| /* |
| * Copyright (c) 2013, 2015, Oracle and/or its affiliates. All rights reserved. |
| * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. |
| * |
| * This code is free software; you can redistribute it and/or modify it |
| * under the terms of the GNU General Public License version 2 only, as |
| * published by the Free Software Foundation. |
| * |
| * This code is distributed in the hope that it will be useful, but WITHOUT |
| * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or |
| * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License |
| * version 2 for more details (a copy is included in the LICENSE file that |
| * accompanied this code). |
| * |
| * You should have received a copy of the GNU General Public License version |
| * 2 along with this work; if not, write to the Free Software Foundation, |
| * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. |
| * |
| * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
| * or visit www.oracle.com if you need additional information or have any |
| * questions. |
| */ |
| package org.graalvm.compiler.lir.amd64; |
| |
| import static org.graalvm.compiler.lir.LIRInstruction.OperandFlag.ILLEGAL; |
| import static org.graalvm.compiler.lir.LIRInstruction.OperandFlag.REG; |
| import static jdk.vm.ci.code.ValueUtil.asRegister; |
| |
| import java.lang.reflect.Array; |
| import java.lang.reflect.Field; |
| |
| import org.graalvm.compiler.asm.Label; |
| import org.graalvm.compiler.asm.amd64.AMD64Address; |
| import org.graalvm.compiler.asm.amd64.AMD64Address.Scale; |
| import org.graalvm.compiler.asm.amd64.AMD64Assembler.ConditionFlag; |
| import org.graalvm.compiler.asm.amd64.AMD64Assembler.OperandSize; |
| import org.graalvm.compiler.asm.amd64.AMD64Assembler.SSEOp; |
| import org.graalvm.compiler.asm.amd64.AMD64MacroAssembler; |
| import org.graalvm.compiler.core.common.LIRKind; |
| import org.graalvm.compiler.lir.LIRInstructionClass; |
| import org.graalvm.compiler.lir.Opcode; |
| import org.graalvm.compiler.lir.asm.CompilationResultBuilder; |
| import org.graalvm.compiler.lir.gen.LIRGeneratorTool; |
| |
| import jdk.vm.ci.amd64.AMD64; |
| import jdk.vm.ci.amd64.AMD64.CPUFeature; |
| import jdk.vm.ci.amd64.AMD64Kind; |
| import jdk.vm.ci.code.Register; |
| import jdk.vm.ci.code.TargetDescription; |
| import jdk.vm.ci.meta.JavaKind; |
| import jdk.vm.ci.meta.Value; |
| import sun.misc.Unsafe; |
| |
| /** |
| * Emits code which compares two arrays of the same length. If the CPU supports any vector |
| * instructions specialized code is emitted to leverage these instructions. |
| */ |
| @Opcode("ARRAY_EQUALS") |
| public final class AMD64ArrayEqualsOp extends AMD64LIRInstruction { |
| public static final LIRInstructionClass<AMD64ArrayEqualsOp> TYPE = LIRInstructionClass.create(AMD64ArrayEqualsOp.class); |
| |
| private final JavaKind kind; |
| private final int arrayBaseOffset; |
| private final int arrayIndexScale; |
| |
| @Def({REG}) protected Value resultValue; |
| @Alive({REG}) protected Value array1Value; |
| @Alive({REG}) protected Value array2Value; |
| @Alive({REG}) protected Value lengthValue; |
| @Temp({REG}) protected Value temp1; |
| @Temp({REG}) protected Value temp2; |
| @Temp({REG}) protected Value temp3; |
| @Temp({REG}) protected Value temp4; |
| |
| @Temp({REG, ILLEGAL}) protected Value temp5; |
| @Temp({REG, ILLEGAL}) protected Value tempXMM; |
| |
| @Temp({REG, ILLEGAL}) protected Value vectorTemp1; |
