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[/] [or1k/] [tags/] [nog_patch_56/] [or1ksim/] [debug/] [gdbcomm.c] - Rev 1765
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/* gdbcomm.c -- Communication routines for gdb Copyright (C) 2001 by Marko Mlinar, markom@opencores.org Code copied from toplevel.c This file is part of OpenRISC 1000 Architectural Simulator. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include <stdlib.h> #include <stdio.h> #include <sys/stat.h> #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <sys/select.h> #include <sys/poll.h> #include <fcntl.h> #include <netdb.h> #include <netinet/tcp.h> #include <unistd.h> #include <string.h> #include "config.h" #ifdef HAVE_INTTYPES_H #include <inttypes.h> #endif #include "port.h" #include "arch.h" #include "gdb.h" #include "gdbcomm.h" #include "vapi.h" #include "sim-config.h" #include "debug_unit.h" static int gdb_read(void* buf,int len); static int gdb_write(const void* buf,int len); static unsigned int serverIP = 0; static unsigned int serverPort = 0; static unsigned int server_fd = 0; static unsigned int gdb_fd = 0; static int tcp_level = 0; /* Added by CZ 24/05/01 */ int GetServerSocket(const char* name,const char* proto,int port) { struct servent *service; struct protoent *protocol; struct sockaddr_in sa; struct hostent *hp; int sockfd; char myname[256]; int flags; char sTemp[256]; /* First, get the protocol number of TCP */ if(!(protocol = getprotobyname(proto))) { sprintf(sTemp,"Unable to load protocol \"%s\"",proto); perror(sTemp); return 0; } tcp_level = protocol->p_proto; /* Save for later */ /* If we weren't passed a non standard port, get the port from the services directory. */ if(!port) { if((service = getservbyname(name,protocol->p_name))) port = ntohs(service->s_port); } /* Create the socket using the TCP protocol */ if((sockfd = socket(PF_INET,SOCK_STREAM,protocol->p_proto)) < 0) { perror("Unable to create socket"); return 0; } flags = 1; if(setsockopt(sockfd,SOL_SOCKET,SO_REUSEADDR,(const char*)&flags,sizeof(int)) < 0) { sprintf(sTemp,"Can not set SO_REUSEADDR option on socket %d",sockfd); perror(sTemp); close(sockfd); return 0; } /* The server should also be non blocking. Get the current flags. */ if(fcntl(sockfd,F_GETFL,&flags) < 0) { sprintf(sTemp,"Unable to get flags for socket %d",sockfd); perror(sTemp); close(sockfd); return 0; } /* Set the nonblocking flag */ if(fcntl(sockfd,F_SETFL, flags | O_NONBLOCK) < 0) { sprintf(sTemp,"Unable to set flags for socket %d to value 0x%08x", sockfd,flags | O_NONBLOCK); perror(sTemp); close(sockfd); return 0; } /* Find out what our address is */ memset(&sa,0,sizeof(struct sockaddr_in)); gethostname(myname,sizeof(myname)); if(!(hp = gethostbyname(myname))) { perror("Unable to read hostname"); close(sockfd); return 0; } /* Bind our socket to the appropriate address */ sa.sin_family = hp->h_addrtype; sa.sin_port = htons(port); if(bind(sockfd,(struct sockaddr*)&sa,sizeof(struct sockaddr_in)) < 0) { sprintf(sTemp,"Unable to bind socket %d to port %d",sockfd,port); perror(sTemp); close(sockfd); return 0; } serverIP = sa.sin_addr.s_addr; flags = sizeof(struct sockaddr_in); if(getsockname(sockfd,(struct sockaddr*)&sa,&flags) < 0) { sprintf(sTemp,"Unable