// Copyright 2014 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package http2 import ( "bytes" "encoding/binary" "errors" "fmt" "io" "log" "strings" "sync" "golang.org/x/net/http/httpguts" "golang.org/x/net/http2/hpack" ) const frameHeaderLen = 9 var padZeros = make([]byte, 255) // zeros for padding // A FrameType is a registered frame type as defined in // https://httpwg.org/specs/rfc7540.html#rfc.section.11.2 type FrameType uint8 const ( FrameData FrameType = 0x0 FrameHeaders FrameType = 0x1 FramePriority FrameType = 0x2 FrameRSTStream FrameType = 0x3 FrameSettings FrameType = 0x4 FramePushPromise FrameType = 0x5 FramePing FrameType = 0x6 FrameGoAway FrameType = 0x7 FrameWindowUpdate FrameType = 0x8 FrameContinuation FrameType = 0x9 ) var frameName = map[FrameType]string{ FrameData: "DATA", FrameHeaders: "HEADERS", FramePriority: "PRIORITY", FrameRSTStream: "RST_STREAM", FrameSettings: "SETTINGS", FramePushPromise: "PUSH_PROMISE", FramePing: "PING", FrameGoAway: "GOAWAY", FrameWindowUpdate: "WINDOW_UPDATE", FrameContinuation: "CONTINUATION", } func (t FrameType) String() string { if s, ok := frameName[t]; ok { return s } return fmt.Sprintf("UNKNOWN_FRAME_TYPE_%d", uint8(t)) } // Flags is a bitmask of HTTP/2 flags. // The meaning of flags varies depending on the frame type. type Flags uint8 // Has reports whether f contains all (0 or more) flags in v. func (f Flags) Has(v Flags) bool { return (f & v) == v } // Frame-specific FrameHeader flag bits. const ( // Data Frame FlagDataEndStream Flags = 0x1 FlagDataPadded Flags = 0x8 // Headers Frame FlagHeadersEndStream Flags = 0x1 FlagHeadersEndHeaders Flags = 0x4 FlagHeadersPadded Flags = 0x8 FlagHeadersPriority Flags = 0x20 // Settings Frame FlagSettingsAck Flags = 0x1 // Ping Frame FlagPingAck Flags = 0x1 // Continuation Frame FlagContinuationEndHeaders Flags = 0x4 FlagPushPromiseEndHeaders Flags = 0x4 FlagPushPromisePadded Flags = 0x8 ) var flagName = map[FrameType]map[Flags]string{ FrameData: { FlagDataEndStream: "END_STREAM", FlagDataPadded: "PADDED", }, FrameHeaders: { FlagHeadersEndStream: "END_STREAM", FlagHeadersEndHeaders: "END_HEADERS", FlagHeadersPadded: "PADDED", FlagHeadersPriority: "PRIORITY", }, FrameSettings: { FlagSettingsAck: "ACK", }, FramePing: { FlagPingAck: "ACK", }, FrameContinuation: { FlagContinuationEndHeaders: "END_HEADERS", }, FramePushPromise: { FlagPushPromiseEndHeaders: "END_HEADERS", FlagPushPromisePadded: "PADDED", }, } // a frameParser parses a frame given its FrameHeader and payload // bytes. The length of payload will always equal fh.Length (which // might be 0). type frameParser func(fc *frameCache, fh FrameHeader, countError func(string), payload []byte) (Frame, error) var frameParsers = map[FrameType]frameParser{ FrameData: parseDataFrame, FrameHeaders: parseHeadersFrame, FramePriority: parsePriorityFrame, FrameRSTStream: parseRSTStreamFrame, FrameSettings: parseSettingsFrame, FramePushPromise: parsePushPromise, FramePing: parsePingFrame, FrameGoAway: parseGoAwayFrame, FrameWindowUpdate: parseWindowUpdateFrame, FrameContinuation: parseContinuationFrame, } func typeFrameParser(t FrameType) frameParser { if f := frameParsers[t]; f != nil { return f } return parseUnknownFrame } // A FrameHeader is the 9 byte header of all HTTP/2 frames. // // See https://httpwg.org/specs/rfc7540.html#FrameHeader type FrameHeader struct { valid bool // caller can access []byte fields in the Frame // Type is the 1 byte frame type. There are ten standard frame // types, but extension frame types may be written by WriteRawFrame // and will be returned by ReadFrame (as UnknownFrame). Type FrameType // Flags are the 1 byte of 8 potential bit flags per frame. // They are specific to the frame type. Flags Flags // Length is the length of the frame, not including the 9 byte header. // The maximum size is one byte less than 16MB (uint24), but only // frames up to 16KB are allowed without peer agreement. Length uint32 // StreamID is which stream this frame is for. Certain frames // are not stream-specific, in which case this field is 0. StreamID uint32 } // Header returns h. It exists so FrameHeaders can be embedded in other // specific frame types and implement the Frame interface. func (h FrameHeader) Header() FrameHeader { return h } func (h FrameHeader) String() string { var buf bytes.Buffer buf.WriteString("[FrameHeader ") h.writeDebug(&buf) buf.WriteByte(']') return buf.String() } func (h FrameHeader) writeDebug(buf *bytes.Buffer) { buf.WriteString(h.Type.String()) if h.Flags != 0 { buf.WriteString(" flags=") set := 0 for i := uint8(0); i < 8; i++ { if h.Flags&(1< 1 { buf.WriteByte('|') } name := flagName[h.Type][Flags(1<>24), byte(streamID>>16), byte(streamID>>8), byte(streamID)) } func (f *Framer) endWrite() error { // Now that we know the final size, fill in the FrameHeader in // the space previously reserved for it. Abuse append. length := len(f.wbuf) - frameHeaderLen if length >= (1 << 24) { return ErrFrameTooLarge } _ = append(f.wbuf[:0], byte(length>>16), byte(length>>8), byte(length)) if f.logWrites { f.logWrite() } n, err := f.w.Write(f.wbuf) if