rust/src/codegen_i128.rs

//! Replaces 128-bit operators with lang item calls

use crate::prelude::*;

pub fn maybe_codegen<'a, 'tcx>(
    fx: &mut FunctionCx<'a, 'tcx, impl Backend>,
    bin_op: BinOp,
    checked: bool,
    is_signed: bool,
    lhs: CValue<'tcx>,
    rhs: CValue<'tcx>,
    out_ty: Ty<'tcx>,
) -> Option<CValue<'tcx>> {
    if lhs.layout().ty != fx.tcx.types.u128 && lhs.layout().ty != fx.tcx.types.i128 {
        return None;
    }

    let lhs_val = lhs.load_scalar(fx);
    let rhs_val = rhs.load_scalar(fx);

    match bin_op {
        BinOp::BitAnd | BinOp::BitOr | BinOp::BitXor => {
            assert!(!checked);
            return None;
        }
        BinOp::Add | BinOp::Sub => {
            return None; // FIXME implement checked versions
        }
        BinOp::Offset => unreachable!("offset should only be used on pointers, not 128bit ints"),
        BinOp::Mul => {
            let res = if checked {
                if is_signed {
                    let oflow_place = CPlace::new_stack_slot(fx, fx.tcx.types.i32);
                    let oflow_addr = oflow_place.to_addr(fx);
                    let oflow_addr = CValue::by_val(oflow_addr, fx.layout_of(fx.tcx.mk_mut_ptr(fx.tcx.types.i32)));
                    let val = fx.easy_call("__muloti4", &[lhs, rhs, oflow_addr], fx.tcx.types.i128);
                    let val = val.load_scalar(fx);
                    let oflow = oflow_place.to_cvalue(fx).load_scalar(fx);
                    let oflow = fx.bcx.ins().icmp_imm(IntCC::NotEqual, oflow, 0);
                    let oflow = fx.bcx.ins().bint(types::I8, oflow);
                    CValue::by_val_pair(val, oflow, fx.layout_of(out_ty))
                } else {
                    // FIXME implement it
                let out_layout = fx.layout_of(out_ty);
                    return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit checked binop unsigned mul")));
                }
            } else {
                let val_ty = if is_signed { fx.tcx.types.i128 } else { fx.tcx.types.u128 };
                fx.easy_call("__multi3", &[lhs, rhs], val_ty)
            };
            return Some(res);
        }
        BinOp::Div => {
            let res = if checked {
                // FIXME implement it
                let out_layout = fx.layout_of(out_ty);
                return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit checked binop div")));
            } else {
                if is_signed {
                    fx.easy_call("__divti3", &[lhs, rhs], fx.tcx.types.i128)
                } else {
                    fx.easy_call("__udivti3", &[lhs, rhs], fx.tcx.types.u128)
                }
            };
            return Some(res);
        }
        BinOp::Rem => {
            let res = if checked {
                // FIXME implement it
                let out_layout = fx.layout_of(out_ty);
                return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit checked binop rem")));
            } else {
                if is_signed {
                    fx.easy_call("__modti3", &[lhs, rhs], fx.tcx.types.i128)
                } else {
                    fx.easy_call("__umodti3", &[lhs, rhs], fx.tcx.types.u128)
                }
            };
            return Some(res);
        }
        BinOp::Lt | BinOp::Le | BinOp::Eq | BinOp::Ge | BinOp::Gt | BinOp::Ne => {
            assert!(!checked);
            let (lhs_lsb, lhs_msb) = fx.bcx.ins().isplit(lhs_val);
            let (rhs_lsb, rhs_msb) = fx.bcx.ins().isplit(rhs_val);
            let res = match (bin_op, is_signed) {
                (BinOp::Eq, _) => {
                    let lsb_eq = fx.bcx.ins().icmp(IntCC::Equal, lhs_lsb, rhs_lsb);
                    let msb_eq = fx.bcx.ins().icmp(IntCC::Equal, lhs_msb, rhs_msb);
                    fx.bcx.ins().band(lsb_eq, msb_eq)
                }
                (BinOp::Ne, _) => {
                    let lsb_ne = fx.bcx.ins().icmp(IntCC::NotEqual, lhs_lsb, rhs_lsb);
                    let msb_ne = fx.bcx.ins().icmp(IntCC::NotEqual, lhs_msb, rhs_msb);
                    fx.bcx.ins().bor(lsb_ne, msb_ne)
                }
                _ => {
                    // FIXME implement it
                    let out_layout = fx.layout_of(out_ty);
                    return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit binop {:?}", bin_op)));
                },
            };

            let res = fx.bcx.ins().bint(types::I8, res);
            let res = CValue::by_val(res, fx.layout_of(fx.tcx.types.bool));
            return Some(res);
        }
        BinOp::Shl | BinOp::Shr => {
            let is_overflow = if checked {
                // rhs >= 128

