path: root/verilog/ConstpropOp.vp

(* *********************************************************************)
(*                                                                     *)
(*              The Compcert verified compiler                         *)
(*                                                                     *)
(*                  Xavier Leroy, INRIA Paris                          *)
(*                                                                     *)
(*  Copyright Institut National de Recherche en Informatique et en     *)
(*  Automatique.  All rights reserved.  This file is distributed       *)
(*  under the terms of the INRIA Non-Commercial License Agreement.     *)
(*                                                                     *)
(* *********************************************************************)

(** Strength reduction for operators and conditions.
    This is the machine-dependent part of [Constprop]. *)

Require Import Coqlib Compopts.
Require Import AST Integers Floats.
Require Import Op Registers.
Require Import ValueDomain ValueAOp.
Require SelectOp.

(** * Converting known values to constants *)

Definition Olea_ptr (a: addressing) := if Archi.ptr64 then Oleal a else Olea a.

Definition const_for_result (a: aval) : option operation :=
  match a with
  | I n => Some(Ointconst n)
  | L n => if Archi.ptr64 then Some(Olongconst n) else None
  | F n => if Compopts.generate_float_constants tt then Some(Ofloatconst n) else None
  | FS n => if Compopts.generate_float_constants tt then Some(Osingleconst n) else None
  | Ptr(Gl id ofs) =>
      if SelectOp.symbol_is_external id then
        if Ptrofs.eq ofs Ptrofs.zero then Some (Oindirectsymbol id) else None
      else
        Some (Olea_ptr (Aglobal id ofs))
  | Ptr(Stk ofs) => Some(Olea_ptr (Ainstack ofs))
  | _ => None
  end.

(** * Operator strength reduction *)

(** We now define auxiliary functions for strength reduction of
  operators and addressing modes: replacing an operator with a cheaper
  one if some of its arguments are statically known.  These are again
  large pattern-matchings expressed in indirect style. *)

Nondetfunction cond_strength_reduction
              (cond: condition) (args: list reg) (vl: list aval) :=
  match cond, args, vl with
  | Ccomp c, r1 :: r2 :: nil, I n1 :: v2 :: nil =>
      (Ccompimm (swap_comparison c) n1, r2 :: nil)
  | Ccomp c, r1 :: r2 :: nil, v1 :: I n2 :: nil =>
      (Ccompimm c n2, r1 :: nil)
  | Ccompu c, r1 :: r2 :: nil, I n1 :: v2 :: nil =>
      (Ccompuimm (swap_comparison c) n1, r2 :: nil)
  | Ccompu c, r1 :: r2 :: nil, v1 :: I n2 :: nil =>
      (Ccompuimm c n2, r1 :: nil)
  | Ccompl c, r1 :: r2 :: nil, L n1 :: v2 :: nil =>
      (Ccomplimm (swap_comparison c) n1, r2 :: nil)
  | Ccompl c, r1 :: r2 :: nil, v1 :: L n2 :: nil =>
      (Ccomplimm c n2, r1 :: nil)
  | Ccomplu c, r1 :: r2 :: nil, L n1 :: v2 :: nil =>
      (Ccompluimm (swap_comparison c) n1, r2 :: nil)
  | Ccomplu c, r1 :: r2 :: nil, v1 :: L n2 :: nil =>
      (Ccompluimm c n2, r1 :: nil)
  | _, _, _ =>
      (cond, args)
  end.

Definition make_cmp_base (c: condition) (args: list reg) (vl: list aval) :=
  let (c', args') := cond_strength_reduction c args vl in (Ocmp c', args').

Definition make_cmp_imm_eq (c: condition) (args: list reg) (vl: list aval) 
                           (n: int) (r1: reg) (v1: aval) :=
  if Int.eq_dec n Int.one && vincl v1 (Uns Ptop 1) then (Omove, r1 :: nil)
  else if Int.eq_dec n Int.zero && vincl v1 (Uns Ptop 1) then (Oxorimm Int.one, r1 :: nil)
  else make_cmp_base c args vl.

