forked from OSchip/llvm-project
2637 lines
106 KiB
C++
2637 lines
106 KiB
C++
//====- X86SpeculativeLoadHardening.cpp - A Spectre v1 mitigation ---------===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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/// \file
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///
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/// Provide a pass which mitigates speculative execution attacks which operate
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/// by speculating incorrectly past some predicate (a type check, bounds check,
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/// or other condition) to reach a load with invalid inputs and leak the data
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/// accessed by that load using a side channel out of the speculative domain.
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///
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/// For details on the attacks, see the first variant in both the Project Zero
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/// writeup and the Spectre paper:
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/// https://googleprojectzero.blogspot.com/2018/01/reading-privileged-memory-with-side.html
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/// https://spectreattack.com/spectre.pdf
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///
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//===----------------------------------------------------------------------===//
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#include "X86.h"
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#include "X86InstrBuilder.h"
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#include "X86InstrInfo.h"
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#include "X86Subtarget.h"
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#include "llvm/ADT/ArrayRef.h"
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#include "llvm/ADT/DenseMap.h"
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#include "llvm/ADT/Optional.h"
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#include "llvm/ADT/STLExtras.h"
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#include "llvm/ADT/ScopeExit.h"
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#include "llvm/ADT/SmallPtrSet.h"
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#include "llvm/ADT/SmallSet.h"
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#include "llvm/ADT/SmallVector.h"
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#include "llvm/ADT/SparseBitVector.h"
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#include "llvm/ADT/Statistic.h"
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#include "llvm/CodeGen/MachineBasicBlock.h"
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#include "llvm/CodeGen/MachineConstantPool.h"
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#include "llvm/CodeGen/MachineFunction.h"
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#include "llvm/CodeGen/MachineFunctionPass.h"
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#include "llvm/CodeGen/MachineInstr.h"
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#include "llvm/CodeGen/MachineInstrBuilder.h"
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#include "llvm/CodeGen/MachineModuleInfo.h"
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#include "llvm/CodeGen/MachineOperand.h"
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#include "llvm/CodeGen/MachineRegisterInfo.h"
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#include "llvm/CodeGen/MachineSSAUpdater.h"
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#include "llvm/CodeGen/TargetInstrInfo.h"
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#include "llvm/CodeGen/TargetRegisterInfo.h"
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#include "llvm/CodeGen/TargetSchedule.h"
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#include "llvm/CodeGen/TargetSubtargetInfo.h"
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#include "llvm/IR/DebugLoc.h"
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#include "llvm/MC/MCSchedule.h"
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#include "llvm/Pass.h"
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#include "llvm/Support/CommandLine.h"
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#include "llvm/Support/Debug.h"
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#include "llvm/Support/raw_ostream.h"
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#include <algorithm>
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#include <cassert>
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#include <iterator>
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#include <utility>
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using namespace llvm;
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#define PASS_KEY "x86-slh"
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#define DEBUG_TYPE PASS_KEY
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STATISTIC(NumCondBranchesTraced, "Number of conditional branches traced");
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STATISTIC(NumBranchesUntraced, "Number of branches unable to trace");
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STATISTIC(NumAddrRegsHardened,
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"Number of address mode used registers hardaned");
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STATISTIC(NumPostLoadRegsHardened,
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"Number of post-load register values hardened");
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STATISTIC(NumCallsOrJumpsHardened,
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"Number of calls or jumps requiring extra hardening");
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STATISTIC(NumInstsInserted, "Number of instructions inserted");
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STATISTIC(NumLFENCEsInserted, "Number of lfence instructions inserted");
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static cl::opt<bool> EnableSpeculativeLoadHardening(
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"x86-speculative-load-hardening",
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cl::desc("Force enable speculative load hardening"), cl::init(false),
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cl::Hidden);
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static cl::opt<bool> HardenEdgesWithLFENCE(
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PASS_KEY "-lfence",
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cl::desc(
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"Use LFENCE along each conditional edge to harden against speculative "
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"loads rather than conditional movs and poisoned pointers."),
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cl::init(false), cl::Hidden);
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static cl::opt<bool> EnablePostLoadHardening(
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PASS_KEY "-post-load",
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cl::desc("Harden the value loaded *after* it is loaded by "
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"flushing the loaded bits to 1. This is hard to do "
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"in general but can be done easily for GPRs."),
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cl::init(true), cl::Hidden);
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static cl::opt<bool> FenceCallAndRet(
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PASS_KEY "-fence-call-and-ret",
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cl::desc("Use a full speculation fence to harden both call and ret edges "
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"rather than a lighter weight mitigation."),
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cl::init(false), cl::Hidden);
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static cl::opt<bool> HardenInterprocedurally(
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PASS_KEY "-ip",
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cl::desc("Harden interprocedurally by passing our state in and out of "
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"functions in the high bits of the stack pointer."),
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cl::init(true), cl::Hidden);
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static cl::opt<bool>
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HardenLoads(PASS_KEY "-loads",
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cl::desc("Sanitize loads from memory. When disable, no "
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"significant security is provided."),
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cl::init(true), cl::Hidden);
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static cl::opt<bool> HardenIndirectCallsAndJumps(
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PASS_KEY "-indirect",
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cl::desc("Harden indirect calls and jumps against using speculatively "
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"stored attacker controlled addresses. This is designed to "
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"mitigate Spectre v1.2 style attacks."),
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cl::init(true), cl::Hidden);
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namespace {
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class X86SpeculativeLoadHardeningPass : public MachineFunctionPass {
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public:
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X86SpeculativeLoadHardeningPass() : MachineFunctionPass(ID) {
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initializeX86SpeculativeLoadHardeningPassPass(
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*PassRegistry::getPassRegistry());
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}
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StringRef getPassName() const override {
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return "X86 speculative load hardening";
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}
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bool runOnMachineFunction(MachineFunction &MF) override;
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void getAnalysisUsage(AnalysisUsage &AU) const override;
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/// Pass identification, replacement for typeid.
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static char ID;
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private:
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/// The information about a block's conditional terminators needed to trace
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/// our predicate state through the exiting edges.
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struct BlockCondInfo {
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MachineBasicBlock *MBB;
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// We mostly have one conditional branch, and in extremely rare cases have
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// two. Three and more are so rare as to be unimportant for compile time.
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SmallVector<MachineInstr *, 2> CondBrs;
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MachineInstr *UncondBr;
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};
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/// Manages the predicate state traced through the program.
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struct PredState {
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unsigned InitialReg;
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unsigned PoisonReg;
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const TargetRegisterClass *RC;
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MachineSSAUpdater SSA;
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PredState(MachineFunction &MF, const TargetRegisterClass *RC)
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: RC(RC), SSA(MF) {}
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};
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const X86Subtarget *Subtarget;
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MachineRegisterInfo *MRI;
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const X86InstrInfo *TII;
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const TargetRegisterInfo *TRI;
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Optional<PredState> PS;
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void hardenEdgesWithLFENCE(MachineFunction &MF);
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SmallVector<BlockCondInfo, 16> collectBlockCondInfo(MachineFunction &MF);
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SmallVector<MachineInstr *, 16>
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tracePredStateThroughCFG(MachineFunction &MF, ArrayRef<BlockCondInfo> Infos);
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void unfoldCallAndJumpLoads(MachineFunction &MF);
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SmallVector<MachineInstr *, 16>
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tracePredStateThroughIndirectBranches(MachineFunction &MF);
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void tracePredStateThroughBlocksAndHarden(MachineFunction &MF);
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unsigned saveEFLAGS(MachineBasicBlock &MBB,
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MachineBasicBlock::iterator InsertPt, DebugLoc Loc);
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void restoreEFLAGS(MachineBasicBlock &MBB,
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MachineBasicBlock::iterator InsertPt, DebugLoc Loc,
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unsigned OFReg);
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void mergePredStateIntoSP(MachineBasicBlock &MBB,
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MachineBasicBlock::iterator InsertPt, DebugLoc Loc,
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unsigned PredStateReg);
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unsigned extractPredStateFromSP(MachineBasicBlock &MBB,
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MachineBasicBlock::iterator InsertPt,
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DebugLoc Loc);
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void
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hardenLoadAddr(MachineInstr &MI, MachineOperand &BaseMO,
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MachineOperand &IndexMO,
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SmallDenseMap<unsigned, unsigned, 32> &AddrRegToHardenedReg);
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MachineInstr *
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sinkPostLoadHardenedInst(MachineInstr &MI,
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SmallPtrSetImpl<MachineInstr *> &HardenedInstrs);
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bool canHardenRegister(unsigned Reg);
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unsigned hardenValueInRegister(unsigned Reg, MachineBasicBlock &MBB,
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MachineBasicBlock::iterator InsertPt,
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DebugLoc Loc);
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unsigned hardenPostLoad(MachineInstr &MI);
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void hardenReturnInstr(MachineInstr &MI);
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void tracePredStateThroughCall(MachineInstr &MI);
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void hardenIndirectCallOrJumpInstr(
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MachineInstr &MI,
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SmallDenseMap<unsigned, unsigned, 32> &AddrRegToHardenedReg);
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};
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} // end anonymous namespace
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char X86SpeculativeLoadHardeningPass::ID = 0;
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void X86SpeculativeLoadHardeningPass::getAnalysisUsage(
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AnalysisUsage &AU) const {
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MachineFunctionPass::getAnalysisUsage(AU);
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}
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static MachineBasicBlock &splitEdge(MachineBasicBlock &MBB,
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MachineBasicBlock &Succ, int SuccCount,
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MachineInstr *Br, MachineInstr *&UncondBr,
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const X86InstrInfo &TII) {
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assert(!Succ.isEHPad() && "Shouldn't get edges to EH pads!");
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MachineFunction &MF = *MBB.getParent();
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MachineBasicBlock &NewMBB = *MF.CreateMachineBasicBlock();
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// We have to insert the new block immediately after the current one as we
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// don't know what layout-successor relationships the successor has and we
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// may not be able to (and generally don't want to) try to fix those up.
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MF.insert(std::next(MachineFunction::iterator(&MBB)), &NewMBB);
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// Update the branch instruction if necessary.
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if (Br) {
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assert(Br->getOperand(0).getMBB() == &Succ &&
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"Didn't start with the right target!");
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Br->getOperand(0).setMBB(&NewMBB);
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// If this successor was reached through a branch rather than fallthrough,
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// we might have *broken* fallthrough and so need to inject a new
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// unconditional branch.
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if (!UncondBr) {
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MachineBasicBlock &OldLayoutSucc =
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*std::next(MachineFunction::iterator(&NewMBB));
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assert(MBB.isSuccessor(&OldLayoutSucc) &&
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"Without an unconditional branch, the old layout successor should "
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"be an actual successor!");
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auto BrBuilder =
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BuildMI(&MBB, DebugLoc(), TII.get(X86::JMP_1)).addMBB(&OldLayoutSucc);
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// Update the unconditional branch now that we've added one.
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UncondBr = &*BrBuilder;
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}
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// Insert unconditional "jump Succ" instruction in the new block if
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// necessary.
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if (!NewMBB.isLayoutSuccessor(&Succ)) {
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SmallVector<MachineOperand, 4> Cond;
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TII.insertBranch(NewMBB, &Succ, nullptr, Cond, Br->getDebugLoc());
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}
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} else {
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assert(!UncondBr &&
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"Cannot have a branchless successor and an unconditional branch!");
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assert(NewMBB.isLayoutSuccessor(&Succ) &&
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"A non-branch successor must have been a layout successor before "
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"and now is a layout successor of the new block.");
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}
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// If this is the only edge to the successor, we can just replace it in the
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// CFG. Otherwise we need to add a new entry in the CFG for the new
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// successor.
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if (SuccCount == 1) {
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MBB.replaceSuccessor(&Succ, &NewMBB);
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} else {
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MBB.splitSuccessor(&Succ, &NewMBB);
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}
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// Hook up the edge from the new basic block to the old successor in the CFG.
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NewMBB.addSuccessor(&Succ);
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// Fix PHI nodes in Succ so they refer to NewMBB instead of MBB.
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for (MachineInstr &MI : Succ) {
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if (!MI.isPHI())
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break;
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for (int OpIdx = 1, NumOps = MI.getNumOperands(); OpIdx < NumOps;
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OpIdx += 2) {
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MachineOperand &OpV = MI.getOperand(OpIdx);
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MachineOperand &OpMBB = MI.getOperand(OpIdx + 1);
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assert(OpMBB.isMBB() && "Block operand to a PHI is not a block!");
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if (OpMBB.getMBB() != &MBB)
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continue;
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// If this is the last edge to the succesor, just replace MBB in the PHI
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if (SuccCount == 1) {
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OpMBB.setMBB(&NewMBB);
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break;
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}
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// Otherwise, append a new pair of operands for the new incoming edge.
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MI.addOperand(MF, OpV);
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MI.addOperand(MF, MachineOperand::CreateMBB(&NewMBB));
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break;
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}
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}
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// Inherit live-ins from the successor
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for (auto &LI : Succ.liveins())
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NewMBB.addLiveIn(LI);
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LLVM_DEBUG(dbgs() << " Split edge from '" << MBB.getName() << "' to '"
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<< Succ.getName() << "'.\n");
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return NewMBB;
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}
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/// Removing duplicate PHI operands to leave the PHI in a canonical and
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/// predictable form.
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///
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/// FIXME: It's really frustrating that we have to do this, but SSA-form in MIR
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/// isn't what you might expect. We may have multiple entries in PHI nodes for
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/// a single predecessor. This makes CFG-updating extremely complex, so here we
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/// simplify all PHI nodes to a model even simpler than the IR's model: exactly
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/// one entry per predecessor, regardless of how many edges there are.
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static void canonicalizePHIOperands(MachineFunction &MF) {
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SmallPtrSet<MachineBasicBlock *, 4> Preds;
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SmallVector<int, 4> DupIndices;
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for (auto &MBB : MF)
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for (auto &MI : MBB) {
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if (!MI.isPHI())
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break;
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// First we scan the operands of the PHI looking for duplicate entries
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// a particular predecessor. We retain the operand index of each duplicate
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// entry found.
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for (int OpIdx = 1, NumOps = MI.getNumOperands(); OpIdx < NumOps;
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OpIdx += 2)
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if (!Preds.insert(MI.getOperand(OpIdx + 1).getMBB()).second)
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DupIndices.push_back(OpIdx);
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// Now walk the duplicate indices, removing both the block and value. Note
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// that these are stored as a vector making this element-wise removal
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// :w
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// potentially quadratic.
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//
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// FIXME: It is really frustrating that we have to use a quadratic
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// removal algorithm here. There should be a better way, but the use-def
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// updates required make that impossible using the public API.
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//
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// Note that we have to process these backwards so that we don't
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// invalidate other indices with each removal.
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while (!DupIndices.empty()) {
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int OpIdx = DupIndices.pop_back_val();
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// Remove both the block and value operand, again in reverse order to
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// preserve indices.
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MI.RemoveOperand(OpIdx + 1);
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MI.RemoveOperand(OpIdx);
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}
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Preds.clear();
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}
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}
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/// Helper to scan a function for loads vulnerable to misspeculation that we
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/// want to harden.
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///
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/// We use this to avoid making changes to functions where there is nothing we
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/// need to do to harden against misspeculation.
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static bool hasVulnerableLoad(MachineFunction &MF) {
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for (MachineBasicBlock &MBB : MF) {
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for (MachineInstr &MI : MBB) {
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// Loads within this basic block after an LFENCE are not at risk of
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// speculatively executing with invalid predicates from prior control
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// flow. So break out of this block but continue scanning the function.
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if (MI.getOpcode() == X86::LFENCE)
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break;
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// Looking for loads only.
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if (!MI.mayLoad())
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continue;
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// An MFENCE is modeled as a load but isn't vulnerable to misspeculation.
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if (MI.getOpcode() == X86::MFENCE)
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continue;
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// We found a load.
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return true;
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}
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}
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// No loads found.
