compiler/debug/elf_debug_writer.cc - LeafOS-Project/android_art - Gitiles

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "elf_debug_writer.h"

 #include <type_traits>
 #include <unordered_map>
 #include <vector>

 #include "base/array_ref.h"
 #include "base/stl_util.h"
 #include "debug/elf_compilation_unit.h"
 #include "debug/elf_debug_frame_writer.h"
 #include "debug/elf_debug_info_writer.h"
 #include "debug/elf_debug_line_writer.h"
 #include "debug/elf_debug_loc_writer.h"
 #include "debug/elf_symtab_writer.h"
 #include "debug/method_debug_info.h"
 #include "dwarf/dwarf_constants.h"
 #include "elf/elf_builder.h"
 #include "elf/elf_debug_reader.h"
 #include "elf/elf_utils.h"
 #include "elf/xz_utils.h"
 #include "jit/debugger_interface.h"
 #include "oat/oat.h"
 #include "stream/vector_output_stream.h"

 namespace art HIDDEN {
 namespace debug {

 using ElfRuntimeTypes = std::conditional<sizeof(void*) == 4, ElfTypes32, ElfTypes64>::type;

 template <typename ElfTypes>
 void WriteDebugInfo(ElfBuilder<ElfTypes>* builder,
                     const DebugInfo& debug_info) {
   // Write .strtab and .symtab.
   WriteDebugSymbols(builder, /* mini-debug-info= */ false, debug_info);

   // Write .debug_frame.
   WriteCFISection(builder, debug_info.compiled_methods);

   // Group the methods into compilation units based on class.
   std::unordered_map<const dex::ClassDef*, ElfCompilationUnit> class_to_compilation_unit;
   for (const MethodDebugInfo& mi : debug_info.compiled_methods) {
     if (mi.dex_file != nullptr) {
       auto& dex_class_def = mi.dex_file->GetClassDef(mi.class_def_index);
       ElfCompilationUnit& cu = class_to_compilation_unit[&dex_class_def];
       cu.methods.push_back(&mi);
       // All methods must have the same addressing mode otherwise the min/max below does not work.
       DCHECK_EQ(cu.methods.front()->is_code_address_text_relative, mi.is_code_address_text_relative);
       cu.is_code_address_text_relative = mi.is_code_address_text_relative;
       cu.code_address = std::min(cu.code_address, mi.code_address);
       cu.code_end = std::max(cu.code_end, mi.code_address + mi.code_size);
     }
   }

   // Sort compilation units to make the compiler output deterministic.
   std::vector<ElfCompilationUnit> compilation_units;
   compilation_units.reserve(class_to_compilation_unit.size());
   for (auto& it : class_to_compilation_unit) {
     // The .debug_line section requires the methods to be sorted by code address.
     std::stable_sort(it.second.methods.begin(),
                      it.second.methods.end(),
                      [](const MethodDebugInfo* a, const MethodDebugInfo* b) {
                          return a->code_address < b->code_address;
                      });
     compilation_units.push_back(std::move(it.second));
   }
   std::sort(compilation_units.begin(),
             compilation_units.end(),
             [](ElfCompilationUnit& a, ElfCompilationUnit& b) {
                 // Sort by index of the first method within the method_infos array.
                 // This assumes that the order of method_infos is deterministic.
                 // Code address is not good for sorting due to possible duplicates.
                 return a.methods.front() < b.methods.front();
             });

   // Write .debug_line section.
   if (!compilation_units.empty()) {
     ElfDebugLineWriter<ElfTypes> line_writer(builder);
     line_writer.Start();
     for (auto& compilation_unit : compilation_units) {
       line_writer.WriteCompilationUnit(compilation_unit);
     }
     line_writer.End();
   }

