mozilla-central/toolkit/xre/dllservices/mozglue/interceptor/Trampoline.h (file symbol)

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at https://mozilla.org/MPL/2.0/. */
#ifndef mozilla_interceptor_Trampoline_h
#define mozilla_interceptor_Trampoline_h
#include "mozilla/Assertions.h"
#include "mozilla/Attributes.h"
#include "mozilla/CheckedInt.h"
#include "mozilla/Maybe.h"
#include "mozilla/Types.h"
#include "mozilla/WindowsProcessMitigations.h"
#include "mozilla/WindowsUnwindInfo.h"
namespace mozilla {
namespace interceptor {
template <typename MMPolicy>
class MOZ_STACK_CLASS Trampoline final {
public:
Trampoline(const MMPolicy* aMMPolicy, uint8_t* const aLocalBase,
const uintptr_t aRemoteBase, const uint32_t aChunkSize)
: mMMPolicy(aMMPolicy),
mPrevLocalProt(0),
mLocalBase(aLocalBase),
mRemoteBase(aRemoteBase),
mOffset(0),
mExeOffset(0),
#ifdef _M_X64
mCopyCodesEndOffset(0),
mExeEndOffset(0),
#endif // _M_X64
mMaxOffset(aChunkSize),
mAccumulatedStatus(true) {
if (!::VirtualProtect(aLocalBase, aChunkSize,
MMPolicy::GetTrampWriteProtFlags(),
&mPrevLocalProt)) {
mPrevLocalProt = 0;
}
}
Trampoline(Trampoline&& aOther)
: mMMPolicy(aOther.mMMPolicy),
mPrevLocalProt(aOther.mPrevLocalProt),
mLocalBase(aOther.mLocalBase),
mRemoteBase(aOther.mRemoteBase),
mOffset(aOther.mOffset),
mExeOffset(aOther.mExeOffset),
#ifdef _M_X64
mCopyCodesEndOffset(aOther.mCopyCodesEndOffset),
mExeEndOffset(aOther.mExeEndOffset),
#endif // _M_X64
mMaxOffset(aOther.mMaxOffset),
mAccumulatedStatus(aOther.mAccumulatedStatus) {
aOther.mPrevLocalProt = 0;
aOther.mAccumulatedStatus = false;
}
MOZ_IMPLICIT Trampoline(decltype(nullptr))
: mMMPolicy(nullptr),
mPrevLocalProt(0),
mLocalBase(nullptr),
mRemoteBase(0),
mOffset(0),
mExeOffset(0),
#ifdef _M_X64
mCopyCodesEndOffset(0),
mExeEndOffset(0),
#endif // _M_X64
mMaxOffset(0),
mAccumulatedStatus(false) {
}
Trampoline(const Trampoline&) = delete;
Trampoline& operator=(const Trampoline&) = delete;
Trampoline& operator=(Trampoline&& aOther) {
Clear();
mMMPolicy = aOther.mMMPolicy;
mPrevLocalProt = aOther.mPrevLocalProt;
mLocalBase = aOther.mLocalBase;
mRemoteBase = aOther.mRemoteBase;
mOffset = aOther.mOffset;
mExeOffset = aOther.mExeOffset;
#ifdef _M_X64
mCopyCodesEndOffset = aOther.mCopyCodesEndOffset;
mExeEndOffset = aOther.mExeEndOffset;
#endif // _M_X64
mMaxOffset = aOther.mMaxOffset;
mAccumulatedStatus = aOther.mAccumulatedStatus;
aOther.mPrevLocalProt = 0;
aOther.mAccumulatedStatus = false;
return *this;
}
~Trampoline() { Clear(); }
explicit operator bool() const {
return IsNull() ||
(mLocalBase && mRemoteBase && mPrevLocalProt && mAccumulatedStatus);
}
bool IsNull() const { return !mMMPolicy; }
#if defined(_M_ARM64)
void WriteInstruction(uint32_t aInstruction) {
const uint32_t kDelta = sizeof(uint32_t);
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += kDelta;
return;
}
if (mOffset + kDelta > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
*reinterpret_cast<uint32_t*>(mLocalBase + mOffset) = aInstruction;
mOffset += kDelta;
}
void WriteLoadLiteral(const uintptr_t aAddress, const uint8_t aReg) {
