[lttv.git] / usertrace-fast / ltt-usertrace-fast.c

/* LTTng user-space "fast" library
 *
 * This daemon is spawned by each traced thread (to share the mmap).
 *
 * Its job is to dump periodically this buffer to disk (when it receives a
 * SIGUSR1 from its parent).
 *
 * It uses the control information in the shared memory area (producer/consumer
 * count).
 *
 * When the parent thread dies (yes, those thing may happen) ;) , this daemon
 * will flush the last buffer and write it to disk.
 *
 * Supplement note for streaming : the daemon is responsible for flushing
 * periodically the buffer if it is streaming data.
 * 
 *
 * Notes :
 * shm memory is typically limited to 4096 units (system wide limit SHMMNI in
 * /proc/sys/kernel/shmmni). As it requires computation time upon creation, we
 * do not use it : we will use a shared mmap() instead which is passed through
 * the fork().
 * MAP_SHARED mmap segment. Updated when msync or munmap are called.
 * MAP_ANONYMOUS.
 * Memory  mapped  by  mmap()  is  preserved across fork(2), with the same
 *   attributes.
 * 
 * Eventually, there will be two mode :
 * * Slow thread spawn : a fork() is done for each new thread. If the process
 *   dies, the data is not lost.
 * * Fast thread spawn : a pthread_create() is done by the application for each
 *   new thread.
 *
 * We use a timer to check periodically if the parent died. I think it is less
 * intrusive than a ptrace() on the parent, which would get every signal. The
 * side effect of this is that we won't be notified if the parent does an
 * exec(). In this case, we will just sit there until the parent exits.
 * 
 *   
 * Copyright 2006 Mathieu Desnoyers
 *
 */

#define inline inline __attribute__((always_inline))

#define _GNU_SOURCE
#define LTT_TRACE
#include <sys/types.h>
#include <sys/wait.h>
#include <unistd.h>
#include <stdlib.h>
#include <stdio.h>
#include <signal.h>
#include <syscall.h>
#include <features.h>
#include <pthread.h>
#include <malloc.h>
#include <string.h>
#include <sys/mman.h>
#include <signal.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <stdlib.h>
#include <sys/param.h>
#include <sys/time.h>
#include <errno.h>

#include <asm/atomic.h>
#include <asm/timex.h>	//for get_cycles()

_syscall0(pid_t,gettid)

#include <ltt/ltt-usertrace-fast.h>

#ifdef LTT_SHOW_DEBUG
#define dbg_printf(...) dbg_printf(__VA_ARGS__)
#else
#define dbg_printf(...)
#endif //LTT_SHOW_DEBUG

	
enum force_switch_mode { FORCE_ACTIVE, FORCE_FLUSH };

/* Writer (the traced application) */

__thread struct ltt_trace_info *thread_trace_info = NULL;

void ltt_usertrace_fast_buffer_switch(void)
{
	struct ltt_trace_info *tmp = thread_trace_info;
	if(tmp)
		kill(tmp->daemon_id, SIGUSR1);
}

/* The cleanup should never be called from a signal handler */
static void ltt_usertrace_fast_cleanup(void *arg)
{
	struct ltt_trace_info *tmp = thread_trace_info;
	if(tmp) {
		thread_trace_info = NULL;
		kill(tmp->daemon_id, SIGUSR2);
		munmap(tmp, sizeof(*tmp));
	}
}

/* Reader (the disk dumper daemon) */

static pid_t traced_pid = 0;
static pid_t traced_tid = 0;
static int parent_exited = 0;

/* signal handling */
static void handler_sigusr1(int signo)
{
	dbg_printf("LTT Signal %d received : parent buffer switch.\n", signo);
}

static void handler_sigusr2(int signo)
{
	dbg_printf("LTT Signal %d received : parent exited.\n", signo);
	parent_exited = 1;
}

static void handler_sigalarm(int signo)
{
	dbg_printf("LTT Signal %d received\n", signo);

	if(getppid() != traced_pid) {
		/* Parent died */
		dbg_printf("LTT Parent %lu died, cleaning up\n", traced_pid);
		traced_pid = 0;
	}
	alarm(3);
}

/* Do a buffer switch. Don't switch if buffer is completely empty */
static void flush_buffer(struct ltt_buf *ltt_buf, enum force_switch_mode mode)
{
	uint64_t tsc;
	int offset_begin, offset_end, offset_old;
	int reserve_commit_diff;
	int consumed_old, consumed_new;
	int commit_count, reserve_count;
	int end_switch_old;

	do {
		offset_old = atomic_read(&ltt_buf->offset);
		offset_begin = offset_old;
		end_switch_old = 0;
		tsc = ltt_get_timestamp();
		if(tsc == 0) {
			/* Error in getting the timestamp : should not happen : it would
			 * mean we are called from an NMI during a write seqlock on xtime. */
			return;
		}

		if(SUBBUF_OFFSET(offset_begin, ltt_buf) != 0) {
			offset_begin = SUBBUF_ALIGN(offset_begin, ltt_buf);
			end_switch_old = 1;
		} else {
      /* we do not have to switch : buffer is empty */
      return;
    }
		if(mode == FORCE_ACTIVE)
			offset_begin += ltt_subbuf_header_len(ltt_buf);
		/* Always begin_switch in FORCE_ACTIVE mode */

