Search in sources :

Example 6 with AMD64Address

use of org.graalvm.compiler.asm.amd64.AMD64Address in project graal by oracle.

the class AMD64HotSpotPatchReturnAddressOp method emitCode.

@Override
public void emitCode(CompilationResultBuilder crb, AMD64MacroAssembler masm) {
    int frameSize = crb.frameMap.frameSize();
    masm.movq(new AMD64Address(rsp, frameSize), asRegister(address));
}
Also used : AMD64Address(org.graalvm.compiler.asm.amd64.AMD64Address)

Example 7 with AMD64Address

use of org.graalvm.compiler.asm.amd64.AMD64Address in project graal by oracle.

the class AMD64HotSpotPushInterpreterFrameOp method emitCode.

@Override
public void emitCode(CompilationResultBuilder crb, AMD64MacroAssembler masm) {
    final Register frameSizeRegister = asRegister(frameSize);
    final Register framePcRegister = asRegister(framePc);
    final Register senderSpRegister = asRegister(senderSp);
    final Register initialInfoRegister = asRegister(initialInfo);
    final int wordSize = 8;
    // We'll push PC and BP by hand.
    masm.subq(frameSizeRegister, 2 * wordSize);
    // Push return address.
    masm.push(framePcRegister);
    // Prolog
    masm.push(initialInfoRegister);
    masm.movq(initialInfoRegister, rsp);
    masm.subq(rsp, frameSizeRegister);
    // This value is corrected by layout_activation_impl.
    masm.movptr(new AMD64Address(initialInfoRegister, config.frameInterpreterFrameLastSpOffset * wordSize), 0);
    // Make the frame walkable.
    masm.movq(new AMD64Address(initialInfoRegister, config.frameInterpreterFrameSenderSpOffset * wordSize), senderSpRegister);
}
Also used : ValueUtil.asRegister(jdk.vm.ci.code.ValueUtil.asRegister) Register(jdk.vm.ci.code.Register) AMD64Address(org.graalvm.compiler.asm.amd64.AMD64Address)

Example 8 with AMD64Address

use of org.graalvm.compiler.asm.amd64.AMD64Address in project graal by oracle.

the class AMD64TruffleCallBoundaryInstrumentationFactory method createBuilder.

@Override
public CompilationResultBuilder createBuilder(CodeCacheProvider codeCache, ForeignCallsProvider foreignCalls, FrameMap frameMap, Assembler asm, DataBuilder dataBuilder, FrameContext frameContext, OptionValues options, DebugContext debug, CompilationResult compilationResult) {
    return new TruffleCallBoundaryInstrumentation(metaAccess, codeCache, foreignCalls, frameMap, asm, dataBuilder, frameContext, options, debug, compilationResult, config, registers) {

        @Override
        protected void injectTailCallCode(int installedCodeOffset, int entryPointOffset) {
            AMD64MacroAssembler masm = (AMD64MacroAssembler) this.asm;
            Register thisRegister = codeCache.getRegisterConfig().getCallingConventionRegisters(JavaCall, JavaKind.Object).get(0);
            Register spillRegister = AMD64.r10;
            Label doProlog = new Label();
            int pos = masm.position();
            if (config.useCompressedOops) {
                // First instruction must be at least 5 bytes long to be safe for patching
                masm.movl(spillRegister, new AMD64Address(thisRegister, installedCodeOffset), true);
                assert masm.position() - pos >= AMD64HotSpotBackend.PATCHED_VERIFIED_ENTRY_POINT_INSTRUCTION_SIZE;
                CompressEncoding encoding = config.getOopEncoding();
                Register heapBaseRegister = AMD64Move.UncompressPointerOp.hasBase(options, encoding) ? registers.getHeapBaseRegister() : null;
                AMD64Move.UncompressPointerOp.emitUncompressCode(masm, spillRegister, encoding.getShift(), heapBaseRegister, true);
            } else {
                // First instruction must be at least 5 bytes long to be safe for patching
                masm.movq(spillRegister, new AMD64Address(thisRegister, installedCodeOffset), true);
                assert masm.position() - pos >= AMD64HotSpotBackend.PATCHED_VERIFIED_ENTRY_POINT_INSTRUCTION_SIZE;
            }
            masm.movq(spillRegister, new AMD64Address(spillRegister, entryPointOffset));
            masm.testq(spillRegister, spillRegister);
            masm.jcc(ConditionFlag.Equal, doProlog);
            masm.jmp(spillRegister);
            masm.bind(doProlog);
        }
    };
}
Also used : TruffleCallBoundaryInstrumentation(org.graalvm.compiler.truffle.compiler.hotspot.TruffleCallBoundaryInstrumentation) Register(jdk.vm.ci.code.Register) AMD64MacroAssembler(org.graalvm.compiler.asm.amd64.AMD64MacroAssembler) Label(org.graalvm.compiler.asm.Label) CompressEncoding(org.graalvm.compiler.core.common.CompressEncoding) AMD64Address(org.graalvm.compiler.asm.amd64.AMD64Address)

