// Licensed to the .NET Foundation under one or more agreements. // The .NET Foundation licenses this file to you under the MIT license. // See the LICENSE file in the project root for more information. /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX UnwindInfo XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ #include "jitpch.h" #ifdef _MSC_VER #pragma hdrstop #endif #if defined(_TARGET_ARM64_) void Compiler::unwindPush(regNumber reg) { unreached(); // use one of the unwindSaveReg* functions instead. } void Compiler::unwindAllocStack(unsigned size) { UnwindInfo* pu = &funCurrentFunc()->uwi; assert(size % 16 == 0); unsigned x = size / 16; if (x <= 0x1F) { // alloc_s: 000xxxxx: allocate small stack with size < 128 (2^5 * 16) // TODO-Review: should say size < 512 pu->AddCode((BYTE)x); } else if (x <= 0x7FF) { // alloc_m: 11000xxx | xxxxxxxx: allocate large stack with size < 16k (2^11 * 16) // TODO-Review: should say size < 32K pu->AddCode(0xC0 | (BYTE)(x >> 8), (BYTE)x); } else { // alloc_l: 11100000 | xxxxxxxx | xxxxxxxx | xxxxxxxx : allocate large stack with size < 256M (2^24 * 16) // // For large stack size, the most significant bits // are stored first (and next to the opCode) per the unwind spec. pu->AddCode(0xE0, (BYTE)(x >> 16), (BYTE)(x >> 8), (BYTE)x); } } void Compiler::unwindSetFrameReg(regNumber reg, unsigned offset) { UnwindInfo* pu = &funCurrentFunc()->uwi; if (offset == 0) { assert(reg == REG_FP); // set_fp: 11100001 : set up r29 : with : mov r29, sp pu->AddCode(0xE1); } else { // add_fp: 11100010 | xxxxxxxx : set up r29 with : add r29, sp, #x * 8 assert(reg == REG_FP); assert((offset % 8) == 0); unsigned x = offset / 8; assert(x <= 0xFF); pu->AddCode(0xE2, (BYTE)x); } } void Compiler::unwindSaveReg(regNumber reg, unsigned offset) { unreached(); } void Compiler::unwindNop() { UnwindInfo* pu = &funCurrentFunc()->uwi; #ifdef DEBUG if (verbose) { printf("unwindNop: adding NOP\n"); } #endif INDEBUG(pu->uwiAddingNOP = true); // nop: 11100011: no unwind operation is required. pu->AddCode(0xE3); INDEBUG(pu->uwiAddingNOP = false); } // unwindSaveRegPair: save a register pair to the stack at the specified byte offset (which must be positive, // a multiple of 8 from 0 to 504). Note that for ARM64 unwind codes, reg2 must be exactly one register higher than reg1, // except for the case of a pair including LR, in which case reg1 must be either FP or R19/R21/R23/R25/R27 (note that it // can't be even, such as R20, because that would mean R19 was saved separately, instead of saving as a pair, // which we should do instead). void Compiler::unwindSaveRegPair(regNumber reg1, regNumber reg2, int offset) { UnwindInfo* pu = &funCurrentFunc()->uwi; // stp reg1, reg2, [sp, #offset] // offset for store pair in prolog must be positive and a multiple of 8. assert(0 <= offset && offset <= 504); assert((offset % 8) == 0); int z = offset / 8; assert(0 <= z && z <= 0x3F); if (reg1 == REG_FP) { // save_fplr: 01zzzzzz: save pair at [sp+#Z*8], offset <= 504 assert(reg2 == REG_LR); pu->AddCode(0x40 | (BYTE)z); } else if (reg2 == REG_LR) { // save_lrpair: 1101011x | xxzzzzzz: save pair at [sp + #Z * 