//===-- MipsNaClELFStreamer.cpp - ELF Object Output for Mips NaCl ---------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements MCELFStreamer for Mips NaCl. It emits .o object files // as required by NaCl's SFI sandbox. It inserts address-masking instructions // before dangerous control-flow and memory access instructions. It inserts // address-masking instructions after instructions that change the stack // pointer. It ensures that the mask and the dangerous instruction are always // emitted in the same bundle. It aligns call + branch delay to the bundle end, // so that return address is always aligned to the start of next bundle. // //===----------------------------------------------------------------------===// #include "Mips.h" #include "MipsELFStreamer.h" #include "MipsMCNaCl.h" #include "llvm/MC/MCELFStreamer.h" using namespace llvm; #define DEBUG_TYPE "mips-mc-nacl" namespace { const unsigned IndirectBranchMaskReg = Mips::T6; const unsigned LoadStoreStackMaskReg = Mips::T7; /// Extend the generic MCELFStreamer class so that it can mask dangerous /// instructions. class MipsNaClELFStreamer : public MipsELFStreamer { public: MipsNaClELFStreamer(MCContext &Context, MCAsmBackend &TAB, raw_ostream &OS, MCCodeEmitter *Emitter) : MipsELFStreamer(Context, TAB, OS, Emitter), PendingCall(false) {} ~MipsNaClELFStreamer() {} private: // Whether we started the sandboxing sequence for calls. Calls are bundled // with branch delays and aligned to the bundle end. bool PendingCall; bool isIndirectJump(const MCInst &MI) { if (MI.getOpcode() == Mips::JALR) { // MIPS32r6/MIPS64r6 doesn't have a JR instruction and uses JALR instead. // JALR is an indirect branch if the link register is $0. assert(MI.getOperand(0).isReg()); return MI.getOperand(0).getReg() == Mips::ZERO; } return MI.getOpcode() == Mips::JR; } bool isStackPointerFirstOperand(const MCInst &MI) { return (MI.getNumOperands() > 0 && MI.getOperand(0).isReg() && MI.getOperand(0).getReg() == Mips::SP); } bool isCall(const MCInst &MI, bool *IsIndirectCall) { unsigned Opcode = MI.getOpcode(); *IsIndirectCall = false; switch (Opcode) { default: return false; case Mips::JAL: case Mips::BAL: case Mips::BAL_BR: case Mips::BLTZAL: case Mips::BGEZAL: return true; case Mips::JALR: // JALR is only a call if the link register is not $0. Otherwise it's an // indirect branch. assert(MI.getOperand(0).isReg()); if (MI.getOperand(0).getReg() == Mips::ZERO) return false; *IsIndirectCall = true; return true; } } void emitMask(unsigned AddrReg, unsigned MaskReg, const MCSubtargetInfo &STI) { MCInst MaskInst; MaskInst.setOpcode(Mips::AND); MaskInst.addOperand(MCOperand::CreateReg(AddrReg)); MaskInst.addOperand(MCOperand::CreateReg(AddrReg)); MaskInst.addOperand(MCOperand::CreateReg(MaskReg)); MipsELFStreamer::EmitInstruction(MaskInst, STI); } // Sandbox indirect branch or return instruction by inserting mask operation // before it. void sandboxIndirectJump(const MCInst &MI, const MCSubtargetInfo &STI) { unsigned AddrReg = MI.getOperand(0).getReg(); EmitBundleLock(false); emitMask(AddrReg, IndirectBranchMaskReg, STI); MipsELFStreamer::EmitInstruction(MI, STI); EmitBundleUnlock(); } // Sandbox memory access or SP change. Insert mask operation before and/or // after the instruction. void sandboxLoadStoreStackChange(const MCInst &MI, unsigned AddrIdx, const MCSubtargetInfo &STI, bool MaskBefore, bool MaskAfter) { EmitBundleLock(false); if (MaskBefore) { // Sandbox memory access. unsigned BaseReg = MI.getOperand(AddrIdx).getReg(); emitMask(BaseReg, LoadStoreStackMaskReg, STI); } MipsELFStreamer::EmitInstruction(MI, STI); if (MaskAfter) { // Sandbox SP change. unsigned SPReg = MI.getOperand(0).getReg(); assert((Mips::SP == SPReg) && "Unexpected stack-pointer register."); emitMask(SPReg, LoadStoreStackMaskReg, STI); } EmitBundleUnlock(); } public: /// This function is the one used to emit instruction data into the ELF /// streamer. We override it to mask dangerous instructions. void EmitInstruction(const MCInst &Inst, const MCSubtargetInfo &STI) override { // Sandbox indirect jumps. if (isIndirectJump(Inst)) { if (PendingCall) report_fatal_error("Dangerous instruction in branch delay slot!"); sandboxIndirectJump(Inst, STI); return; } // Sandbox loads, stores and SP changes. unsigned AddrIdx; bool IsStore; bool IsMemAccess = isBasePlusOffsetMemoryAccess(Inst.getOpcode(), &AddrIdx, &IsStore); bool IsSPFirstOperand = isStackPointerFirstOperand(Inst); if (IsMemAccess || IsSPFirstOperand) { bool MaskBefore = (IsMemAccess && baseRegNeedsLoadStoreMask(Inst.getOperand(AddrIdx) .getReg())); bool MaskAfter = IsSPFirstOperand && !IsStore; if (MaskBefore || MaskAfter) { if (PendingCall) report_fatal_error("Dangerous instruction in branch delay slot!"); sandboxLoadStoreStackChange(Inst, AddrIdx, STI, MaskBefore, MaskAfter); return; } // fallthrough } // Sandbox calls by aligning call and branch delay to the bundle end. // For indirect calls, emit the mask before the call. bool IsIndirectCall; if (isCall(Inst, &IsIndirectCall)) { if (PendingCall) report_fatal_error("Dangerous instruction in branch delay slot!"); // Start the sandboxing sequence by emitting call. EmitBundleLock(true); if (IsIndirectCall) { unsigned TargetReg = Inst.getOperand(1).getReg(); emitMask(TargetReg, IndirectBranchMaskReg, STI); } MipsELFStreamer::EmitInstruction(Inst, STI); PendingCall = true; return; } if (PendingCall) { // Finish the sandboxing sequence by emitting branch delay. MipsELFStreamer::EmitInstruction(Inst, STI); EmitBundleUnlock(); PendingCall = false; return; } // None of the sandboxing applies, just emit the instruction. MipsELFStreamer::EmitInstruction(Inst, STI); } }; } // end anonymous namespace namespace llvm { bool isBasePlusOffsetMemoryAccess(unsigned Opcode, unsigned *AddrIdx, bool *IsStore) { if (IsStore) *IsStore = false; switch (Opcode) { default: return false; // Load instructions with base address register in position 1. case Mips::LB: case Mips::LBu: case Mips::LH: case Mips::LHu: case Mips::LW: case Mips::LWC1: case Mips::LDC1: case Mips::LL: case Mips::LL_R6: case Mips::LWL: case Mips::LWR: *AddrIdx = 1; return true; // Store instructions with base address register in position 1. case Mips::SB: case Mips::SH: case Mips::SW: case Mips::SWC1: case Mips::SDC1: case Mips::SWL: case Mips::SWR: *AddrIdx = 1; if (IsStore) *IsStore = true; return true; // Store instructions with base address register in position 2. case Mips::SC: case Mips::SC_R6: *AddrIdx = 2; if (IsStore) *IsStore = true; return true; } } bool baseRegNeedsLoadStoreMask(unsigned Reg) { // The contents of SP and thread pointer register do not require masking. return Reg != Mips::SP && Reg != Mips::T8; } MCELFStreamer *createMipsNaClELFStreamer(MCContext &Context, MCAsmBackend &TAB, raw_ostream &OS, MCCodeEmitter *Emitter, bool RelaxAll) { MipsNaClELFStreamer *S = new MipsNaClELFStreamer(Context, TAB, OS, Emitter); if (RelaxAll) S->getAssembler().setRelaxAll(true); // Set bundle-alignment as required by the NaCl ABI for the target. S->EmitBundleAlignMode(MIPS_NACL_BUNDLE_ALIGN); return S; } }