bindings/ocaml/test_detail.ml - platform/external/capstone - Gitiles

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

 open Printf
 open List
 open Capstone

 let _X86_CODE16 = "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00";;
 let _X86_CODE32 = "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00";;
 let _X86_CODE64 = "\x55\x48\x8b\x05\xb8\x13\x00\x00";;
 let _ARM_CODE = "\xED\xFF\xFF\xEB\x04\xe0\x2d\xe5\x00\x00\x00\x00\xe0\x83\x22\xe5\xf1\x02\x03\x0e\x00\x00\xa0\xe3\x02\x30\xc1\xe7\x00\x00\x53\xe3";;
 let _ARM_CODE2 = "\x10\xf1\x10\xe7\x11\xf2\x31\xe7\xdc\xa1\x2e\xf3\xe8\x4e\x62\xf3";;
 let _THUMB_CODE = "\x70\x47\xeb\x46\x83\xb0\xc9\x68";;
 let _THUMB_CODE2 = "\x4f\xf0\x00\x01\xbd\xe8\x00\x88";;
 let _MIPS_CODE = "\x0C\x10\x00\x97\x00\x00\x00\x00\x24\x02\x00\x0c\x8f\xa2\x00\x00\x34\x21\x34\x56";;
 let _MIPS_CODE2 = "\x56\x34\x21\x34\xc2\x17\x01\x00";;
 let _ARM64_CODE = "\x21\x7c\x02\x9b\x21\x7c\x00\x53\x00\x40\x21\x4b\xe1\x0b\x40\xb9";;

 let all_tests = [
 	(CS_ARCH_X86, [CS_MODE_16], _X86_CODE16, "X86 16bit (Intel syntax)");
 	(CS_ARCH_X86, [CS_MODE_32; CS_MODE_SYNTAX_ATT], _X86_CODE32, "X86 32bit (ATT syntax)");
 	(CS_ARCH_X86, [CS_MODE_32], _X86_CODE32, "X86 32 (Intel syntax)");
 	(CS_ARCH_X86, [CS_MODE_64], _X86_CODE64, "X86 64 (Intel syntax)");
 	(CS_ARCH_ARM, [CS_MODE_ARM], _ARM_CODE, "ARM");
 	(CS_ARCH_ARM, [CS_MODE_ARM], _ARM_CODE2, "ARM: Cortex-A15 + NEON");
 	(CS_ARCH_ARM, [CS_MODE_THUMB], _THUMB_CODE, "THUMB");
 	(CS_ARCH_ARM, [CS_MODE_THUMB], _THUMB_CODE2, "THUMB-2");
 	(CS_ARCH_ARM64, [CS_MODE_ARM], _ARM64_CODE, "ARM-64");
 	(CS_ARCH_MIPS, [CS_MODE_32; CS_MODE_BIG_ENDIAN], _MIPS_CODE, "MIPS-32 (Big-endian)");
 	(CS_ARCH_MIPS, [CS_MODE_64; CS_MODE_LITTLE_ENDIAN], _MIPS_CODE2, "MIPS-64-EL (Little-endian)");
 ];;


 let print_detail arch insn =
 	(* print immediate operands *)
 	if (Array.length insn.regs_read) > 0 then begin
 		printf "\tImplicit registers read: ";
 		Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn.regs_read;
 		printf "\n";
 	end;

 	if (Array.length insn.regs_write) > 0 then begin
 		printf "\tImplicit registers written: ";
 		Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn.regs_write;
 		printf "\n";
 	end;

 	if (Array.length insn.groups) > 0 then begin
 		printf "\tThis instruction belongs to groups: ";
 		Array.iter (printf "%u ") insn.groups;
 		printf "\n";
 	end;
 	printf "\n";;


 let print_insn arch insn =
 	printf "0x%x\t%s\t%s\n" insn.address insn.mnemonic insn.op_str;
 	print_detail arch insn;;


 let print_arch x =
 	let (arch, mode, code, comment) = x in
 		let insns = cs_disasm_quick arch mode code 0x1000L 0L in
 			printf "*************\n";
 			printf "Platform: %s\n" comment;
 			List.iter (print_insn arch) insns;;

 (*
 List.iter print_arch all_tests;;
 *)

 (* all below code use OO class of Capstone *)
 let print_detail_cls arch insn =
 	(* print immediate operands *)
 	if (Array.length insn#regs_read) > 0 then begin
 		printf "\tImplicit registers read: ";
 		Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn#regs_read;
 		printf "\n";
 	end;

 	if (Array.length insn#regs_write) > 0 then begin
 		printf "\tImplicit registers written: ";
 		Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn#regs_write;
 		printf "\n";
 	end;

 	if (Array.length insn#groups) > 0 then begin
 		printf "\tThis instruction belongs to groups: ";
 		Array.iter (printf "%u ") insn#groups;
 		printf "\n";
 	end;
 	printf "\n";;


 let print_insn_cls arch insn =
 	printf "0x%x\t%s\t%s\n" insn#address insn#mnemonic insn#op_str;
 	print_detail_cls arch insn;;


 let print_arch_cls x =
 	let (arch, mode, code, comment) = x in
 		let d = new cs arch mode in
 			let insns = d#disasm code 0x1000L 0L in
 				printf "*************\n";
 				printf "Platform: %s\n" comment;
 				List.iter (print_insn_cls arch) insns;
 	();;

