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// file      : doc/manual.cli
// copyright : Copyright (c) 2014-2017 Code Synthesis Ltd
// license   : MIT; see accompanying LICENSE file

"\name=build2-build-system-manual"
"\subject=build system"
"\title=Build System"

// NOTES
//
// - Maximum <pre> line is 70 characters.
//

"
\h0#preface|Preface|

This is the preface.

\h1#name-patterns|Name Patterns|

For convenience, in certain contexts, names can be generated with shell-like
wildcard patterns. A name is a \i{name pattern} if its value contains one or
more unquoted wildcard characters or character sequences. For example:

\
./: */                     # All (immediate) subdirectories
exe{hello}: {hxx cxx}{**}  # All C++ header/source files.
pattern = '*.txt'          # Literal '*.txt'.
\

Pattern-based name generation is not performed in certain contexts.
Specifically, it is not performed in target names where it is interpreted
as a pattern for target type/pattern-specific variable assignments. For
example.

\
s = *.txt             # Variable assignment (performed).
./: cxx{*}            # Prerequisite names (performed).
cxx{*}: dist = false  # Target pattern (not performed).
\

In contexts where it is performed, it can be inhibited with quoting, for
example:

\
pat = 'foo*bar'
./: cxx{'foo*bar'}
\

The following characters are wildcards:

\
*  - match any number of characters (including zero)
?  - match any single character
\

If a pattern ends with a directory separator, then it only matches
directories. Otherwise, it only matches files. Matches that start with a dot
(\c{.}) are automatically ignored unless the pattern itself also starts with
this character.

In addition to the above wildcard characters, \c{**} and \c{***} are
recognized as wildcard character sequences. If a pattern contains \c{**}, then
it is matched just like \c{*} but in all the subdirectories, recursively. The
\c{***} wildcard behaves like \c{**} but also matches the start directory
itself. For example:

\
exe{hello}: cxx{**}  # All C++ source files recursively.
\

A group-enclosed (\c{{\}}) pattern value may be followed by
inclusion/exclusion patterns/matches. A subsequent value is treated as an
inclusion or exclusion if it starts with a literal, unquoted plus (\c{+}) or
minus (\c{-}) sign, respectively. In this case the remaining group values, if
any, must all be inclusions or exclusions. If the second value doesn't start
with a plus or minus, then all the group values are considered independent
with leading pluses and minuses not having any special meaning. For example:

\
exe{hello}: cxx{f* -foo}           # Exclude foo if present.
exe{hello}: cxx{f* +foo}           # Include foo if not present.
exe{hello}: cxx{f* -fo?}           # Exclude foo and fox if present.
exe{hello}: cxx{f* +b* -foo -bar}  # Exclude foo and bar if present.
exe{hello}: cxx{f* b* -z*}         # Names matching three patterns.
\

Inclusions and exclusions are applied in the order specified and only to the
result produced up to that point. The order of names in the result is
unspecified. However, it is guaranteed not to contain duplicates. The
pattern and the following inclusions/exclusions must be consistent with
regards to the type of filesystem entry they match. That is, they should
all match either files or directories. For example:

\
exe{hello}: cxx{f* -foo +*oo}  # Exclusion has no effect.
exe{hello}: cxx{f* +*oo}       # Ok, no duplicates.
./: {*/ -build}                # Error: exclusion not a directory.
\

As a more realistic example, let's say we want to exclude source files that
reside in the \c{test/} directories (and their subdirectories) anywhere in
the tree. This can be achieved with the following pattern:

\
exe{hello}: cxx{** -***/test/**}
\

Similarly, if we wanted to exclude all source files that have the \c{-test}
suffix:

\
exe{hello}: cxx{** -**-test}
\

In contrast, the following pattern only excludes such files from the top
directory:

\
exe{hello}: cxx{** -*-test}
\

If many inclusions or exclusions need to be specified, then an
inclusion/exclusion group can be used. For example:

\
exe{hello}: cxx{f* -{foo bar}}  # Exclude foo and bar if present.
\

This is particularly useful if you would like to list the names to exclude
in a variable. For example, this is how we can exclude certain files from
compilation but still include them as ordinary file prerequisites (so that
they are still included into the distribution):

\
exc = foo.cxx bar.cxx
exe{hello}: cxx{f* -{$exc}} file{$exc}
\

One common situation that calls for exclusions is auto-generated source
code. Let's say we have auto-generated command line parser in \c{options.hxx}
and \c{options.cxx}. Because of the in-tree builds, our name pattern may or
may not find these files. Note, however, that we cannot just include them as
non-pattern prerequisites. We also have to exclude them from the pattern match
since otherwise we may end up with duplicate prerequisites. As a result, this
is how we have to handle this case provided we want to continue using patterns
to find other, non-generated source files:

\
exe{hello}: {hxx cxx}{* -options} {hxx cxx}{options}
\

If the name pattern includes an absolute directory, then the pattern match is
performed in that directory and the generated names include absolute
directories as well. Otherwise, the pattern match is performed in the
\i{pattern base} directory. In buildfiles this is \c{src_base} while on the
command line \- the current working directory. In this case the generated
names are relative to the base directory. For example, assuming we have the
\c{foo.cxx} and \c{b/bar.cxx} source files:

\
exe{hello}: $src_base/cxx{**}  # $src_base/cxx{foo} $src_base/b/cxx{bar}
exe{hello}:           cxx{**}  #           cxx{foo}           b/cxx{bar}
\

Pattern matching as well as inclusion/exclusion logic is target
type-specific. If the name pattern does not contain a type, then the
\c{dir{\}} type is assumed if the pattern ends with a directory separator and
\c{file{\}} otherwise.

For the \c{dir{\}} target type the trailing directory separator is added to
the pattern and all the inclusion/exclusion patterns/matches that do not
already end with one. Then the filesystem search is performed for matching
directories. For example:

\
./: dir{* -build}  # Search for */, exclude build/.
\

For the \c{file{\}} and \c{file{\}}-based target types the default extension
(if any) is added to the pattern and all the inclusion/exclusion
patterns/matches that do not already contain an extension. Then the filesystem
search is performed for matching files.

For example, the \c{cxx{\}} target type obtains the default extension from the
\c{extension} variable. Assuming we have the following line in our
\c{root.build}:

\
cxx{*}: extension = cxx
\

And the following in our \c{buildfile}:

\
exe{hello}: {cxx}{* -foo -bar.cxx}
\

The pattern match will first search for all the files matching the \c{*.cxx}
pattern in \c{src_base} and then exclude \c{foo.cxx} and \c{bar.cxx} from the
result. Note also that target type-specific decorations are removed from the
result. So in the above example if the pattern match produces \c{baz.cxx},
then the prerequisite name is \c{cxx{baz\}}, not \c{cxx{baz.cxx\}}.

If the name generation cannot be performed because the base directory is
unknown, target type is unknown, or the target type is not directory or
file-based, then the name pattern is returned as is (that is, as an ordinary
name). Project-qualified names are never considered to be patterns.

\h1#grammar|Grammar|

\
eval:         '(' (eval-comma | eval-qual)? ')'
eval-comma:   eval-ternary (',' eval-ternary)*
eval-ternary: eval-or ('?' eval-ternary ':' eval-ternary)?
eval-or:      eval-and ('||' eval-and)*
eval-and:     eval-comp ('&&' eval-comp)*
eval-comp:    eval-value (('=='|'!='|'<'|'>'|'<='|'>=') eval-value)*
eval-value:   value-attributes? (<value> | eval | '!' eval-value)
eval-qual:    <name> ':' <name>

value-attributes: '[' <key-value-pairs> ']'
\

Note that \c{?:} (ternary operator) and \c{!} (logical not) are
right-associative. Unlike C++, all the comparison operators have the same
precedence. A qualified name cannot be combined with any other operator
(including ternary) unless enclosed in parentheses. The \c{eval} option
in the \c{eval-value} production shall contain single value only (no
commas).

\h1#module-test|Test Module|

The targets to be tested as well as the tests/groups from testscripts to be
run can be narrowed down using the \c{config.test} variable. While this
value is normally specified as a command line override (for example, to
quickly re-run a previously failed test), it can also be persisted in
\c{config.build} in order to create a configuration that will only run a
subset of tests by default. For example:

\
b test config.test=foo/exe{driver} # Only test foo/exe{driver} target.
b test config.test=bar/baz         # Only run bar/baz testscript test.
\

The \c{config.test} variable contains a list of \c{@}-separated pairs with the
left hand side being the target and the right hand side being the testscript
id path. Either can be omitted (along with \c{@}). If the value contains a
target type or ends with a directory separator, then it is treated as a target
name. Otherwise \- an id path. The targets are resolved relative to the root
scope where the \c{config.test} value is set. For example:

\
b test config.test=foo/exe{driver}@bar
\

To specify multiple id paths for the same target we can use the pair
generation syntax:

\
b test config.test=foo/exe{driver}@{bar baz}
\

If no targets are specified (only id paths), then all the targets are tested
(with the testscript tests to be run limited to the specified id paths). If no
id paths are specified (only targets), then all the testscript tests are run
(with the targets to be tested limited to the specified targets). An id path
without a target applies to all the targets being considered.

