package compiler // This file implements the 'defer' keyword in Go. // Defer statements are implemented by transforming the function in the // following way: // * Creating an alloca in the entry block that contains a pointer (initially // null) to the linked list of defer frames. // * Every time a defer statement is executed, a new defer frame is created // using alloca with a pointer to the previous defer frame, and the head // pointer in the entry block is replaced with a pointer to this defer // frame. // * On return, runtime.rundefers is called which calls all deferred functions // from the head of the linked list until it has gone through all defer // frames. import ( "github.com/tinygo-org/tinygo/ir" "golang.org/x/tools/go/ssa" "tinygo.org/x/go-llvm" ) // deferInitFunc sets up this function for future deferred calls. It must be // called from within the entry block when this function contains deferred // calls. func (c *Compiler) deferInitFunc(frame *Frame) { // Some setup. frame.deferFuncs = make(map[*ir.Function]int) frame.deferInvokeFuncs = make(map[string]int) frame.deferClosureFuncs = make(map[*ir.Function]int) // Create defer list pointer. deferType := llvm.PointerType(c.getLLVMRuntimeType("_defer"), 0) frame.deferPtr = c.builder.CreateAlloca(deferType, "deferPtr") c.builder.CreateStore(llvm.ConstPointerNull(deferType), frame.deferPtr) } // emitDefer emits a single defer instruction, to be run when this function // returns. func (c *Compiler) emitDefer(frame *Frame, instr *ssa.Defer) { // The pointer to the previous defer struct, which we will replace to // make a linked list. next := c.builder.CreateLoad(frame.deferPtr, "defer.next") var values []llvm.Value valueTypes := []llvm.Type{c.uintptrType, next.Type()} if instr.Call.IsInvoke() { // Method call on an interface. // Get callback type number. methodName := instr.Call.Method.FullName() if _, ok := frame.deferInvokeFuncs[methodName]; !ok { frame.deferInvokeFuncs[methodName] = len(frame.allDeferFuncs) frame.allDeferFuncs = append(frame.allDeferFuncs, &instr.Call) } callback := llvm.ConstInt(c.uintptrType, uint64(frame.deferInvokeFuncs[methodName]), false) // Collect all values to be put in the struct (starting with // runtime._defer fields, followed by the call parameters). itf := c.getValue(frame, instr.Call.Value) // interface receiverValue := c.builder.CreateExtractValue(itf, 1, "invoke.func.receiver") values = []llvm.Value{callback, next, receiverValue} valueTypes = append(valueTypes, c.i8ptrType) for _, arg := range instr.Call.Args { val := c.getValue(frame, arg) values = append(values, val) valueTypes = append(valueTypes, val.Type()) } } else if callee, ok := instr.Call.Value.(*ssa.Function); ok { // Regular function call. fn := c.ir.GetFunction(callee) if _, ok := frame.deferFuncs[fn]; !ok { frame.deferFuncs[fn] = len(frame.allDeferFuncs) frame.allDeferFuncs = append(frame.allDeferFuncs, fn) } callback := llvm.ConstInt(c.uintptrType, uint64(frame.deferFuncs[fn]), false) // Collect all values to be put in the struct (starting with // runtime._defer fields). values = []llvm.Value{callback, next} for _, param := range instr.Call.Args { llvmParam := c.getValue(frame, param) values = append(values, llvmParam) valueTypes = append(valueTypes, llvmParam.Type()) } } else if makeClosure, ok := instr.Call.Value.(*ssa.MakeClosure); ok { // Immediately applied function literal with free variables. // Extract the context from the closure. We won't need the function // pointer. // TODO: ignore this closure entirely and put pointers to the free // variables directly in the defer struct, avoiding a memory allocation. closure := c.getValue(frame, instr.Call.Value) context := c.builder.CreateExtractValue(closure, 0, "") // Get the callback number. fn := c.ir.GetFunction(makeClosure.Fn.