Example 9 with AMD64Address

use of org.graalvm.compiler.asm.amd64.AMD64Address in project graal by oracle.

the class AMD64ArrayCompareToOp method emitCode.

@Override
public void emitCode(CompilationResultBuilder crb, AMD64MacroAssembler masm) {
    Register result = asRegister(resultValue);
    Register str1 = asRegister(temp1);
    Register str2 = asRegister(temp2);
    // Load array base addresses.
    masm.leaq(str1, new AMD64Address(asRegister(array1Value), array1BaseOffset));
    masm.leaq(str2, new AMD64Address(asRegister(array2Value), array2BaseOffset));
    Register cnt1 = asRegister(length1Value);
    Register cnt2 = asRegister(length2Value);
    // Checkstyle: stop
    Label LENGTH_DIFF_LABEL = new Label();
    Label POP_LABEL = new Label();
    Label DONE_LABEL = new Label();
    Label WHILE_HEAD_LABEL = new Label();
    // used only _LP64 && AVX3
    Label COMPARE_WIDE_VECTORS_LOOP_FAILED = new Label();
    int stride, stride2;
    int adr_stride = -1;
    int adr_stride1 = -1;
    int adr_stride2 = -1;
    // Checkstyle: resume
    int stride2x2 = 0x40;
    AMD64Address.Scale scale = null;
    AMD64Address.Scale scale1 = null;
    AMD64Address.Scale scale2 = null;
    // if (ae != StrIntrinsicNode::LL) {
    if (kind1 == JavaKind.Byte && kind2 == JavaKind.Byte) {
        stride2x2 = 0x20;
    }
    // if (ae == StrIntrinsicNode::LU || ae == StrIntrinsicNode::UL) {
    if (kind1 != kind2) {
        masm.shrl(cnt2, 1);
    }
    // Compute the minimum of the string lengths and the
    // difference of the string lengths (stack).
    // Do the conditional move stuff
    masm.movl(result, cnt1);
    masm.subl(cnt1, cnt2);
    masm.push(cnt1);
    // cnt2 = min(cnt1, cnt2)
    masm.cmovl(ConditionFlag.LessEqual, cnt2, result);
    // Is the minimum length zero?
    masm.testl(cnt2, cnt2);
    masm.jcc(ConditionFlag.Zero, LENGTH_DIFF_LABEL);
    // if (ae == StrIntrinsicNode::LL) {
    if (kind1 == JavaKind.Byte && kind2 == JavaKind.Byte) {
        // Load first bytes
        // result = str1[0]
        masm.movzbl(result, new AMD64Address(str1, 0));
        // cnt1 = str2[0]
        masm.movzbl(cnt1, new AMD64Address(str2, 0));
    // } else if (ae == StrIntrinsicNode::UU) {
    } else if (kind1 == JavaKind.Char && kind2 == JavaKind.Char) {
        // Load first characters
        masm.movzwl(result, new AMD64Address(str1, 0));
        masm.movzwl(cnt1, new AMD64Address(str2, 0));
    } else {
        masm.movzbl(result, new AMD64Address(str1, 0));
        masm.movzwl(cnt1, new AMD64Address(str2, 0));
    }
    masm.subl(result, cnt1);
    masm.jcc(ConditionFlag.NotZero, POP_LABEL);
    // if (ae == StrIntrinsicNode::UU) {
    if (kind1 == JavaKind.Char && kind2 == JavaKind.Char) {
        // Divide length by 2 to get number of chars
        masm.shrl(cnt2, 1);
    }
    masm.cmpl(cnt2, 1);
    masm.jcc(ConditionFlag.Equal, LENGTH_DIFF_LABEL);
    // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
    if (kind1 == kind2) {
        masm.cmpptr(str1, str2);
        masm.jcc(ConditionFlag.Equal, LENGTH_DIFF_LABEL);
        // if (ae == StrIntrinsicNode::LL) {
        if (kind1 == JavaKind.Byte && kind2 == JavaKind.Byte) {
            scale = AMD64Address.Scale.Times1;
            stride = 16;
        } else {
            scale = AMD64Address.Scale.Times2;
            stride = 8;
        }
    } else {
        scale1 = AMD64Address.Scale.Times1;
        scale2 = AMD64Address.Scale.Times2;
        // scale not used
