/* * Copyright (c) 2018, 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 jdk.vm.ci.amd64.AMD64.k1; import static jdk.vm.ci.amd64.AMD64.k2; import static jdk.vm.ci.amd64.AMD64.k3; import static jdk.vm.ci.amd64.AMD64.rax; import static jdk.vm.ci.amd64.AMD64.rdi; import static jdk.vm.ci.amd64.AMD64.rdx; import static jdk.vm.ci.amd64.AMD64.rsi; import static jdk.vm.ci.amd64.AMD64.rsp; import static jdk.vm.ci.code.ValueUtil.asRegister; import static org.graalvm.compiler.lir.LIRInstruction.OperandFlag.REG; import jdk.vm.ci.amd64.AMD64; import org.graalvm.compiler.asm.Label; import org.graalvm.compiler.asm.amd64.AMD64Address; import org.graalvm.compiler.asm.amd64.AMD64Assembler; 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.AMD64Kind; import jdk.vm.ci.code.Register; import jdk.vm.ci.meta.Value; @Opcode("AMD64_STRING_COMPRESS") public final class AMD64StringUTF16CompressOp extends AMD64LIRInstruction { public static final LIRInstructionClass TYPE = LIRInstructionClass.create(AMD64StringUTF16CompressOp.class); @Def({REG}) private Value rres; @Alive({REG}) private Value rsrc; @Alive({REG}) private Value rdst; @Alive({REG}) private Value rlen; @Temp({REG}) private Value vtmp1; @Temp({REG}) private Value vtmp2; @Temp({REG}) private Value vtmp3; @Temp({REG}) private Value vtmp4; @Temp({REG}) private Value rtmp5; public AMD64StringUTF16CompressOp(LIRGeneratorTool tool, Value res, Value src, Value dst, Value len) { super(TYPE); assert asRegister(src).equals(rsi); assert asRegister(dst).equals(rdi); assert asRegister(len).equals(rdx); assert asRegister(res).equals(rax); rres = res; rsrc = src; rdst = dst; rlen = len; LIRKind vkind = LIRKind.value(AMD64Kind.V512_BYTE); vtmp1 = tool.newVariable(vkind); vtmp2 = tool.newVariable(vkind); vtmp3 = tool.newVariable(vkind); vtmp4 = tool.newVariable(vkind); rtmp5 = tool.newVariable(LIRKind.value(AMD64Kind.DWORD)); } @Override public void emitCode(CompilationResultBuilder crb, AMD64MacroAssembler masm) { Register res = asRegister(rres); Register src = asRegister(rsrc); Register dst = asRegister(rdst); Register len = asRegister(rlen); Register tmp1 = asRegister(vtmp1); Register tmp2 = asRegister(vtmp2); Register tmp3 = asRegister(vtmp3); Register tmp4 = asRegister(vtmp4); Register tmp5 = asRegister(rtmp5); charArrayCompress(masm, src, dst, len, tmp1, tmp2, tmp3, tmp4, tmp5, res); } /** * Compress a UTF16 string which de facto is a Latin1 string into a byte array representation * (buffer). * * @param masm the assembler * @param src (rsi) the start address of source char[] to be compressed * @param dst (rdi) the start address of destination byte[] vector * @param len (rdx) the length * @param tmp1 (xmm) temporary xmm register * @param tmp2 (xmm) temporary xmm register * @param tmp3 (xmm) temporary xmm register * @param tmp4 (xmm) temporary xmm register * @param tmp (gpr) temporary gpr register * @param res (rax) the result code (length on success, zero otherwise) */ private static void charArrayCompress(AMD64MacroAssembler masm, Register src, Register dst, Register len, Register tmp1, Register tmp2, Register tmp3, Register tmp4, Register tmp, Register res) { assert tmp1.getRegisterCategory().equals(AMD64.XMM); assert tmp2.getRegisterCategory().equals(AMD64.XMM); assert tmp3.getRegisterCategory().equals(AMD64.XMM); assert tmp4.getRegisterCategory().equals(AMD64.XMM); Label