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authorElizabeth Fischer <elizabeth.fischer@columbia.edu>2016-08-30 23:46:25 -0400
committerElizabeth Fischer <elizabeth.fischer@columbia.edu>2016-08-30 23:48:34 -0400
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-Application Developer Support
-===============================
-
-Three ways to use your Spack packages.
-
-Setting up a User Environment
---------------------------------
-
-Show how to build a script with a bunch of ``module loads`` commands.
-
-
-Filesystem Views
--------------------------------
-
-.. Maybe this is not the right location for this documentation.
-
-The Spack installation area allows for many package installation trees
-to coexist and gives the user choices as to what versions and variants
-of packages to use. To use them, the user must rely on a way to
-aggregate a subset of those packages. The section on Environment
-Modules gives one good way to do that which relies on setting various
-environment variables. An alternative way to aggregate is through
-**filesystem views**.
-
-A filesystem view is a single directory tree which is the union of the
-directory hierarchies of the individual package installation trees
-that have been included. The files of the view's installed packages
-are brought into the view by symbolic or hard links back to their
-location in the original Spack installation area. As the view is
-formed, any clashes due to a file having the exact same path in its
-package installation tree are handled in a first-come-first-served
-basis and a warning is printed. Packages and their dependencies can
-be both added and removed. During removal, empty directories will be
-purged. These operations can be limited to pertain to just the
-packages listed by the user or to exclude specific dependencies and
-they allow for software installed outside of Spack to coexist inside
-the filesystem view tree.
-
-By its nature, a filesystem view represents a particular choice of one
-set of packages among all the versions and variants that are available
-in the Spack installation area. It is thus equivalent to the
-directory hiearchy that might exist under ``/usr/local``. While this
-limits a view to including only one version/variant of any package, it
-provides the benefits of having a simpler and traditional layout which
-may be used without any particular knowledge that its packages were
-built by Spack.
-
-Views can be used for a variety of purposes including:
-
-- A central installation in a traditional layout, eg ``/usr/local`` maintained over time by the sysadmin.
-- A self-contained installation area which may for the basis of a top-level atomic versioning scheme, eg ``/opt/pro`` vs ``/opt/dev``.
-- Providing an atomic and monolithic binary distribution, eg for delivery as a single tarball.
-- Producing ephemeral testing or developing environments.
-
-Using Filesystem Views
-~~~~~~~~~~~~~~~~~~~~~~
-
-A filesystem view is created and packages are linked in by the ``spack
-view`` command's ``symlink`` and ``hardlink`` sub-commands. The
-``spack view remove`` command can be used to unlink some or all of the
-filesystem view.
-
-The following example creates a filesystem view based
-on an installed ``cmake`` package and then removes from the view the
-files in the ``cmake`` package while retaining its dependencies.
-
-.. code-block:: sh
-
-
- $ spack view -v symlink myview cmake@3.5.2
- ==> Linking package: "ncurses"
- ==> Linking package: "zlib"
- ==> Linking package: "openssl"
- ==> Linking package: "cmake"
-
- $ ls myview/
- bin doc etc include lib share
-
- $ ls myview/bin/
- captoinfo clear cpack ctest infotocap openssl tabs toe tset
- ccmake cmake c_rehash infocmp ncurses6-config reset tic tput
-
- $ spack view -v -d false rm myview cmake@3.5.2
- ==> Removing package: "cmake"
-
- $ ls myview/bin/
- captoinfo c_rehash infotocap openssl tabs toe tset
- clear infocmp ncurses6-config reset tic tput
-
-
-Limitations of Filesystem Views
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-
-This section describes some limitations that should be considered in
-using filesystems views.
-
-Filesystem views are merely organizational. The binary executable
-programs, shared libraries and other build products found in a view
-are mere links into the "real" Spack installation area. If a view is
-built with symbolic links it requires the Spack-installed package to
-be kept in place. Building a view with hardlinks removes this
-requirement but any internal paths (eg, rpath or ``#!`` interpreter
-specifications) will still require the Spack-installed package files
-to be in place.
