rust/src/librustc_mir/transform/inline.rs

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//! Inlining pass for MIR functions
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use rustc::hir::CodegenFnAttrFlags;
use rustc::hir::def_id::DefId;
Merge indexed_set.rs into bitvec.rs, and rename it bit_set.rs. Currently we have two files implementing bitsets (and 2D bit matrices). This commit combines them into one, taking the best features from each. This involves renaming a lot of things. The high level changes are as follows. - bitvec.rs --> bit_set.rs - indexed_set.rs --> (removed) - BitArray + IdxSet --> BitSet (merged, see below) - BitVector --> GrowableBitSet - {,Sparse,Hybrid}IdxSet --> {,Sparse,Hybrid}BitSet - BitMatrix --> BitMatrix - SparseBitMatrix --> SparseBitMatrix The changes within the bitset types themselves are as follows. ``` OLD OLD NEW BitArray<C> IdxSet<T> BitSet<T> -------- ------ ------ grow - grow new - (remove) new_empty new_empty new_empty new_filled new_filled new_filled - to_hybrid to_hybrid clear clear clear set_up_to set_up_to set_up_to clear_above - clear_above count - count contains(T) contains(&T) contains(T) contains_all - superset is_empty - is_empty insert(T) add(&T) insert(T) insert_all - insert_all() remove(T) remove(&T) remove(T) words words words words_mut words_mut words_mut - overwrite overwrite merge union union - subtract subtract - intersect intersect iter iter iter ``` In general, when choosing names I went with: - names that are more obvious (e.g. `BitSet` over `IdxSet`). - names that are more like the Rust libraries (e.g. `T` over `C`, `insert` over `add`); - names that are more set-like (e.g. `union` over `merge`, `superset` over `contains_all`, `domain_size` over `num_bits`). Also, using `T` for index arguments seems more sensible than `&T` -- even though the latter is standard in Rust collection types -- because indices are always copyable. It also results in fewer `&` and `*` sigils in practice.
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use rustc_data_structures::bit_set::BitSet;
use rustc_data_structures::indexed_vec::{Idx, IndexVec};
use rustc::mir::*;
use rustc::mir::visit::*;
use rustc::ty::{self, Instance, InstanceDef, ParamEnv, Ty, TyCtxt};
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use rustc::ty::subst::{Subst, SubstsRef};
use std::collections::VecDeque;
use std::iter;
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use crate::transform::{MirPass, MirSource};
use super::simplify::{remove_dead_blocks, CfgSimplifier};
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use syntax::attr;
use rustc_target::spec::abi::Abi;
const DEFAULT_THRESHOLD: usize = 50;
const HINT_THRESHOLD: usize = 100;
const INSTR_COST: usize = 5;
const CALL_PENALTY: usize = 25;
const UNKNOWN_SIZE_COST: usize = 10;
pub struct Inline;
#[derive(Copy, Clone, Debug)]
struct CallSite<'tcx> {
callee: DefId,
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substs: SubstsRef<'tcx>,
bb: BasicBlock,
location: SourceInfo,
}
impl MirPass for Inline {
fn run_pass<'a, 'tcx>(&self,
tcx: TyCtxt<'a, 'tcx, 'tcx>,
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source: MirSource<'tcx>,
mir: &mut Mir<'tcx>) {
if tcx.sess.opts.debugging_opts.mir_opt_level >= 2 {
Inliner { tcx, source }.run_pass(mir);
}
}
}
struct Inliner<'a, 'tcx: 'a> {
tcx: TyCtxt<'a, 'tcx, 'tcx>,
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source: MirSource<'tcx>,
}
impl<'a, 'tcx> Inliner<'a, 'tcx> {
fn run_pass(&self, caller_mir: &mut Mir<'tcx>) {
// Keep a queue of callsites to try inlining on. We take
// advantage of the fact that queries detect cycles here to
// allow us to try and fetch the fully optimized MIR of a
// call; if it succeeds, we can inline it and we know that
// they do not call us. Otherwise, we just don't try to
// inline.
