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src/cpu/x86/vm/nativeInst_x86.hpp@45a1bf98f1bb (annotated)

src/cpu/x86/vm/nativeInst_x86.hpp

Mon, 13 Feb 2012 02:29:22 -0800

author

twisti

date

Mon, 13 Feb 2012 02:29:22 -0800

changeset 3566

45a1bf98f1bb

parent 3388

127b3692c168

child 6876

710a3c8b516e

permissions

-rw-r--r--

7141329: Strange values of stack_size in -XX:+TraceMethodHandles output
Reviewed-by: kvn, never

duke@435	1	/*
iveresov@2686	2	* Copyright (c) 1997, 2011, Oracle and/or its affiliates. All rights reserved.
duke@435	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
duke@435	4	*
duke@435	5	* This code is free software; you can redistribute it and/or modify it
duke@435	6	* under the terms of the GNU General Public License version 2 only, as
duke@435	7	* published by the Free Software Foundation.
duke@435	8	*
duke@435	9	* This code is distributed in the hope that it will be useful, but WITHOUT
duke@435	10	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
duke@435	11	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
duke@435	12	* version 2 for more details (a copy is included in the LICENSE file that
duke@435	13	* accompanied this code).
duke@435	14	*
duke@435	15	* You should have received a copy of the GNU General Public License version
duke@435	16	* 2 along with this work; if not, write to the Free Software Foundation,
duke@435	17	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
duke@435	18	*
trims@1907	19	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
trims@1907	20	* or visit www.oracle.com if you need additional information or have any
trims@1907	21	* questions.
duke@435	22	*
duke@435	23	*/
duke@435	24
stefank@2314	25	#ifndef CPU_X86_VM_NATIVEINST_X86_HPP
stefank@2314	26	#define CPU_X86_VM_NATIVEINST_X86_HPP
stefank@2314	27
stefank@2314	28	#include "asm/assembler.hpp"
stefank@2314	29	#include "memory/allocation.hpp"
stefank@2314	30	#include "runtime/icache.hpp"
stefank@2314	31	#include "runtime/os.hpp"
stefank@2314	32	#include "utilities/top.hpp"
stefank@2314	33
duke@435	34	// We have interfaces for the following instructions:
duke@435	35	// - NativeInstruction
duke@435	36	// - - NativeCall
duke@435	37	// - - NativeMovConstReg
duke@435	38	// - - NativeMovConstRegPatching
duke@435	39	// - - NativeMovRegMem
duke@435	40	// - - NativeMovRegMemPatching
duke@435	41	// - - NativeJump
duke@435	42	// - - NativeIllegalOpCode
duke@435	43	// - - NativeGeneralJump
duke@435	44	// - - NativeReturn
duke@435	45	// - - NativeReturnX (return with argument)
duke@435	46	// - - NativePushConst
duke@435	47	// - - NativeTstRegMem
duke@435	48
duke@435	49	// The base class for different kinds of native instruction abstractions.
duke@435	50	// Provides the primitive operations to manipulate code relative to this.
duke@435	51
duke@435	52	class NativeInstruction VALUE_OBJ_CLASS_SPEC {
duke@435	53	friend class Relocation;
duke@435	54
duke@435	55	public:
duke@435	56	enum Intel_specific_constants {
duke@435	57	nop_instruction_code = 0x90,
duke@435	58	nop_instruction_size = 1
duke@435	59	};
duke@435	60
duke@435	61	bool is_nop() { return ubyte_at(0) == nop_instruction_code; }
kamg@551	62	bool is_dtrace_trap();
duke@435	63	inline bool is_call();
duke@435	64	inline bool is_illegal();
duke@435	65	inline bool is_return();
duke@435	66	inline bool is_jump();
duke@435	67	inline bool is_cond_jump();
duke@435	68	inline bool is_safepoint_poll();
duke@435	69	inline bool is_mov_literal64();
duke@435	70
duke@435	71	protected:
duke@435	72	address addr_at(int offset) const { return address(this) + offset; }
duke@435	73
duke@435	74	s_char sbyte_at(int offset) const { return *(s_char*) addr_at(offset); }
