bool stack_empty(const struct stack *stack) {
null_check(stack);
return stack->head == NULL;
}
bool run(struct context *context,
struct byte_array *program,
struct map *env,
bool in_context)
{
null_check(context);
null_check(program);
program = byte_array_copy(program);
program->current = program->data;
struct program_state *state = NULL;
enum Opcode inst = VM_NIL;
if (context->runtime) {
if (in_context) {
if (!state)
state = (struct program_state*)stack_peek(context->program_stack, 0);
env = state->named_variables; // use the caller's variable set in the new state
}
else
state = program_state_new(context, env);
}
while (program->current < program->data + program->length) {
inst = (enum Opcode)*program->current;
bool really = inst & VM_RLY;
inst &= ~VM_RLY;
#ifdef DEBUG
display_program_counter(context, program);
#endif
program->current++; // increment past the instruction
int32_t pc_offset = 0;
switch (inst) {
case VM_COM:
case VM_ITR: if (iterate(context, inst, state, program)) goto done; break;
case VM_RET: if (ret(context, program)) goto done; break;
case VM_TRO: if (tro(context)) goto done; break;
case VM_TRY: if (vm_trycatch(context, program)) goto done; break;
case VM_EQU:
case VM_MUL:
case VM_DIV:
case VM_ADD:
case VM_SUB:
case VM_NEQ:
case VM_GTN:
case VM_LTN:
case VM_GRQ:
case VM_LEQ:
case VM_BND:
case VM_BOR:
case VM_MOD:
case VM_XOR:
case VM_INV:
case VM_RSF:
case VM_LSF: binary_op(context, inst); break;
case VM_ORR:
case VM_AND: pc_offset = boolean_op(context, program, inst); break;
case VM_NEG:
case VM_NOT: unary_op(context, inst); break;
case VM_SRC: src(context, inst, program); break;
case VM_DST: dst(context, really); break;
case VM_STX:
case VM_SET: set(context, inst, state, program); break;
case VM_JMP: pc_offset = jump(context, program); break;
case VM_IFF: pc_offset = iff(context, program); break;
case VM_CAL: func_call(context, inst, program, NULL); break;
case VM_LST: push_list(context, program); break;
case VM_MAP: push_map(context, program); break;
case VM_NIL: push_nil(context); break;
case VM_INT: push_int(context, program); break;
case VM_FLT: push_float(context, program); break;
case VM_BUL: push_bool(context, program); break;
case VM_STR: push_str(context, program); break;
case VM_VAR: push_var(context, program); break;
case VM_FNC: push_fnc(context, program); break;
case VM_GET: list_get(context, really); break;
case VM_PTX:
case VM_PUT: list_put(context, inst, really); break;
case VM_MET: method(context, program, really); break;
default:
vm_exit_message(context, ERROR_OPCODE);
return false;
}
program->current += pc_offset;
}
if (!context->runtime)
return false;
done:
if (!in_context)
stack_pop(context->program_stack);
return inst == VM_RET;
}
uint8_t byte_array_get(const struct byte_array *within, uint32_t index) {
null_check(within);
assert_message(index < within->length, "out of bounds");
return within->data[index];
}
void* stack_peek(const struct stack *stack, uint8_t index) {
null_check(stack);
struct stack_node *p = stack->head;
for (; index && p; index--, p=p->next);
return p ? p->data : NULL;
}
void MethodHandles::generate_method_handle_dispatch(MacroAssembler* _masm,
vmIntrinsics::ID iid,
Register receiver_reg,
Register member_reg,
bool for_compiler_entry) {
assert(is_signature_polymorphic(iid), "expected invoke iid");
// temps used in this code are not used in *either* compiled or interpreted calling sequences
Register temp1 = r10;
Register temp2 = r11;
Register temp3 = r14; // r13 is live by this point: it contains the sender SP
if (for_compiler_entry) {
assert(receiver_reg == (iid == vmIntrinsics::_linkToStatic ? noreg : j_rarg0), "only valid assignment");
assert_different_registers(temp1, j_rarg0, j_rarg1, j_rarg2, j_rarg3, j_rarg4, j_rarg5, j_rarg6, j_rarg7);
assert_different_registers(temp2, j_rarg0, j_rarg1, j_rarg2, j_rarg3, j_rarg4, j_rarg5, j_rarg6, j_rarg7);
assert_different_registers(temp3, j_rarg0, j_rarg1, j_rarg2, j_rarg3, j_rarg4, j_rarg5, j_rarg6, j_rarg7);
}
assert_different_registers(temp1, temp2, temp3, receiver_reg);
assert_different_registers(temp1, temp2, temp3, member_reg);
if (iid == vmIntrinsics::_invokeBasic) {
// indirect through MH.form.vmentry.vmtarget
jump_to_lambda_form(_masm, receiver_reg, rmethod, temp1, for_compiler_entry);
} else {
// The method is a member invoker used by direct method handles.
if (VerifyMethodHandles) {
// make sure the trailing argument really is a MemberName (caller responsibility)
verify_klass(_masm, member_reg, SystemDictionary::WK_KLASS_ENUM_NAME(java_lang_invoke_MemberName),
"MemberName required for invokeVirtual etc.");
}
Address member_clazz( member_reg, NONZERO(java_lang_invoke_MemberName::clazz_offset_in_bytes()));
Address member_vmindex( member_reg, NONZERO(java_lang_invoke_MemberName::vmindex_offset_in_bytes()));
Address member_vmtarget( member_reg, NONZERO(java_lang_invoke_MemberName::vmtarget_offset_in_bytes()));
Register temp1_recv_klass = temp1;
if (iid != vmIntrinsics::_linkToStatic) {
__ verify_oop(receiver_reg);
if (iid == vmIntrinsics::_linkToSpecial) {
// Don't actually load the klass; just null-check the receiver.
__ null_check(receiver_reg);
} else {
// load receiver klass itself
__ null_check(receiver_reg, oopDesc::klass_offset_in_bytes());
__ load_klass(temp1_recv_klass, receiver_reg);
__ verify_klass_ptr(temp1_recv_klass);
}
BLOCK_COMMENT("check_receiver {");
// The receiver for the MemberName must be in receiver_reg.
// Check the receiver against the MemberName.clazz
if (VerifyMethodHandles && iid == vmIntrinsics::_linkToSpecial) {
// Did not load it above...
__ load_klass(temp1_recv_klass, receiver_reg);
__ verify_klass_ptr(temp1_recv_klass);
}
if (VerifyMethodHandles && iid != vmIntrinsics::_linkToInterface) {
Label L_ok;
Register temp2_defc = temp2;
__ load_heap_oop(temp2_defc, member_clazz);
load_klass_from_Class(_masm, temp2_defc);
__ verify_klass_ptr(temp2_defc);
__ check_klass_subtype(temp1_recv_klass, temp2_defc, temp3, L_ok);
// If we get here, the type check failed!
