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oh momma. a lot of modifications and it appears to be working. w00t.

This commit is contained in:
Andrew Gallant (Ocelot) 2012-05-05 02:56:15 -04:00
parent c222d406b0
commit 4a7b05be36
3 changed files with 3620 additions and 1609 deletions
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111
nexgb/cookie.go Normal file
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@ -0,0 +1,111 @@
package xgb
import (
"errors"
)
type cookie struct {
Sequence uint16
replyChan chan []byte
errorChan chan error
pingChan chan bool
}
func (c *Conn) newCookie(checked, reply bool) cookie {
cookie := cookie{
Sequence: c.newSequenceId(),
replyChan: nil,
errorChan: nil,
pingChan: nil,
}
// There are four different kinds of cookies:
// Checked requests with replies get a reply channel and an error channel.
// Unchecked requests with replies get a reply channel and a ping channel.
// Checked requests w/o replies get a ping channel and an error channel.
// Unchecked requests w/o replies get no channels.
// The reply channel is used to send reply data.
// The error channel is used to send error data.
// The ping channel is used when one of the 'reply' or 'error' channels
// is missing but the other is present. The ping channel is way to force
// the blocking to stop and basically say "the error has been received
// in the main event loop" (when the ping channel is coupled with a reply
// channel) or "the request you made that has no reply was successful"
// (when the ping channel is coupled with an error channel).
if checked {
cookie.errorChan = make(chan error, 1)
if !reply {
cookie.pingChan = make(chan bool, 1)
}
}
if reply {
cookie.replyChan = make(chan []byte, 1)
if !checked {
cookie.pingChan = make(chan bool, 1)
}
}
return cookie
}
func (c cookie) reply() ([]byte, error) {
// checked
if c.errorChan != nil {
return c.replyChecked()
}
return c.replyUnchecked()
}
func (c cookie) replyChecked() ([]byte, error) {
if c.replyChan == nil {
return nil, errors.New("Cannot call 'replyChecked' on a cookie that " +
"is not expecting a *reply* or an error.")
}
if c.errorChan == nil {
return nil, errors.New("Cannot call 'replyChecked' on a cookie that " +
"is not expecting a reply or an *error*.")
}
select {
case reply := <-c.replyChan:
return reply, nil
case err := <-c.errorChan:
return nil, err
}
panic("unreachable")
}
func (c cookie) replyUnchecked() ([]byte, error) {
if c.replyChan == nil {
return nil, errors.New("Cannot call 'replyUnchecked' on a cookie " +
"that is not expecting a *reply*.")
}
select {
case reply := <-c.replyChan:
return reply, nil
case <-c.pingChan:
return nil, nil
}
panic("unreachable")
}
func (c cookie) Check() error {
if c.replyChan != nil {
return errors.New("Cannot call 'Check' on a cookie that is " +
"expecting a *reply*. Use 'Reply' instead.")
}
if c.errorChan == nil {
return errors.New("Cannot call 'Check' on a cookie that is " +
"not expecting a possible *error*.")
}
select {
case err := <-c.errorChan:
return err
case <-c.pingChan:
return nil
}
panic("unreachable")
}

498
nexgb/xgb.go
View File

@ -25,27 +25,18 @@ const (
type Conn struct { type Conn struct {
host string host string
conn net.Conn conn net.Conn
nextCookie uint16
cookies map[uint16]*Cookie
events queue
err error err error
display string display string
defaultScreen int defaultScreen int
scratch [32]byte
Setup SetupInfo Setup SetupInfo
extensions map[string]byte extensions map[string]byte
requestChan chan *Request eventChan chan eventOrError
requestCookieChan chan *Cookie cookieChan chan cookie
replyChan chan bool
eventChan chan bool
errorChan chan bool
xidChan chan xid xidChan chan xid
newIdLock sync.Mutex seqChan chan uint16
writeLock sync.Mutex reqChan chan *request
dequeueLock sync.Mutex
cookieLock sync.Mutex
extLock sync.Mutex extLock sync.Mutex
} }
@ -75,16 +66,18 @@ func NewConnDisplay(display string) (*Conn, error) {
return nil, err return nil, err
} }
conn.xidChan = make(chan xid, 5)
go conn.generateXids()
conn.nextCookie = 1
conn.cookies = make(map[uint16]*Cookie)
conn.events = queue{make([][]byte, 100), 0, 0}
conn.extensions = make(map[string]byte) conn.extensions = make(map[string]byte)
conn.newReadChannels() conn.cookieChan = make(chan cookie, 100)
conn.newRequestChannels() conn.xidChan = make(chan xid, 5)
conn.seqChan = make(chan uint16, 20)
conn.reqChan = make(chan *request, 100)
conn.eventChan = make(chan eventOrError, 100)
go conn.generateXIds()
go conn.generateSeqIds()
go conn.sendRequests()
go conn.readResponses()
return conn, nil return conn, nil
} }
@ -97,43 +90,11 @@ func (c *Conn) Close() {
// Id is used for all X identifiers, such as windows, pixmaps, and GCs. // Id is used for all X identifiers, such as windows, pixmaps, and GCs.