-
-.. FIXME: reference the relocation work of Hegner and Gartung.
-
-As described above, when a view is built only a single instance of a
-file may exist in the unified filesystem tree. If more than one
-package provides a file at the same path (relative to its own root)
-then it is the first package added to the view that "wins". A warning
-is printed and it is up to the user to determine if the conflict
-matters.
-
-It is up to the user to assure a consistent view is produced. In
-particular if the user excludes packages, limits the following of
-dependencies or removes packages the view may become inconsistent. In
-particular, if two packages require the same sub-tree of dependencies,
-removing one package (recursively) will remove its dependencies and
-leave the other package broken.
-
-
-
-Build System Configuration Support
-----------------------------------
-
-Imagine a developer creating a CMake-based (or Autotools) project in a local
-directory, which depends on libraries A-Z. Once Spack has installed
-those dependencies, one would like to run ``cmake`` with appropriate
-command line and environment so CMake can find them. The ``spack
-setup`` command does this conveniently, producing a CMake
-configuration that is essentially the same as how Spack *would have*
-configured the project. This can be demonstrated with a usage
-example:
-
-.. code-block:: bash
-
- cd myproject
- spack setup myproject@local
- mkdir build; cd build
- ../spconfig.py ..
- make
- make install
-
-Notes:
- * Spack must have ``myproject/package.py`` in its repository for
- this to work.
- * ``spack setup`` produces the executable script ``spconfig.py`` in
- the local directory, and also creates the module file for the
- package. ``spconfig.py`` is normally run from the user's
- out-of-source build directory.
- * The version number given to ``spack setup`` is arbitrary, just
- like ``spack diy``. ``myproject/package.py`` does not need to
- have any valid downloadable versions listed (typical when a
- project is new).
- * spconfig.py produces a CMake configuration that *does not* use the
- Spack wrappers. Any resulting binaries *will not* use RPATH,
- unless the user has enabled it. This is recommended for
- development purposes, not production.
- * ``spconfig.py`` is human readable, and can serve as a developer
- reference of what dependencies are being used.
- * ``make install`` installs the package into the Spack repository,
- where it may be used by other Spack packages.
- * CMake-generated makefiles re-run CMake in some circumstances. Use
- of ``spconfig.py`` breaks this behavior, requiring the developer
- to manually re-run ``spconfig.py`` when a ``CMakeLists.txt`` file
- has changed.
-
-CMakePackage
-~~~~~~~~~~~~
-
-In order ot enable ``spack setup`` functionality, the author of
-``myproject/package.py`` must subclass from ``CMakePackage`` instead
-of the standard ``Package`` superclass. Because CMake is
-standardized, the packager does not need to tell Spack how to run
-``cmake; make; make install``. Instead the packager only needs to
-create (optional) methods ``configure_args()`` and ``configure_env()``, which
-provide the arguments (as a list) and extra environment variables (as
-a dict) to provide to the ``cmake`` command. Usually, these will
-translate variant flags into CMake definitions. For example:
-
-.. code-block:: python
-
- def configure_args(self):
- spec = self.spec
- return [
- '-DUSE_EVERYTRACE=%s' % ('YES' if '+everytrace' in spec else 'NO'),
- '-DBUILD_PYTHON=%s' % ('YES' if '+python' in spec else 'NO'),
- '-DBUILD_GRIDGEN=%s' % ('YES' if '+gridgen' in spec else 'NO'),
- '-DBUILD_COUPLER=%s' % ('YES' if '+coupler' in spec else 'NO'),
- '-DUSE_PISM=%s' % ('YES' if '+pism' in spec else 'NO')]
-
-If needed, a packager may also override methods defined in
-``StagedPackage`` (see below).
