test_x86.c - Android社区 - https://www.androidos.net.cn/

/* Capstone Disassembler Engine */
/* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013> */

#include <stdio.h>
#include <stdlib.h>

#include <platform.h>
#include <capstone.h>

static csh handle;

struct platform {
	cs_arch arch;
	cs_mode mode;
	unsigned char *code;
	size_t size;
	char *comment;
	cs_opt_type opt_type;
	cs_opt_value opt_value;
};

static void print_string_hex(char *comment, unsigned char *str, size_t len)
{
	unsigned char *c;

printf("%s", comment);
	for (c = str; c < str + len; c++) {
		printf("0x%02x ", *c & 0xff);
	}

printf("\n");
}

static void print_insn_detail(csh ud, cs_mode mode, cs_insn *ins)
{
	int count, i;
	cs_x86 *x86;

// detail can be NULL on "data" instruction if SKIPDATA option is turned ON
	if (ins->detail == NULL)
		return;

x86 = &(ins->detail->x86);

print_string_hex("\tPrefix:", x86->prefix, 4);

print_string_hex("\tOpcode:", x86->opcode, 4);

printf("\trex: 0x%x\n", x86->rex);

printf("\taddr_size: %u\n", x86->addr_size);
	printf("\tmodrm: 0x%x\n", x86->modrm);
	printf("\tdisp: 0x%x\n", x86->disp);

// SIB is not available in 16-bit mode
	if ((mode & CS_MODE_16) == 0) {
		printf("\tsib: 0x%x\n", x86->sib);
		if (x86->sib_base != X86_REG_INVALID)
			printf("\t\tsib_base: %s\n", cs_reg_name(handle, x86->sib_base));
		if (x86->sib_index != X86_REG_INVALID)
			printf("\t\tsib_index: %s\n", cs_reg_name(handle, x86->sib_index));
		if (x86->sib_scale != 0)
			printf("\t\tsib_scale: %d\n", x86->sib_scale);
	}

// SSE code condition
	if (x86->sse_cc != X86_SSE_CC_INVALID) {
		printf("\tsse_cc: %u\n", x86->sse_cc);
	}

// AVX code condition
	if (x86->avx_cc != X86_AVX_CC_INVALID) {
		printf("\tavx_cc: %u\n", x86->avx_cc);
	}

// AVX Suppress All Exception
	if (x86->avx_sae) {
		printf("\tavx_sae: %u\n", x86->avx_sae);
	}

// AVX Rounding Mode
	if (x86->avx_rm != X86_AVX_RM_INVALID) {
		printf("\tavx_rm: %u\n", x86->avx_rm);
	}

count = cs_op_count(ud, ins, X86_OP_IMM);
	if (count) {
		printf("\timm_count: %u\n", count);
		for (i = 1; i < count + 1; i++) {
			int index = cs_op_index(ud, ins, X86_OP_IMM, i);
			printf("\t\timms[%u]: 0x%" PRIx64 "\n", i, x86->operands[index].imm);
		}
	}

if (x86->op_count)
		printf("\top_count: %u\n", x86->op_count);
	for (i = 0; i < x86->op_count; i++) {
		cs_x86_op *op = &(x86->operands[i]);

switch((int)op->type) {
			case X86_OP_REG:
				printf("\t\toperands[%u].type: REG = %s\n", i, cs_reg_name(handle, op->reg));
				break;
			case X86_OP_IMM:
				printf("\t\toperands[%u].type: IMM = 0x%" PRIx64 "\n", i, op->imm);
				break;
			case X86_OP_MEM:
				printf("\t\toperands[%u].type: MEM\n", i);
				if (op->mem.segment != X86_REG_INVALID)
					printf("\t\t\toperands[%u].mem.segment: REG = %s\n", i, cs_reg_name(handle, op->mem.segment));
				if (op->mem.base != X86_REG_INVALID)
					printf("\t\t\toperands[%u].mem.base: REG = %s\n", i, cs_reg_name(handle, op->mem.base));
				if (op->mem.index != X86_REG_INVALID)
					printf("\t\t\toperands[%u].mem.index: REG = %s\n", i, cs_reg_name(handle, op->mem.index));
				if (op->mem.scale != 1)
					printf("\t\t\toperands[%u].mem.scale: %u\n", i, op->mem.scale);
				if (op->mem.disp != 0)
					printf("\t\t\toperands[%u].mem.disp: 0x%" PRIx64 "\n", i, op->mem.disp);
				break;
			default:
				break;
		}

