aarch64: Add bitrev,clz,cls,ctz for i128 values
This commit is contained in:
Afonso Bordado
@@ -1471,6 +1471,50 @@ pub(crate) fn emit_shr_i128<C: LowerCtx<I = Inst>>(
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});
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}
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pub(crate) fn emit_clz_i128<C: LowerCtx<I = Inst>>(
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ctx: &mut C,
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src: ValueRegs<Reg>,
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dst: ValueRegs<Writable<Reg>>,
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) {
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let src_lo = src.regs()[0];
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let src_hi = src.regs()[1];
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let dst_lo = dst.regs()[0];
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let dst_hi = dst.regs()[1];
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// clz dst_hi, src_hi
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// clz dst_lo, src_lo
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// lsr tmp, dst_hi, #6
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// madd dst_lo, dst_lo, tmp, dst_hi
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// mov dst_hi, 0
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let tmp = ctx.alloc_tmp(I64).only_reg().unwrap();
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ctx.emit(Inst::BitRR {
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rd: dst_hi,
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rn: src_hi,
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op: BitOp::Clz64,
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});
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ctx.emit(Inst::BitRR {
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rd: dst_lo,
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rn: src_lo,
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op: BitOp::Clz64,
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});
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ctx.emit(Inst::AluRRImmShift {
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alu_op: ALUOp::Lsr64,
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rd: tmp,
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rn: dst_hi.to_reg(),
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immshift: ImmShift::maybe_from_u64(6).unwrap(),
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});
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ctx.emit(Inst::AluRRRR {
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alu_op: ALUOp3::MAdd64,
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rd: dst_lo,
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rn: dst_lo.to_reg(),
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rm: tmp.to_reg(),
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ra: dst_hi.to_reg(),
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});
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lower_constant_u64(ctx, dst_hi, 0);
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}
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//=============================================================================
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// Lowering-backend trait implementation.
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@@ -1027,24 +1027,10 @@ pub(crate) fn lower_insn_to_regs<C: LowerCtx<I = Inst>>(
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}
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Opcode::Bitrev | Opcode::Clz | Opcode::Cls | Opcode::Ctz => {
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let rd = get_output_reg(ctx, outputs[0]).only_reg().unwrap();
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let needs_zext = match op {
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Opcode::Bitrev | Opcode::Ctz => false,
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Opcode::Clz | Opcode::Cls => true,
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_ => unreachable!(),
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};
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let ty = ty.unwrap();
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let narrow_mode = if needs_zext && ty_bits(ty) == 64 {
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NarrowValueMode::ZeroExtend64
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} else if needs_zext {
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NarrowValueMode::ZeroExtend32
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} else {
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NarrowValueMode::None
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};
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let rn = put_input_in_reg(ctx, inputs[0], narrow_mode);
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let op_ty = match ty {
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I8 | I16 | I32 => I32,
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I64 => I64,
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I64 | I128 => I64,
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_ => panic!("Unsupported type for Bitrev/Clz/Cls"),
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};
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let bitop = match op {
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@@ -1052,37 +1038,145 @@ pub(crate) fn lower_insn_to_regs<C: LowerCtx<I = Inst>>(
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Opcode::Ctz => BitOp::from((Opcode::Bitrev, op_ty)),
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_ => unreachable!(),
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};
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ctx.emit(Inst::BitRR { rd, rn, op: bitop });
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// Both bitrev and ctz use a bit-reverse (rbit) instruction; ctz to reduce the problem
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// to a clz, and bitrev as the main operation.
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if op == Opcode::Bitrev || op == Opcode::Ctz {
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// Reversing an n-bit value (n < 32) with a 32-bit bitrev instruction will place
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// the reversed result in the highest n bits, so we need to shift them down into
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// place.
