stat.h - platform/external/fio - Gitiles

 #ifndef FIO_STAT_H
 #define FIO_STAT_H

 #include "iolog.h"

 struct group_run_stats {
 	uint64_t max_run[DDIR_RWDIR_CNT], min_run[DDIR_RWDIR_CNT];
 	uint64_t max_bw[DDIR_RWDIR_CNT], min_bw[DDIR_RWDIR_CNT];
 	uint64_t io_kb[DDIR_RWDIR_CNT];
 	uint64_t agg[DDIR_RWDIR_CNT];
 	uint32_t kb_base;
 	uint32_t unit_base;
 	uint32_t groupid;
 	uint32_t unified_rw_rep;
 };

 /*
  * How many depth levels to log
  */
 #define FIO_IO_U_MAP_NR	7
 #define FIO_IO_U_LAT_U_NR 10
 #define FIO_IO_U_LAT_M_NR 12

 /*
  * Aggregate clat samples to report percentile(s) of them.
  *
  * EXECUTIVE SUMMARY
  *
  * FIO_IO_U_PLAT_BITS determines the maximum statistical error on the
  * value of resulting percentiles. The error will be approximately
  * 1/2^(FIO_IO_U_PLAT_BITS+1) of the value.
  *
  * FIO_IO_U_PLAT_GROUP_NR and FIO_IO_U_PLAT_BITS determine the maximum
  * range being tracked for latency samples. The maximum value tracked
  * accurately will be 2^(GROUP_NR + PLAT_BITS -1) microseconds.
  *
  * FIO_IO_U_PLAT_GROUP_NR and FIO_IO_U_PLAT_BITS determine the memory
  * requirement of storing those aggregate counts. The memory used will
  * be (FIO_IO_U_PLAT_GROUP_NR * 2^FIO_IO_U_PLAT_BITS) * sizeof(int)
  * bytes.
  *
  * FIO_IO_U_PLAT_NR is the total number of buckets.
  *
  * DETAILS
  *
  * Suppose the clat varies from 0 to 999 (usec), the straightforward
  * method is to keep an array of (999 + 1) buckets, in which a counter
  * keeps the count of samples which fall in the bucket, e.g.,
  * {[0],[1],...,[999]}. However this consumes a huge amount of space,
  * and can be avoided if an approximation is acceptable.
  *
  * One such method is to let the range of the bucket to be greater
  * than one. This method has low accuracy when the value is small. For
  * example, let the buckets be {[0,99],[100,199],...,[900,999]}, and
  * the represented value of each bucket be the mean of the range. Then
  * a value 0 has an round-off error of 49.5. To improve on this, we
  * use buckets with non-uniform ranges, while bounding the error of
  * each bucket within a ratio of the sample value. A simple example
  * would be when error_bound = 0.005, buckets are {
  * {[0],[1],...,[99]}, {[100,101],[102,103],...,[198,199]},..,
  * {[900,909],[910,919]...}  }. The total range is partitioned into
  * groups with different ranges, then buckets with uniform ranges. An
  * upper bound of the error is (range_of_bucket/2)/value_of_bucket
  *
  * For better efficiency, we implement this using base two. We group
  * samples by their Most Significant Bit (MSB), extract the next M bit
  * of them as an index within the group, and discard the rest of the
  * bits.
  *
  * E.g., assume a sample 'x' whose MSB is bit n (starting from bit 0),
  * and use M bit for indexing
  *
  *        | n |    M bits   | bit (n-M-1) ... bit 0 |
  *
  * Because x is at least 2^n, and bit 0 to bit (n-M-1) is at most
  * (2^(n-M) - 1), discarding bit 0 to (n-M-1) makes the round-off
  * error
  *
  *           2^(n-M)-1    2^(n-M)    1
  *      e <= --------- <= ------- = ---
  *             2^n          2^n     2^M
  *
  * Furthermore, we use "mean" of the range to represent the bucket,
  * the error e can be lowered by half to 1 / 2^(M+1). By using M bits
  * as the index, each group must contains 2^M buckets.
  *
  * E.g. Let M (FIO_IO_U_PLAT_BITS) be 6
  *      Error bound is 1/2^(6+1) = 0.0078125 (< 1%)
  *
  *	Group	MSB	#discarded	range of		#buckets
  *			error_bits	value
  *	----------------------------------------------------------------
  *	0*	0~5	0		[0,63]			64
  *	1*	6	0		[64,127]		64
  *	2	7	1		[128,255]		64
  *	3	8	2		[256,511]		64
  *	4	9	3		[512,1023]		64
  *	...	...	...		[...,...]		...
  *	18	23	17		[8838608,+inf]**	64
  *
  *  * Special cases: when n < (M-1) or when n == (M-1), in both cases,
  *    the value cannot be rounded off. Use all bits of the sample as
  *    index.
  *
  *  ** If a sample's MSB is greater than 23, it will be counted as 23.
  */