A directory target without an explicit target type (for example, \c{foo/}) is
treated specially. It enables all the tests at and under its directory. This
special treatment can be inhibited by specifying the target type explicitly
(for example, \c{dir{foo/\}}).


\h1#module-version|Version Module|

A project can use any version format as long as it meets the package version
requirements. The toolchain also provides additional functionality for
managing projects that conform to the \c{build2} \i{standard version}
format. If you are starting a new project that uses \c{build2}, you are
strongly encouraged to use this versioning scheme. It is based on much thought
and, often painful, experience. If you decide not to follow this advice, you
are essentially on your own when version management is concerned.

The standard \c{build2} project version conforms to \l{http://semver.org
Semantic Versioning} and has the following form:

\
<major>.<minor>.<patch>[-<prerel>]
\

For example:

\
1.2.3
1.2.3-a.1
1.2.3-b.2
\

The \c{build2} package version that uses the standard project version will
then have the following form (\i{epoch} is the versioning scheme version
and \i{revision} is the package revision):

\
[<epoch>~]<major>.<minor>.<patch>[-<prerel>][+<revision>]
\

For example:

\
1.2.3
1.2.3+1
1~1.2.3-a.1+2
\

The \i{major}, \i{minor}, and \i{patch} should be numeric values between \c{0}
and \c{999} and all three cannot be zero at the same time. For initial
development it is recommended to use \c{0} for \i{major}, start with version
\c{0.1.0}, and change to \c{1.0.0} once things stabilize.

In the context of C and C++ (or other compiled languages), you should
increment \i{patch} when making binary-compatible changes, \i{minor} when
making source-compatible changes, and \i{major} when making breaking changes.
While the binary compatibility must be set in stone, the source compatibility
rules can sometimes be bent. For example, you may decide to make a breaking
change in a rarely used interface as part of a minor release. Note also that
in the context of C++ deciding whether a change is binary-compatible is a
non-trivial task. There are resources that list the rules but no automated
tooling yet. If unsure, increment \i{minor}.

If present, the \i{prerel} component signifies a pre-release. Two types of
pre-releases are supported by the standard versioning scheme: \i{final} and
\i{snapshot} (non-pre-release versions are naturally always final). For final
pre-releases the \i{prerel} component has the following form:

\
(a|b).<num>
\

For example:

\
1.2.3-a.1
1.2.3-b.2
\

The letter '\c{a}' signifies an alpha release and '\c{b}' \- beta. The
alpha/beta numbers (\i{num}) should be between 1 and 499.

Note that there is no support for release candidates. Instead, it is
recommended that you use later-stage beta releases for this purpose (and, if
you wish, call them \"release candidates\" in announcements, etc).

What version should be used during development? The common approach is to
increment to the next version and use that until the release. This has one
major drawback: if we publish intermediate snapshots (for example, for
testing) they will all be indistinguishable both between each other and, even
worse, from the final release. One way to remedy this is to increment the
pre-release number before each publication. However, unless automated, this
will be burdensome and error-prone. Also, there is a real possibility of
running out of version numbers if, for example, we do continuous integration
by testing (and therefore publishing) each commit.

To address this, the standard versioning scheme supports \i{snapshot
pre-releases} with the \i{prerel} component having the following form:

\
(a|b).<num>.<snapsn>[.<snapid>]
\

For example:

\
1.2.3-a.1.1422564055.340c0a26a5efed1f
\

In essence, a snapshot pre-release is after the previous final release but
before the next (\c{a.1} and, perhaps, \c{a.2} in the above example) and
is uniquely identified by the snapshot sequence number (\i{snapsn}) and
snapshot id (\i{snapid}).

The \i{num} component has the same semantics as in the final pre-releases
except that it can be \c{0}. The \i{snapsn} component should be either the
special value '\c{z}' or a numeric, non-zero value that increases for each
subsequent snapshot. It must fit into an unsigned 64-bit integer. The
\i{snapid} component, if present, should be an alpha-numeric value that
uniquely identifies the snapshot. It is not required for version comparison
(\i{snapsn} should be sufficient) and is included for reference. It must not
be longer than 16 characters.

Where do the snapshot sn and id come from? Normally from the version control
system. For example, for \c{git}, \i{snapsn} is the commit date (as UNIX
timestamp in the UTC timezone) and \i{snapid} is a 16-character abbreviated
commit id. As discussed below, the \c{build2} \c{version} module extracts
and manages all this information automatically (the use of \c{git} commit
dates is not without limitations; see below for details).

The special '\c{z}' \i{snapsn} value identifies the \i{latest} or
\i{uncommitted} snapshot. It is chosen to be greater than any other possible
\i{snapsn} value and its use is discussed further below.

As an illustration of this approach, let's examine how versions change
during the lifetime of a project:

\
0.1.0-a.0.z     # development after a.0
0.1.0-a.1       # pre-release
0.1.0-a.1.z     # development after a.1
0.1.0-a.2       # pre-release
0.1.0-a.2.z     # development after a.2
0.1.0-b.1       # pre-release
0.1.0-b.1.z     # development after b.1
0.1.0           # release
0.1.1-b.0.z     # development after b.0 (bugfix)
0.2.0-a.0.z     # development after a.0
0.1.1           # release (bugfix)
1.0.0           # release (jumped straight to 1.0.0)
...
\

As shown in the above example, there is nothing wrong with \"jumping\" to a
further version (for example, from alpha to beta, or from beta to release, or
even from alpha to release). We cannot, however, jump backwards (for example,
from beta back to alpha). As a result, a sensible strategy is to start with
\c{a.0} since it can always be upgraded (but not downgrade) at a later stage.

When it comes to the version control systems, the recommended workflow is as
follows: The change to the final version should be the last commit in the
(pre-)release. It is also a good idea to tag this commit with the project
version. A commit immediately after that should change the version to a
snapshot essentially \"opening\" the repository for development.

The project version without the snapshot part can be represented as a 64-bit
decimal value comparable as integers (for example, in preprocessor
directives). The integer representation has the following form:

\
AAABBBCCCDDDE

AAA - major
BBB - minor
CCC - patch
DDD - alpha / beta (DDD + 500)
E   - final (0) / snapshot (1)
\

If the \i{DDDE} value is not zero, then it signifies a pre-release. In this
case one is subtracted from the \i{AAABBBCCC} value. An alpha number is stored
in \i{DDD} as is while beta \- incremented by \c{500}. If \i{E} is \c{1}, then
this is a snapshot after \i{DDD}.

For example:

\
             AAABBBCCCDDDE
0.1.0        0000010000000
0.1.2        0000010010000
1.2.3        0010020030000
2.2.0-a.1    0020019990010
3.0.0-b.2    0029999995020
2.2.0-a.1.z  0020019990011
\

A project that uses standard versioning can rely on the \c{build2} \c{version}
module to simplify and automate version managements. The \c{version} module
has two primary functions: eliminate the need to change the version anywhere
except in the project's manifest file and automatically extract and propagate
the snapshot information (serial number and id).

The \c{version} module must be loaded in the project's \c{bootstrap.build}.
While being loaded, it reads the project's manifest and extracts its version
(which must be in the standard form). The version is then parsed and presented
as the following build system variables (which can be used in the buildfiles):

\
[string] version                     # 2~1.2.3-b.4.1234567.deadbeef+3

[string] version.project             # 1.2.3-b.4.1234567.deadbeef
[uint64] version.project_number      # 0010020025041
[string] version.project_id          # 1.2.3-b.4.deadbeef

[bool]   version.stub                # false (true for 0[+<revision>])

[uint64] version.epoch               # 2

[uint64] version.major               # 1
[uint64] version.minor               # 2
[uint64] version.patch               # 3

[bool]   version.alpha               # false
[bool]   version.beta                # true
[bool]   version.pre_release         # true
[string] version.pre_release_string  # b.4
[uint64] version.pre_release_number  # 4

[bool]   version.snapshot            # true
[uint64] version.snapshot_sn         # 1234567
[string] version.snapshot_id         # deadbeef
[string] version.snapshot_string     # 1234567.deadbeef

[uint64] version.revision            # 3
\

As a convenience, the \c{version} module also extract the \c{summary} and
\c{url} manifest values and sets them as the following build system variables
(this additional information is used, for example, when generating the
\c{pkg-config} files):

\
[string] project.summary
[string] project.url
\

If the version is the latest snapshot (that is, it's in the \c{.z} form), then
the \c{version} module extracts the snapshot information from the version
control system used by the project. Currently only \c{git} is supported with
the following semantics.