const uint32_t kDelta = sizeof(uint32_t) + sizeof(uintptr_t);
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += kDelta;
return;
}
// We grow the literal pool from the *end* of the tramp,
// so we need to ensure that there is enough room for both an instruction
// and a pointer
if (mOffset + kDelta > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
mMaxOffset -= sizeof(uintptr_t);
*reinterpret_cast<uintptr_t*>(mLocalBase + mMaxOffset) = aAddress;
CheckedInt<intptr_t> pc(GetCurrentRemoteAddress());
if (!pc.isValid()) {
mAccumulatedStatus = false;
return;
}
CheckedInt<intptr_t> literal(reinterpret_cast<uintptr_t>(mLocalBase) +
mMaxOffset);
if (!literal.isValid()) {
mAccumulatedStatus = false;
return;
}
CheckedInt<intptr_t> ptrOffset = (literal - pc);
if (!ptrOffset.isValid()) {
mAccumulatedStatus = false;
return;
}
// ptrOffset must be properly aligned
MOZ_ASSERT((ptrOffset.value() % 4) == 0);
ptrOffset /= 4;
CheckedInt<int32_t> offset(ptrOffset.value());
if (!offset.isValid()) {
mAccumulatedStatus = false;
return;
}
// Ensure that offset falls within the range of a signed 19-bit value
if (offset.value() < -0x40000 || offset.value() > 0x3FFFF) {
mAccumulatedStatus = false;
return;
}
const int32_t kimm19Mask = 0x7FFFF;
int32_t masked = offset.value() & kimm19Mask;
MOZ_ASSERT(aReg < 32);
uint32_t loadInstr = 0x58000000 | (masked << 5) | aReg;
WriteInstruction(loadInstr);
}
#else
void WriteByte(uint8_t aValue) {
const uint32_t kDelta = sizeof(uint8_t);
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += kDelta;
return;
}
if (mOffset >= mMaxOffset) {
mAccumulatedStatus = false;
return;
}
*(mLocalBase + mOffset) = aValue;
++mOffset;
}
void WriteInteger(int32_t aValue) {
const uint32_t kDelta = sizeof(int32_t);
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += kDelta;
return;
}
if (mOffset + kDelta > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
*reinterpret_cast<int32_t*>(mLocalBase + mOffset) = aValue;
mOffset += kDelta;
}
void WriteDisp32(uintptr_t aAbsTarget) {
const uint32_t kDelta = sizeof(int32_t);
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += kDelta;
return;
}
if (mOffset + kDelta > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
// This needs to be computed from the remote location
intptr_t remoteTrampPosition = static_cast<intptr_t>(mRemoteBase + mOffset);
intptr_t diff =
static_cast<intptr_t>(aAbsTarget) - (remoteTrampPosition + kDelta);
CheckedInt<int32_t> checkedDisp(diff);
MOZ_ASSERT(checkedDisp.isValid());
if (!checkedDisp.isValid()) {
mAccumulatedStatus = false;
return;
}
int32_t disp = checkedDisp.value();
*reinterpret_cast<int32_t*>(mLocalBase + mOffset) = disp;
mOffset += kDelta;
}
void WriteBytes(void* aAddr, size_t aSize) {
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += aSize;
return;
}
if (mOffset + aSize > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
std::memcpy(reinterpret_cast<void*>(mLocalBase + mOffset), aAddr, aSize);
mOffset += aSize;
}
#endif
void WritePointer(uintptr_t aValue) {
const uint32_t kDelta = sizeof(uintptr_t);
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += kDelta;
return;
