#include <glib.h>
#include <malloc.h>
#include <sys/mman.h>
+#include <string.h>
// For realpath
#include <limits.h>
/* Facility names used in this file */
GQuark LTT_FACILITY_NAME_HEARTBEAT,
- LTT_EVENT_NAME_HEARTBEAT;
+ LTT_EVENT_NAME_HEARTBEAT,
+ LTT_EVENT_NAME_HEARTBEAT_FULL;
GQuark LTT_TRACEFILE_NAME_FACILITIES;
#ifndef g_open
t->ltt_minor_version = any->minor_version;
t->flight_recorder = any->flight_recorder;
t->has_heartbeat = any->has_heartbeat;
- t->freq_scale = any->freq_scale;
+ t->compact_facilities = NULL;
}
tf->buffer_header_size =
sizeof(struct ltt_block_start_header)
+ sizeof(struct ltt_trace_header_0_7);
+ tf->tsc_lsb_truncate = 0;
+ tf->tscbits = 32;
+ tf->tsc_msb_cutoff = 32 - tf->tsc_lsb_truncate - tf->tscbits;
+ tf->tsc_mask = (1ULL<<32)-1;
+ tf->tsc_mask_next_bit = (1ULL<<32);
if(t) {
t->start_freq = ltt_get_uint64(LTT_GET_BO(tf),
&vheader->start_freq);
+ t->freq_scale = ltt_get_uint32(LTT_GET_BO(tf),
+ &vheader->freq_scale);
t->start_tsc = ltt_get_uint64(LTT_GET_BO(tf),
&vheader->start_tsc);
t->start_monotonic = ltt_get_uint64(LTT_GET_BO(tf),
t->start_time.tv_nsec *= 1000; /* microsec to nanosec */
t->start_time_from_tsc = ltt_time_from_uint64(
- (double)t->start_tsc * 1000000.0 / (double)t->start_freq);
+ (double)t->start_tsc
+ * (1000000000.0 / tf->trace->freq_scale)
+ / (double)t->start_freq);
+ t->compact_event_bits = 0;
+ }
+ }
+ break;
+ case 8:
+ {
+ struct ltt_trace_header_0_8 *vheader =
+ (struct ltt_trace_header_0_8 *)header;
+ tf->buffer_header_size =
+ sizeof(struct ltt_block_start_header)
+ + sizeof(struct ltt_trace_header_0_8);
+ tf->tsc_lsb_truncate = vheader->tsc_lsb_truncate;
+ tf->tscbits = vheader->tscbits;
+ tf->tsc_msb_cutoff = 32 - tf->tsc_lsb_truncate - tf->tscbits;
+ tf->tsc_mask = ((1ULL << (tf->tscbits))-1);
+ tf->tsc_mask = tf->tsc_mask << tf->tsc_lsb_truncate;
+ tf->tsc_mask_next_bit = (1ULL<<(tf->tscbits));
+ tf->tsc_mask_next_bit = tf->tsc_mask_next_bit << tf->tsc_lsb_truncate;
+ if(t) {
+ t->start_freq = ltt_get_uint64(LTT_GET_BO(tf),
+ &vheader->start_freq);
+ t->freq_scale = ltt_get_uint32(LTT_GET_BO(tf),
+ &vheader->freq_scale);
+ t->start_tsc = ltt_get_uint64(LTT_GET_BO(tf),
+ &vheader->start_tsc);
+ t->start_monotonic = ltt_get_uint64(LTT_GET_BO(tf),
+ &vheader->start_monotonic);
+ t->start_time.tv_sec = ltt_get_uint64(LTT_GET_BO(tf),
+ &vheader->start_time_sec);
+ t->start_time.tv_nsec = ltt_get_uint64(LTT_GET_BO(tf),
+ &vheader->start_time_usec);
+ t->start_time.tv_nsec *= 1000; /* microsec to nanosec */
+
+ t->start_time_from_tsc = ltt_time_from_uint64(
+ (double)t->start_tsc
+ * (1000000000.0 / tf->trace->freq_scale)
+ / (double)t->start_freq);
+ t->compact_event_bits = 0;
}
}
break;
* The left side is the name, the right side is the number.
