#include "mold.h"

#include <functional>
#include <map>
#include <regex>
#include <tbb/parallel_do.h>
#include <tbb/parallel_for_each.h>
#include <tbb/parallel_scan.h>
#include <tbb/partitioner.h>
#include <unordered_set>

template <typename E>
void apply_exclude_libs(Context<E> &ctx) {
  Timer t(ctx, "apply_exclude_libs");

  if (ctx.arg.exclude_libs.empty())
    return;

  std::unordered_set<std::string_view> set(ctx.arg.exclude_libs.begin(),
                                           ctx.arg.exclude_libs.end());

  for (ObjectFile<E> *file : ctx.objs)
    if (!file->archive_name.empty())
      if (set.contains("ALL") ||
          set.contains(path_filename(file->archive_name)))
        file->exclude_libs = true;
}

template <typename E>
void create_synthetic_sections(Context<E> &ctx) {
  auto add = [&](auto &chunk) {
    ctx.chunks.push_back(chunk.get());
  };

  add(ctx.ehdr = std::make_unique<OutputEhdr<E>>());
  add(ctx.phdr = std::make_unique<OutputPhdr<E>>());
  add(ctx.shdr = std::make_unique<OutputShdr<E>>());
  add(ctx.got = std::make_unique<GotSection<E>>());
  add(ctx.gotplt = std::make_unique<GotPltSection<E>>());
  add(ctx.relplt = std::make_unique<RelPltSection<E>>());
  add(ctx.strtab = std::make_unique<StrtabSection<E>>());
  add(ctx.shstrtab = std::make_unique<ShstrtabSection<E>>());
  add(ctx.plt = std::make_unique<PltSection<E>>());
  add(ctx.pltgot = std::make_unique<PltGotSection<E>>());
  add(ctx.symtab = std::make_unique<SymtabSection<E>>());
  add(ctx.dynsym = std::make_unique<DynsymSection<E>>());
  add(ctx.dynstr = std::make_unique<DynstrSection<E>>());
  add(ctx.eh_frame = std::make_unique<EhFrameSection<E>>());
  add(ctx.dynbss = std::make_unique<DynbssSection<E>>(false));
  add(ctx.dynbss_relro = std::make_unique<DynbssSection<E>>(true));

  if (!ctx.arg.dynamic_linker.empty())
    add(ctx.interp = std::make_unique<InterpSection<E>>());
  if (ctx.arg.build_id.kind != BuildId::NONE)
    add(ctx.buildid = std::make_unique<BuildIdSection<E>>());
  if (ctx.arg.eh_frame_hdr)
    add(ctx.eh_frame_hdr = std::make_unique<EhFrameHdrSection<E>>());
  if (ctx.arg.hash_style_sysv)
    add(ctx.hash = std::make_unique<HashSection<E>>());
  if (ctx.arg.hash_style_gnu)
    add(ctx.gnu_hash = std::make_unique<GnuHashSection<E>>());
  if (!ctx.arg.version_definitions.empty())
    add(ctx.verdef = std::make_unique<VerdefSection<E>>());

  add(ctx.reldyn = std::make_unique<RelDynSection<E>>());
  add(ctx.dynamic = std::make_unique<DynamicSection<E>>());
  add(ctx.versym = std::make_unique<VersymSection<E>>());
  add(ctx.verneed = std::make_unique<VerneedSection<E>>());
  add(ctx.note_property = std::make_unique<NotePropertySection<E>>());

  if (ctx.arg.repro)
    add(ctx.repro = std::make_unique<ReproSection<E>>());
}

template <typename E>
void resolve_symbols(Context<E> &ctx) {
  Timer t(ctx, "resolve_obj_symbols");

  // Register object symbols
  tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
    if (file->is_in_lib)
      file->resolve_lazy_symbols(ctx);
    else
      file->resolve_regular_symbols(ctx);
  });

  // Register DSO symbols
  tbb::parallel_for_each(ctx.dsos, [&](SharedFile<E> *file) {
    file->resolve_dso_symbols(ctx);
  });

