/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2000-2012. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_process.h"
#include "beam_load.h"
#include "bif.h"
#include "error.h"
#include "erl_binary.h"
#include "beam_bp.h"
#include "erl_term.h"
/* *************************************************************************
** Macros
*/
/*
** Memory allocation macros
*/
/* Breakpoint data */
#define Alloc(SZ) erts_alloc(ERTS_ALC_T_BPD, (SZ))
#define ReAlloc(P, SIZ) erts_realloc(ERTS_ALC_T_BPD, (P), (SZ))
#define Free(P) erts_free(ERTS_ALC_T_BPD, (P))
#if defined(ERTS_ENABLE_LOCK_CHECK) && defined(ERTS_SMP)
# define ERTS_SMP_REQ_PROC_MAIN_LOCK(P) \
if ((P)) erts_proc_lc_require_lock((P), ERTS_PROC_LOCK_MAIN)
# define ERTS_SMP_UNREQ_PROC_MAIN_LOCK(P) \
if ((P)) erts_proc_lc_unrequire_lock((P), ERTS_PROC_LOCK_MAIN)
#else
# define ERTS_SMP_REQ_PROC_MAIN_LOCK(P)
# define ERTS_SMP_UNREQ_PROC_MAIN_LOCK(P)
#endif
#define ERTS_BPF_LOCAL_TRACE 0x01
#define ERTS_BPF_META_TRACE 0x02
#define ERTS_BPF_COUNT 0x04
#define ERTS_BPF_COUNT_ACTIVE 0x08
#define ERTS_BPF_DEBUG 0x10
#define ERTS_BPF_TIME_TRACE 0x20
#define ERTS_BPF_TIME_TRACE_ACTIVE 0x40
#define ERTS_BPF_GLOBAL_TRACE 0x80
#define ERTS_BPF_ALL 0xFF
extern BeamInstr beam_return_to_trace[1]; /* OpCode(i_return_to_trace) */
extern BeamInstr beam_return_trace[1]; /* OpCode(i_return_trace) */
extern BeamInstr beam_exception_trace[1]; /* OpCode(i_exception_trace) */
extern BeamInstr beam_return_time_trace[1]; /* OpCode(i_return_time_trace) */
erts_smp_atomic32_t erts_active_bp_index;
erts_smp_atomic32_t erts_staging_bp_index;
/* *************************************************************************
** Local prototypes
*/
/*
** Helpers
*/
static Eterm do_call_trace(Process* c_p, BeamInstr* I, Eterm* reg,
int local, Binary* ms, Eterm tracer_pid);
static void set_break(BpFunctions* f, Binary *match_spec, Uint break_flags,
enum erts_break_op count_op, Eterm tracer_pid);
static void set_function_break(BeamInstr *pc,
Binary *match_spec,
Uint break_flags,
enum erts_break_op count_op,
Eterm tracer_pid);
static void clear_break(BpFunctions* f, Uint break_flags);
static int clear_function_break(BeamInstr *pc, Uint break_flags);
static BpDataTime* get_time_break(BeamInstr *pc);
static GenericBpData* check_break(BeamInstr *pc, Uint break_flags);
static void bp_time_diff(bp_data_time_item_t *item,
process_breakpoint_time_t *pbt,
Uint ms, Uint s, Uint us);
static void bp_meta_unref(BpMetaPid* bmp);
static void bp_count_unref(BpCount* bcp);
static void bp_time_unref(BpDataTime* bdt);
static void consolidate_bp_data(Module* modp, BeamInstr* pc, int local);
static void uninstall_breakpoint(BeamInstr* pc);
/* bp_hash */
#define BP_TIME_ADD(pi0, pi1) \
do { \
Uint r; \
(pi0)->count += (pi1)->count; \
(pi0)->s_time += (pi1)->s_time; \
(pi0)->us_time += (pi1)->us_time; \
r = (pi0)->us_time / 1000000; \
(pi0)->s_time += r; \
(pi0)->us_time = (pi0)->us_time % 1000000; \
} while(0)
static void bp_hash_init(bp_time_hash_t *hash, Uint n);
static void bp_hash_rehash(bp_time_hash_t *hash, Uint n);
static ERTS_INLINE bp_data_time_item_t * bp_hash_get(bp_time_hash_t *hash, bp_data_time_item_t *sitem);
static ERTS_INLINE bp_data_time_item_t * bp_hash_put(bp_time_hash_t *hash, bp_data_time_item_t *sitem);
static void bp_hash_delete(bp_time_hash_t *hash);
/* *************************************************************************
** External interfaces
*/
void
erts_bp_init(void) {
erts_smp_atomic32_init_nob(&erts_active_bp_index, 0);
erts_smp_atomic32_init_nob(&erts_staging_bp_index, 1);
}
void
erts_bp_match_functions(BpFunctions* f, Eterm mfa[3], int specified)
{
ErtsCodeIndex code_ix = erts_active_code_ix();
Uint max_funcs = 0;
int current;
int max_modules = module_code_size(code_ix);
int num_modules = 0;
Module* modp;
Module** module;
Uint i;
module = (Module **) Alloc(max_modules*sizeof(Module *));
num_modules = 0;
for (current = 0; current < max_modules; current++) {
modp = module_code(current, code_ix);
if (modp->curr.code) {
max_funcs += modp->curr.code[MI_NUM_FUNCTIONS];
module[num_modules++] = modp;
}
}
f->matching = (BpFunction *) Alloc(max_funcs*sizeof(BpFunction));
i = 0;
for (current = 0; current < num_modules; current++) {
BeamInstr** code_base = (BeamInstr **) module[current]->curr.code;
BeamInstr* code;
Uint num_functions = (Uint)(UWord) code_base[MI_NUM_FUNCTIONS];
Uint fi;
if (specified > 0) {
if (mfa[0] != make_atom(module[current]->module)) {
/* Wrong module name */
continue;
}
}
for (fi = 0; fi < num_functions; fi++) {
BeamInstr* pc;
int wi;
code = code_base[MI_FUNCTIONS+fi];
ASSERT(code[0] == (BeamInstr) BeamOp(op_i_func_info_IaaI));
pc = code+5;
if (erts_is_native_break(pc)) {
continue;
}
if (is_nil(code[3])) { /* Ignore BIF stub */
continue;
}
for (wi = 0;
wi < specified && (Eterm) code[2+wi] == mfa[wi];
wi++) {
/* Empty loop body */
}
if (wi == specified) {
