include/trace/events/gpu.h - arm/linux-arm-legacy - Git at Google

 #undef TRACE_SYSTEM
 #define TRACE_SYSTEM gpu

 #if !defined(_TRACE_GPU_H) || defined(TRACE_HEADER_MULTI_READ)
 #define _TRACE_GPU_H

 #include <linux/tracepoint.h>
 #include <linux/time.h>

 #define show_secs_from_ns(ns) \
 	({ \
 		u64 t = ns + (NSEC_PER_USEC / 2); \
 		do_div(t, NSEC_PER_SEC); \
 		t; \
 	})

 #define show_usecs_from_ns(ns) \
 	({ \
 		u64 t = ns + (NSEC_PER_USEC / 2) ; \
 		u32 rem; \
 		do_div(t, NSEC_PER_USEC); \
 		rem = do_div(t, USEC_PER_SEC); \
 	})

 /*
  * The gpu_sched_switch event indicates that a switch from one GPU context to
  * another occurred on one of the GPU hardware blocks.
  *
  * The gpu_name argument identifies the GPU hardware block.  Each independently
  * scheduled GPU hardware block should have a different name.  This may be used
  * in different ways for different GPUs.  For example, if a GPU includes
  * multiple processing cores it may use names "GPU 0", "GPU 1", etc.  If a GPU
  * includes a separately scheduled 2D and 3D hardware block, it might use the
  * names "2D" and "3D".
  *
  * The timestamp argument is the timestamp at which the switch occurred on the
  * GPU. These timestamps are in units of nanoseconds and must use
  * approximately the same time as sched_clock, though they need not come from
  * any CPU clock. The timestamps for a single hardware block must be
  * monotonically nondecreasing.  This means that if a variable compensation
  * offset is used to translate from some other clock to the sched_clock, then
  * care must be taken when increasing that offset, and doing so may result in
  * multiple events with the same timestamp.
  *
  * The next_ctx_id argument identifies the next context that was running on
  * the GPU hardware block.  A value of 0 indicates that the hardware block
  * will be idle.
  *
  * The next_prio argument indicates the priority of the next context at the
  * time of the event.  The exact numeric values may mean different things for
  * different GPUs, but they should follow the rule that lower values indicate a
  * higher priority.
  *
  * The next_job_id argument identifies the batch of work that the GPU will be
  * working on.  This should correspond to a job_id that was previously traced
  * as a gpu_job_enqueue event when the batch of work was created.
  */
 TRACE_EVENT(gpu_sched_switch,

 	TP_PROTO(const char *gpu_name, u64 timestamp,
 		u32 next_ctx_id, s32 next_prio, u32 next_job_id),

 	TP_ARGS(gpu_name, timestamp, next_ctx_id, next_prio, next_job_id),

 	TP_STRUCT__entry(
 		__string(       gpu_name,       gpu_name        )
 		__field(        u64,            timestamp       )
 		__field(        u32,            next_ctx_id     )
 		__field(        s32,            next_prio       )
 		__field(        u32,            next_job_id     )
 	),

 	TP_fast_assign(
 		__assign_str(gpu_name, gpu_name);
 		__entry->timestamp = timestamp;
 		__entry->next_ctx_id = next_ctx_id;
 		__entry->next_prio = next_prio;
 		__entry->next_job_id = next_job_id;
 	),

 	TP_printk("gpu_name=%s ts=%llu.%06lu next_ctx_id=%lu next_prio=%ld "
 		"next_job_id=%lu",
 		__get_str(gpu_name),
 		(unsigned long long)show_secs_from_ns(__entry->timestamp),
 		(unsigned long)show_usecs_from_ns(__entry->timestamp),
 		(unsigned long)__entry->next_ctx_id,
 		(long)__entry->next_prio,
 		(unsigned long)__entry->next_job_id)
 );

 /*
  * The gpu_job_enqueue event indicates that a batch of work has been queued up
  * to be processed by the GPU.  This event is not intended to indicate that
  * the batch of work has been submitted to the GPU hardware, but rather that
  * it has been submitted to the GPU kernel driver.
  *
  * This event should be traced on the thread that initiated the work being
  * queued.  For example, if a batch of work is submitted to the kernel by a
  * userland thread, the event should be traced on that thread.
  *
  * The ctx_id field identifies the GPU context in which the batch of work
  * being queued is to be run.
  *
  * The job_id field identifies the batch of work being queued within the given
  * GPU context.  The first batch of work submitted for a given GPU context
  * should have a job_id of 0, and each subsequent batch of work should
  * increment the job_id by 1.
  *
  * The type field identifies the type of the job being enqueued.  The job
  * types may be different for different GPU hardware.  For example, a GPU may
  * differentiate between "2D", "3D", and "compute" jobs.
  */
 TRACE_EVENT(gpu_job_enqueue,

 	TP_PROTO(u32 ctx_id, u32 job_id, const char *type),

 	TP_ARGS(ctx_id, job_id, type),

 	TP_STRUCT__entry(
 		__field(        u32,            ctx_id          )
 		__field(        u32,            job_id          )
 		__string(       type,           type            )
 	),

 	TP_fast_assign(
 		__entry->ctx_id = ctx_id;
 		__entry->job_id = job_id;
 		__assign_str(type, type);
 	),

 	TP_printk("ctx_id=%lu job_id=%lu type=%s",
 		(unsigned long)__entry->ctx_id,
 		(unsigned long)__entry->job_id,
 		__get_str(type))
 );

