From: Pierre-Marc Fournier Date: Fri, 24 Jul 2009 19:45:28 +0000 (-0400) Subject: add experimental depanalysis module X-Git-Tag: v0.12.20~62^2~1 X-Git-Url: https://git.lttng.org./?a=commitdiff_plain;h=8c108c1c55e65e15d59378e2cdc2231f35a84c4c;p=lttv.git add experimental depanalysis module --- diff --git a/lttv/lttv/state.c b/lttv/lttv/state.c index 70ca8cbe..ef688770 100644 --- a/lttv/lttv/state.c +++ b/lttv/lttv/state.c @@ -83,6 +83,7 @@ GQuark LTT_EVENT_SOFT_IRQ_ENTRY, LTT_EVENT_SOFT_IRQ_EXIT, LTT_EVENT_SCHED_SCHEDULE, + LTT_EVENT_SCHED_TRY_WAKEUP, LTT_EVENT_PROCESS_FORK, LTT_EVENT_KTHREAD_CREATE, LTT_EVENT_PROCESS_EXIT, @@ -99,7 +100,10 @@ GQuark LTT_EVENT_SYS_CALL_TABLE, LTT_EVENT_SOFTIRQ_VEC, LTT_EVENT_KPROBE_TABLE, - LTT_EVENT_KPROBE; + LTT_EVENT_KPROBE, + LTT_EVENT_OPEN, + LTT_EVENT_READ, + LTT_EVENT_POLL_EVENT; /* Fields Quarks */ @@ -131,7 +135,8 @@ GQuark LTT_FIELD_ID, LTT_FIELD_ADDRESS, LTT_FIELD_SYMBOL, - LTT_FIELD_IP; + LTT_FIELD_IP, + LTT_FIELD_FD; LttvExecutionMode LTTV_STATE_MODE_UNKNOWN, @@ -1311,6 +1316,24 @@ static void copy_process_state(gpointer key, gpointer value,gpointer user_data) g_array_index(process->user_stack, guint64, i); } new_process->current_function = process->current_function; + + /* fd hash table stuff */ + { + GHashTableIter it; + int key; + GQuark value; + + /* copy every item in the hash table */ + new_process->fds = g_hash_table_new(g_direct_hash, g_direct_equal); + + g_hash_table_iter_init(&it, process->fds); + while (g_hash_table_iter_next (&it, (void *)&key, (void *)&value)) { + g_hash_table_insert(new_process->fds, &key, &value); + } + } + + /* When done creating the new process state, insert it in the + * hash table */ g_hash_table_insert(new_processes, new_process, new_process); } @@ -2327,6 +2350,7 @@ static LttvTracefileState *ltt_state_usertrace_find(LttvTraceState *tcs, return tfs; } +/* Return a new and initialized LttvProcessState structure */ LttvProcessState * lttv_state_create_process(LttvTraceState *tcs, LttvProcessState *parent, @@ -2400,6 +2424,8 @@ lttv_state_create_process(LttvTraceState *tcs, LttvProcessState *parent, /* Allocate an empty function call stack. If it's empty, use 0x0. */ process->user_stack = g_array_sized_new(FALSE, FALSE, sizeof(guint64), 0); + + process->fds = g_hash_table_new(g_direct_hash, g_direct_equal); return process; } @@ -2441,7 +2467,7 @@ lttv_state_find_process_or_create(LttvTraceState *ts, guint cpu, guint pid, /* FIXME : this function should be called when we receive an event telling that * release_task has been called in the kernel. In happens generally when - * the parent waits for its child terminaison, but may also happen in special + * the parent waits for its child termination, but may also happens in special * cases in the child's exit : when the parent ignores its children SIGCCHLD or * has the flag SA_NOCLDWAIT. It can also happen when the child is part * of a killed thread group, but isn't the leader. @@ -2461,6 +2487,10 @@ static int exit_process(LttvTracefileState *tfs, LttvProcessState *process) g_hash_table_remove(ts->processes, &key); g_array_free(process->execution_stack, TRUE); g_array_free(process->user_stack, TRUE); + + /* the following also clears the content */ + g_hash_table_destroy(process->fds); + g_free(process); return 1; } @@ -2470,6 +2500,10 @@ static void free_process_state(gpointer key, gpointer value,gpointer user_data) { g_array_free(((LttvProcessState *)value)->execution_stack, TRUE); g_array_free(((LttvProcessState *)value)->user_stack, TRUE); + + /* the following also clears the content */ + g_hash_table_destroy(((LttvProcessState *)value)->fds); + g_free(value); } @@ -3224,6 +3258,29 @@ static gboolean thread_brand(void *hook_data, void *call_data) return FALSE; } +static gboolean fs_open(void *hook_data, void *call_data) +{ + LttvTracefileState *s = (LttvTracefileState *)call_data; + LttvTraceState *ts = (LttvTraceState *)s->parent.t_context; + LttEvent *e = ltt_tracefile_get_event(s->parent.tf); + LttvTraceHook *th = (LttvTraceHook *)hook_data; + struct marker_field *f; + guint cpu = s->cpu; + int fd; + char *filename; + LttvProcessState *process = ts->running_process[cpu]; + + f = lttv_trace_get_hook_field(th, 0); + fd = ltt_event_get_int(e, f); + + f = lttv_trace_get_hook_field(th, 1); + filename = ltt_event_get_string(e, f); + + g_hash_table_insert(process->fds, fd, g_quark_from_string(filename)); + + return FALSE; +} + static void fix_process(gpointer key, gpointer value, gpointer user_data) { @@ -3677,6 +3734,12 @@ void lttv_state_add_event_hooks(LttvTracesetState *self) FIELD_ARRAY(LTT_FIELD_ID, LTT_FIELD_ADDRESS, LTT_FIELD_SYMBOL), dump_softirq, NULL, &hooks); + lttv_trace_find_hook(ts->parent.t, + LTT_CHANNEL_FS, + LTT_EVENT_OPEN, + FIELD_ARRAY(LTT_FIELD_FD, LTT_FIELD_FILENAME), + fs_open, NULL, &hooks); + /* Add these hooks to each event_by_id hooks list */ nb_tracefile = ts->parent.tracefiles->len; @@ -4366,6 +4429,7 @@ static void module_init() LTT_EVENT_SOFT_IRQ_ENTRY = g_quark_from_string("softirq_entry"); LTT_EVENT_SOFT_IRQ_EXIT = g_quark_from_string("softirq_exit"); LTT_EVENT_SCHED_SCHEDULE = g_quark_from_string("sched_schedule"); + LTT_EVENT_SCHED_TRY_WAKEUP = g_quark_from_string("sched_try_wakeup"); LTT_EVENT_PROCESS_FORK = g_quark_from_string("process_fork"); LTT_EVENT_KTHREAD_CREATE = g_quark_from_string("kthread_create"); LTT_EVENT_PROCESS_EXIT = g_quark_from_string("process_exit"); @@ -4383,6 +4447,9 @@ static void module_init() LTT_EVENT_SOFTIRQ_VEC = g_quark_from_string("softirq_vec"); LTT_EVENT_KPROBE_TABLE = g_quark_from_string("kprobe_table"); LTT_EVENT_KPROBE = g_quark_from_string("kprobe"); + LTT_EVENT_OPEN = g_quark_from_string("open"); + LTT_EVENT_READ = g_quark_from_string("read"); + LTT_EVENT_POLL_EVENT = g_quark_from_string("poll_event"); LTT_FIELD_SYSCALL_ID = g_quark_from_string("syscall_id"); LTT_FIELD_TRAP_ID = g_quark_from_string("trap_id"); @@ -4412,6 +4479,7 @@ static void module_init() LTT_FIELD_ADDRESS = g_quark_from_string("address"); LTT_FIELD_SYMBOL = g_quark_from_string("symbol"); LTT_FIELD_IP = g_quark_from_string("ip"); + LTT_FIELD_FD = g_quark_from_string("fd"); LTTV_CPU_UNKNOWN = g_quark_from_string("unknown"); LTTV_CPU_IDLE = g_quark_from_string("idle"); diff --git a/lttv/lttv/state.h b/lttv/lttv/state.h index ad7f9e06..8ed648f2 100644 --- a/lttv/lttv/state.h +++ b/lttv/lttv/state.h @@ -90,6 +90,7 @@ extern GQuark LTT_EVENT_SOFT_IRQ_ENTRY, LTT_EVENT_SOFT_IRQ_EXIT, LTT_EVENT_SCHED_SCHEDULE, + LTT_EVENT_SCHED_TRY_WAKEUP, LTT_EVENT_PROCESS_FORK, LTT_EVENT_KTHREAD_CREATE, LTT_EVENT_PROCESS_EXIT, @@ -106,7 +107,10 @@ extern GQuark LTT_EVENT_SYS_CALL_TABLE, LTT_EVENT_SOFTIRQ_VEC, LTT_EVENT_KPROBE_TABLE, - LTT_EVENT_KPROBE; + LTT_EVENT_KPROBE, + LTT_EVENT_OPEN, + LTT_EVENT_READ, + LTT_EVENT_POLL_EVENT; /* Fields Quarks */ @@ -137,7 +141,8 @@ extern GQuark LTT_FIELD_ID, LTT_FIELD_ADDRESS, LTT_FIELD_SYMBOL, - LTT_FIELD_IP; + LTT_FIELD_IP, + LTT_FIELD_FD; typedef struct _LttvTracesetState LttvTracesetState; typedef struct _LttvTracesetStateClass LttvTracesetStateClass; @@ -284,6 +289,7 @@ typedef struct _LttvProcessState { LttvProcessType type; /* kernel thread or user space ? */ guint target_pid; /* target PID of the current event. */ guint free_events; /* 0 : none, 1 : free or exit dead, 2 : should delete */ + GHashTable *fds; /* hash table of int (file descriptor) -> GQuark (file name) */ } LttvProcessState; #define ANY_CPU 0 /* For clarity sake : a call to lttv_state_find_process for diff --git a/lttv/modules/text/Makefile.am b/lttv/modules/text/Makefile.am index 03425fb3..0e91ebef 100644 --- a/lttv/modules/text/Makefile.am +++ b/lttv/modules/text/Makefile.am @@ -4,7 +4,7 @@ LIBS += $(GLIB_LIBS) -lgobject-2.0 -L${top_builddir}/ltt -llttvtraceread libdir = ${lttvplugindir} -lib_LTLIBRARIES = libtextDump.la libbatchAnalysis.la libtextFilter.la libprecomputeState.la +lib_LTLIBRARIES = libtextDump.la libbatchAnalysis.la libtextFilter.la libprecomputeState.la libdepanalysis.la libtextDump_la_LDFLAGS = -module -avoid-version libtextDump_la_SOURCES = textDump.c libbatchAnalysis_la_LDFLAGS = -module -avoid-version @@ -13,6 +13,8 @@ libtextFilter_la_LDFLAGS = -module -avoid-version libtextFilter_la_SOURCES = textFilter.c libprecomputeState_la_LDFLAGS = -module -avoid-version libprecomputeState_la_SOURCES = precomputeState.c +libdepanalysis_la_LDFLAGS = -module -avoid-version +libdepanalysis_la_SOURCES = depanalysis.c sstack.c noinst_HEADERS = \ batchanalysis.h diff --git a/lttv/modules/text/depanalysis.c b/lttv/modules/text/depanalysis.c new file mode 100644 index 00000000..ca926174 --- /dev/null +++ b/lttv/modules/text/depanalysis.c @@ -0,0 +1,2048 @@ +/* This file is part of the Linux Trace Toolkit viewer + * Copyright (C) 2008 Pierre-Marc Fournier + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License Version 2 as + * published by the Free Software Foundation; + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 59 Temple Place - Suite 330, Boston, + * MA 02111-1307, USA. + */ + +#ifdef HAVE_CONFIG_H +#include +#endif + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#define _GNU_SOURCE +#include +#include +#include + +#include "sstack.h" + +static LttvHooks + *before_traceset, + *after_traceset, +// *before_trace, + *event_hook; + +static int depanalysis_range_pid = -1; +static int depanalysis_range_pid_searching = -1; +static int depanalysis_use_time=0; +static int depanalysis_event_limit = -1; +static LttTime depanalysis_time1, depanalysis_time2; +static char *arg_t1_str,*arg_t2_str; +static int statedump_finished = 0; + + +struct llev_state_info_irq { + int irq; +}; + +struct llev_state_info_softirq { + int softirq; +}; + +struct llev_state_info_syscall { + int syscall_id; + + int substate; + + void *private; +}; + +struct llev_state_info_syscall__open { + GQuark filename; +}; + +struct llev_state_info_syscall__read { + GQuark filename; +}; + +struct llev_state_info_syscall__poll { + GQuark filename; +}; + +struct llev_state_info_preempted { + int prev_state; +}; + +struct hlev_state_info_blocked { + int syscall_id; + unsigned char trap; /* flag */ + int substate; + + /* Garray of pointers to struct process_state that reflect the + * low-level state stack when respectively entering and exiting the blocked + * state. + */ + GArray *llev_state_entry; + GArray *llev_state_exit; + + int pid_exit; /* FIXME: it's not pretty to