void
db_restart_at_pc(db_regs_t *regs, bool watchpt)
{
db_addr_t pc = PC_REGS(regs);
#ifdef SOFTWARE_SSTEP
db_addr_t brpc;
#endif
if ((db_run_mode == STEP_COUNT) ||
(db_run_mode == STEP_RETURN) ||
(db_run_mode == STEP_CALLT)) {
db_expr_t ins __unused;
/*
* We are about to execute this instruction,
* so count it now.
*/
ins = db_get_value(pc, sizeof(int), false);
db_inst_count++;
db_load_count += inst_load(ins);
db_store_count += inst_store(ins);
#ifdef SOFTWARE_SSTEP
/*
* Account for instructions in delay slots.
*/
brpc = next_instr_address(pc, true);
if ((brpc != pc) &&
(inst_branch(ins) || inst_call(ins) || inst_return(ins))) {
ins = db_get_value(brpc, sizeof(int), false);
db_inst_count++;
db_load_count += inst_load(ins);
db_store_count += inst_store(ins);
}
#endif
}
if (db_run_mode == STEP_CONTINUE) {
if (watchpt || db_find_breakpoint_here(pc)) {
/*
* Step over breakpoint/watchpoint.
*/
db_run_mode = STEP_INVISIBLE;
db_set_single_step(regs);
} else {
db_set_breakpoints();
db_set_watchpoints();
}
} else {
db_set_single_step(regs);
}
}
static void
db_single_step(db_regs_t *regs)
{
if (db_run_mode == STEP_CONTINUE) {
db_run_mode = STEP_INVISIBLE;
db_set_single_step(regs);
}
}
void
db_restart_at_pc(boolean_t watchpt)
{
db_addr_t pc = PC_REGS(DDB_REGS);
if ((db_run_mode == STEP_COUNT) ||
(db_run_mode == STEP_RETURN) ||
(db_run_mode == STEP_CALLT)) {
db_expr_t ins __unused; /* seems used but gcc thinks not */
/*
* We are about to execute this instruction,
* so count it now.
*/
ins = db_get_value(pc, sizeof(int), FALSE);
db_inst_count++;
db_load_count += inst_load(ins);
db_store_count += inst_store(ins);
#ifdef SOFTWARE_SSTEP
/* XXX works on mips, but... */
if (inst_branch(ins) || inst_call(ins)) {
ins = db_get_value(next_instr_address(pc,1),
sizeof(int), FALSE);
db_inst_count++;
db_load_count += inst_load(ins);
db_store_count += inst_store(ins);
}
#endif /* SOFTWARE_SSTEP */
}
if (db_run_mode == STEP_CONTINUE) {
if (watchpt || db_find_breakpoint_here(pc)) {
/*
* Step over breakpoint/watchpoint.
*/
db_run_mode = STEP_INVISIBLE;
db_set_single_step(DDB_REGS);
} else {
db_set_breakpoints();
db_set_watchpoints();
}
} else {
db_set_single_step(DDB_REGS);
}
}
/*
* This function does all command processing for interfacing to
* a remote gdb. Note that the error codes are ignored by gdb
* at present, but might eventually become meaningful. (XXX)
* It might makes sense to use POSIX errno values, because
* that is what the gdb/remote.c functions want to return.
*/
int
kgdb_trap(int type, db_regs_t *regs)
{
label_t jmpbuf;
vaddr_t addr;
size_t len;
u_char *p;
kgdb_entry_notice(type, regs);
if (kgdb_dev == NODEV || kgdb_getc == NULL) {
/* not debugging */
return (0);
}
db_clear_single_step(regs);
if (db_trap_callback)
db_trap_callback(1);
/* Detect and recover from unexpected traps. */
if (kgdb_recover != 0) {
printf("kgdb: caught trap 0x%x at %p\n",
type, (void*)PC_REGS(regs));
kgdb_send("E0E"); /* 14==EFAULT */
longjmp(kgdb_recover);
}
/*
* The first entry to this function is normally through
* a breakpoint trap in kgdb_connect(), in which case we
* must advance past the breakpoint because gdb will not.
*
* Machines vary as to where they leave the PC after a
* breakpoint trap. Those that leave the PC set to the
* address of the trap instruction (i.e. pc532) will not
* define FIXUP_PC_AFTER_BREAK(), and therefore will just
* advance the PC. On machines that leave the PC set to
* the instruction after the trap, FIXUP_PC_AFTER_BREAK
* will be defined to back-up the PC, so that after the
* "first-time" part of the if statement below has run,
* the PC will be the same as it was on entry.
