//---------------------------------------------------------------------------- // // Disassembly portions of Alpha machine implementation. // // Copyright (C) Microsoft Corporation, 2000-2001. // //---------------------------------------------------------------------------- // TODO: // (3) Should registers be treated as 64 or 32bit? Note that Fregs are // 64bits only. -- All registers should be treated as 64bit values // since LDQ/EXTB is done for byte fetches (stores); the intermediate // values could be hidden. #include "ntsdp.hpp" #include "alpha_dis.h" #include "alpha_optable.h" // See Get/SetRegVal comments in machine.hpp. #define RegValError Do_not_use_GetSetRegVal_in_machine_implementations #define GetRegVal(index, val) RegValError #define GetRegVal32(index) RegValError #define GetRegVal64(index) RegValError #define SetRegVal(index, val) RegValError #define SetRegVal32(index, val) RegValError #define SetRegVal64(index, val) RegValError ADDR g_AlphaEffAddr; ALPHA_INSTRUCTION g_AlphaDisinstr; // these are defined in alphaops.h #define NUMBER_OF_BREAK_INSTRUCTIONS 3 #define ALPHA_BP_LEN 4 ULONG g_AlphaTrapInstr = CALLPAL_OP | BPT_FUNC; ULONG g_AlphaBreakInstrs[NUMBER_OF_BREAK_INSTRUCTIONS] = { CALLPAL_OP | BPT_FUNC, CALLPAL_OP | KBPT_FUNC, CALLPAL_OP | CALLKD_FUNC }; #define OPRNDCOL 27 // Column for first operand #define EACOL 40 // column for effective address #define FPTYPECOL 40 // .. for the type of FP instruction BOOL AlphaMachineInfo::Disassemble ( PADDR poffset, PSTR bufptr, BOOL fEAout ) { ULONG opcode; ULONG64 Ea; // Effective Address POPTBLENTRY pEntry; m_BufStart = m_Buf = bufptr; sprintAddr(&m_Buf, poffset); *m_Buf++ = ':'; *m_Buf++ = ' '; if (!GetMemDword(poffset, &g_AlphaDisinstr.Long)) { BufferString("???????? ????\n"); *m_Buf = '\0'; return(FALSE); } BufferHex(g_AlphaDisinstr.Long, 8, FALSE); // Output instruction in Hex *m_Buf++ = ' '; opcode = g_AlphaDisinstr.Memory.Opcode; // Select disassembly procedure from pEntry = findOpCodeEntry(opcode); // Get non-func entry for this code switch (pEntry->iType) { case ALPHA_UNKNOWN: BufferString(pEntry->pszAlphaName); break; case ALPHA_MEMORY: BufferString(pEntry->pszAlphaName); BufferBlanks(OPRNDCOL); BufferReg(g_AlphaDisinstr.Memory.Ra); *m_Buf++ = ','; BufferHex(g_AlphaDisinstr.Memory.MemDisp, (WIDTH_MEM_DISP + 3)/4, TRUE ); *m_Buf++ = '('; BufferReg(g_AlphaDisinstr.Memory.Rb); *m_Buf++ = ')'; break; case ALPHA_FP_MEMORY: BufferString(pEntry->pszAlphaName); BufferBlanks(OPRNDCOL); BufferFReg(g_AlphaDisinstr.Memory.Ra); *m_Buf++ = ','; BufferHex(g_AlphaDisinstr.Memory.MemDisp, (WIDTH_MEM_DISP + 3)/4, TRUE ); *m_Buf++ = '('; BufferReg(g_AlphaDisinstr.Memory.Rb); *m_Buf++ = ')'; break; case ALPHA_MEMSPC: BufferString(findFuncName(pEntry, g_AlphaDisinstr.Memory.MemDisp & BITS_MEM_DISP)); // // Some memory special instructions have an operand // switch (g_AlphaDisinstr.Memory.MemDisp & BITS_MEM_DISP) { case FETCH_FUNC: case FETCH_M_FUNC: // one operand, in Rb BufferBlanks(OPRNDCOL); *m_Buf++ = '0'; *m_Buf++ = '('; BufferReg(g_AlphaDisinstr.Memory.Rb); *m_Buf++ = ')'; break; case RS_FUNC: case RC_FUNC: case RPCC_FUNC: // one operand, in Ra BufferBlanks(OPRNDCOL); BufferReg(g_AlphaDisinstr.Memory.Ra); break; case MB_FUNC: case WMB_FUNC: case MB2_FUNC: case MB3_FUNC: case TRAPB_FUNC: case EXCB_FUNC: // no operands break; default: printf("we shouldn't get here \n"); break; } break; case ALPHA_JUMP: BufferString(findFuncName(pEntry, g_AlphaDisinstr.Jump.Function)); BufferBlanks(OPRNDCOL); BufferReg(g_AlphaDisinstr.Jump.Ra); *m_Buf++ = ','; *m_Buf++ = '('; BufferReg(g_AlphaDisinstr.Jump.Rb); *m_Buf++ = ')'; *m_Buf++ = ','; BufferHex(g_AlphaDisinstr.Jump.Hint, (WIDTH_HINT + 3)/4, TRUE); Ea = GetReg64(GetIntRegNumber(g_AlphaDisinstr.Jump.Rb)) & (~3); BufferEffectiveAddress(Ea); break; case ALPHA_BRANCH: BufferString(pEntry->pszAlphaName); BufferBlanks(OPRNDCOL); BufferReg(g_AlphaDisinstr.Branch.Ra); *m_Buf++ = ','; // // The next line might be a call to GetNextOffset, but // GetNextOffset assumes that it should work from FIR. // Ea = Flat(*poffset) + sizeof(ULONG) + (g_AlphaDisinstr.Branch.BranchDisp * 4); BufferHex(Ea, 16, FALSE); BufferEffectiveAddress(Ea); break; case ALPHA_FP_BRANCH: BufferString(pEntry->pszAlphaName); BufferBlanks(OPRNDCOL); BufferFReg(g_AlphaDisinstr.Branch.Ra); *m_Buf++ = ','; // // The next line might be a call to GetNextOffset, but // GetNextOffset assumes that it should work from FIR. // Ea = Flat(*poffset) + sizeof(ULONG) + (g_AlphaDisinstr.Branch.BranchDisp * 4); BufferHex(Ea, 16, FALSE); BufferEffectiveAddress(Ea); break; case ALPHA_OPERATE: BufferString(findFuncName(pEntry, g_AlphaDisinstr.OpReg.Function)); BufferBlanks(OPRNDCOL); if (g_AlphaDisinstr.OpReg.Opcode != SEXT_OP) { BufferReg(g_AlphaDisinstr.OpReg.Ra); *m_Buf++ = ','; } if (g_AlphaDisinstr.OpReg.RbvType) { *m_Buf++ = '#'; BufferHex(g_AlphaDisinstr.OpLit.Literal, (WIDTH_LIT + 3)/4, TRUE); } else { BufferReg(g_AlphaDisinstr.OpReg.Rb); } *m_Buf++ = ','; BufferReg(g_AlphaDisinstr.OpReg.Rc); break; case ALPHA_FP_OPERATE: { ULONG Function; ULONG Flags; Flags = g_AlphaDisinstr.FpOp.Function & MSK_FP_FLAGS; Function = g_AlphaDisinstr.FpOp.Function & MSK_FP_OP; #if 0 if (fVerboseBuffer) { dprintf("In FP_OPERATE: Flags %08x Function %08x\n", Flags, Function); dprintf("opcode %d \n", opcode); } #endif // // CVTST and CVTST/S are different: they look like // CVTTS with some flags set // if (Function == CVTTS_FUNC) { if (g_AlphaDisinstr.FpOp.Function == CVTST_S_FUNC) { Function = CVTST_S_FUNC; Flags = NONE_FLAGS; } if (g_AlphaDisinstr.FpOp.Function == CVTST_FUNC) { Function = CVTST_FUNC; Flags = NONE_FLAGS; } } BufferString(findFuncName(pEntry, Function)); // // Append the opcode qualifier, if any, to the opcode name. // if ( (opcode == IEEEFP_OP) || (opcode == VAXFP_OP) || (Function == CVTQL_FUNC) ) { BufferString(findFlagName(Flags, Function)); } BufferBlanks(OPRNDCOL); // // If this is a convert instruction, only Rb and Rc are used // if (strncmp("cvt", findFuncName(pEntry, Function), 3) != 