1 //! Cranelift compilation context and main entry point. 2 //! 3 //! When compiling many small functions, it is important to avoid repeatedly allocating and 4 //! deallocating the data structures needed for compilation. The `Context` struct is used to hold 5 //! on to memory allocations between function compilations. 6 //! 7 //! The context does not hold a `TargetIsa` instance which has to be provided as an argument 8 //! instead. This is because an ISA instance is immutable and can be used by multiple compilation 9 //! contexts concurrently. Typically, you would have one context per compilation thread and only a 10 //! single ISA instance. 11 12 use crate::alias_analysis::AliasAnalysis; 13 use crate::dominator_tree::DominatorTree; 14 use crate::egraph::EgraphPass; 15 use crate::flowgraph::ControlFlowGraph; 16 use crate::ir::Function; 17 use crate::isa::TargetIsa; 18 use crate::legalizer::simple_legalize; 19 use crate::loop_analysis::LoopAnalysis; 20 use crate::machinst::{CompiledCode, CompiledCodeStencil}; 21 use crate::nan_canonicalization::do_nan_canonicalization; 22 use crate::remove_constant_phis::do_remove_constant_phis; 23 use crate::result::{CodegenResult, CompileResult}; 24 use crate::settings::{FlagsOrIsa, OptLevel}; 25 use crate::trace; 26 use crate::unreachable_code::eliminate_unreachable_code; 27 use crate::verifier::{verify_context, VerifierErrors, VerifierResult}; 28 use crate::{timing, CompileError}; 29 #[cfg(feature = "souper-harvest")] 30 use alloc::string::String; 31 use alloc::vec::Vec; 32 use cranelift_control::ControlPlane; 33 use target_lexicon::Architecture; 34 35 #[cfg(feature = "souper-harvest")] 36 use crate::souper_harvest::do_souper_harvest; 37 38 /// Persistent data structures and compilation pipeline. 39 pub struct Context { 40 /// The function we're compiling. 41 pub func: Function, 42 43 /// The control flow graph of `func`. 44 pub cfg: ControlFlowGraph, 45 46 /// Dominator tree for `func`. 47 pub domtree: DominatorTree, 48 49 /// Loop analysis of `func`. 50 pub loop_analysis: LoopAnalysis, 51 52 /// Result of MachBackend compilation, if computed. 53 pub(crate) compiled_code: Option<CompiledCode>, 54 55 /// Flag: do we want a disassembly with the CompiledCode? 56 pub want_disasm: bool, 57 } 58 59 impl Context { 60 /// Allocate a new compilation context. 61 /// 62 /// The returned instance should be reused for compiling multiple functions in order to avoid 63 /// needless allocator thrashing. 64 pub fn new() -> Self { 65 Self::for_function(Function::new()) 66 } 67 68 /// Allocate a new compilation context with an existing Function. 69 /// 70 /// The returned instance should be reused for compiling multiple functions in order to avoid 71 /// needless allocator thrashing. 72 pub fn for_function(func: Function) -> Self { 73 Self { 74 func, 75 cfg: ControlFlowGraph::new(), 76 domtree: DominatorTree::new(), 77 loop_analysis: LoopAnalysis::new(), 78 compiled_code: None, 79 want_disasm: false, 80 } 81 } 82 83 /// Clear all data structures in this context. 84 pub fn clear(&mut self) { 85 self.func.clear(); 86 self.cfg.clear(); 87 self.domtree.clear(); 88 self.loop_analysis.clear(); 89 self.compiled_code = None; 90 self.want_disasm = false; 91 } 92 93 /// Returns the compilation result for this function, available after any `compile` function 94 /// has been called. 95 pub fn compiled_code(&self) -> Option<&CompiledCode> { 96 self.compiled_code.as_ref() 97 } 98 99 /// Returns the compilation result for this function, available after any `compile` function 100 /// has been called. 101 pub fn take_compiled_code(&mut self) -> Option<CompiledCode> { 102 self.compiled_code.take() 103 } 104 105 /// Set the flag to request a disassembly when compiling with a 106 /// `MachBackend` backend. 107 pub fn set_disasm(&mut self, val: bool) { 108 self.want_disasm = val; 109 } 110 111 /// Compile the function, and emit machine code into a `Vec<u8>`. 