DisasmCore.cpp@ 2426

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1	/** @file
2	*
3	* VBox disassembler:
4	* Core components
5	*/
6
7	/*
8	* Copyright (C) 2006 InnoTek Systemberatung GmbH
9	*
10	* This file is part of VirtualBox Open Source Edition (OSE), as
11	* available from http://www.virtualbox.org. This file is free software;
12	* you can redistribute it and/or modify it under the terms of the GNU
13	* General Public License as published by the Free Software Foundation,
14	* in version 2 as it comes in the "COPYING" file of the VirtualBox OSE
15	* distribution. VirtualBox OSE is distributed in the hope that it will
16	* be useful, but WITHOUT ANY WARRANTY of any kind.
17	*
18	* If you received this file as part of a commercial VirtualBox
19	* distribution, then only the terms of your commercial VirtualBox
20	* license agreement apply instead of the previous paragraph.
21	*/
22
23
24	/*******************************************************************************
25	* Header Files *
26	*******************************************************************************/
27	#ifdef USING_VISUAL_STUDIO
28	# include <stdafx.h>
29	#endif
30
31	#include <VBox/dis.h>
32	#include <VBox/disopcode.h>
33	#include <VBox/err.h>
34	#define LOG_GROUP LOG_GROUP_DIS
35	#include <VBox/log.h>
36	#include <iprt/assert.h>
37	#include <iprt/string.h>
38	#include <iprt/stdarg.h>
39	#include "DisasmInternal.h"
40	#include "DisasmTables.h"
41
42	#if !defined(DIS_CORE_ONLY) && defined(LOG_ENABLED)
43	# include <stdlib.h>
44	# include <stdio.h>
45	#endif
46
47
48	/*******************************************************************************
49	* Internal Functions *
50	*******************************************************************************/
51	static int disCoreOne(PDISCPUSTATE pCpu, RTUINTPTR InstructionAddr, unsigned *pcbInstruction);
52	#if !defined(DIS_CORE_ONLY) && defined(LOG_ENABLED)
53	static void disasmAddString(char psz, const char pszString);
54	static void disasmAddStringF(char psz, uint32_t cbString, const char pszFormat, ...);
55	static void disasmAddChar(char *psz, char ch);
56	#else
57	# define disasmAddString(psz, pszString) do {} while (0)
58	# ifdef _MSC_VER
59	# define disasmAddStringF __noop
60	# else
61	# define disasmAddStringF(psz, cbString, pszFormat...) do {} while (0) /* Arg wanna get rid of that warning */
62	# endif
63	# define disasmAddChar(psz, ch) do {} while (0)
64	#endif
65
66	static int QueryModRM(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu, int *pSibInc = NULL);
67	static int QueryModRM_SizeOnly(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu, int *pSibInc = NULL);
68	static int UseSIB(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu);
69	static int ParseSIB_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu);
70
71	/*******************************************************************************
72	* Global Variables *
73	*******************************************************************************/
74
75	PFNDISPARSE pfnFullDisasm[IDX_ParseMax] =
76	{
77	ParseIllegal,
78	ParseModRM,
79	UseModRM,
80	ParseImmByte,
81	ParseImmBRel,
82	ParseImmUshort,
83	ParseImmV,
84	ParseImmVRel,
85	ParseImmAddr,
86	ParseFixedReg,
87	ParseImmUlong,
88	ParseImmQword,
89	ParseTwoByteEsc,
90	ParseImmGrpl,
91	ParseShiftGrp2,
92	ParseGrp3,
93	ParseGrp4,
94	ParseGrp5,
95	Parse3DNow,
96	ParseGrp6,
97	ParseGrp7,
98	ParseGrp8,
99	ParseGrp9,
100	ParseGrp10,
101	ParseGrp12,
102	ParseGrp13,
103	ParseGrp14,
104	ParseGrp15,
105	ParseGrp16,
106	ParseModFence,
107	ParseYv,
108	ParseYb,
109	ParseXv,
110	ParseXb,
111	ParseEscFP,
112	ParseNopPause,
113	ParseImmByteSX
114	};
115
116	PFNDISPARSE pfnCalcSize[IDX_ParseMax] =
117	{
118	ParseIllegal,
119	ParseModRM_SizeOnly,
120	UseModRM,
121	ParseImmByte_SizeOnly,
122	ParseImmBRel_SizeOnly,
123	ParseImmUshort_SizeOnly,
124	ParseImmV_SizeOnly,
125	ParseImmVRel_SizeOnly,
126	ParseImmAddr_SizeOnly,
127	ParseFixedReg,
128	ParseImmUlong_SizeOnly,
129	ParseImmQword_SizeOnly,
130	ParseTwoByteEsc,
131	ParseImmGrpl,
132	ParseShiftGrp2,
133	ParseGrp3,
134	ParseGrp4,
135	ParseGrp5,
136	Parse3DNow,
137	ParseGrp6,
138	ParseGrp7,
139	ParseGrp8,
140	ParseGrp9,
141	ParseGrp10,
142	ParseGrp12,
143	ParseGrp13,
144	ParseGrp14,
145	ParseGrp15,
146	ParseGrp16,
147	ParseModFence,
148	ParseYv,
149	ParseYb,
150	ParseXv,
151	ParseXb,
152	ParseEscFP,
153	ParseNopPause,
154	ParseImmByteSX_SizeOnly
155	};
156
157	/**
158	* Array for accessing 32-bit general registers in VMMREGFRAME structure
159	* by register's index from disasm.
160	*/
161	static unsigned g_aReg32Index[] =
162	{
163	RT_OFFSETOF(CPUMCTXCORE, eax), /* USE_REG_EAX */
164	RT_OFFSETOF(CPUMCTXCORE, ecx), /* USE_REG_ECX */
165	RT_OFFSETOF(CPUMCTXCORE, edx), /* USE_REG_EDX */
166	RT_OFFSETOF(CPUMCTXCORE, ebx), /* USE_REG_EBX */
167	RT_OFFSETOF(CPUMCTXCORE, esp), /* USE_REG_ESP */
168	RT_OFFSETOF(CPUMCTXCORE, ebp), /* USE_REG_EBP */
169	RT_OFFSETOF(CPUMCTXCORE, esi), /* USE_REG_ESI */
170	RT_OFFSETOF(CPUMCTXCORE, edi) /* USE_REG_EDI */
171	};
172
173	/**
174	* Macro for accessing 32-bit general purpose registers in CPUMCTXCORE structure.
175	*/
176	#define DIS_READ_REG32(p, idx) ((uint32_t )((char *)(p) + g_aReg32Index[idx]))
177	#define DIS_WRITE_REG32(p, idx, val) ((uint32_t )((char *)(p) + g_aReg32Index[idx]) = val)
178
179	/**
180	* Array for accessing 16-bit general registers in CPUMCTXCORE structure
181	* by register's index from disasm.
182	*/
183	static unsigned g_aReg16Index[] =
184	{
185	RT_OFFSETOF(CPUMCTXCORE, eax), /* USE_REG_AX */
186	RT_OFFSETOF(CPUMCTXCORE, ecx), /* USE_REG_CX */
187	RT_OFFSETOF(CPUMCTXCORE, edx), /* USE_REG_DX */
188	RT_OFFSETOF(CPUMCTXCORE, ebx), /* USE_REG_BX */
189	RT_OFFSETOF(CPUMCTXCORE, esp), /* USE_REG_SP */
190	RT_OFFSETOF(CPUMCTXCORE, ebp), /* USE_REG_BP */
191	RT_OFFSETOF(CPUMCTXCORE, esi), /* USE_REG_SI */
192	RT_OFFSETOF(CPUMCTXCORE, edi) /* USE_REG_DI */
193	};
194
195	/**
196	* Macro for accessing 16-bit general purpose registers in CPUMCTXCORE structure.
197	*/
198	#define DIS_READ_REG16(p, idx) ((uint16_t )((char *)(p) + g_aReg16Index[idx]))
199	#define DIS_WRITE_REG16(p, idx, val) ((uint16_t )((char *)(p) + g_aReg16Index[idx]) = val)
200
201	/**
202	* Array for accessing 8-bit general registers in CPUMCTXCORE structure
203	* by register's index from disasm.
204	*/
205	static unsigned g_aReg8Index[] =
206	{
207	RT_OFFSETOF(CPUMCTXCORE, eax), /* USE_REG_AL */
208	RT_OFFSETOF(CPUMCTXCORE, ecx), /* USE_REG_CL */
209	RT_OFFSETOF(CPUMCTXCORE, edx), /* USE_REG_DL */
210	RT_OFFSETOF(CPUMCTXCORE, ebx), /* USE_REG_BL */
211	RT_OFFSETOF(CPUMCTXCORE, eax) + 1, /* USE_REG_AH */
212	RT_OFFSETOF(CPUMCTXCORE, ecx) + 1, /* USE_REG_CH */
213	RT_OFFSETOF(CPUMCTXCORE, edx) + 1, /* USE_REG_DH */
214	RT_OFFSETOF(CPUMCTXCORE, ebx) + 1 /* USE_REG_BH */
215	};
216
217	/**
218	* Macro for accessing 8-bit general purpose registers in CPUMCTXCORE structure.
219	*/
220	#define DIS_READ_REG8(p, idx) ((uint8_t )((char *)(p) + g_aReg8Index[idx]))
221	#define DIS_WRITE_REG8(p, idx, val) ((uint8_t )((char *)(p) + g_aReg8Index[idx]) = val)
222
223	/**
224	* Array for accessing segment registers in CPUMCTXCORE structure
225	* by register's index from disasm.
226	*/
227	static unsigned g_aRegSegIndex[] =
228	{
229	RT_OFFSETOF(CPUMCTXCORE, es), /* USE_REG_ES */
230	RT_OFFSETOF(CPUMCTXCORE, cs), /* USE_REG_CS */
231	RT_OFFSETOF(CPUMCTXCORE, ss), /* USE_REG_SS */
232	RT_OFFSETOF(CPUMCTXCORE, ds), /* USE_REG_DS */
233	RT_OFFSETOF(CPUMCTXCORE, fs), /* USE_REG_FS */
234	RT_OFFSETOF(CPUMCTXCORE, gs) /* USE_REG_GS */
235	};
236
237	static unsigned g_aRegHidSegIndex[] =
238	{
239	RT_OFFSETOF(CPUMCTXCORE, esHid), /* USE_REG_ES */
240	RT_OFFSETOF(CPUMCTXCORE, csHid), /* USE_REG_CS */
241	RT_OFFSETOF(CPUMCTXCORE, ssHid), /* USE_REG_SS */
242	RT_OFFSETOF(CPUMCTXCORE, dsHid), /* USE_REG_DS */
243	RT_OFFSETOF(CPUMCTXCORE, fsHid), /* USE_REG_FS */
244	RT_OFFSETOF(CPUMCTXCORE, gsHid) /* USE_REG_GS */
245	};
246
247	/**
248	* Macro for accessing segment registers in CPUMCTXCORE structure.
249	*/
250	#define DIS_READ_REGSEG(p, idx) (((uint16_t )((char *)(p) + g_aRegSegIndex[idx])))
251	#define DIS_WRITE_REGSEG(p, idx, val) (((uint16_t )((char *)(p) + g_aRegSegIndex[idx])) = val)
252
253	/**
254	* Parses one instruction.
255	* The result is found in pCpu.
256	*
257	* @returns Success indicator.
258	* @param pCpu Pointer to cpu structure which has DISCPUSTATE::mode set correctly.
259	* @param InstructionAddr Pointer to the instruction to parse.
260	* @param pcbInstruction Where to store the size of the instruction.
261	* NULL is allowed.
262	*/
263	DISDECL(bool) DISCoreOne(PDISCPUSTATE pCpu, RTUINTPTR InstructionAddr, unsigned *pcbInstruction)
264	{
265	/*
266	* Reset instruction settings
267	*/
268	pCpu->prefix = PREFIX_NONE;
269	pCpu->prefix_seg = 0;
270	pCpu->lastprefix = 0;
271	pCpu->addrmode = pCpu->mode;
272	pCpu->opmode = pCpu->mode;
273	pCpu->ModRM = 0;
274	pCpu->SIB = 0;
275	pCpu->param1.parval = 0;
276	pCpu->param2.parval = 0;
277	pCpu->param3.parval = 0;
278	pCpu->param1.szParam[0] = '\0';
279	pCpu->param2.szParam[0] = '\0';
280	pCpu->param3.szParam[0] = '\0';
281	pCpu->param1.flags = 0;
282	pCpu->param2.flags = 0;
283	pCpu->param3.flags = 0;
284	pCpu->param1.size = 0;
285	pCpu->param2.size = 0;
286	pCpu->param3.size = 0;
287	pCpu->pfnReadBytes = 0;
288	pCpu->uFilter = OPTYPE_ALL;
289	pCpu->pfnDisasmFnTable = pfnFullDisasm;
290
291	return VBOX_SUCCESS(disCoreOne(pCpu, InstructionAddr, pcbInstruction));
292	}
293
294	/**
295	* Parses one guest instruction.
