//! Cranelift instruction builder. //! //! A `Builder` provides a convenient interface for inserting instructions into a Cranelift //! function. Many of its methods are generated from the meta language instruction definitions. use crate::ir; use crate::ir::instructions::InstructionFormat; use crate::ir::types; use crate::ir::{DataFlowGraph, InstructionData}; use crate::ir::{Inst, Opcode, Type, Value}; /// Base trait for instruction builders. /// /// The `InstBuilderBase` trait provides the basic functionality required by the methods of the /// generated `InstBuilder` trait. These methods should not normally be used directly. Use the /// methods in the `InstBuilder` trait instead. /// /// Any data type that implements `InstBuilderBase` also gets all the methods of the `InstBuilder` /// trait. pub trait InstBuilderBase<'f>: Sized { /// Get an immutable reference to the data flow graph that will hold the constructed /// instructions. fn data_flow_graph(&self) -> &DataFlowGraph; /// Get a mutable reference to the data flow graph that will hold the constructed /// instructions. fn data_flow_graph_mut(&mut self) -> &mut DataFlowGraph; /// Insert an instruction and return a reference to it, consuming the builder. /// /// The result types may depend on a controlling type variable. For non-polymorphic /// instructions with multiple results, pass `INVALID` for the `ctrl_typevar` argument. fn build(self, data: InstructionData, ctrl_typevar: Type) -> (Inst, &'f mut DataFlowGraph); } // Include trait code generated by `cranelift-codegen/meta/src/gen_inst.rs`. // // This file defines the `InstBuilder` trait as an extension of `InstBuilderBase` with methods per // instruction format and per opcode. include!(concat!(env!("OUT_DIR"), "/inst_builder.rs")); /// Any type implementing `InstBuilderBase` gets all the `InstBuilder` methods for free. impl<'f, T: InstBuilderBase<'f>> InstBuilder<'f> for T {} /// Base trait for instruction inserters. /// /// This is an alternative base trait for an instruction builder to implement. /// /// An instruction inserter can be adapted into an instruction builder by wrapping it in an /// `InsertBuilder`. This provides some common functionality for instruction builders that insert /// new instructions, as opposed to the `ReplaceBuilder` which overwrites existing instructions. pub trait InstInserterBase<'f>: Sized { /// Get an immutable reference to the data flow graph. fn data_flow_graph(&self) -> &DataFlowGraph; /// Get a mutable reference to the data flow graph. fn data_flow_graph_mut(&mut self) -> &mut DataFlowGraph; /// Insert a new instruction which belongs to the DFG. fn insert_built_inst(self, inst: Inst) -> &'f mut DataFlowGraph; } use core::marker::PhantomData; /// Builder that inserts an instruction at the current position. /// /// An `InsertBuilder` is a wrapper for an `InstInserterBase` that turns it into an instruction /// builder with some additional facilities for creating instructions that reuse existing values as /// their results. pub struct InsertBuilder<'f, IIB: InstInserterBase<'f>> { inserter: IIB, unused: PhantomData<&'f u32>, } impl<'f, IIB: InstInserterBase<'f>> InsertBuilder<'f, IIB> { /// Create a new builder which inserts instructions at `pos`. /// The `dfg` and `pos.layout` references should be from the same `Function`. pub fn new(inserter: IIB) -> Self { Self { inserter, unused: PhantomData, } } /// Reuse result values in `reuse`. /// /// Convert this builder into one that will reuse the provided result values instead of /// allocating new ones. The provided values for reuse must not be attached to anything. Any /// missing result values will be allocated as normal. /// /// The `reuse` argument is expected to be an array of `Option`. pub fn with_results(self, reuse: Array) -> InsertReuseBuilder<'f, IIB, Array> where Array: AsRef<[Option]>, { InsertReuseBuilder { inserter: self.inserter, reuse, unused: PhantomData, } } /// Reuse a single result value. /// /// Convert this into a builder that will reuse `v` as the single result value. The reused /// result value `v` must not be attached to anything. /// /// This method should only be used when building an instruction with exactly one result. Use /// `with_results()` for the more general case. pub fn with_result(self, v: Value) -> InsertReuseBuilder<'f, IIB, [Option; 1]> { // TODO: Specialize this to return a different builder that just attaches `v` instead of // calling `make_inst_results_reusing()`. self.with_results([Some(v)]) } } impl<'f, IIB: InstInserterBase<'f>> InstBuilderBase<'f> for