to get socket information for socket %d",sockfd); perror(sTemp); close(sockfd); return 0; } serverPort = ntohs(sa.sin_port); /* Set the backlog to 1 connections */ if(listen(sockfd,1) < 0) { sprintf(sTemp,"Unable to set backlog on socket %d to %d",sockfd,1); perror(sTemp); close(sockfd); return 0; } return sockfd; } void BlockJTAG() { struct pollfd fds[2]; int n = 0; fds[n].fd = server_fd; fds[n].events = POLLIN; fds[n++].revents = 0; if(gdb_fd) { fds[n].fd = gdb_fd; fds[n].events = POLLIN; fds[n++].revents = 0; } poll(fds,n,-1); } void HandleServerSocket(Boolean block) { struct pollfd fds[3]; int n = 0; int timeout = block ? -1 : 0; Boolean data_on_stdin = false; int o_serv_fd = server_fd; if(!o_serv_fd && !gdb_fd) return; if(o_serv_fd) { fds[n].fd = o_serv_fd; fds[n].events = POLLIN; fds[n++].revents = 0; } if(gdb_fd) { fds[n].fd = gdb_fd; fds[n].events = POLLIN; fds[n++].revents = 0; } if(block) { fds[n].fd = 0; fds[n].events = POLLIN; fds[n++].revents = 0; } while(!data_on_stdin) { switch(poll(fds,n,timeout)) { case -1: if(errno == EINTR) continue; perror("poll"); server_fd = 0; break; case 0: /* Nothing interesting going on */ data_on_stdin = true; /* Can only get here if nonblocking */ break; default: /* Make sure to handle the gdb port first! */ if((fds[0].revents && (gdb_fd && !o_serv_fd) || fds[1].revents && (server_fd && gdb_fd))) { int revents = o_serv_fd ? fds[1].revents : fds[0].revents; if(revents & POLLIN) GDBRequest(); else /* Error Occurred */ { fprintf(stderr,"Received flags 0x%08x on gdb socket. Shutting down.\n",revents); close(gdb_fd); gdb_fd = 0; } } if(fds[0].revents && o_serv_fd) { if(fds[0].revents & POLLIN) JTAGRequest(); else /* Error Occurred */ { fprintf(stderr,"Received flags 0x%08x on server. Shutting down.\n",fds[0].revents); close(o_serv_fd); server_fd = 0; serverPort = 0; serverIP = 0; } } if(fds[2].revents || (fds[1].revents && !gdb_fd)) data_on_stdin = true; break; } /* End of switch statement */ } /* End of while statement */ } void JTAGRequest() { struct sockaddr_in sa; struct sockaddr* addr = (struct sockaddr*)&sa; int n = sizeof(struct sockaddr_in); int fd = accept(server_fd,addr,&n); int on_off = 0; /* Turn off Nagel's algorithm on the socket */ int flags; char sTemp[256]; if(fd < 0) { /* This is valid, because a connection could have started, and then terminated due to a protocol error or user initiation before the accept could take place. */ if(errno != EWOULDBLOCK && errno != EAGAIN) { perror("accept"); close(server_fd); server_fd = 0; serverPort = 0; serverIP = 0; } return; } if(gdb_fd) { close(fd); return; } if(fcntl(fd,F_GETFL,&flags) < 0) { sprintf(sTemp,"Unable to get flags for gdb socket %d",fd); perror(sTemp); close(fd); return; } if(fcntl(fd,F_SETFL, flags | O_NONBLOCK) < 0) { sprintf(sTemp,"Unable to set flags for gdb socket %d to value 0x%08x", fd,flags | O_NONBLOCK); perror(sTemp); close(fd); return; } if(setsockopt(fd,tcp_level,TCP_NODELAY,&on_off,sizeof(int)) < 0) { sprintf(sTemp,"Unable to disable Nagel's algorithm for socket %d.