wasmtime/lib/codegen/src/legalizer/boundary.rs

//! Legalize ABI boundaries.
//!
//! This legalizer sub-module contains code for dealing with ABI boundaries:
//!
//! - Function arguments passed to the entry block.
//! - Function arguments passed to call instructions.
//! - Return values from call instructions.
//! - Return values passed to return instructions.
//!
//! The ABI boundary legalization happens in two phases:
//!
//! 1. The `legalize_signatures` function rewrites all the preamble signatures with ABI information
//!    and possibly new argument types. It also rewrites the entry block arguments to match.
//! 2. The `handle_call_abi` and `handle_return_abi` functions rewrite call and return instructions
//!    to match the new ABI signatures.
//!
//! Between the two phases, preamble signatures and call/return arguments don't match. This
//! intermediate state doesn't type check.

use abi::{legalize_abi_value, ValueConversion};
use cursor::{Cursor, FuncCursor};
use flowgraph::ControlFlowGraph;
use ir::instructions::CallInfo;
use ir::{
    AbiParam, ArgumentLoc, ArgumentPurpose, DataFlowGraph, Ebb, Function, Inst, InstBuilder,
    SigRef, Signature, Type, Value, ValueLoc,
};
use isa::TargetIsa;
use legalizer::split::{isplit, vsplit};
use std::vec::Vec;

/// Legalize all the function signatures in `func`.
///
/// This changes all signatures to be ABI-compliant with full `ArgumentLoc` annotations. It doesn't
/// change the entry block arguments, calls, or return instructions, so this can leave the function
/// in a state with type discrepancies.
pub fn legalize_signatures(func: &mut Function, isa: &TargetIsa) {
    legalize_signature(&mut func.signature, true, isa);
    for sig_data in func.dfg.signatures.values_mut() {
        legalize_signature(sig_data, false, isa);
    }

    if let Some(entry) = func.layout.entry_block() {
        legalize_entry_params(func, entry);
        spill_entry_params(func, entry);
    }
}

/// Legalize the libcall signature, which we may generate on the fly after
/// `legalize_signatures` has been called.
pub fn legalize_libcall_signature(signature: &mut Signature, isa: &TargetIsa) {
    legalize_signature(signature, false, isa);
}

/// Legalize the given signature.
///
/// `current` is true if this is the signature for the current function.
fn legalize_signature(signature: &mut Signature, current: bool, isa: &TargetIsa) {
    isa.legalize_signature(signature, current);
    signature.compute_argument_bytes();
}

/// Legalize the entry block parameters after `func`'s signature has been legalized.
///
/// The legalized signature may contain more parameters than the original signature, and the
/// parameter types have been changed. This function goes through the parameters of the entry EBB
/// and replaces them with parameters of the right type for the ABI.
///
/// The original entry EBB parameters are computed from the new ABI parameters by code inserted at
/// the top of the entry block.
fn legalize_entry_params(func: &mut Function, entry: Ebb) {
    let mut has_sret = false;
    let mut has_link = false;
    let mut has_vmctx = false;
    let mut has_sigid = false;

    // Insert position for argument conversion code.
    // We want to insert instructions before the first instruction in the entry block.
    // If the entry block is empty, append instructions to it instead.
    let mut pos = FuncCursor::new(func).at_first_inst(entry);

    // Keep track of the argument types in the ABI-legalized signature.
    let mut abi_arg = 0;