*/
-int get_tracefile_name_number(const gchar *raw_name,
+int get_tracefile_name_number(gchar *raw_name,
GQuark *name,
- guint *num)
+ guint *num,
+ guint *tid,
+ guint *pgid,
+ guint64 *creation)
{
guint raw_name_len = strlen(raw_name);
gchar char_name[PATH_MAX];
int underscore_pos;
long int cpu_num;
gchar *endptr;
+ gchar *tmpptr;
for(i=raw_name_len-1;i>=0;i--) {
if(raw_name[i] == '_') break;
}
- if(i==0) /* Either not found or name length is 0 */
- return -1;
- underscore_pos = i;
+ if(i==-1) { /* Either not found or name length is 0 */
+ /* This is a userspace tracefile */
+ strncpy(char_name, raw_name, raw_name_len);
+ char_name[raw_name_len] = '\0';
+ *name = g_quark_from_string(char_name);
+ *num = 0; /* unknown cpu */
+ for(i=0;i<raw_name_len;i++) {
+ if(raw_name[i] == '/') {
+ break;
+ }
+ }
+ i++;
+ for(;i<raw_name_len;i++) {
+ if(raw_name[i] == '/') {
+ break;
+ }
+ }
+ i++;
+ for(;i<raw_name_len;i++) {
+ if(raw_name[i] == '-') {
+ break;
+ }
+ }
+ if(i == raw_name_len) return -1;
+ i++;
+ tmpptr = &raw_name[i];
+ for(;i<raw_name_len;i++) {
+ if(raw_name[i] == '.') {
+ raw_name[i] = ' ';
+ break;
+ }
+ }
+ *tid = strtoul(tmpptr, &endptr, 10);
+ if(endptr == tmpptr)
+ return -1; /* No digit */
+ if(*tid == ULONG_MAX)
+ return -1; /* underflow / overflow */
+ i++;
+ tmpptr = &raw_name[i];
+ for(;i<raw_name_len;i++) {
+ if(raw_name[i] == '.') {
+ raw_name[i] = ' ';
+ break;
+ }
+ }
+ *pgid = strtoul(tmpptr, &endptr, 10);
+ if(endptr == tmpptr)
+ return -1; /* No digit */
+ if(*pgid == ULONG_MAX)
+ return -1; /* underflow / overflow */
+ i++;
+ tmpptr = &raw_name[i];
+ *creation = strtoull(tmpptr, &endptr, 10);
+ if(endptr == tmpptr)
+ return -1; /* No digit */
+ if(*creation == G_MAXUINT64)
+ return -1; /* underflow / overflow */
+ } else {
+ underscore_pos = i;
- cpu_num = strtol(raw_name+underscore_pos+1, &endptr, 10);
+ cpu_num = strtol(raw_name+underscore_pos+1, &endptr, 10);
- if(endptr == raw_name+underscore_pos+1)
- return -1; /* No digit */
- if(cpu_num == LONG_MIN || cpu_num == LONG_MAX)
- return -1; /* underflow / overflow */
-
- strncpy(char_name, raw_name, underscore_pos);
-
- char_name[underscore_pos] = '\0';
+ if(endptr == raw_name+underscore_pos+1)
+ return -1; /* No digit */
+ if(cpu_num == LONG_MIN || cpu_num == LONG_MAX)
+ return -1; /* underflow / overflow */
+
+ strncpy(char_name, raw_name, underscore_pos);
+ char_name[underscore_pos] = '\0';
+
+ *name = g_quark_from_string(char_name);
+ *num = cpu_num;
+ }
- *name = g_quark_from_string(char_name);
- *num = cpu_num;
return 0;
}
if(ret < 0) continue;
} else if(S_ISREG(stat_buf.st_mode)) {
GQuark name;
- guint num;
+ guint num, tid, pgid;
+ guint64 creation;
GArray *group;
-
- if(get_tracefile_name_number(rel_path, &name, &num))
+ num = tid = pgid = 0;
+ creation = 0;
+ if(get_tracefile_name_number(rel_path, &name, &num, &tid, &pgid, &creation))
continue; /* invalid name */
g_debug("Opening file.\n");
tmp_tf.cpu_online = 1;
tmp_tf.cpu_num = num;
tmp_tf.name = name;
-
+ tmp_tf.tid = tid;
+ tmp_tf.pgid = pgid;
+ tmp_tf.creation = creation;
+ if(tmp_tf.name == g_quark_from_string("/compact")
+ || tmp_tf.name == g_quark_from_string("/flight-compact"))
+ tmp_tf.compact = 1;
+ else
+ tmp_tf.compact = 0;
group = g_datalist_id_get_data(&trace->tracefiles, name);
if(group == NULL) {
/* Elements are automatically cleared when the array is allocated.
