/* * Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #include "precompiled.hpp" #include "asm/assembler.hpp" #include "asm/assembler.inline.hpp" #include "compiler/disassembler.hpp" #include "gc_interface/collectedHeap.inline.hpp" #include "interpreter/interpreter.hpp" #include "memory/cardTableModRefBS.hpp" #include "memory/resourceArea.hpp" #include "memory/universe.hpp" #include "prims/methodHandles.hpp" #include "runtime/biasedLocking.hpp" #include "runtime/interfaceSupport.hpp" #include "runtime/objectMonitor.hpp" #include "runtime/os.hpp" #include "runtime/sharedRuntime.hpp" #include "runtime/stubRoutines.hpp" #include "utilities/macros.hpp" #if INCLUDE_ALL_GCS #include "gc_implementation/g1/g1CollectedHeap.inline.hpp" #include "gc_implementation/g1/g1SATBCardTableModRefBS.hpp" #include "gc_implementation/g1/heapRegion.hpp" #endif // INCLUDE_ALL_GCS #ifdef PRODUCT #define BLOCK_COMMENT(str) /* nothing */ #define STOP(error) stop(error) #else #define BLOCK_COMMENT(str) block_comment(str) #define STOP(error) block_comment(error); stop(error) #endif #define BIND(label) bind(label); BLOCK_COMMENT(#label ":") #ifdef ASSERT bool AbstractAssembler::pd_check_instruction_mark() { return true; } #endif static Assembler::Condition reverse[] = { Assembler::noOverflow /* overflow = 0x0 */ , Assembler::overflow /* noOverflow = 0x1 */ , Assembler::aboveEqual /* carrySet = 0x2, below = 0x2 */ , Assembler::below /* aboveEqual = 0x3, carryClear = 0x3 */ , Assembler::notZero /* zero = 0x4, equal = 0x4 */ , Assembler::zero /* notZero = 0x5, notEqual = 0x5 */ , Assembler::above /* belowEqual = 0x6 */ , Assembler::belowEqual /* above = 0x7 */ , Assembler::positive /* negative = 0x8 */ , Assembler::negative /* positive = 0x9 */ , Assembler::noParity /* parity = 0xa */ , Assembler::parity /* noParity = 0xb */ , Assembler::greaterEqual /* less = 0xc */ , Assembler::less /* greaterEqual = 0xd */ , Assembler::greater /* lessEqual = 0xe */ , Assembler::lessEqual /* greater = 0xf, */ }; // Implementation of MacroAssembler // First all the versions that have distinct versions depending on 32/64 bit // Unless the difference is trivial (1 line or so). #ifndef _LP64 // 32bit versions Address MacroAssembler::as_Address(AddressLiteral adr) { return Address(adr.target(), adr.rspec()); } Address MacroAssembler::as_Address(ArrayAddress adr) { return Address::make_array(adr); } int MacroAssembler::biased_locking_enter(Register lock_reg, Register obj_reg, Register swap_reg, Register tmp_reg, bool swap_reg_contains_mark, Label& done, Label* slow_case, BiasedLockingCounters* counters) { assert(UseBiasedLocking, "why call this otherwise?"); assert(swap_reg == rax, "swap_reg must be rax, for cmpxchg"); assert_different_registers(lock_reg, obj_reg, swap_reg); if (PrintBiasedLockingStatistics && counters == NULL) counters = BiasedLocking::counters(); bool need_tmp_reg = false; if (tmp_reg == noreg) { need_tmp_reg = true; tmp_reg = lock_reg; } else { assert_different_registers(lock_reg, obj_reg, swap_reg, tmp_reg); } assert(markOopDesc::age_shift == markOopDesc::lock_bits + markOopDesc::biased_lock_bits, "biased locking makes assumptions about bit layout"); Address mark_addr (obj_reg, oopDesc::mark_offset_in_bytes()); Address klass_addr (obj_reg, oopDesc::klass_offset_in_bytes()); Address saved_mark_addr(lock_reg, 0); // Biased locking // See whether the lock is currently biased toward our thread and // whether the epoch is still valid // Note that the runtime guarantees sufficient alignment of JavaThread // pointers to allow age to be placed into low bits // First check to see whether biasing is even enabled for this object Label cas_label; int null_check_offset = -1; if (!swap_reg_contains_mark) { null_check_offset = offset(); movl(swap_reg, mark_addr); } if (need_tmp_reg) { push(tmp_reg); } movl(tmp_reg, swap_reg); andl(tmp_reg, markOopDesc::biased_lock_mask_in_place); cmpl(tmp_reg, markOopDesc::biased_lock_pattern); if (need_tmp_reg) { pop(tmp_reg); } jcc(Assembler::notEqual, cas_label); // The bias pattern is present in the object's header. Need to check // whether the bias owner and the epoch are both still current. // Note that because there is no current thread register on x86 we // need to store off the mark word we read out of the object to // avoid reloading it and needing to recheck invariants below. This // store is unfortunate but it makes the overall code shorter and // simpler. movl(saved_mark_addr, swap_reg); if (need_tmp_reg) { push(tmp_reg); } get_thread(tmp_reg); xorl(swap_reg, tmp_reg); if (swap_reg_contains_mark) { null_check_offset = offset(); } movl(tmp_reg, klass_addr); xorl(swap_reg, Address(tmp_reg, Klass::prototype_header_offset())); andl(swap_reg, ~((int) markOopDesc::age_mask_in_place)); if (need_tmp_reg) { pop(tmp_reg); } if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address)counters->biased_lock_entry_count_addr())); } jcc(Assembler::equal, done); Label try_revoke_bias; Label try_rebias; // At this point we know that the header has the bias pattern and // that we are not the bias owner in the current epoch. We need to // figure out more details about the state of the header in order to // know what operations can be legally performed on the object's // header. // If the low three bits in the xor result aren't clear, that means // the prototype header is no longer biased and we have to revoke // the bias on this object. testl(swap_reg, markOopDesc::biased_lock_mask_in_place); jcc(Assembler::notZero, try_revoke_bias); // Biasing is still enabled for this data type. See whether the // epoch of the current bias is still valid, meaning that the epoch // bits of the mark word are equal to the epoch bits of the // prototype header. (Note that the prototype header's epoch bits // only change at a safepoint.) If not, attempt to rebias the object // toward the current thread. Note that we must be absolutely sure // that the current epoch is invalid in order to do this because // otherwise the manipulations it performs on the mark word are // illegal. testl(swap_reg, markOopDesc::epoch_mask_in_place); jcc(Assembler::notZero, try_rebias); // The epoch of the current bias is still valid but we know nothing // about the owner; it might be set or it might be clear. Try to // acquire the bias of the object using an atomic operation. If this // fails we will go in to the runtime to revoke the object's bias. // Note that we first construct the presumed unbiased header so we // don't accidentally blow away another thread's valid bias. movl(swap_reg, saved_mark_addr); andl(swap_reg, markOopDesc::biased_lock_mask_in_place | markOopDesc::age_mask_in_place | markOopDesc::epoch_mask_in_place); if (need_tmp_reg) { push(tmp_reg); } get_thread(tmp_reg); orl(tmp_reg, swap_reg); if (os::is_MP()) { lock(); } cmpxchgptr(tmp_reg, Address(obj_reg, 0)); if (need_tmp_reg) { pop(tmp_reg); } // If the biasing toward our thread failed, this means that // another thread succeeded in biasing it toward itself and we // need to revoke that bias. The revocation will occur in the // interpreter runtime in the slow case. if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address)counters->anonymously_biased_lock_entry_count_addr())); } if (slow_case != NULL) { jcc(Assembler::notZero, *slow_case); } jmp(done); bind(try_rebias); // At this point we know the epoch has expired, meaning that the // current "bias owner", if any, is actually invalid. Under these // circumstances _only_, we are allowed to use the current header's // value as the comparison value when doing the cas to acquire the // bias in the current epoch. In other words, we allow transfer of // the bias from one thread to another directly in this situation. // // FIXME: due to a lack of registers we currently blow away the age // bits in this situation. Should attempt to preserve them. if (need_tmp_reg) { push(tmp_reg); } get_thread(tmp_reg); movl(swap_reg, klass_addr); orl(tmp_reg, Address(swap_reg, Klass::prototype_header_offset())); movl(swap_reg, saved_mark_addr); if (os::is_MP()) { lock(); } cmpxchgptr(tmp_reg, Address(obj_reg, 0)); if (need_tmp_reg) { pop(tmp_reg); } // If the biasing toward our thread failed, then another thread // succeeded in biasing it toward itself and we need to revoke that // bias. The revocation will occur in the runtime in the slow case. if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address)counters->rebiased_lock_entry_count_addr())); } if (slow_case != NULL) { jcc(Assembler::notZero, *slow_case); } jmp(done); bind(try_revoke_bias); // The prototype mark in the klass doesn't have the bias bit set any // more, indicating that objects of this data type are not supposed // to be biased any more. We are going to try to reset the mark of // this object to the prototype value and fall through to the // CAS-based locking scheme. Note that if our CAS fails, it means // that another thread raced us for the privilege of revoking the // bias of this particular object, so it's okay to continue in the // normal locking code. // // FIXME: due to a lack of registers we currently blow away the age // bits in this situation. Should attempt to preserve them. movl(swap_reg, saved_mark_addr); if (need_tmp_reg) { push(tmp_reg); } movl(tmp_reg, klass_addr); movl(tmp_reg, Address(tmp_reg, Klass::prototype_header_offset())); if (os::is_MP()) { lock(); } cmpxchgptr(tmp_reg, Address(obj_reg, 0)); if (need_tmp_reg) { pop(tmp_reg); } // Fall through to the normal CAS-based lock, because no matter what // the result of the above CAS, some thread must have succeeded in // removing the bias bit from the object's header. if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address)counters->revoked_lock_entry_count_addr())); } bind(cas_label); return null_check_offset; } void MacroAssembler::call_VM_leaf_base(address entry_point, int number_of_arguments) { call(RuntimeAddress(entry_point)); increment(rsp, number_of_arguments * wordSize); } void MacroAssembler::cmpklass(Address src1, Metadata* obj) { cmp_literal32(src1, (int32_t)obj, metadata_Relocation::spec_for_immediate()); } void MacroAssembler::cmpklass(Register src1, Metadata* obj) { cmp_literal32(src1, (int32_t)obj, metadata_Relocation::spec_for_immediate()); } void MacroAssembler::cmpoop(Address src1, jobject obj) { cmp_literal32(src1, (int32_t)obj, oop_Relocation::spec_for_immediate()); } void MacroAssembler::cmpoop(Register src1, jobject obj) { cmp_literal32(src1, (int32_t)obj, oop_Relocation::spec_for_immediate()); } void MacroAssembler::extend_sign(Register hi, Register lo) { // According to Intel Doc. AP-526, "Integer Divide", p.18. if (VM_Version::is_P6() && hi == rdx && lo == rax) { cdql(); } else { movl(hi, lo); sarl(hi, 31); } } void MacroAssembler::jC2(Register tmp, Label& L) { // set parity bit if FPU flag C2 is set (via rax) save_rax(tmp); fwait(); fnstsw_ax(); sahf(); restore_rax(tmp); // branch jcc(Assembler::parity, L); } void MacroAssembler::jnC2(Register tmp, Label& L) { // set parity bit if FPU flag C2 is set (via rax) save_rax(tmp); fwait(); fnstsw_ax(); sahf(); restore_rax(tmp); // branch jcc(Assembler::noParity, L); } // 32bit can do a case table jump in one instruction but we no longer allow the base // to be installed in the Address class void MacroAssembler::jump(ArrayAddress entry) { jmp(as_Address(entry)); } // Note: y_lo will be destroyed void MacroAssembler::lcmp2int(Register x_hi, Register x_lo, Register y_hi, Register y_lo) { // Long compare for Java (semantics as described in JVM spec.) Label high, low, done; cmpl(x_hi, y_hi); jcc(Assembler::less, low); jcc(Assembler::greater, high); // x_hi is the return register xorl(x_hi, x_hi); cmpl(x_lo, y_lo); jcc(Assembler::below, low); jcc(Assembler::equal, done); bind(high); xorl(x_hi, x_hi); increment(x_hi); jmp(done); bind(low); xorl(x_hi, x_hi); decrementl(x_hi); bind(done); } void MacroAssembler::lea(Register dst, AddressLiteral src) { mov_literal32(dst, (int32_t)src.target(), src.rspec()); } void MacroAssembler::lea(Address dst, AddressLiteral adr) { // leal(dst, as_Address(adr)); // see note in movl as to why we must use a move mov_literal32(dst, (int32_t) adr.target(), adr.rspec()); } void MacroAssembler::leave() { mov(rsp, rbp); pop(rbp); } void MacroAssembler::lmul(int x_rsp_offset, int y_rsp_offset) { // Multiplication of two Java long values stored on the stack // as illustrated below. Result is in rdx:rax. // // rsp ---> [ ?? ] \ \ // .... | y_rsp_offset | // [ y_lo ] / (in bytes) | x_rsp_offset // [ y_hi ] | (in bytes) // .... | // [ x_lo ] / // [ x_hi ] // .... // // Basic idea: lo(result) = lo(x_lo * y_lo) // hi(result) = hi(x_lo * y_lo) + lo(x_hi * y_lo) + lo(x_lo * y_hi) Address x_hi(rsp, x_rsp_offset + wordSize); Address x_lo(rsp, x_rsp_offset); Address y_hi(rsp, y_rsp_offset + wordSize); Address y_lo(rsp, y_rsp_offset); Label quick; // load x_hi, y_hi and check if quick // multiplication is possible movl(rbx, x_hi); movl(rcx, y_hi); movl(rax, rbx); orl(rbx, rcx); // rbx, = 0 <=> x_hi = 0 and y_hi = 0 jcc(Assembler::zero, quick); // if rbx, = 0 do quick multiply // do full multiplication // 1st step mull(y_lo); // x_hi * y_lo movl(rbx, rax); // save lo(x_hi * y_lo) in rbx, // 2nd step movl(rax, x_lo); mull(rcx); // x_lo * y_hi addl(rbx, rax); // add lo(x_lo * y_hi) to rbx, // 3rd step bind(quick); // note: rbx, = 0 if quick multiply! movl(rax, x_lo); mull(y_lo); // x_lo * y_lo addl(rdx, rbx); // correct hi(x_lo * y_lo) } void MacroAssembler::lneg(Register hi, Register lo) { negl(lo); adcl(hi, 0); negl(hi); } void MacroAssembler::lshl(Register hi, Register lo) { // Java shift left long support (semantics as described in JVM spec., p.305) // (basic idea for shift counts s >= n: x << s == (x << n) << (s - n)) // shift value is in rcx ! assert(hi != rcx, "must not use rcx"); assert(lo != rcx, "must not use rcx"); const Register s = rcx; // shift count const int n = BitsPerWord; Label L; andl(s, 0x3f); // s := s & 0x3f (s < 0x40) cmpl(s, n); // if (s < n) jcc(Assembler::less, L); // else (s >= n) movl(hi, lo); // x := x << n xorl(lo, lo); // Note: subl(s, n) is not needed since the Intel shift instructions work rcx mod n! bind(L); // s (mod n) < n shldl(hi, lo); // x := x << s shll(lo); } void MacroAssembler::lshr(Register hi, Register lo, bool sign_extension) { // Java shift right long support (semantics as described in JVM spec., p.306 & p.310) // (basic idea for shift counts s >= n: x >> s == (x >> n) >> (s - n)) assert(hi != rcx, "must not use rcx"); assert(lo != rcx, "must not use rcx"); const Register s = rcx; // shift count const int n = BitsPerWord; Label L; andl(s, 0x3f); // s := s & 0x3f (s < 0x40) cmpl(s, n); // if (s < n) jcc(Assembler::less, L); // else (s >= n) movl(lo, hi); // x := x >> n if (sign_extension) sarl(hi, 31); else xorl(hi, hi); // Note: subl(s, n) is not needed since the Intel shift instructions work rcx mod n! bind(L); // s (mod n) < n shrdl(lo, hi); // x := x >> s if (sign_extension) sarl(hi); else shrl(hi); } void MacroAssembler::movoop(Register dst, jobject obj) { mov_literal32(dst, (int32_t)obj, oop_Relocation::spec_for_immediate()); } void MacroAssembler::movoop(Address dst, jobject obj) { mov_literal32(dst, (int32_t)obj, oop_Relocation::spec_for_immediate()); } void MacroAssembler::mov_metadata(Register dst, Metadata* obj) { mov_literal32(dst, (int32_t)obj, metadata_Relocation::spec_for_immediate()); } void MacroAssembler::mov_metadata(Address dst, Metadata* obj) { mov_literal32(dst, (int32_t)obj, metadata_Relocation::spec_for_immediate()); } void MacroAssembler::movptr(Register dst, AddressLiteral src) { if (src.is_lval()) { mov_literal32(dst, (intptr_t)src.target(), src.rspec()); } else { movl(dst, as_Address(src)); } } void MacroAssembler::movptr(ArrayAddress dst, Register src) { movl(as_Address(dst), src); } void MacroAssembler::movptr(Register dst, ArrayAddress src) { movl(dst, as_Address(src)); } // src should NEVER be a real pointer. Use AddressLiteral for true pointers void MacroAssembler::movptr(Address dst, intptr_t src) { movl(dst, src); } void MacroAssembler::pop_callee_saved_registers() { pop(rcx); pop(rdx); pop(rdi); pop(rsi); } void MacroAssembler::pop_fTOS() { fld_d(Address(rsp, 0)); addl(rsp, 2 * wordSize); } void MacroAssembler::push_callee_saved_registers() { push(rsi); push(rdi); push(rdx); push(rcx); } void MacroAssembler::push_fTOS() { subl(rsp, 2 * wordSize); fstp_d(Address(rsp, 0)); } void MacroAssembler::pushoop(jobject obj) { push_literal32((int32_t)obj, oop_Relocation::spec_for_immediate()); } void MacroAssembler::pushklass(Metadata* obj) { push_literal32((int32_t)obj, metadata_Relocation::spec_for_immediate()); } void MacroAssembler::pushptr(AddressLiteral src) { if (src.is_lval()) { push_literal32((int32_t)src.target(), src.rspec()); } else { pushl(as_Address(src)); } } void MacroAssembler::set_word_if_not_zero(Register dst) { xorl(dst, dst); set_byte_if_not_zero(dst); } static void pass_arg0(MacroAssembler* masm, Register arg) { masm->push(arg); } static void pass_arg1(MacroAssembler* masm, Register arg) { masm->push(arg); } static void pass_arg2(MacroAssembler* masm, Register arg) { masm->push(arg); } static void pass_arg3(MacroAssembler* masm, Register arg) { masm->push(arg); } #ifndef PRODUCT extern "C" void findpc(intptr_t x); #endif void MacroAssembler::debug32(int rdi, int rsi, int rbp, int rsp, int rbx, int rdx, int rcx, int rax, int eip, char* msg) { // In order to get locks to work, we need to fake a in_VM state JavaThread* thread = JavaThread::current(); JavaThreadState saved_state = thread->thread_state(); thread->set_thread_state(_thread_in_vm); if (ShowMessageBoxOnError) { JavaThread* thread = JavaThread::current(); JavaThreadState saved_state = thread->thread_state(); thread->set_thread_state(_thread_in_vm); if (CountBytecodes || TraceBytecodes || StopInterpreterAt) { ttyLocker ttyl; BytecodeCounter::print(); } // To see where a verify_oop failed, get $ebx+40/X for this frame. // This is the value of eip which points to where verify_oop will return. if (os::message_box(msg, "Execution stopped, print registers?")) { print_state32(rdi, rsi, rbp, rsp, rbx, rdx, rcx, rax, eip); BREAKPOINT; } } else { ttyLocker ttyl; ::tty->print_cr("=============== DEBUG MESSAGE: %s ================\n", msg); } // Don't assert holding the ttyLock assert(false, err_msg("DEBUG MESSAGE: %s", msg)); ThreadStateTransition::transition(thread, _thread_in_vm, saved_state); } void MacroAssembler::print_state32(int rdi, int rsi, int rbp, int rsp, int rbx, int rdx, int rcx, int rax, int eip) { ttyLocker ttyl; FlagSetting fs(Debugging, true); tty->print_cr("eip = 0x%08x", eip); #ifndef PRODUCT if ((WizardMode || Verbose) && PrintMiscellaneous) { tty->cr(); findpc(eip); tty->cr(); } #endif #define PRINT_REG(rax) \ { tty->print("%s = ", #rax); os::print_location(tty, rax); } PRINT_REG(rax); PRINT_REG(rbx); PRINT_REG(rcx); PRINT_REG(rdx); PRINT_REG(rdi); PRINT_REG(rsi); PRINT_REG(rbp); PRINT_REG(rsp); #undef PRINT_REG // Print some words near top of staack. int* dump_sp = (int*) rsp; for (int col1 = 0; col1 < 8; col1++) { tty->print("(rsp+0x%03x) 0x%08x: ", (int)((intptr_t)dump_sp - (intptr_t)rsp), (intptr_t)dump_sp); os::print_location(tty, *dump_sp++); } for (int row = 0; row < 16; row++) { tty->print("(rsp+0x%03x) 0x%08x: ", (int)((intptr_t)dump_sp - (intptr_t)rsp), (intptr_t)dump_sp); for (int col = 0; col < 8; col++) { tty->print(" 0x%08x", *dump_sp++); } tty->cr(); } // Print some instructions around pc: Disassembler::decode((address)eip-64, (address)eip); tty->print_cr("--------"); Disassembler::decode((address)eip, (address)eip+32); } void MacroAssembler::stop(const char* msg) { ExternalAddress message((address)msg); // push address of message pushptr(message.addr()); { Label L; call(L, relocInfo::none); bind(L); } // push eip pusha(); // push registers call(RuntimeAddress(CAST_FROM_FN_PTR(address, MacroAssembler::debug32))); hlt(); } void MacroAssembler::warn(const char* msg) { push_CPU_state(); ExternalAddress message((address) msg); // push address of message pushptr(message.addr()); call(RuntimeAddress(CAST_FROM_FN_PTR(address, warning))); addl(rsp, wordSize); // discard argument pop_CPU_state(); } void MacroAssembler::print_state() { { Label L; call(L, relocInfo::none); bind(L); } // push eip pusha(); // push registers push_CPU_state(); call(RuntimeAddress(CAST_FROM_FN_PTR(address, MacroAssembler::print_state32))); pop_CPU_state(); popa(); addl(rsp, wordSize); } #else // _LP64 // 64 bit versions Address MacroAssembler::as_Address(AddressLiteral adr) { // amd64 always does this as a pc-rel // we can be absolute or disp based on the instruction type // jmp/call are displacements others are absolute assert(!adr.is_lval(), "must be rval"); assert(reachable(adr), "must be"); return Address((int32_t)(intptr_t)(adr.target() - pc()), adr.target(), adr.reloc()); } Address MacroAssembler::as_Address(ArrayAddress adr) { AddressLiteral base = adr.base(); lea(rscratch1, base); Address index = adr.index(); assert(index._disp == 0, "must not have disp"); // maybe it can? Address array(rscratch1, index._index, index._scale, index._disp); return array; } int MacroAssembler::biased_locking_enter(Register lock_reg, Register obj_reg, Register swap_reg, Register tmp_reg, bool swap_reg_contains_mark, Label& done, Label* slow_case, BiasedLockingCounters* counters) { assert(UseBiasedLocking, "why call this otherwise?"); assert(swap_reg == rax, "swap_reg must be rax for cmpxchgq"); assert(tmp_reg != noreg, "tmp_reg must be supplied"); assert_different_registers(lock_reg, obj_reg, swap_reg, tmp_reg); assert(markOopDesc::age_shift == markOopDesc::lock_bits + markOopDesc::biased_lock_bits, "biased locking makes assumptions about bit layout"); Address mark_addr (obj_reg, oopDesc::mark_offset_in_bytes()); Address saved_mark_addr(lock_reg, 0); if (PrintBiasedLockingStatistics && counters == NULL) counters = BiasedLocking::counters(); // Biased locking // See whether the lock is currently biased toward our thread and // whether the epoch is still valid // Note that the runtime guarantees sufficient alignment of JavaThread // pointers to allow age to be placed into low bits // First check to see whether biasing is even enabled for this object Label cas_label; int null_check_offset = -1; if (!swap_reg_contains_mark) { null_check_offset = offset(); movq(swap_reg, mark_addr); } movq(tmp_reg, swap_reg); andq(tmp_reg, markOopDesc::biased_lock_mask_in_place); cmpq(tmp_reg, markOopDesc::biased_lock_pattern); jcc(Assembler::notEqual, cas_label); // The bias pattern is present in the object's header. Need to check // whether the bias owner and the epoch are both still current. load_prototype_header(tmp_reg, obj_reg); orq(tmp_reg, r15_thread); xorq(tmp_reg, swap_reg); andq(tmp_reg, ~((int) markOopDesc::age_mask_in_place)); if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address) counters->anonymously_biased_lock_entry_count_addr())); } jcc(Assembler::equal, done); Label try_revoke_bias; Label try_rebias; // At this point we know that the header has the bias pattern and // that we are not the bias owner in the current epoch. We need to // figure out more details about the state of the