If the project's source directory (\c{src_root}) is clean (that is, it does
not have any changed or untracked files), then the \c{HEAD} commit date and
id are used as the snapshot sn and id, respectively. Otherwise, the snapshot
is left in the \c{.z} form (which signals the latest/uncommitted
snapshot). While we can work with such a \c{.z} snapshot locally, preparing a
distribution of such an uncommitted snapshot is an error.

The use of \c{git} commit dates for snapshot ordering has its limitations:
they have one second resolution which means it is possible to create two
commits with the same date (but not the same commit id and thus snapshot
id). We also need all the committers to have a reasonably accurate
clock. Note, however, that in case of a commit date clash/ordering issue, we
still end up with distinct versions (because of the commit id) \- they are
just not ordered correctly. As a result, we feel that the risks are justified
when the only alternative is manual version management (which is always an
option, nevertheless).

When we prepare a distribution of a snapshot, the \c{version} module
automatically adjusts the package name to include the snapshot information as
well as patches the manifest file in the distribution with the snapshot sn and
id (that is, replacing \c{.z} in the version value with the actual snapshot
information). The result is a package that is specific to this commit.

Besides extracting the version information and making it available as
individual components, the \c{version} module also provide rules for
automatically generating the \c{version} (or \c{Version}/\c{VERSION}) file
that is customarily found in the root of a project as well as the version
headers (or other similar version-based files).

The \c{version} file rule matches a \c{doc} target that contains the
\c{version} substring in its name (comparison is case-insensitive) and that
depends on the project's \c{manifest} file. To utilize this rule you would
normally have something along these lines to your project's root \c{buildfile}:

\
./: ... doc{version}

doc{version}: file{manifest} # Generated by the version module.
doc{version}: dist = true    # Include into the distribution.
\

The \c{version} header rule pre-processes a template file (which means it can
be used to generate any kinds of files, not just C/C++ headers). It matches a
\c{file}-based target that has a corresponding \c{in} prerequisite and also
depends on the project's \c{manifest} file. As an example, let's assume we
want to auto-generate a header called \c{version.hxx} for our \c{libhello}
library. To acomplish this we add the \c{version.hxx.in} template as well as
something along these lines to our \c{buildfile}:

\
lib{hello}: ... hxx{version}

hxx{version}: in{version} $src_root/file{manifest}
hxx{version}: dist = true
\

The header rule is a line-based pre-processor that substitutes fragments
enclosed between (and including) a pair of dollar signs (\c{$}) with \c{$$}
being the escape sequence. As an example, let's assume our \c{version.hxx.in}
contains the following lines:

\
#ifndef LIBHELLO_VERSION

#define LIBHELLO_VERSION     $libhello.version.project_number$ULL
#define LIBHELLO_VERSION_STR \"$libhello.version.project$\"

#endif
\

If our \c{libhello} is at version \c{1.2.3}, then the generated
\c{version.hxx} will look like this:

\
#ifndef LIBHELLO_VERSION

#define LIBHELLO_VERSION     10020030000ULL
#define LIBHELLO_VERSION_STR \"1.2.3\"

#endif
\

The first component after the opening \c{$} should be either the name of the
project itself (like \c{libhello} above) or a name of one of its dependencies
as listed in the manifest. If it is the project itself, then the rest can
refer to one of the \c{version.*} variables that we discussed earlier (in
reality it can be any variable visible from the project's root scope).

If the name refers to one of the dependecies (that is, projects listed with
\c{depends:} in the manifest), then the following special substitutions are
recognized:

\
$<name>.version$                           - textual version constraint
$<name>.condition(<VERSION>[,<SNAPSHOT>])$ - numeric satisfaction condition
$<name>.check(<VERSION>[,<SNAPSHOT>])$     - numeric satisfaction check
\

Here \i{VERSION} is the version number macro and the optional \i{SNAPSHOT} is
the snapshot number macro. The snapshot is only required if you plan to
include snapshot information in your dependency constraints.

As an example, let's assume our \c{libhello} depends on \c{libprint} which
is reflected with the following line in our manifest:

\
depends: libprint >= 2.3.4
\

We also assume that \c{libprint} provides its version information in the
\c{libprint/version.hxx} header and uses analogous-named macros. Here
is how we can add a version check to our \c{version.hxx.in}:

\
#ifndef LIBHELLO_VERSION

#define LIBHELLO_VERSION     $libhello.version.project_number$ULL
#define LIBHELLO_VERSION_STR \"$libhello.version.project$\"

#include <libprint/version.hxx>

$libprint.check(LIBPRINT_VERSION)$

#endif
\

After the substitution our \c{version.hxx} header will look like this:

\
#ifndef LIBHELLO_VERSION

#define LIBHELLO_VERSION     10020030000ULL
#define LIBHELLO_VERSION_STR \"1.2.3\"

#include <libprint/version.hxx>

#ifdef LIBPRINT_VERSION
#  if !(LIBPRINT_VERSION >= 20030040000ULL)
#    error incompatible libprint version, libprint >= 2.3.4 is required
#  endif
#endif

#endif
\

The \c{version} and \c{condition} substitutions are the building blocks of the
\c{check} substitution. For example, here is how we can implement a check with
a customized error message:

\
#if !($libprint.condition(LIBPRINT_VERSION)$)
#  error bad libprint, need libprint $libprint.version$
#endif
\

The \c{version} module also treats one dependency in a special way: if you
specify the required version of the build system in your manifest, then the
module will automatically check it for you. For example, if we have the
following line in our manifest:

\
depends: * build2 >= 0.5.0
\

And someone tries to build our project with \c{build2} \c{0.4.0}, then they
will see an error like this:

\
build/bootstrap.build:3:1: error: incompatible build2 version
  info: running 0.4.0
  info: required 0.5.0
\

What version constraints should be use when depending on other project. We
start with a simple case where we depend on a release. Let's say \c{libprint}
\c{2.3.0} added a feature that we need in our \c{libhello}. If \c{libprint}
follows the source/binary compatibility guidelines discussed above, then
any \c{2.X.Y} version should work provided \c{X >= 3}. And this how we can
specify it in the manifest:

\
depends: libprint [2.3.0 3.0.0-)
\

Let's say we are now working on \c{libhello} \c{2.0.0} and would like to start
using features from \c{libprint} \c{3.0.0}. However, currently, only
pre-releases of \c{3.0.0} are available. If you would like to add a dependency
on a pre-release (most likely from your own pre-release), then the
recommendation is to only allow a specific version, essentially \"expiring\"
the combination as soon as newer versions become available. For example:

\
version: 2.0.0-b.1
depends: libprint == 3.0.0-b.2
\

Finally, let's assume we are feeling adventerous and would like to test
development snapshots of \c{libprint} (most likey from our own snapshots). In
this case the recommendation is to only allow a snapshot range for a specific
pre-release with the understanding and a warning that no compatibility between
snapshot versions is guaranteed. For example:

\
version: 2.0.0-b.1.z
depends: libprint [3.0.0-b.2.1 3.0.0-b.3)
\

\h1#module-cxx|\c{cxx} (C++) Module|

This chapter describes the \c{cxx} build system module which provides the C++
compilation and linking support. Most of its functionality, however, is
provided by the \c{cc} module, a common implementation for the C-family
languages.

\h#cxx-modules|C++ Modules Support|

This section describes the build system support for C++ modules.

\h2#cxx-modules-intro|Modules Introduction|

The goal of this section is to provide a practical introduction to C++ Modules
and to establish key concepts and terminology.

A pre-modules C++ program or library consists of one or more \i{translation
units} which are customarily referred to as C++ source files. Translation
units are compiled to \i{object files} which are then linked together to
form a program or library.

Let's also recap the difference between an \i{external name} and a \i{symbol}:
External names refer to language entities, for example classes, functions, and
so on. The \i{external} qualifier means they are visible across translation
units.