Definition make_cmp_imm_ne (c: condition) (args: list reg) (vl: list aval) 
                           (n: int) (r1: reg) (v1: aval) :=
  if Int.eq_dec n Int.zero && vincl v1 (Uns Ptop 1) then (Omove, r1 :: nil)
  else if Int.eq_dec n Int.one && vincl v1 (Uns Ptop 1) then (Oxorimm Int.one, r1 :: nil)
  else make_cmp_base c args vl.

Nondetfunction make_cmp (c: condition) (args: list reg) (vl: list aval) :=
  match c, args, vl with
  | Ccompimm Ceq n, r1 :: nil, v1 :: nil =>
      make_cmp_imm_eq c args vl n r1 v1
  | Ccompimm Cne n, r1 :: nil, v1 :: nil =>
      make_cmp_imm_ne c args vl n r1 v1
  | Ccompuimm Ceq n, r1 :: nil, v1 :: nil =>
      make_cmp_imm_eq c args vl n r1 v1
  | Ccompuimm Cne n, r1 :: nil, v1 :: nil =>
      make_cmp_imm_ne c args vl n r1 v1
  | _, _, _ =>
      make_cmp_base c args vl
  end.

Definition make_select (c: condition) (ty: typ)
                       (r1 r2: reg) (args: list reg) (vl: list aval) :=
  match resolve_branch (eval_static_condition c vl) with
  | Some b => (Omove, (if b then r1 else r2) :: nil)
  | None =>
      let (c', args') := cond_strength_reduction c args vl in
      (Osel c' ty, r1 :: r2 :: args')
  end.

(** For addressing modes, we need to distinguish
- reductions that produce pointers (i.e. that produce [Aglobal], [Ainstack], [Abased] and [Abasedscaled] addressing modes), which are valid only if the pointer size is right;
- other reductions (producing [Aindexed] or [Aindexed2] modes), which are valid independently of the pointer size.
*)

Nondetfunction addr_strength_reduction_32_generic
                (addr: addressing) (args: list reg) (vl: list aval) :=
  match addr, args, vl with
  | Aindexed2 ofs, r1 :: r2 :: nil, I n1 :: v2 :: nil =>
      (Aindexed (Int.signed n1 + ofs), r2 :: nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, v1 :: I n2 :: nil =>
      (Aindexed (Int.signed n2 + ofs), r1 :: nil)
  | Aindexed2scaled sc ofs, r1 :: r2 :: nil, v1 :: I n2 :: nil =>
      (Aindexed (Int.signed n2 * sc + ofs), r1 :: nil)
  | Aindexed2scaled sc ofs, r1 :: r2 :: nil, I n1 :: v2 :: nil =>
      (Ascaled sc (Int.signed n1 + ofs), r2 :: nil)
  | _, _ =>
      (addr, args)
  end.

Nondetfunction addr_strength_reduction_32
                (addr: addressing) (args: list reg) (vl: list aval) :=

  if Archi.ptr64 then addr_strength_reduction_32_generic addr args vl else

  match addr, args, vl with

  | Aindexed ofs, r1 :: nil, Ptr(Gl symb n) :: nil =>
      (Aglobal symb (Ptrofs.add n (Ptrofs.repr ofs)), nil)
  | Aindexed ofs, r1 :: nil, Ptr(Stk n) :: nil =>
      (Ainstack (Ptrofs.add n (Ptrofs.repr ofs)), nil)

  | Aindexed2 ofs, r1 :: r2 :: nil, Ptr(Gl symb n1) :: I n2 :: nil =>
      (Aglobal symb (Ptrofs.add (Ptrofs.add n1 (Ptrofs.of_int n2)) (Ptrofs.repr ofs)), nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, I n1 :: Ptr(Gl symb n2) :: nil =>
      (Aglobal symb (Ptrofs.add (Ptrofs.add n2 (Ptrofs.of_int n1)) (Ptrofs.repr ofs)), nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, Ptr(Stk n1) :: I n2 :: nil =>
      (Ainstack (Ptrofs.add (Ptrofs.add n1 (Ptrofs.of_int n2)) (Ptrofs.repr ofs)), nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, I n1 :: Ptr(Stk n2) :: nil =>
      (Ainstack (Ptrofs.add (Ptrofs.add (Ptrofs.of_int n1) n2) (Ptrofs.repr ofs)), nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, Ptr(Gl symb n1) :: v2 :: nil =>
      (Abased symb (Ptrofs.add n1 (Ptrofs.repr ofs)), r2 :: nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, v1 :: Ptr(Gl symb n2) :: nil =>
      (Abased symb (Ptrofs.add n2 (Ptrofs.repr ofs)), r1 :: nil)