duke@435	75	u_char ubyte_at(int offset) const { return *(u_char*) addr_at(offset); }
duke@435	76
duke@435	77	jint int_at(int offset) const { return *(jint*) addr_at(offset); }
duke@435	78
duke@435	79	intptr_t ptr_at(int offset) const { return *(intptr_t*) addr_at(offset); }
duke@435	80
duke@435	81	oop oop_at (int offset) const { return *(oop*) addr_at(offset); }
duke@435	82
duke@435	83
duke@435	84	void set_char_at(int offset, char c) { *addr_at(offset) = (u_char)c; wrote(offset); }
duke@435	85	void set_int_at(int offset, jint i) { *(jint*)addr_at(offset) = i; wrote(offset); }
duke@435	86	void set_ptr_at (int offset, intptr_t ptr) { *(intptr_t*) addr_at(offset) = ptr; wrote(offset); }
duke@435	87	void set_oop_at (int offset, oop o) { *(oop*) addr_at(offset) = o; wrote(offset); }
duke@435	88
duke@435	89	// This doesn't really do anything on Intel, but it is the place where
duke@435	90	// cache invalidation belongs, generically:
duke@435	91	void wrote(int offset);
duke@435	92
duke@435	93	public:
duke@435	94
duke@435	95	// unit test stuff
duke@435	96	static void test() {} // override for testing
duke@435	97
duke@435	98	inline friend NativeInstruction* nativeInstruction_at(address address);
duke@435	99	};
duke@435	100
duke@435	101	inline NativeInstruction* nativeInstruction_at(address address) {
duke@435	102	NativeInstruction* inst = (NativeInstruction*)address;
duke@435	103	#ifdef ASSERT
duke@435	104	//inst->verify();
duke@435	105	#endif
duke@435	106	return inst;
duke@435	107	}
duke@435	108
duke@435	109	inline NativeCall* nativeCall_at(address address);
duke@435	110	// The NativeCall is an abstraction for accessing/manipulating native call imm32/rel32off
duke@435	111	// instructions (used to manipulate inline caches, primitive & dll calls, etc.).
duke@435	112
duke@435	113	class NativeCall: public NativeInstruction {
duke@435	114	public:
duke@435	115	enum Intel_specific_constants {
duke@435	116	instruction_code = 0xE8,
duke@435	117	instruction_size = 5,
duke@435	118	instruction_offset = 0,
duke@435	119	displacement_offset = 1,
duke@435	120	return_address_offset = 5
duke@435	121	};
duke@435	122
duke@435	123	enum { cache_line_size = BytesPerWord }; // conservative estimate!
duke@435	124
duke@435	125	address instruction_address() const { return addr_at(instruction_offset); }
duke@435	126	address next_instruction_address() const { return addr_at(return_address_offset); }
duke@435	127	int displacement() const { return (jint) int_at(displacement_offset); }
duke@435	128	address displacement_address() const { return addr_at(displacement_offset); }
duke@435	129	address return_address() const { return addr_at(return_address_offset); }
duke@435	130	address destination() const;
duke@435	131	void set_destination(address dest) {
duke@435	132	#ifdef AMD64
duke@435	133	assert((labs((intptr_t) dest - (intptr_t) return_address()) &
duke@435	134	0xFFFFFFFF00000000) == 0,
duke@435	135	"must be 32bit offset");
duke@435	136	#endif // AMD64
duke@435	137	set_int_at(displacement_offset, dest - return_address());
duke@435	138	}
duke@435	139	void set_destination_mt_safe(address dest);
duke@435	140
duke@435	141	void verify_alignment() { assert((intptr_t)addr_at(displacement_offset) % BytesPerInt == 0, "must be aligned"); }
duke@435	142	void verify();
duke@435	143	void print();
duke@435	144
duke@435	145	// Creation
duke@435	146	inline friend NativeCall* nativeCall_at(address address);
duke@435	147	inline friend NativeCall* nativeCall_before(address return_address);
duke@435	148
duke@435	149	static bool is_call_at(address instr) {
duke@435	150	return ((*instr) & 0xFF) == NativeCall::instruction_code;
