/*
* Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*
*/
#include "precompiled.hpp"
#include "asm/assembler.inline.hpp"
#include "compiler/disassembler.hpp"
#include "gc_interface/collectedHeap.inline.hpp"
#include "interpreter/interpreter.hpp"
#include "memory/cardTableModRefBS.hpp"
#include "memory/resourceArea.hpp"
#include "memory/universe.hpp"
#include "prims/methodHandles.hpp"
#include "runtime/biasedLocking.hpp"
#include "runtime/interfaceSupport.hpp"
#include "runtime/objectMonitor.hpp"
#include "runtime/os.hpp"
#include "runtime/sharedRuntime.hpp"
#include "runtime/stubRoutines.hpp"
#include "utilities/macros.hpp"
#if INCLUDE_ALL_GCS
#include "gc_implementation/g1/g1CollectedHeap.inline.hpp"
#include "gc_implementation/g1/g1SATBCardTableModRefBS.hpp"
#include "gc_implementation/g1/heapRegion.hpp"
#endif // INCLUDE_ALL_GCS
#ifdef PRODUCT
#define BLOCK_COMMENT(str) /* nothing */
#define STOP(error) stop(error)
#else
#define BLOCK_COMMENT(str) block_comment(str)
#define STOP(error) block_comment(error); stop(error)
#endif
// Convert the raw encoding form into the form expected by the
// constructor for Address.
Address Address::make_raw(int base, int index, int scale, int disp, relocInfo::relocType disp_reloc) {
assert(scale == 0, "not supported");
RelocationHolder rspec;
if (disp_reloc != relocInfo::none) {
rspec = Relocation::spec_simple(disp_reloc);
}
Register rindex = as_Register(index);
if (rindex != G0) {
Address madr(as_Register(base), rindex);
madr._rspec = rspec;
return madr;
} else {
Address madr(as_Register(base), disp);
madr._rspec = rspec;
return madr;
}
}
Address Argument::address_in_frame() const {
// Warning: In LP64 mode disp will occupy more than 10 bits, but
// op codes such as ld or ldx, only access disp() to get
// their simm13 argument.
int disp = ((_number - Argument::n_register_parameters + frame::memory_parameter_word_sp_offset) * BytesPerWord) + STACK_BIAS;
if (is_in())
return Address(FP, disp); // In argument.
else
return Address(SP, disp); // Out argument.
}
static const char* argumentNames[][2] = {
{"A0","P0"}, {"A1","P1"}, {"A2","P2"}, {"A3","P3"}, {"A4","P4"},
{"A5","P5"}, {"A6","P6"}, {"A7","P7"}, {"A8","P8"}, {"A9","P9"},
{"A(n>9)","P(n>9)"}
};
const char* Argument::name() const {
int nofArgs = sizeof argumentNames / sizeof argumentNames[0];
int num = number();
if (num >= nofArgs) num = nofArgs - 1;
return argumentNames[num][is_in() ? 1 : 0];
}
#ifdef ASSERT
// On RISC, there's no benefit to verifying instruction boundaries.
bool AbstractAssembler::pd_check_instruction_mark() { return false; }
#endif
// Patch instruction inst at offset inst_pos to refer to dest_pos
// and return the resulting instruction.
// We should have pcs, not offsets, but since all is relative, it will work out
// OK.
int MacroAssembler::patched_branch(int dest_pos, int inst, int inst_pos) {
int m; // mask for displacement field
int v; // new value for displacement field
const int word_aligned_ones = -4;
switch (inv_op(inst)) {
default: ShouldNotReachHere();
case call_op: m = wdisp(word_aligned_ones, 0, 30); v = wdisp(dest_pos, inst_pos, 30); break;
case branch_op:
switch (inv_op2(inst)) {
case fbp_op2: m = wdisp( word_aligned_ones, 0, 19); v = wdisp( dest_pos, inst_pos, 19); break;
case bp_op2: m = wdisp( word_aligned_ones, 0, 19); v = wdisp( dest_pos, inst_pos, 19); break;
case fb_op2: m = wdisp( word_aligned_ones, 0, 22); v = wdisp( dest_pos, inst_pos, 22); break;
case br_op2: m = wdisp( word_aligned_ones, 0, 22); v = wdisp( dest_pos, inst_pos, 22); break;
case bpr_op2: {
if (is_cbcond(inst)) {
m = wdisp10(word_aligned_ones, 0);
v = wdisp10(dest_pos, inst_pos);
} else {
m = wdisp16(word_aligned_ones, 0);
v = wdisp16(dest_pos, inst_pos);
}
break;
}
default: ShouldNotReachHere();
}
}
return inst & ~m | v;
}
// Return the offset of the branch destionation of instruction inst
// at offset pos.
// Should have pcs, but since all is relative, it works out.
int MacroAssembler::branch_destination(int inst, int pos) {
int r;
switch (inv_op(inst)) {
default: ShouldNotReachHere();
case call_op: r = inv_wdisp(inst, pos, 30); break;
case branch_op:
switch (inv_op2(inst)) {
case fbp_op2: r = inv_wdisp( inst, pos, 19); break;
case bp_op2: r = inv_wdisp( inst, pos, 19); break;
case fb_op2: r = inv_wdisp( inst, pos, 22); break;
case br_op2: r = inv_wdisp( inst, pos, 22); break;
case bpr_op2: {
if (is_cbcond(inst)) {
r = inv_wdisp10(inst, pos);
} else {
r = inv_wdisp16(inst, pos);
}
break;
}
default: ShouldNotReachHere();
}
}
return r;
}
void MacroAssembler::null_check(Register reg, int offset) {
if (needs_explicit_null_check((intptr_t)offset)) {
// provoke OS NULL exception if reg = NULL by
// accessing M[reg] w/o changing any registers
ld_ptr(reg, 0, G0);
}
else {
// nothing to do, (later) access of M[reg + offset]
// will provoke OS NULL exception if reg = NULL
}
}
// Ring buffer jumps
#ifndef PRODUCT
void MacroAssembler::ret( bool trace ) { if (trace) {
mov(I7, O7); // traceable register
JMP(O7, 2 * BytesPerInstWord);
} else {
jmpl( I7, 2 * BytesPerInstWord, G0 );
}
}
void MacroAssembler::retl( bool trace ) { if (trace) JMP(O7, 2 * BytesPerInstWord);
else jmpl( O7, 2 * BytesPerInstWord, G0 ); }
#endif /* PRODUCT */
void MacroAssembler::jmp2(Register r1, Register r2, const char* file, int line ) {
assert_not_delayed();
// This can only be traceable if r1 & r2 are visible after a window save
if (TraceJumps) {
#ifndef PRODUCT
save_frame(0);
verify_thread();
ld(G2_thread, in_bytes(JavaThread::jmp_ring_index_offset()), O0);
add(G2_thread, in_bytes(JavaThread::jmp_ring_offset()), O1);
sll(O0, exact_log2(4*sizeof(intptr_t)), O2);
add(O2, O1, O1);
add(r1->after_save(), r2->after_save(), O2);
set((intptr_t)file, O3);
set(line, O4);
Label L;
// get nearby pc, store jmp target
call(L, relocInfo::none); // No relocation for call to pc+0x8
delayed()->st(O2, O1, 0);
bind(L);
// store nearby pc
st(O7, O1, sizeof(intptr_t));
// store file
st(O3, O1, 2*sizeof(intptr_t));
// store line
st(O4, O1, 3*sizeof(intptr_t));
add(O0, 1, O0);
and3(O0, JavaThread::jump_ring_buffer_size - 1, O0);
st(O0, G2_thread, in_bytes(JavaThread::jmp_ring_index_offset()));
restore();
#endif /* PRODUCT */
}
jmpl(r1, r2, G0);
}
void MacroAssembler::jmp(Register r1, int offset, const char* file, int line ) {
assert_not_delayed();
// This can only be traceable if r1 is visible after a window save
if (TraceJumps) {
#ifndef PRODUCT
save_frame(0);
verify_thread();
ld(G2_thread, in_bytes(JavaThread::jmp_ring_index_offset()), O0);
add(G2_thread, in_bytes(JavaThread::jmp_ring_offset()), O1);
sll(O0, exact_log2(4*sizeof(intptr_t)), O2);
add(O2, O1, O1);
add(r1->after_save(), offset, O2);
set((intptr_t)file, O3);
set(line, O4);
Label L;
// get nearby pc, store jmp target
call(L, relocInfo::none); // No relocation for call to pc+0x8
delayed()->st(O2, O1, 0);
bind(L);
// store nearby pc
st(O7, O1, sizeof(intptr_t));
// store file
st(O3, O1, 2*sizeof(intptr_t));
// store line
st(O4, O1, 3*sizeof(intptr_t));
add(O0, 1, O0);
and3(O0, JavaThread::jump_ring_buffer_size - 1, O0);
st(O0, G2_thread, in_bytes(JavaThread::jmp_ring_index_offset()));
restore();
#endif /* PRODUCT */
}
jmp(r1, offset);
}
// This code sequence is relocatable to any address, even on LP64.
void MacroAssembler::jumpl(const AddressLiteral& addrlit, Register temp, Register d, int offset, const char* file, int line) {
assert_not_delayed();
// Force fixed length sethi because NativeJump and NativeFarCall don't handle
// variable length instruction streams.
patchable_sethi(addrlit, temp);
Address a(temp, addrlit.low10() + offset); // Add the offset to the displacement.
if (TraceJumps) {
#ifndef PRODUCT
// Must do the add here so relocation can find the remainder of the
// value to be relocated.
add(a.base(), a.disp(), a.base(), addrlit.rspec(offset));
save_frame(0);
verify_thread();
ld(G2_thread, in_bytes(JavaThread::jmp_ring_index_offset()), O0);
add(G2_thread, in_bytes(JavaThread::jmp_ring_offset()), O1);
sll(O0, exact_log2(4*sizeof(intptr_t)), O2);
add(O2, O1, O1);
set((intptr_t)file, O3);
set(line, O4);
Label L;
// get nearby pc, store jmp target
call(L, relocInfo::none); // No relocation for call to pc+0x8
delayed()->st(a.base()->after_save(), O1, 0);
bind(L);
// store nearby pc
st(O7, O1, sizeof(intptr_t));
// store file
st(O3, O1, 2*sizeof(intptr_t));
// store line
st(O4, O1, 3*sizeof(intptr_t));
add(O0, 1, O0);
and3(O0, JavaThread::jump_ring_buffer_size - 1, O0);
st(O0, G2_thread, in_bytes(JavaThread::jmp_ring_index_offset()));
restore();
jmpl(a.base(), G0, d);
#else
jmpl(a.base(), a.disp(), d);
#endif /* PRODUCT */
} else {
jmpl(a.base(), a.disp(), d);
}
}
void MacroAssembler::jump(const AddressLiteral& addrlit, Register temp, int offset, const char* file, int line) {
jumpl(addrlit, temp, G0, offset, file, line);
}
// Conditional breakpoint (for assertion checks in assembly code)
void MacroAssembler::breakpoint_trap(Condition c, CC cc) {
trap(c, cc, G0, ST_RESERVED_FOR_USER_0);
}
// We want to use ST_BREAKPOINT here, but the debugger is confused by it.
void MacroAssembler::breakpoint_trap() {
trap(ST_RESERVED_FOR_USER_0);
}
// Write serialization page so VM thread can do a pseudo remote membar
// We use the current thread pointer to calculate a thread specific
// offset to write to within the page. This minimizes bus traffic
// due to cache line collision.
void MacroAssembler::serialize_memory(Register thread, Register tmp1, Register tmp2) {
srl(thread, os::get_serialize_page_shift_count(), tmp2);
if (Assembler::is_simm13(os::vm_page_size())) {
and3(tmp2, (os::vm_page_size() - sizeof(int)), tmp2);
}
else {
set((os::vm_page_size() - sizeof(int)), tmp1);
and3(tmp2, tmp1, tmp2);
}
set(os::get_memory_serialize_page(), tmp1);
st(G0, tmp1, tmp2);
}
void MacroAssembler::enter() {
Unimplemented();
}
void MacroAssembler::leave() {
Unimplemented();
}
// Calls to C land
#ifdef ASSERT
// a hook for debugging
static Thread* reinitialize_thread() {
return ThreadLocalStorage::thread();
}
#else
#define reinitialize_thread ThreadLocalStorage::thread
#endif
#ifdef ASSERT
address last_get_thread = NULL;
#endif
// call this when G2_thread is not known to be valid
void MacroAssembler::get_thread() {
save_frame(0); // to avoid clobbering O0
mov(G1, L0); // avoid clobbering G1
mov(G5_method, L1); // avoid clobbering G5
mov(G3, L2); // avoid clobbering G3 also
mov(G4, L5); // avoid clobbering G4
#ifdef ASSERT
AddressLiteral last_get_thread_addrlit(&last_get_thread);
set(last_get_thread_addrlit, L3);
rdpc(L4);
inc(L4, 3 * BytesPerInstWord); // skip rdpc + inc + st_ptr to point L4 at call st_ptr(L4, L3, 0);
#endif
call(CAST_FROM_FN_PTR(address, reinitialize_thread), relocInfo::runtime_call_type);
delayed()->nop();
mov(L0, G1);
mov(L1, G5_method);
mov(L2, G3);
mov(L5, G4);
restore(O0, 0, G2_thread);
}
static Thread* verify_thread_subroutine(Thread* gthread_value) {
Thread* correct_value = ThreadLocalStorage::thread();
guarantee(gthread_value == correct_value, "G2_thread value must be the thread");
return correct_value;
}
void MacroAssembler::verify_thread() {
if (VerifyThread) {
// NOTE: this chops off the heads of the 64-bit O registers.
#ifdef CC_INTERP
save_frame(0);
#else
// make sure G2_thread contains the right value
save_frame_and_mov(0, Lmethod, Lmethod); // to avoid clobbering O0 (and propagate Lmethod for -Xprof)
mov(G1, L1); // avoid clobbering G1
// G2 saved below
mov(G3, L3); // avoid clobbering G3
mov(G4, L4); // avoid clobbering G4
mov(G5_method, L5); // avoid clobbering G5_method
#endif /* CC_INTERP */
#if defined(COMPILER2) && !defined(_LP64)
// Save & restore possible 64-bit Long arguments in G-regs
srlx(G1,32,L0);
srlx(G4,32,L6);
#endif
call(CAST_FROM_FN_PTR(address,verify_thread_subroutine), relocInfo::runtime_call_type);
delayed()->mov(G2_thread, O0);
mov(L1, G1); // Restore G1
// G2 restored below
mov(L3, G3); // restore G3
mov(L4, G4); // restore G4
mov(L5, G5_method); // restore G5_method
#if defined(COMPILER2) && !defined(_LP64)
// Save & restore possible 64-bit Long arguments in G-regs
sllx(L0,32,G2); // Move old high G1 bits high in G2
srl(G1, 0,G1); // Clear current high G1 bits
or3 (G1,G2,G1); // Recover 64-bit G1
sllx(L6,32,G2); // Move old high G4 bits high in G2
srl(G4, 0,G4); // Clear current high G4 bits
or3 (G4,G2,G4); // Recover 64-bit G4
#endif
restore(O0, 0, G2_thread);
}
}
void MacroAssembler::save_thread(const Register thread_cache) {
verify_thread();
if (thread_cache->is_valid()) {
assert(thread_cache->is_local() || thread_cache->is_in(), "bad volatile");
mov(G2_thread, thread_cache);
}
if (VerifyThread) {
// smash G2_thread, as if the VM were about to anyway
set(0x67676767, G2_thread);
}
}
void MacroAssembler::restore_thread(const Register thread_cache) {
if (thread_cache->is_valid()) {
assert(thread_cache->is_local() || thread_cache->is_in(), "bad volatile");
mov(thread_cache, G2_thread);
verify_thread();
} else {
// do it the slow way
get_thread();
}
}
// %%% maybe get rid of [re]set_last_Java_frame
void MacroAssembler::set_last_Java_frame(Register last_java_sp, Register last_Java_pc) {
assert_not_delayed();
Address flags(G2_thread, JavaThread::frame_anchor_offset() +
JavaFrameAnchor::flags_offset());
Address pc_addr(G2_thread, JavaThread::last_Java_pc_offset());
// Always set last_Java_pc and flags first because once last_Java_sp is visible
// has_last_Java_frame is true and users will look at the rest of the fields.
// (Note: flags should always be zero before we get here so doesn't need to be set.)