InsertBuilder<'f, IIB> { fn data_flow_graph(&self) -> &DataFlowGraph { self.inserter.data_flow_graph() } fn data_flow_graph_mut(&mut self) -> &mut DataFlowGraph { self.inserter.data_flow_graph_mut() } fn build(mut self, data: InstructionData, ctrl_typevar: Type) -> (Inst, &'f mut DataFlowGraph) { let inst; { let dfg = self.inserter.data_flow_graph_mut(); inst = dfg.make_inst(data); dfg.make_inst_results(inst, ctrl_typevar); } (inst, self.inserter.insert_built_inst(inst)) } } /// Builder that inserts a new instruction like `InsertBuilder`, but reusing result values. pub struct InsertReuseBuilder<'f, IIB, Array> where IIB: InstInserterBase<'f>, Array: AsRef<[Option]>, { inserter: IIB, reuse: Array, unused: PhantomData<&'f u32>, } impl<'f, IIB, Array> InstBuilderBase<'f> for InsertReuseBuilder<'f, IIB, Array> where IIB: InstInserterBase<'f>, Array: AsRef<[Option]>, { fn data_flow_graph(&self) -> &DataFlowGraph { self.inserter.data_flow_graph() } fn data_flow_graph_mut(&mut self) -> &mut DataFlowGraph { self.inserter.data_flow_graph_mut() } fn build(mut self, data: InstructionData, ctrl_typevar: Type) -> (Inst, &'f mut DataFlowGraph) { let inst; { let dfg = self.inserter.data_flow_graph_mut(); inst = dfg.make_inst(data); // Make an `Iterator>`. let ru = self.reuse.as_ref().iter().cloned(); dfg.make_inst_results_reusing(inst, ctrl_typevar, ru); } (inst, self.inserter.insert_built_inst(inst)) } } /// Instruction builder that replaces an existing instruction. /// /// The inserted instruction will have the same `Inst` number as the old one. /// /// If the old instruction still has result values attached, it is assumed that the new instruction /// produces the same number and types of results. The old result values are preserved. If the /// replacement instruction format does not support multiple results, the builder panics. It is a /// bug to leave result values dangling. pub struct ReplaceBuilder<'f> { dfg: &'f mut DataFlowGraph, inst: Inst, } impl<'f> ReplaceBuilder<'f> { /// Create a `ReplaceBuilder` that will overwrite `inst`. pub fn new(dfg: &'f mut DataFlowGraph, inst: Inst) -> Self { Self { dfg, inst } } } impl<'f> InstBuilderBase<'f> for ReplaceBuilder<'f> { fn data_flow_graph(&self) -> &DataFlowGraph { self.dfg } fn data_flow_graph_mut(&mut self) -> &mut DataFlowGraph { self.dfg } fn build(self, data: InstructionData, ctrl_typevar: Type) -> (Inst, &'f mut DataFlowGraph) { // Splat the new instruction on top of the old one. self.dfg.insts[self.inst] = data; if !self.dfg.has_results(self.inst) { // The old result values were either detached or non-existent. // Construct new ones. self.dfg.make_inst_results(self.inst, ctrl_typevar); } (self.inst, self.dfg) } } #[cfg(test)] mod tests { use crate::cursor::{Cursor, FuncCursor}; use crate::ir::condcodes::*; use crate::ir::types::*; use crate::ir::{Function, InstBuilder, ValueDef}; #[test] fn types() { let mut func = Function::new(); let block0 = func.dfg.make_block(); let arg0 = func.dfg.append_block_param(block0, I32); let mut pos = FuncCursor::new(&mut func); pos.insert_block(block0); // Explicit types. let v0 = pos.ins().iconst(I32, 3); assert_eq!(pos.func.dfg.value_type(v0), I32); // Inferred from inputs. let v1 = pos.ins().iadd(arg0, v0); assert_eq!(pos.func.dfg.value_type(v1), I32); // Formula. let cmp = pos.ins().icmp(IntCC::Equal, arg0, v0); assert_eq!(pos.func.dfg.value_type(cmp), I8); } #[test] fn reuse_results() { let mut func = Function::new(); let block0 = func.dfg.make_block(); let arg0 = func.dfg.append_block_param(block0, I32); let mut pos = FuncCursor::new(&mut func); pos.insert_block(block0); let v0 = pos.ins().iadd_imm(arg0, 17); assert_eq!(pos.func.dfg.value_type(v0), I32); let iadd = pos.prev_inst().unwrap(); assert_eq!(pos.func.dfg.value_def(v0), ValueDef::Result(iadd, 0)); // Detach v0 and reuse it for a different instruction. pos.func.dfg.clear_results(iadd); let v0b = pos.ins().with_result(v0).iconst(I32, 3); assert_eq!(v0, v0b); assert_eq!(pos.current_inst(), Some(iadd)); let iconst = pos.prev_inst().unwrap(); assert!(iadd != iconst); assert_eq!(pos.func.dfg.value_def(v0), ValueDef::Result(iconst, 0)); } #[test] #[should_panic] #[cfg(debug_assertions)] fn panics_when_inserting_wrong_opcode() { use crate::ir::{Opcode, TrapCode}; let mut func = Function::new(); let block0 = func.dfg.make_block(); let mut pos = FuncCursor::new(&mut func); pos.insert_block(block0); // We are trying to create a Opcode::Return with the InstData::Trap, which is obviously wrong pos.ins() .Trap(Opcode::Return, I32, TrapCode::BAD_CONVERSION_TO_INTEGER); } }