Mercurial > hg > truffle
view src/cpu/ppc/vm/cppInterpreter_ppc.cpp @ 20304:a22acf6d7598
8048112: G1 Full GC needs to support the case when the very first region is not available
Summary: Refactor preparation for compaction during Full GC so that it lazily initializes the first compaction point. This also avoids problems later when the first region may not be committed. Also reviewed by K. Barrett.
Reviewed-by: brutisso
| author | tschatzl |
|---|---|
| date | Mon, 21 Jul 2014 10:00:31 +0200 |
| parents | 0bf37f737702 |
| children |
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/* * Copyright (c) 1997, 2014, Oracle and/or its affiliates. All rights reserved. * Copyright 2012, 2014 SAP AG. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #include "precompiled.hpp" #include "asm/assembler.hpp" #include "asm/macroAssembler.inline.hpp" #include "interpreter/bytecodeHistogram.hpp" #include "interpreter/cppInterpreter.hpp" #include "interpreter/interpreter.hpp" #include "interpreter/interpreterGenerator.hpp" #include "interpreter/interpreterRuntime.hpp" #include "oops/arrayOop.hpp" #include "oops/methodData.hpp" #include "oops/method.hpp" #include "oops/oop.inline.hpp" #include "prims/jvmtiExport.hpp" #include "prims/jvmtiThreadState.hpp" #include "runtime/arguments.hpp" #include "runtime/deoptimization.hpp" #include "runtime/frame.inline.hpp" #include "runtime/interfaceSupport.hpp" #include "runtime/sharedRuntime.hpp" #include "runtime/stubRoutines.hpp" #include "runtime/synchronizer.hpp" #include "runtime/timer.hpp" #include "runtime/vframeArray.hpp" #include "utilities/debug.hpp" #ifdef SHARK #include "shark/shark_globals.hpp" #endif #ifdef CC_INTERP #define __ _masm-> // Contains is used for identifying interpreter frames during a stack-walk. // A frame with a PC in InterpretMethod must be identified as a normal C frame. bool CppInterpreter::contains(address pc) { return _code->contains(pc); } #ifdef PRODUCT #define BLOCK_COMMENT(str) // nothing #else #define BLOCK_COMMENT(str) __ block_comment(str) #endif #define BIND(label) bind(label); BLOCK_COMMENT(#label ":") static address interpreter_frame_manager = NULL; static address frame_manager_specialized_return = NULL; static address native_entry = NULL; static address interpreter_return_address = NULL; static address unctrap_frame_manager_entry = NULL; static address deopt_frame_manager_return_atos = NULL; static address deopt_frame_manager_return_btos = NULL; static address deopt_frame_manager_return_itos = NULL; static address deopt_frame_manager_return_ltos = NULL; static address deopt_frame_manager_return_ftos = NULL; static address deopt_frame_manager_return_dtos = NULL; static address deopt_frame_manager_return_vtos = NULL; // A result handler converts/unboxes a native call result into // a java interpreter/compiler result. The current frame is an // interpreter frame. address CppInterpreterGenerator::generate_result_handler_for(BasicType type) { return AbstractInterpreterGenerator::generate_result_handler_for(type); } // tosca based result to c++ interpreter stack based result. address CppInterpreterGenerator::generate_tosca_to_stack_converter(BasicType type) { // // A result is in the native abi result register from a native // method call. We need to return this result to the interpreter by // pushing the result on the interpreter's stack. // // Registers alive: // R3_ARG1(R3_RET)/F1_ARG1(F1_RET) - result to move // R4_ARG2 - address of tos // LR // // Registers updated: // R3_RET(R3_ARG1) - address of new tos (== R17_tos for T_VOID) // int number_of_used_slots = 1; const Register tos = R4_ARG2; Label done; Label is_false; address entry = __ pc(); switch (type) { case T_BOOLEAN: __ cmpwi(CCR0, R3_RET, 0); __ beq(CCR0, is_false); __ li(R3_RET, 1); __ stw(R3_RET, 0, tos); __ b(done); __ bind(is_false); __ li(R3_RET, 0); __ stw(R3_RET, 0, tos); break; case T_BYTE: case T_CHAR: case T_SHORT: case T_INT: __ stw(R3_RET, 0, tos); break; case T_LONG: number_of_used_slots = 2; // mark unused slot for debugging // long goes to topmost slot __ std(R3_RET, -BytesPerWord, tos); __ li(R3_RET, 0); __ std(R3_RET, 0, tos); break; case T_OBJECT: __ verify_oop(R3_RET); __ std(R3_RET, 0, tos); break; case T_FLOAT: __ stfs(F1_RET, 0, tos); break; case T_DOUBLE: number_of_used_slots = 2; // mark unused slot for debugging __ li(R3_RET, 0); __ std(R3_RET, 0, tos); // double goes to topmost slot __ stfd(F1_RET, -BytesPerWord, tos); break; case T_VOID: number_of_used_slots = 0; break; default: ShouldNotReachHere(); } __ BIND(done); // new expression stack top __ addi(R3_RET, tos, -BytesPerWord * number_of_used_slots); __ blr(); return entry; } address CppInterpreterGenerator::generate_stack_to_stack_converter(BasicType type) { // // Copy the result from the callee's stack to the caller's stack, // caller and callee both being interpreted. // // Registers alive // R3_ARG1 - address of callee's tos + BytesPerWord // R4_ARG2 - address of caller's tos [i.e. free location] // LR // // stack grows upwards, memory grows downwards. // // [ free ] <-- callee's tos // [ optional result ] <-- R3_ARG1 // [ optional dummy ] // ... // [ free ] <-- caller's tos, R4_ARG2 // ... // Registers updated // R3_RET(R3_ARG1) - address of caller's new tos // // stack grows upwards, memory grows downwards. // // [ free ] <-- current tos, R3_RET // [ optional result ] // [ optional dummy ] // ... // const Register from = R3_ARG1; const Register ret = R3_ARG1; const Register tos = R4_ARG2; const Register tmp1 = R21_tmp1; const Register tmp2 = R22_tmp2; address entry = __ pc(); switch (type) { case T_BOOLEAN: case T_BYTE: case T_CHAR: case T_SHORT: case T_INT: case T_FLOAT: __ lwz(tmp1, 0, from); __ stw(tmp1, 0, tos); // New expression stack top. __ addi(ret, tos, - BytesPerWord); break; case T_LONG: case T_DOUBLE: // Move both entries for debug purposes even though only one is live. __ ld(tmp1, BytesPerWord, from); __ ld(tmp2, 0, from); __ std(tmp1, 0, tos); __ std(tmp2, -BytesPerWord, tos); // New expression stack top. __ addi(ret, tos, - 2 * BytesPerWord); // two slots break; case T_OBJECT: __ ld(tmp1, 0, from); __ verify_oop(tmp1); __ std(tmp1, 0, tos); // New expression stack top. __ addi(ret, tos, - BytesPerWord); break; case T_VOID: // New expression stack top. __ mr(ret, tos); break; default: ShouldNotReachHere(); } __ blr(); return entry; } address CppInterpreterGenerator::generate_stack_to_native_abi_converter(BasicType type) { // // Load a result from the callee's stack into the caller's expecting // return register, callee being interpreted, caller being call stub // or jit code. // // Registers alive // R3_ARG1 - callee expression tos + BytesPerWord // LR // // stack grows upwards, memory grows downwards. // // [ free ] <-- callee's tos // [ optional result ] <-- R3_ARG1 // [ optional dummy ] // ... // // Registers updated // R3_RET(R3_ARG1)/F1_RET - result // const Register from = R3_ARG1; const Register ret = R3_ARG1; const FloatRegister fret = F1_ARG1; address entry = __ pc(); // Implemented uniformly for both kinds of endianness. The interpreter // implements boolean, byte, char, and short as jint (4 bytes). switch (type) { case T_BOOLEAN: case T_CHAR: // zero extension __ lwz(ret, 0, from); break; case T_BYTE: case T_SHORT: case T_INT: // sign extension __ lwa(ret, 0, from); break; case T_LONG: __ ld(ret, 0, from); break; case T_OBJECT: __ ld(ret, 0, from); __ verify_oop(ret); break; case T_FLOAT: __ lfs(fret, 0, from); break; case T_DOUBLE: __ lfd(fret, 0, from); break; case T_VOID: break; default: ShouldNotReachHere(); } __ blr(); return entry; } address CppInterpreter::return_entry(TosState state, int length, Bytecodes::Code code) { assert(interpreter_return_address != NULL, "Not initialized"); return interpreter_return_address; } address CppInterpreter::deopt_entry(TosState state, int length) { address ret = NULL; if (length != 0) { switch (state) { case atos: ret = deopt_frame_manager_return_atos; break; case btos: ret = deopt_frame_manager_return_itos; break; case ctos: case stos: case itos: ret = deopt_frame_manager_return_itos; break; case ltos: ret = deopt_frame_manager_return_ltos; break; case ftos: ret = deopt_frame_manager_return_ftos; break; case dtos: ret = deopt_frame_manager_return_dtos; break; case vtos: ret = deopt_frame_manager_return_vtos; break; default: ShouldNotReachHere(); } } else { ret = unctrap_frame_manager_entry; // re-execute the bytecode (e.g. uncommon trap, popframe) } assert(ret != NULL, "Not initialized"); return ret; } // // Helpers for commoning out cases in the various type of method entries. // // // Registers alive // R16_thread - JavaThread* // R1_SP - old stack pointer // R19_method - callee's Method // R17_tos - address of caller's tos (prepushed) // R15_prev_state - address of caller's BytecodeInterpreter or 0 // return_pc in R21_tmp15 (only when called within generate_native_entry) // // Registers updated // R14_state - address of callee's interpreter state // R1_SP - new stack pointer // CCR4_is_synced - current method is synchronized // void CppInterpreterGenerator::generate_compute_interpreter_state(Label& stack_overflow_return) { // // Stack layout at this point: // // F1 [TOP_IJAVA_FRAME_ABI] <-- R1_SP // alignment (optional) // [F1's outgoing Java arguments] <-- R17_tos // ... // F2 [PARENT_IJAVA_FRAME_ABI] // ... //============================================================================= // Allocate space for locals other than the parameters, the // interpreter state, monitors, and the expression stack. const Register local_count = R21_tmp1; const Register parameter_count = R22_tmp2; const Register max_stack = R23_tmp3; // Must not be overwritten within this method! // const Register return_pc = R29_tmp9; const ConditionRegister is_synced = CCR4_is_synced; const ConditionRegister is_native = CCR6; const ConditionRegister is_static = CCR7; assert(is_synced != is_native, "condition code registers must be distinct"); assert(is_synced != is_static, "condition code registers must be distinct"); assert(is_native != is_static, "condition code registers must be distinct"); { // Local registers const Register top_frame_size = R24_tmp4; const Register access_flags = R25_tmp5; const Register state_offset = R26_tmp6; Register mem_stack_limit = R27_tmp7; const Register page_size = R28_tmp8; BLOCK_COMMENT("compute_interpreter_state {"); // access_flags = method->access_flags(); // TODO: PPC port: assert(4 == sizeof(AccessFlags), "unexpected field size"); __ lwa(access_flags, method_(access_flags)); // parameter_count = method->constMethod->size_of_parameters(); // TODO: PPC port: assert(2 == ConstMethod::sz_size_of_parameters(), "unexpected field size"); __ ld(max_stack, in_bytes(Method::const_offset()), R19_method); // Max_stack holds constMethod for a while. __ lhz(parameter_count, in_bytes(ConstMethod::size_of_parameters_offset()), max_stack); // local_count = method->constMethod()->max_locals(); // TODO: PPC port: assert(2 == ConstMethod::sz_max_locals(), "unexpected field size"); __ lhz(local_count, in_bytes(ConstMethod::size_of_locals_offset()), max_stack); // max_stack = method->constMethod()->max_stack(); // TODO: PPC port: assert(2 == ConstMethod::sz_max_stack(), "unexpected field size"); __ lhz(max_stack, in_bytes(ConstMethod::max_stack_offset()), max_stack); if (EnableInvokeDynamic) { // Take into account 'extra_stack_entries' needed by method handles (see method.hpp). __ addi(max_stack, max_stack, Method::extra_stack_entries()); } // mem_stack_limit = thread->stack_limit(); __ ld(mem_stack_limit, thread_(stack_overflow_limit)); // Point locals at the first argument. Method's locals are the // parameters on top of caller's expression stack. // tos points past last Java argument __ sldi(R18_locals, parameter_count, Interpreter::logStackElementSize); __ add(R18_locals, R17_tos, R18_locals); // R18_locals - i*BytesPerWord points to i-th Java local (i starts at 0) // Set is_native, is_synced, is_static - will be used later. __ testbitdi(is_native, R0, access_flags, JVM_ACC_NATIVE_BIT); __ testbitdi(is_synced, R0, access_flags, JVM_ACC_SYNCHRONIZED_BIT); assert(is_synced->is_nonvolatile(), "is_synced must be non-volatile"); __ testbitdi(is_static, R0, access_flags, JVM_ACC_STATIC_BIT); // PARENT_IJAVA_FRAME_ABI // // frame_size = // round_to((local_count - parameter_count)*BytesPerWord + // 2*BytesPerWord + // alignment + // frame::interpreter_frame_cinterpreterstate_size_in_bytes() // sizeof(PARENT_IJAVA_FRAME_ABI) // method->is_synchronized() ? sizeof(BasicObjectLock) : 0 + // max_stack*BytesPerWord, // 16) // // Note that this calculation is exactly mirrored by // AbstractInterpreter::layout_activation_impl() [ and // AbstractInterpreter::size_activation() ]. Which is used by // deoptimization so that it can allocate the proper sized // frame. This only happens for interpreted frames so the extra // notes below about max_stack below are not important. The other // thing to note is that for interpreter frames other than the // current activation the size of the stack is the size of the live // portion of the stack at the particular bcp and NOT the maximum // stack that the method might use. // // If we're calling a native method, we replace max_stack (which is // zero) with space for the worst-case signature handler varargs // vector, which is: // // max_stack = max(Argument::n_register_parameters, parameter_count+2); // // We add two slots to the parameter_count, one for the jni // environment and one for a possible native mirror. We allocate // space for at least the number of ABI registers, even though // InterpreterRuntime::slow_signature_handler won't write more than // parameter_count+2 words when it creates the varargs vector at the // top of the stack. The generated slow signature handler will just // load trash into registers beyond the necessary number. We're // still going to cut the stack back by the ABI register parameter // count so as to get SP+16 pointing at the ABI outgoing parameter // area, so we need to allocate at least that much even though we're // going to throw it away. // // Adjust max_stack for native methods: Label skip_native_calculate_max_stack; __ bfalse(is_native, skip_native_calculate_max_stack); // if (is_native) { // max_stack = max(Argument::n_register_parameters, parameter_count+2); __ addi(max_stack, parameter_count, 2*Interpreter::stackElementWords); __ cmpwi(CCR0, max_stack, Argument::n_register_parameters); __ bge(CCR0, skip_native_calculate_max_stack); __ li(max_stack, Argument::n_register_parameters); // } __ bind(skip_native_calculate_max_stack); // max_stack is now in bytes __ slwi(max_stack, max_stack, Interpreter::logStackElementSize); // Calculate number of non-parameter locals (in slots): Label not_java; __ btrue(is_native, not_java); // if (!is_native) { // local_count = non-parameter local count __ sub(local_count, local_count, parameter_count); // } else { // // nothing to do: method->max_locals() == 0 for native methods // } __ bind(not_java); // Calculate top_frame_size and parent_frame_resize. { const Register parent_frame_resize = R12_scratch2; BLOCK_COMMENT("Compute top_frame_size."); // top_frame_size = TOP_IJAVA_FRAME_ABI // + size of interpreter state __ li(top_frame_size, frame::top_ijava_frame_abi_size + frame::interpreter_frame_cinterpreterstate_size_in_bytes()); // + max_stack __ add(top_frame_size, top_frame_size, max_stack); // + stack slots for a BasicObjectLock for synchronized methods { Label not_synced; __ bfalse(is_synced, not_synced); __ addi(top_frame_size, top_frame_size, frame::interpreter_frame_monitor_size_in_bytes()); __ bind(not_synced); } // align __ round_to(top_frame_size, frame::alignment_in_bytes); BLOCK_COMMENT("Compute parent_frame_resize."); // parent_frame_resize = R1_SP - R17_tos __ sub(parent_frame_resize, R1_SP, R17_tos); //__ li(parent_frame_resize, 0); // + PARENT_IJAVA_FRAME_ABI // + extra two slots for the no-parameter/no-locals // method result __ addi(parent_frame_resize, parent_frame_resize, frame::parent_ijava_frame_abi_size + 2*Interpreter::stackElementSize); // + (locals_count - params_count) __ sldi(R0, local_count, Interpreter::logStackElementSize); __ add(parent_frame_resize, parent_frame_resize, R0); // align __ round_to(parent_frame_resize, frame::alignment_in_bytes); // // Stack layout at this point: // // The new frame F0 hasn't yet been pushed, F1 is still the top frame. // // F0 [TOP_IJAVA_FRAME_ABI] // alignment (optional) // [F0's full operand stack] // [F0's monitors] (optional) // [F0's BytecodeInterpreter object] // F1 [PARENT_IJAVA_FRAME_ABI] // alignment (optional) // [F0's Java result] // [F0's non-arg Java locals] // [F1's outgoing Java arguments] <-- R17_tos // ... // F2 [PARENT_IJAVA_FRAME_ABI] // ... // Calculate new R14_state // and // test that the new memory stack pointer is above the limit, // throw a StackOverflowError otherwise. __ sub(R11_scratch1/*F1's SP*/, R1_SP, parent_frame_resize); __ addi(R14_state, R11_scratch1/*F1's SP*/, -frame::interpreter_frame_cinterpreterstate_size_in_bytes()); __ sub(R11_scratch1/*F0's SP*/, R11_scratch1/*F1's SP*/, top_frame_size); BLOCK_COMMENT("Test for stack overflow:"); __ cmpld(CCR0/*is_stack_overflow*/, R11_scratch1, mem_stack_limit); __ blt(CCR0/*is_stack_overflow*/, stack_overflow_return); //============================================================================= // Frame_size doesn't overflow the stack. Allocate new frame and // initialize interpreter state. // Register state // // R15 - local_count // R16 - parameter_count // R17 - max_stack // // R18 - frame_size // R19 - access_flags // CCR4_is_synced - is_synced // // GR_Lstate - pointer to the uninitialized new BytecodeInterpreter. // _last_Java_pc just needs to be close enough that we can identify // the frame as an interpreted frame. It does not need to be the // exact return address from either calling // BytecodeInterpreter::InterpretMethod or the call to a jni native method. // So we can initialize it here with a value of a bundle in this // code fragment. We only do this initialization for java frames // where InterpretMethod needs a a way to get a good pc value to // store in the thread state. For interpreter frames used to call // jni native code we just zero the value in the state and move an // ip as needed in the native entry code. // // const Register last_Java_pc_addr = GR24_SCRATCH; // QQQ 27 // const Register last_Java_pc = GR26_SCRATCH; // Must reference stack before setting new SP since Windows // will not be able to deliver the exception on a bad SP. // Windows also insists that we bang each page one at a time in order // for the OS to map in the reserved pages. If we bang only // the final page, Windows stops delivering exceptions to our // VectoredExceptionHandler and terminates our program. // Linux only requires a single bang but it's rare to have // to bang more than 1 page so the code is enabled for both OS's. // BANG THE STACK // // Nothing to do for PPC, because updating the SP will automatically // bang the page. // Up to here we have calculated the delta for the new C-frame and // checked for a stack-overflow. Now we can savely update SP and // resize the C-frame. // R14_state has already been calculated. __ push_interpreter_frame(top_frame_size, parent_frame_resize, R25_tmp5, R26_tmp6, R27_tmp7, R28_tmp8); } // // Stack layout at this point: // // F0 has been been pushed! // // F0 [TOP_IJAVA_FRAME_ABI] <-- R1_SP // alignment (optional) (now it's here, if required) // [F0's full operand stack] // [F0's monitors] (optional) // [F0's BytecodeInterpreter object] // F1 [PARENT_IJAVA_FRAME_ABI] // alignment (optional) (now it's here, if required) // [F0's Java result] // [F0's non-arg Java locals] // [F1's outgoing Java arguments] // ... // F2 [PARENT_IJAVA_FRAME_ABI] // ... // // R14_state points to F0's BytecodeInterpreter object. // } //============================================================================= // new BytecodeInterpreter-object is save, let's initialize it: BLOCK_COMMENT("New BytecodeInterpreter-object is save."); { // Locals const Register bytecode_addr = R24_tmp4; const Register constants = R25_tmp5; const Register tos = R26_tmp6; const Register stack_base = R27_tmp7; const Register local_addr = R28_tmp8; { Label L; __ btrue(is_native, L); // if (!is_native) { // bytecode_addr = constMethod->codes(); __ ld(bytecode_addr, method_(const)); __ addi(bytecode_addr, bytecode_addr, in_bytes(ConstMethod::codes_offset())); // } __ bind(L); } __ ld(constants, in_bytes(Method::const_offset()), R19_method); __ ld(constants, in_bytes(ConstMethod::constants_offset()), constants); // state->_prev_link = prev_state; __ std(R15_prev_state, state_(_prev_link)); // For assertions only. // TODO: not needed anyway because it coincides with `_monitor_base'. remove! // state->_self_link = state; DEBUG_ONLY(__ std(R14_state, state_(_self_link));) // state->_thread = thread; __ std(R16_thread, state_(_thread)); // state->_method = method; __ std(R19_method, state_(_method)); // state->_locals = locals; __ std(R18_locals, state_(_locals)); // state->_oop_temp = NULL; __ li(R0, 0); __ std(R0, state_(_oop_temp)); // state->_last_Java_fp = *R1_SP // Use *R1_SP as fp __ ld(R0, _abi(callers_sp), R1_SP); __ std(R0, state_(_last_Java_fp)); BLOCK_COMMENT("load Stack base:"); { // Stack_base. // if (!method->synchronized()) { // stack_base = state; // } else { // stack_base = (uintptr_t)state - sizeof(BasicObjectLock); // } Label L; __ mr(stack_base, R14_state); __ bfalse(is_synced, L); __ addi(stack_base, stack_base, -frame::interpreter_frame_monitor_size_in_bytes()); __ bind(L); } // state->_mdx = NULL; __ li(R0, 0); __ std(R0, state_(_mdx)); { // if (method->is_native()) state->_bcp = NULL; // else state->_bcp = bytecode_addr; Label label1, label2; __ bfalse(is_native, label1); __ std(R0, state_(_bcp)); __ b(label2); __ bind(label1); __ std(bytecode_addr, state_(_bcp)); __ bind(label2); } // state->_result._to_call._callee = NULL; __ std(R0, state_(_result._to_call._callee)); // state->_monitor_base = state; __ std(R14_state, state_(_monitor_base)); // state->_msg = BytecodeInterpreter::method_entry; __ li(R0, BytecodeInterpreter::method_entry); __ stw(R0, state_(_msg)); // state->_last_Java_sp = R1_SP; __ std(R1_SP, state_(_last_Java_sp)); // state->_stack_base = stack_base; __ std(stack_base, state_(_stack_base)); // tos = stack_base - 1 slot (prepushed); // state->_stack.Tos(tos); __ addi(tos, stack_base, - Interpreter::stackElementSize); __ std(tos, state_(_stack)); { BLOCK_COMMENT("get last_Java_pc:"); // if (!is_native) state->_last_Java_pc = <some_ip_in_this_code_buffer>; // else state->_last_Java_pc = NULL; (just for neatness) Label label1, label2; __ btrue(is_native, label1); __ get_PC_trash_LR(R0); __ std(R0, state_(_last_Java_pc)); __ b(label2); __ bind(label1); __ li(R0, 0); __ std(R0, state_(_last_Java_pc)); __ bind(label2); } // stack_limit = tos - max_stack; __ sub(R0, tos, max_stack); // state->_stack_limit = stack_limit; __ std(R0, state_(_stack_limit)); // cache = method->constants()->cache(); __ ld(R0, ConstantPool::cache_offset_in_bytes(), constants); // state->_constants = method->constants()->cache(); __ std(R0, state_(_constants)); //============================================================================= // synchronized method, allocate and initialize method object lock. // if (!method->is_synchronized()) goto fill_locals_with_0x0s; Label fill_locals_with_0x0s; __ bfalse(is_synced, fill_locals_with_0x0s); // pool_holder = method->constants()->pool_holder(); const int mirror_offset = in_bytes(Klass::java_mirror_offset()); { Label label1, label2; // lockee = NULL; for java methods, correct value will be inserted in BytecodeInterpretMethod.hpp __ li(R0,0); __ bfalse(is_native, label2); __ bfalse(is_static, label1); // if (method->is_static()) lockee = // pool_holder->klass_part()->java_mirror(); __ ld(R11_scratch1/*pool_holder*/, ConstantPool::pool_holder_offset_in_bytes(), constants); __ ld(R0/*lockee*/, mirror_offset, R11_scratch1/*pool_holder*/); __ b(label2); __ bind(label1); // else lockee = *(oop*)locals; __ ld(R0/*lockee*/, 0, R18_locals); __ bind(label2); // monitor->set_obj(lockee); __ std(R0/*lockee*/, BasicObjectLock::obj_offset_in_bytes(), stack_base); } // See if we need to zero the locals __ BIND(fill_locals_with_0x0s); //============================================================================= // fill locals with 0x0s Label locals_zeroed; __ btrue(is_native, locals_zeroed); if (true /* zerolocals */ || ClearInterpreterLocals) { // local_count is already num_locals_slots - num_param_slots __ sldi(R0, parameter_count, Interpreter::logStackElementSize); __ sub(local_addr, R18_locals, R0); __ cmpdi(CCR0, local_count, 0); __ ble(CCR0, locals_zeroed); __ mtctr(local_count); //__ ld_const_addr(R0, (address) 0xcafe0000babe); __ li(R0, 0); Label zero_slot; __ bind(zero_slot); // first local is at local_addr __ std(R0, 0, local_addr); __ addi(local_addr, local_addr, -BytesPerWord); __ bdnz(zero_slot); } __ BIND(locals_zeroed); } BLOCK_COMMENT("} compute_interpreter_state"); } // Generate code to initiate compilation on invocation counter overflow. void CppInterpreterGenerator::generate_counter_overflow(Label& continue_entry) { // Registers alive // R14_state // R16_thread // // Registers updated // R14_state // R3_ARG1 (=R3_RET) // R4_ARG2 // After entering the vm we remove the activation and retry the // entry point in case the compilation is complete. // InterpreterRuntime::frequency_counter_overflow takes one argument // that indicates if the counter overflow occurs at a backwards // branch (NULL bcp). We pass zero. The call returns the address // of the verified entry point for the method or NULL if the // compilation did not complete (either went background or bailed // out). __ li(R4_ARG2, 0); // Pass false to call_VM so it doesn't check for pending exceptions, // since at this point in the method invocation the exception // handler would try to exit the monitor of synchronized methods // which haven't been entered yet. // // Returns verified_entry_point or NULL, we don't care which. // // Do not use the variant `frequency_counter_overflow' that returns // a structure, because this will change the argument list by a // hidden parameter (gcc 4.1). __ call_VM(noreg, CAST_FROM_FN_PTR(address, InterpreterRuntime::frequency_counter_overflow), R4_ARG2, false); // Returns verified_entry_point or NULL, we don't care which as we ignore it // and run interpreted. // Reload method, it may have moved. __ ld(R19_method, state_(_method)); // We jump now to the label "continue_after_compile". __ b(continue_entry); } // Increment invocation count and check for overflow. // // R19_method must contain Method* of method to profile. void CppInterpreterGenerator::generate_counter_incr(Label& overflow) { Label done; const Register Rcounters = R12_scratch2; const Register iv_be_count = R11_scratch1; const Register invocation_limit = R12_scratch2; const Register invocation_limit_addr = invocation_limit; // Load and ev. allocate MethodCounters object. __ get_method_counters(R19_method, Rcounters, done); // Update standard invocation counters. __ increment_invocation_counter(Rcounters, iv_be_count, R0); // Compare against limit. BLOCK_COMMENT("Compare counter against limit:"); assert(4 == sizeof(InvocationCounter::InterpreterInvocationLimit), "must be 4 bytes"); __ load_const(invocation_limit_addr, (address)&InvocationCounter::InterpreterInvocationLimit); __ lwa(invocation_limit, 0, invocation_limit_addr); __ cmpw(CCR0, iv_be_count, invocation_limit); __ bge(CCR0, overflow); __ bind(done); } // // Call a JNI method. // // Interpreter stub for calling a native method. (C++ interpreter) // This sets up a somewhat different looking stack for calling the native method // than the typical interpreter frame setup. // address CppInterpreterGenerator::generate_native_entry(void) { if (native_entry != NULL) return native_entry; address entry = __ pc(); // Read // R16_thread // R15_prev_state - address of caller's BytecodeInterpreter, if this snippet // gets called by the frame manager. // R19_method - callee's Method // R17_tos - address of caller's tos // R1_SP - caller's stack pointer // R21_sender_SP - initial caller sp // // Update // R14_state - address of caller's BytecodeInterpreter // R3_RET - integer result, if any. // F1_RET - float result, if any. // // // Stack layout at this point: // // 0 [TOP_IJAVA_FRAME_ABI] <-- R1_SP // alignment (optional) // [outgoing Java arguments] <-- R17_tos // ... // PARENT [PARENT_IJAVA_FRAME_ABI] // ... // const bool inc_counter = UseCompiler || CountCompiledCalls; const Register signature_handler_fd = R21_tmp1; const Register pending_exception = R22_tmp2; const Register result_handler_addr = R23_tmp3; const Register native_method_fd = R24_tmp4; const Register access_flags = R25_tmp5; const Register active_handles = R26_tmp6; const Register sync_state = R27_tmp7; const Register sync_state_addr = sync_state; // Address is dead after use. const Register suspend_flags = R24_tmp4; const Register return_pc = R28_tmp8; // Register will be locked for some time. const ConditionRegister is_synced = CCR4_is_synced; // Live-on-exit from compute_interpreter_state. // R1_SP still points to caller's SP at this point. // Save initial_caller_sp to caller's abi. The caller frame must be // resized before returning to get rid of the c2i arguments (if // any). // Override the saved SP with the senderSP so we can pop c2i // arguments (if any) off when we return __ std(R21_sender_SP, _top_ijava_frame_abi(initial_caller_sp), R1_SP); // Save LR to caller's frame. We don't use _abi(lr) here, because it is not safe. __ mflr(return_pc); __ std(return_pc, _top_ijava_frame_abi(frame_manager_lr), R1_SP); assert(return_pc->is_nonvolatile(), "return_pc must be a non-volatile register"); __ verify_method_ptr(R19_method); //============================================================================= // If this snippet gets called by the frame manager (at label // `call_special'), then R15_prev_state is valid. If this snippet // is not called by the frame manager, but e.g. by the call stub or // by compiled code, then R15_prev_state is invalid. { // Set R15_prev_state to 0 if we don't return to the frame // manager; we will return to the call_stub or to compiled code // instead. If R15_prev_state is 0 there will be only one // interpreter frame (we will set this up later) in this C frame! // So we must take care about retrieving prev_state_(_prev_link) // and restoring R1_SP when popping that interpreter. Label prev_state_is_valid; __ load_const(R11_scratch1/*frame_manager_returnpc_addr*/, (address)&frame_manager_specialized_return); __ ld(R12_scratch2/*frame_manager_returnpc*/, 0, R11_scratch1/*frame_manager_returnpc_addr*/); __ cmpd(CCR0, return_pc, R12_scratch2/*frame_manager_returnpc*/); __ beq(CCR0, prev_state_is_valid); __ li(R15_prev_state, 0); __ BIND(prev_state_is_valid); } //============================================================================= // Allocate new frame and initialize interpreter state. Label exception_return; Label exception_return_sync_check; Label stack_overflow_return; // Generate new interpreter state and jump to stack_overflow_return in case of // a stack overflow. generate_compute_interpreter_state(stack_overflow_return); //============================================================================= // Increment invocation counter. On overflow, entry to JNI method // will be compiled. Label invocation_counter_overflow; if (inc_counter) { generate_counter_incr(invocation_counter_overflow); } Label continue_after_compile; __ BIND(continue_after_compile); // access_flags = method->access_flags(); // Load access flags. assert(access_flags->is_nonvolatile(), "access_flags must be in a non-volatile register"); // Type check. // TODO: PPC port: assert(4 == sizeof(AccessFlags), "unexpected field size"); __ lwz(access_flags, method_(access_flags)); // We don't want to reload R19_method and access_flags after calls // to some helper functions. assert(R19_method->is_nonvolatile(), "R19_method must be a non-volatile register"); // Check for synchronized methods. Must happen AFTER invocation counter // check, so method is not locked if counter overflows. { Label method_is_not_synced; // Is_synced is still alive. assert(is_synced->is_nonvolatile(), "is_synced must be non-volatile"); __ bfalse(is_synced, method_is_not_synced); lock_method(); // Reload method, it may have moved. __ ld(R19_method, state_(_method)); __ BIND(method_is_not_synced); } // jvmti/jvmpi support __ notify_method_entry(); // Reload method, it may have moved. __ ld(R19_method, state_(_method)); //============================================================================= // Get and call the signature handler __ ld(signature_handler_fd, method_(signature_handler)); Label call_signature_handler; __ cmpdi(CCR0, signature_handler_fd, 0); __ bne(CCR0, call_signature_handler); // Method has never been called. Either generate a specialized // handler or point to the slow one. // // Pass parameter 'false' to avoid exception check in call_VM. __ call_VM(noreg, CAST_FROM_FN_PTR(address, InterpreterRuntime::prepare_native_call), R19_method, false); // Check for an exception while looking up the target method. If we // incurred one, bail. __ ld(pending_exception, thread_(pending_exception)); __ cmpdi(CCR0, pending_exception, 0); __ bne(CCR0, exception_return_sync_check); // has pending exception // reload method __ ld(R19_method, state_(_method)); // Reload signature handler, it may have been created/assigned in the meanwhile __ ld(signature_handler_fd, method_(signature_handler)); __ BIND(call_signature_handler); // Before we call the signature handler we push a new frame to // protect the interpreter frame volatile registers when we return // from jni but before we can get back to Java. // First set the frame anchor while the SP/FP registers are // convenient and the slow signature handler can use this same frame // anchor. // We have a TOP_IJAVA_FRAME here, which belongs to us. __ set_top_ijava_frame_at_SP_as_last_Java_frame(R1_SP, R12_scratch2/*tmp*/); // Now the interpreter frame (and its call chain) have been // invalidated and flushed. We are now protected against eager // being enabled in native code. Even if it goes eager the // registers will be reloaded as clean and we will invalidate after // the call so no spurious flush should be possible. // Call signature handler and pass locals address. // // Our signature handlers copy required arguments to the C stack // (outgoing C args), R3_ARG1 to R10_ARG8, and F1_ARG1 to // F13_ARG13. __ mr(R3_ARG1, R18_locals); #if !defined(ABI_ELFv2) __ ld(signature_handler_fd, 0, signature_handler_fd); #endif __ call_stub(signature_handler_fd); // reload method __ ld(R19_method, state_(_method)); // Remove the register parameter varargs slots we allocated in // compute_interpreter_state. SP+16 ends up pointing to the ABI // outgoing argument area. // // Not needed on PPC64. //__ add(SP, SP, Argument::n_register_parameters*BytesPerWord); assert(result_handler_addr->is_nonvolatile(), "result_handler_addr must be in a non-volatile register"); // Save across call to native method. __ mr(result_handler_addr, R3_RET); // Set up fixed parameters and call the native method. // If the method is static, get mirror into R4_ARG2. { Label method_is_not_static; // access_flags is non-volatile and still, no need to restore it // restore access flags __ testbitdi(CCR0, R0, access_flags, JVM_ACC_STATIC_BIT); __ bfalse(CCR0, method_is_not_static); // constants = method->constants(); __ ld(R11_scratch1, in_bytes(Method::const_offset()), R19_method); __ ld(R11_scratch1/*constants*/, in_bytes(ConstMethod::constants_offset()), R11_scratch1); // pool_holder = method->constants()->pool_holder(); __ ld(R11_scratch1/*pool_holder*/, ConstantPool::pool_holder_offset_in_bytes(), R11_scratch1/*constants*/); const int mirror_offset = in_bytes(Klass::java_mirror_offset()); // mirror = pool_holder->klass_part()->java_mirror(); __ ld(R0/*mirror*/, mirror_offset, R11_scratch1/*pool_holder*/); // state->_native_mirror = mirror; __ std(R0/*mirror*/, state_(_oop_temp)); // R4_ARG2 = &state->_oop_temp; __ addir(R4_ARG2, state_(_oop_temp)); __ BIND(method_is_not_static); } // At this point, arguments have been copied off the stack into // their JNI positions. Oops are boxed in-place on the stack, with // handles copied to arguments. The result handler address is in a // register. // pass JNIEnv address as first parameter __ addir(R3_ARG1, thread_(jni_environment)); // Load the native_method entry before we change the thread state. __ ld(native_method_fd, method_(native_function)); //============================================================================= // Transition from _thread_in_Java to _thread_in_native. As soon as // we make this change the safepoint code needs to be certain that // the last Java frame we established is good. The pc in that frame // just needs to be near here not an actual return address. // We use release_store_fence to update values like