296	* The result is found in pCpu and pcbInstruction.
297	*
298	* @returns VBox status code.
299	* @param InstructionAddr Address of the instruction to decode. What this means
300	* is left to the pfnReadBytes function.
301	* @param CpuMode The CPU mode. CPUMODE_32BIT, CPUMODE_16BIT, or CPUMODE_64BIT.
302	* @param pfnReadBytes Callback for reading instruction bytes.
303	* @param pvUser User argument for the instruction reader. (Ends up in dwUserData[0].)
304	* @param pCpu Pointer to cpu structure. Will be initialized.
305	* @param pcbInstruction Where to store the size of the instruction.
306	* NULL is allowed.
307	*/
308	DISDECL(int) DISCoreOneEx(RTUINTPTR InstructionAddr, unsigned CpuMode, PFN_DIS_READBYTES pfnReadBytes, void *pvUser,
309	PDISCPUSTATE pCpu, unsigned *pcbInstruction)
310	{
311	/*
312	* Reset instruction settings
313	*/
314	pCpu->prefix = PREFIX_NONE;
315	pCpu->prefix_seg = 0;
316	pCpu->lastprefix = 0;
317	pCpu->mode = CpuMode;
318	pCpu->addrmode = CpuMode;
319	pCpu->opmode = CpuMode;
320	pCpu->ModRM = 0;
321	pCpu->SIB = 0;
322	pCpu->param1.parval = 0;
323	pCpu->param2.parval = 0;
324	pCpu->param3.parval = 0;
325	pCpu->param1.szParam[0] = '\0';
326	pCpu->param2.szParam[0] = '\0';
327	pCpu->param3.szParam[0] = '\0';
328	pCpu->param1.flags = 0;
329	pCpu->param2.flags = 0;
330	pCpu->param3.flags = 0;
331	pCpu->param1.size = 0;
332	pCpu->param2.size = 0;
333	pCpu->param3.size = 0;
334	pCpu->pfnReadBytes = pfnReadBytes;
335	pCpu->dwUserData[0] = (uintptr_t)pvUser; Assert(sizeof(pCpu->dwUserData) >= sizeof(uintptr_t));
336	pCpu->uFilter = OPTYPE_ALL;
337	pCpu->pfnDisasmFnTable = pfnFullDisasm;
338
339	return disCoreOne(pCpu, InstructionAddr, pcbInstruction);
340	}
341
342	/**
343	* Internal worker for DISCoreOne and DISCoreOneEx.
344	*
345	* @returns VBox status code.
346	* @param pCpu Initialized cpu state.
347	* @param InstructionAddr Instruction address.
348	* @param pcbInstruction Where to store the instruction size. Can be NULL.
349	*/
350	static int disCoreOne(PDISCPUSTATE pCpu, RTUINTPTR InstructionAddr, unsigned *pcbInstruction)
351	{
352	/*
353	* Parse byte by byte.
354	*/
355	unsigned iByte = 0;
356
357	while(1)
358	{
359	uint8_t codebyte = DISReadByte(pCpu, InstructionAddr+iByte);
360	uint8_t opcode = g_aOneByteMapX86[codebyte].opcode;
361
362	/* Hardcoded assumption about OP_* values!! */
363	if (opcode <= OP_LOCK)
364	{
365	pCpu->lastprefix = opcode;
366	switch(opcode)
367	{
368	case OP_INVALID:
369	AssertMsgFailed(("Invalid opcode!!\n"));
370	return VERR_GENERAL_FAILURE; /** @todo better error code. */
371
372	// segment override prefix byte
373	case OP_SEG:
374	pCpu->prefix_seg = g_aOneByteMapX86[codebyte].param1 - OP_PARM_REG_SEG_START;
375	pCpu->prefix \|= PREFIX_SEG;
376	iByte += sizeof(uint8_t);
377	continue; //fetch the next byte
378
379	// lock prefix byte
380	case OP_LOCK:
381	pCpu->prefix \|= PREFIX_LOCK;
382	iByte += sizeof(uint8_t);
383	continue; //fetch the next byte
384
385	// address size override prefix byte
386	case OP_ADRSIZE:
387	pCpu->prefix \|= PREFIX_ADDRSIZE;
388	if(pCpu->mode == CPUMODE_16BIT)
389	pCpu->addrmode = CPUMODE_32BIT;
390	else pCpu->addrmode = CPUMODE_16BIT;
391	iByte += sizeof(uint8_t);
392	continue; //fetch the next byte
393
394	// operand size override prefix byte
395	case OP_OPSIZE:
396	pCpu->prefix \|= PREFIX_OPSIZE;
397	if(pCpu->mode == CPUMODE_16BIT)
398	pCpu->opmode = CPUMODE_32BIT;
399	else pCpu->opmode = CPUMODE_16BIT;
400
401	iByte += sizeof(uint8_t);
402	continue; //fetch the next byte
403
404	// rep and repne are not really prefixes, but we'll treat them as such
405	case OP_REPE:
406	pCpu->prefix \|= PREFIX_REP;
407	iByte += sizeof(uint8_t);
408	continue; //fetch the next byte
409
410	case OP_REPNE:
411	pCpu->prefix \|= PREFIX_REPNE;
412	iByte += sizeof(uint8_t);
413	continue; //fetch the next byte
414	}
415	}
416
417	unsigned uIdx = iByte;
418	iByte += sizeof(uint8_t); //first opcode byte
419
420	pCpu->opaddr = InstructionAddr + uIdx;
421	pCpu->opcode = codebyte;
422
423	int cbInc = ParseInstruction(InstructionAddr + iByte, &g_aOneByteMapX86[pCpu->opcode], pCpu);
424
425	iByte += cbInc;
426	break;
427	}
428
429	pCpu->opsize = iByte;
430	if (pcbInstruction)
431	*pcbInstruction = iByte;
432
433	return VINF_SUCCESS;
434	}
435	//*****************************************************************************
436	//*****************************************************************************
437	DISDECL(int) DISGetParamSize(PDISCPUSTATE pCpu, POP_PARAMETER pParam)
438	{
439	int subtype = OP_PARM_VSUBTYPE(pParam->param);
440
441	if(subtype == OP_PARM_v)
442	{
443	subtype = (pCpu->opmode == CPUMODE_32BIT) ? OP_PARM_d : OP_PARM_w;
444	}
445
446	switch(subtype)
447	{
448	case OP_PARM_b:
449	return 1;
450
451	case OP_PARM_w:
452	return 2;
453
454	case OP_PARM_d:
455	return 4;
456
457	case OP_PARM_q:
458	case OP_PARM_dq:
459	return 8;
460
461	case OP_PARM_p:
462	if(pCpu->addrmode == CPUMODE_32BIT)
463	return 8;
464	else
465	return 4;
466
467	default:
468	if(pParam->size)
469	return pParam->size;
470	else //@todo dangerous!!!
471	return 4;
472	}
473	}
474	//*****************************************************************************
475	//*****************************************************************************
476	DISDECL(int) DISDetectSegReg(PDISCPUSTATE pCpu, POP_PARAMETER pParam)
477	{
478	if(pCpu->prefix & PREFIX_SEG)
479	{
480	/* Use specified SEG: prefix. */
481	return pCpu->prefix_seg;
482	}
483	else
484	{
485	/* Guess segment register by parameter type. */
486	if(pParam->flags & USE_REG_GEN32)
487	{
488	if(pParam->base.reg_gen32 == USE_REG_ESP \|\| pParam->base.reg_gen32 == USE_REG_EBP)
489	return USE_REG_SS;
490	}
491	else
492	if(pParam->flags & USE_REG_GEN16)
493	{
494	if(pParam->base.reg_gen16 == USE_REG_SP \|\| pParam->base.reg_gen16 == USE_REG_BP)
495	return USE_REG_SS;
496	}
497	/* Default is use DS: for data access. */
498	return USE_REG_DS;
499	}
500	}
501	//*****************************************************************************
502	//*****************************************************************************
503	DISDECL(uint8_t) DISQuerySegPrefixByte(PDISCPUSTATE pCpu)
504	{
505	Assert(pCpu->prefix & PREFIX_SEG);
506	switch(pCpu->prefix_seg)
507	{
508	case USE_REG_ES:
509	return 0x26;
510	case USE_REG_CS:
511	return 0x2E;
512	case USE_REG_SS:
513	return 0x36;
514	case USE_REG_DS:
515	return 0x3E;
516	case USE_REG_FS:
517	return 0x64;
518	case USE_REG_GS:
519	return 0x65;
520	default:
521	AssertFailed();
522	return 0;
523	}
524	}
525
526
527	/**
528	* Returns the value of the specified 8 bits general purpose register
529	*
530	*/
531	DISDECL(int) DISFetchReg8(PCPUMCTXCORE pCtx, uint32_t reg8, uint8_t *pVal)
532	{
533	AssertReturn(reg8 < ELEMENTS(g_aReg8Index), VERR_INVALID_PARAMETER);
534
535	*pVal = DIS_READ_REG8(pCtx, reg8);
536	return VINF_SUCCESS;
537	}
538
539	/**
540	* Returns the value of the specified 16 bits general purpose register
541	*
542	*/
543	DISDECL(int) DISFetchReg16(PCPUMCTXCORE pCtx, uint32_t reg16, uint16_t *pVal)
544	{
545	AssertReturn(reg16 < ELEMENTS(g_aReg16Index), VERR_INVALID_PARAMETER);
546
547	*pVal = DIS_READ_REG16(pCtx, reg16);
548	return VINF_SUCCESS;
549	}
550
551	/**
552	* Returns the value of the specified 16 bits general purpose register
553	*
554	*/
555	DISDECL(int) DISFetchReg32(PCPUMCTXCORE pCtx, uint32_t reg32, uint32_t *pVal)
556	{
557	AssertReturn(reg32 < ELEMENTS(g_aReg32Index), VERR_INVALID_PARAMETER);
558
559	*pVal = DIS_READ_REG32(pCtx, reg32);
560	return VINF_SUCCESS;
561	}
562
563	/**
564	* Returns the value of the specified segment register
565	*
566	*/
567	DISDECL(int) DISFetchRegSeg(PCPUMCTXCORE pCtx, uint32_t sel, RTSEL *pVal)
568	{
569	AssertReturn(sel < ELEMENTS(g_aRegSegIndex), VERR_INVALID_PARAMETER);
570
571	AssertCompile(sizeof(uint16_t) == sizeof(RTSEL));
572	*pVal = DIS_READ_REGSEG(pCtx, sel);
573	return VINF_SUCCESS;
574	}
575
576	/**
577	* Returns the value of the specified segment register including a pointer to the hidden register in the supplied cpu context
578	*
579	*/
580	DISDECL(int) DISFetchRegSegEx(PCPUMCTXCORE pCtx, uint32_t sel, RTSEL pVal, CPUMSELREGHID *ppSelHidReg)
581	{
582	AssertReturn(sel < ELEMENTS(g_aRegSegIndex), VERR_INVALID_PARAMETER);
583
584	AssertCompile(sizeof(uint16_t) == sizeof(RTSEL));
585	*pVal = DIS_READ_REGSEG(pCtx, sel);
586	ppSelHidReg = (CPUMSELREGHID )((char *)pCtx + g_aRegHidSegIndex[sel]);
587	return VINF_SUCCESS;
588	}
589
590	/**
591	* Updates the value of the specified 32 bits general purpose register
592	*
593	*/
594	DISDECL(int) DISWriteReg32(PCPUMCTXCORE pRegFrame, uint32_t reg32, uint32_t val32)
595	{
596	AssertReturn(reg32 < ELEMENTS(g_aReg32Index), VERR_INVALID_PARAMETER);
597
598	DIS_WRITE_REG32(pRegFrame, reg32, val32);
599	return VINF_SUCCESS;
600	}
601
602	/**
603	* Updates the value of the specified 16 bits general purpose register
604	*
605	*/
606	DISDECL(int) DISWriteReg16(PCPUMCTXCORE pRegFrame, uint32_t reg16, uint16_t val16)
607	{
608	AssertReturn(reg16 < ELEMENTS(g_aReg16Index), VERR_INVALID_PARAMETER);
609
610	DIS_WRITE_REG16(pRegFrame, reg16, val16);
611	return VINF_SUCCESS;
612	}
613
614	/**
615	* Updates the specified 8 bits general purpose register
616	*
617	*/
618	DISDECL(int) DISWriteReg8(PCPUMCTXCORE pRegFrame, uint32_t reg8, uint8_t val8)
619	{
620	AssertReturn(reg8 < ELEMENTS(g_aReg8Index), VERR_INVALID_PARAMETER);
621
622	DIS_WRITE_REG8(pRegFrame, reg8, val8);
623	return VINF_SUCCESS;
624	}
625
626	/**
627	* Updates the specified segment register
628	*
629	*/
630	DISDECL(int) DISWriteRegSeg(PCPUMCTXCORE pCtx, uint32_t sel, RTSEL val)
631	{
632	AssertReturn(sel < ELEMENTS(g_aRegSegIndex), VERR_INVALID_PARAMETER);
633
634	AssertCompile(sizeof(uint16_t) == sizeof(RTSEL));
635	DIS_WRITE_REGSEG(pCtx, sel, val);
636	return VINF_SUCCESS;
637	}
638
639	/**
640	* Returns the value of the parameter in pParam
641	*
642	* @returns VBox error code
643	* @param pCtx CPU context structure pointer
644	* @param pCpu Pointer to cpu structure which have DISCPUSTATE::mode
645	* set correctly.
