[lttng-tools.git] / src / common / kernel-ctl / kernel-ctl.c

/*
 * Copyright (C) 2011 - Julien Desfossez <julien.desfossez@polymtl.ca>
 *                      Mathieu Desnoyers <mathieu.desnoyers@efficios.com>
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License, version 2 only,
 * 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.,
 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 */

#define __USE_LINUX_IOCTL_DEFS
#include <sys/ioctl.h>
#include <string.h>

#include "kernel-ctl.h"
#include "kernel-ioctl.h"

/*
 * This flag indicates which version of the kernel ABI to use. The old
 * ABI (namespace _old) does not support a 32-bit user-space when the
 * kernel is 64-bit. The old ABI is kept here for compatibility but is
 * deprecated and will be removed eventually.
 */
static int lttng_kernel_use_old_abi = -1;

/*
 * Execute the new or old ioctl depending on the ABI version.
 * If the ABI version is not determined yet (lttng_kernel_use_old_abi = -1),
 * this function tests if the new ABI is available and otherwise fallbacks
 * on the old one.
 * This function takes the fd on which the ioctl must be executed and the old
 * and new request codes.
 * It returns the return value of the ioctl executed.
 */
static inline int compat_ioctl_no_arg(int fd, unsigned long oldname,
		unsigned long newname)
{
	int ret;

	if (lttng_kernel_use_old_abi == -1) {
		ret = ioctl(fd, newname);
		if (!ret) {
			lttng_kernel_use_old_abi = 0;
			goto end;
		}
		lttng_kernel_use_old_abi = 1;
	}
	if (lttng_kernel_use_old_abi) {
		ret = ioctl(fd, oldname);
	} else {
		ret = ioctl(fd, newname);
	}

end:
	return ret;
}

int kernctl_create_session(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_SESSION,
			LTTNG_KERNEL_SESSION);
}

/* open the metadata global channel */
int kernctl_open_metadata(int fd, struct lttng_channel_attr *chops)
{
	struct lttng_kernel_old_channel old_channel;
	struct lttng_kernel_channel channel;

	if (lttng_kernel_use_old_abi) {
		old_channel.overwrite = chops->overwrite;
		old_channel.subbuf_size = chops->subbuf_size;
		old_channel.num_subbuf = chops->num_subbuf;
		old_channel.switch_timer_interval = chops->switch_timer_interval;
		old_channel.read_timer_interval = chops->read_timer_interval;
		old_channel.output = chops->output;

		memset(old_channel.padding, 0, sizeof(old_channel.padding));
		/*
		 * The new channel padding is smaller than the old ABI so we use the
		 * new ABI padding size for the memcpy.
		 */
		memcpy(old_channel.padding, chops->padding, sizeof(chops->padding));

		return ioctl(fd, LTTNG_KERNEL_OLD_METADATA, &old_channel);
	}

	channel.overwrite = chops->overwrite;
	channel.subbuf_size = chops->subbuf_size;
	channel.num_subbuf = chops->num_subbuf;
	channel.switch_timer_interval = chops->switch_timer_interval;
	channel.read_timer_interval = chops->read_timer_interval;
	channel.output = chops->output;
	memcpy(channel.padding, chops->padding, sizeof(chops->padding));

	return ioctl(fd, LTTNG_KERNEL_METADATA, &channel);
}

int kernctl_create_channel(int fd, struct lttng_channel_attr *chops)
{
	struct lttng_kernel_channel channel;

	if (lttng_kernel_use_old_abi) {
		struct lttng_kernel_old_channel old_channel;

		old_channel.overwrite = chops->overwrite;
		old_channel.subbuf_size = chops->subbuf_size;
		old_channel.num_subbuf = chops->num_subbuf;
		old_channel.switch_timer_interval = chops->switch_timer_interval;
		old_channel.read_timer_interval = chops->read_timer_interval;
		old_channel.output = chops->output;

		memset(old_channel.padding, 0, sizeof(old_channel.padding));
		/*
		 * The new channel padding is smaller than the old ABI so we use the
		 * new ABI padding size for the memcpy.
		 */
		memcpy(old_channel.padding, chops->padding, sizeof(chops->padding));