        stride = 8;
    }
    // if (UseAVX >= 2 && UseSSE42Intrinsics) {
    if (supportsAVX2(crb.target) && supportsSSE42(crb.target)) {
        Register vec1 = asRegister(vectorTemp1, AMD64Kind.DOUBLE);
        // Checkstyle: stop
        Label COMPARE_WIDE_VECTORS = new Label();
        Label VECTOR_NOT_EQUAL = new Label();
        Label COMPARE_WIDE_TAIL = new Label();
        Label COMPARE_SMALL_STR = new Label();
        Label COMPARE_WIDE_VECTORS_LOOP = new Label();
        Label COMPARE_16_CHARS = new Label();
        Label COMPARE_INDEX_CHAR = new Label();
        Label COMPARE_WIDE_VECTORS_LOOP_AVX2 = new Label();
        Label COMPARE_TAIL_LONG = new Label();
        // used only _LP64 && AVX3
        Label COMPARE_WIDE_VECTORS_LOOP_AVX3 = new Label();
        // Checkstyle: resume
        int pcmpmask = 0x19;
        // if (ae == StrIntrinsicNode::LL) {
        if (kind1 == JavaKind.Byte && kind2 == JavaKind.Byte) {
            pcmpmask &= ~0x01;
        }
        // if (ae == StrIntrinsicNode::LL) {
        if (kind1 == JavaKind.Byte && kind2 == JavaKind.Byte) {
            stride2 = 32;
        } else {
            stride2 = 16;
        }
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            adr_stride = stride << scale.log2;
        } else {
            // stride << scale1;
            adr_stride1 = 8;
            // stride << scale2;
            adr_stride2 = 16;
        }
        assert result.equals(rax) && cnt2.equals(rdx) && cnt1.equals(rcx) : "pcmpestri";
        // rax and rdx are used by pcmpestri as elements counters
        masm.movl(result, cnt2);
        // cnt2 holds the vector count
        masm.andl(cnt2, ~(stride2 - 1));
        masm.jcc(ConditionFlag.Zero, COMPARE_TAIL_LONG);
        // fast path : compare first 2 8-char vectors.
        masm.bind(COMPARE_16_CHARS);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.movdqu(vec1, new AMD64Address(str1, 0));
        } else {
            masm.pmovzxbw(vec1, new AMD64Address(str1, 0));
        }
        masm.pcmpestri(vec1, new AMD64Address(str2, 0), pcmpmask);
        masm.jccb(ConditionFlag.Below, COMPARE_INDEX_CHAR);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.movdqu(vec1, new AMD64Address(str1, adr_stride));
            masm.pcmpestri(vec1, new AMD64Address(str2, adr_stride), pcmpmask);
        } else {
            masm.pmovzxbw(vec1, new AMD64Address(str1, adr_stride1));
            masm.pcmpestri(vec1, new AMD64Address(str2, adr_stride2), pcmpmask);
        }
        masm.jccb(ConditionFlag.AboveEqual, COMPARE_WIDE_VECTORS);
        masm.addl(cnt1, stride);
        // Compare the characters at index in cnt1
        // cnt1 has the offset of the mismatching character
        masm.bind(COMPARE_INDEX_CHAR);
        loadNextElements(masm, result, cnt2, str1, str2, scale, scale1, scale2, cnt1);
        masm.subl(result, cnt2);
        masm.jmp(POP_LABEL);
        // Setup the registers to start vector comparison loop
        masm.bind(COMPARE_WIDE_VECTORS);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.leaq(str1, new AMD64Address(str1, result, scale));
            masm.leaq(str2, new AMD64Address(str2, result, scale));
        } else {
            masm.leaq(str1, new AMD64Address(str1, result, scale1));
            masm.leaq(str2, new AMD64Address(str2, result, scale2));
        }
        masm.subl(result, stride2);
        masm.subl(cnt2, stride2);
        masm.jcc(ConditionFlag.Zero, COMPARE_WIDE_TAIL);
        masm.negq(result);
