mirror of
https://github.com/klzgrad/naiveproxy.git
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1091 lines
41 KiB
C++
1091 lines
41 KiB
C++
// Copyright (c) 2013 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "tools/gn/ninja_binary_target_writer.h"
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#include <stddef.h>
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#include <string.h>
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#include <cstring>
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#include <set>
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#include <sstream>
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#include "base/containers/hash_tables.h"
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#include "base/strings/string_util.h"
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#include "tools/gn/config_values_extractors.h"
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#include "tools/gn/deps_iterator.h"
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#include "tools/gn/err.h"
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#include "tools/gn/escape.h"
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#include "tools/gn/filesystem_utils.h"
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#include "tools/gn/ninja_utils.h"
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#include "tools/gn/scheduler.h"
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#include "tools/gn/settings.h"
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#include "tools/gn/source_file_type.h"
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#include "tools/gn/string_utils.h"
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#include "tools/gn/substitution_writer.h"
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#include "tools/gn/target.h"
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// Represents a set of tool types. Must be first since it is also shared by
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// some helper functions in the anonymous namespace below.
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class NinjaBinaryTargetWriter::SourceFileTypeSet {
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public:
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SourceFileTypeSet() {
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memset(flags_, 0, sizeof(bool) * static_cast<int>(SOURCE_NUMTYPES));
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}
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void Set(SourceFileType type) {
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flags_[static_cast<int>(type)] = true;
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}
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bool Get(SourceFileType type) const {
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return flags_[static_cast<int>(type)];
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}
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private:
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bool flags_[static_cast<int>(SOURCE_NUMTYPES)];
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};
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namespace {
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// Returns the proper escape options for writing compiler and linker flags.
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EscapeOptions GetFlagOptions() {
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EscapeOptions opts;
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opts.mode = ESCAPE_NINJA_COMMAND;
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return opts;
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}
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struct DefineWriter {
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DefineWriter() {
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options.mode = ESCAPE_NINJA_COMMAND;
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}
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void operator()(const std::string& s, std::ostream& out) const {
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out << " -D";
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EscapeStringToStream(out, s, options);
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}
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EscapeOptions options;
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};
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struct IncludeWriter {
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explicit IncludeWriter(PathOutput& path_output) : path_output_(path_output) {
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}
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~IncludeWriter() = default;
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void operator()(const SourceDir& d, std::ostream& out) const {
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std::ostringstream path_out;
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path_output_.WriteDir(path_out, d, PathOutput::DIR_NO_LAST_SLASH);
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const std::string& path = path_out.str();
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if (path[0] == '"')
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out << " \"-I" << path.substr(1);
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else
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out << " -I" << path;
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}
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PathOutput& path_output_;
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};
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// Returns the language-specific suffix for precompiled header files.
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const char* GetPCHLangSuffixForToolType(Toolchain::ToolType type) {
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switch (type) {
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case Toolchain::TYPE_CC:
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return "c";
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case Toolchain::TYPE_CXX:
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return "cc";
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case Toolchain::TYPE_OBJC:
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return "m";
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case Toolchain::TYPE_OBJCXX:
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return "mm";
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default:
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NOTREACHED() << "Not a valid PCH tool type: " << type;
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return "";
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}
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}
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std::string GetWindowsPCHObjectExtension(Toolchain::ToolType tool_type,
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const std::string& obj_extension) {
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const char* lang_suffix = GetPCHLangSuffixForToolType(tool_type);
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std::string result = ".";
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// For MSVC, annotate the obj files with the language type. For example:
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// obj/foo/target_name.precompile.obj ->
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// obj/foo/target_name.precompile.cc.obj
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result += lang_suffix;
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result += obj_extension;
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return result;
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}
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std::string GetGCCPCHOutputExtension(Toolchain::ToolType tool_type) {
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const char* lang_suffix = GetPCHLangSuffixForToolType(tool_type);
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std::string result = ".";
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// For GCC, the output name must have a .gch suffix and be annotated with
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// the language type. For example:
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// obj/foo/target_name.header.h ->
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// obj/foo/target_name.header.h-cc.gch
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// In order for the compiler to pick it up, the output name (minus the .gch
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// suffix MUST match whatever is passed to the -include flag).
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result += "h-";
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result += lang_suffix;
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result += ".gch";
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return result;
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}
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// Returns the language-specific lang recognized by gcc’s -x flag for
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// precompiled header files.
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const char* GetPCHLangForToolType(Toolchain::ToolType type) {
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switch (type) {
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case Toolchain::TYPE_CC:
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return "c-header";
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case Toolchain::TYPE_CXX:
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return "c++-header";
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case Toolchain::TYPE_OBJC:
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return "objective-c-header";
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case Toolchain::TYPE_OBJCXX:
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return "objective-c++-header";
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default:
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NOTREACHED() << "Not a valid PCH tool type: " << type;
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return "";
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}
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}
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// Fills |outputs| with the object or gch file for the precompiled header of the
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// given type (flag type and tool type must match).
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void GetPCHOutputFiles(const Target* target,
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Toolchain::ToolType tool_type,
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std::vector<OutputFile>* outputs) {
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outputs->clear();
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// Compute the tool. This must use the tool type passed in rather than the
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// detected file type of the precompiled source file since the same
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// precompiled source file will be used for separate C/C++ compiles.
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const Tool* tool = target->toolchain()->GetTool(tool_type);
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if (!tool)
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return;
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SubstitutionWriter::ApplyListToCompilerAsOutputFile(
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target, target->config_values().precompiled_source(),
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tool->outputs(), outputs);
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if (outputs->empty())
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return;
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if (outputs->size() > 1)
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outputs->resize(1); // Only link the first output from the compiler tool.
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std::string& output_value = (*outputs)[0].value();
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size_t extension_offset = FindExtensionOffset(output_value);
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if (extension_offset == std::string::npos) {
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// No extension found.