duke@435	151	}
duke@435	152
duke@435	153	static bool is_call_before(address return_address) {
duke@435	154	return is_call_at(return_address - NativeCall::return_address_offset);
duke@435	155	}
duke@435	156
duke@435	157	static bool is_call_to(address instr, address target) {
duke@435	158	return nativeInstruction_at(instr)->is_call() &&
duke@435	159	nativeCall_at(instr)->destination() == target;
duke@435	160	}
duke@435	161
duke@435	162	// MT-safe patching of a call instruction.
duke@435	163	static void insert(address code_pos, address entry);
duke@435	164
duke@435	165	static void replace_mt_safe(address instr_addr, address code_buffer);
duke@435	166	};
duke@435	167
duke@435	168	inline NativeCall* nativeCall_at(address address) {
duke@435	169	NativeCall* call = (NativeCall*)(address - NativeCall::instruction_offset);
duke@435	170	#ifdef ASSERT
duke@435	171	call->verify();
duke@435	172	#endif
duke@435	173	return call;
duke@435	174	}
duke@435	175
duke@435	176	inline NativeCall* nativeCall_before(address return_address) {
duke@435	177	NativeCall* call = (NativeCall*)(return_address - NativeCall::return_address_offset);
duke@435	178	#ifdef ASSERT
duke@435	179	call->verify();
duke@435	180	#endif
duke@435	181	return call;
duke@435	182	}
duke@435	183
duke@435	184	// An interface for accessing/manipulating native mov reg, imm32 instructions.
duke@435	185	// (used to manipulate inlined 32bit data dll calls, etc.)
duke@435	186	class NativeMovConstReg: public NativeInstruction {
duke@435	187	#ifdef AMD64
duke@435	188	static const bool has_rex = true;
duke@435	189	static const int rex_size = 1;
duke@435	190	#else
duke@435	191	static const bool has_rex = false;
duke@435	192	static const int rex_size = 0;
duke@435	193	#endif // AMD64
duke@435	194	public:
duke@435	195	enum Intel_specific_constants {
duke@435	196	instruction_code = 0xB8,
duke@435	197	instruction_size = 1 + rex_size + wordSize,
duke@435	198	instruction_offset = 0,
duke@435	199	data_offset = 1 + rex_size,
duke@435	200	next_instruction_offset = instruction_size,
duke@435	201	register_mask = 0x07
duke@435	202	};
duke@435	203
duke@435	204	address instruction_address() const { return addr_at(instruction_offset); }
duke@435	205	address next_instruction_address() const { return addr_at(next_instruction_offset); }
duke@435	206	intptr_t data() const { return ptr_at(data_offset); }
duke@435	207	void set_data(intptr_t x) { set_ptr_at(data_offset, x); }
duke@435	208
duke@435	209	void verify();
duke@435	210	void print();
duke@435	211
duke@435	212	// unit test stuff
duke@435	213	static void test() {}
duke@435	214
duke@435	215	// Creation
duke@435	216	inline friend NativeMovConstReg* nativeMovConstReg_at(address address);
duke@435	217	inline friend NativeMovConstReg* nativeMovConstReg_before(address address);
duke@435	218	};
duke@435	219
duke@435	220	inline NativeMovConstReg* nativeMovConstReg_at(address address) {
duke@435	221	NativeMovConstReg* test = (NativeMovConstReg*)(address - NativeMovConstReg::instruction_offset);
duke@435	222	#ifdef ASSERT
duke@435	223	test->verify();
duke@435	224	#endif
duke@435	225	return test;
duke@435	226	}
duke@435	227
duke@435	228	inline NativeMovConstReg* nativeMovConstReg_before(address address) {
duke@435	229	NativeMovConstReg* test = (NativeMovConstReg*)(address - NativeMovConstReg::instruction_size - NativeMovConstReg::instruction_offset);
duke@435	230	#ifdef ASSERT
duke@435	231	test->verify();
duke@435	232	#endif
duke@435	233	return test;
duke@435	234	}
duke@435	235
duke@435	236	class NativeMovConstRegPatching: public NativeMovConstReg {
duke@435	237	private:
duke@435	238	friend NativeMovConstRegPatching* nativeMovConstRegPatching_at(address address) {
