Fri, 11 Mar 2011 22:34:57 -0800
7012648: move JSR 292 to package java.lang.invoke and adjust names
Summary: package and class renaming only; delete unused methods and classes
Reviewed-by: twisti
1 /*
2 * Copyright (c) 1997, 2010, Oracle and/or its affiliates. All rights reserved.
3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
4 *
5 * This code is free software; you can redistribute it and/or modify it
6 * under the terms of the GNU General Public License version 2 only, as
7 * published by the Free Software Foundation.
8 *
9 * This code is distributed in the hope that it will be useful, but WITHOUT
10 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
11 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
12 * version 2 for more details (a copy is included in the LICENSE file that
13 * accompanied this code).
14 *
15 * You should have received a copy of the GNU General Public License version
16 * 2 along with this work; if not, write to the Free Software Foundation,
17 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
18 *
19 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
20 * or visit www.oracle.com if you need additional information or have any
21 * questions.
22 *
23 */
25 #ifndef CPU_SPARC_VM_NATIVEINST_SPARC_HPP
26 #define CPU_SPARC_VM_NATIVEINST_SPARC_HPP
28 #include "asm/assembler.hpp"
29 #include "memory/allocation.hpp"
30 #include "runtime/icache.hpp"
31 #include "runtime/os.hpp"
32 #include "utilities/top.hpp"
34 // We have interface for the following instructions:
35 // - NativeInstruction
36 // - - NativeCall
37 // - - NativeFarCall
38 // - - NativeMovConstReg
39 // - - NativeMovConstRegPatching
40 // - - NativeMovRegMem
41 // - - NativeMovRegMemPatching
42 // - - NativeJump
43 // - - NativeGeneralJump
44 // - - NativeIllegalInstruction
45 // The base class for different kinds of native instruction abstractions.
46 // Provides the primitive operations to manipulate code relative to this.
47 class NativeInstruction VALUE_OBJ_CLASS_SPEC {
48 friend class Relocation;
50 public:
51 enum Sparc_specific_constants {
52 nop_instruction_size = 4
53 };
55 bool is_dtrace_trap();
56 bool is_nop() { return long_at(0) == nop_instruction(); }
57 bool is_call() { return is_op(long_at(0), Assembler::call_op); }
58 bool is_sethi() { return (is_op2(long_at(0), Assembler::sethi_op2)
59 && inv_rd(long_at(0)) != G0); }
61 bool sets_cc() {
62 // conservative (returns true for some instructions that do not set the
63 // the condition code, such as, "save".
64 // Does not return true for the deprecated tagged instructions, such as, TADDcc
65 int x = long_at(0);
66 return (is_op(x, Assembler::arith_op) &&
67 (inv_op3(x) & Assembler::cc_bit_op3) == Assembler::cc_bit_op3);
68 }
69 bool is_illegal();
70 bool is_zombie() {
71 int x = long_at(0);
72 return is_op3(x,
73 VM_Version::v9_instructions_work() ?
74 Assembler::ldsw_op3 : Assembler::lduw_op3,
75 Assembler::ldst_op)
76 && Assembler::inv_rs1(x) == G0
77 && Assembler::inv_rd(x) == O7;
78 }
79 bool is_ic_miss_trap(); // Inline-cache uses a trap to detect a miss
80 bool is_return() {
81 // is it the output of MacroAssembler::ret or MacroAssembler::retl?
82 int x = long_at(0);
83 const int pc_return_offset = 8; // see frame_sparc.hpp
84 return is_op3(x, Assembler::jmpl_op3, Assembler::arith_op)
85 && (inv_rs1(x) == I7 || inv_rs1(x) == O7)
86 && inv_immed(x) && inv_simm(x, 13) == pc_return_offset
87 && inv_rd(x) == G0;
88 }
89 bool is_int_jump() {
90 // is it the output of MacroAssembler::b?
91 int x = long_at(0);
92 return is_op2(x, Assembler::bp_op2) || is_op2(x, Assembler::br_op2);
93 }
94 bool is_float_jump() {
95 // is it the output of MacroAssembler::fb?