-
-
-StagedPackage
-~~~~~~~~~~~~~
-
-``CMakePackage`` is implemented by subclassing the ``StagedPackage``
-superclass, which breaks down the standard ``Package.install()``
-method into several sub-stages: ``setup``, ``configure``, ``build``
-and ``install``. Details:
-
-* Instead of implementing the standard ``install()`` method, package
- authors implement the methods for the sub-stages
- ``install_setup()``, ``install_configure()``,
- ``install_build()``, and ``install_install()``.
-
-* The ``spack install`` command runs the sub-stages ``configure``,
- ``build`` and ``install`` in order. (The ``setup`` stage is
- not run by default; see below).
-* The ``spack setup`` command runs the sub-stages ``setup``
- and a dummy install (to create the module file).
-* The sub-stage install methods take no arguments (other than
- ``self``). The arguments ``spec`` and ``prefix`` to the standard
- ``install()`` method may be accessed via ``self.spec`` and
- ``self.prefix``.
-
-GNU Autotools
-~~~~~~~~~~~~~
-
-The ``setup`` functionality is currently only available for
-CMake-based packages. Extending this functionality to GNU
-Autotools-based packages would be easy (and should be done by a
-developer who actively uses Autotools). Packages that use
-non-standard build systems can gain ``setup`` functionality by
-subclassing ``StagedPackage`` directly.
-
diff --git a/lib/spack/docs/spack_workflows.rst b/lib/spack/docs/spack_workflows.rst
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+Spack Workflows
+===============================
+
+The process of using Spack involves building packages, running
+binaries from those packages, and developing software that depends on
+those packages. For example, one might use Spack to build the
+`netcdf` package, use `spack load` to run the `ncdump` binary, and
+finally, write a small C program to read/write a particular NetCDF file.
+
+Spack supports a variety of workflows to suit a variety of situaions
+and user preferences, there is no single way to do all these things.
+This chapter demonstrates different workflows that have been
+developed, pointing out the pros and cons of them.
+
+
+Definitions
+############
+
+First some basic definitions.
+
+Package, Concrete Spec, Installed Package
+------------------------------------------
+
+In Spack, a package is an abstract recipe to build one piece of software.
+Spack packages may be used to build, in principle, any version of that
+software with any set of variants. Examples of packages include
+``curl`` and ``zlib``.
+
+A package may be *instantiated* to produce a concrete spec; one
+possible realization of a particular package, out of combinatorially
+many other realizations. For example, here is a concrete spec
+instantiated from ``curl``:
+
+.. code-block:: sh
+
+ curl@7.50.1%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^openssl@system%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^zlib@1.2.8%gcc@5.3.0 arch=linux-SuSE11-x86_64
+
+Spack's core concretization algorithm generates concrete specs by
+instantiating packages from its repo, based on a set of "hints",
+including user input and the ``packages.yaml`` file. This algorithm
+may be accessed at any time with the ``spack spec`` command. For
+example:
+
+.. code-block:: sh
+
+ $ spack spec curl
+ curl@7.50.1%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^openssl@system%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^zlib@1.2.8%gcc@5.3.0 arch=linux-SuSE11-x86_64
+
+Every time Spack installs a package, that installation corresponds to
+a concrete spec. Only a vanishingly small fraction of possible
+concrete specs will be installed at any one Spack site.
+
+Consistent Sets
+----------------
+
+A set of Spack specs is said to be *consistent* if each package is
+only instantiated one way within it --- that is, if two specs in the
+set have the same package, then they must also have the same version,
+variant, compiler, etc. For example, the following set is consistent:
+
+.. code-block:: sh
+
+ curl@7.50.1%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^openssl@system%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^zlib@1.2.8%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ zlib@1.2.8%gcc@5.3.0 arch=linux-SuSE11-x86_64
+
+The following set is not consistent:
+
+.. code-block:: sh
+
+ curl@7.50.1%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^openssl@system%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ ^zlib@1.2.8%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ zlib@1.2.7%gcc@5.3.0 arch=linux-SuSE11-x86_64
+
+The compatibility of a set of installed packages determines what may
+be done with it. It is always possible to ``spack load`` any set of
+installed packages, whether or not they are consistent, and run their
+binaries from the command line. However, a set of installed packages
+can only be linked together in one binary if it is consistent.