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return;
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}
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DCHECK(extension_offset >= 1);
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DCHECK(output_value[extension_offset - 1] == '.');
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std::string output_extension;
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Tool::PrecompiledHeaderType header_type = tool->precompiled_header_type();
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switch (header_type) {
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case Tool::PCH_MSVC:
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output_extension = GetWindowsPCHObjectExtension(
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tool_type, output_value.substr(extension_offset - 1));
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break;
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case Tool::PCH_GCC:
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output_extension = GetGCCPCHOutputExtension(tool_type);
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break;
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case Tool::PCH_NONE:
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NOTREACHED() << "No outputs for no PCH type.";
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break;
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}
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output_value.replace(extension_offset - 1,
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std::string::npos,
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output_extension);
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}
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// Appends the object files generated by the given source set to the given
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// output vector.
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void AddSourceSetObjectFiles(const Target* source_set,
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UniqueVector<OutputFile>* obj_files) {
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std::vector<OutputFile> tool_outputs; // Prevent allocation in loop.
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NinjaBinaryTargetWriter::SourceFileTypeSet used_types;
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// Compute object files for all sources. Only link the first output from
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// the tool if there are more than one.
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for (const auto& source : source_set->sources()) {
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Toolchain::ToolType tool_type = Toolchain::TYPE_NONE;
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if (source_set->GetOutputFilesForSource(source, &tool_type, &tool_outputs))
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obj_files->push_back(tool_outputs[0]);
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used_types.Set(GetSourceFileType(source));
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}
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// Add MSVC precompiled header object files. GCC .gch files are not object
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// files so they are omitted.
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if (source_set->config_values().has_precompiled_headers()) {
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if (used_types.Get(SOURCE_C)) {
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const Tool* tool = source_set->toolchain()->GetTool(Toolchain::TYPE_CC);
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if (tool && tool->precompiled_header_type() == Tool::PCH_MSVC) {
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GetPCHOutputFiles(source_set, Toolchain::TYPE_CC, &tool_outputs);
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obj_files->Append(tool_outputs.begin(), tool_outputs.end());
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}
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}
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if (used_types.Get(SOURCE_CPP)) {
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const Tool* tool = source_set->toolchain()->GetTool(Toolchain::TYPE_CXX);
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if (tool && tool->precompiled_header_type() == Tool::PCH_MSVC) {
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GetPCHOutputFiles(source_set, Toolchain::TYPE_CXX, &tool_outputs);
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obj_files->Append(tool_outputs.begin(), tool_outputs.end());
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}
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}
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if (used_types.Get(SOURCE_M)) {
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const Tool* tool = source_set->toolchain()->GetTool(Toolchain::TYPE_OBJC);
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if (tool && tool->precompiled_header_type() == Tool::PCH_MSVC) {
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GetPCHOutputFiles(source_set, Toolchain::TYPE_OBJC, &tool_outputs);
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obj_files->Append(tool_outputs.begin(), tool_outputs.end());
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}
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}
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if (used_types.Get(SOURCE_MM)) {
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const Tool* tool = source_set->toolchain()->GetTool(
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Toolchain::TYPE_OBJCXX);
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if (tool && tool->precompiled_header_type() == Tool::PCH_MSVC) {
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GetPCHOutputFiles(source_set, Toolchain::TYPE_OBJCXX, &tool_outputs);
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obj_files->Append(tool_outputs.begin(), tool_outputs.end());
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}
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}
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}
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}
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} // namespace
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NinjaBinaryTargetWriter::NinjaBinaryTargetWriter(const Target* target,
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std::ostream& out)
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: NinjaTargetWriter(target, out),
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tool_(target->toolchain()->GetToolForTargetFinalOutput(target)),
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rule_prefix_(GetNinjaRulePrefixForToolchain(settings_)) {
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}
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NinjaBinaryTargetWriter::~NinjaBinaryTargetWriter() = default;
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void NinjaBinaryTargetWriter::Run() {
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// Figure out what source types are needed.
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SourceFileTypeSet used_types;
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for (const auto& source : target_->sources())
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used_types.Set(GetSourceFileType(source));
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WriteCompilerVars(used_types);
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OutputFile input_dep = WriteInputsStampAndGetDep();
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// The input dependencies will be an order-only dependency. This will cause
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// Ninja to make sure the inputs are up to date before compiling this source,
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// but changes in the inputs deps won't cause the file to be recompiled.
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//
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// This is important to prevent changes in unrelated actions that are
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// upstream of this target from causing everything to be recompiled.
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//
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// Why can we get away with this rather than using implicit deps ("|", which
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// will force rebuilds when the inputs change)? For source code, the
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// computed dependencies of all headers will be computed by the compiler,
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// which will cause source rebuilds if any "real" upstream dependencies
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// change.
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//
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// If a .cc file is generated by an input dependency, Ninja will see the
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// input to the build rule doesn't exist, and that it is an output from a
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// previous step, and build the previous step first. This is a "real"
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// dependency and doesn't need | or || to express.
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//
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// The only case where this rule matters is for the first build where no .d
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// files exist, and Ninja doesn't know what that source file depends on. In
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// this case it's sufficient to ensure that the upstream dependencies are
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// built first. This is exactly what Ninja's order-only dependencies
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// expresses.
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//
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// The order only deps are referenced by each source file compile,
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// but also by PCH compiles. The latter are annoying to count, so omit
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// them here. This means that binary targets with a single source file
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// that also use PCH files won't have a stamp file even though having
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// one would make output ninja file size a bit lower. That's ok, binary
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// targets with a single source are rare.
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size_t num_stamp_uses = target_->sources().size();
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std::vector<OutputFile> order_only_deps = WriteInputDepsStampAndGetDep(
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std::vector<const Target*>(), num_stamp_uses);
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// For GCC builds, the .gch files are not object files, but still need to be
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// added as explicit dependencies below. The .gch output files are placed in
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// |pch_other_files|. This is to prevent linking against them.