8], offset <= 504 assert(REG_R19 <= reg1 && // first legal pair: R19, LR reg1 <= REG_R27); // last legal pair: R27, LR BYTE x = (BYTE)(reg1 - REG_R19); assert((x % 2) == 0); // only legal reg1: R19, R21, R23, R25, R27 x /= 2; assert(0 <= x && x <= 0x7); pu->AddCode(0xD6 | (BYTE)(x >> 2), (BYTE)(x << 6) | (BYTE)z); } else if (emitter::isGeneralRegister(reg1)) { // save_regp: 110010xx | xxzzzzzz: save r(19 + #X) pair at [sp + #Z * 8], offset <= 504 assert(REG_NEXT(reg1) == reg2); assert(REG_R19 <= reg1 && // first legal pair: R19, R20 reg1 <= REG_R27); // last legal pair: R27, R28 (FP is never saved without LR) BYTE x = (BYTE)(reg1 - REG_R19); assert(0 <= x && x <= 0xF); pu->AddCode(0xC8 | (BYTE)(x >> 2), (BYTE)(x << 6) | (BYTE)z); } else { // save_fregp: 1101100x | xxzzzzzz : save pair d(8 + #X) at [sp + #Z * 8], offset <= 504 assert(REG_NEXT(reg1) == reg2); assert(REG_V8 <= reg1 && // first legal pair: V8, V9 reg1 <= REG_V14); // last legal pair: V14, V15 BYTE x = (BYTE)(reg1 - REG_V8); assert(0 <= x && x <= 0x7); pu->AddCode(0xD8 | (BYTE)(x >> 2), (BYTE)(x << 6) | (BYTE)z); } } // unwindSaveRegPairPreindexed: save a register pair to the stack at the specified byte offset (which must be negative, // a multiple of 8 from -512 to -8). Note that for ARM64 unwind codes, reg2 must be exactly one register higher than // reg1. void Compiler::unwindSaveRegPairPreindexed(regNumber reg1, regNumber reg2, int offset) { UnwindInfo* pu = &funCurrentFunc()->uwi; // stp reg1, reg2, [sp, #offset]! // pre-indexed offset in prolog must be negative and a multiple of 8. assert(offset < 0); assert((offset % 8) == 0); if (reg1 == REG_FP) { // save_fplr_x: 10zzzzzz: save pair at [sp-(#Z+1)*8]!, pre-indexed offset >= -512 assert(-512 <= offset); int z = (-offset) / 8 - 1; assert(0 <= z && z <= 0x3F); assert(reg2 == REG_LR); pu->AddCode(0x80 | (BYTE)z); } else if ((reg1 == REG_R19) && (-256 <= offset)) // If the offset is between -512 and -256, we use the save_regp_x unwind code. { // save_r19r20_x: 001zzzzz: save pair at [sp-#Z*8]!, pre-indexed offset >= -248 // NOTE: I'm not sure why we allow Z==0 here; seems useless, and the calculation of offset is different from the // other cases. int z = (-offset) / 8; assert(0 <= z && z <= 0x1F); assert(reg2 == REG_R20); pu->AddCode(0x20 | (BYTE)z); } else if (emitter::isGeneralRegister(reg1)) { // save_regp_x: 110011xx | xxzzzzzz: save pair r(19 + #X) at [sp - (#Z + 1) * 8]!, pre-indexed offset >= -512 assert(-512 <= offset); int z = (-offset) / 8 - 1; assert(0 <= z && z <= 0x3F); assert(REG_NEXT(reg1) == reg2); assert(REG_R19 <= reg1 && // first legal pair: R19, R20 reg1 <= REG_R27); // last legal pair: R27, R28 (FP is never saved without LR) BYTE x = (BYTE)(reg1 - REG_R19); assert(0 <= x && x <= 0xF); pu->AddCode(0xCC | (BYTE)(x >> 2), (BYTE)(x << 6) | (BYTE)z); } else { // save_fregp_x: 1101101x | xxzzzzzz : save pair d(8 + #X), at [sp - (#Z + 1) * 8]!, pre-indexed offset >= -512 assert(-512 <= offset); int z = (-offset) / 8 - 1; assert(0 <= z && z <= 0x3F); assert(REG_NEXT(reg1) == reg2); assert(REG_V8 <= reg1 && // first legal pair: V8, V9 reg1 <= REG_V14); // last legal pair: V14, V15 BYTE x = (BYTE)(reg1 - REG_V8); assert(0 <= x && x <= 0x7); pu->AddCode(0xDA | (BYTE)(x >> 2), (BYTE)(x << 6) | (BYTE)z); } } void Compiler::unwindSaveReg(regNumber reg, int offset) { UnwindInfo* pu = &funCurrentFunc()->uwi; // str reg, [sp, #offset] // offset for store in prolog must be positive and a multiple of 8. assert(0 <= offset && offset <= 504); assert((offset % 8) == 0); int z = offset / 8; assert(0 <= z && z <= 0x3F); if (emitter::isGeneralRegister(reg)) { // save_reg: 110100xx | xxzzzzzz: save reg r(19 + #X) at [sp + #Z * 8], offset <= 504 assert(REG_R19 <= reg && // first legal register: R19 reg <= REG_LR); // last legal register: LR BYTE x = (BYTE)(reg - REG_R19); assert(0 <= x && x <= 0xF); pu->AddCode(0xD0 | (BYTE)(x >> 2), (BYTE)(x << 6) | (BYTE)z); } else { // save_freg: 1101110x | xxzzzzzz : save reg d(8 + #X) at [sp + #Z * 8], offset <= 504 assert(REG_V8 <= reg && // first legal register: V8 reg <= REG_V15); // last legal register: V15 BYTE x = (BYTE)(reg - REG_V8); assert(0 <= x && x <= 0x7); pu->AddCode(0xDC | (BYTE)(x >> 2), (BYTE)(x << 6) | (BYTE)z); } } void Compiler::unwindSaveRegPreindexed(regNumber reg, int offset) { UnwindInfo* pu = &funCurrentFunc()->uwi; // str reg, [sp, #offset]! // pre-indexed offset in prolog must be negative and a multiple of 8. assert(-256 <= offset && offset < 0); assert((offset % 8) == 0); int z = (-offset) / 8 - 1; assert(0 <= z && z <= 0x1F); if (emitter::isGeneralRegister(reg)) { // save_reg_x: 1101010x | xxxzzzzz: save reg r(19 + #X) at [sp - (#Z + 1) * 8]!, pre-indexed offset >= -256 assert(REG_R19 <= reg && // first legal register: R19 reg <= REG_LR); // last legal register: LR BYTE x = (BYTE)(reg - REG_R19); assert(0 <= x && x <= 0xF); pu->AddCode(0xD4 | (BYTE)(x >> 3), (BYTE)(x << 5) | (BYTE)z); } else { // save_freg_x: 11011110 | xxxzzzzz : save reg d(8 + #X) at [sp - (#Z + 1) * 8]!, pre - indexed offset >= -256 assert(REG_V8 <= reg && // first legal register: V8 reg <= REG_V15); // last legal register: V15 BYTE x = (BYTE)(reg - REG_V8); assert(0 <= x && x <= 0x7); pu->AddCode(0xDE, (BYTE)(x << 5) | (BYTE)z); } } void Compiler::unwindSaveNext() { UnwindInfo* pu = &funCurrentFunc()->uwi; // We're saving the next register pair. The caller is responsible for ensuring this is correct! // save_next: 11100110 : save next non - volatile Int or FP register pair. pu->AddCode(0xE6); } void Compiler::unwindReturn(regNumber reg) { // Nothing to do; we will always have at least one trailing "end" opcode in our padding. } /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX Unwind Info Debug helpers XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ #ifdef DEBUG // Return the size of the unwind code (from 1 to 4 bytes), given the first byte of the unwind bytes unsigned GetUnwindSizeFromUnwindHeader(BYTE b1) { static BYTE s_UnwindSize[256] = { // array of unwind sizes, in bytes (as specified in the ARM unwind specification) 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 00-0F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 10-1F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 20-2F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 