646	* @param pParam Pointer to the parameter to parse
647	* @param pParamVal Pointer to parameter value (OUT)
648	* @param parmtype Parameter type
649	*
650	* @note Currently doesn't handle FPU/XMM/MMX/3DNow! parameters correctly!!
651	*
652	*/
653	DISDECL(int) DISQueryParamVal(PCPUMCTXCORE pCtx, PDISCPUSTATE pCpu, POP_PARAMETER pParam, POP_PARAMVAL pParamVal, PARAM_TYPE parmtype)
654	{
655	memset(pParamVal, 0, sizeof(*pParamVal));
656
657	if(pParam->flags & (USE_BASE\|USE_INDEX\|USE_DISPLACEMENT32\|USE_DISPLACEMENT16\|USE_DISPLACEMENT8))
658	{
659	// Effective address
660	pParamVal->type = PARMTYPE_ADDRESS;
661	pParamVal->size = pParam->size;
662
663	if(pParam->flags & USE_BASE)
664	{
665	if(pParam->flags & USE_REG_GEN8)
666	{
667	pParamVal->flags \|= PARAM_VAL8;
668	if(VBOX_FAILURE(DISFetchReg8(pCtx, pParam->base.reg_gen8, &pParamVal->val.val8))) return VERR_INVALID_PARAMETER;
669	}
670	else
671	if(pParam->flags & USE_REG_GEN16)
672	{
673	pParamVal->flags \|= PARAM_VAL16;
674	if(VBOX_FAILURE(DISFetchReg16(pCtx, pParam->base.reg_gen16, &pParamVal->val.val16))) return VERR_INVALID_PARAMETER;
675	}
676	else
677	if(pParam->flags & USE_REG_GEN32)
678	{
679	pParamVal->flags \|= PARAM_VAL32;
680	if(VBOX_FAILURE(DISFetchReg32(pCtx, pParam->base.reg_gen32, &pParamVal->val.val32))) return VERR_INVALID_PARAMETER;
681	}
682	else {
683	AssertFailed();
684	return VERR_INVALID_PARAMETER;
685	}
686	}
687	// Note that scale implies index (SIB byte)
688	if(pParam->flags & USE_INDEX)
689	{
690	uint32_t val32;
691
692	pParamVal->flags \|= PARAM_VAL32;
693	if(VBOX_FAILURE(DISFetchReg32(pCtx, pParam->index.reg_gen, &val32))) return VERR_INVALID_PARAMETER;
694
695	if(pParam->flags & USE_SCALE)
696	{
697	val32 *= pParam->scale;
698	}
699	pParamVal->val.val32 += val32;
700	}
701
702	if(pParam->flags & USE_DISPLACEMENT8)
703	{
704	if(pCpu->mode & CPUMODE_32BIT)
705	{
706	pParamVal->val.val32 += (int32_t)pParam->disp8;
707	}
708	else
709	{
710	pParamVal->val.val16 += (int16_t)pParam->disp8;
711	}
712	}
713	else
714	if(pParam->flags & USE_DISPLACEMENT16)
715	{
716	if(pCpu->mode & CPUMODE_32BIT)
717	{
718	pParamVal->val.val32 += (int32_t)pParam->disp16;
719	}
720	else
721	{
722	pParamVal->val.val16 += pParam->disp16;
723	}
724	}
725	else
726	if(pParam->flags & USE_DISPLACEMENT32)
727	{
728	if(pCpu->mode & CPUMODE_32BIT)
729	{
730	pParamVal->val.val32 += pParam->disp32;
731	}
732	else
733	{
734	Assert(0);
735	}
736	}
737	return VINF_SUCCESS;
738	}
739
740	if(pParam->flags & (USE_REG_GEN8\|USE_REG_GEN16\|USE_REG_GEN32\|USE_REG_FP\|USE_REG_MMX\|USE_REG_XMM\|USE_REG_CR\|USE_REG_DBG\|USE_REG_SEG\|USE_REG_TEST))
741	{
742	if(parmtype == PARAM_DEST)
743	{
744	// Caller needs to interpret the register according to the instruction (source/target, special value etc)
745	pParamVal->type = PARMTYPE_REGISTER;
746	pParamVal->size = pParam->size;
747	return VINF_SUCCESS;
748	}
749	//else PARAM_SOURCE
750
751	pParamVal->type = PARMTYPE_IMMEDIATE;
752
753	if(pParam->flags & USE_REG_GEN8)
754	{
755	pParamVal->flags \|= PARAM_VAL8;
756	pParamVal->size = sizeof(uint8_t);
757	if(VBOX_FAILURE(DISFetchReg8(pCtx, pParam->base.reg_gen8, &pParamVal->val.val8))) return VERR_INVALID_PARAMETER;
758	}
759	else
760	if(pParam->flags & USE_REG_GEN16)
761	{
762	pParamVal->flags \|= PARAM_VAL16;
763	pParamVal->size = sizeof(uint16_t);
764	if(VBOX_FAILURE(DISFetchReg16(pCtx, pParam->base.reg_gen16, &pParamVal->val.val16))) return VERR_INVALID_PARAMETER;
765	}
766	else
767	if(pParam->flags & USE_REG_GEN32)
768	{
769	pParamVal->flags \|= PARAM_VAL32;
770	pParamVal->size = sizeof(uint32_t);
771	if(VBOX_FAILURE(DISFetchReg32(pCtx, pParam->base.reg_gen32, &pParamVal->val.val32))) return VERR_INVALID_PARAMETER;
772	}
773	else
774	{
775	// Caller needs to interpret the register according to the instruction (source/target, special value etc)
776	pParamVal->type = PARMTYPE_REGISTER;
777	}
778	}
779
780	if(pParam->flags & USE_IMMEDIATE)
781	{
782	pParamVal->type = PARMTYPE_IMMEDIATE;
783	if(pParam->flags & (USE_IMMEDIATE8\|USE_IMMEDIATE8_REL))
784	{
785	pParamVal->flags \|= PARAM_VAL8;
786	if(pParam->size == 2)
787	{
788	pParamVal->size = sizeof(uint16_t);
789	pParamVal->val.val16 = (uint8_t)pParam->parval;
790	}
791	else
792	{
793	pParamVal->size = sizeof(uint8_t);
794	pParamVal->val.val8 = (uint8_t)pParam->parval;
795	}
796	}
797	else
798	if(pParam->flags & (USE_IMMEDIATE16\|USE_IMMEDIATE16_REL\|USE_IMMEDIATE_ADDR_0_16\|USE_IMMEDIATE16_SX8))
799	{
800	pParamVal->flags \|= PARAM_VAL16;
801	pParamVal->size = sizeof(uint16_t);
802	pParamVal->val.val16 = (uint16_t)pParam->parval;
803	Assert(pParamVal->size == pParam->size \|\| ((pParam->size == 1) && (pParam->flags & USE_IMMEDIATE16_SX8)) );
804	}
805	else
806	if(pParam->flags & (USE_IMMEDIATE32\|USE_IMMEDIATE32_REL\|USE_IMMEDIATE_ADDR_0_32\|USE_IMMEDIATE32_SX8))
807	{
808	pParamVal->flags \|= PARAM_VAL32;
809	pParamVal->size = sizeof(uint32_t);
810	pParamVal->val.val32 = (uint32_t)pParam->parval;
811	Assert(pParamVal->size == pParam->size \|\| ((pParam->size == 1) && (pParam->flags & USE_IMMEDIATE32_SX8)) );
812	}
813	else
814	if(pParam->flags & (USE_IMMEDIATE64))
815	{
816	pParamVal->flags \|= PARAM_VAL64;
817	pParamVal->size = sizeof(uint64_t);
818	pParamVal->val.val64 = pParam->parval;
819	Assert(pParamVal->size == pParam->size);
820	}
821	else
822	if(pParam->flags & (USE_IMMEDIATE_ADDR_16_16))
823	{
824	pParamVal->flags \|= PARAM_VALFARPTR16;
825	pParamVal->size = sizeof(uint16_t)*2;
826	pParamVal->val.farptr.sel = (uint16_t)RT_LOWORD(pParam->parval >> 16);
827	pParamVal->val.farptr.offset = (uint32_t)RT_LOWORD(pParam->parval);
828	Assert(pParamVal->size == pParam->size);
829	}
830	else
831	if(pParam->flags & (USE_IMMEDIATE_ADDR_16_32))
832	{
833	pParamVal->flags \|= PARAM_VALFARPTR32;
834	pParamVal->size = sizeof(uint16_t) + sizeof(uint32_t);
835	pParamVal->val.farptr.sel = (uint16_t)RT_LOWORD(pParam->parval >> 32);
836	pParamVal->val.farptr.offset = (uint32_t)(pParam->parval & 0xFFFFFFFF);
837	Assert(pParam->size == 8);
838	}
839	}
840	return VINF_SUCCESS;
841	}
842	//*****************************************************************************
843	//*****************************************************************************
844	int ParseInstruction(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, PDISCPUSTATE pCpu)
845	{
846	int size = 0;
847	bool fFiltered = false;
848
849	// Store the opcode format string for disasmPrintf
850	#ifndef DIS_CORE_ONLY
851	pCpu->pszOpcode = pOp->pszOpcode;
852	#endif
853	pCpu->pCurInstr = pOp;
854
855	/*
856	* Apply filter to instruction type to determine if a full disassembly is required.
857	* @note Multibyte opcodes are always marked harmless until the final byte.
858	*/
859	if ((pOp->optype & pCpu->uFilter) == 0)
860	{
861	fFiltered = true;
862	pCpu->pfnDisasmFnTable = pfnCalcSize;
863	}
864	else
865	{
866	/* Not filtered out -> full disassembly */
867	pCpu->pfnDisasmFnTable = pfnFullDisasm;
868	}
869
870	// Should contain the parameter type on input
871	pCpu->param1.param = pOp->param1;
872	pCpu->param2.param = pOp->param2;
873	pCpu->param3.param = pOp->param3;
874
875	if(pOp->idxParse1 != IDX_ParseNop) {
876	size += pCpu->pfnDisasmFnTable[pOp->idxParse1](lpszCodeBlock, pOp, &pCpu->param1, pCpu);
877	if (fFiltered == false) pCpu->param1.size = DISGetParamSize(pCpu, &pCpu->param1);
878	}
879	if(pOp->idxParse2 != IDX_ParseNop) {
880	size += pCpu->pfnDisasmFnTable[pOp->idxParse2](lpszCodeBlock+size, pOp, &pCpu->param2, pCpu);
881	if (fFiltered == false) pCpu->param2.size = DISGetParamSize(pCpu, &pCpu->param2);
882	}
883	if(pOp->idxParse3 != IDX_ParseNop) {
884	size += pCpu->pfnDisasmFnTable[pOp->idxParse3](lpszCodeBlock+size, pOp, &pCpu->param3, pCpu);
885	if (fFiltered == false) pCpu->param3.size = DISGetParamSize(pCpu, &pCpu->param3);
886	}
887	// else simple one byte instruction
888
889	return size;
890	}
891	//*****************************************************************************
892	/* Floating point opcode parsing */
893	//*****************************************************************************
894	int ParseEscFP(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
895	{
896	int index;
897	const OPCODE *fpop;
898	int size = 0;
899
900	pCpu->ModRM = DISReadByte(pCpu, lpszCodeBlock);
901
902	index = pCpu->opcode - 0xD8;
903	if(pCpu->ModRM <= 0xBF)
904	{
905	fpop = &(g_paMapX86_FP_Low[index])[MODRM_REG(pCpu->ModRM)];
906	pCpu->pCurInstr = (PCOPCODE)fpop;
907
908	// Should contain the parameter type on input
909	pCpu->param1.parval = fpop->param1;
910	pCpu->param2.parval = fpop->param2;
911
912	/*
913	* Apply filter to instruction type to determine if a full disassembly is required.
