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/*
* Copyright © 2018 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*/
#ifndef GEN_PERF_H
#define GEN_PERF_H
#include <stdio.h>
#include <stdint.h>
#include <string.h>
#include <sys/sysmacros.h>
#include "util/hash_table.h"
#include "util/ralloc.h"
struct gen_device_info;
struct gen_perf;
struct gen_perf_query_info;
enum gen_perf_counter_type {
GEN_PERF_COUNTER_TYPE_EVENT,
GEN_PERF_COUNTER_TYPE_DURATION_NORM,
GEN_PERF_COUNTER_TYPE_DURATION_RAW,
GEN_PERF_COUNTER_TYPE_THROUGHPUT,
GEN_PERF_COUNTER_TYPE_RAW,
GEN_PERF_COUNTER_TYPE_TIMESTAMP,
};
enum gen_perf_counter_data_type {
GEN_PERF_COUNTER_DATA_TYPE_BOOL32,
GEN_PERF_COUNTER_DATA_TYPE_UINT32,
GEN_PERF_COUNTER_DATA_TYPE_UINT64,
GEN_PERF_COUNTER_DATA_TYPE_FLOAT,
GEN_PERF_COUNTER_DATA_TYPE_DOUBLE,
};
struct gen_pipeline_stat {
uint32_t reg;
uint32_t numerator;
uint32_t denominator;
};
/*
* The largest OA formats we can use include:
* For Haswell:
* 1 timestamp, 45 A counters, 8 B counters and 8 C counters.
* For Gen8+
* 1 timestamp, 1 clock, 36 A counters, 8 B counters and 8 C counters
*/
#define MAX_OA_REPORT_COUNTERS 62
struct gen_perf_query_result {
/**
* Storage for the final accumulated OA counters.
*/
uint64_t accumulator[MAX_OA_REPORT_COUNTERS];
/**
* Hw ID used by the context on which the query was running.
*/
uint32_t hw_id;
/**
* Number of reports accumulated to produce the results.
*/
uint32_t reports_accumulated;
/**
* Frequency in the slices of the GT at the begin and end of the
* query.
*/
uint64_t slice_frequency[2];
/**
* Frequency in the unslice of the GT at the begin and end of the
* query.
*/
uint64_t unslice_frequency[2];
};
struct gen_perf_query_counter {
const char *name;
const char *desc;
enum gen_perf_counter_type type;
enum gen_perf_counter_data_type data_type;
uint64_t raw_max;
size_t offset;
union {
uint64_t (*oa_counter_read_uint64)(struct gen_perf *perf,
const struct gen_perf_query_info *query,
uint64_t *accumulator);
float (*oa_counter_read_float)(struct gen_perf *perf,
const struct gen_perf_query_info *query,
uint64_t *accumulator);
struct gen_pipeline_stat pipeline_stat;
};
};
struct gen_perf_query_register_prog {
uint32_t reg;
uint32_t val;
};
struct gen_perf_query_info {
enum gen_perf_query_type {
GEN_PERF_QUERY_TYPE_OA,
GEN_PERF_QUERY_TYPE_RAW,
GEN_PERF_QUERY_TYPE_PIPELINE,
} kind;
const char *name;
const char *guid;
struct gen_perf_query_counter *counters;
int n_counters;
int max_counters;
size_t data_size;
/* OA specific */
uint64_t oa_metrics_set_id;
int oa_format;
/* For indexing into the accumulator[] ... */
int gpu_time_offset;
int gpu_clock_offset;
int a_offset;
int b_offset;
int c_offset;
/* Register programming for a given query */
struct gen_perf_query_register_prog *flex_regs;
uint32_t n_flex_regs;
struct gen_perf_query_register_prog *mux_regs;
uint32_t n_mux_regs;
struct gen_perf_query_register_prog *b_counter_regs;
uint32_t n_b_counter_regs;
};
struct gen_perf {
struct gen_perf_query_info *queries;
int n_queries;
/* Variables referenced in the XML meta data for OA performance
* counters, e.g in the normalization equations.