/* Store match */
f->matching[i].pc = pc;
f->matching[i].mod = module[current];
i++;
}
}
}
f->matched = i;
Free(module);
}
void
erts_bp_match_export(BpFunctions* f, Eterm mfa[3], int specified)
{
ErtsCodeIndex code_ix = erts_active_code_ix();
int i;
int num_exps = export_list_size(code_ix);
int ne;
f->matching = (BpFunction *) Alloc(num_exps*sizeof(BpFunction));
ne = 0;
for (i = 0; i < num_exps; i++) {
Export* ep = export_list(i, code_ix);
BeamInstr* pc;
int j;
for (j = 0; j < specified && mfa[j] == ep->code[j]; j++) {
/* Empty loop body */
}
if (j < specified) {
continue;
}
pc = ep->code+3;
if (ep->addressv[code_ix] == pc) {
if ((*pc == (BeamInstr) em_apply_bif ||
*pc == (BeamInstr) em_call_error_handler)) {
continue;
}
ASSERT(*pc == (BeamInstr) BeamOp(op_i_generic_breakpoint));
} else if (erts_is_native_break(ep->addressv[code_ix])) {
continue;
}
f->matching[ne].pc = pc;
f->matching[ne].mod = erts_get_module(ep->code[0], code_ix);
ne++;
}
f->matched = ne;
}
void
erts_bp_free_matched_functions(BpFunctions* f)
{
Free(f->matching);
}
void
erts_consolidate_bp_data(BpFunctions* f, int local)
{
BpFunction* fs = f->matching;
Uint i;
Uint n = f->matched;
ERTS_SMP_LC_ASSERT(erts_has_code_write_permission());
for (i = 0; i < n; i++) {
consolidate_bp_data(fs[i].mod, fs[i].pc, local);
}
}
void
erts_consolidate_bif_bp_data(void)
{
int i;
ERTS_SMP_LC_ASSERT(erts_has_code_write_permission());
for (i = 0; i < BIF_SIZE; i++) {
Export *ep = bif_export[i];
consolidate_bp_data(0, ep->code+3, 0);
}
}
static void
consolidate_bp_data(Module* modp, BeamInstr* pc, int local)
{
GenericBp* g = (GenericBp *) pc[-4];
GenericBpData* src;
GenericBpData* dst;
Uint flags;
if (g == 0) {
return;
}
src = &g->data[erts_active_bp_ix()];
dst = &g->data[erts_staging_bp_ix()];
/*
* The contents of the staging area may be out of date.
* Decrement all reference pointers.
*/
flags = dst->flags;
if (flags & (ERTS_BPF_LOCAL_TRACE|ERTS_BPF_GLOBAL_TRACE)) {
MatchSetUnref(dst->local_ms);
}
if (flags & ERTS_BPF_META_TRACE) {
bp_meta_unref(dst->meta_pid);
MatchSetUnref(dst->meta_ms);
}
if (flags & ERTS_BPF_COUNT) {
bp_count_unref(dst->count);
}
if (flags & ERTS_BPF_TIME_TRACE) {
bp_time_unref(dst->time);
}
/*
* If all flags are zero, deallocate all breakpoint data.
*/
flags = dst->flags = src->flags;
if (flags == 0) {
if (modp) {
if (local) {
modp->curr.num_breakpoints--;
} else {
modp->curr.num_traced_exports--;
}
ASSERT(modp->curr.num_breakpoints >= 0);
ASSERT(modp->curr.num_traced_exports >= 0);
ASSERT(*pc != (BeamInstr) BeamOp(op_i_generic_breakpoint));
}
pc[-4] = 0;
Free(g);
return;
}
/*
* Copy the active data to the staging area (making it ready
* for the next time it will be used).
*/
if (flags & (ERTS_BPF_LOCAL_TRACE|ERTS_BPF_GLOBAL_TRACE)) {
dst->local_ms = src->local_ms;
MatchSetRef(dst->local_ms);
}
if (flags & ERTS_BPF_META_TRACE) {
dst->meta_pid = src->meta_pid;
erts_refc_inc(&dst->meta_pid->refc, 1);
dst->meta_ms = src->meta_ms;
MatchSetRef(dst->meta_ms);
}
if (flags & ERTS_BPF_COUNT) {
dst->count = src->count;
erts_refc_inc(&dst->count->refc, 1);
}
if (flags & ERTS_BPF_TIME_TRACE) {
dst->time = src->time;
erts_refc_inc(&dst->time->refc, 1);
ASSERT(dst->time->hash);
}
}
void
erts_commit_staged_bp(void)
{
ErtsBpIndex staging = erts_staging_bp_ix();
ErtsBpIndex active = erts_active_bp_ix();
erts_smp_atomic32_set_nob(&erts_active_bp_index, staging);
erts_smp_atomic32_set_nob(&erts_staging_bp_index, active);
}
void
erts_install_breakpoints(BpFunctions* f)
{
Uint i;
Uint n = f->matched;
BeamInstr br = (BeamInstr) BeamOp(op_i_generic_breakpoint);
for (i = 0; i < n; i++) {
BeamInstr* pc = f->matching[i].pc;
GenericBp* g = (GenericBp *) pc[-4];
if (*pc != br && g) {
Module* modp = f->matching[i].mod;
/*
* The breakpoint must be disabled in the active data
* (it will enabled later by switching bp indices),
* and enabled in the staging data.
*/
ASSERT(g->data[erts_active_bp_ix()].flags == 0);
ASSERT(g->data[erts_staging_bp_ix()].flags != 0);
/*
* The following write is not protected by any lock. We
* assume that the hardware guarantees that a write of an
* aligned word-size (or half-word) writes is atomic
* (i.e. that other processes executing this code will not
* see a half pointer).
*/
*pc = br;
modp->curr.num_breakpoints++;
}
}
}
void
erts_uninstall_breakpoints(BpFunctions* f)
{
Uint i;
Uint n = f->matched;
for (i = 0; i < n; i++) {
BeamInstr* pc = f->matching[i].pc;
uninstall_breakpoint(pc);
}
}
static void
uninstall_breakpoint(BeamInstr* pc)
{
if (*pc == (BeamInstr) BeamOp(op_i_generic_breakpoint)) {
GenericBp* g = (GenericBp *) pc[-4];
if (g->data[erts_active_bp_ix()].flags == 0) {
/*
* The following write is not protected by any lock. We
* assume that the hardware guarantees that a write of an
* aligned word-size (or half-word) writes is atomic
* (i.e. that other processes executing this code will not
* see a half pointer).