  | Aindexed2scaled sc ofs, r1 :: r2 :: nil, Ptr(Gl symb n1) :: I n2 :: nil =>
      (Aglobal symb (Ptrofs.add (Ptrofs.add n1 (Ptrofs.of_int (Int.mul n2 (Int.repr sc)))) (Ptrofs.repr ofs)), nil)

  | Aindexed2scaled sc ofs, r1 :: r2 :: nil, Ptr(Gl symb n1) :: v2 :: nil =>
      (Abasedscaled sc symb (Ptrofs.add n1 (Ptrofs.repr ofs)), r2 :: nil)

  | Abased id ofs, r1 :: nil, I n1 :: nil =>
      (Aglobal id (Ptrofs.add ofs (Ptrofs.of_int n1)), nil)

  | Abasedscaled sc id ofs, r1 :: nil, I n1 :: nil =>
      (Aglobal id (Ptrofs.add ofs (Ptrofs.of_int (Int.mul n1 (Int.repr sc)))), nil)

  | _, _ =>
      addr_strength_reduction_32_generic addr args vl
  end.

Nondetfunction addr_strength_reduction_64_generic
                (addr: addressing) (args: list reg) (vl: list aval) :=
  match addr, args, vl with
  | Aindexed2 ofs, r1 :: r2 :: nil, L n1 :: v2 :: nil =>
      (Aindexed (Int64.signed n1 + ofs), r2 :: nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, v1 :: L n2 :: nil =>
      (Aindexed (Int64.signed n2 + ofs), r1 :: nil)
  | Aindexed2scaled sc ofs, r1 :: r2 :: nil, v1 :: L n2 :: nil =>
      (Aindexed (Int64.signed n2 * sc + ofs), r1 :: nil)
  | Aindexed2scaled sc ofs, r1 :: r2 :: nil, L n1 :: v2 :: nil =>
      (Ascaled sc (Int64.signed n1 + ofs), r2 :: nil)
  | _, _ =>
      (addr, args)
  end.

Nondetfunction addr_strength_reduction_64
                (addr: addressing) (args: list reg) (vl: list aval) :=

  if negb Archi.ptr64 then addr_strength_reduction_64_generic addr args vl else

  match addr, args, vl with

  | Aindexed ofs, r1 :: nil, Ptr(Gl symb n) :: nil =>
      (Aglobal symb (Ptrofs.add n (Ptrofs.repr ofs)), nil)
  | Aindexed ofs, r1 :: nil, Ptr(Stk n) :: nil =>
      (Ainstack (Ptrofs.add n (Ptrofs.repr ofs)), nil)

  | Aindexed2 ofs, r1 :: r2 :: nil, Ptr(Gl symb n1) :: L n2 :: nil =>
      (Aglobal symb (Ptrofs.add (Ptrofs.add n1 (Ptrofs.of_int64 n2)) (Ptrofs.repr ofs)), nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, L n1 :: Ptr(Gl symb n2) :: nil =>
      (Aglobal symb (Ptrofs.add (Ptrofs.add n2 (Ptrofs.of_int64 n1)) (Ptrofs.repr ofs)), nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, Ptr(Stk n1) :: L n2 :: nil =>
      (Ainstack (Ptrofs.add (Ptrofs.add n1 (Ptrofs.of_int64 n2)) (Ptrofs.repr ofs)), nil)
  | Aindexed2 ofs, r1 :: r2 :: nil, L n1 :: Ptr(Stk n2) :: nil =>
      (Ainstack (Ptrofs.add (Ptrofs.add (Ptrofs.of_int64 n1) n2) (Ptrofs.repr ofs)), nil)

  | Aindexed2scaled sc ofs, r1 :: r2 :: nil, Ptr(Gl symb n1) :: L n2 :: nil =>
      (Aglobal symb (Ptrofs.add (Ptrofs.add n1 (Ptrofs.of_int64 (Int64.mul n2 (Int64.repr sc)))) (Ptrofs.repr ofs)), nil)

  | _, _ =>
      addr_strength_reduction_64_generic addr args vl
  end.

