forked from OSchip/llvm-project
992 lines
21 KiB
TableGen
992 lines
21 KiB
TableGen
//===- P9InstrResources.td - P9 Instruction Resource Defs -*- tablegen -*-===//
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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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// This file defines resources required by some of P9 instruction. This is part
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// P9 processor model used for instruction scheduling. Not every instruction
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// is listed here. Instructions in this file belong to itinerary classes that
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// have instructions with different resource requirements.
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//
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// The makeup of the P9 CPU is modeled as follows:
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// - Each CPU is made up of two superslices.
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// - Each superslice is made up of two slices. Therefore, there are 4 slices
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// for each CPU.
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// - Up to 6 instructions can be dispatched to each CPU. Three per superslice.
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// - Each CPU has:
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// - One CY (Crypto) unit P9_CY_*
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// - One DFU (Decimal Floating Point and Quad Precision) unit P9_DFU_*
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// - Two PM (Permute) units. One on each superslice. P9_PM_*
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// - Two DIV (Fixed Point Divide) units. One on each superslize. P9_DIV_*
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// - Four ALU (Fixed Point Arithmetic) units. One on each slice. P9_ALU_*
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// - Four DP (Floating Point) units. One on each slice. P9_DP_*
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// This also includes fixed point multiply add.
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// - Four AGEN (Address Generation) units. One for each slice. P9_AGEN_*
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// - Four Load/Store Queues. P9_LS_*
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// - Each set of instructions will require a number of these resources.
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//===----------------------------------------------------------------------===//
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// Two cycle ALU vector operation that uses an entire superslice.
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// Uses both ALU units (the even ALUE and odd ALUO units), two pipelines
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// (EXECE, EXECO) and all three dispatches (DISP) to the given superslice.
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def : InstRW<[P9_ALUE_2C, P9_ALUO_2C, IP_EXECE_1C, IP_EXECO_1C,
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DISP_1C, DISP_1C, DISP_1C],
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(instrs
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VADDCUW,
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VADDUBM,
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VADDUDM,
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VADDUHM,
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VADDUWM,
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VAND,
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VANDC,
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VCMPEQUB,
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VCMPEQUD,
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VCMPEQUH,
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VCMPEQUW,
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VCMPNEB,
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VCMPNEH,
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VCMPNEW,
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VCMPNEZB,
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VCMPNEZH,
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VCMPNEZW,
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VEQV,
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VEXTSB2D,
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VEXTSB2W,
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VEXTSH2D,
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VEXTSH2W,
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VEXTSW2D,
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VRLB,
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VRLD,
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VRLDMI,
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VRLDNM,
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VRLH,
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VRLW,
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VRLWMI,
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VRLWNM,
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VSRAB,
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VSRAD,
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VSRAH,
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VSRAW,
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VSRB,
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VSRD,
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VSRH,
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VSRW,
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VSLB,
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VSLD,
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VSLH,
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VSLW,
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VMRGEW,
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VMRGOW,
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VNAND,
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VNEGD,
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VNEGW,
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VNOR,
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VOR,
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VORC,
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VPOPCNTB,
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VPOPCNTH,
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VSEL,
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VSUBUBM,
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VSUBUDM,
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VSUBUHM,
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VSUBUWM,
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VXOR,
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V_SET0B,
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V_SET0H,
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V_SET0,
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XVABSDP,
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XVABSSP,
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XVCPSGNDP,
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XVCPSGNSP,
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XVIEXPDP,
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XVNABSDP,
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XVNABSSP,
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XVNEGDP,
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XVNEGSP,
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XVXEXPDP,
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XVIEXPSP,
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XVXEXPSP,
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XXLAND,
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XXLANDC,
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XXLEQV,
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XXLNAND,
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XXLNOR,
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XXLOR,
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XXLORf,
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XXLORC,
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XXLXOR,
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XXSEL,
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XSABSQP,
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XSCPSGNQP,
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XSIEXPQP,
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XSNABSQP,
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XSNEGQP,
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XSXEXPQP
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)>;
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// Restricted Dispatch ALU operation for 3 cycles. The operation runs on a
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// slingle slice. However, since it is Restricted it requires all 3 dispatches
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// (DISP) for that superslice.
