lib/Target/X86/X86SchedSandyBridge.td - llvm - Git at Google

 //=- X86SchedSandyBridge.td - X86 Sandy Bridge Scheduling ----*- tablegen -*-=//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the machine model for Sandy Bridge to support instruction
 // scheduling and other instruction cost heuristics.
 //
 //===----------------------------------------------------------------------===//

 def SandyBridgeModel : SchedMachineModel {
   // All x86 instructions are modeled as a single micro-op, and SB can decode 4
   // instructions per cycle.
   // FIXME: Identify instructions that aren't a single fused micro-op.
   let IssueWidth = 4;
   let MicroOpBufferSize = 168; // Based on the reorder buffer.
   let LoadLatency = 4;
   let MispredictPenalty = 16;

   // Based on the LSD (loop-stream detector) queue size.
   let LoopMicroOpBufferSize = 28;

   // FIXME: SSE4 and AVX are unimplemented. This flag is set to allow
   // the scheduler to assign a default model to unrecognized opcodes.
   let CompleteModel = 0;
 }

 let SchedModel = SandyBridgeModel in {

 // Sandy Bridge can issue micro-ops to 6 different ports in one cycle.

 // Ports 0, 1, and 5 handle all computation.
 def SBPort0 : ProcResource<1>;
 def SBPort1 : ProcResource<1>;
 def SBPort5 : ProcResource<1>;

 // Ports 2 and 3 are identical. They handle loads and the address half of
 // stores.
 def SBPort23 : ProcResource<2>;

 // Port 4 gets the data half of stores. Store data can be available later than
 // the store address, but since we don't model the latency of stores, we can
 // ignore that.
 def SBPort4 : ProcResource<1>;

 // Many micro-ops are capable of issuing on multiple ports.
 def SBPort05  : ProcResGroup<[SBPort0, SBPort5]>;
 def SBPort15  : ProcResGroup<[SBPort1, SBPort5]>;
 def SBPort015 : ProcResGroup<[SBPort0, SBPort1, SBPort5]>;

 // 54 Entry Unified Scheduler
 def SBPortAny : ProcResGroup<[SBPort0, SBPort1, SBPort23, SBPort4, SBPort5]> {
   let BufferSize=54;
 }

 // Integer division issued on port 0.
 def SBDivider : ProcResource<1>;

 // Loads are 4 cycles, so ReadAfterLd registers needn't be available until 4
 // cycles after the memory operand.
 def : ReadAdvance<ReadAfterLd, 4>;

 // Many SchedWrites are defined in pairs with and without a folded load.
 // Instructions with folded loads are usually micro-fused, so they only appear
 // as two micro-ops when queued in the reservation station.
 // This multiclass defines the resource usage for variants with and without
 // folded loads.
 multiclass SBWriteResPair<X86FoldableSchedWrite SchedRW,
                           ProcResourceKind ExePort,
                           int Lat> {
   // Register variant is using a single cycle on ExePort.
   def : WriteRes<SchedRW, [ExePort]> { let Latency = Lat; }

   // Memory variant also uses a cycle on port 2/3 and adds 4 cycles to the
   // latency.
   def : WriteRes<SchedRW.Folded, [SBPort23, ExePort]> {
      let Latency = !add(Lat, 4);
   }
 }

 // A folded store needs a cycle on port 4 for the store data, but it does not
 // need an extra port 2/3 cycle to recompute the address.
 def : WriteRes<WriteRMW, [SBPort4]>;

 def : WriteRes<WriteStore, [SBPort23, SBPort4]>;
 def : WriteRes<WriteLoad,  [SBPort23]> { let Latency = 4; }
 def : WriteRes<WriteMove,  [SBPort015]>;
 def : WriteRes<WriteZero,  []>;

 defm : SBWriteResPair<WriteALU,   SBPort015, 1>;
 defm : SBWriteResPair<WriteIMul,  SBPort1,   3>;
 def  : WriteRes<WriteIMulH, []> { let Latency = 3; }
 defm : SBWriteResPair<WriteShift, SBPort05,  1>;
 defm : SBWriteResPair<WriteJump,  SBPort5,   1>;

