| (* Common code for ARM NEON header file, documentation and test case |
| generators. |
| |
| Copyright (C) 2006-2015 Free Software Foundation, Inc. |
| Contributed by CodeSourcery. |
| |
| 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/>. *) |
| |
| (* Shorthand types for vector elements. *) |
| type elts = S8 | S16 | S32 | S64 | F16 | F32 | U8 | U16 | U32 | U64 | P8 | P16 |
| | P64 | P128 | I8 | I16 | I32 | I64 | B8 | B16 | B32 | B64 | Conv of elts * elts |
| | Cast of elts * elts | NoElts |
| |
| type eltclass = Signed | Unsigned | Float | Poly | Int | Bits |
| | ConvClass of eltclass * eltclass | NoType |
| |
| (* These vector types correspond directly to C types. *) |
| type vectype = T_int8x8 | T_int8x16 |
| | T_int16x4 | T_int16x8 |
| | T_int32x2 | T_int32x4 |
| | T_int64x1 | T_int64x2 |
| | T_uint8x8 | T_uint8x16 |
| | T_uint16x4 | T_uint16x8 |
| | T_uint32x2 | T_uint32x4 |
| | T_uint64x1 | T_uint64x2 |
| | T_float16x4 |
| | T_float32x2 | T_float32x4 |
| | T_poly8x8 | T_poly8x16 |
| | T_poly16x4 | T_poly16x8 |
| | T_immediate of int * int |
| | T_int8 | T_int16 |
| | T_int32 | T_int64 |
| | T_uint8 | T_uint16 |
| | T_uint32 | T_uint64 |
| | T_poly8 | T_poly16 |
| | T_poly64 | T_poly64x1 |
| | T_poly64x2 | T_poly128 |
| | T_float16 | T_float32 |
| | T_arrayof of int * vectype |
| | T_ptrto of vectype | T_const of vectype |
| | T_void | T_intQI |
| | T_intHI | T_intSI |
| | T_intDI | T_intTI |
| | T_floatHF | T_floatSF |
| |
| (* The meanings of the following are: |
| TImode : "Tetra", two registers (four words). |
| EImode : "hExa", three registers (six words). |
| OImode : "Octa", four registers (eight words). |
| CImode : "dodeCa", six registers (twelve words). |
| XImode : "heXadeca", eight registers (sixteen words). |
| *) |
| |
| type inttype = B_TImode | B_EImode | B_OImode | B_CImode | B_XImode |
| |
| type shape_elt = Dreg | Qreg | Corereg | Immed | VecArray of int * shape_elt |
| | PtrTo of shape_elt | CstPtrTo of shape_elt |
| (* These next ones are used only in the test generator. *) |
| | Element_of_dreg (* Used for "lane" variants. *) |
| | Element_of_qreg (* Likewise. *) |
| | All_elements_of_dreg (* Used for "dup" variants. *) |
| | Alternatives of shape_elt list (* Used for multiple valid operands *) |
| |
| type shape_form = All of int * shape_elt |
| | Long |
| | Long_noreg of shape_elt |
| | Wide |
| | Wide_noreg of shape_elt |
| | Narrow |
| | Long_imm |
| | Narrow_imm |
| | Binary_imm of shape_elt |
| | Use_operands of shape_elt array |
| | By_scalar of shape_elt |
| | Unary_scalar of shape_elt |
| | Wide_lane |
| | Wide_scalar |
| | Pair_result of shape_elt |
| |
| type arity = Arity0 of vectype |
| | Arity1 of vectype * vectype |
| | Arity2 of vectype * vectype * vectype |
| | Arity3 of vectype * vectype * vectype * vectype |
| | Arity4 of vectype * vectype * vectype * vectype * vectype |
| |
| type vecmode = V8QI | V4HI | V4HF |V2SI | V2SF | DI |
| | V16QI | V8HI | V4SI | V4SF | V2DI | TI |
| | QI | HI | SI | SF |
| |
| type opcode = |
| (* Binary ops. *) |
| Vadd |
| | Vmul |
| | Vmla |
| | Vmls |
| | Vfma |
| | Vfms |
| | Vsub |
| | Vceq |
| | Vcge |
| | Vcgt |
| | Vcle |
| | Vclt |
| | Vcage |
| | Vcagt |
| | Vcale |
| | Vcalt |
| | Vtst |
| | Vabd |
| | Vaba |
| | Vmax |
| | Vmin |
| | Vpadd |
| | Vpada |
| | Vpmax |
| | Vpmin |
| | Vrecps |
| | Vrsqrts |
| | Vshl |
| | Vshr_n |
| | Vshl_n |
| | Vsra_n |
| | Vsri |
| | Vsli |
| (* Logic binops. *) |
| | Vand |
| | Vorr |
| | Veor |
| | Vbic |
| | Vorn |
| | Vbsl |
| (* Ops with scalar. *) |
| | Vmul_lane |
| | Vmla_lane |
| | Vmls_lane |
| | Vmul_n |
| | Vmla_n |
| | Vmls_n |
| | Vmull_n |
| | Vmull_lane |
| | Vqdmull_n |
| | Vqdmull_lane |
| | Vqdmulh_n |
| | Vqdmulh_lane |
| (* Unary ops. *) |
| | Vrintn |
| | Vrinta |
| | Vrintp |
| | Vrintm |
| | Vrintz |
| | Vabs |
| | Vneg |
| | Vcls |
| | Vclz |
| | Vcnt |
| | Vrecpe |
| | Vrsqrte |
| | Vmvn |
| (* Vector extract. *) |
| | Vext |
| (* Reverse elements. *) |
| | Vrev64 |
| | Vrev32 |
| | Vrev16 |
| (* Transposition ops. *) |
| | Vtrn |
| | Vzip |
| | Vuzp |
| (* Loads and stores (VLD1/VST1/VLD2...), elements and structures. *) |
| | Vldx of int |
| | Vstx of int |
| | Vldx_lane of int |
| | Vldx_dup of int |
| | Vstx_lane of int |
| (* Set/extract lanes from a vector. *) |
| | Vget_lane |
| | Vset_lane |
| (* Initialize vector from bit pattern. *) |
| | Vcreate |
| (* Set all lanes to same value. *) |
| | Vdup_n |
| | Vmov_n (* Is this the same? *) |
| (* Duplicate scalar to all lanes of vector. *) |
| | Vdup_lane |
| (* Combine vectors. *) |
| | Vcombine |
| (* Get quadword high/low parts. *) |
| | Vget_high |
| | Vget_low |
| (* Convert vectors. *) |
| | Vcvt |
| | Vcvt_n |
| (* Narrow/lengthen vectors. *) |
| | Vmovn |
| | Vmovl |
| (* Table lookup. *) |
| | Vtbl of int |
| | Vtbx of int |
| (* Reinterpret casts. *) |
| | Vreinterp |
| |
| let rev_elems revsize elsize nelts _ = |
| let mask = (revsize / elsize) - 1 in |
| let arr = Array.init nelts |
| (fun i -> i lxor mask) in |
| Array.to_list arr |
| |
| let permute_range i stride nelts increment = |
| let rec build i = function |
| 0 -> [] |
| | nelts -> i :: (i + stride) :: build (i + increment) (pred nelts) in |
| build i nelts |
| |
| (* Generate a list of integers suitable for vzip. *) |
| let zip_range i stride nelts = permute_range i stride nelts 1 |
| |
| (* Generate a list of integers suitable for vunzip. *) |
| let uzip_range i stride nelts = permute_range i stride nelts 4 |
| |
| (* Generate a list of integers suitable for trn. *) |
| let trn_range i stride nelts = permute_range i stride nelts 2 |
| |
| let zip_elems _ nelts part = |
| match part with |
| `lo -> zip_range 0 nelts (nelts / 2) |
| | `hi -> zip_range (nelts / 2) nelts (nelts / 2) |
| |
| let uzip_elems _ nelts part = |
| match part with |
| `lo -> uzip_range 0 2 (nelts / 2) |
| | `hi -> uzip_range 1 2 (nelts / 2) |
| |
| let trn_elems _ nelts part = |
| match part with |
| `lo -> trn_range 0 nelts (nelts / 2) |
| | `hi -> trn_range 1 nelts (nelts / 2) |
| |
| (* Features used for documentation, to distinguish between some instruction |
| variants, and to signal special requirements (e.g. swapping arguments). *) |
| |
| type features = |
| Halving |
| | Rounding |
| | Saturating |
| | Dst_unsign |
| | High_half |
| | Doubling |
| | Flipped of string (* Builtin name to use with flipped arguments. *) |
| | InfoWord (* Pass an extra word for signage/rounding etc. (always passed |
| for All _, Long, Wide, Narrow shape_forms. *) |
| (* Implement builtin as shuffle. The parameter is a function which returns |
| masks suitable for __builtin_shuffle: arguments are (element size, |
| number of elements, high/low part selector). *) |
| | Use_shuffle of (int -> int -> [`lo|`hi] -> int list) |
| (* A specification as to the shape of instruction expected upon |
| disassembly, used if it differs from the shape used to build the |
| intrinsic prototype. Multiple entries in the constructor's argument |
| indicate that the intrinsic expands to more than one assembly |
| instruction, each with a corresponding shape specified here. *) |
| | Disassembles_as of shape_form list |
| | Builtin_name of string (* Override the name of the builtin. *) |
| (* Override the name of the instruction. If more than one name |
| is specified, it means that the instruction can have any of those |
| names. *) |
| | Instruction_name of string list |
| (* Mark that the intrinsic yields no instructions, or expands to yield |
| behavior that the test generator cannot test. *) |
| | No_op |
| (* Mark that the intrinsic has constant arguments that cannot be set |
| to the defaults (zero for pointers and one otherwise) in the test |
| cases. The function supplied must return the integer to be written |
| into the testcase for the argument number (0-based) supplied to it. *) |
| | Const_valuator of (int -> int) |
| | Fixed_vector_reg |
| | Fixed_core_reg |
| (* Mark that the intrinsic requires __ARM_FEATURE_string to be defined. *) |
| | Requires_feature of string |
| (* Mark that the intrinsic requires a particular architecture version. *) |
| | Requires_arch of int |
| (* Mark that the intrinsic requires a particular bit in __ARM_FP to |
| be set. *) |
| | Requires_FP_bit of int |
| (* Compiler optimization level for the test. *) |
| | Compiler_optim of string |
| |
| exception MixedMode of elts * elts |
| |
| let rec elt_width = function |
| S8 | U8 | P8 | I8 | B8 -> 8 |
| | S16 | U16 | P16 | I16 | B16 | F16 -> 16 |
| | S32 | F32 | U32 | I32 | B32 -> 32 |
| | S64 | U64 | P64 | I64 | B64 -> 64 |
| | P128 -> 128 |
| | Conv (a, b) -> |
| let wa = elt_width a and wb = elt_width b in |
| if wa = wb then wa else raise (MixedMode (a, b)) |
| | Cast (a, b) -> raise (MixedMode (a, b)) |
| | NoElts -> failwith "No elts" |
| |
| let rec elt_class = function |
| S8 | S16 | S32 | S64 -> Signed |
| | U8 | U16 | U32 | U64 -> Unsigned |
| | P8 | P16 | P64 | P128 -> Poly |
| | F16 | F32 -> Float |
| | I8 | I16 | I32 | I64 -> Int |
| | B8 | B16 | B32 | B64 -> Bits |
| | Conv (a, b) | Cast (a, b) -> ConvClass (elt_class a, elt_class b) |
| | NoElts -> NoType |
| |
| let elt_of_class_width c w = |
| match c, w with |
| Signed, 8 -> S8 |
| | Signed, 16 -> S16 |
| | Signed, 32 -> S32 |
| | Signed, 64 -> S64 |
| | Float, 16 -> F16 |
| | Float, 32 -> F32 |
| | Unsigned, 8 -> U8 |
| | Unsigned, 16 -> U16 |
| | Unsigned, 32 -> U32 |
| | Unsigned, 64 -> U64 |
| | Poly, 8 -> P8 |
| | Poly, 16 -> P16 |
| | Poly, 64 -> P64 |
| | Poly, 128 -> P128 |
| | Int, 8 -> I8 |
| | Int, 16 -> I16 |
| | Int, 32 -> I32 |
| | Int, 64 -> I64 |
| | Bits, 8 -> B8 |
| | Bits, 16 -> B16 |
| | Bits, 32 -> B32 |
| | Bits, 64 -> B64 |
| | _ -> failwith "Bad element type" |
| |
| (* Return unsigned integer element the same width as argument. *) |
| let unsigned_of_elt elt = |
| elt_of_class_width Unsigned (elt_width elt) |
| |
| let signed_of_elt elt = |
| elt_of_class_width Signed (elt_width elt) |
| |
| (* Return untyped bits element the same width as argument. *) |
| let bits_of_elt elt = |
| elt_of_class_width Bits (elt_width elt) |
| |
| let non_signed_variant = function |
| S8 -> I8 |
| | S16 -> I16 |
| | S32 -> I32 |
| | S64 -> I64 |
| | U8 -> I8 |
| | U16 -> I16 |
| | U32 -> I32 |
| | U64 -> I64 |
| | x -> x |
| |
| let poly_unsigned_variant v = |
| let elclass = match elt_class v with |
| Poly -> Unsigned |
| | x -> x in |
| elt_of_class_width elclass (elt_width v) |
| |
| let widen_elt elt = |
| let w = elt_width elt |
| and c = elt_class elt in |
| elt_of_class_width c (w * 2) |
| |
| let narrow_elt elt = |
| let w = elt_width elt |
| and c = elt_class elt in |
| elt_of_class_width c (w / 2) |
| |