}
if (mOffset + kDelta > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
*reinterpret_cast<uintptr_t*>(mLocalBase + mOffset) = aValue;
mOffset += kDelta;
}
void WriteEncodedPointer(void* aValue) {
uintptr_t encoded = ReadOnlyTargetFunction<MMPolicy>::EncodePtr(aValue);
WritePointer(encoded);
}
Maybe<uintptr_t> ReadPointer() {
if (mOffset + sizeof(uintptr_t) > mMaxOffset) {
mAccumulatedStatus = false;
return Nothing();
}
auto result = Some(*reinterpret_cast<uintptr_t*>(mLocalBase + mOffset));
mOffset += sizeof(uintptr_t);
return std::move(result);
}
Maybe<uintptr_t> ReadEncodedPointer() {
Maybe<uintptr_t> encoded(ReadPointer());
if (!encoded) {
return encoded;
}
return Some(ReadOnlyTargetFunction<MMPolicy>::DecodePtr(encoded.value()));
}
#if defined(_M_IX86)
// 32-bit only
void AdjustDisp32AtOffset(uint32_t aOffset, uintptr_t aAbsTarget) {
uint32_t effectiveOffset = mExeOffset + aOffset;
if (effectiveOffset + sizeof(int32_t) > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
intptr_t diff = static_cast<intptr_t>(aAbsTarget) -
static_cast<intptr_t>(mRemoteBase + mExeOffset);
*reinterpret_cast<int32_t*>(mLocalBase + effectiveOffset) += diff;
}
#endif // defined(_M_IX86)
void CopyFrom(uintptr_t aOrigBytes, uint32_t aNumBytes) {
if (!mMMPolicy) {
// Null tramp, just track offset
mOffset += aNumBytes;
return;
}
if (!mMMPolicy || mOffset + aNumBytes > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
if (!mMMPolicy->Read(mLocalBase + mOffset,
reinterpret_cast<void*>(aOrigBytes), aNumBytes)) {
mAccumulatedStatus = false;
return;
}
mOffset += aNumBytes;
}
void CopyCodes(uintptr_t aOrigBytes, uint32_t aNumBytes) {
#ifdef _M_X64
if (mOffset == mCopyCodesEndOffset) {
mCopyCodesEndOffset += aNumBytes;
}
#endif // _M_X64
CopyFrom(aOrigBytes, aNumBytes);
}
void Rewind() { mOffset = 0; }
uintptr_t GetCurrentRemoteAddress() const { return mRemoteBase + mOffset; }
void StartExecutableCode() {
MOZ_ASSERT(!mExeOffset);
mExeOffset = mOffset;
#ifdef _M_X64
mCopyCodesEndOffset = mOffset;
#endif // _M_X64
}
void* EndExecutableCode() {
if (!mAccumulatedStatus || !mMMPolicy) {
return nullptr;
}
#ifdef _M_X64
mExeEndOffset = mOffset;
#endif // _M_X64
// This must always return the start address the executable code
// *in the target process*
return reinterpret_cast<void*>(mRemoteBase + mExeOffset);
}
uint32_t GetCurrentExecutableCodeLen() const { return mOffset - mExeOffset; }
#ifdef _M_X64
void Align(uint32_t aAlignment) {
// aAlignment should be a power of 2
MOZ_ASSERT(!(aAlignment & (aAlignment - 1)));
uint32_t alignedOffset = (mOffset + aAlignment - 1) & ~(aAlignment - 1);
if (alignedOffset > mMaxOffset) {
mAccumulatedStatus = false;
return;
}
mOffset = alignedOffset;
}
// We assume that all instructions that are part of the prologue are left
// intact by detouring code, i.e. that they are copied using CopyCodes. This
// is not true for calls and jumps for example, but calls and jumps cannot be
// part of the prologue. This assumption allows us to copy unwind information
// as-is, because unwind information only refers to instructions within the
// prologue.