    // Process the EBB parameters one at a time, possibly replacing one argument with multiple new
    // ones. We do this by detaching the entry EBB parameters first.
    let ebb_params = pos.func.dfg.detach_ebb_params(entry);
    let mut old_arg = 0;
    while let Some(arg) = ebb_params.get(old_arg, &pos.func.dfg.value_lists) {
        old_arg += 1;

        let abi_type = pos.func.signature.params[abi_arg];
        let arg_type = pos.func.dfg.value_type(arg);
        if arg_type == abi_type.value_type {
            // No value translation is necessary, this argument matches the ABI type.
            // Just use the original EBB argument value. This is the most common case.
            pos.func.dfg.attach_ebb_param(entry, arg);
            match abi_type.purpose {
                ArgumentPurpose::Normal => {}
                ArgumentPurpose::FramePointer => {}
                ArgumentPurpose::CalleeSaved => {}
                ArgumentPurpose::StructReturn => {
                    debug_assert!(!has_sret, "Multiple sret arguments found");
                    has_sret = true;
                }
                ArgumentPurpose::VMContext => {
                    debug_assert!(!has_vmctx, "Multiple vmctx arguments found");
                    has_vmctx = true;
                }
                ArgumentPurpose::SignatureId => {
                    debug_assert!(!has_sigid, "Multiple sigid arguments found");
                    has_sigid = true;
                }
                _ => panic!("Unexpected special-purpose arg {}", abi_type),
            }
            abi_arg += 1;
        } else {
            // Compute the value we want for `arg` from the legalized ABI parameters.
            let mut get_arg = |func: &mut Function, ty| {
                let abi_type = func.signature.params[abi_arg];
                debug_assert_eq!(
                    abi_type.purpose,
                    ArgumentPurpose::Normal,
                    "Can't legalize special-purpose argument"
                );
                if ty == abi_type.value_type {
                    abi_arg += 1;
                    Ok(func.dfg.append_ebb_param(entry, ty))
                } else {
                    Err(abi_type)
                }
            };
            let converted = convert_from_abi(&mut pos, arg_type, Some(arg), &mut get_arg);
            // The old `arg` is no longer an attached EBB argument, but there are probably still
            // uses of the value.
            debug_assert_eq!(pos.func.dfg.resolve_aliases(arg), converted);
        }
    }

    // The legalized signature may contain additional parameters representing special-purpose
    // registers.
    for &arg in &pos.func.signature.params[abi_arg..] {
        match arg.purpose {
            // Any normal parameters should have been processed above.
            ArgumentPurpose::Normal => {
                panic!("Leftover arg: {}", arg);
            }
            // The callee-save parameters should not appear until after register allocation is
            // done.
            ArgumentPurpose::FramePointer | ArgumentPurpose::CalleeSaved => {
                panic!("Premature callee-saved arg {}", arg);
            }
            // These can be meaningfully added by `legalize_signature()`.
            ArgumentPurpose::Link => {
                debug_assert!(!has_link, "Multiple link parameters found");
                has_link = true;
            }
            ArgumentPurpose::StructReturn => {
                debug_assert!(!has_sret, "Multiple sret parameters found");
                has_sret = true;
            }
            ArgumentPurpose::VMContext => {
                debug_assert!(!has_vmctx, "Multiple vmctx parameters found");
                has_vmctx = true;
            }
            ArgumentPurpose::SignatureId => {
                debug_assert!(!has_sigid, "Multiple sigid parameters found");
                has_sigid = true;
            }
        }

        // Just create entry block values to match here. We will use them in `handle_return_abi()`
        // below.
        pos.func.dfg.append_ebb_param(entry, arg.value_type);
    }
}

/// Legalize the results returned from a call instruction to match the ABI signature.
///
/// The cursor `pos` points to a call instruction with at least one return value. The cursor will
/// be left pointing after the instructions inserted to convert the return values.
///
/// This function is very similar to the `legalize_entry_params` function above.
///
/// Returns the possibly new instruction representing the call.
fn legalize_inst_results<ResType>(pos: &mut FuncCursor, mut get_abi_type: ResType) -> Inst
where
    ResType: FnMut(&Function, usize) -> AbiParam,
{
    let call = pos.current_inst()
        .expect("Cursor must point to a call instruction");