914	* @note Multibyte opcodes are always marked harmless until the final byte.
915	*/
916	if ((fpop->optype & pCpu->uFilter) == 0)
917	{
918	pCpu->pfnDisasmFnTable = pfnCalcSize;
919	}
920	else
921	{
922	/* Not filtered out -> full disassembly */
923	pCpu->pfnDisasmFnTable = pfnFullDisasm;
924	}
925
926	// Little hack to make sure the ModRM byte is included in the returned size
927	if(fpop->idxParse1 != IDX_ParseModRM && fpop->idxParse2 != IDX_ParseModRM)
928	{
929	size = sizeof(uint8_t); //ModRM byte
930	}
931
932	if(fpop->idxParse1 != IDX_ParseNop) {
933	size += pCpu->pfnDisasmFnTable[fpop->idxParse1](lpszCodeBlock+size, (PCOPCODE)fpop, pParam, pCpu);
934	}
935	if(fpop->idxParse2 != IDX_ParseNop) {
936	size += pCpu->pfnDisasmFnTable[fpop->idxParse2](lpszCodeBlock+size, (PCOPCODE)fpop, pParam, pCpu);
937	}
938	}
939	else
940	{
941	size = sizeof(uint8_t); //ModRM byte only
942	fpop = &(g_paMapX86_FP_High[index])[pCpu->ModRM - 0xC0];
943	pCpu->pCurInstr = (PCOPCODE)fpop;
944
945	/*
946	* Apply filter to instruction type to determine if a full disassembly is required.
947	* @note Multibyte opcodes are always marked harmless until the final byte.
948	*/
949	if ((fpop->optype & pCpu->uFilter) == 0)
950	{
951	pCpu->pfnDisasmFnTable = pfnCalcSize;
952	}
953	else
954	{
955	/* Not filtered out -> full disassembly */
956	pCpu->pfnDisasmFnTable = pfnFullDisasm;
957	}
958	}
959
960	// Store the opcode format string for disasmPrintf
961	#ifndef DIS_CORE_ONLY
962	pCpu->pszOpcode = fpop->pszOpcode;
963	#endif
964
965	return size;
966	}
967	//*****************************************************************************
968	// SIB byte: (32 bits mode only)
969	// 7 - 6 5 - 3 2-0
970	// Scale Index Base
971	//*****************************************************************************
972	const char *szSIBBaseReg[8] = {"EAX", "ECX", "EDX", "EBX", "ESP", "EBP", "ESI", "EDI"};
973	const char *szSIBIndexReg[8] = {"EAX", "ECX", "EDX", "EBX", NULL, "EBP", "ESI", "EDI"};
974	const char szSIBScale[4] = {"", "2", "4", "8"};
975
976	//*****************************************************************************
977	int UseSIB(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
978	{
979	int scale, base, index;
980	char szTemp[32];
981	szTemp[0] = '\0';
982
983	scale = SIB_SCALE(pCpu->SIB);
984	base = SIB_BASE(pCpu->SIB);
985	index = SIB_INDEX(pCpu->SIB);
986
987	if(szSIBIndexReg[index])
988	{
989	pParam->flags \|= USE_INDEX;
990	pParam->index.reg_gen = index;
991
992	if(scale != 0)
993	{
994	pParam->flags \|= USE_SCALE;
995	pParam->scale = (1<<scale);
996	}
997
998	if(base == 5 && MODRM_MOD(pCpu->ModRM) == 0)
999	disasmAddStringF(szTemp, sizeof(szTemp), "%s%s", szSIBIndexReg[index], szSIBScale[scale]);
1000	else
1001	disasmAddStringF(szTemp, sizeof(szTemp), "%s+%s%s", szSIBBaseReg[base], szSIBIndexReg[index], szSIBScale[scale]);
1002	}
1003	else
1004	{
1005	if(base != 5 \|\| MODRM_MOD(pCpu->ModRM) != 0)
1006	disasmAddStringF(szTemp, sizeof(szTemp), "%s", szSIBBaseReg[base]);
1007	}
1008
1009	if(base == 5 && MODRM_MOD(pCpu->ModRM) == 0)
1010	{
1011	// [scaled index] + disp32
1012	disasmAddString(pParam->szParam, &szTemp[0]);
1013	pParam->flags \|= USE_DISPLACEMENT32;
1014	pParam->disp32 = pCpu->disp;
1015	disasmAddChar(pParam->szParam, '+');
1016	disasmPrintDisp32(pParam);
1017	}
1018	else
1019	{
1020	disasmAddString(pParam->szParam, szTemp);
1021
1022	pParam->flags \|= USE_BASE \| USE_REG_GEN32;
1023	pParam->base.reg_gen32 = base;
1024	}
1025	return 0; //already fetched everything in ParseSIB
1026	}
1027	//*****************************************************************************
1028	//*****************************************************************************
1029	int ParseSIB(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1030	{
1031	int size = sizeof(uint8_t), base;
1032
1033	pCpu->SIB = DISReadByte(pCpu, lpszCodeBlock);
1034	lpszCodeBlock += size;
1035
1036	base = SIB_BASE(pCpu->SIB);
1037	if(base == 5 && MODRM_MOD(pCpu->ModRM) == 0)
1038	{//additional 32 bits displacement
1039	pCpu->disp = DISReadDWord(pCpu, lpszCodeBlock);
1040	size += sizeof(int32_t);
1041	}
1042	return size;
1043	}
1044	//*****************************************************************************
1045	//*****************************************************************************
1046	int ParseSIB_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1047	{
1048	int size = sizeof(uint8_t), base;
1049
1050	pCpu->SIB = DISReadByte(pCpu, lpszCodeBlock);
1051	lpszCodeBlock += size;
1052
1053	base = SIB_BASE(pCpu->SIB);
1054	if(base == 5 && MODRM_MOD(pCpu->ModRM) == 0)
1055	{//additional 32 bits displacement
1056	size += sizeof(int32_t);
1057	}
1058	return size;
1059	}
1060	//*****************************************************************************
1061	// ModR/M byte:
1062	// 7 - 6 5 - 3 2-0
1063	// Mod Reg/Opcode R/M
1064	//*****************************************************************************
1065	int UseModRM(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1066	{
1067	int reg = MODRM_REG(pCpu->ModRM);
1068	int rm = MODRM_RM(pCpu->ModRM);
1069	int mod = MODRM_MOD(pCpu->ModRM);
1070	int vtype = OP_PARM_VTYPE(pParam->param);
1071
1072	switch(vtype)
1073	{
1074	case OP_PARM_G: //general purpose register
1075	disasmModRMReg(pCpu, pOp, reg, pParam, 0);
1076	return 0;
1077
1078	default:
1079	if (IS_OP_PARM_RARE(vtype))
1080	{
1081	switch(vtype)
1082	{
1083	case OP_PARM_C: //control register
1084	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "CR%d", reg);
1085	pParam->flags \|= USE_REG_CR;
1086	pParam->base.reg_ctrl = reg;
1087	return 0;
1088
1089	case OP_PARM_D: //debug register
1090	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "DR%d", reg);
1091	pParam->flags \|= USE_REG_DBG;
1092	pParam->base.reg_dbg = reg;
1093	return 0;
1094
1095	case OP_PARM_P: //MMX register
1096	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "MM%d", reg);
1097	pParam->flags \|= USE_REG_MMX;
1098	pParam->base.reg_mmx = reg;
1099	return 0;
1100
1101	case OP_PARM_S: //segment register
1102	disasmModRMSReg(pCpu, pOp, reg, pParam);
1103	pParam->flags \|= USE_REG_SEG;
1104	return 0;
1105
1106	case OP_PARM_T: //test register
1107	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "TR%d", reg);
1108	pParam->flags \|= USE_REG_TEST;
1109	pParam->base.reg_test = reg;
1110	return 0;
1111
1112	case OP_PARM_V: //XMM register
1113	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "XMM%d", reg);
1114	pParam->flags \|= USE_REG_XMM;
1115	pParam->base.reg_xmm = reg;
1116	return 0;
1117
1118	case OP_PARM_W: //XMM register or memory operand
1119	if (mod == 3)
1120	{
1121	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "XMM%d", rm);
1122	pParam->flags \|= USE_REG_XMM;
1123	pParam->base.reg_xmm = rm;
1124	return 0;
1125	}
1126	/* else memory operand */
1127	}
1128	}
1129	}
1130
1131	//TODO: bound
1132
1133	if(pCpu->addrmode == CPUMODE_32BIT)
1134	{//32 bits addressing mode
1135	switch(mod)
1136	{
1137	case 0: //effective address
1138	disasmGetPtrString(pCpu, pOp, pParam);
1139	disasmAddChar(pParam->szParam, '[');
1140	if(rm == 4) {//SIB byte follows ModRM
1141	UseSIB(lpszCodeBlock, pOp, pParam, pCpu);
1142	}
1143	else
1144	if(rm == 5) {//32 bits displacement
1145	pParam->flags \|= USE_DISPLACEMENT32;
1146	pParam->disp32 = pCpu->disp;
1147	disasmPrintDisp32(pParam);
1148	}
1149	else {//register address
1150	pParam->flags \|= USE_BASE;
1151	disasmModRMReg(pCpu, pOp, rm, pParam, 1);
1152	}
1153	disasmAddChar(pParam->szParam, ']');
1154	break;
1155
1156	case 1: //effective address + 8 bits displacement
1157	disasmGetPtrString(pCpu, pOp, pParam);
1158	disasmAddChar(pParam->szParam, '[');
1159	if(rm == 4) {//SIB byte follows ModRM
1160	UseSIB(lpszCodeBlock, pOp, pParam, pCpu);
1161	}
1162	else
1163	{
1164	pParam->flags \|= USE_BASE;
1165	disasmModRMReg(pCpu, pOp, rm, pParam, 1);
1166	}
1167	pParam->disp8 = pCpu->disp;
1168	pParam->flags \|= USE_DISPLACEMENT8;
1169
1170	if(pParam->disp8 != 0)
1171	{
1172	if(pParam->disp8 > 0)
1173	disasmAddChar(pParam->szParam, '+');
1174	disasmPrintDisp8(pParam);
1175	}
1176	disasmAddChar(pParam->szParam, ']');
1177	break;
1178
1179	case 2: //effective address + 32 bits displacement
1180	disasmGetPtrString(pCpu, pOp, pParam);
1181	disasmAddChar(pParam->szParam, '[');
1182	if(rm == 4) {//SIB byte follows ModRM
1183	UseSIB(lpszCodeBlock, pOp, pParam, pCpu);
1184	}
1185	else
1186	{
1187	pParam->flags \|= USE_BASE;
1188	disasmModRMReg(pCpu, pOp, rm, pParam, 1);
1189	}
1190	pParam->disp32 = pCpu->disp;
1191	pParam->flags \|= USE_DISPLACEMENT32;
1192
1193	if(pParam->disp32 != 0)
1194	{
1195	disasmAddChar(pParam->szParam, '+');
1196	disasmPrintDisp32(pParam);
1197	}
1198	disasmAddChar(pParam->szParam, ']');
1199	break;
1200
1201	case 3: //registers
1202	disasmModRMReg(pCpu, pOp, rm, pParam, 0);
1203	break;
1204	}
1205	}
1206	else
1207	{//16 bits addressing mode
1208	switch(mod)
1209	{
1210	case 0: //effective address
1211	disasmGetPtrString(pCpu, pOp, pParam);
1212	disasmAddChar(pParam->szParam, '[');
1213	if(rm == 6)
1214	{//16 bits displacement
1215	pParam->disp16 = pCpu->disp;
1216	pParam->flags \|= USE_DISPLACEMENT16;
1217	disasmPrintDisp16(pParam);
1218	}
1219	else
1220	{
1221	pParam->flags \|= USE_BASE;
1222	disasmModRMReg16(pCpu, pOp, rm, pParam);
1223	}
1224	disasmAddChar(pParam->szParam, ']');
1225	break;
1226
1227	case 1: //effective address + 8 bits displacement
1228	disasmGetPtrString(pCpu, pOp, pParam);
1229	disasmAddChar(pParam->szParam, '[');
1230	disasmModRMReg16(pCpu, pOp, rm, pParam);
1231	pParam->disp8 = pCpu->disp;
1232	pParam->flags \|= USE_BASE \| USE_DISPLACEMENT8;
1233
1234	if(pParam->disp8 != 0)
1235	{
1236	if(pParam->disp8 > 0)
1237	disasmAddChar(pParam->szParam, '+');
1238	disasmPrintDisp8(pParam);
1239	}
1240	disasmAddChar(pParam->szParam, ']');
1241	break;
1242
1243	case 2: //effective address + 16 bits displacement
1244	disasmGetPtrString(pCpu, pOp, pParam);
1245	disasmAddChar(pParam->szParam, '[');
1246	disasmModRMReg16(pCpu, pOp, rm, pParam);
1247	pParam->disp16 = pCpu->disp;
1248	pParam->flags \|= USE_BASE \| USE_DISPLACEMENT16;
1249
1250	if(pParam->disp16 != 0)
1251	{
1252	disasmAddChar(pParam->szParam, '+');
1253	disasmPrintDisp16(pParam);
1254	}
1255	disasmAddChar(pParam->szParam, ']');
1256	break;
1257
1258	case 3: //registers
1259	disasmModRMReg(pCpu, pOp, rm, pParam, 0);
1260	break;
1261	}
1262	}
1263	return 0; //everything was already fetched in ParseModRM
1264	}
1265	//*****************************************************************************
1266	// Query the size of the ModRM parameters and fetch the immediate data (if any)
1267	//*****************************************************************************
1268	int QueryModRM(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu, int *pSibInc)
1269	{
1270	int mod, rm, sibinc;
1271	int size = 0;
1272
1273	rm = MODRM_RM(pCpu->ModRM);
1274	mod = MODRM_MOD(pCpu->ModRM);
1275
1276	if(!pSibInc)
1277	{
1278	pSibInc = &sibinc;
1279	}
1280
1281	*pSibInc = 0;
1282
1283	if(pCpu->addrmode == CPUMODE_32BIT)
1284	{//32 bits addressing mode
1285	if(mod != 3 && rm == 4)
1286	{//SIB byte follows ModRM
1287	*pSibInc = ParseSIB(lpszCodeBlock, pOp, pParam, pCpu);
1288	lpszCodeBlock += *pSibInc;
1289	size += *pSibInc;
1290	}
1291
1292	switch(mod)
1293	{
1294	case 0: //effective address
1295	if(rm == 5) {//32 bits displacement
1296	pCpu->disp = DISReadDWord(pCpu, lpszCodeBlock);
1297	size += sizeof(int32_t);
1298	}
1299	//else register address
1300	break;
1301
1302	case 1: //effective address + 8 bits displacement
1303	pCpu->disp = (int8_t)DISReadByte(pCpu, lpszCodeBlock);
1304	size += sizeof(char);
1305	break;
1306
1307	case 2: //effective address + 32 bits displacement
1308	pCpu->disp = DISReadDWord(pCpu, lpszCodeBlock);
1309	size += sizeof(int32_t);
1310	break;
1311
1312	case 3: //registers
1313	break;
1314	}
1315	}
1316	else
1317	{//16 bits addressing mode
1318	switch(mod)
1319	{
1320	case 0: //effective address
1321	if(rm == 6) {
1322	pCpu->disp = DISReadWord(pCpu, lpszCodeBlock);
1323	size += sizeof(uint16_t);
1324	}
1325	break;
1326
1327	case 1: //effective address + 8 bits displacement
1328	pCpu->disp = (int8_t)DISReadByte(pCpu, lpszCodeBlock);
1329	size += sizeof(char);
1330	break;
1331
1332	case 2: //effective address + 16 bits displacement
1333	pCpu->disp = (int16_t)DISReadWord(pCpu, lpszCodeBlock);
