package compiler import ( "go/types" "strconv" "golang.org/x/tools/go/ssa" "tinygo.org/x/go-llvm" ) // For a description of the calling convention in prose, see: // https://tinygo.org/compiler-internals/calling-convention/ // The maximum number of arguments that can be expanded from a single struct. If // a struct contains more fields, it is passed as a struct without expanding. const maxFieldsPerParam = 3 // paramInfo contains some information collected about a function parameter, // useful while declaring or defining a function. type paramInfo struct { llvmType llvm.Type name string // name, possibly with suffixes for e.g. struct fields elemSize uint64 // size of pointer element type, or 0 if this isn't a pointer } // paramFlags identifies parameter attributes for flags. Most importantly, it // determines which parameters are dereferenceable_or_null and which aren't. type paramFlags uint8 const ( // Parameter may have the deferenceable_or_null attribute. This attribute // cannot be applied to unsafe.Pointer and to the data pointer of slices. paramIsDeferenceableOrNull = 1 << iota ) // createRuntimeCallCommon creates a runtime call. Use createRuntimeCall or // createRuntimeInvoke instead. func (b *builder) createRuntimeCallCommon(fnName string, args []llvm.Value, name string, isInvoke bool) llvm.Value { fn := b.program.ImportedPackage("runtime").Members[fnName].(*ssa.Function) fnType, llvmFn := b.getFunction(fn) if llvmFn.IsNil() { panic("trying to call non-existent function: " + fn.RelString(nil)) } args = append(args, llvm.Undef(b.i8ptrType)) // unused context parameter if isInvoke { return b.createInvoke(fnType, llvmFn, args, name) } return b.createCall(fnType, llvmFn, args, name) } // createRuntimeCall creates a new call to runtime. with the given // arguments. func (b *builder) createRuntimeCall(fnName string, args []llvm.Value, name string) llvm.Value { return b.createRuntimeCallCommon(fnName, args, name, false) } // createRuntimeInvoke creates a new call to runtime. with the given // arguments. If the runtime call panics, control flow is diverted to the // landing pad block. // Note that "invoke" here is meant in the LLVM sense (a call that can // panic/throw), not in the Go sense (an interface method call). func (b *builder) createRuntimeInvoke(fnName string, args []llvm.Value, name string) llvm.Value { return b.createRuntimeCallCommon(fnName, args, name, true) } // createCall creates a call to the given function with the arguments possibly // expanded. func (b *builder) createCall(fnType llvm.Type, fn llvm.Value, args []llvm.Value, name string) llvm.Value { expanded := make([]llvm.Value, 0, len(args)) for _, arg := range args { fragments := b.expandFormalParam(arg) expanded = append(expanded, fragments...) } return b.CreateCall(fnType, fn, expanded, name) } // createInvoke is like createCall but continues execution at the landing pad if // the call resulted in a panic. func (b *builder) createInvoke(fnType llvm.Type, fn llvm.Value, args []llvm.Value, name string) llvm.Value { if b.hasDeferFrame() { b.createInvokeCheckpoint() } return b.createCall(fnType, fn, args, name) } // Expand an argument type to a list that can be used in a function call // parameter list. func (c *compilerContext) expandFormalParamType(t llvm.Type, name string, goType types.Type) []paramInfo { switch t.TypeKind() { case llvm.StructTypeKind: fieldInfos := c.flattenAggregateType(t, name, goType) if len(fieldInfos) <= maxFieldsPerParam { // managed to expand this parameter return fieldInfos } // failed to expand this parameter: too many fields } // TODO: split small arrays return []paramInfo{c.getParamInfo(t, name, goType)} } // expandFormalParamOffsets returns a list of offsets from the start of an // object of type t after it would have been split up by expandFormalParam. This // is useful for debug information, where it is necessary to know the offset // from the start of the combined object. func (b *builder) expandFormalParamOffsets(t llvm.Type) []uint64 { switch t.TypeKind() { case llvm.StructTypeKind: fields := b.flattenAggregateTypeOffsets(t) if len(fields) <= maxFieldsPerParam { return fields } else { // failed to lower return []uint64{0} } default: // TODO: split small arrays return []uint64{0} } } // expandFormalParam splits a formal param value into pieces, so it can be // passed directly as part of a function call. For example, it splits up small // structs into individual fields. It is the equivalent of expandFormalParamType // for parameter values. func (b *builder) expandFormalParam(v llvm.Value) []llvm.Value { switch v.Type().TypeKind() { case llvm.StructTypeKind: fieldInfos := b.flattenAggregateType(v.Type(), "", nil) if len(fieldInfos) <= maxFieldsPerParam { fields := b.flattenAggregate(v) if len(fields) != len(fieldInfos) { panic("type and value param lowering don't match") } return fields } else { // failed to lower return []llvm.Value{v} } default: // TODO: split small arrays return []llvm.Value{v} } } // Try to flatten a struct type to a list of types. Returns a 1-element slice // with the passed in type if this is not possible. func (c *compilerContext) flattenAggregateType(t llvm.Type, name string, goType types.Type) []paramInfo { switch t.TypeKind() { case llvm.StructTypeKind: var paramInfos []paramInfo for i, subfield := range t.StructElementTypes() { if c.targetData.TypeAllocSize(subfield) == 0 { continue } suffix := strconv.Itoa(i) if goType != nil { // Try to come up with a good suffix for this struct field, // depending on which Go type it's based on. switch goType := goType.Underlying().