		return ioctl(fd, LTTNG_KERNEL_OLD_CHANNEL, &old_channel);
	}

	channel.overwrite = chops->overwrite;
	channel.subbuf_size = chops->subbuf_size;
	channel.num_subbuf = chops->num_subbuf;
	channel.switch_timer_interval = chops->switch_timer_interval;
	channel.read_timer_interval = chops->read_timer_interval;
	channel.output = chops->output;
	memcpy(channel.padding, chops->padding, sizeof(chops->padding));

	return ioctl(fd, LTTNG_KERNEL_CHANNEL, &channel);
}

int kernctl_enable_syscall(int fd, const char *syscall_name)
{
	struct lttng_kernel_event event;

	memset(&event, 0, sizeof(event));
	strncpy(event.name, syscall_name, sizeof(event.name));
	event.name[sizeof(event.name) - 1] = '\0';
	event.instrumentation = LTTNG_KERNEL_SYSCALL;
	event.u.syscall.disable = 0;
	return ioctl(fd, LTTNG_KERNEL_EVENT, &event);
}

int kernctl_disable_syscall(int fd, const char *syscall_name)
{
	struct lttng_kernel_event event;

	memset(&event, 0, sizeof(event));
	strncpy(event.name, syscall_name, sizeof(event.name));
	event.name[sizeof(event.name) - 1] = '\0';
	event.instrumentation = LTTNG_KERNEL_SYSCALL;
	event.u.syscall.disable = 1;
	return ioctl(fd, LTTNG_KERNEL_EVENT, &event);
}

int kernctl_create_stream(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_STREAM,
			LTTNG_KERNEL_STREAM);
}

int kernctl_create_event(int fd, struct lttng_kernel_event *ev)
{
	if (lttng_kernel_use_old_abi) {
		struct lttng_kernel_old_event old_event;

		memcpy(old_event.name, ev->name, sizeof(old_event.name));
		old_event.instrumentation = ev->instrumentation;
		switch (ev->instrumentation) {
		case LTTNG_KERNEL_KPROBE:
			old_event.u.kprobe.addr = ev->u.kprobe.addr;
			old_event.u.kprobe.offset = ev->u.kprobe.offset;
			memcpy(old_event.u.kprobe.symbol_name,
				ev->u.kprobe.symbol_name,
				sizeof(old_event.u.kprobe.symbol_name));
			break;
		case LTTNG_KERNEL_KRETPROBE:
			old_event.u.kretprobe.addr = ev->u.kretprobe.addr;
			old_event.u.kretprobe.offset = ev->u.kretprobe.offset;
			memcpy(old_event.u.kretprobe.symbol_name,
				ev->u.kretprobe.symbol_name,
				sizeof(old_event.u.kretprobe.symbol_name));
			break;
		case LTTNG_KERNEL_FUNCTION:
			memcpy(old_event.u.ftrace.symbol_name,
					ev->u.ftrace.symbol_name,
					sizeof(old_event.u.ftrace.symbol_name));
			break;
		default:
			break;
		}

		return ioctl(fd, LTTNG_KERNEL_OLD_EVENT, &old_event);
	}
	return ioctl(fd, LTTNG_KERNEL_EVENT, ev);
}

int kernctl_add_context(int fd, struct lttng_kernel_context *ctx)
{
	if (lttng_kernel_use_old_abi) {
		struct lttng_kernel_old_context old_ctx;

		old_ctx.ctx = ctx->ctx;
		/* only type that uses the union */
		if (ctx->ctx == LTTNG_KERNEL_CONTEXT_PERF_CPU_COUNTER) {
			old_ctx.u.perf_counter.type =
				ctx->u.perf_counter.type;
			old_ctx.u.perf_counter.config =
				ctx->u.perf_counter.config;
			memcpy(old_ctx.u.perf_counter.name,
				ctx->u.perf_counter.name,
				sizeof(old_ctx.u.perf_counter.name));
		}
		return ioctl(fd, LTTNG_KERNEL_OLD_CONTEXT, &old_ctx);
	}
	return ioctl(fd, LTTNG_KERNEL_CONTEXT, ctx);
}


/* Enable event, channel and session ioctl */
int kernctl_enable(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_ENABLE,
			LTTNG_KERNEL_ENABLE);
}