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return false;
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}
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bool X86SpeculativeLoadHardeningPass::runOnMachineFunction(
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MachineFunction &MF) {
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LLVM_DEBUG(dbgs() << "********** " << getPassName() << " : " << MF.getName()
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<< " **********\n");
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// Only run if this pass is forced enabled or we detect the relevant function
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// attribute requesting SLH.
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if (!EnableSpeculativeLoadHardening &&
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!MF.getFunction().hasFnAttribute(Attribute::SpeculativeLoadHardening))
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return false;
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Subtarget = &MF.getSubtarget<X86Subtarget>();
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MRI = &MF.getRegInfo();
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TII = Subtarget->getInstrInfo();
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TRI = Subtarget->getRegisterInfo();
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// FIXME: Support for 32-bit.
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PS.emplace(MF, &X86::GR64_NOSPRegClass);
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if (MF.begin() == MF.end())
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// Nothing to do for a degenerate empty function...
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return false;
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// We support an alternative hardening technique based on a debug flag.
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if (HardenEdgesWithLFENCE) {
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hardenEdgesWithLFENCE(MF);
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return true;
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}
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// Create a dummy debug loc to use for all the generated code here.
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DebugLoc Loc;
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MachineBasicBlock &Entry = *MF.begin();
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auto EntryInsertPt = Entry.SkipPHIsLabelsAndDebug(Entry.begin());
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// Do a quick scan to see if we have any checkable loads.
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bool HasVulnerableLoad = hasVulnerableLoad(MF);
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// See if we have any conditional branching blocks that we will need to trace
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// predicate state through.
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SmallVector<BlockCondInfo, 16> Infos = collectBlockCondInfo(MF);
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// If we have no interesting conditions or loads, nothing to do here.
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if (!HasVulnerableLoad && Infos.empty())
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return true;
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// The poison value is required to be an all-ones value for many aspects of
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// this mitigation.
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const int PoisonVal = -1;
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PS->PoisonReg = MRI->createVirtualRegister(PS->RC);
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BuildMI(Entry, EntryInsertPt, Loc, TII->get(X86::MOV64ri32), PS->PoisonReg)
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.addImm(PoisonVal);
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++NumInstsInserted;
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// If we have loads being hardened and we've asked for call and ret edges to
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// get a full fence-based mitigation, inject that fence.
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if (HasVulnerableLoad && FenceCallAndRet) {
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// We need to insert an LFENCE at the start of the function to suspend any
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// incoming misspeculation from the caller. This helps two-fold: the caller
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// may not have been protected as this code has been, and this code gets to
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// not take any specific action to protect across calls.
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// FIXME: We could skip this for functions which unconditionally return
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// a constant.
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BuildMI(Entry, EntryInsertPt, Loc, TII->get(X86::LFENCE));
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++NumInstsInserted;
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++NumLFENCEsInserted;
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}
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// If we guarded the entry with an LFENCE and have no conditionals to protect
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// in blocks, then we're done.
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if (FenceCallAndRet && Infos.empty())
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// We may have changed the function's code at this point to insert fences.
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return true;
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// For every basic block in the function which can b
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if (HardenInterprocedurally && !FenceCallAndRet) {
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// Set up the predicate state by extracting it from the incoming stack
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// pointer so we pick up any misspeculation in our caller.
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PS->InitialReg = extractPredStateFromSP(Entry, EntryInsertPt, Loc);
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} else {
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|
// Otherwise, just build the predicate state itself by zeroing a register
|
|
// as we don't need any initial state.
|
|
PS->InitialReg = MRI->createVirtualRegister(PS->RC);
|
|
unsigned PredStateSubReg = MRI->createVirtualRegister(&X86::GR32RegClass);
|
|
auto ZeroI = BuildMI(Entry, EntryInsertPt, Loc, TII->get(X86::MOV32r0),
|
|
PredStateSubReg);
|
|
++NumInstsInserted;
|
|
MachineOperand *ZeroEFLAGSDefOp =
|
|
ZeroI->findRegisterDefOperand(X86::EFLAGS);
|
|
assert(ZeroEFLAGSDefOp && ZeroEFLAGSDefOp->isImplicit() &&
|
|
"Must have an implicit def of EFLAGS!");
|
|
ZeroEFLAGSDefOp->setIsDead(true);
|
|
BuildMI(Entry, EntryInsertPt, Loc, TII->get(X86::SUBREG_TO_REG),
|
|
PS->InitialReg)
|
|
.addImm(0)
|
|
.addReg(PredStateSubReg)
|
|
.addImm(X86::sub_32bit);
|
|
}
|
|
|
|
// We're going to need to trace predicate state throughout the function's
|
|
// CFG. Prepare for this by setting up our initial state of PHIs with unique
|
|
// predecessor entries and all the initial predicate state.
|
|
canonicalizePHIOperands(MF);
|
|
|
|
// Track the updated values in an SSA updater to rewrite into SSA form at the
|
|
// end.
|
|
PS->SSA.Initialize(PS->InitialReg);
|
|
PS->SSA.AddAvailableValue(&Entry, PS->InitialReg);
|
|
|
|
// Trace through the CFG.
|
|
auto CMovs = tracePredStateThroughCFG(MF, Infos);
|
|
|
|
// We may also enter basic blocks in this function via exception handling
|
|
// control flow. Here, if we are hardening interprocedurally, we need to
|
|
// re-capture the predicate state from the throwing code. In the Itanium ABI,
|
|
// the throw will always look like a call to __cxa_throw and will have the
|
|
// predicate state in the stack pointer, so extract fresh predicate state from
|
|
// the stack pointer and make it available in SSA.
|
|
// FIXME: Handle non-itanium ABI EH models.
|
|
if (HardenInterprocedurally) {
|
|
for (MachineBasicBlock &MBB : MF) {
|
|
assert(!MBB.isEHScopeEntry() && "Only Itanium ABI EH supported!");
|
|
assert(!MBB.isEHFuncletEntry() && "Only Itanium ABI EH supported!");
|
|
assert(!MBB.isCleanupFuncletEntry() && "Only Itanium ABI EH supported!");
|
|
if (!MBB.isEHPad())
|
|
continue;
|
|
PS->SSA.AddAvailableValue(
|
|
&MBB,
|
|
extractPredStateFromSP(MBB, MBB.SkipPHIsAndLabels(MBB.begin()), Loc));
|
|
}
|
|
}
|
|
|
|
if (HardenIndirectCallsAndJumps) {
|
|
// If we are going to harden calls and jumps we need to unfold their memory
|
|
// operands.
|
|
unfoldCallAndJumpLoads(MF);
|
|
|
|
// Then we trace predicate state through the indirect branches.
|
|
auto IndirectBrCMovs = tracePredStateThroughIndirectBranches(MF);
|
|
CMovs.append(IndirectBrCMovs.begin(), IndirectBrCMovs.end());
|
|
}
|
|
|
|
// Now that we have the predicate state available at the start of each block
|
|
// in the CFG, trace it through each block, hardening vulnerable instructions
|
|
// as we go.
|
|
tracePredStateThroughBlocksAndHarden(MF);
|
|
|
|
// Now rewrite all the uses of the pred state using the SSA updater to insert
|
|
// PHIs connecting the state between blocks along the CFG edges.
|
|
for (MachineInstr *CMovI : CMovs)
|
|
for (MachineOperand &Op : CMovI->operands()) {
|
|
if (!Op.isReg() || Op.getReg() != PS->InitialReg)
|
|
continue;
|
|
|
|
PS->SSA.RewriteUse(Op);
|
|
}
|
|
|
|
LLVM_DEBUG(dbgs() << "Final speculative load hardened function:\n"; MF.dump();
|
|
dbgs() << "\n"; MF.verify(this));
|
|
return true;
|
|
}
|
|
|
|
/// Implements the naive hardening approach of putting an LFENCE after every
|
|
/// potentially mis-predicted control flow construct.
|
|
///
|
|
/// We include this as an alternative mostly for the purpose of comparison. The
|
|
/// performance impact of this is expected to be extremely severe and not
|
|
/// practical for any real-world users.
|
|
void X86SpeculativeLoadHardeningPass::hardenEdgesWithLFENCE(
|
|
MachineFunction &MF) {
|
|
// First, we scan the function looking for blocks that are reached along edges
|
|
// that we might want to harden.
|
|
SmallSetVector<MachineBasicBlock *, 8> Blocks;
|
|
for (MachineBasicBlock &MBB : MF) {
|
|
// If there are no or only one successor, nothing to do here.
|
|
if (MBB.succ_size() <= 1)
|
|
continue;
|
|
|
|
// Skip blocks unless their terminators start with a branch. Other
|
|
// terminators don't seem interesting for guarding against misspeculation.
|
|
auto TermIt = MBB.getFirstTerminator();
|
|
if (TermIt == MBB.end() || !TermIt->isBranch())
|
|
continue;
|
|
|
|
// Add all the non-EH-pad succossors to the blocks we want to harden. We
|
|
// skip EH pads because there isn't really a condition of interest on
|
|
// entering.
|
|
for (MachineBasicBlock *SuccMBB : MBB.successors())
|
|
if (!SuccMBB->isEHPad())
|
|
Blocks.insert(SuccMBB);
|
|
}
|
|
|
|
for (MachineBasicBlock *MBB : Blocks) {
|
|
auto InsertPt = MBB->SkipPHIsAndLabels(MBB->begin());
|
|
BuildMI(*MBB, InsertPt, DebugLoc(), TII->get(X86::LFENCE));
|
|
++NumInstsInserted;
|
|
++NumLFENCEsInserted;
|
|
}
|
|
}
|
|
|
|
SmallVector<X86SpeculativeLoadHardeningPass::BlockCondInfo, 16>
|
|
X86SpeculativeLoadHardeningPass::collectBlockCondInfo(MachineFunction &MF) {
|
|
SmallVector<BlockCondInfo, 16> Infos;
|
|
|
|
// Walk the function and build up a summary for each block's conditions that
|
|
// we need to trace through.
|
|
for (MachineBasicBlock &MBB : MF) {
|
|
// If there are no or only one successor, nothing to do here.
|
|
if (MBB.succ_size() <= 1)
|
|
continue;
|
|
|
|
// We want to reliably handle any conditional branch terminators in the
|
|
// MBB, so we manually analyze the branch. We can handle all of the
|
|
// permutations here, including ones that analyze branch cannot.
|
|
//
|
|
// The approach is to walk backwards across the terminators, resetting at
|
|
// any unconditional non-indirect branch, and track all conditional edges
|
|
// to basic blocks as well as the fallthrough or unconditional successor
|
|
// edge. For each conditional edge, we track the target and the opposite
|
|
// condition code in order to inject a "no-op" cmov into that successor
|
|
// that will harden the predicate. For the fallthrough/unconditional
|
|
// edge, we inject a separate cmov for each conditional branch with
|
|
// matching condition codes. This effectively implements an "and" of the
|
|
// condition flags, even if there isn't a single condition flag that would
|
|
// directly implement that. We don't bother trying to optimize either of
|
|
// these cases because if such an optimization is possible, LLVM should
|
|
// have optimized the conditional *branches* in that way already to reduce
|
|
// instruction count. This late, we simply assume the minimal number of
|
|
// branch instructions is being emitted and use that to guide our cmov
|
|
// insertion.
|
|
|
|
BlockCondInfo Info = {&MBB, {}, nullptr};
|
|
|
|
// Now walk backwards through the terminators and build up successors they
|
|
// reach and the conditions.
|
|
for (MachineInstr &MI : llvm::reverse(MBB)) {
|
|
// Once we've handled all the terminators, we're done.
|
|
if (!MI.isTerminator())
|
|
break;
|
|
|
|
// If we see a non-branch terminator, we can't handle anything so bail.
|
|
if (!MI.isBranch()) {
|
|
Info.CondBrs.clear();
|
|
break;
|
|
}
|
|
|
|
// If we see an unconditional branch, reset our state, clear any
|
|
// fallthrough, and set this is the "else" successor.
|
|
if (MI.getOpcode() == X86::JMP_1) {
|
|
Info.CondBrs.clear();
|
|
Info.UncondBr = &MI;
|
|
continue;
|
|
}
|
|
|
|
// If we get an invalid condition, we have an indirect branch or some
|
|
// other unanalyzable "fallthrough" case. We model this as a nullptr for
|
|
// the destination so we can still guard any conditional successors.
|
|
// Consider code sequences like:
|
|
// ```
|
|
// jCC L1
|
|
// jmpq *%rax
|
|
// ```
|
|
// We still want to harden the edge to `L1`.
|
|
if (X86::getCondFromBranchOpc(MI.getOpcode()) == X86::COND_INVALID) {
|
|
Info.CondBrs.clear();
|
|
Info.UncondBr = &MI;
|
|
continue;
|
|
}
|
|
|
|
// We have a vanilla conditional branch, add it to our list.
|
|
Info.CondBrs.push_back(&MI);
|
|
}
|
|
if (Info.CondBrs.empty()) {
|
|
++NumBranchesUntraced;
|
|
LLVM_DEBUG(dbgs() << "WARNING: unable to secure successors of block:\n";
|
|
MBB.dump());
|
|
continue;
|
|
}
|
|
|
|
Infos.push_back(Info);
|
|
}
|
|
|
|
return Infos;
|
|
}
|
|
|
|
/// Trace the predicate state through the CFG, instrumenting each conditional
|
|
/// branch such that misspeculation through an edge will poison the predicate
|
|
/// state.
|
|
///
|
|
/// Returns the list of inserted CMov instructions so that they can have their
|
|
/// uses of the predicate state rewritten into proper SSA form once it is
|
|
/// complete.
|
|
SmallVector<MachineInstr *, 16>
|
|
X86SpeculativeLoadHardeningPass::tracePredStateThroughCFG(
|
|
MachineFunction &MF, ArrayRef<BlockCondInfo> Infos) {
|
|
// Collect the inserted cmov instructions so we can rewrite their uses of the
|
|
// predicate state into SSA form.
|
|
SmallVector<MachineInstr *, 16> CMovs;
|
|
|
|
// Now walk all of the basic blocks looking for ones that end in conditional
|
|
// jumps where we need to update this register along each edge.
|
|
for (const BlockCondInfo &Info : Infos) {
|
|
MachineBasicBlock &MBB = *Info.MBB;
|
|
const SmallVectorImpl<MachineInstr *> &CondBrs = Info.CondBrs;
|
|
MachineInstr *UncondBr = Info.UncondBr;
|
|
|
|
LLVM_DEBUG(dbgs() << "Tracing predicate through block: " << MBB.getName()
|
|
<< "\n");
|
|
++NumCondBranchesTraced;
|
|
|
|
// Compute the non-conditional successor as either the target of any
|
|
// unconditional branch or the layout successor.
|
|
MachineBasicBlock *UncondSucc =
|
|
UncondBr ? (UncondBr->getOpcode() == X86::JMP_1
|
|
? UncondBr->getOperand(0).getMBB()
|
|
: nullptr)
|
|
: &*std::next(MachineFunction::iterator(&MBB));
|
|
|
|
// Count how many edges there are to any given successor.
|
|
SmallDenseMap<MachineBasicBlock *, int> SuccCounts;
|
|
if (UncondSucc)
|
|
++SuccCounts[UncondSucc];
|
|
for (auto *CondBr : CondBrs)
|
|
++SuccCounts[CondBr->getOperand(0).getMBB()];
|
|
|
|
// A lambda to insert cmov instructions into a block checking all of the
|
|
// condition codes in a sequence.
|
|
auto BuildCheckingBlockForSuccAndConds =
|
|
[&](MachineBasicBlock &MBB, MachineBasicBlock &Succ, int SuccCount,
|
|
MachineInstr *Br, MachineInstr *&UncondBr,
|
|
ArrayRef<X86::CondCode> Conds) {
|
|
// First, we split the edge to insert the checking block into a safe
|
|
// location.
|
|
auto &CheckingMBB =
|
|
(SuccCount == 1 && Succ.pred_size() == 1)
|
|
? Succ
|
|
: splitEdge(MBB, Succ, SuccCount, Br, UncondBr, *TII);
|
|
|
|
bool LiveEFLAGS = Succ.isLiveIn(X86::EFLAGS);
|
|
if (!LiveEFLAGS)
|
|
CheckingMBB.addLiveIn(X86::EFLAGS);
|
|
|
|
// Now insert the cmovs to implement the checks.