| (* If we're trying to find a mode from a "Use_operands" instruction, use the |
| last vector operand as the dominant mode used to invoke the correct builtin. |
| We must stick to this rule in neon.md. *) |
| let find_key_operand operands = |
| let rec scan opno = |
| match operands.(opno) with |
| Qreg -> Qreg |
| | Dreg -> Dreg |
| | VecArray (_, Qreg) -> Qreg |
| | VecArray (_, Dreg) -> Dreg |
| | _ -> scan (opno-1) |
| in |
| scan ((Array.length operands) - 1) |
| |
| (* Find a vecmode from a shape_elt ELT for an instruction with shape_form |
| SHAPE. For a Use_operands shape, if ARGPOS is passed then return the mode |
| for the given argument position, else determine which argument to return a |
| mode for automatically. *) |
| |
| let rec mode_of_elt ?argpos elt shape = |
| let flt = match elt_class elt with |
| Float | ConvClass(_, Float) -> true | _ -> false in |
| let idx = |
| match elt_width elt with |
| 8 -> 0 | 16 -> 1 | 32 -> 2 | 64 -> 3 | 128 -> 4 |
| | _ -> failwith "Bad element width" |
| in match shape with |
| All (_, Dreg) | By_scalar Dreg | Pair_result Dreg | Unary_scalar Dreg |
| | Binary_imm Dreg | Long_noreg Dreg | Wide_noreg Dreg -> |
| if flt then |
| [| V8QI; V4HF; V2SF; DI |].(idx) |
| else |
| [| V8QI; V4HI; V2SI; DI |].(idx) |
| | All (_, Qreg) | By_scalar Qreg | Pair_result Qreg | Unary_scalar Qreg |
| | Binary_imm Qreg | Long_noreg Qreg | Wide_noreg Qreg -> |
| [| V16QI; V8HI; if flt then V4SF else V4SI; V2DI; TI|].(idx) |
| | All (_, (Corereg | PtrTo _ | CstPtrTo _)) -> |
| [| QI; HI; if flt then SF else SI; DI |].(idx) |
| | Long | Wide | Wide_lane | Wide_scalar |
| | Long_imm -> |
| [| V8QI; V4HI; V2SI; DI |].(idx) |
| | Narrow | Narrow_imm -> [| V16QI; V8HI; V4SI; V2DI |].(idx) |
| | Use_operands ops -> |
| begin match argpos with |
| None -> mode_of_elt ?argpos elt (All (0, (find_key_operand ops))) |
| | Some pos -> mode_of_elt ?argpos elt (All (0, ops.(pos))) |
| end |
| | _ -> failwith "invalid shape" |
| |
| (* Modify an element type dependent on the shape of the instruction and the |
| operand number. *) |
| |
| let shapemap shape no = |
| let ident = fun x -> x in |
| match shape with |
| All _ | Use_operands _ | By_scalar _ | Pair_result _ | Unary_scalar _ |
| | Binary_imm _ -> ident |
| | Long | Long_noreg _ | Wide_scalar | Long_imm -> |
| [| widen_elt; ident; ident |].(no) |
| | Wide | Wide_noreg _ -> [| widen_elt; widen_elt; ident |].(no) |
| | Wide_lane -> [| widen_elt; ident; ident; ident |].(no) |
| | Narrow | Narrow_imm -> [| narrow_elt; ident; ident |].(no) |
| |
| (* Register type (D/Q) of an operand, based on shape and operand number. *) |
| |
| let regmap shape no = |
| match shape with |
| All (_, reg) | Long_noreg reg | Wide_noreg reg -> reg |
| | Long -> [| Qreg; Dreg; Dreg |].(no) |
| | Wide -> [| Qreg; Qreg; Dreg |].(no) |
| | Narrow -> [| Dreg; Qreg; Qreg |].(no) |
| | Wide_lane -> [| Qreg; Dreg; Dreg; Immed |].(no) |
| | Wide_scalar -> [| Qreg; Dreg; Corereg |].(no) |
| | By_scalar reg -> [| reg; reg; Dreg; Immed |].(no) |
| | Unary_scalar reg -> [| reg; Dreg; Immed |].(no) |
| | Pair_result reg -> [| VecArray (2, reg); reg; reg |].(no) |
| | Binary_imm reg -> [| reg; reg; Immed |].(no) |
| | Long_imm -> [| Qreg; Dreg; Immed |].(no) |
| | Narrow_imm -> [| Dreg; Qreg; Immed |].(no) |
| | Use_operands these -> these.(no) |
| |
| let type_for_elt shape elt no = |
| let elt = (shapemap shape no) elt in |
| let reg = regmap shape no in |
| let rec type_for_reg_elt reg elt = |
| match reg with |
| Dreg -> |
| begin match elt with |
| S8 -> T_int8x8 |
| | S16 -> T_int16x4 |
| | S32 -> T_int32x2 |
| | S64 -> T_int64x1 |
| | U8 -> T_uint8x8 |
| | U16 -> T_uint16x4 |
| | U32 -> T_uint32x2 |
| | U64 -> T_uint64x1 |
| | P64 -> T_poly64x1 |
| | P128 -> T_poly128 |
| | F16 -> T_float16x4 |
| | F32 -> T_float32x2 |
| | P8 -> T_poly8x8 |
| | P16 -> T_poly16x4 |
| | _ -> failwith "Bad elt type for Dreg" |
| end |
| | Qreg -> |
| begin match elt with |
| S8 -> T_int8x16 |
| | S16 -> T_int16x8 |
| | S32 -> T_int32x4 |
| | S64 -> T_int64x2 |
| | U8 -> T_uint8x16 |
| | U16 -> T_uint16x8 |
| | U32 -> T_uint32x4 |
| | U64 -> T_uint64x2 |
| | F32 -> T_float32x4 |
| | P8 -> T_poly8x16 |
| | P16 -> T_poly16x8 |
| | P64 -> T_poly64x2 |
| | P128 -> T_poly128 |
| | _ -> failwith "Bad elt type for Qreg" |
| end |
| | Corereg -> |
| begin match elt with |
| S8 -> T_int8 |
| | S16 -> T_int16 |
| | S32 -> T_int32 |
| | S64 -> T_int64 |
| | U8 -> T_uint8 |
| | U16 -> T_uint16 |
| | U32 -> T_uint32 |
| | U64 -> T_uint64 |
| | P8 -> T_poly8 |
| | P16 -> T_poly16 |
| | P64 -> T_poly64 |
| | P128 -> T_poly128 |
| | F32 -> T_float32 |
| | _ -> failwith "Bad elt type for Corereg" |
| end |
| | Immed -> |
| T_immediate (0, 0) |
| | VecArray (num, sub) -> |
| T_arrayof (num, type_for_reg_elt sub elt) |
| | PtrTo x -> |
| T_ptrto (type_for_reg_elt x elt) |
| | CstPtrTo x -> |
| T_ptrto (T_const (type_for_reg_elt x elt)) |
| (* Anything else is solely for the use of the test generator. *) |
| | _ -> assert false |
| in |
| type_for_reg_elt reg elt |
| |
| (* Return size of a vector type, in bits. *) |
| let vectype_size = function |
| T_int8x8 | T_int16x4 | T_int32x2 | T_int64x1 |
| | T_uint8x8 | T_uint16x4 | T_uint32x2 | T_uint64x1 |
| | T_float32x2 | T_poly8x8 | T_poly64x1 | T_poly16x4 | T_float16x4 -> 64 |
| | T_int8x16 | T_int16x8 | T_int32x4 | T_int64x2 |
| | T_uint8x16 | T_uint16x8 | T_uint32x4 | T_uint64x2 |
| | T_float32x4 | T_poly8x16 | T_poly64x2 | T_poly16x8 -> 128 |
| | _ -> raise Not_found |
| |
| let inttype_for_array num elttype = |
| let eltsize = vectype_size elttype in |
| let numwords = (num * eltsize) / 32 in |
| match numwords with |
| 4 -> B_TImode |
| | 6 -> B_EImode |
| | 8 -> B_OImode |
| | 12 -> B_CImode |
| | 16 -> B_XImode |
| | _ -> failwith ("no int type for size " ^ string_of_int numwords) |
| |
| (* These functions return pairs of (internal, external) types, where "internal" |
| types are those seen by GCC, and "external" are those seen by the assembler. |
| These types aren't necessarily the same, since the intrinsics can munge more |
| than one C type into each assembler opcode. *) |
| |
| let make_sign_invariant func shape elt = |
| let arity, elt' = func shape elt in |
| arity, non_signed_variant elt' |
| |
| (* Don't restrict any types. *) |
| |
| let elts_same make_arity shape elt = |
| let vtype = type_for_elt shape elt in |
| make_arity vtype, elt |
| |
| (* As sign_invar_*, but when sign matters. *) |
| let elts_same_io_lane = |
| elts_same (fun vtype -> Arity4 (vtype 0, vtype 0, vtype 1, vtype 2, vtype 3)) |
| |
| let elts_same_io = |
| elts_same (fun vtype -> Arity3 (vtype 0, vtype 0, vtype 1, vtype 2)) |
| |
| let elts_same_2_lane = |
| elts_same (fun vtype -> Arity3 (vtype 0, vtype 1, vtype 2, vtype 3)) |
| |
| let elts_same_3 = elts_same_2_lane |
| |
| let elts_same_2 = |
| elts_same (fun vtype -> Arity2 (vtype 0, vtype 1, vtype 2)) |
| |
| let elts_same_1 = |
| elts_same (fun vtype -> Arity1 (vtype 0, vtype 1)) |
| |
| (* Use for signed/unsigned invariant operations (i.e. where the operation |
| doesn't depend on the sign of the data. *) |
| |
| let sign_invar_io_lane = make_sign_invariant elts_same_io_lane |
| let sign_invar_io = make_sign_invariant elts_same_io |
| let sign_invar_2_lane = make_sign_invariant elts_same_2_lane |
| let sign_invar_2 = make_sign_invariant elts_same_2 |
| let sign_invar_1 = make_sign_invariant elts_same_1 |
| |
| (* Sign-sensitive comparison. *) |
| |
| let cmp_sign_matters shape elt = |
| let vtype = type_for_elt shape elt |
| and rtype = type_for_elt shape (unsigned_of_elt elt) 0 in |
| Arity2 (rtype, vtype 1, vtype 2), elt |
| |
| (* Signed/unsigned invariant comparison. *) |
| |
| let cmp_sign_invar shape elt = |
| let shape', elt' = cmp_sign_matters shape elt in |
| let elt'' = |
| match non_signed_variant elt' with |
| P8 -> I8 |
| | x -> x |
| in |
| shape', elt'' |
| |
| (* Comparison (VTST) where only the element width matters. *) |
| |
| let cmp_bits shape elt = |
| let vtype = type_for_elt shape elt |
| and rtype = type_for_elt shape (unsigned_of_elt elt) 0 |
| and bits_only = bits_of_elt elt in |
| Arity2 (rtype, vtype 1, vtype 2), bits_only |
| |
| let reg_shift shape elt = |
| let vtype = type_for_elt shape elt |
| and op2type = type_for_elt shape (signed_of_elt elt) 2 in |
| Arity2 (vtype 0, vtype 1, op2type), elt |
| |
| (* Genericised constant-shift type-generating function. *) |
| |
| let const_shift mkimm ?arity ?result shape elt = |
| let op2type = (shapemap shape 2) elt in |
| let op2width = elt_width op2type in |
| let op2 = mkimm op2width |
| and op1 = type_for_elt shape elt 1 |
| and r_elt = |
| match result with |
| None -> elt |
| | Some restriction -> restriction elt in |
| let rtype = type_for_elt shape r_elt 0 in |
| match arity with |
| None -> Arity2 (rtype, op1, op2), elt |
| | Some mkarity -> mkarity rtype op1 op2, elt |
| |
| (* Use for immediate right-shifts. *) |
| |
| let shift_right shape elt = |
| const_shift (fun imm -> T_immediate (1, imm)) shape elt |
| |
| let shift_right_acc shape elt = |
| const_shift (fun imm -> T_immediate (1, imm)) |
| ~arity:(fun dst op1 op2 -> Arity3 (dst, dst, op1, op2)) shape elt |
| |
| (* Use for immediate right-shifts when the operation doesn't care about |
| signedness. *) |
| |
| let shift_right_sign_invar = |
| make_sign_invariant shift_right |
| |
| (* Immediate right-shift; result is unsigned even when operand is signed. *) |
| |
| let shift_right_to_uns shape elt = |
| const_shift (fun imm -> T_immediate (1, imm)) ~result:unsigned_of_elt |
| shape elt |
| |
| (* Immediate left-shift. *) |
| |
| let shift_left shape elt = |
| const_shift (fun imm -> T_immediate (0, imm - 1)) shape elt |
| |
| (* Immediate left-shift, unsigned result. *) |
| |
| let shift_left_to_uns shape elt = |
| const_shift (fun imm -> T_immediate (0, imm - 1)) ~result:unsigned_of_elt |
| shape elt |
| |
| (* Immediate left-shift, don't care about signs. *) |
| |
| let shift_left_sign_invar = |
| make_sign_invariant shift_left |
| |
| (* Shift left/right and insert: only element size matters. *) |
| |
| let shift_insert shape elt = |
| let arity, elt = |
| const_shift (fun imm -> T_immediate (1, imm)) |
| ~arity:(fun dst op1 op2 -> Arity3 (dst, dst, op1, op2)) shape elt in |
| arity, bits_of_elt elt |
| |
| (* Get/set lane. *) |
| |
| let get_lane shape elt = |
| let vtype = type_for_elt shape elt in |
| Arity2 (vtype 0, vtype 1, vtype 2), |
| (match elt with P8 -> U8 | P16 -> U16 | S32 | U32 | F32 -> B32 | x -> x) |
| |
| let set_lane shape elt = |
| let vtype = type_for_elt shape elt in |
| Arity3 (vtype 0, vtype 1, vtype 2, vtype 3), bits_of_elt elt |
| |