   // Write .debug_info section.
   if (!compilation_units.empty()) {
     ElfDebugInfoWriter<ElfTypes> info_writer(builder);
     info_writer.Start();
     for (const auto& compilation_unit : compilation_units) {
       ElfCompilationUnitWriter<ElfTypes> cu_writer(&info_writer);
       cu_writer.Write(compilation_unit);
     }
     info_writer.End();
   }
 }

 template <typename ElfTypes>
 static std::vector<uint8_t> MakeMiniDebugInfoInternal(
     InstructionSet isa,
     [[maybe_unused]] const InstructionSetFeatures* features,
     typename ElfTypes::Addr text_section_address,
     size_t text_section_size,
     typename ElfTypes::Addr dex_section_address,
     size_t dex_section_size,
     const DebugInfo& debug_info) {
   std::vector<uint8_t> buffer;
   buffer.reserve(KB);
   VectorOutputStream out("Mini-debug-info ELF file", &buffer);
   std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
   builder->Start(/* write_program_headers= */ false);
   // Mirror ELF sections as NOBITS since the added symbols will reference them.
   if (text_section_size != 0) {
     builder->GetText()->AllocateVirtualMemory(text_section_address, text_section_size);
   }
   if (dex_section_size != 0) {
     builder->GetDex()->AllocateVirtualMemory(dex_section_address, dex_section_size);
   }
   if (!debug_info.Empty()) {
     WriteDebugSymbols(builder.get(), /* mini-debug-info= */ true, debug_info);
   }
   if (!debug_info.compiled_methods.empty()) {
     WriteCFISection(builder.get(), debug_info.compiled_methods);
   }
   builder->End();
   CHECK(builder->Good());
   std::vector<uint8_t> compressed_buffer;
   compressed_buffer.reserve(buffer.size() / 4);
   XzCompress(ArrayRef<const uint8_t>(buffer), &compressed_buffer);
   return compressed_buffer;
 }

 std::vector<uint8_t> MakeMiniDebugInfo(
     InstructionSet isa,
     const InstructionSetFeatures* features,
     uint64_t text_section_address,
     size_t text_section_size,
     uint64_t dex_section_address,
     size_t dex_section_size,
     const DebugInfo& debug_info) {
   if (Is64BitInstructionSet(isa)) {
     return MakeMiniDebugInfoInternal<ElfTypes64>(isa,
                                                  features,
                                                  text_section_address,
                                                  text_section_size,
                                                  dex_section_address,
                                                  dex_section_size,
                                                  debug_info);
   } else {
     return MakeMiniDebugInfoInternal<ElfTypes32>(isa,
                                                  features,
                                                  text_section_address,
                                                  text_section_size,
                                                  dex_section_address,
                                                  dex_section_size,
                                                  debug_info);
   }
 }

 std::vector<uint8_t> MakeElfFileForJIT(InstructionSet isa,
                                        [[maybe_unused]] const InstructionSetFeatures* features,
                                        bool mini_debug_info,
                                        const MethodDebugInfo& method_info) {
   using ElfTypes = ElfRuntimeTypes;
   CHECK_EQ(sizeof(ElfTypes::Addr), static_cast<size_t>(GetInstructionSetPointerSize(isa)));
   CHECK_EQ(method_info.is_code_address_text_relative, false);
   DebugInfo debug_info{};
   debug_info.compiled_methods = ArrayRef<const MethodDebugInfo>(&method_info, 1);
   std::vector<uint8_t> buffer;
   buffer.reserve(KB);
   VectorOutputStream out("Debug ELF file", &buffer);
   std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
   // No program headers since the ELF file is not linked and has no allocated sections.
   builder->Start(/* write_program_headers= */ false);
   builder->GetText()->AllocateVirtualMemory(method_info.code_address, method_info.code_size);
   if (mini_debug_info) {
     // The compression is great help for multiple methods but it is not worth it for a
     // single method due to the overheads so skip the compression here for performance.
     WriteDebugSymbols(builder.get(), /* mini-debug-info= */ true, debug_info);
     WriteCFISection(builder.get(), debug_info.compiled_methods);
   } else {
     WriteDebugInfo(builder.get(), debug_info);
   }
   builder->End();
   CHECK(builder->Good());
   // Verify the ELF file by reading it back using the trivial reader.
   if (kIsDebugBuild) {
     using Elf_Sym = typename ElfTypes::Sym;
     size_t num_syms = 0;
     size_t num_cies = 0;
     size_t num_fdes = 0;
     using Reader = ElfDebugReader<ElfTypes>;
     Reader reader(buffer);
     reader.VisitFunctionSymbols([&](Elf_Sym sym, const char*) {
       DCHECK_EQ(sym.st_value,
                 method_info.code_address + GetInstructionSetEntryPointAdjustment(isa));
       DCHECK_EQ(sym.st_size, method_info.code_size);
       num_syms++;
     });
     reader.VisitDebugFrame([&]([[maybe_unused]] const Reader::CIE* cie) { num_cies++; },
                            [&](const Reader::FDE* fde, [[maybe_unused]] const Reader::CIE* cie) {
                              DCHECK_EQ(fde->sym_addr, method_info.code_address);
                              DCHECK_EQ(fde->sym_size, method_info.code_size);
                              num_fdes++;
                            });
     DCHECK_EQ(num_syms, 1u);
     DCHECK_LE(num_cies, 1u);
     DCHECK_LE(num_fdes, 1u);
   }
   return buffer;
 }

