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//! Cranelift compilation context and main entry point.
//!
//! When compiling many small functions, it is important to avoid repeatedly allocating and
//! deallocating the data structures needed for compilation. The `Context` struct is used to hold
//! on to memory allocations between function compilations.
//!
//! The context does not hold a `TargetIsa` instance which has to be provided as an argument
//! instead. This is because an ISA instance is immutable and can be used by multiple compilation
//! contexts concurrently. Typically, you would have one context per compilation thread and only a
//! single ISA instance.
use crate::alias_analysis::AliasAnalysis;
use crate::dce::do_dce;
use crate::dominator_tree::DominatorTree;
use crate::egraph::EgraphPass;
use crate::flowgraph::ControlFlowGraph;
use crate::ir::Function;
use crate::isa::TargetIsa;
use crate::legalizer::simple_legalize;
use crate::licm::do_licm;
use crate::loop_analysis::LoopAnalysis;
use crate::machinst::{CompiledCode, CompiledCodeStencil};
use crate::nan_canonicalization::do_nan_canonicalization;
use crate::remove_constant_phis::do_remove_constant_phis;
use crate::result::{CodegenResult, CompileResult};
use crate::settings::{FlagsOrIsa, OptLevel};
use crate::simple_gvn::do_simple_gvn;
use crate::simple_preopt::do_preopt;
use crate::trace;
use crate::unreachable_code::eliminate_unreachable_code;
use crate::verifier::{verify_context, VerifierErrors, VerifierResult};
use crate::{timing, CompileError};
#[cfg(feature = "souper-harvest")]
use alloc::string::String;
use alloc::vec::Vec;
#[cfg(feature = "souper-harvest")]
use crate::souper_harvest::do_souper_harvest;
/// Persistent data structures and compilation pipeline.
pub struct Context {
/// The function we're compiling.
pub func: Function,
/// The control flow graph of `func`.
pub cfg: ControlFlowGraph,
/// Dominator tree for `func`.
pub domtree: DominatorTree,
/// Loop analysis of `func`.
pub loop_analysis: LoopAnalysis,
/// Result of MachBackend compilation, if computed.
pub(crate) compiled_code: Option<CompiledCode>,
/// Flag: do we want a disassembly with the CompiledCode?
pub want_disasm: bool,
}
impl Context {
/// Allocate a new compilation context.
///
/// The returned instance should be reused for compiling multiple functions in order to avoid
/// needless allocator thrashing.
pub fn new() -> Self {
Self::for_function(Function::new())
}
/// Allocate a new compilation context with an existing Function.
///
/// The returned instance should be reused for compiling multiple functions in order to avoid
/// needless allocator thrashing.
pub fn for_function(func: Function) -> Self {
Self {
func,
cfg: ControlFlowGraph::new(),
domtree: DominatorTree::new(),
loop_analysis: LoopAnalysis::new(),
compiled_code: None,
want_disasm: false,
}
}
/// Clear all data structures in this context.
pub fn clear(&mut self) {
self.func.clear();
self.cfg.clear();
self.domtree.clear();
self.loop_analysis.clear();
self.compiled_code = None;
self.want_disasm = false;
}
/// Returns the compilation result for this function, available after any `compile` function
/// has been called.
pub fn compiled_code(&self) -> Option<&CompiledCode> {
self.compiled_code.as_ref()
}
/// Set the flag to request a disassembly when compiling with a
/// `MachBackend` backend.
pub fn set_disasm(&mut self, val: bool) {
self.want_disasm = val;
}
/// Compile the function, and emit machine code into a `Vec<u8>`.
///
/// Run the function through all the passes necessary to generate
/// code for the target ISA represented by `isa`, as well as the
/// final step of emitting machine code into a `Vec<u8>`. The
/// machine code is not relocated. Instead, any relocations can be
/// obtained from `compiled_code()`.
///
/// Performs any optimizations that are enabled, unless
/// `optimize()` was already invoked.
///
/// This function calls `compile`, taking care to resize `mem` as
/// needed.
///
/// Returns information about the function's code and read-only
/// data.
pub fn compile_and_emit(
&mut self,
isa: &dyn TargetIsa,
mem: &mut Vec<u8>,
) -> CompileResult<&CompiledCode> {
let compiled_code = self.compile(isa)?;
mem.extend_from_slice(compiled_code.code_buffer());
Ok(compiled_code)
}
/// Internally compiles the function into a stencil.