case LTT_ARCH_TYPE_X86_64:
text = "_x86_64";
break;
+ case LTT_ARCH_TYPE_C2:
+ text = "_c2";
+ break;
+ case LTT_ARCH_TYPE_POWERPC:
+ text = "_powerpc";
+ break;
default:
g_error("Trace from unsupported architecture.");
}
g_debug("Doing LTT_EVENT_FACILITY_LOAD of facility %s",
fac_name);
pos = (tf->event.data + strlen(fac_name) + 1);
- pos += ltt_align((size_t)pos, sizeof(guint32), tf->has_alignment);
+ pos += ltt_align((size_t)pos, tf->trace->arch_size, tf->has_alignment);
fac_load_data = (struct LttFacilityLoad *)pos;
fac = &g_array_index (tf->trace->facilities_by_num, LttFacility,
fac->id = ltt_get_uint32(LTT_GET_BO(tf), &fac_load_data->id);
fac->pointer_size = ltt_get_uint32(LTT_GET_BO(tf),
&fac_load_data->pointer_size);
- fac->int_size = ltt_get_uint32(LTT_GET_BO(tf),
- &fac_load_data->int_size);
+ fac->int_size = ltt_get_uint32(LTT_GET_BO(tf),
+ &fac_load_data->int_size);
fac->long_size = ltt_get_uint32(LTT_GET_BO(tf),
&fac_load_data->long_size);
fac->size_t_size = ltt_get_uint32(LTT_GET_BO(tf),
g_debug("Doing LTT_EVENT_STATE_DUMP_FACILITY_LOAD of facility %s",
fac_name);
pos = (tf->event.data + strlen(fac_name) + 1);
- pos += ltt_align((size_t)pos, sizeof(guint32), tf->has_alignment);
+ pos += ltt_align((size_t)pos, tf->trace->arch_size, tf->has_alignment);
fac_state_dump_load_data = (struct LttStateDumpFacilityLoad *)pos;
fac = &g_array_index (tf->trace->facilities_by_num, LttFacility,
&fac_state_dump_load_data->id);
fac->pointer_size = ltt_get_uint32(LTT_GET_BO(tf),
&fac_state_dump_load_data->pointer_size);
- fac->int_size = ltt_get_uint32(LTT_GET_BO(tf),
- &fac_state_dump_load_data->int_size);
+ fac->int_size = ltt_get_uint32(LTT_GET_BO(tf),
+ &fac_state_dump_load_data->int_size);
fac->long_size = ltt_get_uint32(LTT_GET_BO(tf),
&fac_state_dump_load_data->long_size);
fac->size_t_size = ltt_get_uint32(LTT_GET_BO(tf),
fac_ids, ltt_fac_ids_destroy);
}
g_array_append_val(fac_ids, fac->id);
+ g_debug("fac id : %u", fac->id);
break;
case LTT_EVENT_HEARTBEAT:
break;
+ case LTT_EVENT_HEARTBEAT_FULL:
+ break;
default:
g_warning("Error in processing facility file %s, "
"unknown event id %hhu in core facility.",
if(ltt_process_facility_tracefile(tf))
goto facilities_error;
}
-
+ t->compact_facilities = ltt_trace_facility_get_by_name(t,
+ g_quark_from_string("compact"));
+ if(!t->compact_facilities)
+ t->compact_facilities = ltt_trace_facility_get_by_name(t,
+ g_quark_from_string("flight-compact"));
+ if (t->compact_facilities) {
+ /* FIXME : currently does not support unload/load of compact
+ * facility during tracing. Should check for the currently loaded
+ * version of the facility. */
+ g_assert(t->compact_facilities->len == 1);
+ g_assert(t->compact_facilities);
+ {
+ guint facility_id = g_array_index(t->compact_facilities, guint, 0);
+ LttFacility *fac = ltt_trace_facility_by_id(t, facility_id);
+ unsigned int num = ltt_facility_eventtype_number(fac);
+ /* Could be done much quicker, but not on much used code path */
+ if(num) {
+ t->compact_event_bits = 1;
+ while(num >>= 1)
+ t->compact_event_bits++;
+ } else
+ t->compact_event_bits = 0;
+ }
+ }
+
return t;
/* Error handling */
-guint ltt_tracefile_num(LttTracefile *tf)
+guint ltt_tracefile_cpu(LttTracefile *tf)
{
return tf->cpu_num;
}
+guint ltt_tracefile_tid(LttTracefile *tf)
+{
+ return tf->tid;
+}
+
+guint ltt_tracefile_pgid(LttTracefile *tf)
+{
+ return tf->pgid;
+}
+
+guint64 ltt_tracefile_creation(LttTracefile *tf)