header in order to // know what operations can be legally performed on the object's // header. // If the low three bits in the xor result aren't clear, that means // the prototype header is no longer biased and we have to revoke // the bias on this object. testq(tmp_reg, markOopDesc::biased_lock_mask_in_place); jcc(Assembler::notZero, try_revoke_bias); // Biasing is still enabled for this data type. See whether the // epoch of the current bias is still valid, meaning that the epoch // bits of the mark word are equal to the epoch bits of the // prototype header. (Note that the prototype header's epoch bits // only change at a safepoint.) If not, attempt to rebias the object // toward the current thread. Note that we must be absolutely sure // that the current epoch is invalid in order to do this because // otherwise the manipulations it performs on the mark word are // illegal. testq(tmp_reg, markOopDesc::epoch_mask_in_place); jcc(Assembler::notZero, try_rebias); // The epoch of the current bias is still valid but we know nothing // about the owner; it might be set or it might be clear. Try to // acquire the bias of the object using an atomic operation. If this // fails we will go in to the runtime to revoke the object's bias. // Note that we first construct the presumed unbiased header so we // don't accidentally blow away another thread's valid bias. andq(swap_reg, markOopDesc::biased_lock_mask_in_place | markOopDesc::age_mask_in_place | markOopDesc::epoch_mask_in_place); movq(tmp_reg, swap_reg); orq(tmp_reg, r15_thread); if (os::is_MP()) { lock(); } cmpxchgq(tmp_reg, Address(obj_reg, 0)); // If the biasing toward our thread failed, this means that // another thread succeeded in biasing it toward itself and we // need to revoke that bias. The revocation will occur in the // interpreter runtime in the slow case. if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address) counters->anonymously_biased_lock_entry_count_addr())); } if (slow_case != NULL) { jcc(Assembler::notZero, *slow_case); } jmp(done); bind(try_rebias); // At this point we know the epoch has expired, meaning that the // current "bias owner", if any, is actually invalid. Under these // circumstances _only_, we are allowed to use the current header's // value as the comparison value when doing the cas to acquire the // bias in the current epoch. In other words, we allow transfer of // the bias from one thread to another directly in this situation. // // FIXME: due to a lack of registers we currently blow away the age // bits in this situation. Should attempt to preserve them. load_prototype_header(tmp_reg, obj_reg); orq(tmp_reg, r15_thread); if (os::is_MP()) { lock(); } cmpxchgq(tmp_reg, Address(obj_reg, 0)); // If the biasing toward our thread failed, then another thread // succeeded in biasing it toward itself and we need to revoke that // bias. The revocation will occur in the runtime in the slow case. if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address) counters->rebiased_lock_entry_count_addr())); } if (slow_case != NULL) { jcc(Assembler::notZero, *slow_case); } jmp(done); bind(try_revoke_bias); // The prototype mark in the klass doesn't have the bias bit set any // more, indicating that objects of this data type are not supposed // to be biased any more. We are going to try to reset the mark of // this object to the prototype value and fall through to the // CAS-based locking scheme. Note that if our CAS fails, it means // that another thread raced us for the privilege of revoking the // bias of this particular object, so it's okay to continue in the // normal locking code. // // FIXME: due to a lack of registers we currently blow away the age // bits in this situation. Should attempt to preserve them. load_prototype_header(tmp_reg, obj_reg); if (os::is_MP()) { lock(); } cmpxchgq(tmp_reg, Address(obj_reg, 0)); // Fall through to the normal CAS-based lock, because no matter what // the result of the above CAS, some thread must have succeeded in // removing the bias bit from the object's header. if (counters != NULL) { cond_inc32(Assembler::zero, ExternalAddress((address) counters->revoked_lock_entry_count_addr())); } bind(cas_label); return null_check_offset; } void MacroAssembler::call_VM_leaf_base(address entry_point, int num_args) { Label L, E; #ifdef _WIN64 // Windows always allocates space for it's register args assert(num_args <= 4, "only register arguments supported"); subq(rsp, frame::arg_reg_save_area_bytes); #endif // Align stack if necessary testl(rsp, 15); jcc(Assembler::zero, L); subq(rsp, 8); { call(RuntimeAddress(entry_point)); } addq(rsp, 8); jmp(E); bind(L); { call(RuntimeAddress(entry_point)); } bind(E); #ifdef _WIN64 // restore stack pointer addq(rsp, frame::arg_reg_save_area_bytes); #endif } void MacroAssembler::cmp64(Register src1, AddressLiteral src2) { assert(!src2.is_lval(), "should use cmpptr"); if (reachable(src2)) { cmpq(src1, as_Address(src2)); } else { lea(rscratch1, src2); Assembler::cmpq(src1, Address(rscratch1, 0)); } } int MacroAssembler::corrected_idivq(Register reg) { // Full implementation of Java ldiv and lrem; checks for special // case as described in JVM spec., p.243 & p.271. The function // returns the (pc) offset of the idivl instruction - may be needed // for implicit exceptions. // // normal case special case // // input : rax: dividend min_long // reg: divisor (may not be eax/edx) -1 // // output: rax: quotient (= rax idiv reg) min_long // rdx: remainder (= rax irem reg) 0 assert(reg != rax && reg != rdx, "reg cannot be rax or rdx register"); static const int64_t min_long = 0x8000000000000000; Label normal_case, special_case; // check for special case cmp64(rax, ExternalAddress((address) &min_long)); jcc(Assembler::notEqual, normal_case); xorl(rdx, rdx); // prepare rdx for possible special case (where // remainder = 0) cmpq(reg, -1); jcc(Assembler::equal, special_case); // handle normal case bind(normal_case); cdqq(); int idivq_offset = offset(); idivq(reg); // normal and special case exit bind(special_case); return idivq_offset; } void MacroAssembler::decrementq(Register reg, int value) { if (value == min_jint) { subq(reg, value); return; } if (value < 0) { incrementq(reg, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { decq(reg) ; return; } /* else */ { subq(reg, value) ; return; } } void MacroAssembler::decrementq(Address dst, int value) { if (value == min_jint) { subq(dst, value); return; } if (value < 0) { incrementq(dst, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { decq(dst) ; return; } /* else */ { subq(dst, value) ; return; } } void MacroAssembler::incrementq(Register reg, int value) { if (value == min_jint) { addq(reg, value); return; } if (value < 0) { decrementq(reg, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { incq(reg) ; return; } /* else */ { addq(reg, value) ; return; } } void MacroAssembler::incrementq(Address dst, int value) { if (value == min_jint) { addq(dst, value); return; } if (value < 0) { decrementq(dst, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { incq(dst) ; return; } /* else */ { addq(dst, value) ; return; } } // 32bit can do a case table jump in one instruction but we no longer allow the base // to be installed in the Address class void MacroAssembler::jump(ArrayAddress entry) { lea(rscratch1, entry.base()); Address dispatch = entry.index(); assert(dispatch._base == noreg, "must be"); dispatch._base = rscratch1; jmp(dispatch); } void MacroAssembler::lcmp2int(Register x_hi, Register x_lo, Register y_hi, Register y_lo) { ShouldNotReachHere(); // 64bit doesn't use two regs cmpq(x_lo, y_lo); } void MacroAssembler::lea(Register dst, AddressLiteral src) { mov_literal64(dst, (intptr_t)src.target(), src.rspec()); } void MacroAssembler::lea(Address dst, AddressLiteral adr) { mov_literal64(rscratch1, (intptr_t)adr.target(), adr.rspec()); movptr(dst, rscratch1); } void MacroAssembler::leave() { // %%% is this really better? Why not on 32bit too? emit_int8((unsigned char)0xC9); // LEAVE } void MacroAssembler::lneg(Register hi, Register lo) { ShouldNotReachHere(); // 64bit doesn't use two regs negq(lo); } void MacroAssembler::movoop(Register dst, jobject obj) { mov_literal64(dst, (intptr_t)obj, oop_Relocation::spec_for_immediate()); } void MacroAssembler::movoop(Address dst, jobject obj) { mov_literal64(rscratch1, (intptr_t)obj, oop_Relocation::spec_for_immediate()); movq(dst, rscratch1); } void MacroAssembler::mov_metadata(Register dst, Metadata* obj) { mov_literal64(dst, (intptr_t)obj, metadata_Relocation::spec_for_immediate()); } void MacroAssembler::mov_metadata(Address dst, Metadata* obj) { mov_literal64(rscratch1, (intptr_t)obj, metadata_Relocation::spec_for_immediate()); movq(dst, rscratch1); } void MacroAssembler::movptr(Register dst, AddressLiteral src) { if (src.is_lval()) { mov_literal64(dst, (intptr_t)src.target(), src.rspec()); } else { if (reachable(src)) { movq(dst, as_Address(src)); } else { lea(rscratch1, src); movq(dst, Address(rscratch1,0)); } } } void MacroAssembler::movptr(ArrayAddress dst, Register src) { movq(as_Address(dst), src); } void MacroAssembler::movptr(Register dst, ArrayAddress src) { movq(dst, as_Address(src)); } // src should NEVER be a real pointer. Use AddressLiteral for true pointers void MacroAssembler::movptr(Address dst, intptr_t src) { mov64(rscratch1, src); movq(dst, rscratch1); } // These are mostly for initializing NULL void MacroAssembler::movptr(Address dst, int32_t src) { movslq(dst, src); } void MacroAssembler::movptr(Register dst, int32_t src) { mov64(dst, (intptr_t)src); } void MacroAssembler::pushoop(jobject obj) { movoop(rscratch1, obj); push(rscratch1); } void MacroAssembler::pushklass(Metadata* obj) { mov_metadata(rscratch1, obj); push(rscratch1); } void MacroAssembler::pushptr(AddressLiteral src) { lea(rscratch1, src); if (src.is_lval()) { push(rscratch1); } else { pushq(Address(rscratch1, 0)); } } void MacroAssembler::reset_last_Java_frame(bool clear_fp, bool clear_pc) { // we must set sp to zero to clear frame movptr(Address(r15_thread, JavaThread::last_Java_sp_offset()), NULL_WORD); // must clear fp, so that compiled frames are not confused; it is // possible that we need it only for debugging if (clear_fp) { movptr(Address(r15_thread, JavaThread::last_Java_fp_offset()), NULL_WORD); } if (clear_pc) { movptr(Address(r15_thread, JavaThread::last_Java_pc_offset()), NULL_WORD); } } void MacroAssembler::set_last_Java_frame(Register last_java_sp, Register last_java_fp, address last_java_pc) { // determine last_java_sp register if (!last_java_sp->is_valid()) { last_java_sp = rsp; } // last_java_fp is optional if (last_java_fp->is_valid()) { movptr(Address(r15_thread, JavaThread::last_Java_fp_offset()), last_java_fp); } // last_java_pc is optional if (last_java_pc != NULL) { Address java_pc(r15_thread, JavaThread::frame_anchor_offset() + JavaFrameAnchor::last_Java_pc_offset()); lea(rscratch1, InternalAddress(last_java_pc)); movptr(java_pc, rscratch1); } movptr(Address(r15_thread, JavaThread::last_Java_sp_offset()), last_java_sp); } static void pass_arg0(MacroAssembler* masm, Register arg) { if (c_rarg0 != arg ) { masm->mov(c_rarg0, arg); } } static void pass_arg1(MacroAssembler* masm, Register arg) { if (c_rarg1 != arg ) { masm->mov(c_rarg1, arg); } } static void pass_arg2(MacroAssembler* masm, Register arg) { if (c_rarg2 != arg ) { masm->mov(c_rarg2, arg); } } static void pass_arg3(MacroAssembler* masm, Register arg) { if (c_rarg3 != arg ) { masm->mov(c_rarg3, arg); } } void MacroAssembler::stop(const char* msg) { address rip = pc(); pusha(); // get regs on stack lea(c_rarg0, ExternalAddress((address) msg)); lea(c_rarg1, InternalAddress(rip)); movq(c_rarg2, rsp); // pass pointer to regs array andq(rsp, -16); // align stack as required by ABI call(RuntimeAddress(CAST_FROM_FN_PTR(address, MacroAssembler::debug64))); hlt(); } void MacroAssembler::warn(const char* msg) { push(rbp); movq(rbp, rsp); andq(rsp, -16); // align stack as required by push_CPU_state and call push_CPU_state(); // keeps alignment at 16 bytes lea(c_rarg0, ExternalAddress((address) msg)); call_VM_leaf(CAST_FROM_FN_PTR(address, warning), c_rarg0); pop_CPU_state(); mov(rsp, rbp); pop(rbp); } void MacroAssembler::print_state() { address rip = pc(); pusha(); // get regs on stack push(rbp); movq(rbp, rsp); andq(rsp, -16); // align stack as required by push_CPU_state and call push_CPU_state(); // keeps alignment at 16 bytes lea(c_rarg0, InternalAddress(rip)); lea(c_rarg1, Address(rbp, wordSize)); // pass pointer to regs array call_VM_leaf(CAST_FROM_FN_PTR(address, MacroAssembler::print_state64), c_rarg0, c_rarg1); pop_CPU_state(); mov(rsp, rbp); pop(rbp); popa(); } #ifndef PRODUCT extern "C" void findpc(intptr_t x); #endif void MacroAssembler::debug64(char* msg, int64_t pc, int64_t regs[]) { // In order to get locks to work, we need to fake a in_VM state if (ShowMessageBoxOnError) { JavaThread* thread = JavaThread::current(); JavaThreadState saved_state = thread->thread_state(); thread->set_thread_state(_thread_in_vm); #ifndef PRODUCT if (CountBytecodes || TraceBytecodes || StopInterpreterAt) { ttyLocker ttyl; BytecodeCounter::print(); } #endif // To see where a verify_oop failed, get $ebx+40/X for this frame. // XXX correct this offset for amd64 // This is the value of eip which points to where verify_oop will return. if (os::message_box(msg, "Execution stopped, print registers?")) { print_state64(pc, regs); BREAKPOINT; assert(false, "start up GDB"); } ThreadStateTransition::transition(thread, _thread_in_vm, saved_state); } else { ttyLocker ttyl; ::tty->print_cr("=============== DEBUG MESSAGE: %s ================\n", msg); assert(false, err_msg("DEBUG MESSAGE: %s", msg)); } } void MacroAssembler::print_state64(int64_t pc, int64_t regs[]) { ttyLocker ttyl; FlagSetting fs(Debugging, true); tty->print_cr("rip = 0x%016lx", pc); #ifndef PRODUCT tty->cr(); findpc(pc); tty->cr(); #endif #define PRINT_REG(rax, value) \ { tty->print("%s = ", #rax); os::print_location(tty, value); } PRINT_REG(rax, regs[15]); PRINT_REG(rbx, regs[12]); PRINT_REG(rcx, regs[14]); PRINT_REG(rdx, regs[13]); PRINT_REG(rdi, regs[8]); PRINT_REG(rsi, regs[9]); PRINT_REG(rbp, regs[10]); PRINT_REG(rsp, regs[11]); PRINT_REG(r8 , regs[7]); PRINT_REG(r9 , regs[6]); PRINT_REG(r10, regs[5]); PRINT_REG(r11, regs[4]); PRINT_REG(r12, regs[3]); PRINT_REG(r13, regs[2]); PRINT_REG(r14, regs[1]); PRINT_REG(r15, regs[0]); #undef PRINT_REG // Print some words near top of staack. int64_t* rsp = (int64_t*) regs[11]; int64_t* dump_sp = rsp; for (int col1 = 0; col1 < 8; col1++) { tty->print("(rsp+0x%03x) 0x%016lx: ", (int)((intptr_t)dump_sp - (intptr_t)rsp), (int64_t)dump_sp); os::print_location(tty, *dump_sp++); } for (int row = 0; row < 25; row++) { tty->print("(rsp+0x%03x) 0x%016lx: ", (int)((intptr_t)dump_sp - (intptr_t)rsp), (int64_t)dump_sp); for (int col = 0; col < 4; col++) { tty->print(" 0x%016lx", *dump_sp++); } tty->cr(); } // Print some instructions around pc: Disassembler::decode((address)pc-64, (address)pc); tty->print_cr("--------"); Disassembler::decode((address)pc, (address)pc+32); } #endif // _LP64 // Now versions that are common to 32/64 bit void MacroAssembler::addptr(Register dst, int32_t imm32) { LP64_ONLY(addq(dst, imm32)) NOT_LP64(addl(dst, imm32)); } void MacroAssembler::addptr(Register dst, Register src) { LP64_ONLY(addq(dst, src)) NOT_LP64(addl(dst, src)); } void MacroAssembler::addptr(Address dst, Register src) { LP64_ONLY(addq(dst, src)) NOT_LP64(addl(dst, src)); } void MacroAssembler::addsd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::addsd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::addsd(dst, Address(rscratch1, 0)); } } void MacroAssembler::addss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { addss(dst, as_Address(src)); } else { lea(rscratch1, src); addss(dst, Address(rscratch1, 0)); } } void MacroAssembler::align(int modulus) { if (offset() % modulus != 0) { nop(modulus - (offset() % modulus)); } } void MacroAssembler::andpd(XMMRegister dst, AddressLiteral src) { // Used in sign-masking with aligned address. assert((UseAVX > 0) || (((intptr_t)src.target() & 15) == 0), "SSE mode requires address alignment 16 bytes"); if (reachable(src)) { Assembler::andpd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::andpd(dst, Address(rscratch1, 0)); } } void MacroAssembler::andps(XMMRegister dst, AddressLiteral src) { // Used in sign-masking with aligned address. assert((UseAVX > 0) || (((intptr_t)src.target() & 15) == 0), "SSE mode requires address alignment 16 bytes"); if (reachable(src)) { Assembler::andps(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::andps(dst, Address(rscratch1, 0)); } } void MacroAssembler::andptr(Register dst, int32_t imm32) { LP64_ONLY(andq(dst, imm32)) NOT_LP64(andl(dst, imm32)); } void MacroAssembler::atomic_incl(AddressLiteral counter_addr) { pushf(); if (os::is_MP()) lock(); incrementl(counter_addr); popf(); } // Writes to stack successive pages until offset reached to check for // stack overflow + shadow pages. This clobbers tmp. void MacroAssembler::bang_stack_size(Register size, Register tmp) { movptr(tmp, rsp); // Bang stack for total size given plus shadow page size. // Bang one page at a time because large size can bang beyond yellow and // red zones. Label loop; bind(loop); movl(Address(tmp, (-os::vm_page_size())), size ); subptr(tmp, os::vm_page_size()); subl(size, os::vm_page_size()); jcc(Assembler::greater, loop); // Bang down shadow pages too. // At this point, (tmp-0) is the last address touched, so don't // touch it again. (It was touched as (tmp-pagesize) but then tmp // was post-decremented.) Skip this address by starting at i=1, and // touch a few more pages below. N.B. It is important to touch all // the way down to and including i=StackShadowPages. for (int i = 1; i <= StackShadowPages; i++) { // this could be any sized move but this is can be a debugging crumb // so the bigger the better. movptr(Address(tmp, (-i*os::vm_page_size())), size ); } } void MacroAssembler::biased_locking_exit(Register obj_reg, Register temp_reg, Label& done) { assert(UseBiasedLocking, "why call this otherwise?"); // Check for biased locking unlock case, which is a no-op // Note: we do not have to check the thread ID for two reasons. // First, the interpreter checks for IllegalMonitorStateException at // a higher level. Second, if the bias was revoked while we held the // lock, the object could not be rebiased toward another thread, so // the bias bit would be clear. movptr(temp_reg, Address(obj_reg, oopDesc::mark_offset_in_bytes())); andptr(temp_reg, markOopDesc::biased_lock_mask_in_place); cmpptr(temp_reg, markOopDesc::biased_lock_pattern); jcc(Assembler::equal, done); } void MacroAssembler::c2bool(Register x) { // implements x == 0 ? 0 : 1 // note: must only look at least-significant byte of x // since C-style booleans are stored in one byte // only! (was bug) andl(x, 0xFF); setb(Assembler::notZero, x); } // Wouldn't need if AddressLiteral version had new name void MacroAssembler::call(Label& L, relocInfo::relocType rtype) { Assembler::call(L, rtype); } void MacroAssembler::call(Register entry) { Assembler::call(entry); } void MacroAssembler::call(AddressLiteral entry) { if (reachable(entry)) { Assembler::call_literal(entry.target(), entry.rspec()); } else { lea(rscratch1, entry); Assembler::call(rscratch1); } } void MacroAssembler::ic_call(address entry) { RelocationHolder rh = virtual_call_Relocation::spec(pc()); movptr(rax, (intptr_t)Universe::non_oop_word()); call(AddressLiteral(entry, rh)); } // Implementation of call_VM versions void MacroAssembler::call_VM(Register oop_result, address entry_point, bool check_exceptions) { Label C, E; call(C, relocInfo::none); jmp(E); bind(C); call_VM_helper(oop_result, entry_point, 0, check_exceptions); ret(0); bind(E); } void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, bool check_exceptions) { Label C, E; call(C, relocInfo::none); jmp(E); bind(C); pass_arg1(this, arg_1); call_VM_helper(oop_result, entry_point, 1, check_exceptions); ret(0); bind(E); } void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, bool check_exceptions) { Label C, E; call(C, relocInfo::none); jmp(E); bind(C); LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); pass_arg1(this, arg_1); call_VM_helper(oop_result, entry_point, 2, check_exceptions); ret(0); bind(E); } void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, Register arg_3, bool check_exceptions) { Label C, E; call(C, relocInfo::none); jmp(E); bind(C); LP64_ONLY(assert(arg_1 != c_rarg3, "smashed arg")); LP64_ONLY(assert(arg_2 != c_rarg3, "smashed arg")); pass_arg3(this, arg_3); LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); pass_arg1(this, arg_1); call_VM_helper(oop_result, entry_point, 3, check_exceptions); ret(0); bind(E); } void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, int number_of_arguments, bool check_exceptions) { Register thread = LP64_ONLY(r15_thread) NOT_LP64(noreg); call_VM_base(oop_result, thread, last_java_sp, entry_point, number_of_arguments, check_exceptions); } void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, bool check_exceptions) { pass_arg1(this, arg_1); call_VM(oop_result, last_java_sp, entry_point, 1, check_exceptions); } void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, bool check_exceptions) { LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); pass_arg1(this, arg_1); call_VM(oop_result, last_java_sp, entry_point, 2, check_exceptions); } void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, Register arg_3, bool check_exceptions) { LP64_ONLY(assert(arg_1 != c_rarg3, "smashed arg")); LP64_ONLY(assert(arg_2 != c_rarg3, "smashed arg")); pass_arg3(this, arg_3); LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); pass_arg1(this, arg_1); call_VM(oop_result, last_java_sp, entry_point, 3, check_exceptions); } void MacroAssembler::super_call_VM(Register oop_result, Register last_java_sp, address entry_point, int number_of_arguments, bool check_exceptions) { Register thread = LP64_ONLY(r15_thread) NOT_LP64(noreg); MacroAssembler::call_VM_base(oop_result, thread, last_java_sp, entry_point, number_of_arguments, check_exceptions); } void MacroAssembler::super_call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, bool check_exceptions) { pass_arg1(this, arg_1); super_call_VM(oop_result, last_java_sp, entry_point, 1, check_exceptions); } void MacroAssembler::super_call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, bool check_exceptions) { LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); pass_arg1(this, arg_1); super_call_VM(oop_result, last_java_sp, entry_point, 2, check_exceptions); } void MacroAssembler::super_call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, Register arg_3, bool check_exceptions) { LP64_ONLY(assert(arg_1 != c_rarg3, "smashed arg")); LP64_ONLY(assert(arg_2 != c_rarg3, "smashed arg")); pass_arg3(this, arg_3); LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); pass_arg1(this, arg_1); super_call_VM(oop_result, last_java_sp, entry_point, 3, check_exceptions); } void MacroAssembler::call_VM_base(Register oop_result, Register java_thread, Register last_java_sp, address