#ifdef ASSERT
// Verify that flags was zeroed on return to Java
Label PcOk;
save_frame(0); // to avoid clobbering O0
ld_ptr(pc_addr, L0);
br_null_short(L0, Assembler::pt, PcOk);
STOP("last_Java_pc not zeroed before leaving Java");
bind(PcOk);
// Verify that flags was zeroed on return to Java
Label FlagsOk;
ld(flags, L0);
tst(L0);
br(Assembler::zero, false, Assembler::pt, FlagsOk);
delayed() -> restore();
STOP("flags not zeroed before leaving Java");
bind(FlagsOk);
#endif /* ASSERT */
//
// When returning from calling out from Java mode the frame anchor's last_Java_pc
// will always be set to NULL. It is set here so that if we are doing a call to
// native (not VM) that we capture the known pc and don't have to rely on the
// native call having a standard frame linkage where we can find the pc.
if (last_Java_pc->is_valid()) {
st_ptr(last_Java_pc, pc_addr);
}
#ifdef _LP64
#ifdef ASSERT
// Make sure that we have an odd stack
Label StackOk;
andcc(last_java_sp, 0x01, G0);
br(Assembler::notZero, false, Assembler::pt, StackOk);
delayed()->nop();
STOP("Stack Not Biased in set_last_Java_frame");
bind(StackOk);
#endif // ASSERT
assert( last_java_sp != G4_scratch, "bad register usage in set_last_Java_frame");
add( last_java_sp, STACK_BIAS, G4_scratch );
st_ptr(G4_scratch, G2_thread, JavaThread::last_Java_sp_offset());
#else
st_ptr(last_java_sp, G2_thread, JavaThread::last_Java_sp_offset());
#endif // _LP64
}
void MacroAssembler::reset_last_Java_frame(void) {
assert_not_delayed();
Address sp_addr(G2_thread, JavaThread::last_Java_sp_offset());
Address pc_addr(G2_thread, JavaThread::frame_anchor_offset() + JavaFrameAnchor::last_Java_pc_offset());
Address flags (G2_thread, JavaThread::frame_anchor_offset() + JavaFrameAnchor::flags_offset());
#ifdef ASSERT
// check that it WAS previously set
#ifdef CC_INTERP
save_frame(0);
#else
save_frame_and_mov(0, Lmethod, Lmethod); // Propagate Lmethod to helper frame for -Xprof
#endif /* CC_INTERP */
ld_ptr(sp_addr, L0);
tst(L0);
breakpoint_trap(Assembler::zero, Assembler::ptr_cc);
restore();
#endif // ASSERT
st_ptr(G0, sp_addr);
// Always return last_Java_pc to zero
st_ptr(G0, pc_addr);
// Always null flags after return to Java
st(G0, flags);
}
void MacroAssembler::call_VM_base(
Register oop_result,
Register thread_cache,
Register last_java_sp,
address entry_point,
int number_of_arguments,
bool check_exceptions)
{
assert_not_delayed();
// determine last_java_sp register
if (!last_java_sp->is_valid()) {
last_java_sp = SP;
}
// debugging support
assert(number_of_arguments >= 0 , "cannot have negative number of arguments");
// 64-bit last_java_sp is biased!
set_last_Java_frame(last_java_sp, noreg);
if (VerifyThread) mov(G2_thread, O0); // about to be smashed; pass early
save_thread(thread_cache);
// do the call
call(entry_point, relocInfo::runtime_call_type);
if (!VerifyThread)
delayed()->mov(G2_thread, O0); // pass thread as first argument
else
delayed()->nop(); // (thread already passed)
restore_thread(thread_cache);
reset_last_Java_frame();
// check for pending exceptions. use Gtemp as scratch register.
if (check_exceptions) {
check_and_forward_exception(Gtemp);
}
#ifdef ASSERT
set(badHeapWordVal, G3);
set(badHeapWordVal, G4);
set(badHeapWordVal, G5);
#endif
// get oop result if there is one and reset the value in the thread
if (oop_result->is_valid()) {
get_vm_result(oop_result);
}
}
void MacroAssembler::check_and_forward_exception(Register scratch_reg)
{
Label L;
check_and_handle_popframe(scratch_reg);
check_and_handle_earlyret(scratch_reg);
Address exception_addr(G2_thread, Thread::pending_exception_offset());
ld_ptr(exception_addr, scratch_reg);
br_null_short(scratch_reg, pt, L);
// we use O7 linkage so that forward_exception_entry has the issuing PC
call(StubRoutines::forward_exception_entry(), relocInfo::runtime_call_type);
delayed()->nop();
bind(L);
}
void MacroAssembler::check_and_handle_popframe(Register scratch_reg) {
}
void MacroAssembler::check_and_handle_earlyret(Register scratch_reg) {
}
void MacroAssembler::call_VM(Register oop_result, address entry_point, int number_of_arguments, bool check_exceptions) {
call_VM_base(oop_result, noreg, noreg, entry_point, number_of_arguments, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, bool check_exceptions) {
// O0 is reserved for the thread
mov(arg_1, O1);
call_VM(oop_result, entry_point, 1, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, bool check_exceptions) {
// O0 is reserved for the thread
mov(arg_1, O1);
mov(arg_2, O2); assert(arg_2 != O1, "smashed argument");
call_VM(oop_result, entry_point, 2, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, Register arg_3, bool check_exceptions) {
// O0 is reserved for the thread
mov(arg_1, O1);
mov(arg_2, O2); assert(arg_2 != O1, "smashed argument");
mov(arg_3, O3); assert(arg_3 != O1 && arg_3 != O2, "smashed argument");
call_VM(oop_result, entry_point, 3, check_exceptions);
}
// Note: The following call_VM overloadings are useful when a "save"
// has already been performed by a stub, and the last Java frame is
// the previous one. In that case, last_java_sp must be passed as FP
// instead of SP.
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, int number_of_arguments, bool check_exceptions) {
call_VM_base(oop_result, noreg, last_java_sp, entry_point, number_of_arguments, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, bool check_exceptions) {
// O0 is reserved for the thread
mov(arg_1, O1);
call_VM(oop_result, last_java_sp, entry_point, 1, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, bool check_exceptions) {
// O0 is reserved for the thread
mov(arg_1, O1);
mov(arg_2, O2); assert(arg_2 != O1, "smashed argument");
call_VM(oop_result, last_java_sp, entry_point, 2, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, Register arg_3, bool check_exceptions) {
// O0 is reserved for the thread
mov(arg_1, O1);
mov(arg_2, O2); assert(arg_2 != O1, "smashed argument");
mov(arg_3, O3); assert(arg_3 != O1 && arg_3 != O2, "smashed argument");
call_VM(oop_result, last_java_sp, entry_point, 3, check_exceptions);
}
void MacroAssembler::call_VM_leaf_base(Register thread_cache, address entry_point, int number_of_arguments) {
assert_not_delayed();
save_thread(thread_cache);
// do the call
call(entry_point, relocInfo::runtime_call_type);
delayed()->nop();
restore_thread(thread_cache);
#ifdef ASSERT
set(badHeapWordVal, G3);
set(badHeapWordVal, G4);
set(badHeapWordVal, G5);
#endif
}
void MacroAssembler::call_VM_leaf(Register thread_cache, address entry_point, int number_of_arguments) {
call_VM_leaf_base(thread_cache, entry_point, number_of_arguments);
}
void MacroAssembler::call_VM_leaf(Register thread_cache, address entry_point, Register arg_1) {
mov(arg_1, O0);
call_VM_leaf(thread_cache, entry_point, 1);
}
void MacroAssembler::call_VM_leaf(Register thread_cache, address entry_point, Register arg_1, Register arg_2) {
mov(arg_1, O0);
mov(arg_2, O1); assert(arg_2 != O0, "smashed argument");
call_VM_leaf(thread_cache, entry_point, 2);
}
void MacroAssembler::call_VM_leaf(Register thread_cache, address entry_point, Register arg_1, Register arg_2, Register arg_3) {
mov(arg_1, O0);
mov(arg_2, O1); assert(arg_2 != O0, "smashed argument");
mov(arg_3, O2); assert(arg_3 != O0 && arg_3 != O1, "smashed argument");
call_VM_leaf(thread_cache, entry_point, 3);
}
void MacroAssembler::get_vm_result(Register oop_result) {
verify_thread();
Address vm_result_addr(G2_thread, JavaThread::vm_result_offset());
ld_ptr( vm_result_addr, oop_result);
st_ptr(G0, vm_result_addr);
verify_oop(oop_result);
}
void MacroAssembler::get_vm_result_2(Register metadata_result) {
verify_thread();
Address vm_result_addr_2(G2_thread, JavaThread::vm_result_2_offset());
ld_ptr(vm_result_addr_2, metadata_result);
st_ptr(G0, vm_result_addr_2);
}
// We require that C code which does not return a value in vm_result will
// leave it undisturbed.
void MacroAssembler::set_vm_result(Register oop_result) {
verify_thread();
Address vm_result_addr(G2_thread, JavaThread::vm_result_offset());
verify_oop(oop_result);
# ifdef ASSERT
// Check that we are not overwriting any other oop.
#ifdef CC_INTERP
save_frame(0);
#else
save_frame_and_mov(0, Lmethod, Lmethod); // Propagate Lmethod for -Xprof
#endif /* CC_INTERP */
ld_ptr(vm_result_addr, L0);
tst(L0);
restore();
breakpoint_trap(notZero, Assembler::ptr_cc);
// }
# endif
st_ptr(oop_result, vm_result_addr);
}
void MacroAssembler::ic_call(address entry, bool emit_delay) {
RelocationHolder rspec = virtual_call_Relocation::spec(pc());
patchable_set((intptr_t)Universe::non_oop_word(), G5_inline_cache_reg);
relocate(rspec);
call(entry, relocInfo::none);
if (emit_delay) {
delayed()->nop();
}
}
void MacroAssembler::card_table_write(jbyte* byte_map_base,
Register tmp, Register obj) {
#ifdef _LP64
srlx(obj, CardTableModRefBS::card_shift, obj);
#else
srl(obj, CardTableModRefBS::card_shift, obj);
#endif
assert(tmp != obj, "need separate temp reg");
set((address) byte_map_base, tmp);
stb(G0, tmp, obj);
}
void MacroAssembler::internal_sethi(const AddressLiteral& addrlit, Register d, bool ForceRelocatable) {
address save_pc;
int shiftcnt;
#ifdef _LP64
# ifdef CHECK_DELAY
assert_not_delayed((char*) "cannot put two instructions in delay slot");
# endif
v9_dep();
save_pc = pc();
int msb32 = (int) (addrlit.value() >> 32);
int lsb32 = (int) (addrlit.value());
if (msb32 == 0 && lsb32 >= 0) {
Assembler::sethi(lsb32, d, addrlit.rspec());
}
else if (msb32 == -1) {
Assembler::sethi(~lsb32, d, addrlit.rspec());
xor3(d, ~low10(~0), d);
}
else {
Assembler::sethi(msb32, d, addrlit.rspec()); // msb 22-bits
if (msb32 & 0x3ff) // Any bits?
or3(d, msb32 & 0x3ff, d); // msb 32-bits are now in lsb 32
if (lsb32 & 0xFFFFFC00) { // done?
if ((lsb32 >> 20) & 0xfff) { // Any bits set?
sllx(d, 12, d); // Make room for next 12 bits
or3(d, (lsb32 >> 20) & 0xfff, d); // Or in next 12
shiftcnt = 0; // We already shifted
}
else
shiftcnt = 12;
if ((lsb32 >> 10) & 0x3ff) {
sllx(d, shiftcnt + 10, d); // Make room for last 10 bits
or3(d, (lsb32 >> 10) & 0x3ff, d); // Or in next 10
shiftcnt = 0;
}
else
shiftcnt = 10;
sllx(d, shiftcnt + 10, d); // Shift leaving disp field 0'd
}
else
sllx(d, 32, d);
}
// Pad out the instruction sequence so it can be patched later.
if (ForceRelocatable || (addrlit.rtype() != relocInfo::none &&
addrlit.rtype() != relocInfo::runtime_call_type)) {
while (pc() < (save_pc + (7 * BytesPerInstWord)))
nop();
}
#else
Assembler::sethi(addrlit.value(), d, addrlit.rspec());
#endif
}
void MacroAssembler::sethi(const AddressLiteral& addrlit, Register d) {
internal_sethi(addrlit, d, false);
}
void MacroAssembler::patchable_sethi(const AddressLiteral& addrlit, Register d) {
internal_sethi(addrlit, d, true);
}
int MacroAssembler::insts_for_sethi(address a, bool worst_case) {
#ifdef _LP64
if (worst_case) return 7;
intptr_t iaddr = (intptr_t) a;
int msb32 = (int) (iaddr >> 32);
int lsb32 = (int) (iaddr);
int count;
if (msb32 == 0 && lsb32 >= 0)
count = 1;
else if (msb32 == -1)
count = 2;
else {
count = 2;
if (msb32 & 0x3ff)
count++;
if (lsb32 & 0xFFFFFC00 ) {
if ((lsb32 >> 20) & 0xfff) count += 2;
if ((lsb32 >> 10) & 0x3ff) count += 2;
}
}
return count;
#else
return 1;
#endif
}
int MacroAssembler::worst_case_insts_for_set() {
return insts_for_sethi(NULL, true) + 1;
}
// Keep in sync with MacroAssembler::insts_for_internal_set
void MacroAssembler::internal_set(const AddressLiteral& addrlit, Register d, bool ForceRelocatable) {
intptr_t value = addrlit.value();
if (!ForceRelocatable && addrlit.rspec().type() == relocInfo::none) {
// can optimize
if (-4096 <= value && value <= 4095) {
or3(G0, value, d); // setsw (this leaves upper 32 bits sign-extended)
return;
}
if (inv_hi22(hi22(value)) == value) {
sethi(addrlit, d);
return;
}
}
assert_not_delayed((char*) "cannot put two instructions in delay slot");
internal_sethi(addrlit, d, ForceRelocatable);
if (ForceRelocatable || addrlit.rspec().type() != relocInfo::none || addrlit.low10() != 0) {
add(d, addrlit.low10(), d, addrlit.rspec());
}
}
// Keep in sync with MacroAssembler::internal_set
int MacroAssembler::insts_for_internal_set(intptr_t value) {
// can optimize
if (-4096 <= value && value <= 4095) {
return 1;
}
if (inv_hi22(hi22(value)) == value) {
return insts_for_sethi((address) value);
}
int count = insts_for_sethi((address) value);
AddressLiteral al(value);
if (al.low10() != 0) {
count++;
}
return count;
}
void MacroAssembler::set(const AddressLiteral& al, Register d) {
internal_set(al, d, false);
}
void MacroAssembler::set(intptr_t value, Register d) {
AddressLiteral al(value);
internal_set(al, d, false);
}
void MacroAssembler::set(address addr, Register d, RelocationHolder const& rspec) {
AddressLiteral al(addr, rspec);
internal_set(al, d, false);
}
void MacroAssembler::patchable_set(const AddressLiteral& al, Register d) {
internal_set(al, d, true);
}
void MacroAssembler::patchable_set(intptr_t value, Register d) {
AddressLiteral al(value);
internal_set(al, d, true);
}
void MacroAssembler::set64(jlong value, Register d, Register tmp) {
assert_not_delayed();
v9_dep();
int hi = (int)(value >> 32);
int lo = (int)(value & ~0);
// (Matcher::isSimpleConstant64 knows about the following optimizations.)
if (Assembler::is_simm13(lo) && value == lo) {
or3(G0, lo, d);
} else if (hi == 0) {
Assembler::sethi(lo, d); // hardware version zero-extends to upper 32
if (low10(lo) != 0)
or3(d, low10(lo), d);
}
else if (hi == -1) {
Assembler::sethi(~lo, d); // hardware version zero-extends to upper 32
xor3(d, low10(lo) ^ ~low10(~0), d);
}
else if (lo == 0) {
if (Assembler::is_simm13(hi)) {
or3(G0, hi, d);
} else {
Assembler::sethi(hi, d); // hardware version zero-extends to upper 32
if (low10(hi) != 0)
or3(d, low10(hi), d);
}
sllx(d, 32, d);
}
else {
Assembler::sethi(hi, tmp);
Assembler::sethi(lo, d); // macro assembler version sign-extends
if (low10(hi) != 0)
or3 (tmp, low10(hi), tmp);
if (low10(lo) != 0)
or3 ( d, low10(lo), d);
sllx(tmp, 32, tmp);
or3 (d, tmp, d);
}
}
int MacroAssembler::insts_for_set64(jlong value) {
v9_dep();
int hi = (int) (value >> 32);
int lo = (int) (value & ~0);
int count = 0;
// (Matcher::isSimpleConstant64 knows about the following optimizations.)
if (Assembler::is_simm13(lo) && value == lo) {
count++;
} else if (hi == 0) {
count++;
if (low10(lo) != 0)
count++;
}
else if (hi == -1) {
count += 2;
}
else if (lo == 0) {
if (Assembler::is_simm13(hi)) {
count++;
} else {
count++;
if (low10(hi) != 0)
count++;
}
count++;
}
else {
count += 2;
if (low10(hi) != 0)
count++;
if (low10(lo) != 0)
count++;
count += 2;
}
return count;
}
// compute size in bytes of sparc frame, given
// number of extraWords
int MacroAssembler::total_frame_size_in_bytes(int extraWords) {
int nWords = frame::memory_parameter_word_sp_offset;
nWords += extraWords;
if (nWords & 1) ++nWords; // round up to double-word
return nWords * BytesPerWord;
}
// save_frame: given number of "extra" words in frame,
// issue approp. save instruction (p 200, v8 manual)
void MacroAssembler::save_frame(int extraWords) {
int delta = -total_frame_size_in_bytes(extraWords);
if (is_simm13(delta)) {
save(SP, delta, SP);
} else {
set(delta, G3_scratch);
save(SP, G3_scratch, SP);
}
}
void MacroAssembler::save_frame_c1(int size_in_bytes) {
if (is_simm13(-size_in_bytes)) {
save(SP, -size_in_bytes, SP);
} else {
set(-size_in_bytes, G3_scratch);
save(SP, G3_scratch, SP);
}
}
void MacroAssembler::save_frame_and_mov(int extraWords,
Register s1, Register d1,
Register s2, Register d2) {
assert_not_delayed();
// The trick here is to use precisely the same memory word
// that trap handlers also use to save the register.
// This word cannot be used for any other purpose, but
// it works fine to save the register's value, whether or not
// an interrupt flushes register windows at any given moment!
Address s1_addr;
if (s1->is_valid() && (s1->is_in() || s1->is_local())) {
s1_addr = s1->address_in_saved_window();
st_ptr(s1, s1_addr);
}
Address s2_addr;
if (s2->is_valid() && (s2->is_in() || s2->is_local())) {
s2_addr = s2->address_in_saved_window();
st_ptr(s2, s2_addr);
}
save_frame(extraWords);
if (s1_addr.base() == SP) {
ld_ptr(s1_addr.after_save(), d1);
} else if (s1->is_valid()) {
mov(s1->after_save(), d1);
}
if (s2_addr.base() == SP) {
ld_ptr(s2_addr.after_save(), d2);
} else if (s2->is_valid()) {
mov(s2->after_save(), d2);
}
}
AddressLiteral MacroAssembler::allocate_metadata_address(Metadata* obj) {
assert(oop_recorder() != NULL, "this assembler needs a Recorder");
int index = oop_recorder()->allocate_metadata_index(obj);
RelocationHolder rspec = metadata_Relocation::spec(index);
return AddressLiteral((address)obj, rspec);
}
AddressLiteral MacroAssembler::constant_metadata_address(Metadata* obj) {
assert(oop_recorder() != NULL, "this assembler needs a Recorder");
int index = oop_recorder()->find_index(obj);
RelocationHolder rspec = metadata_Relocation::spec(index);
return AddressLiteral((address)obj, rspec);
}
AddressLiteral MacroAssembler::constant_oop_address(jobject obj) {
assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
assert(Universe::heap()->is_in_reserved(JNIHandles::resolve(obj)), "not an oop");
int oop_index = oop_recorder()->find_index(obj);
return AddressLiteral(obj, oop_Relocation::spec(oop_index));
}
void MacroAssembler::set_narrow_oop(jobject obj, Register d) {
assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
int oop_index = oop_recorder()->find_index(obj);
RelocationHolder rspec = oop_Relocation::spec(oop_index);
assert_not_delayed();
// Relocation with special format (see relocInfo_sparc.hpp).
relocate(rspec, 1);
// Assembler::sethi(0x3fffff, d);
emit_int32( op(branch_op) | rd(d) | op2(sethi_op2) | hi22(0x3fffff) );
// Don't add relocation for 'add'. Do patching during 'sethi' processing.
add(d, 0x3ff, d);
}
void MacroAssembler::set_narrow_klass(Klass* k, Register d) {
assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
int klass_index = oop_recorder()->find_index(k);
RelocationHolder rspec = metadata_Relocation::spec(klass_index);
narrowOop encoded_k = Klass::encode_klass(k);
assert_not_delayed();
// Relocation with special format (see relocInfo_sparc.hpp).
relocate(rspec, 1);
// Assembler::sethi(encoded_k, d);
emit_int32( op(branch_op) | rd(d) | op2(sethi_op2) | hi22(encoded_k) );
// Don't add relocation for 'add'. Do patching during 'sethi' processing.