//
// We use a queue so that we inline "broadly" before we inline
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// in depth. It is unclear if this is the best heuristic,
// really, but that's true of all the heuristics in this
// file. =)
let mut callsites = VecDeque::new();
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let param_env = self.tcx.param_env(self.source.def_id());
// Only do inlining into fn bodies.
let id = self.tcx.hir().as_local_hir_id(self.source.def_id()).unwrap();
if self.tcx.hir().body_owner_kind_by_hir_id(id).is_fn_or_closure()
&& self.source.promoted.is_none()
{
for (bb, bb_data) in caller_mir.basic_blocks().iter_enumerated() {
if let Some(callsite) = self.get_valid_function_call(bb,
bb_data,
caller_mir,
param_env) {
callsites.push_back(callsite);
}
}
} else {
return;
}
let mut local_change;
let mut changed = false;
loop {
local_change = false;
while let Some(callsite) = callsites.pop_front() {
debug!("checking whether to inline callsite {:?}", callsite);
if !self.tcx.is_mir_available(callsite.callee) {
debug!("checking whether to inline callsite {:?} - MIR unavailable", callsite);
continue;
}
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let self_node_id = self.tcx.hir().as_local_node_id(self.source.def_id()).unwrap();
let callee_node_id = self.tcx.hir().as_local_node_id(callsite.callee);
let callee_mir = if let Some(callee_node_id) = callee_node_id {
// Avoid a cycle here by only using `optimized_mir` only if we have
// a lower node id than the callee. This ensures that the callee will
// not inline us. This trick only works without incremental compilation.
// So don't do it if that is enabled.
if !self.tcx.dep_graph.is_fully_enabled()
&& self_node_id.as_u32() < callee_node_id.as_u32() {
self.tcx.optimized_mir(callsite.callee)
} else {
continue;
}
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} else {
// This cannot result in a cycle since the callee MIR is from another crate
// and is already optimized.
self.tcx.optimized_mir(callsite.callee)
};
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let callee_mir = if self.consider_optimizing(callsite, callee_mir) {
self.tcx.subst_and_normalize_erasing_regions(
&callsite.substs,
param_env,
callee_mir,
)
} else {
continue;
};
let start = caller_mir.basic_blocks().len();
debug!("attempting to inline callsite {:?} - mir={:?}", callsite, callee_mir);
if !self.inline_call(callsite, caller_mir, callee_mir) {
debug!("attempting to inline callsite {:?} - failure", callsite);
continue;
}
debug!("attempting to inline callsite {:?} - success", callsite);
// Add callsites from inlined function
for (bb, bb_data) in caller_mir.basic_blocks().iter_enumerated().skip(start) {
if let Some(new_callsite) = self.get_valid_function_call(bb,
bb_data,
caller_mir,
param_env) {
// Don't inline the same function multiple times.
if callsite.callee != new_callsite.callee {
callsites.push_back(new_callsite);
}
}
}
local_change = true;
changed = true;
}
if !local_change {
break;
}
}
// Simplify if we inlined anything.
if changed {
debug!("Running simplify cfg on {:?}", self.source);
CfgSimplifier::new(caller_mir).simplify();
remove_dead_blocks(caller_mir);
}
}
fn get_valid_function_call(&self,
bb: BasicBlock,
bb_data: &BasicBlockData<'tcx>,
caller_mir: &Mir<'tcx>,
param_env: ParamEnv<'tcx>,
) -> Option<CallSite<'tcx>> {
// Don't inline calls that are in cleanup blocks.