Definition addr_strength_reduction
                (addr: addressing) (args: list reg) (vl: list aval) :=
  let addr_args' := 
    if Archi.ptr64
    then addr_strength_reduction_64 addr args vl
    else addr_strength_reduction_32 addr args vl in
  if addressing_valid (fst addr_args') then addr_args' else (addr, args).

Definition make_addimm (n: int) (r: reg) :=
  if Int.eq n Int.zero
  then (Omove, r :: nil)
  else (Olea (Aindexed (Int.signed n)), r :: nil).

Definition make_shlimm (n: int) (r1 r2: reg) :=
  if Int.eq n Int.zero then (Omove, r1 :: nil)
  else if Int.ltu n Int.iwordsize then (Oshlimm n, r1 :: nil)
  else (Oshl, r1 :: r2 :: nil).

Definition make_shrimm (n: int) (r1 r2: reg) :=
  if Int.eq n Int.zero then (Omove, r1 :: nil)
  else if Int.ltu n Int.iwordsize then (Oshrimm n, r1 :: nil)
  else (Oshr, r1 :: r2 :: nil).

Definition make_shruimm (n: int) (r1 r2: reg) :=
  if Int.eq n Int.zero then (Omove, r1 :: nil)
  else if Int.ltu n Int.iwordsize then (Oshruimm n, r1 :: nil)
  else (Oshru, r1 :: r2 :: nil).

Definition make_mulimm (n: int) (r: reg) :=
  if Int.eq n Int.zero then
    (Ointconst Int.zero, nil)
  else if Int.eq n Int.one then
    (Omove, r :: nil)
  else
    match Int.is_power2 n with
    | Some l => (Oshlimm l, r :: nil)
    | None => (Omulimm n, r :: nil)
    end.

Definition make_andimm (n: int) (r: reg) (a: aval) :=
  if Int.eq n Int.zero then (Ointconst Int.zero, nil)
  else if Int.eq n Int.mone then (Omove, r :: nil)
  else if match a with Uns _ m => Int.eq (Int.zero_ext m (Int.not n)) Int.zero
                     | _ => false end
  then (Omove, r :: nil)
  else (Oandimm n, r :: nil).

Definition make_orimm (n: int) (r: reg) :=
  if Int.eq n Int.zero then (Omove, r :: nil)
  else if Int.eq n Int.mone then (Ointconst Int.mone, nil)
  else (Oorimm n, r :: nil).

Definition make_xorimm (n: int) (r: reg) :=
  if Int.eq n Int.zero then (Omove, r :: nil)
  else if Int.eq n Int.mone then (Onot, r :: nil)
  else (Oxorimm n, r :: nil).

Definition make_divimm n (r1 r2: reg) :=
  if Int.eq n Int.one then
    (Omove, r1 :: nil)
  else
    match Int.is_power2 n with
    | Some l => if Int.ltu l (Int.repr 31)
                then (Oshrximm l, r1 :: nil)
                else (Odiv, r1 :: r2 :: nil)
    | None   => (Odiv, r1 :: r2 :: nil)
    end.

Definition make_divuimm n (r1 r2: reg) :=
  if Int.eq n Int.one then
    (Omove, r1 :: nil)
  else
    match Int.is_power2 n with
    | Some l => (Oshruimm l, r1 :: nil)
    | None   => (Odivu, r1 :: r2 :: nil)
    end.

Definition make_moduimm n (r1 r2: reg) :=
  match Int.is_power2 n with
  | Some l => (Oandimm (Int.sub n Int.one), r1 :: nil)
  | None   => (Omodu, r1 :: r2 :: nil)
  end.

Definition make_addlimm (n: int64) (r: reg) :=
  if Int64.eq n Int64.zero
  then (Omove, r :: nil)
  else (Oleal (Aindexed (Int64.signed n)), r :: nil).