*/
*pc = g->orig_instr;
}
}
}
void
erts_set_trace_break(BpFunctions* f, Binary *match_spec)
{
set_break(f, match_spec, ERTS_BPF_LOCAL_TRACE, 0, am_true);
}
void
erts_set_mtrace_break(BpFunctions* f, Binary *match_spec, Eterm tracer_pid)
{
set_break(f, match_spec, ERTS_BPF_META_TRACE, 0, tracer_pid);
}
void
erts_set_call_trace_bif(BeamInstr *pc, Binary *match_spec, int local)
{
Uint flags = local ? ERTS_BPF_LOCAL_TRACE : ERTS_BPF_GLOBAL_TRACE;
set_function_break(pc, match_spec, flags, 0, NIL);
}
void
erts_set_mtrace_bif(BeamInstr *pc, Binary *match_spec, Eterm tracer_pid)
{
set_function_break(pc, match_spec, ERTS_BPF_META_TRACE, 0, tracer_pid);
}
void
erts_set_time_trace_bif(BeamInstr *pc, enum erts_break_op count_op)
{
set_function_break(pc, NULL,
ERTS_BPF_TIME_TRACE|ERTS_BPF_TIME_TRACE_ACTIVE,
count_op, NIL);
}
void
erts_clear_time_trace_bif(BeamInstr *pc) {
clear_function_break(pc, ERTS_BPF_TIME_TRACE|ERTS_BPF_TIME_TRACE_ACTIVE);
}
void
erts_set_debug_break(BpFunctions* f) {
set_break(f, NULL, ERTS_BPF_DEBUG, 0, NIL);
}
void
erts_set_count_break(BpFunctions* f, enum erts_break_op count_op)
{
set_break(f, 0, ERTS_BPF_COUNT|ERTS_BPF_COUNT_ACTIVE,
count_op, NIL);
}
void
erts_set_time_break(BpFunctions* f, enum erts_break_op count_op)
{
set_break(f, 0, ERTS_BPF_TIME_TRACE|ERTS_BPF_TIME_TRACE_ACTIVE,
count_op, NIL);
}
void
erts_clear_trace_break(BpFunctions* f)
{
clear_break(f, ERTS_BPF_LOCAL_TRACE);
}
void
erts_clear_call_trace_bif(BeamInstr *pc, int local)
{
GenericBp* g = (GenericBp *) pc[-4];
if (g) {
Uint flags = local ? ERTS_BPF_LOCAL_TRACE : ERTS_BPF_GLOBAL_TRACE;
if (g->data[erts_staging_bp_ix()].flags & flags) {
clear_function_break(pc, flags);
}
}
}
void
erts_clear_mtrace_break(BpFunctions* f)
{
clear_break(f, ERTS_BPF_META_TRACE);
}
void
erts_clear_mtrace_bif(BeamInstr *pc)
{
clear_function_break(pc, ERTS_BPF_META_TRACE);
}
void
erts_clear_debug_break(BpFunctions* f)
{
ERTS_SMP_LC_ASSERT(erts_smp_thr_progress_is_blocking());
clear_break(f, ERTS_BPF_DEBUG);
}
void
erts_clear_count_break(BpFunctions* f)
{
clear_break(f, ERTS_BPF_COUNT|ERTS_BPF_COUNT_ACTIVE);
}
void
erts_clear_time_break(BpFunctions* f)
{
clear_break(f, ERTS_BPF_TIME_TRACE|ERTS_BPF_TIME_TRACE_ACTIVE);
}
void
erts_clear_all_breaks(BpFunctions* f)
{
clear_break(f, ERTS_BPF_ALL);
}
int
erts_clear_module_break(Module *modp) {
BeamInstr** code_base;
Uint n;
Uint i;
ERTS_SMP_LC_ASSERT(erts_smp_thr_progress_is_blocking());
ASSERT(modp);
code_base = (BeamInstr **) modp->curr.code;
if (code_base == NULL) {
return 0;
}
n = (Uint)(UWord) code_base[MI_NUM_FUNCTIONS];
for (i = 0; i < n; ++i) {
BeamInstr* pc;
pc = code_base[MI_FUNCTIONS+i] + 5;
if (erts_is_native_break(pc)) {
continue;
}
clear_function_break(pc, ERTS_BPF_ALL);
}
erts_commit_staged_bp();
for (i = 0; i < n; ++i) {
BeamInstr* pc;
pc = code_base[MI_FUNCTIONS+i] + 5;
if (erts_is_native_break(pc)) {
continue;
}
uninstall_breakpoint(pc);
consolidate_bp_data(modp, pc, 1);
ASSERT(pc[-4] == 0);
}
return n;
}
void
erts_clear_export_break(Module* modp, BeamInstr* pc)
{
ERTS_SMP_LC_ASSERT(erts_smp_thr_progress_is_blocking());
clear_function_break(pc, ERTS_BPF_ALL);
erts_commit_staged_bp();
*pc = (BeamInstr) 0;
consolidate_bp_data(modp, pc, 0);
ASSERT(pc[-4] == 0);
}
BeamInstr
erts_generic_breakpoint(Process* c_p, BeamInstr* I, Eterm* reg)
{
GenericBp* g;
GenericBpData* bp;
Uint bp_flags;
ErtsBpIndex ix = erts_active_bp_ix();
g = (GenericBp *) I[-4];
bp = &g->data[ix];
bp_flags = bp->flags;
ASSERT((bp_flags & ~ERTS_BPF_ALL) == 0);
if (bp_flags & (ERTS_BPF_LOCAL_TRACE|
ERTS_BPF_GLOBAL_TRACE|
ERTS_BPF_TIME_TRACE_ACTIVE) &&
!IS_TRACED_FL(c_p, F_TRACE_CALLS)) {
bp_flags &= ~(ERTS_BPF_LOCAL_TRACE|
ERTS_BPF_GLOBAL_TRACE|
ERTS_BPF_TIME_TRACE|
ERTS_BPF_TIME_TRACE_ACTIVE);
if (bp_flags == 0) { /* Quick exit */
return g->orig_instr;
}
}
if (bp_flags & ERTS_BPF_LOCAL_TRACE) {
ASSERT((bp_flags & ERTS_BPF_GLOBAL_TRACE) == 0);
(void) do_call_trace(c_p, I, reg, 1, bp->local_ms, am_true);
} else if (bp_flags & ERTS_BPF_GLOBAL_TRACE) {
(void) do_call_trace(c_p, I, reg, 0, bp->local_ms, am_true);
}
if (bp_flags & ERTS_BPF_META_TRACE) {
Eterm old_pid;
Eterm new_pid;
old_pid = (Eterm) erts_smp_atomic_read_nob(&bp->meta_pid->pid);
new_pid = do_call_trace(c_p, I, reg, 1, bp->meta_ms, old_pid);
if (new_pid != old_pid) {
erts_smp_atomic_set_nob(&bp->meta_pid->pid, new_pid);
}
}
if (bp_flags & ERTS_BPF_COUNT_ACTIVE) {
erts_smp_atomic_inc_nob(&bp->count->acount);
}
if (bp_flags & ERTS_BPF_TIME_TRACE_ACTIVE) {
Eterm w;
erts_trace_time_call(c_p, I, bp->time);
w = (BeamInstr) *c_p->cp;
if (! (w == (BeamInstr) BeamOp(op_i_return_time_trace) ||
w == (BeamInstr) BeamOp(op_return_trace) ||
w == (BeamInstr) BeamOp(op_i_return_to_trace)) ) {
Eterm* E = c_p->stop;
ASSERT(c_p->htop <= E && E <= c_p->hend);
if (E - 2 < c_p->htop) {
(void) erts_garbage_collect(c_p, 2, reg, I[-1]);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
}
E = c_p->stop;
ASSERT(c_p->htop <= E && E <= c_p->hend);
E -= 2;
E[0] = make_cp(I);
E[1] = make_cp(c_p->cp); /* original return address */
c_p->cp = beam_return_time_trace;
c_p->stop = E;
}
}
if (bp_flags & ERTS_BPF_DEBUG) {
return (BeamInstr) BeamOp(op_i_debug_breakpoint);
} else {
return g->orig_instr;
}
}
/*
* Entry point called by the trace wrap functions in erl_bif_wrap.c
*
* The trace wrap functions are themselves called through the export
* entries instead of the original BIF functions.