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def : InstRW<[P9_ALU_3C, IP_EXEC_1C, DISP_1C, DISP_1C, DISP_1C],
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(instrs
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FCMPUS,
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FCMPUD,
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XSTSTDCDP,
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XSTSTDCSP
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)>;
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// Standard Dispatch ALU operation for 3 cycles. Only one slice used.
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def : InstRW<[P9_ALU_3C, IP_EXEC_1C, DISP_1C, DISP_1C],
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(instrs
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XSMAXCDP,
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XSMAXDP,
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XSMAXJDP,
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XSMINCDP,
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XSMINDP,
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XSMINJDP,
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XSTDIVDP,
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XSTSQRTDP,
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XSCMPEQDP,
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XSCMPEXPDP,
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XSCMPGEDP,
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XSCMPGTDP,
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XSCMPODP,
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XSCMPUDP,
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XSXSIGDP,
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XSCVSPDPN
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)>;
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// Standard Dispatch ALU operation for 2 cycles. Only one slice used.
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def : InstRW<[P9_ALU_2C, IP_EXEC_1C, DISP_1C, DISP_1C],
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(instrs
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ADDIStocHA,
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ADDItocL,
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MCRF,
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MCRXRX,
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SLD,
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SRD,
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SRAD,
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SRADI,
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RLDIC,
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XSNABSDP,
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XSXEXPDP,
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XSABSDP,
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XSNEGDP,
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XSCPSGNDP
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)>;
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// Restricted Dispatch ALU operation for 2 cycles. The operation runs on a
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// slingle slice. However, since it is Restricted it requires all 3 dispatches
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// (DISP) for that superslice.
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def : InstRW<[P9_ALU_2C, IP_EXEC_1C, DISP_1C, DISP_1C, DISP_1C],
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(instrs
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RLDCL,
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RLDCR,
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RLDIMI,
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RLDICL,
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RLDICR,
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RLDICL_32_64,
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XSIEXPDP,
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FMR,
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FABSD,
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FABSS,
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FNABSD,
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FNABSS,
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FNEGD,
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FNEGS,
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FCPSGND,
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FCPSGNS
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)>;
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// Three cycle ALU vector operation that uses an entire superslice.
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// Uses both ALU units (the even ALUE and odd ALUO units), two pipelines
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// (EXECE, EXECO) and all three dispatches (DISP) to the given superslice.
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def : InstRW<[P9_ALUE_3C, P9_ALUO_3C, IP_EXECE_1C, IP_EXECO_1C,
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DISP_1C, DISP_1C, DISP_1C],
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(instrs
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VBPERMD,
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VABSDUB,
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VABSDUH,
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VABSDUW,
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VADDUBS,
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VADDUHS,
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VADDUWS,
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VAVGSB,
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VAVGSH,
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VAVGSW,
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VAVGUB,
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VAVGUH,
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VAVGUW,
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VCMPEQFP,
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VCMPEQFPo,
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VCMPGEFP,
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VCMPGEFPo,
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VCMPBFP,
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VCMPBFPo,
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VCMPGTFP,
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VCMPGTFPo,
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VCLZB,
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VCLZD,
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VCLZH,
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VCLZW,
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VCTZB,
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VCTZD,
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VCTZH,
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VCTZW,
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VADDSBS,
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VADDSHS,
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VADDSWS,
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VMINFP,
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VMINSB,
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VMINSD,
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VMINSH,
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VMINSW,
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VMINUB,
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VMINUD,
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VMINUH,
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VMINUW,
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VMAXFP,
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VMAXSB,
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VMAXSD,
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VMAXSH,
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VMAXSW,
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VMAXUB,
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VMAXUD,
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VMAXUH,
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VMAXUW,
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VPOPCNTW,
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VPOPCNTD,
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VPRTYBD,
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VPRTYBW,
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VSHASIGMAD,
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VSHASIGMAW,
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VSUBSBS,
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VSUBSHS,
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VSUBSWS,
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VSUBUBS,
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VSUBUHS,
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VSUBUWS,
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VSUBCUW,
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VCMPGTSB,
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VCMPGTSBo,
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VCMPGTSD,
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VCMPGTSDo,
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VCMPGTSH,
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VCMPGTSHo,
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VCMPGTSW,
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VCMPGTSWo,
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VCMPGTUB,
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VCMPGTUBo,
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VCMPGTUD,
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VCMPGTUDo,
