@Test public void testCloneBuilder() { FileTypeSet txtFiles = FileTypeSet.of(FileType.of("txt")); RuleClass.Builder.RuleClassNamePredicate ruleClasses = new RuleClass.Builder.RuleClassNamePredicate("mock_rule"); Attribute parentAttr = attr("x", LABEL_LIST).allowedFileTypes(txtFiles).mandatory().build(); Attribute childAttr1 = parentAttr.cloneBuilder().build(); assertEquals("x", childAttr1.getName()); assertEquals(txtFiles, childAttr1.getAllowedFileTypesPredicate()); assertEquals(Predicates.alwaysTrue(), childAttr1.getAllowedRuleClassesPredicate()); assertTrue(childAttr1.isMandatory()); assertFalse(childAttr1.isNonEmpty()); Attribute childAttr2 = parentAttr.cloneBuilder().nonEmpty().allowedRuleClasses(ruleClasses).build(); assertEquals("x", childAttr2.getName()); assertEquals(txtFiles, childAttr2.getAllowedFileTypesPredicate()); assertEquals(ruleClasses, childAttr2.getAllowedRuleClassesPredicate()); assertTrue(childAttr2.isMandatory()); assertTrue(childAttr2.isNonEmpty()); // Check if the parent attribute is unchanged assertFalse(parentAttr.isNonEmpty()); assertEquals(Predicates.alwaysTrue(), parentAttr.getAllowedRuleClassesPredicate()); }
/** * A class to create C/C++ compile and link actions in a way that is consistent with cc_library. * Rules that generate source files and emulate cc_library on top of that should use this class * instead of the lower-level APIs in CppHelper and CppModel. * * <p>Rules that want to use this class are required to have implicit dependencies on the toolchain, * the STL, the lipo context, and so on. Optionally, they can also have copts, and malloc * attributes, but note that these require explicit calls to the corresponding setter methods. */ public final class CcLibraryHelper { static final FileTypeSet SOURCE_TYPES = FileTypeSet.of( CppFileTypes.CPP_SOURCE, CppFileTypes.CPP_HEADER, CppFileTypes.C_SOURCE, CppFileTypes.ASSEMBLER, CppFileTypes.ASSEMBLER_WITH_C_PREPROCESSOR); /** Function for extracting module maps from CppCompilationDependencies. */ public static final Function<TransitiveInfoCollection, CppModuleMap> CPP_DEPS_TO_MODULES = new Function<TransitiveInfoCollection, CppModuleMap>() { @Override @Nullable public CppModuleMap apply(TransitiveInfoCollection dep) { CppCompilationContext context = dep.getProvider(CppCompilationContext.class); return context == null ? null : context.getCppModuleMap(); } }; /** * Contains the providers as well as the compilation and linking outputs, and the compilation * context. */ public static final class Info { private final ImmutableMap<Class<? extends TransitiveInfoProvider>, TransitiveInfoProvider> providers; private final ImmutableMap<String, NestedSet<Artifact>> outputGroups; private final CcCompilationOutputs compilationOutputs; private final CcLinkingOutputs linkingOutputs; private final CcLinkingOutputs linkingOutputsExcludingPrecompiledLibraries; private final CppCompilationContext context; private Info( Map<Class<? extends TransitiveInfoProvider>, TransitiveInfoProvider> providers, Map<String, NestedSet<Artifact>> outputGroups, CcCompilationOutputs compilationOutputs, CcLinkingOutputs linkingOutputs, CcLinkingOutputs linkingOutputsExcludingPrecompiledLibraries, CppCompilationContext context) { this.providers = ImmutableMap.copyOf(providers); this.outputGroups = ImmutableMap.copyOf(outputGroups); this.compilationOutputs = compilationOutputs; this.linkingOutputs = linkingOutputs; this.linkingOutputsExcludingPrecompiledLibraries = linkingOutputsExcludingPrecompiledLibraries; this.context = context; } public Map<Class<? extends TransitiveInfoProvider>, TransitiveInfoProvider> getProviders() { return providers; } public ImmutableMap<String, NestedSet<Artifact>> getOutputGroups() { return outputGroups; } public CcCompilationOutputs getCcCompilationOutputs() { return compilationOutputs; } public CcLinkingOutputs getCcLinkingOutputs() { return linkingOutputs; } /** * Returns the linking outputs before adding the pre-compiled libraries. Avoid using this - * pre-compiled and locally compiled libraries should be treated identically. This method only * exists for backwards compatibility. */ public CcLinkingOutputs getCcLinkingOutputsExcludingPrecompiledLibraries() { return linkingOutputsExcludingPrecompiledLibraries; } public CppCompilationContext getCppCompilationContext() { return context; } /** * Adds the static, pic-static, and dynamic (both compile-time and execution-time) libraries to * the given builder. */ public void addLinkingOutputsTo(NestedSetBuilder<Artifact> filesBuilder) { filesBuilder.addAll(LinkerInputs.toLibraryArtifacts(linkingOutputs.getStaticLibraries())); filesBuilder.addAll(LinkerInputs.toLibraryArtifacts(linkingOutputs.getPicStaticLibraries())); filesBuilder.addAll(LinkerInputs.toNonSolibArtifacts(linkingOutputs.getDynamicLibraries())); filesBuilder.addAll( LinkerInputs.toNonSolibArtifacts(linkingOutputs.getExecutionDynamicLibraries())); } } private final RuleContext ruleContext; private final BuildConfiguration configuration; private final CppSemantics semantics; private final List<Artifact> publicHeaders = new ArrayList<>(); private final List<Artifact> publicTextualHeaders = new ArrayList<>(); private final List<Artifact> privateHeaders = new ArrayList<>(); private final List<PathFragment> additionalExportedHeaders = new ArrayList<>(); private final List<Pair<Artifact, Label>> compilationUnitSources = new ArrayList<>(); private final List<Artifact> objectFiles = new ArrayList<>(); private final List<Artifact> picObjectFiles = new