+{
+ return tf->creation;
+}
/*****************************************************************************
* Get the number of blocks in the tracefile
****************************************************************************/
return 1;
}
-/* Calculate the real event time based on the buffer boundaries */
-LttTime ltt_interpolate_time(LttTracefile *tf, LttEvent *event)
+LttTime ltt_interpolate_time_from_tsc(LttTracefile *tf, guint64 tsc)
{
LttTime time;
-
-// time = ltt_time_from_uint64(
-// cycles_2_ns(tf, (guint64)(tf->buffer.tsc - tf->buffer.begin.cycle_count)));
- time = ltt_time_from_uint64(
- (double)(tf->buffer.tsc - tf->trace->start_tsc)
- * (1000000000.0 / tf->trace->freq_scale)
- / (double)tf->trace->start_freq);
- //time = ltt_time_add(tf->buffer.begin.timestamp, time);
- time = ltt_time_add(tf->trace->start_time_from_tsc, time);
-
+
+ if(tsc > tf->trace->start_tsc) {
+ time = ltt_time_from_uint64(
+ (double)(tsc - tf->trace->start_tsc)
+ * (1000000000.0 / tf->trace->freq_scale)
+ / (double)tf->trace->start_freq);
+ time = ltt_time_add(tf->trace->start_time_from_tsc, time);
+ } else {
+ time = ltt_time_from_uint64(
+ (double)(tf->trace->start_tsc - tsc)
+ * (1000000000.0 / tf->trace->freq_scale)
+ / (double)tf->trace->start_freq);
+ time = ltt_time_sub(tf->trace->start_time_from_tsc, time);
+ }
return time;
}
+/* Calculate the real event time based on the buffer boundaries */
+LttTime ltt_interpolate_time(LttTracefile *tf, LttEvent *event)
+{
+ return ltt_interpolate_time_from_tsc(tf, tf->buffer.tsc);
+}
+
/* Get the current event of the tracefile : valid until the next read */
LttEvent *ltt_tracefile_get_event(LttTracefile *tf)
/* Read event header */
/* Align the head */
- pos += ltt_align((size_t)pos, tf->trace->arch_size, tf->has_alignment);
+ if(!tf->compact)
+ pos += ltt_align((size_t)pos, tf->trace->arch_size, tf->has_alignment);
+ else {
+ g_assert(tf->trace->has_heartbeat);
+ pos += ltt_align((size_t)pos, sizeof(uint32_t), tf->has_alignment);
+ }
if(tf->trace->has_heartbeat) {
event->timestamp = ltt_get_uint32(LTT_GET_BO(tf),
pos);
- /* 32 bits -> 64 bits tsc */
- /* note : still works for seek and non seek cases. */
- if(event->timestamp < (0xFFFFFFFFULL&tf->buffer.tsc)) {
- tf->buffer.tsc = ((tf->buffer.tsc&0xFFFFFFFF00000000ULL)
- + 0x100000000ULL)
- | (guint64)event->timestamp;
- event->tsc = tf->buffer.tsc;
- } else {
- /* no overflow */
- tf->buffer.tsc = (tf->buffer.tsc&0xFFFFFFFF00000000ULL)
- | (guint64)event->timestamp;
- event->tsc = tf->buffer.tsc;
- }
+ if(!tf->compact) {
+ /* 32 bits -> 64 bits tsc */
+ /* note : still works for seek and non seek cases. */
+ if(event->timestamp < (0xFFFFFFFFULL&tf->buffer.tsc)) {
+ tf->buffer.tsc = ((tf->buffer.tsc&0xFFFFFFFF00000000ULL)
+ + 0x100000000ULL)
+ | (guint64)event->timestamp;
+ event->tsc = tf->buffer.tsc;
+ } else {
+ /* no overflow */
+ tf->buffer.tsc = (tf->buffer.tsc&0xFFFFFFFF00000000ULL)
+ | (guint64)event->timestamp;
+ event->tsc = tf->buffer.tsc;
+ event->compact_data = 0;
+ }
+ } else {
+ /* Compact header */
+ /* We keep the LSB of the previous timestamp, to make sure
+ * we never go back */
+ event->event_id = event->timestamp >> tf->tscbits;
+ event->event_id = event->event_id & ((1 << tf->trace->compact_event_bits) - 1);
+ event->compact_data = event->timestamp >>
+ (tf->trace->compact_event_bits + tf->tscbits);
+ //printf("tsc bits %u, ev bits %u init data %u\n",
