package ndr import ( "bytes" "encoding/binary" "math" ) // Byte sizes of primitive types const ( SizeBool = 1 SizeChar = 1 SizeUint8 = 1 SizeUint16 = 2 SizeUint32 = 4 SizeUint64 = 8 SizeEnum = 2 SizeSingle = 4 SizeDouble = 8 SizePtr = 4 ) // Bool is an NDR Boolean which is a logical quantity that assumes one of two values: TRUE or FALSE. // NDR represents a Boolean as one octet. // It represents a value of FALSE as a zero octet, an octet in which every bit is reset. // It represents a value of TRUE as a non-zero octet, an octet in which one or more bits are set. // Char is an NDR character. // NDR represents a character as one octet. // Characters have two representation formats: ASCII and EBCDIC. // USmall is an unsigned 8 bit integer // UShort is an unsigned 16 bit integer // ULong is an unsigned 32 bit integer // UHyper is an unsigned 64 bit integer // Small is an signed 8 bit integer // Short is an signed 16 bit integer // Long is an signed 32 bit integer // Hyper is an signed 64 bit integer // Enum is the NDR representation of enumerated types as signed short integers (2 octets) // Single is an NDR defined single-precision floating-point data type // Double is an NDR defined double-precision floating-point data type // readBool reads a byte representing a boolean. // NDR represents a Boolean as one octet. // It represents a value of FALSE as a zero octet, an octet in which every bit is reset. // It represents a value of TRUE as a non-zero octet, an octet in which one or more bits are set. func (dec *Decoder) readBool() (bool, error) { i, err := dec.readUint8() if err != nil { return false, err } if i != 0 { return true, nil } return false, nil } // readChar reads bytes representing a 8bit ASCII integer cast to a rune. func (dec *Decoder) readChar() (rune, error) { var r rune a, err := dec.readUint8() if err != nil { return r, err } return rune(a), nil } // readUint8 reads bytes representing a 8bit unsigned integer. func (dec *Decoder) readUint8() (uint8, error) { b, err := dec.r.ReadByte() if err != nil { return uint8(0), err } return uint8(b), nil } // readUint16 reads bytes representing a 16bit unsigned integer. func (dec *Decoder) readUint16() (uint16, error) { dec.ensureAlignment(SizeUint16) b, err := dec.readBytes(SizeUint16) if err != nil { return uint16(0), err } return dec.ch.Endianness.Uint16(b), nil } // readUint32 reads bytes representing a 32bit unsigned integer. func (dec *Decoder) readUint32() (uint32, error) { dec.ensureAlignment(SizeUint32) b, err := dec.readBytes(SizeUint32) if err != nil { return uint32(0), err } return dec.ch.Endianness.Uint32(b), nil } // readUint32 reads bytes representing a 32bit unsigned integer. func (dec *Decoder) readUint64() (uint64, error) { dec.ensureAlignment(SizeUint64) b, err := dec.readBytes(SizeUint64) if err != nil { return uint64(0), err } return dec.ch.Endianness.Uint64(b), nil } func (dec *Decoder) readInt8() (int8, error) { dec.ensureAlignment(SizeUint8) b, err := dec.readBytes(SizeUint8) if err != nil { return 0, err } var i int8 buf := bytes.NewReader(b) err = binary.Read(buf, dec.ch.Endianness, &i) if err != nil { return 0, err } return i, nil } func (dec *Decoder) readInt16() (int16, error) { dec.ensureAlignment(SizeUint16) b, err := dec.readBytes(SizeUint16) if err != nil { return 0, err } var i int16 buf := bytes.NewReader(b) err = binary.Read(buf, dec.ch.Endianness, &i) if err != nil { return 0, err } return i, nil } func (dec *Decoder) readInt32() (int32, error) { dec.ensureAlignment(SizeUint32) b, err := dec.readBytes(SizeUint32) if err != nil { return 0, err } var i int32 buf := bytes.NewReader(b) err = binary.Read(buf, dec.ch.Endianness, &i) if err != nil { return 0, err } return i, nil } func (dec *Decoder) readInt64() (int64, error) { dec.ensureAlignment(SizeUint64) b, err := dec.readBytes(SizeUint64) if err != nil { return 0, err } var i int64 buf := bytes.NewReader(b) err = binary.Read(buf, dec.ch.Endianness, &i) if err != nil { return 0, err } return i, nil } // https://en.wikipedia.org/wiki/IEEE_754-1985 func (dec *Decoder) readFloat32() (f float32, err error) { dec.ensureAlignment(SizeSingle) b, err := dec.readBytes(SizeSingle) if err != nil { return } bits := dec.ch.Endianness.Uint32(b) f = math.Float32frombits(bits) return } func (dec *Decoder) readFloat64() (f float64, err error) { dec.ensureAlignment(SizeDouble) b, err := dec.readBytes(SizeDouble) if err != nil { return } bits := dec.ch.Endianness.Uint64(b) f = math.Float64frombits(bits) return } // NDR enforces NDR alignment of primitive data; that is, any primitive of size n octets is aligned at a octet stream // index that is a multiple of n. (In this version of NDR, n is one of {1, 2, 4, 8}.) An octet stream index indicates // the number of an octet in an octet stream when octets are numbered, beginning with 0, from the first octet in the // stream. Where necessary, an alignment gap, consisting of octets of unspecified value, precedes the representation // of a primitive. The gap is of the smallest size sufficient to align the primitive. func (dec *Decoder) ensureAlignment(n int) { p := dec.size - dec.r.Buffered() if s := p % n; s != 0 { dec.r.Discard(n - s) } }