| @Temp({REG, ILLEGAL}) protected Value vectorTemp2; |
| |
| public AMD64ArrayEqualsOp(LIRGeneratorTool tool, JavaKind kind, Value result, Value array1, Value array2, Value length) { |
| super(TYPE); |
| this.kind = kind; |
| |
| Class<?> arrayClass = Array.newInstance(kind.toJavaClass(), 0).getClass(); |
| this.arrayBaseOffset = UNSAFE.arrayBaseOffset(arrayClass); |
| this.arrayIndexScale = UNSAFE.arrayIndexScale(arrayClass); |
| |
| this.resultValue = result; |
| this.array1Value = array1; |
| this.array2Value = array2; |
| this.lengthValue = length; |
| |
| // Allocate some temporaries. |
| this.temp1 = tool.newVariable(LIRKind.unknownReference(tool.target().arch.getWordKind())); |
| this.temp2 = tool.newVariable(LIRKind.unknownReference(tool.target().arch.getWordKind())); |
| this.temp3 = tool.newVariable(LIRKind.value(tool.target().arch.getWordKind())); |
| this.temp4 = tool.newVariable(LIRKind.value(tool.target().arch.getWordKind())); |
| |
| this.temp5 = kind.isNumericFloat() ? tool.newVariable(LIRKind.value(tool.target().arch.getWordKind())) : Value.ILLEGAL; |
| if (kind == JavaKind.Float) { |
| this.tempXMM = tool.newVariable(LIRKind.value(AMD64Kind.SINGLE)); |
| } else if (kind == JavaKind.Double) { |
| this.tempXMM = tool.newVariable(LIRKind.value(AMD64Kind.DOUBLE)); |
| } else { |
| this.tempXMM = Value.ILLEGAL; |
| } |
| |
| // We only need the vector temporaries if we generate SSE code. |
| if (supportsSSE41(tool.target())) { |
| this.vectorTemp1 = tool.newVariable(LIRKind.value(AMD64Kind.DOUBLE)); |
| this.vectorTemp2 = tool.newVariable(LIRKind.value(AMD64Kind.DOUBLE)); |
| } else { |
| this.vectorTemp1 = Value.ILLEGAL; |
| this.vectorTemp2 = Value.ILLEGAL; |
| } |
| } |
| |
| @Override |
| public void emitCode(CompilationResultBuilder crb, AMD64MacroAssembler masm) { |
| Register result = asRegister(resultValue); |
| Register array1 = asRegister(temp1); |
| Register array2 = asRegister(temp2); |
| Register length = asRegister(temp3); |
| |
| Label trueLabel = new Label(); |
| Label falseLabel = new Label(); |
| Label done = new Label(); |
| |
| // Load array base addresses. |
| masm.leaq(array1, new AMD64Address(asRegister(array1Value), arrayBaseOffset)); |
| masm.leaq(array2, new AMD64Address(asRegister(array2Value), arrayBaseOffset)); |
| |
| // Get array length in bytes. |
| masm.imull(length, asRegister(lengthValue), arrayIndexScale); |
| masm.movl(result, length); // copy |
| |
| if (supportsAVX2(crb.target)) { |
| emitAVXCompare(crb, masm, result, array1, array2, length, trueLabel, falseLabel); |
| } else if (supportsSSE41(crb.target)) { |
| emitSSE41Compare(crb, masm, result, array1, array2, length, trueLabel, falseLabel); |
| } |
| |
| emit8ByteCompare(crb, masm, result, array1, array2, length, trueLabel, falseLabel); |
| emitTailCompares(masm, result, array1, array2, length, trueLabel, falseLabel); |
| |
| // Return true |
| masm.bind(trueLabel); |
| masm.movl(result, 1); |
| masm.jmpb(done); |
| |
| // Return false |
| masm.bind(falseLabel); |
| masm.xorl(result, result); |
| |
| // That's it |
| masm.bind(done); |
| } |
| |
| /** |
| * Returns if the underlying AMD64 architecture supports SSE 4.1 instructions. |
| * |
| * @param target target description of the underlying architecture |
| * @return true if the underlying architecture supports SSE 4.1 |
| */ |
| private static boolean supportsSSE41(TargetDescription target) { |