+
+If the user produces a series of `spack spec` or `spack load`
+commands, in general there is no guarantee of consistency between
+them. Spack's concretization procedure guarantees that the results of
+any *single* `spack spec` call will be consistent. Therefore, the
+best way to ensure a consistent set of specs is to create a Spack
+package with dependencies, and then instantiate that package. We will
+use this technique below.
+
+
+Building Packages
+##################
+
+Suppose you are tasked with installing a set of software packages on a
+system in order to support one application -- both a core application
+program, plus software to prepare input and analyze output. The
+required software might be summed up as a series of ``spack install``
+commands in a script. If needed, this script can always be run again
+in the future. For example:
+
+.. code-block::
+
+ spack install modele-utils
+ spack install emacs
+ spack install ncview
+ spack install nco
+ spack install modele-control
+ spack install py-numpy
+
+In most cases, this script will not correctly install software
+according to your specific needs: choices need to be made for
+variants, versions and virtual dependency choices may be needed. It
+*is* possible to specify these choices by extending specs on the
+command line; however, the same choices must be specified repeatedly.
+For example, if you wish to use ``openmpi`` to satisfy the ``mpi``
+dependency, then ``^openmpi`` will have to appear on *every* ``spack
+install`` line that uses MPI. It can get repetitve fast.
+
+Custimizing Spack installation options is easier to do in the
+``~/.spack/packages.yaml`` file. In this file, you can specify
+preferred versions and variants to use for packages. For exmaple:
+
+.. code-block:: yaml
+
+ packages:
+ python:
+ version: [3.5.1]
+ modele-utils:
+ version: [cmake]
+
+ everytrace:
+ version: [develop]
+ eigen:
+ variants: ~suitesparse
+ netcdf:
+ variants: +mpi
+
+ all:
+ compiler: [gcc@5.3.0]
+ providers:
+ mpi: [openmpi]
+ blas: [openblas]
+ lapack: [openblas]
+
+
+This approach will work as long as you are building packages for just
+one application.
+
+Multiple Applications
+-----------------------
+
+Suppose instead you're building multiple inconsistent applications.
+For example, users want package A to be built with ``openmpi`` and
+package B with ``mpich`` --- but still share many other lower-level
+dependencies. In this case, a single ``packages.yaml`` file will not
+work. Plans are to implement *per-project* ``packages.yaml`` files.
+In the meantime, one could write shell scripts to switch
+``packages.yaml`` between multiple versions as needed, using symlinks.
+
+
+Combinatorial Sets
+--------------------------
+
+Suppose that you are now tasked with systematically building many
+incompatible versions of packages. For example, you need to build
+``petsc`` 9 times for 3 different MPI implementations on 3 different
+compilers, in order to support user needs. In this case, you will
+need to either create 9 different ``packages.yaml`` files; or more
+likely, create 9 different ``spack install`` command lines with the
+correct options in the spec.
+
+
+
+Loading Packages
+#################
+
+Once Spack packages have been built, the next step is to use them. As
+with buiding packages, there are many ways to use them, depending on
+the use case.
+
+Simple Loads
+--------------
+
+Suppose that Spack has been used to install a set of command-line
+programs, which users now wish to use. One can in principle put a
+number of ``spack load`` commands into ``.bashrc``, for example:
+
+.. code-block::
+
+ spack load modele-utils
+ spack load emacs
+ spack load ncview
+ spack load nco
+ spack load modele-control
+
+Although simple load scripts like this are useful in many cases, the
+have some drawbacks:
+
+1. The set of modules loaded by them will in general not be
+ consistent. They are a decent way to load commands to be called
+ from command shells. See below for better ways to assemble a
+ consistent set of packages for building application programs.
