42065
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/*
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* Copyright (c) 2016, Oracle and/or its affiliates. All rights reserved.
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* Copyright (c) 2016 SAP SE. All rights reserved.
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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*
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* This code is free software; you can redistribute it and/or modify it
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* under the terms of the GNU General Public License version 2 only, as
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* published by the Free Software Foundation.
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*
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* This code is distributed in the hope that it will be useful, but WITHOUT
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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* version 2 for more details (a copy is included in the LICENSE file that
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* accompanied this code).
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*
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* You should have received a copy of the GNU General Public License version
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* 2 along with this work; if not, write to the Free Software Foundation,
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* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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*
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* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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* or visit www.oracle.com if you need additional information or have any
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* questions.
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*
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*/
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#include "precompiled.hpp"
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#include "asm/codeBuffer.hpp"
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#include "asm/macroAssembler.inline.hpp"
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#include "compiler/disassembler.hpp"
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#include "gc/shared/collectedHeap.inline.hpp"
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#include "interpreter/interpreter.hpp"
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#include "gc/shared/cardTableModRefBS.hpp"
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#include "memory/resourceArea.hpp"
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#include "memory/universe.hpp"
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#include "oops/klass.inline.hpp"
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#include "opto/compile.hpp"
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#include "opto/intrinsicnode.hpp"
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#include "opto/matcher.hpp"
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#include "prims/methodHandles.hpp"
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#include "registerSaver_s390.hpp"
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#include "runtime/biasedLocking.hpp"
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#include "runtime/icache.hpp"
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#include "runtime/interfaceSupport.hpp"
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#include "runtime/objectMonitor.hpp"
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#include "runtime/os.hpp"
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#include "runtime/sharedRuntime.hpp"
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#include "runtime/stubRoutines.hpp"
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#include "utilities/events.hpp"
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#include "utilities/macros.hpp"
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#if INCLUDE_ALL_GCS
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#include "gc/g1/g1CollectedHeap.inline.hpp"
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#include "gc/g1/g1SATBCardTableModRefBS.hpp"
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#include "gc/g1/heapRegion.hpp"
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#endif
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#include <ucontext.h>
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#define BLOCK_COMMENT(str) block_comment(str)
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#define BIND(label) bind(label); BLOCK_COMMENT(#label ":")
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// Move 32-bit register if destination and source are different.
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void MacroAssembler::lr_if_needed(Register rd, Register rs) {
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if (rs != rd) { z_lr(rd, rs); }
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}
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// Move register if destination and source are different.
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void MacroAssembler::lgr_if_needed(Register rd, Register rs) {
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if (rs != rd) { z_lgr(rd, rs); }
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}
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// Zero-extend 32-bit register into 64-bit register if destination and source are different.
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void MacroAssembler::llgfr_if_needed(Register rd, Register rs) {
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if (rs != rd) { z_llgfr(rd, rs); }
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}
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// Move float register if destination and source are different.
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void MacroAssembler::ldr_if_needed(FloatRegister rd, FloatRegister rs) {
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if (rs != rd) { z_ldr(rd, rs); }
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}
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// Move integer register if destination and source are different.
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// It is assumed that shorter-than-int types are already
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// appropriately sign-extended.
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void MacroAssembler::move_reg_if_needed(Register dst, BasicType dst_type, Register src,
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BasicType src_type) {
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assert((dst_type != T_FLOAT) && (dst_type != T_DOUBLE), "use move_freg for float types");
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assert((src_type != T_FLOAT) && (src_type != T_DOUBLE), "use move_freg for float types");
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if (dst_type == src_type) {
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lgr_if_needed(dst, src); // Just move all 64 bits.
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return;
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}
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switch (dst_type) {
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// Do not support these types for now.
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// case T_BOOLEAN:
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case T_BYTE: // signed byte
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switch (src_type) {
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case T_INT:
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z_lgbr(dst, src);
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break;
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default:
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ShouldNotReachHere();
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}
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return;
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case T_CHAR:
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case T_SHORT:
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switch (src_type) {
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case T_INT:
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if (dst_type == T_CHAR) {
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z_llghr(dst, src);
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} else {
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z_lghr(dst, src);
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}
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break;
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default:
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ShouldNotReachHere();
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}
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return;
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case T_INT:
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switch (src_type) {
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case T_BOOLEAN:
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case T_BYTE:
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case T_CHAR:
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case T_SHORT:
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case T_INT:
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case T_LONG:
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case T_OBJECT:
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case T_ARRAY:
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case T_VOID:
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case T_ADDRESS:
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lr_if_needed(dst, src);
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// llgfr_if_needed(dst, src); // zero-extend (in case we need to find a bug).
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return;
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default:
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assert(false, "non-integer src type");
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return;
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}
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case T_LONG:
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switch (src_type) {
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case T_BOOLEAN:
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case T_BYTE:
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case T_CHAR:
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case T_SHORT:
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case T_INT:
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z_lgfr(dst, src); // sign extension
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return;
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case T_LONG:
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case T_OBJECT:
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case T_ARRAY:
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case T_VOID:
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case T_ADDRESS:
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lgr_if_needed(dst, src);
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return;
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default:
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assert(false, "non-integer src type");
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return;
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}
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return;
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case T_OBJECT:
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case T_ARRAY:
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case T_VOID:
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case T_ADDRESS:
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switch (src_type) {
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// These types don't make sense to be converted to pointers:
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// case T_BOOLEAN:
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// case T_BYTE:
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// case T_CHAR:
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// case T_SHORT:
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case T_INT:
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z_llgfr(dst, src); // zero extension
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return;
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case T_LONG:
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case T_OBJECT:
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case T_ARRAY:
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case T_VOID:
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case T_ADDRESS:
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lgr_if_needed(dst, src);
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return;
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default:
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assert(false, "non-integer src type");
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return;
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}
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return;
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default:
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assert(false, "non-integer dst type");
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return;
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}
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}
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// Move float register if destination and source are different.
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void MacroAssembler::move_freg_if_needed(FloatRegister dst, BasicType dst_type,
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FloatRegister src, BasicType src_type) {
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assert((dst_type == T_FLOAT) || (dst_type == T_DOUBLE), "use move_reg for int types");
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assert((src_type == T_FLOAT) || (src_type == T_DOUBLE), "use move_reg for int types");
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if (dst_type == src_type) {
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ldr_if_needed(dst, src); // Just move all 64 bits.
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} else {
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switch (dst_type) {
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case T_FLOAT:
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assert(src_type == T_DOUBLE, "invalid float type combination");
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z_ledbr(dst, src);
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return;
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case T_DOUBLE:
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assert(src_type == T_FLOAT, "invalid float type combination");
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z_ldebr(dst, src);
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return;
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default:
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assert(false, "non-float dst type");
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return;
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}
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}
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}
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// Optimized emitter for reg to mem operations.
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// Uses modern instructions if running on modern hardware, classic instructions
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// otherwise. Prefers (usually shorter) classic instructions if applicable.
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// Data register (reg) cannot be used as work register.
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//
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// Don't rely on register locking, instead pass a scratch register (Z_R0 by default).
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// CAUTION! Passing registers >= Z_R2 may produce bad results on old CPUs!
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void MacroAssembler::freg2mem_opt(FloatRegister reg,
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int64_t disp,
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Register index,
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Register base,
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void (MacroAssembler::*modern) (FloatRegister, int64_t, Register, Register),
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void (MacroAssembler::*classic)(FloatRegister, int64_t, Register, Register),
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Register scratch) {
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index = (index == noreg) ? Z_R0 : index;
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if (Displacement::is_shortDisp(disp)) {
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(this->*classic)(reg, disp, index, base);
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} else {
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if (Displacement::is_validDisp(disp)) {
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(this->*modern)(reg, disp, index, base);
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} else {
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if (scratch != Z_R0 && scratch != Z_R1) {
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(this->*modern)(reg, disp, index, base); // Will fail with disp out of range.
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} else {
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if (scratch != Z_R0) { // scratch == Z_R1
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if ((scratch == index) || (index == base)) {
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(this->*modern)(reg, disp, index, base); // Will fail with disp out of range.
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} else {
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add2reg(scratch, disp, base);
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(this->*classic)(reg, 0, index, scratch);
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if (base == scratch) {
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add2reg(base, -disp); // Restore base.
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}
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}
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} else { // scratch == Z_R0
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z_lgr(scratch, base);
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add2reg(base, disp);
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(this->*classic)(reg, 0, index, base);
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z_lgr(base, scratch); // Restore base.
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}
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}
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}
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}
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}
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void MacroAssembler::freg2mem_opt(FloatRegister reg, const Address &a, bool is_double) {
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if (is_double) {
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freg2mem_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_FFUN(z_stdy), CLASSIC_FFUN(z_std));
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} else {
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freg2mem_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_FFUN(z_stey), CLASSIC_FFUN(z_ste));
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}
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}
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// Optimized emitter for mem to reg operations.
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// Uses modern instructions if running on modern hardware, classic instructions
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// otherwise. Prefers (usually shorter) classic instructions if applicable.
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// data register (reg) cannot be used as work register.
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//
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// Don't rely on register locking, instead pass a scratch register (Z_R0 by default).
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// CAUTION! Passing registers >= Z_R2 may produce bad results on old CPUs!
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void MacroAssembler::mem2freg_opt(FloatRegister reg,
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int64_t disp,
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Register index,
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Register base,
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void (MacroAssembler::*modern) (FloatRegister, int64_t, Register, Register),
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void (MacroAssembler::*classic)(FloatRegister, int64_t, Register, Register),
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Register scratch) {
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index = (index == noreg) ? Z_R0 : index;
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if (Displacement::is_shortDisp(disp)) {
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(this->*classic)(reg, disp, index, base);
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} else {
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if (Displacement::is_validDisp(disp)) {
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(this->*modern)(reg, disp, index, base);
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} else {
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if (scratch != Z_R0 && scratch != Z_R1) {
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(this->*modern)(reg, disp, index, base); // Will fail with disp out of range.
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} else {
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if (scratch != Z_R0) { // scratch == Z_R1
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if ((scratch == index) || (index == base)) {
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(this->*modern)(reg, disp, index, base); // Will fail with disp out of range.
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} else {
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add2reg(scratch, disp, base);
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(this->*classic)(reg, 0, index, scratch);
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if (base == scratch) {
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add2reg(base, -disp); // Restore base.
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}
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}
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} else { // scratch == Z_R0
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z_lgr(scratch, base);
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add2reg(base, disp);
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(this->*classic)(reg, 0, index, base);
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z_lgr(base, scratch); // Restore base.
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}
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}
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}
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}
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}
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void MacroAssembler::mem2freg_opt(FloatRegister reg, const Address &a, bool is_double) {
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if (is_double) {
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mem2freg_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_FFUN(z_ldy), CLASSIC_FFUN(z_ld));
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} else {
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mem2freg_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_FFUN(z_ley), CLASSIC_FFUN(z_le));
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}
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}
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// Optimized emitter for reg to mem operations.
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// Uses modern instructions if running on modern hardware, classic instructions
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// otherwise. Prefers (usually shorter) classic instructions if applicable.
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// Data register (reg) cannot be used as work register.
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//
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// Don't rely on register locking, instead pass a scratch register
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// (Z_R0 by default)
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// CAUTION! passing registers >= Z_R2 may produce bad results on old CPUs!
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void MacroAssembler::reg2mem_opt(Register reg,
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int64_t disp,
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Register index,
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Register base,
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void (MacroAssembler::*modern) (Register, int64_t, Register, Register),
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void (MacroAssembler::*classic)(Register, int64_t, Register, Register),
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Register scratch) {
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index = (index == noreg) ? Z_R0 : index;
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if (Displacement::is_shortDisp(disp)) {
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(this->*classic)(reg, disp, index, base);
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} else {
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if (Displacement::is_validDisp(disp)) {
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(this->*modern)(reg, disp, index, base);
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} else {
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if (scratch != Z_R0 && scratch != Z_R1) {
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(this->*modern)(reg, disp, index, base); // Will fail with disp out of range.
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} else {
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if (scratch != Z_R0) { // scratch == Z_R1
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if ((scratch == index) || (index == base)) {
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(this->*modern)(reg, disp, index, base); // Will fail with disp out of range.
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} else {
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add2reg(scratch, disp, base);
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(this->*classic)(reg, 0, index, scratch);
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if (base == scratch) {
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add2reg(base, -disp); // Restore base.
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}
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}
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} else { // scratch == Z_R0
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if ((scratch == reg) || (scratch == base) || (reg == base)) {
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(this->*modern)(reg, disp, index, base); // Will fail with disp out of range.
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} else {
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z_lgr(scratch, base);
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add2reg(base, disp);
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(this->*classic)(reg, 0, index, base);
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z_lgr(base, scratch); // Restore base.
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}
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}
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}
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}
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}
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}
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int MacroAssembler::reg2mem_opt(Register reg, const Address &a, bool is_double) {
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int store_offset = offset();
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if (is_double) {
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reg2mem_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_IFUN(z_stg), CLASSIC_IFUN(z_stg));
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} else {
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reg2mem_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_IFUN(z_sty), CLASSIC_IFUN(z_st));
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|
385 |
}
|
|
386 |
return store_offset;
|
|
387 |
}
|
|
388 |
|
|
389 |
// Optimized emitter for mem to reg operations.
|
|
390 |
// Uses modern instructions if running on modern hardware, classic instructions
|
|
391 |
// otherwise. Prefers (usually shorter) classic instructions if applicable.
|
|
392 |
// Data register (reg) will be used as work register where possible.
|
|
393 |
void MacroAssembler::mem2reg_opt(Register reg,
|
|
394 |
int64_t disp,
|
|
395 |
Register index,
|
|
396 |
Register base,
|
|
397 |
void (MacroAssembler::*modern) (Register, int64_t, Register, Register),
|
|
398 |
void (MacroAssembler::*classic)(Register, int64_t, Register, Register)) {
|
|
399 |
index = (index == noreg) ? Z_R0 : index;
|
|
400 |
if (Displacement::is_shortDisp(disp)) {
|
|
401 |
(this->*classic)(reg, disp, index, base);
|
|
402 |
} else {
|
|
403 |
if (Displacement::is_validDisp(disp)) {
|
|
404 |
(this->*modern)(reg, disp, index, base);
|
|
405 |
} else {
|
|
406 |
if ((reg == index) && (reg == base)) {
|
|
407 |
z_sllg(reg, reg, 1);
|
|
408 |
add2reg(reg, disp);
|
|
409 |
(this->*classic)(reg, 0, noreg, reg);
|
|
410 |
} else if ((reg == index) && (reg != Z_R0)) {
|
|
411 |
add2reg(reg, disp);
|
|
412 |
(this->*classic)(reg, 0, reg, base);
|
|
413 |
} else if (reg == base) {
|
|
414 |
add2reg(reg, disp);
|
|
415 |
(this->*classic)(reg, 0, index, reg);
|
|
416 |
} else if (reg != Z_R0) {
|
|
417 |
add2reg(reg, disp, base);
|
|
418 |
(this->*classic)(reg, 0, index, reg);
|
|
419 |
} else { // reg == Z_R0 && reg != base here
|
|
420 |
add2reg(base, disp);
|
|
421 |
(this->*classic)(reg, 0, index, base);
|
|
422 |
add2reg(base, -disp);
|
|
423 |
}
|
|
424 |
}
|
|
425 |
}
|
|
426 |
}
|
|
427 |
|
|
428 |
void MacroAssembler::mem2reg_opt(Register reg, const Address &a, bool is_double) {
|
|
429 |
if (is_double) {
|
|
430 |
z_lg(reg, a);
|
|
431 |
} else {
|
|
432 |
mem2reg_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_IFUN(z_ly), CLASSIC_IFUN(z_l));
|
|
433 |
}
|
|
434 |
}
|
|
435 |
|
|
436 |
void MacroAssembler::mem2reg_signed_opt(Register reg, const Address &a) {
|
|
437 |
mem2reg_opt(reg, a.disp20(), a.indexOrR0(), a.baseOrR0(), MODERN_IFUN(z_lgf), CLASSIC_IFUN(z_lgf));
|
|
438 |
}
|
|
439 |
|
|
440 |
void MacroAssembler::and_imm(Register r, long mask,
|
|
441 |
Register tmp /* = Z_R0 */,
|
|
442 |
bool wide /* = false */) {
|
|
443 |
assert(wide || Immediate::is_simm32(mask), "mask value too large");
|
|
444 |
|
|
445 |
if (!wide) {
|
|
446 |
z_nilf(r, mask);
|
|
447 |
return;
|
|
448 |
}
|
|
449 |
|
|
450 |
assert(r != tmp, " need a different temporary register !");
|
|
451 |
load_const_optimized(tmp, mask);
|
|
452 |
z_ngr(r, tmp);
|
|
453 |
}
|
|
454 |
|
|
455 |
// Calculate the 1's complement.
|
|
456 |
// Note: The condition code is neither preserved nor correctly set by this code!!!
|
|
457 |
// Note: (wide == false) does not protect the high order half of the target register
|
|
458 |
// from alteration. It only serves as optimization hint for 32-bit results.
|
|
459 |
void MacroAssembler::not_(Register r1, Register r2, bool wide) {
|
|
460 |
|
|
461 |
if ((r2 == noreg) || (r2 == r1)) { // Calc 1's complement in place.
|
|
462 |
z_xilf(r1, -1);
|
|
463 |
if (wide) {
|
|
464 |
z_xihf(r1, -1);
|
|
465 |
}
|
|
466 |
} else { // Distinct src and dst registers.
|
|
467 |
if (VM_Version::has_DistinctOpnds()) {
|
|
468 |
load_const_optimized(r1, -1);
|
|
469 |
z_xgrk(r1, r2, r1);
|
|
470 |
} else {
|
|
471 |
if (wide) {
|
|
472 |
z_lgr(r1, r2);
|
|
473 |
z_xilf(r1, -1);
|
|
474 |
z_xihf(r1, -1);
|
|
475 |
} else {
|
|
476 |
z_lr(r1, r2);
|
|
477 |
z_xilf(r1, -1);
|
|
478 |
}
|
|
479 |
}
|
|
480 |
}
|
|
481 |
}
|
|
482 |
|
|
483 |
unsigned long MacroAssembler::create_mask(int lBitPos, int rBitPos) {
|
|
484 |
assert(lBitPos >= 0, "zero is leftmost bit position");
|
|
485 |
assert(rBitPos <= 63, "63 is rightmost bit position");
|
|
486 |
assert(lBitPos <= rBitPos, "inverted selection interval");
|
|
487 |
return (lBitPos == 0 ? (unsigned long)(-1L) : ((1UL<<(63-lBitPos+1))-1)) & (~((1UL<<(63-rBitPos))-1));
|
|
488 |
}
|
|
489 |
|
|
490 |
// Helper function for the "Rotate_then_<logicalOP>" emitters.
|
|
491 |
// Rotate src, then mask register contents such that only bits in range survive.
|
|
492 |
// For oneBits == false, all bits not in range are set to 0. Useful for deleting all bits outside range.
|
|
493 |
// For oneBits == true, all bits not in range are set to 1. Useful for preserving all bits outside range.
|
|
494 |
// The caller must ensure that the selected range only contains bits with defined value.
|
|
495 |
void MacroAssembler::rotate_then_mask(Register dst, Register src, int lBitPos, int rBitPos,
|
|
496 |
int nRotate, bool src32bit, bool dst32bit, bool oneBits) {
|
|
497 |
assert(!(dst32bit && lBitPos < 32), "selection interval out of range for int destination");
|
|
498 |
bool sll4rll = (nRotate >= 0) && (nRotate <= (63-rBitPos)); // Substitute SLL(G) for RLL(G).
|
|
499 |
bool srl4rll = (nRotate < 0) && (-nRotate <= lBitPos); // Substitute SRL(G) for RLL(G).
|
|
500 |
// Pre-determine which parts of dst will be zero after shift/rotate.
|
|
501 |
bool llZero = sll4rll && (nRotate >= 16);
|
|
502 |
bool lhZero = (sll4rll && (nRotate >= 32)) || (srl4rll && (nRotate <= -48));
|
|
503 |
bool lfZero = llZero && lhZero;
|
|
504 |
bool hlZero = (sll4rll && (nRotate >= 48)) || (srl4rll && (nRotate <= -32));
|
|
505 |
bool hhZero = (srl4rll && (nRotate <= -16));
|
|
506 |
bool hfZero = hlZero && hhZero;
|
|
507 |
|
|
508 |
// rotate then mask src operand.
|
|
509 |
// if oneBits == true, all bits outside selected range are 1s.
|
|
510 |
// if oneBits == false, all bits outside selected range are 0s.
|
|
511 |
if (src32bit) { // There might be garbage in the upper 32 bits which will get masked away.
|
|
512 |
if (dst32bit) {
|
|
513 |
z_rll(dst, src, nRotate); // Copy and rotate, upper half of reg remains undisturbed.
|
|
514 |
} else {
|
|
515 |
if (sll4rll) { z_sllg(dst, src, nRotate); }
|
|
516 |
else if (srl4rll) { z_srlg(dst, src, -nRotate); }
|
|
517 |
else { z_rllg(dst, src, nRotate); }
|
|
518 |
}
|
|
519 |
} else {
|
|
520 |
if (sll4rll) { z_sllg(dst, src, nRotate); }
|
|
521 |
else if (srl4rll) { z_srlg(dst, src, -nRotate); }
|
|
522 |
else { z_rllg(dst, src, nRotate); }
|
|
523 |
}
|
|
524 |
|
|
525 |
unsigned long range_mask = create_mask(lBitPos, rBitPos);
|
|
526 |
unsigned int range_mask_h = (unsigned int)(range_mask >> 32);
|
|
527 |
unsigned int range_mask_l = (unsigned int)range_mask;
|
|
528 |
unsigned short range_mask_hh = (unsigned short)(range_mask >> 48);
|
|
529 |
unsigned short range_mask_hl = (unsigned short)(range_mask >> 32);
|
|
530 |
unsigned short range_mask_lh = (unsigned short)(range_mask >> 16);
|
|
531 |
unsigned short range_mask_ll = (unsigned short)range_mask;
|
|
532 |
// Works for z9 and newer H/W.
|
|
533 |
if (oneBits) {
|
|
534 |
if ((~range_mask_l) != 0) { z_oilf(dst, ~range_mask_l); } // All bits outside range become 1s.
|
|
535 |
if (((~range_mask_h) != 0) && !dst32bit) { z_oihf(dst, ~range_mask_h); }
|
|
536 |
} else {
|
|
537 |
// All bits outside range become 0s
|
|
538 |
if (((~range_mask_l) != 0) && !lfZero) {
|
|
539 |
z_nilf(dst, range_mask_l);
|
|
540 |
}
|
|
541 |
if (((~range_mask_h) != 0) && !dst32bit && !hfZero) {
|
|
542 |
z_nihf(dst, range_mask_h);
|
|
543 |
}
|
|
544 |
}
|
|
545 |
}
|
|
546 |
|
|
547 |
// Rotate src, then insert selected range from rotated src into dst.
|
|
548 |
// Clear dst before, if requested.
|
|
549 |
void MacroAssembler::rotate_then_insert(Register dst, Register src, int lBitPos, int rBitPos,
|
|
550 |
int nRotate, bool clear_dst) {
|
|
551 |
// This version does not depend on src being zero-extended int2long.
|
|
552 |
nRotate &= 0x003f; // For risbg, pretend it's an unsigned value.
|
|
553 |
z_risbg(dst, src, lBitPos, rBitPos, nRotate, clear_dst); // Rotate, then insert selected, clear the rest.
|
|
554 |
}
|
|
555 |
|
|
556 |
// Rotate src, then and selected range from rotated src into dst.
|
|
557 |
// Set condition code only if so requested. Otherwise it is unpredictable.
|
|
558 |
// See performance note in macroAssembler_s390.hpp for important information.
|
|
559 |
void MacroAssembler::rotate_then_and(Register dst, Register src, int lBitPos, int rBitPos,
|
|
560 |
int nRotate, bool test_only) {
|
|
561 |
guarantee(!test_only, "Emitter not fit for test_only instruction variant.");
|
|
562 |
// This version does not depend on src being zero-extended int2long.
|
|
563 |
nRotate &= 0x003f; // For risbg, pretend it's an unsigned value.
|
|
564 |
z_rxsbg(dst, src, lBitPos, rBitPos, nRotate, test_only); // Rotate, then xor selected.
|
|
565 |
}
|
|
566 |
|
|
567 |
// Rotate src, then or selected range from rotated src into dst.
|
|
568 |
// Set condition code only if so requested. Otherwise it is unpredictable.
|
|
569 |
// See performance note in macroAssembler_s390.hpp for important information.
|
|
570 |
void MacroAssembler::rotate_then_or(Register dst, Register src, int lBitPos, int rBitPos,
|
|
571 |
int nRotate, bool test_only) {
|
|
572 |
guarantee(!test_only, "Emitter not fit for test_only instruction variant.");
|
|
573 |
// This version does not depend on src being zero-extended int2long.
|
|
574 |
nRotate &= 0x003f; // For risbg, pretend it's an unsigned value.
|
|
575 |
z_rosbg(dst, src, lBitPos, rBitPos, nRotate, test_only); // Rotate, then xor selected.
|
|
576 |
}
|
|
577 |
|
|
578 |
// Rotate src, then xor selected range from rotated src into dst.
|
|
579 |
// Set condition code only if so requested. Otherwise it is unpredictable.
|
|
580 |
// See performance note in macroAssembler_s390.hpp for important information.
|
|
581 |
void MacroAssembler::rotate_then_xor(Register dst, Register src, int lBitPos, int rBitPos,
|
|
582 |
int nRotate, bool test_only) {
|
|
583 |
guarantee(!test_only, "Emitter not fit for test_only instruction variant.");
|
|
584 |
// This version does not depend on src being zero-extended int2long.
|
|
585 |
nRotate &= 0x003f; // For risbg, pretend it's an unsigned value.
|
|
586 |
z_rxsbg(dst, src, lBitPos, rBitPos, nRotate, test_only); // Rotate, then xor selected.
|
|
587 |
}
|
|
588 |
|
|
589 |
void MacroAssembler::add64(Register r1, RegisterOrConstant inc) {
|
|
590 |
if (inc.is_register()) {
|
|
591 |
z_agr(r1, inc.as_register());
|
|
592 |
} else { // constant
|
|
593 |
intptr_t imm = inc.as_constant();
|
|
594 |
add2reg(r1, imm);
|
|
595 |
}
|
|
596 |
}
|
|
597 |
// Helper function to multiply the 64bit contents of a register by a 16bit constant.
|
|
598 |
// The optimization tries to avoid the mghi instruction, since it uses the FPU for
|
|
599 |
// calculation and is thus rather slow.
|
|
600 |
//
|
|
601 |
// There is no handling for special cases, e.g. cval==0 or cval==1.
|
|
602 |
//
|
|
603 |
// Returns len of generated code block.
|
|
604 |
unsigned int MacroAssembler::mul_reg64_const16(Register rval, Register work, int cval) {
|
|
605 |
int block_start = offset();
|
|
606 |
|
|
607 |
bool sign_flip = cval < 0;
|
|
608 |
cval = sign_flip ? -cval : cval;
|
|
609 |
|
|
610 |
BLOCK_COMMENT("Reg64*Con16 {");
|
|
611 |
|
|
612 |
int bit1 = cval & -cval;
|
|
613 |
if (bit1 == cval) {
|
|
614 |
z_sllg(rval, rval, exact_log2(bit1));
|
|
615 |
if (sign_flip) { z_lcgr(rval, rval); }
|
|
616 |
} else {
|
|
617 |
int bit2 = (cval-bit1) & -(cval-bit1);
|
|
618 |
if ((bit1+bit2) == cval) {
|
|
619 |
z_sllg(work, rval, exact_log2(bit1));
|
|
620 |
z_sllg(rval, rval, exact_log2(bit2));
|
|
621 |
z_agr(rval, work);
|
|
622 |
if (sign_flip) { z_lcgr(rval, rval); }
|
|
623 |
} else {
|
|
624 |
if (sign_flip) { z_mghi(rval, -cval); }
|
|
625 |
else { z_mghi(rval, cval); }
|
|
626 |
}
|
|
627 |
}
|
|
628 |
BLOCK_COMMENT("} Reg64*Con16");
|
|
629 |
|
|
630 |
int block_end = offset();
|
|
631 |
return block_end - block_start;
|
|
632 |
}
|
|
633 |
|
|
634 |
// Generic operation r1 := r2 + imm.
|
|
635 |
//
|
|
636 |
// Should produce the best code for each supported CPU version.
|
|
637 |
// r2 == noreg yields r1 := r1 + imm
|
|
638 |
// imm == 0 emits either no instruction or r1 := r2 !
|
|
639 |
// NOTES: 1) Don't use this function where fixed sized
|
|
640 |
// instruction sequences are required!!!
|
|
641 |
// 2) Don't use this function if condition code
|
|
642 |
// setting is required!
|
|
643 |
// 3) Despite being declared as int64_t, the parameter imm
|
|
644 |
// must be a simm_32 value (= signed 32-bit integer).
|
|
645 |
void MacroAssembler::add2reg(Register r1, int64_t imm, Register r2) {
|
|
646 |
assert(Immediate::is_simm32(imm), "probably an implicit conversion went wrong");
|
|
647 |
|
|
648 |
if (r2 == noreg) { r2 = r1; }
|
|
649 |
|
|
650 |
// Handle special case imm == 0.
|
|
651 |
if (imm == 0) {
|
|
652 |
lgr_if_needed(r1, r2);
|
|
653 |
// Nothing else to do.
|
|
654 |
return;
|
|
655 |
}
|
|
656 |
|
|
657 |
if (!PreferLAoverADD || (r2 == Z_R0)) {
|
|
658 |
bool distinctOpnds = VM_Version::has_DistinctOpnds();
|
|
659 |
|
|
660 |
// Can we encode imm in 16 bits signed?
|
|
661 |
if (Immediate::is_simm16(imm)) {
|
|
662 |
if (r1 == r2) {
|
|
663 |
z_aghi(r1, imm);
|
|
664 |
return;
|
|
665 |
}
|
|
666 |
if (distinctOpnds) {
|
|
667 |
z_aghik(r1, r2, imm);
|
|
668 |
return;
|
|
669 |
}
|
|
670 |
z_lgr(r1, r2);
|
|
671 |
z_aghi(r1, imm);
|
|
672 |
return;
|
|
673 |
}
|
|
674 |
} else {
|
|
675 |
// Can we encode imm in 12 bits unsigned?
|
|
676 |
if (Displacement::is_shortDisp(imm)) {
|
|
677 |
z_la(r1, imm, r2);
|
|
678 |
return;
|
|
679 |
}
|
|
680 |
// Can we encode imm in 20 bits signed?
|
|
681 |
if (Displacement::is_validDisp(imm)) {
|
|
682 |
// Always use LAY instruction, so we don't need the tmp register.
|
|
683 |
z_lay(r1, imm, r2);
|
|
684 |
return;
|
|
685 |
}
|
|
686 |
|
|
687 |
}
|
|
688 |
|
|
689 |
// Can handle it (all possible values) with long immediates.
|
|
690 |
lgr_if_needed(r1, r2);
|
|
691 |
z_agfi(r1, imm);
|
|
692 |
}
|
|
693 |
|
|
694 |
// Generic operation r := b + x + d
|
|
695 |
//
|
|
696 |
// Addition of several operands with address generation semantics - sort of:
|
|
697 |
// - no restriction on the registers. Any register will do for any operand.
|
|
698 |
// - x == noreg: operand will be disregarded.
|
|
699 |
// - b == noreg: will use (contents of) result reg as operand (r := r + d).
|
|
700 |
// - x == Z_R0: just disregard
|
|
701 |
// - b == Z_R0: use as operand. This is not address generation semantics!!!
|
|
702 |
//
|
|
703 |
// The same restrictions as on add2reg() are valid!!!
|
|
704 |
void MacroAssembler::add2reg_with_index(Register r, int64_t d, Register x, Register b) {
|
|
705 |
assert(Immediate::is_simm32(d), "probably an implicit conversion went wrong");
|
|
706 |
|
|
707 |
if (x == noreg) { x = Z_R0; }
|
|
708 |
if (b == noreg) { b = r; }
|
|
709 |
|
|
710 |
// Handle special case x == R0.
|
|
711 |
if (x == Z_R0) {
|
|
712 |
// Can simply add the immediate value to the base register.
|
|
713 |
add2reg(r, d, b);
|
|
714 |
return;
|
|
715 |
}
|
|
716 |
|
|
717 |
if (!PreferLAoverADD || (b == Z_R0)) {
|
|
718 |
bool distinctOpnds = VM_Version::has_DistinctOpnds();
|
|
719 |
// Handle special case d == 0.
|
|
720 |
if (d == 0) {
|
|
721 |
if (b == x) { z_sllg(r, b, 1); return; }
|
|
722 |
if (r == x) { z_agr(r, b); return; }
|
|
723 |
if (r == b) { z_agr(r, x); return; }
|
|
724 |
if (distinctOpnds) { z_agrk(r, x, b); return; }
|
|
725 |
z_lgr(r, b);
|
|
726 |
z_agr(r, x);
|
|
727 |
} else {
|
|
728 |
if (x == b) { z_sllg(r, x, 1); }
|
|
729 |
else if (r == x) { z_agr(r, b); }
|
|
730 |
else if (r == b) { z_agr(r, x); }
|
|
731 |
else if (distinctOpnds) { z_agrk(r, x, b); }
|
|
732 |
else {
|
|
733 |
z_lgr(r, b);
|
|
734 |
z_agr(r, x);
|
|
735 |
}
|
|
736 |
add2reg(r, d);
|
|
737 |
}
|
|
738 |
} else {
|
|
739 |
// Can we encode imm in 12 bits unsigned?
|
|
740 |
if (Displacement::is_shortDisp(d)) {
|
|
741 |
z_la(r, d, x, b);
|
|
742 |
return;
|
|
743 |
}
|
|
744 |
// Can we encode imm in 20 bits signed?
|
|
745 |
if (Displacement::is_validDisp(d)) {
|
|
746 |
z_lay(r, d, x, b);
|
|
747 |
return;
|
|
748 |
}
|
|
749 |
z_la(r, 0, x, b);
|
|
750 |
add2reg(r, d);
|
|
751 |
}
|
|
752 |
}
|
|
753 |
|
|
754 |
// Generic emitter (32bit) for direct memory increment.
|
|
755 |
// For optimal code, do not specify Z_R0 as temp register.
|
|
756 |
void MacroAssembler::add2mem_32(const Address &a, int64_t imm, Register tmp) {
|
|
757 |
if (VM_Version::has_MemWithImmALUOps() && Immediate::is_simm8(imm)) {
|
|
758 |
z_asi(a, imm);
|
|
759 |
} else {
|
|
760 |
z_lgf(tmp, a);
|
|
761 |
add2reg(tmp, imm);
|
|
762 |
z_st(tmp, a);
|
|
763 |
}
|
|
764 |
}
|
|
765 |
|
|
766 |
void MacroAssembler::add2mem_64(const Address &a, int64_t imm, Register tmp) {
|
|
767 |
if (VM_Version::has_MemWithImmALUOps() && Immediate::is_simm8(imm)) {
|
|
768 |
z_agsi(a, imm);
|
|
769 |
} else {
|
|
770 |
z_lg(tmp, a);
|
|
771 |
add2reg(tmp, imm);
|
|
772 |
z_stg(tmp, a);
|
|
773 |
}
|
|
774 |
}
|
|
775 |
|
|
776 |
void MacroAssembler::load_sized_value(Register dst, Address src, size_t size_in_bytes, bool is_signed) {
|
|
777 |
switch (size_in_bytes) {
|
|
778 |
case 8: z_lg(dst, src); break;
|
|
779 |
case 4: is_signed ? z_lgf(dst, src) : z_llgf(dst, src); break;
|
|
780 |
case 2: is_signed ? z_lgh(dst, src) : z_llgh(dst, src); break;
|
|
781 |
case 1: is_signed ? z_lgb(dst, src) : z_llgc(dst, src); break;
|
|
782 |
default: ShouldNotReachHere();
|
|
783 |
}
|
|
784 |
}
|
|
785 |
|
|
786 |
void MacroAssembler::store_sized_value(Register src, Address dst, size_t size_in_bytes) {
|
|
787 |
switch (size_in_bytes) {
|
|
788 |
case 8: z_stg(src, dst); break;
|
|
789 |
case 4: z_st(src, dst); break;
|
|
790 |
case 2: z_sth(src, dst); break;
|
|
791 |
case 1: z_stc(src, dst); break;
|
|
792 |
default: ShouldNotReachHere();
|
|
793 |
}
|
|
794 |
}
|
|
795 |
|
|
796 |
// Split a si20 offset (20bit, signed) into an ui12 offset (12bit, unsigned) and
|
|
797 |
// a high-order summand in register tmp.
|
|
798 |
//
|
|
799 |
// return value: < 0: No split required, si20 actually has property uimm12.
|
|
800 |
// >= 0: Split performed. Use return value as uimm12 displacement and
|
|
801 |
// tmp as index register.
|
|
802 |
int MacroAssembler::split_largeoffset(int64_t si20_offset, Register tmp, bool fixed_codelen, bool accumulate) {
|
|
803 |
assert(Immediate::is_simm20(si20_offset), "sanity");
|
|
804 |
int lg_off = (int)si20_offset & 0x0fff; // Punch out low-order 12 bits, always positive.
|
|
805 |
int ll_off = (int)si20_offset & ~0x0fff; // Force low-order 12 bits to zero.
|
|
806 |
assert((Displacement::is_shortDisp(si20_offset) && (ll_off == 0)) ||
|
|
807 |
!Displacement::is_shortDisp(si20_offset), "unexpected offset values");
|
|
808 |
assert((lg_off+ll_off) == si20_offset, "offset splitup error");
|
|
809 |
|
|
810 |
Register work = accumulate? Z_R0 : tmp;
|
|
811 |
|
|
812 |
if (fixed_codelen) { // Len of code = 10 = 4 + 6.
|
|
813 |
z_lghi(work, ll_off>>12); // Implicit sign extension.
|
|
814 |
z_slag(work, work, 12);
|
|
815 |
} else { // Len of code = 0..10.
|
|
816 |
if (ll_off == 0) { return -1; }
|
|
817 |
// ll_off has 8 significant bits (at most) plus sign.
|
|
818 |
if ((ll_off & 0x0000f000) == 0) { // Non-zero bits only in upper halfbyte.
|
|
819 |
z_llilh(work, ll_off >> 16);
|
|
820 |
if (ll_off < 0) { // Sign-extension required.
|
|
821 |
z_lgfr(work, work);
|
|
822 |
}
|
|
823 |
} else {
|
|
824 |
if ((ll_off & 0x000f0000) == 0) { // Non-zero bits only in lower halfbyte.
|
|
825 |
z_llill(work, ll_off);
|
|
826 |
} else { // Non-zero bits in both halfbytes.
|
|
827 |
z_lghi(work, ll_off>>12); // Implicit sign extension.
|
|
828 |
z_slag(work, work, 12);
|
|
829 |
}
|
|
830 |
}
|
|
831 |
}
|
|
832 |
if (accumulate) { z_algr(tmp, work); } // len of code += 4
|
|
833 |
return lg_off;
|
|
834 |
}
|
|
835 |
|
|
836 |
void MacroAssembler::load_float_largeoffset(FloatRegister t, int64_t si20, Register a, Register tmp) {
|
|
837 |
if (Displacement::is_validDisp(si20)) {
|
|
838 |
z_ley(t, si20, a);
|
|
839 |
} else {
|
|
840 |
// Fixed_codelen = true is a simple way to ensure that the size of load_float_largeoffset
|
|
841 |
// does not depend on si20 (scratch buffer emit size == code buffer emit size for constant
|
|
842 |
// pool loads).
|
|
843 |
bool accumulate = true;
|
|
844 |
bool fixed_codelen = true;
|
|
845 |
Register work;
|
|
846 |
|
|
847 |
if (fixed_codelen) {
|
|
848 |
z_lgr(tmp, a); // Lgr_if_needed not applicable due to fixed_codelen.
|
|
849 |
} else {
|
|
850 |
accumulate = (a == tmp);
|
|
851 |
}
|
|
852 |
work = tmp;
|
|
853 |
|
|
854 |
int disp12 = split_largeoffset(si20, work, fixed_codelen, accumulate);
|
|
855 |
if (disp12 < 0) {
|
|
856 |
z_le(t, si20, work);
|
|
857 |
} else {
|
|
858 |
if (accumulate) {
|
|
859 |
z_le(t, disp12, work);
|
|
860 |
} else {
|
|
861 |
z_le(t, disp12, work, a);
|
|
862 |
}
|
|
863 |
}
|
|
864 |
}
|
|
865 |
}
|
|
866 |
|
|
867 |
void MacroAssembler::load_double_largeoffset(FloatRegister t, int64_t si20, Register a, Register tmp) {
|
|
868 |
if (Displacement::is_validDisp(si20)) {
|
|
869 |
z_ldy(t, si20, a);
|
|
870 |
} else {
|
|
871 |
// Fixed_codelen = true is a simple way to ensure that the size of load_double_largeoffset
|
|
872 |
// does not depend on si20 (scratch buffer emit size == code buffer emit size for constant
|
|
873 |
// pool loads).
|
|
874 |
bool accumulate = true;
|
|
875 |
bool fixed_codelen = true;
|
|
876 |
Register work;
|
|
877 |
|
|
878 |
if (fixed_codelen) {
|
|
879 |
z_lgr(tmp, a); // Lgr_if_needed not applicable due to fixed_codelen.
|
|
880 |
} else {
|
|
881 |
accumulate = (a == tmp);
|
|
882 |
}
|
|
883 |
work = tmp;
|
|
884 |
|
|
885 |
int disp12 = split_largeoffset(si20, work, fixed_codelen, accumulate);
|
|
886 |
if (disp12 < 0) {
|
|
887 |
z_ld(t, si20, work);
|
|
888 |
} else {
|
|
889 |
if (accumulate) {
|
|
890 |
z_ld(t, disp12, work);
|
|
891 |
} else {
|
|
892 |
z_ld(t, disp12, work, a);
|
|
893 |
}
|
|
894 |
}
|
|
895 |
}
|
|
896 |
}
|
|
897 |
|
|
898 |
// PCrelative TOC access.
|
|
899 |
// Returns distance (in bytes) from current position to start of consts section.
|
|
900 |
// Returns 0 (zero) if no consts section exists or if it has size zero.
|
|
901 |
long MacroAssembler::toc_distance() {
|
|
902 |
CodeSection* cs = code()->consts();
|
|
903 |
return (long)((cs != NULL) ? cs->start()-pc() : 0);
|
|
904 |
}
|
|
905 |
|
|
906 |
// Implementation on x86/sparc assumes that constant and instruction section are
|
|
907 |
// adjacent, but this doesn't hold. Two special situations may occur, that we must
|
|
908 |
// be able to handle:
|
|
909 |
// 1. const section may be located apart from the inst section.
|
|
910 |
// 2. const section may be empty
|
|
911 |
// In both cases, we use the const section's start address to compute the "TOC",
|
|
912 |
// this seems to occur only temporarily; in the final step we always seem to end up
|
|
913 |
// with the pc-relatice variant.
|
|
914 |
//
|
|
915 |
// PC-relative offset could be +/-2**32 -> use long for disp
|
|
916 |
// Furthermore: makes no sense to have special code for
|
|
917 |
// adjacent const and inst sections.
|
|
918 |
void MacroAssembler::load_toc(Register Rtoc) {
|
|
919 |
// Simply use distance from start of const section (should be patched in the end).
|
|
920 |
long disp = toc_distance();
|
|
921 |
|
|
922 |
RelocationHolder rspec = internal_word_Relocation::spec(pc() + disp);
|
|
923 |
relocate(rspec);
|
|
924 |
z_larl(Rtoc, RelAddr::pcrel_off32(disp)); // Offset is in halfwords.
|
|
925 |
}
|
|
926 |
|
|
927 |
// PCrelative TOC access.
|
|
928 |
// Load from anywhere pcrelative (with relocation of load instr)
|
|
929 |
void MacroAssembler::load_long_pcrelative(Register Rdst, address dataLocation) {
|
|
930 |
address pc = this->pc();
|
|
931 |
ptrdiff_t total_distance = dataLocation - pc;
|
|
932 |
RelocationHolder rspec = internal_word_Relocation::spec(dataLocation);
|
|
933 |
|
|
934 |
assert((total_distance & 0x01L) == 0, "halfword alignment is mandatory");
|
|
935 |
assert(total_distance != 0, "sanity");
|
|
936 |
|
|
937 |
// Some extra safety net.
|
|
938 |
if (!RelAddr::is_in_range_of_RelAddr32(total_distance)) {
|
|
939 |
guarantee(RelAddr::is_in_range_of_RelAddr32(total_distance), "too far away");
|
|
940 |
}
|
|
941 |
|
|
942 |
(this)->relocate(rspec, relocInfo::pcrel_addr_format);
|
|
943 |
z_lgrl(Rdst, RelAddr::pcrel_off32(total_distance));
|
|
944 |
}
|
|
945 |
|
|
946 |
|
|
947 |
// PCrelative TOC access.
|
|
948 |
// Load from anywhere pcrelative (with relocation of load instr)
|
|
949 |
// loaded addr has to be relocated when added to constant pool.
|
|
950 |
void MacroAssembler::load_addr_pcrelative(Register Rdst, address addrLocation) {
|
|
951 |
address pc = this->pc();
|
|
952 |
ptrdiff_t total_distance = addrLocation - pc;
|
|
953 |
RelocationHolder rspec = internal_word_Relocation::spec(addrLocation);
|
|
954 |
|
|
955 |
assert((total_distance & 0x01L) == 0, "halfword alignment is mandatory");
|
|
956 |
|
|
957 |
// Some extra safety net.
|
|
958 |
if (!RelAddr::is_in_range_of_RelAddr32(total_distance)) {
|
|
959 |
guarantee(RelAddr::is_in_range_of_RelAddr32(total_distance), "too far away");
|
|
960 |
}
|
|
961 |
|
|
962 |
(this)->relocate(rspec, relocInfo::pcrel_addr_format);
|
|
963 |
z_lgrl(Rdst, RelAddr::pcrel_off32(total_distance));
|
|
964 |
}
|
|
965 |
|
|
966 |
// Generic operation: load a value from memory and test.
|
|
967 |
// CondCode indicates the sign (<0, ==0, >0) of the loaded value.
|
|
968 |
void MacroAssembler::load_and_test_byte(Register dst, const Address &a) {
|
|
969 |
z_lb(dst, a);
|
|
970 |
z_ltr(dst, dst);
|
|
971 |
}
|
|
972 |
|
|
973 |
void MacroAssembler::load_and_test_short(Register dst, const Address &a) {
|
|
974 |
int64_t disp = a.disp20();
|
|
975 |
if (Displacement::is_shortDisp(disp)) {
|
|
976 |
z_lh(dst, a);
|
|
977 |
} else if (Displacement::is_longDisp(disp)) {
|
|
978 |
z_lhy(dst, a);
|
|
979 |
} else {
|
|
980 |
guarantee(false, "displacement out of range");
|
|
981 |
}
|
|
982 |
z_ltr(dst, dst);
|
|
983 |
}
|
|
984 |
|
|
985 |
void MacroAssembler::load_and_test_int(Register dst, const Address &a) {
|
|
986 |
z_lt(dst, a);
|
|
987 |
}
|
|
988 |
|
|
989 |
void MacroAssembler::load_and_test_int2long(Register dst, const Address &a) {
|
|
990 |
z_ltgf(dst, a);
|
|
991 |
}
|
|
992 |
|
|
993 |
void MacroAssembler::load_and_test_long(Register dst, const Address &a) {
|
|
994 |
z_ltg(dst, a);
|
|
995 |
}
|
|
996 |
|
|
997 |
// Test a bit in memory.
|
|
998 |
void MacroAssembler::testbit(const Address &a, unsigned int bit) {
|
|
999 |
assert(a.index() == noreg, "no index reg allowed in testbit");
|
|
1000 |
if (bit <= 7) {
|
|
1001 |
z_tm(a.disp() + 3, a.base(), 1 << bit);
|
|
1002 |
} else if (bit <= 15) {
|
|
1003 |
z_tm(a.disp() + 2, a.base(), 1 << (bit - 8));
|
|
1004 |
} else if (bit <= 23) {
|
|
1005 |
z_tm(a.disp() + 1, a.base(), 1 << (bit - 16));
|
|
1006 |
} else if (bit <= 31) {
|
|
1007 |
z_tm(a.disp() + 0, a.base(), 1 << (bit - 24));
|
|
1008 |
} else {
|
|
1009 |
ShouldNotReachHere();
|
|
1010 |
}
|
|
1011 |
}
|
|
1012 |
|
|
1013 |
// Test a bit in a register. Result is reflected in CC.
