508 lines
22 KiB
TableGen
508 lines
22 KiB
TableGen
//==- SystemZInstrFP.td - Floating-point SystemZ instructions --*- tblgen-*-==//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//===----------------------------------------------------------------------===//
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// Select instructions
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//===----------------------------------------------------------------------===//
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// C's ?: operator for floating-point operands.
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def SelectF32 : SelectWrapper<FP32>;
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def SelectF64 : SelectWrapper<FP64>;
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def SelectF128 : SelectWrapper<FP128>;
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defm CondStoreF32 : CondStores<FP32, nonvolatile_store,
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nonvolatile_load, bdxaddr20only>;
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defm CondStoreF64 : CondStores<FP64, nonvolatile_store,
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nonvolatile_load, bdxaddr20only>;
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//===----------------------------------------------------------------------===//
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// Move instructions
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//===----------------------------------------------------------------------===//
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// Load zero.
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let hasSideEffects = 0, isAsCheapAsAMove = 1, isMoveImm = 1 in {
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def LZER : InherentRRE<"lzer", 0xB374, FP32, fpimm0>;
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def LZDR : InherentRRE<"lzdr", 0xB375, FP64, fpimm0>;
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def LZXR : InherentRRE<"lzxr", 0xB376, FP128, fpimm0>;
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}
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// Moves between two floating-point registers.
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let hasSideEffects = 0 in {
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def LER : UnaryRR <"ler", 0x38, null_frag, FP32, FP32>;
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def LDR : UnaryRR <"ldr", 0x28, null_frag, FP64, FP64>;
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def LXR : UnaryRRE<"lxr", 0xB365, null_frag, FP128, FP128>;
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// For z13 we prefer LDR over LER to avoid partial register dependencies.
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let isCodeGenOnly = 1 in
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def LDR32 : UnaryRR<"ldr", 0x28, null_frag, FP32, FP32>;
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}
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// Moves between two floating-point registers that also set the condition
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// codes.
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let Defs = [CC], CCValues = 0xF, CompareZeroCCMask = 0xF in {
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defm LTEBR : LoadAndTestRRE<"ltebr", 0xB302, FP32>;
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defm LTDBR : LoadAndTestRRE<"ltdbr", 0xB312, FP64>;
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defm LTXBR : LoadAndTestRRE<"ltxbr", 0xB342, FP128>;
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}
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// Note that LTxBRCompare is not available if we have vector support,
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// since load-and-test instructions will partially clobber the target
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// (vector) register.
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let Predicates = [FeatureNoVector] in {
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defm : CompareZeroFP<LTEBRCompare, FP32>;
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defm : CompareZeroFP<LTDBRCompare, FP64>;
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defm : CompareZeroFP<LTXBRCompare, FP128>;
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}
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// Use a normal load-and-test for compare against zero in case of
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// vector support (via a pseudo to simplify instruction selection).
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let Defs = [CC], usesCustomInserter = 1 in {
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def LTEBRCompare_VecPseudo : Pseudo<(outs), (ins FP32:$R1, FP32:$R2), []>;
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def LTDBRCompare_VecPseudo : Pseudo<(outs), (ins FP64:$R1, FP64:$R2), []>;
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def LTXBRCompare_VecPseudo : Pseudo<(outs), (ins FP128:$R1, FP128:$R2), []>;
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}
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let Predicates = [FeatureVector] in {
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defm : CompareZeroFP<LTEBRCompare_VecPseudo, FP32>;
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defm : CompareZeroFP<LTDBRCompare_VecPseudo, FP64>;
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defm : CompareZeroFP<LTXBRCompare_VecPseudo, FP128>;
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}
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// Moves between 64-bit integer and floating-point registers.
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def LGDR : UnaryRRE<"lgdr", 0xB3CD, bitconvert, GR64, FP64>;
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def LDGR : UnaryRRE<"ldgr", 0xB3C1, bitconvert, FP64, GR64>;
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// fcopysign with an FP32 result.