| let set_lane_notype shape elt = |
| let vtype = type_for_elt shape elt in |
| Arity3 (vtype 0, vtype 1, vtype 2, vtype 3), NoElts |
| |
| let create_vector shape elt = |
| let vtype = type_for_elt shape U64 1 |
| and rtype = type_for_elt shape elt 0 in |
| Arity1 (rtype, vtype), elt |
| |
| let conv make_arity shape elt = |
| let edest, esrc = match elt with |
| Conv (edest, esrc) | Cast (edest, esrc) -> edest, esrc |
| | _ -> failwith "Non-conversion element in conversion" in |
| let vtype = type_for_elt shape esrc |
| and rtype = type_for_elt shape edest 0 in |
| make_arity rtype vtype, elt |
| |
| let conv_1 = conv (fun rtype vtype -> Arity1 (rtype, vtype 1)) |
| let conv_2 = conv (fun rtype vtype -> Arity2 (rtype, vtype 1, vtype 2)) |
| |
| (* Operation has an unsigned result even if operands are signed. *) |
| |
| let dst_unsign make_arity shape elt = |
| let vtype = type_for_elt shape elt |
| and rtype = type_for_elt shape (unsigned_of_elt elt) 0 in |
| make_arity rtype vtype, elt |
| |
| let dst_unsign_1 = dst_unsign (fun rtype vtype -> Arity1 (rtype, vtype 1)) |
| |
| let make_bits_only func shape elt = |
| let arity, elt' = func shape elt in |
| arity, bits_of_elt elt' |
| |
| (* Extend operation. *) |
| |
| let extend shape elt = |
| let vtype = type_for_elt shape elt in |
| Arity3 (vtype 0, vtype 1, vtype 2, vtype 3), bits_of_elt elt |
| |
| (* Table look-up operations. Operand 2 is signed/unsigned for signed/unsigned |
| integer ops respectively, or unsigned for polynomial ops. *) |
| |
| let table mkarity shape elt = |
| let vtype = type_for_elt shape elt in |
| let op2 = type_for_elt shape (poly_unsigned_variant elt) 2 in |
| mkarity vtype op2, bits_of_elt elt |
| |
| let table_2 = table (fun vtype op2 -> Arity2 (vtype 0, vtype 1, op2)) |
| let table_io = table (fun vtype op2 -> Arity3 (vtype 0, vtype 0, vtype 1, op2)) |
| |
| (* Operations where only bits matter. *) |
| |
| let bits_1 = make_bits_only elts_same_1 |
| let bits_2 = make_bits_only elts_same_2 |
| let bits_3 = make_bits_only elts_same_3 |
| |
| (* Store insns. *) |
| let store_1 shape elt = |
| let vtype = type_for_elt shape elt in |
| Arity2 (T_void, vtype 0, vtype 1), bits_of_elt elt |
| |
| let store_3 shape elt = |
| let vtype = type_for_elt shape elt in |
| Arity3 (T_void, vtype 0, vtype 1, vtype 2), bits_of_elt elt |
| |
| let make_notype func shape elt = |
| let arity, _ = func shape elt in |
| arity, NoElts |
| |
| let notype_1 = make_notype elts_same_1 |
| let notype_2 = make_notype elts_same_2 |
| let notype_3 = make_notype elts_same_3 |
| |
| (* Bit-select operations (first operand is unsigned int). *) |
| |
| let bit_select shape elt = |
| let vtype = type_for_elt shape elt |
| and itype = type_for_elt shape (unsigned_of_elt elt) in |
| Arity3 (vtype 0, itype 1, vtype 2, vtype 3), NoElts |
| |
| (* Common lists of supported element types. *) |
| |
| let s_8_32 = [S8; S16; S32] |
| let u_8_32 = [U8; U16; U32] |
| let su_8_32 = [S8; S16; S32; U8; U16; U32] |
| let su_8_64 = S64 :: U64 :: su_8_32 |
| let su_16_64 = [S16; S32; S64; U16; U32; U64] |
| let pf_su_8_16 = [P8; P16; S8; S16; U8; U16] |
| let pf_su_8_32 = P8 :: P16 :: F32 :: su_8_32 |
| let pf_su_8_64 = P8 :: P16 :: F32 :: su_8_64 |
| let suf_32 = [S32; U32; F32] |
| |
| let ops = |
| [ |
| (* Addition. *) |
| Vadd, [], All (3, Dreg), "vadd", sign_invar_2, F32 :: su_8_32; |
| Vadd, [No_op], All (3, Dreg), "vadd", sign_invar_2, [S64; U64]; |
| Vadd, [], All (3, Qreg), "vaddQ", sign_invar_2, F32 :: su_8_64; |
| Vadd, [], Long, "vaddl", elts_same_2, su_8_32; |
| Vadd, [], Wide, "vaddw", elts_same_2, su_8_32; |
| Vadd, [Halving], All (3, Dreg), "vhadd", elts_same_2, su_8_32; |
| Vadd, [Halving], All (3, Qreg), "vhaddQ", elts_same_2, su_8_32; |
| Vadd, [Instruction_name ["vrhadd"]; Rounding; Halving], |
| All (3, Dreg), "vRhadd", elts_same_2, su_8_32; |
| Vadd, [Instruction_name ["vrhadd"]; Rounding; Halving], |
| All (3, Qreg), "vRhaddQ", elts_same_2, su_8_32; |
| Vadd, [Saturating], All (3, Dreg), "vqadd", elts_same_2, su_8_64; |
| Vadd, [Saturating], All (3, Qreg), "vqaddQ", elts_same_2, su_8_64; |
| Vadd, [High_half], Narrow, "vaddhn", sign_invar_2, su_16_64; |
| Vadd, [Instruction_name ["vraddhn"]; Rounding; High_half], |
| Narrow, "vRaddhn", sign_invar_2, su_16_64; |
| |
| (* Multiplication. *) |
| Vmul, [], All (3, Dreg), "vmul", sign_invar_2, P8 :: F32 :: su_8_32; |
| Vmul, [], All (3, Qreg), "vmulQ", sign_invar_2, P8 :: F32 :: su_8_32; |
| Vmul, [Saturating; Doubling; High_half], All (3, Dreg), "vqdmulh", |
| elts_same_2, [S16; S32]; |
| Vmul, [Saturating; Doubling; High_half], All (3, Qreg), "vqdmulhQ", |
| elts_same_2, [S16; S32]; |
| Vmul, |
| [Saturating; Rounding; Doubling; High_half; |
| Instruction_name ["vqrdmulh"]], |
| All (3, Dreg), "vqRdmulh", |
| elts_same_2, [S16; S32]; |
| Vmul, |
| [Saturating; Rounding; Doubling; High_half; |
| Instruction_name ["vqrdmulh"]], |
| All (3, Qreg), "vqRdmulhQ", |
| elts_same_2, [S16; S32]; |
| Vmul, [], Long, "vmull", elts_same_2, P8 :: su_8_32; |
| Vmul, [Saturating; Doubling], Long, "vqdmull", elts_same_2, [S16; S32]; |
| |
| (* Multiply-accumulate. *) |
| Vmla, [], All (3, Dreg), "vmla", sign_invar_io, F32 :: su_8_32; |
| Vmla, [], All (3, Qreg), "vmlaQ", sign_invar_io, F32 :: su_8_32; |
| Vmla, [], Long, "vmlal", elts_same_io, su_8_32; |
| Vmla, [Saturating; Doubling], Long, "vqdmlal", elts_same_io, [S16; S32]; |
| |
| (* Multiply-subtract. *) |
| Vmls, [], All (3, Dreg), "vmls", sign_invar_io, F32 :: su_8_32; |
| Vmls, [], All (3, Qreg), "vmlsQ", sign_invar_io, F32 :: su_8_32; |
| Vmls, [], Long, "vmlsl", elts_same_io, su_8_32; |
| Vmls, [Saturating; Doubling], Long, "vqdmlsl", elts_same_io, [S16; S32]; |
| |
| (* Fused-multiply-accumulate. *) |
| Vfma, [Requires_feature "FMA"], All (3, Dreg), "vfma", elts_same_io, [F32]; |
| Vfma, [Requires_feature "FMA"], All (3, Qreg), "vfmaQ", elts_same_io, [F32]; |
| Vfms, [Requires_feature "FMA"], All (3, Dreg), "vfms", elts_same_io, [F32]; |
| Vfms, [Requires_feature "FMA"], All (3, Qreg), "vfmsQ", elts_same_io, [F32]; |
| |
| (* Round to integral. *) |
| Vrintn, [Builtin_name "vrintn"; Requires_arch 8], Use_operands [| Dreg; Dreg |], |
| "vrndn", elts_same_1, [F32]; |
| Vrintn, [Builtin_name "vrintn"; Requires_arch 8], Use_operands [| Qreg; Qreg |], |
| "vrndqn", elts_same_1, [F32]; |
| Vrinta, [Builtin_name "vrinta"; Requires_arch 8], Use_operands [| Dreg; Dreg |], |
| "vrnda", elts_same_1, [F32]; |
| Vrinta, [Builtin_name "vrinta"; Requires_arch 8], Use_operands [| Qreg; Qreg |], |
| "vrndqa", elts_same_1, [F32]; |
| Vrintp, [Builtin_name "vrintp"; Requires_arch 8], Use_operands [| Dreg; Dreg |], |
| "vrndp", elts_same_1, [F32]; |
| Vrintp, [Builtin_name "vrintp"; Requires_arch 8], Use_operands [| Qreg; Qreg |], |
| "vrndqp", elts_same_1, [F32]; |
| Vrintm, [Builtin_name "vrintm"; Requires_arch 8], Use_operands [| Dreg; Dreg |], |
| "vrndm", elts_same_1, [F32]; |
| Vrintm, [Builtin_name "vrintm"; Requires_arch 8], Use_operands [| Qreg; Qreg |], |
| "vrndqm", elts_same_1, [F32]; |
| Vrintz, [Builtin_name "vrintz"; Requires_arch 8], Use_operands [| Dreg; Dreg |], |
| "vrnd", elts_same_1, [F32]; |
| Vrintz, [Builtin_name "vrintz"; Requires_arch 8], Use_operands [| Qreg; Qreg |], |
| "vrndq", elts_same_1, [F32]; |
| (* Subtraction. *) |
| Vsub, [], All (3, Dreg), "vsub", sign_invar_2, F32 :: su_8_32; |
| Vsub, [No_op], All (3, Dreg), "vsub", sign_invar_2, [S64; U64]; |
| Vsub, [], All (3, Qreg), "vsubQ", sign_invar_2, F32 :: su_8_64; |
| Vsub, [], Long, "vsubl", elts_same_2, su_8_32; |
| Vsub, [], Wide, "vsubw", elts_same_2, su_8_32; |
| Vsub, [Halving], All (3, Dreg), "vhsub", elts_same_2, su_8_32; |
| Vsub, [Halving], All (3, Qreg), "vhsubQ", elts_same_2, su_8_32; |
| Vsub, [Saturating], All (3, Dreg), "vqsub", elts_same_2, su_8_64; |
| Vsub, [Saturating], All (3, Qreg), "vqsubQ", elts_same_2, su_8_64; |
| Vsub, [High_half], Narrow, "vsubhn", sign_invar_2, su_16_64; |
| Vsub, [Instruction_name ["vrsubhn"]; Rounding; High_half], |
| Narrow, "vRsubhn", sign_invar_2, su_16_64; |
| |
| (* Comparison, equal. *) |
| Vceq, [], All (3, Dreg), "vceq", cmp_sign_invar, P8 :: F32 :: su_8_32; |
| Vceq, [], All (3, Qreg), "vceqQ", cmp_sign_invar, P8 :: F32 :: su_8_32; |
| |
| (* Comparison, greater-than or equal. *) |
| Vcge, [], All (3, Dreg), "vcge", cmp_sign_matters, F32 :: s_8_32; |
| Vcge, [Instruction_name ["vcge"]; Builtin_name "vcgeu"], |
| All (3, Dreg), "vcge", cmp_sign_matters, |
| u_8_32; |
| Vcge, [], All (3, Qreg), "vcgeQ", cmp_sign_matters, F32 :: s_8_32; |
| Vcge, [Instruction_name ["vcge"]; Builtin_name "vcgeu"], |
| All (3, Qreg), "vcgeQ", cmp_sign_matters, |
| u_8_32; |
| |
| (* Comparison, less-than or equal. *) |
| Vcle, [Flipped "vcge"], All (3, Dreg), "vcle", cmp_sign_matters, |
| F32 :: s_8_32; |
| Vcle, [Instruction_name ["vcge"]; Flipped "vcgeu"], |
| All (3, Dreg), "vcle", cmp_sign_matters, |
| u_8_32; |
| Vcle, [Instruction_name ["vcge"]; Flipped "vcgeQ"], |
| All (3, Qreg), "vcleQ", cmp_sign_matters, |
| F32 :: s_8_32; |
| Vcle, [Instruction_name ["vcge"]; Flipped "vcgeuQ"], |
| All (3, Qreg), "vcleQ", cmp_sign_matters, |
| u_8_32; |
| |
| (* Comparison, greater-than. *) |
| Vcgt, [], All (3, Dreg), "vcgt", cmp_sign_matters, F32 :: s_8_32; |
| Vcgt, [Instruction_name ["vcgt"]; Builtin_name "vcgtu"], |
| All (3, Dreg), "vcgt", cmp_sign_matters, |
| u_8_32; |
| Vcgt, [], All (3, Qreg), "vcgtQ", cmp_sign_matters, F32 :: s_8_32; |
| Vcgt, [Instruction_name ["vcgt"]; Builtin_name "vcgtu"], |
| All (3, Qreg), "vcgtQ", cmp_sign_matters, |
| u_8_32; |
| |
| (* Comparison, less-than. *) |
| Vclt, [Flipped "vcgt"], All (3, Dreg), "vclt", cmp_sign_matters, |
| F32 :: s_8_32; |
| Vclt, [Instruction_name ["vcgt"]; Flipped "vcgtu"], |
| All (3, Dreg), "vclt", cmp_sign_matters, |
| u_8_32; |
| Vclt, [Instruction_name ["vcgt"]; Flipped "vcgtQ"], |
| All (3, Qreg), "vcltQ", cmp_sign_matters, |
| F32 :: s_8_32; |
| Vclt, [Instruction_name ["vcgt"]; Flipped "vcgtuQ"], |
| All (3, Qreg), "vcltQ", cmp_sign_matters, |
| u_8_32; |
| |
| (* Compare absolute greater-than or equal. *) |
| Vcage, [Instruction_name ["vacge"]], |
| All (3, Dreg), "vcage", cmp_sign_matters, [F32]; |
| Vcage, [Instruction_name ["vacge"]], |
| All (3, Qreg), "vcageQ", cmp_sign_matters, [F32]; |
| |
| (* Compare absolute less-than or equal. *) |
| Vcale, [Instruction_name ["vacge"]; Flipped "vcage"], |
| All (3, Dreg), "vcale", cmp_sign_matters, [F32]; |
| Vcale, [Instruction_name ["vacge"]; Flipped "vcageQ"], |
| All (3, Qreg), "vcaleQ", cmp_sign_matters, [F32]; |
| |
| (* Compare absolute greater-than or equal. *) |
| Vcagt, [Instruction_name ["vacgt"]], |
| All (3, Dreg), "vcagt", cmp_sign_matters, [F32]; |
