| // Copyright (c) 2013 The Chromium Authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style license that can be |
| // found in the LICENSE file. |
| |
| #include "gn/target.h" |
| |
| #include <stddef.h> |
| |
| #include "base/stl_util.h" |
| #include "base/strings/string_util.h" |
| #include "base/strings/stringprintf.h" |
| #include "gn/c_tool.h" |
| #include "gn/config_values_extractors.h" |
| #include "gn/deps_iterator.h" |
| #include "gn/filesystem_utils.h" |
| #include "gn/functions.h" |
| #include "gn/scheduler.h" |
| #include "gn/substitution_writer.h" |
| #include "gn/tool.h" |
| #include "gn/toolchain.h" |
| #include "gn/trace.h" |
| |
| namespace { |
| |
| using ConfigSet = std::set<const Config*>; |
| |
| // Merges the public configs from the given target to the given config list. |
| void MergePublicConfigsFrom(const Target* from_target, |
| UniqueVector<LabelConfigPair>* dest) { |
| const UniqueVector<LabelConfigPair>& pub = from_target->public_configs(); |
| dest->Append(pub.begin(), pub.end()); |
| } |
| |
| // Like MergePublicConfigsFrom above except does the "all dependent" ones. This |
| // additionally adds all configs to the all_dependent_configs_ of the dest |
| // target given in *all_dest. |
| void MergeAllDependentConfigsFrom(const Target* from_target, |
| UniqueVector<LabelConfigPair>* dest, |
| UniqueVector<LabelConfigPair>* all_dest) { |
| for (const auto& pair : from_target->all_dependent_configs()) { |
| all_dest->push_back(pair); |
| dest->push_back(pair); |
| } |
| } |
| |
| Err MakeTestOnlyError(const Item* from, const Item* to) { |
| return Err( |
| from->defined_from(), "Test-only dependency not allowed.", |
| from->label().GetUserVisibleName(false) + |
| "\n" |
| "which is NOT marked testonly can't depend on\n" + |
| to->label().GetUserVisibleName(false) + |
| "\n" |
| "which is marked testonly. Only targets with \"testonly = true\"\n" |
| "can depend on other test-only targets.\n" |
| "\n" |
| "Either mark it test-only or don't do this dependency."); |
| } |
| |
| // Set check_private_deps to true for the first invocation since a target |
| // can see all of its dependencies. For recursive invocations this will be set |
| // to false to follow only public dependency paths. |
| // |
| // Pass a pointer to an empty set for the first invocation. This will be used |
| // to avoid duplicate checking. |
| // |
| // Checking of object files is optional because it is much slower. This allows |
| // us to check targets for normal outputs, and then as a second pass check |
| // object files (since we know it will be an error otherwise). This allows |
| // us to avoid computing all object file names in the common case. |
| bool EnsureFileIsGeneratedByDependency(const Target* target, |
| const OutputFile& file, |
| bool check_private_deps, |
| bool consider_object_files, |
| bool check_data_deps, |
| TargetSet* seen_targets) { |
| if (!seen_targets->add(target)) |
| return false; // Already checked this one and it's not found. |
| |
| // Assume that we have relatively few generated inputs so brute-force |
| // searching here is OK. If this becomes a bottleneck, consider storing |
| // computed_outputs as a hash set. |
| for (const OutputFile& cur : target->computed_outputs()) { |
| if (file == cur) |
| return true; |
| } |
| |
| if (file == target->write_runtime_deps_output()) |
| return true; |
| |
| // Check binary target intermediate files if requested. |
| if (consider_object_files && target->IsBinary()) { |
| std::vector<OutputFile> source_outputs; |
| for (const SourceFile& source : target->sources()) { |
| const char* tool_name; |
| if (!target->GetOutputFilesForSource(source, &tool_name, &source_outputs)) |
| continue; |
| if (base::ContainsValue(source_outputs, file)) |
| return true; |
| } |
| } |
| |
| if (check_data_deps) { |
| check_data_deps = false; // Consider only direct data_deps. |
| for (const auto& pair : target->data_deps()) { |
| if (EnsureFileIsGeneratedByDependency(pair.ptr, file, false, |
| consider_object_files, |
| check_data_deps, seen_targets)) |
| return true; // Found a path. |
| } |
| } |
| |
| // Check all public dependencies (don't do data ones since those are |
| // runtime-only). |
| for (const auto& pair : target->public_deps()) { |
| if (EnsureFileIsGeneratedByDependency(pair.ptr, file, false, |
| consider_object_files, |
| check_data_deps, seen_targets)) |
| return true; // Found a path. |
| } |
| |
| // Only check private deps if requested. |
| if (check_private_deps) { |
| for (const auto& pair : target->private_deps()) { |
| if (EnsureFileIsGeneratedByDependency(pair.ptr, file, false, |
| consider_object_files, |
| check_data_deps, seen_targets)) |
| return true; // Found a path. |
| } |
| if (target->output_type() == Target::CREATE_BUNDLE) { |
| for (auto* dep : target->bundle_data().bundle_deps()) { |
| if (EnsureFileIsGeneratedByDependency(dep, file, false, |
| consider_object_files, |
| check_data_deps, seen_targets)) |
| return true; // Found a path. |
| } |
| } |
| } |
| return false; |
| } |
| |
| // check_this indicates if the given target should be matched against the |
| // patterns. It should be set to false for the first call since assert_no_deps |
| // shouldn't match the target itself. |
| // |
| // visited should point to an empty set, this will be used to prevent |
| // multiple visits. |
| // |
| // *failure_path_str will be filled with a string describing the path of the |
| // dependency failure, and failure_pattern will indicate the pattern in |
| // assert_no that matched the target. |
| // |
| // Returns true if everything is OK. failure_path_str and failure_pattern_index |
| // will be unchanged in this case. |
| bool RecursiveCheckAssertNoDeps(const Target* target, |
| bool check_this, |
| const std::vector<LabelPattern>& assert_no, |
| TargetSet* visited, |
| std::string* failure_path_str, |
| const LabelPattern** failure_pattern) { |
| static const char kIndentPath[] = " "; |
| |
| if (!visited->add(target)) |
| return true; // Already checked this target. |
| |
| if (check_this) { |