 // Combine several mini-debug-info ELF files into one, while filtering some symbols.
 std::vector<uint8_t> PackElfFileForJIT(
     ArrayRef<const JITCodeEntry*> jit_entries,
     ArrayRef<const void*> removed_symbols,
     bool compress,
     /*out*/ size_t* num_symbols) {
   using ElfTypes = ElfRuntimeTypes;
   using Elf_Addr = typename ElfTypes::Addr;
   using Elf_Sym = typename ElfTypes::Sym;
   const InstructionSet isa = kRuntimeISA;
   CHECK_EQ(sizeof(Elf_Addr), static_cast<size_t>(GetInstructionSetPointerSize(isa)));
   const uint32_t kPcAlign = GetInstructionSetInstructionAlignment(isa);
   auto is_pc_aligned = [](const void* pc) { return IsAligned<kPcAlign>(pc); };
   DCHECK(std::all_of(removed_symbols.begin(), removed_symbols.end(), is_pc_aligned));
   auto is_removed_symbol = [&removed_symbols](Elf_Addr addr) {
     // Remove thumb-bit, if any (using the fact that address is instruction aligned).
     const void* code_ptr = AlignDown(reinterpret_cast<const void*>(addr), kPcAlign);
     return std::binary_search(removed_symbols.begin(), removed_symbols.end(), code_ptr);
   };
   uint64_t min_address = std::numeric_limits<uint64_t>::max();
   uint64_t max_address = 0;

   // Produce the inner ELF file.
   // It will contain the symbols (.symtab) and unwind information (.debug_frame).
   std::vector<uint8_t> inner_elf_file;
   {
     inner_elf_file.reserve(1 * KB);  // Approximate size of ELF file with a single symbol.
     VectorOutputStream out("Mini-debug-info ELF file for JIT", &inner_elf_file);
     std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
     builder->Start(/*write_program_headers=*/ false);
     auto* text = builder->GetText();
     auto* strtab = builder->GetStrTab();
     auto* symtab = builder->GetSymTab();
     auto* debug_frame = builder->GetDebugFrame();
     std::deque<Elf_Sym> symbols;

     using Reader = ElfDebugReader<ElfTypes>;
     std::deque<Reader> readers;
     for (const JITCodeEntry* it : jit_entries) {
       readers.emplace_back(GetJITCodeEntrySymFile(it));
     }

     // Write symbols names. All other data is buffered.
     strtab->Start();
     strtab->Write("");  // strtab should start with empty string.
     for (Reader& reader : readers) {
       reader.VisitFunctionSymbols([&](Elf_Sym sym, const char* name) {
           if (is_removed_symbol(sym.st_value)) {
             return;
           }
           sym.st_name = strtab->Write(name);
           symbols.push_back(sym);
           min_address = std::min<uint64_t>(min_address, sym.st_value);
           max_address = std::max<uint64_t>(max_address, sym.st_value + sym.st_size);
       });
     }
     strtab->End();