__ hlt(0);
// __ STOP("receiver class disagrees with MemberName.clazz");
__ bind(L_ok);
}
BLOCK_COMMENT("} check_receiver");
}
if (iid == vmIntrinsics::_linkToSpecial ||
iid == vmIntrinsics::_linkToStatic) {
DEBUG_ONLY(temp1_recv_klass = noreg); // these guys didn't load the recv_klass
}
// Live registers at this point:
// member_reg - MemberName that was the trailing argument
// temp1_recv_klass - klass of stacked receiver, if needed
// r13 - interpreter linkage (if interpreted) ??? FIXME
// r1 ... r0 - compiler arguments (if compiled)
Label L_incompatible_class_change_error;
switch (iid) {
case vmIntrinsics::_linkToSpecial:
if (VerifyMethodHandles) {
verify_ref_kind(_masm, JVM_REF_invokeSpecial, member_reg, temp3);
}
__ ldr(rmethod, member_vmtarget);
break;
case vmIntrinsics::_linkToStatic:
if (VerifyMethodHandles) {
verify_ref_kind(_masm, JVM_REF_invokeStatic, member_reg, temp3);
}
__ ldr(rmethod, member_vmtarget);
break;
case vmIntrinsics::_linkToVirtual:
{
// same as TemplateTable::invokevirtual,
// minus the CP setup and profiling:
if (VerifyMethodHandles) {
verify_ref_kind(_masm, JVM_REF_invokeVirtual, member_reg, temp3);
}
// pick out the vtable index from the MemberName, and then we can discard it:
Register temp2_index = temp2;
__ ldr(temp2_index, member_vmindex);
if (VerifyMethodHandles) {
Label L_index_ok;
__ cmpw(temp2_index, 0U);
__ br(Assembler::GE, L_index_ok);
__ hlt(0);
__ BIND(L_index_ok);
}
// Note: The verifier invariants allow us to ignore MemberName.clazz and vmtarget
// at this point. And VerifyMethodHandles has already checked clazz, if needed.
// get target Method* & entry point
__ lookup_virtual_method(temp1_recv_klass, temp2_index, rmethod);
break;
}
case vmIntrinsics::_linkToInterface:
{
// same as TemplateTable::invokeinterface
// (minus the CP setup and profiling, with different argument motion)
if (VerifyMethodHandles) {
verify_ref_kind(_masm, JVM_REF_invokeInterface, member_reg, temp3);
}
Register temp3_intf = temp3;
__ load_heap_oop(temp3_intf, member_clazz);
load_klass_from_Class(_masm, temp3_intf);
__ verify_klass_ptr(temp3_intf);
Register rindex = rmethod;
__ ldr(rindex, member_vmindex);
if (VerifyMethodHandles) {
Label L;
__ cmpw(rindex, 0U);
__ br(Assembler::GE, L);
__ hlt(0);
__ bind(L);
}
// given intf, index, and recv klass, dispatch to the implementation method
__ lookup_interface_method(temp1_recv_klass, temp3_intf,
// note: next two args must be the same:
rindex, rmethod,
temp2,
L_incompatible_class_change_error);
break;
}
default:
fatal("unexpected intrinsic %d: %s", iid, vmIntrinsics::name_at(iid));
break;
}
// live at this point: rmethod, r13 (if interpreted)
// After figuring out which concrete method to call, jump into it.
// Note that this works in the interpreter with no data motion.
// But the compiled version will require that r2_recv be shifted out.
__ verify_method_ptr(rmethod);
jump_from_method_handle(_masm, rmethod, temp1, for_compiler_entry);
if (iid == vmIntrinsics::_linkToInterface) {
__ bind(L_incompatible_class_change_error);
__ far_jump(RuntimeAddress(StubRoutines::throw_IncompatibleClassChangeError_entry()));
}
}
}
void byte_array_set(struct byte_array *within, uint32_t index, uint8_t byte) {
null_check(within);
assert_message(index < within->length, "out of bounds");
within->data[index] = byte;
}
VtableStub* VtableStubs::create_itable_stub(int vtable_index) {
const int code_length = VtableStub::pd_code_size_limit(false);
VtableStub *s = new(code_length) VtableStub(false, vtable_index);
if (s == NULL) { // Indicates OOM in the code cache.
return NULL;
}
ResourceMark rm;
CodeBuffer cb(s->entry_point(), code_length);
MacroAssembler *masm = new MacroAssembler(&cb);
address start_pc;
int padding_bytes = 0;
#if (!defined(PRODUCT) && defined(COMPILER2))
if (CountCompiledCalls) {
// Count unused bytes
// worst case actual size
padding_bytes += __ load_const_size() - __ load_const_optimized_rtn_len(Z_R1_scratch, (long)SharedRuntime::nof_megamorphic_calls_addr(), true);
// Use generic emitter for direct memory increment.
// Use Z_tmp_1 as scratch register for generic emitter.
__ add2mem_32((Z_R1_scratch), 1, Z_tmp_1);
}
#endif
assert(VtableStub::receiver_location() == Z_R2->as_VMReg(), "receiver expected in Z_ARG1");
// Entry arguments:
// Z_method: Interface
// Z_ARG1: Receiver
const Register rcvr_klass = Z_tmp_1; // Used to compute itable_entry_addr.
// Use extra reg to avoid re-load.
const Register vtable_len = Z_tmp_2; // Used to compute itable_entry_addr.
const Register itable_entry_addr = Z_R1_scratch;
const Register itable_interface = Z_R0_scratch;
// Get receiver klass.
// Must do an explicit check if implicit checks are disabled.
address npe_addr = __ pc(); // npe == NULL ptr exception
__ null_check(Z_ARG1, Z_R1_scratch, oopDesc::klass_offset_in_bytes());
__ load_klass(rcvr_klass, Z_ARG1);
// Load start of itable entries into itable_entry.
__ z_llgf(vtable_len, Address(rcvr_klass, InstanceKlass::vtable_length_offset()));
__ z_sllg(vtable_len, vtable_len, exact_log2(vtableEntry::size_in_bytes()));
// Loop over all itable entries until desired interfaceOop(Rinterface) found.
const int vtable_base_offset = in_bytes(InstanceKlass::vtable_start_offset());
// Count unused bytes.
start_pc = __ pc();
__ add2reg_with_index(itable_entry_addr, vtable_base_offset + itableOffsetEntry::interface_offset_in_bytes(), rcvr_klass, vtable_len);
padding_bytes += 20 - (__ pc() - start_pc);
const int itable_offset_search_inc = itableOffsetEntry::size() * wordSize;
Label search;
__ bind(search);
// Handle IncompatibleClassChangeError in itable stubs.
// If the entry is NULL then we've reached the end of the table
// without finding the expected interface, so throw an exception.
NearLabel throw_icce;
__ load_and_test_long(itable_interface, Address(itable_entry_addr));
__ z_bre(throw_icce); // Throw the exception out-of-line.
// Count unused bytes.
start_pc = __ pc();
__ add2reg(itable_entry_addr, itable_offset_search_inc);
padding_bytes += 20 - (__ pc() - start_pc);
__ z_cgr(itable_interface, Z_method);
__ z_brne(search);
// Entry found. Itable_entry_addr points to the subsequent entry (itable_offset_search_inc too far).