96 int x = long_at(0);
97 return is_op2(x, Assembler::fbp_op2) || is_op2(x, Assembler::fb_op2);
98 }
99 bool is_jump() {
100 return is_int_jump() || is_float_jump();
101 }
102 bool is_cond_jump() {
103 int x = long_at(0);
104 return (is_int_jump() && Assembler::inv_cond(x) != Assembler::always) ||
105 (is_float_jump() && Assembler::inv_cond(x) != Assembler::f_always);
106 }
108 bool is_stack_bang() {
109 int x = long_at(0);
110 return is_op3(x, Assembler::stw_op3, Assembler::ldst_op) &&
111 (inv_rd(x) == G0) && (inv_rs1(x) == SP) && (inv_rs2(x) == G3_scratch);
112 }
114 bool is_prefetch() {
115 int x = long_at(0);
116 return is_op3(x, Assembler::prefetch_op3, Assembler::ldst_op);
117 }
119 bool is_membar() {
120 int x = long_at(0);
121 return is_op3(x, Assembler::membar_op3, Assembler::arith_op) &&
122 (inv_rd(x) == G0) && (inv_rs1(x) == O7);
123 }
125 bool is_safepoint_poll() {
126 int x = long_at(0);
127 #ifdef _LP64
128 return is_op3(x, Assembler::ldx_op3, Assembler::ldst_op) &&
129 #else
130 return is_op3(x, Assembler::lduw_op3, Assembler::ldst_op) &&
131 #endif
132 (inv_rd(x) == G0) && (inv_immed(x) ? Assembler::inv_simm13(x) == 0 : inv_rs2(x) == G0);
133 }
135 bool is_zero_test(Register ®);
136 bool is_load_store_with_small_offset(Register reg);
138 public:
139 #ifdef ASSERT
140 static int rdpc_instruction() { return Assembler::op(Assembler::arith_op ) | Assembler::op3(Assembler::rdreg_op3) | Assembler::u_field(5, 18, 14) | Assembler::rd(O7); }
141 #else
142 // Temporary fix: in optimized mode, u_field is a macro for efficiency reasons (see Assembler::u_field) - needs to be fixed
143 static int rdpc_instruction() { return Assembler::op(Assembler::arith_op ) | Assembler::op3(Assembler::rdreg_op3) | u_field(5, 18, 14) | Assembler::rd(O7); }
144 #endif
145 static int nop_instruction() { return Assembler::op(Assembler::branch_op) | Assembler::op2(Assembler::sethi_op2); }
146 static int illegal_instruction(); // the output of __ breakpoint_trap()
147 static int call_instruction(address destination, address pc) { return Assembler::op(Assembler::call_op) | Assembler::wdisp((intptr_t)destination, (intptr_t)pc, 30); }
149 static int branch_instruction(Assembler::op2s op2val, Assembler::Condition c, bool a) {
150 return Assembler::op(Assembler::branch_op) | Assembler::op2(op2val) | Assembler::annul(a) | Assembler::cond(c);
151 }
153 static int op3_instruction(Assembler::ops opval, Register rd, Assembler::op3s op3val, Register rs1, int simm13a) {
154 return Assembler::op(opval) | Assembler::rd(rd) | Assembler::op3(op3val) | Assembler::rs1(rs1) | Assembler::immed(true) | Assembler::simm(simm13a, 13);
155 }
157 static int sethi_instruction(Register rd, int imm22a) {
158 return Assembler::op(Assembler::branch_op) | Assembler::rd(rd) | Assembler::op2(Assembler::sethi_op2) | Assembler::hi22(imm22a);
159 }
161 protected:
162 address addr_at(int offset) const { return address(this) + offset; }
163 int long_at(int offset) const { return *(int*)addr_at(offset); }
164 void set_long_at(int offset, int i); /* deals with I-cache */
165 void set_jlong_at(int offset, jlong i); /* deals with I-cache */
166 void set_addr_at(int offset, address x); /* deals with I-cache */
168 address instruction_address() const { return addr_at(0); }
169 address next_instruction_address() const { return addr_at(BytesPerInstWord); }
171 static bool is_op( int x, Assembler::ops opval) {
172 return Assembler::inv_op(x) == opval;
173 }
174 static bool is_op2(int x, Assembler::op2s op2val) {
175 return Assembler::inv_op(x) == Assembler::branch_op && Assembler::inv_op2(x) == op2val;
176 }
177 static bool is_op3(int x, Assembler::op3s op3val, Assembler::ops opval) {
178 return Assembler::inv_op(x) == opval && Assembler::inv_op3(x) == op3val;
179 }
181 // utilities to help subclasses decode:
182 static Register inv_rd( int x ) { return Assembler::inv_rd( x); }
183 static Register inv_rs1( int x ) { return Assembler::inv_rs1(x); }
184 static Register inv_rs2( int x ) { return Assembler::inv_rs2(x); }
186 static bool inv_immed( int x ) { return Assembler::inv_immed(x); }
187 static bool inv_annul( int x ) { return (Assembler::annul(true) & x) != 0; }
188 static int inv_cond( int x ) { return Assembler::inv_cond(x); }
190 static int inv_op( int x ) { return Assembler::inv_op( x); }
191 static int inv_op2( int x ) { return Assembler::inv_op2(x); }