		/* Test new buffer integrity */
		reserve_commit_diff = 
			atomic_read(
				&ltt_buf->reserve_count[SUBBUF_INDEX(offset_begin, ltt_buf)])
			- atomic_read(
					&ltt_buf->commit_count[SUBBUF_INDEX(offset_begin, ltt_buf)]);
		if(reserve_commit_diff == 0) {
      /* Next buffer not corrupted. */ 
      if(mode == FORCE_ACTIVE
				&& (offset_begin-atomic_read(&ltt_buf->consumed))
											>= ltt_buf->alloc_size) {
      	/* We do not overwrite non consumed buffers and we are full : ignore
        	 switch while tracing is active. */ 
        return;
      }   
    } else { 
      /* Next subbuffer corrupted. Force pushing reader even in normal mode */
    }
			
		offset_end = offset_begin;
	} while(atomic_cmpxchg(&ltt_buf->offset, offset_old, offset_end)
							!= offset_old);


	if(mode == FORCE_ACTIVE) {
		/* Push the reader if necessary */
		do {
			consumed_old = atomic_read(&ltt_buf->consumed);
			/* If buffer is in overwrite mode, push the reader consumed count if
				 the write position has reached it and we are not at the first
				 iteration (don't push the reader farther than the writer). 
				 This operation can be done concurrently by many writers in the
				 same buffer, the writer being at the fartest write position sub-buffer
				 index in the buffer being the one which will win this loop. */
			/* If the buffer is not in overwrite mode, pushing the reader only
				 happen if a sub-buffer is corrupted */
			if((SUBBUF_TRUNC(offset_end, ltt_buf) 
					- SUBBUF_TRUNC(consumed_old, ltt_buf)) 
							>= ltt_buf->alloc_size)
				consumed_new = SUBBUF_ALIGN(consumed_old, ltt_buf);
			else {
				consumed_new = consumed_old;
				break;
			}
		} while(atomic_cmpxchg(&ltt_buf->consumed, consumed_old, consumed_new)
				!= consumed_old);

		if(consumed_old != consumed_new) {
			/* Reader pushed : we are the winner of the push, we can therefore
				 reequilibrate reserve and commit. Atomic increment of the commit
				 count permits other writers to play around with this variable
				 before us. We keep track of corrupted_subbuffers even in overwrite
				 mode :
				 we never want to write over a non completely committed sub-buffer : 
				 possible causes : the buffer size is too low compared to the unordered
				 data input, or there is a writer who died between the reserve and the
				 commit. */
			if(reserve_commit_diff) {
				/* We have to alter the sub-buffer commit count : a sub-buffer is
					 corrupted */
				atomic_add(reserve_commit_diff,
								&ltt_buf->commit_count[SUBBUF_INDEX(offset_begin, ltt_buf)]);
				atomic_inc(&ltt_buf->corrupted_subbuffers);
			}
		}
	}

	/* Always switch */

	if(end_switch_old) {
		/* old subbuffer */
		/* Concurrency safe because we are the last and only thread to alter this
			 sub-buffer. As long as it is not delivered and read, no other thread can
			 alter the offset, alter the reserve_count or call the
			 client_buffer_end_callback on this sub-buffer.
			 The only remaining threads could be the ones with pending commits. They
			 will have to do the deliver themself.
			 Not concurrency safe in overwrite mode. We detect corrupted subbuffers with
			 commit and reserve counts. We keep a corrupted sub-buffers count and push
			 the readers across these sub-buffers.
			 Not concurrency safe if a writer is stalled in a subbuffer and
			 another writer switches in, finding out it's corrupted. The result will be
			 than the old (uncommited) subbuffer will be declared corrupted, and that
			 the new subbuffer will be declared corrupted too because of the commit
			 count adjustment.
			 Offset old should never be 0. */
		ltt_buffer_end_callback(ltt_buf, tsc, offset_old,
				SUBBUF_INDEX((offset_old), ltt_buf));
		/* Setting this reserve_count will allow the sub-buffer to be delivered by
			 the last committer. */
		reserve_count = atomic_add_return((SUBBUF_OFFSET((offset_old-1),
                                                      ltt_buf) + 1),
										&ltt_buf->reserve_count[SUBBUF_INDEX((offset_old),
                                                          ltt_buf)]);
		if(reserve_count == atomic_read(
				&ltt_buf->commit_count[SUBBUF_INDEX((offset_old), ltt_buf)])) {
			ltt_deliver_callback(ltt_buf, SUBBUF_INDEX((offset_old), ltt_buf), NULL);
		}
	}
	
	if(mode == FORCE_ACTIVE) {
		/* New sub-buffer */
		/* This code can be executed unordered : writers may already have written
			 to the sub-buffer before this code gets executed, caution. */
		/* The commit makes sure that this code is executed before the deliver
			 of this sub-buffer */
		ltt_buffer_begin_callback(ltt_buf, tsc, SUBBUF_INDEX(offset_begin, ltt_buf));
		commit_count = atomic_add_return(ltt_subbuf_header_len(ltt_buf),
								 &ltt_buf->commit_count[SUBBUF_INDEX(offset_begin, ltt_buf)]);
		/* Check if the written buffer has to be delivered */
		if(commit_count	== atomic_read(
					&ltt_buf->reserve_count[SUBBUF_INDEX(offset_begin, ltt_buf)])) {
			ltt_deliver_callback(ltt_buf, SUBBUF_INDEX(offset_begin, ltt_buf), NULL);
		}
	}

}

static inline int ltt_buffer_get(struct ltt_buf *ltt_buf,
		unsigned int *offset)
{
	unsigned int consumed_old, consumed_idx;
	consumed_old = atomic_read(&ltt_buf->consumed);
	consumed_idx = SUBBUF_INDEX(consumed_old, ltt_buf);
	
	if(atomic_read(&ltt_buf->commit_count[consumed_idx])
		!= atomic_read(&ltt_buf->reserve_count[consumed_idx])) {
		return -EAGAIN;
	}
	if((SUBBUF_TRUNC(atomic_read(&ltt_buf->offset), ltt_buf)
				-SUBBUF_TRUNC(consumed_old, ltt_buf)) == 0) {
		return -EAGAIN;
	}
	
