compiler/rustc_codegen_cranelift/src/cast.rs - third_party/github.com/rust-lang/rust - Git at Google

 //! Various number casting functions

 use crate::prelude::*;

 pub(crate) fn clif_intcast(
     fx: &mut FunctionCx<'_, '_, '_>,
     val: Value,
     to: Type,
     signed: bool,
 ) -> Value {
     let from = fx.bcx.func.dfg.value_type(val);
     match (from, to) {
         // equal
         (_, _) if from == to => val,

         // extend
         (_, types::I128) => {
             let lo = if from == types::I64 {
                 val
             } else if signed {
                 fx.bcx.ins().sextend(types::I64, val)
             } else {
                 fx.bcx.ins().uextend(types::I64, val)
             };
             let hi = if signed {
                 fx.bcx.ins().sshr_imm(lo, 63)
             } else {
                 fx.bcx.ins().iconst(types::I64, 0)
             };
             fx.bcx.ins().iconcat(lo, hi)
         }
         (_, _) if to.wider_or_equal(from) => {
             if signed {
                 fx.bcx.ins().sextend(to, val)
             } else {
                 fx.bcx.ins().uextend(to, val)
             }
         }

         // reduce
         (types::I128, _) => {
             let (lsb, _msb) = fx.bcx.ins().isplit(val);
             if to == types::I64 { lsb } else { fx.bcx.ins().ireduce(to, lsb) }
         }
         (_, _) => fx.bcx.ins().ireduce(to, val),
     }
 }

 pub(crate) fn clif_int_or_float_cast(
     fx: &mut FunctionCx<'_, '_, '_>,
     from: Value,
     from_signed: bool,
     to_ty: Type,
     to_signed: bool,
 ) -> Value {
     let from_ty = fx.bcx.func.dfg.value_type(from);

     if from_ty.is_int() && to_ty.is_int() {
         // int-like -> int-like
         clif_intcast(
             fx,
             from,
             to_ty,
             // This is correct as either from_signed == to_signed (=> this is trivially correct)
             // Or from_clif_ty == to_clif_ty, which means this is a no-op.
             from_signed,
         )
     } else if from_ty.is_int() && to_ty.is_float() {
         if from_ty == types::I128 {
             // _______ss__f_
             // __float  tisf: i128 -> f32
             // __float  tidf: i128 -> f64
             // __floatuntisf: u128 -> f32
             // __floatuntidf: u128 -> f64

             let name = format!(
                 "__float{sign}ti{flt}f",
                 sign = if from_signed { "" } else { "un" },
                 flt = match to_ty {
                     types::F32 => "s",
                     types::F64 => "d",
                     _ => unreachable!("{:?}", to_ty),
                 },
             );

             let from_rust_ty = if from_signed { fx.tcx.types.i128 } else { fx.tcx.types.u128 };

             let to_rust_ty = match to_ty {
                 types::F32 => fx.tcx.types.f32,
                 types::F64 => fx.tcx.types.f64,
                 _ => unreachable!(),
             };

             return fx
                 .easy_call(&name, &[CValue::by_val(from, fx.layout_of(from_rust_ty))], to_rust_ty)
                 .load_scalar(fx);
         }

         // int-like -> float
         if from_signed {
             fx.bcx.ins().fcvt_from_sint(to_ty, from)
         } else {
             fx.bcx.ins().fcvt_from_uint(to_ty, from)
         }
     } else if from_ty.is_float() && to_ty.is_int() {
         if to_ty == types::I128 {
             // _____sssf___
             // __fix   sfti: f32 -> i128
             // __fix   dfti: f64 -> i128
             // __fixunssfti: f32 -> u128
             // __fixunsdfti: f64 -> u128

             let name = format!(
                 "__fix{sign}{flt}fti",
                 sign = if to_signed { "" } else { "uns" },
                 flt = match from_ty {
                     types::F32 => "s",
                     types::F64 => "d",
                     _ => unreachable!("{:?}", to_ty),
                 },
             );

             let from_rust_ty = match from_ty {
                 types::F32 => fx.tcx.types.f32,
                 types::F64 => fx.tcx.types.f64,
                 _ => unreachable!(),
             };

             let to_rust_ty = if to_signed { fx.tcx.types.i128 } else { fx.tcx.types.u128 };

             return fx
                 .easy_call(&name, &[CValue::by_val(from, fx.layout_of(from_rust_ty))], to_rust_ty)
                 .load_scalar(fx);
         }