  // Mark reachable objects to decide which files to include
  // into an output.
  std::vector<ObjectFile<E> *> live_objs = ctx.objs;
  erase(live_objs, [](InputFile<E> *file) { return !file->is_alive; });

  for (std::string_view name : ctx.arg.undefined)
    if (InputFile<E> *file = Symbol<E>::intern(ctx, name)->file)
      if (!file->is_alive.exchange(true) && !file->is_dso)
        live_objs.push_back((ObjectFile<E> *)file);

  tbb::parallel_do(live_objs,
                   [&](ObjectFile<E> *file,
                       tbb::parallel_do_feeder<ObjectFile<E> *> &feeder) {
    file->mark_live_objects(ctx, [&](ObjectFile<E> *obj) { feeder.add(obj); });
  });

  // Remove symbols of eliminated objects.
  tbb::parallel_for_each(ctx.objs, [](ObjectFile<E> *file) {
    if (!file->is_alive)
      for (Symbol<E> *sym : file->get_global_syms())
        if (sym->file == file)
          new (sym) Symbol<E>(sym->name());
  });

  // Eliminate unused archive members.
  erase(ctx.objs, [](InputFile<E> *file) { return !file->is_alive; });

  // Mark live DSOs
  tbb::parallel_for_each(ctx.objs, [](ObjectFile<E> *file) {
    for (i64 i = file->first_global; i < file->elf_syms.size(); i++) {
      const ElfSym<E> &esym = file->elf_syms[i];
      Symbol<E> &sym = *file->symbols[i];
      if (esym.is_undef_strong() && sym.file && sym.file->is_dso) {
        std::lock_guard lock(sym.mu);
        sym.file->is_alive = true;
        sym.is_weak = false;
      }
    }
  });

  // DSOs referenced by live DSOs are also alive.
  std::vector<SharedFile<E> *> live_dsos = ctx.dsos;
  erase(live_dsos, [](SharedFile<E> *file) { return !file->is_alive; });

  tbb::parallel_do(live_dsos,
                   [&](SharedFile<E> *file,
                       tbb::parallel_do_feeder<SharedFile<E> *> &feeder) {
    for (Symbol<E> *sym : file->globals)
      if (sym->file && sym->file != file && sym->file->is_dso &&
          !sym->file->is_alive.exchange(true))
        feeder.add(file);
  });

  // Remove symbols of unreferenced DSOs.
  tbb::parallel_for_each(ctx.dsos, [](SharedFile<E> *file) {
    if (!file->is_alive)
      for (Symbol<E> *sym : file->symbols)
        if (sym->file == file)
          new (sym) Symbol<E>(sym->name());
  });

  // Remove unreferenced DSOs
  erase(ctx.dsos, [](InputFile<E> *file) { return !file->is_alive; });

  // Register common symbols
  tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
    file->resolve_common_symbols(ctx);
  });

  if (Symbol<E> *sym = Symbol<E>::intern(ctx, "__gnu_lto_slim"); sym->file)
    Fatal(ctx) << *sym->file << ": looks like this file contains a GCC "
               << "intermediate code, but mold does not support LTO";
}

template <typename E>
void eliminate_comdats(Context<E> &ctx) {
  Timer t(ctx, "eliminate_comdats");

  tbb::parallel_for_each(ctx.objs, [](ObjectFile<E> *file) {
    file->resolve_comdat_groups();
  });

  tbb::parallel_for_each(ctx.objs, [](ObjectFile<E> *file) {
    file->eliminate_duplicate_comdat_groups();
  });
}

template <typename E>
void convert_common_symbols(Context<E> &ctx) {
  Timer t(ctx, "convert_common_symbols");

  tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
    file->convert_common_symbols(ctx);
  });
}

template <typename E>
static std::string get_cmdline_args(Context<E> &ctx) {
  std::stringstream ss;
  ss << ctx.cmdline_args[1];
  for (i64 i = 2; i < ctx.cmdline_args.size(); i++)
    ss << " " << ctx.cmdline_args[i];
  return ss.str();
}

template <typename E>
void add_comment_string(Context<E> &ctx, std::string str) {
  std::string_view buf = save_string(ctx, str);
  MergedSection<E> *sec =
    MergedSection<E>::get_instance(ctx, ".comment", SHT_PROGBITS, 0);
  SectionFragment<E> *frag = sec->insert({buf.data(), buf.size() + 1}, 1);
  frag->is_alive = true;
}

template <typename E>
void compute_merged_section_sizes(Context<E> &ctx) {
  Timer t(ctx, "compute_merged_section_sizes");