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VCMPGTUH,
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VCMPGTUHo,
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VCMPGTUW,
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VCMPGTUWo,
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VCMPNEBo,
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VCMPNEHo,
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VCMPNEWo,
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VCMPNEZBo,
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VCMPNEZHo,
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VCMPNEZWo,
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VCMPEQUBo,
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VCMPEQUDo,
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VCMPEQUHo,
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VCMPEQUWo,
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XVCMPEQDP,
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XVCMPEQDPo,
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XVCMPEQSP,
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XVCMPEQSPo,
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XVCMPGEDP,
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XVCMPGEDPo,
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XVCMPGESP,
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XVCMPGESPo,
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XVCMPGTDP,
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XVCMPGTDPo,
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XVCMPGTSP,
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XVCMPGTSPo,
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XVMAXDP,
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XVMAXSP,
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XVMINDP,
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XVMINSP,
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XVTDIVDP,
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XVTDIVSP,
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XVTSQRTDP,
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XVTSQRTSP,
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XVTSTDCDP,
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XVTSTDCSP,
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XVXSIGDP,
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XVXSIGSP
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)>;
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// 7 cycle DP vector operation that uses an entire superslice.
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// Uses both DP units (the even DPE and odd DPO units), two pipelines
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// (EXECE, EXECO) and all three dispatches (DISP) to the given superslice.
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def : InstRW<[P9_DPE_7C, P9_DPO_7C, IP_EXECE_1C, IP_EXECO_1C,
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DISP_1C, DISP_1C, DISP_1C],
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(instrs
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VADDFP,
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VCTSXS,
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VCTSXS_0,
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VCTUXS,
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VCTUXS_0,
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VEXPTEFP,
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VLOGEFP,
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VMADDFP,
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VMHADDSHS,
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VNMSUBFP,
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VREFP,
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VRFIM,
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VRFIN,
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VRFIP,
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VRFIZ,
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VRSQRTEFP,
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VSUBFP,
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XVADDDP,
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XVADDSP,
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XVCVDPSP,
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XVCVDPSXDS,
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XVCVDPSXWS,
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XVCVDPUXDS,
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XVCVDPUXWS,
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XVCVHPSP,
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XVCVSPDP,
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XVCVSPHP,
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XVCVSPSXDS,
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XVCVSPSXWS,
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XVCVSPUXDS,
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XVCVSPUXWS,
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XVCVSXDDP,
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XVCVSXDSP,
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XVCVSXWDP,
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XVCVSXWSP,
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XVCVUXDDP,
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XVCVUXDSP,
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XVCVUXWDP,
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XVCVUXWSP,
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XVMADDADP,
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XVMADDASP,
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XVMADDMDP,
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XVMADDMSP,
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XVMSUBADP,
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XVMSUBASP,
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XVMSUBMDP,
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XVMSUBMSP,
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XVMULDP,
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XVMULSP,
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XVNMADDADP,
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XVNMADDASP,
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XVNMADDMDP,
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XVNMADDMSP,
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XVNMSUBADP,
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XVNMSUBASP,
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XVNMSUBMDP,
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XVNMSUBMSP,
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XVRDPI,
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XVRDPIC,
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XVRDPIM,
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XVRDPIP,
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XVRDPIZ,
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XVREDP,
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XVRESP,
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XVRSPI,
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XVRSPIC,
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XVRSPIM,
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XVRSPIP,
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XVRSPIZ,
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XVRSQRTEDP,
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XVRSQRTESP,
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XVSUBDP,
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XVSUBSP,
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VCFSX,
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VCFSX_0,
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VCFUX,
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VCFUX_0,
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VMHRADDSHS,
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VMLADDUHM,
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VMSUMMBM,
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VMSUMSHM,
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VMSUMSHS,
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VMSUMUBM,
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VMSUMUHM,
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VMSUMUHS,
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VMULESB,
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VMULESH,
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VMULESW,
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VMULEUB,
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VMULEUH,
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VMULEUW,
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VMULOSB,
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VMULOSH,
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VMULOSW,
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VMULOUB,
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VMULOUH,
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VMULOUW,
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VMULUWM,
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VSUM2SWS,
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VSUM4SBS,
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VSUM4SHS,
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VSUM4UBS,
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VSUMSWS
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)>;
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// 7 cycle Restricted DP operation. One DP unit, one EXEC pipeline and all three
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// dispatch units for the superslice.