	*offset = consumed_old;

	return 0;
}

static inline int ltt_buffer_put(struct ltt_buf *ltt_buf,
		unsigned int offset)
{
	unsigned int consumed_old, consumed_new;
	int ret;

	consumed_old = offset;
	consumed_new = SUBBUF_ALIGN(consumed_old, ltt_buf);
	if(atomic_cmpxchg(&ltt_buf->consumed, consumed_old, consumed_new)
			!= consumed_old) {
		/* We have been pushed by the writer : the last buffer read _is_
		 * corrupted!
		 * It can also happen if this is a buffer we never got. */
		return -EIO;
	} else {
		if(atomic_inc_return(&ltt_buf->writer_futex) <= 0) {
			atomic_set(&ltt_buf->writer_futex, 1);
			/* tell the client that buffer is now unfull */
			ret = futex((unsigned long)&ltt_buf->writer_futex,
					FUTEX_WAKE, 1, 0, 0, 0);
			if(ret != 1) {
				dbg_printf("LTT warning : race condition : writer not waiting or too many writers\n");
			}
		}
	}
}

static int read_subbuffer(struct ltt_buf *ltt_buf, int fd)
{
	unsigned int consumed_old;
	int err;
	dbg_printf("LTT read buffer\n");


	err = ltt_buffer_get(ltt_buf, &consumed_old);
	if(err != 0) {
		if(err != -EAGAIN) dbg_printf("LTT Reserving sub buffer failed\n");
		goto get_error;
	}

	err = TEMP_FAILURE_RETRY(write(fd,
				ltt_buf->start 
					+ (consumed_old & ((ltt_buf->alloc_size)-1)),
				ltt_buf->subbuf_size));

	if(err < 0) {
		perror("Error in writing to file");
		goto write_error;
	}
#if 0
	err = fsync(pair->trace);
	if(err < 0) {
		ret = errno;
		perror("Error in writing to file");
		goto write_error;
	}
#endif //0
write_error:
	err = ltt_buffer_put(ltt_buf, consumed_old);

	if(err != 0) {
		if(err == -EIO) {
			dbg_printf("Reader has been pushed by the writer, last subbuffer corrupted.\n");
			/* FIXME : we may delete the last written buffer if we wish. */
		}
		goto get_error;
	}

get_error:
	return err;
}

/* This function is called by ltt_rw_init which has signals blocked */
static void ltt_usertrace_fast_daemon(struct ltt_trace_info *shared_trace_info,
		sigset_t oldset, pid_t l_traced_pid, pthread_t l_traced_tid)
{
	struct sigaction act;
	int ret;
	int fd_process;
	char outfile_name[PATH_MAX];
	char identifier_name[PATH_MAX];


	traced_pid = l_traced_pid;
	traced_tid = l_traced_tid;

	dbg_printf("LTT ltt_usertrace_fast_daemon : init is %d, pid is %lu, traced_pid is %lu, traced_tid is %lu\n",
			shared_trace_info->init, getpid(), traced_pid, traced_tid);

	act.sa_handler = handler_sigusr1;
	act.sa_flags = 0;
	sigemptyset(&(act.sa_mask));
	sigaddset(&(act.sa_mask), SIGUSR1);
	sigaction(SIGUSR1, &act, NULL);

	act.sa_handler = handler_sigusr2;
	act.sa_flags = 0;
	sigemptyset(&(act.sa_mask));
	sigaddset(&(act.sa_mask), SIGUSR2);
	sigaction(SIGUSR2, &act, NULL);

	act.sa_handler = handler_sigalarm;
	act.sa_flags = 0;
	sigemptyset(&(act.sa_mask));
	sigaddset(&(act.sa_mask), SIGALRM);
	sigaction(SIGALRM, &act, NULL);

	/* Enable signals */
	ret = pthread_sigmask(SIG_SETMASK, &oldset, NULL);
	if(ret) {
		dbg_printf("LTT Error in pthread_sigmask\n");
	}

	alarm(3);

	/* Open output files */
	umask(00000);
	ret = mkdir(LTT_USERTRACE_ROOT, 0777);
	if(ret < 0 && errno != EEXIST) {
		perror("LTT Error in creating output (mkdir)");
		exit(-1);
	}
	ret = chdir(LTT_USERTRACE_ROOT);
	if(ret < 0) {
		perror("LTT Error in creating output (chdir)");
		exit(-1);
	}
	snprintf(identifier_name, PATH_MAX-1,	"%lu.%lu.%llu",
			traced_tid, traced_pid, get_cycles());
	snprintf(outfile_name, PATH_MAX-1,	"process-%s", identifier_name);
#ifndef LTT_NULL_OUTPUT_TEST
	fd_process = creat(outfile_name, 0644);
#else
	/* NULL test */
	ret = symlink("/dev/null", outfile_name);
	if(ret < 0) {
		perror("error in symlink");
	}
	fd_process = open(outfile_name, O_WRONLY);
	if(fd_process < 0) {
		perror("Error in open");
	}
#endif //LTT_NULL_OUTPUT_TEST
	
	while(1) {
		pause();
		if(traced_pid == 0) break; /* parent died */
		if(parent_exited) break;
		dbg_printf("LTT Doing a buffer switch read. pid is : %lu\n", getpid());
	
		do {
			ret = read_subbuffer(&shared_trace_info->channel.process, fd_process);
		} while(ret == 0);
	}

	/* The parent thread is dead and we have finished with the buffer */

	/* Buffer force switch (flush). Using FLUSH instead of ACTIVE because we know
	 * there is no writer. */
	flush_buffer(&shared_trace_info->channel.process, FORCE_FLUSH);
	do {
		ret = read_subbuffer(&shared_trace_info->channel.process, fd_process);
	} while(ret == 0);


	close(fd_process);
	
	munmap(shared_trace_info, sizeof(*shared_trace_info));
	
	exit(0);
}


/* Reader-writer initialization */

static enum ltt_process_role { LTT_ROLE_WRITER, LTT_ROLE_READER }
	role = LTT_ROLE_WRITER;


void ltt_rw_init(void)
{
	pid_t pid;
	struct ltt_trace_info *shared_trace_info;
	int ret;
	sigset_t set, oldset;
	pid_t l_traced_pid = getpid();
	pid_t l_traced_tid = gettid();