| // Check this target against the given list of patterns. |
| for (const LabelPattern& pattern : assert_no) { |
| if (pattern.Matches(target->label())) { |
| // Found a match. |
| *failure_pattern = &pattern; |
| *failure_path_str = |
| kIndentPath + target->label().GetUserVisibleName(false); |
| return false; |
| } |
| } |
| } |
| |
| // Recursively check dependencies. |
| for (const auto& pair : target->GetDeps(Target::DEPS_ALL)) { |
| if (pair.ptr->output_type() == Target::EXECUTABLE) |
| continue; |
| if (!RecursiveCheckAssertNoDeps(pair.ptr, true, assert_no, visited, |
| failure_path_str, failure_pattern)) { |
| // To reconstruct the path, prepend the current target to the error. |
| std::string prepend_path = |
| kIndentPath + target->label().GetUserVisibleName(false) + " ->\n"; |
| failure_path_str->insert(0, prepend_path); |
| return false; |
| } |
| } |
| |
| return true; |
| } |
| |
| } // namespace |
| |
| const char kExecution_Help[] = |
| R"(Build graph and execution overview |
| |
| Overall build flow |
| |
| 1. Look for ".gn" file (see "gn help dotfile") in the current directory and |
| walk up the directory tree until one is found. Set this directory to be |
| the "source root" and interpret this file to find the name of the build |
| config file. |
| |
| 2. Execute the build config file identified by .gn to set up the global |
| variables and default toolchain name. Any arguments, variables, defaults, |
| etc. set up in this file will be visible to all files in the build. |
| |
| 3. Load the //BUILD.gn (in the source root directory). |
| |
| 4. Recursively evaluate rules and load BUILD.gn in other directories as |
| necessary to resolve dependencies. If a BUILD file isn't found in the |
| specified location, GN will look in the corresponding location inside |
| the secondary_source defined in the dotfile (see "gn help dotfile"). |
| |
| 5. When a target's dependencies are resolved, write out the `.ninja` |
| file to disk. |
| |
| 6. When all targets are resolved, write out the root build.ninja file. |
| |
| Note that the BUILD.gn file name may be modulated by .gn arguments such as |
| build_file_extension. |
| |
| Executing target definitions and templates |
| |
| Build files are loaded in parallel. This means it is impossible to |
| interrogate a target from GN code for any information not derivable from its |
| label (see "gn help label"). The exception is the get_target_outputs() |
| function which requires the target being interrogated to have been defined |
| previously in the same file. |
| |
| Targets are declared by their type and given a name: |
| |
| static_library("my_static_library") { |
| ... target parameter definitions ... |
| } |
| |
| There is also a generic "target" function for programmatically defined types |
| (see "gn help target"). You can define new types using templates (see "gn |
| help template"). A template defines some custom code that expands to one or |
| more other targets. |
| |
| Before executing the code inside the target's { }, the target defaults are |
| applied (see "gn help set_defaults"). It will inject implicit variable |
| definitions that can be overridden by the target code as necessary. Typically |
| this mechanism is used to inject a default set of configs that define the |
| global compiler and linker flags. |
| |
| Which targets are built |
| |
| All targets encountered in the default toolchain (see "gn help toolchain") |
| will have build rules generated for them, even if no other targets reference |
| them. Their dependencies must resolve and they will be added to the implicit |
| "all" rule (see "gn help ninja_rules"). |
| |
| Targets in non-default toolchains will only be generated when they are |
| required (directly or transitively) to build a target in the default |
| toolchain. |
| |
| Some targets might be associated but without a formal build dependency (for |
| example, related tools or optional variants). A target that is marked as |
| "generated" can propagate its generated state to an associated target using |
| "gen_deps". This will make the referenced dependency have Ninja rules |
| generated in the same cases the source target has but without a build-time |
| dependency and even in non-default toolchains. |
| |
| See also "gn help ninja_rules". |
| |
| Dependencies |
| |
| The only difference between "public_deps" and "deps" except for pushing |
| configs around the build tree and allowing includes for the purposes of "gn |
| check". |
| |
| A target's "data_deps" are guaranteed to be built whenever the target is |
| built, but the ordering is not defined. The meaning of this is dependencies |
| required at runtime. Currently data deps will be complete before the target |
| is linked, but this is not semantically guaranteed and this is undesirable |
| from a build performance perspective. Since we hope to change this in the |
| future, do not rely on this behavior. |
| )"; |
| |
| Target::Target(const Settings* settings, |
| const Label& label, |
| const SourceFileSet& build_dependency_files) |
| : Item(settings, label, build_dependency_files) {} |
| |
| Target::~Target() = default; |
| |
| // A technical note on accessors defined below: Using a static global |
| // constant is much faster at runtime than using a static local one. |
| // |
| // In other words: |
| // |
| // static const Foo kEmptyFoo; |
| // |
| // const Foo& Target::foo() const { |
| // return foo_ ? *foo_ : kEmptyFoo; |
| // } |
| // |
| // Is considerably faster than: |
| // |
| // const Foo& Target::foo() const { |
| // if (foo_) { |
| // return *foo_; |
| // } else { |
| // static const Foo kEmptyFoo; |
| // return kEmptyFoo; |
| // } |
| // } |
| // |
| // Because the latter requires relatively expensive atomic operations |
| // in the second branch. |
| // |
| |
| static const BundleData kEmptyBundleData; |
| |
| const BundleData& Target::bundle_data() const { |
| return bundle_data_ ? *bundle_data_ : kEmptyBundleData; |
| } |
| |
| BundleData& Target::bundle_data() { |
| if (!bundle_data_) |
| bundle_data_ = std::make_unique<BundleData>(); |
| return *bundle_data_; |