    // We theoretically allow for call instructions that return a number of fixed results before
    // the call return values. In practice, it doesn't happen.
    let fixed_results = pos.func.dfg[call].opcode().constraints().fixed_results();
    debug_assert_eq!(fixed_results, 0, "Fixed results on calls not supported");

    let results = pos.func.dfg.detach_results(call);
    let mut next_res = 0;
    let mut abi_res = 0;

    // Point immediately after the call.
    pos.next_inst();

    while let Some(res) = results.get(next_res, &pos.func.dfg.value_lists) {
        next_res += 1;

        let res_type = pos.func.dfg.value_type(res);
        if res_type == get_abi_type(pos.func, abi_res).value_type {
            // No value translation is necessary, this result matches the ABI type.
            pos.func.dfg.attach_result(call, res);
            abi_res += 1;
        } else {
            let mut get_res = |func: &mut Function, ty| {
                let abi_type = get_abi_type(func, abi_res);
                if ty == abi_type.value_type {
                    let last_res = func.dfg.append_result(call, ty);
                    abi_res += 1;
                    Ok(last_res)
                } else {
                    Err(abi_type)
                }
            };
            let v = convert_from_abi(pos, res_type, Some(res), &mut get_res);
            debug_assert_eq!(pos.func.dfg.resolve_aliases(res), v);
        }
    }

    call
}

/// Compute original value of type `ty` from the legalized ABI arguments.
///
/// The conversion is recursive, controlled by the `get_arg` closure which is called to retrieve an
/// ABI argument. It returns:
///
/// - `Ok(arg)` if the requested type matches the next ABI argument.
/// - `Err(arg_type)` if further conversions are needed from the ABI argument `arg_type`.
///
/// If the `into_result` value is provided, the converted result will be written into that value.
fn convert_from_abi<GetArg>(
    pos: &mut FuncCursor,
    ty: Type,
    into_result: Option<Value>,
    get_arg: &mut GetArg,
) -> Value
where
    GetArg: FnMut(&mut Function, Type) -> Result<Value, AbiParam>,
{
    // Terminate the recursion when we get the desired type.
    let arg_type = match get_arg(pos.func, ty) {
        Ok(v) => {
            debug_assert_eq!(pos.func.dfg.value_type(v), ty);
            debug_assert_eq!(into_result, None);
            return v;
        }
        Err(t) => t,
    };

    // Reconstruct how `ty` was legalized into the `arg_type` argument.
    let conversion = legalize_abi_value(ty, &arg_type);

    dbg!("convert_from_abi({}): {:?}", ty, conversion);

    // The conversion describes value to ABI argument. We implement the reverse conversion here.
    match conversion {
        // Construct a `ty` by concatenating two ABI integers.
        ValueConversion::IntSplit => {
            let abi_ty = ty.half_width().expect("Invalid type for conversion");
            let lo = convert_from_abi(pos, abi_ty, None, get_arg);
            let hi = convert_from_abi(pos, abi_ty, None, get_arg);
            dbg!(
                "intsplit {}: {}, {}: {}",
                lo,
                pos.func.dfg.value_type(lo),
                hi,
                pos.func.dfg.value_type(hi)
            );
            pos.ins().with_results([into_result]).iconcat(lo, hi)
        }
        // Construct a `ty` by concatenating two halves of a vector.
        ValueConversion::VectorSplit => {
            let abi_ty = ty.half_vector().expect("Invalid type for conversion");
            let lo = convert_from_abi(pos, abi_ty, None, get_arg);
            let hi = convert_from_abi(pos, abi_ty, None, get_arg);
            pos.ins().with_results([into_result]).vconcat(lo, hi)
        }
        // Construct a `ty` by bit-casting from an integer type.
        ValueConversion::IntBits => {
            debug_assert!(!ty.is_int());
            let abi_ty = Type::int(ty.bits()).expect("Invalid type for conversion");
            let arg = convert_from_abi(pos, abi_ty, None, get_arg);
            pos.ins().with_results([into_result]).bitcast(ty, arg)
        }
        // ABI argument is a sign-extended version of the value we want.
        ValueConversion::Sext(abi_ty) => {
            let arg = convert_from_abi(pos, abi_ty, None, get_arg);
            // TODO: Currently, we don't take advantage of the ABI argument being sign-extended.
            // We could insert an `assert_sreduce` which would fold with a following `sextend` of
            // this value.
            pos.ins().with_results([into_result]).ireduce(ty, arg)
        }
        ValueConversion::Uext(abi_ty) => {
            let arg = convert_from_abi(pos, abi_ty, None, get_arg);
            // TODO: Currently, we don't take advantage of the ABI argument being sign-extended.
            // We could insert an `assert_ureduce` which would fold with a following `uextend` of
            // this value.
            pos.ins().with_results([into_result]).ireduce(ty, arg)
        }
    }
}