ArrayList<>(); private final List<String> copts = new ArrayList<>(); @Nullable private Pattern nocopts; private final List<String> linkopts = new ArrayList<>(); private final Set<String> defines = new LinkedHashSet<>(); private final List<TransitiveInfoCollection> deps = new ArrayList<>(); private final List<Artifact> linkstamps = new ArrayList<>(); private final List<Artifact> prerequisites = new ArrayList<>(); private final List<PathFragment> looseIncludeDirs = new ArrayList<>(); private final List<PathFragment> systemIncludeDirs = new ArrayList<>(); private final List<PathFragment> includeDirs = new ArrayList<>(); @Nullable private Artifact dynamicLibrary; private LinkTargetType linkType = LinkTargetType.STATIC_LIBRARY; private HeadersCheckingMode headersCheckingMode = HeadersCheckingMode.LOOSE; private boolean neverlink; private boolean fake; private final List<LibraryToLink> staticLibraries = new ArrayList<>(); private final List<LibraryToLink> picStaticLibraries = new ArrayList<>(); private final List<LibraryToLink> dynamicLibraries = new ArrayList<>(); private boolean emitLinkActionsIfEmpty; private boolean emitCcNativeLibrariesProvider; private boolean emitCcSpecificLinkParamsProvider; private boolean emitInterfaceSharedObjects; private boolean emitDynamicLibrary = true; private boolean checkDepsGenerateCpp = true; private boolean emitCompileProviders; private final FeatureConfiguration featureConfiguration; public CcLibraryHelper( RuleContext ruleContext, CppSemantics semantics, FeatureConfiguration featureConfiguration) { this.ruleContext = Preconditions.checkNotNull(ruleContext); this.configuration = ruleContext.getConfiguration(); this.semantics = Preconditions.checkNotNull(semantics); this.featureConfiguration = Preconditions.checkNotNull(featureConfiguration); } /** Sets fields that overlap for cc_library and cc_binary rules. */ public CcLibraryHelper fromCommon(CcCommon common) { this.addCopts(common.getCopts()) .addDefines(common.getDefines()) .addDeps(ruleContext.getPrerequisites("deps", Mode.TARGET)) .addIncludeDirs(common.getIncludeDirs()) .addLooseIncludeDirs(common.getLooseIncludeDirs()) .addPicIndependentObjectFiles(common.getLinkerScripts()) .addSystemIncludeDirs(common.getSystemIncludeDirs()) .setNoCopts(common.getNoCopts()) .setHeadersCheckingMode(semantics.determineHeadersCheckingMode(ruleContext)); return this; } /** * Adds {@code headers} as public header files. These files will be made visible to dependent * rules. They may be parsed/preprocessed or compiled into a header module depending on the * configuration. */ public CcLibraryHelper addPublicHeaders(Collection<Artifact> headers) { for (Artifact header : headers) { addHeader(header, ruleContext.getLabel()); } return this; } /** * Adds {@code headers} as public header files. These files will be made visible to dependent * rules. They may be parsed/preprocessed or compiled into a header module depending on the * configuration. */ public CcLibraryHelper addPublicHeaders(Artifact... headers) { addPublicHeaders(Arrays.asList(headers)); return this; } /** * Adds {@code headers} as public header files. These files will be made visible to dependent * rules. They may be parsed/preprocessed or compiled into a header module depending on the * configuration. */ public CcLibraryHelper addPublicHeaders(Iterable<Pair<Artifact, Label>> headers) { for (Pair<Artifact, Label> header : headers) { addHeader(header.first, header.second); } return this; } /** * Add the corresponding files as public header files, i.e., these files will not be compiled, but * are made visible as includes to dependent rules in module maps. */ public CcLibraryHelper addAdditionalExportedHeaders( Iterable<PathFragment> additionalExportedHeaders) { Iterables.addAll(this.additionalExportedHeaders, additionalExportedHeaders); return this; } /** * Add the corresponding files as public textual header files. These files will not be compiled * into a target's header module, but will be made visible as textual includes to dependent rules. */ public CcLibraryHelper addPublicTextualHeaders(Iterable<Artifact> textualHeaders) { Iterables.addAll(this.publicTextualHeaders, textualHeaders); for (Artifact header : textualHeaders) { this.additionalExportedHeaders.add(header.getExecPath()); } return this; } /** * Add the corresponding files as source files. These may also be header files, in which case they * will not be compiled, but also not made visible as includes to dependent rules. */ public CcLibraryHelper addSources(Collection<Artifact> sources) { for (Artifact source : sources) { addSource(source, ruleContext.getLabel()); } return this; } /** * Add the corresponding files as source files. These may also be header files, in which case they * will not be compiled, but also not made visible as includes to dependent rules. */ public CcLibraryHelper addSources(Iterable<Pair<Artifact, Label>> sources) { for (Pair<Artifact, Label> source : sources) { addSource(source.first, source.second); } return this; } /** * Add the corresponding files as source files. These may also be header files, in which case they * will not be compiled, but also not made visible as includes to dependent rules. */ public CcLibraryHelper addSources(Artifact... sources) { return addSources(Arrays.asList(sources)); } /** * Adds a header to {@code publicHeaders} and in case header processing is switched on for the * file type also to compilationUnitSources. */ private void addHeader(Artifact header, Label label) { boolean isHeader = CppFileTypes.CPP_HEADER.matches(header.getExecPath()); boolean isTextualInclude = CppFileTypes.CPP_TEXTUAL_INCLUDE.matches(header.getExecPath()); publicHeaders.add(header); if (isTextualInclude || !isHeader || !shouldProcessHeaders()) { return; } compilationUnitSources.add(Pair.of(header, label)); } /** * Adds a source to {@code compilationUnitSources} if it is a compiled file type (including * parsed/preprocessed header) and to {@code privateHeaders} if it is a header. */ private void addSource(Artifact source, Label label) { boolean isHeader = CppFileTypes.CPP_HEADER.matches(source.getExecPath()); boolean isTextualInclude = CppFileTypes.CPP_TEXTUAL_INCLUDE.matches(source.getExecPath()); boolean isCompiledSource = SOURCE_TYPES.matches(source.getExecPathString()); if (isHeader || isTextualInclude) { privateHeaders.add(source); } if (isTextualInclude || !isCompiledSource || (isHeader && !shouldProcessHeaders())) { return; } compilationUnitSources.add(Pair.of(source, label)); } private boolean shouldProcessHeaders() { return featureConfiguration.isEnabled(CppRuleClasses.PREPROCESS_HEADERS) || featureConfiguration.isEnabled(CppRuleClasses.PARSE_HEADERS); } /** * Returns the compilation unit sources. That includes all compiled source files as well as * headers that will be parsed or preprocessed. */ public ImmutableList<Pair<Artifact, Label>> getCompilationUnitSources() { return ImmutableList.copyOf(this.compilationUnitSources); } /** * Add the corresponding files as linker inputs for non-PIC links. If the corresponding files are * compiled with PIC, the final link may or may not fail. Note that the final link may not happen * here, if {@code --start_end_lib} is enabled, but instead at any binary that transitively * depends on the current rule. */ public CcLibraryHelper addObjectFiles(Iterable<Artifact> objectFiles) { Iterables.addAll(this.objectFiles, objectFiles); return this; } /** * Add the corresponding files as linker inputs for PIC links. If the corresponding files are not * compiled with PIC, the final link may or may not fail. Note that the final link may not happen * here, if {@code --start_end_lib} is enabled, but instead at any binary that transitively * depends on the current rule. */ public CcLibraryHelper addPicObjectFiles(Iterable<Artifact> picObjectFiles) { Iterables.addAll(this.picObjectFiles, picObjectFiles); return this; } /** Add the corresponding files as linker inputs for both PIC and non-PIC links. */ public CcLibraryHelper addPicIndependentObjectFiles(Iterable<Artifact> objectFiles) { addPicObjectFiles(objectFiles); return addObjectFiles(objectFiles); } /** Add the corresponding files as linker inputs for both PIC and non-PIC links. */ public CcLibraryHelper addPicIndependentObjectFiles(Artifact... objectFiles) { return addPicIndependentObjectFiles(Arrays.asList(objectFiles)); } /** * Add the corresponding files as static libraries into the linker outputs (i.e., after the linker * action) - this makes them available for linking to binary rules that depend on this rule. */ public CcLibraryHelper addStaticLibraries(Iterable<LibraryToLink> libraries) { Iterables.addAll(staticLibraries, libraries); return this; } /** * Add the corresponding files as static libraries into the linker outputs (i.e., after the linker * action) - this makes them available for linking to binary rules that depend on this rule. */ public CcLibraryHelper addPicStaticLibraries(Iterable<LibraryToLink> libraries) { Iterables.addAll(picStaticLibraries, libraries); return this; } /** * Add the corresponding files as dynamic libraries into the linker outputs (i.e., after the * linker action) - this makes them available for linking to binary rules that depend on this * rule. */ public CcLibraryHelper addDynamicLibraries(Iterable<LibraryToLink> libraries) { Iterables.addAll(dynamicLibraries, libraries); return this; } /** Adds the copts to the compile command line. */ public CcLibraryHelper addCopts(Iterable<String> copts) { Iterables.addAll(this.copts, copts); return this; } /** Sets a pattern that is used to filter copts; set to {@code null} for no filtering. */ public CcLibraryHelper setNoCopts(@Nullable Pattern nocopts) { this.nocopts = nocopts; return this; } /** Adds the given options as linker options to the link command. */ public CcLibraryHelper addLinkopts(Iterable<String> linkopts) { Iterables.addAll(this.linkopts, linkopts); return this; } /** Adds the given defines to the compiler command line. */ public CcLibraryHelper addDefines(Iterable<String> defines) { Iterables.addAll(this.defines, defines); return this; } /** * Adds the given targets as dependencies - this can include explicit dependencies on other rules * (like from a "deps" attribute) and also implicit dependencies on runtime libraries. */ public CcLibraryHelper addDeps(Iterable<? extends TransitiveInfoCollection> deps) { for (TransitiveInfoCollection dep : deps) { Preconditions.checkArgument( dep.getConfiguration() == null || configuration.equalsOrIsSupersetOf(dep.getConfiguration()), "dep " + dep.getLabel() + " has a different config than " + ruleContext.getLabel()); this.deps.add(dep); } return this; } /** * Adds the given linkstamps. Note that linkstamps are usually not compiled at the library level, * but only in the dependent binary rules. */ public CcLibraryHelper addLinkstamps(Iterable<? extends TransitiveInfoCollection> linkstamps) { for (TransitiveInfoCollection linkstamp : linkstamps) { Iterables.addAll( this.linkstamps, linkstamp.getProvider(FileProvider.class).getFilesToBuild()); } return