*/
Eterm
erts_bif_trace(int bif_index, Process* p, Eterm* args, BeamInstr* I)
{
Eterm result;
Eterm (*func)(Process*, Eterm*, BeamInstr*);
Export* ep = bif_export[bif_index];
Uint32 flags = 0, flags_meta = 0;
Eterm meta_tracer_pid = NIL;
int applying = (I == &(ep->code[3])); /* Yup, the apply code for a bif
* is actually in the
* export entry */
BeamInstr *cp = p->cp;
GenericBp* g;
GenericBpData* bp = NULL;
Uint bp_flags = 0;
ERTS_SMP_CHK_HAVE_ONLY_MAIN_PROC_LOCK(p);
g = (GenericBp *) ep->fake_op_func_info_for_hipe[1];
if (g) {
bp = &g->data[erts_active_bp_ix()];
bp_flags = bp->flags;
}
/*
* Make continuation pointer OK, it is not during direct BIF calls,
* but it is correct during apply of bif.
*/
if (!applying) {
p->cp = I;
}
if (bp_flags & (ERTS_BPF_LOCAL_TRACE|ERTS_BPF_GLOBAL_TRACE) &&
IS_TRACED_FL(p, F_TRACE_CALLS)) {
int local = !!(bp_flags & ERTS_BPF_LOCAL_TRACE);
flags = erts_call_trace(p, ep->code, bp->local_ms, args,
local, &ERTS_TRACER_PROC(p));
}
if (bp_flags & ERTS_BPF_META_TRACE) {
Eterm tpid1, tpid2;
tpid1 = tpid2 =
(Eterm) erts_smp_atomic_read_nob(&bp->meta_pid->pid);
flags_meta = erts_call_trace(p, ep->code, bp->meta_ms, args,
0, &tpid2);
meta_tracer_pid = tpid2;
if (tpid1 != tpid2) {
erts_smp_atomic_set_nob(&bp->meta_pid->pid, tpid2);
}
}
if (bp_flags & ERTS_BPF_TIME_TRACE_ACTIVE &&
IS_TRACED_FL(p, F_TRACE_CALLS)) {
BeamInstr *pc = (BeamInstr *)ep->code+3;
erts_trace_time_call(p, pc, bp->time);
}
/* Restore original continuation pointer (if changed). */
p->cp = cp;
func = bif_table[bif_index].f;
result = func(p, args, I);
if (applying && (flags & MATCH_SET_RETURN_TO_TRACE)) {
BeamInstr i_return_trace = beam_return_trace[0];
BeamInstr i_return_to_trace = beam_return_to_trace[0];
BeamInstr i_return_time_trace = beam_return_time_trace[0];
Eterm *cpp;
/* Maybe advance cp to skip trace stack frames */
for (cpp = p->stop; ; cp = cp_val(*cpp++)) {
if (*cp == i_return_trace) {
/* Skip stack frame variables */
while (is_not_CP(*cpp)) cpp++;
cpp += 2; /* Skip return_trace parameters */
} else if (*cp == i_return_time_trace) {
/* Skip stack frame variables */
while (is_not_CP(*cpp)) cpp++;
cpp += 1; /* Skip return_time_trace parameters */
} else if (*cp == i_return_to_trace) {
/* A return_to trace message is going to be generated
* by normal means, so we do not have to.
*/
cp = NULL;
break;
} else break;
}
}
/* Try to get these in the order
* they usually appear in normal code... */
if (is_non_value(result)) {
Uint reason = p->freason;
if (reason != TRAP) {
Eterm class;
Eterm value = p->fvalue;
DeclareTmpHeapNoproc(nocatch,3);
UseTmpHeapNoproc(3);
/* Expand error value like in handle_error() */
if (reason & EXF_ARGLIST) {
Eterm *tp;
ASSERT(is_tuple(value));
tp = tuple_val(value);
value = tp[1];
}
if ((reason & EXF_THROWN) && (p->catches <= 0)) {
value = TUPLE2(nocatch, am_nocatch, value);
reason = EXC_ERROR;
}
/* Note: expand_error_value() could theoretically
* allocate on the heap, but not for any error
* returned by a BIF, and it would do no harm,
* just be annoying.