/// Convert `value` to match an ABI signature by inserting instructions at `pos`.
///
/// This may require expanding the value to multiple ABI arguments. The conversion process is
/// recursive and controlled by the `put_arg` closure. When a candidate argument value is presented
/// to the closure, it will perform one of two actions:
///
/// 1. If the suggested argument has an acceptable value type, consume it by adding it to the list
///    of arguments and return `Ok(())`.
/// 2. If the suggested argument doesn't have the right value type, don't change anything, but
///    return the `Err(AbiParam)` that is needed.
///
fn convert_to_abi<PutArg>(
    pos: &mut FuncCursor,
    cfg: &ControlFlowGraph,
    value: Value,
    put_arg: &mut PutArg,
) where
    PutArg: FnMut(&mut Function, Value) -> Result<(), AbiParam>,
{
    // Start by invoking the closure to either terminate the recursion or get the argument type
    // we're trying to match.
    let arg_type = match put_arg(pos.func, value) {
        Ok(_) => return,
        Err(t) => t,
    };

    let ty = pos.func.dfg.value_type(value);
    match legalize_abi_value(ty, &arg_type) {
        ValueConversion::IntSplit => {
            let curpos = pos.position();
            let srcloc = pos.srcloc();
            let (lo, hi) = isplit(&mut pos.func, cfg, curpos, srcloc, value);
            convert_to_abi(pos, cfg, lo, put_arg);
            convert_to_abi(pos, cfg, hi, put_arg);
        }
        ValueConversion::VectorSplit => {
            let curpos = pos.position();
            let srcloc = pos.srcloc();
            let (lo, hi) = vsplit(&mut pos.func, cfg, curpos, srcloc, value);
            convert_to_abi(pos, cfg, lo, put_arg);
            convert_to_abi(pos, cfg, hi, put_arg);
        }
        ValueConversion::IntBits => {
            debug_assert!(!ty.is_int());
            let abi_ty = Type::int(ty.bits()).expect("Invalid type for conversion");
            let arg = pos.ins().bitcast(abi_ty, value);
            convert_to_abi(pos, cfg, arg, put_arg);
        }
        ValueConversion::Sext(abi_ty) => {
            let arg = pos.ins().sextend(abi_ty, value);
            convert_to_abi(pos, cfg, arg, put_arg);
        }
        ValueConversion::Uext(abi_ty) => {
            let arg = pos.ins().uextend(abi_ty, value);
            convert_to_abi(pos, cfg, arg, put_arg);
        }
    }
}

/// Check if a sequence of arguments match a desired sequence of argument types.
fn check_arg_types(dfg: &DataFlowGraph, args: &[Value], types: &[AbiParam]) -> bool {
    let arg_types = args.iter().map(|&v| dfg.value_type(v));
    let sig_types = types.iter().map(|&at| at.value_type);
    arg_types.eq(sig_types)
}