| AMD64 arch = (AMD64) target.arch; |
| return arch.getFeatures().contains(CPUFeature.SSE4_1); |
| } |
| |
| /** |
| * Vector size used in {@link #emitSSE41Compare}. |
| */ |
| private static final int SSE4_1_VECTOR_SIZE = 16; |
| |
| /** |
| * Emits code that uses SSE4.1 128-bit (16-byte) vector compares. |
| */ |
| private void emitSSE41Compare(CompilationResultBuilder crb, AMD64MacroAssembler masm, Register result, Register array1, Register array2, Register length, Label trueLabel, Label falseLabel) { |
| assert supportsSSE41(crb.target); |
| |
| Register vector1 = asRegister(vectorTemp1, AMD64Kind.DOUBLE); |
| Register vector2 = asRegister(vectorTemp2, AMD64Kind.DOUBLE); |
| |
| Label loop = new Label(); |
| Label compareTail = new Label(); |
| |
| boolean requiresNaNCheck = kind.isNumericFloat(); |
| Label loopCheck = new Label(); |
| Label nanCheck = new Label(); |
| |
| // Compare 16-byte vectors |
| masm.andl(result, SSE4_1_VECTOR_SIZE - 1); // tail count (in bytes) |
| masm.andl(length, ~(SSE4_1_VECTOR_SIZE - 1)); // vector count (in bytes) |
| masm.jcc(ConditionFlag.Zero, compareTail); |
| |
| masm.leaq(array1, new AMD64Address(array1, length, Scale.Times1, 0)); |
| masm.leaq(array2, new AMD64Address(array2, length, Scale.Times1, 0)); |
| masm.negq(length); |
| |
| // Align the main loop |
| masm.align(crb.target.wordSize * 2); |
| masm.bind(loop); |
| masm.movdqu(vector1, new AMD64Address(array1, length, Scale.Times1, 0)); |
| masm.movdqu(vector2, new AMD64Address(array2, length, Scale.Times1, 0)); |
| masm.pxor(vector1, vector2); |
| masm.ptest(vector1, vector1); |
| masm.jcc(ConditionFlag.NotZero, requiresNaNCheck ? nanCheck : falseLabel); |
| |
| masm.bind(loopCheck); |
| masm.addq(length, SSE4_1_VECTOR_SIZE); |
| masm.jcc(ConditionFlag.NotZero, loop); |
| |
| masm.testl(result, result); |
| masm.jcc(ConditionFlag.Zero, trueLabel); |
| |
| if (requiresNaNCheck) { |
| Label unalignedCheck = new Label(); |
| masm.jmpb(unalignedCheck); |
| masm.bind(nanCheck); |
| emitFloatCompareWithinRange(crb, masm, array1, array2, length, 0, falseLabel, SSE4_1_VECTOR_SIZE); |
| masm.jmpb(loopCheck); |
| masm.bind(unalignedCheck); |
| } |
| |
| /* |
| * Compare the remaining bytes with an unaligned memory load aligned to the end of the |
| * array. |
| */ |
| masm.movdqu(vector1, new AMD64Address(array1, result, Scale.Times1, -SSE4_1_VECTOR_SIZE)); |
| masm.movdqu(vector2, new AMD64Address(array2, result, Scale.Times1, -SSE4_1_VECTOR_SIZE)); |
| masm.pxor(vector1, vector2); |
| masm.ptest(vector1, vector1); |
| if (requiresNaNCheck) { |
| masm.jcc(ConditionFlag.Zero, trueLabel); |
| emitFloatCompareWithinRange(crb, masm, array1, array2, result, -SSE4_1_VECTOR_SIZE, falseLabel, SSE4_1_VECTOR_SIZE); |
| } else { |
| masm.jcc(ConditionFlag.NotZero, falseLabel); |
| } |
| masm.jmp(trueLabel); |
| |
| masm.bind(compareTail); |
| masm.movl(length, result); |
| } |
| |
| /** |
| * Returns if the underlying AMD64 architecture supports AVX instructions. |
| * |
| * @param target target description of the underlying architecture |
| * @return true if the underlying architecture supports AVX |
| */ |
| private static boolean supportsAVX2(TargetDescription target) { |
| AMD64 arch = (AMD64) target.arch; |
| return arch.getFeatures().contains(CPUFeature.AVX2); |
| } |
| |
| /** |
| * Vector size used in {@link #emitAVXCompare}. |
| */ |
| private static final int AVX_VECTOR_SIZE = 32; |
| |
