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;; Scheduling for the Intel P6 family of processors
;; Copyright (C) 2004, 2005, 2007, 2008, 2010 Free Software Foundation, Inc.
;;
;; This file is part of GCC.
;;
;; GCC is free software; you can redistribute it and/or modify
;; it under the terms of the GNU General Public License as published by
;; the Free Software Foundation; either version 3, or (at your option)
;; any later version.
;;
;; GCC is distributed in the hope that it will be useful,
;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
;; GNU General Public License for more details.
;;
;; You should have received a copy of the GNU General Public License
;; along with GCC; see the file COPYING3. If not see
;; <http://www.gnu.org/licenses/>. */
;; The P6 family includes the Pentium Pro, Pentium II, Pentium III, Celeron
;; and Xeon lines of CPUs. The DFA scheduler description in this file is
;; based on information that can be found in the following three documents:
;;
;; "P6 Family of Processors Hardware Developer's Manual",
;; Intel, September 1999.
;;
;; "Intel Architecture Optimization Manual",
;; Intel, 1999 (Order Number: 245127-001).
;;
;; "How to optimize for the Pentium family of microprocessors",
;; by Agner Fog, PhD.
;;
;; The P6 pipeline has three major components:
;; 1) the FETCH/DECODE unit, an in-order issue front-end
;; 2) the DISPATCH/EXECUTE unit, which is the out-of-order core
;; 3) the RETIRE unit, an in-order retirement unit
;;
;; So, the P6 CPUs have out-of-order cores, but the instruction decoder and
;; retirement unit are naturally in-order.
;;
;; BUS INTERFACE UNIT
;; / \
;; L1 ICACHE L1 DCACHE
;; / | \ | \
;; DECODER0 DECODER1 DECODER2 DISP/EXEC RETIRE
;; \ | / | |
;; INSTRUCTION POOL __________|_______/
;; (inc. reorder buffer)
;;
;; Since the P6 CPUs execute instructions out-of-order, the most important
;; consideration in performance tuning is making sure enough micro-ops are
;; ready for execution in the out-of-order core, while not stalling the
;; decoder.
;;
;; TODO:
;; - Find a less crude way to model complex instructions, in
;; particular how many cycles they take to be decoded.
;; - Include decoder latencies in the total reservation latencies.
;; This isn't necessary right now because we assume for every
;; instruction that it never blocks a decoder.
;; - Figure out where the p0 and p1 reservations come from. These
;; appear not to be in the manual
;; - Lots more because I'm sure this is still far from optimal :-)
;; The ppro_idiv and ppro_fdiv automata are used to model issue
;; latencies of idiv and fdiv type insns.
(define_automaton "ppro_decoder,ppro_core,ppro_idiv,ppro_fdiv,ppro_load,ppro_store")
;; Simple instructions of the register-register form have only one uop.
;; Load instructions are also only one uop. Store instructions decode to
;; two uops, and simple read-modify instructions also take two uops.
;; Simple instructions of the register-memory form have two to three uops.
;; Simple read-modify-write instructions have four uops. The rules for
;; the decoder are simple:
;; - an instruction with 1 uop can be decoded by any of the three
;; decoders in one cycle.
;; - an instruction with 1 to 4 uops can be decoded only by decoder 0
;; but still in only one cycle.
;; - a complex (microcode) instruction can also only be decoded by
;; decoder 0, and this takes an unspecified number of cycles.
;;
;; The goal is to schedule such that we have a few-one-one uops sequence
;; in each cycle, to decode as many instructions per cycle as possible.
(define_cpu_unit "decoder0" "ppro_decoder")
(define_cpu_unit "decoder1" "ppro_decoder")
(define_cpu_unit "decoder2" "ppro_decoder")
;; We first wish to find an instruction for decoder0, so exclude
;; decoder1 and decoder2 from being reserved until decoder 0 is
;; reserved.
(presence_set "decoder1" "decoder0")
(presence_set "decoder2" "decoder0")
;; Most instructions can be decoded on any of the three decoders.
(define_reservation "decodern" "(decoder0|decoder1|decoder2)")
;; The out-of-order core has five pipelines. During each cycle, the core
;; may dispatch zero or one uop on the port of any of the five pipelines
;; so the maximum number of dispatched uops per cycle is 5. In practicer,
;; 3 uops per cycle is more realistic.