| Vcagt, [Instruction_name ["vacgt"]], |
| All (3, Qreg), "vcagtQ", cmp_sign_matters, [F32]; |
| |
| (* Compare absolute less-than or equal. *) |
| Vcalt, [Instruction_name ["vacgt"]; Flipped "vcagt"], |
| All (3, Dreg), "vcalt", cmp_sign_matters, [F32]; |
| Vcalt, [Instruction_name ["vacgt"]; Flipped "vcagtQ"], |
| All (3, Qreg), "vcaltQ", cmp_sign_matters, [F32]; |
| |
| (* Test bits. *) |
| Vtst, [], All (3, Dreg), "vtst", cmp_bits, P8 :: su_8_32; |
| Vtst, [], All (3, Qreg), "vtstQ", cmp_bits, P8 :: su_8_32; |
| |
| (* Absolute difference. *) |
| Vabd, [], All (3, Dreg), "vabd", elts_same_2, F32 :: su_8_32; |
| Vabd, [], All (3, Qreg), "vabdQ", elts_same_2, F32 :: su_8_32; |
| Vabd, [], Long, "vabdl", elts_same_2, su_8_32; |
| |
| (* Absolute difference and accumulate. *) |
| Vaba, [], All (3, Dreg), "vaba", elts_same_io, su_8_32; |
| Vaba, [], All (3, Qreg), "vabaQ", elts_same_io, su_8_32; |
| Vaba, [], Long, "vabal", elts_same_io, su_8_32; |
| |
| (* Max. *) |
| Vmax, [], All (3, Dreg), "vmax", elts_same_2, F32 :: su_8_32; |
| Vmax, [], All (3, Qreg), "vmaxQ", elts_same_2, F32 :: su_8_32; |
| |
| (* Min. *) |
| Vmin, [], All (3, Dreg), "vmin", elts_same_2, F32 :: su_8_32; |
| Vmin, [], All (3, Qreg), "vminQ", elts_same_2, F32 :: su_8_32; |
| |
| (* Pairwise add. *) |
| Vpadd, [], All (3, Dreg), "vpadd", sign_invar_2, F32 :: su_8_32; |
| Vpadd, [], Long_noreg Dreg, "vpaddl", elts_same_1, su_8_32; |
| Vpadd, [], Long_noreg Qreg, "vpaddlQ", elts_same_1, su_8_32; |
| |
| (* Pairwise add, widen and accumulate. *) |
| Vpada, [], Wide_noreg Dreg, "vpadal", elts_same_2, su_8_32; |
| Vpada, [], Wide_noreg Qreg, "vpadalQ", elts_same_2, su_8_32; |
| |
| (* Folding maximum, minimum. *) |
| Vpmax, [], All (3, Dreg), "vpmax", elts_same_2, F32 :: su_8_32; |
| Vpmin, [], All (3, Dreg), "vpmin", elts_same_2, F32 :: su_8_32; |
| |
| (* Reciprocal step. *) |
| Vrecps, [], All (3, Dreg), "vrecps", elts_same_2, [F32]; |
| Vrecps, [], All (3, Qreg), "vrecpsQ", elts_same_2, [F32]; |
| Vrsqrts, [], All (3, Dreg), "vrsqrts", elts_same_2, [F32]; |
| Vrsqrts, [], All (3, Qreg), "vrsqrtsQ", elts_same_2, [F32]; |
| |
| (* Vector shift left. *) |
| Vshl, [], All (3, Dreg), "vshl", reg_shift, su_8_64; |
| Vshl, [], All (3, Qreg), "vshlQ", reg_shift, su_8_64; |
| Vshl, [Instruction_name ["vrshl"]; Rounding], |
| All (3, Dreg), "vRshl", reg_shift, su_8_64; |
| Vshl, [Instruction_name ["vrshl"]; Rounding], |
| All (3, Qreg), "vRshlQ", reg_shift, su_8_64; |
| Vshl, [Saturating], All (3, Dreg), "vqshl", reg_shift, su_8_64; |
| Vshl, [Saturating], All (3, Qreg), "vqshlQ", reg_shift, su_8_64; |
| Vshl, [Instruction_name ["vqrshl"]; Saturating; Rounding], |
| All (3, Dreg), "vqRshl", reg_shift, su_8_64; |
| Vshl, [Instruction_name ["vqrshl"]; Saturating; Rounding], |
| All (3, Qreg), "vqRshlQ", reg_shift, su_8_64; |
| |
| (* Vector shift right by constant. *) |
| Vshr_n, [], Binary_imm Dreg, "vshr_n", shift_right, su_8_64; |
| Vshr_n, [], Binary_imm Qreg, "vshrQ_n", shift_right, su_8_64; |
| Vshr_n, [Instruction_name ["vrshr"]; Rounding], Binary_imm Dreg, |
| "vRshr_n", shift_right, su_8_64; |
| Vshr_n, [Instruction_name ["vrshr"]; Rounding], Binary_imm Qreg, |
| "vRshrQ_n", shift_right, su_8_64; |
| Vshr_n, [], Narrow_imm, "vshrn_n", shift_right_sign_invar, su_16_64; |
| Vshr_n, [Instruction_name ["vrshrn"]; Rounding], Narrow_imm, "vRshrn_n", |
| shift_right_sign_invar, su_16_64; |
| Vshr_n, [Saturating], Narrow_imm, "vqshrn_n", shift_right, su_16_64; |
| Vshr_n, [Instruction_name ["vqrshrn"]; Saturating; Rounding], Narrow_imm, |
| "vqRshrn_n", shift_right, su_16_64; |
| Vshr_n, [Saturating; Dst_unsign], Narrow_imm, "vqshrun_n", |
| shift_right_to_uns, [S16; S32; S64]; |
| Vshr_n, [Instruction_name ["vqrshrun"]; Saturating; Dst_unsign; Rounding], |
| Narrow_imm, "vqRshrun_n", shift_right_to_uns, [S16; S32; S64]; |
| |
| (* Vector shift left by constant. *) |
| Vshl_n, [], Binary_imm Dreg, "vshl_n", shift_left_sign_invar, su_8_64; |
| Vshl_n, [], Binary_imm Qreg, "vshlQ_n", shift_left_sign_invar, su_8_64; |
| Vshl_n, [Saturating], Binary_imm Dreg, "vqshl_n", shift_left, su_8_64; |
| Vshl_n, [Saturating], Binary_imm Qreg, "vqshlQ_n", shift_left, su_8_64; |
| Vshl_n, [Saturating; Dst_unsign], Binary_imm Dreg, "vqshlu_n", |
| shift_left_to_uns, [S8; S16; S32; S64]; |
| Vshl_n, [Saturating; Dst_unsign], Binary_imm Qreg, "vqshluQ_n", |
| shift_left_to_uns, [S8; S16; S32; S64]; |
| Vshl_n, [], Long_imm, "vshll_n", shift_left, su_8_32; |
| |
| (* Vector shift right by constant and accumulate. *) |
| Vsra_n, [], Binary_imm Dreg, "vsra_n", shift_right_acc, su_8_64; |
| Vsra_n, [], Binary_imm Qreg, "vsraQ_n", shift_right_acc, su_8_64; |
| Vsra_n, [Instruction_name ["vrsra"]; Rounding], Binary_imm Dreg, |
| "vRsra_n", shift_right_acc, su_8_64; |
| Vsra_n, [Instruction_name ["vrsra"]; Rounding], Binary_imm Qreg, |
| "vRsraQ_n", shift_right_acc, su_8_64; |
| |
| (* Vector shift right and insert. *) |
| Vsri, [Requires_feature "CRYPTO"], Use_operands [| Dreg; Dreg; Immed |], "vsri_n", shift_insert, |
| [P64]; |
| Vsri, [], Use_operands [| Dreg; Dreg; Immed |], "vsri_n", shift_insert, |
| P8 :: P16 :: su_8_64; |
| Vsri, [Requires_feature "CRYPTO"], Use_operands [| Qreg; Qreg; Immed |], "vsriQ_n", shift_insert, |
| [P64]; |
| Vsri, [], Use_operands [| Qreg; Qreg; Immed |], "vsriQ_n", shift_insert, |
| P8 :: P16 :: su_8_64; |
| |
| (* Vector shift left and insert. *) |
| Vsli, [Requires_feature "CRYPTO"], Use_operands [| Dreg; Dreg; Immed |], "vsli_n", shift_insert, |
| [P64]; |
| Vsli, [], Use_operands [| Dreg; Dreg; Immed |], "vsli_n", shift_insert, |
| P8 :: P16 :: su_8_64; |
| Vsli, [Requires_feature "CRYPTO"], Use_operands [| Qreg; Qreg; Immed |], "vsliQ_n", shift_insert, |
| [P64]; |
| Vsli, [], Use_operands [| Qreg; Qreg; Immed |], "vsliQ_n", shift_insert, |
| P8 :: P16 :: su_8_64; |
| |
| (* Absolute value. *) |
| Vabs, [], All (2, Dreg), "vabs", elts_same_1, [S8; S16; S32; F32]; |
| Vabs, [], All (2, Qreg), "vabsQ", elts_same_1, [S8; S16; S32; F32]; |
| Vabs, [Saturating], All (2, Dreg), "vqabs", elts_same_1, [S8; S16; S32]; |
| Vabs, [Saturating], All (2, Qreg), "vqabsQ", elts_same_1, [S8; S16; S32]; |
| |
| (* Negate. *) |
| Vneg, [], All (2, Dreg), "vneg", elts_same_1, [S8; S16; S32; F32]; |
| Vneg, [], All (2, Qreg), "vnegQ", elts_same_1, [S8; S16; S32; F32]; |
| Vneg, [Saturating], All (2, Dreg), "vqneg", elts_same_1, [S8; S16; S32]; |
| Vneg, [Saturating], All (2, Qreg), "vqnegQ", elts_same_1, [S8; S16; S32]; |
| |
| (* Bitwise not. *) |
| Vmvn, [], All (2, Dreg), "vmvn", notype_1, P8 :: su_8_32; |
| Vmvn, [], All (2, Qreg), "vmvnQ", notype_1, P8 :: su_8_32; |
| |
| (* Count leading sign bits. *) |
| Vcls, [], All (2, Dreg), "vcls", elts_same_1, [S8; S16; S32]; |
| Vcls, [], All (2, Qreg), "vclsQ", elts_same_1, [S8; S16; S32]; |
| |
| (* Count leading zeros. *) |
| Vclz, [], All (2, Dreg), "vclz", sign_invar_1, su_8_32; |
| Vclz, [], All (2, Qreg), "vclzQ", sign_invar_1, su_8_32; |
| |
| (* Count number of set bits. *) |
| Vcnt, [], All (2, Dreg), "vcnt", bits_1, [P8; S8; U8]; |
| Vcnt, [], All (2, Qreg), "vcntQ", bits_1, [P8; S8; U8]; |
| |
| (* Reciprocal estimate. *) |
| Vrecpe, [], All (2, Dreg), "vrecpe", elts_same_1, [U32; F32]; |
| Vrecpe, [], All (2, Qreg), "vrecpeQ", elts_same_1, [U32; F32]; |
| |
| (* Reciprocal square-root estimate. *) |
| Vrsqrte, [], All (2, Dreg), "vrsqrte", elts_same_1, [U32; F32]; |
| Vrsqrte, [], All (2, Qreg), "vrsqrteQ", elts_same_1, [U32; F32]; |
| |
| (* Get lanes from a vector. *) |
| Vget_lane, |
| [InfoWord; Disassembles_as [Use_operands [| Corereg; Element_of_dreg |]]; |
| Instruction_name ["vmov"]], |
| Use_operands [| Corereg; Dreg; Immed |], |
| "vget_lane", get_lane, pf_su_8_32; |
| Vget_lane, |
| [No_op; |
| InfoWord; |
| Disassembles_as [Use_operands [| Corereg; Corereg; Dreg |]]; |
| Instruction_name ["vmov"]; Const_valuator (fun _ -> 0)], |
| Use_operands [| Corereg; Dreg; Immed |], |
| "vget_lane", notype_2, [S64; U64]; |
| Vget_lane, |
| [InfoWord; Disassembles_as [Use_operands [| Corereg; Element_of_dreg |]]; |
| Instruction_name ["vmov"]], |
| Use_operands [| Corereg; Qreg; Immed |], |
| "vgetQ_lane", get_lane, pf_su_8_32; |
| Vget_lane, |
| [InfoWord; |
| Disassembles_as [Use_operands [| Corereg; Corereg; Dreg |]]; |
| Instruction_name ["vmov"; "fmrrd"]; Const_valuator (fun _ -> 0); |
| Fixed_core_reg], |
| Use_operands [| Corereg; Qreg; Immed |], |
| "vgetQ_lane", notype_2, [S64; U64]; |
| |
| (* Set lanes in a vector. *) |
| Vset_lane, [Disassembles_as [Use_operands [| Element_of_dreg; Corereg |]]; |
| Instruction_name ["vmov"]], |
| Use_operands [| Dreg; Corereg; Dreg; Immed |], "vset_lane", |
| set_lane, pf_su_8_32; |
| Vset_lane, [No_op; |
| Disassembles_as [Use_operands [| Dreg; Corereg; Corereg |]]; |
| Instruction_name ["vmov"]; Const_valuator (fun _ -> 0)], |
| Use_operands [| Dreg; Corereg; Dreg; Immed |], "vset_lane", |
| set_lane_notype, [S64; U64]; |
| Vset_lane, [Disassembles_as [Use_operands [| Element_of_dreg; Corereg |]]; |
| Instruction_name ["vmov"]], |
| Use_operands [| Qreg; Corereg; Qreg; Immed |], "vsetQ_lane", |
| set_lane, pf_su_8_32; |
| Vset_lane, [Disassembles_as [Use_operands [| Dreg; Corereg; Corereg |]]; |
| Instruction_name ["vmov"]; Const_valuator (fun _ -> 0)], |
| Use_operands [| Qreg; Corereg; Qreg; Immed |], "vsetQ_lane", |
| set_lane_notype, [S64; U64]; |
| |
| (* Create vector from literal bit pattern. *) |
| Vcreate, |
| [Requires_feature "CRYPTO"; No_op], (* Not really, but it can yield various things that are too |
| hard for the test generator at this time. *) |
| Use_operands [| Dreg; Corereg |], "vcreate", create_vector, |
| [P64]; |
| Vcreate, |
| [No_op], (* Not really, but it can yield various things that are too |
| hard for the test generator at this time. *) |
| Use_operands [| Dreg; Corereg |], "vcreate", create_vector, |
| pf_su_8_64; |
| |
| (* Set all lanes to the same value. *) |
| Vdup_n, |
| [Disassembles_as [Use_operands [| Dreg; |
| Alternatives [ Corereg; |
| Element_of_dreg ] |]]], |
| Use_operands [| Dreg; Corereg |], "vdup_n", bits_1, |
| pf_su_8_32; |
| Vdup_n, |
| [No_op; Requires_feature "CRYPTO"; |
| Instruction_name ["vmov"]; |
| Disassembles_as [Use_operands [| Dreg; Corereg; Corereg |]]], |
| Use_operands [| Dreg; Corereg |], "vdup_n", notype_1, |
| [P64]; |
| Vdup_n, |
| [No_op; |
| Instruction_name ["vmov"]; |
| Disassembles_as [Use_operands [| Dreg; Corereg; Corereg |]]], |
| Use_operands [| Dreg; Corereg |], "vdup_n", notype_1, |
| [S64; U64]; |
| Vdup_n, |
| [No_op; Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| Qreg; |
| Alternatives [ Corereg; |
| Element_of_dreg ] |]]], |