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let isCodeGenOnly = 1 in {
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def CPSDRss : BinaryRRFb<"cpsdr", 0xB372, fcopysign, FP32, FP32, FP32>;
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def CPSDRsd : BinaryRRFb<"cpsdr", 0xB372, fcopysign, FP32, FP32, FP64>;
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}
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// The sign of an FP128 is in the high register.
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def : Pat<(fcopysign FP32:$src1, FP128:$src2),
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(CPSDRsd FP32:$src1, (EXTRACT_SUBREG FP128:$src2, subreg_h64))>;
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// fcopysign with an FP64 result.
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let isCodeGenOnly = 1 in
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def CPSDRds : BinaryRRFb<"cpsdr", 0xB372, fcopysign, FP64, FP64, FP32>;
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def CPSDRdd : BinaryRRFb<"cpsdr", 0xB372, fcopysign, FP64, FP64, FP64>;
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// The sign of an FP128 is in the high register.
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def : Pat<(fcopysign FP64:$src1, FP128:$src2),
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(CPSDRdd FP64:$src1, (EXTRACT_SUBREG FP128:$src2, subreg_h64))>;
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// fcopysign with an FP128 result. Use "upper" as the high half and leave
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// the low half as-is.
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class CopySign128<RegisterOperand cls, dag upper>
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: Pat<(fcopysign FP128:$src1, cls:$src2),
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(INSERT_SUBREG FP128:$src1, upper, subreg_h64)>;
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def : CopySign128<FP32, (CPSDRds (EXTRACT_SUBREG FP128:$src1, subreg_h64),
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FP32:$src2)>;
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def : CopySign128<FP64, (CPSDRdd (EXTRACT_SUBREG FP128:$src1, subreg_h64),
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FP64:$src2)>;
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def : CopySign128<FP128, (CPSDRdd (EXTRACT_SUBREG FP128:$src1, subreg_h64),
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(EXTRACT_SUBREG FP128:$src2, subreg_h64))>;
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defm LoadStoreF32 : MVCLoadStore<load, f32, MVCSequence, 4>;
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defm LoadStoreF64 : MVCLoadStore<load, f64, MVCSequence, 8>;
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defm LoadStoreF128 : MVCLoadStore<load, f128, MVCSequence, 16>;
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//===----------------------------------------------------------------------===//
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// Load instructions
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//===----------------------------------------------------------------------===//
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let canFoldAsLoad = 1, SimpleBDXLoad = 1 in {
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defm LE : UnaryRXPair<"le", 0x78, 0xED64, load, FP32, 4>;
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defm LD : UnaryRXPair<"ld", 0x68, 0xED65, load, FP64, 8>;
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// For z13 we prefer LDE over LE to avoid partial register dependencies.
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def LDE32 : UnaryRXE<"lde", 0xED24, null_frag, FP32, 4>;
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// These instructions are split after register allocation, so we don't
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// want a custom inserter.
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let Has20BitOffset = 1, HasIndex = 1, Is128Bit = 1 in {
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def LX : Pseudo<(outs FP128:$dst), (ins bdxaddr20only128:$src),
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[(set FP128:$dst, (load bdxaddr20only128:$src))]>;
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}
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}
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//===----------------------------------------------------------------------===//
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// Store instructions
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//===----------------------------------------------------------------------===//
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let SimpleBDXStore = 1 in {
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defm STE : StoreRXPair<"ste", 0x70, 0xED66, store, FP32, 4>;
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defm STD : StoreRXPair<"std", 0x60, 0xED67, store, FP64, 8>;
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// These instructions are split after register allocation, so we don't
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// want a custom inserter.
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let Has20BitOffset = 1, HasIndex = 1, Is128Bit = 1 in {
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def STX : Pseudo<(outs), (ins FP128:$src, bdxaddr20only128:$dst),
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[(store FP128:$src, bdxaddr20only128:$dst)]>;
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}
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}
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//===----------------------------------------------------------------------===//
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// Conversion instructions
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//===----------------------------------------------------------------------===//
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// Convert floating-point values to narrower representations, rounding
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// according to the current mode. The destination of LEXBR and LDXBR
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// is a 128-bit value, but only the first register of the pair is used.