// Get offset of vtable for interface.
const Register vtable_offset = Z_R1_scratch;
const Register itable_method = rcvr_klass; // Calculated before.
const int vtable_offset_offset = (itableOffsetEntry::offset_offset_in_bytes() -
itableOffsetEntry::interface_offset_in_bytes()) -
itable_offset_search_inc;
__ z_llgf(vtable_offset, vtable_offset_offset, itable_entry_addr);
// Compute itableMethodEntry and get method and entry point for compiler.
const int method_offset = (itableMethodEntry::size() * wordSize * vtable_index) +
itableMethodEntry::method_offset_in_bytes();
__ z_lg(Z_method, method_offset, vtable_offset, itable_method);
#ifndef PRODUCT
if (DebugVtables) {
Label ok1;
__ z_ltgr(Z_method, Z_method);
__ z_brne(ok1);
__ stop("method is null",103);
__ bind(ok1);
}
#endif
address ame_addr = __ pc();
// Must do an explicit check if implicit checks are disabled.
if (!ImplicitNullChecks) {
__ compare64_and_branch(Z_method, (intptr_t) 0, Assembler::bcondEqual, throw_icce);
}
__ z_lg(Z_R1_scratch, in_bytes(Method::from_compiled_offset()), Z_method);
__ z_br(Z_R1_scratch);
// Handle IncompatibleClassChangeError in itable stubs.
__ bind(throw_icce);
// Count unused bytes
// worst case actual size
// We force resolving of the call site by jumping to
// the "handle wrong method" stub, and so let the
// interpreter runtime do all the dirty work.
padding_bytes += __ load_const_size() - __ load_const_optimized_rtn_len(Z_R1_scratch, (long)SharedRuntime::get_handle_wrong_method_stub(), true);
__ z_br(Z_R1_scratch);
masm->flush();
s->set_exception_points(npe_addr, ame_addr);
return s;
}
// Used by compiler only; may use only caller saved, non-argument registers.
VtableStub* VtableStubs::create_vtable_stub(int vtable_index) {
const int code_length = VtableStub::pd_code_size_limit(true);
VtableStub *s = new(code_length) VtableStub(true, vtable_index);
if (s == NULL) { // Indicates OOM In the code cache.
return NULL;
}
ResourceMark rm;
CodeBuffer cb(s->entry_point(), code_length);
MacroAssembler *masm = new MacroAssembler(&cb);
address start_pc;
int padding_bytes = 0;
#if (!defined(PRODUCT) && defined(COMPILER2))
if (CountCompiledCalls) {
// Count unused bytes
// worst case actual size
padding_bytes += __ load_const_size() - __ load_const_optimized_rtn_len(Z_R1_scratch, (long)SharedRuntime::nof_megamorphic_calls_addr(), true);
// Use generic emitter for direct memory increment.
// Abuse Z_method as scratch register for generic emitter.
// It is loaded further down anyway before it is first used.
__ add2mem_32(Address(Z_R1_scratch), 1, Z_method);
}
#endif
assert(VtableStub::receiver_location() == Z_R2->as_VMReg(), "receiver expected in Z_ARG1");
// Get receiver klass.
// Must do an explicit check if implicit checks are disabled.
address npe_addr = __ pc(); // npe == NULL ptr exception
__ null_check(Z_ARG1, Z_R1_scratch, oopDesc::klass_offset_in_bytes());
const Register rcvr_klass = Z_R1_scratch;
__ load_klass(rcvr_klass, Z_ARG1);
// Set method (in case of interpreted method), and destination address.
int entry_offset = in_bytes(InstanceKlass::vtable_start_offset()) +
vtable_index * vtableEntry::size_in_bytes();
#ifndef PRODUCT
if (DebugVtables) {
Label L;
// Check offset vs vtable length.
const Register vtable_idx = Z_R0_scratch;
// Count unused bytes.
// worst case actual size
padding_bytes += __ load_const_size() - __ load_const_optimized_rtn_len(vtable_idx, vtable_index*vtableEntry::size_in_bytes(), true);
assert(Immediate::is_uimm12(in_bytes(InstanceKlass::vtable_length_offset())), "disp to large");
__ z_cl(vtable_idx, in_bytes(InstanceKlass::vtable_length_offset()), rcvr_klass);
__ z_brl(L);
__ z_lghi(Z_ARG3, vtable_index); // Debug code, don't optimize.
__ call_VM(noreg, CAST_FROM_FN_PTR(address, bad_compiled_vtable_index), Z_ARG1, Z_ARG3, false);
// Count unused bytes (assume worst case here).
padding_bytes += 12;
__ bind(L);
}
#endif
int v_off = entry_offset + vtableEntry::method_offset_in_bytes();
// Duplicate safety code from enc_class Java_Dynamic_Call_dynTOC.
if (Displacement::is_validDisp(v_off)) {
__ z_lg(Z_method/*method oop*/, v_off, rcvr_klass/*class oop*/);
// Account for the load_const in the else path.
padding_bytes += __ load_const_size();
} else {
// Worse case, offset does not fit in displacement field.
__ load_const(Z_method, v_off); // Z_method temporarily holds the offset value.
__ z_lg(Z_method/*method oop*/, 0, Z_method/*method offset*/, rcvr_klass/*class oop*/);
}
#ifndef PRODUCT
if (DebugVtables) {
Label L;
__ z_ltgr(Z_method, Z_method);
__ z_brne(L);
__ stop("Vtable entry is ZERO",102);
__ bind(L);
}
#endif
address ame_addr = __ pc(); // ame = abstract method error
// Must do an explicit check if implicit checks are disabled.
__ null_check(Z_method, Z_R1_scratch, in_bytes(Method::from_compiled_offset()));
__ z_lg(Z_R1_scratch, in_bytes(Method::from_compiled_offset()), Z_method);
__ z_br(Z_R1_scratch);
masm->flush();
s->set_exception_points(npe_addr, ame_addr);
return s;
}
int main(int argc, char *argv[]) {
// Initialize the custom allocator
sf_mem_init(MAX_HEAP_SIZE);
// Tell the user about the fields
info("Initialized heap with %dmb of heap space.\n", MAX_HEAP_SIZE >> 20);
//press_to_cont();
// Print out title for first test
printf("=== Test1: Allocation test ===\n");
// Test #1: Allocate an integer
int *value1 = sf_malloc(sizeof(int));
null_check(value1, sizeof(int));
payload_check(value1);
// Print out the allocator block
sf_varprint(value1);
//press_to_cont();
// Now assign a value
printf("=== Test2: Assignment test ===\n");
info("Attempting to assign value1 = %d\n", VALUE1_VALUE);
// Assign the value
*value1 = VALUE1_VALUE;
// Now check its value
check_prim_contents(value1, VALUE1_VALUE, "%d", "value1");
//press_to_cont();
printf("=== Test3: Allocate a second variable ===\n");
info("Attempting to assign value2 = %ld\n", VALUE2_VALUE);
long *value2 = sf_malloc(sizeof(long));
null_check(value2, sizeof(long));
payload_check(value2);
sf_varprint(value2);
// Assign a value
*value2 = VALUE2_VALUE;
// Check value
check_prim_contents(value2, VALUE2_VALUE, "%ld", "value2");
//press_to_cont();
printf("=== Test4: does value1 still equal %d ===\n", VALUE1_VALUE);
check_prim_contents(value1, VALUE1_VALUE, "%d", "value1");
//press_to_cont();
// Snapshot the freelist
printf("=== Test5: Perform a snapshot ===\n");
sf_snapshot(true);
//press_to_cont();
// Free a variable
printf("=== Test6: Free a block and snapshot ===\n");
info("Freeing value1...\n");
sf_free(value1);
sf_snapshot(true);
//press_to_cont();
// Allocate more memory
printf("=== Test7: 8192 byte allocation ===\n");
void *memory = sf_calloc(4096,1);
sf_varprint(memory);
perror("Testing calloc");
sf_snapshot(true);
memory = sf_malloc(8192);
sf_varprint(memory);
perror("Testing free");
sf_free(memory);
//press_to_cont();
return EXIT_SUCCESS;
}
Node* null_check_receiver() {
assert(argument(0)->bottom_type()->isa_ptr(), "must be");
return null_check(argument(0));
}
//------------------------------------------------------------------------------
// MethodHandles::generate_method_handle_stub
//
// Generate an "entry" field for a method handle.