add(d, low10(encoded_k), d);
}
void MacroAssembler::align(int modulus) {
while (offset() % modulus != 0) nop();
}
void RegistersForDebugging::print(outputStream* s) {
FlagSetting fs(Debugging, true);
int j;
for (j = 0; j < 8; ++j) {
if (j != 6) { s->print("i%d = ", j); os::print_location(s, i[j]); }
else { s->print( "fp = " ); os::print_location(s, i[j]); }
}
s->cr();
for (j = 0; j < 8; ++j) {
s->print("l%d = ", j); os::print_location(s, l[j]);
}
s->cr();
for (j = 0; j < 8; ++j) {
if (j != 6) { s->print("o%d = ", j); os::print_location(s, o[j]); }
else { s->print( "sp = " ); os::print_location(s, o[j]); }
}
s->cr();
for (j = 0; j < 8; ++j) {
s->print("g%d = ", j); os::print_location(s, g[j]);
}
s->cr();
// print out floats with compression
for (j = 0; j < 32; ) {
jfloat val = f[j];
int last = j;
for ( ; last+1 < 32; ++last ) {
char b1[1024], b2[1024];
sprintf(b1, "%f", val);
sprintf(b2, "%f", f[last+1]);
if (strcmp(b1, b2))
break;
}
s->print("f%d", j);
if ( j != last ) s->print(" - f%d", last);
s->print(" = %f", val);
s->fill_to(25);
s->print_cr(" (0x%x)", val);
j = last + 1;
}
s->cr();
// and doubles (evens only)
for (j = 0; j < 32; ) {
jdouble val = d[j];
int last = j;
for ( ; last+1 < 32; ++last ) {
char b1[1024], b2[1024];
sprintf(b1, "%f", val);
sprintf(b2, "%f", d[last+1]);
if (strcmp(b1, b2))
break;
}
s->print("d%d", 2 * j);
if ( j != last ) s->print(" - d%d", last);
s->print(" = %f", val);
s->fill_to(30);
s->print("(0x%x)", *(int*)&val);
s->fill_to(42);
s->print_cr("(0x%x)", *(1 + (int*)&val));
j = last + 1;
}
s->cr();
}
void RegistersForDebugging::save_registers(MacroAssembler* a) {
a->sub(FP, round_to(sizeof(RegistersForDebugging), sizeof(jdouble)) - STACK_BIAS, O0);
a->flushw();
int i;
for (i = 0; i < 8; ++i) {
a->ld_ptr(as_iRegister(i)->address_in_saved_window().after_save(), L1); a->st_ptr( L1, O0, i_offset(i));
a->ld_ptr(as_lRegister(i)->address_in_saved_window().after_save(), L1); a->st_ptr( L1, O0, l_offset(i));
a->st_ptr(as_oRegister(i)->after_save(), O0, o_offset(i));
a->st_ptr(as_gRegister(i)->after_save(), O0, g_offset(i));
}
for (i = 0; i < 32; ++i) {
a->stf(FloatRegisterImpl::S, as_FloatRegister(i), O0, f_offset(i));
}
for (i = 0; i < 64; i += 2) {
a->stf(FloatRegisterImpl::D, as_FloatRegister(i), O0, d_offset(i));
}
}
void RegistersForDebugging::restore_registers(MacroAssembler* a, Register r) {
for (int i = 1; i < 8; ++i) {
a->ld_ptr(r, g_offset(i), as_gRegister(i));
}
for (int j = 0; j < 32; ++j) {
a->ldf(FloatRegisterImpl::S, O0, f_offset(j), as_FloatRegister(j));
}
for (int k = 0; k < 64; k += 2) {
a->ldf(FloatRegisterImpl::D, O0, d_offset(k), as_FloatRegister(k));
}
}
// pushes double TOS element of FPU stack on CPU stack; pops from FPU stack
void MacroAssembler::push_fTOS() {
// %%%%%% need to implement this
}
// pops double TOS element from CPU stack and pushes on FPU stack
void MacroAssembler::pop_fTOS() {
// %%%%%% need to implement this
}
void MacroAssembler::empty_FPU_stack() {
// %%%%%% need to implement this
}
void MacroAssembler::_verify_oop(Register reg, const char* msg, const char * file, int line) {
// plausibility check for oops
if (!VerifyOops) return;
if (reg == G0) return; // always NULL, which is always an oop
BLOCK_COMMENT("verify_oop {");
char buffer[64];
#ifdef COMPILER1
if (CommentedAssembly) {
snprintf(buffer, sizeof(buffer), "verify_oop at %d", offset());
block_comment(buffer);
}
#endif
const char* real_msg = NULL;
{
ResourceMark rm;
stringStream ss;
ss.print("%s at offset %d (%s:%d)", msg, offset(), file, line);
real_msg = code_string(ss.as_string());
}
// Call indirectly to solve generation ordering problem
AddressLiteral a(StubRoutines::verify_oop_subroutine_entry_address());
// Make some space on stack above the current register window.
// Enough to hold 8 64-bit registers.
add(SP,-8*8,SP);
// Save some 64-bit registers; a normal 'save' chops the heads off
// of 64-bit longs in the 32-bit build.
stx(O0,SP,frame::register_save_words*wordSize+STACK_BIAS+0*8);
stx(O1,SP,frame::register_save_words*wordSize+STACK_BIAS+1*8);
mov(reg,O0); // Move arg into O0; arg might be in O7 which is about to be crushed
stx(O7,SP,frame::register_save_words*wordSize+STACK_BIAS+7*8);
// Size of set() should stay the same
patchable_set((intptr_t)real_msg, O1);
// Load address to call to into O7
load_ptr_contents(a, O7);
// Register call to verify_oop_subroutine
callr(O7, G0);
delayed()->nop();
// recover frame size
add(SP, 8*8,SP);
BLOCK_COMMENT("} verify_oop");
}
void MacroAssembler::_verify_oop_addr(Address addr, const char* msg, const char * file, int line) {
// plausibility check for oops
if (!VerifyOops) return;
const char* real_msg = NULL;
{
ResourceMark rm;
stringStream ss;
ss.print("%s at SP+%d (%s:%d)", msg, addr.disp(), file, line);
real_msg = code_string(ss.as_string());
}
// Call indirectly to solve generation ordering problem
AddressLiteral a(StubRoutines::verify_oop_subroutine_entry_address());
// Make some space on stack above the current register window.
// Enough to hold 8 64-bit registers.
add(SP,-8*8,SP);
// Save some 64-bit registers; a normal 'save' chops the heads off
// of 64-bit longs in the 32-bit build.
stx(O0,SP,frame::register_save_words*wordSize+STACK_BIAS+0*8);
stx(O1,SP,frame::register_save_words*wordSize+STACK_BIAS+1*8);
ld_ptr(addr.base(), addr.disp() + 8*8, O0); // Load arg into O0; arg might be in O7 which is about to be crushed
stx(O7,SP,frame::register_save_words*wordSize+STACK_BIAS+7*8);
// Size of set() should stay the same
patchable_set((intptr_t)real_msg, O1);
// Load address to call to into O7
load_ptr_contents(a, O7);
// Register call to verify_oop_subroutine
callr(O7, G0);
delayed()->nop();
// recover frame size
add(SP, 8*8,SP);
}
// side-door communication with signalHandler in os_solaris.cpp
address MacroAssembler::_verify_oop_implicit_branch[3] = { NULL };
// This macro is expanded just once; it creates shared code. Contract:
// receives an oop in O0. Must restore O0 & O7 from TLS. Must not smash ANY
// registers, including flags. May not use a register 'save', as this blows
// the high bits of the O-regs if they contain Long values. Acts as a 'leaf'
// call.
void MacroAssembler::verify_oop_subroutine() {
// Leaf call; no frame.
Label succeed, fail, null_or_fail;
// O0 and O7 were saved already (O0 in O0's TLS home, O7 in O5's TLS home).
// O0 is now the oop to be checked. O7 is the return address.
Register O0_obj = O0;
// Save some more registers for temps.
stx(O2,SP,frame::register_save_words*wordSize+STACK_BIAS+2*8);
stx(O3,SP,frame::register_save_words*wordSize+STACK_BIAS+3*8);
stx(O4,SP,frame::register_save_words*wordSize+STACK_BIAS+4*8);
stx(O5,SP,frame::register_save_words*wordSize+STACK_BIAS+5*8);
// Save flags
Register O5_save_flags = O5;
rdccr( O5_save_flags );
{ // count number of verifies
Register O2_adr = O2;
Register O3_accum = O3;
inc_counter(StubRoutines::verify_oop_count_addr(), O2_adr, O3_accum);
}
Register O2_mask = O2;
Register O3_bits = O3;
Register O4_temp = O4;
// mark lower end of faulting range
assert(_verify_oop_implicit_branch[0] == NULL, "set once");
_verify_oop_implicit_branch[0] = pc();
// We can't check the mark oop because it could be in the process of
// locking or unlocking while this is running.
set(Universe::verify_oop_mask (), O2_mask);
set(Universe::verify_oop_bits (), O3_bits);
// assert((obj & oop_mask) == oop_bits);
and3(O0_obj, O2_mask, O4_temp);
cmp_and_brx_short(O4_temp, O3_bits, notEqual, pn, null_or_fail);
if ((NULL_WORD & Universe::verify_oop_mask()) == Universe::verify_oop_bits()) {
// the null_or_fail case is useless; must test for null separately
br_null_short(O0_obj, pn, succeed);
}
// Check the Klass* of this object for being in the right area of memory.
// Cannot do the load in the delay above slot in case O0 is null
load_klass(O0_obj, O0_obj);
// assert((klass != NULL)
br_null_short(O0_obj, pn, fail);
wrccr( O5_save_flags ); // Restore CCR's
// mark upper end of faulting range
_verify_oop_implicit_branch[1] = pc();
//-----------------------
// all tests pass
bind(succeed);
// Restore prior 64-bit registers
ldx(SP,frame::register_save_words*wordSize+STACK_BIAS+0*8,O0);
ldx(SP,frame::register_save_words*wordSize+STACK_BIAS+1*8,O1);
ldx(SP,frame::register_save_words*wordSize+STACK_BIAS+2*8,O2);
ldx(SP,frame::register_save_words*wordSize+STACK_BIAS+3*8,O3);
ldx(SP,frame::register_save_words*wordSize+STACK_BIAS+4*8,O4);
ldx(SP,frame::register_save_words*wordSize+STACK_BIAS+5*8,O5);
retl(); // Leaf return; restore prior O7 in delay slot
delayed()->ldx(SP,frame::register_save_words*wordSize+STACK_BIAS+7*8,O7);
//-----------------------
bind(null_or_fail); // nulls are less common but OK
br_null(O0_obj, false, pt, succeed);
delayed()->wrccr( O5_save_flags ); // Restore CCR's
//-----------------------
// report failure:
bind(fail);
_verify_oop_implicit_branch[2] = pc();
wrccr( O5_save_flags ); // Restore CCR's
save_frame(::round_to(sizeof(RegistersForDebugging) / BytesPerWord, 2));
// stop_subroutine expects message pointer in I1.
mov(I1, O1);
// Restore prior 64-bit registers
ldx(FP,frame::register_save_words*wordSize+STACK_BIAS+0*8,I0);
ldx(FP,frame::register_save_words*wordSize+STACK_BIAS+1*8,I1);
ldx(FP,frame::register_save_words*wordSize+STACK_BIAS+2*8,I2);
ldx(FP,frame::register_save_words*wordSize+STACK_BIAS+3*8,I3);
ldx(FP,frame::register_save_words*wordSize+STACK_BIAS+4*8,I4);
ldx(FP,frame::register_save_words*wordSize+STACK_BIAS+5*8,I5);
// factor long stop-sequence into subroutine to save space
assert(StubRoutines::Sparc::stop_subroutine_entry_address(), "hasn't been generated yet");
// call indirectly to solve generation ordering problem
AddressLiteral al(StubRoutines::Sparc::stop_subroutine_entry_address());
load_ptr_contents(al, O5);
jmpl(O5, 0, O7);
delayed()->nop();
}
void MacroAssembler::stop(const char* msg) {
// save frame first to get O7 for return address
// add one word to size in case struct is odd number of words long
// It must be doubleword-aligned for storing doubles into it.
save_frame(::round_to(sizeof(RegistersForDebugging) / BytesPerWord, 2));
// stop_subroutine expects message pointer in I1.
// Size of set() should stay the same
patchable_set((intptr_t)msg, O1);
// factor long stop-sequence into subroutine to save space
assert(StubRoutines::Sparc::stop_subroutine_entry_address(), "hasn't been generated yet");
// call indirectly to solve generation ordering problem
AddressLiteral a(StubRoutines::Sparc::stop_subroutine_entry_address());
load_ptr_contents(a, O5);
jmpl(O5, 0, O7);
delayed()->nop();
breakpoint_trap(); // make stop actually stop rather than writing
// unnoticeable results in the output files.
// restore(); done in callee to save space!
}
void MacroAssembler::warn(const char* msg) {
save_frame(::round_to(sizeof(RegistersForDebugging) / BytesPerWord, 2));
RegistersForDebugging::save_registers(this);
mov(O0, L0);
// Size of set() should stay the same
patchable_set((intptr_t)msg, O0);
call( CAST_FROM_FN_PTR(address, warning) );
delayed()->nop();
// ret();
// delayed()->restore();
RegistersForDebugging::restore_registers(this, L0);
restore();
}
void MacroAssembler::untested(const char* what) {
// We must be able to turn interactive prompting off
// in order to run automated test scripts on the VM
// Use the flag ShowMessageBoxOnError
const char* b = NULL;
{
ResourceMark rm;
stringStream ss;
ss.print("untested: %s", what);
b = code_string(ss.as_string());
}
if (ShowMessageBoxOnError) { STOP(b); }
else { warn(b); }
}
void MacroAssembler::stop_subroutine() {
RegistersForDebugging::save_registers(this);
// for the sake of the debugger, stick a PC on the current frame
// (this assumes that the caller has performed an extra "save")
mov(I7, L7);
add(O7, -7 * BytesPerInt, I7);
save_frame(); // one more save to free up another O7 register
mov(I0, O1); // addr of reg save area
// We expect pointer to message in I1. Caller must set it up in O1
mov(I1, O0); // get msg
call (CAST_FROM_FN_PTR(address, MacroAssembler::debug), relocInfo::runtime_call_type);
delayed()->nop();
restore();
RegistersForDebugging::restore_registers(this, O0);
save_frame(0);
call(CAST_FROM_FN_PTR(address,breakpoint));
delayed()->nop();
restore();
mov(L7, I7);
retl();
delayed()->restore(); // see stop above
}
void MacroAssembler::debug(char* msg, RegistersForDebugging* regs) {
if ( ShowMessageBoxOnError ) {
JavaThread* thread = JavaThread::current();
JavaThreadState saved_state = thread->thread_state();
thread->set_thread_state(_thread_in_vm);
{
// In order to get locks work, we need to fake a in_VM state
ttyLocker ttyl;
::tty->print_cr("EXECUTION STOPPED: %s\n", msg);
if (CountBytecodes || TraceBytecodes || StopInterpreterAt) {
BytecodeCounter::print();
}
if (os::message_box(msg, "Execution stopped, print registers?"))
regs->print(::tty);
}
BREAKPOINT;
ThreadStateTransition::transition(JavaThread::current(), _thread_in_vm, saved_state);
}
else {
::tty->print_cr("=============== DEBUG MESSAGE: %s ================\n", msg);
}
assert(false, err_msg("DEBUG MESSAGE: %s", msg));
}
void MacroAssembler::calc_mem_param_words(Register Rparam_words, Register Rresult) {
subcc( Rparam_words, Argument::n_register_parameters, Rresult); // how many mem words?
Label no_extras;
br( negative, true, pt, no_extras ); // if neg, clear reg
delayed()->set(0, Rresult); // annuled, so only if taken
bind( no_extras );
}
void MacroAssembler::calc_frame_size(Register Rextra_words, Register Rresult) {
#ifdef _LP64
add(Rextra_words, frame::memory_parameter_word_sp_offset, Rresult);
#else
add(Rextra_words, frame::memory_parameter_word_sp_offset + 1, Rresult);
#endif
bclr(1, Rresult);
sll(Rresult, LogBytesPerWord, Rresult); // Rresult has total frame bytes
}
void MacroAssembler::calc_frame_size_and_save(Register Rextra_words, Register Rresult) {
calc_frame_size(Rextra_words, Rresult);
neg(Rresult);
save(SP, Rresult, SP);
}
// ---------------------------------------------------------
Assembler::RCondition cond2rcond(Assembler::Condition c) {
switch (c) {
/*case zero: */
case Assembler::equal: return Assembler::rc_z;
case Assembler::lessEqual: return Assembler::rc_lez;
case Assembler::less: return Assembler::rc_lz;
/*case notZero:*/
case Assembler::notEqual: return Assembler::rc_nz;
case Assembler::greater: return Assembler::rc_gz;
case Assembler::greaterEqual: return Assembler::rc_gez;
}
ShouldNotReachHere();
return Assembler::rc_z;
}
// compares (32 bit) register with zero and branches. NOT FOR USE WITH 64-bit POINTERS
void MacroAssembler::cmp_zero_and_br(Condition c, Register s1, Label& L, bool a, Predict p) {
tst(s1);
br (c, a, p, L);
}
// Compares a pointer register with zero and branches on null.
// Does a test & branch on 32-bit systems and a register-branch on 64-bit.
void MacroAssembler::br_null( Register s1, bool a, Predict p, Label& L ) {
assert_not_delayed();
#ifdef _LP64
bpr( rc_z, a, p, s1, L );
#else
tst(s1);
br ( zero, a, p, L );
#endif
}
void MacroAssembler::br_notnull( Register s1, bool a, Predict p, Label& L ) {
assert_not_delayed();
#ifdef _LP64
bpr( rc_nz, a, p, s1, L );
#else
tst(s1);
br ( notZero, a, p, L );
#endif
}
// Compare registers and branch with nop in delay slot or cbcond without delay slot.
