/* Memory-access and commands for remote NINDY process, for GDB. Copyright (C) 1990-1991 Free Software Foundation, Inc. Contributed by Intel Corporation. Modified from remote.c by Chris Benenati. GDB is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY. No author or distributor accepts responsibility to anyone for the consequences of using it or for whether it serves any particular purpose or works at all, unless he says so in writing. Refer to the GDB General Public License for full details. Everyone is granted permission to copy, modify and redistribute GDB, but only under the conditions described in the GDB General Public License. A copy of this license is supposed to have been given to you along with GDB so you can know your rights and responsibilities. It should be in a file named COPYING. Among other things, the copyright notice and this notice must be preserved on all copies. In other words, go ahead and share GDB, but don't try to stop anyone else from sharing it farther. Help stamp out software hoarding! */ /* Except for the data cache routines, this file bears little resemblence to remote.c. A new (although similar) protocol has been specified, and portions of the code are entirely dependent on having an i80960 with a NINDY ROM monitor at the other end of the line. */ /***************************************************************************** * * REMOTE COMMUNICATION PROTOCOL BETWEEN GDB960 AND THE NINDY ROM MONITOR. * * * MODES OF OPERATION * ----- -- --------- * * As far as NINDY is concerned, GDB is always in one of two modes: command * mode or passthrough mode. * * In command mode (the default) pre-defined packets containing requests * are sent by GDB to NINDY. NINDY never talks except in reponse to a request. * * Once the the user program is started, GDB enters passthrough mode, to give * the user program access to the terminal. GDB remains in this mode until * NINDY indicates that the program has stopped. * * * PASSTHROUGH MODE * ----------- ---- * * GDB writes all input received from the keyboard directly to NINDY, and writes * all characters received from NINDY directly to the monitor. * * Keyboard input is neither buffered nor echoed to the monitor. * * GDB remains in passthrough mode until NINDY sends a single ^P character, * to indicate that the user process has stopped. * * Note: * GDB assumes NINDY performs a 'flushreg' when the user program stops. * * * COMMAND MODE * ------- ---- * * All info (except for message ack and nak) is transferred between gdb * and the remote processor in messages of the following format: * * # * * where * # is a literal character * * ASCII information; all numeric information is in the * form of hex digits ('0'-'9' and lowercase 'a'-'f'). * * * is a pair of ASCII hex digits representing an 8-bit * checksum formed by adding together each of the * characters in . * * The receiver of a message always sends a single character to the sender * to indicate that the checksum was good ('+') or bad ('-'); the sender * re-transmits the entire message over until a '+' is received. * * In response to a command NINDY always sends back either data or * a result code of the form "Xnn", where "nn" are hex digits and "X00" * means no errors. (Exceptions: the "s" and "c" commands don't respond.) * * SEE THE HEADER OF THE FILE "gdb.c" IN THE NINDY MONITOR SOURCE CODE FOR A * FULL DESCRIPTION OF LEGAL COMMANDS. * * SEE THE FILE "stop.h" IN THE NINDY MONITOR SOURCE CODE FOR A LIST * OF STOP CODES. * ******************************************************************************/ #include #include #include #include #include "defs.h" #include "param.h" #include "frame.h" #include "inferior.h" #include "target.h" #include "gdbcore.h" #include "command.h" #include "bfd.h" #include "ieee-float.h" #include "wait.h" #include #include #include #include "nindy-share/ttycntl.h" #include "nindy-share/demux.h" #include "nindy-share/env.h" #include "nindy-share/stop.h" extern int unlink(); extern char *getenv(); extern char *mktemp(); extern char *coffstrip(); extern value call_function_by_hand (); extern void generic_mourn_inferior (); extern struct target_ops nindy_ops; extern jmp_buf to_top_level; extern FILE *instream; extern struct ext_format ext_format_i960; /* i960-tdep.c */ extern char ninStopWhy (); int nindy_initial_brk; /* nonzero if want to send an initial BREAK to nindy */ int nindy_old_protocol; /* nonzero if want to use old protocol */ char *nindy_ttyname; /* name of tty to talk to nindy on, or null */ #define DLE '\020' /* Character NINDY sends to indicate user program has * halted. */ #define TRUE 1 #define FALSE 0 int nindy_fd = 0; /* Descriptor for I/O to NINDY */ static int have_regs = 0; /* 1 iff regs read since i960 last halted */ static int regs_changed = 0; /* 1 iff regs were modified since last read */ extern char *exists(); static void dcache_flush (), dcache_poke (), dcache_init(); static int dcache_fetch (); /* FIXME, we can probably use the normal terminal_inferior stuff here. We have to do terminal_inferior and then set up the passthrough settings initially. Thereafter, terminal_ours and terminal_inferior will automatically swap the settings around for us. */ /* Restore TTY to normal operation */ static TTY_STRUCT orig_tty; /* TTY attributes before entering passthrough */ static void restore_tty() { ioctl( 0, TIOCSETN, &orig_tty ); } /* Recover from ^Z or ^C while remote process is running */ static void (*old_ctrlc)(); /* Signal handlers before entering passthrough */ #ifdef SIGTSTP static void (*old_ctrlz)(); #endif static #ifdef USG void #endif cleanup() { restore_tty(); signal(SIGINT, old_ctrlc); #ifdef SIGTSTP signal(SIGTSTP, old_ctrlz); #endif error("\n\nYou may need to reset the 80960 and/or reload your program.\n"); } /* Clean up anything that needs cleaning when losing control. */ static char *savename; static void nindy_close (quitting) int quitting; { if (nindy_fd) close (nindy_fd); nindy_fd = 0; if (savename) free (savename); savename = 0; } /* Open a connection to a remote debugger. FIXME, there should be a way to specify the various options that are now specified with gdb command-line options. (baud_rate, old_protocol, and initial_brk) */ void nindy_open (name, from_tty) char *name; /* "/dev/ttyXX", "ttyXX", or "XX": tty to be opened */ int from_tty; { if (!name) error_no_arg ("serial port device name"); target_preopen (from_tty); nindy_close (0); have_regs = regs_changed = 0; dcache_init(); /* Allow user to interrupt the following -- we could hang if * there's no NINDY at the other end of the remote tty. */ immediate_quit++; nindy_fd = ninConnect( name, baud_rate? baud_rate: "9600", nindy_initial_brk, !from_tty, nindy_old_protocol ); immediate_quit--; if ( nindy_fd < 0 ){ nindy_fd = 0; error( "Can't open tty '%s'", name ); } savename = savestring (name, strlen (name)); push_target (&nindy_ops); target_fetch_registers(-1); } /* User-initiated quit of nindy operations. */ static void nindy_detach (name, from_tty) char *name; int from_tty; { if (name) error ("Too many arguments"); pop_target (); } static void nindy_files_info () { printf("\tAttached to %s at %s bps%s%s.\n", savename, baud_rate? baud_rate: "9600", nindy_old_protocol? " in old protocol": "", nindy_initial_brk? " with initial break": ""); } /****************************************************************************** * remote_load: * Download an object file to the remote system by invoking the "comm960" * utility. We look for "comm960" in $G960BIN, $G960BASE/bin, and * DEFAULT_BASE/bin/HOST/bin where * DEFAULT_BASE is defined in env.h, and * HOST must be defined on the compiler invocation line. ******************************************************************************/ static void nindy_load( filename, from_tty ) char *filename; int from_tty; { char *tmpfile; struct cleanup *old_chain; char *scratch_pathname; int scratch_chan; if (!filename) filename = get_exec_file (1); filename = tilde_expand (filename); make_cleanup (free, filename); scratch_chan = openp (getenv ("PATH"), 1, filename, O_RDONLY, 0, &scratch_pathname); if (scratch_chan < 0) perror_with_name (filename); close (scratch_chan); /* Slightly wasteful FIXME */ have_regs = regs_changed = 0; mark_breakpoints_out(); inferior_pid = 0; dcache_flush(); tmpfile = coffstrip(scratch_pathname); if ( tmpfile ){ old_chain = make_cleanup(unlink,tmpfile); immediate_quit++; ninDownload( tmpfile, !from_tty ); /* FIXME, don't we want this merged in here? */ immediate_quit--; do_cleanups (old_chain); } } /* Return the number of characters in the buffer before the first DLE character. */ static int non_dle( buf, n ) char *buf; /* Character buffer; NOT '\0'-terminated */ int n; /* Number of characters in buffer */ { int i; for ( i = 0; i < n; i++ ){ if ( buf[i] == DLE ){ break; } } return i; } /* Tell the remote machine to resume. */ void nindy_resume (step, siggnal) int step, siggnal; { if (siggnal != 0 && siggnal != stop_signal) error ("Can't send signals to remote NINDY targets."); dcache_flush(); if ( regs_changed ){ nindy_store_registers (); regs_changed = 0; } have_regs = 0; ninGo( step ); } /* Wait until the remote machine stops. While waiting, operate in passthrough * mode; i.e., pass everything NINDY sends to stdout, and everything from * stdin to NINDY. * * Return to caller, storing status in 'status' just as `wait' would. */ void nindy_wait( status ) WAITTYPE *status; { DEMUX_DECL; /* OS-dependent data needed by DEMUX... macros */ char buf[500]; /* FIXME, what is "500" here? */ int i, n; unsigned char stop_exit; unsigned char stop_code; TTY_STRUCT tty; long ip_value, fp_value, sp_value; /* Reg values from stop */ WSETEXIT( (*status), 0 ); /* OPERATE IN PASSTHROUGH MODE UNTIL NINDY SENDS A DLE CHARACTER */ /* Save current tty attributes, set up signals to restore them. */ ioctl( 0, TIOCGETP, &orig_tty ); old_ctrlc = signal( SIGINT, cleanup ); #ifdef SIGTSTP old_ctrlz = signal( SIGTSTP, cleanup ); #endif /* Pass input from keyboard to NINDY as it arrives. * NINDY will interpret and perform echo. */ tty = orig_tty; TTY_NINDYTERM( tty ); ioctl( 0, TIOCSETN, &tty ); while ( 1 ){ /* Go to sleep until there's something for us on either * the remote port or stdin. */ DEMUX_WAIT( nindy_fd ); /* Pass input through to correct place */ n = DEMUX_READ( 0, buf, sizeof(buf) ); if ( n ){ /* Input on stdin */ write( nindy_fd, buf, n ); } n = DEMUX_READ( nindy_fd, buf, sizeof(buf) ); if ( n ){ /* Input on remote */ /* Write out any characters in buffer preceding DLE */ i = non_dle( buf, n ); if ( i > 0 ){ write( 1, buf, i ); } if ( i != n ){ /* There *was* a DLE in the buffer */ stop_exit = ninStopWhy( &stop_code, &ip_value, &fp_value, &sp_value); if ( !stop_exit && (stop_code==STOP_SRQ) ){ immediate_quit++; ninSrq(); immediate_quit--; } else { /* Get out of loop */ supply_register (IP_REGNUM, &ip_value); supply_register (FP_REGNUM, &fp_value); supply_register (SP_REGNUM, &sp_value); break; } } } } signal( SIGINT, old_ctrlc ); #ifdef SIGTSTP signal( SIGTSTP, old_ctrlz ); #endif restore_tty(); if ( stop_exit ){ /* User program exited */ WSETEXIT( (*status), stop_code ); } else { /* Fault or trace */ switch (stop_code){ case STOP_GDB_BPT: case TRACE_STEP: /* Make it look like a VAX trace trap */ stop_code = SIGTRAP; break; default: /* The target is not running Unix, and its faults/traces do not map nicely into Unix signals. Make sure they do not get confused with Unix signals by numbering them with values higher than the highest legal Unix signal. code in i960_print_fault(), called via PRINT_RANDOM_SIGNAL, will interpret the value. */ stop_code += NSIG; break; } WSETSTOP( (*status), stop_code ); } } /* Read the remote registers into the block REGS. */ /* This is the block that ninRegsGet