package ws import ( "bytes" "encoding/binary" "math/rand" ) // Constants defined by specification. const ( // All control frames MUST have a payload length of 125 bytes or less and MUST NOT be fragmented. MaxControlFramePayloadSize = 125 ) // OpCode represents operation code. type OpCode byte // Operation codes defined by specification. // See https://tools.ietf.org/html/rfc6455#section-5.2 const ( OpContinuation OpCode = 0x0 OpText OpCode = 0x1 OpBinary OpCode = 0x2 OpClose OpCode = 0x8 OpPing OpCode = 0x9 OpPong OpCode = 0xa ) // IsControl checks whether the c is control operation code. // See https://tools.ietf.org/html/rfc6455#section-5.5 func (c OpCode) IsControl() bool { // RFC6455: Control frames are identified by opcodes where // the most significant bit of the opcode is 1. // // Note that OpCode is only 4 bit length. return c&0x8 != 0 } // IsData checks whether the c is data operation code. // See https://tools.ietf.org/html/rfc6455#section-5.6 func (c OpCode) IsData() bool { // RFC6455: Data frames (e.g., non-control frames) are identified by opcodes // where the most significant bit of the opcode is 0. // // Note that OpCode is only 4 bit length. return c&0x8 == 0 } // IsReserved checks whether the c is reserved operation code. // See https://tools.ietf.org/html/rfc6455#section-5.2 func (c OpCode) IsReserved() bool { // RFC6455: // %x3-7 are reserved for further non-control frames // %xB-F are reserved for further control frames return (0x3 <= c && c <= 0x7) || (0xb <= c && c <= 0xf) } // StatusCode represents the encoded reason for closure of websocket connection. // // There are few helper methods on StatusCode that helps to define a range in // which given code is lay in. accordingly to ranges defined in specification. // // See https://tools.ietf.org/html/rfc6455#section-7.4 type StatusCode uint16 // StatusCodeRange describes range of StatusCode values. type StatusCodeRange struct { Min, Max StatusCode } // Status code ranges defined by specification. // See https://tools.ietf.org/html/rfc6455#section-7.4.2 var ( StatusRangeNotInUse = StatusCodeRange{0, 999} StatusRangeProtocol = StatusCodeRange{1000, 2999} StatusRangeApplication = StatusCodeRange{3000, 3999} StatusRangePrivate = StatusCodeRange{4000, 4999} ) // Status codes defined by specification. // See https://tools.ietf.org/html/rfc6455#section-7.4.1 const ( StatusNormalClosure StatusCode = 1000 StatusGoingAway StatusCode = 1001 StatusProtocolError StatusCode = 1002 StatusUnsupportedData StatusCode = 1003 StatusNoMeaningYet StatusCode = 1004 StatusInvalidFramePayloadData StatusCode = 1007 StatusPolicyViolation StatusCode = 1008 StatusMessageTooBig StatusCode = 1009 StatusMandatoryExt StatusCode = 1010 StatusInternalServerError StatusCode = 1011 StatusTLSHandshake StatusCode = 1015 // StatusAbnormalClosure is a special code designated for use in // applications. StatusAbnormalClosure StatusCode = 1006 // StatusNoStatusRcvd is a special code designated for use in applications. StatusNoStatusRcvd StatusCode = 1005 ) // In reports whether the code is defined in given range. func (s StatusCode) In(r StatusCodeRange) bool { return r.Min <= s && s <= r.Max } // Empty reports whether the code is empty. // Empty code has no any meaning neither app level codes nor other. // This method is useful just to check that code is golang default value 0. func (s StatusCode) Empty() bool { return s == 0 } // IsNotUsed reports whether the code is predefined in not used range. func (s StatusCode) IsNotUsed() bool { return s.In(StatusRangeNotInUse) } // IsApplicationSpec reports whether the code should be defined by // application, framework or libraries specification. func (s StatusCode) IsApplicationSpec() bool { return s.In(StatusRangeApplication) } // IsPrivateSpec reports whether the code should be defined privately. func (s StatusCode) IsPrivateSpec() bool { return s.In(StatusRangePrivate) } // IsProtocolSpec reports whether the code should be defined by protocol specification. func (s StatusCode) IsProtocolSpec() bool { return s.In(StatusRangeProtocol) } // IsProtocolDefined reports whether the code is already defined by protocol specification. func (s StatusCode) IsProtocolDefined() bool { switch s { case StatusNormalClosure, StatusGoingAway, StatusProtocolError, StatusUnsupportedData, StatusInvalidFramePayloadData, StatusPolicyViolation, StatusMessageTooBig, StatusMandatoryExt, StatusInternalServerError, StatusNoStatusRcvd, StatusAbnormalClosure, StatusTLSHandshake: return true } return false } // IsProtocolReserved reports whether the code is defined by protocol specification // to be reserved only for application usage purpose. func (s StatusCode) IsProtocolReserved() bool { switch s { // [RFC6455]: {1005,1006,1015} is a reserved value and MUST NOT be set as a status code in a // Close control frame by an endpoint. case StatusNoStatusRcvd, StatusAbnormalClosure, StatusTLSHandshake: return true default: return false } } // Compiled control frames for common use cases. // For construct-serialize optimizations. var ( CompiledPing = MustCompileFrame(NewPingFrame(nil)) CompiledPong = MustCompileFrame(NewPongFrame(nil)) CompiledClose = MustCompileFrame(NewCloseFrame(nil)) CompiledCloseNormalClosure = MustCompileFrame(closeFrameNormalClosure) CompiledCloseGoingAway = MustCompileFrame(closeFrameGoingAway) CompiledCloseProtocolError = MustCompileFrame(closeFrameProtocolError) CompiledCloseUnsupportedData = MustCompileFrame(closeFrameUnsupportedData) CompiledCloseNoMeaningYet = MustCompileFrame(closeFrameNoMeaningYet) CompiledCloseInvalidFramePayloadData = MustCompileFrame(closeFrameInvalidFramePayloadData) CompiledClosePolicyViolation = MustCompileFrame(closeFramePolicyViolation) CompiledCloseMessageTooBig = MustCompileFrame(closeFrameMessageTooBig) CompiledCloseMandatoryExt = MustCompileFrame(closeFrameMandatoryExt) CompiledCloseInternalServerError = MustCompileFrame(closeFrameInternalServerError) CompiledCloseTLSHandshake = MustCompileFrame(closeFrameTLSHandshake) ) // Header represents websocket frame header. // See https://tools.ietf.org/html/rfc6455#section-5.2 type Header struct { Fin bool Rsv byte OpCode OpCode Masked bool Mask [4]byte Length int64 } // Rsv1 reports whether the header has first rsv bit set. func (h Header) Rsv1() bool { return h.Rsv&bit5 != 0 } // Rsv2 reports whether the header has second rsv bit set. func (h Header) Rsv2() bool { return h.Rsv&bit6 != 0 } // Rsv3 reports whether the header has third rsv bit set. func (h Header) Rsv3() bool { return h.Rsv&bit7 != 0 } // Frame represents websocket frame. // See https://tools.ietf.org/html/rfc6455#section-5.2 type Frame struct { Header Header Payload []byte } // NewFrame creates frame with given operation code, // flag of completeness and payload bytes. func NewFrame(op OpCode, fin bool, p []byte) Frame { return Frame{ Header: Header{ Fin: fin, OpCode: op, Length: int64(len(p)), }, Payload: p, } } // NewTextFrame creates text frame with p as payload. // Note that p is not copied. func NewTextFrame(p []byte) Frame { return NewFrame(OpText, true, p) } // NewBinaryFrame creates binary frame with p as payload. // Note that p is not copied. func NewBinaryFrame(p []byte) Frame { return NewFrame(OpBinary, true, p) } // NewPingFrame creates ping frame with p as payload. // Note that p is not copied. // Note that p must have length of MaxControlFramePayloadSize bytes or less due // to RFC. func NewPingFrame(p []byte) Frame { return NewFrame(OpPing, true, p) } // NewPongFrame creates pong frame with p as payload. // Note that p is not copied. // Note that p must have length of MaxControlFramePayloadSize bytes or less due // to RFC. func NewPongFrame(p []byte) Frame { return NewFrame(OpPong, true, p) } // NewCloseFrame creates close frame with given close body. // Note that p is not copied. // Note that p must have length of MaxControlFramePayloadSize bytes or less due // to RFC. func NewCloseFrame(p []byte) Frame { return NewFrame(OpClose, true, p) } // NewCloseFrameBody