     // Create .text covering the code range. Needed for gdb to find the symbols.
     if (max_address > min_address) {
       text->AllocateVirtualMemory(min_address, max_address - min_address);
     }

     // Add the symbols.
     *num_symbols = symbols.size();
     for (; !symbols.empty(); symbols.pop_front()) {
       symtab->Add(symbols.front(), text);
     }
     symtab->WriteCachedSection();

     // Add the CFI/unwind section.
     debug_frame->Start();
     // ART always produces the same CIE, so we copy the first one and ignore the rest.
     bool copied_cie = false;
     for (Reader& reader : readers) {
       reader.VisitDebugFrame(
           [&](const Reader::CIE* cie) {
             if (!copied_cie) {
               debug_frame->WriteFully(cie->data(), cie->size());
               copied_cie = true;
             }
           },
           [&](const Reader::FDE* fde, [[maybe_unused]] const Reader::CIE* cie) {
             DCHECK(copied_cie);
             DCHECK_EQ(fde->cie_pointer, 0);
             if (!is_removed_symbol(fde->sym_addr)) {
               debug_frame->WriteFully(fde->data(), fde->size());
             }
           });
     }
     debug_frame->End();

     builder->End();
     CHECK(builder->Good());
   }

   // Produce the outer ELF file.
   // It contains only the inner ELF file compressed as .gnu_debugdata section.
   // This extra wrapping is not necessary but the compression saves space.
   if (compress) {
     std::vector<uint8_t> outer_elf_file;
     std::vector<uint8_t> gnu_debugdata;
     gnu_debugdata.reserve(inner_elf_file.size() / 4);
     XzCompress(ArrayRef<const uint8_t>(inner_elf_file), &gnu_debugdata);

     outer_elf_file.reserve(KB + gnu_debugdata.size());
     VectorOutputStream out("Mini-debug-info ELF file for JIT", &outer_elf_file);
     std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
     builder->Start(/*write_program_headers=*/ false);
     if (max_address > min_address) {
       builder->GetText()->AllocateVirtualMemory(min_address, max_address - min_address);
     }
     builder->WriteSection(".gnu_debugdata", &gnu_debugdata);
     builder->End();
     CHECK(builder->Good());
     return outer_elf_file;
   } else {
     return inner_elf_file;
   }
 }

 std::vector<uint8_t> WriteDebugElfFileForClasses(
     InstructionSet isa,
     [[maybe_unused]] const InstructionSetFeatures* features,
     const ArrayRef<mirror::Class*>& types) REQUIRES_SHARED(Locks::mutator_lock_) {
   using ElfTypes = ElfRuntimeTypes;
   CHECK_EQ(sizeof(ElfTypes::Addr), static_cast<size_t>(GetInstructionSetPointerSize(isa)));
   std::vector<uint8_t> buffer;
   buffer.reserve(KB);
   VectorOutputStream out("Debug ELF file", &buffer);
   std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
   // No program headers since the ELF file is not linked and has no allocated sections.
   builder->Start(/* write_program_headers= */ false);
   ElfDebugInfoWriter<ElfTypes> info_writer(builder.get());
   info_writer.Start();
   ElfCompilationUnitWriter<ElfTypes> cu_writer(&info_writer);
   cu_writer.Write(types);
   info_writer.End();

   builder->End();
   CHECK(builder->Good());
   return buffer;
 }

 // Explicit instantiations
 template void WriteDebugInfo<ElfTypes32>(
     ElfBuilder<ElfTypes32>* builder,
     const DebugInfo& debug_info);
 template void WriteDebugInfo<ElfTypes64>(
     ElfBuilder<ElfTypes64>* builder,
     const DebugInfo& debug_info);

