cranelift_codegen/ir/instructions.rs
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//! Instruction formats and opcodes.
//!
//! The `instructions` module contains definitions for instruction formats, opcodes, and the
//! in-memory representation of IR instructions.
//!
//! A large part of this module is auto-generated from the instruction descriptions in the meta
//! directory.
use crate::constant_hash::Table;
use alloc::vec::Vec;
use core::fmt::{self, Display, Formatter};
use core::ops::{Deref, DerefMut};
use core::str::FromStr;
#[cfg(feature = "enable-serde")]
use serde_derive::{Deserialize, Serialize};
use crate::bitset::ScalarBitSet;
use crate::entity;
use crate::ir::{
self,
condcodes::{FloatCC, IntCC},
trapcode::TrapCode,
types, Block, FuncRef, MemFlags, SigRef, StackSlot, Type, Value,
};
/// Some instructions use an external list of argument values because there is not enough space in
/// the 16-byte `InstructionData` struct. These value lists are stored in a memory pool in
/// `dfg.value_lists`.
pub type ValueList = entity::EntityList<Value>;
/// Memory pool for holding value lists. See `ValueList`.
pub type ValueListPool = entity::ListPool<Value>;
/// A pair of a Block and its arguments, stored in a single EntityList internally.
///
/// NOTE: We don't expose either value_to_block or block_to_value outside of this module because
/// this operation is not generally safe. However, as the two share the same underlying layout,
/// they can be stored in the same value pool.
///
/// BlockCall makes use of this shared layout by storing all of its contents (a block and its
/// argument) in a single EntityList. This is a bit better than introducing a new entity type for
/// the pair of a block name and the arguments entity list, as we don't pay any indirection penalty
/// to get to the argument values -- they're stored in-line with the block in the same list.
///
/// The BlockCall::new function guarantees this layout by requiring a block argument that's written
/// in as the first element of the EntityList. Any subsequent entries are always assumed to be real
/// Values.
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct BlockCall {
/// The underlying storage for the BlockCall. The first element of the values EntityList is
/// guaranteed to always be a Block encoded as a Value via BlockCall::block_to_value.
/// Consequently, the values entity list is never empty.
values: entity::EntityList<Value>,
}
impl BlockCall {
// NOTE: the only uses of this function should be internal to BlockCall. See the block comment
// on BlockCall for more context.
fn value_to_block(val: Value) -> Block {
Block::from_u32(val.as_u32())
}
// NOTE: the only uses of this function should be internal to BlockCall. See the block comment
// on BlockCall for more context.
fn block_to_value(block: Block) -> Value {
Value::from_u32(block.as_u32())
}
/// Construct a BlockCall with the given block and arguments.
pub fn new(block: Block, args: &[Value], pool: &mut ValueListPool) -> Self {
let mut values = ValueList::default();
values.push(Self::block_to_value(block), pool);
values.extend(args.iter().copied(), pool);
Self { values }
}
/// Return the block for this BlockCall.
pub fn block(&self, pool: &ValueListPool) -> Block {
let val = self.values.first(pool).unwrap();
Self::value_to_block(val)
}
/// Replace the block for this BlockCall.
pub fn set_block(&mut self, block: Block, pool: &mut ValueListPool) {
*self.values.get_mut(0, pool).unwrap() = Self::block_to_value(block);
}
/// Append an argument to the block args.
pub fn append_argument(&mut self, arg: Value, pool: &mut ValueListPool) {
self.values.push(arg, pool);
}
/// Return a slice for the arguments of this block.
pub fn args_slice<'a>(&self, pool: &'a ValueListPool) -> &'a [Value] {
&self.values.as_slice(pool)[1..]
}
/// Return a slice for the arguments of this block.
pub fn args_slice_mut<'a>(&'a mut self, pool: &'a mut ValueListPool) -> &'a mut [Value] {
&mut self.values.as_mut_slice(pool)[1..]