        // In a loop, compare 16-chars (32-bytes) at once using (vpxor+vptest)
        masm.bind(COMPARE_WIDE_VECTORS_LOOP);
        // if (VM_Version::supports_avx512vlbw()) { // trying 64 bytes fast loop
        if (supportsAVX512VLBW(crb.target)) {
            masm.cmpl(cnt2, stride2x2);
            masm.jccb(ConditionFlag.Below, COMPARE_WIDE_VECTORS_LOOP_AVX2);
            // cnt2 holds the vector count
            masm.testl(cnt2, stride2x2 - 1);
            // means we cannot subtract by 0x40
            masm.jccb(ConditionFlag.NotZero, COMPARE_WIDE_VECTORS_LOOP_AVX2);
            // the hottest loop
            masm.bind(COMPARE_WIDE_VECTORS_LOOP_AVX3);
            // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
            if (kind1 == kind2) {
                masm.evmovdquq(vec1, new AMD64Address(str1, result, scale), AvxVectorLen.AVX_512bit);
                // k7 == 11..11, if operands equal, otherwise k7 has some 0
                masm.evpcmpeqb(k7, vec1, new AMD64Address(str2, result, scale), AvxVectorLen.AVX_512bit);
            } else {
                masm.vpmovzxbw(vec1, new AMD64Address(str1, result, scale1), AvxVectorLen.AVX_512bit);
                // k7 == 11..11, if operands equal, otherwise k7 has some 0
                masm.evpcmpeqb(k7, vec1, new AMD64Address(str2, result, scale2), AvxVectorLen.AVX_512bit);
            }
            masm.kortestql(k7, k7);
            // miscompare
            masm.jcc(ConditionFlag.AboveEqual, COMPARE_WIDE_VECTORS_LOOP_FAILED);
            // update since we already compared at this addr
            masm.addq(result, stride2x2);
            // and sub the size too
            masm.subl(cnt2, stride2x2);
            masm.jccb(ConditionFlag.NotZero, COMPARE_WIDE_VECTORS_LOOP_AVX3);
            masm.vpxor(vec1, vec1, vec1);
            masm.jmpb(COMPARE_WIDE_TAIL);
        }
        masm.bind(COMPARE_WIDE_VECTORS_LOOP_AVX2);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.vmovdqu(vec1, new AMD64Address(str1, result, scale));
            masm.vpxor(vec1, vec1, new AMD64Address(str2, result, scale));
        } else {
            masm.vpmovzxbw(vec1, new AMD64Address(str1, result, scale1), AvxVectorLen.AVX_256bit);
            masm.vpxor(vec1, vec1, new AMD64Address(str2, result, scale2));
        }
        masm.vptest(vec1, vec1);
        masm.jcc(ConditionFlag.NotZero, VECTOR_NOT_EQUAL);
        masm.addq(result, stride2);
        masm.subl(cnt2, stride2);
        masm.jcc(ConditionFlag.NotZero, COMPARE_WIDE_VECTORS_LOOP);
        // clean upper bits of YMM registers
        masm.vpxor(vec1, vec1, vec1);
        // compare wide vectors tail
        masm.bind(COMPARE_WIDE_TAIL);
        masm.testq(result, result);
        masm.jcc(ConditionFlag.Zero, LENGTH_DIFF_LABEL);
        masm.movl(result, stride2);
        masm.movl(cnt2, result);
        masm.negq(result);
        masm.jmp(COMPARE_WIDE_VECTORS_LOOP_AVX2);
        // Identifies the mismatching (higher or lower)16-bytes in the 32-byte vectors.
        masm.bind(VECTOR_NOT_EQUAL);
        // clean upper bits of YMM registers
        masm.vpxor(vec1, vec1, vec1);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.leaq(str1, new AMD64Address(str1, result, scale));
            masm.leaq(str2, new AMD64Address(str2, result, scale));
        } else {
            masm.leaq(str1, new AMD64Address(str1, result, scale1));
            masm.leaq(str2, new AMD64Address(str2, result, scale2));
        }
        masm.jmp(COMPARE_16_CHARS);