// AVX broadcast type
		if (op->avx_bcast != X86_AVX_BCAST_INVALID)
			printf("\t\toperands[%u].avx_bcast: %u\n", i, op->avx_bcast);

// AVX zero opmask {z}
		if (op->avx_zero_opmask != false)
			printf("\t\toperands[%u].avx_zero_opmask: TRUE\n", i);

printf("\t\toperands[%u].size: %u\n", i, op->size);
	}

printf("\n");
}

static void test()
{
//#define X86_CODE32 "\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x78\x56\x00\x00"
//#define X86_CODE32 "\x05\x78\x56\x00\x00"
//#define X86_CODE32 "\x01\xd8"
//#define X86_CODE32 "\x05\x23\x01\x00\x00"
//#define X86_CODE32 "\x8d\x87\x89\x67\x00\x00"
//#define X86_CODE32 "\xa1\x13\x48\x6d\x3a\x8b\x81\x23\x01\x00\x00\x8b\x84\x39\x23\x01\x00\x00"
//#define X86_CODE32 "\xb4\xc6"	// mov	ah, 0x6c
//#define X86_CODE32 "\x77\x04"	// ja +6
#define X86_CODE64 "\x55\x48\x8b\x05\xb8\x13\x00\x00"
//#define X86_CODE64 "\xe9\x79\xff\xff\xff"	// jmp 0xf7e

#define X86_CODE16 "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x23\x01\x00\x00\x36\x8b\x84\x91\x23\x01\x00\x00\x41\x8d\x84\x39\x89\x67\x00\x00\x8d\x87\x89\x67\x00\x00\xb4\xc6"
//#define X86_CODE16 "\x67\x00\x18"
#define X86_CODE32 "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x23\x01\x00\x00\x36\x8b\x84\x91\x23\x01\x00\x00\x41\x8d\x84\x39\x89\x67\x00\x00\x8d\x87\x89\x67\x00\x00\xb4\xc6"
//#define X86_CODE32 "\x0f\xa7\xc0"	// xstorerng
//#define X86_CODE32 "\x64\xa1\x18\x00\x00\x00"	// mov eax, dword ptr fs:[18]
//#define X86_CODE32 "\x64\xa3\x00\x00\x00\x00"	// mov [fs:0x0], eax
//#define X86_CODE32 "\xd1\xe1"	// shl ecx, 1
//#define X86_CODE32 "\xd1\xc8"	// ror eax, 1
//#define X86_CODE32 "\x83\xC0\x80"	// add	eax, -x80
//#define X86_CODE32 "\xe8\x26\xfe\xff\xff"		// call	0xe2b
//#define X86_CODE32 "\xcd\x80"		// int 0x80
//#define X86_CODE32 "\x24\xb8"		// and    $0xb8,%al
//#define X86_CODE32 "\xf0\x01\xd8"   // lock add eax,ebx
//#define X86_CODE32 "\xf3\xaa"		// rep stosb

struct platform platforms[] = {
		{
			CS_ARCH_X86,
			CS_MODE_16,
			(unsigned char *)X86_CODE16,
			sizeof(X86_CODE16) - 1,
			"X86 16bit (Intel syntax)"
		},
		{
			CS_ARCH_X86,
			CS_MODE_32,
			(unsigned char *)X86_CODE32,
			sizeof(X86_CODE32) - 1,
			"X86 32 (AT&T syntax)",
			CS_OPT_SYNTAX,
			CS_OPT_SYNTAX_ATT,
		},
		{
			CS_ARCH_X86,
			CS_MODE_32,
			(unsigned char *)X86_CODE32,
			sizeof(X86_CODE32) - 1,
			"X86 32 (Intel syntax)"
		},
		{
			CS_ARCH_X86,
			CS_MODE_64,
			(unsigned char *)X86_CODE64,
			sizeof(X86_CODE64) - 1,
			"X86 64 (Intel syntax)"
		},
	};

