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/* Remote debugging interface for various or1k debugging protocols. Currently supported or1k targets are: simulator, jtag, dummy. Copyright 1993-1995, 2000 Free Software Foundation, Inc. Contributed by Cygnus Support. Written by Marko Mlinar <markom@opencores.org> This file is part of GDB. 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include "defs.h" #include "inferior.h" #include "bfd.h" #include "symfile.h" #include "gdb_wait.h" #include "gdbcmd.h" #include "gdbcore.h" #include "target.h" #include "remote-utils.h" #include "gdb_string.h" #include "tm.h" #include <signal.h> #include <sys/types.h> #include <sys/stat.h> #include <sys/ioctl.h> #include <fcntl.h> #define debug if (remote_debug) printf_unfiltered /* The following prototype is necessary or the compiler will not correctly promote the data argument to ULONGEST */ static void or1k_write_reg (unsigned int, ULONGEST); static int insn_modifies_gprs (unsigned int insn); /* JTAG or1k target ops. */ extern void jtag_init PARAMS ((char * args)); extern ULONGEST jtag_read_reg PARAMS ((unsigned int regno)); extern void jtag_write_reg PARAMS ((unsigned int regno, ULONGEST data)); extern void jtag_done PARAMS ((void)); extern int jtag_read_block PARAMS ((unsigned int regno, void* block, int nRegisters)); extern int jtag_write_block PARAMS ((unsigned int regno, void* block, int nRegisters)); extern void jtag_set_chain PARAMS ((int chain)); struct target_ops or1k_jtag_ops; static struct or1k_target_ops or1k_target_jtag = { "jtag", jtag_init, jtag_done, jtag_read_reg, jtag_write_reg, jtag_read_block, jtag_write_block, jtag_set_chain, NULL, &or1k_jtag_ops, OPS_MAGIC }; /* simulator or1k target ops. */ struct target_ops or1k_sim_ops; static struct or1k_target_ops or1k_target_sim = { "simulator", NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, &or1k_sim_ops, OPS_MAGIC }; /* dummy or1k target ops. */ struct target_ops or1k_dummy_ops; static struct or1k_target_ops or1k_target_dummy = { "dummy", NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, &or1k_dummy_ops, OPS_MAGIC }; const char *str_err[] = { "None", "CRC error" }; const char *status_name[] = { "UNDEFINED", "CONNECTING", "DISCONNECTING", "RUNNING", "STOPPED" }; /* Names for matchpoint related stuff. */ static char *ct_names[] = { "DIS", "IFEA", "LEA", "SEA", "AEA", "LDATA", "SDATA", "ADATA" }; static char *cc_names[] = { "&", "==", "<", "<=", ">", ">=", "!=", "ERR" }; static char *ch_names[] = { "ERR", "&", "|", "ERR" }; /* Implementation specific information. Set by or1k_initialize. */ struct struct_or1k_implementation or1k_implementation; /* Current target status. */ static enum target_status or1k_status = TARGET_UNDEFINED; /* The target vector. */ struct target_ops or1k_dummy_ops, or1k_jtag_ops, or1k_sim_ops; /* Currently active target description (if or1k_is_open == 1) */ static struct target_ops *current_ops; /* Currently active or1k target operations. */ static struct or1k_target_ops *current_or1k_target = NULL; /* Set to 1 if the target is open. */ static int or1k_is_open = 0; /* Error last occured, zero = ok. */ int err = 0; /* Nonzero, if we changed something (except DMR1 which is updated on every run anyway). */ int debug_regs_changed; /* Number of interrupts while waiting for process. */ static int interrupt_count = 0; /* Reason of last stop. */ static int hit_watchpoint = 0; static int hit_breakpoint = 0; static int step_link_insn = 0; static int new_pc_set = 0; /* Current register values. */ unsigned int dmr1 = 0; unsigned int dmr2 = 0; unsigned int dsr = 0; unsigned int drr = 0; unsigned int lr = 0; /* Current matchpoints. */ unsigned int dvr[MAX_MATCHPOINTS]; struct dcr_struct dcr[MAX_MATCHPOINTS]; /* Number of matchpoint users */ int matchpoint_user_count[MAX_MATCHPOINTS] = {0}; /* Old SIGINT handler. */ static void (*ofunc) PARAMS ((int)); /* Handle low-level error that we can't recover from. Note that just error()ing out from target_wait or some such low-level place will cause all hell to break loose--the rest of GDB will tend to get left in an inconsistent state. */ static NORETURN void or1k_error (char *string,...) { va_list args; va_start (args, string); target_terminal_ours (); wrap_here (""); /* Force out any buffered output */ gdb_flush (gdb_stdout); if (error_pre_print) fprintf_filtered (gdb_stderr, error_pre_print); vfprintf_filtered (gdb_stderr, string, args); fprintf_filtered (gdb_stderr, "\n"); va_end (args); gdb_flush (gdb_stderr); /* Clean up in such a way that or1k_close won't try to talk to the board (it almost surely won't work since we weren't able to talk to it). */ or1k_is_open = 0; printf_unfiltered ("Ending remote or1k debugging.\n"); target_mourn_inferior (); return_to_top_level (RETURN_ERROR); } const char * or1k_err_name (e) int e; { return str_err[e]; } /* putc_readable - print a character, displaying non-printable chars in ^x notation or in hex. */ static void fputc_readable (ch, file) int ch; struct ui_file *file; { if (ch == '\n') fputc_unfiltered ('\n', file); else if (ch == '\r') fprintf_unfiltered (file, "\\r"); else if (ch < 0x20) /* ASCII control character */ fprintf_unfiltered (file, "^%c", ch + '@'); else if (ch >= 0x7f) /* non-ASCII characters (rubout or greater) */ fprintf_unfiltered (file, "[%02x]", ch & 0xff); else fputc_unfiltered (ch, file); } /* puts_readable - print a string, displaying non-printable chars in ^x notation or in hex. */ static void fputs_readable (string, file) char *string; struct ui_file *file; { int c; while ((c = *string++) != '\0') fputc_readable (c, file); } /* Sets scan chain. */ static void or1k_set_chain (chain) int chain; { if (current_or1k_target != NULL && current_or1k_target->to_set_chain != NULL) current_or1k_target->to_set_chain (chain); } /* Sets register/memory regno to data. */ static void or1k_write_reg (regno, data) unsigned int regno; ULONGEST data; { if (current_or1k_target != NULL && current_or1k_target->to_write_reg != NULL) current_or1k_target->to_write_reg (regno, data); } /* Reads register/memory from regno. */ static ULONGEST or1k_read_reg (regno) unsigned int regno; { if (current_or1k_target != NULL && current_or1k_target->to_read_reg != NULL) return current_or1k_target->to_read_reg (regno); else return 0x1234; } /* Sets SPR register regno to data. */ void or1k_write_spr_reg (regno, data) unsigned int regno; unsigned int data; { or1k_set_chain (SC_RISC_DEBUG); or1k_write_reg (regno, (ULONGEST)data); if (regno == PC_SPRNUM) { hit_breakpoint = 0; step_link_insn = 0; new_pc_set = 1; } } /* Reads register SPR from regno. */ unsigned int or1k_read_spr_reg (regno) unsigned int regno; { or1k_set_chain (SC_RISC_DEBUG); return or1k_read_reg (regno); } /* Sets mem to data. */ void or1k_write_mem (addr, data) unsigned int addr; unsigned int data; { or1k_set_chain (SC_WISHBONE); or1k_write_reg (addr, (ULONGEST)data); } /* Reads register SPR from regno. */ unsigned int or1k_read_mem (addr) unsigned int addr; { or1k_set_chain (SC_WISHBONE); return or1k_read_reg (addr); } /* Stalls the CPU. */ static void or1k_stall () { int val; or1k_set_chain (SC_REGISTER); val = or1k_read_reg (JTAG_RISCOP); or1k_write_reg (JTAG_RISCOP, val | 1); or1k_read_reg (JTAG_RISCOP); /* Be cautious - disable trace. */ val = or1k_read_reg (JTAG_MODER); or1k_write_reg (JTAG_MODER, val & ~2); } /* Unstalls the CPU. */ static void or1k_unstall () { unsigned int val; or1k_set_chain (SC_REGISTER); val = or1k_read_reg (JTAG_RISCOP); or1k_write_reg (JTAG_RISCOP, val & ~1); or1k_read_reg (JTAG_RISCOP); } /* Resets the CPU and stalls it. */ static void or1k_reset () { unsigned int val; int i; debug ("%08x\n", or1k_read_reg (JTAG_RISCOP)); or1k_set_chain (SC_REGISTER); /* Be cautious - disable trace. */ val = or1k_read_reg (JTAG_MODER); or1k_write_reg (JTAG_MODER, val & ~2); val = or1k_read_reg (JTAG_RISCOP); val &= ~3; /* Assert reset signal. */ or1k_write_reg (JTAG_RISCOP, val | 3); /* Just do something */ for (i = 0; i < 100; i++) or1k_read_reg (JTAG_RISCOP); /* give it some time */ usleep (1000); or1k_set_chain (SC_REGISTER); /* Release reset signal, but keep in stall state. */ or1k_write_reg (JTAG_RISCOP, val | 1); or1k_read_reg (JTAG_RISCOP); } /* Synchronizes debug registers in memory with those on target, if there is any change. */ static void or1k_commit_debug_registers () { int i; unsigned int u; if (!debug_regs_changed) return; /* Matchpoints (breakpoints, watchpoints). */ for (i = 0; i < NUM_MATCHPOINTS; i++) { unsigned int u; or1k_write_spr_reg (DVR0_SPRNUM + i, dvr[i]); memcpy (&u, &dcr[i], sizeof(dcr[i])); or1k_write_spr_reg (DCR0_SPRNUM + i, u); } or1k_write_spr_reg (DMR1_SPRNUM, dmr1); or1k_write_spr_reg (DMR2_SPRNUM, dmr2); /* Trace dependent. */ or1k_set_chain (SC_REGISTER); memcpy (&u, &or1k_htrace.trig, sizeof(or1k_htrace.trig)); or1k_write_reg (JTAG_TSEL, u); memcpy (&u, &or1k_htrace.qual, sizeof(or1k_htrace.qual)); or1k_write_reg (JTAG_QSEL, u); memcpy (&u, &or1k_htrace.stop, sizeof(or1k_htrace.stop)); or1k_write_reg (JTAG_SSEL, u); debug_regs_changed = 0; for (i = 0; i < NUM_RECORDS; i++) { memcpy (&u, &or1k_htrace.recwp[i], sizeof(or1k_htrace.recwp[i])); or1k_write_reg (JTAG_RECWP0 + i, u); } memcpy (&u, &or1k_htrace.recbp, sizeof(or1k_htrace.recbp)); or1k_write_reg (JTAG_RECBP0, u); memcpy (&u, &or1k_htrace.moder, sizeof(or1k_htrace.moder)); or1k_write_reg (JTAG_MODER, u); } static void or1k_set_undefined_cleanups (arg) PTR arg; { or1k_status = TARGET_UNDEFINED; } /* Initialize a new connection to the or1k board, and make sure we are really connected. */ static void or1k_init (args) char *args; { struct cleanup *old_cleanups = make_cleanup (or1k_set_undefined_cleanups, NULL); int i; unsigned int tmp; FILE *f; /* What is this code doing here? I don't see any way it can happen, and it might mean or1k_initializing didn't get cleared properly. So I'll make it a warning. */ if (or1k_status == TARGET_CONNECTING) { warning ("internal error: or1k_initialize called twice"); return; } or1k_status = TARGET_CONNECTING; if (current_or1k_target != NULL && current_or1k_target->to_init != NULL) current_or1k_target->to_init (args); debug("%08x\n", read_pc ()); or1k_stall (); debug("%08x\n", read_pc ()); usleep (1000); /* Determine implementation configuration. */ or1k_implementation.VR = or1k_read_spr_reg (VR_SPRNUM); or1k_implementation.UPR = or1k_read_spr_reg (UPR_SPRNUM); /* Determine number of gpr_regs. */ tmp = or1k_read_spr_reg (CPUCFGR_SPRNUM); or1k_implementation.num_gpr_regs = ((tmp >> 4) & 1)?(16):(32); /* Is any vector or floating point support present? */ or1k_implementation.vf_present = ((tmp >> 7) & 7) != 0; or1k_implementation.num_vfpr_regs = (or1k_implementation.vf_present)?