R_API int r_debug_esil_stepi (RDebug *d) {
RAnalOp op;
ut8 obuf[64];
int ret = 1;
dbg = d;
if (!ESIL) {
ESIL = r_anal_esil_new (R_TRUE);
// TODO setup something?
}
r_debug_reg_sync (dbg, R_REG_TYPE_GPR, R_FALSE);
opc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
dbg->iob.read_at (dbg->iob.io, opc, obuf, sizeof (obuf));
//dbg->iob.read_at (dbg->iob.io, npc, buf, sizeof (buf));
//dbg->anal->reg = dbg->reg; // hack
ESIL->cb.hook_mem_read = &esilbreak_mem_read;
ESIL->cb.hook_mem_write = &esilbreak_mem_write;
ESIL->cb.hook_reg_read = &esilbreak_reg_read;
ESIL->cb.hook_reg_write = &esilbreak_reg_write;
if (prestep) {
// required when a exxpression is like <= == ..
// otherwise it will stop at the next instruction
if (r_debug_step (dbg, 1)<1) {
eprintf ("Step failed\n");
return 0;
}
r_debug_reg_sync (dbg, R_REG_TYPE_GPR, R_FALSE);
// npc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
}
if (r_anal_op (dbg->anal, &op, opc, obuf, sizeof (obuf))) {
if (esilbreak_check_pc (dbg, opc)) {
eprintf ("STOP AT 0x%08"PFMT64x"\n", opc);
ret = 0;
} else {
r_anal_esil_set_pc (ESIL, opc);
eprintf ("0x%08"PFMT64x" %s\n", opc, R_STRBUF_SAFEGET (&op.esil));
(void)r_anal_esil_parse (ESIL, R_STRBUF_SAFEGET (&op.esil));
//r_anal_esil_dumpstack (ESIL);
r_anal_esil_stack_free (ESIL);
ret = 1;
}
}
if (!prestep) {
if (ret && !has_match) {
if (r_debug_step (dbg, 1)<1) {
eprintf ("Step failed\n");
return 0;
}
r_debug_reg_sync (dbg, R_REG_TYPE_GPR, R_FALSE);
// npc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
}
}
return ret;
}
R_API int r_debug_continue_until_optype(RDebug *dbg, int type, int over) {
int ret, n = 0;
ut64 pc, buf_pc = 0;
RAnalOp op;
ut8 buf[DBG_BUF_SIZE];
if (r_debug_is_dead (dbg)) {
return R_FALSE;
}
if (!dbg->anal || !dbg->reg) {
eprintf ("Undefined pointer at dbg->anal\n");
return R_FALSE;
}
r_debug_step (dbg, 1);
r_debug_reg_sync (dbg, R_REG_TYPE_GPR, R_FALSE);
// Initial refill
buf_pc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
dbg->iob.read_at (dbg->iob.io, buf_pc, buf, sizeof (buf));
// step first, we dont want to check current optype
for (;;) {
r_debug_reg_sync (dbg, R_REG_TYPE_GPR, R_FALSE);
pc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
// Try to keep the buffer full
if (pc - buf_pc > sizeof (buf)) {
buf_pc = pc;
dbg->iob.read_at (dbg->iob.io, buf_pc, buf, sizeof (buf));
}
// Analyze the opcode
if (!r_anal_op (dbg->anal, &op, pc, buf + (pc - buf_pc), sizeof (buf) - (pc - buf_pc))) {
eprintf ("Decode error at %"PFMT64x"\n", pc);
return R_FALSE;
}
if (op.type == type)
break;
// Step over and repeat
ret = over ?
r_debug_step_over (dbg, 1) :
r_debug_step (dbg, 1);
if (!ret) {
eprintf ("r_debug_step: failed\n");
break;
}
n++;
}
return n;
}
R_API int r_debug_step_over(RDebug *dbg, int steps) {
RAnalOp op;
ut8 buf[64];
int ret = -1;
if (r_debug_is_dead (dbg))
return R_FALSE;
if (dbg->h && dbg->h->step_over) {
if (steps<1) steps = 1;
while (steps--)
if (!dbg->h->step_over (dbg))
return R_FALSE;
return R_TRUE;
}
if (dbg->anal && dbg->reg) {
ut64 pc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
dbg->iob.read_at (dbg->iob.io, pc, buf, sizeof (buf));
r_anal_op (dbg->anal, &op, pc, buf, sizeof (buf));
if (op.type & R_ANAL_OP_TYPE_CALL
|| op.type & R_ANAL_OP_TYPE_UCALL) {
ut64 bpaddr = pc + op.length;
r_bp_add_sw (dbg->bp, bpaddr, 1, R_BP_PROT_EXEC);