192 static int inv_op3( int x ) { return Assembler::inv_op3(x); }
194 static int inv_simm( int x, int nbits ) { return Assembler::inv_simm(x, nbits); }
195 static intptr_t inv_wdisp( int x, int nbits ) { return Assembler::inv_wdisp( x, 0, nbits); }
196 static intptr_t inv_wdisp16( int x ) { return Assembler::inv_wdisp16(x, 0); }
197 static int branch_destination_offset(int x) { return Assembler::branch_destination(x, 0); }
198 static int patch_branch_destination_offset(int dest_offset, int x) {
199 return Assembler::patched_branch(dest_offset, x, 0);
200 }
201 void set_annul_bit() { set_long_at(0, long_at(0) | Assembler::annul(true)); }
203 // utility for checking if x is either of 2 small constants
204 static bool is_either(int x, int k1, int k2) {
205 // return x == k1 || x == k2;
206 return (1 << x) & (1 << k1 | 1 << k2);
207 }
209 // utility for checking overflow of signed instruction fields
210 static bool fits_in_simm(int x, int nbits) {
211 // cf. Assembler::assert_signed_range()
212 // return -(1 << nbits-1) <= x && x < ( 1 << nbits-1),
213 return (unsigned)(x + (1 << nbits-1)) < (unsigned)(1 << nbits);
214 }
216 // set a signed immediate field
217 static int set_simm(int insn, int imm, int nbits) {
218 return (insn &~ Assembler::simm(-1, nbits)) | Assembler::simm(imm, nbits);
219 }
221 // set a wdisp field (disp should be the difference of two addresses)
222 static int set_wdisp(int insn, intptr_t disp, int nbits) {
223 return (insn &~ Assembler::wdisp((intptr_t)-4, (intptr_t)0, nbits)) | Assembler::wdisp(disp, 0, nbits);
224 }
226 static int set_wdisp16(int insn, intptr_t disp) {
227 return (insn &~ Assembler::wdisp16((intptr_t)-4, 0)) | Assembler::wdisp16(disp, 0);
228 }
230 // get a simm13 field from an arithmetic or memory instruction
231 static int get_simm13(int insn) {
232 assert(is_either(Assembler::inv_op(insn),
233 Assembler::arith_op, Assembler::ldst_op) &&
234 (insn & Assembler::immed(true)), "must have a simm13 field");
235 return Assembler::inv_simm(insn, 13);
236 }
238 // set the simm13 field of an arithmetic or memory instruction
239 static bool set_simm13(int insn, int imm) {
240 get_simm13(insn); // tickle the assertion check
241 return set_simm(insn, imm, 13);
242 }
244 // combine the fields of a sethi stream (7 instructions ) and an add, jmp or ld/st
245 static intptr_t data64( address pc, int arith_insn ) {
246 assert(is_op2(*(unsigned int *)pc, Assembler::sethi_op2), "must be sethi");
247 intptr_t hi = (intptr_t)gethi( (unsigned int *)pc );
248 intptr_t lo = (intptr_t)get_simm13(arith_insn);
249 assert((unsigned)lo < (1 << 10), "offset field of set_oop must be 10 bits");
250 return hi | lo;
251 }
253 // Regenerate the instruction sequence that performs the 64 bit
254 // sethi. This only does the sethi. The disp field (bottom 10 bits)
255 // must be handled separately.
256 static void set_data64_sethi(address instaddr, intptr_t x);
258 // combine the fields of a sethi/simm13 pair (simm13 = or, add, jmpl, ld/st)
259 static int data32(int sethi_insn, int arith_insn) {
260 assert(is_op2(sethi_insn, Assembler::sethi_op2), "must be sethi");
261 int hi = Assembler::inv_hi22(sethi_insn);
262 int lo = get_simm13(arith_insn);
263 assert((unsigned)lo < (1 << 10), "offset field of set_oop must be 10 bits");
264 return hi | lo;
265 }
267 static int set_data32_sethi(int sethi_insn, int imm) {
268 // note that Assembler::hi22 clips the low 10 bits for us
269 assert(is_op2(sethi_insn, Assembler::sethi_op2), "must be sethi");
270 return (sethi_insn &~ Assembler::hi22(-1)) | Assembler::hi22(imm);
271 }
273 static int set_data32_simm13(int arith_insn, int imm) {
274 get_simm13(arith_insn); // tickle the assertion check
275 int imm10 = Assembler::low10(imm);
276 return (arith_insn &~ Assembler::simm(-1, 13)) | Assembler::simm(imm10, 13);
277 }
279 static int low10(int imm) {
280 return Assembler::low10(imm);
281 }
283 // Perform the inverse of the LP64 Macroassembler::sethi
284 // routine. Extracts the 54 bits of address from the instruction
285 // stream. This routine must agree with the sethi routine in
286 // assembler_inline_sparc.hpp
287 static address gethi( unsigned int *pc ) {
288 int i = 0;
289 uintptr_t adr;
290 // We first start out with the real sethi instruction
291 assert(is_op2(*pc, Assembler::sethi_op2), "in gethi - must be sethi");
292 adr = (unsigned int)Assembler::inv_hi22( *(pc++) );
293 i++;
294 while ( i < 7 ) {