duke@435	239	NativeMovConstRegPatching* test = (NativeMovConstRegPatching*)(address - instruction_offset);
duke@435	240	#ifdef ASSERT
duke@435	241	test->verify();
duke@435	242	#endif
duke@435	243	return test;
duke@435	244	}
duke@435	245	};
duke@435	246
duke@435	247	// An interface for accessing/manipulating native moves of the form:
never@739	248	// mov[b/w/l/q] [reg + offset], reg (instruction_code_reg2mem)
never@739	249	// mov[b/w/l/q] reg, [reg+offset] (instruction_code_mem2reg
never@739	250	// mov[s/z]x[w/b/q] [reg + offset], reg
duke@435	251	// fld_s [reg+offset]
duke@435	252	// fld_d [reg+offset]
duke@435	253	// fstp_s [reg + offset]
duke@435	254	// fstp_d [reg + offset]
never@739	255	// mov_literal64 scratch,<pointer> ; mov[b/w/l/q] 0(scratch),reg | mov[b/w/l/q] reg,0(scratch)
duke@435	256	//
duke@435	257	// Warning: These routines must be able to handle any instruction sequences
duke@435	258	// that are generated as a result of the load/store byte,word,long
duke@435	259	// macros. For example: The load_unsigned_byte instruction generates
duke@435	260	// an xor reg,reg inst prior to generating the movb instruction. This
duke@435	261	// class must skip the xor instruction.
duke@435	262
duke@435	263	class NativeMovRegMem: public NativeInstruction {
duke@435	264	public:
duke@435	265	enum Intel_specific_constants {
never@739	266	instruction_prefix_wide_lo = Assembler::REX,
never@739	267	instruction_prefix_wide_hi = Assembler::REX_WRXB,
duke@435	268	instruction_code_xor = 0x33,
duke@435	269	instruction_extended_prefix = 0x0F,
never@739	270	instruction_code_mem2reg_movslq = 0x63,
duke@435	271	instruction_code_mem2reg_movzxb = 0xB6,
duke@435	272	instruction_code_mem2reg_movsxb = 0xBE,
duke@435	273	instruction_code_mem2reg_movzxw = 0xB7,
duke@435	274	instruction_code_mem2reg_movsxw = 0xBF,
duke@435	275	instruction_operandsize_prefix = 0x66,
never@739	276	instruction_code_reg2mem = 0x89,
never@739	277	instruction_code_mem2reg = 0x8b,
duke@435	278	instruction_code_reg2memb = 0x88,
duke@435	279	instruction_code_mem2regb = 0x8a,
duke@435	280	instruction_code_float_s = 0xd9,
duke@435	281	instruction_code_float_d = 0xdd,
duke@435	282	instruction_code_long_volatile = 0xdf,
duke@435	283	instruction_code_xmm_ss_prefix = 0xf3,
duke@435	284	instruction_code_xmm_sd_prefix = 0xf2,
duke@435	285	instruction_code_xmm_code = 0x0f,
duke@435	286	instruction_code_xmm_load = 0x10,
duke@435	287	instruction_code_xmm_store = 0x11,
duke@435	288	instruction_code_xmm_lpd = 0x12,
duke@435	289
kvn@3388	290	instruction_VEX_prefix_2bytes = Assembler::VEX_2bytes,
kvn@3388	291	instruction_VEX_prefix_3bytes = Assembler::VEX_3bytes,
kvn@3388	292
duke@435	293	instruction_size = 4,
duke@435	294	instruction_offset = 0,
duke@435	295	data_offset = 2,
duke@435	296	next_instruction_offset = 4
duke@435	297	};
duke@435	298
never@739	299	// helper
never@739	300	int instruction_start() const;
duke@435	301
never@739	302	address instruction_address() const;
duke@435	303
never@739	304	address next_instruction_address() const;
never@739	305
never@739	306	int offset() const;
never@739	307
never@739	308	void set_offset(int x);
duke@435	309
duke@435	310	void add_offset_in_bytes(int add_offset) { set_offset ( ( offset() + add_offset ) ); }
duke@435	311
duke@435	312	void verify();
duke@435	313	void print ();
duke@435	314
duke@435	315	// unit test stuff
duke@435	316	static void test() {}
duke@435	317
duke@435	318	private:
duke@435	319	inline friend NativeMovRegMem* nativeMovRegMem_at (address address);
duke@435	320	};
duke@435	321
duke@435	322	inline NativeMovRegMem* nativeMovRegMem_at (address address) {