112 #[deprecated = "use Context::compile"] 113 pub fn compile_and_emit( 114 &mut self, 115 isa: &dyn TargetIsa, 116 mem: &mut Vec<u8>, 117 ctrl_plane: &mut ControlPlane, 118 ) -> CompileResult<&CompiledCode> { 119 let compiled_code = self.compile(isa, ctrl_plane)?; 120 mem.extend_from_slice(compiled_code.code_buffer()); 121 Ok(compiled_code) 122 } 123 124 /// Internally compiles the function into a stencil. 125 /// 126 /// Public only for testing and fuzzing purposes. 127 pub fn compile_stencil( 128 &mut self, 129 isa: &dyn TargetIsa, 130 ctrl_plane: &mut ControlPlane, 131 ) -> CodegenResult<CompiledCodeStencil> { 132 let _tt = timing::compile(); 133 134 self.verify_if(isa)?; 135 136 self.optimize(isa, ctrl_plane)?; 137 138 isa.compile_function(&self.func, &self.domtree, self.want_disasm, ctrl_plane) 139 } 140 141 /// Optimize the function, performing all compilation steps up to 142 /// but not including machine-code lowering and register 143 /// allocation. 144 /// 145 /// Public only for testing purposes. 146 pub fn optimize( 147 &mut self, 148 isa: &dyn TargetIsa, 149 ctrl_plane: &mut ControlPlane, 150 ) -> CodegenResult<()> { 151 log::debug!( 152 "Number of CLIF instructions to optimize: {}", 153 self.func.dfg.num_insts() 154 ); 155 log::debug!( 156 "Number of CLIF blocks to optimize: {}", 157 self.func.dfg.num_blocks() 158 ); 159 160 let opt_level = isa.flags().opt_level(); 161 crate::trace!( 162 "Optimizing (opt level {:?}):\n{}", 163 opt_level, 164 self.func.display() 165 ); 166 167 self.compute_cfg(); 168 if isa.flags().enable_nan_canonicalization() { 169 self.canonicalize_nans(isa)?; 170 } 171 172 self.legalize(isa)?; 173 174 self.compute_domtree(); 175 self.eliminate_unreachable_code(isa)?; 176 self.remove_constant_phis(isa)?; 177 178 self.func.dfg.resolve_all_aliases(); 179 180 if opt_level != OptLevel::None { 181 self.egraph_pass(isa, ctrl_plane)?; 182 } 183 184 Ok(()) 185 } 186 187 /// Compile the function, 188 /// 189 /// Run the function through all the passes necessary to generate 190 /// code for the target ISA represented by `isa`. The generated 191 /// machine code is not relocated. Instead, any relocations can be 192 /// obtained from `compiled_code.buffer.relocs()`. 193 /// 194 /// Performs any optimizations that are enabled, unless 195 /// `optimize()` was already invoked. 196 /// 197 /// Returns the generated machine code as well as information about 198 /// the function's code and read-only data. 199 pub fn compile( 200 &mut self, 201 isa: &dyn TargetIsa, 202 ctrl_plane: &mut ControlPlane, 203 ) -> CompileResult<&CompiledCode> { 204 let stencil = self 205 .compile_stencil(isa, ctrl_plane) 206 .map_err(|error| CompileError { 207 inner: error, 208 func: &self.func, 209 })?; 210 Ok(self 211 .compiled_code 212 .insert(stencil.apply_params(&self.func.params))) 213 } 214 215 /// If available, return information about the code layout in the 216 /// final machine code: the offsets (in bytes) of each basic-block 217 /// start, and all basic-block edges. 218 #[deprecated = "use CompiledCode::get_code_bb_layout"] 219 pub fn get_code_bb_layout(&self) -> Option<(Vec<usize>, Vec<(usize, usize)>)> { 220 self.compiled_code().map(CompiledCode::get_code_bb_layout) 221 } 222 223 /// Creates unwind information for the function. 224 /// 225 /// Returns `None` if the function has no unwind information. 226 #[cfg(feature = "unwind")] 227 #[deprecated = "use CompiledCode::create_unwind_info"] 228 pub fn create_unwind_info( 229 &self, 230 isa: &dyn TargetIsa, 231 ) -> CodegenResult<Option<crate::isa::unwind::UnwindInfo>> { 232 self.compiled_code().unwrap().create_unwind_info(isa) 233 } 234 235 /// Run the verifier on the function. 236 /// 237 /// Also check that the dominator tree and control flow graph are consistent with the function. 238 /// 239 /// TODO: rename to "CLIF validate" or similar. 240 pub fn verify<'a, FOI: Into<FlagsOrIsa<'a>>>(&self, fisa: FOI) -> VerifierResult<()> { 241 let mut errors = VerifierErrors::default(); 242 let _ = verify_context(&self.func, &self.cfg, &self.domtree, fisa, &mut errors); 243 244 if errors.is_empty() { 245 Ok(()) 246 } else { 247 Err(errors) 248 } 249 } 250 251 /// Run the verifier only if the `enable_verifier` setting is true. 252 pub fn verify_if<'a, FOI: Into<FlagsOrIsa<'a>>>(&self, fisa: FOI) -> CodegenResult<()> { 253 let fisa = fisa.into(); 254 if fisa.flags.enable_verifier() { 255 self.verify(fisa)?; 256 } 257 Ok(()) 258 } 259 260 /// Perform constant-phi removal on the function. 