the thread state, where // we don't want the current thread to continue until all our prior memory // accesses (including the new thread state) are visible to other threads. __ li(R0, _thread_in_native); __ release(); // TODO: PPC port: assert(4 == JavaThread::sz_thread_state(), "unexpected field size"); __ stw(R0, thread_(thread_state)); if (UseMembar) { __ fence(); } //============================================================================= // Call the native method. Argument registers must not have been // overwritten since "__ call_stub(signature_handler);" (except for // ARG1 and ARG2 for static methods) __ call_c(native_method_fd); __ std(R3_RET, state_(_native_lresult)); __ stfd(F1_RET, state_(_native_fresult)); // The frame_manager_lr field, which we use for setting the last // java frame, gets overwritten by the signature handler. Restore // it now. __ get_PC_trash_LR(R11_scratch1); __ std(R11_scratch1, _top_ijava_frame_abi(frame_manager_lr), R1_SP); // Because of GC R19_method may no longer be valid. // Block, if necessary, before resuming in _thread_in_Java state. // In order for GC to work, don't clear the last_Java_sp until after // blocking. //============================================================================= // Switch thread to "native transition" state before reading the // synchronization state. This additional state is necessary // because reading and testing the synchronization state is not // atomic w.r.t. GC, as this scenario demonstrates: Java thread A, // in _thread_in_native state, loads _not_synchronized and is // preempted. VM thread changes sync state to synchronizing and // suspends threads for GC. Thread A is resumed to finish this // native method, but doesn't block here since it didn't see any // synchronization in progress, and escapes. // We use release_store_fence to update values like the thread state, where // we don't want the current thread to continue until all our prior memory // accesses (including the new thread state) are visible to other threads. __ li(R0/*thread_state*/, _thread_in_native_trans); __ release(); __ stw(R0/*thread_state*/, thread_(thread_state)); if (UseMembar) { __ fence(); } // Write serialization page so that the VM thread can do a pseudo remote // membar. We use the current thread pointer to calculate a thread // specific offset to write to within the page. This minimizes bus // traffic due to cache line collision. else { __ serialize_memory(R16_thread, R11_scratch1, R12_scratch2); } // Now before we return to java we must look for a current safepoint // (a new safepoint can not start since we entered native_trans). // We must check here because a current safepoint could be modifying // the callers registers right this moment. // Acquire isn't strictly necessary here because of the fence, but // sync_state is declared to be volatile, so we do it anyway. __ load_const(sync_state_addr, SafepointSynchronize::address_of_state()); // TODO: PPC port: assert(4 == SafepointSynchronize::sz_state(), "unexpected field size"); __ lwz(sync_state, 0, sync_state_addr); // TODO: PPC port: assert(4 == Thread::sz_suspend_flags(), "unexpected field size"); __ lwz(suspend_flags, thread_(suspend_flags)); __ acquire(); Label sync_check_done; Label do_safepoint; // No synchronization in progress nor yet synchronized __ cmpwi(CCR0, sync_state, SafepointSynchronize::_not_synchronized); // not suspended __ cmpwi(CCR1, suspend_flags, 0); __ bne(CCR0, do_safepoint); __ beq(CCR1, sync_check_done); __ bind(do_safepoint); // Block. We do the call directly and leave the current // last_Java_frame setup undisturbed. We must save any possible // native result acrosss the call. No oop is present __ mr(R3_ARG1, R16_thread); #if defined(ABI_ELFv2) __ call_c(CAST_FROM_FN_PTR(address, JavaThread::check_special_condition_for_native_trans), relocInfo::none); #else __ call_c(CAST_FROM_FN_PTR(FunctionDescriptor*, JavaThread::check_special_condition_for_native_trans), relocInfo::none); #endif __ bind(sync_check_done); //============================================================================= // <<<<<< Back in Interpreter Frame >>>>> // We are in thread_in_native_trans here and back in the normal // interpreter frame. We don't have to do anything special about // safepoints and we can switch to Java mode anytime we are ready. // Note: frame::interpreter_frame_result has a dependency on how the // method result is saved across the call to post_method_exit. For // native methods it assumes that the non-FPU/non-void result is // saved in _native_lresult and a FPU result in _native_fresult. If // this changes then the interpreter_frame_result implementation // will need to be updated too. // On PPC64, we have stored the result directly after the native call. //============================================================================= // back in Java // We use release_store_fence to update values like the thread state, where // we don't want the current thread to continue until all our prior memory // accesses (including the new thread state) are visible to other threads. __ li(R0/*thread_state*/, _thread_in_Java); __ release(); __ stw(R0/*thread_state*/, thread_(thread_state)); if (UseMembar) { __ fence(); } __ reset_last_Java_frame(); // Reload GR27_method, call killed it. We can't look at // state->_method until we're back in java state because in java // state gc can't happen until we get to a safepoint. // // We've set thread_state to _thread_in_Java already, so restoring // R19_method from R14_state works; R19_method is invalid, because // GC may have happened. __ ld(R19_method, state_(_method)); // reload method, may have moved // jvmdi/jvmpi support. Whether we've got an exception pending or // not, and whether unlocking throws an exception or not, we notify // on native method exit. If we do have an exception, we'll end up // in the caller's context to handle it, so if we don't do the // notify here, we'll drop it on the floor. __ notify_method_exit(true/*native method*/, ilgl /*illegal state (not used for native methods)*/, InterpreterMacroAssembler::NotifyJVMTI, false /*check_exceptions*/); //============================================================================= // Handle exceptions // See if we must unlock. // { Label method_is_not_synced; // is_synced is still alive assert(is_synced->is_nonvolatile(), "is_synced must be non-volatile"); __ bfalse(is_synced, method_is_not_synced); unlock_method(); __ bind(method_is_not_synced); } // Reset active handles after returning from native. // thread->active_handles()->clear(); __ ld(active_handles, thread_(active_handles)); // JNIHandleBlock::_top is an int. // TODO: PPC port: assert(4 == JNIHandleBlock::top_size_in_bytes(), "unexpected field size"); __ li(R0, 0); __ stw(R0, JNIHandleBlock::top_offset_in_bytes(), active_handles); Label no_pending_exception_from_native_method; __ ld(R0/*pending_exception*/, thread_(pending_exception)); __ cmpdi(CCR0, R0/*pending_exception*/, 0); __ beq(CCR0, no_pending_exception_from_native_method); //----------------------------------------------------------------------------- // An exception is pending. We call into the runtime only if the // caller was not interpreted. If it was interpreted the // interpreter will do the correct thing. If it isn't interpreted // (call stub/compiled code) we will change our return and continue. __ BIND(exception_return); Label return_to_initial_caller_with_pending_exception; __ cmpdi(CCR0, R15_prev_state, 0); __ beq(CCR0, return_to_initial_caller_with_pending_exception); // We are returning to an interpreter activation, just pop the state, // pop our frame, leave the exception pending, and return. __ pop_interpreter_state(/*prev_state_may_be_0=*/false); __ pop_interpreter_frame(R11_scratch1, R12_scratch2, R21_tmp1 /* set to return pc */, R22_tmp2); __ mtlr(R21_tmp1); __ blr(); __ BIND(exception_return_sync_check); assert(is_synced->is_nonvolatile(), "is_synced must be non-volatile"); __ bfalse(is_synced, exception_return); unlock_method(); __ b(exception_return); __ BIND(return_to_initial_caller_with_pending_exception); // We are returning to a c2i-adapter / call-stub, get the address of the // exception handler, pop the frame and return to the handler. // First, pop to caller's frame. __ pop_interpreter_frame(R11_scratch1, R12_scratch2, R21_tmp1 /* set to return pc */, R22_tmp2); __ push_frame_reg_args(0, R11_scratch1); // Get the address of the exception handler. __ call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::exception_handler_for_return_address), R16_thread, R21_tmp1 /* return pc */); __ pop_frame(); // Load the PC of the the exception handler into LR. __ mtlr(R3_RET); // Load exception into R3_ARG1 and clear pending exception in thread. __ ld(R3_ARG1/*exception*/, thread_(pending_exception)); __ li(R4_ARG2, 0); __ std(R4_ARG2, thread_(pending_exception)); // Load the original return pc into R4_ARG2. __ mr(R4_ARG2/*issuing_pc*/, R21_tmp1); // Resize frame to get rid of a potential extension. __ resize_frame_to_initial_caller(R11_scratch1, R12_scratch2); // Return to exception handler. __ blr(); //----------------------------------------------------------------------------- // No exception pending. __ BIND(no_pending_exception_from_native_method); // Move native method result back into proper registers and return. // Invoke result handler (may unbox/promote). __ ld(R3_RET, state_(_native_lresult)); __ lfd(F1_RET, state_(_native_fresult)); __ call_stub(result_handler_addr); // We have created a new BytecodeInterpreter object, now we must destroy it. // // Restore previous R14_state and caller's SP. R15_prev_state may // be 0 here, because our caller may be the call_stub or compiled // code. __ pop_interpreter_state(/*prev_state_may_be_0=*/true); __ pop_interpreter_frame(R11_scratch1, R12_scratch2, R21_tmp1 /* set to return pc */, R22_tmp2); // Resize frame to get rid of a potential extension. __ resize_frame_to_initial_caller(R11_scratch1, R12_scratch2); // Must use the return pc which was loaded from the caller's frame // as the VM uses return-pc-patching for deoptimization. __ mtlr(R21_tmp1); __ blr(); //============================================================================= // We encountered an exception while computing the interpreter // state, so R14_state isn't valid. Act as if we just returned from // the callee method with a pending exception. __ BIND(stack_overflow_return); // // Register state: // R14_state invalid; trashed by compute_interpreter_state // R15_prev_state valid, but may be 0 // // R1_SP valid, points to caller's SP; wasn't yet updated by // compute_interpreter_state // // Create exception oop and make it pending. // Throw the exception via RuntimeStub "throw_StackOverflowError_entry". // // Previously, we called C-Code directly. As a consequence, a // possible GC tried to process the argument oops of the top frame // (see RegisterMap::clear, which sets the corresponding flag to // true). This lead to crashes because: // 1. The top register map did not contain locations for the argument registers // 2. The arguments are dead anyway, could be already overwritten in the worst case // Solution: Call via special runtime stub that pushes it's own // frame. This runtime stub has the flag "CodeBlob::caller_must_gc_arguments()" // set to "false", what prevents the dead arguments getting GC'd. // // 2 cases exist: // 1. We were called by the c2i adapter / call stub // 2. We were called by the frame manager // // Both cases are handled by this code: // 1. - initial_caller_sp was saved in both cases on entry, so it's safe to load it back even if it was not changed. // - control flow will be: // throw_stackoverflow_stub->VM->throw_stackoverflow_stub->forward_excep->excp_blob of caller method // 2. - control flow will be: // throw_stackoverflow_stub->VM->throw_stackoverflow_stub->forward_excep->rethrow_excp_entry of frame manager->resume_method // Since we restored the caller SP above, the rethrow_excp_entry can restore the original interpreter state // registers using the stack and resume the calling method with a pending excp. // Pop any c2i extension from the stack, restore LR just to be sure __ ld(R0, _top_ijava_frame_abi(frame_manager_lr), R1_SP); __ mtlr(R0); // Resize frame to get rid of a potential extension. __ resize_frame_to_initial_caller(R11_scratch1, R12_scratch2); assert(StubRoutines::throw_StackOverflowError_entry() != NULL, "generated