| Use_operands [| Qreg; Corereg |], "vdupQ_n", bits_1, |
| [P64]; |
| Vdup_n, |
| [Disassembles_as [Use_operands [| Qreg; |
| Alternatives [ Corereg; |
| Element_of_dreg ] |]]], |
| Use_operands [| Qreg; Corereg |], "vdupQ_n", bits_1, |
| pf_su_8_32; |
| Vdup_n, |
| [No_op; |
| Instruction_name ["vmov"]; |
| Disassembles_as [Use_operands [| Dreg; Corereg; Corereg |]; |
| Use_operands [| Dreg; Corereg; Corereg |]]], |
| Use_operands [| Qreg; Corereg |], "vdupQ_n", notype_1, |
| [S64; U64]; |
| |
| (* These are just aliases for the above. *) |
| Vmov_n, |
| [Builtin_name "vdup_n"; |
| Disassembles_as [Use_operands [| Dreg; |
| Alternatives [ Corereg; |
| Element_of_dreg ] |]]], |
| Use_operands [| Dreg; Corereg |], |
| "vmov_n", bits_1, pf_su_8_32; |
| Vmov_n, |
| [No_op; |
| Builtin_name "vdup_n"; |
| Instruction_name ["vmov"]; |
| Disassembles_as [Use_operands [| Dreg; Corereg; Corereg |]]], |
| Use_operands [| Dreg; Corereg |], |
| "vmov_n", notype_1, [S64; U64]; |
| Vmov_n, |
| [Builtin_name "vdupQ_n"; |
| Disassembles_as [Use_operands [| Qreg; |
| Alternatives [ Corereg; |
| Element_of_dreg ] |]]], |
| Use_operands [| Qreg; Corereg |], |
| "vmovQ_n", bits_1, pf_su_8_32; |
| Vmov_n, |
| [No_op; |
| Builtin_name "vdupQ_n"; |
| Instruction_name ["vmov"]; |
| Disassembles_as [Use_operands [| Dreg; Corereg; Corereg |]; |
| Use_operands [| Dreg; Corereg; Corereg |]]], |
| Use_operands [| Qreg; Corereg |], |
| "vmovQ_n", notype_1, [S64; U64]; |
| |
| (* Duplicate, lane version. We can't use Use_operands here because the |
| rightmost register (always Dreg) would be picked up by find_key_operand, |
| when we want the leftmost register to be used in this case (otherwise |
| the modes are indistinguishable in neon.md, etc. *) |
| Vdup_lane, |
| [Disassembles_as [Use_operands [| Dreg; Element_of_dreg |]]], |
| Unary_scalar Dreg, "vdup_lane", bits_2, pf_su_8_32; |
| Vdup_lane, |
| [No_op; Requires_feature "CRYPTO"; Const_valuator (fun _ -> 0)], |
| Unary_scalar Dreg, "vdup_lane", bits_2, [P64]; |
| Vdup_lane, |
| [No_op; Const_valuator (fun _ -> 0)], |
| Unary_scalar Dreg, "vdup_lane", bits_2, [S64; U64]; |
| Vdup_lane, |
| [Disassembles_as [Use_operands [| Qreg; Element_of_dreg |]]], |
| Unary_scalar Qreg, "vdupQ_lane", bits_2, pf_su_8_32; |
| Vdup_lane, |
| [No_op; Requires_feature "CRYPTO"; Const_valuator (fun _ -> 0)], |
| Unary_scalar Qreg, "vdupQ_lane", bits_2, [P64]; |
| Vdup_lane, |
| [No_op; Const_valuator (fun _ -> 0)], |
| Unary_scalar Qreg, "vdupQ_lane", bits_2, [S64; U64]; |
| |
| (* Combining vectors. *) |
| Vcombine, [Requires_feature "CRYPTO"; No_op], |
| Use_operands [| Qreg; Dreg; Dreg |], "vcombine", notype_2, |
| [P64]; |
| Vcombine, [No_op], |
| Use_operands [| Qreg; Dreg; Dreg |], "vcombine", notype_2, |
| pf_su_8_64; |
| |
| (* Splitting vectors. *) |
| Vget_high, [Requires_feature "CRYPTO"; No_op], |
| Use_operands [| Dreg; Qreg |], "vget_high", |
| notype_1, [P64]; |
| Vget_high, [No_op], |
| Use_operands [| Dreg; Qreg |], "vget_high", |
| notype_1, pf_su_8_64; |
| Vget_low, [Instruction_name ["vmov"]; |
| Disassembles_as [Use_operands [| Dreg; Dreg |]]; |
| Fixed_vector_reg], |
| Use_operands [| Dreg; Qreg |], "vget_low", |
| notype_1, pf_su_8_32; |
| Vget_low, [Requires_feature "CRYPTO"; No_op], |
| Use_operands [| Dreg; Qreg |], "vget_low", |
| notype_1, [P64]; |
| Vget_low, [No_op], |
| Use_operands [| Dreg; Qreg |], "vget_low", |
| notype_1, [S64; U64]; |
| |
| (* Conversions. *) |
| Vcvt, [InfoWord], All (2, Dreg), "vcvt", conv_1, |
| [Conv (S32, F32); Conv (U32, F32); Conv (F32, S32); Conv (F32, U32)]; |
| Vcvt, [InfoWord], All (2, Qreg), "vcvtQ", conv_1, |
| [Conv (S32, F32); Conv (U32, F32); Conv (F32, S32); Conv (F32, U32)]; |
| Vcvt, [Builtin_name "vcvt" ; Requires_FP_bit 1], |
| Use_operands [| Dreg; Qreg; |], "vcvt", conv_1, [Conv (F16, F32)]; |
| Vcvt, [Builtin_name "vcvt" ; Requires_FP_bit 1], |
| Use_operands [| Qreg; Dreg; |], "vcvt", conv_1, [Conv (F32, F16)]; |
| Vcvt_n, [InfoWord], Use_operands [| Dreg; Dreg; Immed |], "vcvt_n", conv_2, |
| [Conv (S32, F32); Conv (U32, F32); Conv (F32, S32); Conv (F32, U32)]; |
| Vcvt_n, [InfoWord], Use_operands [| Qreg; Qreg; Immed |], "vcvtQ_n", conv_2, |
| [Conv (S32, F32); Conv (U32, F32); Conv (F32, S32); Conv (F32, U32)]; |
| |
| (* Move, narrowing. *) |
| Vmovn, [Disassembles_as [Use_operands [| Dreg; Qreg |]]], |
| Narrow, "vmovn", sign_invar_1, su_16_64; |
| Vmovn, [Disassembles_as [Use_operands [| Dreg; Qreg |]]; Saturating], |
| Narrow, "vqmovn", elts_same_1, su_16_64; |
| Vmovn, |
| [Disassembles_as [Use_operands [| Dreg; Qreg |]]; Saturating; Dst_unsign], |
| Narrow, "vqmovun", dst_unsign_1, |
| [S16; S32; S64]; |
| |
| (* Move, long. *) |
| Vmovl, [Disassembles_as [Use_operands [| Qreg; Dreg |]]], |
| Long, "vmovl", elts_same_1, su_8_32; |
| |
| (* Table lookup. *) |
| Vtbl 1, |
| [Instruction_name ["vtbl"]; |
| Disassembles_as [Use_operands [| Dreg; VecArray (1, Dreg); Dreg |]]], |
| Use_operands [| Dreg; Dreg; Dreg |], "vtbl1", table_2, [U8; S8; P8]; |
| Vtbl 2, [Instruction_name ["vtbl"]], |
| Use_operands [| Dreg; VecArray (2, Dreg); Dreg |], "vtbl2", table_2, |
| [U8; S8; P8]; |
| Vtbl 3, [Instruction_name ["vtbl"]], |
| Use_operands [| Dreg; VecArray (3, Dreg); Dreg |], "vtbl3", table_2, |
| [U8; S8; P8]; |
| Vtbl 4, [Instruction_name ["vtbl"]], |
| Use_operands [| Dreg; VecArray (4, Dreg); Dreg |], "vtbl4", table_2, |
| [U8; S8; P8]; |
| |
| (* Extended table lookup. *) |
| Vtbx 1, |
| [Instruction_name ["vtbx"]; |
| Disassembles_as [Use_operands [| Dreg; VecArray (1, Dreg); Dreg |]]], |
| Use_operands [| Dreg; Dreg; Dreg |], "vtbx1", table_io, [U8; S8; P8]; |
| Vtbx 2, [Instruction_name ["vtbx"]], |
| Use_operands [| Dreg; VecArray (2, Dreg); Dreg |], "vtbx2", table_io, |
| [U8; S8; P8]; |
| Vtbx 3, [Instruction_name ["vtbx"]], |
| Use_operands [| Dreg; VecArray (3, Dreg); Dreg |], "vtbx3", table_io, |
| [U8; S8; P8]; |
| Vtbx 4, [Instruction_name ["vtbx"]], |
| Use_operands [| Dreg; VecArray (4, Dreg); Dreg |], "vtbx4", table_io, |
| [U8; S8; P8]; |
| |
| (* Multiply, lane. (note: these were undocumented at the time of |
| writing). *) |
| Vmul_lane, [], By_scalar Dreg, "vmul_lane", sign_invar_2_lane, |
| [S16; S32; U16; U32; F32]; |
| Vmul_lane, [], By_scalar Qreg, "vmulQ_lane", sign_invar_2_lane, |
| [S16; S32; U16; U32; F32]; |
| |
| (* Multiply-accumulate, lane. *) |
| Vmla_lane, [], By_scalar Dreg, "vmla_lane", sign_invar_io_lane, |
| [S16; S32; U16; U32; F32]; |
| Vmla_lane, [], By_scalar Qreg, "vmlaQ_lane", sign_invar_io_lane, |
| [S16; S32; U16; U32; F32]; |
| Vmla_lane, [], Wide_lane, "vmlal_lane", elts_same_io_lane, |
| [S16; S32; U16; U32]; |
| Vmla_lane, [Saturating; Doubling], Wide_lane, "vqdmlal_lane", |
| elts_same_io_lane, [S16; S32]; |
| |
| (* Multiply-subtract, lane. *) |
| Vmls_lane, [], By_scalar Dreg, "vmls_lane", sign_invar_io_lane, |
| [S16; S32; U16; U32; F32]; |
| Vmls_lane, [], By_scalar Qreg, "vmlsQ_lane", sign_invar_io_lane, |
| [S16; S32; U16; U32; F32]; |
| Vmls_lane, [], Wide_lane, "vmlsl_lane", elts_same_io_lane, |
| [S16; S32; U16; U32]; |
| Vmls_lane, [Saturating; Doubling], Wide_lane, "vqdmlsl_lane", |
| elts_same_io_lane, [S16; S32]; |
| |
| (* Long multiply, lane. *) |
| Vmull_lane, [], |
| Wide_lane, "vmull_lane", elts_same_2_lane, [S16; S32; U16; U32]; |
| |
| (* Saturating doubling long multiply, lane. *) |
| Vqdmull_lane, [Saturating; Doubling], |
| Wide_lane, "vqdmull_lane", elts_same_2_lane, [S16; S32]; |
| |
| (* Saturating doubling long multiply high, lane. *) |
| Vqdmulh_lane, [Saturating; Halving], |
| By_scalar Qreg, "vqdmulhQ_lane", elts_same_2_lane, [S16; S32]; |
| Vqdmulh_lane, [Saturating; Halving], |
| By_scalar Dreg, "vqdmulh_lane", elts_same_2_lane, [S16; S32]; |
| Vqdmulh_lane, [Saturating; Halving; Rounding; |
| Instruction_name ["vqrdmulh"]], |
| By_scalar Qreg, "vqRdmulhQ_lane", elts_same_2_lane, [S16; S32]; |
| Vqdmulh_lane, [Saturating; Halving; Rounding; |
| Instruction_name ["vqrdmulh"]], |
| By_scalar Dreg, "vqRdmulh_lane", elts_same_2_lane, [S16; S32]; |
| |
| (* Vector multiply by scalar. *) |
| Vmul_n, [InfoWord; |
| Disassembles_as [Use_operands [| Dreg; Dreg; Element_of_dreg |]]], |
| Use_operands [| Dreg; Dreg; Corereg |], "vmul_n", |
| sign_invar_2, [S16; S32; U16; U32; F32]; |
| Vmul_n, [InfoWord; |
| Disassembles_as [Use_operands [| Qreg; Qreg; Element_of_dreg |]]], |
| Use_operands [| Qreg; Qreg; Corereg |], "vmulQ_n", |
| sign_invar_2, [S16; S32; U16; U32; F32]; |
| |
| (* Vector long multiply by scalar. *) |
| Vmull_n, [Instruction_name ["vmull"]; |
| Disassembles_as [Use_operands [| Qreg; Dreg; Element_of_dreg |]]], |
| Wide_scalar, "vmull_n", |
| elts_same_2, [S16; S32; U16; U32]; |
| |
| (* Vector saturating doubling long multiply by scalar. *) |
| Vqdmull_n, [Saturating; Doubling; |
| Disassembles_as [Use_operands [| Qreg; Dreg; |
| Element_of_dreg |]]], |
| Wide_scalar, "vqdmull_n", |
| elts_same_2, [S16; S32]; |
| |
| (* Vector saturating doubling long multiply high by scalar. *) |
| Vqdmulh_n, |
| [Saturating; Halving; InfoWord; |
| Disassembles_as [Use_operands [| Qreg; Qreg; Element_of_dreg |]]], |
| Use_operands [| Qreg; Qreg; Corereg |], |
| "vqdmulhQ_n", elts_same_2, [S16; S32]; |
| Vqdmulh_n, |
| [Saturating; Halving; InfoWord; |
| Disassembles_as [Use_operands [| Dreg; Dreg; Element_of_dreg |]]], |
| Use_operands [| Dreg; Dreg; Corereg |], |
| "vqdmulh_n", elts_same_2, [S16; S32]; |
| Vqdmulh_n, |
| [Saturating; Halving; Rounding; InfoWord; |
| Instruction_name ["vqrdmulh"]; |
| Disassembles_as [Use_operands [| Qreg; Qreg; Element_of_dreg |]]], |
| Use_operands [| Qreg; Qreg; Corereg |], |
| "vqRdmulhQ_n", elts_same_2, [S16; S32]; |
| Vqdmulh_n, |
| [Saturating; Halving; Rounding; InfoWord; |
| Instruction_name ["vqrdmulh"]; |
| Disassembles_as [Use_operands [| Dreg; Dreg; Element_of_dreg |]]], |
| Use_operands [| Dreg; Dreg; Corereg |], |
| "vqRdmulh_n", elts_same_2, [S16; S32]; |
| |
| (* Vector multiply-accumulate by scalar. *) |
| Vmla_n, [InfoWord; |
| Disassembles_as [Use_operands [| Dreg; Dreg; Element_of_dreg |]]], |
| Use_operands [| Dreg; Dreg; Corereg |], "vmla_n", |
| sign_invar_io, [S16; S32; U16; U32; F32]; |
| Vmla_n, [InfoWord; |
| Disassembles_as [Use_operands [| Qreg; Qreg; Element_of_dreg |]]], |
| Use_operands [| Qreg; Qreg; Corereg |], "vmlaQ_n", |
| sign_invar_io, [S16; S32; U16; U32; F32]; |
| Vmla_n, [], Wide_scalar, "vmlal_n", elts_same_io, [S16; S32; U16; U32]; |
| Vmla_n, [Saturating; Doubling], Wide_scalar, "vqdmlal_n", elts_same_io, |
| [S16; S32]; |
| |
| (* Vector multiply subtract by scalar. *) |
| Vmls_n, [InfoWord; |
| Disassembles_as [Use_operands [| Dreg; Dreg; Element_of_dreg |]]], |
