Documentation ¶
Overview ¶
Package pktline implements reading payloads form pkt-lines and encoding pkt-lines from payloads.
Index ¶
Examples ¶
Constants ¶
const (
// MaxPayloadSize is the maximum payload size of a pkt-line in bytes.
MaxPayloadSize = 65516
)
Variables ¶
var ( // FlushPkt are the contents of a flush-pkt pkt-line. FlushPkt = []byte{'0', '0', '0', '0'} // Flush is the payload to use with the Encode method to encode a flush-pkt. Flush = []byte{} // FlushString is the payload to use with the EncodeString method to encode a flush-pkt. FlushString = "" // ErrPayloadTooLong is returned by the Encode methods when any of the // provided payloads is bigger than MaxPayloadSize. ErrPayloadTooLong = errors.New("payload is too long") )
var ErrInvalidPktLen = errors.New("invalid pkt-len found")
ErrInvalidPktLen is returned by Err() when an invalid pkt-len is found.
Functions ¶
This section is empty.
Types ¶
type Encoder ¶
type Encoder struct {
// contains filtered or unexported fields
}
An Encoder writes pkt-lines to an output stream.
Example ¶
// Create an encoder that writes pktlines to stdout. e := pktline.NewEncoder(os.Stdout) // Encode some data as a new pkt-line. _ = e.Encode([]byte("data\n")) // error checks removed for brevity // Encode a flush-pkt. _ = e.Flush() // Encode a couple of byte slices and a flush in one go. Each of // them will end up as payloads of their own pktlines. _ = e.Encode( []byte("hello\n"), []byte("world!\n"), pktline.Flush, ) // You can also encode strings: _ = e.EncodeString( "foo\n", "bar\n", pktline.FlushString, ) // You can also format and encode a payload: _ = e.Encodef(" %s %d\n", "foo", 42)
Output: 0009data 0000000ahello 000bworld! 00000008foo 0008bar 0000000c foo 42
func NewEncoder ¶
NewEncoder returns a new encoder that writes to w.
func (*Encoder) Encode ¶
Encode encodes a pkt-line with the payload specified and write it to the output stream. If several payloads are specified, each of them will get streamed in their own pkt-lines.
func (*Encoder) EncodeString ¶
EncodeString works similarly as Encode but payloads are specified as strings.
type Scanner ¶
type Scanner struct {
// contains filtered or unexported fields
}
Scanner provides a convenient interface for reading the payloads of a series of pkt-lines. It takes an io.Reader providing the source, which then can be tokenized through repeated calls to the Scan method.
After each Scan call, the Bytes method will return the payload of the corresponding pkt-line on a shared buffer, which will be 65516 bytes or smaller. Flush pkt-lines are represented by empty byte slices.
Scanning stops at EOF or the first I/O error.
Example ¶
package main import ( "bytes" "fmt" "io" "strings" "gopkg.in/src-d/go-git.v4/plumbing/format/packp/pktline" . "gopkg.in/check.v1" ) type SuiteScanner struct{} var _ = Suite(&SuiteScanner{}) func (s *SuiteScanner) TestInvalid(c *C) { for _, test := range [...]string{ "0001", "0002", "0003", "0004", "0001asdfsadf", "0004foo", "fff1", "fff2", "gorka", "0", "003", " 5a", "5 a", "5 \n", "-001", "-000", } { r := strings.NewReader(test) sc := pktline.NewScanner(r) _ = sc.Scan() c.Assert(sc.Err(), ErrorMatches, pktline.ErrInvalidPktLen.Error(), Commentf("data = %q", test)) } } func (s *SuiteScanner) TestEmptyReader(c *C) { r := strings.NewReader("") sc := pktline.NewScanner(r) hasPayload := sc.Scan() c.Assert(hasPayload, Equals, false) c.Assert(sc.Err(), Equals, nil) } func (s *SuiteScanner) TestFlush(c *C) { var buf bytes.Buffer e := pktline.NewEncoder(&buf) err := e.Flush() c.Assert(err, IsNil) sc := pktline.NewScanner(&buf) c.Assert(sc.Scan(), Equals, true) payload := sc.Bytes() c.Assert(len(payload), Equals, 0) } func (s *SuiteScanner) TestPktLineTooShort(c *C) { r := strings.NewReader("010cfoobar") sc := pktline.NewScanner(r) c.Assert(sc.Scan(), Equals, false) c.Assert(sc.Err(), ErrorMatches, "unexpected EOF") } func (s *SuiteScanner) TestScanAndPayload(c *C) { for _, test := range [...]string{ "a", "a\n", strings.Repeat("a", 100), strings.Repeat("a", 100) + "\n", strings.Repeat("\x00", 100), strings.Repeat("\x00", 100) + "\n", strings.Repeat("a", pktline.MaxPayloadSize), strings.Repeat("a", pktline.MaxPayloadSize-1) + "\n", } { var buf bytes.Buffer e := pktline.NewEncoder(&buf) err := e.EncodeString(test) c.Assert(err, IsNil, Commentf("input len=%x, contents=%.10q\n", len(test), test)) sc := pktline.NewScanner(&buf) c.Assert(sc.Scan(), Equals, true, Commentf("test = %.20q...", test)) obtained := sc.Bytes() c.Assert(obtained, DeepEquals, []byte(test), Commentf("in = %.20q out = %.20q", test, string(obtained))) } } func (s *SuiteScanner) TestSkip(c *C) { for _, test := range [...]struct { input []string n int expected []byte }{ { input: []string{ "first", "second", "third"}, n: 1, expected: []byte("second"), }, { input: []string{ "first", "second", "third"}, n: 2, expected: []byte("third"), }, } { var buf bytes.Buffer e := pktline.NewEncoder(&buf) err := e.EncodeString(test.input...) c.Assert(err, IsNil) sc := pktline.NewScanner(&buf) for i := 0; i < test.n; i++ { c.Assert(sc.Scan(), Equals, true, Commentf("scan error = %s", sc.Err())) } c.Assert(sc.Scan(), Equals, true, Commentf("scan error = %s", sc.Err())) obtained := sc.Bytes() c.Assert(obtained, DeepEquals, test.expected, Commentf("\nin = %.20q\nout = %.20q\nexp = %.20q", test.input, obtained, test.expected)) } } func (s *SuiteScanner) TestEOF(c *C) { var buf bytes.Buffer e := pktline.NewEncoder(&buf) err := e.EncodeString("first", "second") c.Assert(err, IsNil) sc := pktline.NewScanner(&buf) for sc.Scan() { } c.Assert(sc.Err(), IsNil) } // A section are several non flush-pkt lines followed by a flush-pkt, which // how the git protocol sends long messages. func (s *SuiteScanner) TestReadSomeSections(c *C) { nSections := 2 nLines := 4 data := sectionsExample(c, nSections, nLines) sc := pktline.NewScanner(data) sectionCounter := 0 lineCounter := 0 for sc.Scan() { if len(sc.Bytes()) == 0 { sectionCounter++ } lineCounter++ } c.Assert(sc.Err(), IsNil) c.Assert(sectionCounter, Equals, nSections) c.Assert(lineCounter, Equals, (1+nLines)*nSections) } // returns nSection sections, each of them with nLines pkt-lines (not // counting the flush-pkt: // // 0009 0.0\n // 0009 0.1\n // ... // 0000 // and so on func sectionsExample(c *C, nSections, nLines int) io.Reader { var buf bytes.Buffer e := pktline.NewEncoder(&buf) for section := 0; section < nSections; section++ { ss := []string{} for line := 0; line < nLines; line++ { line := fmt.Sprintf(" %d.%d\n", section, line) ss = append(ss, line) } err := e.EncodeString(ss...) c.Assert(err, IsNil) err = e.Flush() c.Assert(err, IsNil) } return &buf } func main() { // A reader is needed as input. input := strings.NewReader("000ahello\n" + "000bworld!\n" + "0000", ) // Create the scanner... s := pktline.NewScanner(input) // and scan every pkt-line found in the input. for s.Scan() { payload := s.Bytes() if len(payload) == 0 { // zero sized payloads correspond to flush-pkts. fmt.Println("FLUSH-PKT DETECTED\n") } else { // otherwise, you will be able to access the full payload. fmt.Printf("PAYLOAD = %q\n", string(payload)) } } // this will catch any error when reading from the input, if any. if s.Err() != nil { fmt.Println(s.Err()) } }
Output: PAYLOAD = "hello\n" PAYLOAD = "world!\n" FLUSH-PKT DETECTED
func NewScanner ¶
NewScanner returns a new Scanner to read from r.
func (*Scanner) Bytes ¶
Bytes returns the most recent payload generated by a call to Scan. The underlying array may point to data that will be overwritten by a subsequent call to Scan. It does no allocation.
func (*Scanner) Scan ¶
Scan advances the Scanner to the next pkt-line, whose payload will then be available through the Bytes method. Scanning stops at EOF or the first I/O error. After Scan returns false, the Err method will return any error that occurred during scanning, except that if it was io.EOF, Err will return nil.