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src/cpu/sparc/vm/nativeInst_sparc.hpp@740e263c80c6 (annotated)

src/cpu/sparc/vm/nativeInst_sparc.hpp

Thu, 15 Aug 2013 20:04:10 -0400

author

hseigel

date

Thu, 15 Aug 2013 20:04:10 -0400

changeset 5528

740e263c80c6

parent 5283

46c544b8fbfc

child 6198

55fb97c4c58d

permissions

-rw-r--r--

8003424: Enable Class Data Sharing for CompressedOops
8016729: ObjectAlignmentInBytes=16 now forces the use of heap based compressed oops
8005933: The -Xshare:auto option is ignored for -server
Summary: Move klass metaspace above the heap and support CDS with compressed klass ptrs.
Reviewed-by: coleenp, kvn, mgerdin, tschatzl, stefank

duke@435	1	/*
coleenp@4037	2	* Copyright (c) 1997, 2012, 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_SPARC_VM_NATIVEINST_SPARC_HPP
stefank@2314	26	#define CPU_SPARC_VM_NATIVEINST_SPARC_HPP
stefank@2314	27
twisti@4323	28	#include "asm/macroAssembler.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 interface for the following instructions:
duke@435	35	// - NativeInstruction
duke@435	36	// - - NativeCall
duke@435	37	// - - NativeFarCall
duke@435	38	// - - NativeMovConstReg
duke@435	39	// - - NativeMovConstRegPatching
duke@435	40	// - - NativeMovRegMem
duke@435	41	// - - NativeMovRegMemPatching
duke@435	42	// - - NativeJump
duke@435	43	// - - NativeGeneralJump
duke@435	44	// - - NativeIllegalInstruction
duke@435	45	// The base class for different kinds of native instruction abstractions.
duke@435	46	// Provides the primitive operations to manipulate code relative to this.
duke@435	47	class NativeInstruction VALUE_OBJ_CLASS_SPEC {
duke@435	48	friend class Relocation;
duke@435	49
duke@435	50	public:
duke@435	51	enum Sparc_specific_constants {
duke@435	52	nop_instruction_size = 4
duke@435	53	};
duke@435	54
kamg@551	55	bool is_dtrace_trap();
duke@435	56	bool is_nop() { return long_at(0) == nop_instruction(); }
duke@435	57	bool is_call() { return is_op(long_at(0), Assembler::call_op); }
duke@435	58	bool is_sethi() { return (is_op2(long_at(0), Assembler::sethi_op2)
duke@435	59	&& inv_rd(long_at(0)) != G0); }
duke@435	60
duke@435	61	bool sets_cc() {
duke@435	62	// conservative (returns true for some instructions that do not set the
duke@435	63	// the condition code, such as, "save".
duke@435	64	// Does not return true for the deprecated tagged instructions, such as, TADDcc
duke@435	65	int x = long_at(0);
duke@435	66	return (is_op(x, Assembler::arith_op) &&
duke@435	67	(inv_op3(x) & Assembler::cc_bit_op3) == Assembler::cc_bit_op3);
duke@435	68	}
duke@435	69	bool is_illegal();
duke@435	70	bool is_zombie() {
duke@435	71	int x = long_at(0);
duke@435	72	return is_op3(x,
morris@5283	73	Assembler::ldsw_op3,
duke@435	74	Assembler::ldst_op)
duke@435	75	&& Assembler::inv_rs1(x) == G0
duke@435	76	&& Assembler::inv_rd(x) == O7;
duke@435	77	}
duke@435	78	bool is_ic_miss_trap(); // Inline-cache uses a trap to detect a miss
duke@435	79	bool is_return() {
duke@435	80	// is it the output of MacroAssembler::ret or MacroAssembler::retl?
duke@435	81	int x = long_at(0);
duke@435	82	const int pc_return_offset = 8; // see frame_sparc.hpp
duke@435	83	return is_op3(x, Assembler::jmpl_op3, Assembler::arith_op)
duke@435	84	&& (inv_rs1(x) == I7 || inv_rs1(x) == O7)
duke@435	85	&& inv_immed(x) && inv_simm(x, 13) == pc_return_offset
duke@435	86	&& inv_rd(x) == G0;
duke@435	87	}
duke@435	88	bool is_int_jump() {
duke@435	89	// is it the output of MacroAssembler::b?
duke@435	90	int x = long_at(0);
duke@435	91	return is_op2(x, Assembler::bp_op2) || is_op2(x, Assembler::br_op2);
duke@435	92	}
duke@435	93	bool is_float_jump() {
duke@435	94	// is it the output of MacroAssembler::fb?
duke@435	95	int x = long_at(0);
duke@435	96	return is_op2(x, Assembler::fbp_op2) || is_op2(x, Assembler::fb_op2);
duke@435	97	}
duke@435	98	bool is_jump() {
duke@435	99	return is_int_jump() || is_float_jump();
duke@435	100	}
duke@435	101	bool is_cond_jump() {
duke@435	102	int x = long_at(0);
duke@435	103	return (is_int_jump() && Assembler::inv_cond(x) != Assembler::always) ||
duke@435	104	(is_float_jump() && Assembler::inv_cond(x) != Assembler::f_always);
duke@435	105	}
duke@435	106
duke@435	107	bool is_stack_bang() {
duke@435	108	int x = long_at(0);
duke@435	109	return is_op3(x, Assembler::stw_op3, Assembler::ldst_op) &&
duke@435	110	(inv_rd(x) == G0) && (inv_rs1(x) == SP) && (inv_rs2(x) == G3_scratch);
duke@435	111	}
duke@435	112
duke@435	113	bool is_prefetch() {
duke@435	114	int x = long_at(0);
duke@435	115	return is_op3(x, Assembler::prefetch_op3, Assembler::ldst_op);
duke@435	116	}
duke@435	117
duke@435	118	bool is_membar() {
duke@435	119	int x = long_at(0);
duke@435	120	return is_op3(x, Assembler::membar_op3, Assembler::arith_op) &&
duke@435	121	(inv_rd(x) == G0) && (inv_rs1(x) == O7);
duke@435	122	}
duke@435	123
duke@435	124	bool is_safepoint_poll() {
duke@435	125	int x = long_at(0);
duke@435	126	#ifdef _LP64
duke@435	127	return is_op3(x, Assembler::ldx_op3, Assembler::ldst_op) &&
duke@435	128	#else
duke@435	129	return is_op3(x, Assembler::lduw_op3, Assembler::ldst_op) &&
duke@435	130	#endif
