| version 1.3, 2000/01/04 09:14:14 |
version 1.7, 2000/01/15 03:46:27 |
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| % $OpenXM: OpenXM/doc/issac2000/session-management.tex,v 1.2 2000/01/02 07:32:12 takayama Exp $ |
% $OpenXM: OpenXM/doc/issac2000/session-management.tex,v 1.6 2000/01/15 00:20:46 takayama Exp $ |
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| \section{Session Management} |
\section{Session Management} |
| |
\label{secsession} |
| %MEMO: key words: |
%MEMO: key words: |
| %Security (ssh PAM), initial negotiation of byte order, |
%Security (ssh PAM), initial negotiation of byte order, |
| %mathcap, interruption, debugging window, etc. |
%mathcap, interruption, debugging window, etc. |
| Line 17 distributed computation. |
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| Line 17 distributed computation. |
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| |
|
| \subsection{Interface of servers} |
\subsection{Interface of servers} |
| |
|
| A server has the following I/O streams at its startup. The numbers |
A server has additional I/O streams for exchanging data between |
| indicate stream descriptors. |
a client and itself other than ones for diagnostic |
| |
messages. As the streams are for binary data, |
| \begin{description} |
the byte order conversion is necessary when a |
| \item{\bf 1} standard output |
client and a server have different byte orders. It is determined by |
| \item{\bf 2} standard error |
exchanging the preferable byte order of each peer. If the preference |
| \item{\bf 3} input from a client |
does not coincide with each other, |
| \item{\bf 4} output to a client |
then the network byte order is used. |
| \end{description} |
This implies that all servers and clients should be able to |
| |
handle the network byte |
| A server reads data from the stream {\bf 3} and writes results to the |
|
| stream {\bf 4}. The streams {\bf 1} and {\bf 2} are provided for |
|
| diagnostic messages from the server. As {\bf 3} and {\bf 4} are |
|
| streams for binary data, the byte order conversion is necessary when a |
|
| client and a server have different byte orders. There are several |
|
| methods to treat it and we adopted the following scheme. |
|
| |
|
| \begin{itemize} |
|
| \item A server writes 1 byte representing the preferable byte order. |
|
| \item After reading the byte, a client writes 1 byte representing the |
|
| preferable byte order. |
|
| \item On each side, if the preference coicides with each other then |
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| the byte order is used. Otherwise the network byte order is used. |
|
| \end{itemize} |
|
| |
|
| This implies that all servers and clients can handle the network byte |
|
| order. Nevertheless it is necessary to negotiate the byte order to |
order. Nevertheless it is necessary to negotiate the byte order to |
| skip the byte order conversion because its cost is often dominant over |
skip the byte order conversion because its cost is often dominant over |
| fast networks. |
fast networks. |
| Line 60 the launcher as follows. |
|
| Line 44 the launcher as follows. |
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| \item A launcher is invoked from a client or by hand. |
\item A launcher is invoked from a client or by hand. |
| When the launcher is invoked, a port number for TCP/IP connection |
When the launcher is invoked, a port number for TCP/IP connection |
| and the name of a server should be informed. |
and the name of a server should be informed. |
| \item The launcher and the client establish a conection with the |
\item The launcher and the client establish a connection with the |
| specified port number. |
specified port number. |
| \item The launcher create a process and execute the server after |
\item The launcher create a process and execute the server after |
| setting the streams {\bf 3} and {\bf 4} appropriately. |
setting the binary I/O channels appropriately. |
| An application to display messages written to the streams {\bf 1} and |
|
| {\bf 2} may be invoked if necessary. |
|
| \end{enumerate} |
\end{enumerate} |
| |
|
| Though the above is all the task as a launcher, the launcher process |
After finishing the above task as a launcher, the launcher process |
| acts as a control server and controls the server process created by |
acts as a control server and controls the server process created by |
| itself. As for a control server see Section \ref{control}. |
itself. As for a control server see Section \ref{control}. |
| |
|
| Line 77 itself. As for a control server see Section \ref{contr |
|
| Line 59 itself. As for a control server see Section \ref{contr |
|
| When we use a mathematical software, an execution time or necessary |
