oprofile-0.9.7/daemon/opd_spu.c - nest-learning-thermostat/5.1.7/oprofile - Git at Google

 /**
  * @file daemon/opd_spu.c
  * Processing the sample buffer for Cell BE SPU profile
  *
  * @remark Copyright 2007 OProfile authors
  * @remark Read the file COPYING
  *
  * @author Maynard Johnson
  * (C) Copyright IBM Corporation 2007
  */

 #include "opd_interface.h"
 #include "opd_printf.h"
 #include "opd_sfile.h"
 #include "opd_stats.h"
 #include "opd_trans.h"
 #include "op_libiberty.h"

 #include <stdlib.h>
 #include <stdio.h>

 struct spu_context_info {
 	pid_t tid;
 	pid_t tgid;
 	cookie_t app_cookie;
 	uint64_t embedded_offset;
 	cookie_t spu_cookie;
 };

 static struct spu_context_info * spu_context_cache;

 /* Forward declaration */
 static void process_spu_samples(struct transient * trans);

 void (*special_processor)(struct transient *);

 /*
  * This function is called when the first value found in the
  * buffer (after the beginning ESCAPE_CODE) is SPU_PROFILING_CODE.
  * Once we get here, the rest of the processing of the buffer is
  * Cell-SPU-specific, so we do not need to return until the
  * trans.buffer is empty.
  */
 void code_spu_profiling(struct transient * trans)
 {
 	/* Next value in buffer is the number of SPUs. */
 	unsigned long long num_spus = pop_buffer_value(trans);
 	/* Free the cache from previous run */
 	free(spu_context_cache);
 	spu_context_cache = xmalloc(sizeof(struct spu_context_info) * num_spus);
 	special_processor = process_spu_samples;
 	process_spu_samples(trans);
 }

 void code_spu_ctx_switch(struct transient * trans)
 {
 	clear_trans_current(trans);

 	if (!enough_remaining(trans, 6)) {
 		trans->remaining = 0;
 		return;
 	}

 	/* First value in the buffer for an SPU context switch is
 	 * the SPU number.  For SPU profiling, 'cpu' = 'spu'.
 	 */
 	trans->cpu = pop_buffer_value(trans);
 	trans->tid = pop_buffer_value(trans);
 	trans->tgid = pop_buffer_value(trans);
 	trans->app_cookie = pop_buffer_value(trans);

 	if (vmisc) {
 		char const * app = find_cookie(trans->app_cookie);
 		printf("SPU_CTX_SWITCH to tid %lu, tgid %lu, cookie %llx(%s)\n",
 		       (unsigned long)trans->tid, (unsigned long)trans->tgid,
 		       trans->app_cookie, app ? app : "none");
 	}

 	/* The trans->cookie will point to the binary file where the SPU ELF
 	 * can be found.  If the SPU ELF is embedded, it may be embedded in
 	 * either the executable application binary or a shared lib.  If shared
 	 * library, then trans->cookie will differ from the previously obtained
 	 * trans->app_cookie.  For the non-embedded case, trans->cookie always
 	 * points to a separate binary file.
 	 */
 	trans->cookie = pop_buffer_value(trans);
 	trans->embedded_offset = pop_buffer_value(trans);
 }


 static void cache_spu_context_info(struct transient * trans)
 {
 	int i = trans->cpu;
 	spu_context_cache[i].tid = trans->tid;
 	spu_context_cache[i].tgid = trans->tgid;
 	spu_context_cache[i].app_cookie = trans->app_cookie;
 	spu_context_cache[i].embedded_offset = trans->embedded_offset;
 	spu_context_cache[i].spu_cookie = trans->cookie;
 }

 static void update_trans_for_spu(struct transient * trans)
 {
 	int i = trans->cpu;
 	trans->tid = spu_context_cache[i].tid;
 	trans->tgid = spu_context_cache[i].tgid;
 	trans->app_cookie = spu_context_cache[i].app_cookie;
 	trans->embedded_offset = spu_context_cache[i].embedded_offset;
 	trans->cookie = spu_context_cache[i].spu_cookie;
 }
 #define SPU_NUM_MASK 0xFFFFFFFF00000000ULL
 #define SPU_CYCLES_COUNTER 0

