+++ /dev/null
-/* $Id$ */
-
-/* GridRPC - Fake Grid RPC thingy doing matrix multiplications (as expected)*/
-
-/* Copyright (c) 2005 Martin Quinson. All rights reserved. */
-
-/* This program is free software; you can redistribute it and/or modify it
- * under the terms of the license (GNU LGPL) which comes with this package. */
-
-#include "gras.h"
-
-#define MATSIZE 128
-
-XBT_LOG_NEW_DEFAULT_CATEGORY(MatMult,"Messages specific to this example");
-
-GRAS_DEFINE_TYPE(s_matrix,
-struct s_matrix {
- int rows;
- int cols;
- double *ctn GRAS_ANNOTE(size, rows*cols);
-};)
-typedef struct s_matrix matrix_t;
-
-static void mat_dump(matrix_t *mat, const char* name) {
- int i,j;
-
- printf(">>> Matrix %s dump (%d x %d)\n",name,mat->rows,mat->cols);
- for (i=0; i<mat->rows; i++) {
- printf(" ");
- for (j=0; j<mat->cols; j++)
- printf(" %.2f",mat->ctn[i*mat->cols + j]);
- printf("\n");
- }
- printf("<<< end of matrix %s dump\n",name);
-}
-
-/* register messages which may be sent and their payload
- (common to client and server) */
-static void register_messages(void) {
- gras_datadesc_type_t matrix_type, request_type;
-
- matrix_type=gras_datadesc_by_symbol(s_matrix);
- request_type=gras_datadesc_array_fixed("matrix_t[2]",matrix_type,2);
-
- gras_msgtype_declare("answer", matrix_type);
- gras_msgtype_declare("request", request_type);
-}
-
-/* Function prototypes */
-int server (int argc,char *argv[]);
-int client (int argc,char *argv[]);
-
-/* **********************************************************************
- * Server code
- * **********************************************************************/
-
-static int server_cb_request_handler(gras_msg_cb_ctx_t ctx, void *payload_data) {
- gras_socket_t expeditor=gras_msg_cb_ctx_from(ctx);
-
- /* 1. Get the payload into the data variable */
- matrix_t *data=(matrix_t*)payload_data;
- matrix_t result;
- int i,j,k;
-
- /* 2. Make some room to return the result */
- result.rows = data[0].rows;
- result.cols = data[1].cols;
- result.ctn = xbt_malloc0(sizeof(double) * result.rows * result.cols);
-
- /* 3. Do the computation */
- for (i=0; i<result.rows; i++)
- for (j=0; j<result.cols; j++)
- for (k=0; k<data[1].rows; k++)
- result.ctn[i*result.cols + j] += data[0].ctn[i*result.cols +k] *data[1].ctn[k*result.cols +j];
-
- /* 4. Send it back as payload of a pong message to the expeditor */
- gras_msg_send(expeditor, gras_msgtype_by_name("answer"), &result);
-
- /* 5. Cleanups */
- free(data[0].ctn);
- free(data[1].ctn);
- free(result.ctn);
- gras_socket_close(expeditor);
-
- return 1;
-} /* end_of_server_cb_request_handler */
-
-int server (int argc,char *argv[]) {
- xbt_ex_t e;
- gras_socket_t sock=NULL;
- int port = 4000;
-
- /* 1. Init the GRAS infrastructure */
- gras_init(&argc,argv);
-
- /* 2. Get the port I should listen on from the command line, if specified */
- if (argc == 2) {
- port=atoi(argv[1]);
- }
-
- /* 3. Create my master socket */
- INFO1("Launch server (port=%d)", port);
- TRY {
- sock = gras_socket_server(port);
- } CATCH(e) {
- RETHROW0("Unable to establish a server socket: %s");
- }
-
- /* 4. Register the known messages and payloads. */
- register_messages();
-
- /* 5. Register my callback */
- gras_cb_register(gras_msgtype_by_name("request"),&server_cb_request_handler);
-
- /* 6. Wait up to 10 minutes for an incomming message to handle */
- gras_msg_handle(600.0);
-
- /* 7. Free the allocated resources, and shut GRAS down */
- gras_socket_close(sock);
- gras_exit();
-
- INFO0("Done.");
- return 0;
-} /* end_of_server */
-
-/* **********************************************************************
- * Client code
- * **********************************************************************/
-
-/* Function prototypes */
-
-int client(int argc,char *argv[]) {
- xbt_ex_t e;
- gras_socket_t toserver=NULL; /* peer */
-
- gras_socket_t from;
- matrix_t request[2], answer;
-
- int i,j;
-
- const char *host = "127.0.0.1";
- int port = 4000;
-
- /* 1. Init the GRAS's infrastructure */
- gras_init(&argc, argv);
-
- /* 2. Get the server's address. The command line override defaults when specified */
- if (argc == 3) {
- host=argv[1];
- port=atoi(argv[2]);
- }
-
- INFO2("Launch client (server on %s:%d)",host,port);
-
- /* 3. Wait for the server startup */
- gras_os_sleep(1);
-
- /* 4. Create a socket to speak to the server */
- TRY {
- toserver=gras_socket_client(host,port);
- } CATCH(e) {
- RETHROW0("Unable to connect to the server: %s");
- }
- INFO2("Connected to %s:%d.",host,port);
-
-
- /* 5. Register the messages (before use) */
- register_messages();
-
- /* 6. Keep the user informed of what's going on */
- INFO2(">>>>>>>> Connected to server which is on %s:%d <<<<<<<<",
- gras_socket_peer_name(toserver),gras_socket_peer_port(toserver));
-
- /* 7. Prepare and send the request to the server */
-
- request[0].rows=request[0].cols=request[1].rows=request[1].cols=MATSIZE;
-
- request[0].ctn=xbt_malloc0(sizeof(double)*MATSIZE*MATSIZE);
- request[1].ctn=xbt_malloc0(sizeof(double)*MATSIZE*MATSIZE);
-
- for (i=0; i<MATSIZE; i++) {
- request[0].ctn[i*MATSIZE+i] = 1;
- for (j=0; j<MATSIZE; j++)
- request[1].ctn[i*MATSIZE+j] = i*MATSIZE+j;
- }
- /* mat_dump(&request[0],"C:sent0");*/
- /* mat_dump(&request[1],"C:sent1");*/
-
- gras_msg_send(toserver, gras_msgtype_by_name("request"), &request);
-
- free(request[0].ctn);
- free(request[1].ctn);
-
- INFO2(">>>>>>>> Request sent to %s:%d <<<<<<<<",
- gras_socket_peer_name(toserver),gras_socket_peer_port(toserver));
-
- /* 8. Wait for the answer from the server, and deal with issues */
- gras_msg_wait(6000,gras_msgtype_by_name("answer"),&from,&answer);
-
- /* mat_dump(&answer,"C:answer");*/
- for (i=0; i<MATSIZE*MATSIZE; i++)
- xbt_assert(answer.ctn[i]==i);
-
- /* 9. Keep the user informed of what's going on, again */
- INFO2(">>>>>>>> Got answer from %s:%d <<<<<<<<",
- gras_socket_peer_name(from),gras_socket_peer_port(from));
-
- /* 10. Free the allocated resources, and shut GRAS down */
- free(answer.ctn);
- gras_socket_close(toserver);
- gras_exit();
- INFO0("Done.");
- return 0;
-} /* end_of_client */