and ninRegsPut handles. */ struct nindy_regs { char local_regs[16 * 4]; char global_regs[16 * 4]; char pcw_acw[2 * 4]; char ip[4]; char tcw[4]; char fp_as_double[4 * 8]; }; static int nindy_fetch_registers(regno) int regno; { struct nindy_regs nindy_regs; int regnum, inv; double dub; immediate_quit++; ninRegsGet( (char *) &nindy_regs ); immediate_quit--; bcopy (nindy_regs.local_regs, ®isters[REGISTER_BYTE (R0_REGNUM)], 16*4); bcopy (nindy_regs.global_regs, ®isters[REGISTER_BYTE (G0_REGNUM)], 16*4); bcopy (nindy_regs.pcw_acw, ®isters[REGISTER_BYTE (PCW_REGNUM)], 2*4); bcopy (nindy_regs.ip, ®isters[REGISTER_BYTE (IP_REGNUM)], 1*4); bcopy (nindy_regs.tcw, ®isters[REGISTER_BYTE (TCW_REGNUM)], 1*4); for (regnum = FP0_REGNUM; regnum < FP0_REGNUM + 4; regnum++) { dub = unpack_double (builtin_type_double, &nindy_regs.fp_as_double[8 * (regnum - FP0_REGNUM)], &inv); /* dub now in host byte order */ double_to_ieee_extended (&ext_format_i960, &dub, ®isters[REGISTER_BYTE (regnum)]); } registers_fetched (); return 0; } static void nindy_prepare_to_store() { nindy_fetch_registers(-1); } static int nindy_store_registers(regno) int regno; { struct nindy_regs nindy_regs; int regnum, inv; double dub; bcopy (®isters[REGISTER_BYTE (R0_REGNUM)], nindy_regs.local_regs, 16*4); bcopy (®isters[REGISTER_BYTE (G0_REGNUM)], nindy_regs.global_regs, 16*4); bcopy (®isters[REGISTER_BYTE (PCW_REGNUM)], nindy_regs.pcw_acw, 2*4); bcopy (®isters[REGISTER_BYTE (IP_REGNUM)], nindy_regs.ip, 1*4); bcopy (®isters[REGISTER_BYTE (TCW_REGNUM)], nindy_regs.tcw, 1*4); /* Float regs. Only works on IEEE_FLOAT hosts. */ for (regnum = FP0_REGNUM; regnum < FP0_REGNUM + 4; regnum++) { ieee_extended_to_double (&ext_format_i960, ®isters[REGISTER_BYTE (regnum)], &dub); /* dub now in host byte order */ /* FIXME-someday, the arguments to unpack_double are backward. It expects a target double and returns a host; we pass the opposite. This mostly works but not quite. */ dub = unpack_double (builtin_type_double, &dub, &inv); /* dub now in target byte order */ bcopy ((char *)&dub, &nindy_regs.fp_as_double[8 * (regnum - FP0_REGNUM)], 8); } immediate_quit++; ninRegsPut( (char *) &nindy_regs ); immediate_quit--; return 0; } /* Read a word from remote address ADDR and return it. * This goes through the data cache. */ int nindy_fetch_word (addr) CORE_ADDR addr; { return dcache_fetch (addr); } /* Write a word WORD into remote address ADDR. This goes through the data cache. */ void nindy_store_word (addr, word) CORE_ADDR addr; int word; { dcache_poke (addr, word); } /* Copy LEN bytes to or from inferior's memory starting at MEMADDR to debugger memory starting at MYADDR. Copy to inferior if WRITE is nonzero. Returns the length copied. This is stolen almost directly from infptrace.c's child_xfer_memory, which also deals with a word-oriented memory interface. Sometime, FIXME, rewrite this to not use the word-oriented routines. */ int nindy_xfer_inferior_memory(memaddr, myaddr, len, write, target) CORE_ADDR memaddr; char *myaddr; int len; int write; struct target_ops *target; /* ignored */ { register int i; /* Round starting address down to longword boundary. */ register CORE_ADDR addr = memaddr & - sizeof (int); /* Round ending address up; get number of longwords that makes. */ register int count = (((memaddr + len) - addr) + sizeof (int) - 1) / sizeof (int); /* Allocate buffer of that many longwords. */ register int *buffer = (int *) alloca (count * sizeof (int)); if (write) { /* Fill start and end extra bytes of buffer with existing memory data. */ if (addr != memaddr || len < (int)sizeof (int)) { /* Need part of initial word -- fetch it. */ buffer[0] = nindy_fetch_word (addr); } if (count > 1) /* FIXME, avoid if even boundary */ { buffer[count - 1] = nindy_fetch_word (addr + (count - 1) * sizeof (int)); } /* Copy data to be written over corresponding part of buffer */ bcopy (myaddr, (char *) buffer + (memaddr & (sizeof (int) - 