/* Disable event, channel and session ioctl */
int kernctl_disable(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_DISABLE,
			LTTNG_KERNEL_DISABLE);
}

int kernctl_start_session(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_SESSION_START,
			LTTNG_KERNEL_SESSION_START);
}

int kernctl_stop_session(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_SESSION_STOP,
			LTTNG_KERNEL_SESSION_STOP);
}

int kernctl_tracepoint_list(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_TRACEPOINT_LIST,
			LTTNG_KERNEL_TRACEPOINT_LIST);
}

int kernctl_tracer_version(int fd, struct lttng_kernel_tracer_version *v)
{
	int ret;

	if (lttng_kernel_use_old_abi == -1) {
		ret = ioctl(fd, LTTNG_KERNEL_TRACER_VERSION, v);
		if (!ret) {
			lttng_kernel_use_old_abi = 0;
			goto end;
		}
		lttng_kernel_use_old_abi = 1;
	}
	if (lttng_kernel_use_old_abi) {
		struct lttng_kernel_old_tracer_version old_v;

		ret = ioctl(fd, LTTNG_KERNEL_OLD_TRACER_VERSION, &old_v);
		if (ret) {
			goto end;
		}
		v->major = old_v.major;
		v->minor = old_v.minor;
		v->patchlevel = old_v.patchlevel;
	} else {
		ret = ioctl(fd, LTTNG_KERNEL_TRACER_VERSION, v);
	}

end:
	return ret;
}

int kernctl_wait_quiescent(int fd)
{
	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_WAIT_QUIESCENT,
			LTTNG_KERNEL_WAIT_QUIESCENT);
}

int kernctl_calibrate(int fd, struct lttng_kernel_calibrate *calibrate)
{
	int ret;

	if (lttng_kernel_use_old_abi == -1) {
		ret = ioctl(fd, LTTNG_KERNEL_CALIBRATE, calibrate);
		if (!ret) {
			lttng_kernel_use_old_abi = 0;
			goto end;
		}
		lttng_kernel_use_old_abi = 1;
	}
	if (lttng_kernel_use_old_abi) {
		struct lttng_kernel_old_calibrate old_calibrate;

		old_calibrate.type = calibrate->type;
		ret = ioctl(fd, LTTNG_KERNEL_OLD_CALIBRATE, &old_calibrate);
		if (ret) {
			goto end;
		}
		calibrate->type = old_calibrate.type;
	} else {
		ret = ioctl(fd, LTTNG_KERNEL_CALIBRATE, calibrate);
	}

end:
	return ret;
}


int kernctl_buffer_flush(int fd)
{
	return ioctl(fd, RING_BUFFER_FLUSH);
}


/* Buffer operations */

/* For mmap mode, readable without "get" operation */

/* returns the length to mmap. */
int kernctl_get_mmap_len(int fd, unsigned long *len)
{
	return ioctl(fd, RING_BUFFER_GET_MMAP_LEN, len);
}

/* returns the maximum size for sub-buffers. */
int kernctl_get_max_subbuf_size(int fd, unsigned long *len)
{
	return ioctl(fd, RING_BUFFER_GET_MAX_SUBBUF_SIZE, len);
}

/*
 * For mmap mode, operate on the current packet (between get/put or
 * get_next/put_next).
 */

/* returns the offset of the subbuffer belonging to the mmap reader. */
int kernctl_get_mmap_read_offset(int fd, unsigned long *off)
{
	return ioctl(fd, RING_BUFFER_GET_MMAP_READ_OFFSET, off);
}

/* returns the size of the current sub-buffer, without padding (for mmap). */
int kernctl_get_subbuf_size(int fd, unsigned long *len)
{
	return ioctl(fd, RING_BUFFER_GET_SUBBUF_SIZE, len);
}

/* returns the size of the current sub-buffer, without padding (for mmap). */
int kernctl_get_padded_subbuf_size(int fd, unsigned long *len)
{
	return ioctl(fd, RING_BUFFER_GET_PADDED_SUBBUF_SIZE, len);
}

/* Get exclusive read access to the next sub-buffer that can be read. */
int kernctl_get_next_subbuf(int fd)
{
	return ioctl(fd, RING_BUFFER_GET_NEXT_SUBBUF);
}


/* Release exclusive sub-buffer access, move consumer forward. */
int kernctl_put_next_subbuf(int fd)
{
	return ioctl(fd, RING_BUFFER_PUT_NEXT_SUBBUF);
}

/* snapshot */

/* Get a snapshot of the current ring buffer producer and consumer positions */
int kernctl_snapshot(int fd)
{
	return ioctl(fd, RING_BUFFER_SNAPSHOT);
}