// Compare integer (32 bit) values (icc only).
void MacroAssembler::cmp_and_br_short(Register s1, Register s2, Condition c,
Predict p, Label& L) {
assert_not_delayed();
if (use_cbcond(L)) {
Assembler::cbcond(c, icc, s1, s2, L);
} else {
cmp(s1, s2);
br(c, false, p, L);
delayed()->nop();
}
}
// Compare integer (32 bit) values (icc only).
void MacroAssembler::cmp_and_br_short(Register s1, int simm13a, Condition c,
Predict p, Label& L) {
assert_not_delayed();
if (is_simm(simm13a,5) && use_cbcond(L)) {
Assembler::cbcond(c, icc, s1, simm13a, L);
} else {
cmp(s1, simm13a);
br(c, false, p, L);
delayed()->nop();
}
}
// Branch that tests xcc in LP64 and icc in !LP64
void MacroAssembler::cmp_and_brx_short(Register s1, Register s2, Condition c,
Predict p, Label& L) {
assert_not_delayed();
if (use_cbcond(L)) {
Assembler::cbcond(c, ptr_cc, s1, s2, L);
} else {
cmp(s1, s2);
brx(c, false, p, L);
delayed()->nop();
}
}
// Branch that tests xcc in LP64 and icc in !LP64
void MacroAssembler::cmp_and_brx_short(Register s1, int simm13a, Condition c,
Predict p, Label& L) {
assert_not_delayed();
if (is_simm(simm13a,5) && use_cbcond(L)) {
Assembler::cbcond(c, ptr_cc, s1, simm13a, L);
} else {
cmp(s1, simm13a);
brx(c, false, p, L);
delayed()->nop();
}
}
// Short branch version for compares a pointer with zero.
void MacroAssembler::br_null_short(Register s1, Predict p, Label& L) {
assert_not_delayed();
if (use_cbcond(L)) {
Assembler::cbcond(zero, ptr_cc, s1, 0, L);
return;
}
br_null(s1, false, p, L);
delayed()->nop();
}
void MacroAssembler::br_notnull_short(Register s1, Predict p, Label& L) {
assert_not_delayed();
if (use_cbcond(L)) {
Assembler::cbcond(notZero, ptr_cc, s1, 0, L);
return;
}
br_notnull(s1, false, p, L);
delayed()->nop();
}
// Unconditional short branch
void MacroAssembler::ba_short(Label& L) {
if (use_cbcond(L)) {
Assembler::cbcond(equal, icc, G0, G0, L);
return;
}
br(always, false, pt, L);
delayed()->nop();
}
// instruction sequences factored across compiler & interpreter
void MacroAssembler::lcmp( Register Ra_hi, Register Ra_low,
Register Rb_hi, Register Rb_low,
Register Rresult) {
Label check_low_parts, done;
cmp(Ra_hi, Rb_hi ); // compare hi parts
br(equal, true, pt, check_low_parts);
delayed()->cmp(Ra_low, Rb_low); // test low parts
// And, with an unsigned comparison, it does not matter if the numbers
// are negative or not.
// E.g., -2 cmp -1: the low parts are 0xfffffffe and 0xffffffff.
// The second one is bigger (unsignedly).
// Other notes: The first move in each triplet can be unconditional
// (and therefore probably prefetchable).
// And the equals case for the high part does not need testing,
// since that triplet is reached only after finding the high halves differ.
mov(-1, Rresult);
ba(done);
delayed()->movcc(greater, false, icc, 1, Rresult);
bind(check_low_parts);
mov( -1, Rresult);
movcc(equal, false, icc, 0, Rresult);
movcc(greaterUnsigned, false, icc, 1, Rresult);
bind(done);
}
void MacroAssembler::lneg( Register Rhi, Register Rlow ) {
subcc( G0, Rlow, Rlow );
subc( G0, Rhi, Rhi );
}
void MacroAssembler::lshl( Register Rin_high, Register Rin_low,
Register Rcount,
Register Rout_high, Register Rout_low,
Register Rtemp ) {
Register Ralt_count = Rtemp;
Register Rxfer_bits = Rtemp;
assert( Ralt_count != Rin_high
&& Ralt_count != Rin_low
&& Ralt_count != Rcount
&& Rxfer_bits != Rin_low
&& Rxfer_bits != Rin_high
&& Rxfer_bits != Rcount
&& Rxfer_bits != Rout_low
&& Rout_low != Rin_high,
"register alias checks");
Label big_shift, done;
// This code can be optimized to use the 64 bit shifts in V9.
// Here we use the 32 bit shifts.
and3( Rcount, 0x3f, Rcount); // take least significant 6 bits
subcc(Rcount, 31, Ralt_count);
br(greater, true, pn, big_shift);
delayed()->dec(Ralt_count);
// shift < 32 bits, Ralt_count = Rcount-31
// We get the transfer bits by shifting right by 32-count the low
// register. This is done by shifting right by 31-count and then by one
// more to take care of the special (rare) case where count is zero
// (shifting by 32 would not work).
neg(Ralt_count);
// The order of the next two instructions is critical in the case where
// Rin and Rout are the same and should not be reversed.
srl(Rin_low, Ralt_count, Rxfer_bits); // shift right by 31-count
if (Rcount != Rout_low) {
sll(Rin_low, Rcount, Rout_low); // low half
}
sll(Rin_high, Rcount, Rout_high);
if (Rcount == Rout_low) {
sll(Rin_low, Rcount, Rout_low); // low half
}
srl(Rxfer_bits, 1, Rxfer_bits ); // shift right by one more
ba(done);
delayed()->or3(Rout_high, Rxfer_bits, Rout_high); // new hi value: or in shifted old hi part and xfer from low
// shift >= 32 bits, Ralt_count = Rcount-32
bind(big_shift);
sll(Rin_low, Ralt_count, Rout_high );
clr(Rout_low);
bind(done);
}
void MacroAssembler::lshr( Register Rin_high, Register Rin_low,
Register Rcount,
Register Rout_high, Register Rout_low,
Register Rtemp ) {
Register Ralt_count = Rtemp;
Register Rxfer_bits = Rtemp;
assert( Ralt_count != Rin_high
&& Ralt_count != Rin_low
&& Ralt_count != Rcount
&& Rxfer_bits != Rin_low
&& Rxfer_bits != Rin_high
&& Rxfer_bits != Rcount
&& Rxfer_bits != Rout_high
&& Rout_high != Rin_low,
"register alias checks");
Label big_shift, done;
// This code can be optimized to use the 64 bit shifts in V9.
// Here we use the 32 bit shifts.
and3( Rcount, 0x3f, Rcount); // take least significant 6 bits
subcc(Rcount, 31, Ralt_count);
br(greater, true, pn, big_shift);
delayed()->dec(Ralt_count);
// shift < 32 bits, Ralt_count = Rcount-31
// We get the transfer bits by shifting left by 32-count the high
// register. This is done by shifting left by 31-count and then by one
// more to take care of the special (rare) case where count is zero
// (shifting by 32 would not work).
neg(Ralt_count);
if (Rcount != Rout_low) {
srl(Rin_low, Rcount, Rout_low);
}
// The order of the next two instructions is critical in the case where
// Rin and Rout are the same and should not be reversed.
sll(Rin_high, Ralt_count, Rxfer_bits); // shift left by 31-count
sra(Rin_high, Rcount, Rout_high ); // high half
sll(Rxfer_bits, 1, Rxfer_bits); // shift left by one more
if (Rcount == Rout_low) {
srl(Rin_low, Rcount, Rout_low);
}
ba(done);
delayed()->or3(Rout_low, Rxfer_bits, Rout_low); // new low value: or shifted old low part and xfer from high
// shift >= 32 bits, Ralt_count = Rcount-32
bind(big_shift);
sra(Rin_high, Ralt_count, Rout_low);
sra(Rin_high, 31, Rout_high); // sign into hi
bind( done );
}
void MacroAssembler::lushr( Register Rin_high, Register Rin_low,
Register Rcount,
Register Rout_high, Register Rout_low,
Register Rtemp ) {
Register Ralt_count = Rtemp;
Register Rxfer_bits = Rtemp;
assert( Ralt_count != Rin_high
&& Ralt_count != Rin_low
&& Ralt_count != Rcount
&& Rxfer_bits != Rin_low
&& Rxfer_bits != Rin_high
&& Rxfer_bits != Rcount
&& Rxfer_bits != Rout_high
&& Rout_high != Rin_low,
"register alias checks");
Label big_shift, done;
// This code can be optimized to use the 64 bit shifts in V9.
// Here we use the 32 bit shifts.
and3( Rcount, 0x3f, Rcount); // take least significant 6 bits
subcc(Rcount, 31, Ralt_count);
br(greater, true, pn, big_shift);
delayed()->dec(Ralt_count);
// shift < 32 bits, Ralt_count = Rcount-31
// We get the transfer bits by shifting left by 32-count the high
// register. This is done by shifting left by 31-count and then by one
// more to take care of the special (rare) case where count is zero
// (shifting by 32 would not work).
neg(Ralt_count);
if (Rcount != Rout_low) {
srl(Rin_low, Rcount, Rout_low);
}
// The order of the next two instructions is critical in the case where
// Rin and Rout are the same and should not be reversed.
sll(Rin_high, Ralt_count, Rxfer_bits); // shift left by 31-count
srl(Rin_high, Rcount, Rout_high ); // high half
sll(Rxfer_bits, 1, Rxfer_bits); // shift left by one more
if (Rcount == Rout_low) {
srl(Rin_low, Rcount, Rout_low);
}
ba(done);
delayed()->or3(Rout_low, Rxfer_bits, Rout_low); // new low value: or shifted old low part and xfer from high
// shift >= 32 bits, Ralt_count = Rcount-32
bind(big_shift);
srl(Rin_high, Ralt_count, Rout_low);
clr(Rout_high);
bind( done );
}
#ifdef _LP64
void MacroAssembler::lcmp( Register Ra, Register Rb, Register Rresult) {
cmp(Ra, Rb);
mov(-1, Rresult);
movcc(equal, false, xcc, 0, Rresult);
movcc(greater, false, xcc, 1, Rresult);
}
#endif
void MacroAssembler::load_sized_value(Address src, Register dst, size_t size_in_bytes, bool is_signed) {
switch (size_in_bytes) {
case 8: ld_long(src, dst); break;
case 4: ld( src, dst); break;
case 2: is_signed ? ldsh(src, dst) : lduh(src, dst); break;
case 1: is_signed ? ldsb(src, dst) : ldub(src, dst); break;
default: ShouldNotReachHere();
}
}
void MacroAssembler::store_sized_value(Register src, Address dst, size_t size_in_bytes) {
switch (size_in_bytes) {
case 8: st_long(src, dst); break;
case 4: st( src, dst); break;
case 2: sth( src, dst); break;
case 1: stb( src, dst); break;
default: ShouldNotReachHere();
}
}
void MacroAssembler::float_cmp( bool is_float, int unordered_result,
FloatRegister Fa, FloatRegister Fb,
Register Rresult) {
if (is_float) {
fcmp(FloatRegisterImpl::S, fcc0, Fa, Fb);
} else {
fcmp(FloatRegisterImpl::D, fcc0, Fa, Fb);
}
if (unordered_result == 1) {
mov( -1, Rresult);
movcc(f_equal, true, fcc0, 0, Rresult);
movcc(f_unorderedOrGreater, true, fcc0, 1, Rresult);
} else {
mov( -1, Rresult);
movcc(f_equal, true, fcc0, 0, Rresult);
movcc(f_greater, true, fcc0, 1, Rresult);
}
}
void MacroAssembler::save_all_globals_into_locals() {
mov(G1,L1);
mov(G2,L2);
mov(G3,L3);
mov(G4,L4);
mov(G5,L5);
mov(G6,L6);
mov(G7,L7);
}
void MacroAssembler::restore_globals_from_locals() {
mov(L1,G1);
mov(L2,G2);
mov(L3,G3);
mov(L4,G4);
mov(L5,G5);
mov(L6,G6);
mov(L7,G7);
}
RegisterOrConstant MacroAssembler::delayed_value_impl(intptr_t* delayed_value_addr,
Register tmp,
int offset) {
intptr_t value = *delayed_value_addr;
if (value != 0)
return RegisterOrConstant(value + offset);
// load indirectly to solve generation ordering problem
AddressLiteral a(delayed_value_addr);
load_ptr_contents(a, tmp);
#ifdef ASSERT
tst(tmp);
breakpoint_trap(zero, xcc);
#endif
if (offset != 0)
add(tmp, offset, tmp);
return RegisterOrConstant(tmp);
}
RegisterOrConstant MacroAssembler::regcon_andn_ptr(RegisterOrConstant s1, RegisterOrConstant s2, RegisterOrConstant d, Register temp) {
assert(d.register_or_noreg() != G0, "lost side effect");
if ((s2.is_constant() && s2.as_constant() == 0) ||
(s2.is_register() && s2.as_register() == G0)) {
// Do nothing, just move value.
if (s1.is_register()) {
if (d.is_constant()) d = temp;
mov(s1.as_register(), d.as_register());
return d;
} else {
return s1;
}
}
if (s1.is_register()) {
assert_different_registers(s1.as_register(), temp);
if (d.is_constant()) d = temp;
andn(s1.as_register(), ensure_simm13_or_reg(s2, temp), d.as_register());
return d;
} else {
if (s2.is_register()) {
assert_different_registers(s2.as_register(), temp);
if (d.is_constant()) d = temp;
set(s1.as_constant(), temp);
andn(temp, s2.as_register(), d.as_register());
return d;
} else {
intptr_t res = s1.as_constant() & ~s2.as_constant();
return res;
}
}
}
RegisterOrConstant MacroAssembler::regcon_inc_ptr(RegisterOrConstant s1, RegisterOrConstant s2, RegisterOrConstant d, Register temp) {
assert(d.register_or_noreg() != G0, "lost side effect");
if ((s2.is_constant() && s2.as_constant() == 0) ||
(s2.is_register() && s2.as_register() == G0)) {
// Do nothing, just move value.
if (s1.is_register()) {
if (d.is_constant()) d = temp;
mov(s1.as_register(), d.as_register());
return d;
} else {
return s1;
}
}
if (s1.is_register()) {
assert_different_registers(s1.as_register(), temp);
if (d.is_constant()) d = temp;
add(s1.as_register(), ensure_simm13_or_reg(s2, temp), d.as_register());
return d;
} else {
if (s2.is_register()) {
assert_different_registers(s2.as_register(), temp);
if (d.is_constant()) d = temp;
add(s2.as_register(), ensure_simm13_or_reg(s1, temp), d.as_register());
return d;
} else {
intptr_t res = s1.as_constant() + s2.as_constant();
return res;
}
}
}
RegisterOrConstant MacroAssembler::regcon_sll_ptr(RegisterOrConstant s1, RegisterOrConstant s2, RegisterOrConstant d, Register temp) {
assert(d.register_or_noreg() != G0, "lost side effect");
if (!is_simm13(s2.constant_or_zero()))
s2 = (s2.as_constant() & 0xFF);
if ((s2.is_constant() && s2.as_constant() == 0) ||
(s2.is_register() && s2.as_register() == G0)) {
// Do nothing, just move value.
if (s1.is_register()) {
if (d.is_constant()) d = temp;
mov(s1.as_register(), d.as_register());
return d;
} else {
return s1;
}
}
if (s1.is_register()) {
assert_different_registers(s1.as_register(), temp);
if (d.is_constant()) d = temp;
sll_ptr(s1.as_register(), ensure_simm13_or_reg(s2, temp), d.as_register());
return d;
} else {
if (s2.is_register()) {
assert_different_registers(s2.as_register(), temp);
if (d.is_constant()) d = temp;
set(s1.as_constant(), temp);
sll_ptr(temp, s2.as_register(), d.as_register());
return d;
} else {
intptr_t res = s1.as_constant() << s2.as_constant();
return res;
}
}
}
// Look up the method for a megamorphic invokeinterface call.
// The target method is determined by <intf_klass, itable_index>.
// The receiver klass is in recv_klass.
// On success, the result will be in method_result, and execution falls through.
// On failure, execution transfers to the given label.
void MacroAssembler::lookup_interface_method(Register recv_klass,
Register intf_klass,
RegisterOrConstant itable_index,
Register method_result,
Register scan_temp,
Register sethi_temp,
Label& L_no_such_interface) {
assert_different_registers(recv_klass, intf_klass, method_result, scan_temp);
assert(itable_index.is_constant() || itable_index.as_register() == method_result,
"caller must use same register for non-constant itable index as for method");
Label L_no_such_interface_restore;
bool did_save = false;
if (scan_temp == noreg || sethi_temp == noreg) {
Register recv_2 = recv_klass->is_global() ? recv_klass : L0;
Register intf_2 = intf_klass->is_global() ? intf_klass : L1;
assert(method_result->is_global(), "must be able to return value");
scan_temp = L2;
sethi_temp = L3;
save_frame_and_mov(0, recv_klass, recv_2, intf_klass, intf_2);
recv_klass = recv_2;
intf_klass = intf_2;
did_save = true;
}
// Compute start of first itableOffsetEntry (which is at the end of the vtable)
int vtable_base = InstanceKlass::vtable_start_offset() * wordSize;
int scan_step = itableOffsetEntry::size() * wordSize;
int vte_size = vtableEntry::size() * wordSize;
lduw(recv_klass, InstanceKlass::vtable_length_offset() * wordSize, scan_temp);
// %%% We should store the aligned, prescaled offset in the klassoop.
// Then the next several instructions would fold away.
int round_to_unit = ((HeapWordsPerLong > 1) ? BytesPerLong : 0);
int itb_offset = vtable_base;
if (round_to_unit != 0) {
// hoist first instruction of round_to(scan_temp, BytesPerLong):
itb_offset += round_to_unit - wordSize;
}
int itb_scale = exact_log2(vtableEntry::size() * wordSize);
sll(scan_temp, itb_scale, scan_temp);
add(scan_temp, itb_offset, scan_temp);
if (round_to_unit != 0) {
// Round up to align_object_offset boundary
// see code for InstanceKlass::start_of_itable!
// Was: round_to(scan_temp, BytesPerLong);
// Hoisted: add(scan_temp, BytesPerLong-1, scan_temp);
and3(scan_temp, -round_to_unit, scan_temp);
}
add(recv_klass, scan_temp, scan_temp);
// Adjust recv_klass by scaled itable_index, so we can free itable_index.
RegisterOrConstant itable_offset = itable_index;
itable_offset = regcon_sll_ptr(itable_index, exact_log2(itableMethodEntry::size() * wordSize), itable_offset);
itable_offset = regcon_inc_ptr(itable_offset, itableMethodEntry::method_offset_in_bytes(), itable_offset);
add(recv_klass, ensure_simm13_or_reg(itable_offset, sethi_temp), recv_klass);
// for (scan = klass->itable(); scan->interface() != NULL; scan += scan_step) {
// if (scan->interface() == intf) {
// result = (klass + scan->offset() + itable_index);
// }
// }
Label L_search, L_found_method;
for (int peel = 1; peel >= 0; peel--) {
// %%%% Could load both offset and interface in one ldx, if they were
// in the opposite order. This would save a load.
ld_ptr(scan_temp, itableOffsetEntry::interface_offset_in_bytes(), method_result);
// Check that this entry is non-null. A null entry means that
// the receiver class doesn't implement the interface, and wasn't the
// same as when the caller was compiled.
bpr(Assembler::rc_z, false, Assembler::pn, method_result, did_save ? L_no_such_interface_restore : L_no_such_interface);
delayed()->cmp(method_result, intf_klass);
if (peel) {
brx(Assembler::equal, false, Assembler::pt, L_found_method);
} else {
brx(Assembler::notEqual, false, Assembler::pn, L_search);
// (invert the test to fall through to found_method...)
}
delayed()->add(scan_temp, scan_step, scan_temp);
if (!peel) break;
bind(L_search);
}
bind(L_found_method);
// Got a hit.
int ito_offset = itableOffsetEntry::offset_offset_in_bytes();
// scan_temp[-scan_step] points to the vtable offset we need
ito_offset -= scan_step;
lduw(scan_temp, ito_offset, scan_temp);
ld_ptr(recv_klass, scan_temp, method_result);
if (did_save) {
Label L_done;
ba(L_done);
delayed()->restore();
bind(L_no_such_interface_restore);
ba(L_no_such_interface);
delayed()->restore();
bind(L_done);
}
}
// virtual method calling
void MacroAssembler::lookup_virtual_method(Register recv_klass,
RegisterOrConstant vtable_index,
Register method_result) {
assert_different_registers(recv_klass, method_result, vtable_index.register_or_noreg());
Register sethi_temp = method_result;
const int base = (InstanceKlass::vtable_start_offset() * wordSize +
// method pointer offset within the vtable entry:
vtableEntry::method_offset_in_bytes());
RegisterOrConstant vtable_offset = vtable_index;
// Each of the following three lines potentially generates an instruction.