  // Mark section fragments referenced by live objects.
  if (!ctx.arg.gc_sections) {
    tbb::parallel_for_each(ctx.objs, [](ObjectFile<E> *file) {
      for (SectionFragment<E> *frag : file->fragments)
        frag->is_alive = true;
    });
  }

  // Add an identification string to .comment.
  add_comment_string(ctx, get_version_string());

  // Embed command line arguments for debugging.
  if (char *env = getenv("MOLD_DEBUG"); env && env[0])
    add_comment_string(ctx, "mold command line: " + get_cmdline_args(ctx));

  tbb::parallel_for_each(ctx.merged_sections,
                         [](std::unique_ptr<MergedSection<E>> &sec) {
    sec->assign_offsets();
  });
}

template <typename T>
static std::vector<std::span<T>> split(std::vector<T> &input, i64 unit) {
  assert(input.size() > 0);
  std::span<T> span(input);
  std::vector<std::span<T>> vec;

  while (span.size() >= unit) {
    vec.push_back(span.subspan(0, unit));
    span = span.subspan(unit);
  }
  if (!span.empty())
    vec.push_back(span);
  return vec;
}

// So far, each input section has a pointer to its corresponding
// output section, but there's no reverse edge to get a list of
// input sections from an output section. This function creates it.
//
// An output section may contain millions of input sections.
// So, we append input sections to output sections in parallel.
template <typename E>
void bin_sections(Context<E> &ctx) {
  Timer t(ctx, "bin_sections");

  static constexpr i64 num_shards = 128;
  i64 unit = (ctx.objs.size() + num_shards - 1) / num_shards;
  std::vector<std::span<ObjectFile<E> *>> slices = split(ctx.objs, unit);

  i64 num_osec = ctx.output_sections.size();

  std::vector<std::vector<std::vector<InputSection<E> *>>> groups(slices.size());
  for (i64 i = 0; i < groups.size(); i++)
    groups[i].resize(num_osec);

  tbb::parallel_for((i64)0, (i64)slices.size(), [&](i64 i) {
    for (ObjectFile<E> *file : slices[i])
      for (std::unique_ptr<InputSection<E>> &isec : file->sections)
        if (isec && isec->is_alive)
          groups[i][isec->output_section->idx].push_back(isec.get());
  });

  std::vector<i64> sizes(num_osec);

  for (std::span<std::vector<InputSection<E> *>> group : groups)
    for (i64 i = 0; i < group.size(); i++)
      sizes[i] += group[i].size();

  tbb::parallel_for((i64)0, num_osec, [&](i64 j) {
    ctx.output_sections[j]->members.reserve(sizes[j]);
    for (i64 i = 0; i < groups.size(); i++)
      append(ctx.output_sections[j]->members, groups[i][j]);
  });
}

template <typename E>
void check_duplicate_symbols(Context<E> &ctx) {
  Timer t(ctx, "check_dup_syms");

  tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
    for (i64 i = file->first_global; i < file->elf_syms.size(); i++) {
      const ElfSym<E> &esym = file->elf_syms[i];
      Symbol<E> &sym = *file->symbols[i];

      if (sym.file == file || sym.file == ctx.internal_obj ||
          esym.is_undef() || esym.is_common() || (esym.st_bind == STB_WEAK))
        continue;

      if (!esym.is_abs() && !file->get_section(esym)->is_alive)
        continue;

      Error(ctx) << "duplicate symbol: " << *file << ": " << *sym.file
                 << ": " << sym;
    }
  });

  Error<E>::checkpoint(ctx);
}

template <typename E>
void sort_init_fini(Context<E> &ctx) {
  Timer t(ctx, "sort_init_fini");

  auto get_priority = [](InputSection<E> *isec) {
    static std::regex re(R"(_array\.(\d+)$)");
    std::string name = isec->name().begin();
    std::smatch m;
    if (std::regex_search(name, m, re))
      return std::stoi(m[1]);
    return 65536;
  };

  for (std::unique_ptr<OutputSection<E>> &osec : ctx.output_sections) {
    if (osec->name == ".init_array" || osec->name == ".fini_array") {
      sort(osec->members, [&](InputSection<E> *a, InputSection<E> *b) {
        return get_priority(a) < get_priority(b);
      });
    }
  }
}

template <typename E>
std::vector<OutputChunk<E> *> collect_output_sections(Context<E> &ctx) {
  std::vector<OutputChunk<E> *> vec;

  for (std::unique_ptr<OutputSection<E>> &osec : ctx.output_sections)
    if (!osec->members.empty())
      vec.push_back(osec.get());
  for (std::unique_ptr<MergedSection<E>> &osec : ctx.merged_sections)
    if (osec->shdr.sh_size)
      vec.push_back(osec.get());