///
/// Public only for testing and fuzzing purposes.
pub fn compile_stencil(&mut self, isa: &dyn TargetIsa) -> CodegenResult<CompiledCodeStencil> {
let _tt = timing::compile();
self.verify_if(isa)?;
self.optimize(isa)?;
isa.compile_function(&self.func, &self.domtree, self.want_disasm)
}
/// Optimize the function, performing all compilation steps up to
/// but not including machine-code lowering and register
/// allocation.
///
/// Public only for testing purposes.
pub fn optimize(&mut self, isa: &dyn TargetIsa) -> CodegenResult<()> {
log::debug!(
"Number of CLIF instructions to optimize: {}",
self.func.dfg.num_insts()
);
log::debug!(
"Number of CLIF blocks to optimize: {}",
self.func.dfg.num_blocks()
);
let opt_level = isa.flags().opt_level();
crate::trace!(
"Optimizing (opt level {:?}):\n{}",
opt_level,
self.func.display()
);
self.compute_cfg();
if !isa.flags().use_egraphs() && opt_level != OptLevel::None {
self.preopt(isa)?;
}
if isa.flags().enable_nan_canonicalization() {
self.canonicalize_nans(isa)?;
}
self.legalize(isa)?;
if !isa.flags().use_egraphs() && opt_level != OptLevel::None {
self.compute_domtree();
self.compute_loop_analysis();
self.licm(isa)?;
self.simple_gvn(isa)?;
}
self.compute_domtree();
self.eliminate_unreachable_code(isa)?;
if opt_level != OptLevel::None {
self.dce(isa)?;
}
self.remove_constant_phis(isa)?;
if opt_level != OptLevel::None {
if isa.flags().use_egraphs() {
self.egraph_pass()?;
} else if isa.flags().enable_alias_analysis() {
for _ in 0..2 {
self.replace_redundant_loads()?;
self.simple_gvn(isa)?;
}
}
}
Ok(())
}
/// Compile the function.
///
/// Run the function through all the passes necessary to generate code for the target ISA
/// represented by `isa`. This does not include the final step of emitting machine code into a
/// code sink.
///
/// Returns information about the function's code and read-only data.
pub fn compile(&mut self, isa: &dyn TargetIsa) -> CompileResult<&CompiledCode> {
let stencil = self.compile_stencil(isa).map_err(|error| CompileError {
inner: error,
func: &self.func,
})?;
Ok(self
.compiled_code
.insert(stencil.apply_params(&self.func.params)))
}
/// If available, return information about the code layout in the
/// final machine code: the offsets (in bytes) of each basic-block
/// start, and all basic-block edges.
#[deprecated = "use CompiledCode::get_code_bb_layout"]
pub fn get_code_bb_layout(&self) -> Option<(Vec<usize>, Vec<(usize, usize)>)> {
self.compiled_code().map(CompiledCode::get_code_bb_layout)
}
/// Creates unwind information for the function.
///
/// Returns `None` if the function has no unwind information.
#[cfg(feature = "unwind")]
#[deprecated = "use CompiledCode::create_unwind_info"]
pub fn create_unwind_info(
&self,
isa: &dyn TargetIsa,
) -> CodegenResult<Option<crate::isa::unwind::UnwindInfo>> {
self.compiled_code().unwrap().create_unwind_info(isa)
}
/// Run the verifier on the function.
///
/// Also check that the dominator tree and control flow graph are consistent with the function.
pub fn verify<'a, FOI: Into<FlagsOrIsa<'a>>>(&self, fisa: FOI) -> VerifierResult<()> {
let mut errors = VerifierErrors::default();
let _ = verify_context(&self.func, &self.cfg, &self.domtree, fisa, &mut errors);
if errors.is_empty() {
Ok(())
} else {
Err(errors)
}
}
/// Run the verifier only if the `enable_verifier` setting is true.
pub fn verify_if<'a, FOI: Into<FlagsOrIsa<'a>>>(&self, fisa: FOI) -> CodegenResult<()> {
let fisa = fisa.into();
if fisa.flags.enable_verifier() {
self.verify(fisa)?;
}
Ok(())
}
/// Perform dead-code elimination on the function.
pub fn dce<'a, FOI: Into<FlagsOrIsa<'a>>>(&mut self, fisa: FOI) -> CodegenResult<()> {
do_dce(&mut self.func, &mut self.domtree);
self.verify_if(fisa)?;
Ok(())
}
/// Perform constant-phi removal on the function.