// This determines how the method handle will respond to calls.
void MethodHandles::generate_method_handle_stub(MacroAssembler* _masm, MethodHandles::EntryKind ek) {
// Here is the register state during an interpreted call,
// as set up by generate_method_handle_interpreter_entry():
// - rbx: garbage temp (was MethodHandle.invoke methodOop, unused)
// - rcx: receiver method handle
// - rax: method handle type (only used by the check_mtype entry point)
// - rsi/r13: sender SP (must preserve; see prepare_to_jump_from_interpreted)
// - rdx: garbage temp, can blow away
const Register rcx_recv = rcx;
const Register rax_argslot = rax;
const Register rbx_temp = rbx;
const Register rdx_temp = rdx;
// This guy is set up by prepare_to_jump_from_interpreted (from interpreted calls)
// and gen_c2i_adapter (from compiled calls):
const Register saved_last_sp = LP64_ONLY(r13) NOT_LP64(rsi);
// Argument registers for _raise_exception.
// 32-bit: Pass first two oop/int args in registers ECX and EDX.
const Register rarg0_code = LP64_ONLY(j_rarg0) NOT_LP64(rcx);
const Register rarg1_actual = LP64_ONLY(j_rarg1) NOT_LP64(rdx);
const Register rarg2_required = LP64_ONLY(j_rarg2) NOT_LP64(rdi);
assert_different_registers(rarg0_code, rarg1_actual, rarg2_required, saved_last_sp);
guarantee(java_lang_invoke_MethodHandle::vmentry_offset_in_bytes() != 0, "must have offsets");
// some handy addresses
Address rbx_method_fie( rbx, methodOopDesc::from_interpreted_offset() );
Address rbx_method_fce( rbx, methodOopDesc::from_compiled_offset() );
Address rcx_mh_vmtarget( rcx_recv, java_lang_invoke_MethodHandle::vmtarget_offset_in_bytes() );
Address rcx_dmh_vmindex( rcx_recv, java_lang_invoke_DirectMethodHandle::vmindex_offset_in_bytes() );
Address rcx_bmh_vmargslot( rcx_recv, java_lang_invoke_BoundMethodHandle::vmargslot_offset_in_bytes() );
Address rcx_bmh_argument( rcx_recv, java_lang_invoke_BoundMethodHandle::argument_offset_in_bytes() );
Address rcx_amh_vmargslot( rcx_recv, java_lang_invoke_AdapterMethodHandle::vmargslot_offset_in_bytes() );
Address rcx_amh_argument( rcx_recv, java_lang_invoke_AdapterMethodHandle::argument_offset_in_bytes() );
Address rcx_amh_conversion( rcx_recv, java_lang_invoke_AdapterMethodHandle::conversion_offset_in_bytes() );
Address vmarg; // __ argument_address(vmargslot)
const int java_mirror_offset = klassOopDesc::klass_part_offset_in_bytes() + Klass::java_mirror_offset_in_bytes();
if (have_entry(ek)) {
__ nop(); // empty stubs make SG sick
return;
}
address interp_entry = __ pc();
trace_method_handle(_masm, entry_name(ek));
BLOCK_COMMENT(entry_name(ek));
switch ((int) ek) {
case _raise_exception:
{
// Not a real MH entry, but rather shared code for raising an
// exception. Since we use the compiled entry, arguments are
// expected in compiler argument registers.
assert(raise_exception_method(), "must be set");
assert(raise_exception_method()->from_compiled_entry(), "method must be linked");
const Register rdi_pc = rax;
__ pop(rdi_pc); // caller PC
__ mov(rsp, saved_last_sp); // cut the stack back to where the caller started
Register rbx_method = rbx_temp;
Label L_no_method;
// FIXME: fill in _raise_exception_method with a suitable java.lang.invoke method
__ movptr(rbx_method, ExternalAddress((address) &_raise_exception_method));
__ testptr(rbx_method, rbx_method);
__ jccb(Assembler::zero, L_no_method);
const int jobject_oop_offset = 0;
__ movptr(rbx_method, Address(rbx_method, jobject_oop_offset)); // dereference the jobject
__ testptr(rbx_method, rbx_method);
__ jccb(Assembler::zero, L_no_method);
__ verify_oop(rbx_method);
NOT_LP64(__ push(rarg2_required));
__ push(rdi_pc); // restore caller PC
__ jmp(rbx_method_fce); // jump to compiled entry
// Do something that is at least causes a valid throw from the interpreter.
__ bind(L_no_method);
__ push(rarg2_required);
__ push(rarg1_actual);
__ jump(ExternalAddress(Interpreter::throw_WrongMethodType_entry()));
}
break;
case _invokestatic_mh:
case _invokespecial_mh:
{
Register rbx_method = rbx_temp;
__ load_heap_oop(rbx_method, rcx_mh_vmtarget); // target is a methodOop
__ verify_oop(rbx_method);
// same as TemplateTable::invokestatic or invokespecial,
// minus the CP setup and profiling:
if (ek == _invokespecial_mh) {
// Must load & check the first argument before entering the target method.
__ load_method_handle_vmslots(rax_argslot, rcx_recv, rdx_temp);
__ movptr(rcx_recv, __ argument_address(rax_argslot, -1));
__ null_check(rcx_recv);
__ verify_oop(rcx_recv);
}
__ jmp(rbx_method_fie);
}
break;
case _invokevirtual_mh:
{
// same as TemplateTable::invokevirtual,
// minus the CP setup and profiling:
// pick out the vtable index and receiver offset from the MH,
// and then we can discard it:
__ load_method_handle_vmslots(rax_argslot, rcx_recv, rdx_temp);
Register rbx_index = rbx_temp;
__ movl(rbx_index, rcx_dmh_vmindex);
// Note: The verifier allows us to ignore rcx_mh_vmtarget.