 }  // namespace debug
 }  // namespace art
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "elf_debug_writer.h"

	#include <type_traits>
	#include <unordered_map>
	#include <vector>

	#include "base/array_ref.h"
	#include "base/stl_util.h"
	#include "debug/elf_compilation_unit.h"
	#include "debug/elf_debug_frame_writer.h"
	#include "debug/elf_debug_info_writer.h"
	#include "debug/elf_debug_line_writer.h"
	#include "debug/elf_debug_loc_writer.h"
	#include "debug/elf_symtab_writer.h"
	#include "debug/method_debug_info.h"
	#include "dwarf/dwarf_constants.h"
	#include "elf/elf_builder.h"
	#include "elf/elf_debug_reader.h"
	#include "elf/elf_utils.h"
	#include "elf/xz_utils.h"
	#include "jit/debugger_interface.h"
	#include "oat/oat.h"
	#include "stream/vector_output_stream.h"

	namespace art HIDDEN {
	namespace debug {

	using ElfRuntimeTypes = std::conditional<sizeof(void*) == 4, ElfTypes32, ElfTypes64>::type;

	template <typename ElfTypes>
	void WriteDebugInfo(ElfBuilder<ElfTypes>* builder,
	const DebugInfo& debug_info) {
	// Write .strtab and .symtab.
	WriteDebugSymbols(builder, /* mini-debug-info= */ false, debug_info);

	// Write .debug_frame.
	WriteCFISection(builder, debug_info.compiled_methods);

	// Group the methods into compilation units based on class.
	std::unordered_map<const dex::ClassDef*, ElfCompilationUnit> class_to_compilation_unit;
	for (const MethodDebugInfo& mi : debug_info.compiled_methods) {
	if (mi.dex_file != nullptr) {
	auto& dex_class_def = mi.dex_file->GetClassDef(mi.class_def_index);
	ElfCompilationUnit& cu = class_to_compilation_unit[&dex_class_def];
	cu.methods.push_back(&mi);
	// All methods must have the same addressing mode otherwise the min/max below does not work.
	DCHECK_EQ(cu.methods.front()->is_code_address_text_relative, mi.is_code_address_text_relative);
	cu.is_code_address_text_relative = mi.is_code_address_text_relative;
	cu.code_address = std::min(cu.code_address, mi.code_address);
	cu.code_end = std::max(cu.code_end, mi.code_address + mi.code_size);
	}
	}

	// Sort compilation units to make the compiler output deterministic.
	std::vector<ElfCompilationUnit> compilation_units;
	compilation_units.reserve(class_to_compilation_unit.size());
	for (auto& it : class_to_compilation_unit) {
	// The .debug_line section requires the methods to be sorted by code address.
	std::stable_sort(it.second.methods.begin(),
	it.second.methods.end(),
	[](const MethodDebugInfo* a, const MethodDebugInfo* b) {
	return a->code_address < b->code_address;
	});
	compilation_units.push_back(std::move(it.second));
	}
	std::sort(compilation_units.begin(),
	compilation_units.end(),
	[](ElfCompilationUnit& a, ElfCompilationUnit& b) {
	// Sort by index of the first method within the method_infos array.
	// This assumes that the order of method_infos is deterministic.
	// Code address is not good for sorting due to possible duplicates.
	return a.methods.front() < b.methods.front();
	});

	// Write .debug_line section.
	if (!compilation_units.empty()) {
	ElfDebugLineWriter<ElfTypes> line_writer(builder);
	line_writer.Start();
	for (auto& compilation_unit : compilation_units) {
	line_writer.WriteCompilationUnit(compilation_unit);
	}
	line_writer.End();
	}