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def LEDBR : UnaryRRE<"ledbr", 0xB344, fpround, FP32, FP64>;
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def LEXBR : UnaryRRE<"lexbr", 0xB346, null_frag, FP128, FP128>;
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def LDXBR : UnaryRRE<"ldxbr", 0xB345, null_frag, FP128, FP128>;
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def LEDBRA : TernaryRRFe<"ledbra", 0xB344, FP32, FP64>,
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Requires<[FeatureFPExtension]>;
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def LEXBRA : TernaryRRFe<"lexbra", 0xB346, FP128, FP128>,
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Requires<[FeatureFPExtension]>;
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def LDXBRA : TernaryRRFe<"ldxbra", 0xB345, FP128, FP128>,
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Requires<[FeatureFPExtension]>;
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def : Pat<(f32 (fpround FP128:$src)),
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(EXTRACT_SUBREG (LEXBR FP128:$src), subreg_hr32)>;
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def : Pat<(f64 (fpround FP128:$src)),
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(EXTRACT_SUBREG (LDXBR FP128:$src), subreg_h64)>;
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// Extend register floating-point values to wider representations.
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def LDEBR : UnaryRRE<"ldebr", 0xB304, fpextend, FP64, FP32>;
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def LXEBR : UnaryRRE<"lxebr", 0xB306, fpextend, FP128, FP32>;
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def LXDBR : UnaryRRE<"lxdbr", 0xB305, fpextend, FP128, FP64>;
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// Extend memory floating-point values to wider representations.
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def LDEB : UnaryRXE<"ldeb", 0xED04, extloadf32, FP64, 4>;
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def LXEB : UnaryRXE<"lxeb", 0xED06, extloadf32, FP128, 4>;
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def LXDB : UnaryRXE<"lxdb", 0xED05, extloadf64, FP128, 8>;
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// Convert a signed integer register value to a floating-point one.
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def CEFBR : UnaryRRE<"cefbr", 0xB394, sint_to_fp, FP32, GR32>;
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def CDFBR : UnaryRRE<"cdfbr", 0xB395, sint_to_fp, FP64, GR32>;
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def CXFBR : UnaryRRE<"cxfbr", 0xB396, sint_to_fp, FP128, GR32>;
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def CEGBR : UnaryRRE<"cegbr", 0xB3A4, sint_to_fp, FP32, GR64>;
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def CDGBR : UnaryRRE<"cdgbr", 0xB3A5, sint_to_fp, FP64, GR64>;
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def CXGBR : UnaryRRE<"cxgbr", 0xB3A6, sint_to_fp, FP128, GR64>;
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// The FP extension feature provides versions of the above that allow
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// specifying rounding mode and inexact-exception suppression flags.
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let Predicates = [FeatureFPExtension] in {
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def CEFBRA : TernaryRRFe<"cefbra", 0xB394, FP32, GR32>;
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def CDFBRA : TernaryRRFe<"cdfbra", 0xB395, FP64, GR32>;
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def CXFBRA : TernaryRRFe<"cxfbra", 0xB396, FP128, GR32>;
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def CEGBRA : TernaryRRFe<"cegbra", 0xB3A4, FP32, GR64>;
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def CDGBRA : TernaryRRFe<"cdgbra", 0xB3A5, FP64, GR64>;
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def CXGBRA : TernaryRRFe<"cxgbra", 0xB3A6, FP128, GR64>;
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}
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// Convert am unsigned integer register value to a floating-point one.