__ movptr(rcx_recv, __ argument_address(rax_argslot, -1));
__ null_check(rcx_recv, oopDesc::klass_offset_in_bytes());
// get receiver klass
Register rax_klass = rax_argslot;
__ load_klass(rax_klass, rcx_recv);
__ verify_oop(rax_klass);
// get target methodOop & entry point
const int base = instanceKlass::vtable_start_offset() * wordSize;
assert(vtableEntry::size() * wordSize == wordSize, "adjust the scaling in the code below");
Address vtable_entry_addr(rax_klass,
rbx_index, Address::times_ptr,
base + vtableEntry::method_offset_in_bytes());
Register rbx_method = rbx_temp;
__ movptr(rbx_method, vtable_entry_addr);
__ verify_oop(rbx_method);
__ jmp(rbx_method_fie);
}
break;
case _invokeinterface_mh:
{
// same as TemplateTable::invokeinterface,
// minus the CP setup and profiling:
// pick out the interface and itable index from the MH.
__ load_method_handle_vmslots(rax_argslot, rcx_recv, rdx_temp);
Register rdx_intf = rdx_temp;
Register rbx_index = rbx_temp;
__ load_heap_oop(rdx_intf, rcx_mh_vmtarget);
__ movl(rbx_index, rcx_dmh_vmindex);
__ movptr(rcx_recv, __ argument_address(rax_argslot, -1));
__ null_check(rcx_recv, oopDesc::klass_offset_in_bytes());
// get receiver klass
Register rax_klass = rax_argslot;
__ load_klass(rax_klass, rcx_recv);
__ verify_oop(rax_klass);
Register rdi_temp = rdi;
Register rbx_method = rbx_index;
// get interface klass
Label no_such_interface;
__ verify_oop(rdx_intf);
__ lookup_interface_method(rax_klass, rdx_intf,
// note: next two args must be the same:
rbx_index, rbx_method,
rdi_temp,
no_such_interface);
__ verify_oop(rbx_method);
__ jmp(rbx_method_fie);
__ hlt();
__ bind(no_such_interface);
// Throw an exception.
// For historical reasons, it will be IncompatibleClassChangeError.
__ mov(rbx_temp, rcx_recv); // rarg2_required might be RCX
assert_different_registers(rarg2_required, rbx_temp);
__ movptr(rarg2_required, Address(rdx_intf, java_mirror_offset)); // required interface
__ mov( rarg1_actual, rbx_temp); // bad receiver
__ movl( rarg0_code, (int) Bytecodes::_invokeinterface); // who is complaining?
__ jump(ExternalAddress(from_interpreted_entry(_raise_exception)));
}
break;
case _bound_ref_mh:
case _bound_int_mh:
case _bound_long_mh:
case _bound_ref_direct_mh:
case _bound_int_direct_mh:
case _bound_long_direct_mh:
{
bool direct_to_method = (ek >= _bound_ref_direct_mh);
BasicType arg_type = T_ILLEGAL;
int arg_mask = _INSERT_NO_MASK;
int arg_slots = -1;
get_ek_bound_mh_info(ek, arg_type, arg_mask, arg_slots);
// make room for the new argument:
__ movl(rax_argslot, rcx_bmh_vmargslot);
__ lea(rax_argslot, __ argument_address(rax_argslot));
insert_arg_slots(_masm, arg_slots * stack_move_unit(), arg_mask, rax_argslot, rbx_temp, rdx_temp);
// store bound argument into the new stack slot:
__ load_heap_oop(rbx_temp, rcx_bmh_argument);
if (arg_type == T_OBJECT) {
__ movptr(Address(rax_argslot, 0), rbx_temp);
} else {
Address prim_value_addr(rbx_temp, java_lang_boxing_object::value_offset_in_bytes(arg_type));
const int arg_size = type2aelembytes(arg_type);
__ load_sized_value(rdx_temp, prim_value_addr, arg_size, is_signed_subword_type(arg_type), rbx_temp);
__ store_sized_value(Address(rax_argslot, 0), rdx_temp, arg_size, rbx_temp);
}
if (direct_to_method) {
Register rbx_method = rbx_temp;
__ load_heap_oop(rbx_method, rcx_mh_vmtarget);
__ verify_oop(rbx_method);
__ jmp(rbx_method_fie);
} else {
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ verify_oop(rcx_recv);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
}
break;
case _adapter_retype_only:
case _adapter_retype_raw:
// immediately jump to the next MH layer:
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ verify_oop(rcx_recv);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
// This is OK when all parameter types widen.
// It is also OK when a return type narrows.
break;
case _adapter_check_cast:
{
// temps:
Register rbx_klass = rbx_temp; // interesting AMH data
// check a reference argument before jumping to the next layer of MH:
__ movl(rax_argslot, rcx_amh_vmargslot);
vmarg = __ argument_address(rax_argslot);
// What class are we casting to?
__ load_heap_oop(rbx_klass, rcx_amh_argument); // this is a Class object!
__ load_heap_oop(rbx_klass, Address(rbx_klass, java_lang_Class::klass_offset_in_bytes()));
Label done;
__ movptr(rdx_temp, vmarg);
__ testptr(rdx_temp, rdx_temp);
__ jcc(Assembler::zero, done); // no cast if null
__ load_klass(rdx_temp, rdx_temp);
// live at this point:
// - rbx_klass: klass required by the target method
// - rdx_temp: argument klass to test
// - rcx_recv: adapter method handle
__ check_klass_subtype(rdx_temp, rbx_klass, rax_argslot, done);
// If we get here, the type check failed!
// Call the wrong_method_type stub, passing the failing argument type in rax.
Register rax_mtype = rax_argslot;
__ movl(rax_argslot, rcx_amh_vmargslot); // reload argslot field
__ movptr(rdx_temp, vmarg);
assert_different_registers(rarg2_required, rdx_temp);
__ load_heap_oop(rarg2_required, rcx_amh_argument); // required class
__ mov( rarg1_actual, rdx_temp); // bad object
__ movl( rarg0_code, (int) Bytecodes::_checkcast); // who is complaining?
__ jump(ExternalAddress(from_interpreted_entry(_raise_exception)));
__ bind(done);
// get the new MH:
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
break;
case _adapter_prim_to_prim:
case _adapter_ref_to_prim:
// handled completely by optimized cases
__ stop("init_AdapterMethodHandle should not issue this");
break;
case _adapter_opt_i2i: // optimized subcase of adapt_prim_to_prim
//case _adapter_opt_f2i: // optimized subcase of adapt_prim_to_prim
case _adapter_opt_l2i: // optimized subcase of adapt_prim_to_prim
case _adapter_opt_unboxi: // optimized subcase of adapt_ref_to_prim
{
// perform an in-place conversion to int or an int subword
__ movl(rax_argslot, rcx_amh_vmargslot);
vmarg = __ argument_address(rax_argslot);
switch (ek) {
case _adapter_opt_i2i:
__ movl(rdx_temp, vmarg);
break;
case _adapter_opt_l2i:
{
// just delete the extra slot; on a little-endian machine we keep the first
__ lea(rax_argslot, __ argument_address(rax_argslot, 1));
remove_arg_slots(_masm, -stack_move_unit(),
rax_argslot, rbx_temp, rdx_temp);
vmarg = Address(rax_argslot, -Interpreter::stackElementSize);
__ movl(rdx_temp, vmarg);
}
break;
case _adapter_opt_unboxi:
{
// Load the value up from the heap.