  // Sections are added to the section lists in an arbitrary order because
  // they are created in parallel.
  // Sort them to to make the output deterministic.
  sort(vec, [](OutputChunk<E> *x, OutputChunk<E> *y) {
    return std::tuple(x->name, x->shdr.sh_type, x->shdr.sh_flags) <
           std::tuple(y->name, y->shdr.sh_type, y->shdr.sh_flags);
  });
  return vec;
}

template <typename E>
void compute_section_sizes(Context<E> &ctx) {
  Timer t(ctx, "compute_section_sizes");

  tbb::parallel_for_each(ctx.output_sections,
                         [&](std::unique_ptr<OutputSection<E>> &osec) {
    if (osec->members.empty())
      return;

    struct T {
      i64 offset;
      i64 align;
    };

    T sum = tbb::parallel_scan(
      tbb::blocked_range<i64>(0, osec->members.size(), 10000),
      T{0, 1},
      [&](const tbb::blocked_range<i64> &r, T sum, bool is_final) {
        for (i64 i = r.begin(); i < r.end(); i++) {
          InputSection<E> &isec = *osec->members[i];
          sum.offset = align_to(sum.offset, isec.shdr.sh_addralign);
          if (is_final)
            isec.offset = sum.offset;
          sum.offset += isec.shdr.sh_size;
          sum.align = std::max<i64>(sum.align, isec.shdr.sh_addralign);
        }
        return sum;
      },
      [](T lhs, T rhs) {
        i64 offset = align_to(lhs.offset, rhs.align) + rhs.offset;
        i64 align = std::max(lhs.align, rhs.align);
        return T{offset, align};
      },
      tbb::simple_partitioner());

    osec->shdr.sh_size = sum.offset;
    osec->shdr.sh_addralign = sum.align;
  });
}

template <typename E>
void claim_unresolved_symbols(Context<E> &ctx) {
  Timer t(ctx, "claim_unresolved_symbols");
  tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
    file->claim_unresolved_symbols(ctx);
  });
}

template <typename E>
void scan_rels(Context<E> &ctx) {
  Timer t(ctx, "scan_rels");

  // Scan relocations to find dynamic symbols.
  tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
    file->scan_relocations(ctx);
  });

  // Exit if there was a relocation that refers an undefined symbol.
  Error<E>::checkpoint(ctx);

  // Add symbol aliases for COPYREL.
  tbb::parallel_for_each(ctx.dsos, [&](SharedFile<E> *file) {
    for (Symbol<E> *sym : file->symbols)
      if (sym->file == file && (sym->flags & NEEDS_COPYREL))
        for (Symbol<E> *alias : file->find_aliases(sym))
          alias->flags |= NEEDS_DYNSYM;
  });

  // Aggregate dynamic symbols to a single vector.
  std::vector<InputFile<E> *> files;
  append(files, ctx.objs);
  append(files, ctx.dsos);

  std::vector<std::vector<Symbol<E> *>> vec(files.size());

  tbb::parallel_for((i64)0, (i64)files.size(), [&](i64 i) {
    for (Symbol<E> *sym : files[i]->symbols) {
      if (!files[i]->is_dso && (sym->is_imported || sym->is_exported))
        sym->flags |= NEEDS_DYNSYM;
      if (sym->file == files[i] && sym->flags)
        vec[i].push_back(sym);
    }
  });

  std::vector<Symbol<E> *> syms = flatten(vec);

  ctx.symbol_aux.resize(syms.size());
  for (i64 i = 0; i < syms.size(); i++)
    syms[i]->aux_idx = i;