| } |
| |
| static ConfigValues kEmptyConfigValues; |
| |
| const ConfigValues& Target::config_values() const { |
| return config_values_ ? *config_values_ : kEmptyConfigValues; |
| } |
| |
| ConfigValues& Target::config_values() { |
| if (!config_values_) |
| config_values_ = std::make_unique<ConfigValues>(); |
| return *config_values_; |
| } |
| |
| static const ActionValues kEmptyActionValues; |
| |
| const ActionValues& Target::action_values() const { |
| return action_values_ ? *action_values_ : kEmptyActionValues; |
| } |
| |
| ActionValues& Target::action_values() { |
| if (!action_values_) |
| action_values_ = std::make_unique<ActionValues>(); |
| return *action_values_; |
| } |
| |
| static const RustValues kEmptyRustValues; |
| |
| const RustValues& Target::rust_values() const { |
| return rust_values_ ? *rust_values_ : kEmptyRustValues; |
| } |
| |
| RustValues& Target::rust_values() { |
| if (!rust_values_) |
| rust_values_ = std::make_unique<RustValues>(); |
| return *rust_values_; |
| } |
| |
| static const SwiftValues kEmptySwiftValues; |
| |
| const SwiftValues& Target::swift_values() const { |
| return swift_values_ ? *swift_values_ : kEmptySwiftValues; |
| } |
| |
| SwiftValues& Target::swift_values() { |
| if (!swift_values_) |
| swift_values_ = std::make_unique<SwiftValues>(); |
| return *swift_values_; |
| } |
| |
| static const Metadata kEmptyMetadata; |
| |
| const Metadata& Target::metadata() const { |
| return metadata_ ? *metadata_ : kEmptyMetadata; |
| } |
| |
| Metadata& Target::metadata() { |
| if (!metadata_) |
| metadata_ = std::make_unique<Metadata>(); |
| return *metadata_; |
| } |
| |
| static const Target::GeneratedFile kEmptyGeneratedFile; |
| |
| const Target::GeneratedFile& Target::generated_file() const { |
| return generated_file_ ? *generated_file_ : kEmptyGeneratedFile; |
| } |
| |
| Target::GeneratedFile& Target::generated_file() { |
| if (!generated_file_) |
| generated_file_ = std::make_unique<Target::GeneratedFile>(); |
| return *generated_file_; |
| } |
| |
| // static |
| const char* Target::GetStringForOutputType(OutputType type) { |
| switch (type) { |
| case UNKNOWN: |
| return "unknown"; |
| case GROUP: |
| return functions::kGroup; |
| case EXECUTABLE: |
| return functions::kExecutable; |
| case LOADABLE_MODULE: |
| return functions::kLoadableModule; |
| case SHARED_LIBRARY: |
| return functions::kSharedLibrary; |
| case STATIC_LIBRARY: |
| return functions::kStaticLibrary; |
| case SOURCE_SET: |
| return functions::kSourceSet; |
| case COPY_FILES: |
| return functions::kCopy; |
| case ACTION: |
| return functions::kAction; |
| case ACTION_FOREACH: |
| return functions::kActionForEach; |
| case BUNDLE_DATA: |
| return functions::kBundleData; |
| case CREATE_BUNDLE: |
| return functions::kCreateBundle; |
| case GENERATED_FILE: |
| return functions::kGeneratedFile; |
| case RUST_LIBRARY: |
| return functions::kRustLibrary; |
| case RUST_PROC_MACRO: |
| return functions::kRustProcMacro; |
| default: |
| return ""; |
| } |
| } |
| |
| Target* Target::AsTarget() { |
| return this; |
| } |
| |
| const Target* Target::AsTarget() const { |
| return this; |
| } |
| |
| bool Target::OnResolved(Err* err) { |
| DCHECK(output_type_ != UNKNOWN); |
| DCHECK(toolchain_) << "Toolchain should have been set before resolving."; |
| |
| ScopedTrace trace(TraceItem::TRACE_ON_RESOLVED, label()); |
| trace.SetToolchain(settings()->toolchain_label()); |
| |
| // Copy this target's own dependent and public configs to the list of configs |
| // applying to it. |
| configs_.Append(all_dependent_configs_.begin(), all_dependent_configs_.end()); |
| MergePublicConfigsFrom(this, &configs_); |
| |
| // Check visibility for just this target's own configs, before dependents are |
| // added, but after public_configs and all_dependent_configs are merged. |
| if (!CheckConfigVisibility(err)) |
| return false; |
| |
| // Copy public configs from all dependencies into the list of configs |
| // applying to this target (configs_). |
| PullDependentTargetConfigs(); |
| |
| // Copies public dependencies' public configs to this target's public |
| // configs. These configs have already been applied to this target by |
| // PullDependentTargetConfigs above, along with the public configs from |
| // private deps. This step re-exports them as public configs for targets that |
| // depend on this one. |
| for (const auto& dep : public_deps_) { |
| if (dep.ptr->toolchain() == toolchain() || |
| dep.ptr->toolchain()->propagates_configs()) |
| public_configs_.Append(dep.ptr->public_configs().begin(), |
| dep.ptr->public_configs().end()); |
| } |
| |
| // Copy our own libs and lib_dirs to the final set. This will be from our |
| // target and all of our configs. We do this specially since these must be |
| // inherited through the dependency tree (other flags don't work this way). |
| // |
| // This needs to happen after we pull dependent target configs for the |
| // public config's libs to be included here. And it needs to happen |
| // before pulling the dependent target libs so the libs are in the correct |
| // order (local ones first, then the dependency's). |
| for (ConfigValuesIterator iter(this); !iter.done(); iter.Next()) { |
| const ConfigValues& cur = iter.cur(); |
| all_lib_dirs_.Append(cur.lib_dirs().begin(), cur.lib_dirs().end()); |
| all_libs_.Append(cur.libs().begin(), cur.libs().end()); |
| |
| all_framework_dirs_.Append(cur.framework_dirs().begin(), |
| cur.framework_dirs().end()); |
| all_frameworks_.Append(cur.frameworks().begin(), cur.frameworks().end()); |
| all_weak_frameworks_.Append(cur.weak_frameworks().begin(), |
| cur.weak_frameworks().end()); |
| } |
| |
| PullRecursiveBundleData(); |
| PullDependentTargetLibs(); |
| PullRecursiveHardDeps(); |
| if (!ResolvePrecompiledHeaders(err)) |
| return false; |
| |
| if (!FillOutputFiles(err)) |
| return false; |
| |
| if (!SwiftValues::OnTargetResolved(this, err)) |
| return false; |
| |
| if (!CheckSourceSetLanguages(err)) |
| return false; |
| if (!CheckVisibility(err)) |
| return false; |
| if (!CheckTestonly(err)) |
| return false; |