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std::vector<OutputFile> pch_obj_files;
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std::vector<OutputFile> pch_other_files;
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WritePCHCommands(used_types, input_dep, order_only_deps, &pch_obj_files,
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&pch_other_files);
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std::vector<OutputFile>* pch_files = !pch_obj_files.empty() ?
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&pch_obj_files : &pch_other_files;
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// Treat all pch output files as explicit dependencies of all
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// compiles that support them. Some notes:
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//
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// - On Windows, the .pch file is the input to the compile, not the
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// precompiled header's corresponding object file that we're using here.
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// But Ninja's depslog doesn't support multiple outputs from the
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// precompiled header compile step (it outputs both the .pch file and a
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// corresponding .obj file). So we consistently list the .obj file and the
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// .pch file we really need comes along with it.
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//
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// - GCC .gch files are not object files, therefore they are not added to the
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// object file list.
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std::vector<OutputFile> obj_files;
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std::vector<SourceFile> other_files;
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WriteSources(*pch_files, input_dep, order_only_deps, &obj_files,
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&other_files);
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// Link all MSVC pch object files. The vector will be empty on GCC toolchains.
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obj_files.insert(obj_files.end(), pch_obj_files.begin(), pch_obj_files.end());
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if (!CheckForDuplicateObjectFiles(obj_files))
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return;
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if (target_->output_type() == Target::SOURCE_SET) {
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WriteSourceSetStamp(obj_files);
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#ifndef NDEBUG
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// Verify that the function that separately computes a source set's object
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// files match the object files just computed.
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UniqueVector<OutputFile> computed_obj;
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AddSourceSetObjectFiles(target_, &computed_obj);
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DCHECK_EQ(obj_files.size(), computed_obj.size());
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for (const auto& obj : obj_files)
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DCHECK_NE(static_cast<size_t>(-1), computed_obj.IndexOf(obj));
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#endif
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} else {
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WriteLinkerStuff(obj_files, other_files, input_dep);
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}
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}
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void NinjaBinaryTargetWriter::WriteCompilerVars(
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const SourceFileTypeSet& used_types) {
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const SubstitutionBits& subst = target_->toolchain()->substitution_bits();
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// Defines.
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if (subst.used[SUBSTITUTION_DEFINES]) {
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out_ << kSubstitutionNinjaNames[SUBSTITUTION_DEFINES] << " =";
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RecursiveTargetConfigToStream<std::string>(
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target_, &ConfigValues::defines, DefineWriter(), out_);
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out_ << std::endl;
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}
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// Include directories.
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if (subst.used[SUBSTITUTION_INCLUDE_DIRS]) {
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out_ << kSubstitutionNinjaNames[SUBSTITUTION_INCLUDE_DIRS] << " =";
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PathOutput include_path_output(
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path_output_.current_dir(),
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settings_->build_settings()->root_path_utf8(),
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ESCAPE_NINJA_COMMAND);
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RecursiveTargetConfigToStream<SourceDir>(
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target_, &ConfigValues::include_dirs,
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IncludeWriter(include_path_output), out_);
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out_ << std::endl;
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}
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bool has_precompiled_headers =
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target_->config_values().has_precompiled_headers();
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EscapeOptions opts = GetFlagOptions();
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if (used_types.Get(SOURCE_S) || used_types.Get(SOURCE_ASM)) {
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WriteOneFlag(SUBSTITUTION_ASMFLAGS, false, Toolchain::TYPE_NONE,
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&ConfigValues::asmflags, opts);
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}
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if (used_types.Get(SOURCE_C) || used_types.Get(SOURCE_CPP) ||
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used_types.Get(SOURCE_M) || used_types.Get(SOURCE_MM)) {
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WriteOneFlag(SUBSTITUTION_CFLAGS, false, Toolchain::TYPE_NONE,
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&ConfigValues::cflags, opts);
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}
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if (used_types.Get(SOURCE_C)) {
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WriteOneFlag(SUBSTITUTION_CFLAGS_C, has_precompiled_headers,
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Toolchain::TYPE_CC, &ConfigValues::cflags_c, opts);
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}
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if (used_types.Get(SOURCE_CPP)) {
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WriteOneFlag(SUBSTITUTION_CFLAGS_CC, has_precompiled_headers,
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Toolchain::TYPE_CXX, &ConfigValues::cflags_cc, opts);
|
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}
|
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if (used_types.Get(SOURCE_M)) {
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WriteOneFlag(SUBSTITUTION_CFLAGS_OBJC, has_precompiled_headers,
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Toolchain::TYPE_OBJC, &ConfigValues::cflags_objc, opts);
|
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}
|
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if (used_types.Get(SOURCE_MM)) {
|
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WriteOneFlag(SUBSTITUTION_CFLAGS_OBJCC, has_precompiled_headers,
|
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Toolchain::TYPE_OBJCXX, &ConfigValues::cflags_objcc, opts);
|
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}
|
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WriteSharedVars(subst);
|
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}
|
||
|
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OutputFile NinjaBinaryTargetWriter::WriteInputsStampAndGetDep() const {
|
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CHECK(target_->toolchain())
|
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<< "Toolchain not set on target "
|
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<< target_->label().GetUserVisibleName(true);
|
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std::vector<const SourceFile*> inputs;
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for (ConfigValuesIterator iter(target_); !iter.done(); iter.Next()) {
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for (const auto& input : iter.cur().inputs()) {
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inputs.push_back(&input);
|
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}
|
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}
|
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if (inputs.size() == 0)
|
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return OutputFile(); // No inputs
|
||
|
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// If we only have one input, return it directly instead of writing a stamp
|
||
// file for it.
|
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if (inputs.size() == 1)
|
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return OutputFile(settings_->build_settings(), *inputs[0]);
|
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|
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// Make a stamp file.
|
||
OutputFile input_stamp_file =
|
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GetBuildDirForTargetAsOutputFile(target_, BuildDirType::OBJ);
|
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input_stamp_file.value().append(target_->label().name());
|
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input_stamp_file.value().append(".inputs.stamp");
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out_ << "build ";
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path_output_.WriteFile(out_, input_stamp_file);
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out_ << ": "
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<< GetNinjaRulePrefixForToolchain(settings_)
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<< Toolchain::ToolTypeToName(Toolchain::TYPE_STAMP);
|
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// File inputs.