0) { BufferFReg(g_AlphaDisinstr.FpOp.Fa); *m_Buf++ = ','; } BufferFReg(g_AlphaDisinstr.FpOp.Fb); *m_Buf++ = ','; BufferFReg(g_AlphaDisinstr.FpOp.Fc); break; } case ALPHA_FP_CONVERT: BufferString(pEntry->pszAlphaName); BufferBlanks(OPRNDCOL); BufferFReg(g_AlphaDisinstr.FpOp.Fa); *m_Buf++ = ','; BufferFReg(g_AlphaDisinstr.FpOp.Fb); break; case ALPHA_CALLPAL: BufferString(findFuncName(pEntry, g_AlphaDisinstr.Pal.Function)); break; case ALPHA_EV4_PR: if ((g_AlphaDisinstr.Long & MSK_EV4_PR) == 0) { BufferString("NOP"); } else { BufferString(pEntry->pszAlphaName); BufferBlanks(OPRNDCOL); BufferReg(g_AlphaDisinstr.EV4_PR.Ra); *m_Buf++ = ','; if(g_AlphaDisinstr.EV4_PR.Ra != g_AlphaDisinstr.EV4_PR.Rb) { BufferReg(g_AlphaDisinstr.EV4_PR.Rb); *m_Buf++ = ','; } BufferString(findFuncName(pEntry, (g_AlphaDisinstr.Long & MSK_EV4_PR))); } break; case ALPHA_EV4_MEM: BufferString(pEntry->pszAlphaName); BufferBlanks(OPRNDCOL); BufferReg(g_AlphaDisinstr.EV4_MEM.Ra); *m_Buf++ = ','; BufferReg(g_AlphaDisinstr.EV4_MEM.Rb); break; case ALPHA_EV4_REI: BufferString(pEntry->pszAlphaName); break; default: BufferString("Invalid type"); break; } Off(*poffset) += sizeof(ULONG); NotFlat(*poffset); ComputeFlatAddress(poffset, NULL); *m_Buf++ = '\n'; *m_Buf = '\0'; return(TRUE); } void AlphaMachineInfo::BufferReg (ULONG regnum) { BufferString(RegNameFromIndex(GetIntRegNumber(regnum))); } void AlphaMachineInfo::BufferFReg (ULONG regnum) { *m_Buf++ = 'f'; if (regnum > 9) *m_Buf++ = (UCHAR)('0' + regnum / 10); *m_Buf++ = (UCHAR)('0' + regnum % 10); } /*** BufferEffectiveAddress - Print EA symbolically * * Purpose: * Given the effective address (for a branch, jump or * memory instruction, print it symbolically, if * symbols are available. * * Input: * offset - computed by the caller as * for jumps, the value in Rb * for branches, func(PC, displacement) * for memory, func(PC, displacement) * * Returns: * None * *************************************************************************/ void AlphaMachineInfo::BufferEffectiveAddress( ULONG64 offset ) { CHAR chAddrBuffer[MAX_SYMBOL_LEN]; ULONG64 displacement; PCHAR pszTemp; UCHAR ch; // // MBH - i386 compiler bug with fast calling standard. // If "chAddrBuffer is used as a calling argument to // GetSymbol, it believes (here, but not in the other // uses of GetSymbol that the size is 60+8=68. // PCHAR pch = chAddrBuffer; BufferBlanks(EACOL); GetSymbolStdCall(offset, pch, sizeof(chAddrBuffer), &displacement, NULL); if (chAddrBuffer[0]) { pszTemp = chAddrBuffer; while (ch = *pszTemp++) { *m_Buf++ = ch; } if (displacement) { *m_Buf++ = '+'; BufferHex(displacement, 8, TRUE); } } else { BufferHex(offset, 16, FALSE); } // Save EA. ADDRFLAT(&g_AlphaEffAddr, offset); } BOOL AlphaMachineInfo::IsBreakpointInstruction(PADDR Addr) { UCHAR Instr[ALPHA_BP_LEN]; if (GetMemString(Addr, Instr, ALPHA_BP_LEN) != ALPHA_BP_LEN) { return FALSE; } LONG index; // // ALPHA has several breakpoint instructions - see // if we have hit any of them. // index = 0; do { if (!memcmp(Instr, (PUCHAR)&g_AlphaBreakInstrs[index], ALPHA_BP_LEN)) { return TRUE; } } while (++index < NUMBER_OF_BREAK_INSTRUCTIONS); return FALSE; } HRESULT AlphaMachineInfo::InsertBreakpointInstruction(PUSER_DEBUG_SERVICES Services, ULONG64 Process, ULONG64 Offset, PUCHAR SaveInstr, PULONG64 ChangeStart, PULONG ChangeLen) { *ChangeStart = Offset; *ChangeLen = ALPHA_BP_LEN; ULONG Done; HRESULT Status; Status = Services->ReadVirtual(Process, Offset, SaveInstr, ALPHA_BP_LEN, &Done); if (Status == S_OK && Done != ALPHA_BP_LEN) { Status = HRESULT_FROM_WIN32(ERROR_READ_FAULT); } if (Status == S_OK) { Status = Services->WriteVirtual(Process, Offset, &g_AlphaTrapInstr, ALPHA_BP_LEN, &Done); if (Status == S_OK && Done != ALPHA_BP_LEN) { Status = HRESULT_FROM_WIN32(ERROR_WRITE_FAULT); } } return Status; } HRESULT AlphaMachineInfo::RemoveBreakpointInstruction(PUSER_DEBUG_SERVICES Services, ULONG64 Process, ULONG64 Offset, PUCHAR SaveInstr, PULONG64 ChangeStart, PULONG ChangeLen) { *ChangeStart = Offset; *ChangeLen = ALPHA_BP_LEN; ULONG Done; HRESULT Status; Status = Services->WriteVirtual(Process, Offset, SaveInstr, ALPHA_BP_LEN, &Done); if (Status == S_OK && Done != ALPHA_BP_LEN) { Status = HRESULT_FROM_WIN32(ERROR_WRITE_FAULT); } return Status; } void AlphaMachineInfo::AdjustPCPastBreakpointInstruction(PADDR Addr, ULONG BreakType) { DBG_ASSERT(BreakType == DEBUG_BREAKPOINT_CODE); SetPC(AddrAdd(Addr, ALPHA_BP_LEN)); } BOOL AlphaMachineInfo::IsCallDisasm(PCSTR Disasm) { return strstr(Disasm, " jsr") != NULL; } BOOL AlphaMachineInfo::IsReturnDisasm(PCSTR Disasm) { return strstr(Disasm, " ret ") != NULL && strstr(Disasm, " ra") != NULL; } BOOL AlphaMachineInfo::IsSystemCallDisasm(PCSTR Disasm) { return strstr(Disasm, " CallSys") != NULL; } BOOL AlphaMachineInfo::IsDelayInstruction(PADDR Addr) { return(FALSE); } void AlphaMachineInfo::GetEffectiveAddr(PADDR Addr) { *Addr = g_AlphaEffAddr; } void AlphaMachineInfo::GetNextOffset(BOOL StepOver, PADDR NextAddr, PULONG NextMachine) { ULONG64 rv; ULONG opcode; ULONG64 firaddr; ULONG64 updatedpc; ULONG64 branchTarget; ADDR fir; // Canonical form to shorten tests; Abs is absolute value LONG Can, Abs; LARGE_INTEGER Rav; LARGE_INTEGER Rbv; LARGE_INTEGER Fav; // NextMachine is always the same. *NextMachine = m_ExecTypes[0]; // // Get current address // firaddr = GetReg64(ALPHA_FIR); // // relative addressing updates PC first // Assume next sequential instruction is next offset // updatedpc = firaddr + sizeof(ULONG); rv = updatedpc; ADDRFLAT( &fir, firaddr); GetMemDword(&fir, &(g_AlphaDisinstr.Long)); // Get current instruction opcode = g_AlphaDisinstr.Memory.Opcode; switch(findOpCodeEntry(opcode)->iType) { case ALPHA_JUMP: switch(g_AlphaDisinstr.Jump.Function) { case JSR_FUNC: case JSR_CO_FUNC: if (StepOver) { // // Step over the subroutine call; // break; } // // fall through // case JMP_FUNC: case RET_FUNC: Rbv.QuadPart = GetReg64(GetIntRegNumber(g_AlphaDisinstr.Jump.Rb)); if (m_Ptr64) { rv = (Rbv.QuadPart & (~3)); } else { rv = EXTEND64(Rbv.LowPart & (~3)); } break; } break; case ALPHA_BRANCH: branchTarget = (updatedpc + (g_AlphaDisinstr.Branch.BranchDisp * 4)); Rav.QuadPart = GetReg64(GetIntRegNumber(g_AlphaDisinstr.Branch.Ra)); // // set up a canonical value for computing the branch test // - works with ALPHA, MIPS and 386 hosts // Can = Rav.LowPart & 1; if ((LONG)Rav.HighPart < 0) { Can |= 0x80000000; } if ((Rav.LowPart & 0xfffffffe) || (Rav.HighPart & 0x7fffffff)) { Can |= 2; } #if 0 VerbOut("Rav High %08lx Low %08lx Canonical %08lx\n", Rav.HighPart, Rav.LowPart, Can); VerbOut("returnvalue %08lx branchTarget %08lx\n", rv, branchTarget); #endif switch(opcode) { case BR_OP: rv = branchTarget; break; case BSR_OP: if (!StepOver) rv = branchTarget; break; case BEQ_OP: if (Can == 0) rv = branchTarget; break; case BLT_OP: if (Can < 0) rv = branchTarget; break; case BLE_OP: if (Can <= 0) rv = branchTarget; break; case BNE_OP: if (Can != 0) rv = branchTarget; break; case BGE_OP: if (Can >= 0) rv = branchTarget; break; case BGT_OP: if (Can > 0) rv = branchTarget; break; case BLBC_OP: if ((Can & 0x1) == 0) rv = branchTarget; break; case BLBS_OP: if ((Can & 0x1) == 1) rv = branchTarget; break; } break; case ALPHA_FP_BRANCH: branchTarget = (updatedpc + (g_AlphaDisinstr.Branch.BranchDisp * 4)); Fav.QuadPart = GetReg64(g_AlphaDisinstr.Branch.Ra); // // Set up a canonical value for computing the branch test // Can = Fav.HighPart & 0x80000000; // // The absolute value is needed -0 and non-zero computation // Abs = Fav.LowPart || (Fav.HighPart & 0x7fffffff); if (Can && (Abs == 0x0)) { // // negative 0 should be considered as zero // Can = 0x0; } else { Can |= Abs; } #if 0 VerbOut("Fav High %08lx Low %08lx Canonical %08lx Absolute %08lx\n", Fav.HighPart, Fav.LowPart, Can, Abs); VerbOut("returnvalue %08lx branchTarget %08lx\n", rv, branchTarget); #endif switch(opcode) { case FBEQ_OP: if (Can == 0) rv = branchTarget; break; case FBLT_OP: if (Can < 0) rv = branchTarget; break; case FBNE_OP: if (Can != 0) rv = branchTarget; break; case FBLE_OP: if (Can <= 0) rv = branchTarget; break; case FBGE_OP: if (Can >= 0) rv = branchTarget; break; case FBGT_OP: if (Can > 0) rv = branchTarget; break; } break; } #if 0 VerbOut("GetNextOffset returning %08lx\n", rv); #endif ADDRFLAT( NextAddr, rv ); } void AlphaMachineInfo::IncrementBySmallestInstruction(PADDR Addr) { AddrAdd(Addr, 4); } void AlphaMachineInfo::DecrementBySmallestInstruction(PADDR Addr) { AddrSub(Addr, 4); } void AlphaMachineInfo::PrintStackFrameAddresses(ULONG Flags, PDEBUG_STACK_FRAME StackFrame) { // // this is pure hack... // Alpha's "return address" is really the address of the // instruction where control left the frame. Show the address of // the next instruction, to make it easy to set a BP on the // return site. It will still be wrong sometimes, but it will // be right more often this way. // DEBUG_STACK_FRAME AlphaStackFrame = *StackFrame; if (AlphaStackFrame.ReturnOffset) { AlphaStackFrame.ReturnOffset += 4; } MachineInfo::PrintStackFrameAddresses(Flags, &AlphaStackFrame); }