/// Check if the arguments of the call `inst` match the signature.
///
/// Returns `Ok(())` if the signature matches and no changes are needed, or `Err(sig_ref)` if the
/// signature doesn't match.
fn check_call_signature(dfg: &DataFlowGraph, inst: Inst) -> Result<(), SigRef> {
    // Extract the signature and argument values.
    let (sig_ref, args) = match dfg[inst].analyze_call(&dfg.value_lists) {
        CallInfo::Direct(func, args) => (dfg.ext_funcs[func].signature, args),
        CallInfo::Indirect(sig_ref, args) => (sig_ref, args),
        CallInfo::NotACall => panic!("Expected call, got {:?}", dfg[inst]),
    };
    let sig = &dfg.signatures[sig_ref];

    if check_arg_types(dfg, args, &sig.params[..])
        && check_arg_types(dfg, dfg.inst_results(inst), &sig.returns[..])
    {
        // All types check out.
        Ok(())
    } else {
        // Call types need fixing.
        Err(sig_ref)
    }
}

/// Check if the arguments of the return `inst` match the signature.
fn check_return_signature(dfg: &DataFlowGraph, inst: Inst, sig: &Signature) -> bool {
    check_arg_types(dfg, dfg.inst_variable_args(inst), &sig.returns)
}

/// Insert ABI conversion code for the arguments to the call or return instruction at `pos`.
///
/// - `abi_args` is the number of arguments that the ABI signature requires.
/// - `get_abi_type` is a closure that can provide the desired `AbiParam` for a given ABI
///   argument number in `0..abi_args`.
///
fn legalize_inst_arguments<ArgType>(
    pos: &mut FuncCursor,
    cfg: &ControlFlowGraph,
    abi_args: usize,
    mut get_abi_type: ArgType,
) where
    ArgType: FnMut(&Function, usize) -> AbiParam,
{
    let inst = pos.current_inst()
        .expect("Cursor must point to a call instruction");

    // Lift the value list out of the call instruction so we modify it.
    let mut vlist = pos.func.dfg[inst]
        .take_value_list()
        .expect("Call must have a value list");

    // The value list contains all arguments to the instruction, including the callee on an
    // indirect call which isn't part of the call arguments that must match the ABI signature.
    // Figure out how many fixed values are at the front of the list. We won't touch those.
    let fixed_values = pos.func.dfg[inst]
        .opcode()
        .constraints()
        .fixed_value_arguments();
    let have_args = vlist.len(&pos.func.dfg.value_lists) - fixed_values;

    // Grow the value list to the right size and shift all the existing arguments to the right.
    // This lets us write the new argument values into the list without overwriting the old
    // arguments.
    //
    // Before:
    //
    //    <-->              fixed_values
    //        <-----------> have_args
    //   [FFFFOOOOOOOOOOOOO]
    //
    // After grow_at():
    //
    //    <-->                     fixed_values
    //               <-----------> have_args
    //        <------------------> abi_args
    //   [FFFF-------OOOOOOOOOOOOO]
    //               ^
    //               old_arg_offset
    //
    // After writing the new arguments:
    //
    //    <-->                     fixed_values
    //        <------------------> abi_args
    //   [FFFFNNNNNNNNNNNNNNNNNNNN]
    //
    vlist.grow_at(
        fixed_values,
        abi_args - have_args,
        &mut pos.func.dfg.value_lists,
    );
    let old_arg_offset = fixed_values + abi_args - have_args;

    let mut abi_arg = 0;
    for old_arg in 0..have_args {
        let old_value = vlist
            .get(old_arg_offset + old_arg, &pos.func.dfg.value_lists)
            .unwrap();
        let mut put_arg = |func: &mut Function, arg| {
            let abi_type = get_abi_type(func, abi_arg);
            if func.dfg.value_type(arg) == abi_type.value_type {
                // This is the argument type we need.
                vlist.as_mut_slice(&mut func.dfg.value_lists)[fixed_values + abi_arg] = arg;
                abi_arg += 1;
                Ok(())
            } else {
                Err(abi_type)
            }
        };
        convert_to_abi(pos, cfg, old_value, &mut put_arg);
    }