*/
value = expand_error_value(p, reason, value);
class = exception_tag[GET_EXC_CLASS(reason)];
if (flags_meta & MATCH_SET_EXCEPTION_TRACE) {
erts_trace_exception(p, ep->code, class, value,
&meta_tracer_pid);
}
if (flags & MATCH_SET_EXCEPTION_TRACE) {
erts_trace_exception(p, ep->code, class, value,
&ERTS_TRACER_PROC(p));
}
if ((flags & MATCH_SET_RETURN_TO_TRACE) && p->catches > 0) {
/* can only happen if(local)*/
Eterm *ptr = p->stop;
ASSERT(is_CP(*ptr));
ASSERT(ptr <= STACK_START(p));
/* Search the nearest stack frame for a catch */
while (++ptr < STACK_START(p)) {
if (is_CP(*ptr)) break;
if (is_catch(*ptr)) {
if (applying) {
/* Apply of BIF, cp is in calling function */
if (cp) erts_trace_return_to(p, cp);
} else {
/* Direct bif call, I points into
* calling function */
erts_trace_return_to(p, I);
}
}
}
}
UnUseTmpHeapNoproc(3);
if ((flags_meta|flags) & MATCH_SET_EXCEPTION_TRACE) {
erts_smp_proc_lock(p, ERTS_PROC_LOCKS_ALL_MINOR);
ERTS_TRACE_FLAGS(p) |= F_EXCEPTION_TRACE;
erts_smp_proc_unlock(p, ERTS_PROC_LOCKS_ALL_MINOR);
}
}
} else {
if (flags_meta & MATCH_SET_RX_TRACE) {
erts_trace_return(p, ep->code, result, &meta_tracer_pid);
}
/* MATCH_SET_RETURN_TO_TRACE cannot occur if(meta) */
if (flags & MATCH_SET_RX_TRACE) {
erts_trace_return(p, ep->code, result, &ERTS_TRACER_PROC(p));
}
if (flags & MATCH_SET_RETURN_TO_TRACE) {
/* can only happen if(local)*/
if (applying) {
/* Apply of BIF, cp is in calling function */
if (cp) erts_trace_return_to(p, cp);
} else {
/* Direct bif call, I points into calling function */
erts_trace_return_to(p, I);
}
}
}
ERTS_SMP_CHK_HAVE_ONLY_MAIN_PROC_LOCK(p);
return result;
}
static Eterm
do_call_trace(Process* c_p, BeamInstr* I, Eterm* reg,
int local, Binary* ms, Eterm tracer_pid)
{
Eterm* cpp;
int return_to_trace = 0;
BeamInstr w;
BeamInstr *cp_save;
Uint32 flags;
Uint need = 0;
Eterm* E = c_p->stop;
w = *c_p->cp;
if (w == (BeamInstr) BeamOp(op_return_trace)) {
cpp = &E[2];
} else if (w == (BeamInstr) BeamOp(op_i_return_to_trace)) {
return_to_trace = 1;
cpp = &E[0];
} else if (w == (BeamInstr) BeamOp(op_i_return_time_trace)) {
cpp = &E[0];
} else {
cpp = NULL;
}
if (cpp) {
for (;;) {
BeamInstr w = *cp_val(*cpp);
if (w == (BeamInstr) BeamOp(op_return_trace)) {
cpp += 3;
} else if (w == (BeamInstr) BeamOp(op_i_return_to_trace)) {
return_to_trace = 1;
cpp += 1;
} else if (w == (BeamInstr) BeamOp(op_i_return_time_trace)) {
cpp += 2;
} else {
break;
}
}
cp_save = c_p->cp;
c_p->cp = (BeamInstr *) cp_val(*cpp);
ASSERT(is_CP(*cpp));
}
ERTS_SMP_UNREQ_PROC_MAIN_LOCK(c_p);
flags = erts_call_trace(c_p, I-3, ms, reg, local, &tracer_pid);
ERTS_SMP_REQ_PROC_MAIN_LOCK(c_p);
if (cpp) {
c_p->cp = cp_save;
}
ASSERT(!ERTS_PROC_IS_EXITING(c_p));
if ((flags & MATCH_SET_RETURN_TO_TRACE) && !return_to_trace) {
need += 1;
}
if (flags & MATCH_SET_RX_TRACE) {
need += 3;
}
if (need) {
ASSERT(c_p->htop <= E && E <= c_p->hend);
if (E - need < c_p->htop) {
(void) erts_garbage_collect(c_p, need, reg, I[-1]);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
E = c_p->stop;
}
}
if (flags & MATCH_SET_RETURN_TO_TRACE && !return_to_trace) {
E -= 1;
ASSERT(c_p->htop <= E && E <= c_p->hend);
E[0] = make_cp(c_p->cp);
c_p->cp = beam_return_to_trace;
}
if (flags & MATCH_SET_RX_TRACE) {
E -= 3;
ASSERT(c_p->htop <= E && E <= c_p->hend);
ASSERT(is_CP((Eterm) (UWord) (I - 3)));
ASSERT(am_true == tracer_pid ||
is_internal_pid(tracer_pid) || is_internal_port(tracer_pid));
E[2] = make_cp(c_p->cp);
E[1] = tracer_pid;
E[0] = make_cp(I - 3); /* We ARE at the beginning of an
instruction,
the funcinfo is above i. */
c_p->cp = (flags & MATCH_SET_EXCEPTION_TRACE) ?
beam_exception_trace : beam_return_trace;
erts_smp_proc_lock(c_p, ERTS_PROC_LOCKS_ALL_MINOR);
ERTS_TRACE_FLAGS(c_p) |= F_EXCEPTION_TRACE;
erts_smp_proc_unlock(c_p, ERTS_PROC_LOCKS_ALL_MINOR);
}
c_p->stop = E;
return tracer_pid;
}
void
erts_trace_time_call(Process* c_p, BeamInstr* I, BpDataTime* bdt)
{
Uint ms,s,us;
process_breakpoint_time_t *pbt = NULL;
bp_data_time_item_t sitem, *item = NULL;
bp_time_hash_t *h = NULL;
BpDataTime *pbdt = NULL;
ASSERT(c_p);
ASSERT(erts_smp_atomic32_read_acqb(&c_p->state) & ERTS_PSFLG_RUNNING);
/* get previous timestamp and breakpoint
* from the process psd */
pbt = ERTS_PROC_GET_CALL_TIME(c_p);
get_sys_now(&ms, &s, &us);
/* get pbt
* timestamp = t0
* lookup bdt from code
* set ts0 to pbt
* add call count here?