err == nil && n != len(f.wbuf) { err = io.ErrShortWrite } return err } func (f *Framer) logWrite() { if f.debugFramer == nil { f.debugFramerBuf = new(bytes.Buffer) f.debugFramer = NewFramer(nil, f.debugFramerBuf) f.debugFramer.logReads = false // we log it ourselves, saying "wrote" below // Let us read anything, even if we accidentally wrote it // in the wrong order: f.debugFramer.AllowIllegalReads = true } f.debugFramerBuf.Write(f.wbuf) fr, err := f.debugFramer.ReadFrame() if err != nil { f.debugWriteLoggerf("http2: Framer %p: failed to decode just-written frame", f) return } f.debugWriteLoggerf("http2: Framer %p: wrote %v", f, summarizeFrame(fr)) } func (f *Framer) writeByte(v byte) { f.wbuf = append(f.wbuf, v) } func (f *Framer) writeBytes(v []byte) { f.wbuf = append(f.wbuf, v...) } func (f *Framer) writeUint16(v uint16) { f.wbuf = append(f.wbuf, byte(v>>8), byte(v)) } func (f *Framer) writeUint32(v uint32) { f.wbuf = append(f.wbuf, byte(v>>24), byte(v>>16), byte(v>>8), byte(v)) } const ( minMaxFrameSize = 1 << 14 maxFrameSize = 1<<24 - 1 ) // SetReuseFrames allows the Framer to reuse Frames. // If called on a Framer, Frames returned by calls to ReadFrame are only // valid until the next call to ReadFrame. func (fr *Framer) SetReuseFrames() { if fr.frameCache != nil { return } fr.frameCache = &frameCache{} } type frameCache struct { dataFrame DataFrame } func (fc *frameCache) getDataFrame() *DataFrame { if fc == nil { return &DataFrame{} } return &fc.dataFrame } // NewFramer returns a Framer that writes frames to w and reads them from r. func NewFramer(w io.Writer, r io.Reader) *Framer { fr := &Framer{ w: w, r: r, countError: func(string) {}, logReads: logFrameReads, logWrites: logFrameWrites, debugReadLoggerf: log.Printf, debugWriteLoggerf: log.Printf, } fr.getReadBuf = func(size uint32) []byte { if cap(fr.readBuf) >= int(size) { return fr.readBuf[:size] } fr.readBuf = make([]byte, size) return fr.readBuf } fr.SetMaxReadFrameSize(maxFrameSize) return fr } // SetMaxReadFrameSize sets the maximum size of a frame // that will be read by a subsequent call to ReadFrame. // It is the caller's responsibility to advertise this // limit with a SETTINGS frame. func (fr *Framer) SetMaxReadFrameSize(v uint32) { if v > maxFrameSize { v = maxFrameSize } fr.maxReadSize = v } // ErrorDetail returns a more detailed error of the last error // returned by Framer.ReadFrame. For instance, if ReadFrame // returns a StreamError with code PROTOCOL_ERROR, ErrorDetail // will say exactly what was invalid. ErrorDetail is not guaranteed // to return a non-nil value and like the rest of the http2 package, // its return value is not protected by an API compatibility promise. // ErrorDetail is reset after the next call to ReadFrame. func (fr *Framer) ErrorDetail() error { return fr.errDetail } // ErrFrameTooLarge is returned from Framer.ReadFrame when the peer // sends a frame that is larger than declared with SetMaxReadFrameSize. var ErrFrameTooLarge = errors.New("http2: frame too large") // terminalReadFrameError reports whether err is an unrecoverable // error from ReadFrame and no other frames should be read. func terminalReadFrameError(err error) bool { if _, ok := err.(StreamError); ok { return false } return err != nil } // ReadFrame reads a single frame. The returned Frame is only valid // until the next call to ReadFrame. // // If the frame is larger than previously set with SetMaxReadFrameSize, the // returned error is ErrFrameTooLarge. Other errors may be of type // ConnectionError, StreamError, or anything else from the underlying // reader. func (fr *Framer) ReadFrame() (Frame, error) { fr.errDetail = nil if fr.lastFrame != nil { fr.lastFrame.invalidate() } fh, err := readFrameHeader(fr.headerBuf[:], fr.r) if err != nil { return nil, err } if fh.Length > fr.maxReadSize { return nil, ErrFrameTooLarge } payload := fr.getReadBuf(fh.Length) if _, err := io.ReadFull(fr.r, payload); err != nil { return nil, err } f, err := typeFrameParser(fh.Type)(fr.frameCache, fh, fr.countError, payload) if err != nil { if ce, ok := err.(connError); ok { return nil, fr.connError(ce.Code, ce.Reason) } return nil, err } if err := fr.checkFrameOrder(f); err != nil { return nil, err } if fr.logReads { fr.debugReadLoggerf("http2: Framer %p: read %v", fr, summarizeFrame(f)) } if fh.Type == FrameHeaders && fr.ReadMetaHeaders != nil { return fr.readMetaFrame(f.