	/* parent : create the shared memory map */
	shared_trace_info = mmap(0, sizeof(*thread_trace_info),
			PROT_READ|PROT_WRITE, MAP_SHARED|MAP_ANONYMOUS, 0, 0);
	shared_trace_info->init=0;
	shared_trace_info->filter=0;
	shared_trace_info->daemon_id=0;
	shared_trace_info->nesting=0;
	memset(&shared_trace_info->channel.process, 0,
			sizeof(shared_trace_info->channel.process));
	/* Tricky semaphore : is in a shared memory space, so it's ok for a fast
	 * mutex (futex). */
	atomic_set(&shared_trace_info->channel.process.writer_futex, LTT_N_SUBBUFS);
	shared_trace_info->channel.process.alloc_size = LTT_BUF_SIZE_PROCESS;
	shared_trace_info->channel.process.subbuf_size = LTT_SUBBUF_SIZE_PROCESS;
	shared_trace_info->channel.process.start =
						shared_trace_info->channel.process_buf;
	ltt_buffer_begin_callback(&shared_trace_info->channel.process,
			ltt_get_timestamp(), 0);
	
	shared_trace_info->init = 1;

	/* Disable signals */
  ret = sigfillset(&set);
  if(ret) {
    dbg_printf("LTT Error in sigfillset\n");
  } 
	
	
  ret = pthread_sigmask(SIG_BLOCK, &set, &oldset);
  if(ret) {
    dbg_printf("LTT Error in pthread_sigmask\n");
  }

	pid = fork();
	if(pid > 0) {
		/* Parent */
		shared_trace_info->daemon_id = pid;
		thread_trace_info = shared_trace_info;

		/* Enable signals */
		ret = pthread_sigmask(SIG_SETMASK, &oldset, NULL);
		if(ret) {
			dbg_printf("LTT Error in pthread_sigmask\n");
		}
	} else if(pid == 0) {
		pid_t sid;
		/* Child */
		role = LTT_ROLE_READER;
		sid = setsid();
		//Not a good idea to renice, unless futex wait eventually implement
		//priority inheritence.
		//ret = nice(1);
		//if(ret < 0) {
		//	perror("Error in nice");
		//}
		if(sid < 0) {
			perror("Error setting sid");
		}
		ltt_usertrace_fast_daemon(shared_trace_info, oldset, l_traced_pid,
					l_traced_tid);
		/* Should never return */
		exit(-1);
	} else if(pid < 0) {
		/* fork error */
		perror("LTT Error in forking ltt-usertrace-fast");
	}
}

static __thread struct _pthread_cleanup_buffer cleanup_buffer;

void ltt_thread_init(void)
{
	_pthread_cleanup_push(&cleanup_buffer, ltt_usertrace_fast_cleanup, NULL);
	ltt_rw_init();
}
	
void __attribute__((constructor)) __ltt_usertrace_fast_init(void)
{
  dbg_printf("LTT usertrace-fast init\n");