*/
if (pbt == 0) {
/* First call of process to instrumented function */
pbt = Alloc(sizeof(process_breakpoint_time_t));
(void) ERTS_PROC_SET_CALL_TIME(c_p, ERTS_PROC_LOCK_MAIN, pbt);
} else {
ASSERT(pbt->pc);
/* add time to previous code */
bp_time_diff(&sitem, pbt, ms, s, us);
sitem.pid = c_p->common.id;
sitem.count = 0;
/* previous breakpoint */
pbdt = get_time_break(pbt->pc);
/* if null then the breakpoint was removed */
if (pbdt) {
h = &(pbdt->hash[bp_sched2ix_proc(c_p)]);
ASSERT(h);
ASSERT(h->item);
item = bp_hash_get(h, &sitem);
if (!item) {
item = bp_hash_put(h, &sitem);
} else {
BP_TIME_ADD(item, &sitem);
}
}
}
/* Add count to this code */
sitem.pid = c_p->common.id;
sitem.count = 1;
sitem.s_time = 0;
sitem.us_time = 0;
/* this breakpoint */
ASSERT(bdt);
h = &(bdt->hash[bp_sched2ix_proc(c_p)]);
ASSERT(h);
ASSERT(h->item);
item = bp_hash_get(h, &sitem);
if (!item) {
item = bp_hash_put(h, &sitem);
} else {
BP_TIME_ADD(item, &sitem);
}
pbt->pc = I;
pbt->ms = ms;
pbt->s = s;
pbt->us = us;
}
void
erts_trace_time_return(Process *p, BeamInstr *pc)
{
Uint ms,s,us;
process_breakpoint_time_t *pbt = NULL;
bp_data_time_item_t sitem, *item = NULL;
bp_time_hash_t *h = NULL;
BpDataTime *pbdt = NULL;
ASSERT(p);
ASSERT(erts_smp_atomic32_read_acqb(&p->state) & ERTS_PSFLG_RUNNING);
/* get previous timestamp and breakpoint
* from the process psd */
pbt = ERTS_PROC_GET_CALL_TIME(p);
get_sys_now(&ms,&s,&us);
/* get pbt
* lookup bdt from code
* timestamp = t1
* get ts0 from pbt
* get item from bdt->hash[bp_hash(p->id)]
* ack diff (t1, t0) to item
*/
if (pbt) {
/* might have been removed due to
* trace_pattern(false)
*/
ASSERT(pbt->pc);
bp_time_diff(&sitem, pbt, ms, s, us);
sitem.pid = p->common.id;
sitem.count = 0;
/* previous breakpoint */
pbdt = get_time_break(pbt->pc);
/* beware, the trace_pattern might have been removed */
if (pbdt) {
h = &(pbdt->hash[bp_sched2ix_proc(p)]);
ASSERT(h);
ASSERT(h->item);
item = bp_hash_get(h, &sitem);
if (!item) {
item = bp_hash_put(h, &sitem);
} else {
BP_TIME_ADD(item, &sitem);
}
}
pbt->pc = pc;
pbt->ms = ms;
pbt->s = s;
pbt->us = us;
}
}
int
erts_is_trace_break(BeamInstr *pc, Binary **match_spec_ret, int local)
{
Uint flags = local ? ERTS_BPF_LOCAL_TRACE : ERTS_BPF_GLOBAL_TRACE;
GenericBpData* bp = check_break(pc, flags);
if (bp) {
if (match_spec_ret) {
*match_spec_ret = bp->local_ms;
}
return 1;
}
return 0;
}
int
erts_is_mtrace_break(BeamInstr *pc, Binary **match_spec_ret,
Eterm *tracer_pid_ret)
{
GenericBpData* bp = check_break(pc, ERTS_BPF_META_TRACE);
if (bp) {
if (match_spec_ret) {
*match_spec_ret = bp->meta_ms;
}
if (tracer_pid_ret) {
*tracer_pid_ret =
(Eterm) erts_smp_atomic_read_nob(&bp->meta_pid->pid);
}
return 1;
}
return 0;
}
int
erts_is_native_break(BeamInstr *pc) {
#ifdef HIPE
ASSERT(pc[-5] == (BeamInstr) BeamOp(op_i_func_info_IaaI));
return pc[0] == (BeamInstr) BeamOp(op_hipe_trap_call)
|| pc[0] == (BeamInstr) BeamOp(op_hipe_trap_call_closure);
#else
return 0;
#endif
}
int
erts_is_count_break(BeamInstr *pc, Uint *count_ret)
{
GenericBpData* bp = check_break(pc, ERTS_BPF_COUNT);
if (bp) {
if (count_ret) {
*count_ret = (Uint) erts_smp_atomic_read_nob(&bp->count->acount);
}
return 1;
}
return 0;
}
int erts_is_time_break(Process *p, BeamInstr *pc, Eterm *retval) {
Uint i, ix;
bp_time_hash_t hash;
Uint size;
Eterm *hp, t;
bp_data_time_item_t *item = NULL;
BpDataTime *bdt = get_time_break(pc);
if (bdt) {
if (retval) {
/* collect all hashes to one hash */
bp_hash_init(&hash, 64);
/* foreach threadspecific hash */
for (i = 0; i < bdt->n; i++) {
bp_data_time_item_t *sitem;
/* foreach hash bucket not NIL*/
for(ix = 0; ix < bdt->hash[i].n; ix++) {
item = &(bdt->hash[i].item[ix]);
if (item->pid != NIL) {
sitem = bp_hash_get(&hash, item);
if (sitem) {
BP_TIME_ADD(sitem, item);
} else {
bp_hash_put(&hash, item);
}
}
}
}
/* *retval should be NIL or term from previous bif in export entry */
if (hash.used > 0) {
size = (5 + 2)*hash.used;
hp = HAlloc(p, size);
for(ix = 0; ix < hash.n; ix++) {
item = &(hash.item[ix]);
if (item->pid != NIL) {
t = TUPLE4(hp, item->pid,
make_small(item->count),
make_small(item->s_time),
make_small(item->us_time));
hp += 5;
*retval = CONS(hp, t, *retval); hp += 2;
}
}
}
bp_hash_delete(&hash);
}
return 1;
}
return 0;
}
BeamInstr *
erts_find_local_func(Eterm mfa[3]) {
Module *modp;
BeamInstr** code_base;
BeamInstr* code_ptr;
Uint i,n;
if ((modp = erts_get_module(mfa[0], erts_active_code_ix())) == NULL)
return NULL;
if ((code_base = (BeamInstr **) modp->curr.code) == NULL)
return NULL;
n = (BeamInstr) code_base[MI_NUM_FUNCTIONS];
for (i = 0; i < n; ++i) {
code_ptr = code_base[MI_FUNCTIONS+i];
ASSERT(((BeamInstr) BeamOp(op_i_func_info_IaaI)) == code_ptr[0]);
ASSERT(mfa[0] == ((Eterm) code_ptr[2]) ||
is_nil((Eterm) code_ptr[2]));
if (mfa[1] == ((Eterm) code_ptr[3]) &&