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let Predicates = [FeatureFPExtension] in {
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def CELFBR : TernaryRRFe<"celfbr", 0xB390, FP32, GR32>;
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def CDLFBR : TernaryRRFe<"cdlfbr", 0xB391, FP64, GR32>;
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def CXLFBR : TernaryRRFe<"cxlfbr", 0xB392, FP128, GR32>;
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def CELGBR : TernaryRRFe<"celgbr", 0xB3A0, FP32, GR64>;
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def CDLGBR : TernaryRRFe<"cdlgbr", 0xB3A1, FP64, GR64>;
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def CXLGBR : TernaryRRFe<"cxlgbr", 0xB3A2, FP128, GR64>;
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def : Pat<(f32 (uint_to_fp GR32:$src)), (CELFBR 0, GR32:$src, 0)>;
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def : Pat<(f64 (uint_to_fp GR32:$src)), (CDLFBR 0, GR32:$src, 0)>;
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def : Pat<(f128 (uint_to_fp GR32:$src)), (CXLFBR 0, GR32:$src, 0)>;
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def : Pat<(f32 (uint_to_fp GR64:$src)), (CELGBR 0, GR64:$src, 0)>;
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def : Pat<(f64 (uint_to_fp GR64:$src)), (CDLGBR 0, GR64:$src, 0)>;
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def : Pat<(f128 (uint_to_fp GR64:$src)), (CXLGBR 0, GR64:$src, 0)>;
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}
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// Convert a floating-point register value to a signed integer value,
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// with the second operand (modifier M3) specifying the rounding mode.
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let Defs = [CC] in {
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def CFEBR : BinaryRRFe<"cfebr", 0xB398, GR32, FP32>;
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def CFDBR : BinaryRRFe<"cfdbr", 0xB399, GR32, FP64>;
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def CFXBR : BinaryRRFe<"cfxbr", 0xB39A, GR32, FP128>;
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def CGEBR : BinaryRRFe<"cgebr", 0xB3A8, GR64, FP32>;
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def CGDBR : BinaryRRFe<"cgdbr", 0xB3A9, GR64, FP64>;
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def CGXBR : BinaryRRFe<"cgxbr", 0xB3AA, GR64, FP128>;
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}
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// fp_to_sint always rounds towards zero, which is modifier value 5.
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def : Pat<(i32 (fp_to_sint FP32:$src)), (CFEBR 5, FP32:$src)>;
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def : Pat<(i32 (fp_to_sint FP64:$src)), (CFDBR 5, FP64:$src)>;
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def : Pat<(i32 (fp_to_sint FP128:$src)), (CFXBR 5, FP128:$src)>;
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def : Pat<(i64 (fp_to_sint FP32:$src)), (CGEBR 5, FP32:$src)>;
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def : Pat<(i64 (fp_to_sint FP64:$src)), (CGDBR 5, FP64:$src)>;
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def : Pat<(i64 (fp_to_sint FP128:$src)), (CGXBR 5, FP128:$src)>;
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// The FP extension feature provides versions of the above that allow
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// also specifying the inexact-exception suppression flag.
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let Predicates = [FeatureFPExtension], Defs = [CC] in {
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def CFEBRA : TernaryRRFe<"cfebra", 0xB398, GR32, FP32>;
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def CFDBRA : TernaryRRFe<"cfdbra", 0xB399, GR32, FP64>;
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def CFXBRA : TernaryRRFe<"cfxbra", 0xB39A, GR32, FP128>;
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def CGEBRA : TernaryRRFe<"cgebra", 0xB3A8, GR64, FP32>;
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def CGDBRA : TernaryRRFe<"cgdbra", 0xB3A9, GR64, FP64>;
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def CGXBRA : TernaryRRFe<"cgxbra", 0xB3AA, GR64, FP128>;
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}
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// Convert a floating-point register value to an unsigned integer value.