entry_point, int number_of_arguments, bool check_exceptions) { // determine java_thread register if (!java_thread->is_valid()) { #ifdef _LP64 java_thread = r15_thread; #else java_thread = rdi; get_thread(java_thread); #endif // LP64 } // determine last_java_sp register if (!last_java_sp->is_valid()) { last_java_sp = rsp; } // debugging support assert(number_of_arguments >= 0 , "cannot have negative number of arguments"); LP64_ONLY(assert(java_thread == r15_thread, "unexpected register")); #ifdef ASSERT // TraceBytecodes does not use r12 but saves it over the call, so don't verify // r12 is the heapbase. LP64_ONLY(if ((UseCompressedOops || UseCompressedClassPointers) && !TraceBytecodes) verify_heapbase("call_VM_base: heap base corrupted?");) #endif // ASSERT assert(java_thread != oop_result , "cannot use the same register for java_thread & oop_result"); assert(java_thread != last_java_sp, "cannot use the same register for java_thread & last_java_sp"); // push java thread (becomes first argument of C function) NOT_LP64(push(java_thread); number_of_arguments++); LP64_ONLY(mov(c_rarg0, r15_thread)); // set last Java frame before call assert(last_java_sp != rbp, "can't use ebp/rbp"); // Only interpreter should have to set fp set_last_Java_frame(java_thread, last_java_sp, rbp, NULL); // do the call, remove parameters MacroAssembler::call_VM_leaf_base(entry_point, number_of_arguments); // restore the thread (cannot use the pushed argument since arguments // may be overwritten by C code generated by an optimizing compiler); // however can use the register value directly if it is callee saved. if (LP64_ONLY(true ||) java_thread == rdi || java_thread == rsi) { // rdi & rsi (also r15) are callee saved -> nothing to do #ifdef ASSERT guarantee(java_thread != rax, "change this code"); push(rax); { Label L; get_thread(rax); cmpptr(java_thread, rax); jcc(Assembler::equal, L); STOP("MacroAssembler::call_VM_base: rdi not callee saved?"); bind(L); } pop(rax); #endif } else { get_thread(java_thread); } // reset last Java frame // Only interpreter should have to clear fp reset_last_Java_frame(java_thread, true, false); #ifndef CC_INTERP // C++ interp handles this in the interpreter check_and_handle_popframe(java_thread); check_and_handle_earlyret(java_thread); #endif /* CC_INTERP */ if (check_exceptions) { // check for pending exceptions (java_thread is set upon return) cmpptr(Address(java_thread, Thread::pending_exception_offset()), (int32_t) NULL_WORD); #ifndef _LP64 jump_cc(Assembler::notEqual, RuntimeAddress(StubRoutines::forward_exception_entry())); #else // This used to conditionally jump to forward_exception however it is // possible if we relocate that the branch will not reach. So we must jump // around so we can always reach Label ok; jcc(Assembler::equal, ok); jump(RuntimeAddress(StubRoutines::forward_exception_entry())); bind(ok); #endif // LP64 } // get oop result if there is one and reset the value in the thread if (oop_result->is_valid()) { get_vm_result(oop_result, java_thread); } } void MacroAssembler::call_VM_helper(Register oop_result, address entry_point, int number_of_arguments, bool check_exceptions) { // Calculate the value for last_Java_sp // somewhat subtle. call_VM does an intermediate call // which places a return address on the stack just under the // stack pointer as the user finsihed with it. This allows // use to retrieve last_Java_pc from last_Java_sp[-1]. // On 32bit we then have to push additional args on the stack to accomplish // the actual requested call. On 64bit call_VM only can use register args // so the only extra space is the return address that call_VM created. // This hopefully explains the calculations here. #ifdef _LP64 // We've pushed one address, correct last_Java_sp lea(rax, Address(rsp, wordSize)); #else lea(rax, Address(rsp, (1 + number_of_arguments) * wordSize)); #endif // LP64 call_VM_base(oop_result, noreg, rax, entry_point, number_of_arguments, check_exceptions); } void MacroAssembler::call_VM_leaf(address entry_point, int number_of_arguments) { call_VM_leaf_base(entry_point, number_of_arguments); } void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0) { pass_arg0(this, arg_0); call_VM_leaf(entry_point, 1); } void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0, Register arg_1) { LP64_ONLY(assert(arg_0 != c_rarg1, "smashed arg")); pass_arg1(this, arg_1); pass_arg0(this, arg_0); call_VM_leaf(entry_point, 2); } void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0, Register arg_1, Register arg_2) { LP64_ONLY(assert(arg_0 != c_rarg2, "smashed arg")); LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); LP64_ONLY(assert(arg_0 != c_rarg1, "smashed arg")); pass_arg1(this, arg_1); pass_arg0(this, arg_0); call_VM_leaf(entry_point, 3); } void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0) { pass_arg0(this, arg_0); MacroAssembler::call_VM_leaf_base(entry_point, 1); } void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1) { LP64_ONLY(assert(arg_0 != c_rarg1, "smashed arg")); pass_arg1(this, arg_1); pass_arg0(this, arg_0); MacroAssembler::call_VM_leaf_base(entry_point, 2); } void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1, Register arg_2) { LP64_ONLY(assert(arg_0 != c_rarg2, "smashed arg")); LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); LP64_ONLY(assert(arg_0 != c_rarg1, "smashed arg")); pass_arg1(this, arg_1); pass_arg0(this, arg_0); MacroAssembler::call_VM_leaf_base(entry_point, 3); } void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1, Register arg_2, Register arg_3) { LP64_ONLY(assert(arg_0 != c_rarg3, "smashed arg")); LP64_ONLY(assert(arg_1 != c_rarg3, "smashed arg")); LP64_ONLY(assert(arg_2 != c_rarg3, "smashed arg")); pass_arg3(this, arg_3); LP64_ONLY(assert(arg_0 != c_rarg2, "smashed arg")); LP64_ONLY(assert(arg_1 != c_rarg2, "smashed arg")); pass_arg2(this, arg_2); LP64_ONLY(assert(arg_0 != c_rarg1, "smashed arg")); pass_arg1(this, arg_1); pass_arg0(this, arg_0); MacroAssembler::call_VM_leaf_base(entry_point, 4); } void MacroAssembler::get_vm_result(Register oop_result, Register java_thread) { movptr(oop_result, Address(java_thread, JavaThread::vm_result_offset())); movptr(Address(java_thread, JavaThread::vm_result_offset()), NULL_WORD); verify_oop(oop_result, "broken oop in call_VM_base"); } void MacroAssembler::get_vm_result_2(Register metadata_result, Register java_thread) { movptr(metadata_result, Address(java_thread, JavaThread::vm_result_2_offset())); movptr(Address(java_thread, JavaThread::vm_result_2_offset()), NULL_WORD); } void MacroAssembler::check_and_handle_earlyret(Register java_thread) { } void MacroAssembler::check_and_handle_popframe(Register java_thread) { } void MacroAssembler::cmp32(AddressLiteral src1, int32_t imm) { if (reachable(src1)) { cmpl(as_Address(src1), imm); } else { lea(rscratch1, src1); cmpl(Address(rscratch1, 0), imm); } } void MacroAssembler::cmp32(Register src1, AddressLiteral src2) { assert(!src2.is_lval(), "use cmpptr"); if (reachable(src2)) { cmpl(src1, as_Address(src2)); } else { lea(rscratch1, src2); cmpl(src1, Address(rscratch1, 0)); } } void MacroAssembler::cmp32(Register src1, int32_t imm) { Assembler::cmpl(src1, imm); } void MacroAssembler::cmp32(Register src1, Address src2) { Assembler::cmpl(src1, src2); } void MacroAssembler::cmpsd2int(XMMRegister opr1, XMMRegister opr2, Register dst, bool unordered_is_less) { ucomisd(opr1, opr2); Label L; if (unordered_is_less) { movl(dst, -1); jcc(Assembler::parity, L); jcc(Assembler::below , L); movl(dst, 0); jcc(Assembler::equal , L); increment(dst); } else { // unordered is greater movl(dst, 1); jcc(Assembler::parity, L); jcc(Assembler::above , L); movl(dst, 0); jcc(Assembler::equal , L); decrementl(dst); } bind(L); } void MacroAssembler::cmpss2int(XMMRegister opr1, XMMRegister opr2, Register dst, bool unordered_is_less) { ucomiss(opr1, opr2); Label L; if (unordered_is_less) { movl(dst, -1); jcc(Assembler::parity, L); jcc(Assembler::below , L); movl(dst, 0); jcc(Assembler::equal , L); increment(dst); } else { // unordered is greater movl(dst, 1); jcc(Assembler::parity, L); jcc(Assembler::above , L); movl(dst, 0); jcc(Assembler::equal , L); decrementl(dst); } bind(L); } void MacroAssembler::cmp8(AddressLiteral src1, int imm) { if (reachable(src1)) { cmpb(as_Address(src1), imm); } else { lea(rscratch1, src1); cmpb(Address(rscratch1, 0), imm); } } void MacroAssembler::cmpptr(Register src1, AddressLiteral src2) { #ifdef _LP64 if (src2.is_lval()) { movptr(rscratch1, src2); Assembler::cmpq(src1, rscratch1); } else if (reachable(src2)) { cmpq(src1, as_Address(src2)); } else { lea(rscratch1, src2); Assembler::cmpq(src1, Address(rscratch1, 0)); } #else if (src2.is_lval()) { cmp_literal32(src1, (int32_t) src2.target(), src2.rspec()); } else { cmpl(src1, as_Address(src2)); } #endif // _LP64 } void MacroAssembler::cmpptr(Address src1, AddressLiteral src2) { assert(src2.is_lval(), "not a mem-mem compare"); #ifdef _LP64 // moves src2's literal address movptr(rscratch1, src2); Assembler::cmpq(src1, rscratch1); #else cmp_literal32(src1, (int32_t) src2.target(), src2.rspec()); #endif // _LP64 } void MacroAssembler::locked_cmpxchgptr(Register reg, AddressLiteral adr) { if (reachable(adr)) { if (os::is_MP()) lock(); cmpxchgptr(reg, as_Address(adr)); } else { lea(rscratch1, adr); if (os::is_MP()) lock(); cmpxchgptr(reg, Address(rscratch1, 0)); } } void MacroAssembler::cmpxchgptr(Register reg, Address adr) { LP64_ONLY(cmpxchgq(reg, adr)) NOT_LP64(cmpxchgl(reg, adr)); } void MacroAssembler::comisd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::comisd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::comisd(dst, Address(rscratch1, 0)); } } void MacroAssembler::comiss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::comiss(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::comiss(dst, Address(rscratch1, 0)); } } void MacroAssembler::cond_inc32(Condition cond, AddressLiteral counter_addr) { Condition negated_cond = negate_condition(cond); Label L; jcc(negated_cond, L); atomic_incl(counter_addr); bind(L); } int MacroAssembler::corrected_idivl(Register reg) { // Full implementation of Java idiv and irem; checks for // special case as described in JVM spec., p.243 & p.271. // The function returns the (pc) offset of the idivl // instruction - may be needed for implicit exceptions. // // normal case special case // // input : rax,: dividend min_int // reg: divisor (may not be rax,/rdx) -1 // // output: rax,: quotient (= rax, idiv reg) min_int // rdx: remainder (= rax, irem reg) 0 assert(reg != rax && reg != rdx, "reg cannot be rax, or rdx register"); const int min_int = 0x80000000; Label normal_case, special_case; // check for special case cmpl(rax, min_int); jcc(Assembler::notEqual, normal_case); xorl(rdx, rdx); // prepare rdx for possible special case (where remainder = 0) cmpl(reg, -1); jcc(Assembler::equal, special_case); // handle normal case bind(normal_case); cdql(); int idivl_offset = offset(); idivl(reg); // normal and special case exit bind(special_case); return idivl_offset; } void MacroAssembler::decrementl(Register reg, int value) { if (value == min_jint) {subl(reg, value) ; return; } if (value < 0) { incrementl(reg, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { decl(reg) ; return; } /* else */ { subl(reg, value) ; return; } } void MacroAssembler::decrementl(Address dst, int value) { if (value == min_jint) {subl(dst, value) ; return; } if (value < 0) { incrementl(dst, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { decl(dst) ; return; } /* else */ { subl(dst, value) ; return; } } void MacroAssembler::division_with_shift (Register reg, int shift_value) { assert (shift_value > 0, "illegal shift value"); Label _is_positive; testl (reg, reg); jcc (Assembler::positive, _is_positive); int offset = (1 << shift_value) - 1 ; if (offset == 1) { incrementl(reg); } else { addl(reg, offset); } bind (_is_positive); sarl(reg, shift_value); } void MacroAssembler::divsd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::divsd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::divsd(dst, Address(rscratch1, 0)); } } void MacroAssembler::divss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::divss(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::divss(dst, Address(rscratch1, 0)); } } // !defined(COMPILER2) is because of stupid core builds #if !defined(_LP64) || defined(COMPILER1) || !defined(COMPILER2) void MacroAssembler::empty_FPU_stack() { if (VM_Version::supports_mmx()) { emms(); } else { for (int i = 8; i-- > 0; ) ffree(i); } } #endif // !LP64 || C1 || !C2 // Defines obj, preserves var_size_in_bytes void MacroAssembler::eden_allocate(Register obj, Register var_size_in_bytes, int con_size_in_bytes, Register t1, Label& slow_case) { assert(obj == rax, "obj must be in rax, for cmpxchg"); assert_different_registers(obj, var_size_in_bytes, t1); if (CMSIncrementalMode || !Universe::heap()->supports_inline_contig_alloc()) { jmp(slow_case); } else { Register end = t1; Label retry; bind(retry); ExternalAddress heap_top((address) Universe::heap()->top_addr()); movptr(obj, heap_top); if (var_size_in_bytes == noreg) { lea(end, Address(obj, con_size_in_bytes)); } else { lea(end, Address(obj, var_size_in_bytes, Address::times_1)); } // if end < obj then we wrapped around => object too long => slow case cmpptr(end, obj); jcc(Assembler::below, slow_case); cmpptr(end, ExternalAddress((address) Universe::heap()->end_addr())); jcc(Assembler::above, slow_case); // Compare obj with the top addr, and if still equal, store the new top addr in // end at the address of the top addr pointer. Sets ZF if was equal, and clears // it otherwise. Use lock prefix for atomicity on MPs. locked_cmpxchgptr(end, heap_top); jcc(Assembler::notEqual, retry); } } void MacroAssembler::enter() { push(rbp); mov(rbp, rsp); } // A 5 byte nop that is safe for patching (see patch_verified_entry) void MacroAssembler::fat_nop() { if (UseAddressNop) { addr_nop_5(); } else { emit_int8(0x26); // es: emit_int8(0x2e); // cs: emit_int8(0x64); // fs: emit_int8(0x65); // gs: emit_int8((unsigned char)0x90); } } void MacroAssembler::fcmp(Register tmp) { fcmp(tmp, 1, true, true); } void MacroAssembler::fcmp(Register tmp, int index, bool pop_left, bool pop_right) { assert(!pop_right || pop_left, "usage error"); if (VM_Version::supports_cmov()) { assert(tmp == noreg, "unneeded temp"); if (pop_left) { fucomip(index); } else { fucomi(index); } if (pop_right) { fpop(); } } else { assert(tmp != noreg, "need temp"); if (pop_left) { if (pop_right) { fcompp(); } else { fcomp(index); } } else { fcom(index); } // convert FPU condition into eflags condition via rax, save_rax(tmp); fwait(); fnstsw_ax(); sahf(); restore_rax(tmp); } // condition codes set as follows: // // CF (corresponds to C0) if x < y // PF (corresponds to C2) if unordered // ZF (corresponds to C3) if x = y } void MacroAssembler::fcmp2int(Register dst, bool unordered_is_less) { fcmp2int(dst, unordered_is_less, 1, true, true); } void MacroAssembler::fcmp2int(Register dst, bool unordered_is_less, int index, bool pop_left, bool pop_right) { fcmp(VM_Version::supports_cmov() ? noreg : dst, index, pop_left, pop_right); Label L; if (unordered_is_less) { movl(dst, -1); jcc(Assembler::parity, L); jcc(Assembler::below , L); movl(dst, 0); jcc(Assembler::equal , L); increment(dst); } else { // unordered is greater movl(dst, 1); jcc(Assembler::parity, L); jcc(Assembler::above , L); movl(dst, 0); jcc(Assembler::equal , L); decrementl(dst); } bind(L); } void MacroAssembler::fld_d(AddressLiteral src) { fld_d(as_Address(src)); } void MacroAssembler::fld_s(AddressLiteral src) { fld_s(as_Address(src)); } void MacroAssembler::fld_x(AddressLiteral src) { Assembler::fld_x(as_Address(src)); } void MacroAssembler::fldcw(AddressLiteral src) { Assembler::fldcw(as_Address(src)); } void MacroAssembler::pow_exp_core_encoding() { // kills rax, rcx, rdx subptr(rsp,sizeof(jdouble)); // computes 2^X. Stack: X ... // f2xm1 computes 2^X-1 but only operates on -1<=X<=1. Get int(X) and // keep it on the thread's stack to compute 2^int(X) later // then compute 2^(X-int(X)) as (2^(X-int(X)-1+1) // final result is obtained with: 2^X = 2^int(X) * 2^(X-int(X)) fld_s(0); // Stack: X X ... frndint(); // Stack: int(X) X ... fsuba(1); // Stack: int(X) X-int(X) ... fistp_s(Address(rsp,0)); // move int(X) as integer to thread's stack. Stack: X-int(X) ... f2xm1(); // Stack: 2^(X-int(X))-1 ... fld1(); // Stack: 1 2^(X-int(X))-1 ... faddp(1); // Stack: 2^(X-int(X)) // computes 2^(int(X)): add exponent bias (1023) to int(X), then // shift int(X)+1023 to exponent position. // Exponent is limited to 11 bits if int(X)+1023 does not fit in 11 // bits, set result to NaN. 0x000 and 0x7FF are reserved exponent // values so detect them and set result to NaN. movl(rax,Address(rsp,0)); movl(rcx, -2048); // 11 bit mask and valid NaN binary encoding addl(rax, 1023); movl(rdx,rax); shll(rax,20); // Check that 0 < int(X)+1023 < 2047. Otherwise set rax to NaN. addl(rdx,1); // Check that 1 < int(X)+1023+1 < 2048 // in 3 steps: // 1- (int(X)+1023+1)&-2048 == 0 => 0 <= int(X)+1023+1 < 2048 // 2- (int(X)+1023+1)&-2048 != 0 // 3- (int(X)+1023+1)&-2048 != 1 // Do 2- first because addl just updated the flags. cmov32(Assembler::equal,rax,rcx); cmpl(rdx,1); cmov32(Assembler::equal,rax,rcx); testl(rdx,rcx); cmov32(Assembler::notEqual,rax,rcx); movl(Address(rsp,4),rax); movl(Address(rsp,0),0); fmul_d(Address(rsp,0)); // Stack: 2^X ... addptr(rsp,sizeof(jdouble)); } void MacroAssembler::increase_precision() { subptr(rsp, BytesPerWord); fnstcw(Address(rsp, 0)); movl(rax, Address(rsp, 0)); orl(rax, 0x300); push(rax); fldcw(Address(rsp, 0)); pop(rax); } void MacroAssembler::restore_precision() { fldcw(Address(rsp, 0)); addptr(rsp, BytesPerWord); } void MacroAssembler::fast_pow() { // computes X^Y = 2^(Y * log2(X)) // if fast computation is not possible, result is NaN. Requires // fallback from user of this macro. // increase precision for intermediate steps of the computation increase_precision(); fyl2x(); // Stack: (Y*log2(X)) ... pow_exp_core_encoding(); // Stack: exp(X) ... restore_precision(); } void MacroAssembler::fast_exp() { // computes exp(X) = 2^(X * log2(e)) // if fast computation is not possible, result is NaN. Requires // fallback from user of this macro. // increase precision for intermediate steps of the computation increase_precision(); fldl2e(); // Stack: log2(e) X ... fmulp(1); // Stack: (X*log2(e)) ... pow_exp_core_encoding(); // Stack: exp(X) ... restore_precision(); } void MacroAssembler::pow_or_exp(bool is_exp, int num_fpu_regs_in_use) { // kills rax, rcx, rdx // pow and exp needs 2 extra registers on the fpu stack. Label slow_case, done; Register tmp = noreg; if (!VM_Version::supports_cmov()) { // fcmp needs a temporary so preserve rdx, tmp = rdx; } Register tmp2 = rax; Register tmp3 = rcx; if (is_exp) { // Stack: X fld_s(0); // duplicate argument for runtime call. Stack: X X fast_exp(); // Stack: exp(X) X fcmp(tmp, 0, false, false); // Stack: exp(X) X // exp(X) not equal to itself: exp(X) is NaN go to slow case. jcc(Assembler::parity, slow_case); // get rid of duplicate argument. Stack: exp(X) if (num_fpu_regs_in_use > 0) { fxch(); fpop(); } else { ffree(1); } jmp(done); } else { // Stack: X Y Label x_negative, y_odd; fldz(); // Stack: 0 X Y fcmp(tmp, 1, true, false); // Stack: X Y jcc(Assembler::above, x_negative); // X >= 0 fld_s(1); // duplicate arguments for runtime call. Stack: Y X Y fld_s(1); // Stack: X Y X Y fast_pow(); // Stack: X^Y X Y fcmp(tmp, 0, false, false); // Stack: X^Y X Y // X^Y not equal to itself: X^Y is NaN go to slow case. jcc(Assembler::parity, slow_case); // get rid of duplicate arguments. Stack: X^Y if (num_fpu_regs_in_use > 0) { fxch(); fpop(); fxch(); fpop(); } else { ffree(2); ffree(1); } jmp(done); // X <= 0 bind(x_negative); fld_s(1); // Stack: Y X Y frndint(); // Stack: int(Y) X Y fcmp(tmp, 2, false, false); // Stack: int(Y) X Y jcc(Assembler::notEqual, slow_case); subptr(rsp, 8); // For X^Y, when X < 0, Y has to be an integer and the final // result depends on whether it's odd or even. We just checked // that int(Y) == Y. We move int(Y) to gp registers as a 64 bit // integer to test its parity. If int(Y) is huge and doesn't fit // in the 64 bit integer range, the integer indefinite value will // end up in the gp registers. Huge numbers are all even, the // integer indefinite number is even so it's fine. #ifdef ASSERT // Let's check we don't end up with an integer indefinite number // when not expected. First test for huge numbers: check whether // int(Y)+1 == int(Y) which is true for very large numbers and // those are all even. A 64 bit integer is guaranteed to not // overflow for numbers where y+1 != y (when precision is set to // double precision). Label y_not_huge; fld1(); // Stack: 1 int(Y) X Y fadd(1); // Stack: 1+int(Y) int(Y) X Y #ifdef _LP64 // trip to memory to force the precision down from double extended // precision fstp_d(Address(rsp, 0)); fld_d(Address(rsp, 0)); #endif fcmp(tmp, 1, true, false); // Stack: int(Y) X Y #endif // move int(Y) as 64 bit integer to thread's stack fistp_d(Address(rsp,0)); // Stack: X Y #ifdef ASSERT jcc(Assembler::notEqual, y_not_huge); // Y is huge so we know it's even. It may not fit in a 64 bit // integer and we don't want the debug code below to see the // integer indefinite value so overwrite int(Y) on the thread's // stack with 0. movl(Address(rsp, 0), 0); movl(Address(rsp, 4), 0); bind(y_not_huge); #endif fld_s(1); // duplicate arguments for runtime call. Stack: Y X Y fld_s(1); // Stack: X Y X Y fabs(); // Stack: abs(X) Y X Y fast_pow(); // Stack: abs(X)^Y X Y fcmp(tmp, 0, false, false); // Stack: abs(X)^Y X Y // abs(X)^Y not equal to itself: abs(X)^Y is NaN go to slow case. pop(tmp2); NOT_LP64(pop(tmp3)); jcc(Assembler::parity, slow_case); #ifdef ASSERT // Check that int(Y) is not integer indefinite value (int // overflow). Shouldn't happen because for values that would // overflow, 1+int(Y)==Y which was tested earlier. #ifndef _LP64 { Label integer; testl(tmp2, tmp2); jcc(Assembler::notZero, integer); cmpl(tmp3, 0x80000000); jcc(Assembler::notZero, integer); STOP("integer indefinite value shouldn't be seen here"); bind(integer); } #else { Label integer; mov(tmp3, tmp2); // preserve tmp2 for parity check below shlq(tmp3, 1); jcc(Assembler::carryClear, integer); jcc(Assembler::notZero, integer); STOP("integer indefinite value shouldn't be seen here"); bind(integer); } #endif #endif // get rid of duplicate arguments. Stack: X^Y if (num_fpu_regs_in_use > 0) { fxch(); fpop(); fxch(); fpop(); } else { ffree(2); ffree(1); } testl(tmp2, 1); jcc(Assembler::zero, done); // X <= 0, Y even: X^Y = abs(X)^Y // X <= 0, Y even: X^Y = -abs(X)^Y fchs(); // Stack: -abs(X)^Y Y jmp(done); } // slow case: runtime call bind(slow_case); fpop(); // pop incorrect result or int(Y) fp_runtime_fallback(is_exp ? CAST_FROM_FN_PTR(address, SharedRuntime::dexp) : CAST_FROM_FN_PTR(address, SharedRuntime::dpow), is_exp ? 