uint64_t address = 0x1000;
	cs_insn *insn;
	int i;
	size_t count;

for (i = 0; i < sizeof(platforms)/sizeof(platforms[0]); i++) {
		cs_err err = cs_open(platforms[i].arch, platforms[i].mode, &handle);
		if (err) {
			printf("Failed on cs_open() with error returned: %u\n", err);
			continue;
		}

if (platforms[i].opt_type)
			cs_option(handle, platforms[i].opt_type, platforms[i].opt_value);

cs_option(handle, CS_OPT_DETAIL, CS_OPT_ON);

count = cs_disasm(handle, platforms[i].code, platforms[i].size, address, 0, &insn);
		if (count) {
			size_t j;

printf("****************\n");
			printf("Platform: %s\n", platforms[i].comment);
			print_string_hex("Code:", platforms[i].code, platforms[i].size);
			printf("Disasm:\n");

for (j = 0; j < count; j++) {
				printf("0x%" PRIx64 ":\t%s\t%s\n", insn[j].address, insn[j].mnemonic, insn[j].op_str);
				print_insn_detail(handle, platforms[i].mode, &insn[j]);
			}
			printf("0x%" PRIx64 ":\n", insn[j-1].address + insn[j-1].size);

// free memory allocated by cs_disasm()
			cs_free(insn, count);
		} else {
			printf("****************\n");
			printf("Platform: %s\n", platforms[i].comment);
			print_string_hex("Code:", platforms[i].code, platforms[i].size);
			printf("ERROR: Failed to disasm given code!\n");
		}

printf("\n");

cs_close(&handle);
	}
}

int main()
{
	test();

return 0;
}

C++程序 | 252行 | 6.96 KB

/* Capstone Disassembler Engine */
/* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013> */

#include <stdio.h>
#include <stdlib.h>

#include <platform.h>
#include <capstone.h>

static csh handle;

struct platform {
	cs_arch arch;
	cs_mode mode;
	unsigned char *code;
	size_t size;
	char *comment;
	cs_opt_type opt_type;
	cs_opt_value opt_value;
};

static void print_string_hex(char *comment, unsigned char *str, size_t len)
{
	unsigned char *c;

	printf("%s", comment);
	for (c = str; c < str + len; c++) {
		printf("0x%02x ", *c & 0xff);
	}

	printf("\n");
}

static void print_insn_detail(csh ud, cs_mode mode, cs_insn *ins)
{
	int count, i;
	cs_x86 *x86;

	// detail can be NULL on "data" instruction if SKIPDATA option is turned ON
	if (ins->detail == NULL)
		return;

	x86 = &(ins->detail->x86);

	print_string_hex("\tPrefix:", x86->prefix, 4);

	print_string_hex("\tOpcode:", x86->opcode, 4);

	printf("\trex: 0x%x\n", x86->rex);

	printf("\taddr_size: %u\n", x86->addr_size);
	printf("\tmodrm: 0x%x\n", x86->modrm);
	printf("\tdisp: 0x%x\n", x86->disp);

	// SIB is not available in 16-bit mode
	if ((mode & CS_MODE_16) == 0) {
		printf("\tsib: 0x%x\n", x86->sib);
		if (x86->sib_base != X86_REG_INVALID)
			printf("\t\tsib_base: %s\n", cs_reg_name(handle, x86->sib_base));
		if (x86->sib_index != X86_REG_INVALID)
			printf("\t\tsib_index: %s\n", cs_reg_name(handle, x86->sib_index));
		if (x86->sib_scale != 0)
			printf("\t\tsib_scale: %d\n", x86->sib_scale);
	}

	// SSE code condition
	if (x86->sse_cc != X86_SSE_CC_INVALID) {
		printf("\tsse_cc: %u\n", x86->sse_cc);
	}