	ltt_rw_init();
}

void __attribute__((destructor)) __ltt_usertrace_fast_fini(void)
{
	if(role == LTT_ROLE_WRITER) {
	  dbg_printf("LTT usertrace-fast fini\n");
		ltt_usertrace_fast_cleanup(NULL);
	}
}
Commit	Line	Data
700d350d	1	/* LTTng user-space "fast" library
	2	*
	3	* This daemon is spawned by each traced thread (to share the mmap).
	4	*
	5	* Its job is to dump periodically this buffer to disk (when it receives a
	6	* SIGUSR1 from its parent).
	7	*
	8	* It uses the control information in the shared memory area (producer/consumer
	9	* count).
	10	*
	11	* When the parent thread dies (yes, those thing may happen) ;) , this daemon
	12	* will flush the last buffer and write it to disk.
	13	*
	14	* Supplement note for streaming : the daemon is responsible for flushing
	15	* periodically the buffer if it is streaming data.
	16	*
b09f3215	17	*
700d350d	18	* Notes :
	19	* shm memory is typically limited to 4096 units (system wide limit SHMMNI in
	20	* /proc/sys/kernel/shmmni). As it requires computation time upon creation, we
	21	* do not use it : we will use a shared mmap() instead which is passed through
	22	* the fork().
	23	* MAP_SHARED mmap segment. Updated when msync or munmap are called.
	24	* MAP_ANONYMOUS.
	25	* Memory mapped by mmap() is preserved across fork(2), with the same
	26	* attributes.
	27	*
	28	* Eventually, there will be two mode :
	29	* * Slow thread spawn : a fork() is done for each new thread. If the process
	30	* dies, the data is not lost.
	31	* * Fast thread spawn : a pthread_create() is done by the application for each
	32	* new thread.
a85b8f41	33	*
	34	* We use a timer to check periodically if the parent died. I think it is less
	35	* intrusive than a ptrace() on the parent, which would get every signal. The
	36	* side effect of this is that we won't be notified if the parent does an
	37	* exec(). In this case, we will just sit there until the parent exits.
	38	*
	39	*
b09f3215	40	* Copyright 2006 Mathieu Desnoyers
	41	*
	42	*/
	43
8a9103df	44	#define inline inline __attribute__((always_inline))
8a9103df	45
32f2b04a	46	#define _GNU_SOURCE
8b30e7bc	47	#define LTT_TRACE
b09f3215	48	#include <sys/types.h>
	49	#include <sys/wait.h>
	50	#include <unistd.h>
	51	#include <stdlib.h>
	52	#include <stdio.h>
	53	#include <signal.h>
	54	#include <syscall.h>
	55	#include <features.h>
	56	#include <pthread.h>
	57	#include <malloc.h>
	58	#include <string.h>
700d350d	59	#include <sys/mman.h>
700d350d	60	#include <signal.h>
77b31f39	61	#include <sys/stat.h>
	62	#include <fcntl.h>
	63	#include <stdlib.h>
	64	#include <sys/param.h>
47d7d576	65	#include <sys/time.h>
8b30e7bc	66	#include <errno.h>
77b31f39	67
32f2b04a	68	#include <asm/atomic.h>
77b31f39	69	#include <asm/timex.h> //for get_cycles()
b09f3215	70
8b30e7bc	71	_syscall0(pid_t,gettid)
8b30e7bc	72
b5d612cb	73	#include <ltt/ltt-usertrace-fast.h>
b09f3215	74
8a9103df	75	#ifdef LTT_SHOW_DEBUG
	76	#define dbg_printf(...) dbg_printf(__VA_ARGS__)
	77	#else
	78	#define dbg_printf(...)
	79	#endif //LTT_SHOW_DEBUG
	80
	81
32f2b04a	82	enum force_switch_mode { FORCE_ACTIVE, FORCE_FLUSH };
b09f3215	83
e8efa18d	84	/* Writer (the traced application) */
b09f3215	85
e8efa18d	86	__thread struct ltt_trace_info *thread_trace_info = NULL;
700d350d	87
e8efa18d	88	void ltt_usertrace_fast_buffer_switch(void)
e8efa18d	89	{
a85b8f41	90	struct ltt_trace_info *tmp = thread_trace_info;
	91	if(tmp)
	92	kill(tmp->daemon_id, SIGUSR1);
e8efa18d	93	}
700d350d	94
77b31f39	95	/* The cleanup should never be called from a signal handler */
e8efa18d	96	static void ltt_usertrace_fast_cleanup(void *arg)
b09f3215	97	{
a85b8f41	98	struct ltt_trace_info *tmp = thread_trace_info;
	99	if(tmp) {
	100	thread_trace_info = NULL;
	101	kill(tmp->daemon_id, SIGUSR2);
	102	munmap(tmp, sizeof(*tmp));
	103	}
700d350d	104	}
b09f3215	105
e8efa18d	106	/* Reader (the disk dumper daemon) */
700d350d	107
a85b8f41	108	static pid_t traced_pid = 0;
4c992ad5	109	static pid_t traced_tid = 0;
e8efa18d	110	static int parent_exited = 0;
700d350d	111
e8efa18d	112	/* signal handling */
e8efa18d	113	static void handler_sigusr1(int signo)
700d350d	114	{
8a9103df	115	dbg_printf("LTT Signal %d received : parent buffer switch.\n", signo);
e8efa18d	116	}
	117
	118	static void handler_sigusr2(int signo)
	119	{
8a9103df	120	dbg_printf("LTT Signal %d received : parent exited.\n", signo);
e8efa18d	121	parent_exited = 1;
	122	}
	123
	124	static void handler_sigalarm(int signo)
	125	{
8a9103df	126	dbg_printf("LTT Signal %d received\n", signo);
e8efa18d	127
a85b8f41	128	if(getppid() != traced_pid) {
e8efa18d	129	/* Parent died */
8a9103df	130	dbg_printf("LTT Parent %lu died, cleaning up\n", traced_pid);
a85b8f41	131	traced_pid = 0;
e8efa18d	132	}
e8efa18d	133	alarm(3);
b09f3215	134	}
b09f3215	135
47d7d576	136	/* Do a buffer switch. Don't switch if buffer is completely empty */
32f2b04a	137	static void flush_buffer(struct ltt_buf *ltt_buf, enum force_switch_mode mode)
47d7d576	138	{
32f2b04a	139	uint64_t tsc;
	140	int offset_begin, offset_end, offset_old;
	141	int reserve_commit_diff;
	142	int consumed_old, consumed_new;
	143	int commit_count, reserve_count;
	144	int end_switch_old;
47d7d576	145
32f2b04a	146	do {
