Lightemerald/windows-user-space-emulator
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Merge remote-tracking branch 'origin/main' into multi-platform-support

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# Conflicts:
#	src/analyzer/main.cpp
#	src/emulator/memory_region.hpp
#	src/windows-emulator/io_device.cpp
#	src/windows-emulator/module/module_mapping.cpp
#	src/windows-emulator/process_context.hpp
#	src/windows-emulator/syscalls.cpp
#	src/windows-emulator/windows_emulator.cpp
This commit is contained in:
momo5502
2025-01-05 14:44:17 +01:00
parent 24f53bc498 38f2f13fad
commit f75f95cc61
36 changed files with 2643 additions and 978 deletions
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132
src/windows-emulator/module/module_mapping.cpp
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@@ -19,7 +19,7 @@ namespace
return nt_headers_offset + (first_section_absolute - absolute_base);
}
std::vector<uint8_t> read_mapped_memory(emulator& emu, const mapped_module& binary)
std::vector<uint8_t> read_mapped_memory(const emulator& emu, const mapped_module& binary)
{
std::vector<uint8_t> memory{};
memory.resize(binary.size_of_image);
@@ -40,20 +40,24 @@ namespace
const auto export_directory = buffer.as<IMAGE_EXPORT_DIRECTORY>(export_directory_entry.
VirtualAddress).get();
//const auto function_count = export_directory->NumberOfFunctions;
const auto names_count = export_directory.NumberOfNames;
//const auto function_count = export_directory.NumberOfFunctions;
const auto names = buffer.as<DWORD>(export_directory.AddressOfNames);
const auto ordinals = buffer.as<WORD>(export_directory.AddressOfNameOrdinals);
const auto functions = buffer.as<DWORD>(export_directory.AddressOfFunctions);
binary.exports.reserve(names_count);
for (DWORD i = 0; i < names_count; i++)
{
const auto ordinal = ordinals.get(i);
exported_symbol symbol{};
symbol.ordinal = ordinals.get(i);
symbol.name = buffer.as_string(names.get(i));
symbol.rva = functions.get(symbol.ordinal);
symbol.ordinal = export_directory.Base + ordinal;
symbol.rva = functions.get(ordinal);
symbol.address = binary.image_base + symbol.rva;
symbol.name = buffer.as_string(names.get(i));
binary.exports.push_back(std::move(symbol));
}
@@ -137,7 +141,7 @@ namespace
}
}
void map_sections(emulator& emu, const mapped_module& binary,
void map_sections(emulator& emu, mapped_module& binary,
const utils::safe_buffer_accessor<const uint8_t> buffer,
const PENTHeaders_t<std::uint64_t>& nt_headers, const uint64_t nt_headers_offset)
{
@@ -176,81 +180,85 @@ namespace
const auto size_of_section = page_align_up(std::max(section.SizeOfRawData, section.Misc.VirtualSize));
emu.protect_memory(target_ptr, size_of_section, permissions, nullptr);
}
}
std::optional<mapped_module> map_module(emulator& emu, const std::span<const uint8_t> data,
std::filesystem::path file)
{
mapped_module binary{};
binary.path = std::move(file);
binary.name = binary.path.filename().string();
mapped_section section_info{};
section_info.region.start = target_ptr;
section_info.region.length = size_of_section;
section_info.region.permissions = permissions;
utils::safe_buffer_accessor buffer{data};
const auto dos_header = buffer.as<PEDosHeader_t>(0).get();
const auto nt_headers_offset = dos_header.e_lfanew;
const auto nt_headers = buffer.as<PENTHeaders_t<std::uint64_t>>(nt_headers_offset).get();
auto& optional_header = nt_headers.OptionalHeader;
binary.image_base = optional_header.ImageBase;
binary.size_of_image = optional_header.SizeOfImage; // TODO: Sanitize
if (!emu.allocate_memory(binary.image_base, binary.size_of_image, memory_permission::read))
{
binary.image_base = emu.find_free_allocation_base(binary.size_of_image);