*
* On the first entry here, we expect that gdb is not yet
* listening to us, so just enter the interaction loop.
* After the debugger is "active" (connected) it will be
* waiting for a "signaled" message from us.
*/
if (kgdb_active == 0) {
if (!IS_BREAKPOINT_TRAP(type, 0)) {
/* No debugger active -- let trap handle this. */
if (db_trap_callback)
db_trap_callback(0);
return (0);
}
/* Make the PC point at the breakpoint... */
#ifdef FIXUP_PC_AFTER_BREAK
FIXUP_PC_AFTER_BREAK(regs);
#endif
/* ... and then advance past it. */
#ifdef PC_ADVANCE
PC_ADVANCE(regs);
#else
PC_REGS(regs) += BKPT_SIZE;
#endif
kgdb_active = 1;
} else {
/* Tell remote host that an exception has occurred. */
snprintf(buffer, sizeof(buffer), "S%02x", kgdb_signal(type));
kgdb_send(buffer);
}
/* Stick frame regs into our reg cache. */
kgdb_getregs(regs, gdb_regs);
/*
* Interact with gdb until it lets us go.
* If we cause a trap, resume here.
*/
(void)setjmp((kgdb_recover = &jmpbuf));
for (;;) {
kgdb_recv(buffer, sizeof(buffer));
switch (buffer[0]) {
default:
/* Unknown command. */
kgdb_send("");
continue;
case KGDB_SIGNAL:
/*
* if this command came from a running gdb,
* answer it -- the other guy has no way of
* knowing if we're in or out of this loop
* when he issues a "remote-signal".
*/
snprintf(buffer, sizeof(buffer), "S%02x",
kgdb_signal(type));
kgdb_send(buffer);
continue;
case KGDB_REG_R:
mem2hex(buffer, gdb_regs, sizeof(gdb_regs));
kgdb_send(buffer);
continue;
case KGDB_REG_W:
p = hex2mem(gdb_regs, buffer + 1, sizeof(gdb_regs));
if (p == NULL || *p != '\0')
kgdb_send("E01");
else {
kgdb_setregs(regs, gdb_regs);
kgdb_send("OK");
}
continue;
case KGDB_MEM_R:
p = buffer + 1;
addr = hex2i(&p);
if (*p++ != ',') {
kgdb_send("E02");
continue;
}
len = hex2i(&p);
if (*p != '\0') {
kgdb_send("E03");
continue;
}
if (len > sizeof(buffer) / 2) {
kgdb_send("E04");
continue;
}
if (kgdb_acc(addr, len) == 0) {
kgdb_send("E05");
continue;
}
char *ptr = (char *)buffer + sizeof(buffer) / 2;
db_read_bytes(addr, len, ptr);
mem2hex(buffer, ptr, len);
kgdb_send(buffer);
continue;
case KGDB_MEM_W:
p = buffer + 1;
addr = hex2i(&p);
if (*p++ != ',') {
kgdb_send("E06");
continue;
}
len = hex2i(&p);
if (*p++ != ':') {
kgdb_send("E07");
continue;
}
if (len > (sizeof(buffer) - (p - buffer))) {
kgdb_send("E08");
continue;
}
p = hex2mem(buffer, p, sizeof(buffer));
if (p == NULL) {
kgdb_send("E09");
continue;
}
if (kgdb_acc(addr, len) == 0) {
kgdb_send("E0A");
continue;
}
db_write_bytes(addr, len, (char *)buffer);
kgdb_send("OK");
continue;
case KGDB_DETACH:
case KGDB_KILL:
kgdb_active = 0;
printf("kgdb detached\n");
db_clear_single_step(regs);
kgdb_send("OK");
goto out;
case KGDB_CONT:
if (buffer[1]) {
p = buffer + 1;
addr = hex2i(&p);
if (*p) {
kgdb_send("E0B");
continue;
}
PC_REGS(regs) = addr;
DPRINTF(("kgdb: continuing at %08lx\n", addr));
} else {
DPRINTF((
"kgdb: continuing at old address %08lx\n",
(vaddr_t)PC_REGS(regs)));
}
db_clear_single_step(regs);
goto out;
case KGDB_STEP:
if (buffer[1]) {
p = buffer + 1;
addr = hex2i(&p);
if (*p) {
kgdb_send("E0B");
continue;
}
PC_REGS(regs) = addr;
}
db_set_single_step(regs);
goto out;
}
}
out:
if (db_trap_callback)
db_trap_callback(0);
kgdb_recover = 0;
return (1);
}