ret = r_debug_continue (dbg);
r_bp_del (dbg->bp, bpaddr);
} else {
ret = r_debug_step (dbg, 1);
}
} else eprintf ("Undefined debugger backend\n");
return ret;
}
R_API int r_debug_continue_syscalls(RDebug *dbg, int *sc, int n_sc) {
int i, reg, ret = R_FALSE;
if (!dbg || !dbg->h || r_debug_is_dead (dbg))
return R_FALSE;
if (!dbg->h->contsc) {
/* user-level syscall tracing */
r_debug_continue_until_optype (dbg, R_ANAL_OP_TYPE_SWI, 0);
return show_syscall (dbg, "a0");
}
if (!r_debug_reg_sync (dbg, R_REG_TYPE_GPR, R_FALSE)) {
eprintf ("--> cannot read registers\n");
return -1;
}
{
int err;
reg = (int)r_debug_reg_get_err (dbg, "sn", &err);
if (err) {
eprintf ("Cannot find 'sn' register for current arch-os.\n");
return -1;
}
}
for (;;) {
if (r_cons_singleton()->breaked)
break;
#if __linux__
// step is needed to avoid dupped contsc results
r_debug_step (dbg, 1);
#endif
dbg->h->contsc (dbg, dbg->pid, 0); // TODO handle return value
// wait until continuation
r_debug_wait (dbg);
if (!r_debug_reg_sync (dbg, R_REG_TYPE_GPR, R_FALSE)) {
eprintf ("--> cannot sync regs, process is probably dead\n");
return -1;
}
reg = show_syscall (dbg, "sn");
if (n_sc == -1)
continue;
if (n_sc == 0) {
break;
}
for (i=0; i<n_sc; i++) {
if (sc[i] == reg)
return reg;
}
// TODO: must use r_core_cmd(as)..import code from rcore
}
return ret;
}
R_API int r_debug_continue_until(RDebug *dbg, ut64 addr) {
// TODO: use breakpoint+continue... more efficient
RRegItem *ripc = r_reg_get (dbg->reg, dbg->reg->name[R_REG_NAME_PC], R_REG_TYPE_GPR);
int n = 0;
ut64 pc = r_reg_get_value (dbg->reg, ripc);
while (pc != addr && !r_debug_is_dead (dbg)) {
r_debug_step (dbg, 1);
// TODO: obey breakpoints too?
/* TODO: check if the debugger stops at the right address */
pc = r_reg_get_value (dbg->reg, ripc);
n++;
}
return n;
}
/*
* replace breakpoints before we continue execution
*
* this is called from r_debug_step_hard or r_debug_continue_kill
*
* this is a trick process because of breakpoints/tracepoints.
*
* if a breakpoint was just hit, we need step over that instruction before
* allowing the caller to proceed as desired.
*
* if the user wants to step, the single step here does the job.
*/
static int r_debug_recoil(RDebug *dbg, RDebugRecoilMode rc_mode) {
/* if bp_addr is not set, we must not have actually hit a breakpoint */
if (!dbg->reason.bp_addr) {
return r_debug_bps_enable (dbg);
}
/* don't do anything if we already are recoiling */
if (dbg->recoil_mode != R_DBG_RECOIL_NONE) {
/* the first time recoil is called with swstep, we just need to
* look up the bp and step past it.
* the second time it's called, the new sw breakpoint should exist
* so we just restore all except what we originally hit and reset.
*/
if (dbg->swstep) {
if (!r_bp_restore_except (dbg->bp, true, dbg->reason.bp_addr)) {
return false;
}
return true;
}
/* otherwise, avoid recursion */
return true;
}
/* we have entered recoil! */
dbg->recoil_mode = rc_mode;
/* step over the place with the breakpoint and let the caller resume */
if (r_debug_step (dbg, 1) != 1) {
return false;
}
/* when stepping away from a breakpoint during recoil in stepping mode,
* the r_debug_bp_hit function tells us that it was called
* innapropriately by setting bp_addr back to zero. however, recoil_mode
* is still set. we use this condition to know not to proceed but
* pretend as if we had.