duke@435	131	(inv_rd(x) == G0) && (inv_immed(x) ? Assembler::inv_simm13(x) == 0 : inv_rs2(x) == G0);
duke@435	132	}
duke@435	133
duke@435	134	bool is_zero_test(Register &reg);
duke@435	135	bool is_load_store_with_small_offset(Register reg);
duke@435	136
duke@435	137	public:
duke@435	138	#ifdef ASSERT
duke@435	139	static int rdpc_instruction() { return Assembler::op(Assembler::arith_op ) | Assembler::op3(Assembler::rdreg_op3) | Assembler::u_field(5, 18, 14) | Assembler::rd(O7); }
duke@435	140	#else
duke@435	141	// Temporary fix: in optimized mode, u_field is a macro for efficiency reasons (see Assembler::u_field) - needs to be fixed
duke@435	142	static int rdpc_instruction() { return Assembler::op(Assembler::arith_op ) | Assembler::op3(Assembler::rdreg_op3) | u_field(5, 18, 14) | Assembler::rd(O7); }
duke@435	143	#endif
duke@435	144	static int nop_instruction() { return Assembler::op(Assembler::branch_op) | Assembler::op2(Assembler::sethi_op2); }
duke@435	145	static int illegal_instruction(); // the output of __ breakpoint_trap()
duke@435	146	static int call_instruction(address destination, address pc) { return Assembler::op(Assembler::call_op) | Assembler::wdisp((intptr_t)destination, (intptr_t)pc, 30); }
duke@435	147
duke@435	148	static int branch_instruction(Assembler::op2s op2val, Assembler::Condition c, bool a) {
duke@435	149	return Assembler::op(Assembler::branch_op) | Assembler::op2(op2val) | Assembler::annul(a) | Assembler::cond(c);
duke@435	150	}
duke@435	151
duke@435	152	static int op3_instruction(Assembler::ops opval, Register rd, Assembler::op3s op3val, Register rs1, int simm13a) {
duke@435	153	return Assembler::op(opval) | Assembler::rd(rd) | Assembler::op3(op3val) | Assembler::rs1(rs1) | Assembler::immed(true) | Assembler::simm(simm13a, 13);
duke@435	154	}
duke@435	155
duke@435	156	static int sethi_instruction(Register rd, int imm22a) {
duke@435	157	return Assembler::op(Assembler::branch_op) | Assembler::rd(rd) | Assembler::op2(Assembler::sethi_op2) | Assembler::hi22(imm22a);
duke@435	158	}
duke@435	159
duke@435	160	protected:
duke@435	161	address addr_at(int offset) const { return address(this) + offset; }
duke@435	162	int long_at(int offset) const { return *(int*)addr_at(offset); }
duke@435	163	void set_long_at(int offset, int i); /* deals with I-cache */
duke@435	164	void set_jlong_at(int offset, jlong i); /* deals with I-cache */
duke@435	165	void set_addr_at(int offset, address x); /* deals with I-cache */
duke@435	166
duke@435	167	address instruction_address() const { return addr_at(0); }
duke@435	168	address next_instruction_address() const { return addr_at(BytesPerInstWord); }
duke@435	169
duke@435	170	static bool is_op( int x, Assembler::ops opval) {
duke@435	171	return Assembler::inv_op(x) == opval;
duke@435	172	}
duke@435	173	static bool is_op2(int x, Assembler::op2s op2val) {
duke@435	174	return Assembler::inv_op(x) == Assembler::branch_op && Assembler::inv_op2(x) == op2val;
duke@435	175	}
duke@435	176	static bool is_op3(int x, Assembler::op3s op3val, Assembler::ops opval) {
duke@435	177	return Assembler::inv_op(x) == opval && Assembler::inv_op3(x) == op3val;
duke@435	178	}
duke@435	179
duke@435	180	// utilities to help subclasses decode:
duke@435	181	static Register inv_rd( int x ) { return Assembler::inv_rd( x); }
duke@435	182	static Register inv_rs1( int x ) { return Assembler::inv_rs1(x); }
duke@435	183	static Register inv_rs2( int x ) { return Assembler::inv_rs2(x); }
duke@435	184
duke@435	185	static bool inv_immed( int x ) { return Assembler::inv_immed(x); }
duke@435	186	static bool inv_annul( int x ) { return (Assembler::annul(true) & x) != 0; }
duke@435	187	static int inv_cond( int x ) { return Assembler::inv_cond(x); }
duke@435	188
duke@435	189	static int inv_op( int x ) { return Assembler::inv_op( x); }
duke@435	190	static int inv_op2( int x ) { return Assembler::inv_op2(x); }
duke@435	191	static int inv_op3( int x ) { return Assembler::inv_op3(x); }
duke@435	192
duke@435	193	static int inv_simm( int x, int nbits ) { return Assembler::inv_simm(x, nbits); }
duke@435	194	static intptr_t inv_wdisp( int x, int nbits ) { return Assembler::inv_wdisp( x, 0, nbits); }
duke@435	195	static intptr_t inv_wdisp16( int x ) { return Assembler::inv_wdisp16(x, 0); }
twisti@4323	196	static int branch_destination_offset(int x) { return MacroAssembler::branch_destination(x, 0); }
duke@435	197	static int patch_branch_destination_offset(int dest_offset, int x) {
twisti@4323	198	return MacroAssembler::patched_branch(dest_offset, x, 0);
duke@435	199	}
duke@435	200
duke@435	201	// utility for checking if x is either of 2 small constants
duke@435	202	static bool is_either(int x, int k1, int k2) {
duke@435	203	// return x == k1 || x == k2;
duke@435	204	return (1 << x) & (1 << k1 | 1 << k2);
duke@435	205	}
duke@435	206
duke@435	207	// utility for checking overflow of signed instruction fields
duke@435	208	static bool fits_in_simm(int x, int nbits) {
duke@435	209	// cf. Assembler::assert_signed_range()
duke@435	210	// return -(1 << nbits-1) <= x && x < ( 1 << nbits-1),
duke@435	211	return (unsigned)(x + (1 << nbits-1)) < (unsigned)(1 << nbits);
duke@435	212	}
duke@435	213