 #define FIO_IO_U_PLAT_BITS 6
 #define FIO_IO_U_PLAT_VAL (1 << FIO_IO_U_PLAT_BITS)
 #define FIO_IO_U_PLAT_GROUP_NR 19
 #define FIO_IO_U_PLAT_NR (FIO_IO_U_PLAT_GROUP_NR * FIO_IO_U_PLAT_VAL)
 #define FIO_IO_U_LIST_MAX_LEN 20 /* The size of the default and user-specified
 					list of percentiles */

 #define MAX_PATTERN_SIZE	512
 #define FIO_JOBNAME_SIZE	128
 #define FIO_VERROR_SIZE		128

 struct thread_stat {
 	char name[FIO_JOBNAME_SIZE];
 	char verror[FIO_VERROR_SIZE];
 	uint32_t error;
 	uint32_t thread_number;
 	uint32_t groupid;
 	uint32_t pid;
 	char description[FIO_JOBNAME_SIZE];
 	uint32_t members;
 	uint32_t unified_rw_rep;

 	/*
 	 * bandwidth and latency stats
 	 */
 	struct io_stat clat_stat[DDIR_RWDIR_CNT]; /* completion latency */
 	struct io_stat slat_stat[DDIR_RWDIR_CNT]; /* submission latency */
 	struct io_stat lat_stat[DDIR_RWDIR_CNT]; /* total latency */
 	struct io_stat bw_stat[DDIR_RWDIR_CNT]; /* bandwidth stats */
 	struct io_stat iops_stat[DDIR_RWDIR_CNT]; /* IOPS stats */

 	/*
 	 * fio system usage accounting
 	 */
 	uint64_t usr_time;
 	uint64_t sys_time;
 	uint64_t ctx;
 	uint64_t minf, majf;

 	/*
 	 * IO depth and latency stats
 	 */
 	uint64_t clat_percentiles;
 	uint64_t percentile_precision;
 	fio_fp64_t percentile_list[FIO_IO_U_LIST_MAX_LEN];

 	uint32_t io_u_map[FIO_IO_U_MAP_NR];
 	uint32_t io_u_submit[FIO_IO_U_MAP_NR];
 	uint32_t io_u_complete[FIO_IO_U_MAP_NR];
 	uint32_t io_u_lat_u[FIO_IO_U_LAT_U_NR];
 	uint32_t io_u_lat_m[FIO_IO_U_LAT_M_NR];
 	uint32_t io_u_plat[DDIR_RWDIR_CNT][FIO_IO_U_PLAT_NR];
 	uint64_t total_io_u[3];
 	uint64_t short_io_u[3];
 	uint64_t total_submit;
 	uint64_t total_complete;

 	uint64_t io_bytes[DDIR_RWDIR_CNT];
 	uint64_t runtime[DDIR_RWDIR_CNT];
 	uint64_t total_run_time;

 	/*
 	 * IO Error related stats
 	 */
 	uint16_t continue_on_error;
 	uint64_t total_err_count;
 	uint32_t first_error;

 	uint32_t kb_base;
 	uint32_t unit_base;
 };

 struct jobs_eta {
 	uint32_t nr_running;
 	uint32_t nr_ramp;
 	uint32_t nr_pending;
 	uint32_t nr_setting_up;
 	uint32_t files_open;
 	uint32_t m_rate[DDIR_RWDIR_CNT], t_rate[DDIR_RWDIR_CNT];
 	uint32_t m_iops[DDIR_RWDIR_CNT], t_iops[DDIR_RWDIR_CNT];
 	uint32_t rate[DDIR_RWDIR_CNT];
 	uint32_t iops[DDIR_RWDIR_CNT];
 	uint64_t elapsed_sec;
 	uint64_t eta_sec;
 	uint32_t is_pow2;
 	uint32_t unit_base;