|
|
1014 |
void MacroAssembler::testbit(Register r, unsigned int bitPos) {
|
|
1015 |
if (bitPos < 16) {
|
|
1016 |
z_tmll(r, 1U<<bitPos);
|
|
1017 |
} else if (bitPos < 32) {
|
|
1018 |
z_tmlh(r, 1U<<(bitPos-16));
|
|
1019 |
} else if (bitPos < 48) {
|
|
1020 |
z_tmhl(r, 1U<<(bitPos-32));
|
|
1021 |
} else if (bitPos < 64) {
|
|
1022 |
z_tmhh(r, 1U<<(bitPos-48));
|
|
1023 |
} else {
|
|
1024 |
ShouldNotReachHere();
|
|
1025 |
}
|
|
1026 |
}
|
|
1027 |
|
|
1028 |
// Clear a register, i.e. load const zero into reg.
|
|
1029 |
// Return len (in bytes) of generated instruction(s).
|
|
1030 |
// whole_reg: Clear 64 bits if true, 32 bits otherwise.
|
|
1031 |
// set_cc: Use instruction that sets the condition code, if true.
|
|
1032 |
int MacroAssembler::clear_reg(Register r, bool whole_reg, bool set_cc) {
|
|
1033 |
unsigned int start_off = offset();
|
|
1034 |
if (whole_reg) {
|
|
1035 |
set_cc ? z_xgr(r, r) : z_laz(r, 0, Z_R0);
|
|
1036 |
} else { // Only 32bit register.
|
|
1037 |
set_cc ? z_xr(r, r) : z_lhi(r, 0);
|
|
1038 |
}
|
|
1039 |
return offset() - start_off;
|
|
1040 |
}
|
|
1041 |
|
|
1042 |
#ifdef ASSERT
|
|
1043 |
int MacroAssembler::preset_reg(Register r, unsigned long pattern, int pattern_len) {
|
|
1044 |
switch (pattern_len) {
|
|
1045 |
case 1:
|
|
1046 |
pattern = (pattern & 0x000000ff) | ((pattern & 0x000000ff)<<8);
|
|
1047 |
case 2:
|
|
1048 |
pattern = (pattern & 0x0000ffff) | ((pattern & 0x0000ffff)<<16);
|
|
1049 |
case 4:
|
|
1050 |
pattern = (pattern & 0xffffffffL) | ((pattern & 0xffffffffL)<<32);
|
|
1051 |
case 8:
|
|
1052 |
return load_const_optimized_rtn_len(r, pattern, true);
|
|
1053 |
break;
|
|
1054 |
default:
|
|
1055 |
guarantee(false, "preset_reg: bad len");
|
|
1056 |
}
|
|
1057 |
return 0;
|
|
1058 |
}
|
|
1059 |
#endif
|
|
1060 |
|
|
1061 |
// addr: Address descriptor of memory to clear index register will not be used !
|
|
1062 |
// size: Number of bytes to clear.
|
|
1063 |
// !!! DO NOT USE THEM FOR ATOMIC MEMORY CLEARING !!!
|
|
1064 |
// !!! Use store_const() instead !!!
|
|
1065 |
void MacroAssembler::clear_mem(const Address& addr, unsigned size) {
|
|
1066 |
guarantee(size <= 256, "MacroAssembler::clear_mem: size too large");
|
|
1067 |
|
|
1068 |
if (size == 1) {
|
|
1069 |
z_mvi(addr, 0);
|
|
1070 |
return;
|
|
1071 |
}
|
|
1072 |
|
|
1073 |
switch (size) {
|
|
1074 |
case 2: z_mvhhi(addr, 0);
|
|
1075 |
return;
|
|
1076 |
case 4: z_mvhi(addr, 0);
|
|
1077 |
return;
|
|
1078 |
case 8: z_mvghi(addr, 0);
|
|
1079 |
return;
|
|
1080 |
default: ; // Fallthru to xc.
|
|
1081 |
}
|
|
1082 |
|
|
1083 |
z_xc(addr, size, addr);
|
|
1084 |
}
|
|
1085 |
|
|
1086 |
void MacroAssembler::align(int modulus) {
|
|
1087 |
while (offset() % modulus != 0) z_nop();
|
|
1088 |
}
|
|
1089 |
|
|
1090 |
// Special version for non-relocateable code if required alignment
|
|
1091 |
// is larger than CodeEntryAlignment.
|
|
1092 |
void MacroAssembler::align_address(int modulus) {
|
|
1093 |
while ((uintptr_t)pc() % modulus != 0) z_nop();
|
|
1094 |
}
|
|
1095 |
|
|
1096 |
Address MacroAssembler::argument_address(RegisterOrConstant arg_slot,
|
|
1097 |
Register temp_reg,
|
|
1098 |
int64_t extra_slot_offset) {
|
|
1099 |
// On Z, we can have index and disp in an Address. So don't call argument_offset,
|
|
1100 |
// which issues an unnecessary add instruction.
|
|
1101 |
int stackElementSize = Interpreter::stackElementSize;
|
|
1102 |
int64_t offset = extra_slot_offset * stackElementSize;
|
|
1103 |
const Register argbase = Z_esp;
|
|
1104 |
if (arg_slot.is_constant()) {
|
|
1105 |
offset += arg_slot.as_constant() * stackElementSize;
|
|
1106 |
return Address(argbase, offset);
|
|
1107 |
}
|
|
1108 |
// else
|
|
1109 |
assert(temp_reg != noreg, "must specify");
|
|
1110 |
assert(temp_reg != Z_ARG1, "base and index are conflicting");
|
|
1111 |
z_sllg(temp_reg, arg_slot.as_register(), exact_log2(stackElementSize)); // tempreg = arg_slot << 3
|
|
1112 |
return Address(argbase, temp_reg, offset);
|
|
1113 |
}
|
|
1114 |
|
|
1115 |
|
|
1116 |
//===================================================================
|
|
1117 |
//=== START C O N S T A N T S I N C O D E S T R E A M ===
|
|
1118 |
//===================================================================
|
|
1119 |
//=== P A T CH A B L E C O N S T A N T S ===
|
|
1120 |
//===================================================================
|
|
1121 |
|
|
1122 |
|
|
1123 |
//---------------------------------------------------
|
|
1124 |
// Load (patchable) constant into register
|
|
1125 |
//---------------------------------------------------
|
|
1126 |
|
|
1127 |
|
|
1128 |
// Load absolute address (and try to optimize).
|
|
1129 |
// Note: This method is usable only for position-fixed code,
|
|
1130 |
// referring to a position-fixed target location.
|
|
1131 |
// If not so, relocations and patching must be used.
|
|
1132 |
void MacroAssembler::load_absolute_address(Register d, address addr) {
|
|
1133 |
assert(addr != NULL, "should not happen");
|
|
1134 |
BLOCK_COMMENT("load_absolute_address:");
|
|
1135 |
if (addr == NULL) {
|
|
1136 |
z_larl(d, pc()); // Dummy emit for size calc.
|
|
1137 |
return;
|
|
1138 |
}
|
|
1139 |
|
|
1140 |
if (RelAddr::is_in_range_of_RelAddr32(addr, pc())) {
|
|
1141 |
z_larl(d, addr);
|
|
1142 |
return;
|
|
1143 |
}
|
|
1144 |
|
|
1145 |
load_const_optimized(d, (long)addr);
|
|
1146 |
}
|
|
1147 |
|
|
1148 |
// Load a 64bit constant.
|
|
1149 |
// Patchable code sequence, but not atomically patchable.
|
|
1150 |
// Make sure to keep code size constant -> no value-dependent optimizations.
|
|
1151 |
// Do not kill condition code.
|
|
1152 |
void MacroAssembler::load_const(Register t, long x) {
|
|
1153 |
Assembler::z_iihf(t, (int)(x >> 32));
|
|
1154 |
Assembler::z_iilf(t, (int)(x & 0xffffffff));
|
|
1155 |
}
|
|
1156 |
|
|
1157 |
// Load a 32bit constant into a 64bit register, sign-extend or zero-extend.
|
|
1158 |
// Patchable code sequence, but not atomically patchable.
|
|
1159 |
// Make sure to keep code size constant -> no value-dependent optimizations.
|
|
1160 |
// Do not kill condition code.
|
|
1161 |
void MacroAssembler::load_const_32to64(Register t, int64_t x, bool sign_extend) {
|
|
1162 |
if (sign_extend) { Assembler::z_lgfi(t, x); }
|
|
1163 |
else { Assembler::z_llilf(t, x); }
|
|
1164 |
}
|
|
1165 |
|
|
1166 |
// Load narrow oop constant, no decompression.
|
|
1167 |
void MacroAssembler::load_narrow_oop(Register t, narrowOop a) {
|
|
1168 |
assert(UseCompressedOops, "must be on to call this method");
|
|
1169 |
load_const_32to64(t, a, false /*sign_extend*/);
|
|
1170 |
}
|
|
1171 |
|
|
1172 |
// Load narrow klass constant, compression required.
|
|
1173 |
void MacroAssembler::load_narrow_klass(Register t, Klass* k) {
|
|
1174 |
assert(UseCompressedClassPointers, "must be on to call this method");
|
|
1175 |
narrowKlass encoded_k = Klass::encode_klass(k);
|
|
1176 |
load_const_32to64(t, encoded_k, false /*sign_extend*/);
|
|
1177 |
}
|
|
1178 |
|
|
1179 |
//------------------------------------------------------
|
|
1180 |
// Compare (patchable) constant with register.
|
|
1181 |
//------------------------------------------------------
|
|
1182 |
|
|
1183 |
// Compare narrow oop in reg with narrow oop constant, no decompression.
|
|
1184 |
void MacroAssembler::compare_immediate_narrow_oop(Register oop1, narrowOop oop2) {
|
|
1185 |
assert(UseCompressedOops, "must be on to call this method");
|
|
1186 |
|
|
1187 |
Assembler::z_clfi(oop1, oop2);
|
|
1188 |
}
|
|
1189 |
|
|
1190 |
// Compare narrow oop in reg with narrow oop constant, no decompression.
|
|
1191 |
void MacroAssembler::compare_immediate_narrow_klass(Register klass1, Klass* klass2) {
|
|
1192 |
assert(UseCompressedClassPointers, "must be on to call this method");
|
|
1193 |
narrowKlass encoded_k = Klass::encode_klass(klass2);
|
|
1194 |
|
|
1195 |
Assembler::z_clfi(klass1, encoded_k);
|
|
1196 |
}
|
|
1197 |
|
|
1198 |
//----------------------------------------------------------
|
|
1199 |
// Check which kind of load_constant we have here.
|
|
1200 |
//----------------------------------------------------------
|
|
1201 |
|
|
1202 |
// Detection of CPU version dependent load_const sequence.
|
|
1203 |
// The detection is valid only for code sequences generated by load_const,
|
|
1204 |
// not load_const_optimized.
|
|
1205 |
bool MacroAssembler::is_load_const(address a) {
|
|
1206 |
unsigned long inst1, inst2;
|
|
1207 |
unsigned int len1, len2;
|
|
1208 |
|
|
1209 |
len1 = get_instruction(a, &inst1);
|
|
1210 |
len2 = get_instruction(a + len1, &inst2);
|
|
1211 |
|
|
1212 |
return is_z_iihf(inst1) && is_z_iilf(inst2);
|
|
1213 |
}
|
|
1214 |
|
|
1215 |
// Detection of CPU version dependent load_const_32to64 sequence.
|
|
1216 |
// Mostly used for narrow oops and narrow Klass pointers.
|
|
1217 |
// The detection is valid only for code sequences generated by load_const_32to64.
|
|
1218 |
bool MacroAssembler::is_load_const_32to64(address pos) {
|
|
1219 |
unsigned long inst1, inst2;
|
|
1220 |
unsigned int len1;
|
|
1221 |
|
|
1222 |
len1 = get_instruction(pos, &inst1);
|
|
1223 |
return is_z_llilf(inst1);
|
|
1224 |
}
|
|
1225 |
|
|
1226 |
// Detection of compare_immediate_narrow sequence.
|
|
1227 |
// The detection is valid only for code sequences generated by compare_immediate_narrow_oop.
|
|
1228 |
bool MacroAssembler::is_compare_immediate32(address pos) {
|
|
1229 |
return is_equal(pos, CLFI_ZOPC, RIL_MASK);
|
|
1230 |
}
|
|
1231 |
|
|
1232 |
// Detection of compare_immediate_narrow sequence.
|
|
1233 |
// The detection is valid only for code sequences generated by compare_immediate_narrow_oop.
|
|
1234 |
bool MacroAssembler::is_compare_immediate_narrow_oop(address pos) {
|
|
1235 |
return is_compare_immediate32(pos);
|
|
1236 |
}
|
|
1237 |
|
|
1238 |
// Detection of compare_immediate_narrow sequence.
|
|
1239 |
// The detection is valid only for code sequences generated by compare_immediate_narrow_klass.
|
|
1240 |
bool MacroAssembler::is_compare_immediate_narrow_klass(address pos) {
|
|
1241 |
return is_compare_immediate32(pos);
|
|
1242 |
}
|
|
1243 |
|
|
1244 |
//-----------------------------------
|
|
1245 |
// patch the load_constant
|
|
1246 |
//-----------------------------------
|
|
1247 |
|
|
1248 |
// CPU-version dependend patching of load_const.
|
|
1249 |
void MacroAssembler::patch_const(address a, long x) {
|
|
1250 |
assert(is_load_const(a), "not a load of a constant");
|
|
1251 |
set_imm32((address)a, (int) ((x >> 32) & 0xffffffff));
|
|
1252 |
set_imm32((address)(a + 6), (int)(x & 0xffffffff));
|
|
1253 |
}
|
|
1254 |
|
|
1255 |
// Patching the value of CPU version dependent load_const_32to64 sequence.
|
|
1256 |
// The passed ptr MUST be in compressed format!
|
|
1257 |
int MacroAssembler::patch_load_const_32to64(address pos, int64_t np) {
|
|
1258 |
assert(is_load_const_32to64(pos), "not a load of a narrow ptr (oop or klass)");
|
|
1259 |
|
|
1260 |
set_imm32(pos, np);
|
|
1261 |
return 6;
|
|
1262 |
}
|
|
1263 |
|
|
1264 |
// Patching the value of CPU version dependent compare_immediate_narrow sequence.
|
|
1265 |
// The passed ptr MUST be in compressed format!
|
|
1266 |
int MacroAssembler::patch_compare_immediate_32(address pos, int64_t np) {
|
|
1267 |
assert(is_compare_immediate32(pos), "not a compressed ptr compare");
|
|
1268 |
|
|
1269 |
set_imm32(pos, np);
|
|
1270 |
return 6;
|
|
1271 |
}
|
|
1272 |
|
|
1273 |
// Patching the immediate value of CPU version dependent load_narrow_oop sequence.
|
|
1274 |
// The passed ptr must NOT be in compressed format!
|
|
1275 |
int MacroAssembler::patch_load_narrow_oop(address pos, oop o) {
|
|
1276 |
assert(UseCompressedOops, "Can only patch compressed oops");
|
|
1277 |
|
|
1278 |
narrowOop no = oopDesc::encode_heap_oop(o);
|
|
1279 |
return patch_load_const_32to64(pos, no);
|
|
1280 |
}
|
|
1281 |
|
|
1282 |
// Patching the immediate value of CPU version dependent load_narrow_klass sequence.
|
|
1283 |
// The passed ptr must NOT be in compressed format!
|
|
1284 |
int MacroAssembler::patch_load_narrow_klass(address pos, Klass* k) {
|
|
1285 |
assert(UseCompressedClassPointers, "Can only patch compressed klass pointers");
|
|
1286 |
|
|
1287 |
narrowKlass nk = Klass::encode_klass(k);
|
|
1288 |
return patch_load_const_32to64(pos, nk);
|
|
1289 |
}
|
|
1290 |
|
|
1291 |
// Patching the immediate value of CPU version dependent compare_immediate_narrow_oop sequence.
|
|
1292 |
// The passed ptr must NOT be in compressed format!
|
|
1293 |
int MacroAssembler::patch_compare_immediate_narrow_oop(address pos, oop o) {
|
|
1294 |
assert(UseCompressedOops, "Can only patch compressed oops");
|
|
1295 |
|
|
1296 |
narrowOop no = oopDesc::encode_heap_oop(o);
|
|
1297 |
return patch_compare_immediate_32(pos, no);
|
|
1298 |
}
|
|
1299 |
|
|
1300 |
// Patching the immediate value of CPU version dependent compare_immediate_narrow_klass sequence.
|
|
1301 |
// The passed ptr must NOT be in compressed format!
|
|
1302 |
int MacroAssembler::patch_compare_immediate_narrow_klass(address pos, Klass* k) {
|
|
1303 |
assert(UseCompressedClassPointers, "Can only patch compressed klass pointers");
|
|
1304 |
|
|
1305 |
narrowKlass nk = Klass::encode_klass(k);
|
|
1306 |
return patch_compare_immediate_32(pos, nk);
|
|
1307 |
}
|
|
1308 |
|
|
1309 |
//------------------------------------------------------------------------
|
|
1310 |
// Extract the constant from a load_constant instruction stream.
|
|
1311 |
//------------------------------------------------------------------------
|
|
1312 |
|
|
1313 |
// Get constant from a load_const sequence.
|
|
1314 |
long MacroAssembler::get_const(address a) {
|
|
1315 |
assert(is_load_const(a), "not a load of a constant");
|
|
1316 |
unsigned long x;
|
|
1317 |
x = (((unsigned long) (get_imm32(a,0) & 0xffffffff)) << 32);
|
|
1318 |
x |= (((unsigned long) (get_imm32(a,1) & 0xffffffff)));
|
|
1319 |
return (long) x;
|
|
1320 |
}
|
|
1321 |
|
|
1322 |
//--------------------------------------
|
|
1323 |
// Store a constant in memory.
|
|
1324 |
//--------------------------------------
|
|
1325 |
|
|
1326 |
// General emitter to move a constant to memory.
|
|
1327 |
// The store is atomic.
|
|
1328 |
// o Address must be given in RS format (no index register)
|
|
1329 |
// o Displacement should be 12bit unsigned for efficiency. 20bit signed also supported.
|
|
1330 |
// o Constant can be 1, 2, 4, or 8 bytes, signed or unsigned.
|
|
1331 |
// o Memory slot can be 1, 2, 4, or 8 bytes, signed or unsigned.
|
|
1332 |
// o Memory slot must be at least as wide as constant, will assert otherwise.
|
|
1333 |
// o Signed constants will sign-extend, unsigned constants will zero-extend to slot width.
|
|
1334 |
int MacroAssembler::store_const(const Address &dest, long imm,
|
|
1335 |
unsigned int lm, unsigned int lc,
|
|
1336 |
Register scratch) {
|
|
1337 |
int64_t disp = dest.disp();
|
|
1338 |
Register base = dest.base();
|
|
1339 |
assert(!dest.has_index(), "not supported");
|
|
1340 |
assert((lm==1)||(lm==2)||(lm==4)||(lm==8), "memory length not supported");
|
|
1341 |
assert((lc==1)||(lc==2)||(lc==4)||(lc==8), "constant length not supported");
|
|
1342 |
assert(lm>=lc, "memory slot too small");
|
|
1343 |
assert(lc==8 || Immediate::is_simm(imm, lc*8), "const out of range");
|
|
1344 |
assert(Displacement::is_validDisp(disp), "displacement out of range");
|
|
1345 |
|
|
1346 |
bool is_shortDisp = Displacement::is_shortDisp(disp);
|
|
1347 |
int store_offset = -1;
|
|
1348 |
|
|
1349 |
// For target len == 1 it's easy.
|
|
1350 |
if (lm == 1) {
|
|
1351 |
store_offset = offset();
|
|
1352 |
if (is_shortDisp) {
|
|
1353 |
z_mvi(disp, base, imm);
|
|
1354 |
return store_offset;
|
|
1355 |
} else {
|
|
1356 |
z_mviy(disp, base, imm);
|
|
1357 |
return store_offset;
|
|
1358 |
}
|
|
1359 |
}
|
|
1360 |
|
|
1361 |
// All the "good stuff" takes an unsigned displacement.
|
|
1362 |
if (is_shortDisp) {
|
|
1363 |
// NOTE: Cannot use clear_mem for imm==0, because it is not atomic.
|
|
1364 |
|
|
1365 |
store_offset = offset();
|
|
1366 |
switch (lm) {
|
|
1367 |
case 2: // Lc == 1 handled correctly here, even for unsigned. Instruction does no widening.
|
|
1368 |
z_mvhhi(disp, base, imm);
|
|
1369 |
return store_offset;
|
|
1370 |
case 4:
|
|
1371 |
if (Immediate::is_simm16(imm)) {
|
|
1372 |
z_mvhi(disp, base, imm);
|
|
1373 |
return store_offset;
|
|
1374 |
}
|
|
1375 |
break;
|
|
1376 |
case 8:
|
|
1377 |
if (Immediate::is_simm16(imm)) {
|
|
1378 |
z_mvghi(disp, base, imm);
|
|
1379 |
return store_offset;
|
|
1380 |
}
|
|
1381 |
break;
|
|
1382 |
default:
|
|
1383 |
ShouldNotReachHere();
|
|
1384 |
break;
|
|
1385 |
}
|
|
1386 |
}
|
|
1387 |
|
|
1388 |
// Can't optimize, so load value and store it.
|
|
1389 |
guarantee(scratch != noreg, " need a scratch register here !");
|
|
1390 |
if (imm != 0) {
|
|
1391 |
load_const_optimized(scratch, imm); // Preserves CC anyway.
|
|
1392 |
} else {
|
|
1393 |
// Leave CC alone!!
|
|
1394 |
(void) clear_reg(scratch, true, false); // Indicate unused result.
|
|
1395 |
}
|
|
1396 |
|
|
1397 |
store_offset = offset();
|
|
1398 |
if (is_shortDisp) {
|
|
1399 |
switch (lm) {
|
|
1400 |
case 2:
|
|
1401 |
z_sth(scratch, disp, Z_R0, base);
|
|
1402 |
return store_offset;
|
|
1403 |
case 4:
|
|
1404 |
z_st(scratch, disp, Z_R0, base);
|
|
1405 |
return store_offset;
|
|
1406 |
case 8:
|
|
1407 |
z_stg(scratch, disp, Z_R0, base);
|
|
1408 |
return store_offset;
|
|
1409 |
default:
|
|
1410 |
ShouldNotReachHere();
|
|
1411 |
break;
|
|
1412 |
}
|
|
1413 |
} else {
|
|
1414 |
switch (lm) {
|
|
1415 |
case 2:
|
|
1416 |
z_sthy(scratch, disp, Z_R0, base);
|
|
1417 |
return store_offset;
|
|
1418 |
case 4:
|
|
1419 |
z_sty(scratch, disp, Z_R0, base);
|
|
1420 |
return store_offset;
|
|
1421 |
case 8:
|
|
1422 |
z_stg(scratch, disp, Z_R0, base);
|
|
1423 |
return store_offset;
|
|
1424 |
default:
|
|
1425 |
ShouldNotReachHere();
|
|
1426 |
break;
|
|
1427 |
}
|
|
1428 |
}
|
|
1429 |
return -1; // should not reach here
|
|
1430 |
}
|
|
1431 |
|
|
1432 |
//===================================================================
|
|
1433 |
//=== N O T P A T CH A B L E C O N S T A N T S ===
|
|
1434 |
//===================================================================
|
|
1435 |
|
|
1436 |
// Load constant x into register t with a fast instrcution sequence
|
|
1437 |
// depending on the bits in x. Preserves CC under all circumstances.
|
|
1438 |
int MacroAssembler::load_const_optimized_rtn_len(Register t, long x, bool emit) {
|
|
1439 |
if (x == 0) {
|
|
1440 |
int len;
|
|
1441 |
if (emit) {
|
|
1442 |
len = clear_reg(t, true, false);
|
|
1443 |
} else {
|
|
1444 |
len = 4;
|
|
1445 |
}
|
|
1446 |
return len;
|
|
1447 |
}
|
|
1448 |
|
|
1449 |
if (Immediate::is_simm16(x)) {
|
|
1450 |
if (emit) { z_lghi(t, x); }
|
|
1451 |
return 4;
|
|
1452 |
}
|
|
1453 |
|
|
1454 |
// 64 bit value: | part1 | part2 | part3 | part4 |
|
|
1455 |
// At least one part is not zero!
|
|
1456 |
int part1 = ((x >> 32) & 0xffff0000) >> 16;
|
|
1457 |
int part2 = (x >> 32) & 0x0000ffff;
|
|
1458 |
int part3 = (x & 0xffff0000) >> 16;
|
|
1459 |
int part4 = (x & 0x0000ffff);
|
|
1460 |
|
|
1461 |
// Lower word only (unsigned).
|
|
1462 |
if ((part1 == 0) && (part2 == 0)) {
|
|
1463 |
if (part3 == 0) {
|
|
1464 |
if (emit) z_llill(t, part4);
|
|
1465 |
return 4;
|
|
1466 |
}
|
|
1467 |
if (part4 == 0) {
|
|
1468 |
if (emit) z_llilh(t, part3);
|
|
1469 |
return 4;
|
|
1470 |
}
|
|
1471 |
if (emit) z_llilf(t, (int)(x & 0xffffffff));
|
|
1472 |
return 6;
|
|
1473 |
}
|
|
1474 |
|
|
1475 |
// Upper word only.
|
|
1476 |
if ((part3 == 0) && (part4 == 0)) {
|
|
1477 |
if (part1 == 0) {
|
|
1478 |
if (emit) z_llihl(t, part2);
|
|
1479 |
return 4;
|
|
1480 |
}
|
|
1481 |
if (part2 == 0) {
|
|
1482 |
if (emit) z_llihh(t, part1);
|
|
1483 |
return 4;
|
|
1484 |
}
|
|
1485 |
if (emit) z_llihf(t, (int)(x >> 32));
|
|
1486 |
return 6;
|
|
1487 |
}
|
|
1488 |
|
|
1489 |
// Lower word only (signed).
|
|
1490 |
if ((part1 == 0x0000ffff) && (part2 == 0x0000ffff) && ((part3 & 0x00008000) != 0)) {
|
|
1491 |
if (emit) z_lgfi(t, (int)(x & 0xffffffff));
|
|
1492 |
return 6;
|
|
1493 |
}
|
|
1494 |
|
|
1495 |
int len = 0;
|
|
1496 |
|
|
1497 |
if ((part1 == 0) || (part2 == 0)) {
|
|
1498 |
if (part1 == 0) {
|
|
1499 |
if (emit) z_llihl(t, part2);
|
|
1500 |
len += 4;
|
|
1501 |
} else {
|
|
1502 |
if (emit) z_llihh(t, part1);
|
|
1503 |
len += 4;
|
|
1504 |
}
|
|
1505 |
} else {
|
|
1506 |
if (emit) z_llihf(t, (int)(x >> 32));
|
|
1507 |
len += 6;
|
|
1508 |
}
|
|
1509 |
|
|
1510 |
if ((part3 == 0) || (part4 == 0)) {
|
|
1511 |
if (part3 == 0) {
|
|
1512 |
if (emit) z_iill(t, part4);
|
|
1513 |
len += 4;
|
|
1514 |
} else {
|
|
1515 |
if (emit) z_iilh(t, part3);
|
|
1516 |
len += 4;
|
|
1517 |
}
|
|
1518 |
} else {
|
|
1519 |
if (emit) z_iilf(t, (int)(x & 0xffffffff));
|
|
1520 |
len += 6;
|
|
1521 |
}
|
|
1522 |
return len;
|
|
1523 |
}
|
|
1524 |
|
|
1525 |
//=====================================================================
|
|
1526 |
//=== H I G H E R L E V E L B R A N C H E M I T T E R S ===
|
|
1527 |
//=====================================================================
|
|
1528 |
|
|
1529 |
// Note: In the worst case, one of the scratch registers is destroyed!!!
|
|
1530 |
void MacroAssembler::compare32_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& lbl) {
|
|
1531 |
// Right operand is constant.
|
|
1532 |
if (x2.is_constant()) {
|
|
1533 |
jlong value = x2.as_constant();
|
|
1534 |
compare_and_branch_optimized(r1, value, cond, lbl, /*len64=*/false, /*has_sign=*/true);
|
|
1535 |
return;
|
|
1536 |
}
|
|
1537 |
|
|
1538 |
// Right operand is in register.
|
|
1539 |
compare_and_branch_optimized(r1, x2.as_register(), cond, lbl, /*len64=*/false, /*has_sign=*/true);
|
|
1540 |
}
|
|
1541 |
|
|
1542 |
// Note: In the worst case, one of the scratch registers is destroyed!!!
|
|
1543 |
void MacroAssembler::compareU32_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& lbl) {
|
|
1544 |
// Right operand is constant.
|
|
1545 |
if (x2.is_constant()) {
|
|
1546 |
jlong value = x2.as_constant();
|
|
1547 |
compare_and_branch_optimized(r1, value, cond, lbl, /*len64=*/false, /*has_sign=*/false);
|
|
1548 |
return;
|
|
1549 |
}
|
|
1550 |
|
|
1551 |
// Right operand is in register.
|
|
1552 |
compare_and_branch_optimized(r1, x2.as_register(), cond, lbl, /*len64=*/false, /*has_sign=*/false);
|
|
1553 |
}
|
|
1554 |
|
|
1555 |
// Note: In the worst case, one of the scratch registers is destroyed!!!
|
|
1556 |
void MacroAssembler::compare64_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& lbl) {
|
|
1557 |
// Right operand is constant.
|
|
1558 |
if (x2.is_constant()) {
|
|
1559 |
jlong value = x2.as_constant();
|
|
1560 |
compare_and_branch_optimized(r1, value, cond, lbl, /*len64=*/true, /*has_sign=*/true);
|
|
1561 |
return;
|
|
1562 |
}
|
|
1563 |
|
|
1564 |
// Right operand is in register.
|
|
1565 |
compare_and_branch_optimized(r1, x2.as_register(), cond, lbl, /*len64=*/true, /*has_sign=*/true);
|
|
1566 |
}
|
|
1567 |
|
|
1568 |
void MacroAssembler::compareU64_and_branch(Register r1, RegisterOrConstant x2, branch_condition cond, Label& lbl) {
|
|
1569 |
// Right operand is constant.
|
|
1570 |
if (x2.is_constant()) {
|
|
1571 |
jlong value = x2.as_constant();
|
|
1572 |
compare_and_branch_optimized(r1, value, cond, lbl, /*len64=*/true, /*has_sign=*/false);
|
|
1573 |
return;
|
|
1574 |
}
|
|
1575 |
|
|
1576 |
// Right operand is in register.
|
|
1577 |
compare_and_branch_optimized(r1, x2.as_register(), cond, lbl, /*len64=*/true, /*has_sign=*/false);
|
|
1578 |
}
|
|
1579 |
|
|
1580 |
// Generate an optimal branch to the branch target.
|
|
1581 |
// Optimal means that a relative branch (brc or brcl) is used if the
|
|
1582 |
// branch distance is short enough. Loading the target address into a
|
|
1583 |
// register and branching via reg is used as fallback only.
|
|
1584 |
//
|
|
1585 |
// Used registers:
|
|
1586 |
// Z_R1 - work reg. Holds branch target address.
|
|
1587 |
// Used in fallback case only.
|
|
1588 |
//
|
|
1589 |
// This version of branch_optimized is good for cases where the target address is known
|
|
1590 |
// and constant, i.e. is never changed (no relocation, no patching).
|
|
1591 |
void MacroAssembler::branch_optimized(Assembler::branch_condition cond, address branch_addr) {
|
|
1592 |
address branch_origin = pc();
|
|
1593 |
|
|
1594 |
if (RelAddr::is_in_range_of_RelAddr16(branch_addr, branch_origin)) {
|
|
1595 |
z_brc(cond, branch_addr);
|
|
1596 |
} else if (RelAddr::is_in_range_of_RelAddr32(branch_addr, branch_origin)) {
|
|
1597 |
z_brcl(cond, branch_addr);
|
|
1598 |
} else {
|
|
1599 |
load_const_optimized(Z_R1, branch_addr); // CC must not get killed by load_const_optimized.
|
|
1600 |
z_bcr(cond, Z_R1);
|
|
1601 |
}
|
|
1602 |
}
|
|
1603 |
|
|
1604 |
// This version of branch_optimized is good for cases where the target address
|
|
1605 |
// is potentially not yet known at the time the code is emitted.
|
|
1606 |
//
|
|
1607 |
// One very common case is a branch to an unbound label which is handled here.
|
|
1608 |
// The caller might know (or hope) that the branch distance is short enough
|
|
1609 |
// to be encoded in a 16bit relative address. In this case he will pass a
|
|
1610 |
// NearLabel branch_target.
|
|
1611 |
// Care must be taken with unbound labels. Each call to target(label) creates
|
|
1612 |
// an entry in the patch queue for that label to patch all references of the label
|
|
1613 |
// once it gets bound. Those recorded patch locations must be patchable. Otherwise,
|
|
1614 |
// an assertion fires at patch time.
|
|
1615 |
void MacroAssembler::branch_optimized(Assembler::branch_condition cond, Label& branch_target) {
|
|
1616 |
if (branch_target.is_bound()) {
|
|
1617 |
address branch_addr = target(branch_target);
|
|
1618 |
branch_optimized(cond, branch_addr);
|
|
1619 |
} else {
|
|
1620 |
z_brcl(cond, branch_target); // Let's hope target is in range. Otherwise, we will abort at patch time.
|
|
1621 |
}
|
|
1622 |
}
|
|
1623 |
|
|
1624 |
// Generate an optimal compare and branch to the branch target.
|
|
1625 |
// Optimal means that a relative branch (clgrj, brc or brcl) is used if the
|
|
1626 |
// branch distance is short enough. Loading the target address into a
|
|
1627 |
// register and branching via reg is used as fallback only.
|
|
1628 |
//
|
|
1629 |
// Input:
|
|
1630 |
// r1 - left compare operand
|
|
1631 |
// r2 - right compare operand
|
|
1632 |
void MacroAssembler::compare_and_branch_optimized(Register r1,
|
|
1633 |
Register r2,
|
|
1634 |
Assembler::branch_condition cond,
|
|
1635 |
address branch_addr,
|
|
1636 |
bool len64,
|
|
1637 |
bool has_sign) {
|
|
1638 |
unsigned int casenum = (len64?2:0)+(has_sign?0:1);
|
|
1639 |
|
|
1640 |
address branch_origin = pc();
|
|
1641 |
if (VM_Version::has_CompareBranch() && RelAddr::is_in_range_of_RelAddr16(branch_addr, branch_origin)) {
|
|
1642 |
switch (casenum) {
|
|
1643 |
case 0: z_crj( r1, r2, cond, branch_addr); break;
|
|
1644 |
case 1: z_clrj (r1, r2, cond, branch_addr); break;
|
|
1645 |
case 2: z_cgrj(r1, r2, cond, branch_addr); break;
|
|
1646 |
case 3: z_clgrj(r1, r2, cond, branch_addr); break;
|
|
1647 |
default: ShouldNotReachHere(); break;
|
|
1648 |
}
|
|
1649 |
} else {
|
|
1650 |
switch (casenum) {
|
|
1651 |
case 0: z_cr( r1, r2); break;
|
|
1652 |
case 1: z_clr(r1, r2); break;
|
|
1653 |
case 2: z_cgr(r1, r2); break;
|
|
1654 |
case 3: z_clgr(r1, r2); break;
|
|
1655 |
default: ShouldNotReachHere(); break;
|
|
1656 |
}
|
|
1657 |
branch_optimized(cond, branch_addr);
|
|
1658 |
}
|
|
1659 |
}
|
|
1660 |
|
|
1661 |
// Generate an optimal compare and branch to the branch target.
|
|
1662 |
// Optimal means that a relative branch (clgij, brc or brcl) is used if the
|
|
1663 |
// branch distance is short enough. Loading the target address into a
|
|
1664 |
// register and branching via reg is used as fallback only.
|
|
1665 |
//
|
|
1666 |
// Input:
|
|
1667 |
// r1 - left compare operand (in register)
|
|
1668 |
// x2 - right compare operand (immediate)
|
|
1669 |
void MacroAssembler::compare_and_branch_optimized(Register r1,
|
|
1670 |
jlong x2,
|
|
1671 |
Assembler::branch_condition cond,
|
|
1672 |
Label& branch_target,
|
|
1673 |
bool len64,
|
|
1674 |
bool has_sign) {
|
|
1675 |
address branch_origin = pc();
|
|
1676 |
bool x2_imm8 = (has_sign && Immediate::is_simm8(x2)) || (!has_sign && Immediate::is_uimm8(x2));
|
|
1677 |
bool is_RelAddr16 = (branch_target.is_bound() &&
|
|
1678 |
RelAddr::is_in_range_of_RelAddr16(target(branch_target), branch_origin));
|
|
1679 |
unsigned int casenum = (len64?2:0)+(has_sign?0:1);
|
|
1680 |
|
|
1681 |
if (VM_Version::has_CompareBranch() && is_RelAddr16 && x2_imm8) {
|
|
1682 |
switch (casenum) {
|
|
1683 |
case 0: z_cij( r1, x2, cond, branch_target); break;
|
|
1684 |
case 1: z_clij(r1, x2, cond, branch_target); break;
|
|
1685 |
case 2: z_cgij(r1, x2, cond, branch_target); break;
|
|
1686 |
case 3: z_clgij(r1, x2, cond, branch_target); break;
|
|
1687 |
default: ShouldNotReachHere(); break;
|
|
1688 |
}
|
|
1689 |
return;
|
|
1690 |
}
|
|
1691 |
|
|
1692 |
if (x2 == 0) {
|
|
1693 |
switch (casenum) {
|
|
1694 |
case 0: z_ltr(r1, r1); break;
|
|
1695 |
case 1: z_ltr(r1, r1); break; // Caution: unsigned test only provides zero/notZero indication!
|
|
1696 |
case 2: z_ltgr(r1, r1); break;
|
|
1697 |
case 3: z_ltgr(r1, r1); break; // Caution: unsigned test only provides zero/notZero indication!
|
|
1698 |
default: ShouldNotReachHere(); break;
|
|
1699 |
}
|
|
1700 |
} else {
|
|
1701 |
if ((has_sign && Immediate::is_simm16(x2)) || (!has_sign && Immediate::is_uimm(x2, 15))) {
|
|
1702 |
switch (casenum) {
|
|
1703 |
case 0: z_chi(r1, x2); break;
|
|
1704 |
case 1: z_chi(r1, x2); break; // positive immediate < 2**15
|
|
1705 |
case 2: z_cghi(r1, x2); break;
|
|
1706 |
case 3: z_cghi(r1, x2); break; // positive immediate < 2**15
|
|
1707 |
default: break;
|
|
1708 |
}
|
|
1709 |
} else if ( (has_sign && Immediate::is_simm32(x2)) || (!has_sign && Immediate::is_uimm32(x2)) ) {
|
|
1710 |
switch (casenum) {
|
|
1711 |
case 0: z_cfi( r1, x2); break;
|
|
1712 |
case 1: z_clfi(r1, x2); break;
|
|
1713 |
case 2: z_cgfi(r1, x2); break;
|
|
1714 |
case 3: z_clgfi(r1, x2); break;
|
|
1715 |
default: ShouldNotReachHere(); break;
|
|
1716 |
}
|
|
1717 |
} else {
|
|
1718 |
// No instruction with immediate operand possible, so load into register.
|
|
1719 |
Register scratch = (r1 != Z_R0) ? Z_R0 : Z_R1;
|
|
1720 |
load_const_optimized(scratch, x2);
|
|
1721 |
switch (casenum) {
|
|
1722 |
case 0: z_cr( r1, scratch); break;
|
|
1723 |
case 1: z_clr(r1, scratch); break;
|
|
1724 |
case 2: z_cgr(r1, scratch); break;
|
|
1725 |
case 3: z_clgr(r1, scratch); break;
|
|
1726 |
default: ShouldNotReachHere(); break;
|
|
1727 |
}
|
|
1728 |
}
|
|
1729 |
}
|
|
1730 |
branch_optimized(cond, branch_target);
|
|
1731 |
}
|
|
1732 |
|
|
1733 |
// Generate an optimal compare and branch to the branch target.
|
|
1734 |
// Optimal means that a relative branch (clgrj, brc or brcl) is used if the
|
|
1735 |
// branch distance is short enough. Loading the target address into a
|
|
1736 |
// register and branching via reg is used as fallback only.
|
|
1737 |
//
|
|
1738 |
// Input:
|
|
1739 |
// r1 - left compare operand
|
|
1740 |
// r2 - right compare operand
|
|
1741 |
void MacroAssembler::compare_and_branch_optimized(Register r1,
|
|
1742 |
Register r2,
|
|
1743 |
Assembler::branch_condition cond,
|
|
1744 |
Label& branch_target,
|
|
1745 |
bool len64,
|
|
1746 |
bool has_sign) {
|
|
1747 |
unsigned int casenum = (len64?2:0)+(has_sign?0:1);
|
|
1748 |
|
|
1749 |
if (branch_target.is_bound()) {
|
|
1750 |
address branch_addr = target(branch_target);
|
|
1751 |
compare_and_branch_optimized(r1, r2, cond, branch_addr, len64, has_sign);
|
|
1752 |
} else {
|
|
1753 |
{
|
|
1754 |
switch (casenum) {
|
|
1755 |
case 0: z_cr( r1, r2); break;
|
|
1756 |
case 1: z_clr(r1, r2); break;
|
|
1757 |
case 2: z_cgr(r1, r2); break;
|
|
1758 |
case 3: z_clgr(r1, r2); break;
|
|
1759 |
default: ShouldNotReachHere(); break;
|
|
1760 |
}
|
|
1761 |
branch_optimized(cond, branch_target);
|
|
1762 |
}
|
|
1763 |
}
|
|
1764 |
}
|
|
1765 |
|
|
1766 |
//===========================================================================
|
|
1767 |
//=== END H I G H E R L E V E L B R A N C H E M I T T E R S ===
|
|
1768 |
//===========================================================================
|
|
1769 |
|
|
1770 |
AddressLiteral MacroAssembler::allocate_metadata_address(Metadata* obj) {
|
|
1771 |
assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
|
|
1772 |
int index = oop_recorder()->allocate_metadata_index(obj);
|
|
1773 |
RelocationHolder rspec = metadata_Relocation::spec(index);
|
|
1774 |
return AddressLiteral((address)obj, rspec);
|
|
1775 |
}
|
|
1776 |
|
|
1777 |
AddressLiteral MacroAssembler::constant_metadata_address(Metadata* obj) {
|
|
1778 |
assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
|
|
1779 |
int index = oop_recorder()->find_index(obj);
|
|
1780 |
RelocationHolder rspec = metadata_Relocation::spec(index);
|
|
1781 |
return AddressLiteral((address)obj, rspec);
|
|
1782 |
}
|
|
1783 |
|
|
1784 |
AddressLiteral MacroAssembler::allocate_oop_address(jobject obj) {
|
|
1785 |
assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
|
|
1786 |
int oop_index = oop_recorder()->allocate_oop_index(obj);
|
|
1787 |
return AddressLiteral(address(obj), oop_Relocation::spec(oop_index));
|
|
1788 |
}
|
|
1789 |
|
|
1790 |
AddressLiteral MacroAssembler::constant_oop_address(jobject obj) {
|
|
1791 |
assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
|
|
1792 |
int oop_index = oop_recorder()->find_index(obj);
|
|
1793 |
return AddressLiteral(address(obj), oop_Relocation::spec(oop_index));
|
|
1794 |
}
|
|
1795 |
|
|
1796 |
// NOTE: destroys r
|
|
1797 |
void MacroAssembler::c2bool(Register r, Register t) {
|
|
1798 |
z_lcr(t, r); // t = -r
|
|
1799 |
z_or(r, t); // r = -r OR r
|
|
1800 |
z_srl(r, 31); // Yields 0 if r was 0, 1 otherwise.
|
|
1801 |
}
|
|
1802 |
|
|
1803 |
RegisterOrConstant MacroAssembler::delayed_value_impl(intptr_t* delayed_value_addr,
|
|
1804 |
Register tmp,
|
|
1805 |
int offset) {
|
|
1806 |
intptr_t value = *delayed_value_addr;
|
|
1807 |
if (value != 0) {
|
|
1808 |
return RegisterOrConstant(value + offset);
|
|
1809 |
}
|
|
1810 |
|
|
1811 |
BLOCK_COMMENT("delayed_value {");
|
|
1812 |
// Load indirectly to solve generation ordering problem.
|
|
1813 |
load_absolute_address(tmp, (address) delayed_value_addr); // tmp = a;
|
|
1814 |
z_lg(tmp, 0, tmp); // tmp = *tmp;
|
|
1815 |
|
|
1816 |
#ifdef ASSERT
|
|
1817 |
NearLabel L;
|
|
1818 |
compare64_and_branch(tmp, (intptr_t)0L, Assembler::bcondNotEqual, L);
|
|
1819 |
z_illtrap();
|
|
1820 |
bind(L);
|
|
1821 |
#endif
|
|
1822 |
|
|
1823 |
if (offset != 0) {
|
|
1824 |
z_agfi(tmp, offset); // tmp = tmp + offset;
|
|
1825 |
}
|
|
1826 |
|
|
1827 |
BLOCK_COMMENT("} delayed_value");
|
|
1828 |
return RegisterOrConstant(tmp);
|
|
1829 |
}
|
|
1830 |
|
|
1831 |
// Patch instruction `inst' at offset `inst_pos' to refer to `dest_pos'
|
|
1832 |
// and return the resulting instruction.
|
|
1833 |
// Dest_pos and inst_pos are 32 bit only. These parms can only designate
|
|
1834 |
// relative positions.
|
|
1835 |
// Use correct argument types. Do not pre-calculate distance.
|
|
1836 |
unsigned long MacroAssembler::patched_branch(address dest_pos, unsigned long inst, address inst_pos) {
|
|
1837 |
int c = 0;
|
|
1838 |
unsigned long patched_inst = 0;
|
|
1839 |
if (is_call_pcrelative_short(inst) ||
|
|
1840 |
is_branch_pcrelative_short(inst) ||
|
|
1841 |
is_branchoncount_pcrelative_short(inst) ||
|
|
1842 |
is_branchonindex32_pcrelative_short(inst)) {
|
|
1843 |
c = 1;
|
|
1844 |
int m = fmask(15, 0); // simm16(-1, 16, 32);
|
|
1845 |
int v = simm16(RelAddr::pcrel_off16(dest_pos, inst_pos), 16, 32);
|
|
1846 |
patched_inst = (inst & ~m) | v;
|
|
1847 |
} else if (is_compareandbranch_pcrelative_short(inst)) {
|
|
1848 |
c = 2;
|
|
1849 |
long m = fmask(31, 16); // simm16(-1, 16, 48);
|
|
1850 |
long v = simm16(RelAddr::pcrel_off16(dest_pos, inst_pos), 16, 48);
|
|
1851 |
patched_inst = (inst & ~m) | v;
|
|
1852 |
} else if (is_branchonindex64_pcrelative_short(inst)) {
|
|
1853 |
c = 3;
|
|
1854 |
long m = fmask(31, 16); // simm16(-1, 16, 48);
|
|
1855 |
long v = simm16(RelAddr::pcrel_off16(dest_pos, inst_pos), 16, 48);
|
|
1856 |
patched_inst = (inst & ~m) | v;
|
|
1857 |
} else if (is_call_pcrelative_long(inst) || is_branch_pcrelative_long(inst)) {
|
|
1858 |
c = 4;
|
|
1859 |
long m = fmask(31, 0); // simm32(-1, 16, 48);
|
|
1860 |
long v = simm32(RelAddr::pcrel_off32(dest_pos, inst_pos), 16, 48);
|
|
1861 |
patched_inst = (inst & ~m) | v;
|
|
1862 |
} else if (is_pcrelative_long(inst)) { // These are the non-branch pc-relative instructions.
