package gen import ( "io" "strconv" ) func unmarshal(w io.Writer) *unmarshalGen { return &unmarshalGen{ p: printer{w: w}, } } type unmarshalGen struct { passes p printer hasfield bool } func (u *unmarshalGen) Method() Method { return Unmarshal } func (u *unmarshalGen) needsField() { if u.hasfield { return } u.p.print("\nvar field []byte; _ = field") u.hasfield = true } func (u *unmarshalGen) Execute(p Elem) error { u.hasfield = false if !u.p.ok() { return u.p.err } p = u.applyall(p) if p == nil { return nil } if !IsPrintable(p) { return nil } u.p.comment("UnmarshalMsg implements msgp.Unmarshaler") u.p.printf("\nfunc (%s %s) UnmarshalMsg(bts []byte) (o []byte, err error) {", p.Varname(), methodReceiver(p)) next(u, p) u.p.print("\no = bts") u.p.nakedReturn() unsetReceiver(p) return u.p.err } // does assignment to the variable "name" with the type "base" func (u *unmarshalGen) assignAndCheck(name string, base string) { if !u.p.ok() { return } u.p.printf("\n%s, bts, err = msgp.Read%sBytes(bts)", name, base) u.p.print(errcheck) } func (u *unmarshalGen) gStruct(s *Struct) { if !u.p.ok() { return } if s.AsTuple { u.tuple(s) } else { u.mapstruct(s) } return } func (u *unmarshalGen) tuple(s *Struct) { // open block sz := randIdent() u.p.declare(sz, u32) u.assignAndCheck(sz, arrayHeader) u.p.arrayCheck(strconv.Itoa(len(s.Fields)), sz) for i := range s.Fields { if !u.p.ok() { return } next(u, s.Fields[i].FieldElem) } } func (u *unmarshalGen) mapstruct(s *Struct) { u.needsField() sz := randIdent() u.p.declare(sz, u32) u.assignAndCheck(sz, mapHeader) u.p.printf("\nfor %s > 0 {", sz) u.p.printf("\n%s--; field, bts, err = msgp.ReadMapKeyZC(bts)", sz) u.p.print(errcheck) u.p.print("\nswitch msgp.UnsafeString(field) {") for i := range s.Fields { if !u.p.ok() { return } u.p.printf("\ncase \"%s\":", s.Fields[i].FieldTag) next(u, s.Fields[i].FieldElem) } u.p.print("\ndefault:\nbts, err = msgp.Skip(bts)") u.p.print(errcheck) u.p.print("\n}\n}") // close switch and for loop } func (u *unmarshalGen) gBase(b *BaseElem) { if !u.p.ok() { return } refname := b.Varname() // assigned to lowered := b.Varname() // passed as argument if b.Convert { // begin 'tmp' block refname = randIdent() lowered = b.ToBase() + "(" + lowered + ")" u.p.printf("\n{\nvar %s %s", refname, b.BaseType()) } switch b.Value { case Bytes: u.p.printf("\n%s, bts, err = msgp.ReadBytesBytes(bts, %s)", refname, lowered) case Ext: u.p.printf("\nbts, err = msgp.ReadExtensionBytes(bts, %s)", lowered) case IDENT: u.p.printf("\nbts, err = %s.UnmarshalMsg(bts)", lowered) default: u.p.printf("\n%s, bts, err = msgp.Read%sBytes(bts)", refname, b.BaseName()) } if b.Convert { // close 'tmp' block u.p.printf("\n%s = %s(%s)\n}", b.Varname(), b.FromBase(), refname) } u.p.print(errcheck) } func (u *unmarshalGen) gArray(a *Array) { if !u.p.ok() { return } // special case for [const]byte objects // see decode.go for symmetry if be, ok := a.Els.(*BaseElem); ok && be.Value == Byte { u.p.printf("\nbts, err = msgp.ReadExactBytes(bts, (%s)[:])", a.Varname()) u.p.print(errcheck) return } sz := randIdent() u.p.declare(sz, u32) u.assignAndCheck(sz, arrayHeader) u.p.arrayCheck(a.Size, sz) u.p.rangeBlock(a.Index, a.Varname(), u, a.Els) } func (u *unmarshalGen) gSlice(s *Slice) { if !u.p.ok() { return } sz := randIdent() u.p.declare(sz, u32) u.assignAndCheck(sz, arrayHeader) u.p.resizeSlice(sz, s) u.p.rangeBlock(s.Index, s.Varname(), u, s.Els) } func (u *unmarshalGen) gMap(m *Map) { if !u.p.ok() { return } sz := randIdent() u.p.declare(sz, u32) u.assignAndCheck(sz, mapHeader) // allocate or clear map u.p.resizeMap(sz, m) // loop and get key,value u.p.printf("\nfor %s > 0 {", sz) u.p.printf("\nvar %s string; var %s %s; %s--", m.Keyidx, m.Validx, m.Value.TypeName(), sz) u.assignAndCheck(m.Keyidx, stringTyp) next(u, m.Value) u.p.mapAssign(m) u.p.closeblock() } func (u *unmarshalGen) gPtr(p *Ptr) { u.p.printf("\nif msgp.IsNil(bts) { bts, err = msgp.ReadNilBytes(bts); if err != nil { return }; %s = nil; } else { ", p.Varname()) u.p.initPtr(p) next(u, p.Value) u.p.closeblock() }