+ // tf->tscbits, tf->trace->compact_event_bits, event->compact_data);
+ /* Put the compact data back in original endianness */
+ event->compact_data = ltt_get_uint32(LTT_GET_BO(tf), &event->compact_data);
+ event->event_size = 0xFFFF;
+ //printf("Found compact event %d\n", event->event_id);
+ //printf("Compact data %d\n", event->compact_data);
+ event->timestamp = event->timestamp << tf->tsc_lsb_truncate;
+ event->timestamp = event->timestamp & tf->tsc_mask;
+ //printf("timestamp 0x%lX\n", event->timestamp);
+ //printf("mask 0x%llX\n", tf->tsc_mask);
+ //printf("mask_next 0x%llX\n", tf->tsc_mask_next_bit);
+ //printf("previous tsc 0x%llX\n", tf->buffer.tsc);
+ //printf("previous tsc&mask 0x%llX\n", tf->tsc_mask&tf->buffer.tsc);
+ //printf("previous tsc&(~mask) 0x%llX\n", tf->buffer.tsc&(~tf->tsc_mask));
+ if(event->timestamp < (tf->tsc_mask&tf->buffer.tsc)) {
+ //printf("wrap\n");
+ tf->buffer.tsc = ((tf->buffer.tsc&(~tf->tsc_mask))
+ + tf->tsc_mask_next_bit)
+ | (guint64)event->timestamp;
+ event->tsc = tf->buffer.tsc;
+ } else {
+ //printf("no wrap\n");
+ /* no overflow */
+ tf->buffer.tsc = (tf->buffer.tsc&(~tf->tsc_mask))
+ | (guint64)event->timestamp;
+ event->tsc = tf->buffer.tsc;
+ }
+ //printf("current tsc 0x%llX\n", tf->buffer.tsc);
+ event->facility_id = g_array_index(tf->trace->compact_facilities, guint, 0);
+ }
pos += sizeof(guint32);
} else {
event->tsc = ltt_get_uint64(LTT_GET_BO(tf), pos);
tf->buffer.tsc = event->tsc;
+ event->compact_data = 0;
pos += sizeof(guint64);
}
event->event_time = ltt_interpolate_time(tf, event);
- event->facility_id = *(guint8*)pos;
- pos += sizeof(guint8);
- event->event_id = *(guint8*)pos;
- pos += sizeof(guint8);
+ if(!tf->compact) {
+ event->facility_id = *(guint8*)pos;
+ pos += sizeof(guint8);
- event->event_size = ltt_get_uint16(LTT_GET_BO(tf), pos);
- pos += sizeof(guint16);
-
+ event->event_id = *(guint8*)pos;
+ pos += sizeof(guint8);
+
+ event->event_size = ltt_get_uint16(LTT_GET_BO(tf), pos);
+ pos += sizeof(guint16);
+ } else {
+ /* Compact event */
+ }
/* Align the head */
- pos += ltt_align((size_t)pos, tf->trace->arch_size, tf->has_alignment);
+ if(!tf->compact)
+ pos += ltt_align((size_t)pos, tf->trace->arch_size, tf->has_alignment);
event->data = pos;
/* get the data size and update the event fields with the current
- * information */
+ * information. Also update the time if a heartbeat_full event is found. */
ltt_update_event_size(tf);
return 0;
&header->begin.cycle_count);
tf->buffer.begin.freq = ltt_get_uint64(LTT_GET_BO(tf),
&header->begin.freq);
- tf->buffer.begin.timestamp = ltt_time_add(
+ if(tf->buffer.begin.freq == 0)
+ tf->buffer.begin.freq = tf->trace->start_freq;
+
+ tf->buffer.begin.timestamp = ltt_interpolate_time_from_tsc(tf,
+ tf->buffer.begin.cycle_count);
+#if 0
+ ltt_time_add(
ltt_time_from_uint64(
(double)(tf->buffer.begin.cycle_count
- tf->trace->start_tsc) * 1000000.0
/ (double)tf->trace->start_freq),
- tf->trace->start_time_from_tsc);
+ tf->trace->start_time_from_tsc);
+#endif //0
#if 0
tf->buffer.end.timestamp = ltt_time_add(
&header->end.cycle_count);
tf->buffer.end.freq = ltt_get_uint64(LTT_GET_BO(tf),
&header->end.freq);
+ if(tf->buffer.end.freq == 0)
+ tf->buffer.end.freq = tf->trace->start_freq;
+
tf->buffer.lost_size = ltt_get_uint32(LTT_GET_BO(tf),
&header->lost_size);
- tf->buffer.end.timestamp = ltt_time_add(
+ tf->buffer.end.timestamp = ltt_interpolate_time_from_tsc(tf,
+ tf->buffer.end.cycle_count);