\nsetsockopt",fd); perror(sTemp); close(fd); return; } gdb_fd = fd; } void GDBRequest() { JTAGProxyWriteMessage msg_write; JTAGProxyReadMessage msg_read; JTAGProxyChainMessage msg_chain; JTAGProxyWriteResponse resp_write; JTAGProxyReadResponse resp_read; JTAGProxyChainResponse resp_chain; JTAGProxyBlockWriteMessage *msg_bwrite; JTAGProxyBlockReadMessage msg_bread; JTAGProxyBlockWriteResponse resp_bwrite; JTAGProxyBlockReadResponse *resp_bread; char *buf; int err = 0; uint32_t command,length; int len,i; /* First, we must read the incomming command */ if(gdb_read(&command,sizeof(uint32_t)) < 0) { if(gdb_fd) { perror("gdb socket - 1"); close(gdb_fd); gdb_fd = 0; } return; } if(gdb_read(&length,sizeof(uint32_t)) < 0) { if(gdb_fd) { perror("gdb socket - 2"); close(gdb_fd); gdb_fd = 0; } return; } length = ntohl(length); /* Now, verify the protocol and implement the command */ switch(ntohl(command)) { case JTAG_COMMAND_WRITE: if(length != sizeof(msg_write) - 8) { ProtocolClean(length,JTAG_PROXY_PROTOCOL_ERROR); return; } buf = (char*)&msg_write; if(gdb_read(&buf[8],length) < 0) { if(gdb_fd) { perror("gdb socket - 3"); close(gdb_fd); gdb_fd = 0; } return; } msg_write.address = ntohl(msg_write.address); msg_write.data_H = ntohl(msg_write.data_H); msg_write.data_L = ntohl(msg_write.data_L); err = DebugSetRegister(msg_write.address,msg_write.data_L); resp_write.status = htonl(err); if(gdb_write(&resp_write,sizeof(resp_write)) < 0) { if(gdb_fd) { perror("gdb socket - 4"); close(gdb_fd); gdb_fd = 0; } return; } break; case JTAG_COMMAND_READ: if(length != sizeof(msg_read) - 8) { ProtocolClean(length,JTAG_PROXY_PROTOCOL_ERROR); return; } buf = (char*)&msg_read; if(gdb_read(&buf[8],length) < 0) { if(gdb_fd) { perror("gdb socket - 5"); close(gdb_fd); gdb_fd = 0; } return; } msg_read.address = ntohl(msg_read.address); err = DebugGetRegister(msg_read.address,&resp_read.data_L); resp_read.status = htonl(err); resp_read.data_H = 0; resp_read.data_L = htonl(resp_read.data_L); if(gdb_write(&resp_read,sizeof(resp_read)) < 0) { if(gdb_fd) { perror("gdb socket - 6"); close(gdb_fd); gdb_fd = 0; } return; } break; case JTAG_COMMAND_BLOCK_WRITE: if(length < sizeof(JTAGProxyBlockWriteMessage)-8) { ProtocolClean(length,JTAG_PROXY_PROTOCOL_ERROR); return; } if(!(buf = (char*)malloc(8+length))) { ProtocolClean(length,JTAG_PROXY_OUT_OF_MEMORY); return; } msg_bwrite = (JTAGProxyBlockWriteMessage*)buf; if(gdb_read(&buf[8],length) < 0) { if(gdb_fd) { perror("gdb socket - 5"); close(gdb_fd); gdb_fd = 0; } free(buf); return; } msg_bwrite->address = ntohl(msg_bwrite->address); msg_bwrite->nRegisters = ntohl(msg_bwrite->nRegisters); for(i=0;i<msg_bwrite->nRegisters;i++) { int t_err = 0; msg_bwrite->data[i] = ntohl(msg_bwrite->data[i]); t_err = DebugSetRegister(msg_bwrite->address + 4 * i,msg_bwrite->data[i]); err = err ? err : t_err; } resp_bwrite.status = htonl(err); free(buf); buf = NULL; msg_bwrite = NULL; if(gdb_write(&resp_bwrite,sizeof(resp_bwrite)) < 0) { if(gdb_fd) { perror("gdb socket - 4"); close(gdb_fd); gdb_fd = 0; } return; } break; case JTAG_COMMAND_BLOCK_READ: if(length != sizeof(msg_bread) - 8) { ProtocolClean(length,JTAG_PROXY_PROTOCOL_ERROR); return; } buf = (char*)&msg_bread; if(gdb_read(&buf[8],length) < 0) { if(gdb_fd) { perror("gdb socket - 5"); close(gdb_fd); gdb_fd = 0; } return; } msg_bread.address = ntohl(msg_bread.address); msg_bread.nRegisters = ntohl(msg_bread.nRegisters); len = sizeof(JTAGProxyBlockReadResponse) + 4*(msg_bread.nRegisters-1); if(!