 // This is for simple LEAs with one or two input operands.
 // The complex ones can only execute on port 1, and they require two cycles on
 // the port to read all inputs. We don't model that.
 def : WriteRes<WriteLEA, [SBPort15]>;

 // This is quite rough, latency depends on the dividend.
 def : WriteRes<WriteIDiv, [SBPort0, SBDivider]> {
   let Latency = 25;
   let ResourceCycles = [1, 10];
 }
 def : WriteRes<WriteIDivLd, [SBPort23, SBPort0, SBDivider]> {
   let Latency = 29;
   let ResourceCycles = [1, 1, 10];
 }

 // Scalar and vector floating point.
 defm : SBWriteResPair<WriteFAdd,   SBPort1, 3>;
 defm : SBWriteResPair<WriteFMul,   SBPort0, 5>;
 defm : SBWriteResPair<WriteFDiv,   SBPort0, 12>; // 10-14 cycles.
 defm : SBWriteResPair<WriteFRcp,   SBPort0, 5>;
 defm : SBWriteResPair<WriteFRsqrt, SBPort0, 5>;
 defm : SBWriteResPair<WriteFSqrt,  SBPort0, 15>;
 defm : SBWriteResPair<WriteCvtF2I, SBPort1, 3>;
 defm : SBWriteResPair<WriteCvtI2F, SBPort1, 4>;
 defm : SBWriteResPair<WriteCvtF2F, SBPort1, 3>;
 defm : SBWriteResPair<WriteFShuffle,  SBPort5,  1>;
 defm : SBWriteResPair<WriteFBlend,  SBPort05,  1>;
 def : WriteRes<WriteFVarBlend, [SBPort0, SBPort5]> {
   let Latency = 2;
   let ResourceCycles = [1, 1];
 }
 def : WriteRes<WriteFVarBlendLd, [SBPort0, SBPort5, SBPort23]> {
   let Latency = 6;
   let ResourceCycles = [1, 1, 1];
 }

 // Vector integer operations.
 defm : SBWriteResPair<WriteVecShift, SBPort05,  1>;
 defm : SBWriteResPair<WriteVecLogic, SBPort015, 1>;
 defm : SBWriteResPair<WriteVecALU,   SBPort15,  1>;
 defm : SBWriteResPair<WriteVecIMul,  SBPort0,   5>;
 defm : SBWriteResPair<WriteShuffle,  SBPort15,  1>;
 defm : SBWriteResPair<WriteBlend,  SBPort15,  1>;
 def : WriteRes<WriteVarBlend, [SBPort1, SBPort5]> {
   let Latency = 2;
   let ResourceCycles = [1, 1];
 }
 def : WriteRes<WriteVarBlendLd, [SBPort1, SBPort5, SBPort23]> {
   let Latency = 6;
   let ResourceCycles = [1, 1, 1];
 }
 def : WriteRes<WriteMPSAD, [SBPort0, SBPort1, SBPort5]> {
   let Latency = 6;
   let ResourceCycles = [1, 1, 1];
 }
 def : WriteRes<WriteMPSADLd, [SBPort0, SBPort1, SBPort5, SBPort23]> {
   let Latency = 6;
   let ResourceCycles = [1, 1, 1, 1];
 }

 ////////////////////////////////////////////////////////////////////////////////
 // Horizontal add/sub  instructions.
 ////////////////////////////////////////////////////////////////////////////////
 // HADD, HSUB PS/PD
 // x,x / v,v,v.
 def : WriteRes<WriteFHAdd, [SBPort1]> {
   let Latency = 3;
 }