|
|
1863 |
c = 5;
|
|
1864 |
long m = fmask(31, 0); // simm32(-1, 16, 48);
|
|
1865 |
long v = simm32(RelAddr::pcrel_off32(dest_pos, inst_pos), 16, 48);
|
|
1866 |
patched_inst = (inst & ~m) | v;
|
|
1867 |
} else {
|
|
1868 |
print_dbg_msg(tty, inst, "not a relative branch", 0);
|
|
1869 |
dump_code_range(tty, inst_pos, 32, "not a pcrelative branch");
|
|
1870 |
ShouldNotReachHere();
|
|
1871 |
}
|
|
1872 |
|
|
1873 |
long new_off = get_pcrel_offset(patched_inst);
|
|
1874 |
if (new_off != (dest_pos-inst_pos)) {
|
|
1875 |
tty->print_cr("case %d: dest_pos = %p, inst_pos = %p, disp = %ld(%12.12lx)", c, dest_pos, inst_pos, new_off, new_off);
|
|
1876 |
print_dbg_msg(tty, inst, "<- original instruction: branch patching error", 0);
|
|
1877 |
print_dbg_msg(tty, patched_inst, "<- patched instruction: branch patching error", 0);
|
|
1878 |
#ifdef LUCY_DBG
|
|
1879 |
VM_Version::z_SIGSEGV();
|
|
1880 |
#endif
|
|
1881 |
ShouldNotReachHere();
|
|
1882 |
}
|
|
1883 |
return patched_inst;
|
|
1884 |
}
|
|
1885 |
|
|
1886 |
// Only called when binding labels (share/vm/asm/assembler.cpp)
|
|
1887 |
// Pass arguments as intended. Do not pre-calculate distance.
|
|
1888 |
void MacroAssembler::pd_patch_instruction(address branch, address target) {
|
|
1889 |
unsigned long stub_inst;
|
|
1890 |
int inst_len = get_instruction(branch, &stub_inst);
|
|
1891 |
|
|
1892 |
set_instruction(branch, patched_branch(target, stub_inst, branch), inst_len);
|
|
1893 |
}
|
|
1894 |
|
|
1895 |
|
|
1896 |
// Extract relative address (aka offset).
|
|
1897 |
// inv_simm16 works for 4-byte instructions only.
|
|
1898 |
// compare and branch instructions are 6-byte and have a 16bit offset "in the middle".
|
|
1899 |
long MacroAssembler::get_pcrel_offset(unsigned long inst) {
|
|
1900 |
|
|
1901 |
if (MacroAssembler::is_pcrelative_short(inst)) {
|
|
1902 |
if (((inst&0xFFFFffff00000000UL) == 0) && ((inst&0x00000000FFFF0000UL) != 0)) {
|
|
1903 |
return RelAddr::inv_pcrel_off16(inv_simm16(inst));
|
|
1904 |
} else {
|
|
1905 |
return RelAddr::inv_pcrel_off16(inv_simm16_48(inst));
|
|
1906 |
}
|
|
1907 |
}
|
|
1908 |
|
|
1909 |
if (MacroAssembler::is_pcrelative_long(inst)) {
|
|
1910 |
return RelAddr::inv_pcrel_off32(inv_simm32(inst));
|
|
1911 |
}
|
|
1912 |
|
|
1913 |
print_dbg_msg(tty, inst, "not a pcrelative instruction", 6);
|
|
1914 |
#ifdef LUCY_DBG
|
|
1915 |
VM_Version::z_SIGSEGV();
|
|
1916 |
#else
|
|
1917 |
ShouldNotReachHere();
|
|
1918 |
#endif
|
|
1919 |
return -1;
|
|
1920 |
}
|
|
1921 |
|
|
1922 |
long MacroAssembler::get_pcrel_offset(address pc) {
|
|
1923 |
unsigned long inst;
|
|
1924 |
unsigned int len = get_instruction(pc, &inst);
|
|
1925 |
|
|
1926 |
#ifdef ASSERT
|
|
1927 |
long offset;
|
|
1928 |
if (MacroAssembler::is_pcrelative_short(inst) || MacroAssembler::is_pcrelative_long(inst)) {
|
|
1929 |
offset = get_pcrel_offset(inst);
|
|
1930 |
} else {
|
|
1931 |
offset = -1;
|
|
1932 |
}
|
|
1933 |
|
|
1934 |
if (offset == -1) {
|
|
1935 |
dump_code_range(tty, pc, 32, "not a pcrelative instruction");
|
|
1936 |
#ifdef LUCY_DBG
|
|
1937 |
VM_Version::z_SIGSEGV();
|
|
1938 |
#else
|
|
1939 |
ShouldNotReachHere();
|
|
1940 |
#endif
|
|
1941 |
}
|
|
1942 |
return offset;
|
|
1943 |
#else
|
|
1944 |
return get_pcrel_offset(inst);
|
|
1945 |
#endif // ASSERT
|
|
1946 |
}
|
|
1947 |
|
|
1948 |
// Get target address from pc-relative instructions.
|
|
1949 |
address MacroAssembler::get_target_addr_pcrel(address pc) {
|
|
1950 |
assert(is_pcrelative_long(pc), "not a pcrelative instruction");
|
|
1951 |
return pc + get_pcrel_offset(pc);
|
|
1952 |
}
|
|
1953 |
|
|
1954 |
// Patch pc relative load address.
|
|
1955 |
void MacroAssembler::patch_target_addr_pcrel(address pc, address con) {
|
|
1956 |
unsigned long inst;
|
|
1957 |
// Offset is +/- 2**32 -> use long.
|
|
1958 |
ptrdiff_t distance = con - pc;
|
|
1959 |
|
|
1960 |
get_instruction(pc, &inst);
|
|
1961 |
|
|
1962 |
if (is_pcrelative_short(inst)) {
|
|
1963 |
*(short *)(pc+2) = RelAddr::pcrel_off16(con, pc); // Instructions are at least 2-byte aligned, no test required.
|
|
1964 |
|
|
1965 |
// Some extra safety net.
|
|
1966 |
if (!RelAddr::is_in_range_of_RelAddr16(distance)) {
|
|
1967 |
print_dbg_msg(tty, inst, "distance out of range (16bit)", 4);
|
|
1968 |
dump_code_range(tty, pc, 32, "distance out of range (16bit)");
|
|
1969 |
guarantee(RelAddr::is_in_range_of_RelAddr16(distance), "too far away (more than +/- 2**16");
|
|
1970 |
}
|
|
1971 |
return;
|
|
1972 |
}
|
|
1973 |
|
|
1974 |
if (is_pcrelative_long(inst)) {
|
|
1975 |
*(int *)(pc+2) = RelAddr::pcrel_off32(con, pc);
|
|
1976 |
|
|
1977 |
// Some Extra safety net.
|
|
1978 |
if (!RelAddr::is_in_range_of_RelAddr32(distance)) {
|
|
1979 |
print_dbg_msg(tty, inst, "distance out of range (32bit)", 6);
|
|
1980 |
dump_code_range(tty, pc, 32, "distance out of range (32bit)");
|
|
1981 |
guarantee(RelAddr::is_in_range_of_RelAddr32(distance), "too far away (more than +/- 2**32");
|
|
1982 |
}
|
|
1983 |
return;
|
|
1984 |
}
|
|
1985 |
|
|
1986 |
guarantee(false, "not a pcrelative instruction to patch!");
|
|
1987 |
}
|
|
1988 |
|
|
1989 |
// "Current PC" here means the address just behind the basr instruction.
|
|
1990 |
address MacroAssembler::get_PC(Register result) {
|
|
1991 |
z_basr(result, Z_R0); // Don't branch, just save next instruction address in result.
|
|
1992 |
return pc();
|
|
1993 |
}
|
|
1994 |
|
|
1995 |
// Get current PC + offset.
|
|
1996 |
// Offset given in bytes, must be even!
|
|
1997 |
// "Current PC" here means the address of the larl instruction plus the given offset.
|
|
1998 |
address MacroAssembler::get_PC(Register result, int64_t offset) {
|
|
1999 |
address here = pc();
|
|
2000 |
z_larl(result, offset/2); // Save target instruction address in result.
|
|
2001 |
return here + offset;
|
|
2002 |
}
|
|
2003 |
|
|
2004 |
// Resize_frame with SP(new) = SP(old) - [offset].
|
|
2005 |
void MacroAssembler::resize_frame_sub(Register offset, Register fp, bool load_fp)
|
|
2006 |
{
|
|
2007 |
assert_different_registers(offset, fp, Z_SP);
|
|
2008 |
if (load_fp) { z_lg(fp, _z_abi(callers_sp), Z_SP); }
|
|
2009 |
|
|
2010 |
z_sgr(Z_SP, offset);
|
|
2011 |
z_stg(fp, _z_abi(callers_sp), Z_SP);
|
|
2012 |
}
|
|
2013 |
|
|
2014 |
// Resize_frame with SP(new) = [addr].
|
|
2015 |
void MacroAssembler::resize_frame_absolute(Register addr, Register fp, bool load_fp) {
|
|
2016 |
assert_different_registers(addr, fp, Z_SP);
|
|
2017 |
if (load_fp) { z_lg(fp, _z_abi(callers_sp), Z_SP); }
|
|
2018 |
|
|
2019 |
if (addr != Z_R0) {
|
|
2020 |
// Minimize stalls by not using Z_SP immediately after update.
|
|
2021 |
z_stg(fp, _z_abi(callers_sp), addr);
|
|
2022 |
z_lgr(Z_SP, addr);
|
|
2023 |
} else {
|
|
2024 |
z_lgr(Z_SP, addr);
|
|
2025 |
z_stg(fp, _z_abi(callers_sp), Z_SP);
|
|
2026 |
}
|
|
2027 |
}
|
|
2028 |
|
|
2029 |
// Resize_frame with SP(new) = SP(old) + offset.
|
|
2030 |
void MacroAssembler::resize_frame(RegisterOrConstant offset, Register fp, bool load_fp) {
|
|
2031 |
assert_different_registers(fp, Z_SP);
|
|
2032 |
if (load_fp) z_lg(fp, _z_abi(callers_sp), Z_SP);
|
|
2033 |
|
|
2034 |
if (Displacement::is_validDisp((int)_z_abi(callers_sp) + offset.constant_or_zero())) {
|
|
2035 |
// Minimize stalls by first using, then updating Z_SP.
|
|
2036 |
// Do that only if we have a small positive offset or if ExtImm are available.
|
|
2037 |
z_stg(fp, Address(Z_SP, offset, _z_abi(callers_sp)));
|
|
2038 |
add64(Z_SP, offset);
|
|
2039 |
} else {
|
|
2040 |
add64(Z_SP, offset);
|
|
2041 |
z_stg(fp, _z_abi(callers_sp), Z_SP);
|
|
2042 |
}
|
|
2043 |
}
|
|
2044 |
|
|
2045 |
void MacroAssembler::push_frame(Register bytes, Register old_sp, bool copy_sp, bool bytes_with_inverted_sign) {
|
|
2046 |
#ifdef ASSERT
|
|
2047 |
assert_different_registers(bytes, old_sp, Z_SP);
|
|
2048 |
if (!copy_sp) {
|
|
2049 |
z_cgr(old_sp, Z_SP);
|
|
2050 |
asm_assert_eq("[old_sp]!=[Z_SP]", 0x211);
|
|
2051 |
}
|
|
2052 |
#endif
|
|
2053 |
if (copy_sp) { z_lgr(old_sp, Z_SP); }
|
|
2054 |
if (bytes_with_inverted_sign) {
|
|
2055 |
z_stg(old_sp, 0, bytes, Z_SP);
|
|
2056 |
add2reg_with_index(Z_SP, 0, bytes, Z_SP);
|
|
2057 |
} else {
|
|
2058 |
z_sgr(Z_SP, bytes); // Z_sgfr sufficient, but probably not faster.
|
|
2059 |
z_stg(old_sp, 0, Z_SP);
|
|
2060 |
}
|
|
2061 |
}
|
|
2062 |
|
|
2063 |
unsigned int MacroAssembler::push_frame(unsigned int bytes, Register scratch) {
|
|
2064 |
long offset = Assembler::align(bytes, frame::alignment_in_bytes);
|
|
2065 |
|
|
2066 |
if (Displacement::is_validDisp(-offset)) {
|
|
2067 |
// Minimize stalls by first using, then updating Z_SP.
|
|
2068 |
// Do that only if we have ExtImm available.
|
|
2069 |
z_stg(Z_SP, -offset, Z_SP);
|
|
2070 |
add2reg(Z_SP, -offset);
|
|
2071 |
} else {
|
|
2072 |
if (scratch != Z_R0 && scratch != Z_R1) {
|
|
2073 |
z_stg(Z_SP, -offset, Z_SP);
|
|
2074 |
add2reg(Z_SP, -offset);
|
|
2075 |
} else { // scratch == Z_R0 || scratch == Z_R1
|
|
2076 |
z_lgr(scratch, Z_SP);
|
|
2077 |
add2reg(Z_SP, -offset);
|
|
2078 |
z_stg(scratch, 0, Z_SP);
|
|
2079 |
}
|
|
2080 |
}
|
|
2081 |
return offset;
|
|
2082 |
}
|
|
2083 |
|
|
2084 |
// Push a frame of size `bytes' plus abi160 on top.
|
|
2085 |
unsigned int MacroAssembler::push_frame_abi160(unsigned int bytes) {
|
|
2086 |
BLOCK_COMMENT("push_frame_abi160 {");
|
|
2087 |
unsigned int res = push_frame(bytes + frame::z_abi_160_size);
|
|
2088 |
BLOCK_COMMENT("} push_frame_abi160");
|
|
2089 |
return res;
|
|
2090 |
}
|
|
2091 |
|
|
2092 |
// Pop current C frame.
|
|
2093 |
void MacroAssembler::pop_frame() {
|
|
2094 |
BLOCK_COMMENT("pop_frame:");
|
|
2095 |
Assembler::z_lg(Z_SP, _z_abi(callers_sp), Z_SP);
|
|
2096 |
}
|
|
2097 |
|
|
2098 |
void MacroAssembler::call_VM_leaf_base(address entry_point, bool allow_relocation) {
|
|
2099 |
if (allow_relocation) {
|
|
2100 |
call_c(entry_point);
|
|
2101 |
} else {
|
|
2102 |
call_c_static(entry_point);
|
|
2103 |
}
|
|
2104 |
}
|
|
2105 |
|
|
2106 |
void MacroAssembler::call_VM_leaf_base(address entry_point) {
|
|
2107 |
bool allow_relocation = true;
|
|
2108 |
call_VM_leaf_base(entry_point, allow_relocation);
|
|
2109 |
}
|
|
2110 |
|
|
2111 |
void MacroAssembler::call_VM_base(Register oop_result,
|
|
2112 |
Register last_java_sp,
|
|
2113 |
address entry_point,
|
|
2114 |
bool allow_relocation,
|
|
2115 |
bool check_exceptions) { // Defaults to true.
|
|
2116 |
// Allow_relocation indicates, if true, that the generated code shall
|
|
2117 |
// be fit for code relocation or referenced data relocation. In other
|
|
2118 |
// words: all addresses must be considered variable. PC-relative addressing
|
|
2119 |
// is not possible then.
|
|
2120 |
// On the other hand, if (allow_relocation == false), addresses and offsets
|
|
2121 |
// may be considered stable, enabling us to take advantage of some PC-relative
|
|
2122 |
// addressing tweaks. These might improve performance and reduce code size.
|
|
2123 |
|
|
2124 |
// Determine last_java_sp register.
|
|
2125 |
if (!last_java_sp->is_valid()) {
|
|
2126 |
last_java_sp = Z_SP; // Load Z_SP as SP.
|
|
2127 |
}
|
|
2128 |
|
|
2129 |
set_top_ijava_frame_at_SP_as_last_Java_frame(last_java_sp, Z_R1, allow_relocation);
|
|
2130 |
|
|
2131 |
// ARG1 must hold thread address.
|
|
2132 |
z_lgr(Z_ARG1, Z_thread);
|
|
2133 |
|
|
2134 |
address return_pc = NULL;
|
|
2135 |
if (allow_relocation) {
|
|
2136 |
return_pc = call_c(entry_point);
|
|
2137 |
} else {
|
|
2138 |
return_pc = call_c_static(entry_point);
|
|
2139 |
}
|
|
2140 |
|
|
2141 |
reset_last_Java_frame(allow_relocation);
|
|
2142 |
|
|
2143 |
// C++ interp handles this in the interpreter.
|
|
2144 |
check_and_handle_popframe(Z_thread);
|
|
2145 |
check_and_handle_earlyret(Z_thread);
|
|
2146 |
|
|
2147 |
// Check for pending exceptions.
|
|
2148 |
if (check_exceptions) {
|
|
2149 |
// Check for pending exceptions (java_thread is set upon return).
|
|
2150 |
load_and_test_long(Z_R0_scratch, Address(Z_thread, Thread::pending_exception_offset()));
|
|
2151 |
|
|
2152 |
// This used to conditionally jump to forward_exception however it is
|
|
2153 |
// possible if we relocate that the branch will not reach. So we must jump
|
|
2154 |
// around so we can always reach.
|
|
2155 |
|
|
2156 |
Label ok;
|
|
2157 |
z_bre(ok); // Bcondequal is the same as bcondZero.
|
|
2158 |
call_stub(StubRoutines::forward_exception_entry());
|
|
2159 |
bind(ok);
|
|
2160 |
}
|
|
2161 |
|
|
2162 |
// Get oop result if there is one and reset the value in the thread.
|
|
2163 |
if (oop_result->is_valid()) {
|
|
2164 |
get_vm_result(oop_result);
|
|
2165 |
}
|
|
2166 |
|
|
2167 |
_last_calls_return_pc = return_pc; // Wipe out other (error handling) calls.
|
|
2168 |
}
|
|
2169 |
|
|
2170 |
void MacroAssembler::call_VM_base(Register oop_result,
|
|
2171 |
Register last_java_sp,
|
|
2172 |
address entry_point,
|
|
2173 |
bool check_exceptions) { // Defaults to true.
|
|
2174 |
bool allow_relocation = true;
|
|
2175 |
call_VM_base(oop_result, last_java_sp, entry_point, allow_relocation, check_exceptions);
|
|
2176 |
}
|
|
2177 |
|
|
2178 |
// VM calls without explicit last_java_sp.
|
|
2179 |
|
|
2180 |
void MacroAssembler::call_VM(Register oop_result, address entry_point, bool check_exceptions) {
|
|
2181 |
// Call takes possible detour via InterpreterMacroAssembler.
|
|
2182 |
call_VM_base(oop_result, noreg, entry_point, true, check_exceptions);
|
|
2183 |
}
|
|
2184 |
|
|
2185 |
void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, bool check_exceptions) {
|
|
2186 |
// Z_ARG1 is reserved for the thread.
|
|
2187 |
lgr_if_needed(Z_ARG2, arg_1);
|
|
2188 |
call_VM(oop_result, entry_point, check_exceptions);
|
|
2189 |
}
|
|
2190 |
|
|
2191 |
void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, bool check_exceptions) {
|
|
2192 |
// Z_ARG1 is reserved for the thread.
|
|
2193 |
lgr_if_needed(Z_ARG2, arg_1);
|
|
2194 |
assert(arg_2 != Z_ARG2, "smashed argument");
|
|
2195 |
lgr_if_needed(Z_ARG3, arg_2);
|
|
2196 |
call_VM(oop_result, entry_point, check_exceptions);
|
|
2197 |
}
|
|
2198 |
|
|
2199 |
void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2,
|
|
2200 |
Register arg_3, bool check_exceptions) {
|
|
2201 |
// Z_ARG1 is reserved for the thread.
|
|
2202 |
lgr_if_needed(Z_ARG2, arg_1);
|
|
2203 |
assert(arg_2 != Z_ARG2, "smashed argument");
|
|
2204 |
lgr_if_needed(Z_ARG3, arg_2);
|
|
2205 |
assert(arg_3 != Z_ARG2 && arg_3 != Z_ARG3, "smashed argument");
|
|
2206 |
lgr_if_needed(Z_ARG4, arg_3);
|
|
2207 |
call_VM(oop_result, entry_point, check_exceptions);
|
|
2208 |
}
|
|
2209 |
|
|
2210 |
// VM static calls without explicit last_java_sp.
|
|
2211 |
|
|
2212 |
void MacroAssembler::call_VM_static(Register oop_result, address entry_point, bool check_exceptions) {
|
|
2213 |
// Call takes possible detour via InterpreterMacroAssembler.
|
|
2214 |
call_VM_base(oop_result, noreg, entry_point, false, check_exceptions);
|
|
2215 |
}
|
|
2216 |
|
|
2217 |
void MacroAssembler::call_VM_static(Register oop_result, address entry_point, Register arg_1, Register arg_2,
|
|
2218 |
Register arg_3, bool check_exceptions) {
|
|
2219 |
// Z_ARG1 is reserved for the thread.
|
|
2220 |
lgr_if_needed(Z_ARG2, arg_1);
|
|
2221 |
assert(arg_2 != Z_ARG2, "smashed argument");
|
|
2222 |
lgr_if_needed(Z_ARG3, arg_2);
|
|
2223 |
assert(arg_3 != Z_ARG2 && arg_3 != Z_ARG3, "smashed argument");
|
|
2224 |
lgr_if_needed(Z_ARG4, arg_3);
|
|
2225 |
call_VM_static(oop_result, entry_point, check_exceptions);
|
|
2226 |
}
|
|
2227 |
|
|
2228 |
// VM calls with explicit last_java_sp.
|
|
2229 |
|
|
2230 |
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, bool check_exceptions) {
|
|
2231 |
// Call takes possible detour via InterpreterMacroAssembler.
|
|
2232 |
call_VM_base(oop_result, last_java_sp, entry_point, true, check_exceptions);
|
|
2233 |
}
|
|
2234 |
|
|
2235 |
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, bool check_exceptions) {
|
|
2236 |
// Z_ARG1 is reserved for the thread.
|
|
2237 |
lgr_if_needed(Z_ARG2, arg_1);
|
|
2238 |
call_VM(oop_result, last_java_sp, entry_point, check_exceptions);
|
|
2239 |
}
|
|
2240 |
|
|
2241 |
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1,
|
|
2242 |
Register arg_2, bool check_exceptions) {
|
|
2243 |
// Z_ARG1 is reserved for the thread.
|
|
2244 |
lgr_if_needed(Z_ARG2, arg_1);
|
|
2245 |
assert(arg_2 != Z_ARG2, "smashed argument");
|
|
2246 |
lgr_if_needed(Z_ARG3, arg_2);
|
|
2247 |
call_VM(oop_result, last_java_sp, entry_point, check_exceptions);
|
|
2248 |
}
|
|
2249 |
|
|
2250 |
void MacroAssembler::call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1,
|
|
2251 |
Register arg_2, Register arg_3, bool check_exceptions) {
|
|
2252 |
// Z_ARG1 is reserved for the thread.
|
|
2253 |
lgr_if_needed(Z_ARG2, arg_1);
|
|
2254 |
assert(arg_2 != Z_ARG2, "smashed argument");
|
|
2255 |
lgr_if_needed(Z_ARG3, arg_2);
|
|
2256 |
assert(arg_3 != Z_ARG2 && arg_3 != Z_ARG3, "smashed argument");
|
|
2257 |
lgr_if_needed(Z_ARG4, arg_3);
|
|
2258 |
call_VM(oop_result, last_java_sp, entry_point, check_exceptions);
|
|
2259 |
}
|
|
2260 |
|
|
2261 |
// VM leaf calls.
|
|
2262 |
|
|
2263 |
void MacroAssembler::call_VM_leaf(address entry_point) {
|
|
2264 |
// Call takes possible detour via InterpreterMacroAssembler.
|
|
2265 |
call_VM_leaf_base(entry_point, true);
|
|
2266 |
}
|
|
2267 |
|
|
2268 |
void MacroAssembler::call_VM_leaf(address entry_point, Register arg_1) {
|
|
2269 |
if (arg_1 != noreg) lgr_if_needed(Z_ARG1, arg_1);
|
|
2270 |
call_VM_leaf(entry_point);
|
|
2271 |
}
|
|
2272 |
|
|
2273 |
void MacroAssembler::call_VM_leaf(address entry_point, Register arg_1, Register arg_2) {
|
|
2274 |
if (arg_1 != noreg) lgr_if_needed(Z_ARG1, arg_1);
|
|
2275 |
assert(arg_2 != Z_ARG1, "smashed argument");
|
|
2276 |
if (arg_2 != noreg) lgr_if_needed(Z_ARG2, arg_2);
|
|
2277 |
call_VM_leaf(entry_point);
|
|
2278 |
}
|
|
2279 |
|
|
2280 |
void MacroAssembler::call_VM_leaf(address entry_point, Register arg_1, Register arg_2, Register arg_3) {
|
|
2281 |
if (arg_1 != noreg) lgr_if_needed(Z_ARG1, arg_1);
|
|
2282 |
assert(arg_2 != Z_ARG1, "smashed argument");
|
|
2283 |
if (arg_2 != noreg) lgr_if_needed(Z_ARG2, arg_2);
|
|
2284 |
assert(arg_3 != Z_ARG1 && arg_3 != Z_ARG2, "smashed argument");
|
|
2285 |
if (arg_3 != noreg) lgr_if_needed(Z_ARG3, arg_3);
|
|
2286 |
call_VM_leaf(entry_point);
|
|
2287 |
}
|
|
2288 |
|
|
2289 |
// Static VM leaf calls.
|
|
2290 |
// Really static VM leaf calls are never patched.
|
|
2291 |
|
|
2292 |
void MacroAssembler::call_VM_leaf_static(address entry_point) {
|
|
2293 |
// Call takes possible detour via InterpreterMacroAssembler.
|
|
2294 |
call_VM_leaf_base(entry_point, false);
|
|
2295 |
}
|
|
2296 |
|
|
2297 |
void MacroAssembler::call_VM_leaf_static(address entry_point, Register arg_1) {
|
|
2298 |
if (arg_1 != noreg) lgr_if_needed(Z_ARG1, arg_1);
|
|
2299 |
call_VM_leaf_static(entry_point);
|
|
2300 |
}
|
|
2301 |
|
|
2302 |
void MacroAssembler::call_VM_leaf_static(address entry_point, Register arg_1, Register arg_2) {
|
|
2303 |
if (arg_1 != noreg) lgr_if_needed(Z_ARG1, arg_1);
|
|
2304 |
assert(arg_2 != Z_ARG1, "smashed argument");
|
|
2305 |
if (arg_2 != noreg) lgr_if_needed(Z_ARG2, arg_2);
|
|
2306 |
call_VM_leaf_static(entry_point);
|
|
2307 |
}
|
|
2308 |
|
|
2309 |
void MacroAssembler::call_VM_leaf_static(address entry_point, Register arg_1, Register arg_2, Register arg_3) {
|
|
2310 |
if (arg_1 != noreg) lgr_if_needed(Z_ARG1, arg_1);
|
|
2311 |
assert(arg_2 != Z_ARG1, "smashed argument");
|
|
2312 |
if (arg_2 != noreg) lgr_if_needed(Z_ARG2, arg_2);
|
|
2313 |
assert(arg_3 != Z_ARG1 && arg_3 != Z_ARG2, "smashed argument");
|
|
2314 |
if (arg_3 != noreg) lgr_if_needed(Z_ARG3, arg_3);
|
|
2315 |
call_VM_leaf_static(entry_point);
|
|
2316 |
}
|
|
2317 |
|
|
2318 |
// Don't use detour via call_c(reg).
|
|
2319 |
address MacroAssembler::call_c(address function_entry) {
|
|
2320 |
load_const(Z_R1, function_entry);
|
|
2321 |
return call(Z_R1);
|
|
2322 |
}
|
|
2323 |
|
|
2324 |
// Variant for really static (non-relocatable) calls which are never patched.
|
|
2325 |
address MacroAssembler::call_c_static(address function_entry) {
|
|
2326 |
load_absolute_address(Z_R1, function_entry);
|
|
2327 |
#if 0 // def ASSERT
|
|
2328 |
// Verify that call site did not move.
|
|
2329 |
load_const_optimized(Z_R0, function_entry);
|
|
2330 |
z_cgr(Z_R1, Z_R0);
|
|
2331 |
z_brc(bcondEqual, 3);
|
|
2332 |
z_illtrap(0xba);
|
|
2333 |
#endif
|
|
2334 |
return call(Z_R1);
|
|
2335 |
}
|
|
2336 |
|
|
2337 |
address MacroAssembler::call_c_opt(address function_entry) {
|
|
2338 |
bool success = call_far_patchable(function_entry, -2 /* emit relocation + constant */);
|
|
2339 |
_last_calls_return_pc = success ? pc() : NULL;
|
|
2340 |
return _last_calls_return_pc;
|
|
2341 |
}
|
|
2342 |
|
|
2343 |
// Identify a call_far_patchable instruction: LARL + LG + BASR
|
|
2344 |
//
|
|
2345 |
// nop ; optionally, if required for alignment
|
|
2346 |
// lgrl rx,A(TOC entry) ; PC-relative access into constant pool
|
|
2347 |
// basr Z_R14,rx ; end of this instruction must be aligned to a word boundary
|
|
2348 |
//
|
|
2349 |
// Code pattern will eventually get patched into variant2 (see below for detection code).
|
|
2350 |
//
|
|
2351 |
bool MacroAssembler::is_call_far_patchable_variant0_at(address instruction_addr) {
|
|
2352 |
address iaddr = instruction_addr;
|
|
2353 |
|
|
2354 |
// Check for the actual load instruction.
|
|
2355 |
if (!is_load_const_from_toc(iaddr)) { return false; }
|
|
2356 |
iaddr += load_const_from_toc_size();
|
|
2357 |
|
|
2358 |
// Check for the call (BASR) instruction, finally.
|
|
2359 |
assert(iaddr-instruction_addr+call_byregister_size() == call_far_patchable_size(), "size mismatch");
|
|
2360 |
return is_call_byregister(iaddr);
|
|
2361 |
}
|
|
2362 |
|
|
2363 |
// Identify a call_far_patchable instruction: BRASL
|
|
2364 |
//
|
|
2365 |
// Code pattern to suits atomic patching:
|
|
2366 |
// nop ; Optionally, if required for alignment.
|
|
2367 |
// nop ... ; Multiple filler nops to compensate for size difference (variant0 is longer).
|
|
2368 |
// nop ; For code pattern detection: Prepend each BRASL with a nop.
|
|
2369 |
// brasl Z_R14,<reladdr> ; End of code must be 4-byte aligned !
|
|
2370 |
bool MacroAssembler::is_call_far_patchable_variant2_at(address instruction_addr) {
|
|
2371 |
const address call_addr = (address)((intptr_t)instruction_addr + call_far_patchable_size() - call_far_pcrelative_size());
|
|
2372 |
|
|
2373 |
// Check for correct number of leading nops.
|
|
2374 |
address iaddr;
|
|
2375 |
for (iaddr = instruction_addr; iaddr < call_addr; iaddr += nop_size()) {
|
|
2376 |
if (!is_z_nop(iaddr)) { return false; }
|
|
2377 |
}
|
|
2378 |
assert(iaddr == call_addr, "sanity");
|
|
2379 |
|
|
2380 |
// --> Check for call instruction.
|
|
2381 |
if (is_call_far_pcrelative(call_addr)) {
|
|
2382 |
assert(call_addr-instruction_addr+call_far_pcrelative_size() == call_far_patchable_size(), "size mismatch");
|
|
2383 |
return true;
|
|
2384 |
}
|
|
2385 |
|
|
2386 |
return false;
|
|
2387 |
}
|
|
2388 |
|
|
2389 |
// Emit a NOT mt-safely patchable 64 bit absolute call.
|
|
2390 |
// If toc_offset == -2, then the destination of the call (= target) is emitted
|
|
2391 |
// to the constant pool and a runtime_call relocation is added
|
|
2392 |
// to the code buffer.
|
|
2393 |
// If toc_offset != -2, target must already be in the constant pool at
|
|
2394 |
// _ctableStart+toc_offset (a caller can retrieve toc_offset
|
|
2395 |
// from the runtime_call relocation).
|
|
2396 |
// Special handling of emitting to scratch buffer when there is no constant pool.
|
|
2397 |
// Slightly changed code pattern. We emit an additional nop if we would
|
|
2398 |
// not end emitting at a word aligned address. This is to ensure
|
|
2399 |
// an atomically patchable displacement in brasl instructions.
|
|
2400 |
//
|
|
2401 |
// A call_far_patchable comes in different flavors:
|
|
2402 |
// - LARL(CP) / LG(CP) / BR (address in constant pool, access via CP register)
|
|
2403 |
// - LGRL(CP) / BR (address in constant pool, pc-relative accesss)
|
|
2404 |
// - BRASL (relative address of call target coded in instruction)
|
|
2405 |
// All flavors occupy the same amount of space. Length differences are compensated
|
|
2406 |
// by leading nops, such that the instruction sequence always ends at the same
|
|
2407 |
// byte offset. This is required to keep the return offset constant.
|
|
2408 |
// Furthermore, the return address (the end of the instruction sequence) is forced
|
|
2409 |
// to be on a 4-byte boundary. This is required for atomic patching, should we ever
|
|
2410 |
// need to patch the call target of the BRASL flavor.
|
|
2411 |
// RETURN value: false, if no constant pool entry could be allocated, true otherwise.
|
|
2412 |
bool MacroAssembler::call_far_patchable(address target, int64_t tocOffset) {
|
|
2413 |
// Get current pc and ensure word alignment for end of instr sequence.
|
|
2414 |
const address start_pc = pc();
|
|
2415 |
const intptr_t start_off = offset();
|
|
2416 |
assert(!call_far_patchable_requires_alignment_nop(start_pc), "call_far_patchable requires aligned address");
|
|
2417 |
const ptrdiff_t dist = (ptrdiff_t)(target - (start_pc + 2)); // Prepend each BRASL with a nop.
|
|
2418 |
const bool emit_target_to_pool = (tocOffset == -2) && !code_section()->scratch_emit();
|
|
2419 |
const bool emit_relative_call = !emit_target_to_pool &&
|
|
2420 |
RelAddr::is_in_range_of_RelAddr32(dist) &&
|
|
2421 |
ReoptimizeCallSequences &&
|
|
2422 |
!code_section()->scratch_emit();
|
|
2423 |
|
|
2424 |
if (emit_relative_call) {
|
|
2425 |
// Add padding to get the same size as below.
|
|
2426 |
const unsigned int padding = call_far_patchable_size() - call_far_pcrelative_size();
|
|
2427 |
unsigned int current_padding;
|
|
2428 |
for (current_padding = 0; current_padding < padding; current_padding += nop_size()) { z_nop(); }
|
|
2429 |
assert(current_padding == padding, "sanity");
|
|
2430 |
|
|
2431 |
// relative call: len = 2(nop) + 6 (brasl)
|
|
2432 |
// CodeBlob resize cannot occur in this case because
|
|
2433 |
// this call is emitted into pre-existing space.
|
|
2434 |
z_nop(); // Prepend each BRASL with a nop.
|
|
2435 |
z_brasl(Z_R14, target);
|
|
2436 |
} else {
|
|
2437 |
// absolute call: Get address from TOC.
|
|
2438 |
// len = (load TOC){6|0} + (load from TOC){6} + (basr){2} = {14|8}
|
|
2439 |
if (emit_target_to_pool) {
|
|
2440 |
// When emitting the call for the first time, we do not need to use
|
|
2441 |
// the pc-relative version. It will be patched anyway, when the code
|
|
2442 |
// buffer is copied.
|
|
2443 |
// Relocation is not needed when !ReoptimizeCallSequences.
|
|
2444 |
relocInfo::relocType rt = ReoptimizeCallSequences ? relocInfo::runtime_call_w_cp_type : relocInfo::none;
|
|
2445 |
AddressLiteral dest(target, rt);
|
|
2446 |
// Store_oop_in_toc() adds dest to the constant table. As side effect, this kills
|
|
2447 |
// inst_mark(). Reset if possible.
|
|
2448 |
bool reset_mark = (inst_mark() == pc());
|
|
2449 |
tocOffset = store_oop_in_toc(dest);
|
|
2450 |
if (reset_mark) { set_inst_mark(); }
|
|
2451 |
if (tocOffset == -1) {
|
|
2452 |
return false; // Couldn't create constant pool entry.
|
|
2453 |
}
|
|
2454 |
}
|
|
2455 |
assert(offset() == start_off, "emit no code before this point!");
|
|
2456 |
|
|
2457 |
address tocPos = pc() + tocOffset;
|
|
2458 |
if (emit_target_to_pool) {
|
|
2459 |
tocPos = code()->consts()->start() + tocOffset;
|
|
2460 |
}
|
|
2461 |
load_long_pcrelative(Z_R14, tocPos);
|
|
2462 |
z_basr(Z_R14, Z_R14);
|
|
2463 |
}
|
|
2464 |
|
|
2465 |
#ifdef ASSERT
|
|
2466 |
// Assert that we can identify the emitted call.
|
|
2467 |
assert(is_call_far_patchable_at(addr_at(start_off)), "can't identify emitted call");
|
|
2468 |
assert(offset() == start_off+call_far_patchable_size(), "wrong size");
|
|
2469 |
|
|
2470 |
if (emit_target_to_pool) {
|
|
2471 |
assert(get_dest_of_call_far_patchable_at(addr_at(start_off), code()->consts()->start()) == target,
|
|
2472 |
"wrong encoding of dest address");
|
|
2473 |
}
|
|
2474 |
#endif
|
|
2475 |
return true; // success
|
|
2476 |
}
|
|
2477 |
|
|
2478 |
// Identify a call_far_patchable instruction.
|
|
2479 |
// For more detailed information see header comment of call_far_patchable.
|
|
2480 |
bool MacroAssembler::is_call_far_patchable_at(address instruction_addr) {
|
|
2481 |
return is_call_far_patchable_variant2_at(instruction_addr) || // short version: BRASL
|
|
2482 |
is_call_far_patchable_variant0_at(instruction_addr); // long version LARL + LG + BASR
|
|
2483 |
}
|
|
2484 |
|
|
2485 |
// Does the call_far_patchable instruction use a pc-relative encoding
|
|
2486 |
// of the call destination?
|
|
2487 |
bool MacroAssembler::is_call_far_patchable_pcrelative_at(address instruction_addr) {
|
|
2488 |
// Variant 2 is pc-relative.
|
|
2489 |
return is_call_far_patchable_variant2_at(instruction_addr);
|
|
2490 |
}
|
|
2491 |
|
|
2492 |
bool MacroAssembler::is_call_far_pcrelative(address instruction_addr) {
|
|
2493 |
// Prepend each BRASL with a nop.
|
|
2494 |
return is_z_nop(instruction_addr) && is_z_brasl(instruction_addr + nop_size()); // Match at position after one nop required.
|
|
2495 |
}
|
|
2496 |
|
|
2497 |
// Set destination address of a call_far_patchable instruction.
|
|
2498 |
void MacroAssembler::set_dest_of_call_far_patchable_at(address instruction_addr, address dest, int64_t tocOffset) {
|
|
2499 |
ResourceMark rm;
|
|
2500 |
|
|
2501 |
// Now that CP entry is verified, patch call to a pc-relative call (if circumstances permit).
|
|
2502 |
int code_size = MacroAssembler::call_far_patchable_size();
|
|
2503 |
CodeBuffer buf(instruction_addr, code_size);
|
|
2504 |
MacroAssembler masm(&buf);
|
|
2505 |
masm.call_far_patchable(dest, tocOffset);
|
|
2506 |
ICache::invalidate_range(instruction_addr, code_size); // Empty on z.
|
|
2507 |
}
|
|
2508 |
|
|
2509 |
// Get dest address of a call_far_patchable instruction.
|
|
2510 |
address MacroAssembler::get_dest_of_call_far_patchable_at(address instruction_addr, address ctable) {
|
|
2511 |
// Dynamic TOC: absolute address in constant pool.
|
|
2512 |
// Check variant2 first, it is more frequent.
|
|
2513 |
|
|
2514 |
// Relative address encoded in call instruction.
|
|
2515 |
if (is_call_far_patchable_variant2_at(instruction_addr)) {
|
|
2516 |
return MacroAssembler::get_target_addr_pcrel(instruction_addr + nop_size()); // Prepend each BRASL with a nop.
|
|
2517 |
|
|
2518 |
// Absolute address in constant pool.
|
|
2519 |
} else if (is_call_far_patchable_variant0_at(instruction_addr)) {
|
|
2520 |
address iaddr = instruction_addr;
|
|
2521 |
|
|
2522 |
long tocOffset = get_load_const_from_toc_offset(iaddr);
|
|
2523 |
address tocLoc = iaddr + tocOffset;
|
|
2524 |
return *(address *)(tocLoc);
|
|
2525 |
} else {
|
|
2526 |
fprintf(stderr, "MacroAssembler::get_dest_of_call_far_patchable_at has a problem at %p:\n", instruction_addr);
|
|
2527 |
fprintf(stderr, "not a call_far_patchable: %16.16lx %16.16lx, len = %d\n",
|
|
2528 |
*(unsigned long*)instruction_addr,
|
|
2529 |
*(unsigned long*)(instruction_addr+8),
|
|
2530 |
call_far_patchable_size());
|
|
2531 |
Disassembler::decode(instruction_addr, instruction_addr+call_far_patchable_size());
|
|
2532 |
ShouldNotReachHere();
|
|
2533 |
return NULL;
|
|
2534 |
}
|
|
2535 |
}
|
|
2536 |
|
|
2537 |
void MacroAssembler::align_call_far_patchable(address pc) {
|
|
2538 |
if (call_far_patchable_requires_alignment_nop(pc)) { z_nop(); }
|
|
2539 |
}
|
|
2540 |
|
|
2541 |
void MacroAssembler::check_and_handle_earlyret(Register java_thread) {
|
|
2542 |
}
|
|
2543 |
|
|
2544 |
void MacroAssembler::check_and_handle_popframe(Register java_thread) {
|
|
2545 |
}
|
|
2546 |
|
|
2547 |
// Read from the polling page.
|
|
2548 |
// Use TM or TMY instruction, depending on read offset.
|
|
2549 |
// offset = 0: Use TM, safepoint polling.
|
|
2550 |
// offset < 0: Use TMY, profiling safepoint polling.
|
|
2551 |
void MacroAssembler::load_from_polling_page(Register polling_page_address, int64_t offset) {
|
|
2552 |
if (Immediate::is_uimm12(offset)) {
|
|
2553 |
z_tm(offset, polling_page_address, mask_safepoint);
|
|
2554 |
} else {
|
|
2555 |
z_tmy(offset, polling_page_address, mask_profiling);
|
|
2556 |
}
|
|
2557 |
}
|
|
2558 |
|
|
2559 |
// Check whether z_instruction is a read access to the polling page
|
|
2560 |
// which was emitted by load_from_polling_page(..).
|
|
2561 |
bool MacroAssembler::is_load_from_polling_page(address instr_loc) {
|
|
2562 |
unsigned long z_instruction;
|
|
2563 |
unsigned int ilen = get_instruction(instr_loc, &z_instruction);
|
|
2564 |
|
|
2565 |
if (ilen == 2) { return false; } // It's none of the allowed instructions.
|
|
2566 |
|
|
2567 |
if (ilen == 4) {
|
|
2568 |
if (!is_z_tm(z_instruction)) { return false; } // It's len=4, but not a z_tm. fail.
|
|
2569 |
|
|
2570 |
int ms = inv_mask(z_instruction,8,32); // mask
|
|
2571 |
int ra = inv_reg(z_instruction,16,32); // base register
|
|
2572 |
int ds = inv_uimm12(z_instruction); // displacement
|
|
2573 |
|
|
2574 |
if (!(ds == 0 && ra != 0 && ms == mask_safepoint)) {
|
|
2575 |
return false; // It's not a z_tm(0, ra, mask_safepoint). Fail.
|
|
2576 |
}
|
|
2577 |
|
|
2578 |
} else { /* if (ilen == 6) */
|
|
2579 |
|
|
2580 |
assert(!is_z_lg(z_instruction), "old form (LG) polling page access. Please fix and use TM(Y).");
|
|
2581 |
|
|
2582 |
if (!is_z_tmy(z_instruction)) { return false; } // It's len=6, but not a z_tmy. fail.
|
|
2583 |
|
|
2584 |
int ms = inv_mask(z_instruction,8,48); // mask
|
|
2585 |
int ra = inv_reg(z_instruction,16,48); // base register
|
|
2586 |
int ds = inv_simm20(z_instruction); // displacement
|
|
2587 |
}
|
|
2588 |
|
|
2589 |
return true;
|
|
2590 |
}
|
|
2591 |
|
|
2592 |
// Extract poll address from instruction and ucontext.
|
|
2593 |
address MacroAssembler::get_poll_address(address instr_loc, void* ucontext) {
|
|
2594 |
assert(ucontext != NULL, "must have ucontext");
|
|
2595 |
ucontext_t* uc = (ucontext_t*) ucontext;
|
|
2596 |
unsigned long z_instruction;
|
|
2597 |
unsigned int ilen = get_instruction(instr_loc, &z_instruction);
|
|
2598 |
|
|
2599 |
if (ilen == 4 && is_z_tm(z_instruction)) {
|
|
2600 |
int ra = inv_reg(z_instruction, 16, 32); // base register
|
|
2601 |
int ds = inv_uimm12(z_instruction); // displacement
|
|
2602 |
address addr = (address)uc->uc_mcontext.gregs[ra];
|
|
2603 |
return addr + ds;
|
|
2604 |
} else if (ilen == 6 && is_z_tmy(z_instruction)) {
|
|
2605 |
int ra = inv_reg(z_instruction, 16, 48); // base register
|
|
2606 |
int ds = inv_simm20(z_instruction); // displacement
|
|
2607 |
address addr = (address)uc->uc_mcontext.gregs[ra];
|
|
2608 |
return addr + ds;
|
|
2609 |
}
|
|
2610 |
|
|
2611 |
ShouldNotReachHere();
|
|
2612 |
return NULL;
|
|
2613 |
}
|
|
2614 |
|
|
2615 |
// Extract poll register from instruction.
|
|
2616 |
uint MacroAssembler::get_poll_register(address instr_loc) {
|
|
2617 |
unsigned long z_instruction;
|
|
2618 |
unsigned int ilen = get_instruction(instr_loc, &z_instruction);
|
|
2619 |
|
|
2620 |
if (ilen == 4 && is_z_tm(z_instruction)) {
|
|
2621 |
return (uint)inv_reg(z_instruction, 16, 32); // base register
|
|
2622 |
} else if (ilen == 6 && is_z_tmy(z_instruction)) {
|
|
2623 |
return (uint)inv_reg(z_instruction, 16, 48); // base register
|
|
2624 |
}
|
|
2625 |
|
|
2626 |
ShouldNotReachHere();
|
|
2627 |
return 0;
|
|
2628 |
}
|
|
2629 |
|
|
2630 |
bool MacroAssembler::is_memory_serialization(int instruction, JavaThread* thread, void* ucontext) {
|
|
2631 |
ShouldNotCallThis();
|
|
2632 |
return false;
|
|
2633 |
}
|
|
2634 |
|
|
2635 |
// Write serialization page so VM thread can do a pseudo remote membar
|
|
2636 |
// We use the current thread pointer to calculate a thread specific
|
|
2637 |
// offset to write to within the page. This minimizes bus traffic
|
|
2638 |
// due to cache line collision.
|
|
2639 |
void MacroAssembler::serialize_memory(Register thread, Register tmp1, Register tmp2) {
|
|
2640 |
assert_different_registers(tmp1, tmp2);
|
|
2641 |
z_sllg(tmp2, thread, os::get_serialize_page_shift_count());
|
|
2642 |
load_const_optimized(tmp1, (long) os::get_memory_serialize_page());
|
|
2643 |
|
|
2644 |
int mask = os::get_serialize_page_mask();
|
|
2645 |
if (Immediate::is_uimm16(mask)) {
|
|
2646 |
z_nill(tmp2, mask);
|
|
2647 |
z_llghr(tmp2, tmp2);
|
|
2648 |
} else {
|
|
2649 |
z_nilf(tmp2, mask);
|
|
2650 |
z_llgfr(tmp2, tmp2);
|
|
2651 |
}
|
|
2652 |
|
|
2653 |
z_release();
|
|
2654 |
z_st(Z_R0, 0, tmp2, tmp1);
|
|
2655 |
}
|
|
2656 |
|
|
2657 |
// Don't rely on register locking, always use Z_R1 as scratch register instead.