	147	offset_old = atomic_read(&ltt_buf->offset);
	148	offset_begin = offset_old;
	149	end_switch_old = 0;
	150	tsc = ltt_get_timestamp();
	151	if(tsc == 0) {
	152	/* Error in getting the timestamp : should not happen : it would
	153	* mean we are called from an NMI during a write seqlock on xtime. */
	154	return;
	155	}
	156
	157	if(SUBBUF_OFFSET(offset_begin, ltt_buf) != 0) {
	158	offset_begin = SUBBUF_ALIGN(offset_begin, ltt_buf);
	159	end_switch_old = 1;
	160	} else {
	161	/* we do not have to switch : buffer is empty */
	162	return;
	163	}
	164	if(mode == FORCE_ACTIVE)
	165	offset_begin += ltt_subbuf_header_len(ltt_buf);
	166	/* Always begin_switch in FORCE_ACTIVE mode */
	167
	168	/* Test new buffer integrity */
	169	reserve_commit_diff =
	170	atomic_read(
	171	&ltt_buf->reserve_count[SUBBUF_INDEX(offset_begin, ltt_buf)])
	172	- atomic_read(
	173	&ltt_buf->commit_count[SUBBUF_INDEX(offset_begin, ltt_buf)]);
	174	if(reserve_commit_diff == 0) {
	175	/* Next buffer not corrupted. */
	176	if(mode == FORCE_ACTIVE
	177	&& (offset_begin-atomic_read(&ltt_buf->consumed))
	178	>= ltt_buf->alloc_size) {
	179	/* We do not overwrite non consumed buffers and we are full : ignore
	180	switch while tracing is active. */
	181	return;
	182	}
	183	} else {
	184	/* Next subbuffer corrupted. Force pushing reader even in normal mode */
	185	}
	186
	187	offset_end = offset_begin;
	188	} while(atomic_cmpxchg(&ltt_buf->offset, offset_old, offset_end)
	189	!= offset_old);
	190
	191
	192	if(mode == FORCE_ACTIVE) {
	193	/* Push the reader if necessary */
	194	do {
	195	consumed_old = atomic_read(&ltt_buf->consumed);
	196	/* If buffer is in overwrite mode, push the reader consumed count if
	197	the write position has reached it and we are not at the first
	198	iteration (don't push the reader farther than the writer).
	199	This operation can be done concurrently by many writers in the
	200	same buffer, the writer being at the fartest write position sub-buffer
	201	index in the buffer being the one which will win this loop. */
	202	/* If the buffer is not in overwrite mode, pushing the reader only
	203	happen if a sub-buffer is corrupted */
	204	if((SUBBUF_TRUNC(offset_end, ltt_buf)
	205	- SUBBUF_TRUNC(consumed_old, ltt_buf))
	206	>= ltt_buf->alloc_size)
	207	consumed_new = SUBBUF_ALIGN(consumed_old, ltt_buf);
	208	else {
	209	consumed_new = consumed_old;
210	break;
211	}
212	} while(atomic_cmpxchg(&ltt_buf->consumed, consumed_old, consumed_new)
213	!= consumed_old);
214
215	if(consumed_old != consumed_new) {
216	/* Reader pushed : we are the winner of the push, we can therefore
217	reequilibrate reserve and commit. Atomic increment of the commit
218	count permits other writers to play around with this variable
219	before us. We keep track of corrupted_subbuffers even in overwrite
220	mode :
221	we never want to write over a non completely committed sub-buffer :
222	possible causes : the buffer size is too low compared to the unordered
223	data input, or there is a writer who died between the reserve and the
224	commit. */
225	if(reserve_commit_diff) {
226	/* We have to alter the sub-buffer commit count : a sub-buffer is
227	corrupted */
228	atomic_add(reserve_commit_diff,
229	&ltt_buf->commit_count[SUBBUF_INDEX(offset_begin, ltt_buf)]);
230	atomic_inc(&ltt_buf->corrupted_subbuffers);
231	}
232	}
233	}
234
235	/* Always switch */
236
237	if(end_switch_old) {
238	/* old subbuffer */
239	/* Concurrency safe because we are the last and only thread to alter this
240	sub-buffer. As long as it is not delivered and read, no other thread can
241	alter the offset, alter the reserve_count or call the
242	client_buffer_end_callback on this sub-buffer.
243	The only remaining threads could be the ones with pending commits. They
244	will have to do the deliver themself.
245	Not concurrency safe in overwrite mode. We detect corrupted subbuffers with
246	commit and reserve counts. We keep a corrupted sub-buffers count and push
247	the readers across these sub-buffers.
248	Not concurrency safe if a writer is stalled in a subbuffer and
249	another writer switches in, finding out it's corrupted. The result will be
250	than the old (uncommited) subbuffer will be declared corrupted, and that
251	the new subbuffer will be declared corrupted too because of the commit
252	count adjustment.
253	Offset old should never be 0. */
254	ltt_buffer_end_callback(ltt_buf, tsc, offset_old,
255	SUBBUF_INDEX((offset_old), ltt_buf));
256	/* Setting this reserve_count will allow the sub-buffer to be delivered by
257	the last committer. */
258	reserve_count = atomic_add_return((SUBBUF_OFFSET((offset_old-1),
259	ltt_buf) + 1),
260	&ltt_buf->reserve_count[SUBBUF_INDEX((offset_old),
261	ltt_buf)]);
262	if(reserve_count == atomic_read(
263	&ltt_buf->commit_count[SUBBUF_INDEX((offset_old), ltt_buf)])) {
264	ltt_deliver_callback(ltt_buf, SUBBUF_INDEX((offset_old), ltt_buf), NULL);
265	}
266	}
267
268	if(mode == FORCE_ACTIVE) {
269	/* New sub-buffer */
270	/* This code can be executed unordered : writers may already have written
271	to the sub-buffer before this code gets executed, caution. */
272	/* The commit makes sure that this code is executed before the deliver