	// AVX code condition
	if (x86->avx_cc != X86_AVX_CC_INVALID) {
		printf("\tavx_cc: %u\n", x86->avx_cc);
	}

	// AVX Suppress All Exception
	if (x86->avx_sae) {
		printf("\tavx_sae: %u\n", x86->avx_sae);
	}

	// AVX Rounding Mode
	if (x86->avx_rm != X86_AVX_RM_INVALID) {
		printf("\tavx_rm: %u\n", x86->avx_rm);
	}

	count = cs_op_count(ud, ins, X86_OP_IMM);
	if (count) {
		printf("\timm_count: %u\n", count);
		for (i = 1; i < count + 1; i++) {
			int index = cs_op_index(ud, ins, X86_OP_IMM, i);
			printf("\t\timms[%u]: 0x%" PRIx64 "\n", i, x86->operands[index].imm);
		}
	}

	if (x86->op_count)
		printf("\top_count: %u\n", x86->op_count);
	for (i = 0; i < x86->op_count; i++) {
		cs_x86_op *op = &(x86->operands[i]);

		switch((int)op->type) {
			case X86_OP_REG:
				printf("\t\toperands[%u].type: REG = %s\n", i, cs_reg_name(handle, op->reg));
				break;
			case X86_OP_IMM:
				printf("\t\toperands[%u].type: IMM = 0x%" PRIx64 "\n", i, op->imm);
				break;
			case X86_OP_MEM:
				printf("\t\toperands[%u].type: MEM\n", i);
				if (op->mem.segment != X86_REG_INVALID)
					printf("\t\t\toperands[%u].mem.segment: REG = %s\n", i, cs_reg_name(handle, op->mem.segment));
				if (op->mem.base != X86_REG_INVALID)
					printf("\t\t\toperands[%u].mem.base: REG = %s\n", i, cs_reg_name(handle, op->mem.base));
				if (op->mem.index != X86_REG_INVALID)
					printf("\t\t\toperands[%u].mem.index: REG = %s\n", i, cs_reg_name(handle, op->mem.index));
				if (op->mem.scale != 1)
					printf("\t\t\toperands[%u].mem.scale: %u\n", i, op->mem.scale);
				if (op->mem.disp != 0)
					printf("\t\t\toperands[%u].mem.disp: 0x%" PRIx64 "\n", i, op->mem.disp);
				break;
			default:
				break;
		}

		// AVX broadcast type
		if (op->avx_bcast != X86_AVX_BCAST_INVALID)
			printf("\t\toperands[%u].avx_bcast: %u\n", i, op->avx_bcast);

		// AVX zero opmask {z}
		if (op->avx_zero_opmask != false)
			printf("\t\toperands[%u].avx_zero_opmask: TRUE\n", i);

		printf("\t\toperands[%u].size: %u\n", i, op->size);
	}

	printf("\n");
}

static void test()
{
//#define X86_CODE32 "\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x78\x56\x00\x00"
//#define X86_CODE32 "\x05\x78\x56\x00\x00"
//#define X86_CODE32 "\x01\xd8"
//#define X86_CODE32 "\x05\x23\x01\x00\x00"
//#define X86_CODE32 "\x8d\x87\x89\x67\x00\x00"
//#define X86_CODE32 "\xa1\x13\x48\x6d\x3a\x8b\x81\x23\x01\x00\x00\x8b\x84\x39\x23\x01\x00\x00"
//#define X86_CODE32 "\xb4\xc6"	// mov	ah, 0x6c
//#define X86_CODE32 "\x77\x04"	// ja +6
#define X86_CODE64 "\x55\x48\x8b\x05\xb8\x13\x00\x00"
//#define X86_CODE64 "\xe9\x79\xff\xff\xff"	// jmp 0xf7e