| if (!CheckAssertNoDeps(err)) |
| return false; |
| CheckSourcesGenerated(); |
| |
| if (!write_runtime_deps_output_.value().empty()) |
| g_scheduler->AddWriteRuntimeDepsTarget(this); |
| |
| if (output_type_ == GENERATED_FILE) { |
| DCHECK(!computed_outputs_.empty()); |
| g_scheduler->AddGeneratedFile( |
| computed_outputs_[0].AsSourceFile(settings()->build_settings())); |
| } |
| |
| return true; |
| } |
| |
| bool Target::IsBinary() const { |
| return output_type_ == EXECUTABLE || output_type_ == SHARED_LIBRARY || |
| output_type_ == LOADABLE_MODULE || output_type_ == STATIC_LIBRARY || |
| output_type_ == SOURCE_SET || output_type_ == RUST_LIBRARY || |
| output_type_ == RUST_PROC_MACRO; |
| } |
| |
| bool Target::IsLinkable() const { |
| return output_type_ == STATIC_LIBRARY || output_type_ == SHARED_LIBRARY || |
| output_type_ == RUST_LIBRARY || output_type_ == RUST_PROC_MACRO; |
| } |
| |
| bool Target::IsFinal() const { |
| return output_type_ == EXECUTABLE || output_type_ == SHARED_LIBRARY || |
| output_type_ == LOADABLE_MODULE || output_type_ == ACTION || |
| output_type_ == ACTION_FOREACH || output_type_ == COPY_FILES || |
| output_type_ == CREATE_BUNDLE || output_type_ == RUST_PROC_MACRO || |
| (output_type_ == STATIC_LIBRARY && complete_static_lib_); |
| } |
| |
| bool Target::IsDataOnly() const { |
| // BUNDLE_DATA exists only to declare inputs to subsequent CREATE_BUNDLE |
| // targets. Changing only contents of the bundle data target should not cause |
| // a binary to be re-linked. It should affect only the CREATE_BUNDLE steps |
| // instead. As a result, normal targets should treat this as a data |
| // dependency. |
| return output_type_ == BUNDLE_DATA; |
| } |
| |
| DepsIteratorRange Target::GetDeps(DepsIterationType type) const { |
| if (type == DEPS_LINKED) { |
| return DepsIteratorRange( |
| DepsIterator(&public_deps_, &private_deps_, nullptr)); |
| } |
| // All deps. |
| return DepsIteratorRange( |
| DepsIterator(&public_deps_, &private_deps_, &data_deps_)); |
| } |
| |
| std::string Target::GetComputedOutputName() const { |
| DCHECK(toolchain_) |
| << "Toolchain must be specified before getting the computed output name."; |
| |
| const std::string& name = |
| output_name_.empty() ? label().name() : output_name_; |
| |
| std::string result; |
| const Tool* tool = toolchain_->GetToolForTargetFinalOutput(this); |
| if (tool) { |
| // Only add the prefix if the name doesn't already have it and it's not |
| // being overridden. |
| if (!output_prefix_override_ && |
| !base::StartsWith(name, tool->output_prefix(), |
| base::CompareCase::SENSITIVE)) |
| result = tool->output_prefix(); |
| } |
| result.append(name); |
| return result; |
| } |
| |
| bool Target::SetToolchain(const Toolchain* toolchain, Err* err) { |
| DCHECK(!toolchain_); |
| DCHECK_NE(UNKNOWN, output_type_); |
| toolchain_ = toolchain; |
| |
| const Tool* tool = toolchain->GetToolForTargetFinalOutput(this); |
| if (tool) |
| return true; |
| |
| // Tool not specified for this target type. |
| if (err) { |
| *err = |
| Err(defined_from(), "This target uses an undefined tool.", |
| base::StringPrintf( |
| "The target %s\n" |
| "of type \"%s\"\n" |
| "uses toolchain %s\n" |
| "which doesn't have the tool \"%s\" defined.\n\n" |
| "Alas, I can not continue.", |
| label().GetUserVisibleName(false).c_str(), |
| GetStringForOutputType(output_type_), |
| label().GetToolchainLabel().GetUserVisibleName(false).c_str(), |
| Tool::GetToolTypeForTargetFinalOutput(this))); |
| } |
| return false; |
| } |
| |
| bool Target::GetOutputsAsSourceFiles(const LocationRange& loc_for_error, |
| bool build_complete, |
| std::vector<SourceFile>* outputs, |
| Err* err) const { |
| const static char kBuildIncompleteMsg[] = |
| "This target is a binary target which can't be queried for its " |
| "outputs\nduring the build. It will work for action, action_foreach, " |
| "generated_file,\nand copy targets."; |
| |
| outputs->clear(); |
| |
| std::vector<SourceFile> files; |
| if (output_type() == Target::ACTION || output_type() == Target::COPY_FILES || |
| output_type() == Target::ACTION_FOREACH || |
| output_type() == Target::GENERATED_FILE) { |
| action_values().GetOutputsAsSourceFiles(this, outputs); |
| } else if (output_type() == Target::CREATE_BUNDLE) { |
| if (!bundle_data().GetOutputsAsSourceFiles(settings(), this, outputs, err)) |
| return false; |
| } else if (IsBinary() && output_type() != Target::SOURCE_SET) { |
| // Binary target with normal outputs (source sets have stamp outputs like |
| // groups). |
| DCHECK(IsBinary()) << static_cast<int>(output_type()); |
| if (!build_complete) { |
| // Can't access the toolchain for a target before the build is complete. |
| // Otherwise it will race with loading and setting the toolchain |
| // definition. |
| *err = Err(loc_for_error, kBuildIncompleteMsg); |
| return false; |
| } |
| |
| const Tool* tool = toolchain()->GetToolForTargetFinalOutput(this); |
| |
| std::vector<OutputFile> output_files; |
| SubstitutionWriter::ApplyListToLinkerAsOutputFile( |
| this, tool, tool->outputs(), &output_files); |
| for (const OutputFile& output_file : output_files) { |
| outputs->push_back( |
| output_file.AsSourceFile(settings()->build_settings())); |
| } |
| } else { |
| // Everything else (like a group or bundle_data) has a stamp output. The |
| // dependency output file should have computed what this is. This won't be |
| // valid unless the build is complete. |
| if (!build_complete) { |
| *err = Err(loc_for_error, kBuildIncompleteMsg); |
| return false; |
| } |
| outputs->push_back( |
| dependency_output_file().AsSourceFile(settings()->build_settings())); |
| } |
| return true; |
| } |
| |
| bool Target::GetOutputFilesForSource(const SourceFile& source, |
| const char** computed_tool_type, |
| std::vector<OutputFile>* outputs) const { |
| DCHECK(toolchain()); // Should be resolved before calling. |
| |
| outputs->clear(); |
| *computed_tool_type = Tool::kToolNone; |
| |
| if (output_type() == Target::COPY_FILES || |
| output_type() == Target::ACTION_FOREACH) { |
| // These target types apply the output pattern to the input. |