|
|
2658 |
void MacroAssembler::bang_stack_with_offset(int offset) {
|
|
2659 |
// Stack grows down, caller passes positive offset.
|
|
2660 |
assert(offset > 0, "must bang with positive offset");
|
|
2661 |
if (Displacement::is_validDisp(-offset)) {
|
|
2662 |
z_tmy(-offset, Z_SP, mask_stackbang);
|
|
2663 |
} else {
|
|
2664 |
add2reg(Z_R1, -offset, Z_SP); // Do not destroy Z_SP!!!
|
|
2665 |
z_tm(0, Z_R1, mask_stackbang); // Just banging.
|
|
2666 |
}
|
|
2667 |
}
|
|
2668 |
|
|
2669 |
// Defines obj, preserves var_size_in_bytes, okay for t2 == var_size_in_bytes.
|
|
2670 |
void MacroAssembler::tlab_allocate(Register obj,
|
|
2671 |
Register var_size_in_bytes,
|
|
2672 |
int con_size_in_bytes,
|
|
2673 |
Register t1,
|
|
2674 |
Label& slow_case) {
|
|
2675 |
assert_different_registers(obj, var_size_in_bytes, t1);
|
|
2676 |
Register end = t1;
|
|
2677 |
Register thread = Z_thread;
|
|
2678 |
|
|
2679 |
z_lg(obj, Address(thread, JavaThread::tlab_top_offset()));
|
|
2680 |
if (var_size_in_bytes == noreg) {
|
|
2681 |
z_lay(end, Address(obj, con_size_in_bytes));
|
|
2682 |
} else {
|
|
2683 |
z_lay(end, Address(obj, var_size_in_bytes));
|
|
2684 |
}
|
|
2685 |
z_cg(end, Address(thread, JavaThread::tlab_end_offset()));
|
|
2686 |
branch_optimized(bcondHigh, slow_case);
|
|
2687 |
|
|
2688 |
// Update the tlab top pointer.
|
|
2689 |
z_stg(end, Address(thread, JavaThread::tlab_top_offset()));
|
|
2690 |
|
|
2691 |
// Recover var_size_in_bytes if necessary.
|
|
2692 |
if (var_size_in_bytes == end) {
|
|
2693 |
z_sgr(var_size_in_bytes, obj);
|
|
2694 |
}
|
|
2695 |
}
|
|
2696 |
|
|
2697 |
// Emitter for interface method lookup.
|
|
2698 |
// input: recv_klass, intf_klass, itable_index
|
|
2699 |
// output: method_result
|
|
2700 |
// kills: itable_index, temp1_reg, Z_R0, Z_R1
|
|
2701 |
// TODO: Temp2_reg is unused. we may use this emitter also in the itable stubs.
|
|
2702 |
// If the register is still not needed then, remove it.
|
|
2703 |
void MacroAssembler::lookup_interface_method(Register recv_klass,
|
|
2704 |
Register intf_klass,
|
|
2705 |
RegisterOrConstant itable_index,
|
|
2706 |
Register method_result,
|
|
2707 |
Register temp1_reg,
|
|
2708 |
Register temp2_reg,
|
|
2709 |
Label& no_such_interface) {
|
|
2710 |
|
|
2711 |
const Register vtable_len = temp1_reg; // Used to compute itable_entry_addr.
|
|
2712 |
const Register itable_entry_addr = Z_R1_scratch;
|
|
2713 |
const Register itable_interface = Z_R0_scratch;
|
|
2714 |
|
|
2715 |
BLOCK_COMMENT("lookup_interface_method {");
|
|
2716 |
|
|
2717 |
// Load start of itable entries into itable_entry_addr.
|
|
2718 |
z_llgf(vtable_len, Address(recv_klass, InstanceKlass::vtable_length_offset()));
|
|
2719 |
z_sllg(vtable_len, vtable_len, exact_log2(vtableEntry::size_in_bytes()));
|
|
2720 |
|
|
2721 |
// Loop over all itable entries until desired interfaceOop(Rinterface) found.
|
|
2722 |
const int vtable_base_offset = in_bytes(InstanceKlass::vtable_start_offset());
|
|
2723 |
|
|
2724 |
add2reg_with_index(itable_entry_addr,
|
|
2725 |
vtable_base_offset + itableOffsetEntry::interface_offset_in_bytes(),
|
|
2726 |
recv_klass, vtable_len);
|
|
2727 |
|
|
2728 |
const int itable_offset_search_inc = itableOffsetEntry::size() * wordSize;
|
|
2729 |
Label search;
|
|
2730 |
|
|
2731 |
bind(search);
|
|
2732 |
|
|
2733 |
// Handle IncompatibleClassChangeError.
|
|
2734 |
// If the entry is NULL then we've reached the end of the table
|
|
2735 |
// without finding the expected interface, so throw an exception.
|
|
2736 |
load_and_test_long(itable_interface, Address(itable_entry_addr));
|
|
2737 |
z_bre(no_such_interface);
|
|
2738 |
|
|
2739 |
add2reg(itable_entry_addr, itable_offset_search_inc);
|
|
2740 |
z_cgr(itable_interface, intf_klass);
|
|
2741 |
z_brne(search);
|
|
2742 |
|
|
2743 |
// Entry found and itable_entry_addr points to it, get offset of vtable for interface.
|
|
2744 |
|
|
2745 |
const int vtable_offset_offset = (itableOffsetEntry::offset_offset_in_bytes() -
|
|
2746 |
itableOffsetEntry::interface_offset_in_bytes()) -
|
|
2747 |
itable_offset_search_inc;
|
|
2748 |
|
|
2749 |
// Compute itableMethodEntry and get method and entry point
|
|
2750 |
// we use addressing with index and displacement, since the formula
|
|
2751 |
// for computing the entry's offset has a fixed and a dynamic part,
|
|
2752 |
// the latter depending on the matched interface entry and on the case,
|
|
2753 |
// that the itable index has been passed as a register, not a constant value.
|
|
2754 |
int method_offset = itableMethodEntry::method_offset_in_bytes();
|
|
2755 |
// Fixed part (displacement), common operand.
|
|
2756 |
Register itable_offset; // Dynamic part (index register).
|
|
2757 |
|
|
2758 |
if (itable_index.is_register()) {
|
|
2759 |
// Compute the method's offset in that register, for the formula, see the
|
|
2760 |
// else-clause below.
|
|
2761 |
itable_offset = itable_index.as_register();
|
|
2762 |
|
|
2763 |
z_sllg(itable_offset, itable_offset, exact_log2(itableMethodEntry::size() * wordSize));
|
|
2764 |
z_agf(itable_offset, vtable_offset_offset, itable_entry_addr);
|
|
2765 |
} else {
|
|
2766 |
itable_offset = Z_R1_scratch;
|
|
2767 |
// Displacement increases.
|
|
2768 |
method_offset += itableMethodEntry::size() * wordSize * itable_index.as_constant();
|
|
2769 |
|
|
2770 |
// Load index from itable.
|
|
2771 |
z_llgf(itable_offset, vtable_offset_offset, itable_entry_addr);
|
|
2772 |
}
|
|
2773 |
|
|
2774 |
// Finally load the method's oop.
|
|
2775 |
z_lg(method_result, method_offset, itable_offset, recv_klass);
|
|
2776 |
BLOCK_COMMENT("} lookup_interface_method");
|
|
2777 |
}
|
|
2778 |
|
|
2779 |
// Lookup for virtual method invocation.
|
|
2780 |
void MacroAssembler::lookup_virtual_method(Register recv_klass,
|
|
2781 |
RegisterOrConstant vtable_index,
|
|
2782 |
Register method_result) {
|
|
2783 |
assert_different_registers(recv_klass, vtable_index.register_or_noreg());
|
|
2784 |
assert(vtableEntry::size() * wordSize == wordSize,
|
|
2785 |
"else adjust the scaling in the code below");
|
|
2786 |
|
|
2787 |
BLOCK_COMMENT("lookup_virtual_method {");
|
|
2788 |
|
|
2789 |
const int base = in_bytes(Klass::vtable_start_offset());
|
|
2790 |
|
|
2791 |
if (vtable_index.is_constant()) {
|
|
2792 |
// Load with base + disp.
|
|
2793 |
Address vtable_entry_addr(recv_klass,
|
|
2794 |
vtable_index.as_constant() * wordSize +
|
|
2795 |
base +
|
|
2796 |
vtableEntry::method_offset_in_bytes());
|
|
2797 |
|
|
2798 |
z_lg(method_result, vtable_entry_addr);
|
|
2799 |
} else {
|
|
2800 |
// Shift index properly and load with base + index + disp.
|
|
2801 |
Register vindex = vtable_index.as_register();
|
|
2802 |
Address vtable_entry_addr(recv_klass, vindex,
|
|
2803 |
base + vtableEntry::method_offset_in_bytes());
|
|
2804 |
|
|
2805 |
z_sllg(vindex, vindex, exact_log2(wordSize));
|
|
2806 |
z_lg(method_result, vtable_entry_addr);
|
|
2807 |
}
|
|
2808 |
BLOCK_COMMENT("} lookup_virtual_method");
|
|
2809 |
}
|
|
2810 |
|
|
2811 |
// Factor out code to call ic_miss_handler.
|
|
2812 |
// Generate code to call the inline cache miss handler.
|
|
2813 |
//
|
|
2814 |
// In most cases, this code will be generated out-of-line.
|
|
2815 |
// The method parameters are intended to provide some variability.
|
|
2816 |
// ICM - Label which has to be bound to the start of useful code (past any traps).
|
|
2817 |
// trapMarker - Marking byte for the generated illtrap instructions (if any).
|
|
2818 |
// Any value except 0x00 is supported.
|
|
2819 |
// = 0x00 - do not generate illtrap instructions.
|
|
2820 |
// use nops to fill ununsed space.
|
|
2821 |
// requiredSize - required size of the generated code. If the actually
|
|
2822 |
// generated code is smaller, use padding instructions to fill up.
|
|
2823 |
// = 0 - no size requirement, no padding.
|
|
2824 |
// scratch - scratch register to hold branch target address.
|
|
2825 |
//
|
|
2826 |
// The method returns the code offset of the bound label.
|
|
2827 |
unsigned int MacroAssembler::call_ic_miss_handler(Label& ICM, int trapMarker, int requiredSize, Register scratch) {
|
|
2828 |
intptr_t startOffset = offset();
|
|
2829 |
|
|
2830 |
// Prevent entry at content_begin().
|
|
2831 |
if (trapMarker != 0) {
|
|
2832 |
z_illtrap(trapMarker);
|
|
2833 |
}
|
|
2834 |
|
|
2835 |
// Load address of inline cache miss code into scratch register
|
|
2836 |
// and branch to cache miss handler.
|
|
2837 |
BLOCK_COMMENT("IC miss handler {");
|
|
2838 |
BIND(ICM);
|
|
2839 |
unsigned int labelOffset = offset();
|
|
2840 |
AddressLiteral icmiss(SharedRuntime::get_ic_miss_stub());
|
|
2841 |
|
|
2842 |
load_const_optimized(scratch, icmiss);
|
|
2843 |
z_br(scratch);
|
|
2844 |
|
|
2845 |
// Fill unused space.
|
|
2846 |
if (requiredSize > 0) {
|
|
2847 |
while ((offset() - startOffset) < requiredSize) {
|
|
2848 |
if (trapMarker == 0) {
|
|
2849 |
z_nop();
|
|
2850 |
} else {
|
|
2851 |
z_illtrap(trapMarker);
|
|
2852 |
}
|
|
2853 |
}
|
|
2854 |
}
|
|
2855 |
BLOCK_COMMENT("} IC miss handler");
|
|
2856 |
return labelOffset;
|
|
2857 |
}
|
|
2858 |
|
|
2859 |
void MacroAssembler::nmethod_UEP(Label& ic_miss) {
|
|
2860 |
Register ic_reg = as_Register(Matcher::inline_cache_reg_encode());
|
|
2861 |
int klass_offset = oopDesc::klass_offset_in_bytes();
|
|
2862 |
if (!ImplicitNullChecks || MacroAssembler::needs_explicit_null_check(klass_offset)) {
|
|
2863 |
if (VM_Version::has_CompareBranch()) {
|
|
2864 |
z_cgij(Z_ARG1, 0, Assembler::bcondEqual, ic_miss);
|
|
2865 |
} else {
|
|
2866 |
z_ltgr(Z_ARG1, Z_ARG1);
|
|
2867 |
z_bre(ic_miss);
|
|
2868 |
}
|
|
2869 |
}
|
|
2870 |
// Compare cached class against klass from receiver.
|
|
2871 |
compare_klass_ptr(ic_reg, klass_offset, Z_ARG1, false);
|
|
2872 |
z_brne(ic_miss);
|
|
2873 |
}
|
|
2874 |
|
|
2875 |
void MacroAssembler::check_klass_subtype_fast_path(Register sub_klass,
|
|
2876 |
Register super_klass,
|
|
2877 |
Register temp1_reg,
|
|
2878 |
Label* L_success,
|
|
2879 |
Label* L_failure,
|
|
2880 |
Label* L_slow_path,
|
|
2881 |
RegisterOrConstant super_check_offset) {
|
|
2882 |
|
|
2883 |
const int sc_offset = in_bytes(Klass::secondary_super_cache_offset());
|
|
2884 |
const int sco_offset = in_bytes(Klass::super_check_offset_offset());
|
|
2885 |
|
|
2886 |
bool must_load_sco = (super_check_offset.constant_or_zero() == -1);
|
|
2887 |
bool need_slow_path = (must_load_sco ||
|
|
2888 |
super_check_offset.constant_or_zero() == sc_offset);
|
|
2889 |
|
|
2890 |
// Input registers must not overlap.
|
|
2891 |
assert_different_registers(sub_klass, super_klass, temp1_reg);
|
|
2892 |
if (super_check_offset.is_register()) {
|
|
2893 |
assert_different_registers(sub_klass, super_klass,
|
|
2894 |
super_check_offset.as_register());
|
|
2895 |
} else if (must_load_sco) {
|
|
2896 |
assert(temp1_reg != noreg, "supply either a temp or a register offset");
|
|
2897 |
}
|
|
2898 |
|
|
2899 |
const Register Rsuper_check_offset = temp1_reg;
|
|
2900 |
|
|
2901 |
NearLabel L_fallthrough;
|
|
2902 |
int label_nulls = 0;
|
|
2903 |
if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; }
|
|
2904 |
if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; }
|
|
2905 |
if (L_slow_path == NULL) { L_slow_path = &L_fallthrough; label_nulls++; }
|
|
2906 |
assert(label_nulls <= 1 ||
|
|
2907 |
(L_slow_path == &L_fallthrough && label_nulls <= 2 && !need_slow_path),
|
|
2908 |
"at most one NULL in the batch, usually");
|
|
2909 |
|
|
2910 |
BLOCK_COMMENT("check_klass_subtype_fast_path {");
|
|
2911 |
// If the pointers are equal, we are done (e.g., String[] elements).
|
|
2912 |
// This self-check enables sharing of secondary supertype arrays among
|
|
2913 |
// non-primary types such as array-of-interface. Otherwise, each such
|
|
2914 |
// type would need its own customized SSA.
|
|
2915 |
// We move this check to the front of the fast path because many
|
|
2916 |
// type checks are in fact trivially successful in this manner,
|
|
2917 |
// so we get a nicely predicted branch right at the start of the check.
|
|
2918 |
compare64_and_branch(sub_klass, super_klass, bcondEqual, *L_success);
|
|
2919 |
|
|
2920 |
// Check the supertype display, which is uint.
|
|
2921 |
if (must_load_sco) {
|
|
2922 |
z_llgf(Rsuper_check_offset, sco_offset, super_klass);
|
|
2923 |
super_check_offset = RegisterOrConstant(Rsuper_check_offset);
|
|
2924 |
}
|
|
2925 |
Address super_check_addr(sub_klass, super_check_offset, 0);
|
|
2926 |
z_cg(super_klass, super_check_addr); // compare w/ displayed supertype
|
|
2927 |
|
|
2928 |
// This check has worked decisively for primary supers.
|
|
2929 |
// Secondary supers are sought in the super_cache ('super_cache_addr').
|
|
2930 |
// (Secondary supers are interfaces and very deeply nested subtypes.)
|
|
2931 |
// This works in the same check above because of a tricky aliasing
|
|
2932 |
// between the super_cache and the primary super display elements.
|
|
2933 |
// (The 'super_check_addr' can address either, as the case requires.)
|
|
2934 |
// Note that the cache is updated below if it does not help us find
|
|
2935 |
// what we need immediately.
|
|
2936 |
// So if it was a primary super, we can just fail immediately.
|
|
2937 |
// Otherwise, it's the slow path for us (no success at this point).
|
|
2938 |
|
|
2939 |
// Hacked jmp, which may only be used just before L_fallthrough.
|
|
2940 |
#define final_jmp(label) \
|
|
2941 |
if (&(label) == &L_fallthrough) { /*do nothing*/ } \
|
|
2942 |
else { branch_optimized(Assembler::bcondAlways, label); } /*omit semicolon*/
|
|
2943 |
|
|
2944 |
if (super_check_offset.is_register()) {
|
|
2945 |
branch_optimized(Assembler::bcondEqual, *L_success);
|
|
2946 |
z_cfi(super_check_offset.as_register(), sc_offset);
|
|
2947 |
if (L_failure == &L_fallthrough) {
|
|
2948 |
branch_optimized(Assembler::bcondEqual, *L_slow_path);
|
|
2949 |
} else {
|
|
2950 |
branch_optimized(Assembler::bcondNotEqual, *L_failure);
|
|
2951 |
final_jmp(*L_slow_path);
|
|
2952 |
}
|
|
2953 |
} else if (super_check_offset.as_constant() == sc_offset) {
|
|
2954 |
// Need a slow path; fast failure is impossible.
|
|
2955 |
if (L_slow_path == &L_fallthrough) {
|
|
2956 |
branch_optimized(Assembler::bcondEqual, *L_success);
|
|
2957 |
} else {
|
|
2958 |
branch_optimized(Assembler::bcondNotEqual, *L_slow_path);
|
|
2959 |
final_jmp(*L_success);
|
|
2960 |
}
|
|
2961 |
} else {
|
|
2962 |
// No slow path; it's a fast decision.
|
|
2963 |
if (L_failure == &L_fallthrough) {
|
|
2964 |
branch_optimized(Assembler::bcondEqual, *L_success);
|
|
2965 |
} else {
|
|
2966 |
branch_optimized(Assembler::bcondNotEqual, *L_failure);
|
|
2967 |
final_jmp(*L_success);
|
|
2968 |
}
|
|
2969 |
}
|
|
2970 |
|
|
2971 |
bind(L_fallthrough);
|
|
2972 |
#undef local_brc
|
|
2973 |
#undef final_jmp
|
|
2974 |
BLOCK_COMMENT("} check_klass_subtype_fast_path");
|
|
2975 |
// fallthru (to slow path)
|
|
2976 |
}
|
|
2977 |
|
|
2978 |
void MacroAssembler::check_klass_subtype_slow_path(Register Rsubklass,
|
|
2979 |
Register Rsuperklass,
|
|
2980 |
Register Rarray_ptr, // tmp
|
|
2981 |
Register Rlength, // tmp
|
|
2982 |
Label* L_success,
|
|
2983 |
Label* L_failure) {
|
|
2984 |
// Input registers must not overlap.
|
|
2985 |
// Also check for R1 which is explicitely used here.
|
|
2986 |
assert_different_registers(Z_R1, Rsubklass, Rsuperklass, Rarray_ptr, Rlength);
|
|
2987 |
NearLabel L_fallthrough, L_loop;
|
|
2988 |
int label_nulls = 0;
|
|
2989 |
if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; }
|
|
2990 |
if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; }
|
|
2991 |
assert(label_nulls <= 1, "at most one NULL in the batch");
|
|
2992 |
|
|
2993 |
const int ss_offset = in_bytes(Klass::secondary_supers_offset());
|
|
2994 |
const int sc_offset = in_bytes(Klass::secondary_super_cache_offset());
|
|
2995 |
|
|
2996 |
const int length_offset = Array<Klass*>::length_offset_in_bytes();
|
|
2997 |
const int base_offset = Array<Klass*>::base_offset_in_bytes();
|
|
2998 |
|
|
2999 |
// Hacked jmp, which may only be used just before L_fallthrough.
|
|
3000 |
#define final_jmp(label) \
|
|
3001 |
if (&(label) == &L_fallthrough) { /*do nothing*/ } \
|
|
3002 |
else branch_optimized(Assembler::bcondAlways, label) /*omit semicolon*/
|
|
3003 |
|
|
3004 |
NearLabel loop_iterate, loop_count, match;
|
|
3005 |
|
|
3006 |
BLOCK_COMMENT("check_klass_subtype_slow_path {");
|
|
3007 |
z_lg(Rarray_ptr, ss_offset, Rsubklass);
|
|
3008 |
|
|
3009 |
load_and_test_int(Rlength, Address(Rarray_ptr, length_offset));
|
|
3010 |
branch_optimized(Assembler::bcondZero, *L_failure);
|
|
3011 |
|
|
3012 |
// Oops in table are NO MORE compressed.
|
|
3013 |
z_cg(Rsuperklass, base_offset, Rarray_ptr); // Check array element for match.
|
|
3014 |
z_bre(match); // Shortcut for array length = 1.
|
|
3015 |
|
|
3016 |
// No match yet, so we must walk the array's elements.
|
|
3017 |
z_lngfr(Rlength, Rlength);
|
|
3018 |
z_sllg(Rlength, Rlength, LogBytesPerWord); // -#bytes of cache array
|
|
3019 |
z_llill(Z_R1, BytesPerWord); // Set increment/end index.
|
|
3020 |
add2reg(Rlength, 2 * BytesPerWord); // start index = -(n-2)*BytesPerWord
|
|
3021 |
z_slgr(Rarray_ptr, Rlength); // start addr: += (n-2)*BytesPerWord
|
|
3022 |
z_bru(loop_count);
|
|
3023 |
|
|
3024 |
BIND(loop_iterate);
|
|
3025 |
z_cg(Rsuperklass, base_offset, Rlength, Rarray_ptr); // Check array element for match.
|
|
3026 |
z_bre(match);
|
|
3027 |
BIND(loop_count);
|
|
3028 |
z_brxlg(Rlength, Z_R1, loop_iterate);
|
|
3029 |
|
|
3030 |
// Rsuperklass not found among secondary super classes -> failure.
|
|
3031 |
branch_optimized(Assembler::bcondAlways, *L_failure);
|
|
3032 |
|
|
3033 |
// Got a hit. Return success (zero result). Set cache.
|
|
3034 |
// Cache load doesn't happen here. For speed it is directly emitted by the compiler.
|
|
3035 |
|
|
3036 |
BIND(match);
|
|
3037 |
|
|
3038 |
z_stg(Rsuperklass, sc_offset, Rsubklass); // Save result to cache.
|
|
3039 |
|
|
3040 |
final_jmp(*L_success);
|
|
3041 |
|
|
3042 |
// Exit to the surrounding code.
|
|
3043 |
BIND(L_fallthrough);
|
|
3044 |
#undef local_brc
|
|
3045 |
#undef final_jmp
|
|
3046 |
BLOCK_COMMENT("} check_klass_subtype_slow_path");
|
|
3047 |
}
|
|
3048 |
|
|
3049 |
// Emitter for combining fast and slow path.
|
|
3050 |
void MacroAssembler::check_klass_subtype(Register sub_klass,
|
|
3051 |
Register super_klass,
|
|
3052 |
Register temp1_reg,
|
|
3053 |
Register temp2_reg,
|
|
3054 |
Label& L_success) {
|
|
3055 |
NearLabel failure;
|
|
3056 |
BLOCK_COMMENT(err_msg("check_klass_subtype(%s subclass of %s) {", sub_klass->name(), super_klass->name()));
|
|
3057 |
check_klass_subtype_fast_path(sub_klass, super_klass, temp1_reg,
|
|
3058 |
&L_success, &failure, NULL);
|
|
3059 |
check_klass_subtype_slow_path(sub_klass, super_klass,
|
|
3060 |
temp1_reg, temp2_reg, &L_success, NULL);
|
|
3061 |
BIND(failure);
|
|
3062 |
BLOCK_COMMENT("} check_klass_subtype");
|
|
3063 |
}
|
|
3064 |
|
|
3065 |
// Increment a counter at counter_address when the eq condition code is
|
|
3066 |
// set. Kills registers tmp1_reg and tmp2_reg and preserves the condition code.
|
|
3067 |
void MacroAssembler::increment_counter_eq(address counter_address, Register tmp1_reg, Register tmp2_reg) {
|
|
3068 |
Label l;
|
|
3069 |
z_brne(l);
|
|
3070 |
load_const(tmp1_reg, counter_address);
|
|
3071 |
add2mem_32(Address(tmp1_reg), 1, tmp2_reg);
|
|
3072 |
z_cr(tmp1_reg, tmp1_reg); // Set cc to eq.
|
|
3073 |
bind(l);
|
|
3074 |
}
|
|
3075 |
|
|
3076 |
// Semantics are dependent on the slow_case label:
|
|
3077 |
// If the slow_case label is not NULL, failure to biased-lock the object
|
|
3078 |
// transfers control to the location of the slow_case label. If the
|
|
3079 |
// object could be biased-locked, control is transferred to the done label.
|
|
3080 |
// The condition code is unpredictable.
|
|
3081 |
//
|
|
3082 |
// If the slow_case label is NULL, failure to biased-lock the object results
|
|
3083 |
// in a transfer of control to the done label with a condition code of not_equal.
|
|
3084 |
// If the biased-lock could be successfully obtained, control is transfered to
|
|
3085 |
// the done label with a condition code of equal.
|
|
3086 |
// It is mandatory to react on the condition code At the done label.
|
|
3087 |
//
|
|
3088 |
void MacroAssembler::biased_locking_enter(Register obj_reg,
|
|
3089 |
Register mark_reg,
|
|
3090 |
Register temp_reg,
|
|
3091 |
Register temp2_reg, // May be Z_RO!
|
|
3092 |
Label &done,
|
|
3093 |
Label *slow_case) {
|
|
3094 |
assert(UseBiasedLocking, "why call this otherwise?");
|
|
3095 |
assert_different_registers(obj_reg, mark_reg, temp_reg, temp2_reg);
|
|
3096 |
|
|
3097 |
Label cas_label; // Try, if implemented, CAS locking. Fall thru to slow path otherwise.
|
|
3098 |
|
|
3099 |
BLOCK_COMMENT("biased_locking_enter {");
|
|
3100 |
|
|
3101 |
// Biased locking
|
|
3102 |
// See whether the lock is currently biased toward our thread and
|
|
3103 |
// whether the epoch is still valid.
|
|
3104 |
// Note that the runtime guarantees sufficient alignment of JavaThread
|
|
3105 |
// pointers to allow age to be placed into low bits.
|
|
3106 |
assert(markOopDesc::age_shift == markOopDesc::lock_bits + markOopDesc::biased_lock_bits,
|
|
3107 |
"biased locking makes assumptions about bit layout");
|
|
3108 |
z_lr(temp_reg, mark_reg);
|
|
3109 |
z_nilf(temp_reg, markOopDesc::biased_lock_mask_in_place);
|
|
3110 |
z_chi(temp_reg, markOopDesc::biased_lock_pattern);
|
|
3111 |
z_brne(cas_label); // Try cas if object is not biased, i.e. cannot be biased locked.
|
|
3112 |
|
|
3113 |
load_prototype_header(temp_reg, obj_reg);
|
|
3114 |
load_const_optimized(temp2_reg, ~((int) markOopDesc::age_mask_in_place));
|
|
3115 |
|
|
3116 |
z_ogr(temp_reg, Z_thread);
|
|
3117 |
z_xgr(temp_reg, mark_reg);
|
|
3118 |
z_ngr(temp_reg, temp2_reg);
|
|
3119 |
if (PrintBiasedLockingStatistics) {
|
|
3120 |
increment_counter_eq((address) BiasedLocking::biased_lock_entry_count_addr(), mark_reg, temp2_reg);
|
|
3121 |
// Restore mark_reg.
|
|
3122 |
z_lg(mark_reg, oopDesc::mark_offset_in_bytes(), obj_reg);
|
|
3123 |
}
|
|
3124 |
branch_optimized(Assembler::bcondEqual, done); // Biased lock obtained, return success.
|
|
3125 |
|
|
3126 |
Label try_revoke_bias;
|
|
3127 |
Label try_rebias;
|
|
3128 |
Address mark_addr = Address(obj_reg, oopDesc::mark_offset_in_bytes());
|
|
3129 |
|
|
3130 |
//----------------------------------------------------------------------------
|
|
3131 |
// At this point we know that the header has the bias pattern and
|
|
3132 |
// that we are not the bias owner in the current epoch. We need to
|
|
3133 |
// figure out more details about the state of the header in order to
|
|
3134 |
// know what operations can be legally performed on the object's
|
|
3135 |
// header.
|
|
3136 |
|
|
3137 |
// If the low three bits in the xor result aren't clear, that means
|
|
3138 |
// the prototype header is no longer biased and we have to revoke
|
|
3139 |
// the bias on this object.
|
|
3140 |
z_tmll(temp_reg, markOopDesc::biased_lock_mask_in_place);
|
|
3141 |
z_brnaz(try_revoke_bias);
|
|
3142 |
|
|
3143 |
// Biasing is still enabled for this data type. See whether the
|
|
3144 |
// epoch of the current bias is still valid, meaning that the epoch
|
|
3145 |
// bits of the mark word are equal to the epoch bits of the
|
|
3146 |
// prototype header. (Note that the prototype header's epoch bits
|
|
3147 |
// only change at a safepoint.) If not, attempt to rebias the object
|
|
3148 |
// toward the current thread. Note that we must be absolutely sure
|
|
3149 |
// that the current epoch is invalid in order to do this because
|
|
3150 |
// otherwise the manipulations it performs on the mark word are
|
|
3151 |
// illegal.
|
|
3152 |
z_tmll(temp_reg, markOopDesc::epoch_mask_in_place);
|
|
3153 |
z_brnaz(try_rebias);
|
|
3154 |
|
|
3155 |
//----------------------------------------------------------------------------
|
|
3156 |
// The epoch of the current bias is still valid but we know nothing
|
|
3157 |
// about the owner; it might be set or it might be clear. Try to
|
|
3158 |
// acquire the bias of the object using an atomic operation. If this
|
|
3159 |
// fails we will go in to the runtime to revoke the object's bias.
|
|
3160 |
// Note that we first construct the presumed unbiased header so we
|
|
3161 |
// don't accidentally blow away another thread's valid bias.
|
|
3162 |
z_nilf(mark_reg, markOopDesc::biased_lock_mask_in_place | markOopDesc::age_mask_in_place |
|
|
3163 |
markOopDesc::epoch_mask_in_place);
|
|
3164 |
z_lgr(temp_reg, Z_thread);
|
|
3165 |
z_llgfr(mark_reg, mark_reg);
|
|
3166 |
z_ogr(temp_reg, mark_reg);
|
|
3167 |
|
|
3168 |
assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
|
|
3169 |
|
|
3170 |
z_csg(mark_reg, temp_reg, 0, obj_reg);
|
|
3171 |
|
|
3172 |
// If the biasing toward our thread failed, this means that
|
|
3173 |
// another thread succeeded in biasing it toward itself and we
|
|
3174 |
// need to revoke that bias. The revocation will occur in the
|
|
3175 |
// interpreter runtime in the slow case.
|
|
3176 |
|
|
3177 |
if (PrintBiasedLockingStatistics) {
|
|
3178 |
increment_counter_eq((address) BiasedLocking::anonymously_biased_lock_entry_count_addr(),
|
|
3179 |
temp_reg, temp2_reg);
|
|
3180 |
}
|
|
3181 |
if (slow_case != NULL) {
|
|
3182 |
branch_optimized(Assembler::bcondNotEqual, *slow_case); // Biased lock not obtained, need to go the long way.
|
|
3183 |
}
|
|
3184 |
branch_optimized(Assembler::bcondAlways, done); // Biased lock status given in condition code.
|
|
3185 |
|
|
3186 |
//----------------------------------------------------------------------------
|
|
3187 |
bind(try_rebias);
|
|
3188 |
// At this point we know the epoch has expired, meaning that the
|
|
3189 |
// current "bias owner", if any, is actually invalid. Under these
|
|
3190 |
// circumstances _only_, we are allowed to use the current header's
|
|
3191 |
// value as the comparison value when doing the cas to acquire the
|
|
3192 |
// bias in the current epoch. In other words, we allow transfer of
|
|
3193 |
// the bias from one thread to another directly in this situation.
|
|
3194 |
|
|
3195 |
z_nilf(mark_reg, markOopDesc::biased_lock_mask_in_place | markOopDesc::age_mask_in_place | markOopDesc::epoch_mask_in_place);
|
|
3196 |
load_prototype_header(temp_reg, obj_reg);
|
|
3197 |
z_llgfr(mark_reg, mark_reg);
|
|
3198 |
|
|
3199 |
z_ogr(temp_reg, Z_thread);
|
|
3200 |
|
|
3201 |
assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
|
|
3202 |
|
|
3203 |
z_csg(mark_reg, temp_reg, 0, obj_reg);
|
|
3204 |
|
|
3205 |
// If the biasing toward our thread failed, this means that
|
|
3206 |
// another thread succeeded in biasing it toward itself and we
|
|
3207 |
// need to revoke that bias. The revocation will occur in the
|
|
3208 |
// interpreter runtime in the slow case.
|
|
3209 |
|
|
3210 |
if (PrintBiasedLockingStatistics) {
|
|
3211 |
increment_counter_eq((address) BiasedLocking::rebiased_lock_entry_count_addr(), temp_reg, temp2_reg);
|
|
3212 |
}
|
|
3213 |
if (slow_case != NULL) {
|
|
3214 |
branch_optimized(Assembler::bcondNotEqual, *slow_case); // Biased lock not obtained, need to go the long way.
|
|
3215 |
}
|
|
3216 |
z_bru(done); // Biased lock status given in condition code.
|
|
3217 |
|
|
3218 |
//----------------------------------------------------------------------------
|
|
3219 |
bind(try_revoke_bias);
|
|
3220 |
// The prototype mark in the klass doesn't have the bias bit set any
|
|
3221 |
// more, indicating that objects of this data type are not supposed
|
|
3222 |
// to be biased any more. We are going to try to reset the mark of
|
|
3223 |
// this object to the prototype value and fall through to the
|
|
3224 |
// CAS-based locking scheme. Note that if our CAS fails, it means
|
|
3225 |
// that another thread raced us for the privilege of revoking the
|
|
3226 |
// bias of this particular object, so it's okay to continue in the
|
|
3227 |
// normal locking code.
|
|
3228 |
load_prototype_header(temp_reg, obj_reg);
|
|
3229 |
|
|
3230 |
assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
|
|
3231 |
|
|
3232 |
z_csg(mark_reg, temp_reg, 0, obj_reg);
|
|
3233 |
|
|
3234 |
// Fall through to the normal CAS-based lock, because no matter what
|
|
3235 |
// the result of the above CAS, some thread must have succeeded in
|
|
3236 |
// removing the bias bit from the object's header.
|
|
3237 |
if (PrintBiasedLockingStatistics) {
|
|
3238 |
// z_cgr(mark_reg, temp2_reg);
|
|
3239 |
increment_counter_eq((address) BiasedLocking::revoked_lock_entry_count_addr(), temp_reg, temp2_reg);
|
|
3240 |
}
|
|
3241 |
|
|
3242 |
bind(cas_label);
|
|
3243 |
BLOCK_COMMENT("} biased_locking_enter");
|
|
3244 |
}
|
|
3245 |
|
|
3246 |
void MacroAssembler::biased_locking_exit(Register mark_addr, Register temp_reg, Label& done) {
|
|
3247 |
// Check for biased locking unlock case, which is a no-op
|
|
3248 |
// Note: we do not have to check the thread ID for two reasons.
|
|
3249 |
// First, the interpreter checks for IllegalMonitorStateException at
|
|
3250 |
// a higher level. Second, if the bias was revoked while we held the
|
|
3251 |
// lock, the object could not be rebiased toward another thread, so
|
|
3252 |
// the bias bit would be clear.
|
|
3253 |
BLOCK_COMMENT("biased_locking_exit {");
|
|
3254 |
|
|
3255 |
z_lg(temp_reg, 0, mark_addr);
|
|
3256 |
z_nilf(temp_reg, markOopDesc::biased_lock_mask_in_place);
|
|
3257 |
|
|
3258 |
z_chi(temp_reg, markOopDesc::biased_lock_pattern);
|
|
3259 |
z_bre(done);
|
|
3260 |
BLOCK_COMMENT("} biased_locking_exit");
|
|
3261 |
}
|
|
3262 |
|
|
3263 |
void MacroAssembler::compiler_fast_lock_object(Register oop, Register box, Register temp1, Register temp2, bool try_bias) {
|
|
3264 |
Register displacedHeader = temp1;
|
|
3265 |
Register currentHeader = temp1;
|
|
3266 |
Register temp = temp2;
|
|
3267 |
NearLabel done, object_has_monitor;
|
|
3268 |
|
|
3269 |
BLOCK_COMMENT("compiler_fast_lock_object {");
|
|
3270 |
|
|
3271 |
// Load markOop from oop into mark.
|
|
3272 |
z_lg(displacedHeader, 0, oop);
|
|
3273 |
|
|
3274 |
if (try_bias) {
|
|
3275 |
biased_locking_enter(oop, displacedHeader, temp, Z_R0, done);
|
|
3276 |
}
|
|
3277 |
|
|
3278 |
// Handle existing monitor.
|
|
3279 |
if ((EmitSync & 0x01) == 0) {
|
|
3280 |
// The object has an existing monitor iff (mark & monitor_value) != 0.
|
|
3281 |
guarantee(Immediate::is_uimm16(markOopDesc::monitor_value), "must be half-word");
|
|
3282 |
z_lr(temp, displacedHeader);
|
|
3283 |
z_nill(temp, markOopDesc::monitor_value);
|
|
3284 |
z_brne(object_has_monitor);
|
|
3285 |
}
|
|
3286 |
|
|
3287 |
// Set mark to markOop | markOopDesc::unlocked_value.
|
|
3288 |
z_oill(displacedHeader, markOopDesc::unlocked_value);
|
|
3289 |
|
|
3290 |
// Load Compare Value application register.
|
|
3291 |
|
|
3292 |
// Initialize the box (must happen before we update the object mark).
|
|
3293 |
z_stg(displacedHeader, BasicLock::displaced_header_offset_in_bytes(), box);
|
|
3294 |
|
|
3295 |
// Memory Fence (in cmpxchgd)
|
|
3296 |
// Compare object markOop with mark and if equal exchange scratch1 with object markOop.
|
|
3297 |
|
|
3298 |
// If the compare-and-swap succeeded, then we found an unlocked object and we
|
|
3299 |
// have now locked it.
|
|
3300 |
z_csg(displacedHeader, box, 0, oop);
|
|
3301 |
assert(currentHeader==displacedHeader, "must be same register"); // Identified two registers from z/Architecture.
|
|
3302 |
z_bre(done);
|
|
3303 |
|
|
3304 |
// We did not see an unlocked object so try the fast recursive case.
|
|
3305 |
|
|
3306 |
z_sgr(currentHeader, Z_SP);
|
|
3307 |
load_const_optimized(temp, (~(os::vm_page_size()-1) | markOopDesc::lock_mask_in_place));
|
|
3308 |
|
|
3309 |
z_ngr(currentHeader, temp);
|
|
3310 |
// z_brne(done);
|
|
3311 |
// z_release();
|
|
3312 |
z_stg(currentHeader/*==0 or not 0*/, BasicLock::displaced_header_offset_in_bytes(), box);
|
|
3313 |
|
|
3314 |
z_bru(done);
|
|
3315 |
|
|
3316 |
if ((EmitSync & 0x01) == 0) {
|
|
3317 |
Register zero = temp;
|
|
3318 |
Register monitor_tagged = displacedHeader; // Tagged with markOopDesc::monitor_value.
|
|
3319 |
bind(object_has_monitor);
|
|
3320 |
// The object's monitor m is unlocked iff m->owner == NULL,
|
|
3321 |
// otherwise m->owner may contain a thread or a stack address.
|
|
3322 |
//
|
|
3323 |
// Try to CAS m->owner from NULL to current thread.
|
|
3324 |
z_lghi(zero, 0);
|
|
3325 |
// If m->owner is null, then csg succeeds and sets m->owner=THREAD and CR=EQ.
|
|
3326 |
z_csg(zero, Z_thread, OM_OFFSET_NO_MONITOR_VALUE_TAG(owner), monitor_tagged);
|
|
3327 |
// Store a non-null value into the box.
|
|
3328 |
z_stg(box, BasicLock::displaced_header_offset_in_bytes(), box);
|
|
3329 |
#ifdef ASSERT
|
|
3330 |
z_brne(done);
|
|
3331 |
// We've acquired the monitor, check some invariants.
|
|
3332 |
// Invariant 1: _recursions should be 0.
|
|
3333 |
asm_assert_mem8_is_zero(OM_OFFSET_NO_MONITOR_VALUE_TAG(recursions), monitor_tagged,
|
|
3334 |
"monitor->_recursions should be 0", -1);
|
|
3335 |
z_ltgr(zero, zero); // Set CR=EQ.
|
|
3336 |
#endif
|
|
3337 |
}
|
|
3338 |
bind(done);
|
|
3339 |
|
|
3340 |
BLOCK_COMMENT("} compiler_fast_lock_object");
|
|
3341 |
// If locking was successful, CR should indicate 'EQ'.
|
|
3342 |
// The compiler or the native wrapper generates a branch to the runtime call
|
|
3343 |
// _complete_monitor_locking_Java.
|
|
3344 |
}
|
|
3345 |
|
|
3346 |
void MacroAssembler::compiler_fast_unlock_object(Register oop, Register box, Register temp1, Register temp2, bool try_bias) {
|
|
3347 |
Register displacedHeader = temp1;
|
|
3348 |
Register currentHeader = temp2;
|
|
3349 |
Register temp = temp1;
|
|
3350 |
Register monitor = temp2;
|
|
3351 |
|
|
3352 |
Label done, object_has_monitor;
|
|
3353 |
|
|
3354 |
BLOCK_COMMENT("compiler_fast_unlock_object {");
|
|
3355 |
|
|
3356 |
if (try_bias) {
|
|
3357 |
biased_locking_exit(oop, currentHeader, done);
|
|
3358 |
}
|
|
3359 |
|
|
3360 |
// Find the lock address and load the displaced header from the stack.
|
|
3361 |
// if the displaced header is zero, we have a recursive unlock.
|
|
3362 |
load_and_test_long(displacedHeader, Address(box, BasicLock::displaced_header_offset_in_bytes()));
|
|
3363 |
z_bre(done);
|
|
3364 |
|
|
3365 |
// Handle existing monitor.
|
|
3366 |
if ((EmitSync & 0x02) == 0) {
|
|
3367 |
// The object has an existing monitor iff (mark & monitor_value) != 0.
|
|
3368 |
z_lg(currentHeader, oopDesc::mark_offset_in_bytes(), oop);
|
|
3369 |
guarantee(Immediate::is_uimm16(markOopDesc::monitor_value), "must be half-word");
|
|
3370 |
z_nill(currentHeader, markOopDesc::monitor_value);
|
|
3371 |
z_brne(object_has_monitor);
|
|
3372 |
}
|
|
3373 |
|
|
3374 |
// Check if it is still a light weight lock, this is true if we see
|
|
3375 |
// the stack address of the basicLock in the markOop of the object
|
|
3376 |
// copy box to currentHeader such that csg does not kill it.
|
|
3377 |
z_lgr(currentHeader, box);
|
|
3378 |
z_csg(currentHeader, displacedHeader, 0, oop);
|
|
3379 |
z_bru(done); // Csg sets CR as desired.
|
|
3380 |
|
|
3381 |
// Handle existing monitor.
|
|
3382 |
if ((EmitSync & 0x02) == 0) {
|
|
3383 |
bind(object_has_monitor);
|
|
3384 |
z_lg(currentHeader, oopDesc::mark_offset_in_bytes(), oop); // CurrentHeader is tagged with monitor_value set.
|
|
3385 |
load_and_test_long(temp, Address(currentHeader, OM_OFFSET_NO_MONITOR_VALUE_TAG(recursions)));
|
|
3386 |
z_brne(done);
|
|
3387 |
load_and_test_long(temp, Address(currentHeader, OM_OFFSET_NO_MONITOR_VALUE_TAG(owner)));
|
|
3388 |
z_brne(done);
|
|
3389 |
load_and_test_long(temp, Address(currentHeader, OM_OFFSET_NO_MONITOR_VALUE_TAG(EntryList)));
|
|
3390 |
z_brne(done);
|
|
3391 |
load_and_test_long(temp, Address(currentHeader, OM_OFFSET_NO_MONITOR_VALUE_TAG(cxq)));
|
|
3392 |
z_brne(done);
|
|
3393 |
z_release();
|
|
3394 |
z_stg(temp/*=0*/, OM_OFFSET_NO_MONITOR_VALUE_TAG(owner), currentHeader);
|
|
3395 |
}
|
|
3396 |
|
|
3397 |
bind(done);
|
|
3398 |
|
|
3399 |
BLOCK_COMMENT("} compiler_fast_unlock_object");
|
|
3400 |
// flag == EQ indicates success
|
|
3401 |
// flag == NE indicates failure
|
|
3402 |
}
|
|
3403 |
|
|
3404 |
// Write to card table for modification at store_addr - register is destroyed afterwards.
|
|
3405 |
void MacroAssembler::card_write_barrier_post(Register store_addr, Register tmp) {
|
|
3406 |
CardTableModRefBS* bs = (CardTableModRefBS*) Universe::heap()->barrier_set();
|
|
3407 |
assert(bs->kind() == BarrierSet::CardTableForRS ||
|
|
3408 |
bs->kind() == BarrierSet::CardTableExtension, "wrong barrier");
|
|
3409 |
assert_different_registers(store_addr, tmp);
|
|
3410 |
z_srlg(store_addr, store_addr, CardTableModRefBS::card_shift);
|
|
3411 |
load_absolute_address(tmp, (address)bs->byte_map_base);
|
|
3412 |
z_agr(store_addr, tmp);
|
|
3413 |
z_mvi(0, store_addr, 0); // Store byte 0.
|
|
3414 |
}
|
|
3415 |
|
|
3416 |
#if INCLUDE_ALL_GCS
|
|
3417 |
|
|
3418 |
//------------------------------------------------------
|
|
3419 |
// General G1 pre-barrier generator.
|
|
3420 |
// Purpose: record the previous value if it is not null.
|
|
3421 |
// All non-tmps are preserved.
|
|
3422 |
//------------------------------------------------------
|
|
3423 |
void MacroAssembler::g1_write_barrier_pre(Register Robj,
|
|
3424 |
RegisterOrConstant offset,
|
|
3425 |
Register Rpre_val, // Ideally, this is a non-volatile register.
|
|
3426 |
Register Rval, // Will be preserved.
|
|
3427 |
Register Rtmp1, // If Rpre_val is volatile, either Rtmp1
|
|
3428 |
Register Rtmp2, // or Rtmp2 has to be non-volatile..
|
|
3429 |
bool pre_val_needed // Save Rpre_val across runtime call, caller uses it.
|
|
3430 |
) {
|
|
3431 |
Label callRuntime, filtered;
|
|
3432 |
const int active_offset = in_bytes(JavaThread::satb_mark_queue_offset() + SATBMarkQueue::byte_offset_of_active());
|
|
3433 |
const int buffer_offset = in_bytes(JavaThread::satb_mark_queue_offset() + SATBMarkQueue::byte_offset_of_buf());
|
|
3434 |
const int index_offset = in_bytes(JavaThread::satb_mark_queue_offset() + SATBMarkQueue::byte_offset_of_index());
|
|
3435 |
assert_different_registers(Rtmp1, Rtmp2, Z_R0_scratch); // None of the Rtmp<i> must be Z_R0!!
|
|
3436 |
|
|
3437 |
BLOCK_COMMENT("g1_write_barrier_pre {");
|
|
3438 |
|
|
3439 |
// Is marking active?
|
|
3440 |
// Note: value is loaded for test purposes only. No further use here.