  // Assign offsets in additional tables for each dynamic symbol.
  for (Symbol<E> *sym : syms) {
    if ((sym->flags & NEEDS_COPYREL) && sym->esym().is_undef_weak()) {
      // Weak undefined symbols can be converted to imported symbols, but
      // we can't create copy relocations against them because we don't
      // know their symbol sizes. Therefore, if we have to create copyrels
      // against such symbols, we instead turns the symbols into
      // non-imported absoute ones with value 0. That means weak symbols
      // are exported only when compiled with -fPIC, and the same program
      // can have different meanings depending on the presence or absense
      // that flag. That's bad, but this is the best we can do.
      sym->is_imported = false;
      sym->flags = 0;
      continue;
    }

    if (sym->flags & NEEDS_DYNSYM)
      ctx.dynsym->add_symbol(ctx, sym);

    if (sym->flags & NEEDS_GOT)
      ctx.got->add_got_symbol(ctx, sym);

    if (sym->flags & NEEDS_PLT) {
      if (sym->flags & NEEDS_GOT)
        ctx.pltgot->add_symbol(ctx, sym);
      else
        ctx.plt->add_symbol(ctx, sym);
    }

    if (sym->flags & NEEDS_GOTTP)
      ctx.got->add_gottp_symbol(ctx, sym);

    if (sym->flags & NEEDS_TLSGD)
      ctx.got->add_tlsgd_symbol(ctx, sym);

    if (sym->flags & NEEDS_TLSDESC)
      ctx.got->add_tlsdesc_symbol(ctx, sym);

    if (sym->flags & NEEDS_TLSLD)
      ctx.got->add_tlsld(ctx);

    if (sym->flags & NEEDS_COPYREL) {
      assert(sym->file->is_dso);
      SharedFile<E> *file = (SharedFile<E> *)sym->file;
      sym->copyrel_readonly = file->is_readonly(ctx, sym);

      if (sym->copyrel_readonly)
        ctx.dynbss_relro->add_symbol(ctx, sym);
      else
        ctx.dynbss->add_symbol(ctx, sym);

      for (Symbol<E> *alias : file->find_aliases(sym)) {
        alias->has_copyrel = true;
        alias->value = sym->value;
        alias->copyrel_readonly = sym->copyrel_readonly;
        ctx.dynsym->add_symbol(ctx, alias);
      }
    }

    sym->flags = 0;
  }
}

template <typename E>
void apply_version_script(Context<E> &ctx) {
  Timer t(ctx, "apply_version_script");

  for (VersionPattern &elem : ctx.arg.version_patterns) {
    assert(elem.pattern != "*");

    if (!elem.is_extern_cpp &&
        elem.pattern.find('*') == elem.pattern.npos) {
      Symbol<E>::intern(ctx, elem.pattern)->ver_idx = elem.ver_idx;
      continue;
    }

    std::regex re = glob_to_regex(elem.pattern);

    tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
      for (Symbol<E> *sym : file->get_global_syms()) {
        if (sym->file == file) {
          std::string_view name = elem.is_extern_cpp
            ? sym->get_demangled_name() : sym->name();
          if (std::regex_match(name.begin(), name.end(), re))
            sym->ver_idx = elem.ver_idx;
        }
      }
    });
  }
}

template <typename E>
void parse_symbol_version(Context<E> &ctx) {
  if (!ctx.arg.shared)
    return;

  Timer t(ctx, "parse_symbol_version");

  std::unordered_map<std::string_view, u16> verdefs;
  for (i64 i = 0; i < ctx.arg.version_definitions.size(); i++)
    verdefs[ctx.arg.version_definitions[i]] = i + VER_NDX_LAST_RESERVED + 1;

  tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
    for (i64 i = 0; i < file->symbols.size() - file->first_global; i++) {
      if (!file->symvers[i])
        continue;

      Symbol<E> *sym = file->symbols[i + file->first_global];
      if (sym->file != file)
        continue;

      std::string_view ver = file->symvers[i];

      bool is_default = false;
      if (ver.starts_with('@')) {
        is_default = true;
        ver = ver.substr(1);
      }

      auto it = verdefs.find(ver);
      if (it == verdefs.end()) {
        Error(ctx) << *file << ": symbol " << *sym <<  " has undefined version "
                   << ver;
        continue;
      }

      sym->ver_idx = it->second;
      if (!is_default)
        sym->ver_idx |= VERSYM_HIDDEN;
    }
  });
}

template <typename E>
void compute_import_export(Context<E> &ctx) {
  Timer t(ctx, "compute_import_export");