 static void opd_put_spu_sample
 (struct transient * trans, unsigned long long pc)
 {
 	unsigned long spu_number = (pc & SPU_NUM_MASK) >> 32;
 	if (trans->cpu != spu_number) {
 		trans->cpu = spu_number;
 	        clear_trans_current(trans);
 		update_trans_for_spu(trans);
 	}
 	/* get the current sfile if needed */
 	if (!trans->current)
 		trans->current = sfile_find(trans);

 	if (trans->tracing != TRACING_ON)
 		trans->event = SPU_CYCLES_COUNTER;

 	trans->pc = (pc & ~SPU_NUM_MASK);
 	/* log the sample or arc */
 	sfile_log_sample(trans);

 	/* switch to trace mode */
 	if (trans->tracing == TRACING_START)
 		trans->tracing = TRACING_ON;

 	update_trans_last(trans);
 }

 /*
  * This function processes SPU context switches and
  * SPU program counter samples.  After processing a
  * context switch (via handlers[code)), we cache the
  * SPU context information that has been temporarily
  * stored in trans.
  */
 static void process_spu_samples(struct transient * trans)
 {
 	unsigned long long code;
 	trans->in_kernel = 0;
 	while (trans->remaining) {
 		code = pop_buffer_value(trans);

 		if (!is_escape_code(code)) {
 			opd_put_spu_sample(trans, code);
 			continue;
 		}

 		if (!trans->remaining) {
 			verbprintf(vmisc, "Dangling ESCAPE_CODE.\n");
 			opd_stats[OPD_DANGLING_CODE]++;
 			break;
 		}

 		/* started with ESCAPE_CODE, next is type */
 		code = pop_buffer_value(trans);

 		if (code >= LAST_CODE) {
 			fprintf(stderr, "Unknown code %llu\n", code);
 			abort();
 		}

 		handlers[code](trans);
 		cache_spu_context_info(trans);
 	}
 }
	/**
	* @file daemon/opd_spu.c
	* Processing the sample buffer for Cell BE SPU profile
	*
	* @remark Copyright 2007 OProfile authors
	* @remark Read the file COPYING
	*
	* @author Maynard Johnson
	* (C) Copyright IBM Corporation 2007
	*/

	#include "opd_interface.h"
	#include "opd_printf.h"
	#include "opd_sfile.h"
	#include "opd_stats.h"
	#include "opd_trans.h"
	#include "op_libiberty.h"

	#include <stdlib.h>
	#include <stdio.h>

	struct spu_context_info {
	pid_t tid;
	pid_t tgid;
	cookie_t app_cookie;
	uint64_t embedded_offset;
	cookie_t spu_cookie;
	};

	static struct spu_context_info * spu_context_cache;

	/* Forward declaration */
	static void process_spu_samples(struct transient * trans);

	void (special_processor)(struct transient );

	/*
	* This function is called when the first value found in the
	* buffer (after the beginning ESCAPE_CODE) is SPU_PROFILING_CODE.
	* Once we get here, the rest of the processing of the buffer is
	* Cell-SPU-specific, so we do not need to return until the
	* trans.buffer is empty.
	*/
	void code_spu_profiling(struct transient * trans)
	{
	/* Next value in buffer is the number of SPUs. */
	unsigned long long num_spus = pop_buffer_value(trans);
	/* Free the cache from previous run */
	free(spu_context_cache);
	spu_context_cache = xmalloc(sizeof(struct spu_context_info) * num_spus);
	special_processor = process_spu_samples;
	process_spu_samples(trans);
	}

	void code_spu_ctx_switch(struct transient * trans)
	{
	clear_trans_current(trans);