}
/// Remove the argument at ix from the argument list.
pub fn remove(&mut self, ix: usize, pool: &mut ValueListPool) {
self.values.remove(1 + ix, pool)
}
/// Clear out the arguments list.
pub fn clear(&mut self, pool: &mut ValueListPool) {
self.values.truncate(1, pool)
}
/// Appends multiple elements to the arguments.
pub fn extend<I>(&mut self, elements: I, pool: &mut ValueListPool)
where
I: IntoIterator<Item = Value>,
{
self.values.extend(elements, pool)
}
/// Return a value that can display this block call.
pub fn display<'a>(&self, pool: &'a ValueListPool) -> DisplayBlockCall<'a> {
DisplayBlockCall { block: *self, pool }
}
/// Deep-clone the underlying list in the same pool. The returned
/// list will have identical contents but changes to this list
/// will not change its contents or vice-versa.
pub fn deep_clone(&self, pool: &mut ValueListPool) -> Self {
Self {
values: self.values.deep_clone(pool),
}
}
}
/// Wrapper for the context needed to display a [BlockCall] value.
pub struct DisplayBlockCall<'a> {
block: BlockCall,
pool: &'a ValueListPool,
}
impl<'a> Display for DisplayBlockCall<'a> {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
write!(f, "{}", self.block.block(&self.pool))?;
let args = self.block.args_slice(&self.pool);
if !args.is_empty() {
write!(f, "(")?;
for (ix, arg) in args.iter().enumerate() {
if ix > 0 {
write!(f, ", ")?;
}
write!(f, "{}", arg)?;
}
write!(f, ")")?;
}
Ok(())
}
}
// Include code generated by `cranelift-codegen/meta/src/gen_inst.rs`. This file contains:
//
// - The `pub enum InstructionFormat` enum with all the instruction formats.
// - The `pub enum InstructionData` enum with all the instruction data fields.
// - The `pub enum Opcode` definition with all known opcodes,
// - The `const OPCODE_FORMAT: [InstructionFormat; N]` table.
// - The private `fn opcode_name(Opcode) -> &'static str` function, and
// - The hash table `const OPCODE_HASH_TABLE: [Opcode; N]`.
//
// For value type constraints:
//
// - The `const OPCODE_CONSTRAINTS : [OpcodeConstraints; N]` table.
// - The `const TYPE_SETS : [ValueTypeSet; N]` table.
// - The `const OPERAND_CONSTRAINTS : [OperandConstraint; N]` table.
//
include!(concat!(env!("OUT_DIR"), "/opcodes.rs"));
impl Display for Opcode {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
write!(f, "{}", opcode_name(*self))
}
}
impl Opcode {
/// Get the instruction format for this opcode.
pub fn format(self) -> InstructionFormat {
OPCODE_FORMAT[self as usize - 1]
}
/// Get the constraint descriptor for this opcode.
/// Panic if this is called on `NotAnOpcode`.
pub fn constraints(self) -> OpcodeConstraints {
OPCODE_CONSTRAINTS[self as usize - 1]
}
/// Is this instruction a GC safepoint?
///
/// Safepoints are all kinds of calls, except for tail calls.
#[inline]
pub fn is_safepoint(self) -> bool {
self.is_call() && !self.is_return()
}
}
// This trait really belongs in cranelift-reader where it is used by the `.clif` file parser, but since
// it critically depends on the `opcode_name()` function which is needed here anyway, it lives in
// this module. This also saves us from running the build script twice to generate code for the two
// separate crates.
impl FromStr for Opcode {
type Err = &'static str;
/// Parse an Opcode name from a string.
fn from_str(s: &str) -> Result<Self, &'static str> {
use crate::constant_hash::{probe, simple_hash};
match probe::<&str, [Option<Self>]>(&OPCODE_HASH_TABLE, s, simple_hash(s)) {
Err(_) => Err("Unknown opcode"),
// We unwrap here because probe() should have ensured that the entry
// at this index is not None.
Ok(i) => Ok(OPCODE_HASH_TABLE[i].unwrap()),
}
}
}
impl<'a> Table<&'a str> for [Option<Opcode>] {
fn len(&self) -> usize {
self.len()
}
fn key(&self, idx: usize) -> Option<&'a str> {
self[idx].map(opcode_name)
}
}
/// A variable list of `Value` operands used for function call arguments and passing arguments to
/// basic blocks.