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let right_shift = match ty {
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I8 => Some(24),
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I16 => Some(16),
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I32 => None,
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I64 => None,
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_ => panic!("Unsupported type for Bitrev"),
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};
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if let Some(s) = right_shift {
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ctx.emit(Inst::AluRRImmShift {
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alu_op: ALUOp::Lsr32,
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rd,
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rn: rd.to_reg(),
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immshift: ImmShift::maybe_from_u64(s).unwrap(),
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if ty == I128 {
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let out_regs = get_output_reg(ctx, outputs[0]);
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let in_regs = put_input_in_regs(ctx, inputs[0]);
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let in_lo = in_regs.regs()[0];
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let in_hi = in_regs.regs()[1];
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let out_lo = out_regs.regs()[0];
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let out_hi = out_regs.regs()[1];
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if op == Opcode::Bitrev || op == Opcode::Ctz {
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ctx.emit(Inst::BitRR {
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rd: out_hi,
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rn: in_lo,
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op: bitop,
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});
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ctx.emit(Inst::BitRR {
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rd: out_lo,
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rn: in_hi,
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op: bitop,
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});
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}
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}
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if op == Opcode::Ctz {
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ctx.emit(Inst::BitRR {
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op: BitOp::from((Opcode::Clz, op_ty)),
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rd,
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rn: rd.to_reg(),
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});
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if op == Opcode::Ctz {
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// We have reduced the problem to a clz by reversing the inputs previouly
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emit_clz_i128(ctx, out_regs.map(|r| r.to_reg()), out_regs);
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} else if op == Opcode::Clz {
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emit_clz_i128(ctx, in_regs, out_regs);
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} else if op == Opcode::Cls {
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// cls out_hi, in_hi
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// cls out_lo, in_lo
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// eon sign_eq, in_hi, in_lo
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// lsr sign_eq, sign_eq, #63
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// madd out_lo, out_lo, sign_eq, sign_eq
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// cmp out_hi, #63
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// csel out_lo, out_lo, xzr, eq
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// add out_lo, out_lo, out_hi
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// mov out_hi, 0
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let sign_eq = ctx.alloc_tmp(I64).only_reg().unwrap();
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let xzr = writable_zero_reg();
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ctx.emit(Inst::BitRR {
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rd: out_lo,
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rn: in_lo,
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op: bitop,
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});
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ctx.emit(Inst::BitRR {
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rd: out_hi,
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rn: in_hi,
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op: bitop,
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});
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ctx.emit(Inst::AluRRR {
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alu_op: ALUOp::EorNot64,
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rd: sign_eq,
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rn: in_hi,
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rm: in_lo,
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});
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ctx.emit(Inst::AluRRImmShift {
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alu_op: ALUOp::Lsr64,
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rd: sign_eq,
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rn: sign_eq.to_reg(),
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immshift: ImmShift::maybe_from_u64(63).unwrap(),
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});
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ctx.emit(Inst::AluRRRR {
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alu_op: ALUOp3::MAdd64,
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rd: out_lo,
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rn: out_lo.to_reg(),
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rm: sign_eq.to_reg(),
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ra: sign_eq.to_reg(),
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});
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ctx.emit(Inst::AluRRImm12 {
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alu_op: ALUOp::SubS64,
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rd: xzr,
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rn: out_hi.to_reg(),
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imm12: Imm12::maybe_from_u64(63).unwrap(),
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});
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ctx.emit(Inst::CSel {
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cond: Cond::Eq,
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rd: out_lo,
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rn: out_lo.to_reg(),
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rm: xzr.to_reg(),
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});
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ctx.emit(Inst::AluRRR {
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alu_op: ALUOp::Add64,
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rd: out_lo,
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rn: out_lo.to_reg(),
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rm: out_hi.to_reg(),
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});
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lower_constant_u64(ctx, out_hi, 0);
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}
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} else {
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let rd = get_output_reg(ctx, outputs[0]).only_reg().unwrap();
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let needs_zext = match op {
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Opcode::Bitrev | Opcode::Ctz => false,
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Opcode::Clz | Opcode::Cls => true,
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_ => unreachable!(),
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};
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let narrow_mode = if needs_zext && ty_bits(ty) == 64 {
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NarrowValueMode::ZeroExtend64
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} else if needs_zext {
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NarrowValueMode::ZeroExtend32
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} else {
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NarrowValueMode::None
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};
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let rn = put_input_in_reg(ctx, inputs[0], narrow_mode);
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ctx.emit(Inst::BitRR { rd, rn, op: bitop });
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// Both bitrev and ctz use a bit-reverse (rbit) instruction; ctz to reduce the problem
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// to a clz, and bitrev as the main operation.
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if op == Opcode::Bitrev || op == Opcode::Ctz {
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// Reversing an n-bit value (n < 32) with a 32-bit bitrev instruction will place
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// the reversed result in the highest n bits, so we need to shift them down into
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// place.
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let right_shift = match ty {
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I8 => Some(24),
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I16 => Some(16),
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I32 => None,
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I64 => None,
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_ => panic!("Unsupported type for Bitrev"),
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};
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if let Some(s) = right_shift {
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ctx.emit(Inst::AluRRImmShift {
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alu_op: ALUOp::Lsr32,
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rd,
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rn: rd.to_reg(),
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immshift: ImmShift::maybe_from_u64(s).unwrap(),
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});
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}
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}
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if op == Opcode::Ctz {
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ctx.emit(Inst::BitRR {
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op: BitOp::from((Opcode::Clz, op_ty)),
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rd,
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rn: rd.to_reg(),
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});
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}
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}
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}
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