(buf = (char*)malloc(len))) { ProtocolClean(0,JTAG_PROXY_OUT_OF_MEMORY); return; } resp_bread = (JTAGProxyBlockReadResponse*)buf; for(i=0;i<msg_bread.nRegisters;i++) { int t_err; t_err = DebugGetRegister(msg_bread.address + 4 * i,&resp_bread->data[i]); resp_bread->data[i] = htonl(resp_bread->data[i]); err = err ? err : t_err; } resp_bread->status = htonl(err); resp_bread->nRegisters = htonl(msg_bread.nRegisters); if(gdb_write(resp_bread,len) < 0) { if(gdb_fd) { perror("gdb socket - 6"); close(gdb_fd); gdb_fd = 0; } free(buf); return; } free(buf); buf = NULL; resp_bread = NULL; break; case JTAG_COMMAND_CHAIN: if(length != sizeof(msg_chain) - 8) { ProtocolClean(length,JTAG_PROXY_PROTOCOL_ERROR); return; } buf = (char*)&msg_chain; if(gdb_read(&buf[8],sizeof(msg_chain)-8) < 0) { if(gdb_fd) { perror("gdb socket - 7"); close(gdb_fd); gdb_fd = 0; } return; } msg_chain.chain = htonl(msg_chain.chain); err = DebugSetChain(msg_chain.chain); resp_chain.status = htonl(err); if(gdb_write(&resp_chain,sizeof(resp_chain)) < 0) { if(gdb_fd) { perror("gdb socket - 8"); close(gdb_fd); gdb_fd = 0; } return; } break; default: ProtocolClean(length,JTAG_PROXY_COMMAND_NOT_IMPLEMENTED); break; } } void ProtocolClean(int length,int32_t err) { char buf[4096]; err = htonl(err); if((gdb_read(buf,length) < 0) || (gdb_write(&err,sizeof(err)) < 0) && gdb_fd) { perror("gdb socket - 9"); close(gdb_fd); gdb_fd = 0; } } static int gdb_write(const void* buf,int len) { int n, log_n = 0; const char* w_buf = (const char*)buf; const uint32_t* log_buf = (const uint32_t*)buf; struct pollfd block; while(len) { if((n = write(gdb_fd,w_buf,len)) < 0) { switch(errno) { case EWOULDBLOCK: /* or EAGAIN */ /* We've been called on a descriptor marked for nonblocking I/O. We better simulate blocking behavior. */ block.fd = gdb_fd; block.events = POLLOUT; block.revents = 0; poll(&block,1,-1); continue; case EINTR: continue; case EPIPE: close(gdb_fd); gdb_fd = 0; return -1; default: return -1; } } else { len -= n; w_buf += n; if ( config.debug.vapi_id ) for ( log_n += n; log_n >= 4; log_n -= 4, ++ log_buf ) vapi_write_log_file( VAPI_COMMAND_SEND, config.debug.vapi_id, ntohl(*log_buf) ); } } return 0; } static int gdb_read(void* buf,int len) { int n, log_n = 0; char* r_buf = (char*)buf; uint32_t* log_buf = (uint32_t*)buf; struct pollfd block; while(len) { if((n = read(gdb_fd,r_buf,len)) < 0) { switch(errno) { case EWOULDBLOCK: /* or EAGAIN */ /* We've been called on a descriptor marked for nonblocking I/O. We better simulate blocking behavior. */ block.fd = gdb_fd; block.events = POLLIN; block.revents = 0; poll(&block,1,-1); continue; case EINTR: continue; default: return -1; } } else if(n == 0) { close(gdb_fd); gdb_fd = 0; return -1; } else { len -= n; r_buf += n; if ( config.debug.vapi_id ) for ( log_n += n; log_n >= 4; log_n -= 4, ++ log_buf ) vapi_write_log_file( VAPI_COMMAND_REQUEST, config.debug.vapi_id, ntohl(*log_buf) ); } } return 0; } int gdbcomm_init () { serverPort = config.debug.server_port; if((server_fd = GetServerSocket("or1ksim","tcp",serverPort))) PRINTF("JTAG Proxy server started on port %d\n",serverPort); else PRINTF("Cannot start JTAG proxy server on port %d\n", serverPort); }