+
+2. The ``spack spec`` and ``spack install`` commands use a
+ sophisticated concretization algorithm that chooses the "best"
+ among several options, taking into account ``packages.yaml`` file.
+ The ``spack load`` and ``spack module loads`` commands, on the
+ other thand, are not very smart: if the user-supplied spec matches
+ more than one installed package, then ``spack module loads`` will
+ fail. This may change in the future. For now, the workaround is to
+ be more specific on any ``spack module loads`` lines that fail.
+
+
+Cached Simple Loads
+----------------------
+
+Anoter problem with using `spack load` is, it is slow; a typical user
+environment could take several seconds to load, and would not be
+appropriate to put into ``.bashrc`` directly. It is preferable to use
+a series of ``spack module loads`` commands to pre-compute which
+modules to load. These can be put in a script that is run whenever
+installed Spack packages change. For example:
+
+.. code-block:: sh
+ #!/bin/sh
+ #
+ # Generate module load commands in ~/env/spackenv
+
+ cat <<EOF | /bin/sh >$HOME/env/spackenv
+ FIND='spack module loads --prefix linux-SuSE11-x86_64/'
+
+ \$FIND modele-utils
+ \$FIND emacs
+ \$FIND ncview
+ \$FIND nco
+ \$FIND modele-control
+ EOF
+
+The output of this file is written in ``~/env/spackenv``:
+
+.. code-block:: sh
+
+ # binutils@2.25%gcc@5.3.0+gold~krellpatch~libiberty arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/binutils-2.25-gcc-5.3.0-6w5d2t4
+ # python@2.7.12%gcc@5.3.0~tk~ucs4 arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/python-2.7.12-gcc-5.3.0-2azoju2
+ # ncview@2.1.7%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/ncview-2.1.7-gcc-5.3.0-uw3knq2
+ # nco@4.5.5%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/nco-4.5.5-gcc-5.3.0-7aqmimu
+ # modele-control@develop%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/modele-control-develop-gcc-5.3.0-7rddsij
+ # zlib@1.2.8%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/zlib-1.2.8-gcc-5.3.0-fe5onbi
+ # curl@7.50.1%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/curl-7.50.1-gcc-5.3.0-4vlev55
+ # hdf5@1.10.0-patch1%gcc@5.3.0+cxx~debug+fortran+mpi+shared~szip~threadsafe arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/hdf5-1.10.0-patch1-gcc-5.3.0-pwnsr4w
+ # netcdf@4.4.1%gcc@5.3.0~hdf4+mpi arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/netcdf-4.4.1-gcc-5.3.0-rl5canv
+ # netcdf-fortran@4.4.4%gcc@5.3.0 arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/netcdf-fortran-4.4.4-gcc-5.3.0-stdk2xq
+ # modele-utils@cmake%gcc@5.3.0+aux+diags+ic arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/modele-utils-cmake-gcc-5.3.0-idyjul5
+ # everytrace@develop%gcc@5.3.0+fortran+mpi arch=linux-SuSE11-x86_64
+ module load linux-SuSE11-x86_64/everytrace-develop-gcc-5.3.0-p5wmb25
+
+Users may now put ``source ~/env/spackenv`` into ``.bashrc``.
+
+.. note ::
+
+ Some module systems put a prefix on the names of modules created
+ by Spack. For example, that prefix is ``linux-SuSE11-x86_64/`` in
+ the above case. If a prefix is not needed, you may omit the
+ ``--prefix`` flag from ``spack module loads``.