have this here; find this info elsewhere */ + LttTime time_woken; + + void *private; +}; + +struct hlev_state_info_blocked__open { + GQuark filename; +}; + +struct hlev_state_info_blocked__read { + GQuark filename; +}; + +struct hlev_state_info_blocked__poll { + GQuark filename; +}; + +struct hlev_state_info_interrupted_irq { + int irq; +}; + +struct hlev_state_info_interrupted_softirq { + int softirq; +}; + +struct summary_tree_node { + char *name; + GHashTable *children; + LttTime duration; + GArray *episodes; + int id_for_episodes; +}; + +struct state_info { + char name[40]; + int size_priv; + char *tree_path[6]; +}; + +struct state_info llev_state_infos[] = { + { "UNKNOWN", 0, { NULL } }, + { "RUNNING", 0, { NULL } }, + { "SYSCALL", sizeof(struct llev_state_info_syscall), { NULL } }, + { "IRQ", sizeof(struct llev_state_info_irq), { NULL } }, + { "SOFTIRQ", sizeof(struct llev_state_info_softirq), { NULL } }, + { "TRAP", 0, { NULL } }, + { "PREEMPTED", sizeof(struct llev_state_info_preempted), { NULL } }, +}; + +struct state_info hlev_state_infos[] = { + { "UNKNOWN", 0, { "Total", "Unknown", NULL } }, + { "RUNNING", 0, { "Total", "Working", NULL } }, + { "BLOCKED", sizeof(struct hlev_state_info_blocked), { "Total", "Blocked", NULL } }, + { "INTERRUPTED_IRQ", sizeof(struct hlev_state_info_interrupted_irq), { "Total", "Interrupted", "IRQ", NULL } }, + { "INTERRUPTED_SOFTIRQ", sizeof(struct hlev_state_info_interrupted_softirq), { "Total", "Interrupted", "SoftIRQ", NULL } }, + { "INTERRUPTED_CPU", 0, { "Total", "Interrupted", "Preempted", NULL } }, + { "INTERRUPTED_POST_BLOCK", 0, { "Total", "Interrupted", "Waiting schedule after blocking", NULL } }, +}; + +enum llev_state { + LLEV_UNKNOWN=0, + LLEV_RUNNING, + LLEV_SYSCALL, + LLEV_IRQ, + LLEV_SOFTIRQ, + LLEV_TRAP, + LLEV_PREEMPTED, +}; + +enum llev_syscall_substate { + LLEV_SYSCALL__UNDEFINED, + LLEV_SYSCALL__OPEN, + LLEV_SYSCALL__READ, + LLEV_SYSCALL__POLL, +}; + +enum hlev_event { + HLEV_EVENT_TRY_WAKEUP=0, +}; + +enum hlev_state { + HLEV_UNKNOWN=0, + HLEV_RUNNING, + HLEV_BLOCKED, + HLEV_INTERRUPTED_IRQ, + HLEV_INTERRUPTED_SOFTIRQ, + HLEV_INTERRUPTED_CPU, + HLEV_INTERRUPTED_POST_BLOCK, +}; + +enum hlev_state_blocked { + HLEV_BLOCKED__UNDEFINED, + HLEV_BLOCKED__OPEN, + HLEV_BLOCKED__READ, + HLEV_BLOCKED__POLL, +}; + +struct sstack_event { + int event_type; + void *private; +}; + +struct try_wakeup_event { + int pid; /* this sould be more precise avec pid may be reused */ + LttTime time; + struct process *waker; +}; + +struct process_state { + int bstate; + int cause_type; + void *private; + + LttTime time_begin; + LttTime time_end; +}; + +struct process_with_state { + struct process *process; + struct process_state state; +}; + +#define PROCESS_STATE_STACK_SIZE 10 +struct process { + int pid; + GQuark name; + int parent; + + struct sstack *stack; + struct process_state *llev_state_stack[PROCESS_STATE_STACK_SIZE]; + int stack_current; + struct process_state *hlev_state; + GArray *hlev_history; +}; + +static inline void *old_process_state_private_data(struct process *p) +{ + return p->llev_state_stack[p->stack_current]->private; +} + +static inline struct process_state *process_find_state(struct process *p, enum llev_state st) +{ + int i; + + for(i=p->stack->array->len-1; i>=0; i--) { + struct sstack_item *item = g_array_index(p->stack->array, struct sstack_item *, i); + + struct process_with_state *pwstate = item->data_val; + if(pwstate->state.bstate == st) { + return &pwstate->state; + } + } + + return NULL; +} + +static int find_pos_in_stack(enum llev_state lls, struct process *p) +{ + int i; + for(i=p->stack_current; i>=0; i--) { + if(p->llev_state_stack[i]->bstate == lls) + return i; + } + + return -1; +} + +static struct process_state *find_in_stack(enum llev_state lls, struct process *p) +{ + int result; + + result = find_pos_in_stack(lls, p); + + if(result >= 0) + return p->llev_state_stack[result]; + else + return NULL; + +} + +/* called back from sstack on deletion of a data_val which is + * a struct process_with_state + */ + +static void delete_data_val(struct process_with_state *pwstate) +{ + // FIXME: Free this also + //g_free(pwstate->state.private); + + // FIXME: this is really ugly. Don't free the pwstate if the state is LLEV_RUNNING. + // LLEV_RUNNING is a special case that's being processed and deleted immediately after + // being inserted on the sstack, to prevent state begin accumulated because it couldn't + // be processed before the end of the trace. If we free the state, we get invalid memory + // reads when looking at it on the state_stack. + //if(pwstate->state.bstate != LLEV_RUNNING) + // g_free(pwstate); +} + +static struct sstack_item *prepare_push_item(struct process *p, enum llev_state st, LttTime t) +{ + struct process_with_state *pwstate = g_malloc(sizeof(struct process_with_state)); + struct sstack_item *item; + + int wait_for_pop = 0; + + if(st == LLEV_SYSCALL) { + /* We need to push LLEV_SYSCALL as wait_for_pop because it depends on some of + * its children. If we don't do this, it's going to get processed immediately + * by the sstack and we might miss some details about it that will come later. + */ + wait_for_pop = 1; + } + + item = sstack_item_new_push(wait_for_pop); + + //printf("pushing in context of %d\n", p->pid); + + pwstate->process = p; + pwstate->state.bstate = st; + pwstate->state.time_begin = t; + pwstate->state.private = g_malloc(llev_state_infos[st].size_priv); + + item->data_val = pwstate; + item->delete_data_val = delete_data_val; +} + +static void *item_private(struct sstack_item *item) +{ + struct process_with_state *pwstate = item->data_val; + return pwstate->state.private; +} + +static void commit_item(struct process *p, struct sstack_item *item) +{ + sstack_add_item(p->stack, item); +} + +static void old_process_push_llev_state(struct process *p, struct process_state *pstate) +{ + if(++p->stack_current >= PROCESS_STATE_STACK_SIZE) { + fprintf(stderr, "depanalysis: internal process stack overflow\n"); + abort(); + } + + p->llev_state_stack[p->stack_current] = pstate; +} + +static void live_complete_process_push_llev_state(struct process *p, enum llev_state st, LttTime t) +{ + struct process_state *pstate = g_malloc(sizeof(struct process_state)); + + pstate->bstate = st; + pstate->time_begin = t; + pstate->private = g_malloc(llev_state_infos[st].size_priv); + + old_process_push_llev_state(p, pstate); +} + +static void prepare_pop_item_commit_nocheck(struct process *p, enum llev_state st, LttTime t) +{ + struct process_with_state *pwstate; + struct sstack_item *item = sstack_item_new_pop(); + + int push_idx; + + if(p->stack->pushes->len > 0) + push_idx = g_array_index(p->stack->pushes, int, p->stack->pushes->len-1); + else + push_idx = -1; + + if(push_idx >= 0) { + pwstate = g_array_index(p->stack->array, struct sstack_item *, push_idx)->data_val; + pwstate->process = p; + pwstate->state.time_end = t; + item->data_val = pwstate; + /* don't set delete_data_val because we use the same pwstate as push, and we don't want to free it twice */ + } + else { + + pwstate = g_malloc(sizeof(struct process_with_state)); + pwstate->process = p; + item->data_val = pwstate; + pwstate->state.time_end = t; + pwstate->state.bstate = st; + } + + sstack_add_item(p->stack, item); + +} + +static void prepare_pop_item_commit(struct process *p, enum llev_state st, LttTime t) +{ + struct process_with_state *pwstate; + struct sstack_item *item = sstack_item_new_pop(); + + int push_idx; + + if(p->stack->pushes->len > 0) + push_idx = g_array_index(p->stack->pushes, int, p->stack->pushes->len-1); + else + push_idx = -1; + + if(push_idx >= 0) { + /* FIXME: ugly workaround for kernel bug that generates two kernel_arch_syscall_exit on fork. + * The bug only occurs upon creation of new processes. But these processes always have + * a LLEV_RUNNING at index 0. */ + if(push_idx >= p->stack->array->len) + return; + + pwstate = g_array_index(p->stack->array, struct sstack_item *, push_idx)->data_val; + + if(pwstate->state.bstate != st) { + /* FIXME: ugly workaround for kernel bug that generates two kernel_arch_syscall_exit on fork */ + if(st != LLEV_SYSCALL) { + printf("bad pop! at "); + print_time(t); + printf("\n"); + print_stack(p->stack); + abort(); + } + else { + /* case where we have a double syscall_exit */ + return; + } + } + } + + prepare_pop_item_commit_nocheck(p, st, t); +} + + +static int try_pop_blocked_llev_preempted(struct process *p, LttTime t) +{ + int push_idx; + struct process_with_state *pwstate; + + if(p->stack->pushes->len > 0) + push_idx = g_array_index(p->stack->pushes, int, p->stack->pushes->len-1); + else + push_idx = -1; + + if(push_idx >= 0) { + pwstate = g_array_index(p->stack->array, struct sstack_item *, push_idx)->data_val; + + if(!(pwstate->state.bstate == LLEV_PREEMPTED && ((struct llev_state_info_preempted *)pwstate->state.private)->prev_state > 0)) { + printf("double try wake up\n"); + return 0; + } + } + + prepare_pop_item_commit_nocheck(p, LLEV_PREEMPTED, t); + return 1; +} + +static void old_process_pop_llev_state(struct process *p, struct process_state *pstate) +{ + /* Ensure we are really popping the current state */ + /* FIXME: pstate->bstate is uninitialized? */ + // Commenting because it does not work. The way things work now, this check cannot work. + //if(p->llev_state_stack[p->stack_current]->bstate != LLEV_UNKNOWN && p->llev_state_stack[p->stack_current]->bstate != pstate->bstate) { + // printf("ERROR! bad pop!\n"); + // abort(); + //} + + /* Actually change the that position */ + if(p->stack_current >= 0) + p->stack_current--; + + /* If stack empty, we must put something in it */ + if(p->stack_current == -1) { + if(pstate->bstate == LLEV_SYSCALL) { + //process_push_llev_state(p, LLEV_RUNNING, pstate->time_end); + live_complete_process_push_llev_state(p, LLEV_RUNNING, pstate->time_end); + } + else { + live_complete_process_push_llev_state(p, LLEV_UNKNOWN, pstate->time_end); + } + } +} + +static GHashTable *process_hash_table; +static GHashTable *syscall_table; +static GHashTable *irq_table; +static GHashTable *softirq_table; + +/* Insert the hooks before and after each trace and tracefile, and for each + event. Print a global header. */ + +static FILE *a_file; + +static GString *a_string; + +static gboolean write_traceset_header(void *hook_data, void *call_data) +{ + LttvTracesetContext *tc = (LttvTracesetContext *)call_data; + + g_info("Traceset header"); + + /* Print the trace set header */ + fprintf(a_file,"Trace set contains %d traces\n\n", + lttv_traceset_number(tc->ts)); + + return FALSE; +} + +inline void print_time(LttTime t) +{ + //printf("%lu.