(*HeadersFrame)) } return f, nil } // connError returns ConnectionError(code) but first // stashes away a public reason to the caller can optionally relay it // to the peer before hanging up on them. This might help others debug // their implementations. func (fr *Framer) connError(code ErrCode, reason string) error { fr.errDetail = errors.New(reason) return ConnectionError(code) } // checkFrameOrder reports an error if f is an invalid frame to return // next from ReadFrame. Mostly it checks whether HEADERS and // CONTINUATION frames are contiguous. func (fr *Framer) checkFrameOrder(f Frame) error { last := fr.lastFrame fr.lastFrame = f if fr.AllowIllegalReads { return nil } fh := f.Header() if fr.lastHeaderStream != 0 { if fh.Type != FrameContinuation { return fr.connError(ErrCodeProtocol, fmt.Sprintf("got %s for stream %d; expected CONTINUATION following %s for stream %d", fh.Type, fh.StreamID, last.Header().Type, fr.lastHeaderStream)) } if fh.StreamID != fr.lastHeaderStream { return fr.connError(ErrCodeProtocol, fmt.Sprintf("got CONTINUATION for stream %d; expected stream %d", fh.StreamID, fr.lastHeaderStream)) } } else if fh.Type == FrameContinuation { return fr.connError(ErrCodeProtocol, fmt.Sprintf("unexpected CONTINUATION for stream %d", fh.StreamID)) } switch fh.Type { case FrameHeaders, FrameContinuation: if fh.Flags.Has(FlagHeadersEndHeaders) { fr.lastHeaderStream = 0 } else { fr.lastHeaderStream = fh.StreamID } } return nil } // A DataFrame conveys arbitrary, variable-length sequences of octets // associated with a stream. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.1 type DataFrame struct { FrameHeader data []byte } func (f *DataFrame) StreamEnded() bool { return f.FrameHeader.Flags.Has(FlagDataEndStream) } // Data returns the frame's data octets, not including any padding // size byte or padding suffix bytes. // The caller must not retain the returned memory past the next // call to ReadFrame. func (f *DataFrame) Data() []byte { f.checkValid() return f.data } func parseDataFrame(fc *frameCache, fh FrameHeader, countError func(string), payload []byte) (Frame, error) { if fh.StreamID == 0 { // DATA frames MUST be associated with a stream. If a // DATA frame is received whose stream identifier // field is 0x0, the recipient MUST respond with a // connection error (Section 5.4.1) of type // PROTOCOL_ERROR. countError("frame_data_stream_0") return nil, connError{ErrCodeProtocol, "DATA frame with stream ID 0"} } f := fc.getDataFrame() f.FrameHeader = fh var padSize byte if fh.Flags.Has(FlagDataPadded) { var err error payload, padSize, err = readByte(payload) if err != nil { countError("frame_data_pad_byte_short") return nil, err } } if int(padSize) > len(payload) { // If the length of the padding is greater than the // length of the frame payload, the recipient MUST // treat this as a connection error. // Filed: https://github.com/http2/http2-spec/issues/610 countError("frame_data_pad_too_big") return nil, connError{ErrCodeProtocol, "pad size larger than data payload"} } f.data = payload[:len(payload)-int(padSize)] return f, nil } var ( errStreamID = errors.New("invalid stream ID") errDepStreamID = errors.New("invalid dependent stream ID") errPadLength = errors.New("pad length too large") errPadBytes = errors.New("padding bytes must all be zeros unless AllowIllegalWrites is enabled") ) func validStreamIDOrZero(streamID uint32) bool { return streamID&(1<<31) == 0 } func validStreamID(streamID uint32) bool { return streamID != 0 && streamID&(1<<31) == 0 } // WriteData writes a DATA frame. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility not to violate the maximum frame size // and to not call other Write methods concurrently. func (f *Framer) WriteData(streamID uint32, endStream bool, data []byte) error { return f.WriteDataPadded(streamID, endStream, data, nil) } // WriteDataPadded writes a DATA frame with optional padding. // // If pad is nil, the padding bit is not sent. // The length of pad must not exceed 255 bytes. // The bytes of pad must all be zero, unless f.AllowIllegalWrites is set. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility not to violate the maximum frame size // and to not call other Write methods concurrently. func (f *Framer) WriteDataPadded(streamID uint32, endStream bool, data, pad []byte) error { if err := f.startWriteDataPadded(streamID, endStream, data, pad); err != nil { return err } return f.endWrite() } // startWriteDataPadded is WriteDataPadded, but only writes the frame to the Framer's internal buffer. // The caller should call endWrite to flush the frame to the underlying writer. func (f *Framer) startWriteDataPadded(streamID uint32, endStream bool, data, pad []byte) error { if !validStreamID(streamID) && !f.AllowIllegalWrites { return errStreamID } if len(pad) > 0 { if len(pad) > 255 { return errPadLength } if !f.AllowIllegalWrites { for _, b := range pad { if b != 0 { // "Padding octets MUST be set to zero when sending." return errPadBytes } } } } var flags Flags if endStream { flags |= FlagDataEndStream } if pad != nil { flags |= FlagDataPadded } f.startWrite(FrameData, flags, streamID) if pad != nil { f.wbuf = append(f.wbuf, byte(len(pad))) } f.wbuf = append(f.wbuf, data...) f.wbuf = append(f.wbuf, pad...) return nil } // A SettingsFrame conveys configuration parameters that affect how // endpoints communicate, such as preferences and constraints on peer // behavior. // // See https://httpwg.org/specs/rfc7540.html#SETTINGS type SettingsFrame struct { FrameHeader p []byte } func parseSettingsFrame(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (Frame, error) { if fh.Flags.Has(FlagSettingsAck) && fh.Length > 0 { // When this (ACK 0x1) bit is set, the payload of the // SETTINGS frame MUST be empty. Receipt of a // SETTINGS frame with the ACK flag