encodes a closure code and a reason into a binary // representation. // // It returns slice which is at most MaxControlFramePayloadSize bytes length. // If the reason is too big it will be cropped to fit the limit defined by the // spec. // // See https://tools.ietf.org/html/rfc6455#section-5.5 func NewCloseFrameBody(code StatusCode, reason string) []byte { n := min(2+len(reason), MaxControlFramePayloadSize) p := make([]byte, n) crop := min(MaxControlFramePayloadSize-2, len(reason)) PutCloseFrameBody(p, code, reason[:crop]) return p } // PutCloseFrameBody encodes code and reason into buf. // // It will panic if the buffer is too small to accommodate a code or a reason. // // PutCloseFrameBody does not check buffer to be RFC compliant, but note that // by RFC it must be at most MaxControlFramePayloadSize. func PutCloseFrameBody(p []byte, code StatusCode, reason string) { _ = p[1+len(reason)] binary.BigEndian.PutUint16(p, uint16(code)) copy(p[2:], reason) } // MaskFrame masks frame and returns frame with masked payload and Mask header's field set. // Note that it copies f payload to prevent collisions. // For less allocations you could use MaskFrameInPlace or construct frame manually. func MaskFrame(f Frame) Frame { return MaskFrameWith(f, NewMask()) } // MaskFrameWith masks frame with given mask and returns frame // with masked payload and Mask header's field set. // Note that it copies f payload to prevent collisions. // For less allocations you could use MaskFrameInPlaceWith or construct frame manually. func MaskFrameWith(f Frame, mask [4]byte) Frame { // TODO(gobwas): check CopyCipher ws copy() Cipher(). p := make([]byte, len(f.Payload)) copy(p, f.Payload) f.Payload = p return MaskFrameInPlaceWith(f, mask) } // MaskFrameInPlace masks frame and returns frame with masked payload and Mask // header's field set. // Note that it applies xor cipher to f.Payload without copying, that is, it // modifies f.Payload inplace. func MaskFrameInPlace(f Frame) Frame { return MaskFrameInPlaceWith(f, NewMask()) } // MaskFrameInPlaceWith masks frame with given mask and returns frame // with masked payload and Mask header's field set. // Note that it applies xor cipher to f.Payload without copying, that is, it // modifies f.Payload inplace. func MaskFrameInPlaceWith(f Frame, m [4]byte) Frame { f.Header.Masked = true f.Header.Mask = m Cipher(f.Payload, m, 0) return f } // NewMask creates new random mask. func NewMask() (ret [4]byte) { binary.BigEndian.PutUint32(ret[:], rand.Uint32()) return } // CompileFrame returns byte representation of given frame. // In terms of memory consumption it is useful to precompile static frames // which are often used. func CompileFrame(f Frame) (bts []byte, err error) { buf := bytes.NewBuffer(make([]byte, 0, 16)) err = WriteFrame(buf, f) bts = buf.Bytes() return } // MustCompileFrame is like CompileFrame but panics if frame can not be // encoded. func MustCompileFrame(f Frame) []byte { bts, err := CompileFrame(f) if err != nil { panic(err) } return bts } // Rsv creates rsv byte representation. func Rsv(r1, r2, r3 bool) (rsv byte) { if r1 { rsv |= bit5 } if r2 { rsv |= bit6 } if r3 { rsv |= bit7 } return rsv } func makeCloseFrame(code StatusCode) Frame { return NewCloseFrame(NewCloseFrameBody(code, "")) } var ( closeFrameNormalClosure = makeCloseFrame(StatusNormalClosure) closeFrameGoingAway = makeCloseFrame(StatusGoingAway) closeFrameProtocolError = makeCloseFrame(StatusProtocolError) closeFrameUnsupportedData = makeCloseFrame(StatusUnsupportedData) closeFrameNoMeaningYet = makeCloseFrame(StatusNoMeaningYet) closeFrameInvalidFramePayloadData = makeCloseFrame(StatusInvalidFramePayloadData) closeFramePolicyViolation = makeCloseFrame(StatusPolicyViolation) closeFrameMessageTooBig = makeCloseFrame(StatusMessageTooBig) closeFrameMandatoryExt = makeCloseFrame(StatusMandatoryExt) closeFrameInternalServerError = makeCloseFrame(StatusInternalServerError) closeFrameTLSHandshake = makeCloseFrame(StatusTLSHandshake) )