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//! External function calls.
//!
//! To a Cranelift function, all functions are "external". Directly called functions must be
//! declared in the preamble, and all function calls must have a signature.
//!
//! This module declares the data types used to represent external functions and call signatures.
use crate::ir::{ExternalName, SigRef, Type};
use crate::isa::CallConv;
use alloc::vec::Vec;
use core::fmt;
use core::str::FromStr;
#[cfg(feature = "enable-serde")]
use serde::{Deserialize, Serialize};
use super::function::FunctionParameters;
/// Function signature.
///
/// The function signature describes the types of formal parameters and return values along with
/// other details that are needed to call a function correctly.
///
/// A signature can optionally include ISA-specific ABI information which specifies exactly how
/// arguments and return values are passed.
#[derive(Clone, Debug, PartialEq, Eq, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct Signature {
/// The arguments passed to the function.
pub params: Vec<AbiParam>,
/// Values returned from the function.
pub returns: Vec<AbiParam>,
/// Calling convention.
pub call_conv: CallConv,
}
impl Signature {
/// Create a new blank signature.
pub fn new(call_conv: CallConv) -> Self {
Self {
params: Vec::new(),
returns: Vec::new(),
call_conv,
}
}
/// Clear the signature so it is identical to a fresh one returned by `new()`.
pub fn clear(&mut self, call_conv: CallConv) {
self.params.clear();
self.returns.clear();
self.call_conv = call_conv;
}
/// Find the index of a presumed unique special-purpose parameter.
pub fn special_param_index(&self, purpose: ArgumentPurpose) -> Option<usize> {
self.params.iter().rposition(|arg| arg.purpose == purpose)
}
/// Find the index of a presumed unique special-purpose parameter.
pub fn special_return_index(&self, purpose: ArgumentPurpose) -> Option<usize> {
self.returns.iter().rposition(|arg| arg.purpose == purpose)
}
/// Does this signature have a parameter whose `ArgumentPurpose` is
/// `purpose`?
pub fn uses_special_param(&self, purpose: ArgumentPurpose) -> bool {
self.special_param_index(purpose).is_some()
}
/// Does this signature have a return whose `ArgumentPurpose` is `purpose`?
pub fn uses_special_return(&self, purpose: ArgumentPurpose) -> bool {
self.special_return_index(purpose).is_some()
}
/// How many special parameters does this function have?
pub fn num_special_params(&self) -> usize {
self.params
.iter()
.filter(|p| p.purpose != ArgumentPurpose::Normal)
.count()
}
/// How many special returns does this function have?
pub fn num_special_returns(&self) -> usize {
self.returns
.iter()
.filter(|r| r.purpose != ArgumentPurpose::Normal)
.count()
}
/// Does this signature take an struct return pointer parameter?
pub fn uses_struct_return_param(&self) -> bool {
self.uses_special_param(ArgumentPurpose::StructReturn)
}
/// Does this return more than one normal value? (Pre-struct return
/// legalization)
pub fn is_multi_return(&self) -> bool {
self.returns
.iter()
.filter(|r| r.purpose == ArgumentPurpose::Normal)
.count()
> 1
}
}
fn write_list(f: &mut fmt::Formatter, args: &[AbiParam]) -> fmt::Result {
match args.split_first() {
None => {}
Some((first, rest)) => {
write!(f, "{}", first)?;
for arg in rest {
write!(f, ", {}", arg)?;
}
}
}
Ok(())
}
impl fmt::Display for Signature {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "(")?;
write_list(f, &self.params)?;
write!(f, ")")?;
if !self.returns.is_empty() {
write!(f, " -> ")?;
write_list(f, &self.returns)?;
}
write!(f, " {}", self.call_conv)
}
}
/// Function parameter or return value descriptor.
///
/// This describes the value type being passed to or from a function along with flags that affect
/// how the argument is passed.