bool AddUnwindInfo(uintptr_t aOrigFuncAddr, uintptr_t aOrigFuncStopOffset) {
if constexpr (!MMPolicy::kSupportsUnwindInfo) {
return false;
}
if (!mMMPolicy) {
return false;
}
uint32_t origFuncOffsetFromBeginAddr = 0;
uint32_t origFuncOffsetToEndAddr = 0;
uintptr_t origImageBase = 0;
auto unwindInfoData =
mMMPolicy->LookupUnwindInfo(aOrigFuncAddr, &origFuncOffsetFromBeginAddr,
&origFuncOffsetToEndAddr, &origImageBase);
if (!unwindInfoData) {
// If the original function does not have unwind info, there is nothing
// more to do.
return true;
}
// We do not support hooking at a location that isn't the beginning of a
// function.
MOZ_ASSERT(origFuncOffsetFromBeginAddr == 0);
if (origFuncOffsetFromBeginAddr != 0) {
return false;
}
IterableUnwindInfo unwindInfoIt(unwindInfoData.get());
auto& unwindInfo = unwindInfoIt.Info();
// The prologue should contain only instructions that we detour using
// CopyCodes. If not, there is most likely a mismatch between the unwind
// information and the actual code we are detouring, so we stop here. This
// is a best-effort safeguard intended to detect situations where e.g.
// third-party injected code would have altered the function we are
// detouring.
if (mCopyCodesEndOffset < aOrigFuncStopOffset &&
unwindInfo.size_of_prolog > mCopyCodesEndOffset) {
return false;
}
// According to the documentation, the array is sorted by descending order
// of offset in the prologue. Let's double check this assumption if in
// debug. This also checks that the full unwind information isn't
// ill-formed, thanks to all the MOZ_ASSERT in iteration code.
# ifdef DEBUG
uint8_t previousOffset = 0xFF;
for (const auto& unwindCode : unwindInfoIt) {
MOZ_ASSERT(unwindCode.offset_in_prolog <= previousOffset);
previousOffset = unwindCode.offset_in_prolog;
}
# endif // DEBUG
// We skip entries that are not part of the code we have detoured.
// This code relies on the array being sorted by descending order of offset
// in the prolog.
uint8_t firstRelevantCode = 0;
uint8_t countOfCodes = 0;
auto it = unwindInfoIt.begin();
for (; it != unwindInfoIt.end(); ++it) {
const auto& unwindCode = *it;
if (unwindCode.offset_in_prolog <= aOrigFuncStopOffset) {
// Found a relevant entry
firstRelevantCode = it.Index();
countOfCodes = unwindInfo.count_of_codes - firstRelevantCode;
break;
}
}
// Check that we encountered no ill-formed unwind codes.
if (!it.IsValid() && !it.IsAtEnd()) {
return false;
}
// We do not support chained unwind info. We should add support for chained
// unwind info if we ever reach this assert. Since we hook functions at
// their start address, this should not happen.
if (unwindInfo.flags & UNW_FLAG_CHAININFO) {
MOZ_ASSERT(
false,
"Tried to detour at a location with chained unwind information");
return false;
}
// We do not support exception handler info either. This could be a problem
// if we detour code that does not belong to the prologue and contains a
// call instruction, as this handler would then not be found if unwinding
// from callees. The following assert checks that this does not happen.
//
// Our current assumption is that all the functions we hook either have no
// associated exception handlers, or it is __GSHandlerCheck. This handler
// is the most commonly found, for example it is present in LdrLoadDll,
// SendMessageTimeoutW, GetWindowInfo. It is added to functions that use
// stack buffers, in order to mitigate stack buffer overflows. We explain
// below why it is not a problem that we do not preserve __GSHandlerCheck
// information when we detour code.
//
// Preserving exception handler information would raise two challenges:
//
// (1) if the exception handler was not written in a generic way, it may
// behave differently when called for our detoured code compared to
// what it would do if called from the original location of the code;
// (2) the exception handler can be followed by handler-specific data,
// which we cannot copy because we do not know its size.