  // Export symbols referenced by DSOs.
  if (!ctx.arg.shared) {
    tbb::parallel_for_each(ctx.dsos, [&](SharedFile<E> *file) {
      for (Symbol<E> *sym : file->globals) {
        if (sym->file && !sym->file->is_dso && sym->visibility != STV_HIDDEN) {
          std::lock_guard lock(sym->mu);
          sym->is_exported = true;
        }
      }
    });
  }

  // Global symbols are exported from DSO by default.
  if (ctx.arg.shared || ctx.arg.export_dynamic) {
    tbb::parallel_for_each(ctx.objs, [&](ObjectFile<E> *file) {
      for (Symbol<E> *sym : file->get_global_syms()) {
        if (sym->file != file)
          continue;

        if (sym->visibility == STV_HIDDEN || sym->ver_idx == VER_NDX_LOCAL)
          continue;

        sym->is_exported = true;

        if (ctx.arg.shared && sym->visibility != STV_PROTECTED &&
            !ctx.arg.Bsymbolic &&
            !(ctx.arg.Bsymbolic_functions && sym->get_type() == STT_FUNC))
          sym->is_imported = true;
      }
    });
  }
}

template <typename E>
void clear_padding(Context<E> &ctx) {
  Timer t(ctx, "clear_padding");

  auto zero = [&](OutputChunk<E> *chunk, i64 next_start) {
    i64 pos = chunk->shdr.sh_offset;
    if (chunk->shdr.sh_type != SHT_NOBITS)
      pos += chunk->shdr.sh_size;
    memset(ctx.buf + pos, 0, next_start - pos);
  };

  for (i64 i = 1; i < ctx.chunks.size(); i++)
    zero(ctx.chunks[i - 1], ctx.chunks[i]->shdr.sh_offset);
  zero(ctx.chunks.back(), ctx.output_file->filesize);
}

// We want to sort output chunks in the following order.
//
//   ELF header
//   program header
//   .interp
//   note
//   alloc readonly data
//   alloc readonly code
//   alloc writable tdata
//   alloc writable tbss
//   alloc writable RELRO data
//   alloc writable RELRO bss
//   alloc writable non-RELRO data
//   alloc writable non-RELRO bss
//   nonalloc
//   section header
template <typename E>
i64 get_section_rank(Context<E> &ctx, OutputChunk<E> *chunk) {
  u64 type = chunk->shdr.sh_type;
  u64 flags = chunk->shdr.sh_flags;

  if (chunk == ctx.ehdr.get())
    return -4;
  if (chunk == ctx.phdr.get())
    return -3;
  if (chunk == ctx.interp.get())
    return -2;
  if (type == SHT_NOTE && (flags & SHF_ALLOC))
    return -1;
  if (chunk == ctx.shdr.get())
    return 1 << 6;
  if (!(flags & SHF_ALLOC))
    return 1 << 5;

  bool writable = (flags & SHF_WRITE);
  bool exec = (flags & SHF_EXECINSTR);
  bool tls = (flags & SHF_TLS);
  bool relro = is_relro(ctx, chunk);
  bool is_bss = (type == SHT_NOBITS);

  return (writable << 4) | (exec << 3) | (!tls << 2) |
         (!relro << 1) | is_bss;
}

// Returns the smallest number n such that
// n >= val and n % align == skew.
inline u64 align_with_skew(u64 val, u64 align, u64 skew) {
  return align_to(val + align - skew, align) - align + skew;
}

// Assign virtual addresses and file offsets to output sections.
template <typename E>
i64 set_osec_offsets(Context<E> &ctx) {
  Timer t(ctx, "osec_offset");

  u64 fileoff = 0;
  u64 vaddr = ctx.arg.image_base;

  i64 i = 0;
  i64 end = 0;
  while (ctx.chunks[end]->shdr.sh_flags & SHF_ALLOC)
    end++;

  while (i < end) {
    fileoff = align_with_skew(fileoff, PAGE_SIZE, vaddr % PAGE_SIZE);

