/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 1999-2018. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* %CopyrightEnd%
*/
/*
* Support functions for tracing.
*
* Ideas for future speed improvements in tracing framework:
* * Move ErtsTracerNif into ErtsTracer
* + Removes need for locking
* + Removes hash lookup overhead
* + Use a refc on the ErtsTracerNif to know when it can
* be freed. We don't want to allocate a separate
* ErtsTracerNif for each module used.
* * Optimize GenericBp for cache locality by reusing equivalent
* GenericBp and GenericBpData in multiple tracer points.
* + Possibly we want to use specialized instructions for different
* types of trace so that the knowledge of which struct is used
* can be in the instruction.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_process.h"
#include "big.h"
#include "bif.h"
#include "dist.h"
#include "beam_bp.h"
#include "error.h"
#include "erl_binary.h"
#include "erl_bits.h"
#include "erl_thr_progress.h"
#include "erl_bif_unique.h"
#include "erl_map.h"
#if 0
#define DEBUG_PRINTOUTS
#else
#undef DEBUG_PRINTOUTS
#endif
/* Pseudo export entries. Never filled in with data, only used to
yield unique pointers of the correct type. */
Export exp_send, exp_receive, exp_timeout;
static ErtsTracer system_seq_tracer;
static Uint default_proc_trace_flags;
static ErtsTracer default_proc_tracer;
static Uint default_port_trace_flags;
static ErtsTracer default_port_tracer;
static Eterm system_monitor;
static Eterm system_profile;
static erts_atomic_t system_logger;
#ifdef HAVE_ERTS_NOW_CPU
int erts_cpu_timestamp;
#endif
static erts_mtx_t smq_mtx;
static erts_rwmtx_t sys_trace_rwmtx;
enum ErtsSysMsgType {
SYS_MSG_TYPE_UNDEFINED,
SYS_MSG_TYPE_SYSMON,
SYS_MSG_TYPE_ERRLGR,
SYS_MSG_TYPE_PROC_MSG,
SYS_MSG_TYPE_SYSPROF
};
#define ERTS_TRACE_TS_NOW_MAX_SIZE \
4
#define ERTS_TRACE_TS_MONOTONIC_MAX_SIZE \
ERTS_MAX_SINT64_HEAP_SIZE
#define ERTS_TRACE_TS_STRICT_MONOTONIC_MAX_SIZE \
(3 + ERTS_MAX_SINT64_HEAP_SIZE \
+ ERTS_MAX_UINT64_HEAP_SIZE)
#define ERTS_TRACE_PATCH_TS_MAX_SIZE \
(1 + ((ERTS_TRACE_TS_NOW_MAX_SIZE \
> ERTS_TRACE_TS_MONOTONIC_MAX_SIZE) \
? ((ERTS_TRACE_TS_NOW_MAX_SIZE \
> ERTS_TRACE_TS_STRICT_MONOTONIC_MAX_SIZE) \
? ERTS_TRACE_TS_NOW_MAX_SIZE \
: ERTS_TRACE_TS_STRICT_MONOTONIC_MAX_SIZE) \
: ((ERTS_TRACE_TS_MONOTONIC_MAX_SIZE \
> ERTS_TRACE_TS_STRICT_MONOTONIC_MAX_SIZE) \
? ERTS_TRACE_TS_MONOTONIC_MAX_SIZE \
: ERTS_TRACE_TS_STRICT_MONOTONIC_MAX_SIZE)))
#define TFLGS_TS_TYPE(p) ERTS_TFLGS2TSTYPE(ERTS_TRACE_FLAGS((p)))
/*
* FUTURE CHANGES:
*
* The timestamp functionality has intentionally been
* split in two parts for future use even though it
* is not used like this today. take_timestamp() takes
* the timestamp and calculate heap need for it (which
* is not constant). write_timestamp() writes the
* timestamp to the allocated heap. That is, one typically
* want to take the timestamp before allocating the heap
* and then write it to the heap.
*
* The trace output functionality now use patch_ts_size(),
* write_ts(), and patch_ts(). write_ts() both takes the
* timestamp and writes it. Since we don't know the
* heap need when allocating the heap area we need to
* over allocate (maximum size from patch_ts_size()) and
* then potentially (often) shrink the heap area after the
* timestamp has been written. The only reason it is
* currently done this way is because we do not want to
* make major changes of the trace behavior in a patch.
* This is planned to be changed in next major release.
*/
typedef struct {
int ts_type_flag;
union {
struct {
Uint ms;
Uint s;
Uint us;
} now;
struct {
ErtsMonotonicTime time;
Sint64 raw_unique;
} monotonic;
} u;
} ErtsTraceTimeStamp;
static ERTS_INLINE Uint
take_timestamp(ErtsTraceTimeStamp *tsp, int ts_type)
{
int ts_type_flag = ts_type & -ts_type; /* least significant flag */
ASSERT(ts_type_flag == ERTS_TRACE_FLG_NOW_TIMESTAMP
|| ts_type_flag == ERTS_TRACE_FLG_MONOTONIC_TIMESTAMP
|| ts_type_flag == ERTS_TRACE_FLG_STRICT_MONOTONIC_TIMESTAMP
|| ts_type_flag == 0);
tsp->ts_type_flag = ts_type_flag;
switch (ts_type_flag) {
case 0:
return (Uint) 0;
case ERTS_TRACE_FLG_NOW_TIMESTAMP:
#ifdef HAVE_ERTS_NOW_CPU
if (erts_cpu_timestamp)
erts_get_now_cpu(&tsp->u.now.ms, &tsp->u.now.s, &tsp->u.now.us);
else
#endif
get_now(&tsp->u.now.ms, &tsp->u.now.s, &tsp->u.now.us);
return (Uint) 4;
case ERTS_TRACE_FLG_MONOTONIC_TIMESTAMP:
case ERTS_TRACE_FLG_STRICT_MONOTONIC_TIMESTAMP: {
Uint hsz = 0;
ErtsMonotonicTime mtime = erts_get_monotonic_time(NULL);
mtime = ERTS_MONOTONIC_TO_NSEC(mtime);
mtime += ERTS_MONOTONIC_OFFSET_NSEC;
hsz = (IS_SSMALL(mtime) ?
(Uint) 0
: ERTS_SINT64_HEAP_SIZE((Sint64) mtime));
tsp->u.monotonic.time = mtime;
if (ts_type_flag == ERTS_TRACE_FLG_STRICT_MONOTONIC_TIMESTAMP) {
Sint64 raw_unique;
hsz += 3; /* 2-tuple */
raw_unique = erts_raw_get_unique_monotonic_integer();
tsp->u.monotonic.raw_unique = raw_unique;
hsz += erts_raw_unique_monotonic_integer_heap_size(raw_unique, 0);
}
return hsz;
}
default:
ERTS_INTERNAL_ERROR("invalid timestamp type");
return 0;
}
}
static ERTS_INLINE Eterm
write_timestamp(ErtsTraceTimeStamp *tsp, Eterm **hpp)
{
int ts_type_flag = tsp->ts_type_flag;
Eterm res;
switch (ts_type_flag) {
case 0:
return NIL;
case ERTS_TRACE_FLG_NOW_TIMESTAMP:
res = TUPLE3(*hpp,
make_small(tsp->u.now.ms),
make_small(tsp->u.now.s),
make_small(tsp->u.now.us));
*hpp += 4;
return res;
case ERTS_TRACE_FLG_MONOTONIC_TIMESTAMP:
case ERTS_TRACE_FLG_STRICT_MONOTONIC_TIMESTAMP: {
Sint64 mtime, raw;
Eterm unique, emtime;
mtime = (Sint64) tsp->u.monotonic.time;
emtime = (IS_SSMALL(mtime)
? make_small((Sint64) mtime)
: erts_sint64_to_big((Sint64) mtime, hpp));
if (ts_type_flag == ERTS_TRACE_FLG_MONOTONIC_TIMESTAMP)
return emtime;
raw = tsp->u.monotonic.raw_unique;
unique = erts_raw_make_unique_monotonic_integer_value(hpp, raw, 0);
res = TUPLE2(*hpp, emtime, unique);
*hpp += 3;
return res;
}
default:
ERTS_INTERNAL_ERROR("invalid timestamp type");
return THE_NON_VALUE;
}
}
static ERTS_INLINE Uint
patch_ts_size(int ts_type)
{
int ts_type_flag = ts_type & -ts_type; /* least significant flag */
switch (ts_type_flag) {
case 0:
return 0;
case ERTS_TRACE_FLG_NOW_TIMESTAMP:
return 1 + ERTS_TRACE_TS_NOW_MAX_SIZE;
case ERTS_TRACE_FLG_MONOTONIC_TIMESTAMP:
return 1 + ERTS_TRACE_TS_MONOTONIC_MAX_SIZE;
case ERTS_TRACE_FLG_STRICT_MONOTONIC_TIMESTAMP:
return 1 + ERTS_TRACE_TS_STRICT_MONOTONIC_MAX_SIZE;
default:
ERTS_INTERNAL_ERROR("invalid timestamp type");
return 0;
}
}
/*
* Write a timestamp. The timestamp MUST be the last
* thing built on the heap. This since write_ts() might
* adjust the size of the used area.
*/
static Eterm
write_ts(int ts_type, Eterm *hp, ErlHeapFragment *bp, Process *tracer)
{
ErtsTraceTimeStamp ts;
Sint shrink;
Eterm res, *ts_hp = hp;
Uint hsz;
ASSERT(ts_type);
hsz = take_timestamp(&ts, ts_type);
res = write_timestamp(&ts, &ts_hp);
ASSERT(ts_hp == hp + hsz);
switch (ts.ts_type_flag) {
case ERTS_TRACE_FLG_MONOTONIC_TIMESTAMP:
shrink = ERTS_TRACE_TS_MONOTONIC_MAX_SIZE;
break;
case ERTS_TRACE_FLG_STRICT_MONOTONIC_TIMESTAMP:
shrink = ERTS_TRACE_TS_STRICT_MONOTONIC_MAX_SIZE;
break;
default:
return res;
}
shrink -= hsz;
ASSERT(shrink >= 0);
if (shrink) {
if (bp)
bp->used_size -= shrink;
}
return res;
}
static void enqueue_sys_msg_unlocked(enum ErtsSysMsgType type,
Eterm from,
Eterm to,
Eterm msg,
ErlHeapFragment *bp);
static void enqueue_sys_msg(enum ErtsSysMsgType type,
Eterm from,
Eterm to,
Eterm msg,
ErlHeapFragment *bp);
static void init_sys_msg_dispatcher(void);
static void init_tracer_nif(void);
static int tracer_cmp_fun(void*, void*);
static HashValue tracer_hash_fun(void*);
static void *tracer_alloc_fun(void*);
static void tracer_free_fun(void*);
typedef struct ErtsTracerNif_ ErtsTracerNif;
void erts_init_trace(void) {
erts_rwmtx_opt_t rwmtx_opts = ERTS_RWMTX_OPT_DEFAULT_INITER;
rwmtx_opts.type = ERTS_RWMTX_TYPE_EXTREMELY_FREQUENT_READ;
rwmtx_opts.lived = ERTS_RWMTX_LONG_LIVED;
erts_rwmtx_init_opt(&sys_trace_rwmtx, &rwmtx_opts, "sys_tracers", NIL,
ERTS_LOCK_FLAGS_PROPERTY_STATIC | ERTS_LOCK_FLAGS_CATEGORY_DEBUG);
#ifdef HAVE_ERTS_NOW_CPU
erts_cpu_timestamp = 0;
#endif
erts_bif_trace_init();
erts_system_monitor_clear(NULL);
erts_system_profile_clear(NULL);
default_proc_trace_flags = F_INITIAL_TRACE_FLAGS;
default_proc_tracer = erts_tracer_nil;
default_port_trace_flags = F_INITIAL_TRACE_FLAGS;
default_port_tracer = erts_tracer_nil;
system_seq_tracer = erts_tracer_nil;
erts_atomic_init_nob(&system_logger, am_logger);
init_sys_msg_dispatcher();
init_tracer_nif();
}
#define ERTS_ALLOC_SYSMSG_HEAP(SZ, BPP, OHPP, UNUSED) \
(*(BPP) = new_message_buffer((SZ)), \
*(OHPP) = &(*(BPP))->off_heap, \
(*(BPP))->mem)
enum ErtsTracerOpt {
TRACE_FUN_DEFAULT = 0,
TRACE_FUN_ENABLED = 1,
TRACE_FUN_T_SEND = 2,
TRACE_FUN_T_RECEIVE = 3,
TRACE_FUN_T_CALL = 4,
TRACE_FUN_T_SCHED_PROC = 5,
TRACE_FUN_T_SCHED_PORT = 6,
TRACE_FUN_T_GC = 7,
TRACE_FUN_T_PROCS = 8,
TRACE_FUN_T_PORTS = 9,
TRACE_FUN_E_SEND = 10,
TRACE_FUN_E_RECEIVE = 11,
TRACE_FUN_E_CALL = 12,
TRACE_FUN_E_SCHED_PROC = 13,
TRACE_FUN_E_SCHED_PORT = 14,
TRACE_FUN_E_GC = 15,
TRACE_FUN_E_PROCS = 16,
TRACE_FUN_E_PORTS = 17
};
#define NIF_TRACER_TYPES (18)
static ERTS_INLINE int
send_to_tracer_nif_raw(Process *c_p, Process *tracee, const ErtsTracer tracer,
Uint trace_flags, Eterm t_p_id, ErtsTracerNif *tnif,
enum ErtsTracerOpt topt,
Eterm tag, Eterm msg, Eterm extra, Eterm pam_result);
static ERTS_INLINE int
send_to_tracer_nif(Process *c_p, ErtsPTabElementCommon *t_p,
Eterm t_p_id, ErtsTracerNif *tnif,
enum ErtsTracerOpt topt,
Eterm tag, Eterm msg, Eterm extra,
Eterm pam_result);
static ERTS_INLINE Eterm
call_enabled_tracer(const ErtsTracer tracer,
ErtsTracerNif **tnif_ref,
enum ErtsTracerOpt topt,
Eterm tag, Eterm t_p_id);
static int
is_tracer_enabled(Process* c_p, ErtsProcLocks c_p_locks,
ErtsPTabElementCommon *t_p,
ErtsTracerNif **tnif_ret,
enum ErtsTracerOpt topt, Eterm tag);
static Uint active_sched;
void
erts_system_profile_setup_active_schedulers(void)
{
ERTS_LC_ASSERT(erts_thr_progress_is_blocking());