#[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct AbiParam {
/// Type of the argument value.
pub value_type: Type,
/// Special purpose of argument, or `Normal`.
pub purpose: ArgumentPurpose,
/// Method for extending argument to a full register.
pub extension: ArgumentExtension,
}
impl AbiParam {
/// Create a parameter with default flags.
pub fn new(vt: Type) -> Self {
Self {
value_type: vt,
extension: ArgumentExtension::None,
purpose: ArgumentPurpose::Normal,
}
}
/// Create a special-purpose parameter that is not (yet) bound to a specific register.
pub fn special(vt: Type, purpose: ArgumentPurpose) -> Self {
Self {
value_type: vt,
extension: ArgumentExtension::None,
purpose,
}
}
/// Convert `self` to a parameter with the `uext` flag set.
pub fn uext(self) -> Self {
debug_assert!(self.value_type.is_int(), "uext on {} arg", self.value_type);
Self {
extension: ArgumentExtension::Uext,
..self
}
}
/// Convert `self` to a parameter type with the `sext` flag set.
pub fn sext(self) -> Self {
debug_assert!(self.value_type.is_int(), "sext on {} arg", self.value_type);
Self {
extension: ArgumentExtension::Sext,
..self
}
}
}
impl fmt::Display for AbiParam {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{}", self.value_type)?;
match self.extension {
ArgumentExtension::None => {}
ArgumentExtension::Uext => write!(f, " uext")?,
ArgumentExtension::Sext => write!(f, " sext")?,
}
if self.purpose != ArgumentPurpose::Normal {
write!(f, " {}", self.purpose)?;
}
Ok(())
}
}
/// Function argument extension options.
///
/// On some architectures, small integer function arguments and/or return values are extended to
/// the width of a general-purpose register.
///
/// This attribute specifies how an argument or return value should be extended *if the platform
/// and ABI require it*. Because the frontend (CLIF generator) does not know anything about the
/// particulars of the target's ABI, and the CLIF should be platform-independent, these attributes
/// specify *how* to extend (according to the signedness of the original program) rather than
/// *whether* to extend.
#[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub enum ArgumentExtension {
/// No extension, high bits are indeterminate.
None,
/// Unsigned extension: high bits in register are 0.
Uext,
/// Signed extension: high bits in register replicate sign bit.
Sext,
}
/// The special purpose of a function argument.
///
/// Function arguments and return values are used to pass user program values between functions,
/// but they are also used to represent special registers with significance to the ABI such as
/// frame pointers and callee-saved registers.
///
/// The argument purpose is used to indicate any special meaning of an argument or return value.
#[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub enum ArgumentPurpose {
/// A normal user program value passed to or from a function.
Normal,
/// A C struct passed as argument.
StructArgument(u32),
/// Struct return pointer.
///
/// When a function needs to return more data than will fit in registers, the caller passes a
/// pointer to a memory location where the return value can be written. In some ABIs, this
/// struct return pointer is passed in a specific register.
///
/// This argument kind can also appear as a return value for ABIs that require a function with
/// a `StructReturn` pointer argument to also return that pointer in a register.
StructReturn,
/// A VM context pointer.
///
/// This is a pointer to a context struct containing details about the current sandbox. It is
/// used as a base pointer for `vmctx` global values.
VMContext,
/// A stack limit pointer.
///
/// This is a pointer to a stack limit. It is used to check the current stack pointer
/// against. Can only appear once in a signature.
StackLimit,
}
impl fmt::Display for ArgumentPurpose {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str(match self {
Self::Normal => "normal",
Self::StructArgument(size) => return write!(f, "sarg({})", size),
Self::StructReturn => "sret",
Self::VMContext => "vmctx",
Self::StackLimit => "stack_limit",
})
}
}
impl FromStr for ArgumentPurpose {
type Err = ();
fn from_str(s: &str) -> Result<Self, ()> {
match s {
"normal" => Ok(Self::Normal),
"sret" => Ok(Self::StructReturn),
"vmctx" => Ok(Self::VMContext),
"stack_limit" => Ok(Self::StackLimit),
_ if s.starts_with("sarg(") => {
if !s.ends_with(")") {
return Err(());
}
// Parse 'sarg(size)'
let size: u32 = s["sarg(".len()..s.len() - 1].parse().map_err(|_| ())?;
Ok(Self::StructArgument(size))
}
_ => Err(()),
}
}
}
/// An external function.
