package transform // This file provides function to lower interface intrinsics to their final LLVM // form, optimizing them in the process. // // During SSA construction, the following pseudo-call is created (see // src/runtime/interface.go): // runtime.typeAssert(typecode, assertedType) // Additionally, interface type asserts and interface invoke functions are // declared but not defined, so the optimizer will leave them alone. // // This pass lowers these functions to their final form: // // typeAssert: // Replaced with an icmp instruction so it can be directly used in a type // switch. This is very easy to optimize for LLVM: it will often translate a // type switch into a regular switch statement. // // interface type assert: // These functions are defined by creating a big type switch over all the // concrete types implementing this interface. // // interface invoke: // These functions are defined with a similar type switch, but instead of // checking for the appropriate type, these functions will call the // underlying method instead. // // Note that this way of implementing interfaces is very different from how the // main Go compiler implements them. For more details on how the main Go // compiler does it: https://research.swtch.com/interfaces import ( "sort" "strings" "github.com/tinygo-org/tinygo/compileopts" "tinygo.org/x/go-llvm" ) // signatureInfo is a Go signature of an interface method. It does not represent // any method in particular. type signatureInfo struct { name string methods []*methodInfo interfaces []*interfaceInfo } // methodInfo describes a single method on a concrete type. type methodInfo struct { *signatureInfo function llvm.Value } // typeInfo describes a single concrete Go type, which can be a basic or a named // type. If it is a named type, it may have methods. type typeInfo struct { name string typecode llvm.Value methodSet llvm.Value methods []*methodInfo } // getMethod looks up the method on this type with the given signature and // returns it. The method must exist on this type, otherwise getMethod will // panic. func (t *typeInfo) getMethod(signature *signatureInfo) *methodInfo { for _, method := range t.methods { if method.signatureInfo == signature { return method } } panic("could not find method") } // interfaceInfo keeps information about a Go interface type, including all // methods it has. type interfaceInfo struct { name string // "tinygo-methods" attribute signatures map[string]*signatureInfo // method set types []*typeInfo // types this interface implements } // lowerInterfacesPass keeps state related to the interface lowering pass. The // pass has been implemented as an object type because of its complexity, but // should be seen as a regular function call (see LowerInterfaces). type lowerInterfacesPass struct { mod llvm.Module config *compileopts.Config builder llvm.Builder dibuilder *llvm.DIBuilder difiles map[string]llvm.Metadata ctx llvm.Context uintptrType llvm.Type types map[string]*typeInfo signatures map[string]*signatureInfo interfaces map[string]*interfaceInfo } // LowerInterfaces lowers all intermediate interface calls and globals that are // emitted by the compiler as higher-level intrinsics. They need some lowering // before LLVM can work on them. This is done so that a few cleanup passes can // run before assigning the final type codes. func LowerInterfaces(mod llvm.Module, config *compileopts.Config) error { targetData := llvm.NewTargetData(mod.DataLayout()) defer targetData.Dispose() p := &lowerInterfacesPass{ mod: mod, config: config, builder: mod.Context().NewBuilder(), ctx: mod.Context(), uintptrType: mod.Context().IntType(targetData.PointerSize() * 8), types: make(map[string]*typeInfo), signatures: make(map[string]*signatureInfo), interfaces: make(map[string]*interfaceInfo), } defer p.builder.Dispose() if config.Debug() { p.dibuilder = llvm.NewDIBuilder(mod) defer p.dibuilder.Destroy() defer p.dibuilder.Finalize() p.difiles = make(map[string]llvm.Metadata) } return p.run() } // run runs the pass itself. func (p *lowerInterfacesPass) run() error { if p.dibuilder != nil { p.dibuilder.CreateCompileUnit(llvm.DICompileUnit{ Language: 0xb, // DW_LANG_C99 (0xc, off-by-one?) File: "", Dir: "", Producer: "TinyGo", Optimized: true, }) } // Collect all type codes. for global := p.mod.FirstGlobal(); !global.IsNil(); global = llvm.NextGlobal(global) { if strings.HasPrefix(global.Name(), "reflect/types.type:") { // Retrieve