;;
;; Two of the five pipelines contain several execution units:
;;
;; Port 0 Port 1 Port 2 Port 3 Port 4
;; ALU ALU LOAD SAC SDA
;; FPU JUE
;; AGU MMX
;; MMX P3FPU
;; P3FPU
;;
;; (SAC=Store Address Calculation, SDA=Store Data Unit, P3FPU = SSE unit,
;; JUE = Jump Execution Unit, AGU = Address Generation Unit)
;;
(define_cpu_unit "p0,p1" "ppro_core")
(define_cpu_unit "p2" "ppro_load")
(define_cpu_unit "p3,p4" "ppro_store")
(define_cpu_unit "idiv" "ppro_idiv")
(define_cpu_unit "fdiv" "ppro_fdiv")
;; Only the irregular instructions have to be modeled here. A load
;; increases the latency by 2 or 3, or by nothing if the manual gives
;; a latency already. Store latencies are not accounted for.
;;
;; The simple instructions follow a very regular pattern of 1 uop per
;; reg-reg operation, 1 uop per load on port 2. and 2 uops per store
;; on port 4 and port 3. These instructions are modelled at the bottom
;; of this file.
;;
;; For microcoded instructions we don't know how many uops are produced.
;; These instructions are the "complex" ones in the Intel manuals. All
;; we _do_ know is that they typically produce four or more uops, so
;; they can only be decoded on decoder0. Modelling their latencies
;; doesn't make sense because we don't know how these instructions are
;; executed in the core. So we just model that they can only be decoded
;; on decoder 0, and say that it takes a little while before the result
;; is available.
(define_insn_reservation "ppro_complex_insn" 6
(and (eq_attr "cpu" "pentiumpro")
(eq_attr "type" "other,multi,call,callv,str"))
"decoder0")
;; imov with memory operands does not use the integer units.
(define_insn_reservation "ppro_imov" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "imov")))
"decodern,(p0|p1)")
(define_insn_reservation "ppro_imov_load" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(eq_attr "type" "imov")))
"decodern,p2")
(define_insn_reservation "ppro_imov_store" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "store")
(eq_attr "type" "imov")))
"decoder0,p4+p3")
;; imovx always decodes to one uop, and also doesn't use the integer
;; units if it has memory operands.
(define_insn_reservation "ppro_imovx" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "imovx")))
"decodern,(p0|p1)")
(define_insn_reservation "ppro_imovx_load" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(eq_attr "type" "imovx")))
"decodern,p2")
;; lea executes on port 0 with latency one and throughput 1.
(define_insn_reservation "ppro_lea" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "lea")))
"decodern,p0")
;; Shift and rotate execute on port 0 with latency and throughput 1.
;; The load and store units need to be reserved when memory operands
;; are involved.
(define_insn_reservation "ppro_shift_rotate" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "ishift,ishift1,rotate,rotate1")))
"decodern,p0")
(define_insn_reservation "ppro_shift_rotate_mem" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "!none")
(eq_attr "type" "ishift,ishift1,rotate,rotate1")))
"decoder0,p2+p0,p4+p3")
;; The P6 has a sophisticated branch prediction mechanism to minimize
;; latencies due to branching. In particular, it has a fast way to
;; execute branches that are taken multiple times (such as in loops).
;; Branches not taken suffer no penalty, and correctly predicted
;; branches cost only one fetch cycle. Mispredicted branches are very
;; costly: typically 15 cycles and possibly as many as 26 cycles.
;;
;; Unfortunately all this makes it quite difficult to properly model
;; the latencies for the compiler. Here I've made the choice to be
;; optimistic and assume branches are often predicted correctly, so
;; they have latency 1, and the decoders are not blocked.
;;
;; In addition, the model assumes a branch always decodes to only 1 uop,
;; which is not exactly true because there are a few instructions that
;; decode to 2 uops or microcode. But this probably gives the best
;; results because we can assume these instructions can decode on all
;; decoders.
(define_insn_reservation "ppro_branch" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "ibr")))
"decodern,p1")
;; ??? Indirect branches probably have worse latency than this.
(define_insn_reservation "ppro_indirect_branch" 6
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "!none")
(eq_attr "type" "ibr")))
"decoder0,p2+p1")
(define_insn_reservation "ppro_leave" 4
(and (eq_attr "cpu" "pentiumpro")
(eq_attr "type" "leave"))
"decoder0,p2+(p0|p1),(p0|p1)")
;; imul has throughput one, but latency 4, and can only execute on port 0.
(define_insn_reservation "ppro_imul" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "imul")))
"decodern,p0")
(define_insn_reservation "ppro_imul_mem" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "!none")
(eq_attr "type" "imul")))
"decoder0,p2+p0")
;; div and idiv are very similar, so we model them the same.
;; QI, HI, and SI have issue latency 12, 21, and 37, respectively.