|
|
3441 |
if (in_bytes(SATBMarkQueue::byte_width_of_active()) == 4) {
|
|
3442 |
load_and_test_int(Rtmp1, Address(Z_thread, active_offset));
|
|
3443 |
} else {
|
|
3444 |
guarantee(in_bytes(SATBMarkQueue::byte_width_of_active()) == 1, "Assumption");
|
|
3445 |
load_and_test_byte(Rtmp1, Address(Z_thread, active_offset));
|
|
3446 |
}
|
|
3447 |
z_bre(filtered); // Activity indicator is zero, so there is no marking going on currently.
|
|
3448 |
|
|
3449 |
// Do we need to load the previous value into Rpre_val?
|
|
3450 |
if (Robj != noreg) {
|
|
3451 |
// Load the previous value...
|
|
3452 |
Register ixReg = offset.is_register() ? offset.register_or_noreg() : Z_R0;
|
|
3453 |
if (UseCompressedOops) {
|
|
3454 |
z_llgf(Rpre_val, offset.constant_or_zero(), ixReg, Robj);
|
|
3455 |
} else {
|
|
3456 |
z_lg(Rpre_val, offset.constant_or_zero(), ixReg, Robj);
|
|
3457 |
}
|
|
3458 |
}
|
|
3459 |
assert(Rpre_val != noreg, "must have a real register");
|
|
3460 |
|
|
3461 |
// Is the previous value NULL?
|
|
3462 |
// Note: pre_val is loaded, decompressed and stored (directly or via runtime call).
|
|
3463 |
// Register contents is preserved across runtime call if caller requests to do so.
|
|
3464 |
z_ltgr(Rpre_val, Rpre_val);
|
|
3465 |
z_bre(filtered); // previous value is NULL, so we don't need to record it.
|
|
3466 |
|
|
3467 |
// Decode the oop now. We know it's not NULL.
|
|
3468 |
if (Robj != noreg && UseCompressedOops) {
|
|
3469 |
oop_decoder(Rpre_val, Rpre_val, /*maybeNULL=*/false);
|
|
3470 |
}
|
|
3471 |
|
|
3472 |
// OK, it's not filtered, so we'll need to call enqueue.
|
|
3473 |
|
|
3474 |
// We can store the original value in the thread's buffer
|
|
3475 |
// only if index > 0. Otherwise, we need runtime to handle.
|
|
3476 |
// (The index field is typed as size_t.)
|
|
3477 |
Register Rbuffer = Rtmp1, Rindex = Rtmp2;
|
|
3478 |
|
|
3479 |
z_lg(Rbuffer, buffer_offset, Z_thread);
|
|
3480 |
|
|
3481 |
load_and_test_long(Rindex, Address(Z_thread, index_offset));
|
|
3482 |
z_bre(callRuntime); // If index == 0, goto runtime.
|
|
3483 |
|
|
3484 |
add2reg(Rindex, -wordSize); // Decrement index.
|
|
3485 |
z_stg(Rindex, index_offset, Z_thread);
|
|
3486 |
|
|
3487 |
// Record the previous value.
|
|
3488 |
z_stg(Rpre_val, 0, Rbuffer, Rindex);
|
|
3489 |
z_bru(filtered); // We are done.
|
|
3490 |
|
|
3491 |
Rbuffer = noreg; // end of life
|
|
3492 |
Rindex = noreg; // end of life
|
|
3493 |
|
|
3494 |
bind(callRuntime);
|
|
3495 |
|
|
3496 |
// Save Rpre_val (result) over runtime call.
|
|
3497 |
// Requires Rtmp1, Rtmp2, or Rpre_val to be non-volatile.
|
|
3498 |
Register Rpre_save = Rpre_val;
|
|
3499 |
if (pre_val_needed && Rpre_val->is_volatile()) {
|
|
3500 |
guarantee(!Rtmp1->is_volatile() || !Rtmp2->is_volatile(), "oops!");
|
|
3501 |
Rpre_save = !Rtmp1->is_volatile() ? Rtmp1 : Rtmp2;
|
|
3502 |
}
|
|
3503 |
lgr_if_needed(Rpre_save, Rpre_val);
|
|
3504 |
|
|
3505 |
// Preserve inputs by spilling them into the top frame.
|
|
3506 |
if (Robj != noreg && Robj->is_volatile()) {
|
|
3507 |
z_stg(Robj, Robj->encoding()*BytesPerWord, Z_SP);
|
|
3508 |
}
|
|
3509 |
if (offset.is_register() && offset.as_register()->is_volatile()) {
|
|
3510 |
Register Roff = offset.as_register();
|
|
3511 |
z_stg(Roff, Roff->encoding()*BytesPerWord, Z_SP);
|
|
3512 |
}
|
|
3513 |
if (Rval != noreg && Rval->is_volatile()) {
|
|
3514 |
z_stg(Rval, Rval->encoding()*BytesPerWord, Z_SP);
|
|
3515 |
}
|
|
3516 |
|
|
3517 |
// Push frame to protect top frame with return pc and spilled register values.
|
|
3518 |
save_return_pc();
|
|
3519 |
push_frame_abi160(0); // Will use Z_R0 as tmp on old CPUs.
|
|
3520 |
|
|
3521 |
call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_pre), Rpre_val, Z_thread);
|
|
3522 |
|
|
3523 |
pop_frame();
|
|
3524 |
restore_return_pc();
|
|
3525 |
|
|
3526 |
// Restore spilled values.
|
|
3527 |
if (Robj != noreg && Robj->is_volatile()) {
|
|
3528 |
z_lg(Robj, Robj->encoding()*BytesPerWord, Z_SP);
|
|
3529 |
}
|
|
3530 |
if (offset.is_register() && offset.as_register()->is_volatile()) {
|
|
3531 |
Register Roff = offset.as_register();
|
|
3532 |
z_lg(Roff, Roff->encoding()*BytesPerWord, Z_SP);
|
|
3533 |
}
|
|
3534 |
if (Rval != noreg && Rval->is_volatile()) {
|
|
3535 |
z_lg(Rval, Rval->encoding()*BytesPerWord, Z_SP);
|
|
3536 |
}
|
|
3537 |
|
|
3538 |
// Restore Rpre_val (result) after runtime call.
|
|
3539 |
lgr_if_needed(Rpre_val, Rpre_save);
|
|
3540 |
|
|
3541 |
bind(filtered);
|
|
3542 |
BLOCK_COMMENT("} g1_write_barrier_pre");
|
|
3543 |
}
|
|
3544 |
|
|
3545 |
// General G1 post-barrier generator.
|
|
3546 |
// Purpose: Store cross-region card.
|
|
3547 |
void MacroAssembler::g1_write_barrier_post(Register Rstore_addr,
|
|
3548 |
Register Rnew_val,
|
|
3549 |
Register Rtmp1,
|
|
3550 |
Register Rtmp2,
|
|
3551 |
Register Rtmp3) {
|
|
3552 |
Label callRuntime, filtered;
|
|
3553 |
|
|
3554 |
assert_different_registers(Rstore_addr, Rnew_val, Rtmp1, Rtmp2); // Most probably, Rnew_val == Rtmp3.
|
|
3555 |
|
|
3556 |
G1SATBCardTableModRefBS* bs = (G1SATBCardTableModRefBS*) Universe::heap()->barrier_set();
|
|
3557 |
assert(bs->kind() == BarrierSet::G1SATBCTLogging, "wrong barrier");
|
|
3558 |
|
|
3559 |
BLOCK_COMMENT("g1_write_barrier_post {");
|
|
3560 |
|
|
3561 |
// Does store cross heap regions?
|
|
3562 |
// It does if the two addresses specify different grain addresses.
|
|
3563 |
if (G1RSBarrierRegionFilter) {
|
|
3564 |
if (VM_Version::has_DistinctOpnds()) {
|
|
3565 |
z_xgrk(Rtmp1, Rstore_addr, Rnew_val);
|
|
3566 |
} else {
|
|
3567 |
z_lgr(Rtmp1, Rstore_addr);
|
|
3568 |
z_xgr(Rtmp1, Rnew_val);
|
|
3569 |
}
|
|
3570 |
z_srag(Rtmp1, Rtmp1, HeapRegion::LogOfHRGrainBytes);
|
|
3571 |
z_bre(filtered);
|
|
3572 |
}
|
|
3573 |
|
|
3574 |
// Crosses regions, storing NULL?
|
|
3575 |
#ifdef ASSERT
|
|
3576 |
z_ltgr(Rnew_val, Rnew_val);
|
|
3577 |
asm_assert_ne("null oop not allowed (G1)", 0x255); // TODO: also on z? Checked by caller on PPC64, so following branch is obsolete:
|
|
3578 |
z_bre(filtered); // Safety net: don't break if we have a NULL oop.
|
|
3579 |
#endif
|
|
3580 |
Rnew_val = noreg; // end of lifetime
|
|
3581 |
|
|
3582 |
// Storing region crossing non-NULL, is card already dirty?
|
|
3583 |
assert(sizeof(*bs->byte_map_base) == sizeof(jbyte), "adjust this code");
|
|
3584 |
assert_different_registers(Rtmp1, Rtmp2, Rtmp3);
|
|
3585 |
// Make sure not to use Z_R0 for any of these registers.
|
|
3586 |
Register Rcard_addr = (Rtmp1 != Z_R0_scratch) ? Rtmp1 : Rtmp3;
|
|
3587 |
Register Rbase = (Rtmp2 != Z_R0_scratch) ? Rtmp2 : Rtmp3;
|
|
3588 |
|
|
3589 |
// calculate address of card
|
|
3590 |
load_const_optimized(Rbase, (address)bs->byte_map_base); // Card table base.
|
|
3591 |
z_srlg(Rcard_addr, Rstore_addr, CardTableModRefBS::card_shift); // Index into card table.
|
|
3592 |
add2reg_with_index(Rcard_addr, 0, Rcard_addr, Rbase); // Explicit calculation needed for cli.
|
|
3593 |
Rbase = noreg; // end of lifetime
|
|
3594 |
|
|
3595 |
// Filter young.
|
|
3596 |
assert((unsigned int)G1SATBCardTableModRefBS::g1_young_card_val() <= 255, "otherwise check this code");
|
|
3597 |
z_cli(0, Rcard_addr, (int)G1SATBCardTableModRefBS::g1_young_card_val());
|
|
3598 |
z_bre(filtered);
|
|
3599 |
|
|
3600 |
// Check the card value. If dirty, we're done.
|
|
3601 |
// This also avoids false sharing of the (already dirty) card.
|
|
3602 |
z_sync(); // Required to support concurrent cleaning.
|
|
3603 |
assert((unsigned int)CardTableModRefBS::dirty_card_val() <= 255, "otherwise check this code");
|
|
3604 |
z_cli(0, Rcard_addr, CardTableModRefBS::dirty_card_val()); // Reload after membar.
|
|
3605 |
z_bre(filtered);
|
|
3606 |
|
|
3607 |
// Storing a region crossing, non-NULL oop, card is clean.
|
|
3608 |
// Dirty card and log.
|
|
3609 |
z_mvi(0, Rcard_addr, CardTableModRefBS::dirty_card_val());
|
|
3610 |
|
|
3611 |
Register Rcard_addr_x = Rcard_addr;
|
|
3612 |
Register Rqueue_index = (Rtmp2 != Z_R0_scratch) ? Rtmp2 : Rtmp1;
|
|
3613 |
Register Rqueue_buf = (Rtmp3 != Z_R0_scratch) ? Rtmp3 : Rtmp1;
|
|
3614 |
const int qidx_off = in_bytes(JavaThread::dirty_card_queue_offset() + SATBMarkQueue::byte_offset_of_index());
|
|
3615 |
const int qbuf_off = in_bytes(JavaThread::dirty_card_queue_offset() + SATBMarkQueue::byte_offset_of_buf());
|
|
3616 |
if ((Rcard_addr == Rqueue_buf) || (Rcard_addr == Rqueue_index)) {
|
|
3617 |
Rcard_addr_x = Z_R0_scratch; // Register shortage. We have to use Z_R0.
|
|
3618 |
}
|
|
3619 |
lgr_if_needed(Rcard_addr_x, Rcard_addr);
|
|
3620 |
|
|
3621 |
load_and_test_long(Rqueue_index, Address(Z_thread, qidx_off));
|
|
3622 |
z_bre(callRuntime); // Index == 0 then jump to runtime.
|
|
3623 |
|
|
3624 |
z_lg(Rqueue_buf, qbuf_off, Z_thread);
|
|
3625 |
|
|
3626 |
add2reg(Rqueue_index, -wordSize); // Decrement index.
|
|
3627 |
z_stg(Rqueue_index, qidx_off, Z_thread);
|
|
3628 |
|
|
3629 |
z_stg(Rcard_addr_x, 0, Rqueue_index, Rqueue_buf); // Store card.
|
|
3630 |
z_bru(filtered);
|
|
3631 |
|
|
3632 |
bind(callRuntime);
|
|
3633 |
|
|
3634 |
// TODO: do we need a frame? Introduced to be on the safe side.
|
|
3635 |
bool needs_frame = true;
|
|
3636 |
|
|
3637 |
// VM call need frame to access(write) O register.
|
|
3638 |
if (needs_frame) {
|
|
3639 |
save_return_pc();
|
|
3640 |
push_frame_abi160(0); // Will use Z_R0 as tmp on old CPUs.
|
|
3641 |
}
|
|
3642 |
|
|
3643 |
// Save the live input values.
|
|
3644 |
call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_post), Rcard_addr_x, Z_thread);
|
|
3645 |
|
|
3646 |
if (needs_frame) {
|
|
3647 |
pop_frame();
|
|
3648 |
restore_return_pc();
|
|
3649 |
}
|
|
3650 |
|
|
3651 |
bind(filtered);
|
|
3652 |
|
|
3653 |
BLOCK_COMMENT("} g1_write_barrier_post");
|
|
3654 |
}
|
|
3655 |
#endif // INCLUDE_ALL_GCS
|
|
3656 |
|
|
3657 |
// Last_Java_sp must comply to the rules in frame_s390.hpp.
|
|
3658 |
void MacroAssembler::set_last_Java_frame(Register last_Java_sp, Register last_Java_pc, bool allow_relocation) {
|
|
3659 |
BLOCK_COMMENT("set_last_Java_frame {");
|
|
3660 |
|
|
3661 |
// Always set last_Java_pc and flags first because once last_Java_sp
|
|
3662 |
// is visible has_last_Java_frame is true and users will look at the
|
|
3663 |
// rest of the fields. (Note: flags should always be zero before we
|
|
3664 |
// get here so doesn't need to be set.)
|
|
3665 |
|
|
3666 |
// Verify that last_Java_pc was zeroed on return to Java.
|
|
3667 |
if (allow_relocation) {
|
|
3668 |
asm_assert_mem8_is_zero(in_bytes(JavaThread::last_Java_pc_offset()),
|
|
3669 |
Z_thread,
|
|
3670 |
"last_Java_pc not zeroed before leaving Java",
|
|
3671 |
0x200);
|
|
3672 |
} else {
|
|
3673 |
asm_assert_mem8_is_zero_static(in_bytes(JavaThread::last_Java_pc_offset()),
|
|
3674 |
Z_thread,
|
|
3675 |
"last_Java_pc not zeroed before leaving Java",
|
|
3676 |
0x200);
|
|
3677 |
}
|
|
3678 |
|
|
3679 |
// When returning from calling out from Java mode the frame anchor's
|
|
3680 |
// last_Java_pc will always be set to NULL. It is set here so that
|
|
3681 |
// if we are doing a call to native (not VM) that we capture the
|
|
3682 |
// known pc and don't have to rely on the native call having a
|
|
3683 |
// standard frame linkage where we can find the pc.
|
|
3684 |
if (last_Java_pc!=noreg) {
|
|
3685 |
z_stg(last_Java_pc, Address(Z_thread, JavaThread::last_Java_pc_offset()));
|
|
3686 |
}
|
|
3687 |
|
|
3688 |
// This membar release is not required on z/Architecture, since the sequence of stores
|
|
3689 |
// in maintained. Nevertheless, we leave it in to document the required ordering.
|
|
3690 |
// The implementation of z_release() should be empty.
|
|
3691 |
// z_release();
|
|
3692 |
|
|
3693 |
z_stg(last_Java_sp, Address(Z_thread, JavaThread::last_Java_sp_offset()));
|
|
3694 |
BLOCK_COMMENT("} set_last_Java_frame");
|
|
3695 |
}
|
|
3696 |
|
|
3697 |
void MacroAssembler::reset_last_Java_frame(bool allow_relocation) {
|
|
3698 |
BLOCK_COMMENT("reset_last_Java_frame {");
|
|
3699 |
|
|
3700 |
if (allow_relocation) {
|
|
3701 |
asm_assert_mem8_isnot_zero(in_bytes(JavaThread::last_Java_sp_offset()),
|
|
3702 |
Z_thread,
|
|
3703 |
"SP was not set, still zero",
|
|
3704 |
0x202);
|
|
3705 |
} else {
|
|
3706 |
asm_assert_mem8_isnot_zero_static(in_bytes(JavaThread::last_Java_sp_offset()),
|
|
3707 |
Z_thread,
|
|
3708 |
"SP was not set, still zero",
|
|
3709 |
0x202);
|
|
3710 |
}
|
|
3711 |
|
|
3712 |
// _last_Java_sp = 0
|
|
3713 |
// Clearing storage must be atomic here, so don't use clear_mem()!
|
|
3714 |
store_const(Address(Z_thread, JavaThread::last_Java_sp_offset()), 0);
|
|
3715 |
|
|
3716 |
// _last_Java_pc = 0
|
|
3717 |
store_const(Address(Z_thread, JavaThread::last_Java_pc_offset()), 0);
|
|
3718 |
|
|
3719 |
BLOCK_COMMENT("} reset_last_Java_frame");
|
|
3720 |
return;
|
|
3721 |
}
|
|
3722 |
|
|
3723 |
void MacroAssembler::set_top_ijava_frame_at_SP_as_last_Java_frame(Register sp, Register tmp1, bool allow_relocation) {
|
|
3724 |
assert_different_registers(sp, tmp1);
|
|
3725 |
|
|
3726 |
// We cannot trust that code generated by the C++ compiler saves R14
|
|
3727 |
// to z_abi_160.return_pc, because sometimes it spills R14 using stmg at
|
|
3728 |
// z_abi_160.gpr14 (e.g. InterpreterRuntime::_new()).
|
|
3729 |
// Therefore we load the PC into tmp1 and let set_last_Java_frame() save
|
|
3730 |
// it into the frame anchor.
|
|
3731 |
get_PC(tmp1);
|
|
3732 |
set_last_Java_frame(/*sp=*/sp, /*pc=*/tmp1, allow_relocation);
|
|
3733 |
}
|
|
3734 |
|
|
3735 |
void MacroAssembler::set_thread_state(JavaThreadState new_state) {
|
|
3736 |
z_release();
|
|
3737 |
|
|
3738 |
assert(Immediate::is_uimm16(_thread_max_state), "enum value out of range for instruction");
|
|
3739 |
assert(sizeof(JavaThreadState) == sizeof(int), "enum value must have base type int");
|
|
3740 |
store_const(Address(Z_thread, JavaThread::thread_state_offset()), new_state, Z_R0, false);
|
|
3741 |
}
|
|
3742 |
|
|
3743 |
void MacroAssembler::get_vm_result(Register oop_result) {
|
|
3744 |
verify_thread();
|
|
3745 |
|
|
3746 |
z_lg(oop_result, Address(Z_thread, JavaThread::vm_result_offset()));
|
|
3747 |
clear_mem(Address(Z_thread, JavaThread::vm_result_offset()), sizeof(void*));
|
|
3748 |
|
|
3749 |
verify_oop(oop_result);
|
|
3750 |
}
|
|
3751 |
|
|
3752 |
void MacroAssembler::get_vm_result_2(Register result) {
|
|
3753 |
verify_thread();
|
|
3754 |
|
|
3755 |
z_lg(result, Address(Z_thread, JavaThread::vm_result_2_offset()));
|
|
3756 |
clear_mem(Address(Z_thread, JavaThread::vm_result_2_offset()), sizeof(void*));
|
|
3757 |
}
|
|
3758 |
|
|
3759 |
// We require that C code which does not return a value in vm_result will
|
|
3760 |
// leave it undisturbed.
|
|
3761 |
void MacroAssembler::set_vm_result(Register oop_result) {
|
|
3762 |
z_stg(oop_result, Address(Z_thread, JavaThread::vm_result_offset()));
|
|
3763 |
}
|
|
3764 |
|
|
3765 |
// Explicit null checks (used for method handle code).
|
|
3766 |
void MacroAssembler::null_check(Register reg, Register tmp, int64_t offset) {
|
|
3767 |
if (!ImplicitNullChecks) {
|
|
3768 |
NearLabel ok;
|
|
3769 |
|
|
3770 |
compare64_and_branch(reg, (intptr_t) 0, Assembler::bcondNotEqual, ok);
|
|
3771 |
|
|
3772 |
// We just put the address into reg if it was 0 (tmp==Z_R0 is allowed so we can't use it for the address).
|
|
3773 |
address exception_entry = Interpreter::throw_NullPointerException_entry();
|
|
3774 |
load_absolute_address(reg, exception_entry);
|
|
3775 |
z_br(reg);
|
|
3776 |
|
|
3777 |
bind(ok);
|
|
3778 |
} else {
|
|
3779 |
if (needs_explicit_null_check((intptr_t)offset)) {
|
|
3780 |
// Provoke OS NULL exception if reg = NULL by
|
|
3781 |
// accessing M[reg] w/o changing any registers.
|
|
3782 |
z_lg(tmp, 0, reg);
|
|
3783 |
}
|
|
3784 |
// else
|
|
3785 |
// Nothing to do, (later) access of M[reg + offset]
|
|
3786 |
// will provoke OS NULL exception if reg = NULL.
|
|
3787 |
}
|
|
3788 |
}
|
|
3789 |
|
|
3790 |
//-------------------------------------
|
|
3791 |
// Compressed Klass Pointers
|
|
3792 |
//-------------------------------------
|
|
3793 |
|
|
3794 |
// Klass oop manipulations if compressed.
|
|
3795 |
void MacroAssembler::encode_klass_not_null(Register dst, Register src) {
|
|
3796 |
Register current = (src != noreg) ? src : dst; // Klass is in dst if no src provided. (dst == src) also possible.
|
|
3797 |
address base = Universe::narrow_klass_base();
|
|
3798 |
int shift = Universe::narrow_klass_shift();
|
|
3799 |
assert(UseCompressedClassPointers, "only for compressed klass ptrs");
|
|
3800 |
|
|
3801 |
BLOCK_COMMENT("cKlass encoder {");
|
|
3802 |
|
|
3803 |
#ifdef ASSERT
|
|
3804 |
Label ok;
|
|
3805 |
z_tmll(current, KlassAlignmentInBytes-1); // Check alignment.
|
|
3806 |
z_brc(Assembler::bcondAllZero, ok);
|
|
3807 |
// The plain disassembler does not recognize illtrap. It instead displays
|
|
3808 |
// a 32-bit value. Issueing two illtraps assures the disassembler finds
|
|
3809 |
// the proper beginning of the next instruction.
|
|
3810 |
z_illtrap(0xee);
|
|
3811 |
z_illtrap(0xee);
|
|
3812 |
bind(ok);
|
|
3813 |
#endif
|
|
3814 |
|
|
3815 |
if (base != NULL) {
|
|
3816 |
unsigned int base_h = ((unsigned long)base)>>32;
|
|
3817 |
unsigned int base_l = (unsigned int)((unsigned long)base);
|
|
3818 |
if ((base_h != 0) && (base_l == 0) && VM_Version::has_HighWordInstr()) {
|
|
3819 |
lgr_if_needed(dst, current);
|
|
3820 |
z_aih(dst, -((int)base_h)); // Base has no set bits in lower half.
|
|
3821 |
} else if ((base_h == 0) && (base_l != 0)) {
|
|
3822 |
lgr_if_needed(dst, current);
|
|
3823 |
z_agfi(dst, -(int)base_l);
|
|
3824 |
} else {
|
|
3825 |
load_const(Z_R0, base);
|
|
3826 |
lgr_if_needed(dst, current);
|
|
3827 |
z_sgr(dst, Z_R0);
|
|
3828 |
}
|
|
3829 |
current = dst;
|
|
3830 |
}
|
|
3831 |
if (shift != 0) {
|
|
3832 |
assert (LogKlassAlignmentInBytes == shift, "decode alg wrong");
|
|
3833 |
z_srlg(dst, current, shift);
|
|
3834 |
current = dst;
|
|
3835 |
}
|
|
3836 |
lgr_if_needed(dst, current); // Move may be required (if neither base nor shift != 0).
|
|
3837 |
|
|
3838 |
BLOCK_COMMENT("} cKlass encoder");
|
|
3839 |
}
|
|
3840 |
|
|
3841 |
// This function calculates the size of the code generated by
|
|
3842 |
// decode_klass_not_null(register dst, Register src)
|
|
3843 |
// when (Universe::heap() != NULL). Hence, if the instructions
|
|
3844 |
// it generates change, then this method needs to be updated.
|
|
3845 |
int MacroAssembler::instr_size_for_decode_klass_not_null() {
|
|
3846 |
address base = Universe::narrow_klass_base();
|
|
3847 |
int shift_size = Universe::narrow_klass_shift() == 0 ? 0 : 6; /* sllg */
|
|
3848 |
int addbase_size = 0;
|
|
3849 |
assert(UseCompressedClassPointers, "only for compressed klass ptrs");
|
|
3850 |
|
|
3851 |
if (base != NULL) {
|
|
3852 |
unsigned int base_h = ((unsigned long)base)>>32;
|
|
3853 |
unsigned int base_l = (unsigned int)((unsigned long)base);
|
|
3854 |
if ((base_h != 0) && (base_l == 0) && VM_Version::has_HighWordInstr()) {
|
|
3855 |
addbase_size += 6; /* aih */
|
|
3856 |
} else if ((base_h == 0) && (base_l != 0)) {
|
|
3857 |
addbase_size += 6; /* algfi */
|
|
3858 |
} else {
|
|
3859 |
addbase_size += load_const_size();
|
|
3860 |
addbase_size += 4; /* algr */
|
|
3861 |
}
|
|
3862 |
}
|
|
3863 |
#ifdef ASSERT
|
|
3864 |
addbase_size += 10;
|
|
3865 |
addbase_size += 2; // Extra sigill.
|
|
3866 |
#endif
|
|
3867 |
return addbase_size + shift_size;
|
|
3868 |
}
|
|
3869 |
|
|
3870 |
// !!! If the instructions that get generated here change
|
|
3871 |
// then function instr_size_for_decode_klass_not_null()
|
|
3872 |
// needs to get updated.
|
|
3873 |
// This variant of decode_klass_not_null() must generate predictable code!
|
|
3874 |
// The code must only depend on globally known parameters.
|
|
3875 |
void MacroAssembler::decode_klass_not_null(Register dst) {
|
|
3876 |
address base = Universe::narrow_klass_base();
|
|
3877 |
int shift = Universe::narrow_klass_shift();
|
|
3878 |
int beg_off = offset();
|
|
3879 |
assert(UseCompressedClassPointers, "only for compressed klass ptrs");
|
|
3880 |
|
|
3881 |
BLOCK_COMMENT("cKlass decoder (const size) {");
|
|
3882 |
|
|
3883 |
if (shift != 0) { // Shift required?
|
|
3884 |
z_sllg(dst, dst, shift);
|
|
3885 |
}
|
|
3886 |
if (base != NULL) {
|
|
3887 |
unsigned int base_h = ((unsigned long)base)>>32;
|
|
3888 |
unsigned int base_l = (unsigned int)((unsigned long)base);
|
|
3889 |
if ((base_h != 0) && (base_l == 0) && VM_Version::has_HighWordInstr()) {
|
|
3890 |
z_aih(dst, base_h); // Base has no set bits in lower half.
|
|
3891 |
} else if ((base_h == 0) && (base_l != 0)) {
|
|
3892 |
z_algfi(dst, base_l); // Base has no set bits in upper half.
|
|
3893 |
} else {
|
|
3894 |
load_const(Z_R0, base); // Base has set bits everywhere.
|
|
3895 |
z_algr(dst, Z_R0);
|
|
3896 |
}
|
|
3897 |
}
|
|
3898 |
|
|
3899 |
#ifdef ASSERT
|
|
3900 |
Label ok;
|
|
3901 |
z_tmll(dst, KlassAlignmentInBytes-1); // Check alignment.
|
|
3902 |
z_brc(Assembler::bcondAllZero, ok);
|
|
3903 |
// The plain disassembler does not recognize illtrap. It instead displays
|
|
3904 |
// a 32-bit value. Issueing two illtraps assures the disassembler finds
|
|
3905 |
// the proper beginning of the next instruction.
|
|
3906 |
z_illtrap(0xd1);
|
|
3907 |
z_illtrap(0xd1);
|
|
3908 |
bind(ok);
|
|
3909 |
#endif
|
|
3910 |
assert(offset() == beg_off + instr_size_for_decode_klass_not_null(), "Code gen mismatch.");
|
|
3911 |
|
|
3912 |
BLOCK_COMMENT("} cKlass decoder (const size)");
|
|
3913 |
}
|
|
3914 |
|
|
3915 |
// This variant of decode_klass_not_null() is for cases where
|
|
3916 |
// 1) the size of the generated instructions may vary
|
|
3917 |
// 2) the result is (potentially) stored in a register different from the source.
|
|
3918 |
void MacroAssembler::decode_klass_not_null(Register dst, Register src) {
|
|
3919 |
address base = Universe::narrow_klass_base();
|
|
3920 |
int shift = Universe::narrow_klass_shift();
|
|
3921 |
assert(UseCompressedClassPointers, "only for compressed klass ptrs");
|
|
3922 |
|
|
3923 |
BLOCK_COMMENT("cKlass decoder {");
|
|
3924 |
|
|
3925 |
if (src == noreg) src = dst;
|
|
3926 |
|
|
3927 |
if (shift != 0) { // Shift or at least move required?
|
|
3928 |
z_sllg(dst, src, shift);
|
|
3929 |
} else {
|
|
3930 |
lgr_if_needed(dst, src);
|
|
3931 |
}
|
|
3932 |
|
|
3933 |
if (base != NULL) {
|
|
3934 |
unsigned int base_h = ((unsigned long)base)>>32;
|
|
3935 |
unsigned int base_l = (unsigned int)((unsigned long)base);
|
|
3936 |
if ((base_h != 0) && (base_l == 0) && VM_Version::has_HighWordInstr()) {
|
|
3937 |
z_aih(dst, base_h); // Base has not set bits in lower half.
|
|
3938 |
} else if ((base_h == 0) && (base_l != 0)) {
|
|
3939 |
z_algfi(dst, base_l); // Base has no set bits in upper half.
|
|
3940 |
} else {
|
|
3941 |
load_const_optimized(Z_R0, base); // Base has set bits everywhere.
|
|
3942 |
z_algr(dst, Z_R0);
|
|
3943 |
}
|
|
3944 |
}
|
|
3945 |
|
|
3946 |
#ifdef ASSERT
|
|
3947 |
Label ok;
|
|
3948 |
z_tmll(dst, KlassAlignmentInBytes-1); // Check alignment.
|
|
3949 |
z_brc(Assembler::bcondAllZero, ok);
|
|
3950 |
// The plain disassembler does not recognize illtrap. It instead displays
|
|
3951 |
// a 32-bit value. Issueing two illtraps assures the disassembler finds
|
|
3952 |
// the proper beginning of the next instruction.
|
|
3953 |
z_illtrap(0xd2);
|
|
3954 |
z_illtrap(0xd2);
|
|
3955 |
bind(ok);
|
|
3956 |
#endif
|
|
3957 |
BLOCK_COMMENT("} cKlass decoder");
|
|
3958 |
}
|
|
3959 |
|
|
3960 |
void MacroAssembler::load_klass(Register klass, Address mem) {
|
|
3961 |
if (UseCompressedClassPointers) {
|
|
3962 |
z_llgf(klass, mem);
|
|
3963 |
// Attention: no null check here!
|
|
3964 |
decode_klass_not_null(klass);
|
|
3965 |
} else {
|
|
3966 |
z_lg(klass, mem);
|
|
3967 |
}
|
|
3968 |
}
|
|
3969 |
|
|
3970 |
void MacroAssembler::load_klass(Register klass, Register src_oop) {
|
|
3971 |
if (UseCompressedClassPointers) {
|
|
3972 |
z_llgf(klass, oopDesc::klass_offset_in_bytes(), src_oop);
|
|
3973 |
// Attention: no null check here!
|
|
3974 |
decode_klass_not_null(klass);
|
|
3975 |
} else {
|
|
3976 |
z_lg(klass, oopDesc::klass_offset_in_bytes(), src_oop);
|
|
3977 |
}
|
|
3978 |
}
|
|
3979 |
|
|
3980 |
void MacroAssembler::load_prototype_header(Register Rheader, Register Rsrc_oop) {
|
|
3981 |
assert_different_registers(Rheader, Rsrc_oop);
|
|
3982 |
load_klass(Rheader, Rsrc_oop);
|
|
3983 |
z_lg(Rheader, Address(Rheader, Klass::prototype_header_offset()));
|
|
3984 |
}
|
|
3985 |
|
|
3986 |
void MacroAssembler::store_klass(Register klass, Register dst_oop, Register ck) {
|
|
3987 |
if (UseCompressedClassPointers) {
|
|
3988 |
assert_different_registers(dst_oop, klass, Z_R0);
|
|
3989 |
if (ck == noreg) ck = klass;
|
|
3990 |
encode_klass_not_null(ck, klass);
|
|
3991 |
z_st(ck, Address(dst_oop, oopDesc::klass_offset_in_bytes()));
|
|
3992 |
} else {
|
|
3993 |
z_stg(klass, Address(dst_oop, oopDesc::klass_offset_in_bytes()));
|
|
3994 |
}
|
|
3995 |
}
|
|
3996 |
|
|
3997 |
void MacroAssembler::store_klass_gap(Register s, Register d) {
|
|
3998 |
if (UseCompressedClassPointers) {
|
|
3999 |
assert(s != d, "not enough registers");
|
|
4000 |
z_st(s, Address(d, oopDesc::klass_gap_offset_in_bytes()));
|
|
4001 |
}
|
|
4002 |
}
|
|
4003 |
|
|
4004 |
// Compare klass ptr in memory against klass ptr in register.
|
|
4005 |
//
|
|
4006 |
// Rop1 - klass in register, always uncompressed.
|
|
4007 |
// disp - Offset of klass in memory, compressed/uncompressed, depending on runtime flag.
|
|
4008 |
// Rbase - Base address of cKlass in memory.
|
|
4009 |
// maybeNULL - True if Rop1 possibly is a NULL.
|
|
4010 |
void MacroAssembler::compare_klass_ptr(Register Rop1, int64_t disp, Register Rbase, bool maybeNULL) {
|
|
4011 |
|
|
4012 |
BLOCK_COMMENT("compare klass ptr {");
|
|
4013 |
|
|
4014 |
if (UseCompressedClassPointers) {
|
|
4015 |
const int shift = Universe::narrow_klass_shift();
|
|
4016 |
address base = Universe::narrow_klass_base();
|
|
4017 |
|
|
4018 |
assert((shift == 0) || (shift == LogKlassAlignmentInBytes), "cKlass encoder detected bad shift");
|
|
4019 |
assert_different_registers(Rop1, Z_R0);
|
|
4020 |
assert_different_registers(Rop1, Rbase, Z_R1);
|
|
4021 |
|
|
4022 |
// First encode register oop and then compare with cOop in memory.
|
|
4023 |
// This sequence saves an unnecessary cOop load and decode.
|
|
4024 |
if (base == NULL) {
|
|
4025 |
if (shift == 0) {
|
|
4026 |
z_cl(Rop1, disp, Rbase); // Unscaled
|
|
4027 |
} else {
|
|
4028 |
z_srlg(Z_R0, Rop1, shift); // ZeroBased
|
|
4029 |
z_cl(Z_R0, disp, Rbase);
|
|
4030 |
}
|
|
4031 |
} else { // HeapBased
|
|
4032 |
#ifdef ASSERT
|
|
4033 |
bool used_R0 = true;
|
|
4034 |
bool used_R1 = true;
|
|
4035 |
#endif
|
|
4036 |
Register current = Rop1;
|
|
4037 |
Label done;
|
|
4038 |
|
|
4039 |
if (maybeNULL) { // NULL ptr must be preserved!
|
|
4040 |
z_ltgr(Z_R0, current);
|
|
4041 |
z_bre(done);
|
|
4042 |
current = Z_R0;
|
|
4043 |
}
|
|
4044 |
|
|
4045 |
unsigned int base_h = ((unsigned long)base)>>32;
|
|
4046 |
unsigned int base_l = (unsigned int)((unsigned long)base);
|
|
4047 |
if ((base_h != 0) && (base_l == 0) && VM_Version::has_HighWordInstr()) {
|
|
4048 |
lgr_if_needed(Z_R0, current);
|
|
4049 |
z_aih(Z_R0, -((int)base_h)); // Base has no set bits in lower half.
|
|
4050 |
} else if ((base_h == 0) && (base_l != 0)) {
|
|
4051 |
lgr_if_needed(Z_R0, current);
|
|
4052 |
z_agfi(Z_R0, -(int)base_l);
|
|
4053 |
} else {
|
|
4054 |
int pow2_offset = get_oop_base_complement(Z_R1, ((uint64_t)(intptr_t)base));
|
|
4055 |
add2reg_with_index(Z_R0, pow2_offset, Z_R1, Rop1); // Subtract base by adding complement.
|
|
4056 |
}
|
|
4057 |
|
|
4058 |
if (shift != 0) {
|
|
4059 |
z_srlg(Z_R0, Z_R0, shift);
|
|
4060 |
}
|
|
4061 |
bind(done);
|
|
4062 |
z_cl(Z_R0, disp, Rbase);
|
|
4063 |
#ifdef ASSERT
|
|
4064 |
if (used_R0) preset_reg(Z_R0, 0xb05bUL, 2);
|
|
4065 |
if (used_R1) preset_reg(Z_R1, 0xb06bUL, 2);
|
|
4066 |
#endif
|
|
4067 |
}
|
|
4068 |
} else {
|
|
4069 |
z_clg(Rop1, disp, Z_R0, Rbase);
|
|
4070 |
}
|
|
4071 |
BLOCK_COMMENT("} compare klass ptr");
|
|
4072 |
}
|
|
4073 |
|
|
4074 |
//---------------------------
|
|
4075 |
// Compressed oops
|
|
4076 |
//---------------------------
|
|
4077 |
|
|
4078 |
void MacroAssembler::encode_heap_oop(Register oop) {
|
|
4079 |
oop_encoder(oop, oop, true /*maybe null*/);
|
|
4080 |
}
|
|
4081 |
|
|
4082 |
void MacroAssembler::encode_heap_oop_not_null(Register oop) {
|
|
4083 |
oop_encoder(oop, oop, false /*not null*/);
|
|
4084 |
}
|
|
4085 |
|
|
4086 |
// Called with something derived from the oop base. e.g. oop_base>>3.
|
|
4087 |
int MacroAssembler::get_oop_base_pow2_offset(uint64_t oop_base) {
|
|
4088 |
unsigned int oop_base_ll = ((unsigned int)(oop_base >> 0)) & 0xffff;
|
|
4089 |
unsigned int oop_base_lh = ((unsigned int)(oop_base >> 16)) & 0xffff;
|
|
4090 |
unsigned int oop_base_hl = ((unsigned int)(oop_base >> 32)) & 0xffff;
|
|
4091 |
unsigned int oop_base_hh = ((unsigned int)(oop_base >> 48)) & 0xffff;
|
|
4092 |
unsigned int n_notzero_parts = (oop_base_ll == 0 ? 0:1)
|
|
4093 |
+ (oop_base_lh == 0 ? 0:1)
|
|
4094 |
+ (oop_base_hl == 0 ? 0:1)
|
|
4095 |
+ (oop_base_hh == 0 ? 0:1);
|
|
4096 |
|
|
4097 |
assert(oop_base != 0, "This is for HeapBased cOops only");
|
|
4098 |
|
|
4099 |
if (n_notzero_parts != 1) { // Check if oop_base is just a few pages shy of a power of 2.
|
|
4100 |
uint64_t pow2_offset = 0x10000 - oop_base_ll;
|
|
4101 |
if (pow2_offset < 0x8000) { // This might not be necessary.
|
|
4102 |
uint64_t oop_base2 = oop_base + pow2_offset;
|
|
4103 |
|
|
4104 |
oop_base_ll = ((unsigned int)(oop_base2 >> 0)) & 0xffff;
|
|
4105 |
oop_base_lh = ((unsigned int)(oop_base2 >> 16)) & 0xffff;
|
|
4106 |
oop_base_hl = ((unsigned int)(oop_base2 >> 32)) & 0xffff;
|
|
4107 |
oop_base_hh = ((unsigned int)(oop_base2 >> 48)) & 0xffff;
|
|
4108 |
n_notzero_parts = (oop_base_ll == 0 ? 0:1) +
|
|
4109 |
(oop_base_lh == 0 ? 0:1) +
|
|
4110 |
(oop_base_hl == 0 ? 0:1) +
|
|
4111 |
(oop_base_hh == 0 ? 0:1);
|
|
4112 |
if (n_notzero_parts == 1) {
|
|
4113 |
assert(-(int64_t)pow2_offset != (int64_t)-1, "We use -1 to signal uninitialized base register");
|
|
4114 |
return -pow2_offset;
|
|
4115 |
}
|
|
4116 |
}
|
|
4117 |
}
|
|
4118 |
return 0;
|
|
4119 |
}
|
|
4120 |
|
|
4121 |
// If base address is offset from a straight power of two by just a few pages,
|
|
4122 |
// return this offset to the caller for a possible later composite add.
|
|
4123 |
// TODO/FIX: will only work correctly for 4k pages.
|
|
4124 |
int MacroAssembler::get_oop_base(Register Rbase, uint64_t oop_base) {
|
|
4125 |
int pow2_offset = get_oop_base_pow2_offset(oop_base);
|
|
4126 |
|
|
4127 |
load_const_optimized(Rbase, oop_base - pow2_offset); // Best job possible.
|
|
4128 |
|
|
4129 |
return pow2_offset;
|
|
4130 |
}
|
|
4131 |
|
|
4132 |
int MacroAssembler::get_oop_base_complement(Register Rbase, uint64_t oop_base) {
|
|
4133 |
int offset = get_oop_base(Rbase, oop_base);
|
|
4134 |
z_lcgr(Rbase, Rbase);
|
|
4135 |
return -offset;
|
|
4136 |
}
|
|
4137 |
|
|
4138 |
// Compare compressed oop in memory against oop in register.
|
|
4139 |
// Rop1 - Oop in register.
|
|
4140 |
// disp - Offset of cOop in memory.
|
|
4141 |
// Rbase - Base address of cOop in memory.
|
|
4142 |
// maybeNULL - True if Rop1 possibly is a NULL.
|
|
4143 |
// maybeNULLtarget - Branch target for Rop1 == NULL, if flow control shall NOT continue with compare instruction.
|
|
4144 |
void MacroAssembler::compare_heap_oop(Register Rop1, Address mem, bool maybeNULL) {
|
|
4145 |
Register Rbase = mem.baseOrR0();
|
|
4146 |
Register Rindex = mem.indexOrR0();
|
|
4147 |
int64_t disp = mem.disp();
|
|
4148 |
|
|
4149 |
const int shift = Universe::narrow_oop_shift();
|
|
4150 |
address base = Universe::narrow_oop_base();
|
|
4151 |
|
|
4152 |
assert(UseCompressedOops, "must be on to call this method");
|
|
4153 |
assert(Universe::heap() != NULL, "java heap must be initialized to call this method");
|
|
4154 |
assert((shift == 0) || (shift == LogMinObjAlignmentInBytes), "cOop encoder detected bad shift");
|
|
4155 |
assert_different_registers(Rop1, Z_R0);
|
|
4156 |
assert_different_registers(Rop1, Rbase, Z_R1);
|
|
4157 |
assert_different_registers(Rop1, Rindex, Z_R1);
|
|
4158 |
|
|
4159 |
BLOCK_COMMENT("compare heap oop {");
|
|
4160 |
|
|
4161 |
// First encode register oop and then compare with cOop in memory.
|
|
4162 |
// This sequence saves an unnecessary cOop load and decode.
|
|
4163 |
if (base == NULL) {
|
|
4164 |
if (shift == 0) {
|
|
4165 |
z_cl(Rop1, disp, Rindex, Rbase); // Unscaled
|
|
4166 |
} else {
|
|
4167 |
z_srlg(Z_R0, Rop1, shift); // ZeroBased
|
|
4168 |
z_cl(Z_R0, disp, Rindex, Rbase);
|
|
4169 |
}
|
|
4170 |
} else { // HeapBased
|
|
4171 |
#ifdef ASSERT
|
|
4172 |
bool used_R0 = true;
|
|
4173 |
bool used_R1 = true;
|
|
4174 |
#endif
|
|
4175 |
Label done;
|
|
4176 |
int pow2_offset = get_oop_base_complement(Z_R1, ((uint64_t)(intptr_t)base));
|
|
4177 |
|
|
4178 |
if (maybeNULL) { // NULL ptr must be preserved!
|
|
4179 |
z_ltgr(Z_R0, Rop1);
|
|
4180 |
z_bre(done);
|
|
4181 |
}
|
|
4182 |
|
|
4183 |
add2reg_with_index(Z_R0, pow2_offset, Z_R1, Rop1);
|
|
4184 |
z_srlg(Z_R0, Z_R0, shift);
|
|
4185 |
|
|
4186 |
bind(done);
|
|
4187 |
z_cl(Z_R0, disp, Rindex, Rbase);
|
|
4188 |
#ifdef ASSERT
|
|
4189 |
if (used_R0) preset_reg(Z_R0, 0xb05bUL, 2);
|
|
4190 |
if (used_R1) preset_reg(Z_R1, 0xb06bUL, 2);
|
|
4191 |
#endif
|
|
4192 |
}
|
|
4193 |
BLOCK_COMMENT("} compare heap oop");
|
|
4194 |
}
|
|
4195 |
|
|
4196 |
// Load heap oop and decompress, if necessary.
|
|
4197 |
void MacroAssembler::load_heap_oop(Register dest, const Address &a) {
|
|
4198 |
if (UseCompressedOops) {
|
|
4199 |
z_llgf(dest, a.disp(), a.indexOrR0(), a.baseOrR0());
|
|
4200 |
oop_decoder(dest, dest, true);
|
|
4201 |
} else {
|
|
4202 |
z_lg(dest, a.disp(), a.indexOrR0(), a.baseOrR0());
|
|
4203 |
}
|
|
4204 |
}
|
|
4205 |
|
|
4206 |
// Load heap oop and decompress, if necessary.
|
|
4207 |
void MacroAssembler::load_heap_oop(Register dest, int64_t disp, Register base) {
|
|
4208 |
if (UseCompressedOops) {
|
|
4209 |
z_llgf(dest, disp, base);
|
|
4210 |
oop_decoder(dest, dest, true);
|
|
4211 |
} else {
|
|
4212 |
z_lg(dest, disp, base);
|
|
4213 |
}
|
|
4214 |
}
|
|
4215 |
|
|
4216 |
// Load heap oop and decompress, if necessary.
|
|
4217 |
void MacroAssembler::load_heap_oop_not_null(Register dest, int64_t disp, Register base) {
|
|
4218 |
if (UseCompressedOops) {
|
|
4219 |
z_llgf(dest, disp, base);
|
|
4220 |
oop_decoder(dest, dest, false);
|
|
4221 |
} else {
|
|
4222 |
z_lg(dest, disp, base);
|
|
4223 |
}
|
|
4224 |
}
|
|
4225 |
|
|
4226 |
// Compress, if necessary, and store oop to heap.
|
|
4227 |
void MacroAssembler::store_heap_oop(Register Roop, RegisterOrConstant offset, Register base) {
|
|
4228 |
Register Ridx = offset.is_register() ? offset.register_or_noreg() : Z_R0;
|
|
4229 |
if (UseCompressedOops) {
|
|
4230 |
assert_different_registers(Roop, offset.register_or_noreg(), base);
|
|
4231 |
encode_heap_oop(Roop);
|
|
4232 |
z_st(Roop, offset.constant_or_zero(), Ridx, base);
|
|
4233 |
} else {
|
|
4234 |
z_stg(Roop, offset.constant_or_zero(), Ridx, base);
|
|
4235 |
}
|
|
4236 |
}
|
|
4237 |
|
|
4238 |
// Compress, if necessary, and store oop to heap. Oop is guaranteed to be not NULL.