Definition make_shllimm (n: int) (r1 r2: reg) :=
  if Int.eq n Int.zero then (Omove, r1 :: nil)
  else if Int.ltu n Int64.iwordsize' then (Oshllimm n, r1 :: nil)
  else (Oshll, r1 :: r2 :: nil).

Definition make_shrlimm (n: int) (r1 r2: reg) :=
  if Int.eq n Int.zero then (Omove, r1 :: nil)
  else if Int.ltu n Int64.iwordsize' then (Oshrlimm n, r1 :: nil)
  else (Oshrl, r1 :: r2 :: nil).

Definition make_shrluimm (n: int) (r1 r2: reg) :=
  if Int.eq n Int.zero then (Omove, r1 :: nil)
  else if Int.ltu n Int64.iwordsize' then (Oshrluimm n, r1 :: nil)
  else (Oshrlu, r1 :: r2 :: nil).

Definition make_mullimm (n: int64) (r: reg) :=
  if Int64.eq n Int64.zero then
    (Olongconst Int64.zero, nil)
  else if Int64.eq n Int64.one then
    (Omove, r :: nil)
  else
    match Int64.is_power2' n with
    | Some l => (Oshllimm l, r :: nil)
    | None => (Omullimm n, r :: nil)
    end.

Definition make_andlimm (n: int64) (r: reg) (a: aval) :=
  if Int64.eq n Int64.zero then (Olongconst Int64.zero, nil)
  else if Int64.eq n Int64.mone then (Omove, r :: nil)
  else (Oandlimm n, r :: nil).

Definition make_orlimm (n: int64) (r: reg) :=
  if Int64.eq n Int64.zero then (Omove, r :: nil)
  else if Int64.eq n Int64.mone then (Olongconst Int64.mone, nil)
  else (Oorlimm n, r :: nil).

Definition make_xorlimm (n: int64) (r: reg) :=
  if Int64.eq n Int64.zero then (Omove, r :: nil)
  else if Int64.eq n Int64.mone then (Onotl, r :: nil)
  else (Oxorlimm n, r :: nil).

Definition make_divlimm n (r1 r2: reg) :=
  match Int64.is_power2' n with
  | Some l => if Int.ltu l (Int.repr 63)
              then (Oshrxlimm l, r1 :: nil)
              else (Odivl, r1 :: r2 :: nil)
  | None   => (Odivl, r1 :: r2 :: nil)
  end.

Definition make_divluimm n (r1 r2: reg) :=
  match Int64.is_power2' n with
  | Some l => (Oshrluimm l, r1 :: nil)
  | None   => (Odivlu, r1 :: r2 :: nil)
  end.

Definition make_modluimm n (r1 r2: reg) :=
  match Int64.is_power2 n with
  | Some l => (Oandlimm (Int64.sub n Int64.one), r1 :: nil)
  | None   => (Omodlu, r1 :: r2 :: nil)
  end.

Definition make_mulfimm (n: float) (r r1 r2: reg) :=
  if Float.eq_dec n (Float.of_int (Int.repr 2))
  then (Oaddf, r :: r :: nil)
  else (Omulf, r1 :: r2 :: nil).

Definition make_mulfsimm (n: float32) (r r1 r2: reg) :=
  if Float32.eq_dec n (Float32.of_int (Int.repr 2))
  then (Oaddfs, r :: r :: nil)
  else (Omulfs, r1 :: r2 :: nil).

Definition make_cast8signed (r: reg) (a: aval) :=
  if vincl a (Sgn Ptop 8) then (Omove, r :: nil) else (Ocast8signed, r :: nil).
Definition make_cast8unsigned (r: reg) (a: aval) :=
  if vincl a (Uns Ptop 8) then (Omove, r :: nil) else (Ocast8unsigned, r :: nil).
Definition make_cast16signed (r: reg) (a: aval) :=
  if vincl a (Sgn Ptop 16) then (Omove, r :: nil) else (Ocast16signed, r :: nil).
Definition make_cast16unsigned (r: reg) (a: aval) :=
  if vincl a (Uns Ptop 16) then (Omove, r :: nil) else (Ocast16unsigned, r :: nil).