Symbols are derived from external names for use inside object files. They are
the cross-referencing mechanism for linking a program from multiple,
separately-compiled translation units. Not all external names end up becoming
symbols and symbols are often \i{decorated} with additional information, for
example, a namespace. We often talk about a symbol having to be satisfied by
linking an object file or a library that provides it.

What is a C++ module? It is hard to give a single but intuitive answer to this
question.  So we will try to answer it from three different perspectives: that
of a module consumer, a module producer, and a build system that tries to make
those two play nice. But we can make one thing clear at the outset: modules
are a \i{language-level} not a preprocessor-level mechanism; it is \c{import},
not \c{#import}.

One may also wonder why C++ modules, what are the benefits? Modules offer
isolation, both from preprocessor macros and other module's symbols. Unlike
headers, modules require explicit exportation of entities that will be visible
to the consumers. In this sense they are a \i{physical design mechanism} that
forces us to think how we structure our code. Modules promise significant
build speedups since importing a module, unlike including a header, should be
essentially free. Modules are also the first step to not needing the
preprocessor in most translation units. Finally, modules have a chance of
bringing to mainstream reliable and easy to setup distributed C++ compilation,
since now build systems can make sure compilers on the local and remote hosts
are provided with identical inputs.

To refer to a module we use a \i{module name}, a sequence of dot-separated
identifiers, for example \c{hello.core}. While the specification does not
assign any hierarchical semantics to this sequence, it is customary to refer
to \c{hello.core} as a submodule of \c{hello}. We discuss submodules and the
module naming guidelines below.

From a consumer's perspective, a module is a collection of external names,
called \i{module interface}, that become \i{visible} once the module is
imported:

\
import hello.core
\

What exactly does \i{visible} mean? To quote the standard: \i{An
import-declaration makes exported declarations [...] visible to name lookup in
the current translation unit, in the same namespaces and contexts [...]}. One
intuitive way to think about this visibility is \i{as-if} there were only a
single translation unit for the entire program that contained all the modules
as well as all their consumers. In such a translation unit all the names would
be visible to everyone in exactly the same way and no entity would be
redeclared.

This visibility semantics suggests that modules are not a name scoping
mechanism and are orthogonal to namespaces. Specifically, a module can export
names from any number of namespaces, including the global namespace. While the
module name and its namespace names need not be related, it usually makes
sense to have a parallel naming scheme, as discussed below. Finally, the
\c{import} declaration does not imply any additional visibility for names
declared inside namespaces and to access such names we must continue using the
standard mechanisms, such as qualification or using declaration/directive.
For example:

\
import hello.core;        // Exports hello::say().

say ();                   // Error.
hello::say ();            // Ok.

using namespace hello;
say ();                   // Ok.
\

Note also that from the consumer's perspective a module does not provide
any symbols, only C++ entity names. If we use a name from a module, then we
may have to satisfy the corresponding symbol(s) using the usual mechanisms:
link an object file or a library that provides them. In this respect, modules
are similar to headers and as with headers module's use is not limited to
libraries; they make perfect sense when structuring programs. Furthermore,
a library may also have private or implementation modules that are not
meant to be used by the library's users.

The producer perspective on modules is predictably more complex. In
pre-modules C++ we only had one kind of translation unit (or source
file). With modules there are three kinds: \i{module interface unit},
\i{module implementation unit}, and the original kind which we will
call a \i{non-module translation unit}.

From the producer's perspective, a module is a collection of module translation
units: one interface unit and zero or more implementation units. A simple
module may consist of just the interface unit that includes implementations
of all its functions (not necessarily inline). A more complex module may
span multiple implementation units.

A translation unit is a module interface unit if it contains an \i{exporting
module declaration}:

\
export module hello.core;
\

A translation unit is a module implementation unit if it contains a
\i{non-exporting module declaration}:

\
module hello.core;
\

While module interface units may use the same file extension as normal source
files, we recommend that a different extension be used to distinguish them as
such, similar to header files. While the compiler vendors suggest various (and
predictably different) extensions, our recommendation is \c{.mxx} for the
\c{.hxx/.cxx} source file naming and \c{.mpp} for \c{.hpp/.cpp}. And if you
are using some other naming scheme, perhaps now is a good opportunity to
switch to one of the above. Using the source file extension for module
implementation units appears reasonable and that's what we recommend.

A module declaration (exporting or non-exporting) starts a \i{module purview}
that extends until the end of the module translation unit. Any name declared
in a module's purview \i{belongs} to said module. For example:

\
#include <string>                // Not in purview.

export module hello.core;        // Start of purview.

void
say_hello (const std::string&);  // In purview.
\

A name that belongs to a module is \i{invisible} to the module's consumers
unless it is \i{exported}. A name can be declared exported only in a module
interface unit, only in the module's purview, and there are several syntactic
ways to accomplish this. We can start the declaration with the \c{export}
specifier, for example:

\
export module hello.core;

export enum class volume {quiet, normal, loud};

export void
say_hello (const char*, volume);
\

Alternatively, we can enclose one or more declarations into an \i{exported
group}, for example:

\
export module hello.core;

export
{
  enum class volume {quiet, normal, loud};

  void
  say_hello (const char*, volume);
}
\

Finally, if a namespace definition is declared exported, then every name
in its body is exported, for example:

\
export module hello.core;

export namespace hello
{
  enum class volume {quiet, normal, loud};

  void
  say (const char*, volume);
}

namespace hello
{
  void
  impl (const char*, volume); // Not exported.
}
\

Up until now we've only been talking about module's names. What about module's
symbols? For exported names, the resulting symbols would be the same as if
those names were declared outside of a module's purview (or as if no modules
were used at all). Non-exported names, on the other hand, have \i{module
linkage}: their symbols can be resolved from this module's units but not from
other translation units. They also cannot clash with symbols for identical
names from other modules (and non-modules). This is usually achieved by
decorating the non-exported symbols with a module name.

This ownership model has one important backwards-compatibility implication: a
library built with modules enabled can be linked to a program that still uses
headers. And vice versa: we can build and use a module for a library that was
built with headers.

What about the preprocessor? Modules do not export preprocessor macros,
only C++ names. A macro defined in the module interface unit cannot affect
the module's consumers. And macros defined by the module's consumers cannot
affect the module interface they are importing. In other words, module
producers and consumers are isolated from each other when the preprocessor
is concerned. This is not to say that the preprocessor cannot be used by
either, it just doesn't \"leak\" through the module interface. One practical
implication of this model is the insignificance of the import order.

If a module imports another module in its purview, the imported module's
names are not made automatically visible to the consumers of the importing
module. This is unlike headers and can be surprising. Consider this module
interface as an example:

\
export module hello;

import std.core;

export void
say_hello (const std::string&);
\

And this module consumer:

\
import hello;

int
main ()
{
  say_hello (\"World\");
}
\

This example will result in a compile error and the diagnostics may
confusingly indicate that there is no known conversion from a C string to
\"something\" called \c{std::string}. But with the understanding of the
difference between \c{import} and \c{#include} the reason should be clear:
while the module interface \"sees\" \c{std::string} (because it imported its
module), we do not (since we did not). So the fix is to explicitly import
\c{std.core}:

\
import std.core;
import hello;

int
main ()
{
  say_hello (\"World\");
}
\

A module, however, can choose to re-export a module it imports. In this case,
all the names from the imported module will also be visible to the importing
module's consumers. For example, with this change to the module interface the
first version of our consumer will compile without errors (note that whether
this is a good design choice is debatable):

\
export module hello;

export import std.core;

export void
say_hello (const std::string&);
\

One way to think of a re-export is \i{as-if} an import of a module also
\"injects\" all the imports said module re-exports, recursively. That's
essentially how most compilers implement it.

Module re-export is the mechanism for assembling bigger modules out of
submodules. As an example, let's say we had the \c{hello.core},
\c{hello.basic}, and \c{hello.extra} modules. To make life easier for users
that want to import all of them we can create the \c{hello} module that
re-exports the three:

\
export module hello;

export
{
  import hello.core;
  import hello.basic;
  import hello.extra;
}
\

Besides starting a module purview, a non-exporting module declaration in the
implemenation unit also makes non-internal linkage names declared or made
visible in the \i{interface purview} visible in the \i{implementation
purview}. In this sense non-exporting module declaration acts as an extended
\c{import}. For example:

\
import hello.impl;          // Not visible (exports impl()).

void
extra_impl ();              // Not visible.

export module hello.extra;  // Start of interface purview.

import hello.core;          // Visible (exports core()).

void
extra ();                   // visible.

static void
extra2 ();                  // Not visible (internal linkage).
\

And this is the implementation unit:

\
module hello.extra;         // Start of implementation purview.

void
f ()
{
  impl ();        // Error.
  extra_impl ();  // Error.
  core ();        // Ok.
  extra ();       // Ok.
  extra2 ();      // Error.
}
\

In particular, this means that while the relative order of imports is not
significant, the placement of imports in the module interface unit relative
to the module declaration can be.