active_sched = erts_active_schedulers();
}
static void
exiting_reset(Eterm exiting)
{
erts_rwmtx_rwlock(&sys_trace_rwmtx);
if (exiting == system_monitor) {
system_monitor = NIL;
/* Let the trace message dispatcher clear flags, etc */
}
if (exiting == system_profile) {
system_profile = NIL;
/* Let the trace message dispatcher clear flags, etc */
}
erts_rwmtx_rwunlock(&sys_trace_rwmtx);
}
void
erts_trace_check_exiting(Eterm exiting)
{
int reset = 0;
erts_rwmtx_rlock(&sys_trace_rwmtx);
if (exiting == system_monitor)
reset = 1;
else if (exiting == system_profile)
reset = 1;
erts_rwmtx_runlock(&sys_trace_rwmtx);
if (reset)
exiting_reset(exiting);
}
ErtsTracer
erts_set_system_seq_tracer(Process *c_p, ErtsProcLocks c_p_locks, ErtsTracer new)
{
ErtsTracer old;
if (!ERTS_TRACER_IS_NIL(new)) {
Eterm nif_result = call_enabled_tracer(
new, NULL, TRACE_FUN_ENABLED, am_trace_status, am_undefined);
switch (nif_result) {
case am_trace: break;
default:
return THE_NON_VALUE;
}
}
erts_rwmtx_rwlock(&sys_trace_rwmtx);
old = system_seq_tracer;
system_seq_tracer = erts_tracer_nil;
erts_tracer_update(&system_seq_tracer, new);
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "set seq tracer new=%T old=%T\n", new, old);
#endif
erts_rwmtx_rwunlock(&sys_trace_rwmtx);
return old;
}
ErtsTracer
erts_get_system_seq_tracer(void)
{
ErtsTracer st;
erts_rwmtx_rlock(&sys_trace_rwmtx);
st = system_seq_tracer;
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "get seq tracer %T\n", st);
#endif
erts_rwmtx_runlock(&sys_trace_rwmtx);
if (st != erts_tracer_nil &&
call_enabled_tracer(st, NULL, TRACE_FUN_ENABLED,
am_trace_status, am_undefined) == am_remove) {
st = erts_set_system_seq_tracer(NULL, 0, erts_tracer_nil);
ERTS_TRACER_CLEAR(&st);
}
return st;
}
static ERTS_INLINE void
get_default_tracing(Uint *flagsp, ErtsTracer *tracerp,
Uint *default_trace_flags,
ErtsTracer *default_tracer)
{
if (!(*default_trace_flags & TRACEE_FLAGS))
ERTS_TRACER_CLEAR(default_tracer);
if (ERTS_TRACER_IS_NIL(*default_tracer)) {
*default_trace_flags &= ~TRACEE_FLAGS;
} else {
Eterm nif_res;
nif_res = call_enabled_tracer(*default_tracer,
NULL, TRACE_FUN_ENABLED,
am_trace_status, am_undefined);
switch (nif_res) {
case am_trace: break;
default: {
ErtsTracer curr_default_tracer = *default_tracer;
if (tracerp) {
/* we only have a rlock, so we have to unlock and then rwlock */
erts_rwmtx_runlock(&sys_trace_rwmtx);
erts_rwmtx_rwlock(&sys_trace_rwmtx);
}
/* check if someone else changed default tracer
while we got the write lock, if so we don't do
anything. */
if (curr_default_tracer == *default_tracer) {
*default_trace_flags &= ~TRACEE_FLAGS;
ERTS_TRACER_CLEAR(default_tracer);
}
if (tracerp) {
erts_rwmtx_rwunlock(&sys_trace_rwmtx);
erts_rwmtx_rlock(&sys_trace_rwmtx);
}
}
}
}
if (flagsp)
*flagsp = *default_trace_flags;
if (tracerp) {
erts_tracer_update(tracerp,*default_tracer);
}
}
static ERTS_INLINE void
erts_change_default_tracing(int setflags, Uint flags,
const ErtsTracer tracer,
Uint *default_trace_flags,
ErtsTracer *default_tracer)
{
if (setflags)
*default_trace_flags |= flags;
else
*default_trace_flags &= ~flags;
erts_tracer_update(default_tracer, tracer);
get_default_tracing(NULL, NULL, default_trace_flags, default_tracer);
}
void
erts_change_default_proc_tracing(int setflags, Uint flagsp,
const ErtsTracer tracer)
{
erts_rwmtx_rwlock(&sys_trace_rwmtx);
erts_change_default_tracing(
setflags, flagsp, tracer,
&default_proc_trace_flags,
&default_proc_tracer);
erts_rwmtx_rwunlock(&sys_trace_rwmtx);
}
void
erts_change_default_port_tracing(int setflags, Uint flagsp,
const ErtsTracer tracer)
{
erts_rwmtx_rwlock(&sys_trace_rwmtx);
erts_change_default_tracing(
setflags, flagsp, tracer,
&default_port_trace_flags,
&default_port_tracer);
erts_rwmtx_rwunlock(&sys_trace_rwmtx);
}
void
erts_get_default_proc_tracing(Uint *flagsp, ErtsTracer *tracerp)
{
erts_rwmtx_rlock(&sys_trace_rwmtx);
*tracerp = erts_tracer_nil; /* initialize */
get_default_tracing(
flagsp, tracerp,
&default_proc_trace_flags,
&default_proc_tracer);
erts_rwmtx_runlock(&sys_trace_rwmtx);
}
void
erts_get_default_port_tracing(Uint *flagsp, ErtsTracer *tracerp)
{
erts_rwmtx_rlock(&sys_trace_rwmtx);
*tracerp = erts_tracer_nil; /* initialize */
get_default_tracing(
flagsp, tracerp,
&default_port_trace_flags,
&default_port_tracer);
erts_rwmtx_runlock(&sys_trace_rwmtx);
}
void
erts_set_system_monitor(Eterm monitor)
{
erts_rwmtx_rwlock(&sys_trace_rwmtx);
system_monitor = monitor;
erts_rwmtx_rwunlock(&sys_trace_rwmtx);
}
Eterm
erts_get_system_monitor(void)
{
Eterm monitor;
erts_rwmtx_rlock(&sys_trace_rwmtx);
monitor = system_monitor;
erts_rwmtx_runlock(&sys_trace_rwmtx);
return monitor;
}
/* Performance monitoring */
void erts_set_system_profile(Eterm profile) {
erts_rwmtx_rwlock(&sys_trace_rwmtx);
system_profile = profile;
erts_rwmtx_rwunlock(&sys_trace_rwmtx);
}
Eterm
erts_get_system_profile(void) {
Eterm profile;
erts_rwmtx_rlock(&sys_trace_rwmtx);
profile = system_profile;
erts_rwmtx_runlock(&sys_trace_rwmtx);
return profile;
}
static void
write_sys_msg_to_port(Eterm unused_to,
Port* trace_port,
Eterm unused_from,
enum ErtsSysMsgType unused_type,
Eterm message) {
byte *buffer;
byte *ptr;
Uint size;
if (erts_encode_ext_size(message, &size) != ERTS_EXT_SZ_OK)
erts_exit(ERTS_ERROR_EXIT, "Internal error: System limit\n");
buffer = (byte *) erts_alloc(ERTS_ALC_T_TMP, size);
ptr = buffer;
erts_encode_ext(message, &ptr);
if (!(ptr <= buffer+size)) {
erts_exit(ERTS_ERROR_EXIT, "Internal error in do_send_to_port: %d\n", ptr-buffer);
}
erts_raw_port_command(trace_port, buffer, ptr-buffer);
erts_free(ERTS_ALC_T_TMP, (void *) buffer);
}
static void
trace_sched_aux(Process *p, ErtsProcLocks locks, Eterm what)
{
Eterm tmp, *hp;
int curr_func;
ErtsTracerNif *tnif = NULL;
if (ERTS_TRACER_IS_NIL(ERTS_TRACER(p)))
return;
switch (what) {
case am_out:
case am_out_exiting:
case am_out_exited:
case am_in:
case am_in_exiting:
break;
default:
ASSERT(0);
break;
}
if (!is_tracer_enabled(p, locks, &p->common, &tnif, TRACE_FUN_E_SCHED_PROC, what))
return;
if (ERTS_PROC_IS_EXITING(p))
curr_func = 0;
else {
if (!p->current)
p->current = find_function_from_pc(p->i);
curr_func = p->current != NULL;
}
if (!curr_func) {
tmp = make_small(0);
} else {
hp = HAlloc(p, 4);
tmp = TUPLE3(hp,p->current->module,p->current->function,
make_small(p->current->arity));
hp += 4;
}
send_to_tracer_nif(p, &p->common, p->common.id, tnif, TRACE_FUN_T_SCHED_PROC,
what, tmp, THE_NON_VALUE, am_true);
}
/* Send {trace_ts, Pid, What, {Mod, Func, Arity}, Timestamp}
* or {trace, Pid, What, {Mod, Func, Arity}}
*
* where 'What' is supposed to be 'in', 'out', 'in_exiting',
* 'out_exiting', or 'out_exited'.
*/
void
trace_sched(Process *p, ErtsProcLocks locks, Eterm what)
{
trace_sched_aux(p, locks, what);
}
/* Send {trace_ts, Pid, Send, Msg, DestPid, Timestamp}
* or {trace, Pid, Send, Msg, DestPid}
*
* where 'Send' is 'send' or 'send_to_non_existing_process'.
*/
void
trace_send(Process *p, Eterm to, Eterm msg)
{
Eterm operation = am_send;
ErtsTracerNif *tnif = NULL;
ErtsTracingEvent* te;
Eterm pam_result;
ErtsThrPrgrDelayHandle dhndl;
ASSERT(ARE_TRACE_FLAGS_ON(p, F_TRACE_SEND));
te = &erts_send_tracing[erts_active_bp_ix()];
if (!te->on) {
return;
}
if (te->match_spec) {
Eterm args[2];
Uint32 return_flags;
args[0] = to;
args[1] = msg;
pam_result = erts_match_set_run_trace(p, p,
te->match_spec, args, 2,
ERTS_PAM_TMP_RESULT, &return_flags);
if (pam_result == am_false)
return;
if (ERTS_TRACE_FLAGS(p) & F_TRACE_SILENT) {
erts_match_set_release_result_trace(p, pam_result);
return;
}
} else
pam_result = am_true;
dhndl = erts_thr_progress_unmanaged_delay();
if (is_internal_pid(to)) {
if (!erts_proc_lookup(to))
goto send_to_non_existing_process;
}
else if(is_external_pid(to)
&& external_pid_dist_entry(to) == erts_this_dist_entry) {
send_to_non_existing_process:
operation = am_send_to_non_existing_process;
}
if (is_tracer_enabled(p, ERTS_PROC_LOCK_MAIN, &p->common, &tnif,
TRACE_FUN_E_SEND, operation)) {
send_to_tracer_nif(p, &p->common, p->common.id, tnif, TRACE_FUN_T_SEND,
operation, msg, to, pam_result);
}
erts_thr_progress_unmanaged_continue(dhndl);
erts_match_set_release_result_trace(p, pam_result);
}
/* Send {trace_ts, Pid, receive, Msg, Timestamp}
* or {trace, Pid, receive, Msg}
*/
void
trace_receive(Process* receiver,
Eterm from,
Eterm msg, ErtsTracingEvent* te)
{
ErtsTracerNif *tnif = NULL;
Eterm pam_result;
if (!te) {
te = &erts_receive_tracing[erts_active_bp_ix()];
if (!te->on)
return;
}
else ASSERT(te->on);
if (te->match_spec) {
Eterm args[3];
Uint32 return_flags;
if (is_pid(from)) {
args[0] = pid_node_name(from);
args[1] = from;
}
else {
ASSERT(is_atom(from));
args[0] = from; /* node name or other atom (e.g 'system') */
args[1] = am_undefined;
}
args[2] = msg;
pam_result = erts_match_set_run_trace(NULL, receiver,
te->match_spec, args, 3,
ERTS_PAM_TMP_RESULT, &return_flags);
if (pam_result == am_false)
return;
if (ERTS_TRACE_FLAGS(receiver) & F_TRACE_SILENT) {
erts_match_set_release_result_trace(NULL, pam_result);
return;
}
} else
pam_result = am_true;
if (is_tracer_enabled(NULL, 0, &receiver->common, &tnif,
TRACE_FUN_E_RECEIVE, am_receive)) {
send_to_tracer_nif(NULL, &receiver->common, receiver->common.id,
tnif, TRACE_FUN_T_RECEIVE,
am_receive, msg, THE_NON_VALUE, pam_result);
}
erts_match_set_release_result_trace(NULL, pam_result);
}
int
seq_trace_update_send(Process *p)
{
ErtsTracer seq_tracer = erts_get_system_seq_tracer();
ASSERT((is_tuple(SEQ_TRACE_TOKEN(p)) || is_nil(SEQ_TRACE_TOKEN(p))));
if (have_no_seqtrace(SEQ_TRACE_TOKEN(p)) ||
(seq_tracer != NIL &&
call_enabled_tracer(seq_tracer, NULL,
TRACE_FUN_ENABLED, am_seq_trace,
p ? p->common.id : am_undefined) != am_trace)
#ifdef USE_VM_PROBES
|| (SEQ_TRACE_TOKEN(p) == am_have_dt_utag)
#endif
) {
return 0;
}
SEQ_TRACE_TOKEN_SENDER(p) = p->common.id;
SEQ_TRACE_TOKEN_SERIAL(p) =
make_small(++(p -> seq_trace_clock));
SEQ_TRACE_TOKEN_LASTCNT(p) =
make_small(p -> seq_trace_lastcnt);
return 1;
}
/* Send a sequential trace message to the sequential tracer.