Nondetfunction op_strength_reduction
              (op: operation) (args: list reg) (vl: list aval) :=
  match op, args, vl with
  | Ocast8signed, r1 :: nil, v1 :: nil => make_cast8signed r1 v1
  | Ocast8unsigned, r1 :: nil, v1 :: nil => make_cast8unsigned r1 v1
  | Ocast16signed, r1 :: nil, v1 :: nil => make_cast16signed r1 v1
  | Ocast16unsigned, r1 :: nil, v1 :: nil => make_cast16unsigned r1 v1
  | Osub, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_addimm (Int.neg n2) r1
  | Omul, r1 :: r2 :: nil, I n1 :: v2 :: nil => make_mulimm n1 r2
  | Omul, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_mulimm n2 r1
  | Odiv, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_divimm n2 r1 r2
  | Odivu, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_divuimm n2 r1 r2
  | Omodu, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_moduimm n2 r1 r2
  | Oand, r1 :: r2 :: nil, I n1 :: v2 :: nil => make_andimm n1 r2 v2
  | Oand, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_andimm n2 r1 v1
  | Oandimm n, r1 :: nil, v1 :: nil => make_andimm n r1 v1
  | Oor, r1 :: r2 :: nil, I n1 :: v2 :: nil => make_orimm n1 r2
  | Oor, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_orimm n2 r1
  | Oxor, r1 :: r2 :: nil, I n1 :: v2 :: nil => make_xorimm n1 r2
  | Oxor, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_xorimm n2 r1
  | Oshl, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_shlimm n2 r1 r2
  | Oshr, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_shrimm n2 r1 r2
  | Oshru, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_shruimm n2 r1 r2
  | Olea addr, args, vl =>
      let (addr', args') := addr_strength_reduction_32 addr args vl in
      (Olea addr', args')
  | Osubl, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_addlimm (Int64.neg n2) r1
  | Omull, r1 :: r2 :: nil, L n1 :: v2 :: nil => make_mullimm n1 r2
  | Omull, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_mullimm n2 r1
  | Odivl, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_divlimm n2 r1 r2
  | Odivlu, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_divluimm n2 r1 r2
  | Omodlu, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_modluimm n2 r1 r2
  | Oandl, r1 :: r2 :: nil, L n1 :: v2 :: nil => make_andlimm n1 r2 v2
  | Oandl, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_andlimm n2 r1 v1
  | Oandlimm n, r1 :: nil, v1 :: nil => make_andlimm n r1 v1
  | Oorl, r1 :: r2 :: nil, L n1 :: v2 :: nil => make_orlimm n1 r2
  | Oorl, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_orlimm n2 r1
  | Oxorl, r1 :: r2 :: nil, L n1 :: v2 :: nil => make_xorlimm n1 r2
  | Oxorl, r1 :: r2 :: nil, v1 :: L n2 :: nil => make_xorlimm n2 r1
  | Oshll, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_shllimm n2 r1 r2
  | Oshrl, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_shrlimm n2 r1 r2
  | Oshrlu, r1 :: r2 :: nil, v1 :: I n2 :: nil => make_shrluimm n2 r1 r2
  | Oleal addr, args, vl =>
      let (addr', args') := addr_strength_reduction_64 addr args vl in
      (Oleal addr', args')
  | Ocmp c, args, vl => make_cmp c args vl
  | Osel c ty, r1 :: r2 :: args, v1 :: v2 :: vl => make_select c ty r1 r2 args vl
  | Omulf, r1 :: r2 :: nil, v1 :: F n2 :: nil => make_mulfimm n2 r1 r1 r2
  | Omulf, r1 :: r2 :: nil, F n1 :: v2 :: nil => make_mulfimm n1 r2 r1 r2
  | Omulfs, r1 :: r2 :: nil, v1 :: FS n2 :: nil => make_mulfsimm n2 r1 r1 r2
  | Omulfs, r1 :: r2 :: nil, FS n1 :: v2 :: nil => make_mulfsimm n1 r2 r1 r2
  | _, _, _ => (op, args)
  end.