1334	size += sizeof(uint16_t);
1335	break;
1336
1337	case 3: //registers
1338	break;
1339	}
1340	}
1341	return size;
1342	}
1343	//*****************************************************************************
1344	// Query the size of the ModRM parameters and fetch the immediate data (if any)
1345	//*****************************************************************************
1346	int QueryModRM_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu, int *pSibInc)
1347	{
1348	int mod, rm, sibinc;
1349	int size = 0;
1350
1351	rm = MODRM_RM(pCpu->ModRM);
1352	mod = MODRM_MOD(pCpu->ModRM);
1353
1354	if(!pSibInc)
1355	{
1356	pSibInc = &sibinc;
1357	}
1358
1359	*pSibInc = 0;
1360
1361	if(pCpu->addrmode == CPUMODE_32BIT)
1362	{//32 bits addressing mode
1363	if(mod != 3 && rm == 4)
1364	{//SIB byte follows ModRM
1365	*pSibInc = ParseSIB_SizeOnly(lpszCodeBlock, pOp, pParam, pCpu);
1366	lpszCodeBlock += *pSibInc;
1367	size += *pSibInc;
1368	}
1369
1370	switch(mod)
1371	{
1372	case 0: //effective address
1373	if(rm == 5) {//32 bits displacement
1374	size += sizeof(int32_t);
1375	}
1376	//else register address
1377	break;
1378
1379	case 1: //effective address + 8 bits displacement
1380	size += sizeof(char);
1381	break;
1382
1383	case 2: //effective address + 32 bits displacement
1384	size += sizeof(int32_t);
1385	break;
1386
1387	case 3: //registers
1388	break;
1389	}
1390	}
1391	else
1392	{//16 bits addressing mode
1393	switch(mod)
1394	{
1395	case 0: //effective address
1396	if(rm == 6) {
1397	size += sizeof(uint16_t);
1398	}
1399	break;
1400
1401	case 1: //effective address + 8 bits displacement
1402	size += sizeof(char);
1403	break;
1404
1405	case 2: //effective address + 16 bits displacement
1406	size += sizeof(uint16_t);
1407	break;
1408
1409	case 3: //registers
1410	break;
1411	}
1412	}
1413	return size;
1414	}
1415	//*****************************************************************************
1416	//*****************************************************************************
1417	int ParseIllegal(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1418	{
1419	AssertFailed();
1420	return 0;
1421	}
1422	//*****************************************************************************
1423	//*****************************************************************************
1424	int ParseModRM(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1425	{
1426	int size = sizeof(uint8_t); //ModRM byte
1427	int sibinc;
1428
1429	pCpu->ModRM = DISReadByte(pCpu, lpszCodeBlock);
1430	lpszCodeBlock += sizeof(uint8_t);
1431
1432	size += QueryModRM(lpszCodeBlock, pOp, pParam, pCpu, &sibinc);
1433	lpszCodeBlock += sibinc;
1434
1435	UseModRM(lpszCodeBlock, pOp, pParam, pCpu);
1436
1437	return size;
1438	}
1439	//*****************************************************************************
1440	//*****************************************************************************
1441	int ParseModRM_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1442	{
1443	int size = sizeof(uint8_t); //ModRM byte
1444	int sibinc;
1445
1446	pCpu->ModRM = DISReadByte(pCpu, lpszCodeBlock);
1447	lpszCodeBlock += sizeof(uint8_t);
1448
1449	size += QueryModRM_SizeOnly(lpszCodeBlock, pOp, pParam, pCpu, &sibinc);
1450	lpszCodeBlock += sibinc;
1451
1452	/* UseModRM is not necessary here; we're only interested in the opcode size */
1453	return size;
1454	}
1455	//*****************************************************************************
1456	//*****************************************************************************
1457	int ParseModFence(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1458	{
1459	////AssertMsgFailed(("??\n"));
1460	//nothing to do apparently
1461	return 0;
1462	}
1463	//*****************************************************************************
1464	//*****************************************************************************
1465	int ParseImmByte(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1466	{
1467	pParam->parval = DISReadByte(pCpu, lpszCodeBlock);
1468	pParam->flags \|= USE_IMMEDIATE8;
1469
1470	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%02Xh", (uint32_t)pParam->parval);
1471	return sizeof(uint8_t);
1472	}
1473	//*****************************************************************************
1474	//*****************************************************************************
1475	int ParseImmByte_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1476	{
1477	return sizeof(uint8_t);
1478	}
1479	//*****************************************************************************
1480	//*****************************************************************************
1481	int ParseImmByteSX(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1482	{
1483	if(pCpu->opmode == CPUMODE_32BIT)
1484	{
1485	pParam->parval = (uint32_t)(int8_t)DISReadByte(pCpu, lpszCodeBlock);
1486	pParam->flags \|= USE_IMMEDIATE32_SX8;
1487	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%08Xh", (uint32_t)pParam->parval);
1488	}
1489	else
1490	{
1491	pParam->parval = (uint16_t)(int8_t)DISReadByte(pCpu, lpszCodeBlock);
1492	pParam->flags \|= USE_IMMEDIATE16_SX8;
1493	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%04Xh", (uint16_t)pParam->parval);
1494	}
1495	return sizeof(uint8_t);
1496	}
1497	//*****************************************************************************
1498	//*****************************************************************************
1499	int ParseImmByteSX_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1500	{
1501	return sizeof(uint8_t);
1502	}
1503	//*****************************************************************************
1504	//*****************************************************************************
1505	int ParseImmUshort(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1506	{
1507	pParam->parval = DISReadWord(pCpu, lpszCodeBlock);
1508	pParam->flags \|= USE_IMMEDIATE16;
1509
1510	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%04Xh", (uint16_t)pParam->parval);
1511	return sizeof(uint16_t);
1512	}
1513	//*****************************************************************************
1514	//*****************************************************************************
1515	int ParseImmUshort_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1516	{
1517	return sizeof(uint16_t);
1518	}
1519	//*****************************************************************************
1520	//*****************************************************************************
1521	int ParseImmUlong(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1522	{
1523	pParam->parval = DISReadDWord(pCpu, lpszCodeBlock);
1524	pParam->flags \|= USE_IMMEDIATE32;
1525
1526	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%08Xh", (uint32_t)pParam->parval);
1527	return sizeof(uint32_t);
1528	}
1529	//*****************************************************************************
1530	//*****************************************************************************
1531	int ParseImmUlong_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1532	{
1533	return sizeof(uint32_t);
1534	}
1535	//*****************************************************************************
1536	//*****************************************************************************
1537	int ParseImmQword(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1538	{
1539	pParam->parval = DISReadQWord(pCpu, lpszCodeBlock);
1540	pParam->flags \|= USE_IMMEDIATE64;
1541
1542	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%08X", (uint32_t)pParam->parval);
1543	disasmAddStringF(&pParam->szParam[9], sizeof(pParam->szParam)-9, "%08Xh", (uint32_t)(pParam->parval >> 32));
1544	return sizeof(uint64_t);
1545	}
1546	//*****************************************************************************
1547	//*****************************************************************************
1548	int ParseImmQword_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1549	{
1550	return sizeof(uint64_t);
1551	}
1552	//*****************************************************************************
1553	//*****************************************************************************
1554	int ParseImmV(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1555	{
1556	if(pCpu->opmode == CPUMODE_32BIT)
1557	{
1558	pParam->parval = DISReadDWord(pCpu, lpszCodeBlock);
1559	pParam->flags \|= USE_IMMEDIATE32;
1560
1561	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%08Xh", (uint32_t)pParam->parval);
1562	return sizeof(uint32_t);
1563	}
1564	else
1565	{
1566	pParam->parval = DISReadWord(pCpu, lpszCodeBlock);
1567	pParam->flags \|= USE_IMMEDIATE16;
1568
1569	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%04Xh", (uint32_t)pParam->parval);
1570	return sizeof(uint16_t);
1571	}
1572	}
1573	//*****************************************************************************
1574	//*****************************************************************************
1575	int ParseImmV_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1576	{
1577	if(pCpu->opmode == CPUMODE_32BIT)
1578	{
1579	return sizeof(uint32_t);
1580	}
1581	else
1582	{
1583	return sizeof(uint16_t);
1584	}
1585	}
1586	//*****************************************************************************
1587	// Relative displacement for branches (rel. to next instruction)
1588	//*****************************************************************************
1589	int ParseImmBRel(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1590	{
1591	pParam->parval = DISReadByte(pCpu, lpszCodeBlock);
1592	pParam->flags \|= USE_IMMEDIATE8_REL;
1593
1594	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), " (0%02Xh)", (uint32_t)pParam->parval);
1595	return sizeof(char);
1596	}
1597	//*****************************************************************************
1598	// Relative displacement for branches (rel. to next instruction)
1599	//*****************************************************************************
1600	int ParseImmBRel_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1601	{
1602	return sizeof(char);
1603	}
1604	//*****************************************************************************
1605	// Relative displacement for branches (rel. to next instruction)
1606	//*****************************************************************************
1607	int ParseImmVRel(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1608	{
1609	if(pCpu->opmode == CPUMODE_32BIT)
1610	{
1611	pParam->parval = DISReadDWord(pCpu, lpszCodeBlock);
1612	pParam->flags \|= USE_IMMEDIATE32_REL;
1613
1614	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), " (0%08Xh)", (uint32_t)pParam->parval);
1615	return sizeof(int32_t);
1616	}
1617	else
1618	{
1619	pParam->parval = DISReadWord(pCpu, lpszCodeBlock);
1620	pParam->flags \|= USE_IMMEDIATE16_REL;
1621
1622	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), " (0%04Xh)", (uint32_t)pParam->parval);
1623	return sizeof(uint16_t);
1624	}
1625	}
1626	//*****************************************************************************
1627	// Relative displacement for branches (rel. to next instruction)
1628	//*****************************************************************************
1629	int ParseImmVRel_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1630	{
1631	if(pCpu->opmode == CPUMODE_32BIT)
1632	{
1633	return sizeof(int32_t);
1634	}
1635	else
1636	{
1637	return sizeof(uint16_t);
1638	}
1639	}
1640	//*****************************************************************************
1641	//*****************************************************************************
1642	int ParseImmAddr(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1643	{
1644	disasmGetPtrString(pCpu, pOp, pParam);
1645	if(pCpu->addrmode == CPUMODE_32BIT)
1646	{
1647	if(OP_PARM_VSUBTYPE(pParam->param) == OP_PARM_p)
1648	{// far 16:32 pointer
1649	pParam->parval = DISReadDWord(pCpu, lpszCodeBlock);
1650	((uint32_t)&pParam->parval+1) = DISReadWord(pCpu, lpszCodeBlock+sizeof(uint32_t));
1651	pParam->flags \|= USE_IMMEDIATE_ADDR_16_32;
1652
1653	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%04X:0%08Xh", (uint32_t)(pParam->parval>>32), (uint32_t)pParam->parval);
1654	return sizeof(uint32_t) + sizeof(uint16_t);
1655	}
1656	else
1657	{// near 32 bits pointer
1658	/*
1659	* Note: used only in "mov al\|ax\|eax, [Addr]" and "mov [Addr], al\|ax\|eax"
1660	* so we treat it like displacement.