| private void emitAVXCompare(CompilationResultBuilder crb, AMD64MacroAssembler masm, Register result, Register array1, Register array2, Register length, Label trueLabel, Label falseLabel) { |
| assert supportsAVX2(crb.target); |
| |
| Register vector1 = asRegister(vectorTemp1, AMD64Kind.DOUBLE); |
| Register vector2 = asRegister(vectorTemp2, AMD64Kind.DOUBLE); |
| |
| Label loop = new Label(); |
| Label compareTail = new Label(); |
| |
| boolean requiresNaNCheck = kind.isNumericFloat(); |
| Label loopCheck = new Label(); |
| Label nanCheck = new Label(); |
| |
| // Compare 16-byte vectors |
| masm.andl(result, AVX_VECTOR_SIZE - 1); // tail count (in bytes) |
| masm.andl(length, ~(AVX_VECTOR_SIZE - 1)); // vector count (in bytes) |
| masm.jcc(ConditionFlag.Zero, compareTail); |
| |
| masm.leaq(array1, new AMD64Address(array1, length, Scale.Times1, 0)); |
| masm.leaq(array2, new AMD64Address(array2, length, Scale.Times1, 0)); |
| masm.negq(length); |
| |
| // Align the main loop |
| masm.align(crb.target.wordSize * 2); |
| masm.bind(loop); |
| masm.vmovdqu(vector1, new AMD64Address(array1, length, Scale.Times1, 0)); |
| masm.vmovdqu(vector2, new AMD64Address(array2, length, Scale.Times1, 0)); |
| masm.vpxor(vector1, vector1, vector2); |
| masm.vptest(vector1, vector1); |
| masm.jcc(ConditionFlag.NotZero, requiresNaNCheck ? nanCheck : falseLabel); |
| |
| masm.bind(loopCheck); |
| masm.addq(length, AVX_VECTOR_SIZE); |
| masm.jcc(ConditionFlag.NotZero, loop); |
| |
| masm.testl(result, result); |
| masm.jcc(ConditionFlag.Zero, trueLabel); |
| |
| if (requiresNaNCheck) { |
| Label unalignedCheck = new Label(); |
| masm.jmpb(unalignedCheck); |
| masm.bind(nanCheck); |
| emitFloatCompareWithinRange(crb, masm, array1, array2, length, 0, falseLabel, AVX_VECTOR_SIZE); |
| masm.jmpb(loopCheck); |
| masm.bind(unalignedCheck); |
| } |
| |
| /* |
| * Compare the remaining bytes with an unaligned memory load aligned to the end of the |
| * array. |
| */ |
| masm.vmovdqu(vector1, new AMD64Address(array1, result, Scale.Times1, -AVX_VECTOR_SIZE)); |
| masm.vmovdqu(vector2, new AMD64Address(array2, result, Scale.Times1, -AVX_VECTOR_SIZE)); |
| masm.vpxor(vector1, vector1, vector2); |
| masm.vptest(vector1, vector1); |
| if (requiresNaNCheck) { |
| masm.jcc(ConditionFlag.Zero, trueLabel); |
| emitFloatCompareWithinRange(crb, masm, array1, array2, result, -AVX_VECTOR_SIZE, falseLabel, AVX_VECTOR_SIZE); |
| } else { |
| masm.jcc(ConditionFlag.NotZero, falseLabel); |
| } |
| masm.jmp(trueLabel); |
| |
| masm.bind(compareTail); |
| masm.movl(length, result); |
| } |
| |
| /** |
| * Vector size used in {@link #emit8ByteCompare}. |
| */ |
| private static final int VECTOR_SIZE = 8; |
| |
| /** |
| * Emits code that uses 8-byte vector compares. |
| */ |
| private void emit8ByteCompare(CompilationResultBuilder crb, AMD64MacroAssembler masm, Register result, Register array1, Register array2, Register length, Label trueLabel, Label falseLabel) { |
| Label loop = new Label(); |
| Label compareTail = new Label(); |
| |
| boolean requiresNaNCheck = kind.isNumericFloat(); |
| Label loopCheck = new Label(); |
| Label nanCheck = new Label(); |
| |
| Register temp = asRegister(temp4); |
| |
| masm.andl(result, VECTOR_SIZE - 1); // tail count (in bytes) |
| masm.andl(length, ~(VECTOR_SIZE - 1)); // vector count (in bytes) |
| masm.jcc(ConditionFlag.Zero, compareTail); |
| |
| masm.leaq(array1, new AMD64Address(array1, length, Scale.Times1, 0)); |