duke@435	214	// set a signed immediate field
duke@435	215	static int set_simm(int insn, int imm, int nbits) {
duke@435	216	return (insn &~ Assembler::simm(-1, nbits)) | Assembler::simm(imm, nbits);
duke@435	217	}
duke@435	218
duke@435	219	// set a wdisp field (disp should be the difference of two addresses)
duke@435	220	static int set_wdisp(int insn, intptr_t disp, int nbits) {
duke@435	221	return (insn &~ Assembler::wdisp((intptr_t)-4, (intptr_t)0, nbits)) | Assembler::wdisp(disp, 0, nbits);
duke@435	222	}
duke@435	223
duke@435	224	static int set_wdisp16(int insn, intptr_t disp) {
duke@435	225	return (insn &~ Assembler::wdisp16((intptr_t)-4, 0)) | Assembler::wdisp16(disp, 0);
duke@435	226	}
duke@435	227
duke@435	228	// get a simm13 field from an arithmetic or memory instruction
duke@435	229	static int get_simm13(int insn) {
duke@435	230	assert(is_either(Assembler::inv_op(insn),
duke@435	231	Assembler::arith_op, Assembler::ldst_op) &&
duke@435	232	(insn & Assembler::immed(true)), "must have a simm13 field");
duke@435	233	return Assembler::inv_simm(insn, 13);
duke@435	234	}
duke@435	235
duke@435	236	// set the simm13 field of an arithmetic or memory instruction
duke@435	237	static bool set_simm13(int insn, int imm) {
duke@435	238	get_simm13(insn); // tickle the assertion check
duke@435	239	return set_simm(insn, imm, 13);
duke@435	240	}
duke@435	241
duke@435	242	// combine the fields of a sethi stream (7 instructions ) and an add, jmp or ld/st
duke@435	243	static intptr_t data64( address pc, int arith_insn ) {
duke@435	244	assert(is_op2(*(unsigned int *)pc, Assembler::sethi_op2), "must be sethi");
duke@435	245	intptr_t hi = (intptr_t)gethi( (unsigned int *)pc );
duke@435	246	intptr_t lo = (intptr_t)get_simm13(arith_insn);
coleenp@4037	247	assert((unsigned)lo < (1 << 10), "offset field of set_metadata must be 10 bits");
duke@435	248	return hi | lo;
duke@435	249	}
duke@435	250
duke@435	251	// Regenerate the instruction sequence that performs the 64 bit
duke@435	252	// sethi. This only does the sethi. The disp field (bottom 10 bits)
twisti@1040	253	// must be handled separately.
duke@435	254	static void set_data64_sethi(address instaddr, intptr_t x);
never@2657	255	static void verify_data64_sethi(address instaddr, intptr_t x);
duke@435	256
duke@435	257	// combine the fields of a sethi/simm13 pair (simm13 = or, add, jmpl, ld/st)
duke@435	258	static int data32(int sethi_insn, int arith_insn) {
duke@435	259	assert(is_op2(sethi_insn, Assembler::sethi_op2), "must be sethi");
duke@435	260	int hi = Assembler::inv_hi22(sethi_insn);
duke@435	261	int lo = get_simm13(arith_insn);
coleenp@4037	262	assert((unsigned)lo < (1 << 10), "offset field of set_metadata must be 10 bits");
duke@435	263	return hi | lo;
duke@435	264	}
duke@435	265
duke@435	266	static int set_data32_sethi(int sethi_insn, int imm) {
duke@435	267	// note that Assembler::hi22 clips the low 10 bits for us
duke@435	268	assert(is_op2(sethi_insn, Assembler::sethi_op2), "must be sethi");
duke@435	269	return (sethi_insn &~ Assembler::hi22(-1)) | Assembler::hi22(imm);
duke@435	270	}
duke@435	271
duke@435	272	static int set_data32_simm13(int arith_insn, int imm) {
duke@435	273	get_simm13(arith_insn); // tickle the assertion check
duke@435	274	int imm10 = Assembler::low10(imm);
duke@435	275	return (arith_insn &~ Assembler::simm(-1, 13)) | Assembler::simm(imm10, 13);
duke@435	276	}
duke@435	277
duke@435	278	static int low10(int imm) {
duke@435	279	return Assembler::low10(imm);
duke@435	280	}
duke@435	281
duke@435	282	// Perform the inverse of the LP64 Macroassembler::sethi
duke@435	283	// routine. Extracts the 54 bits of address from the instruction
duke@435	284	// stream. This routine must agree with the sethi routine in
duke@435	285	// assembler_inline_sparc.hpp
duke@435	286	static address gethi( unsigned int *pc ) {
duke@435	287	int i = 0;
duke@435	288	uintptr_t adr;
duke@435	289	// We first start out with the real sethi instruction
duke@435	290	assert(is_op2(*pc, Assembler::sethi_op2), "in gethi - must be sethi");
duke@435	291	adr = (unsigned int)Assembler::inv_hi22( *(pc++) );
duke@435	292	i++;
duke@435	293	while ( i < 7 ) {
duke@435	294	// We're done if we hit a nop
duke@435	295	if ( (int)*pc == nop_instruction() ) break;
duke@435	296	assert ( Assembler::inv_op(*pc) == Assembler::arith_op, "in gethi - must be arith_op" );
duke@435	297	switch ( Assembler::inv_op3(*pc) ) {
duke@435	298	case Assembler::xor_op3:
duke@435	299	adr ^= (intptr_t)get_simm13( *pc );
duke@435	300	return ( (address)adr );
duke@435	301	break;
duke@435	302	case Assembler::sll_op3:
duke@435	303	adr <<= ( *pc & 0x3f );
duke@435	304	break;
duke@435	305	case Assembler::or_op3:
duke@435	306	adr |= (intptr_t)get_simm13( *pc );
duke@435	307	break;
duke@435	308	default:
duke@435	309	assert ( 0, "in gethi - Should not reach here" );
duke@435	310	break;
duke@435	311	}
duke@435	312	pc++;
duke@435	313	i++;
duke@435	314	}
duke@435	315	return ( (address)adr );
duke@435	316	}
duke@435	317
duke@435	318	public:
duke@435	319	void verify();
duke@435	320	void print();
duke@435	321
duke@435	322	// unit test stuff
duke@435	323	static void test() {} // override for testing