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let Predicates = [FeatureFPExtension] in {
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let Defs = [CC] in {
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def CLFEBR : TernaryRRFe<"clfebr", 0xB39C, GR32, FP32>;
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def CLFDBR : TernaryRRFe<"clfdbr", 0xB39D, GR32, FP64>;
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def CLFXBR : TernaryRRFe<"clfxbr", 0xB39E, GR32, FP128>;
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def CLGEBR : TernaryRRFe<"clgebr", 0xB3AC, GR64, FP32>;
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def CLGDBR : TernaryRRFe<"clgdbr", 0xB3AD, GR64, FP64>;
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def CLGXBR : TernaryRRFe<"clgxbr", 0xB3AE, GR64, FP128>;
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}
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def : Pat<(i32 (fp_to_uint FP32:$src)), (CLFEBR 5, FP32:$src, 0)>;
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def : Pat<(i32 (fp_to_uint FP64:$src)), (CLFDBR 5, FP64:$src, 0)>;
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def : Pat<(i32 (fp_to_uint FP128:$src)), (CLFXBR 5, FP128:$src, 0)>;
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def : Pat<(i64 (fp_to_uint FP32:$src)), (CLGEBR 5, FP32:$src, 0)>;
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def : Pat<(i64 (fp_to_uint FP64:$src)), (CLGDBR 5, FP64:$src, 0)>;
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def : Pat<(i64 (fp_to_uint FP128:$src)), (CLGXBR 5, FP128:$src, 0)>;
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}
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//===----------------------------------------------------------------------===//
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// Unary arithmetic
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//===----------------------------------------------------------------------===//
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// We prefer generic instructions during isel, because they do not
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// clobber CC and therefore give the scheduler more freedom. In cases
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// the CC is actually useful, the SystemZElimCompare pass will try to
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// convert generic instructions into opcodes that also set CC. Note
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// that lcdf / lpdf / lndf only affect the sign bit, and can therefore
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// be used with fp32 as well. This could be done for fp128, in which
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// case the operands would have to be tied.
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// Negation (Load Complement).
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let Defs = [CC], CCValues = 0xF, CompareZeroCCMask = 0xF in {
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def LCEBR : UnaryRRE<"lcebr", 0xB303, null_frag, FP32, FP32>;
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def LCDBR : UnaryRRE<"lcdbr", 0xB313, null_frag, FP64, FP64>;
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def LCXBR : UnaryRRE<"lcxbr", 0xB343, fneg, FP128, FP128>;
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}
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// Generic form, which does not set CC.
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def LCDFR : UnaryRRE<"lcdfr", 0xB373, fneg, FP64, FP64>;
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let isCodeGenOnly = 1 in
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def LCDFR_32 : UnaryRRE<"lcdfr", 0xB373, fneg, FP32, FP32>;
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// Absolute value (Load Positive).
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let Defs = [CC], CCValues = 0xF, CompareZeroCCMask = 0xF in {
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def LPEBR : UnaryRRE<"lpebr", 0xB300, null_frag, FP32, FP32>;
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def LPDBR : UnaryRRE<"lpdbr", 0xB310, null_frag, FP64, FP64>;
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def LPXBR : UnaryRRE<"lpxbr", 0xB340, fabs, FP128, FP128>;
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}
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// Generic form, which does not set CC.
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def LPDFR : UnaryRRE<"lpdfr", 0xB370, fabs, FP64, FP64>;
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let isCodeGenOnly = 1 in
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def LPDFR_32 : UnaryRRE<"lpdfr", 0xB370, fabs, FP32, FP32>;
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// Negative absolute value (Load Negative).
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let Defs = [CC], CCValues = 0xF, CompareZeroCCMask = 0xF in {
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def LNEBR : UnaryRRE<"lnebr", 0xB301, null_frag, FP32, FP32>;
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def LNDBR : UnaryRRE<"lndbr", 0xB311, null_frag, FP64, FP64>;
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def LNXBR : UnaryRRE<"lnxbr", 0xB341, fnabs, FP128, FP128>;
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}
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// Generic form, which does not set CC.
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def LNDFR : UnaryRRE<"lndfr", 0xB371, fnabs, FP64, FP64>;
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let isCodeGenOnly = 1 in
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def LNDFR_32 : UnaryRRE<"lndfr", 0xB371, fnabs, FP32, FP32>;
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// Square root.
