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// 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.
#ifndef COMPONENTS_ZUCCHINI_IMAGE_UTILS_H_
#define COMPONENTS_ZUCCHINI_IMAGE_UTILS_H_
#include <stddef.h>
#include <stdint.h>
#include <string>
#include "base/format_macros.h"
#include "base/macros.h"
#include "base/numerics/safe_conversions.h"
#include "base/strings/stringprintf.h"
#include "components/zucchini/buffer_view.h"
#include "components/zucchini/typed_value.h"
#include "third_party/abseil-cpp/absl/types/optional.h"
namespace zucchini {
// offset_t is used to describe an offset in an image.
// Files bigger than 4GB are not supported.
using offset_t = uint32_t;
// Divide by 2 since label marking uses the most significant bit.
constexpr offset_t kOffsetBound = static_cast<offset_t>(-1) / 2;
// Use 0xFFFFFFF*E*, since 0xFFFFFFF*F* is a sentinel value for Dex references.
constexpr offset_t kInvalidOffset = static_cast<offset_t>(-2);
// key_t is used to identify an offset in a table.
using key_t = uint32_t;
enum Bitness : uint8_t {
// The numerical values are intended to simplify WidthOf() below.
kBit32 = 4,
kBit64 = 8
};
inline uint32_t WidthOf(Bitness bitness) {
return static_cast<uint32_t>(bitness);
}
// Used to uniquely identify a reference type.
// Strongly typed objects are used to avoid ambiguitees with PoolTag.
struct TypeTag : public TypedValue<TypeTag, uint8_t> {
// inheriting constructor:
using TypedValue<TypeTag, uint8_t>::TypedValue;
};
// Used to uniquely identify a pool.
struct PoolTag : public TypedValue<PoolTag, uint8_t> {
// inheriting constructor:
using TypedValue<PoolTag, uint8_t>::TypedValue;
};
constexpr TypeTag kNoTypeTag(0xFF); // Typically used to identify raw data.
constexpr PoolTag kNoPoolTag(0xFF);
// Specification of references in an image file.
struct ReferenceTypeTraits {
constexpr ReferenceTypeTraits(offset_t width_in,
TypeTag type_tag_in,
PoolTag pool_tag_in)
: width(width_in), type_tag(type_tag_in), pool_tag(pool_tag_in) {}
// |width| specifies number of bytes covered by the reference's binary
// encoding.
const offset_t width;
// |type_tag| identifies the reference type being described.
const TypeTag type_tag;
// |pool_tag| identifies the pool this type belongs to.
const PoolTag pool_tag;
};
// There is no need to store |type| because references of the same type are
// always aggregated into the same container, and so during iteration we'd have
// |type| already.
struct Reference {
offset_t location;
offset_t target;
};
inline bool operator==(const Reference& a, const Reference& b) {
return a.location == b.location && a.target == b.target;
}
// Interface for extracting References through member function GetNext().
// This is used by Disassemblers to extract references from an image file.
// Typically, a Reader lazily extracts values and does not hold any storage.
class ReferenceReader {
public:
virtual ~ReferenceReader() = default;
// Returns the next available Reference, or nullopt_t if exhausted.
// Extracted References must be ordered by their location in the image.
virtual absl::optional<Reference> GetNext() = 0;
};
// Interface for writing References through member function
// PutNext(reference). This is used by Disassemblers to write new References
// in the image file.
class ReferenceWriter {
public:
virtual ~ReferenceWriter() = default;
// Writes |reference| in the underlying image file. This operation always
// succeeds.
virtual void PutNext(Reference reference) = 0;
};
// An Equivalence is a block of length |length| that approximately match in
// |old_image| at an offset of |src_offset| and in |new_image| at an offset of
// |dst_offset|.
struct Equivalence {
offset_t src_offset;
offset_t dst_offset;
offset_t length;
offset_t src_end() const { return src_offset + length; }
offset_t dst_end() const { return dst_offset + length; }
};
inline bool operator==(const Equivalence& a, const Equivalence& b) {
return a.src_offset == b.src_offset && a.dst_offset == b.dst_offset &&
a.length == b.length;
}
// Same as Equivalence, but with a similarity score. This is only used when
// generating the patch.
struct EquivalenceCandidate {
Equivalence eq;
double similarity;
};
template <size_t N>
inline constexpr uint32_t ExeTypeToUint32(const char (&exe_type)[N]) {
static_assert(N == 5, "Expected ExeType of length 4 + 1 null byte.");
return (exe_type[3] << 24) | (exe_type[2] << 16) | (exe_type[1] << 8) |
exe_type[0];
}
// Enumerations for supported executables. Values in this enum must be distinct.