this; } /** * Adds the given prerequisites as prerequisites for the generated compile actions. This ensures * that the corresponding files exist - otherwise the action fails. Note that these dependencies * add edges to the action graph, and can therefore increase the length of the critical path, * i.e., make the build slower. */ public CcLibraryHelper addCompilationPrerequisites(Iterable<Artifact> prerequisites) { Iterables.addAll(this.prerequisites, prerequisites); return this; } /** * Adds the given precompiled files to this helper. Shared and static libraries are added as * compilation prerequisites, and object files are added as pic or non-pic object files * respectively. */ public CcLibraryHelper addPrecompiledFiles(PrecompiledFiles precompiledFiles) { addCompilationPrerequisites(precompiledFiles.getSharedLibraries()); addCompilationPrerequisites(precompiledFiles.getStaticLibraries()); addObjectFiles(precompiledFiles.getObjectFiles(false)); addPicObjectFiles(precompiledFiles.getObjectFiles(true)); return this; } /** * Adds the given directories to the loose include directories that are only allowed to be * referenced when headers checking is {@link HeadersCheckingMode#LOOSE} or {@link * HeadersCheckingMode#WARN}. */ public CcLibraryHelper addLooseIncludeDirs(Iterable<PathFragment> looseIncludeDirs) { Iterables.addAll(this.looseIncludeDirs, looseIncludeDirs); return this; } /** * Adds the given directories to the system include directories (they are passed with {@code * "-isystem"} to the compiler); these are also passed to dependent rules. */ public CcLibraryHelper addSystemIncludeDirs(Iterable<PathFragment> systemIncludeDirs) { Iterables.addAll(this.systemIncludeDirs, systemIncludeDirs); return this; } /** * Adds the given directories to the quote include directories (they are passed with {@code * "-iquote"} to the compiler); these are also passed to dependent rules. */ public CcLibraryHelper addIncludeDirs(Iterable<PathFragment> includeDirs) { Iterables.addAll(this.includeDirs, includeDirs); return this; } /** * Overrides the path for the generated dynamic library - this should only be called if the * dynamic library is an implicit or explicit output of the rule, i.e., if it is accessible by * name from other rules in the same package. Set to {@code null} to use the default computation. */ public CcLibraryHelper setDynamicLibrary(@Nullable Artifact dynamicLibrary) { this.dynamicLibrary = dynamicLibrary; return this; } /** * Marks the output of this rule as alwayslink, i.e., the corresponding symbols will be retained * by the linker even if they are not otherwise used. This is useful for libraries that register * themselves somewhere during initialization. * * <p>This only sets the link type (see {@link #setLinkType}), either to a static library or to an * alwayslink static library (blaze uses a different file extension to signal alwayslink to * downstream code). */ public CcLibraryHelper setAlwayslink(boolean alwayslink) { linkType = alwayslink ? LinkTargetType.ALWAYS_LINK_STATIC_LIBRARY : LinkTargetType.STATIC_LIBRARY; return this; } /** * Directly set the link type. This can be used instead of {@link #setAlwayslink}. Setting * anything other than a static link causes this class to skip the link action creation. */ public CcLibraryHelper setLinkType(LinkTargetType linkType) { this.linkType = Preconditions.checkNotNull(linkType); return this; } /** * Marks the resulting code as neverlink, i.e., the code will not be linked into dependent * libraries or binaries - the header files are still available. */ public CcLibraryHelper setNeverLink(boolean neverlink) { this.neverlink = neverlink; return this; } /** Sets the given headers checking mode. The default is {@link HeadersCheckingMode#LOOSE}. */ public CcLibraryHelper setHeadersCheckingMode(HeadersCheckingMode headersCheckingMode) { this.headersCheckingMode = Preconditions.checkNotNull(headersCheckingMode); return this; } /** * Marks the resulting code as fake, i.e., the code will not actually be compiled or linked, but * instead, the compile command is written to a file and added to the runfiles. This is currently * used for non-compilation tests. Unfortunately, the design is problematic, so please don't add * any further uses. */ public CcLibraryHelper setFake(boolean fake) { this.fake = fake; return this; } /** This adds the {@link CcNativeLibraryProvider} to the providers created by this class. */ public CcLibraryHelper enableCcNativeLibrariesProvider() { this.emitCcNativeLibrariesProvider = true; return this; } /** * This adds the {@link CcSpecificLinkParamsProvider} to the providers created by this class. * Otherwise the result will contain an instance of {@link CcLinkParamsProvider}. */ public CcLibraryHelper enableCcSpecificLinkParamsProvider() { this.emitCcSpecificLinkParamsProvider = true; return this; } /** * Enables or disables generation of link actions if there are no object files. Some rules declare * a <code>.a</code> or <code>.so</code> implicit output, which requires that these files are * created even if there are no object files, so be careful when calling this. * * <p>This is disabled by default. */ public CcLibraryHelper setGenerateLinkActionsIfEmpty(boolean emitLinkActionsIfEmpty) { this.emitLinkActionsIfEmpty = emitLinkActionsIfEmpty; return this; } /** * Enables the optional generation of interface dynamic libraries - this is only used when the * linker generates a dynamic library, and only if the crosstool supports it. The default