/* Get the consumer position (iteration start) */
int kernctl_snapshot_get_consumed(int fd, unsigned long *pos)
{
	return ioctl(fd, RING_BUFFER_SNAPSHOT_GET_CONSUMED, pos);
}

/* Get the producer position (iteration end) */
int kernctl_snapshot_get_produced(int fd, unsigned long *pos)
{
	return ioctl(fd, RING_BUFFER_SNAPSHOT_GET_PRODUCED, pos);
}

/* Get exclusive read access to the specified sub-buffer position */
int kernctl_get_subbuf(int fd, unsigned long *len)
{
	return ioctl(fd, RING_BUFFER_GET_SUBBUF, len);
}

/* Release exclusive sub-buffer access */
int kernctl_put_subbuf(int fd)
{
	return ioctl(fd, RING_BUFFER_PUT_SUBBUF);
}

/* Returns the timestamp begin of the current sub-buffer. */
int kernctl_get_timestamp_begin(int fd, uint64_t *timestamp_begin)
{
	return ioctl(fd, LTTNG_RING_BUFFER_GET_TIMESTAMP_BEGIN, timestamp_begin);
}

/* Returns the timestamp end of the current sub-buffer. */
int kernctl_get_timestamp_end(int fd, uint64_t *timestamp_end)
{
	return ioctl(fd, LTTNG_RING_BUFFER_GET_TIMESTAMP_END, timestamp_end);
}

/* Returns the number of discarded events in the current sub-buffer. */
int kernctl_get_events_discarded(int fd, uint64_t *events_discarded)
{
	return ioctl(fd, LTTNG_RING_BUFFER_GET_EVENTS_DISCARDED, events_discarded);
}

/* Returns the content size in the current sub-buffer. */
int kernctl_get_content_size(int fd, uint64_t *content_size)
{
	return ioctl(fd, LTTNG_RING_BUFFER_GET_CONTENT_SIZE, content_size);
}

/* Returns the packet size in the current sub-buffer. */
int kernctl_get_packet_size(int fd, uint64_t *packet_size)
{
	return ioctl(fd, LTTNG_RING_BUFFER_GET_PACKET_SIZE, packet_size);
}

/* Returns the stream id of the current sub-buffer. */
int kernctl_get_stream_id(int fd, uint64_t *stream_id)
{
	return ioctl(fd, LTTNG_RING_BUFFER_GET_STREAM_ID, stream_id);
}