| masm.leaq(array2, new AMD64Address(array2, length, Scale.Times1, 0)); |
| masm.negq(length); |
| |
| // Align the main loop |
| masm.align(crb.target.wordSize * 2); |
| masm.bind(loop); |
| masm.movq(temp, new AMD64Address(array1, length, Scale.Times1, 0)); |
| masm.cmpq(temp, new AMD64Address(array2, length, Scale.Times1, 0)); |
| masm.jcc(ConditionFlag.NotEqual, requiresNaNCheck ? nanCheck : falseLabel); |
| |
| masm.bind(loopCheck); |
| masm.addq(length, VECTOR_SIZE); |
| masm.jccb(ConditionFlag.NotZero, loop); |
| |
| masm.testl(result, result); |
| masm.jcc(ConditionFlag.Zero, trueLabel); |
| |
| if (requiresNaNCheck) { |
| // NaN check is slow path and hence placed outside of the main loop. |
| Label unalignedCheck = new Label(); |
| masm.jmpb(unalignedCheck); |
| masm.bind(nanCheck); |
| // At most two iterations, unroll in the emitted code. |
| for (int offset = 0; offset < VECTOR_SIZE; offset += kind.getByteCount()) { |
| emitFloatCompare(masm, array1, array2, length, offset, falseLabel, kind.getByteCount() == VECTOR_SIZE); |
| } |
| masm.jmpb(loopCheck); |
| masm.bind(unalignedCheck); |
| } |
| |
| /* |
| * Compare the remaining bytes with an unaligned memory load aligned to the end of the |
| * array. |
| */ |
| masm.movq(temp, new AMD64Address(array1, result, Scale.Times1, -VECTOR_SIZE)); |
| masm.cmpq(temp, new AMD64Address(array2, result, Scale.Times1, -VECTOR_SIZE)); |
| if (requiresNaNCheck) { |
| masm.jcc(ConditionFlag.Equal, trueLabel); |
| // At most two iterations, unroll in the emitted code. |
| for (int offset = 0; offset < VECTOR_SIZE; offset += kind.getByteCount()) { |
| emitFloatCompare(masm, array1, array2, result, -VECTOR_SIZE + offset, falseLabel, kind.getByteCount() == VECTOR_SIZE); |
| } |
| } else { |
| masm.jccb(ConditionFlag.NotEqual, falseLabel); |
| } |
| masm.jmpb(trueLabel); |
| |
| masm.bind(compareTail); |
| masm.movl(length, result); |
| } |
| |
| /** |
| * Emits code to compare the remaining 1 to 4 bytes. |
| */ |
| private void emitTailCompares(AMD64MacroAssembler masm, Register result, Register array1, Register array2, Register length, Label trueLabel, Label falseLabel) { |
| Label compare2Bytes = new Label(); |
| Label compare1Byte = new Label(); |
| |
| Register temp = asRegister(temp4); |
| |
| if (kind.getByteCount() <= 4) { |
| // Compare trailing 4 bytes, if any. |
| masm.testl(result, 4); |
| masm.jccb(ConditionFlag.Zero, compare2Bytes); |
| masm.movl(temp, new AMD64Address(array1, 0)); |
| masm.cmpl(temp, new AMD64Address(array2, 0)); |
| if (kind == JavaKind.Float) { |
| masm.jccb(ConditionFlag.Equal, trueLabel); |
| emitFloatCompare(masm, array1, array2, Register.None, 0, falseLabel, true); |
| masm.jmpb(trueLabel); |
| } else { |
| masm.jccb(ConditionFlag.NotEqual, falseLabel); |
| } |
| if (kind.getByteCount() <= 2) { |
| // Move array pointers forward. |
| masm.leaq(array1, new AMD64Address(array1, 4)); |
| masm.leaq(array2, new AMD64Address(array2, 4)); |
| |
| // Compare trailing 2 bytes, if any. |
| masm.bind(compare2Bytes); |
| masm.testl(result, 2); |
| masm.jccb(ConditionFlag.Zero, compare1Byte); |
| masm.movzwl(temp, new AMD64Address(array1, 0)); |
| masm.movzwl(length, new AMD64Address(array2, 0)); |
| masm.cmpl(temp, length); |
| masm.jccb(ConditionFlag.NotEqual, falseLabel); |
| |
| // The one-byte tail compare is only required for boolean and byte arrays. |
| if (kind.getByteCount() <= 1) { |