;; These issue latencies are modelled via the ppro_div automaton.
(define_insn_reservation "ppro_idiv_QI" 19
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "QI")
(eq_attr "type" "idiv"))))
"decoder0,(p0+idiv)*2,(p0|p1)+idiv,idiv*9")
(define_insn_reservation "ppro_idiv_QI_load" 19
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "QI")
(eq_attr "type" "idiv"))))
"decoder0,p2+p0+idiv,p0+idiv,(p0|p1)+idiv,idiv*9")
(define_insn_reservation "ppro_idiv_HI" 23
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "HI")
(eq_attr "type" "idiv"))))
"decoder0,(p0+idiv)*3,(p0|p1)+idiv,idiv*17")
(define_insn_reservation "ppro_idiv_HI_load" 23
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "HI")
(eq_attr "type" "idiv"))))
"decoder0,p2+p0+idiv,p0+idiv,(p0|p1)+idiv,idiv*18")
(define_insn_reservation "ppro_idiv_SI" 39
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SI")
(eq_attr "type" "idiv"))))
"decoder0,(p0+idiv)*3,(p0|p1)+idiv,idiv*33")
(define_insn_reservation "ppro_idiv_SI_load" 39
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "SI")
(eq_attr "type" "idiv"))))
"decoder0,p2+p0+idiv,p0+idiv,(p0|p1)+idiv,idiv*34")
;; Floating point operations always execute on port 0.
;; ??? where do these latencies come from? fadd has latency 3 and
;; has throughput "1/cycle (align with FADD)". What do they
;; mean and how can we model that?
(define_insn_reservation "ppro_fop" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none,unknown")
(eq_attr "type" "fop")))
"decodern,p0")
(define_insn_reservation "ppro_fop_load" 5
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(eq_attr "type" "fop")))
"decoder0,p2+p0,p0")
(define_insn_reservation "ppro_fop_store" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "store")
(eq_attr "type" "fop")))
"decoder0,p0,p0,p0+p4+p3")
(define_insn_reservation "ppro_fop_both" 5
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "both")
(eq_attr "type" "fop")))
"decoder0,p2+p0,p0+p4+p3")
(define_insn_reservation "ppro_fsgn" 1
(and (eq_attr "cpu" "pentiumpro")
(eq_attr "type" "fsgn"))
"decodern,p0")
(define_insn_reservation "ppro_fistp" 5
(and (eq_attr "cpu" "pentiumpro")
(eq_attr "type" "fistp"))
"decoder0,p0*2,p4+p3")
(define_insn_reservation "ppro_fcmov" 2
(and (eq_attr "cpu" "pentiumpro")
(eq_attr "type" "fcmov"))
"decoder0,p0*2")
(define_insn_reservation "ppro_fcmp" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "fcmp")))
"decodern,p0")
(define_insn_reservation "ppro_fcmp_load" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(eq_attr "type" "fcmp")))
"decoder0,p2+p0")
(define_insn_reservation "ppro_fmov" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "fmov")))
"decodern,p0")
(define_insn_reservation "ppro_fmov_load" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "!XF")
(eq_attr "type" "fmov"))))
"decodern,p2")
(define_insn_reservation "ppro_fmov_XF_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "XF")
(eq_attr "type" "fmov"))))
"decoder0,(p2+p0)*2")
(define_insn_reservation "ppro_fmov_store" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "store")
(and (eq_attr "mode" "!XF")
(eq_attr "type" "fmov"))))
"decodern,p0")
(define_insn_reservation "ppro_fmov_XF_store" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "store")
(and (eq_attr "mode" "XF")
(eq_attr "type" "fmov"))))
"decoder0,(p0+p4),(p0+p3)")
;; fmul executes on port 0 with latency 5. It has issue latency 2,
;; but we don't model this.
(define_insn_reservation "ppro_fmul" 5
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "fmul")))
"decoder0,p0*2")
(define_insn_reservation "ppro_fmul_load" 6
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(eq_attr "type" "fmul")))
"decoder0,p2+p0,p0")
;; fdiv latencies depend on the mode of the operands. XFmode gives
;; a latency of 38 cycles, DFmode gives 32, and SFmode gives latency 18.
;; Division by a power of 2 takes only 9 cycles, but we cannot model
;; that. Throughput is equal to latency - 1, which we model using the
;; ppro_div automaton.