#[derive(Clone, Debug)]
pub struct VariableArgs(Vec<Value>);
impl VariableArgs {
/// Create an empty argument list.
pub fn new() -> Self {
Self(Vec::new())
}
/// Add an argument to the end.
pub fn push(&mut self, v: Value) {
self.0.push(v)
}
/// Check if the list is empty.
pub fn is_empty(&self) -> bool {
self.0.is_empty()
}
/// Convert this to a value list in `pool` with `fixed` prepended.
pub fn into_value_list(self, fixed: &[Value], pool: &mut ValueListPool) -> ValueList {
let mut vlist = ValueList::default();
vlist.extend(fixed.iter().cloned(), pool);
vlist.extend(self.0, pool);
vlist
}
}
// Coerce `VariableArgs` into a `&[Value]` slice.
impl Deref for VariableArgs {
type Target = [Value];
fn deref(&self) -> &[Value] {
&self.0
}
}
impl DerefMut for VariableArgs {
fn deref_mut(&mut self) -> &mut [Value] {
&mut self.0
}
}
impl Display for VariableArgs {
fn fmt(&self, fmt: &mut Formatter) -> fmt::Result {
for (i, val) in self.0.iter().enumerate() {
if i == 0 {
write!(fmt, "{}", val)?;
} else {
write!(fmt, ", {}", val)?;
}
}
Ok(())
}
}
impl Default for VariableArgs {
fn default() -> Self {
Self::new()
}
}
/// Analyzing an instruction.
///
/// Avoid large matches on instruction formats by using the methods defined here to examine
/// instructions.
impl InstructionData {
/// Get the destinations of this instruction, if it's a branch.
///
/// `br_table` returns the empty slice.
pub fn branch_destination<'a>(&'a self, jump_tables: &'a ir::JumpTables) -> &[BlockCall] {
match self {
Self::Jump {
ref destination, ..
} => std::slice::from_ref(destination),
Self::Brif { blocks, .. } => blocks.as_slice(),
Self::BranchTable { table, .. } => jump_tables.get(*table).unwrap().all_branches(),
_ => {
debug_assert!(!self.opcode().is_branch());
&[]
}
}
}
/// Get a mutable slice of the destinations of this instruction, if it's a branch.
///
/// `br_table` returns the empty slice.
pub fn branch_destination_mut<'a>(
&'a mut self,
jump_tables: &'a mut ir::JumpTables,
) -> &mut [BlockCall] {
match self {
Self::Jump {
ref mut destination,
..
} => std::slice::from_mut(destination),
Self::Brif { blocks, .. } => blocks.as_mut_slice(),
Self::BranchTable { table, .. } => {
jump_tables.get_mut(*table).unwrap().all_branches_mut()
}
_ => {
debug_assert!(!self.opcode().is_branch());
&mut []
}
}
}
/// Replace the values used in this instruction according to the given
/// function.
pub fn map_values(
&mut self,
pool: &mut ValueListPool,
jump_tables: &mut ir::JumpTables,
mut f: impl FnMut(Value) -> Value,
) {
for arg in self.arguments_mut(pool) {
*arg = f(*arg);
}
for block in self.branch_destination_mut(jump_tables) {
for arg in block.args_slice_mut(pool) {
*arg = f(*arg);
}
}
}
/// If this is a trapping instruction, get its trap code. Otherwise, return
/// `None`.
pub fn trap_code(&self) -> Option<TrapCode> {
match *self {
Self::CondTrap { code, .. } | Self::Trap { code, .. } => Some(code),
_ => None,
}
}
/// If this is a control-flow instruction depending on an integer condition, gets its
/// condition. Otherwise, return `None`.
pub fn cond_code(&self) -> Option<IntCC> {
match self {
&InstructionData::IntCompare { cond, .. }
| &InstructionData::IntCompareImm { cond, .. } => Some(cond),
_ => None,
}
}
/// If this is a control-flow instruction depending on a floating-point condition, gets its
/// condition. Otherwise, return `None`.
pub fn fp_cond_code(&self) -> Option<FloatCC> {
match self {
&InstructionData::FloatCompare { cond, .. } => Some(cond),
_ => None,
}
}
/// If this is a trapping instruction, get an exclusive reference to its
/// trap code. Otherwise, return `None`.
pub fn trap_code_mut(&mut self) -> Option<&mut TrapCode> {
match self {
Self::CondTrap { code, .. } | Self::Trap { code, .. } => Some(code),
_ => None,
}
}
/// If this is an atomic read/modify/write instruction, return its subopcode.
