//===--------- aarch32.cpp - Generic JITLink arm/thumb utilities ----------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // Generic utilities for graphs representing arm/thumb objects. // //===----------------------------------------------------------------------===// #include "llvm/ExecutionEngine/JITLink/aarch32.h" #include "llvm/ADT/StringExtras.h" #include "llvm/BinaryFormat/ELF.h" #include "llvm/ExecutionEngine/JITLink/JITLink.h" #include "llvm/Object/ELFObjectFile.h" #include "llvm/Support/Endian.h" #include "llvm/Support/MathExtras.h" #define DEBUG_TYPE "jitlink" namespace llvm { namespace jitlink { namespace aarch32 { /// Encode 22-bit immediate value for branch instructions without J1J2 range /// extension (formats B T4, BL T1 and BLX T2). /// /// 00000:Imm11H:Imm11L:0 -> [ 00000:Imm11H, 00000:Imm11L ] /// J1^ ^J2 will always be 1 /// HalfWords encodeImmBT4BlT1BlxT2(int64_t Value) { constexpr uint32_t J1J2 = 0x2800; uint32_t Imm11H = (Value >> 12) & 0x07ff; uint32_t Imm11L = (Value >> 1) & 0x07ff; return HalfWords{Imm11H, Imm11L | J1J2}; } /// Decode 22-bit immediate value for branch instructions without J1J2 range /// extension (formats B T4, BL T1 and BLX T2). /// /// [ 00000:Imm11H, 00000:Imm11L ] -> 00000:Imm11H:Imm11L:0 /// J1^ ^J2 will always be 1 /// int64_t decodeImmBT4BlT1BlxT2(uint32_t Hi, uint32_t Lo) { uint32_t Imm11H = Hi & 0x07ff; uint32_t Imm11L = Lo & 0x07ff; return SignExtend64<22>(Imm11H << 12 | Imm11L << 1); } /// Encode 25-bit immediate value for branch instructions with J1J2 range /// extension (formats B T4, BL T1 and BLX T2). /// /// S:I1:I2:Imm10:Imm11:0 -> [ 00000:S:Imm10, 00:J1:0:J2:Imm11 ] /// HalfWords encodeImmBT4BlT1BlxT2_J1J2(int64_t Value) { uint32_t S = (Value >> 14) & 0x0400; uint32_t J1 = (((~(Value >> 10)) ^ (Value >> 11)) & 0x2000); uint32_t J2 = (((~(Value >> 11)) ^ (Value >> 13)) & 0x0800); uint32_t Imm10 = (Value >> 12) & 0x03ff; uint32_t Imm11 = (Value >> 1) & 0x07ff; return HalfWords{S | Imm10, J1 | J2 | Imm11}; } /// Decode 25-bit immediate value for branch instructions with J1J2 range /// extension (formats B T4, BL T1 and BLX T2). /// /// [ 00000:S:Imm10, 00:J1:0:J2:Imm11] -> S:I1:I2:Imm10:Imm11:0 /// int64_t decodeImmBT4BlT1BlxT2_J1J2(uint32_t Hi, uint32_t Lo) { uint32_t S = Hi & 0x0400; uint32_t I1 = ~((Lo ^ (Hi << 3)) << 10) & 0x00800000; uint32_t I2 = ~((Lo ^ (Hi << 1)) << 11) & 0x00400000; uint32_t Imm10 = Hi & 0x03ff; uint32_t Imm11 = Lo & 0x07ff; return SignExtend64<25>(S << 14 | I1 | I2 | Imm10 << 12 | Imm11 << 1); } /// Encode 16-bit immediate value for move instruction formats MOVT T1 and /// MOVW T3. /// /// Imm4:Imm1:Imm3:Imm8 -> [ 00000:i:000000:Imm4, 0:Imm3:0000:Imm8 ] /// HalfWords encodeImmMovtT1MovwT3(uint16_t Value) { uint32_t Imm4 = (Value >> 12) & 0x0f; uint32_t Imm1 = (Value >> 11) & 0x01; uint32_t Imm3 = (Value >> 8) & 0x07; uint32_t Imm8 = Value & 0xff; return HalfWords{Imm1 << 10 | Imm4, Imm3 << 12 | Imm8}; } /// Decode 16-bit immediate value from move instruction formats MOVT T1 and /// MOVW T3. /// /// [ 00000:i:000000:Imm4, 0:Imm3:0000:Imm8 ] -> Imm4:Imm1:Imm3:Imm8 /// uint16_t