                // FIXME support non 128bit rhs
                /*let (rhs_lsb, rhs_msb) = fx.bcx.ins().isplit(rhs_val);
                let rhs_msb_gt_0 = fx.bcx.ins().icmp_imm(IntCC::NotEqual, rhs_msb, 0);
                let rhs_lsb_ge_128 = fx.bcx.ins().icmp_imm(IntCC::SignedGreaterThan, rhs_lsb, 127);
                let is_overflow = fx.bcx.ins().bor(rhs_msb_gt_0, rhs_lsb_ge_128);*/
                let is_overflow = fx.bcx.ins().bconst(types::B1, false);

                Some(fx.bcx.ins().bint(types::I8, is_overflow))
            } else {
                None
            };

            // Optimize `val >> 64`, because compiler_builtins uses it to deconstruct an 128bit
            // integer into its lsb and msb.
            // https://github.com/rust-lang-nursery/compiler-builtins/blob/79a6a1603d5672cbb9187ff41ff4d9b5048ac1cb/src/int/mod.rs#L217
            if let Some(64) = resolve_value_imm(fx.bcx.func, rhs_val) {
                let (lhs_lsb, lhs_msb) = fx.bcx.ins().isplit(lhs_val);
                let all_zeros = fx.bcx.ins().iconst(types::I64, 0);
                let val = match (bin_op, is_signed) {
                    (BinOp::Shr, false) => {
                        let val = fx.bcx.ins().iconcat(lhs_msb, all_zeros);
                        Some(CValue::by_val(val, fx.layout_of(fx.tcx.types.u128)))
                    }
                    (BinOp::Shr, true) => {
                        let sign = fx.bcx.ins().icmp_imm(IntCC::SignedLessThan, lhs_msb, 0);
                        let all_ones = fx.bcx.ins().iconst(types::I64, u64::max_value() as i64);
                        let all_sign_bits = fx.bcx.ins().select(sign, all_zeros, all_ones);

                        let val = fx.bcx.ins().iconcat(lhs_msb, all_sign_bits);
                        Some(CValue::by_val(val, fx.layout_of(fx.tcx.types.i128)))
                    }
                    (BinOp::Shl, _) => {
                        let val = fx.bcx.ins().iconcat(all_zeros, lhs_lsb);
                        Some(CValue::by_val(val, fx.layout_of(out_ty)))
                    }
                    _ => None
                };
                if let Some(val) = val {
                    if let Some(is_overflow) = is_overflow {
                        let val = val.load_scalar(fx);
                        return Some(CValue::by_val_pair(val, is_overflow, fx.layout_of(out_ty)))
                    } else {
                        return Some(val);
                    }
                }
            }

            let truncated_rhs = clif_intcast(fx, rhs_val, types::I32, false);
            let truncated_rhs = CValue::by_val(truncated_rhs, fx.layout_of(fx.tcx.types.u32));
            let val = match (bin_op, is_signed) {
                (BinOp::Shl, false) => {
                    fx.easy_call("__ashlti3", &[lhs, truncated_rhs], fx.tcx.types.u128)
                }
                (BinOp::Shl, true) => {
                    fx.easy_call("__ashlti3", &[lhs, truncated_rhs], fx.tcx.types.i128)
                }
                (BinOp::Shr, false) => {
                    fx.easy_call("__lshrti3", &[lhs, truncated_rhs], fx.tcx.types.u128)
                }
                (BinOp::Shr, true) => {
                    fx.easy_call("__ashrti3", &[lhs, truncated_rhs], fx.tcx.types.i128)
                }
                (_, _) => unreachable!(),
            };
            if let Some(is_overflow) = is_overflow {
                let val = val.load_scalar(fx);
                Some(CValue::by_val_pair(val, is_overflow, fx.layout_of(out_ty)))
            } else {
                Some(val)
            }
        }
    }
}
Implement most 128bit binops 2019-07-07 11:08:38 -05:00			`//! Replaces 128-bit operators with lang item calls`

			`use crate::prelude::*;`

			`pub fn maybe_codegen<'a, 'tcx>(`
			`fx: &mut FunctionCx<'a, 'tcx, impl Backend>,`
			`bin_op: BinOp,`
			`checked: bool,`
			`is_signed: bool,`
			`lhs: CValue<'tcx>,`
			`rhs: CValue<'tcx>,`
			`out_ty: Ty<'tcx>,`
			`) -> Option<CValue<'tcx>> {`
			`if lhs.layout().ty != fx.tcx.types.u128 && lhs.layout().ty != fx.tcx.types.i128 {`
			`return None;`
			`}`