*/
if (!dbg->reason.bp_addr && dbg->recoil_mode == R_DBG_RECOIL_STEP) {
/* restore all sw breakpoints. we are about to step/continue so these need
* to be in place. */
if (!r_bp_restore (dbg->bp, true)) {
return false;
}
return true;
}
return r_debug_bps_enable (dbg);
}
R_API int r_debug_continue_until(struct r_debug_t *dbg, ut64 addr) {
// TODO: use breakpoint+continue... more efficient
int n = 0;
ut64 pc = 0;
if (r_debug_is_dead (dbg))
return R_FALSE;
do {
if (pc !=0) r_debug_step (dbg, 1);
n++;
} while (pc != addr && !r_debug_is_dead (dbg));
return n;
//struct r_debug_bp_t *bp = r_debug_bp_add (dbg, addr);
//int ret = r_debug_continue(dbg);
/* TODO: check if the debugger stops at the right address */
//r_debug_bp_del(dbg, bp);
//return -1;
}
R_API int r_debug_continue_kill(RDebug *dbg, int sig) {
ut64 pc;
int retwait, ret = R_FALSE;
if (!dbg)
return R_FALSE;
#if __WINDOWS__
r_cons_break(w32_break_process, dbg);
#endif
repeat:
if (r_debug_is_dead (dbg))
return R_FALSE;
if (dbg->h && dbg->h->cont) {
r_bp_restore (dbg->bp, R_TRUE); // set sw breakpoints
ret = dbg->h->cont (dbg, dbg->pid, dbg->tid, sig);
dbg->reason.signum = 0;
retwait = r_debug_wait (dbg);
#if __WINDOWS__
if (retwait != R_DEBUG_REASON_DEAD) {
ret = dbg->tid;
}
#endif
r_bp_restore (dbg->bp, R_FALSE); // unset sw breakpoints
//r_debug_recoil (dbg);
if (r_debug_recoil (dbg) || (dbg->reason.type == R_DEBUG_REASON_BREAKPOINT)) {
/* check if cur bp demands tracing or not */
pc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
RBreakpointItem *b = r_bp_get_at (dbg->bp, pc);
if (b) {
/* check if cur bp demands tracing or not */
if (b->trace) {
eprintf("hit tracepoit at: %"PFMT64x"\n",pc);
} else {
eprintf("hit breakpoint at: %"PFMT64x"\n",pc);
}
if (dbg->trace->enabled)
r_debug_trace_pc (dbg);
// TODO: delegate this to RCore.bphit(RCore, RBreakopintItem)
if (dbg->corebind.core && dbg->corebind.bphit) {
dbg->corebind.bphit (dbg->corebind.core, b);
}
if (b->trace) {
r_debug_step (dbg, 1);
goto repeat;
}
}
}
#if 0
#if __UNIX__
/* XXX Uh? */
if (dbg->stop_all_threads && dbg->pid>0)
r_sandbox_kill (dbg->pid, SIGSTOP);
#endif
#endif
r_debug_select (dbg, dbg->pid, ret);
sig = 0; // clear continuation after signal if needed
if (retwait == R_DEBUG_REASON_SIGNAL && dbg->reason.signum != -1) {
int what = r_debug_signal_what (dbg, dbg->reason.signum);
if (what & R_DBG_SIGNAL_CONT) {
sig = dbg->reason.signum;
eprintf ("Continue into the signal %d handler\n", sig);
goto repeat;
} else if (what & R_DBG_SIGNAL_SKIP) {
// skip signal. requires skipping one instruction
ut8 buf[64];
RAnalOp op = {0};
ut64 pc = r_debug_reg_get (dbg, "pc");
dbg->iob.read_at (dbg->iob.io, pc, buf, sizeof (buf));
r_anal_op (dbg->anal, &op, pc, buf, sizeof (buf));
if (op.size>0) {
const char *signame = r_debug_signal_resolve_i (dbg, dbg->reason.signum);
r_debug_reg_set (dbg, "pc", pc+op.size);
eprintf ("Skip signal %d handler %s\n",
dbg->reason.signum, signame);
goto repeat;
} else {
ut64 pc = r_debug_reg_get (dbg, "pc");
eprintf ("Stalled with an exception at 0x%08"PFMT64x"\n", pc);
}
}
}
}
return ret;
}
R_API int r_debug_step_over(RDebug *dbg, int steps) {
RAnalOp op;
ut64 buf_pc, pc;
ut8 buf[DBG_BUF_SIZE];
int i;
if (r_debug_is_dead (dbg))
return R_FALSE;
if (steps < 1)
steps = 1;
if (dbg->h && dbg->h->step_over) {
for (i = 0; i < steps; i++)
if (!dbg->h->step_over (dbg))
return R_FALSE;
return i;
}
if (!dbg->anal || !dbg->reg)
return R_FALSE;
// Initial refill
buf_pc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
dbg->iob.read_at (dbg->iob.io, buf_pc, buf, sizeof (buf));
for (i = 0; i < steps; i++) {
pc = r_debug_reg_get (dbg, dbg->reg->name[R_REG_NAME_PC]);
// Try to keep the buffer full
if (pc - buf_pc > sizeof (buf)) {
buf_pc = pc;
dbg->iob.read_at (dbg->iob.io, buf_pc, buf, sizeof (buf));
}
// Analyze the opcode
if (!r_anal_op (dbg->anal, &op, pc, buf + (pc - buf_pc), sizeof (buf) - (pc - buf_pc))) {
eprintf ("Decode error at %"PFMT64x"\n", pc);
return R_FALSE;
}
// Skip over all the subroutine calls
if (op.type == R_ANAL_OP_TYPE_CALL ||
op.type == R_ANAL_OP_TYPE_CCALL ||
op.type == R_ANAL_OP_TYPE_UCALL ||
op.type == R_ANAL_OP_TYPE_UCCALL) {
// Use op.fail here instead of pc+op.size to enforce anal backends to fill in this field
if (!r_debug_continue_until (dbg, op.fail)) {
eprintf ("Could not step over call @ 0x%"PFMT64x"\n", pc);
return R_FALSE;
}
} else if ((op.prefix & (R_ANAL_OP_PREFIX_REP | R_ANAL_OP_PREFIX_REPNE | R_ANAL_OP_PREFIX_LOCK))) {
//eprintf ("REP: skip to next instruction...\n");
if (!r_debug_continue_until (dbg, pc+op.size)) {
eprintf ("step over failed over rep\n");
return R_FALSE;
}
} else r_debug_step (dbg, 1);
}
return i;
}