(define_insn_reservation "ppro_fdiv_SF" 18
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "fdiv,fpspc"))))
"decodern,p0+fdiv,fdiv*16")
(define_insn_reservation "ppro_fdiv_SF_load" 19
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "SF")
(eq_attr "type" "fdiv,fpspc"))))
"decoder0,p2+p0+fdiv,fdiv*16")
(define_insn_reservation "ppro_fdiv_DF" 32
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "DF")
(eq_attr "type" "fdiv,fpspc"))))
"decodern,p0+fdiv,fdiv*30")
(define_insn_reservation "ppro_fdiv_DF_load" 33
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "DF")
(eq_attr "type" "fdiv,fpspc"))))
"decoder0,p2+p0+fdiv,fdiv*30")
(define_insn_reservation "ppro_fdiv_XF" 38
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "XF")
(eq_attr "type" "fdiv,fpspc"))))
"decodern,p0+fdiv,fdiv*36")
(define_insn_reservation "ppro_fdiv_XF_load" 39
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "XF")
(eq_attr "type" "fdiv,fpspc"))))
"decoder0,p2+p0+fdiv,fdiv*36")
;; MMX instructions can execute on either port 0 or port 1 with a
;; throughput of 1/cycle.
;; on port 0: - ALU (latency 1)
;; - Multiplier Unit (latency 3)
;; on port 1: - ALU (latency 1)
;; - Shift Unit (latency 1)
;;
;; MMX instructions are either of the type reg-reg, or read-modify, and
;; except for mmxshft and mmxmul they can execute on port 0 or port 1,
;; so they behave as "simple" instructions that need no special modelling.
;; We only have to model mmxshft and mmxmul.
(define_insn_reservation "ppro_mmx_shft" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "mmxshft")))
"decodern,p1")
(define_insn_reservation "ppro_mmx_shft_load" 2
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "mmxshft")))
"decoder0,p2+p1")
(define_insn_reservation "ppro_mmx_mul" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "mmxmul")))
"decodern,p0")
(define_insn_reservation "ppro_mmx_mul_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(eq_attr "type" "mmxmul")))
"decoder0,p2+p0")
(define_insn_reservation "ppro_sse_mmxcvt" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "mode" "DI")
(eq_attr "type" "mmxcvt")))
"decodern,p1")
;; FIXME: These are Pentium III only, but we cannot tell here if
;; we're generating code for PentiumPro/Pentium II or Pentium III
;; (define_insn_reservation "ppro_sse_mmxshft" 2
;; (and (eq_attr "cpu" "pentiumpro")
;; (and (eq_attr "mode" "DI")
;; (eq_attr "type" "mmxshft")))
;; "decodern,p0")
;; SSE is very complicated, and takes a bit more effort.
;; ??? I assumed that all SSE instructions decode on decoder0,
;; but is this correct?
;; The sfence instruction.
(define_insn_reservation "ppro_sse_sfence" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "unknown")
(eq_attr "type" "sse")))
"decoder0,p4+p3")
;; FIXME: This reservation is all wrong when we're scheduling sqrtss.
(define_insn_reservation "ppro_sse_SF" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "mode" "SF")
(eq_attr "type" "sse")))
"decodern,p0")
(define_insn_reservation "ppro_sse_add_SF" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "sseadd"))))
"decodern,p1")
(define_insn_reservation "ppro_sse_add_SF_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "SF")
(eq_attr "type" "sseadd"))))
"decoder0,p2+p1")
(define_insn_reservation "ppro_sse_cmp_SF" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssecmp"))))
"decoder0,p1")
(define_insn_reservation "ppro_sse_cmp_SF_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssecmp"))))
"decoder0,p2+p1")
(define_insn_reservation "ppro_sse_comi_SF" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssecomi"))))
"decodern,p0")
(define_insn_reservation "ppro_sse_comi_SF_load" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssecomi"))))
"decoder0,p2+p0")
(define_insn_reservation "ppro_sse_mul_SF" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssemul"))))
"decodern,p0")
(define_insn_reservation "ppro_sse_mul_SF_load" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssemul"))))
"decoder0,p2+p0")
;; FIXME: ssediv doesn't close p0 for 17 cycles, surely???