duke@435	324
duke@435	325	inline friend NativeInstruction* nativeInstruction_at(address address);
duke@435	326	};
duke@435	327
duke@435	328	inline NativeInstruction* nativeInstruction_at(address address) {
duke@435	329	NativeInstruction* inst = (NativeInstruction*)address;
duke@435	330	#ifdef ASSERT
duke@435	331	inst->verify();
duke@435	332	#endif
duke@435	333	return inst;
duke@435	334	}
duke@435	335
duke@435	336
duke@435	337
duke@435	338	//-----------------------------------------------------------------------------
duke@435	339
duke@435	340	// The NativeCall is an abstraction for accessing/manipulating native call imm32 instructions.
duke@435	341	// (used to manipulate inline caches, primitive & dll calls, etc.)
duke@435	342	inline NativeCall* nativeCall_at(address instr);
duke@435	343	inline NativeCall* nativeCall_overwriting_at(address instr,
duke@435	344	address destination);
duke@435	345	inline NativeCall* nativeCall_before(address return_address);
duke@435	346	class NativeCall: public NativeInstruction {
duke@435	347	public:
duke@435	348	enum Sparc_specific_constants {
duke@435	349	instruction_size = 8,
duke@435	350	return_address_offset = 8,
duke@435	351	call_displacement_width = 30,
duke@435	352	displacement_offset = 0,
duke@435	353	instruction_offset = 0
duke@435	354	};
duke@435	355	address instruction_address() const { return addr_at(0); }
duke@435	356	address next_instruction_address() const { return addr_at(instruction_size); }
duke@435	357	address return_address() const { return addr_at(return_address_offset); }
duke@435	358
duke@435	359	address destination() const { return inv_wdisp(long_at(0), call_displacement_width) + instruction_address(); }
duke@435	360	address displacement_address() const { return addr_at(displacement_offset); }
duke@435	361	void set_destination(address dest) { set_long_at(0, set_wdisp(long_at(0), dest - instruction_address(), call_displacement_width)); }
duke@435	362	void set_destination_mt_safe(address dest);
duke@435	363
duke@435	364	void verify_alignment() {} // do nothing on sparc
duke@435	365	void verify();
duke@435	366	void print();
duke@435	367
duke@435	368	// unit test stuff
duke@435	369	static void test();
duke@435	370
duke@435	371	// Creation
duke@435	372	friend inline NativeCall* nativeCall_at(address instr);
duke@435	373	friend NativeCall* nativeCall_overwriting_at(address instr, address destination = NULL) {
duke@435	374	// insert a "blank" call:
duke@435	375	NativeCall* call = (NativeCall*)instr;
duke@435	376	call->set_long_at(0 * BytesPerInstWord, call_instruction(destination, instr));
duke@435	377	call->set_long_at(1 * BytesPerInstWord, nop_instruction());
duke@435	378	assert(call->addr_at(2 * BytesPerInstWord) - instr == instruction_size, "instruction size");
duke@435	379	// check its structure now:
duke@435	380	assert(nativeCall_at(instr)->destination() == destination, "correct call destination");
duke@435	381	return call;
duke@435	382	}
duke@435	383
duke@435	384	friend inline NativeCall* nativeCall_before(address return_address) {
duke@435	385	NativeCall* call = (NativeCall*)(return_address - return_address_offset);
duke@435	386	#ifdef ASSERT
duke@435	387	call->verify();
duke@435	388	#endif
duke@435	389	return call;
duke@435	390	}
duke@435	391
duke@435	392	static bool is_call_at(address instr) {
duke@435	393	return nativeInstruction_at(instr)->is_call();
duke@435	394	}
duke@435	395
duke@435	396	static bool is_call_before(address instr) {
duke@435	397	return nativeInstruction_at(instr - return_address_offset)->is_call();
duke@435	398	}
duke@435	399
duke@435	400	static bool is_call_to(address instr, address target) {
duke@435	401	return nativeInstruction_at(instr)->is_call() &&
duke@435	402	nativeCall_at(instr)->destination() == target;
duke@435	403	}
duke@435	404
duke@435	405	// MT-safe patching of a call instruction.
duke@435	406	static void insert(address code_pos, address entry) {
duke@435	407	(void)nativeCall_overwriting_at(code_pos, entry);
duke@435	408	}
duke@435	409
duke@435	410	static void replace_mt_safe(address instr_addr, address code_buffer);
duke@435	411	};
duke@435	412	inline NativeCall* nativeCall_at(address instr) {
duke@435	413	NativeCall* call = (NativeCall*)instr;
duke@435	414	#ifdef ASSERT
duke@435	415	call->verify();
duke@435	416	#endif
duke@435	417	return call;
duke@435	418	}
duke@435	419
duke@435	420	// The NativeFarCall is an abstraction for accessing/manipulating native call-anywhere
duke@435	421	// instructions in the sparcv9 vm. Used to call native methods which may be loaded
duke@435	422	// anywhere in the address space, possibly out of reach of a call instruction.
duke@435	423
duke@435	424	#ifndef _LP64
duke@435	425
duke@435	426	// On 32-bit systems, a far call is the same as a near one.
duke@435	427	class NativeFarCall;
duke@435	428	inline NativeFarCall* nativeFarCall_at(address instr);
duke@435	429	class NativeFarCall : public NativeCall {
duke@435	430	public:
duke@435	431	friend inline NativeFarCall* nativeFarCall_at(address instr) { return (NativeFarCall*)nativeCall_at(instr); }
duke@435	432	friend NativeFarCall* nativeFarCall_overwriting_at(address instr, address destination = NULL)