1661	*/
1662	pParam->disp32 = DISReadDWord(pCpu, lpszCodeBlock);
1663	pParam->flags \|= USE_DISPLACEMENT32;
1664
1665	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "[0%08Xh]", pParam->disp32);
1666	return sizeof(uint32_t);
1667	}
1668	}
1669	else
1670	{
1671	if(OP_PARM_VSUBTYPE(pParam->param) == OP_PARM_p)
1672	{// far 16:16 pointer
1673	pParam->parval = DISReadDWord(pCpu, lpszCodeBlock);
1674	pParam->flags \|= USE_IMMEDIATE_ADDR_16_16;
1675
1676	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "0%04X:0%04Xh", (uint32_t)(pParam->parval>>16), (uint16_t)pParam->parval );
1677	return sizeof(uint32_t);
1678	}
1679	else
1680	{// near 16 bits pointer
1681	/*
1682	* Note: used only in "mov al\|ax\|eax, [Addr]" and "mov [Addr], al\|ax\|eax"
1683	* so we treat it like displacement.
1684	*/
1685	pParam->disp16 = DISReadWord(pCpu, lpszCodeBlock);
1686	pParam->flags \|= USE_DISPLACEMENT16;
1687
1688	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "[0%04Xh]", (uint32_t)pParam->disp16);
1689	return sizeof(uint16_t);
1690	}
1691	}
1692	}
1693	//*****************************************************************************
1694	//*****************************************************************************
1695	int ParseImmAddr_SizeOnly(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1696	{
1697	if(pCpu->addrmode == CPUMODE_32BIT)
1698	{
1699	if(OP_PARM_VSUBTYPE(pParam->param) == OP_PARM_p)
1700	{// far 16:32 pointer
1701	return sizeof(uint32_t) + sizeof(uint16_t);
1702	}
1703	else
1704	{// near 32 bits pointer
1705	return sizeof(uint32_t);
1706	}
1707	}
1708	else
1709	{
1710	if(OP_PARM_VSUBTYPE(pParam->param) == OP_PARM_p)
1711	{// far 16:16 pointer
1712	return sizeof(uint32_t);
1713	}
1714	else
1715	{// near 16 bits pointer
1716	return sizeof(uint16_t);
1717	}
1718	}
1719	}
1720	//*****************************************************************************
1721	//*****************************************************************************
1722	int ParseFixedReg(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1723	{
1724	/*
1725	* Sets up flags for stored in OPC fixed registers.
1726	*/
1727
1728	if(pParam->param == OP_PARM_NONE)
1729	{
1730	/* No parameter at all. */
1731	return 0;
1732	}
1733
1734	if(pParam->param < OP_PARM_REG_SEG_START)
1735	{
1736	/* 32-bit EAX..EDI registers. */
1737
1738	if(pCpu->opmode == CPUMODE_32BIT)
1739	{
1740	/* Use 32-bit registers. */
1741	pParam->base.reg_gen32 = pParam->param - OP_PARM_REG_GEN32_START;
1742	pParam->flags \|= USE_REG_GEN32;
1743	pParam->size = 4;
1744	}
1745	else
1746	{
1747	/* Use 16-bit registers. */
1748	pParam->base.reg_gen16 = pParam->param - OP_PARM_REG_GEN32_START;
1749	pParam->flags \|= USE_REG_GEN16;
1750	pParam->size = 2;
1751	pParam->param = pParam->param - OP_PARM_REG_GEN32_START + OP_PARM_REG_GEN16_START;
1752	}
1753	}
1754	else
1755	if(pParam->param < OP_PARM_REG_GEN16_START)
1756	{
1757	/* Segment ES..GS registers. */
1758	pParam->base.reg_seg = pParam->param - OP_PARM_REG_SEG_START;
1759	pParam->flags \|= USE_REG_SEG;
1760	pParam->size = 2;
1761	}
1762	else
1763	if(pParam->param < OP_PARM_REG_GEN8_START)
1764	{
1765	/* 16-bit AX..DI registers. */
1766	pParam->base.reg_gen16 = pParam->param - OP_PARM_REG_GEN16_START;
1767	pParam->flags \|= USE_REG_GEN16;
1768	pParam->size = 2;
1769	}
1770	else
1771	if(pParam->param < OP_PARM_REG_FP_START)
1772	{
1773	/* 8-bit AL..DL, AH..DH registers. */
1774	pParam->base.reg_gen8 = pParam->param - OP_PARM_REG_GEN8_START;
1775	pParam->flags \|= USE_REG_GEN8;
1776	pParam->size = 1;
1777	}
1778	else
1779	if(pParam->param <= OP_PARM_REGFP_7)
1780	{
1781	/* FPU registers. */
1782	pParam->base.reg_fp = pParam->param - OP_PARM_REG_FP_START;
1783	pParam->flags \|= USE_REG_FP;
1784	pParam->size = 10;
1785	}
1786	/* else - not supported for now registers. */
1787
1788	return 0;
1789	}
1790	//*****************************************************************************
1791	//*****************************************************************************
1792	int ParseXv(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1793	{
1794	disasmGetPtrString(pCpu, pOp, pParam);
1795	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), (pCpu->addrmode == CPUMODE_32BIT) ? "DS:ESI" : "DS:SI");
1796
1797	pParam->flags \|= USE_POINTER_DS_BASED;
1798	if(pCpu->addrmode == CPUMODE_32BIT)
1799	{
1800	pParam->base.reg_gen32 = USE_REG_ESI;
1801	pParam->flags \|= USE_REG_GEN32;
1802	}
1803	else
1804	{
1805	pParam->base.reg_gen16 = USE_REG_SI;
1806	pParam->flags \|= USE_REG_GEN16;
1807	}
1808	return 0; //no additional opcode bytes
1809	}
1810	//*****************************************************************************
1811	//*****************************************************************************
1812	int ParseXb(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1813	{
1814	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), (pCpu->addrmode == CPUMODE_32BIT) ? "DS:ESI" : "DS:SI");
1815
1816	pParam->flags \|= USE_POINTER_DS_BASED;
1817	if(pCpu->addrmode == CPUMODE_32BIT)
1818	{
1819	pParam->base.reg_gen32 = USE_REG_ESI;
1820	pParam->flags \|= USE_REG_GEN32;
1821	}
1822	else
1823	{
1824	pParam->base.reg_gen16 = USE_REG_SI;
1825	pParam->flags \|= USE_REG_GEN16;
1826	}
1827	return 0; //no additional opcode bytes
1828	}
1829	//*****************************************************************************
1830	//*****************************************************************************
1831	int ParseYv(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1832	{
1833	disasmGetPtrString(pCpu, pOp, pParam);
1834	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), (pCpu->addrmode == CPUMODE_32BIT) ? "ES:EDI" : "ES:DI");
1835
1836	pParam->flags \|= USE_POINTER_ES_BASED;
1837	if(pCpu->addrmode == CPUMODE_32BIT)
1838	{
1839	pParam->base.reg_gen32 = USE_REG_EDI;
1840	pParam->flags \|= USE_REG_GEN32;
1841	}
1842	else
1843	{
1844	pParam->base.reg_gen16 = USE_REG_DI;
1845	pParam->flags \|= USE_REG_GEN16;
1846	}
1847	return 0; //no additional opcode bytes
1848	}
1849	//*****************************************************************************
1850	//*****************************************************************************
1851	int ParseYb(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1852	{
1853	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), (pCpu->addrmode == CPUMODE_32BIT) ? "ES:EDI" : "ES:DI");
1854
1855	pParam->flags \|= USE_POINTER_ES_BASED;
1856	if(pCpu->addrmode == CPUMODE_32BIT)
1857	{
1858	pParam->base.reg_gen32 = USE_REG_EDI;
1859	pParam->flags \|= USE_REG_GEN32;
1860	}
1861	else
1862	{
1863	pParam->base.reg_gen16 = USE_REG_DI;
1864	pParam->flags \|= USE_REG_GEN16;
1865	}
1866	return 0; //no additional opcode bytes
1867	}
1868	//*****************************************************************************
1869	//*****************************************************************************
1870	int ParseTwoByteEsc(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1871	{
1872	const OPCODE *pOpcode;
1873	int size = sizeof(uint8_t);
1874
1875	//2nd byte
1876	pCpu->opcode = DISReadByte(pCpu, lpszCodeBlock);
1877	pOpcode = &g_aTwoByteMapX86[pCpu->opcode];
1878
1879	/* Handle opcode table extensions that rely on the address, repe or repne prefix byte. */
1880	/** @todo Should we take the first or last prefix byte in case of multiple prefix bytes??? */
1881	if (pCpu->lastprefix)
1882	{
1883	switch(pCpu->lastprefix)
1884	{
1885	case OP_OPSIZE: /* 0x66 */
1886	if (g_aTwoByteMapX86_PF66[pCpu->opcode].opcode != OP_INVALID)
1887	{
1888	/* Table entry is valid, so use the extension table. */
1889	pOpcode = &g_aTwoByteMapX86_PF66[pCpu->opcode];
1890
1891	/* Cancel prefix changes. */
1892	pCpu->prefix &= ~PREFIX_OPSIZE;
1893	pCpu->opmode = pCpu->mode;
1894	}
1895	break;
1896
1897	case OP_REPNE: /* 0xF2 */
1898	if (g_aTwoByteMapX86_PFF2[pCpu->opcode].opcode != OP_INVALID)
1899	{
1900	/* Table entry is valid, so use the extension table. */
1901	pOpcode = &g_aTwoByteMapX86_PFF2[pCpu->opcode];
1902
1903	/* Cancel prefix changes. */
1904	pCpu->prefix &= ~PREFIX_REPNE;
1905	}
1906	break;
1907
1908	case OP_REPE: /* 0xF3 */
1909	if (g_aTwoByteMapX86_PFF3[pCpu->opcode].opcode != OP_INVALID)
1910	{
1911	/* Table entry is valid, so use the extension table. */
1912	pOpcode = &g_aTwoByteMapX86_PFF3[pCpu->opcode];
1913
1914	/* Cancel prefix changes. */
1915	pCpu->prefix &= ~PREFIX_REP;
1916	}
1917	break;
1918	}
1919	}
1920
1921	size += ParseInstruction(lpszCodeBlock+size, pOpcode, pCpu);
1922	return size;
1923	}
1924	//*****************************************************************************
1925	//*****************************************************************************
1926	int ParseNopPause(RTUINTPTR pu8CodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1927	{
1928	int size = 0;
1929
1930	if (pCpu->prefix & PREFIX_REP)
1931	{
1932	pOp = &g_aMapX86_NopPause[1]; /* PAUSE */
1933	pCpu->prefix &= ~PREFIX_REP;
1934	}
1935	else
1936	pOp = &g_aMapX86_NopPause[0]; /* NOP */
1937
1938	size += ParseInstruction(pu8CodeBlock, pOp, pCpu);
1939	return size;
1940	}
1941	//*****************************************************************************
1942	//*****************************************************************************
1943	int ParseImmGrpl(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1944	{
1945	int idx = (pCpu->opcode - 0x80) * 8;
1946	int size = 0, modrm, reg;
1947
1948	modrm = DISReadByte(pCpu, lpszCodeBlock);
1949	reg = MODRM_REG(modrm);
1950
1951	pOp = (PCOPCODE)&g_aMapX86_Group1[idx+reg];
1952	//little hack to make sure the ModRM byte is included in the returned size
1953	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
1954	{
1955	size = sizeof(uint8_t); //ModRM byte
1956	}
1957
1958	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
1959
1960	return size;
1961	}
1962	//*****************************************************************************
1963	//*****************************************************************************
1964	int ParseShiftGrp2(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
1965	{
1966	int idx;
1967	int size = 0, modrm, reg;
1968
1969	switch(pCpu->opcode)
1970	{
1971	case 0xC0:
1972	case 0xC1:
1973	idx = (pCpu->opcode - 0xC0)*8;
1974	break;
1975
1976	case 0xD0:
1977	case 0xD1:
1978	case 0xD2:
1979	case 0xD3:
1980	idx = (pCpu->opcode - 0xD0 + 2)*8;
1981	break;
1982
1983	default:
1984	AssertMsgFailed(("Oops\n"));
1985	return sizeof(uint8_t);
1986	}
1987
1988	modrm = DISReadByte(pCpu, lpszCodeBlock);
1989	reg = MODRM_REG(modrm);
1990
1991	pOp = (PCOPCODE)&g_aMapX86_Group2[idx+reg];
1992
1993	//little hack to make sure the ModRM byte is included in the returned size
1994	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
1995	{
1996	size = sizeof(uint8_t); //ModRM byte