* p is the caller (which contains the trace token),
* msg is the original message, type is trace type (SEQ_TRACE_SEND etc),
* and receiver is the receiver of the message.
*
* The message to be received by the sequential tracer is:
*
* TraceMsg =
* {seq_trace, Label, {Type, {Lastcnt, Serial}, Sender, Receiver, Msg} [,Timestamp] }
*
*/
void
seq_trace_output_generic(Eterm token, Eterm msg, Uint type,
Eterm receiver, Process *process, Eterm exitfrom)
{
Eterm mess;
Eterm* hp;
Eterm label;
Eterm lastcnt_serial;
Eterm type_atom;
ErtsTracer seq_tracer;
int seq_tracer_flags = 0;
#define LOCAL_HEAP_SIZE (64)
DeclareTmpHeapNoproc(local_heap,LOCAL_HEAP_SIZE);
seq_tracer = erts_get_system_seq_tracer();
ASSERT(is_tuple(token) || is_nil(token));
if (token == NIL || (process && ERTS_TRACE_FLAGS(process) & F_SENSITIVE) ||
ERTS_TRACER_IS_NIL(seq_tracer) ||
call_enabled_tracer(seq_tracer,
NULL, TRACE_FUN_ENABLED,
am_seq_trace,
process ? process->common.id : am_undefined) != am_trace) {
return;
}
if ((unsigned_val(SEQ_TRACE_T_FLAGS(token)) & type) == 0) {
/* No flags set, nothing to do */
return;
}
switch (type) {
case SEQ_TRACE_SEND: type_atom = am_send; break;
case SEQ_TRACE_PRINT: type_atom = am_print; break;
case SEQ_TRACE_RECEIVE: type_atom = am_receive; break;
default:
erts_exit(ERTS_ERROR_EXIT, "invalid type in seq_trace_output_generic: %d:\n", type);
return; /* To avoid warning */
}
UseTmpHeapNoproc(LOCAL_HEAP_SIZE);
hp = local_heap;
label = SEQ_TRACE_T_LABEL(token);
lastcnt_serial = TUPLE2(hp, SEQ_TRACE_T_LASTCNT(token),
SEQ_TRACE_T_SERIAL(token));
hp += 3;
if (exitfrom != NIL) {
msg = TUPLE3(hp, am_EXIT, exitfrom, msg);
hp += 4;
}
mess = TUPLE5(hp, type_atom, lastcnt_serial, SEQ_TRACE_T_SENDER(token), receiver, msg);
hp += 6;
seq_tracer_flags |= ERTS_SEQTFLGS2TFLGS(unsigned_val(SEQ_TRACE_T_FLAGS(token)));
send_to_tracer_nif_raw(NULL, process, seq_tracer, seq_tracer_flags,
label, NULL, TRACE_FUN_DEFAULT, am_seq_trace, mess,
THE_NON_VALUE, am_true);
UnUseTmpHeapNoproc(LOCAL_HEAP_SIZE);
#undef LOCAL_HEAP_SIZE
}
/* Send {trace_ts, Pid, return_to, {Mod, Func, Arity}, Timestamp}
* or {trace, Pid, return_to, {Mod, Func, Arity}}
*/
void
erts_trace_return_to(Process *p, BeamInstr *pc)
{
Eterm mfa;
ErtsCodeMFA *cmfa = find_function_from_pc(pc);
if (!cmfa) {
mfa = am_undefined;
} else {
Eterm *hp = HAlloc(p, 4);
mfa = TUPLE3(hp, cmfa->module, cmfa->function,
make_small(cmfa->arity));
}
send_to_tracer_nif(p, &p->common, p->common.id, NULL, TRACE_FUN_T_CALL,
am_return_to, mfa, THE_NON_VALUE, am_true);
}
/* Send {trace_ts, Pid, return_from, {Mod, Name, Arity}, Retval, Timestamp}
* or {trace, Pid, return_from, {Mod, Name, Arity}, Retval}
*/
void
erts_trace_return(Process* p, ErtsCodeMFA *mfa,
Eterm retval, ErtsTracer *tracer)
{
Eterm* hp;
Eterm mfa_tuple;
Uint meta_flags, *tracee_flags;
ASSERT(tracer);
if (ERTS_TRACER_COMPARE(*tracer, erts_tracer_true)) {
/* Breakpoint trace enabled without specifying tracer =>
* use process tracer and flags
*/
tracer = &ERTS_TRACER(p);
}
if (ERTS_TRACER_IS_NIL(*tracer)) {
/* Trace disabled */
return;
}
ASSERT(IS_TRACER_VALID(*tracer));
if (tracer == &ERTS_TRACER(p)) {
/* Tracer specified in process structure =>
* non-breakpoint trace =>
* use process flags
*/
tracee_flags = &ERTS_TRACE_FLAGS(p);
if (! (*tracee_flags & F_TRACE_CALLS)) {
return;
}
} else {
/* Tracer not specified in process structure =>
* tracer specified in breakpoint =>
* meta trace =>
* use fixed flag set instead of process flags
*/
meta_flags = F_TRACE_CALLS | F_NOW_TS;
tracee_flags = &meta_flags;
}
hp = HAlloc(p, 4);
mfa_tuple = TUPLE3(hp, mfa->module, mfa->function,
make_small(mfa->arity));
hp += 4;
send_to_tracer_nif_raw(p, NULL, *tracer, *tracee_flags, p->common.id,
NULL, TRACE_FUN_T_CALL, am_return_from, mfa_tuple,
retval, am_true);
}
/* Send {trace_ts, Pid, exception_from, {Mod, Name, Arity}, {Class,Value},
* Timestamp}
* or {trace, Pid, exception_from, {Mod, Name, Arity}, {Class,Value},
* Timestamp}
*
* Where Class is atomic but Value is any term.
*/
void
erts_trace_exception(Process* p, ErtsCodeMFA *mfa, Eterm class, Eterm value,
ErtsTracer *tracer)
{
Eterm* hp;
Eterm mfa_tuple, cv;
Uint meta_flags, *tracee_flags;
ASSERT(tracer);
if (ERTS_TRACER_COMPARE(*tracer, erts_tracer_true)) {
/* Breakpoint trace enabled without specifying tracer =>
* use process tracer and flags
*/
tracer = &ERTS_TRACER(p);
}
if (ERTS_TRACER_IS_NIL(*tracer)) {
/* Trace disabled */
return;
}
ASSERT(IS_TRACER_VALID(*tracer));
if (tracer == &ERTS_TRACER(p)) {
/* Tracer specified in process structure =>
* non-breakpoint trace =>
* use process flags
*/
tracee_flags = &ERTS_TRACE_FLAGS(p);
if (! (*tracee_flags & F_TRACE_CALLS)) {
return;
}
} else {
/* Tracer not specified in process structure =>
* tracer specified in breakpoint =>
* meta trace =>
* use fixed flag set instead of process flags
*/
meta_flags = F_TRACE_CALLS | F_NOW_TS;
tracee_flags = &meta_flags;
}
hp = HAlloc(p, 7);;
mfa_tuple = TUPLE3(hp, mfa->module, mfa->function, make_small(mfa->arity));
hp += 4;
cv = TUPLE2(hp, class, value);
hp += 3;
send_to_tracer_nif_raw(p, NULL, *tracer, *tracee_flags, p->common.id,
NULL, TRACE_FUN_T_CALL, am_exception_from, mfa_tuple, cv, am_true);
}
/*
* This function implements the new call trace.
*
* Send {trace_ts, Pid, call, {Mod, Func, A}, PamResult, Timestamp}
* or {trace_ts, Pid, call, {Mod, Func, A}, Timestamp}
* or {trace, Pid, call, {Mod, Func, A}, PamResult}
* or {trace, Pid, call, {Mod, Func, A}
*
* where 'A' is arity or argument list depending on trace flag 'arity'.
*
* If *tracer_pid is am_true, it is a breakpoint trace that shall use
* the process tracer, if it is NIL no trace message is generated,
* if it is a pid or port we do a meta trace.
*/
Uint32
erts_call_trace(Process* p, ErtsCodeInfo *info, Binary *match_spec,
Eterm* args, int local, ErtsTracer *tracer)
{
Eterm* hp;
Eterm mfa_tuple;
int arity;
int i;
Uint32 return_flags;
Eterm pam_result = am_true;
Uint meta_flags, *tracee_flags;
ErtsTracerNif *tnif = NULL;
Eterm transformed_args[MAX_ARG];
ErtsTracer pre_ms_tracer = erts_tracer_nil;
ERTS_LC_ASSERT(erts_proc_lc_my_proc_locks(p) & ERTS_PROC_LOCK_MAIN);
ASSERT(tracer);
if (ERTS_TRACER_COMPARE(*tracer, erts_tracer_true)) {
/* Breakpoint trace enabled without specifying tracer =>
* use process tracer and flags
*/
tracer = &ERTS_TRACER(p);
}
if (ERTS_TRACER_IS_NIL(*tracer)) {
/* Trace disabled */
return 0;
}
ASSERT(IS_TRACER_VALID(*tracer));
if (tracer == &ERTS_TRACER(p)) {
/* Tracer specified in process structure =>
* non-breakpoint trace =>
* use process flags
*/
tracee_flags = &ERTS_TRACE_FLAGS(p);
/* Is is not ideal at all to call this check twice,
it should be optimized so that only one call is made. */
if (!is_tracer_enabled(p, ERTS_PROC_LOCK_MAIN, &p->common, &tnif,
TRACE_FUN_ENABLED, am_trace_status)
|| !is_tracer_enabled(p, ERTS_PROC_LOCK_MAIN, &p->common, &tnif,
TRACE_FUN_E_CALL, am_call)) {
return 0;
}
} else {
/* Tracer not specified in process structure =>
* tracer specified in breakpoint =>
* meta trace =>
* use fixed flag set instead of process flags
*/
if (ERTS_TRACE_FLAGS(p) & F_SENSITIVE) {
/* No trace messages for sensitive processes. */
return 0;
}
meta_flags = F_TRACE_CALLS | F_NOW_TS;
tracee_flags = &meta_flags;
switch (call_enabled_tracer(*tracer,
&tnif, TRACE_FUN_ENABLED,
am_trace_status, p->common.id)) {
default:
case am_remove: *tracer = erts_tracer_nil;
case am_discard: return 0;
case am_trace:
switch (call_enabled_tracer(*tracer,
&tnif, TRACE_FUN_T_CALL,
am_call, p->common.id)) {
default:
case am_discard: return 0;
case am_trace: break;
}
break;
}
}
/*
* Because of the delayed sub-binary creation optimization introduced in
* R12B, (at most) one of arguments can be a match context instead of
* a binary. Since we don't want to handle match contexts in utility functions
* such as size_object() and copy_struct(), we must make sure that we
* temporarily convert any match contexts to sub binaries.
*/
arity = info->mfa.arity;
for (i = 0; i < arity; i++) {
Eterm arg = args[i];
if (is_boxed(arg) && header_is_bin_matchstate(*boxed_val(arg))) {
ErlBinMatchState* ms = (ErlBinMatchState *) boxed_val(arg);
ErlBinMatchBuffer* mb = &ms->mb;
Uint bit_size;
ErlSubBin *sub_bin_heap = (ErlSubBin *)HAlloc(p, ERL_SUB_BIN_SIZE);
bit_size = mb->size - mb->offset;
sub_bin_heap->thing_word = HEADER_SUB_BIN;
sub_bin_heap->size = BYTE_OFFSET(bit_size);
sub_bin_heap->bitsize = BIT_OFFSET(bit_size);
sub_bin_heap->offs = BYTE_OFFSET(mb->offset);
sub_bin_heap->bitoffs = BIT_OFFSET(mb->offset);
sub_bin_heap->is_writable = 0;
sub_bin_heap->orig = mb->orig;
arg = make_binary(sub_bin_heap);
}
transformed_args[i] = arg;
}
args = transformed_args;
/*
* If there is a PAM program, run it. Return if it fails.
*
* Some precedence rules:
*
* - No proc flags, e.g 'silent' or 'return_to'
* has any effect on meta trace.
* - The 'silent' process trace flag silences all call
* related messages, e.g 'call', 'return_to' and 'return_from'.
* - The {message,_} PAM function does not affect {return_trace}.
* - The {message,false} PAM function shall give the same
* 'call' trace message as no PAM match.
* - The {message,true} PAM function shall give the same
* 'call' trace message as a nonexistent PAM program.