(define_insn_reservation "ppro_sse_div_SF" 18
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssediv"))))
"decoder0,p0*17")
(define_insn_reservation "ppro_sse_div_SF_load" 18
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssediv"))))
"decoder0,(p2+p0),p0*16")
(define_insn_reservation "ppro_sse_icvt_SF" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "mode" "SF")
(eq_attr "type" "sseicvt")))
"decoder0,(p2+p1)*2")
(define_insn_reservation "ppro_sse_icvt_SI" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "mode" "SI")
(eq_attr "type" "sseicvt")))
"decoder0,(p2+p1)")
(define_insn_reservation "ppro_sse_mov_SF" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssemov"))))
"decoder0,(p0|p1)")
(define_insn_reservation "ppro_sse_mov_SF_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssemov"))))
"decoder0,p2+(p0|p1)")
(define_insn_reservation "ppro_sse_mov_SF_store" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "store")
(and (eq_attr "mode" "SF")
(eq_attr "type" "ssemov"))))
"decoder0,p4+p3")
(define_insn_reservation "ppro_sse_V4SF" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "sse")))
"decoder0,p1*2")
(define_insn_reservation "ppro_sse_add_V4SF" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "sseadd"))))
"decoder0,p1*2")
(define_insn_reservation "ppro_sse_add_V4SF_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "sseadd"))))
"decoder0,(p2+p1)*2")
(define_insn_reservation "ppro_sse_cmp_V4SF" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssecmp"))))
"decoder0,p1*2")
(define_insn_reservation "ppro_sse_cmp_V4SF_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssecmp"))))
"decoder0,(p2+p1)*2")
(define_insn_reservation "ppro_sse_cvt_V4SF" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none,unknown")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssecvt"))))
"decoder0,p1*2")
(define_insn_reservation "ppro_sse_cvt_V4SF_other" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "!none,unknown")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssecmp"))))
"decoder0,p1,p4+p3")
(define_insn_reservation "ppro_sse_mul_V4SF" 5
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssemul"))))
"decoder0,p0*2")
(define_insn_reservation "ppro_sse_mul_V4SF_load" 5
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssemul"))))
"decoder0,(p2+p0)*2")
;; FIXME: p0 really closed this long???
(define_insn_reservation "ppro_sse_div_V4SF" 48
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssediv"))))
"decoder0,p0*34")
(define_insn_reservation "ppro_sse_div_V4SF_load" 48
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssediv"))))
"decoder0,(p2+p0)*2,p0*32")
(define_insn_reservation "ppro_sse_log_V4SF" 2
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "sselog,sselog1"))))
"decodern,p1")
(define_insn_reservation "ppro_sse_log_V4SF_load" 2
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "sselog,sselog1"))))
"decoder0,(p2+p1)")
(define_insn_reservation "ppro_sse_mov_V4SF" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssemov"))))
"decoder0,(p0|p1)*2")
(define_insn_reservation "ppro_sse_mov_V4SF_load" 2
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssemov"))))
"decoder0,p2*2")
(define_insn_reservation "ppro_sse_mov_V4SF_store" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "store")
(and (eq_attr "mode" "V4SF")
(eq_attr "type" "ssemov"))))
"decoder0,(p4+p3)*2")
;; All other instructions are modelled as simple instructions.
;; We have already modelled all i387 floating point instructions, so all
;; other instructions execute on either port 0 or port 1. This includes
;; the ALU units, and the MMX units.
;;
;; reg-reg instructions produce 1 uop so they can be decoded on any of
;; the three decoders.
(define_insn_reservation "ppro_insn" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "none,unknown")
(eq_attr "type" "alu,alu1,negnot,incdec,icmp,test,setcc,icmov,push,pop,fxch,sseiadd,sseishft,sseishft1,sseimul,mmx,mmxadd,mmxcmp")))
"decodern,(p0|p1)")
;; read-modify and register-memory instructions have 2 or three uops,
;; so they have to be decoded on decoder0.
(define_insn_reservation "ppro_insn_load" 3
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "load")
(eq_attr "type" "alu,alu1,negnot,incdec,icmp,test,setcc,icmov,push,pop,fxch,sseiadd,sseishft,sseishft1,sseimul,mmx,mmxadd,mmxcmp")))
"decoder0,p2+(p0|p1)")
(define_insn_reservation "ppro_insn_store" 1
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "store")
(eq_attr "type" "alu,alu1,negnot,incdec,icmp,test,setcc,icmov,push,pop,fxch,sseiadd,sseishft,sseishft1,sseimul,mmx,mmxadd,mmxcmp")))
"decoder0,(p0|p1),p4+p3")
;; read-modify-store instructions produce 4 uops so they have to be
;; decoded on decoder0 as well.
(define_insn_reservation "ppro_insn_both" 4
(and (eq_attr "cpu" "pentiumpro")
(and (eq_attr "memory" "both")
(eq_attr "type" "alu,alu1,negnot,incdec,icmp,test,setcc,icmov,push,pop,fxch,sseiadd,sseishft,sseishft1,sseimul,mmx,mmxadd,mmxcmp")))
"decoder0,p2+(p0|p1),p4+p3")
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