|
|
auto InsertPt = CheckingMBB.begin();
|
|
assert((InsertPt == CheckingMBB.end() || !InsertPt->isPHI()) &&
|
|
"Should never have a PHI in the initial checking block as it "
|
|
"always has a single predecessor!");
|
|
|
|
// We will wire each cmov to each other, but need to start with the
|
|
// incoming pred state.
|
|
unsigned CurStateReg = PS->InitialReg;
|
|
|
|
for (X86::CondCode Cond : Conds) {
|
|
int PredStateSizeInBytes = TRI->getRegSizeInBits(*PS->RC) / 8;
|
|
auto CMovOp = X86::getCMovFromCond(Cond, PredStateSizeInBytes);
|
|
|
|
unsigned UpdatedStateReg = MRI->createVirtualRegister(PS->RC);
|
|
// Note that we intentionally use an empty debug location so that
|
|
// this picks up the preceding location.
|
|
auto CMovI = BuildMI(CheckingMBB, InsertPt, DebugLoc(),
|
|
TII->get(CMovOp), UpdatedStateReg)
|
|
.addReg(CurStateReg)
|
|
.addReg(PS->PoisonReg);
|
|
// If this is the last cmov and the EFLAGS weren't originally
|
|
// live-in, mark them as killed.
|
|
if (!LiveEFLAGS && Cond == Conds.back())
|
|
CMovI->findRegisterUseOperand(X86::EFLAGS)->setIsKill(true);
|
|
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting cmov: "; CMovI->dump();
|
|
dbgs() << "\n");
|
|
|
|
// The first one of the cmovs will be using the top level
|
|
// `PredStateReg` and need to get rewritten into SSA form.
|
|
if (CurStateReg == PS->InitialReg)
|
|
CMovs.push_back(&*CMovI);
|
|
|
|
// The next cmov should start from this one's def.
|
|
CurStateReg = UpdatedStateReg;
|
|
}
|
|
|
|
// And put the last one into the available values for SSA form of our
|
|
// predicate state.
|
|
PS->SSA.AddAvailableValue(&CheckingMBB, CurStateReg);
|
|
};
|
|
|
|
std::vector<X86::CondCode> UncondCodeSeq;
|
|
for (auto *CondBr : CondBrs) {
|
|
MachineBasicBlock &Succ = *CondBr->getOperand(0).getMBB();
|
|
int &SuccCount = SuccCounts[&Succ];
|
|
|
|
X86::CondCode Cond = X86::getCondFromBranchOpc(CondBr->getOpcode());
|
|
X86::CondCode InvCond = X86::GetOppositeBranchCondition(Cond);
|
|
UncondCodeSeq.push_back(Cond);
|
|
|
|
BuildCheckingBlockForSuccAndConds(MBB, Succ, SuccCount, CondBr, UncondBr,
|
|
{InvCond});
|
|
|
|
// Decrement the successor count now that we've split one of the edges.
|
|
// We need to keep the count of edges to the successor accurate in order
|
|
// to know above when to *replace* the successor in the CFG vs. just
|
|
// adding the new successor.
|
|
--SuccCount;
|
|
}
|
|
|
|
// Since we may have split edges and changed the number of successors,
|
|
// normalize the probabilities. This avoids doing it each time we split an
|
|
// edge.
|
|
MBB.normalizeSuccProbs();
|
|
|
|
// Finally, we need to insert cmovs into the "fallthrough" edge. Here, we
|
|
// need to intersect the other condition codes. We can do this by just
|
|
// doing a cmov for each one.
|
|
if (!UncondSucc)
|
|
// If we have no fallthrough to protect (perhaps it is an indirect jump?)
|
|
// just skip this and continue.
|
|
continue;
|
|
|
|
assert(SuccCounts[UncondSucc] == 1 &&
|
|
"We should never have more than one edge to the unconditional "
|
|
"successor at this point because every other edge must have been "
|
|
"split above!");
|
|
|
|
// Sort and unique the codes to minimize them.
|
|
llvm::sort(UncondCodeSeq);
|
|
UncondCodeSeq.erase(std::unique(UncondCodeSeq.begin(), UncondCodeSeq.end()),
|
|
UncondCodeSeq.end());
|
|
|
|
// Build a checking version of the successor.
|
|
BuildCheckingBlockForSuccAndConds(MBB, *UncondSucc, /*SuccCount*/ 1,
|
|
UncondBr, UncondBr, UncondCodeSeq);
|
|
}
|
|
|
|
return CMovs;
|
|
}
|
|
|
|
/// Compute the register class for the unfolded load.
|
|
///
|
|
/// FIXME: This should probably live in X86InstrInfo, potentially by adding
|
|
/// a way to unfold into a newly created vreg rather than requiring a register
|
|
/// input.
|
|
static const TargetRegisterClass *
|
|
getRegClassForUnfoldedLoad(MachineFunction &MF, const X86InstrInfo &TII,
|
|
unsigned Opcode) {
|
|
unsigned Index;
|
|
unsigned UnfoldedOpc = TII.getOpcodeAfterMemoryUnfold(
|
|
Opcode, /*UnfoldLoad*/ true, /*UnfoldStore*/ false, &Index);
|
|
const MCInstrDesc &MCID = TII.get(UnfoldedOpc);
|
|
return TII.getRegClass(MCID, Index, &TII.getRegisterInfo(), MF);
|
|
}
|
|
|
|
void X86SpeculativeLoadHardeningPass::unfoldCallAndJumpLoads(
|
|
MachineFunction &MF) {
|
|
for (MachineBasicBlock &MBB : MF)
|
|
for (auto MII = MBB.instr_begin(), MIE = MBB.instr_end(); MII != MIE;) {
|
|
// Grab a reference and increment the iterator so we can remove this
|
|
// instruction if needed without disturbing the iteration.
|
|
MachineInstr &MI = *MII++;
|
|
|
|
// Must either be a call or a branch.
|
|
if (!MI.isCall() && !MI.isBranch())
|
|
continue;
|
|
// We only care about loading variants of these instructions.
|
|
if (!MI.mayLoad())
|
|
continue;
|
|
|
|
switch (MI.getOpcode()) {
|
|
default: {
|
|
LLVM_DEBUG(
|
|
dbgs() << "ERROR: Found an unexpected loading branch or call "
|
|
"instruction:\n";
|
|
MI.dump(); dbgs() << "\n");
|
|
report_fatal_error("Unexpected loading branch or call!");
|
|
}
|
|
|
|
case X86::FARCALL16m:
|
|
case X86::FARCALL32m:
|
|
case X86::FARCALL64:
|
|
case X86::FARJMP16m:
|
|
case X86::FARJMP32m:
|
|
case X86::FARJMP64:
|
|
// We cannot mitigate far jumps or calls, but we also don't expect them
|
|
// to be vulnerable to Spectre v1.2 style attacks.
|
|
continue;
|
|
|
|
case X86::CALL16m:
|
|
case X86::CALL16m_NT:
|
|
case X86::CALL32m:
|
|
case X86::CALL32m_NT:
|
|
case X86::CALL64m:
|
|
case X86::CALL64m_NT:
|
|
case X86::JMP16m:
|
|
case X86::JMP16m_NT:
|
|
case X86::JMP32m:
|
|
case X86::JMP32m_NT:
|
|
case X86::JMP64m:
|
|
case X86::JMP64m_NT:
|
|
case X86::TAILJMPm64:
|
|
case X86::TAILJMPm64_REX:
|
|
case X86::TAILJMPm:
|
|
case X86::TCRETURNmi64:
|
|
case X86::TCRETURNmi: {
|
|
// Use the generic unfold logic now that we know we're dealing with
|
|
// expected instructions.
|
|
// FIXME: We don't have test coverage for all of these!
|
|
auto *UnfoldedRC = getRegClassForUnfoldedLoad(MF, *TII, MI.getOpcode());
|
|
if (!UnfoldedRC) {
|
|
LLVM_DEBUG(dbgs()
|
|
<< "ERROR: Unable to unfold load from instruction:\n";
|
|
MI.dump(); dbgs() << "\n");
|
|
report_fatal_error("Unable to unfold load!");
|
|
}
|
|
unsigned Reg = MRI->createVirtualRegister(UnfoldedRC);
|
|
SmallVector<MachineInstr *, 2> NewMIs;
|
|
// If we were able to compute an unfolded reg class, any failure here
|
|
// is just a programming error so just assert.
|
|
bool Unfolded =
|
|
TII->unfoldMemoryOperand(MF, MI, Reg, /*UnfoldLoad*/ true,
|
|
/*UnfoldStore*/ false, NewMIs);
|
|
(void)Unfolded;
|
|
assert(Unfolded &&
|
|
"Computed unfolded register class but failed to unfold");
|
|
// Now stitch the new instructions into place and erase the old one.
|
|
for (auto *NewMI : NewMIs)
|
|
MBB.insert(MI.getIterator(), NewMI);
|
|
MI.eraseFromParent();
|
|
LLVM_DEBUG({
|
|
dbgs() << "Unfolded load successfully into:\n";
|
|
for (auto *NewMI : NewMIs) {
|
|
NewMI->dump();
|
|
dbgs() << "\n";
|
|
}
|
|
});
|
|
continue;
|
|
}
|
|
}
|
|
llvm_unreachable("Escaped switch with default!");
|
|
}
|
|
}
|
|
|
|
/// Trace the predicate state through indirect branches, instrumenting them to
|
|
/// poison the state if a target is reached that does not match the expected
|
|
/// target.
|
|
///
|
|
/// This is designed to mitigate Spectre variant 1 attacks where an indirect
|
|
/// branch is trained to predict a particular target and then mispredicts that
|
|
/// target in a way that can leak data. Despite using an indirect branch, this
|
|
/// is really a variant 1 style attack: it does not steer execution to an
|
|
/// arbitrary or attacker controlled address, and it does not require any
|
|
/// special code executing next to the victim. This attack can also be mitigated
|
|
/// through retpolines, but those require either replacing indirect branches
|
|
/// with conditional direct branches or lowering them through a device that
|
|
/// blocks speculation. This mitigation can replace these retpoline-style
|
|
/// mitigations for jump tables and other indirect branches within a function
|
|
/// when variant 2 isn't a risk while allowing limited speculation. Indirect
|
|
/// calls, however, cannot be mitigated through this technique without changing
|
|
/// the ABI in a fundamental way.
|
|
SmallVector<MachineInstr *, 16>
|
|
X86SpeculativeLoadHardeningPass::tracePredStateThroughIndirectBranches(
|
|
MachineFunction &MF) {
|
|
// We use the SSAUpdater to insert PHI nodes for the target addresses of
|
|
// indirect branches. We don't actually need the full power of the SSA updater
|
|
// in this particular case as we always have immediately available values, but
|
|
// this avoids us having to re-implement the PHI construction logic.
|
|
MachineSSAUpdater TargetAddrSSA(MF);
|
|
TargetAddrSSA.Initialize(MRI->createVirtualRegister(&X86::GR64RegClass));
|
|
|
|
// Track which blocks were terminated with an indirect branch.
|
|
SmallPtrSet<MachineBasicBlock *, 4> IndirectTerminatedMBBs;
|
|
|
|
// We need to know what blocks end up reached via indirect branches. We
|
|
// expect this to be a subset of those whose address is taken and so track it
|
|
// directly via the CFG.
|
|
SmallPtrSet<MachineBasicBlock *, 4> IndirectTargetMBBs;
|
|
|
|
// Walk all the blocks which end in an indirect branch and make the
|
|
// target address available.
|
|
for (MachineBasicBlock &MBB : MF) {
|
|
// Find the last terminator.
|
|
auto MII = MBB.instr_rbegin();
|
|
while (MII != MBB.instr_rend() && MII->isDebugInstr())
|
|
++MII;
|
|
if (MII == MBB.instr_rend())
|
|
continue;
|
|
MachineInstr &TI = *MII;
|
|
if (!TI.isTerminator() || !TI.isBranch())
|
|
// No terminator or non-branch terminator.
|
|
continue;
|
|
|
|
unsigned TargetReg;
|
|
|
|
switch (TI.getOpcode()) {
|
|
default:
|
|
// Direct branch or conditional branch (leading to fallthrough).
|
|
continue;
|
|
|
|
case X86::FARJMP16m:
|
|
case X86::FARJMP32m:
|
|
case X86::FARJMP64:
|
|
// We cannot mitigate far jumps or calls, but we also don't expect them
|
|
// to be vulnerable to Spectre v1.2 or v2 (self trained) style attacks.
|
|
continue;
|
|
|
|
case X86::JMP16m:
|
|
case X86::JMP16m_NT:
|
|
case X86::JMP32m:
|
|
case X86::JMP32m_NT:
|
|
case X86::JMP64m:
|
|
case X86::JMP64m_NT:
|
|
// Mostly as documentation.
|
|
report_fatal_error("Memory operand jumps should have been unfolded!");
|
|
|
|
case X86::JMP16r:
|
|
report_fatal_error(
|
|
"Support for 16-bit indirect branches is not implemented.");
|
|
case X86::JMP32r:
|
|
report_fatal_error(
|
|
"Support for 32-bit indirect branches is not implemented.");
|
|
|
|
case X86::JMP64r:
|
|
TargetReg = TI.getOperand(0).getReg();
|
|
}
|
|
|
|
// We have definitely found an indirect branch. Verify that there are no
|
|
// preceding conditional branches as we don't yet support that.
|
|
if (llvm::any_of(MBB.terminators(), [&](MachineInstr &OtherTI) {
|
|
return !OtherTI.isDebugInstr() && &OtherTI != &TI;
|
|
})) {
|
|
LLVM_DEBUG({
|
|
dbgs() << "ERROR: Found other terminators in a block with an indirect "
|
|
"branch! This is not yet supported! Terminator sequence:\n";
|
|
for (MachineInstr &MI : MBB.terminators()) {
|
|
MI.dump();
|
|
dbgs() << '\n';
|
|
}
|
|
});
|
|
report_fatal_error("Unimplemented terminator sequence!");
|
|
}
|
|
|
|
// Make the target register an available value for this block.
|
|
TargetAddrSSA.AddAvailableValue(&MBB, TargetReg);
|
|
IndirectTerminatedMBBs.insert(&MBB);
|
|
|
|
// Add all the successors to our target candidates.
|
|
for (MachineBasicBlock *Succ : MBB.successors())
|
|
IndirectTargetMBBs.insert(Succ);
|
|
}
|
|
|
|
// Keep track of the cmov instructions we insert so we can return them.
|
|
SmallVector<MachineInstr *, 16> CMovs;
|
|
|
|
// If we didn't find any indirect branches with targets, nothing to do here.
|
|
if (IndirectTargetMBBs.empty())
|
|
return CMovs;
|
|
|
|
// We found indirect branches and targets that need to be instrumented to
|
|
// harden loads within them. Walk the blocks of the function (to get a stable
|
|
// ordering) and instrument each target of an indirect branch.
|
|
for (MachineBasicBlock &MBB : MF) {
|
|
// Skip the blocks that aren't candidate targets.
|
|
if (!IndirectTargetMBBs.count(&MBB))
|
|
continue;
|
|
|
|
// We don't expect EH pads to ever be reached via an indirect branch. If
|
|
// this is desired for some reason, we could simply skip them here rather
|
|
// than asserting.
|
|
assert(!MBB.isEHPad() &&
|
|
"Unexpected EH pad as target of an indirect branch!");
|
|
|
|
// We should never end up threading EFLAGS into a block to harden
|
|
// conditional jumps as there would be an additional successor via the
|
|
// indirect branch. As a consequence, all such edges would be split before
|
|
// reaching here, and the inserted block will handle the EFLAGS-based
|
|
// hardening.
|
|
assert(!MBB.isLiveIn(X86::EFLAGS) &&
|
|
"Cannot check within a block that already has live-in EFLAGS!");
|
|
|
|
// We can't handle having non-indirect edges into this block unless this is
|
|
// the only successor and we can synthesize the necessary target address.