if bb_data.is_cleanup { return None; }
// Only consider direct calls to functions
let terminator = bb_data.terminator();
if let TerminatorKind::Call { func: ref op, .. } = terminator.kind {
if let ty::FnDef(callee_def_id, substs) = op.ty(caller_mir, self.tcx).sty {
let instance = Instance::resolve(self.tcx,
param_env,
callee_def_id,
substs)?;
if let InstanceDef::Virtual(..) = instance.def {
return None;
}
return Some(CallSite {
callee: instance.def_id(),
substs: instance.substs,
bb,
location: terminator.source_info
});
}
}
None
}
fn consider_optimizing(&self,
callsite: CallSite<'tcx>,
callee_mir: &Mir<'tcx>)
-> bool
{
debug!("consider_optimizing({:?})", callsite);
self.should_inline(callsite, callee_mir)
&& self.tcx.consider_optimizing(|| format!("Inline {:?} into {:?}",
callee_mir.span,
callsite))
}
fn should_inline(&self,
callsite: CallSite<'tcx>,
callee_mir: &Mir<'tcx>)
-> bool
{
debug!("should_inline({:?})", callsite);
let tcx = self.tcx;
// Don't inline closures that have capture debuginfo
// FIXME: Handle closures better
if callee_mir.__upvar_debuginfo_codegen_only_do_not_use.len() > 0 {
debug!(" upvar debuginfo present - not inlining");
return false;
}
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// Cannot inline generators which haven't been transformed yet
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if callee_mir.yield_ty.is_some() {
debug!(" yield ty present - not inlining");
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return false;
}
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// Do not inline {u,i}128 lang items, codegen const eval depends
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// on detecting calls to these lang items and intercepting them
if tcx.is_binop_lang_item(callsite.callee).is_some() {
debug!(" not inlining 128bit integer lang item");
return false;
}
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let codegen_fn_attrs = tcx.codegen_fn_attrs(callsite.callee);
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let hinted = match codegen_fn_attrs.inline {
// Just treat inline(always) as a hint for now,
// there are cases that prevent inlining that we
// need to check for first.
attr::InlineAttr::Always => true,
attr::InlineAttr::Never => {
debug!("#[inline(never)] present - not inlining");
return false
}
attr::InlineAttr::Hint => true,
attr::InlineAttr::None => false,
};
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// Only inline local functions if they would be eligible for cross-crate
// inlining. This is to ensure that the final crate doesn't have MIR that
// reference unexported symbols
if callsite.callee.is_local() {
if callsite.substs.non_erasable_generics().count() == 0 && !hinted {
debug!(" callee is an exported function - not inlining");
return false;
}
}
let mut threshold = if hinted {
HINT_THRESHOLD
} else {
DEFAULT_THRESHOLD
};
// Significantly lower the threshold for inlining cold functions
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if codegen_fn_attrs.flags.contains(CodegenFnAttrFlags::COLD) {
threshold /= 5;
}
// Give a bonus functions with a small number of blocks,
// We normally have two or three blocks for even
// very small functions.
if callee_mir.basic_blocks().len() <= 3 {
threshold += threshold / 4;
}
debug!(" final inline threshold = {}", threshold);
// FIXME: Give a bonus to functions with only a single caller
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let param_env = tcx.param_env(self.source.def_id());
let mut first_block = true;
let mut cost = 0;
// Traverse the MIR manually so we can account for the effects of
// inlining on the CFG.
let mut work_list = vec![START_BLOCK];
Merge indexed_set.rs into bitvec.rs, and rename it bit_set.rs. Currently we have two files implementing bitsets (and 2D bit matrices). This commit combines them into one, taking the best features from each. This involves renaming a lot of things. The high level changes are as follows. - bitvec.rs --> bit_set.rs - indexed_set.rs --> (removed) - BitArray + IdxSet --> BitSet (merged, see below) - BitVector --> GrowableBitSet - {,Sparse,Hybrid}IdxSet --> {,Sparse,Hybrid}BitSet - BitMatrix --> BitMatrix - SparseBitMatrix --> SparseBitMatrix The changes within the bitset types themselves are as follows. ``` OLD OLD NEW BitArray<C> IdxSet<T> BitSet<T> -------- ------ ------ grow - grow new - (remove) new_empty new_empty new_empty new_filled new_filled new_filled - to_hybrid to_hybrid clear clear clear set_up_to set_up_to set_up_to clear_above - clear_above count - count contains(T) contains(&T) contains(T) contains_all - superset is_empty - is_empty insert(T) add(&T) insert(T) insert_all - insert_all() remove(T) remove(&T) remove(T) words words words words_mut words_mut words_mut - overwrite overwrite merge union union - subtract subtract - intersect intersect iter iter iter ``` In general, when choosing names I went with: - names that are more obvious (e.g. `BitSet` over `IdxSet`). - names that are more like the Rust libraries (e.g. `T` over `C`, `insert` over `add`); - names that are more set-like (e.g. `union` over `merge`, `superset` over `contains_all`, `domain_size` over `num_bits`). Also, using `T` for index arguments seems more sensible than `&T` -- even though the latter is standard in Rust collection types -- because indices are always copyable. It also results in fewer `&` and `*` sigils in practice.