1)), len); /* Write the entire buffer. */ for (i = 0; i < count; i++, addr += sizeof (int)) { errno = 0; nindy_store_word (addr, buffer[i]); if (errno) return 0; } } else { /* Read all the longwords */ for (i = 0; i < count; i++, addr += sizeof (int)) { errno = 0; buffer[i] = nindy_fetch_word (addr); if (errno) return 0; QUIT; } /* Copy appropriate bytes out of the buffer. */ bcopy ((char *) buffer + (memaddr & (sizeof (int) - 1)), myaddr, len); } return len; } /* The data cache records all the data read from the remote machine since the last time it stopped. Each cache block holds 16 bytes of data starting at a multiple-of-16 address. */ #define DCACHE_SIZE 64 /* Number of cache blocks */ struct dcache_block { struct dcache_block *next, *last; unsigned int addr; /* Address for which data is recorded. */ int data[4]; }; struct dcache_block dcache_free, dcache_valid; /* Free all the data cache blocks, thus discarding all cached data. */ static void dcache_flush () { register struct dcache_block *db; while ((db = dcache_valid.next) != &dcache_valid) { remque (db); insque (db, &dcache_free); } } /* * If addr is present in the dcache, return the address of the block * containing it. */ static struct dcache_block * dcache_hit (addr) unsigned int addr; { register struct dcache_block *db; if (addr & 3) abort (); /* Search all cache blocks for one that is at this address. */ db = dcache_valid.next; while (db != &dcache_valid) { if ((addr & 0xfffffff0) == db->addr) return db; db = db->next; } return NULL; } /* Return the int data at address ADDR in dcache block DC. */ static int dcache_value (db, addr) struct dcache_block *db; unsigned int addr; { if (addr & 3) abort (); return (db->data[(addr>>2)&3]); } /* Get a free cache block, put or keep it on the valid list, and return its address. The caller should store into the block the address and data that it describes, then remque it from the free list and insert it into the valid list. This procedure prevents errors from creeping in if a ninMemGet is interrupted (which used to put garbage blocks in the valid list...). */ static struct dcache_block * dcache_alloc () { register struct dcache_block *db; if ((db = dcache_free.next) == &dcache_free) { /* If we can't get one from the free list, take last valid and put it on the free list. */ db = dcache_valid.last; remque (db); insque (db, &dcache_free); } remque (db); insque (db, &dcache_valid); return (db); } /* Return the contents of the word at address ADDR in the remote machine, using the data cache. */ static int dcache_fetch (addr) CORE_ADDR addr; { register struct dcache_block *db; db = dcache_hit (addr); if (db == 0) { db = dcache_alloc (); immediate_quit++; ninMemGet(addr & ~0xf, (unsigned char *)db->data, 16); immediate_quit--; db->addr = addr & ~0xf; remque (db); /* Off the free list */ insque (db, &dcache_valid); /* On the valid list */ } return (dcache_value (db, addr)); } /* Write the word at ADDR both in the data cache and in the remote machine. */ static void dcache_poke (addr, data) CORE_ADDR addr; int data; { register struct dcache_block *db; /* First make sure the word is IN the cache. DB is its cache block. */ db = dcache_hit (addr); if (db == 0) { db = dcache_alloc (); immediate_quit++; ninMemGet(addr & ~0xf, (unsigned char *)db->data, 16); immediate_quit--; db->addr = addr & ~0xf; remque (db); /* Off the free list */ insque (db, &dcache_valid); /* On the valid list */ } /* Modify the word in the cache. */ db->data[(addr>>2)&3] = data; /* Send the changed word. */ immediate_quit++; ninMemPut(addr, (unsigned char *)&data, 4); immediate_quit--; } /* The cache itself. */ struct dcache_block the_cache[DCACHE_SIZE]; /* Initialize the data cache. */ static void dcache_init () { register i; register struct dcache_block *db; db = the_cache; dcache_free.next = dcache_free.last = &dcache_free; dcache_valid.next = dcache_valid.last = &dcache_valid; for (i=0;i