 // x,m / v,v,m.
 def : WriteRes<WriteFHAddLd, [SBPort1, SBPort23]> {
   let Latency = 7;
   let ResourceCycles = [1, 1];
 }

 // PHADD|PHSUB (S) W/D.
 // v <- v,v.
 def : WriteRes<WritePHAdd, [SBPort15]>;

 // v <- v,m.
 def : WriteRes<WritePHAddLd, [SBPort15, SBPort23]> {
   let Latency = 5;
   let ResourceCycles = [1, 1];
 }

 // String instructions.
 // Packed Compare Implicit Length Strings, Return Mask
 def : WriteRes<WritePCmpIStrM, [SBPort015]> {
   let Latency = 11;
   let ResourceCycles = [3];
 }
 def : WriteRes<WritePCmpIStrMLd, [SBPort015, SBPort23]> {
   let Latency = 11;
   let ResourceCycles = [3, 1];
 }

 // Packed Compare Explicit Length Strings, Return Mask
 def : WriteRes<WritePCmpEStrM, [SBPort015]> {
   let Latency = 11;
   let ResourceCycles = [8];
 }
 def : WriteRes<WritePCmpEStrMLd, [SBPort015, SBPort23]> {
   let Latency = 11;
   let ResourceCycles = [7, 1];
 }

 // Packed Compare Implicit Length Strings, Return Index
 def : WriteRes<WritePCmpIStrI, [SBPort015]> {
   let Latency = 3;
   let ResourceCycles = [3];
 }
 def : WriteRes<WritePCmpIStrILd, [SBPort015, SBPort23]> {
   let Latency = 3;
   let ResourceCycles = [3, 1];
 }

 // Packed Compare Explicit Length Strings, Return Index
 def : WriteRes<WritePCmpEStrI, [SBPort015]> {
   let Latency = 4;
   let ResourceCycles = [8];
 }
 def : WriteRes<WritePCmpEStrILd, [SBPort015, SBPort23]> {
   let Latency = 4;
   let ResourceCycles = [7, 1];
 }

 // AES Instructions.
 def : WriteRes<WriteAESDecEnc, [SBPort015]> {
   let Latency = 8;
   let ResourceCycles = [2];
 }
 def : WriteRes<WriteAESDecEncLd, [SBPort015, SBPort23]> {
   let Latency = 8;
   let ResourceCycles = [2, 1];
 }

 def : WriteRes<WriteAESIMC, [SBPort015]> {
   let Latency = 8;
   let ResourceCycles = [2];
 }
 def : WriteRes<WriteAESIMCLd, [SBPort015, SBPort23]> {
   let Latency = 8;
   let ResourceCycles = [2, 1];
 }

 def : WriteRes<WriteAESKeyGen, [SBPort015]> {
   let Latency = 8;
   let ResourceCycles = [11];
 }
 def : WriteRes<WriteAESKeyGenLd, [SBPort015, SBPort23]> {
   let Latency = 8;
   let ResourceCycles = [10, 1];
 }

 // Carry-less multiplication instructions.
 def : WriteRes<WriteCLMul, [SBPort015]> {
   let Latency = 14;
   let ResourceCycles = [18];
 }
 def : WriteRes<WriteCLMulLd, [SBPort015, SBPort23]> {
   let Latency = 14;
   let ResourceCycles = [17, 1];
 }


 def : WriteRes<WriteSystem,     [SBPort015]> { let Latency = 100; }
 def : WriteRes<WriteMicrocoded, [SBPort015]> { let Latency = 100; }
 def : WriteRes<WriteFence, [SBPort23, SBPort4]>;
 def : WriteRes<WriteNop, []>;