set and a length // field value other than 0 MUST be treated as a // connection error (Section 5.4.1) of type // FRAME_SIZE_ERROR. countError("frame_settings_ack_with_length") return nil, ConnectionError(ErrCodeFrameSize) } if fh.StreamID != 0 { // SETTINGS frames always apply to a connection, // never a single stream. The stream identifier for a // SETTINGS frame MUST be zero (0x0). If an endpoint // receives a SETTINGS frame whose stream identifier // field is anything other than 0x0, the endpoint MUST // respond with a connection error (Section 5.4.1) of // type PROTOCOL_ERROR. countError("frame_settings_has_stream") return nil, ConnectionError(ErrCodeProtocol) } if len(p)%6 != 0 { countError("frame_settings_mod_6") // Expecting even number of 6 byte settings. return nil, ConnectionError(ErrCodeFrameSize) } f := &SettingsFrame{FrameHeader: fh, p: p} if v, ok := f.Value(SettingInitialWindowSize); ok && v > (1<<31)-1 { countError("frame_settings_window_size_too_big") // Values above the maximum flow control window size of 2^31 - 1 MUST // be treated as a connection error (Section 5.4.1) of type // FLOW_CONTROL_ERROR. return nil, ConnectionError(ErrCodeFlowControl) } return f, nil } func (f *SettingsFrame) IsAck() bool { return f.FrameHeader.Flags.Has(FlagSettingsAck) } func (f *SettingsFrame) Value(id SettingID) (v uint32, ok bool) { f.checkValid() for i := 0; i < f.NumSettings(); i++ { if s := f.Setting(i); s.ID == id { return s.Val, true } } return 0, false } // Setting returns the setting from the frame at the given 0-based index. // The index must be >= 0 and less than f.NumSettings(). func (f *SettingsFrame) Setting(i int) Setting { buf := f.p return Setting{ ID: SettingID(binary.BigEndian.Uint16(buf[i*6 : i*6+2])), Val: binary.BigEndian.Uint32(buf[i*6+2 : i*6+6]), } } func (f *SettingsFrame) NumSettings() int { return len(f.p) / 6 } // HasDuplicates reports whether f contains any duplicate setting IDs. func (f *SettingsFrame) HasDuplicates() bool { num := f.NumSettings() if num == 0 { return false } // If it's small enough (the common case), just do the n^2 // thing and avoid a map allocation. if num < 10 { for i := 0; i < num; i++ { idi := f.Setting(i).ID for j := i + 1; j < num; j++ { idj := f.Setting(j).ID if idi == idj { return true } } } return false } seen := map[SettingID]bool{} for i := 0; i < num; i++ { id := f.Setting(i).ID if seen[id] { return true } seen[id] = true } return false } // ForeachSetting runs fn for each setting. // It stops and returns the first error. func (f *SettingsFrame) ForeachSetting(fn func(Setting) error) error { f.checkValid() for i := 0; i < f.NumSettings(); i++ { if err := fn(f.Setting(i)); err != nil { return err } } return nil } // WriteSettings writes a SETTINGS frame with zero or more settings // specified and the ACK bit not set. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility to not call other Write methods concurrently. func (f *Framer) WriteSettings(settings ...Setting) error { f.startWrite(FrameSettings, 0, 0) for _, s := range settings { f.writeUint16(uint16(s.ID)) f.writeUint32(s.Val) } return f.endWrite() } // WriteSettingsAck writes an empty SETTINGS frame with the ACK bit set. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility to not call other Write methods concurrently. func (f *Framer) WriteSettingsAck() error { f.startWrite(FrameSettings, FlagSettingsAck, 0) return f.endWrite() } // A PingFrame is a mechanism for measuring a minimal round trip time // from the sender, as well as determining whether an idle connection // is still functional. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.7 type PingFrame struct { FrameHeader Data [8]byte } func (f *PingFrame) IsAck() bool { return f.Flags.Has(FlagPingAck) } func parsePingFrame(_ *frameCache, fh FrameHeader, countError func(string), payload []byte) (Frame, error) { if len(payload) != 8 { countError("frame_ping_length") return nil, ConnectionError(ErrCodeFrameSize) } if fh.StreamID != 0 { countError("frame_ping_has_stream") return nil, ConnectionError(ErrCodeProtocol) } f := &PingFrame{FrameHeader: fh} copy(f.Data[:], payload) return f, nil } func (f *Framer) WritePing(ack bool, data [8]byte) error { var flags Flags if ack { flags = FlagPingAck } f.startWrite(FramePing, flags, 0) f.writeBytes(data[:]) return f.endWrite() } // A GoAwayFrame informs the remote peer to stop creating streams on this connection. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.8 type GoAwayFrame struct { FrameHeader LastStreamID uint32 ErrCode ErrCode debugData []byte } // DebugData returns any debug data in the GOAWAY frame. Its contents // are not defined. // The caller must not retain the returned memory past the next // call to ReadFrame. func (f *GoAwayFrame) DebugData() []byte { f.checkValid() return f.debugData } func parseGoAwayFrame(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (Frame, error) { if fh.StreamID != 0 { countError("frame_goaway_has_stream") return nil, ConnectionError(ErrCodeProtocol) } if len(p) < 8 { countError("frame_goaway_short") return nil, ConnectionError(ErrCodeFrameSize) } return &GoAwayFrame{ FrameHeader: fh, LastStreamID: binary.BigEndian.Uint32(p[:4]) & (1<<31 - 1), ErrCode: ErrCode(binary.BigEndian.Uint32(p[4:8])), debugData: p[8:], }, nil } func (f *Framer) WriteGoAway(maxStreamID uint32, code ErrCode, debugData []byte) error { f.startWrite(FrameGoAway, 0, 0) f.writeUint32(maxStreamID & (1<<31 - 1)) f.writeUint32(uint32(code)) f.writeBytes(debugData) return f.endWrite() } // An UnknownFrame is the frame type returned when the frame type is unknown // or no specific frame type parser exists. type UnknownFrame struct { FrameHeader p []byte } // Payload returns the frame's payload (after the header). It is not // valid to call this method after a subsequent call to // Framer.ReadFrame, nor is it valid to retain the returned slice. // The memory is owned by the Framer and is invalidated when the next // frame is read. func (f *UnknownFrame) Payload() []byte { f.checkValid() return f.p } func parseUnknownFrame(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (Frame, error) { return &UnknownFrame{fh, p}, nil } // A WindowUpdateFrame is used to implement flow control. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.9 type WindowUpdateFrame struct { FrameHeader Increment uint32 // never read with high bit set } func parseWindowUpdateFrame(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (Frame, error) { if len(p) != 4 { countError("frame_windowupdate_bad_len") return nil, ConnectionError(ErrCodeFrameSize) } inc := binary.BigEndian.Uint32(p[:4]) & 0x7fffffff // mask off high reserved bit if inc == 0 { // A receiver MUST treat the receipt of a // WINDOW_UPDATE frame with an flow control window // increment of 0 as a stream error (Section 5.4.2) of // type PROTOCOL_ERROR; errors on the connection flow // control window MUST be treated as a connection // error (Section 5.4.1). if fh.StreamID == 0 { countError("frame_windowupdate_zero_inc_conn") return nil, ConnectionError(ErrCodeProtocol) } countError("frame_windowupdate_zero_inc_stream") return nil, streamError(fh.StreamID, ErrCodeProtocol) } return &WindowUpdateFrame{ FrameHeader: fh, Increment: inc, }, nil } // WriteWindowUpdate writes a WINDOW_UPDATE frame. // The increment value must be between 1 and 2,147,483,647, inclusive. // If the Stream ID is zero, the window update applies to the // connection as a whole. func (f *Framer) WriteWindowUpdate(streamID, incr uint32) error { // "The legal range for the increment to the flow control window is 1 to 2^31-1 (2,147,483,647) octets." if (incr < 1 || incr > 2147483647) && !f.AllowIllegalWrites { return errors.New("illegal window increment value") } f.startWrite(FrameWindowUpdate, 0, streamID) f.writeUint32(incr) return f.endWrite() } // A HeadersFrame is used to open a stream and additionally carries a // header block fragment. type HeadersFrame struct { FrameHeader // Priority is set if FlagHeadersPriority is set in the FrameHeader. Priority PriorityParam headerFragBuf []byte // not owned } func (f *HeadersFrame) HeaderBlockFragment() []byte { f.checkValid() return f.headerFragBuf } func (f *HeadersFrame) HeadersEnded() bool { return f.FrameHeader.Flags.Has(FlagHeadersEndHeaders) } func (f *HeadersFrame) StreamEnded() bool { return f.FrameHeader.Flags.Has(FlagHeadersEndStream) } func (f *HeadersFrame) HasPriority() bool { return f.FrameHeader.Flags.Has(FlagHeadersPriority) } func parseHeadersFrame(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (_ Frame, err error) { hf := &HeadersFrame{ FrameHeader: fh, } if fh.StreamID == 0 { // HEADERS frames MUST be associated with a stream. If a HEADERS frame // is received whose stream identifier field is 0x0, the recipient MUST // respond with a connection error (Section 5.4.1) of type // PROTOCOL_ERROR. countError("frame_headers_zero_stream") return nil, connError{ErrCodeProtocol, "HEADERS frame with stream ID 0"} } var padLength uint8 if fh.Flags.Has(FlagHeadersPadded) { if p, padLength, err = readByte(p); err != nil { countError("frame_headers_pad_short") return } } if fh.Flags.Has(FlagHeadersPriority) { var v uint32 p, v, err = readUint32(p) if err != nil { countError("frame_headers_prio_short") return nil, err } hf.Priority.StreamDep = v & 0x7fffffff hf.Priority.Exclusive = (v != hf.Priority.StreamDep) // high bit was set p, hf.Priority.Weight, err = readByte(p) if err != nil { countError("frame_headers_prio_weight_short") return nil, err } } if len(p)-int(padLength) < 0 { countError("frame_headers_pad_too_big") return nil, streamError(fh.StreamID, ErrCodeProtocol) } hf.headerFragBuf = p[:len(p)-int(padLength)] return hf, nil } // HeadersFrameParam are the parameters for writing a HEADERS frame. type HeadersFrameParam struct { // StreamID is the required Stream ID to initiate. StreamID uint32 // BlockFragment is part (or all) of a Header Block. BlockFragment []byte // EndStream indicates that the header block is the last that // the endpoint will send for the identified stream. Setting // this flag causes the stream to enter one of "half closed" // states. EndStream bool // EndHeaders indicates that this frame contains an entire // header block and is not followed by any // CONTINUATION frames. EndHeaders bool // PadLength is the optional number of bytes of zeros to add // to this frame. PadLength uint8 // Priority, if non-zero, includes stream priority information // in the HEADER frame. Priority PriorityParam } // WriteHeaders writes a single HEADERS frame. // // This is a low-level header writing method. Encoding headers and // splitting them into any necessary CONTINUATION frames is handled // elsewhere. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility to not call other Write methods concurrently. func (f *Framer) WriteHeaders(p HeadersFrameParam) error { if !validStreamID(p.StreamID) && !f.AllowIllegalWrites { return errStreamID } var flags Flags if p.PadLength != 0 { flags |= FlagHeadersPadded } if p.EndStream { flags |= FlagHeadersEndStream } if p.EndHeaders { flags |= FlagHeadersEndHeaders } if !p.Priority.IsZero() { flags |= FlagHeadersPriority } f.startWrite(FrameHeaders, flags, p.StreamID) if p.PadLength != 0 { f.writeByte(p.PadLength) } if !p.Priority.IsZero() { v := p.Priority.StreamDep if !validStreamIDOrZero(v) && !f.AllowIllegalWrites { return errDepStreamID } if p.Priority.Exclusive { v |= 1 << 31 } f.writeUint32(v) f.writeByte(p.Priority.Weight) } f.wbuf = append(f.wbuf, p.BlockFragment...) f.wbuf = append(f.wbuf, padZeros[:p.PadLength]...) return f.endWrite() } // A PriorityFrame specifies the sender-advised priority of a stream. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.3 type PriorityFrame struct { FrameHeader PriorityParam } // PriorityParam are the stream prioritzation parameters. type PriorityParam struct { // StreamDep is a 31-bit stream identifier for the // stream that this stream depends on. Zero means no // dependency. StreamDep uint32 // Exclusive is whether the dependency is exclusive. Exclusive bool // Weight is the stream's zero-indexed weight. It should be // set together with StreamDep, or neither should be set. Per // the spec, "Add one to the value to obtain a weight between // 1 and 256." Weight uint8 } func (p PriorityParam) IsZero() bool { return p == PriorityParam{} } func parsePriorityFrame(_ *frameCache, fh FrameHeader, countError func(string), payload []byte) (Frame, error) { if fh.StreamID == 0 { countError("frame_priority_zero_stream") return nil, connError{ErrCodeProtocol, "PRIORITY frame with stream ID 0"} } if len(payload) != 5 { countError("frame_priority_bad_length") return nil, connError{ErrCodeFrameSize, fmt.Sprintf("PRIORITY frame payload size was %d; want 5", len(payload))} } v := binary.BigEndian.Uint32(payload[:4]) streamID := v & 0x7fffffff // mask off high bit return &PriorityFrame{ FrameHeader: fh, PriorityParam: PriorityParam{ Weight: payload[4], StreamDep: streamID, Exclusive: streamID != v, // was high bit set? }, }, nil } // WritePriority writes a PRIORITY frame. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility to not call other Write methods concurrently. func (f *Framer) WritePriority(streamID uint32, p PriorityParam) error { if !validStreamID(streamID) && !f.AllowIllegalWrites { return errStreamID } if !validStreamIDOrZero(p.StreamDep) { return errDepStreamID } f.startWrite(FramePriority, 0, streamID) v := p.StreamDep if p.Exclusive { v |= 1 << 31 } f.writeUint32(v) f.writeByte(p.Weight) return f.endWrite() } // A RSTStreamFrame allows for abnormal termination of a stream. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.4 type RSTStreamFrame struct { FrameHeader ErrCode ErrCode } func parseRSTStreamFrame(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (Frame, error) { if len(p) != 4 { countError("frame_rststream_bad_len") return nil, ConnectionError(ErrCodeFrameSize) } if fh.StreamID == 0 { countError("frame_rststream_zero_stream") return nil, ConnectionError(ErrCodeProtocol) } return &RSTStreamFrame{fh, ErrCode(binary.BigEndian.Uint32(p[:4]))}, nil } // WriteRSTStream writes a RST_STREAM frame. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility to not call other Write methods concurrently. func (f *Framer) WriteRSTStream(streamID uint32, code ErrCode) error { if !validStreamID(streamID) && !f.AllowIllegalWrites { return errStreamID } f.startWrite(FrameRSTStream, 0, streamID) f.writeUint32(uint32(code)) return f.endWrite() } // A ContinuationFrame is used to continue a sequence of header block fragments. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.10 type ContinuationFrame struct { FrameHeader headerFragBuf []byte } func parseContinuationFrame(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (Frame, error) { if fh.StreamID == 0 { countError("frame_continuation_zero_stream") return nil, connError{ErrCodeProtocol, "CONTINUATION frame with stream ID 0"} } return &ContinuationFrame{fh, p}, nil } func (f *ContinuationFrame) HeaderBlockFragment() []byte { f.checkValid() return f.headerFragBuf } func (f *ContinuationFrame) HeadersEnded() bool { return f.FrameHeader.Flags.Has(FlagContinuationEndHeaders) } // WriteContinuation writes a CONTINUATION frame. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility to not call other Write methods concurrently. func (f *Framer) WriteContinuation(streamID uint32, endHeaders bool, headerBlockFragment []byte) error { if !validStreamID(streamID) && !f.AllowIllegalWrites { return errStreamID } var flags Flags if endHeaders { flags |= FlagContinuationEndHeaders } f.startWrite(FrameContinuation, flags, streamID) f.wbuf = append(f.wbuf, headerBlockFragment...) return f.endWrite() } // A PushPromiseFrame is used to initiate a server stream. // See https://httpwg.org/specs/rfc7540.html#rfc.section.6.6 type PushPromiseFrame struct { FrameHeader PromiseID uint32 headerFragBuf []byte // not owned } func (f *PushPromiseFrame) HeaderBlockFragment() []byte { f.checkValid() return f.headerFragBuf } func (f *PushPromiseFrame) HeadersEnded() bool { return f.FrameHeader.Flags.Has(FlagPushPromiseEndHeaders) } func parsePushPromise(_ *frameCache, fh FrameHeader, countError func(string), p []byte) (_ Frame, err error) { pp := &PushPromiseFrame{ FrameHeader: fh, } if pp.StreamID == 0 { // PUSH_PROMISE frames MUST be associated with an existing, // peer-initiated stream. The stream identifier of a // PUSH_PROMISE frame indicates the stream it is associated // with. If the stream identifier field specifies the value // 0x0, a recipient MUST respond with a connection error // (Section 5.4.1) of type PROTOCOL_ERROR. countError("frame_pushpromise_zero_stream") return nil, ConnectionError(ErrCodeProtocol) } // The PUSH_PROMISE frame includes optional padding. // Padding fields and flags are identical to those defined for DATA frames var padLength uint8 if fh.Flags.Has(FlagPushPromisePadded) { if p, padLength, err = readByte(p); err != nil { countError("frame_pushpromise_pad_short") return } } p, pp.PromiseID, err = readUint32(p) if err != nil { countError("frame_pushpromise_promiseid_short") return } pp.PromiseID = pp.PromiseID & (1<<31 - 1) if int(padLength) > len(p) { // like the DATA frame, error out if padding is longer than the body. countError("frame_pushpromise_pad_too_big") return nil, ConnectionError(ErrCodeProtocol) } pp.headerFragBuf = p[:len(p)-int(padLength)] return pp, nil } // PushPromiseParam are the parameters for writing a PUSH_PROMISE frame. type PushPromiseParam struct { // StreamID is the required Stream ID to initiate. StreamID uint32 // PromiseID is the required Stream ID which this // Push Promises PromiseID uint32 // BlockFragment is part (or all) of a Header Block. BlockFragment []byte // EndHeaders indicates that this frame contains an entire // header block and is not followed by any // CONTINUATION frames. EndHeaders bool // PadLength is the optional number of bytes of zeros to add // to this frame. PadLength uint8 } // WritePushPromise writes a single PushPromise Frame. // // As with Header Frames, This is the low level call for writing // individual frames. Continuation frames are handled elsewhere. // // It will perform exactly one Write to the underlying Writer. // It is the caller's responsibility to not call other Write methods concurrently. func (f *Framer) WritePushPromise(p PushPromiseParam) error { if !validStreamID(p.StreamID) && !f.AllowIllegalWrites { return errStreamID } var flags Flags if p.PadLength != 0 { flags |= FlagPushPromisePadded } if p.EndHeaders { flags |= FlagPushPromiseEndHeaders } f.startWrite(FramePushPromise, flags, p.StreamID) if p.PadLength != 0 { f.writeByte(p.PadLength) } if !validStreamID(p.PromiseID) && !f.AllowIllegalWrites { return errStreamID } f.writeUint32(p.PromiseID) f.wbuf = append(f.wbuf, p.BlockFragment...) f.wbuf = append(f.wbuf, padZeros[:p.PadLength]...) return f.endWrite() } // WriteRawFrame writes a raw frame. This can be used to write // extension frames unknown to this package. func (f *Framer) WriteRawFrame(t FrameType, flags Flags, streamID uint32, payload []byte) error { f.startWrite(t, flags, streamID) f.writeBytes(payload) return f.endWrite() } func readByte(p []byte) (remain []byte, b byte, err error) { if len(p) == 0 { return nil, 0, io.ErrUnexpectedEOF } return p[1:], p[0], nil } func readUint32(p []byte) (remain []byte, v uint32, err error) { if len(p) < 4 { return nil, 0, io.ErrUnexpectedEOF } return p[4:], binary.BigEndian.Uint32(p[:4]), nil } type streamEnder interface { StreamEnded() bool } type headersEnder interface { HeadersEnded() bool } type headersOrContinuation interface { headersEnder HeaderBlockFragment() []byte } // A MetaHeadersFrame is the representation of one HEADERS frame and // zero or more contiguous CONTINUATION frames and the decoding of // their HPACK-encoded contents. // // This type of frame does not appear on the wire and is only returned // by the Framer when Framer.ReadMetaHeaders is set. type MetaHeadersFrame struct { *HeadersFrame // Fields are the fields contained in the HEADERS and // CONTINUATION frames. The underlying slice is owned by the // Framer and must not be retained after the next call to // ReadFrame. // // Fields are guaranteed to be in the correct http2 order and // not have unknown pseudo header fields or invalid header // field names or values. Required pseudo header fields may be // missing, however. Use the MetaHeadersFrame.Pseudo accessor // method access pseudo headers. Fields []hpack.HeaderField // Truncated is whether the max header list size limit was hit // and Fields is incomplete. The hpack decoder state is still // valid, however. Truncated bool } // PseudoValue returns the given pseudo header field's value. // The provided pseudo field should not contain the leading colon. func (mh *MetaHeadersFrame) PseudoValue(pseudo string) string { for _, hf := range mh.Fields { if !hf.IsPseudo() { return "" } if hf.Name[1:] == pseudo { return hf.Value } } return "" } // RegularFields returns the regular (non-pseudo) header fields of mh. // The caller does not own the returned slice. func (mh *MetaHeadersFrame) RegularFields() []hpack.HeaderField { for i, hf := range mh.Fields { if !hf.IsPseudo() { return mh.Fields[i:] } } return nil } // PseudoFields returns the pseudo header fields of mh. // The caller does not own the returned slice. func (mh *MetaHeadersFrame) PseudoFields() []hpack.HeaderField { for i, hf := range mh.Fields { if !hf.IsPseudo() { return mh.Fields[:i] } } return mh.Fields } func (mh *MetaHeadersFrame) checkPseudos() error { var isRequest, isResponse bool pf := mh.PseudoFields() for i, hf := range pf { switch hf.Name { case ":method", ":path", ":scheme", ":authority": isRequest = true case ":status": isResponse = true default: return pseudoHeaderError(hf.Name) } // Check for duplicates. // This would be a bad algorithm, but N is 4. // And this doesn't allocate. for _, hf2 := range pf[:i] { if hf.Name == hf2.Name { return duplicatePseudoHeaderError(hf.Name) } } } if isRequest && isResponse { return errMixPseudoHeaderTypes } return nil } func (fr *Framer) maxHeaderStringLen() int { v := int(fr.maxHeaderListSize()) if v < 0 { // If maxHeaderListSize overflows an int, use no limit (0). return 0 } return v } // readMetaFrame returns 0 or more CONTINUATION frames from fr and // merge them into the provided hf and returns a MetaHeadersFrame // with the decoded hpack values. func (fr *Framer) readMetaFrame(hf *HeadersFrame) (*MetaHeadersFrame, error) { if fr.AllowIllegalReads { return nil, errors.New("illegal use of AllowIllegalReads with ReadMetaHeaders") } mh := &MetaHeadersFrame{ HeadersFrame: hf, } var remainSize = fr.maxHeaderListSize() var sawRegular bool var invalid error // pseudo header field errors hdec := fr.ReadMetaHeaders hdec.SetEmitEnabled(true) hdec.SetMaxStringLength(fr.maxHeaderStringLen()) hdec.SetEmitFunc(func(hf hpack.HeaderField) { if VerboseLogs && fr.logReads { fr.debugReadLoggerf("http2: decoded hpack field %+v", hf) } if !httpguts.ValidHeaderFieldValue(hf.Value) { // Don't include the value in the error, because it may be sensitive. invalid = headerFieldValueError(hf.Name) } isPseudo := strings.HasPrefix(hf.Name, ":") if isPseudo { if sawRegular { invalid = errPseudoAfterRegular } } else { sawRegular = true if !validWireHeaderFieldName(hf.Name) { invalid = headerFieldNameError(hf.Name) } } if invalid != nil { hdec.SetEmitEnabled(false) return } size := hf.Size() if size > remainSize { hdec.SetEmitEnabled(false) mh.Truncated = true return } remainSize -= size mh.Fields = append(mh.Fields, hf) }) // Lose reference to MetaHeadersFrame: defer hdec.SetEmitFunc(func(hf hpack.HeaderField) {}) var hc headersOrContinuation = hf for { frag := hc.HeaderBlockFragment() if _, err := hdec.Write(frag); err != nil { return nil, ConnectionError(ErrCodeCompression) } if hc.HeadersEnded() { break } if f, err := fr.ReadFrame(); err != nil { return nil, err } else { hc = f.(*ContinuationFrame) // guaranteed by checkFrameOrder } } mh.HeadersFrame.headerFragBuf = nil mh.HeadersFrame.invalidate() if err := hdec.Close(); err != nil { return nil, ConnectionError(ErrCodeCompression) } if invalid != nil { fr.errDetail = invalid if VerboseLogs { log.Printf("http2: invalid header: %v", invalid) } return nil, StreamError{mh.StreamID, ErrCodeProtocol, invalid} } if err := mh.checkPseudos(); err != nil { fr.errDetail = err if VerboseLogs { log.Printf("http2: invalid pseudo headers: %v", err) } return nil, StreamError{mh.StreamID, ErrCodeProtocol, err} } return mh, nil } func summarizeFrame(f Frame) string { var buf bytes.Buffer f.Header().writeDebug(&buf) switch f := f.(type) { case *SettingsFrame: n := 0 f.ForeachSetting(func(s Setting) error { n++ if n == 1 { buf.WriteString(", settings:") } fmt.Fprintf(&buf, " %v=%v,", s.ID, s.Val) return nil }) if n > 0 { buf.Truncate(buf.Len() - 1) // remove trailing comma } case *DataFrame: data := f.Data() const max = 256 if len(data) > max { data = data[:max] } fmt.Fprintf(&buf, " data=%q", data) if len(f.Data()) > max { fmt.Fprintf(&buf, " (%d bytes omitted)", len(f.Data())-max) } case *WindowUpdateFrame: if f.StreamID == 0 { buf.WriteString(" (conn)") } fmt.Fprintf(&buf, " incr=%v", f.Increment) case *PingFrame: fmt.Fprintf(&buf, " ping=%q", f.Data[:]) case *GoAwayFrame: fmt.Fprintf(&buf, " LastStreamID=%v ErrCode=%v Debug=%q", f.LastStreamID, f.ErrCode, f.debugData) case *RSTStreamFrame: fmt.Fprintf(&buf, " ErrCode=%v", f.ErrCode) } return buf.String() }