__ movptr(rdx_temp, vmarg);
int value_offset = java_lang_boxing_object::value_offset_in_bytes(T_INT);
#ifdef ASSERT
for (int bt = T_BOOLEAN; bt < T_INT; bt++) {
if (is_subword_type(BasicType(bt)))
assert(value_offset == java_lang_boxing_object::value_offset_in_bytes(BasicType(bt)), "");
}
#endif
__ null_check(rdx_temp, value_offset);
__ movl(rdx_temp, Address(rdx_temp, value_offset));
// We load this as a word. Because we are little-endian,
// the low bits will be correct, but the high bits may need cleaning.
// The vminfo will guide us to clean those bits.
}
break;
default:
ShouldNotReachHere();
}
// Do the requested conversion and store the value.
Register rbx_vminfo = rbx_temp;
__ movl(rbx_vminfo, rcx_amh_conversion);
assert(CONV_VMINFO_SHIFT == 0, "preshifted");
// get the new MH:
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
// (now we are done with the old MH)
// original 32-bit vmdata word must be of this form:
// | MBZ:6 | signBitCount:8 | srcDstTypes:8 | conversionOp:8 |
__ xchgptr(rcx, rbx_vminfo); // free rcx for shifts
__ shll(rdx_temp /*, rcx*/);
Label zero_extend, done;
__ testl(rcx, CONV_VMINFO_SIGN_FLAG);
__ jccb(Assembler::zero, zero_extend);
// this path is taken for int->byte, int->short
__ sarl(rdx_temp /*, rcx*/);
__ jmpb(done);
__ bind(zero_extend);
// this is taken for int->char
__ shrl(rdx_temp /*, rcx*/);
__ bind(done);
__ movl(vmarg, rdx_temp); // Store the value.
__ xchgptr(rcx, rbx_vminfo); // restore rcx_recv
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
break;
case _adapter_opt_i2l: // optimized subcase of adapt_prim_to_prim
case _adapter_opt_unboxl: // optimized subcase of adapt_ref_to_prim
{
// perform an in-place int-to-long or ref-to-long conversion
__ movl(rax_argslot, rcx_amh_vmargslot);
// on a little-endian machine we keep the first slot and add another after
__ lea(rax_argslot, __ argument_address(rax_argslot, 1));
insert_arg_slots(_masm, stack_move_unit(), _INSERT_INT_MASK,
rax_argslot, rbx_temp, rdx_temp);
Address vmarg1(rax_argslot, -Interpreter::stackElementSize);
Address vmarg2 = vmarg1.plus_disp(Interpreter::stackElementSize);
switch (ek) {
case _adapter_opt_i2l:
{
#ifdef _LP64
__ movslq(rdx_temp, vmarg1); // Load sign-extended
__ movq(vmarg1, rdx_temp); // Store into first slot
#else
__ movl(rdx_temp, vmarg1);
__ sarl(rdx_temp, BitsPerInt - 1); // __ extend_sign()
__ movl(vmarg2, rdx_temp); // store second word
#endif
}
break;
case _adapter_opt_unboxl:
{
// Load the value up from the heap.
__ movptr(rdx_temp, vmarg1);
int value_offset = java_lang_boxing_object::value_offset_in_bytes(T_LONG);
assert(value_offset == java_lang_boxing_object::value_offset_in_bytes(T_DOUBLE), "");
__ null_check(rdx_temp, value_offset);
#ifdef _LP64
__ movq(rbx_temp, Address(rdx_temp, value_offset));
__ movq(vmarg1, rbx_temp);
#else
__ movl(rbx_temp, Address(rdx_temp, value_offset + 0*BytesPerInt));
__ movl(rdx_temp, Address(rdx_temp, value_offset + 1*BytesPerInt));
__ movl(vmarg1, rbx_temp);
__ movl(vmarg2, rdx_temp);
#endif
}
break;
default:
ShouldNotReachHere();
}
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
break;
case _adapter_opt_f2d: // optimized subcase of adapt_prim_to_prim
case _adapter_opt_d2f: // optimized subcase of adapt_prim_to_prim
{
// perform an in-place floating primitive conversion
__ movl(rax_argslot, rcx_amh_vmargslot);
__ lea(rax_argslot, __ argument_address(rax_argslot, 1));
if (ek == _adapter_opt_f2d) {
insert_arg_slots(_masm, stack_move_unit(), _INSERT_INT_MASK,
rax_argslot, rbx_temp, rdx_temp);
}
Address vmarg(rax_argslot, -Interpreter::stackElementSize);
#ifdef _LP64
if (ek == _adapter_opt_f2d) {
__ movflt(xmm0, vmarg);
__ cvtss2sd(xmm0, xmm0);
__ movdbl(vmarg, xmm0);
} else {
__ movdbl(xmm0, vmarg);
__ cvtsd2ss(xmm0, xmm0);
__ movflt(vmarg, xmm0);
}
#else //_LP64
if (ek == _adapter_opt_f2d) {
__ fld_s(vmarg); // load float to ST0
__ fstp_s(vmarg); // store single
} else {
__ fld_d(vmarg); // load double to ST0
__ fstp_s(vmarg); // store single
}
#endif //_LP64
if (ek == _adapter_opt_d2f) {
remove_arg_slots(_masm, -stack_move_unit(),
rax_argslot, rbx_temp, rdx_temp);
}
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
break;
case _adapter_prim_to_ref:
__ unimplemented(entry_name(ek)); // %%% FIXME: NYI
break;
case _adapter_swap_args:
case _adapter_rot_args:
// handled completely by optimized cases
__ stop("init_AdapterMethodHandle should not issue this");
break;
case _adapter_opt_swap_1:
case _adapter_opt_swap_2:
case _adapter_opt_rot_1_up:
case _adapter_opt_rot_1_down:
case _adapter_opt_rot_2_up:
case _adapter_opt_rot_2_down:
{
int swap_bytes = 0, rotate = 0;
get_ek_adapter_opt_swap_rot_info(ek, swap_bytes, rotate);
// 'argslot' is the position of the first argument to swap
__ movl(rax_argslot, rcx_amh_vmargslot);
__ lea(rax_argslot, __ argument_address(rax_argslot));
// 'vminfo' is the second
Register rbx_destslot = rbx_temp;
__ movl(rbx_destslot, rcx_amh_conversion);
assert(CONV_VMINFO_SHIFT == 0, "preshifted");
__ andl(rbx_destslot, CONV_VMINFO_MASK);
__ lea(rbx_destslot, __ argument_address(rbx_destslot));
DEBUG_ONLY(verify_argslot(_masm, rbx_destslot, "swap point must fall within current frame"));
if (!rotate) {
for (int i = 0; i < swap_bytes; i += wordSize) {
__ movptr(rdx_temp, Address(rax_argslot , i));
__ push(rdx_temp);
__ movptr(rdx_temp, Address(rbx_destslot, i));
__ movptr(Address(rax_argslot, i), rdx_temp);
__ pop(rdx_temp);
__ movptr(Address(rbx_destslot, i), rdx_temp);
}
} else {
// push the first chunk, which is going to get overwritten
for (int i = swap_bytes; (i -= wordSize) >= 0; ) {
__ movptr(rdx_temp, Address(rax_argslot, i));
__ push(rdx_temp);
}
if (rotate > 0) {
// rotate upward
__ subptr(rax_argslot, swap_bytes);
#ifdef ASSERT
{
// Verify that argslot > destslot, by at least swap_bytes.