pub fn atomic_rmw_op(&self) -> Option<ir::AtomicRmwOp> {
match self {
&InstructionData::AtomicRmw { op, .. } => Some(op),
_ => None,
}
}
/// If this is a load/store instruction, returns its immediate offset.
pub fn load_store_offset(&self) -> Option<i32> {
match self {
&InstructionData::Load { offset, .. }
| &InstructionData::StackLoad { offset, .. }
| &InstructionData::Store { offset, .. }
| &InstructionData::StackStore { offset, .. } => Some(offset.into()),
_ => None,
}
}
/// If this is a load/store instruction, return its memory flags.
pub fn memflags(&self) -> Option<MemFlags> {
match self {
&InstructionData::Load { flags, .. }
| &InstructionData::LoadNoOffset { flags, .. }
| &InstructionData::Store { flags, .. }
| &InstructionData::StoreNoOffset { flags, .. }
| &InstructionData::AtomicCas { flags, .. }
| &InstructionData::AtomicRmw { flags, .. } => Some(flags),
_ => None,
}
}
/// If this instruction references a stack slot, return it
pub fn stack_slot(&self) -> Option<StackSlot> {
match self {
&InstructionData::StackStore { stack_slot, .. }
| &InstructionData::StackLoad { stack_slot, .. } => Some(stack_slot),
_ => None,
}
}
/// Return information about a call instruction.
///
/// Any instruction that can call another function reveals its call signature here.
pub fn analyze_call<'a>(&'a self, pool: &'a ValueListPool) -> CallInfo<'a> {
match *self {
Self::Call {
func_ref, ref args, ..
} => CallInfo::Direct(func_ref, args.as_slice(pool)),
Self::CallIndirect {
sig_ref, ref args, ..
} => CallInfo::Indirect(sig_ref, &args.as_slice(pool)[1..]),
_ => {
debug_assert!(!self.opcode().is_call());
CallInfo::NotACall
}
}
}
#[inline]
pub(crate) fn mask_immediates(&mut self, ctrl_typevar: Type) {
if ctrl_typevar.is_invalid() {
return;
}
let bit_width = ctrl_typevar.bits();
match self {
Self::UnaryImm { opcode: _, imm } => {
*imm = imm.mask_to_width(bit_width);
}
Self::BinaryImm64 {
opcode,
arg: _,
imm,
} => {
if *opcode == Opcode::SdivImm || *opcode == Opcode::SremImm {
*imm = imm.mask_to_width(bit_width);
}
}
Self::IntCompareImm {
opcode,
arg: _,
cond,
imm,
} => {
debug_assert_eq!(*opcode, Opcode::IcmpImm);
if cond.unsigned() != *cond {
*imm = imm.mask_to_width(bit_width);
}
}
_ => {}
}
}
}
/// Information about call instructions.
pub enum CallInfo<'a> {
/// This is not a call instruction.
NotACall,
/// This is a direct call to an external function declared in the preamble. See
/// `DataFlowGraph.ext_funcs`.
Direct(FuncRef, &'a [Value]),
/// This is an indirect call with the specified signature. See `DataFlowGraph.signatures`.
Indirect(SigRef, &'a [Value]),
}
/// Value type constraints for a given opcode.
///
/// The `InstructionFormat` determines the constraints on most operands, but `Value` operands and
/// results are not determined by the format. Every `Opcode` has an associated
/// `OpcodeConstraints` object that provides the missing details.
#[derive(Clone, Copy)]
pub struct OpcodeConstraints {
/// Flags for this opcode encoded as a bit field:
///
/// Bits 0-2:
/// Number of fixed result values. This does not include `variable_args` results as are
/// produced by call instructions.
///
/// Bit 3:
/// This opcode is polymorphic and the controlling type variable can be inferred from the
/// designated input operand. This is the `typevar_operand` index given to the
/// `InstructionFormat` meta language object. When this bit is not set, the controlling
/// type variable must be the first output value instead.
///
/// Bit 4:
/// This opcode is polymorphic and the controlling type variable does *not* appear as the
/// first result type.
///
/// Bits 5-7:
/// Number of fixed value arguments. The minimum required number of value operands.
flags: u8,
/// Permitted set of types for the controlling type variable as an index into `TYPE_SETS`.
typeset_offset: u8,
/// Offset into `OPERAND_CONSTRAINT` table of the descriptors for this opcode. The first
/// `num_fixed_results()` entries describe the result constraints, then follows constraints for
/// the fixed `Value` input operands. (`num_fixed_value_arguments()` of them).
constraint_offset: u16,
}
impl OpcodeConstraints {
/// Can the controlling type variable for this opcode be inferred from the designated value
/// input operand?