duke@435	323	NativeMovRegMem* test = (NativeMovRegMem*)(address - NativeMovRegMem::instruction_offset);
duke@435	324	#ifdef ASSERT
duke@435	325	test->verify();
duke@435	326	#endif
duke@435	327	return test;
duke@435	328	}
duke@435	329
duke@435	330	class NativeMovRegMemPatching: public NativeMovRegMem {
duke@435	331	private:
duke@435	332	friend NativeMovRegMemPatching* nativeMovRegMemPatching_at (address address) {
duke@435	333	NativeMovRegMemPatching* test = (NativeMovRegMemPatching*)(address - instruction_offset);
duke@435	334	#ifdef ASSERT
duke@435	335	test->verify();
duke@435	336	#endif
duke@435	337	return test;
duke@435	338	}
duke@435	339	};
duke@435	340
duke@435	341
duke@435	342
duke@435	343	// An interface for accessing/manipulating native leal instruction of form:
duke@435	344	// leal reg, [reg + offset]
duke@435	345
duke@435	346	class NativeLoadAddress: public NativeMovRegMem {
never@739	347	#ifdef AMD64
never@739	348	static const bool has_rex = true;
never@739	349	static const int rex_size = 1;
never@739	350	#else
never@739	351	static const bool has_rex = false;
never@739	352	static const int rex_size = 0;
never@739	353	#endif // AMD64
duke@435	354	public:
duke@435	355	enum Intel_specific_constants {
never@739	356	instruction_prefix_wide = Assembler::REX_W,
never@739	357	instruction_prefix_wide_extended = Assembler::REX_WB,
never@739	358	lea_instruction_code = 0x8D,
never@739	359	mov64_instruction_code = 0xB8
duke@435	360	};
duke@435	361
duke@435	362	void verify();
duke@435	363	void print ();
duke@435	364
duke@435	365	// unit test stuff
duke@435	366	static void test() {}
duke@435	367
duke@435	368	private:
duke@435	369	friend NativeLoadAddress* nativeLoadAddress_at (address address) {
duke@435	370	NativeLoadAddress* test = (NativeLoadAddress*)(address - instruction_offset);
duke@435	371	#ifdef ASSERT
duke@435	372	test->verify();
duke@435	373	#endif
duke@435	374	return test;
duke@435	375	}
duke@435	376	};
duke@435	377
duke@435	378	// jump rel32off
duke@435	379
duke@435	380	class NativeJump: public NativeInstruction {
duke@435	381	public:
duke@435	382	enum Intel_specific_constants {
duke@435	383	instruction_code = 0xe9,
duke@435	384	instruction_size = 5,
duke@435	385	instruction_offset = 0,
duke@435	386	data_offset = 1,
duke@435	387	next_instruction_offset = 5
duke@435	388	};
duke@435	389
duke@435	390	address instruction_address() const { return addr_at(instruction_offset); }
duke@435	391	address next_instruction_address() const { return addr_at(next_instruction_offset); }
duke@435	392	address jump_destination() const {
duke@435	393	address dest = (int_at(data_offset)+next_instruction_address());
never@739	394	// 32bit used to encode unresolved jmp as jmp -1
never@739	395	// 64bit can't produce this so it used jump to self.
never@739	396	// Now 32bit and 64bit use jump to self as the unresolved address
never@739	397	// which the inline cache code (and relocs) know about
never@739	398
duke@435	399	// return -1 if jump to self
duke@435	400	dest = (dest == (address) this) ? (address) -1 : dest;
duke@435	401	return dest;
duke@435	402	}
duke@435	403
duke@435	404	void set_jump_destination(address dest) {
duke@435	405	intptr_t val = dest - next_instruction_address();
never@749	406	if (dest == (address) -1) {
never@749	407	val = -5; // jump to self
never@749	408	}
duke@435	409	#ifdef AMD64
never@739	410	assert((labs(val) & 0xFFFFFFFF00000000) == 0 || dest == (address)-1, "must be 32bit offset or -1");
duke@435	411	#endif // AMD64
duke@435	412	set_int_at(data_offset, (jint)val);
duke@435	413	}
duke@435	414
duke@435	415	// Creation
duke@435	416	inline friend NativeJump* nativeJump_at(address address);