			`let lhs_val = lhs.load_scalar(fx);`
			`let rhs_val = rhs.load_scalar(fx);`

			`match bin_op {`
Implement 128bit shl and shr binops 2019-07-20 10:44:41 -05:00			`BinOp::BitAnd \| BinOp::BitOr \| BinOp::BitXor => {`
			`assert!(!checked);`
			`return None;`
			`}`
			`BinOp::Add \| BinOp::Sub => {`
			`return None; // FIXME implement checked versions`
			`}`
Implement most 128bit binops 2019-07-07 11:08:38 -05:00			`BinOp::Offset => unreachable!("offset should only be used on pointers, not 128bit ints"),`
			`BinOp::Mul => {`
			`let res = if checked {`
			`if is_signed {`
			`let oflow_place = CPlace::new_stack_slot(fx, fx.tcx.types.i32);`
			`let oflow_addr = oflow_place.to_addr(fx);`
			`let oflow_addr = CValue::by_val(oflow_addr, fx.layout_of(fx.tcx.mk_mut_ptr(fx.tcx.types.i32)));`
			`let val = fx.easy_call("__muloti4", &[lhs, rhs, oflow_addr], fx.tcx.types.i128);`
			`let val = val.load_scalar(fx);`
			`let oflow = oflow_place.to_cvalue(fx).load_scalar(fx);`
			`let oflow = fx.bcx.ins().icmp_imm(IntCC::NotEqual, oflow, 0);`
			`let oflow = fx.bcx.ins().bint(types::I8, oflow);`
			`CValue::by_val_pair(val, oflow, fx.layout_of(out_ty))`
			`} else {`
			`// FIXME implement it`
			`let out_layout = fx.layout_of(out_ty);`
			`return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit checked binop unsigned mul")));`
			`}`
			`} else {`
			`let val_ty = if is_signed { fx.tcx.types.i128 } else { fx.tcx.types.u128 };`
			`fx.easy_call("__multi3", &[lhs, rhs], val_ty)`
			`};`
			`return Some(res);`
			`}`
			`BinOp::Div => {`
			`let res = if checked {`
			`// FIXME implement it`
			`let out_layout = fx.layout_of(out_ty);`
			`return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit checked binop div")));`
			`} else {`
			`if is_signed {`
			`fx.easy_call("__divti3", &[lhs, rhs], fx.tcx.types.i128)`
			`} else {`
			`fx.easy_call("__udivti3", &[lhs, rhs], fx.tcx.types.u128)`
			`}`
			`};`
			`return Some(res);`
			`}`
			`BinOp::Rem => {`
			`let res = if checked {`
			`// FIXME implement it`
			`let out_layout = fx.layout_of(out_ty);`
			`return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit checked binop rem")));`
			`} else {`
			`if is_signed {`
			`fx.easy_call("__modti3", &[lhs, rhs], fx.tcx.types.i128)`
			`} else {`
			`fx.easy_call("__umodti3", &[lhs, rhs], fx.tcx.types.u128)`
			`}`
			`};`
			`return Some(res);`
			`}`
			`BinOp::Lt \| BinOp::Le \| BinOp::Eq \| BinOp::Ge \| BinOp::Gt \| BinOp::Ne => {`
			`assert!(!checked);`
			`let (lhs_lsb, lhs_msb) = fx.bcx.ins().isplit(lhs_val);`
			`let (rhs_lsb, rhs_msb) = fx.bcx.ins().isplit(rhs_val);`
			`let res = match (bin_op, is_signed) {`
			`(BinOp::Eq, _) => {`
			`let lsb_eq = fx.bcx.ins().icmp(IntCC::Equal, lhs_lsb, rhs_lsb);`
			`let msb_eq = fx.bcx.ins().icmp(IntCC::Equal, lhs_msb, rhs_msb);`
			`fx.bcx.ins().band(lsb_eq, msb_eq)`
			`}`
			`(BinOp::Ne, _) => {`
			`let lsb_ne = fx.bcx.ins().icmp(IntCC::NotEqual, lhs_lsb, rhs_lsb);`
			`let msb_ne = fx.bcx.ins().icmp(IntCC::NotEqual, lhs_msb, rhs_msb);`
			`fx.bcx.ins().bor(lsb_ne, msb_ne)`
			`}`
			`_ => {`
			`// FIXME implement it`
			`let out_layout = fx.layout_of(out_ty);`
			`return Some(crate::trap::trap_unreachable_ret_value(fx, out_layout, format!("unimplemented 128bit binop {:?}", bin_op)));`
			`},`
			`};`