duke@435	433	{ return (NativeFarCall*)nativeCall_overwriting_at(instr, destination); }
duke@435	434	friend NativeFarCall* nativeFarCall_before(address return_address)
duke@435	435	{ return (NativeFarCall*)nativeCall_before(return_address); }
duke@435	436	};
duke@435	437
duke@435	438	#else
duke@435	439
duke@435	440	// The format of this extended-range call is:
duke@435	441	// jumpl_to addr, lreg
duke@435	442	// == sethi %hi54(addr), O7 ; jumpl O7, %lo10(addr), O7 ; <delay>
duke@435	443	// That is, it is essentially the same as a NativeJump.
duke@435	444	class NativeFarCall;
duke@435	445	inline NativeFarCall* nativeFarCall_overwriting_at(address instr, address destination);
duke@435	446	inline NativeFarCall* nativeFarCall_at(address instr);
duke@435	447	class NativeFarCall: public NativeInstruction {
duke@435	448	public:
duke@435	449	enum Sparc_specific_constants {
duke@435	450	// instruction_size includes the delay slot instruction.
duke@435	451	instruction_size = 9 * BytesPerInstWord,
duke@435	452	return_address_offset = 9 * BytesPerInstWord,
duke@435	453	jmpl_offset = 7 * BytesPerInstWord,
duke@435	454	displacement_offset = 0,
duke@435	455	instruction_offset = 0
duke@435	456	};
duke@435	457	address instruction_address() const { return addr_at(0); }
duke@435	458	address next_instruction_address() const { return addr_at(instruction_size); }
duke@435	459	address return_address() const { return addr_at(return_address_offset); }
duke@435	460
duke@435	461	address destination() const {
duke@435	462	return (address) data64(addr_at(0), long_at(jmpl_offset));
duke@435	463	}
duke@435	464	address displacement_address() const { return addr_at(displacement_offset); }
duke@435	465	void set_destination(address dest);
duke@435	466
duke@435	467	bool destination_is_compiled_verified_entry_point();
duke@435	468
duke@435	469	void verify();
duke@435	470	void print();
duke@435	471
duke@435	472	// unit test stuff
duke@435	473	static void test();
duke@435	474
duke@435	475	// Creation
duke@435	476	friend inline NativeFarCall* nativeFarCall_at(address instr) {
duke@435	477	NativeFarCall* call = (NativeFarCall*)instr;
duke@435	478	#ifdef ASSERT
duke@435	479	call->verify();
duke@435	480	#endif
duke@435	481	return call;
duke@435	482	}
duke@435	483
duke@435	484	friend inline NativeFarCall* nativeFarCall_overwriting_at(address instr, address destination = NULL) {
duke@435	485	Unimplemented();
duke@435	486	NativeFarCall* call = (NativeFarCall*)instr;
duke@435	487	return call;
duke@435	488	}
duke@435	489
duke@435	490	friend NativeFarCall* nativeFarCall_before(address return_address) {
duke@435	491	NativeFarCall* call = (NativeFarCall*)(return_address - return_address_offset);
duke@435	492	#ifdef ASSERT
duke@435	493	call->verify();
duke@435	494	#endif
duke@435	495	return call;
duke@435	496	}
duke@435	497
duke@435	498	static bool is_call_at(address instr);
duke@435	499
duke@435	500	// MT-safe patching of a call instruction.
duke@435	501	static void insert(address code_pos, address entry) {
duke@435	502	(void)nativeFarCall_overwriting_at(code_pos, entry);
duke@435	503	}
duke@435	504	static void replace_mt_safe(address instr_addr, address code_buffer);
duke@435	505	};
duke@435	506
duke@435	507	#endif // _LP64
duke@435	508
coleenp@4037	509	// An interface for accessing/manipulating native set_metadata imm, reg instructions.
duke@435	510	// (used to manipulate inlined data references, etc.)
coleenp@4037	511	// set_metadata imm, reg
duke@435	512	// == sethi %hi22(imm), reg ; add reg, %lo10(imm), reg
duke@435	513	class NativeMovConstReg;
duke@435	514	inline NativeMovConstReg* nativeMovConstReg_at(address address);
duke@435	515	class NativeMovConstReg: public NativeInstruction {
duke@435	516	public:
duke@435	517	enum Sparc_specific_constants {
duke@435	518	sethi_offset = 0,
duke@435	519	#ifdef _LP64
duke@435	520	add_offset = 7 * BytesPerInstWord,
duke@435	521	instruction_size = 8 * BytesPerInstWord
duke@435	522	#else
duke@435	523	add_offset = 4,
duke@435	524	instruction_size = 8
duke@435	525	#endif
duke@435	526	};
duke@435	527
duke@435	528	address instruction_address() const { return addr_at(0); }
duke@435	529	address next_instruction_address() const { return addr_at(instruction_size); }
duke@435	530
duke@435	531	// (The [set_]data accessor respects oop_type relocs also.)
duke@435	532	intptr_t data() const;
duke@435	533	void set_data(intptr_t x);
duke@435	534
duke@435	535	// report the destination register
duke@435	536	Register destination() { return inv_rd(long_at(sethi_offset)); }
duke@435	537
duke@435	538	void verify();
duke@435	539	void print();
duke@435	540
duke@435	541	// unit test stuff
duke@435	542	static void test();
duke@435	543
duke@435	544	// Creation
duke@435	545	friend inline NativeMovConstReg* nativeMovConstReg_at(address address) {
duke@435	546	NativeMovConstReg* test = (NativeMovConstReg*)address;
duke@435	547	#ifdef ASSERT
duke@435	548	test->verify();
duke@435	549	#endif
duke@435	550	return test;
duke@435	551	}
duke@435	552
duke@435	553
duke@435	554	friend NativeMovConstReg* nativeMovConstReg_before(address address) {