        // Compare tail chars, length between 1 to 15 chars
        masm.bind(COMPARE_TAIL_LONG);
        masm.movl(cnt2, result);
        masm.cmpl(cnt2, stride);
        masm.jcc(ConditionFlag.Less, COMPARE_SMALL_STR);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.movdqu(vec1, new AMD64Address(str1, 0));
        } else {
            masm.pmovzxbw(vec1, new AMD64Address(str1, 0));
        }
        masm.pcmpestri(vec1, new AMD64Address(str2, 0), pcmpmask);
        masm.jcc(ConditionFlag.Below, COMPARE_INDEX_CHAR);
        masm.subq(cnt2, stride);
        masm.jcc(ConditionFlag.Zero, LENGTH_DIFF_LABEL);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.leaq(str1, new AMD64Address(str1, result, scale));
            masm.leaq(str2, new AMD64Address(str2, result, scale));
        } else {
            masm.leaq(str1, new AMD64Address(str1, result, scale1));
            masm.leaq(str2, new AMD64Address(str2, result, scale2));
        }
        masm.negq(cnt2);
        masm.jmpb(WHILE_HEAD_LABEL);
        masm.bind(COMPARE_SMALL_STR);
    } else if (supportsSSE42(crb.target)) {
        Register vec1 = asRegister(vectorTemp1, AMD64Kind.DOUBLE);
        // Checkstyle: stop
        Label COMPARE_WIDE_VECTORS = new Label();
        Label VECTOR_NOT_EQUAL = new Label();
        Label COMPARE_TAIL = new Label();
        // Checkstyle: resume
        int pcmpmask = 0x19;
        // Setup to compare 8-char (16-byte) vectors,
        // start from first character again because it has aligned address.
        masm.movl(result, cnt2);
        // cnt2 holds the vector count
        masm.andl(cnt2, ~(stride - 1));
        // if (ae == StrIntrinsicNode::LL) {
        if (kind1 == JavaKind.Byte && kind2 == JavaKind.Byte) {
            pcmpmask &= ~0x01;
        }
        masm.jcc(ConditionFlag.Zero, COMPARE_TAIL);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.leaq(str1, new AMD64Address(str1, result, scale));
            masm.leaq(str2, new AMD64Address(str2, result, scale));
        } else {
            masm.leaq(str1, new AMD64Address(str1, result, scale1));
            masm.leaq(str2, new AMD64Address(str2, result, scale2));
        }
        masm.negq(result);
        // rcx - first mismatched element index
        assert result.equals(rax) && cnt2.equals(rdx) && cnt1.equals(rcx) : "pcmpestri";
        masm.bind(COMPARE_WIDE_VECTORS);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.movdqu(vec1, new AMD64Address(str1, result, scale));
            masm.pcmpestri(vec1, new AMD64Address(str2, result, scale), pcmpmask);
        } else {
            masm.pmovzxbw(vec1, new AMD64Address(str1, result, scale1));
            masm.pcmpestri(vec1, new AMD64Address(str2, result, scale2), pcmpmask);
        }
        // After pcmpestri cnt1(rcx) contains mismatched element index
        // CF==1
        masm.jccb(ConditionFlag.Below, VECTOR_NOT_EQUAL);
        masm.addq(result, stride);
        masm.subq(cnt2, stride);
        masm.jccb(ConditionFlag.NotZero, COMPARE_WIDE_VECTORS);
        // compare wide vectors tail
        masm.testq(result, result);
        masm.jcc(ConditionFlag.Zero, LENGTH_DIFF_LABEL);
        masm.movl(cnt2, stride);
        masm.movl(result, stride);
        masm.negq(result);
        // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
        if (kind1 == kind2) {
            masm.movdqu(vec1, new AMD64Address(str1, result, scale));
            masm.pcmpestri(vec1, new AMD64Address(str2, result, scale), pcmpmask);