|
|
for (MachineBasicBlock *Pred : MBB.predecessors()) {
|
|
// If we've already handled this by extracting the target directly,
|
|
// nothing to do.
|
|
if (IndirectTerminatedMBBs.count(Pred))
|
|
continue;
|
|
|
|
// Otherwise, we have to be the only successor. We generally expect this
|
|
// to be true as conditional branches should have had a critical edge
|
|
// split already. We don't however need to worry about EH pad successors
|
|
// as they'll happily ignore the target and their hardening strategy is
|
|
// resilient to all ways in which they could be reached speculatively.
|
|
if (!llvm::all_of(Pred->successors(), [&](MachineBasicBlock *Succ) {
|
|
return Succ->isEHPad() || Succ == &MBB;
|
|
})) {
|
|
LLVM_DEBUG({
|
|
dbgs() << "ERROR: Found conditional entry to target of indirect "
|
|
"branch!\n";
|
|
Pred->dump();
|
|
MBB.dump();
|
|
});
|
|
report_fatal_error("Cannot harden a conditional entry to a target of "
|
|
"an indirect branch!");
|
|
}
|
|
|
|
// Now we need to compute the address of this block and install it as a
|
|
// synthetic target in the predecessor. We do this at the bottom of the
|
|
// predecessor.
|
|
auto InsertPt = Pred->getFirstTerminator();
|
|
unsigned TargetReg = MRI->createVirtualRegister(&X86::GR64RegClass);
|
|
if (MF.getTarget().getCodeModel() == CodeModel::Small &&
|
|
!Subtarget->isPositionIndependent()) {
|
|
// Directly materialize it into an immediate.
|
|
auto AddrI = BuildMI(*Pred, InsertPt, DebugLoc(),
|
|
TII->get(X86::MOV64ri32), TargetReg)
|
|
.addMBB(&MBB);
|
|
++NumInstsInserted;
|
|
(void)AddrI;
|
|
LLVM_DEBUG(dbgs() << " Inserting mov: "; AddrI->dump();
|
|
dbgs() << "\n");
|
|
} else {
|
|
auto AddrI = BuildMI(*Pred, InsertPt, DebugLoc(), TII->get(X86::LEA64r),
|
|
TargetReg)
|
|
.addReg(/*Base*/ X86::RIP)
|
|
.addImm(/*Scale*/ 1)
|
|
.addReg(/*Index*/ 0)
|
|
.addMBB(&MBB)
|
|
.addReg(/*Segment*/ 0);
|
|
++NumInstsInserted;
|
|
(void)AddrI;
|
|
LLVM_DEBUG(dbgs() << " Inserting lea: "; AddrI->dump();
|
|
dbgs() << "\n");
|
|
}
|
|
// And make this available.
|
|
TargetAddrSSA.AddAvailableValue(Pred, TargetReg);
|
|
}
|
|
|
|
// Materialize the needed SSA value of the target. Note that we need the
|
|
// middle of the block as this block might at the bottom have an indirect
|
|
// branch back to itself. We can do this here because at this point, every
|
|
// predecessor of this block has an available value. This is basically just
|
|
// automating the construction of a PHI node for this target.
|
|
unsigned TargetReg = TargetAddrSSA.GetValueInMiddleOfBlock(&MBB);
|
|
|
|
// Insert a comparison of the incoming target register with this block's
|
|
// address.
|
|
auto InsertPt = MBB.SkipPHIsLabelsAndDebug(MBB.begin());
|
|
if (MF.getTarget().getCodeModel() == CodeModel::Small &&
|
|
!Subtarget->isPositionIndependent()) {
|
|
// Check directly against a relocated immediate when we can.
|
|
auto CheckI = BuildMI(MBB, InsertPt, DebugLoc(), TII->get(X86::CMP64ri32))
|
|
.addReg(TargetReg, RegState::Kill)
|
|
.addMBB(&MBB);
|
|
++NumInstsInserted;
|
|
(void)CheckI;
|
|
LLVM_DEBUG(dbgs() << " Inserting cmp: "; CheckI->dump(); dbgs() << "\n");
|
|
} else {
|
|
// Otherwise compute the address into a register first.
|
|
unsigned AddrReg = MRI->createVirtualRegister(&X86::GR64RegClass);
|
|
auto AddrI =
|
|
BuildMI(MBB, InsertPt, DebugLoc(), TII->get(X86::LEA64r), AddrReg)
|
|
.addReg(/*Base*/ X86::RIP)
|
|
.addImm(/*Scale*/ 1)
|
|
.addReg(/*Index*/ 0)
|
|
.addMBB(&MBB)
|
|
.addReg(/*Segment*/ 0);
|
|
++NumInstsInserted;
|
|
(void)AddrI;
|
|
LLVM_DEBUG(dbgs() << " Inserting lea: "; AddrI->dump(); dbgs() << "\n");
|
|
auto CheckI = BuildMI(MBB, InsertPt, DebugLoc(), TII->get(X86::CMP64rr))
|
|
.addReg(TargetReg, RegState::Kill)
|
|
.addReg(AddrReg, RegState::Kill);
|
|
++NumInstsInserted;
|
|
(void)CheckI;
|
|
LLVM_DEBUG(dbgs() << " Inserting cmp: "; CheckI->dump(); dbgs() << "\n");
|
|
}
|
|
|
|
// Now cmov over the predicate if the comparison wasn't equal.
|
|
int PredStateSizeInBytes = TRI->getRegSizeInBits(*PS->RC) / 8;
|
|
auto CMovOp = X86::getCMovFromCond(X86::COND_NE, PredStateSizeInBytes);
|
|
unsigned UpdatedStateReg = MRI->createVirtualRegister(PS->RC);
|
|
auto CMovI =
|
|
BuildMI(MBB, InsertPt, DebugLoc(), TII->get(CMovOp), UpdatedStateReg)
|
|
.addReg(PS->InitialReg)
|
|
.addReg(PS->PoisonReg);
|
|
CMovI->findRegisterUseOperand(X86::EFLAGS)->setIsKill(true);
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting cmov: "; CMovI->dump(); dbgs() << "\n");
|
|
CMovs.push_back(&*CMovI);
|
|
|
|
// And put the new value into the available values for SSA form of our
|
|
// predicate state.
|
|
PS->SSA.AddAvailableValue(&MBB, UpdatedStateReg);
|
|
}
|
|
|
|
// Return all the newly inserted cmov instructions of the predicate state.
|
|
return CMovs;
|
|
}
|
|
|
|
/// Returns true if the instruction has no behavior (specified or otherwise)
|
|
/// that is based on the value of any of its register operands
|
|
///
|
|
/// A classical example of something that is inherently not data invariant is an
|
|
/// indirect jump -- the destination is loaded into icache based on the bits set
|
|
/// in the jump destination register.
|
|
///
|
|
/// FIXME: This should become part of our instruction tables.
|
|
static bool isDataInvariant(MachineInstr &MI) {
|
|
switch (MI.getOpcode()) {
|
|
default:
|
|
// By default, assume that the instruction is not data invariant.
|
|
return false;
|
|
|
|
// Some target-independent operations that trivially lower to data-invariant
|
|
// instructions.
|
|
case TargetOpcode::COPY:
|
|
case TargetOpcode::INSERT_SUBREG:
|
|
case TargetOpcode::SUBREG_TO_REG:
|
|
return true;
|
|
|
|
// On x86 it is believed that imul is constant time w.r.t. the loaded data.
|
|
// However, they set flags and are perhaps the most surprisingly constant
|
|
// time operations so we call them out here separately.
|
|
case X86::IMUL16rr:
|
|
case X86::IMUL16rri8:
|
|
case X86::IMUL16rri:
|
|
case X86::IMUL32rr:
|
|
case X86::IMUL32rri8:
|
|
case X86::IMUL32rri:
|
|
case X86::IMUL64rr:
|
|
case X86::IMUL64rri32:
|
|
case X86::IMUL64rri8:
|
|
|
|
// Bit scanning and counting instructions that are somewhat surprisingly
|
|
// constant time as they scan across bits and do other fairly complex
|
|
// operations like popcnt, but are believed to be constant time on x86.
|
|
// However, these set flags.
|
|
case X86::BSF16rr:
|
|
case X86::BSF32rr:
|
|
case X86::BSF64rr:
|
|
case X86::BSR16rr:
|
|
case X86::BSR32rr:
|
|
case X86::BSR64rr:
|
|
case X86::LZCNT16rr:
|
|
case X86::LZCNT32rr:
|
|
case X86::LZCNT64rr:
|
|
case X86::POPCNT16rr:
|
|
case X86::POPCNT32rr:
|
|
case X86::POPCNT64rr:
|
|
case X86::TZCNT16rr:
|
|
case X86::TZCNT32rr:
|
|
case X86::TZCNT64rr:
|
|
|
|
// Bit manipulation instructions are effectively combinations of basic
|
|
// arithmetic ops, and should still execute in constant time. These also
|
|
// set flags.
|
|
case X86::BLCFILL32rr:
|
|
case X86::BLCFILL64rr:
|
|
case X86::BLCI32rr:
|
|
case X86::BLCI64rr:
|
|
case X86::BLCIC32rr:
|
|
case X86::BLCIC64rr:
|
|
case X86::BLCMSK32rr:
|
|
case X86::BLCMSK64rr:
|
|
case X86::BLCS32rr:
|
|
case X86::BLCS64rr:
|
|
case X86::BLSFILL32rr:
|
|
case X86::BLSFILL64rr:
|
|
case X86::BLSI32rr:
|
|
case X86::BLSI64rr:
|
|
case X86::BLSIC32rr:
|
|
case X86::BLSIC64rr:
|
|
case X86::BLSMSK32rr:
|
|
case X86::BLSMSK64rr:
|
|
case X86::BLSR32rr:
|
|
case X86::BLSR64rr:
|
|
case X86::TZMSK32rr:
|
|
case X86::TZMSK64rr:
|
|
|
|
// Bit extracting and clearing instructions should execute in constant time,
|
|
// and set flags.
|
|
case X86::BEXTR32rr:
|
|
case X86::BEXTR64rr:
|
|
case X86::BEXTRI32ri:
|
|
case X86::BEXTRI64ri:
|
|
case X86::BZHI32rr:
|
|
case X86::BZHI64rr:
|
|
|
|
// Shift and rotate.
|
|
case X86::ROL8r1: case X86::ROL16r1: case X86::ROL32r1: case X86::ROL64r1:
|
|
case X86::ROL8rCL: case X86::ROL16rCL: case X86::ROL32rCL: case X86::ROL64rCL:
|
|
case X86::ROL8ri: case X86::ROL16ri: case X86::ROL32ri: case X86::ROL64ri:
|
|
case X86::ROR8r1: case X86::ROR16r1: case X86::ROR32r1: case X86::ROR64r1:
|
|
case X86::ROR8rCL: case X86::ROR16rCL: case X86::ROR32rCL: case X86::ROR64rCL:
|
|
case X86::ROR8ri: case X86::ROR16ri: case X86::ROR32ri: case X86::ROR64ri:
|
|
case X86::SAR8r1: case X86::SAR16r1: case X86::SAR32r1: case X86::SAR64r1:
|
|
case X86::SAR8rCL: case X86::SAR16rCL: case X86::SAR32rCL: case X86::SAR64rCL:
|
|
case X86::SAR8ri: case X86::SAR16ri: case X86::SAR32ri: case X86::SAR64ri:
|
|
case X86::SHL8r1: case X86::SHL16r1: case X86::SHL32r1: case X86::SHL64r1:
|
|
case X86::SHL8rCL: case X86::SHL16rCL: case X86::SHL32rCL: case X86::SHL64rCL:
|
|
case X86::SHL8ri: case X86::SHL16ri: case X86::SHL32ri: case X86::SHL64ri:
|
|
case X86::SHR8r1: case X86::SHR16r1: case X86::SHR32r1: case X86::SHR64r1:
|
|
case X86::SHR8rCL: case X86::SHR16rCL: case X86::SHR32rCL: case X86::SHR64rCL:
|
|
case X86::SHR8ri: case X86::SHR16ri: case X86::SHR32ri: case X86::SHR64ri:
|
|
case X86::SHLD16rrCL: case X86::SHLD32rrCL: case X86::SHLD64rrCL:
|
|
case X86::SHLD16rri8: case X86::SHLD32rri8: case X86::SHLD64rri8:
|
|
case X86::SHRD16rrCL: case X86::SHRD32rrCL: case X86::SHRD64rrCL:
|
|
case X86::SHRD16rri8: case X86::SHRD32rri8: case X86::SHRD64rri8:
|
|
|
|
// Basic arithmetic is constant time on the input but does set flags.
|
|
case X86::ADC8rr: case X86::ADC8ri:
|
|
case X86::ADC16rr: case X86::ADC16ri: case X86::ADC16ri8:
|
|
case X86::ADC32rr: case X86::ADC32ri: case X86::ADC32ri8:
|
|
case X86::ADC64rr: case X86::ADC64ri8: case X86::ADC64ri32:
|
|
case X86::ADD8rr: case X86::ADD8ri:
|
|
case X86::ADD16rr: case X86::ADD16ri: case X86::ADD16ri8:
|
|
case X86::ADD32rr: case X86::ADD32ri: case X86::ADD32ri8:
|
|
case X86::ADD64rr: case X86::ADD64ri8: case X86::ADD64ri32:
|
|
case X86::AND8rr: case X86::AND8ri:
|
|
case X86::AND16rr: case X86::AND16ri: case X86::AND16ri8:
|
|
case X86::AND32rr: case X86::AND32ri: case X86::AND32ri8:
|
|
case X86::AND64rr: case X86::AND64ri8: case X86::AND64ri32:
|
|
case X86::OR8rr: case X86::OR8ri:
|
|
case X86::OR16rr: case X86::OR16ri: case X86::OR16ri8:
|
|
case X86::OR32rr: case X86::OR32ri: case X86::OR32ri8:
|
|
case X86::OR64rr: case X86::OR64ri8: case X86::OR64ri32:
|
|
case X86::SBB8rr: case X86::SBB8ri:
|
|
case X86::SBB16rr: case X86::SBB16ri: case X86::SBB16ri8:
|
|
case X86::SBB32rr: case X86::SBB32ri: case X86::SBB32ri8:
|
|
case X86::SBB64rr: case X86::SBB64ri8: case X86::SBB64ri32:
|
|
case X86::SUB8rr: case X86::SUB8ri:
|
|
case X86::SUB16rr: case X86::SUB16ri: case X86::SUB16ri8:
|
|
case X86::SUB32rr: case X86::SUB32ri: case X86::SUB32ri8:
|
|
case X86::SUB64rr: case X86::SUB64ri8: case X86::SUB64ri32:
|
|
case X86::XOR8rr: case X86::XOR8ri:
|
|
case X86::XOR16rr: case X86::XOR16ri: case X86::XOR16ri8:
|
|
case X86::XOR32rr: case X86::XOR32ri: case X86::XOR32ri8:
|
|
case X86::XOR64rr: case X86::XOR64ri8: case X86::XOR64ri32:
|
|
// Arithmetic with just 32-bit and 64-bit variants and no immediates.
|
|
case X86::ADCX32rr: case X86::ADCX64rr:
|
|
case X86::ADOX32rr: case X86::ADOX64rr:
|
|
case X86::ANDN32rr: case X86::ANDN64rr:
|
|
// Unary arithmetic operations.
|
|
case X86::DEC8r: case X86::DEC16r: case X86::DEC32r: case X86::DEC64r:
|
|
case X86::INC8r: case X86::INC16r: case X86::INC32r: case X86::INC64r:
|
|
case X86::NEG8r: case X86::NEG16r: case X86::NEG32r: case X86::NEG64r:
|
|
// Check whether the EFLAGS implicit-def is dead. We assume that this will
|
|
// always find the implicit-def because this code should only be reached
|
|
// for instructions that do in fact implicitly def this.
|
|
if (!MI.findRegisterDefOperand(X86::EFLAGS)->isDead()) {
|
|
// If we would clobber EFLAGS that are used, just bail for now.