         // float -> int-like
         if to_ty == types::I8 || to_ty == types::I16 {
             // FIXME implement fcvt_to_*int_sat.i8/i16
             let val = if to_signed {
                 fx.bcx.ins().fcvt_to_sint_sat(types::I32, from)
             } else {
                 fx.bcx.ins().fcvt_to_uint_sat(types::I32, from)
             };
             let (min, max) = match (to_ty, to_signed) {
                 (types::I8, false) => (0, i64::from(u8::MAX)),
                 (types::I16, false) => (0, i64::from(u16::MAX)),
                 (types::I8, true) => (i64::from(i8::MIN), i64::from(i8::MAX)),
                 (types::I16, true) => (i64::from(i16::MIN), i64::from(i16::MAX)),
                 _ => unreachable!(),
             };
             let min_val = fx.bcx.ins().iconst(types::I32, min);
             let max_val = fx.bcx.ins().iconst(types::I32, max);

             let val = if to_signed {
                 let has_underflow = fx.bcx.ins().icmp_imm(IntCC::SignedLessThan, val, min);
                 let has_overflow = fx.bcx.ins().icmp_imm(IntCC::SignedGreaterThan, val, max);
                 let bottom_capped = fx.bcx.ins().select(has_underflow, min_val, val);
                 fx.bcx.ins().select(has_overflow, max_val, bottom_capped)
             } else {
                 let has_overflow = fx.bcx.ins().icmp_imm(IntCC::UnsignedGreaterThan, val, max);
                 fx.bcx.ins().select(has_overflow, max_val, val)
             };
             fx.bcx.ins().ireduce(to_ty, val)
         } else if to_signed {
             fx.bcx.ins().fcvt_to_sint_sat(to_ty, from)
         } else {
             fx.bcx.ins().fcvt_to_uint_sat(to_ty, from)
         }
     } else if from_ty.is_float() && to_ty.is_float() {
         // float -> float
         match (from_ty, to_ty) {
             (types::F32, types::F64) => fx.bcx.ins().fpromote(types::F64, from),
             (types::F64, types::F32) => fx.bcx.ins().fdemote(types::F32, from),
             _ => from,
         }
     } else {
         unreachable!("cast value from {:?} to {:?}", from_ty, to_ty);
     }
 }
	//! Various number casting functions

	use crate::prelude::*;

	pub(crate) fn clif_intcast(
	fx: &mut FunctionCx<'_, '_, '_>,
	val: Value,
	to: Type,
	signed: bool,
	) -> Value {
	let from = fx.bcx.func.dfg.value_type(val);
	match (from, to) {
	// equal
	(_, _) if from == to => val,

	// extend
	(_, types::I128) => {
	let lo = if from == types::I64 {
	val
	} else if signed {
	fx.bcx.ins().sextend(types::I64, val)
	} else {
	fx.bcx.ins().uextend(types::I64, val)
	};
	let hi = if signed {
	fx.bcx.ins().sshr_imm(lo, 63)
	} else {
	fx.bcx.ins().iconst(types::I64, 0)
	};
	fx.bcx.ins().iconcat(lo, hi)
	}
	(_, _) if to.wider_or_equal(from) => {
	if signed {
	fx.bcx.ins().sextend(to, val)
	} else {
	fx.bcx.ins().uextend(to, val)
	}
	}

	// reduce
	(types::I128, _) => {
	let (lsb, _msb) = fx.bcx.ins().isplit(val);
	if to == types::I64 { lsb } else { fx.bcx.ins().ireduce(to, lsb) }
	}
	(_, _) => fx.bcx.ins().ireduce(to, val),
	}
	}

	pub(crate) fn clif_int_or_float_cast(
	fx: &mut FunctionCx<'_, '_, '_>,
	from: Value,
	from_signed: bool,
	to_ty: Type,
	to_signed: bool,
	) -> Value {
	let from_ty = fx.bcx.func.dfg.value_type(from);

	if from_ty.is_int() && to_ty.is_int() {
	// int-like -> int-like
	clif_intcast(
	fx,
	from,
	to_ty,
	// This is correct as either from_signed == to_signed (=> this is trivially correct)
	// Or from_clif_ty == to_clif_ty, which means this is a no-op.
	from_signed,
	)
	} else if from_ty.is_int() && to_ty.is_float() {
	if from_ty == types::I128 {
	// _______ss__f_
	// __float tisf: i128 -> f32
	// __float tidf: i128 -> f64
	// __floatuntisf: u128 -> f32
	// __floatuntidf: u128 -> f64