1 : 2, num_fpu_regs_in_use); // Come here with result in F-TOS bind(done); } void MacroAssembler::fpop() { ffree(); fincstp(); } void MacroAssembler::fremr(Register tmp) { save_rax(tmp); { Label L; bind(L); fprem(); fwait(); fnstsw_ax(); #ifdef _LP64 testl(rax, 0x400); jcc(Assembler::notEqual, L); #else sahf(); jcc(Assembler::parity, L); #endif // _LP64 } restore_rax(tmp); // Result is in ST0. // Note: fxch & fpop to get rid of ST1 // (otherwise FPU stack could overflow eventually) fxch(1); fpop(); } void MacroAssembler::incrementl(AddressLiteral dst) { if (reachable(dst)) { incrementl(as_Address(dst)); } else { lea(rscratch1, dst); incrementl(Address(rscratch1, 0)); } } void MacroAssembler::incrementl(ArrayAddress dst) { incrementl(as_Address(dst)); } void MacroAssembler::incrementl(Register reg, int value) { if (value == min_jint) {addl(reg, value) ; return; } if (value < 0) { decrementl(reg, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { incl(reg) ; return; } /* else */ { addl(reg, value) ; return; } } void MacroAssembler::incrementl(Address dst, int value) { if (value == min_jint) {addl(dst, value) ; return; } if (value < 0) { decrementl(dst, -value); return; } if (value == 0) { ; return; } if (value == 1 && UseIncDec) { incl(dst) ; return; } /* else */ { addl(dst, value) ; return; } } void MacroAssembler::jump(AddressLiteral dst) { if (reachable(dst)) { jmp_literal(dst.target(), dst.rspec()); } else { lea(rscratch1, dst); jmp(rscratch1); } } void MacroAssembler::jump_cc(Condition cc, AddressLiteral dst) { if (reachable(dst)) { InstructionMark im(this); relocate(dst.reloc()); const int short_size = 2; const int long_size = 6; int offs = (intptr_t)dst.target() - ((intptr_t)pc()); if (dst.reloc() == relocInfo::none && is8bit(offs - short_size)) { // 0111 tttn #8-bit disp emit_int8(0x70 | cc); emit_int8((offs - short_size) & 0xFF); } else { // 0000 1111 1000 tttn #32-bit disp emit_int8(0x0F); emit_int8((unsigned char)(0x80 | cc)); emit_int32(offs - long_size); } } else { #ifdef ASSERT warning("reversing conditional branch"); #endif /* ASSERT */ Label skip; jccb(reverse[cc], skip); lea(rscratch1, dst); Assembler::jmp(rscratch1); bind(skip); } } void MacroAssembler::ldmxcsr(AddressLiteral src) { if (reachable(src)) { Assembler::ldmxcsr(as_Address(src)); } else { lea(rscratch1, src); Assembler::ldmxcsr(Address(rscratch1, 0)); } } int MacroAssembler::load_signed_byte(Register dst, Address src) { int off; if (LP64_ONLY(true ||) VM_Version::is_P6()) { off = offset(); movsbl(dst, src); // movsxb } else { off = load_unsigned_byte(dst, src); shll(dst, 24); sarl(dst, 24); } return off; } // Note: load_signed_short used to be called load_signed_word. // Although the 'w' in x86 opcodes refers to the term "word" in the assembler // manual, which means 16 bits, that usage is found nowhere in HotSpot code. // The term "word" in HotSpot means a 32- or 64-bit machine word. int MacroAssembler::load_signed_short(Register dst, Address src) { int off; if (LP64_ONLY(true ||) VM_Version::is_P6()) { // This is dubious to me since it seems safe to do a signed 16 => 64 bit // version but this is what 64bit has always done. This seems to imply // that users are only using 32bits worth. off = offset(); movswl(dst, src); // movsxw } else { off = load_unsigned_short(dst, src); shll(dst, 16); sarl(dst, 16); } return off; } int MacroAssembler::load_unsigned_byte(Register dst, Address src) { // According to Intel Doc. AP-526, "Zero-Extension of Short", p.16, // and "3.9 Partial Register Penalties", p. 22). int off; if (LP64_ONLY(true || ) VM_Version::is_P6() || src.uses(dst)) { off = offset(); movzbl(dst, src); // movzxb } else { xorl(dst, dst); off = offset(); movb(dst, src); } return off; } // Note: load_unsigned_short used to be called load_unsigned_word. int MacroAssembler::load_unsigned_short(Register dst, Address src) { // According to Intel Doc. AP-526, "Zero-Extension of Short", p.16, // and "3.9 Partial Register Penalties", p. 22). int off; if (LP64_ONLY(true ||) VM_Version::is_P6() || src.uses(dst)) { off = offset(); movzwl(dst, src); // movzxw } else { xorl(dst, dst); off = offset(); movw(dst, src); } return off; } void MacroAssembler::load_sized_value(Register dst, Address src, size_t size_in_bytes, bool is_signed, Register dst2) { switch (size_in_bytes) { #ifndef _LP64 case 8: assert(dst2 != noreg, "second dest register required"); movl(dst, src); movl(dst2, src.plus_disp(BytesPerInt)); break; #else case 8: movq(dst, src); break; #endif case 4: movl(dst, src); break; case 2: is_signed ? load_signed_short(dst, src) : load_unsigned_short(dst, src); break; case 1: is_signed ? load_signed_byte( dst, src) : load_unsigned_byte( dst, src); break; default: ShouldNotReachHere(); } } void MacroAssembler::store_sized_value(Address dst, Register src, size_t size_in_bytes, Register src2) { switch (size_in_bytes) { #ifndef _LP64 case 8: assert(src2 != noreg, "second source register required"); movl(dst, src); movl(dst.plus_disp(BytesPerInt), src2); break; #else case 8: movq(dst, src); break; #endif case 4: movl(dst, src); break; case 2: movw(dst, src); break; case 1: movb(dst, src); break; default: ShouldNotReachHere(); } } void MacroAssembler::mov32(AddressLiteral dst, Register src) { if (reachable(dst)) { movl(as_Address(dst), src); } else { lea(rscratch1, dst); movl(Address(rscratch1, 0), src); } } void MacroAssembler::mov32(Register dst, AddressLiteral src) { if (reachable(src)) { movl(dst, as_Address(src)); } else { lea(rscratch1, src); movl(dst, Address(rscratch1, 0)); } } // C++ bool manipulation void MacroAssembler::movbool(Register dst, Address src) { if(sizeof(bool) == 1) movb(dst, src); else if(sizeof(bool) == 2) movw(dst, src); else if(sizeof(bool) == 4) movl(dst, src); else // unsupported ShouldNotReachHere(); } void MacroAssembler::movbool(Address dst, bool boolconst) { if(sizeof(bool) == 1) movb(dst, (int) boolconst); else if(sizeof(bool) == 2) movw(dst, (int) boolconst); else if(sizeof(bool) == 4) movl(dst, (int) boolconst); else // unsupported ShouldNotReachHere(); } void MacroAssembler::movbool(Address dst, Register src) { if(sizeof(bool) == 1) movb(dst, src); else if(sizeof(bool) == 2) movw(dst, src); else if(sizeof(bool) == 4) movl(dst, src); else // unsupported ShouldNotReachHere(); } void MacroAssembler::movbyte(ArrayAddress dst, int src) { movb(as_Address(dst), src); } void MacroAssembler::movdl(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { movdl(dst, as_Address(src)); } else { lea(rscratch1, src); movdl(dst, Address(rscratch1, 0)); } } void MacroAssembler::movq(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { movq(dst, as_Address(src)); } else { lea(rscratch1, src); movq(dst, Address(rscratch1, 0)); } } void MacroAssembler::movdbl(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { if (UseXmmLoadAndClearUpper) { movsd (dst, as_Address(src)); } else { movlpd(dst, as_Address(src)); } } else { lea(rscratch1, src); if (UseXmmLoadAndClearUpper) { movsd (dst, Address(rscratch1, 0)); } else { movlpd(dst, Address(rscratch1, 0)); } } } void MacroAssembler::movflt(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { movss(dst, as_Address(src)); } else { lea(rscratch1, src); movss(dst, Address(rscratch1, 0)); } } void MacroAssembler::movptr(Register dst, Register src) { LP64_ONLY(movq(dst, src)) NOT_LP64(movl(dst, src)); } void MacroAssembler::movptr(Register dst, Address src) { LP64_ONLY(movq(dst, src)) NOT_LP64(movl(dst, src)); } // src should NEVER be a real pointer. Use AddressLiteral for true pointers void MacroAssembler::movptr(Register dst, intptr_t src) { LP64_ONLY(mov64(dst, src)) NOT_LP64(movl(dst, src)); } void MacroAssembler::movptr(Address dst, Register src) { LP64_ONLY(movq(dst, src)) NOT_LP64(movl(dst, src)); } void MacroAssembler::movdqu(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::movdqu(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::movdqu(dst, Address(rscratch1, 0)); } } void MacroAssembler::movdqa(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::movdqa(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::movdqa(dst, Address(rscratch1, 0)); } } void MacroAssembler::movsd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::movsd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::movsd(dst, Address(rscratch1, 0)); } } void MacroAssembler::movss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::movss(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::movss(dst, Address(rscratch1, 0)); } } void MacroAssembler::mulsd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::mulsd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::mulsd(dst, Address(rscratch1, 0)); } } void MacroAssembler::mulss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::mulss(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::mulss(dst, Address(rscratch1, 0)); } } void MacroAssembler::null_check(Register reg, int offset) { if (needs_explicit_null_check(offset)) { // provoke OS NULL exception if reg = NULL by // accessing M[reg] w/o changing any (non-CC) registers // NOTE: cmpl is plenty here to provoke a segv cmpptr(rax, Address(reg, 0)); // Note: should probably use testl(rax, Address(reg, 0)); // may be shorter code (however, this version of // testl needs to be implemented first) } else { // nothing to do, (later) access of M[reg + offset] // will provoke OS NULL exception if reg = NULL } } void MacroAssembler::os_breakpoint() { // instead of directly emitting a breakpoint, call os:breakpoint for better debugability // (e.g., MSVC can't call ps() otherwise) call(RuntimeAddress(CAST_FROM_FN_PTR(address, os::breakpoint))); } void MacroAssembler::pop_CPU_state() { pop_FPU_state(); pop_IU_state(); } void MacroAssembler::pop_FPU_state() { NOT_LP64(frstor(Address(rsp, 0));) LP64_ONLY(fxrstor(Address(rsp, 0));) addptr(rsp, FPUStateSizeInWords * wordSize); } void MacroAssembler::pop_IU_state() { popa(); LP64_ONLY(addq(rsp, 8)); popf(); } // Save Integer and Float state // Warning: Stack must be 16 byte aligned (64bit) void MacroAssembler::push_CPU_state() { push_IU_state(); push_FPU_state(); } void MacroAssembler::push_FPU_state() { subptr(rsp, FPUStateSizeInWords * wordSize); #ifndef _LP64 fnsave(Address(rsp, 0)); fwait(); #else fxsave(Address(rsp, 0)); #endif // LP64 } void MacroAssembler::push_IU_state() { // Push flags first because pusha kills them pushf(); // Make sure rsp stays 16-byte aligned LP64_ONLY(subq(rsp, 8)); pusha(); } void MacroAssembler::reset_last_Java_frame(Register java_thread, bool clear_fp, bool clear_pc) { // determine java_thread register if (!java_thread->is_valid()) { java_thread = rdi; get_thread(java_thread); } // we must set sp to zero to clear frame movptr(Address(java_thread, JavaThread::last_Java_sp_offset()), NULL_WORD); if (clear_fp) { movptr(Address(java_thread, JavaThread::last_Java_fp_offset()), NULL_WORD); } if (clear_pc) movptr(Address(java_thread, JavaThread::last_Java_pc_offset()), NULL_WORD); } void MacroAssembler::restore_rax(Register tmp) { if (tmp == noreg) pop(rax); else if (tmp != rax) mov(rax, tmp); } void MacroAssembler::round_to(Register reg, int modulus) { addptr(reg, modulus - 1); andptr(reg, -modulus); } void MacroAssembler::save_rax(Register tmp) { if (tmp == noreg) push(rax); else if (tmp != rax) mov(tmp, rax); } // Write serialization page so VM thread can do a pseudo remote membar. // We use the current thread pointer to calculate a thread specific // offset to write to within the page. This minimizes bus traffic // due to cache line collision. void MacroAssembler::serialize_memory(Register thread, Register tmp) { movl(tmp, thread); shrl(tmp, os::get_serialize_page_shift_count()); andl(tmp, (os::vm_page_size() - sizeof(int))); Address index(noreg, tmp, Address::times_1); ExternalAddress page(os::get_memory_serialize_page()); // Size of store must match masking code above movl(as_Address(ArrayAddress(page, index)), tmp); } // Calls to C land // // When entering C land, the rbp, & rsp of the last Java frame have to be recorded // in the (thread-local) JavaThread object. When leaving C land, the last Java fp // has to be reset to 0. This is required to allow proper stack traversal. void MacroAssembler::set_last_Java_frame(Register java_thread, Register last_java_sp, Register last_java_fp, address last_java_pc) { // determine java_thread register if (!java_thread->is_valid()) { java_thread = rdi; get_thread(java_thread); } // determine last_java_sp register if (!last_java_sp->is_valid()) { last_java_sp = rsp; } // last_java_fp is optional if (last_java_fp->is_valid()) { movptr(Address(java_thread, JavaThread::last_Java_fp_offset()), last_java_fp); } // last_java_pc is optional if (last_java_pc != NULL) { lea(Address(java_thread, JavaThread::frame_anchor_offset() + JavaFrameAnchor::last_Java_pc_offset()), InternalAddress(last_java_pc)); } movptr(Address(java_thread, JavaThread::last_Java_sp_offset()), last_java_sp); } void MacroAssembler::shlptr(Register dst, int imm8) { LP64_ONLY(shlq(dst, imm8)) NOT_LP64(shll(dst, imm8)); } void MacroAssembler::shrptr(Register dst, int imm8) { LP64_ONLY(shrq(dst, imm8)) NOT_LP64(shrl(dst, imm8)); } void MacroAssembler::sign_extend_byte(Register reg) { if (LP64_ONLY(true ||) (VM_Version::is_P6() && reg->has_byte_register())) { movsbl(reg, reg); // movsxb } else { shll(reg, 24); sarl(reg, 24); } } void MacroAssembler::sign_extend_short(Register reg) { if (LP64_ONLY(true ||) VM_Version::is_P6()) { movswl(reg, reg); // movsxw } else { shll(reg, 16); sarl(reg, 16); } } void MacroAssembler::testl(Register dst, AddressLiteral src) { assert(reachable(src), "Address should be reachable"); testl(dst, as_Address(src)); } void MacroAssembler::sqrtsd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::sqrtsd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::sqrtsd(dst, Address(rscratch1, 0)); } } void MacroAssembler::sqrtss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::sqrtss(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::sqrtss(dst, Address(rscratch1, 0)); } } void MacroAssembler::subsd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::subsd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::subsd(dst, Address(rscratch1, 0)); } } void MacroAssembler::subss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::subss(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::subss(dst, Address(rscratch1, 0)); } } void MacroAssembler::ucomisd(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::ucomisd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::ucomisd(dst, Address(rscratch1, 0)); } } void MacroAssembler::ucomiss(XMMRegister dst, AddressLiteral src) { if (reachable(src)) { Assembler::ucomiss(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::ucomiss(dst, Address(rscratch1, 0)); } } void MacroAssembler::xorpd(XMMRegister dst, AddressLiteral src) { // Used in sign-bit flipping with aligned address. assert((UseAVX > 0) || (((intptr_t)src.target() & 15) == 0), "SSE mode requires address alignment 16 bytes"); if (reachable(src)) { Assembler::xorpd(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::xorpd(dst, Address(rscratch1, 0)); } } void MacroAssembler::xorps(XMMRegister dst, AddressLiteral src) { // Used in sign-bit flipping with aligned address. assert((UseAVX > 0) || (((intptr_t)src.target() & 15) == 0), "SSE mode requires address alignment 16 bytes"); if (reachable(src)) { Assembler::xorps(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::xorps(dst, Address(rscratch1, 0)); } } void MacroAssembler::pshufb(XMMRegister dst, AddressLiteral src) { // Used in sign-bit flipping with aligned address. bool aligned_adr = (((intptr_t)src.target() & 15) == 0); assert((UseAVX > 0) || aligned_adr, "SSE mode requires address alignment 16 bytes"); if (reachable(src)) { Assembler::pshufb(dst, as_Address(src)); } else { lea(rscratch1, src); Assembler::pshufb(dst, Address(rscratch1, 0)); } } // AVX 3-operands instructions void MacroAssembler::vaddsd(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vaddsd(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vaddsd(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vaddss(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vaddss(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vaddss(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vandpd(XMMRegister dst, XMMRegister nds, AddressLiteral src, bool vector256) { if (reachable(src)) { vandpd(dst, nds, as_Address(src), vector256); } else { lea(rscratch1, src); vandpd(dst, nds, Address(rscratch1, 0), vector256); } } void MacroAssembler::vandps(XMMRegister dst, XMMRegister nds, AddressLiteral src, bool vector256) { if (reachable(src)) { vandps(dst, nds, as_Address(src), vector256); } else { lea(rscratch1, src); vandps(dst, nds, Address(rscratch1, 0), vector256); } } void MacroAssembler::vdivsd(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vdivsd(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vdivsd(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vdivss(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vdivss(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vdivss(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vmulsd(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vmulsd(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vmulsd(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vmulss(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vmulss(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vmulss(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vsubsd(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vsubsd(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vsubsd(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vsubss(XMMRegister dst, XMMRegister nds, AddressLiteral src) { if (reachable(src)) { vsubss(dst, nds, as_Address(src)); } else { lea(rscratch1, src); vsubss(dst, nds, Address(rscratch1, 0)); } } void MacroAssembler::vxorpd(XMMRegister dst, XMMRegister nds, AddressLiteral src, bool vector256) { if (reachable(src)) { vxorpd(dst, nds, as_Address(src), vector256); } else { lea(rscratch1, src); vxorpd(dst, nds, Address(rscratch1, 0), vector256); } } void MacroAssembler::vxorps(XMMRegister dst, XMMRegister nds, AddressLiteral src, bool vector256) { if (reachable(src)) { vxorps(dst, nds, as_Address(src), vector256); } else { lea(rscratch1, src); vxorps(dst, nds, Address(rscratch1, 0), vector256); } } ////////////////////////////////////////////////////////////////////////////////// #if INCLUDE_ALL_GCS void MacroAssembler::g1_write_barrier_pre(Register obj, Register pre_val, Register thread, Register tmp, bool tosca_live, bool expand_call) { // If expand_call is true then we expand the call_VM_leaf macro // directly to skip generating the check by // InterpreterMacroAssembler::call_VM_leaf_base that checks _last_sp. #ifdef _LP64 assert(thread == r15_thread, "must be"); #endif // _LP64 Label done; Label runtime; assert(pre_val != noreg, "check this code"); if (obj != noreg) { assert_different_registers(obj, pre_val, tmp); assert(pre_val != rax, "check this code"); } Address in_progress(thread, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_active())); Address index(thread, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_index())); Address buffer(thread, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_buf())); // Is marking active? if (in_bytes(PtrQueue::byte_width_of_active()) == 4) { cmpl(in_progress, 0); } else { assert(in_bytes(PtrQueue::byte_width_of_active()) == 1, "Assumption"); cmpb(in_progress, 0); } jcc(Assembler::equal, done); // Do we need to load the previous value? if (obj != noreg) { load_heap_oop(pre_val, Address(obj, 0)); } // Is the previous value null? cmpptr(pre_val, (int32_t) NULL_WORD); jcc(Assembler::equal, done); // Can we store original value in the thread's buffer? // Is index == 0? // (The index field is typed as size_t.) movptr(tmp, index); // tmp := *index_adr cmpptr(tmp, 0); // tmp == 0? jcc(Assembler::equal, runtime); // If yes, goto runtime subptr(tmp, wordSize); // tmp := tmp - wordSize movptr(index, tmp); // *index_adr := tmp addptr(tmp, buffer); // tmp := tmp + *buffer_adr // Record the previous value movptr(Address(tmp, 0), pre_val); jmp(done); bind(runtime); // save the live input values if(tosca_live) push(rax); if (obj != noreg && obj != rax) push(obj); if (pre_val != rax) push(pre_val); // Calling the runtime using the regular call_VM_leaf mechanism generates // code (generated by InterpreterMacroAssember::call_VM_leaf_base) // that checks that the *(ebp+frame::interpreter_frame_last_sp) == NULL. // // If we care generating the pre-barrier without a frame (e.g. in the // intrinsified Reference.get() routine) then ebp might be pointing to // the caller frame and so this check will most likely fail at runtime. // // Expanding the call directly bypasses the generation of the check. // So when we do not have have a full interpreter frame on the stack // expand_call should be passed true. NOT_LP64( push(thread); ) if (expand_call) { LP64_ONLY( assert(pre_val != c_rarg1, "smashed arg"); ) pass_arg1(this, thread); pass_arg0(this, pre_val); MacroAssembler::call_VM_leaf_base(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_pre), 2); } else { call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_pre), pre_val, thread); } NOT_LP64( pop(thread); ) // save the live input values if (pre_val != rax) pop(pre_val); if (obj != noreg && obj != rax) pop(obj); if(tosca_live) pop(rax); bind(done); } void MacroAssembler::g1_write_barrier_post(Register store_addr, Register new_val, Register thread, Register tmp, Register tmp2) { #ifdef _LP64 assert(thread == r15_thread, "must be"); #endif // _LP64 Address queue_index(thread, in_bytes(JavaThread::dirty_card_queue_offset() + PtrQueue::byte_offset_of_index())); Address buffer(thread, in_bytes(JavaThread::dirty_card_queue_offset() + PtrQueue::byte_offset_of_buf())); BarrierSet* bs = Universe::heap()->barrier_set(); CardTableModRefBS* ct = (CardTableModRefBS*)bs; assert(sizeof(*ct->byte_map_base) == sizeof(jbyte), "adjust this code"); Label done; Label runtime; // Does store cross heap regions? movptr(tmp, store_addr); xorptr(tmp, new_val); shrptr(tmp, HeapRegion::LogOfHRGrainBytes); jcc(Assembler::equal, done); // crosses regions, storing NULL? cmpptr(new_val, (int32_t) NULL_WORD); jcc(Assembler::equal, done); // storing region crossing non-NULL, is card already dirty? const Register card_addr = tmp; const Register cardtable = tmp2; movptr(card_addr, store_addr); shrptr(card_addr, CardTableModRefBS::card_shift); // Do not use ExternalAddress to load 'byte_map_base', since 'byte_map_base' is NOT // a valid address and therefore is not properly handled by the relocation code. movptr(cardtable, (intptr_t)ct->byte_map_base); addptr(card_addr, cardtable); cmpb(Address(card_addr, 0), (int)G1SATBCardTableModRefBS::g1_young_card_val()); jcc(Assembler::equal, done); membar(Assembler::Membar_mask_bits(Assembler::StoreLoad)); cmpb(Address(card_addr, 0), (int)CardTableModRefBS::dirty_card_val()); jcc(Assembler::equal, done); // storing a region crossing, non-NULL oop, card is clean. // dirty card and log. movb(Address(card_addr, 0), (int)CardTableModRefBS::dirty_card_val()); cmpl(queue_index, 0); jcc(Assembler::equal, runtime); subl(queue_index, wordSize); movptr(tmp2, buffer); #ifdef _LP64 movslq(rscratch1, queue_index); addq(tmp2, rscratch1); movq(Address(tmp2, 0), card_addr); #else addl(tmp2, queue_index); movl(Address(tmp2, 0), card_addr); #endif jmp(done); bind(runtime); // save the live input values push(store_addr); push(new_val); #ifdef _LP64 call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_post), card_addr, r15_thread); #else push(thread); call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_post), card_addr, thread); pop(thread); #endif pop(new_val); pop(store_addr); bind(done); } #endif // INCLUDE_ALL_GCS ////////////////////////////////////////////////////////////////////////////////// void MacroAssembler::store_check(Register obj) { // Does a store check for the oop in register obj. The content of // register obj is destroyed afterwards. store_check_part_1(obj); store_check_part_2(obj); } void MacroAssembler::store_check(Register obj, Address dst) { store_check(obj); } // split the store check operation so that other instructions can be scheduled inbetween void MacroAssembler::store_check_part_1(Register obj) { BarrierSet* bs = Universe::heap()->barrier_set(); assert(bs->kind() == BarrierSet::CardTableModRef, "Wrong barrier set kind"); shrptr(obj, CardTableModRefBS::card_shift); } void MacroAssembler::store_check_part_2(Register obj) { BarrierSet* bs = Universe::heap()->barrier_set(); assert(bs->kind() == BarrierSet::CardTableModRef, "Wrong barrier set kind"); CardTableModRefBS* ct = (CardTableModRefBS*)bs; assert(sizeof(*ct->byte_map_base) == sizeof(jbyte), "adjust this code"); // The calculation for byte_map_base is as follows: // byte_map_base = _byte_map - (uintptr_t(low_bound) >> card_shift); // So this essentially converts an address to a displacement and it will // never need to be relocated. On 64bit however the value may be too // large for a 32bit displacement. intptr_t disp = (intptr_t) ct->byte_map_base; if (is_simm32(disp)) { Address cardtable(noreg, obj, Address::times_1, disp); movb(cardtable, 0); } else { // By doing it as an ExternalAddress 'disp' could be converted to a rip-relative // displacement and done in a single instruction given favorable mapping and a // smarter version of as_Address. However, 'ExternalAddress' generates a relocation // entry and that entry is not properly handled by the relocation code. AddressLiteral cardtable((address)ct->byte_map_base, relocInfo::none); Address index(noreg, obj, Address::times_1); movb(as_Address(ArrayAddress(cardtable, index)), 0); } } void MacroAssembler::subptr(Register dst, int32_t imm32) { LP64_ONLY(subq(dst, imm32)) NOT_LP64(subl(dst, imm32)); } // Force generation of a 4 byte immediate value even if it fits into 8bit void MacroAssembler::subptr_imm32(Register dst, int32_t imm32) { LP64_ONLY(subq_imm32(dst, imm32)) NOT_LP64(subl_imm32(dst, imm32)); } void MacroAssembler::subptr(Register dst, Register src) { LP64_ONLY(subq(dst, src)) NOT_LP64(subl(dst, src)); } // C++ bool manipulation void MacroAssembler::testbool(Register dst) { if(sizeof(bool) == 1) testb(dst, 0xff); else if(sizeof(bool) == 2) { // testw implementation needed for two byte bools ShouldNotReachHere(); } else if(sizeof(bool) == 4) testl(dst, dst); else // unsupported ShouldNotReachHere(); } void MacroAssembler::testptr(Register dst, Register src) { LP64_ONLY(testq(dst, src)) NOT_LP64(testl(dst, src)); } // Defines obj, preserves var_size_in_bytes, okay for t2 == var_size_in_bytes. void MacroAssembler::tlab_allocate(Register obj, Register var_size_in_bytes, int con_size_in_bytes, Register t1, Register t2, Label& slow_case) { assert_different_registers(obj, t1, t2); assert_different_registers(obj, var_size_in_bytes, t1); Register end = t2; Register thread = NOT_LP64(t1) LP64_ONLY(r15_thread); verify_tlab(); NOT_LP64(get_thread(thread)); movptr(obj, Address(thread, JavaThread::tlab_top_offset())); if (var_size_in_bytes == noreg) { lea(end, Address(obj, con_size_in_bytes)); } else { lea(end, Address(obj, var_size_in_bytes, Address::times_1)); } cmpptr(end, Address(thread, JavaThread::tlab_end_offset())); jcc(Assembler::above, slow_case); // update the tlab top pointer movptr(Address(thread, JavaThread::tlab_top_offset()), end); // recover var_size_in_bytes if necessary if (var_size_in_bytes == end) { subptr(var_size_in_bytes, obj); } verify_tlab(); } // Preserves rbx, and rdx. Register MacroAssembler::tlab_refill(Label& retry, Label& try_eden, Label& slow_case) { Register top = rax; Register t1 = rcx; Register t2 = rsi; Register thread_reg = NOT_LP64(rdi) LP64_ONLY(r15_thread); assert_different_registers(top, thread_reg, t1, t2, /* preserve: */ rbx, rdx); Label do_refill, discard_tlab; if (CMSIncrementalMode || !Universe::heap()->supports_inline_contig_alloc()) { // No allocation in the shared eden. jmp(slow_case); } NOT_LP64(get_thread(thread_reg)); movptr(top, Address(thread_reg, in_bytes(JavaThread::tlab_top_offset()))); movptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_end_offset()))); // calculate amount of free space subptr(t1, top); shrptr(t1, LogHeapWordSize); // Retain tlab and allocate object in shared space if // the amount free in the tlab is too large to discard. cmpptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_refill_waste_limit_offset()))); jcc(Assembler::lessEqual, discard_tlab); // Retain // %%% yuck as movptr... movptr(t2, (int32_t) ThreadLocalAllocBuffer::refill_waste_limit_increment()); addptr(Address(thread_reg, in_bytes(JavaThread::tlab_refill_waste_limit_offset())), t2); if (TLABStats) { // increment number of slow_allocations addl(Address(thread_reg, in_bytes(JavaThread::tlab_slow_allocations_offset())), 1); } jmp(try_eden); bind(discard_tlab); if (TLABStats) { // increment number of refills addl(Address(thread_reg, in_bytes(JavaThread::tlab_number_of_refills_offset())), 1); // accumulate wastage -- t1 is amount free in tlab addl(Address(thread_reg, in_bytes(JavaThread::tlab_fast_refill_waste_offset())), t1); } // if tlab is currently allocated (top or end != null) then // fill [top, end + alignment_reserve) with array object testptr(top, top); jcc(Assembler::zero, do_refill); // set up the mark word movptr(Address(top, oopDesc::mark_offset_in_bytes()), (intptr_t)markOopDesc::prototype()->copy_set_hash(0x2)); // set the length to the remaining space subptr(t1, typeArrayOopDesc::header_size(T_INT)); addptr(t1, (int32_t)ThreadLocalAllocBuffer::alignment_reserve()); shlptr(t1, log2_intptr(HeapWordSize/sizeof(jint))); movl(Address(top, arrayOopDesc::length_offset_in_bytes()), t1); // set klass to intArrayKlass // dubious reloc why not an oop reloc? movptr(t1, ExternalAddress((address)Universe::intArrayKlassObj_addr())); // store klass last. concurrent gcs assumes klass length is valid if // klass field is not null. store_klass(top, t1); movptr(t1, top); subptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_start_offset()))); incr_allocated_bytes(thread_reg, t1, 0); // refill the tlab with an eden allocation bind(do_refill); movptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_size_offset()))); shlptr(t1, LogHeapWordSize); // allocate new tlab, address returned in top eden_allocate(top, t1, 0, t2, slow_case); // Check that t1 was preserved in eden_allocate. #ifdef ASSERT if (UseTLAB) { Label ok; Register tsize = rsi; assert_different_registers(tsize, thread_reg, t1); push(tsize); movptr(tsize, Address(thread_reg, in_bytes(JavaThread::tlab_size_offset()))); shlptr(tsize, LogHeapWordSize); cmpptr(t1, tsize); jcc(Assembler::equal, ok); STOP("assert(t1 != tlab size)"); should_not_reach_here(); bind(ok); pop(tsize); } #endif movptr(Address(thread_reg, in_bytes(JavaThread::tlab_start_offset())), top); movptr(Address(thread_reg, in_bytes(JavaThread::tlab_top_offset())), top); addptr(top, t1); subptr(top, (int32_t)ThreadLocalAllocBuffer::alignment_reserve_in_bytes()); movptr(Address(thread_reg, in_bytes(JavaThread::tlab_end_offset())), top); verify_tlab(); jmp(retry); return thread_reg; // for use by caller } void MacroAssembler::incr_allocated_bytes(Register thread, Register var_size_in_bytes, int con_size_in_bytes, Register t1) { if (!thread->is_valid()) { #ifdef _LP64 thread = r15_thread; #else assert(t1->is_valid(), "need temp reg"); thread = t1; get_thread(thread); #endif } #ifdef _LP64 if (var_size_in_bytes->is_valid()) { addq(Address(thread, in_bytes(JavaThread::allocated_bytes_offset())), var_size_in_bytes); } else { addq(Address(thread, in_bytes(JavaThread::allocated_bytes_offset())), con_size_in_bytes); } #else if (var_size_in_bytes->is_valid()) { addl(Address(thread, in_bytes(JavaThread::allocated_bytes_offset())), var_size_in_bytes); } else { addl(Address(thread, in_bytes(JavaThread::allocated_bytes_offset())), con_size_in_bytes); } adcl(Address(thread, in_bytes(JavaThread::allocated_bytes_offset())+4), 0); #endif } void MacroAssembler::fp_runtime_fallback(address runtime_entry, int nb_args, int num_fpu_regs_in_use) { pusha(); // if we are coming from c1, xmm registers may be live int off = 0; if (UseSSE == 1) { subptr(rsp, sizeof(jdouble)*8); movflt(Address(rsp,off++*sizeof(jdouble)),xmm0); movflt(Address(rsp,off++*sizeof(jdouble)),xmm1); movflt(Address(rsp,off++*sizeof(jdouble)),xmm2); movflt(Address(rsp,off++*sizeof(jdouble)),xmm3); movflt(Address(rsp,off++*sizeof(jdouble)),xmm4); movflt(Address(rsp,off++*sizeof(jdouble)),xmm5); movflt(Address(rsp,off++*sizeof(jdouble)),xmm6); movflt(Address(rsp,off++*sizeof(jdouble)),xmm7); } else if (UseSSE >= 2) { #ifdef COMPILER2 if (MaxVectorSize > 16) { assert(UseAVX > 0, "256bit vectors are supported only with AVX"); // Save upper half of YMM registes subptr(rsp, 16 * LP64_ONLY(16) NOT_LP64(8)); vextractf128h(Address(rsp, 0),xmm0); vextractf128h(Address(rsp, 16),xmm1); vextractf128h(Address(rsp, 32),xmm2); vextractf128h(Address(rsp, 48),xmm3); vextractf128h(Address(rsp, 64),xmm4); vextractf128h(Address(rsp, 80),xmm5); vextractf128h(Address(rsp, 96),xmm6); vextractf128h(Address(rsp,112),xmm7); #ifdef _LP64 vextractf128h(Address(rsp,128),xmm8); vextractf128h(Address(rsp,144),xmm9); vextractf128h(Address(rsp,160),xmm10); vextractf128h(Address(rsp,176),xmm11); vextractf128h(Address(rsp,192),xmm12); vextractf128h(Address(rsp,208),xmm13); vextractf128h(Address(rsp,224),xmm14); vextractf128h(Address(rsp,240),xmm15); #endif } #endif // Save whole 128bit (16 bytes) XMM regiters subptr(rsp, 16 * LP64_ONLY(16) NOT_LP64(8)); movdqu(Address(rsp,off++*16),xmm0); movdqu(Address(rsp,off++*16),xmm1); movdqu(Address(rsp,off++*16),xmm2); movdqu(Address(rsp,off++*16),xmm3); movdqu(Address(rsp,off++*16),xmm4); movdqu(Address(rsp,off++*16),xmm5); movdqu(Address(rsp,off++*16),xmm6); movdqu(Address(rsp,off++*16),xmm7); #ifdef _LP64 movdqu(Address(rsp,off++*16),xmm8); movdqu(Address(rsp,off++*16),xmm9); movdqu(Address(rsp,off++*16),xmm10); movdqu(Address(rsp,off++*16),xmm11); movdqu(Address(rsp,off++*16),xmm12); movdqu(Address(rsp,off++*16),xmm13); movdqu(Address(rsp,off++*16),xmm14); movdqu(Address(rsp,off++*16),xmm15); #endif } // Preserve registers across runtime call int incoming_argument_and_return_value_offset = -1; if (num_fpu_regs_in_use > 1) { // Must preserve all other FPU regs (could alternatively convert // SharedRuntime::dsin, dcos etc. into assembly routines known not to trash // FPU state, but can not trust C compiler) NEEDS_CLEANUP; // NOTE that in this case we also push the incoming argument(s) to // the stack and restore it later; we also use this stack slot to // hold the return value from dsin, dcos etc. for (int i = 0; i < num_fpu_regs_in_use; i++) { subptr(rsp, sizeof(jdouble)); fstp_d(Address(rsp, 0)); } incoming_argument_and_return_value_offset = sizeof(jdouble)*(num_fpu_regs_in_use-1); for (int i = nb_args-1; i >= 0; i--) { fld_d(Address(rsp, incoming_argument_and_return_value_offset-i*sizeof(jdouble))); } } subptr(rsp, nb_args*sizeof(jdouble)); for (int i = 0; i < nb_args; i++) { fstp_d(Address(rsp, i*sizeof(jdouble))); } #ifdef _LP64 if (nb_args > 0) { movdbl(xmm0, Address(rsp, 0)); } if (nb_args > 1) { movdbl(xmm1, Address(rsp, sizeof(jdouble))); } assert(nb_args <= 2, "unsupported number of args"); #endif // _LP64 // NOTE: we must not use call_VM_leaf here because that requires a // complete interpreter frame in debug mode -- same bug as 4387334 // MacroAssembler::call_VM_leaf_base is perfectly safe and will // do proper 64bit abi NEEDS_CLEANUP; // Need to add stack banging before this runtime call if it needs to // be taken; however, there is no generic stack banging routine at // the MacroAssembler level MacroAssembler::call_VM_leaf_base(runtime_entry, 0); #ifdef _LP64 movsd(Address(rsp, 0), xmm0); fld_d(Address(rsp, 0)); #endif // _LP64 addptr(rsp, sizeof(jdouble) * nb_args); if (num_fpu_regs_in_use > 1) { // Must save return value to stack and then restore entire FPU // stack except incoming arguments fstp_d(Address(rsp, incoming_argument_and_return_value_offset)); for (int i = 0; i < num_fpu_regs_in_use - nb_args; i++) { fld_d(Address(rsp, 0)); addptr(rsp, sizeof(jdouble)); } fld_d(Address(rsp, (nb_args-1)*sizeof(jdouble))); addptr(rsp, sizeof(jdouble) * nb_args); } off = 0; if (UseSSE == 1) { movflt(xmm0, Address(rsp,off++*sizeof(jdouble))); movflt(xmm1, Address(rsp,off++*sizeof(jdouble))); movflt(xmm2, Address(rsp,off++*sizeof(jdouble))); movflt(xmm3, Address(rsp,off++*sizeof(jdouble))); movflt(xmm4, Address(rsp,off++*sizeof(jdouble))); movflt(xmm5, Address(rsp,off++*sizeof(jdouble))); movflt(xmm6, Address(rsp,off++*sizeof(jdouble))); movflt(xmm7, Address(rsp,off++*sizeof(jdouble))); addptr(rsp, sizeof(jdouble)*8); } else if (UseSSE >= 2) { // Restore whole 128bit (16 bytes) XMM regiters movdqu(xmm0, Address(rsp,off++*16)); movdqu(xmm1, Address(rsp,off++*16)); movdqu(xmm2, Address(rsp,off++*16)); movdqu(xmm3, Address(rsp,off++*16)); movdqu(xmm4, Address(rsp,off++*16)); movdqu(xmm5, Address(rsp,off++*16)); movdqu(xmm6, Address(rsp,off++*16)); movdqu(xmm7, Address(rsp,off++*16)); #ifdef _LP64 movdqu(xmm8, Address(rsp,off++*16)); movdqu(xmm9, Address(rsp,off++*16)); movdqu(xmm10, Address(rsp,off++*16)); movdqu(xmm11, Address(rsp,off++*16)); movdqu(xmm12, Address(rsp,off++*16)); movdqu(xmm13, Address(rsp,off++*16)); movdqu(xmm14, Address(rsp,off++*16)); movdqu(xmm15, Address(rsp,off++*16)); #endif addptr(rsp, 16 * LP64_ONLY(16) NOT_LP64(8)); #ifdef COMPILER2 if (MaxVectorSize > 16) { // Restore upper half of YMM registes. vinsertf128h(xmm0, Address(rsp, 0)); vinsertf128h(xmm1, Address(rsp, 16)); vinsertf128h(xmm2, Address(rsp, 32)); vinsertf128h(xmm3, Address(rsp, 48)); vinsertf128h(xmm4, Address(rsp, 64)); vinsertf128h(xmm5, Address(rsp, 80)); vinsertf128h(xmm6, Address(rsp, 96)); vinsertf128h(xmm7, Address(rsp,112)); #ifdef _LP64 vinsertf128h(xmm8, Address(rsp,128)); vinsertf128h(xmm9, Address(rsp,144)); vinsertf128h(xmm10, Address(rsp,160)); vinsertf128h(xmm11, Address(rsp,176)); vinsertf128h(xmm12, Address(rsp,192)); vinsertf128h(xmm13, Address(rsp,208)); vinsertf128h(xmm14, Address(rsp,224)); vinsertf128h(xmm15, Address(rsp,240)); #endif addptr(rsp, 16 * LP64_ONLY(16) NOT_LP64(8)); } #endif } popa(); } static const double pi_4 = 0.7853981633974483; void MacroAssembler::trigfunc(char trig, int num_fpu_regs_in_use) { // A hand-coded argument reduction for values in fabs(pi/4, pi/2) // was attempted in this code; unfortunately it appears that the // switch to 80-bit precision and back causes this to be // unprofitable compared with simply performing a runtime call if // the argument is out of the (-pi/4, pi/4) range. Register tmp = noreg; if (!VM_Version::supports_cmov()) { // fcmp needs a temporary so preserve rbx, tmp = rbx; push(tmp); } Label slow_case, done; ExternalAddress pi4_adr = (address)&pi_4; if (reachable(pi4_adr)) { // x ?<= pi/4 fld_d(pi4_adr); fld_s(1); // Stack: X PI/4 X fabs(); // Stack: |X| PI/4 X fcmp(tmp); jcc(Assembler::above, slow_case); // fastest case: -pi/4 <= x <= pi/4 switch(trig) { case 's': fsin(); break; case 'c': fcos(); break; case 't': ftan(); break; default: assert(false, "bad intrinsic"); break; } jmp(done); } // slow case: runtime call bind(slow_case); switch(trig) { case 's': { fp_runtime_fallback(CAST_FROM_FN_PTR(address, SharedRuntime::dsin), 1, num_fpu_regs_in_use); } break; case 'c': { fp_runtime_fallback(CAST_FROM_FN_PTR(address, SharedRuntime::dcos), 1, num_fpu_regs_in_use); } break; case 't': { fp_runtime_fallback(CAST_FROM_FN_PTR(address, SharedRuntime::dtan), 1, num_fpu_regs_in_use); } break; default: assert(false, "bad intrinsic"); break; } // Come here with result in F-TOS bind(done); if (tmp != noreg) { pop(tmp); } } // Look up the method for a megamorphic invokeinterface call. // The target method is determined by . // The receiver klass is in recv_klass. // On success, the result will be in method_result, and execution falls through. // On failure, execution transfers to the given label. void MacroAssembler::lookup_interface_method(Register recv_klass, Register intf_klass, RegisterOrConstant itable_index, Register method_result, Register scan_temp, Label& L_no_such_interface) { assert_different_registers(recv_klass, intf_klass, method_result, scan_temp); assert(itable_index.is_constant() || itable_index.as_register() == method_result, "caller must use same register for non-constant itable index as for method"); // Compute start of first itableOffsetEntry (which is at the end of the vtable) int vtable_base = InstanceKlass::vtable_start_offset() * wordSize; int itentry_off = itableMethodEntry::method_offset_in_bytes(); int scan_step = itableOffsetEntry::size() * wordSize; int vte_size = vtableEntry::size() * wordSize; Address::ScaleFactor times_vte_scale = Address::times_ptr; assert(vte_size == wordSize, "else adjust times_vte_scale"); movl(scan_temp, Address(recv_klass, InstanceKlass::vtable_length_offset() * wordSize)); // %%% Could store the aligned, prescaled offset in the klassoop. lea(scan_temp, Address(recv_klass, scan_temp, times_vte_scale, vtable_base)); if (HeapWordsPerLong > 1) { // Round up to align_object_offset boundary // see code for InstanceKlass::start_of_itable! round_to(scan_temp, BytesPerLong); } // Adjust recv_klass by scaled itable_index, so we can free itable_index. assert(itableMethodEntry::size() * wordSize == wordSize, "adjust the scaling in the code below"); lea(recv_klass, Address(recv_klass, itable_index, Address::times_ptr, itentry_off)); // for (scan = klass->itable(); scan->interface() != NULL; scan += scan_step) { // if (scan->interface() == intf) { // result = (klass + scan->offset() + itable_index); // } // } Label search, found_method; for (int peel = 1; peel >= 0; peel--) { movptr(method_result, Address(scan_temp, itableOffsetEntry::interface_offset_in_bytes())); cmpptr(intf_klass, method_result); if (peel) { jccb(Assembler::equal, found_method); } else { jccb(Assembler::notEqual, search); // (invert the test to fall through to found_method...) } if (!peel) break; bind(search); // Check that the previous entry is non-null. A null entry means that // the receiver class doesn't implement the interface, and wasn't the // same as when the caller was compiled. testptr(method_result, method_result); jcc(Assembler::zero, L_no_such_interface); addptr(scan_temp, scan_step); } bind(found_method); // Got a hit. movl(scan_temp, Address(scan_temp, itableOffsetEntry::offset_offset_in_bytes())); movptr(method_result, Address(recv_klass, scan_temp, Address::times_1)); } // virtual method calling void MacroAssembler::lookup_virtual_method(Register recv_klass, RegisterOrConstant vtable_index, Register method_result) { const int base = InstanceKlass::vtable_start_offset() * wordSize; assert(vtableEntry::size() * wordSize == wordSize, "else adjust the scaling in the code below"); Address vtable_entry_addr(recv_klass, vtable_index, Address::times_ptr, base + vtableEntry::method_offset_in_bytes()); movptr(method_result, vtable_entry_addr); } void MacroAssembler::check_klass_subtype(Register sub_klass, Register super_klass, Register temp_reg, Label& L_success) { Label L_failure; check_klass_subtype_fast_path(sub_klass, super_klass, temp_reg, &L_success, &L_failure, NULL); check_klass_subtype_slow_path(sub_klass, super_klass, temp_reg, noreg, &L_success, NULL); bind(L_failure); } void MacroAssembler::check_klass_subtype_fast_path(Register sub_klass, Register super_klass, Register temp_reg, Label* L_success, Label* L_failure, Label* L_slow_path, RegisterOrConstant super_check_offset) { assert_different_registers(sub_klass, super_klass, temp_reg); bool must_load_sco = (super_check_offset.constant_or_zero() == -1); if (super_check_offset.is_register()) { assert_different_registers(sub_klass, super_klass, super_check_offset.as_register()); } else if (must_load_sco) { assert(temp_reg != noreg, "supply either a temp or a register offset"); } Label L_fallthrough; int label_nulls = 0; if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; } if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; } if (L_slow_path == NULL) { L_slow_path = &L_fallthrough; label_nulls++; } assert(label_nulls <= 1, "at most one NULL in the batch"); int sc_offset = in_bytes(Klass::secondary_super_cache_offset()); int sco_offset = in_bytes(Klass::super_check_offset_offset()); Address super_check_offset_addr(super_klass, sco_offset); // Hacked jcc, which "knows" that L_fallthrough, at least, is in // range of a jccb. If this routine grows larger, reconsider at // least some of these. #define local_jcc(assembler_cond, label) \ if (&(label) == &L_fallthrough) jccb(assembler_cond, label); \ else jcc( assembler_cond, label) /*omit semi*/ // Hacked jmp, which may only be used just before L_fallthrough. #define final_jmp(label) \ if (&(label) == &L_fallthrough) { /*do nothing*/ } \ else jmp(label) /*omit semi*/ // If the pointers are equal, we are done (e.g., String[] elements). // This self-check enables sharing of secondary supertype arrays among // non-primary types such as array-of-interface. Otherwise, each such // type would need its own customized SSA. // We move this check to the front of the fast path because many // type checks are in fact trivially successful in this manner, // so we get a nicely predicted branch right at the start of the check. cmpptr(sub_klass, super_klass); local_jcc(Assembler::equal, *L_success); // Check the supertype display: if (must_load_sco) { // Positive movl does right thing on LP64. movl(temp_reg, super_check_offset_addr); super_check_offset = RegisterOrConstant(temp_reg); } Address super_check_addr(sub_klass, super_check_offset, Address::times_1, 0); cmpptr(super_klass, super_check_addr); // load displayed supertype // This check has worked decisively for primary supers. // Secondary supers are sought in the super_cache ('super_cache_addr'). // (Secondary supers are interfaces and very deeply nested subtypes.) // This works in the same check above because of a tricky aliasing // between the super_cache and the primary super display elements. // (The 'super_check_addr' can address either, as the case requires.) // Note that the cache is updated below if it does not help us find // what we need immediately. // So if it was a primary super, we can just fail immediately. // Otherwise, it's the slow path for us (no success at this