type Id uint32 type Id uint32
// Request is used to abstract the difference between a request
// that expects a reply and a request that doesn't expect a reply.
type Request struct {
buf []byte
cookieChan chan *Cookie
}
func newRequest(buf []byte, needsReply bool) *Request {
req := &Request{
buf: buf,
cookieChan: nil,
}
if needsReply {
req.cookieChan = make(chan *Cookie)
}
return req
}
// Cookies are the sequence numbers used to pair replies up with their requests
type Cookie struct {
id uint16
replyChan chan []byte
errorChan chan error
}
func newCookie(id uint16) *Cookie {
return &Cookie{
id: id,
replyChan: make(chan []byte, 1),
errorChan: make(chan error, 1),
}
}
// Event is an interface that can contain any of the events returned by the // Event is an interface that can contain any of the events returned by the
// server. Use a type assertion switch to extract the Event structs. // server. Use a type assertion switch to extract the Event structs.
type Event interface { type Event interface {
ImplementsEvent() ImplementsEvent()
Bytes() []byte
} }
// newEventFuncs is a map from event numbers to functions that create // newEventFuncs is a map from event numbers to functions that create
@ -153,6 +114,10 @@ type Error interface {
// the corresponding error. // the corresponding error.
var newErrorFuncs = map[int]func(buf []byte) Error{} var newErrorFuncs = map[int]func(buf []byte) Error{}
// eventOrError corresponds to values that can be either an event or an
// error.
type eventOrError interface{}
// NewID generates a new unused ID for use with requests like CreateWindow. // NewID generates a new unused ID for use with requests like CreateWindow.
// If no new ids can be generated, the id returned is 0 and error is non-nil. // If no new ids can be generated, the id returned is 0 and error is non-nil.
func (c *Conn) NewId() (Id, error) { func (c *Conn) NewId() (Id, error) {
@ -164,7 +129,7 @@ func (c *Conn) NewId() (Id, error) {
} }
// xid encapsulates a resource identifier being sent over the Conn.xidChan // xid encapsulates a resource identifier being sent over the Conn.xidChan
// channel. If no new resource id can be generated, id is set to -1 and a // channel. If no new resource id can be generated, id is set to 0 and a
// non-nil error is set in xid.err. // non-nil error is set in xid.err.
type xid struct { type xid struct {
id Id id Id
@ -174,7 +139,24 @@ type xid struct {
// generateXids sends new Ids down the channel for NewId to use. // generateXids sends new Ids down the channel for NewId to use.
// This needs to be updated to use the XC Misc extension once we run out of // This needs to be updated to use the XC Misc extension once we run out of
// new ids. // new ids.
func (conn *Conn) generateXids() { // Thanks to libxcb/src/xcb_xid.c. This code is greatly inspired by it.
func (conn *Conn) generateXIds() {
// This requires some explanation. From the horse's mouth:
// "The resource-id-mask contains a single contiguous set of bits (at least
// 18). The client allocates resource IDs for types WINDOW, PIXMAP,
// CURSOR, FONT, GCONTEXT, and COLORMAP by choosing a value with only some
// subset of these bits set and ORing it with resource-id-base. Only values
// constructed in this way can be used to name newly created resources over
// this connection."
// So for example (using 8 bit integers), the mask might look like:
// 00111000
// So that valid values would be 00101000, 00110000, 00001000, and so on.
