 and SHA256 checksums are in the files
,(file "112be1054505027982e64d56b0879049c12737c6"),
,(file "d2f19c786fcd3feb329004c8747803fba581a02d") and
,(file "0d2eaa5619c14b43326101200d0f27b0d8a1a4b1") respectively.]))))

  (chapter :title [Contributing]
    (p [ccwl is developed on GitHub at ,(ref
:url "https://github.com/arunisaac/ccwl"). Feedback, suggestions,
feature requests, bug reports and pull requests are all
welcome. Unclear and unspecific error messages are considered a
bug. Do report them!])))