//===-- PPCScheduleE500mc.td - e500mc Scheduling Defs ------*- 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 itinerary class data for the Freescale e500mc 32-bit // Power processor. // // All information is derived from the "e500mc Core Reference Manual", // Freescale Document Number E500MCRM, Rev. 1, 03/2012. // //===----------------------------------------------------------------------===// // Relevant functional units in the Freescale e500mc core: // // * Decode & Dispatch // Can dispatch up to 2 instructions per clock cycle to either the GPR Issue // queues (GIQx), FP Issue Queue (FIQ), or Branch issue queue (BIQ). def DIS0 : FuncUnit; // Dispatch stage - insn 1 def DIS1 : FuncUnit; // Dispatch stage - insn 2 // * Execute // 6 pipelined execution units: SFX0, SFX1, BU, FPU, LSU, CFX. // Some instructions can only execute in SFX0 but not SFX1. // The CFX has a bypass path, allowing non-divide instructions to execute // while a divide instruction is executed. def SFX0 : FuncUnit; // Simple unit 0 def SFX1 : FuncUnit; // Simple unit 1 def BU : FuncUnit; // Branch unit def CFX_DivBypass : FuncUnit; // CFX divide bypass path def CFX_0 : FuncUnit; // CFX pipeline def LSU_0 : FuncUnit; // LSU pipeline def FPU_0 : FuncUnit; // FPU pipeline def CR_Bypass : Bypass; def PPCE500mcItineraries : ProcessorItineraries< [DIS0, DIS1, SFX0, SFX1, BU, CFX_DivBypass, CFX_0, LSU_0, FPU_0], [CR_Bypass, GPR_Bypass, FPR_Bypass], [ InstrItinData, InstrStage<1, [SFX0, SFX1]>], [4, 1, 1], // Latency = 1 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1]>], [4, 1, 1], // Latency = 1 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1]>], [5, 1, 1], // Latency = 1 or 2 [CR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [CFX_0], 0>, InstrStage<14, [CFX_DivBypass]>], [17, 1, 1], // Latency=4..35, Repeat= 4..35 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<8, [FPU_0]>], [11], // Latency = 8 [FPR_Bypass]>, InstrItinData, InstrStage<8, [FPU_0]>], [11, 1, 1], // Latency = 8 [NoBypass, NoBypass, NoBypass]>, InstrItinData, InstrStage<1, [CFX_0]>], [7, 1, 1], // Latency = 4, Repeat rate = 1 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [CFX_0]>], [7, 1, 1], // Latency = 4, Repeat rate = 1 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [CFX_0]>], [7, 1, 1], // Latency = 4, Repeat rate = 1 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1]>], [4, 1, 1], // Latency = 1 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1]>], [4, 1, 1], // Latency = 1 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<2, [SFX0]>], [5, 1], // Latency = 2, Repeat rate = 2 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [BU]>], [4, 1], // Latency = 1 [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [BU]>], [4, 1, 1], // Latency = 1 [CR_Bypass, CR_Bypass, CR_Bypass]>, InstrItinData, InstrStage<1, [BU]>], [4, 1], // Latency = 1 [CR_Bypass, CR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1]>], [4, 1, 1], // Latency = 1 [CR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3, Repeat rate = 1 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1], 0>, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass], 2>, // 2 micro-ops InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1], 0>, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [NoBypass, GPR_Bypass], 2>, // 2 micro-ops InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>], [6, 1, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1], 0>, InstrStage<1, [LSU_0]>], [6, 1, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass, GPR_Bypass], 2>, // 2 micro-ops InstrItinData, InstrStage<1, [LSU_0]>], [7, 1, 1], // Latency = 4 [FPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1], 0>, InstrStage<1, [LSU_0]>], [7, 1, 1], // Latency = 4 [FPR_Bypass, GPR_Bypass, GPR_Bypass], 2>, // 2 micro-ops InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1], 0>, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>], [7, 1], // Latency = r+3 [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<3, [LSU_0]>], [6, 1, 1], // Latency = 3, Repeat rate = 3 [GPR_Bypass, GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>], [6, 1], // Latency = 3 [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0]>]>, InstrItinData, InstrStage<4, [SFX0]>], [7, 1], [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<2, [SFX0, SFX1]>], [5, 1], // Latency = 2, Repeat rate = 4 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0]>], [5, 1], [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [LSU_0], 0>]>, InstrItinData, InstrStage<5, [SFX0]>], [8, 1], [GPR_Bypass, CR_Bypass]>, InstrItinData, InstrStage<4, [SFX0]>], [7, 1], // Latency = 4, Repeat rate = 4 [GPR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1]>], [4, 1], // Latency = 1, Repeat rate = 1 [GPR_Bypass, CR_Bypass]>, InstrItinData, InstrStage<4, [SFX0]>], [7, 1], // Latency = 4, Repeat rate = 4 [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0, SFX1]>], [4, 1], // Latency = 1, Repeat rate = 1 [CR_Bypass, GPR_Bypass]>, InstrItinData, InstrStage<1, [SFX0]>], [4, 1], [NoBypass, GPR_Bypass]>, InstrItinData, InstrStage<2, [FPU_0]>], [11, 1, 1], // Latency = 8, Repeat rate = 2 [FPR_Bypass, FPR_Bypass, FPR_Bypass]>, InstrItinData, InstrStage<4, [FPU_0]>], [13, 1, 1], // Latency = 10, Repeat rate = 4 [FPR_Bypass, FPR_Bypass, FPR_Bypass]>, InstrItinData, InstrStage<2, [FPU_0]>], [11, 1, 1], // Latency = 8, Repeat rate = 2 [CR_Bypass, FPR_Bypass, FPR_Bypass]>, InstrItinData, InstrStage<68, [FPU_0]>], [71, 1, 1], // Latency = 68, Repeat rate = 68 [FPR_Bypass, FPR_Bypass, FPR_Bypass]>, InstrItinData, InstrStage<38, [FPU_0]>], [41, 1, 1], // Latency = 38, Repeat rate = 38 [FPR_Bypass, FPR_Bypass, FPR_Bypass]>, InstrItinData, InstrStage<4, [FPU_0]>], [13, 1, 1, 1], // Latency = 10, Repeat rate = 4 [FPR_Bypass, FPR_Bypass, FPR_Bypass, FPR_Bypass]>, InstrItinData, InstrStage<38, [FPU_0]>], [41, 1], // Latency = 38, Repeat rate = 38 [FPR_Bypass, FPR_Bypass]> ]>; // ===---------------------------------------------------------------------===// // e500mc machine model for scheduling and other instruction cost heuristics. def PPCE500mcModel : SchedMachineModel { let IssueWidth = 2; // 2 micro-ops are dispatched per cycle. let MinLatency = -1; // OperandCycles are interpreted as MinLatency. let LoadLatency = 5; // Optimistic load latency assuming bypass. // This is overriden by OperandCycles if the // Itineraries are queried instead. let Itineraries = PPCE500mcItineraries; }