Go type information based on an opaque global variable. // Only the name of the global is relevant, the object itself is // discarded afterwards. name := strings.TrimPrefix(global.Name(), "reflect/types.type:") if _, ok := p.types[name]; !ok { t := &typeInfo{ name: name, typecode: global, } p.types[name] = t initializer := global.Initializer() if initializer.IsNil() { continue } methodSet := llvm.ConstExtractValue(initializer, []uint32{2}) p.addTypeMethods(t, methodSet) } } } // Find all interface type asserts and interface method thunks. var interfaceAssertFunctions []llvm.Value var interfaceInvokeFunctions []llvm.Value for fn := p.mod.FirstFunction(); !fn.IsNil(); fn = llvm.NextFunction(fn) { methodsAttr := fn.GetStringAttributeAtIndex(-1, "tinygo-methods") if methodsAttr.IsNil() { continue } if !hasUses(fn) { // Don't bother defining this function. continue } p.addInterface(methodsAttr.GetStringValue()) invokeAttr := fn.GetStringAttributeAtIndex(-1, "tinygo-invoke") if invokeAttr.IsNil() { // Type assert. interfaceAssertFunctions = append(interfaceAssertFunctions, fn) } else { // Interface invoke. interfaceInvokeFunctions = append(interfaceInvokeFunctions, fn) } } // Find all the interfaces that are implemented per type. for _, t := range p.types { // This type has no methods, so don't spend time calculating them. if len(t.methods) == 0 { continue } // Pre-calculate a set of signatures that this type has, for easy // lookup/check. typeSignatureSet := make(map[*signatureInfo]struct{}) for _, method := range t.methods { typeSignatureSet[method.signatureInfo] = struct{}{} } // A set of interfaces, mapped from the name to the info. // When the name maps to a nil pointer, one of the methods of this type // exists in the given interface but not all of them so this type // doesn't implement the interface. satisfiesInterfaces := make(map[string]*interfaceInfo) for _, method := range t.methods { for _, itf := range method.interfaces { if _, ok := satisfiesInterfaces[itf.name]; ok { // interface already checked with a different method continue } // check whether this interface satisfies this type satisfies := true for _, itfSignature := range itf.signatures { if _, ok := typeSignatureSet[itfSignature]; !ok { satisfiesInterfaces[itf.name] = nil // does not satisfy satisfies = false break } } if !satisfies { continue } satisfiesInterfaces[itf.name] = itf } } // Add this type to all interfaces that satisfy this type. for _, itf := range satisfiesInterfaces { if itf == nil { // Interface does not implement this type, but one of the // methods on this type also exists on the interface. continue } itf.types = append(itf.types, t) } } // Sort all types added to the interfaces. for _, itf := range p.interfaces { sort.Slice(itf.types, func(i, j int) bool { return itf.types[i].name > itf.types[j].name }) } // Define all interface invoke thunks. for _, fn := range interfaceInvokeFunctions { methodsAttr := fn.GetStringAttributeAtIndex(-1, "tinygo-methods") invokeAttr := fn.GetStringAttributeAtIndex(-1, "tinygo-invoke") itf := p.interfaces[methodsAttr.GetStringValue()] signature := itf.signatures[invokeAttr.GetStringValue()] p.defineInterfaceMethodFunc(fn, itf, signature) } // Define all interface type assert functions. for _, fn := range interfaceAssertFunctions { methodsAttr := fn.GetStringAttributeAtIndex(-1, "tinygo-methods") itf := p.interfaces[methodsAttr.GetStringValue()] p.defineInterfaceImplementsFunc(fn, itf) } // Replace each type assert with an actual type comparison or (if the type // assert is impossible) the constant false. llvmFalse := llvm.ConstInt(p.ctx.Int1Type(), 0, false) for _, use := range getUses(p.mod.NamedFunction("runtime.typeAssert")) { actualType := use.Operand(0) name := strings.TrimPrefix(use.Operand(1).Name(), "reflect/types.typeid:") if t, ok := p.types[name]; ok { // The type exists in the program, so lower to a regular integer // comparison. p.builder.SetInsertPointBefore(use) commaOk := p.builder.CreateICmp(llvm.IntEQ, llvm.ConstPtrToInt(t.typecode, p.uintptrType), actualType, "typeassert.ok") use.ReplaceAllUsesWith(commaOk) } else { // The type does not exist in the program, so lower to a constant // false. This is trivially further optimized. // TODO: eventually it'll be necessary to handle reflect.PtrTo and // reflect.New calls which create new types not present in the // original