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let mut visited = BitSet::new_empty(callee_mir.basic_blocks().len());
while let Some(bb) = work_list.pop() {
if !visited.insert(bb.index()) { continue; }
let blk = &callee_mir.basic_blocks()[bb];
for stmt in &blk.statements {
// Don't count StorageLive/StorageDead in the inlining cost.
match stmt.kind {
StatementKind::StorageLive(_) |
StatementKind::StorageDead(_) |
StatementKind::Nop => {}
_ => cost += INSTR_COST
}
}
let term = blk.terminator();
let mut is_drop = false;
match term.kind {
TerminatorKind::Drop { ref location, target, unwind } |
TerminatorKind::DropAndReplace { ref location, target, unwind, .. } => {
is_drop = true;
work_list.push(target);
// If the location doesn't actually need dropping, treat it like
// a regular goto.
let ty = location.ty(callee_mir, tcx).subst(tcx, callsite.substs).ty;
if ty.needs_drop(tcx, param_env) {
cost += CALL_PENALTY;
if let Some(unwind) = unwind {
work_list.push(unwind);
}
} else {
cost += INSTR_COST;
}
}
TerminatorKind::Unreachable |
TerminatorKind::Call { destination: None, .. } if first_block => {
// If the function always diverges, don't inline
// unless the cost is zero
threshold = 0;
}
TerminatorKind::Call {func: Operand::Constant(ref f), .. } => {
if let ty::FnDef(def_id, _) = f.ty.sty {
// Don't give intrinsics the extra penalty for calls
let f = tcx.fn_sig(def_id);
if f.abi() == Abi::RustIntrinsic || f.abi() == Abi::PlatformIntrinsic {
cost += INSTR_COST;
} else {
cost += CALL_PENALTY;
}
}
}
TerminatorKind::Assert { .. } => cost += CALL_PENALTY,
_ => cost += INSTR_COST
}
if !is_drop {
for &succ in term.successors() {
work_list.push(succ);
}
}
first_block = false;
}
// Count up the cost of local variables and temps, if we know the size
// use that, otherwise we use a moderately-large dummy cost.
let ptr_size = tcx.data_layout.pointer_size.bytes();
for v in callee_mir.vars_and_temps_iter() {
let v = &callee_mir.local_decls[v];
let ty = v.ty.subst(tcx, callsite.substs);
// Cost of the var is the size in machine-words, if we know
// it.
if let Some(size) = type_size_of(tcx, param_env.clone(), ty) {
cost += (size / ptr_size) as usize;
} else {
cost += UNKNOWN_SIZE_COST;
}
}
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if let attr::InlineAttr::Always = codegen_fn_attrs.inline {
debug!("INLINING {:?} because inline(always) [cost={}]", callsite, cost);
true
} else {
if cost <= threshold {
debug!("INLINING {:?} [cost={} <= threshold={}]", callsite, cost, threshold);
true
} else {
debug!("NOT inlining {:?} [cost={} > threshold={}]", callsite, cost, threshold);
false
}
}
}
fn inline_call(&self,
callsite: CallSite<'tcx>,
caller_mir: &mut Mir<'tcx>,
mut callee_mir: Mir<'tcx>) -> bool {
let terminator = caller_mir[callsite.bb].terminator.take().unwrap();
match terminator.kind {
// FIXME: Handle inlining of diverging calls
TerminatorKind::Call { args, destination: Some(destination), cleanup, .. } => {
debug!("Inlined {:?} into {:?}", callsite.callee, self.source);
let mut local_map = IndexVec::with_capacity(callee_mir.local_decls.len());
let mut scope_map = IndexVec::with_capacity(callee_mir.source_scopes.len());
let mut promoted_map = IndexVec::with_capacity(callee_mir.promoted.len());
for mut scope in callee_mir.source_scopes.iter().cloned() {
if scope.parent_scope.is_none() {
scope.parent_scope = Some(callsite.location.scope);
scope.span = callee_mir.span;
}
scope.span = callsite.location.span;
let idx = caller_mir.source_scopes.push(scope);
scope_map.push(idx);
}
for loc in callee_mir.vars_and_temps_iter() {
let mut local = callee_mir.local_decls[loc].clone();
local.source_info.scope =
scope_map[local.source_info.scope];
local.source_info.span = callsite.location.span;
local.visibility_scope = scope_map[local.visibility_scope];
let idx = caller_mir.local_decls.push(local);
local_map.push(idx);
}
promoted_map.extend(
callee_mir.promoted.iter().cloned().map(|p| caller_mir.promoted.push(p))
);
// If the call is something like `a[*i] = f(i)`, where
// `i : &mut usize`, then just duplicating the `a[*i]`
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// Place could result in two different locations if `f`
// writes to `i`. To prevent this we need to create a temporary
// borrow of the place and pass the destination as `*temp` instead.