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def : InstRW<[P9_DP_7C, IP_EXEC_1C, DISP_1C, DISP_1C, DISP_1C],
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(instrs
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FRSP,
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FRIND,
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FRINS,
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FRIPD,
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FRIPS,
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FRIZD,
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FRIZS,
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FRIMD,
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FRIMS,
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FRE,
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FRES,
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FRSQRTE,
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FRSQRTES,
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FMADDS,
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FMADD,
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FMSUBS,
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FMSUB,
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FNMADDS,
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FNMADD,
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FNMSUBS,
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FNMSUB,
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FSELD,
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FSELS,
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FADDS,
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FMULS,
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FMUL,
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FSUBS,
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FCFID,
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FCTID,
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FCTIDZ,
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FCFIDU,
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FCFIDS,
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FCFIDUS,
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FCTIDUZ,
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FCTIWUZ,
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FCTIW,
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FCTIWZ,
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XSMADDADP,
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XSMADDASP,
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XSMADDMDP,
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XSMADDMSP,
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XSMSUBADP,
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XSMSUBASP,
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XSMSUBMDP,
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XSMSUBMSP,
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XSMULDP,
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XSMULSP,
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XSNMADDADP,
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XSNMADDASP,
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XSNMADDMDP,
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XSNMADDMSP,
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XSNMSUBADP,
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XSNMSUBASP,
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XSNMSUBMDP,
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XSNMSUBMSP
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)>;
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// 7 cycle Restricted DP operation and one 2 cycle ALU operation.
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// The DP is restricted so we need a full 5 dispatches.
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def : InstRW<[P9_DPOpAndALUOp_9C, IP_EXEC_1C, IP_EXEC_1C,
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DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
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(instrs
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FMULo,
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FMADDo,
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FMSUBo,
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FNMADDo,
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FNMSUBo
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)>;
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// 7 cycle DP operation. One DP unit, one EXEC pipeline and two dispatch units.
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def : InstRW<[P9_DP_7C, IP_EXEC_1C, DISP_1C, DISP_1C],
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(instrs
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XSADDDP,
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XSADDSP,
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XSCVDPHP,
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XSCVDPSP,
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XSCVDPSXDS,
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XSCVDPSXDSs,
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XSCVDPSXWS,
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XSCVDPUXDS,
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XSCVDPUXDSs,
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XSCVDPUXWS,
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XSCVHPDP,
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XSCVSPDP,
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XSCVSXDDP,
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XSCVSXDSP,
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XSCVUXDDP,
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XSCVUXDSP,
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XSRDPI,
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XSRDPIC,
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XSRDPIM,
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XSRDPIP,
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XSRDPIZ,
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XSREDP,
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XSRESP,
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//XSRSP,
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XSRSQRTEDP,
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XSRSQRTESP,
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XSSUBDP,
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XSSUBSP,
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XSCVDPSPN
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)>;
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|
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// Three Cycle PM operation. Only one PM unit per superslice so we use the whole
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// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
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// dispatches.