program. use.ReplaceAllUsesWith(llvmFalse) } use.EraseFromParentAsInstruction() } // Remove all method sets, which are now unnecessary and inhibit later // optimizations if they are left in place. Also remove references to the // interface type assert functions just to be sure. zeroUintptr := llvm.ConstNull(p.uintptrType) for _, t := range p.types { initializer := t.typecode.Initializer() methodSet := llvm.ConstExtractValue(initializer, []uint32{2}) initializer = llvm.ConstInsertValue(initializer, llvm.ConstNull(methodSet.Type()), []uint32{2}) initializer = llvm.ConstInsertValue(initializer, zeroUintptr, []uint32{4}) t.typecode.SetInitializer(initializer) } return nil } // addTypeMethods reads the method set of the given type info struct. It // retrieves the signatures and the references to the method functions // themselves for later type<->interface matching. func (p *lowerInterfacesPass) addTypeMethods(t *typeInfo, methodSet llvm.Value) { if !t.methodSet.IsNil() || methodSet.IsNull() { // no methods or methods already read return } methodSet = methodSet.Operand(0) // get global from GEP // This type has methods, collect all methods of this type. t.methodSet = methodSet set := methodSet.Initializer() // get value from global for i := 0; i < set.Type().ArrayLength(); i++ { methodData := llvm.ConstExtractValue(set, []uint32{uint32(i)}) signatureGlobal := llvm.ConstExtractValue(methodData, []uint32{0}) signatureName := signatureGlobal.Name() function := llvm.ConstExtractValue(methodData, []uint32{1}).Operand(0) signature := p.getSignature(signatureName) method := &methodInfo{ function: function, signatureInfo: signature, } signature.methods = append(signature.methods, method) t.methods = append(t.methods, method) } } // addInterface reads information about an interface, which is the // fully-qualified name and the signatures of all methods it has. func (p *lowerInterfacesPass) addInterface(methodsString string) { if _, ok := p.interfaces[methodsString]; ok { return } t := &interfaceInfo{ name: methodsString, signatures: make(map[string]*signatureInfo), } p.interfaces[methodsString] = t for _, method := range strings.Split(methodsString, "; ") { signature := p.getSignature(method) signature.interfaces = append(signature.interfaces, t) t.signatures[method] = signature } } // getSignature returns a new *signatureInfo, creating it if it doesn't already // exist. func (p *lowerInterfacesPass) getSignature(name string) *signatureInfo { if _, ok := p.signatures[name]; !ok { p.signatures[name] = &signatureInfo{ name: name, } } return p.signatures[name] } // defineInterfaceImplementsFunc defines the interface type assert function. It // checks whether the given interface type (passed as an argument) is one of the // types it implements. // // The type match is implemented using an if/else chain over all possible types. // This if/else chain is easily converted to a big switch over all possible // types by the LLVM simplifycfg pass. func (p *lowerInterfacesPass) defineInterfaceImplementsFunc(fn llvm.Value, itf *interfaceInfo) { // Create the function and function signature. fn.Param(0).SetName("actualType") fn.SetLinkage(llvm.InternalLinkage) fn.SetUnnamedAddr(true) AddStandardAttributes(fn, p.config) // Start the if/else chain at the entry block. entry := p.ctx.AddBasicBlock(fn, "entry") thenBlock := p.ctx.AddBasicBlock(fn, "then") p.builder.SetInsertPointAtEnd(entry) if p.dibuilder != nil { difile := p.getDIFile("") diFuncType := p.dibuilder.CreateSubroutineType(llvm.DISubroutineType{ File: difile, }) difunc := p.dibuilder.CreateFunction(difile, llvm.DIFunction{ Name: "(Go interface assert)", File: difile, Line: 0, Type: diFuncType, LocalToUnit: true, IsDefinition: true, ScopeLine: 0, Flags: llvm.FlagPrototyped, Optimized: true, }) fn.SetSubprogram(difunc) p.builder.SetCurrentDebugLocation(0, 0, difunc, llvm.Metadata{}) } // Iterate over all possible types. Each iteration creates a new branch // either to the 'then' block (success) or the .next block, for the next // check. actualType := fn.Param(0) for _, typ := range itf.types { nextBlock := p.ctx.AddBasicBlock(fn, typ.name+".next") cmp := p.builder.CreateICmp(llvm.IntEQ, actualType, llvm.ConstPtrToInt(typ.typecode, p.uintptrType), typ.name+".icmp") p.builder.CreateCondBr(cmp, thenBlock, nextBlock) p.builder.SetInsertPointAtEnd(nextBlock) } // The builder is now inserting at the last *.next block. Once we reach // this point, all types