|
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for (const auto* input : inputs) {
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out_ << " ";
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path_output_.WriteFile(out_, *input);
|
||
}
|
||
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out_ << "\n";
|
||
return input_stamp_file;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteOneFlag(
|
||
SubstitutionType subst_enum,
|
||
bool has_precompiled_headers,
|
||
Toolchain::ToolType tool_type,
|
||
const std::vector<std::string>& (ConfigValues::* getter)() const,
|
||
EscapeOptions flag_escape_options) {
|
||
if (!target_->toolchain()->substitution_bits().used[subst_enum])
|
||
return;
|
||
|
||
out_ << kSubstitutionNinjaNames[subst_enum] << " =";
|
||
|
||
if (has_precompiled_headers) {
|
||
const Tool* tool = target_->toolchain()->GetTool(tool_type);
|
||
if (tool && tool->precompiled_header_type() == Tool::PCH_MSVC) {
|
||
// Name the .pch file.
|
||
out_ << " /Fp";
|
||
path_output_.WriteFile(out_, GetWindowsPCHFile(tool_type));
|
||
|
||
// Enables precompiled headers and names the .h file. It's a string
|
||
// rather than a file name (so no need to rebase or use path_output_).
|
||
out_ << " /Yu" << target_->config_values().precompiled_header();
|
||
RecursiveTargetConfigStringsToStream(target_, getter,
|
||
flag_escape_options, out_);
|
||
} else if (tool && tool->precompiled_header_type() == Tool::PCH_GCC) {
|
||
// The targets to build the .gch files should omit the -include flag
|
||
// below. To accomplish this, each substitution flag is overwritten in the
|
||
// target rule and these values are repeated. The -include flag is omitted
|
||
// in place of the required -x <header lang> flag for .gch targets.
|
||
RecursiveTargetConfigStringsToStream(target_, getter,
|
||
flag_escape_options, out_);
|
||
|
||
// Compute the gch file (it will be language-specific).
|
||
std::vector<OutputFile> outputs;
|
||
GetPCHOutputFiles(target_, tool_type, &outputs);
|
||
if (!outputs.empty()) {
|
||
// Trim the .gch suffix for the -include flag.
|
||
// e.g. for gch file foo/bar/target.precompiled.h.gch:
|
||
// -include foo/bar/target.precompiled.h
|
||
std::string pch_file = outputs[0].value();
|
||
pch_file.erase(pch_file.length() - 4);
|
||
out_ << " -include " << pch_file;
|
||
}
|
||
} else {
|
||
RecursiveTargetConfigStringsToStream(target_, getter,
|
||
flag_escape_options, out_);
|
||
}
|
||
} else {
|
||
RecursiveTargetConfigStringsToStream(target_, getter,
|
||
flag_escape_options, out_);
|
||
}
|
||
out_ << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WritePCHCommands(
|
||
const SourceFileTypeSet& used_types,
|
||
const OutputFile& input_dep,
|
||
const std::vector<OutputFile>& order_only_deps,
|
||
std::vector<OutputFile>* object_files,
|
||
std::vector<OutputFile>* other_files) {
|
||
if (!target_->config_values().has_precompiled_headers())
|
||
return;
|
||
|
||
const Tool* tool_c = target_->toolchain()->GetTool(Toolchain::TYPE_CC);
|
||
if (tool_c &&
|
||
tool_c->precompiled_header_type() != Tool::PCH_NONE &&
|
||
used_types.Get(SOURCE_C)) {
|
||
WritePCHCommand(SUBSTITUTION_CFLAGS_C, Toolchain::TYPE_CC,
|
||
tool_c->precompiled_header_type(), input_dep,
|
||
order_only_deps, object_files, other_files);
|
||
}
|
||
const Tool* tool_cxx = target_->toolchain()->GetTool(Toolchain::TYPE_CXX);
|
||
if (tool_cxx &&
|
||
tool_cxx->precompiled_header_type() != Tool::PCH_NONE &&
|
||
used_types.Get(SOURCE_CPP)) {
|
||
WritePCHCommand(SUBSTITUTION_CFLAGS_CC, Toolchain::TYPE_CXX,
|
||
tool_cxx->precompiled_header_type(), input_dep,
|
||
order_only_deps, object_files, other_files);
|
||
}
|
||
|
||
const Tool* tool_objc = target_->toolchain()->GetTool(Toolchain::TYPE_OBJC);
|
||
if (tool_objc &&
|
||
tool_objc->precompiled_header_type() == Tool::PCH_GCC &&
|
||
used_types.Get(SOURCE_M)) {
|
||
WritePCHCommand(SUBSTITUTION_CFLAGS_OBJC, Toolchain::TYPE_OBJC,
|
||
tool_objc->precompiled_header_type(), input_dep,
|
||
order_only_deps, object_files, other_files);
|
||
}
|
||
|
||
const Tool* tool_objcxx =
|
||
target_->toolchain()->GetTool(Toolchain::TYPE_OBJCXX);
|
||
if (tool_objcxx &&
|
||
tool_objcxx->precompiled_header_type() == Tool::PCH_GCC &&
|
||
used_types.Get(SOURCE_MM)) {
|
||
WritePCHCommand(SUBSTITUTION_CFLAGS_OBJCC, Toolchain::TYPE_OBJCXX,
|
||
tool_objcxx->precompiled_header_type(), input_dep,
|
||
order_only_deps, object_files, other_files);
|
||
}
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WritePCHCommand(
|
||
SubstitutionType flag_type,
|
||
Toolchain::ToolType tool_type,
|
||
Tool::PrecompiledHeaderType header_type,
|
||
const OutputFile& input_dep,
|
||
const std::vector<OutputFile>& order_only_deps,
|
||
std::vector<OutputFile>* object_files,
|
||
std::vector<OutputFile>* other_files) {
|
||
switch (header_type) {
|
||
case Tool::PCH_MSVC:
|
||
WriteWindowsPCHCommand(flag_type, tool_type, input_dep, order_only_deps,
|
||
object_files);
|
||
break;
|
||
case Tool::PCH_GCC:
|
||
WriteGCCPCHCommand(flag_type, tool_type, input_dep, order_only_deps,
|
||
other_files);
|
||
break;
|
||
case Tool::PCH_NONE:
|
||
NOTREACHED() << "Cannot write a PCH command with no PCH header type";
|
||
break;
|
||
}
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteGCCPCHCommand(
|
||
SubstitutionType flag_type,
|
||
Toolchain::ToolType tool_type,
|
||
const OutputFile& input_dep,
|
||
const std::vector<OutputFile>& order_only_deps,
|
||
std::vector<OutputFile>* gch_files) {
|
||
// Compute the pch output file (it will be language-specific).