The final perspective that we consider is that of the build system. From its
point of view the central piece of the module infrastructure is the \i{binary
module interface}: a binary file that is produced by compiling the module
interface unit and that is required when compiling any translation unit that
imports this module (as well as the module's implementation units).

So, in a nutshell, the main functionality of a build system when it comes to
modules support is figuring out the order in which all the translation units
should be compiled and making sure that every compilation is able to find the
binary module interfaces it needs.

Predictably, the details are more complex. Compiling a module interface unit
produces two outputs: the binary module interface and the object file. The
latter contains object code for non-inline functions, global variables, etc.,
that the interface unit may define. This object file has to be linked when
producing any binary (program or library) that uses this module.

Also, all the compilers currently implement module re-export as a shallow
reference to the re-exported module name which means that their binary
interfaces must be discoverable as well, recursively. In fact, currently, all
the imports are handled like this, though a different implementation is at
least plausible, if unlikely.

While the details vary between compilers, the contents of the module binary
interface can range from a stream of preprocessed tokens to something fairly
close to object code. As a result, binary interfaces can be sensitive to the
compiler options and if the options used to produce the binary interface (for
example, when building a library) are sufficiently different compared to the
ones used when compiling the module consumers, the binary interface may be
unusable. So while a build system should strive to reuse existing binary
interfaces, it should also be prepared to compile its own versions \"on the
side\".

This also suggests that binary module interfaces are not a distribution
mechanism and should probably not be installed. Instead, we should install and
distribute module interface sources and build systems should be prepared to
compile them, again, on the side.


\h2#cxx-modules-build|Building Modules|

Compiler support for C++ Modules is still experimental. As a result, it is
currently only enabled if the C++ standard is set to \c{experimental}. After
loading the \c{cxx} module we can check if modules are enabled using the
\c{cxx.features.modules} boolean variable. This is what the corresponding
\c{root.build} fragment could look like for a modularized project:

\
cxx.std = experimental

using cxx

assert $cxx.features.modules 'c++ compiler does not support modules'

mxx{*}: extension = mxx
cxx{*}: extension = cxx
\

To support C++ modules the \c{cxx} (build system) module defines several
additional target types. The \c{mxx{\}} target is a module interface unit.
As you can see from the above \c{root.build} fragment, in this project we
are using the \c{.mxx} extension for our module interface files. While
you can use the same extension as for \c{cxx{\}} (source files), this is
not recommended since some functionality, such as wildcard patterns, will
become unusable.

The \c{bmi{\}} group and its \c{bmie{\}}, \c{bmia{\}}, and \c{bmis{\}}
members are used for binary module interfaces targets. We normally do
not need to mention them explicitly in our buildfiles except, perhaps,
to specify additional, module interface-specific compile options. We
will see some example of this below.

To build a modularized executable or library we simply list the module
interfaces as its prerequisites, just as we do source files. As an example,
let's build the \c{hello} program that we have started in the introduction
(you can find the complete project in the \l{https://build2.org/pkg/hello
Hello Repository} under \c{mhello}). Specifically, we assume our project
contains the following files:

\
// file: hello.mxx (module interface)

export module hello;

import std.core;

export void
say_hello (const std::string&);
\

\
// file: hello.cxx (module implementation)

module hello;

import std.io;

using namespace std;

void
say_hello (const string& name)
{
  cout << \"Hello, \" << name << '!' << endl;
}
\

\
// file: driver.cxx

import std.core;
import hello;

int
main ()
{
  say_hello (\"World\");
}
\

To build a \c{hello} executable from these files we can write the following
\c{buildfile}:

\
exe{hello}: cxx{driver} {mxx cxx}{hello}
\

Or, if you prefer to use wildcard patterns:

\
exe{hello}: {mxx cxx}{*}
\

Alternatively, we can package the module into a library and then link the
library to the executable:

\
exe{hello}: cxx{driver} lib{hello}
lib{hello}: {mxx cxx}{hello}
\

As you might have surmised from the above, the modules support implementation
automatically resolves imports to module interface units that are specified
either as direct prerequisites or as prerequisites of library prerequisites.

To perform this resolution without a significant overhead, the implementation
delays the extraction of the actual module name from module interface units
(since not all available module interfaces are necessarily imported by all the
translation units). Instead, the implementation tries to guess which interface
unit implements each module being imported based on the interface file
path. Or, more precisely, a two-step resolution process is performed: first a
best match between the desired module name and the file path is sought and
then the actual module name is extracted and the correctness of the initial
guess is verified.

The practical implication of this implementation detail is that our module
interface files must embed a portion of a module name, or, more precisely, a
sufficient amount of \"module name tail\" to unambiguously resolve all the
modules used in a project. Note also that this guesswork is only performed for
direct module interface prerequisites; for those that come from libraries the
module names are known and are therefore matched exactly.

As an example, let's assume our \c{hello} project had two modules:
\c{hello.core} and \c{hello.extra}. While we could call our interface files
\c{hello.core.mxx} and \c{hello.extra.mxx}, respectively, this doesn't look
particularly good and may be contrary to the file naming scheme used in our
project. To resolve this issue the match of module names to file names is
made \"fuzzy\": it is case-insensitive, it treats all separators (dots, dashes,
underscores, etc) as equal, and it treats a case change as an imaginary
separator. As a result, the following naming schemes will all match the
\c{hello.core} module name:

\
hello-core.mxx
hello_core.mxx
HelloCore.mxx
hello/core.mxx
\

We also don't have to embed the full module name. In our case, for example, it
would be most natural to call the files \c{core.mxx} and \c{extra.mxx} since
they are already in the project directory called \c{hello/}. This will work
since our module names can still be guessed correctly and unambiguously.

If a guess turns out to be incorrect, the implementation issues diagnostics
and exits with an error. To resolve this situation we can either adjust the
interface file names or we can specify the module name explicitly with the
\c{cc.module_name} variable. The latter approach can be used with interface
file names that have nothing in common with module names, for example:

\
mxx{foobar}@./: cc.module_name = hello
\

Note also that standard library modules (\c{std} and \c{std.*}) are treated
specially: they are not fuzzy-matched and they need not be resolvable to
the corresponding \c{mxx{\}} or \c{bmi{\}} in which case it is assumed
they will be resolved in an ad hoc way by the compiler. This means that if
you want to build your own standard library module (for example, because
your compiler doesn't yet ship one; note that this may not be supported
by all compilers), then you have to specify the module name explicitly.
For example:

\
exe{hello}: cxx{driver} {mxx cxx}{hello} mxx{std-core}

mxx{std-core}@./: cc.module_name = std.core
\

When C++ modules are enabled and available, the build system makes sure the
\c{__cpp_modules} feature test macro is defined. Currently, its value is
\c{201703} for VC and \c{201704} for GCC and Clang but this will most likely
change in the future.

One major difference between the current C++ modules implementation in VC and
the other two compilers is the use of the \c{export module} syntax to identify
the interface units. While both GCC and Clang have adopted this new syntax,
VC is still using the old one without the \c{export} keyword. We can use the
\c{__cpp_modules} macro to provide a portable declaration:

\
#if __cpp_modules >= 201704
export
#endif
module hello;
\

Note, however, that the modules support in \c{build2} provides temporary
\"magic\" that allows us to use the new syntax even with VC.

\h2#cxx-modules-symexport|Module Symbols Exporting|

When building a shared library, some platforms (notably Windows) require that
we explicitly export symbols that must be accessible to the library users.
If you don't need to support such platforms, you can thank your lucky stars
and skip this section.

When using headers, the traditional way of achieving this is via an \"export
macro\" that is used to mark exported APIs, for example:

\
LIBHELLO_EXPORT void
say_hello (const string&);
\

This macro is then appropriately defined (often in a separate \"export
header\") to export symbols when building the shared library and to import
them when building the library's users.

Introduction of modules changes this in a number of ways, at least as
implemented by VC (hopefully other compilers will follow suit). While we
still have to explicitly mark exported symbols in our module interface
unit, there is no need (and, in fact, no way) to do the same when said
module is imported. Instead, the compiler automatically treats all
such explicitly exported symbols (note: symbols, not names) as imported.

One notable aspect of this new model is the locality of the export macro: it
is only defined when compiling the module interface unit and is not visible to
the consumers of the module. This is unlike headers where the macro has to
have a unique per-library name (that \c{LIBHELLO_} prefix) because a header
from one library can be included while building another library.