 // AVX2 is not supported on that architecture, but we should define the basic
 // scheduling resources anyway.
 defm : SBWriteResPair<WriteFShuffle256, SBPort0,  1>;
 defm : SBWriteResPair<WriteShuffle256, SBPort0,  1>;
 defm : SBWriteResPair<WriteVarVecShift, SBPort0,  1>;
 } // SchedModel
	//=- X86SchedSandyBridge.td - X86 Sandy Bridge Scheduling ----- tablegen --=//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the machine model for Sandy Bridge to support instruction
	// scheduling and other instruction cost heuristics.
	//
	//===----------------------------------------------------------------------===//

	def SandyBridgeModel : SchedMachineModel {
	// All x86 instructions are modeled as a single micro-op, and SB can decode 4
	// instructions per cycle.
	// FIXME: Identify instructions that aren't a single fused micro-op.
	let IssueWidth = 4;
	let MicroOpBufferSize = 168; // Based on the reorder buffer.
	let LoadLatency = 4;
	let MispredictPenalty = 16;

	// Based on the LSD (loop-stream detector) queue size.
	let LoopMicroOpBufferSize = 28;

	// FIXME: SSE4 and AVX are unimplemented. This flag is set to allow
	// the scheduler to assign a default model to unrecognized opcodes.
	let CompleteModel = 0;
	}

	let SchedModel = SandyBridgeModel in {

	// Sandy Bridge can issue micro-ops to 6 different ports in one cycle.

	// Ports 0, 1, and 5 handle all computation.
	def SBPort0 : ProcResource<1>;
	def SBPort1 : ProcResource<1>;
	def SBPort5 : ProcResource<1>;

	// Ports 2 and 3 are identical. They handle loads and the address half of
	// stores.
	def SBPort23 : ProcResource<2>;

	// Port 4 gets the data half of stores. Store data can be available later than
	// the store address, but since we don't model the latency of stores, we can
	// ignore that.
	def SBPort4 : ProcResource<1>;

	// Many micro-ops are capable of issuing on multiple ports.
	def SBPort05 : ProcResGroup<[SBPort0, SBPort5]>;
	def SBPort15 : ProcResGroup<[SBPort1, SBPort5]>;
	def SBPort015 : ProcResGroup<[SBPort0, SBPort1, SBPort5]>;

	// 54 Entry Unified Scheduler
	def SBPortAny : ProcResGroup<[SBPort0, SBPort1, SBPort23, SBPort4, SBPort5]> {
	let BufferSize=54;
	}

	// Integer division issued on port 0.
	def SBDivider : ProcResource<1>;

	// Loads are 4 cycles, so ReadAfterLd registers needn't be available until 4
	// cycles after the memory operand.
	def : ReadAdvance<ReadAfterLd, 4>;

	// Many SchedWrites are defined in pairs with and without a folded load.
	// Instructions with folded loads are usually micro-fused, so they only appear
	// as two micro-ops when queued in the reservation station.
	// This multiclass defines the resource usage for variants with and without
	// folded loads.
	multiclass SBWriteResPair<X86FoldableSchedWrite SchedRW,
	ProcResourceKind ExePort,
	int Lat> {
	// Register variant is using a single cycle on ExePort.
	def : WriteRes<SchedRW, [ExePort]> { let Latency = Lat; }

	// Memory variant also uses a cycle on port 2/3 and adds 4 cycles to the
	// latency.
	def : WriteRes<SchedRW.Folded, [SBPort23, ExePort]> {
	let Latency = !add(Lat, 4);
	}
	}

	// A folded store needs a cycle on port 4 for the store data, but it does not
	// need an extra port 2/3 cycle to recompute the address.
	def : WriteRes<WriteRMW, [SBPort4]>;

	def : WriteRes<WriteStore, [SBPort23, SBPort4]>;
	def : WriteRes<WriteLoad, [SBPort23]> { let Latency = 4; }
	def : WriteRes<WriteMove, [SBPort015]>;
	def : WriteRes<WriteZero, []>;

	defm : SBWriteResPair<WriteALU, SBPort015, 1>;
	defm : SBWriteResPair<WriteIMul, SBPort1, 3>;
	def : WriteRes<WriteIMulH, []> { let Latency = 3; }
	defm : SBWriteResPair<WriteShift, SBPort05, 1>;
	defm : SBWriteResPair<WriteJump, SBPort5, 1>;