// Thus, the idea is to increment it by the place of the last least
// significant '1'. In this case, that value would be 00001000. To get
// that value, we can AND the original mask with its two's complement:
// 00111000 & 11001000 = 00001000.
// And we use that value to increment the last resource id to get a new one.
// (And then, of course, we OR it with resource-id-base.)
inc := conn.Setup.ResourceIdMask & -conn.Setup.ResourceIdMask inc := conn.Setup.ResourceIdMask & -conn.Setup.ResourceIdMask
max := conn.Setup.ResourceIdMask max := conn.Setup.ResourceIdMask
last := uint32(0) last := uint32(0)
@ -196,11 +178,224 @@ func (conn *Conn) generateXids() {
} }
} }
// newSeqId fetches the next sequence id from the Conn.seqChan channel.
func (c *Conn) newSequenceId() uint16 {
return <-c.seqChan
}
// generateSeqIds returns new sequence ids.
// A sequence id is generated for *every* request. It's the identifier used
// to match up replies with requests.
// Since sequence ids can only be 16 bit integers we start over at zero when it
// comes time to wrap.
// FIXME: 65,536 requests without replies cannot be made in a single sequence.
func (c *Conn) generateSeqIds() {
seqid := uint16(1)
for {
c.seqChan <- seqid
if seqid == uint16((1 << 16) - 1) {
seqid = 0
} else {
seqid++
}
}
}
// request encapsulates a buffer of raw bytes (containing the request data)
// and a cookie, which when combined represents a single request.
// The cookie is used to match up the reply/error.
type request struct {
buf []byte
cookie cookie
}
// newRequest takes the bytes an a cookie, constructs a request type,
// and sends it over the Conn.reqChan channel. It then returns the cookie
// (for convenience).
func (c *Conn) newRequest(buf []byte, cookie cookie) {
c.reqChan <- &request{buf: buf, cookie: cookie}
}
// sendRequests is run as a single goroutine that takes requests and writes
// the bytes to the wire and adds the cookie to the cookie queue.
func (c *Conn) sendRequests() {
for req := range c.reqChan {
c.cookieChan <- req.cookie
if _, err := c.conn.Write(req.buf); err != nil {
fmt.Fprintf(os.Stderr, "x protocol write error: %s\n", err)
close(c.reqChan)
return
}
}
}
// readResponses is a goroutine that reads events, errors and
// replies off the wire.
// When an event is read, it is always added to the event channel.
// When an error is read, if it corresponds to an existing checked cookie,
// it is sent to that cookie's error channel. Otherwise it is added to the
// event channel.
// When a reply is read, it is added to the corresponding cookie's reply
// channel. (It is an error if no such cookie exists in this case.)
// Finally, cookies that came "before" this reply are always cleaned up.
func (c *Conn) readResponses() {
var (
err Error
event Event
seq uint16
replyBytes []byte
)
buf := make([]byte, 32)
for {
err, event, seq = nil, nil, 0
if _, err := io.ReadFull(c.conn, buf); err != nil {
fmt.Fprintf(os.Stderr, "x protocol read error: %s\n", err)
close(c.eventChan)
break
}
switch buf[0] {
case 0: // This is an error
// Use the constructor function for this error (that is auto
// generated) by looking it up by the error number.
err = newErrorFuncs[int(buf[1])](buf)
seq = err.SequenceId()
// This error is either sent to the event channel or a specific
// cookie's error channel below.
case 1: // This is a reply
seq = Get16(buf[2:])
// check to see if this reply has more bytes to be read
size := Get32(buf[4:])
if size > 0 {
byteCount := 32 + size * 4
biggerBuf := make([]byte, byteCount)
copy(biggerBuf[:32], buf)
if _, err := io.ReadFull(c.conn, biggerBuf[32:]); err != nil {
fmt.Fprintf(os.Stderr, "x protocol read error: %s\n", err)
close(c.eventChan)
break
}
replyBytes = biggerBuf
} else {
replyBytes = buf
}
// This reply is sent to its corresponding cookie below.
default: // This is an event
// Use the constructor function for this event (like for errors,
// and is also auto generated) by looking it up by the event number.