is not * to generate interface dynamic libraries. */ public CcLibraryHelper enableInterfaceSharedObjects() { this.emitInterfaceSharedObjects = true; return this; } /** * This enables or disables the generation of a dynamic library link action. The default is to * generate a dynamic library. Note that the selection between dynamic or static linking is * performed at the binary rule level. */ public CcLibraryHelper setCreateDynamicLibrary(boolean emitDynamicLibrary) { this.emitDynamicLibrary = emitDynamicLibrary; return this; } /** * Disables checking that the deps actually are C++ rules. By default, the {@link #build} method * uses {@link LanguageDependentFragment.Checker#depSupportsLanguage} to check that all deps * provide C++ providers. */ public CcLibraryHelper setCheckDepsGenerateCpp(boolean checkDepsGenerateCpp) { this.checkDepsGenerateCpp = checkDepsGenerateCpp; return this; } /** * Enables the output of the {@code files_to_compile} and {@code compilation_prerequisites} output * groups. */ // TODO(bazel-team): We probably need to adjust this for the multi-language rules. public CcLibraryHelper enableCompileProviders() { this.emitCompileProviders = true; return this; } /** Create the C++ compile and link actions, and the corresponding C++-related providers. */ public Info build() { // Fail early if there is no lipo context collector on the rule - otherwise we end up failing // in lipo optimization. Preconditions.checkState( // 'cc_inc_library' rules do not compile, and thus are not affected by LIPO. ruleContext.getRule().getRuleClass().equals("cc_inc_library") || ruleContext.getRule().isAttrDefined(":lipo_context_collector", BuildType.LABEL)); if (checkDepsGenerateCpp) { for (LanguageDependentFragment dep : AnalysisUtils.getProviders(deps, LanguageDependentFragment.class)) { LanguageDependentFragment.Checker.depSupportsLanguage( ruleContext, dep, CppRuleClasses.LANGUAGE); } } CppModel model = initializeCppModel(); CppCompilationContext cppCompilationContext = initializeCppCompilationContext(model); model.setContext(cppCompilationContext); boolean compileHeaderModules = featureConfiguration.isEnabled(CppRuleClasses.HEADER_MODULES); Preconditions.checkState( !compileHeaderModules || cppCompilationContext.getCppModuleMap() != null, "All cc rules must support module maps."); // Create compile actions (both PIC and non-PIC). CcCompilationOutputs ccOutputs = model.createCcCompileActions(); if (!objectFiles.isEmpty() || !picObjectFiles.isEmpty()) { // Merge the pre-compiled object files into the compiler outputs. ccOutputs = new CcCompilationOutputs.Builder() .merge(ccOutputs) .addLTOBitcodeFile(ccOutputs.getLtoBitcodeFiles()) .addObjectFiles(objectFiles) .addPicObjectFiles(picObjectFiles) .build(); } // Create link actions (only if there are object files or if explicitly requested). CcLinkingOutputs ccLinkingOutputs = CcLinkingOutputs.EMPTY; if (emitLinkActionsIfEmpty || !ccOutputs.isEmpty()) { // On some systems, the linker gives an error message if there are no input files. Even with // the check above, this can still happen if there is a .nopic.o or .o files in srcs, but no // other files. To fix that, we'd have to check for each link action individually. // // An additional pre-existing issue is that the header check tokens are dropped if we don't // generate any link actions, effectively disabling header checking in some cases. if (linkType.isStaticLibraryLink()) { // TODO(bazel-team): This can't create the link action for a cc_binary yet. ccLinkingOutputs = model.createCcLinkActions(ccOutputs); } } CcLinkingOutputs originalLinkingOutputs = ccLinkingOutputs; if (!(staticLibraries.isEmpty() && picStaticLibraries.isEmpty() && dynamicLibraries.isEmpty())) { // Merge the pre-compiled libraries (static & dynamic) into the linker outputs. ccLinkingOutputs = new CcLinkingOutputs.Builder() .merge(ccLinkingOutputs) .addStaticLibraries(staticLibraries) .addPicStaticLibraries(picStaticLibraries) .addDynamicLibraries(dynamicLibraries) .addExecutionDynamicLibraries(dynamicLibraries) .build(); } DwoArtifactsCollector dwoArtifacts = DwoArtifactsCollector.transitiveCollector(ccOutputs, deps); Runfiles cppStaticRunfiles = collectCppRunfiles(ccLinkingOutputs, true); Runfiles cppSharedRunfiles = collectCppRunfiles(ccLinkingOutputs, false); // By very careful when adding new providers here - it can potentially affect a lot of rules. // We should consider merging most of these providers into a single provider. Map<Class<? extends TransitiveInfoProvider>, TransitiveInfoProvider> providers = new LinkedHashMap<>(); providers.put( CppRunfilesProvider.class, new CppRunfilesProvider(cppStaticRunfiles, cppSharedRunfiles)); providers.put(CppCompilationContext.class, cppCompilationContext); providers.put( CppDebugFileProvider.class, new CppDebugFileProvider( dwoArtifacts.getDwoArtifacts(), dwoArtifacts.getPicDwoArtifacts())); providers.put(TransitiveLipoInfoProvider.class, collectTransitiveLipoInfo(ccOutputs)); Map<String, NestedSet<Artifact>> outputGroups = new TreeMap<>(); outputGroups.put(OutputGroupProvider.TEMP_FILES, getTemps(ccOutputs)); if (emitCompileProviders) { boolean isLipoCollector = ruleContext.getFragment(CppConfiguration.class).isLipoContextCollector(); boolean processHeadersInDependencies = ruleContext.getFragment(CppConfiguration.class).processHeadersInDependencies(); boolean usePic = CppHelper.usePic(ruleContext, false); outputGroups.put( OutputGroupProvider.FILES_TO_COMPILE, ccOutputs.getFilesToCompile(isLipoCollector, processHeadersInDependencies, usePic)); outputGroups.put( OutputGroupProvider.COMPILATION_PREREQUISITES, CcCommon.collectCompilationPrerequisites(ruleContext, cppCompilationContext)); } // TODO(bazel-team): Maybe we can infer these from other data at the places where they are // used. if (emitCcNativeLibrariesProvider) { providers.put( CcNativeLibraryProvider.class, new CcNativeLibraryProvider(collectNativeCcLibraries(ccLinkingOutputs))); } providers.put( CcExecutionDynamicLibrariesProvider.class, collectExecutionDynamicLibraryArtifacts(ccLinkingOutputs.getExecutionDynamicLibraries())); boolean forcePic = ruleContext.getFragment(CppConfiguration.class).forcePic(); if (emitCcSpecificLinkParamsProvider) { providers.put( CcSpecificLinkParamsProvider.class, new CcSpecificLinkParamsProvider( createCcLinkParamsStore(ccLinkingOutputs, cppCompilationContext, forcePic))); } else { providers.put( CcLinkParamsProvider.class, new CcLinkParamsProvider( createCcLinkParamsStore(ccLinkingOutputs, cppCompilationContext, forcePic))); } return new Info( providers, outputGroups, ccOutputs, ccLinkingOutputs, originalLinkingOutputs, cppCompilationContext); } /** Creates the C/C++ compilation action creator. */ private CppModel initializeCppModel() { return new CppModel(ruleContext, semantics) .addCompilationUnitSources(compilationUnitSources) .addCopts(copts) .setLinkTargetType(linkType) .setNeverLink(neverlink) .setFake(fake) .setAllowInterfaceSharedObjects(emitInterfaceSharedObjects) .setCreateDynamicLibrary(emitDynamicLibrary) // Note: this doesn't actually save the temps, it just makes the CppModel use the // configurations --save_temps setting to decide whether to actually save the temps. .setSaveTemps(true) .setNoCopts(nocopts) .setDynamicLibrary(dynamicLibrary) .addLinkopts(linkopts) .setFeatureConfiguration(featureConfiguration); } /** Create context for cc compile action from generated inputs. */ private CppCompilationContext initializeCppCompilationContext(CppModel model) { CppCompilationContext.Builder contextBuilder = new CppCompilationContext.Builder(ruleContext); // Setup the include path; local include directories come before those inherited from deps or // from the toolchain; in case of aliasing (same include file found on different entries), // prefer the local include rather than the inherited one. // Add in the roots for well-formed include names for source files and // generated files. It is important that the execRoot (EMPTY_FRAGMENT) comes // before the genfilesFragment to preferably pick up source files. Otherwise // we might pick up stale generated files. PathFragment repositoryPath = ruleContext.getLabel().getPackageIdentifier().getRepository().getPathFragment(); contextBuilder.addQuoteIncludeDir(repositoryPath); contextBuilder.addQuoteIncludeDir( ruleContext.getConfiguration().getGenfilesFragment().getRelative(repositoryPath)); for (PathFragment systemIncludeDir : systemIncludeDirs) { contextBuilder.addSystemIncludeDir(systemIncludeDir); } for (PathFragment includeDir : includeDirs) { contextBuilder.addIncludeDir(includeDir); } contextBuilder.mergeDependentContexts( AnalysisUtils.getProviders(deps, CppCompilationContext.class)); CppHelper.mergeToolchainDependentContext(ruleContext, contextBuilder); // But defines come after those inherited from deps. contextBuilder.addDefines(defines); // There are no ordering constraints for declared include dirs/srcs, or the pregrepped headers. contextBuilder.addDeclaredIncludeSrcs(publicHeaders); contextBuilder.addDeclaredIncludeSrcs(publicTextualHeaders); contextBuilder.addDeclaredIncludeSrcs(privateHeaders); contextBuilder.addPregreppedHeaderMap( CppHelper.createExtractInclusions(ruleContext, semantics, publicHeaders)); contextBuilder.addPregreppedHeaderMap( CppHelper.createExtractInclusions(ruleContext, semantics, publicTextualHeaders)); contextBuilder.addPregreppedHeaderMap( CppHelper.createExtractInclusions(ruleContext, semantics, privateHeaders)); contextBuilder.addCompilationPrerequisites(prerequisites); // Add this package's dir to declaredIncludeDirs, & this rule's headers to declaredIncludeSrcs // Note: no include dir for STRICT mode. if (headersCheckingMode == HeadersCheckingMode.WARN) { contextBuilder.addDeclaredIncludeWarnDir(ruleContext.getLabel().getPackageFragment()); for (PathFragment looseIncludeDir : looseIncludeDirs) { contextBuilder.addDeclaredIncludeWarnDir(looseIncludeDir); } } else if (headersCheckingMode == HeadersCheckingMode.LOOSE) { contextBuilder.addDeclaredIncludeDir(ruleContext.getLabel().getPackageFragment()); for (PathFragment looseIncludeDir : looseIncludeDirs) { contextBuilder.addDeclaredIncludeDir(looseIncludeDir); } } if (featureConfiguration.isEnabled(CppRuleClasses.MODULE_MAPS)) { CppModuleMap cppModuleMap = CppHelper.addCppModuleMapToContext(ruleContext, contextBuilder); // TODO(bazel-team): addCppModuleMapToContext second-guesses whether module maps should // actually be enabled, so we need to double-check here. Who would write code like this? if (cppModuleMap != null) { CppModuleMapAction action = new CppModuleMapAction( ruleContext.getActionOwner(), cppModuleMap, privateHeaders, publicHeaders, collectModuleMaps(), additionalExportedHeaders, featureConfiguration.isEnabled(CppRuleClasses.HEADER_MODULES), featureConfiguration.isEnabled(CppRuleClasses.MODULE_MAP_HOME_CWD), featureConfiguration.isEnabled(CppRuleClasses.GENERATE_SUBMODULES), !featureConfiguration.isEnabled(CppRuleClasses.MODULE_MAP_WITHOUT_EXTERN_MODULE)); ruleContext.registerAction(action); } if (model.getGeneratesPicHeaderModule()) { contextBuilder.setPicHeaderModule(model.getPicHeaderModule(cppModuleMap.getArtifact())); } if (model.getGeneratesNoPicHeaderModule()) { contextBuilder.setHeaderModule(model.getHeaderModule(cppModuleMap.getArtifact())); } if (featureConfiguration.isEnabled(CppRuleClasses.USE_HEADER_MODULES) && featureConfiguration.isEnabled(CppRuleClasses.TRANSITIVE_MODULE_MAPS)) { contextBuilder.setProvideTransitiveModuleMaps(true); } } semantics.setupCompilationContext(ruleContext, contextBuilder); return contextBuilder.build(); } /** Creates context for cc compile action from generated inputs. */ public CppCompilationContext initializeCppCompilationContext() { return initializeCppCompilationContext(initializeCppModel()); } private Iterable<CppModuleMap> collectModuleMaps() { // Cpp module maps may be null for some rules. We filter the nulls out at the end. List<CppModuleMap> result = new ArrayList<>(); Iterables.addAll(result, Iterables.transform(deps, CPP_DEPS_TO_MODULES)); if (ruleContext.getRule().getAttributeDefinition(":stl") != null) { CppCompilationContext stl = ruleContext.getPrerequisite(":stl", Mode.TARGET, CppCompilationContext.class); if (stl != null) { result.add(stl.getCppModuleMap()); } } CcToolchainProvider toolchain = CppHelper.getToolchain(ruleContext); if (toolchain != null) { result.add(toolchain.getCppCompilationContext().getCppModuleMap()); } return Iterables.filter(result, Predicates.<CppModuleMap>notNull()); } private TransitiveLipoInfoProvider collectTransitiveLipoInfo(CcCompilationOutputs outputs) { if (CppHelper.getFdoSupport(ruleContext).getFdoRoot() == null) { return TransitiveLipoInfoProvider.EMPTY; } NestedSetBuilder<IncludeScannable> scannableBuilder = NestedSetBuilder.stableOrder(); // TODO(bazel-team): Only fetch the STL prerequisite in one place. TransitiveInfoCollection stl = ruleContext.getPrerequisite(":stl", Mode.TARGET); if (stl != null) { TransitiveLipoInfoProvider provider = stl.getProvider(TransitiveLipoInfoProvider.class); if (provider != null) { scannableBuilder.addTransitive(provider.getTransitiveIncludeScannables()); } } for (TransitiveLipoInfoProvider dep : AnalysisUtils.getProviders(deps, TransitiveLipoInfoProvider.class)) { scannableBuilder.addTransitive(dep.getTransitiveIncludeScannables()); } for (IncludeScannable scannable : outputs.getLipoScannables()) { Preconditions.checkState(scannable.getIncludeScannerSources().size() == 1); scannableBuilder.add(scannable); } return new TransitiveLipoInfoProvider(scannableBuilder.build()); } private Runfiles collectCppRunfiles( CcLinkingOutputs ccLinkingOutputs, boolean linkingStatically) { Runfiles.Builder builder = new Runfiles.Builder(ruleContext.getWorkspaceName()); builder.addTargets(deps, RunfilesProvider.DEFAULT_RUNFILES); builder.addTargets(deps, CppRunfilesProvider.runfilesFunction(linkingStatically)); // Add the shared libraries to the runfiles. builder.addArtifacts(ccLinkingOutputs.getLibrariesForRunfiles(linkingStatically)); return builder.build(); } private CcLinkParamsStore createCcLinkParamsStore( final CcLinkingOutputs ccLinkingOutputs, final CppCompilationContext cppCompilationContext, final boolean forcePic) { return new CcLinkParamsStore() { @Override protected void collect( CcLinkParams.Builder builder, boolean linkingStatically, boolean linkShared) { builder.addLinkstamps(linkstamps, cppCompilationContext); builder.addTransitiveTargets( deps, CcLinkParamsProvider.TO_LINK_PARAMS, CcSpecificLinkParamsProvider.TO_LINK_PARAMS); if (!neverlink) { builder.addLibraries( ccLinkingOutputs.getPreferredLibraries( linkingStatically, /*preferPic=*/ linkShared || forcePic)); builder.addLinkOpts(linkopts); } } }; } private NestedSet<LinkerInput> collectNativeCcLibraries(CcLinkingOutputs ccLinkingOutputs) { NestedSetBuilder<LinkerInput> result = NestedSetBuilder.linkOrder(); result.addAll(ccLinkingOutputs.getDynamicLibraries()); for (CcNativeLibraryProvider dep : AnalysisUtils.getProviders(deps, CcNativeLibraryProvider.class)) { result.addTransitive(dep.getTransitiveCcNativeLibraries()); } return result.build(); } private CcExecutionDynamicLibrariesProvider collectExecutionDynamicLibraryArtifacts( List<LibraryToLink> executionDynamicLibraries) { Iterable<Artifact> artifacts = LinkerInputs.toLibraryArtifacts(executionDynamicLibraries); if (!Iterables.isEmpty(artifacts)) { return new CcExecutionDynamicLibrariesProvider( NestedSetBuilder.wrap(Order.STABLE_ORDER, artifacts)); } NestedSetBuilder<Artifact> builder = NestedSetBuilder.stableOrder(); for (CcExecutionDynamicLibrariesProvider dep : AnalysisUtils.getProviders(deps, CcExecutionDynamicLibrariesProvider.class)) { builder.addTransitive(dep.getExecutionDynamicLibraryArtifacts()); } return builder.isEmpty() ? CcExecutionDynamicLibrariesProvider.EMPTY : new CcExecutionDynamicLibrariesProvider(builder.build()); } private NestedSet<Artifact> getTemps(CcCompilationOutputs compilationOutputs) { return ruleContext.getFragment(CppConfiguration.class).isLipoContextCollector() ? NestedSetBuilder.<Artifact>emptySet(Order.STABLE_ORDER) : compilationOutputs.getTemps(); } }
