// WritePackage writes to buf a human-readable summary of p. func WritePackage(buf *bytes.Buffer, p *Package) { fmt.Fprintf(buf, "%s:\n", p) var names []string maxname := 0 for name := range p.Members { if l := len(name); l > maxname { maxname = l } names = append(names, name) } sort.Strings(names) for _, name := range names { switch mem := p.Members[name].(type) { case *NamedConst: fmt.Fprintf(buf, " const %-*s %s = %s\n", maxname, name, mem.Name(), mem.Value.RelString(p.Object)) case *Function: fmt.Fprintf(buf, " func %-*s %s\n", maxname, name, types.TypeString(p.Object, mem.Type())) case *Type: fmt.Fprintf(buf, " type %-*s %s\n", maxname, name, types.TypeString(p.Object, mem.Type().Underlying())) for _, meth := range typeutil.IntuitiveMethodSet(mem.Type(), &p.Prog.MethodSets) { fmt.Fprintf(buf, " %s\n", types.SelectionString(p.Object, meth)) } case *Global: fmt.Fprintf(buf, " var %-*s %s\n", maxname, name, types.TypeString(p.Object, mem.Type().(*types.Pointer).Elem())) } } fmt.Fprintf(buf, "\n") }
// prettyFunc pretty-prints fn for the user interface. // TODO(adonovan): return HTML so we have more markup freedom. func prettyFunc(this *types.Package, fn *ssa.Function) string { if fn.Parent() != nil { return fmt.Sprintf("%s in %s", types.TypeString(this, fn.Signature), prettyFunc(this, fn.Parent())) } if fn.Synthetic != "" && fn.Name() == "init" { // (This is the actual initializer, not a declared 'func init'). if fn.Pkg.Object == this { return "package initializer" } return fmt.Sprintf("%q package initializer", fn.Pkg.Object.Path()) } return fn.RelString(this) }
func relType(t types.Type, from *types.Package) string { return types.TypeString(from, t) }
func (a *analysis) namedType(obj *types.TypeName, implements map[*types.Named]implementsFacts) { this := obj.Pkg() T := obj.Type().(*types.Named) v := &TypeInfoJSON{ Name: obj.Name(), Size: sizes.Sizeof(T), Align: sizes.Alignof(T), Methods: []anchorJSON{}, // (JS wants non-nil) } // addFact adds the fact "is implemented by T" (by) or // "implements T" (!by) to group. addFact := func(group *implGroupJSON, T types.Type, by bool) { Tobj := deref(T).(*types.Named).Obj() var byKind string if by { // Show underlying kind of implementing type, // e.g. "slice", "array", "struct". s := reflect.TypeOf(T.Underlying()).String() byKind = strings.ToLower(strings.TrimPrefix(s, "*types.")) } group.Facts = append(group.Facts, implFactJSON{ ByKind: byKind, Other: anchorJSON{ Href: a.posURL(Tobj.Pos(), len(Tobj.Name())), Text: types.TypeString(this, T), }, }) } // IMPLEMENTS if r, ok := implements[T]; ok { if isInterface(T) { // "T is implemented by <conc>" ... // "T is implemented by <iface>"... // "T implements <iface>"... group := implGroupJSON{ Descr: types.TypeString(this, T), } // Show concrete types first; use two passes. for _, sub := range r.to { if !isInterface(sub) { addFact(&group, sub, true) } } for _, sub := range r.to { if isInterface(sub) { addFact(&group, sub, true) } } for _, super := range r.from { addFact(&group, super, false) } v.ImplGroups = append(v.ImplGroups, group) } else { // T is concrete. if r.from != nil { // "T implements <iface>"... group := implGroupJSON{ Descr: types.TypeString(this, T), } for _, super := range r.from { addFact(&group, super, false) } v.ImplGroups = append(v.ImplGroups, group) } if r.fromPtr != nil { // "*C implements <iface>"... group := implGroupJSON{ Descr: "*" + types.TypeString(this, T), } for _, psuper := range r.fromPtr { addFact(&group, psuper, false) } v.ImplGroups = append(v.ImplGroups, group) } } } // METHOD SETS for _, sel := range typeutil.IntuitiveMethodSet(T, &a.prog.MethodSets) { meth := sel.Obj().(*types.Func) pos := meth.Pos() // may be 0 for error.Error v.Methods = append(v.Methods, anchorJSON{ Href: a.posURL(pos, len(meth.Name())), Text: types.SelectionString(this, sel), }) } // Since there can be many specs per decl, we // can't attach the link to the keyword 'type' // (as we do with 'func'); we use the Ident. fi, offset := a.fileAndOffset(obj.Pos()) fi.addLink(aLink{ start: offset, end: offset + len(obj.Name()), title: fmt.Sprintf("type info for %s", obj.Name()), onclick: fmt.Sprintf("onClickTypeInfo(%d)", fi.addData(v)), }) // Add info for exported package-level types to the package info. if obj.Exported() && isPackageLevel(obj) { // TODO(adonovan): this.Path() is not unique! // It is possible to declare a non-test package called x_test. a.result.pkgInfo(this.Path()).addType(v) } }