|
||
std::vector<OutputFile> outputs;
|
||
GetPCHOutputFiles(target_, tool_type, &outputs);
|
||
if (outputs.empty())
|
||
return;
|
||
|
||
gch_files->insert(gch_files->end(), outputs.begin(), outputs.end());
|
||
|
||
std::vector<OutputFile> extra_deps;
|
||
if (!input_dep.value().empty())
|
||
extra_deps.push_back(input_dep);
|
||
|
||
// Build line to compile the file.
|
||
WriteCompilerBuildLine(target_->config_values().precompiled_source(),
|
||
extra_deps, order_only_deps, tool_type, outputs);
|
||
|
||
// This build line needs a custom language-specific flags value. Rule-specific
|
||
// variables are just indented underneath the rule line.
|
||
out_ << " " << kSubstitutionNinjaNames[flag_type] << " =";
|
||
|
||
// Each substitution flag is overwritten in the target rule to replace the
|
||
// implicitly generated -include flag with the -x <header lang> flag required
|
||
// for .gch targets.
|
||
EscapeOptions opts = GetFlagOptions();
|
||
if (tool_type == Toolchain::TYPE_CC) {
|
||
RecursiveTargetConfigStringsToStream(target_,
|
||
&ConfigValues::cflags_c, opts, out_);
|
||
} else if (tool_type == Toolchain::TYPE_CXX) {
|
||
RecursiveTargetConfigStringsToStream(target_,
|
||
&ConfigValues::cflags_cc, opts, out_);
|
||
} else if (tool_type == Toolchain::TYPE_OBJC) {
|
||
RecursiveTargetConfigStringsToStream(target_,
|
||
&ConfigValues::cflags_objc, opts, out_);
|
||
} else if (tool_type == Toolchain::TYPE_OBJCXX) {
|
||
RecursiveTargetConfigStringsToStream(target_,
|
||
&ConfigValues::cflags_objcc, opts, out_);
|
||
}
|
||
|
||
// Append the command to specify the language of the .gch file.
|
||
out_ << " -x " << GetPCHLangForToolType(tool_type);
|
||
|
||
// Write two blank lines to help separate the PCH build lines from the
|
||
// regular source build lines.
|
||
out_ << std::endl << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteWindowsPCHCommand(
|
||
SubstitutionType flag_type,
|
||
Toolchain::ToolType tool_type,
|
||
const OutputFile& input_dep,
|
||
const std::vector<OutputFile>& order_only_deps,
|
||
std::vector<OutputFile>* object_files) {
|
||
// Compute the pch output file (it will be language-specific).
|
||
std::vector<OutputFile> outputs;
|
||
GetPCHOutputFiles(target_, tool_type, &outputs);
|
||
if (outputs.empty())
|
||
return;
|
||
|
||
object_files->insert(object_files->end(), outputs.begin(), outputs.end());
|
||
|
||
std::vector<OutputFile> extra_deps;
|
||
if (!input_dep.value().empty())
|
||
extra_deps.push_back(input_dep);
|
||
|
||
// Build line to compile the file.
|
||
WriteCompilerBuildLine(target_->config_values().precompiled_source(),
|
||
extra_deps, order_only_deps, tool_type, outputs);
|
||
|
||
// This build line needs a custom language-specific flags value. Rule-specific
|
||
// variables are just indented underneath the rule line.
|
||
out_ << " " << kSubstitutionNinjaNames[flag_type] << " =";
|
||
|
||
// Append the command to generate the .pch file.
|
||
// This adds the value to the existing flag instead of overwriting it.
|
||
out_ << " ${" << kSubstitutionNinjaNames[flag_type] << "}";
|
||
out_ << " /Yc" << target_->config_values().precompiled_header();
|
||
|
||
// Write two blank lines to help separate the PCH build lines from the
|
||
// regular source build lines.
|
||
out_ << std::endl << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteSources(
|
||
const std::vector<OutputFile>& pch_deps,
|
||
const OutputFile& input_dep,
|
||
const std::vector<OutputFile>& order_only_deps,
|
||
std::vector<OutputFile>* object_files,
|
||
std::vector<SourceFile>* other_files) {
|
||
object_files->reserve(object_files->size() + target_->sources().size());
|
||
|
||
std::vector<OutputFile> tool_outputs; // Prevent reallocation in loop.
|
||
std::vector<OutputFile> deps;
|
||
for (const auto& source : target_->sources()) {
|
||
// Clear the vector but maintain the max capacity to prevent reallocations.
|
||
deps.resize(0);
|
||
Toolchain::ToolType tool_type = Toolchain::TYPE_NONE;
|
||
if (!target_->GetOutputFilesForSource(source, &tool_type, &tool_outputs)) {
|
||
if (GetSourceFileType(source) == SOURCE_DEF)
|
||
other_files->push_back(source);
|
||
continue; // No output for this source.
|
||
}
|
||
|
||
if (!input_dep.value().empty())
|
||
deps.push_back(input_dep);
|
||
|
||
if (tool_type != Toolchain::TYPE_NONE) {
|
||
// Only include PCH deps that correspond to the tool type, for instance,
|
||
// do not specify target_name.precompile.cc.obj (a CXX PCH file) as a dep
|
||
// for the output of a C tool type.