*/
return_flags = 0;
if (match_spec) {
/* we have to make a copy of the tracer here as the match spec
may remove it, and we still want to generate a trace message */
erts_tracer_update(&pre_ms_tracer, *tracer);
tracer = &pre_ms_tracer;
pam_result = erts_match_set_run_trace(p, p,
match_spec, args, arity,
ERTS_PAM_TMP_RESULT, &return_flags);
}
if (tracee_flags == &meta_flags) {
/* Meta trace */
if (pam_result == am_false) {
UnUseTmpHeap(ERL_SUB_BIN_SIZE,p);
ERTS_TRACER_CLEAR(&pre_ms_tracer);
return return_flags;
}
} else {
/* Non-meta trace */
if (*tracee_flags & F_TRACE_SILENT) {
erts_match_set_release_result_trace(p, pam_result);
UnUseTmpHeap(ERL_SUB_BIN_SIZE,p);
ERTS_TRACER_CLEAR(&pre_ms_tracer);
return 0;
}
if (pam_result == am_false) {
UnUseTmpHeap(ERL_SUB_BIN_SIZE,p);
ERTS_TRACER_CLEAR(&pre_ms_tracer);
return return_flags;
}
if (local && (*tracee_flags & F_TRACE_RETURN_TO)) {
return_flags |= MATCH_SET_RETURN_TO_TRACE;
}
}
ASSERT(!ERTS_TRACER_IS_NIL(*tracer));
/*
* Build the the {M,F,A} tuple in the local heap.
* (A is arguments or arity.)
*/
if (*tracee_flags & F_TRACE_ARITY_ONLY) {
hp = HAlloc(p, 4);
mfa_tuple = make_small(arity);
} else {
hp = HAlloc(p, 4 + arity * 2);
mfa_tuple = NIL;
for (i = arity-1; i >= 0; i--) {
mfa_tuple = CONS(hp, args[i], mfa_tuple);
hp += 2;
}
}
mfa_tuple = TUPLE3(hp, info->mfa.module, info->mfa.function, mfa_tuple);
hp += 4;
/*
* Build the trace tuple and send it to the port.
*/
send_to_tracer_nif_raw(p, NULL, *tracer, *tracee_flags, p->common.id,
tnif, TRACE_FUN_T_CALL, am_call, mfa_tuple,
THE_NON_VALUE, pam_result);
if (match_spec) {
erts_match_set_release_result_trace(p, pam_result);
if (tracer == &pre_ms_tracer)
ERTS_TRACER_CLEAR(&pre_ms_tracer);
}
return return_flags;
}
/* Sends trace message:
* {trace_ts, ProcessPid, What, Data, Timestamp}
* or {trace, ProcessPid, What, Data}
*
* 'what' must be atomic, 'data' may be a deep term.
* 'c_p' is the currently executing process, may be NULL.
* 't_p' is the traced process.
*/
void
trace_proc(Process *c_p, ErtsProcLocks c_p_locks,
Process *t_p, Eterm what, Eterm data)
{
ErtsTracerNif *tnif = NULL;
if (is_tracer_enabled(NULL, 0, &t_p->common, &tnif,
TRACE_FUN_E_PROCS, what))
send_to_tracer_nif(NULL, &t_p->common, t_p->common.id, tnif, TRACE_FUN_T_PROCS,
what, data, THE_NON_VALUE, am_true);
}
/* Sends trace message:
* {trace_ts, ParentPid, spawn, ChildPid, {Mod, Func, Args}, Timestamp}
* or {trace, ParentPid, spawn, ChildPid, {Mod, Func, Args}}
*
* 'pid' is the ChildPid, 'mod' and 'func' must be atomic,
* and 'args' may be a deep term.
*/
void
trace_proc_spawn(Process *p, Eterm what, Eterm pid,
Eterm mod, Eterm func, Eterm args)
{
ErtsTracerNif *tnif = NULL;
if (is_tracer_enabled(NULL, 0,
&p->common, &tnif, TRACE_FUN_E_PROCS, what)) {
Eterm mfa;
Eterm* hp;
hp = HAlloc(p, 4);
mfa = TUPLE3(hp, mod, func, args);
hp += 4;
send_to_tracer_nif(NULL, &p->common, p->common.id, tnif, TRACE_FUN_T_PROCS,
what, pid, mfa, am_true);
}
}
void save_calls(Process *p, Export *e)
{
if ((ERTS_TRACE_FLAGS(p) & F_SENSITIVE) == 0) {
struct saved_calls *scb = ERTS_PROC_GET_SAVED_CALLS_BUF(p);
if (scb) {
Export **ct = &scb->ct[0];
int len = scb->len;
ct[scb->cur] = e;
if (++scb->cur >= len)
scb->cur = 0;
if (scb->n < len)
scb->n++;
}
}
}
/* Sends trace message:
* {trace_ts, Pid, What, Msg, Timestamp}
* or {trace, Pid, What, Msg}
*
* where 'What' must be atomic and 'Msg' is:
* [{heap_size, HeapSize}, {old_heap_size, OldHeapSize},
* {stack_size, StackSize}, {recent_size, RecentSize},
* {mbuf_size, MbufSize}]
*
* where 'HeapSize', 'OldHeapSize', 'StackSize', 'RecentSize and 'MbufSize'
* are all small (atomic) integers.
*/
void
trace_gc(Process *p, Eterm what, Uint size, Eterm msg)
{
ErtsTracerNif *tnif = NULL;
Eterm* o_hp = NULL;
Eterm* hp;
Uint sz = 0;
Eterm tup;
if (is_tracer_enabled(p, ERTS_PROC_LOCK_MAIN, &p->common, &tnif,
TRACE_FUN_E_GC, what)) {
if (is_non_value(msg)) {
(void) erts_process_gc_info(p, &sz, NULL, 0, 0);
o_hp = hp = erts_alloc(ERTS_ALC_T_TMP, (sz + 3 + 2) * sizeof(Eterm));
msg = erts_process_gc_info(p, NULL, &hp, 0, 0);
tup = TUPLE2(hp, am_wordsize, make_small(size)); hp += 3;
msg = CONS(hp, tup, msg); hp += 2;
}
send_to_tracer_nif(p, &p->common, p->common.id, tnif, TRACE_FUN_T_GC,
what, msg, THE_NON_VALUE, am_true);
if (o_hp)
erts_free(ERTS_ALC_T_TMP, o_hp);
}
}
void
monitor_long_schedule_proc(Process *p, ErtsCodeMFA *in_fp,
ErtsCodeMFA *out_fp, Uint time)
{
ErlHeapFragment *bp;
ErlOffHeap *off_heap;
Uint hsz;
Eterm *hp, list, in_mfa = am_undefined, out_mfa = am_undefined;
Eterm in_tpl, out_tpl, tmo_tpl, tmo, msg;
/*
* Size: {monitor, pid, long_schedule, [{timeout, T}, {in, {M,F,A}},{out,{M,F,A}}]} ->
* 5 (top tuple of 4), (3 (elements) * 2 (cons)) + 3 (timeout tuple of 2) + size of Timeout +
* (2 * 3 (in/out tuple of 2)) +
* 0 (unknown) or 4 (MFA tuple of 3) + 0 (unknown) or 4 (MFA tuple of 3)
* = 20 + (in_fp != NULL) ? 4 : 0 + (out_fp != NULL) ? 4 : 0 + size of Timeout
*/
hsz = 20 + ((in_fp != NULL) ? 4 : 0) + ((out_fp != NULL) ? 4 : 0);
(void) erts_bld_uint(NULL, &hsz, time);
hp = ERTS_ALLOC_SYSMSG_HEAP(hsz, &bp, &off_heap, monitor_p);
tmo = erts_bld_uint(&hp, NULL, time);
if (in_fp != NULL) {
in_mfa = TUPLE3(hp, in_fp->module, in_fp->function,
make_small(in_fp->arity));
hp +=4;
}
if (out_fp != NULL) {
out_mfa = TUPLE3(hp, out_fp->module, out_fp->function,
make_small(out_fp->arity));
hp +=4;
}
tmo_tpl = TUPLE2(hp,am_timeout, tmo);
hp += 3;
in_tpl = TUPLE2(hp,am_in,in_mfa);
hp += 3;
out_tpl = TUPLE2(hp,am_out,out_mfa);
hp += 3;
list = CONS(hp,out_tpl,NIL);
hp += 2;
list = CONS(hp,in_tpl,list);
hp += 2;
list = CONS(hp,tmo_tpl,list);
hp += 2;
msg = TUPLE4(hp, am_monitor, p->common.id, am_long_schedule, list);
hp += 5;
enqueue_sys_msg(SYS_MSG_TYPE_SYSMON, p->common.id, NIL, msg, bp);
}
void
monitor_long_schedule_port(Port *pp, ErtsPortTaskType type, Uint time)
{
ErlHeapFragment *bp;
ErlOffHeap *off_heap;
Uint hsz;
Eterm *hp, list, op;
Eterm op_tpl, tmo_tpl, tmo, msg;
/*
* Size: {monitor, port, long_schedule, [{timeout, T}, {op, Operation}]} ->
* 5 (top tuple of 4), (2 (elements) * 2 (cons)) + 3 (timeout tuple of 2)
* + size of Timeout + 3 (op tuple of 2 atoms)
* = 15 + size of Timeout
*/
hsz = 15;
(void) erts_bld_uint(NULL, &hsz, time);
hp = ERTS_ALLOC_SYSMSG_HEAP(hsz, &bp, &off_heap, monitor_p);
switch (type) {
case ERTS_PORT_TASK_PROC_SIG: op = am_proc_sig; break;
case ERTS_PORT_TASK_TIMEOUT: op = am_timeout; break;
case ERTS_PORT_TASK_INPUT: op = am_input; break;
case ERTS_PORT_TASK_OUTPUT: op = am_output; break;
case ERTS_PORT_TASK_DIST_CMD: op = am_dist_cmd; break;
default: op = am_undefined; break;
}
tmo = erts_bld_uint(&hp, NULL, time);
op_tpl = TUPLE2(hp,am_port_op,op);
hp += 3;
tmo_tpl = TUPLE2(hp,am_timeout, tmo);
hp += 3;
list = CONS(hp,op_tpl,NIL);
hp += 2;
list = CONS(hp,tmo_tpl,list);
hp += 2;
msg = TUPLE4(hp, am_monitor, pp->common.id, am_long_schedule, list);
hp += 5;
enqueue_sys_msg(SYS_MSG_TYPE_SYSMON, pp->common.id, NIL, msg, bp);
}
void
monitor_long_gc(Process *p, Uint time) {
ErlHeapFragment *bp;
ErlOffHeap *off_heap;
Uint hsz;
Eterm *hp, list, msg;
Eterm tags[] = {
am_timeout,
am_old_heap_block_size,
am_heap_block_size,
am_mbuf_size,
am_stack_size,
am_old_heap_size,
am_heap_size
};
UWord values[] = {
time,
OLD_HEAP(p) ? OLD_HEND(p) - OLD_HEAP(p) : 0,
HEAP_SIZE(p),
MBUF_SIZE(p),
STACK_START(p) - p->stop,
OLD_HEAP(p) ? OLD_HTOP(p) - OLD_HEAP(p) : 0,
HEAP_TOP(p) - HEAP_START(p)
};
#ifdef DEBUG
Eterm *hp_end;
#endif
hsz = 0;
(void) erts_bld_atom_uword_2tup_list(NULL,
&hsz,
sizeof(values)/sizeof(*values),
tags,
values);
hsz += 5 /* 4-tuple */;
hp = ERTS_ALLOC_SYSMSG_HEAP(hsz, &bp, &off_heap, monitor_p);
#ifdef DEBUG
hp_end = hp + hsz;
#endif
list = erts_bld_atom_uword_2tup_list(&hp,
NULL,
sizeof(values)/sizeof(*values),
tags,
values);
msg = TUPLE4(hp, am_monitor, p->common.id, am_long_gc, list);
#ifdef DEBUG
hp += 5 /* 4-tuple */;
ASSERT(hp == hp_end);
#endif
enqueue_sys_msg(SYS_MSG_TYPE_SYSMON, p->common.id, NIL, msg, bp);
}
void
monitor_large_heap(Process *p) {
ErlHeapFragment *bp;
ErlOffHeap *off_heap;
Uint hsz;
Eterm *hp, list, msg;
Eterm tags[] = {
am_old_heap_block_size,
am_heap_block_size,
am_mbuf_size,
am_stack_size,
am_old_heap_size,
am_heap_size
};
UWord values[] = {
OLD_HEAP(p) ? OLD_HEND(p) - OLD_HEAP(p) : 0,
HEAP_SIZE(p),
MBUF_SIZE(p),
STACK_START(p) - p->stop,
OLD_HEAP(p) ? OLD_HTOP(p) - OLD_HEAP(p) : 0,
HEAP_TOP(p) - HEAP_START(p)
};
#ifdef DEBUG
Eterm *hp_end;
#endif
hsz = 0;
(void) erts_bld_atom_uword_2tup_list(NULL,
&hsz,
sizeof(values)/sizeof(*values),
tags,
values);
hsz += 5 /* 4-tuple */;
hp = ERTS_ALLOC_SYSMSG_HEAP(hsz, &bp, &off_heap, monitor_p);
#ifdef DEBUG
hp_end = hp + hsz;
#endif
list = erts_bld_atom_uword_2tup_list(&hp,
NULL,
sizeof(values)/sizeof(*values),
tags,
values);
msg = TUPLE4(hp, am_monitor, p->common.id, am_large_heap, list);
#ifdef DEBUG
hp += 5 /* 4-tuple */;
ASSERT(hp == hp_end);
#endif
enqueue_sys_msg(SYS_MSG_TYPE_SYSMON, p->common.id, NIL, msg, bp);
}
void
monitor_generic(Process *p, Eterm type, Eterm spec) {
ErlHeapFragment *bp;
ErlOffHeap *off_heap;
Eterm *hp, msg;
hp = ERTS_ALLOC_SYSMSG_HEAP(5, &bp, &off_heap, monitor_p);
msg = TUPLE4(hp, am_monitor, p->common.id, type, spec);
hp += 5;
enqueue_sys_msg(SYS_MSG_TYPE_SYSMON, p->common.id, NIL, msg, bp);
}
/* Begin system_profile tracing */
/* Scheduler profiling */
void
profile_scheduler(Eterm scheduler_id, Eterm state) {
Eterm *hp, msg;
ErlHeapFragment *bp = NULL;
Uint hsz;
hsz = 7 + patch_ts_size(erts_system_profile_ts_type)-1;
bp = new_message_buffer(hsz);
hp = bp->mem;
erts_mtx_lock(&smq_mtx);
switch (state) {
case am_active:
active_sched++;
break;
case am_inactive:
active_sched--;
break;
default:
ASSERT(!"Invalid state");
break;
}
msg = TUPLE6(hp, am_profile, am_scheduler, scheduler_id,
state, make_small(active_sched),
NIL /* Will be overwritten by timestamp */);
hp += 7;
/* Write timestamp in element 6 of the 'msg' tuple */
hp[-1] = write_ts(erts_system_profile_ts_type, hp, bp, NULL);
enqueue_sys_msg_unlocked(SYS_MSG_TYPE_SYSPROF, NIL, NIL, msg, bp);
erts_mtx_unlock(&smq_mtx);
}
/* Port profiling */
void
trace_port_open(Port *p, Eterm calling_pid, Eterm drv_name) {
ErtsTracerNif *tnif = NULL;
ERTS_CHK_NO_PROC_LOCKS;
if (is_tracer_enabled(NULL, 0, &p->common, &tnif, TRACE_FUN_E_PORTS, am_open))
send_to_tracer_nif(NULL, &p->common, p->common.id, tnif, TRACE_FUN_T_PORTS,
am_open, calling_pid, drv_name, am_true);
}
/* Sends trace message:
* {trace_ts, PortPid, What, Data, Timestamp}
* or {trace, PortPid, What, Data}
*
* 'what' must be atomic, 'data' must be atomic.