We can continue using the same export macro and header with modules and, in
fact, that's the recommended approach when maintaining dual, header/module
arrangements for backwards compatibility (discussed below). However, for
module-only codebases, we have an opportunity to improve the situation in two
ways: we can use a single, keyword-like macro instead of a library-specific
one and we can make the build system manage it for us thus getting rid of the
export header.

To enable this functionality in \c{build2} we set the
\c{cxx.features.symexport} boolean variable to \c{true} before loading the
\c{cxx} module. For example:

\
cxx.std = experimental

cxx.features.symexport = true

using cxx

...
\

Once enabled, \c{build2} automatically defines the \c{__symexport} macro to
the appropriate value depending on the platform and the type of library being
built. As library authors, all we have to do is use it in appropriate places
in our module interface units, for example:

\
export module hello;

import std.core;

export __symexport void
say_hello (const std::string&);
\

As an aside, you may be wondering why can't a module export automatically mean
a symbol export? While you will normally want to export symbols of all your
module-exported names, you may also need to do so for some non-module-exported
ones. For example:

\
export module foo;

__symexport void
f_impl ();

export __symexport inline void
f ()
{
  f_impl ();
}
\

Furthermore, symbol exporting is a murky area with many limitations and
pitfalls (such as auto-exporting of base classes). As a result, it would not
be unreasonable to expect such an automatic module exporting to only further
muddy the matter.


\h2#cxx-modules-install|Modules Installation|

As discussed in the introduction, binary module interfaces are not a
distribution mechanism and installing module interface sources appears to be
the preferred approach.

Module interface units are by default installed in the same location as
headers (for example, \c{/usr/include}). However, instead of relying on a
header-like search mechanism (\c{-I} paths, etc.), an explicit list of
exported modules is provided for each library in its \c{.pc} (\c{pkg-config})
file.

Specifically, the library's \c{.pc} file contains the \c{modules} variable
that lists all the exported modules in the \c{<name>=<path>} form with
\c{<name>} being the module's C++ name and \c{<path>} \- the module interface
file's absolute path. For example:

\
Name: libhello
Version: 1.0.0
Cflags:
Libs: -L/usr/lib -lhello

modules = hello.core=/usr/include/hello/core.mxx hello.extra=/usr/include/hello/extra.mxx
\

Additional module properties are specified with variables in the
\c{module_<property>.<name>} form, for example:

\
module_symexport.hello.core = true
module_preprocessed.hello.core = all
\

Currently, two properties are defined. The \c{symexport} property with the
boolean value signals whether the module uses the \c{__symexport} support
discussed above.

The \c{preprocessed} property indicates the degree of preprocessing the module
unit requires and is used to optimize module compilation. Valid values are
\c{none} (not preprocessed), \c{includes} (no \c{#include} directives in the
source), \c{modules} (as above plus no module declarations depend on the
preprocessor, for example, \c{#ifdef}, etc.), and \c{all} (the source is fully
preprocessed). Note that for \c{all} the source may still contain comments and
line continuations.


\h2#cxx-modules-guidelines|Modules Design Guidelines|

Modules are a physical design mechanism for structuring and organizing our
code. Their explicit exportation semantics combined with the way modules are
built makes many aspects of creating and consuming modules significantly
different compared to headers. This section provides basic guidelines for
designing modules. We start with the overall considerations such as module
granularity and partitioning into translation units then continue with the
structure of typical module interface and implementation units. The following
section disscusses practical approaches to modularizing existing code and
providing the dual, header/module interface for backwards-compatibility.

Unlike headers, the cost of importing modules should be negligible. As a
result, it may be tempting to create \"mega-modules\", for example, one per
library. After all, this is how the standard library is modularized with its
fairly large \c{std.core} and \c{std.io} modules.

There is, however, a significant drawback to going this route: every time we
make a change, all consumers of such a mega-module will have to be recompiled,
whether the change affects them or not. And the bigger the module the higher
the chance that the change does not affect a large portion of the consumers.
Note that this is not an issue for the standard library modules since they are
not expected to change often.

Another, more subtle, issue with mega-modules (which does affect the standard
library) is the inability to re-export only specific interfaces, as will be
discussed below.

The other extreme in choosing module granularity is a large number of
\"mini-modules\". Their main drawback is the tediousness of importation by the
consumers.

The sensible approach is then to create modules of conceptually-related and
commonly-used entities possibly together with aggregate modules for ease of
importation. Which also happens to be generally good design.

As an example, let's consider an XML library that provides support for both
parsing and serialization. Since it is common for applications to only use one
of the functionalities, it probably makes sense to provide the \c{xml.parser}
and \c{xml.serializer} modules. While it is not too tedious to import both,
for convenience we could also provide the \c{xml} module that re-exports the
other two.

Once we are past selecting an appropriate granularity for our modules, the
next question is how to partition them into translation units. A module can
consist of just the interface unit and, as discussed above, such a unit can
contain anything an implementation unit can, including non-inline function
definitions. Some then view this as an opportunity to get rid of the
header/source separation and have everything in a single file.

There are a number of drawbacks with this approach: Every time we change
anything in the module interface unit, all its consumers have to be
recompiled. If we keep everything in a single file, then every time we change
the implementation we will trigger a recompliations that would have been
avoided had the implementation been factored out into a separate unit.

Another issues is the readability of the interface which could be
significantly reduced if littered with implementation details. We could keep
the interface separate by moving the implementation to the bottom of the
interface file but then we might as well move it to a separate file and avoid
unnecessary recompilations.

The sensible guideline is then to have a separate module implementation unit
exept perhaps for modules with a simple implementation that is mostly
inline/template. Note that more complex modules may have sevaral
implementation units, however, based on our granularity guideline, those
should be fairly rare.

Once we start writing our first real module the immediate question that
ususally comes up is where to put \c{#include} directives and \c{import}
declarations and in what order. To recap, a module unit, both interface and
implementation, is split into two parts: before the module declaration which
obeys the usual or \"old\" translation unit rules and after the module
declaration which is the module purview. Inside the module purview all
non-exported declarations have module linkage which means their symbols are
invisible to any other module (including the global module). With this
understandig, consider the following module interface:

\
export module hello;

#include <string>
\

Do you see the problem? We have included \c{<string>} in the module purview
which means all its names (as well as all the names in any headers it might
include, recursively) are now declared as having the \c{hello} module linkage.
The result of doing this can range from silent code blot to strange-looking
unresolved symbols.

The guideline this leads to should be clear: including a header in module
purview is almost always a bad idea. There are, however, a few types of
headers that may make sense to include in the module purview. The first are
headers that only define preprocessor macros, for example, configuration or
export headers. There are also cases where we do want the included
declarations to end up in the module purview. The most common example is files
that contain inline/template function implementations that have been factored
out for code organization reasons. As an example, consider the following
module interface that uses an export headers (which sets up symbols exporting
macros) as well as an inline file:

\
#include <string>

export module hello;

#include <libhello/export.hxx>

export namespace hello
{
  ...
}

#include <libhello/hello.ixx>
\

A note on inline/template files: in header-based projects we could include
additional headers in those files, for example, if the included declarations
are only needed in the implementation. For the reason just discussed, this
won't work with modules and we have to move all the includes into the
interface file, before the module purview. On the other hand, with modules, it
is safe to use using-directives (for example, \c{using namespace std;}) in
inline/template files (and, with care, even in the interface file).

What about imports, where should we import other modules. Again, to recap,
unlike a header inclusing, an \c{import} declaration only makes exported names
visible without (re)declaring them. As result, in a module implementation
units, it doesn't really matter where we place imports, in or out of the
module purview. There are, however, two differences when it comes to module
interface units: only imports in the purview are visible to implementation
units and we can only re-export an imported module from the purview.

The guideline is then for interface units to import in the module purview
unless there is a good reason not to make the import visible to the
implementation units. And for implementation units is to always import in the
purview for consistency. For example:

\
#include <cassert>

export module hello;

import std.core;

#include <libhello/export.hxx>

export namespace hello
{
  ...
}

#include <libhello/hello.ixx>
\

Based on these guidelines we can also create a module interface unit template:

\
// Module interface unit.

<header includes>

export module <name>;      // Start of module purview.

<module imports>

<special header includes>  // Configuration, export, etc.

<module interface>

<inline/template includes>
\

As well as the module implementation unit template:

\
// Module implementation unit.

<header includes>

module <name>;             // Start of module purview.

<extra module imports>     // Only additional to interface.