 	/*
 	 * Network 'copy' of run_str[]
 	 */
 	uint32_t nr_threads;
 	uint8_t run_str[];
 };

 extern void stat_init(void);
 extern void stat_exit(void);

 extern void show_thread_status(struct thread_stat *ts, struct group_run_stats *rs);
 extern void show_group_stats(struct group_run_stats *rs);
 extern int calc_thread_status(struct jobs_eta *je, int force);
 extern void display_thread_status(struct jobs_eta *je);
 extern void show_run_stats(void);
 extern void show_running_run_stats(void);
 extern void check_for_running_stats(void);
 extern void sum_thread_stats(struct thread_stat *dst, struct thread_stat *src, int nr);
 extern void sum_group_stats(struct group_run_stats *dst, struct group_run_stats *src);
 extern void init_thread_stat(struct thread_stat *ts);
 extern void init_group_run_stat(struct group_run_stats *gs);
 extern void eta_to_str(char *str, unsigned long eta_sec);
 extern int calc_lat(struct io_stat *is, unsigned long *min, unsigned long *max, double *mean, double *dev);
 extern unsigned int calc_clat_percentiles(unsigned int *io_u_plat, unsigned long nr, fio_fp64_t *plist, unsigned int **output, unsigned int *maxv, unsigned int *minv);
 extern void stat_calc_lat_m(struct thread_stat *ts, double *io_u_lat);
 extern void stat_calc_lat_u(struct thread_stat *ts, double *io_u_lat);
 extern void stat_calc_dist(unsigned int *map, unsigned long total, double *io_u_dist);

 static inline int usec_to_msec(unsigned long *min, unsigned long *max,
 			       double *mean, double *dev)
 {
 	if (*min > 1000 && *max > 1000 && *mean > 1000.0 && *dev > 1000.0) {
 		*min /= 1000;
 		*max /= 1000;
 		*mean /= 1000.0;
 		*dev /= 1000.0;
 		return 0;
 	}

 	return 1;
 }

 #endif
	#ifndef FIO_STAT_H
	#define FIO_STAT_H

	#include "iolog.h"

	struct group_run_stats {
	uint64_t max_run[DDIR_RWDIR_CNT], min_run[DDIR_RWDIR_CNT];
	uint64_t max_bw[DDIR_RWDIR_CNT], min_bw[DDIR_RWDIR_CNT];
	uint64_t io_kb[DDIR_RWDIR_CNT];
	uint64_t agg[DDIR_RWDIR_CNT];
	uint32_t kb_base;
	uint32_t unit_base;
	uint32_t groupid;
	uint32_t unified_rw_rep;
	};

	/*
	* How many depth levels to log
	*/
	#define FIO_IO_U_MAP_NR 7
	#define FIO_IO_U_LAT_U_NR 10
	#define FIO_IO_U_LAT_M_NR 12