        } else {
            masm.pmovzxbw(vec1, new AMD64Address(str1, result, scale1));
            masm.pcmpestri(vec1, new AMD64Address(str2, result, scale2), pcmpmask);
        }
        masm.jccb(ConditionFlag.AboveEqual, LENGTH_DIFF_LABEL);
        // Mismatched characters in the vectors
        masm.bind(VECTOR_NOT_EQUAL);
        masm.addq(cnt1, result);
        loadNextElements(masm, result, cnt2, str1, str2, scale, scale1, scale2, cnt1);
        masm.subl(result, cnt2);
        masm.jmpb(POP_LABEL);
        // limit is zero
        masm.bind(COMPARE_TAIL);
        masm.movl(cnt2, result);
    // Fallthru to tail compare
    }
    // if (ae == StrIntrinsicNode::LL || ae == StrIntrinsicNode::UU) {
    if (kind1 == kind2) {
        masm.leaq(str1, new AMD64Address(str1, cnt2, scale));
        masm.leaq(str2, new AMD64Address(str2, cnt2, scale));
    } else {
        masm.leaq(str1, new AMD64Address(str1, cnt2, scale1));
        masm.leaq(str2, new AMD64Address(str2, cnt2, scale2));
    }
    // first character was compared already
    masm.decrementl(cnt2);
    masm.negq(cnt2);
    // Compare the rest of the elements
    masm.bind(WHILE_HEAD_LABEL);
    loadNextElements(masm, result, cnt1, str1, str2, scale, scale1, scale2, cnt2);
    masm.subl(result, cnt1);
    masm.jccb(ConditionFlag.NotZero, POP_LABEL);
    masm.incrementq(cnt2, 1);
    masm.jccb(ConditionFlag.NotZero, WHILE_HEAD_LABEL);
    // Strings are equal up to min length. Return the length difference.
    masm.bind(LENGTH_DIFF_LABEL);
    masm.pop(result);
    // if (ae == StrIntrinsicNode::UU) {
    if (kind1 == JavaKind.Char && kind2 == JavaKind.Char) {
        // Divide diff by 2 to get number of chars
        masm.sarl(result, 1);
    }
    masm.jmpb(DONE_LABEL);
    // if (VM_Version::supports_avx512vlbw()) {
    if (supportsAVX512VLBW(crb.target)) {
        masm.bind(COMPARE_WIDE_VECTORS_LOOP_FAILED);
        masm.kmovql(cnt1, k7);
        masm.notq(cnt1);
        masm.bsfq(cnt2, cnt1);
        // if (ae != StrIntrinsicNode::LL) {
        if (kind1 != JavaKind.Byte && kind2 != JavaKind.Byte) {
            // Divide diff by 2 to get number of chars
            masm.sarl(cnt2, 1);
        }
        masm.addq(result, cnt2);
        // if (ae == StrIntrinsicNode::LL) {
        if (kind1 == JavaKind.Byte && kind2 == JavaKind.Byte) {
            masm.movzbl(cnt1, new AMD64Address(str2, result, Scale.Times1));
            masm.movzbl(result, new AMD64Address(str1, result, Scale.Times1));
        } else if (kind1 == JavaKind.Char && kind2 == JavaKind.Char) {
            masm.movzwl(cnt1, new AMD64Address(str2, result, scale));
            masm.movzwl(result, new AMD64Address(str1, result, scale));
        } else {
            masm.movzwl(cnt1, new AMD64Address(str2, result, scale2));
            masm.movzbl(result, new AMD64Address(str1, result, scale1));
        }
        masm.subl(result, cnt1);
        masm.jmpb(POP_LABEL);
    }
    // Discard the stored length difference
    masm.bind(POP_LABEL);
    masm.pop(cnt1);
    // That's it
    masm.bind(DONE_LABEL);
    // if (ae == StrIntrinsicNode::UL) {
    if (kind1 == JavaKind.Char && kind2 == JavaKind.Byte) {
        masm.negl(result);
    }
}
Also used : Register(jdk.vm.ci.code.Register) ValueUtil.asRegister(jdk.vm.ci.code.ValueUtil.asRegister) Scale(org.graalvm.compiler.asm.amd64.AMD64Address.Scale) Label(org.graalvm.compiler.asm.Label) AMD64Address(org.graalvm.compiler.asm.amd64.AMD64Address)