295 // We're done if we hit a nop
296 if ( (int)*pc == nop_instruction() ) break;
297 assert ( Assembler::inv_op(*pc) == Assembler::arith_op, "in gethi - must be arith_op" );
298 switch ( Assembler::inv_op3(*pc) ) {
299 case Assembler::xor_op3:
300 adr ^= (intptr_t)get_simm13( *pc );
301 return ( (address)adr );
302 break;
303 case Assembler::sll_op3:
304 adr <<= ( *pc & 0x3f );
305 break;
306 case Assembler::or_op3:
307 adr |= (intptr_t)get_simm13( *pc );
308 break;
309 default:
310 assert ( 0, "in gethi - Should not reach here" );
311 break;
312 }
313 pc++;
314 i++;
315 }
316 return ( (address)adr );
317 }
319 public:
320 void verify();
321 void print();
323 // unit test stuff
324 static void test() {} // override for testing
326 inline friend NativeInstruction* nativeInstruction_at(address address);
327 };
329 inline NativeInstruction* nativeInstruction_at(address address) {
330 NativeInstruction* inst = (NativeInstruction*)address;
331 #ifdef ASSERT
332 inst->verify();
333 #endif
334 return inst;
335 }
339 //-----------------------------------------------------------------------------
341 // The NativeCall is an abstraction for accessing/manipulating native call imm32 instructions.
342 // (used to manipulate inline caches, primitive & dll calls, etc.)
343 inline NativeCall* nativeCall_at(address instr);
344 inline NativeCall* nativeCall_overwriting_at(address instr,
345 address destination);
346 inline NativeCall* nativeCall_before(address return_address);
347 class NativeCall: public NativeInstruction {
348 public:
349 enum Sparc_specific_constants {
350 instruction_size = 8,
351 return_address_offset = 8,
352 call_displacement_width = 30,
353 displacement_offset = 0,
354 instruction_offset = 0
355 };
356 address instruction_address() const { return addr_at(0); }
357 address next_instruction_address() const { return addr_at(instruction_size); }
358 address return_address() const { return addr_at(return_address_offset); }
360 address destination() const { return inv_wdisp(long_at(0), call_displacement_width) + instruction_address(); }
361 address displacement_address() const { return addr_at(displacement_offset); }
362 void set_destination(address dest) { set_long_at(0, set_wdisp(long_at(0), dest - instruction_address(), call_displacement_width)); }
363 void set_destination_mt_safe(address dest);
365 void verify_alignment() {} // do nothing on sparc
366 void verify();
367 void print();
369 // unit test stuff
370 static void test();
372 // Creation
373 friend inline NativeCall* nativeCall_at(address instr);
374 friend NativeCall* nativeCall_overwriting_at(address instr, address destination = NULL) {
375 // insert a "blank" call:
376 NativeCall* call = (NativeCall*)instr;
377 call->set_long_at(0 * BytesPerInstWord, call_instruction(destination, instr));
378 call->set_long_at(1 * BytesPerInstWord, nop_instruction());
379 assert(call->addr_at(2 * BytesPerInstWord) - instr == instruction_size, "instruction size");
380 // check its structure now:
381 assert(nativeCall_at(instr)->destination() == destination, "correct call destination");
382 return call;
383 }
385 friend inline NativeCall* nativeCall_before(address return_address) {
386 NativeCall* call = (NativeCall*)(return_address - return_address_offset);
387 #ifdef ASSERT
388 call->verify();
389 #endif
390 return call;
391 }
393 static bool is_call_at(address instr) {
394 return nativeInstruction_at(instr)->is_call();
395 }
397 static bool is_call_before(address instr) {
398 return nativeInstruction_at(instr - return_address_offset)->is_call();
399 }
401 static bool is_call_to(address instr, address target) {
402 return nativeInstruction_at(instr)->is_call() &&
403 nativeCall_at(instr)->destination() == target;
404 }
406 // MT-safe patching of a call instruction.
407 static void insert(address code_pos, address entry) {
408 (void)nativeCall_overwriting_at(code_pos, entry);
409 }
411 static void replace_mt_safe(address instr_addr, address code_buffer);
412 };
413 inline NativeCall* nativeCall_at(address instr) {
414 NativeCall* call = (NativeCall*)instr;
415 #ifdef ASSERT
416 call->verify();
417 #endif
418 return call;
419 }
421 // The NativeFarCall is an abstraction for accessing/manipulating native call-anywhere
422 // instructions in the sparcv9 vm. Used to call native methods which may be loaded
423 // anywhere in the address space, possibly out of reach of a call instruction.