* 't_p' is the traced port.
*/
void
trace_port(Port *t_p, Eterm what, Eterm data) {
ErtsTracerNif *tnif = NULL;
ERTS_LC_ASSERT(erts_lc_is_port_locked(t_p)
|| erts_thr_progress_is_blocking());
ERTS_CHK_NO_PROC_LOCKS;
if (is_tracer_enabled(NULL, 0, &t_p->common, &tnif, TRACE_FUN_E_PORTS, what))
send_to_tracer_nif(NULL, &t_p->common, t_p->common.id, tnif, TRACE_FUN_T_PORTS,
what, data, THE_NON_VALUE, am_true);
}
static Eterm
trace_port_tmp_binary(char *bin, Sint sz, Binary **bptrp, Eterm **hp)
{
if (sz <= ERL_ONHEAP_BIN_LIMIT) {
ErlHeapBin *hb = (ErlHeapBin *)*hp;
hb->thing_word = header_heap_bin(sz);
hb->size = sz;
sys_memcpy(hb->data, bin, sz);
*hp += heap_bin_size(sz);
return make_binary(hb);
} else {
ProcBin* pb = (ProcBin *)*hp;
Binary *bptr = erts_bin_nrml_alloc(sz);
sys_memcpy(bptr->orig_bytes, bin, sz);
pb->thing_word = HEADER_PROC_BIN;
pb->size = sz;
pb->next = NULL;
pb->val = bptr;
pb->bytes = (byte*) bptr->orig_bytes;
pb->flags = 0;
*bptrp = bptr;
*hp += PROC_BIN_SIZE;
return make_binary(pb);
}
}
/* Sends trace message:
* {trace, PortPid, 'receive', {pid(), {command, iolist()}}}
* {trace, PortPid, 'receive', {pid(), {control, pid()}}}
* {trace, PortPid, 'receive', {pid(), exit}}
*
*/
void
trace_port_receive(Port *t_p, Eterm caller, Eterm what, ...)
{
ErtsTracerNif *tnif = NULL;
ERTS_LC_ASSERT(erts_lc_is_port_locked(t_p)
|| erts_thr_progress_is_blocking());
ERTS_CHK_NO_PROC_LOCKS;
if (is_tracer_enabled(NULL, 0, &t_p->common, &tnif, TRACE_FUN_E_RECEIVE, am_receive)) {
/* We can use a stack heap here, as the nif is called in the
context of a port */
#define LOCAL_HEAP_SIZE (3 + 3 + heap_bin_size(ERL_ONHEAP_BIN_LIMIT) + 3)
DeclareTmpHeapNoproc(local_heap,LOCAL_HEAP_SIZE);
Eterm *hp, data, *orig_hp = NULL;
Binary *bptr = NULL;
va_list args;
UseTmpHeapNoproc(LOCAL_HEAP_SIZE);
hp = local_heap;
if (what == am_close) {
data = what;
} else {
Eterm arg;
va_start(args, what);
if (what == am_command) {
char *bin = va_arg(args, char *);
Sint sz = va_arg(args, Sint);
va_end(args);
arg = trace_port_tmp_binary(bin, sz, &bptr, &hp);
} else if (what == am_call || what == am_control) {
unsigned int command = va_arg(args, unsigned int);
char *bin = va_arg(args, char *);
Sint sz = va_arg(args, Sint);
Eterm cmd;
va_end(args);
arg = trace_port_tmp_binary(bin, sz, &bptr, &hp);
#if defined(ARCH_32)
if (!IS_USMALL(0, command)) {
*hp = make_pos_bignum_header(1);
BIG_DIGIT(hp, 0) = (Uint)command;
cmd = make_big(hp);
hp += 2;
} else
#endif
{
cmd = make_small((Sint)command);
}
arg = TUPLE2(hp, cmd, arg);
hp += 3;
} else if (what == am_commandv) {
ErlIOVec *evp = va_arg(args, ErlIOVec*);
int i;
va_end(args);
if ((6 + evp->vsize * (2+PROC_BIN_SIZE+ERL_SUB_BIN_SIZE)) > LOCAL_HEAP_SIZE) {
hp = erts_alloc(ERTS_ALC_T_TMP,
(6 + evp->vsize * (2+PROC_BIN_SIZE+ERL_SUB_BIN_SIZE)) * sizeof(Eterm));
orig_hp = hp;
}
arg = NIL;
/* Convert each element in the ErlIOVec to a sub bin that points
to a procbin. We don't have to increment the proc bin refc as
the port task keeps the reference alive. */
for (i = evp->vsize-1; i >= 0; i--) {
if (evp->iov[i].iov_len) {
ProcBin* pb = (ProcBin*)hp;
ErlSubBin *sb;
ASSERT(evp->binv[i]);
pb->thing_word = HEADER_PROC_BIN;
pb->val = ErlDrvBinary2Binary(evp->binv[i]);
pb->size = pb->val->orig_size;
pb->next = NULL;
pb->bytes = (byte*) pb->val->orig_bytes;
pb->flags = 0;
hp += PROC_BIN_SIZE;
sb = (ErlSubBin*) hp;
sb->thing_word = HEADER_SUB_BIN;
sb->size = evp->iov[i].iov_len;
sb->offs = (byte*)(evp->iov[i].iov_base) - pb->bytes;
sb->orig = make_binary(pb);
sb->bitoffs = 0;
sb->bitsize = 0;
sb->is_writable = 0;
hp += ERL_SUB_BIN_SIZE;
arg = CONS(hp, make_binary(sb), arg);
hp += 2;
}
}
what = am_command;
} else {
arg = va_arg(args, Eterm);
va_end(args);
}
data = TUPLE2(hp, what, arg);
hp += 3;
}
data = TUPLE2(hp, caller, data);
hp += 3;
ASSERT(hp <= (local_heap + LOCAL_HEAP_SIZE) || orig_hp);
send_to_tracer_nif(NULL, &t_p->common, t_p->common.id, tnif,
TRACE_FUN_T_RECEIVE,
am_receive, data, THE_NON_VALUE, am_true);
if (bptr)
erts_bin_release(bptr);
if (orig_hp)
erts_free(ERTS_ALC_T_TMP, orig_hp);
UnUseTmpHeapNoproc(LOCAL_HEAP_SIZE);
}
#undef LOCAL_HEAP_SIZE
}
void
trace_port_send(Port *t_p, Eterm receiver, Eterm msg, int exists)
{
ErtsTracerNif *tnif = NULL;
Eterm op = exists ? am_send : am_send_to_non_existing_process;
ERTS_LC_ASSERT(erts_lc_is_port_locked(t_p)
|| erts_thr_progress_is_blocking());
ERTS_CHK_NO_PROC_LOCKS;
if (is_tracer_enabled(NULL, 0, &t_p->common, &tnif, TRACE_FUN_E_SEND, op))
send_to_tracer_nif(NULL, &t_p->common, t_p->common.id, tnif, TRACE_FUN_T_SEND,
op, msg, receiver, am_true);
}
void trace_port_send_binary(Port *t_p, Eterm to, Eterm what, char *bin, Sint sz)
{
ErtsTracerNif *tnif = NULL;
ERTS_LC_ASSERT(erts_lc_is_port_locked(t_p)
|| erts_thr_progress_is_blocking());
ERTS_CHK_NO_PROC_LOCKS;
if (is_tracer_enabled(NULL, 0, &t_p->common, &tnif, TRACE_FUN_E_SEND, am_send)) {
Eterm msg;
Binary* bptr = NULL;
#define LOCAL_HEAP_SIZE (3 + 3 + heap_bin_size(ERL_ONHEAP_BIN_LIMIT))
DeclareTmpHeapNoproc(local_heap,LOCAL_HEAP_SIZE);
Eterm *hp;
ERTS_CT_ASSERT(heap_bin_size(ERL_ONHEAP_BIN_LIMIT) >= PROC_BIN_SIZE);
UseTmpHeapNoproc(LOCAL_HEAP_SIZE);
hp = local_heap;
msg = trace_port_tmp_binary(bin, sz, &bptr, &hp);
msg = TUPLE2(hp, what, msg);
hp += 3;
msg = TUPLE2(hp, t_p->common.id, msg);
hp += 3;
send_to_tracer_nif(NULL, &t_p->common, t_p->common.id, tnif, TRACE_FUN_T_SEND,
am_send, msg, to, am_true);
if (bptr)
erts_bin_release(bptr);
UnUseTmpHeapNoproc(LOCAL_HEAP_SIZE);
#undef LOCAL_HEAP_SIZE
}
}
/* Send {trace_ts, Pid, What, {Mod, Func, Arity}, Timestamp}
* or {trace, Pid, What, {Mod, Func, Arity}}
*
* where 'What' is supposed to be 'in' or 'out' and
* where 'where' is supposed to be location (callback)
* for the port.
*/
void
trace_sched_ports(Port *p, Eterm what) {
trace_sched_ports_where(p, what, make_small(0));
}
void
trace_sched_ports_where(Port *t_p, Eterm what, Eterm where) {
ErtsTracerNif *tnif = NULL;
ERTS_LC_ASSERT(erts_lc_is_port_locked(t_p)
|| erts_thr_progress_is_blocking());
ERTS_CHK_NO_PROC_LOCKS;
if (is_tracer_enabled(NULL, 0, &t_p->common, &tnif, TRACE_FUN_E_SCHED_PORT, what))
send_to_tracer_nif(NULL, &t_p->common, t_p->common.id,
tnif, TRACE_FUN_T_SCHED_PORT,
what, where, THE_NON_VALUE, am_true);
}
/* Port profiling */
void
profile_runnable_port(Port *p, Eterm status) {
Eterm *hp, msg;
ErlHeapFragment *bp = NULL;
Eterm count = make_small(0);
Uint hsz;
hsz = 6 + patch_ts_size(erts_system_profile_ts_type)-1;
bp = new_message_buffer(hsz);
hp = bp->mem;
erts_mtx_lock(&smq_mtx);
msg = TUPLE5(hp, am_profile, p->common.id, status, count,
NIL /* Will be overwritten by timestamp */);
hp += 6;
/* Write timestamp in element 5 of the 'msg' tuple */
hp[-1] = write_ts(erts_system_profile_ts_type, hp, bp, NULL);
enqueue_sys_msg_unlocked(SYS_MSG_TYPE_SYSPROF, p->common.id, NIL, msg, bp);
erts_mtx_unlock(&smq_mtx);
}
/* Process profiling */
void
profile_runnable_proc(Process *p, Eterm status){
Eterm *hp, msg;
Eterm where = am_undefined;
ErlHeapFragment *bp = NULL;
ErtsCodeMFA *cmfa = NULL;
ErtsThrPrgrDelayHandle dhndl;
Uint hsz = 4 + 6 + patch_ts_size(erts_system_profile_ts_type)-1;
/* Assumptions:
* We possibly don't have the MAIN_LOCK for the process p here.