|
|
LLVM_DEBUG(dbgs() << " Unable to harden post-load due to EFLAGS: ";
|
|
MI.dump(); dbgs() << "\n");
|
|
return false;
|
|
}
|
|
|
|
// Otherwise, fallthrough to handle these the same as instructions that
|
|
// don't set EFLAGS.
|
|
LLVM_FALLTHROUGH;
|
|
|
|
// Unlike other arithmetic, NOT doesn't set EFLAGS.
|
|
case X86::NOT8r: case X86::NOT16r: case X86::NOT32r: case X86::NOT64r:
|
|
|
|
// Various move instructions used to zero or sign extend things. Note that we
|
|
// intentionally don't support the _NOREX variants as we can't handle that
|
|
// register constraint anyways.
|
|
case X86::MOVSX16rr8:
|
|
case X86::MOVSX32rr8: case X86::MOVSX32rr16:
|
|
case X86::MOVSX64rr8: case X86::MOVSX64rr16: case X86::MOVSX64rr32:
|
|
case X86::MOVZX16rr8:
|
|
case X86::MOVZX32rr8: case X86::MOVZX32rr16:
|
|
case X86::MOVZX64rr8: case X86::MOVZX64rr16:
|
|
case X86::MOV32rr:
|
|
|
|
// Arithmetic instructions that are both constant time and don't set flags.
|
|
case X86::RORX32ri:
|
|
case X86::RORX64ri:
|
|
case X86::SARX32rr:
|
|
case X86::SARX64rr:
|
|
case X86::SHLX32rr:
|
|
case X86::SHLX64rr:
|
|
case X86::SHRX32rr:
|
|
case X86::SHRX64rr:
|
|
|
|
// LEA doesn't actually access memory, and its arithmetic is constant time.
|
|
case X86::LEA16r:
|
|
case X86::LEA32r:
|
|
case X86::LEA64_32r:
|
|
case X86::LEA64r:
|
|
return true;
|
|
}
|
|
}
|
|
|
|
/// Returns true if the instruction has no behavior (specified or otherwise)
|
|
/// that is based on the value loaded from memory or the value of any
|
|
/// non-address register operands.
|
|
///
|
|
/// For example, if the latency of the instruction is dependent on the
|
|
/// particular bits set in any of the registers *or* any of the bits loaded from
|
|
/// memory.
|
|
///
|
|
/// A classical example of something that is inherently not data invariant is an
|
|
/// indirect jump -- the destination is loaded into icache based on the bits set
|
|
/// in the jump destination register.
|
|
///
|
|
/// FIXME: This should become part of our instruction tables.
|
|
static bool isDataInvariantLoad(MachineInstr &MI) {
|
|
switch (MI.getOpcode()) {
|
|
default:
|
|
// By default, assume that the load will immediately leak.
|
|
return false;
|
|
|
|
// On x86 it is believed that imul is constant time w.r.t. the loaded data.
|
|
// However, they set flags and are perhaps the most surprisingly constant
|
|
// time operations so we call them out here separately.
|
|
case X86::IMUL16rm:
|
|
case X86::IMUL16rmi8:
|
|
case X86::IMUL16rmi:
|
|
case X86::IMUL32rm:
|
|
case X86::IMUL32rmi8:
|
|
case X86::IMUL32rmi:
|
|
case X86::IMUL64rm:
|
|
case X86::IMUL64rmi32:
|
|
case X86::IMUL64rmi8:
|
|
|
|
// Bit scanning and counting instructions that are somewhat surprisingly
|
|
// constant time as they scan across bits and do other fairly complex
|
|
// operations like popcnt, but are believed to be constant time on x86.
|
|
// However, these set flags.
|
|
case X86::BSF16rm:
|
|
case X86::BSF32rm:
|
|
case X86::BSF64rm:
|
|
case X86::BSR16rm:
|
|
case X86::BSR32rm:
|
|
case X86::BSR64rm:
|
|
case X86::LZCNT16rm:
|
|
case X86::LZCNT32rm:
|
|
case X86::LZCNT64rm:
|
|
case X86::POPCNT16rm:
|
|
case X86::POPCNT32rm:
|
|
case X86::POPCNT64rm:
|
|
case X86::TZCNT16rm:
|
|
case X86::TZCNT32rm:
|
|
case X86::TZCNT64rm:
|
|
|
|
// Bit manipulation instructions are effectively combinations of basic
|
|
// arithmetic ops, and should still execute in constant time. These also
|
|
// set flags.
|
|
case X86::BLCFILL32rm:
|
|
case X86::BLCFILL64rm:
|
|
case X86::BLCI32rm:
|
|
case X86::BLCI64rm:
|
|
case X86::BLCIC32rm:
|
|
case X86::BLCIC64rm:
|
|
case X86::BLCMSK32rm:
|
|
case X86::BLCMSK64rm:
|
|
case X86::BLCS32rm:
|
|
case X86::BLCS64rm:
|
|
case X86::BLSFILL32rm:
|
|
case X86::BLSFILL64rm:
|
|
case X86::BLSI32rm:
|
|
case X86::BLSI64rm:
|
|
case X86::BLSIC32rm:
|
|
case X86::BLSIC64rm:
|
|
case X86::BLSMSK32rm:
|
|
case X86::BLSMSK64rm:
|
|
case X86::BLSR32rm:
|
|
case X86::BLSR64rm:
|
|
case X86::TZMSK32rm:
|
|
case X86::TZMSK64rm:
|
|
|
|
// Bit extracting and clearing instructions should execute in constant time,
|
|
// and set flags.
|
|
case X86::BEXTR32rm:
|
|
case X86::BEXTR64rm:
|
|
case X86::BEXTRI32mi:
|
|
case X86::BEXTRI64mi:
|
|
case X86::BZHI32rm:
|
|
case X86::BZHI64rm:
|
|
|
|
// Basic arithmetic is constant time on the input but does set flags.
|
|
case X86::ADC8rm:
|
|
case X86::ADC16rm:
|
|
case X86::ADC32rm:
|
|
case X86::ADC64rm:
|
|
case X86::ADCX32rm:
|
|
case X86::ADCX64rm:
|
|
case X86::ADD8rm:
|
|
case X86::ADD16rm:
|
|
case X86::ADD32rm:
|
|
case X86::ADD64rm:
|
|
case X86::ADOX32rm:
|
|
case X86::ADOX64rm:
|
|
case X86::AND8rm:
|
|
case X86::AND16rm:
|
|
case X86::AND32rm:
|
|
case X86::AND64rm:
|
|
case X86::ANDN32rm:
|
|
case X86::ANDN64rm:
|
|
case X86::OR8rm:
|
|
case X86::OR16rm:
|
|
case X86::OR32rm:
|
|
case X86::OR64rm:
|
|
case X86::SBB8rm:
|
|
case X86::SBB16rm:
|
|
case X86::SBB32rm:
|
|
case X86::SBB64rm:
|
|
case X86::SUB8rm:
|
|
case X86::SUB16rm:
|
|
case X86::SUB32rm:
|
|
case X86::SUB64rm:
|
|
case X86::XOR8rm:
|
|
case X86::XOR16rm:
|
|
case X86::XOR32rm:
|
|
case X86::XOR64rm:
|
|
// Check whether the EFLAGS implicit-def is dead. We assume that this will
|
|
// always find the implicit-def because this code should only be reached
|
|
// for instructions that do in fact implicitly def this.
|
|
if (!MI.findRegisterDefOperand(X86::EFLAGS)->isDead()) {
|
|
// If we would clobber EFLAGS that are used, just bail for now.
|
|
LLVM_DEBUG(dbgs() << " Unable to harden post-load due to EFLAGS: ";
|
|
MI.dump(); dbgs() << "\n");
|
|
return false;
|
|
}
|
|
|
|
// Otherwise, fallthrough to handle these the same as instructions that
|
|
// don't set EFLAGS.
|
|
LLVM_FALLTHROUGH;
|
|
|
|
// Integer multiply w/o affecting flags is still believed to be constant
|
|
// time on x86. Called out separately as this is among the most surprising
|
|
// instructions to exhibit that behavior.
|
|
case X86::MULX32rm:
|
|
case X86::MULX64rm:
|
|
|
|
// Arithmetic instructions that are both constant time and don't set flags.
|
|
case X86::RORX32mi:
|
|
case X86::RORX64mi:
|
|
case X86::SARX32rm:
|
|
case X86::SARX64rm:
|
|
case X86::SHLX32rm:
|
|
case X86::SHLX64rm:
|
|
case X86::SHRX32rm:
|
|
case X86::SHRX64rm:
|
|
|
|
// Conversions are believed to be constant time and don't set flags.
|
|
case X86::CVTTSD2SI64rm: case X86::VCVTTSD2SI64rm: case X86::VCVTTSD2SI64Zrm:
|
|
case X86::CVTTSD2SIrm: case X86::VCVTTSD2SIrm: case X86::VCVTTSD2SIZrm:
|
|
case X86::CVTTSS2SI64rm: case X86::VCVTTSS2SI64rm: case X86::VCVTTSS2SI64Zrm:
|
|
case X86::CVTTSS2SIrm: case X86::VCVTTSS2SIrm: case X86::VCVTTSS2SIZrm:
|
|
case X86::CVTSI2SDrm: case X86::VCVTSI2SDrm: case X86::VCVTSI2SDZrm:
|
|
case X86::CVTSI2SSrm: case X86::VCVTSI2SSrm: case X86::VCVTSI2SSZrm:
|
|
case X86::CVTSI642SDrm: case X86::VCVTSI642SDrm: case X86::VCVTSI642SDZrm:
|
|
case X86::CVTSI642SSrm: case X86::VCVTSI642SSrm: case X86::VCVTSI642SSZrm:
|
|
case X86::CVTSS2SDrm: case X86::VCVTSS2SDrm: case X86::VCVTSS2SDZrm:
|
|
case X86::CVTSD2SSrm: case X86::VCVTSD2SSrm: case X86::VCVTSD2SSZrm:
|
|
// AVX512 added unsigned integer conversions.
|
|
case X86::VCVTTSD2USI64Zrm:
|
|
case X86::VCVTTSD2USIZrm:
|
|
case X86::VCVTTSS2USI64Zrm:
|
|
case X86::VCVTTSS2USIZrm:
|
|
case X86::VCVTUSI2SDZrm:
|
|
case X86::VCVTUSI642SDZrm:
|
|
case X86::VCVTUSI2SSZrm:
|
|
case X86::VCVTUSI642SSZrm:
|
|
|
|
// Loads to register don't set flags.
|
|
case X86::MOV8rm:
|
|
case X86::MOV8rm_NOREX:
|
|
case X86::MOV16rm:
|
|
case X86::MOV32rm:
|
|
case X86::MOV64rm:
|
|
case X86::MOVSX16rm8:
|
|
case X86::MOVSX32rm16:
|
|
case X86::MOVSX32rm8:
|
|
case X86::MOVSX32rm8_NOREX:
|
|
case X86::MOVSX64rm16:
|
|
case X86::MOVSX64rm32:
|
|
case X86::MOVSX64rm8:
|
|
case X86::MOVZX16rm8:
|
|
case X86::MOVZX32rm16:
|
|
case X86::MOVZX32rm8:
|
|
case X86::MOVZX32rm8_NOREX:
|
|
case X86::MOVZX64rm16:
|
|
case X86::MOVZX64rm8:
|
|
return true;
|
|
}
|
|
}
|
|
|
|
static bool isEFLAGSLive(MachineBasicBlock &MBB, MachineBasicBlock::iterator I,
|
|
const TargetRegisterInfo &TRI) {
|
|
// Check if EFLAGS are alive by seeing if there is a def of them or they
|
|
// live-in, and then seeing if that def is in turn used.
|
|
for (MachineInstr &MI : llvm::reverse(llvm::make_range(MBB.begin(), I))) {
|
|
if (MachineOperand *DefOp = MI.findRegisterDefOperand(X86::EFLAGS)) {
|
|
// If the def is dead, then EFLAGS is not live.
|
|
if (DefOp->isDead())
|
|
return false;
|
|
|
|
// Otherwise we've def'ed it, and it is live.
|
|
return true;
|
|
}
|
|
// While at this instruction, also check if we use and kill EFLAGS
|
|
// which means it isn't live.
|
|
if (MI.killsRegister(X86::EFLAGS, &TRI))
|
|
return false;
|
|
}
|
|
|
|
// If we didn't find anything conclusive (neither definitely alive or
|
|
// definitely dead) return whether it lives into the block.
|
|
return MBB.isLiveIn(X86::EFLAGS);
|
|
}
|
|
|
|
/// Trace the predicate state through each of the blocks in the function,
|
|
/// hardening everything necessary along the way.
|
|
///
|
|
/// We call this routine once the initial predicate state has been established
|
|
/// for each basic block in the function in the SSA updater. This routine traces
|
|
/// it through the instructions within each basic block, and for non-returning
|
|
/// blocks informs the SSA updater about the final state that lives out of the
|
|
/// block. Along the way, it hardens any vulnerable instruction using the
|
|
/// currently valid predicate state. We have to do these two things together
|
|
/// because the SSA updater only works across blocks. Within a block, we track
|
|
/// the current predicate state directly and update it as it changes.
|
|
///
|
|
/// This operates in two passes over each block. First, we analyze the loads in
|
|
/// the block to determine which strategy will be used to harden them: hardening
|
|
/// the address or hardening the loaded value when loaded into a register
|
|
/// amenable to hardening. We have to process these first because the two
|
|
/// strategies may interact -- later hardening may change what strategy we wish
|
|
/// to use. We also will analyze data dependencies between loads and avoid
|
|
/// hardening those loads that are data dependent on a load with a hardened
|
|
/// address. We also skip hardening loads already behind an LFENCE as that is
|
|
/// sufficient to harden them against misspeculation.
|
|
///
|
|
/// Second, we actively trace the predicate state through the block, applying
|
|
/// the hardening steps we determined necessary in the first pass as we go.
|
|
///
|
|
/// These two passes are applied to each basic block. We operate one block at a
|
|
/// time to simplify reasoning about reachability and sequencing.
|
|
void X86SpeculativeLoadHardeningPass::tracePredStateThroughBlocksAndHarden(
|
|
MachineFunction &MF) {
|
|
SmallPtrSet<MachineInstr *, 16> HardenPostLoad;
|
|
SmallPtrSet<MachineInstr *, 16> HardenLoadAddr;
|
|
|
|
SmallSet<unsigned, 16> HardenedAddrRegs;
|
|
|
|
SmallDenseMap<unsigned, unsigned, 32> AddrRegToHardenedReg;
|
|
|
|
// Track the set of load-dependent registers through the basic block. Because
|
|
// the values of these registers have an existing data dependency on a loaded
|
|
// value which we would have checked, we can omit any checks on them.
|
|
SparseBitVector<> LoadDepRegs;
|
|
|
|
for (MachineBasicBlock &MBB : MF) {
|
|
// The first pass over the block: collect all the loads which can have their
|
|
// loaded value hardened and all the loads that instead need their address
|
|
// hardened. During this walk we propagate load dependence for address
|
|
// hardened loads and also look for LFENCE to stop hardening wherever
|
|
// possible. When deciding whether or not to harden the loaded value or not,
|
|
// we check to see if any registers used in the address will have been
|
|
// hardened at this point and if so, harden any remaining address registers
|
|
// as that often successfully re-uses hardened addresses and minimizes
|
|
// instructions.
|
|
//
|
|
// FIXME: We should consider an aggressive mode where we continue to keep as
|
|
// many loads value hardened even when some address register hardening would
|
|
// be free (due to reuse).
|
|
//
|
|
// Note that we only need this pass if we are actually hardening loads.
|
|
if (HardenLoads)
|
|
for (MachineInstr &MI : MBB) {
|
|
// We naively assume that all def'ed registers of an instruction have
|
|
// a data dependency on all of their operands.
|
|
// FIXME: Do a more careful analysis of x86 to build a conservative
|
|
// model here.