// But the total number of address formation instructions will always be
// at most two, and will often be zero. In any case, it will be optimal.
// If vtable_index is a register, we will have (sll_ptr N,x; inc_ptr B,x; ld_ptr k,x).
// If vtable_index is a constant, we will have at most (set B+X<<N,t; ld_ptr k,t).
vtable_offset = regcon_sll_ptr(vtable_index, exact_log2(vtableEntry::size() * wordSize), vtable_offset);
vtable_offset = regcon_inc_ptr(vtable_offset, base, vtable_offset, sethi_temp);
Address vtable_entry_addr(recv_klass, ensure_simm13_or_reg(vtable_offset, sethi_temp));
ld_ptr(vtable_entry_addr, method_result);
}
void MacroAssembler::check_klass_subtype(Register sub_klass,
Register super_klass,
Register temp_reg,
Register temp2_reg,
Label& L_success) {
Register sub_2 = sub_klass;
Register sup_2 = super_klass;
if (!sub_2->is_global()) sub_2 = L0;
if (!sup_2->is_global()) sup_2 = L1;
bool did_save = false;
if (temp_reg == noreg || temp2_reg == noreg) {
temp_reg = L2;
temp2_reg = L3;
save_frame_and_mov(0, sub_klass, sub_2, super_klass, sup_2);
sub_klass = sub_2;
super_klass = sup_2;
did_save = true;
}
Label L_failure, L_pop_to_failure, L_pop_to_success;
check_klass_subtype_fast_path(sub_klass, super_klass,
temp_reg, temp2_reg,
(did_save ? &L_pop_to_success : &L_success),
(did_save ? &L_pop_to_failure : &L_failure), NULL);
if (!did_save)
save_frame_and_mov(0, sub_klass, sub_2, super_klass, sup_2);
check_klass_subtype_slow_path(sub_2, sup_2,
L2, L3, L4, L5,
NULL, &L_pop_to_failure);
// on success:
bind(L_pop_to_success);
restore();
ba_short(L_success);
// on failure:
bind(L_pop_to_failure);
restore();
bind(L_failure);
}
void MacroAssembler::check_klass_subtype_fast_path(Register sub_klass,
Register super_klass,
Register temp_reg,
Register temp2_reg,
Label* L_success,
Label* L_failure,
Label* L_slow_path,
RegisterOrConstant super_check_offset) {
int sc_offset = in_bytes(Klass::secondary_super_cache_offset());
int sco_offset = in_bytes(Klass::super_check_offset_offset());
bool must_load_sco = (super_check_offset.constant_or_zero() == -1);
bool need_slow_path = (must_load_sco ||
super_check_offset.constant_or_zero() == sco_offset);
assert_different_registers(sub_klass, super_klass, temp_reg);
if (super_check_offset.is_register()) {
assert_different_registers(sub_klass, super_klass, temp_reg,
super_check_offset.as_register());
} else if (must_load_sco) {
assert(temp2_reg != noreg, "supply either a temp or a register offset");
}
Label L_fallthrough;
int label_nulls = 0;
if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; }
if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; }
if (L_slow_path == NULL) { L_slow_path = &L_fallthrough; label_nulls++; }
assert(label_nulls <= 1 ||
(L_slow_path == &L_fallthrough && label_nulls <= 2 && !need_slow_path),
"at most one NULL in the batch, usually");
// If the pointers are equal, we are done (e.g., String[] elements).
// This self-check enables sharing of secondary supertype arrays among
// non-primary types such as array-of-interface. Otherwise, each such
// type would need its own customized SSA.
// We move this check to the front of the fast path because many
// type checks are in fact trivially successful in this manner,
// so we get a nicely predicted branch right at the start of the check.
cmp(super_klass, sub_klass);
brx(Assembler::equal, false, Assembler::pn, *L_success);
delayed()->nop();
// Check the supertype display:
if (must_load_sco) {
// The super check offset is always positive...
lduw(super_klass, sco_offset, temp2_reg);
super_check_offset = RegisterOrConstant(temp2_reg);
// super_check_offset is register.
assert_different_registers(sub_klass, super_klass, temp_reg, super_check_offset.as_register());
}
ld_ptr(sub_klass, super_check_offset, temp_reg);
cmp(super_klass, temp_reg);
// This check has worked decisively for primary supers.
// Secondary supers are sought in the super_cache ('super_cache_addr').
// (Secondary supers are interfaces and very deeply nested subtypes.)
// This works in the same check above because of a tricky aliasing
// between the super_cache and the primary super display elements.
// (The 'super_check_addr' can address either, as the case requires.)
// Note that the cache is updated below if it does not help us find
// what we need immediately.
// So if it was a primary super, we can just fail immediately.
// Otherwise, it's the slow path for us (no success at this point).
// Hacked ba(), which may only be used just before L_fallthrough.
#define FINAL_JUMP(label) \
if (&(label) != &L_fallthrough) { \
ba(label); delayed()->nop(); \
}
if (super_check_offset.is_register()) {
brx(Assembler::equal, false, Assembler::pn, *L_success);
delayed()->cmp(super_check_offset.as_register(), sc_offset);
if (L_failure == &L_fallthrough) {
brx(Assembler::equal, false, Assembler::pt, *L_slow_path);
delayed()->nop();
} else {
brx(Assembler::notEqual, false, Assembler::pn, *L_failure);
delayed()->nop();
FINAL_JUMP(*L_slow_path);
}
} else if (super_check_offset.as_constant() == sc_offset) {
// Need a slow path; fast failure is impossible.
if (L_slow_path == &L_fallthrough) {
brx(Assembler::equal, false, Assembler::pt, *L_success);
delayed()->nop();
} else {
brx(Assembler::notEqual, false, Assembler::pn, *L_slow_path);
delayed()->nop();
FINAL_JUMP(*L_success);
}
} else {
// No slow path; it's a fast decision.
if (L_failure == &L_fallthrough) {
brx(Assembler::equal, false, Assembler::pt, *L_success);
delayed()->nop();
} else {
brx(Assembler::notEqual, false, Assembler::pn, *L_failure);
delayed()->nop();
FINAL_JUMP(*L_success);
}
}
bind(L_fallthrough);
#undef FINAL_JUMP
}
void MacroAssembler::check_klass_subtype_slow_path(Register sub_klass,
Register super_klass,
Register count_temp,
Register scan_temp,
Register scratch_reg,
Register coop_reg,
Label* L_success,
Label* L_failure) {
assert_different_registers(sub_klass, super_klass,
count_temp, scan_temp, scratch_reg, coop_reg);
Label L_fallthrough, L_loop;
int label_nulls = 0;
if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; }
if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; }
assert(label_nulls <= 1, "at most one NULL in the batch");
// a couple of useful fields in sub_klass:
int ss_offset = in_bytes(Klass::secondary_supers_offset());
int sc_offset = in_bytes(Klass::secondary_super_cache_offset());
// Do a linear scan of the secondary super-klass chain.
// This code is rarely used, so simplicity is a virtue here.
#ifndef PRODUCT
int* pst_counter = &SharedRuntime::_partial_subtype_ctr;
inc_counter((address) pst_counter, count_temp, scan_temp);
#endif
// We will consult the secondary-super array.
ld_ptr(sub_klass, ss_offset, scan_temp);
Register search_key = super_klass;
// Load the array length. (Positive movl does right thing on LP64.)
lduw(scan_temp, Array<Klass*>::length_offset_in_bytes(), count_temp);
// Check for empty secondary super list
tst(count_temp);
// In the array of super classes elements are pointer sized.
int element_size = wordSize;
// Top of search loop
bind(L_loop);
br(Assembler::equal, false, Assembler::pn, *L_failure);
delayed()->add(scan_temp, element_size, scan_temp);
// Skip the array header in all array accesses.
int elem_offset = Array<Klass*>::base_offset_in_bytes();
elem_offset -= element_size; // the scan pointer was pre-incremented also
// Load next super to check
ld_ptr( scan_temp, elem_offset, scratch_reg );
// Look for Rsuper_klass on Rsub_klass's secondary super-class-overflow list
cmp(scratch_reg, search_key);
// A miss means we are NOT a subtype and need to keep looping
brx(Assembler::notEqual, false, Assembler::pn, L_loop);
delayed()->deccc(count_temp); // decrement trip counter in delay slot
// Success. Cache the super we found and proceed in triumph.
st_ptr(super_klass, sub_klass, sc_offset);
if (L_success != &L_fallthrough) {
ba(*L_success);
delayed()->nop();
}
bind(L_fallthrough);
}
RegisterOrConstant MacroAssembler::argument_offset(RegisterOrConstant arg_slot,
Register temp_reg,
int extra_slot_offset) {
// cf. TemplateTable::prepare_invoke(), if (load_receiver).
int stackElementSize = Interpreter::stackElementSize;
int offset = extra_slot_offset * stackElementSize;
if (arg_slot.is_constant()) {
offset += arg_slot.as_constant() * stackElementSize;
return offset;
} else {
assert(temp_reg != noreg, "must specify");
sll_ptr(arg_slot.as_register(), exact_log2(stackElementSize), temp_reg);
if (offset != 0)
add(temp_reg, offset, temp_reg);
return temp_reg;
}
}
Address MacroAssembler::argument_address(RegisterOrConstant arg_slot,
Register temp_reg,
int extra_slot_offset) {
return Address(Gargs, argument_offset(arg_slot, temp_reg, extra_slot_offset));
}
void MacroAssembler::biased_locking_enter(Register obj_reg, Register mark_reg,
Register temp_reg,
Label& done, Label* slow_case,
BiasedLockingCounters* counters) {
assert(UseBiasedLocking, "why call this otherwise?");
if (PrintBiasedLockingStatistics) {
assert_different_registers(obj_reg, mark_reg, temp_reg, O7);
if (counters == NULL)
counters = BiasedLocking::counters();
}
Label cas_label;
// Biased locking
// See whether the lock is currently biased toward our thread and
// whether the epoch is still valid
// Note that the runtime guarantees sufficient alignment of JavaThread
// pointers to allow age to be placed into low bits
assert(markOopDesc::age_shift == markOopDesc::lock_bits + markOopDesc::biased_lock_bits, "biased locking makes assumptions about bit layout");
and3(mark_reg, markOopDesc::biased_lock_mask_in_place, temp_reg);
cmp_and_brx_short(temp_reg, markOopDesc::biased_lock_pattern, Assembler::notEqual, Assembler::pn, cas_label);
load_klass(obj_reg, temp_reg);
ld_ptr(Address(temp_reg, Klass::prototype_header_offset()), temp_reg);
or3(G2_thread, temp_reg, temp_reg);
xor3(mark_reg, temp_reg, temp_reg);
andcc(temp_reg, ~((int) markOopDesc::age_mask_in_place), temp_reg);
if (counters != NULL) {
cond_inc(Assembler::equal, (address) counters->biased_lock_entry_count_addr(), mark_reg, temp_reg);
// Reload mark_reg as we may need it later
ld_ptr(Address(obj_reg, oopDesc::mark_offset_in_bytes()), mark_reg);
}
brx(Assembler::equal, true, Assembler::pt, done);
delayed()->nop();
Label try_revoke_bias;
Label try_rebias;
Address mark_addr = Address(obj_reg, oopDesc::mark_offset_in_bytes());
assert(mark_addr.disp() == 0, "cas must take a zero displacement");
// At this point we know that the header has the bias pattern and
// that we are not the bias owner in the current epoch. We need to
// figure out more details about the state of the header in order to
// know what operations can be legally performed on the object's
// header.
// If the low three bits in the xor result aren't clear, that means
// the prototype header is no longer biased and we have to revoke
// the bias on this object.
btst(markOopDesc::biased_lock_mask_in_place, temp_reg);
brx(Assembler::notZero, false, Assembler::pn, try_revoke_bias);
// Biasing is still enabled for this data type. See whether the
// epoch of the current bias is still valid, meaning that the epoch
// bits of the mark word are equal to the epoch bits of the
// prototype header. (Note that the prototype header's epoch bits
// only change at a safepoint.) If not, attempt to rebias the object
// toward the current thread. Note that we must be absolutely sure
// that the current epoch is invalid in order to do this because
// otherwise the manipulations it performs on the mark word are
// illegal.
delayed()->btst(markOopDesc::epoch_mask_in_place, temp_reg);
brx(Assembler::notZero, false, Assembler::pn, try_rebias);
// The epoch of the current bias is still valid but we know nothing
// about the owner; it might be set or it might be clear. Try to
// acquire the bias of the object using an atomic operation. If this
// fails we will go in to the runtime to revoke the object's bias.
// Note that we first construct the presumed unbiased header so we
// don't accidentally blow away another thread's valid bias.
delayed()->and3(mark_reg,
markOopDesc::biased_lock_mask_in_place | markOopDesc::age_mask_in_place | markOopDesc::epoch_mask_in_place,
mark_reg);
or3(G2_thread, mark_reg, temp_reg);
cas_ptr(mark_addr.base(), mark_reg, temp_reg);
// If the biasing toward our thread failed, this means that
// another thread succeeded in biasing it toward itself and we
// need to revoke that bias. The revocation will occur in the
// interpreter runtime in the slow case.
cmp(mark_reg, temp_reg);
if (counters != NULL) {
cond_inc(Assembler::zero, (address) counters->anonymously_biased_lock_entry_count_addr(), mark_reg, temp_reg);
}
if (slow_case != NULL) {
brx(Assembler::notEqual, true, Assembler::pn, *slow_case);
delayed()->nop();
}
ba_short(done);
bind(try_rebias);
// At this point we know the epoch has expired, meaning that the
// current "bias owner", if any, is actually invalid. Under these
// circumstances _only_, we are allowed to use the current header's
// value as the comparison value when doing the cas to acquire the
// bias in the current epoch. In other words, we allow transfer of
// the bias from one thread to another directly in this situation.
//
// FIXME: due to a lack of registers we currently blow away the age
// bits in this situation. Should attempt to preserve them.
load_klass(obj_reg, temp_reg);
ld_ptr(Address(temp_reg, Klass::prototype_header_offset()), temp_reg);
or3(G2_thread, temp_reg, temp_reg);
cas_ptr(mark_addr.base(), mark_reg, temp_reg);
// If the biasing toward our thread failed, this means that
// another thread succeeded in biasing it toward itself and we
// need to revoke that bias. The revocation will occur in the
// interpreter runtime in the slow case.
cmp(mark_reg, temp_reg);
if (counters != NULL) {
cond_inc(Assembler::zero, (address) counters->rebiased_lock_entry_count_addr(), mark_reg, temp_reg);
}
if (slow_case != NULL) {
brx(Assembler::notEqual, true, Assembler::pn, *slow_case);
delayed()->nop();
}
ba_short(done);
bind(try_revoke_bias);
// The prototype mark in the klass doesn't have the bias bit set any
// more, indicating that objects of this data type are not supposed
// to be biased any more. We are going to try to reset the mark of
// this object to the prototype value and fall through to the
// CAS-based locking scheme. Note that if our CAS fails, it means
// that another thread raced us for the privilege of revoking the
// bias of this particular object, so it's okay to continue in the
// normal locking code.
//
// FIXME: due to a lack of registers we currently blow away the age
// bits in this situation. Should attempt to preserve them.
load_klass(obj_reg, temp_reg);
ld_ptr(Address(temp_reg, Klass::prototype_header_offset()), temp_reg);
cas_ptr(mark_addr.base(), mark_reg, temp_reg);
// Fall through to the normal CAS-based lock, because no matter what
// the result of the above CAS, some thread must have succeeded in
// removing the bias bit from the object's header.
if (counters != NULL) {
cmp(mark_reg, temp_reg);
cond_inc(Assembler::zero, (address) counters->revoked_lock_entry_count_addr(), mark_reg, temp_reg);
}
bind(cas_label);
}
void MacroAssembler::biased_locking_exit (Address mark_addr, Register temp_reg, Label& done,
bool allow_delay_slot_filling) {
// Check for biased locking unlock case, which is a no-op
// Note: we do not have to check the thread ID for two reasons.
// First, the interpreter checks for IllegalMonitorStateException at
// a higher level. Second, if the bias was revoked while we held the
// lock, the object could not be rebiased toward another thread, so
// the bias bit would be clear.
ld_ptr(mark_addr, temp_reg);
and3(temp_reg, markOopDesc::biased_lock_mask_in_place, temp_reg);
cmp(temp_reg, markOopDesc::biased_lock_pattern);
brx(Assembler::equal, allow_delay_slot_filling, Assembler::pt, done);
delayed();
if (!allow_delay_slot_filling) {
nop();
}
}
// compiler_lock_object() and compiler_unlock_object() are direct transliterations
// of i486.ad fast_lock() and fast_unlock(). See those methods for detailed comments.
// The code could be tightened up considerably.
//
// box->dhw disposition - post-conditions at DONE_LABEL.
// - Successful inflated lock: box->dhw != 0.
// Any non-zero value suffices.
// Consider G2_thread, rsp, boxReg, or unused_mark()
// - Successful Stack-lock: box->dhw == mark.
// box->dhw must contain the displaced mark word value
// - Failure -- icc.ZFlag == 0 and box->dhw is undefined.
// The slow-path fast_enter() and slow_enter() operators
// are responsible for setting box->dhw = NonZero (typically ::unused_mark).