labelReturnLength = new Label(); Label labelReturnZero = new Label(); Label labelDone = new Label(); Label labelBelowThreshold = new Label(); assert len.number != res.number; masm.push(len); // Save length for return. if (masm.supports(AMD64.CPUFeature.AVX512BW) && masm.supports(AMD64.CPUFeature.AVX512VL) && masm.supports(AMD64.CPUFeature.BMI2)) { Label labelRestoreK1ReturnZero = new Label(); Label labelAvxPostAlignment = new Label(); // If the length of the string is less than 32, we chose not to use the // AVX512 instructions. masm.testl(len, -32); masm.jcc(AMD64Assembler.ConditionFlag.Zero, labelBelowThreshold); // First check whether a character is compressible (<= 0xff). // Create mask to test for Unicode chars inside (zmm) vector. masm.movl(res, 0x00ff); masm.evpbroadcastw(tmp2, res); masm.kmovq(k3, k1); // Save k1 masm.testl(len, -64); masm.jcc(AMD64Assembler.ConditionFlag.Zero, labelAvxPostAlignment); masm.movl(tmp, dst); masm.andl(tmp, (32 - 1)); masm.negl(tmp); masm.andl(tmp, (32 - 1)); // bail out when there is nothing to be done masm.testl(tmp, tmp); masm.jcc(AMD64Assembler.ConditionFlag.Zero, labelAvxPostAlignment); // Compute (1 << N) - 1 = ~(~0 << N), where N is the remaining number // of characters to process. masm.movl(res, -1); masm.shlxl(res, res, tmp); masm.notl(res); masm.kmovd(k1, res); masm.evmovdqu16(tmp1, k1, new AMD64Address(src)); masm.evpcmpuw(k2, k1, tmp1, tmp2, 2 /* le */); masm.ktestd(k2, k1); masm.jcc(AMD64Assembler.ConditionFlag.CarryClear, labelRestoreK1ReturnZero); masm.evpmovwb(new AMD64Address(dst), k1, tmp1); masm.addq(src, tmp); masm.addq(src, tmp); masm.addq(dst, tmp); masm.subl(len, tmp); masm.bind(labelAvxPostAlignment); // end of alignment Label labelAvx512LoopTail = new Label(); masm.movl(tmp, len); masm.andl(tmp, -32); // The vector count (in chars). masm.jcc(AMD64Assembler.ConditionFlag.Zero, labelAvx512LoopTail); masm.andl(len, 32 - 1); // The tail count (in chars). masm.leaq(src, new AMD64Address(src, tmp, AMD64Address.Scale.Times2)); masm.leaq(dst, new AMD64Address(dst, tmp, AMD64Address.Scale.Times1)); masm.negq(tmp); Label labelAvx512Loop = new Label(); // Test and compress 32 chars per iteration, reading 512-bit vectors and // writing 256-bit compressed ditto. masm.bind(labelAvx512Loop); masm.evmovdqu16(tmp1, new AMD64Address(src, tmp, AMD64Address.Scale.Times2)); masm.evpcmpuw(k2, tmp1, tmp2, 2 /* le */); masm.kortestd(k2, k2); masm.jcc(AMD64Assembler.ConditionFlag.CarryClear, labelRestoreK1ReturnZero); // All 32 chars in the current vector (chunk) are valid for compression, // write truncated byte elements to memory. masm.evpmovwb(new AMD64Address(dst, tmp, AMD64Address.Scale.Times1), tmp1); masm.addq(tmp, 32); masm.jcc(AMD64Assembler.ConditionFlag.NotZero, labelAvx512Loop); masm.bind(labelAvx512LoopTail); masm.kmovq(k1, k3); // Restore k1 // All done if the tail count is zero. masm.testl(len, len); masm.jcc(AMD64Assembler.ConditionFlag.Zero, labelReturnLength); // Compute (1 << N) - 1 = ~(~0 << N), where N is the remaining number // of characters to process. masm.movl(res, -1); masm.shlxl(res, res, len); masm.notl(res); masm.kmovd(k1, res); masm.evmovdqu16(tmp1, k1, new AMD64Address(src)); masm.evpcmpuw(k2, k1, tmp1, tmp2, 2 /* le */); masm.ktestd(k2, k1); masm.jcc(AMD64Assembler.ConditionFlag.CarryClear, labelRestoreK1ReturnZero); masm.evpmovwb(new