| // Move array pointers forward before we compare the last trailing byte. |
| masm.leaq(array1, new AMD64Address(array1, 2)); |
| masm.leaq(array2, new AMD64Address(array2, 2)); |
| |
| // Compare trailing byte, if any. |
| masm.bind(compare1Byte); |
| masm.testl(result, 1); |
| masm.jccb(ConditionFlag.Zero, trueLabel); |
| masm.movzbl(temp, new AMD64Address(array1, 0)); |
| masm.movzbl(length, new AMD64Address(array2, 0)); |
| masm.cmpl(temp, length); |
| masm.jccb(ConditionFlag.NotEqual, falseLabel); |
| } else { |
| masm.bind(compare1Byte); |
| } |
| } else { |
| masm.bind(compare2Bytes); |
| } |
| } |
| } |
| |
| /** |
| * Emits code to fall through if {@code src} is NaN, otherwise jump to {@code branchOrdered}. |
| */ |
| private void emitNaNCheck(AMD64MacroAssembler masm, AMD64Address src, Label branchIfNonNaN) { |
| assert kind.isNumericFloat(); |
| Register tempXMMReg = asRegister(tempXMM); |
| if (kind == JavaKind.Float) { |
| masm.movflt(tempXMMReg, src); |
| } else { |
| masm.movdbl(tempXMMReg, src); |
| } |
| SSEOp.UCOMIS.emit(masm, kind == JavaKind.Float ? OperandSize.PS : OperandSize.PD, tempXMMReg, tempXMMReg); |
| masm.jcc(ConditionFlag.NoParity, branchIfNonNaN); |
| } |
| |
| /** |
| * Emits code to compare if two floats are bitwise equal or both NaN. |
| */ |
| private void emitFloatCompare(AMD64MacroAssembler masm, Register base1, Register base2, Register index, int offset, Label falseLabel, boolean skipBitwiseCompare) { |
| AMD64Address address1 = new AMD64Address(base1, index, Scale.Times1, offset); |
| AMD64Address address2 = new AMD64Address(base2, index, Scale.Times1, offset); |
| |
| Label bitwiseEqual = new Label(); |
| |
| if (!skipBitwiseCompare) { |
| // Bitwise compare |
| Register temp = asRegister(temp4); |
| |
| if (kind == JavaKind.Float) { |
| masm.movl(temp, address1); |
| masm.cmpl(temp, address2); |
| } else { |
| masm.movq(temp, address1); |
| masm.cmpq(temp, address2); |
| } |
| masm.jccb(ConditionFlag.Equal, bitwiseEqual); |
| } |
| |
| emitNaNCheck(masm, address1, falseLabel); |
| emitNaNCheck(masm, address2, falseLabel); |
| |
| masm.bind(bitwiseEqual); |
| } |
| |
| /** |
| * Emits code to compare float equality within a range. |
| */ |
| private void emitFloatCompareWithinRange(CompilationResultBuilder crb, AMD64MacroAssembler masm, Register base1, Register base2, Register index, int offset, Label falseLabel, int range) { |
| assert kind.isNumericFloat(); |
| Label loop = new Label(); |
| Register i = asRegister(temp5); |
| |
| masm.movq(i, range); |
| masm.negq(i); |
| // Align the main loop |
| masm.align(crb.target.wordSize * 2); |
| masm.bind(loop); |
| emitFloatCompare(masm, base1, base2, index, offset, falseLabel, kind.getByteCount() == range); |
| masm.addq(index, kind.getByteCount()); |
| masm.addq(i, kind.getByteCount()); |
| masm.jccb(ConditionFlag.NotZero, loop); |
| // Floats within the range are equal, revert change to the register index |
| masm.subq(index, range); |
| } |
| |
| private static final Unsafe UNSAFE = initUnsafe(); |
| |
| private static Unsafe initUnsafe() { |
| try { |
| return Unsafe.getUnsafe(); |
| } catch (SecurityException se) { |
| try { |
| Field theUnsafe = Unsafe.class.getDeclaredField("theUnsafe"); |
| theUnsafe.setAccessible(true); |
| return (Unsafe) theUnsafe.get(Unsafe.class); |
| } catch (Exception e) { |
| throw new RuntimeException("exception while trying to get Unsafe", e); |
| } |
| } |
| } |
| } |