    // Put the modified value list back.
    pos.func.dfg[inst].put_value_list(vlist);
}

/// Insert ABI conversion code before and after the call instruction at `pos`.
///
/// Instructions inserted before the call will compute the appropriate ABI values for the
/// callee's new ABI-legalized signature. The function call arguments are rewritten in place to
/// match the new signature.
///
/// Instructions will be inserted after the call to convert returned ABI values back to the
/// original return values. The call's result values will be adapted to match the new signature.
///
/// Returns `true` if any instructions were inserted.
pub fn handle_call_abi(mut inst: Inst, func: &mut Function, cfg: &ControlFlowGraph) -> bool {
    let pos = &mut FuncCursor::new(func).at_inst(inst);
    pos.use_srcloc(inst);

    // Start by checking if the argument types already match the signature.
    let sig_ref = match check_call_signature(&pos.func.dfg, inst) {
        Ok(_) => return spill_call_arguments(pos),
        Err(s) => s,
    };

    // OK, we need to fix the call arguments to match the ABI signature.
    let abi_args = pos.func.dfg.signatures[sig_ref].params.len();
    legalize_inst_arguments(pos, cfg, abi_args, |func, abi_arg| {
        func.dfg.signatures[sig_ref].params[abi_arg]
    });

    if !pos.func.dfg.signatures[sig_ref].returns.is_empty() {
        inst = legalize_inst_results(pos, |func, abi_res| {
            func.dfg.signatures[sig_ref].returns[abi_res]
        });
    }

    debug_assert!(
        check_call_signature(&pos.func.dfg, inst).is_ok(),
        "Signature still wrong: {}, {}{}",
        pos.func.dfg.display_inst(inst, None),
        sig_ref,
        pos.func.dfg.signatures[sig_ref]
    );

    // Go back and insert spills for any stack arguments.
    pos.goto_inst(inst);
    spill_call_arguments(pos);

    // Yes, we changed stuff.
    true
}

/// Insert ABI conversion code before and after the return instruction at `inst`.
///
/// Return `true` if any instructions were inserted.
pub fn handle_return_abi(inst: Inst, func: &mut Function, cfg: &ControlFlowGraph) -> bool {
    // Check if the returned types already match the signature.
    if check_return_signature(&func.dfg, inst, &func.signature) {
        return false;
    }

    // Count the special-purpose return values (`link`, `sret`, and `vmctx`) that were appended to
    // the legalized signature.
    let special_args = func.signature
        .returns
        .iter()
        .rev()
        .take_while(|&rt| {
            rt.purpose == ArgumentPurpose::Link
                || rt.purpose == ArgumentPurpose::StructReturn
                || rt.purpose == ArgumentPurpose::VMContext
        })
        .count();
    let abi_args = func.signature.returns.len() - special_args;

    let pos = &mut FuncCursor::new(func).at_inst(inst);
    pos.use_srcloc(inst);

    legalize_inst_arguments(pos, cfg, abi_args, |func, abi_arg| {
        func.signature.returns[abi_arg]
    });
    debug_assert_eq!(pos.func.dfg.inst_variable_args(inst).len(), abi_args);