*
* All uint64_t for consistent operand types in generated code
*/
struct {
uint64_t timestamp_frequency; /** $GpuTimestampFrequency */
uint64_t n_eus; /** $EuCoresTotalCount */
uint64_t n_eu_slices; /** $EuSlicesTotalCount */
uint64_t n_eu_sub_slices; /** $EuSubslicesTotalCount */
uint64_t eu_threads_count; /** $EuThreadsCount */
uint64_t slice_mask; /** $SliceMask */
uint64_t subslice_mask; /** $SubsliceMask */
uint64_t gt_min_freq; /** $GpuMinFrequency */
uint64_t gt_max_freq; /** $GpuMaxFrequency */
uint64_t revision; /** $SkuRevisionId */
} sys_vars;
/* OA metric sets, indexed by GUID, as know by Mesa at build time, to
* cross-reference with the GUIDs of configs advertised by the kernel at
* runtime
*/
struct hash_table *oa_metrics_table;
/* Location of the device's sysfs entry. */
char sysfs_dev_dir[256];
int (*ioctl)(int, unsigned long, void *);
};
static inline size_t
gen_perf_query_counter_get_size(const struct gen_perf_query_counter *counter)
{
switch (counter->data_type) {
case GEN_PERF_COUNTER_DATA_TYPE_BOOL32:
return sizeof(uint32_t);
case GEN_PERF_COUNTER_DATA_TYPE_UINT32:
return sizeof(uint32_t);
case GEN_PERF_COUNTER_DATA_TYPE_UINT64:
return sizeof(uint64_t);
case GEN_PERF_COUNTER_DATA_TYPE_FLOAT:
return sizeof(float);
case GEN_PERF_COUNTER_DATA_TYPE_DOUBLE:
return sizeof(double);
default:
unreachable("invalid counter data type");
}
}
static inline struct gen_perf_query_info *
gen_perf_query_append_query_info(struct gen_perf *perf, int max_counters)
{
struct gen_perf_query_info *query;
perf->queries = reralloc(perf, perf->queries,
struct gen_perf_query_info,
++perf->n_queries);
query = &perf->queries[perf->n_queries - 1];
memset(query, 0, sizeof(*query));
if (max_counters > 0) {
query->max_counters = max_counters;
query->counters =
rzalloc_array(perf, struct gen_perf_query_counter, max_counters);
}
return query;
}
static inline void
gen_perf_query_info_add_stat_reg(struct gen_perf_query_info *query,
uint32_t reg,
uint32_t numerator,
uint32_t denominator,
const char *name,
const char *description)
{
struct gen_perf_query_counter *counter;
assert(query->n_counters < query->max_counters);
counter = &query->counters[query->n_counters];
counter->name = name;
counter->desc = description;
counter->type = GEN_PERF_COUNTER_TYPE_RAW;
counter->data_type = GEN_PERF_COUNTER_DATA_TYPE_UINT64;
counter->offset = sizeof(uint64_t) * query->n_counters;
counter->pipeline_stat.reg = reg;
counter->pipeline_stat.numerator = numerator;
counter->pipeline_stat.denominator = denominator;
query->n_counters++;
}
static inline void
gen_perf_query_info_add_basic_stat_reg(struct gen_perf_query_info *query,
uint32_t reg, const char *name)
{
gen_perf_query_info_add_stat_reg(query, reg, 1, 1, name, name);
}
static inline struct gen_perf *
gen_perf_new(void *ctx, int (*ioctl_cb)(int, unsigned long, void *))
{
struct gen_perf *perf = rzalloc(ctx, struct gen_perf);
perf->ioctl = ioctl_cb;
return perf;
}
bool gen_perf_load_oa_metrics(struct gen_perf *perf, int fd,
const struct gen_device_info *devinfo);
bool gen_perf_load_metric_id(struct gen_perf *perf, const char *guid,
uint64_t *metric_id);
void gen_perf_query_result_read_frequencies(struct gen_perf_query_result *result,
const struct gen_device_info *devinfo,
const uint32_t *start,
const uint32_t *end);
void gen_perf_query_result_accumulate(struct gen_perf_query_result *result,
const struct gen_perf_query_info *query,
const uint32_t *start,
const uint32_t *end);
void gen_perf_query_result_clear(struct gen_perf_query_result *result);
#endif /* GEN_PERF_H */
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