point). if (super_check_offset.is_register()) { local_jcc(Assembler::equal, *L_success); cmpl(super_check_offset.as_register(), sc_offset); if (L_failure == &L_fallthrough) { local_jcc(Assembler::equal, *L_slow_path); } else { local_jcc(Assembler::notEqual, *L_failure); final_jmp(*L_slow_path); } } else if (super_check_offset.as_constant() == sc_offset) { // Need a slow path; fast failure is impossible. if (L_slow_path == &L_fallthrough) { local_jcc(Assembler::equal, *L_success); } else { local_jcc(Assembler::notEqual, *L_slow_path); final_jmp(*L_success); } } else { // No slow path; it's a fast decision. if (L_failure == &L_fallthrough) { local_jcc(Assembler::equal, *L_success); } else { local_jcc(Assembler::notEqual, *L_failure); final_jmp(*L_success); } } bind(L_fallthrough); #undef local_jcc #undef final_jmp } void MacroAssembler::check_klass_subtype_slow_path(Register sub_klass, Register super_klass, Register temp_reg, Register temp2_reg, Label* L_success, Label* L_failure, bool set_cond_codes) { assert_different_registers(sub_klass, super_klass, temp_reg); if (temp2_reg != noreg) assert_different_registers(sub_klass, super_klass, temp_reg, temp2_reg); #define IS_A_TEMP(reg) ((reg) == temp_reg || (reg) == temp2_reg) Label L_fallthrough; int label_nulls = 0; if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; } if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; } assert(label_nulls <= 1, "at most one NULL in the batch"); // a couple of useful fields in sub_klass: int ss_offset = in_bytes(Klass::secondary_supers_offset()); int sc_offset = in_bytes(Klass::secondary_super_cache_offset()); Address secondary_supers_addr(sub_klass, ss_offset); Address super_cache_addr( sub_klass, sc_offset); // Do a linear scan of the secondary super-klass chain. // This code is rarely used, so simplicity is a virtue here. // The repne_scan instruction uses fixed registers, which we must spill. // Don't worry too much about pre-existing connections with the input regs. assert(sub_klass != rax, "killed reg"); // killed by mov(rax, super) assert(sub_klass != rcx, "killed reg"); // killed by lea(rcx, &pst_counter) // Get super_klass value into rax (even if it was in rdi or rcx). bool pushed_rax = false, pushed_rcx = false, pushed_rdi = false; if (super_klass != rax || UseCompressedOops) { if (!IS_A_TEMP(rax)) { push(rax); pushed_rax = true; } mov(rax, super_klass); } if (!IS_A_TEMP(rcx)) { push(rcx); pushed_rcx = true; } if (!IS_A_TEMP(rdi)) { push(rdi); pushed_rdi = true; } #ifndef PRODUCT int* pst_counter = &SharedRuntime::_partial_subtype_ctr; ExternalAddress pst_counter_addr((address) pst_counter); NOT_LP64( incrementl(pst_counter_addr) ); LP64_ONLY( lea(rcx, pst_counter_addr) ); LP64_ONLY( incrementl(Address(rcx, 0)) ); #endif //PRODUCT // We will consult the secondary-super array. movptr(rdi, secondary_supers_addr); // Load the array length. (Positive movl does right thing on LP64.) movl(rcx, Address(rdi, Array::length_offset_in_bytes())); // Skip to start of data. addptr(rdi, Array::base_offset_in_bytes()); // Scan RCX words at [RDI] for an occurrence of RAX. // Set NZ/Z based on last compare. // Z flag value will not be set by 'repne' if RCX == 0 since 'repne' does // not change flags (only scas instruction which is repeated sets flags). // Set Z = 0 (not equal) before 'repne' to indicate that class was not found. testptr(rax,rax); // Set Z = 0 repne_scan(); // Unspill the temp. registers: if (pushed_rdi) pop(rdi); if (pushed_rcx) pop(rcx); if (pushed_rax) pop(rax); if (set_cond_codes) { // Special hack for the AD files: rdi is guaranteed non-zero. assert(!pushed_rdi, "rdi must be left non-NULL"); // Also, the condition codes are properly set Z/NZ on succeed/failure. } if (L_failure == &L_fallthrough) jccb(Assembler::notEqual, *L_failure); else jcc(Assembler::notEqual, *L_failure); // Success. Cache the super we found and proceed in triumph. movptr(super_cache_addr, super_klass); if (L_success != &L_fallthrough) { jmp(*L_success); } #undef IS_A_TEMP bind(L_fallthrough); } void MacroAssembler::cmov32(Condition cc, Register dst, Address src) { if (VM_Version::supports_cmov()) { cmovl(cc, dst, src); } else { Label L; jccb(negate_condition(cc), L); movl(dst, src); bind(L); } } void MacroAssembler::cmov32(Condition cc, Register dst, Register src) { if (VM_Version::supports_cmov()) { cmovl(cc, dst, src); } else { Label L; jccb(negate_condition(cc), L); movl(dst, src); bind(L); } } void MacroAssembler::verify_oop(Register reg, const char* s) { if (!VerifyOops) return; // Pass register number to verify_oop_subroutine const char* b = NULL; { ResourceMark rm; stringStream ss; ss.print("verify_oop: %s: %s", reg->name(), s); b = code_string(ss.as_string()); } BLOCK_COMMENT("verify_oop {"); #ifdef _LP64 push(rscratch1); // save r10, trashed by movptr() #endif push(rax); // save rax, push(reg); // pass register argument ExternalAddress buffer((address) b); // avoid using pushptr, as it modifies scratch registers // and our contract is not to modify anything movptr(rax, buffer.addr()); push(rax); // call indirectly to solve generation ordering problem movptr(rax, ExternalAddress(StubRoutines::verify_oop_subroutine_entry_address())); call(rax); // Caller pops the arguments (oop, message) and restores rax, r10 BLOCK_COMMENT("} verify_oop"); } RegisterOrConstant MacroAssembler::delayed_value_impl(intptr_t* delayed_value_addr, Register tmp, int offset) { intptr_t value = *delayed_value_addr; if (value != 0) return RegisterOrConstant(value + offset); // load indirectly to solve generation ordering problem movptr(tmp, ExternalAddress((address) delayed_value_addr)); #ifdef ASSERT { Label L; testptr(tmp, tmp); if (WizardMode) { const char* buf = NULL; { ResourceMark rm; stringStream ss; ss.print("DelayedValue="INTPTR_FORMAT, delayed_value_addr[1]); buf = code_string(ss.as_string()); } jcc(Assembler::notZero, L); STOP(buf); } else { jccb(Assembler::notZero, L); hlt(); } bind(L); } #endif if (offset != 0) addptr(tmp, offset); return RegisterOrConstant(tmp); } Address MacroAssembler::argument_address(RegisterOrConstant arg_slot, int extra_slot_offset) { // cf. TemplateTable::prepare_invoke(), if (load_receiver). int stackElementSize = Interpreter::stackElementSize; int offset = Interpreter::expr_offset_in_bytes(extra_slot_offset+0); #ifdef ASSERT int offset1 = Interpreter::expr_offset_in_bytes(extra_slot_offset+1); assert(offset1 - offset == stackElementSize, "correct arithmetic"); #endif Register scale_reg = noreg; Address::ScaleFactor scale_factor = Address::no_scale; if (arg_slot.is_constant()) { offset += arg_slot.as_constant() * stackElementSize; } else { scale_reg = arg_slot.as_register(); scale_factor = Address::times(stackElementSize); } offset += wordSize; // return PC is on stack return Address(rsp, scale_reg, scale_factor, offset); } void MacroAssembler::verify_oop_addr(Address addr, const char* s) { if (!VerifyOops) return; // Address adjust(addr.base(), addr.index(), addr.scale(), addr.disp() + BytesPerWord); // Pass register number to verify_oop_subroutine const char* b = NULL; { ResourceMark rm; stringStream ss; ss.print("verify_oop_addr: %s", s); b = code_string(ss.as_string()); } #ifdef _LP64 push(rscratch1); // save r10, trashed by movptr() #endif push(rax); // save rax, // addr may contain rsp so we will have to adjust it based on the push // we just did (and on 64 bit we do two pushes) // NOTE: 64bit seemed to have had a bug in that it did movq(addr, rax); which // stores rax into addr which is backwards of what was intended. if (addr.uses(rsp)) { lea(rax, addr); pushptr(Address(rax, LP64_ONLY(2 *) BytesPerWord)); } else { pushptr(addr); } ExternalAddress buffer((address) b); // pass msg argument // avoid using pushptr, as it modifies scratch registers // and our contract is not to modify anything movptr(rax, buffer.addr()); push(rax); // call indirectly to solve generation ordering problem movptr(rax, ExternalAddress(StubRoutines::verify_oop_subroutine_entry_address())); call(rax); // Caller pops the arguments (addr, message) and restores rax, r10. } void MacroAssembler::verify_tlab() { #ifdef ASSERT if (UseTLAB && VerifyOops) { Label next, ok; Register t1 = rsi; Register thread_reg = NOT_LP64(rbx) LP64_ONLY(r15_thread); push(t1); NOT_LP64(push(thread_reg)); NOT_LP64(get_thread(thread_reg)); movptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_top_offset()))); cmpptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_start_offset()))); jcc(Assembler::aboveEqual, next); STOP("assert(top >= start)"); should_not_reach_here(); bind(next); movptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_end_offset()))); cmpptr(t1, Address(thread_reg, in_bytes(JavaThread::tlab_top_offset()))); jcc(Assembler::aboveEqual, ok); STOP("assert(top <= end)"); should_not_reach_here(); bind(ok); NOT_LP64(pop(thread_reg)); pop(t1); } #endif } class ControlWord { public: int32_t _value; int rounding_control() const { return (_value >> 10) & 3 ; } int precision_control() const { return (_value >> 8) & 3 ; } bool precision() const { return ((_value >> 5) & 1) != 0; } bool underflow() const { return ((_value >> 4) & 1) != 0; } bool overflow() const { return ((_value >> 3) & 1) != 0; } bool zero_divide() const { return ((_value >> 2) & 1) != 0; } bool denormalized() const { return ((_value >> 1) & 1) != 0; } bool invalid() const { return ((_value >> 0) & 1) != 0; } void print() const { // rounding control const char* rc; switch (rounding_control()) { case 0: rc = "round near"; break; case 1: rc = "round down"; break; case 2: rc = "round up "; break; case 3: rc = "chop "; break; }; // precision control const char* pc; switch (precision_control()) { case 0: pc = "24 bits "; break; case 1: pc = "reserved"; break; case 2: pc = "53 bits "; break; case 3: pc = "64 bits "; break; }; // flags char f[9]; f[0] = ' '; f[1] = ' '; f[2] = (precision ()) ? 'P' : 'p'; f[3] = (underflow ()) ? 'U' : 'u'; f[4] = (overflow ()) ? 'O' : 'o'; f[5] = (zero_divide ()) ? 'Z' : 'z'; f[6] = (denormalized()) ? 'D' : 'd'; f[7] = (invalid ()) ? 'I' : 'i'; f[8] = '\x0'; // output printf("%04x masks = %s, %s, %s", _value & 0xFFFF, f, rc, pc); } }; class StatusWord { public: int32_t _value; bool busy() const { return ((_value >> 15) & 1) != 0; } bool C3() const { return ((_value >> 14) & 1) != 0; } bool C2() const { return ((_value >> 10) & 1) != 0; } bool C1() const { return ((_value >> 9) & 1) != 0; } bool C0() const { return ((_value >> 8) & 1) != 0; } int top() const { return (_value >> 11) & 7 ; } bool error_status() const { return ((_value >> 7) & 1) != 0; } bool stack_fault() const { return ((_value >> 6) & 1) != 0; } bool precision() const { return ((_value >> 5) & 1) != 0; } bool underflow() const { return ((_value >> 4) & 1) != 0; } bool overflow() const { return ((_value >> 3) & 1) != 0; } bool zero_divide() const { return ((_value >> 2) & 1) != 0; } bool denormalized() const { return ((_value >> 1) & 1) != 0; } bool invalid() const { return ((_value >> 0) & 1) != 0; } void print() const { // condition codes char c[5]; c[0] = (C3()) ? '3' : '-'; c[1] = (C2()) ? '2' : '-'; c[2] = (C1()) ? '1' : '-'; c[3] = (C0()) ? '0' : '-'; c[4] = '\x0'; // flags char f[9]; f[0] = (error_status()) ? 'E' : '-'; f[1] = (stack_fault ()) ? 'S' : '-'; f[2] = (precision ()) ? 'P' : '-'; f[3] = (underflow ()) ? 'U' : '-'; f[4] = (overflow ()) ? 'O' : '-'; f[5] = (zero_divide ()) ? 'Z' : '-'; f[6] = (denormalized()) ? 'D' : '-'; f[7] = (invalid ()) ? 'I' : '-'; f[8] = '\x0'; // output printf("%04x flags = %s, cc = %s, top = %d", _value & 0xFFFF, f, c, top()); } }; class TagWord { public: int32_t _value; int tag_at(int i) const { return (_value >> (i*2)) & 3; } void print() const { printf("%04x", _value & 0xFFFF); } }; class FPU_Register { public: int32_t _m0; int32_t _m1; int16_t _ex; bool is_indefinite() const { return _ex == -1 && _m1 == (int32_t)0xC0000000 && _m0 == 0; } void print() const { char sign = (_ex < 0) ? '-' : '+'; const char* kind = (_ex == 0x7FFF || _ex == (int16_t)-1) ? "NaN" : " "; printf("%c%04hx.%08x%08x %s", sign, _ex, _m1, _m0, kind); }; }; class FPU_State { public: enum { register_size = 10, number_of_registers = 8, register_mask = 7 }; ControlWord _control_word; StatusWord _status_word; TagWord _tag_word; int32_t _error_offset; int32_t _error_selector; int32_t _data_offset; int32_t _data_selector; int8_t _register[register_size * number_of_registers]; int tag_for_st(int i) const { return _tag_word.tag_at((_status_word.top() + i) & register_mask); } FPU_Register* st(int i) const { return (FPU_Register*)&_register[register_size * i]; } const char* tag_as_string(int tag) const { switch (tag) { case 0: return "valid"; case 1: return "zero"; case 2: return "special"; case 3: return "empty"; } ShouldNotReachHere(); return NULL; } void print() const { // print computation registers { int t = _status_word.top(); for (int i = 0; i < number_of_registers; i++) { int j = (i - t) & register_mask; printf("%c r%d = ST%d = ", (j == 0 ? '*' : ' '), i, j); st(j)->print(); printf(" %s\n", tag_as_string(_tag_word.tag_at(i))); } } printf("\n"); // print control registers printf("ctrl = "); _control_word.print(); printf("\n"); printf("stat = "); _status_word .print(); printf("\n"); printf("tags = "); _tag_word .print(); printf("\n"); } }; class Flag_Register { public: int32_t _value; bool overflow() const { return ((_value >> 11) & 1) != 0; } bool direction() const { return ((_value >> 10) & 1) != 0; } bool sign() const { return ((_value >> 7) & 1) != 0; } bool zero() const { return ((_value >> 6) & 1) != 0; } bool auxiliary_carry() const { return ((_value >> 4) & 1) != 0; } bool parity() const { return ((_value >> 2) & 1) != 0; } bool carry() const { return ((_value >> 0) & 1) != 0; } void print() const { // flags char f[8]; f[0] = (overflow ()) ? 'O' : '-'; f[1] = (direction ()) ? 'D' : '-'; f[2] = (sign ()) ? 'S' : '-'; f[3] = (zero ()) ? 'Z' : '-'; f[4] = (auxiliary_carry()) ? 'A' : '-'; f[5] = (parity ()) ? 'P' : '-'; f[6] = (carry ()) ? 'C' : '-'; f[7] = '\x0'; // output printf("%08x flags = %s", _value, f); } }; class IU_Register { public: int32_t _value; void print() const { printf("%08x %11d", _value, _value); } }; class IU_State { public: Flag_Register _eflags; IU_Register _rdi; IU_Register _rsi; IU_Register _rbp; IU_Register _rsp; IU_Register _rbx; IU_Register _rdx; IU_Register _rcx; IU_Register _rax; void print() const { // computation registers printf("rax, = "); _rax.print(); printf("\n"); printf("rbx, = "); _rbx.print(); printf("\n"); printf("rcx = "); _rcx.print(); printf("\n"); printf("rdx = "); _rdx.print(); printf("\n"); printf("rdi = "); _rdi.print(); printf("\n"); printf("rsi = "); _rsi.print(); printf("\n"); printf("rbp, = "); _rbp.print(); printf("\n"); printf("rsp = "); _rsp.print(); printf("\n"); printf("\n"); // control registers printf("flgs = "); _eflags.print(); printf("\n"); } }; class CPU_State { public: FPU_State _fpu_state; IU_State _iu_state; void print() const { printf("--------------------------------------------------\n"); _iu_state .print(); printf("\n"); _fpu_state.print(); printf("--------------------------------------------------\n"); } }; static void _print_CPU_state(CPU_State* state) { state->print(); }; void MacroAssembler::print_CPU_state() { push_CPU_state(); push(rsp); // pass CPU state call(RuntimeAddress(CAST_FROM_FN_PTR(address, _print_CPU_state))); addptr(rsp, wordSize); // discard argument pop_CPU_state(); } static bool _verify_FPU(int stack_depth, char* s, CPU_State* state) { static int counter = 0; FPU_State* fs = &state->_fpu_state; counter++; // For leaf calls, only verify that the top few elements remain empty. // We only need 1 empty at the top for C2 code. if( stack_depth < 0 ) { if( fs->tag_for_st(7) != 3 ) { printf("FPR7 not empty\n"); state->print(); assert(false, "error"); return false; } return true; // All other stack states do not matter } assert((fs->_control_word._value & 0xffff) == StubRoutines::_fpu_cntrl_wrd_std, "bad FPU control word"); // compute stack depth int i = 0; while (i < FPU_State::number_of_registers && fs->tag_for_st(i) < 3) i++; int d = i; while (i < FPU_State::number_of_registers && fs->tag_for_st(i) == 3) i++; // verify findings if (i != FPU_State::number_of_registers) { // stack not contiguous printf("%s: stack not contiguous at ST%d\n", s, i); state->print(); assert(false, "error"); return false; } // check if computed stack depth corresponds to expected stack depth if (stack_depth < 0) { // expected stack depth is -stack_depth or less if (d > -stack_depth) { // too many elements on the stack printf("%s: <= %d stack elements expected but found %d\n", s, -stack_depth, d); state->print(); assert(false, "error"); return false; } } else { // expected stack depth is stack_depth if (d != stack_depth) { // wrong stack depth printf("%s: %d stack elements expected but found %d\n", s, stack_depth, d); state->print(); assert(false, "error"); return false; } } // everything is cool return true; } void MacroAssembler::verify_FPU(int stack_depth, const char* s) { if (!VerifyFPU) return; push_CPU_state(); push(rsp); // pass CPU state ExternalAddress msg((address) s); // pass message string s pushptr(msg.addr()); push(stack_depth); // pass stack depth call(RuntimeAddress(CAST_FROM_FN_PTR(address, _verify_FPU))); addptr(rsp, 3 * wordSize); // discard arguments // check for error { Label L; testl(rax, rax); jcc(Assembler::notZero, L); int3(); // break if error condition bind(L); } pop_CPU_state(); } void MacroAssembler::restore_cpu_control_state_after_jni() { // Either restore the MXCSR register after returning from the JNI Call // or verify that it wasn't changed (with -Xcheck:jni flag). if (VM_Version::supports_sse()) { if (RestoreMXCSROnJNICalls) { ldmxcsr(ExternalAddress(StubRoutines::addr_mxcsr_std())); } else if (CheckJNICalls) { call(RuntimeAddress(StubRoutines::x86::verify_mxcsr_entry())); } } if (VM_Version::supports_avx()) { // Clear upper bits of YMM registers to avoid SSE <-> AVX transition penalty. vzeroupper(); } #ifndef _LP64 // Either restore the x87 floating pointer control word after returning // from the JNI call or verify that it wasn't changed. if (CheckJNICalls) { call(RuntimeAddress(StubRoutines::x86::verify_fpu_cntrl_wrd_entry())); } #endif // _LP64 } void MacroAssembler::load_klass(Register dst, Register src) { #ifdef _LP64 if (UseCompressedClassPointers) { movl(dst, Address(src, oopDesc::klass_offset_in_bytes())); decode_klass_not_null(dst); } else #endif movptr(dst, Address(src, oopDesc::klass_offset_in_bytes())); } void MacroAssembler::load_prototype_header(Register dst, Register src) { load_klass(dst, src); movptr(dst, Address(dst, Klass::prototype_header_offset())); } void MacroAssembler::store_klass(Register dst, Register src) { #ifdef _LP64 if (UseCompressedClassPointers) { encode_klass_not_null(src); movl(Address(dst, oopDesc::klass_offset_in_bytes()), src); } else #endif movptr(Address(dst, oopDesc::klass_offset_in_bytes()), src); } void MacroAssembler::load_heap_oop(Register dst, Address src) { #ifdef _LP64 // FIXME: Must change all places where we try to load the klass. if (UseCompressedOops) { movl(dst, src); decode_heap_oop(dst); } else #endif movptr(dst, src); } // Doesn't do verfication, generates fixed size code void MacroAssembler::load_heap_oop_not_null(Register dst, Address src) { #ifdef _LP64 if (UseCompressedOops) { movl(dst, src); decode_heap_oop_not_null(dst); } else #endif movptr(dst, src); } void MacroAssembler::store_heap_oop(Address dst, Register src) { #ifdef _LP64 if (UseCompressedOops) { assert(!dst.uses(src), "not enough registers"); encode_heap_oop(src); movl(dst, src); } else #endif movptr(dst, src); } void MacroAssembler::cmp_heap_oop(Register src1, Address src2, Register tmp) { assert_different_registers(src1, tmp); #ifdef _LP64 if (UseCompressedOops) { bool did_push = false; if (tmp == noreg) { tmp = rax; push(tmp); did_push = true; assert(!src2.uses(rsp), "can't push"); } load_heap_oop(tmp, src2); cmpptr(src1, tmp); if (did_push) pop(tmp); } else #endif cmpptr(src1, src2); } // Used for storing NULLs. void MacroAssembler::store_heap_oop_null(Address dst) { #ifdef _LP64 if (UseCompressedOops) { movl(dst, (int32_t)NULL_WORD); } else { movslq(dst, (int32_t)NULL_WORD); } #else movl(dst, (int32_t)NULL_WORD); #endif } #ifdef _LP64 void MacroAssembler::store_klass_gap(Register dst, Register src) { if (UseCompressedClassPointers) { // Store to klass gap in destination movl(Address(dst, oopDesc::klass_gap_offset_in_bytes()), src); } } #ifdef ASSERT void MacroAssembler::verify_heapbase(const char* msg) { assert (UseCompressedOops, "should be compressed"); assert (Universe::heap() != NULL, "java heap should be initialized"); if (CheckCompressedOops) { Label ok; push(rscratch1); // cmpptr trashes rscratch1 cmpptr(r12_heapbase, ExternalAddress((address)Universe::narrow_ptrs_base_addr())); jcc(Assembler::equal, ok); STOP(msg); bind(ok); pop(rscratch1); } } #endif // Algorithm must match oop.inline.hpp encode_heap_oop. void MacroAssembler::encode_heap_oop(Register r) { #ifdef ASSERT verify_heapbase("MacroAssembler::encode_heap_oop: heap base corrupted?"); #endif verify_oop(r, "broken oop in encode_heap_oop"); if (Universe::narrow_oop_base() == NULL) { if (Universe::narrow_oop_shift() != 0) { assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong"); shrq(r, LogMinObjAlignmentInBytes); } return; } testq(r, r); cmovq(Assembler::equal, r, r12_heapbase); subq(r, r12_heapbase); shrq(r, LogMinObjAlignmentInBytes); } void MacroAssembler::encode_heap_oop_not_null(Register r) { #ifdef ASSERT verify_heapbase("MacroAssembler::encode_heap_oop_not_null: heap base corrupted?"); if (CheckCompressedOops) { Label ok; testq(r, r); jcc(Assembler::notEqual, ok); STOP("null oop passed to encode_heap_oop_not_null"); bind(ok); } #endif verify_oop(r, "broken oop in encode_heap_oop_not_null"); if (Universe::narrow_oop_base() != NULL) { subq(r, r12_heapbase); } if (Universe::narrow_oop_shift() != 0) { assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong"); shrq(r, LogMinObjAlignmentInBytes); } } void MacroAssembler::encode_heap_oop_not_null(Register dst, Register src) { #ifdef ASSERT verify_heapbase("MacroAssembler::encode_heap_oop_not_null2: heap base corrupted?"); if (CheckCompressedOops) { Label ok; testq(src, src); jcc(Assembler::notEqual, ok); STOP("null oop passed to encode_heap_oop_not_null2"); bind(ok); } #endif verify_oop(src, "broken oop in encode_heap_oop_not_null2"); if (dst != src) { movq(dst, src); } if (Universe::narrow_oop_base() != NULL) { subq(dst, r12_heapbase); } if (Universe::narrow_oop_shift() != 0) { assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong"); shrq(dst, LogMinObjAlignmentInBytes); } } void MacroAssembler::decode_heap_oop(Register r) { #ifdef ASSERT verify_heapbase("MacroAssembler::decode_heap_oop: heap base corrupted?"); #endif if (Universe::narrow_oop_base() == NULL) { if (Universe::narrow_oop_shift() != 0) { assert (LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong"); shlq(r, LogMinObjAlignmentInBytes); } } else { Label done; shlq(r, LogMinObjAlignmentInBytes); jccb(Assembler::equal, done); addq(r, r12_heapbase); bind(done); } verify_oop(r, "broken oop in decode_heap_oop"); } void MacroAssembler::decode_heap_oop_not_null(Register r) { // Note: it will change flags assert (UseCompressedOops, "should only be used for compressed headers"); assert (Universe::heap() != NULL, "java heap should be initialized"); // Cannot assert, unverified entry point counts instructions (see .ad file) // vtableStubs also counts instructions in pd_code_size_limit. // Also do not verify_oop as this is called by verify_oop. if (Universe::narrow_oop_shift() != 0) { assert(LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong"); shlq(r, LogMinObjAlignmentInBytes); if (Universe::narrow_oop_base() != NULL) { addq(r, r12_heapbase); } } else { assert (Universe::narrow_oop_base() == NULL, "sanity"); } } void MacroAssembler::decode_heap_oop_not_null(Register dst, Register src) { // Note: it will change flags assert (UseCompressedOops, "should only be used for compressed headers"); assert (Universe::heap() != NULL, "java heap should be initialized"); // Cannot assert, unverified entry point counts instructions (see .ad file) // vtableStubs also counts instructions in pd_code_size_limit. // Also do not verify_oop as this is called by verify_oop. if (Universe::narrow_oop_shift() != 0) { assert(LogMinObjAlignmentInBytes == Universe::narrow_oop_shift(), "decode alg wrong"); if (LogMinObjAlignmentInBytes == Address::times_8) { leaq(dst, Address(r12_heapbase, src, Address::times_8, 0)); } else { if (dst != src) { movq(dst, src); } shlq(dst, LogMinObjAlignmentInBytes); if (Universe::narrow_oop_base() != NULL) { addq(dst, r12_heapbase); } } } else { assert (Universe::narrow_oop_base() == NULL, "sanity"); if (dst != src) { movq(dst, src); } } } void MacroAssembler::encode_klass_not_null(Register r) { if (Universe::narrow_klass_base() != NULL) { // Use r12 as a scratch register in which to temporarily load the narrow_klass_base. assert(r != r12_heapbase, "Encoding a klass in r12"); mov64(r12_heapbase, (int64_t)Universe::narrow_klass_base()); subq(r, r12_heapbase); } if (Universe::narrow_klass_shift() != 0) { assert (LogKlassAlignmentInBytes == Universe::narrow_klass_shift(), "decode alg wrong"); shrq(r, LogKlassAlignmentInBytes); } if (Universe::narrow_klass_base() != NULL) { reinit_heapbase(); } } void MacroAssembler::encode_klass_not_null(Register dst, Register src) { if (dst == src) { encode_klass_not_null(src); } else { if (Universe::narrow_klass_base() != NULL) { mov64(dst, (int64_t)Universe::narrow_klass_base()); negq(dst); addq(dst, src); } else { movptr(dst, src); } if (Universe::narrow_klass_shift() != 0) { assert (LogKlassAlignmentInBytes == Universe::narrow_klass_shift(), "decode alg wrong"); shrq(dst, LogKlassAlignmentInBytes); } } } // Function instr_size_for_decode_klass_not_null() counts the instructions // generated by decode_klass_not_null(register r) and reinit_heapbase(), // when (Universe::heap() != NULL). Hence, if the instructions they // generate change, then this method needs to be updated. int MacroAssembler::instr_size_for_decode_klass_not_null() { assert (UseCompressedClassPointers, "only for compressed klass ptrs"); if (Universe::narrow_klass_base() != NULL) { // mov64 + addq + shlq? + mov64 (for reinit_heapbase()). return (Universe::narrow_klass_shift() == 0 ? 