1997	}
1998
1999	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2000
2001	return size;
2002	}
2003	//*****************************************************************************
2004	//*****************************************************************************
2005	int ParseGrp3(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2006	{
2007	int idx = (pCpu->opcode - 0xF6) * 8;
2008	int size = 0, modrm, reg;
2009
2010	modrm = DISReadByte(pCpu, lpszCodeBlock);
2011	reg = MODRM_REG(modrm);
2012
2013	pOp = (PCOPCODE)&g_aMapX86_Group3[idx+reg];
2014
2015	//little hack to make sure the ModRM byte is included in the returned size
2016	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2017	{
2018	size = sizeof(uint8_t); //ModRM byte
2019	}
2020
2021	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2022
2023	return size;
2024	}
2025	//*****************************************************************************
2026	//*****************************************************************************
2027	int ParseGrp4(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2028	{
2029	int size = 0, modrm, reg;
2030
2031	modrm = DISReadByte(pCpu, lpszCodeBlock);
2032	reg = MODRM_REG(modrm);
2033
2034	pOp = (PCOPCODE)&g_aMapX86_Group4[reg];
2035
2036	//little hack to make sure the ModRM byte is included in the returned size
2037	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2038	{
2039	size = sizeof(uint8_t); //ModRM byte
2040	}
2041
2042	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2043
2044	return size;
2045	}
2046	//*****************************************************************************
2047	//*****************************************************************************
2048	int ParseGrp5(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2049	{
2050	int size = 0, modrm, reg;
2051
2052	modrm = DISReadByte(pCpu, lpszCodeBlock);
2053	reg = MODRM_REG(modrm);
2054
2055	pOp = (PCOPCODE)&g_aMapX86_Group5[reg];
2056
2057	//little hack to make sure the ModRM byte is included in the returned size
2058	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2059	{
2060	size = sizeof(uint8_t); //ModRM byte
2061	}
2062
2063	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2064
2065	return size;
2066	}
2067	//*****************************************************************************
2068	// 0xF 0xF [ModRM] [SIB] [displacement] imm8_opcode
2069	// It would appear the ModRM byte must always be present. How else can you
2070	// determine the offset of the imm8_opcode byte otherwise?
2071	//
2072	//*****************************************************************************
2073	int Parse3DNow(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2074	{
2075	int size = 0, modrmsize;
2076
2077	#ifdef DEBUG_Sander
2078	//needs testing
2079	AssertMsgFailed(("Test me\n"));
2080	#endif
2081
2082	pCpu->ModRM = DISReadByte(pCpu, lpszCodeBlock);
2083
2084	modrmsize = QueryModRM(lpszCodeBlock+sizeof(uint8_t), pOp, pParam, pCpu);
2085
2086	uint8_t opcode = DISReadByte(pCpu, lpszCodeBlock+sizeof(uint8_t)+modrmsize);
2087
2088	pOp = (PCOPCODE)&g_aTwoByteMapX86_3DNow[opcode];
2089
2090	//little hack to make sure the ModRM byte is included in the returned size
2091	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2092	{
2093	#ifdef DEBUG_Sander /* bird, 2005-06-28: Alex is getting this during full installation of win2ksp4. */
2094	AssertMsgFailed(("Oops!\n")); //shouldn't happen!
2095	#endif
2096	size = sizeof(uint8_t); //ModRM byte
2097	}
2098
2099	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2100	size += sizeof(uint8_t); //imm8_opcode uint8_t
2101
2102	return size;
2103	}
2104	//*****************************************************************************
2105	//*****************************************************************************
2106	int ParseGrp6(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2107	{
2108	int size = 0, modrm, reg;
2109
2110	modrm = DISReadByte(pCpu, lpszCodeBlock);
2111	reg = MODRM_REG(modrm);
2112
2113	pOp = (PCOPCODE)&g_aMapX86_Group6[reg];
2114
2115	//little hack to make sure the ModRM byte is included in the returned size
2116	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2117	{
2118	size = sizeof(uint8_t); //ModRM byte
2119	}
2120
2121	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2122
2123	return size;
2124	}
2125	//*****************************************************************************
2126	//*****************************************************************************
2127	int ParseGrp7(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2128	{
2129	int size = 0, modrm, reg, rm, mod;
2130
2131	modrm = DISReadByte(pCpu, lpszCodeBlock);
2132	mod = MODRM_MOD(modrm);
2133	reg = MODRM_REG(modrm);
2134	rm = MODRM_RM(modrm);
2135
2136	if (mod == 3 && rm == 0)
2137	{
2138	pOp = (PCOPCODE)&g_aMapX86_Group7_mod11_rm000[reg];
2139	}
2140	else
2141	if (mod == 3 && rm == 1)
2142	{
2143	pOp = (PCOPCODE)&g_aMapX86_Group7_mod11_rm001[reg];
2144	}
2145	else
2146	pOp = (PCOPCODE)&g_aMapX86_Group7_mem[reg];
2147
2148	//little hack to make sure the ModRM byte is included in the returned size
2149	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2150	{
2151	size = sizeof(uint8_t); //ModRM byte
2152	}
2153
2154	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2155
2156	return size;
2157	}
2158	//*****************************************************************************
2159	//*****************************************************************************
2160	int ParseGrp8(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2161	{
2162	int size = 0, modrm, reg;
2163
2164	modrm = DISReadByte(pCpu, lpszCodeBlock);
2165	reg = MODRM_REG(modrm);
2166
2167	pOp = (PCOPCODE)&g_aMapX86_Group8[reg];
2168
2169	//little hack to make sure the ModRM byte is included in the returned size
2170	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2171	{
2172	size = sizeof(uint8_t); //ModRM byte
2173	}
2174
2175	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2176
2177	return size;
2178	}
2179	//*****************************************************************************
2180	//*****************************************************************************
2181	int ParseGrp9(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2182	{
2183	int size = 0, modrm, reg;
2184
2185	modrm = DISReadByte(pCpu, lpszCodeBlock);
2186	reg = MODRM_REG(modrm);
2187
2188	pOp = (PCOPCODE)&g_aMapX86_Group9[reg];
2189
2190	//little hack to make sure the ModRM byte is included in the returned size
2191	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2192	{
2193	size = sizeof(uint8_t); //ModRM byte
2194	}
2195
2196	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2197
2198	return size;
2199	}
2200	//*****************************************************************************
2201	//*****************************************************************************
2202	int ParseGrp10(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2203	{
2204	int size = 0, modrm, reg;
2205
2206	modrm = DISReadByte(pCpu, lpszCodeBlock);
2207	reg = MODRM_REG(modrm);
2208
2209	pOp = (PCOPCODE)&g_aMapX86_Group10[reg];
2210
2211	//little hack to make sure the ModRM byte is included in the returned size
2212	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2213	{
2214	size = sizeof(uint8_t); //ModRM byte
2215	}
2216
2217	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2218
2219	return size;
2220	}
2221	//*****************************************************************************
2222	//*****************************************************************************
2223	int ParseGrp12(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2224	{
2225	int size = 0, modrm, reg;
2226
2227	modrm = DISReadByte(pCpu, lpszCodeBlock);
2228	reg = MODRM_REG(modrm);
2229
2230	if(pCpu->prefix & PREFIX_OPSIZE)
2231	{
2232	reg += 8; //2nd table
2233	}
2234
2235	pOp = (PCOPCODE)&g_aMapX86_Group12[reg];
2236
2237	//little hack to make sure the ModRM byte is included in the returned size
2238	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2239	{
2240	size = sizeof(uint8_t); //ModRM byte
2241	}
2242
2243	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2244
2245	return size;
2246	}
2247	//*****************************************************************************
2248	//*****************************************************************************
2249	int ParseGrp13(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2250	{
2251	int size = 0, modrm, reg;
2252
2253	modrm = DISReadByte(pCpu, lpszCodeBlock);
2254	reg = MODRM_REG(modrm);
2255	if(pCpu->prefix & PREFIX_OPSIZE)
2256	{
2257	reg += 8; //2nd table
2258	}
2259
2260	pOp = (PCOPCODE)&g_aMapX86_Group13[reg];
2261
2262	//little hack to make sure the ModRM byte is included in the returned size
2263	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2264	{
2265	size = sizeof(uint8_t); //ModRM byte
2266	}
2267
2268	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2269
2270	return size;
2271	}
2272	//*****************************************************************************
2273	//*****************************************************************************
2274	int ParseGrp14(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2275	{
2276	int size = 0, modrm, reg;
2277
2278	modrm = DISReadByte(pCpu, lpszCodeBlock);
2279	reg = MODRM_REG(modrm);
2280	if(pCpu->prefix & PREFIX_OPSIZE)
2281	{
2282	reg += 8; //2nd table
2283	}
2284
2285	pOp = (PCOPCODE)&g_aMapX86_Group14[reg];
2286
2287	//little hack to make sure the ModRM byte is included in the returned size
2288	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2289	{
2290	size = sizeof(uint8_t); //ModRM byte
2291	}
2292
2293	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2294
2295	return size;
2296	}
2297	//*****************************************************************************
2298	//*****************************************************************************
2299	int ParseGrp15(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2300	{
2301	int size = 0, modrm, reg, mod, rm;
2302
2303	modrm = DISReadByte(pCpu, lpszCodeBlock);
2304	mod = MODRM_MOD(modrm);
2305	reg = MODRM_REG(modrm);
2306	rm = MODRM_RM(modrm);
2307
2308	if (mod == 3 && rm == 0)
2309	pOp = (PCOPCODE)&g_aMapX86_Group15_mod11_rm000[reg];
2310	else
2311	pOp = (PCOPCODE)&g_aMapX86_Group15_mem[reg];
2312
2313	//little hack to make sure the ModRM byte is included in the returned size
2314	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2315	{
2316	size = sizeof(uint8_t); //ModRM byte
2317	}
2318
2319	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2320
2321	return size;
2322	}
2323	//*****************************************************************************