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fn dest_needs_borrow(place: &Place<'_>) -> bool {
place.iterate(|place_base, place_projection| {
for proj in place_projection {
match proj.elem {
ProjectionElem::Deref |
ProjectionElem::Index(_) => return true,
_ => {}
}
}
match place_base {
// Static variables need a borrow because the callee
// might modify the same static.
PlaceBase::Static(_) => true,
_ => false
}
})
}
let dest = if dest_needs_borrow(&destination.0) {
debug!("Creating temp for return destination");
let dest = Rvalue::Ref(
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self.tcx.lifetimes.re_erased,
BorrowKind::Mut { allow_two_phase_borrow: false },
destination.0);
let ty = dest.ty(caller_mir, self.tcx);
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let temp = LocalDecl::new_temp(ty, callsite.location.span);
let tmp = caller_mir.local_decls.push(temp);
let tmp = Place::Base(PlaceBase::Local(tmp));
let stmt = Statement {
source_info: callsite.location,
kind: StatementKind::Assign(tmp.clone(), box dest)
};
caller_mir[callsite.bb]
.statements.push(stmt);
tmp.deref()
} else {
destination.0
};
let return_block = destination.1;
// Copy the arguments if needed.
let args: Vec<_> = self.make_call_args(args, &callsite, caller_mir);
let bb_len = caller_mir.basic_blocks().len();
let mut integrator = Integrator {
block_idx: bb_len,
args: &args,
local_map,
scope_map,
promoted_map,
_callsite: callsite,
destination: dest,
return_block,
cleanup_block: cleanup,
in_cleanup_block: false
};
for (bb, mut block) in callee_mir.basic_blocks_mut().drain_enumerated(..) {
integrator.visit_basic_block_data(bb, &mut block);
caller_mir.basic_blocks_mut().push(block);
}
let terminator = Terminator {
source_info: callsite.location,
kind: TerminatorKind::Goto { target: BasicBlock::new(bb_len) }
};
caller_mir[callsite.bb].terminator = Some(terminator);
true
}
kind => {
caller_mir[callsite.bb].terminator = Some(Terminator {
source_info: terminator.source_info,
kind,
});
false
}
}
}
fn make_call_args(
&self,
args: Vec<Operand<'tcx>>,
callsite: &CallSite<'tcx>,
caller_mir: &mut Mir<'tcx>,
) -> Vec<Local> {
let tcx = self.tcx;
// There is a bit of a mismatch between the *caller* of a closure and the *callee*.
// The caller provides the arguments wrapped up in a tuple:
//
// tuple_tmp = (a, b, c)
// Fn::call(closure_ref, tuple_tmp)
//
// meanwhile the closure body expects the arguments (here, `a`, `b`, and `c`)
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// as distinct arguments. (This is the "rust-call" ABI hack.) Normally, codegen has
// the job of unpacking this tuple. But here, we are codegen. =) So we want to create
// a vector like
//
// [closure_ref, tuple_tmp.0, tuple_tmp.1, tuple_tmp.2]
//
// Except for one tiny wrinkle: we don't actually want `tuple_tmp.0`. It's more convenient
// if we "spill" that into *another* temporary, so that we can map the argument
// variable in the callee MIR directly to an argument variable on our side.