* We assume that we can read from p->current and p->i atomically
*/
dhndl = erts_thr_progress_unmanaged_delay(); /* suspend purge operations */
if (!ERTS_PROC_IS_EXITING(p)) {
if (p->current) {
cmfa = p->current;
} else {
cmfa = find_function_from_pc(p->i);
}
}
if (!cmfa) {
hsz -= 4;
}
bp = new_message_buffer(hsz);
hp = bp->mem;
if (cmfa) {
where = TUPLE3(hp, cmfa->module, cmfa->function,
make_small(cmfa->arity));
hp += 4;
} else {
where = make_small(0);
}
erts_thr_progress_unmanaged_continue(dhndl);
erts_mtx_lock(&smq_mtx);
msg = TUPLE5(hp, am_profile, p->common.id, status, where,
NIL /* Will be overwritten by timestamp */);
hp += 6;
/* Write timestamp in element 5 of the 'msg' tuple */
hp[-1] = write_ts(erts_system_profile_ts_type, hp, bp, NULL);
enqueue_sys_msg_unlocked(SYS_MSG_TYPE_SYSPROF, p->common.id, NIL, msg, bp);
erts_mtx_unlock(&smq_mtx);
}
/* End system_profile tracing */
typedef struct ErtsSysMsgQ_ ErtsSysMsgQ;
struct ErtsSysMsgQ_ {
ErtsSysMsgQ *next;
enum ErtsSysMsgType type;
Eterm from;
Eterm to;
Eterm msg;
ErlHeapFragment *bp;
};
static ErtsSysMsgQ *sys_message_queue;
static ErtsSysMsgQ *sys_message_queue_end;
static erts_tid_t sys_msg_dispatcher_tid;
static erts_cnd_t smq_cnd;
ERTS_QUALLOC_IMPL(smq_element, ErtsSysMsgQ, 20, ERTS_ALC_T_SYS_MSG_Q)
static void
enqueue_sys_msg_unlocked(enum ErtsSysMsgType type,
Eterm from,
Eterm to,
Eterm msg,
ErlHeapFragment *bp)
{
ErtsSysMsgQ *smqp;
smqp = smq_element_alloc();
smqp->next = NULL;
smqp->type = type;
smqp->from = from;
smqp->to = to;
smqp->msg = msg;
smqp->bp = bp;
if (sys_message_queue_end) {
ASSERT(sys_message_queue);
sys_message_queue_end->next = smqp;
}
else {
ASSERT(!sys_message_queue);
sys_message_queue = smqp;
}
sys_message_queue_end = smqp;
erts_cnd_signal(&smq_cnd);
}
static void
enqueue_sys_msg(enum ErtsSysMsgType type,
Eterm from,
Eterm to,
Eterm msg,
ErlHeapFragment *bp)
{
erts_mtx_lock(&smq_mtx);
enqueue_sys_msg_unlocked(type, from, to, msg, bp);
erts_mtx_unlock(&smq_mtx);
}
Eterm
erts_get_system_logger(void)
{
return (Eterm)erts_atomic_read_nob(&system_logger);
}
Eterm
erts_set_system_logger(Eterm logger)
{
if (logger != am_logger && logger != am_undefined && !is_internal_pid(logger))
return THE_NON_VALUE;
return (Eterm)erts_atomic_xchg_nob(&system_logger, logger);
}
void
erts_queue_error_logger_message(Eterm from, Eterm msg, ErlHeapFragment *bp)
{
enqueue_sys_msg(SYS_MSG_TYPE_ERRLGR, from, erts_get_system_logger(), msg, bp);
}
void
erts_send_sys_msg_proc(Eterm from, Eterm to, Eterm msg, ErlHeapFragment *bp)
{
ASSERT(is_internal_pid(to));
enqueue_sys_msg(SYS_MSG_TYPE_PROC_MSG, from, to, msg, bp);
}
#ifdef DEBUG_PRINTOUTS
static void
print_msg_type(ErtsSysMsgQ *smqp)
{
switch (smqp->type) {
case SYS_MSG_TYPE_SYSMON:
erts_fprintf(stderr, "SYSMON ");
break;
case SYS_MSG_TYPE_SYSPROF:
erts_fprintf(stderr, "SYSPROF ");
break;
case SYS_MSG_TYPE_ERRLGR:
erts_fprintf(stderr, "ERRLGR ");
break;
case SYS_MSG_TYPE_PROC_MSG:
erts_fprintf(stderr, "PROC_MSG ");
break;
default:
erts_fprintf(stderr, "??? ");
break;
}
}
#endif
static void
sys_msg_disp_failure(ErtsSysMsgQ *smqp, Eterm receiver)
{
switch (smqp->type) {
case SYS_MSG_TYPE_SYSMON:
if (receiver == NIL
&& !erts_system_monitor_long_gc
&& !erts_system_monitor_long_schedule
&& !erts_system_monitor_large_heap
&& !erts_system_monitor_flags.busy_port
&& !erts_system_monitor_flags.busy_dist_port)
break; /* Everything is disabled */
erts_thr_progress_block();
if (system_monitor == receiver || receiver == NIL)
erts_system_monitor_clear(NULL);
erts_thr_progress_unblock();
break;
case SYS_MSG_TYPE_SYSPROF:
if (receiver == NIL
&& !erts_system_profile_flags.runnable_procs
&& !erts_system_profile_flags.runnable_ports
&& !erts_system_profile_flags.exclusive
&& !erts_system_profile_flags.scheduler)
break;
/* Block system to clear flags */
erts_thr_progress_block();
if (system_profile == receiver || receiver == NIL) {
erts_system_profile_clear(NULL);
}
erts_thr_progress_unblock();
break;
case SYS_MSG_TYPE_ERRLGR: {
char *no_elgger = "(no logger present)";
Eterm *tp;
Eterm tag;
if (is_not_tuple(smqp->msg)) {
unexpected_elmsg:
erts_fprintf(stderr,
"%s unexpected logger message: %T\n",
no_elgger,
smqp->msg);
}
tp = tuple_val(smqp->msg);
if (arityval(tp[0]) != 2)
goto unexpected_elmsg;
if (is_not_tuple(tp[2]))
goto unexpected_elmsg;
tp = tuple_val(tp[2]);
if (arityval(tp[0]) != 3)
goto unexpected_elmsg;
tag = tp[1];
if (is_not_tuple(tp[3]))
goto unexpected_elmsg;
tp = tuple_val(tp[3]);
if (arityval(tp[0]) != 3)
goto unexpected_elmsg;
if (is_not_list(tp[3]))
goto unexpected_elmsg;
erts_fprintf(stderr, "%s %T: %T\n",
no_elgger, tag, CAR(list_val(tp[3])));
break;
}
case SYS_MSG_TYPE_PROC_MSG:
break;
default:
ASSERT(0);
}
}
static void
sys_msg_dispatcher_wakeup(void *vwait_p)
{
int *wait_p = (int *) vwait_p;
erts_mtx_lock(&smq_mtx);
*wait_p = 0;
erts_cnd_signal(&smq_cnd);
erts_mtx_unlock(&smq_mtx);
}
static void
sys_msg_dispatcher_prep_wait(void *vwait_p)
{
int *wait_p = (int *) vwait_p;
erts_mtx_lock(&smq_mtx);
*wait_p = 1;
erts_mtx_unlock(&smq_mtx);
}
static void
sys_msg_dispatcher_fin_wait(void *vwait_p)
{
int *wait_p = (int *) vwait_p;
erts_mtx_lock(&smq_mtx);
*wait_p = 0;
erts_mtx_unlock(&smq_mtx);
}
static void
sys_msg_dispatcher_wait(void *vwait_p)
{
int *wait_p = (int *) vwait_p;
erts_mtx_lock(&smq_mtx);
while (*wait_p)
erts_cnd_wait(&smq_cnd, &smq_mtx);
erts_mtx_unlock(&smq_mtx);
}
static void *
sys_msg_dispatcher_func(void *unused)
{
ErtsThrPrgrCallbacks callbacks;
ErtsSysMsgQ *local_sys_message_queue = NULL;
ErtsThrPrgrData *tpd;
int wait = 0;
#ifdef ERTS_ENABLE_LOCK_CHECK
erts_lc_set_thread_name("system message dispatcher");
#endif
callbacks.arg = (void *) &wait;
callbacks.wakeup = sys_msg_dispatcher_wakeup;
callbacks.prepare_wait = sys_msg_dispatcher_prep_wait;
callbacks.wait = sys_msg_dispatcher_wait;
callbacks.finalize_wait = sys_msg_dispatcher_fin_wait;
tpd = erts_thr_progress_register_managed_thread(NULL, &callbacks, 0);
while (1) {
int end_wait = 0;
ErtsSysMsgQ *smqp;
ERTS_LC_ASSERT(!erts_thr_progress_is_blocking());
erts_mtx_lock(&smq_mtx);
/* Free previously used queue ... */
while (local_sys_message_queue) {
smqp = local_sys_message_queue;
local_sys_message_queue = smqp->next;
smq_element_free(smqp);
}
/* Fetch current trace message queue ... */
if (!sys_message_queue) {
erts_mtx_unlock(&smq_mtx);
end_wait = 1;
erts_thr_progress_active(tpd, 0);
erts_thr_progress_prepare_wait(tpd);
erts_mtx_lock(&smq_mtx);
}
while (!sys_message_queue)
erts_cnd_wait(&smq_cnd, &smq_mtx);
local_sys_message_queue = sys_message_queue;
sys_message_queue = NULL;
sys_message_queue_end = NULL;
erts_mtx_unlock(&smq_mtx);
if (end_wait) {
erts_thr_progress_finalize_wait(tpd);
erts_thr_progress_active(tpd, 1);
}
/* Send trace messages ... */
ASSERT(local_sys_message_queue);
for (smqp = local_sys_message_queue; smqp; smqp = smqp->next) {
Eterm receiver;
ErtsProcLocks proc_locks = ERTS_PROC_LOCKS_MSG_SEND;
Process *proc = NULL;
Port *port = NULL;
if (erts_thr_progress_update(tpd))
erts_thr_progress_leader_update(tpd);
#ifdef DEBUG_PRINTOUTS
print_msg_type(smqp);
#endif
switch (smqp->type) {
case SYS_MSG_TYPE_PROC_MSG:
receiver = smqp->to;
break;
case SYS_MSG_TYPE_SYSMON:
receiver = erts_get_system_monitor();
if (smqp->from == receiver) {
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "MSG=%T to %T... ",
smqp->msg, receiver);
#endif
goto drop_sys_msg;
}
break;
case SYS_MSG_TYPE_SYSPROF:
receiver = erts_get_system_profile();
if (smqp->from == receiver) {
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "MSG=%T to %T... ",
smqp->msg, receiver);
#endif
goto drop_sys_msg;
}
break;
case SYS_MSG_TYPE_ERRLGR:
receiver = smqp->to;
break;
default:
receiver = NIL;
break;
}
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "MSG=%T to %T... ", smqp->msg, receiver);
#endif
if (is_internal_pid(receiver)) {
proc = erts_pid2proc(NULL, 0, receiver, proc_locks);
if (!proc) {
if (smqp->type == SYS_MSG_TYPE_ERRLGR) {
/* Bad logger process, send to kernel 'logger' process */
erts_set_system_logger(am_logger);
receiver = erts_get_system_logger();
goto logger;
} else {
/* Bad tracer */
goto failure;
}
}
else {
ErtsMessage *mp;
queue_proc_msg:
mp = erts_alloc_message(0, NULL);
mp->data.heap_frag = smqp->bp;
erts_queue_message(proc,proc_locks,mp,smqp->msg,am_system);
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "delivered\n");
#endif
erts_proc_unlock(proc, proc_locks);
}
} else if (receiver == am_logger) {
logger:
proc = erts_whereis_process(NULL,0,am_logger,proc_locks,0);
if (!proc)
goto failure;
else if (smqp->from == proc->common.id)
goto drop_sys_msg;
else
goto queue_proc_msg;
}
else if (receiver == am_undefined) {
goto drop_sys_msg;
}
else if (is_internal_port(receiver)) {
port = erts_thr_id2port_sflgs(receiver,
ERTS_PORT_SFLGS_INVALID_TRACER_LOOKUP);
if (!port)
goto failure;
else {
write_sys_msg_to_port(receiver,
port,
smqp->from,
smqp->type,
smqp->msg);
if (port->control_flags & PORT_CONTROL_FLAG_HEAVY)
port->control_flags &= ~PORT_CONTROL_FLAG_HEAVY;
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "delivered\n");
#endif
erts_thr_port_release(port);
if (smqp->bp)
free_message_buffer(smqp->bp);
}
}
else {
failure:
sys_msg_disp_failure(smqp, receiver);
drop_sys_msg:
if (proc)
erts_proc_unlock(proc, proc_locks);
if (smqp->bp)
free_message_buffer(smqp->bp);
#ifdef DEBUG_PRINTOUTS
erts_fprintf(stderr, "dropped\n");
#endif
}
}
}
return NULL;
}
void
erts_foreach_sys_msg_in_q(void (*func)(Eterm,
Eterm,
Eterm,
ErlHeapFragment *))
{
ErtsSysMsgQ *sm;
erts_mtx_lock(&smq_mtx);