Example 10 with AMD64Address

use of org.graalvm.compiler.asm.amd64.AMD64Address in project graal by oracle.

the class AMD64ArrayEqualsOp method emitTailCompares.

/**
 * 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);
        }
    }
}
Also used : Register(jdk.vm.ci.code.Register) ValueUtil.asRegister(jdk.vm.ci.code.ValueUtil.asRegister) Label(org.graalvm.compiler.asm.Label) AMD64Address(org.graalvm.compiler.asm.amd64.AMD64Address)

Aggregations

AMD64Address (org.graalvm.compiler.asm.amd64.AMD64Address)36 Register (jdk.vm.ci.code.Register)26 ValueUtil.asRegister (jdk.vm.ci.code.ValueUtil.asRegister)23 Label (org.graalvm.compiler.asm.Label)15 ArrayDataPointerConstant (org.graalvm.compiler.lir.asm.ArrayDataPointerConstant)7 CallingConvention (jdk.vm.ci.code.CallingConvention)6 RegisterConfig (jdk.vm.ci.code.RegisterConfig)5 TargetDescription (jdk.vm.ci.code.TargetDescription)5 Field (java.lang.reflect.Field)4 AMD64Assembler (org.graalvm.compiler.asm.amd64.AMD64Assembler)4 AssemblerTest (org.graalvm.compiler.asm.test.AssemblerTest)4 CompilationResult (org.graalvm.compiler.code.CompilationResult)4 Test (org.junit.Test)4 AMD64MacroAssembler (org.graalvm.compiler.asm.amd64.AMD64MacroAssembler)3 AMD64Kind (jdk.vm.ci.amd64.AMD64Kind)2 Scale (org.graalvm.compiler.asm.amd64.AMD64Address.Scale)2 CGlobalDataReference (com.oracle.svm.core.graal.code.CGlobalDataReference)1 SubstrateRegisterConfig (com.oracle.svm.core.graal.meta.SubstrateRegisterConfig)1 AMD64.rax (jdk.vm.ci.amd64.AMD64.rax)1 AMD64.rbx (jdk.vm.ci.amd64.AMD64.rbx)1