	// Write .debug_info section.
	if (!compilation_units.empty()) {
	ElfDebugInfoWriter<ElfTypes> info_writer(builder);
	info_writer.Start();
	for (const auto& compilation_unit : compilation_units) {
	ElfCompilationUnitWriter<ElfTypes> cu_writer(&info_writer);
	cu_writer.Write(compilation_unit);
	}
	info_writer.End();
	}
	}

	template <typename ElfTypes>
	static std::vector<uint8_t> MakeMiniDebugInfoInternal(
	InstructionSet isa,
	[[maybe_unused]] const InstructionSetFeatures* features,
	typename ElfTypes::Addr text_section_address,
	size_t text_section_size,
	typename ElfTypes::Addr dex_section_address,
	size_t dex_section_size,
	const DebugInfo& debug_info) {
	std::vector<uint8_t> buffer;
	buffer.reserve(KB);
	VectorOutputStream out("Mini-debug-info ELF file", &buffer);
	std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
	builder->Start(/* write_program_headers= */ false);
	// Mirror ELF sections as NOBITS since the added symbols will reference them.
	if (text_section_size != 0) {
	builder->GetText()->AllocateVirtualMemory(text_section_address, text_section_size);
	}
	if (dex_section_size != 0) {
	builder->GetDex()->AllocateVirtualMemory(dex_section_address, dex_section_size);
	}
	if (!debug_info.Empty()) {
	WriteDebugSymbols(builder.get(), /* mini-debug-info= */ true, debug_info);
	}
	if (!debug_info.compiled_methods.empty()) {
	WriteCFISection(builder.get(), debug_info.compiled_methods);
	}
	builder->End();
	CHECK(builder->Good());
	std::vector<uint8_t> compressed_buffer;
	compressed_buffer.reserve(buffer.size() / 4);
	XzCompress(ArrayRef<const uint8_t>(buffer), &compressed_buffer);
	return compressed_buffer;
	}

	std::vector<uint8_t> MakeMiniDebugInfo(
	InstructionSet isa,
	const InstructionSetFeatures* features,
	uint64_t text_section_address,
	size_t text_section_size,
	uint64_t dex_section_address,
	size_t dex_section_size,
	const DebugInfo& debug_info) {
	if (Is64BitInstructionSet(isa)) {
	return MakeMiniDebugInfoInternal<ElfTypes64>(isa,
	features,
	text_section_address,
	text_section_size,
	dex_section_address,
	dex_section_size,
	debug_info);
	} else {
	return MakeMiniDebugInfoInternal<ElfTypes32>(isa,
	features,
	text_section_address,
	text_section_size,
	dex_section_address,
	dex_section_size,
	debug_info);
	}
	}

	std::vector<uint8_t> MakeElfFileForJIT(InstructionSet isa,
	[[maybe_unused]] const InstructionSetFeatures* features,
	bool mini_debug_info,
	const MethodDebugInfo& method_info) {
	using ElfTypes = ElfRuntimeTypes;
	CHECK_EQ(sizeof(ElfTypes::Addr), static_cast<size_t>(GetInstructionSetPointerSize(isa)));
	CHECK_EQ(method_info.is_code_address_text_relative, false);
	DebugInfo debug_info{};
	debug_info.compiled_methods = ArrayRef<const MethodDebugInfo>(&method_info, 1);
	std::vector<uint8_t> buffer;
	buffer.reserve(KB);
	VectorOutputStream out("Debug ELF file", &buffer);
	std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
	// No program headers since the ELF file is not linked and has no allocated sections.
	builder->Start(/* write_program_headers= */ false);
	builder->GetText()->AllocateVirtualMemory(method_info.code_address, method_info.code_size);
	if (mini_debug_info) {
	// The compression is great help for multiple methods but it is not worth it for a
	// single method due to the overheads so skip the compression here for performance.
	WriteDebugSymbols(builder.get(), /* mini-debug-info= */ true, debug_info);
	WriteCFISection(builder.get(), debug_info.compiled_methods);
	} else {
	WriteDebugInfo(builder.get(), debug_info);
	}
	builder->End();
	CHECK(builder->Good());
	// Verify the ELF file by reading it back using the trivial reader.
	if (kIsDebugBuild) {
	using Elf_Sym = typename ElfTypes::Sym;
	size_t num_syms = 0;
	size_t num_cies = 0;
	size_t num_fdes = 0;
	using Reader = ElfDebugReader<ElfTypes>;
	Reader reader(buffer);
	reader.VisitFunctionSymbols([&](Elf_Sym sym, const char*) {
	DCHECK_EQ(sym.st_value,
	method_info.code_address + GetInstructionSetEntryPointAdjustment(isa));
	DCHECK_EQ(sym.st_size, method_info.code_size);
	num_syms++;
	});
	reader.VisitDebugFrame([&]([[maybe_unused]] const Reader::CIE* cie) { num_cies++; },
	[&](const Reader::FDE* fde, [[maybe_unused]] const Reader::CIE* cie) {
	DCHECK_EQ(fde->sym_addr, method_info.code_address);
	DCHECK_EQ(fde->sym_size, method_info.code_size);
	num_fdes++;
	});
	DCHECK_EQ(num_syms, 1u);
	DCHECK_LE(num_cies, 1u);
	DCHECK_LE(num_fdes, 1u);
	}
	return buffer;
	}