/// This also implies that this opcode is polymorphic.
pub fn use_typevar_operand(self) -> bool {
(self.flags & 0x8) != 0
}
/// Is it necessary to look at the designated value input operand in order to determine the
/// controlling type variable, or is it good enough to use the first return type?
///
/// Most polymorphic instructions produce a single result with the type of the controlling type
/// variable. A few polymorphic instructions either don't produce any results, or produce
/// results with a fixed type. These instructions return `true`.
pub fn requires_typevar_operand(self) -> bool {
(self.flags & 0x10) != 0
}
/// Get the number of *fixed* result values produced by this opcode.
/// This does not include `variable_args` produced by calls.
pub fn num_fixed_results(self) -> usize {
(self.flags & 0x7) as usize
}
/// Get the number of *fixed* input values required by this opcode.
///
/// This does not include `variable_args` arguments on call and branch instructions.
///
/// The number of fixed input values is usually implied by the instruction format, but
/// instruction formats that use a `ValueList` put both fixed and variable arguments in the
/// list. This method returns the *minimum* number of values required in the value list.
pub fn num_fixed_value_arguments(self) -> usize {
((self.flags >> 5) & 0x7) as usize
}
/// Get the offset into `TYPE_SETS` for the controlling type variable.
/// Returns `None` if the instruction is not polymorphic.
fn typeset_offset(self) -> Option<usize> {
let offset = usize::from(self.typeset_offset);
if offset < TYPE_SETS.len() {
Some(offset)
} else {
None
}
}
/// Get the offset into OPERAND_CONSTRAINTS where the descriptors for this opcode begin.
fn constraint_offset(self) -> usize {
self.constraint_offset as usize
}
/// Get the value type of result number `n`, having resolved the controlling type variable to
/// `ctrl_type`.
pub fn result_type(self, n: usize, ctrl_type: Type) -> Type {
debug_assert!(n < self.num_fixed_results(), "Invalid result index");
match OPERAND_CONSTRAINTS[self.constraint_offset() + n].resolve(ctrl_type) {
ResolvedConstraint::Bound(t) => t,
ResolvedConstraint::Free(ts) => panic!("Result constraints can't be free: {:?}", ts),
}
}
/// Get the value type of input value number `n`, having resolved the controlling type variable
/// to `ctrl_type`.
///
/// Unlike results, it is possible for some input values to vary freely within a specific
/// `ValueTypeSet`. This is represented with the `ArgumentConstraint::Free` variant.
pub fn value_argument_constraint(self, n: usize, ctrl_type: Type) -> ResolvedConstraint {
debug_assert!(
n < self.num_fixed_value_arguments(),
"Invalid value argument index"
);
let offset = self.constraint_offset() + self.num_fixed_results();
OPERAND_CONSTRAINTS[offset + n].resolve(ctrl_type)
}
/// Get the typeset of allowed types for the controlling type variable in a polymorphic
/// instruction.
pub fn ctrl_typeset(self) -> Option<ValueTypeSet> {
self.typeset_offset().map(|offset| TYPE_SETS[offset])
}
/// Is this instruction polymorphic?
pub fn is_polymorphic(self) -> bool {
self.ctrl_typeset().is_some()
}
}
type BitSet8 = ScalarBitSet<u8>;
type BitSet16 = ScalarBitSet<u16>;
/// A value type set describes the permitted set of types for a type variable.
#[derive(Clone, Copy, Debug, Default, PartialEq, Eq)]
pub struct ValueTypeSet {
/// Allowed lane sizes
pub lanes: BitSet16,
/// Allowed int widths
pub ints: BitSet8,
/// Allowed float widths
pub floats: BitSet8,
/// Allowed ref widths
pub refs: BitSet8,
/// Allowed dynamic vectors minimum lane sizes
pub dynamic_lanes: BitSet16,
}
impl ValueTypeSet {
/// Is `scalar` part of the base type set?