+
+
+Transitive Dependencies
+---------------------------
+
+In the script above, each ``spack module loads`` command generates a
+*single* ``module load`` line. Transitive dependencies do not usually
+need to be load, only modules the user needs in in ``$PATH``. This is
+because Spack builds binaries with RPATH. Spack's RPATH policy has
+some nice features:
+
+ 1. Modules for multiple inconsistent applications may be loaded
+ simultaneously. In the above example (Multiple Applications),
+ package A and package B can coexist together in the user's $PATH,
+ even though they use different MPIs.
+
+ 2. RPATH eliminates a whole class of strange errors that can happen
+ in non-RPATH binaries when the wrong ``LD_LIBRARY_PATH`` is
+ loaded.
+
+ 3. Recursive module systems such as LMod are not necessary.
+
+ 4. Modules are not needed at all to execute binaries. If a path to a
+ binary is known, it may be executed. For example, the path for a
+ Spack-built compiler can be given to an IDE without requiring the
+ IDE to load that compiler's module.
+
+Unfortunately, Spacks' RPATH support does not work in all case. For example:
+
+ 1. Software comes in many forms --- not just compiled ELF binaries,
+ but also as interpreted code in Python, R, JVM bytecode, etc.
+ Those systems almost universally use an environment variable
+ analogous to ``LD_LIBRARY_PATH`` to dynamically load libraries.
+
+ 2. Although Spack generally builds binaries with RPATH, it does not
+ currently do so for compiled Python extensions (for example,
+ ``py-numpy``). Any libraries that these extensions depend on
+ (``openblas`` in this case, for example) must be specified in the
+ ``LD_LIBRARY_PATH``.`
+
+ 3. In some cases, Spack-generated binaries end up without a
+ functional RPATH for no discernable reason.
+
+In cases where RPATH support doesn't make things "just work," it can
+be necessary to load a module's dependencies as well as the module
+itself. This is done by adding the ``--dependencies`` flag to the
+``spack module loads`` command. For example, the following line,
+added to the script above, would be used to load Numpy, along with
+core Python, Setup TOols and a number of other packages:
+
+.. code-block:: sh
+ \$FIND --dependencies py-numpy
+
+Extension Packages
+---------------------
+
+Extensions (::ref:`packaging_extension` section) may be used as as an
+alternative to loading Python packages directly. If extensions are
+activated, then ``spack load python`` will also load all the
+extensions activated for the given ``python``. However, Spack
+extensions have two potential drawbacks:
+
+1. Activated packages that involve compiled C extensions may still
+ need their dependencies to be loaded manually. For example,
+ ``spack load openblas`` might be required to make ``py-numpy``
+ work.
+
+2. Extensions "break" a core feature of Spack, which is that multiple
+ versions of a package can co-exist side-by-side. For example,
+ suppose you wish to run a Python in two different environments but
+ the same basic Python --- one with ``py-numpy@1.7`` and one with
+ ``py-numpy@1.8``. Spack extensions will not support this potential
+ debugging use case.
+
+
+
+Filesystem Views
+-------------------------------
+
+The above
+
+.. Maybe this is not the right location for this documentation.
+
+The Spack installation area allows for many package installation trees
+to coexist and gives the user choices as to what versions and variants
+of packages to use. To use them, the user must rely on a way to
+aggregate a subset of those packages. The section on Environment
+Modules gives one good way to do that which relies on setting various
+environment variables. An alternative way to aggregate is through
+**filesystem views**.
+
+A filesystem view is a single directory tree which is the union of the
+directory hierarchies of the individual package installation trees
+that have been included. The files of the view's installed packages
+are brought into the view by symbolic or hard links back to their
+location in the original Spack installation area. As the view is
+formed, any clashes due to a file having the exact same path in its
+package installation tree are handled in a first-come-first-served
+basis and a warning is printed. Packages and their dependencies can
+be both added and removed. During removal, empty directories will be
+purged. These operations can be limited to pertain to just the
+packages listed by the user or to exclude specific dependencies and
+they allow for software installed outside of Spack to coexist inside
+the filesystem view tree.