in wrong order"); // Load target address of the runtime stub. __ load_const(R12_scratch2, (StubRoutines::throw_StackOverflowError_entry())); __ mtctr(R12_scratch2); __ bctr(); //============================================================================= // Counter overflow. if (inc_counter) { // Handle invocation counter overflow __ bind(invocation_counter_overflow); generate_counter_overflow(continue_after_compile); } native_entry = entry; return entry; } bool AbstractInterpreter::can_be_compiled(methodHandle m) { // No special entry points that preclude compilation. return true; } // Unlock the current method. // void CppInterpreterGenerator::unlock_method(void) { // Find preallocated monitor and unlock method. Method monitor is // the first one. // Registers alive // R14_state // // Registers updated // volatiles // const Register monitor = R4_ARG2; // Pass address of initial monitor we allocated. // // First monitor. __ addi(monitor, R14_state, -frame::interpreter_frame_monitor_size_in_bytes()); // Unlock method __ unlock_object(monitor); } // Lock the current method. // void CppInterpreterGenerator::lock_method(void) { // Find preallocated monitor and lock method. Method monitor is the // first one. // // Registers alive // R14_state // // Registers updated // volatiles // const Register monitor = R4_ARG2; const Register object = R5_ARG3; // Pass address of initial monitor we allocated. __ addi(monitor, R14_state, -frame::interpreter_frame_monitor_size_in_bytes()); // Pass object address. __ ld(object, BasicObjectLock::obj_offset_in_bytes(), monitor); // Lock method. __ lock_object(monitor, object); } // Generate code for handling resuming a deopted method. void CppInterpreterGenerator::generate_deopt_handling(Register result_index) { //============================================================================= // Returning from a compiled method into a deopted method. The // bytecode at the bcp has completed. The result of the bytecode is // in the native abi (the tosca for the template based // interpreter). Any stack space that was used by the bytecode that // has completed has been removed (e.g. parameters for an invoke) so // all that we have to do is place any pending result on the // expression stack and resume execution on the next bytecode. Label return_from_deopt_common; // R3_RET and F1_RET are live here! Load the array index of the // required result stub address and continue at return_from_deopt_common. // Deopt needs to jump to here to enter the interpreter (return a result). deopt_frame_manager_return_atos = __ pc(); __ li(result_index, AbstractInterpreter::BasicType_as_index(T_OBJECT)); __ b(return_from_deopt_common); deopt_frame_manager_return_btos = __ pc(); __ li(result_index, AbstractInterpreter::BasicType_as_index(T_BOOLEAN)); __ b(return_from_deopt_common); deopt_frame_manager_return_itos = __ pc(); __ li(result_index, AbstractInterpreter::BasicType_as_index(T_INT)); __ b(return_from_deopt_common); deopt_frame_manager_return_ltos = __ pc(); __ li(result_index, AbstractInterpreter::BasicType_as_index(T_LONG)); __ b(return_from_deopt_common); deopt_frame_manager_return_ftos = __ pc(); __ li(result_index, AbstractInterpreter::BasicType_as_index(T_FLOAT)); __ b(return_from_deopt_common); deopt_frame_manager_return_dtos = __ pc(); __ li(result_index, AbstractInterpreter::BasicType_as_index(T_DOUBLE)); __ b(return_from_deopt_common); deopt_frame_manager_return_vtos = __ pc(); __ li(result_index, AbstractInterpreter::BasicType_as_index(T_VOID)); // Last one, fall-through to return_from_deopt_common. // Deopt return common. An index is present that lets us move any // possible result being return to the interpreter's stack. // __ BIND(return_from_deopt_common); } // Generate the code to handle a more_monitors message from the c++ interpreter. void CppInterpreterGenerator::generate_more_monitors() { // // Registers alive // R16_thread - JavaThread* // R15_prev_state - previous BytecodeInterpreter or 0 // R14_state - BytecodeInterpreter* address of receiver's interpreter state // R1_SP - old stack pointer // // Registers updated // R1_SP - new stack pointer // // Very-local scratch registers. const Register old_tos = R21_tmp1; const Register new_tos = R22_tmp2; const Register stack_base = R23_tmp3; const Register stack_limit = R24_tmp4; const Register slot = R25_tmp5; const Register n_slots = R25_tmp5; // Interpreter state fields. const Register msg = R24_tmp4; // Load up relevant interpreter state. __ ld(stack_base, state_(_stack_base)); // Old stack_base __ ld(old_tos, state_(_stack)); // Old tos __ ld(stack_limit, state_(_stack_limit)); // Old stack_limit // extracted monitor_size int monitor_size = frame::interpreter_frame_monitor_size_in_bytes(); assert(Assembler::is_aligned((unsigned int)monitor_size, (unsigned int)frame::alignment_in_bytes), "size of a monitor must respect alignment of SP"); // Save and restore top LR __ ld(R12_scratch2, _top_ijava_frame_abi(frame_manager_lr), R1_SP); __ resize_frame(-monitor_size, R11_scratch1);// Allocate space for new monitor __ std(R12_scratch2, _top_ijava_frame_abi(frame_manager_lr), R1_SP); // Initial_caller_sp is used as unextended_sp for non initial callers. __ std(R1_SP, _top_ijava_frame_abi(initial_caller_sp), R1_SP); __ addi(stack_base, stack_base, -monitor_size); // New stack_base __ addi(new_tos, old_tos, -monitor_size); // New tos __ addi(stack_limit, stack_limit, -monitor_size); // New stack_limit __ std(R1_SP, state_(_last_Java_sp)); // Update frame_bottom __ std(stack_base, state_(_stack_base)); // Update stack_base __ std(new_tos, state_(_stack)); // Update tos __ std(stack_limit, state_(_stack_limit)); // Update stack_limit __ li(msg, BytecodeInterpreter::got_monitors); // Tell interpreter we allocated the lock __ stw(msg, state_(_msg)); // Shuffle expression stack down. Recall that stack_base points // just above the new expression stack bottom. Old_tos and new_tos // are used to scan thru the old and new expression stacks. Label copy_slot, copy_slot_finished; __ sub(n_slots, stack_base, new_tos); __ srdi_(n_slots, n_slots, LogBytesPerWord); // compute number of slots to copy assert(LogBytesPerWord == 3, "conflicts assembler instructions"); __ beq(CCR0, copy_slot_finished); // nothing to copy __ mtctr(n_slots); // loop __ bind(copy_slot); __ ldu(slot, BytesPerWord, old_tos); // slot = *++old_tos; __ stdu(slot, BytesPerWord, new_tos); // *++new_tos = slot; __ bdnz(copy_slot); __ bind(copy_slot_finished); // Restart interpreter __ li(R0, 0); __ std(R0, BasicObjectLock::obj_offset_in_bytes(), stack_base); // Mark lock as unused } address CppInterpreterGenerator::generate_normal_entry(void) { if (interpreter_frame_manager != NULL) return interpreter_frame_manager; address entry = __ pc(); address return_from_native_pc = (address) NULL; // Initial entry to frame manager (from call_stub or c2i_adapter) // // Registers alive // R16_thread - JavaThread* // R19_method - callee's Method (method to be invoked) // R17_tos - address of sender tos (prepushed) // R1_SP - SP prepared by call stub such that caller's outgoing args are near top // LR - return address to caller (call_stub or c2i_adapter) // R21_sender_SP - initial caller sp // // Registers updated // R15_prev_state - 0 // // Stack layout at this point: // // 0 [TOP_IJAVA_FRAME_ABI] <-- R1_SP // alignment (optional) // [outgoing Java arguments] <-- R17_tos // ... // PARENT [PARENT_IJAVA_FRAME_ABI] // ... // // Save initial_caller_sp to caller's abi. // The caller frame must be resized before returning to get rid of // the c2i part on top of the calling compiled frame (if any). // R21_tmp1 must match sender_sp in gen_c2i_adapter. // Now override the saved SP with the senderSP so we can pop c2i // arguments (if any) off when we return. __ std(R21_sender_SP, _top_ijava_frame_abi(initial_caller_sp), R1_SP); // Save LR to caller's frame. We don't use _abi(lr) here, // because it is not safe. __ mflr(R0); __ std(R0, _top_ijava_frame_abi(frame_manager_lr), R1_SP); // If we come here, it is the first invocation of the frame manager. // So there is no previous interpreter state. __ li(R15_prev_state, 0); // Fall through to where "recursive" invocations go. //============================================================================= // Dispatch an instance of the interpreter. Recursive activations // come here. Label re_dispatch; __ BIND(re_dispatch); // // Registers alive // R16_thread - JavaThread* // R19_method - callee's Method // R17_tos - address of caller's tos (prepushed) // R15_prev_state - address of caller's BytecodeInterpreter or 0 // R1_SP - caller's SP trimmed such that caller's outgoing args are near top. // // Stack layout at this point: // // 0 [TOP_IJAVA_FRAME_ABI] // alignment (optional) // [outgoing Java arguments] // ... // PARENT [PARENT_IJAVA_FRAME_ABI] // ... // fall through to interpreted execution //============================================================================= // Allocate a new Java frame and initialize the new interpreter state. Label stack_overflow_return; // Create a suitable new Java frame plus a new BytecodeInterpreter instance // in the current (frame manager's) C frame. generate_compute_interpreter_state(stack_overflow_return); // fall through //============================================================================= // Interpreter dispatch. Label call_interpreter; __ BIND(call_interpreter); // // Registers alive // R16_thread - JavaThread* // R15_prev_state - previous BytecodeInterpreter or 0 // R14_state - address of receiver's BytecodeInterpreter // R1_SP - receiver's stack pointer // // Thread fields. const Register pending_exception = R21_tmp1; // Interpreter state fields. const Register msg = R24_tmp4; // Method fields. const Register parameter_count = R25_tmp5; const Register result_index = R26_tmp6; const Register dummy = R28_tmp8; // Address of various interpreter stubs. // R29_tmp9 is reserved. const Register stub_addr = R27_tmp7; // Uncommon trap needs to jump to here to enter the interpreter // (re-execute current bytecode). unctrap_frame_manager_entry = __ pc(); // If we are profiling, store our fp (BSP) in the thread so we can // find it during a tick. if (Arguments::has_profile()) { // On PPC64 we store the pointer to the current BytecodeInterpreter, // instead of the bsp of ia64. This should suffice to be able to // find all interesting information. __ std(R14_state, thread_(last_interpreter_fp)); } // R16_thread, R14_state and R15_prev_state are nonvolatile // registers. There is no need to save these. If we needed to save // some state in the current Java frame, this could be a place to do // so. // Call Java bytecode dispatcher passing "BytecodeInterpreter* istate". __ call_VM_leaf(CAST_FROM_FN_PTR(address, JvmtiExport::can_post_interpreter_events() ? BytecodeInterpreter::runWithChecks : BytecodeInterpreter::run), R14_state); interpreter_return_address = __ last_calls_return_pc(); // R16_thread, R14_state and R15_prev_state have their values preserved. // If we are profiling, clear the fp in the thread to tell // the profiler that we are no longer in the interpreter. if (Arguments::has_profile()) { __ li(R11_scratch1, 0); __ std(R11_scratch1, thread_(last_interpreter_fp)); } // Load message from bytecode dispatcher. // TODO: PPC port: guarantee(4 == BytecodeInterpreter::sz_msg(), "unexpected field size"); __ lwz(msg, state_(_msg)); Label more_monitors; Label return_from_native; Label return_from_native_common; Label return_from_native_no_exception; Label return_from_interpreted_method; Label return_from_recursive_activation; Label unwind_recursive_activation; Label resume_interpreter; Label return_to_initial_caller; Label unwind_initial_activation; Label unwind_initial_activation_pending_exception; Label call_method; Label call_special; Label retry_method; Label retry_method_osr; Label popping_frame; Label throwing_exception; // Branch according to the received message __ cmpwi(CCR1, msg, BytecodeInterpreter::call_method); __ cmpwi(CCR2, msg, BytecodeInterpreter::return_from_method); __ beq(CCR1, call_method); __ beq(CCR2, return_from_interpreted_method); __ cmpwi(CCR3, msg, BytecodeInterpreter::more_monitors); __ cmpwi(CCR4, msg, BytecodeInterpreter::throwing_exception); __ beq(CCR3, more_monitors); __ beq(CCR4, throwing_exception); __ cmpwi(CCR5, msg, BytecodeInterpreter::popping_frame); __ cmpwi(CCR6, msg, BytecodeInterpreter::do_osr); __ beq(CCR5, popping_frame); __ beq(CCR6, retry_method_osr); __ stop("bad message from interpreter"); //============================================================================= // Add a monitor just below the existing one(s). State->_stack_base // points to the lowest existing one, so we insert the new one just // below it and shuffle the expression stack down. Ref. the above // stack layout picture, we must update _stack_base, _stack, _stack_limit // and _last_Java_sp in the interpreter state. __ BIND(more_monitors); generate_more_monitors(); __ b(call_interpreter); generate_deopt_handling(result_index); // Restoring the R14_state is already done by the deopt_blob. // Current tos includes no parameter slots. __ ld(R17_tos, state_(_stack)); __ li(msg, BytecodeInterpreter::deopt_resume); __ b(return_from_native_common); // We are sent here when we are unwinding from a native method or // adapter with an exception pending. We need to notify the interpreter // that there is an exception to process. // We arrive here also if the frame manager called an (interpreted) target // which returns with a StackOverflow exception. // The control flow is in this case is: // frame_manager->throw_excp_stub->forward_excp->rethrow_excp_entry AbstractInterpreter::_rethrow_exception_entry = __ pc(); // Restore R14_state. __ ld(R14_state, 0, R1_SP); __ addi(R14_state, R14_state, -frame::interpreter_frame_cinterpreterstate_size_in_bytes()); // Store exception oop into thread object. __ std(R3_RET, thread_(pending_exception)); __ li(msg, BytecodeInterpreter::method_resume /*rethrow_exception*/); // // NOTE: the interpreter frame as setup be deopt does NOT include // any parameter slots (good thing since we have no callee here // and couldn't remove them) so we don't have to do any calculations // here to figure it out. // __ ld(R17_tos, state_(_stack)); __ b(return_from_native_common); //============================================================================= // Returning from a native method. Result is in the native abi // location so we must move it to the java expression stack. __ BIND(return_from_native); guarantee(return_from_native_pc == (address) NULL, "precondition"); return_from_native_pc = __ pc(); // Restore R14_state. __ ld(R14_state, 0, R1_SP); __ addi(R14_state, R14_state, -frame::interpreter_frame_cinterpreterstate_size_in_bytes()); // // Registers alive // R16_thread // R14_state - address of caller's BytecodeInterpreter. // R3_RET - integer result, if any. // F1_RET - float result, if any. // // Registers updated // R19_method - callee's Method // R17_tos - caller's tos, with outgoing args popped // result_index - index of result handler. // msg - message for resuming interpreter. // // Very-local scratch registers. const ConditionRegister have_pending_exception = CCR0; // Load callee Method, gc may have moved it. __ ld(R19_method, state_(_result._to_call._callee)); // Load address of caller's tos. includes parameter slots. __ ld(R17_tos, state_(_stack)); // Pop callee's parameters. __ ld(parameter_count, in_bytes(Method::const_offset()), R19_method); __ lhz(parameter_count, in_bytes(ConstMethod::size_of_parameters_offset()), parameter_count); __ sldi(parameter_count, parameter_count, Interpreter::logStackElementSize); __ add(R17_tos, R17_tos, parameter_count); // Result stub address array index // TODO: PPC port: assert(4 == sizeof(AccessFlags), "unexpected field size"); __ lwa(result_index, method_(result_index)); __ li(msg, BytecodeInterpreter::method_resume); // // Registers alive // R16_thread // R14_state - address of caller's BytecodeInterpreter. // R17_tos - address of caller's tos with outgoing args already popped // R3_RET - integer return value, if any. // F1_RET - float return value, if any. // result_index - index of result handler. // msg - message for resuming interpreter. // // Registers updated // R3_RET - new address of caller's tos, including result, if any // __ BIND(return_from_native_common); // Check for pending exception __ ld(pending_exception, thread_(pending_exception)); __ cmpdi(CCR0, pending_exception, 0); __ beq(CCR0, return_from_native_no_exception); // If there's a pending exception, we really have no result, so // R3_RET is dead. Resume_interpreter assumes the new tos is in // R3_RET. __ mr(R3_RET, R17_tos); // `resume_interpreter' expects R15_prev_state to be alive. __ ld(R15_prev_state, state_(_prev_link)); __ b(resume_interpreter); __ BIND(return_from_native_no_exception); // No pending exception, copy method result from native ABI register // to tos. // Address of stub descriptor address array. __ load_const(stub_addr, CppInterpreter::tosca_result_to_stack()); // Pass address of tos to stub. __ mr(R4_ARG2, R17_tos); // Address of stub descriptor address. __ sldi(result_index, result_index, LogBytesPerWord); __ add(stub_addr, stub_addr, result_index); // Stub descriptor address. __ ld(stub_addr, 0, stub_addr); // TODO: don't do this via a call, do it in place! // // call stub via descriptor // in R3_ARG1/F1_ARG1: result value (R3_RET or F1_RET) __ call_stub(stub_addr); // new tos = result of call in R3_RET // `resume_interpreter' expects R15_prev_state to be alive. __ ld(R15_prev_state, state_(_prev_link)); __ b(resume_interpreter); //============================================================================= // We encountered an exception while computing the interpreter // state, so R14_state isn't valid. Act as if we just returned from // the callee method with a pending exception. __ BIND(stack_overflow_return); // // Registers alive // R16_thread - JavaThread* // R1_SP - old stack pointer // R19_method - callee's Method // R17_tos - address of caller's tos (prepushed) // R15_prev_state - address of caller's BytecodeInterpreter or 0 // R18_locals - address of callee's locals array // // Registers updated // R3_RET - address of resuming tos, if recursive unwind Label Lskip_unextend_SP; { const ConditionRegister is_initial_call = CCR0; const Register tos_save = R21_tmp1; const Register tmp = R22_tmp2; assert(tos_save->is_nonvolatile(), "need a nonvolatile"); // Is the exception thrown in the initial Java frame of this frame // manager frame? __ cmpdi(is_initial_call, R15_prev_state, 0); __ bne(is_initial_call, Lskip_unextend_SP); // Pop any c2i extension from the stack. This is necessary in the // non-recursive case (that is we were called by the c2i adapter, // meaning we have to prev state). In this case we entered the frame // manager through a special entry which pushes the orignal // unextended SP to the stack. Here we load it back. __ ld(R0, _top_ijava_frame_abi(frame_manager_lr), R1_SP); __ mtlr(R0); // Resize frame to get rid of a potential extension. __ resize_frame_to_initial_caller(R11_scratch1, R12_scratch2); // Fall through __ bind(Lskip_unextend_SP); // Throw the exception via RuntimeStub "throw_StackOverflowError_entry". // // Previously, we called C-Code directly. As a consequence, a // possible GC tried to process the argument oops of the top frame // (see RegisterMap::clear, which sets the corresponding flag to // true). This lead to crashes because: // 1. The top register map did not contain locations for the argument registers // 2. The arguments are dead anyway, could be already overwritten in the worst case // Solution: Call via special runtime stub that pushes it's own frame. This runtime stub has the flag // "CodeBlob::caller_must_gc_arguments()" set to "false", what prevents the dead arguments getting GC'd. // // 2 cases exist: // 1. We were called by the c2i adapter / call stub // 2. We were called by the frame manager // // Both cases are handled by this code: // 1. - initial_caller_sp was saved on stack => Load it back and we're ok // - control flow will be: // throw_stackoverflow_stub->VM->throw_stackoverflow_stub->forward_excep->excp_blob of calling method // 2. - control flow will be: // throw_stackoverflow_stub->VM->throw_stackoverflow_stub->forward_excep-> // ->rethrow_excp_entry of frame manager->resume_method // Since we restored the caller SP above, the rethrow_excp_entry can restore the original interpreter state // registers using the stack and resume the calling method with a pending excp. assert(StubRoutines::throw_StackOverflowError_entry() != NULL, "generated in wrong order"); __ load_const(R3_ARG1, (StubRoutines::throw_StackOverflowError_entry())); __ mtctr(R3_ARG1); __ bctr(); } //============================================================================= // We have popped a frame from an interpreted call. We are assured // of returning to an interpreted call by the popframe abi. We have // no return value all we have to do is pop the current frame and // then make sure that the top of stack (of the caller) gets set to // where it was when we entered the callee (i.e. the args are still // in place). Or we are returning to the interpreter. In the first // case we must extract result (if any) from the java expression // stack and store it in the location the native abi would expect // for a call returning this type. In the second case we must simply // do a stack to stack move as we unwind. __ BIND(popping_frame); // Registers alive // R14_state // R15_prev_state // R17_tos // // Registers updated // R19_method // R3_RET // msg { Label L; // Reload callee method, gc may have moved it. __ ld(R19_method, state_(_method)); // We may be returning to a deoptimized frame in which case the // usual assumption of a recursive return is not true. // not equal = is recursive call __ cmpdi(CCR0, R15_prev_state, 0); __ bne(CCR0, L); // Pop_frame capability. // The pop_frame api says that the underlying frame is a Java frame, in this case // (prev_state==null) it must be a compiled frame: // // Stack at this point: I, C2I + C, ... // // The outgoing arguments of the call have just been copied (popframe_preserve_args). // By the pop_frame api, we must end up in an interpreted frame. So the compiled frame // will be deoptimized. Deoptimization will restore the outgoing arguments from // popframe_preserve_args, adjust the tos such that it includes the popframe_preserve_args, // and adjust the bci such that the call will be executed again. // We have no results, just pop the interpreter frame, resize the compiled frame to get rid // of the c2i extension and return to the deopt_handler. __ b(unwind_initial_activation); // is recursive call __ bind(L); // Resume_interpreter expects the original tos in R3_RET. __ ld(R3_RET, prev_state_(_stack)); // We're done. __ li(msg, BytecodeInterpreter::popping_frame); __ b(unwind_recursive_activation); } //============================================================================= // We have finished an interpreted call. We are either returning to // native (call_stub/c2) or we are returning to the interpreter. // When returning to native, we must extract the result (if any) // from the java expression stack and store it in the location the // native abi expects. When returning to the interpreter we must // simply do a stack to stack move as we unwind. __ BIND(return_from_interpreted_method); // // Registers alive // R16_thread - JavaThread* // R15_prev_state - address of caller's BytecodeInterpreter or 0 // R14_state - address of callee's interpreter state // R1_SP - callee's stack pointer // // Registers updated // R19_method - callee's method // R3_RET - address of result (new caller's tos), // // if returning to interpreted // msg - message for interpreter, // if returning to interpreted // // Check if this is the initial invocation of the frame manager. // If so, R15_prev_state will be null. __ cmpdi(CCR0, R15_prev_state, 0); // Reload callee method, gc may have moved it. __ ld(R19_method, state_(_method)); // Load the method's result type. __ lwz(result_index, method_(result_index)); // Go to return_to_initial_caller if R15_prev_state is null. __ beq(CCR0, return_to_initial_caller); // Copy callee's result to caller's expression stack via inline stack-to-stack // converters. { Register new_tos = R3_RET; Register from_temp = R4_ARG2; Register from = R5_ARG3; Register tos = R6_ARG4; Register tmp1 = R7_ARG5; Register tmp2 = R8_ARG6; ConditionRegister result_type_is_void = CCR1; ConditionRegister result_type_is_long = CCR2; ConditionRegister result_type_is_double = CCR3; Label stack_to_stack_void; Label