AMD64Address(dst), k1, tmp1); masm.kmovq(k1, k3); // Restore k1 masm.jmp(labelReturnLength); masm.bind(labelRestoreK1ReturnZero); masm.kmovq(k1, k3); // Restore k1 masm.jmp(labelReturnZero); } if (masm.supports(AMD64.CPUFeature.SSE4_2)) { Label labelSSETail = new Label(); masm.bind(labelBelowThreshold); masm.movl(tmp, 0xff00ff00); // Create mask to test for Unicode chars in vectors. masm.movl(res, len); masm.andl(res, -16); masm.jccb(AMD64Assembler.ConditionFlag.Zero, labelSSETail); masm.andl(len, 16 - 1); // Compress 16 chars per iteration. masm.movdl(tmp1, tmp); masm.pshufd(tmp1, tmp1, 0); // Store Unicode mask in 'vtmp1'. masm.pxor(tmp4, tmp4); masm.leaq(src, new AMD64Address(src, res, AMD64Address.Scale.Times2)); masm.leaq(dst, new AMD64Address(dst, res, AMD64Address.Scale.Times1)); masm.negq(res); Label lSSELoop = new Label(); // Test and compress 16 chars per iteration, reading 128-bit vectors and // writing 64-bit compressed ditto. masm.bind(lSSELoop); masm.movdqu(tmp2, new AMD64Address(src, res, AMD64Address.Scale.Times2)); // load // 1st 8 // characters masm.movdqu(tmp3, new AMD64Address(src, res, AMD64Address.Scale.Times2, 16)); // load // next 8 // characters masm.por(tmp4, tmp2); masm.por(tmp4, tmp3); masm.ptest(tmp4, tmp1); // Check for Unicode chars in vector. masm.jcc(AMD64Assembler.ConditionFlag.NotZero, labelReturnZero); masm.packuswb(tmp2, tmp3); // Only ASCII chars; compress each to a byte. masm.movdqu(new AMD64Address(dst, res, AMD64Address.Scale.Times1), tmp2); masm.addq(res, 16); masm.jcc(AMD64Assembler.ConditionFlag.NotZero, lSSELoop); Label labelCopyChars = new Label(); // Test and compress another 8 chars before final tail copy. masm.bind(labelSSETail); masm.movl(res, len); masm.andl(res, -8); masm.jccb(AMD64Assembler.ConditionFlag.Zero, labelCopyChars); masm.andl(len, 8 - 1); masm.movdl(tmp1, tmp); masm.pshufd(tmp1, tmp1, 0); // Store Unicode mask in 'vtmp1'. masm.pxor(tmp3, tmp3); masm.movdqu(tmp2, new AMD64Address(src)); masm.ptest(tmp2, tmp1); // Check for Unicode chars in vector. masm.jccb(AMD64Assembler.ConditionFlag.NotZero, labelReturnZero); masm.packuswb(tmp2, tmp3); // Only ASCII chars; compress each to a byte. masm.movq(new AMD64Address(dst), tmp2); masm.addq(src, 16); masm.addq(dst, 8); masm.bind(labelCopyChars); } // Compress any remaining characters using a vanilla implementation. masm.testl(len, len); masm.jccb(AMD64Assembler.ConditionFlag.Zero, labelReturnLength); masm.leaq(src, new AMD64Address(src, len, AMD64Address.Scale.Times2)); masm.leaq(dst, new AMD64Address(dst, len, AMD64Address.Scale.Times1)); masm.negq(len); Label labelCopyCharsLoop = new Label(); // Compress a single character per iteration. masm.bind(labelCopyCharsLoop); masm.movzwl(res, new AMD64Address(src, len, AMD64Address.Scale.Times2)); masm.testl(res, 0xff00); // Check if Unicode character. masm.jccb(AMD64Assembler.ConditionFlag.NotZero, labelReturnZero); // An ASCII character; compress to a byte. masm.movb(new AMD64Address(dst, len, AMD64Address.Scale.Times1), res); masm.incrementq(len, 1); masm.jcc(AMD64Assembler.ConditionFlag.NotZero, labelCopyCharsLoop); // If compression succeeded, return the length. masm.bind(labelReturnLength); masm.pop(res); masm.jmpb(labelDone); // If compression failed, return 0. masm.bind(labelReturnZero); masm.xorl(res, res); masm.addq(rsp, 8 /* wordSize */); masm.bind(labelDone); } }