%lu", t.tv_sec, t.tv_nsec); + double f; + f = (double)t.tv_sec + ((double)t.tv_nsec)/1000000000.0; + printf("%.9f", f); +} + +GArray *oldstyle_stack_to_garray(struct process_state_stack **oldstyle_stack, int current) +{ + GArray *retval; + int i; + + retval = g_array_new(FALSE, FALSE, sizeof(struct process_state_stack *)); + + for(i=0; istack_current; i>=0; i--) { + enum llev_state st; + st = p->llev_state_stack[i]->bstate; + + if(st == LLEV_RUNNING || st == LLEV_TRAP || st == LLEV_SYSCALL) { + new_hlev = HLEV_RUNNING; + break; + } + else if(st == LLEV_IRQ) { + new_hlev = HLEV_INTERRUPTED_IRQ; + break; + } + else if(st == LLEV_SOFTIRQ) { + new_hlev = HLEV_INTERRUPTED_SOFTIRQ; + break; + } + else if(st == LLEV_PREEMPTED) { + int prev_state = ((struct llev_state_info_preempted *) old_process_state_private_data(p))->prev_state; + + if(prev_state == 0) { + new_hlev = HLEV_INTERRUPTED_CPU; + } + else if(prev_state == -1) { + new_hlev = HLEV_INTERRUPTED_POST_BLOCK; + } + else { + new_hlev = HLEV_BLOCKED; + } + break; + } + else if(st == LLEV_UNKNOWN) { + new_hlev = HLEV_UNKNOWN; + break; + } + else { + abort(); + } + } + + /* If no state change, do nothing */ + if(p->hlev_state != NULL && new_hlev == p->hlev_state->bstate) { + return; + } + + p->hlev_state->time_end = t; + /* This check is here because we initially put HLEV_UNKNOWN as hlev state, but in the case + * of processes newly created, it is immediately replaced by HLEV_BLOCKED. In order to avoid + * having a UNKNOWN state of duration 0 in the summary, we don't add it. This isn't as elegant + * as it ought to be. + */ + if(ltt_time_compare(p->hlev_state->time_begin, p->hlev_state->time_end) != 0) + g_array_append_val(p->hlev_history, p->hlev_state); + p->hlev_state = g_malloc(sizeof(struct process_state)); + p->hlev_state->bstate = new_hlev; + p->hlev_state->time_begin = t; + p->hlev_state->private = g_malloc(hlev_state_infos[new_hlev].size_priv); + + //printf("depanalysis: now at hlev state %s\n", hlev_state_infos[new_hlev].name); + + /* Set private data */ + switch(p->hlev_state->bstate) { + case HLEV_UNKNOWN: + break; + case HLEV_RUNNING: + break; + case HLEV_BLOCKED: { + struct hlev_state_info_blocked *hlev_blocked_private = p->hlev_state->private; + //struct process_state *ps = find_in_stack(LLEV_SYSCALL, p); + int syscall_pos = find_pos_in_stack(LLEV_SYSCALL, p); + int trap_pos = find_pos_in_stack(LLEV_TRAP, p); + + /* init vals */ + hlev_blocked_private->syscall_id = 1; + hlev_blocked_private->trap = 0; + hlev_blocked_private->substate = HLEV_BLOCKED__UNDEFINED; + hlev_blocked_private->private = NULL; + hlev_blocked_private->llev_state_entry = oldstyle_stack_to_garray(p->llev_state_stack, p->stack_current); + hlev_blocked_private->llev_state_exit = NULL; + + //g_assert(syscall_pos >= 0 || trap_pos >= 0); + + if(trap_pos > syscall_pos) { + hlev_blocked_private->trap = 1; + } + + /* initial value, may be changed below */ + hlev_blocked_private->substate = HLEV_BLOCKED__UNDEFINED; + + if(syscall_pos >= 0) { + struct process_state *ps = p->llev_state_stack[syscall_pos]; + struct llev_state_info_syscall *llev_syscall_private = (struct llev_state_info_syscall *) ps->private; + hlev_blocked_private->syscall_id = llev_syscall_private->syscall_id; + + if(llev_syscall_private->substate == LLEV_SYSCALL__OPEN) { + struct llev_state_info_syscall__open *llev_syscall_open_private; + struct hlev_state_info_blocked__open *hlev_blocked_open_private; + llev_syscall_open_private = llev_syscall_private->private; + hlev_blocked_private->substate = HLEV_BLOCKED__OPEN; + hlev_blocked_open_private = g_malloc(sizeof(struct hlev_state_info_blocked__open)); + hlev_blocked_private->private = hlev_blocked_open_private; + hlev_blocked_open_private->filename = llev_syscall_open_private->filename; + + //printf("depanalysis: blocked in an open!\n"); + } + else if(llev_syscall_private->substate == LLEV_SYSCALL__READ) { + struct llev_state_info_syscall__read *llev_syscall_read_private; + struct hlev_state_info_blocked__read *hlev_blocked_read_private; + llev_syscall_read_private = llev_syscall_private->private; + hlev_blocked_private->substate = HLEV_BLOCKED__READ; + hlev_blocked_read_private = g_malloc(sizeof(struct hlev_state_info_blocked__read)); + hlev_blocked_private->private = hlev_blocked_read_private; + hlev_blocked_read_private->filename = llev_syscall_read_private->filename; + + //printf("depanalysis: blocked in a read!\n"); + } + else if(llev_syscall_private->substate == LLEV_SYSCALL__POLL) { + struct llev_state_info_syscall__poll *llev_syscall_poll_private; + struct hlev_state_info_blocked__poll *hlev_blocked_poll_private; + llev_syscall_poll_private = llev_syscall_private->private; + hlev_blocked_private->substate = HLEV_BLOCKED__POLL; + hlev_blocked_poll_private = g_malloc(sizeof(struct hlev_state_info_blocked__poll)); + hlev_blocked_private->private = hlev_blocked_poll_private; + hlev_blocked_poll_private->filename = llev_syscall_poll_private->filename; + + //printf("depanalysis: blocked in a read!\n"); + } + } + else { + hlev_blocked_private->syscall_id = -1; + } + + break; + } + case HLEV_INTERRUPTED_IRQ: { + struct hlev_state_info_interrupted_irq *sinfo = p->hlev_state->private; + struct process_state *ps = find_in_stack(LLEV_IRQ, p); + if(ps == NULL) + abort(); + else + sinfo->irq = ((struct llev_state_info_irq *) ps->private)->irq; + break; + } + case HLEV_INTERRUPTED_SOFTIRQ: { + struct hlev_state_info_interrupted_softirq *sinfo = p->hlev_state->private; + struct process_state *ps = find_in_stack(LLEV_SOFTIRQ, p); + if(ps == NULL) + abort(); + else + sinfo->softirq = ((struct llev_state_info_softirq *) ps->private)->softirq; + break; + } + default: + break; + }; +} + +static gint compare_summary_tree_node_times(gconstpointer a, gconstpointer b) +{ + struct summary_tree_node *n1 = (struct summary_tree_node *) a; + struct summary_tree_node *n2 = (struct summary_tree_node *) b; + + return ltt_time_compare(n2->duration, n1->duration); +} + +/* Print an item of the simple summary tree, and recurse, printing its children. + * + * If depth == -1, this is the root: we don't print a label, we only recurse into + * the children. + */ + +static void print_summary_item(struct summary_tree_node *node, int depth) +{ + GList *vals; + + if(depth >= 0) { + printf("\t%*s (", strlen(node->name)+2*depth, node->name); + print_time(node->duration); + printf(") <%d>\n", node->id_for_episodes); + } + + if(!node->children) + return; + + vals = g_hash_table_get_values(node->children); + + /* sort the values */ + vals = g_list_sort(vals, compare_summary_tree_node_times); + + while(vals) { + print_summary_item((struct summary_tree_node *)vals->data, depth+1); + vals = vals->next; + } + + /* we must free the list returned by g_hash_table_get_values() */ + g_list_free(vals); +} + +static inline void print_irq(int irq) +{ + printf("IRQ %d [%s]", irq, g_quark_to_string(g_hash_table_lookup(irq_table, &irq))); +} + +static inline void print_softirq(int softirq) +{ + printf("SoftIRQ %d [%s]", softirq, g_quark_to_string(g_hash_table_lookup(softirq_table, &softirq))); +} + +static inline void print_pid(int pid) +{ + struct process *event_process_info = g_hash_table_lookup(process_hash_table, &pid); + + char *pname; + + if(event_process_info == NULL) + pname = "?"; + else + pname = g_quark_to_string(event_process_info->name); + printf("%d [%s]", pid, pname); +} + +static void modify_path_with_private(GArray *path, struct process_state *pstate) +{ + //GString tmps = g_string_new(""); + char *tmps; + + // FIXME: fix this leak + switch(pstate->bstate) { + case HLEV_INTERRUPTED_IRQ: + asprintf(&tmps, "IRQ %d [%s]", ((struct hlev_state_info_interrupted_irq *)pstate->private)->irq, g_quark_to_string(g_hash_table_lookup(irq_table, &((struct hlev_state_info_interrupted_irq *)pstate->private)->irq))); + g_array_append_val(path, tmps); + break; + case HLEV_INTERRUPTED_SOFTIRQ: + asprintf(&tmps, "SoftIRQ %d [%s]", ((struct hlev_state_info_interrupted_softirq *)pstate->private)->softirq, g_quark_to_string(g_hash_table_lookup(softirq_table, &((struct hlev_state_info_interrupted_softirq *)pstate->private)->softirq))); + g_array_append_val(path, tmps); + break; + case HLEV_BLOCKED: { + struct hlev_state_info_blocked *hlev_blocked_private = (struct hlev_state_info_blocked *)pstate->private; + + if(hlev_blocked_private->trap) { + char *ptr = "Trap"; + g_array_append_val(path, ptr); + } + + if(hlev_blocked_private->syscall_id == -1) { + char *ptr = "Userspace"; + g_array_append_val(path, ptr); + } + else { + asprintf(&tmps, "Syscall %d [%s]", hlev_blocked_private->syscall_id, g_quark_to_string(g_hash_table_lookup(syscall_table, &hlev_blocked_private->syscall_id))); + g_array_append_val(path, tmps); + } + + if(((struct hlev_state_info_blocked *)pstate->private)->substate == HLEV_BLOCKED__OPEN) { + char *str = g_quark_to_string(((struct hlev_state_info_blocked__open *)((struct hlev_state_info_blocked *)pstate->private)->private)->filename); + g_array_append_val(path, str); + } + else if(((struct hlev_state_info_blocked *)pstate->private)->substate == HLEV_BLOCKED__READ) { + char *str; + asprintf(&str, "%s", g_quark_to_string(((struct hlev_state_info_blocked__read *)((struct hlev_state_info_blocked *)pstate->private)->private)->filename)); + g_array_append_val(path, str); + /* FIXME: this must be freed at some point */ + //free(str); + } + else if(((struct hlev_state_info_blocked *)pstate->private)->substate == HLEV_BLOCKED__POLL) { + char *str; + asprintf(&str, "%s", g_quark_to_string(((struct hlev_state_info_blocked__poll *)((struct hlev_state_info_blocked *)pstate->private)->private)->filename)); + g_array_append_val(path, str); + /* FIXME: this must be freed at some point */ + //free(str); + } + break; + } + }; +} + +void print_stack_garray_horizontal(GArray *stack) +{ + /* FIXME: this function doesn't work if we delete the states as we process them because we + * try to read those states here to print the low level stack. + */ + int i; + + for(i=0; ilen; i++) { + struct process_state *pstate = g_array_index(stack, struct process_state *, i); + printf("%s", llev_state_infos[pstate->bstate].name); + + if(pstate->bstate == LLEV_SYSCALL) { + struct llev_state_info_syscall *llev_syscall_private = pstate->private; + printf(" %d [%s]", llev_syscall_private->syscall_id, g_quark_to_string(g_hash_table_lookup(syscall_table, &llev_syscall_private->syscall_id))); + } + + printf(", "); + + } +} + +static int dicho_search_state_ending_after(struct process *p, LttTime t) +{ + int under = 0; + int over = p->hlev_history->len-1; + struct process_state *pstate; + int result; + + if(over < 1) + return -1; + + /* If the last element is smaller or equal than the time we are searching for, + * no match + */ + pstate = g_array_index(p->hlev_history, struct process_state *, over); + if(ltt_time_compare(pstate->time_end, t) <= 0) { + return -1; + } + /* no need to check for the equal case */ + + pstate = g_array_index(p->hlev_history, struct process_state *, under); + result = ltt_time_compare(pstate->time_end, t); + if(result >= 1) { + /* trivial match at the first element if it is greater or equal + * than the time we want + */ + return under; + } + + while(1) { + int dicho; + + dicho = (under+over)/2; + pstate = g_array_index(p->hlev_history, struct process_state *, dicho); + result = ltt_time_compare(pstate->time_end, t); + + if(result == -1) { + under = dicho; + } + else if(result == 1) { + over = dicho; + } + else { + /* exact match */ + return dicho+1; + } + + if(over-under == 1) { + /* we have converged */ + return over; + } + } + +} + +/* FIXME: this shouldn't be based on pids in case of reuse + * FIXME: should add a list of processes used to avoid loops + */ + +static struct process_state *find_state_ending_after(int pid, LttTime t) +{ + struct process *p; + int result; + + + p = g_hash_table_lookup(process_hash_table, &pid); + if(!p) + return NULL; + + result = dicho_search_state_ending_after(p, t); + + if(result == -1) + return NULL; + else + return g_array_index(p->hlev_history, struct process_state *, result); +} + +static void print_delay_pid(int pid, LttTime t1, LttTime t2, int offset) +{ + struct process *p; + int i; + + p = g_hash_table_lookup(process_hash_table, &pid); + if(!p) + return; + + i = dicho_search_state_ending_after(p, t1); + for(; ihlev_history->len; i++) { + struct process_state *pstate = g_array_index(p->hlev_history, struct process_state *, i); + if(ltt_time_compare(pstate->time_end, t2) > 0) + break; + + if(pstate->bstate == HLEV_BLOCKED) { + struct hlev_state_info_blocked *state_private_blocked; + state_private_blocked = pstate->private; + struct process_state *state_unblocked; + + printf("%*s", 8*offset, ""); + printf("Blocked in "); + print_stack_garray_horizontal(state_private_blocked->llev_state_entry); + + printf("(times: "); + print_time(pstate->time_begin); + printf("-"); + print_time(pstate->time_end); + + printf(", dur: %f)\n", 1e-9*ltt_time_to_double(ltt_time_sub(pstate->time_end, pstate->time_begin))); + + state_unblocked = find_state_ending_after(state_private_blocked->pid_exit, state_private_blocked->time_woken); + if(state_unblocked) { + if(state_unblocked->bstate == HLEV_INTERRUPTED_IRQ) { + struct hlev_state_info_interrupted_irq *priv = state_unblocked->private; + /* if in irq or softirq, we don't care what the waking process was doing because they are asynchroneous events */ + printf("%*s", 8*offset, ""); + printf("Woken up by an IRQ: "); + print_irq(priv->irq); + printf("\n"); + } + else if(state_unblocked->bstate == HLEV_INTERRUPTED_SOFTIRQ) { + struct hlev_state_info_interrupted_softirq *priv = state_unblocked->private; + printf("%*s", 8*offset, ""); + printf("Woken up by a SoftIRQ: "); + print_softirq(priv->softirq); + printf("\n"); + } + else { + LttTime t1prime=t1; + LttTime t2prime=t2; + + if(ltt_time_compare(t1prime, pstate->time_begin) < 0) + t1prime = pstate->time_begin; + if(ltt_time_compare(t2prime, pstate->time_end) > 0) + t2prime = pstate->time_end; + + print_delay_pid(state_private_blocked->pid_exit, t1prime, t2prime, offset+1); + printf("%*s", 8*offset, ""); + printf("Woken up in context of "); + print_pid(state_private_blocked->pid_exit); + if(state_private_blocked->llev_state_exit) { + print_stack_garray_horizontal(state_private_blocked->llev_state_exit); + } + else { + } + printf(" in high-level state %s", hlev_state_infos[state_unblocked->bstate].name); + printf("\n"); + } + } + else { + printf("%*s", 8*offset, ""); + printf("Weird... cannot find in what state the waker (%d) was\n", state_private_blocked->pid_exit); + } + + + //print_delay_pid(state_private_blocked->pid_exit, pstate->time_start, pstate->time_end); + //printf("\t\t Woken up in context of %d: ", state_private_blocked->pid_exit); + //if(state_private_blocked->llev_state_exit) { + // print_stack_garray_horizontal(state_private_blocked->llev_state_exit); + // printf("here3 (%d)\n", state_private_blocked->llev_state_exit->len); + //} + //else + // printf("the private_blocked %p had a null exit stack\n", state_private_blocked); + //printf("\n"); + } + } +} + +static void print_range_critical_path(int process, LttTime t1, LttTime t2) +{ + printf("Critical path for requested range:\n"); + printf("Final process is %d\n", process); + print_delay_pid(process, t1, t2, 2); +} + +static void print_process_critical_path_summary() +{ + struct process *pinfo; + GList *pinfos; + int i,j; + + pinfos = g_hash_table_get_values(process_hash_table); + if(pinfos == NULL) { + fprintf(stderr, "error: no process found\n"); + return; + } + + printf("Process Critical Path Summary:\n"); + + for(;;) { + struct summary_tree_node base_node = { children: NULL }; + + struct process_state *hlev_state_cur; + + pinfo = (struct process *)pinfos->data; + printf("\tProcess %d [%s]\n", pinfo->pid, g_quark_to_string(pinfo->name)); + + if(pinfo->hlev_history->len < 1) + goto next_iter; + + print_delay_pid(pinfo->pid, g_array_index(pinfo->hlev_history, struct process_state *, 0)->time_begin, g_array_index(pinfo->hlev_history, struct process_state *, pinfo->hlev_history->len - 1)->time_end, 2); + + next_iter: + + if(pinfos->next) + pinfos = pinfos->next; + else + break; + } +} + +gint compare_states_length(gconstpointer a, gconstpointer b) +{ + struct process_state **s1 = (struct process_state **)a; + struct process_state **s2 = (struct process_state **)b; + gint val; + + val = ltt_time_compare(ltt_time_sub((*s2)->time_end, (*s2)->time_begin), ltt_time_sub((*s1)->time_end, (*s1)->time_begin)); + return val; +} + +static void print_simple_summary() +{ + struct process *pinfo; + GList *pinfos; + GList *pinfos_first; + int i,j; + int id_for_episodes = 0; + + /* we save all the nodes here to print the episodes table quickly */ + GArray *all_nodes = g_array_new(FALSE, FALSE, sizeof(struct summary_tree_node *)); + + pinfos_first = g_hash_table_get_values(process_hash_table); + if(pinfos_first == NULL) { + fprintf(stderr, "error: no processes found\n"); + return; + } + pinfos = pinfos_first; + + printf("Simple summary:\n"); + + /* For each process */ + for(;;) { + struct summary_tree_node base_node = { children: NULL, name: "Root" }; + + struct process_state *hlev_state_cur; + + pinfo = (struct process *)pinfos->data; + printf("\tProcess %d [%s]\n", pinfo->pid, g_quark_to_string(pinfo->name)); + + /* For each state in the process history */ + for(i=0; ihlev_history->len; i++) { + struct process_state *pstate = g_array_index(pinfo->hlev_history, struct process_state *, i); + struct summary_tree_node *node_cur = &base_node; + GArray *tree_path_garray; + + /* Modify the path based on private data */ + tree_path_garray = g_array_new(FALSE, FALSE, sizeof(char *)); + { + int count=0; + char **tree_path_cur2 = hlev_state_infos[pstate->bstate].tree_path; + while(*tree_path_cur2) { + count++; + tree_path_cur2++; + } + g_array_append_vals(tree_path_garray, hlev_state_infos[pstate->bstate].tree_path, count); + } + modify_path_with_private(tree_path_garray, pstate); + + /* Walk the path, adding the nodes to the summary */ + for(j=0; jlen; j++) { + struct summary_tree_node *newnode; + GQuark componentquark; + + /* Have a path component we must follow */ + if(!node_cur->children) { + /* must create the hash table for the children */ + node_cur->children = g_hash_table_new(g_int_hash, g_int_equal); + } + + /* try to get the node for the next component */ + componentquark = g_quark_from_string(g_array_index(tree_path_garray, char *, j)); + newnode = g_hash_table_lookup(node_cur->children, &componentquark); + if(newnode == NULL) { + newnode = g_malloc(sizeof(struct summary_tree_node)); + newnode->children = NULL; + newnode->name = g_array_index(tree_path_garray, char *, j); + newnode->duration = ltt_time_zero; + newnode->id_for_episodes = id_for_episodes++; + newnode->episodes = g_array_new(FALSE, FALSE, sizeof(struct process_state *)); + g_hash_table_insert(node_cur->children, &componentquark, newnode); + + g_array_append_val(all_nodes, newnode); + } + node_cur = newnode; + + node_cur->duration = ltt_time_add(node_cur->duration, ltt_time_sub(pstate->time_end, pstate->time_begin)); + g_array_append_val(node_cur->episodes, pstate); + } + } + + /* print the summary */ + print_summary_item(&base_node, -1); + + printf("\n"); + + if(pinfos->next) + pinfos = pinfos->next; + else + break; + } + + printf("\n"); + + printf("Episode list\n"); + pinfos = pinfos_first; + + /* For all the nodes of the Simple summary tree */ + for(i=0; ilen; i++) { + struct summary_tree_node *node = (struct summary_tree_node *)g_array_index(all_nodes, struct summary_tree_node *, i); + + /* Sort the episodes from longest to shortest */ + g_array_sort(node->episodes, compare_states_length); + + printf("\tNode id: <%d>\n", node->id_for_episodes); + /* For each episode of the node */ + for(j=0; jepisodes->len; j++) { + struct process_state *st = g_array_index(node->episodes, struct process_state *, j); + + printf("\t\t"); + print_time(st->time_begin); + printf("-"); + print_time(st->time_end); + printf(" (%f)\n", 1e-9*ltt_time_to_double(ltt_time_sub(st->time_end,st->time_begin))); + } + } +} + +static void print_simple_summary_pid_range(int pid, LttTime t1, LttTime t2) +{ + struct process *pinfo; + int i,j; + int id_for_episodes = 0; + + /* we save all the nodes here to print the episodes table quickly */ + GArray *all_nodes = g_array_new(FALSE, FALSE, sizeof(struct summary_tree_node *)); + + pinfo = g_hash_table_lookup(process_hash_table, &pid); + + { + struct