// Note that we AND the event number with 127 so that we ignore
// the most significant bit (which is set when it was sent from
// a SendEvent request).
event = newEventFuncs[int(buf[0] & 127)](buf)
// seq = event.SequenceId() // 0 for KeymapNotify
// Put the event into the queue.
c.eventChan <- event
// No more processing for events.
continue
// If this was a KeymapNotify event, then we don't do any more
// processing since we don't have any sequence id.
// if event != nil {
// if _, ok := event.(KeymapNotifyEvent); ok {
// continue
// }
// }
}
// At this point, we have a sequence number and we're either
// processing an error or a reply, which are both responses to
// requests. So all we have to do is find the cookie corresponding
// to this error/reply, and send the appropriate data to it.
// In doing so, we make sure that any cookies that came before it
// are marked as successful if they are void and checked.
// If there's a cookie that requires a reply that is before this
// reply, then something is wrong.
for cookie := range c.cookieChan {
// This is the cookie we're looking for. Process and break.
if cookie.Sequence == seq {
if err != nil { // this is an error to a request
// synchronous processing
if cookie.errorChan != nil {
cookie.errorChan <- err
} else { // asynchronous processing
c.eventChan <- err
}
} else { // this is a reply
if cookie.replyChan == nil {
fmt.Fprintf(os.Stderr,
"Reply with sequence id %d does not have a " +
"cookie with a valid reply channel.\n", seq)
} else {
cookie.replyChan <- replyBytes
}
}
break
}
switch {
// Checked requests with replies
case cookie.replyChan != nil && cookie.errorChan != nil:
fmt.Fprintf(os.Stderr,
"Found cookie with sequence id %d that is expecting a " +
"reply but will never get it.\n", cookie.Sequence)
// Unchecked requests with replies
case cookie.replyChan != nil && cookie.pingChan != nil:
cookie.pingChan <- true
// Checked requests without replies
case cookie.pingChan != nil && cookie.errorChan != nil:
cookie.pingChan <- true
// Unchecked requests without replies don't have any channels,
// so we can't do anything with them except let them pass by.
}
}
}
}
// processEventOrError takes an eventOrError, type switches on it,
// and returns it in Go idiomatic style.
func processEventOrError(everr eventOrError) (Event, Error) {
switch ee := everr.(type) {
case Event:
return ee, nil
case Error:
return nil, ee
default:
fmt.Fprintf(os.Stderr, "Invalid event/error type: %T\n", everr)
}
panic("unreachable")
}
// WaitForEvent returns the next event from the server.
// It will block until an event is available.
func (c *Conn) WaitForEvent() (Event, Error) {
return processEventOrError(<-c.eventChan)
}
// PollForEvent returns the next event from the server if one is available in
// the internal queue.
// It will not block.
func (c *Conn) PollForEvent() (Event, Error) {
select {
case everr := <-c.eventChan:
return processEventOrError(everr)
default:
return nil, nil
}
panic("unreachable")
}
// RegisterExtension adds the respective extension's major op code to // RegisterExtension adds the respective extension's major op code to
// the extensions map. // the extensions map.
func (c *Conn) RegisterExtension(name string) error { func (c *Conn) RegisterExtension(name string) error {
nameUpper := strings.ToUpper(name) nameUpper := strings.ToUpper(name)
reply, err := c.QueryExtension(uint16(len(nameUpper)), nameUpper) reply, err := c.QueryExtension(uint16(len(nameUpper)), nameUpper).Reply()
switch { switch {
case err != nil: case err != nil:
@ -216,190 +411,3 @@ func (c *Conn) RegisterExtension(name string) error {
return nil return nil
} }
// A simple queue used to stow away events.
type queue struct {
data [][]byte
a, b int
}
func (q *queue) queue(item []byte) {
if q.b == len(q.data) {
if q.a > 0 {
copy(q.data, q.data[q.a:q.b])
q.a, q.b = 0, q.b-q.a
} else {
newData := make([][]byte, (len(q.data)*3)/2)
copy(newData, q.data)
q.data = newData
}
}
q.data[q.b] = item
q.b++
}
func (q *queue) dequeue(c *Conn) []byte {
c.dequeueLock.Lock()
defer c.dequeueLock.Unlock()
if q.a < q.b {
item := q.data[q.a]
q.a++
return item
}
return nil
}
// newWriteChan creates the channel required for writing to the net.Conn.