<module implementation>
\

Let's also discuss module naming. Module names are in a separate \"name
plane\" and do not collide with namespace, type, or function names. Also, as
mentioned earlier, the standard does not assign a hierarchical meaning to
module names though it is customary to assume that module \c{hello.core}
is a submodule of \c{hello} and importing the latter also imports the
former.

It is important to choose good names for public modules (that is, modules
packaged into libraries and used by a wide range of consumers) since changing
them later can be costly. We have more leeway with naming private modules
(that is, the ones used by programs or internal to the libraries) though it's
worth it to come up with a consistent naming scheme here as well.

The general guideline is to start names of public modules with the library's
namespace name followed by a name describing the module's functionality. In
particular, if a module is dedicated to housing a single class (or, more
generally, has a single primary entiry), then it makes sense to use its name
as the module name's last component.

As a concrete example, consider \c{libbutl} (the \c{build2} utility library):
All its components are in the \c{butl} namespace so all its module names start
with \c{butl.}. One of its components is the \c{small_vector} class template
which resides in its own module called \c{butl.small_vector}. Another
component is a collection of string parsing utilities that are grouped into
the \c{butl::string_parser} namespace with the corresponding module name
called \c{butl.string_parser}.

When is it a good idea to re-export a module? The two straightfowards cases
are when we are building an aggregate module out of submodules, for example,
\c{xml} out of \c{xml.parser} and \c{xml.serializer}, or when one module
extends or superceeds another, for example, as \c{std.core} extends
\c{std.fundamental}. It is also clear that there is no need to re-export a
module that we only use in the implementation of our module. The case when we
use a module in our interface is, however, a lot less clear cut.

But before considering the last case in more detail, let's understand the
issue with re-export. In other words, why not simply re-export any module we
import in our interface? In essence, re-export implictly injects another
module import anywhere our module is imported. If we re-export \c{std.core}
then any consumer of our module will also automatically \"see\" all the names
exported by \c{std.core}. They can then start using names from \c{std} without
explicitly importing \c{std.core} and everthing will compile until one day
they may no longer need to import our module or we no longer need to import
\c{std.core}. In a sense, re-export becomes part of our interface and it is
generally good design to keep interfaces minimal.

And so, at the outset, the guideline is then to only re-export the minimum
necessary (and which is the reason why it may make sense to divide
\c{std.core} into submodules such as \c{std.core.string}, \c{std.core.vector},
etc).

Let's now discuss a few concere examples to get a sense of when re-export
might or might not be appropriate. Unfortunately, there does not seem to be a
hard and fast rule and instead one has to rely on a good sense of design.

To start, let's consider a simple module that uses \c{std::string} in its
inteface:

\
export module hello;

import std.core;

export namespace hello
{
  void say (const std::string&);
}
\

Should we re-export \c{std.core} (or, \c{std.core.string}) in this case? Most
likely not. If consumers of our module want to use \c{std::string} in order to
pass an argument to our function, then it is natural to expect them to
explicitly import the necessary module. In a sense, this is analogous to
scoping: nobody expects to be able to use just \c{string} (without \c{std::})
because of \c{using namespace hello;}.

So it seems that a mere usage of a name in an interface does not generally
warrant a re-export. The fact that a consumer may not even use this part of
our interface further supports this conclusion.

Let's now consider a more interesting case (inspired by real events):

\
export module small_vector;

import std.core;

template <typename T, std::size_t N>
export class small_vector: public std::vector<T, ...>
{
  ...
};
\

Here we have the \c{small_vector} container implemented in terms of
\c{std::vector} by providing a custom allocator and with most of the functions
derived as is. Consider now this innocent-looking consumer code:

\
import small_vector;

small_vector<int, 1> a, b;

if (a == b) // Error.
  ...
\

We don't reference \c{std::vector} directly so presumably we shouldn't need to
import its module. However, the comparion won't compile: our \c{small_vector}
implementation re-uses the comparion operators provided by \c{std::vector}
(via implicit to-base conversion) but they aren't visible.

There is palpable difference between the two cases: the first merely uses
\c{std.core} interface while the second is \i{based on} and, in a sense,
\i{extends} it which feels like a stronger relationship. Re-exporting
\c{std.core} (or, better yet, \c{std.core.version}, should it become
available) does not seem unreasonable.

Note also that there is no re-export of headers. In the previous example, if
the standard library is not modularized and we have to use it via headers,
then the consumers of our \c{small_vector} will always have to explicitly
include \c{<vector>}. This suggest that modularizing a codebase that still
consumes substantial components (like the standard library) via headers can
incur some development overhead compared to the old, headers-only approach.


\h2#cxx-modules-existing|Modularizing Existing Code|

The aim of this section is to provide practical guideliness to modularizing
existing codebases as well as supporting the dual, header/module interface for
backwards-compatibility.

Predictably, a well modularized (in the general sense) set of headers makes
conversion to C++ modules easier. As a result, it may make sense to spend some
time cleaning and re-organizing your headers prior to attempting
modularization. Inclusion cycles will be particularly hard to deal with (C++
modules do not allow circular interface dependencies).

Let's first discuss why the modularization approach illustrated by the
following example does not generally work:

\
export module hello;

export
{
#include \"hello.hxx\"
}
\

There are several issue that usually make this unworkable. Firstly, the header
we are trying to export most likely includes other headers. For example, our
\c{hello.hxx} may include \c{<string>} and we have already discussed why
including it in the module purview is a bad idea. Secondly, the included
header may declare more names than what should be exported, for example, some
implementation details. In fact, it may declare names with local linkage
(uncommon for headers but not impossible) which is illegal to export. Finally,
the header may define macros which will no longer be visible to the consumer.

Sometimes, however, this can be the only approach available (for example, if
trying to non-intrusively modularize a third-party library). It is possible to
work around the first issue by \i{pre-including} outside of the module purview
headers that should not be exported. Here we rely on the fact that the second
inclusion of the same header will be ignored. For example:

\
#include <string> // Pre-include to suppress inclusion in hello.hxx.

export module hello;

export
{
#include \"hello.hxx\"
}
\

Needless to say this approach is very brittle and usually requires that you
place all the inter-related headers into a single module.

When starting modularization of a codebase there are two decisions we have to
make at the outset: the level of the modules support we can rely upon and the
level of backwards compatibility we need to provide.

The two modules support levels we distinguish are just modules and modules
with the modularized standard library. The choice we have to make then is
whether to support the standard library only as headers, only as modules, or
both. Note that some compiler/standard library combinations may not be usable
in some of these modes.

The possible backwards compatibility levels are \i{modules-only} (consumption
via headers is no longer supported), \i{modules-or-headers} (consumption
either via headers or modules), and \i{modules-and-headers} (as the previous
case but with support for consuming a library built with modules via headers
and vice versa).

What kind of situations call for the last level? We may need to continue
offering the library as headers if we have a large number of existing
consumers that cannot possibly be all modularized at once (or even ever). So
the situation we may end up in is a mixture of consumers trying to use the
same build of our library with some of them using modules and some \-
headers. The situation where we may want to consume a library built with
headers via modules is also not far fetched: the library might have been built
with an older version of the compiler (for example, it was installed from a
distribution's package) while the consumer is being built with a compiler
version that supports modules. Note that as discussed earlier the modules
ownership semantics supports both kinds of \"cross-usage\".

Generally, compiler implementations do not support mixing inclusion and
importation of the same entities in the same translation unit. This makes
migration tricky if you plan to use the modularized standard library because
of its parvasive use. There are two plausible strategies to handling this
aspect of migration: If you are planning to consume the standard library
exclusively as modules, then it may make sense to first change your entire
codebase to do that. Simply replace all the standard library header inclusions
with importation of the relevant \c{std.*} modules.

The alternative strategy is to first complete the modularization of your
entire project (as discussed next) while continuing consuming the standard
library as headers. Once this is done, we can normally switch to using the
modularized standard library quite easily. The reason for waiting until the
complete modularization is to eliminate header inclusion between components in
our project which would often result in conflicting styles of the standard
library consumption.

Note also that due to the lack of header re-export support discussed earlier,
it may make perfect sense to only support the modularized standard library
when modules are enabled even when providing backwards compatibility with
headers. In fact, if all the compiler/standard library implementations that
your project caters to support the modularize standard library, then there is
little sense not to impose such as restriction.

The overall strategy for modularizing our own componets is to identify and
modularize inter-dependent sets of headers one at a time starting from the
lower-level components (so that any newly modularized set only depends on the
already modularized ones). After converting each set we can switch its
consumers to using imports keeping our entire project buildable and usable.