425 #ifndef _LP64
427 // On 32-bit systems, a far call is the same as a near one.
428 class NativeFarCall;
429 inline NativeFarCall* nativeFarCall_at(address instr);
430 class NativeFarCall : public NativeCall {
431 public:
432 friend inline NativeFarCall* nativeFarCall_at(address instr) { return (NativeFarCall*)nativeCall_at(instr); }
433 friend NativeFarCall* nativeFarCall_overwriting_at(address instr, address destination = NULL)
434 { return (NativeFarCall*)nativeCall_overwriting_at(instr, destination); }
435 friend NativeFarCall* nativeFarCall_before(address return_address)
436 { return (NativeFarCall*)nativeCall_before(return_address); }
437 };
439 #else
441 // The format of this extended-range call is:
442 // jumpl_to addr, lreg
443 // == sethi %hi54(addr), O7 ; jumpl O7, %lo10(addr), O7 ; <delay>
444 // That is, it is essentially the same as a NativeJump.
445 class NativeFarCall;
446 inline NativeFarCall* nativeFarCall_overwriting_at(address instr, address destination);
447 inline NativeFarCall* nativeFarCall_at(address instr);
448 class NativeFarCall: public NativeInstruction {
449 public:
450 enum Sparc_specific_constants {
451 // instruction_size includes the delay slot instruction.
452 instruction_size = 9 * BytesPerInstWord,
453 return_address_offset = 9 * BytesPerInstWord,
454 jmpl_offset = 7 * BytesPerInstWord,
455 displacement_offset = 0,
456 instruction_offset = 0
457 };
458 address instruction_address() const { return addr_at(0); }
459 address next_instruction_address() const { return addr_at(instruction_size); }
460 address return_address() const { return addr_at(return_address_offset); }
462 address destination() const {
463 return (address) data64(addr_at(0), long_at(jmpl_offset));
464 }
465 address displacement_address() const { return addr_at(displacement_offset); }
466 void set_destination(address dest);
468 bool destination_is_compiled_verified_entry_point();
470 void verify();
471 void print();
473 // unit test stuff
474 static void test();
476 // Creation
477 friend inline NativeFarCall* nativeFarCall_at(address instr) {
478 NativeFarCall* call = (NativeFarCall*)instr;
479 #ifdef ASSERT
480 call->verify();
481 #endif
482 return call;
483 }
485 friend inline NativeFarCall* nativeFarCall_overwriting_at(address instr, address destination = NULL) {
486 Unimplemented();
487 NativeFarCall* call = (NativeFarCall*)instr;
488 return call;
489 }
491 friend NativeFarCall* nativeFarCall_before(address return_address) {
492 NativeFarCall* call = (NativeFarCall*)(return_address - return_address_offset);
493 #ifdef ASSERT
494 call->verify();
495 #endif
496 return call;
497 }
499 static bool is_call_at(address instr);
501 // MT-safe patching of a call instruction.
502 static void insert(address code_pos, address entry) {
503 (void)nativeFarCall_overwriting_at(code_pos, entry);
504 }
505 static void replace_mt_safe(address instr_addr, address code_buffer);
506 };
508 #endif // _LP64
510 // An interface for accessing/manipulating native set_oop imm, reg instructions.
511 // (used to manipulate inlined data references, etc.)
512 // set_oop imm, reg
513 // == sethi %hi22(imm), reg ; add reg, %lo10(imm), reg
514 class NativeMovConstReg;
515 inline NativeMovConstReg* nativeMovConstReg_at(address address);
516 class NativeMovConstReg: public NativeInstruction {
517 public:
518 enum Sparc_specific_constants {
519 sethi_offset = 0,
520 #ifdef _LP64
521 add_offset = 7 * BytesPerInstWord,
522 instruction_size = 8 * BytesPerInstWord
523 #else
524 add_offset = 4,
525 instruction_size = 8
526 #endif
527 };
529 address instruction_address() const { return addr_at(0); }
530 address next_instruction_address() const { return addr_at(instruction_size); }
532 // (The [set_]data accessor respects oop_type relocs also.)
533 intptr_t data() const;
534 void set_data(intptr_t x);
536 // report the destination register
537 Register destination() { return inv_rd(long_at(sethi_offset)); }
539 void verify();
540 void print();
542 // unit test stuff
543 static void test();
545 // Creation
546 friend inline NativeMovConstReg* nativeMovConstReg_at(address address) {
547 NativeMovConstReg* test = (NativeMovConstReg*)address;
548 #ifdef ASSERT
549 test->verify();
550 #endif
551 return test;
552 }
555 friend NativeMovConstReg* nativeMovConstReg_before(address address) {
556 NativeMovConstReg* test = (NativeMovConstReg*)(address - instruction_size);
557 #ifdef ASSERT
558 test->verify();
559 #endif
560 return test;
561 }
563 };
566 // An interface for accessing/manipulating native set_oop imm, reg instructions.