	if (!enough_remaining(trans, 6)) {
	trans->remaining = 0;
	return;
	}

	/* First value in the buffer for an SPU context switch is
	* the SPU number. For SPU profiling, 'cpu' = 'spu'.
	*/
	trans->cpu = pop_buffer_value(trans);
	trans->tid = pop_buffer_value(trans);
	trans->tgid = pop_buffer_value(trans);
	trans->app_cookie = pop_buffer_value(trans);

	if (vmisc) {
	char const * app = find_cookie(trans->app_cookie);
	printf("SPU_CTX_SWITCH to tid %lu, tgid %lu, cookie %llx(%s)\n",
	(unsigned long)trans->tid, (unsigned long)trans->tgid,
	trans->app_cookie, app ? app : "none");
	}

	/* The trans->cookie will point to the binary file where the SPU ELF
	* can be found. If the SPU ELF is embedded, it may be embedded in
	* either the executable application binary or a shared lib. If shared
	* library, then trans->cookie will differ from the previously obtained
	* trans->app_cookie. For the non-embedded case, trans->cookie always
	* points to a separate binary file.
	*/
	trans->cookie = pop_buffer_value(trans);
	trans->embedded_offset = pop_buffer_value(trans);
	}


	static void cache_spu_context_info(struct transient * trans)
	{
	int i = trans->cpu;
	spu_context_cache[i].tid = trans->tid;
	spu_context_cache[i].tgid = trans->tgid;
	spu_context_cache[i].app_cookie = trans->app_cookie;
	spu_context_cache[i].embedded_offset = trans->embedded_offset;
	spu_context_cache[i].spu_cookie = trans->cookie;
	}

	static void update_trans_for_spu(struct transient * trans)
	{
	int i = trans->cpu;
	trans->tid = spu_context_cache[i].tid;
	trans->tgid = spu_context_cache[i].tgid;
	trans->app_cookie = spu_context_cache[i].app_cookie;
	trans->embedded_offset = spu_context_cache[i].embedded_offset;
	trans->cookie = spu_context_cache[i].spu_cookie;
	}
	#define SPU_NUM_MASK 0xFFFFFFFF00000000ULL
	#define SPU_CYCLES_COUNTER 0

	static void opd_put_spu_sample
	(struct transient * trans, unsigned long long pc)
	{
	unsigned long spu_number = (pc & SPU_NUM_MASK) >> 32;
	if (trans->cpu != spu_number) {
	trans->cpu = spu_number;
	clear_trans_current(trans);
	update_trans_for_spu(trans);
	}
	/* get the current sfile if needed */
	if (!trans->current)
	trans->current = sfile_find(trans);

	if (trans->tracing != TRACING_ON)
	trans->event = SPU_CYCLES_COUNTER;

	trans->pc = (pc & ~SPU_NUM_MASK);
	/* log the sample or arc */
	sfile_log_sample(trans);

	/* switch to trace mode */
	if (trans->tracing == TRACING_START)
	trans->tracing = TRACING_ON;

	update_trans_last(trans);
	}

	/*
	* This function processes SPU context switches and
	* SPU program counter samples. After processing a
	* context switch (via handlers[code)), we cache the
	* SPU context information that has been temporarily
	* stored in trans.
	*/
	static void process_spu_samples(struct transient * trans)
	{
	unsigned long long code;
	trans->in_kernel = 0;
	while (trans->remaining) {
	code = pop_buffer_value(trans);

	if (!is_escape_code(code)) {
	opd_put_spu_sample(trans, code);
	continue;
	}

	if (!trans->remaining) {
	verbprintf(vmisc, "Dangling ESCAPE_CODE.\n");
	opd_stats[OPD_DANGLING_CODE]++;
	break;
	}

	/* started with ESCAPE_CODE, next is type */
	code = pop_buffer_value(trans);

	if (code >= LAST_CODE) {
	fprintf(stderr, "Unknown code %llu\n", code);
	abort();
	}

	handlers[code](trans);
	cache_spu_context_info(trans);
	}
	}