package gen import ( "io" "strconv" ) func decode(w io.Writer) *decodeGen { return &decodeGen{ p: printer{w: w}, hasfield: false, } } type decodeGen struct { passes p printer hasfield bool } func (d *decodeGen) Method() Method { return Decode } func (d *decodeGen) needsField() { if d.hasfield { return } d.p.print("\nvar field []byte; _ = field") d.hasfield = true } func (d *decodeGen) Execute(p Elem) error { p = d.applyall(p) if p == nil { return nil } d.hasfield = false if !d.p.ok() { return d.p.err } if !IsPrintable(p) { return nil } d.p.comment("DecodeMsg implements msgp.Decodable") d.p.printf("\nfunc (%s %s) DecodeMsg(dc *msgp.Reader) (err error) {", p.Varname(), methodReceiver(p)) next(d, p) d.p.nakedReturn() unsetReceiver(p) return d.p.err } func (d *decodeGen) gStruct(s *Struct) { if !d.p.ok() { return } if s.AsTuple { d.structAsTuple(s) } else { d.structAsMap(s) } return } func (d *decodeGen) assignAndCheck(name string, typ string) { if !d.p.ok() { return } d.p.printf("\n%s, err = dc.Read%s()", name, typ) d.p.print(errcheck) } func (d *decodeGen) structAsTuple(s *Struct) { nfields := len(s.Fields) sz := randIdent() d.p.declare(sz, u32) d.assignAndCheck(sz, arrayHeader) d.p.arrayCheck(strconv.Itoa(nfields), sz) for i := range s.Fields { if !d.p.ok() { return } next(d, s.Fields[i].FieldElem) } } func (d *decodeGen) structAsMap(s *Struct) { d.needsField() sz := randIdent() d.p.declare(sz, u32) d.assignAndCheck(sz, mapHeader) d.p.printf("\nfor %s > 0 {\n%s--", sz, sz) d.assignAndCheck("field", mapKey) d.p.print("\nswitch msgp.UnsafeString(field) {") for i := range s.Fields { d.p.printf("\ncase \"%s\":", s.Fields[i].FieldTag) next(d, s.Fields[i].FieldElem) if !d.p.ok() { return } } d.p.print("\ndefault:\nerr = dc.Skip()") d.p.print(errcheck) d.p.closeblock() // close switch d.p.closeblock() // close for loop } func (d *decodeGen) gBase(b *BaseElem) { if !d.p.ok() { return } // open block for 'tmp' var tmp string if b.Convert { tmp = randIdent() d.p.printf("\n{ var %s %s", tmp, b.BaseType()) } vname := b.Varname() // e.g. "z.FieldOne" bname := b.BaseName() // e.g. "Float64" // handle special cases // for object type. switch b.Value { case Bytes: if b.Convert { d.p.printf("\n%s, err = dc.ReadBytes([]byte(%s))", tmp, vname) } else { d.p.printf("\n%s, err = dc.ReadBytes(%s)", vname, vname) } case IDENT: d.p.printf("\nerr = %s.DecodeMsg(dc)", vname) case Ext: d.p.printf("\nerr = dc.ReadExtension(%s)", vname) default: if b.Convert { d.p.printf("\n%s, err = dc.Read%s()", tmp, bname) } else { d.p.printf("\n%s, err = dc.Read%s()", vname, bname) } } // close block for 'tmp' if b.Convert { d.p.printf("\n%s = %s(%s)\n}", vname, b.FromBase(), tmp) } d.p.print(errcheck) } func (d *decodeGen) gMap(m *Map) { if !d.p.ok() { return } sz := randIdent() // resize or allocate map d.p.declare(sz, u32) d.assignAndCheck(sz, mapHeader) d.p.resizeMap(sz, m) // for element in map, read string/value // pair and assign d.p.printf("\nfor %s > 0 {\n%s--", sz, sz) d.p.declare(m.Keyidx, "string") d.p.declare(m.Validx, m.Value.TypeName()) d.assignAndCheck(m.Keyidx, stringTyp) next(d, m.Value) d.p.mapAssign(m) d.p.closeblock() } func (d *decodeGen) gSlice(s *Slice) { if !d.p.ok() { return } sz := randIdent() d.p.declare(sz, u32) d.assignAndCheck(sz, arrayHeader) d.p.resizeSlice(sz, s) d.p.rangeBlock(s.Index, s.Varname(), d, s.Els) } func (d *decodeGen) gArray(a *Array) { if !d.p.ok() { return } // special case if we have [const]byte if be, ok := a.Els.(*BaseElem); ok && (be.Value == Byte || be.Value == Uint8) { d.p.printf("\nerr = dc.ReadExactBytes((%s)[:])", a.Varname()) d.p.print(errcheck) return } sz := randIdent() d.p.declare(sz, u32) d.assignAndCheck(sz, arrayHeader) d.p.arrayCheck(a.Size, sz) d.p.rangeBlock(a.Index, a.Varname(), d, a.Els) } func (d *decodeGen) gPtr(p *Ptr) { if !d.p.ok() { return } d.p.print("\nif dc.IsNil() {") d.p.print("\nerr = dc.ReadNil()") d.p.print(errcheck) d.p.printf("\n%s = nil\n} else {", p.Varname()) d.p.initPtr(p) next(d, p.Value) d.p.closeblock() }