#ifndef CAPSTONE_ENGINE_H #define CAPSTONE_ENGINE_H /* Capstone Disassembler Engine */ /* By Nguyen Anh Quynh , 2013> */ #ifdef __cplusplus extern "C" { #endif #include #include #include // Capstone API version #define CS_API_MAJOR 2 #define CS_API_MINOR 0 // Macro to create combined version which can be compared to // result of cs_version() API. #define CS_MAKE_VERSION(major, minor) ((major << 8) + minor) // Handle using with all API typedef size_t csh; // Architecture type typedef enum cs_arch { CS_ARCH_ARM = 0, // ARM architecture (including Thumb, Thumb-2) CS_ARCH_ARM64, // ARM-64, also called AArch64 CS_ARCH_MIPS, // Mips architecture CS_ARCH_X86, // X86 architecture (including x86 & x86-64) CS_ARCH_PPC, // PowerPC architecture CS_ARCH_MAX, CS_ARCH_ALL = 0xFFFF, } cs_arch; // Mode type typedef enum cs_mode { CS_MODE_LITTLE_ENDIAN = 0, // little endian mode (default mode) CS_MODE_ARM = 0, // 32-bit ARM CS_MODE_16 = 1 << 1, // 16-bit mode CS_MODE_32 = 1 << 2, // 32-bit mode CS_MODE_64 = 1 << 3, // 64-bit mode CS_MODE_THUMB = 1 << 4, // ARM's Thumb mode, including Thumb-2 CS_MODE_MICRO = 1 << 4, // MicroMips mode (MIPS architecture) CS_MODE_N64 = 1 << 5, // Nintendo-64 mode (MIPS architecture) CS_MODE_BIG_ENDIAN = 1 << 31 // big endian mode } cs_mode; typedef void* (*malloc_t)(size_t size); typedef void* (*calloc_t)(size_t nmemb, size_t size); typedef void* (*realloc_t)(void *ptr, size_t size); typedef void (*free_t)(void *ptr); // User-defined memory malloc/calloc/realloc/free functions // These functions will be used internally to dynamically manage memory. // By default, Capstone uses system's malloc(), calloc(), realloc() & free(). typedef struct cs_opt_mem { malloc_t malloc; calloc_t calloc; realloc_t realloc; free_t free; } cs_opt_mem; // Runtime option for the disassembled engine typedef enum cs_opt_type { CS_OPT_SYNTAX = 1, // Asssembly output syntax CS_OPT_DETAIL, // Break down instruction structure into details CS_OPT_MODE, // Change engine's mode at run-time CS_OPT_MEM, // User-defined memory malloc/calloc/free } cs_opt_type; // Runtime option value (associated with option type above) typedef enum cs_opt_value { CS_OPT_OFF = 0, // Turn OFF an option (CS_OPT_DETAIL) CS_OPT_ON = 3, // Turn ON an option - default option for CS_OPT_DETAIL CS_OPT_SYNTAX_DEFAULT = 0, // Default asm syntax (CS_OPT_SYNTAX). CS_OPT_SYNTAX_INTEL, // X86 Intel asm syntax - default on X86 (CS_OPT_SYNTAX). CS_OPT_SYNTAX_ATT, // X86 ATT asm syntax (CS_OPT_SYNTAX) CS_OPT_SYNTAX_NOREGNAME, // PPC asm syntax: Prints register name with only number (CS_OPT_SYNTAX) } cs_opt_value; #include "arm.h" #include "arm64.h" #include "mips.h" #include "x86.h" #include "ppc.h" // NOTE: All information in cs_detail is only available when CS_OPT_DETAIL = CS_OPT_ON typedef struct cs_detail { uint8_t regs_read[12]; // list of implicit registers read by this insn uint8_t regs_read_count; // number of implicit registers read by this insn uint8_t regs_write[20]; // list of implicit registers modified by this insn uint8_t regs_write_count; // number of implicit registers modified by this insn uint8_t groups[8]; // list of group this instruction belong to uint8_t groups_count; // number of groups this insn belongs to // Architecture-specific instruction info union { cs_x86 x86; // X86 architecture, including 16-bit, 32-bit & 64-bit mode cs_arm64 arm64; // ARM64 architecture (aka AArch64) cs_arm arm; // ARM architecture (including Thumb/Thumb2) cs_mips mips; // MIPS architecture cs_ppc ppc; // PowerPC architecture }; } cs_detail; // Detail information of disassembled instruction typedef struct cs_insn { // Instruction ID // Find the instruction id from header file of corresponding architecture, // such as arm.h for ARM, x86.h for X86, etc... // This information is available even when CS_OPT_DETAIL = CS_OPT_OFF unsigned int id; // Address (EIP) of this instruction // This information is available even when CS_OPT_DETAIL = CS_OPT_OFF uint64_t address; // Size of this instruction // This information is available even when CS_OPT_DETAIL = CS_OPT_OFF uint16_t size; // Machine bytes of this instruction, with number of bytes indicated by @size above // This information is available even when CS_OPT_DETAIL = CS_OPT_OFF uint8_t bytes[16]; // Ascii text of instruction mnemonic // This information is available even when CS_OPT_DETAIL = CS_OPT_OFF char mnemonic[32]; // Ascii text