30-3F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 40-4F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 50-5F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 60-6F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 70-7F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 80-8F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // 90-9F 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // A0-AF 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // B0-BF 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, // C0-CF 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 1, // D0-DF 4, 1, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, // E0-EF 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 // F0-FF }; unsigned size = s_UnwindSize[b1]; assert(1 <= size && size <= 4); return size; } #endif // DEBUG /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX Unwind Info Support Classes XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ /////////////////////////////////////////////////////////////////////////////// // // UnwindCodesBase // /////////////////////////////////////////////////////////////////////////////// #ifdef DEBUG // Walk the prolog codes and calculate the size of the prolog or epilog, in bytes. unsigned UnwindCodesBase::GetCodeSizeFromUnwindCodes(bool isProlog) { BYTE* pCodesStart = GetCodes(); BYTE* pCodes = pCodesStart; unsigned size = 0; for (;;) { BYTE b1 = *pCodes; if (IsEndCode(b1)) { break; // We hit an "end" code; we're done } size += 4; // All codes represent 4 byte instructions. pCodes += GetUnwindSizeFromUnwindHeader(b1); assert(pCodes - pCodesStart < 256); // 255 is the absolute maximum number of code bytes allowed } return size; } #endif // DEBUG /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX Debug dumpers XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ #ifdef DEBUG // start is 0-based index from LSB, length is number of bits DWORD ExtractBits(DWORD dw, DWORD start, DWORD length) { return (dw >> start) & ((1 << length) - 1); } // Dump the unwind data. // Arguments: // isHotCode: true if this unwind data is for the hot section // startOffset: byte offset of the code start that this unwind data represents // endOffset: byte offset of the code end that this unwind data represents // pHeader: pointer to the unwind data blob // unwindBlockSize: size in bytes of the unwind data blob void DumpUnwindInfo(Compiler* comp, bool isHotCode, UNATIVE_OFFSET startOffset, UNATIVE_OFFSET endOffset, const BYTE* const pHeader, ULONG unwindBlockSize) { printf("Unwind Info%s:\n", isHotCode ? "" : " COLD"); // pHeader is not guaranteed to be aligned. We put four 0xFF end codes at the end // to provide padding, and round down to get a multiple of 4 bytes in size. DWORD UNALIGNED* pdw = (DWORD UNALIGNED*)pHeader; DWORD dw; dw = *pdw++; DWORD codeWords = ExtractBits(dw, 27, 5); DWORD epilogCount = ExtractBits(dw, 22, 5); DWORD EBit = ExtractBits(dw, 21, 1); DWORD XBit = ExtractBits(dw, 20, 1); DWORD Vers = ExtractBits(dw, 18, 2); DWORD functionLength = ExtractBits(dw, 0, 18); printf(" >> Start offset : 0x%06x (not in