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llvm-mirror/lib/Target/X86/X86Schedule.td

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//===-- X86Schedule.td - X86 Scheduling Definitions --------*- tablegen -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//===----------------------------------------------------------------------===//
// InstrSchedModel annotations for out-of-order CPUs.
// Instructions with folded loads need to read the memory operand immediately,
// but other register operands don't have to be read until the load is ready.
// These operands are marked with ReadAfterLd.
def ReadAfterLd : SchedRead;
// Instructions with both a load and a store folded are modeled as a folded
// load + WriteRMW.
def WriteRMW : SchedWrite;
// Most instructions can fold loads, so almost every SchedWrite comes in two
// variants: With and without a folded load.
// An X86FoldableSchedWrite holds a reference to the corresponding SchedWrite
// with a folded load.
class X86FoldableSchedWrite : SchedWrite {
// The SchedWrite to use when a load is folded into the instruction.
SchedWrite Folded;
}
// Multiclass that produces a linked pair of SchedWrites.
multiclass X86SchedWritePair {
// Register-Memory operation.
def Ld : SchedWrite;
// Register-Register operation.
def NAME : X86FoldableSchedWrite {
let Folded = !cast<SchedWrite>(NAME#"Ld");
}
}
// Loads, stores, and moves, not folded with other operations.
def WriteLoad : SchedWrite;
def WriteStore : SchedWrite;
def WriteMove : SchedWrite;
// Arithmetic.
defm WriteALU : X86SchedWritePair; // Simple integer ALU op.
def WriteALURMW : WriteSequence<[WriteALULd, WriteStore]>;
defm WriteIMul : X86SchedWritePair; // Integer multiplication.
def WriteIMulH : SchedWrite; // Integer multiplication, high part.
defm WriteIDiv : X86SchedWritePair; // Integer division.
def WriteLEA : SchedWrite; // LEA instructions can't fold loads.
defm WriteBitScan : X86SchedWritePair; // Bit scan forward/reverse.
defm WritePOPCNT : X86SchedWritePair; // Bit population count.
defm WriteLZCNT : X86SchedWritePair; // Leading zero count.
defm WriteTZCNT : X86SchedWritePair; // Trailing zero count.
defm WriteCMOV : X86SchedWritePair; // Conditional move.
def WriteSETCC : SchedWrite; // Set register based on condition code.
def WriteSETCCStore : SchedWrite;
// Integer shifts and rotates.
defm WriteShift : X86SchedWritePair;
// BMI1 BEXTR, BMI2 BZHI
defm WriteBEXTR : X86SchedWritePair;
defm WriteBZHI : X86SchedWritePair;
// Idioms that clear a register, like xorps %xmm0, %xmm0.
// These can often bypass execution ports completely.
def WriteZero : SchedWrite;
// Branches don't produce values, so they have no latency, but they still
// consume resources. Indirect branches can fold loads.
defm WriteJump : X86SchedWritePair;
// Floating point. This covers both scalar and vector operations.
def WriteFLoad : SchedWrite;
def WriteFStore : SchedWrite;
def WriteFMove : SchedWrite;
defm WriteFAdd : X86SchedWritePair; // Floating point add/sub.
defm WriteFCmp : X86SchedWritePair; // Floating point compare.
defm WriteFCom : X86SchedWritePair; // Floating point compare to flags.
defm WriteFMul : X86SchedWritePair; // Floating point multiplication.
defm WriteFDiv : X86SchedWritePair; // Floating point division.
defm WriteFSqrt : X86SchedWritePair; // Floating point square root.
defm WriteFRcp : X86SchedWritePair; // Floating point reciprocal estimate.
defm WriteFRsqrt : X86SchedWritePair; // Floating point reciprocal square root estimate.
defm WriteFMA : X86SchedWritePair; // Fused Multiply Add.
defm WriteFMAS : X86SchedWritePair; // Fused Multiply Add (Scalar).
defm WriteFMAY : X86SchedWritePair; // Fused Multiply Add (YMM/ZMM).
defm WriteFSign : X86SchedWritePair; // Floating point fabs/fchs.
defm WriteFLogic : X86SchedWritePair; // Floating point and/or/xor logicals.
defm WriteFLogicY : X86SchedWritePair; // Floating point and/or/xor logicals (YMM/ZMM).
defm WriteFShuffle : X86SchedWritePair; // Floating point vector shuffles.
defm WriteFVarShuffle : X86SchedWritePair; // Floating point vector variable shuffles.
defm WriteFBlend : X86SchedWritePair; // Floating point vector blends.
defm WriteFVarBlend : X86SchedWritePair; // Fp vector variable blends.