of instruction operands // This information is available even when CS_OPT_DETAIL = CS_OPT_OFF char op_str[96]; // Pointer to cs_detail. // NOTE: detail pointer is only valid (not NULL) when CS_OP_DETAIL = CS_OPT_ON // Otherwise, if CS_OPT_DETAIL = CS_OPT_OFF, @detail = NULL cs_detail *detail; } cs_insn; // Calculate the offset of a disassembled instruction in its buffer, given its position // in its array of disassembled insn // NOTE: this macro works with position (>=1), not index #define CS_INSN_OFFSET(insns, post) (insns[post - 1].address - insns[0].address) // All type of errors encountered by Capstone API. // These are values returned by cs_errno() typedef enum cs_err { CS_ERR_OK = 0, // No error: everything was fine CS_ERR_MEM, // Out-Of-Memory error: cs_open(), cs_disasm_ex() CS_ERR_ARCH, // Unsupported architecture: cs_open() CS_ERR_HANDLE, // Invalid handle: cs_op_count(), cs_op_index() CS_ERR_CSH, // Invalid csh argument: cs_close(), cs_errno(), cs_option() CS_ERR_MODE, // Invalid/unsupported mode: cs_open() CS_ERR_OPTION, // Invalid/unsupported option: cs_option() CS_ERR_DETAIL, // Information is unavailable because detail option is OFF } cs_err; /* Return combined API version & major and minor version numbers. @major: major number of API version @minor: minor number of API version @return hexical number as (major << 8 | minor), which encodes both major & minor versions. NOTE: This returned value can be compared with version number made with macro CS_MAKE_VERSION For example, second API version would return 1 in @major, and 1 in @minor The return value would be 0x0101 NOTE: if you only care about returned value, but not major and minor values, set both @major & @minor arguments to NULL. */ unsigned int cs_version(int *major, int *minor); /* Check if a particular arch is supported by this library. @arch: the architecture to be checked. To verify if this library supports everything, use CS_ARCH_ALL @return True if this library supports the given arch. */ bool cs_support(cs_arch arch); /* Initialize CS handle: this must be done before any usage of CS. @arch: architecture type (CS_ARCH_*) @mode: hardware mode. This is combined of CS_MODE_* @handle: pointer to handle, which will be updated at return time @return CS_ERR_OK on success, or other value on failure (refer to cs_err enum for detailed error). */ cs_err cs_open(cs_arch arch, cs_mode mode, csh *handle); /* Close CS handle: MUST do to release the handle when it is not used anymore. NOTE: this must be only called when there is no longer usage of Capstone, not even access to cs_insn array. The reason is the this API releases some cached memory, thus access to any Capstone API after cs_close() might crash your application. @handle: handle returned by cs_open() @return CS_ERR_OK on success, or other value on failure (refer to cs_err enum for detailed error). */ cs_err cs_close(csh handle); /* Set option for disassembling engine at runtime @handle: handle returned by cs_open() @type: type of option to be set @value: option value corresponding with @type @return CS_ERR_OK on success, or other value on failure. Refer to cs_err enum for detailed error. NOTE: in the case of CS_OPT_MEM, handle's value can be anything, so that cs_option(handle, CS_OPT_MEM, value) can (i.e must) be called even before cs_open() */ cs_err cs_option(csh handle, cs_opt_type type, size_t value); /* Report the last error number when some API function fail. Like glibc's errno, cs_errno might not retain its old value once accessed. @handle: handle returned by cs_open() @return: error code of cs_err enum type (CS_ERR_*, see above) */ cs_err cs_errno(csh handle); /* Return a string describing given error code. @code: error code (see CS_ERR_* above) @return: returns a pointer to a string that describes the error code passed in the argument @code */ const char *cs_strerror(cs_err code); /* Dynamicly allocate memory to contain disasm insn Disassembled instructions will be put into @*insn NOTE 1: this API will automatically determine memory needed to contain output disassembled instructions in @insn. NOTE 2: caller must free() the allocated memory itself to avoid memory leaking @handle: handle returned by cs_open() @code: buffer containing raw binary code to be disassembled @code_size: size of above code @address: address of the first insn in given raw code buffer @insn: array of insn filled in by this