567 // (used to manipulate inlined data references, etc.)
568 // set_oop imm, reg
569 // == sethi %hi22(imm), reg; nop; add reg, %lo10(imm), reg
570 //
571 // Note that it is identical to NativeMovConstReg with the exception of a nop between the
572 // sethi and the add. The nop is required to be in the delay slot of the call instruction
573 // which overwrites the sethi during patching.
574 class NativeMovConstRegPatching;
575 inline NativeMovConstRegPatching* nativeMovConstRegPatching_at(address address);class NativeMovConstRegPatching: public NativeInstruction {
576 public:
577 enum Sparc_specific_constants {
578 sethi_offset = 0,
579 #ifdef _LP64
580 nop_offset = 7 * BytesPerInstWord,
581 #else
582 nop_offset = sethi_offset + BytesPerInstWord,
583 #endif
584 add_offset = nop_offset + BytesPerInstWord,
585 instruction_size = add_offset + BytesPerInstWord
586 };
588 address instruction_address() const { return addr_at(0); }
589 address next_instruction_address() const { return addr_at(instruction_size); }
591 // (The [set_]data accessor respects oop_type relocs also.)
592 int data() const;
593 void set_data(int x);
595 // report the destination register
596 Register destination() { return inv_rd(long_at(sethi_offset)); }
598 void verify();
599 void print();
601 // unit test stuff
602 static void test();
604 // Creation
605 friend inline NativeMovConstRegPatching* nativeMovConstRegPatching_at(address address) {
606 NativeMovConstRegPatching* test = (NativeMovConstRegPatching*)address;
607 #ifdef ASSERT
608 test->verify();
609 #endif
610 return test;
611 }
614 friend NativeMovConstRegPatching* nativeMovConstRegPatching_before(address address) {
615 NativeMovConstRegPatching* test = (NativeMovConstRegPatching*)(address - instruction_size);
616 #ifdef ASSERT
617 test->verify();
618 #endif
619 return test;
620 }
622 };
625 // An interface for accessing/manipulating native memory ops
626 // ld* [reg + offset], reg
627 // st* reg, [reg + offset]
628 // sethi %hi(imm), reg; add reg, %lo(imm), reg; ld* [reg1 + reg], reg2
629 // sethi %hi(imm), reg; add reg, %lo(imm), reg; st* reg2, [reg1 + reg]
630 // Ops covered: {lds,ldu,st}{w,b,h}, {ld,st}{d,x}
631 //
632 class NativeMovRegMem;
633 inline NativeMovRegMem* nativeMovRegMem_at (address address);
634 class NativeMovRegMem: public NativeInstruction {
635 public:
636 enum Sparc_specific_constants {
637 op3_mask_ld = 1 << Assembler::lduw_op3 |
638 1 << Assembler::ldub_op3 |
639 1 << Assembler::lduh_op3 |
640 1 << Assembler::ldd_op3 |
641 1 << Assembler::ldsw_op3 |
642 1 << Assembler::ldsb_op3 |
643 1 << Assembler::ldsh_op3 |
644 1 << Assembler::ldx_op3,
645 op3_mask_st = 1 << Assembler::stw_op3 |
646 1 << Assembler::stb_op3 |
647 1 << Assembler::sth_op3 |
648 1 << Assembler::std_op3 |
649 1 << Assembler::stx_op3,
650 op3_ldst_int_limit = Assembler::ldf_op3,
651 op3_mask_ldf = 1 << (Assembler::ldf_op3 - op3_ldst_int_limit) |
652 1 << (Assembler::lddf_op3 - op3_ldst_int_limit),
653 op3_mask_stf = 1 << (Assembler::stf_op3 - op3_ldst_int_limit) |
654 1 << (Assembler::stdf_op3 - op3_ldst_int_limit),
656 offset_width = 13,
657 sethi_offset = 0,
658 #ifdef _LP64
659 add_offset = 7 * BytesPerInstWord,
660 #else
661 add_offset = 4,
662 #endif
663 ldst_offset = add_offset + BytesPerInstWord
664 };
665 bool is_immediate() const {
666 // check if instruction is ld* [reg + offset], reg or st* reg, [reg + offset]
667 int i0 = long_at(0);
668 return (is_op(i0, Assembler::ldst_op));
669 }
671 address instruction_address() const { return addr_at(0); }
672 address next_instruction_address() const {
673 #ifdef _LP64
674 return addr_at(is_immediate() ? 4 : (7 * BytesPerInstWord));
675 #else
676 return addr_at(is_immediate() ? 4 : 12);
677 #endif
678 }
679 intptr_t offset() const {
680 return is_immediate()? inv_simm(long_at(0), offset_width) :
681 nativeMovConstReg_at(addr_at(0))->data();
682 }
683 void set_offset(intptr_t x) {