 #undef show_secs_from_ns
 #undef show_usecs_from_ns

 #endif /* _TRACE_GPU_H */

 /* This part must be outside protection */
 #include <trace/define_trace.h>
	#undef TRACE_SYSTEM
	#define TRACE_SYSTEM gpu

	#if !defined(_TRACE_GPU_H) \|\| defined(TRACE_HEADER_MULTI_READ)
	#define _TRACE_GPU_H

	#include <linux/tracepoint.h>
	#include <linux/time.h>

	#define show_secs_from_ns(ns) \
	({ \
	u64 t = ns + (NSEC_PER_USEC / 2); \
	do_div(t, NSEC_PER_SEC); \
	t; \
	})

	#define show_usecs_from_ns(ns) \
	({ \
	u64 t = ns + (NSEC_PER_USEC / 2) ; \
	u32 rem; \
	do_div(t, NSEC_PER_USEC); \
	rem = do_div(t, USEC_PER_SEC); \
	})

	/*
	* The gpu_sched_switch event indicates that a switch from one GPU context to
	* another occurred on one of the GPU hardware blocks.
	*
	* The gpu_name argument identifies the GPU hardware block. Each independently
	* scheduled GPU hardware block should have a different name. This may be used
	* in different ways for different GPUs. For example, if a GPU includes
	* multiple processing cores it may use names "GPU 0", "GPU 1", etc. If a GPU
	* includes a separately scheduled 2D and 3D hardware block, it might use the
	* names "2D" and "3D".
	*
	* The timestamp argument is the timestamp at which the switch occurred on the
	* GPU. These timestamps are in units of nanoseconds and must use
	* approximately the same time as sched_clock, though they need not come from
	* any CPU clock. The timestamps for a single hardware block must be
	* monotonically nondecreasing. This means that if a variable compensation
	* offset is used to translate from some other clock to the sched_clock, then
	* care must be taken when increasing that offset, and doing so may result in
	* multiple events with the same timestamp.
	*
	* The next_ctx_id argument identifies the next context that was running on
	* the GPU hardware block. A value of 0 indicates that the hardware block
	* will be idle.
	*
	* The next_prio argument indicates the priority of the next context at the
	* time of the event. The exact numeric values may mean different things for
	* different GPUs, but they should follow the rule that lower values indicate a
	* higher priority.
	*
	* The next_job_id argument identifies the batch of work that the GPU will be
	* working on. This should correspond to a job_id that was previously traced
	* as a gpu_job_enqueue event when the batch of work was created.
	*/
	TRACE_EVENT(gpu_sched_switch,

	TP_PROTO(const char *gpu_name, u64 timestamp,
	u32 next_ctx_id, s32 next_prio, u32 next_job_id),

	TP_ARGS(gpu_name, timestamp, next_ctx_id, next_prio, next_job_id),

	TP_STRUCT__entry(
	__string( gpu_name, gpu_name )
	__field( u64, timestamp )
	__field( u32, next_ctx_id )
	__field( s32, next_prio )
	__field( u32, next_job_id )
	),

	TP_fast_assign(
	__assign_str(gpu_name, gpu_name);
	__entry->timestamp = timestamp;
	__entry->next_ctx_id = next_ctx_id;
	__entry->next_prio = next_prio;
	__entry->next_job_id = next_job_id;
	),

	TP_printk("gpu_name=%s ts=%llu.%06lu next_ctx_id=%lu next_prio=%ld "
	"next_job_id=%lu",
	__get_str(gpu_name),
	(unsigned long long)show_secs_from_ns(__entry->timestamp),
	(unsigned long)show_usecs_from_ns(__entry->timestamp),
	(unsigned long)__entry->next_ctx_id,
	(long)__entry->next_prio,
	(unsigned long)__entry->next_job_id)
	);

	/*
	* The gpu_job_enqueue event indicates that a batch of work has been queued up
	* to be processed by the GPU. This event is not intended to indicate that
	* the batch of work has been submitted to the GPU hardware, but rather that
	* it has been submitted to the GPU kernel driver.
	*
	* This event should be traced on the thread that initiated the work being
	* queued. For example, if a batch of work is submitted to the kernel by a
	* userland thread, the event should be traced on that thread.
	*
	* The ctx_id field identifies the GPU context in which the batch of work
	* being queued is to be run.
	*
	* The job_id field identifies the batch of work being queued within the given
	* GPU context. The first batch of work submitted for a given GPU context
	* should have a job_id of 0, and each subsequent batch of work should
	* increment the job_id by 1.
	*
	* The type field identifies the type of the job being enqueued. The job
	* types may be different for different GPU hardware. For example, a GPU may
	* differentiate between "2D", "3D", and "compute" jobs.
	*/
	TRACE_EVENT(gpu_job_enqueue,

	TP_PROTO(u32 ctx_id, u32 job_id, const char *type),

	TP_ARGS(ctx_id, job_id, type),

	TP_STRUCT__entry(
	__field( u32, ctx_id )
	__field( u32, job_id )
	__string( type, type )
	),

	TP_fast_assign(
	__entry->ctx_id = ctx_id;
	__entry->job_id = job_id;
	__assign_str(type, type);
	),

	TP_printk("ctx_id=%lu job_id=%lu type=%s",
	(unsigned long)__entry->ctx_id,
	(unsigned long)__entry->job_id,
	__get_str(type))
	);

	#undef show_secs_from_ns
	#undef show_usecs_from_ns

	#endif /* _TRACE_GPU_H */

	/* This part must be outside protection */
	#include <trace/define_trace.h>