20 : 24); } else { // longest load decode klass function, mov64, leaq return 16; } } // !!! If the instructions that get generated here change then function // instr_size_for_decode_klass_not_null() needs to get updated. void MacroAssembler::decode_klass_not_null(Register r) { // Note: it will change flags assert (UseCompressedClassPointers, "should only be used for compressed headers"); assert(r != r12_heapbase, "Decoding a klass in r12"); // Cannot assert, unverified entry point counts instructions (see .ad file) // vtableStubs also counts instructions in pd_code_size_limit. // Also do not verify_oop as this is called by verify_oop. if (Universe::narrow_klass_shift() != 0) { assert(LogKlassAlignmentInBytes == Universe::narrow_klass_shift(), "decode alg wrong"); shlq(r, LogKlassAlignmentInBytes); } // Use r12 as a scratch register in which to temporarily load the narrow_klass_base. if (Universe::narrow_klass_base() != NULL) { mov64(r12_heapbase, (int64_t)Universe::narrow_klass_base()); addq(r, r12_heapbase); reinit_heapbase(); } } void MacroAssembler::decode_klass_not_null(Register dst, Register src) { // Note: it will change flags assert (UseCompressedClassPointers, "should only be used for compressed headers"); if (dst == src) { decode_klass_not_null(dst); } else { // Cannot assert, unverified entry point counts instructions (see .ad file) // vtableStubs also counts instructions in pd_code_size_limit. // Also do not verify_oop as this is called by verify_oop. mov64(dst, (int64_t)Universe::narrow_klass_base()); if (Universe::narrow_klass_shift() != 0) { assert(LogKlassAlignmentInBytes == Universe::narrow_klass_shift(), "decode alg wrong"); assert(LogKlassAlignmentInBytes == Address::times_8, "klass not aligned on 64bits?"); leaq(dst, Address(dst, src, Address::times_8, 0)); } else { addq(dst, src); } } } void MacroAssembler::set_narrow_oop(Register dst, jobject obj) { assert (UseCompressedOops, "should only be used for compressed headers"); assert (Universe::heap() != NULL, "java heap should be initialized"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int oop_index = oop_recorder()->find_index(obj); RelocationHolder rspec = oop_Relocation::spec(oop_index); mov_narrow_oop(dst, oop_index, rspec); } void MacroAssembler::set_narrow_oop(Address dst, jobject obj) { assert (UseCompressedOops, "should only be used for compressed headers"); assert (Universe::heap() != NULL, "java heap should be initialized"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int oop_index = oop_recorder()->find_index(obj); RelocationHolder rspec = oop_Relocation::spec(oop_index); mov_narrow_oop(dst, oop_index, rspec); } void MacroAssembler::set_narrow_klass(Register dst, Klass* k) { assert (UseCompressedClassPointers, "should only be used for compressed headers"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int klass_index = oop_recorder()->find_index(k); RelocationHolder rspec = metadata_Relocation::spec(klass_index); mov_narrow_oop(dst, Klass::encode_klass(k), rspec); } void MacroAssembler::set_narrow_klass(Address dst, Klass* k) { assert (UseCompressedClassPointers, "should only be used for compressed headers"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int klass_index = oop_recorder()->find_index(k); RelocationHolder rspec = metadata_Relocation::spec(klass_index); mov_narrow_oop(dst, Klass::encode_klass(k), rspec); } void MacroAssembler::cmp_narrow_oop(Register dst, jobject obj) { assert (UseCompressedOops, "should only be used for compressed headers"); assert (Universe::heap() != NULL, "java heap should be initialized"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int oop_index = oop_recorder()->find_index(obj); RelocationHolder rspec = oop_Relocation::spec(oop_index); Assembler::cmp_narrow_oop(dst, oop_index, rspec); } void MacroAssembler::cmp_narrow_oop(Address dst, jobject obj) { assert (UseCompressedOops, "should only be used for compressed headers"); assert (Universe::heap() != NULL, "java heap should be initialized"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int oop_index = oop_recorder()->find_index(obj); RelocationHolder rspec = oop_Relocation::spec(oop_index); Assembler::cmp_narrow_oop(dst, oop_index, rspec); } void MacroAssembler::cmp_narrow_klass(Register dst, Klass* k) { assert (UseCompressedClassPointers, "should only be used for compressed headers"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int klass_index = oop_recorder()->find_index(k); RelocationHolder rspec = metadata_Relocation::spec(klass_index); Assembler::cmp_narrow_oop(dst, Klass::encode_klass(k), rspec); } void MacroAssembler::cmp_narrow_klass(Address dst, Klass* k) { assert (UseCompressedClassPointers, "should only be used for compressed headers"); assert (oop_recorder() != NULL, "this assembler needs an OopRecorder"); int klass_index = oop_recorder()->find_index(k); RelocationHolder rspec = metadata_Relocation::spec(klass_index); Assembler::cmp_narrow_oop(dst, Klass::encode_klass(k), rspec); } void MacroAssembler::reinit_heapbase() { if (UseCompressedOops || UseCompressedClassPointers) { if (Universe::heap() != NULL) { if (Universe::narrow_oop_base() == NULL) { MacroAssembler::xorptr(r12_heapbase, r12_heapbase); } else { mov64(r12_heapbase, (int64_t)Universe::narrow_ptrs_base()); } } else { movptr(r12_heapbase, ExternalAddress((address)Universe::narrow_ptrs_base_addr())); } } } #endif // _LP64 // C2 compiled method's prolog code. void MacroAssembler::verified_entry(int framesize, bool stack_bang, bool fp_mode_24b) { // WARNING: Initial instruction MUST be 5 bytes or longer so that // NativeJump::patch_verified_entry will be able to patch out the entry // code safely. The push to verify stack depth is ok at 5 bytes, // the frame allocation can be either 3 or 6 bytes. So if we don't do // stack bang then we must use the 6 byte frame allocation even if // we have no frame. :-( assert((framesize & (StackAlignmentInBytes-1)) == 0, "frame size not aligned"); // Remove word for return addr framesize -= wordSize; // Calls to C2R adapters often do not accept exceptional returns. // We require that their callers must bang for them. But be careful, because // some VM calls (such as call site linkage) can use several kilobytes of // stack. But the stack safety zone should account for that. // See bugs 4446381, 4468289, 4497237. if (stack_bang) { generate_stack_overflow_check(framesize); // We always push rbp, so that on return to interpreter rbp, will be // restored correctly and we can correct the stack. push(rbp); // Remove word for ebp framesize -= wordSize; // Create frame if (framesize) { subptr(rsp, framesize); } } else { // Create frame (force generation of a 4 byte immediate value) subptr_imm32(rsp, framesize); // Save RBP register now. framesize -= wordSize; movptr(Address(rsp, framesize), rbp); } if (VerifyStackAtCalls) { // Majik cookie to verify stack depth framesize -= wordSize; movptr(Address(rsp, framesize), (int32_t)0xbadb100d); } #ifndef _LP64 // If method sets FPU control word do it now if (fp_mode_24b) { fldcw(ExternalAddress(StubRoutines::addr_fpu_cntrl_wrd_24())); } if (UseSSE >= 2 && VerifyFPU) { verify_FPU(0, "FPU stack must be clean on entry"); } #endif #ifdef ASSERT if (VerifyStackAtCalls) { Label L; push(rax); mov(rax, rsp); andptr(rax, StackAlignmentInBytes-1); cmpptr(rax, StackAlignmentInBytes-wordSize); pop(rax); jcc(Assembler::equal, L); STOP("Stack is not properly aligned!"); bind(L); } #endif } void MacroAssembler::clear_mem(Register base, Register cnt, Register tmp) { // cnt - number of qwords (8-byte words). // base - start address, qword aligned. assert(base==rdi, "base register must be edi for rep stos"); assert(tmp==rax, "tmp register must be eax for rep stos"); assert(cnt==rcx, "cnt register must be ecx for rep stos"); xorptr(tmp, tmp); if (UseFastStosb) { shlptr(cnt,3); // convert to number of bytes rep_stosb(); } else { NOT_LP64(shlptr(cnt,1);) // convert to number of dwords for 32-bit VM rep_stos(); } } // IndexOf for constant substrings with size >= 8 chars // which don't need to be loaded through stack. void MacroAssembler::string_indexofC8(Register str1, Register str2, Register cnt1, Register cnt2, int int_cnt2, Register result, XMMRegister vec, Register tmp) { ShortBranchVerifier sbv(this); assert(UseSSE42Intrinsics, "SSE4.2 is required"); // This method uses pcmpestri inxtruction with bound registers // inputs: // xmm - substring // rax - substring length (elements count) // mem - scanned string // rdx - string length (elements count) // 0xd - mode: 1100 (substring search) + 01 (unsigned shorts) // outputs: // rcx - matched index in string assert(cnt1 == rdx && cnt2 == rax && tmp == rcx, "pcmpestri"); Label RELOAD_SUBSTR, SCAN_TO_SUBSTR, SCAN_SUBSTR, RET_FOUND, RET_NOT_FOUND, EXIT, FOUND_SUBSTR, MATCH_SUBSTR_HEAD, RELOAD_STR, FOUND_CANDIDATE; // Note, inline_string_indexOf() generates checks: // if (substr.count > string.count) return -1; // if (substr.count == 0) return 0; assert(int_cnt2 >= 8, "this code isused only for cnt2 >= 8 chars"); // Load substring. movdqu(vec, Address(str2, 0)); movl(cnt2, int_cnt2); movptr(result, str1); // string addr if (int_cnt2 > 8) { jmpb(SCAN_TO_SUBSTR); // Reload substr for rescan, this code // is executed only for large substrings (> 8 chars) bind(RELOAD_SUBSTR); movdqu(vec, Address(str2, 0)); negptr(cnt2); // Jumped here with negative cnt2, convert to positive bind(RELOAD_STR); // We came here after the beginning of the substring was // matched but the rest of it was not so we need to search // again. Start from the next element after the previous match. // cnt2 is number of substring reminding elements and // cnt1 is number of string reminding elements when cmp failed. // Restored cnt1 = cnt1 - cnt2 + int_cnt2 subl(cnt1, cnt2); addl(cnt1, int_cnt2); movl(cnt2, int_cnt2); // Now restore cnt2 decrementl(cnt1); // Shift to next element cmpl(cnt1, cnt2); jccb(Assembler::negative, RET_NOT_FOUND); // Left less then substring addptr(result, 2); } // (int_cnt2 > 8) // Scan string for start of substr in 16-byte vectors bind(SCAN_TO_SUBSTR); pcmpestri(vec, Address(result, 0), 0x0d); jccb(Assembler::below, FOUND_CANDIDATE); // CF == 1 subl(cnt1, 8); jccb(Assembler::lessEqual, RET_NOT_FOUND); // Scanned full string cmpl(cnt1, cnt2); jccb(Assembler::negative, RET_NOT_FOUND); // Left less then substring addptr(result, 16); jmpb(SCAN_TO_SUBSTR); // Found a potential substr bind(FOUND_CANDIDATE); // Matched whole vector if first element matched (tmp(rcx) == 0). if (int_cnt2 == 8) { jccb(Assembler::overflow, RET_FOUND); // OF == 1 } else { // int_cnt2 > 8 jccb(Assembler::overflow, FOUND_SUBSTR); } // After pcmpestri tmp(rcx) contains matched element index // Compute start addr of substr lea(result, Address(result, tmp, Address::times_2)); // Make sure string is still long enough subl(cnt1, tmp); cmpl(cnt1, cnt2); if (int_cnt2 == 8) { jccb(Assembler::greaterEqual, SCAN_TO_SUBSTR); } else { // int_cnt2 > 8 jccb(Assembler::greaterEqual, MATCH_SUBSTR_HEAD); } // Left less then substring. bind(RET_NOT_FOUND); movl(result, -1); jmpb(EXIT); if (int_cnt2 > 8) { // This code is optimized for the case when whole substring // is matched if its head is matched. bind(MATCH_SUBSTR_HEAD); pcmpestri(vec, Address(result, 0), 0x0d); // Reload only string if does not match jccb(Assembler::noOverflow, RELOAD_STR); // OF == 0 Label CONT_SCAN_SUBSTR; // Compare the rest of substring (> 8 chars). bind(FOUND_SUBSTR); // First 8 chars are already matched. negptr(cnt2); addptr(cnt2, 8); bind(SCAN_SUBSTR); subl(cnt1, 8); cmpl(cnt2, -8); // Do not read beyond substring jccb(Assembler::lessEqual, CONT_SCAN_SUBSTR); // Back-up strings to avoid reading beyond substring: // cnt1 = cnt1 - cnt2 + 8 addl(cnt1, cnt2); // cnt2 is negative addl(cnt1, 8); movl(cnt2, 8); negptr(cnt2); bind(CONT_SCAN_SUBSTR); if (int_cnt2 < (int)G) { movdqu(vec, Address(str2, cnt2, Address::times_2, int_cnt2*2)); pcmpestri(vec, Address(result, cnt2, Address::times_2, int_cnt2*2), 0x0d); } else { // calculate index in register to avoid integer overflow (int_cnt2*2) movl(tmp, int_cnt2); addptr(tmp, cnt2); movdqu(vec, Address(str2, tmp, Address::times_2, 0)); pcmpestri(vec, Address(result, tmp, Address::times_2, 0), 0x0d); } // Need to reload strings pointers if not matched whole vector jcc(Assembler::noOverflow, RELOAD_SUBSTR); // OF == 0 addptr(cnt2, 8); jcc(Assembler::negative, SCAN_SUBSTR); // Fall through if found full substring } // (int_cnt2 > 8) bind(RET_FOUND); // Found result if we matched full small substring. // Compute substr offset subptr(result, str1); shrl(result, 1); // index bind(EXIT); } // string_indexofC8 // Small strings are loaded through stack if they cross page boundary. void MacroAssembler::string_indexof(Register str1, Register str2, Register cnt1, Register cnt2, int int_cnt2, Register result, XMMRegister vec, Register tmp) { ShortBranchVerifier sbv(this); assert(UseSSE42Intrinsics, "SSE4.2 is required"); // // int_cnt2 is length of small (< 8 chars) constant substring // or (-1) for non constant substring in which case its length // is in cnt2 register. // // Note, inline_string_indexOf() generates checks: // if (substr.count > string.count) return -1; // if (substr.count == 0) return 0; // assert(int_cnt2 == -1 || (0 < int_cnt2 && int_cnt2 < 8), "should be != 0"); // This method uses pcmpestri inxtruction with bound registers // inputs: // xmm - substring // rax - substring length (elements count) // mem - scanned string // rdx - string length (elements count) // 0xd - mode: 1100 (substring search) + 01 (unsigned shorts) // outputs: // rcx - matched index in string assert(cnt1 == rdx && cnt2 == rax && tmp == rcx, "pcmpestri"); Label RELOAD_SUBSTR, SCAN_TO_SUBSTR, SCAN_SUBSTR, ADJUST_STR, RET_FOUND, RET_NOT_FOUND, CLEANUP, FOUND_SUBSTR, FOUND_CANDIDATE; { //======================================================== // We don't know where these strings are located // and we can't read beyond them. Load them through stack. Label BIG_STRINGS, CHECK_STR, COPY_SUBSTR, COPY_STR; movptr(tmp, rsp); // save old SP if (int_cnt2 > 0) { // small (< 8 chars) constant substring if (int_cnt2 == 1) { // One char load_unsigned_short(result, Address(str2, 0)); movdl(vec, result); // move 32 bits } else if (int_cnt2 == 2) { // Two chars movdl(vec, Address(str2, 0)); // move 32 bits } else if (int_cnt2 == 4) { // Four chars movq(vec, Address(str2, 0)); // move 64 bits } else { // cnt2 = { 3, 5, 6, 7 } // Array header size is 12 bytes in 32-bit VM // + 6 bytes for 3 chars == 18 bytes, // enough space to load vec and shift. assert(HeapWordSize*TypeArrayKlass::header_size() >= 12,"sanity"); movdqu(vec, Address(str2, (int_cnt2*2)-16)); psrldq(vec, 16-(int_cnt2*2)); } } else { // not constant substring cmpl(cnt2, 8); jccb(Assembler::aboveEqual, BIG_STRINGS); // Both strings are big enough // We can read beyond string if srt+16 does not cross page boundary // since heaps are aligned and mapped by pages. assert(os::vm_page_size() < (int)G, "default page should be small"); movl(result, str2); // We need only low 32 bits andl(result, (os::vm_page_size()-1)); cmpl(result, (os::vm_page_size()-16)); jccb(Assembler::belowEqual, CHECK_STR); // Move small strings to stack to allow load 16 bytes into vec. subptr(rsp, 16); int stk_offset = wordSize-2; push(cnt2); bind(COPY_SUBSTR); load_unsigned_short(result, Address(str2, cnt2, Address::times_2, -2)); movw(Address(rsp, cnt2, Address::times_2, stk_offset), result); decrement(cnt2); jccb(Assembler::notZero, COPY_SUBSTR); pop(cnt2); movptr(str2, rsp); // New substring address } // non constant bind(CHECK_STR); cmpl(cnt1, 8); jccb(Assembler::aboveEqual, BIG_STRINGS); // Check cross page boundary. movl(result, str1); // We need only low 32 bits andl(result, (os::vm_page_size()-1)); cmpl(result, (os::vm_page_size()-16)); jccb(Assembler::belowEqual, BIG_STRINGS); subptr(rsp, 16); int stk_offset = -2; if (int_cnt2 < 0) { // not constant push(cnt2); stk_offset += wordSize; } movl(cnt2, cnt1); bind(COPY_STR); load_unsigned_short(result, Address(str1, cnt2, Address::times_2, -2)); movw(Address(rsp, cnt2, Address::times_2, stk_offset), result); decrement(cnt2); jccb(Assembler::notZero, COPY_STR); if (int_cnt2 < 0) { // not constant pop(cnt2); } movptr(str1, rsp); // New string address bind(BIG_STRINGS); // Load substring. if (int_cnt2 < 0) { // -1 movdqu(vec, Address(str2, 0)); push(cnt2); // substr count push(str2); // substr addr push(str1); // string addr } else { // Small (< 8 chars) constant substrings are loaded already. movl(cnt2, int_cnt2); } push(tmp); // original SP } // Finished loading //======================================================== // Start search // movptr(result, str1); // string addr if (int_cnt2 < 0) { // Only for non constant substring jmpb(SCAN_TO_SUBSTR); // SP saved at sp+0 // String saved at sp+1*wordSize // Substr saved at sp+2*wordSize // Substr count saved at sp+3*wordSize // Reload substr for rescan, this code // is executed only for large substrings (> 8 chars) bind(RELOAD_SUBSTR); movptr(str2, Address(rsp, 2*wordSize)); movl(cnt2, Address(rsp, 3*wordSize)); movdqu(vec, Address(str2, 0)); // We came here after the beginning of the substring was // matched but the rest of it was not so we need to search // again. Start from the next element after the previous match. subptr(str1, result); // Restore counter shrl(str1, 1); addl(cnt1, str1); decrementl(cnt1); // Shift to next element cmpl(cnt1, cnt2); jccb(Assembler::negative, RET_NOT_FOUND); // Left less then substring addptr(result, 2); } // non constant // Scan string for start of substr in 16-byte vectors bind(SCAN_TO_SUBSTR); assert(cnt1 == rdx && cnt2 == rax && tmp == rcx, "pcmpestri"); pcmpestri(vec, Address(result, 0), 0x0d); jccb(Assembler::below, FOUND_CANDIDATE); // CF == 1 subl(cnt1, 8); jccb(Assembler::lessEqual, RET_NOT_FOUND); // Scanned full string cmpl(cnt1, cnt2); jccb(Assembler::negative, RET_NOT_FOUND); // Left less then substring addptr(result, 16); bind(ADJUST_STR); cmpl(cnt1, 8); // Do not read beyond string jccb(Assembler::greaterEqual, SCAN_TO_SUBSTR); // Back-up string to avoid reading beyond string. lea(result, Address(result, cnt1, Address::times_2, -16)); movl(cnt1, 8); jmpb(SCAN_TO_SUBSTR); // Found a potential substr bind(FOUND_CANDIDATE); // After pcmpestri tmp(rcx) contains matched element index // Make sure string is still long enough subl(cnt1, tmp); cmpl(cnt1, cnt2); jccb(Assembler::greaterEqual, FOUND_SUBSTR); // Left less then substring. bind(RET_NOT_FOUND); movl(result, -1); jmpb(CLEANUP); bind(FOUND_SUBSTR); // Compute start addr of substr lea(result, Address(result, tmp, Address::times_2)); if (int_cnt2 > 0) { // Constant substring // Repeat search for small substring (< 8 chars) // from new point without reloading substring. // Have to check that we don't read beyond string. cmpl(tmp, 8-int_cnt2); jccb(Assembler::greater, ADJUST_STR); // Fall through if matched whole substring. } else { // non constant assert(int_cnt2 == -1, "should be != 0"); addl(tmp, cnt2); // Found result if we matched whole substring. cmpl(tmp, 8); jccb(Assembler::lessEqual, RET_FOUND); // Repeat search for small substring (<= 8 chars) // from new point 'str1' without reloading substring. cmpl(cnt2, 8); // Have to check that we don't read beyond string. jccb(Assembler::lessEqual, ADJUST_STR); Label CHECK_NEXT, CONT_SCAN_SUBSTR, RET_FOUND_LONG; // Compare the rest of substring (> 8 chars). movptr(str1, result); cmpl(tmp, cnt2); // First 8 chars are already matched. jccb(Assembler::equal, CHECK_NEXT); bind(SCAN_SUBSTR); pcmpestri(vec, Address(str1, 0), 0x0d); // Need to reload strings pointers if not matched whole vector jcc(Assembler::noOverflow, RELOAD_SUBSTR); // OF == 0 bind(CHECK_NEXT); subl(cnt2, 8); jccb(Assembler::lessEqual, RET_FOUND_LONG); // Found full substring addptr(str1, 16); addptr(str2, 16); subl(cnt1, 