	// This is for simple LEAs with one or two input operands.
	// The complex ones can only execute on port 1, and they require two cycles on
	// the port to read all inputs. We don't model that.
	def : WriteRes<WriteLEA, [SBPort15]>;

	// This is quite rough, latency depends on the dividend.
	def : WriteRes<WriteIDiv, [SBPort0, SBDivider]> {
	let Latency = 25;
	let ResourceCycles = [1, 10];
	}
	def : WriteRes<WriteIDivLd, [SBPort23, SBPort0, SBDivider]> {
	let Latency = 29;
	let ResourceCycles = [1, 1, 10];
	}

	// Scalar and vector floating point.
	defm : SBWriteResPair<WriteFAdd, SBPort1, 3>;
	defm : SBWriteResPair<WriteFMul, SBPort0, 5>;
	defm : SBWriteResPair<WriteFDiv, SBPort0, 12>; // 10-14 cycles.
	defm : SBWriteResPair<WriteFRcp, SBPort0, 5>;
	defm : SBWriteResPair<WriteFRsqrt, SBPort0, 5>;
	defm : SBWriteResPair<WriteFSqrt, SBPort0, 15>;
	defm : SBWriteResPair<WriteCvtF2I, SBPort1, 3>;
	defm : SBWriteResPair<WriteCvtI2F, SBPort1, 4>;
	defm : SBWriteResPair<WriteCvtF2F, SBPort1, 3>;
	defm : SBWriteResPair<WriteFShuffle, SBPort5, 1>;
	defm : SBWriteResPair<WriteFBlend, SBPort05, 1>;
	def : WriteRes<WriteFVarBlend, [SBPort0, SBPort5]> {
	let Latency = 2;
	let ResourceCycles = [1, 1];
	}
	def : WriteRes<WriteFVarBlendLd, [SBPort0, SBPort5, SBPort23]> {
	let Latency = 6;
	let ResourceCycles = [1, 1, 1];
	}

	// Vector integer operations.
	defm : SBWriteResPair<WriteVecShift, SBPort05, 1>;
	defm : SBWriteResPair<WriteVecLogic, SBPort015, 1>;
	defm : SBWriteResPair<WriteVecALU, SBPort15, 1>;
	defm : SBWriteResPair<WriteVecIMul, SBPort0, 5>;
	defm : SBWriteResPair<WriteShuffle, SBPort15, 1>;
	defm : SBWriteResPair<WriteBlend, SBPort15, 1>;
	def : WriteRes<WriteVarBlend, [SBPort1, SBPort5]> {
	let Latency = 2;
	let ResourceCycles = [1, 1];
	}
	def : WriteRes<WriteVarBlendLd, [SBPort1, SBPort5, SBPort23]> {
	let Latency = 6;
	let ResourceCycles = [1, 1, 1];
	}
	def : WriteRes<WriteMPSAD, [SBPort0, SBPort1, SBPort5]> {
	let Latency = 6;
	let ResourceCycles = [1, 1, 1];
	}
	def : WriteRes<WriteMPSADLd, [SBPort0, SBPort1, SBPort5, SBPort23]> {
	let Latency = 6;
	let ResourceCycles = [1, 1, 1, 1];
	}

	////////////////////////////////////////////////////////////////////////////////
	// Horizontal add/sub instructions.
	////////////////////////////////////////////////////////////////////////////////
	// HADD, HSUB PS/PD
	// x,x / v,v,v.
	def : WriteRes<WriteFHAdd, [SBPort1]> {
	let Latency = 3;
	}

	// x,m / v,v,m.
	def : WriteRes<WriteFHAddLd, [SBPort1, SBPort23]> {
	let Latency = 7;
	let ResourceCycles = [1, 1];
	}