|
|
if (llvm::any_of(MI.uses(), [&](MachineOperand &Op) {
|
|
return Op.isReg() && LoadDepRegs.test(Op.getReg());
|
|
}))
|
|
for (MachineOperand &Def : MI.defs())
|
|
if (Def.isReg())
|
|
LoadDepRegs.set(Def.getReg());
|
|
|
|
// Both Intel and AMD are guiding that they will change the semantics of
|
|
// LFENCE to be a speculation barrier, so if we see an LFENCE, there is
|
|
// no more need to guard things in this block.
|
|
if (MI.getOpcode() == X86::LFENCE)
|
|
break;
|
|
|
|
// If this instruction cannot load, nothing to do.
|
|
if (!MI.mayLoad())
|
|
continue;
|
|
|
|
// Some instructions which "load" are trivially safe or unimportant.
|
|
if (MI.getOpcode() == X86::MFENCE)
|
|
continue;
|
|
|
|
// Extract the memory operand information about this instruction.
|
|
// FIXME: This doesn't handle loading pseudo instructions which we often
|
|
// could handle with similarly generic logic. We probably need to add an
|
|
// MI-layer routine similar to the MC-layer one we use here which maps
|
|
// pseudos much like this maps real instructions.
|
|
const MCInstrDesc &Desc = MI.getDesc();
|
|
int MemRefBeginIdx = X86II::getMemoryOperandNo(Desc.TSFlags);
|
|
if (MemRefBeginIdx < 0) {
|
|
LLVM_DEBUG(dbgs()
|
|
<< "WARNING: unable to harden loading instruction: ";
|
|
MI.dump());
|
|
continue;
|
|
}
|
|
|
|
MemRefBeginIdx += X86II::getOperandBias(Desc);
|
|
|
|
MachineOperand &BaseMO =
|
|
MI.getOperand(MemRefBeginIdx + X86::AddrBaseReg);
|
|
MachineOperand &IndexMO =
|
|
MI.getOperand(MemRefBeginIdx + X86::AddrIndexReg);
|
|
|
|
// If we have at least one (non-frame-index, non-RIP) register operand,
|
|
// and neither operand is load-dependent, we need to check the load.
|
|
unsigned BaseReg = 0, IndexReg = 0;
|
|
if (!BaseMO.isFI() && BaseMO.getReg() != X86::RIP &&
|
|
BaseMO.getReg() != X86::NoRegister)
|
|
BaseReg = BaseMO.getReg();
|
|
if (IndexMO.getReg() != X86::NoRegister)
|
|
IndexReg = IndexMO.getReg();
|
|
|
|
if (!BaseReg && !IndexReg)
|
|
// No register operands!
|
|
continue;
|
|
|
|
// If any register operand is dependent, this load is dependent and we
|
|
// needn't check it.
|
|
// FIXME: Is this true in the case where we are hardening loads after
|
|
// they complete? Unclear, need to investigate.
|
|
if ((BaseReg && LoadDepRegs.test(BaseReg)) ||
|
|
(IndexReg && LoadDepRegs.test(IndexReg)))
|
|
continue;
|
|
|
|
// If post-load hardening is enabled, this load is compatible with
|
|
// post-load hardening, and we aren't already going to harden one of the
|
|
// address registers, queue it up to be hardened post-load. Notably,
|
|
// even once hardened this won't introduce a useful dependency that
|
|
// could prune out subsequent loads.
|
|
if (EnablePostLoadHardening && isDataInvariantLoad(MI) &&
|
|
MI.getDesc().getNumDefs() == 1 && MI.getOperand(0).isReg() &&
|
|
canHardenRegister(MI.getOperand(0).getReg()) &&
|
|
!HardenedAddrRegs.count(BaseReg) &&
|
|
!HardenedAddrRegs.count(IndexReg)) {
|
|
HardenPostLoad.insert(&MI);
|
|
HardenedAddrRegs.insert(MI.getOperand(0).getReg());
|
|
continue;
|
|
}
|
|
|
|
// Record this instruction for address hardening and record its register
|
|
// operands as being address-hardened.
|
|
HardenLoadAddr.insert(&MI);
|
|
if (BaseReg)
|
|
HardenedAddrRegs.insert(BaseReg);
|
|
if (IndexReg)
|
|
HardenedAddrRegs.insert(IndexReg);
|
|
|
|
for (MachineOperand &Def : MI.defs())
|
|
if (Def.isReg())
|
|
LoadDepRegs.set(Def.getReg());
|
|
}
|
|
|
|
// Now re-walk the instructions in the basic block, and apply whichever
|
|
// hardening strategy we have elected. Note that we do this in a second
|
|
// pass specifically so that we have the complete set of instructions for
|
|
// which we will do post-load hardening and can defer it in certain
|
|
// circumstances.
|
|
for (MachineInstr &MI : MBB) {
|
|
if (HardenLoads) {
|
|
// We cannot both require hardening the def of a load and its address.
|
|
assert(!(HardenLoadAddr.count(&MI) && HardenPostLoad.count(&MI)) &&
|
|
"Requested to harden both the address and def of a load!");
|
|
|
|
// Check if this is a load whose address needs to be hardened.
|
|
if (HardenLoadAddr.erase(&MI)) {
|
|
const MCInstrDesc &Desc = MI.getDesc();
|
|
int MemRefBeginIdx = X86II::getMemoryOperandNo(Desc.TSFlags);
|
|
assert(MemRefBeginIdx >= 0 && "Cannot have an invalid index here!");
|
|
|
|
MemRefBeginIdx += X86II::getOperandBias(Desc);
|
|
|
|
MachineOperand &BaseMO =
|
|
MI.getOperand(MemRefBeginIdx + X86::AddrBaseReg);
|
|
MachineOperand &IndexMO =
|
|
MI.getOperand(MemRefBeginIdx + X86::AddrIndexReg);
|
|
hardenLoadAddr(MI, BaseMO, IndexMO, AddrRegToHardenedReg);
|
|
continue;
|
|
}
|
|
|
|
// Test if this instruction is one of our post load instructions (and
|
|
// remove it from the set if so).
|
|
if (HardenPostLoad.erase(&MI)) {
|
|
assert(!MI.isCall() && "Must not try to post-load harden a call!");
|
|
|
|
// If this is a data-invariant load, we want to try and sink any
|
|
// hardening as far as possible.
|
|
if (isDataInvariantLoad(MI)) {
|
|
// Sink the instruction we'll need to harden as far as we can down
|
|
// the graph.
|
|
MachineInstr *SunkMI = sinkPostLoadHardenedInst(MI, HardenPostLoad);
|
|
|
|
// If we managed to sink this instruction, update everything so we
|
|
// harden that instruction when we reach it in the instruction
|
|
// sequence.
|
|
if (SunkMI != &MI) {
|
|
// If in sinking there was no instruction needing to be hardened,
|
|
// we're done.
|
|
if (!SunkMI)
|
|
continue;
|
|
|
|
// Otherwise, add this to the set of defs we harden.
|
|
HardenPostLoad.insert(SunkMI);
|
|
continue;
|
|
}
|
|
}
|
|
|
|
unsigned HardenedReg = hardenPostLoad(MI);
|
|
|
|
// Mark the resulting hardened register as such so we don't re-harden.
|
|
AddrRegToHardenedReg[HardenedReg] = HardenedReg;
|
|
|
|
continue;
|
|
}
|
|
|
|
// Check for an indirect call or branch that may need its input hardened
|
|
// even if we couldn't find the specific load used, or were able to
|
|
// avoid hardening it for some reason. Note that here we cannot break
|
|
// out afterward as we may still need to handle any call aspect of this
|
|
// instruction.
|
|
if ((MI.isCall() || MI.isBranch()) && HardenIndirectCallsAndJumps)
|
|
hardenIndirectCallOrJumpInstr(MI, AddrRegToHardenedReg);
|
|
}
|
|
|
|
// After we finish hardening loads we handle interprocedural hardening if
|
|
// enabled and relevant for this instruction.
|
|
if (!HardenInterprocedurally)
|
|
continue;
|
|
if (!MI.isCall() && !MI.isReturn())
|
|
continue;
|
|
|
|
// If this is a direct return (IE, not a tail call) just directly harden
|
|
// it.
|
|
if (MI.isReturn() && !MI.isCall()) {
|
|
hardenReturnInstr(MI);
|
|
continue;
|
|
}
|
|
|
|
// Otherwise we have a call. We need to handle transferring the predicate
|
|
// state into a call and recovering it after the call returns (unless this
|
|
// is a tail call).
|
|
assert(MI.isCall() && "Should only reach here for calls!");
|
|
tracePredStateThroughCall(MI);
|
|
}
|
|
|
|
HardenPostLoad.clear();
|
|
HardenLoadAddr.clear();
|
|
HardenedAddrRegs.clear();
|
|
AddrRegToHardenedReg.clear();
|
|
|
|
// Currently, we only track data-dependent loads within a basic block.
|
|
// FIXME: We should see if this is necessary or if we could be more
|
|
// aggressive here without opening up attack avenues.
|
|
LoadDepRegs.clear();
|
|
}
|
|
}
|
|
|
|
/// Save EFLAGS into the returned GPR. This can in turn be restored with
|
|
/// `restoreEFLAGS`.
|
|
///
|
|
/// Note that LLVM can only lower very simple patterns of saved and restored
|
|
/// EFLAGS registers. The restore should always be within the same basic block
|
|
/// as the save so that no PHI nodes are inserted.
|
|
unsigned X86SpeculativeLoadHardeningPass::saveEFLAGS(
|
|
MachineBasicBlock &MBB, MachineBasicBlock::iterator InsertPt,
|
|
DebugLoc Loc) {
|
|
// FIXME: Hard coding this to a 32-bit register class seems weird, but matches
|
|
// what instruction selection does.
|
|
unsigned Reg = MRI->createVirtualRegister(&X86::GR32RegClass);
|
|
// We directly copy the FLAGS register and rely on later lowering to clean
|
|
// this up into the appropriate setCC instructions.
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::COPY), Reg).addReg(X86::EFLAGS);
|
|
++NumInstsInserted;
|
|
return Reg;
|
|
}
|
|
|
|
/// Restore EFLAGS from the provided GPR. This should be produced by
|
|
/// `saveEFLAGS`.
|
|
///
|
|
/// This must be done within the same basic block as the save in order to
|
|
/// reliably lower.
|
|
void X86SpeculativeLoadHardeningPass::restoreEFLAGS(
|
|
MachineBasicBlock &MBB, MachineBasicBlock::iterator InsertPt, DebugLoc Loc,
|
|
unsigned Reg) {
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::COPY), X86::EFLAGS).addReg(Reg);
|
|
++NumInstsInserted;
|
|
}
|
|
|
|
/// Takes the current predicate state (in a register) and merges it into the
|
|
/// stack pointer. The state is essentially a single bit, but we merge this in
|
|
/// a way that won't form non-canonical pointers and also will be preserved
|
|
/// across normal stack adjustments.
|
|
void X86SpeculativeLoadHardeningPass::mergePredStateIntoSP(
|
|
MachineBasicBlock &MBB, MachineBasicBlock::iterator InsertPt, DebugLoc Loc,
|
|
unsigned PredStateReg) {
|
|
unsigned TmpReg = MRI->createVirtualRegister(PS->RC);
|
|
// FIXME: This hard codes a shift distance based on the number of bits needed
|
|
// to stay canonical on 64-bit. We should compute this somehow and support
|
|
// 32-bit as part of that.
|
|
auto ShiftI = BuildMI(MBB, InsertPt, Loc, TII->get(X86::SHL64ri), TmpReg)
|
|
.addReg(PredStateReg, RegState::Kill)
|
|
.addImm(47);
|
|
ShiftI->addRegisterDead(X86::EFLAGS, TRI);
|
|
++NumInstsInserted;
|
|
auto OrI = BuildMI(MBB, InsertPt, Loc, TII->get(X86::OR64rr), X86::RSP)
|
|
.addReg(X86::RSP)
|
|
.addReg(TmpReg, RegState::Kill);
|
|
OrI->addRegisterDead(X86::EFLAGS, TRI);
|
|
++NumInstsInserted;
|
|
}
|
|
|
|
/// Extracts the predicate state stored in the high bits of the stack pointer.
|
|
unsigned X86SpeculativeLoadHardeningPass::extractPredStateFromSP(
|
|
MachineBasicBlock &MBB, MachineBasicBlock::iterator InsertPt,
|
|
DebugLoc Loc) {
|
|
unsigned PredStateReg = MRI->createVirtualRegister(PS->RC);
|
|
unsigned TmpReg = MRI->createVirtualRegister(PS->RC);
|
|
|
|
// We know that the stack pointer will have any preserved predicate state in
|
|
// its high bit. We just want to smear this across the other bits. Turns out,
|
|
// this is exactly what an arithmetic right shift does.
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(TargetOpcode::COPY), TmpReg)
|
|
.addReg(X86::RSP);
|
|
auto ShiftI =
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::SAR64ri), PredStateReg)
|
|
.addReg(TmpReg, RegState::Kill)
|
|
.addImm(TRI->getRegSizeInBits(*PS->RC) - 1);
|
|
ShiftI->addRegisterDead(X86::EFLAGS, TRI);
|
|
++NumInstsInserted;
|
|
|
|
return PredStateReg;
|
|
}
|
|
|
|
void X86SpeculativeLoadHardeningPass::hardenLoadAddr(
|
|
MachineInstr &MI, MachineOperand &BaseMO, MachineOperand &IndexMO,
|
|
SmallDenseMap<unsigned, unsigned, 32> &AddrRegToHardenedReg) {
|
|
MachineBasicBlock &MBB = *MI.getParent();
|
|
DebugLoc Loc = MI.getDebugLoc();
|
|
|
|
// Check if EFLAGS are alive by seeing if there is a def of them or they
|
|
// live-in, and then seeing if that def is in turn used.
|
|
bool EFLAGSLive = isEFLAGSLive(MBB, MI.getIterator(), *TRI);
|
|
|
|
SmallVector<MachineOperand *, 2> HardenOpRegs;
|
|
|
|
if (BaseMO.isFI()) {
|
|
// A frame index is never a dynamically controllable load, so only
|
|
// harden it if we're covering fixed address loads as well.
|
|
LLVM_DEBUG(
|
|
dbgs() << " Skipping hardening base of explicit stack frame load: ";
|
|
MI.dump(); dbgs() << "\n");
|
|
} else if (BaseMO.getReg() == X86::RIP ||
|
|
BaseMO.getReg() == X86::NoRegister) {
|
|
// For both RIP-relative addressed loads or absolute loads, we cannot
|
|
// meaningfully harden them because the address being loaded has no
|
|
// dynamic component.
|
|
//
|
|
// FIXME: When using a segment base (like TLS does) we end up with the
|
|
// dynamic address being the base plus -1 because we can't mutate the
|
|
// segment register here. This allows the signed 32-bit offset to point at
|
|
// valid segment-relative addresses and load them successfully.
|
|
LLVM_DEBUG(
|
|
dbgs() << " Cannot harden base of "
|
|
<< (BaseMO.getReg() == X86::RIP ? "RIP-relative" : "no-base")
|
|
<< " address in a load!");
|
|
} else {
|
|
assert(BaseMO.isReg() &&
|
|
"Only allowed to have a frame index or register base.");
|
|
HardenOpRegs.push_back(&BaseMO);
|
|
}
|
|
|
|
if (IndexMO.getReg() != X86::NoRegister &&
|
|
(HardenOpRegs.empty() ||
|
|
HardenOpRegs.front()->getReg() != IndexMO.getReg()))
|
|
HardenOpRegs.push_back(&IndexMO);
|
|
|
|
assert((HardenOpRegs.size() == 1 || HardenOpRegs.size() == 2) &&
|
|
"Should have exactly one or two registers to harden!");
|
|
assert((HardenOpRegs.size() == 1 ||
|
|
HardenOpRegs[0]->getReg() != HardenOpRegs[1]->getReg()) &&
|
|
"Should not have two of the same registers!");
|
|
|
|
// Remove any registers that have alreaded been checked.
|
|
llvm::erase_if(HardenOpRegs, [&](MachineOperand *Op) {
|
|
// See if this operand's register has already been checked.