/* Returns the current timestamp. */
int kernctl_get_current_timestamp(int fd, uint64_t *ts)
{
	return ioctl(fd, LTTNG_RING_BUFFER_GET_CURRENT_TIMESTAMP, ts);
}
Commit	Line	Data
	1	/*
	2	* Copyright (C) 2011 - Julien Desfossez <julien.desfossez@polymtl.ca>
	3	* Mathieu Desnoyers <mathieu.desnoyers@efficios.com>
	4	*
	5	* This program is free software; you can redistribute it and/or modify
	6	* it under the terms of the GNU General Public License, version 2 only,
	7	* as published by the Free Software Foundation.
	8	*
	9	* This program is distributed in the hope that it will be useful,
	10	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	11	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	12	* GNU General Public License for more details.
	13	*
	14	* You should have received a copy of the GNU General Public License along
	15	* with this program; if not, write to the Free Software Foundation, Inc.,
	16	* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
	17	*/
	18
	19	#define __USE_LINUX_IOCTL_DEFS
	20	#include <sys/ioctl.h>
	21	#include <string.h>
	22
	23	#include "kernel-ctl.h"
	24	#include "kernel-ioctl.h"
	25
	26	/*
	27	* This flag indicates which version of the kernel ABI to use. The old
	28	* ABI (namespace _old) does not support a 32-bit user-space when the
	29	* kernel is 64-bit. The old ABI is kept here for compatibility but is
	30	* deprecated and will be removed eventually.
	31	*/
	32	static int lttng_kernel_use_old_abi = -1;
	33
	34	/*
	35	* Execute the new or old ioctl depending on the ABI version.
	36	* If the ABI version is not determined yet (lttng_kernel_use_old_abi = -1),
	37	* this function tests if the new ABI is available and otherwise fallbacks
	38	* on the old one.
	39	* This function takes the fd on which the ioctl must be executed and the old
	40	* and new request codes.
	41	* It returns the return value of the ioctl executed.
	42	*/
	43	static inline int compat_ioctl_no_arg(int fd, unsigned long oldname,
	44	unsigned long newname)
	45	{
	46	int ret;
	47
	48	if (lttng_kernel_use_old_abi == -1) {
	49	ret = ioctl(fd, newname);
	50	if (!ret) {
	51	lttng_kernel_use_old_abi = 0;
	52	goto end;
	53	}
	54	lttng_kernel_use_old_abi = 1;
	55	}
	56	if (lttng_kernel_use_old_abi) {
	57	ret = ioctl(fd, oldname);
	58	} else {
	59	ret = ioctl(fd, newname);
	60	}
	61
	62	end:
	63	return ret;
	64	}
	65
	66	int kernctl_create_session(int fd)
	67	{
	68	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_SESSION,
	69	LTTNG_KERNEL_SESSION);
	70	}
	71
	72	/* open the metadata global channel */
	73	int kernctl_open_metadata(int fd, struct lttng_channel_attr *chops)
	74	{
	75	struct lttng_kernel_old_channel old_channel;
	76	struct lttng_kernel_channel channel;
	77
	78	if (lttng_kernel_use_old_abi) {
	79	old_channel.overwrite = chops->overwrite;
	80	old_channel.subbuf_size = chops->subbuf_size;
	81	old_channel.num_subbuf = chops->num_subbuf;
	82	old_channel.switch_timer_interval = chops->switch_timer_interval;
	83	old_channel.read_timer_interval = chops->read_timer_interval;
	84	old_channel.output = chops->output;
	85
	86	memset(old_channel.padding, 0, sizeof(old_channel.padding));
	87	/*
	88	* The new channel padding is smaller than the old ABI so we use the
	89	* new ABI padding size for the memcpy.
	90	*/
	91	memcpy(old_channel.padding, chops->padding, sizeof(chops->padding));
	92
	93	return ioctl(fd, LTTNG_KERNEL_OLD_METADATA, &old_channel);
	94	}
	95
	96	channel.overwrite = chops->overwrite;
	97	channel.subbuf_size = chops->subbuf_size;
	98	channel.num_subbuf = chops->num_subbuf;
	99	channel.switch_timer_interval = chops->switch_timer_interval;
	100	channel.read_timer_interval = chops->read_timer_interval;
	101	channel.output = chops->output;