|
|
4239 |
void MacroAssembler::store_heap_oop_not_null(Register Roop, RegisterOrConstant offset, Register base) {
|
|
4240 |
Register Ridx = offset.is_register() ? offset.register_or_noreg() : Z_R0;
|
|
4241 |
if (UseCompressedOops) {
|
|
4242 |
assert_different_registers(Roop, offset.register_or_noreg(), base);
|
|
4243 |
encode_heap_oop_not_null(Roop);
|
|
4244 |
z_st(Roop, offset.constant_or_zero(), Ridx, base);
|
|
4245 |
} else {
|
|
4246 |
z_stg(Roop, offset.constant_or_zero(), Ridx, base);
|
|
4247 |
}
|
|
4248 |
}
|
|
4249 |
|
|
4250 |
// Store NULL oop to heap.
|
|
4251 |
void MacroAssembler::store_heap_oop_null(Register zero, RegisterOrConstant offset, Register base) {
|
|
4252 |
Register Ridx = offset.is_register() ? offset.register_or_noreg() : Z_R0;
|
|
4253 |
if (UseCompressedOops) {
|
|
4254 |
z_st(zero, offset.constant_or_zero(), Ridx, base);
|
|
4255 |
} else {
|
|
4256 |
z_stg(zero, offset.constant_or_zero(), Ridx, base);
|
|
4257 |
}
|
|
4258 |
}
|
|
4259 |
|
|
4260 |
//-------------------------------------------------
|
|
4261 |
// Encode compressed oop. Generally usable encoder.
|
|
4262 |
//-------------------------------------------------
|
|
4263 |
// Rsrc - contains regular oop on entry. It remains unchanged.
|
|
4264 |
// Rdst - contains compressed oop on exit.
|
|
4265 |
// Rdst and Rsrc may indicate same register, in which case Rsrc does not remain unchanged.
|
|
4266 |
//
|
|
4267 |
// Rdst must not indicate scratch register Z_R1 (Z_R1_scratch) for functionality.
|
|
4268 |
// Rdst should not indicate scratch register Z_R0 (Z_R0_scratch) for performance.
|
|
4269 |
//
|
|
4270 |
// only32bitValid is set, if later code only uses the lower 32 bits. In this
|
|
4271 |
// case we must not fix the upper 32 bits.
|
|
4272 |
void MacroAssembler::oop_encoder(Register Rdst, Register Rsrc, bool maybeNULL,
|
|
4273 |
Register Rbase, int pow2_offset, bool only32bitValid) {
|
|
4274 |
|
|
4275 |
const address oop_base = Universe::narrow_oop_base();
|
|
4276 |
const int oop_shift = Universe::narrow_oop_shift();
|
|
4277 |
const bool disjoint = Universe::narrow_oop_base_disjoint();
|
|
4278 |
|
|
4279 |
assert(UseCompressedOops, "must be on to call this method");
|
|
4280 |
assert(Universe::heap() != NULL, "java heap must be initialized to call this encoder");
|
|
4281 |
assert((oop_shift == 0) || (oop_shift == LogMinObjAlignmentInBytes), "cOop encoder detected bad shift");
|
|
4282 |
|
|
4283 |
if (disjoint || (oop_base == NULL)) {
|
|
4284 |
BLOCK_COMMENT("cOop encoder zeroBase {");
|
|
4285 |
if (oop_shift == 0) {
|
|
4286 |
if (oop_base != NULL && !only32bitValid) {
|
|
4287 |
z_llgfr(Rdst, Rsrc); // Clear upper bits in case the register will be decoded again.
|
|
4288 |
} else {
|
|
4289 |
lgr_if_needed(Rdst, Rsrc);
|
|
4290 |
}
|
|
4291 |
} else {
|
|
4292 |
z_srlg(Rdst, Rsrc, oop_shift);
|
|
4293 |
if (oop_base != NULL && !only32bitValid) {
|
|
4294 |
z_llgfr(Rdst, Rdst); // Clear upper bits in case the register will be decoded again.
|
|
4295 |
}
|
|
4296 |
}
|
|
4297 |
BLOCK_COMMENT("} cOop encoder zeroBase");
|
|
4298 |
return;
|
|
4299 |
}
|
|
4300 |
|
|
4301 |
bool used_R0 = false;
|
|
4302 |
bool used_R1 = false;
|
|
4303 |
|
|
4304 |
BLOCK_COMMENT("cOop encoder general {");
|
|
4305 |
assert_different_registers(Rdst, Z_R1);
|
|
4306 |
assert_different_registers(Rsrc, Rbase);
|
|
4307 |
if (maybeNULL) {
|
|
4308 |
Label done;
|
|
4309 |
// We reorder shifting and subtracting, so that we can compare
|
|
4310 |
// and shift in parallel:
|
|
4311 |
//
|
|
4312 |
// cycle 0: potential LoadN, base = <const>
|
|
4313 |
// cycle 1: base = !base dst = src >> 3, cmp cr = (src != 0)
|
|
4314 |
// cycle 2: if (cr) br, dst = dst + base + offset
|
|
4315 |
|
|
4316 |
// Get oop_base components.
|
|
4317 |
if (pow2_offset == -1) {
|
|
4318 |
if (Rdst == Rbase) {
|
|
4319 |
if (Rdst == Z_R1 || Rsrc == Z_R1) {
|
|
4320 |
Rbase = Z_R0;
|
|
4321 |
used_R0 = true;
|
|
4322 |
} else {
|
|
4323 |
Rdst = Z_R1;
|
|
4324 |
used_R1 = true;
|
|
4325 |
}
|
|
4326 |
}
|
|
4327 |
if (Rbase == Z_R1) {
|
|
4328 |
used_R1 = true;
|
|
4329 |
}
|
|
4330 |
pow2_offset = get_oop_base_complement(Rbase, ((uint64_t)(intptr_t)oop_base) >> oop_shift);
|
|
4331 |
}
|
|
4332 |
assert_different_registers(Rdst, Rbase);
|
|
4333 |
|
|
4334 |
// Check for NULL oop (must be left alone) and shift.
|
|
4335 |
if (oop_shift != 0) { // Shift out alignment bits
|
|
4336 |
if (((intptr_t)oop_base&0xc000000000000000L) == 0L) { // We are sure: no single address will have the leftmost bit set.
|
|
4337 |
z_srag(Rdst, Rsrc, oop_shift); // Arithmetic shift sets the condition code.
|
|
4338 |
} else {
|
|
4339 |
z_srlg(Rdst, Rsrc, oop_shift);
|
|
4340 |
z_ltgr(Rsrc, Rsrc); // This is the recommended way of testing for zero.
|
|
4341 |
// This probably is faster, as it does not write a register. No!
|
|
4342 |
// z_cghi(Rsrc, 0);
|
|
4343 |
}
|
|
4344 |
} else {
|
|
4345 |
z_ltgr(Rdst, Rsrc); // Move NULL to result register.
|
|
4346 |
}
|
|
4347 |
z_bre(done);
|
|
4348 |
|
|
4349 |
// Subtract oop_base components.
|
|
4350 |
if ((Rdst == Z_R0) || (Rbase == Z_R0)) {
|
|
4351 |
z_algr(Rdst, Rbase);
|
|
4352 |
if (pow2_offset != 0) { add2reg(Rdst, pow2_offset); }
|
|
4353 |
} else {
|
|
4354 |
add2reg_with_index(Rdst, pow2_offset, Rbase, Rdst);
|
|
4355 |
}
|
|
4356 |
if (!only32bitValid) {
|
|
4357 |
z_llgfr(Rdst, Rdst); // Clear upper bits in case the register will be decoded again.
|
|
4358 |
}
|
|
4359 |
bind(done);
|
|
4360 |
|
|
4361 |
} else { // not null
|
|
4362 |
// Get oop_base components.
|
|
4363 |
if (pow2_offset == -1) {
|
|
4364 |
pow2_offset = get_oop_base_complement(Rbase, (uint64_t)(intptr_t)oop_base);
|
|
4365 |
}
|
|
4366 |
|
|
4367 |
// Subtract oop_base components and shift.
|
|
4368 |
if (Rdst == Z_R0 || Rsrc == Z_R0 || Rbase == Z_R0) {
|
|
4369 |
// Don't use lay instruction.
|
|
4370 |
if (Rdst == Rsrc) {
|
|
4371 |
z_algr(Rdst, Rbase);
|
|
4372 |
} else {
|
|
4373 |
lgr_if_needed(Rdst, Rbase);
|
|
4374 |
z_algr(Rdst, Rsrc);
|
|
4375 |
}
|
|
4376 |
if (pow2_offset != 0) add2reg(Rdst, pow2_offset);
|
|
4377 |
} else {
|
|
4378 |
add2reg_with_index(Rdst, pow2_offset, Rbase, Rsrc);
|
|
4379 |
}
|
|
4380 |
if (oop_shift != 0) { // Shift out alignment bits.
|
|
4381 |
z_srlg(Rdst, Rdst, oop_shift);
|
|
4382 |
}
|
|
4383 |
if (!only32bitValid) {
|
|
4384 |
z_llgfr(Rdst, Rdst); // Clear upper bits in case the register will be decoded again.
|
|
4385 |
}
|
|
4386 |
}
|
|
4387 |
#ifdef ASSERT
|
|
4388 |
if (used_R0 && Rdst != Z_R0 && Rsrc != Z_R0) { preset_reg(Z_R0, 0xb01bUL, 2); }
|
|
4389 |
if (used_R1 && Rdst != Z_R1 && Rsrc != Z_R1) { preset_reg(Z_R1, 0xb02bUL, 2); }
|
|
4390 |
#endif
|
|
4391 |
BLOCK_COMMENT("} cOop encoder general");
|
|
4392 |
}
|
|
4393 |
|
|
4394 |
//-------------------------------------------------
|
|
4395 |
// decode compressed oop. Generally usable decoder.
|
|
4396 |
//-------------------------------------------------
|
|
4397 |
// Rsrc - contains compressed oop on entry.
|
|
4398 |
// Rdst - contains regular oop on exit.
|
|
4399 |
// Rdst and Rsrc may indicate same register.
|
|
4400 |
// Rdst must not be the same register as Rbase, if Rbase was preloaded (before call).
|
|
4401 |
// Rdst can be the same register as Rbase. Then, either Z_R0 or Z_R1 must be available as scratch.
|
|
4402 |
// Rbase - register to use for the base
|
|
4403 |
// pow2_offset - offset of base to nice value. If -1, base must be loaded.
|
|
4404 |
// For performance, it is good to
|
|
4405 |
// - avoid Z_R0 for any of the argument registers.
|
|
4406 |
// - keep Rdst and Rsrc distinct from Rbase. Rdst == Rsrc is ok for performance.
|
|
4407 |
// - avoid Z_R1 for Rdst if Rdst == Rbase.
|
|
4408 |
void MacroAssembler::oop_decoder(Register Rdst, Register Rsrc, bool maybeNULL, Register Rbase, int pow2_offset) {
|
|
4409 |
|
|
4410 |
const address oop_base = Universe::narrow_oop_base();
|
|
4411 |
const int oop_shift = Universe::narrow_oop_shift();
|
|
4412 |
const bool disjoint = Universe::narrow_oop_base_disjoint();
|
|
4413 |
|
|
4414 |
assert(UseCompressedOops, "must be on to call this method");
|
|
4415 |
assert(Universe::heap() != NULL, "java heap must be initialized to call this decoder");
|
|
4416 |
assert((oop_shift == 0) || (oop_shift == LogMinObjAlignmentInBytes),
|
|
4417 |
"cOop encoder detected bad shift");
|
|
4418 |
|
|
4419 |
// cOops are always loaded zero-extended from memory. No explicit zero-extension necessary.
|
|
4420 |
|
|
4421 |
if (oop_base != NULL) {
|
|
4422 |
unsigned int oop_base_hl = ((unsigned int)((uint64_t)(intptr_t)oop_base >> 32)) & 0xffff;
|
|
4423 |
unsigned int oop_base_hh = ((unsigned int)((uint64_t)(intptr_t)oop_base >> 48)) & 0xffff;
|
|
4424 |
unsigned int oop_base_hf = ((unsigned int)((uint64_t)(intptr_t)oop_base >> 32)) & 0xFFFFffff;
|
|
4425 |
if (disjoint && (oop_base_hl == 0 || oop_base_hh == 0)) {
|
|
4426 |
BLOCK_COMMENT("cOop decoder disjointBase {");
|
|
4427 |
// We do not need to load the base. Instead, we can install the upper bits
|
|
4428 |
// with an OR instead of an ADD.
|
|
4429 |
Label done;
|
|
4430 |
|
|
4431 |
// Rsrc contains a narrow oop. Thus we are sure the leftmost <oop_shift> bits will never be set.
|
|
4432 |
if (maybeNULL) { // NULL ptr must be preserved!
|
|
4433 |
z_slag(Rdst, Rsrc, oop_shift); // Arithmetic shift sets the condition code.
|
|
4434 |
z_bre(done);
|
|
4435 |
} else {
|
|
4436 |
z_sllg(Rdst, Rsrc, oop_shift); // Logical shift leaves condition code alone.
|
|
4437 |
}
|
|
4438 |
if ((oop_base_hl != 0) && (oop_base_hh != 0)) {
|
|
4439 |
z_oihf(Rdst, oop_base_hf);
|
|
4440 |
} else if (oop_base_hl != 0) {
|
|
4441 |
z_oihl(Rdst, oop_base_hl);
|
|
4442 |
} else {
|
|
4443 |
assert(oop_base_hh != 0, "not heapbased mode");
|
|
4444 |
z_oihh(Rdst, oop_base_hh);
|
|
4445 |
}
|
|
4446 |
bind(done);
|
|
4447 |
BLOCK_COMMENT("} cOop decoder disjointBase");
|
|
4448 |
} else {
|
|
4449 |
BLOCK_COMMENT("cOop decoder general {");
|
|
4450 |
// There are three decode steps:
|
|
4451 |
// scale oop offset (shift left)
|
|
4452 |
// get base (in reg) and pow2_offset (constant)
|
|
4453 |
// add base, pow2_offset, and oop offset
|
|
4454 |
// The following register overlap situations may exist:
|
|
4455 |
// Rdst == Rsrc, Rbase any other
|
|
4456 |
// not a problem. Scaling in-place leaves Rbase undisturbed.
|
|
4457 |
// Loading Rbase does not impact the scaled offset.
|
|
4458 |
// Rdst == Rbase, Rsrc any other
|
|
4459 |
// scaling would destroy a possibly preloaded Rbase. Loading Rbase
|
|
4460 |
// would destroy the scaled offset.
|
|
4461 |
// Remedy: use Rdst_tmp if Rbase has been preloaded.
|
|
4462 |
// use Rbase_tmp if base has to be loaded.
|
|
4463 |
// Rsrc == Rbase, Rdst any other
|
|
4464 |
// Only possible without preloaded Rbase.
|
|
4465 |
// Loading Rbase does not destroy compressed oop because it was scaled into Rdst before.
|
|
4466 |
// Rsrc == Rbase, Rdst == Rbase
|
|
4467 |
// Only possible without preloaded Rbase.
|
|
4468 |
// Loading Rbase would destroy compressed oop. Scaling in-place is ok.
|
|
4469 |
// Remedy: use Rbase_tmp.
|
|
4470 |
//
|
|
4471 |
Label done;
|
|
4472 |
Register Rdst_tmp = Rdst;
|
|
4473 |
Register Rbase_tmp = Rbase;
|
|
4474 |
bool used_R0 = false;
|
|
4475 |
bool used_R1 = false;
|
|
4476 |
bool base_preloaded = pow2_offset >= 0;
|
|
4477 |
guarantee(!(base_preloaded && (Rsrc == Rbase)), "Register clash, check caller");
|
|
4478 |
assert(oop_shift != 0, "room for optimization");
|
|
4479 |
|
|
4480 |
// Check if we need to use scratch registers.
|
|
4481 |
if (Rdst == Rbase) {
|
|
4482 |
assert(!(((Rdst == Z_R0) && (Rsrc == Z_R1)) || ((Rdst == Z_R1) && (Rsrc == Z_R0))), "need a scratch reg");
|
|
4483 |
if (Rdst != Rsrc) {
|
|
4484 |
if (base_preloaded) { Rdst_tmp = (Rdst == Z_R1) ? Z_R0 : Z_R1; }
|
|
4485 |
else { Rbase_tmp = (Rdst == Z_R1) ? Z_R0 : Z_R1; }
|
|
4486 |
} else {
|
|
4487 |
Rbase_tmp = (Rdst == Z_R1) ? Z_R0 : Z_R1;
|
|
4488 |
}
|
|
4489 |
}
|
|
4490 |
if (base_preloaded) lgr_if_needed(Rbase_tmp, Rbase);
|
|
4491 |
|
|
4492 |
// Scale oop and check for NULL.
|
|
4493 |
// Rsrc contains a narrow oop. Thus we are sure the leftmost <oop_shift> bits will never be set.
|
|
4494 |
if (maybeNULL) { // NULL ptr must be preserved!
|
|
4495 |
z_slag(Rdst_tmp, Rsrc, oop_shift); // Arithmetic shift sets the condition code.
|
|
4496 |
z_bre(done);
|
|
4497 |
} else {
|
|
4498 |
z_sllg(Rdst_tmp, Rsrc, oop_shift); // Logical shift leaves condition code alone.
|
|
4499 |
}
|
|
4500 |
|
|
4501 |
// Get oop_base components.
|
|
4502 |
if (!base_preloaded) {
|
|
4503 |
pow2_offset = get_oop_base(Rbase_tmp, (uint64_t)(intptr_t)oop_base);
|
|
4504 |
}
|
|
4505 |
|
|
4506 |
// Add up all components.
|
|
4507 |
if ((Rbase_tmp == Z_R0) || (Rdst_tmp == Z_R0)) {
|
|
4508 |
z_algr(Rdst_tmp, Rbase_tmp);
|
|
4509 |
if (pow2_offset != 0) { add2reg(Rdst_tmp, pow2_offset); }
|
|
4510 |
} else {
|
|
4511 |
add2reg_with_index(Rdst_tmp, pow2_offset, Rbase_tmp, Rdst_tmp);
|
|
4512 |
}
|
|
4513 |
|
|
4514 |
bind(done);
|
|
4515 |
lgr_if_needed(Rdst, Rdst_tmp);
|
|
4516 |
#ifdef ASSERT
|
|
4517 |
if (used_R0 && Rdst != Z_R0 && Rsrc != Z_R0) { preset_reg(Z_R0, 0xb03bUL, 2); }
|
|
4518 |
if (used_R1 && Rdst != Z_R1 && Rsrc != Z_R1) { preset_reg(Z_R1, 0xb04bUL, 2); }
|
|
4519 |
#endif
|
|
4520 |
BLOCK_COMMENT("} cOop decoder general");
|
|
4521 |
}
|
|
4522 |
} else {
|
|
4523 |
BLOCK_COMMENT("cOop decoder zeroBase {");
|
|
4524 |
if (oop_shift == 0) {
|
|
4525 |
lgr_if_needed(Rdst, Rsrc);
|
|
4526 |
} else {
|
|
4527 |
z_sllg(Rdst, Rsrc, oop_shift);
|
|
4528 |
}
|
|
4529 |
BLOCK_COMMENT("} cOop decoder zeroBase");
|
|
4530 |
}
|
|
4531 |
}
|
|
4532 |
|
|
4533 |
void MacroAssembler::load_mirror(Register mirror, Register method) {
|
|
4534 |
mem2reg_opt(mirror, Address(method, Method::const_offset()));
|
|
4535 |
mem2reg_opt(mirror, Address(mirror, ConstMethod::constants_offset()));
|
|
4536 |
mem2reg_opt(mirror, Address(mirror, ConstantPool::pool_holder_offset_in_bytes()));
|
|
4537 |
mem2reg_opt(mirror, Address(mirror, Klass::java_mirror_offset()));
|
|
4538 |
}
|
|
4539 |
|
|
4540 |
//---------------------------------------------------------------
|
|
4541 |
//--- Operations on arrays.
|
|
4542 |
//---------------------------------------------------------------
|
|
4543 |
|
|
4544 |
// Compiler ensures base is doubleword aligned and cnt is #doublewords.
|
|
4545 |
// Emitter does not KILL cnt and base arguments, since they need to be copied to
|
|
4546 |
// work registers anyway.
|
|
4547 |
// Actually, only r0, r1, and r5 are killed.
|
|
4548 |
unsigned int MacroAssembler::Clear_Array(Register cnt_arg, Register base_pointer_arg, Register src_addr, Register src_len) {
|
|
4549 |
// Src_addr is evenReg.
|
|
4550 |
// Src_len is odd_Reg.
|
|
4551 |
|
|
4552 |
int block_start = offset();
|
|
4553 |
Register tmp_reg = src_len; // Holds target instr addr for EX.
|
|
4554 |
Register dst_len = Z_R1; // Holds dst len for MVCLE.
|
|
4555 |
Register dst_addr = Z_R0; // Holds dst addr for MVCLE.
|
|
4556 |
|
|
4557 |
Label doXC, doMVCLE, done;
|
|
4558 |
|
|
4559 |
BLOCK_COMMENT("Clear_Array {");
|
|
4560 |
|
|
4561 |
// Check for zero len and convert to long.
|
|
4562 |
z_ltgfr(src_len, cnt_arg); // Remember casted value for doSTG case.
|
|
4563 |
z_bre(done); // Nothing to do if len == 0.
|
|
4564 |
|
|
4565 |
// Prefetch data to be cleared.
|
|
4566 |
if (VM_Version::has_Prefetch()) {
|
|
4567 |
z_pfd(0x02, 0, Z_R0, base_pointer_arg);
|
|
4568 |
z_pfd(0x02, 256, Z_R0, base_pointer_arg);
|
|
4569 |
}
|
|
4570 |
|
|
4571 |
z_sllg(dst_len, src_len, 3); // #bytes to clear.
|
|
4572 |
z_cghi(src_len, 32); // Check for len <= 256 bytes (<=32 DW).
|
|
4573 |
z_brnh(doXC); // If so, use executed XC to clear.
|
|
4574 |
|
|
4575 |
// MVCLE: initialize long arrays (general case).
|
|
4576 |
bind(doMVCLE);
|
|
4577 |
z_lgr(dst_addr, base_pointer_arg);
|
|
4578 |
clear_reg(src_len, true, false); // Src len of MVCLE is zero.
|
|
4579 |
|
|
4580 |
MacroAssembler::move_long_ext(dst_addr, src_addr, 0);
|
|
4581 |
z_bru(done);
|
|
4582 |
|
|
4583 |
// XC: initialize short arrays.
|
|
4584 |
Label XC_template; // Instr template, never exec directly!
|
|
4585 |
bind(XC_template);
|
|
4586 |
z_xc(0,0,base_pointer_arg,0,base_pointer_arg);
|
|
4587 |
|
|
4588 |
bind(doXC);
|
|
4589 |
add2reg(dst_len, -1); // Get #bytes-1 for EXECUTE.
|
|
4590 |
if (VM_Version::has_ExecuteExtensions()) {
|
|
4591 |
z_exrl(dst_len, XC_template); // Execute XC with var. len.
|
|
4592 |
} else {
|
|
4593 |
z_larl(tmp_reg, XC_template);
|
|
4594 |
z_ex(dst_len,0,Z_R0,tmp_reg); // Execute XC with var. len.
|
|
4595 |
}
|
|
4596 |
// z_bru(done); // fallthru
|
|
4597 |
|
|
4598 |
bind(done);
|
|
4599 |
|
|
4600 |
BLOCK_COMMENT("} Clear_Array");
|
|
4601 |
|
|
4602 |
int block_end = offset();
|
|
4603 |
return block_end - block_start;
|
|
4604 |
}
|
|
4605 |
|
|
4606 |
// Compiler ensures base is doubleword aligned and cnt is count of doublewords.
|
|
4607 |
// Emitter does not KILL any arguments nor work registers.
|
|
4608 |
// Emitter generates up to 16 XC instructions, depending on the array length.
|
|
4609 |
unsigned int MacroAssembler::Clear_Array_Const(long cnt, Register base) {
|
|
4610 |
int block_start = offset();
|
|
4611 |
int off;
|
|
4612 |
int lineSize_Bytes = AllocatePrefetchStepSize;
|
|
4613 |
int lineSize_DW = AllocatePrefetchStepSize>>LogBytesPerWord;
|
|
4614 |
bool doPrefetch = VM_Version::has_Prefetch();
|
|
4615 |
int XC_maxlen = 256;
|
|
4616 |
int numXCInstr = cnt > 0 ? (cnt*BytesPerWord-1)/XC_maxlen+1 : 0;
|
|
4617 |
|
|
4618 |
BLOCK_COMMENT("Clear_Array_Const {");
|
|
4619 |
assert(cnt*BytesPerWord <= 4096, "ClearArrayConst can handle 4k only");
|
|
4620 |
|
|
4621 |
// Do less prefetching for very short arrays.
|
|
4622 |
if (numXCInstr > 0) {
|
|
4623 |
// Prefetch only some cache lines, then begin clearing.
|
|
4624 |
if (doPrefetch) {
|
|
4625 |
if (cnt*BytesPerWord <= lineSize_Bytes/4) { // If less than 1/4 of a cache line to clear,
|
|
4626 |
z_pfd(0x02, 0, Z_R0, base); // prefetch just the first cache line.
|
|
4627 |
} else {
|
|
4628 |
assert(XC_maxlen == lineSize_Bytes, "ClearArrayConst needs 256B cache lines");
|
|
4629 |
for (off = 0; (off < AllocatePrefetchLines) && (off <= numXCInstr); off ++) {
|
|
4630 |
z_pfd(0x02, off*lineSize_Bytes, Z_R0, base);
|
|
4631 |
}
|
|
4632 |
}
|
|
4633 |
}
|
|
4634 |
|
|
4635 |
for (off=0; off<(numXCInstr-1); off++) {
|
|
4636 |
z_xc(off*XC_maxlen, XC_maxlen-1, base, off*XC_maxlen, base);
|
|
4637 |
|
|
4638 |
// Prefetch some cache lines in advance.
|
|
4639 |
if (doPrefetch && (off <= numXCInstr-AllocatePrefetchLines)) {
|
|
4640 |
z_pfd(0x02, (off+AllocatePrefetchLines)*lineSize_Bytes, Z_R0, base);
|
|
4641 |
}
|
|
4642 |
}
|
|
4643 |
if (off*XC_maxlen < cnt*BytesPerWord) {
|
|
4644 |
z_xc(off*XC_maxlen, (cnt*BytesPerWord-off*XC_maxlen)-1, base, off*XC_maxlen, base);
|
|
4645 |
}
|
|
4646 |
}
|
|
4647 |
BLOCK_COMMENT("} Clear_Array_Const");
|
|
4648 |
|
|
4649 |
int block_end = offset();
|
|
4650 |
return block_end - block_start;
|
|
4651 |
}
|
|
4652 |
|
|
4653 |
// Compiler ensures base is doubleword aligned and cnt is #doublewords.
|
|
4654 |
// Emitter does not KILL cnt and base arguments, since they need to be copied to
|
|
4655 |
// work registers anyway.
|
|
4656 |
// Actually, only r0, r1, r4, and r5 (which are work registers) are killed.
|
|
4657 |
//
|
|
4658 |
// For very large arrays, exploit MVCLE H/W support.
|
|
4659 |
// MVCLE instruction automatically exploits H/W-optimized page mover.
|
|
4660 |
// - Bytes up to next page boundary are cleared with a series of XC to self.
|
|
4661 |
// - All full pages are cleared with the page mover H/W assist.
|
|
4662 |
// - Remaining bytes are again cleared by a series of XC to self.
|
|
4663 |
//
|
|
4664 |
unsigned int MacroAssembler::Clear_Array_Const_Big(long cnt, Register base_pointer_arg, Register src_addr, Register src_len) {
|
|
4665 |
// Src_addr is evenReg.
|
|
4666 |
// Src_len is odd_Reg.
|
|
4667 |
|
|
4668 |
int block_start = offset();
|
|
4669 |
Register dst_len = Z_R1; // Holds dst len for MVCLE.
|
|
4670 |
Register dst_addr = Z_R0; // Holds dst addr for MVCLE.
|
|
4671 |
|
|
4672 |
BLOCK_COMMENT("Clear_Array_Const_Big {");
|
|
4673 |
|
|
4674 |
// Get len to clear.
|
|
4675 |
load_const_optimized(dst_len, (long)cnt*8L); // in Bytes = #DW*8
|
|
4676 |
|
|
4677 |
// Prepare other args to MVCLE.
|
|
4678 |
z_lgr(dst_addr, base_pointer_arg);
|
|
4679 |
// Indicate unused result.
|
|
4680 |
(void) clear_reg(src_len, true, false); // Src len of MVCLE is zero.
|
|
4681 |
|
|
4682 |
// Clear.
|
|
4683 |
MacroAssembler::move_long_ext(dst_addr, src_addr, 0);
|
|
4684 |
BLOCK_COMMENT("} Clear_Array_Const_Big");
|
|
4685 |
|
|
4686 |
int block_end = offset();
|
|
4687 |
return block_end - block_start;
|
|
4688 |
}
|
|
4689 |
|
|
4690 |
// Allocator.
|
|
4691 |
unsigned int MacroAssembler::CopyRawMemory_AlignedDisjoint(Register src_reg, Register dst_reg,
|
|
4692 |
Register cnt_reg,
|
|
4693 |
Register tmp1_reg, Register tmp2_reg) {
|
|
4694 |
// Tmp1 is oddReg.
|
|
4695 |
// Tmp2 is evenReg.
|
|
4696 |
|
|
4697 |
int block_start = offset();
|
|
4698 |
Label doMVC, doMVCLE, done, MVC_template;
|
|
4699 |
|
|
4700 |
BLOCK_COMMENT("CopyRawMemory_AlignedDisjoint {");
|
|
4701 |
|
|
4702 |
// Check for zero len and convert to long.
|
|
4703 |
z_ltgfr(cnt_reg, cnt_reg); // Remember casted value for doSTG case.
|
|
4704 |
z_bre(done); // Nothing to do if len == 0.
|
|
4705 |
|
|
4706 |
z_sllg(Z_R1, cnt_reg, 3); // Dst len in bytes. calc early to have the result ready.
|
|
4707 |
|
|
4708 |
z_cghi(cnt_reg, 32); // Check for len <= 256 bytes (<=32 DW).
|
|
4709 |
z_brnh(doMVC); // If so, use executed MVC to clear.
|
|
4710 |
|
|
4711 |
bind(doMVCLE); // A lot of data (more than 256 bytes).
|
|
4712 |
// Prep dest reg pair.
|
|
4713 |
z_lgr(Z_R0, dst_reg); // dst addr
|
|
4714 |
// Dst len already in Z_R1.
|
|
4715 |
// Prep src reg pair.
|
|
4716 |
z_lgr(tmp2_reg, src_reg); // src addr
|
|
4717 |
z_lgr(tmp1_reg, Z_R1); // Src len same as dst len.
|
|
4718 |
|
|
4719 |
// Do the copy.
|
|
4720 |
move_long_ext(Z_R0, tmp2_reg, 0xb0); // Bypass cache.
|
|
4721 |
z_bru(done); // All done.
|
|
4722 |
|
|
4723 |
bind(MVC_template); // Just some data (not more than 256 bytes).
|
|
4724 |
z_mvc(0, 0, dst_reg, 0, src_reg);
|
|
4725 |
|
|
4726 |
bind(doMVC);
|
|
4727 |
|
|
4728 |
if (VM_Version::has_ExecuteExtensions()) {
|
|
4729 |
add2reg(Z_R1, -1);
|
|
4730 |
} else {
|
|
4731 |
add2reg(tmp1_reg, -1, Z_R1);
|
|
4732 |
z_larl(Z_R1, MVC_template);
|
|
4733 |
}
|
|
4734 |
|
|
4735 |
if (VM_Version::has_Prefetch()) {
|
|
4736 |
z_pfd(1, 0,Z_R0,src_reg);
|
|
4737 |
z_pfd(2, 0,Z_R0,dst_reg);
|
|
4738 |
// z_pfd(1,256,Z_R0,src_reg); // Assume very short copy.
|
|
4739 |
// z_pfd(2,256,Z_R0,dst_reg);
|
|
4740 |
}
|
|
4741 |
|
|
4742 |
if (VM_Version::has_ExecuteExtensions()) {
|
|
4743 |
z_exrl(Z_R1, MVC_template);
|
|
4744 |
} else {
|
|
4745 |
z_ex(tmp1_reg, 0, Z_R0, Z_R1);
|
|
4746 |
}
|
|
4747 |
|
|
4748 |
bind(done);
|
|
4749 |
|
|
4750 |
BLOCK_COMMENT("} CopyRawMemory_AlignedDisjoint");
|
|
4751 |
|
|
4752 |
int block_end = offset();
|
|
4753 |
return block_end - block_start;
|
|
4754 |
}
|
|
4755 |
|
|
4756 |
//------------------------------------------------------
|
|
4757 |
// Special String Intrinsics. Implementation
|
|
4758 |
//------------------------------------------------------
|
|
4759 |
|
|
4760 |
// Intrinsics for CompactStrings
|
|
4761 |
|
|
4762 |
// Compress char[] to byte[]. odd_reg contains cnt. Kills dst. Early clobber: result
|
|
4763 |
// The result is the number of characters copied before the first incompatible character was found.
|
|
4764 |
// If tmp2 is provided and the compression fails, the compression stops exactly at this point and the result is precise.
|
|
4765 |
//
|
|
4766 |
// Note: Does not behave exactly like package private StringUTF16 compress java implementation in case of failure:
|
|
4767 |
// - Different number of characters may have been written to dead array (if tmp2 not provided).
|
|
4768 |
// - Returns a number <cnt instead of 0. (Result gets compared with cnt.)
|
|
4769 |
unsigned int MacroAssembler::string_compress(Register result, Register src, Register dst, Register odd_reg,
|
|
4770 |
Register even_reg, Register tmp, Register tmp2) {
|
|
4771 |
int block_start = offset();
|
|
4772 |
Label Lloop1, Lloop2, Lslow, Ldone;
|
|
4773 |
const Register addr2 = dst, ind1 = result, mask = tmp;
|
|
4774 |
const bool precise = (tmp2 != noreg);
|
|
4775 |
|
|
4776 |
BLOCK_COMMENT("string_compress {");
|
|
4777 |
|
|
4778 |
z_sll(odd_reg, 1); // Number of bytes to read. (Must be a positive simm32.)
|
|
4779 |
clear_reg(ind1); // Index to read.
|
|
4780 |
z_llilf(mask, 0xFF00FF00);
|
|
4781 |
z_ahi(odd_reg, -16); // Last possible index for fast loop.
|
|
4782 |
z_brl(Lslow);
|
|
4783 |
|
|
4784 |
// ind1: index, even_reg: index increment, odd_reg: index limit
|
|
4785 |
z_iihf(mask, 0xFF00FF00);
|
|
4786 |
z_lhi(even_reg, 16);
|
|
4787 |
|
|
4788 |
bind(Lloop1); // 8 Characters per iteration.
|
|
4789 |
z_lg(Z_R0, Address(src, ind1));
|
|
4790 |
z_lg(Z_R1, Address(src, ind1, 8));
|
|
4791 |
if (precise) {
|
|
4792 |
if (VM_Version::has_DistinctOpnds()) {
|
|
4793 |
z_ogrk(tmp2, Z_R0, Z_R1);
|
|
4794 |
} else {
|
|
4795 |
z_lgr(tmp2, Z_R0);
|
|
4796 |
z_ogr(tmp2, Z_R1);
|
|
4797 |
}
|
|
4798 |
z_ngr(tmp2, mask);
|
|
4799 |
z_brne(Lslow); // Failed fast case, retry slowly.
|
|
4800 |
}
|
|
4801 |
z_stcmh(Z_R0, 5, 0, addr2);
|
|
4802 |
z_stcm(Z_R0, 5, 2, addr2);
|
|
4803 |
if (!precise) { z_ogr(Z_R0, Z_R1); }
|
|
4804 |
z_stcmh(Z_R1, 5, 4, addr2);
|
|
4805 |
z_stcm(Z_R1, 5, 6, addr2);
|
|
4806 |
if (!precise) {
|
|
4807 |
z_ngr(Z_R0, mask);
|
|
4808 |
z_brne(Ldone); // Failed (more than needed was written).
|
|
4809 |
}
|
|
4810 |
z_aghi(addr2, 8);
|
|
4811 |
z_brxle(ind1, even_reg, Lloop1);
|
|
4812 |
|
|
4813 |
bind(Lslow);
|
|
4814 |
// Compute index limit and skip if negative.
|
|
4815 |
z_ahi(odd_reg, 16-2); // Last possible index for slow loop.
|
|
4816 |
z_lhi(even_reg, 2);
|
|
4817 |
z_cr(ind1, odd_reg);
|
|
4818 |
z_brh(Ldone);
|
|
4819 |
|
|
4820 |
bind(Lloop2); // 1 Character per iteration.
|
|
4821 |
z_llh(Z_R0, Address(src, ind1));
|
|
4822 |
z_tmll(Z_R0, 0xFF00);
|
|
4823 |
z_brnaz(Ldone); // Failed slow case: Return number of written characters.
|
|
4824 |
z_stc(Z_R0, Address(addr2));
|
|
4825 |
z_aghi(addr2, 1);
|
|
4826 |
z_brxle(ind1, even_reg, Lloop2);
|
|
4827 |
|
|
4828 |
bind(Ldone); // result = ind1 = 2*cnt
|
|
4829 |
z_srl(ind1, 1);
|
|
4830 |
|
|
4831 |
BLOCK_COMMENT("} string_compress");
|
|
4832 |
|
|
4833 |
return offset() - block_start;
|
|
4834 |
}
|
|
4835 |
|
|
4836 |
// Inflate byte[] to char[].
|
|
4837 |
unsigned int MacroAssembler::string_inflate_trot(Register src, Register dst, Register cnt, Register tmp) {
|
|
4838 |
int block_start = offset();
|
|
4839 |
|
|
4840 |
BLOCK_COMMENT("string_inflate {");
|
|
4841 |
|
|
4842 |
Register stop_char = Z_R0;
|
|
4843 |
Register table = Z_R1;
|
|
4844 |
Register src_addr = tmp;
|
|
4845 |
|
|
4846 |
assert_different_registers(Z_R0, Z_R1, tmp, src, dst, cnt);
|
|
4847 |
assert(dst->encoding()%2 == 0, "must be even reg");
|
|
4848 |
assert(cnt->encoding()%2 == 1, "must be odd reg");
|
|
4849 |
assert(cnt->encoding() - dst->encoding() == 1, "must be even/odd pair");
|
|
4850 |
|
|
4851 |
StubRoutines::zarch::generate_load_trot_table_addr(this, table); // kills Z_R0 (if ASSERT)
|
|
4852 |
clear_reg(stop_char); // Stop character. Not used here, but initialized to have a defined value.
|
|
4853 |
lgr_if_needed(src_addr, src);
|
|
4854 |
z_llgfr(cnt, cnt); // # src characters, must be a positive simm32.
|
|
4855 |
|
|
4856 |
translate_ot(dst, src_addr, /* mask = */ 0x0001);
|
|
4857 |
|
|
4858 |
BLOCK_COMMENT("} string_inflate");
|
|
4859 |
|
|
4860 |
return offset() - block_start;
|
|
4861 |
}
|
|
4862 |
|
|
4863 |
// Inflate byte[] to char[]. odd_reg contains cnt. Kills src.
|
|
4864 |
unsigned int MacroAssembler::string_inflate(Register src, Register dst, Register odd_reg,
|
|
4865 |
Register even_reg, Register tmp) {
|
|
4866 |
int block_start = offset();
|
|
4867 |
|
|
4868 |
BLOCK_COMMENT("string_inflate {");
|
|
4869 |
|
|
4870 |
Label Lloop1, Lloop2, Lslow, Ldone;
|
|
4871 |
const Register addr1 = src, ind2 = tmp;
|
|
4872 |
|
|
4873 |
z_sll(odd_reg, 1); // Number of bytes to write. (Must be a positive simm32.)
|
|
4874 |
clear_reg(ind2); // Index to write.
|
|
4875 |
z_ahi(odd_reg, -16); // Last possible index for fast loop.
|
|
4876 |
z_brl(Lslow);
|
|
4877 |
|
|
4878 |
// ind2: index, even_reg: index increment, odd_reg: index limit
|
|
4879 |
clear_reg(Z_R0);
|
|
4880 |
clear_reg(Z_R1);
|
|
4881 |
z_lhi(even_reg, 16);
|
|
4882 |
|
|
4883 |
bind(Lloop1); // 8 Characters per iteration.
|
|
4884 |
z_icmh(Z_R0, 5, 0, addr1);
|
|
4885 |
z_icmh(Z_R1, 5, 4, addr1);
|
|
4886 |
z_icm(Z_R0, 5, 2, addr1);
|
|
4887 |
z_icm(Z_R1, 5, 6, addr1);
|
|
4888 |
z_aghi(addr1, 8);
|
|
4889 |
z_stg(Z_R0, Address(dst, ind2));
|
|
4890 |
z_stg(Z_R1, Address(dst, ind2, 8));
|
|
4891 |
z_brxle(ind2, even_reg, Lloop1);
|
|
4892 |
|
|
4893 |
bind(Lslow);
|
|
4894 |
// Compute index limit and skip if negative.
|
|
4895 |
z_ahi(odd_reg, 16-2); // Last possible index for slow loop.
|
|
4896 |
z_lhi(even_reg, 2);
|
|
4897 |
z_cr(ind2, odd_reg);
|
|
4898 |
z_brh(Ldone);
|
|
4899 |
|
|
4900 |
bind(Lloop2); // 1 Character per iteration.
|
|
4901 |
z_llc(Z_R0, Address(addr1));
|
|
4902 |
z_sth(Z_R0, Address(dst, ind2));
|
|
4903 |
z_aghi(addr1, 1);
|
|
4904 |
z_brxle(ind2, even_reg, Lloop2);
|
|
4905 |
|
|
4906 |
bind(Ldone);
|
|
4907 |
|
|
4908 |
BLOCK_COMMENT("} string_inflate");
|
|
4909 |
|
|
4910 |
return offset() - block_start;
|
|
4911 |
}
|
|
4912 |
|
|
4913 |
// Kills src.
|
|
4914 |
unsigned int MacroAssembler::has_negatives(Register result, Register src, Register cnt,
|
|
4915 |
Register odd_reg, Register even_reg, Register tmp) {
|
|
4916 |
int block_start = offset();
|
|
4917 |
Label Lloop1, Lloop2, Lslow, Lnotfound, Ldone;
|
|
4918 |
const Register addr = src, mask = tmp;
|
|
4919 |
|
|
4920 |
BLOCK_COMMENT("has_negatives {");
|
|
4921 |
|
|
4922 |
z_llgfr(Z_R1, cnt); // Number of bytes to read. (Must be a positive simm32.)
|
|
4923 |
z_llilf(mask, 0x80808080);
|
|
4924 |
z_lhi(result, 1); // Assume true.
|
|
4925 |
// Last possible addr for fast loop.
|
|
4926 |
z_lay(odd_reg, -16, Z_R1, src);
|
|
4927 |
z_chi(cnt, 16);
|
|
4928 |
z_brl(Lslow);
|
|
4929 |
|
|
4930 |
// ind1: index, even_reg: index increment, odd_reg: index limit
|
|
4931 |
z_iihf(mask, 0x80808080);
|
|
4932 |
z_lghi(even_reg, 16);
|
|
4933 |
|
|
4934 |
bind(Lloop1); // 16 bytes per iteration.
|
|
4935 |
z_lg(Z_R0, Address(addr));
|
|
4936 |
z_lg(Z_R1, Address(addr, 8));
|
|
4937 |
z_ogr(Z_R0, Z_R1);
|
|
4938 |
z_ngr(Z_R0, mask);
|
|
4939 |
z_brne(Ldone); // If found return 1.
|
|
4940 |
z_brxlg(addr, even_reg, Lloop1);
|
|
4941 |
|
|
4942 |
bind(Lslow);
|
|
4943 |
z_aghi(odd_reg, 16-1); // Last possible addr for slow loop.
|
|
4944 |
z_lghi(even_reg, 1);
|
|
4945 |
z_cgr(addr, odd_reg);
|
|
4946 |
z_brh(Lnotfound);
|
|
4947 |
|
|
4948 |
bind(Lloop2); // 1 byte per iteration.
|
|
4949 |
z_cli(Address(addr), 0x80);
|
|
4950 |
z_brnl(Ldone); // If found return 1.
|
|
4951 |
z_brxlg(addr, even_reg, Lloop2);
|
|
4952 |
|
|
4953 |
bind(Lnotfound);
|
|
4954 |
z_lhi(result, 0);
|
|
4955 |
|
|
4956 |
bind(Ldone);
|
|
4957 |
|
|
4958 |
BLOCK_COMMENT("} has_negatives");
|
|
4959 |
|
|
4960 |
return offset() - block_start;
|
|
4961 |
}
|
|
4962 |
|
|
4963 |
// kill: cnt1, cnt2, odd_reg, even_reg; early clobber: result
|
|
4964 |
unsigned int MacroAssembler::string_compare(Register str1, Register str2,
|
|
4965 |
Register cnt1, Register cnt2,
|
|
4966 |
Register odd_reg, Register even_reg, Register result, int ae) {
|
|
4967 |
int block_start = offset();
|
|
4968 |
|
|
4969 |
assert_different_registers(str1, cnt1, cnt2, odd_reg, even_reg, result);
|
|
4970 |
assert_different_registers(str2, cnt1, cnt2, odd_reg, even_reg, result);
|
|
4971 |
|
|
4972 |
// If strings are equal up to min length, return the length difference.
|
|
4973 |
const Register diff = result, // Pre-set result with length difference.
|
|
4974 |
min = cnt1, // min number of bytes
|
|
4975 |
tmp = cnt2;
|
|
4976 |
|
|
4977 |
// Note: Making use of the fact that compareTo(a, b) == -compareTo(b, a)
|
|
4978 |
// we interchange str1 and str2 in the UL case and negate the result.
|
|
4979 |
// Like this, str1 is always latin1 encoded, except for the UU case.
|
|
4980 |
// In addition, we need 0 (or sign which is 0) extend when using 64 bit register.
|
|
4981 |
const bool used_as_LU = (ae == StrIntrinsicNode::LU || ae == StrIntrinsicNode::UL);
|
|
4982 |
|
|
4983 |
BLOCK_COMMENT("string_compare {");
|
|
4984 |
|
|
4985 |
if (used_as_LU) {
|
|
4986 |
z_srl(cnt2, 1);
|
|
4987 |
}
|
|
4988 |
|
|
4989 |
// See if the lengths are different, and calculate min in cnt1.
|
|
4990 |
// Save diff in case we need it for a tie-breaker.
|
|
4991 |
|
|
4992 |
// diff = cnt1 - cnt2
|
|
4993 |
if (VM_Version::has_DistinctOpnds()) {
|
|
4994 |
z_srk(diff, cnt1, cnt2);
|
|
4995 |
} else {
|
|
4996 |
z_lr(diff, cnt1);
|
|
4997 |
z_sr(diff, cnt2);
|
|
4998 |
}
|
|
4999 |
if (str1 != str2) {
|
|
5000 |
if (VM_Version::has_LoadStoreConditional()) {
|
|
5001 |
z_locr(min, cnt2, Assembler::bcondHigh);
|
|
5002 |
} else {
|
|
5003 |
Label Lskip;
|
|
5004 |
z_brl(Lskip); // min ok if cnt1 < cnt2
|
|
5005 |
z_lr(min, cnt2); // min = cnt2
|
|
5006 |
bind(Lskip);
|
|
5007 |
}
|
|
5008 |
}
|
|
5009 |
|
|
5010 |
if (ae == StrIntrinsicNode::UU) {
|
|
5011 |
z_sra(diff, 1);
|
|
5012 |
}
|
|
5013 |
if (str1 != str2) {
|
|
5014 |
Label Ldone;
|
|
5015 |
if (used_as_LU) {
|
|
5016 |
// Loop which searches the first difference character by character.
|
|
5017 |
Label Lloop;
|
|
5018 |
const Register ind1 = Z_R1,
|
|
5019 |
ind2 = min;
|
|
5020 |
int stride1 = 1, stride2 = 2; // See comment above.