When we use a mathematical software, an execution time or necessary |
| storage is often unknown in advance. Therefore it is desirable |
storage is often unknown in advance. Therefore it is desirable |
| to be able to abort an execution and to start another execution. |
to be able to abort an execution and to start another execution. |
| On a usual session on UNIX it is done by an interruption from a keyboard. |
In OpenXM we adopted the following simple and robust method. |
| Internally it is realized by an exeption processing initiated by |
|
| a {\bf signal}, but it is not easy to send a signal to a server. |
|
| Especially if a server and a client run on different machines, |
|
| the client cannot send a signal to the server directly. |
|
| Though Some operating systems provide facilities to attach |
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| signals such as {\tt SIGIO} and {\tt SIGURG} to a stream data, they are |
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| system dependent and lack robustness. |
|
| On OpenXM we adopted the following simple and robust method. |
|
| |
|
| An OpenXM server has logically two I/O channels: one for exchanging |
An OpenXM server has logically two I/O channels: one for exchanging |
| data for computations and the other for controling computations. The |
data for computations and the other for controlling computations. The |
| control channel is used to send commands to control execution on the |
control channel is used to send commands to control execution on the |
| server. There are several ways of implementing the control channel. |
server. The launcher introduced in Section \ref{launcher} |
| Among them it is common to use the launcher introduced in Section |
is used as a control process. We call such a process a {\bf |
| \ref{launcher} as a control process. We call such a process a {\bf |
|
| control server}. In contrast, we call a server for computation an {\bf |
control server}. In contrast, we call a server for computation an {\bf |
| engine}. In this case the control server and the engine runs on the |
engine}. In this case the control server and the engine runs on the |
| same machine and it is easy to maniputalate the engine, especially to |
same machine and it is easy to manipulate the engine, especially to |
| send a signal from the control server. A control server is also an |
send a signal from the control server. A control server is also an |
| OpenXM stackmachine and the following {\tt SM} commands are provided. |
OpenXM stackmachine and it accepts {\tt SM\_control\_*} commands |
| |
to send signals to a server or to terminate a server. |
| |
|
| \begin{description} |
|
| \item {\tt SM\_control\_reset\_connection} |
|
| It requests a control server to send the {\tt SIGUSR1} signal. |
|
| |
|
| \item {\tt SM\_control\_kill} |
|
| It requests a control server to terminate an engine. |
|
| |
|
| \item {\tt SM\_control\_intr} |
|
| It requests a control server to send the {\tt SIGINT} signal. |
|
| \end{description} |
|
| |
|
| \subsection{Resetting a connection} |
\subsection{Resetting a connection} |
| |
|
| By using the control channel a client can send a signal to an engine |
By using the control channel a client can send a signal to an engine |
| Line 137 initiate a safe resetting of a connection. We show the |
|
| Line 100 initiate a safe resetting of a connection. We show the |
|
| a server and a client from the initiation to the completion of |
a server and a client from the initiation to the completion of |
| a resetting. |
a resetting. |
| |
|
| \noindent |
\centerline{\fbox{client}} |
| \fbox{client} |
|
| |
|
| \begin{enumerate} |
\begin{enumerate} |
| \item The client sends {\tt SM\_control\_reset\_connection} to the |
\item The client sends {\tt SM\_control\_reset\_connection} to the |
| control server. |
control server. The control server sends {\tt SIGUSR1} to the engine. |
| \item The client enters the resetting state. it skips all {\tt |
\item The client enters the resetting state. it skips all {\tt |
| OX} messages from the engine until it recieves {\tt OX\_SYNC\_BALL}. |
OX} messages from the engine until it receives {\tt OX\_SYNC\_BALL}. |
| \item After receiving {\tt OX\_SYNC\_BALL} the client sends |
\item After receiving {\tt OX\_SYNC\_BALL} the client sends |
| {\tt OX\_SYNC\_BALL} to the engine and returns to the usual state. |
{\tt OX\_SYNC\_BALL} to the engine and returns to the usual state. |
| \end{enumerate} |
\end{enumerate} |
| |
|
| \noindent |
\centerline{\fbox{engine}} |
| \fbox{engine} |
|
| |
|
| \begin{enumerate} |
\begin{enumerate} |
| \item After receiving {\tt SIGUSR1} from the control server, |
\item After receiving {\tt SIGUSR1} from the control server, |
| Line 161 the client reads and skips {\tt OX} messages soon afte |