(32):(0); /* Determine max number of supported matchpoints. */ tmp = or1k_read_spr_reg (DCFGR_SPRNUM); or1k_implementation.num_matchpoints = tmp & 7; or1k_implementation.num_used_matchpoints = 0; or1k_implementation.has_counters = tmp & 4 == 1; /* Is implementation supported? */ /* First we should have system and debug groups implemented. */ if (or1k_implementation.VR & (1 << SPR_SYSTEM_GROUP) == 0) error ("System group should be available in the or1k implementation."); if (or1k_implementation.VR & (1 << SPR_DEBUG_GROUP) == 0) error ("Debug group should be available in the or1k implementation."); if (or1k_implementation.has_counters) warning ("Counters not supported."); /* Delete break, watch, catch points. */ for(i = 0; i < NUM_MATCHPOINTS; i++) { memset (&dcr[i], 0, sizeof (dcr[i])); matchpoint_user_count[i] = 0; } dmr1 = 0; dmr2 = 0; memset (&or1k_htrace, 0, sizeof (or1k_htrace)); /* RECSELDEPEND = 0 does not match our trace scheme. */ or1k_htrace.moder.rec_sel_dep = 1; debug_regs_changed = 0;//1; or1k_commit_debug_registers (); if (err != 0) error ("Cannot connect."); /* Enable exceptions */ or1k_write_spr_reg (SR_SPRNUM, or1k_read_spr_reg(SR_SPRNUM) | 0x2); /* Stop when breakpoint occurs. */ or1k_write_spr_reg (DSR_SPRNUM, dsr = 0x2000); do_cleanups (old_cleanups); /* This should cause an error if not connected. */ or1k_fetch_registers (-1); set_current_frame (create_new_frame (read_fp (), read_pc ())); select_frame (get_current_frame (), 0); /* Just empty it. */ if ((f = fopen (TRACE_FILENAME, "wb+")) == NULL) error ("Cannot open trace file."); fclose (f); trace_size = 0; or1k_status = TARGET_STOPPED; } /* Kill the process running on the board. */ void or1k_kill () { if (or1k_status != TARGET_RUNNING) return; or1k_status = TARGET_UNDEFINED; or1k_reset(); or1k_status = TARGET_STOPPED; inferior_pid = 0; } /* Open a connection to the remote board. */ static void or1k_open (name, from_tty) char *name; int from_tty; { or1k_init (name); /* Switch to using remote target now. */ current_ops = current_or1k_target->gdb_ops; or1k_is_open = 1; push_target (current_ops); /* FIXME: Should we call start_remote here? */ /* This is really the job of start_remote however, that makes an assumption that the target is about to print out a status message of some sort. That doesn't happen here (in fact, it may not be possible to get the monitor to send the appropriate packet). */ flush_cached_frames (); registers_changed (); stop_pc = read_pc (); set_current_frame (create_new_frame (read_fp (), stop_pc)); select_frame (get_current_frame (), 0); print_stack_frame (selected_frame, -1, 1); } /* This is the generic stop called via the target vector. When a target interrupt is requested, either by the command line or the GUI, we will eventually end up here. */ static void or1k_stop () { /* Send a break or a ^C, depending on user preference. */ debug ("remote_stop called\n"); /* We should not stop the target immediately, since it can be in an unfinished state. So we do a single step. This should not affect on anything. */ or1k_stall (); /* HW STEP. Set DMR1_ST. */ dmr1 |= DMR1_ST; or1k_write_spr_reg (DMR1_SPRNUM, dmr1); dmr1 &= ~DMR1_ST; or1k_unstall (); } /* Close a connection to the remote board. */ static void or1k_close (quitting) int quitting; { if (or1k_is_open) { or1k_kill (); if (current_or1k_target != NULL && current_or1k_target->to_done != NULL) current_or1k_target->to_done (); current_or1k_target = NULL; } generic_mourn_inferior (); } /* Detach from the remote board. */ static void or1k_detach (args, from_tty) char *args; int from_tty; { if (args) error ("Argument given to \"detach\" when remotely debugging."); pop_target (); or1k_close (1); if (from_tty) printf_unfiltered ("Ending remote or1k debugging.\n"); } /* Appends trace data to the trace file. */ static void or1k_read_trace () { struct htrace_data_struct data; ULONGEST tmp; int first = 1; FILE *fd; if ((fd = fopen (TRACE_FILENAME, "ab")) == NULL) { warning ("Cannot append to trace file."); return; } or1k_set_chain (SC_TRACE); while (1) { tmp = or1k_read_reg (0); memcpy (&data, &tmp, sizeof (data)); /* Last record reached. */ if (!data.valid) break; data.valid = first; first = 0; if (!fwrite (&data, sizeof (data), 1, fd)) { warning ("Cannot write trace data"); break; } } fclose (fd); } /* ^C Interrupt handling */ /* Ask the user what to do when an interrupt is received. */ static void interrupt_query () { target_terminal_ours (); if (query ("Interrupted while waiting for the program.\n\ Give up (and stop debugging it)? ")) { target_mourn_inferior (); return_to_top_level (RETURN_QUIT); } target_terminal_inferior (); } static void or1k_interrupt_twice (int signo); /* The command line interface's stop routine. This function is installed as a signal handler for SIGINT. The first time a user requests a stop, we call remote_stop to send a break or ^C. If there is no response from the target (it didn't stop when the user requested it), we ask the user if he'd like to detach from the target. */ static void or1k_interrupt (signo) int signo; { debug ("interrupt"); /* If this doesn't work, try more severe steps. */ signal (signo, or1k_interrupt_twice); debug ("remote_interrupt called\n"); interrupt_count++; } /* The user typed ^C twice. */ static void or1k_interrupt_twice (signo) int signo; { debug ("interrupt2"); signal (signo, ofunc); interrupt_query (); signal (signo, or1k_interrupt); } /* Resume execution of the target process. STEP says whether to single-step or to run free; SIGGNAL is the signal value (e.g. SIGINT) to be given to the target, or zero for no signal. */ static void or1k_resume (pid, step, siggnal) int pid, step; enum target_signal siggnal; { unsigned int pc; unsigned int ppc; unsigned int npc; unsigned int val; unsigned int ppc_insn; unsigned int pc_insn; pc = read_pc(); npc = or1k_read_spr_reg (PC_SPRNUM); ppc = or1k_read_spr_reg (PPC_SPRNUM); debug ("pc = %08x BP = %x npc = %08x ppc = %08x\n", pc, breakpoint_here_p (pc), npc, ppc); debug ("resume %i, %i, %i\n",step, siggnal, or1k_status); if (or1k_status != TARGET_STOPPED) if (or1k_status == TARGET_RUNNING) error ("Program is already running."); else error ("The program is not being run."); /* Clear reason register for later. */ or1k_write_spr_reg (DRR_SPRNUM, 0); or1k_commit_debug_registers (); /* Fetch previous insn */ ppc_insn = or1k_fetch_instruction (ppc); /* Fetch next insn */ pc_insn = or1k_fetch_instruction (pc); if (step) { /* HW STEP. Set DMR1_ST. */ dmr1 |= DMR1_ST; or1k_write_spr_reg (DMR1_SPRNUM, dmr1); dmr1 &= ~DMR1_ST; if (new_pc_set) { debug("resume: 1\n"); /* If new PC was set, then just set it again to fill the pipeline */ or1k_write_spr_reg (PC_SPRNUM, pc); if (is_delayed (pc_insn) && insn_modifies_gprs (pc_insn)) { debug("resume: 10\n"); /* We are steping across jump an link insn - save link register, so we will be able to restore it when we will step across delay slot insn */ step_link_insn = 1; lr = or1k_read_spr_reg (REGNUM_TO_SPRNUM(9)); } } else if (is_delayed (ppc_insn) && (ppc != pc)) { debug("resume: 2\n"); /* Steping across delay slot insn - we have to reexcute branch insn */ if (breakpoint_here_p (ppc)) or1k_write_mem(ppc, ppc_insn); if (insn_modifies_gprs (ppc_insn) && step_link_insn) { debug("resume: 11\n"); /* If this is delay slot of jump an link insn that was allready executed - restore link register first */ or1k_write_spr_reg (REGNUM_TO_SPRNUM(9), lr); step_link_insn = 0; } or1k_write_spr_reg (PC_SPRNUM, ppc); or1k_unstall (); or1k_set_chain (SC_REGISTER); val = or1k_read_reg (JTAG_RISCOP); do { val = or1k_read_reg (JTAG_RISCOP); } while ((val & 1) == 0); } else if (hit_breakpoint && ((ppc + 4) != npc) && (pc != npc)) { debug("resume: 3\n"); /* Trapped on delay slot instruction. */ /* Set PC to branch insn preceding delay slot. */ or1k_write_spr_reg (PC_SPRNUM, ppc - 4); if (insn_modifies_gprs (or1k_fetch_instruction (ppc - 4))) { debug("resume: 12\n"); /* We are steping across jump an link insn - save link register, so we will be able to restore it when we will step across delay slot insn */ step_link_insn = 1; lr = or1k_read_spr_reg (REGNUM_TO_SPRNUM(9)); } or1k_unstall (); or1k_set_chain (SC_REGISTER); val = or1k_read_reg (JTAG_RISCOP); do { val = or1k_read_reg (JTAG_RISCOP); } while ((val & 1) == 0); } else { debug("resume: 4\n"); /* Steping across 'non delay slot' insn - set PC to fill the pipeline */ or1k_write_spr_reg (PC_SPRNUM, pc); if (is_delayed (pc_insn) && insn_modifies_gprs (pc_insn)) { debug("resume: 13\n"); /* We are steping across jump an link insn - save link register, so we will be able to restore it when we will step across delay slot insn */ step_link_insn = 1; lr = or1k_read_spr_reg (REGNUM_TO_SPRNUM(9)); } } } else { dmr1 &= ~DMR1_ST; or1k_write_spr_reg (DMR1_SPRNUM, dmr1); if (new_pc_set) { debug("resume: 5\n"); /* If new PC was set, then just set it again to fill the pipeline */ step_link_insn = 0; or1k_write_spr_reg (PC_SPRNUM, pc); } else if (is_delayed (ppc_insn) && !breakpoint_here_p (ppc)) { debug("resume: 6\n"); /* If next insn is delay slot insn - set PC to previous branch insn and continue from there to refill the pipeline */ if (insn_modifies_gprs (ppc_insn) && step_link_insn) { debug("resume: 14\n"); /* If this is delay slot of jump an link insn that was allready executed - restore link register first */ or1k_write_spr_reg (REGNUM_TO_SPRNUM(9), lr); step_link_insn = 0; } or1k_write_spr_reg (PC_SPRNUM, ppc); } else if (is_delayed (ppc_insn) && breakpoint_here_p (ppc)) { debug("resume: 7\n"); /* If next insn is delay slot insn and previous branch insn is actually BP - replace BP with original branch insn, set PC to that insn step over it, put back BP and continue */ or1k_write_mem(ppc, ppc_insn); dmr1 |= DMR1_ST; or1k_write_spr_reg (DMR1_SPRNUM, dmr1); dmr1 &= ~DMR1_ST; or1k_write_spr_reg (PC_SPRNUM, ppc); if (insn_modifies_gprs (ppc_insn) && step_link_insn) { debug("resume: 15\n"); /* If this is delay slot of jump an link insn that was allready executed - restore link register first */ or1k_write_spr_reg (REGNUM_TO_SPRNUM(9), lr); step_link_insn = 0; } or1k_unstall (); or1k_set_chain (SC_REGISTER); val = or1k_read_reg (JTAG_RISCOP); do { val = or1k_read_reg (JTAG_RISCOP); } while ((val & 1) == 0); or1k_write_mem(ppc, 0x21000001); or1k_write_spr_reg (DMR1_SPRNUM, dmr1); } else { debug("resume: 8\n"); /* Continue from 'non delay slot' insn - set PC to fill the pipeline */ or1k_write_spr_reg (PC_SPRNUM, pc); } } /* Now we are in normal program flow again */ new_pc_set = 0; /* We can now continue normally, independent of step */ or1k_unstall (); or1k_status = TARGET_RUNNING; debug ("-resume %i, %i, %i\n",step, siggnal, or1k_status); } /* Wait until the remote stops, and return a wait status. */ static int or1k_wait (pid, status) int pid; struct target_waitstatus *status; { unsigned long val; unsigned long pc; unsigned long ppc; char buf[MAX_REGISTER_RAW_SIZE]; interrupt_count = 0; debug ("wait %i %i\n", pid, or1k_status); /* If we have not sent a single step or continue command, then the board is waiting for us to do something. Return a status indicating that it is stopped. */ if (or1k_status != TARGET_RUNNING) { if (or1k_status != TARGET_STOPPED) error("Target in invalid state."); status->kind = TARGET_WAITKIND_STOPPED; status->value.sig = TARGET_SIGNAL_TRAP; return 0; } if (err) or1k_error ("Remote failure: %s", or1k_err_name (err)); /* Set new signal handler */ ofunc = signal (SIGINT, or1k_interrupt); /* Wait for risc to stop. */ do { or1k_set_chain (SC_REGISTER); val = or1k_read_reg (JTAG_RISCOP); /* When we press Ctrl-C, interrupt count is set, but we must wait for or1k_read_reg to finish, otherwise we would interrupt transaction. */ if (interrupt_count) or1k_stop (); usleep (10); debug ("%i", val); } while ((val & 1) == 0); drr = or1k_read_spr_reg (DRR_SPRNUM); /* Restore old INT signal handler */ signal (SIGINT, ofunc); /* Single step does not set trap exception, so we set it manually to simplify our code */ dmr1 = or1k_read_spr_reg (DMR1_SPRNUM); if (dmr1 & DMR1_ST) drr |= DRR_TE; status->kind = TARGET_WAITKIND_STOPPED; debug ("epcr0 = %08x\n", or1k_read_spr_reg (EPCR0_SPRNUM)); debug ("drr = %08x\n", drr); registers_changed (); pc = read_pc (); ppc = or1k_read_spr_reg (PPC_SPRNUM); debug ("ppc = %08x\n", ppc); if (drr & DRR_TE) { /* If single step is not set, we should correct the pc. */ if (!