|
||
//
|
||
// This makes the assumption that pch_deps only contains pch output files
|
||
// with the naming scheme specified in GetWindowsPCHObjectExtension or
|
||
// GetGCCPCHOutputExtension.
|
||
const Tool* tool = target_->toolchain()->GetTool(tool_type);
|
||
if (tool->precompiled_header_type() != Tool::PCH_NONE) {
|
||
for (const auto& dep : pch_deps) {
|
||
const std::string& output_value = dep.value();
|
||
size_t extension_offset = FindExtensionOffset(output_value);
|
||
if (extension_offset == std::string::npos)
|
||
continue;
|
||
std::string output_extension;
|
||
if (tool->precompiled_header_type() == Tool::PCH_MSVC) {
|
||
output_extension = GetWindowsPCHObjectExtension(
|
||
tool_type, output_value.substr(extension_offset - 1));
|
||
} else if (tool->precompiled_header_type() == Tool::PCH_GCC) {
|
||
output_extension = GetGCCPCHOutputExtension(tool_type);
|
||
}
|
||
if (output_value.compare(output_value.size() -
|
||
output_extension.size(), output_extension.size(),
|
||
output_extension) == 0) {
|
||
deps.push_back(dep);
|
||
}
|
||
}
|
||
}
|
||
WriteCompilerBuildLine(source, deps, order_only_deps, tool_type,
|
||
tool_outputs);
|
||
}
|
||
|
||
// It's theoretically possible for a compiler to produce more than one
|
||
// output, but we'll only link to the first output.
|
||
object_files->push_back(tool_outputs[0]);
|
||
}
|
||
out_ << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteCompilerBuildLine(
|
||
const SourceFile& source,
|
||
const std::vector<OutputFile>& extra_deps,
|
||
const std::vector<OutputFile>& order_only_deps,
|
||
Toolchain::ToolType tool_type,
|
||
const std::vector<OutputFile>& outputs) {
|
||
out_ << "build";
|
||
path_output_.WriteFiles(out_, outputs);
|
||
|
||
out_ << ": " << rule_prefix_ << Toolchain::ToolTypeToName(tool_type);
|
||
out_ << " ";
|
||
path_output_.WriteFile(out_, source);
|
||
|
||
if (!extra_deps.empty()) {
|
||
out_ << " |";
|
||
path_output_.WriteFiles(out_, extra_deps);
|
||
}
|
||
|
||
if (!order_only_deps.empty()) {
|
||
out_ << " ||";
|
||
path_output_.WriteFiles(out_, order_only_deps);
|
||
}
|
||
out_ << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteLinkerStuff(
|
||
const std::vector<OutputFile>& object_files,
|
||
const std::vector<SourceFile>& other_files,
|
||
const OutputFile& input_dep) {
|
||
std::vector<OutputFile> output_files;
|
||
SubstitutionWriter::ApplyListToLinkerAsOutputFile(
|
||
target_, tool_, tool_->outputs(), &output_files);
|
||
|
||
out_ << "build";
|
||
path_output_.WriteFiles(out_, output_files);
|
||
|
||
out_ << ": " << rule_prefix_
|
||
<< Toolchain::ToolTypeToName(
|
||
target_->toolchain()->GetToolTypeForTargetFinalOutput(target_));
|
||
|
||
UniqueVector<OutputFile> extra_object_files;
|
||
UniqueVector<const Target*> linkable_deps;
|
||
UniqueVector<const Target*> non_linkable_deps;
|
||
GetDeps(&extra_object_files, &linkable_deps, &non_linkable_deps);
|
||
|
||
// Object files.
|
||
path_output_.WriteFiles(out_, object_files);
|
||
path_output_.WriteFiles(out_, extra_object_files);
|
||
|
||
// Dependencies.
|
||
std::vector<OutputFile> implicit_deps;
|
||
std::vector<OutputFile> solibs;
|
||
for (const Target* cur : linkable_deps) {
|
||
// All linkable deps should have a link output file.
|
||
DCHECK(!cur->link_output_file().value().empty())
|
||
<< "No link output file for "
|
||
<< target_->label().GetUserVisibleName(false);
|
||
|
||
if (cur->dependency_output_file().value() !=
|
||
cur->link_output_file().value()) {
|
||
// This is a shared library with separate link and deps files. Save for
|
||
// later.
|
||
implicit_deps.push_back(cur->dependency_output_file());
|
||
solibs.push_back(cur->link_output_file());
|
||
} else {
|
||
// Normal case, just link to this target.
|
||
out_ << " ";
|
||
path_output_.WriteFile(out_, cur->link_output_file());
|
||
}
|
||
}
|
||
|
||
const SourceFile* optional_def_file = nullptr;
|
||
if (!other_files.empty()) {
|
||
for (const SourceFile& src_file : other_files) {
|
||
if (GetSourceFileType(src_file) == SOURCE_DEF) {
|
||
optional_def_file = &src_file;
|
||
implicit_deps.push_back(
|
||
OutputFile(settings_->build_settings(), src_file));
|
||
break; // Only one def file is allowed.
|
||
}
|
||
}
|
||
}
|
||
|
||
// Libraries specified by paths.
|
||
const OrderedSet<LibFile>& libs = target_->all_libs();
|
||
for (size_t i = 0; i < libs.size(); i++) {
|
||
if (libs[i].is_source_file()) {
|
||
implicit_deps.push_back(
|
||
OutputFile(settings_->build_settings(), libs[i].source_file()));
|
||
}
|
||
}
|
||
|
||
// The input dependency is only needed if there are no object files, as the
|
||
// dependency is normally provided transitively by the source files.
|
||
if (!input_dep.value().empty() && object_files.empty())
|
||
implicit_deps.push_back(input_dep);
|
||
|
||
// Append implicit dependencies collected above.
