Mercurial > hg > truffle
view graal/com.oracle.max.asmdis/src/com/sun/max/asm/gen/cisc/x86/X86AssemblyTester.java @ 3734:b55f2b8f83fd
Remove deprecated files.
author | Thomas Wuerthinger <thomas.wuerthinger@oracle.com> |
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date | Sat, 17 Dec 2011 20:34:58 +0100 |
parents | e233f5660da4 |
children | bc8527f3071c |
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/* * Copyright (c) 2007, 2011, 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 com.sun.max.asm.gen.cisc.x86; import java.io.*; import java.util.*; import com.sun.max.*; import com.sun.max.asm.*; import com.sun.max.asm.gen.*; import com.sun.max.asm.x86.*; import com.sun.max.io.*; import com.sun.max.lang.*; /** */ public abstract class X86AssemblyTester<Template_Type extends X86Template> extends AssemblyTester<Template_Type> { public X86AssemblyTester(Assembly<Template_Type> assembly, WordWidth addressWidth, EnumSet<AssemblyTestComponent> components) { super(assembly, addressWidth, components); } @Override public X86Assembly<Template_Type> assembly() { final Class<X86Assembly<Template_Type>> type = null; return Utils.cast(type, super.assembly()); } private String getSibIndexAndScale(Queue<X86Operand> operands, Queue<Argument> arguments) { X86Parameter parameter = (X86Parameter) operands.remove(); assert parameter.place() == ParameterPlace.SIB_INDEX || parameter.place() == ParameterPlace.SIB_INDEX_REXX; final String result = arguments.remove().externalValue() + ","; parameter = (X86Parameter) operands.remove(); assert parameter.place() == ParameterPlace.SIB_SCALE; return result + arguments.remove().externalValue() + ")"; } private String getOperand(X86Template template, Queue<X86Operand> operands, Queue<Argument> arguments, String label) { final X86Operand operand = operands.remove(); if (operand instanceof ImplicitOperand) { final ImplicitOperand implicitOperand = (ImplicitOperand) operand; if (implicitOperand.externalPresence() == ImplicitOperand.ExternalPresence.OMITTED) { return ""; } final Argument argument = implicitOperand.argument(); if (argument instanceof ImmediateArgument) { return "$" + implicitOperand.argument().externalValue(); } return implicitOperand.argument().externalValue(); } final X86Parameter parameter = (X86Parameter) operand; final Argument argument = arguments.remove(); if (parameter instanceof X86DisplacementParameter) { assert parameter.place() == ParameterPlace.APPEND; final ImmediateArgument immediateArgument = (ImmediateArgument) argument; String prefix = immediateArgument.signedExternalValue() + "("; final X86Parameter nextParameter = (X86Parameter) operands.element(); if (IndirectRegister.class.isAssignableFrom(nextParameter.type())) { operands.remove(); return prefix + arguments.remove().externalValue() + ")"; } if (nextParameter.place() == ParameterPlace.SIB_BASE || nextParameter.place() == ParameterPlace.SIB_BASE_REXB) { operands.remove(); prefix += arguments.remove().externalValue() + ","; } return prefix + getSibIndexAndScale(operands, arguments); } if (parameter.place() == ParameterPlace.SIB_BASE || parameter.place() == ParameterPlace.SIB_BASE_REXB) { return "(" + argument.externalValue() + "," + getSibIndexAndScale(operands, arguments); } if (IndirectRegister.class.isAssignableFrom(parameter.type())) { return "(" + argument.externalValue() + ")"; } if (parameter instanceof X86AddressParameter) { final X86Operand nextOperand = operands.peek(); if (nextOperand instanceof X86Parameter) { final X86Parameter nextParameter = (X86Parameter) nextOperand; if (nextParameter.place() == ParameterPlace.SIB_INDEX || nextParameter.place() == ParameterPlace.SIB_INDEX_REXX) { return argument.externalValue() + "(," + getSibIndexAndScale(operands, arguments); } } } if (parameter instanceof X86OffsetParameter) { if (template.addressSizeAttribute() == WordWidth.BITS_64 && template.rmCase() == X86TemplateContext.RMCase.SDWORD) { return argument.externalValue() + "(%rip)"; } final ImmediateArgument immediateArgument = (ImmediateArgument) argument; return label + " + (" + immediateArgument.signedExternalValue() + ")"; } if (parameter.getClass() == X86ImmediateParameter.class) { return "$" + argument.externalValue(); } return argument.externalValue(); } /** * Yes, 'X86DisassembledInstruction.toString()' may be similar, * but it pertains only to our own private disassembly output style, * whereas here, we have to comply strictly with the requirements of GNU asm (gas). * We keep these two objectives completely separate and * we want to keep the code in this file here stable. */ @Override protected void assembleExternally(IndentWriter stream, Template_Type template, List<Argument> argumentList, String label) { final WordWidth externalCodeSizeAttribute = template.externalCodeSizeAttribute(); if (externalCodeSizeAttribute != null) { stream.println(".code" + externalCodeSizeAttribute.numberOfBits); } else { stream.println(".code" + addressWidth().numberOfBits); } final LinkedList<X86Operand> operandQueue = new LinkedList<X86Operand>(template.operands()); final LinkedList<Argument> argumentQueue = new LinkedList<Argument>(argumentList); String first = ""; if (!operandQueue.isEmpty()) { first = getOperand(template, operandQueue, argumentQueue, label); } String second = ""; if (!operandQueue.isEmpty()) { second = getOperand(template, operandQueue, argumentQueue, label); } String third = ""; if (!operandQueue.isEmpty()) { third = getOperand(template, operandQueue, argumentQueue, label); } stream.print(template.externalName()); stream.print(" "); if (third.length() > 0) { stream.print(third + ","); } if (template.isExternalOperandOrderingInverted()) { if (second.length() > 0) { stream.print(second + ","); } stream.println(first); } else { if (first.length() > 0) { stream.print(first + ","); } stream.println(second); } stream.outdent(); stream.println(label + ":"); stream.indent(); } @Override protected byte[] readExternalInstruction(PushbackInputStream externalInputStream, Template_Type template, byte[] internalBytes) throws IOException { if (X86Opcode.isFloatingPointEscape(template.opcode1())) { // We skip FWAIT instructions that the external assembler may inject before floating point operations final int externalOpcode = externalInputStream.read(); if (externalOpcode != X86Opcode.FWAIT.ordinal()) { externalInputStream.unread(externalOpcode); } } final byte[] externalBytes = new byte[internalBytes.length]; int i = 0; final WordWidth externalCodeSizeAttribute = template.externalCodeSizeAttribute(); if (externalCodeSizeAttribute != null && externalCodeSizeAttribute != addressWidth()) { if (template.addressSizeAttribute() == externalCodeSizeAttribute) { assert internalBytes[0] == X86Opcode.ADDRESS_SIZE.byteValue(); externalBytes[i++] = X86Opcode.ADDRESS_SIZE.byteValue(); } else { assert internalBytes[0] != X86Opcode.ADDRESS_SIZE.byteValue(); final int externalOpcode = externalInputStream.read(); if (externalOpcode != X86Opcode.ADDRESS_SIZE.ordinal()) { externalInputStream.unread(externalOpcode); } } if (template.instructionSelectionPrefix() != HexByte._66) { if (template.operandSizeAttribute() == externalCodeSizeAttribute && externalCodeSizeAttribute == WordWidth.BITS_16) { assert internalBytes[i] == X86Opcode.OPERAND_SIZE.byteValue(); externalBytes[i++] = X86Opcode.OPERAND_SIZE.byteValue(); } else if (template.operandSizeAttribute() != WordWidth.BITS_16) { assert internalBytes[i] != X86Opcode.OPERAND_SIZE.byteValue(); final int externalOpcode = externalInputStream.read(); if (externalOpcode != X86Opcode.OPERAND_SIZE.ordinal()) { externalInputStream.unread(externalOpcode); } } } if (externalCodeSizeAttribute != WordWidth.BITS_64 && template.operandSizeAttribute() == WordWidth.BITS_64 && template.instructionDescription().defaultOperandSize() != WordWidth.BITS_64) { assert 0x40 <= internalBytes[i] && internalBytes[i] <= 0x4F; // is REX prefix externalBytes[i] = internalBytes[i]; i++; } } while (i < externalBytes.length) { externalBytes[i] = (byte) externalInputStream.read(); i++; } return externalBytes; } @Override protected boolean readNop(InputStream stream) throws IOException { final int instruction = stream.read(); return instruction == 0x90; } @Override protected String disassembleFields(Template_Type template, byte[] assembledInstruction) { return "<not yet implemented>"; } }