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def : InstRW<[P9_PM_3C, IP_EXECO_1C, IP_EXECE_1C, DISP_1C, DISP_1C, DISP_1C],
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(instrs
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VBPERMQ,
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VCLZLSBB,
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VCTZLSBB,
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VEXTRACTD,
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VEXTRACTUB,
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VEXTRACTUH,
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VEXTRACTUW,
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|
VEXTUBLX,
|
|
VEXTUBRX,
|
|
VEXTUHLX,
|
|
VEXTUHRX,
|
|
VEXTUWLX,
|
|
VEXTUWRX,
|
|
VGBBD,
|
|
VINSERTB,
|
|
VINSERTD,
|
|
VINSERTH,
|
|
VINSERTW,
|
|
VMRGHB,
|
|
VMRGHH,
|
|
VMRGHW,
|
|
VMRGLB,
|
|
VMRGLH,
|
|
VMRGLW,
|
|
VPERM,
|
|
VPERMR,
|
|
VPERMXOR,
|
|
VPKPX,
|
|
VPKSDSS,
|
|
VPKSDUS,
|
|
VPKSHSS,
|
|
VPKSHUS,
|
|
VPKSWSS,
|
|
VPKSWUS,
|
|
VPKUDUM,
|
|
VPKUDUS,
|
|
VPKUHUM,
|
|
VPKUHUS,
|
|
VPKUWUM,
|
|
VPKUWUS,
|
|
VPRTYBQ,
|
|
VSL,
|
|
VSLDOI,
|
|
VSLO,
|
|
VSLV,
|
|
VSPLTB,
|
|
VSPLTBs,
|
|
VSPLTH,
|
|
VSPLTHs,
|
|
VSPLTISB,
|
|
VSPLTISH,
|
|
VSPLTISW,
|
|
VSPLTW,
|
|
VSR,
|
|
VSRO,
|
|
VSRV,
|
|
VUPKHPX,
|
|
VUPKHSB,
|
|
VUPKHSH,
|
|
VUPKHSW,
|
|
VUPKLPX,
|
|
VUPKLSB,
|
|
VUPKLSH,
|
|
VUPKLSW,
|
|
XXBRD,
|
|
XXBRH,
|
|
XXBRQ,
|
|
XXBRW,
|
|
XXEXTRACTUW,
|
|
XXINSERTW,
|
|
XXMRGHW,
|
|
XXMRGLW,
|
|
XXPERM,
|
|
XXPERMR,
|
|
XXSLDWI,
|
|
XXSPLTIB,
|
|
XXSPLTW,
|
|
XXSPLTWs,
|
|
XXPERMDI,
|
|
XXPERMDIs,
|
|
VADDCUQ,
|
|
VADDECUQ,
|
|
VADDEUQM,
|
|
VADDUQM,
|
|
VMUL10CUQ,
|
|
VMUL10ECUQ,
|
|
VMUL10EUQ,
|
|
VMUL10UQ,
|
|
VSUBCUQ,
|
|
VSUBECUQ,
|
|
VSUBEUQM,
|
|
VSUBUQM,
|
|
XSCMPEXPQP,
|
|
XSCMPOQP,
|
|
XSCMPUQP,
|
|
XSTSTDCQP,
|
|
XSXSIGQP
|
|
)>;
|
|
|
|
// 12 Cycle DFU operation. Only one DFU unit per CPU so we use a whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_DFU_12C, IP_EXECE_1C, IP_EXECO_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XSADDQP,
|
|
XSADDQPO,
|
|
XSCVDPQP,
|
|
XSCVQPDP,
|
|
XSCVQPDPO,
|
|
XSCVQPSDZ,
|
|
XSCVQPSWZ,
|
|
XSCVQPUDZ,
|
|
XSCVQPUWZ,
|
|
XSCVSDQP,
|
|
XSCVUDQP,
|
|
XSRQPI,
|
|
XSRQPXP,
|
|
XSSUBQP,
|
|
XSSUBQPO
|
|
)>;
|
|
|
|
// 24 Cycle DFU operation. Only one DFU unit per CPU so we use a whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_DFU_24C, IP_EXECE_1C, IP_EXECO_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XSMADDQP,
|
|
XSMADDQPO,
|
|
XSMSUBQP,
|
|
XSMSUBQPO,
|
|
XSMULQP,
|
|
XSMULQPO,
|
|
XSNMADDQP,
|
|
XSNMADDQPO,
|
|
XSNMSUBQP,
|
|
XSNMSUBQPO
|
|
)>;
|
|
|
|
// 58 Cycle DFU operation. Only one DFU unit per CPU so we use a whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_DFU_58C, IP_EXECE_1C, IP_EXECO_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XSDIVQP,
|
|
XSDIVQPO
|
|
)>;
|
|
|
|
// 76 Cycle DFU operation. Only one DFU unit per CPU so we use a whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_DFU_76C, IP_EXECE_1C, IP_EXECO_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XSSQRTQP,
|
|
XSSQRTQPO
|
|
)>;
|
|
|
|
// 5 Cycle load uses a single slice.