pub fn remove_constant_phis<'a, FOI: Into<FlagsOrIsa<'a>>>(
&mut self,
fisa: FOI,
) -> CodegenResult<()> {
do_remove_constant_phis(&mut self.func, &mut self.domtree);
self.verify_if(fisa)?;
Ok(())
}
/// Perform pre-legalization rewrites on the function.
pub fn preopt(&mut self, isa: &dyn TargetIsa) -> CodegenResult<()> {
do_preopt(&mut self.func, isa);
self.verify_if(isa)?;
Ok(())
}
/// Perform NaN canonicalizing rewrites on the function.
pub fn canonicalize_nans(&mut self, isa: &dyn TargetIsa) -> CodegenResult<()> {
do_nan_canonicalization(&mut self.func);
self.verify_if(isa)
}
/// Run the legalizer for `isa` on the function.
pub fn legalize(&mut self, isa: &dyn TargetIsa) -> CodegenResult<()> {
// Legalization invalidates the domtree and loop_analysis by mutating the CFG.
// TODO: Avoid doing this when legalization doesn't actually mutate the CFG.
self.domtree.clear();
self.loop_analysis.clear();
// Run some specific legalizations only.
simple_legalize(&mut self.func, &mut self.cfg, isa);
self.verify_if(isa)
}
/// Compute the control flow graph.
pub fn compute_cfg(&mut self) {
self.cfg.compute(&self.func)
}
/// Compute dominator tree.
pub fn compute_domtree(&mut self) {
self.domtree.compute(&self.func, &self.cfg)
}
/// Compute the loop analysis.
pub fn compute_loop_analysis(&mut self) {
self.loop_analysis
.compute(&self.func, &self.cfg, &self.domtree)
}
/// Compute the control flow graph and dominator tree.
pub fn flowgraph(&mut self) {
self.compute_cfg();
self.compute_domtree()
}
/// Perform simple GVN on the function.
pub fn simple_gvn<'a, FOI: Into<FlagsOrIsa<'a>>>(&mut self, fisa: FOI) -> CodegenResult<()> {
do_simple_gvn(&mut self.func, &mut self.domtree);
self.verify_if(fisa)
}
/// Perform LICM on the function.
pub fn licm(&mut self, isa: &dyn TargetIsa) -> CodegenResult<()> {
do_licm(
&mut self.func,
&mut self.cfg,
&mut self.domtree,
&mut self.loop_analysis,
);
self.verify_if(isa)
}
/// Perform unreachable code elimination.
pub fn eliminate_unreachable_code<'a, FOI>(&mut self, fisa: FOI) -> CodegenResult<()>
where
FOI: Into<FlagsOrIsa<'a>>,
{
eliminate_unreachable_code(&mut self.func, &mut self.cfg, &self.domtree);
self.verify_if(fisa)
}
/// Replace all redundant loads with the known values in
/// memory. These are loads whose values were already loaded by
/// other loads earlier, as well as loads whose values were stored
/// by a store instruction to the same instruction (so-called
/// "store-to-load forwarding").
pub fn replace_redundant_loads(&mut self) -> CodegenResult<()> {
let mut analysis = AliasAnalysis::new(&self.func, &self.domtree);
analysis.compute_and_update_aliases(&mut self.func);
Ok(())
}
/// Harvest candidate left-hand sides for superoptimization with Souper.
#[cfg(feature = "souper-harvest")]
pub fn souper_harvest(
&mut self,
out: &mut std::sync::mpsc::Sender<String>,
) -> CodegenResult<()> {
do_souper_harvest(&self.func, out);
Ok(())
}
/// Run optimizations via the egraph infrastructure.
pub fn egraph_pass(&mut self) -> CodegenResult<()> {
let _tt = timing::egraph();
trace!(
"About to optimize with egraph phase:\n{}",
self.func.display()
);
self.compute_loop_analysis();
let mut alias_analysis = AliasAnalysis::new(&self.func, &self.domtree);
let mut pass = EgraphPass::new(
&mut self.func,
&self.domtree,
&self.loop_analysis,
&mut alias_analysis,
);
pass.run();
log::debug!("egraph stats: {:?}", pass.stats);
trace!("After egraph optimization:\n{}", self.func.display());
Ok(())
}
}