| std::vector<SourceFile> output_files; |
| SubstitutionWriter::ApplyListToSourceAsOutputFile( |
| this, settings(), action_values().outputs(), source, outputs); |
| } else if (!IsBinary()) { |
| // All other non-binary target types just return the target outputs. We |
| // don't know if the build is complete and it doesn't matter for non-binary |
| // targets, so just assume it's not and pass "false". |
| std::vector<SourceFile> outputs_as_source_files; |
| Err err; // We can ignore the error and return empty for failure. |
| GetOutputsAsSourceFiles(LocationRange(), false, &outputs_as_source_files, |
| &err); |
| |
| // Convert to output files. |
| for (const auto& cur : outputs_as_source_files) |
| outputs->emplace_back(OutputFile(settings()->build_settings(), cur)); |
| } else { |
| // All binary targets do a tool lookup. |
| DCHECK(IsBinary()); |
| |
| const SourceFile::Type file_type = source.GetType(); |
| if (file_type == SourceFile::SOURCE_UNKNOWN) |
| return false; |
| if (file_type == SourceFile::SOURCE_O) { |
| // Object files just get passed to the output and not compiled. |
| outputs->emplace_back(OutputFile(settings()->build_settings(), source)); |
| return true; |
| } |
| |
| // Rust generates on a module level, not source. |
| if (file_type == SourceFile::SOURCE_RS) |
| return false; |
| |
| *computed_tool_type = Tool::GetToolTypeForSourceType(file_type); |
| if (*computed_tool_type == Tool::kToolNone) |
| return false; // No tool for this file (it's a header file or something). |
| const Tool* tool = toolchain_->GetTool(*computed_tool_type); |
| if (!tool) |
| return false; // Tool does not apply for this toolchain.file. |
| |
| // Swift may generate on a module or source level. |
| if (file_type == SourceFile::SOURCE_SWIFT) { |
| if (tool->partial_outputs().list().empty()) |
| return false; |
| } |
| |
| const SubstitutionList& substitution_list = |
| file_type == SourceFile::SOURCE_SWIFT ? tool->partial_outputs() |
| : tool->outputs(); |
| |
| // Figure out what output(s) this compiler produces. |
| SubstitutionWriter::ApplyListToCompilerAsOutputFile( |
| this, source, substitution_list, outputs); |
| } |
| return !outputs->empty(); |
| } |
| |
| void Target::PullDependentTargetConfigs() { |
| for (const auto& pair : GetDeps(DEPS_LINKED)) { |
| if (pair.ptr->toolchain() == toolchain() || |
| pair.ptr->toolchain()->propagates_configs()) |
| MergeAllDependentConfigsFrom(pair.ptr, &configs_, |
| &all_dependent_configs_); |
| } |
| for (const auto& pair : GetDeps(DEPS_LINKED)) { |
| if (pair.ptr->toolchain() == toolchain() || |
| pair.ptr->toolchain()->propagates_configs()) |
| MergePublicConfigsFrom(pair.ptr, &configs_); |
| } |
| } |
| |
| void Target::PullDependentTargetLibsFrom(const Target* dep, bool is_public) { |
| // Direct dependent libraries. |
| if (dep->output_type() == STATIC_LIBRARY || |
| dep->output_type() == SHARED_LIBRARY || |
| dep->output_type() == RUST_LIBRARY || |
| dep->output_type() == RUST_PROC_MACRO || |
| dep->output_type() == SOURCE_SET || |
| (dep->output_type() == CREATE_BUNDLE && |
| dep->bundle_data().is_framework())) { |
| inherited_libraries_.Append(dep, is_public); |
| } |
| |
| if (dep->output_type() == STATIC_LIBRARY || |
| dep->output_type() == SHARED_LIBRARY || |
| dep->output_type() == RUST_LIBRARY) { |
| rust_transitive_libs_.Append(dep, is_public); |
| |
| // Propagate public dependent libraries. |
| for (const auto& transitive : |
| dep->rust_transitive_libs_.GetOrderedAndPublicFlag()) { |
| if (transitive.second) { |
| rust_transitive_libs_.Append(transitive.first, is_public); |
| } |
| } |
| } |
| |
| // Rust libraries (those meant for consumption by another Rust target) are |
| // handled the same way, whether static or dynamic. |
| if (dep->output_type() == RUST_LIBRARY || |
| RustValues::InferredCrateType(dep) == RustValues::CRATE_DYLIB) { |
| rust_transitive_libs_.AppendInherited(dep->rust_transitive_libs_, |
| is_public); |
| |
| // If there is a transitive dependency that is not a rust library, place it |
| // in the normal location |
| for (const auto& inherited : |
| rust_transitive_libs_.GetOrderedAndPublicFlag()) { |
| if (!RustValues::IsRustLibrary(inherited.first)) { |
| inherited_libraries_.Append(inherited.first, inherited.second); |
| } |
| } |
| } else if (dep->output_type() == RUST_PROC_MACRO) { |
| // We will need to specify the path to find a procedural macro, |
| // but have no need to specify the paths to find its dependencies |
| // as the procedural macro is now a complete .so. |
| rust_transitive_libs_.Append(dep, is_public); |
| } else if (dep->output_type() == SHARED_LIBRARY) { |
| // Shared library dependendencies are inherited across public shared |
| // library boundaries. |
| // |
| // In this case: |
| // EXE -> INTERMEDIATE_SHLIB --[public]--> FINAL_SHLIB |
| // The EXE will also link to to FINAL_SHLIB. The public dependency means |
| // that the EXE can use the headers in FINAL_SHLIB so the FINAL_SHLIB |
| // will need to appear on EXE's link line. |
| // |
| // However, if the dependency is private: |
| // EXE -> INTERMEDIATE_SHLIB --[private]--> FINAL_SHLIB |
| // the dependency will not be propagated because INTERMEDIATE_SHLIB is |
| // not granting permission to call functions from FINAL_SHLIB. If EXE |
| // wants to use functions (and link to) FINAL_SHLIB, it will need to do |
| // so explicitly. |
| // |
| // Static libraries and source sets aren't inherited across shared |
| // library boundaries because they will be linked into the shared |
| // library. Rust dylib deps are handled above and transitive deps are |
| // resolved by the compiler. |
| inherited_libraries_.AppendPublicSharedLibraries(dep->inherited_libraries(), |
| is_public); |
| } else if (!dep->IsFinal()) { |
| // The current target isn't linked, so propagate linked deps and |
| // libraries up the dependency tree. |
| inherited_libraries_.AppendInherited(dep->inherited_libraries(), is_public); |
| rust_transitive_libs_.AppendInherited(dep->rust_transitive_libs_, |
| is_public); |
| } else if (dep->complete_static_lib()) { |
