// Copyright 2017 The Bazel Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package starlarkstruct defines the Starlark types 'struct' and // 'module', both optional language extensions. // package starlarkstruct // import "go.starlark.net/starlarkstruct" // It is tempting to introduce a variant of Struct that is a wrapper // around a Go struct value, for stronger typing guarantees and more // efficient and convenient field lookup. However: // 1) all fields of Starlark structs are optional, so we cannot represent // them using more specific types such as String, Int, *Depset, and // *File, as such types give no way to represent missing fields. // 2) the efficiency gain of direct struct field access is rather // marginal: finding the index of a field by binary searching on the // sorted list of field names is quite fast compared to the other // overheads. // 3) the gains in compactness and spatial locality are also rather // marginal: the array behind the []entry slice is (due to field name // strings) only a factor of 2 larger than the corresponding Go struct // would be, and, like the Go struct, requires only a single allocation. import ( "fmt" "sort" "strings" "go.starlark.net/starlark" "go.starlark.net/syntax" ) // Make is the implementation of a built-in function that instantiates // an immutable struct from the specified keyword arguments. // // An application can add 'struct' to the Starlark environment like so: // // globals := starlark.StringDict{ // "struct": starlark.NewBuiltin("struct", starlarkstruct.Make), // } // func Make(_ *starlark.Thread, _ *starlark.Builtin, args starlark.Tuple, kwargs []starlark.Tuple) (starlark.Value, error) { if len(args) > 0 { return nil, fmt.Errorf("struct: unexpected positional arguments") } return FromKeywords(Default, kwargs), nil } // FromKeywords returns a new struct instance whose fields are specified by the // key/value pairs in kwargs. (Each kwargs[i][0] must be a starlark.String.) func FromKeywords(constructor starlark.Value, kwargs []starlark.Tuple) *Struct { if constructor == nil { panic("nil constructor") } s := &Struct{ constructor: constructor, entries: make(entries, 0, len(kwargs)), } for _, kwarg := range kwargs { k := string(kwarg[0].(starlark.String)) v := kwarg[1] s.entries = append(s.entries, entry{k, v}) } sort.Sort(s.entries) return s } // FromStringDict returns a whose elements are those of d. // The constructor parameter specifies the constructor; use Default for an ordinary struct. func FromStringDict(constructor starlark.Value, d starlark.StringDict) *Struct { if constructor == nil { panic("nil constructor") } s := &Struct{ constructor: constructor, entries: make(entries, 0, len(d)), } for k, v := range d { s.entries = append(s.entries, entry{k, v}) } sort.Sort(s.entries) return s } // Struct is an immutable Starlark type that maps field names to values. // It is not iterable and does not support len. // // A struct has a constructor, a distinct value that identifies a class // of structs, and which appears in the struct's string representation. // // Operations such as x+y fail if the constructors of the two operands // are not equal. // // The default constructor, Default, is the string "struct", but // clients may wish to 'brand' structs for their own purposes. // The constructor value appears in the printed form of the value, // and is accessible using the Constructor method. // // Use Attr to access its fields and AttrNames to enumerate them. type Struct struct { constructor starlark.Value entries entries // sorted by name } // Default is the default constructor for structs. // It is merely the string "struct". const Default = starlark.String("struct") type entries []entry func (a entries) Len() int { return len(a) } func (a entries) Less(i, j int) bool { return a[i].name < a[j].name } func (a entries) Swap(i, j int) { a[i], a[j] = a[j], a[i] } type entry struct { name string value starlark.Value } var ( _ starlark.HasAttrs = (*Struct)(nil) _ starlark.HasBinary = (*Struct)(nil) ) // ToStringDict adds a name/value entry to d for each field of the struct. func (s *Struct) ToStringDict(d starlark.StringDict) { for _, e := range s.entries { d[e.name] = e.value } } func (s *Struct) String() string { buf := new(strings.Builder) if s.constructor == Default { // NB: The Java implementation always prints struct // even for Bazel provider instances. buf.WriteString("struct") // avoid String()'s quotation } else { buf.WriteString(s.constructor.String()) } buf.WriteByte('(') for i, e := range s.entries { if i > 0 { buf.WriteString(", ") } buf.WriteString(e.name) buf.WriteString(" = ") buf.WriteString(e.value.String()) } buf.WriteByte(')') return buf.String() } // Constructor returns the constructor used to create this struct. func (s *Struct) Constructor() starlark.Value { return s.constructor } func (s *Struct) Type() string { return "struct" } func (s *Struct) Truth() starlark.Bool { return true } // even when empty func (s *Struct) Hash() (uint32, error) { // Same algorithm as Tuple.hash, but with different primes. var x, m uint32 = 8731, 9839 for _, e := range s.entries { namehash, _ := starlark.String(e.name).Hash() x = x ^ 3*namehash y, err := e.value.Hash() if err != nil { return 0, err } x = x ^ y*m m += 7349 } return x, nil } func (s *Struct) Freeze() { for _, e := range s.entries { e.value.Freeze() } } func (x *Struct) Binary(op syntax.Token, y starlark.Value, side starlark.Side) (starlark.Value, error) { if y, ok := y.(*Struct); ok && op == syntax.PLUS { if side == starlark.Right { x, y = y, x } if eq, err := starlark.Equal(x.constructor, y.constructor); err != nil { return nil, fmt.Errorf("in %s + %s: error comparing constructors: %v", x.constructor, y.constructor, err) } else if !eq { return nil, fmt.Errorf("cannot add structs of different constructors: %s + %s", x.constructor, y.constructor) } z := make(starlark.StringDict, x.len()+y.len()) for _, e := range x.entries { z[e.name] = e.value } for _, e := range y.entries { z[e.name] = e.value } return FromStringDict(x.constructor, z), nil } return nil, nil // unhandled } // Attr returns the value of the specified field. func (s *Struct) Attr(name string) (starlark.Value, error) { // Binary search the entries. // This implementation is a specialization of // sort.Search that avoids dynamic dispatch. n := len(s.entries) i, j := 0, n for i < j { h := int(uint(i+j) >> 1) if s.entries[h].name < name { i = h + 1 } else { j = h } } if i < n && s.entries[i].name == name { return s.entries[i].value, nil } var ctor string if s.constructor != Default { ctor = s.constructor.String() + " " } return nil, starlark.NoSuchAttrError( fmt.Sprintf("%sstruct has no .%s attribute", ctor, name)) } func (s *Struct) len() int { return len(s.entries) } // AttrNames returns a new sorted list of the struct fields. func (s *Struct) AttrNames() []string { names := make([]string, len(s.entries)) for i, e := range s.entries { names[i] = e.name } return names } func (x *Struct) CompareSameType(op syntax.Token, y_ starlark.Value, depth int) (bool, error) { y := y_.(*Struct) switch op { case syntax.EQL: return structsEqual(x, y, depth) case syntax.NEQ: eq, err := structsEqual(x, y, depth) return !eq, err default: return false, fmt.Errorf("%s %s %s not implemented", x.Type(), op, y.Type()) } } func structsEqual(x, y *Struct, depth int) (bool, error) { if x.len() != y.len() { return false, nil } if eq, err := starlark.Equal(x.constructor, y.constructor); err != nil { return false, fmt.Errorf("error comparing struct constructors %v and %v: %v", x.constructor, y.constructor, err) } else if !eq { return false, nil } for i, n := 0, x.len(); i < n; i++ { if x.entries[i].name != y.entries[i].name { return false, nil } else if eq, err := starlark.EqualDepth(x.entries[i].value, y.entries[i].value, depth-1); err != nil { return false, err } else if !eq { return false, nil } } return true, nil }