for (sm = sys_message_queue; sm; sm = sm->next) {
Eterm to;
switch (sm->type) {
case SYS_MSG_TYPE_SYSMON:
to = erts_get_system_monitor();
break;
case SYS_MSG_TYPE_SYSPROF:
to = erts_get_system_profile();
break;
case SYS_MSG_TYPE_ERRLGR:
to = erts_get_system_logger();
break;
default:
to = NIL;
break;
}
(*func)(sm->from, to, sm->msg, sm->bp);
}
erts_mtx_unlock(&smq_mtx);
}
static void
init_sys_msg_dispatcher(void)
{
erts_thr_opts_t thr_opts = ERTS_THR_OPTS_DEFAULT_INITER;
thr_opts.detached = 1;
thr_opts.name = "sys_msg_dispatcher";
init_smq_element_alloc();
sys_message_queue = NULL;
sys_message_queue_end = NULL;
erts_cnd_init(&smq_cnd);
erts_mtx_init(&smq_mtx, "sys_msg_q", NIL,
ERTS_LOCK_FLAGS_PROPERTY_STATIC | ERTS_LOCK_FLAGS_CATEGORY_DEBUG);
erts_thr_create(&sys_msg_dispatcher_tid,
sys_msg_dispatcher_func,
NULL,
&thr_opts);
}
#include "erl_nif.h"
typedef struct {
char *name;
Uint arity;
ErlNifFunc *cb;
} ErtsTracerType;
struct ErtsTracerNif_ {
HashBucket hb;
Eterm module;
struct erl_module_nif* nif_mod;
ErtsTracerType tracers[NIF_TRACER_TYPES];
};
static void init_tracer_template(ErtsTracerNif *tnif) {
/* default tracer functions */
tnif->tracers[TRACE_FUN_DEFAULT].name = "trace";
tnif->tracers[TRACE_FUN_DEFAULT].arity = 5;
tnif->tracers[TRACE_FUN_DEFAULT].cb = NULL;
tnif->tracers[TRACE_FUN_ENABLED].name = "enabled";
tnif->tracers[TRACE_FUN_ENABLED].arity = 3;
tnif->tracers[TRACE_FUN_ENABLED].cb = NULL;
/* specific tracer functions */
tnif->tracers[TRACE_FUN_T_SEND].name = "trace_send";
tnif->tracers[TRACE_FUN_T_SEND].arity = 5;
tnif->tracers[TRACE_FUN_T_SEND].cb = NULL;
tnif->tracers[TRACE_FUN_T_RECEIVE].name = "trace_receive";
tnif->tracers[TRACE_FUN_T_RECEIVE].arity = 5;
tnif->tracers[TRACE_FUN_T_RECEIVE].cb = NULL;
tnif->tracers[TRACE_FUN_T_CALL].name = "trace_call";
tnif->tracers[TRACE_FUN_T_CALL].arity = 5;
tnif->tracers[TRACE_FUN_T_CALL].cb = NULL;
tnif->tracers[TRACE_FUN_T_SCHED_PROC].name = "trace_running_procs";
tnif->tracers[TRACE_FUN_T_SCHED_PROC].arity = 5;
tnif->tracers[TRACE_FUN_T_SCHED_PROC].cb = NULL;
tnif->tracers[TRACE_FUN_T_SCHED_PORT].name = "trace_running_ports";
tnif->tracers[TRACE_FUN_T_SCHED_PORT].arity = 5;
tnif->tracers[TRACE_FUN_T_SCHED_PORT].cb = NULL;
tnif->tracers[TRACE_FUN_T_GC].name = "trace_garbage_collection";
tnif->tracers[TRACE_FUN_T_GC].arity = 5;
tnif->tracers[TRACE_FUN_T_GC].cb = NULL;
tnif->tracers[TRACE_FUN_T_PROCS].name = "trace_procs";
tnif->tracers[TRACE_FUN_T_PROCS].arity = 5;
tnif->tracers[TRACE_FUN_T_PROCS].cb = NULL;
tnif->tracers[TRACE_FUN_T_PORTS].name = "trace_ports";
tnif->tracers[TRACE_FUN_T_PORTS].arity = 5;
tnif->tracers[TRACE_FUN_T_PORTS].cb = NULL;
/* specific enabled functions */
tnif->tracers[TRACE_FUN_E_SEND].name = "enabled_send";
tnif->tracers[TRACE_FUN_E_SEND].arity = 3;
tnif->tracers[TRACE_FUN_E_SEND].cb = NULL;
tnif->tracers[TRACE_FUN_E_RECEIVE].name = "enabled_receive";
tnif->tracers[TRACE_FUN_E_RECEIVE].arity = 3;
tnif->tracers[TRACE_FUN_E_RECEIVE].cb = NULL;
tnif->tracers[TRACE_FUN_E_CALL].name = "enabled_call";
tnif->tracers[TRACE_FUN_E_CALL].arity = 3;
tnif->tracers[TRACE_FUN_E_CALL].cb = NULL;
tnif->tracers[TRACE_FUN_E_SCHED_PROC].name = "enabled_running_procs";
tnif->tracers[TRACE_FUN_E_SCHED_PROC].arity = 3;
tnif->tracers[TRACE_FUN_E_SCHED_PROC].cb = NULL;
tnif->tracers[TRACE_FUN_E_SCHED_PORT].name = "enabled_running_ports";
tnif->tracers[TRACE_FUN_E_SCHED_PORT].arity = 3;
tnif->tracers[TRACE_FUN_E_SCHED_PORT].cb = NULL;
tnif->tracers[TRACE_FUN_E_GC].name = "enabled_garbage_collection";
tnif->tracers[TRACE_FUN_E_GC].arity = 3;
tnif->tracers[TRACE_FUN_E_GC].cb = NULL;
tnif->tracers[TRACE_FUN_E_PROCS].name = "enabled_procs";
tnif->tracers[TRACE_FUN_E_PROCS].arity = 3;
tnif->tracers[TRACE_FUN_E_PROCS].cb = NULL;
tnif->tracers[TRACE_FUN_E_PORTS].name = "enabled_ports";
tnif->tracers[TRACE_FUN_E_PORTS].arity = 3;
tnif->tracers[TRACE_FUN_E_PORTS].cb = NULL;
}
static Hash *tracer_hash = NULL;
static erts_rwmtx_t tracer_mtx;
static ErtsTracerNif *
load_tracer_nif(const ErtsTracer tracer)
{
Module* mod = erts_get_module(ERTS_TRACER_MODULE(tracer),
erts_active_code_ix());
struct erl_module_instance *instance;
ErlNifFunc *funcs;
int num_of_funcs;
ErtsTracerNif tnif_tmpl, *tnif;
ErtsTracerType *tracers;
int i,j;
if (!mod || !mod->curr.nif) {
return NULL;
}
instance = &mod->curr;
init_tracer_template(&tnif_tmpl);
tnif_tmpl.nif_mod = instance->nif;
tnif_tmpl.module = ERTS_TRACER_MODULE(tracer);
tracers = tnif_tmpl.tracers;
num_of_funcs = erts_nif_get_funcs(instance->nif, &funcs);
for(i = 0; i < num_of_funcs; i++) {
for (j = 0; j < NIF_TRACER_TYPES; j++) {
if (sys_strcmp(tracers[j].name, funcs[i].name) == 0 && tracers[j].arity == funcs[i].arity) {
tracers[j].cb = &(funcs[i]);
break;
}
}
}
if (tracers[TRACE_FUN_DEFAULT].cb == NULL || tracers[TRACE_FUN_ENABLED].cb == NULL ) {
return NULL;
}
erts_rwmtx_rwlock(&tracer_mtx);
tnif = hash_put(tracer_hash, &tnif_tmpl);
erts_rwmtx_rwunlock(&tracer_mtx);
return tnif;
}
static ERTS_INLINE ErtsTracerNif *
lookup_tracer_nif(const ErtsTracer tracer)
{
ErtsTracerNif tnif_tmpl;
ErtsTracerNif *tnif;
tnif_tmpl.module = ERTS_TRACER_MODULE(tracer);
erts_rwmtx_rlock(&tracer_mtx);
if ((tnif = hash_get(tracer_hash, &tnif_tmpl)) == NULL) {
erts_rwmtx_runlock(&tracer_mtx);
tnif = load_tracer_nif(tracer);
ASSERT(!tnif || tnif->nif_mod);
return tnif;
}
erts_rwmtx_runlock(&tracer_mtx);
ASSERT(tnif->nif_mod);
return tnif;
}
/* This function converts an Erlang tracer term to ErtsTracer.
It returns THE_NON_VALUE if an invalid tracer term was given.
Accepted input is:
pid() || port() || {prefix, pid()} || {prefix, port()} ||
{prefix, atom(), term()} || {atom(), term()}
*/
ErtsTracer
erts_term_to_tracer(Eterm prefix, Eterm t)
{
ErtsTracer tracer = erts_tracer_nil;
ASSERT(is_atom(prefix) || prefix == THE_NON_VALUE);
if (!is_nil(t)) {
Eterm module = am_erl_tracer, state = THE_NON_VALUE;
Eterm hp[2];
if (is_tuple(t)) {
Eterm *tp = tuple_val(t);
if (prefix != THE_NON_VALUE) {
if (arityval(tp[0]) == 2 && tp[1] == prefix)
t = tp[2];
else if (arityval(tp[0]) == 3 && tp[1] == prefix && is_atom(tp[2])) {
module = tp[2];
state = tp[3];
}
} else {
if (arityval(tp[0]) == 2 && is_atom(tp[1])) {
module = tp[1];
state = tp[2];
}
}
}
if (state == THE_NON_VALUE && (is_internal_pid(t) || is_internal_port(t)))
state = t;
if (state == THE_NON_VALUE)
return THE_NON_VALUE;
erts_tracer_update(&tracer, CONS(hp, module, state));
}
if (!lookup_tracer_nif(tracer)) {
ASSERT(ERTS_TRACER_MODULE(tracer) != am_erl_tracer);
ERTS_TRACER_CLEAR(&tracer);
return THE_NON_VALUE;
}
return tracer;
}
Eterm
erts_tracer_to_term(Process *p, ErtsTracer tracer)
{
if (ERTS_TRACER_IS_NIL(tracer))
return am_false;
if (ERTS_TRACER_MODULE(tracer) == am_erl_tracer)
/* Have to manage these specifically in order to be
backwards compatible */
return ERTS_TRACER_STATE(tracer);
else {
Eterm *hp = HAlloc(p, 3);
return TUPLE2(hp, ERTS_TRACER_MODULE(tracer),
copy_object(ERTS_TRACER_STATE(tracer), p));
}
}
Eterm
erts_build_tracer_to_term(Eterm **hpp, ErlOffHeap *ohp, Uint *szp, ErtsTracer tracer)
{
Eterm res;
Eterm state;
Uint sz;
if (ERTS_TRACER_IS_NIL(tracer))
return am_false;
state = ERTS_TRACER_STATE(tracer);
sz = is_immed(state) ? 0 : size_object(state);
if (szp)
*szp += sz;
if (hpp)
res = is_immed(state) ? state : copy_struct(state, sz, hpp, ohp);
else
res = THE_NON_VALUE;
if (ERTS_TRACER_MODULE(tracer) != am_erl_tracer) {
if (szp)
*szp += 3;
if (hpp) {
res = TUPLE2(*hpp, ERTS_TRACER_MODULE(tracer), res);
*hpp += 3;
}
}
return res;
}
static ERTS_INLINE int
send_to_tracer_nif_raw(Process *c_p, Process *tracee,
const ErtsTracer tracer, Uint tracee_flags,
Eterm t_p_id, ErtsTracerNif *tnif,
enum ErtsTracerOpt topt,
Eterm tag, Eterm msg, Eterm extra, Eterm pam_result)
{
if (tnif || (tnif = lookup_tracer_nif(tracer)) != NULL) {
#define MAP_SIZE 4
Eterm argv[5], local_heap[3+MAP_SIZE /* values */ + (MAP_SIZE+1 /* keys */)];
flatmap_t *map = (flatmap_t*)(local_heap+(MAP_SIZE+1));
Eterm *map_values = flatmap_get_values(map);
Eterm *map_keys = local_heap + 1;
Uint map_elem_count = 0;
topt = (tnif->tracers[topt].cb) ? topt : TRACE_FUN_DEFAULT;
ASSERT(topt < NIF_TRACER_TYPES);
argv[0] = tag;
argv[1] = ERTS_TRACER_STATE(tracer);
argv[2] = t_p_id;
argv[3] = msg;
argv[4] = make_flatmap(map);
map->thing_word = MAP_HEADER_FLATMAP;
if (extra != THE_NON_VALUE) {
map_keys[map_elem_count] = am_extra;
map_values[map_elem_count++] = extra;
}
if (pam_result != am_true) {
map_keys[map_elem_count] = am_match_spec_result;
map_values[map_elem_count++] = pam_result;
}
if (tracee_flags & F_TRACE_SCHED_NO) {
map_keys[map_elem_count] = am_scheduler_id;
map_values[map_elem_count++] = make_small(erts_get_scheduler_id());
}
map_keys[map_elem_count] = am_timestamp;
if (tracee_flags & F_NOW_TS)
#ifdef HAVE_ERTS_NOW_CPU
if (erts_cpu_timestamp)
map_values[map_elem_count++] = am_cpu_timestamp;
else
#endif
map_values[map_elem_count++] = am_timestamp;
else if (tracee_flags & F_STRICT_MON_TS)
map_values[map_elem_count++] = am_strict_monotonic;
else if (tracee_flags & F_MON_TS)
map_values[map_elem_count++] = am_monotonic;
map->size = map_elem_count;
map->keys = make_tuple(local_heap);
local_heap[0] = make_arityval(map_elem_count);
#undef MAP_SIZE
erts_nif_call_function(c_p, tracee ? tracee : c_p,
tnif->nif_mod,
tnif->tracers[topt].cb,
tnif->tracers[topt].arity,
argv);
}
return 1;
}
static ERTS_INLINE int
send_to_tracer_nif(Process *c_p, ErtsPTabElementCommon *t_p,
Eterm t_p_id, ErtsTracerNif *tnif, enum ErtsTracerOpt topt,
Eterm tag, Eterm msg, Eterm extra, Eterm pam_result)
{