((BeamInstr) mfa[2]) == code_ptr[4]) {
return code_ptr + 5;
}
}
return NULL;
}
static void bp_hash_init(bp_time_hash_t *hash, Uint n) {
Uint size = sizeof(bp_data_time_item_t)*n;
Uint i;
hash->n = n;
hash->used = 0;
hash->item = (bp_data_time_item_t *)Alloc(size);
sys_memzero(hash->item, size);
for(i = 0; i < n; ++i) {
hash->item[i].pid = NIL;
}
}
static void bp_hash_rehash(bp_time_hash_t *hash, Uint n) {
bp_data_time_item_t *item = NULL;
Uint size = sizeof(bp_data_time_item_t)*n;
Uint ix;
Uint hval;
item = (bp_data_time_item_t *)Alloc(size);
sys_memzero(item, size);
for( ix = 0; ix < n; ++ix) {
item[ix].pid = NIL;
}
/* rehash, old hash -> new hash */
for( ix = 0; ix < hash->n; ix++) {
if (hash->item[ix].pid != NIL) {
hval = ((hash->item[ix].pid) >> 4) % n; /* new n */
while (item[hval].pid != NIL) {
hval = (hval + 1) % n;
}
item[hval].pid = hash->item[ix].pid;
item[hval].count = hash->item[ix].count;
item[hval].s_time = hash->item[ix].s_time;
item[hval].us_time = hash->item[ix].us_time;
}
}
Free(hash->item);
hash->n = n;
hash->item = item;
}
static ERTS_INLINE bp_data_time_item_t * bp_hash_get(bp_time_hash_t *hash, bp_data_time_item_t *sitem) {
Eterm pid = sitem->pid;
Uint hval = (pid >> 4) % hash->n;
bp_data_time_item_t *item = NULL;
item = hash->item;
while (item[hval].pid != pid) {
if (item[hval].pid == NIL) return NULL;
hval = (hval + 1) % hash->n;
}
return &(item[hval]);
}
static ERTS_INLINE bp_data_time_item_t * bp_hash_put(bp_time_hash_t *hash, bp_data_time_item_t* sitem) {
Uint hval;
float r = 0.0;
bp_data_time_item_t *item;
/* make sure that the hash is not saturated */
/* if saturated, rehash it */
r = hash->used / (float) hash->n;
if (r > 0.7f) {
bp_hash_rehash(hash, hash->n * 2);
}
/* Do hval after rehash */
hval = (sitem->pid >> 4) % hash->n;
/* find free slot */
item = hash->item;
while (item[hval].pid != NIL) {
hval = (hval + 1) % hash->n;
}
item = &(hash->item[hval]);
item->pid = sitem->pid;
item->s_time = sitem->s_time;
item->us_time = sitem->us_time;
item->count = sitem->count;
hash->used++;
return item;
}
static void bp_hash_delete(bp_time_hash_t *hash) {
hash->n = 0;
hash->used = 0;
Free(hash->item);
hash->item = NULL;
}
static void bp_time_diff(bp_data_time_item_t *item, /* out */
process_breakpoint_time_t *pbt, /* in */
Uint ms, Uint s, Uint us) {
int ds,dus;
#ifdef DEBUG
int dms;
dms = ms - pbt->ms;
#endif
ds = s - pbt->s;
dus = us - pbt->us;
/* get_sys_now may return zero difftime,
* this is ok.
*/
#ifdef DEBUG
ASSERT(dms >= 0 || ds >= 0 || dus >= 0);
#endif
if (dus < 0) {
dus += 1000000;
ds -= 1;
}
if (ds < 0) {
ds += 1000000;
}
item->s_time = ds;
item->us_time = dus;
}
void erts_schedule_time_break(Process *p, Uint schedule) {
Uint ms, s, us;
process_breakpoint_time_t *pbt = NULL;
bp_data_time_item_t sitem, *item = NULL;
bp_time_hash_t *h = NULL;
BpDataTime *pbdt = NULL;
ASSERT(p);
pbt = ERTS_PROC_GET_CALL_TIME(p);
if (pbt) {
switch(schedule) {
case ERTS_BP_CALL_TIME_SCHEDULE_EXITING :
break;
case ERTS_BP_CALL_TIME_SCHEDULE_OUT :
/* When a process is scheduled _out_,
* timestamp it and add its delta to
* the previous breakpoint.
*/
pbdt = get_time_break(pbt->pc);
if (pbdt) {
get_sys_now(&ms,&s,&us);
bp_time_diff(&sitem, pbt, ms, s, us);
sitem.pid = p->common.id;
sitem.count = 0;
h = &(pbdt->hash[bp_sched2ix_proc(p)]);
ASSERT(h);
ASSERT(h->item);
item = bp_hash_get(h, &sitem);
if (!item) {
item = bp_hash_put(h, &sitem);
} else {
BP_TIME_ADD(item, &sitem);
}
}
break;
case ERTS_BP_CALL_TIME_SCHEDULE_IN :
/* When a process is scheduled _in_,
* timestamp it and remove the previous
* timestamp in the psd.
*/
get_sys_now(&ms,&s,&us);
pbt->ms = ms;
pbt->s = s;
pbt->us = us;
break;
default :
ASSERT(0);
/* will never happen */
break;
}
} /* pbt */
}
/* *************************************************************************
** Local helpers
*/
static void
set_break(BpFunctions* f, Binary *match_spec, Uint break_flags,
enum erts_break_op count_op, Eterm tracer_pid)
{
Uint i;
Uint n;
n = f->matched;
for (i = 0; i < n; i++) {
BeamInstr* pc = f->matching[i].pc;
set_function_break(pc, match_spec, break_flags,
count_op, tracer_pid);
}
}
static void
set_function_break(BeamInstr *pc, Binary *match_spec, Uint break_flags,
enum erts_break_op count_op, Eterm tracer_pid)
{
GenericBp* g;
GenericBpData* bp;
Uint common;
ErtsBpIndex ix = erts_staging_bp_ix();
ERTS_SMP_LC_ASSERT(erts_has_code_write_permission());
g = (GenericBp *) pc[-4];
if (g == 0) {
int i;
if (count_op == erts_break_reset || count_op == erts_break_stop) {
/* Do not insert a new breakpoint */
return;
}
g = Alloc(sizeof(GenericBp));
g->orig_instr = *pc;
for (i = 0; i < ERTS_NUM_BP_IX; i++) {
g->data[i].flags = 0;
}
pc[-4] = (BeamInstr) g;
}
bp = &g->data[ix];
/*
* If we are changing an existing breakpoint, clean up old data.