// So we introduce temporaries like:
//
// tmp0 = tuple_tmp.0
// tmp1 = tuple_tmp.1
// tmp2 = tuple_tmp.2
//
// and the vector is `[closure_ref, tmp0, tmp1, tmp2]`.
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if tcx.is_closure(callsite.callee) {
let mut args = args.into_iter();
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let self_ = self.create_temp_if_necessary(args.next().unwrap(), callsite, caller_mir);
let tuple = self.create_temp_if_necessary(args.next().unwrap(), callsite, caller_mir);
assert!(args.next().is_none());
let tuple = Place::Base(PlaceBase::Local(tuple));
let tuple_tys = if let ty::Tuple(s) = tuple.ty(caller_mir, tcx).ty.sty {
s
} else {
bug!("Closure arguments are not passed as a tuple");
};
// The `closure_ref` in our example above.
let closure_ref_arg = iter::once(self_);
// The `tmp0`, `tmp1`, and `tmp2` in our example abonve.
let tuple_tmp_args =
tuple_tys.iter().enumerate().map(|(i, ty)| {
// This is e.g., `tuple_tmp.0` in our example above.
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let tuple_field = Operand::Move(tuple.clone().field(
Field::new(i),
ty.expect_ty(),
));
// Spill to a local to make e.g., `tmp0`.
self.create_temp_if_necessary(tuple_field, callsite, caller_mir)
});
closure_ref_arg.chain(tuple_tmp_args).collect()
} else {
args.into_iter()
.map(|a| self.create_temp_if_necessary(a, callsite, caller_mir))
.collect()
}
}
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/// If `arg` is already a temporary, returns it. Otherwise, introduces a fresh
/// temporary `T` and an instruction `T = arg`, and returns `T`.
fn create_temp_if_necessary(
&self,
arg: Operand<'tcx>,
callsite: &CallSite<'tcx>,
caller_mir: &mut Mir<'tcx>,
) -> Local {
// FIXME: Analysis of the usage of the arguments to avoid
// unnecessary temporaries.
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if let Operand::Move(Place::Base(PlaceBase::Local(local))) = arg {
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if caller_mir.local_kind(local) == LocalKind::Temp {
// Reuse the operand if it's a temporary already
return local;
}
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}
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debug!("Creating temp for argument {:?}", arg);
// Otherwise, create a temporary for the arg
let arg = Rvalue::Use(arg);
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let ty = arg.ty(caller_mir, self.tcx);
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let arg_tmp = LocalDecl::new_temp(ty, callsite.location.span);
let arg_tmp = caller_mir.local_decls.push(arg_tmp);
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let stmt = Statement {
source_info: callsite.location,
kind: StatementKind::Assign(Place::Base(PlaceBase::Local(arg_tmp)), box arg),
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};
caller_mir[callsite.bb].statements.push(stmt);
arg_tmp
}
}
fn type_size_of<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
ty: Ty<'tcx>) -> Option<u64> {
tcx.layout_of(param_env.and(ty)).ok().map(|layout| layout.size.bytes())
}
/**
* Integrator.
*
* Integrates blocks from the callee function into the calling function.
* Updates block indices, references to locals and other control flow
* stuff.