    // Each group consists of zero or more non-BSS sections followed
    // by zero or more BSS sections. Virtual addresses of non-BSS
    // sections need to be congruent to file offsets modulo the page size.
    // BSS sections don't increment file offsets.
    for (; i < end && ctx.chunks[i]->shdr.sh_type != SHT_NOBITS; i++) {
      OutputChunk<E> &chunk = *ctx.chunks[i];
      u64 prev_vaddr = vaddr;

      if (chunk.new_page)
        vaddr = align_to(vaddr, PAGE_SIZE);
      vaddr = align_to(vaddr, chunk.shdr.sh_addralign);
      fileoff += vaddr - prev_vaddr;

      chunk.shdr.sh_addr = vaddr;
      vaddr += chunk.shdr.sh_size;

      chunk.shdr.sh_offset = fileoff;
      fileoff += chunk.shdr.sh_size;
    }

    for (; i < end && ctx.chunks[i]->shdr.sh_type == SHT_NOBITS; i++) {
      OutputChunk<E> &chunk = *ctx.chunks[i];

      if (chunk.new_page)
        vaddr = align_to(vaddr, PAGE_SIZE);
      vaddr = align_to(vaddr, chunk.shdr.sh_addralign);
      fileoff = align_with_skew(fileoff, PAGE_SIZE, vaddr % PAGE_SIZE);

      chunk.shdr.sh_addr = vaddr;
      chunk.shdr.sh_offset = fileoff;
      if (!(chunk.shdr.sh_flags & SHF_TLS))
        vaddr += chunk.shdr.sh_size;
    }
  }

  for (; i < ctx.chunks.size(); i++) {
    OutputChunk<E> &chunk = *ctx.chunks[i];
    assert(!(chunk.shdr.sh_flags & SHF_ALLOC));
    fileoff = align_to(fileoff, chunk.shdr.sh_addralign);
    chunk.shdr.sh_offset = fileoff;
    fileoff += chunk.shdr.sh_size;
  }
  return fileoff;
}

template <typename E>
static i64 get_num_irelative_relocs(Context<E> &ctx) {
  i64 n = 0;
  for (Symbol<E> *sym : ctx.got->got_syms)
    if (sym->get_type() == STT_GNU_IFUNC)
      n++;
  return n;
}

template <typename E>
void fix_synthetic_symbols(Context<E> &ctx) {
  auto start = [](Symbol<E> *sym, auto &chunk) {
    if (sym && chunk) {
      sym->shndx = chunk->shndx;
      sym->value = chunk->shdr.sh_addr;
    }
  };

  auto stop = [](Symbol<E> *sym, auto &chunk) {
    if (sym && chunk) {
      sym->shndx = chunk->shndx;
      sym->value = chunk->shdr.sh_addr + chunk->shdr.sh_size;
    }
  };

  // __bss_start
  for (OutputChunk<E> *chunk : ctx.chunks) {
    if (chunk->kind == OutputChunk<E>::REGULAR && chunk->name == ".bss") {
      start(ctx.__bss_start, chunk);
      break;
    }
  }

  // __ehdr_start and __executable_start
  for (OutputChunk<E> *chunk : ctx.chunks) {
    if (chunk->shndx == 1) {
      ctx.__ehdr_start->shndx = 1;
      ctx.__ehdr_start->value = ctx.ehdr->shdr.sh_addr;

      ctx.__executable_start->shndx = 1;
      ctx.__executable_start->value = ctx.ehdr->shdr.sh_addr;
      break;
    }
  }

  // __rel_iplt_start
  start(ctx.__rel_iplt_start, ctx.reldyn);

  // __rel_iplt_end
  ctx.__rel_iplt_end->shndx = ctx.reldyn->shndx;
  ctx.__rel_iplt_end->value = ctx.reldyn->shdr.sh_addr +
    get_num_irelative_relocs(ctx) * sizeof(ElfRel<E>);

  // __{init,fini}_array_{start,end}
  for (OutputChunk<E> *chunk : ctx.chunks) {
    switch (chunk->shdr.sh_type) {
    case SHT_INIT_ARRAY:
      start(ctx.__init_array_start, chunk);
      stop(ctx.__init_array_end, chunk);
      break;
    case SHT_FINI_ARRAY:
      start(ctx.__fini_array_start, chunk);
      stop(ctx.__fini_array_end, chunk);
      break;
    }
  }