	102	memcpy(channel.padding, chops->padding, sizeof(chops->padding));
	103
	104	return ioctl(fd, LTTNG_KERNEL_METADATA, &channel);
	105	}
	106
	107	int kernctl_create_channel(int fd, struct lttng_channel_attr *chops)
	108	{
	109	struct lttng_kernel_channel channel;
	110
	111	if (lttng_kernel_use_old_abi) {
	112	struct lttng_kernel_old_channel old_channel;
	113
	114	old_channel.overwrite = chops->overwrite;
	115	old_channel.subbuf_size = chops->subbuf_size;
	116	old_channel.num_subbuf = chops->num_subbuf;
	117	old_channel.switch_timer_interval = chops->switch_timer_interval;
	118	old_channel.read_timer_interval = chops->read_timer_interval;
	119	old_channel.output = chops->output;
	120
	121	memset(old_channel.padding, 0, sizeof(old_channel.padding));
	122	/*
	123	* The new channel padding is smaller than the old ABI so we use the
	124	* new ABI padding size for the memcpy.
	125	*/
	126	memcpy(old_channel.padding, chops->padding, sizeof(chops->padding));
	127
	128	return ioctl(fd, LTTNG_KERNEL_OLD_CHANNEL, &old_channel);
	129	}
	130
	131	channel.overwrite = chops->overwrite;
	132	channel.subbuf_size = chops->subbuf_size;
	133	channel.num_subbuf = chops->num_subbuf;
	134	channel.switch_timer_interval = chops->switch_timer_interval;
	135	channel.read_timer_interval = chops->read_timer_interval;
	136	channel.output = chops->output;
	137	memcpy(channel.padding, chops->padding, sizeof(chops->padding));
	138
	139	return ioctl(fd, LTTNG_KERNEL_CHANNEL, &channel);
	140	}
	141
	142	int kernctl_enable_syscall(int fd, const char *syscall_name)
	143	{
	144	struct lttng_kernel_event event;
	145
	146	memset(&event, 0, sizeof(event));
	147	strncpy(event.name, syscall_name, sizeof(event.name));
	148	event.name[sizeof(event.name) - 1] = '\0';
	149	event.instrumentation = LTTNG_KERNEL_SYSCALL;
	150	event.u.syscall.disable = 0;
	151	return ioctl(fd, LTTNG_KERNEL_EVENT, &event);
	152	}
	153
	154	int kernctl_disable_syscall(int fd, const char *syscall_name)
	155	{
	156	struct lttng_kernel_event event;
	157
	158	memset(&event, 0, sizeof(event));
	159	strncpy(event.name, syscall_name, sizeof(event.name));
	160	event.name[sizeof(event.name) - 1] = '\0';
	161	event.instrumentation = LTTNG_KERNEL_SYSCALL;
	162	event.u.syscall.disable = 1;
	163	return ioctl(fd, LTTNG_KERNEL_EVENT, &event);
	164	}
	165
	166	int kernctl_create_stream(int fd)
	167	{
	168	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_STREAM,
	169	LTTNG_KERNEL_STREAM);
	170	}
	171
	172	int kernctl_create_event(int fd, struct lttng_kernel_event *ev)
	173	{
	174	if (lttng_kernel_use_old_abi) {
	175	struct lttng_kernel_old_event old_event;
	176
	177	memcpy(old_event.name, ev->name, sizeof(old_event.name));
	178	old_event.instrumentation = ev->instrumentation;
	179	switch (ev->instrumentation) {
	180	case LTTNG_KERNEL_KPROBE:
	181	old_event.u.kprobe.addr = ev->u.kprobe.addr;
	182	old_event.u.kprobe.offset = ev->u.kprobe.offset;
	183	memcpy(old_event.u.kprobe.symbol_name,
	184	ev->u.kprobe.symbol_name,
	185	sizeof(old_event.u.kprobe.symbol_name));
	186	break;
	187	case LTTNG_KERNEL_KRETPROBE:
	188	old_event.u.kretprobe.addr = ev->u.kretprobe.addr;
	189	old_event.u.kretprobe.offset = ev->u.kretprobe.offset;
	190	memcpy(old_event.u.kretprobe.symbol_name,
	191	ev->u.kretprobe.symbol_name,
	192	sizeof(old_event.u.kretprobe.symbol_name));
	193	break;
	194	case LTTNG_KERNEL_FUNCTION:
	195	memcpy(old_event.u.ftrace.symbol_name,
	196	ev->u.ftrace.symbol_name,
	197	sizeof(old_event.u.ftrace.symbol_name));
	198	break;
	199	default:
	200	break;
	201	}
	202
	203	return ioctl(fd, LTTNG_KERNEL_OLD_EVENT, &old_event);
	204	}
	205	return ioctl(fd, LTTNG_KERNEL_EVENT, ev);
	206	}
	207