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def SQEBR : UnaryRRE<"sqebr", 0xB314, fsqrt, FP32, FP32>;
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def SQDBR : UnaryRRE<"sqdbr", 0xB315, fsqrt, FP64, FP64>;
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def SQXBR : UnaryRRE<"sqxbr", 0xB316, fsqrt, FP128, FP128>;
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def SQEB : UnaryRXE<"sqeb", 0xED14, loadu<fsqrt>, FP32, 4>;
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def SQDB : UnaryRXE<"sqdb", 0xED15, loadu<fsqrt>, FP64, 8>;
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// Round to an integer, with the second operand (modifier M3) specifying
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// the rounding mode. These forms always check for inexact conditions.
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def FIEBR : BinaryRRFe<"fiebr", 0xB357, FP32, FP32>;
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def FIDBR : BinaryRRFe<"fidbr", 0xB35F, FP64, FP64>;
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def FIXBR : BinaryRRFe<"fixbr", 0xB347, FP128, FP128>;
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// frint rounds according to the current mode (modifier 0) and detects
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// inexact conditions.
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def : Pat<(frint FP32:$src), (FIEBR 0, FP32:$src)>;
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def : Pat<(frint FP64:$src), (FIDBR 0, FP64:$src)>;
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def : Pat<(frint FP128:$src), (FIXBR 0, FP128:$src)>;
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let Predicates = [FeatureFPExtension] in {
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// Extended forms of the FIxBR instructions. M4 can be set to 4
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// to suppress detection of inexact conditions.
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def FIEBRA : TernaryRRFe<"fiebra", 0xB357, FP32, FP32>;
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def FIDBRA : TernaryRRFe<"fidbra", 0xB35F, FP64, FP64>;
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def FIXBRA : TernaryRRFe<"fixbra", 0xB347, FP128, FP128>;
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// fnearbyint is like frint but does not detect inexact conditions.
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def : Pat<(fnearbyint FP32:$src), (FIEBRA 0, FP32:$src, 4)>;
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def : Pat<(fnearbyint FP64:$src), (FIDBRA 0, FP64:$src, 4)>;
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def : Pat<(fnearbyint FP128:$src), (FIXBRA 0, FP128:$src, 4)>;
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// floor is no longer allowed to raise an inexact condition,
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// so restrict it to the cases where the condition can be suppressed.
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// Mode 7 is round towards -inf.
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def : Pat<(ffloor FP32:$src), (FIEBRA 7, FP32:$src, 4)>;
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def : Pat<(ffloor FP64:$src), (FIDBRA 7, FP64:$src, 4)>;
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def : Pat<(ffloor FP128:$src), (FIXBRA 7, FP128:$src, 4)>;
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// Same idea for ceil, where mode 6 is round towards +inf.
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def : Pat<(fceil FP32:$src), (FIEBRA 6, FP32:$src, 4)>;
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def : Pat<(fceil FP64:$src), (FIDBRA 6, FP64:$src, 4)>;
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def : Pat<(fceil FP128:$src), (FIXBRA 6, FP128:$src, 4)>;
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// Same idea for trunc, where mode 5 is round towards zero.
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def : Pat<(ftrunc FP32:$src), (FIEBRA 5, FP32:$src, 4)>;
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def : Pat<(ftrunc FP64:$src), (FIDBRA 5, FP64:$src, 4)>;
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def : Pat<(ftrunc FP128:$src), (FIXBRA 5, FP128:$src, 4)>;
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// Same idea for round, where mode 1 is round towards nearest with
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// ties away from zero.
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def : Pat<(fround FP32:$src), (FIEBRA 1, FP32:$src, 4)>;
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def : Pat<(fround FP64:$src), (FIDBRA 1, FP64:$src, 4)>;
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def : Pat<(fround FP128:$src), (FIXBRA 1, FP128:$src, 4)>;
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}
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//===----------------------------------------------------------------------===//
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// Binary arithmetic
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//===----------------------------------------------------------------------===//
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// Addition.
