/* * Copyright (c) 2015, 2016, 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 jdk.vm.ci.code.test.amd64; import static jdk.vm.ci.amd64.AMD64.xmm0; import jdk.vm.ci.amd64.AMD64; import jdk.vm.ci.amd64.AMD64Kind; import jdk.vm.ci.code.CallingConvention; import jdk.vm.ci.code.CodeCacheProvider; import jdk.vm.ci.code.DebugInfo; import jdk.vm.ci.code.Register; import jdk.vm.ci.code.RegisterValue; import jdk.vm.ci.code.StackSlot; import jdk.vm.ci.code.site.ConstantReference; import jdk.vm.ci.code.site.DataSectionReference; import jdk.vm.ci.code.test.TestAssembler; import jdk.vm.ci.code.test.TestHotSpotVMConfig; import jdk.vm.ci.hotspot.HotSpotCallingConventionType; import jdk.vm.ci.hotspot.HotSpotConstant; import jdk.vm.ci.hotspot.HotSpotForeignCallTarget; import jdk.vm.ci.meta.AllocatableValue; import jdk.vm.ci.meta.JavaKind; import jdk.vm.ci.meta.VMConstant; public class AMD64TestAssembler extends TestAssembler { public AMD64TestAssembler(CodeCacheProvider codeCache, TestHotSpotVMConfig config) { super(codeCache, config, 16, 16, AMD64Kind.DWORD, AMD64.rax, AMD64.rcx, AMD64.rdi, AMD64.r8, AMD64.r9, AMD64.r10); } private void emitFatNop() { // 5 byte NOP: // NOP DWORD ptr [EAX + EAX*1 + 00H] code.emitByte(0x0F); code.emitByte(0x1F); code.emitByte(0x44); code.emitByte(0x00); code.emitByte(0x00); } @Override public void emitPrologue() { // WARNING: Initial instruction MUST be 5 bytes or longer so that // NativeJump::patch_verified_entry will be able to patch out the entry // code safely. emitFatNop(); code.emitByte(0x50 | AMD64.rbp.encoding); // PUSH rbp emitMove(true, AMD64.rbp, AMD64.rsp); // MOV rbp, rsp setDeoptRescueSlot(newStackSlot(AMD64Kind.QWORD)); } @Override public void emitEpilogue() { recordMark(config.MARKID_DEOPT_HANDLER_ENTRY); recordCall(new HotSpotForeignCallTarget(config.handleDeoptStub), 5, true, null); code.emitByte(0xE8); // CALL rel32 code.emitInt(0xDEADDEAD); } @Override public void emitGrowStack(int size) { // SUB rsp, size code.emitByte(0x48); code.emitByte(0x81); code.emitByte(0xEC); code.emitInt(size); } @Override public Register emitIntArg0() { return codeCache.getRegisterConfig().getCallingConventionRegisters(HotSpotCallingConventionType.JavaCall, JavaKind.Int)[0]; } @Override public Register emitIntArg1() { return codeCache.getRegisterConfig().getCallingConventionRegisters(HotSpotCallingConventionType.JavaCall, JavaKind.Int)[1]; } private void emitREX(boolean w, int r, int x, int b) { int wrxb = (w ? 0x08 : 0) | ((r >> 3) << 2) | ((x >> 3) << 1) | (b >> 3); if (wrxb != 0) { code.emitByte(0x40 | wrxb); } } private void emitModRMReg(boolean w, int opcode, int r, int m) { emitREX(w, r, 0, m); code.emitByte((byte) opcode); code.emitByte((byte) 0xC0 | ((r & 0x7) << 3) | (m & 0x7)); } private void emitModRMMemory(boolean w, int opcode, int r, int b, int offset) { emitREX(w, r, 0, b); code.emitByte((byte) opcode); code.emitByte((byte) 0x80 | ((r & 0x7) << 3) | (b & 0x7)); code.emitInt(offset); } @Override public Register emitLoadInt(int c) { Register ret = newRegister(); return emitLoadInt(ret, c); } public Register emitLoadInt(Register ret, int c) { emitREX(false, 0, 0, ret.encoding); code.emitByte(0xB8 | (ret.encoding & 0x7)); // MOV r32, imm32 code.emitInt(c); return ret; } @Override public Register emitLoadLong(long c) { Register ret = newRegister(); return emitLoadLong(ret, c); } public Register emitLoadLong(Register ret, long c) { emitREX(true, 0, 0, ret.encoding); code.emitByte(0xB8 | (ret.encoding & 0x7)); // MOV r64, imm64 code.emitLong(c); return ret; } @Override public Register emitLoadFloat(float c) { Register ret = AMD64.xmm0; return emitLoadFloat(ret, c); } public Register emitLoadFloat(Register