+#if 0
+ ltt_time_add(
ltt_time_from_uint64(
(double)(tf->buffer.end.cycle_count
- tf->trace->start_tsc) * 1000000.0
/ (double)tf->trace->start_freq),
tf->trace->start_time_from_tsc);
-
+#endif //0
tf->buffer.tsc = tf->buffer.begin.cycle_count;
tf->event.tsc = tf->buffer.tsc;
tf->buffer.freq = tf->buffer.begin.freq;
void ltt_update_event_size(LttTracefile *tf)
{
off_t size = 0;
-
- /* Specific handling of core events : necessary to read the facility control
- * tracefile. */
LttFacility *f = ltt_trace_get_facility_by_num(tf->trace,
tf->event.facility_id);
-
- if(likely(tf->event.facility_id == LTT_FACILITY_CORE)) {
- switch((enum ltt_core_events)tf->event.event_id) {
- case LTT_EVENT_FACILITY_LOAD:
- size = strlen((char*)tf->event.data) + 1;
- //g_debug("Update Event facility load of facility %s", (char*)tf->event.data);
- size += ltt_align(size, sizeof(guint32), tf->has_alignment);
- size += sizeof(struct LttFacilityLoad);
- break;
- case LTT_EVENT_FACILITY_UNLOAD:
- //g_debug("Update Event facility unload");
- size = sizeof(struct LttFacilityUnload);
- break;
- case LTT_EVENT_STATE_DUMP_FACILITY_LOAD:
- size = strlen((char*)tf->event.data) + 1;
- size += ltt_align(size, sizeof(guint32), tf->has_alignment);
- //g_debug("Update Event facility load state dump of facility %s",
- // (char*)tf->event.data);
- size += sizeof(struct LttStateDumpFacilityLoad);
- break;
- case LTT_EVENT_HEARTBEAT:
- //g_debug("Update Event heartbeat");
- size = sizeof(TimeHeartbeat);
- break;
- default:
- g_warning("Error in getting event size : tracefile %s, "
- "unknown event id %hhu in core facility.",
- g_quark_to_string(tf->name),
- tf->event.event_id);
- goto event_id_error;
-
- }
- } else {
- if(!f->exists) {
- g_error("Unknown facility %hhu (0x%hhx) in tracefile %s",
+ char *tscdata;
+
+ if(!f->exists) {
+ /* Specific handling of core events : necessary to read the facility control
+ * tracefile. */
+
+ if(likely(tf->event.facility_id == LTT_FACILITY_CORE)) {
+ switch((enum ltt_core_events)tf->event.event_id) {
+ case LTT_EVENT_FACILITY_LOAD:
+ size = strlen((char*)tf->event.data) + 1;
+ //g_debug("Update Event facility load of facility %s", (char*)tf->event.data);
+ size += ltt_align(size, sizeof(guint32), tf->has_alignment);
+ size += sizeof(struct LttFacilityLoad);
+ break;
+ case LTT_EVENT_FACILITY_UNLOAD:
+ //g_debug("Update Event facility unload");
+ size = sizeof(struct LttFacilityUnload);
+ break;
+ case LTT_EVENT_STATE_DUMP_FACILITY_LOAD:
+ size = strlen((char*)tf->event.data) + 1;
+ size += ltt_align(size, sizeof(guint32), tf->has_alignment);
+ //g_debug("Update Event facility load state dump of facility %s",
+ // (char*)tf->event.data);
+ size += sizeof(struct LttStateDumpFacilityLoad);
+ break;
+ case LTT_EVENT_HEARTBEAT:
+ //g_debug("Update Event heartbeat");
+ size = sizeof(TimeHeartbeat);
+ break;
+ case LTT_EVENT_HEARTBEAT_FULL:
+ //g_debug("Update Event heartbeat full");
+ tscdata = (char*)(tf->event.data);
+ tf->event.tsc = ltt_get_uint64(LTT_GET_BO(tf), tscdata);
+ tf->buffer.tsc = tf->event.tsc;
+ tf->event.event_time = ltt_interpolate_time(tf, &tf->event);
+ size = sizeof(TimeHeartbeatFull);
+ size += ltt_align(size, sizeof(guint64), tf->has_alignment);
+ break;
+ default:
+ g_warning("Error in getting event size : tracefile %s, "
+ "unknown event id %hhu in core facility.",
+ g_quark_to_string(tf->name),
+ tf->event.event_id);
+ goto event_id_error;
+
+ }