261 pub fn remove_constant_phis<'a, FOI: Into<FlagsOrIsa<'a>>>( 262 &mut self, 263 fisa: FOI, 264 ) -> CodegenResult<()> { 265 do_remove_constant_phis(&mut self.func, &mut self.domtree); 266 self.verify_if(fisa)?; 267 Ok(()) 268 } 269 270 /// Perform NaN canonicalizing rewrites on the function. 271 pub fn canonicalize_nans(&mut self, isa: &dyn TargetIsa) -> CodegenResult<()> { 272 // Currently only RiscV64 is the only arch that may not have vector support. 273 let has_vector_support = match isa.triple().architecture { 274 Architecture::Riscv64(_) => match isa.isa_flags().iter().find(|f| f.name == "has_v") { 275 Some(value) => value.as_bool().unwrap_or(false), 276 None => false, 277 }, 278 _ => true, 279 }; 280 do_nan_canonicalization(&mut self.func, has_vector_support); 281 self.verify_if(isa) 282 } 283 284 /// Run the legalizer for `isa` on the function. 285 pub fn legalize(&mut self, isa: &dyn TargetIsa) -> CodegenResult<()> { 286 // Legalization invalidates the domtree and loop_analysis by mutating the CFG. 287 // TODO: Avoid doing this when legalization doesn't actually mutate the CFG. 288 self.domtree.clear(); 289 self.loop_analysis.clear(); 290 291 // Run some specific legalizations only. 292 simple_legalize(&mut self.func, isa); 293 self.verify_if(isa) 294 } 295 296 /// Compute the control flow graph. 297 pub fn compute_cfg(&mut self) { 298 self.cfg.compute(&self.func) 299 } 300 301 /// Compute dominator tree. 302 pub fn compute_domtree(&mut self) { 303 self.domtree.compute(&self.func, &self.cfg) 304 } 305 306 /// Compute the loop analysis. 307 pub fn compute_loop_analysis(&mut self) { 308 self.loop_analysis 309 .compute(&self.func, &self.cfg, &self.domtree) 310 } 311 312 /// Compute the control flow graph and dominator tree. 313 pub fn flowgraph(&mut self) { 314 self.compute_cfg(); 315 self.compute_domtree() 316 } 317 318 /// Perform unreachable code elimination. 319 pub fn eliminate_unreachable_code<'a, FOI>(&mut self, fisa: FOI) -> CodegenResult<()> 320 where 321 FOI: Into<FlagsOrIsa<'a>>, 322 { 323 eliminate_unreachable_code(&mut self.func, &mut self.cfg, &self.domtree); 324 self.verify_if(fisa) 325 } 326 327 /// Replace all redundant loads with the known values in 328 /// memory. These are loads whose values were already loaded by 329 /// other loads earlier, as well as loads whose values were stored 330 /// by a store instruction to the same instruction (so-called 331 /// "store-to-load forwarding"). 332 pub fn replace_redundant_loads(&mut self) -> CodegenResult<()> { 333 let mut analysis = AliasAnalysis::new(&self.func, &self.domtree); 334 analysis.compute_and_update_aliases(&mut self.func); 335 Ok(()) 336 } 337 338 /// Harvest candidate left-hand sides for superoptimization with Souper. 339 #[cfg(feature = "souper-harvest")] 340 pub fn souper_harvest( 341 &mut self, 342 out: &mut std::sync::mpsc::Sender<String>, 343 ) -> CodegenResult<()> { 344 do_souper_harvest(&self.func, out); 345 Ok(()) 346 } 347 348 /// Run optimizations via the egraph infrastructure. 349 pub fn egraph_pass<'a, FOI>( 350 &mut self, 351 fisa: FOI, 352 ctrl_plane: &mut ControlPlane, 353 ) -> CodegenResult<()> 354 where 355 FOI: Into<FlagsOrIsa<'a>>, 356 { 357 let _tt = timing::egraph(); 358 359 trace!( 360 "About to optimize with egraph phase:\n{}", 361 self.func.display() 362 ); 363 let fisa = fisa.into(); 364 self.compute_loop_analysis(); 365 let mut alias_analysis = AliasAnalysis::new(&self.func, &self.domtree); 366 let mut pass = EgraphPass::new( 367 &mut self.func, 368 &self.domtree, 369 &self.loop_analysis, 370 &mut alias_analysis, 371 &fisa.flags, 372 ctrl_plane, 373 ); 374 pass.run(); 375 log::debug!("egraph stats: {:?}", pass.stats); 376 trace!("After egraph optimization:\n{}", self.func.display()); 377 378 self.verify_if(fisa) 379 } 380 } 381