    // Append special return arguments for any `sret`, `link`, and `vmctx` return values added to
    // the legalized signature. These values should simply be propagated from the entry block
    // arguments.
    if special_args > 0 {
        dbg!(
            "Adding {} special-purpose arguments to {}",
            special_args,
            pos.func.dfg.display_inst(inst, None)
        );
        let mut vlist = pos.func.dfg[inst].take_value_list().unwrap();
        for arg in &pos.func.signature.returns[abi_args..] {
            match arg.purpose {
                ArgumentPurpose::Link
                | ArgumentPurpose::StructReturn
                | ArgumentPurpose::VMContext => {}
                ArgumentPurpose::Normal => panic!("unexpected return value {}", arg),
                _ => panic!("Unsupported special purpose return value {}", arg),
            }
            // A `link`/`sret`/`vmctx` return value can only appear in a signature that has a
            // unique matching argument. They are appended at the end, so search the signature from
            // the end.
            let idx = pos.func
                .signature
                .params
                .iter()
                .rposition(|t| t.purpose == arg.purpose)
                .expect("No matching special purpose argument.");
            // Get the corresponding entry block value and add it to the return instruction's
            // arguments.
            let val = pos.func
                .dfg
                .ebb_params(pos.func.layout.entry_block().unwrap())[idx];
            debug_assert_eq!(pos.func.dfg.value_type(val), arg.value_type);
            vlist.push(val, &mut pos.func.dfg.value_lists);
        }
        pos.func.dfg[inst].put_value_list(vlist);
    }

    debug_assert!(
        check_return_signature(&pos.func.dfg, inst, &pos.func.signature),
        "Signature still wrong: {} / signature {}",
        pos.func.dfg.display_inst(inst, None),
        pos.func.signature
    );

    // Yes, we changed stuff.
    true
}

/// Assign stack slots to incoming function parameters on the stack.
///
/// Values that are passed into the function on the stack must be assigned to an `IncomingArg`
/// stack slot already during legalization.
fn spill_entry_params(func: &mut Function, entry: Ebb) {
    for (abi, &arg) in func.signature.params.iter().zip(func.dfg.ebb_params(entry)) {
        if let ArgumentLoc::Stack(offset) = abi.location {
            let ss = func.stack_slots.make_incoming_arg(abi.value_type, offset);
            func.locations[arg] = ValueLoc::Stack(ss);
        }
    }
}

/// Assign stack slots to outgoing function arguments on the stack.
///
/// Values that are passed to a called function on the stack must be assigned to a matching
/// `OutgoingArg` stack slot. The assignment must happen immediately before the call.
///
/// TODO: The outgoing stack slots can be written a bit earlier, as long as there are no branches
/// or calls between writing the stack slots and the call instruction. Writing the slots earlier
/// could help reduce register pressure before the call.
fn spill_call_arguments(pos: &mut FuncCursor) -> bool {
    let inst = pos.current_inst()
        .expect("Cursor must point to a call instruction");
    let sig_ref = pos.func
        .dfg
        .call_signature(inst)
        .expect("Call instruction expected.");

    // Start by building a list of stack slots and arguments to be replaced.
    // This requires borrowing `pos.func.dfg`, so we can't change anything.
    let arglist = {
        let locations = &pos.func.locations;
        let stack_slots = &mut pos.func.stack_slots;
        pos.func
            .dfg
            .inst_variable_args(inst)
            .iter()
            .zip(&pos.func.dfg.signatures[sig_ref].params)
            .enumerate()
            .filter_map(|(idx, (&arg, abi))| {
                match abi.location {
                    ArgumentLoc::Stack(offset) => {
                        // Assign `arg` to a new stack slot, unless it's already in the correct
                        // slot. The legalization needs to be idempotent, so we should see a
                        // correct outgoing slot on the second pass.
                        let ss = stack_slots.get_outgoing_arg(abi.value_type, offset);
                        if locations[arg] != ValueLoc::Stack(ss) {
                            Some((idx, arg, ss))
                        } else {
                            None
                        }
                    }
                    _ => None,
                }
            })
            .collect::<Vec<_>>()
    };

    if arglist.is_empty() {
        return false;
    }

    // Insert the spill instructions and rewrite call arguments.
    for (idx, arg, ss) in arglist {
        let stack_val = pos.ins().spill(arg);
        pos.func.locations[stack_val] = ValueLoc::Stack(ss);
        pos.func.dfg.inst_variable_args_mut(inst)[idx] = stack_val;
    }

    // We changed stuff.
    true
}