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author | Boris Kolpackov <boris@codesynthesis.com> | 2021-04-09 09:50:50 +0200 |
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committer | Boris Kolpackov <boris@codesynthesis.com> | 2021-04-09 09:50:50 +0200 |
commit | 5e392c9141ffa4e864319fc5268ce96388085699 (patch) | |
tree | 6c5a1b64fdb4124bde910ad85deedee38487cdf7 /doc | |
parent | e9f69e067da3e096e1e64be70ec2b6de30f71d2c (diff) |
Document hermetic build configuration support
Diffstat (limited to 'doc')
-rw-r--r-- | doc/manual.cli | 198 |
1 files changed, 183 insertions, 15 deletions
diff --git a/doc/manual.cli b/doc/manual.cli index e09aef8..af9699e 100644 --- a/doc/manual.cli +++ b/doc/manual.cli @@ -1652,15 +1652,15 @@ examine each of them starting with \c{config}. \h2#intro-operations-config|Configuring| -As mentioned briefly earlier, the \c{config} module provides support for -persisting configurations by having us \i{configure} our projects. At first it -may feel natural to call \c{configure} an operation. There is, however, a -conceptual problem: we don't really configure a target. And, perhaps after -some meditation, it should become clear that what we are really doing is -configuring operations on targets. For example, configuring updating a C++ -project might involve detecting and saving information about the C++ compiler -while configuring installing it may require specifying the installation -directory. +As mentioned briefly earlier, the \l{#module-config \c{config}} module +provides support for persisting configurations by having us \i{configure} our +projects. At first it may feel natural to call \c{configure} an operation. +There is, however, a conceptual problem: we don't really configure a +target. And, perhaps after some meditation, it should become clear that what +we are really doing is configuring operations on targets. For example, +configuring updating a C++ project might involve detecting and saving +information about the C++ compiler while configuring installing it may require +specifying the installation directory. In other words, \c{configure} is an operation on operation on targets \- a meta-operation. And so in \c{build2} we have the concept of a \i{build system @@ -1776,6 +1776,20 @@ $ b configure config.cxx=\"g++ -L/opt/install\" | + +If we would like to prevent subsequent changes to the environment from +affecting our build configuration, we can make it \i{hermetic} (see +\l{#module-config-hermetic Hermetic Build Configurations} for details): + +\ +$ b configure config.config.hermetic=true ... +\ + +\N|One prominent use of hermetic configurations is to preserve the build +environment of the Visual Studio development command prompt. That is, +hermetically configuring our project in a suitable Visual Studio command +prompt makes us free to build it from any other prompt or shell, IDE, etc.| + We can also configure out of source builds of our projects. In this case, besides \c{config.build}, \c{configure} also saves the location of the source directory so that we don't have to repeat that either. Remember, this is how @@ -4572,12 +4586,19 @@ the optional functionality case, the default should probably be to provide it. As discussed in the introduction, the central part of the build configuration functionality are the \i{configuration variables}. One of the key features that make them special is support for automatic persistence in the -\c{build/config.build} file provided by the \c{config} module (see -\l{#intro-operations-config Configuring} for details). The following example, -based on the \c{libhello} project from the introduction, gives an overview of -the project configuration functionality with the remainder of the chapter -providing the detailed explanation of all the parts shown as well as the -alternative approaches. +\c{build/config.build} file provided by the \l{#module-config \c{config}} +module (see \l{#intro-operations-config Configuring} for details). + +\N|Another mechanism that can be used for project configuration is environment +variables. While not recommended, sometimes it may be forced on us by external +factors. In such cases, environment variables that affect the build result +should be reported with the \c{config.environment} directive as discussed in +\l{#module-config-hermetic Hermetic Build Configurations}.| + +The following example, based on the \c{libhello} project from the introduction, +gives an overview of the project configuration functionality with the +remainder of the chapter providing the detailed explanation of all the parts +shown as well as the alternative approaches. \ libhello/ @@ -5581,6 +5602,153 @@ of the same file in the same scope are not automatically ignored. See also \l{#directives-include \c{include}}. +\h1#module-config|\c{config} Module| + +\N{This chapter is a work in progress and is incomplete.} + +\h#module-config-hermetic|Hermetic Build Configurations| + +Hermetic build configurations save environment variables that affect the +project along with other project configuration in the \c{build/config.build} +file. These saved environment variables are then used instead of the current +environment when performing operations on the project, thus making sure the +project \"sees\" exactly the same environment as during configuration. + +\N|While currently hermetic configurations only deal with the environment, in +the future this functionality may be extended to also support disallowing +changes to external resources (compilers, system headers and libraries, etc).