684 if (is_immediate()) {
685 guarantee(fits_in_simm(x, offset_width), "data block offset overflow");
686 set_long_at(0, set_simm(long_at(0), x, offset_width));
687 } else
688 nativeMovConstReg_at(addr_at(0))->set_data(x);
689 }
691 void add_offset_in_bytes(intptr_t radd_offset) {
692 set_offset (offset() + radd_offset);
693 }
695 void copy_instruction_to(address new_instruction_address);
697 void verify();
698 void print ();
700 // unit test stuff
701 static void test();
703 private:
704 friend inline NativeMovRegMem* nativeMovRegMem_at (address address) {
705 NativeMovRegMem* test = (NativeMovRegMem*)address;
706 #ifdef ASSERT
707 test->verify();
708 #endif
709 return test;
710 }
711 };
714 // An interface for accessing/manipulating native memory ops
715 // ld* [reg + offset], reg
716 // st* reg, [reg + offset]
717 // sethi %hi(imm), reg; nop; add reg, %lo(imm), reg; ld* [reg1 + reg], reg2
718 // sethi %hi(imm), reg; nop; add reg, %lo(imm), reg; st* reg2, [reg1 + reg]
719 // Ops covered: {lds,ldu,st}{w,b,h}, {ld,st}{d,x}
720 //
721 // Note that it is identical to NativeMovRegMem with the exception of a nop between the
722 // sethi and the add. The nop is required to be in the delay slot of the call instruction
723 // which overwrites the sethi during patching.
724 class NativeMovRegMemPatching;
725 inline NativeMovRegMemPatching* nativeMovRegMemPatching_at (address address);
726 class NativeMovRegMemPatching: public NativeInstruction {
727 public:
728 enum Sparc_specific_constants {
729 op3_mask_ld = 1 << Assembler::lduw_op3 |
730 1 << Assembler::ldub_op3 |
731 1 << Assembler::lduh_op3 |
732 1 << Assembler::ldd_op3 |
733 1 << Assembler::ldsw_op3 |
734 1 << Assembler::ldsb_op3 |
735 1 << Assembler::ldsh_op3 |
736 1 << Assembler::ldx_op3,
737 op3_mask_st = 1 << Assembler::stw_op3 |
738 1 << Assembler::stb_op3 |
739 1 << Assembler::sth_op3 |
740 1 << Assembler::std_op3 |
741 1 << Assembler::stx_op3,
742 op3_ldst_int_limit = Assembler::ldf_op3,
743 op3_mask_ldf = 1 << (Assembler::ldf_op3 - op3_ldst_int_limit) |
744 1 << (Assembler::lddf_op3 - op3_ldst_int_limit),
745 op3_mask_stf = 1 << (Assembler::stf_op3 - op3_ldst_int_limit) |
746 1 << (Assembler::stdf_op3 - op3_ldst_int_limit),
748 offset_width = 13,
749 sethi_offset = 0,
750 #ifdef _LP64
751 nop_offset = 7 * BytesPerInstWord,
752 #else
753 nop_offset = 4,
754 #endif
755 add_offset = nop_offset + BytesPerInstWord,
756 ldst_offset = add_offset + BytesPerInstWord
757 };
758 bool is_immediate() const {
759 // check if instruction is ld* [reg + offset], reg or st* reg, [reg + offset]
760 int i0 = long_at(0);
761 return (is_op(i0, Assembler::ldst_op));
762 }
764 address instruction_address() const { return addr_at(0); }
765 address next_instruction_address() const {
766 return addr_at(is_immediate()? 4 : 16);
767 }
768 int offset() const {
769 return is_immediate()? inv_simm(long_at(0), offset_width) :
770 nativeMovConstRegPatching_at(addr_at(0))->data();
771 }
772 void set_offset(int x) {
773 if (is_immediate()) {
774 guarantee(fits_in_simm(x, offset_width), "data block offset overflow");
775 set_long_at(0, set_simm(long_at(0), x, offset_width));
776 }
777 else
778 nativeMovConstRegPatching_at(addr_at(0))->set_data(x);
779 }
781 void add_offset_in_bytes(intptr_t radd_offset) {
782 set_offset (offset() + radd_offset);
783 }
785 void copy_instruction_to(address new_instruction_address);
787 void verify();
788 void print ();
790 // unit test stuff
791 static void test();
793 private:
794 friend inline NativeMovRegMemPatching* nativeMovRegMemPatching_at (address address) {
795 NativeMovRegMemPatching* test = (NativeMovRegMemPatching*)address;
796 #ifdef ASSERT
797 test->verify();
798 #endif
799 return test;
800 }
801 };
804 // An interface for accessing/manipulating native jumps
805 // jump_to addr
806 // == sethi %hi22(addr), temp ; jumpl reg, %lo10(addr), G0 ; <delay>