|
|
auto It = AddrRegToHardenedReg.find(Op->getReg());
|
|
if (It == AddrRegToHardenedReg.end())
|
|
// Not checked, so retain this one.
|
|
return false;
|
|
|
|
// Otherwise, we can directly update this operand and remove it.
|
|
Op->setReg(It->second);
|
|
return true;
|
|
});
|
|
// If there are none left, we're done.
|
|
if (HardenOpRegs.empty())
|
|
return;
|
|
|
|
// Compute the current predicate state.
|
|
unsigned StateReg = PS->SSA.GetValueAtEndOfBlock(&MBB);
|
|
|
|
auto InsertPt = MI.getIterator();
|
|
|
|
// If EFLAGS are live and we don't have access to instructions that avoid
|
|
// clobbering EFLAGS we need to save and restore them. This in turn makes
|
|
// the EFLAGS no longer live.
|
|
unsigned FlagsReg = 0;
|
|
if (EFLAGSLive && !Subtarget->hasBMI2()) {
|
|
EFLAGSLive = false;
|
|
FlagsReg = saveEFLAGS(MBB, InsertPt, Loc);
|
|
}
|
|
|
|
for (MachineOperand *Op : HardenOpRegs) {
|
|
unsigned OpReg = Op->getReg();
|
|
auto *OpRC = MRI->getRegClass(OpReg);
|
|
unsigned TmpReg = MRI->createVirtualRegister(OpRC);
|
|
|
|
// If this is a vector register, we'll need somewhat custom logic to handle
|
|
// hardening it.
|
|
if (!Subtarget->hasVLX() && (OpRC->hasSuperClassEq(&X86::VR128RegClass) ||
|
|
OpRC->hasSuperClassEq(&X86::VR256RegClass))) {
|
|
assert(Subtarget->hasAVX2() && "AVX2-specific register classes!");
|
|
bool Is128Bit = OpRC->hasSuperClassEq(&X86::VR128RegClass);
|
|
|
|
// Move our state into a vector register.
|
|
// FIXME: We could skip this at the cost of longer encodings with AVX-512
|
|
// but that doesn't seem likely worth it.
|
|
unsigned VStateReg = MRI->createVirtualRegister(&X86::VR128RegClass);
|
|
auto MovI =
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::VMOV64toPQIrr), VStateReg)
|
|
.addReg(StateReg);
|
|
(void)MovI;
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting mov: "; MovI->dump(); dbgs() << "\n");
|
|
|
|
// Broadcast it across the vector register.
|
|
unsigned VBStateReg = MRI->createVirtualRegister(OpRC);
|
|
auto BroadcastI = BuildMI(MBB, InsertPt, Loc,
|
|
TII->get(Is128Bit ? X86::VPBROADCASTQrr
|
|
: X86::VPBROADCASTQYrr),
|
|
VBStateReg)
|
|
.addReg(VStateReg);
|
|
(void)BroadcastI;
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting broadcast: "; BroadcastI->dump();
|
|
dbgs() << "\n");
|
|
|
|
// Merge our potential poison state into the value with a vector or.
|
|
auto OrI =
|
|
BuildMI(MBB, InsertPt, Loc,
|
|
TII->get(Is128Bit ? X86::VPORrr : X86::VPORYrr), TmpReg)
|
|
.addReg(VBStateReg)
|
|
.addReg(OpReg);
|
|
(void)OrI;
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting or: "; OrI->dump(); dbgs() << "\n");
|
|
} else if (OpRC->hasSuperClassEq(&X86::VR128XRegClass) ||
|
|
OpRC->hasSuperClassEq(&X86::VR256XRegClass) ||
|
|
OpRC->hasSuperClassEq(&X86::VR512RegClass)) {
|
|
assert(Subtarget->hasAVX512() && "AVX512-specific register classes!");
|
|
bool Is128Bit = OpRC->hasSuperClassEq(&X86::VR128XRegClass);
|
|
bool Is256Bit = OpRC->hasSuperClassEq(&X86::VR256XRegClass);
|
|
if (Is128Bit || Is256Bit)
|
|
assert(Subtarget->hasVLX() && "AVX512VL-specific register classes!");
|
|
|
|
// Broadcast our state into a vector register.
|
|
unsigned VStateReg = MRI->createVirtualRegister(OpRC);
|
|
unsigned BroadcastOp =
|
|
Is128Bit ? X86::VPBROADCASTQrZ128r
|
|
: Is256Bit ? X86::VPBROADCASTQrZ256r : X86::VPBROADCASTQrZr;
|
|
auto BroadcastI =
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(BroadcastOp), VStateReg)
|
|
.addReg(StateReg);
|
|
(void)BroadcastI;
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting broadcast: "; BroadcastI->dump();
|
|
dbgs() << "\n");
|
|
|
|
// Merge our potential poison state into the value with a vector or.
|
|
unsigned OrOp = Is128Bit ? X86::VPORQZ128rr
|
|
: Is256Bit ? X86::VPORQZ256rr : X86::VPORQZrr;
|
|
auto OrI = BuildMI(MBB, InsertPt, Loc, TII->get(OrOp), TmpReg)
|
|
.addReg(VStateReg)
|
|
.addReg(OpReg);
|
|
(void)OrI;
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting or: "; OrI->dump(); dbgs() << "\n");
|
|
} else {
|
|
// FIXME: Need to support GR32 here for 32-bit code.
|
|
assert(OpRC->hasSuperClassEq(&X86::GR64RegClass) &&
|
|
"Not a supported register class for address hardening!");
|
|
|
|
if (!EFLAGSLive) {
|
|
// Merge our potential poison state into the value with an or.
|
|
auto OrI = BuildMI(MBB, InsertPt, Loc, TII->get(X86::OR64rr), TmpReg)
|
|
.addReg(StateReg)
|
|
.addReg(OpReg);
|
|
OrI->addRegisterDead(X86::EFLAGS, TRI);
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting or: "; OrI->dump(); dbgs() << "\n");
|
|
} else {
|
|
// We need to avoid touching EFLAGS so shift out all but the least
|
|
// significant bit using the instruction that doesn't update flags.
|
|
auto ShiftI =
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::SHRX64rr), TmpReg)
|
|
.addReg(OpReg)
|
|
.addReg(StateReg);
|
|
(void)ShiftI;
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting shrx: "; ShiftI->dump();
|
|
dbgs() << "\n");
|
|
}
|
|
}
|
|
|
|
// Record this register as checked and update the operand.
|
|
assert(!AddrRegToHardenedReg.count(Op->getReg()) &&
|
|
"Should not have checked this register yet!");
|
|
AddrRegToHardenedReg[Op->getReg()] = TmpReg;
|
|
Op->setReg(TmpReg);
|
|
++NumAddrRegsHardened;
|
|
}
|
|
|
|
// And restore the flags if needed.
|
|
if (FlagsReg)
|
|
restoreEFLAGS(MBB, InsertPt, Loc, FlagsReg);
|
|
}
|
|
|
|
MachineInstr *X86SpeculativeLoadHardeningPass::sinkPostLoadHardenedInst(
|
|
MachineInstr &InitialMI, SmallPtrSetImpl<MachineInstr *> &HardenedInstrs) {
|
|
assert(isDataInvariantLoad(InitialMI) &&
|
|
"Cannot get here with a non-invariant load!");
|
|
|
|
// See if we can sink hardening the loaded value.
|
|
auto SinkCheckToSingleUse =
|
|
[&](MachineInstr &MI) -> Optional<MachineInstr *> {
|
|
unsigned DefReg = MI.getOperand(0).getReg();
|
|
|
|
// We need to find a single use which we can sink the check. We can
|
|
// primarily do this because many uses may already end up checked on their
|
|
// own.
|
|
MachineInstr *SingleUseMI = nullptr;
|
|
for (MachineInstr &UseMI : MRI->use_instructions(DefReg)) {
|
|
// If we're already going to harden this use, it is data invariant and
|
|
// within our block.
|
|
if (HardenedInstrs.count(&UseMI)) {
|
|
if (!isDataInvariantLoad(UseMI)) {
|
|
// If we've already decided to harden a non-load, we must have sunk
|
|
// some other post-load hardened instruction to it and it must itself
|
|
// be data-invariant.
|
|
assert(isDataInvariant(UseMI) &&
|
|
"Data variant instruction being hardened!");
|
|
continue;
|
|
}
|
|
|
|
// Otherwise, this is a load and the load component can't be data
|
|
// invariant so check how this register is being used.
|
|
const MCInstrDesc &Desc = UseMI.getDesc();
|
|
int MemRefBeginIdx = X86II::getMemoryOperandNo(Desc.TSFlags);
|
|
assert(MemRefBeginIdx >= 0 &&
|
|
"Should always have mem references here!");
|
|
MemRefBeginIdx += X86II::getOperandBias(Desc);
|
|
|
|
MachineOperand &BaseMO =
|
|
UseMI.getOperand(MemRefBeginIdx + X86::AddrBaseReg);
|
|
MachineOperand &IndexMO =
|
|
UseMI.getOperand(MemRefBeginIdx + X86::AddrIndexReg);
|
|
if ((BaseMO.isReg() && BaseMO.getReg() == DefReg) ||
|
|
(IndexMO.isReg() && IndexMO.getReg() == DefReg))
|
|
// The load uses the register as part of its address making it not
|
|
// invariant.
|
|
return {};
|
|
|
|
continue;
|
|
}
|
|
|
|
if (SingleUseMI)
|
|
// We already have a single use, this would make two. Bail.
|
|
return {};
|
|
|
|
// If this single use isn't data invariant, isn't in this block, or has
|
|
// interfering EFLAGS, we can't sink the hardening to it.
|
|
if (!isDataInvariant(UseMI) || UseMI.getParent() != MI.getParent())
|
|
return {};
|
|
|
|
// If this instruction defines multiple registers bail as we won't harden
|
|
// all of them.
|
|
if (UseMI.getDesc().getNumDefs() > 1)
|
|
return {};
|
|
|
|
// If this register isn't a virtual register we can't walk uses of sanely,
|
|
// just bail. Also check that its register class is one of the ones we
|
|
// can harden.
|
|
unsigned UseDefReg = UseMI.getOperand(0).getReg();
|
|
if (!TRI->isVirtualRegister(UseDefReg) ||
|
|
!canHardenRegister(UseDefReg))
|
|
return {};
|
|
|
|
SingleUseMI = &UseMI;
|
|
}
|
|
|
|
// If SingleUseMI is still null, there is no use that needs its own
|
|
// checking. Otherwise, it is the single use that needs checking.
|
|
return {SingleUseMI};
|
|
};
|
|
|
|
MachineInstr *MI = &InitialMI;
|
|
while (Optional<MachineInstr *> SingleUse = SinkCheckToSingleUse(*MI)) {
|
|
// Update which MI we're checking now.
|
|
MI = *SingleUse;
|
|
if (!MI)
|
|
break;
|
|
}
|
|
|
|
return MI;
|
|
}
|
|
|
|
bool X86SpeculativeLoadHardeningPass::canHardenRegister(unsigned Reg) {
|
|
auto *RC = MRI->getRegClass(Reg);
|
|
int RegBytes = TRI->getRegSizeInBits(*RC) / 8;
|
|
if (RegBytes > 8)
|
|
// We don't support post-load hardening of vectors.
|
|
return false;
|
|
|
|
// If this register class is explicitly constrained to a class that doesn't
|
|
// require REX prefix, we may not be able to satisfy that constraint when
|
|
// emitting the hardening instructions, so bail out here.
|
|
// FIXME: This seems like a pretty lame hack. The way this comes up is when we
|
|
// end up both with a NOREX and REX-only register as operands to the hardening
|
|
// instructions. It would be better to fix that code to handle this situation
|
|
// rather than hack around it in this way.
|
|
const TargetRegisterClass *NOREXRegClasses[] = {
|
|
&X86::GR8_NOREXRegClass, &X86::GR16_NOREXRegClass,
|
|
&X86::GR32_NOREXRegClass, &X86::GR64_NOREXRegClass};
|
|
if (RC == NOREXRegClasses[Log2_32(RegBytes)])
|
|
return false;
|
|
|
|
const TargetRegisterClass *GPRRegClasses[] = {
|
|
&X86::GR8RegClass, &X86::GR16RegClass, &X86::GR32RegClass,
|
|
&X86::GR64RegClass};
|
|
return RC->hasSuperClassEq(GPRRegClasses[Log2_32(RegBytes)]);
|
|
}
|
|
|
|
/// Harden a value in a register.
|
|
///
|
|
/// This is the low-level logic to fully harden a value sitting in a register
|
|
/// against leaking during speculative execution.
|
|
///
|
|
/// Unlike hardening an address that is used by a load, this routine is required
|
|
/// to hide *all* incoming bits in the register.
|
|
///
|
|
/// `Reg` must be a virtual register. Currently, it is required to be a GPR no
|
|
/// larger than the predicate state register. FIXME: We should support vector
|
|
/// registers here by broadcasting the predicate state.
|
|
///
|
|
/// The new, hardened virtual register is returned. It will have the same
|
|
/// register class as `Reg`.
|
|
unsigned X86SpeculativeLoadHardeningPass::hardenValueInRegister(
|
|
unsigned Reg, MachineBasicBlock &MBB, MachineBasicBlock::iterator InsertPt,
|
|
DebugLoc Loc) {
|
|
assert(canHardenRegister(Reg) && "Cannot harden this register!");
|
|
assert(TRI->isVirtualRegister(Reg) && "Cannot harden a physical register!");
|
|
|
|
auto *RC = MRI->getRegClass(Reg);
|
|
int Bytes = TRI->getRegSizeInBits(*RC) / 8;
|
|
|
|
unsigned StateReg = PS->SSA.GetValueAtEndOfBlock(&MBB);
|
|
|
|
// FIXME: Need to teach this about 32-bit mode.
|
|
if (Bytes != 8) {
|
|
unsigned SubRegImms[] = {X86::sub_8bit, X86::sub_16bit, X86::sub_32bit};
|
|
unsigned SubRegImm = SubRegImms[Log2_32(Bytes)];
|
|
unsigned NarrowStateReg = MRI->createVirtualRegister(RC);
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(TargetOpcode::COPY), NarrowStateReg)
|
|
.addReg(StateReg, 0, SubRegImm);
|
|
StateReg = NarrowStateReg;
|
|
}
|
|
|
|
unsigned FlagsReg = 0;
|
|
if (isEFLAGSLive(MBB, InsertPt, *TRI))
|
|
FlagsReg = saveEFLAGS(MBB, InsertPt, Loc);
|
|
|
|
unsigned NewReg = MRI->createVirtualRegister(RC);
|
|
unsigned OrOpCodes[] = {X86::OR8rr, X86::OR16rr, X86::OR32rr, X86::OR64rr};
|
|
unsigned OrOpCode = OrOpCodes[Log2_32(Bytes)];
|
|
auto OrI = BuildMI(MBB, InsertPt, Loc, TII->get(OrOpCode), NewReg)
|
|
.addReg(StateReg)
|
|
.addReg(Reg);
|
|
OrI->addRegisterDead(X86::EFLAGS, TRI);
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting or: "; OrI->dump(); dbgs() << "\n");
|
|
|
|
if (FlagsReg)
|
|
restoreEFLAGS(MBB, InsertPt, Loc, FlagsReg);
|
|
|
|
return NewReg;
|
|
}
|
|
|
|
/// Harden a load by hardening the loaded value in the defined register.
|
|
///
|
|
/// We can harden a non-leaking load into a register without touching the
|
|
/// address by just hiding all of the loaded bits during misspeculation. We use
|
|
/// an `or` instruction to do this because we set up our poison value as all
|
|
/// ones. And the goal is just for the loaded bits to not be exposed to
|
|
/// execution and coercing them to one is sufficient.
|
|
///
|
|
/// Returns the newly hardened register.