(dmr1 & DMR1_ST)) /* PC has already stepped over the l.trap instruction. */ pc = ppc; status->value.sig = TARGET_SIGNAL_TRAP; drr &= ~DRR_TE; } else if (drr & DRR_RSTE) { status->value.sig = TARGET_SIGNAL_REALTIME_33; drr &= ~DRR_RSTE; } else if (drr & DRR_BUSEE) { status->value.sig = TARGET_SIGNAL_BUS; drr &= ~DRR_BUSEE; } else if (drr & DRR_AE) { status->value.sig = TARGET_SIGNAL_REALTIME_36; drr &= ~DRR_AE; } else if (drr & DRR_IIE) { status->value.sig = TARGET_SIGNAL_ILL; drr &= ~DRR_IIE; } else if (drr & DRR_RE) { status->value.sig = TARGET_SIGNAL_REALTIME_39; drr &= ~DRR_RE; } else if (drr & DRR_IME) { status->value.sig = TARGET_SIGNAL_REALTIME_38; drr &= ~DRR_IME; } else if (drr & DRR_DME) { status->value.sig = TARGET_SIGNAL_REALTIME_37; drr &= ~DRR_DME; } else if (drr & DRR_DPFE) { status->value.sig = TARGET_SIGNAL_REALTIME_34; drr &= ~DRR_DPFE; } else if (drr & DRR_IPFE) { status->value.sig = TARGET_SIGNAL_REALTIME_35; drr &= ~DRR_DPFE; } else if (drr & DRR_SCE) { status->value.sig = TARGET_SIGNAL_REALTIME_40; drr &= ~DRR_SCE; } else if (drr & DRR_HPINTE) { status->value.sig = TARGET_SIGNAL_INT; drr &= ~DRR_HPINTE; } else if (drr & DRR_LPINTE) { status->value.sig = TARGET_SIGNAL_INT; drr &= ~DRR_LPINTE; } else { status->value.sig = TARGET_SIGNAL_UNKNOWN; warning ("Invalid exception occured."); } /* Update drr register */ or1k_write_spr_reg (DRR_SPRNUM, drr); /* Write into PC flushes the pipeline! */ /* We got the number the register holds, but gdb expects to see a value in the target byte ordering. */ /* write_pc (pc); */ store_unsigned_integer (buf, REGISTER_RAW_SIZE (PC_REGNUM), pc); supply_register (PC_REGNUM, buf); hit_breakpoint = breakpoint_here_p (pc); /*or1k_write_spr_reg (PC_SPRNUM, pc); store_unsigned_integer (buf, REGISTER_RAW_SIZE (PC_REGNUM), pc); supply_register (PC_REGNUM, buf);*/ /* Log remote stop. */ or1k_status = TARGET_STOPPED; /* Determine what caused trap - breakpoint or watchpoint. */ if (status->value.sig == TARGET_SIGNAL_TRAP) { /* Search all active breakpoints for a match. */ CORE_ADDR pc = read_pc (); int breakpoint = 0; int i; unsigned char break_bytes[4] = BRK_INSTR_STRUCT; unsigned long b_insn = ntohl(*((unsigned long*)break_bytes)); unsigned long value = pc; for (i = 0; i < or1k_implementation.num_used_matchpoints; i++) if (dvr[i] == pc && dcr[i].dp && dcr[i].cc == CC_EQUAL && !dcr[i].sc && dcr[i].ct == CT_FETCH) { breakpoint = 1; break; } hit_watchpoint = !breakpoint; /* Cause the trap/breakpoint exception to be ignored. This is the behavior of the simulator when the PC value is changed by a write command. All pending exceptions are cleared and the simulator continues at the PC value specified. We need to do this if the instruction at the current PC has the value BRK_INSTR_STRUCT */ if(b_insn == or1k_read_mem((pc & 3))) { or1k_write_spr_reg(PC_SPRNUM,value); } } else hit_watchpoint = 0; /* If the stop PC is in the _exit function, assume we hit the 'break 0x3ff' instruction in _exit, so this is not a normal breakpoint. */ { char *func_name; CORE_ADDR func_start; CORE_ADDR pc = read_pc (); find_pc_partial_function (pc, &func_name, &func_start, NULL); if (func_name != NULL && strcmp (func_name, "_exit") == 0 && func_start == pc) status->kind = TARGET_WAITKIND_EXITED; } or1k_read_trace (); debug ("-wait %i %i\n", pid, or1k_status); return 0; } /* Fetch a word from the target board. All memory accesses to the remote board are word aligned. */ unsigned int or1k_fetch_word (addr) CORE_ADDR addr; { if (addr & 3) { int subaddr = addr & 3; unsigned char buf[8]; unsigned int low, high; addr >>= 2; low = or1k_read_mem (addr << 2); high = or1k_read_reg ((addr + 1) << 2); memcpy (&buf[0], &low, 4); memcpy (&buf[4], &high, 4); memcpy (&low, &buf[subaddr], 4); return low; } else { return or1k_read_mem (addr); } } /* Store a word to the target board. Returns errno code or zero for success. All memory accesses to the remote board are word aligned. */ static int or1k_store_word (addr, val) CORE_ADDR addr; unsigned int val; { if (addr & 3) { int subaddr = addr & 3; unsigned char buf[8]; unsigned int low, high; addr >>= 2; low = or1k_read_mem (addr << 2); high = or1k_read_mem ((addr + 1) << 2); memcpy (&buf[0], &low, 4); memcpy (&buf[4], &high, 4); memcpy (&buf[subaddr], &val, 4); memcpy (&low, &buf[0], 4); memcpy (&high, &buf[4], 4); or1k_write_mem (addr << 2, low); or1k_write_mem ((addr + 1) << 2, high); } else { or1k_write_mem (addr, val); } return err; } /* Fetch the remote registers. */ void or1k_fetch_registers (regno) int regno; { unsigned int val; if (regno == -1) { for (regno = 0; regno < NUM_REGS; regno++) or1k_fetch_registers (regno); return; } if (regno >= NUM_REGS) error("Invalid register number!"); /* Convert to SPRNUM and read. */ val = or1k_read_spr_reg (REGNUM_TO_SPRNUM(regno)); { char buf[MAX_REGISTER_RAW_SIZE]; /* We got the number the register holds, but gdb expects to see a value in the target byte ordering. */ store_unsigned_integer (buf, REGISTER_RAW_SIZE (regno), val); supply_register (regno, buf); } if (err) or1k_error ("Can't read register %d(%i): %s", regno, REGNUM_TO_SPRNUM(regno), or1k_err_name (err)); } /* Fetch and return instruction from the specified location. */ unsigned int or1k_fetch_instruction (addr) CORE_ADDR addr; { char buf[OR1K_INSTLEN]; int status; status = read_memory_nobpt (addr, buf, OR1K_INSTLEN); if (status) memory_error (status, addr); return extract_unsigned_integer (buf, OR1K_INSTLEN); } /* Currently not needed. */ static void or1k_prepare_to_store () { } /* Store remote register(s). */ static void or1k_store_registers (regno) int regno; { if (regno == -1) { for (regno = 0; regno < NUM_REGS; regno++) or1k_store_registers (regno); return; } if (regno >= NUM_REGS) error("Invalid register number!"); or1k_write_spr_reg (REGNUM_TO_SPRNUM(regno), read_register (regno)); if (err) or1k_error ("Can't write register %d(%i): %s", regno, REGNUM_TO_SPRNUM(regno), or1k_err_name (err)); } /* Read or write LEN bytes from inferior memory at MEMADDR, transferring to or from debugger address MYADDR. Write to inferior if SHOULD_WRITE is nonzero. Returns length of data written or read; 0 for error. Note that protocol gives us the correct value for a longword, since it transfers values in ASCII. We want the byte values, so we have to swap the longword values. */ static int or1k_xfer_memory (memaddr, myaddr, len, write, ignore) CORE_ADDR memaddr; char *myaddr; int len; int write; struct target_ops *ignore; { register int i; /* Round starting address down to longword boundary. */ register CORE_ADDR addr = memaddr & ~3; /* Round ending address up; get number of longwords that makes. */ register int count = (((memaddr + len) - addr) + 3) / 4; /* Allocate buffer of that many longwords. */ register char *buffer = alloca (count * 4); int status; int block_xfer_size = 256; /* CZ 21/06/01 ... number of 32 bit words */ int nBlocks = (count + block_xfer_size -1)/block_xfer_size; int terminate = 0; /* Terminate the printing of '*'s... */ #ifdef DEBUG_JTAG debug ("xfer_memory %s addr=%x, len=%i, \n", write?"write":"read", memaddr, len); fflush(stdout); #endif #if 0 if (memaddr >= MEM_SPACE) error("Invalid address"); #endif /* (CZ 21/06/01 -- because upper layers which know nothing about Or1k or JTAG call this function directly, it is always necessary to set the chain to point to the Debug Unit. Otherwise, it may be pointing to the Development Interface chain, in which case we're going to get bupkiss... */ if (write) { /* Fill start and end extra bytes of buffer with existing data. */ if (addr != memaddr || len < 4) { /* Need part of initial word -- fetch it. */ store_unsigned_integer (&buffer[0], 4, or1k_fetch_word (addr)); } if (count > 1) { /* Need part of last word -- fetch it. FIXME: we do this even if we don't need it. */ store_unsigned_integer (&buffer[(count - 1) * 4], 4, or1k_fetch_word (addr + (count - 1) * 4)); } /* Copy data to be written over corresponding part of buffer */ memcpy ((char *) buffer + (memaddr & 3), myaddr, len); /* CZ: rewrote the block transfer routines to make the code a little more efficient for implementations that can handle variable sized scan chains. Might be useful in the future. Certainly makes downloads to the simulator more efficient. */ for(i=0;i<nBlocks;i++,count-=block_xfer_size,addr += block_xfer_size*4) { int j; int n = count < block_xfer_size ? count : block_xfer_size; unsigned long *__buf; if(!(__buf = (unsigned long*)malloc(n*sizeof(unsigned long)))) { errno = ERR_MEM; return 0; } for(j=0;j<n;j++) __buf[j] = (unsigned long)extract_unsigned_integer(&buffer[(i * block_xfer_size +j)*4], 4); or1k_set_chain (SC_WISHBONE); status = or1k_store_block(addr,__buf,n); free(__buf); if(n == block_xfer_size) { debug ("*"); gdb_flush (gdb_stdout); } if (status) { errno = status; return 0; } /* FIXME: Do we want a QUIT here? */ } if (terminate) debug ("\n"); } else { for(i=0;i<nBlocks;i++,count-=block_xfer_size,addr += block_xfer_size*4) { int j; int n = count < block_xfer_size ? count : block_xfer_size; unsigned long *__buf; or1k_set_chain (SC_WISHBONE); __buf = (unsigned long*)malloc(n*sizeof(unsigned long)); status = or1k_load_block(addr,__buf,n); if (!status) for(j=0;j<n;j++) store_unsigned_integer (&buffer[(i * block_xfer_size +j)*4], 4, __buf[j]); else errno = status; free(__buf); if(status) return 0; } /* Copy appropriate bytes out of the buffer. */ memcpy (myaddr, buffer + (memaddr & 3), len); } return len; } int or1k_load_block(CORE_ADDR addr,void* buffer,int nRegisters) { int i=0; unsigned int regno = addr; if (current_or1k_target != NULL && current_or1k_target->to_read_block != NULL) return current_or1k_target->to_read_block (regno,buffer,nRegisters); else for(i=0;i<nRegisters;i++) ((unsigned long*)buffer)[i] = 0x1234; return 0; } int or1k_store_block(CORE_ADDR addr,void* buffer,int nRegisters) { unsigned int regno = addr; if (current_or1k_target != NULL && current_or1k_target->to_write_block != NULL) return current_or1k_target->to_write_block (regno,buffer,nRegisters); return 0; } /* Print info on this target. */ static void or1k_files_info (ignore) struct target_ops *ignore; { char *file = "nothing"; if (exec_bfd) file = bfd_get_filename (exec_bfd); printf_filtered ("or1k_files_info: file \"%s\"\n", file); if (exec_bfd) { printf_filtered ("\tAttached to %s running program %s\n", target_shortname, file); } /* Print target info. */ printf_filtered ("Status: %s\n", status_name[or1k_status]); } /* Tell whether we can support a hardware breakpoint. */ static int or1k_can_use_hardware_breakpoint () { int i; /* Search for unused breakpoint. */ return or1k_implementation.num_used_matchpoints < or1k_implementation.num_matchpoints; } /* Insert a breakpoint. On targets that don't have built-in breakpoint support, we read the contents of the target location and stash it, then overwrite it with a breakpoint instruction. ADDR is the target location in the target machine. CONTENTS_CACHE is a pointer to memory allocated for saving the target contents. It is guaranteed by the caller to be long enough to save sizeof BREAKPOINT bytes (this is accomplished via BREAKPOINT_MAX). */ int or1k_insert_breakpoint (addr, contents_cache) CORE_ADDR addr; char *contents_cache; { if (or1k_can_use_hardware_breakpoint()) return set_breakpoint (addr); else return memory_insert_breakpoint (addr, contents_cache); } int or1k_remove_breakpoint (addr, contents_cache) CORE_ADDR addr; char *contents_cache; { /* First try to remove HW breakpoint at address */ if (clear_breakpoint (addr)) return memory_remove_breakpoint (addr, contents_cache); else return 0; } /* Tell whether this target can support a hardware breakpoint. CNT is the number of hardware breakpoints already installed. This implements the TARGET_CAN_USE_HARDWARE_WATCHPOINT macro. Lower bound is estimated. !!! Can we estimate better? */ int or1k_can_use_hardware_watchpoint (bp_type, cnt) enum bptype bp_type; int cnt; { /* Are there at least two matchpoints left for watch? - estimate lower bound */ return cnt + ((bp_type == bp_hardware_watchpoint)?(1):(0)) <= or1k_implementation.num_matchpoints; } /* Moves matchpoint. This is very tricky - we have to update all references to matchpoint indexes. We assume here that matchpoint with index to is unused! */ static void move_matchpoint (int from, int to) { int i, j, tmp, chaining; if (matchpoint_user_count[to] != 0) error ("Internal: Destination matchpoint still has users"); matchpoint_user_count[to] = matchpoint_user_count[from]; matchpoint_user_count[from] = 0; debug_regs_changed = 1; dvr[to] = dvr[from]; dcr[to] = dcr[from]; dcr[from].dp = 0; /* Copy chaining bits. */ chaining = dmr1 & (3 << (2 * from)); dmr1 &= ~(3 << (2 * to)); dmr1 |= chaining << (2 * to); dmr1 &= ~(3 << (2 * from)); /* Copy watchpoint bits */ tmp = dmr2 & (1 << from); dmr2 &= 1 << to; dmr2 |= tmp << to; dmr2 &= 1 << from; /* Update hwatch table. Here we assume that matchpoint group is connected (it cannot be implemented in HW otherwise), so if we move first, we will have to move others later. */ for (i = 0; i < num_hw_watches; i++) if (or1k_hwatch[i].matchpoint_start == from) or1k_hwatch[i].matchpoint_start = to; /* Update htrace struct. */ tmp = or1k_htrace.trig.wp_trig & (1 << from); or1k_htrace.trig.wp_trig &= 1 << to; or1k_htrace.trig.wp_trig |= tmp << to; or1k_htrace.trig.wp_trig &= 1 << from; tmp = or1k_htrace.qual.wp_trig & (1 << from); or1k_htrace.qual.wp_trig &= 1 << to; or1k_htrace.qual.wp_trig |= tmp << to; or1k_htrace.qual.wp_trig &= 1 << from; tmp = or1k_htrace.stop.wp_trig & (1 << from); or1k_htrace.stop.wp_trig &= 1 << to; or1k_htrace.stop.wp_trig |= tmp << to; or1k_htrace.stop.wp_trig &= 1 << from; for (i = 0; i < MAX_MATCHPOINTS; i++) { tmp = or1k_htrace.wp_record_uses[i] & (1 << from); or1k_htrace.wp_record_uses[i] &= 1 << to; or1k_htrace.wp_record_uses[i] |= tmp << to; or1k_htrace.wp_record_uses[i] &= 1 << from; } /* Do we need to move other references also? */ } /* Sifts unused matchpoints to higher indexses. */ void sift_matchpoints () { int i, first_free = 0; for (i = 0; i < or1k_implementation.num_matchpoints; i++) if (dcr[i].dp) { /* Move references. */ move_matchpoint (i, first_free); first_free++; } /* Unused matchpoints should be disabled by move_matchpoint, so we are done here. */ } /* Translates gdb watchpoint type into one in DCR register. */ static int translate_type (gdb_type) int gdb_type; { switch (gdb_type) { case 0: return CT_SDATA; case 1: return CT_LDATA; case 2: return CT_ADATA; default: error ("Invalid type."); } } /* Set a data watchpoint. ADDR and LEN should be obvious. TYPE is 0 for a write watchpoint, 1 for a read watchpoint, or 2 for a read/write watchpoint. */ int or1k_insert_watchpoint (addr, len, type) CORE_ADDR addr; int len; int type; { int i; if (len < 1) return -1; type = translate_type (type); /* Moves unused watchpoints to the top. */ sift_matchpoints (); /* Place at first free matchpoint. */ i = or1k_implementation.num_used_matchpoints; dvr[i] = addr; dcr[i].dp = 1; dcr[i].cc = CC_GREATE; dcr[i].sc = 0; dcr[i].ct = type; /* Set && chaining here. */ dmr1 &= ~(3 << (2 * i)); dmr1 |= CHAINING_AND << (2 * i); /* Set upper watchpoint bound. */ i++; dvr[i] = addr + len - 1; dcr[i].dp = 1; dcr[i].cc = CC_LESSE; dcr[i].sc = 0; dcr[i].ct = type; /* Matchpoints will cause breakpoints */ dmr2 |= (1 << i); or1k_implementation.num_used_matchpoints += 2; debug_regs_changed = 1; return 0; } /* Removes a data watchpoint. ADDR and LEN should be obvious. TYPE is 0 for a write watchpoint, 1 for a read watchpoint, or 2 for a read/write watchpoint. */ int or1k_remove_watchpoint (addr, len, type) CORE_ADDR addr; int len; int type; { int i, found = -1; if (len < 1) return -1; type = translate_type (type); /* Find the right one. */ for (i = 0; i < or1k_implementation.num_used_matchpoints; i++) if (dvr[i] == addr && dcr[i].dp && dcr[i].cc == CC_GREATE && !dcr[i].sc && dcr[i].ct == type && dvr[i + 1] == addr + len - 1 && dcr[i + 1].dp && dcr[i + 1].cc == CC_LESSE && !dcr[i + 1].sc && dcr[i + 1].ct == type) { found = i; break; } if (found < 0) return -1; dcr[found].dp = 0; dcr[found + 1].dp = 0; /* Matchpoints will not cause breakpoints anymore. */ dmr2 &= ~(1 << i); or1k_implementation.num_used_matchpoints -= 2; debug_regs_changed = 1; return 0; } int or1k_stopped_by_watchpoint (void) { /* For now, no watchpoints */ return 0; /* return hit_watchpoint; */ } /* Insert a breakpoint. */ int set_breakpoint (addr) CORE_ADDR addr; { int i; /* Search for unused breakpoint. */ for (i = 0; i < NUM_MATCHPOINTS; i++) if (dcr[i].dp == 0) break; if (i >= NUM_MATCHPOINTS) return 1; dvr[i] = addr; dcr[i].dp = 1; dcr[i].cc = CC_EQUAL; dcr[i].sc = 0; dcr[i].ct = CT_FETCH; or1k_implementation.num_used_matchpoints++; /* No chaining here. */ dmr1 &= ~(3 << (2*i)); /* Matchpoints will cause breakpoints */ dmr2 |= (1 << i); debug_regs_changed = 1; return 0; } /* Clear a breakpoint. */ int clear_breakpoint (addr) CORE_ADDR addr; { int i; /* Search for matching breakpoint. */ for (i = 0; i < NUM_MATCHPOINTS; i++) if ((dcr[i].dp == 1) && (dvr[i] == addr) && (dcr[i].cc == CC_EQUAL) && (dcr[i].sc == 0) && (dcr[i].ct == CT_FETCH)) break; if (i >= NUM_MATCHPOINTS) return 1; dcr[i].dp = 0; /* Matchpoints will cause breakpoints */ dmr2 &= ~(1 << i); or1k_implementation.num_used_matchpoints--; debug_regs_changed = 1; return 0; } /* Start running on the target board. */ static void or1k_create_inferior (execfile, args, env) char *execfile; char *args; char **env; { CORE_ADDR entry_pt; if (args && *args) { warning ("Can't pass arguments to remote OR1K board; arguments ignored."); /* And don't try to use them on the next "run" command. */ execute_command ("set args", 0); } if (execfile == 0 || exec_bfd == 0) error ("No executable file specified"); or1k_kill (); remove_breakpoints (); entry_pt = (CORE_ADDR) bfd_get_start_address (exec_bfd); init_wait_for_inferior (); /* FIXME: Should we set inferior_pid here? */ /* Needed to get correct instruction in cache */ insert_breakpoints (); clear_proceed_status (); or1k_status = TARGET_STOPPED; proceed (entry_pt, TARGET_SIGNAL_DEFAULT, 0); } /* Clean up after a process. Actually nothing to do. */ static void or1k_mourn_inferior () { generic_mourn_inferior (); } static void or1k_dummy_open (name, from_tty) char *name; int from_tty; { target_preopen (from_tty); if (or1k_is_open) unpush_target (current_ops); current_or1k_target = &or1k_target_dummy; or1k_open (name, from_tty); } static void or1k_jtag_open (name, from_tty) char *name; int from_tty; { target_preopen (from_tty); if (or1k_is_open) unpush_target (current_ops); current_or1k_target = &or1k_target_jtag; or1k_open (name, from_tty); } static void or1k_sim_open (name, from_tty) char *name; int from_tty; { /* target_preopen (from_tty); - do we need this ? */ if (or1k_is_open) unpush_target (current_ops); current_or1k_target = &or1k_target_sim; or1k_open (name, from_tty); } /* Executes command on the target. */ void or1k_sim_cmd (char *args, int from_tty) { if (current_or1k_target != NULL && current_or1k_target->to_exec_command != NULL) current_or1k_target->to_exec_command (args, from_tty); else error ("Command not supported on this target. "); } /* Displays matchpoints usage. */ void info_matchpoints_command (char *args, int from_tty) { int i; for (i = 0; i < or1k_implementation.num_matchpoints; i++) { printf_filtered ("WP%i ", i); if (dcr[i].dp) { int chaining = (dmr1 << 2*i) & 3; printf_filtered ("= %s ", ct_names[dcr[i].ct]); if (dcr[i]. sc) printf_filtered ("s%s %i", cc_names[dcr[i].cc], (int)dvr[i]); else printf_filtered ("%s %u", cc_names[dcr[i].cc], (unsigned int)dvr[i]); if (chaining) printf_filtered ("%s WP%i", ch_names[chaining], i - 1); } else printf_filtered ("NOT USED"); if ((dmr2 >> i) & 1) printf_filtered (", causes breakpoint"); if ((dmr2 >> (i + 11)) & 1) printf_filtered (", increments counter"); printf_filtered ("\n"); } } static int insn_modifies_gprs(unsigned int insn) { /* l.jal */ if ((insn >> 26) == 0x01) return 1; /* l.jalr */ if ((insn >> 26) == 0x12) return 1; return 0; } void _initialize_remote_or1k () { /* Initialize the fields in or1k_ops that are common to all targets. */ or1k_dummy_ops.to_close = or1k_close; or1k_dummy_ops.to_detach = or1k_detach; or1k_dummy_ops.to_resume = or1k_resume; or1k_dummy_ops.to_wait = or1k_wait; or1k_dummy_ops.to_fetch_registers = or1k_fetch_registers; or1k_dummy_ops.to_store_registers = or1k_store_registers; or1k_dummy_ops.to_prepare_to_store = or1k_prepare_to_store; or1k_dummy_ops.to_xfer_memory = or1k_xfer_memory; or1k_dummy_ops.to_files_info = or1k_files_info; or1k_dummy_ops.to_insert_breakpoint = or1k_insert_breakpoint; or1k_dummy_ops.to_remove_breakpoint = or1k_remove_breakpoint; or1k_dummy_ops.to_kill = or1k_kill; or1k_dummy_ops.to_load = generic_load; or1k_dummy_ops.to_create_inferior = or1k_create_inferior; or1k_dummy_ops.to_mourn_inferior = or1k_mourn_inferior; or1k_dummy_ops.to_stratum = process_stratum; or1k_dummy_ops.to_stop = or1k_stop; /* We can access memory while program is running. */ or1k_dummy_ops.to_has_all_memory = 0; or1k_dummy_ops.to_has_memory = 1; or1k_dummy_ops.to_has_stack = 1; or1k_dummy_ops.to_has_registers = 1; or1k_dummy_ops.to_has_execution = 1; or1k_dummy_ops.to_magic = OPS_MAGIC; /* Copy the common fields to all target vectors. */ or1k_jtag_ops = or1k_sim_ops = or1k_dummy_ops; /* Initialize target-specific fields in the target vectors adn add targets. */ or1k_jtag_ops.to_shortname = "jtag"; or1k_jtag_ops.to_longname = "Remote or1k debugging over JTAG port"; or1k_jtag_ops.to_doc = "Debug a board using the OR1K remote debugging protocol" " over a parallel line.\nThe argument is the parallel port it is connected " "to, or, if it is formatted\nas a URL of the form jtag://<hostname>:<port>," " then the argument refers to\na remote JTAG proxy server.\n"; or1k_jtag_ops.to_open = or1k_jtag_open; add_target (&or1k_jtag_ops); or1k_dummy_ops.to_shortname = "dummy"; or1k_dummy_ops.to_longname = "Dummy target"; or1k_dummy_ops.to_doc = "Actually no real target attached - more like /dev/null.\n"; or1k_dummy_ops.to_open = or1k_dummy_open; add_target (&or1k_dummy_ops); or1k_sim_ops.to_shortname = "sim"; or1k_sim_ops.to_longname = "Remote or1k debugging using architecture simulator"; or1k_sim_ops.to_doc = "Debug using an architecture simulator.\n"; or1k_sim_ops.to_open = or1k_sim_open; add_target (&or1k_sim_ops); add_info ("matchpoints", info_matchpoints_command, "Show current matchpoints allocation status."); }
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