ret, float c) { DataSectionReference ref = new DataSectionReference(); ref.setOffset(data.position()); data.emitFloat(c); recordDataPatchInCode(ref); emitREX(false, ret.encoding, 0, 0); code.emitByte(0xF3); code.emitByte(0x0F); code.emitByte(0x10); // MOVSS xmm1, xmm2/m32 code.emitByte(0x05 | ((ret.encoding & 0x7) << 3)); // xmm, [rip+offset] code.emitInt(0xDEADDEAD); return ret; } public Register emitLoadDouble(double c) { Register ret = AMD64.xmm0; return emitLoadDouble(ret, c); } public Register emitLoadDouble(Register ret, double c) { DataSectionReference ref = new DataSectionReference(); ref.setOffset(data.position()); data.emitDouble(c); recordDataPatchInCode(ref); emitREX(false, ret.encoding, 0, 0); code.emitByte(0xF2); code.emitByte(0x0F); code.emitByte(0x10); // MOVSD xmm1, xmm2/m32 code.emitByte(0x05 | ((ret.encoding & 0x7) << 3)); // xmm, [rip+offset] code.emitInt(0xDEADDEAD); return ret; } @Override public Register emitLoadPointer(HotSpotConstant c) { recordDataPatchInCode(new ConstantReference((VMConstant) c)); if (c.isCompressed()) { Register ret = newRegister(); emitREX(false, 0, 0, ret.encoding); code.emitByte(0xB8 | (ret.encoding & 0x7)); // MOV r32, imm32 code.emitInt(0xDEADDEAD); return ret; } else { return emitLoadLong(0xDEADDEADDEADDEADL); } } private Register emitLoadPointer(DataSectionReference ref, boolean narrow) { recordDataPatchInCode(ref); Register ret = newRegister(); emitREX(!narrow, ret.encoding, 0, 0); code.emitByte(0x8B); // MOV r64,r/m64 code.emitByte(0x05 | ((ret.encoding & 0x7) << 3)); // r64, [rip+offset] code.emitInt(0xDEADDEAD); return ret; } @Override public Register emitLoadPointer(DataSectionReference ref) { return emitLoadPointer(ref, false); } @Override public Register emitLoadNarrowPointer(DataSectionReference ref) { return emitLoadPointer(ref, true); } @Override public Register emitLoadPointer(Register b, int offset) { Register ret = newRegister(); emitModRMMemory(true, 0x8B, ret.encoding, b.encoding, offset); // MOV r64,r/m64 return ret; } @Override public StackSlot emitIntToStack(Register a) { StackSlot ret = newStackSlot(AMD64Kind.DWORD); return emitIntToStack(ret, a); } public StackSlot emitIntToStack(StackSlot ret, Register a) { // MOV r/m32,r32 emitModRMMemory(false, 0x89, a.encoding, AMD64.rbp.encoding, ret.getRawOffset() + 16); return ret; } @Override public StackSlot emitLongToStack(Register a) { StackSlot ret = newStackSlot(AMD64Kind.QWORD); return emitLongToStack(ret, a); } public StackSlot emitLongToStack(StackSlot ret, Register a) { // MOV r/m64,r64 emitModRMMemory(true, 0x89, a.encoding, AMD64.rbp.encoding, ret.getRawOffset() + 16); return ret; } @Override public StackSlot emitFloatToStack(Register a) { StackSlot ret = newStackSlot(AMD64Kind.SINGLE); return emitFloatToStack(ret, a); } public StackSlot emitFloatToStack(StackSlot ret, Register a) { emitREX(false, a.encoding, 0, 0); code.emitByte(0xF3); code.emitByte(0x0F); code.emitByte(0x11); // MOVSS xmm2/m32, xmm1 code.emitByte(0x85 | ((a.encoding & 0x7) << 3)); // [rbp+offset] if (ret.getRawOffset() < 0) { code.emitInt(ret.getRawOffset() + 16); } else { code.emitInt(-(frameSize - ret.getRawOffset()) + 16); } return ret; } public StackSlot emitDoubleToStack(Register a) { StackSlot ret = newStackSlot(AMD64Kind.DOUBLE); return emitDoubleToStack(ret, a); } public StackSlot emitDoubleToStack(StackSlot ret, Register a) { emitREX(false, a.encoding, 0, 0); code.emitByte(0xF2); code.emitByte(0x0F); code.emitByte(0x11); // MOVSD xmm2/m32, xmm1 code.emitByte(0x85 | ((a.encoding & 0x7) << 3)); // [rbp+offset] if (ret.getRawOffset() < 0) { code.emitInt(ret.getRawOffset() + 16); } else { code.emitInt(-(frameSize - ret.getRawOffset()) + 16); } return ret; } @Override public StackSlot emitPointerToStack(Register a) { StackSlot ret = newStackSlot(AMD64Kind.QWORD); // MOV r/m64,r64 emitModRMMemory(true, 0x89, a.encoding, AMD64.rbp.encoding, ret.getRawOffset() + 16); return ret; } @Override public StackSlot emitNarrowPointerToStack(Register a) { StackSlot ret = newStackSlot(AMD64Kind.DWORD); // MOV r/m32,r32 emitModRMMemory(false, 0x89, a.encoding, AMD64.rbp.encoding, ret.getRawOffset() + 16); return ret; } @Override public Register emitUncompressPointer(Register compressed, long base, int shift) { if (shift > 0) { emitModRMReg(true, 0xC1, 4, compressed.encoding); code.emitByte(shift); } if (base == 0) { return compressed; } else { Register tmp = emitLoadLong(base); emitModRMReg(true, 0x03, tmp.encoding, compressed.encoding); return tmp; } } @Override public Register emitIntAdd(Register a, Register b) { emitModRMReg(false, 0x03, a.encoding, b.encoding); return a; } private void emitMove(boolean w, Register to, Register from) { if (to != from) { emitModRMReg(w, 0x8B, to.encoding, from.encoding); } } @Override public void emitIntRet(Register a) { emitMove(false, AMD64.rax, a); // MOV eax, ... emitMove(true, AMD64.rsp, AMD64.rbp); // MOV rsp, rbp code.emitByte(0x58 | AMD64.rbp.encoding); // POP rbp code.emitByte(0xC3); // RET } @Override public void emitFloatRet(Register a) { assert a == xmm0 : "Unimplemented move " + a; emitMove(true, AMD64.rsp, AMD64.rbp); // MOV rsp, rbp code.emitByte(0x58 | AMD64.rbp.encoding); // POP rbp code.emitByte(0xC3); // RET } @Override public void emitPointerRet(Register a) { emitMove(true, AMD64.rax, a); // MOV rax, ... emitMove(true, AMD64.rsp, AMD64.rbp); // MOV rsp, rbp code.emitByte(0x58 | AMD64.rbp.encoding); // POP rbp code.emitByte(0xC3); // RET } @Override public void emitTrap(DebugInfo info) { recordImplicitException(info); // MOV rax, [0] code.emitByte(0x8B); code.emitByte(0x04); code.emitByte(0x25); code.emitInt(0); } @Override public void emitLoad(AllocatableValue av, Object prim) { if (av instanceof RegisterValue) { Register reg = ((RegisterValue) av).getRegister(); if (prim instanceof Float) { emitLoadFloat(reg, (Float) prim); } else if (prim instanceof Double) { emitLoadDouble(reg, (Double) prim); } else if (prim instanceof Integer) { emitLoadInt(reg, (Integer) prim); } else if (prim instanceof Long) { emitLoadLong(reg, (Long) prim); } } else if (av instanceof StackSlot) { StackSlot slot = (StackSlot) av; if (prim instanceof Float) { emitFloatToStack(slot, emitLoadFloat((Float) prim)); } else if (prim instanceof Double) { emitDoubleToStack(slot, emitLoadDouble((Double) prim)); } else if (prim instanceof Integer) { emitIntToStack(slot, emitLoadInt((Integer) prim)); } else if (prim instanceof Long) { emitLongToStack(slot, emitLoadLong((Long) prim)); } assert false : "Unimplemented"; } else { throw new IllegalArgumentException("Unknown value " + av); } } @Override public void emitCallPrologue(CallingConvention cc, Object... prim) { emitGrowStack(cc.getStackSize()); frameSize += cc.getStackSize(); AllocatableValue[] args = cc.getArguments(); // Do the emission in reverse, this avoids register collisons of xmm0 - which is used a // scratch register when putting arguments on the stack. for (int i = args.length - 1; i >= 0; i--) { emitLoad(args[i], prim[i]); } } @Override public void emitCall(long addr) { Register target = emitLoadLong(addr); code.emitByte(0xFF); // CALL r/m64 int enc = target.encoding; if (enc >= 8) { code.emitByte(0x41); enc -= 8; } code.emitByte(0xD0 | enc); } @Override public void emitCallEpilogue(CallingConvention cc) { emitGrowStack(-cc.getStackSize()); frameSize -= cc.getStackSize(); } }