	/*
	* Aggregate clat samples to report percentile(s) of them.
	*
	* EXECUTIVE SUMMARY
	*
	* FIO_IO_U_PLAT_BITS determines the maximum statistical error on the
	* value of resulting percentiles. The error will be approximately
	* 1/2^(FIO_IO_U_PLAT_BITS+1) of the value.
	*
	* FIO_IO_U_PLAT_GROUP_NR and FIO_IO_U_PLAT_BITS determine the maximum
	* range being tracked for latency samples. The maximum value tracked
	* accurately will be 2^(GROUP_NR + PLAT_BITS -1) microseconds.
	*
	* FIO_IO_U_PLAT_GROUP_NR and FIO_IO_U_PLAT_BITS determine the memory
	* requirement of storing those aggregate counts. The memory used will
	* be (FIO_IO_U_PLAT_GROUP_NR * 2^FIO_IO_U_PLAT_BITS) * sizeof(int)
	* bytes.
	*
	* FIO_IO_U_PLAT_NR is the total number of buckets.
	*
	* DETAILS
	*
	* Suppose the clat varies from 0 to 999 (usec), the straightforward
	* method is to keep an array of (999 + 1) buckets, in which a counter
	* keeps the count of samples which fall in the bucket, e.g.,
	* {[0],[1],...,[999]}. However this consumes a huge amount of space,
	* and can be avoided if an approximation is acceptable.
	*
	* One such method is to let the range of the bucket to be greater
	* than one. This method has low accuracy when the value is small. For
	* example, let the buckets be {[0,99],[100,199],...,[900,999]}, and
	* the represented value of each bucket be the mean of the range. Then
	* a value 0 has an round-off error of 49.5. To improve on this, we
	* use buckets with non-uniform ranges, while bounding the error of
	* each bucket within a ratio of the sample value. A simple example
	* would be when error_bound = 0.005, buckets are {
	* {[0],[1],...,[99]}, {[100,101],[102,103],...,[198,199]},..,
	* {[900,909],[910,919]...} }. The total range is partitioned into
	* groups with different ranges, then buckets with uniform ranges. An
	* upper bound of the error is (range_of_bucket/2)/value_of_bucket
	*
	* For better efficiency, we implement this using base two. We group
	* samples by their Most Significant Bit (MSB), extract the next M bit
	* of them as an index within the group, and discard the rest of the
	* bits.
	*
	* E.g., assume a sample 'x' whose MSB is bit n (starting from bit 0),
	* and use M bit for indexing
	*
	* \| n \| M bits \| bit (n-M-1) ... bit 0 \|
	*
	* Because x is at least 2^n, and bit 0 to bit (n-M-1) is at most
	* (2^(n-M) - 1), discarding bit 0 to (n-M-1) makes the round-off
	* error
	*
	* 2^(n-M)-1 2^(n-M) 1
	* e <= --------- <= ------- = ---
	* 2^n 2^n 2^M
	*
	* Furthermore, we use "mean" of the range to represent the bucket,
	* the error e can be lowered by half to 1 / 2^(M+1). By using M bits
	* as the index, each group must contains 2^M buckets.
	*
	* E.g. Let M (FIO_IO_U_PLAT_BITS) be 6
	* Error bound is 1/2^(6+1) = 0.0078125 (< 1%)
	*
	* Group MSB #discarded range of #buckets
	* error_bits value
	* ----------------------------------------------------------------
	* 0* 0~5 0 [0,63] 64
	* 1* 6 0 [64,127] 64
	* 2 7 1 [128,255] 64
	* 3 8 2 [256,511] 64
	* 4 9 3 [512,1023] 64
	* ... ... ... [...,...] ...
	* 18 23 17 [8838608,+inf]** 64
	*
	* * Special cases: when n < (M-1) or when n == (M-1), in both cases,
	* the value cannot be rounded off. Use all bits of the sample as
	* index.
	*
	* ** If a sample's MSB is greater than 23, it will be counted as 23.
	*/

	#define FIO_IO_U_PLAT_BITS 6
	#define FIO_IO_U_PLAT_VAL (1 << FIO_IO_U_PLAT_BITS)
	#define FIO_IO_U_PLAT_GROUP_NR 19
	#define FIO_IO_U_PLAT_NR (FIO_IO_U_PLAT_GROUP_NR * FIO_IO_U_PLAT_VAL)
	#define FIO_IO_U_LIST_MAX_LEN 20 /* The size of the default and user-specified
	list of percentiles */

	#define MAX_PATTERN_SIZE 512
	#define FIO_JOBNAME_SIZE 128
	#define FIO_VERROR_SIZE 128

	struct thread_stat {
	char name[FIO_JOBNAME_SIZE];
	char verror[FIO_VERROR_SIZE];
	uint32_t error;
	uint32_t thread_number;
	uint32_t groupid;
	uint32_t pid;
	char description[FIO_JOBNAME_SIZE];
	uint32_t members;
	uint32_t unified_rw_rep;

	/*
	* bandwidth and latency stats
	*/
	struct io_stat clat_stat[DDIR_RWDIR_CNT]; /* completion latency */
	struct io_stat slat_stat[DDIR_RWDIR_CNT]; /* submission latency */
	struct io_stat lat_stat[DDIR_RWDIR_CNT]; /* total latency */
	struct io_stat bw_stat[DDIR_RWDIR_CNT]; /* bandwidth stats */
	struct io_stat iops_stat[DDIR_RWDIR_CNT]; /* IOPS stats */