///
/// Note that the base type set does not have to be included in the type set proper.
fn is_base_type(self, scalar: Type) -> bool {
let l2b = u8::try_from(scalar.log2_lane_bits()).unwrap();
if scalar.is_int() {
self.ints.contains(l2b)
} else if scalar.is_float() {
self.floats.contains(l2b)
} else if scalar.is_ref() {
self.refs.contains(l2b)
} else {
false
}
}
/// Does `typ` belong to this set?
pub fn contains(self, typ: Type) -> bool {
if typ.is_dynamic_vector() {
let l2l = u8::try_from(typ.log2_min_lane_count()).unwrap();
self.dynamic_lanes.contains(l2l) && self.is_base_type(typ.lane_type())
} else {
let l2l = u8::try_from(typ.log2_lane_count()).unwrap();
self.lanes.contains(l2l) && self.is_base_type(typ.lane_type())
}
}
/// Get an example member of this type set.
///
/// This is used for error messages to avoid suggesting invalid types.
pub fn example(self) -> Type {
let t = if self.ints.max().unwrap_or(0) > 5 {
types::I32
} else if self.floats.max().unwrap_or(0) > 5 {
types::F32
} else {
types::I8
};
t.by(1 << self.lanes.min().unwrap()).unwrap()
}
}
/// Operand constraints. This describes the value type constraints on a single `Value` operand.
enum OperandConstraint {
/// This operand has a concrete value type.
Concrete(Type),
/// This operand can vary freely within the given type set.
/// The type set is identified by its index into the TYPE_SETS constant table.
Free(u8),
/// This operand is the same type as the controlling type variable.
Same,
/// This operand is `ctrlType.lane_of()`.
LaneOf,
/// This operand is `ctrlType.as_truthy()`.
AsTruthy,
/// This operand is `ctrlType.half_width()`.
HalfWidth,
/// This operand is `ctrlType.double_width()`.
DoubleWidth,
/// This operand is `ctrlType.split_lanes()`.
SplitLanes,
/// This operand is `ctrlType.merge_lanes()`.
MergeLanes,
/// This operands is `ctrlType.dynamic_to_vector()`.
DynamicToVector,
/// This operand is `ctrlType.narrower()`.
Narrower,
/// This operand is `ctrlType.wider()`.
Wider,
}
impl OperandConstraint {
/// Resolve this operand constraint into a concrete value type, given the value of the
/// controlling type variable.
pub fn resolve(&self, ctrl_type: Type) -> ResolvedConstraint {
use self::OperandConstraint::*;
use self::ResolvedConstraint::Bound;
match *self {
Concrete(t) => Bound(t),
Free(vts) => ResolvedConstraint::Free(TYPE_SETS[vts as usize]),
Same => Bound(ctrl_type),
LaneOf => Bound(ctrl_type.lane_of()),
AsTruthy => Bound(ctrl_type.as_truthy()),
HalfWidth => Bound(ctrl_type.half_width().expect("invalid type for half_width")),
DoubleWidth => Bound(
ctrl_type
.double_width()
.expect("invalid type for double_width"),
),
SplitLanes => {
if ctrl_type.is_dynamic_vector() {
Bound(
ctrl_type
.dynamic_to_vector()
.expect("invalid type for dynamic_to_vector")
.split_lanes()
.expect("invalid type for split_lanes")
.vector_to_dynamic()
.expect("invalid dynamic type"),
)
} else {
Bound(
ctrl_type
.split_lanes()
.expect("invalid type for split_lanes"),
)
}
}
MergeLanes => {
if ctrl_type.is_dynamic_vector() {
Bound(
ctrl_type
.dynamic_to_vector()
.expect("invalid type for dynamic_to_vector")
.merge_lanes()
.expect("invalid type for merge_lanes")
.vector_to_dynamic()
.expect("invalid dynamic type"),
)
} else {
Bound(
ctrl_type
.merge_lanes()
.expect("invalid type for merge_lanes"),
)
}
}
DynamicToVector => Bound(
ctrl_type
.dynamic_to_vector()
.expect("invalid type for dynamic_to_vector"),
),
Narrower => {
let ctrl_type_bits = ctrl_type.log2_lane_bits();
let mut tys = ValueTypeSet::default();
// We're testing scalar values, only.
tys.lanes = ScalarBitSet::from_range(0, 1);
if ctrl_type.is_int() {
// The upper bound in from_range is exclusive, and we want to exclude the
// control type to construct the interval of [I8, ctrl_type).