| // Inherit only final targets through _complete_ static libraries. |
| // |
| // Inherited final libraries aren't linked into complete static libraries. |
| // They are forwarded here so that targets that depend on complete |
| // static libraries can link them in. Conversely, since complete static |
| // libraries link in non-final targets they shouldn't be inherited. |
| for (const auto& inherited : |
| dep->inherited_libraries().GetOrderedAndPublicFlag()) { |
| if (inherited.first->IsFinal()) { |
| inherited_libraries_.Append(inherited.first, |
| is_public && inherited.second); |
| } |
| } |
| } |
| |
| // Library settings are always inherited across static library boundaries. |
| if (!dep->IsFinal() || dep->output_type() == STATIC_LIBRARY) { |
| all_lib_dirs_.Append(dep->all_lib_dirs()); |
| all_libs_.Append(dep->all_libs()); |
| |
| all_framework_dirs_.Append(dep->all_framework_dirs()); |
| all_frameworks_.Append(dep->all_frameworks()); |
| all_weak_frameworks_.Append(dep->all_weak_frameworks()); |
| } |
| } |
| |
| void Target::PullDependentTargetLibs() { |
| for (const auto& dep : public_deps_) |
| PullDependentTargetLibsFrom(dep.ptr, true); |
| for (const auto& dep : private_deps_) |
| PullDependentTargetLibsFrom(dep.ptr, false); |
| } |
| |
| void Target::PullRecursiveHardDeps() { |
| for (const auto& pair : GetDeps(DEPS_LINKED)) { |
| // Direct hard dependencies. |
| if (hard_dep() || pair.ptr->hard_dep()) { |
| recursive_hard_deps_.insert(pair.ptr); |
| continue; |
| } |
| |
| // If |pair.ptr| is binary target and |pair.ptr| has no public header, |
| // |this| target does not need to have |pair.ptr|'s hard_deps as its |
| // hard_deps to start compiles earlier. Unless the target compiles a |
| // Swift module (since they also generate a header that can be used |
| // by the current target). |
| if (pair.ptr->IsBinary() && !pair.ptr->all_headers_public() && |
| pair.ptr->public_headers().empty() && |
| !pair.ptr->swift_values().builds_module()) { |
| continue; |
| } |
| |
| // Recursive hard dependencies of all dependencies. |
| recursive_hard_deps_.insert(pair.ptr->recursive_hard_deps().begin(), |
| pair.ptr->recursive_hard_deps().end()); |
| } |
| } |
| |
| void Target::PullRecursiveBundleData() { |
| for (const auto& pair : GetDeps(DEPS_LINKED)) { |
| // Don't propagate bundle_data once they are added to a bundle. |
| if (pair.ptr->output_type() == CREATE_BUNDLE) |
| continue; |
| |
| // Don't propagate across toolchain. |
| if (pair.ptr->toolchain() != toolchain()) |
| continue; |
| |
| // Direct dependency on a bundle_data target. |
| if (pair.ptr->output_type() == BUNDLE_DATA) { |
| bundle_data().AddBundleData(pair.ptr); |
| } |
| |
| // Recursive bundle_data informations from all dependencies. |
| if (pair.ptr->has_bundle_data()) { |
| for (auto* target : pair.ptr->bundle_data().bundle_deps()) |
| bundle_data().AddBundleData(target); |
| } |
| } |
| |
| if (has_bundle_data()) |
| bundle_data().OnTargetResolved(this); |
| } |
| |
| bool Target::FillOutputFiles(Err* err) { |
| const Tool* tool = toolchain_->GetToolForTargetFinalOutput(this); |
| bool check_tool_outputs = false; |
| switch (output_type_) { |
| case GROUP: |
| case BUNDLE_DATA: |
| case CREATE_BUNDLE: |
| case SOURCE_SET: |
| case COPY_FILES: |
| case ACTION: |
| case ACTION_FOREACH: |
| case GENERATED_FILE: { |
| // These don't get linked to and use stamps which should be the first |
| // entry in the outputs. These stamps are named |
| // "<target_out_dir>/<targetname>.stamp". Setting "output_name" does not |
| // affect the stamp file name: it is always based on the original target |
| // name. |
| dependency_output_file_ = |
| GetBuildDirForTargetAsOutputFile(this, BuildDirType::OBJ); |
| dependency_output_file_.value().append(label().name()); |
| dependency_output_file_.value().append(".stamp"); |
| break; |
| } |
| case EXECUTABLE: |
| case LOADABLE_MODULE: |
| // Executables and loadable modules don't get linked to, but the first |
| // output is used for dependency management. |
| CHECK_GE(tool->outputs().list().size(), 1u); |
| check_tool_outputs = true; |
| dependency_output_file_ = |
| SubstitutionWriter::ApplyPatternToLinkerAsOutputFile( |
| this, tool, tool->outputs().list()[0]); |
| |
| if (tool->runtime_outputs().list().empty()) { |
| // Default to the first output for the runtime output. |
| runtime_outputs_.push_back(dependency_output_file_); |
| } else { |
| SubstitutionWriter::ApplyListToLinkerAsOutputFile( |
| this, tool, tool->runtime_outputs(), &runtime_outputs_); |
| } |
| break; |
| case RUST_LIBRARY: |
| case STATIC_LIBRARY: |
| // Static libraries both have dependencies and linking going off of the |
| // first output. |
| CHECK(tool->outputs().list().size() >= 1); |
| check_tool_outputs = true; |
| link_output_file_ = dependency_output_file_ = |
| SubstitutionWriter::ApplyPatternToLinkerAsOutputFile( |
| this, tool, tool->outputs().list()[0]); |
| break; |
| case RUST_PROC_MACRO: |
| case SHARED_LIBRARY: |
| CHECK(tool->outputs().list().size() >= 1); |
| check_tool_outputs = true; |
| if (const CTool* ctool = tool->AsC()) { |
| if (ctool->link_output().empty() && ctool->depend_output().empty()) { |
| // Default behavior, use the first output file for both. |
| link_output_file_ = dependency_output_file_ = |
| SubstitutionWriter::ApplyPatternToLinkerAsOutputFile( |
| this, tool, tool->outputs().list()[0]); |
| } else { |
| // Use the tool-specified ones. |
| if (!ctool->link_output().empty()) { |
| link_output_file_ = |
| SubstitutionWriter::ApplyPatternToLinkerAsOutputFile( |
| this, tool, ctool->link_output()); |
| } |
| if (!ctool->depend_output().empty()) { |
| dependency_output_file_ = |
| SubstitutionWriter::ApplyPatternToLinkerAsOutputFile( |
| this, tool, ctool->depend_output()); |
| } |
| } |
| if (tool->runtime_outputs().list().empty()) { |
| // Default to the link output for the runtime output. |
| runtime_outputs_.push_back(link_output_file_); |
| } else { |
| SubstitutionWriter::ApplyListToLinkerAsOutputFile( |
| this, tool, tool->runtime_outputs(), &runtime_outputs_); |