private static ConfiguredTarget addStructFieldsAndBuild( RuleContext ruleContext, RuleConfiguredTargetBuilder builder, Object target, Artifact executable, Map<String, Class<? extends TransitiveInfoProvider>> registeredProviderTypes) throws EvalException { Location loc = null; Runfiles statelessRunfiles = null; Runfiles dataRunfiles = null; Runfiles defaultRunfiles = null; if (target instanceof SkylarkClassObject) { SkylarkClassObject struct = (SkylarkClassObject) target; loc = struct.getCreationLoc(); for (String key : struct.getKeys()) { if (key.equals("files")) { // If we specify files_to_build we don't have the executable in it by default. builder.setFilesToBuild( cast("files", struct, SkylarkNestedSet.class, Artifact.class, loc) .getSet(Artifact.class)); } else if (key.equals("runfiles")) { statelessRunfiles = cast("runfiles", struct, Runfiles.class, loc); } else if (key.equals("data_runfiles")) { dataRunfiles = cast("data_runfiles", struct, Runfiles.class, loc); } else if (key.equals("default_runfiles")) { defaultRunfiles = cast("default_runfiles", struct, Runfiles.class, loc); } else if (key.equals("output_groups")) { addOutputGroups(struct.getValue(key), loc, builder); } else if (key.equals("instrumented_files")) { SkylarkClassObject insStruct = cast("instrumented_files", struct, SkylarkClassObject.class, loc); Location insLoc = insStruct.getCreationLoc(); FileTypeSet fileTypeSet = FileTypeSet.ANY_FILE; if (insStruct.getKeys().contains("extensions")) { @SuppressWarnings("unchecked") List<String> exts = cast("extensions", insStruct, SkylarkList.class, String.class, insLoc); if (exts.isEmpty()) { fileTypeSet = FileTypeSet.NO_FILE; } else { FileType[] fileTypes = new FileType[exts.size()]; for (int i = 0; i < fileTypes.length; i++) { fileTypes[i] = FileType.of(exts.get(i)); } fileTypeSet = FileTypeSet.of(fileTypes); } } List<String> dependencyAttributes = Collections.emptyList(); if (insStruct.getKeys().contains("dependency_attributes")) { dependencyAttributes = cast("dependency_attributes", insStruct, SkylarkList.class, String.class, insLoc); } List<String> sourceAttributes = Collections.emptyList(); if (insStruct.getKeys().contains("source_attributes")) { sourceAttributes = cast("source_attributes", insStruct, SkylarkList.class, String.class, insLoc); } InstrumentationSpec instrumentationSpec = new InstrumentationSpec(fileTypeSet) .withSourceAttributes(sourceAttributes.toArray(new String[0])) .withDependencyAttributes(dependencyAttributes.toArray(new String[0])); InstrumentedFilesProvider instrumentedFilesProvider = InstrumentedFilesCollector.collect( ruleContext, instrumentationSpec, InstrumentedFilesCollector.NO_METADATA_COLLECTOR, Collections.<Artifact>emptySet()); builder.addProvider(InstrumentedFilesProvider.class, instrumentedFilesProvider); } else if (registeredProviderTypes.containsKey(key)) { Class<? extends TransitiveInfoProvider> providerType = registeredProviderTypes.get(key); TransitiveInfoProvider provider = cast(key, struct, providerType, loc); builder.addProvider(providerType, provider); } else if (key.equals("providers")) { Iterable iterable = cast(key, struct, Iterable.class, loc); for (Object o : iterable) { SkylarkClassObject declaredProvider = SkylarkType.cast( o, SkylarkClassObject.class, loc, "The value of 'providers' should be a sequence of declared providers"); builder.addSkylarkDeclaredProvider(declaredProvider, loc); } } else if (!key.equals("executable")) { // We handled executable already. builder.addSkylarkTransitiveInfo(key, struct.getValue(key), loc); } } } else if (target instanceof Iterable) { loc = ruleContext.getRule().getRuleClassObject().getConfiguredTargetFunction().getLocation(); for (Object o : (Iterable) target) { SkylarkClassObject declaredProvider = SkylarkType.cast( o, SkylarkClassObject.class, loc, "A return value of rule implementation function should be " + "a sequence of declared providers"); Location creationLoc = declaredProvider.getCreationLocOrNull(); builder.addSkylarkDeclaredProvider( declaredProvider, creationLoc != null ? creationLoc : loc); } } if ((statelessRunfiles != null) && (dataRunfiles != null || defaultRunfiles != null)) { throw new EvalException( loc, "Cannot specify the provider 'runfiles' " + "together with 'data_runfiles' or 'default_runfiles'"); } if (statelessRunfiles == null && dataRunfiles == null && defaultRunfiles == null) { // No runfiles specified, set default statelessRunfiles = Runfiles.EMPTY; } RunfilesProvider runfilesProvider = statelessRunfiles != null ? RunfilesProvider.simple(merge(statelessRunfiles, executable, ruleContext)) : RunfilesProvider.withData( // The executable doesn't get into the default runfiles if we have runfiles states. // This is to keep skylark genrule consistent with the original genrule. defaultRunfiles != null ? defaultRunfiles : Runfiles.EMPTY, dataRunfiles != null ? dataRunfiles : Runfiles.EMPTY); builder.addProvider(RunfilesProvider.class, runfilesProvider); Runfiles computedDefaultRunfiles = runfilesProvider.getDefaultRunfiles(); // This works because we only allowed to call a rule *_test iff it's a test type rule. boolean testRule = TargetUtils.isTestRuleName(ruleContext.getRule().getRuleClass()); if (testRule && computedDefaultRunfiles.isEmpty()) { throw new EvalException(loc, "Test rules have to define runfiles"); } if (executable != null || testRule) { RunfilesSupport runfilesSupport = computedDefaultRunfiles.isEmpty() ? null : RunfilesSupport.withExecutable(ruleContext, computedDefaultRunfiles, executable); builder.setRunfilesSupport(runfilesSupport, executable); } if (ruleContext.getRule().getRuleClassObject().isSkylarkTestable()) { SkylarkClassObject actions = ActionsProvider.create(ruleContext.getAnalysisEnvironment().getRegisteredActions()); builder.addSkylarkDeclaredProvider(actions, loc); } try { return builder.build(); } catch (IllegalArgumentException e) { throw new EvalException(loc, e.getMessage()); } }