807 // jumpl_to addr, lreg
808 // == sethi %hi22(addr), temp ; jumpl reg, %lo10(addr), lreg ; <delay>
809 class NativeJump;
810 inline NativeJump* nativeJump_at(address address);
811 class NativeJump: public NativeInstruction {
812 private:
813 void guarantee_displacement(int disp, int width) {
814 guarantee(fits_in_simm(disp, width + 2), "branch displacement overflow");
815 }
817 public:
818 enum Sparc_specific_constants {
819 sethi_offset = 0,
820 #ifdef _LP64
821 jmpl_offset = 7 * BytesPerInstWord,
822 instruction_size = 9 * BytesPerInstWord // includes delay slot
823 #else
824 jmpl_offset = 1 * BytesPerInstWord,
825 instruction_size = 3 * BytesPerInstWord // includes delay slot
826 #endif
827 };
829 address instruction_address() const { return addr_at(0); }
830 address next_instruction_address() const { return addr_at(instruction_size); }
832 #ifdef _LP64
833 address jump_destination() const {
834 return (address) data64(instruction_address(), long_at(jmpl_offset));
835 }
836 void set_jump_destination(address dest) {
837 set_data64_sethi( instruction_address(), (intptr_t)dest);
838 set_long_at(jmpl_offset, set_data32_simm13( long_at(jmpl_offset), (intptr_t)dest));
839 }
840 #else
841 address jump_destination() const {
842 return (address) data32(long_at(sethi_offset), long_at(jmpl_offset));
843 }
844 void set_jump_destination(address dest) {
845 set_long_at(sethi_offset, set_data32_sethi( long_at(sethi_offset), (intptr_t)dest));
846 set_long_at(jmpl_offset, set_data32_simm13( long_at(jmpl_offset), (intptr_t)dest));
847 }
848 #endif
850 // Creation
851 friend inline NativeJump* nativeJump_at(address address) {
852 NativeJump* jump = (NativeJump*)address;
853 #ifdef ASSERT
854 jump->verify();
855 #endif
856 return jump;
857 }
859 void verify();
860 void print();
862 // Unit testing stuff
863 static void test();
865 // Insertion of native jump instruction
866 static void insert(address code_pos, address entry);
867 // MT-safe insertion of native jump at verified method entry
868 static void check_verified_entry_alignment(address entry, address verified_entry) {
869 // nothing to do for sparc.
870 }
871 static void patch_verified_entry(address entry, address verified_entry, address dest);
872 };
876 // Despite the name, handles only simple branches.
877 class NativeGeneralJump;
878 inline NativeGeneralJump* nativeGeneralJump_at(address address);
879 class NativeGeneralJump: public NativeInstruction {
880 public:
881 enum Sparc_specific_constants {
882 instruction_size = 8
883 };
885 address instruction_address() const { return addr_at(0); }
886 address jump_destination() const { return addr_at(0) + branch_destination_offset(long_at(0)); }
887 void set_jump_destination(address dest) {
888 int patched_instr = patch_branch_destination_offset(dest - addr_at(0), long_at(0));
889 set_long_at(0, patched_instr);
890 }
891 void set_annul() { set_annul_bit(); }
892 NativeInstruction *delay_slot_instr() { return nativeInstruction_at(addr_at(4));}
893 void fill_delay_slot(int instr) { set_long_at(4, instr);}
894 Assembler::Condition condition() {
895 int x = long_at(0);
896 return (Assembler::Condition) Assembler::inv_cond(x);
897 }
899 // Creation
900 friend inline NativeGeneralJump* nativeGeneralJump_at(address address) {
901 NativeGeneralJump* jump = (NativeGeneralJump*)(address);
902 #ifdef ASSERT
903 jump->verify();
904 #endif
905 return jump;
906 }
908 // Insertion of native general jump instruction
909 static void insert_unconditional(address code_pos, address entry);
910 static void replace_mt_safe(address instr_addr, address code_buffer);
912 void verify();
913 };
916 class NativeIllegalInstruction: public NativeInstruction {
917 public:
918 enum Sparc_specific_constants {
919 instruction_size = 4
920 };
922 // Insert illegal opcode as specific address
923 static void insert(address code_pos);
924 };
926 #endif // CPU_SPARC_VM_NATIVEINST_SPARC_HPP