duke@435	555	NativeMovConstReg* test = (NativeMovConstReg*)(address - instruction_size);
duke@435	556	#ifdef ASSERT
duke@435	557	test->verify();
duke@435	558	#endif
duke@435	559	return test;
duke@435	560	}
duke@435	561
duke@435	562	};
duke@435	563
duke@435	564
coleenp@4037	565	// An interface for accessing/manipulating native set_metadata imm, reg instructions.
duke@435	566	// (used to manipulate inlined data references, etc.)
coleenp@4037	567	// set_metadata imm, reg
duke@435	568	// == sethi %hi22(imm), reg; nop; add reg, %lo10(imm), reg
duke@435	569	//
duke@435	570	// Note that it is identical to NativeMovConstReg with the exception of a nop between the
duke@435	571	// sethi and the add. The nop is required to be in the delay slot of the call instruction
duke@435	572	// which overwrites the sethi during patching.
duke@435	573	class NativeMovConstRegPatching;
duke@435	574	inline NativeMovConstRegPatching* nativeMovConstRegPatching_at(address address);class NativeMovConstRegPatching: public NativeInstruction {
duke@435	575	public:
duke@435	576	enum Sparc_specific_constants {
duke@435	577	sethi_offset = 0,
duke@435	578	#ifdef _LP64
duke@435	579	nop_offset = 7 * BytesPerInstWord,
duke@435	580	#else
duke@435	581	nop_offset = sethi_offset + BytesPerInstWord,
duke@435	582	#endif
duke@435	583	add_offset = nop_offset + BytesPerInstWord,
duke@435	584	instruction_size = add_offset + BytesPerInstWord
duke@435	585	};
duke@435	586
duke@435	587	address instruction_address() const { return addr_at(0); }
duke@435	588	address next_instruction_address() const { return addr_at(instruction_size); }
duke@435	589
duke@435	590	// (The [set_]data accessor respects oop_type relocs also.)
duke@435	591	int data() const;
duke@435	592	void set_data(int x);
duke@435	593
duke@435	594	// report the destination register
duke@435	595	Register destination() { return inv_rd(long_at(sethi_offset)); }
duke@435	596
duke@435	597	void verify();
duke@435	598	void print();
duke@435	599
duke@435	600	// unit test stuff
duke@435	601	static void test();
duke@435	602
duke@435	603	// Creation
duke@435	604	friend inline NativeMovConstRegPatching* nativeMovConstRegPatching_at(address address) {
duke@435	605	NativeMovConstRegPatching* test = (NativeMovConstRegPatching*)address;
duke@435	606	#ifdef ASSERT
duke@435	607	test->verify();
duke@435	608	#endif
duke@435	609	return test;
duke@435	610	}
duke@435	611
duke@435	612
duke@435	613	friend NativeMovConstRegPatching* nativeMovConstRegPatching_before(address address) {
duke@435	614	NativeMovConstRegPatching* test = (NativeMovConstRegPatching*)(address - instruction_size);
duke@435	615	#ifdef ASSERT
duke@435	616	test->verify();
duke@435	617	#endif
duke@435	618	return test;
duke@435	619	}
duke@435	620
duke@435	621	};
duke@435	622
duke@435	623
duke@435	624	// An interface for accessing/manipulating native memory ops
duke@435	625	// ld* [reg + offset], reg
duke@435	626	// st* reg, [reg + offset]
duke@435	627	// sethi %hi(imm), reg; add reg, %lo(imm), reg; ld* [reg1 + reg], reg2
duke@435	628	// sethi %hi(imm), reg; add reg, %lo(imm), reg; st* reg2, [reg1 + reg]
duke@435	629	// Ops covered: {lds,ldu,st}{w,b,h}, {ld,st}{d,x}
duke@435	630	//
duke@435	631	class NativeMovRegMem;
duke@435	632	inline NativeMovRegMem* nativeMovRegMem_at (address address);
duke@435	633	class NativeMovRegMem: public NativeInstruction {
duke@435	634	public:
duke@435	635	enum Sparc_specific_constants {
duke@435	636	op3_mask_ld = 1 << Assembler::lduw_op3 |
duke@435	637	1 << Assembler::ldub_op3 |
duke@435	638	1 << Assembler::lduh_op3 |
duke@435	639	1 << Assembler::ldd_op3 |
duke@435	640	1 << Assembler::ldsw_op3 |
duke@435	641	1 << Assembler::ldsb_op3 |
duke@435	642	1 << Assembler::ldsh_op3 |
duke@435	643	1 << Assembler::ldx_op3,
duke@435	644	op3_mask_st = 1 << Assembler::stw_op3 |
duke@435	645	1 << Assembler::stb_op3 |
duke@435	646	1 << Assembler::sth_op3 |
duke@435	647	1 << Assembler::std_op3 |
duke@435	648	1 << Assembler::stx_op3,
duke@435	649	op3_ldst_int_limit = Assembler::ldf_op3,
duke@435	650	op3_mask_ldf = 1 << (Assembler::ldf_op3 - op3_ldst_int_limit) |
duke@435	651	1 << (Assembler::lddf_op3 - op3_ldst_int_limit),
duke@435	652	op3_mask_stf = 1 << (Assembler::stf_op3 - op3_ldst_int_limit) |
duke@435	653	1 << (Assembler::stdf_op3 - op3_ldst_int_limit),
duke@435	654
duke@435	655	offset_width = 13,
duke@435	656	sethi_offset = 0,
duke@435	657	#ifdef _LP64
duke@435	658	add_offset = 7 * BytesPerInstWord,
duke@435	659	#else
duke@435	660	add_offset = 4,
duke@435	661	#endif
duke@435	662	ldst_offset = add_offset + BytesPerInstWord
duke@435	663	};
duke@435	664	bool is_immediate() const {
duke@435	665	// check if instruction is ld* [reg + offset], reg or st* reg, [reg + offset]
duke@435	666	int i0 = long_at(0);
duke@435	667	return (is_op(i0, Assembler::ldst_op));
duke@435	668	}
duke@435	669
duke@435	670	address instruction_address() const { return addr_at(0); }
duke@435	671	address next_instruction_address() const {
duke@435	672	#ifdef _LP64
duke@435	673	return addr_at(is_immediate() ? 4 : (7 * BytesPerInstWord));
duke@435	674	#else
duke@435	675	return addr_at(is_immediate() ? 4 : 12);
duke@435	676	#endif
duke@435	677	}