*/
struct Integrator<'a, 'tcx: 'a> {
block_idx: usize,
args: &'a [Local],
local_map: IndexVec<Local, Local>,
scope_map: IndexVec<SourceScope, SourceScope>,
promoted_map: IndexVec<Promoted, Promoted>,
_callsite: CallSite<'tcx>,
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destination: Place<'tcx>,
return_block: BasicBlock,
cleanup_block: Option<BasicBlock>,
in_cleanup_block: bool,
}
impl<'a, 'tcx> Integrator<'a, 'tcx> {
fn update_target(&self, tgt: BasicBlock) -> BasicBlock {
let new = BasicBlock::new(tgt.index() + self.block_idx);
debug!("Updating target `{:?}`, new: `{:?}`", tgt, new);
new
}
}
impl<'a, 'tcx> MutVisitor<'tcx> for Integrator<'a, 'tcx> {
fn visit_local(&mut self,
local: &mut Local,
_ctxt: PlaceContext,
_location: Location) {
if *local == RETURN_PLACE {
match self.destination {
Place::Base(PlaceBase::Local(l)) => {
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*local = l;
return;
},
ref place => bug!("Return place is {:?}, not local", place)
}
}
let idx = local.index() - 1;
if idx < self.args.len() {
*local = self.args[idx];
return;
}
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*local = self.local_map[Local::new(idx - self.args.len())];
}
fn visit_place(&mut self,
place: &mut Place<'tcx>,
_ctxt: PlaceContext,
_location: Location) {
match place {
Place::Base(PlaceBase::Local(RETURN_PLACE)) => {
// Return pointer; update the place itself
*place = self.destination.clone();
},
Place::Base(
PlaceBase::Static(box Static { kind: StaticKind::Promoted(promoted), .. })
) => {
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if let Some(p) = self.promoted_map.get(*promoted).cloned() {
*promoted = p;
}
},
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_ => self.super_place(place, _ctxt, _location)
}
}
fn visit_basic_block_data(&mut self, block: BasicBlock, data: &mut BasicBlockData<'tcx>) {
self.in_cleanup_block = data.is_cleanup;
self.super_basic_block_data(block, data);
self.in_cleanup_block = false;
}
fn visit_retag(
&mut self,
kind: &mut RetagKind,
place: &mut Place<'tcx>,
loc: Location,
) {
self.super_retag(kind, place, loc);
// We have to patch all inlined retags to be aware that they are no longer
// happening on function entry.
if *kind == RetagKind::FnEntry {
*kind = RetagKind::Default;
}
}
fn visit_terminator_kind(&mut self,
kind: &mut TerminatorKind<'tcx>, loc: Location) {
self.super_terminator_kind(kind, loc);
match *kind {
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TerminatorKind::GeneratorDrop |
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TerminatorKind::Yield { .. } => bug!(),
TerminatorKind::Goto { ref mut target} => {
*target = self.update_target(*target);
}
TerminatorKind::SwitchInt { ref mut targets, .. } => {
for tgt in targets {
*tgt = self.update_target(*tgt);
}
}
TerminatorKind::Drop { ref mut target, ref mut unwind, .. } |
TerminatorKind::DropAndReplace { ref mut target, ref mut unwind, .. } => {
*target = self.update_target(*target);
if let Some(tgt) = *unwind {
*unwind = Some(self.update_target(tgt));
} else if !self.in_cleanup_block {
// Unless this drop is in a cleanup block, add an unwind edge to
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// the original call's cleanup block
*unwind = self.cleanup_block;
}
}
TerminatorKind::Call { ref mut destination, ref mut cleanup, .. } => {
if let Some((_, ref mut tgt)) = *destination {
*tgt = self.update_target(*tgt);
}
if let Some(tgt) = *cleanup {
*cleanup = Some(self.update_target(tgt));
} else if !self.in_cleanup_block {
// Unless this call is in a cleanup block, add an unwind edge to
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// the original call's cleanup block
*cleanup = self.cleanup_block;
}
}
TerminatorKind::Assert { ref mut target, ref mut cleanup, .. } => {
*target = self.update_target(*target);
if let Some(tgt) = *cleanup {
*cleanup = Some(self.update_target(tgt));
} else if !self.in_cleanup_block {
// Unless this assert is in a cleanup block, add an unwind edge to
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// the original call's cleanup block
*cleanup = self.cleanup_block;
}
}
TerminatorKind::Return => {
*kind = TerminatorKind::Goto { target: self.return_block };
}
TerminatorKind::Resume => {
if let Some(tgt) = self.cleanup_block {
*kind = TerminatorKind::Goto { target: tgt }
}
}
TerminatorKind::Abort => { }
TerminatorKind::Unreachable => { }
TerminatorKind::FalseEdges { ref mut real_target, ref mut imaginary_targets } => {
*real_target = self.update_target(*real_target);
for target in imaginary_targets {
*target = self.update_target(*target);
}
}
TerminatorKind::FalseUnwind { real_target: _ , unwind: _ } =>
// see the ordering of passes in the optimized_mir query.
bug!("False unwinds should have been removed before inlining")
}
}
fn visit_source_scope(&mut self, scope: &mut SourceScope) {
*scope = self.scope_map[*scope];
}
}