  // _end, _etext, _edata and the like
  for (OutputChunk<E> *chunk : ctx.chunks) {
    if (chunk->kind == OutputChunk<E>::HEADER)
      continue;

    if (chunk->shdr.sh_flags & SHF_ALLOC) {
      stop(ctx._end, chunk);
      stop(ctx.end, chunk);
    }

    if (chunk->shdr.sh_flags & SHF_EXECINSTR) {
      stop(ctx._etext, chunk);
      stop(ctx.etext, chunk);
    }

    if (chunk->shdr.sh_type != SHT_NOBITS &&
        (chunk->shdr.sh_flags & SHF_ALLOC)) {
      stop(ctx._edata, chunk);
      stop(ctx.edata, chunk);
    }
  }

  // _DYNAMIC
  start(ctx._DYNAMIC, ctx.dynamic);

  // _GLOBAL_OFFSET_TABLE_
  start(ctx._GLOBAL_OFFSET_TABLE_, ctx.gotplt);

  // __GNU_EH_FRAME_HDR
  start(ctx.__GNU_EH_FRAME_HDR, ctx.eh_frame_hdr);

  // __start_ and __stop_ symbols
  for (OutputChunk<E> *chunk : ctx.chunks) {
    if (is_c_identifier(chunk->name)) {
      std::string_view sym1 =
        save_string(ctx, "__start_" + std::string(chunk->name));
      std::string_view sym2 =
        save_string(ctx, "__stop_" + std::string(chunk->name));

      start(Symbol<E>::intern(ctx, sym1), chunk);
      stop(Symbol<E>::intern(ctx, sym2), chunk);
    }
  }
}

template <typename E>
void compress_debug_sections(Context<E> &ctx) {
  Timer t(ctx, "compress_debug_sections");

  tbb::parallel_for((i64)0, (i64)ctx.chunks.size(), [&](i64 i) {
    OutputChunk<E> &chunk = *ctx.chunks[i];

    if ((chunk.shdr.sh_flags & SHF_ALLOC) || chunk.shdr.sh_size == 0 ||
        !chunk.name.starts_with(".debug"))
      return;

    OutputChunk<E> *comp = nullptr;
    if (ctx.arg.compress_debug_sections == COMPRESS_GABI)
      comp = new GabiCompressedSection<E>(ctx, chunk);
    else if (ctx.arg.compress_debug_sections == COMPRESS_GNU)
      comp = new GnuCompressedSection<E>(ctx, chunk);
    assert(comp);

    ctx.output_chunks.push_back(std::unique_ptr<OutputChunk<E>>(comp));
    ctx.chunks[i] = comp;
  });

  ctx.shstrtab->update_shdr(ctx);
  ctx.ehdr->update_shdr(ctx);
  ctx.shdr->update_shdr(ctx);
}

#define INSTANTIATE(E)                                                  \
  template void apply_exclude_libs(Context<E> &ctx);                    \
  template void create_synthetic_sections(Context<E> &ctx);             \
  template void resolve_symbols(Context<E> &ctx);                       \
  template void eliminate_comdats(Context<E> &ctx);                     \
  template void convert_common_symbols(Context<E> &ctx);                \
  template void compute_merged_section_sizes(Context<E> &ctx);          \
  template void bin_sections(Context<E> &ctx);                          \
  template void check_duplicate_symbols(Context<E> &ctx);               \
  template void sort_init_fini(Context<E> &ctx);                        \
  template std::vector<OutputChunk<E> *>                                \
    collect_output_sections(Context<E> &ctx);                           \
  template void compute_section_sizes(Context<E> &ctx);                 \
  template void claim_unresolved_symbols(Context<E> &ctx);              \
  template void scan_rels(Context<E> &ctx);                             \
  template void apply_version_script(Context<E> &ctx);                  \
  template void parse_symbol_version(Context<E> &ctx);                  \
  template void compute_import_export(Context<E> &ctx);                 \
  template void clear_padding(Context<E> &ctx);                         \
  template i64 get_section_rank(Context<E> &ctx, OutputChunk<E> *chunk); \
  template i64 set_osec_offsets(Context<E> &ctx);                       \
  template void fix_synthetic_symbols(Context<E> &ctx);                 \
  template void compress_debug_sections(Context<E> &ctx);

INSTANTIATE(X86_64);
INSTANTIATE(I386);