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let Defs = [CC], CCValues = 0xF, CompareZeroCCMask = 0xF in {
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|
let isCommutable = 1 in {
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|
def AEBR : BinaryRRE<"aebr", 0xB30A, fadd, FP32, FP32>;
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def ADBR : BinaryRRE<"adbr", 0xB31A, fadd, FP64, FP64>;
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def AXBR : BinaryRRE<"axbr", 0xB34A, fadd, FP128, FP128>;
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}
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def AEB : BinaryRXE<"aeb", 0xED0A, fadd, FP32, load, 4>;
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def ADB : BinaryRXE<"adb", 0xED1A, fadd, FP64, load, 8>;
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}
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|
|
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// Subtraction.
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|
let Defs = [CC], CCValues = 0xF, CompareZeroCCMask = 0xF in {
|
|
def SEBR : BinaryRRE<"sebr", 0xB30B, fsub, FP32, FP32>;
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def SDBR : BinaryRRE<"sdbr", 0xB31B, fsub, FP64, FP64>;
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def SXBR : BinaryRRE<"sxbr", 0xB34B, fsub, FP128, FP128>;
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|
|
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def SEB : BinaryRXE<"seb", 0xED0B, fsub, FP32, load, 4>;
|
|
def SDB : BinaryRXE<"sdb", 0xED1B, fsub, FP64, load, 8>;
|
|
}
|
|
|
|
// Multiplication.
|
|
let isCommutable = 1 in {
|
|
def MEEBR : BinaryRRE<"meebr", 0xB317, fmul, FP32, FP32>;
|
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def MDBR : BinaryRRE<"mdbr", 0xB31C, fmul, FP64, FP64>;
|
|
def MXBR : BinaryRRE<"mxbr", 0xB34C, fmul, FP128, FP128>;
|
|
}
|
|
def MEEB : BinaryRXE<"meeb", 0xED17, fmul, FP32, load, 4>;
|
|
def MDB : BinaryRXE<"mdb", 0xED1C, fmul, FP64, load, 8>;
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|
|
|
// f64 multiplication of two FP32 registers.
|
|
def MDEBR : BinaryRRE<"mdebr", 0xB30C, null_frag, FP64, FP32>;
|
|
def : Pat<(fmul (f64 (fpextend FP32:$src1)), (f64 (fpextend FP32:$src2))),
|
|
(MDEBR (INSERT_SUBREG (f64 (IMPLICIT_DEF)),
|
|
FP32:$src1, subreg_r32), FP32:$src2)>;
|
|
|
|
// f64 multiplication of an FP32 register and an f32 memory.
|
|
def MDEB : BinaryRXE<"mdeb", 0xED0C, null_frag, FP64, load, 4>;
|
|
def : Pat<(fmul (f64 (fpextend FP32:$src1)),
|
|
(f64 (extloadf32 bdxaddr12only:$addr))),
|
|
(MDEB (INSERT_SUBREG (f64 (IMPLICIT_DEF)), FP32:$src1, subreg_r32),
|
|
bdxaddr12only:$addr)>;
|
|
|
|
// f128 multiplication of two FP64 registers.
|
|
def MXDBR : BinaryRRE<"mxdbr", 0xB307, null_frag, FP128, FP64>;
|
|
def : Pat<(fmul (f128 (fpextend FP64:$src1)), (f128 (fpextend FP64:$src2))),
|
|
(MXDBR (INSERT_SUBREG (f128 (IMPLICIT_DEF)),
|
|
FP64:$src1, subreg_h64), FP64:$src2)>;
|
|
|
|
// f128 multiplication of an FP64 register and an f64 memory.
|
|
def MXDB : BinaryRXE<"mxdb", 0xED07, null_frag, FP128, load, 8>;
|
|
def : Pat<(fmul (f128 (fpextend FP64:$src1)),
|
|
(f128 (extloadf64 bdxaddr12only:$addr))),
|
|
(MXDB (INSERT_SUBREG (f128 (IMPLICIT_DEF)), FP64:$src1, subreg_h64),
|
|
bdxaddr12only:$addr)>;
|
|
|
|
// Fused multiply-add.