| } |
| } else if (const RustTool* rstool = tool->AsRust()) { |
| // Default behavior, use the first output file for both. |
| link_output_file_ = dependency_output_file_ = |
| SubstitutionWriter::ApplyPatternToLinkerAsOutputFile( |
| this, tool, tool->outputs().list()[0]); |
| } |
| break; |
| case UNKNOWN: |
| default: |
| NOTREACHED(); |
| } |
| |
| // Count anything generated from bundle_data dependencies. |
| if (output_type_ == CREATE_BUNDLE) { |
| if (!bundle_data().GetOutputFiles(settings(), this, &computed_outputs_, |
| err)) |
| return false; |
| } |
| |
| // Count all outputs from this tool as something generated by this target. |
| if (check_tool_outputs) { |
| SubstitutionWriter::ApplyListToLinkerAsOutputFile( |
| this, tool, tool->outputs(), &computed_outputs_); |
| |
| // Output names aren't canonicalized in the same way that source files |
| // are. For example, the tool outputs often use |
| // {{some_var}}/{{output_name}} which expands to "./foo", but this won't |
| // match "foo" which is what we'll compute when converting a SourceFile to |
| // an OutputFile. |
| for (auto& out : computed_outputs_) |
| NormalizePath(&out.value()); |
| } |
| |
| // Also count anything the target has declared to be an output. |
| if (action_values_.get()) { |
| std::vector<SourceFile> outputs_as_sources; |
| action_values_->GetOutputsAsSourceFiles(this, &outputs_as_sources); |
| for (const SourceFile& out : outputs_as_sources) |
| computed_outputs_.push_back( |
| OutputFile(settings()->build_settings(), out)); |
| } |
| |
| return true; |
| } |
| |
| bool Target::ResolvePrecompiledHeaders(Err* err) { |
| // Precompiled headers are stored on a ConfigValues struct. This way, the |
| // build can set all the precompiled header settings in a config and apply |
| // it to many targets. Likewise, the precompiled header values may be |
| // specified directly on a target. |
| // |
| // Unlike other values on configs which are lists that just get concatenated, |
| // the precompiled header settings are unique values. We allow them to be |
| // specified anywhere, but if they are specified in more than one place all |
| // places must match. |
| |
| // Track where the current settings came from for issuing errors. |
| bool has_precompiled_headers = |
| config_values_.get() && config_values_->has_precompiled_headers(); |
| const Label* pch_header_settings_from = NULL; |
| if (has_precompiled_headers) |
| pch_header_settings_from = &label(); |
| |
| for (ConfigValuesIterator iter(this); !iter.done(); iter.Next()) { |
| if (!iter.GetCurrentConfig()) |
| continue; // Skip the one on the target itself. |
| |
| const Config* config = iter.GetCurrentConfig(); |
| const ConfigValues& cur = config->resolved_values(); |
| if (!cur.has_precompiled_headers()) |
| continue; // This one has no precompiled header info, skip. |
| |
| if (has_precompiled_headers) { |
| // Already have a precompiled header values, the settings must match. |
| if (config_values_->precompiled_header() != cur.precompiled_header() || |
| config_values_->precompiled_source() != cur.precompiled_source()) { |
| *err = Err( |
| defined_from(), "Precompiled header setting conflict.", |
| "The target " + label().GetUserVisibleName(false) + |
| "\n" |
| "has conflicting precompiled header settings.\n" |
| "\n" |
| "From " + |
| pch_header_settings_from->GetUserVisibleName(false) + |
| "\n header: " + config_values_->precompiled_header() + |
| "\n source: " + config_values_->precompiled_source().value() + |
| "\n\n" |
| "From " + |
| config->label().GetUserVisibleName(false) + |
| "\n header: " + cur.precompiled_header() + |
| "\n source: " + cur.precompiled_source().value()); |
| return false; |
| } |
| } else { |
| // Have settings from a config, apply them to ourselves. |
| pch_header_settings_from = &config->label(); |
| config_values().set_precompiled_header(cur.precompiled_header()); |
| config_values().set_precompiled_source(cur.precompiled_source()); |
| } |
| } |
| |
| return true; |
| } |
| |
| bool Target::CheckVisibility(Err* err) const { |
| for (const auto& pair : GetDeps(DEPS_ALL)) { |
| if (!Visibility::CheckItemVisibility(this, pair.ptr, err)) |
| return false; |
| } |
| return true; |
| } |
| |
| bool Target::CheckConfigVisibility(Err* err) const { |
| for (ConfigValuesIterator iter(this); !iter.done(); iter.Next()) { |
| if (const Config* config = iter.GetCurrentConfig()) |
| if (!Visibility::CheckItemVisibility(this, config, err)) |
| return false; |
| } |
| return true; |
| } |
| |
| bool Target::CheckSourceSetLanguages(Err* err) const { |
| if (output_type() == Target::SOURCE_SET && |
| source_types_used().RustSourceUsed()) { |
| *err = Err(defined_from(), "source_set contained Rust code.", |
| label().GetUserVisibleName(false) + |
| " has Rust code. Only C/C++ source_sets are supported."); |
| return false; |
| } |
| return true; |
| } |
| |
| bool Target::CheckTestonly(Err* err) const { |
| // If the current target is marked testonly, it can include both testonly |
| // and non-testonly targets, so there's nothing to check. |
| if (testonly()) |
| return true; |
| |
| // Verify no deps have "testonly" set. |
| for (const auto& pair : GetDeps(DEPS_ALL)) { |
| if (pair.ptr->testonly()) { |
| *err = MakeTestOnlyError(this, pair.ptr); |
| return false; |
| } |
| } |
| |
| // Verify no configs have "testonly" set. |
| for (ConfigValuesIterator iter(this); !iter.done(); iter.Next()) { |
| if (const Config* config = iter.GetCurrentConfig()) { |
| if (config->testonly()) { |
| *err = MakeTestOnlyError(this, config); |
| return false; |
| } |
| } |
| } |
| |
| return true; |
| } |
| |
| bool Target::CheckAssertNoDeps(Err* err) const { |
| if (assert_no_deps_.empty()) |
| return true; |
| |
| TargetSet visited; |
| std::string failure_path_str; |
| const LabelPattern* failure_pattern = nullptr; |
| |
| if (!RecursiveCheckAssertNoDeps(this, false, assert_no_deps_, &visited, |
| &failure_path_str, &failure_pattern)) { |
| *err = Err( |
| defined_from(), "assert_no_deps failed.", |
| label().GetUserVisibleName(false) + |