|
|
unsigned X86SpeculativeLoadHardeningPass::hardenPostLoad(MachineInstr &MI) {
|
|
MachineBasicBlock &MBB = *MI.getParent();
|
|
DebugLoc Loc = MI.getDebugLoc();
|
|
|
|
auto &DefOp = MI.getOperand(0);
|
|
unsigned OldDefReg = DefOp.getReg();
|
|
auto *DefRC = MRI->getRegClass(OldDefReg);
|
|
|
|
// Because we want to completely replace the uses of this def'ed value with
|
|
// the hardened value, create a dedicated new register that will only be used
|
|
// to communicate the unhardened value to the hardening.
|
|
unsigned UnhardenedReg = MRI->createVirtualRegister(DefRC);
|
|
DefOp.setReg(UnhardenedReg);
|
|
|
|
// Now harden this register's value, getting a hardened reg that is safe to
|
|
// use. Note that we insert the instructions to compute this *after* the
|
|
// defining instruction, not before it.
|
|
unsigned HardenedReg = hardenValueInRegister(
|
|
UnhardenedReg, MBB, std::next(MI.getIterator()), Loc);
|
|
|
|
// Finally, replace the old register (which now only has the uses of the
|
|
// original def) with the hardened register.
|
|
MRI->replaceRegWith(/*FromReg*/ OldDefReg, /*ToReg*/ HardenedReg);
|
|
|
|
++NumPostLoadRegsHardened;
|
|
return HardenedReg;
|
|
}
|
|
|
|
/// Harden a return instruction.
|
|
///
|
|
/// Returns implicitly perform a load which we need to harden. Without hardening
|
|
/// this load, an attacker my speculatively write over the return address to
|
|
/// steer speculation of the return to an attacker controlled address. This is
|
|
/// called Spectre v1.1 or Bounds Check Bypass Store (BCBS) and is described in
|
|
/// this paper:
|
|
/// https://people.csail.mit.edu/vlk/spectre11.pdf
|
|
///
|
|
/// We can harden this by introducing an LFENCE that will delay any load of the
|
|
/// return address until prior instructions have retired (and thus are not being
|
|
/// speculated), or we can harden the address used by the implicit load: the
|
|
/// stack pointer.
|
|
///
|
|
/// If we are not using an LFENCE, hardening the stack pointer has an additional
|
|
/// benefit: it allows us to pass the predicate state accumulated in this
|
|
/// function back to the caller. In the absence of a BCBS attack on the return,
|
|
/// the caller will typically be resumed and speculatively executed due to the
|
|
/// Return Stack Buffer (RSB) prediction which is very accurate and has a high
|
|
/// priority. It is possible that some code from the caller will be executed
|
|
/// speculatively even during a BCBS-attacked return until the steering takes
|
|
/// effect. Whenever this happens, the caller can recover the (poisoned)
|
|
/// predicate state from the stack pointer and continue to harden loads.
|
|
void X86SpeculativeLoadHardeningPass::hardenReturnInstr(MachineInstr &MI) {
|
|
MachineBasicBlock &MBB = *MI.getParent();
|
|
DebugLoc Loc = MI.getDebugLoc();
|
|
auto InsertPt = MI.getIterator();
|
|
|
|
if (FenceCallAndRet)
|
|
// No need to fence here as we'll fence at the return site itself. That
|
|
// handles more cases than we can handle here.
|
|
return;
|
|
|
|
// Take our predicate state, shift it to the high 17 bits (so that we keep
|
|
// pointers canonical) and merge it into RSP. This will allow the caller to
|
|
// extract it when we return (speculatively).
|
|
mergePredStateIntoSP(MBB, InsertPt, Loc, PS->SSA.GetValueAtEndOfBlock(&MBB));
|
|
}
|
|
|
|
/// Trace the predicate state through a call.
|
|
///
|
|
/// There are several layers of this needed to handle the full complexity of
|
|
/// calls.
|
|
///
|
|
/// First, we need to send the predicate state into the called function. We do
|
|
/// this by merging it into the high bits of the stack pointer.
|
|
///
|
|
/// For tail calls, this is all we need to do.
|
|
///
|
|
/// For calls where we might return and resume the control flow, we need to
|
|
/// extract the predicate state from the high bits of the stack pointer after
|
|
/// control returns from the called function.
|
|
///
|
|
/// We also need to verify that we intended to return to this location in the
|
|
/// code. An attacker might arrange for the processor to mispredict the return
|
|
/// to this valid but incorrect return address in the program rather than the
|
|
/// correct one. See the paper on this attack, called "ret2spec" by the
|
|
/// researchers, here:
|
|
/// https://christian-rossow.de/publications/ret2spec-ccs2018.pdf
|
|
///
|
|
/// The way we verify that we returned to the correct location is by preserving
|
|
/// the expected return address across the call. One technique involves taking
|
|
/// advantage of the red-zone to load the return address from `8(%rsp)` where it
|
|
/// was left by the RET instruction when it popped `%rsp`. Alternatively, we can
|
|
/// directly save the address into a register that will be preserved across the
|
|
/// call. We compare this intended return address against the address
|
|
/// immediately following the call (the observed return address). If these
|
|
/// mismatch, we have detected misspeculation and can poison our predicate
|
|
/// state.
|
|
void X86SpeculativeLoadHardeningPass::tracePredStateThroughCall(
|
|
MachineInstr &MI) {
|
|
MachineBasicBlock &MBB = *MI.getParent();
|
|
MachineFunction &MF = *MBB.getParent();
|
|
auto InsertPt = MI.getIterator();
|
|
DebugLoc Loc = MI.getDebugLoc();
|
|
|
|
if (FenceCallAndRet) {
|
|
if (MI.isReturn())
|
|
// Tail call, we don't return to this function.
|
|
// FIXME: We should also handle noreturn calls.
|
|
return;
|
|
|
|
// We don't need to fence before the call because the function should fence
|
|
// in its entry. However, we do need to fence after the call returns.
|
|
// Fencing before the return doesn't correctly handle cases where the return
|
|
// itself is mispredicted.
|
|
BuildMI(MBB, std::next(InsertPt), Loc, TII->get(X86::LFENCE));
|
|
++NumInstsInserted;
|
|
++NumLFENCEsInserted;
|
|
return;
|
|
}
|
|
|
|
// First, we transfer the predicate state into the called function by merging
|
|
// it into the stack pointer. This will kill the current def of the state.
|
|
unsigned StateReg = PS->SSA.GetValueAtEndOfBlock(&MBB);
|
|
mergePredStateIntoSP(MBB, InsertPt, Loc, StateReg);
|
|
|
|
// If this call is also a return, it is a tail call and we don't need anything
|
|
// else to handle it so just return. Also, if there are no further
|
|
// instructions and no successors, this call does not return so we can also
|
|
// bail.
|
|
if (MI.isReturn() || (std::next(InsertPt) == MBB.end() && MBB.succ_empty()))
|
|
return;
|
|
|
|
// Create a symbol to track the return address and attach it to the call
|
|
// machine instruction. We will lower extra symbols attached to call
|
|
// instructions as label immediately following the call.
|
|
MCSymbol *RetSymbol =
|
|
MF.getContext().createTempSymbol("slh_ret_addr",
|
|
/*AlwaysAddSuffix*/ true);
|
|
MI.setPostInstrSymbol(MF, RetSymbol);
|
|
|
|
const TargetRegisterClass *AddrRC = &X86::GR64RegClass;
|
|
unsigned ExpectedRetAddrReg = 0;
|
|
|
|
// If we have no red zones or if the function returns twice (possibly without
|
|
// using the `ret` instruction) like setjmp, we need to save the expected
|
|
// return address prior to the call.
|
|
if (MF.getFunction().hasFnAttribute(Attribute::NoRedZone) ||
|
|
MF.exposesReturnsTwice()) {
|
|
// If we don't have red zones, we need to compute the expected return
|
|
// address prior to the call and store it in a register that lives across
|
|
// the call.
|
|
//
|
|
// In some ways, this is doubly satisfying as a mitigation because it will
|
|
// also successfully detect stack smashing bugs in some cases (typically,
|
|
// when a callee-saved register is used and the callee doesn't push it onto
|
|
// the stack). But that isn't our primary goal, so we only use it as
|
|
// a fallback.
|
|
//
|
|
// FIXME: It isn't clear that this is reliable in the face of
|
|
// rematerialization in the register allocator. We somehow need to force
|
|
// that to not occur for this particular instruction, and instead to spill
|
|
// or otherwise preserve the value computed *prior* to the call.
|
|
//
|
|
// FIXME: It is even less clear why MachineCSE can't just fold this when we
|
|
// end up having to use identical instructions both before and after the
|
|
// call to feed the comparison.
|
|
ExpectedRetAddrReg = MRI->createVirtualRegister(AddrRC);
|
|
if (MF.getTarget().getCodeModel() == CodeModel::Small &&
|
|
!Subtarget->isPositionIndependent()) {
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::MOV64ri32), ExpectedRetAddrReg)
|
|
.addSym(RetSymbol);
|
|
} else {
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::LEA64r), ExpectedRetAddrReg)
|
|
.addReg(/*Base*/ X86::RIP)
|
|
.addImm(/*Scale*/ 1)
|
|
.addReg(/*Index*/ 0)
|
|
.addSym(RetSymbol)
|
|
.addReg(/*Segment*/ 0);
|
|
}
|
|
}
|
|
|
|
// Step past the call to handle when it returns.
|
|
++InsertPt;
|
|
|
|
// If we didn't pre-compute the expected return address into a register, then
|
|
// red zones are enabled and the return address is still available on the
|
|
// stack immediately after the call. As the very first instruction, we load it
|
|
// into a register.
|
|
if (!ExpectedRetAddrReg) {
|
|
ExpectedRetAddrReg = MRI->createVirtualRegister(AddrRC);
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::MOV64rm), ExpectedRetAddrReg)
|
|
.addReg(/*Base*/ X86::RSP)
|
|
.addImm(/*Scale*/ 1)
|
|
.addReg(/*Index*/ 0)
|
|
.addImm(/*Displacement*/ -8) // The stack pointer has been popped, so
|
|
// the return address is 8-bytes past it.
|
|
.addReg(/*Segment*/ 0);
|
|
}
|
|
|
|
// Now we extract the callee's predicate state from the stack pointer.
|
|
unsigned NewStateReg = extractPredStateFromSP(MBB, InsertPt, Loc);
|
|
|
|
// Test the expected return address against our actual address. If we can
|
|
// form this basic block's address as an immediate, this is easy. Otherwise
|
|
// we compute it.
|
|
if (MF.getTarget().getCodeModel() == CodeModel::Small &&
|
|
!Subtarget->isPositionIndependent()) {
|
|
// FIXME: Could we fold this with the load? It would require careful EFLAGS
|
|
// management.
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::CMP64ri32))
|
|
.addReg(ExpectedRetAddrReg, RegState::Kill)
|
|
.addSym(RetSymbol);
|
|
} else {
|
|
unsigned ActualRetAddrReg = MRI->createVirtualRegister(AddrRC);
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::LEA64r), ActualRetAddrReg)
|
|
.addReg(/*Base*/ X86::RIP)
|
|
.addImm(/*Scale*/ 1)
|
|
.addReg(/*Index*/ 0)
|
|
.addSym(RetSymbol)
|
|
.addReg(/*Segment*/ 0);
|
|
BuildMI(MBB, InsertPt, Loc, TII->get(X86::CMP64rr))
|
|
.addReg(ExpectedRetAddrReg, RegState::Kill)
|
|
.addReg(ActualRetAddrReg, RegState::Kill);
|
|
}
|
|
|
|
// Now conditionally update the predicate state we just extracted if we ended
|
|
// up at a different return address than expected.
|
|
int PredStateSizeInBytes = TRI->getRegSizeInBits(*PS->RC) / 8;
|
|
auto CMovOp = X86::getCMovFromCond(X86::COND_NE, PredStateSizeInBytes);
|
|
|
|
unsigned UpdatedStateReg = MRI->createVirtualRegister(PS->RC);
|
|
auto CMovI = BuildMI(MBB, InsertPt, Loc, TII->get(CMovOp), UpdatedStateReg)
|
|
.addReg(NewStateReg, RegState::Kill)
|
|
.addReg(PS->PoisonReg);
|
|
CMovI->findRegisterUseOperand(X86::EFLAGS)->setIsKill(true);
|
|
++NumInstsInserted;
|
|
LLVM_DEBUG(dbgs() << " Inserting cmov: "; CMovI->dump(); dbgs() << "\n");
|
|
|
|
PS->SSA.AddAvailableValue(&MBB, UpdatedStateReg);
|
|
}
|
|
|
|
/// An attacker may speculatively store over a value that is then speculatively
|
|
/// loaded and used as the target of an indirect call or jump instruction. This
|
|
/// is called Spectre v1.2 or Bounds Check Bypass Store (BCBS) and is described
|
|
/// in this paper:
|
|
/// https://people.csail.mit.edu/vlk/spectre11.pdf
|
|
///
|
|
/// When this happens, the speculative execution of the call or jump will end up
|
|
/// being steered to this attacker controlled address. While most such loads
|
|
/// will be adequately hardened already, we want to ensure that they are
|
|
/// definitively treated as needing post-load hardening. While address hardening
|
|
/// is sufficient to prevent secret data from leaking to the attacker, it may
|
|
/// not be sufficient to prevent an attacker from steering speculative
|
|
/// execution. We forcibly unfolded all relevant loads above and so will always
|
|
/// have an opportunity to post-load harden here, we just need to scan for cases
|
|
/// not already flagged and add them.
|
|
void X86SpeculativeLoadHardeningPass::hardenIndirectCallOrJumpInstr(
|
|
MachineInstr &MI,
|
|
SmallDenseMap<unsigned, unsigned, 32> &AddrRegToHardenedReg) {
|
|
switch (MI.getOpcode()) {
|
|
case X86::FARCALL16m:
|
|
case X86::FARCALL32m:
|
|
case X86::FARCALL64:
|
|
case X86::FARJMP16m:
|
|
case X86::FARJMP32m:
|
|
case X86::FARJMP64:
|
|
// We don't need to harden either far calls or far jumps as they are
|
|
// safe from Spectre.
|
|
return;
|
|
|
|
default:
|
|
break;
|
|
}
|
|
|
|
// We should never see a loading instruction at this point, as those should
|
|
// have been unfolded.
|
|
assert(!MI.mayLoad() && "Found a lingering loading instruction!");
|
|
|
|
// If the first operand isn't a register, this is a branch or call
|
|
// instruction with an immediate operand which doesn't need to be hardened.
|
|
if (!MI.getOperand(0).isReg())
|
|
return;
|
|
|
|
// For all of these, the target register is the first operand of the
|
|
// instruction.
|
|
auto &TargetOp = MI.getOperand(0);
|
|
unsigned OldTargetReg = TargetOp.getReg();
|
|
|
|
// Try to lookup a hardened version of this register. We retain a reference
|
|
// here as we want to update the map to track any newly computed hardened
|
|
// register.
|
|
unsigned &HardenedTargetReg = AddrRegToHardenedReg[OldTargetReg];
|
|
|
|
// If we don't have a hardened register yet, compute one. Otherwise, just use
|
|
// the already hardened register.
|
|
//
|
|
// FIXME: It is a little suspect that we use partially hardened registers that
|
|
// only feed addresses. The complexity of partial hardening with SHRX
|
|
// continues to pile up. Should definitively measure its value and consider
|
|
// eliminating it.
|
|
if (!HardenedTargetReg)
|
|
HardenedTargetReg = hardenValueInRegister(
|
|
OldTargetReg, *MI.getParent(), MI.getIterator(), MI.getDebugLoc());
|
|
|
|
// Set the target operand to the hardened register.
|
|
TargetOp.setReg(HardenedTargetReg);
|
|
|
|
++NumCallsOrJumpsHardened;
|
|
}
|
|
|
|
INITIALIZE_PASS_BEGIN(X86SpeculativeLoadHardeningPass, PASS_KEY,
|
|
"X86 speculative load hardener", false, false)
|
|
INITIALIZE_PASS_END(X86SpeculativeLoadHardeningPass, PASS_KEY,
|
|
"X86 speculative load hardener", false, false)
|
|
|
|
FunctionPass *llvm::createX86SpeculativeLoadHardeningPass() {
|
|
return new X86SpeculativeLoadHardeningPass();
|
|
}
|