void CompiledDirectStaticCall::set_to_interpreted(const methodHandle& callee, address entry) {
address stub = find_stub(/*is_aot*/ false);
guarantee(stub != NULL, "stub not found");
if (TraceICs) {
ResourceMark rm;
tty->print_cr("CompiledDirectStaticCall@" INTPTR_FORMAT ": set_to_interpreted %s",
p2i(instruction_address()),
callee->name_and_sig_as_C_string());
}
// Creation also verifies the object.
NativeMovConstReg* method_holder = nativeMovConstReg_at(stub + NativeCall::get_IC_pos_in_java_to_interp_stub());
NativeJump* jump = nativeJump_at(method_holder->next_instruction_address());
// A generated lambda form might be deleted from the Lambdaform
// cache in MethodTypeForm. If a jit compiled lambdaform method
// becomes not entrant and the cache access returns null, the new
// resolve will lead to a new generated LambdaForm.
assert(method_holder->data() == 0 || method_holder->data() == (intptr_t)callee() || callee->is_compiled_lambda_form(),
"a) MT-unsafe modification of inline cache");
assert(jump->jump_destination() == (address)-1 || jump->jump_destination() == entry,
"b) MT-unsafe modification of inline cache");
// Update stub.
method_holder->set_data((intptr_t)callee());
jump->set_jump_destination(entry);
// Update jump to call.
set_destination_mt_safe(stub);
}
void CompiledStaticCall::set_to_interpreted(methodHandle callee, address entry) {
address stub = find_stub();
guarantee(stub != NULL, "stub not found");
if (TraceICs) {
ResourceMark rm;
tty->print_cr("CompiledStaticCall@" INTPTR_FORMAT ": set_to_interpreted %s",
p2i(instruction_address()),
callee->name_and_sig_as_C_string());
}
// Creation also verifies the object.
NativeMovConstReg* method_holder = nativeMovConstReg_at(stub);
NativeJump* jump = nativeJump_at(method_holder->next_instruction_address());
assert(method_holder->data() == 0 || method_holder->data() == (intptr_t)callee(),
"a) MT-unsafe modification of inline cache");
assert(jump->jump_destination() == (address)-1 || jump->jump_destination() == entry,
"b) MT-unsafe modification of inline cache");
// Update stub.
method_holder->set_data((intptr_t)callee());
jump->set_jump_destination(entry);
// Update jump to call.
set_destination_mt_safe(stub);
}
address Relocation::pd_call_destination(address orig_addr) {
intptr_t adj = 0;
address inst_loc = addr();
if (orig_addr != NULL) {
// We just moved this call instruction from orig_addr to addr().
// This means its target will appear to have grown by addr() - orig_addr.
adj = -(inst_loc - orig_addr);
}
if (NativeFarCall::is_far_call_at(inst_loc)) {
NativeFarCall* call = nativeFarCall_at(inst_loc);
return call->destination() + (intptr_t)(call->is_pcrelative() ? adj : 0);
} else if (NativeJump::is_jump_at(inst_loc)) {
NativeJump* jump = nativeJump_at(inst_loc);
return jump->jump_destination() + (intptr_t)(jump->is_pcrelative() ? adj : 0);
} else if (NativeConditionalFarBranch::is_conditional_far_branch_at(inst_loc)) {
NativeConditionalFarBranch* branch = NativeConditionalFarBranch_at(inst_loc);
return branch->branch_destination();
} else {
// There are two instructions at the beginning of a stub, therefore we
// load at orig_addr + 8.
orig_addr = nativeCall_at(inst_loc)->get_trampoline();
if (orig_addr == NULL) {
return (address) -1;
} else {
return (address) nativeMovConstReg_at(orig_addr + 8)->data();
}
}
}
void Relocation::pd_set_call_destination(address x) {
NativeInstruction* ni = nativeInstruction_at(addr());
if (ni->is_call()) {
nativeCall_at(addr())->set_destination(x);
} else if (ni->is_jump()) {
NativeJump* nj = nativeJump_at(addr());
// Unresolved jumps are recognized by a destination of -1
// However 64bit can't actually produce such an address
// and encodes a jump to self but jump_destination will
// return a -1 as the signal. We must not relocate this
// jmp or the ic code will not see it as unresolved.
if (nj->jump_destination() == (address) -1) {
x = addr(); // jump to self
}
nj->set_jump_destination(x);
} else if (ni->is_cond_jump()) {
// %%%% kludge this, for now, until we get a jump_destination method
address old_dest = nativeGeneralJump_at(addr())->jump_destination();
address disp = Assembler::locate_operand(addr(), Assembler::call32_operand);
*(jint*)disp += (x - old_dest);
} else if (ni->is_mov_literal64()) {
((NativeMovConstReg*)ni)->set_data((intptr_t)x);
} else {
ShouldNotReachHere();
}
}
// Code for unit testing implementation of NativeJump class
void NativeJump::test() {
#ifdef ASSERT
ResourceMark rm;
CodeBuffer cb("test", 100, 100);
MacroAssembler* a = new MacroAssembler(&cb);
NativeJump* nj;
uint idx;
int offsets[] = {
0x0,
0xffffffff,
0x7fffffff,
0x80000000,
4096,
4097,
0x20,
0x4000,
};
VM_Version::allow_all();
AddressLiteral al(0x7fffbbbb, relocInfo::external_word_type);
a->sethi(al, I3);
a->jmpl(I3, al.low10(), G0, RelocationHolder::none);
a->delayed()->nop();
a->sethi(al, I3);
a->jmpl(I3, al.low10(), L3, RelocationHolder::none);
a->delayed()->nop();
nj = nativeJump_at( cb.insts_begin() );
nj->print();
nj = nativeJump_at( nj->next_instruction_address() );
for (idx = 0; idx < ARRAY_SIZE(offsets); idx++) {
nj->set_jump_destination( nj->instruction_address() + offsets[idx] );
assert(nj->jump_destination() == (nj->instruction_address() + offsets[idx]), "check unit test");
nj->print();
}
VM_Version::revert();
#endif // ASSERT
}
address InlineCacheBuffer::ic_buffer_entry_point(address code_begin) {
NativeMovConstReg* move = nativeMovConstReg_at(code_begin); // creation also verifies the object
NativeJump* jump = nativeJump_at(move->next_instruction_address());
return jump->jump_destination();
}
address InlineCacheBuffer::ic_buffer_entry_point(address code_begin) {
address jump_address;
jump_address = code_begin + NativeInstruction::instruction_size;
NativeJump* jump = nativeJump_at(jump_address);
return jump->jump_destination();
}