unwind data)\n", comp->dspOffset(startOffset)); printf(" >> End offset : 0x%06x (not in unwind data)\n", comp->dspOffset(endOffset)); printf(" Code Words : %u\n", codeWords); printf(" Epilog Count : %u\n", epilogCount); printf(" E bit : %u\n", EBit); printf(" X bit : %u\n", XBit); printf(" Vers : %u\n", Vers); printf(" Function Length : %u (0x%05x) Actual length = %u (0x%06x)\n", functionLength, functionLength, functionLength * 4, functionLength * 4); assert(functionLength * 4 == endOffset - startOffset); if (codeWords == 0 && epilogCount == 0) { // We have an extension word specifying a larger number of Code Words or Epilog Counts // than can be specified in the header word. dw = *pdw++; codeWords = ExtractBits(dw, 16, 8); epilogCount = ExtractBits(dw, 0, 16); assert((dw & 0xF0000000) == 0); // reserved field should be zero printf(" ---- Extension word ----\n"); printf(" Extended Code Words : %u\n", codeWords); printf(" Extended Epilog Count : %u\n", epilogCount); } bool epilogStartAt[1024] = {}; // One byte per possible epilog start index; initialized to false if (EBit == 0) { // We have an array of epilog scopes printf(" ---- Epilog scopes ----\n"); if (epilogCount == 0) { printf(" No epilogs\n"); } else { for (DWORD scope = 0; scope < epilogCount; scope++) { dw = *pdw++; DWORD epilogStartOffset = ExtractBits(dw, 0, 18); DWORD res = ExtractBits(dw, 18, 4); DWORD epilogStartIndex = ExtractBits(dw, 22, 10); // Note that epilogStartOffset for a funclet is the offset from the beginning // of the current funclet, not the offset from the beginning of the main function. // To help find it when looking through JitDump output, also show the offset from // the beginning of the main function. DWORD epilogStartOffsetFromMainFunctionBegin = epilogStartOffset * 4 + startOffset; assert(res == 0); printf(" ---- Scope %d\n", scope); printf(" Epilog Start Offset : %u (0x%05x) Actual offset = %u (0x%06x) Offset from main " "function begin = %u (0x%06x)\n", comp->dspOffset(epilogStartOffset), comp->dspOffset(epilogStartOffset), comp->dspOffset(epilogStartOffset * 4), comp->dspOffset(epilogStartOffset * 4), comp->dspOffset(epilogStartOffsetFromMainFunctionBegin), comp->dspOffset(epilogStartOffsetFromMainFunctionBegin)); printf(" Epilog Start Index : %u (0x%02x)\n", epilogStartIndex, epilogStartIndex); epilogStartAt[epilogStartIndex] = true; // an epilog starts at this offset in the unwind codes } } } else { printf(" --- One epilog, unwind codes at %u\n", epilogCount); assert(epilogCount < ArrLen(epilogStartAt)); epilogStartAt[epilogCount] = true; // the one and only epilog starts its unwind codes at this offset } // Dump the unwind codes printf(" ---- Unwind codes ----\n"); DWORD countOfUnwindCodes = codeWords * 4; PBYTE pUnwindCode = (PBYTE)pdw; BYTE b1, b2, b3, b4; DWORD x, z; for (DWORD i = 0; i < countOfUnwindCodes; i++) { // Does this byte start an epilog sequence? If so, note that fact. if (epilogStartAt[i]) { printf(" ---- Epilog start at index %u ----\n", i); } b1 = *pUnwindCode++; if ((b1 & 0xE0) == 0) { // alloc_s: 000xxxxx: allocate small stack with size < 128 (2^5 * 16) // TODO-Review:should say size < 512 x = b1 & 0x1F; printf(" %02X alloc_s #%u (0x%02X); sub sp, sp, #%u (0x%03X)\n", b1, x, x, x * 16, x * 16); } else if ((b1 & 0xE0) == 0x20) { // save_r19r20_x: 001zzzzz: save pair at [sp-#Z*8]!, pre-indexed offset >= -248 z = b1 & 0x1F; printf(" %02X save_r19r20_x #%u (0x%02X); stp %s, %s, [sp, #-%u]!