void MethodHandles::trace_method_handle(MacroAssembler* _masm, const char* adaptername) { if (!TraceMethodHandles) return; BLOCK_COMMENT("trace_method_handle {"); __ enter(); __ andptr(rsp, -16); // align stack if needed for FPU state __ pusha(); __ mov(rbx, rsp); // for retreiving saved_regs // Note: saved_regs must be in the entered frame for the // robust stack walking implemented in trace_method_handle_stub. // save FP result, valid at some call sites (adapter_opt_return_float, ...) __ increment(rsp, -2 * wordSize); if (UseSSE >= 2) { __ movdbl(Address(rsp, 0), xmm0); } else if (UseSSE == 1) { __ movflt(Address(rsp, 0), xmm0); } else { __ fst_d(Address(rsp, 0)); } // Incoming state: // rcx: method handle // // To avoid calling convention issues, build a record on the stack // and pass the pointer to that instead. __ push(rbp); // entry_sp (with extra align space) __ push(rbx); // pusha saved_regs __ push(rcx); // mh __ push(rcx); // slot for adaptername __ movptr(Address(rsp, 0), (intptr_t) adaptername); __ super_call_VM_leaf(CAST_FROM_FN_PTR(address, trace_method_handle_stub_wrapper), rsp); __ increment(rsp, sizeof(MethodHandleStubArguments)); if (UseSSE >= 2) { __ movdbl(xmm0, Address(rsp, 0)); } else if (UseSSE == 1) { __ movflt(xmm0, Address(rsp, 0)); } else { __ fld_d(Address(rsp, 0)); } __ increment(rsp, 2 * wordSize); __ popa(); __ leave(); BLOCK_COMMENT("} trace_method_handle"); }
void InterpreterRuntime::SignatureHandlerGenerator::pass_double() { const Address src(from(), Interpreter::local_offset_in_bytes(offset() + 1)); #ifdef _WIN64 if (_num_args < Argument::n_float_register_parameters_c-1) { __ movdbl(as_XMMRegister(++_num_args), src); } else { __ movptr(rax, src); __ movptr(Address(to(), _stack_offset), rax); _stack_offset += wordSize; } #else if (_num_fp_args < Argument::n_float_register_parameters_c) { __ movdbl(as_XMMRegister(_num_fp_args++), src); } else { __ movptr(rax, src); __ movptr(Address(to(), _stack_offset), rax); _stack_offset += wordSize; } #endif }
/** * Method entry for static native method: * java.lang.Double.longBitsToDouble(long bits) */ address InterpreterGenerator::generate_Double_longBitsToDouble_entry() { if (UseSSE >= 2) { address entry = __ pc(); // rsi: the sender's SP // Skip safepoint check (compiler intrinsic versions of this method // do not perform safepoint checks either). // Load 'bits' into xmm0 (interpreter returns results in xmm0) __ movdbl(xmm0, Address(rsp, wordSize)); // Return __ pop(rdi); // get return address __ mov(rsp, rsi); // set rsp to the sender's SP __ jmp(rdi); return entry; } return NULL; }
address TemplateInterpreterGenerator::generate_slow_signature_handler() { address entry = __ pc(); // rbx: method // r14: pointer to locals // c_rarg3: first stack arg - wordSize __ mov(c_rarg3, rsp); // adjust rsp __ subptr(rsp, 4 * wordSize); __ call_VM(noreg, CAST_FROM_FN_PTR(address, InterpreterRuntime::slow_signature_handler), rbx, r14, c_rarg3); // rax: result handler // Stack layout: // rsp: 3 integer or float args (if static first is unused) // 1 float/double identifiers // return address // stack args // garbage // expression stack bottom // bcp (NULL) // ... // Do FP first so we can use c_rarg3 as temp __ movl(c_rarg3, Address(rsp, 3 * wordSize)); // float/double identifiers for ( int i= 0; i < Argument::n_int_register_parameters_c-1; i++ ) { XMMRegister floatreg = as_XMMRegister(i+1); Label isfloatordouble, isdouble, next; __ testl(c_rarg3, 1 << (i*2)); // Float or Double? __ jcc(Assembler::notZero, isfloatordouble); // Do Int register here switch ( i ) { case 0: __ movl(rscratch1, Address(rbx, Method::access_flags_offset())); __ testl(rscratch1, JVM_ACC_STATIC); __ cmovptr(Assembler::zero, c_rarg1, Address(rsp, 0)); break; case 1: __ movptr(c_rarg2, Address(rsp, wordSize)); break; case 2: __ movptr(c_rarg3, Address(rsp, 2 * wordSize)); break; default: break; } __ jmp (next); __ bind(isfloatordouble); __ testl(c_rarg3, 1 << ((i*2)+1)); // Double? __ jcc(Assembler::notZero, isdouble); // Do Float Here __ movflt(floatreg, Address(rsp, i * wordSize)); __ jmp(next); // Do Double here __ bind(isdouble); __ movdbl(floatreg, Address(rsp, i * wordSize)); __ bind(next); } // restore rsp __ addptr(rsp, 4 * wordSize); __ ret(0); return entry; }
address TemplateInterpreterGenerator::generate_math_entry(AbstractInterpreter::MethodKind kind) { // rbx,: Method* // rcx: scratrch // r13: sender sp if (!InlineIntrinsics) return NULL; // Generate a vanilla entry address entry_point = __ pc(); // These don't need a safepoint check because they aren't virtually // callable. We won't enter these intrinsics from compiled code. // If in the future we added an intrinsic which was virtually callable // we'd have to worry about how to safepoint so that this code is used. // mathematical functions inlined by compiler // (interpreter must provide identical implementation // in order to avoid monotonicity bugs when switching // from interpreter to compiler in the middle of some // computation) // // stack: [ ret adr ] <-- rsp // [ lo(arg) ] // [ hi(arg) ] // if (kind == Interpreter::java_lang_math_fmaD) { __ movdbl(xmm0, Address(rsp, wordSize)); __ movdbl(xmm1, Address(rsp, 3 * wordSize)); __ movdbl(xmm2, Address(rsp, 5 * wordSize)); __ fmad(xmm0, xmm1, xmm2, xmm0); } else if (kind == Interpreter::java_lang_math_fmaF) { __ movflt(xmm0, Address(rsp, wordSize)); __ movflt(xmm1, Address(rsp, 2 * wordSize)); __ movflt(xmm2, Address(rsp, 3 * wordSize)); __ fmaf(xmm0, xmm1, xmm2, xmm0); } else if (kind == Interpreter::java_lang_math_sqrt) { __ sqrtsd(xmm0, Address(rsp, wordSize)); } else if (kind == Interpreter::java_lang_math_exp) { __ movdbl(xmm0, Address(rsp, wordSize)); if (StubRoutines::dexp() != NULL) { __ call(RuntimeAddress(CAST_FROM_FN_PTR(address, StubRoutines::dexp()))); } else { __ call_VM_leaf0(CAST_FROM_FN_PTR(address, SharedRuntime::dexp)); } } else if (kind == Interpreter::java_lang_math_log) { __ movdbl(xmm0, Address(rsp, wordSize)); if (StubRoutines::dlog() != NULL) { __ call(RuntimeAddress(CAST_FROM_FN_PTR(address, StubRoutines::dlog()))); } else { __ call_VM_leaf0(CAST_FROM_FN_PTR(address, SharedRuntime::dlog)); } } else if (kind == Interpreter::java_lang_math_log10) { __ movdbl(xmm0, Address(rsp, wordSize)); if (StubRoutines::dlog10() != NULL) { __ call(RuntimeAddress(CAST_FROM_FN_PTR(address, StubRoutines::dlog10()))); } else { __ call_VM_leaf0(CAST_FROM_FN_PTR(address, SharedRuntime::dlog10)); } } else if (kind == Interpreter::java_lang_math_sin) { __ movdbl(xmm0, Address(rsp, wordSize)); if (StubRoutines::dsin() != NULL) { __ call(RuntimeAddress(CAST_FROM_FN_PTR(address, StubRoutines::dsin()))); } else { __ call_VM_leaf0(CAST_FROM_FN_PTR(address, SharedRuntime::dsin)); } } else if (kind == Interpreter::java_lang_math_cos) { __ movdbl(xmm0, Address(rsp, wordSize)); if (StubRoutines::dcos() != NULL) { __ call(RuntimeAddress(CAST_FROM_FN_PTR(address, StubRoutines::dcos()))); } else { __ call_VM_leaf0(CAST_FROM_FN_PTR(address, SharedRuntime::dcos)); } } else if (kind == Interpreter::java_lang_math_pow) { __ movdbl(xmm1, Address(rsp, wordSize)); __ movdbl(xmm0, Address(rsp, 3 * wordSize)); if (StubRoutines::dpow() != NULL) { __ call(RuntimeAddress(CAST_FROM_FN_PTR(address, StubRoutines::dpow()))); } else { __ call_VM_leaf0(CAST_FROM_FN_PTR(address, SharedRuntime::dpow)); } } else if (kind == Interpreter::java_lang_math_tan) { __ movdbl(xmm0, Address(rsp, wordSize)); if (StubRoutines::dtan() != NULL) { __ call(RuntimeAddress(CAST_FROM_FN_PTR(address, StubRoutines::dtan()))); } else { __ call_VM_leaf0(CAST_FROM_FN_PTR(address, SharedRuntime::dtan)); } } else { __ fld_d(Address(rsp, wordSize)); switch (kind) { case Interpreter::java_lang_math_abs: __ fabs(); break; default: ShouldNotReachHere(); } // return double result in xmm0 for interpreter and compilers. __ subptr(rsp, 2*wordSize); // Round to 64bit precision __ fstp_d(Address(rsp, 0)); __ movdbl(xmm0, Address(rsp, 0)); __ addptr(rsp, 2*wordSize); } __ pop(rax); __ mov(rsp, r13); __ jmp(rax); return entry_point; }
address TemplateInterpreterGenerator::generate_slow_signature_handler() { address entry = __ pc(); // rbx: method // r14: pointer to locals // c_rarg3: first stack arg - wordSize __ mov(c_rarg3, rsp); // adjust rsp __ subptr(rsp, 14 * wordSize); __ call_VM(noreg, CAST_FROM_FN_PTR(address, InterpreterRuntime::slow_signature_handler), rbx, r14, c_rarg3); // rax: result handler // Stack layout: // rsp: 5 integer args (if static first is unused) // 1 float/double identifiers // 8 double args // return address // stack args // garbage // expression stack bottom // bcp (NULL) // ... // Do FP first so we can use c_rarg3 as temp __ movl(c_rarg3, Address(rsp, 5 * wordSize)); // float/double identifiers for (int i = 0; i < Argument::n_float_register_parameters_c; i++) { const XMMRegister r = as_XMMRegister(i); Label d, done; __ testl(c_rarg3, 1 << i); __ jcc(Assembler::notZero, d); __ movflt(r, Address(rsp, (6 + i) * wordSize)); __ jmp(done); __ bind(d); __ movdbl(r, Address(rsp, (6 + i) * wordSize)); __ bind(done); } // Now handle integrals. Only do c_rarg1 if not static. __ movl(c_rarg3, Address(rbx, Method::access_flags_offset())); __ testl(c_rarg3, JVM_ACC_STATIC); __ cmovptr(Assembler::zero, c_rarg1, Address(rsp, 0)); __ movptr(c_rarg2, Address(rsp, wordSize)); __ movptr(c_rarg3, Address(rsp, 2 * wordSize)); __ movptr(c_rarg4, Address(rsp, 3 * wordSize)); __ movptr(c_rarg5, Address(rsp, 4 * wordSize)); // restore rsp __ addptr(rsp, 14 * wordSize); __ ret(0); return entry; }
address JNI_FastGetField::generate_fast_get_float_field0(BasicType type) { const char *name; switch (type) { case T_FLOAT: name = "jni_fast_GetFloatField"; break; case T_DOUBLE: name = "jni_fast_GetDoubleField"; break; default: ShouldNotReachHere(); } ResourceMark rm; BufferBlob* b = BufferBlob::create(name, BUFFER_SIZE*wordSize); address fast_entry = b->instructions_begin(); CodeBuffer cbuf(fast_entry, b->instructions_size()); MacroAssembler* masm = new MacroAssembler(&cbuf); Label slow_with_pop, slow; // stack layout: offset from rsp (in words): // return pc 0 // jni env 1 // obj 2 // jfieldID 3 ExternalAddress counter(SafepointSynchronize::safepoint_counter_addr()); __ mov32 (rcx, counter); __ testb (rcx, 1); __ jcc (Assembler::notZero, slow); if (os::is_MP()) { __ mov(rax, rcx); __ andptr(rax, 1); // rax, must end up 0 __ movptr(rdx, Address(rsp, rax, Address::times_1, 2*wordSize)); // obj, notice rax, is 0. // rdx is data dependent on rcx. } else { __ movptr(rdx, Address(rsp, 2*wordSize)); // obj } __ movptr(rax, Address(rsp, 3*wordSize)); // jfieldID __ movptr(rdx, Address(rdx, 0)); // *obj __ shrptr(rax, 2); // offset assert(count < LIST_CAPACITY, "LIST_CAPACITY too small"); speculative_load_pclist[count] = __ pc(); switch (type) { #ifndef _LP64 case T_FLOAT: __ fld_s (Address(rdx, rax, Address::times_1)); break; case T_DOUBLE: __ fld_d (Address(rdx, rax, Address::times_1)); break; #else case T_FLOAT: __ movflt (xmm0, Address(robj, roffset, Address::times_1)); break; case T_DOUBLE: __ movdbl (xmm0, Address(robj, roffset, Address::times_1)); break; #endif // _LP64 default: ShouldNotReachHere(); } Address ca1; if (os::is_MP()) { __ fst_s (Address(rsp, -4)); __ lea(rdx, counter); __ movl (rax, Address(rsp, -4)); // garbage hi-order bits on 64bit are harmless. __ xorptr(rdx, rax); __ xorptr(rdx, rax); __ cmp32(rcx, Address(rdx, 0)); // rax, ^ counter_addr ^ rax, = address // ca1 is data dependent on the field // access. } else { __ cmp32(rcx, counter); } __ jcc (Assembler::notEqual, slow_with_pop); #ifndef _WINDOWS __ ret (0); #else // __stdcall calling convention __ ret (3*wordSize); #endif __ bind (slow_with_pop); // invalid load. pop FPU stack. __ fstp_d (0); slowcase_entry_pclist[count++] = __ pc(); __ bind (slow); address slow_case_addr; switch (type) { case T_FLOAT: slow_case_addr = jni_GetFloatField_addr(); break; case T_DOUBLE: slow_case_addr = jni_GetDoubleField_addr(); break; default: ShouldNotReachHere(); } // tail call __ jump (ExternalAddress(slow_case_addr)); __ flush (); #ifndef _WINDOWS return fast_entry; #else switch (type) { case T_FLOAT: jni_fast_GetFloatField_fp = (GetFloatField_t)fast_entry; break; case T_DOUBLE: jni_fast_GetDoubleField_fp = (GetDoubleField_t)fast_entry; } return os::win32::fast_jni_accessor_wrapper(type); #endif }
address InterpreterGenerator::generate_math_entry(AbstractInterpreter::MethodKind kind) { // rbx,: methodOop // rcx: scratrch // rsi: sender sp if (!InlineIntrinsics) return NULL; // Generate a vanilla entry address entry_point = __ pc(); // These don't need a safepoint check because they aren't virtually // callable. We won't enter these intrinsics from compiled code. // If in the future we added an intrinsic which was virtually callable // we'd have to worry about how to safepoint so that this code is used. // mathematical functions inlined by compiler // (interpreter must provide identical implementation // in order to avoid monotonicity bugs when switching // from interpreter to compiler in the middle of some // computation) // // stack: [ ret adr ] <-- rsp // [ lo(arg) ] // [ hi(arg) ] // // Note: For JDK 1.2 StrictMath doesn't exist and Math.sin/cos/sqrt are // native methods. Interpreter::method_kind(...) does a check for // native methods first before checking for intrinsic methods and // thus will never select this entry point. Make sure it is not // called accidentally since the SharedRuntime entry points will // not work for JDK 1.2. // // We no longer need to check for JDK 1.2 since it's EOL'ed. // The following check existed in pre 1.6 implementation, // if (Universe::is_jdk12x_version()) { // __ should_not_reach_here(); // } // Universe::is_jdk12x_version() always returns false since // the JDK