8); cmpl(cnt2, 8); // Do not read beyond substring jccb(Assembler::greaterEqual, CONT_SCAN_SUBSTR); // Back-up strings to avoid reading beyond substring. lea(str2, Address(str2, cnt2, Address::times_2, -16)); lea(str1, Address(str1, cnt2, Address::times_2, -16)); subl(cnt1, cnt2); movl(cnt2, 8); addl(cnt1, 8); bind(CONT_SCAN_SUBSTR); movdqu(vec, Address(str2, 0)); jmpb(SCAN_SUBSTR); bind(RET_FOUND_LONG); movptr(str1, Address(rsp, wordSize)); } // non constant bind(RET_FOUND); // Compute substr offset subptr(result, str1); shrl(result, 1); // index bind(CLEANUP); pop(rsp); // restore SP } // string_indexof // Compare strings. void MacroAssembler::string_compare(Register str1, Register str2, Register cnt1, Register cnt2, Register result, XMMRegister vec1) { ShortBranchVerifier sbv(this); Label LENGTH_DIFF_LABEL, POP_LABEL, DONE_LABEL, WHILE_HEAD_LABEL; // Compute the minimum of the string lengths and the // difference of the string lengths (stack). // Do the conditional move stuff movl(result, cnt1); subl(cnt1, cnt2); push(cnt1); cmov32(Assembler::lessEqual, cnt2, result); // Is the minimum length zero? testl(cnt2, cnt2); jcc(Assembler::zero, LENGTH_DIFF_LABEL); // Compare first characters load_unsigned_short(result, Address(str1, 0)); load_unsigned_short(cnt1, Address(str2, 0)); subl(result, cnt1); jcc(Assembler::notZero, POP_LABEL); cmpl(cnt2, 1); jcc(Assembler::equal, LENGTH_DIFF_LABEL); // Check if the strings start at the same location. cmpptr(str1, str2); jcc(Assembler::equal, LENGTH_DIFF_LABEL); Address::ScaleFactor scale = Address::times_2; int stride = 8; if (UseAVX >= 2 && UseSSE42Intrinsics) { Label COMPARE_WIDE_VECTORS, VECTOR_NOT_EQUAL, COMPARE_WIDE_TAIL, COMPARE_SMALL_STR; Label COMPARE_WIDE_VECTORS_LOOP, COMPARE_16_CHARS, COMPARE_INDEX_CHAR; Label COMPARE_TAIL_LONG; int pcmpmask = 0x19; // Setup to compare 16-chars (32-bytes) vectors, // start from first character again because it has aligned address. int stride2 = 16; int adr_stride = stride << scale; int adr_stride2 = stride2 << scale; assert(result == rax && cnt2 == rdx && cnt1 == rcx, "pcmpestri"); // rax and rdx are used by pcmpestri as elements counters movl(result, cnt2); andl(cnt2, ~(stride2-1)); // cnt2 holds the vector count jcc(Assembler::zero, COMPARE_TAIL_LONG); // fast path : compare first 2 8-char vectors. bind(COMPARE_16_CHARS); movdqu(vec1, Address(str1, 0)); pcmpestri(vec1, Address(str2, 0), pcmpmask); jccb(Assembler::below, COMPARE_INDEX_CHAR); movdqu(vec1, Address(str1, adr_stride)); pcmpestri(vec1, Address(str2, adr_stride), pcmpmask); jccb(Assembler::aboveEqual, COMPARE_WIDE_VECTORS); addl(cnt1, stride); // Compare the characters at index in cnt1 bind(COMPARE_INDEX_CHAR); //cnt1 has the offset of the mismatching character load_unsigned_short(result, Address(str1, cnt1, scale)); load_unsigned_short(cnt2, Address(str2, cnt1, scale)); subl(result, cnt2); jmp(POP_LABEL); // Setup the registers to start vector comparison loop bind(COMPARE_WIDE_VECTORS); lea(str1, Address(str1, result, scale)); lea(str2, Address(str2, result, scale)); subl(result, stride2); subl(cnt2, stride2); jccb(Assembler::zero, COMPARE_WIDE_TAIL); negptr(result); // In a loop, compare 16-chars (32-bytes) at once using (vpxor+vptest) bind(COMPARE_WIDE_VECTORS_LOOP); vmovdqu(vec1, Address(str1, result, scale)); vpxor(vec1, Address(str2, result, scale)); vptest(vec1, vec1); jccb(Assembler::notZero, VECTOR_NOT_EQUAL); addptr(result, stride2); subl(cnt2, stride2); jccb(Assembler::notZero, COMPARE_WIDE_VECTORS_LOOP); // clean upper bits of YMM registers vzeroupper(); // compare wide vectors tail bind(COMPARE_WIDE_TAIL); testptr(result, result); jccb(Assembler::zero, LENGTH_DIFF_LABEL); movl(result, stride2); movl(cnt2, result); negptr(result); jmpb(COMPARE_WIDE_VECTORS_LOOP); // Identifies the mismatching (higher or lower)16-bytes in the 32-byte vectors. bind(VECTOR_NOT_EQUAL); // clean upper bits of YMM registers vzeroupper(); lea(str1, Address(str1, result, scale)); lea(str2, Address(str2, result, scale)); jmp(COMPARE_16_CHARS); // Compare tail chars, length between 1 to 15 chars bind(COMPARE_TAIL_LONG); movl(cnt2, result); cmpl(cnt2, stride); jccb(Assembler::less, COMPARE_SMALL_STR); movdqu(vec1, Address(str1, 0)); pcmpestri(vec1, Address(str2, 0), pcmpmask); jcc(Assembler::below, COMPARE_INDEX_CHAR); subptr(cnt2, stride); jccb(Assembler::zero, LENGTH_DIFF_LABEL); lea(str1, Address(str1, result, scale)); lea(str2, Address(str2, result, scale)); negptr(cnt2); jmpb(WHILE_HEAD_LABEL); bind(COMPARE_SMALL_STR); } else if (UseSSE42Intrinsics) { Label COMPARE_WIDE_VECTORS, VECTOR_NOT_EQUAL, COMPARE_TAIL; int pcmpmask = 0x19; // Setup to compare 8-char (16-byte) vectors, // start from first character again because it has aligned address. movl(result, cnt2); andl(cnt2, ~(stride - 1)); // cnt2 holds the vector count jccb(Assembler::zero, COMPARE_TAIL); lea(str1, Address(str1, result, scale)); lea(str2, Address(str2, result, scale)); negptr(result); // pcmpestri // inputs: // vec1- substring // rax - negative string length (elements count) // mem - scaned string // rdx - string length (elements count) // pcmpmask - cmp mode: 11000 (string compare with negated result) // + 00 (unsigned bytes) or + 01 (unsigned shorts) // outputs: // rcx - first mismatched element index assert(result == rax && cnt2 == rdx && cnt1 == rcx, "pcmpestri"); bind(COMPARE_WIDE_VECTORS); movdqu(vec1, Address(str1, result, scale)); pcmpestri(vec1, Address(str2, result, scale), pcmpmask); // After pcmpestri cnt1(rcx) contains mismatched element index jccb(Assembler::below, VECTOR_NOT_EQUAL); // CF==1 addptr(result, stride); subptr(cnt2, stride); jccb(Assembler::notZero, COMPARE_WIDE_VECTORS); // compare wide vectors tail testptr(result, result); jccb(Assembler::zero, LENGTH_DIFF_LABEL); movl(cnt2, stride); movl(result, stride); negptr(result); movdqu(vec1, Address(str1, result, scale)); pcmpestri(vec1, Address(str2, result, scale), pcmpmask); jccb(Assembler::aboveEqual, LENGTH_DIFF_LABEL); // Mismatched characters in the vectors bind(VECTOR_NOT_EQUAL); addptr(cnt1, result); load_unsigned_short(result, Address(str1, cnt1, scale)); load_unsigned_short(cnt2, Address(str2, cnt1, scale)); subl(result, cnt2); jmpb(POP_LABEL); bind(COMPARE_TAIL); // limit is zero movl(cnt2, result); // Fallthru to tail compare } // Shift str2 and str1 to the end of the arrays, negate min lea(str1, Address(str1, cnt2, scale)); lea(str2, Address(str2, cnt2, scale)); decrementl(cnt2); // first character was compared already negptr(cnt2); // Compare the rest of the elements bind(WHILE_HEAD_LABEL); load_unsigned_short(result, Address(str1, cnt2, scale, 0)); load_unsigned_short(cnt1, Address(str2, cnt2, scale, 0)); subl(result, cnt1); jccb(Assembler::notZero, POP_LABEL); increment(cnt2); jccb(Assembler::notZero, WHILE_HEAD_LABEL); // Strings are equal up to min length. Return the length difference. bind(LENGTH_DIFF_LABEL); pop(result); jmpb(DONE_LABEL); // Discard the stored length difference bind(POP_LABEL); pop(cnt1); // That's it bind(DONE_LABEL); } // Compare char[] arrays aligned to 4 bytes or substrings. void MacroAssembler::char_arrays_equals(bool is_array_equ, Register ary1, Register ary2, Register limit, Register result, Register chr, XMMRegister vec1, XMMRegister vec2) { ShortBranchVerifier sbv(this); Label TRUE_LABEL, FALSE_LABEL, DONE, COMPARE_VECTORS, COMPARE_CHAR; int length_offset = arrayOopDesc::length_offset_in_bytes(); int base_offset = arrayOopDesc::base_offset_in_bytes(T_CHAR); // Check the input args cmpptr(ary1, ary2); jcc(Assembler::equal, TRUE_LABEL); if (is_array_equ) { // Need additional checks for arrays_equals. testptr(ary1, ary1); jcc(Assembler::zero, FALSE_LABEL); testptr(ary2, ary2); jcc(Assembler::zero, FALSE_LABEL); // Check the lengths movl(limit, Address(ary1, length_offset)); cmpl(limit, Address(ary2, length_offset)); jcc(Assembler::notEqual, FALSE_LABEL); } // count == 0 testl(limit, limit); jcc(Assembler::zero, TRUE_LABEL); if (is_array_equ) { // Load array address lea(ary1, Address(ary1, base_offset)); lea(ary2, Address(ary2, base_offset)); } shll(limit, 1); // byte count != 0 movl(result, limit); // copy if (UseAVX >= 2) { // With AVX2, use 32-byte vector compare Label COMPARE_WIDE_VECTORS, COMPARE_TAIL; // Compare 32-byte vectors andl(result, 0x0000001e); // tail count (in bytes) andl(limit, 0xffffffe0); // vector count (in bytes) jccb(Assembler::zero, COMPARE_TAIL); lea(ary1, Address(ary1, limit, Address::times_1)); lea(ary2, Address(ary2, limit, Address::times_1)); negptr(limit); bind(COMPARE_WIDE_VECTORS); vmovdqu(vec1, Address(ary1, limit, Address::times_1)); vmovdqu(vec2, Address(ary2, limit, Address::times_1)); vpxor(vec1, vec2); vptest(vec1, vec1); jccb(Assembler::notZero, FALSE_LABEL); addptr(limit, 32); jcc(Assembler::notZero, COMPARE_WIDE_VECTORS); testl(result, result); jccb(Assembler::zero, TRUE_LABEL); vmovdqu(vec1, Address(ary1, result, Address::times_1, -32)); vmovdqu(vec2, Address(ary2, result, Address::times_1, -32)); vpxor(vec1, vec2); vptest(vec1, vec1); jccb(Assembler::notZero, FALSE_LABEL); jmpb(TRUE_LABEL); bind(COMPARE_TAIL); // limit is zero movl(limit, result); // Fallthru to tail compare } else if (UseSSE42Intrinsics) { // With SSE4.2, use double quad vector compare Label COMPARE_WIDE_VECTORS, COMPARE_TAIL; // Compare 16-byte vectors andl(result, 0x0000000e); // tail count (in bytes) andl(limit, 0xfffffff0); // vector count (in bytes) jccb(Assembler::zero, COMPARE_TAIL); lea(ary1, Address(ary1, limit, Address::times_1)); lea(ary2, Address(ary2, limit, Address::times_1)); negptr(limit); bind(COMPARE_WIDE_VECTORS); movdqu(vec1, Address(ary1, limit, Address::times_1)); movdqu(vec2, Address(ary2, limit, Address::times_1)); pxor(vec1, vec2); ptest(vec1, vec1); jccb(Assembler::notZero, FALSE_LABEL); addptr(limit, 16); jcc(Assembler::notZero, COMPARE_WIDE_VECTORS); testl(result, result); jccb(Assembler::zero, TRUE_LABEL); movdqu(vec1, Address(ary1, result, Address::times_1, -16)); movdqu(vec2, Address(ary2, result, Address::times_1, -16)); pxor(vec1, vec2); ptest(vec1, vec1); jccb(Assembler::notZero, FALSE_LABEL); jmpb(TRUE_LABEL); bind(COMPARE_TAIL); // limit is zero movl(limit, result); // Fallthru to tail compare } // Compare 4-byte vectors andl(limit, 0xfffffffc); // vector count (in bytes) jccb(Assembler::zero, COMPARE_CHAR); lea(ary1, Address(ary1, limit, Address::times_1)); lea(ary2, Address(ary2, limit, Address::times_1)); negptr(limit); bind(COMPARE_VECTORS); movl(chr, Address(ary1, limit, Address::times_1)); cmpl(chr, Address(ary2, limit, Address::times_1)); jccb(Assembler::notEqual, FALSE_LABEL); addptr(limit, 4); jcc(Assembler::notZero, COMPARE_VECTORS); // Compare trailing char (final 2 bytes), if any bind(COMPARE_CHAR); testl(result, 0x2); // tail char jccb(Assembler::zero, TRUE_LABEL); load_unsigned_short(chr, Address(ary1, 0)); load_unsigned_short(limit, Address(ary2, 0)); cmpl(chr, limit); jccb(Assembler::notEqual, FALSE_LABEL); bind(TRUE_LABEL); movl(result, 1); // return true jmpb(DONE); bind(FALSE_LABEL); xorl(result, result); // return false // That's it bind(DONE); if (UseAVX >= 2) { // clean upper bits of YMM registers vzeroupper(); } } void MacroAssembler::generate_fill(BasicType t, bool aligned, Register to, Register value, Register count, Register rtmp, XMMRegister xtmp) { ShortBranchVerifier sbv(this); assert_different_registers(to, value, count, rtmp); Label L_exit, L_skip_align1, L_skip_align2, L_fill_byte; Label L_fill_2_bytes, L_fill_4_bytes; int shift = -1; switch (t) { case T_BYTE: shift = 2; break; case T_SHORT: shift = 1; break; case T_INT: shift = 0; break; default: ShouldNotReachHere(); } if (t == T_BYTE) { andl(value, 0xff); movl(rtmp, value); shll(rtmp, 8); orl(value, rtmp); } if (t == T_SHORT) { andl(value, 0xffff); } if (t == T_BYTE || t == T_SHORT) { movl(rtmp, value); shll(rtmp, 16); orl(value, rtmp); } cmpl(count, 2<= 2, "supported cpu only" ); Label L_fill_32_bytes_loop, L_check_fill_8_bytes, L_fill_8_bytes_loop, L_fill_8_bytes; movdl(xtmp, value); if (UseAVX >= 2 && UseUnalignedLoadStores) { // Fill 64-byte chunks Label L_fill_64_bytes_loop, L_check_fill_32_bytes; vpbroadcastd(xtmp, xtmp); subl(count, 16 << shift); jcc(Assembler::less, L_check_fill_32_bytes); align(16); BIND(L_fill_64_bytes_loop); vmovdqu(Address(to, 0), xtmp); vmovdqu(Address(to, 32), xtmp); addptr(to, 64); subl(count, 16 << shift); jcc(Assembler::greaterEqual, L_fill_64_bytes_loop); BIND(L_check_fill_32_bytes); addl(count, 8 << shift); jccb(Assembler::less, L_check_fill_8_bytes); vmovdqu(Address(to, 0), xtmp); addptr(to, 32); subl(count, 8 << shift); BIND(L_check_fill_8_bytes); // clean upper bits of YMM registers vzeroupper(); } else { // Fill 32-byte chunks pshufd(xtmp, xtmp, 0); subl(count, 8 << shift); jcc(Assembler::less, L_check_fill_8_bytes); align(16); BIND(L_fill_32_bytes_loop); if (UseUnalignedLoadStores) { movdqu(Address(to, 0), xtmp); movdqu(Address(to, 16), xtmp); } else { movq(Address(to, 0), xtmp); movq(Address(to, 8), xtmp); movq(Address(to, 16), xtmp); movq(Address(to, 24), xtmp); } addptr(to, 32); subl(count, 8 << shift); jcc(Assembler::greaterEqual, L_fill_32_bytes_loop); BIND(L_check_fill_8_bytes); } addl(count, 8 << shift); jccb(Assembler::zero, L_exit); jmpb(L_fill_8_bytes); // // length is too short, just fill qwords // BIND(L_fill_8_bytes_loop); movq(Address(to, 0), xtmp); addptr(to, 8); BIND(L_fill_8_bytes); subl(count, 1 << (shift + 1)); jcc(Assembler::greaterEqual, L_fill_8_bytes_loop); } } // fill trailing 4 bytes BIND(L_fill_4_bytes); testl(count, 1<= 2) { Label L_chars_8_check, L_copy_8_chars, L_copy_8_chars_exit; Label L_chars_16_check, L_copy_16_chars, L_copy_16_chars_exit; if (UseAVX >= 2) { Label L_chars_32_check, L_copy_32_chars, L_copy_32_chars_exit; movl(tmp5, 0xff00ff00); // create mask to test for Unicode chars in vector movdl(tmp1Reg, tmp5); vpbroadcastd(tmp1Reg, tmp1Reg); jmpb(L_chars_32_check); bind(L_copy_32_chars); vmovdqu(tmp3Reg, Address(src, len, Address::times_2, -64)); vmovdqu(tmp4Reg, Address(src, len, Address::times_2, -32)); vpor(tmp2Reg, tmp3Reg, tmp4Reg, /* vector256 */ true); vptest(tmp2Reg, tmp1Reg); // check for Unicode chars in vector jccb(Assembler::notZero, L_copy_32_chars_exit); vpackuswb(tmp3Reg, tmp3Reg, tmp4Reg, /* vector256 */ true); vpermq(tmp4Reg, tmp3Reg, 0xD8, /* vector256 */ true); vmovdqu(Address(dst, len, Address::times_1, -32), tmp4Reg); bind(L_chars_32_check); addptr(len, 32); jccb(Assembler::lessEqual, L_copy_32_chars); bind(L_copy_32_chars_exit); subptr(len, 16); jccb(Assembler::greater, L_copy_16_chars_exit); } else if (UseSSE42Intrinsics) { movl(tmp5, 0xff00ff00); // create mask to test for Unicode chars in vector movdl(tmp1Reg, tmp5); pshufd(tmp1Reg, tmp1Reg, 0); jmpb(L_chars_16_check); } bind(L_copy_16_chars); if (UseAVX >= 2) { vmovdqu(tmp2Reg, Address(src, len, Address::times_2, -32)); vptest(tmp2Reg, tmp1Reg); jccb(Assembler::notZero, L_copy_16_chars_exit); vpackuswb(tmp2Reg, tmp2Reg, tmp1Reg, /* vector256 */ true); vpermq(tmp3Reg, tmp2Reg, 0xD8, /* vector256 */ true); } else { if (UseAVX > 0) { movdqu(tmp3Reg, Address(src, len, Address::times_2, -32)); movdqu(tmp4Reg, Address(src, len, Address::times_2, -16)); vpor(tmp2Reg, tmp3Reg, tmp4Reg, /* vector256 */ false); } else { movdqu(tmp3Reg, Address(src, len, Address::times_2, -32)); por(tmp2Reg, tmp3Reg); movdqu(tmp4Reg, Address(src, len, Address::times_2, -16)); por(tmp2Reg, tmp4Reg); } ptest(tmp2Reg, tmp1Reg); // check for Unicode chars in vector jccb(Assembler::notZero, L_copy_16_chars_exit); packuswb(tmp3Reg, tmp4Reg); } movdqu(Address(dst, len, Address::times_1, -16), tmp3Reg); bind(L_chars_16_check); addptr(len, 16); jccb(Assembler::lessEqual, L_copy_16_chars); bind(L_copy_16_chars_exit); if (UseAVX >= 2) { // clean upper bits of YMM registers vzeroupper(); } subptr(len, 8); jccb(Assembler::greater, L_copy_8_chars_exit); bind(L_copy_8_chars); movdqu(tmp3Reg, Address(src, len, Address::times_2, -16)); ptest(tmp3Reg, tmp1Reg); jccb(Assembler::notZero, L_copy_8_chars_exit); packuswb(tmp3Reg, tmp1Reg); movq(Address(dst, len, Address::times_1, -8), tmp3Reg); addptr(len, 8); jccb(Assembler::lessEqual, L_copy_8_chars); bind(L_copy_8_chars_exit); subptr(len, 8); jccb(Assembler::zero, L_done); } bind(L_copy_1_char); load_unsigned_short(tmp5, Address(src, len, Address::times_2, 0)); testl(tmp5, 0xff00); // check if Unicode char jccb(Assembler::notZero, L_copy_1_char_exit); movb(Address(dst, len, Address::times_1, 0), tmp5); addptr(len, 1); jccb(Assembler::less, L_copy_1_char); bind(L_copy_1_char_exit); addptr(result, len); // len is negative count of not processed elements bind(L_done); } /** * Emits code to update CRC-32 with a byte value according to constants in table * * @param [in,out]crc Register containing the crc. * @param [in]val Register containing the byte to fold into the CRC. * @param [in]table Register containing the table of crc constants. * * uint32_t crc; * val = crc_table[(val ^ crc) & 0xFF]; * crc = val ^ (crc >> 8); * */ void MacroAssembler::update_byte_crc32(Register crc, Register val, Register table) { xorl(val, crc); andl(val, 0xFF); shrl(crc, 8); // unsigned shift xorl(crc, Address(table, val, Address::times_4, 0)); } /** * Fold 128-bit data chunk */ void MacroAssembler::fold_128bit_crc32(XMMRegister xcrc, XMMRegister xK, XMMRegister xtmp, Register buf, int offset) { vpclmulhdq(xtmp, xK, xcrc); // [123:64] vpclmulldq(xcrc, xK, xcrc); // [63:0] vpxor(xcrc, xcrc, Address(buf, offset), false /* vector256 */); pxor(xcrc, xtmp); } void MacroAssembler::fold_128bit_crc32(XMMRegister xcrc, XMMRegister xK, XMMRegister xtmp, XMMRegister xbuf) { vpclmulhdq(xtmp, xK, xcrc); vpclmulldq(xcrc, xK, xcrc); pxor(xcrc, xbuf); pxor(xcrc, xtmp); } /** * 8-bit folds to compute 32-bit CRC * * uint64_t xcrc; * timesXtoThe32[xcrc & 0xFF] ^ (xcrc >> 8); */ void MacroAssembler::fold_8bit_crc32(XMMRegister xcrc, Register table, XMMRegister xtmp, Register tmp) { movdl(tmp, xcrc); andl(tmp, 0xFF); movdl(xtmp, Address(table, tmp, Address::times_4, 0)); psrldq(xcrc, 1); // unsigned shift one byte pxor(xcrc, xtmp); } /** * uint32_t crc; * timesXtoThe32[crc & 0xFF] ^ (crc >> 8); */ void MacroAssembler::fold_8bit_crc32(Register crc, Register table, Register tmp) { movl(tmp, crc); andl(tmp, 0xFF); shrl(crc, 8); xorl(crc, Address(table, tmp, Address::times_4, 0)); } /** * @param crc register containing existing CRC (32-bit) * @param buf register pointing to input byte buffer (byte*) * @param len register containing number of bytes * @param table register that will contain address of CRC table * @param tmp scratch register */ void MacroAssembler::kernel_crc32(Register crc, Register buf, Register len, Register table, Register tmp) { assert_different_registers(crc, buf, len, table, tmp, rax); Label L_tail, L_tail_restore, L_tail_loop, L_exit, L_align_loop, L_aligned; Label L_fold_tail, L_fold_128b, L_fold_512b, L_fold_512b_loop, L_fold_tail_loop; lea(table, ExternalAddress(StubRoutines::crc_table_addr())); notl(crc); // ~crc cmpl(len, 16); jcc(Assembler::less, L_tail); // Align buffer to 16 bytes movl(tmp, buf); andl(tmp, 0xF); jccb(Assembler::zero, L_aligned); subl(tmp, 16); addl(len, tmp); align(4); BIND(L_align_loop); movsbl(rax, Address(buf, 0)); // load byte with sign extension update_byte_crc32(crc, rax, table); increment(buf); incrementl(tmp); jccb(Assembler::less, L_align_loop); BIND(L_aligned); movl(tmp, len); // save shrl(len, 4); jcc(Assembler::zero, L_tail_restore); // Fold crc into first bytes of vector movdqa(xmm1, Address(buf, 0)); movdl(rax, xmm1); xorl(crc, rax); pinsrd(xmm1, crc, 0); addptr(buf, 16); subl(len, 4); // len > 0 jcc(Assembler::less, L_fold_tail); movdqa(xmm2, Address(buf, 0)); movdqa(xmm3, Address(buf, 16)); movdqa(xmm4, Address(buf, 32)); addptr(buf, 48); subl(len, 3); jcc(Assembler::lessEqual, L_fold_512b); // Fold total 512 bits of polynomial on each iteration, // 128 bits per each of 4 parallel streams. movdqu(xmm0, ExternalAddress(StubRoutines::x86::crc_by128_masks_addr() + 32)); align(32); BIND(L_fold_512b_loop); fold_128bit_crc32(xmm1, xmm0, xmm5, buf, 0); fold_128bit_crc32(xmm2, xmm0, xmm5, buf, 16); fold_128bit_crc32(xmm3, xmm0, xmm5, buf, 32); fold_128bit_crc32(xmm4, xmm0, xmm5, buf, 48); addptr(buf, 64); subl(len, 4); jcc(Assembler::greater, L_fold_512b_loop); // Fold 512 bits to 128 bits. BIND(L_fold_512b); movdqu(xmm0, ExternalAddress(StubRoutines::x86::crc_by128_masks_addr() + 16)); fold_128bit_crc32(xmm1, xmm0, xmm5, xmm2); fold_128bit_crc32(xmm1, xmm0, xmm5, xmm3); fold_128bit_crc32(xmm1, xmm0, xmm5, xmm4); // Fold the rest of 128 bits data chunks BIND(L_fold_tail); addl(len, 3); jccb(Assembler::lessEqual, L_fold_128b); movdqu(xmm0, ExternalAddress(StubRoutines::x86::crc_by128_masks_addr() + 16)); BIND(L_fold_tail_loop); fold_128bit_crc32(xmm1, xmm0, xmm5, buf, 0); addptr(buf, 16); decrementl(len); jccb(Assembler::greater, L_fold_tail_loop); // Fold 128 bits in xmm1 down into 32 bits in crc register. BIND(L_fold_128b); movdqu(xmm0, ExternalAddress(StubRoutines::x86::crc_by128_masks_addr())); vpclmulqdq(xmm2, xmm0, xmm1, 0x1); vpand(xmm3, xmm0, xmm2, false /* vector256 */); vpclmulqdq(xmm0, xmm0, xmm3, 0x1); psrldq(xmm1, 8); psrldq(xmm2, 4); pxor(xmm0, xmm1); pxor(xmm0, xmm2); // 8 8-bit folds to compute 32-bit CRC. for (int j = 0; j < 4; j++) { fold_8bit_crc32(xmm0, table, xmm1, rax); } movdl(crc, xmm0); // mov 32 bits to general register for (int j = 0; j < 4; j++) { fold_8bit_crc32(crc, table, rax); } BIND(L_tail_restore); movl(len, tmp); // restore BIND(L_tail); andl(len, 0xf); jccb(Assembler::zero, L_exit); // Fold the rest of bytes align(4); BIND(L_tail_loop); movsbl(rax, Address(buf, 0)); // load byte with sign extension update_byte_crc32(crc, rax, table); increment(buf); decrementl(len); jccb(Assembler::greater, L_tail_loop); BIND(L_exit); notl(crc); // ~c } #undef BIND #undef BLOCK_COMMENT Assembler::Condition MacroAssembler::negate_condition(Assembler::Condition cond) { switch (cond) { // Note some conditions are synonyms for others case Assembler::zero: return Assembler::notZero; case Assembler::notZero: return Assembler::zero; case Assembler::less: return Assembler::greaterEqual; case Assembler::lessEqual: return Assembler::greater; case Assembler::greater: return Assembler::lessEqual; case Assembler::greaterEqual: return Assembler::less; case Assembler::below: return Assembler::aboveEqual; case Assembler::belowEqual: return Assembler::above; case Assembler::above: return Assembler::belowEqual; case Assembler::aboveEqual: return Assembler::below; case Assembler::overflow: return Assembler::noOverflow; case Assembler::noOverflow: return Assembler::overflow; case Assembler::negative: return Assembler::positive; case Assembler::positive: return Assembler::negative; case Assembler::parity: return Assembler::noParity; case Assembler::noParity: return Assembler::parity; } ShouldNotReachHere(); return Assembler::overflow; } SkipIfEqual::SkipIfEqual( MacroAssembler* masm, const bool* flag_addr, bool value) { _masm = masm; _masm->cmp8(ExternalAddress((address)flag_addr), value); _masm->jcc(Assembler::equal, _label); } SkipIfEqual::~SkipIfEqual() { _masm->bind(_label); }