function NOTE: @insn will be allocated by this function, and should be freed with cs_free() API. @count: number of instrutions to be disassembled, or 0 to get all of them @return: the number of succesfully disassembled instructions, or 0 if this function failed to disassemble the given code On failure, call cs_errno() for error code. */ size_t cs_disasm_ex(csh handle, const uint8_t *code, size_t code_size, uint64_t address, size_t count, cs_insn **insn); /* Free memory allocated in @insn by cs_disasm_ex() @insn: pointer returned by @insn argument in cs_disasm_ex() @count: number of cs_insn structures returned by cs_disasm_ex() */ void cs_free(cs_insn *insn, size_t count); /* Return friendly name of regiser in a string Find the instruction id from header file of corresponding architecture (arm.h for ARM, x86.h for X86, ...) @handle: handle returned by cs_open() @reg: register id @return: string name of the register, or NULL if @reg_id is invalid. */ const char *cs_reg_name(csh handle, unsigned int reg_id); /* Return friendly name of an instruction in a string Find the instruction id from header file of corresponding architecture (arm.h for ARM, x86.h for X86, ...) @handle: handle returned by cs_open() @insn: instruction id @return: string name of the instruction, or NULL if @insn_id is invalid. */ const char *cs_insn_name(csh handle, unsigned int insn_id); /* Check if a disassembled instruction belong to a particular group. Find the group id from header file of corresponding architecture (arm.h for ARM, x86.h for X86, ...) Internally, this simply verifies if @group_id matches any member of insn->groups array. @handle: handle returned by cs_open() @insn: disassembled instruction structure received from cs_disasm() or cs_disasm_ex() @group_id: group that you want to check if this instruction belong to. @return: true if this instruction indeed belongs to aboved group, or false otherwise. */ bool cs_insn_group(csh handle, cs_insn *insn, unsigned int group_id); /* Check if a disassembled instruction IMPLICITLY used a particular register. Find the register id from header file of corresponding architecture (arm.h for ARM, x86.h for X86, ...) Internally, this simply verifies if @reg_id matches any member of insn->regs_read array. @insn: disassembled instruction structure received from cs_disasm() or cs_disasm_ex() @reg_id: register that you want to check if this instruction used it. @return: true if this instruction indeed implicitly used aboved register, or false otherwise. */ bool cs_reg_read(csh handle, cs_insn *insn, unsigned int reg_id); /* Check if a disassembled instruction IMPLICITLY modified a particular register. Find the register id from header file of corresponding architecture (arm.h for ARM, x86.h for X86, ...) Internally, this simply verifies if @reg_id matches any member of insn->regs_write array. @insn: disassembled instruction structure received from cs_disasm() or cs_disasm_ex() @reg_id: register that you want to check if this instruction modified it. @return: true if this instruction indeed implicitly modified aboved register, or false otherwise. */ bool cs_reg_write(csh handle, cs_insn *insn, unsigned int reg_id); /* Count the number of operands of a given type. Find the operand type in header file of corresponding architecture (arm.h for ARM, x86.h for X86, ...) @handle: handle returned by cs_open() @insn: disassembled instruction structure received from cs_disasm() or cs_disasm_ex() @op_type: Operand type to be found. @return: number of operands of given type @op_type in instruction @insn, or -1 on failure. */ int cs_op_count(csh handle, cs_insn *insn, unsigned int op_type); /* Retrieve the position of operand of given type in arch.op_info[] array. Later, the operand can be accessed using the returned position. Find the operand type in header file of corresponding architecture (arm.h for ARM, x86.h for X86, ...) @handle: handle returned by cs_open() @insn: disassembled instruction structure received from cs_disasm() or cs_disasm_ex() @op_type: Operand type to be found. @position: position of the operand to be found. This must be in the range [1, cs_op_count(handle, insn, op_type)] @return: index of operand of given type @op_type in arch.op_info[] array in instruction @insn, or -1 on failure. */ int cs_op_index(csh handle, cs_insn *insn, unsigned int op_type, unsigned int position); #ifdef __cplusplus } #endif #endif