	// PHADD\|PHSUB (S) W/D.
	// v <- v,v.
	def : WriteRes<WritePHAdd, [SBPort15]>;

	// v <- v,m.
	def : WriteRes<WritePHAddLd, [SBPort15, SBPort23]> {
	let Latency = 5;
	let ResourceCycles = [1, 1];
	}

	// String instructions.
	// Packed Compare Implicit Length Strings, Return Mask
	def : WriteRes<WritePCmpIStrM, [SBPort015]> {
	let Latency = 11;
	let ResourceCycles = [3];
	}
	def : WriteRes<WritePCmpIStrMLd, [SBPort015, SBPort23]> {
	let Latency = 11;
	let ResourceCycles = [3, 1];
	}

	// Packed Compare Explicit Length Strings, Return Mask
	def : WriteRes<WritePCmpEStrM, [SBPort015]> {
	let Latency = 11;
	let ResourceCycles = [8];
	}
	def : WriteRes<WritePCmpEStrMLd, [SBPort015, SBPort23]> {
	let Latency = 11;
	let ResourceCycles = [7, 1];
	}

	// Packed Compare Implicit Length Strings, Return Index
	def : WriteRes<WritePCmpIStrI, [SBPort015]> {
	let Latency = 3;
	let ResourceCycles = [3];
	}
	def : WriteRes<WritePCmpIStrILd, [SBPort015, SBPort23]> {
	let Latency = 3;
	let ResourceCycles = [3, 1];
	}

	// Packed Compare Explicit Length Strings, Return Index
	def : WriteRes<WritePCmpEStrI, [SBPort015]> {
	let Latency = 4;
	let ResourceCycles = [8];
	}
	def : WriteRes<WritePCmpEStrILd, [SBPort015, SBPort23]> {
	let Latency = 4;
	let ResourceCycles = [7, 1];
	}

	// AES Instructions.
	def : WriteRes<WriteAESDecEnc, [SBPort015]> {
	let Latency = 8;
	let ResourceCycles = [2];
	}
	def : WriteRes<WriteAESDecEncLd, [SBPort015, SBPort23]> {
	let Latency = 8;
	let ResourceCycles = [2, 1];
	}

	def : WriteRes<WriteAESIMC, [SBPort015]> {
	let Latency = 8;
	let ResourceCycles = [2];
	}
	def : WriteRes<WriteAESIMCLd, [SBPort015, SBPort23]> {
	let Latency = 8;
	let ResourceCycles = [2, 1];
	}

	def : WriteRes<WriteAESKeyGen, [SBPort015]> {
	let Latency = 8;
	let ResourceCycles = [11];
	}
	def : WriteRes<WriteAESKeyGenLd, [SBPort015, SBPort23]> {
	let Latency = 8;
	let ResourceCycles = [10, 1];
	}

	// Carry-less multiplication instructions.
	def : WriteRes<WriteCLMul, [SBPort015]> {
	let Latency = 14;
	let ResourceCycles = [18];
	}
	def : WriteRes<WriteCLMulLd, [SBPort015, SBPort23]> {
	let Latency = 14;
	let ResourceCycles = [17, 1];
	}


	def : WriteRes<WriteSystem, [SBPort015]> { let Latency = 100; }
	def : WriteRes<WriteMicrocoded, [SBPort015]> { let Latency = 100; }
	def : WriteRes<WriteFence, [SBPort23, SBPort4]>;
	def : WriteRes<WriteNop, []>;

	// AVX2 is not supported on that architecture, but we should define the basic
	// scheduling resources anyway.
	defm : SBWriteResPair<WriteFShuffle256, SBPort0, 1>;
	defm : SBWriteResPair<WriteShuffle256, SBPort0, 1>;
	defm : SBWriteResPair<WriteVarVecShift, SBPort0, 1>;
	} // SchedModel