/*++ Copyright (c) 1990-2001 Microsoft Corporation Module Name: kdcpuapi.c Abstract: This module implements CPU specific remote debug APIs. Author: Mark Lucovsky (markl) 04-Sep-1990 Revision History: 24-sep-90 bryanwi Port to the x86. --*/ #include #include "kdp.h" #define END_OF_CONTROL_SPACE extern ULONG KdpCurrentSymbolStart, KdpCurrentSymbolEnd; extern ULONG KdSpecialCalls[]; extern ULONG KdNumberOfSpecialCalls; LONG KdpLevelChange ( ULONG Pc, PCONTEXT ContextRecord, PBOOLEAN SpecialCall ); LONG regValue( UCHAR reg, PCONTEXT ContextRecord ); BOOLEAN KdpIsSpecialCall ( ULONG Pc, PCONTEXT ContextRecord, UCHAR opcode, UCHAR ModRM ); ULONG KdpGetReturnAddress ( PCONTEXT ContextRecord ); ULONG KdpGetCallNextOffset ( ULONG Pc, PCONTEXT ContextRecord ); #ifdef ALLOC_PRAGMA #pragma alloc_text(PAGEKD, KdpLevelChange) #pragma alloc_text(PAGEKD, regValue) #pragma alloc_text(PAGEKD, KdpIsSpecialCall) #pragma alloc_text(PAGEKD, KdpGetReturnAddress) #pragma alloc_text(PAGEKD, KdpAllowDisable) #pragma alloc_text(PAGEKD, KdpSetContextState) #pragma alloc_text(PAGEKD, KdpSetStateChange) #pragma alloc_text(PAGEKD, KdpGetStateChange) #pragma alloc_text(PAGEKD, KdpSysReadControlSpace) #pragma alloc_text(PAGEKD, KdpSysWriteControlSpace) #pragma alloc_text(PAGEKD, KdpSysReadIoSpace) #pragma alloc_text(PAGEKD, KdpSysWriteIoSpace) #pragma alloc_text(PAGEKD, KdpSysReadMsr) #pragma alloc_text(PAGEKD, KdpSysWriteMsr) #pragma alloc_text(PAGEKD, KdpGetCallNextOffset) #endif /**** KdpIsTryFinallyReturn - detect finally optimization * * Input: * pc - program counter of instruction to check * ContextRecord - machine specific context * * Output: * returns TRUE if this is a try-finally returning to the same * scope ***************************************************************************/ BOOLEAN KdpIsTryFinallyReturn ( ULONG Pc, PCONTEXT ContextRecord ) { ULONG retaddr; ULONG calldisp; UCHAR inst; // // The complier generates code for a try-finally that involves having // a ret instruction that does not match with a call instruction. // This ret never returns a value (ie, it's a c3 return and not a // c2). It always returns into the current symbol scope. It is never // preceeded by a leave, which (hopefully) should differentiate it // from recursive returns. Check for this, and if we find it count // it as *0* level change. // // As an optimization, the compiler will often change: // CALL // RET // into: // JMP // In either case, we figure out the return address. It's the first 4 bytes // on the stack. // if (!NT_SUCCESS(KdpCopyFromPtr(&retaddr, ContextRecord->Esp, 4, NULL))) { return FALSE; } // DPRINT(( "Start %x return %x end %x\n", KdpCurrentSymbolStart, retaddr, KdpCurrentSymbolEnd )); if ( (KdpCurrentSymbolStart < retaddr) && (retaddr < KdpCurrentSymbolEnd) ) { // // Well, things aren't this nice. We may have transferred but not yet // updated the start/end. This case occurs in a call to a thunk. We // look to see if the instruction before the return address is a call. // Gross and not 100% reliable. // if (!NT_SUCCESS(KdpCopyFromPtr(&inst, (PCHAR)retaddr - 5, 1, NULL))) { return FALSE; } if (!NT_SUCCESS(KdpCopyFromPtr(&calldisp, (PCHAR)retaddr - 4, 4, NULL))) { return FALSE; } if (inst == 0xe8 && calldisp + retaddr == Pc) { // DPRINT(( "call to thunk @ %x\n", Pc )); return FALSE; } // // returning to the current function. Either a finally // or a recursive return. Check for a leave. This is not 100% // reliable since we are betting on an instruction longer than a byte // and not ending with 0xc9. // if (!NT_SUCCESS(KdpCopyFromPtr(&inst, (PCHAR)Pc - 1, 1, NULL))) { return FALSE; } if ( inst != 0xc9 ) { // not a leave. Assume a try-finally. // DPRINT(( "transfer at %x is try-finally\n", Pc )); return TRUE; } } // // This appears to be a true RET instruction // return FALSE; } /**** KdpLevelChange - say how the instruction affects the call level * * Input: * pc - program counter of instruction to check * ContextRecord - machine specific context * SpecialCall - pointer to returned boolean indicating if the * instruction is a transfer to a special routine * * Output: * returns -1 for a level pop, 1 for a push and 0 if it is * unchanged. * NOTE: This function belongs in some other file. I should move it. ***************************************************************************/ LONG KdpLevelChange ( ULONG Pc, PCONTEXT ContextRecord, PBOOLEAN SpecialCall ) { UCHAR membuf[2]; ULONG Addr; membuf[0] = 0xcc; membuf[1] = 0xcc; KdpCopyFromPtr(membuf, Pc, 2, NULL); switch (membuf[0]) { case 0xe8: // CALL direct w/32 bit displacement // // For try/finally, the compiler may, in addition to the push/ret trick // below, use a call to the finally thunk. Since we treat a RET to // within the same symbol scope as not changing levels, we will also // treat such a call as not changing levels either // if (!NT_SUCCESS(KdpCopyFromPtr(&Addr, (PCHAR)Pc + 1, 4, NULL))) { Addr = 0; } else { Addr += Pc + 5; } if ((KdpCurrentSymbolStart <= Addr) && (Addr < KdpCurrentSymbolEnd)) { *SpecialCall = FALSE; return 0; } case 0x9a: // CALL segmented 16:32 *SpecialCall = KdpIsSpecialCall( Pc, ContextRecord, membuf[0], membuf[1] ); return 1; case 0xff: // // This is a compound instruction. Dispatch on operation // switch (membuf[1] & 0x38) { case 0x10: // CALL with mod r/m *SpecialCall = KdpIsSpecialCall( Pc, ContextRecord, membuf[0], membuf[1] ); return 1; case 0x20: // JMP with mod r/m *SpecialCall = KdpIsSpecialCall( Pc, ContextRecord, membuf[0], membuf[1] ); // // If this is a try/finally, we'd like to treat it as call since the // return inside the destination will bring us back to this context. // However, if it is a jmp to a special routine, we must treat it // as a no-level change operation since we won't see the special // routines's return. // // If it is not a try/finally, we'd like to treat it as a no-level // change, unless again, it is a transfer to a special call which // views this as a level up. // if (KdpIsTryFinallyReturn( Pc, ContextRecord )) { if (*SpecialCall) { // // We won't see the return, so pretend it is just // inline code // return 0; } else { // // The destinations return will bring us back to this // context // return 1; } } else if (*SpecialCall) { // // We won't see the return but we are, indeed, doing one. // return -1; } else { return 0; } default: *SpecialCall = FALSE; return 0; } case 0xc3: // RET // // If we are a try/finally ret, then we indicate that it is NOT a level // change // if (KdpIsTryFinallyReturn( Pc, ContextRecord )) { *SpecialCall = FALSE; return 0; } case 0xc2: // RET w/16 bit esp change case 0xca: // RETF w/16 bit esp change case 0xcb: // RETF *SpecialCall = FALSE; return -1; default: *SpecialCall = FALSE; return 0; } } // KdpLevelChange LONG regValue( UCHAR reg, PCONTEXT ContextRecord ) { switch (reg) { case 0x0: return(ContextRecord->Eax); break; case 0x1: return(ContextRecord->Ecx); break; case 0x2: return(ContextRecord->Edx); break; case 0x3: return(ContextRecord->Ebx); break; case 0x4: return(ContextRecord->Esp); break; case 0x5: return(ContextRecord->Ebp); break; case 0x6: return(ContextRecord->Esi); break; case 0x7: return(ContextRecord->Edi); break; } return 0; } BOOLEAN KdpIsSpecialCall ( ULONG Pc, PCONTEXT ContextRecord, UCHAR opcode, UCHAR modRM ) /*++ Routine Description: Check to see if the instruction at pc is a call to one of the SpecialCall routines. Argument: Pc - program counter of instruction in question. --*/ { UCHAR sib; ULONG callAddr; ULONG addrAddr; LONG offset; ULONG i; char d8; callAddr = 0; if ( opcode == 0xe8 ) { // // Signed offset from pc // if (NT_SUCCESS(KdpCopyFromPtr(&offset, (PCHAR)Pc + 1, 4, NULL))) { callAddr = Pc + offset + 5; // +5 for instr len. } } else if ( opcode == 0xff ) { if ( ((modRM & 0x38) != 0x10) && ((modRM & 0x38) != 0x20) ) { // not call or jump return FALSE; } if ( (modRM & 0x08) == 0x08 ) { // m16:16 or m16:32 -- we don't handle this return FALSE; } if ( (modRM & 0xc0) == 0xc0 ) { /* Direct register addressing */ callAddr = regValue( (UCHAR)(modRM&0x7), ContextRecord ); } else if ( (modRM & 0xc7) == 0x05 ) { // // Calls across dll boundaries involve a call into a jump table, // wherein the jump address is set to the real called routine at DLL // load time. Check to see if we're calling such an instruction, // and if so, compute its target address and set callAddr there. // // ff15 or ff25 -- call or jump indirect with disp32. Get // address of address // if (NT_SUCCESS(KdpCopyFromPtr(&addrAddr, (PCHAR)Pc + 2, 4, NULL))) { // // Get real destination address // if (!NT_SUCCESS(KdpCopyFromPtr(&callAddr, addrAddr, 4, NULL))) { callAddr = 0; } } // DPRINT(( "Indirect call/jmp @ %x\n", Pc )); } else if ( (modRM & 0x7) == 0x4 ) { LONG indexValue; /* sib byte present */ if (!NT_SUCCESS(KdpCopyFromPtr(&sib, (PCHAR)Pc + 2, 1, NULL))) { sib = 0; } indexValue = regValue( (UCHAR)((sib & 0x31) >> 3), ContextRecord ); switch ( sib&0xc0 ) { case 0x0: /* x1 */ break; case 0x40: indexValue *= 2; break; case 0x80: indexValue *= 4; break; case 0xc0: indexValue *= 8; break; } /* switch */ switch ( modRM & 0xc0 ) { case 0x0: /* no displacement */ if ( (sib & 0x7) == 0x5 ) { // DPRINT(("funny call #1 at %x\n", Pc)); return FALSE; } callAddr = indexValue + regValue((UCHAR)(sib&0x7), ContextRecord ); break; case 0x40: if ( (sib & 0x6) == 0x4 ) { // DPRINT(("Funny call #2\n")); /* calling into the stack */ return FALSE; } if (!NT_SUCCESS(KdpCopyFromPtr( &d8, (PCHAR)Pc + 3, 1, NULL))) { d8 = 0; } callAddr = indexValue + d8 + regValue((UCHAR)(sib&0x7), ContextRecord ); break; case 0x80: if ( (sib & 0x6) == 0x4 ) { // DPRINT(("Funny call #3\n")); /* calling into the stack */ return FALSE; } if (!NT_SUCCESS(KdpCopyFromPtr(&offset, (PCHAR)Pc + 3, 4, NULL))) { offset = 0; } callAddr = indexValue + offset + regValue((UCHAR)(sib&0x7), ContextRecord ); break; case 0xc0: ASSERT( FALSE ); break; } } else { //KdPrint(( "undecoded call at %x\n", // CONTEXT_TO_PROGRAM_COUNTER(ContextRecord) )); return FALSE; } } else if ( opcode == 0x9a ) { /* Absolute address call (best I can tell, cc doesn't generate this) */ if (!NT_SUCCESS(KdpCopyFromPtr( &callAddr, (PCHAR)Pc + 1, 4, NULL))) { callAddr = 0; } } else { return FALSE; } // // Calls across dll boundaries involve a call into a jump table, // wherein the jump address is set to the real called routine at DLL // load time. Check to see if we're calling such an instruction, // and if so, compute its target address and set callAddr there. // #if 0 if (!NT_SUCCESS(KdpCopyFromPtr( &twoBytes, (PCHAR)callAddr, 2, NULL))) { twoBytes = 0; } if ( twoBytes == 0x25ff ) { /* i386 is little-Endian; really 0xff25 */ // // This is a 'jmp dword ptr [mem]' instruction, which is the sort of // jump used for a dll-boundary crossing call. Fixup callAddr. // if (!NT_SUCCESS(KdpCopyFromPtr( &addrAddr, (PCHAR)callAddr + 2, 4, NULL))) { callAddr = 0; } else if (!NT_SUCCESS(KdpCopyFromPtr( &callAddr, addrAddr, 4, NULL))) { callAddr = 0; } } #endif for ( i = 0; i < KdNumberOfSpecialCalls; i++ ) { if ( KdSpecialCalls[i] == callAddr ) { return TRUE; } } return FALSE; } /* * Find the return address of the current function. Only works when * locals haven't yet been pushed (ie, on the first instruction of the * function). */ ULONG KdpGetReturnAddress ( PCONTEXT ContextRecord ) { ULONG retaddr; if (!NT_SUCCESS(KdpCopyFromPtr(&retaddr, ContextRecord->Esp, 4, NULL))) { retaddr = 0; } return retaddr; } // KdpGetReturnAddress NTSTATUS KdpAllowDisable( VOID ) /*++ Routine Description: Determines whether the current state of the debugger allows disabling or not. Arguments: None. Return Value: NTSTATUS. --*/ { PKPRCB Prcb; ULONG Processor; // // If any kernel data breakpoints are active on any processor we can't // disable the debugger. // for (Processor = 0; Processor < (ULONG)KeNumberProcessors; Processor++) { Prcb = KiProcessorBlock[Processor]; if (Prcb->ProcessorState.SpecialRegisters.KernelDr7 & 0xff) { return STATUS_ACCESS_DENIED; } } return STATUS_SUCCESS; } VOID KdpSetContextState( IN OUT PDBGKD_ANY_WAIT_STATE_CHANGE WaitStateChange, IN PCONTEXT ContextRecord ) { PKPRCB Prcb; // // Special registers for the x86 // Prcb = KeGetCurrentPrcb(); WaitStateChange->ControlReport.Dr6 = Prcb->ProcessorState.SpecialRegisters.KernelDr6; WaitStateChange->ControlReport.Dr7 = Prcb->ProcessorState.SpecialRegisters.KernelDr7; WaitStateChange->ControlReport.SegCs = (USHORT)(ContextRecord->SegCs); WaitStateChange->ControlReport.SegDs = (USHORT)(ContextRecord->SegDs); WaitStateChange->ControlReport.SegEs = (USHORT)(ContextRecord->SegEs); WaitStateChange->ControlReport.SegFs = (USHORT)(ContextRecord->SegFs); WaitStateChange->ControlReport.EFlags = ContextRecord->EFlags; WaitStateChange->ControlReport.ReportFlags = X86_REPORT_INCLUDES_SEGS; // If the current code segment is a known flat code // segment let the debugger know so that it doesn't // have to retrieve the descriptor. if (ContextRecord->SegCs == KGDT_R0_CODE || ContextRecord->SegCs == KGDT_R3_CODE + 3) { WaitStateChange->ControlReport.ReportFlags |= X86_REPORT_STANDARD_CS; } } VOID KdpSetStateChange( IN OUT PDBGKD_ANY_WAIT_STATE_CHANGE WaitStateChange, IN PEXCEPTION_RECORD ExceptionRecord, IN PCONTEXT ContextRecord, IN BOOLEAN SecondChance ) /*++ Routine Description: Fill in the Wait_State_Change message record. Arguments: WaitStateChange - Supplies pointer to record to fill in ExceptionRecord - Supplies a pointer to an exception record. ContextRecord - Supplies a pointer to a context record. SecondChance - Supplies a boolean value that determines whether this is the first or second chance for the exception. Return Value: None. --*/ { UNREFERENCED_PARAMETER (ExceptionRecord); UNREFERENCED_PARAMETER (SecondChance); KdpSetContextState(WaitStateChange, ContextRecord); } VOID KdpGetStateChange( IN PDBGKD_MANIPULATE_STATE64 ManipulateState, IN PCONTEXT ContextRecord ) /*++ Routine Description: Extract continuation control data from Manipulate_State message Arguments: ManipulateState - supplies pointer to Manipulate_State packet ContextRecord - Supplies a pointer to a context record. Return Value: None. --*/ { PKPRCB Prcb; ULONG Processor; if (NT_SUCCESS(ManipulateState->u.Continue2.ContinueStatus) == TRUE) { // // If