duke@435	678	intptr_t offset() const {
duke@435	679	return is_immediate()? inv_simm(long_at(0), offset_width) :
duke@435	680	nativeMovConstReg_at(addr_at(0))->data();
duke@435	681	}
duke@435	682	void set_offset(intptr_t x) {
duke@435	683	if (is_immediate()) {
duke@435	684	guarantee(fits_in_simm(x, offset_width), "data block offset overflow");
duke@435	685	set_long_at(0, set_simm(long_at(0), x, offset_width));
duke@435	686	} else
duke@435	687	nativeMovConstReg_at(addr_at(0))->set_data(x);
duke@435	688	}
duke@435	689
duke@435	690	void add_offset_in_bytes(intptr_t radd_offset) {
duke@435	691	set_offset (offset() + radd_offset);
duke@435	692	}
duke@435	693
duke@435	694	void copy_instruction_to(address new_instruction_address);
duke@435	695
duke@435	696	void verify();
duke@435	697	void print ();
duke@435	698
duke@435	699	// unit test stuff
duke@435	700	static void test();
duke@435	701
duke@435	702	private:
duke@435	703	friend inline NativeMovRegMem* nativeMovRegMem_at (address address) {
duke@435	704	NativeMovRegMem* test = (NativeMovRegMem*)address;
duke@435	705	#ifdef ASSERT
duke@435	706	test->verify();
duke@435	707	#endif
duke@435	708	return test;
duke@435	709	}
duke@435	710	};
duke@435	711
duke@435	712
duke@435	713	// An interface for accessing/manipulating native memory ops
duke@435	714	// ld* [reg + offset], reg
duke@435	715	// st* reg, [reg + offset]
duke@435	716	// sethi %hi(imm), reg; nop; add reg, %lo(imm), reg; ld* [reg1 + reg], reg2
duke@435	717	// sethi %hi(imm), reg; nop; add reg, %lo(imm), reg; st* reg2, [reg1 + reg]
duke@435	718	// Ops covered: {lds,ldu,st}{w,b,h}, {ld,st}{d,x}
duke@435	719	//
duke@435	720	// Note that it is identical to NativeMovRegMem with the exception of a nop between the
duke@435	721	// sethi and the add. The nop is required to be in the delay slot of the call instruction
duke@435	722	// which overwrites the sethi during patching.
duke@435	723	class NativeMovRegMemPatching;
duke@435	724	inline NativeMovRegMemPatching* nativeMovRegMemPatching_at (address address);
duke@435	725	class NativeMovRegMemPatching: public NativeInstruction {
duke@435	726	public:
duke@435	727	enum Sparc_specific_constants {
duke@435	728	op3_mask_ld = 1 << Assembler::lduw_op3 |
duke@435	729	1 << Assembler::ldub_op3 |
duke@435	730	1 << Assembler::lduh_op3 |
duke@435	731	1 << Assembler::ldd_op3 |
duke@435	732	1 << Assembler::ldsw_op3 |
duke@435	733	1 << Assembler::ldsb_op3 |
duke@435	734	1 << Assembler::ldsh_op3 |
duke@435	735	1 << Assembler::ldx_op3,
duke@435	736	op3_mask_st = 1 << Assembler::stw_op3 |
duke@435	737	1 << Assembler::stb_op3 |
duke@435	738	1 << Assembler::sth_op3 |
duke@435	739	1 << Assembler::std_op3 |
duke@435	740	1 << Assembler::stx_op3,
duke@435	741	op3_ldst_int_limit = Assembler::ldf_op3,
duke@435	742	op3_mask_ldf = 1 << (Assembler::ldf_op3 - op3_ldst_int_limit) |
duke@435	743	1 << (Assembler::lddf_op3 - op3_ldst_int_limit),
duke@435	744	op3_mask_stf = 1 << (Assembler::stf_op3 - op3_ldst_int_limit) |
duke@435	745	1 << (Assembler::stdf_op3 - op3_ldst_int_limit),
duke@435	746
duke@435	747	offset_width = 13,
duke@435	748	sethi_offset = 0,
duke@435	749	#ifdef _LP64
duke@435	750	nop_offset = 7 * BytesPerInstWord,
duke@435	751	#else
duke@435	752	nop_offset = 4,
duke@435	753	#endif
duke@435	754	add_offset = nop_offset + BytesPerInstWord,
duke@435	755	ldst_offset = add_offset + BytesPerInstWord
duke@435	756	};
duke@435	757	bool is_immediate() const {
duke@435	758	// check if instruction is ld* [reg + offset], reg or st* reg, [reg + offset]
duke@435	759	int i0 = long_at(0);
duke@435	760	return (is_op(i0, Assembler::ldst_op));
duke@435	761	}
duke@435	762
duke@435	763	address instruction_address() const { return addr_at(0); }
duke@435	764	address next_instruction_address() const {
duke@435	765	return addr_at(is_immediate()? 4 : 16);
duke@435	766	}
duke@435	767	int offset() const {
duke@435	768	return is_immediate()? inv_simm(long_at(0), offset_width) :
duke@435	769	nativeMovConstRegPatching_at(addr_at(0))->data();
duke@435	770	}
duke@435	771	void set_offset(int x) {
duke@435	772	if (is_immediate()) {
duke@435	773	guarantee(fits_in_simm(x, offset_width), "data block offset overflow");
duke@435	774	set_long_at(0, set_simm(long_at(0), x, offset_width));
duke@435	775	}
duke@435	776	else
duke@435	777	nativeMovConstRegPatching_at(addr_at(0))->set_data(x);
duke@435	778	}
duke@435	779
duke@435	780	void add_offset_in_bytes(intptr_t radd_offset) {
duke@435	781	set_offset (offset() + radd_offset);
duke@435	782	}
duke@435	783
duke@435	784	void copy_instruction_to(address new_instruction_address);
duke@435	785
duke@435	786	void verify();
duke@435	787	void print ();
duke@435	788
duke@435	789	// unit test stuff
duke@435	790	static void test();
duke@435	791
duke@435	792	private:
duke@435	793	friend inline NativeMovRegMemPatching* nativeMovRegMemPatching_at (address address) {
duke@435	794	NativeMovRegMemPatching* test = (NativeMovRegMemPatching*)address;
duke@435	795	#ifdef ASSERT
duke@435	796	test->verify();
duke@435	797	#endif
duke@435	798	return test;
duke@435	799	}
duke@435	800	};
duke@435	801
duke@435	802
duke@435	803	// An interface for accessing/manipulating native jumps