273	of this sub-buffer */
274	ltt_buffer_begin_callback(ltt_buf, tsc, SUBBUF_INDEX(offset_begin, ltt_buf));
275	commit_count = atomic_add_return(ltt_subbuf_header_len(ltt_buf),
276	&ltt_buf->commit_count[SUBBUF_INDEX(offset_begin, ltt_buf)]);
277	/* Check if the written buffer has to be delivered */
278	if(commit_count == atomic_read(
279	&ltt_buf->reserve_count[SUBBUF_INDEX(offset_begin, ltt_buf)])) {
280	ltt_deliver_callback(ltt_buf, SUBBUF_INDEX(offset_begin, ltt_buf), NULL);
281	}
282	}
47d7d576	283
	284	}
	285
	286	static inline int ltt_buffer_get(struct ltt_buf *ltt_buf,
	287	unsigned int *offset)
	288	{
	289	unsigned int consumed_old, consumed_idx;
	290	consumed_old = atomic_read(&ltt_buf->consumed);
	291	consumed_idx = SUBBUF_INDEX(consumed_old, ltt_buf);
	292
	293	if(atomic_read(&ltt_buf->commit_count[consumed_idx])
	294	!= atomic_read(&ltt_buf->reserve_count[consumed_idx])) {
	295	return -EAGAIN;
	296	}
	297	if((SUBBUF_TRUNC(atomic_read(&ltt_buf->offset), ltt_buf)
	298	-SUBBUF_TRUNC(consumed_old, ltt_buf)) == 0) {
	299	return -EAGAIN;
	300	}
	301
	302	*offset = consumed_old;
	303
	304	return 0;
	305	}
	306
	307	static inline int ltt_buffer_put(struct ltt_buf *ltt_buf,
	308	unsigned int offset)
	309	{
	310	unsigned int consumed_old, consumed_new;
	311	int ret;
	312
	313	consumed_old = offset;
	314	consumed_new = SUBBUF_ALIGN(consumed_old, ltt_buf);
	315	if(atomic_cmpxchg(&ltt_buf->consumed, consumed_old, consumed_new)
	316	!= consumed_old) {
	317	/* We have been pushed by the writer : the last buffer read _is_
	318	* corrupted!
	319	* It can also happen if this is a buffer we never got. */
	320	return -EIO;
	321	} else {
b402c055	322	if(atomic_inc_return(&ltt_buf->writer_futex) <= 0) {
b402c055	323	atomic_set(&ltt_buf->writer_futex, 1);
47d7d576	324	/* tell the client that buffer is now unfull */
b402c055	325	ret = futex((unsigned long)&ltt_buf->writer_futex,
32f2b04a	326	FUTEX_WAKE, 1, 0, 0, 0);
47d7d576	327	if(ret != 1) {
8a9103df	328	dbg_printf("LTT warning : race condition : writer not waiting or too many writers\n");
47d7d576	329	}
47d7d576	330	}
	331	}
	332	}
	333
47d7d576	334	static int read_subbuffer(struct ltt_buf *ltt_buf, int fd)
47d7d576	335	{
32f2b04a	336	unsigned int consumed_old;
47d7d576	337	int err;
8a9103df	338	dbg_printf("LTT read buffer\n");
47d7d576	339
47d7d576	340
32f2b04a	341	err = ltt_buffer_get(ltt_buf, &consumed_old);
5ffa9d14	342	if(err != 0) {
8a9103df	343	if(err != -EAGAIN) dbg_printf("LTT Reserving sub buffer failed\n");
47d7d576	344	goto get_error;
	345	}
	346
	347	err = TEMP_FAILURE_RETRY(write(fd,
	348	ltt_buf->start
	349	+ (consumed_old & ((ltt_buf->alloc_size)-1)),
	350	ltt_buf->subbuf_size));
	351
	352	if(err < 0) {
	353	perror("Error in writing to file");
	354	goto write_error;
	355	}
	356	#if 0
	357	err = fsync(pair->trace);
	358	if(err < 0) {
	359	ret = errno;
	360	perror("Error in writing to file");
	361	goto write_error;
	362	}
	363	#endif //0
	364	write_error:
32f2b04a	365	err = ltt_buffer_put(ltt_buf, consumed_old);
47d7d576	366
	367	if(err != 0) {
	368	if(err == -EIO) {
8a9103df	369	dbg_printf("Reader has been pushed by the writer, last subbuffer corrupted.\n");
47d7d576	370	/* FIXME : we may delete the last written buffer if we wish. */
	371	}
	372	goto get_error;
	373	}
	374
	375	get_error:
	376	return err;
	377	}
e8efa18d	378
a85b8f41	379	/* This function is called by ltt_rw_init which has signals blocked */
700d350d	380	static void ltt_usertrace_fast_daemon(struct ltt_trace_info *shared_trace_info,
4c992ad5	381	sigset_t oldset, pid_t l_traced_pid, pthread_t l_traced_tid)
700d350d	382	{
	383	struct sigaction act;
	384	int ret;
b402c055	385	int fd_process;
77b31f39	386	char outfile_name[PATH_MAX];
	387	char identifier_name[PATH_MAX];
	388
700d350d	389
a85b8f41	390	traced_pid = l_traced_pid;
4c992ad5	391	traced_tid = l_traced_tid;
e8efa18d	392
8a9103df	393	dbg_printf("LTT ltt_usertrace_fast_daemon : init is %d, pid is %lu, traced_pid is %lu, traced_tid is %lu\n",
4c992ad5	394	shared_trace_info->init, getpid(), traced_pid, traced_tid);
700d350d	395
e8efa18d	396	act.sa_handler = handler_sigusr1;
700d350d	397	act.sa_flags = 0;
	398	sigemptyset(&(act.sa_mask));
	399	sigaddset(&(act.sa_mask), SIGUSR1);
	400	sigaction(SIGUSR1, &act, NULL);
e8efa18d	401
	402	act.sa_handler = handler_sigusr2;
	403	act.sa_flags = 0;
	404	sigemptyset(&(act.sa_mask));
	405	sigaddset(&(act.sa_mask), SIGUSR2);
	406	sigaction(SIGUSR2, &act, NULL);
	407
	408	act.sa_handler = handler_sigalarm;
	409	act.sa_flags = 0;
	410	sigemptyset(&(act.sa_mask));
	411	sigaddset(&(act.sa_mask), SIGALRM);
	412	sigaction(SIGALRM, &act, NULL);
	413
700d350d	414	/* Enable signals */
	415	ret = pthread_sigmask(SIG_SETMASK, &oldset, NULL);
	416	if(ret) {
8a9103df	417	dbg_printf("LTT Error in pthread_sigmask\n");
700d350d	418	}
700d350d	419
e8efa18d	420	alarm(3);
e8efa18d	421
77b31f39	422	/* Open output files */
	423	umask(00000);
	424	ret = mkdir(LTT_USERTRACE_ROOT, 0777);
	425	if(ret < 0 && errno != EEXIST) {
	426	perror("LTT Error in creating output (mkdir)");
	427	exit(-1);
	428	}
	429	ret = chdir(LTT_USERTRACE_ROOT);
	430	if(ret < 0) {
	431	perror("LTT Error in creating output (chdir)");