*/
common = break_flags & bp->flags;
if (common & (ERTS_BPF_LOCAL_TRACE|ERTS_BPF_GLOBAL_TRACE)) {
MatchSetUnref(bp->local_ms);
} else if (common & ERTS_BPF_META_TRACE) {
MatchSetUnref(bp->meta_ms);
bp_meta_unref(bp->meta_pid);
} else if (common & ERTS_BPF_COUNT) {
if (count_op == erts_break_stop) {
bp->flags &= ~ERTS_BPF_COUNT_ACTIVE;
} else {
bp->flags |= ERTS_BPF_COUNT_ACTIVE;
erts_smp_atomic_set_nob(&bp->count->acount, 0);
}
ASSERT((bp->flags & ~ERTS_BPF_ALL) == 0);
return;
} else if (common & ERTS_BPF_TIME_TRACE) {
BpDataTime* bdt = bp->time;
Uint i = 0;
if (count_op == erts_break_stop) {
bp->flags &= ~ERTS_BPF_TIME_TRACE_ACTIVE;
} else {
bp->flags |= ERTS_BPF_TIME_TRACE_ACTIVE;
for (i = 0; i < bdt->n; i++) {
bp_hash_delete(&(bdt->hash[i]));
bp_hash_init(&(bdt->hash[i]), 32);
}
}
ASSERT((bp->flags & ~ERTS_BPF_ALL) == 0);
return;
}
/*
* Initialize the new breakpoint data.
*/
if (break_flags & (ERTS_BPF_LOCAL_TRACE|ERTS_BPF_GLOBAL_TRACE)) {
MatchSetRef(match_spec);
bp->local_ms = match_spec;
} else if (break_flags & ERTS_BPF_META_TRACE) {
BpMetaPid* bmp;
MatchSetRef(match_spec);
bp->meta_ms = match_spec;
bmp = Alloc(sizeof(BpMetaPid));
erts_refc_init(&bmp->refc, 1);
erts_smp_atomic_init_nob(&bmp->pid, tracer_pid);
bp->meta_pid = bmp;
} else if (break_flags & ERTS_BPF_COUNT) {
BpCount* bcp;
ASSERT((bp->flags & ERTS_BPF_COUNT) == 0);
bcp = Alloc(sizeof(BpCount));
erts_refc_init(&bcp->refc, 1);
erts_smp_atomic_init_nob(&bcp->acount, 0);
bp->count = bcp;
} else if (break_flags & ERTS_BPF_TIME_TRACE) {
BpDataTime* bdt;
int i;
ASSERT((bp->flags & ERTS_BPF_TIME_TRACE) == 0);
bdt = Alloc(sizeof(BpDataTime));
erts_refc_init(&bdt->refc, 1);
bdt->n = erts_no_schedulers;
bdt->hash = Alloc(sizeof(bp_time_hash_t)*(bdt->n));
for (i = 0; i < bdt->n; i++) {
bp_hash_init(&(bdt->hash[i]), 32);
}
bp->time = bdt;
}
bp->flags |= break_flags;
ASSERT((bp->flags & ~ERTS_BPF_ALL) == 0);
}
static void
clear_break(BpFunctions* f, Uint break_flags)
{
Uint i;
Uint n;
n = f->matched;
for (i = 0; i < n; i++) {
BeamInstr* pc = f->matching[i].pc;
clear_function_break(pc, break_flags);
}
}
static int
clear_function_break(BeamInstr *pc, Uint break_flags)
{
GenericBp* g;
GenericBpData* bp;
Uint common;
ErtsBpIndex ix = erts_staging_bp_ix();
ERTS_SMP_LC_ASSERT(erts_has_code_write_permission());
if ((g = (GenericBp *) pc[-4]) == 0) {
return 1;
}
bp = &g->data[ix];
ASSERT((bp->flags & ~ERTS_BPF_ALL) == 0);
common = bp->flags & break_flags;
bp->flags &= ~break_flags;
if (common & (ERTS_BPF_LOCAL_TRACE|ERTS_BPF_GLOBAL_TRACE)) {
MatchSetUnref(bp->local_ms);
}
if (common & ERTS_BPF_META_TRACE) {
MatchSetUnref(bp->meta_ms);
bp_meta_unref(bp->meta_pid);
}
if (common & ERTS_BPF_COUNT) {
ASSERT((bp->flags & ERTS_BPF_COUNT_ACTIVE) == 0);
bp_count_unref(bp->count);
}
if (common & ERTS_BPF_TIME_TRACE) {
ASSERT((bp->flags & ERTS_BPF_TIME_TRACE_ACTIVE) == 0);
bp_time_unref(bp->time);
}
ASSERT((bp->flags & ~ERTS_BPF_ALL) == 0);
return 1;
}
static void
bp_meta_unref(BpMetaPid* bmp)
{
if (erts_refc_dectest(&bmp->refc, 0) <= 0) {
Free(bmp);
}
}
static void
bp_count_unref(BpCount* bcp)
{
if (erts_refc_dectest(&bcp->refc, 0) <= 0) {
Free(bcp);
}
}
static void
bp_time_unref(BpDataTime* bdt)
{
if (erts_refc_dectest(&bdt->refc, 0) <= 0) {
Uint i = 0;
Uint j = 0;
Process *h_p = NULL;
bp_data_time_item_t* item = NULL;
process_breakpoint_time_t* pbt = NULL;
/* remove all psd associated with the hash
* and then delete the hash.
* ... sigh ...
*/
for (i = 0; i < bdt->n; ++i) {
if (bdt->hash[i].used) {
for (j = 0; j < bdt->hash[i].n; ++j) {
item = &(bdt->hash[i].item[j]);
if (item->pid != NIL) {
h_p = erts_pid2proc(NULL, 0, item->pid,
ERTS_PROC_LOCK_MAIN);
if (h_p) {
pbt = ERTS_PROC_SET_CALL_TIME(h_p,
ERTS_PROC_LOCK_MAIN,
NULL);
if (pbt) {
Free(pbt);
}
erts_smp_proc_unlock(h_p, ERTS_PROC_LOCK_MAIN);
}
}
}
}
bp_hash_delete(&(bdt->hash[i]));
}
Free(bdt->hash);
Free(bdt);
}
}
static BpDataTime*
get_time_break(BeamInstr *pc)
{
GenericBpData* bp = check_break(pc, ERTS_BPF_TIME_TRACE);
return bp ? bp->time : 0;
}
static GenericBpData*
check_break(BeamInstr *pc, Uint break_flags)
{
GenericBp* g = (GenericBp *) pc[-4];
ASSERT(pc[-5] == (BeamInstr) BeamOp(op_i_func_info_IaaI));
if (erts_is_native_break(pc)) {
return 0;
}
if (g) {
GenericBpData* bp = &g->data[erts_active_bp_ix()];
ASSERT((bp->flags & ~ERTS_BPF_ALL) == 0);
if (bp->flags & break_flags) {
return bp;
}
}
return 0;
}