Label L_ok;
__ cmpptr(rax_argslot, rbx_destslot);
__ jccb(Assembler::aboveEqual, L_ok);
__ stop("source must be above destination (upward rotation)");
__ bind(L_ok);
}
#endif
// work argslot down to destslot, copying contiguous data upwards
// pseudo-code:
// rax = src_addr - swap_bytes
// rbx = dest_addr
// while (rax >= rbx) *(rax + swap_bytes) = *(rax + 0), rax--;
Label loop;
__ bind(loop);
__ movptr(rdx_temp, Address(rax_argslot, 0));
__ movptr(Address(rax_argslot, swap_bytes), rdx_temp);
__ addptr(rax_argslot, -wordSize);
__ cmpptr(rax_argslot, rbx_destslot);
__ jccb(Assembler::aboveEqual, loop);
} else {
__ addptr(rax_argslot, swap_bytes);
#ifdef ASSERT
{
// Verify that argslot < destslot, by at least swap_bytes.
Label L_ok;
__ cmpptr(rax_argslot, rbx_destslot);
__ jccb(Assembler::belowEqual, L_ok);
__ stop("source must be below destination (downward rotation)");
__ bind(L_ok);
}
#endif
// work argslot up to destslot, copying contiguous data downwards
// pseudo-code:
// rax = src_addr + swap_bytes
// rbx = dest_addr
// while (rax <= rbx) *(rax - swap_bytes) = *(rax + 0), rax++;
Label loop;
__ bind(loop);
__ movptr(rdx_temp, Address(rax_argslot, 0));
__ movptr(Address(rax_argslot, -swap_bytes), rdx_temp);
__ addptr(rax_argslot, wordSize);
__ cmpptr(rax_argslot, rbx_destslot);
__ jccb(Assembler::belowEqual, loop);
}
// pop the original first chunk into the destination slot, now free
for (int i = 0; i < swap_bytes; i += wordSize) {
__ pop(rdx_temp);
__ movptr(Address(rbx_destslot, i), rdx_temp);
}
}
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
break;
case _adapter_dup_args:
{
// 'argslot' is the position of the first argument to duplicate
__ movl(rax_argslot, rcx_amh_vmargslot);
__ lea(rax_argslot, __ argument_address(rax_argslot));
// 'stack_move' is negative number of words to duplicate
Register rdx_stack_move = rdx_temp;
__ movl2ptr(rdx_stack_move, rcx_amh_conversion);
__ sarptr(rdx_stack_move, CONV_STACK_MOVE_SHIFT);
int argslot0_num = 0;
Address argslot0 = __ argument_address(RegisterOrConstant(argslot0_num));
assert(argslot0.base() == rsp, "");
int pre_arg_size = argslot0.disp();
assert(pre_arg_size % wordSize == 0, "");
assert(pre_arg_size > 0, "must include PC");
// remember the old rsp+1 (argslot[0])
Register rbx_oldarg = rbx_temp;
__ lea(rbx_oldarg, argslot0);
// move rsp down to make room for dups
__ lea(rsp, Address(rsp, rdx_stack_move, Address::times_ptr));
// compute the new rsp+1 (argslot[0])
Register rdx_newarg = rdx_temp;
__ lea(rdx_newarg, argslot0);
__ push(rdi); // need a temp
// (preceding push must be done after arg addresses are taken!)
// pull down the pre_arg_size data (PC)
for (int i = -pre_arg_size; i < 0; i += wordSize) {
__ movptr(rdi, Address(rbx_oldarg, i));
__ movptr(Address(rdx_newarg, i), rdi);
}
// copy from rax_argslot[0...] down to new_rsp[1...]
// pseudo-code:
// rbx = old_rsp+1
// rdx = new_rsp+1
// rax = argslot
// while (rdx < rbx) *rdx++ = *rax++
Label loop;
__ bind(loop);
__ movptr(rdi, Address(rax_argslot, 0));
__ movptr(Address(rdx_newarg, 0), rdi);
__ addptr(rax_argslot, wordSize);
__ addptr(rdx_newarg, wordSize);
__ cmpptr(rdx_newarg, rbx_oldarg);
__ jccb(Assembler::less, loop);
__ pop(rdi); // restore temp
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
break;
case _adapter_drop_args:
{
// 'argslot' is the position of the first argument to nuke
__ movl(rax_argslot, rcx_amh_vmargslot);
__ lea(rax_argslot, __ argument_address(rax_argslot));
__ push(rdi); // need a temp
// (must do previous push after argslot address is taken)
// 'stack_move' is number of words to drop
Register rdi_stack_move = rdi;
__ movl2ptr(rdi_stack_move, rcx_amh_conversion);
__ sarptr(rdi_stack_move, CONV_STACK_MOVE_SHIFT);
remove_arg_slots(_masm, rdi_stack_move,
rax_argslot, rbx_temp, rdx_temp);
__ pop(rdi); // restore temp
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
}
break;
case _adapter_collect_args:
__ unimplemented(entry_name(ek)); // %%% FIXME: NYI
break;
case _adapter_spread_args:
// handled completely by optimized cases
__ stop("init_AdapterMethodHandle should not issue this");
break;
case _adapter_opt_spread_0:
case _adapter_opt_spread_1:
case _adapter_opt_spread_more:
{
// spread an array out into a group of arguments
int length_constant = get_ek_adapter_opt_spread_info(ek);
// find the address of the array argument
__ movl(rax_argslot, rcx_amh_vmargslot);
__ lea(rax_argslot, __ argument_address(rax_argslot));
// grab some temps
{ __ push(rsi); __ push(rdi); }
// (preceding pushes must be done after argslot address is taken!)
#define UNPUSH_RSI_RDI \
{ __ pop(rdi); __ pop(rsi); }
// arx_argslot points both to the array and to the first output arg
vmarg = Address(rax_argslot, 0);
// Get the array value.
Register rsi_array = rsi;
Register rdx_array_klass = rdx_temp;
BasicType elem_type = T_OBJECT;
int length_offset = arrayOopDesc::length_offset_in_bytes();
int elem0_offset = arrayOopDesc::base_offset_in_bytes(elem_type);
__ movptr(rsi_array, vmarg);
Label skip_array_check;
if (length_constant == 0) {
__ testptr(rsi_array, rsi_array);
__ jcc(Assembler::zero, skip_array_check);
}
__ null_check(rsi_array, oopDesc::klass_offset_in_bytes());
__ load_klass(rdx_array_klass, rsi_array);
// Check the array type.