			`let res = fx.bcx.ins().bint(types::I8, res);`
			`let res = CValue::by_val(res, fx.layout_of(fx.tcx.types.bool));`
			`return Some(res);`
			`}`
			`BinOp::Shl \| BinOp::Shr => {`
Implement 128bit shl and shr binops 2019-07-20 10:44:41 -05:00			`let is_overflow = if checked {`
			`// rhs >= 128`

			`// FIXME support non 128bit rhs`
			`/*let (rhs_lsb, rhs_msb) = fx.bcx.ins().isplit(rhs_val);`
			`let rhs_msb_gt_0 = fx.bcx.ins().icmp_imm(IntCC::NotEqual, rhs_msb, 0);`
			`let rhs_lsb_ge_128 = fx.bcx.ins().icmp_imm(IntCC::SignedGreaterThan, rhs_lsb, 127);`
			`let is_overflow = fx.bcx.ins().bor(rhs_msb_gt_0, rhs_lsb_ge_128);*/`
			`let is_overflow = fx.bcx.ins().bconst(types::B1, false);`

			`Some(fx.bcx.ins().bint(types::I8, is_overflow))`
			`} else {`
			`None`
			`};`

			// Optimize `val >> 64`, because compiler_builtins uses it to deconstruct an 128bit
			`// integer into its lsb and msb.`
			`// https://github.com/rust-lang-nursery/compiler-builtins/blob/79a6a1603d5672cbb9187ff41ff4d9b5048ac1cb/src/int/mod.rs#L217`
			`if let Some(64) = resolve_value_imm(fx.bcx.func, rhs_val) {`
			`let (lhs_lsb, lhs_msb) = fx.bcx.ins().isplit(lhs_val);`
			`let all_zeros = fx.bcx.ins().iconst(types::I64, 0);`
			`let val = match (bin_op, is_signed) {`
			`(BinOp::Shr, false) => {`
			`let val = fx.bcx.ins().iconcat(lhs_msb, all_zeros);`
			`Some(CValue::by_val(val, fx.layout_of(fx.tcx.types.u128)))`
			`}`
			`(BinOp::Shr, true) => {`
			`let sign = fx.bcx.ins().icmp_imm(IntCC::SignedLessThan, lhs_msb, 0);`
			`let all_ones = fx.bcx.ins().iconst(types::I64, u64::max_value() as i64);`
			`let all_sign_bits = fx.bcx.ins().select(sign, all_zeros, all_ones);`

			`let val = fx.bcx.ins().iconcat(lhs_msb, all_sign_bits);`
			`Some(CValue::by_val(val, fx.layout_of(fx.tcx.types.i128)))`
			`}`
			`(BinOp::Shl, _) => {`
			`let val = fx.bcx.ins().iconcat(all_zeros, lhs_lsb);`
			`Some(CValue::by_val(val, fx.layout_of(out_ty)))`
			`}`
			`_ => None`
			`};`
			`if let Some(val) = val {`
			`if let Some(is_overflow) = is_overflow {`
			`let val = val.load_scalar(fx);`
			`return Some(CValue::by_val_pair(val, is_overflow, fx.layout_of(out_ty)))`
			`} else {`
			`return Some(val);`
			`}`
			`}`
			`}`

			`let truncated_rhs = clif_intcast(fx, rhs_val, types::I32, false);`
			`let truncated_rhs = CValue::by_val(truncated_rhs, fx.layout_of(fx.tcx.types.u32));`
			`let val = match (bin_op, is_signed) {`
			`(BinOp::Shl, false) => {`
			`fx.easy_call("__ashlti3", &[lhs, truncated_rhs], fx.tcx.types.u128)`
			`}`
			`(BinOp::Shl, true) => {`
			`fx.easy_call("__ashlti3", &[lhs, truncated_rhs], fx.tcx.types.i128)`
			`}`
			`(BinOp::Shr, false) => {`
			`fx.easy_call("__lshrti3", &[lhs, truncated_rhs], fx.tcx.types.u128)`
			`}`
			`(BinOp::Shr, true) => {`
			`fx.easy_call("__ashrti3", &[lhs, truncated_rhs], fx.tcx.types.i128)`
			`}`
			`(_, _) => unreachable!(),`
			`};`
			`if let Some(is_overflow) = is_overflow {`
			`let val = val.load_scalar(fx);`
			`Some(CValue::by_val_pair(val, is_overflow, fx.layout_of(out_ty)))`
			`} else {`
			`Some(val)`
			`}`
Implement most 128bit binops 2019-07-07 11:08:38 -05:00			`}`
			`}`
			`}`