summary_tree_node base_node = { children: NULL, name: "Root" }; + + struct process_state *hlev_state_cur; + + printf("\tProcess %d [%s]\n", pinfo->pid, g_quark_to_string(pinfo->name)); + + /* For each state in the process history */ + for(i=0; ihlev_history->len; i++) { + struct process_state *pstate = g_array_index(pinfo->hlev_history, struct process_state *, i); + struct summary_tree_node *node_cur = &base_node; + GArray *tree_path_garray; + + if(ltt_time_compare(pstate->time_end, t1) < 0) + continue; + + if(ltt_time_compare(pstate->time_end, t2) > 0) + break; + + /* Modify the path based on private data */ + tree_path_garray = g_array_new(FALSE, FALSE, sizeof(char *)); + { + int count=0; + char **tree_path_cur2 = hlev_state_infos[pstate->bstate].tree_path; + while(*tree_path_cur2) { + count++; + tree_path_cur2++; + } + g_array_append_vals(tree_path_garray, hlev_state_infos[pstate->bstate].tree_path, count); + } + modify_path_with_private(tree_path_garray, pstate); + + /* Walk the path, adding the nodes to the summary */ + for(j=0; jlen; j++) { + struct summary_tree_node *newnode; + GQuark componentquark; + + /* Have a path component we must follow */ + if(!node_cur->children) { + /* must create the hash table for the children */ + node_cur->children = g_hash_table_new(g_int_hash, g_int_equal); + } + + /* try to get the node for the next component */ + componentquark = g_quark_from_string(g_array_index(tree_path_garray, char *, j)); + newnode = g_hash_table_lookup(node_cur->children, &componentquark); + if(newnode == NULL) { + newnode = g_malloc(sizeof(struct summary_tree_node)); + newnode->children = NULL; + newnode->name = g_array_index(tree_path_garray, char *, j); + newnode->duration = ltt_time_zero; + newnode->id_for_episodes = id_for_episodes++; + newnode->episodes = g_array_new(FALSE, FALSE, sizeof(struct process_state *)); + g_hash_table_insert(node_cur->children, &componentquark, newnode); + + g_array_append_val(all_nodes, newnode); + } + node_cur = newnode; + + node_cur->duration = ltt_time_add(node_cur->duration, ltt_time_sub(pstate->time_end, pstate->time_begin)); + g_array_append_val(node_cur->episodes, pstate); + } + } + + /* print the summary */ + print_summary_item(&base_node, -1); + + printf("\n"); + } + + printf("\n"); + + printf("Episode list\n"); + + /* For all the nodes of the Simple summary tree */ + for(i=0; ilen; i++) { + struct summary_tree_node *node = (struct summary_tree_node *)g_array_index(all_nodes, struct summary_tree_node *, i); + + /* Sort the episodes from longest to shortest */ + g_array_sort(node->episodes, compare_states_length); + + printf("\tNode id: <%d>\n", node->id_for_episodes); + /* For each episode of the node */ + for(j=0; jepisodes->len; j++) { + struct process_state *st = g_array_index(node->episodes, struct process_state *, j); + + printf("\t\t"); + print_time(st->time_begin); + printf("-"); + print_time(st->time_end); + printf(" (%f)\n", 1e-9*ltt_time_to_double(ltt_time_sub(st->time_end,st->time_begin))); + } + } +} + +static void flush_process_sstacks(void) +{ + GList *pinfos; + + pinfos = g_hash_table_get_values(process_hash_table); + while(pinfos) { + struct process *pinfo = (struct process *)pinfos->data; + + sstack_force_flush(pinfo->stack); + + pinfos = pinfos->next; + } + + g_list_free(pinfos); +} + +struct family_item { + int pid; + LttTime creation; +}; + +void print_range_reports(int pid, LttTime t1, LttTime t2) +{ + GArray *family = g_array_new(FALSE, FALSE, sizeof(struct family_item)); + int i; + + /* reconstruct the parental sequence */ + for(;;) { + struct process *pinfo; + struct family_item fi; + LttTime cur_beg; + + pinfo = g_hash_table_lookup(process_hash_table, &pid); + if(pinfo == NULL) + abort(); + + fi.pid = pid; + cur_beg = g_array_index(pinfo->hlev_history, struct process_state *, 0)->time_begin; + fi.creation = cur_beg; + g_array_append_val(family, fi); + + if(ltt_time_compare(cur_beg, t1) == -1) { + /* current pid starts before the interesting time */ + break; + } + if(pinfo->parent == -1) { + printf("unable to go back, we don't know the parent of %d\n", fi.pid); + abort(); + } + /* else, we go on */ + pid = pinfo->parent; + + } + + printf("Simple summary for range:\n"); + for(i=family->len-1; i>=0; i--) { + LttTime iter_t1, iter_t2; + int iter_pid = g_array_index(family, struct family_item, i).pid; + + if(i == family->len-1) + iter_t1 = t1; + else + iter_t1 = g_array_index(family, struct family_item, i).creation; + + if(i == 0) + iter_t2 = t2; + else + iter_t2 = g_array_index(family, struct family_item, i-1).creation; + + printf("This section of summary concerns pid %d between "); + print_time(iter_t1); + printf(" and "); + print_time(iter_t2); + printf(".\n"); + print_simple_summary_pid_range(iter_pid, iter_t1, iter_t2); + } + print_range_critical_path(depanalysis_range_pid, t1, t2); +} + +static gboolean write_traceset_footer(void *hook_data, void *call_data) +{ + LttvTracesetContext *tc = (LttvTracesetContext *)call_data; + + g_info("TextDump traceset footer"); + + fprintf(a_file,"End trace set\n\n"); + +// if(LTTV_IS_TRACESET_STATS(tc)) { +// lttv_stats_sum_traceset((LttvTracesetStats *)tc, ltt_time_infinite); +// print_stats(a_file, (LttvTracesetStats *)tc); +// } + + /* After processing all the events, we need to flush the sstacks + * because some unfinished states may remain in them. We want them + * event though there are incomplete. + */ + flush_process_sstacks(); + + /* print the reports */ + print_simple_summary(); + print_process_critical_path_summary(); + printf("depanalysis_use_time = %d\n", depanalysis_use_time); + if(depanalysis_use_time == 3) { + if(depanalysis_range_pid == -1 && depanalysis_range_pid_searching >= 0) + depanalysis_range_pid = depanalysis_range_pid_searching; + + if(depanalysis_range_pid >= 0) { + print_range_reports(depanalysis_range_pid, depanalysis_time1, depanalysis_time2); + } + else + printf("range critical path: could not find the end of the range\n"); + } + + return FALSE; +} + +#if 0 +static gboolean write_trace_header(void *hook_data, void *call_data) +{ + LttvTraceContext *tc = (LttvTraceContext *)call_data; +#if 0 //FIXME + LttSystemDescription *system = ltt_trace_system_description(tc->t); + + fprintf(a_file," Trace from %s in %s\n%s\n\n", + ltt_trace_system_description_node_name(system), + ltt_trace_system_description_domain_name(system), + ltt_trace_system_description_description(system)); +#endif //0 + return FALSE; +} +#endif + + +static int write_event_content(void *hook_data, void *call_data) +{ + gboolean result; + +// LttvIAttribute *attributes = LTTV_IATTRIBUTE(lttv_global_attributes()); + + LttvTracefileContext *tfc = (LttvTracefileContext *)call_data; + + LttvTracefileState *tfs = (LttvTracefileState *)call_data; + + LttEvent *e; + + guint cpu = tfs->cpu; + LttvTraceState *ts = (LttvTraceState*)tfc->t_context; + LttvProcessState *process = ts->running_process[cpu]; + + e = ltt_tracefile_get_event(tfc->tf); + + lttv_event_to_string(e, a_string, TRUE, 1, tfs); + +// if(a_state) { + g_string_append_printf(a_string, " %s ", + g_quark_to_string(process->state->s)); +// } + + g_string_append_printf(a_string,"\n"); + + fputs(a_string->str, a_file); + return FALSE; +} + +static int field_get_value_int(struct LttEvent *e, struct marker_info *info, GQuark f) +{ + struct marker_field *marker_field; + int found=0; + + for_each_marker_field(marker_field, info) { + if (marker_field->name == f) { + found = 1; + break; + } + } + g_assert(found); + return ltt_event_get_long_unsigned(e, marker_field); +} + +static char *field_get_value_string(struct LttEvent *e, struct marker_info *info, GQuark f) +{ + struct marker_field *marker_field; + int found=0; + + for_each_marker_field(marker_field, info) { + if (marker_field->name == f) { + found = 1; + break; + } + } + g_assert(found); + return ltt_event_get_string(e, marker_field); +} + +void process_delayed_stack_action(struct process *pinfo, struct sstack_item *item) +{ + //printf("processing delayed stack action on pid %d at ", pinfo->pid); + //if(((struct process_with_state *) item->data_val)->state.time_begin.tv_nsec == 987799696) + // printf("HERE!!!\n"); + //print_time(((struct process_with_state *) item->data_val)->state.time_begin); + //printf("\n"); + //printf("stack before:\n"); + //print_stack(pinfo->stack); + + if(item->data_type == SSTACK_TYPE_PUSH) { + struct process_with_state *pwstate = item->data_val; + //printf("pushing\n"); + old_process_push_llev_state(pinfo, &pwstate->state); + update_hlev_state(pinfo, pwstate->state.time_begin); + } + else if(item->data_type == SSTACK_TYPE_POP) { + struct process_with_state *pwstate = item->data_val; + //printf("popping\n"); + old_process_pop_llev_state(pinfo, &pwstate->state); + update_hlev_state(pinfo, pwstate->state.time_end); + } + else if(item->data_type == SSTACK_TYPE_EVENT) { + struct sstack_event *se = item->data_val; + if(se->event_type == HLEV_EVENT_TRY_WAKEUP) { + /* FIXME: should change hlev event from BLOCKED to INTERRUPTED CPU when receiving TRY_WAKEUP */ + struct try_wakeup_event *twe = se->private; + + /* FIXME: maybe do some more rigorous checking here */ + if(pinfo->hlev_state->bstate == HLEV_BLOCKED) { + struct hlev_state_info_blocked *hlev_blocked_private = pinfo->hlev_state->private; + + hlev_blocked_private->pid_exit = twe->pid; + hlev_blocked_private->time_woken = twe->time; + hlev_blocked_private->llev_state_exit = oldstyle_stack_to_garray(twe->waker->llev_state_stack, twe->waker->stack_current); + //printf("set a non null exit stack on %p, and stack size is %d\n", hlev_blocked_private, hlev_blocked_private->llev_state_exit->len); + + /* + if(p->stack_current >= 0 && p->llev_state_stack[p->stack_current]->bstate == LLEV_PREEMPTED) { + old_process_pop_llev_state(pinfo, p->llev_state_stack[p->stack_current]); + update_hlev_state(pinfo + old_process_push_llev_state + }*/ + + } + } + } + + //printf("stack after:\n"); + //print_stack(pinfo->stack); +} + +static struct process *get_or_init_process_info(struct LttEvent *e, GQuark name, int pid, int *new) +{ + gconstpointer val; + + val = g_hash_table_lookup(process_hash_table, &pid); + if(val == NULL) { + struct process *pinfo; + int i; + + /* Initialize new pinfo for newly discovered process */ + pinfo = g_malloc(sizeof(struct process)); + pinfo->pid = pid; + pinfo->parent = -1; /* unknown parent */ + pinfo->hlev_history = g_array_new(FALSE, FALSE, sizeof(struct process_state *)); + pinfo->stack = sstack_new(); + pinfo->stack_current=-1; + pinfo->stack->process_func = process_delayed_stack_action; + pinfo->stack->process_func_arg = pinfo; + for(i=0; illev_state_stack[i] = g_malloc(sizeof(struct process_state)); + } + + pinfo->hlev_state = g_malloc(sizeof(struct process_state)); + pinfo->hlev_state->bstate = HLEV_UNKNOWN; + pinfo->hlev_state->time_begin = e->event_time; + pinfo->hlev_state->private = NULL; + + /* set the name */ + pinfo->name = name; + + g_hash_table_insert(process_hash_table, &pinfo->pid, pinfo); + if(new) + *new = 1; + return pinfo; + } + else { + if(new) + *new = 0; + return val; + + } +} + +static int differentiate_swappers(int pid, LttEvent *e) +{ + if(pid == 0) + return pid+e->tracefile->cpu_num+2000000; + else + return pid; +} + +static int process_event(void *hook_data, void *call_data) +{ + LttvTracefileContext *tfc = (LttvTracefileContext *)call_data; + LttvTracefileState *tfs = (LttvTracefileState *)call_data; + LttEvent *e; + struct marker_info *info; + + /* Extract data from event structures and state */ + guint cpu = tfs->cpu; + LttvTraceState *ts = (LttvTraceState*)tfc->t_context; + LttvProcessState *process = ts->running_process[cpu]; + LttTrace *trace = ts->parent.t; + struct process *pinfo; + + e = ltt_tracefile_get_event(tfs->parent.tf); + + info = marker_get_info_from_id(tfc->tf->mdata, e->event_id); + + //if(depanalysis_use_time && (ltt_time_compare(e->timestamp, arg_t1) == -1 || ltt_time_compare(e->timestamp, arg_t2) == 1)) { + // return; + //} + /* Set the pid for the dependency analysis at each event, until we are passed the range. */ + if(depanalysis_use_time == 3) { + if(ltt_time_compare(e->event_time, depanalysis_time2) <= 0) { + depanalysis_range_pid = process->pid; + } + else { + /* Should stop processing and print results */ + } + } + + /* Code to limit the event count */ + if(depanalysis_event_limit > 0) { + depanalysis_event_limit--; + } + else if(depanalysis_event_limit == 0) { + write_traceset_footer(hook_data, call_data); + printf("exit due to event limit reached\n"); + exit(0); + } + + /* write event like textDump for now, for debugging purposes */ + //write_event_content(hook_data, call_data); + + if(tfc->tf->name == LTT_CHANNEL_SYSCALL_STATE && info->name == LTT_EVENT_SYS_CALL_TABLE) { + GQuark q; + int *pint = g_malloc(sizeof(int)); + + *pint = field_get_value_int(e, info, LTT_FIELD_ID); + q = g_quark_from_string(field_get_value_string(e, info, LTT_FIELD_SYMBOL)); + g_hash_table_insert(syscall_table, pint, q); + } + else if(tfc->tf->name == LTT_CHANNEL_IRQ_STATE && info->name == LTT_EVENT_LIST_INTERRUPT) { + GQuark q; + int *pint = g_malloc(sizeof(int)); + + *pint = field_get_value_int(e, info, LTT_FIELD_IRQ_ID); + q = g_quark_from_string(field_get_value_string(e, info, LTT_FIELD_ACTION)); + g_hash_table_insert(irq_table, pint, q); + } + else if(tfc->tf->name == LTT_CHANNEL_SOFTIRQ_STATE && info->name == LTT_EVENT_SOFTIRQ_VEC) { + GQuark q; + int *pint = g_malloc(sizeof(int)); + + *pint = field_get_value_int(e, info, LTT_FIELD_ID); + q = g_quark_from_string(field_get_value_string(e, info, LTT_FIELD_SYMBOL)); + g_hash_table_insert(softirq_table, pint, q); + } + + + /* Only look at events after the statedump is finished. + * Before that, the pids in the LttvProcessState are not reliable + */ + if(statedump_finished == 0) { + if(tfc->tf->name == LTT_CHANNEL_GLOBAL_STATE && info->name == LTT_EVENT_STATEDUMP_END) + statedump_finished = 1; + else + return FALSE; + + } + + pinfo = get_or_init_process_info(e, process->name, differentiate_swappers(process->pid, e), NULL); + + /* the state machine + * Process the event in the context of each process + */ + + if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_IRQ_ENTRY) { + struct process *event_process_info = pinfo; + struct sstack_item *item; + + item = prepare_push_item(event_process_info, LLEV_IRQ, e->event_time); + ((struct llev_state_info_irq *) item_private(item))->irq = field_get_value_int(e, info, LTT_FIELD_IRQ_ID); + commit_item(event_process_info, item); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_IRQ_EXIT) { + struct process *event_process_info = pinfo; + + prepare_pop_item_commit(event_process_info, LLEV_IRQ, e->event_time); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_SCHED_SCHEDULE) { + int next_pid = field_get_value_int(e, info, LTT_FIELD_NEXT_PID); + int prev_pid = field_get_value_int(e, info, LTT_FIELD_PREV_PID); + if(next_pid != 0) { + struct process *event_process_info = get_or_init_process_info(e, process->name, differentiate_swappers(next_pid, e), NULL); + prepare_pop_item_commit(event_process_info, LLEV_PREEMPTED, e->event_time); + } + if(prev_pid != 0) { + struct sstack_item *item; + struct process *event_process_info = get_or_init_process_info(e, process->name, differentiate_swappers(prev_pid, e), NULL); + + item = prepare_push_item(event_process_info, LLEV_PREEMPTED, e->event_time); + ((struct llev_state_info_preempted *) item_private(item))->prev_state = field_get_value_int(e, info, LTT_FIELD_PREV_STATE); + commit_item(event_process_info, item); + } + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_TRAP_ENTRY) { + struct process *event_process_info = pinfo; + struct sstack_item *item; + + item = prepare_push_item(event_process_info, LLEV_TRAP, e->event_time); + commit_item(event_process_info, item); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_TRAP_EXIT) { + struct process *event_process_info = pinfo; + + prepare_pop_item_commit(event_process_info, LLEV_TRAP, e->event_time); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_SYSCALL_ENTRY) { + struct process *event_process_info = pinfo; + struct sstack_item *item; + + item = prepare_push_item(event_process_info, LLEV_SYSCALL, e->event_time); + ((struct llev_state_info_syscall *) item_private(item))->syscall_id = field_get_value_int(e, info, LTT_FIELD_SYSCALL_ID); + ((struct llev_state_info_syscall *) item_private(item))->substate = LLEV_SYSCALL__UNDEFINED; + commit_item(event_process_info, item); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_SYSCALL_EXIT) { + struct process *event_process_info = pinfo; + + prepare_pop_item_commit(event_process_info, LLEV_SYSCALL, e->event_time); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_SOFT_IRQ_ENTRY) { + struct process *event_process_info = pinfo; + struct sstack_item *item; + + item = prepare_push_item(event_process_info, LLEV_SOFTIRQ, e->event_time); + ((struct llev_state_info_softirq *) item_private(item))->softirq = field_get_value_int(e, info, LTT_FIELD_SOFT_IRQ_ID); + commit_item(event_process_info, item); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_SOFT_IRQ_EXIT) { + struct process *event_process_info = pinfo; + + prepare_pop_item_commit(event_process_info, LLEV_SOFTIRQ, e->event_time); + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_PROCESS_FORK) { + int pid = differentiate_swappers(field_get_value_int(e, info, LTT_FIELD_CHILD_PID), e); + struct process *event_process_info = get_or_init_process_info(e, process->name, differentiate_swappers(field_get_value_int(e, info, LTT_FIELD_CHILD_PID), e), NULL); + struct sstack_item *item; + + event_process_info->parent = process->pid; + //printf("At "); + //print_time(e->event_time); + //printf(", fork in process %d (%s), creating child %d\n", differentiate_swappers(process->pid, e), g_quark_to_string(process->name), pid); + + item = prepare_push_item(event_process_info, LLEV_RUNNING, e->event_time); + commit_item(event_process_info, item); + item = prepare_push_item(event_process_info, LLEV_SYSCALL, e->event_time); + /* FIXME: this sets fork() as syscall, it's pretty inelegant */ + ((struct llev_state_info_syscall *) item_private(item))->syscall_id = 57; + ((struct llev_state_info_syscall *) item_private(item))->substate = LLEV_SYSCALL__UNDEFINED; + commit_item(event_process_info, item); + + item = prepare_push_item(event_process_info, LLEV_PREEMPTED, e->event_time); + /* Consider fork as BLOCKED */ + ((struct llev_state_info_preempted *) item_private(item))->prev_state = 1; + commit_item(event_process_info, item); + + //printf("process %d now has a stack of height %d\n", differentiate_swappers(process->pid, e), get_or_init_process_info(e, process->name, differentiate_swappers(process->pid, cpu), NULL)->stack_current-1); + + } + else if(tfc->tf->name == LTT_CHANNEL_FS && info->name == LTT_EVENT_EXEC) { + struct process *event_process_info = pinfo; + + guint cpu = tfs->cpu; + LttvProcessState *process_state = ts->running_process[cpu]; + event_process_info->name = process_state->name; + } + else if(tfc->tf->name == LTT_CHANNEL_FS && info->name == LTT_EVENT_OPEN) { + struct process_state *pstate = process_find_state(pinfo, LLEV_SYSCALL); + struct llev_state_info_syscall *llev_syscall_private; + struct llev_state_info_syscall__open *llev_syscall_open_private; + + /* TODO: this is too easy */ + if(pstate == NULL) + goto next_iter; + + llev_syscall_private = (struct llev_state_info_syscall *)pstate->private; + + //printf("depanalysis: found an open with state %d in pid %d\n", pstate->bstate, process->pid); + if(pstate->bstate == LLEV_UNKNOWN) + goto next_iter; + + g_assert(pstate->bstate == LLEV_SYSCALL); + g_assert(llev_syscall_private->substate == LLEV_SYSCALL__UNDEFINED); + + llev_syscall_private->substate = LLEV_SYSCALL__OPEN; + //printf("setting substate LLEV_SYSCALL__OPEN on syscall_private %p\n", llev_syscall_private); + llev_syscall_private->private = g_malloc(sizeof(struct llev_state_info_syscall__open)); + llev_syscall_open_private = llev_syscall_private->private; + + llev_syscall_open_private->filename = g_quark_from_string(field_get_value_string(e, info, LTT_FIELD_FILENAME)); + + } + else if(tfc->tf->name == LTT_CHANNEL_FS && info->name == LTT_EVENT_READ) { + struct process_state *pstate = process_find_state(pinfo, LLEV_SYSCALL); + struct llev_state_info_syscall *llev_syscall_private; + struct llev_state_info_syscall__read *llev_syscall_read_private; + GQuark pfileq; + int fd; + + /* TODO: this is too easy */ + if(pstate == NULL) + goto next_iter; + + llev_syscall_private = (struct llev_state_info_syscall *)pstate->private; + + //printf("depanalysis: found an read with state %d in pid %d\n", pstate->bstate, process->pid); + if(pstate->bstate == LLEV_UNKNOWN) + goto