Register rbx_klass = rbx_temp;
__ load_heap_oop(rbx_klass, rcx_amh_argument); // this is a Class object!
__ load_heap_oop(rbx_klass, Address(rbx_klass, java_lang_Class::klass_offset_in_bytes()));
Label ok_array_klass, bad_array_klass, bad_array_length;
__ check_klass_subtype(rdx_array_klass, rbx_klass, rdi, ok_array_klass);
// If we get here, the type check failed!
__ jmp(bad_array_klass);
__ bind(ok_array_klass);
// Check length.
if (length_constant >= 0) {
__ cmpl(Address(rsi_array, length_offset), length_constant);
} else {
Register rbx_vminfo = rbx_temp;
__ movl(rbx_vminfo, rcx_amh_conversion);
assert(CONV_VMINFO_SHIFT == 0, "preshifted");
__ andl(rbx_vminfo, CONV_VMINFO_MASK);
__ cmpl(rbx_vminfo, Address(rsi_array, length_offset));
}
__ jcc(Assembler::notEqual, bad_array_length);
Register rdx_argslot_limit = rdx_temp;
// Array length checks out. Now insert any required stack slots.
if (length_constant == -1) {
// Form a pointer to the end of the affected region.
__ lea(rdx_argslot_limit, Address(rax_argslot, Interpreter::stackElementSize));
// 'stack_move' is negative number of words to insert
Register rdi_stack_move = rdi;
__ movl2ptr(rdi_stack_move, rcx_amh_conversion);
__ sarptr(rdi_stack_move, CONV_STACK_MOVE_SHIFT);
Register rsi_temp = rsi_array; // spill this
insert_arg_slots(_masm, rdi_stack_move, -1,
rax_argslot, rbx_temp, rsi_temp);
// reload the array (since rsi was killed)
__ movptr(rsi_array, vmarg);
} else if (length_constant > 1) {
int arg_mask = 0;
int new_slots = (length_constant - 1);
for (int i = 0; i < new_slots; i++) {
arg_mask <<= 1;
arg_mask |= _INSERT_REF_MASK;
}
insert_arg_slots(_masm, new_slots * stack_move_unit(), arg_mask,
rax_argslot, rbx_temp, rdx_temp);
} else if (length_constant == 1) {
// no stack resizing required
} else if (length_constant == 0) {
remove_arg_slots(_masm, -stack_move_unit(),
rax_argslot, rbx_temp, rdx_temp);
}
// Copy from the array to the new slots.
// Note: Stack change code preserves integrity of rax_argslot pointer.
// So even after slot insertions, rax_argslot still points to first argument.
if (length_constant == -1) {
// [rax_argslot, rdx_argslot_limit) is the area we are inserting into.
Register rsi_source = rsi_array;
__ lea(rsi_source, Address(rsi_array, elem0_offset));
Label loop;
__ bind(loop);
__ movptr(rbx_temp, Address(rsi_source, 0));
__ movptr(Address(rax_argslot, 0), rbx_temp);
__ addptr(rsi_source, type2aelembytes(elem_type));
__ addptr(rax_argslot, Interpreter::stackElementSize);
__ cmpptr(rax_argslot, rdx_argslot_limit);
__ jccb(Assembler::less, loop);
} else if (length_constant == 0) {
__ bind(skip_array_check);
// nothing to copy
} else {
int elem_offset = elem0_offset;
int slot_offset = 0;
for (int index = 0; index < length_constant; index++) {
__ movptr(rbx_temp, Address(rsi_array, elem_offset));
__ movptr(Address(rax_argslot, slot_offset), rbx_temp);
elem_offset += type2aelembytes(elem_type);
slot_offset += Interpreter::stackElementSize;
}
}
// Arguments are spread. Move to next method handle.
UNPUSH_RSI_RDI;
__ load_heap_oop(rcx_recv, rcx_mh_vmtarget);
__ jump_to_method_handle_entry(rcx_recv, rdx_temp);
__ bind(bad_array_klass);
UNPUSH_RSI_RDI;
assert(!vmarg.uses(rarg2_required), "must be different registers");
__ movptr(rarg2_required, Address(rdx_array_klass, java_mirror_offset)); // required type
__ movptr(rarg1_actual, vmarg); // bad array
__ movl( rarg0_code, (int) Bytecodes::_aaload); // who is complaining?
__ jump(ExternalAddress(from_interpreted_entry(_raise_exception)));
__ bind(bad_array_length);
UNPUSH_RSI_RDI;
assert(!vmarg.uses(rarg2_required), "must be different registers");
__ mov (rarg2_required, rcx_recv); // AMH requiring a certain length
__ movptr(rarg1_actual, vmarg); // bad array
__ movl( rarg0_code, (int) Bytecodes::_arraylength); // who is complaining?
__ jump(ExternalAddress(from_interpreted_entry(_raise_exception)));
#undef UNPUSH_RSI_RDI
}
break;
case _adapter_flyby:
case _adapter_ricochet:
__ unimplemented(entry_name(ek)); // %%% FIXME: NYI
break;
default: ShouldNotReachHere();
}
__ hlt();
address me_cookie = MethodHandleEntry::start_compiled_entry(_masm, interp_entry);
__ unimplemented(entry_name(ek)); // %%% FIXME: NYI
init_entry(ek, MethodHandleEntry::finish_compiled_entry(_masm, me_cookie));
}
void LIR_Assembler::emit_op1(LIR_Op1* op) {
switch (op->code()) {
case lir_move:
if (op->move_kind() == lir_move_volatile) {
assert(op->patch_code() == lir_patch_none, "can't patch volatiles");
volatile_move_op(op->in_opr(), op->result_opr(), op->type(), op->info());
} else {
move_op(op->in_opr(),op->result_opr(),op->tmp1_opr(),op->tmp2_opr(),op->tmp3_opr(),op->type(),
op->patch_code(), op->info(), op->move_kind() == lir_move_unaligned);
}
break;
case lir_prefetchr:
prefetchr(op->in_opr());
break;
case lir_prefetchw:
prefetchw(op->in_opr());
break;
case lir_return:
return_op(op->in_opr());
break;
case lir_branch:
break;
case lir_push:
push(op->in_opr());
break;
case lir_pop:
pop(op->in_opr());
break;
case lir_neg:
negate(op->in_opr(), op->result_opr());
break;
case lir_bit_test:
bit_test(op->in_opr(),op->result_opr());
break;
case lir_leal:
leal(op->in_opr(), op->result_opr());
break;
case lir_null_check:
if (GenerateCompilerNullChecks) {
null_check(op->in_opr(),op->info());
}
break;
case lir_klassTable_oop_load:
klassTable_oop_load(op->in_opr(), op->result_opr(), op->tmp1_opr());
break;
case lir_monaddr:
monitor_address(op->in_opr()->as_constant_ptr()->as_jint(), op->result_opr());
break;
default:
Unimplemented();
break;
}
}
void global_free(void) {
null_check();
globals->free_all(globals, &free);
};
int global_get_bool(const char * id) {
null_check();
int * ip = (int *) globals->get(globals, id);
if(ip != NULL){ return *ip; }
return 0;
};
char * global_get_str(const char * id) {
null_check();
return (char *) globals->get(globals, id);
};