|
||
if (!implicit_deps.empty()) {
|
||
out_ << " |";
|
||
path_output_.WriteFiles(out_, implicit_deps);
|
||
}
|
||
|
||
// Append data dependencies as order-only dependencies.
|
||
//
|
||
// This will include data dependencies and input dependencies (like when
|
||
// this target depends on an action). Having the data dependencies in this
|
||
// list ensures that the data is available at runtime when the user builds
|
||
// this target.
|
||
//
|
||
// The action dependencies are not strictly necessary in this case. They
|
||
// should also have been collected via the input deps stamp that each source
|
||
// file has for an order-only dependency, and since this target depends on
|
||
// the sources, there is already an implicit order-only dependency. However,
|
||
// it's extra work to separate these out and there's no disadvantage to
|
||
// listing them again.
|
||
WriteOrderOnlyDependencies(non_linkable_deps);
|
||
|
||
// End of the link "build" line.
|
||
out_ << std::endl;
|
||
|
||
// The remaining things go in the inner scope of the link line.
|
||
if (target_->output_type() == Target::EXECUTABLE ||
|
||
target_->output_type() == Target::SHARED_LIBRARY ||
|
||
target_->output_type() == Target::LOADABLE_MODULE) {
|
||
WriteLinkerFlags(optional_def_file);
|
||
WriteLibs();
|
||
} else if (target_->output_type() == Target::STATIC_LIBRARY) {
|
||
out_ << " arflags =";
|
||
RecursiveTargetConfigStringsToStream(target_, &ConfigValues::arflags,
|
||
GetFlagOptions(), out_);
|
||
out_ << std::endl;
|
||
}
|
||
WriteOutputSubstitutions();
|
||
WriteSolibs(solibs);
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteLinkerFlags(
|
||
const SourceFile* optional_def_file) {
|
||
out_ << " ldflags =";
|
||
|
||
// First the ldflags from the target and its config.
|
||
RecursiveTargetConfigStringsToStream(target_, &ConfigValues::ldflags,
|
||
GetFlagOptions(), out_);
|
||
|
||
// Followed by library search paths that have been recursively pushed
|
||
// through the dependency tree.
|
||
const OrderedSet<SourceDir> all_lib_dirs = target_->all_lib_dirs();
|
||
if (!all_lib_dirs.empty()) {
|
||
// Since we're passing these on the command line to the linker and not
|
||
// to Ninja, we need to do shell escaping.
|
||
PathOutput lib_path_output(path_output_.current_dir(),
|
||
settings_->build_settings()->root_path_utf8(),
|
||
ESCAPE_NINJA_COMMAND);
|
||
for (size_t i = 0; i < all_lib_dirs.size(); i++) {
|
||
out_ << " " << tool_->lib_dir_switch();
|
||
lib_path_output.WriteDir(out_, all_lib_dirs[i],
|
||
PathOutput::DIR_NO_LAST_SLASH);
|
||
}
|
||
}
|
||
|
||
if (optional_def_file) {
|
||
out_ << " /DEF:";
|
||
path_output_.WriteFile(out_, *optional_def_file);
|
||
}
|
||
|
||
out_ << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteLibs() {
|
||
out_ << " libs =";
|
||
|
||
// Libraries that have been recursively pushed through the dependency tree.
|
||
EscapeOptions lib_escape_opts;
|
||
lib_escape_opts.mode = ESCAPE_NINJA_COMMAND;
|
||
const OrderedSet<LibFile> all_libs = target_->all_libs();
|
||
const std::string framework_ending(".framework");
|
||
for (size_t i = 0; i < all_libs.size(); i++) {
|
||
const LibFile& lib_file = all_libs[i];
|
||
const std::string& lib_value = lib_file.value();
|
||
if (lib_file.is_source_file()) {
|
||
out_ << " ";
|
||
path_output_.WriteFile(out_, lib_file.source_file());
|
||
} else if (base::EndsWith(lib_value, framework_ending,
|
||
base::CompareCase::INSENSITIVE_ASCII)) {
|
||
// Special-case libraries ending in ".framework" to support Mac: Add the
|
||
// -framework switch and don't add the extension to the output.
|
||
out_ << " -framework ";
|
||
EscapeStringToStream(
|
||
out_, lib_value.substr(0, lib_value.size() - framework_ending.size()),
|
||
lib_escape_opts);
|
||
} else {
|
||
out_ << " " << tool_->lib_switch();
|
||
EscapeStringToStream(out_, lib_value, lib_escape_opts);
|
||
}
|
||
}
|
||
out_ << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteOutputSubstitutions() {
|
||
out_ << " output_extension = "
|
||
<< SubstitutionWriter::GetLinkerSubstitution(
|
||
target_, tool_, SUBSTITUTION_OUTPUT_EXTENSION);
|
||
out_ << std::endl;
|
||
out_ << " output_dir = "
|
||
<< SubstitutionWriter::GetLinkerSubstitution(
|
||
target_, tool_, SUBSTITUTION_OUTPUT_DIR);
|
||
out_ << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteSolibs(
|
||
const std::vector<OutputFile>& solibs) {
|
||
if (solibs.empty())
|
||
return;
|
||
|
||
out_ << " solibs =";
|
||
path_output_.WriteFiles(out_, solibs);
|
||
out_ << std::endl;
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteSourceSetStamp(
|
||
const std::vector<OutputFile>& object_files) {
|
||
// The stamp rule for source sets is generally not used, since targets that
|
||
// depend on this will reference the object files directly. However, writing
|
||
// this rule allows the user to type the name of the target and get a build
|
||
// which can be convenient for development.
|
||
UniqueVector<OutputFile> extra_object_files;
|
||
UniqueVector<const Target*> linkable_deps;
|
||
UniqueVector<const Target*> non_linkable_deps;
|
||
GetDeps(&extra_object_files, &linkable_deps, &non_linkable_deps);
|
||
|
||
// The classifier should never put extra object files in a source set:
|
||
// any source sets that we depend on should appear in our non-linkable
|
||
// deps instead.
