//! Cretonne 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 binemit::{relax_branches, shrink_instructions, CodeOffset, MemoryCodeSink, RelocSink, TrapSink}; use dce::do_dce; use dominator_tree::DominatorTree; use flowgraph::ControlFlowGraph; use ir::Function; use isa::TargetIsa; use legalize_function; use licm::do_licm; use loop_analysis::LoopAnalysis; use postopt::do_postopt; use preopt::do_preopt; use regalloc; use result::{CtonError, CtonResult}; use settings::{FlagsOrIsa, OptLevel}; use simple_gvn::do_simple_gvn; use timing; use unreachable_code::eliminate_unreachable_code; use verifier; /// 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, /// Register allocation context. pub regalloc: regalloc::Context, /// Loop analysis of `func`. pub loop_analysis: LoopAnalysis, } 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(), regalloc: regalloc::Context::new(), loop_analysis: LoopAnalysis::new(), } } /// Clear all data structures in this context. pub fn clear(&mut self) { self.func.clear(); self.cfg.clear(); self.domtree.clear(); self.regalloc.clear(); self.loop_analysis.clear(); } /// Compile the function, and emit machine code into a `Vec`. /// /// 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`. The machine code is not relocated. Instead, any relocations are emitted /// into `relocs`. /// /// This function calls `compile` and `emit_to_memory`, taking care to resize `mem` as /// needed, so it provides a safe interface. pub fn compile_and_emit( &mut self, isa: &TargetIsa, mem: &mut Vec, relocs: &mut RelocSink, traps: &mut TrapSink, ) -> CtonResult { let code_size = self.compile(isa)?; let old_len = mem.len(); mem.resize(old_len + code_size as usize, 0); unsafe { self.emit_to_memory( isa, mem.as_mut_ptr().offset(old_len as isize), relocs, traps, ) }; 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 the size of the function's code. pub fn compile(&mut self, isa: &TargetIsa) -> Result { let _tt = timing::compile(); self.verify_if(isa)?; self.compute_cfg(); if isa.flags().opt_level() != OptLevel::Fastest { self.preopt(isa)?; } self.legalize(isa)?; if isa.flags().opt_level() != OptLevel::Fastest { self.postopt(isa)?; } if isa.flags().opt_level() == OptLevel::Best { self.compute_domtree(); self.compute_loop_analysis(); self.licm(isa)?; self.simple_gvn(isa)?; } self.compute_domtree(); self.eliminate_unreachable_code(isa)?; if isa.flags().opt_level() != OptLevel::Fastest { self.dce(isa)?; } self.regalloc(isa)?; self.prologue_epilogue(isa)?; if isa.flags().opt_level() == OptLevel::Best { self.shrink_instructions(isa)?; } self.relax_branches(isa) } /// Emit machine code directly into raw memory. /// /// Write all of the function's machine code to the memory at `mem`. The size of the machine /// code is returned by `compile` above. /// /// The machine code is not relocated. Instead, any relocations are emitted into `relocs`. /// /// This function is unsafe since it does not perform bounds checking on the memory buffer, /// and it can't guarantee that the `mem` pointer is valid. pub unsafe fn emit_to_memory( &self, isa: &TargetIsa, mem: *mut u8, relocs: &mut RelocSink, traps: &mut TrapSink, ) { let _tt = timing::binemit(); isa.emit_function(&self.func, &mut MemoryCodeSink::new(mem, relocs, traps)); } /// 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>>(&self, fisa: FOI) -> verifier::Result { verifier::verify_context(&self.func, &self.cfg, &self.domtree, fisa) } /// Run the verifier only if the `enable_verifier` setting is true. pub fn verify_if<'a, FOI: Into>>(&self, fisa: FOI) -> CtonResult { let fisa = fisa.into(); if fisa.flags.enable_verifier() { self.verify(fisa).map_err(Into::into) } else { Ok(()) } } /// Run the locations verifier on the function. pub fn verify_locations(&self, isa: &TargetIsa) -> verifier::Result { verifier::verify_locations(isa, &self.func, None) } /// Run the locations verifier only if the `enable_verifier` setting is true. pub fn verify_locations_if(&self, isa: &TargetIsa) -> CtonResult { if isa.flags().enable_verifier() { self.verify_locations(isa).map_err(Into::into) } else { Ok(()) } } /// Perform dead-code elimination on the function. pub fn dce<'a, FOI: Into>>(&mut self, fisa: FOI) -> CtonResult { do_dce(&mut self.func, &mut self.domtree); self.verify_if(fisa)?; Ok(()) } /// Perform pre-legalization rewrites on the function. pub fn preopt(&mut self, isa: &TargetIsa) -> CtonResult { do_preopt(&mut self.func); self.verify_if(isa)?; Ok(()) } /// Run the legalizer for `isa` on the function. pub fn legalize(&mut self, isa: &TargetIsa) -> CtonResult { // 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(); legalize_function(&mut self.func, &mut self.cfg, isa); self.verify_if(isa) } /// Perform post-legalization rewrites on the function. pub fn postopt(&mut self, isa: &TargetIsa) -> CtonResult { do_postopt(&mut self.func, isa); self.verify_if(isa)?; Ok(()) } /// 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>>(&mut self, fisa: FOI) -> CtonResult { do_simple_gvn(&mut self.func, &mut self.domtree); self.verify_if(fisa) } /// Perform LICM on the function. pub fn licm<'a, FOI: Into>>(&mut self, fisa: FOI) -> CtonResult { do_licm( &mut self.func, &mut self.cfg, &mut self.domtree, &mut self.loop_analysis, ); self.verify_if(fisa) } /// Perform unreachable code elimination. pub fn eliminate_unreachable_code<'a, FOI>(&mut self, fisa: FOI) -> CtonResult where FOI: Into>, { eliminate_unreachable_code(&mut self.func, &mut self.cfg, &self.domtree); self.verify_if(fisa) } /// Run the register allocator. pub fn regalloc(&mut self, isa: &TargetIsa) -> CtonResult { self.regalloc.run( isa, &mut self.func, &self.cfg, &mut self.domtree, ) } /// Insert prologue and epilogues after computing the stack frame layout. pub fn prologue_epilogue(&mut self, isa: &TargetIsa) -> CtonResult { isa.prologue_epilogue(&mut self.func)?; self.verify_if(isa)?; self.verify_locations_if(isa)?; Ok(()) } /// Run the instruction shrinking pass. pub fn shrink_instructions(&mut self, isa: &TargetIsa) -> CtonResult { shrink_instructions(&mut self.func, isa); self.verify_if(isa)?; self.verify_locations_if(isa)?; Ok(()) } /// Run the branch relaxation pass and return the final code size. pub fn relax_branches(&mut self, isa: &TargetIsa) -> Result { let code_size = relax_branches(&mut self.func, isa)?; self.verify_if(isa)?; self.verify_locations_if(isa)?; Ok(code_size) } }