| " has an assert_no_deps entry:\n " + failure_pattern->Describe() + |
| "\nwhich fails for the dependency path:\n" + failure_path_str); |
| return false; |
| } |
| return true; |
| } |
| |
| void Target::CheckSourcesGenerated() const { |
| // Checks that any inputs or sources to this target that are in the build |
| // directory are generated by a target that this one transitively depends on |
| // in some way. We already guarantee that all generated files are written |
| // to the build dir. |
| // |
| // See Scheduler::AddUnknownGeneratedInput's declaration for more. |
| for (const SourceFile& file : sources_) |
| CheckSourceGenerated(file); |
| for (ConfigValuesIterator iter(this); !iter.done(); iter.Next()) { |
| for (const SourceFile& file : iter.cur().inputs()) |
| CheckSourceGenerated(file); |
| } |
| // TODO(agrieve): Check all_libs_ here as well (those that are source files). |
| // http://crbug.com/571731 |
| } |
| |
| void Target::CheckSourceGenerated(const SourceFile& source) const { |
| if (!IsStringInOutputDir(settings()->build_settings()->build_dir(), |
| source.value())) |
| return; // Not in output dir, this is OK. |
| |
| // Tell the scheduler about unknown files. This will be noted for later so |
| // the list of files written by the GN build itself (often response files) |
| // can be filtered out of this list. |
| OutputFile out_file(settings()->build_settings(), source); |
| TargetSet seen_targets; |
| bool check_data_deps = false; |
| bool consider_object_files = false; |
| if (!EnsureFileIsGeneratedByDependency(this, out_file, true, |
| consider_object_files, check_data_deps, |
| &seen_targets)) { |
| seen_targets.clear(); |
| // Allow dependency to be through data_deps for files generated by gn. |
| check_data_deps = |
| g_scheduler->IsFileGeneratedByWriteRuntimeDeps(out_file) || |
| g_scheduler->IsFileGeneratedByTarget(source); |
| // Check object files (much slower and very rare) only if the "normal" |
| // output check failed. |
| consider_object_files = !check_data_deps; |
| if (!EnsureFileIsGeneratedByDependency(this, out_file, true, |
| consider_object_files, |
| check_data_deps, &seen_targets)) |
| g_scheduler->AddUnknownGeneratedInput(this, source); |
| } |
| } |
| |
| bool Target::GetMetadata(const std::vector<std::string>& keys_to_extract, |
| const std::vector<std::string>& keys_to_walk, |
| const SourceDir& rebase_dir, |
| bool deps_only, |
| std::vector<Value>* result, |
| TargetSet* targets_walked, |
| Err* err) const { |
| std::vector<Value> next_walk_keys; |
| std::vector<Value> current_result; |
| // If deps_only, this is the top-level target and thus we don't want to |
| // collect its metadata, only that of its deps and data_deps. |
| if (deps_only) { |
| // Empty string will be converted below to mean all deps and data_deps. |
| // Origin is null because this isn't declared anywhere, and should never |
| // trigger any errors. |
| next_walk_keys.push_back(Value(nullptr, "")); |
| } else { |
| // Otherwise, we walk this target and collect the appropriate data. |
| // NOTE: Always call WalkStep() even when have_metadata() is false, |
| // because WalkStep() will append to 'next_walk_keys' in this case. |
| // See https://crbug.com/1273069. |
| if (!metadata().WalkStep(settings()->build_settings(), keys_to_extract, |
| keys_to_walk, rebase_dir, &next_walk_keys, |
| ¤t_result, err)) |
| return false; |
| } |
| |
| // Gather walk keys and find the appropriate target. Targets identified in |
| // the walk key set must be deps or data_deps of the declaring target. |
| const DepsIteratorRange& all_deps = GetDeps(Target::DEPS_ALL); |
| const SourceDir& current_dir = label().dir(); |
| for (const auto& next : next_walk_keys) { |
| DCHECK(next.type() == Value::STRING); |
| |
| // If we hit an empty string in this list, add all deps and data_deps. The |
| // ordering in the resulting list of values as a result will be the data |
| // from each explicitly listed dep prior to this, followed by all data in |
| // walk order of the remaining deps. |
| if (next.string_value().empty()) { |
| for (const auto& dep : all_deps) { |
| // If we haven't walked this dep yet, go down into it. |
| if (targets_walked->add(dep.ptr)) { |
| if (!dep.ptr->GetMetadata(keys_to_extract, keys_to_walk, rebase_dir, |
| false, result, targets_walked, err)) |
| return false; |
| } |
| } |
| |
| // Any other walk keys are superfluous, as they can only be a subset of |
| // all deps. |
| break; |
| } |
| |
| // Otherwise, look through the target's deps for the specified one. |
| // Canonicalize the label if possible. |
| Label next_label = Label::Resolve( |
| current_dir, settings()->build_settings()->root_path_utf8(), |
| settings()->toolchain_label(), next, err); |
| if (next_label.is_null()) { |
| *err = Err(next.origin(), std::string("Failed to canonicalize ") + |
| next.string_value() + std::string(".")); |
| } |
| std::string canonicalize_next_label = next_label.GetUserVisibleName(true); |
| |
| bool found_next = false; |
| for (const auto& dep : all_deps) { |
| // Match against the label with the toolchain. |
| if (dep.label.GetUserVisibleName(true) == canonicalize_next_label) { |
| // If we haven't walked this dep yet, go down into it. |
| if (targets_walked->add(dep.ptr)) { |
| if (!dep.ptr->GetMetadata(keys_to_extract, keys_to_walk, rebase_dir, |
| false, result, targets_walked, err)) |
| return false; |
| } |
| // We found it, so we can exit this search now. |
| found_next = true; |
| break; |
| } |
| } |
| // If we didn't find the specified dep in the target, that's an error. |
| // Propagate it back to the user. |
| if (!found_next) { |
| *err = Err(next.origin(), |
| std::string("I was expecting ") + canonicalize_next_label + |
| std::string(" to be a dependency of ") + |
| label().GetUserVisibleName(true) + |
| ". Make sure it's included in the deps or data_deps, and " |
| "that you've specified the appropriate toolchain."); |
| return false; |
| } |
| } |
| result->insert(result->end(), std::make_move_iterator(current_result.begin()), |
| std::make_move_iterator(current_result.end())); |
| return true; |
| } |