duke@435	417
duke@435	418	void verify();
duke@435	419
duke@435	420	// Unit testing stuff
duke@435	421	static void test() {}
duke@435	422
duke@435	423	// Insertion of native jump instruction
duke@435	424	static void insert(address code_pos, address entry);
duke@435	425	// MT-safe insertion of native jump at verified method entry
duke@435	426	static void check_verified_entry_alignment(address entry, address verified_entry);
duke@435	427	static void patch_verified_entry(address entry, address verified_entry, address dest);
duke@435	428	};
duke@435	429
duke@435	430	inline NativeJump* nativeJump_at(address address) {
duke@435	431	NativeJump* jump = (NativeJump*)(address - NativeJump::instruction_offset);
duke@435	432	#ifdef ASSERT
duke@435	433	jump->verify();
duke@435	434	#endif
duke@435	435	return jump;
duke@435	436	}
duke@435	437
duke@435	438	// Handles all kinds of jump on Intel. Long/far, conditional/unconditional
duke@435	439	class NativeGeneralJump: public NativeInstruction {
duke@435	440	public:
duke@435	441	enum Intel_specific_constants {
duke@435	442	// Constants does not apply, since the lengths and offsets depends on the actual jump
duke@435	443	// used
duke@435	444	// Instruction codes:
duke@435	445	// Unconditional jumps: 0xE9 (rel32off), 0xEB (rel8off)
duke@435	446	// Conditional jumps: 0x0F8x (rel32off), 0x7x (rel8off)
duke@435	447	unconditional_long_jump = 0xe9,
duke@435	448	unconditional_short_jump = 0xeb,
duke@435	449	instruction_size = 5
duke@435	450	};
duke@435	451
duke@435	452	address instruction_address() const { return addr_at(0); }
duke@435	453	address jump_destination() const;
duke@435	454
duke@435	455	// Creation
duke@435	456	inline friend NativeGeneralJump* nativeGeneralJump_at(address address);
duke@435	457
duke@435	458	// Insertion of native general jump instruction
duke@435	459	static void insert_unconditional(address code_pos, address entry);
duke@435	460	static void replace_mt_safe(address instr_addr, address code_buffer);
duke@435	461
duke@435	462	void verify();
duke@435	463	};
duke@435	464
duke@435	465	inline NativeGeneralJump* nativeGeneralJump_at(address address) {
duke@435	466	NativeGeneralJump* jump = (NativeGeneralJump*)(address);
duke@435	467	debug_only(jump->verify();)
duke@435	468	return jump;
duke@435	469	}
duke@435	470
duke@435	471	class NativePopReg : public NativeInstruction {
duke@435	472	public:
duke@435	473	enum Intel_specific_constants {
duke@435	474	instruction_code = 0x58,
duke@435	475	instruction_size = 1,
duke@435	476	instruction_offset = 0,
duke@435	477	data_offset = 1,
duke@435	478	next_instruction_offset = 1
duke@435	479	};
duke@435	480
duke@435	481	// Insert a pop instruction
duke@435	482	static void insert(address code_pos, Register reg);
duke@435	483	};
duke@435	484
duke@435	485
duke@435	486	class NativeIllegalInstruction: public NativeInstruction {
duke@435	487	public:
duke@435	488	enum Intel_specific_constants {
duke@435	489	instruction_code = 0x0B0F, // Real byte order is: 0x0F, 0x0B
duke@435	490	instruction_size = 2,
duke@435	491	instruction_offset = 0,
duke@435	492	next_instruction_offset = 2
duke@435	493	};
duke@435	494
duke@435	495	// Insert illegal opcode as specific address
duke@435	496	static void insert(address code_pos);
duke@435	497	};
duke@435	498
duke@435	499	// return instruction that does not pop values of the stack
duke@435	500	class NativeReturn: public NativeInstruction {
duke@435	501	public:
duke@435	502	enum Intel_specific_constants {
duke@435	503	instruction_code = 0xC3,
duke@435	504	instruction_size = 1,
duke@435	505	instruction_offset = 0,
duke@435	506	next_instruction_offset = 1
duke@435	507	};
duke@435	508	};