|
|
5021 |
|
|
5022 |
// ind1: index, even_reg: index increment, odd_reg: index limit
|
|
5023 |
z_llilf(ind1, (unsigned int)(-stride1));
|
|
5024 |
z_lhi(even_reg, stride1);
|
|
5025 |
add2reg(odd_reg, -stride1, min);
|
|
5026 |
clear_reg(ind2); // kills min
|
|
5027 |
|
|
5028 |
bind(Lloop);
|
|
5029 |
z_brxh(ind1, even_reg, Ldone);
|
|
5030 |
z_llc(tmp, Address(str1, ind1));
|
|
5031 |
z_llh(Z_R0, Address(str2, ind2));
|
|
5032 |
z_ahi(ind2, stride2);
|
|
5033 |
z_sr(tmp, Z_R0);
|
|
5034 |
z_bre(Lloop);
|
|
5035 |
|
|
5036 |
z_lr(result, tmp);
|
|
5037 |
|
|
5038 |
} else {
|
|
5039 |
// Use clcle in fast loop (only for same encoding).
|
|
5040 |
z_lgr(Z_R0, str1);
|
|
5041 |
z_lgr(even_reg, str2);
|
|
5042 |
z_llgfr(Z_R1, min);
|
|
5043 |
z_llgfr(odd_reg, min);
|
|
5044 |
|
|
5045 |
if (ae == StrIntrinsicNode::LL) {
|
|
5046 |
compare_long_ext(Z_R0, even_reg, 0);
|
|
5047 |
} else {
|
|
5048 |
compare_long_uni(Z_R0, even_reg, 0);
|
|
5049 |
}
|
|
5050 |
z_bre(Ldone);
|
|
5051 |
z_lgr(Z_R1, Z_R0);
|
|
5052 |
if (ae == StrIntrinsicNode::LL) {
|
|
5053 |
z_llc(Z_R0, Address(even_reg));
|
|
5054 |
z_llc(result, Address(Z_R1));
|
|
5055 |
} else {
|
|
5056 |
z_llh(Z_R0, Address(even_reg));
|
|
5057 |
z_llh(result, Address(Z_R1));
|
|
5058 |
}
|
|
5059 |
z_sr(result, Z_R0);
|
|
5060 |
}
|
|
5061 |
|
|
5062 |
// Otherwise, return the difference between the first mismatched chars.
|
|
5063 |
bind(Ldone);
|
|
5064 |
}
|
|
5065 |
|
|
5066 |
if (ae == StrIntrinsicNode::UL) {
|
|
5067 |
z_lcr(result, result); // Negate result (see note above).
|
|
5068 |
}
|
|
5069 |
|
|
5070 |
BLOCK_COMMENT("} string_compare");
|
|
5071 |
|
|
5072 |
return offset() - block_start;
|
|
5073 |
}
|
|
5074 |
|
|
5075 |
unsigned int MacroAssembler::array_equals(bool is_array_equ, Register ary1, Register ary2, Register limit,
|
|
5076 |
Register odd_reg, Register even_reg, Register result, bool is_byte) {
|
|
5077 |
int block_start = offset();
|
|
5078 |
|
|
5079 |
BLOCK_COMMENT("array_equals {");
|
|
5080 |
|
|
5081 |
assert_different_registers(ary1, limit, odd_reg, even_reg);
|
|
5082 |
assert_different_registers(ary2, limit, odd_reg, even_reg);
|
|
5083 |
|
|
5084 |
Label Ldone, Ldone_true, Ldone_false, Lclcle, CLC_template;
|
|
5085 |
int base_offset = 0;
|
|
5086 |
|
|
5087 |
if (ary1 != ary2) {
|
|
5088 |
if (is_array_equ) {
|
|
5089 |
base_offset = arrayOopDesc::base_offset_in_bytes(is_byte ? T_BYTE : T_CHAR);
|
|
5090 |
|
|
5091 |
// Return true if the same array.
|
|
5092 |
compareU64_and_branch(ary1, ary2, Assembler::bcondEqual, Ldone_true);
|
|
5093 |
|
|
5094 |
// Return false if one of them is NULL.
|
|
5095 |
compareU64_and_branch(ary1, (intptr_t)0, Assembler::bcondEqual, Ldone_false);
|
|
5096 |
compareU64_and_branch(ary2, (intptr_t)0, Assembler::bcondEqual, Ldone_false);
|
|
5097 |
|
|
5098 |
// Load the lengths of arrays.
|
|
5099 |
z_llgf(odd_reg, Address(ary1, arrayOopDesc::length_offset_in_bytes()));
|
|
5100 |
|
|
5101 |
// Return false if the two arrays are not equal length.
|
|
5102 |
z_c(odd_reg, Address(ary2, arrayOopDesc::length_offset_in_bytes()));
|
|
5103 |
z_brne(Ldone_false);
|
|
5104 |
|
|
5105 |
// string len in bytes (right operand)
|
|
5106 |
if (!is_byte) {
|
|
5107 |
z_chi(odd_reg, 128);
|
|
5108 |
z_sll(odd_reg, 1); // preserves flags
|
|
5109 |
z_brh(Lclcle);
|
|
5110 |
} else {
|
|
5111 |
compareU32_and_branch(odd_reg, (intptr_t)256, Assembler::bcondHigh, Lclcle);
|
|
5112 |
}
|
|
5113 |
} else {
|
|
5114 |
z_llgfr(odd_reg, limit); // Need to zero-extend prior to using the value.
|
|
5115 |
compareU32_and_branch(limit, (intptr_t)256, Assembler::bcondHigh, Lclcle);
|
|
5116 |
}
|
|
5117 |
|
|
5118 |
|
|
5119 |
// Use clc instruction for up to 256 bytes.
|
|
5120 |
{
|
|
5121 |
Register str1_reg = ary1,
|
|
5122 |
str2_reg = ary2;
|
|
5123 |
if (is_array_equ) {
|
|
5124 |
str1_reg = Z_R1;
|
|
5125 |
str2_reg = even_reg;
|
|
5126 |
add2reg(str1_reg, base_offset, ary1); // string addr (left operand)
|
|
5127 |
add2reg(str2_reg, base_offset, ary2); // string addr (right operand)
|
|
5128 |
}
|
|
5129 |
z_ahi(odd_reg, -1); // Clc uses decremented limit. Also compare result to 0.
|
|
5130 |
z_brl(Ldone_true);
|
|
5131 |
// Note: We could jump to the template if equal.
|
|
5132 |
|
|
5133 |
assert(VM_Version::has_ExecuteExtensions(), "unsupported hardware");
|
|
5134 |
z_exrl(odd_reg, CLC_template);
|
|
5135 |
z_bre(Ldone_true);
|
|
5136 |
// fall through
|
|
5137 |
|
|
5138 |
bind(Ldone_false);
|
|
5139 |
clear_reg(result);
|
|
5140 |
z_bru(Ldone);
|
|
5141 |
|
|
5142 |
bind(CLC_template);
|
|
5143 |
z_clc(0, 0, str1_reg, 0, str2_reg);
|
|
5144 |
}
|
|
5145 |
|
|
5146 |
// Use clcle instruction.
|
|
5147 |
{
|
|
5148 |
bind(Lclcle);
|
|
5149 |
add2reg(even_reg, base_offset, ary2); // string addr (right operand)
|
|
5150 |
add2reg(Z_R0, base_offset, ary1); // string addr (left operand)
|
|
5151 |
|
|
5152 |
z_lgr(Z_R1, odd_reg); // string len in bytes (left operand)
|
|
5153 |
if (is_byte) {
|
|
5154 |
compare_long_ext(Z_R0, even_reg, 0);
|
|
5155 |
} else {
|
|
5156 |
compare_long_uni(Z_R0, even_reg, 0);
|
|
5157 |
}
|
|
5158 |
z_lghi(result, 0); // Preserve flags.
|
|
5159 |
z_brne(Ldone);
|
|
5160 |
}
|
|
5161 |
}
|
|
5162 |
// fall through
|
|
5163 |
|
|
5164 |
bind(Ldone_true);
|
|
5165 |
z_lghi(result, 1); // All characters are equal.
|
|
5166 |
bind(Ldone);
|
|
5167 |
|
|
5168 |
BLOCK_COMMENT("} array_equals");
|
|
5169 |
|
|
5170 |
return offset() - block_start;
|
|
5171 |
}
|
|
5172 |
|
|
5173 |
// kill: haycnt, needlecnt, odd_reg, even_reg; early clobber: result
|
|
5174 |
unsigned int MacroAssembler::string_indexof(Register result, Register haystack, Register haycnt,
|
|
5175 |
Register needle, Register needlecnt, int needlecntval,
|
|
5176 |
Register odd_reg, Register even_reg, int ae) {
|
|
5177 |
int block_start = offset();
|
|
5178 |
|
|
5179 |
// Ensure 0<needlecnt<=haycnt in ideal graph as prerequisite!
|
|
5180 |
assert(ae != StrIntrinsicNode::LU, "Invalid encoding");
|
|
5181 |
const int h_csize = (ae == StrIntrinsicNode::LL) ? 1 : 2;
|
|
5182 |
const int n_csize = (ae == StrIntrinsicNode::UU) ? 2 : 1;
|
|
5183 |
Label L_needle1, L_Found, L_NotFound;
|
|
5184 |
|
|
5185 |
BLOCK_COMMENT("string_indexof {");
|
|
5186 |
|
|
5187 |
if (needle == haystack) {
|
|
5188 |
z_lhi(result, 0);
|
|
5189 |
} else {
|
|
5190 |
|
|
5191 |
// Load first character of needle (R0 used by search_string instructions).
|
|
5192 |
if (n_csize == 2) { z_llgh(Z_R0, Address(needle)); } else { z_llgc(Z_R0, Address(needle)); }
|
|
5193 |
|
|
5194 |
// Compute last haystack addr to use if no match gets found.
|
|
5195 |
if (needlecnt != noreg) { // variable needlecnt
|
|
5196 |
z_ahi(needlecnt, -1); // Remaining characters after first one.
|
|
5197 |
z_sr(haycnt, needlecnt); // Compute index succeeding last element to compare.
|
|
5198 |
if (n_csize == 2) { z_sll(needlecnt, 1); } // In bytes.
|
|
5199 |
} else { // constant needlecnt
|
|
5200 |
assert((needlecntval & 0x7fff) == needlecntval, "must be positive simm16 immediate");
|
|
5201 |
// Compute index succeeding last element to compare.
|
|
5202 |
if (needlecntval != 1) { z_ahi(haycnt, 1 - needlecntval); }
|
|
5203 |
}
|
|
5204 |
|
|
5205 |
z_llgfr(haycnt, haycnt); // Clear high half.
|
|
5206 |
z_lgr(result, haystack); // Final result will be computed from needle start pointer.
|
|
5207 |
if (h_csize == 2) { z_sll(haycnt, 1); } // Scale to number of bytes.
|
|
5208 |
z_agr(haycnt, haystack); // Point to address succeeding last element (haystack+scale*(haycnt-needlecnt+1)).
|
|
5209 |
|
|
5210 |
if (h_csize != n_csize) {
|
|
5211 |
assert(ae == StrIntrinsicNode::UL, "Invalid encoding");
|
|
5212 |
|
|
5213 |
if (needlecnt != noreg || needlecntval != 1) {
|
|
5214 |
if (needlecnt != noreg) {
|
|
5215 |
compare32_and_branch(needlecnt, (intptr_t)0, Assembler::bcondEqual, L_needle1);
|
|
5216 |
}
|
|
5217 |
|
|
5218 |
// Main Loop: UL version (now we have at least 2 characters).
|
|
5219 |
Label L_OuterLoop, L_InnerLoop, L_Skip;
|
|
5220 |
bind(L_OuterLoop); // Search for 1st 2 characters.
|
|
5221 |
z_lgr(Z_R1, haycnt);
|
|
5222 |
MacroAssembler::search_string_uni(Z_R1, result);
|
|
5223 |
z_brc(Assembler::bcondNotFound, L_NotFound);
|
|
5224 |
z_lgr(result, Z_R1);
|
|
5225 |
|
|
5226 |
z_lghi(Z_R1, n_csize);
|
|
5227 |
z_lghi(even_reg, h_csize);
|
|
5228 |
bind(L_InnerLoop);
|
|
5229 |
z_llgc(odd_reg, Address(needle, Z_R1));
|
|
5230 |
z_ch(odd_reg, Address(result, even_reg));
|
|
5231 |
z_brne(L_Skip);
|
|
5232 |
if (needlecnt != noreg) { z_cr(Z_R1, needlecnt); } else { z_chi(Z_R1, needlecntval - 1); }
|
|
5233 |
z_brnl(L_Found);
|
|
5234 |
z_aghi(Z_R1, n_csize);
|
|
5235 |
z_aghi(even_reg, h_csize);
|
|
5236 |
z_bru(L_InnerLoop);
|
|
5237 |
|
|
5238 |
bind(L_Skip);
|
|
5239 |
z_aghi(result, h_csize); // This is the new address we want to use for comparing.
|
|
5240 |
z_bru(L_OuterLoop);
|
|
5241 |
}
|
|
5242 |
|
|
5243 |
} else {
|
|
5244 |
const intptr_t needle_bytes = (n_csize == 2) ? ((needlecntval - 1) << 1) : (needlecntval - 1);
|
|
5245 |
Label L_clcle;
|
|
5246 |
|
|
5247 |
if (needlecnt != noreg || (needlecntval != 1 && needle_bytes <= 256)) {
|
|
5248 |
if (needlecnt != noreg) {
|
|
5249 |
compare32_and_branch(needlecnt, 256, Assembler::bcondHigh, L_clcle);
|
|
5250 |
z_ahi(needlecnt, -1); // remaining bytes -1 (for CLC)
|
|
5251 |
z_brl(L_needle1);
|
|
5252 |
}
|
|
5253 |
|
|
5254 |
// Main Loop: clc version (now we have at least 2 characters).
|
|
5255 |
Label L_OuterLoop, CLC_template;
|
|
5256 |
bind(L_OuterLoop); // Search for 1st 2 characters.
|
|
5257 |
z_lgr(Z_R1, haycnt);
|
|
5258 |
if (h_csize == 1) {
|
|
5259 |
MacroAssembler::search_string(Z_R1, result);
|
|
5260 |
} else {
|
|
5261 |
MacroAssembler::search_string_uni(Z_R1, result);
|
|
5262 |
}
|
|
5263 |
z_brc(Assembler::bcondNotFound, L_NotFound);
|
|
5264 |
z_lgr(result, Z_R1);
|
|
5265 |
|
|
5266 |
if (needlecnt != noreg) {
|
|
5267 |
assert(VM_Version::has_ExecuteExtensions(), "unsupported hardware");
|
|
5268 |
z_exrl(needlecnt, CLC_template);
|
|
5269 |
} else {
|
|
5270 |
z_clc(h_csize, needle_bytes -1, Z_R1, n_csize, needle);
|
|
5271 |
}
|
|
5272 |
z_bre(L_Found);
|
|
5273 |
z_aghi(result, h_csize); // This is the new address we want to use for comparing.
|
|
5274 |
z_bru(L_OuterLoop);
|
|
5275 |
|
|
5276 |
if (needlecnt != noreg) {
|
|
5277 |
bind(CLC_template);
|
|
5278 |
z_clc(h_csize, 0, Z_R1, n_csize, needle);
|
|
5279 |
}
|
|
5280 |
}
|
|
5281 |
|
|
5282 |
if (needlecnt != noreg || needle_bytes > 256) {
|
|
5283 |
bind(L_clcle);
|
|
5284 |
|
|
5285 |
// Main Loop: clcle version (now we have at least 256 bytes).
|
|
5286 |
Label L_OuterLoop, CLC_template;
|
|
5287 |
bind(L_OuterLoop); // Search for 1st 2 characters.
|
|
5288 |
z_lgr(Z_R1, haycnt);
|
|
5289 |
if (h_csize == 1) {
|
|
5290 |
MacroAssembler::search_string(Z_R1, result);
|
|
5291 |
} else {
|
|
5292 |
MacroAssembler::search_string_uni(Z_R1, result);
|
|
5293 |
}
|
|
5294 |
z_brc(Assembler::bcondNotFound, L_NotFound);
|
|
5295 |
|
|
5296 |
add2reg(Z_R0, n_csize, needle);
|
|
5297 |
add2reg(even_reg, h_csize, Z_R1);
|
|
5298 |
z_lgr(result, Z_R1);
|
|
5299 |
if (needlecnt != noreg) {
|
|
5300 |
z_llgfr(Z_R1, needlecnt); // needle len in bytes (left operand)
|
|
5301 |
z_llgfr(odd_reg, needlecnt);
|
|
5302 |
} else {
|
|
5303 |
load_const_optimized(Z_R1, needle_bytes);
|
|
5304 |
if (Immediate::is_simm16(needle_bytes)) { z_lghi(odd_reg, needle_bytes); } else { z_lgr(odd_reg, Z_R1); }
|
|
5305 |
}
|
|
5306 |
if (h_csize == 1) {
|
|
5307 |
compare_long_ext(Z_R0, even_reg, 0);
|
|
5308 |
} else {
|
|
5309 |
compare_long_uni(Z_R0, even_reg, 0);
|
|
5310 |
}
|
|
5311 |
z_bre(L_Found);
|
|
5312 |
|
|
5313 |
if (n_csize == 2) { z_llgh(Z_R0, Address(needle)); } else { z_llgc(Z_R0, Address(needle)); } // Reload.
|
|
5314 |
z_aghi(result, h_csize); // This is the new address we want to use for comparing.
|
|
5315 |
z_bru(L_OuterLoop);
|
|
5316 |
}
|
|
5317 |
}
|
|
5318 |
|
|
5319 |
if (needlecnt != noreg || needlecntval == 1) {
|
|
5320 |
bind(L_needle1);
|
|
5321 |
|
|
5322 |
// Single needle character version.
|
|
5323 |
if (h_csize == 1) {
|
|
5324 |
MacroAssembler::search_string(haycnt, result);
|
|
5325 |
} else {
|
|
5326 |
MacroAssembler::search_string_uni(haycnt, result);
|
|
5327 |
}
|
|
5328 |
z_lgr(result, haycnt);
|
|
5329 |
z_brc(Assembler::bcondFound, L_Found);
|
|
5330 |
}
|
|
5331 |
|
|
5332 |
bind(L_NotFound);
|
|
5333 |
add2reg(result, -1, haystack); // Return -1.
|
|
5334 |
|
|
5335 |
bind(L_Found); // Return index (or -1 in fallthrough case).
|
|
5336 |
z_sgr(result, haystack);
|
|
5337 |
if (h_csize == 2) { z_srag(result, result, exact_log2(sizeof(jchar))); }
|
|
5338 |
}
|
|
5339 |
BLOCK_COMMENT("} string_indexof");
|
|
5340 |
|
|
5341 |
return offset() - block_start;
|
|
5342 |
}
|
|
5343 |
|
|
5344 |
// early clobber: result
|
|
5345 |
unsigned int MacroAssembler::string_indexof_char(Register result, Register haystack, Register haycnt,
|
|
5346 |
Register needle, jchar needleChar, Register odd_reg, Register even_reg, bool is_byte) {
|
|
5347 |
int block_start = offset();
|
|
5348 |
|
|
5349 |
BLOCK_COMMENT("string_indexof_char {");
|
|
5350 |
|
|
5351 |
if (needle == haystack) {
|
|
5352 |
z_lhi(result, 0);
|
|
5353 |
} else {
|
|
5354 |
|
|
5355 |
Label Ldone;
|
|
5356 |
|
|
5357 |
z_llgfr(odd_reg, haycnt); // Preset loop ctr/searchrange end.
|
|
5358 |
if (needle == noreg) {
|
|
5359 |
load_const_optimized(Z_R0, (unsigned long)needleChar);
|
|
5360 |
} else {
|
|
5361 |
if (is_byte) {
|
|
5362 |
z_llgcr(Z_R0, needle); // First (and only) needle char.
|
|
5363 |
} else {
|
|
5364 |
z_llghr(Z_R0, needle); // First (and only) needle char.
|
|
5365 |
}
|
|
5366 |
}
|
|
5367 |
|
|
5368 |
if (!is_byte) {
|
|
5369 |
z_agr(odd_reg, odd_reg); // Calc #bytes to be processed with SRSTU.
|
|
5370 |
}
|
|
5371 |
|
|
5372 |
z_lgr(even_reg, haystack); // haystack addr
|
|
5373 |
z_agr(odd_reg, haystack); // First char after range end.
|
|
5374 |
z_lghi(result, -1);
|
|
5375 |
|
|
5376 |
if (is_byte) {
|
|
5377 |
MacroAssembler::search_string(odd_reg, even_reg);
|
|
5378 |
} else {
|
|
5379 |
MacroAssembler::search_string_uni(odd_reg, even_reg);
|
|
5380 |
}
|
|
5381 |
z_brc(Assembler::bcondNotFound, Ldone);
|
|
5382 |
if (is_byte) {
|
|
5383 |
if (VM_Version::has_DistinctOpnds()) {
|
|
5384 |
z_sgrk(result, odd_reg, haystack);
|
|
5385 |
} else {
|
|
5386 |
z_sgr(odd_reg, haystack);
|
|
5387 |
z_lgr(result, odd_reg);
|
|
5388 |
}
|
|
5389 |
} else {
|
|
5390 |
z_slgr(odd_reg, haystack);
|
|
5391 |
z_srlg(result, odd_reg, exact_log2(sizeof(jchar)));
|
|
5392 |
}
|
|
5393 |
|
|
5394 |
bind(Ldone);
|
|
5395 |
}
|
|
5396 |
BLOCK_COMMENT("} string_indexof_char");
|
|
5397 |
|
|
5398 |
return offset() - block_start;
|
|
5399 |
}
|
|
5400 |
|
|
5401 |
|
|
5402 |
//-------------------------------------------------
|
|
5403 |
// Constants (scalar and oop) in constant pool
|
|
5404 |
//-------------------------------------------------
|
|
5405 |
|
|
5406 |
// Add a non-relocated constant to the CP.
|
|
5407 |
int MacroAssembler::store_const_in_toc(AddressLiteral& val) {
|
|
5408 |
long value = val.value();
|
|
5409 |
address tocPos = long_constant(value);
|
|
5410 |
|
|
5411 |
if (tocPos != NULL) {
|
|
5412 |
int tocOffset = (int)(tocPos - code()->consts()->start());
|
|
5413 |
return tocOffset;
|
|
5414 |
}
|
|
5415 |
// Address_constant returned NULL, so no constant entry has been created.
|
|
5416 |
// In that case, we return a "fatal" offset, just in case that subsequently
|
|
5417 |
// generated access code is executed.
|
|
5418 |
return -1;
|
|
5419 |
}
|
|
5420 |
|
|
5421 |
// Returns the TOC offset where the address is stored.
|
|
5422 |
// Add a relocated constant to the CP.
|
|
5423 |
int MacroAssembler::store_oop_in_toc(AddressLiteral& oop) {
|
|
5424 |
// Use RelocationHolder::none for the constant pool entry.
|
|
5425 |
// Otherwise we will end up with a failing NativeCall::verify(x),
|
|
5426 |
// where x is the address of the constant pool entry.
|
|
5427 |
address tocPos = address_constant((address)oop.value(), RelocationHolder::none);
|
|
5428 |
|
|
5429 |
if (tocPos != NULL) {
|
|
5430 |
int tocOffset = (int)(tocPos - code()->consts()->start());
|
|
5431 |
RelocationHolder rsp = oop.rspec();
|
|
5432 |
Relocation *rel = rsp.reloc();
|
|
5433 |
|
|
5434 |
// Store toc_offset in relocation, used by call_far_patchable.
|
|
5435 |
if ((relocInfo::relocType)rel->type() == relocInfo::runtime_call_w_cp_type) {
|
|
5436 |
((runtime_call_w_cp_Relocation *)(rel))->set_constant_pool_offset(tocOffset);
|
|
5437 |
}
|
|
5438 |
// Relocate at the load's pc.
|
|
5439 |
relocate(rsp);
|
|
5440 |
|
|
5441 |
return tocOffset;
|
|
5442 |
}
|
|
5443 |
// Address_constant returned NULL, so no constant entry has been created
|
|
5444 |
// in that case, we return a "fatal" offset, just in case that subsequently
|
|
5445 |
// generated access code is executed.
|
|
5446 |
return -1;
|
|
5447 |
}
|
|
5448 |
|
|
5449 |
bool MacroAssembler::load_const_from_toc(Register dst, AddressLiteral& a, Register Rtoc) {
|
|
5450 |
int tocOffset = store_const_in_toc(a);
|
|
5451 |
if (tocOffset == -1) return false;
|
|
5452 |
address tocPos = tocOffset + code()->consts()->start();
|
|
5453 |
assert((address)code()->consts()->start() != NULL, "Please add CP address");
|
|
5454 |
|
|
5455 |
load_long_pcrelative(dst, tocPos);
|
|
5456 |
return true;
|
|
5457 |
}
|
|
5458 |
|
|
5459 |
bool MacroAssembler::load_oop_from_toc(Register dst, AddressLiteral& a, Register Rtoc) {
|
|
5460 |
int tocOffset = store_oop_in_toc(a);
|
|
5461 |
if (tocOffset == -1) return false;
|
|
5462 |
address tocPos = tocOffset + code()->consts()->start();
|
|
5463 |
assert((address)code()->consts()->start() != NULL, "Please add CP address");
|
|
5464 |
|
|
5465 |
load_addr_pcrelative(dst, tocPos);
|
|
5466 |
return true;
|
|
5467 |
}
|
|
5468 |
|
|
5469 |
// If the instruction sequence at the given pc is a load_const_from_toc
|
|
5470 |
// sequence, return the value currently stored at the referenced position
|
|
5471 |
// in the TOC.
|
|
5472 |
intptr_t MacroAssembler::get_const_from_toc(address pc) {
|
|
5473 |
|
|
5474 |
assert(is_load_const_from_toc(pc), "must be load_const_from_pool");
|
|
5475 |
|
|
5476 |
long offset = get_load_const_from_toc_offset(pc);
|
|
5477 |
address dataLoc = NULL;
|
|
5478 |
if (is_load_const_from_toc_pcrelative(pc)) {
|
|
5479 |
dataLoc = pc + offset;
|
|
5480 |
} else {
|
|
5481 |
CodeBlob* cb = CodeCache::find_blob_unsafe(pc); // Else we get assertion if nmethod is zombie.
|
|
5482 |
assert(cb && cb->is_nmethod(), "sanity");
|
|
5483 |
nmethod* nm = (nmethod*)cb;
|
|
5484 |
dataLoc = nm->ctable_begin() + offset;
|
|
5485 |
}
|
|
5486 |
return *(intptr_t *)dataLoc;
|
|
5487 |
}
|
|
5488 |
|
|
5489 |
// If the instruction sequence at the given pc is a load_const_from_toc
|
|
5490 |
// sequence, copy the passed-in new_data value into the referenced
|
|
5491 |
// position in the TOC.
|
|
5492 |
void MacroAssembler::set_const_in_toc(address pc, unsigned long new_data, CodeBlob *cb) {
|
|
5493 |
assert(is_load_const_from_toc(pc), "must be load_const_from_pool");
|
|
5494 |
|
|
5495 |
long offset = MacroAssembler::get_load_const_from_toc_offset(pc);
|
|
5496 |
address dataLoc = NULL;
|
|
5497 |
if (is_load_const_from_toc_pcrelative(pc)) {
|
|
5498 |
dataLoc = pc+offset;
|
|
5499 |
} else {
|
|
5500 |
nmethod* nm = CodeCache::find_nmethod(pc);
|
|
5501 |
assert((cb == NULL) || (nm == (nmethod*)cb), "instruction address should be in CodeBlob");
|
|
5502 |
dataLoc = nm->ctable_begin() + offset;
|
|
5503 |
}
|
|
5504 |
if (*(unsigned long *)dataLoc != new_data) { // Prevent cache invalidation: update only if necessary.
|
|
5505 |
*(unsigned long *)dataLoc = new_data;
|
|
5506 |
}
|
|
5507 |
}
|
|
5508 |
|
|
5509 |
// Dynamic TOC. Getter must only be called if "a" is a load_const_from_toc
|
|
5510 |
// site. Verify by calling is_load_const_from_toc() before!!
|
|
5511 |
// Offset is +/- 2**32 -> use long.
|
|
5512 |
long MacroAssembler::get_load_const_from_toc_offset(address a) {
|
|
5513 |
assert(is_load_const_from_toc_pcrelative(a), "expected pc relative load");
|
|
5514 |
// expected code sequence:
|
|
5515 |
// z_lgrl(t, simm32); len = 6
|
|
5516 |
unsigned long inst;
|
|
5517 |
unsigned int len = get_instruction(a, &inst);
|
|
5518 |
return get_pcrel_offset(inst);
|
|
5519 |
}
|
|
5520 |
|
|
5521 |
//**********************************************************************************
|
|
5522 |
// inspection of generated instruction sequences for a particular pattern
|
|
5523 |
//**********************************************************************************
|
|
5524 |
|
|
5525 |
bool MacroAssembler::is_load_const_from_toc_pcrelative(address a) {
|
|
5526 |
#ifdef ASSERT
|
|
5527 |
unsigned long inst;
|
|
5528 |
unsigned int len = get_instruction(a+2, &inst);
|
|
5529 |
if ((len == 6) && is_load_pcrelative_long(a) && is_call_pcrelative_long(inst)) {
|
|
5530 |
const int range = 128;
|
|
5531 |
Assembler::dump_code_range(tty, a, range, "instr(a) == z_lgrl && instr(a+2) == z_brasl");
|
|
5532 |
VM_Version::z_SIGSEGV();
|
|
5533 |
}
|
|
5534 |
#endif
|
|
5535 |
// expected code sequence:
|
|
5536 |
// z_lgrl(t, relAddr32); len = 6
|
|
5537 |
//TODO: verify accessed data is in CP, if possible.
|
|
5538 |
return is_load_pcrelative_long(a); // TODO: might be too general. Currently, only lgrl is used.
|
|
5539 |
}
|
|
5540 |
|
|
5541 |
bool MacroAssembler::is_load_const_from_toc_call(address a) {
|
|
5542 |
return is_load_const_from_toc(a) && is_call_byregister(a + load_const_from_toc_size());
|
|
5543 |
}
|
|
5544 |
|
|
5545 |
bool MacroAssembler::is_load_const_call(address a) {
|
|
5546 |
return is_load_const(a) && is_call_byregister(a + load_const_size());
|
|
5547 |
}
|
|
5548 |
|
|
5549 |
//-------------------------------------------------
|
|
5550 |
// Emitters for some really CICS instructions
|
|
5551 |
//-------------------------------------------------
|
|
5552 |
|
|
5553 |
void MacroAssembler::move_long_ext(Register dst, Register src, unsigned int pad) {
|
|
5554 |
assert(dst->encoding()%2==0, "must be an even/odd register pair");
|
|
5555 |
assert(src->encoding()%2==0, "must be an even/odd register pair");
|
|
5556 |
assert(pad<256, "must be a padding BYTE");
|
|
5557 |
|
|
5558 |
Label retry;
|
|
5559 |
bind(retry);
|
|
5560 |
Assembler::z_mvcle(dst, src, pad);
|
|
5561 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5562 |
}
|
|
5563 |
|
|
5564 |
void MacroAssembler::compare_long_ext(Register left, Register right, unsigned int pad) {
|
|
5565 |
assert(left->encoding() % 2 == 0, "must be an even/odd register pair");
|
|
5566 |
assert(right->encoding() % 2 == 0, "must be an even/odd register pair");
|
|
5567 |
assert(pad<256, "must be a padding BYTE");
|
|
5568 |
|
|
5569 |
Label retry;
|
|
5570 |
bind(retry);
|
|
5571 |
Assembler::z_clcle(left, right, pad, Z_R0);
|
|
5572 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5573 |
}
|
|
5574 |
|
|
5575 |
void MacroAssembler::compare_long_uni(Register left, Register right, unsigned int pad) {
|
|
5576 |
assert(left->encoding() % 2 == 0, "must be an even/odd register pair");
|
|
5577 |
assert(right->encoding() % 2 == 0, "must be an even/odd register pair");
|
|
5578 |
assert(pad<=0xfff, "must be a padding HALFWORD");
|
|
5579 |
assert(VM_Version::has_ETF2(), "instruction must be available");
|
|
5580 |
|
|
5581 |
Label retry;
|
|
5582 |
bind(retry);
|
|
5583 |
Assembler::z_clclu(left, right, pad, Z_R0);
|
|
5584 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5585 |
}
|
|
5586 |
|
|
5587 |
void MacroAssembler::search_string(Register end, Register start) {
|
|
5588 |
assert(end->encoding() != 0, "end address must not be in R0");
|
|
5589 |
assert(start->encoding() != 0, "start address must not be in R0");
|
|
5590 |
|
|
5591 |
Label retry;
|
|
5592 |
bind(retry);
|
|
5593 |
Assembler::z_srst(end, start);
|
|
5594 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5595 |
}
|
|
5596 |
|
|
5597 |
void MacroAssembler::search_string_uni(Register end, Register start) {
|
|
5598 |
assert(end->encoding() != 0, "end address must not be in R0");
|
|
5599 |
assert(start->encoding() != 0, "start address must not be in R0");
|
|
5600 |
assert(VM_Version::has_ETF3(), "instruction must be available");
|
|
5601 |
|
|
5602 |
Label retry;
|
|
5603 |
bind(retry);
|
|
5604 |
Assembler::z_srstu(end, start);
|
|
5605 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5606 |
}
|
|
5607 |
|
|
5608 |
void MacroAssembler::kmac(Register srcBuff) {
|
|
5609 |
assert(srcBuff->encoding() != 0, "src buffer address can't be in Z_R0");
|
|
5610 |
assert(srcBuff->encoding() % 2 == 0, "src buffer/len must be an even/odd register pair");
|
|
5611 |
|
|
5612 |
Label retry;
|
|
5613 |
bind(retry);
|
|
5614 |
Assembler::z_kmac(Z_R0, srcBuff);
|
|
5615 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5616 |
}
|
|
5617 |
|
|
5618 |
void MacroAssembler::kimd(Register srcBuff) {
|
|
5619 |
assert(srcBuff->encoding() != 0, "src buffer address can't be in Z_R0");
|
|
5620 |
assert(srcBuff->encoding() % 2 == 0, "src buffer/len must be an even/odd register pair");
|
|
5621 |
|
|
5622 |
Label retry;
|
|
5623 |
bind(retry);
|
|
5624 |
Assembler::z_kimd(Z_R0, srcBuff);
|
|
5625 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5626 |
}
|
|
5627 |
|
|
5628 |
void MacroAssembler::klmd(Register srcBuff) {
|
|
5629 |
assert(srcBuff->encoding() != 0, "src buffer address can't be in Z_R0");
|
|
5630 |
assert(srcBuff->encoding() % 2 == 0, "src buffer/len must be an even/odd register pair");
|
|
5631 |
|
|
5632 |
Label retry;
|
|
5633 |
bind(retry);
|
|
5634 |
Assembler::z_klmd(Z_R0, srcBuff);
|
|
5635 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5636 |
}
|
|
5637 |
|
|
5638 |
void MacroAssembler::km(Register dstBuff, Register srcBuff) {
|
|
5639 |
// DstBuff and srcBuff are allowed to be the same register (encryption in-place).
|
|
5640 |
// DstBuff and srcBuff storage must not overlap destructively, and neither must overlap the parameter block.
|
|
5641 |
assert(srcBuff->encoding() != 0, "src buffer address can't be in Z_R0");
|
|
5642 |
assert(dstBuff->encoding() % 2 == 0, "dst buffer addr must be an even register");
|
|
5643 |
assert(srcBuff->encoding() % 2 == 0, "src buffer addr/len must be an even/odd register pair");
|
|
5644 |
|
|
5645 |
Label retry;
|
|
5646 |
bind(retry);
|
|
5647 |
Assembler::z_km(dstBuff, srcBuff);
|
|
5648 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5649 |
}
|
|
5650 |
|
|
5651 |
void MacroAssembler::kmc(Register dstBuff, Register srcBuff) {
|
|
5652 |
// DstBuff and srcBuff are allowed to be the same register (encryption in-place).
|
|
5653 |
// DstBuff and srcBuff storage must not overlap destructively, and neither must overlap the parameter block.
|
|
5654 |
assert(srcBuff->encoding() != 0, "src buffer address can't be in Z_R0");
|
|
5655 |
assert(dstBuff->encoding() % 2 == 0, "dst buffer addr must be an even register");
|
|
5656 |
assert(srcBuff->encoding() % 2 == 0, "src buffer addr/len must be an even/odd register pair");
|
|
5657 |
|
|
5658 |
Label retry;
|
|
5659 |
bind(retry);
|
|
5660 |
Assembler::z_kmc(dstBuff, srcBuff);
|
|
5661 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5662 |
}
|
|
5663 |
|
|
5664 |
void MacroAssembler::cksm(Register crcBuff, Register srcBuff) {
|
|
5665 |
assert(srcBuff->encoding() % 2 == 0, "src buffer addr/len must be an even/odd register pair");
|
|
5666 |
|
|
5667 |
Label retry;
|
|
5668 |
bind(retry);
|
|
5669 |
Assembler::z_cksm(crcBuff, srcBuff);
|
|
5670 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5671 |
}
|
|
5672 |
|
|
5673 |
void MacroAssembler::translate_oo(Register r1, Register r2, uint m3) {
|
|
5674 |
assert(r1->encoding() % 2 == 0, "dst addr/src len must be an even/odd register pair");
|
|
5675 |
assert((m3 & 0b1110) == 0, "Unused mask bits must be zero");
|
|
5676 |
|
|
5677 |
Label retry;
|
|
5678 |
bind(retry);
|
|
5679 |
Assembler::z_troo(r1, r2, m3);
|
|
5680 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5681 |
}
|
|
5682 |
|
|
5683 |
void MacroAssembler::translate_ot(Register r1, Register r2, uint m3) {
|
|
5684 |
assert(r1->encoding() % 2 == 0, "dst addr/src len must be an even/odd register pair");
|
|
5685 |
assert((m3 & 0b1110) == 0, "Unused mask bits must be zero");
|
|
5686 |
|
|
5687 |
Label retry;
|
|
5688 |
bind(retry);
|
|
5689 |
Assembler::z_trot(r1, r2, m3);
|
|
5690 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5691 |
}
|
|
5692 |
|
|
5693 |
void MacroAssembler::translate_to(Register r1, Register r2, uint m3) {
|
|
5694 |
assert(r1->encoding() % 2 == 0, "dst addr/src len must be an even/odd register pair");
|
|
5695 |
assert((m3 & 0b1110) == 0, "Unused mask bits must be zero");
|
|
5696 |
|
|
5697 |
Label retry;
|
|
5698 |
bind(retry);
|
|
5699 |
Assembler::z_trto(r1, r2, m3);
|
|
5700 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5701 |
}
|
|
5702 |
|
|
5703 |
void MacroAssembler::translate_tt(Register r1, Register r2, uint m3) {
|
|
5704 |
assert(r1->encoding() % 2 == 0, "dst addr/src len must be an even/odd register pair");
|
|
5705 |
assert((m3 & 0b1110) == 0, "Unused mask bits must be zero");
|
|
5706 |
|
|
5707 |
Label retry;
|
|
5708 |
bind(retry);
|
|
5709 |
Assembler::z_trtt(r1, r2, m3);
|
|
5710 |
Assembler::z_brc(Assembler::bcondOverflow /* CC==3 (iterate) */, retry);
|
|
5711 |
}
|
|
5712 |
|
|
5713 |
void MacroAssembler::generate_safepoint_check(Label& slow_path, Register scratch, bool may_relocate) {
|
|
5714 |
if (scratch == noreg) scratch = Z_R1;
|
|
5715 |
address Astate = SafepointSynchronize::address_of_state();
|
|
5716 |
BLOCK_COMMENT("safepoint check:");
|
|
5717 |
|
|
5718 |
if (may_relocate) {
|
|
5719 |
ptrdiff_t total_distance = Astate - this->pc();
|
|
5720 |
if (RelAddr::is_in_range_of_RelAddr32(total_distance)) {
|
|
5721 |
RelocationHolder rspec = external_word_Relocation::spec(Astate);
|
|
5722 |
(this)->relocate(rspec, relocInfo::pcrel_addr_format);
|
|
5723 |
load_absolute_address(scratch, Astate);
|
|
5724 |
} else {
|
|
5725 |
load_const_optimized(scratch, Astate);
|
|
5726 |
}
|
|
5727 |
} else {
|
|
5728 |
load_absolute_address(scratch, Astate);
|
|
5729 |
}
|
|
5730 |
z_cli(/*SafepointSynchronize::sz_state()*/4-1, scratch, SafepointSynchronize::_not_synchronized);
|
|
5731 |
z_brne(slow_path);
|
|
5732 |
}
|
|
5733 |
|
|
5734 |
|
|
5735 |
void MacroAssembler::generate_type_profiling(const Register Rdata,
|
|
5736 |
const Register Rreceiver_klass,
|
|
5737 |
const Register Rwanted_receiver_klass,
|
|
5738 |
const Register Rmatching_row,
|
|
5739 |
bool is_virtual_call) {
|
|
5740 |
const int row_size = in_bytes(ReceiverTypeData::receiver_offset(1)) -
|
|
5741 |
in_bytes(ReceiverTypeData::receiver_offset(0));
|
|
5742 |
const int num_rows = ReceiverTypeData::row_limit();
|
|
5743 |
NearLabel found_free_row;
|
|
5744 |
NearLabel do_increment;
|
|
5745 |
NearLabel found_no_slot;
|
|
5746 |
|
|
5747 |
BLOCK_COMMENT("type profiling {");
|
|
5748 |
|
|
5749 |
// search for:
|
|
5750 |
// a) The type given in Rwanted_receiver_klass.
|
|
5751 |
// b) The *first* empty row.
|
|
5752 |
|
|
5753 |
// First search for a) only, just running over b) with no regard.
|
|
5754 |
// This is possible because
|
|
5755 |
// wanted_receiver_class == receiver_class && wanted_receiver_class == 0
|
|
5756 |
// is never true (receiver_class can't be zero).
|
|
5757 |
for (int row_num = 0; row_num < num_rows; row_num++) {
|
|
5758 |
// Row_offset should be a well-behaved positive number. The generated code relies
|
|
5759 |
// on that wrt constant code size. Add2reg can handle all row_offset values, but
|
|
5760 |
// will have to vary generated code size.
|
|
5761 |
int row_offset = in_bytes(ReceiverTypeData::receiver_offset(row_num));
|
|
5762 |
assert(Displacement::is_shortDisp(row_offset), "Limitation of generated code");
|
|
5763 |
|
|
5764 |
// Is Rwanted_receiver_klass in this row?
|
|
5765 |
if (VM_Version::has_CompareBranch()) {
|
|
5766 |
z_lg(Rwanted_receiver_klass, row_offset, Z_R0, Rdata);
|
|
5767 |
// Rmatching_row = Rdata + row_offset;
|
|
5768 |
add2reg(Rmatching_row, row_offset, Rdata);
|
|
5769 |
// if (*row_recv == (intptr_t) receiver_klass) goto fill_existing_slot;
|
|
5770 |
compare64_and_branch(Rwanted_receiver_klass, Rreceiver_klass, Assembler::bcondEqual, do_increment);
|
|
5771 |
} else {
|
|
5772 |
add2reg(Rmatching_row, row_offset, Rdata);
|
|
5773 |
z_cg(Rreceiver_klass, row_offset, Z_R0, Rdata);
|
|
5774 |
z_bre(do_increment);
|
|
5775 |
}
|
|
5776 |
}
|
|
5777 |
|
|
5778 |
// Now that we did not find a match, let's search for b).
|
|
5779 |
|
|
5780 |
// We could save the first calculation of Rmatching_row if we woud search for a) in reverse order.
|
|
5781 |
// We would then end up here with Rmatching_row containing the value for row_num == 0.
|
|
5782 |
// We would not see much benefit, if any at all, because the CPU can schedule
|
|
5783 |
// two instructions together with a branch anyway.
|
|
5784 |
for (int row_num = 0; row_num < num_rows; row_num++) {
|
|
5785 |
int row_offset = in_bytes(ReceiverTypeData::receiver_offset(row_num));
|
|
5786 |
|
|
5787 |
// Has this row a zero receiver_klass, i.e. is it empty?
|
|
5788 |
if (VM_Version::has_CompareBranch()) {
|
|
5789 |
z_lg(Rwanted_receiver_klass, row_offset, Z_R0, Rdata);
|
|
5790 |
// Rmatching_row = Rdata + row_offset
|
|
5791 |
add2reg(Rmatching_row, row_offset, Rdata);
|
|
5792 |
// if (*row_recv == (intptr_t) 0) goto found_free_row
|
|
5793 |
compare64_and_branch(Rwanted_receiver_klass, (intptr_t)0, Assembler::bcondEqual, found_free_row);
|
|
5794 |
} else {
|
|
5795 |
add2reg(Rmatching_row, row_offset, Rdata);
|
|
5796 |
load_and_test_long(Rwanted_receiver_klass, Address(Rdata, row_offset));
|
|
5797 |
z_bre(found_free_row); // zero -> Found a free row.
|
|
5798 |
}
|
|
5799 |
}
|
|
5800 |
|
|
5801 |
// No match, no empty row found.
|
|
5802 |
// Increment total counter to indicate polymorphic case.
|
|
5803 |
if (is_virtual_call) {
|
|
5804 |
add2mem_64(Address(Rdata, CounterData::count_offset()), 1, Rmatching_row);
|
|
5805 |
}
|
|
5806 |
z_bru(found_no_slot);
|
|
5807 |
|
|
5808 |
// Here we found an empty row, but we have not found Rwanted_receiver_klass.
|
|
5809 |
// Rmatching_row holds the address to the first empty row.
|
|
5810 |
bind(found_free_row);
|
|
5811 |
// Store receiver_klass into empty slot.
|
|
5812 |
z_stg(Rreceiver_klass, 0, Z_R0, Rmatching_row);
|
|
5813 |
|
|
5814 |
// Increment the counter of Rmatching_row.
|
|
5815 |
bind(do_increment);
|
|
5816 |
ByteSize counter_offset = ReceiverTypeData::receiver_count_offset(0) - ReceiverTypeData::receiver_offset(0);
|
|
5817 |
add2mem_64(Address(Rmatching_row, counter_offset), 1, Rdata);
|
|
5818 |
|
|
5819 |
bind(found_no_slot);
|
|
5820 |
|
|
5821 |
BLOCK_COMMENT("} type profiling");
|
|
5822 |
}
|
|
5823 |
|
|
5824 |
//---------------------------------------
|
|
5825 |
// Helpers for Intrinsic Emitters
|
|
5826 |
//---------------------------------------
|
|
5827 |
|
|
5828 |
/**
|
|
5829 |
* uint32_t crc;
|
|
5830 |
* timesXtoThe32[crc & 0xFF] ^ (crc >> 8);
|
|
5831 |
*/
|
|
5832 |
void MacroAssembler::fold_byte_crc32(Register crc, Register val, Register table, Register tmp) {
|
|
5833 |
assert_different_registers(crc, table, tmp);
|
|
5834 |
assert_different_registers(val, table);
|
|
5835 |
if (crc == val) { // Must rotate first to use the unmodified value.
|
|
5836 |
rotate_then_insert(tmp, val, 56-2, 63-2, 2, true); // Insert byte 7 of val, shifted left by 2, into byte 6..7 of tmp, clear the rest.
|
|
5837 |
z_srl(crc, 8); // Unsigned shift, clear leftmost 8 bits.
|
|
5838 |
} else {
|
|
5839 |
z_srl(crc, 8); // Unsigned shift, clear leftmost 8 bits.
|
|
5840 |
rotate_then_insert(tmp, val, 56-2, 63-2, 2, true); // Insert byte 7 of val, shifted left by 2, into byte 6..7 of tmp, clear the rest.
|
|
5841 |
}
|
|
5842 |
z_x(crc, Address(table, tmp, 0));
|
|
5843 |
}
|
|
5844 |
|
|
5845 |
/**
|
|
5846 |
* uint32_t crc;
|
|
5847 |
* timesXtoThe32[crc & 0xFF] ^ (crc >> 8);
|
|
5848 |
*/
|
|
5849 |
void MacroAssembler::fold_8bit_crc32(Register crc, Register table, Register tmp) {
|
|
5850 |
fold_byte_crc32(crc, crc, table, tmp);
|
|
5851 |
}
|
|
5852 |
|
|
5853 |
/**
|
|
5854 |
* Emits code to update CRC-32 with a byte value according to constants in table.