| Use_operands [| Dreg; Dreg; Corereg |], "vmls_n", |
| sign_invar_io, [S16; S32; U16; U32; F32]; |
| Vmls_n, [InfoWord; |
| Disassembles_as [Use_operands [| Qreg; Qreg; Element_of_dreg |]]], |
| Use_operands [| Qreg; Qreg; Corereg |], "vmlsQ_n", |
| sign_invar_io, [S16; S32; U16; U32; F32]; |
| Vmls_n, [], Wide_scalar, "vmlsl_n", elts_same_io, [S16; S32; U16; U32]; |
| Vmls_n, [Saturating; Doubling], Wide_scalar, "vqdmlsl_n", elts_same_io, |
| [S16; S32]; |
| |
| (* Vector extract. *) |
| Vext, [Requires_feature "CRYPTO"; Const_valuator (fun _ -> 0)], |
| Use_operands [| Dreg; Dreg; Dreg; Immed |], "vext", extend, |
| [P64]; |
| Vext, [Const_valuator (fun _ -> 0)], |
| Use_operands [| Dreg; Dreg; Dreg; Immed |], "vext", extend, |
| pf_su_8_64; |
| Vext, [Requires_feature "CRYPTO"; Const_valuator (fun _ -> 0)], |
| Use_operands [| Qreg; Qreg; Qreg; Immed |], "vextQ", extend, |
| [P64]; |
| Vext, [Const_valuator (fun _ -> 0)], |
| Use_operands [| Qreg; Qreg; Qreg; Immed |], "vextQ", extend, |
| pf_su_8_64; |
| |
| (* Reverse elements. *) |
| Vrev64, [Use_shuffle (rev_elems 64)], All (2, Dreg), "vrev64", bits_1, |
| P8 :: P16 :: F32 :: su_8_32; |
| Vrev64, [Use_shuffle (rev_elems 64)], All (2, Qreg), "vrev64Q", bits_1, |
| P8 :: P16 :: F32 :: su_8_32; |
| Vrev32, [Use_shuffle (rev_elems 32)], All (2, Dreg), "vrev32", bits_1, |
| [P8; P16; S8; U8; S16; U16]; |
| Vrev32, [Use_shuffle (rev_elems 32)], All (2, Qreg), "vrev32Q", bits_1, |
| [P8; P16; S8; U8; S16; U16]; |
| Vrev16, [Use_shuffle (rev_elems 16)], All (2, Dreg), "vrev16", bits_1, |
| [P8; S8; U8]; |
| Vrev16, [Use_shuffle (rev_elems 16)], All (2, Qreg), "vrev16Q", bits_1, |
| [P8; S8; U8]; |
| |
| (* Bit selection. *) |
| Vbsl, |
| [Requires_feature "CRYPTO"; Instruction_name ["vbsl"; "vbit"; "vbif"]; |
| Disassembles_as [Use_operands [| Dreg; Dreg; Dreg |]]], |
| Use_operands [| Dreg; Dreg; Dreg; Dreg |], "vbsl", bit_select, |
| [P64]; |
| Vbsl, |
| [Instruction_name ["vbsl"; "vbit"; "vbif"]; |
| Disassembles_as [Use_operands [| Dreg; Dreg; Dreg |]]], |
| Use_operands [| Dreg; Dreg; Dreg; Dreg |], "vbsl", bit_select, |
| pf_su_8_64; |
| Vbsl, |
| [Requires_feature "CRYPTO"; Instruction_name ["vbsl"; "vbit"; "vbif"]; |
| Disassembles_as [Use_operands [| Qreg; Qreg; Qreg |]]], |
| Use_operands [| Qreg; Qreg; Qreg; Qreg |], "vbslQ", bit_select, |
| [P64]; |
| Vbsl, |
| [Instruction_name ["vbsl"; "vbit"; "vbif"]; |
| Disassembles_as [Use_operands [| Qreg; Qreg; Qreg |]]], |
| Use_operands [| Qreg; Qreg; Qreg; Qreg |], "vbslQ", bit_select, |
| pf_su_8_64; |
| |
| Vtrn, [Use_shuffle trn_elems], Pair_result Dreg, "vtrn", bits_2, pf_su_8_16; |
| Vtrn, [Use_shuffle trn_elems; Instruction_name ["vuzp"]], Pair_result Dreg, "vtrn", bits_2, suf_32; |
| Vtrn, [Use_shuffle trn_elems], Pair_result Qreg, "vtrnQ", bits_2, pf_su_8_32; |
| (* Zip elements. *) |
| Vzip, [Use_shuffle zip_elems], Pair_result Dreg, "vzip", bits_2, pf_su_8_16; |
| Vzip, [Use_shuffle zip_elems; Instruction_name ["vuzp"]], Pair_result Dreg, "vzip", bits_2, suf_32; |
| Vzip, [Use_shuffle zip_elems], Pair_result Qreg, "vzipQ", bits_2, pf_su_8_32; |
| |
| (* Unzip elements. *) |
| Vuzp, [Use_shuffle uzip_elems], Pair_result Dreg, "vuzp", bits_2, |
| pf_su_8_32; |
| Vuzp, [Use_shuffle uzip_elems], Pair_result Qreg, "vuzpQ", bits_2, |
| pf_su_8_32; |
| |
| (* Element/structure loads. VLD1 variants. *) |
| Vldx 1, |
| [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Dreg; CstPtrTo Corereg |], "vld1", bits_1, |
| [P64]; |
| Vldx 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Dreg; CstPtrTo Corereg |], "vld1", bits_1, |
| pf_su_8_64; |
| Vldx 1, [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg |], "vld1Q", bits_1, |
| [P64]; |
| Vldx 1, [Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg |], "vld1Q", bits_1, |
| pf_su_8_64; |
| |
| Vldx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Dreg; CstPtrTo Corereg; Dreg; Immed |], |
| "vld1_lane", bits_3, pf_su_8_32; |
| Vldx_lane 1, |
| [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]; |
| Const_valuator (fun _ -> 0)], |
| Use_operands [| Dreg; CstPtrTo Corereg; Dreg; Immed |], |
| "vld1_lane", bits_3, [P64]; |
| Vldx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]; |
| Const_valuator (fun _ -> 0)], |
| Use_operands [| Dreg; CstPtrTo Corereg; Dreg; Immed |], |
| "vld1_lane", bits_3, [S64; U64]; |
| Vldx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg; Qreg; Immed |], |
| "vld1Q_lane", bits_3, pf_su_8_32; |
| Vldx_lane 1, |
| [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg; Qreg; Immed |], |
| "vld1Q_lane", bits_3, [P64]; |
| Vldx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg; Qreg; Immed |], |
| "vld1Q_lane", bits_3, [S64; U64]; |
| |
| Vldx_dup 1, |
| [Disassembles_as [Use_operands [| VecArray (1, All_elements_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Dreg; CstPtrTo Corereg |], "vld1_dup", |
| bits_1, pf_su_8_32; |
| Vldx_dup 1, |
| [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Dreg; CstPtrTo Corereg |], "vld1_dup", |
| bits_1, [P64]; |
| Vldx_dup 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Dreg; CstPtrTo Corereg |], "vld1_dup", |
| bits_1, [S64; U64]; |
| Vldx_dup 1, |
| [Disassembles_as [Use_operands [| VecArray (2, All_elements_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg |], "vld1Q_dup", |
| bits_1, pf_su_8_32; |
| (* Treated identically to vld1_dup above as we now |
| do a single load followed by a duplicate. *) |
| Vldx_dup 1, |
| [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg |], "vld1Q_dup", |
| bits_1, [P64]; |
| Vldx_dup 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| Qreg; CstPtrTo Corereg |], "vld1Q_dup", |
| bits_1, [S64; U64]; |
| |
| (* VST1 variants. *) |
| Vstx 1, [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Dreg |], "vst1", |
| store_1, [P64]; |
| Vstx 1, [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Dreg |], "vst1", |
| store_1, pf_su_8_64; |
| Vstx 1, [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Qreg |], "vst1Q", |
| store_1, [P64]; |
| Vstx 1, [Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Qreg |], "vst1Q", |
| store_1, pf_su_8_64; |
| |
| Vstx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Dreg; Immed |], |
| "vst1_lane", store_3, pf_su_8_32; |
| Vstx_lane 1, |
| [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]; |
| Const_valuator (fun _ -> 0)], |
| Use_operands [| PtrTo Corereg; Dreg; Immed |], |
| "vst1_lane", store_3, [P64]; |
| Vstx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]; |
| Const_valuator (fun _ -> 0)], |
| Use_operands [| PtrTo Corereg; Dreg; Immed |], |
| "vst1_lane", store_3, [U64; S64]; |
| Vstx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Qreg; Immed |], |
| "vst1Q_lane", store_3, pf_su_8_32; |
| Vstx_lane 1, |
| [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Qreg; Immed |], |
| "vst1Q_lane", store_3, [P64]; |
| Vstx_lane 1, |
| [Disassembles_as [Use_operands [| VecArray (1, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; Qreg; Immed |], |
| "vst1Q_lane", store_3, [U64; S64]; |
| |
| (* VLD2 variants. *) |
| Vldx 2, [], Use_operands [| VecArray (2, Dreg); CstPtrTo Corereg |], |
| "vld2", bits_1, pf_su_8_32; |
| Vldx 2, [Requires_feature "CRYPTO"; Instruction_name ["vld1"]], |
| Use_operands [| VecArray (2, Dreg); CstPtrTo Corereg |], |
| "vld2", bits_1, [P64]; |
| Vldx 2, [Instruction_name ["vld1"]], |
| Use_operands [| VecArray (2, Dreg); CstPtrTo Corereg |], |
| "vld2", bits_1, [S64; U64]; |
| Vldx 2, [Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| CstPtrTo Corereg |]; |
| Use_operands [| VecArray (2, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (2, Qreg); CstPtrTo Corereg |], |
| "vld2Q", bits_1, pf_su_8_32; |
| |
| Vldx_lane 2, |
| [Disassembles_as [Use_operands |
| [| VecArray (2, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (2, Dreg); CstPtrTo Corereg; |
| VecArray (2, Dreg); Immed |], |
| "vld2_lane", bits_3, P8 :: P16 :: F32 :: su_8_32; |
| Vldx_lane 2, |
| [Disassembles_as [Use_operands |
| [| VecArray (2, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (2, Qreg); CstPtrTo Corereg; |
| VecArray (2, Qreg); Immed |], |
| "vld2Q_lane", bits_3, [P16; F32; U16; U32; S16; S32]; |
| |
| Vldx_dup 2, |
| [Disassembles_as [Use_operands |
| [| VecArray (2, All_elements_of_dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (2, Dreg); CstPtrTo Corereg |], |
| "vld2_dup", bits_1, pf_su_8_32; |
| Vldx_dup 2, |
| [Requires_feature "CRYPTO"; |
| Instruction_name ["vld1"]; Disassembles_as [Use_operands |
| [| VecArray (2, Dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (2, Dreg); CstPtrTo Corereg |], |
| "vld2_dup", bits_1, [P64]; |
| Vldx_dup 2, |
| [Instruction_name ["vld1"]; Disassembles_as [Use_operands |
| [| VecArray (2, Dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (2, Dreg); CstPtrTo Corereg |], |
| "vld2_dup", bits_1, [S64; U64]; |
| |
| (* VST2 variants. *) |
| Vstx 2, [Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (2, Dreg) |], "vst2", |
| store_1, pf_su_8_32; |
| Vstx 2, [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| PtrTo Corereg |]]; |
| Instruction_name ["vst1"]], |
| Use_operands [| PtrTo Corereg; VecArray (2, Dreg) |], "vst2", |
| store_1, [P64]; |
| Vstx 2, [Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| PtrTo Corereg |]]; |
| Instruction_name ["vst1"]], |
| Use_operands [| PtrTo Corereg; VecArray (2, Dreg) |], "vst2", |
| store_1, [S64; U64]; |
| Vstx 2, [Disassembles_as [Use_operands [| VecArray (2, Dreg); |
| PtrTo Corereg |]; |
| Use_operands [| VecArray (2, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (2, Qreg) |], "vst2Q", |
| store_1, pf_su_8_32; |
| |
| Vstx_lane 2, |
| [Disassembles_as [Use_operands |
| [| VecArray (2, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (2, Dreg); Immed |], "vst2_lane", |
| store_3, P8 :: P16 :: F32 :: su_8_32; |
| Vstx_lane 2, |
| [Disassembles_as [Use_operands |
| [| VecArray (2, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (2, Qreg); Immed |], "vst2Q_lane", |
| store_3, [P16; F32; U16; U32; S16; S32]; |
| |
| (* VLD3 variants. *) |
| Vldx 3, [], Use_operands [| VecArray (3, Dreg); CstPtrTo Corereg |], |
| "vld3", bits_1, pf_su_8_32; |
| Vldx 3, [Requires_feature "CRYPTO"; Instruction_name ["vld1"]], |
| Use_operands [| VecArray (3, Dreg); CstPtrTo Corereg |], |
| "vld3", bits_1, [P64]; |
| Vldx 3, [Instruction_name ["vld1"]], |
| Use_operands [| VecArray (3, Dreg); CstPtrTo Corereg |], |
| "vld3", bits_1, [S64; U64]; |
| Vldx 3, [Disassembles_as [Use_operands [| VecArray (3, Dreg); |
| CstPtrTo Corereg |]; |
| Use_operands [| VecArray (3, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (3, Qreg); CstPtrTo Corereg |], |