	let name = format!(
	"__float{sign}ti{flt}f",
	sign = if from_signed { "" } else { "un" },
	flt = match to_ty {
	types::F32 => "s",
	types::F64 => "d",
	_ => unreachable!("{:?}", to_ty),
	},
	);

	let from_rust_ty = if from_signed { fx.tcx.types.i128 } else { fx.tcx.types.u128 };

	let to_rust_ty = match to_ty {
	types::F32 => fx.tcx.types.f32,
	types::F64 => fx.tcx.types.f64,
	_ => unreachable!(),
	};

	return fx
	.easy_call(&name, &[CValue::by_val(from, fx.layout_of(from_rust_ty))], to_rust_ty)
	.load_scalar(fx);
	}

	// int-like -> float
	if from_signed {
	fx.bcx.ins().fcvt_from_sint(to_ty, from)
	} else {
	fx.bcx.ins().fcvt_from_uint(to_ty, from)
	}
	} else if from_ty.is_float() && to_ty.is_int() {
	if to_ty == types::I128 {
	// _____sssf___
	// __fix sfti: f32 -> i128
	// __fix dfti: f64 -> i128
	// __fixunssfti: f32 -> u128
	// __fixunsdfti: f64 -> u128

	let name = format!(
	"__fix{sign}{flt}fti",
	sign = if to_signed { "" } else { "uns" },
	flt = match from_ty {
	types::F32 => "s",
	types::F64 => "d",
	_ => unreachable!("{:?}", to_ty),
	},
	);

	let from_rust_ty = match from_ty {
	types::F32 => fx.tcx.types.f32,
	types::F64 => fx.tcx.types.f64,
	_ => unreachable!(),
	};

	let to_rust_ty = if to_signed { fx.tcx.types.i128 } else { fx.tcx.types.u128 };

	return fx
	.easy_call(&name, &[CValue::by_val(from, fx.layout_of(from_rust_ty))], to_rust_ty)
	.load_scalar(fx);
	}

	// float -> int-like
	if to_ty == types::I8 \|\| to_ty == types::I16 {
	// FIXME implement fcvt_to_*int_sat.i8/i16
	let val = if to_signed {
	fx.bcx.ins().fcvt_to_sint_sat(types::I32, from)
	} else {
	fx.bcx.ins().fcvt_to_uint_sat(types::I32, from)
	};
	let (min, max) = match (to_ty, to_signed) {
	(types::I8, false) => (0, i64::from(u8::MAX)),
	(types::I16, false) => (0, i64::from(u16::MAX)),
	(types::I8, true) => (i64::from(i8::MIN), i64::from(i8::MAX)),
	(types::I16, true) => (i64::from(i16::MIN), i64::from(i16::MAX)),
	_ => unreachable!(),
	};
	let min_val = fx.bcx.ins().iconst(types::I32, min);
	let max_val = fx.bcx.ins().iconst(types::I32, max);

	let val = if to_signed {
	let has_underflow = fx.bcx.ins().icmp_imm(IntCC::SignedLessThan, val, min);
	let has_overflow = fx.bcx.ins().icmp_imm(IntCC::SignedGreaterThan, val, max);
	let bottom_capped = fx.bcx.ins().select(has_underflow, min_val, val);
	fx.bcx.ins().select(has_overflow, max_val, bottom_capped)
	} else {
	let has_overflow = fx.bcx.ins().icmp_imm(IntCC::UnsignedGreaterThan, val, max);
	fx.bcx.ins().select(has_overflow, max_val, val)
	};
	fx.bcx.ins().ireduce(to_ty, val)
	} else if to_signed {
	fx.bcx.ins().fcvt_to_sint_sat(to_ty, from)
	} else {
	fx.bcx.ins().fcvt_to_uint_sat(to_ty, from)
	}
	} else if from_ty.is_float() && to_ty.is_float() {
	// float -> float
	match (from_ty, to_ty) {
	(types::F32, types::F64) => fx.bcx.ins().fpromote(types::F64, from),
	(types::F64, types::F32) => fx.bcx.ins().fdemote(types::F32, from),
	_ => from,
	}
	} else {
	unreachable!("cast value from {:?} to {:?}", from_ty, to_ty);
	}
	}