tys.ints = BitSet8::from_range(3, ctrl_type_bits as u8);
} else if ctrl_type.is_float() {
// The upper bound in from_range is exclusive, and we want to exclude the
// control type to construct the interval of [F16, ctrl_type).
tys.floats = BitSet8::from_range(4, ctrl_type_bits as u8);
} else {
panic!("The Narrower constraint only operates on floats or ints");
}
ResolvedConstraint::Free(tys)
}
Wider => {
let ctrl_type_bits = ctrl_type.log2_lane_bits();
let mut tys = ValueTypeSet::default();
// We're testing scalar values, only.
tys.lanes = ScalarBitSet::from_range(0, 1);
if ctrl_type.is_int() {
let lower_bound = ctrl_type_bits as u8 + 1;
// The largest integer type we can represent in `BitSet8` is I128, which is
// represented by bit 7 in the bit set. Adding one to exclude I128 from the
// lower bound would overflow as 2^8 doesn't fit in a u8, but this would
// already describe the empty set so instead we leave `ints` in its default
// empty state.
if lower_bound < BitSet8::capacity() {
// The interval should include all types wider than `ctrl_type`, so we use
// `2^8` as the upper bound, and add one to the bits of `ctrl_type` to define
// the interval `(ctrl_type, I128]`.
tys.ints = BitSet8::from_range(lower_bound, 8);
}
} else if ctrl_type.is_float() {
// Same as above but for `tys.floats`, as the largest float type is F128.
let lower_bound = ctrl_type_bits as u8 + 1;
if lower_bound < BitSet8::capacity() {
tys.floats = BitSet8::from_range(lower_bound, 8);
}
} else {
panic!("The Wider constraint only operates on floats or ints");
}
ResolvedConstraint::Free(tys)
}
}
}
}
/// The type constraint on a value argument once the controlling type variable is known.
#[derive(Copy, Clone, Debug, PartialEq, Eq)]
pub enum ResolvedConstraint {
/// The operand is bound to a known type.
Bound(Type),
/// The operand type can vary freely within the given set.
Free(ValueTypeSet),
}
#[cfg(test)]
mod tests {
use super::*;
use alloc::string::ToString;
#[test]
fn inst_data_is_copy() {
fn is_copy<T: Copy>() {}
is_copy::<InstructionData>();
}
#[test]
fn inst_data_size() {
// The size of `InstructionData` is performance sensitive, so make sure
// we don't regress it unintentionally.
assert_eq!(std::mem::size_of::<InstructionData>(), 16);
}
#[test]
fn opcodes() {
use core::mem;
let x = Opcode::Iadd;
let mut y = Opcode::Isub;
assert!(x != y);
y = Opcode::Iadd;
assert_eq!(x, y);
assert_eq!(x.format(), InstructionFormat::Binary);
assert_eq!(format!("{:?}", Opcode::IaddImm), "IaddImm");
assert_eq!(Opcode::IaddImm.to_string(), "iadd_imm");
// Check the matcher.
assert_eq!("iadd".parse::<Opcode>(), Ok(Opcode::Iadd));
assert_eq!("iadd_imm".parse::<Opcode>(), Ok(Opcode::IaddImm));
assert_eq!("iadd\0".parse::<Opcode>(), Err("Unknown opcode"));
assert_eq!("".parse::<Opcode>(), Err("Unknown opcode"));
assert_eq!("\0".parse::<Opcode>(), Err("Unknown opcode"));
// Opcode is a single byte, and because Option<Opcode> originally came to 2 bytes, early on
// Opcode included a variant NotAnOpcode to avoid the unnecessary bloat. Since then the Rust
// compiler has brought in NonZero optimization, meaning that an enum not using the 0 value
// can be optional for no size cost. We want to ensure Option<Opcode> remains small.
assert_eq!(mem::size_of::<Opcode>(), mem::size_of::<Option<Opcode>>());
}
#[test]
fn instruction_data() {
use core::mem;
// The size of the `InstructionData` enum is important for performance. It should not
// exceed 16 bytes. Use `Box<FooData>` out-of-line payloads for instruction formats that
// require more space than that. It would be fine with a data structure smaller than 16
// bytes, but what are the odds of that?