NT_SUCCESS returns TRUE, then the debugger is doing a // continue, and it makes sense to apply control changes. // Otherwise the debugger is saying that it doesn't know what // to do with this exception, so control values are ignored. // if (ManipulateState->u.Continue2.ControlSet.TraceFlag == TRUE) { ContextRecord->EFlags |= 0x100L; } else { ContextRecord->EFlags &= ~0x100L; } for (Processor = 0; Processor < (ULONG)KeNumberProcessors; Processor++) { Prcb = KiProcessorBlock[Processor]; Prcb->ProcessorState.SpecialRegisters.KernelDr7 = ManipulateState->u.Continue2.ControlSet.Dr7; Prcb->ProcessorState.SpecialRegisters.KernelDr6 = 0L; } if (ManipulateState->u.Continue2.ControlSet.CurrentSymbolStart != 1) { KdpCurrentSymbolStart = ManipulateState->u.Continue2.ControlSet.CurrentSymbolStart; KdpCurrentSymbolEnd = ManipulateState->u.Continue2.ControlSet.CurrentSymbolEnd; } } } NTSTATUS KdpSysReadControlSpace( ULONG Processor, ULONG64 Address, PVOID Buffer, ULONG Request, PULONG Actual ) /*++ Routine Description: Reads implementation specific system data. IMPLEMENTATION NOTE: On the X86, control space is defined as follows: 0: Base of KPROCESSOR_STATE structure. (KPRCB.ProcessorState) This includes CONTEXT record, followed by a SPECIAL_REGISTERs record Arguments: Processor - Processor's information to access. Address - Offset in control space. Buffer - Data buffer. Request - Amount of data to move. Actual - Amount of data actually moved. Return Value: NTSTATUS. --*/ { ULONG Length, t; PVOID StartAddr; NTSTATUS Status; Length = Request; if ((Address < sizeof(KPROCESSOR_STATE)) && (Processor < (ULONG)KeNumberProcessors)) { t = (ULONG)(sizeof(KPROCESSOR_STATE)) - (ULONG)Address; if (t < Length) { Length = t; } StartAddr = (PVOID) ((ULONG)Address + (ULONG)&(KiProcessorBlock[Processor]->ProcessorState)); Status = KdpCopyToPtr(Buffer, StartAddr, Length, Actual); } else { Status = STATUS_UNSUCCESSFUL; *Actual = 0; } return Status; } NTSTATUS KdpSysWriteControlSpace( ULONG Processor, ULONG64 Address, PVOID Buffer, ULONG Request, PULONG Actual ) /*++ Routine Description: Writes implementation specific system data. Control space for x86 is as defined above. Arguments: Processor - Processor's information to access. Address - Offset in control space. Buffer - Data buffer. Request - Amount of data to move. Actual - Amount of data actually moved. Return Value: NTSTATUS. --*/ { PVOID StartAddr; NTSTATUS Status; if (((Address + Request) <= sizeof(KPROCESSOR_STATE)) && (Processor < (ULONG)KeNumberProcessors)) { StartAddr = (PVOID) ((ULONG)Address + (ULONG)&(KiProcessorBlock[Processor]->ProcessorState)); Status = KdpCopyFromPtr(StartAddr, Buffer, Request, Actual); } else { Status = STATUS_UNSUCCESSFUL; *Actual = 0; } return Status; } NTSTATUS KdpSysReadIoSpace( INTERFACE_TYPE InterfaceType, ULONG BusNumber, ULONG AddressSpace, ULONG64 Address, PVOID Buffer, ULONG Request, PULONG Actual ) /*++ Routine Description: Reads system I/O locations. Arguments: InterfaceType - I/O interface type. BusNumber - Bus number. AddressSpace - Address space. Address - I/O address. Buffer - Data buffer. Request - Amount of data to move. Actual - Amount of data actually moved. Return Value: NTSTATUS. --*/ { NTSTATUS Status = STATUS_SUCCESS; if (InterfaceType != Isa || BusNumber != 0 || AddressSpace != 1) { *Actual = 0; return STATUS_UNSUCCESSFUL; } // // Check Size and Alignment // switch ( Request ) { case 1: *(PUCHAR)Buffer = READ_PORT_UCHAR((PUCHAR)(ULONG_PTR)Address); *Actual = 1; break; case 2: if ( Address & 1 ) { Status = STATUS_DATATYPE_MISALIGNMENT; } else { *(PUSHORT)Buffer = READ_PORT_USHORT((PUSHORT)(ULONG_PTR)Address); *Actual = 2; } break; case 4: if ( Address & 3 ) { Status = STATUS_DATATYPE_MISALIGNMENT; } else { *(PULONG)Buffer = READ_PORT_ULONG((PULONG)(ULONG_PTR)Address); *Actual = 4; } break; default: Status = STATUS_INVALID_PARAMETER; *Actual = 0; break; } return Status; } NTSTATUS KdpSysWriteIoSpace( INTERFACE_TYPE InterfaceType, ULONG BusNumber, ULONG AddressSpace, ULONG64 Address, PVOID Buffer, ULONG Request, PULONG Actual ) /*++ Routine Description: Writes system I/O locations. Arguments: InterfaceType - I/O interface type. BusNumber - Bus number. AddressSpace - Address space. Address - I/O address. Buffer - Data buffer. Request - Amount of data to move. Actual - Amount of data actually moved. Return Value: NTSTATUS. --*/ { NTSTATUS Status = STATUS_SUCCESS; if (InterfaceType != Isa || BusNumber != 0 || AddressSpace != 1) { *Actual = 0; return STATUS_UNSUCCESSFUL; } // // Check Size and Alignment // switch ( Request ) { case 1: WRITE_PORT_UCHAR((PUCHAR)(ULONG_PTR)Address, *(PUCHAR)Buffer); *Actual = 1; break; case 2: if ( Address & 1 ) { Status = STATUS_DATATYPE_MISALIGNMENT; } else { WRITE_PORT_USHORT((PUSHORT)(ULONG_PTR)Address, *(PUSHORT)Buffer); *Actual = 2; } break; case 4: if ( Address & 3 ) { Status = STATUS_DATATYPE_MISALIGNMENT; } else { WRITE_PORT_ULONG((PULONG)(ULONG_PTR)Address, *(PULONG)Buffer); *Actual = 4; } break; default: Status = STATUS_INVALID_PARAMETER; *Actual = 0; break; } return Status; } NTSTATUS KdpSysReadMsr( ULONG Msr, PULONG64 Data ) /*++ Routine Description: Reads an MSR. Arguments: Msr - MSR index. Data - Data buffer. Return Value: NTSTATUS. --*/ { NTSTATUS Status = STATUS_SUCCESS; try { *Data = RDMSR(Msr); } except (EXCEPTION_EXECUTE_HANDLER) { *Data = 0; Status = STATUS_NO_SUCH_DEVICE; } return Status; } NTSTATUS KdpSysWriteMsr( ULONG Msr, PULONG64 Data ) /*++ Routine Description: Writes an MSR. Arguments: Msr - MSR index. Data - Data buffer. Return Value: NTSTATUS. --*/ { NTSTATUS Status = STATUS_SUCCESS; try { WRMSR (Msr, *Data); } except (EXCEPTION_EXECUTE_HANDLER) { Status = STATUS_NO_SUCH_DEVICE; } return Status; } /*** KdpGetCallNextOffset - compute "next" instruction on a call-like instruction * * Purpose: * Compute how many bytes are in a call-type instruction * so that a breakpoint can be set upon this instruction's * return. Treat indirect jmps as if they were call/ret/ret * * Returns: * offset to "next" instruction, or 0 if it wasn't a call instruction. * *************************************************************************/ ULONG KdpGetCallNextOffset ( ULONG Pc, PCONTEXT ContextRecord ) { UCHAR membuf[2]; UCHAR opcode; ULONG sib; ULONG disp; if (!NT_SUCCESS(KdpCopyFromPtr( membuf, Pc, 2, NULL ))) { return 0; } opcode = membuf[0]; if ( opcode == 0xe8 ) { // CALL 32 bit disp return Pc+5; } else if ( opcode == 0x9a ) { // CALL 16:32 return Pc+7; } else if ( opcode == 0xff ) { if ( membuf[1] == 0x25) { // JMP indirect return KdpGetReturnAddress( ContextRecord ); } sib = ((membuf[1] & 0x07) == 0x04) ? 1 : 0; disp = (membuf[1] & 0xc0) >> 6; switch (disp) { case 0: if ( (membuf[1] & 0x07) == 0x05 ) { disp = 4; // disp32 alone } else { // disp = 0; // no displacement with reg or sib } break; case 1: // disp = 1; // disp8 with reg or sib break; case 2: disp = 4; // disp32 with reg or sib break; case 3: disp = 0; // direct register addressing (e.g., call esi) break; } return Pc + 2 + sib + disp; } return 0; } // KdpGetCallNextOffset