	/*
	* fio system usage accounting
	*/
	uint64_t usr_time;
	uint64_t sys_time;
	uint64_t ctx;
	uint64_t minf, majf;

	/*
	* IO depth and latency stats
	*/
	uint64_t clat_percentiles;
	uint64_t percentile_precision;
	fio_fp64_t percentile_list[FIO_IO_U_LIST_MAX_LEN];

	uint32_t io_u_map[FIO_IO_U_MAP_NR];
	uint32_t io_u_submit[FIO_IO_U_MAP_NR];
	uint32_t io_u_complete[FIO_IO_U_MAP_NR];
	uint32_t io_u_lat_u[FIO_IO_U_LAT_U_NR];
	uint32_t io_u_lat_m[FIO_IO_U_LAT_M_NR];
	uint32_t io_u_plat[DDIR_RWDIR_CNT][FIO_IO_U_PLAT_NR];
	uint64_t total_io_u[3];
	uint64_t short_io_u[3];
	uint64_t total_submit;
	uint64_t total_complete;

	uint64_t io_bytes[DDIR_RWDIR_CNT];
	uint64_t runtime[DDIR_RWDIR_CNT];
	uint64_t total_run_time;

	/*
	* IO Error related stats
	*/
	uint16_t continue_on_error;
	uint64_t total_err_count;
	uint32_t first_error;

	uint32_t kb_base;
	uint32_t unit_base;
	};

	struct jobs_eta {
	uint32_t nr_running;
	uint32_t nr_ramp;
	uint32_t nr_pending;
	uint32_t nr_setting_up;
	uint32_t files_open;
	uint32_t m_rate[DDIR_RWDIR_CNT], t_rate[DDIR_RWDIR_CNT];
	uint32_t m_iops[DDIR_RWDIR_CNT], t_iops[DDIR_RWDIR_CNT];
	uint32_t rate[DDIR_RWDIR_CNT];
	uint32_t iops[DDIR_RWDIR_CNT];
	uint64_t elapsed_sec;
	uint64_t eta_sec;
	uint32_t is_pow2;
	uint32_t unit_base;

	/*
	* Network 'copy' of run_str[]
	*/
	uint32_t nr_threads;
	uint8_t run_str[];
	};

	extern void stat_init(void);
	extern void stat_exit(void);

	extern void show_thread_status(struct thread_stat ts, struct group_run_stats rs);
	extern void show_group_stats(struct group_run_stats *rs);
	extern int calc_thread_status(struct jobs_eta *je, int force);
	extern void display_thread_status(struct jobs_eta *je);
	extern void show_run_stats(void);
	extern void show_running_run_stats(void);
	extern void check_for_running_stats(void);
	extern void sum_thread_stats(struct thread_stat dst, struct thread_stat src, int nr);
	extern void sum_group_stats(struct group_run_stats dst, struct group_run_stats src);
	extern void init_thread_stat(struct thread_stat *ts);
	extern void init_group_run_stat(struct group_run_stats *gs);
	extern void eta_to_str(char *str, unsigned long eta_sec);
	extern int calc_lat(struct io_stat is, unsigned long min, unsigned long max, double mean, double *dev);
	extern unsigned int calc_clat_percentiles(unsigned int io_u_plat, unsigned long nr, fio_fp64_t plist, unsigned int *output, unsigned int maxv, unsigned int *minv);
	extern void stat_calc_lat_m(struct thread_stat ts, double io_u_lat);
	extern void stat_calc_lat_u(struct thread_stat ts, double io_u_lat);
	extern void stat_calc_dist(unsigned int map, unsigned long total, double io_u_dist);

	static inline int usec_to_msec(unsigned long min, unsigned long max,
	double mean, double dev)
	{
	if (min > 1000 && max > 1000 && mean > 1000.0 && dev > 1000.0) {
	*min /= 1000;
	*max /= 1000;
	*mean /= 1000.0;
	*dev /= 1000.0;
	return 0;
	}

	return 1;
	}

	#endif