assert_eq!(mem::size_of::<InstructionData>(), 16);
}
#[test]
fn constraints() {
let a = Opcode::Iadd.constraints();
assert!(a.use_typevar_operand());
assert!(!a.requires_typevar_operand());
assert_eq!(a.num_fixed_results(), 1);
assert_eq!(a.num_fixed_value_arguments(), 2);
assert_eq!(a.result_type(0, types::I32), types::I32);
assert_eq!(a.result_type(0, types::I8), types::I8);
assert_eq!(
a.value_argument_constraint(0, types::I32),
ResolvedConstraint::Bound(types::I32)
);
assert_eq!(
a.value_argument_constraint(1, types::I32),
ResolvedConstraint::Bound(types::I32)
);
let b = Opcode::Bitcast.constraints();
assert!(!b.use_typevar_operand());
assert!(!b.requires_typevar_operand());
assert_eq!(b.num_fixed_results(), 1);
assert_eq!(b.num_fixed_value_arguments(), 1);
assert_eq!(b.result_type(0, types::I32), types::I32);
assert_eq!(b.result_type(0, types::I8), types::I8);
match b.value_argument_constraint(0, types::I32) {
ResolvedConstraint::Free(vts) => assert!(vts.contains(types::F32)),
_ => panic!("Unexpected constraint from value_argument_constraint"),
}
let c = Opcode::Call.constraints();
assert_eq!(c.num_fixed_results(), 0);
assert_eq!(c.num_fixed_value_arguments(), 0);
let i = Opcode::CallIndirect.constraints();
assert_eq!(i.num_fixed_results(), 0);
assert_eq!(i.num_fixed_value_arguments(), 1);
let cmp = Opcode::Icmp.constraints();
assert!(cmp.use_typevar_operand());
assert!(cmp.requires_typevar_operand());
assert_eq!(cmp.num_fixed_results(), 1);
assert_eq!(cmp.num_fixed_value_arguments(), 2);
assert_eq!(cmp.result_type(0, types::I64), types::I8);
}
#[test]
fn value_set() {
use crate::ir::types::*;
let vts = ValueTypeSet {
lanes: BitSet16::from_range(0, 8),
ints: BitSet8::from_range(4, 7),
floats: BitSet8::from_range(0, 0),
refs: BitSet8::from_range(5, 7),
dynamic_lanes: BitSet16::from_range(0, 4),
};
assert!(!vts.contains(I8));
assert!(vts.contains(I32));
assert!(vts.contains(I64));
assert!(vts.contains(I32X4));
assert!(vts.contains(I32X4XN));
assert!(!vts.contains(F16));
assert!(!vts.contains(F32));
assert!(!vts.contains(F128));
assert!(vts.contains(R32));
assert!(vts.contains(R64));
assert_eq!(vts.example().to_string(), "i32");
let vts = ValueTypeSet {
lanes: BitSet16::from_range(0, 8),
ints: BitSet8::from_range(0, 0),
floats: BitSet8::from_range(5, 7),
refs: BitSet8::from_range(0, 0),
dynamic_lanes: BitSet16::from_range(0, 8),
};
assert_eq!(vts.example().to_string(), "f32");
let vts = ValueTypeSet {
lanes: BitSet16::from_range(1, 8),
ints: BitSet8::from_range(0, 0),
floats: BitSet8::from_range(5, 7),
refs: BitSet8::from_range(0, 0),
dynamic_lanes: BitSet16::from_range(0, 8),
};
assert_eq!(vts.example().to_string(), "f32x2");
let vts = ValueTypeSet {
lanes: BitSet16::from_range(2, 8),
ints: BitSet8::from_range(3, 7),
floats: BitSet8::from_range(0, 0),
refs: BitSet8::from_range(0, 0),
dynamic_lanes: BitSet16::from_range(0, 8),
};
assert_eq!(vts.example().to_string(), "i32x4");
let vts = ValueTypeSet {
// TypeSet(lanes=(1, 256), ints=(8, 64))
lanes: BitSet16::from_range(0, 9),
ints: BitSet8::from_range(3, 7),
floats: BitSet8::from_range(0, 0),
refs: BitSet8::from_range(0, 0),
dynamic_lanes: BitSet16::from_range(0, 8),
};
assert!(vts.contains(I32));
assert!(vts.contains(I32X4));
assert!(!vts.contains(R32));
assert!(!vts.contains(R64));
}
}