version is not yet determined when this method is called. // This method is called during interpreter_init() whereas // JDK version is only determined when universe2_init() is called. // Note: For JDK 1.3 StrictMath exists and Math.sin/cos/sqrt are // java methods. Interpreter::method_kind(...) will select // this entry point for the corresponding methods in JDK 1.3. // get argument __ fld_d(Address(rsp, 1*wordSize)); switch (kind) { case Interpreter::java_lang_math_sin : __ trigfunc('s'); break; case Interpreter::java_lang_math_cos : __ trigfunc('c'); break; case Interpreter::java_lang_math_tan : __ trigfunc('t'); break; case Interpreter::java_lang_math_sqrt: __ fsqrt(); break; case Interpreter::java_lang_math_abs: __ fabs(); break; case Interpreter::java_lang_math_log: __ flog(); // Store to stack to convert 80bit precision back to 64bits __ push_fTOS(); __ pop_fTOS(); break; case Interpreter::java_lang_math_log10: __ flog10(); // Store to stack to convert 80bit precision back to 64bits __ push_fTOS(); __ pop_fTOS(); break; default : ShouldNotReachHere(); } // return double result in xmm0 for interpreter and compilers. if (UseSSE >= 2) { __ subptr(rsp, 2*wordSize); __ fstp_d(Address(rsp, 0)); __ movdbl(xmm0, Address(rsp, 0)); __ addptr(rsp, 2*wordSize); } // done, result in FPU ST(0) or XMM0 __ pop(rdi); // get return address __ mov(rsp, rsi); // set sp to sender sp __ jmp(rdi); return entry_point; }
address JNI_FastGetField::generate_fast_get_float_field0(BasicType type) { const char *name; switch (type) { case T_FLOAT: name = "jni_fast_GetFloatField"; break; case T_DOUBLE: name = "jni_fast_GetDoubleField"; break; default: ShouldNotReachHere(); } ResourceMark rm; BufferBlob* b = BufferBlob::create(name, BUFFER_SIZE); address fast_entry = b->instructions_begin(); CodeBuffer cbuf(fast_entry, b->instructions_size()); MacroAssembler* masm = new MacroAssembler(&cbuf); Label slow; ExternalAddress counter(SafepointSynchronize::safepoint_counter_addr()); __ mov32 (rcounter, counter); __ mov (robj, c_rarg1); __ testb (rcounter, 1); __ jcc (Assembler::notZero, slow); if (os::is_MP()) { __ xorptr(robj, rcounter); __ xorptr(robj, rcounter); // obj, since // robj ^ rcounter ^ rcounter == robj // robj is data dependent on rcounter. } __ movptr(robj, Address(robj, 0)); // *obj __ mov (roffset, c_rarg2); __ shrptr(roffset, 2); // offset assert(count < LIST_CAPACITY, "LIST_CAPACITY too small"); speculative_load_pclist[count] = __ pc(); switch (type) { case T_FLOAT: __ movflt (xmm0, Address(robj, roffset, Address::times_1)); break; case T_DOUBLE: __ movdbl (xmm0, Address(robj, roffset, Address::times_1)); break; default: ShouldNotReachHere(); } if (os::is_MP()) { __ lea(rcounter_addr, counter); __ movdq (rax, xmm0); // counter address is data dependent on xmm0. __ xorptr(rcounter_addr, rax); __ xorptr(rcounter_addr, rax); __ cmpl (rcounter, Address(rcounter_addr, 0)); } else { __ cmp32 (rcounter, counter); } __ jcc (Assembler::notEqual, slow); __ ret (0); slowcase_entry_pclist[count++] = __ pc(); __ bind (slow); address slow_case_addr; switch (type) { case T_FLOAT: slow_case_addr = jni_GetFloatField_addr(); break; case T_DOUBLE: slow_case_addr = jni_GetDoubleField_addr(); } // tail call __ jump (ExternalAddress(slow_case_addr)); __ flush (); return fast_entry; }
//------------------------------------------------------------------------------ // 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)); }