duke@435	509
duke@435	510	// return instruction that does pop values of the stack
duke@435	511	class NativeReturnX: public NativeInstruction {
duke@435	512	public:
duke@435	513	enum Intel_specific_constants {
duke@435	514	instruction_code = 0xC2,
duke@435	515	instruction_size = 2,
duke@435	516	instruction_offset = 0,
duke@435	517	next_instruction_offset = 2
duke@435	518	};
duke@435	519	};
duke@435	520
duke@435	521	// Simple test vs memory
duke@435	522	class NativeTstRegMem: public NativeInstruction {
duke@435	523	public:
duke@435	524	enum Intel_specific_constants {
iveresov@2686	525	instruction_rex_prefix_mask = 0xF0,
iveresov@2686	526	instruction_rex_prefix = Assembler::REX,
iveresov@2686	527	instruction_code_memXregl = 0x85,
iveresov@2686	528	modrm_mask = 0x38, // select reg from the ModRM byte
iveresov@2686	529	modrm_reg = 0x00 // rax
duke@435	530	};
duke@435	531	};
duke@435	532
duke@435	533	inline bool NativeInstruction::is_illegal() { return (short)int_at(0) == (short)NativeIllegalInstruction::instruction_code; }
duke@435	534	inline bool NativeInstruction::is_call() { return ubyte_at(0) == NativeCall::instruction_code; }
duke@435	535	inline bool NativeInstruction::is_return() { return ubyte_at(0) == NativeReturn::instruction_code ||
duke@435	536	ubyte_at(0) == NativeReturnX::instruction_code; }
duke@435	537	inline bool NativeInstruction::is_jump() { return ubyte_at(0) == NativeJump::instruction_code ||
duke@435	538	ubyte_at(0) == 0xEB; /* short jump */ }
duke@435	539	inline bool NativeInstruction::is_cond_jump() { return (int_at(0) & 0xF0FF) == 0x800F /* long jump */ ||
duke@435	540	(ubyte_at(0) & 0xF0) == 0x70; /* short jump */ }
duke@435	541	inline bool NativeInstruction::is_safepoint_poll() {
duke@435	542	#ifdef AMD64
iveresov@2686	543	if (Assembler::is_polling_page_far()) {
iveresov@2686	544	// two cases, depending on the choice of the base register in the address.
iveresov@2686	545	if (((ubyte_at(0) & NativeTstRegMem::instruction_rex_prefix_mask) == NativeTstRegMem::instruction_rex_prefix &&
iveresov@2686	546	ubyte_at(1) == NativeTstRegMem::instruction_code_memXregl &&
iveresov@2686	547	(ubyte_at(2) & NativeTstRegMem::modrm_mask) == NativeTstRegMem::modrm_reg) ||
iveresov@2686	548	ubyte_at(0) == NativeTstRegMem::instruction_code_memXregl &&
iveresov@2686	549	(ubyte_at(1) & NativeTstRegMem::modrm_mask) == NativeTstRegMem::modrm_reg) {
iveresov@2686	550	return true;
iveresov@2686	551	} else {
iveresov@2686	552	return false;
iveresov@2686	553	}
never@739	554	} else {
iveresov@2686	555	if (ubyte_at(0) == NativeTstRegMem::instruction_code_memXregl &&
iveresov@2686	556	ubyte_at(1) == 0x05) { // 00 rax 101
iveresov@2686	557	address fault = addr_at(6) + int_at(2);
iveresov@2686	558	return os::is_poll_address(fault);
iveresov@2686	559	} else {
iveresov@2686	560	return false;
iveresov@2686	561	}
never@739	562	}
duke@435	563	#else
never@739	564	return ( ubyte_at(0) == NativeMovRegMem::instruction_code_mem2reg ||
duke@435	565	ubyte_at(0) == NativeTstRegMem::instruction_code_memXregl ) &&
duke@435	566	(ubyte_at(1)&0xC7) == 0x05 && /* Mod R/M == disp32 */
duke@435	567	(os::is_poll_address((address)int_at(2)));
duke@435	568	#endif // AMD64
duke@435	569	}
duke@435	570
duke@435	571	inline bool NativeInstruction::is_mov_literal64() {
duke@435	572	#ifdef AMD64
duke@435	573	return ((ubyte_at(0) == Assembler::REX_W || ubyte_at(0) == Assembler::REX_WB) &&
duke@435	574	(ubyte_at(1) & (0xff ^ NativeMovConstReg::register_mask)) == 0xB8);
duke@435	575	#else
duke@435	576	return false;
duke@435	577	#endif // AMD64
duke@435	578	}
stefank@2314	579
stefank@2314	580	#endif // CPU_X86_VM_NATIVEINST_X86_HPP