	208	int kernctl_add_context(int fd, struct lttng_kernel_context *ctx)
	209	{
	210	if (lttng_kernel_use_old_abi) {
	211	struct lttng_kernel_old_context old_ctx;
	212
	213	old_ctx.ctx = ctx->ctx;
	214	/* only type that uses the union */
	215	if (ctx->ctx == LTTNG_KERNEL_CONTEXT_PERF_CPU_COUNTER) {
	216	old_ctx.u.perf_counter.type =
	217	ctx->u.perf_counter.type;
	218	old_ctx.u.perf_counter.config =
	219	ctx->u.perf_counter.config;
	220	memcpy(old_ctx.u.perf_counter.name,
	221	ctx->u.perf_counter.name,
	222	sizeof(old_ctx.u.perf_counter.name));
	223	}
	224	return ioctl(fd, LTTNG_KERNEL_OLD_CONTEXT, &old_ctx);
	225	}
	226	return ioctl(fd, LTTNG_KERNEL_CONTEXT, ctx);
	227	}
	228
	229
	230	/* Enable event, channel and session ioctl */
	231	int kernctl_enable(int fd)
	232	{
	233	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_ENABLE,
	234	LTTNG_KERNEL_ENABLE);
	235	}
	236
	237	/* Disable event, channel and session ioctl */
	238	int kernctl_disable(int fd)
	239	{
	240	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_DISABLE,
	241	LTTNG_KERNEL_DISABLE);
	242	}
	243
	244	int kernctl_start_session(int fd)
	245	{
	246	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_SESSION_START,
	247	LTTNG_KERNEL_SESSION_START);
	248	}
	249
	250	int kernctl_stop_session(int fd)
	251	{
	252	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_SESSION_STOP,
	253	LTTNG_KERNEL_SESSION_STOP);
	254	}
	255
	256	int kernctl_tracepoint_list(int fd)
	257	{
	258	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_TRACEPOINT_LIST,
	259	LTTNG_KERNEL_TRACEPOINT_LIST);
	260	}
	261
	262	int kernctl_tracer_version(int fd, struct lttng_kernel_tracer_version *v)
	263	{
	264	int ret;
	265
	266	if (lttng_kernel_use_old_abi == -1) {
	267	ret = ioctl(fd, LTTNG_KERNEL_TRACER_VERSION, v);
	268	if (!ret) {
	269	lttng_kernel_use_old_abi = 0;
	270	goto end;
	271	}
	272	lttng_kernel_use_old_abi = 1;
	273	}
	274	if (lttng_kernel_use_old_abi) {
	275	struct lttng_kernel_old_tracer_version old_v;
	276
	277	ret = ioctl(fd, LTTNG_KERNEL_OLD_TRACER_VERSION, &old_v);
	278	if (ret) {
	279	goto end;
	280	}
	281	v->major = old_v.major;
	282	v->minor = old_v.minor;
	283	v->patchlevel = old_v.patchlevel;
	284	} else {
	285	ret = ioctl(fd, LTTNG_KERNEL_TRACER_VERSION, v);
	286	}
	287
	288	end:
	289	return ret;
	290	}
	291
	292	int kernctl_wait_quiescent(int fd)
	293	{
	294	return compat_ioctl_no_arg(fd, LTTNG_KERNEL_OLD_WAIT_QUIESCENT,
	295	LTTNG_KERNEL_WAIT_QUIESCENT);
	296	}
	297
	298	int kernctl_calibrate(int fd, struct lttng_kernel_calibrate *calibrate)
	299	{
	300	int ret;
	301
	302	if (lttng_kernel_use_old_abi == -1) {
	303	ret = ioctl(fd, LTTNG_KERNEL_CALIBRATE, calibrate);
	304	if (!ret) {
	305	lttng_kernel_use_old_abi = 0;
	306	goto end;
	307	}
	308	lttng_kernel_use_old_abi = 1;
	309	}
	310	if (lttng_kernel_use_old_abi) {
	311	struct lttng_kernel_old_calibrate old_calibrate;
	312
	313	old_calibrate.type = calibrate->type;
	314	ret = ioctl(fd, LTTNG_KERNEL_OLD_CALIBRATE, &old_calibrate);
	315	if (ret) {
	316	goto end;
	317	}
	318	calibrate->type = old_calibrate.type;
	319	} else {
	320	ret = ioctl(fd, LTTNG_KERNEL_CALIBRATE, calibrate);
	321	}
	322
	323	end:
	324	return ret;
	325	}
	326
	327
	328	int kernctl_buffer_flush(int fd)
	329	{
	330	return ioctl(fd, RING_BUFFER_FLUSH);
	331	}
	332
	333
	334	/* Buffer operations */
	335
	336	/* For mmap mode, readable without "get" operation */
	337
	338	/* returns the length to mmap. */
	339	int kernctl_get_mmap_len(int fd, unsigned long *len)
	340	{
	341	return ioctl(fd, RING_BUFFER_GET_MMAP_LEN, len);
	342	}
	343
	344	/* returns the maximum size for sub-buffers. */
	345	int kernctl_get_max_subbuf_size(int fd, unsigned long *len)
	346	{
	347	return ioctl(fd, RING_BUFFER_GET_MAX_SUBBUF_SIZE, len);