const auto is_dll = nt_headers.FileHeader.Characteristics & IMAGE_FILE_DLL;
const auto has_dynamic_base =
optional_header.DllCharacteristics & IMAGE_DLLCHARACTERISTICS_DYNAMIC_BASE;
const auto is_relocatable = is_dll || has_dynamic_base;
if (!is_relocatable || !emu.allocate_memory(binary.image_base, binary.size_of_image,
memory_permission::read))
for (size_t j = 0; j < sizeof(section.Name) && section.Name[j]; ++j)
{
return {};
section_info.name.push_back(static_cast<char>(section.Name[j]));
}
binary.sections.push_back(std::move(section_info));
}
binary.entry_point = binary.image_base + optional_header.AddressOfEntryPoint;
const auto* header_buffer = buffer.get_pointer_for_range(0, optional_header.SizeOfHeaders);
emu.write_memory(binary.image_base, header_buffer,
optional_header.SizeOfHeaders);
map_sections(emu, binary, buffer, nt_headers, nt_headers_offset);
auto mapped_memory = read_mapped_memory(emu, binary);
utils::safe_buffer_accessor<uint8_t> mapped_buffer{mapped_memory};
apply_relocations(binary, mapped_buffer, optional_header);
collect_exports(binary, mapped_buffer, optional_header);
emu.write_memory(binary.image_base, mapped_memory.data(), mapped_memory.size());
return binary;
}
}
std::optional<mapped_module> map_module_from_data(emulator& emu, const std::span<const uint8_t> data,
std::filesystem::path file)
mapped_module map_module_from_data(emulator& emu, const std::span<const uint8_t> data,
std::filesystem::path file)
{
try
mapped_module binary{};
binary.path = std::move(file);
binary.name = binary.path.filename().string();
utils::safe_buffer_accessor buffer{data};
const auto dos_header = buffer.as<PEDosHeader_t>(0).get();
const auto nt_headers_offset = dos_header.e_lfanew;
const auto nt_headers = buffer.as<PENTHeaders_t<std::uint64_t>>(nt_headers_offset).get();
auto& optional_header = nt_headers.OptionalHeader;
if (nt_headers.FileHeader.Machine != PEMachineType::AMD64)
{
return map_module(emu, data, std::move(file));
throw std::runtime_error("Unsupported architecture!");
}
catch (...)
binary.image_base = optional_header.ImageBase;
binary.size_of_image = page_align_up(optional_header.SizeOfImage); // TODO: Sanitize
if (!emu.allocate_memory(binary.image_base, binary.size_of_image, memory_permission::read))
{
return {};
binary.image_base = emu.find_free_allocation_base(binary.size_of_image);
const auto is_dll = nt_headers.FileHeader.Characteristics & IMAGE_FILE_DLL;
const auto has_dynamic_base =
optional_header.DllCharacteristics & IMAGE_DLLCHARACTERISTICS_DYNAMIC_BASE;
const auto is_relocatable = is_dll || has_dynamic_base;
if (!is_relocatable || !emu.allocate_memory(binary.image_base, binary.size_of_image,
memory_permission::read))
{
throw std::runtime_error("Memory range not allocatable");
}
}
binary.entry_point = binary.image_base + optional_header.AddressOfEntryPoint;
const auto* header_buffer = buffer.get_pointer_for_range(0, optional_header.SizeOfHeaders);
emu.write_memory(binary.image_base, header_buffer,
optional_header.SizeOfHeaders);
map_sections(emu, binary, buffer, nt_headers, nt_headers_offset);
auto mapped_memory = read_mapped_memory(emu, binary);
utils::safe_buffer_accessor<uint8_t> mapped_buffer{mapped_memory};
apply_relocations(binary, mapped_buffer, optional_header);
collect_exports(binary, mapped_buffer, optional_header);
emu.write_memory(binary.image_base, mapped_memory.data(), mapped_memory.size());
return binary;
}
std::optional<mapped_module> map_module_from_file(emulator& emu, std::filesystem::path file)
mapped_module map_module_from_file(emulator& emu, std::filesystem::path file)
{
const auto data = utils::io::read_file(file);
if (data.empty())
{
return {};
throw std::runtime_error("Bad file data");
}
return map_module_from_data(emu, data, std::move(file));