|
|
def : InstRW<[P9_LS_5C, IP_AGEN_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
LXSDX,
|
|
LXVD2X,
|
|
LXSIWZX,
|
|
LXV,
|
|
LXVX,
|
|
LXSD,
|
|
DFLOADf64,
|
|
XFLOADf64
|
|
)>;
|
|
|
|
// 4 Cycle load uses a single slice.
|
|
def : InstRW<[P9_LS_4C, IP_AGEN_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
COPY
|
|
)>;
|
|
|
|
// 4 Cycle Restricted load uses a single slice but the dispatch for the whole
|
|
// superslice.
|
|
def : InstRW<[P9_LS_4C, IP_AGEN_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
LFIWZX,
|
|
LFDX,
|
|
LFD
|
|
)>;
|
|
|
|
// Cracked Restricted Load instruction.
|
|
// Requires consecutive Load and ALU pieces totaling 6 cycles. The Load and ALU
|
|
// operations cannot be done at the same time and so their latencies are added.
|
|
// Full 6 dispatches are required as this is both cracked and restricted.
|
|
def : InstRW<[P9_LoadAndALUOp_6C, IP_EXEC_1C, IP_AGEN_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
LFIWAX,
|
|
LFSX,
|
|
LFS
|
|
)>;
|
|
|
|
// Cracked Load instruction.
|
|
// Requires consecutive Load and ALU pieces totaling 7 cycles. The Load and ALU
|
|
// operations cannot be done at the same time and so their latencies are added.
|
|
// Full 4 dispatches are required as this is a cracked instruction.
|
|
def : InstRW<[P9_LoadAndALUOp_7C, IP_AGEN_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
LXSSPX,
|
|
LXSIWAX,
|
|
LXSSP,
|
|
DFLOADf32,
|
|
XFLOADf32,
|
|
LIWAX,
|
|
LIWZX
|
|
)>;
|
|
|
|
// Cracked Load that requires the PM resource.
|
|
// Since the Load and the PM cannot be done at the same time the latencies are
|
|
// added. Requires 8 cycles.
|
|
// Since the PM requires the full superslice we need both EXECE, EXECO pipelines
|
|
// as well as 3 dispatches for the PM. The Load requires the remaining 2
|
|
// dispatches.
|
|
def : InstRW<[P9_LoadAndPMOp_8C, IP_AGEN_1C, IP_EXECE_1C, IP_EXECO_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
LXVDSX,
|
|
LXVWSX,
|
|
LXVW4X
|
|
)>;
|
|
|
|
// Single slice Restricted store operation. The restricted operation requires
|
|
// all three dispatches for the superslice.