//
// __GSHandlerCheck checks that the stack cookie value wasn't overwritten
// before continuing to unwind and call further handlers. That is a
// security feature that we want to preserve. However, since these
// functions allocate stack space and write the stack cookie as part of
// their prologue, the 13 bytes that we detour are necessarily part of
// their prologue, which must contain at least the following instructions:
//
// 48 81 ec XX XX XX XX sub rsp, 0xXXXXXXXX
// 48 8b 05 XX XX XX XX mov rax, qword ptr [rip+__security_cookie]
// 48 33 c4 xor rax, rsp
// 48 89 84 24 XX XX XX XX mov qword ptr [RSP + 0xXXXXXXXX],RAX
//
// As a consequence, code associated with __GSHandlerCheck will necessarily
// satisfy (aOrigFuncStopOffset <= unwindInfo.size_of_prolog), and it is OK
// to not preserve handler info in that case.
# ifdef DEBUG
if (aOrigFuncStopOffset > unwindInfo.size_of_prolog) {
MOZ_ASSERT(!(unwindInfo.flags & (UNW_FLAG_EHANDLER | UNW_FLAG_UHANDLER)));
}
# endif // DEBUG
// The unwind info must be DWORD-aligned
Align(sizeof(uint32_t));
if (!mAccumulatedStatus) {
return false;
}
uintptr_t unwindInfoOffset = mOffset;
unwindInfo.flags &=
~(UNW_FLAG_CHAININFO | UNW_FLAG_EHANDLER | UNW_FLAG_UHANDLER);
unwindInfo.count_of_codes = countOfCodes;
if (aOrigFuncStopOffset < unwindInfo.size_of_prolog) {
unwindInfo.size_of_prolog = aOrigFuncStopOffset;
}
WriteBytes(reinterpret_cast<void*>(&unwindInfo),
offsetof(UnwindInfo, unwind_code));
if (!mAccumulatedStatus) {
return false;
}
WriteBytes(
reinterpret_cast<void*>(&unwindInfo.unwind_code[firstRelevantCode]),
countOfCodes * sizeof(UnwindCode));
if (!mAccumulatedStatus) {
return false;
}
// The function table must be DWORD-aligned
Align(sizeof(uint32_t));
if (!mAccumulatedStatus) {
return false;
}
uintptr_t functionTableOffset = mOffset;
WriteInteger(mExeOffset);
if (!mAccumulatedStatus) {
return false;
}
WriteInteger(mExeEndOffset);
if (!mAccumulatedStatus) {
return false;
}
WriteInteger(unwindInfoOffset);
if (!mAccumulatedStatus) {
return false;
}
return mMMPolicy->AddFunctionTable(mRemoteBase + functionTableOffset, 1,
mRemoteBase);
}
#endif // _M_X64
Trampoline<MMPolicy>& operator--() {
MOZ_ASSERT(mOffset);
--mOffset;
return *this;
}
private:
void Clear() {
if (!mLocalBase || !mPrevLocalProt) {
return;
}
DebugOnly<bool> ok = !!::VirtualProtect(mLocalBase, mMaxOffset,
mPrevLocalProt, &mPrevLocalProt);
MOZ_ASSERT(ok);
mLocalBase = nullptr;
mRemoteBase = 0;
mPrevLocalProt = 0;
mAccumulatedStatus = false;
}
private:
const MMPolicy* mMMPolicy;
DWORD mPrevLocalProt;
uint8_t* mLocalBase;
uintptr_t mRemoteBase;
uint32_t mOffset;
uint32_t mExeOffset;
#ifdef _M_X64
uint32_t mCopyCodesEndOffset;
uint32_t mExeEndOffset;
#endif // _M_X64
uint32_t mMaxOffset;
bool mAccumulatedStatus;
};
template <typename MMPolicy>
class MOZ_STACK_CLASS TrampolineCollection final {
public:
class MOZ_STACK_CLASS TrampolineIterator final {
public:
Trampoline<MMPolicy> operator*() {
uint32_t offset = mCurTramp * mCollection.mTrampSize;
return Trampoline<MMPolicy>(
&mCollection.mMMPolicy, mCollection.mLocalBase + offset,
mCollection.mRemoteBase + offset, mCollection.mTrampSize);
}
TrampolineIterator& operator++() {
++mCurTramp;
return *this;
}
bool operator!=(const TrampolineIterator& aOther) const {
return mCurTramp != aOther.mCurTramp;
}
private:
explicit TrampolineIterator(
const TrampolineCollection<MMPolicy>& aCollection,
const uint32_t aCurTramp = 0)
: mCollection(aCollection), mCurTramp(aCurTramp) {}
const TrampolineCollection<MMPolicy>& mCollection;
uint32_t mCurTramp;
friend class TrampolineCollection<MMPolicy>;
};
explicit TrampolineCollection(const MMPolicy& aMMPolicy)
: mMMPolicy(aMMPolicy),
mLocalBase(0),
mRemoteBase(0),
mTrampSize(0),
mNumTramps(0),
mPrevProt(0),
mCS(nullptr) {}
TrampolineCollection(const MMPolicy& aMMPolicy, uint8_t* const aLocalBase,
const uintptr_t aRemoteBase, const uint32_t aTrampSize,
const uint32_t aNumTramps)
: mMMPolicy(aMMPolicy),
mLocalBase(aLocalBase),
mRemoteBase(aRemoteBase),
mTrampSize(aTrampSize),
mNumTramps(aNumTramps),
mPrevProt(0),
mCS(nullptr) {
if (!aNumTramps) {
return;
}
BOOL ok = mMMPolicy.Protect(aLocalBase, aNumTramps * aTrampSize,
PAGE_EXECUTE_READWRITE, &mPrevProt);
if (!ok) {
// When destroying a sandboxed process that uses
// MITIGATION_DYNAMIC_CODE_DISABLE, we won't be allowed to write to our
// executable memory so we just do nothing. If we fail to get access
// to memory for any other reason, we still don't want to crash but we
// do assert.
MOZ_ASSERT(IsDynamicCodeDisabled());
mNumTramps = 0;
mPrevProt = 0;
}
}
~TrampolineCollection() {
if (!mPrevProt) {
return;
}
mMMPolicy.Protect(mLocalBase, mNumTramps * mTrampSize, mPrevProt,
&mPrevProt);
if (mCS) {
::LeaveCriticalSection(mCS);
}
}
void Lock(CRITICAL_SECTION& aCS) {
if (!mPrevProt || mCS) {
return;
}
mCS = &aCS;
::EnterCriticalSection(&aCS);
}
TrampolineIterator begin() const {
if (!mPrevProt) {
return end();
}
return TrampolineIterator(*this);
}
TrampolineIterator end() const {
return TrampolineIterator(*this, mNumTramps);
}
TrampolineCollection(const TrampolineCollection&) = delete;
TrampolineCollection& operator=(const TrampolineCollection&) = delete;
TrampolineCollection& operator=(TrampolineCollection&&) = delete;
TrampolineCollection(TrampolineCollection&& aOther)
: mMMPolicy(aOther.mMMPolicy),
mLocalBase(aOther.mLocalBase),
mRemoteBase(aOther.mRemoteBase),
mTrampSize(aOther.mTrampSize),
mNumTramps(aOther.mNumTramps),
mPrevProt(aOther.mPrevProt),
mCS(aOther.mCS) {
aOther.mPrevProt = 0;
aOther.mCS = nullptr;
}
private:
const MMPolicy& mMMPolicy;
uint8_t* const mLocalBase;
const uintptr_t mRemoteBase;
const uint32_t mTrampSize;
uint32_t mNumTramps;
uint32_t mPrevProt;
CRITICAL_SECTION* mCS;
friend class TrampolineIterator;
};
} // namespace interceptor
} // namespace mozilla
#endif // mozilla_interceptor_Trampoline_h