| + +To create a hermetic configuration we use the \c{config.config.hermetic} +configuration variable. For example: + +\ +$ b configure config.config.hermetic=true +\ + +\N|Hermetic configurations are not the default because they are not without +drawbacks. Firstly, a hermetic configuration may break if the saved +environment becomes incompatible with the rest of the system. For example, you +may re-install an external program (say, a compiler) into a different location +and update your \c{PATH} to match the new setup. However, a hermetic +configuration will \"see\" the first change but not the second. + +Another issue is the commands printed during a hermetic build: they are +executed in the saved environment which may not match the environment in which +the build system was invoked. As a result, we cannot easily re-execute such +commands, which is often handy during build troubleshooting. + +It is also important to keep in mind that a non-hermetic build configuration +does not break or produce incorrect results if the environment changes. +Instead, changes to the environment are detected and affected targets are +automatically rebuilt. + +The two use-cases where hermetic configurations are really useful are when we +need to save an environment which is not generally available (for example, an +environment of a Visual Studio development command prompt) or when our build +results need to exactly match the specific configuration (for example, because +parts of the overall result have already been built and installed, as is the +case with build system modules).| + +If we now examine \c{config.build}, we will see something along these lines: + +\ +$ cat build/config.build + +config.config.hermetic = true +config.config.environment = CPATH CPLUS_INCLUDE_PATH PATH=... +\ + +\N|Hermetic configuration support is built on top of the low-level +\c{config.config.environment} configuration variable which allows us to +specify custom environment variables and their values. Specifically, it +contains a list of environment variable \"sets\" (\c{\i{name}=\i{value}}) +and \"unsets\" (\ci{name}). For example: + +\ +$ b configure \ + config.config.environment=\"PATH=/bin:/usr/bin LD_LIBRARY_PATH\" +\ + +Specifying \c{config.config.hermetic=true} simply instructs the \c{config} +module to collect and save in \c{config.config.environment} environment +variables that affect the project. These include: + +\ul| + +\li|built-in variables (such as \c{PATH} and \c{LD_LIBRARY_PATH} or equivalent),| + +\li|variables that affect external programs as reported by build system +modules (such as \c{CPLUS_INCLUDE_PATH} reported by the \c{cxx} module) or +by imported programs via metadata,| + +\li|variables reported by the project itself with the \c{config.environment} +directive (discussed below).||| + +Reconfiguring a hermetic configuration preserves the saved environment unless +\i{re-hermetization} is explicitly requested with the +\c{config.config.hermetic.reload} configuration variable. For example: + +\ +$ b configure config.config.hermetic.reload=true +\ + +\N|Note that \c{config.config.hermetic.reload} is transient and is not stored +in \c{config.build}. In other words, there is no way to create a hermetic +configuration that is re-hermetized by default during reconfiguration.| + +To \i{de-hermetize} a hermetic build configuration, reconfigure it with +\c{config.config.hermetic=false}. + +\N|The \c{config.config.hermetic} variable has essentially a tri-state value: +\c{true} means keep hermetized (save the environment in +\c{config.config.environment}), \c{false} means keep de-hermetized (clear +\c{config.config.environment}) and \c{null} or undefined means don't touch +\c{config.config.environment}.| + +We can adjust the set of environment variables saved in a hermetic +configuration using the \c{config.config.hermetic.environment} configuration +variable. It contains a list of inclusions (\ci{name}) and exclusions +(\c{\i{name}@false}) which are applied to the final set of environment +variables that affect the project. For example: + +\ +LC_ALL=C b configure \ + config.config.hermetic=true \ + config.config.hermetic.environment=\"LC_ALL PATH@false\" +\ + +Typically, the set of environment variables that affect the project is +discovered automatically. Specifically, modules that we use (such as \c{cxx}) +are expected to report the environment variables that affect the programs they +invoke (such as the C++ compiler). Similarly, programs that we import in our +\c{buildfiles} (for example to use in ad hoc recipes) are expected to report +environment variables that affect them as part of their metadata. + +However, there are situations where we need to report an environment variable +manually. These include calling the \c{$getenv()} function from a +\c{buildfile} or invoking a program (either in an ad hoc recipe, the \c{run} +directive, or the \c{$run*()} function family) that either does not provide +the metadata or does not report the environment as part of it. In such cases +we should report the environment variable manually using the +\c{config.environment} directive. For example: + +\ +config.environment USE_FOO + +foo = $getenv(USE_FOO) + +if ($foo != [null]) + cxx.poptions += \"-DUSE_FOO=$foo\" +\ + +\N|Normally, we would want to report variables that affect the build result +rather than build byproducts (for example, diagnostics). This is, for example, +the reason why locale-related environment variables are not saved by default. +Also, sometime environment variables only affect certain modes of a program. +If such modes are not used, then there is no need to report the corresponding +variables.| + + \h1#module-test|\c{test} Module| \N{This chapter is a work in progress and is incomplete.} |