	// Combine several mini-debug-info ELF files into one, while filtering some symbols.
	std::vector<uint8_t> PackElfFileForJIT(
	ArrayRef<const JITCodeEntry*> jit_entries,
	ArrayRef<const void*> removed_symbols,
	bool compress,
	/out/ size_t* num_symbols) {
	using ElfTypes = ElfRuntimeTypes;
	using Elf_Addr = typename ElfTypes::Addr;
	using Elf_Sym = typename ElfTypes::Sym;
	const InstructionSet isa = kRuntimeISA;
	CHECK_EQ(sizeof(Elf_Addr), static_cast<size_t>(GetInstructionSetPointerSize(isa)));
	const uint32_t kPcAlign = GetInstructionSetInstructionAlignment(isa);
	auto is_pc_aligned = [](const void* pc) { return IsAligned<kPcAlign>(pc); };
	DCHECK(std::all_of(removed_symbols.begin(), removed_symbols.end(), is_pc_aligned));
	auto is_removed_symbol = [&removed_symbols](Elf_Addr addr) {
	// Remove thumb-bit, if any (using the fact that address is instruction aligned).
	const void* code_ptr = AlignDown(reinterpret_cast<const void*>(addr), kPcAlign);
	return std::binary_search(removed_symbols.begin(), removed_symbols.end(), code_ptr);
	};
	uint64_t min_address = std::numeric_limits<uint64_t>::max();
	uint64_t max_address = 0;

	// Produce the inner ELF file.
	// It will contain the symbols (.symtab) and unwind information (.debug_frame).
	std::vector<uint8_t> inner_elf_file;
	{
	inner_elf_file.reserve(1 * KB); // Approximate size of ELF file with a single symbol.
	VectorOutputStream out("Mini-debug-info ELF file for JIT", &inner_elf_file);
	std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
	builder->Start(/write_program_headers=/ false);
	auto* text = builder->GetText();
	auto* strtab = builder->GetStrTab();
	auto* symtab = builder->GetSymTab();
	auto* debug_frame = builder->GetDebugFrame();
	std::deque<Elf_Sym> symbols;

	using Reader = ElfDebugReader<ElfTypes>;
	std::deque<Reader> readers;
	for (const JITCodeEntry* it : jit_entries) {
	readers.emplace_back(GetJITCodeEntrySymFile(it));
	}

	// Write symbols names. All other data is buffered.
	strtab->Start();
	strtab->Write(""); // strtab should start with empty string.
	for (Reader& reader : readers) {
	reader.VisitFunctionSymbols([&](Elf_Sym sym, const char* name) {
	if (is_removed_symbol(sym.st_value)) {
	return;
	}
	sym.st_name = strtab->Write(name);
	symbols.push_back(sym);
	min_address = std::min<uint64_t>(min_address, sym.st_value);
	max_address = std::max<uint64_t>(max_address, sym.st_value + sym.st_size);
	});
	}
	strtab->End();