+
+By its nature, a filesystem view represents a particular choice of one
+set of packages among all the versions and variants that are available
+in the Spack installation area. It is thus equivalent to the
+directory hiearchy that might exist under ``/usr/local``. While this
+limits a view to including only one version/variant of any package, it
+provides the benefits of having a simpler and traditional layout which
+may be used without any particular knowledge that its packages were
+built by Spack.
+
+Views can be used for a variety of purposes including:
+
+- A central installation in a traditional layout, eg ``/usr/local`` maintained over time by the sysadmin.
+- A self-contained installation area which may for the basis of a top-level atomic versioning scheme, eg ``/opt/pro`` vs ``/opt/dev``.
+- Providing an atomic and monolithic binary distribution, eg for delivery as a single tarball.
+- Producing ephemeral testing or developing environments.
+
+Using Filesystem Views
+~~~~~~~~~~~~~~~~~~~~~~
+
+A filesystem view is created and packages are linked in by the ``spack
+view`` command's ``symlink`` and ``hardlink`` sub-commands. The
+``spack view remove`` command can be used to unlink some or all of the
+filesystem view.
+
+The following example creates a filesystem view based
+on an installed ``cmake`` package and then removes from the view the
+files in the ``cmake`` package while retaining its dependencies.
+
+.. code-block:: sh
+
+
+ $ spack view -v symlink myview cmake@3.5.2
+ ==> Linking package: "ncurses"
+ ==> Linking package: "zlib"
+ ==> Linking package: "openssl"
+ ==> Linking package: "cmake"
+
+ $ ls myview/
+ bin doc etc include lib share
+
+ $ ls myview/bin/
+ captoinfo clear cpack ctest infotocap openssl tabs toe tset
+ ccmake cmake c_rehash infocmp ncurses6-config reset tic tput
+
+ $ spack view -v -d false rm myview cmake@3.5.2
+ ==> Removing package: "cmake"
+
+ $ ls myview/bin/
+ captoinfo c_rehash infotocap openssl tabs toe tset
+ clear infocmp ncurses6-config reset tic tput
+
+
+Limitations of Filesystem Views
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+This section describes some limitations that should be considered in
+using filesystems views.
+
+Filesystem views are merely organizational. The binary executable
+programs, shared libraries and other build products found in a view
+are mere links into the "real" Spack installation area. If a view is
+built with symbolic links it requires the Spack-installed package to
+be kept in place. Building a view with hardlinks removes this
+requirement but any internal paths (eg, rpath or ``#!`` interpreter
+specifications) will still require the Spack-installed package files
+to be in place.
+
+.. FIXME: reference the relocation work of Hegner and Gartung.
+
+As described above, when a view is built only a single instance of a
+file may exist in the unified filesystem tree. If more than one
+package provides a file at the same path (relative to its own root)
+then it is the first package added to the view that "wins". A warning
+is printed and it is up to the user to determine if the conflict
+matters.
+
+It is up to the user to assure a consistent view is produced. In
+particular if the user excludes packages, limits the following of
+dependencies or removes packages the view may become inconsistent. In
+particular, if two packages require the same sub-tree of dependencies,
+removing one package (recursively) will remove its dependencies and
+leave the other package broken.
+
+
+
+Build System Configuration Support
+----------------------------------
+
+Imagine a developer creating a CMake-based (or Autotools) project in a local
+directory, which depends on libraries A-Z. Once Spack has installed
+those dependencies, one would like to run ``cmake`` with appropriate
+command line and environment so CMake can find them. The ``spack
+setup`` command does this conveniently, producing a CMake
+configuration that is essentially the same as how Spack *would have*
+configured the project. This can be demonstrated with a usage
+example:
+
+.. code-block:: bash
+
+ cd myproject
+ spack setup myproject@local
+ mkdir build; cd build
+ ../spconfig.py ..