|
| Line 122 the client reads and skips {\tt OX} messages soon afte |
|
| {\tt SM\_control\_reset\_connection}. |
{\tt SM\_control\_reset\_connection}. |
| \item The engine sends {\tt OX\_SYNC\_BALL} to the client. |
\item The engine sends {\tt OX\_SYNC\_BALL} to the client. |
| \item The engine skips all {\tt OX} messages from the engine until it |
\item The engine skips all {\tt OX} messages from the engine until it |
| recieves {\tt OX\_SYNC\_BALL}. |
receives {\tt OX\_SYNC\_BALL}. |
| \item After receiving {\tt OX\_SYNC\_BALL} the engine returns to the |
\item After receiving {\tt OX\_SYNC\_BALL} the engine returns to the |
| usual state. |
usual state. |
| \end{enumerate} |
\end{enumerate} |
| |
|
| {\tt OX\_SYNC\_BALL} means an end mark of the data remaining in the |
{\tt OX\_SYNC\_BALL} means an end mark of the data remaining in the |
| I/O streams. After reading it it is assured that the stream is empty |
I/O streams. After reading it it is assured that each stream is empty |
| and that a request from a client correctly corresponds to the response |
and that the subsequent request from a client correctly |
| from the server. For a safe resetting, it is important that the |
corresponds to the response from the server. |
| following actions are executed always in that order. |
We note that we don't have to associate {\tt OX\_SYNC\_BALL} with |
| |
any special action to be executed by the server because it is |
| |
assured that the peer is in the resetting state when one receives |
| |
{\tt OX\_SYNC\_BALL}. |
| |
|
| \begin{enumerate} |
\subsection{Debugging supports} |
| \item A signal is sent to an engine by a request from a client. |
To help debugging on the server, various supports are possible. If |
| \item The engine sends {\tt OX\_SYNC\_BALL} to the client. |
|
| \item The client sends {\tt OX\_SYNC\_BALL} to the engine after |
|
| receiving {\tt OX\_SYNC\_BALL}. |
|
| \end{enumerate} |
|
| |
|
| This assures that the peer is in the resetting state when one receives |
|
| {\tt OX\_SYNC\_BALL}. By this fact we don't have to associate it with |
|
| any special action to be executed by the server. Especially it can be |
|
| ignored if processes are in the usual state. If the above order is not |
|
| preserved, then both {\tt SM\_control\_reset\_connection} and {\tt |
|
| OX\_SYNC\_BALL} must initiate an engine into entering the resetting |
|
| state, and it makes the resetting scheme complicated and it may |
|
| introduce unexpected bugs. For example, if a client sends {\tt |
|
| OX\_SYNC\_BALL} without waiting {\tt OX\_SYNC\_BALL} from the engine, |
|
| then it is possible that the engine recieves it before the arrival of |
|
| the signal. We note that we really encountered serious bugs caused |
|
| by such an inappropriate protocol before reaching the final specicication. |
|
| |
|
| \subsection{Debugging} |
|
| An OpenXM server may allow definition and execution of functions |
|
| written in the user language proper to the server. To help debugging |
|
| such functions on the server, various supports are possible. If |
|
| servers are executed on X window system, then the control server can |
servers are executed on X window system, then the control server can |
| attach an {\tt xterm} to the standard outputs of the engine, which |
attach an {\tt xterm} to the standard outputs of the engine to display |
| makes it possible to display messages from the engine. Furthermore, if |
diagnostic messages from the engine. |
| the engine provides an inteface to input commands which directly |
Furthermore, if the engine provides an interface to input commands, |
| controls the engine, then debugging of user define programs will be |
then debugging of user defined programs will be |
| possible. For example {\tt Risa/Asir} provides a function {\tt |
possible. For example {\tt ox\_asir}, which is |
| debug()} to debug user defined functions. {\tt ox\_asir}, which is |
the OpenXM server of {\tt Risa/Asir}, can pop up a window to input |
| the OpenXM server of {\tt Risa/Asir}, pops up a window to input |
debug commands and the debugging similar to that on usual terminals is possible. |
| debug commands when {\tt debug()} is executed on the server. |
One can also send {\tt SIGINT} by using {\tt SM\_control\_to\_debug\_mode} |
| As the responses to the commands are displayed on the {\tt xterm}, |
and it provides a similar functionality to entering the debugging |
| the debugging similar to that on usual terminals is possible. |
|
| Moreover one can send {\tt SIGINT} by using {\tt SM\_control\_intr} |
|
| and it provides a similar functinality to entering the debugging |
|
| mode from a keyboard interruption. |
mode from a keyboard interruption. |
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