#if defined(ERTS_ENABLE_LOCK_CHECK)
if (c_p) {
/* We have to hold the main lock of the currently executing process */
erts_proc_lc_chk_have_proc_locks(c_p, ERTS_PROC_LOCK_MAIN);
}
if (is_internal_pid(t_p->id)) {
/* We have to have at least one lock */
ERTS_LC_ASSERT(erts_proc_lc_my_proc_locks((Process*)t_p) & ERTS_PROC_LOCKS_ALL);
} else {
ASSERT(is_internal_port(t_p->id));
ERTS_LC_ASSERT(erts_lc_is_port_locked((Port*)t_p));
}
#endif
return send_to_tracer_nif_raw(c_p,
is_internal_pid(t_p->id) ? (Process*)t_p : NULL,
t_p->tracer, t_p->trace_flags,
t_p_id, tnif, topt, tag, msg, extra,
pam_result);
}
static ERTS_INLINE Eterm
call_enabled_tracer(const ErtsTracer tracer,
ErtsTracerNif **tnif_ret,
enum ErtsTracerOpt topt,
Eterm tag, Eterm t_p_id) {
ErtsTracerNif *tnif = lookup_tracer_nif(tracer);
if (tnif) {
Eterm argv[] = {tag, ERTS_TRACER_STATE(tracer), t_p_id},
ret;
topt = (tnif->tracers[topt].cb) ? topt : TRACE_FUN_ENABLED;
ASSERT(topt < NIF_TRACER_TYPES);
ASSERT(tnif->tracers[topt].cb != NULL);
if (tnif_ret) *tnif_ret = tnif;
ret = erts_nif_call_function(NULL, NULL, tnif->nif_mod,
tnif->tracers[topt].cb,
tnif->tracers[topt].arity,
argv);
if (tag == am_trace_status && ret != am_remove)
return am_trace;
ASSERT(tag == am_trace_status || ret != am_remove);
return ret;
}
return tag == am_trace_status ? am_remove : am_discard;
}
static int
is_tracer_enabled(Process* c_p, ErtsProcLocks c_p_locks,
ErtsPTabElementCommon *t_p,
ErtsTracerNif **tnif_ret,
enum ErtsTracerOpt topt, Eterm tag) {
Eterm nif_result;
#if defined(ERTS_ENABLE_LOCK_CHECK)
if (c_p)
ERTS_LC_ASSERT(erts_proc_lc_my_proc_locks(c_p) == c_p_locks
|| erts_thr_progress_is_blocking());
if (is_internal_pid(t_p->id)) {
/* We have to have at least one lock */
ERTS_LC_ASSERT(erts_proc_lc_my_proc_locks((Process*)t_p) & ERTS_PROC_LOCKS_ALL
|| erts_thr_progress_is_blocking());
} else {
ASSERT(is_internal_port(t_p->id));
ERTS_LC_ASSERT(erts_lc_is_port_locked((Port*)t_p)
|| erts_thr_progress_is_blocking());
}
#endif
nif_result = call_enabled_tracer(t_p->tracer, tnif_ret, topt, tag, t_p->id);
switch (nif_result) {
case am_discard: return 0;
case am_trace: return 1;
case THE_NON_VALUE:
case am_remove: ASSERT(tag == am_trace_status); break;
default:
/* only am_remove should be returned, but if
something else is returned we fall-through
and remove the tracer. */
ASSERT(0);
}
/* Only remove tracer on (self() or ports) AND we are on a normal scheduler */
if (is_internal_port(t_p->id) || (c_p && c_p->common.id == t_p->id)) {
ErtsSchedulerData *esdp = erts_get_scheduler_data();
ErtsProcLocks c_p_xlocks = 0;
if (esdp && !ERTS_SCHEDULER_IS_DIRTY(esdp)) {
if (is_internal_pid(t_p->id)) {
ERTS_LC_ASSERT(erts_proc_lc_my_proc_locks(c_p) & ERTS_PROC_LOCK_MAIN);
if (c_p_locks != ERTS_PROC_LOCKS_ALL) {
c_p_xlocks = ~c_p_locks & ERTS_PROC_LOCKS_ALL;
if (erts_proc_trylock(c_p, c_p_xlocks) == EBUSY) {
erts_proc_unlock(c_p, c_p_locks & ~ERTS_PROC_LOCK_MAIN);
erts_proc_lock(c_p, ERTS_PROC_LOCKS_ALL_MINOR);
}
}
}
erts_tracer_replace(t_p, erts_tracer_nil);
t_p->trace_flags &= ~TRACEE_FLAGS;
if (c_p_xlocks)
erts_proc_unlock(c_p, c_p_xlocks);
}
}
return 0;
}
int erts_is_tracer_enabled(const ErtsTracer tracer, ErtsPTabElementCommon *t_p)
{
ErtsTracerNif *tnif = lookup_tracer_nif(tracer);
if (tnif) {
Eterm nif_result = call_enabled_tracer(tracer, &tnif,
TRACE_FUN_ENABLED,
am_trace_status,
t_p->id);
switch (nif_result) {
case am_discard:
case am_trace: return 1;
default:
break;
}
}
return 0;
}
int erts_is_tracer_proc_enabled(Process* c_p, ErtsProcLocks c_p_locks,
ErtsPTabElementCommon *t_p)
{
return is_tracer_enabled(c_p, c_p_locks, t_p, NULL, TRACE_FUN_ENABLED,
am_trace_status);
}
int erts_is_tracer_proc_enabled_send(Process* c_p, ErtsProcLocks c_p_locks,
ErtsPTabElementCommon *t_p)
{
return is_tracer_enabled(c_p, c_p_locks, t_p, NULL, TRACE_FUN_T_SEND, am_send);
}
void erts_tracer_replace(ErtsPTabElementCommon *t_p, const ErtsTracer tracer)
{
#if defined(ERTS_ENABLE_LOCK_CHECK)
if (is_internal_pid(t_p->id) && !erts_thr_progress_is_blocking()) {
erts_proc_lc_chk_have_proc_locks((Process*)t_p, ERTS_PROC_LOCKS_ALL);
} else if (is_internal_port(t_p->id)) {
ERTS_LC_ASSERT(erts_lc_is_port_locked((Port*)t_p)
|| erts_thr_progress_is_blocking());
}
#endif
if (ERTS_TRACER_COMPARE(t_p->tracer, tracer))
return;
erts_tracer_update(&t_p->tracer, tracer);
}
static void free_tracer(void *p)
{
ErtsTracer tracer = (ErtsTracer)p;
if (is_immed(ERTS_TRACER_STATE(tracer))) {
erts_free(ERTS_ALC_T_HEAP_FRAG, ptr_val(tracer));
} else {
ErlHeapFragment *hf = (void*)((char*)(ptr_val(tracer)) - offsetof(ErlHeapFragment, mem));
free_message_buffer(hf);
}
}
/* un-define erts_tracer_update before implementation */
#ifdef erts_tracer_update
#undef erts_tracer_update
#endif
/*
* ErtsTracer is either NIL, 'true' or [Mod | State]
*
* - If State is immediate then the memory for
* the cons cell is just two words + sizeof(ErtsThrPrgrLaterOp) large.
* - If State is a complex term then the cons cell
* is allocated in an ErlHeapFragment where the cons
* ptr points to the mem field. So in order to get the
* ptr to the fragment you do this:
* (char*)(ptr_val(tracer)) - offsetof(ErlHeapFragment, mem)
* Normally you shouldn't have to care about this though
* as erts_tracer_update takes care of it for you.
*
* When ErtsTracer is stored in the stack as part of a
* return trace, the cons cell is stored on the heap of
* the process.
*
* The cons cell is not always stored on the heap as:
* 1) for port/meta tracing there is no heap
* 2) we would need the main lock in order to
* read the tracer which is undesirable.
*
* One way to optimize this (memory wise) is to keep an refc and only bump
* the refc when *tracer is NIL.
*/
void
erts_tracer_update(ErtsTracer *tracer, const ErtsTracer new_tracer)
{
ErlHeapFragment *hf;
if (is_not_nil(*tracer)) {
Uint offs = 2;
UWord size = 2 * sizeof(Eterm) + sizeof(ErtsThrPrgrLaterOp);
ErtsThrPrgrLaterOp *lop;
ASSERT(is_list(*tracer));
if (is_not_immed(ERTS_TRACER_STATE(*tracer))) {
hf = (void*)(((char*)(ptr_val(*tracer)) - offsetof(ErlHeapFragment, mem)));
offs = hf->used_size;
size = hf->alloc_size * sizeof(Eterm) + sizeof(ErlHeapFragment);
ASSERT(offs == size_object(*tracer));
}
/* sparc assumes that all structs are double word aligned, so we
have to align the ErtsThrPrgrLaterOp struct otherwise it may
segfault.*/
if ((UWord)(ptr_val(*tracer) + offs) % (sizeof(UWord)*2) == sizeof(UWord))
offs += 1;
lop = (ErtsThrPrgrLaterOp*)(ptr_val(*tracer) + offs);
ASSERT((UWord)lop % (sizeof(UWord)*2) == 0);
/* We schedule the free:ing of the tracer until after a thread progress
has been made so that we know that no schedulers have any references
to it. Because we do this, it is possible to release all locks of a
process/port and still use the ErtsTracer of that port/process
without having to worry if it is free'd.
*/
erts_schedule_thr_prgr_later_cleanup_op(
free_tracer, (void*)(*tracer), lop, size);
}
if (is_nil(new_tracer)) {
*tracer = new_tracer;
} else if (is_immed(ERTS_TRACER_STATE(new_tracer))) {
/* If tracer state is an immediate we only allocate a 2 Eterm heap.
Not sure if it is worth it, we save 4 words (sizeof(ErlHeapFragment))
per tracer. */
Eterm *hp = erts_alloc(ERTS_ALC_T_HEAP_FRAG,
3*sizeof(Eterm) + sizeof(ErtsThrPrgrLaterOp));
*tracer = CONS(hp, ERTS_TRACER_MODULE(new_tracer),
ERTS_TRACER_STATE(new_tracer));
} else {
Eterm *hp, tracer_state = ERTS_TRACER_STATE(new_tracer),
tracer_module = ERTS_TRACER_MODULE(new_tracer);
Uint sz = size_object(tracer_state);
hf = new_message_buffer(sz + 2 /* cons cell */ +
(sizeof(ErtsThrPrgrLaterOp)+sizeof(Eterm)-1)/sizeof(Eterm) + 1);
hp = hf->mem + 2;
hf->used_size -= (sizeof(ErtsThrPrgrLaterOp)+sizeof(Eterm)-1)/sizeof(Eterm) + 1;
*tracer = copy_struct(tracer_state, sz, &hp, &hf->off_heap);
*tracer = CONS(hf->mem, tracer_module, *tracer);
ASSERT((void*)(((char*)(ptr_val(*tracer)) - offsetof(ErlHeapFragment, mem))) == hf);
}
}
static void init_tracer_nif()
{
erts_rwmtx_opt_t rwmtx_opt = ERTS_RWMTX_OPT_DEFAULT_INITER;
rwmtx_opt.type = ERTS_RWMTX_TYPE_EXTREMELY_FREQUENT_READ;
rwmtx_opt.lived = ERTS_RWMTX_LONG_LIVED;
erts_rwmtx_init_opt(&tracer_mtx, &rwmtx_opt, "tracer_mtx", NIL,
ERTS_LOCK_FLAGS_PROPERTY_STATIC | ERTS_LOCK_FLAGS_CATEGORY_DEBUG);
erts_tracer_nif_clear();
}
int erts_tracer_nif_clear()
{
erts_rwmtx_rlock(&tracer_mtx);
if (!tracer_hash || tracer_hash->nobjs) {
HashFunctions hf;
hf.hash = tracer_hash_fun;
hf.cmp = tracer_cmp_fun;
hf.alloc = tracer_alloc_fun;
hf.free = tracer_free_fun;
hf.meta_alloc = (HMALLOC_FUN) erts_alloc;
hf.meta_free = (HMFREE_FUN) erts_free;
hf.meta_print = (HMPRINT_FUN) erts_print;
erts_rwmtx_runlock(&tracer_mtx);
erts_rwmtx_rwlock(&tracer_mtx);
if (tracer_hash)
hash_delete(tracer_hash);
tracer_hash = hash_new(ERTS_ALC_T_TRACER_NIF, "tracer_hash", 10, hf);
erts_rwmtx_rwunlock(&tracer_mtx);
return 1;
}
erts_rwmtx_runlock(&tracer_mtx);
return 0;
}
static int tracer_cmp_fun(void* a, void* b)
{
return ((ErtsTracerNif*)a)->module != ((ErtsTracerNif*)b)->module;
}
static HashValue tracer_hash_fun(void* obj)
{
return make_internal_hash(((ErtsTracerNif*)obj)->module, 0);
}
static void *tracer_alloc_fun(void* tmpl)
{
ErtsTracerNif *obj = erts_alloc(ERTS_ALC_T_TRACER_NIF,
sizeof(ErtsTracerNif) +
sizeof(ErtsThrPrgrLaterOp));
sys_memcpy(obj, tmpl, sizeof(*obj));
return obj;
}
static void tracer_free_fun_cb(void* obj)
{
erts_free(ERTS_ALC_T_TRACER_NIF, obj);
}
static void tracer_free_fun(void* obj)
{
ErtsTracerNif *tnif = obj;
erts_schedule_thr_prgr_later_op(
tracer_free_fun_cb, obj,
(ErtsThrPrgrLaterOp*)(tnif + 1));
}