// - Biased: box->dhw is undefined
//
// SPARC refworkload performance - specifically jetstream and scimark - are
// extremely sensitive to the size of the code emitted by compiler_lock_object
// and compiler_unlock_object. Critically, the key factor is code size, not path
// length. (Simply experiments to pad CLO with unexecuted NOPs demonstrte the
// effect).
void MacroAssembler::compiler_lock_object(Register Roop, Register Rmark,
Register Rbox, Register Rscratch,
BiasedLockingCounters* counters,
bool try_bias) {
Address mark_addr(Roop, oopDesc::mark_offset_in_bytes());
verify_oop(Roop);
Label done ;
if (counters != NULL) {
inc_counter((address) counters->total_entry_count_addr(), Rmark, Rscratch);
}
if (EmitSync & 1) {
mov(3, Rscratch);
st_ptr(Rscratch, Rbox, BasicLock::displaced_header_offset_in_bytes());
cmp(SP, G0);
return ;
}
if (EmitSync & 2) {
// Fetch object's markword
ld_ptr(mark_addr, Rmark);
if (try_bias) {
biased_locking_enter(Roop, Rmark, Rscratch, done, NULL, counters);
}
// Save Rbox in Rscratch to be used for the cas operation
mov(Rbox, Rscratch);
// set Rmark to markOop | markOopDesc::unlocked_value
or3(Rmark, markOopDesc::unlocked_value, Rmark);
// Initialize the box. (Must happen before we update the object mark!)
st_ptr(Rmark, Rbox, BasicLock::displaced_header_offset_in_bytes());
// compare object markOop with Rmark and if equal exchange Rscratch with object markOop
assert(mark_addr.disp() == 0, "cas must take a zero displacement");
cas_ptr(mark_addr.base(), Rmark, Rscratch);
// if compare/exchange succeeded we found an unlocked object and we now have locked it
// hence we are done
cmp(Rmark, Rscratch);
#ifdef _LP64
sub(Rscratch, STACK_BIAS, Rscratch);
#endif
brx(Assembler::equal, false, Assembler::pt, done);
delayed()->sub(Rscratch, SP, Rscratch); //pull next instruction into delay slot
// we did not find an unlocked object so see if this is a recursive case
// sub(Rscratch, SP, Rscratch);
assert(os::vm_page_size() > 0xfff, "page size too small - change the constant");
andcc(Rscratch, 0xfffff003, Rscratch);
st_ptr(Rscratch, Rbox, BasicLock::displaced_header_offset_in_bytes());
bind (done);
return ;
}
Label Egress ;
if (EmitSync & 256) {
Label IsInflated ;
ld_ptr(mark_addr, Rmark); // fetch obj->mark
// Triage: biased, stack-locked, neutral, inflated
if (try_bias) {
biased_locking_enter(Roop, Rmark, Rscratch, done, NULL, counters);
// Invariant: if control reaches this point in the emitted stream
// then Rmark has not been modified.
}
// Store mark into displaced mark field in the on-stack basic-lock "box"
// Critically, this must happen before the CAS
// Maximize the ST-CAS distance to minimize the ST-before-CAS penalty.
st_ptr(Rmark, Rbox, BasicLock::displaced_header_offset_in_bytes());
andcc(Rmark, 2, G0);
brx(Assembler::notZero, false, Assembler::pn, IsInflated);
delayed()->
// Try stack-lock acquisition.
// Beware: the 1st instruction is in a delay slot
mov(Rbox, Rscratch);
or3(Rmark, markOopDesc::unlocked_value, Rmark);
assert(mark_addr.disp() == 0, "cas must take a zero displacement");
cas_ptr(mark_addr.base(), Rmark, Rscratch);
cmp(Rmark, Rscratch);
brx(Assembler::equal, false, Assembler::pt, done);
delayed()->sub(Rscratch, SP, Rscratch);
// Stack-lock attempt failed - check for recursive stack-lock.
// See the comments below about how we might remove this case.
#ifdef _LP64
sub(Rscratch, STACK_BIAS, Rscratch);
#endif
assert(os::vm_page_size() > 0xfff, "page size too small - change the constant");
andcc(Rscratch, 0xfffff003, Rscratch);
br(Assembler::always, false, Assembler::pt, done);
delayed()-> st_ptr(Rscratch, Rbox, BasicLock::displaced_header_offset_in_bytes());
bind(IsInflated);
if (EmitSync & 64) {
// If m->owner != null goto IsLocked
// Pessimistic form: Test-and-CAS vs CAS
// The optimistic form avoids RTS->RTO cache line upgrades.
ld_ptr(Rmark, ObjectMonitor::owner_offset_in_bytes() - 2, Rscratch);
andcc(Rscratch, Rscratch, G0);
brx(Assembler::notZero, false, Assembler::pn, done);
delayed()->nop();
// m->owner == null : it's unlocked.
}
// Try to CAS m->owner from null to Self
// Invariant: if we acquire the lock then _recursions should be 0.
add(Rmark, ObjectMonitor::owner_offset_in_bytes()-2, Rmark);
mov(G2_thread, Rscratch);
cas_ptr(Rmark, G0, Rscratch);
cmp(Rscratch, G0);
// Intentional fall-through into done
} else {
// Aggressively avoid the Store-before-CAS penalty
// Defer the store into box->dhw until after the CAS
Label IsInflated, Recursive ;
// Anticipate CAS -- Avoid RTS->RTO upgrade
// prefetch (mark_addr, Assembler::severalWritesAndPossiblyReads);
ld_ptr(mark_addr, Rmark); // fetch obj->mark
// Triage: biased, stack-locked, neutral, inflated
if (try_bias) {
biased_locking_enter(Roop, Rmark, Rscratch, done, NULL, counters);
// Invariant: if control reaches this point in the emitted stream
// then Rmark has not been modified.
}
andcc(Rmark, 2, G0);
brx(Assembler::notZero, false, Assembler::pn, IsInflated);
delayed()-> // Beware - dangling delay-slot
// Try stack-lock acquisition.
// Transiently install BUSY (0) encoding in the mark word.
// if the CAS of 0 into the mark was successful then we execute:
// ST box->dhw = mark -- save fetched mark in on-stack basiclock box
// ST obj->mark = box -- overwrite transient 0 value
// This presumes TSO, of course.
mov(0, Rscratch);
or3(Rmark, markOopDesc::unlocked_value, Rmark);
assert(mark_addr.disp() == 0, "cas must take a zero displacement");
cas_ptr(mark_addr.base(), Rmark, Rscratch);
// prefetch (mark_addr, Assembler::severalWritesAndPossiblyReads);
cmp(Rscratch, Rmark);
brx(Assembler::notZero, false, Assembler::pn, Recursive);
delayed()->st_ptr(Rmark, Rbox, BasicLock::displaced_header_offset_in_bytes());
if (counters != NULL) {
cond_inc(Assembler::equal, (address) counters->fast_path_entry_count_addr(), Rmark, Rscratch);
}
ba(done);
delayed()->st_ptr(Rbox, mark_addr);
bind(Recursive);
// Stack-lock attempt failed - check for recursive stack-lock.
// Tests show that we can remove the recursive case with no impact
// on refworkload 0.83. If we need to reduce the size of the code
// emitted by compiler_lock_object() the recursive case is perfect
// candidate.
//
// A more extreme idea is to always inflate on stack-lock recursion.
// This lets us eliminate the recursive checks in compiler_lock_object
// and compiler_unlock_object and the (box->dhw == 0) encoding.
// A brief experiment - requiring changes to synchronizer.cpp, interpreter,
// and showed a performance *increase*. In the same experiment I eliminated
// the fast-path stack-lock code from the interpreter and always passed
// control to the "slow" operators in synchronizer.cpp.
// RScratch contains the fetched obj->mark value from the failed CAS.
#ifdef _LP64
sub(Rscratch, STACK_BIAS, Rscratch);
#endif
sub(Rscratch, SP, Rscratch);
assert(os::vm_page_size() > 0xfff, "page size too small - change the constant");
andcc(Rscratch, 0xfffff003, Rscratch);
if (counters != NULL) {
// Accounting needs the Rscratch register
st_ptr(Rscratch, Rbox, BasicLock::displaced_header_offset_in_bytes());
cond_inc(Assembler::equal, (address) counters->fast_path_entry_count_addr(), Rmark, Rscratch);
ba_short(done);
} else {
ba(done);
delayed()->st_ptr(Rscratch, Rbox, BasicLock::displaced_header_offset_in_bytes());
}
bind (IsInflated);
if (EmitSync & 64) {
// If m->owner != null goto IsLocked
// Test-and-CAS vs CAS
// Pessimistic form avoids futile (doomed) CAS attempts
// The optimistic form avoids RTS->RTO cache line upgrades.
ld_ptr(Rmark, ObjectMonitor::owner_offset_in_bytes() - 2, Rscratch);
andcc(Rscratch, Rscratch, G0);
brx(Assembler::notZero, false, Assembler::pn, done);
delayed()->nop();
// m->owner == null : it's unlocked.
}
// Try to CAS m->owner from null to Self
// Invariant: if we acquire the lock then _recursions should be 0.
add(Rmark, ObjectMonitor::owner_offset_in_bytes()-2, Rmark);
mov(G2_thread, Rscratch);
cas_ptr(Rmark, G0, Rscratch);
cmp(Rscratch, G0);
// ST box->displaced_header = NonZero.
// Any non-zero value suffices:
// unused_mark(), G2_thread, RBox, RScratch, rsp, etc.
st_ptr(Rbox, Rbox, BasicLock::displaced_header_offset_in_bytes());
// Intentional fall-through into done
}
bind (done);
}
void MacroAssembler::compiler_unlock_object(Register Roop, Register Rmark,
Register Rbox, Register Rscratch,
bool try_bias) {
Address mark_addr(Roop, oopDesc::mark_offset_in_bytes());
Label done ;
if (EmitSync & 4) {
cmp(SP, G0);
return ;
}
if (EmitSync & 8) {
if (try_bias) {
biased_locking_exit(mark_addr, Rscratch, done);
}
// Test first if it is a fast recursive unlock
ld_ptr(Rbox, BasicLock::displaced_header_offset_in_bytes(), Rmark);
br_null_short(Rmark, Assembler::pt, done);
// Check if it is still a light weight lock, this is is true if we see
// the stack address of the basicLock in the markOop of the object
assert(mark_addr.disp() == 0, "cas must take a zero displacement");
cas_ptr(mark_addr.base(), Rbox, Rmark);
ba(done);
delayed()->cmp(Rbox, Rmark);
bind(done);
return ;
}
// Beware ... If the aggregate size of the code emitted by CLO and CUO is
// is too large performance rolls abruptly off a cliff.
// This could be related to inlining policies, code cache management, or
// I$ effects.
Label LStacked ;
if (try_bias) {
// TODO: eliminate redundant LDs of obj->mark
biased_locking_exit(mark_addr, Rscratch, done);
}
ld_ptr(Roop, oopDesc::mark_offset_in_bytes(), Rmark);
ld_ptr(Rbox, BasicLock::displaced_header_offset_in_bytes(), Rscratch);
andcc(Rscratch, Rscratch, G0);
brx(Assembler::zero, false, Assembler::pn, done);
delayed()->nop(); // consider: relocate fetch of mark, above, into this DS
andcc(Rmark, 2, G0);
brx(Assembler::zero, false, Assembler::pt, LStacked);
delayed()->nop();
// It's inflated
// Conceptually we need a #loadstore|#storestore "release" MEMBAR before
// the ST of 0 into _owner which releases the lock. This prevents loads
// and stores within the critical section from reordering (floating)
// past the store that releases the lock. But TSO is a strong memory model
// and that particular flavor of barrier is a noop, so we can safely elide it.
// Note that we use 1-0 locking by default for the inflated case. We
// close the resultant (and rare) race by having contented threads in
// monitorenter periodically poll _owner.
ld_ptr(Rmark, ObjectMonitor::owner_offset_in_bytes() - 2, Rscratch);
ld_ptr(Rmark, ObjectMonitor::recursions_offset_in_bytes() - 2, Rbox);
xor3(Rscratch, G2_thread, Rscratch);
orcc(Rbox, Rscratch, Rbox);
brx(Assembler::notZero, false, Assembler::pn, done);
delayed()->
ld_ptr(Rmark, ObjectMonitor::EntryList_offset_in_bytes() - 2, Rscratch);
ld_ptr(Rmark, ObjectMonitor::cxq_offset_in_bytes() - 2, Rbox);
orcc(Rbox, Rscratch, G0);
if (EmitSync & 65536) {
Label LSucc ;
brx(Assembler::notZero, false, Assembler::pn, LSucc);
delayed()->nop();
ba(done);
delayed()->st_ptr(G0, Rmark, ObjectMonitor::owner_offset_in_bytes() - 2);
bind(LSucc);
st_ptr(G0, Rmark, ObjectMonitor::owner_offset_in_bytes() - 2);
if (os::is_MP()) { membar (StoreLoad); }
ld_ptr(Rmark, ObjectMonitor::succ_offset_in_bytes() - 2, Rscratch);
andcc(Rscratch, Rscratch, G0);
brx(Assembler::notZero, false, Assembler::pt, done);
delayed()->andcc(G0, G0, G0);
add(Rmark, ObjectMonitor::owner_offset_in_bytes()-2, Rmark);
mov(G2_thread, Rscratch);
cas_ptr(Rmark, G0, Rscratch);
// invert icc.zf and goto done
br_notnull(Rscratch, false, Assembler::pt, done);
delayed()->cmp(G0, G0);
ba(done);
delayed()->cmp(G0, 1);
} else {
brx(Assembler::notZero, false, Assembler::pn, done);
delayed()->nop();
ba(done);
delayed()->st_ptr(G0, Rmark, ObjectMonitor::owner_offset_in_bytes() - 2);
}
bind (LStacked);
// Consider: we could replace the expensive CAS in the exit
// path with a simple ST of the displaced mark value fetched from
// the on-stack basiclock box. That admits a race where a thread T2
// in the slow lock path -- inflating with monitor M -- could race a
// thread T1 in the fast unlock path, resulting in a missed wakeup for T2.
// More precisely T1 in the stack-lock unlock path could "stomp" the
// inflated mark value M installed by T2, resulting in an orphan
// object monitor M and T2 becoming stranded. We can remedy that situation
// by having T2 periodically poll the object's mark word using timed wait
// operations. If T2 discovers that a stomp has occurred it vacates
// the monitor M and wakes any other threads stranded on the now-orphan M.
// In addition the monitor scavenger, which performs deflation,
// would also need to check for orpan monitors and stranded threads.
//
// Finally, inflation is also used when T2 needs to assign a hashCode
// to O and O is stack-locked by T1. The "stomp" race could cause
// an assigned hashCode value to be lost. We can avoid that condition
// and provide the necessary hashCode stability invariants by ensuring
// that hashCode generation is idempotent between copying GCs.
// For example we could compute the hashCode of an object O as
// O's heap address XOR some high quality RNG value that is refreshed
// at GC-time. The monitor scavenger would install the hashCode
// found in any orphan monitors. Again, the mechanism admits a
// lost-update "stomp" WAW race but detects and recovers as needed.
//
// A prototype implementation showed excellent results, although
// the scavenger and timeout code was rather involved.
cas_ptr(mark_addr.base(), Rbox, Rscratch);
cmp(Rbox, Rscratch);
// Intentional fall through into done ...
bind(done);
}
void MacroAssembler::print_CPU_state() {
// %%%%% need to implement this
}
void MacroAssembler::verify_FPU(int stack_depth, const char* s) {
// %%%%% need to implement this
}
void MacroAssembler::push_IU_state() {
// %%%%% need to implement this
}
void MacroAssembler::pop_IU_state() {
// %%%%% need to implement this
}
void MacroAssembler::push_FPU_state() {
// %%%%% need to implement this
}
void MacroAssembler::pop_FPU_state() {
// %%%%% need to implement this
}
void MacroAssembler::push_CPU_state() {
// %%%%% need to implement this
}
void MacroAssembler::pop_CPU_state() {
// %%%%% need to implement this
}
void MacroAssembler::verify_tlab() {
#ifdef ASSERT
if (UseTLAB && VerifyOops) {
Label next, next2, ok;
Register t1 = L0;
Register t2 = L1;
Register t3 = L2;
save_frame(0);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_top_offset()), t1);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_start_offset()), t2);
or3(t1, t2, t3);
cmp_and_br_short(t1, t2, Assembler::greaterEqual, Assembler::pn, next);
STOP("assert(top >= start)");
should_not_reach_here();
bind(next);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_top_offset()), t1);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_end_offset()), t2);
or3(t3, t2, t3);
cmp_and_br_short(t1, t2, Assembler::lessEqual, Assembler::pn, next2);
STOP("assert(top <= end)");
should_not_reach_here();
bind(next2);
and3(t3, MinObjAlignmentInBytesMask, t3);
cmp_and_br_short(t3, 0, Assembler::lessEqual, Assembler::pn, ok);
STOP("assert(aligned)");
should_not_reach_here();
bind(ok);
restore();
}
#endif
}
void MacroAssembler::eden_allocate(
Register obj, // result: pointer to object after successful allocation
Register var_size_in_bytes, // object size in bytes if unknown at compile time; invalid otherwise
int con_size_in_bytes, // object size in bytes if known at compile time
Register t1, // temp register
Register t2, // temp register
Label& slow_case // continuation point if fast allocation fails
){
// make sure arguments make sense
assert_different_registers(obj, var_size_in_bytes, t1, t2);
assert(0 <= con_size_in_bytes && Assembler::is_simm13(con_size_in_bytes), "illegal object size");
assert((con_size_in_bytes & MinObjAlignmentInBytesMask) == 0, "object size is not multiple of alignment");
if (CMSIncrementalMode || !Universe::heap()->supports_inline_contig_alloc()) {
// No allocation in the shared eden.
ba(slow_case);
delayed()->nop();
} else {
// get eden boundaries
// note: we need both top & top_addr!
const Register top_addr = t1;
const Register end = t2;
CollectedHeap* ch = Universe::heap();
set((intx)ch->top_addr(), top_addr);
intx delta = (intx)ch->end_addr() - (intx)ch->top_addr();
ld_ptr(top_addr, delta, end);
ld_ptr(top_addr, 0, obj);
// try to allocate
Label retry;
bind(retry);
#ifdef ASSERT
// make sure eden top is properly aligned
{
Label L;
btst(MinObjAlignmentInBytesMask, obj);
br(Assembler::zero, false, Assembler::pt, L);
delayed()->nop();
STOP("eden top is not properly aligned");
bind(L);
}
#endif // ASSERT
const Register free = end;
sub(end, obj, free); // compute amount of free space
if (var_size_in_bytes->is_valid()) {
// size is unknown at compile time
cmp(free, var_size_in_bytes);
br(Assembler::lessUnsigned, false, Assembler::pn, slow_case); // if there is not enough space go the slow case
delayed()->add(obj, var_size_in_bytes, end);
} else {
// size is known at compile time
cmp(free, con_size_in_bytes);
br(Assembler::lessUnsigned, false, Assembler::pn, slow_case); // if there is not enough space go the slow case
delayed()->add(obj, con_size_in_bytes, end);
}
// Compare obj with the value at top_addr; if still equal, swap the value of
// end with the value at top_addr. If not equal, read the value at top_addr
// into end.