(type) { case *types.Interface: suffix = []string{"typecode", "value"}[i] case *types.Slice: suffix = []string{"data", "len", "cap"}[i] case *types.Struct: suffix = goType.Field(i).Name() case *types.Basic: switch goType.Kind() { case types.Complex64, types.Complex128: suffix = []string{"r", "i"}[i] case types.String: suffix = []string{"data", "len"}[i] } case *types.Signature: suffix = []string{"context", "funcptr"}[i] } } subInfos := c.flattenAggregateType(subfield, name+"."+suffix, extractSubfield(goType, i)) paramInfos = append(paramInfos, subInfos...) } return paramInfos default: return []paramInfo{c.getParamInfo(t, name, goType)} } } // getParamInfo collects information about a parameter. For example, if this // parameter is pointer-like, it will also store the element type for the // dereferenceable_or_null attribute. func (c *compilerContext) getParamInfo(t llvm.Type, name string, goType types.Type) paramInfo { info := paramInfo{ llvmType: t, name: name, } if goType != nil { switch underlying := goType.Underlying().(type) { case *types.Pointer: // Pointers in Go must either point to an object or be nil. info.elemSize = c.targetData.TypeAllocSize(c.getLLVMType(underlying.Elem())) case *types.Chan: // Channels are implemented simply as a *runtime.channel. info.elemSize = c.targetData.TypeAllocSize(c.getLLVMRuntimeType("channel")) case *types.Map: // Maps are similar to channels: they are implemented as a // *runtime.hashmap. info.elemSize = c.targetData.TypeAllocSize(c.getLLVMRuntimeType("hashmap")) } } return info } // extractSubfield extracts a field from a struct, or returns null if this is // not a struct and thus no subfield can be obtained. func extractSubfield(t types.Type, field int) types.Type { if t == nil { return nil } switch t := t.Underlying().(type) { case *types.Struct: return t.Field(field).Type() case *types.Interface, *types.Slice, *types.Basic, *types.Signature: // These Go types are (sometimes) implemented as LLVM structs but can't // really be split further up in Go (with the possible exception of // complex numbers). return nil default: // This should be unreachable. panic("cannot split subfield: " + t.String()) } } // flattenAggregateTypeOffsets returns the offsets from the start of an object of // type t if this object were flattened like in flattenAggregate. Used together // with flattenAggregate to know the start indices of each value in the // non-flattened object. // // Note: this is an implementation detail, use expandFormalParamOffsets instead. func (c *compilerContext) flattenAggregateTypeOffsets(t llvm.Type) []uint64 { switch t.TypeKind() { case llvm.StructTypeKind: var fields []uint64 for fieldIndex, field := range t.StructElementTypes() { if c.targetData.TypeAllocSize(field) == 0 { continue } suboffsets := c.flattenAggregateTypeOffsets(field) offset := c.targetData.ElementOffset(t, fieldIndex) for i := range suboffsets { suboffsets[i] += offset } fields = append(fields, suboffsets...) } return fields default: return []uint64{0} } } // flattenAggregate breaks down a struct into its elementary values for argument // passing. It is the value equivalent of flattenAggregateType func (b *builder) flattenAggregate(v llvm.Value) []llvm.Value { switch v.Type().TypeKind() { case llvm.StructTypeKind: var fields []llvm.Value for i, field := range v.Type().StructElementTypes() { if b.targetData.TypeAllocSize(field) == 0 { continue } subfield := b.CreateExtractValue(v, i, "") subfields := b.flattenAggregate(subfield) fields = append(fields, subfields...) } return fields default: return []llvm.Value{v} } } // collapseFormalParam combines an aggregate object back into the original // value. This is used to join multiple LLVM parameters into a single Go value // in the function entry block. func (b *builder) collapseFormalParam(t llvm.Type, fields []llvm.Value) llvm.Value { param, remaining := b.collapseFormalParamInternal(t, fields) if len(remaining) != 0 { panic("failed to expand back all fields") } return param } // collapseFormalParamInternal is an implementation detail of // collapseFormalParam: it works by recursing until there are no fields left. func (b *builder) collapseFormalParamInternal(t llvm.Type, fields []llvm.Value) (llvm.Value, []llvm.Value) { switch t.TypeKind() { case llvm.StructTypeKind: flattened := b.flattenAggregateType(t, "", nil) if len(flattened) <= maxFieldsPerParam { value := llvm.ConstNull(t) for i, subtyp := range t.StructElementTypes() { if b.targetData.TypeAllocSize(subtyp) == 0 { continue } structField, remaining := b.collapseFormalParamInternal(subtyp, fields) fields = remaining value = b.CreateInsertValue(value, structField, i, "") } return value, fields } else { // this struct was not flattened return fields[0], fields[1:] } default: return fields[0], fields[1:] } }