While it would have been even better to be able modularize just a single
component at a time, this does not seem to work in practice because we will
have to continue consuming some of the components as headers. Since such
headers can only be imported out of module purview it becomes hard to reason
(both for us and the compiler) what is imported/included and where. For
example, it's not uncommon to end up importing the module in its
implementation unit which not something that all implementations handle
garcefully.

Let's now explore how we can provide the various levels of backwards
compatibility discussed above. Here we rely on two feature test macros to
determine the available modules support level: \c{__cpp_modules} (modules are
available) and \c{__cpp_lib_modules} (standard library modules are available,
assumes \c{__cpp_modules} is also defined).

If backwards compatibility is not necessary (the \i{modules-only} level), then
we can use the module interface and implementation unit templates presented
earlier and follow the above guidelines. If we continue consuming the standard
library as headers, then we don't need to change anything in this area. If we
only want to support the modularized standard library, then we simply replace
the standard library header inclusions with the corresponing module
imports. If we want to support both ways, then we can use the following
templates. The module interface unit template:

\
// C includes, if any.

#ifndef __cpp_lib_modules
<std-includes>
#endif

// Other includes, if any.

export module <name>;

#ifdef __cpp_lib_modules
<std-imports>
#endif
\

The module implementation unit template:

\
// C includes, if any.

#ifndef __cpp_lib_modules
<std-includes>

<extra-std-includes>
#endif

// Other includes, if any.

module <name>;

#ifdef __cpp_lib_modules
<extra-std-imports>        // Only imports additional to interface.
#endif
\

For example:

\
// hello.mxx (module interface)

#ifndef __cpp_lib_modules
#include <string>
#endif

export module hello;

#ifdef __cpp_lib_modules
import std.core;
#endif

export void say_hello (const std::string& name);
\

\
// hello.cxx (module implementation)

#ifndef __cpp_lib_modules
#include <string>

#include <iostream>
#endif

module hello;

#ifdef __cpp_lib_modules
import std.io;
#endif

using namespace std;

void say_hello (const string& n)
{
  cout << \"Hello, \" << n << '!' << endl;
}
\

If we need support for symbol exporting in this setup (that is, we are
building a library and need to support Windows), then we can use the
\c{__symexport} mechanism discussed earlier, for example:

\
// hello.mxx (module interface)

...

export __symexport void say_hello (const std::string& name);
\

The consumer code in the \i{modules-only} setup is straightforward: they
simply import the desired modules.

To support consumption via headers when modules are unavailable (the
\i{modules-or-headers} level) we can use the following setup. Here we also
support the dual header/modules consumption for the standard library (if this
is not required, replace \c{#ifndef __cpp_lib_modules} with \c{#ifndef
__cpp_modules} and remove \c{#ifdef __cpp_lib_modules}). The module interface
unit template:

\
#ifndef __cpp_modules
#pragma once
#endif

// C includes, if any.

#ifndef __cpp_lib_modules
<std-includes>
#endif

// Other includes, if any.

#ifdef __cpp_modules
export module <name>;

#ifdef __cpp_lib_modules
<std-imports>
#endif
#endif
\

The module implementation unit template:

\
#ifndef __cpp_modules
#include <module-interface-file>
#endif

// C includes, if any.

#ifndef __cpp_lib_modules
<std-includes>

<extra-std-includes>
#endif

// Other includes, if any

#ifdef __cpp_modules
module <name>;

#ifdef __cpp_lib_modules
<extra-std-imports>        // Only imports additional to interface.
#endif
#endif
\

Besides these templates we will most likely also need an export header that
appropriately defines a module export macro depending on whether modules are
used or not. This is also the place where we can handle symbol exporting. For
example, here is what it can look like for our \c{libhello} library:

\
// export.hxx (module and symbol export)

#pragma once

#ifdef __cpp_modules
#  define LIBHELLO_MODEXPORT export
#else
#  define LIBHELLO_MODEXPORT
#endif

#if   defined(LIBHELLO_SHARED_BUILD)
#  ifdef _WIN32
#    define LIBHELLO_SYMEXPORT __declspec(dllexport)
#  else
#    define LIBHELLO_SYMEXPORT
#  endif
#elif defined(LIBHELLO_SHARED)
#  ifdef _WIN32
#    define LIBHELLO_SYMEXPORT __declspec(dllimport)
#  else
#    define LIBHELLO_SYMEXPORT
#  endif
#else
#  define LIBHELLO_SYMEXPORT
#endif
\

And this is the module that uses it and provides the dual header/module
support:

\
// hello.mxx (module interface)

#ifndef __cpp_modules
#pragma once
#endif

#ifndef __cpp_lib_modules
#include <string>
#endif

#ifdef __cpp_modules
export module hello;

#ifdef __cpp_lib_modules
import std.core;
#endif
#endif

#include <libhello/export.hxx>

LIBHELLO_MODEXPORT namespace hello
{
  LIBHELLO_SYMEXPORT void say (const std::string& name);
}
\

\
// hello.cxx (module implementation)

#ifndef __cpp_modules
#include <libhello/hello.mxx>
#endif

#ifndef __cpp_lib_modules
#include <string>

#include <iostream>
#endif

#ifdef __cpp_modules
module hello;

#ifdef __cpp_lib_modules
import std.io;
#endif
#endif

using namespace std;

namespace hello
{
  void say (const string& n)
  {
    cout << \"Hello, \" << n << '!' << endl;
  }
}
\

The consumer code in the \i{modules-or-headers} setup has to use either
inclusion or importation depending on the modules support availability, for
example:

\
#ifndef __cpp_modules
#include <libhello/hello.mxx>
#else
import hello;
#endif
\

Predictably, the final backwards compatibility level (\c{modules-and-headers})
is the most onerous to support. Here existing consumers have to continue
working with the modularized version of our library which means we have to
retain all the existing headers. We also cannot assume that just because
modules are available they are used (a consumer may still prefer headers),
which means we cannot rely on (only) the \c{__cpp_modules} and
\c{__cpp_lib_modules} macros to make the decisions.

One way to arrange this is to retain the header and adjust it according to the
previous level template but with one important difference: instead of using
the standard modules macro we use our custom ones (we can also have
unconditional \c{#pragma once}). For example:

\
// hello.hxx (module header)

#pragma once

#ifndef LIBHELLO_LIB_MODULES
#include <string>
#endif

#ifdef LIBHELLO_MODULES
export module hello;

#ifdef LIBHELLO_LIB_MODULES
import std.core;
#endif
#endif

#include <libhello/export.hxx>

LIBHELLO_MODEXPORT namespace hello
{
  LIBHELLO_SYMEXPORT void say (const std::string& name);
}
\

Now if this header is included (for example, by an existing consumer) then
none of these macros will be defined and the header will act as, well, a plain
old header. Note that we will also need to make the equivalent change in the
export header.

We also provide the module interface unit which appropriately defines the two
custom macros and then simply includes the header:

\
// hello.mxx (module interface)

#ifdef __cpp_modules
#define LIBHELLO_MODULES
#endif

#ifdef __cpp_lib_modules
#define LIBHELLO_LIB_MODULES
#endif

#include <libhello/hello.hxx>
\

The module implementation unit can remain unchanged. In particular, we
continue including \c{hello.mxx} if modules support is unavailable. However,
if you find the use of different macros in the header and source files
confusing, then instead it can be adjusted as follows (note that now we are
including \c{hello.hxx}):

\
// hello.cxx (module implementation)

#ifdef __cpp_modules
#define LIBHELLO_MODULES
#endif

#ifdef __cpp_lib_modules
#define LIBHELLO_LIB_MODULES
#endif

#ifndef LIBHELLO_MODULES
#include <libhello/hello.hxx>
#endif

#ifndef LIBHELLO_LIB_MODULES
#include <string>

#include <iostream>
#endif

#ifdef LIBHELLO_MODULES
module hello;

#ifdef LIBHELLO_LIB_MODULES
import std.io;
#endif
#endif

...
\

In this case it may also make sense to factor the \c{*_MODULES} macro
defintions into a common header.

In the \i{modules-and-headers} setup the existing consumers that would like to
continue using headers don't require any changes. And for those that would
like to use module if available the arrangement is the same as for the
previous compatibility level.

If our module needs to \"export\" macros then the recommended approach is to
simply provide an additional header that the consumer includes. While it might
be tempting to also wrap the module import into this header, some may prefer
to explicitly import the module and include the header, especially if the
macros may not be needed by all consumers. This way we can also keep the
header macro-only which means it can be included freely, in or out of module
purviews.
"