(*ssa.Function)) if _, ok := frame.deferClosureFuncs[fn]; !ok { frame.deferClosureFuncs[fn] = len(frame.allDeferFuncs) frame.allDeferFuncs = append(frame.allDeferFuncs, makeClosure) } callback := llvm.ConstInt(c.uintptrType, uint64(frame.deferClosureFuncs[fn]), false) // Collect all values to be put in the struct (starting with // runtime._defer fields, followed by all parameters including the // context pointer). values = []llvm.Value{callback, next} for _, param := range instr.Call.Args { llvmParam := c.getValue(frame, param) values = append(values, llvmParam) valueTypes = append(valueTypes, llvmParam.Type()) } values = append(values, context) valueTypes = append(valueTypes, context.Type()) } else { c.addError(instr.Pos(), "todo: defer on uncommon function call type") return } // Make a struct out of the collected values to put in the defer frame. deferFrameType := c.ctx.StructType(valueTypes, false) deferFrame := llvm.ConstNull(deferFrameType) for i, value := range values { deferFrame = c.builder.CreateInsertValue(deferFrame, value, i, "") } // Put this struct in an alloca. alloca := c.builder.CreateAlloca(deferFrameType, "defer.alloca") c.builder.CreateStore(deferFrame, alloca) if c.needsStackObjects() { c.trackPointer(alloca) } // Push it on top of the linked list by replacing deferPtr. allocaCast := c.builder.CreateBitCast(alloca, next.Type(), "defer.alloca.cast") c.builder.CreateStore(allocaCast, frame.deferPtr) } // emitRunDefers emits code to run all deferred functions. func (c *Compiler) emitRunDefers(frame *Frame) { // Add a loop like the following: // for stack != nil { // _stack := stack // stack = stack.next // switch _stack.callback { // case 0: // // run first deferred call // case 1: // // run second deferred call // // etc. // default: // unreachable // } // } // Create loop. loophead := c.ctx.AddBasicBlock(frame.fn.LLVMFn, "rundefers.loophead") loop := c.ctx.AddBasicBlock(frame.fn.LLVMFn, "rundefers.loop") unreachable := c.ctx.AddBasicBlock(frame.fn.LLVMFn, "rundefers.default") end := c.ctx.AddBasicBlock(frame.fn.LLVMFn, "rundefers.end") c.builder.CreateBr(loophead) // Create loop head: // for stack != nil { c.builder.SetInsertPointAtEnd(loophead) deferData := c.builder.CreateLoad(frame.deferPtr, "") stackIsNil := c.builder.CreateICmp(llvm.IntEQ, deferData, llvm.ConstPointerNull(deferData.Type()), "stackIsNil") c.builder.CreateCondBr(stackIsNil, end, loop) // Create loop body: // _stack := stack // stack = stack.next // switch stack.callback { c.builder.SetInsertPointAtEnd(loop) nextStackGEP := c.builder.CreateInBoundsGEP(deferData, []llvm.Value{ llvm.ConstInt(c.ctx.Int32Type(), 0, false), llvm.ConstInt(c.ctx.Int32Type(), 1, false), // .next field }, "stack.next.gep") nextStack := c.builder.CreateLoad(nextStackGEP, "stack.next") c.builder.CreateStore(nextStack, frame.deferPtr) gep := c.builder.CreateInBoundsGEP(deferData, []llvm.Value{ llvm.ConstInt(c.ctx.Int32Type(), 0, false), llvm.ConstInt(c.ctx.Int32Type(), 0, false), // .callback field }, "callback.gep") callback := c.builder.CreateLoad(gep, "callback") sw := c.builder.CreateSwitch(callback, unreachable, len(frame.allDeferFuncs)) for i, callback := range frame.allDeferFuncs { // Create switch case, for example: // case 0: // // run first deferred call block := c.ctx.AddBasicBlock(frame.fn.LLVMFn, "rundefers.callback") sw.AddCase(llvm.ConstInt(c.uintptrType, uint64(i), false), block) c.builder.SetInsertPointAtEnd(block) switch callback := callback.