duke@435	804	// jump_to addr
duke@435	805	// == sethi %hi22(addr), temp ; jumpl reg, %lo10(addr), G0 ; <delay>
duke@435	806	// jumpl_to addr, lreg
duke@435	807	// == sethi %hi22(addr), temp ; jumpl reg, %lo10(addr), lreg ; <delay>
duke@435	808	class NativeJump;
duke@435	809	inline NativeJump* nativeJump_at(address address);
duke@435	810	class NativeJump: public NativeInstruction {
duke@435	811	private:
duke@435	812	void guarantee_displacement(int disp, int width) {
duke@435	813	guarantee(fits_in_simm(disp, width + 2), "branch displacement overflow");
duke@435	814	}
duke@435	815
duke@435	816	public:
duke@435	817	enum Sparc_specific_constants {
duke@435	818	sethi_offset = 0,
duke@435	819	#ifdef _LP64
duke@435	820	jmpl_offset = 7 * BytesPerInstWord,
duke@435	821	instruction_size = 9 * BytesPerInstWord // includes delay slot
duke@435	822	#else
duke@435	823	jmpl_offset = 1 * BytesPerInstWord,
duke@435	824	instruction_size = 3 * BytesPerInstWord // includes delay slot
duke@435	825	#endif
duke@435	826	};
duke@435	827
duke@435	828	address instruction_address() const { return addr_at(0); }
duke@435	829	address next_instruction_address() const { return addr_at(instruction_size); }
duke@435	830
duke@435	831	#ifdef _LP64
duke@435	832	address jump_destination() const {
duke@435	833	return (address) data64(instruction_address(), long_at(jmpl_offset));
duke@435	834	}
duke@435	835	void set_jump_destination(address dest) {
duke@435	836	set_data64_sethi( instruction_address(), (intptr_t)dest);
duke@435	837	set_long_at(jmpl_offset, set_data32_simm13( long_at(jmpl_offset), (intptr_t)dest));
duke@435	838	}
duke@435	839	#else
duke@435	840	address jump_destination() const {
duke@435	841	return (address) data32(long_at(sethi_offset), long_at(jmpl_offset));
duke@435	842	}
duke@435	843	void set_jump_destination(address dest) {
duke@435	844	set_long_at(sethi_offset, set_data32_sethi( long_at(sethi_offset), (intptr_t)dest));
duke@435	845	set_long_at(jmpl_offset, set_data32_simm13( long_at(jmpl_offset), (intptr_t)dest));
duke@435	846	}
duke@435	847	#endif
duke@435	848
duke@435	849	// Creation
duke@435	850	friend inline NativeJump* nativeJump_at(address address) {
duke@435	851	NativeJump* jump = (NativeJump*)address;
duke@435	852	#ifdef ASSERT
duke@435	853	jump->verify();
duke@435	854	#endif
duke@435	855	return jump;
duke@435	856	}
duke@435	857
duke@435	858	void verify();
duke@435	859	void print();
duke@435	860
duke@435	861	// Unit testing stuff
duke@435	862	static void test();
duke@435	863
duke@435	864	// Insertion of native jump instruction
duke@435	865	static void insert(address code_pos, address entry);
duke@435	866	// MT-safe insertion of native jump at verified method entry
duke@435	867	static void check_verified_entry_alignment(address entry, address verified_entry) {
duke@435	868	// nothing to do for sparc.
duke@435	869	}
duke@435	870	static void patch_verified_entry(address entry, address verified_entry, address dest);
duke@435	871	};
duke@435	872
duke@435	873
duke@435	874
duke@435	875	// Despite the name, handles only simple branches.
duke@435	876	class NativeGeneralJump;
duke@435	877	inline NativeGeneralJump* nativeGeneralJump_at(address address);
duke@435	878	class NativeGeneralJump: public NativeInstruction {
duke@435	879	public:
duke@435	880	enum Sparc_specific_constants {
duke@435	881	instruction_size = 8
duke@435	882	};
duke@435	883
duke@435	884	address instruction_address() const { return addr_at(0); }
duke@435	885	address jump_destination() const { return addr_at(0) + branch_destination_offset(long_at(0)); }
duke@435	886	void set_jump_destination(address dest) {
duke@435	887	int patched_instr = patch_branch_destination_offset(dest - addr_at(0), long_at(0));
duke@435	888	set_long_at(0, patched_instr);
duke@435	889	}
duke@435	890	NativeInstruction *delay_slot_instr() { return nativeInstruction_at(addr_at(4));}
duke@435	891	void fill_delay_slot(int instr) { set_long_at(4, instr);}
duke@435	892	Assembler::Condition condition() {
duke@435	893	int x = long_at(0);
duke@435	894	return (Assembler::Condition) Assembler::inv_cond(x);
duke@435	895	}
duke@435	896
duke@435	897	// Creation
duke@435	898	friend inline NativeGeneralJump* nativeGeneralJump_at(address address) {
duke@435	899	NativeGeneralJump* jump = (NativeGeneralJump*)(address);
duke@435	900	#ifdef ASSERT
duke@435	901	jump->verify();
duke@435	902	#endif
duke@435	903	return jump;
duke@435	904	}
duke@435	905
duke@435	906	// Insertion of native general jump instruction
duke@435	907	static void insert_unconditional(address code_pos, address entry);
duke@435	908	static void replace_mt_safe(address instr_addr, address code_buffer);
duke@435	909
duke@435	910	void verify();
duke@435	911	};
duke@435	912
duke@435	913
duke@435	914	class NativeIllegalInstruction: public NativeInstruction {
duke@435	915	public:
duke@435	916	enum Sparc_specific_constants {
duke@435	917	instruction_size = 4
duke@435	918	};
duke@435	919
duke@435	920	// Insert illegal opcode as specific address
duke@435	921	static void insert(address code_pos);
duke@435	922	};
stefank@2314	923
stefank@2314	924	#endif // CPU_SPARC_VM_NATIVEINST_SPARC_HPP