decodeImmMovtT1MovwT3(uint32_t Hi, uint32_t Lo) { uint32_t Imm4 = Hi & 0x0f; uint32_t Imm1 = (Hi >> 10) & 0x01; uint32_t Imm3 = (Lo >> 12) & 0x07; uint32_t Imm8 = Lo & 0xff; uint32_t Imm16 = Imm4 << 12 | Imm1 << 11 | Imm3 << 8 | Imm8; assert(Imm16 <= 0xffff && "Decoded value out-of-range"); return Imm16; } /// Encode register ID for instruction formats MOVT T1 and MOVW T3. /// /// Rd4 -> [0000000000000000, 0000:Rd4:00000000] /// HalfWords encodeRegMovtT1MovwT3(int64_t Value) { uint32_t Rd4 = (Value & 0x0f) << 8; return HalfWords{0, Rd4}; } /// Decode register ID from instruction formats MOVT T1 and MOVW T3. /// /// [0000000000000000, 0000:Rd4:00000000] -> Rd4 /// int64_t decodeRegMovtT1MovwT3(uint32_t Hi, uint32_t Lo) { uint32_t Rd4 = (Lo >> 8) & 0x0f; return Rd4; } /// 32-bit Thumb instructions are stored as two little-endian halfwords. /// An instruction at address A encodes bytes A+1, A in the first halfword (Hi), /// followed by bytes A+3, A+2 in the second halfword (Lo). struct WritableThumbRelocation { /// Create a writable reference to a Thumb32 fixup. WritableThumbRelocation(char *FixupPtr) : Hi{*reinterpret_cast(FixupPtr)}, Lo{*reinterpret_cast(FixupPtr + 2)} {} support::ulittle16_t &Hi; // First halfword support::ulittle16_t &Lo; // Second halfword }; struct ThumbRelocation { /// Create a read-only reference to a Thumb32 fixup. ThumbRelocation(const char *FixupPtr) : Hi{*reinterpret_cast(FixupPtr)}, Lo{*reinterpret_cast(FixupPtr + 2)} {} /// Create a read-only Thumb32 fixup from a writeable one. ThumbRelocation(WritableThumbRelocation &Writable) : Hi{Writable.Hi}, Lo(Writable.Lo) {} const support::ulittle16_t &Hi; // First halfword const support::ulittle16_t &Lo; // Second halfword }; Error makeUnexpectedOpcodeError(const LinkGraph &G, const ThumbRelocation &R, Edge::Kind Kind) { return make_error( formatv("Invalid opcode [ 0x{0:x4}, 0x{1:x4} ] for relocation: {2}", static_cast(R.Hi), static_cast(R.Lo), G.getEdgeKindName(Kind))); } template bool checkOpcode(const ThumbRelocation &R) { uint16_t Hi = R.Hi & FixupInfo::OpcodeMask.Hi; uint16_t Lo = R.Lo & FixupInfo::OpcodeMask.Lo; return Hi == FixupInfo::Opcode.Hi && Lo == FixupInfo::Opcode.Lo; } template bool checkRegister(const ThumbRelocation &R, HalfWords Reg) { uint16_t Hi = R.Hi & FixupInfo::RegMask.Hi; uint16_t Lo = R.Lo & FixupInfo::RegMask.Lo; return Hi == Reg.Hi && Lo == Reg.Lo; } template void writeRegister(WritableThumbRelocation &R, HalfWords Reg) { static constexpr HalfWords Mask = FixupInfo::RegMask; assert((Mask.Hi & Reg.Hi) == Reg.Hi && (Mask.Hi & Reg.Hi) == Reg.Hi && "Value bits exceed bit range of given mask"); R.Hi = (R.Hi & ~Mask.Hi) | Reg.Hi; R.Lo = (R.Lo & ~Mask.Lo) | Reg.Lo; } template void writeImmediate(WritableThumbRelocation &R, HalfWords Imm) { static constexpr HalfWords Mask = FixupInfo::ImmMask; assert((Mask.Hi & Imm.Hi) == Imm.Hi && (Mask.Hi & Imm.Hi) == Imm.Hi && "Value bits exceed bit range of given mask"); R.Hi = (R.Hi & ~Mask.Hi) | Imm.Hi; R.Lo = (R.Lo & ~Mask.Lo) | Imm.Lo; } Expected readAddendData(LinkGraph &G, Block &B, const Edge &E) { support::endianness Endian = G.getEndianness(); assert(Endian != support::native && "Declare as little or big explicitly"); Edge::Kind Kind = E.getKind(); const char *BlockWorkingMem = B.getContent().data(); const char *FixupPtr = BlockWorkingMem + E.getOffset(); switch (Kind) { case Data_Delta32: case Data_Pointer32: return SignExtend64<32>(support::endian::read32(FixupPtr, Endian)); default: return make_error( "In graph " + G.getName() + ", section " + B.getSection().getName() + " can not read implicit addend for aarch32 edge kind " + G.getEdgeKindName(E.getKind())); } } Expected readAddendArm(LinkGraph &G, Block &B, const Edge &E) { Edge::Kind Kind = E.getKind(); switch (Kind) { case Arm_Call: return make_error( "Addend extraction for relocation type not yet implemented: " + StringRef(G.getEdgeKindName(Kind))); default: return make_error( "In graph " + G.getName() + ", section " + B.getSection().getName() + " can not read implicit addend for aarch32 edge kind " + G.getEdgeKindName(E.getKind())); } } Expected readAddendThumb(LinkGraph &G, Block &B, const Edge &E, const ArmConfig &ArmCfg) { ThumbRelocation R(B.getContent().data() + E.getOffset()); Edge::Kind Kind = E.getKind(); switch (Kind) { case Thumb_Call: if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); return LLVM_LIKELY(ArmCfg.J1J2BranchEncoding) ? decodeImmBT4BlT1BlxT2_J1J2(R.Hi, R.Lo) : decodeImmBT4BlT1BlxT2(R.Hi, R.Lo); case Thumb_Jump24: if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); if (R.Lo & FixupInfo::LoBitConditional) return make_error("Relocation expects an unconditional " "B.W branch instruction: " + StringRef(G.getEdgeKindName(Kind))); return LLVM_LIKELY(ArmCfg.J1J2BranchEncoding) ? decodeImmBT4BlT1BlxT2_J1J2(R.Hi, R.Lo) : decodeImmBT4BlT1BlxT2(R.Hi, R.Lo); case Thumb_MovwAbsNC: if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); // Initial addend is interpreted as a signed value return SignExtend64<16>(decodeImmMovtT1MovwT3(R.Hi, R.Lo)); case Thumb_MovtAbs: if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); // Initial addend is interpreted as a signed value return SignExtend64<16>(decodeImmMovtT1MovwT3(R.Hi, R.Lo)); default: return make_error( "In graph " + G.getName() + ", section " + B.getSection().getName() + " can not read implicit addend for aarch32 edge kind " + G.getEdgeKindName(E.getKind())); } } Error applyFixupData(LinkGraph &G, Block &B, const Edge &E) { using namespace support; char *BlockWorkingMem = B.getAlreadyMutableContent().data(); char *FixupPtr = BlockWorkingMem + E.getOffset(); auto Write32 = [FixupPtr, Endian = G.getEndianness()](int64_t Value) { assert(Endian != native && "Must be explicit: little or big"); assert(isInt<32>(Value) && "Must be in signed 32-bit range"); uint32_t Imm = static_cast(Value); if (LLVM_LIKELY(Endian == little)) endian::write32(FixupPtr, Imm); else endian::write32(FixupPtr, Imm); }; Edge::Kind Kind = E.getKind(); uint64_t FixupAddress = (B.getAddress() + E.getOffset()).getValue(); int64_t Addend = E.getAddend(); Symbol &TargetSymbol = E.getTarget(); uint64_t TargetAddress = TargetSymbol.getAddress().getValue(); assert(!TargetSymbol.hasTargetFlags(ThumbSymbol)); // Regular