///
/// Information about a function that can be called directly with a direct `call` instruction.
#[derive(Clone, Debug, PartialEq, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct ExtFuncData {
/// Name of the external function.
pub name: ExternalName,
/// Call signature of function.
pub signature: SigRef,
/// Will this function be defined nearby, such that it will always be a certain distance away,
/// after linking? If so, references to it can avoid going through a GOT or PLT. Note that
/// symbols meant to be preemptible cannot be considered colocated.
///
/// If `true`, some backends may use relocation forms that have limited range. The exact
/// distance depends on the code model in use. Currently on AArch64, for example, Cranelift
/// uses a custom code model supporting up to +/- 128MB displacements. If it is unknown how
/// far away the target will be, it is best not to set the `colocated` flag; in general, this
/// flag is best used when the target is known to be in the same unit of code generation, such
/// as a Wasm module.
///
/// See the documentation for `RelocDistance` for more details. A `colocated` flag value of
/// `true` implies `RelocDistance::Near`.
pub colocated: bool,
}
impl ExtFuncData {
/// Returns a displayable version of the `ExtFuncData`, with or without extra context to
/// prettify the output.
pub fn display<'a>(
&'a self,
params: Option<&'a FunctionParameters>,
) -> DisplayableExtFuncData<'a> {
DisplayableExtFuncData {
ext_func: self,
params,
}
}
}
/// A displayable `ExtFuncData`, with extra context to prettify the output.
pub struct DisplayableExtFuncData<'a> {
ext_func: &'a ExtFuncData,
params: Option<&'a FunctionParameters>,
}
impl<'a> fmt::Display for DisplayableExtFuncData<'a> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
if self.ext_func.colocated {
write!(f, "colocated ")?;
}
write!(
f,
"{} {}",
self.ext_func.name.display(self.params),
self.ext_func.signature
)
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::ir::types::{F32, I32, I8};
use alloc::string::ToString;
#[test]
fn argument_type() {
let t = AbiParam::new(I32);
assert_eq!(t.to_string(), "i32");
let mut t = t.uext();
assert_eq!(t.to_string(), "i32 uext");
assert_eq!(t.sext().to_string(), "i32 sext");
t.purpose = ArgumentPurpose::StructReturn;
assert_eq!(t.to_string(), "i32 uext sret");
}
#[test]
fn argument_purpose() {
let all_purpose = [
(ArgumentPurpose::Normal, "normal"),
(ArgumentPurpose::StructReturn, "sret"),
(ArgumentPurpose::VMContext, "vmctx"),
(ArgumentPurpose::StackLimit, "stack_limit"),
(ArgumentPurpose::StructArgument(42), "sarg(42)"),
];
for &(e, n) in &all_purpose {
assert_eq!(e.to_string(), n);
assert_eq!(Ok(e), n.parse());
}
}
#[test]
fn call_conv() {
for &cc in &[
CallConv::Fast,
CallConv::Cold,
CallConv::SystemV,
CallConv::WindowsFastcall,
] {
assert_eq!(Ok(cc), cc.to_string().parse())
}
}
#[test]
fn signatures() {
let mut sig = Signature::new(CallConv::WindowsFastcall);
assert_eq!(sig.to_string(), "() windows_fastcall");
sig.params.push(AbiParam::new(I32));
assert_eq!(sig.to_string(), "(i32) windows_fastcall");
sig.returns.push(AbiParam::new(F32));
assert_eq!(sig.to_string(), "(i32) -> f32 windows_fastcall");
sig.params.push(AbiParam::new(I32.by(4).unwrap()));
assert_eq!(sig.to_string(), "(i32, i32x4) -> f32 windows_fastcall");
sig.returns.push(AbiParam::new(I8));
assert_eq!(sig.to_string(), "(i32, i32x4) -> f32, i8 windows_fastcall");
}
}