blob: ab4372c7c047b2353dde71e86bfe32ec2308a615 [file] [log] [blame]
// Copyright 2017 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "components/zucchini/abs32_utils.h"
#include <algorithm>
#include <type_traits>
#include <utility>
#include "base/logging.h"
#include "components/zucchini/io_utils.h"
namespace zucchini {
namespace {
// Templated helper for AbsoluteAddress::Read().
template <typename T>
bool ReadAbs(ConstBufferView image, offset_t offset, uint64_t* value) {
static_assert(std::is_unsigned<T>::value, "Value type must be unsigned.");
if (!image.can_access<T>(offset))
return false;
*value = static_cast<uint64_t>(image.read<T>(offset));
return true;
}
// Templated helper for AbsoluteAddress::Write().
template <typename T>
bool WriteAbs(offset_t offset, T value, MutableBufferView* image) {
static_assert(std::is_unsigned<T>::value, "Value type must be unsigned.");
if (!image->can_access<T>(offset))
return false;
image->write<T>(offset, value);
return true;
}
} // namespace
/******** AbsoluteAddress ********/
AbsoluteAddress::AbsoluteAddress(Bitness bitness, uint64_t image_base)
: bitness_(bitness), image_base_(image_base), value_(image_base) {
CHECK(bitness_ == kBit64 || image_base_ < 0x100000000ULL);
}
AbsoluteAddress::AbsoluteAddress(AbsoluteAddress&&) = default;
AbsoluteAddress::~AbsoluteAddress() = default;
bool AbsoluteAddress::FromRva(rva_t rva) {
if (rva >= kRvaBound)
return false;
uint64_t value = image_base_ + rva;
// Check overflow, which manifests as |value| "wrapping around", resulting in
// |value| less than |image_base_| (preprocessing needed for 32-bit).
if (((bitness_ == kBit32) ? (value & 0xFFFFFFFFU) : value) < image_base_)
return false;
value_ = value;
return true;
}
rva_t AbsoluteAddress::ToRva() const {
if (value_ < image_base_)
return kInvalidRva;
uint64_t raw_rva = value_ - image_base_;
if (raw_rva >= kRvaBound)
return kInvalidRva;
return static_cast<rva_t>(raw_rva);
}
bool AbsoluteAddress::Read(offset_t offset, const ConstBufferView& image) {
// Read raw data; |value_| is not guaranteed to represent a valid RVA.
if (bitness_ == kBit32)
return ReadAbs<uint32_t>(image, offset, &value_);
DCHECK_EQ(kBit64, bitness_);
return ReadAbs<uint64_t>(image, offset, &value_);
}
bool AbsoluteAddress::Write(offset_t offset, MutableBufferView* image) {
if (bitness_ == kBit32)
return WriteAbs<uint32_t>(offset, static_cast<uint32_t>(value_), image);
DCHECK_EQ(kBit64, bitness_);
return WriteAbs<uint64_t>(offset, value_, image);
}
/******** Abs32RvaExtractorWin32 ********/
Abs32RvaExtractorWin32::Abs32RvaExtractorWin32(
ConstBufferView image,
AbsoluteAddress&& addr,
const std::vector<offset_t>& abs32_locations,
offset_t lo,
offset_t hi)
: image_(image), addr_(std::move(addr)) {
CHECK_LE(lo, hi);
auto find_and_check = [&addr](const std::vector<offset_t>& locations,
offset_t offset) {
auto it = std::lower_bound(locations.begin(), locations.end(), offset);
// Ensure |offset| does not straddle a reference body.
CHECK(it == locations.begin() || offset - *(it - 1) >= addr.width());
return it;
};
cur_abs32_ = find_and_check(abs32_locations, lo);
end_abs32_ = find_and_check(abs32_locations, hi);
}
Abs32RvaExtractorWin32::Abs32RvaExtractorWin32(Abs32RvaExtractorWin32&&) =
default;
Abs32RvaExtractorWin32::~Abs32RvaExtractorWin32() = default;
base::Optional<Abs32RvaExtractorWin32::Unit> Abs32RvaExtractorWin32::GetNext() {
while (cur_abs32_ < end_abs32_) {
offset_t location = *(cur_abs32_++);
if (!addr_.Read(location, image_))
continue;
rva_t target_rva = addr_.ToRva();
if (target_rva == kInvalidRva)
continue;
return Unit{location, target_rva};
}
return base::nullopt;
}
/******** Abs32ReaderWin32 ********/
Abs32ReaderWin32::Abs32ReaderWin32(Abs32RvaExtractorWin32&& abs32_rva_extractor,
const AddressTranslator& translator)
: abs32_rva_extractor_(std::move(abs32_rva_extractor)),
target_rva_to_offset_(translator) {}
Abs32ReaderWin32::~Abs32ReaderWin32() = default;
base::Optional<Reference> Abs32ReaderWin32::GetNext() {
for (auto unit = abs32_rva_extractor_.GetNext(); unit.has_value();
unit = abs32_rva_extractor_.GetNext()) {
offset_t location = unit->location;
offset_t target = target_rva_to_offset_.Convert(unit->target_rva);
if (target == kInvalidOffset)
continue;
return Reference{location, target};
}
return base::nullopt;
}
/******** Abs32WriterWin32 ********/
Abs32WriterWin32::Abs32WriterWin32(MutableBufferView image,
AbsoluteAddress&& addr,
const AddressTranslator& translator)
: image_(image),
addr_(std::move(addr)),
target_offset_to_rva_(translator) {}
Abs32WriterWin32::~Abs32WriterWin32() = default;
void Abs32WriterWin32::PutNext(Reference ref) {
rva_t target_rva = target_offset_to_rva_.Convert(ref.target);
if (target_rva != kInvalidRva) {
addr_.FromRva(target_rva);
addr_.Write(ref.location, &image_);
}
}
/******** Exported Functions ********/
size_t RemoveOverlappingAbs32Locations(Bitness bitness,
std::vector<offset_t>* locations) {
if (locations->size() <= 1)
return 0;
uint32_t width = WidthOf(bitness);
auto slow = locations->begin();
auto fast = locations->begin() + 1;
for (;;) {
// Find next good location.
while (fast != locations->end() && *fast - *slow < width)
++fast;
// Advance |slow|. For the last iteration this becomes the new sentinel.
++slow;
if (fast == locations->end())
break;
// Compactify good locations (potentially overwrite bad locations).
if (slow != fast)
*slow = *fast;
++fast;
}
size_t num_removed = locations->end() - slow;
locations->erase(slow, locations->end());
return num_removed;
}
} // namespace zucchini