next_iter; + + g_assert(pstate->bstate == LLEV_SYSCALL); + g_assert(llev_syscall_private->substate == LLEV_SYSCALL__UNDEFINED); + + llev_syscall_private->substate = LLEV_SYSCALL__READ; + //printf("setting substate LLEV_SYSCALL__READ on syscall_private %p\n", llev_syscall_private); + llev_syscall_private->private = g_malloc(sizeof(struct llev_state_info_syscall__read)); + llev_syscall_read_private = llev_syscall_private->private; + + fd = field_get_value_int(e, info, LTT_FIELD_FD); + pfileq = g_hash_table_lookup(process->fds, fd); + if(pfileq) { + llev_syscall_read_private->filename = pfileq; + } + else { + char *tmp; + asprintf(&tmp, "Unknown filename, fd %d", fd); + llev_syscall_read_private->filename = g_quark_from_string(tmp); + free(tmp); + } + } + else if(tfc->tf->name == LTT_CHANNEL_FS && info->name == LTT_EVENT_POLL_EVENT) { + struct process_state *pstate = process_find_state(pinfo, LLEV_SYSCALL); + struct llev_state_info_syscall *llev_syscall_private; + struct llev_state_info_syscall__poll *llev_syscall_poll_private; + GQuark pfileq; + int fd; + + /* TODO: this is too easy */ + if(pstate == NULL) + goto next_iter; + + llev_syscall_private = (struct llev_state_info_syscall *)pstate->private; + + //printf("depanalysis: found an poll with state %d in pid %d\n", pstate->bstate, process->pid); + if(pstate->bstate == LLEV_UNKNOWN) + goto next_iter; + + /* poll doesn't have a single event that gives the syscall args. instead, there can be an arbitrary + * number of fs_pollfd or fd_poll_event events + * We use the fd_poll_event event, which occurs for each fd that had activity causing a return of the poll() + * For now we only use the first. + * We should do something about this. FIXME + */ + if(llev_syscall_private->substate == LLEV_SYSCALL__POLL) + goto next_iter; + + g_assert(pstate->bstate == LLEV_SYSCALL); + g_assert(llev_syscall_private->substate == LLEV_SYSCALL__UNDEFINED); + + llev_syscall_private->substate = LLEV_SYSCALL__POLL; + //printf("setting substate LLEV_SYSCALL__POLL on syscall_private %p\n", llev_syscall_private); + llev_syscall_private->private = g_malloc(sizeof(struct llev_state_info_syscall__poll)); + llev_syscall_poll_private = llev_syscall_private->private; + + fd = field_get_value_int(e, info, LTT_FIELD_FD); + pfileq = g_hash_table_lookup(process->fds, fd); + if(pfileq) { + llev_syscall_poll_private->filename = pfileq; + } + else { + char *tmp; + asprintf(&tmp, "Unknown filename, fd %d", fd); + llev_syscall_poll_private->filename = g_quark_from_string(tmp); + free(tmp); + } + } + else if(tfc->tf->name == LTT_CHANNEL_KERNEL && info->name == LTT_EVENT_SCHED_TRY_WAKEUP) { + struct sstack_event *se = g_malloc(sizeof(struct sstack_event)); + struct try_wakeup_event *twe = g_malloc(sizeof(struct try_wakeup_event)); + struct sstack_item *item = sstack_item_new_event(); + int target = field_get_value_int(e, info, LTT_FIELD_PID); + struct process *target_pinfo; + int result; + + se->event_type = HLEV_EVENT_TRY_WAKEUP; + se->private = twe; + //printf("pushing try wake up event in context of %d\n", pinfo->pid); + + twe->pid = differentiate_swappers(process->pid, e); + twe->time = e->event_time; + twe->waker = pinfo; + + /* FIXME: the target could not yet have an entry in the hash table, we would then lose data */ + target_pinfo = g_hash_table_lookup(process_hash_table, &target); + if(!target_pinfo) + goto next_iter; + + item->data_val = se; + item->delete_data_val = delete_data_val; + + sstack_add_item(target_pinfo->stack, item); + + /* Now pop the blocked schedule out of the target */ + result = try_pop_blocked_llev_preempted(target_pinfo, e->event_time); + + if(result) { + struct sstack_item *item; + struct process *event_process_info = target_pinfo; + + item = prepare_push_item(event_process_info, LLEV_PREEMPTED, e->event_time); + ((struct llev_state_info_preempted *) item_private(item))->prev_state = -1; /* special value meaning post-block sched out */ + commit_item(event_process_info, item); + } + + } + + next_iter: + skip_state_machine: + return FALSE; +} + +void print_sstack_private(struct sstack_item *item) +{ + struct process_with_state *pwstate = item->data_val; + + if(pwstate && item->data_type == SSTACK_TYPE_PUSH) + printf("\tstate: %s", llev_state_infos[pwstate->state.bstate].name); + + printf(" ("); + print_time(pwstate->state.time_begin); + printf("-"); + print_time(pwstate->state.time_end); + printf("\n"); + +} + +static LttTime ltt_time_from_string(const char *str) +{ + LttTime retval; + + char *decdot = strchr(str, '.'); + + if(decdot) { + *decdot = '\0'; + retval.tv_nsec = atol(decdot+1); + } + else { + retval.tv_nsec = 0; + } + + retval.tv_sec = atol(str); + + return retval; +} + +static void arg_t1(void *hook_data) +{ + printf("arg_t1\n"); + depanalysis_use_time |= 1; + depanalysis_time1 = ltt_time_from_string(arg_t1_str); +} + +static void arg_t2(void *hook_data) +{ + depanalysis_use_time |= 2; + depanalysis_time2 = ltt_time_from_string(arg_t2_str); +} + +static void arg_pid(void *hook_data) +{ +} + +static void arg_limit(void *hook_data) +{ +} + +static void init() +{ + gboolean result; + + print_sstack_item_data = print_sstack_private; + + LttvAttributeValue value; + + LttvIAttribute *attributes = LTTV_IATTRIBUTE(lttv_global_attributes()); + + a_file = stdout; + + lttv_option_add("dep-time-start", 0, "dependency analysis time of analysis start", "time", + LTTV_OPT_STRING, &arg_t1_str, arg_t1, NULL); + lttv_option_add("dep-time-end", 0, "dependency analysis time of analysis end", "time", + LTTV_OPT_STRING, &arg_t2_str, arg_t2, NULL); + lttv_option_add("dep-pid", 0, "dependency analysis pid", "pid", + LTTV_OPT_INT, &depanalysis_range_pid_searching, arg_pid, NULL); + lttv_option_add("limit-events", 0, "dependency limit event count", "count", + LTTV_OPT_INT, &depanalysis_event_limit, arg_limit, NULL); + + process_hash_table = g_hash_table_new(g_int_hash, g_int_equal); + syscall_table = g_hash_table_new(g_int_hash, g_int_equal); + irq_table = g_hash_table_new(g_int_hash, g_int_equal); + softirq_table = g_hash_table_new(g_int_hash, g_int_equal); + + a_string = g_string_new(""); + + result = lttv_iattribute_find_by_path(attributes, "hooks/event", + LTTV_POINTER, &value); + g_assert(result); + event_hook = *(value.v_pointer); + g_assert(event_hook); + lttv_hooks_add(event_hook, process_event, NULL, LTTV_PRIO_DEFAULT); + +// result = lttv_iattribute_find_by_path(attributes, "hooks/trace/before", +// LTTV_POINTER, &value); +// g_assert(result); +// before_trace = *(value.v_pointer); +// g_assert(before_trace); +// lttv_hooks_add(before_trace, write_trace_header, NULL, LTTV_PRIO_DEFAULT); +// + result = lttv_iattribute_find_by_path(attributes, "hooks/traceset/before", + LTTV_POINTER, &value); + g_assert(result); + before_traceset = *(value.v_pointer); + g_assert(before_traceset); + lttv_hooks_add(before_traceset, write_traceset_header, NULL, + LTTV_PRIO_DEFAULT); + + result = lttv_iattribute_find_by_path(attributes, "hooks/traceset/after", + LTTV_POINTER, &value); + g_assert(result); + after_traceset = *(value.v_pointer); + g_assert(after_traceset); + lttv_hooks_add(after_traceset, write_traceset_footer, NULL, + LTTV_PRIO_DEFAULT); +} + +static void destroy() +{ + lttv_option_remove("dep-time-start"); + lttv_option_remove("dep-time-end"); + lttv_option_remove("dep-pid"); + lttv_option_remove("limit-events"); + + g_hash_table_destroy(process_hash_table); + g_hash_table_destroy(syscall_table); + g_hash_table_destroy(irq_table); + g_hash_table_destroy(softirq_table); + + g_string_free(a_string, TRUE); + + lttv_hooks_remove_data(event_hook, write_event_content, NULL); +// lttv_hooks_remove_data(before_trace, write_trace_header, NULL); + lttv_hooks_remove_data(before_traceset, write_traceset_header, NULL); + lttv_hooks_remove_data(after_traceset, write_traceset_footer, NULL); +} + +LTTV_MODULE("depanalysis", "Dependency analysis test", \ + "Produce a dependency analysis of a trace", \ + init, destroy, "stats", "batchAnalysis", "option", "print") + diff --git a/lttv/modules/text/sstack.c b/lttv/modules/text/sstack.c new file mode 100644 index 00000000..532bab33 --- /dev/null +++ b/lttv/modules/text/sstack.c @@ -0,0 +1,405 @@ +#include + +#include "sstack.h" + +/* This is the implementation of sstack, a data structure that holds + * operations done on a stack in order to play them on a stack a short + * while later. They are played when dependencies are fulfilled. The + * operations are held in a queue. + * + * Operations include PUSH of data, POP, as well as other special markers. + * + * Stack operations are defined by a struct sstack_item. Each struct + * sstack_item has 3 flags: + * - finished + * - processable + * - deletable + * + * Finished is raised when all the dependencies of the operation are + * fulfilled. POPs are always created finished because they have no + * dependencies. PUSHes are marked finished when their corresponding + * POP is added to the queueit is the PUSHes + * that contain the and EVENTs are always created finished. + * + * Once an operation is finished + */ + +void (*print_sstack_item_data)(struct sstack_item *); + +/* Debugging function: print a queue item */ + +static void print_item(struct sstack_item *item) +{ + char *label; + + if(item->data_type == SSTACK_TYPE_PUSH) { + label = "PUSH"; + } + else if(item->data_type == SSTACK_TYPE_POP) { + label = "POP"; + } + else { + label = "UNKNOWN"; + } + + printf("%-10s %-2u%-2u%-2u", label, item->finished, item->processable, item->deletable); + /* hack: call this external, application-dependant function to show the private data in the item */ + print_sstack_item_data(item); +} + +/* Debugging function: print the queue as it is now */ + +void print_stack(struct sstack *stack) +{ + int i; + + printf("************************\n"); + printf("** %-10s F P D\n", "label"); + for(i=0; iarray->len; i++) { + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, i); + + printf("** %-3d- ", i); + print_item(item); + } + printf("\n"); +} + +static void try_start_deleting(struct sstack *stack) +{ + int index = stack->array->len-1; + + while(index >= 0 && g_array_index(stack->array, struct sstack_item *, index)->deletable) { + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, index); + + if(item->delete_data_val) + item->delete_data_val(item->data_val); + + //g_array_free(item->depends, FALSE); + //g_array_free(item->rev_depends, FALSE); + g_free(item); + + g_array_remove_index(stack->array, index); + index--; + } + + if(stack->proc_index > stack->array->len) + stack->proc_index = stack->array->len; +} + +/* An item is deletable as soon as it is processed. However, all the items after it + * in the list must be deleted before it can be deleted. + * + * After this function, try_start_deleting must be called. + */ + +static void mark_deletable(struct sstack *stack, int index) +{ + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, index); + + item->deletable = 1; + +// if(index == stack->array->len - 1) { +// start_deleting(stack); +// } +} + +#if 0 +/* Called to process an index of the queue */ + +static void process(struct sstack *stack, int index) +{ + g_assert(stack->proc_index == index); + + //printf("sstack: starting to process\n"); + while(stack->proc_index < stack->array->len) { + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, stack->proc_index); + + if(!item->processable) + break; + + //printf("sstack: processing "); + //print_item(item); + + if(stack->process_func) { + stack->process_func(stack->process_func_arg, item); + } + else { + printf("warning: no process func\n"); + } + + stack->proc_index++; + + mark_deletable(stack, stack->proc_index-1); + if(item->pushpop >= 0 && item->pushpop < stack->proc_index-1) { + mark_deletable(stack, item->pushpop); + } + try_start_deleting(stack); + } + //printf("sstack: stopping processing\n"); +} + +/* Called to mark an index of the queue as processable */ + +static void mark_processable(struct sstack *stack, int index) +{ + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, index); + + item->processable = 1; + + if(stack->proc_index <= stack->array->len && stack->proc_index == index) { + process(stack, index); + } +} + +/* Called to check whether an index of the queue could be marked processable. If so, + * mark it processable. + * + * To be processable, an item must: + * - be finished + * - have its push/pop dependency fulfilled + * - have its other dependencies fulfilled + */ + +static void try_mark_processable(struct sstack *stack, int index) +{ + int i; + int all_finished = 1; + + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, index); + + //for(i=0; iarray->len; i++) { + // if(!g_array_index(stack->array, struct sstack_item *, index)->finished) { + // all_finished = 0; + // break; + // } + //} + + /* Theoritically, we should confirm that the push/pop dependency is + * finished, but in practice, it's not necessary. If we are a push, the + * corresponding pop is always finished. If we are a pop and we exist, + * the corresponding push is necessarily finished. + */ + + //if(all_finished) { + if(item->finished) { + mark_processable(stack, index); + } + //} +} + +/* Called to mark an index of the queue as finished */ + +static void mark_finished(struct sstack *stack, int index) +{ + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, index); + + item->finished = 1; + + try_mark_processable(stack, index); +} + +#endif +/* --------------------- */ + +static void try_advance_processing(struct sstack *stack) +{ + //g_assert(stack->proc_index == index); + + //printf("sstack: starting to process\n"); + while(stack->proc_index < stack->array->len) { + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, stack->proc_index); + + //if(!item->finished) { + // break; + //} + + //printf("sstack: processing "); + //print_item(item); + + if(stack->process_func) { + stack->process_func(stack->process_func_arg, item); + } + else { + printf("warning: no process func\n"); + } + + stack->proc_index++; + + if(item->data_type == SSTACK_TYPE_POP) + mark_deletable(stack, stack->proc_index-1); + if(item->pushpop >= 0 && item->pushpop < stack->proc_index-1) { + mark_deletable(stack, item->pushpop); + } + } + try_start_deleting(stack); + //printf("sstack: stopping processing\n"); +} + + +/* Add an item to the queue */ + +void sstack_add_item(struct sstack *stack, struct sstack_item *item) +{ + int index; + + g_array_append_val(stack->array, item); + + //printf("stack after adding\n"); + //print_stack(stack); + + index = stack->array->len-1; + + if(item->data_type == SSTACK_TYPE_PUSH) { + int top_of_wait_pop_stack; + + if(stack->wait_pop_stack->len && g_array_index(stack->wait_pop_stack, int, stack->wait_pop_stack->len-1)) { + /* if the preceding is a wait_for_pop (and there is a preceding), push a wait_for_pop */ + const int one=1; + g_array_append_val(stack->wait_pop_stack, one); + } + else { + /* otherwise, push what the item wants */ + g_array_append_val(stack->wait_pop_stack, item->wait_pop); + } + + top_of_wait_pop_stack = g_array_index(stack->wait_pop_stack, int, stack->wait_pop_stack->len-1); + + g_array_append_val(stack->pushes, index); + + //printf("after pushing:\n"); + //print_stack(stack); + if(top_of_wait_pop_stack == 0) { + try_advance_processing(stack); + /* ASSERT that we processed the whole sstack */ + } + //printf("after processing:\n"); + //print_stack(stack); + } + else if(item->data_type == SSTACK_TYPE_POP) { + item->finished = 1; + + if(stack->pushes->len > 0) { + /* FIXME: confirm we are popping what we expected to pop */ + item->pushpop = g_array_index(stack->pushes, int, stack->pushes->len-1); + g_array_index(stack->array, struct sstack_item *, item->pushpop)->pushpop = index; + g_array_index(stack->array, struct sstack_item *, item->pushpop)->finished = 1; + + g_array_remove_index(stack->pushes, stack->pushes->len-1); + } + + if(stack->wait_pop_stack->len > 0) { + int top_of_wait_pop_stack; + + g_array_remove_index(stack->wait_pop_stack, stack->wait_pop_stack->len-1); + + if(stack->wait_pop_stack->len > 0) { + top_of_wait_pop_stack = g_array_index(stack->wait_pop_stack, int, stack->wait_pop_stack->len-1); + + if(top_of_wait_pop_stack == 0) + try_advance_processing(stack); + } + else { + try_advance_processing(stack); + } + } + else { + try_advance_processing(stack); + } + } + + //printf("stack after processing\n"); + //print_stack(stack); +} + +/* Force processing of all items */ + +void sstack_force_flush(struct sstack *stack) +{ + int i; + + for(i=0; iarray->len; i++) { + struct sstack_item *item = g_array_index(stack->array, struct sstack_item *, i); + + if(!item->finished) { + item->finished = 1; + } + } + + try_advance_processing(stack); +} + +/* Create a new sstack */ + +struct sstack *sstack_new(void) +{ + struct sstack *retval; + + retval = (struct sstack *) g_malloc(sizeof(struct sstack)); + + retval->array = g_array_new(FALSE, FALSE, sizeof(struct sstack_item *)); + retval->pushes = g_array_new(FALSE, FALSE, sizeof(int)); + retval->wait_pop_stack = g_array_new(FALSE, FALSE, sizeof(int)); + retval->proc_index = 0; + retval->process_func = NULL; + + return retval; +} + +/* Create a new sstack_item. Normally not invoked directly. See other functions below. */ + +struct sstack_item *sstack_item_new(void) +{ + struct sstack_item *retval; + + retval = (struct sstack_item *) g_malloc(sizeof(struct sstack_item)); + retval->finished = 0; + retval->processable = 0; + retval->deletable = 0; + retval->data_type = 0; + retval->data_val = NULL; + retval->delete_data_val = NULL; + retval->pushpop = -1; + retval->wait_pop = 0; + //retval->depends = g_array_new(FALSE, FALSE, sizeof(int)); + //retval->rev_depends = g_array_new(FALSE, FALSE, sizeof(int)); + + return retval; +} + +/* Create a new sstack_item that will represent a PUSH operation */ + +struct sstack_item *sstack_item_new_push(unsigned char wait_pop) +{ + struct sstack_item *retval = sstack_item_new(); + + retval->data_type = SSTACK_TYPE_PUSH; + retval->wait_pop = wait_pop; + + return retval; +} + +/* Create a new sstack_item that will represent a POP operation */ + +struct sstack_item *sstack_item_new_pop(void) +{ + struct sstack_item *retval = sstack_item_new(); + + retval->data_type = SSTACK_TYPE_POP; + retval->finished = 1; + + return retval; +} + +/* Create a new sstack_item that will represent an EVENT operation */ + +struct sstack_item *sstack_item_new_event(void) +{ + struct sstack_item *retval = sstack_item_new(); + + retval->data_type = SSTACK_TYPE_EVENT; + retval->finished = 1; + retval->processable = 1; + retval->deletable = 1; + + return retval; +} diff --git a/lttv/modules/text/sstack.h b/lttv/modules/text/sstack.h new file mode 100644 index 00000000..4ff713b1 --- /dev/null +++ b/lttv/modules/text/sstack.h @@ -0,0 +1,72 @@ +#ifndef SSTACK_H +#define SSTACK_H + +#define SSTACK_TYPE_PUSH 1 +#define SSTACK_TYPE_POP 2 +#define SSTACK_TYPE_EVENT 3 + +//#define SSTACK_PUSH_VAL(i) (()i->data_val) + +/* An item of a struct sstack, that describes a stack operation */ + +struct sstack_item { + /* state flags */ + unsigned char finished; + unsigned char processable; + unsigned char deletable; + + /* Type of operation: SSTACK_TYPE_PUSH, SSTACK_TYPE_POP or SSTACK_TYPE_EVENT */ + int data_type; + /* private, application-dependant data */ + void *data_val; + + /* Function to call to delete data_val */ + void (*delete_data_val)(void *data_val); + + /* The index of the corresponding push (for a pop) or pop (for a push) */ + int pushpop; + + /* Does this item require that we wait for its pop to process it */ + int wait_pop; + + GArray *depends; + GArray *rev_depends; +}; + +/* external debugging function to print the private data of an item */ +extern void (*print_sstack_item_data)(struct sstack_item *); + +/* An actual sstack */ + +struct sstack { + GArray *array; + + /* Stack of the indexes of the pushes that have been done. An index is popped when the + * corresponding pop is added to the sstack. This enables us to find the index of the + * last push. + */ + GArray *pushes; + + /* Stack of 0's and 1's. 0: don't wait for pop to process the children + * 1: wait for pop to process its children + */ + GArray *wait_pop_stack; + + /* Next item we must try to process */ + int proc_index; + + void (*process_func)(void *arg, struct sstack_item *item); + void *process_func_arg; /* the pointer passed as the "arg" argument of process_func */ +}; + +struct sstack_item *sstack_new_item(); + +void sstack_add_item(struct sstack *stack, struct sstack_item *item); + +struct sstack *sstack_new(void); +struct sstack_item *sstack_item_new(void); +struct sstack_item *sstack_item_new_push(unsigned char finished); +struct sstack_item *sstack_item_new_pop(void); +struct sstack_item *sstack_item_new_evt(void); + +#endif /* SSTACK_H */