(type) { case *ssa.CallCommon: // Call on an interface value. if !callback.IsInvoke() { panic("expected an invoke call, not a direct call") } // Get the real defer struct type and cast to it. valueTypes := []llvm.Type{c.uintptrType, llvm.PointerType(c.getLLVMRuntimeType("_defer"), 0), c.i8ptrType} for _, arg := range callback.Args { valueTypes = append(valueTypes, c.getLLVMType(arg.Type())) } deferFrameType := c.ctx.StructType(valueTypes, false) deferFramePtr := c.builder.CreateBitCast(deferData, llvm.PointerType(deferFrameType, 0), "deferFrame") // Extract the params from the struct (including receiver). forwardParams := []llvm.Value{} zero := llvm.ConstInt(c.ctx.Int32Type(), 0, false) for i := 2; i < len(valueTypes); i++ { gep := c.builder.CreateInBoundsGEP(deferFramePtr, []llvm.Value{zero, llvm.ConstInt(c.ctx.Int32Type(), uint64(i), false)}, "gep") forwardParam := c.builder.CreateLoad(gep, "param") forwardParams = append(forwardParams, forwardParam) } // Add the context parameter. An interface call cannot also be a // closure but we have to supply the parameter anyway for platforms // with a strict calling convention. forwardParams = append(forwardParams, llvm.Undef(c.i8ptrType)) // Parent coroutine handle. forwardParams = append(forwardParams, llvm.Undef(c.i8ptrType)) fnPtr, _ := c.getInvokeCall(frame, callback) c.createCall(fnPtr, forwardParams, "") case *ir.Function: // Direct call. // Get the real defer struct type and cast to it. valueTypes := []llvm.Type{c.uintptrType, llvm.PointerType(c.getLLVMRuntimeType("_defer"), 0)} for _, param := range callback.Params { valueTypes = append(valueTypes, c.getLLVMType(param.Type())) } deferFrameType := c.ctx.StructType(valueTypes, false) deferFramePtr := c.builder.CreateBitCast(deferData, llvm.PointerType(deferFrameType, 0), "deferFrame") // Extract the params from the struct. forwardParams := []llvm.Value{} zero := llvm.ConstInt(c.ctx.Int32Type(), 0, false) for i := range callback.Params { gep := c.builder.CreateInBoundsGEP(deferFramePtr, []llvm.Value{zero, llvm.ConstInt(c.ctx.Int32Type(), uint64(i+2), false)}, "gep") forwardParam := c.builder.CreateLoad(gep, "param") forwardParams = append(forwardParams, forwardParam) } // Add the context parameter. We know it is ignored by the receiving // function, but we have to pass one anyway. forwardParams = append(forwardParams, llvm.Undef(c.i8ptrType)) // Parent coroutine handle. forwardParams = append(forwardParams, llvm.Undef(c.i8ptrType)) // Call real function. c.createCall(callback.LLVMFn, forwardParams, "") case *ssa.MakeClosure: // Get the real defer struct type and cast to it. fn := c.ir.GetFunction(callback.Fn.(*ssa.Function)) valueTypes := []llvm.Type{c.uintptrType, llvm.PointerType(c.getLLVMRuntimeType("_defer"), 0)} params := fn.Signature.Params() for i := 0; i < params.Len(); i++ { valueTypes = append(valueTypes, c.getLLVMType(params.At(i).Type())) } valueTypes = append(valueTypes, c.i8ptrType) // closure deferFrameType := c.ctx.StructType(valueTypes, false) deferFramePtr := c.builder.CreateBitCast(deferData, llvm.PointerType(deferFrameType, 0), "deferFrame") // Extract the params from the struct. forwardParams := []llvm.Value{} zero := llvm.ConstInt(c.ctx.Int32Type(), 0, false) for i := 2; i < len(valueTypes); i++ { gep := c.builder.CreateInBoundsGEP(deferFramePtr, []llvm.Value{zero, llvm.ConstInt(c.ctx.Int32Type(), uint64(i), false)}, "") forwardParam := c.builder.CreateLoad(gep, "param") forwardParams = append(forwardParams, forwardParam) } // Parent coroutine handle. forwardParams = append(forwardParams, llvm.Undef(c.i8ptrType)) // Call deferred function. c.createCall(fn.LLVMFn, forwardParams, "") default: panic("unknown deferred function type") } // Branch back to the start of the loop. c.builder.CreateBr(loophead) } // Create default unreachable block: // default: // unreachable // } c.builder.SetInsertPointAtEnd(unreachable) c.builder.CreateUnreachable() // End of loop. c.builder.SetInsertPointAtEnd(end) }