// Once present, values should never be altered or removed to ensure backwards
// compatibility and patch type collision avoidance.
enum ExecutableType : uint32_t {
kExeTypeUnknown = UINT32_MAX,
kExeTypeNoOp = ExeTypeToUint32("NoOp"),
kExeTypeWin32X86 = ExeTypeToUint32("Px86"),
kExeTypeWin32X64 = ExeTypeToUint32("Px64"),
kExeTypeElfX86 = ExeTypeToUint32("Ex86"),
kExeTypeElfX64 = ExeTypeToUint32("Ex64"),
kExeTypeElfAArch32 = ExeTypeToUint32("EA32"),
kExeTypeElfAArch64 = ExeTypeToUint32("EA64"),
kExeTypeDex = ExeTypeToUint32("DEX "),
kExeTypeZtf = ExeTypeToUint32("ZTF "),
};
constexpr ExecutableType CastToExecutableType(uint32_t possible_exe_type) {
switch (static_cast<ExecutableType>(possible_exe_type)) {
case kExeTypeNoOp: // Falls through.
case kExeTypeWin32X86: // Falls through.
case kExeTypeWin32X64: // Falls through.
case kExeTypeElfX86: // Falls through.
case kExeTypeElfX64: // Falls through.
case kExeTypeElfAArch32: // Falls through.
case kExeTypeElfAArch64: // Falls through.
case kExeTypeDex: // Falls through.
case kExeTypeZtf: // Falls through.
case kExeTypeUnknown:
return static_cast<ExecutableType>(possible_exe_type);
default:
return kExeTypeUnknown;
}
}
inline std::string CastExecutableTypeToString(ExecutableType exe_type) {
uint32_t v = static_cast<uint32_t>(exe_type);
char result[] = {static_cast<char>(v), static_cast<char>(v >> 8),
static_cast<char>(v >> 16), static_cast<char>(v >> 24), 0};
return result;
}
// A region in an image with associated executable type |exe_type|. If
// |exe_type == kExeTypeNoOp|, then the Element represents a region of raw data.
struct Element : public BufferRegion {
Element() = default;
constexpr Element(const BufferRegion& region_in, ExecutableType exe_type_in)
: BufferRegion(region_in), exe_type(exe_type_in) {}
constexpr explicit Element(const BufferRegion& region_in)
: BufferRegion(region_in), exe_type(kExeTypeNoOp) {}
// Similar to lo() and hi(), but returns values in offset_t.
offset_t BeginOffset() const { return base::checked_cast<offset_t>(lo()); }
offset_t EndOffset() const { return base::checked_cast<offset_t>(hi()); }
BufferRegion region() const { return {offset, size}; }
friend bool operator==(const Element& a, const Element& b) {
return a.exe_type == b.exe_type && a.offset == b.offset && a.size == b.size;
}
ExecutableType exe_type;
};
// A matched pair of Elements.
struct ElementMatch {
bool IsValid() const { return old_element.exe_type == new_element.exe_type; }
ExecutableType exe_type() const { return old_element.exe_type; }
// Represents match as "#+#=#+#", where "#" denotes the integers:
// [offset in "old", size in "old", offset in "new", size in "new"].
// Note that element type is omitted.
std::string ToString() const {
return base::StringPrintf("%" PRIuS "+%" PRIuS "=%" PRIuS "+%" PRIuS "",
old_element.offset, old_element.size,
new_element.offset, new_element.size);
}
Element old_element;
Element new_element;
};
} // namespace zucchini
#endif // COMPONENTS_ZUCCHINI_IMAGE_UTILS_H_