 List.iter print_arch_cls all_tests;;
	(* Capstone Disassembler Engine
	* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013> *)

	open Printf
	open List
	open Capstone

	let _X86_CODE16 = "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00";;
	let _X86_CODE32 = "\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00";;
	let _X86_CODE64 = "\x55\x48\x8b\x05\xb8\x13\x00\x00";;
	let _ARM_CODE = "\xED\xFF\xFF\xEB\x04\xe0\x2d\xe5\x00\x00\x00\x00\xe0\x83\x22\xe5\xf1\x02\x03\x0e\x00\x00\xa0\xe3\x02\x30\xc1\xe7\x00\x00\x53\xe3";;
	let _ARM_CODE2 = "\x10\xf1\x10\xe7\x11\xf2\x31\xe7\xdc\xa1\x2e\xf3\xe8\x4e\x62\xf3";;
	let _THUMB_CODE = "\x70\x47\xeb\x46\x83\xb0\xc9\x68";;
	let _THUMB_CODE2 = "\x4f\xf0\x00\x01\xbd\xe8\x00\x88";;
	let _MIPS_CODE = "\x0C\x10\x00\x97\x00\x00\x00\x00\x24\x02\x00\x0c\x8f\xa2\x00\x00\x34\x21\x34\x56";;
	let _MIPS_CODE2 = "\x56\x34\x21\x34\xc2\x17\x01\x00";;
	let _ARM64_CODE = "\x21\x7c\x02\x9b\x21\x7c\x00\x53\x00\x40\x21\x4b\xe1\x0b\x40\xb9";;

	let all_tests = [
	(CS_ARCH_X86, [CS_MODE_16], _X86_CODE16, "X86 16bit (Intel syntax)");
	(CS_ARCH_X86, [CS_MODE_32; CS_MODE_SYNTAX_ATT], _X86_CODE32, "X86 32bit (ATT syntax)");
	(CS_ARCH_X86, [CS_MODE_32], _X86_CODE32, "X86 32 (Intel syntax)");
	(CS_ARCH_X86, [CS_MODE_64], _X86_CODE64, "X86 64 (Intel syntax)");
	(CS_ARCH_ARM, [CS_MODE_ARM], _ARM_CODE, "ARM");
	(CS_ARCH_ARM, [CS_MODE_ARM], _ARM_CODE2, "ARM: Cortex-A15 + NEON");
	(CS_ARCH_ARM, [CS_MODE_THUMB], _THUMB_CODE, "THUMB");
	(CS_ARCH_ARM, [CS_MODE_THUMB], _THUMB_CODE2, "THUMB-2");
	(CS_ARCH_ARM64, [CS_MODE_ARM], _ARM64_CODE, "ARM-64");
	(CS_ARCH_MIPS, [CS_MODE_32; CS_MODE_BIG_ENDIAN], _MIPS_CODE, "MIPS-32 (Big-endian)");
	(CS_ARCH_MIPS, [CS_MODE_64; CS_MODE_LITTLE_ENDIAN], _MIPS_CODE2, "MIPS-64-EL (Little-endian)");
	];;


	let print_detail arch insn =
	(* print immediate operands *)
	if (Array.length insn.regs_read) > 0 then begin
	printf "\tImplicit registers read: ";
	Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn.regs_read;
	printf "\n";
	end;

	if (Array.length insn.regs_write) > 0 then begin
	printf "\tImplicit registers written: ";
	Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn.regs_write;
	printf "\n";
	end;

	if (Array.length insn.groups) > 0 then begin
	printf "\tThis instruction belongs to groups: ";
	Array.iter (printf "%u ") insn.groups;
	printf "\n";
	end;
	printf "\n";;


	let print_insn arch insn =
	printf "0x%x\t%s\t%s\n" insn.address insn.mnemonic insn.op_str;
	print_detail arch insn;;


	let print_arch x =
	let (arch, mode, code, comment) = x in
	let insns = cs_disasm_quick arch mode code 0x1000L 0L in
	printf "*************\n";
	printf "Platform: %s\n" comment;
	List.iter (print_insn arch) insns;;

	(*
	List.iter print_arch all_tests;;
	*)

	(* all below code use OO class of Capstone *)
	let print_detail_cls arch insn =
	(* print immediate operands *)
	if (Array.length insn#regs_read) > 0 then begin
	printf "\tImplicit registers read: ";
	Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn#regs_read;
	printf "\n";
	end;

	if (Array.length insn#regs_write) > 0 then begin
	printf "\tImplicit registers written: ";
	Array.iter (fun x -> printf "%s "(cs_reg_name arch x)) insn#regs_write;
	printf "\n";
	end;

	if (Array.length insn#groups) > 0 then begin
	printf "\tThis instruction belongs to groups: ";
	Array.iter (printf "%u ") insn#groups;
	printf "\n";
	end;
	printf "\n";;


	let print_insn_cls arch insn =
	printf "0x%x\t%s\t%s\n" insn#address insn#mnemonic insn#op_str;
	print_detail_cls arch insn;;


	let print_arch_cls x =
	let (arch, mode, code, comment) = x in
	let d = new cs arch mode in
	let insns = d#disasm code 0x1000L 0L in
	printf "*************\n";
	printf "Platform: %s\n" comment;
	List.iter (print_insn_cls arch) insns;
	();;

	List.iter print_arch_cls all_tests;;