| "vld3Q", bits_1, P8 :: P16 :: F32 :: su_8_32; |
| |
| Vldx_lane 3, |
| [Disassembles_as [Use_operands |
| [| VecArray (3, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (3, Dreg); CstPtrTo Corereg; |
| VecArray (3, Dreg); Immed |], |
| "vld3_lane", bits_3, P8 :: P16 :: F32 :: su_8_32; |
| Vldx_lane 3, |
| [Disassembles_as [Use_operands |
| [| VecArray (3, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (3, Qreg); CstPtrTo Corereg; |
| VecArray (3, Qreg); Immed |], |
| "vld3Q_lane", bits_3, [P16; F32; U16; U32; S16; S32]; |
| |
| Vldx_dup 3, |
| [Disassembles_as [Use_operands |
| [| VecArray (3, All_elements_of_dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (3, Dreg); CstPtrTo Corereg |], |
| "vld3_dup", bits_1, pf_su_8_32; |
| Vldx_dup 3, |
| [Requires_feature "CRYPTO"; |
| Instruction_name ["vld1"]; Disassembles_as [Use_operands |
| [| VecArray (3, Dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (3, Dreg); CstPtrTo Corereg |], |
| "vld3_dup", bits_1, [P64]; |
| Vldx_dup 3, |
| [Instruction_name ["vld1"]; Disassembles_as [Use_operands |
| [| VecArray (3, Dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (3, Dreg); CstPtrTo Corereg |], |
| "vld3_dup", bits_1, [S64; U64]; |
| |
| (* VST3 variants. *) |
| Vstx 3, [Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (3, Dreg) |], "vst3", |
| store_1, pf_su_8_32; |
| Vstx 3, [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]]; |
| Instruction_name ["vst1"]], |
| Use_operands [| PtrTo Corereg; VecArray (3, Dreg) |], "vst3", |
| store_1, [P64]; |
| Vstx 3, [Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]]; |
| Instruction_name ["vst1"]], |
| Use_operands [| PtrTo Corereg; VecArray (3, Dreg) |], "vst3", |
| store_1, [S64; U64]; |
| Vstx 3, [Disassembles_as [Use_operands [| VecArray (3, Dreg); |
| PtrTo Corereg |]; |
| Use_operands [| VecArray (3, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (3, Qreg) |], "vst3Q", |
| store_1, pf_su_8_32; |
| |
| Vstx_lane 3, |
| [Disassembles_as [Use_operands |
| [| VecArray (3, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (3, Dreg); Immed |], "vst3_lane", |
| store_3, P8 :: P16 :: F32 :: su_8_32; |
| Vstx_lane 3, |
| [Disassembles_as [Use_operands |
| [| VecArray (3, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (3, Qreg); Immed |], "vst3Q_lane", |
| store_3, [P16; F32; U16; U32; S16; S32]; |
| |
| (* VLD4/VST4 variants. *) |
| Vldx 4, [], Use_operands [| VecArray (4, Dreg); CstPtrTo Corereg |], |
| "vld4", bits_1, pf_su_8_32; |
| Vldx 4, [Requires_feature "CRYPTO"; Instruction_name ["vld1"]], |
| Use_operands [| VecArray (4, Dreg); CstPtrTo Corereg |], |
| "vld4", bits_1, [P64]; |
| Vldx 4, [Instruction_name ["vld1"]], |
| Use_operands [| VecArray (4, Dreg); CstPtrTo Corereg |], |
| "vld4", bits_1, [S64; U64]; |
| Vldx 4, [Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| CstPtrTo Corereg |]; |
| Use_operands [| VecArray (4, Dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (4, Qreg); CstPtrTo Corereg |], |
| "vld4Q", bits_1, P8 :: P16 :: F32 :: su_8_32; |
| |
| Vldx_lane 4, |
| [Disassembles_as [Use_operands |
| [| VecArray (4, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (4, Dreg); CstPtrTo Corereg; |
| VecArray (4, Dreg); Immed |], |
| "vld4_lane", bits_3, P8 :: P16 :: F32 :: su_8_32; |
| Vldx_lane 4, |
| [Disassembles_as [Use_operands |
| [| VecArray (4, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (4, Qreg); CstPtrTo Corereg; |
| VecArray (4, Qreg); Immed |], |
| "vld4Q_lane", bits_3, [P16; F32; U16; U32; S16; S32]; |
| |
| Vldx_dup 4, |
| [Disassembles_as [Use_operands |
| [| VecArray (4, All_elements_of_dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (4, Dreg); CstPtrTo Corereg |], |
| "vld4_dup", bits_1, pf_su_8_32; |
| Vldx_dup 4, |
| [Requires_feature "CRYPTO"; |
| Instruction_name ["vld1"]; Disassembles_as [Use_operands |
| [| VecArray (4, Dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (4, Dreg); CstPtrTo Corereg |], |
| "vld4_dup", bits_1, [P64]; |
| Vldx_dup 4, |
| [Instruction_name ["vld1"]; Disassembles_as [Use_operands |
| [| VecArray (4, Dreg); CstPtrTo Corereg |]]], |
| Use_operands [| VecArray (4, Dreg); CstPtrTo Corereg |], |
| "vld4_dup", bits_1, [S64; U64]; |
| |
| Vstx 4, [Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (4, Dreg) |], "vst4", |
| store_1, pf_su_8_32; |
| Vstx 4, [Requires_feature "CRYPTO"; |
| Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]]; |
| Instruction_name ["vst1"]], |
| Use_operands [| PtrTo Corereg; VecArray (4, Dreg) |], "vst4", |
| store_1, [P64]; |
| Vstx 4, [Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]]; |
| Instruction_name ["vst1"]], |
| Use_operands [| PtrTo Corereg; VecArray (4, Dreg) |], "vst4", |
| store_1, [S64; U64]; |
| Vstx 4, [Disassembles_as [Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]; |
| Use_operands [| VecArray (4, Dreg); |
| PtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (4, Qreg) |], "vst4Q", |
| store_1, pf_su_8_32; |
| |
| Vstx_lane 4, |
| [Disassembles_as [Use_operands |
| [| VecArray (4, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (4, Dreg); Immed |], "vst4_lane", |
| store_3, P8 :: P16 :: F32 :: su_8_32; |
| Vstx_lane 4, |
| [Disassembles_as [Use_operands |
| [| VecArray (4, Element_of_dreg); |
| CstPtrTo Corereg |]]], |
| Use_operands [| PtrTo Corereg; VecArray (4, Qreg); Immed |], "vst4Q_lane", |
| store_3, [P16; F32; U16; U32; S16; S32]; |
| |
| (* Logical operations. And. *) |
| Vand, [], All (3, Dreg), "vand", notype_2, su_8_32; |
| Vand, [No_op], All (3, Dreg), "vand", notype_2, [S64; U64]; |
| Vand, [], All (3, Qreg), "vandQ", notype_2, su_8_64; |
| |
| (* Or. *) |
| Vorr, [], All (3, Dreg), "vorr", notype_2, su_8_32; |
| Vorr, [No_op], All (3, Dreg), "vorr", notype_2, [S64; U64]; |
| Vorr, [], All (3, Qreg), "vorrQ", notype_2, su_8_64; |
| |
| (* Eor. *) |
| Veor, [], All (3, Dreg), "veor", notype_2, su_8_32; |
| Veor, [No_op], All (3, Dreg), "veor", notype_2, [S64; U64]; |
| Veor, [], All (3, Qreg), "veorQ", notype_2, su_8_64; |
| |
| (* Bic (And-not). *) |
| Vbic, [Compiler_optim "-O2"], All (3, Dreg), "vbic", notype_2, su_8_32; |
| Vbic, [No_op; Compiler_optim "-O2"], All (3, Dreg), "vbic", notype_2, [S64; U64]; |
| Vbic, [Compiler_optim "-O2"], All (3, Qreg), "vbicQ", notype_2, su_8_64; |
| |
| (* Or-not. *) |
| Vorn, [Compiler_optim "-O2"], All (3, Dreg), "vorn", notype_2, su_8_32; |
| Vorn, [No_op; Compiler_optim "-O2"], All (3, Dreg), "vorn", notype_2, [S64; U64]; |
| Vorn, [Compiler_optim "-O2"], All (3, Qreg), "vornQ", notype_2, su_8_64; |
| ] |
| |
| let type_in_crypto_only t |
| = (t == P64) || (t == P128) |
| |
| let cross_product s1 s2 |
| = List.filter (fun (e, e') -> e <> e') |
| (List.concat (List.map (fun e1 -> List.map (fun e2 -> (e1,e2)) s1) s2)) |
| |
| let reinterp = |
| let elems = P8 :: P16 :: F32 :: P64 :: su_8_64 in |
| let casts = cross_product elems elems in |
| List.map |
| (fun (convto, convfrom) -> |
| Vreinterp, (if (type_in_crypto_only convto) || (type_in_crypto_only convfrom) |
| then [Requires_feature "CRYPTO"] else []) @ [No_op], Use_operands [| Dreg; Dreg |], |
| "vreinterpret", conv_1, [Cast (convto, convfrom)]) |
| casts |
| |
| let reinterpq = |
| let elems = P8 :: P16 :: F32 :: P64 :: P128 :: su_8_64 in |
| let casts = cross_product elems elems in |
| List.map |
| (fun (convto, convfrom) -> |
| Vreinterp, (if (type_in_crypto_only convto) || (type_in_crypto_only convfrom) |
| then [Requires_feature "CRYPTO"] else []) @ [No_op], Use_operands [| Qreg; Qreg |], |
| "vreinterpretQ", conv_1, [Cast (convto, convfrom)]) |
| casts |
| |
| (* Output routines. *) |
| |
| let rec string_of_elt = function |
| S8 -> "s8" | S16 -> "s16" | S32 -> "s32" | S64 -> "s64" |
| | U8 -> "u8" | U16 -> "u16" | U32 -> "u32" | U64 -> "u64" |
| | I8 -> "i8" | I16 -> "i16" | I32 -> "i32" | I64 -> "i64" |
| | B8 -> "8" | B16 -> "16" | B32 -> "32" | B64 -> "64" |
| | F16 -> "f16" | F32 -> "f32" | P8 -> "p8" | P16 -> "p16" |
| | P64 -> "p64" | P128 -> "p128" |
| | Conv (a, b) | Cast (a, b) -> string_of_elt a ^ "_" ^ string_of_elt b |
| | NoElts -> failwith "No elts" |
| |
| let string_of_elt_dots elt = |
| match elt with |
| Conv (a, b) | Cast (a, b) -> string_of_elt a ^ "." ^ string_of_elt b |
| | _ -> string_of_elt elt |
| |
| let string_of_vectype vt = |
| let rec name affix = function |
| T_int8x8 -> affix "int8x8" |
| | T_int8x16 -> affix "int8x16" |
| | T_int16x4 -> affix "int16x4" |
| | T_int16x8 -> affix "int16x8" |
| | T_int32x2 -> affix "int32x2" |
| | T_int32x4 -> affix "int32x4" |
| | T_int64x1 -> affix "int64x1" |
| | T_int64x2 -> affix "int64x2" |
| | T_uint8x8 -> affix "uint8x8" |
| | T_uint8x16 -> affix "uint8x16" |
| | T_uint16x4 -> affix "uint16x4" |
| | T_uint16x8 -> affix "uint16x8" |
| | T_uint32x2 -> affix "uint32x2" |
| | T_uint32x4 -> affix "uint32x4" |
| | T_uint64x1 -> affix "uint64x1" |
| | T_uint64x2 -> affix "uint64x2" |
| | T_float16x4 -> affix "float16x4" |
| | T_float32x2 -> affix "float32x2" |
| | T_float32x4 -> affix "float32x4" |
| | T_poly8x8 -> affix "poly8x8" |
| | T_poly8x16 -> affix "poly8x16" |
| | T_poly16x4 -> affix "poly16x4" |
| | T_poly16x8 -> affix "poly16x8" |
| | T_int8 -> affix "int8" |
| | T_int16 -> affix "int16" |
| | T_int32 -> affix "int32" |
| | T_int64 -> affix "int64" |
| | T_uint8 -> affix "uint8" |
| | T_uint16 -> affix "uint16" |
| | T_uint32 -> affix "uint32" |
| | T_uint64 -> affix "uint64" |
| | T_poly8 -> affix "poly8" |
| | T_poly16 -> affix "poly16" |
| | T_poly64 -> affix "poly64" |
| | T_poly64x1 -> affix "poly64x1" |
| | T_poly64x2 -> affix "poly64x2" |
| | T_poly128 -> affix "poly128" |
| | T_float16 -> affix "float16" |
| | T_float32 -> affix "float32" |
| | T_immediate _ -> "const int" |
| | T_void -> "void" |
| | T_intQI -> "__builtin_neon_qi" |
| | T_intHI -> "__builtin_neon_hi" |
| | T_intSI -> "__builtin_neon_si" |
| | T_intDI -> "__builtin_neon_di" |
| | T_intTI -> "__builtin_neon_ti" |
| | T_floatHF -> "__builtin_neon_hf" |
| | T_floatSF -> "__builtin_neon_sf" |
| | T_arrayof (num, base) -> |
| let basename = name (fun x -> x) base in |
| affix (Printf.sprintf "%sx%d" basename num) |
| | T_ptrto x -> |
| let basename = name affix x in |
| Printf.sprintf "%s *" basename |
| | T_const x -> |
| let basename = name affix x in |
| Printf.sprintf "const %s" basename |
| in |
| name (fun x -> x ^ "_t") vt |
| |
| let string_of_inttype = function |
| B_TImode -> "__builtin_neon_ti" |
| | B_EImode -> "__builtin_neon_ei" |
| | B_OImode -> "__builtin_neon_oi" |
| | B_CImode -> "__builtin_neon_ci" |
| | B_XImode -> "__builtin_neon_xi" |
| |
| let string_of_mode = function |