data relocations have size 4, alignment 1 and write the full 32-bit // result to the place; no need for overflow checking. There are three // exceptions: R_ARM_ABS8, R_ARM_ABS16, R_ARM_PREL31 switch (Kind) { case Data_Delta32: { int64_t Value = TargetAddress - FixupAddress + Addend; if (!isInt<32>(Value)) return makeTargetOutOfRangeError(G, B, E); Write32(Value); return Error::success(); } case Data_Pointer32: { int64_t Value = TargetAddress + Addend; if (!isInt<32>(Value)) return makeTargetOutOfRangeError(G, B, E); Write32(Value); return Error::success(); } default: return make_error( "In graph " + G.getName() + ", section " + B.getSection().getName() + " encountered unfixable aarch32 edge kind " + G.getEdgeKindName(E.getKind())); } } Error applyFixupArm(LinkGraph &G, Block &B, const Edge &E) { Edge::Kind Kind = E.getKind(); switch (Kind) { case Arm_Call: return make_error( "Fix-up for relocation type not yet implemented: " + StringRef(G.getEdgeKindName(Kind))); default: return make_error( "In graph " + G.getName() + ", section " + B.getSection().getName() + " encountered unfixable aarch32 edge kind " + G.getEdgeKindName(E.getKind())); } } Error applyFixupThumb(LinkGraph &G, Block &B, const Edge &E, const ArmConfig &ArmCfg) { WritableThumbRelocation R(B.getAlreadyMutableContent().data() + E.getOffset()); Edge::Kind Kind = E.getKind(); uint64_t FixupAddress = (B.getAddress() + E.getOffset()).getValue(); int64_t Addend = E.getAddend(); Symbol &TargetSymbol = E.getTarget(); uint64_t TargetAddress = TargetSymbol.getAddress().getValue(); if (TargetSymbol.hasTargetFlags(ThumbSymbol)) TargetAddress |= 0x01; switch (Kind) { case Thumb_Jump24: { if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); if (R.Lo & FixupInfo::LoBitConditional) return make_error("Relocation expects an unconditional " "B.W branch instruction: " + StringRef(G.getEdgeKindName(Kind))); if (!(TargetSymbol.hasTargetFlags(ThumbSymbol))) return make_error("Branch relocation needs interworking " "stub when bridging to ARM: " + StringRef(G.getEdgeKindName(Kind))); int64_t Value = TargetAddress - FixupAddress + Addend; if (LLVM_LIKELY(ArmCfg.J1J2BranchEncoding)) { if (!isInt<25>(Value)) return makeTargetOutOfRangeError(G, B, E); writeImmediate(R, encodeImmBT4BlT1BlxT2_J1J2(Value)); } else { if (!isInt<22>(Value)) return makeTargetOutOfRangeError(G, B, E); writeImmediate(R, encodeImmBT4BlT1BlxT2(Value)); } return Error::success(); } case Thumb_Call: { if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); int64_t Value = TargetAddress - FixupAddress + Addend; // The call instruction itself is Thumb. The call destination can either be // Thumb or Arm. We use BL to stay in Thumb and BLX to change to Arm. bool TargetIsArm = !TargetSymbol.hasTargetFlags(ThumbSymbol); bool InstrIsBlx = (R.Lo & FixupInfo::LoBitNoBlx) == 0; if (TargetIsArm != InstrIsBlx) { if (LLVM_LIKELY(TargetIsArm)) { // Change opcode BL -> BLX and fix range value (account for 4-byte // aligned destination while instruction may only be 2-byte aligned // and clear Thumb bit). R.Lo = R.Lo & ~FixupInfo::LoBitNoBlx; R.Lo = R.Lo & ~FixupInfo::LoBitH; Value = alignTo(Value, 4); } else { // Change opcode BLX -> BL and set Thumb bit R.Lo = R.Lo & ~FixupInfo::LoBitNoBlx; Value |= 0x01; } } if (LLVM_LIKELY(ArmCfg.J1J2BranchEncoding)) { if (!isInt<25>(Value)) return makeTargetOutOfRangeError(G, B, E); writeImmediate(R, encodeImmBT4BlT1BlxT2_J1J2(Value)); } else { if (!isInt<22>(Value)) return makeTargetOutOfRangeError(G, B, E); writeImmediate(R, encodeImmBT4BlT1BlxT2(Value)); } assert(((R.Lo & FixupInfo::LoBitNoBlx) || (R.Lo & FixupInfo::LoBitH) == 0) && "Opcode BLX implies H bit is clear (avoid UB in BLX T2)"); return Error::success(); } case Thumb_MovwAbsNC: { if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); uint16_t Value = (TargetAddress + Addend) & 0xffff; writeImmediate(R, encodeImmMovtT1MovwT3(Value)); return Error::success(); } case Thumb_MovtAbs: { if (!checkOpcode(R)) return makeUnexpectedOpcodeError(G, R, Kind); uint16_t Value = ((TargetAddress + Addend) >> 16) & 0xffff; writeImmediate(R, encodeImmMovtT1MovwT3(Value)); return Error::success(); } default: return make_error( "In graph " + G.getName() + ", section " + B.getSection().getName() + " encountered unfixable aarch32 edge kind " + G.getEdgeKindName(E.getKind())); } } const uint8_t Thumbv7ABS[] = { 0x40, 0xf2, 0x00, 0x0c, // movw r12, #0x0000 ; lower 16-bit 0xc0, 0xf2, 0x00, 0x0c, // movt r12, #0x0000 ; upper 16-bit 0x60, 0x47 // bx r12 }; template <> Symbol &StubsManager::createEntry(LinkGraph &G, Symbol &Target) { constexpr uint64_t Alignment = 4; Block &B = addStub(G, Thumbv7ABS, Alignment); LLVM_DEBUG({ const char *StubPtr = B.getContent().data(); HalfWords Reg12 = encodeRegMovtT1MovwT3(12); assert(checkRegister(StubPtr, Reg12) && checkRegister(StubPtr + 4, Reg12) && "Linker generated stubs may only corrupt register r12 (IP)"); }); B.addEdge(Thumb_MovwAbsNC, 0, Target, 0); B.addEdge(Thumb_MovtAbs, 4, Target, 0); Symbol &Stub = G.addAnonymousSymbol(B, 0, B.getSize(), true, false); Stub.setTargetFlags(ThumbSymbol); return Stub; } const char *getEdgeKindName(Edge::Kind K) { #define KIND_NAME_CASE(K) \ case K: \ return #K; switch (K) { KIND_NAME_CASE(Data_Delta32) KIND_NAME_CASE(Arm_Call) KIND_NAME_CASE(Thumb_Call) KIND_NAME_CASE(Thumb_Jump24) KIND_NAME_CASE(Thumb_MovwAbsNC) KIND_NAME_CASE(Thumb_MovtAbs) default: return getGenericEdgeKindName(K); } #undef KIND_NAME_CASE } const char *getCPUArchName(ARMBuildAttrs::CPUArch K) { #define CPUARCH_NAME_CASE(K) \ case K: \ return #K; using namespace ARMBuildAttrs; switch (K) { CPUARCH_NAME_CASE(Pre_v4) CPUARCH_NAME_CASE(v4) CPUARCH_NAME_CASE(v4T) CPUARCH_NAME_CASE(v5T) CPUARCH_NAME_CASE(v5TE) CPUARCH_NAME_CASE(v5TEJ) CPUARCH_NAME_CASE(v6) CPUARCH_NAME_CASE(v6KZ) CPUARCH_NAME_CASE(v6T2) CPUARCH_NAME_CASE(v6K) CPUARCH_NAME_CASE(v7) CPUARCH_NAME_CASE(v6_M) CPUARCH_NAME_CASE(v6S_M) CPUARCH_NAME_CASE(v7E_M) CPUARCH_NAME_CASE(v8_A) CPUARCH_NAME_CASE(v8_R) CPUARCH_NAME_CASE(v8_M_Base) CPUARCH_NAME_CASE(v8_M_Main) CPUARCH_NAME_CASE(v8_1_M_Main) CPUARCH_NAME_CASE(v9_A) } llvm_unreachable("Missing CPUArch in switch?"); #undef CPUARCH_NAME_CASE } } // namespace aarch32 } // namespace jitlink } // namespace llvm