have been checked so the type assert will have // failed. p.builder.CreateRet(llvm.ConstInt(p.ctx.Int1Type(), 0, false)) // Fill 'then' block (type assert was successful). p.builder.SetInsertPointAtEnd(thenBlock) p.builder.CreateRet(llvm.ConstInt(p.ctx.Int1Type(), 1, false)) } // defineInterfaceMethodFunc defines this thunk by calling the concrete method // of the type that implements this interface. // // Matching the actual type is implemented using an if/else chain over all // possible types. This is later converted to a switch statement by the LLVM // simplifycfg pass. func (p *lowerInterfacesPass) defineInterfaceMethodFunc(fn llvm.Value, itf *interfaceInfo, signature *signatureInfo) { context := fn.LastParam() actualType := llvm.PrevParam(context) returnType := fn.Type().ElementType().ReturnType() context.SetName("context") actualType.SetName("actualType") fn.SetLinkage(llvm.InternalLinkage) fn.SetUnnamedAddr(true) AddStandardAttributes(fn, p.config) // Collect the params that will be passed to the functions to call. // These params exclude the receiver (which may actually consist of multiple // parts). params := make([]llvm.Value, fn.ParamsCount()-3) for i := range params { params[i] = fn.Param(i + 1) } params = append(params, llvm.Undef(llvm.PointerType(p.ctx.Int8Type(), 0)), ) // Start chain in the entry block. entry := p.ctx.AddBasicBlock(fn, "entry") p.builder.SetInsertPointAtEnd(entry) if p.dibuilder != nil { difile := p.getDIFile("") diFuncType := p.dibuilder.CreateSubroutineType(llvm.DISubroutineType{ File: difile, }) difunc := p.dibuilder.CreateFunction(difile, llvm.DIFunction{ Name: "(Go interface method)", File: difile, Line: 0, Type: diFuncType, LocalToUnit: true, IsDefinition: true, ScopeLine: 0, Flags: llvm.FlagPrototyped, Optimized: true, }) fn.SetSubprogram(difunc) p.builder.SetCurrentDebugLocation(0, 0, difunc, llvm.Metadata{}) } // Define all possible functions that can be called. for _, typ := range itf.types { // Create type check (if/else). bb := p.ctx.AddBasicBlock(fn, typ.name) next := p.ctx.AddBasicBlock(fn, typ.name+".next") cmp := p.builder.CreateICmp(llvm.IntEQ, actualType, llvm.ConstPtrToInt(typ.typecode, p.uintptrType), typ.name+".icmp") p.builder.CreateCondBr(cmp, bb, next) // The function we will redirect to when the interface has this type. function := typ.getMethod(signature).function p.builder.SetInsertPointAtEnd(bb) receiver := fn.FirstParam() if receiver.Type() != function.FirstParam().Type() { // When the receiver is a pointer, it is not wrapped. This means the // i8* has to be cast to the correct pointer type of the target // function. receiver = p.builder.CreateBitCast(receiver, function.FirstParam().Type(), "") } // Check whether the called function has the same signature as would be // expected from the parameters. This can happen in rare cases when // named struct types are renamed after merging multiple LLVM modules. paramTypes := []llvm.Type{receiver.Type()} for _, param := range params { paramTypes = append(paramTypes, param.Type()) } calledFunctionType := function.Type() sig := llvm.PointerType(llvm.FunctionType(returnType, paramTypes, false), calledFunctionType.PointerAddressSpace()) if sig != function.Type() { function = p.builder.CreateBitCast(function, sig, "") } retval := p.builder.CreateCall(function, append([]llvm.Value{receiver}, params...), "") if retval.Type().TypeKind() == llvm.VoidTypeKind { p.builder.CreateRetVoid() } else { p.builder.CreateRet(retval) } // Start next comparison in the 'next' block (which is jumped to when // the type doesn't match). p.builder.SetInsertPointAtEnd(next) } // The builder now points to the last *.then block, after all types have // been checked. Call runtime.nilPanic here. // The only other possible value remaining is nil for nil interfaces. We // could panic with a different message here such as "nil interface" but // that would increase code size and "nil panic" is close enough. Most // importantly, it avoids undefined behavior when accidentally calling a // method on a nil interface. nilPanic := p.mod.NamedFunction("runtime.nilPanic") p.builder.CreateCall(nilPanic, []llvm.Value{ llvm.Undef(llvm.PointerType(p.ctx.Int8Type(), 0)), }, "") p.builder.CreateUnreachable() } func (p *lowerInterfacesPass) getDIFile(file string) llvm.Metadata { difile, ok := p.difiles[file] if !ok { difile = p.dibuilder.CreateFile(file, "") p.difiles[file] = difile } return difile }