\n", b1, z, z, getRegName(REG_R19), getRegName(REG_R20), z * 8); } else if ((b1 & 0xC0) == 0x40) { // save_fplr: 01zzzzzz: save pair at [sp+#Z*8], offset <= 504 z = b1 & 0x3F; printf(" %02X save_fplr #%u (0x%02X); stp %s, %s, [sp, #%u]\n", b1, z, z, getRegName(REG_FP), getRegName(REG_LR), z * 8); } else if ((b1 & 0xC0) == 0x80) { // save_fplr_x: 10zzzzzz: save pair at [sp-(#Z+1)*8]!, pre-indexed offset >= -512 z = b1 & 0x3F; printf(" %02X save_fplr_x #%u (0x%02X); stp %s, %s, [sp, #-%u]!\n", b1, z, z, getRegName(REG_FP), getRegName(REG_LR), (z + 1) * 8); } else if ((b1 & 0xF8) == 0xC0) { // alloc_m: 11000xxx | xxxxxxxx: allocate large stack with size < 16k (2^11 * 16) // TODO-Review: should save size < 32K assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x7) << 8) | (DWORD)b2; printf(" %02X %02X alloc_m #%u (0x%03X); sub sp, sp, #%u (0x%04X)\n", b1, b2, x, x, x * 16, x * 16); } else if ((b1 & 0xFC) == 0xC8) { // save_regp: 110010xx | xxzzzzzz: save r(19 + #X) pair at [sp + #Z * 8], offset <= 504 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x3) << 2) | (DWORD)(b2 >> 6); z = (DWORD)(b2 & 0x3F); printf(" %02X %02X save_regp X#%u Z#%u (0x%02X); stp %s, %s, [sp, #%u]\n", b1, b2, x, z, z, getRegName(REG_R19 + x), getRegName(REG_R19 + x + 1), z * 8); } else if ((b1 & 0xFC) == 0xCC) { // save_regp_x: 110011xx | xxzzzzzz: save pair r(19 + #X) at [sp - (#Z + 1) * 8]!, pre-indexed offset >= // -512 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x3) << 2) | (DWORD)(b2 >> 6); z = (DWORD)(b2 & 0x3F); printf(" %02X %02X save_regp_x X#%u Z#%u (0x%02X); stp %s, %s, [sp, #-%u]!\n", b1, b2, x, z, z, getRegName(REG_R19 + x), getRegName(REG_R19 + x + 1), (z + 1) * 8); } else if ((b1 & 0xFC) == 0xD0) { // save_reg: 110100xx | xxzzzzzz: save reg r(19 + #X) at [sp + #Z * 8], offset <= 504 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x3) << 2) | (DWORD)(b2 >> 6); z = (DWORD)(b2 & 0x3F); printf(" %02X %02X save_reg X#%u Z#%u (0x%02X); str %s, [sp, #%u]\n", b1, b2, x, z, z, getRegName(REG_R19 + x), z * 8); } else if ((b1 & 0xFE) == 0xD4) { // save_reg_x: 1101010x | xxxzzzzz: save reg r(19 + #X) at [sp - (#Z + 1) * 8]!, pre-indexed offset >= -256 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x1) << 3) | (DWORD)(b2 >> 5); z = (DWORD)(b2 & 0x1F); printf(" %02X %02X save_reg_x X#%u Z#%u (0x%02X); str %s, [sp, #-%u]!\n", b1, b2, x, z, z, getRegName(REG_R19 + x), (z + 1) * 8); } else if ((b1 & 0xFE) == 0xD6) { // save_lrpair: 1101011x | xxzzzzzz: save pair at [sp + #Z * 8], offset <= 504 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x1) << 2) | (DWORD)(b2 >> 6); z = (DWORD)(b2 & 0x3F); printf(" %02X %02X save_lrpair X#%u Z#%u (0x%02X); stp %s, %s, [sp, #%u]\n", b1, b2, x, z, z, getRegName(REG_R19 + 2 * x), getRegName(REG_LR), z * 8); } else if ((b1 & 0xFE) == 0xD8) { // save_fregp: 1101100x | xxzzzzzz : save pair d(8 + #X) at [sp + #Z * 8], offset <= 504 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x1) << 2) | (DWORD)(b2 >> 6); z = (DWORD)(b2 & 0x3F); printf(" %02X %02X save_fregp X#%u Z#%u (0x%02X); stp %s, %s, [sp, #%u]\n", b1, b2, x, z, z, getRegName(REG_V8 + x, true), getRegName(REG_V8 + x + 1, true), z * 8); } else if ((b1 & 0xFE) == 0xDA) { // save_fregp_x: 1101101x | xxzzzzzz : save pair d(8 + #X), at [sp - (#Z + 1) * 8]!, pre-indexed offset >= // -512 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x1) << 2) | (DWORD)(b2 >> 6); z = (DWORD)(b2 & 0x3F); printf(" %02X %02X save_fregp_x X#%u Z#%u (0x%02X); stp %s, %s, [sp, #-%u]!\n", b1, b2, x, z, z, getRegName(REG_V8 + x, true), getRegName(REG_V8 + x + 1, true), (z + 1) * 8); } else if ((b1 & 0xFE) == 0xDC) { // save_freg: 1101110x | xxzzzzzz : save reg d(8 + #X) at [sp + #Z * 8], offset <= 504 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = ((DWORD)(b1 & 0x1) << 2) | (DWORD)(b2 >> 6); z = (DWORD)(b2 & 0x3F); printf(" %02X %02X save_freg X#%u Z#%u (0x%02X); str %s, [sp, #%u]\n", b1, b2, x, z, z, getRegName(REG_V8 + x, true), z * 8); } else if (b1 == 0xDE) { // save_freg_x: 11011110 | xxxzzzzz : save reg d(8 + #X) at [sp - (#Z + 1) * 8]!, pre - indexed offset >= // -256 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = (DWORD)(b2 >> 5); z = (DWORD)(b2 & 0x1F); printf(" %02X %02X save_freg_x X#%u Z#%u (0x%02X); str %s, [sp, #-%u]!\n", b1, b2, x, z, z, getRegName(REG_V8 + x, true), (z + 1) * 8); } else if (b1 == 0xE0) { // alloc_l: 11100000 | xxxxxxxx | xxxxxxxx | xxxxxxxx : allocate large stack with size < 256M (2^24 * 16) assert(i + 3 < countOfUnwindCodes); b2 = *pUnwindCode++; b3 = *pUnwindCode++; b4 = *pUnwindCode++; i += 3; x = ((DWORD)b2 << 16) | ((DWORD)b3 << 8) | (DWORD)b4; printf(" %02X %02X %02X %02X alloc_l %u (0x%06X); sub sp, sp, #%u (%06X)\n", b1, b2, b3, b4, x, x, x * 16, x * 16); } else if (b1 == 0xE1) { // set_fp: 11100001 : set up r29 : with : mov r29, sp printf(" %02X set_fp; mov %s, sp\n", b1, getRegName(REG_FP)); } else if (b1 == 0xE2) { // add_fp: 11100010 | xxxxxxxx : set up r29 with : add r29, sp, #x * 8 assert(i + 1 < countOfUnwindCodes); b2 = *pUnwindCode++; i++; x = (DWORD)b2; printf(" %02X %02X add_fp %u (0x%02X); add %s, sp, #%u\n", b1, b2, x, x, getRegName(REG_FP), x * 8); } else if (b1 == 0xE3) { // nop: 11100011: no unwind operation is required. printf(" %02X nop\n", b1); } else if (b1 == 0xE4) { // end: 11100100 : end of unwind code printf(" %02X end\n", b1); } else if (b1 == 0xE5) { // end_c: 11100101 : end of unwind code in current chained scope. printf(" %02X end_c\n", b1); } else if (b1 == 0xE6) { // save_next: 11100110 : save next non - volatile Int or FP register pair. printf(" %02X save_next\n", b1); } else { // Unknown / reserved unwind code assert(!"Internal error decoding unwind codes"); } } pdw += codeWords; assert((PBYTE)pdw == pUnwindCode); assert((PBYTE)pdw == pHeader + unwindBlockSize); assert(XBit == 0); // We don't handle the case where exception data is present, such as the Exception Handler RVA printf("\n"); } #endif // DEBUG #endif // _TARGET_ARM64_