+ goto no_offset; /* Skip the field computation */
+ } else {
+ g_warning("Unknown facility %hhu (0x%hhx) in tracefile %s",
tf->event.facility_id,
tf->event.facility_id,
g_quark_to_string(tf->name));
goto facility_error;
}
+ }
- LttEventType *event_type =
- ltt_facility_eventtype_get(f, tf->event.event_id);
-
- if(!event_type) {
- g_error("Unknown event id %hhu in facility %s in tracefile %s",
- tf->event.event_id,
- g_quark_to_string(f->name),
- g_quark_to_string(tf->name));
- goto event_type_error;
- }
-
- /* Compute the dynamic offsets */
- compute_offsets(tf, f, event_type, &size, tf->event.data);
+ LttEventType *event_type =
+ ltt_facility_eventtype_get(f, tf->event.event_id);
- //g_debug("Event root field : f.e %hhu.%hhu size %zd",
- // tf->event.facility_id,
- // tf->event.event_id, size);
+ if(!event_type) {
+ g_warning("Unknown event id %hhu in facility %s in tracefile %s",
+ tf->event.event_id,
+ g_quark_to_string(f->name),
+ g_quark_to_string(tf->name));
+ goto event_type_error;
}
+ /* Compute the dynamic offsets */
+ compute_offsets(tf, f, event_type, &size, tf->event.data);
+
+ //g_debug("Event root field : f.e %hhu.%hhu size %zd",
+ // tf->event.facility_id,
+ // tf->event.event_id, size);
+
+no_offset:
tf->event.data_size = size;
/* Check consistency between kernel and LTTV structure sizes */
/* Event size too big to fit in the event size field */
tf->event.event_size = tf->event.data_size;
}
- g_assert(tf->event.data_size == tf->event.event_size);
+ if (tf->event.data_size != tf->event.event_size) {
+ g_error("Kernel/LTTV event size differs for event %s.%s: kernel %u, LTTV %u",
+ g_quark_to_string(f->name), g_quark_to_string(event_type->name),
+ tf->event.event_size, tf->event.data_size);
+ exit(-1);
+ }
+ //g_assert(tf->event.data_size == tf->event.event_size);
return;
facility_error:
event_type_error:
event_id_error:
- tf->event.data_size = 0;
+ if(tf->event.event_size == 0xFFFF) {
+ g_error("Cannot jump over an unknown event bigger than 0xFFFE bytes");
+ }
+ /* The facility is unknown : use the kernel information about this event
+ * to jump over it. */
+ tf->event.data_size = tf->event.event_size;
}
case LTT_FLOAT:
case LTT_ENUM:
/* Align offset on type size */
+ g_assert(field->field_size != 0);
return field->field_size;
break;
case LTT_STRING:
- return 0;
+ return 1;
break;
case LTT_ARRAY:
g_assert(type->fields->len == 1);
case LTT_SEQUENCE:
g_assert(type->fields->len == 2);
{
- off_t localign = 0;
+ off_t localign = 1;
LttField *child = &g_array_index(type->fields, LttField, 0);
localign = max(localign, get_alignment(child));
case LTT_UNION:
{
guint i;
- off_t localign = 0;
+ off_t localign = 1;
for(i=0; i<type->fields->len; i++) {
LttField *child = &g_array_index(type->fields, LttField, i);
case LTT_NONE:
default:
g_error("get_alignment : unknown type");
+ return -1;
}
-
}
/*****************************************************************************
****************************************************************************/
-gint precompute_fields_offsets(LttFacility *fac, LttField *field, off_t *offset)
+gint precompute_fields_offsets(LttFacility *fac, LttField *field, off_t *offset, gint is_compact)
{
LttType *type = &field->field_type;
+
+ if(unlikely(is_compact)) {
+ g_assert(field->field_size != 0);
+ /* FIXME THIS IS A HUUUUUGE hack :
+ * offset is between the compact_data field in struct LttEvent
+ * and the address of the field root in the memory map.