func (c *Conn) newRequestChannels() {
c.requestChan = make(chan *Request, writeBuffer)
c.requestCookieChan = make(chan *Cookie, 1)
go func() {
for request := range c.requestChan {
cookieNum := c.nextCookie
c.nextCookie++
if request.cookieChan != nil {
cookie := newCookie(cookieNum)
c.cookies[cookieNum] = cookie
request.cookieChan <- cookie
}
if _, err := c.conn.Write(request.buf); err != nil {
fmt.Fprintf(os.Stderr, "x protocol write error: %s\n", err)
close(c.requestChan)
return
}
}
}()
}
// request is a buffered write to net.Conn.
func (c *Conn) request(buf []byte, needsReply bool) *Cookie {
req := newRequest(buf, needsReply)
c.requestChan <- req
if req.cookieChan != nil {
cookie := <-req.cookieChan
close(req.cookieChan)
return cookie
}
return nil
}
func (c *Conn) sendRequest(needsReply bool, bufs ...[]byte) *Cookie {
if len(bufs) == 1 {
return c.request(bufs[0], needsReply)
}
total := make([]byte, 0)
for _, buf := range bufs {
total = append(total, buf...)
}
return c.request(total, needsReply)
}
func (c *Conn) newReadChannels() {
c.eventChan = make(chan bool, readBuffer)
onError := func() {
panic("read error")
}
go func() {
for {
buf := make([]byte, 32)
if _, err := io.ReadFull(c.conn, buf); err != nil {
fmt.Fprintf(os.Stderr, "x protocol read error: %s\n", err)
onError()
return
}
switch buf[0] {
case 0:
// err := &Error{
// Detail: buf[1],
// Cookie: uint16(get16(buf[2:])),
// Id: Id(get32(buf[4:])),
// Minor: get16(buf[8:]),
// Major: buf[10],
// }
err := newErrorFuncs[int(buf[1])](buf)
if cookie, ok := c.cookies[err.SequenceId()]; ok {
cookie.errorChan <- err
} else {
fmt.Fprintf(os.Stderr, "x protocol error: %s\n", err)
}
case 1:
seq := uint16(Get16(buf[2:]))
if _, ok := c.cookies[seq]; !ok {
continue
}
size := Get32(buf[4:])
if size > 0 {
bigbuf := make([]byte, 32+size*4, 32+size*4)
copy(bigbuf[0:32], buf)
if _, err := io.ReadFull(c.conn, bigbuf[32:]); err != nil {
fmt.Fprintf(os.Stderr,
"x protocol read error: %s\n", err)
onError()
return
}
c.cookies[seq].replyChan <- bigbuf
} else {
c.cookies[seq].replyChan <- buf
}
default:
c.events.queue(buf)
select {
case c.eventChan <- true:
default:
}
}
}
}()
}
func (c *Conn) waitForReply(cookie *Cookie) ([]byte, error) {
if cookie == nil {
panic("nil cookie")
}
if _, ok := c.cookies[cookie.id]; !ok {
panic("waiting for a cookie that will never come")
}
select {
case reply := <-cookie.replyChan:
return reply, nil
case err := <-cookie.errorChan:
return nil, err
}
panic("unreachable")
}
// WaitForEvent returns the next event from the server.
// It will block until an event is available.
func (c *Conn) WaitForEvent() (Event, error) {
for {
if reply := c.events.dequeue(c); reply != nil {
evCode := reply[0] & 0x7f
return newEventFuncs[int(evCode)](reply), nil
}
if !<-c.eventChan {
return nil, errors.New("Event channel has been closed.")
}
}
panic("unreachable")
}
// PollForEvent returns the next event from the server if one is available in the internal queue.
// It will not read from the connection, so you must call WaitForEvent to receive new events.
// Only use this function to empty the queue without blocking.
func (c *Conn) PollForEvent() (Event, error) {
if reply := c.events.dequeue(c); reply != nil {
evCode := reply[0] & 0x7f
return newEventFuncs[int(evCode)](reply), nil
}
return nil, nil
}

4620
nexgb/xproto.go
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