|
|
def : InstRW<[P9_LS_1C, IP_EXEC_1C, IP_AGEN_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
STFS,
|
|
STFD,
|
|
STFIWX,
|
|
STFSX,
|
|
STFDX,
|
|
STXSDX,
|
|
STXSSPX,
|
|
STXSIWX,
|
|
DFSTOREf32,
|
|
DFSTOREf64,
|
|
XFSTOREf32,
|
|
XFSTOREf64,
|
|
STIWX
|
|
)>;
|
|
|
|
// Store operation that requires the whole superslice.
|
|
def : InstRW<[P9_LS_1C, IP_EXECE_1C, IP_EXECO_1C, IP_AGEN_1C,
|
|
DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
STXVD2X,
|
|
STXVW4X
|
|
)>;
|
|
|
|
|
|
// 16 Cycle DIV operation. Only one DIV unit per superslice so we use the whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_DIV_16C_8, IP_EXECO_1C, IP_EXECE_1C,
|
|
DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
DIVW,
|
|
DIVWU,
|
|
MODSW
|
|
)>;
|
|
|
|
// 24 Cycle DIV operation. Only one DIV unit per superslice so we use the whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_DIV_24C_8, IP_EXECO_1C, IP_EXECE_1C,
|
|
DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
DIVWE,
|
|
DIVD,
|
|
DIVWEU,
|
|
DIVDU,
|
|
MODSD,
|
|
MODUD,
|
|
MODUW
|
|
)>;
|
|
|
|
// 40 Cycle DIV operation. Only one DIV unit per superslice so we use the whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_DIV_40C_8, IP_EXECO_1C, IP_EXECE_1C,
|
|
DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
DIVDE,
|
|
DIVDEU
|
|
)>;
|
|
|
|
// Cracked DIV and ALU operation. Requires one full slice for the ALU operation
|
|
// and one full superslice for the DIV operation since there is only one DIV
|
|
// per superslice. Latency of DIV plus ALU is 26.
|
|
def : InstRW<[P9_IntDivAndALUOp_26C_8, IP_EXECE_1C, IP_EXECO_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
DIVDo,
|
|
DIVDUo,
|
|
DIVWEo,
|
|
DIVWEUo
|
|
)>;
|
|
|
|
// Cracked DIV and ALU operation. Requires one full slice for the ALU operation
|
|
// and one full superslice for the DIV operation since there is only one DIV
|
|
// per superslice. Latency of DIV plus ALU is 42.
|
|
def : InstRW<[P9_IntDivAndALUOp_42C_8, IP_EXECE_1C, IP_EXECO_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
DIVDEo,
|
|
DIVDEUo
|
|
)>;
|
|
|
|
// CR access instructions in _BrMCR, IIC_BrMCRX.
|
|
|
|
// Cracked, restricted, ALU operations.
|
|
// Here the two ALU ops can actually be done in parallel and therefore the
|
|
// latencies are not added together. Otherwise this is like having two
|
|
// instructions running together on two pipelines and 6 dispatches.
|
|
// ALU ops are 2 cycles each.
|
|
def : InstRW<[P9_ALU_2C, P9_ALU_2C, IP_EXEC_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
MTOCRF,
|
|
MTOCRF8,
|
|
MTCRF,
|
|
MTCRF8
|
|
)>;
|
|
|
|
// Cracked, restricted, ALU operations.
|
|
// Here the two ALU ops can actually be done in parallel and therefore the
|
|
// latencies are not added together. Otherwise this is like having two
|
|
// instructions running together on two pipelines and 6 dispatches.
|
|
// ALU ops are 3 cycles each.
|
|
def : InstRW<[P9_ALU_3C, P9_ALU_3C, IP_EXEC_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
MCRFS
|
|
)>;
|
|
|
|
// FP Div instructions in IIC_FPDivD and IIC_FPDivS.
|
|
|
|
// 33 Cycle DP Instruction Restricted. Takes one slice and 3 dispatches.
|
|
def : InstRW<[P9_DP_33C_8, IP_EXEC_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
FDIV
|
|
)>;
|
|
|
|
// 33 Cycle DP Instruction Restricted and Cracked with 2 Cycle ALU.