|
|
5855 |
*
|
|
5856 |
* @param [in,out]crc Register containing the crc.
|
|
5857 |
* @param [in]val Register containing the byte to fold into the CRC.
|
|
5858 |
* @param [in]table Register containing the table of crc constants.
|
|
5859 |
*
|
|
5860 |
* uint32_t crc;
|
|
5861 |
* val = crc_table[(val ^ crc) & 0xFF];
|
|
5862 |
* crc = val ^ (crc >> 8);
|
|
5863 |
*/
|
|
5864 |
void MacroAssembler::update_byte_crc32(Register crc, Register val, Register table) {
|
|
5865 |
z_xr(val, crc);
|
|
5866 |
fold_byte_crc32(crc, val, table, val);
|
|
5867 |
}
|
|
5868 |
|
|
5869 |
|
|
5870 |
/**
|
|
5871 |
* @param crc register containing existing CRC (32-bit)
|
|
5872 |
* @param buf register pointing to input byte buffer (byte*)
|
|
5873 |
* @param len register containing number of bytes
|
|
5874 |
* @param table register pointing to CRC table
|
|
5875 |
*/
|
|
5876 |
void MacroAssembler::update_byteLoop_crc32(Register crc, Register buf, Register len, Register table,
|
|
5877 |
Register data, bool invertCRC) {
|
|
5878 |
assert_different_registers(crc, buf, len, table, data);
|
|
5879 |
|
|
5880 |
Label L_mainLoop, L_done;
|
|
5881 |
const int mainLoop_stepping = 1;
|
|
5882 |
|
|
5883 |
// Process all bytes in a single-byte loop.
|
|
5884 |
z_ltr(len, len);
|
|
5885 |
z_brnh(L_done);
|
|
5886 |
|
|
5887 |
if (invertCRC) {
|
|
5888 |
not_(crc, noreg, false); // ~c
|
|
5889 |
}
|
|
5890 |
|
|
5891 |
bind(L_mainLoop);
|
|
5892 |
z_llgc(data, Address(buf, (intptr_t)0));// Current byte of input buffer (zero extended). Avoids garbage in upper half of register.
|
|
5893 |
add2reg(buf, mainLoop_stepping); // Advance buffer position.
|
|
5894 |
update_byte_crc32(crc, data, table);
|
|
5895 |
z_brct(len, L_mainLoop); // Iterate.
|
|
5896 |
|
|
5897 |
if (invertCRC) {
|
|
5898 |
not_(crc, noreg, false); // ~c
|
|
5899 |
}
|
|
5900 |
|
|
5901 |
bind(L_done);
|
|
5902 |
}
|
|
5903 |
|
|
5904 |
/**
|
|
5905 |
* Emits code to update CRC-32 with a 4-byte value according to constants in table.
|
|
5906 |
* Implementation according to jdk/src/share/native/java/util/zip/zlib-1.2.8/crc32.c.
|
|
5907 |
*
|
|
5908 |
*/
|
|
5909 |
void MacroAssembler::update_1word_crc32(Register crc, Register buf, Register table, int bufDisp, int bufInc,
|
|
5910 |
Register t0, Register t1, Register t2, Register t3) {
|
|
5911 |
// This is what we implement (the DOBIG4 part):
|
|
5912 |
//
|
|
5913 |
// #define DOBIG4 c ^= *++buf4; \
|
|
5914 |
// c = crc_table[4][c & 0xff] ^ crc_table[5][(c >> 8) & 0xff] ^ \
|
|
5915 |
// crc_table[6][(c >> 16) & 0xff] ^ crc_table[7][c >> 24]
|
|
5916 |
// #define DOBIG32 DOBIG4; DOBIG4; DOBIG4; DOBIG4; DOBIG4; DOBIG4; DOBIG4; DOBIG4
|
|
5917 |
const int ix0 = 4*(4*CRC32_COLUMN_SIZE);
|
|
5918 |
const int ix1 = 5*(4*CRC32_COLUMN_SIZE);
|
|
5919 |
const int ix2 = 6*(4*CRC32_COLUMN_SIZE);
|
|
5920 |
const int ix3 = 7*(4*CRC32_COLUMN_SIZE);
|
|
5921 |
|
|
5922 |
// XOR crc with next four bytes of buffer.
|
|
5923 |
lgr_if_needed(t0, crc);
|
|
5924 |
z_x(t0, Address(buf, bufDisp));
|
|
5925 |
if (bufInc != 0) {
|
|
5926 |
add2reg(buf, bufInc);
|
|
5927 |
}
|
|
5928 |
|
|
5929 |
// Chop crc into 4 single-byte pieces, shifted left 2 bits, to form the table indices.
|
|
5930 |
rotate_then_insert(t3, t0, 56-2, 63-2, 2, true); // ((c >> 0) & 0xff) << 2
|
|
5931 |
rotate_then_insert(t2, t0, 56-2, 63-2, 2-8, true); // ((c >> 8) & 0xff) << 2
|
|
5932 |
rotate_then_insert(t1, t0, 56-2, 63-2, 2-16, true); // ((c >> 16) & 0xff) << 2
|
|
5933 |
rotate_then_insert(t0, t0, 56-2, 63-2, 2-24, true); // ((c >> 24) & 0xff) << 2
|
|
5934 |
|
|
5935 |
// Load pre-calculated table values.
|
|
5936 |
// Use columns 4..7 for big-endian.
|
|
5937 |
z_ly(t3, Address(table, t3, (intptr_t)ix0));
|
|
5938 |
z_ly(t2, Address(table, t2, (intptr_t)ix1));
|
|
5939 |
z_ly(t1, Address(table, t1, (intptr_t)ix2));
|
|
5940 |
z_ly(t0, Address(table, t0, (intptr_t)ix3));
|
|
5941 |
|
|
5942 |
// Calculate new crc from table values.
|
|
5943 |
z_xr(t2, t3);
|
|
5944 |
z_xr(t0, t1);
|
|
5945 |
z_xr(t0, t2); // Now crc contains the final checksum value.
|
|
5946 |
lgr_if_needed(crc, t0);
|
|
5947 |
}
|
|
5948 |
|
|
5949 |
/**
|
|
5950 |
* @param crc register containing existing CRC (32-bit)
|
|
5951 |
* @param buf register pointing to input byte buffer (byte*)
|
|
5952 |
* @param len register containing number of bytes
|
|
5953 |
* @param table register pointing to CRC table
|
|
5954 |
*
|
|
5955 |
* uses Z_R10..Z_R13 as work register. Must be saved/restored by caller!
|
|
5956 |
*/
|
|
5957 |
void MacroAssembler::kernel_crc32_2word(Register crc, Register buf, Register len, Register table,
|
|
5958 |
Register t0, Register t1, Register t2, Register t3) {
|
|
5959 |
assert_different_registers(crc, buf, len, table);
|
|
5960 |
|
|
5961 |
Label L_mainLoop, L_tail;
|
|
5962 |
Register data = t0;
|
|
5963 |
Register ctr = Z_R0;
|
|
5964 |
const int mainLoop_stepping = 8;
|
|
5965 |
const int tailLoop_stepping = 1;
|
|
5966 |
const int log_stepping = exact_log2(mainLoop_stepping);
|
|
5967 |
|
|
5968 |
// Don't test for len <= 0 here. This pathological case should not occur anyway.
|
|
5969 |
// Optimizing for it by adding a test and a branch seems to be a waste of CPU cycles.
|
|
5970 |
// The situation itself is detected and handled correctly by the conditional branches
|
|
5971 |
// following aghi(len, -stepping) and aghi(len, +stepping).
|
|
5972 |
|
|
5973 |
not_(crc, noreg, false); // 1s complement of crc
|
|
5974 |
|
|
5975 |
#if 0
|
|
5976 |
{
|
|
5977 |
// Pre-mainLoop alignment did not show any positive effect on performance.
|
|
5978 |
// We leave the code in for reference. Maybe the vector instructions in z13 depend on alignment.
|
|
5979 |
|
|
5980 |
z_cghi(len, mainLoop_stepping); // Alignment is useless for short data streams.
|
|
5981 |
z_brnh(L_tail);
|
|
5982 |
|
|
5983 |
// Align buf to word (4-byte) boundary.
|
|
5984 |
z_lcr(ctr, buf);
|
|
5985 |
rotate_then_insert(ctr, ctr, 62, 63, 0, true); // TODO: should set cc
|
|
5986 |
z_sgfr(len, ctr); // Remaining len after alignment.
|
|
5987 |
|
|
5988 |
update_byteLoop_crc32(crc, buf, ctr, table, data, false);
|
|
5989 |
}
|
|
5990 |
#endif
|
|
5991 |
|
|
5992 |
// Check for short (<mainLoop_stepping bytes) buffer.
|
|
5993 |
z_srag(ctr, len, log_stepping);
|
|
5994 |
z_brnh(L_tail);
|
|
5995 |
|
|
5996 |
z_lrvr(crc, crc); // Revert byte order because we are dealing with big-endian data.
|
|
5997 |
rotate_then_insert(len, len, 64-log_stepping, 63, 0, true); // #bytes for tailLoop
|
|
5998 |
|
|
5999 |
BIND(L_mainLoop);
|
|
6000 |
update_1word_crc32(crc, buf, table, 0, 0, crc, t1, t2, t3);
|
|
6001 |
update_1word_crc32(crc, buf, table, 4, mainLoop_stepping, crc, t1, t2, t3);
|
|
6002 |
z_brct(ctr, L_mainLoop); // Iterate.
|
|
6003 |
|
|
6004 |
z_lrvr(crc, crc); // Revert byte order back to original.
|
|
6005 |
|
|
6006 |
// Process last few (<8) bytes of buffer.
|
|
6007 |
BIND(L_tail);
|
|
6008 |
update_byteLoop_crc32(crc, buf, len, table, data, false);
|
|
6009 |
|
|
6010 |
not_(crc, noreg, false); // 1s complement of crc
|
|
6011 |
}
|
|
6012 |
|
|
6013 |
/**
|
|
6014 |
* @param crc register containing existing CRC (32-bit)
|
|
6015 |
* @param buf register pointing to input byte buffer (byte*)
|
|
6016 |
* @param len register containing number of bytes
|
|
6017 |
* @param table register pointing to CRC table
|
|
6018 |
*
|
|
6019 |
* uses Z_R10..Z_R13 as work register. Must be saved/restored by caller!
|
|
6020 |
*/
|
|
6021 |
void MacroAssembler::kernel_crc32_1word(Register crc, Register buf, Register len, Register table,
|
|
6022 |
Register t0, Register t1, Register t2, Register t3) {
|
|
6023 |
assert_different_registers(crc, buf, len, table);
|
|
6024 |
|
|
6025 |
Label L_mainLoop, L_tail;
|
|
6026 |
Register data = t0;
|
|
6027 |
Register ctr = Z_R0;
|
|
6028 |
const int mainLoop_stepping = 4;
|
|
6029 |
const int log_stepping = exact_log2(mainLoop_stepping);
|
|
6030 |
|
|
6031 |
// Don't test for len <= 0 here. This pathological case should not occur anyway.
|
|
6032 |
// Optimizing for it by adding a test and a branch seems to be a waste of CPU cycles.
|
|
6033 |
// The situation itself is detected and handled correctly by the conditional branches
|
|
6034 |
// following aghi(len, -stepping) and aghi(len, +stepping).
|
|
6035 |
|
|
6036 |
not_(crc, noreg, false); // 1s complement of crc
|
|
6037 |
|
|
6038 |
// Check for short (<4 bytes) buffer.
|
|
6039 |
z_srag(ctr, len, log_stepping);
|
|
6040 |
z_brnh(L_tail);
|
|
6041 |
|
|
6042 |
z_lrvr(crc, crc); // Revert byte order because we are dealing with big-endian data.
|
|
6043 |
rotate_then_insert(len, len, 64-log_stepping, 63, 0, true); // #bytes for tailLoop
|
|
6044 |
|
|
6045 |
BIND(L_mainLoop);
|
|
6046 |
update_1word_crc32(crc, buf, table, 0, mainLoop_stepping, crc, t1, t2, t3);
|
|
6047 |
z_brct(ctr, L_mainLoop); // Iterate.
|
|
6048 |
z_lrvr(crc, crc); // Revert byte order back to original.
|
|
6049 |
|
|
6050 |
// Process last few (<8) bytes of buffer.
|
|
6051 |
BIND(L_tail);
|
|
6052 |
update_byteLoop_crc32(crc, buf, len, table, data, false);
|
|
6053 |
|
|
6054 |
not_(crc, noreg, false); // 1s complement of crc
|
|
6055 |
}
|
|
6056 |
|
|
6057 |
/**
|
|
6058 |
* @param crc register containing existing CRC (32-bit)
|
|
6059 |
* @param buf register pointing to input byte buffer (byte*)
|
|
6060 |
* @param len register containing number of bytes
|
|
6061 |
* @param table register pointing to CRC table
|
|
6062 |
*/
|
|
6063 |
void MacroAssembler::kernel_crc32_1byte(Register crc, Register buf, Register len, Register table,
|
|
6064 |
Register t0, Register t1, Register t2, Register t3) {
|
|
6065 |
assert_different_registers(crc, buf, len, table);
|
|
6066 |
Register data = t0;
|
|
6067 |
|
|
6068 |
update_byteLoop_crc32(crc, buf, len, table, data, true);
|
|
6069 |
}
|
|
6070 |
|
|
6071 |
void MacroAssembler::kernel_crc32_singleByte(Register crc, Register buf, Register len, Register table, Register tmp) {
|
|
6072 |
assert_different_registers(crc, buf, len, table, tmp);
|
|
6073 |
|
|
6074 |
not_(crc, noreg, false); // ~c
|
|
6075 |
|
|
6076 |
z_llgc(tmp, Address(buf, (intptr_t)0)); // Current byte of input buffer (zero extended). Avoids garbage in upper half of register.
|
|
6077 |
update_byte_crc32(crc, tmp, table);
|
|
6078 |
|
|
6079 |
not_(crc, noreg, false); // ~c
|
|
6080 |
}
|
|
6081 |
|
|
6082 |
//
|
|
6083 |
// Code for BigInteger::multiplyToLen() intrinsic.
|
|
6084 |
//
|
|
6085 |
|
|
6086 |
// dest_lo += src1 + src2
|
|
6087 |
// dest_hi += carry1 + carry2
|
|
6088 |
// Z_R7 is destroyed !
|
|
6089 |
void MacroAssembler::add2_with_carry(Register dest_hi, Register dest_lo,
|
|
6090 |
Register src1, Register src2) {
|
|
6091 |
clear_reg(Z_R7);
|
|
6092 |
z_algr(dest_lo, src1);
|
|
6093 |
z_alcgr(dest_hi, Z_R7);
|
|
6094 |
z_algr(dest_lo, src2);
|
|
6095 |
z_alcgr(dest_hi, Z_R7);
|
|
6096 |
}
|
|
6097 |
|
|
6098 |
// Multiply 64 bit by 64 bit first loop.
|
|
6099 |
void MacroAssembler::multiply_64_x_64_loop(Register x, Register xstart,
|
|
6100 |
Register x_xstart,
|
|
6101 |
Register y, Register y_idx,
|
|
6102 |
Register z,
|
|
6103 |
Register carry,
|
|
6104 |
Register product,
|
|
6105 |
Register idx, Register kdx) {
|
|
6106 |
// jlong carry, x[], y[], z[];
|
|
6107 |
// for (int idx=ystart, kdx=ystart+1+xstart; idx >= 0; idx--, kdx--) {
|
|
6108 |
// huge_128 product = y[idx] * x[xstart] + carry;
|
|
6109 |
// z[kdx] = (jlong)product;
|
|
6110 |
// carry = (jlong)(product >>> 64);
|
|
6111 |
// }
|
|
6112 |
// z[xstart] = carry;
|
|
6113 |
|
|
6114 |
Label L_first_loop, L_first_loop_exit;
|
|
6115 |
Label L_one_x, L_one_y, L_multiply;
|
|
6116 |
|
|
6117 |
z_aghi(xstart, -1);
|
|
6118 |
z_brl(L_one_x); // Special case: length of x is 1.
|
|
6119 |
|
|
6120 |
// Load next two integers of x.
|
|
6121 |
z_sllg(Z_R1_scratch, xstart, LogBytesPerInt);
|
|
6122 |
mem2reg_opt(x_xstart, Address(x, Z_R1_scratch, 0));
|
|
6123 |
|
|
6124 |
|
|
6125 |
bind(L_first_loop);
|
|
6126 |
|
|
6127 |
z_aghi(idx, -1);
|
|
6128 |
z_brl(L_first_loop_exit);
|
|
6129 |
z_aghi(idx, -1);
|
|
6130 |
z_brl(L_one_y);
|
|
6131 |
|
|
6132 |
// Load next two integers of y.
|
|
6133 |
z_sllg(Z_R1_scratch, idx, LogBytesPerInt);
|
|
6134 |
mem2reg_opt(y_idx, Address(y, Z_R1_scratch, 0));
|
|
6135 |
|
|
6136 |
|
|
6137 |
bind(L_multiply);
|
|
6138 |
|
|
6139 |
Register multiplicand = product->successor();
|
|
6140 |
Register product_low = multiplicand;
|
|
6141 |
|
|
6142 |
lgr_if_needed(multiplicand, x_xstart);
|
|
6143 |
z_mlgr(product, y_idx); // multiplicand * y_idx -> product::multiplicand
|
|
6144 |
clear_reg(Z_R7);
|
|
6145 |
z_algr(product_low, carry); // Add carry to result.
|
|
6146 |
z_alcgr(product, Z_R7); // Add carry of the last addition.
|
|
6147 |
add2reg(kdx, -2);
|
|
6148 |
|
|
6149 |
// Store result.
|
|
6150 |
z_sllg(Z_R7, kdx, LogBytesPerInt);
|
|
6151 |
reg2mem_opt(product_low, Address(z, Z_R7, 0));
|
|
6152 |
lgr_if_needed(carry, product);
|
|
6153 |
z_bru(L_first_loop);
|
|
6154 |
|
|
6155 |
|
|
6156 |
bind(L_one_y); // Load one 32 bit portion of y as (0,value).
|
|
6157 |
|
|
6158 |
clear_reg(y_idx);
|
|
6159 |
mem2reg_opt(y_idx, Address(y, (intptr_t) 0), false);
|
|
6160 |
z_bru(L_multiply);
|
|
6161 |
|
|
6162 |
|
|
6163 |
bind(L_one_x); // Load one 32 bit portion of x as (0,value).
|
|
6164 |
|
|
6165 |
clear_reg(x_xstart);
|
|
6166 |
mem2reg_opt(x_xstart, Address(x, (intptr_t) 0), false);
|
|
6167 |
z_bru(L_first_loop);
|
|
6168 |
|
|
6169 |
bind(L_first_loop_exit);
|
|
6170 |
}
|
|
6171 |
|
|
6172 |
// Multiply 64 bit by 64 bit and add 128 bit.
|
|
6173 |
void MacroAssembler::multiply_add_128_x_128(Register x_xstart, Register y,
|
|
6174 |
Register z,
|
|
6175 |
Register yz_idx, Register idx,
|
|
6176 |
Register carry, Register product,
|
|
6177 |
int offset) {
|
|
6178 |
// huge_128 product = (y[idx] * x_xstart) + z[kdx] + carry;
|
|
6179 |
// z[kdx] = (jlong)product;
|
|
6180 |
|
|
6181 |
Register multiplicand = product->successor();
|
|
6182 |
Register product_low = multiplicand;
|
|
6183 |
|
|
6184 |
z_sllg(Z_R7, idx, LogBytesPerInt);
|
|
6185 |
mem2reg_opt(yz_idx, Address(y, Z_R7, offset));
|
|
6186 |
|
|
6187 |
lgr_if_needed(multiplicand, x_xstart);
|
|
6188 |
z_mlgr(product, yz_idx); // multiplicand * yz_idx -> product::multiplicand
|
|
6189 |
mem2reg_opt(yz_idx, Address(z, Z_R7, offset));
|
|
6190 |
|
|
6191 |
add2_with_carry(product, product_low, carry, yz_idx);
|
|
6192 |
|
|
6193 |
z_sllg(Z_R7, idx, LogBytesPerInt);
|
|
6194 |
reg2mem_opt(product_low, Address(z, Z_R7, offset));
|
|
6195 |
|
|
6196 |
}
|
|
6197 |
|
|
6198 |
// Multiply 128 bit by 128 bit. Unrolled inner loop.
|
|
6199 |
void MacroAssembler::multiply_128_x_128_loop(Register x_xstart,
|
|
6200 |
Register y, Register z,
|
|
6201 |
Register yz_idx, Register idx,
|
|
6202 |
Register jdx,
|
|
6203 |
Register carry, Register product,
|
|
6204 |
Register carry2) {
|
|
6205 |
// jlong carry, x[], y[], z[];
|
|
6206 |
// int kdx = ystart+1;
|
|
6207 |
// for (int idx=ystart-2; idx >= 0; idx -= 2) { // Third loop
|
|
6208 |
// huge_128 product = (y[idx+1] * x_xstart) + z[kdx+idx+1] + carry;
|
|
6209 |
// z[kdx+idx+1] = (jlong)product;
|
|
6210 |
// jlong carry2 = (jlong)(product >>> 64);
|
|
6211 |
// product = (y[idx] * x_xstart) + z[kdx+idx] + carry2;
|
|
6212 |
// z[kdx+idx] = (jlong)product;
|
|
6213 |
// carry = (jlong)(product >>> 64);
|
|
6214 |
// }
|
|
6215 |
// idx += 2;
|
|
6216 |
// if (idx > 0) {
|
|
6217 |
// product = (y[idx] * x_xstart) + z[kdx+idx] + carry;
|
|
6218 |
// z[kdx+idx] = (jlong)product;
|
|
6219 |
// carry = (jlong)(product >>> 64);
|
|
6220 |
// }
|
|
6221 |
|
|
6222 |
Label L_third_loop, L_third_loop_exit, L_post_third_loop_done;
|
|
6223 |
|
|
6224 |
// scale the index
|
|
6225 |
lgr_if_needed(jdx, idx);
|
|
6226 |
and_imm(jdx, 0xfffffffffffffffcL);
|
|
6227 |
rshift(jdx, 2);
|
|
6228 |
|
|
6229 |
|
|
6230 |
bind(L_third_loop);
|
|
6231 |
|
|
6232 |
z_aghi(jdx, -1);
|
|
6233 |
z_brl(L_third_loop_exit);
|
|
6234 |
add2reg(idx, -4);
|
|
6235 |
|
|
6236 |
multiply_add_128_x_128(x_xstart, y, z, yz_idx, idx, carry, product, 8);
|
|
6237 |
lgr_if_needed(carry2, product);
|
|
6238 |
|
|
6239 |
multiply_add_128_x_128(x_xstart, y, z, yz_idx, idx, carry2, product, 0);
|
|
6240 |
lgr_if_needed(carry, product);
|
|
6241 |
z_bru(L_third_loop);
|
|
6242 |
|
|
6243 |
|
|
6244 |
bind(L_third_loop_exit); // Handle any left-over operand parts.
|
|
6245 |
|
|
6246 |
and_imm(idx, 0x3);
|
|
6247 |
z_brz(L_post_third_loop_done);
|
|
6248 |
|
|
6249 |
Label L_check_1;
|
|
6250 |
|
|
6251 |
z_aghi(idx, -2);
|
|
6252 |
z_brl(L_check_1);
|
|
6253 |
|
|
6254 |
multiply_add_128_x_128(x_xstart, y, z, yz_idx, idx, carry, product, 0);
|
|
6255 |
lgr_if_needed(carry, product);
|
|
6256 |
|
|
6257 |
|
|
6258 |
bind(L_check_1);
|
|
6259 |
|
|
6260 |
add2reg(idx, 0x2);
|
|
6261 |
and_imm(idx, 0x1);
|
|
6262 |
z_aghi(idx, -1);
|
|
6263 |
z_brl(L_post_third_loop_done);
|
|
6264 |
|
|
6265 |
Register multiplicand = product->successor();
|
|
6266 |
Register product_low = multiplicand;
|
|
6267 |
|
|
6268 |
z_sllg(Z_R7, idx, LogBytesPerInt);
|
|
6269 |
clear_reg(yz_idx);
|
|
6270 |
mem2reg_opt(yz_idx, Address(y, Z_R7, 0), false);
|
|
6271 |
lgr_if_needed(multiplicand, x_xstart);
|
|
6272 |
z_mlgr(product, yz_idx); // multiplicand * yz_idx -> product::multiplicand
|
|
6273 |
clear_reg(yz_idx);
|
|
6274 |
mem2reg_opt(yz_idx, Address(z, Z_R7, 0), false);
|
|
6275 |
|
|
6276 |
add2_with_carry(product, product_low, yz_idx, carry);
|
|
6277 |
|
|
6278 |
z_sllg(Z_R7, idx, LogBytesPerInt);
|
|
6279 |
reg2mem_opt(product_low, Address(z, Z_R7, 0), false);
|
|
6280 |
rshift(product_low, 32);
|
|
6281 |
|
|
6282 |
lshift(product, 32);
|
|
6283 |
z_ogr(product_low, product);
|
|
6284 |
lgr_if_needed(carry, product_low);
|
|
6285 |
|
|
6286 |
bind(L_post_third_loop_done);
|
|
6287 |
}
|
|
6288 |
|
|
6289 |
void MacroAssembler::multiply_to_len(Register x, Register xlen,
|
|
6290 |
Register y, Register ylen,
|
|
6291 |
Register z,
|
|
6292 |
Register tmp1, Register tmp2,
|
|
6293 |
Register tmp3, Register tmp4,
|
|
6294 |
Register tmp5) {
|
|
6295 |
ShortBranchVerifier sbv(this);
|
|
6296 |
|
|
6297 |
assert_different_registers(x, xlen, y, ylen, z,
|
|
6298 |
tmp1, tmp2, tmp3, tmp4, tmp5, Z_R1_scratch, Z_R7);
|
|
6299 |
assert_different_registers(x, xlen, y, ylen, z,
|
|
6300 |
tmp1, tmp2, tmp3, tmp4, tmp5, Z_R8);
|
|
6301 |
|
|
6302 |
z_stmg(Z_R7, Z_R13, _z_abi(gpr7), Z_SP);
|
|
6303 |
|
|
6304 |
// In openJdk, we store the argument as 32-bit value to slot.
|
|
6305 |
Address zlen(Z_SP, _z_abi(remaining_cargs)); // Int in long on big endian.
|
|
6306 |
|
|
6307 |
const Register idx = tmp1;
|
|
6308 |
const Register kdx = tmp2;
|
|
6309 |
const Register xstart = tmp3;
|
|
6310 |
|
|
6311 |
const Register y_idx = tmp4;
|
|
6312 |
const Register carry = tmp5;
|
|
6313 |
const Register product = Z_R0_scratch;
|
|
6314 |
const Register x_xstart = Z_R8;
|
|
6315 |
|
|
6316 |
// First Loop.
|
|
6317 |
//
|
|
6318 |
// final static long LONG_MASK = 0xffffffffL;
|
|
6319 |
// int xstart = xlen - 1;
|
|
6320 |
// int ystart = ylen - 1;
|
|
6321 |
// long carry = 0;
|
|
6322 |
// for (int idx=ystart, kdx=ystart+1+xstart; idx >= 0; idx-, kdx--) {
|
|
6323 |
// long product = (y[idx] & LONG_MASK) * (x[xstart] & LONG_MASK) + carry;
|
|
6324 |
// z[kdx] = (int)product;
|
|
6325 |
// carry = product >>> 32;
|
|
6326 |
// }
|
|
6327 |
// z[xstart] = (int)carry;
|
|
6328 |
//
|
|
6329 |
|
|
6330 |
lgr_if_needed(idx, ylen); // idx = ylen
|
|
6331 |
z_llgf(kdx, zlen); // C2 does not respect int to long conversion for stub calls, thus load zero-extended.
|
|
6332 |
clear_reg(carry); // carry = 0
|
|
6333 |
|
|
6334 |
Label L_done;
|
|
6335 |
|
|
6336 |
lgr_if_needed(xstart, xlen);
|
|
6337 |
z_aghi(xstart, -1);
|
|
6338 |
z_brl(L_done);
|
|
6339 |
|
|
6340 |
multiply_64_x_64_loop(x, xstart, x_xstart, y, y_idx, z, carry, product, idx, kdx);
|
|
6341 |
|
|
6342 |
NearLabel L_second_loop;
|
|
6343 |
compare64_and_branch(kdx, RegisterOrConstant((intptr_t) 0), bcondEqual, L_second_loop);
|
|
6344 |
|
|
6345 |
NearLabel L_carry;
|
|
6346 |
z_aghi(kdx, -1);
|
|
6347 |
z_brz(L_carry);
|
|
6348 |
|
|
6349 |
// Store lower 32 bits of carry.
|
|
6350 |
z_sllg(Z_R1_scratch, kdx, LogBytesPerInt);
|
|
6351 |
reg2mem_opt(carry, Address(z, Z_R1_scratch, 0), false);
|
|
6352 |
rshift(carry, 32);
|
|
6353 |
z_aghi(kdx, -1);
|
|
6354 |
|
|
6355 |
|
|
6356 |
bind(L_carry);
|
|
6357 |
|
|
6358 |
// Store upper 32 bits of carry.
|
|
6359 |
z_sllg(Z_R1_scratch, kdx, LogBytesPerInt);
|
|
6360 |
reg2mem_opt(carry, Address(z, Z_R1_scratch, 0), false);
|
|
6361 |
|
|
6362 |
// Second and third (nested) loops.
|
|
6363 |
//
|
|
6364 |
// for (int i = xstart-1; i >= 0; i--) { // Second loop
|
|
6365 |
// carry = 0;
|
|
6366 |
// for (int jdx=ystart, k=ystart+1+i; jdx >= 0; jdx--, k--) { // Third loop
|
|
6367 |
// long product = (y[jdx] & LONG_MASK) * (x[i] & LONG_MASK) +
|
|
6368 |
// (z[k] & LONG_MASK) + carry;
|
|
6369 |
// z[k] = (int)product;
|
|
6370 |
// carry = product >>> 32;
|
|
6371 |
// }
|
|
6372 |
// z[i] = (int)carry;
|
|
6373 |
// }
|
|
6374 |
//
|
|
6375 |
// i = xlen, j = tmp1, k = tmp2, carry = tmp5, x[i] = rdx
|
|
6376 |
|
|
6377 |
const Register jdx = tmp1;
|
|
6378 |
|
|
6379 |
bind(L_second_loop);
|
|
6380 |
|
|
6381 |
clear_reg(carry); // carry = 0;
|
|
6382 |
lgr_if_needed(jdx, ylen); // j = ystart+1
|
|
6383 |
|
|
6384 |
z_aghi(xstart, -1); // i = xstart-1;
|
|
6385 |
z_brl(L_done);
|
|
6386 |
|
|
6387 |
// Use free slots in the current stackframe instead of push/pop.
|
|
6388 |
Address zsave(Z_SP, _z_abi(carg_1));
|
|
6389 |
reg2mem_opt(z, zsave);
|
|
6390 |
|
|
6391 |
|
|
6392 |
Label L_last_x;
|
|
6393 |
|
|
6394 |
z_sllg(Z_R1_scratch, xstart, LogBytesPerInt);
|
|
6395 |
load_address(z, Address(z, Z_R1_scratch, 4)); // z = z + k - j
|
|
6396 |
z_aghi(xstart, -1); // i = xstart-1;
|
|
6397 |
z_brl(L_last_x);
|
|
6398 |
|
|
6399 |
z_sllg(Z_R1_scratch, xstart, LogBytesPerInt);
|
|
6400 |
mem2reg_opt(x_xstart, Address(x, Z_R1_scratch, 0));
|
|
6401 |
|
|
6402 |
|
|
6403 |
Label L_third_loop_prologue;
|
|
6404 |
|
|
6405 |
bind(L_third_loop_prologue);
|
|
6406 |
|
|
6407 |
Address xsave(Z_SP, _z_abi(carg_2));
|
|
6408 |
Address xlensave(Z_SP, _z_abi(carg_3));
|
|
6409 |
Address ylensave(Z_SP, _z_abi(carg_4));
|
|
6410 |
|
|
6411 |
reg2mem_opt(x, xsave);
|
|
6412 |
reg2mem_opt(xstart, xlensave);
|
|
6413 |
reg2mem_opt(ylen, ylensave);
|
|
6414 |
|
|
6415 |
|
|
6416 |
multiply_128_x_128_loop(x_xstart, y, z, y_idx, jdx, ylen, carry, product, x);
|
|
6417 |
|
|
6418 |
mem2reg_opt(z, zsave);
|
|
6419 |
mem2reg_opt(x, xsave);
|
|
6420 |
mem2reg_opt(xlen, xlensave); // This is the decrement of the loop counter!
|
|
6421 |
mem2reg_opt(ylen, ylensave);
|
|
6422 |
|
|
6423 |
add2reg(tmp3, 1, xlen);
|
|
6424 |
z_sllg(Z_R1_scratch, tmp3, LogBytesPerInt);
|
|
6425 |
reg2mem_opt(carry, Address(z, Z_R1_scratch, 0), false);
|
|
6426 |
z_aghi(tmp3, -1);
|
|
6427 |
z_brl(L_done);
|
|
6428 |
|
|
6429 |
rshift(carry, 32);
|
|
6430 |
z_sllg(Z_R1_scratch, tmp3, LogBytesPerInt);
|
|
6431 |
reg2mem_opt(carry, Address(z, Z_R1_scratch, 0), false);
|
|
6432 |
z_bru(L_second_loop);
|
|
6433 |
|
|
6434 |
// Next infrequent code is moved outside loops.
|
|
6435 |
bind(L_last_x);
|
|
6436 |
|
|
6437 |
clear_reg(x_xstart);
|
|
6438 |
mem2reg_opt(x_xstart, Address(x, (intptr_t) 0), false);
|
|
6439 |
z_bru(L_third_loop_prologue);
|
|
6440 |
|
|
6441 |
bind(L_done);
|
|
6442 |
|
|
6443 |
z_lmg(Z_R7, Z_R13, _z_abi(gpr7), Z_SP);
|
|
6444 |
}
|
|
6445 |
|
|
6446 |
#ifndef PRODUCT
|
|
6447 |
// Assert if CC indicates "not equal" (check_equal==true) or "equal" (check_equal==false).
|
|
6448 |
void MacroAssembler::asm_assert(bool check_equal, const char *msg, int id) {
|
|
6449 |
Label ok;
|
|
6450 |
if (check_equal) {
|
|
6451 |
z_bre(ok);
|
|
6452 |
} else {
|
|
6453 |
z_brne(ok);
|
|
6454 |
}
|
|
6455 |
stop(msg, id);
|
|
6456 |
bind(ok);
|
|
6457 |
}
|
|
6458 |
|
|
6459 |
// Assert if CC indicates "low".
|
|
6460 |
void MacroAssembler::asm_assert_low(const char *msg, int id) {
|
|
6461 |
Label ok;
|
|
6462 |
z_brnl(ok);
|
|
6463 |
stop(msg, id);
|
|
6464 |
bind(ok);
|
|
6465 |
}
|
|
6466 |
|
|
6467 |
// Assert if CC indicates "high".
|
|
6468 |
void MacroAssembler::asm_assert_high(const char *msg, int id) {
|
|
6469 |
Label ok;
|
|
6470 |
z_brnh(ok);
|
|
6471 |
stop(msg, id);
|
|
6472 |
bind(ok);
|
|
6473 |
}
|
|
6474 |
|
|
6475 |
// Assert if CC indicates "not equal" (check_equal==true) or "equal" (check_equal==false)
|
|
6476 |
// generate non-relocatable code.
|
|
6477 |
void MacroAssembler::asm_assert_static(bool check_equal, const char *msg, int id) {
|
|
6478 |
Label ok;
|
|
6479 |
if (check_equal) { z_bre(ok); }
|
|
6480 |
else { z_brne(ok); }
|
|
6481 |
stop_static(msg, id);
|
|
6482 |
bind(ok);
|
|
6483 |
}
|
|
6484 |
|
|
6485 |
void MacroAssembler::asm_assert_mems_zero(bool check_equal, bool allow_relocation, int size, int64_t mem_offset,
|
|
6486 |
Register mem_base, const char* msg, int id) {
|
|
6487 |
switch (size) {
|
|
6488 |
case 4:
|
|
6489 |
load_and_test_int(Z_R0, Address(mem_base, mem_offset));
|
|
6490 |
break;
|
|
6491 |
case 8:
|
|
6492 |
load_and_test_long(Z_R0, Address(mem_base, mem_offset));
|
|
6493 |
break;
|
|
6494 |
default:
|
|
6495 |
ShouldNotReachHere();
|
|
6496 |
}
|
|
6497 |
if (allow_relocation) { asm_assert(check_equal, msg, id); }
|
|
6498 |
else { asm_assert_static(check_equal, msg, id); }
|
|
6499 |
}
|
|
6500 |
|
|
6501 |
// Check the condition
|
|
6502 |
// expected_size == FP - SP
|
|
6503 |
// after transformation:
|
|
6504 |
// expected_size - FP + SP == 0
|
|
6505 |
// Destroys Register expected_size if no tmp register is passed.
|
|
6506 |
void MacroAssembler::asm_assert_frame_size(Register expected_size, Register tmp, const char* msg, int id) {
|
|
6507 |
if (tmp == noreg) {
|
|
6508 |
tmp = expected_size;
|
|
6509 |
} else {
|
|
6510 |
if (tmp != expected_size) {
|
|
6511 |
z_lgr(tmp, expected_size);
|
|
6512 |
}
|
|
6513 |
z_algr(tmp, Z_SP);
|
|
6514 |
z_slg(tmp, 0, Z_R0, Z_SP);
|
|
6515 |
asm_assert_eq(msg, id);
|
|
6516 |
}
|
|
6517 |
}
|
|
6518 |
#endif // !PRODUCT
|
|
6519 |
|
|
6520 |
void MacroAssembler::verify_thread() {
|
|
6521 |
if (VerifyThread) {
|
|
6522 |
unimplemented("", 117);
|
|
6523 |
}
|
|
6524 |
}
|
|
6525 |
|
|
6526 |
// Plausibility check for oops.
|
|
6527 |
void MacroAssembler::verify_oop(Register oop, const char* msg) {
|
|
6528 |
if (!VerifyOops) return;
|
|
6529 |
|
|
6530 |
BLOCK_COMMENT("verify_oop {");
|
|
6531 |
Register tmp = Z_R0;
|
|
6532 |
unsigned int nbytes_save = 6 *8;
|
|
6533 |
address entry = StubRoutines::verify_oop_subroutine_entry_address();
|
|
6534 |
save_return_pc();
|
|
6535 |
push_frame_abi160(nbytes_save);
|
|
6536 |
z_stmg(Z_R0, Z_R5, 160, Z_SP);
|
|
6537 |
|
|
6538 |
z_lgr(Z_ARG2, oop);
|
|
6539 |
load_const(Z_ARG1, (address) msg);
|
|
6540 |
load_const(Z_R1, entry);
|
|
6541 |
z_lg(Z_R1, 0, Z_R1);
|
|
6542 |
call_c(Z_R1);
|
|
6543 |
|
|
6544 |
z_lmg(Z_R0, Z_R5, 160, Z_SP);
|
|
6545 |
pop_frame();
|
|
6546 |
|
|
6547 |
restore_return_pc();
|
|
6548 |
BLOCK_COMMENT("} verify_oop ");
|
|
6549 |
}
|
|
6550 |
|
|
6551 |
const char* MacroAssembler::stop_types[] = {
|
|
6552 |
"stop",
|
|
6553 |
"untested",
|
|
6554 |
"unimplemented",
|
|
6555 |
"shouldnotreachhere"
|
|
6556 |
};
|
|
6557 |
|
|
6558 |
static void stop_on_request(const char* tp, const char* msg) {
|
|
6559 |
tty->print("Z assembly code requires stop: (%s) %s\n", tp, msg);
|
|
6560 |
guarantee(false, "Z assembly code requires stop: %s", msg);
|
|
6561 |
}
|
|
6562 |
|
|
6563 |
void MacroAssembler::stop(int type, const char* msg, int id) {
|
|
6564 |
BLOCK_COMMENT(err_msg("stop: %s {", msg));
|
|
6565 |
|
|
6566 |
// Setup arguments.
|
|
6567 |
load_const(Z_ARG1, (void*) stop_types[type%stop_end]);
|
|
6568 |
load_const(Z_ARG2, (void*) msg);
|
|
6569 |
get_PC(Z_R14); // Following code pushes a frame without entering a new function. Use current pc as return address.
|
|
6570 |
save_return_pc(); // Saves return pc Z_R14.
|
|
6571 |
push_frame_abi160(0);
|
|
6572 |
call_VM_leaf(CAST_FROM_FN_PTR(address, stop_on_request), Z_ARG1, Z_ARG2);
|
|
6573 |
// The plain disassembler does not recognize illtrap. It instead displays
|
|
6574 |
// a 32-bit value. Issueing two illtraps assures the disassembler finds
|
|
6575 |
// the proper beginning of the next instruction.
|
|
6576 |
z_illtrap(); // Illegal instruction.
|
|
6577 |
z_illtrap(); // Illegal instruction.
|
|
6578 |
|
|
6579 |
BLOCK_COMMENT(" } stop");
|
|
6580 |
}
|
|
6581 |
|
|
6582 |
// Special version of stop() for code size reduction.
|
|
6583 |
// Reuses the previously generated call sequence, if any.
|
|
6584 |
// Generates the call sequence on its own, if necessary.
|
|
6585 |
// Note: This code will work only in non-relocatable code!
|
|
6586 |
// The relative address of the data elements (arg1, arg2) must not change.
|
|
6587 |
// The reentry point must not move relative to it's users. This prerequisite
|
|
6588 |
// should be given for "hand-written" code, if all chain calls are in the same code blob.
|
|
6589 |
// Generated code must not undergo any transformation, e.g. ShortenBranches, to be safe.
|
|
6590 |
address MacroAssembler::stop_chain(address reentry, int type, const char* msg, int id, bool allow_relocation) {
|
|
6591 |
BLOCK_COMMENT(err_msg("stop_chain(%s,%s): %s {", reentry==NULL?"init":"cont", allow_relocation?"reloc ":"static", msg));
|
|
6592 |
|
|
6593 |
// Setup arguments.
|
|
6594 |
if (allow_relocation) {
|
|
6595 |
// Relocatable version (for comparison purposes). Remove after some time.
|
|
6596 |
load_const(Z_ARG1, (void*) stop_types[type%stop_end]);
|
|
6597 |
load_const(Z_ARG2, (void*) msg);
|
|
6598 |
} else {
|
|
6599 |
load_absolute_address(Z_ARG1, (address)stop_types[type%stop_end]);
|
|
6600 |
load_absolute_address(Z_ARG2, (address)msg);
|
|
6601 |
}
|
|
6602 |
if ((reentry != NULL) && RelAddr::is_in_range_of_RelAddr16(reentry, pc())) {
|
|
6603 |
BLOCK_COMMENT("branch to reentry point:");
|
|
6604 |
z_brc(bcondAlways, reentry);
|
|
6605 |
} else {
|
|
6606 |
BLOCK_COMMENT("reentry point:");
|
|
6607 |
reentry = pc(); // Re-entry point for subsequent stop calls.
|
|
6608 |
save_return_pc(); // Saves return pc Z_R14.
|
|
6609 |
push_frame_abi160(0);
|
|
6610 |
if (allow_relocation) {
|
|
6611 |
reentry = NULL; // Prevent reentry if code relocation is allowed.
|
|
6612 |
call_VM_leaf(CAST_FROM_FN_PTR(address, stop_on_request), Z_ARG1, Z_ARG2);
|
|
6613 |
} else {
|
|
6614 |
call_VM_leaf_static(CAST_FROM_FN_PTR(address, stop_on_request), Z_ARG1, Z_ARG2);
|
|
6615 |
}
|
|
6616 |
z_illtrap(); // Illegal instruction as emergency stop, should the above call return.
|
|
6617 |
}
|
|
6618 |
BLOCK_COMMENT(" } stop_chain");
|
|
6619 |
|
|
6620 |
return reentry;
|
|
6621 |
}
|
|
6622 |
|
|
6623 |
// Special version of stop() for code size reduction.
|
|
6624 |
// Assumes constant relative addresses for data and runtime call.
|
|
6625 |
void MacroAssembler::stop_static(int type, const char* msg, int id) {
|
|
6626 |
stop_chain(NULL, type, msg, id, false);
|
|
6627 |
}
|
|
6628 |
|
|
6629 |
void MacroAssembler::stop_subroutine() {
|
|
6630 |
unimplemented("stop_subroutine", 710);
|
|
6631 |
}
|
|
6632 |
|
|
6633 |
// Prints msg to stdout from within generated code..
|
|
6634 |
void MacroAssembler::warn(const char* msg) {
|
|
6635 |
RegisterSaver::save_live_registers(this, RegisterSaver::all_registers, Z_R14);
|
|
6636 |
load_absolute_address(Z_R1, (address) warning);
|
|
6637 |
load_absolute_address(Z_ARG1, (address) msg);
|
|
6638 |
(void) call(Z_R1);
|
|
6639 |
RegisterSaver::restore_live_registers(this, RegisterSaver::all_registers);
|
|
6640 |
}
|
|
6641 |
|
|
6642 |
#ifndef PRODUCT
|
|
6643 |
|
|
6644 |
// Write pattern 0x0101010101010101 in region [low-before, high+after].
|
|
6645 |
void MacroAssembler::zap_from_to(Register low, Register high, Register val, Register addr, int before, int after) {
|
|
6646 |
if (!ZapEmptyStackFields) return;
|
|
6647 |
BLOCK_COMMENT("zap memory region {");
|
|
6648 |
load_const_optimized(val, 0x0101010101010101);
|
|
6649 |
int size = before + after;
|
|
6650 |
if (low == high && size < 5 && size > 0) {
|
|
6651 |
int offset = -before*BytesPerWord;
|
|
6652 |
for (int i = 0; i < size; ++i) {
|
|
6653 |
z_stg(val, Address(low, offset));
|
|
6654 |
offset +=(1*BytesPerWord);
|
|
6655 |
}
|
|
6656 |
} else {
|
|
6657 |
add2reg(addr, -before*BytesPerWord, low);
|
|
6658 |
if (after) {
|
|
6659 |
#ifdef ASSERT
|
|
6660 |
jlong check = after * BytesPerWord;
|
|
6661 |
assert(Immediate::is_simm32(check) && Immediate::is_simm32(-check), "value not encodable !");
|
|
6662 |
#endif
|
|
6663 |
add2reg(high, after * BytesPerWord);
|
|
6664 |
}
|
|
6665 |
NearLabel loop;
|
|
6666 |
bind(loop);
|
|
6667 |
z_stg(val, Address(addr));
|
|
6668 |
add2reg(addr, 8);
|
|
6669 |
compare64_and_branch(addr, high, bcondNotHigh, loop);
|
|
6670 |
if (after) {
|
|
6671 |
add2reg(high, -after * BytesPerWord);
|
|
6672 |
}
|
|
6673 |
}
|
|
6674 |
BLOCK_COMMENT("} zap memory region");
|
|
6675 |
}
|
|
6676 |
#endif // !PRODUCT
|
|
6677 |
|
|
6678 |
SkipIfEqual::SkipIfEqual(MacroAssembler* masm, const bool* flag_addr, bool value, Register _rscratch) {
|
|
6679 |
_masm = masm;
|
|
6680 |
_masm->load_absolute_address(_rscratch, (address)flag_addr);
|
|
6681 |
_masm->load_and_test_int(_rscratch, Address(_rscratch));
|
|
6682 |
if (value) {
|
|
6683 |
_masm->z_brne(_label); // Skip if true, i.e. != 0.
|
|
6684 |
} else {
|
|
6685 |
_masm->z_bre(_label); // Skip if false, i.e. == 0.
|
|
6686 |
}
|
|
6687 |
}
|
|
6688 |
|
|
6689 |
SkipIfEqual::~SkipIfEqual() {
|
|
6690 |
_masm->bind(_label);
|
|
6691 |
}
|