#define X86_CODE16 "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x23\x01\x00\x00\x36\x8b\x84\x91\x23\x01\x00\x00\x41\x8d\x84\x39\x89\x67\x00\x00\x8d\x87\x89\x67\x00\x00\xb4\xc6"
//#define X86_CODE16 "\x67\x00\x18"
#define X86_CODE32 "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x23\x01\x00\x00\x36\x8b\x84\x91\x23\x01\x00\x00\x41\x8d\x84\x39\x89\x67\x00\x00\x8d\x87\x89\x67\x00\x00\xb4\xc6"
//#define X86_CODE32 "\x0f\xa7\xc0"	// xstorerng
//#define X86_CODE32 "\x64\xa1\x18\x00\x00\x00"	// mov eax, dword ptr fs:[18]
//#define X86_CODE32 "\x64\xa3\x00\x00\x00\x00"	// mov [fs:0x0], eax
//#define X86_CODE32 "\xd1\xe1"	// shl ecx, 1
//#define X86_CODE32 "\xd1\xc8"	// ror eax, 1
//#define X86_CODE32 "\x83\xC0\x80"	// add	eax, -x80
//#define X86_CODE32 "\xe8\x26\xfe\xff\xff"		// call	0xe2b
//#define X86_CODE32 "\xcd\x80"		// int 0x80
//#define X86_CODE32 "\x24\xb8"		// and    $0xb8,%al
//#define X86_CODE32 "\xf0\x01\xd8"   // lock add eax,ebx
//#define X86_CODE32 "\xf3\xaa"		// rep stosb

	struct platform platforms[] = {
		{
			CS_ARCH_X86,
			CS_MODE_16,
			(unsigned char *)X86_CODE16,
			sizeof(X86_CODE16) - 1,
			"X86 16bit (Intel syntax)"
		},
		{
			CS_ARCH_X86,
			CS_MODE_32,
			(unsigned char *)X86_CODE32,
			sizeof(X86_CODE32) - 1,
			"X86 32 (AT&T syntax)",
			CS_OPT_SYNTAX,
			CS_OPT_SYNTAX_ATT,
		},
		{
			CS_ARCH_X86,
			CS_MODE_32,
			(unsigned char *)X86_CODE32,
			sizeof(X86_CODE32) - 1,
			"X86 32 (Intel syntax)"
		},
		{
			CS_ARCH_X86,
			CS_MODE_64,
			(unsigned char *)X86_CODE64,
			sizeof(X86_CODE64) - 1,
			"X86 64 (Intel syntax)"
		},
	};

	uint64_t address = 0x1000;
	cs_insn *insn;
	int i;
	size_t count;

	for (i = 0; i < sizeof(platforms)/sizeof(platforms[0]); i++) {
		cs_err err = cs_open(platforms[i].arch, platforms[i].mode, &handle);
		if (err) {
			printf("Failed on cs_open() with error returned: %u\n", err);
			continue;
		}

		if (platforms[i].opt_type)
			cs_option(handle, platforms[i].opt_type, platforms[i].opt_value);

		cs_option(handle, CS_OPT_DETAIL, CS_OPT_ON);

		count = cs_disasm(handle, platforms[i].code, platforms[i].size, address, 0, &insn);
		if (count) {
			size_t j;

			printf("****************\n");
			printf("Platform: %s\n", platforms[i].comment);
			print_string_hex("Code:", platforms[i].code, platforms[i].size);
			printf("Disasm:\n");

			for (j = 0; j < count; j++) {
				printf("0x%" PRIx64 ":\t%s\t%s\n", insn[j].address, insn[j].mnemonic, insn[j].op_str);
				print_insn_detail(handle, platforms[i].mode, &insn[j]);
			}
			printf("0x%" PRIx64 ":\n", insn[j-1].address + insn[j-1].size);

			// free memory allocated by cs_disasm()
			cs_free(insn, count);
		} else {
			printf("****************\n");
			printf("Platform: %s\n", platforms[i].comment);
			print_string_hex("Code:", platforms[i].code, platforms[i].size);
			printf("ERROR: Failed to disasm given code!\n");
		}

		printf("\n");

		cs_close(&handle);
	}
}

int main()
{
	test();

	return 0;
}

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