|
|
def : InstRW<[P9_DPOpAndALUOp_35C_8, IP_EXEC_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
FDIVo
|
|
)>;
|
|
|
|
// 33 Cycle DP Instruction. Takes one slice and 2 dispatches.
|
|
def : InstRW<[P9_DP_33C_8, IP_EXEC_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XSDIVDP
|
|
)>;
|
|
|
|
// 22 Cycle DP Instruction Restricted. Takes one slice and 3 dispatches.
|
|
def : InstRW<[P9_DP_22C_5, IP_EXEC_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
FDIVS
|
|
)>;
|
|
|
|
// 22 Cycle DP Instruction Restricted and Cracked with 2 Cycle ALU.
|
|
def : InstRW<[P9_DPOpAndALUOp_24C_5, IP_EXEC_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
FDIVSo
|
|
)>;
|
|
|
|
// 22 Cycle DP Instruction. Takes one slice and 2 dispatches.
|
|
def : InstRW<[P9_DP_22C_5, IP_EXEC_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XSDIVSP
|
|
)>;
|
|
|
|
// 24 Cycle DP Vector Instruction. Takes one full superslice.
|
|
// Includes both EXECE, EXECO pipelines and all 3 dispatches for the given
|
|
// superslice.
|
|
def : InstRW<[P9_DPE_24C_8, P9_DPO_24C_8, IP_EXECE_1C, IP_EXECO_1C,
|
|
DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XVDIVSP
|
|
)>;
|
|
|
|
// 33 Cycle DP Vector Instruction. Takes one full superslice.
|
|
// Includes both EXECE, EXECO pipelines and all 3 dispatches for the given
|
|
// superslice.
|
|
def : InstRW<[P9_DPE_33C_8, P9_DPO_33C_8, IP_EXECE_1C, IP_EXECO_1C,
|
|
DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
XVDIVDP
|
|
)>;
|
|
|
|
// Load instructions in IIC_LdStLFDU and IIC_LdStLFDUX.
|
|
|
|
// Instruction cracked into three pieces. One Load and two ALU operations.
|
|
// The Load and one of the ALU ops cannot be run at the same time and so the
|
|
// latencies are added together for 6 cycles. The remainaing ALU is 2 cycles.
|
|
// Both the load and the ALU that depends on it are restricted and so they take
|
|
// a total of 6 dispatches. The final 2 dispatches come from the second ALU op.
|
|
// The two EXEC pipelines are for the 2 ALUs while the AGEN is for the load.
|
|
def : InstRW<[P9_LoadAndALUOp_6C, P9_ALU_2C,
|
|
IP_AGEN_1C, IP_EXEC_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
LFSU,
|
|
LFSUX
|
|
)>;
|
|
|
|
// Cracked instruction made up of a Load and an ALU. The ALU does not depend on
|
|
// the load and so it can be run at the same time as the load. The load is also
|
|
// restricted. 3 dispatches are from the restricted load while the other two
|
|
// are from the ALU. The AGEN pipeline is from the load and the EXEC pipeline
|
|
// is required for the ALU.
|
|
def : InstRW<[P9_LS_4C, P9_ALU_2C, IP_AGEN_1C, IP_EXEC_1C,
|
|
DISP_1C, DISP_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
LFDU,
|
|
LFDUX
|
|
)>;
|
|
|
|
// Crypto Instructions
|
|
|
|
// 6 Cycle CY operation. Only one CY unit per CPU so we use a whole
|
|
// superslice. That includes both exec pipelines (EXECO, EXECE) and all three
|
|
// dispatches.
|
|
def : InstRW<[P9_CY_6C, IP_EXECO_1C, IP_EXECE_1C, DISP_1C, DISP_1C, DISP_1C],
|
|
(instrs
|
|
VPMSUMB,
|
|
VPMSUMD,
|
|
VPMSUMH,
|
|
VPMSUMW,
|
|
VCIPHER,
|
|
VCIPHERLAST,
|
|
VNCIPHER,
|
|
VNCIPHERLAST,
|
|
VSBOX
|
|
)>;
|