cas_ptr(top_addr, obj, end);
// if someone beat us on the allocation, try again, otherwise continue
cmp(obj, end);
brx(Assembler::notEqual, false, Assembler::pn, retry);
delayed()->mov(end, obj); // nop if successfull since obj == end
#ifdef ASSERT
// make sure eden top is properly aligned
{
Label L;
const Register top_addr = t1;
set((intx)ch->top_addr(), top_addr);
ld_ptr(top_addr, 0, top_addr);
btst(MinObjAlignmentInBytesMask, top_addr);
br(Assembler::zero, false, Assembler::pt, L);
delayed()->nop();
STOP("eden top is not properly aligned");
bind(L);
}
#endif // ASSERT
}
}
void MacroAssembler::tlab_allocate(
Register obj, // result: pointer to object after successful allocation
Register var_size_in_bytes, // object size in bytes if unknown at compile time; invalid otherwise
int con_size_in_bytes, // object size in bytes if known at compile time
Register t1, // temp register
Label& slow_case // continuation point if fast allocation fails
){
// make sure arguments make sense
assert_different_registers(obj, var_size_in_bytes, t1);
assert(0 <= con_size_in_bytes && is_simm13(con_size_in_bytes), "illegal object size");
assert((con_size_in_bytes & MinObjAlignmentInBytesMask) == 0, "object size is not multiple of alignment");
const Register free = t1;
verify_tlab();
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_top_offset()), obj);
// calculate amount of free space
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_end_offset()), free);
sub(free, obj, free);
Label done;
if (var_size_in_bytes == noreg) {
cmp(free, con_size_in_bytes);
} else {
cmp(free, var_size_in_bytes);
}
br(Assembler::less, false, Assembler::pn, slow_case);
// calculate the new top pointer
if (var_size_in_bytes == noreg) {
delayed()->add(obj, con_size_in_bytes, free);
} else {
delayed()->add(obj, var_size_in_bytes, free);
}
bind(done);
#ifdef ASSERT
// make sure new free pointer is properly aligned
{
Label L;
btst(MinObjAlignmentInBytesMask, free);
br(Assembler::zero, false, Assembler::pt, L);
delayed()->nop();
STOP("updated TLAB free is not properly aligned");
bind(L);
}
#endif // ASSERT
// update the tlab top pointer
st_ptr(free, G2_thread, in_bytes(JavaThread::tlab_top_offset()));
verify_tlab();
}
void MacroAssembler::tlab_refill(Label& retry, Label& try_eden, Label& slow_case) {
Register top = O0;
Register t1 = G1;
Register t2 = G3;
Register t3 = O1;
assert_different_registers(top, t1, t2, t3, G4, G5 /* preserve G4 and G5 */);
Label do_refill, discard_tlab;
if (CMSIncrementalMode || !Universe::heap()->supports_inline_contig_alloc()) {
// No allocation in the shared eden.
ba(slow_case);
delayed()->nop();
}
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_top_offset()), top);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_end_offset()), t1);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_refill_waste_limit_offset()), t2);
// calculate amount of free space
sub(t1, top, t1);
srl_ptr(t1, LogHeapWordSize, t1);
// Retain tlab and allocate object in shared space if
// the amount free in the tlab is too large to discard.
cmp(t1, t2);
brx(Assembler::lessEqual, false, Assembler::pt, discard_tlab);
// increment waste limit to prevent getting stuck on this slow path
delayed()->add(t2, ThreadLocalAllocBuffer::refill_waste_limit_increment(), t2);
st_ptr(t2, G2_thread, in_bytes(JavaThread::tlab_refill_waste_limit_offset()));
if (TLABStats) {
// increment number of slow_allocations
ld(G2_thread, in_bytes(JavaThread::tlab_slow_allocations_offset()), t2);
add(t2, 1, t2);
stw(t2, G2_thread, in_bytes(JavaThread::tlab_slow_allocations_offset()));
}
ba(try_eden);
delayed()->nop();
bind(discard_tlab);
if (TLABStats) {
// increment number of refills
ld(G2_thread, in_bytes(JavaThread::tlab_number_of_refills_offset()), t2);
add(t2, 1, t2);
stw(t2, G2_thread, in_bytes(JavaThread::tlab_number_of_refills_offset()));
// accumulate wastage
ld(G2_thread, in_bytes(JavaThread::tlab_fast_refill_waste_offset()), t2);
add(t2, t1, t2);
stw(t2, G2_thread, in_bytes(JavaThread::tlab_fast_refill_waste_offset()));
}
// if tlab is currently allocated (top or end != null) then
// fill [top, end + alignment_reserve) with array object
br_null_short(top, Assembler::pn, do_refill);
set((intptr_t)markOopDesc::prototype()->copy_set_hash(0x2), t2);
st_ptr(t2, top, oopDesc::mark_offset_in_bytes()); // set up the mark word
// set klass to intArrayKlass
sub(t1, typeArrayOopDesc::header_size(T_INT), t1);
add(t1, ThreadLocalAllocBuffer::alignment_reserve(), t1);
sll_ptr(t1, log2_intptr(HeapWordSize/sizeof(jint)), t1);
st(t1, top, arrayOopDesc::length_offset_in_bytes());
set((intptr_t)Universe::intArrayKlassObj_addr(), t2);
ld_ptr(t2, 0, t2);
// store klass last. concurrent gcs assumes klass length is valid if
// klass field is not null.
store_klass(t2, top);
verify_oop(top);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_start_offset()), t1);
sub(top, t1, t1); // size of tlab's allocated portion
incr_allocated_bytes(t1, t2, t3);
// refill the tlab with an eden allocation
bind(do_refill);
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_size_offset()), t1);
sll_ptr(t1, LogHeapWordSize, t1);
// allocate new tlab, address returned in top
eden_allocate(top, t1, 0, t2, t3, slow_case);
st_ptr(top, G2_thread, in_bytes(JavaThread::tlab_start_offset()));
st_ptr(top, G2_thread, in_bytes(JavaThread::tlab_top_offset()));
#ifdef ASSERT
// check that tlab_size (t1) is still valid
{
Label ok;
ld_ptr(G2_thread, in_bytes(JavaThread::tlab_size_offset()), t2);
sll_ptr(t2, LogHeapWordSize, t2);
cmp_and_br_short(t1, t2, Assembler::equal, Assembler::pt, ok);
STOP("assert(t1 == tlab_size)");
should_not_reach_here();
bind(ok);
}
#endif // ASSERT
add(top, t1, top); // t1 is tlab_size
sub(top, ThreadLocalAllocBuffer::alignment_reserve_in_bytes(), top);
st_ptr(top, G2_thread, in_bytes(JavaThread::tlab_end_offset()));
verify_tlab();
ba(retry);
delayed()->nop();
}
void MacroAssembler::incr_allocated_bytes(RegisterOrConstant size_in_bytes,
Register t1, Register t2) {
// Bump total bytes allocated by this thread
assert(t1->is_global(), "must be global reg"); // so all 64 bits are saved on a context switch
assert_different_registers(size_in_bytes.register_or_noreg(), t1, t2);
// v8 support has gone the way of the dodo
ldx(G2_thread, in_bytes(JavaThread::allocated_bytes_offset()), t1);
add(t1, ensure_simm13_or_reg(size_in_bytes, t2), t1);
stx(t1, G2_thread, in_bytes(JavaThread::allocated_bytes_offset()));
}
Assembler::Condition MacroAssembler::negate_condition(Assembler::Condition cond) {
switch (cond) {
// Note some conditions are synonyms for others
case Assembler::never: return Assembler::always;
case Assembler::zero: return Assembler::notZero;
case Assembler::lessEqual: return Assembler::greater;
case Assembler::less: return Assembler::greaterEqual;
case Assembler::lessEqualUnsigned: return Assembler::greaterUnsigned;
case Assembler::lessUnsigned: return Assembler::greaterEqualUnsigned;
case Assembler::negative: return Assembler::positive;
case Assembler::overflowSet: return Assembler::overflowClear;
case Assembler::always: return Assembler::never;
case Assembler::notZero: return Assembler::zero;
case Assembler::greater: return Assembler::lessEqual;
case Assembler::greaterEqual: return Assembler::less;
case Assembler::greaterUnsigned: return Assembler::lessEqualUnsigned;
case Assembler::greaterEqualUnsigned: return Assembler::lessUnsigned;
case Assembler::positive: return Assembler::negative;
case Assembler::overflowClear: return Assembler::overflowSet;
}
ShouldNotReachHere(); return Assembler::overflowClear;
}
void MacroAssembler::cond_inc(Assembler::Condition cond, address counter_ptr,
Register Rtmp1, Register Rtmp2 /*, Register Rtmp3, Register Rtmp4 */) {
Condition negated_cond = negate_condition(cond);
Label L;
brx(negated_cond, false, Assembler::pt, L);
delayed()->nop();
inc_counter(counter_ptr, Rtmp1, Rtmp2);
bind(L);
}
void MacroAssembler::inc_counter(address counter_addr, Register Rtmp1, Register Rtmp2) {
AddressLiteral addrlit(counter_addr);
sethi(addrlit, Rtmp1); // Move hi22 bits into temporary register.
Address addr(Rtmp1, addrlit.low10()); // Build an address with low10 bits.
ld(addr, Rtmp2);
inc(Rtmp2);
st(Rtmp2, addr);
}
void MacroAssembler::inc_counter(int* counter_addr, Register Rtmp1, Register Rtmp2) {
inc_counter((address) counter_addr, Rtmp1, Rtmp2);
}
SkipIfEqual::SkipIfEqual(
MacroAssembler* masm, Register temp, const bool* flag_addr,
Assembler::Condition condition) {
_masm = masm;
AddressLiteral flag(flag_addr);
_masm->sethi(flag, temp);
_masm->ldub(temp, flag.low10(), temp);
_masm->tst(temp);
_masm->br(condition, false, Assembler::pt, _label);
_masm->delayed()->nop();
}
SkipIfEqual::~SkipIfEqual() {
_masm->bind(_label);
}
// Writes to stack successive pages until offset reached to check for
// stack overflow + shadow pages. This clobbers tsp and scratch.
void MacroAssembler::bang_stack_size(Register Rsize, Register Rtsp,
Register Rscratch) {
// Use stack pointer in temp stack pointer
mov(SP, Rtsp);
// Bang stack for total size given plus stack shadow page size.
// Bang one page at a time because a large size can overflow yellow and
// red zones (the bang will fail but stack overflow handling can't tell that
// it was a stack overflow bang vs a regular segv).
int offset = os::vm_page_size();
Register Roffset = Rscratch;
Label loop;
bind(loop);
set((-offset)+STACK_BIAS, Rscratch);
st(G0, Rtsp, Rscratch);
set(offset, Roffset);
sub(Rsize, Roffset, Rsize);
cmp(Rsize, G0);
br(Assembler::greater, false, Assembler::pn, loop);
delayed()->sub(Rtsp, Roffset, Rtsp);
// Bang down shadow pages too.
// At this point, (tmp-0) is the last address touched, so don't
// touch it again. (It was touched as (tmp-pagesize) but then tmp
// was post-decremented.) Skip this address by starting at i=1, and
// touch a few more pages below. N.B. It is important to touch all
// the way down to and including i=StackShadowPages.
for (int i = 1; i < StackShadowPages; i++) {
set((-i*offset)+STACK_BIAS, Rscratch);
st(G0, Rtsp, Rscratch);
}
}
///////////////////////////////////////////////////////////////////////////////////
#if INCLUDE_ALL_GCS
static address satb_log_enqueue_with_frame = NULL;
static u_char* satb_log_enqueue_with_frame_end = NULL;
static address satb_log_enqueue_frameless = NULL;
static u_char* satb_log_enqueue_frameless_end = NULL;
static int EnqueueCodeSize = 128 DEBUG_ONLY( + 256); // Instructions?
static void generate_satb_log_enqueue(bool with_frame) {
BufferBlob* bb = BufferBlob::create("enqueue_with_frame", EnqueueCodeSize);
CodeBuffer buf(bb);
MacroAssembler masm(&buf);
#define __ masm.
address start = __ pc();
Register pre_val;
Label refill, restart;
if (with_frame) {
__ save_frame(0);
pre_val = I0; // Was O0 before the save.
} else {
pre_val = O0;
}
int satb_q_index_byte_offset =
in_bytes(JavaThread::satb_mark_queue_offset() +
PtrQueue::byte_offset_of_index());
int satb_q_buf_byte_offset =
in_bytes(JavaThread::satb_mark_queue_offset() +
PtrQueue::byte_offset_of_buf());
assert(in_bytes(PtrQueue::byte_width_of_index()) == sizeof(intptr_t) &&
in_bytes(PtrQueue::byte_width_of_buf()) == sizeof(intptr_t),
"check sizes in assembly below");
__ bind(restart);
// Load the index into the SATB buffer. PtrQueue::_index is a size_t
// so ld_ptr is appropriate.
__ ld_ptr(G2_thread, satb_q_index_byte_offset, L0);
// index == 0?
__ cmp_and_brx_short(L0, G0, Assembler::equal, Assembler::pn, refill);
__ ld_ptr(G2_thread, satb_q_buf_byte_offset, L1);
__ sub(L0, oopSize, L0);
__ st_ptr(pre_val, L1, L0); // [_buf + index] := I0
if (!with_frame) {
// Use return-from-leaf
__ retl();
__ delayed()->st_ptr(L0, G2_thread, satb_q_index_byte_offset);
} else {
// Not delayed.
__ st_ptr(L0, G2_thread, satb_q_index_byte_offset);
}
if (with_frame) {
__ ret();
__ delayed()->restore();
}
__ bind(refill);
address handle_zero =
CAST_FROM_FN_PTR(address,
&SATBMarkQueueSet::handle_zero_index_for_thread);
// This should be rare enough that we can afford to save all the
// scratch registers that the calling context might be using.
__ mov(G1_scratch, L0);
__ mov(G3_scratch, L1);
__ mov(G4, L2);
// We need the value of O0 above (for the write into the buffer), so we
// save and restore it.
__ mov(O0, L3);
// Since the call will overwrite O7, we save and restore that, as well.
__ mov(O7, L4);
__ call_VM_leaf(L5, handle_zero, G2_thread);
__ mov(L0, G1_scratch);
__ mov(L1, G3_scratch);
__ mov(L2, G4);
__ mov(L3, O0);
__ br(Assembler::always, /*annul*/false, Assembler::pt, restart);
__ delayed()->mov(L4, O7);
if (with_frame) {
satb_log_enqueue_with_frame = start;
satb_log_enqueue_with_frame_end = __ pc();
} else {
satb_log_enqueue_frameless = start;
satb_log_enqueue_frameless_end = __ pc();
}
#undef __
}
static inline void generate_satb_log_enqueue_if_necessary(bool with_frame) {
if (with_frame) {
if (satb_log_enqueue_with_frame == 0) {
generate_satb_log_enqueue(with_frame);
assert(satb_log_enqueue_with_frame != 0, "postcondition.");
if (G1SATBPrintStubs) {
tty->print_cr("Generated with-frame satb enqueue:");
Disassembler::decode((u_char*)satb_log_enqueue_with_frame,
satb_log_enqueue_with_frame_end,
tty);
}
}
} else {
if (satb_log_enqueue_frameless == 0) {
generate_satb_log_enqueue(with_frame);
assert(satb_log_enqueue_frameless != 0, "postcondition.");
if (G1SATBPrintStubs) {
tty->print_cr("Generated frameless satb enqueue:");
Disassembler::decode((u_char*)satb_log_enqueue_frameless,
satb_log_enqueue_frameless_end,
tty);
}
}
}
}
void MacroAssembler::g1_write_barrier_pre(Register obj,
Register index,
int offset,
Register pre_val,
Register tmp,
bool preserve_o_regs) {
Label filtered;
if (obj == noreg) {
// We are not loading the previous value so make
// sure that we don't trash the value in pre_val
// with the code below.
assert_different_registers(pre_val, tmp);
} else {
// We will be loading the previous value
// in this code so...
assert(offset == 0 || index == noreg, "choose one");
assert(pre_val == noreg, "check this code");
}
// Is marking active?
if (in_bytes(PtrQueue::byte_width_of_active()) == 4) {
ld(G2,
in_bytes(JavaThread::satb_mark_queue_offset() +
PtrQueue::byte_offset_of_active()),
tmp);
} else {
guarantee(in_bytes(PtrQueue::byte_width_of_active()) == 1,
"Assumption");
ldsb(G2,
in_bytes(JavaThread::satb_mark_queue_offset() +
PtrQueue::byte_offset_of_active()),
tmp);
}
// Is marking active?
cmp_and_br_short(tmp, G0, Assembler::equal, Assembler::pt, filtered);
// Do we need to load the previous value?
if (obj != noreg) {
// Load the previous value...
if (index == noreg) {
if (Assembler::is_simm13(offset)) {
load_heap_oop(obj, offset, tmp);
} else {
set(offset, tmp);
load_heap_oop(obj, tmp, tmp);
}
} else {
load_heap_oop(obj, index, tmp);
}
// Previous value has been loaded into tmp
pre_val = tmp;
}
assert(pre_val != noreg, "must have a real register");
// Is the previous value null?
cmp_and_brx_short(pre_val, G0, Assembler::equal, Assembler::pt, filtered);
// OK, it's not filtered, so we'll need to call enqueue. In the normal
// case, pre_val will be a scratch G-reg, but there are some cases in
// which it's an O-reg. In the first case, do a normal call. In the
// latter, do a save here and call the frameless version.
guarantee(pre_val->is_global() || pre_val->is_out(),
"Or we need to think harder.");
if (pre_val->is_global() && !preserve_o_regs) {
generate_satb_log_enqueue_if_necessary(true); // with frame
call(satb_log_enqueue_with_frame);
delayed()->mov(pre_val, O0);
} else {
generate_satb_log_enqueue_if_necessary(false); // frameless
save_frame(0);
call(satb_log_enqueue_frameless);
delayed()->mov(pre_val->after_save(), O0);
restore();
}
bind(filtered);
}
static address dirty_card_log_enqueue = 0;
static u_char* dirty_card_log_enqueue_end = 0;
// This gets to assume that o0 contains the object address.
static void generate_dirty_card_log_enqueue(jbyte* byte_map_base) {
BufferBlob* bb = BufferBlob::create("dirty_card_enqueue", EnqueueCodeSize*2);
CodeBuffer buf(bb);
MacroAssembler masm(&buf);
#define __ masm.
address start = __ pc();
Label not_already_dirty, restart, refill, young_card;
#ifdef _LP64
__ srlx(O0, CardTableModRefBS::card_shift, O0);
#else
__ srl(O0, CardTableModRefBS::card_shift, O0);
#endif
AddressLiteral addrlit(byte_map_base);
__ set(addrlit, O1); // O1 := <card table base>
__ ldub(O0, O1, O2); // O2 := [O0 + O1]
__ cmp_and_br_short(O2, G1SATBCardTableModRefBS::g1_young_card_val(), Assembler::equal, Assembler::pt, young_card);
__ membar(Assembler::Membar_mask_bits(Assembler::StoreLoad));
__ ldub(O0, O1, O2); // O2 := [O0 + O1]
assert(CardTableModRefBS::dirty_card_val() == 0, "otherwise check this code");
__ cmp_and_br_short(O2, G0, Assembler::notEqual, Assembler::pt, not_already_dirty);
__ bind(young_card);
// We didn't take the branch, so we're already dirty: return.
// Use return-from-leaf
__ retl();
__ delayed()->nop();
// Not dirty.
__ bind(not_already_dirty);
// Get O0 + O1 into a reg by itself
__ add(O0, O1, O3);
// First, dirty it.
__ stb(G0, O3, G0); // [cardPtr] := 0 (i.e., dirty).
int dirty_card_q_index_byte_offset =
in_bytes(JavaThread::dirty_card_queue_offset() +
PtrQueue::byte_offset_of_index());
int dirty_card_q_buf_byte_offset =
in_bytes(JavaThread::dirty_card_queue_offset() +
PtrQueue::byte_offset_of_buf());
__ bind(restart);
// Load the index into the update buffer. PtrQueue::_index is
// a size_t so ld_ptr is appropriate here.