	432	exit(-1);
	433	}
	434	snprintf(identifier_name, PATH_MAX-1, "%lu.%lu.%llu",
46903a9a	435	traced_tid, traced_pid, get_cycles());
b402c055	436	snprintf(outfile_name, PATH_MAX-1, "process-%s", identifier_name);
	437	#ifndef LTT_NULL_OUTPUT_TEST
	438	fd_process = creat(outfile_name, 0644);
	439	#else
	440	/* NULL test */
	441	ret = symlink("/dev/null", outfile_name);
	442	if(ret < 0) {
	443	perror("error in symlink");
	444	}
	445	fd_process = open(outfile_name, O_WRONLY);
	446	if(fd_process < 0) {
	447	perror("Error in open");
	448	}
	449	#endif //LTT_NULL_OUTPUT_TEST
77b31f39	450
700d350d	451	while(1) {
700d350d	452	pause();
a85b8f41	453	if(traced_pid == 0) break; /* parent died */
e8efa18d	454	if(parent_exited) break;
8a9103df	455	dbg_printf("LTT Doing a buffer switch read. pid is : %lu\n", getpid());
47d7d576	456
47d7d576	457	do {
b402c055	458	ret = read_subbuffer(&shared_trace_info->channel.process, fd_process);
47d7d576	459	} while(ret == 0);
700d350d	460	}
700d350d	461
32f2b04a	462	/* The parent thread is dead and we have finished with the buffer */
	463
	464	/* Buffer force switch (flush). Using FLUSH instead of ACTIVE because we know
	465	* there is no writer. */
b402c055	466	flush_buffer(&shared_trace_info->channel.process, FORCE_FLUSH);
47d7d576	467	do {
b402c055	468	ret = read_subbuffer(&shared_trace_info->channel.process, fd_process);
47d7d576	469	} while(ret == 0);
	470
	471
b402c055	472	close(fd_process);
77b31f39	473
e8efa18d	474	munmap(shared_trace_info, sizeof(*shared_trace_info));
	475
	476	exit(0);
700d350d	477	}
b09f3215	478
e8efa18d	479
	480	/* Reader-writer initialization */
	481
	482	static enum ltt_process_role { LTT_ROLE_WRITER, LTT_ROLE_READER }
	483	role = LTT_ROLE_WRITER;
	484
	485
	486	void ltt_rw_init(void)
b09f3215	487	{
700d350d	488	pid_t pid;
	489	struct ltt_trace_info *shared_trace_info;
	490	int ret;
	491	sigset_t set, oldset;
a85b8f41	492	pid_t l_traced_pid = getpid();
4c992ad5	493	pid_t l_traced_tid = gettid();
700d350d	494
700d350d	495	/* parent : create the shared memory map */
a85b8f41	496	shared_trace_info = mmap(0, sizeof(*thread_trace_info),
700d350d	497	PROT_READ\|PROT_WRITE, MAP_SHARED\|MAP_ANONYMOUS, 0, 0);
8a9103df	498	shared_trace_info->init=0;
	499	shared_trace_info->filter=0;
	500	shared_trace_info->daemon_id=0;
	501	shared_trace_info->nesting=0;
b402c055	502	memset(&shared_trace_info->channel.process, 0,
b402c055	503	sizeof(shared_trace_info->channel.process));
47d7d576	504	/* Tricky semaphore : is in a shared memory space, so it's ok for a fast
47d7d576	505	* mutex (futex). */
b402c055	506	atomic_set(&shared_trace_info->channel.process.writer_futex, LTT_N_SUBBUFS);
	507	shared_trace_info->channel.process.alloc_size = LTT_BUF_SIZE_PROCESS;
	508	shared_trace_info->channel.process.subbuf_size = LTT_SUBBUF_SIZE_PROCESS;
	509	shared_trace_info->channel.process.start =
	510	shared_trace_info->channel.process_buf;
	511	ltt_buffer_begin_callback(&shared_trace_info->channel.process,
5ffa9d14	512	ltt_get_timestamp(), 0);
5ffa9d14	513
a85b8f41	514	shared_trace_info->init = 1;
700d350d	515
	516	/* Disable signals */
	517	ret = sigfillset(&set);
	518	if(ret) {
8a9103df	519	dbg_printf("LTT Error in sigfillset\n");
700d350d	520	}
	521
	522
	523	ret = pthread_sigmask(SIG_BLOCK, &set, &oldset);
	524	if(ret) {
8a9103df	525	dbg_printf("LTT Error in pthread_sigmask\n");
700d350d	526	}
a85b8f41	527
700d350d	528	pid = fork();
	529	if(pid > 0) {
	530	/* Parent */
a85b8f41	531	shared_trace_info->daemon_id = pid;
a85b8f41	532	thread_trace_info = shared_trace_info;
700d350d	533
	534	/* Enable signals */
	535	ret = pthread_sigmask(SIG_SETMASK, &oldset, NULL);
	536	if(ret) {
8a9103df	537	dbg_printf("LTT Error in pthread_sigmask\n");
700d350d	538	}
700d350d	539	} else if(pid == 0) {
b5d612cb	540	pid_t sid;
700d350d	541	/* Child */
e8efa18d	542	role = LTT_ROLE_READER;
b5d612cb	543	sid = setsid();
b402c055	544	//Not a good idea to renice, unless futex wait eventually implement
	545	//priority inheritence.
	546	//ret = nice(1);
	547	//if(ret < 0) {
	548	// perror("Error in nice");
	549	//}
b5d612cb	550	if(sid < 0) {
	551	perror("Error setting sid");
	552	}
77b31f39	553	ltt_usertrace_fast_daemon(shared_trace_info, oldset, l_traced_pid,
4c992ad5	554	l_traced_tid);
700d350d	555	/* Should never return */
	556	exit(-1);
	557	} else if(pid < 0) {
	558	/* fork error */
a35eaa9c	559	perror("LTT Error in forking ltt-usertrace-fast");
700d350d	560	}
b09f3215	561	}
b09f3215	562
e8efa18d	563	static __thread struct _pthread_cleanup_buffer cleanup_buffer;
	564
	565	void ltt_thread_init(void)
	566	{
	567	_pthread_cleanup_push(&cleanup_buffer, ltt_usertrace_fast_cleanup, NULL);
	568	ltt_rw_init();
	569	}
	570
04180f7f	571	void __attribute__((constructor)) __ltt_usertrace_fast_init(void)
b09f3215	572	{
8a9103df	573	dbg_printf("LTT usertrace-fast init\n");
b09f3215	574
e8efa18d	575	ltt_rw_init();
700d350d	576	}
	577
	578	void __attribute__((destructor)) __ltt_usertrace_fast_fini(void)
	579	{
e8efa18d	580	if(role == LTT_ROLE_WRITER) {
8a9103df	581	dbg_printf("LTT usertrace-fast fini\n");
e8efa18d	582	ltt_usertrace_fast_cleanup(NULL);
e8efa18d	583	}
b09f3215	584	}
b09f3215	585