	348	}
	349
	350	/*
	351	* For mmap mode, operate on the current packet (between get/put or
	352	* get_next/put_next).
	353	*/
	354
	355	/* returns the offset of the subbuffer belonging to the mmap reader. */
	356	int kernctl_get_mmap_read_offset(int fd, unsigned long *off)
	357	{
	358	return ioctl(fd, RING_BUFFER_GET_MMAP_READ_OFFSET, off);
	359	}
	360
	361	/* returns the size of the current sub-buffer, without padding (for mmap). */
	362	int kernctl_get_subbuf_size(int fd, unsigned long *len)
	363	{
	364	return ioctl(fd, RING_BUFFER_GET_SUBBUF_SIZE, len);
	365	}
	366
	367	/* returns the size of the current sub-buffer, without padding (for mmap). */
	368	int kernctl_get_padded_subbuf_size(int fd, unsigned long *len)
	369	{
	370	return ioctl(fd, RING_BUFFER_GET_PADDED_SUBBUF_SIZE, len);
	371	}
	372
	373	/* Get exclusive read access to the next sub-buffer that can be read. */
	374	int kernctl_get_next_subbuf(int fd)
	375	{
	376	return ioctl(fd, RING_BUFFER_GET_NEXT_SUBBUF);
	377	}
	378
	379
	380	/* Release exclusive sub-buffer access, move consumer forward. */
	381	int kernctl_put_next_subbuf(int fd)
	382	{
	383	return ioctl(fd, RING_BUFFER_PUT_NEXT_SUBBUF);
	384	}
	385
	386	/* snapshot */
	387
	388	/* Get a snapshot of the current ring buffer producer and consumer positions */
	389	int kernctl_snapshot(int fd)
	390	{
	391	return ioctl(fd, RING_BUFFER_SNAPSHOT);
	392	}
	393
	394	/* Get the consumer position (iteration start) */
	395	int kernctl_snapshot_get_consumed(int fd, unsigned long *pos)
	396	{
	397	return ioctl(fd, RING_BUFFER_SNAPSHOT_GET_CONSUMED, pos);
	398	}
	399
	400	/* Get the producer position (iteration end) */
	401	int kernctl_snapshot_get_produced(int fd, unsigned long *pos)
	402	{
	403	return ioctl(fd, RING_BUFFER_SNAPSHOT_GET_PRODUCED, pos);
	404	}
	405
	406	/* Get exclusive read access to the specified sub-buffer position */
	407	int kernctl_get_subbuf(int fd, unsigned long *len)
	408	{
	409	return ioctl(fd, RING_BUFFER_GET_SUBBUF, len);
	410	}
	411
	412	/* Release exclusive sub-buffer access */
	413	int kernctl_put_subbuf(int fd)
	414	{
	415	return ioctl(fd, RING_BUFFER_PUT_SUBBUF);
	416	}
	417
	418	/* Returns the timestamp begin of the current sub-buffer. */
	419	int kernctl_get_timestamp_begin(int fd, uint64_t *timestamp_begin)
	420	{
	421	return ioctl(fd, LTTNG_RING_BUFFER_GET_TIMESTAMP_BEGIN, timestamp_begin);
	422	}
	423
	424	/* Returns the timestamp end of the current sub-buffer. */
	425	int kernctl_get_timestamp_end(int fd, uint64_t *timestamp_end)
	426	{
	427	return ioctl(fd, LTTNG_RING_BUFFER_GET_TIMESTAMP_END, timestamp_end);
	428	}
	429
	430	/* Returns the number of discarded events in the current sub-buffer. */
	431	int kernctl_get_events_discarded(int fd, uint64_t *events_discarded)
	432	{
	433	return ioctl(fd, LTTNG_RING_BUFFER_GET_EVENTS_DISCARDED, events_discarded);
	434	}
	435
	436	/* Returns the content size in the current sub-buffer. */
	437	int kernctl_get_content_size(int fd, uint64_t *content_size)
	438	{
	439	return ioctl(fd, LTTNG_RING_BUFFER_GET_CONTENT_SIZE, content_size);
	440	}
	441
	442	/* Returns the packet size in the current sub-buffer. */
	443	int kernctl_get_packet_size(int fd, uint64_t *packet_size)
	444	{
	445	return ioctl(fd, LTTNG_RING_BUFFER_GET_PACKET_SIZE, packet_size);
	446	}
	447
	448	/* Returns the stream id of the current sub-buffer. */
	449	int kernctl_get_stream_id(int fd, uint64_t *stream_id)
	450	{
	451	return ioctl(fd, LTTNG_RING_BUFFER_GET_STREAM_ID, stream_id);
	452	}
	453
	454	/* Returns the current timestamp. */
	455	int kernctl_get_current_timestamp(int fd, uint64_t *ts)
	456	{
	457	return ioctl(fd, LTTNG_RING_BUFFER_GET_CURRENT_TIMESTAMP, ts);
	458	}