// FMA Scheduling helper class.
class FMASC { X86FoldableSchedWrite Sched = WriteFAdd; }
// Horizontal Add/Sub (float and integer)
defm WriteFHAdd : X86SchedWritePair;
defm WritePHAdd : X86SchedWritePair;
// Vector integer operations.
def WriteVecLoad : SchedWrite;
def WriteVecStore : SchedWrite;
def WriteVecMove : SchedWrite;
defm WriteVecALU : X86SchedWritePair; // Vector integer ALU op, no logicals.
defm WriteVecLogic : X86SchedWritePair; // Vector integer and/or/xor logicals.
defm WriteVecShift : X86SchedWritePair; // Vector integer shifts.
defm WriteVecIMul : X86SchedWritePair; // Vector integer multiply.
defm WritePMULLD : X86SchedWritePair; // PMULLD
defm WriteShuffle : X86SchedWritePair; // Vector shuffles.
defm WriteVarShuffle : X86SchedWritePair; // Vector variable shuffles.
defm WriteBlend : X86SchedWritePair; // Vector blends.
defm WriteVarBlend : X86SchedWritePair; // Vector variable blends.
defm WritePSADBW : X86SchedWritePair; // Vector PSADBW.
defm WriteMPSAD : X86SchedWritePair; // Vector MPSAD.
defm WritePHMINPOS : X86SchedWritePair; // Vector PHMINPOS.
// Vector insert/extract operations.
defm WriteVecInsert : X86SchedWritePair; // Insert gpr to vector element.
def WriteVecExtract : SchedWrite; // Extract vector element to gpr.
def WriteVecExtractSt : SchedWrite; // Extract vector element and store.
// MOVMSK operations.
def WriteFMOVMSK : SchedWrite;
def WriteVecMOVMSK : SchedWrite;
def WriteMMXMOVMSK : SchedWrite;
// Conversion between integer and float.
defm WriteCvtF2I : X86SchedWritePair; // Float -> Integer.
defm WriteCvtI2F : X86SchedWritePair; // Integer -> Float.
defm WriteCvtF2F : X86SchedWritePair; // Float -> Float size conversion.
def WriteCvtF2FSt : SchedWrite; // // Float -> Float + store size conversion.
// CRC32 instruction.
defm WriteCRC32 : X86SchedWritePair;
// Strings instructions.
// Packed Compare Implicit Length Strings, Return Mask
defm WritePCmpIStrM : X86SchedWritePair;
// Packed Compare Explicit Length Strings, Return Mask
defm WritePCmpEStrM : X86SchedWritePair;
// Packed Compare Implicit Length Strings, Return Index
defm WritePCmpIStrI : X86SchedWritePair;
// Packed Compare Explicit Length Strings, Return Index
defm WritePCmpEStrI : X86SchedWritePair;
// AES instructions.
defm WriteAESDecEnc : X86SchedWritePair; // Decryption, encryption.
defm WriteAESIMC : X86SchedWritePair; // InvMixColumn.
defm WriteAESKeyGen : X86SchedWritePair; // Key Generation.
// Carry-less multiplication instructions.
defm WriteCLMul : X86SchedWritePair;
// Load/store MXCSR
def WriteLDMXCSR : SchedWrite;
def WriteSTMXCSR : SchedWrite;
// Catch-all for expensive system instructions.
def WriteSystem : SchedWrite;
// AVX2.
defm WriteFShuffle256 : X86SchedWritePair; // Fp 256-bit width vector shuffles.
defm WriteFVarShuffle256 : X86SchedWritePair; // Fp 256-bit width variable shuffles.
defm WriteShuffle256 : X86SchedWritePair; // 256-bit width vector shuffles.
defm WriteVarShuffle256 : X86SchedWritePair; // 256-bit width vector variable shuffles.
defm WriteVarVecShift : X86SchedWritePair; // Variable vector shifts.
// Old microcoded instructions that nobody use.
def WriteMicrocoded : SchedWrite;
// Fence instructions.
def WriteFence : SchedWrite;
// Nop, not very useful expect it provides a model for nops!
def WriteNop : SchedWrite;
//===----------------------------------------------------------------------===//
// Generic Processor Scheduler Models.
// IssueWidth is analogous to the number of decode units. Core and its
// descendents, including Nehalem and SandyBridge have 4 decoders.
// Resources beyond the decoder operate on micro-ops and are bufferred
// so adjacent micro-ops don't directly compete.
//
// MicroOpBufferSize > 1 indicates that RAW dependencies can be
// decoded in the same cycle. The value 32 is a reasonably arbitrary
// number of in-flight instructions.
//
// HighLatency=10 is optimistic. X86InstrInfo::isHighLatencyDef
// indicates high latency opcodes. Alternatively, InstrItinData
// entries may be included here to define specific operand
// latencies. Since these latencies are not used for pipeline hazards,
// they do not need to be exact.
//
// The GenericX86Model contains no instruction schedules
// and disables PostRAScheduler.
class GenericX86Model : SchedMachineModel {
let IssueWidth = 4;
let MicroOpBufferSize = 32;
let LoadLatency = 4;
let HighLatency = 10;
let PostRAScheduler = 0;
let CompleteModel = 0;
}
def GenericModel : GenericX86Model;
// Define a model with the PostRAScheduler enabled.
def GenericPostRAModel : GenericX86Model {
let PostRAScheduler = 1;
}