stack_to_stack_double_slot; // T_LONG, T_DOUBLE Label stack_to_stack_single_slot; // T_BOOLEAN, T_BYTE, T_CHAR, T_SHORT, T_INT, T_FLOAT, T_OBJECT Label stack_to_stack_done; // Pass callee's address of tos + BytesPerWord __ ld(from_temp, state_(_stack)); // result type: void __ cmpwi(result_type_is_void, result_index, AbstractInterpreter::BasicType_as_index(T_VOID)); // Pass caller's tos == callee's locals address __ ld(tos, state_(_locals)); // result type: long __ cmpwi(result_type_is_long, result_index, AbstractInterpreter::BasicType_as_index(T_LONG)); __ addi(from, from_temp, Interpreter::stackElementSize); // !! don't branch above this line !! // handle void __ beq(result_type_is_void, stack_to_stack_void); // result type: double __ cmpwi(result_type_is_double, result_index, AbstractInterpreter::BasicType_as_index(T_DOUBLE)); // handle long or double __ beq(result_type_is_long, stack_to_stack_double_slot); __ beq(result_type_is_double, stack_to_stack_double_slot); // fall through to single slot types (incl. object) { __ BIND(stack_to_stack_single_slot); // T_BOOLEAN, T_BYTE, T_CHAR, T_SHORT, T_INT, T_FLOAT, T_OBJECT __ ld(tmp1, 0, from); __ std(tmp1, 0, tos); // New expression stack top __ addi(new_tos, tos, - BytesPerWord); __ b(stack_to_stack_done); } { __ BIND(stack_to_stack_double_slot); // T_LONG, T_DOUBLE // Move both entries for debug purposes even though only one is live __ ld(tmp1, BytesPerWord, from); __ ld(tmp2, 0, from); __ std(tmp1, 0, tos); __ std(tmp2, -BytesPerWord, tos); // new expression stack top __ addi(new_tos, tos, - 2 * BytesPerWord); // two slots __ b(stack_to_stack_done); } { __ BIND(stack_to_stack_void); // T_VOID // new expression stack top __ mr(new_tos, tos); // fall through to stack_to_stack_done } __ BIND(stack_to_stack_done); } // new tos = R3_RET // Get the message for the interpreter __ li(msg, BytecodeInterpreter::method_resume); // And fall thru //============================================================================= // Restore caller's interpreter state and pass pointer to caller's // new tos to caller. __ BIND(unwind_recursive_activation); // // Registers alive // R15_prev_state - address of caller's BytecodeInterpreter // R3_RET - address of caller's tos // msg - message for caller's BytecodeInterpreter // R1_SP - callee's stack pointer // // Registers updated // R14_state - address of caller's BytecodeInterpreter // R15_prev_state - address of its parent or 0 // // Pop callee's interpreter and set R14_state to caller's interpreter. __ pop_interpreter_state(/*prev_state_may_be_0=*/false); // And fall thru //============================================================================= // Resume the (calling) interpreter after a call. __ BIND(resume_interpreter); // // Registers alive // R14_state - address of resuming BytecodeInterpreter // R15_prev_state - address of its parent or 0 // R3_RET - address of resuming tos // msg - message for resuming interpreter // R1_SP - callee's stack pointer // // Registers updated // R1_SP - caller's stack pointer // // Restore C stack pointer of caller (resuming interpreter), // R14_state already points to the resuming BytecodeInterpreter. __ pop_interpreter_frame_to_state(R14_state, R21_tmp1, R11_scratch1, R12_scratch2); // Store new address of tos (holding return value) in interpreter state. __ std(R3_RET, state_(_stack)); // Store message for interpreter. __ stw(msg, state_(_msg)); __ b(call_interpreter); //============================================================================= // Interpreter returning to native code (call_stub/c1/c2) from // initial activation. Convert stack result and unwind activation. __ BIND(return_to_initial_caller); // // Registers alive // R19_method - callee's Method // R14_state - address of callee's interpreter state // R16_thread - JavaThread // R1_SP - callee's stack pointer // // Registers updated // R3_RET/F1_RET - result in expected output register // // If we have an exception pending we have no result and we // must figure out where to really return to. // __ ld(pending_exception, thread_(pending_exception)); __ cmpdi(CCR0, pending_exception, 0); __ bne(CCR0, unwind_initial_activation_pending_exception); __ lwa(result_index, method_(result_index)); // Address of stub descriptor address array. __ load_const(stub_addr, CppInterpreter::stack_result_to_native()); // Pass address of callee's tos + BytesPerWord. // Will then point directly to result. __ ld(R3_ARG1, state_(_stack)); __ addi(R3_ARG1, R3_ARG1, Interpreter::stackElementSize); // Address of stub descriptor address __ sldi(result_index, result_index, LogBytesPerWord); __ add(stub_addr, stub_addr, result_index); // Stub descriptor address __ ld(stub_addr, 0, stub_addr); // TODO: don't do this via a call, do it in place! // // call stub via descriptor __ call_stub(stub_addr); __ BIND(unwind_initial_activation); // Unwind from initial activation. No exception is pending. // // Stack layout at this point: // // 0 [TOP_IJAVA_FRAME_ABI] <-- R1_SP // ... // CALLER [PARENT_IJAVA_FRAME_ABI] // ... // CALLER [unextended ABI] // ... // // The CALLER frame has a C2I adapter or is an entry-frame. // // An interpreter frame exists, we may pop the TOP_IJAVA_FRAME and // turn the caller's PARENT_IJAVA_FRAME back into a TOP_IJAVA_FRAME. // But, we simply restore the return pc from the caller's frame and // use the caller's initial_caller_sp as the new SP which pops the // interpreter frame and "resizes" the caller's frame to its "unextended" // size. // get rid of top frame __ pop_frame(); // Load return PC from parent frame. __ ld(R21_tmp1, _parent_ijava_frame_abi(lr), R1_SP); // Resize frame to get rid of a potential extension. __ resize_frame_to_initial_caller(R11_scratch1, R12_scratch2); // update LR __ mtlr(R21_tmp1); // return __ blr(); //============================================================================= // Unwind from initial activation. An exception is pending __ BIND(unwind_initial_activation_pending_exception); // // Stack layout at this point: // // 0 [TOP_IJAVA_FRAME_ABI] <-- R1_SP // ... // CALLER [PARENT_IJAVA_FRAME_ABI] // ... // CALLER [unextended ABI] // ... // // The CALLER frame has a C2I adapter or is an entry-frame. // // An interpreter frame exists, we may pop the TOP_IJAVA_FRAME and // turn the caller's PARENT_IJAVA_FRAME back into a TOP_IJAVA_FRAME. // But, we just pop the current TOP_IJAVA_FRAME and fall through __ pop_frame(); __ ld(R3_ARG1, _top_ijava_frame_abi(lr), R1_SP); // // Stack layout at this point: // // CALLER [PARENT_IJAVA_FRAME_ABI] <-- R1_SP // ... // CALLER [unextended ABI] // ... // // The CALLER frame has a C2I adapter or is an entry-frame. // // Registers alive // R16_thread // R3_ARG1 - return address to caller // // Registers updated // R3_ARG1 - address of pending exception // R4_ARG2 - issuing pc = return address to caller // LR - address of exception handler stub // // Resize frame to get rid of a potential extension. __ resize_frame_to_initial_caller(R11_scratch1, R12_scratch2); __ mr(R14, R3_ARG1); // R14 := ARG1 __ mr(R4_ARG2, R3_ARG1); // ARG2 := ARG1 // Find the address of the "catch_exception" stub. __ push_frame_reg_args(0, R11_scratch1); __ call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::exception_handler_for_return_address), R16_thread, R4_ARG2); __ pop_frame(); // Load continuation address into LR. __ mtlr(R3_RET); // Load address of pending exception and clear it in thread object. __ ld(R3_ARG1/*R3_RET*/, thread_(pending_exception)); __ li(R4_ARG2, 0); __ std(R4_ARG2, thread_(pending_exception)); // re-load issuing pc __ mr(R4_ARG2, R14); // Branch to found exception handler. __ blr(); //============================================================================= // Call a new method. Compute new args and trim the expression stack // to only what we are currently using and then recurse. __ BIND(call_method); // // Registers alive // R16_thread // R14_state - address of caller's BytecodeInterpreter // R1_SP - caller's stack pointer // // Registers updated // R15_prev_state - address of caller's BytecodeInterpreter // R17_tos - address of caller's tos // R19_method - callee's Method // R1_SP - trimmed back // // Very-local scratch registers. const Register offset = R21_tmp1; const Register tmp = R22_tmp2; const Register self_entry = R23_tmp3; const Register stub_entry = R24_tmp4; const ConditionRegister cr = CCR0; // Load the address of the frame manager. __ load_const(self_entry, &interpreter_frame_manager); __ ld(self_entry, 0, self_entry); // Load BytecodeInterpreter._result._to_call._callee (callee's Method). __ ld(R19_method, state_(_result._to_call._callee)); // Load BytecodeInterpreter._stack (outgoing tos). __ ld(R17_tos, state_(_stack)); // Save address of caller's BytecodeInterpreter. __ mr(R15_prev_state, R14_state); // Load the callee's entry point. // Load BytecodeInterpreter._result._to_call._callee_entry_point. __ ld(stub_entry, state_(_result._to_call._callee_entry_point)); // Check whether stub_entry is equal to self_entry. __ cmpd(cr, self_entry, stub_entry); // if (self_entry == stub_entry) // do a re-dispatch __ beq(cr, re_dispatch); // else // call the specialized entry (adapter for jni or compiled code) __ BIND(call_special); // // Call the entry generated by `InterpreterGenerator::generate_native_entry'. // // Registers alive // R16_thread // R15_prev_state - address of caller's BytecodeInterpreter // R19_method - callee's Method // R17_tos - address of caller's tos // R1_SP - caller's stack pointer // // Mark return from specialized entry for generate_native_entry. guarantee(return_from_native_pc != (address) NULL, "precondition"); frame_manager_specialized_return = return_from_native_pc; // Set sender_SP in case we call interpreter native wrapper which // will expect it. Compiled code should not care. __ mr(R21_sender_SP, R1_SP); // Do a tail call here, and let the link register point to // frame_manager_specialized_return which is return_from_native_pc. __ load_const(tmp, frame_manager_specialized_return); __ call_stub_and_return_to(stub_entry, tmp /* return_pc=tmp */); //============================================================================= // // InterpretMethod triggered OSR compilation of some Java method M // and now asks to run the compiled code. We call this code the // `callee'. // // This is our current idea on how OSR should look like on PPC64: // // While interpreting a Java method M the stack is: // // (InterpretMethod (M), IJAVA_FRAME (M), ANY_FRAME, ...). // // After having OSR compiled M, `InterpretMethod' returns to the // frame manager, sending the message `retry_method_osr'. The stack // is: // // (IJAVA_FRAME (M), ANY_FRAME, ...). // // The compiler will have generated an `nmethod' suitable for // continuing execution of M at the bytecode index at which OSR took // place. So now the frame manager calls the OSR entry. The OSR // entry sets up a JIT_FRAME for M and continues execution of M with // initial state determined by the IJAVA_FRAME. // // (JIT_FRAME (M), IJAVA_FRAME (M), ANY_FRAME, ...). // __ BIND(retry_method_osr); { // // Registers alive // R16_thread // R15_prev_state - address of caller's BytecodeInterpreter // R14_state - address of callee's BytecodeInterpreter // R1_SP - callee's SP before call to InterpretMethod // // Registers updated // R17 - pointer to callee's locals array // (declared via `interpreter_arg_ptr_reg' in the AD file) // R19_method - callee's Method // R1_SP - callee's SP (will become SP of OSR adapter frame) // // Provide a debugger breakpoint in the frame manager if breakpoints // in osr'd methods are requested. #ifdef COMPILER2 NOT_PRODUCT( if (OptoBreakpointOSR) { __ illtrap(); } ) #endif // Load callee's pointer to locals array from callee's state. // __ ld(R17, state_(_locals)); // Load osr entry. __ ld(R12_scratch2, state_(_result._osr._osr_entry)); // Load address of temporary osr buffer to arg1. __ ld(R3_ARG1, state_(_result._osr._osr_buf)); __ mtctr(R12_scratch2); // Load method, gc may move it during execution of osr'd method. __ ld(R22_tmp2, state_(_method)); // Load message 'call_method'. __ li(R23_tmp3, BytecodeInterpreter::call_method); { // Pop the IJAVA frame of the method which we are going to call osr'd. Label no_state, skip_no_state; __ pop_interpreter_state(/*prev_state_may_be_0=*/true); __ cmpdi(CCR0, R14_state,0); __ beq(CCR0, no_state); // return to interpreter __ pop_interpreter_frame_to_state(R14_state, R11_scratch1, R12_scratch2, R21_tmp1); // Init _result._to_call._callee and tell gc that it contains a valid oop // by setting _msg to 'call_method'. __ std(R22_tmp2, state_(_result._to_call._callee)); // TODO: PPC port: assert(4 == BytecodeInterpreter::sz_msg(), "unexpected field size"); __ stw(R23_tmp3, state_(_msg)); __ load_const(R21_tmp1, frame_manager_specialized_return); __ b(skip_no_state); __ bind(no_state); // Return to initial caller. // Get rid of top frame. __ pop_frame(); // Load return PC from parent frame. __ ld(R21_tmp1, _parent_ijava_frame_abi(lr), R1_SP); // Resize frame to get rid of a potential extension. __ resize_frame_to_initial_caller(R11_scratch1, R12_scratch2); __ bind(skip_no_state); // Update LR with return pc. __ mtlr(R21_tmp1); } // Jump to the osr entry point. __ bctr(); } //============================================================================= // Interpreted method "returned" with an exception, pass it on. // Pass no result, unwind activation and continue/return to // interpreter/call_stub/c2. __ BIND(throwing_exception); // Check if this is the initial invocation of the frame manager. If // so, previous interpreter state in R15_prev_state will be null. // New tos of caller is callee's first parameter address, that is // callee's incoming arguments are popped. __ ld(R3_RET, state_(_locals)); // Check whether this is an initial call. __ cmpdi(CCR0, R15_prev_state, 0); // Yes, called from the call stub or from generated code via a c2i frame. __ beq(CCR0, unwind_initial_activation_pending_exception); // Send resume message, interpreter will see the exception first. __ li(msg, BytecodeInterpreter::method_resume); __ b(unwind_recursive_activation); //============================================================================= // Push the last instruction out to the code buffer. { __ unimplemented("end of InterpreterGenerator::generate_normal_entry", 128); } interpreter_frame_manager = entry; return interpreter_frame_manager; } // Generate code for various sorts of method entries // address AbstractInterpreterGenerator::generate_method_entry(AbstractInterpreter::MethodKind kind) { address entry_point = NULL; switch (kind) { case Interpreter::zerolocals : break; case Interpreter::zerolocals_synchronized : break; case Interpreter::native : // Fall thru case Interpreter::native_synchronized : entry_point = ((CppInterpreterGenerator*)this)->generate_native_entry(); break; case Interpreter::empty : break; case Interpreter::accessor : entry_point = ((InterpreterGenerator*)this)->generate_accessor_entry(); break; case Interpreter::abstract : entry_point = ((InterpreterGenerator*)this)->generate_abstract_entry(); break; // These are special interpreter intrinsics which we don't support so far. case Interpreter::java_lang_math_sin : break; case Interpreter::java_lang_math_cos : break; case Interpreter::java_lang_math_tan : break; case Interpreter::java_lang_math_abs : break; case Interpreter::java_lang_math_log : break; case Interpreter::java_lang_math_log10 : break; case Interpreter::java_lang_math_sqrt : break; case Interpreter::java_lang_math_pow : break; case Interpreter::java_lang_math_exp : break; case Interpreter::java_lang_ref_reference_get: entry_point = ((InterpreterGenerator*)this)->generate_Reference_get_entry(); break; default : ShouldNotReachHere(); break; } if (entry_point) { return entry_point; } return ((InterpreterGenerator*)this)->generate_normal_entry(); } InterpreterGenerator::InterpreterGenerator(StubQueue* code) : CppInterpreterGenerator(code) { generate_all(); // down here so it can be "virtual" } // How much stack a topmost interpreter method activation needs in words. int AbstractInterpreter::size_top_interpreter_activation(Method* method) { // Computation is in bytes not words to match layout_activation_impl // below, but the return is in words. // // 0 [TOP_IJAVA_FRAME_ABI] \ // alignment (optional) \ | // [operand stack / Java parameters] > stack | | // [monitors] (optional) > monitors | | // [PARENT_IJAVA_FRAME_ABI] \ | | // [BytecodeInterpreter object] > interpreter \ | | | // alignment (optional) | round | parent | round | top // [Java result] (2 slots) > result | | | | // [Java non-arg locals] \ locals | | | | // [arg locals] / / / / / // int locals = method->max_locals() * BytesPerWord; int interpreter = frame::interpreter_frame_cinterpreterstate_size_in_bytes(); int result = 2 * BytesPerWord; int parent = round_to(interpreter + result + locals, 16) + frame::parent_ijava_frame_abi_size; int stack = method->max_stack() * BytesPerWord; int monitors = method->is_synchronized() ? frame::interpreter_frame_monitor_size_in_bytes() : 0; int top = round_to(parent + monitors + stack, 16) + frame::top_ijava_frame_abi_size; return (top / BytesPerWord); } void BytecodeInterpreter::layout_interpreterState(interpreterState to_fill, frame* caller, frame* current, Method* method, intptr_t* locals, intptr_t* stack, intptr_t* stack_base, intptr_t* monitor_base, intptr_t* frame_sp, bool is_top_frame) { // What about any vtable? // to_fill->_thread = JavaThread::current(); // This gets filled in later but make it something recognizable for now. to_fill->_bcp = method->code_base(); to_fill->_locals = locals; to_fill->_constants = method->constants()->cache(); to_fill->_method = method; to_fill->_mdx = NULL; to_fill->_stack = stack; if (is_top_frame && JavaThread::current()->popframe_forcing_deopt_reexecution()) { to_fill->_msg = deopt_resume2; } else { to_fill->_msg = method_resume; } to_fill->_result._to_call._bcp_advance = 0; to_fill->_result._to_call._callee_entry_point = NULL; // doesn't matter to anyone to_fill->_result._to_call._callee = NULL; // doesn't matter to anyone to_fill->_prev_link = NULL; if (caller->is_interpreted_frame()) { interpreterState prev = caller->get_interpreterState(); // Support MH calls. Make sure the interpreter will return the right address: // 1. Caller did ordinary interpreted->compiled call call: Set a prev_state // which makes the CPP interpreter return to frame manager "return_from_interpreted_method" // entry after finishing execution. // 2. Caller did a MH call: If the caller has a MethodHandleInvoke in it's // state (invariant: must be the caller of the bottom vframe) we used the // "call_special" entry to do the call, meaning the arguments have not been // popped from the stack. Therefore, don't enter a prev state in this case // in order to return to "return_from_native" frame manager entry which takes // care of popping arguments. Also, don't overwrite the MH.invoke Method in // the prev_state in order to be able to figure out the number of arguments to // pop. // The parameter method can represent MethodHandle.invokeExact(...). // The MethodHandleCompiler generates these synthetic Methods, // including bytecodes, if an invokedynamic call gets inlined. In // this case we want to return like from any other interpreted // Java call, so we set _prev_link. to_fill->_prev_link = prev; if (*prev->_bcp == Bytecodes::_invokeinterface || *prev->_bcp == Bytecodes::_invokedynamic) { prev->_result._to_call._bcp_advance = 5; } else { prev->_result._to_call._bcp_advance = 3; } } to_fill->_oop_temp = NULL; to_fill->_stack_base = stack_base; // Need +1 here because stack_base points to the word just above the // first expr stack entry and stack_limit is supposed to point to // the word just below the last expr stack entry. See // generate_compute_interpreter_state. to_fill->_stack_limit = stack_base - (method->max_stack() + 1); to_fill->_monitor_base = (BasicObjectLock*) monitor_base; to_fill->_frame_bottom = frame_sp; // PPC64 specific to_fill->_last_Java_pc = NULL; to_fill->_last_Java_fp = NULL; to_fill->_last_Java_sp = frame_sp; #ifdef ASSERT to_fill->_self_link = to_fill; to_fill->_native_fresult = 123456.789; to_fill->_native_lresult = CONST64(0xdeafcafedeadc0de); #endif } void BytecodeInterpreter::pd_layout_interpreterState(interpreterState istate, address last_Java_pc, intptr_t* last_Java_fp) { istate->_last_Java_pc = last_Java_pc; istate->_last_Java_fp = last_Java_fp; } // Computes monitor_size and top_frame_size in bytes. static void frame_size_helper(int max_stack, int monitors, int& monitor_size, int& top_frame_size) { monitor_size = frame::interpreter_frame_monitor_size_in_bytes() * monitors; top_frame_size = round_to(frame::interpreter_frame_cinterpreterstate_size_in_bytes() + monitor_size + max_stack * Interpreter::stackElementSize + 2 * Interpreter::stackElementSize, frame::alignment_in_bytes) + frame::top_ijava_frame_abi_size; } // Returns number of stackElementWords needed for the interpreter frame with the // given sections. int AbstractInterpreter::size_activation(int max_stack, int temps, int extra_args, int monitors, int callee_params, int callee_locals, bool is_top_frame) { int monitor_size = 0; int top_frame_size = 0; frame_size_helper(max_stack, monitors, monitor_size, top_frame_size); int frame_size; if (is_top_frame) { frame_size = top_frame_size; } else { frame_size = round_to(frame::interpreter_frame_cinterpreterstate_size_in_bytes() + monitor_size + (temps - callee_params + callee_locals) * Interpreter::stackElementSize + 2 * Interpreter::stackElementSize, frame::alignment_in_bytes) + frame::parent_ijava_frame_abi_size; assert(extra_args == 0, "non-zero for top_frame only"); } return frame_size / Interpreter::stackElementSize; } void AbstractInterpreter::layout_activation(Method* method, int temps, // Number of slots on java expression stack in use. int popframe_args, int monitors, // Number of active monitors. int caller_actual_parameters, int callee_params,// Number of slots for callee parameters. int callee_locals,// Number of slots for locals. frame* caller, frame* interpreter_frame, bool is_top_frame, bool is_bottom_frame) { // NOTE this code must exactly mimic what // InterpreterGenerator::generate_compute_interpreter_state() does // as far as allocating an interpreter frame. However there is an // exception. With the C++ based interpreter only the top most frame // has a full sized expression stack. The 16 byte slop factor is // both the abi scratch area and a place to hold a result from a // callee on its way to the callers stack. int monitor_size = 0; int top_frame_size = 0; frame_size_helper(method->max_stack(), monitors, monitor_size, top_frame_size); intptr_t sp = (intptr_t)interpreter_frame->sp(); intptr_t fp = *(intptr_t *)sp; assert(fp == (intptr_t)caller->sp(), "fp must match"); interpreterState cur_state = (interpreterState)(fp - frame::interpreter_frame_cinterpreterstate_size_in_bytes()); // Now fill in the interpreterState object. intptr_t* locals; if (caller->is_interpreted_frame()) { // Locals must agree with the caller because it will be used to set the // caller's tos when we return. interpreterState prev = caller->get_interpreterState(); // Calculate start of "locals" for MH calls. For MH calls, the // current method() (= MH target) and prev->callee() (= // MH.invoke*()) are different and especially have different // signatures. To pop the argumentsof the caller, we must use // the prev->callee()->size_of_arguments() because that's what // the caller actually pushed. Currently, for synthetic MH // calls (deoptimized from inlined MH calls), detected by // is_method_handle_invoke(), we use the callee's arguments // because here, the caller's and callee's signature match. if (true /*!caller->is_at_mh_callsite()*/) { locals = prev->stack() + method->size_of_parameters(); } else { // Normal MH call. locals = prev->stack() + prev->callee()->size_of_parameters(); } } else { bool is_deopted; locals = (intptr_t*) (fp + ((method->max_locals() - 1) * BytesPerWord) + frame::parent_ijava_frame_abi_size); } intptr_t* monitor_base = (intptr_t*) cur_state; intptr_t* stack_base = (intptr_t*) ((intptr_t) monitor_base - monitor_size); // Provide pop_frame capability on PPC64, add popframe_args. // +1 because stack is always prepushed. intptr_t* stack = (intptr_t*) ((intptr_t) stack_base - (temps + popframe_args + 1) * BytesPerWord); BytecodeInterpreter::layout_interpreterState(cur_state, caller, interpreter_frame, method, locals, stack, stack_base, monitor_base, (intptr_t*)(((intptr_t)fp) - top_frame_size), is_top_frame); BytecodeInterpreter::pd_layout_interpreterState(cur_state, interpreter_return_address, interpreter_frame->fp()); } #endif // CC_INTERP