+ make
+ make install
+
+Notes:
+ * Spack must have ``myproject/package.py`` in its repository for
+ this to work.
+ * ``spack setup`` produces the executable script ``spconfig.py`` in
+ the local directory, and also creates the module file for the
+ package. ``spconfig.py`` is normally run from the user's
+ out-of-source build directory.
+ * The version number given to ``spack setup`` is arbitrary, just
+ like ``spack diy``. ``myproject/package.py`` does not need to
+ have any valid downloadable versions listed (typical when a
+ project is new).
+ * spconfig.py produces a CMake configuration that *does not* use the
+ Spack wrappers. Any resulting binaries *will not* use RPATH,
+ unless the user has enabled it. This is recommended for
+ development purposes, not production.
+ * ``spconfig.py`` is human readable, and can serve as a developer
+ reference of what dependencies are being used.
+ * ``make install`` installs the package into the Spack repository,
+ where it may be used by other Spack packages.
+ * CMake-generated makefiles re-run CMake in some circumstances. Use
+ of ``spconfig.py`` breaks this behavior, requiring the developer
+ to manually re-run ``spconfig.py`` when a ``CMakeLists.txt`` file
+ has changed.
+
+CMakePackage
+~~~~~~~~~~~~
+
+In order ot enable ``spack setup`` functionality, the author of
+``myproject/package.py`` must subclass from ``CMakePackage`` instead
+of the standard ``Package`` superclass. Because CMake is
+standardized, the packager does not need to tell Spack how to run
+``cmake; make; make install``. Instead the packager only needs to
+create (optional) methods ``configure_args()`` and ``configure_env()``, which
+provide the arguments (as a list) and extra environment variables (as
+a dict) to provide to the ``cmake`` command. Usually, these will
+translate variant flags into CMake definitions. For example:
+
+.. code-block:: python
+
+ def configure_args(self):
+ spec = self.spec
+ return [
+ '-DUSE_EVERYTRACE=%s' % ('YES' if '+everytrace' in spec else 'NO'),
+ '-DBUILD_PYTHON=%s' % ('YES' if '+python' in spec else 'NO'),
+ '-DBUILD_GRIDGEN=%s' % ('YES' if '+gridgen' in spec else 'NO'),
+ '-DBUILD_COUPLER=%s' % ('YES' if '+coupler' in spec else 'NO'),
+ '-DUSE_PISM=%s' % ('YES' if '+pism' in spec else 'NO')]
+
+If needed, a packager may also override methods defined in
+``StagedPackage`` (see below).
+
+
+StagedPackage
+~~~~~~~~~~~~~
+
+``CMakePackage`` is implemented by subclassing the ``StagedPackage``
+superclass, which breaks down the standard ``Package.install()``
+method into several sub-stages: ``setup``, ``configure``, ``build``
+and ``install``. Details:
+
+* Instead of implementing the standard ``install()`` method, package
+ authors implement the methods for the sub-stages
+ ``install_setup()``, ``install_configure()``,
+ ``install_build()``, and ``install_install()``.
+
+* The ``spack install`` command runs the sub-stages ``configure``,
+ ``build`` and ``install`` in order. (The ``setup`` stage is
+ not run by default; see below).
+* The ``spack setup`` command runs the sub-stages ``setup``
+ and a dummy install (to create the module file).
+* The sub-stage install methods take no arguments (other than
+ ``self``). The arguments ``spec`` and ``prefix`` to the standard
+ ``install()`` method may be accessed via ``self.spec`` and
+ ``self.prefix``.
+
+GNU Autotools
+~~~~~~~~~~~~~
+
+The ``setup`` functionality is currently only available for
+CMake-based packages. Extending this functionality to GNU
+Autotools-based packages would be easy (and should be done by a
+developer who actively uses Autotools). Packages that use
+non-standard build systems can gain ``setup`` functionality by
+subclassing ``StagedPackage`` directly.
+