2324	//*****************************************************************************
2325	int ParseGrp16(RTUINTPTR lpszCodeBlock, PCOPCODE pOp, POP_PARAMETER pParam, PDISCPUSTATE pCpu)
2326	{
2327	int size = 0, modrm, reg;
2328
2329	modrm = DISReadByte(pCpu, lpszCodeBlock);
2330	reg = MODRM_REG(modrm);
2331
2332	pOp = (PCOPCODE)&g_aMapX86_Group16[reg];
2333
2334	//little hack to make sure the ModRM byte is included in the returned size
2335	if(pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM)
2336	{
2337	size = sizeof(uint8_t); //ModRM byte
2338	}
2339
2340	size += ParseInstruction(lpszCodeBlock, pOp, pCpu);
2341
2342	return size;
2343	}
2344	//*****************************************************************************
2345	const char *szModRMReg8[] = {"AL", "CL", "DL", "BL", "AH", "CH", "DH", "BH"};
2346	const char *szModRMReg16[] = {"AX", "CX", "DX", "BX", "SP", "BP", "SI", "DI"};
2347	const char *szModRMReg32[] = {"EAX", "ECX", "EDX", "EBX", "ESP", "EBP", "ESI", "EDI"};
2348	//*****************************************************************************
2349	void disasmModRMReg(PDISCPUSTATE pCpu, PCOPCODE pOp, int idx, POP_PARAMETER pParam, int fRegAddr)
2350	{
2351	int subtype, type, mod;
2352
2353	mod = MODRM_MOD(pCpu->ModRM);
2354
2355	type = OP_PARM_VTYPE(pParam->param);
2356	subtype = OP_PARM_VSUBTYPE(pParam->param);
2357	if (fRegAddr)
2358	{
2359	subtype = OP_PARM_d;
2360	}
2361	else
2362	if(subtype == OP_PARM_v \|\| subtype == OP_PARM_NONE)
2363	{
2364	subtype = (pCpu->opmode == CPUMODE_32BIT) ? OP_PARM_d : OP_PARM_w;
2365	}
2366
2367	switch(subtype)
2368	{
2369	case OP_PARM_b:
2370	disasmAddString(pParam->szParam, szModRMReg8[idx]);
2371	pParam->flags \|= USE_REG_GEN8;
2372	pParam->base.reg_gen8 = idx;
2373	break;
2374
2375	case OP_PARM_w:
2376	disasmAddString(pParam->szParam, szModRMReg16[idx]);
2377	pParam->flags \|= USE_REG_GEN16;
2378	pParam->base.reg_gen16 = idx;
2379	break;
2380
2381	case OP_PARM_d:
2382	disasmAddString(pParam->szParam, szModRMReg32[idx]);
2383	pParam->flags \|= USE_REG_GEN32;
2384	pParam->base.reg_gen32 = idx;
2385	break;
2386
2387	default:
2388	#ifdef IN_RING3
2389	Log(("disasmModRMReg %x:%x failed!!\n", type, subtype));
2390	DIS_THROW(ExceptionInvalidModRM);
2391	#else
2392	AssertMsgFailed(("Oops!\n"));
2393	#endif
2394	break;
2395	}
2396	}
2397	//*****************************************************************************
2398	const char *szModRMReg1616[8] = {"BX+SI", "BX+DI", "BP+SI", "BP+DI", "SI", "DI", "BP", "BX"};
2399	int BaseModRMReg16[8] = { USE_REG_BX, USE_REG_BX, USE_REG_BP, USE_REG_BP, USE_REG_SI, USE_REG_DI, USE_REG_BP, USE_REG_BX};
2400	int IndexModRMReg16[4] = { USE_REG_SI, USE_REG_DI, USE_REG_SI, USE_REG_DI};
2401	//*****************************************************************************
2402	void disasmModRMReg16(PDISCPUSTATE pCpu, PCOPCODE pOp, int idx, POP_PARAMETER pParam)
2403	{
2404	disasmAddString(pParam->szParam, szModRMReg1616[idx]);
2405	pParam->flags \|= USE_REG_GEN16;
2406	pParam->base.reg_gen16 = BaseModRMReg16[idx];
2407	if(idx < 4)
2408	{
2409	pParam->flags \|= USE_INDEX;
2410	pParam->index.reg_gen = IndexModRMReg16[idx];
2411	}
2412	}
2413	//*****************************************************************************
2414	const char *szModRMSegReg[6] = {"ES", "CS", "SS", "DS", "FS", "GS"};
2415	//*****************************************************************************
2416	void disasmModRMSReg(PDISCPUSTATE pCpu, PCOPCODE pOp, int idx, POP_PARAMETER pParam)
2417	{
2418	#if 0 //def DEBUG_Sander
2419	AssertMsg(idx < (int)ELEMENTS(szModRMSegReg), ("idx=%d\n", idx));
2420	#endif
2421	#ifdef IN_RING3
2422	if(idx >= (int)ELEMENTS(szModRMSegReg))
2423	{
2424	Log(("disasmModRMSReg %d failed!!\n", idx));
2425	DIS_THROW(ExceptionInvalidParameter);
2426	}
2427	#endif
2428
2429	idx = RT_MIN(idx, (int)ELEMENTS(szModRMSegReg)-1);
2430	disasmAddString(pParam->szParam, szModRMSegReg[idx]);
2431	pParam->flags \|= USE_REG_SEG;
2432	pParam->base.reg_seg = idx;
2433	}
2434	//*****************************************************************************
2435	//*****************************************************************************
2436	void disasmPrintAbs32(POP_PARAMETER pParam)
2437	{
2438	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "%08Xh", pParam->disp32);
2439	}
2440	//*****************************************************************************
2441	//*****************************************************************************
2442	void disasmPrintDisp32(POP_PARAMETER pParam)
2443	{
2444	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "%08Xh", pParam->disp32);
2445	}
2446	//*****************************************************************************
2447	//*****************************************************************************
2448	void disasmPrintDisp8(POP_PARAMETER pParam)
2449	{
2450	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "%d", pParam->disp8);
2451	}
2452	//*****************************************************************************
2453	//*****************************************************************************
2454	void disasmPrintDisp16(POP_PARAMETER pParam)
2455	{
2456	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "%04Xh", pParam->disp16);
2457	}
2458	//*****************************************************************************
2459	//*****************************************************************************
2460	void disasmGetPtrString(PDISCPUSTATE pCpu, PCOPCODE pOp, POP_PARAMETER pParam)
2461	{
2462	int subtype = OP_PARM_VSUBTYPE(pParam->param);
2463
2464	if(subtype == OP_PARM_v)
2465	{
2466	subtype = (pCpu->opmode == CPUMODE_32BIT) ? OP_PARM_d : OP_PARM_w;
2467	}
2468
2469	switch(subtype)
2470	{
2471	case OP_PARM_a: //two words or dwords depending on operand size (bound only)
2472	break;
2473
2474	case OP_PARM_b:
2475	disasmAddString(pParam->szParam, "byte ptr ");
2476	break;
2477
2478	case OP_PARM_w:
2479	disasmAddString(pParam->szParam, "word ptr ");
2480	break;
2481
2482	case OP_PARM_d:
2483	disasmAddString(pParam->szParam, "dword ptr ");
2484	break;
2485
2486	case OP_PARM_q:
2487	case OP_PARM_dq:
2488	disasmAddString(pParam->szParam, "qword ptr ");
2489	break;
2490
2491	case OP_PARM_p:
2492	disasmAddString(pParam->szParam, "far ptr ");
2493	break;
2494
2495	case OP_PARM_s:
2496	break; //??
2497
2498	case OP_PARM_z:
2499	break;
2500	default:
2501	break; //no pointer type specified/necessary
2502	}
2503	if (pCpu->prefix & PREFIX_SEG)
2504	disasmAddStringF(pParam->szParam, sizeof(pParam->szParam), "%s:", szModRMSegReg[pCpu->prefix_seg]);
2505	}
2506	#ifndef IN_GC
2507	//*****************************************************************************
2508	/* Read functions for getting the opcode bytes */
2509	//*****************************************************************************
2510	uint8_t DISReadByte(PDISCPUSTATE pCpu, RTUINTPTR pAddress)
2511	{
2512	if(pCpu->pfnReadBytes)
2513	{
2514	uint8_t temp = 0;
2515	int rc;
2516
2517	rc = pCpu->pfnReadBytes(pAddress, &temp, sizeof(temp), (RTUINTPTR)pCpu);
2518	if(VBOX_FAILURE(rc))
2519	{
2520	Log(("DISReadByte failed!!\n"));
2521	DIS_THROW(ExceptionMemRead);
2522	}
2523	return temp;
2524	}
2525	#ifdef IN_RING0
2526	AssertMsgFailed(("DISReadByte with no read callback in ring 0!!\n"));
2527	return 0;
2528	#else
2529	else return (uint8_t )pAddress;
2530	#endif
2531	}
2532	//*****************************************************************************
2533	//*****************************************************************************
2534	uint16_t DISReadWord(PDISCPUSTATE pCpu, RTUINTPTR pAddress)
2535	{
2536	if(pCpu->pfnReadBytes)
2537	{
2538	uint16_t temp = 0;
2539	int rc;
2540
2541	rc = pCpu->pfnReadBytes(pAddress, (uint8_t*)&temp, sizeof(temp), (RTUINTPTR)pCpu);
2542	if(VBOX_FAILURE(rc))
2543	{
2544	Log(("DISReadWord failed!!\n"));
2545	DIS_THROW(ExceptionMemRead);
2546	}
2547	return temp;
2548	}
2549	#ifdef IN_RING0
2550	AssertMsgFailed(("DISReadWord with no read callback in ring 0!!\n"));
2551	return 0;
2552	#else
2553	else return (uint16_t )pAddress;
2554	#endif
2555	}
2556	//*****************************************************************************
2557	//*****************************************************************************
2558	uint32_t DISReadDWord(PDISCPUSTATE pCpu, RTUINTPTR pAddress)
2559	{
2560	if(pCpu->pfnReadBytes)
2561	{
2562	uint32_t temp = 0;
2563	int rc;
2564
2565	rc = pCpu->pfnReadBytes(pAddress, (uint8_t*)&temp, sizeof(temp), (RTUINTPTR)pCpu);
2566	if(VBOX_FAILURE(rc))
2567	{
2568	Log(("DISReadDWord failed!!\n"));
2569	DIS_THROW(ExceptionMemRead);
2570	}
2571	return temp;
2572	}
2573	#ifdef IN_RING0
2574	AssertMsgFailed(("DISReadDWord with no read callback in ring 0!!\n"));
2575	return 0;
2576	#else
2577	else return (uint32_t )pAddress;
2578	#endif
2579	}
2580	//*****************************************************************************
2581	//*****************************************************************************
2582	uint64_t DISReadQWord(PDISCPUSTATE pCpu, RTUINTPTR pAddress)
2583	{
2584	if(pCpu->pfnReadBytes)
2585	{
2586	uint64_t temp = 0;
2587	int rc;
2588
2589	rc = pCpu->pfnReadBytes(pAddress, (uint8_t*)&temp, sizeof(temp), (RTUINTPTR)pCpu);
2590	if(VBOX_FAILURE(rc))
2591	{
2592	Log(("DISReadQWord %x failed!!\n", pAddress));
2593	DIS_THROW(ExceptionMemRead);
2594	}
2595
2596	return temp;
2597	}
2598	#ifdef IN_RING0
2599	AssertMsgFailed(("DISReadQWord with no read callback in ring 0!!\n"));
2600	return 0;
2601	#else
2602	else return (uint64_t )pAddress;
2603	#endif
2604	}
2605	#endif /* IN_GC */
2606
2607	#if !defined(DIS_CORE_ONLY) && defined(LOG_ENABLED)
2608	//*****************************************************************************
2609	//*****************************************************************************
2610	void disasmAddString(char psz, const char pszAdd)
2611	{
2612	strcat(psz, pszAdd);
2613	}
2614	//*****************************************************************************
2615	//*****************************************************************************
2616	void disasmAddStringF(char psz, uint32_t size, const char pszFormat, ...)
2617	{
2618	va_list args;
2619	va_start(args, pszFormat);
2620	RTStrPrintfV(psz + strlen(psz), size, pszFormat, args);
2621	va_end(args);
2622	}
2623
2624	//*****************************************************************************
2625	//*****************************************************************************
2626	void disasmAddChar(char *psz, char ch)
2627	{
2628	char sz[2];
2629
2630	sz[0] = ch;
2631	sz[1] = '\0';
2632	strcat(psz, sz);
2633	}
2634	#endif /* !DIS_CORE_ONLY */

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source: vbox/trunk/src/VBox/Disassembler/DisasmCore.cpp@ 2426

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