	// Create .text covering the code range. Needed for gdb to find the symbols.
	if (max_address > min_address) {
	text->AllocateVirtualMemory(min_address, max_address - min_address);
	}

	// Add the symbols.
	*num_symbols = symbols.size();
	for (; !symbols.empty(); symbols.pop_front()) {
	symtab->Add(symbols.front(), text);
	}
	symtab->WriteCachedSection();

	// Add the CFI/unwind section.
	debug_frame->Start();
	// ART always produces the same CIE, so we copy the first one and ignore the rest.
	bool copied_cie = false;
	for (Reader& reader : readers) {
	reader.VisitDebugFrame(
	[&](const Reader::CIE* cie) {
	if (!copied_cie) {
	debug_frame->WriteFully(cie->data(), cie->size());
	copied_cie = true;
	}
	},
	[&](const Reader::FDE* fde, [[maybe_unused]] const Reader::CIE* cie) {
	DCHECK(copied_cie);
	DCHECK_EQ(fde->cie_pointer, 0);
	if (!is_removed_symbol(fde->sym_addr)) {
	debug_frame->WriteFully(fde->data(), fde->size());
	}
	});
	}
	debug_frame->End();

	builder->End();
	CHECK(builder->Good());
	}

	// Produce the outer ELF file.
	// It contains only the inner ELF file compressed as .gnu_debugdata section.
	// This extra wrapping is not necessary but the compression saves space.
	if (compress) {
	std::vector<uint8_t> outer_elf_file;
	std::vector<uint8_t> gnu_debugdata;
	gnu_debugdata.reserve(inner_elf_file.size() / 4);
	XzCompress(ArrayRef<const uint8_t>(inner_elf_file), &gnu_debugdata);

	outer_elf_file.reserve(KB + gnu_debugdata.size());
	VectorOutputStream out("Mini-debug-info ELF file for JIT", &outer_elf_file);
	std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
	builder->Start(/write_program_headers=/ false);
	if (max_address > min_address) {
	builder->GetText()->AllocateVirtualMemory(min_address, max_address - min_address);
	}
	builder->WriteSection(".gnu_debugdata", &gnu_debugdata);
	builder->End();
	CHECK(builder->Good());
	return outer_elf_file;
	} else {
	return inner_elf_file;
	}
	}

	std::vector<uint8_t> WriteDebugElfFileForClasses(
	InstructionSet isa,
	[[maybe_unused]] const InstructionSetFeatures* features,
	const ArrayRef<mirror::Class*>& types) REQUIRES_SHARED(Locks::mutator_lock_) {
	using ElfTypes = ElfRuntimeTypes;
	CHECK_EQ(sizeof(ElfTypes::Addr), static_cast<size_t>(GetInstructionSetPointerSize(isa)));
	std::vector<uint8_t> buffer;
	buffer.reserve(KB);
	VectorOutputStream out("Debug ELF file", &buffer);
	std::unique_ptr<ElfBuilder<ElfTypes>> builder(new ElfBuilder<ElfTypes>(isa, &out));
	// No program headers since the ELF file is not linked and has no allocated sections.
	builder->Start(/* write_program_headers= */ false);
	ElfDebugInfoWriter<ElfTypes> info_writer(builder.get());
	info_writer.Start();
	ElfCompilationUnitWriter<ElfTypes> cu_writer(&info_writer);
	cu_writer.Write(types);
	info_writer.End();

	builder->End();
	CHECK(builder->Good());
	return buffer;
	}

	// Explicit instantiations
	template void WriteDebugInfo<ElfTypes32>(
	ElfBuilder<ElfTypes32>* builder,
	const DebugInfo& debug_info);
	template void WriteDebugInfo<ElfTypes64>(
	ElfBuilder<ElfTypes64>* builder,
	const DebugInfo& debug_info);

	} // namespace debug
	} // namespace art