|
|
def MAEBR : TernaryRRD<"maebr", 0xB30E, z_fma, FP32>;
|
|
def MADBR : TernaryRRD<"madbr", 0xB31E, z_fma, FP64>;
|
|
|
|
def MAEB : TernaryRXF<"maeb", 0xED0E, z_fma, FP32, load, 4>;
|
|
def MADB : TernaryRXF<"madb", 0xED1E, z_fma, FP64, load, 8>;
|
|
|
|
// Fused multiply-subtract.
|
|
def MSEBR : TernaryRRD<"msebr", 0xB30F, z_fms, FP32>;
|
|
def MSDBR : TernaryRRD<"msdbr", 0xB31F, z_fms, FP64>;
|
|
|
|
def MSEB : TernaryRXF<"mseb", 0xED0F, z_fms, FP32, load, 4>;
|
|
def MSDB : TernaryRXF<"msdb", 0xED1F, z_fms, FP64, load, 8>;
|
|
|
|
// Division.
|
|
def DEBR : BinaryRRE<"debr", 0xB30D, fdiv, FP32, FP32>;
|
|
def DDBR : BinaryRRE<"ddbr", 0xB31D, fdiv, FP64, FP64>;
|
|
def DXBR : BinaryRRE<"dxbr", 0xB34D, fdiv, FP128, FP128>;
|
|
|
|
def DEB : BinaryRXE<"deb", 0xED0D, fdiv, FP32, load, 4>;
|
|
def DDB : BinaryRXE<"ddb", 0xED1D, fdiv, FP64, load, 8>;
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Comparisons
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
let Defs = [CC], CCValues = 0xF in {
|
|
def CEBR : CompareRRE<"cebr", 0xB309, z_fcmp, FP32, FP32>;
|
|
def CDBR : CompareRRE<"cdbr", 0xB319, z_fcmp, FP64, FP64>;
|
|
def CXBR : CompareRRE<"cxbr", 0xB349, z_fcmp, FP128, FP128>;
|
|
|
|
def CEB : CompareRXE<"ceb", 0xED09, z_fcmp, FP32, load, 4>;
|
|
def CDB : CompareRXE<"cdb", 0xED19, z_fcmp, FP64, load, 8>;
|
|
}
|
|
|
|
// Test Data Class.
|
|
let Defs = [CC], CCValues = 0xC in {
|
|
def TCEB : TestRXE<"tceb", 0xED10, z_tdc, FP32>;
|
|
def TCDB : TestRXE<"tcdb", 0xED11, z_tdc, FP64>;
|
|
def TCXB : TestRXE<"tcxb", 0xED12, z_tdc, FP128>;
|
|
}
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Floating-point control register instructions
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
let hasSideEffects = 1 in {
|
|
def EFPC : InherentRRE<"efpc", 0xB38C, GR32, int_s390_efpc>;
|
|
def STFPC : StoreInherentS<"stfpc", 0xB29C, storei<int_s390_efpc>, 4>;
|
|
|
|
def SFPC : SideEffectUnaryRRE<"sfpc", 0xB384, GR32, int_s390_sfpc>;
|
|
def LFPC : SideEffectUnaryS<"lfpc", 0xB29D, loadu<int_s390_sfpc>, 4>;
|
|
|
|
def SFASR : SideEffectUnaryRRE<"sfasr", 0xB385, GR32, null_frag>;
|
|
def LFAS : SideEffectUnaryS<"lfas", 0xB2BD, null_frag, 4>;
|
|
|
|
def SRNMB : SideEffectAddressS<"srnmb", 0xB2B8, null_frag, shift12only>,
|
|
Requires<[FeatureFPExtension]>;
|
|
def SRNM : SideEffectAddressS<"srnm", 0xB299, null_frag, shift12only>;
|
|
def SRNMT : SideEffectAddressS<"srnmt", 0xB2B9, null_frag, shift12only>;
|
|
}
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Peepholes
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
def : Pat<(f32 fpimmneg0), (LCDFR_32 (LZER))>;
|
|
def : Pat<(f64 fpimmneg0), (LCDFR (LZDR))>;
|
|
def : Pat<(f128 fpimmneg0), (LCXBR (LZXR))>;
|