+ * ark. Both will stay at the same addresses while the event
+ * is readable, so it's ok.
+ */
+ field->offset_root = 0;
+ field->fixed_root = FIELD_FIXED;
+ return 0;
+ }
switch(type->type_class) {
case LTT_INT_FIXED:
field->fixed_root = FIELD_FIXED;
child = &g_array_index(type->fields, LttField, 0);
- ret = precompute_fields_offsets(fac, child, offset);
+ ret = precompute_fields_offsets(fac, child, offset, is_compact);
g_assert(ret == 0); /* Seq len cannot have variable len */
child = &g_array_index(type->fields, LttField, 1);
for(i=0; i< type->fields->len; i++) {
child = &g_array_index(type->fields, LttField, i);
- ret = precompute_fields_offsets(fac, child, offset);
+ ret = precompute_fields_offsets(fac, child, offset, is_compact);
if(ret) break;
}
for(i=0; i< type->fields->len; i++) {
*offset = field->offset_root;
child = &g_array_index(type->fields, LttField, i);
- ret = precompute_fields_offsets(fac, child, offset);
+ ret = precompute_fields_offsets(fac, child, offset, is_compact);
if(ret) break;
}
/* Precompute all known offsets */
for(i=0; i<event->fields->len; i++) {
LttField *field = &g_array_index(event->fields, LttField, i);
- ret = precompute_fields_offsets(fac, field, &offset);
+ if(event->has_compact_data && i == 0)
+ ret = precompute_fields_offsets(fac, field, &offset, 1);
+ else
+ ret = precompute_fields_offsets(fac, field, &offset, 0);
if(ret) break;
}
}
size_t max_size;
switch(type->type_class) {
+ case LTT_INT_FIXED:
+ case LTT_UINT_FIXED:
+ case LTT_CHAR:
+ case LTT_UCHAR:
+ case LTT_SHORT:
+ case LTT_USHORT:
case LTT_INT:
case LTT_UINT:
case LTT_FLOAT:
field->fixed_size = FIELD_FIXED;
}
break;
+ case LTT_NONE:
+ g_error("unexpected type NONE");
+ break;
}
}
break;
case LTT_NONE:
default:
- g_error("precompute_fields_offsets : unknown type");
+ g_error("check_fields_compatibility : unknown type");
}
end:
}
switch(type1->type_class) {
+ case LTT_INT_FIXED:
+ case LTT_UINT_FIXED:
+ case LTT_POINTER:
+ case LTT_CHAR:
+ case LTT_UCHAR:
+ case LTT_SHORT:
+ case LTT_USHORT:
case LTT_INT:
case LTT_UINT:
case LTT_FLOAT:
{
LTT_FACILITY_NAME_HEARTBEAT = g_quark_from_string("heartbeat");
LTT_EVENT_NAME_HEARTBEAT = g_quark_from_string("heartbeat");
+ LTT_EVENT_NAME_HEARTBEAT_FULL = g_quark_from_string("heartbeat_full");
LTT_TRACEFILE_NAME_FACILITIES = g_quark_from_string("/control/facilities");
}