| V8QI -> "v8qi" | V4HI -> "v4hi" | V4HF -> "v4hf" | V2SI -> "v2si" |
| | V2SF -> "v2sf" | DI -> "di" | V16QI -> "v16qi" | V8HI -> "v8hi" |
| | V4SI -> "v4si" | V4SF -> "v4sf" | V2DI -> "v2di" | QI -> "qi" |
| | HI -> "hi" | SI -> "si" | SF -> "sf" | TI -> "ti" |
| |
| (* Use uppercase chars for letters which form part of the intrinsic name, but |
| should be omitted from the builtin name (the info is passed in an extra |
| argument, instead). *) |
| let intrinsic_name name = String.lowercase name |
| |
| (* Allow the name of the builtin to be overridden by things (e.g. Flipped) |
| found in the features list. *) |
| let builtin_name features name = |
| let name = List.fold_right |
| (fun el name -> |
| match el with |
| Flipped x | Builtin_name x -> x |
| | _ -> name) |
| features name in |
| let islower x = let str = String.make 1 x in (String.lowercase str) = str |
| and buf = Buffer.create (String.length name) in |
| String.iter (fun c -> if islower c then Buffer.add_char buf c) name; |
| Buffer.contents buf |
| |
| (* Transform an arity into a list of strings. *) |
| let strings_of_arity a = |
| match a with |
| | Arity0 vt -> [string_of_vectype vt] |
| | Arity1 (vt1, vt2) -> [string_of_vectype vt1; string_of_vectype vt2] |
| | Arity2 (vt1, vt2, vt3) -> [string_of_vectype vt1; |
| string_of_vectype vt2; |
| string_of_vectype vt3] |
| | Arity3 (vt1, vt2, vt3, vt4) -> [string_of_vectype vt1; |
| string_of_vectype vt2; |
| string_of_vectype vt3; |
| string_of_vectype vt4] |
| | Arity4 (vt1, vt2, vt3, vt4, vt5) -> [string_of_vectype vt1; |
| string_of_vectype vt2; |
| string_of_vectype vt3; |
| string_of_vectype vt4; |
| string_of_vectype vt5] |
| |
| (* Suffixes on the end of builtin names that are to be stripped in order |
| to obtain the name used as an instruction. They are only stripped if |
| preceded immediately by an underscore. *) |
| let suffixes_to_strip = [ "n"; "lane"; "dup" ] |
| |
| (* Get the possible names of an instruction corresponding to a "name" from the |
| ops table. This is done by getting the equivalent builtin name and |
| stripping any suffixes from the list at the top of this file, unless |
| the features list presents with an Instruction_name entry, in which |
| case that is used; or unless the features list presents with a Flipped |
| entry, in which case that is used. If both such entries are present, |
| the first in the list will be chosen. *) |
| let get_insn_names features name = |
| let names = try |
| begin |
| match List.find (fun feature -> match feature with |
| Instruction_name _ -> true |
| | Flipped _ -> true |
| | _ -> false) features |
| with |
| Instruction_name names -> names |
| | Flipped name -> [name] |
| | _ -> assert false |
| end |
| with Not_found -> [builtin_name features name] |
| in |
| begin |
| List.map (fun name' -> |
| try |
| let underscore = String.rindex name' '_' in |
| let our_suffix = String.sub name' (underscore + 1) |
| ((String.length name') - underscore - 1) |
| in |
| let rec strip remaining_suffixes = |
| match remaining_suffixes with |
| [] -> name' |
| | s::ss when our_suffix = s -> String.sub name' 0 underscore |
| | _::ss -> strip ss |
| in |
| strip suffixes_to_strip |
| with (Not_found | Invalid_argument _) -> name') names |
| end |
| |
| (* Apply a function to each element of a list and then comma-separate |
| the resulting strings. *) |
| let rec commas f elts acc = |
| match elts with |
| [] -> acc |
| | [elt] -> acc ^ (f elt) |
| | elt::elts -> |
| commas f elts (acc ^ (f elt) ^ ", ") |
| |
| (* Given a list of features and the shape specified in the "ops" table, apply |
| a function to each possible shape that the instruction may have. |
| By default, this is the "shape" entry in "ops". If the features list |
| contains a Disassembles_as entry, the shapes contained in that entry are |
| mapped to corresponding outputs and returned in a list. If there is more |
| than one Disassembles_as entry, only the first is used. *) |
| let analyze_all_shapes features shape f = |
| try |
| match List.find (fun feature -> |
| match feature with Disassembles_as _ -> true |
| | _ -> false) |
| features with |
| Disassembles_as shapes -> List.map f shapes |
| | _ -> assert false |
| with Not_found -> [f shape] |
| |
| (* The crypto intrinsics have unconventional shapes and are not that |
| numerous to be worth the trouble of encoding here. We implement them |
| explicitly here. *) |
| let crypto_intrinsics = |
| " |
| #ifdef __ARM_FEATURE_CRYPTO |
| |
| __extension__ static __inline poly128_t __attribute__ ((__always_inline__)) |
| vldrq_p128 (poly128_t const * __ptr) |
| { |
| #ifdef __ARM_BIG_ENDIAN |
| poly64_t* __ptmp = (poly64_t*) __ptr; |
| poly64_t __d0 = vld1_p64 (__ptmp); |
| poly64_t __d1 = vld1_p64 (__ptmp + 1); |
| return vreinterpretq_p128_p64 (vcombine_p64 (__d1, __d0)); |
| #else |
| return vreinterpretq_p128_p64 (vld1q_p64 ((poly64_t*) __ptr)); |
| #endif |
| } |
| |
| __extension__ static __inline void __attribute__ ((__always_inline__)) |
| vstrq_p128 (poly128_t * __ptr, poly128_t __val) |
| { |
| #ifdef __ARM_BIG_ENDIAN |
| poly64x2_t __tmp = vreinterpretq_p64_p128 (__val); |
| poly64_t __d0 = vget_high_p64 (__tmp); |
| poly64_t __d1 = vget_low_p64 (__tmp); |
| vst1q_p64 ((poly64_t*) __ptr, vcombine_p64 (__d0, __d1)); |
| #else |
| vst1q_p64 ((poly64_t*) __ptr, vreinterpretq_p64_p128 (__val)); |
| #endif |
| } |
| |
| /* The vceq_p64 intrinsic does not map to a single instruction. |
| Instead we emulate it by performing a 32-bit variant of the vceq |
| and applying a pairwise min reduction to the result. |
| vceq_u32 will produce two 32-bit halves, each of which will contain either |
| all ones or all zeros depending on whether the corresponding 32-bit |
| halves of the poly64_t were equal. The whole poly64_t values are equal |
| if and only if both halves are equal, i.e. vceq_u32 returns all ones. |
| If the result is all zeroes for any half then the whole result is zeroes. |
| This is what the pairwise min reduction achieves. */ |
| |
| __extension__ static __inline uint64x1_t __attribute__ ((__always_inline__)) |
| vceq_p64 (poly64x1_t __a, poly64x1_t __b) |
| { |
| uint32x2_t __t_a = vreinterpret_u32_p64 (__a); |
| uint32x2_t __t_b = vreinterpret_u32_p64 (__b); |
| uint32x2_t __c = vceq_u32 (__t_a, __t_b); |
| uint32x2_t __m = vpmin_u32 (__c, __c); |
| return vreinterpret_u64_u32 (__m); |
| } |
| |
| /* The vtst_p64 intrinsic does not map to a single instruction. |
| We emulate it in way similar to vceq_p64 above but here we do |
| a reduction with max since if any two corresponding bits |
| in the two poly64_t's match, then the whole result must be all ones. */ |
| |
| __extension__ static __inline uint64x1_t __attribute__ ((__always_inline__)) |
| vtst_p64 (poly64x1_t __a, poly64x1_t __b) |
| { |
| uint32x2_t __t_a = vreinterpret_u32_p64 (__a); |
| uint32x2_t __t_b = vreinterpret_u32_p64 (__b); |
| uint32x2_t __c = vtst_u32 (__t_a, __t_b); |
| uint32x2_t __m = vpmax_u32 (__c, __c); |
| return vreinterpret_u64_u32 (__m); |
| } |
| |
| __extension__ static __inline uint8x16_t __attribute__ ((__always_inline__)) |
| vaeseq_u8 (uint8x16_t __data, uint8x16_t __key) |
| { |
| return __builtin_arm_crypto_aese (__data, __key); |
| } |
| |
| __extension__ static __inline uint8x16_t __attribute__ ((__always_inline__)) |
| vaesdq_u8 (uint8x16_t __data, uint8x16_t __key) |
| { |
| return __builtin_arm_crypto_aesd (__data, __key); |
| } |
| |
| __extension__ static __inline uint8x16_t __attribute__ ((__always_inline__)) |
| vaesmcq_u8 (uint8x16_t __data) |
| { |
| return __builtin_arm_crypto_aesmc (__data); |
| } |
| |
| __extension__ static __inline uint8x16_t __attribute__ ((__always_inline__)) |
| vaesimcq_u8 (uint8x16_t __data) |
| { |
| return __builtin_arm_crypto_aesimc (__data); |
| } |
| |
| __extension__ static __inline uint32_t __attribute__ ((__always_inline__)) |
| vsha1h_u32 (uint32_t __hash_e) |
| { |
| uint32x4_t __t = vdupq_n_u32 (0); |
| __t = vsetq_lane_u32 (__hash_e, __t, 0); |
| __t = __builtin_arm_crypto_sha1h (__t); |
| return vgetq_lane_u32 (__t, 0); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha1cq_u32 (uint32x4_t __hash_abcd, uint32_t __hash_e, uint32x4_t __wk) |
| { |
| uint32x4_t __t = vdupq_n_u32 (0); |
| __t = vsetq_lane_u32 (__hash_e, __t, 0); |
| return __builtin_arm_crypto_sha1c (__hash_abcd, __t, __wk); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha1pq_u32 (uint32x4_t __hash_abcd, uint32_t __hash_e, uint32x4_t __wk) |
| { |
| uint32x4_t __t = vdupq_n_u32 (0); |
| __t = vsetq_lane_u32 (__hash_e, __t, 0); |
| return __builtin_arm_crypto_sha1p (__hash_abcd, __t, __wk); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha1mq_u32 (uint32x4_t __hash_abcd, uint32_t __hash_e, uint32x4_t __wk) |
| { |
| uint32x4_t __t = vdupq_n_u32 (0); |
| __t = vsetq_lane_u32 (__hash_e, __t, 0); |
| return __builtin_arm_crypto_sha1m (__hash_abcd, __t, __wk); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha1su0q_u32 (uint32x4_t __w0_3, uint32x4_t __w4_7, uint32x4_t __w8_11) |
| { |
| return __builtin_arm_crypto_sha1su0 (__w0_3, __w4_7, __w8_11); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha1su1q_u32 (uint32x4_t __tw0_3, uint32x4_t __w12_15) |
| { |
| return __builtin_arm_crypto_sha1su1 (__tw0_3, __w12_15); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha256hq_u32 (uint32x4_t __hash_abcd, uint32x4_t __hash_efgh, uint32x4_t __wk) |
| { |
| return __builtin_arm_crypto_sha256h (__hash_abcd, __hash_efgh, __wk); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha256h2q_u32 (uint32x4_t __hash_abcd, uint32x4_t __hash_efgh, uint32x4_t __wk) |
| { |
| return __builtin_arm_crypto_sha256h2 (__hash_abcd, __hash_efgh, __wk); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha256su0q_u32 (uint32x4_t __w0_3, uint32x4_t __w4_7) |
| { |
| return __builtin_arm_crypto_sha256su0 (__w0_3, __w4_7); |
| } |
| |
| __extension__ static __inline uint32x4_t __attribute__ ((__always_inline__)) |
| vsha256su1q_u32 (uint32x4_t __tw0_3, uint32x4_t __w8_11, uint32x4_t __w12_15) |
| { |
| return __builtin_arm_crypto_sha256su1 (__tw0_3, __w8_11, __w12_15); |
| } |
| |
| __extension__ static __inline poly128_t __attribute__ ((__always_inline__)) |
| vmull_p64 (poly64_t __a, poly64_t __b) |
| { |
| return (poly128_t) __builtin_arm_crypto_vmullp64 ((uint64_t) __a, (uint64_t) __b); |
| } |
| |
| __extension__ static __inline poly128_t __attribute__ ((__always_inline__)) |
| vmull_high_p64 (poly64x2_t __a, poly64x2_t __b) |
| { |
| poly64_t __t1 = vget_high_p64 (__a); |
| poly64_t __t2 = vget_high_p64 (__b); |
| |
| return (poly128_t) __builtin_arm_crypto_vmullp64 ((uint64_t) __t1, (uint64_t) __t2); |
| } |
| |
| #endif |
| " |