|
||
DCHECK(extra_object_files.empty());
|
||
|
||
std::vector<OutputFile> order_only_deps;
|
||
for (auto* dep : non_linkable_deps)
|
||
order_only_deps.push_back(dep->dependency_output_file());
|
||
|
||
WriteStampForTarget(object_files, order_only_deps);
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::GetDeps(
|
||
UniqueVector<OutputFile>* extra_object_files,
|
||
UniqueVector<const Target*>* linkable_deps,
|
||
UniqueVector<const Target*>* non_linkable_deps) const {
|
||
// Normal public/private deps.
|
||
for (const auto& pair : target_->GetDeps(Target::DEPS_LINKED)) {
|
||
ClassifyDependency(pair.ptr, extra_object_files,
|
||
linkable_deps, non_linkable_deps);
|
||
}
|
||
|
||
// Inherited libraries.
|
||
for (auto* inherited_target : target_->inherited_libraries().GetOrdered()) {
|
||
ClassifyDependency(inherited_target, extra_object_files,
|
||
linkable_deps, non_linkable_deps);
|
||
}
|
||
|
||
// Data deps.
|
||
for (const auto& data_dep_pair : target_->data_deps())
|
||
non_linkable_deps->push_back(data_dep_pair.ptr);
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::ClassifyDependency(
|
||
const Target* dep,
|
||
UniqueVector<OutputFile>* extra_object_files,
|
||
UniqueVector<const Target*>* linkable_deps,
|
||
UniqueVector<const Target*>* non_linkable_deps) const {
|
||
// Only the following types of outputs have libraries linked into them:
|
||
// EXECUTABLE
|
||
// SHARED_LIBRARY
|
||
// _complete_ STATIC_LIBRARY
|
||
//
|
||
// Child deps of intermediate static libraries get pushed up the
|
||
// dependency tree until one of these is reached, and source sets
|
||
// don't link at all.
|
||
bool can_link_libs = target_->IsFinal();
|
||
|
||
if (dep->output_type() == Target::SOURCE_SET ||
|
||
// If a complete static library depends on an incomplete static library,
|
||
// manually link in the object files of the dependent library as if it
|
||
// were a source set. This avoids problems with braindead tools such as
|
||
// ar which don't properly link dependent static libraries.
|
||
(target_->complete_static_lib() &&
|
||
dep->output_type() == Target::STATIC_LIBRARY &&
|
||
!dep->complete_static_lib())) {
|
||
// Source sets have their object files linked into final targets
|
||
// (shared libraries, executables, loadable modules, and complete static
|
||
// libraries). Intermediate static libraries and other source sets
|
||
// just forward the dependency, otherwise the files in the source
|
||
// set can easily get linked more than once which will cause
|
||
// multiple definition errors.
|
||
if (can_link_libs)
|
||
AddSourceSetObjectFiles(dep, extra_object_files);
|
||
|
||
// Add the source set itself as a non-linkable dependency on the current
|
||
// target. This will make sure that anything the source set's stamp file
|
||
// depends on (like data deps) are also built before the current target
|
||
// can be complete. Otherwise, these will be skipped since this target
|
||
// will depend only on the source set's object files.
|
||
non_linkable_deps->push_back(dep);
|
||
} else if (target_->complete_static_lib() && dep->IsFinal()) {
|
||
non_linkable_deps->push_back(dep);
|
||
} else if (can_link_libs && dep->IsLinkable()) {
|
||
linkable_deps->push_back(dep);
|
||
} else {
|
||
non_linkable_deps->push_back(dep);
|
||
}
|
||
}
|
||
|
||
void NinjaBinaryTargetWriter::WriteOrderOnlyDependencies(
|
||
const UniqueVector<const Target*>& non_linkable_deps) {
|
||
if (!non_linkable_deps.empty()) {
|
||
out_ << " ||";
|
||
|
||
// Non-linkable targets.
|
||
for (auto* non_linkable_dep : non_linkable_deps) {
|
||
out_ << " ";
|
||
path_output_.WriteFile(out_, non_linkable_dep->dependency_output_file());
|
||
}
|
||
}
|
||
}
|
||
|
||
OutputFile NinjaBinaryTargetWriter::GetWindowsPCHFile(
|
||
Toolchain::ToolType tool_type) const {
|
||
// Use "obj/{dir}/{target_name}_{lang}.pch" which ends up
|
||
// looking like "obj/chrome/browser/browser_cc.pch"
|
||
OutputFile ret = GetBuildDirForTargetAsOutputFile(target_, BuildDirType::OBJ);
|
||
ret.value().append(target_->label().name());
|
||
ret.value().push_back('_');
|
||
ret.value().append(GetPCHLangSuffixForToolType(tool_type));
|
||
ret.value().append(".pch");
|
||
|
||
return ret;
|
||
}
|
||
|
||
bool NinjaBinaryTargetWriter::CheckForDuplicateObjectFiles(
|
||
const std::vector<OutputFile>& files) const {
|
||
base::hash_set<std::string> set;
|
||
for (const auto& file : files) {
|
||
if (!set.insert(file.value()).second) {
|
||
Err err(
|
||
target_->defined_from(),
|
||
"Duplicate object file",
|
||
"The target " + target_->label().GetUserVisibleName(false) +
|
||
"\ngenerates two object files with the same name:\n " +
|
||
file.value() + "\n"
|
||
"\n"
|
||
"It could be you accidentally have a file listed twice in the\n"
|
||
"sources. Or, depending on how your toolchain maps sources to\n"
|
||
"object files, two source files with the same name in different\n"
|
||
"directories could map to the same object file.\n"
|
||
"\n"
|
||
"In the latter case, either rename one of the files or move one of\n"
|
||
"the sources to a separate source_set to avoid them both being in\n"
|
||
"the same target.");
|
||
g_scheduler->FailWithError(err);
|
||
return false;
|
||
}
|
||
}
|
||
return true;
|
||
}
|