__ ld_ptr(G2_thread, dirty_card_q_index_byte_offset, L0);
// index == 0?
__ cmp_and_brx_short(L0, G0, Assembler::equal, Assembler::pn, refill);
__ ld_ptr(G2_thread, dirty_card_q_buf_byte_offset, L1);
__ sub(L0, oopSize, L0);
__ st_ptr(O3, L1, L0); // [_buf + index] := I0
// Use return-from-leaf
__ retl();
__ delayed()->st_ptr(L0, G2_thread, dirty_card_q_index_byte_offset);
__ bind(refill);
address handle_zero =
CAST_FROM_FN_PTR(address,
&DirtyCardQueueSet::handle_zero_index_for_thread);
// This should be rare enough that we can afford to save all the
// scratch registers that the calling context might be using.
__ mov(G1_scratch, L3);
__ mov(G3_scratch, L5);
// We need the value of O3 above (for the write into the buffer), so we
// save and restore it.
__ mov(O3, L6);
// Since the call will overwrite O7, we save and restore that, as well.
__ mov(O7, L4);
__ call_VM_leaf(L7_thread_cache, handle_zero, G2_thread);
__ mov(L3, G1_scratch);
__ mov(L5, G3_scratch);
__ mov(L6, O3);
__ br(Assembler::always, /*annul*/false, Assembler::pt, restart);
__ delayed()->mov(L4, O7);
dirty_card_log_enqueue = start;
dirty_card_log_enqueue_end = __ pc();
// XXX Should have a guarantee here about not going off the end!
// Does it already do so? Do an experiment...
#undef __
}
static inline void
generate_dirty_card_log_enqueue_if_necessary(jbyte* byte_map_base) {
if (dirty_card_log_enqueue == 0) {
generate_dirty_card_log_enqueue(byte_map_base);
assert(dirty_card_log_enqueue != 0, "postcondition.");
if (G1SATBPrintStubs) {
tty->print_cr("Generated dirty_card enqueue:");
Disassembler::decode((u_char*)dirty_card_log_enqueue,
dirty_card_log_enqueue_end,
tty);
}
}
}
void MacroAssembler::g1_write_barrier_post(Register store_addr, Register new_val, Register tmp) {
Label filtered;
MacroAssembler* post_filter_masm = this;
if (new_val == G0) return;
G1SATBCardTableModRefBS* bs = (G1SATBCardTableModRefBS*) Universe::heap()->barrier_set();
assert(bs->kind() == BarrierSet::G1SATBCT ||
bs->kind() == BarrierSet::G1SATBCTLogging, "wrong barrier");
if (G1RSBarrierRegionFilter) {
xor3(store_addr, new_val, tmp);
#ifdef _LP64
srlx(tmp, HeapRegion::LogOfHRGrainBytes, tmp);
#else
srl(tmp, HeapRegion::LogOfHRGrainBytes, tmp);
#endif
// XXX Should I predict this taken or not? Does it matter?
cmp_and_brx_short(tmp, G0, Assembler::equal, Assembler::pt, filtered);
}
// If the "store_addr" register is an "in" or "local" register, move it to
// a scratch reg so we can pass it as an argument.
bool use_scr = !(store_addr->is_global() || store_addr->is_out());
// Pick a scratch register different from "tmp".
Register scr = (tmp == G1_scratch ? G3_scratch : G1_scratch);
// Make sure we use up the delay slot!
if (use_scr) {
post_filter_masm->mov(store_addr, scr);
} else {
post_filter_masm->nop();
}
generate_dirty_card_log_enqueue_if_necessary(bs->byte_map_base);
save_frame(0);
call(dirty_card_log_enqueue);
if (use_scr) {
delayed()->mov(scr, O0);
} else {
delayed()->mov(store_addr->after_save(), O0);
}
restore();
bind(filtered);
}
#endif // INCLUDE_ALL_GCS
///////////////////////////////////////////////////////////////////////////////////
void MacroAssembler::card_write_barrier_post(Register store_addr, Register new_val, Register tmp) {
// If we're writing constant NULL, we can skip the write barrier.
if (new_val == G0) return;
CardTableModRefBS* bs = (CardTableModRefBS*) Universe::heap()->barrier_set();
assert(bs->kind() == BarrierSet::CardTableModRef ||
bs->kind() == BarrierSet::CardTableExtension, "wrong barrier");
card_table_write(bs->byte_map_base, tmp, store_addr);
}
void MacroAssembler::load_klass(Register src_oop, Register klass) {
// The number of bytes in this code is used by
// MachCallDynamicJavaNode::ret_addr_offset()
// if this changes, change that.
if (UseCompressedClassPointers) {
lduw(src_oop, oopDesc::klass_offset_in_bytes(), klass);
decode_klass_not_null(klass);
} else {
ld_ptr(src_oop, oopDesc::klass_offset_in_bytes(), klass);
}
}
void MacroAssembler::store_klass(Register klass, Register dst_oop) {
if (UseCompressedClassPointers) {
assert(dst_oop != klass, "not enough registers");
encode_klass_not_null(klass);
st(klass, dst_oop, oopDesc::klass_offset_in_bytes());
} else {
st_ptr(klass, dst_oop, oopDesc::klass_offset_in_bytes());
}
}
void MacroAssembler::store_klass_gap(Register s, Register d) {
if (UseCompressedClassPointers) {
assert(s != d, "not enough registers");
st(s, d, oopDesc::klass_gap_offset_in_bytes());
}
}
void MacroAssembler::load_heap_oop(const Address& s, Register d) {
if (UseCompressedOops) {
lduw(s, d);
decode_heap_oop(d);
} else {
ld_ptr(s, d);
}
}
void MacroAssembler::load_heap_oop(Register s1, Register s2, Register d) {
if (UseCompressedOops) {
lduw(s1, s2, d);
decode_heap_oop(d, d);
} else {
ld_ptr(s1, s2, d);
}
}
void MacroAssembler::load_heap_oop(Register s1, int simm13a, Register d) {
if (UseCompressedOops) {
lduw(s1, simm13a, d);
decode_heap_oop(d, d);
} else {
ld_ptr(s1, simm13a, d);
}
}
void MacroAssembler::load_heap_oop(Register s1, RegisterOrConstant s2, Register d) {
if (s2.is_constant()) load_heap_oop(s1, s2.as_constant(), d);
else load_heap_oop(s1, s2.as_register(), d);
}
void MacroAssembler::store_heap_oop(Register d, Register s1, Register s2) {
if (UseCompressedOops) {
assert(s1 != d && s2 != d, "not enough registers");
encode_heap_oop(d);
st(d, s1, s2);
} else {
st_ptr(d, s1, s2);
}
}
void MacroAssembler::store_heap_oop(Register d, Register s1, int simm13a) {
if (UseCompressedOops) {
assert(s1 != d, "not enough registers");
encode_heap_oop(d);
st(d, s1, simm13a);
} else {
st_ptr(d, s1, simm13a);
}
}
void MacroAssembler::store_heap_oop(Register d, const Address& a, int offset) {
if (UseCompressedOops) {
assert(a.base() != d, "not enough registers");
encode_heap_oop(d);
st(d, a, offset);
} else {
st_ptr(d, a, offset);
}
}
void MacroAssembler::encode_heap_oop(Register src, Register dst) {
assert (UseCompressedOops, "must be compressed");
assert (Universe::heap() != NULL, "java heap should be initialized");
assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong");
verify_oop(src);
if (Universe::narrow_oop_base() == NULL) {
srlx(src, LogMinObjAlignmentInBytes, dst);
return;
}
Label done;
if (src == dst) {
// optimize for frequent case src == dst
bpr(rc_nz, true, Assembler::pt, src, done);
delayed() -> sub(src, G6_heapbase, dst); // annuled if not taken
bind(done);
srlx(src, LogMinObjAlignmentInBytes, dst);
} else {
bpr(rc_z, false, Assembler::pn, src, done);
delayed() -> mov(G0, dst);
// could be moved before branch, and annulate delay,
// but may add some unneeded work decoding null
sub(src, G6_heapbase, dst);
srlx(dst, LogMinObjAlignmentInBytes, dst);
bind(done);
}
}
void MacroAssembler::encode_heap_oop_not_null(Register r) {
assert (UseCompressedOops, "must be compressed");
assert (Universe::heap() != NULL, "java heap should be initialized");
assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong");
verify_oop(r);
if (Universe::narrow_oop_base() != NULL)
sub(r, G6_heapbase, r);
srlx(r, LogMinObjAlignmentInBytes, r);
}
void MacroAssembler::encode_heap_oop_not_null(Register src, Register dst) {
assert (UseCompressedOops, "must be compressed");
assert (Universe::heap() != NULL, "java heap should be initialized");
assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong");
verify_oop(src);
if (Universe::narrow_oop_base() == NULL) {
srlx(src, LogMinObjAlignmentInBytes, dst);
} else {
sub(src, G6_heapbase, dst);
srlx(dst, LogMinObjAlignmentInBytes, dst);
}
}
// Same algorithm as oops.inline.hpp decode_heap_oop.
void MacroAssembler::decode_heap_oop(Register src, Register dst) {
assert (UseCompressedOops, "must be compressed");
assert (Universe::heap() != NULL, "java heap should be initialized");
assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong");
sllx(src, LogMinObjAlignmentInBytes, dst);
if (Universe::narrow_oop_base() != NULL) {
Label done;
bpr(rc_nz, true, Assembler::pt, dst, done);
delayed() -> add(dst, G6_heapbase, dst); // annuled if not taken
bind(done);
}
verify_oop(dst);
}
void MacroAssembler::decode_heap_oop_not_null(Register r) {
// Do not add assert code to this unless you change vtableStubs_sparc.cpp
// pd_code_size_limit.
// Also do not verify_oop as this is called by verify_oop.
assert (UseCompressedOops, "must be compressed");
assert (Universe::heap() != NULL, "java heap should be initialized");
assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong");
sllx(r, LogMinObjAlignmentInBytes, r);
if (Universe::narrow_oop_base() != NULL)
add(r, G6_heapbase, r);
}
void MacroAssembler::decode_heap_oop_not_null(Register src, Register dst) {
// Do not add assert code to this unless you change vtableStubs_sparc.cpp
// pd_code_size_limit.
// Also do not verify_oop as this is called by verify_oop.
assert (UseCompressedOops, "must be compressed");
assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong");
sllx(src, LogMinObjAlignmentInBytes, dst);
if (Universe::narrow_oop_base() != NULL)
add(dst, G6_heapbase, dst);
}
void MacroAssembler::encode_klass_not_null(Register r) {
assert (UseCompressedClassPointers, "must be compressed");
if (Universe::narrow_klass_base() != NULL) {
assert(r != G6_heapbase, "bad register choice");
set((intptr_t)Universe::narrow_klass_base(), G6_heapbase);
sub(r, G6_heapbase, r);
if (Universe::narrow_klass_shift() != 0) {
assert (LogKlassAlignmentInBytes == Universe::narrow_klass_shift(), "decode alg wrong");
srlx(r, LogKlassAlignmentInBytes, r);
}
reinit_heapbase();
} else {
assert (LogKlassAlignmentInBytes == Universe::narrow_klass_shift() || Universe::narrow_klass_shift() == 0, "decode alg wrong");
srlx(r, Universe::narrow_klass_shift(), r);
}
}
void MacroAssembler::encode_klass_not_null(Register src, Register dst) {
if (src == dst) {
encode_klass_not_null(src);
} else {
assert (UseCompressedClassPointers, "must be compressed");
if (Universe::narrow_klass_base() != NULL) {
set((intptr_t)Universe::narrow_klass_base(), dst);
sub(src, dst, dst);
if (Universe::narrow_klass_shift() != 0) {
srlx(dst, LogKlassAlignmentInBytes, dst);
}
} else {
// shift src into dst
assert (LogKlassAlignmentInBytes == Universe::narrow_klass_shift() || Universe::narrow_klass_shift() == 0, "decode alg wrong");
srlx(src, Universe::narrow_klass_shift(), dst);
}
}
}
// Function instr_size_for_decode_klass_not_null() counts the instructions
// generated by decode_klass_not_null() and reinit_heapbase(). Hence, if
// the instructions they generate change, then this method needs to be updated.
int MacroAssembler::instr_size_for_decode_klass_not_null() {
assert (UseCompressedClassPointers, "only for compressed klass ptrs");
int num_instrs = 1; // shift src,dst or add
if (Universe::narrow_klass_base() != NULL) {
// set + add + set
num_instrs += insts_for_internal_set((intptr_t)Universe::narrow_klass_base()) +
insts_for_internal_set((intptr_t)Universe::narrow_ptrs_base());
if (Universe::narrow_klass_shift() != 0) {
num_instrs += 1; // sllx
}
}
return num_instrs * BytesPerInstWord;
}
// !!! If the instructions that get generated here change then function
// instr_size_for_decode_klass_not_null() needs to get updated.
void MacroAssembler::decode_klass_not_null(Register r) {
// Do not add assert code to this unless you change vtableStubs_sparc.cpp
// pd_code_size_limit.
assert (UseCompressedClassPointers, "must be compressed");
if (Universe::narrow_klass_base() != NULL) {
assert(r != G6_heapbase, "bad register choice");
set((intptr_t)Universe::narrow_klass_base(), G6_heapbase);
if (Universe::narrow_klass_shift() != 0)
sllx(r, LogKlassAlignmentInBytes, r);
add(r, G6_heapbase, r);
reinit_heapbase();
} else {
assert (LogKlassAlignmentInBytes == Universe::narrow_klass_shift() || Universe::narrow_klass_shift() == 0, "decode alg wrong");
sllx(r, Universe::narrow_klass_shift(), r);
}
}
void MacroAssembler::decode_klass_not_null(Register src, Register dst) {
if (src == dst) {
decode_klass_not_null(src);
} else {
// Do not add assert code to this unless you change vtableStubs_sparc.cpp
// pd_code_size_limit.
assert (UseCompressedClassPointers, "must be compressed");
if (Universe::narrow_klass_base() != NULL) {
if (Universe::narrow_klass_shift() != 0) {
assert((src != G6_heapbase) && (dst != G6_heapbase), "bad register choice");
set((intptr_t)Universe::narrow_klass_base(), G6_heapbase);
sllx(src, LogKlassAlignmentInBytes, dst);
add(dst, G6_heapbase, dst);
reinit_heapbase();
} else {
set((intptr_t)Universe::narrow_klass_base(), dst);
add(src, dst, dst);
}
} else {
// shift/mov src into dst.
assert (LogKlassAlignmentInBytes == Universe::narrow_klass_shift() || Universe::narrow_klass_shift() == 0, "decode alg wrong");
sllx(src, Universe::narrow_klass_shift(), dst);
}
}
}
void MacroAssembler::reinit_heapbase() {
if (UseCompressedOops || UseCompressedClassPointers) {
if (Universe::heap() != NULL) {
set((intptr_t)Universe::narrow_ptrs_base(), G6_heapbase);
} else {
AddressLiteral base(Universe::narrow_ptrs_base_addr());
load_ptr_contents(base, G6_heapbase);
}
}
}
// Compare char[] arrays aligned to 4 bytes.
void MacroAssembler::char_arrays_equals(Register ary1, Register ary2,
Register limit, Register result,
Register chr1, Register chr2, Label& Ldone) {
Label Lvector, Lloop;
assert(chr1 == result, "should be the same");
// Note: limit contains number of bytes (2*char_elements) != 0.
andcc(limit, 0x2, chr1); // trailing character ?
br(Assembler::zero, false, Assembler::pt, Lvector);
delayed()->nop();
// compare the trailing char
sub(limit, sizeof(jchar), limit);
lduh(ary1, limit, chr1);
lduh(ary2, limit, chr2);
cmp(chr1, chr2);
br(Assembler::notEqual, true, Assembler::pt, Ldone);
delayed()->mov(G0, result); // not equal
// only one char ?
cmp_zero_and_br(zero, limit, Ldone, true, Assembler::pn);
delayed()->add(G0, 1, result); // zero-length arrays are equal
// word by word compare, dont't need alignment check
bind(Lvector);
// Shift ary1 and ary2 to the end of the arrays, negate limit
add(ary1, limit, ary1);
add(ary2, limit, ary2);
neg(limit, limit);
lduw(ary1, limit, chr1);
bind(Lloop);
lduw(ary2, limit, chr2);
cmp(chr1, chr2);
br(Assembler::notEqual, true, Assembler::pt, Ldone);
delayed()->mov(G0, result); // not equal
inccc(limit, 2*sizeof(jchar));
// annul LDUW if branch is not taken to prevent access past end of array
br(Assembler::notZero, true, Assembler::pt, Lloop);
delayed()->lduw(ary1, limit, chr1); // hoisted
// Caller should set it:
// add(G0, 1, result); // equals
}
// Use BIS for zeroing (count is in bytes).
void MacroAssembler::bis_zeroing(Register to, Register count, Register temp, Label& Ldone) {
assert(UseBlockZeroing && VM_Version::has_block_zeroing(), "only works with BIS zeroing");
Register end = count;
int cache_line_size = VM_Version::prefetch_data_size();
// Minimum count when BIS zeroing can be used since
// it needs membar which is expensive.
int block_zero_size = MAX2(cache_line_size*3, (int)BlockZeroingLowLimit);
Label small_loop;
// Check if count is negative (dead code) or zero.
// Note, count uses 64bit in 64 bit VM.
cmp_and_brx_short(count, 0, Assembler::lessEqual, Assembler::pn, Ldone);
// Use BIS zeroing only for big arrays since it requires membar.
if (Assembler::is_simm13(block_zero_size)) { // < 4096
cmp(count, block_zero_size);
} else {
set(block_zero_size, temp);
cmp(count, temp);
}
br(Assembler::lessUnsigned, false, Assembler::pt, small_loop);
delayed()->add(to, count, end);
// Note: size is >= three (32 bytes) cache lines.
// Clean the beginning of space up to next cache line.
for (int offs = 0; offs < cache_line_size; offs += 8) {
stx(G0, to, offs);
}
// align to next cache line
add(to, cache_line_size, to);
and3(to, -cache_line_size, to);
// Note: size left >= two (32 bytes) cache lines.
// BIS should not be used to zero tail (64 bytes)
// to avoid zeroing a header of the following object.
sub(end, (cache_line_size*2)-8, end);
Label bis_loop;
bind(bis_loop);
stxa(G0, to, G0, Assembler::ASI_ST_BLKINIT_PRIMARY);
add(to, cache_line_size, to);
cmp_and_brx_short(to, end, Assembler::lessUnsigned, Assembler::pt, bis_loop);
// BIS needs membar.
membar(Assembler::StoreLoad);
add(end, (cache_line_size*2)-8, end); // restore end
cmp_and_brx_short(to, end, Assembler::greaterEqualUnsigned, Assembler::pn, Ldone);
// Clean the tail.
bind(small_loop);
stx(G0, to, 0);
add(to, 8, to);
cmp_and_brx_short(to, end, Assembler::lessUnsigned, Assembler::pt, small_loop);
nop(); // Separate short branches
}