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perfstat.cc
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perfstat.cc
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/* Masstree
* Eddie Kohler, Yandong Mao, Robert Morris
* Copyright (c) 2012-2013 President and Fellows of Harvard College
* Copyright (c) 2012-2013 Massachusetts Institute of Technology
*
* 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, subject to the conditions
* listed in the Masstree LICENSE file. These conditions include: you must
* preserve this copyright notice, and you cannot mention the copyright
* holders in advertising related to the Software without their permission.
* The Software is provided WITHOUT ANY WARRANTY, EXPRESS OR IMPLIED. This
* notice is a summary of the Masstree LICENSE file; the license in that file
* is legally binding.
*/
#include "perfstat.hh"
#include "compiler.hh"
#include "kvstats.hh"
#if HAVE_NUMA_H
#include <numa.h>
#endif
enum { MaxCores = 48 }; // Maximum number of cores kvdb statistics support
enum { MaxNumaNode = 8 }; // Maximum number of Numa node kvdb statistics support
enum { CoresPerChip = MaxCores / MaxNumaNode };
namespace Perf {
#if MEMSTATS && HAVE_NUMA_H && HAVE_LIBNUMA
static struct {
long long free;
long long size;
} numa[MaxNumaNode];
#endif
void
stat::initmain(bool pinthreads) {
(void) pinthreads;
#if PMC_ENABLED
always_assert(pinthreads && "Using performance counter requires pinning threads to cores!");
#endif
#if MEMSTATS && HAVE_NUMA_H && HAVE_LIBNUMA
if (numa_available() != -1) {
always_assert(numa_max_node() <= MaxNumaNode);
for (int i = 0; i <= numa_max_node(); i++)
numa[i].size = numa_node_size64(i, &numa[i].free);
}
#endif
}
template <typename T>
kvstats
sum_all_cores(const stat **s, int n, const int offset) {
kvstats sum;
for (int i = 0; i < n; i++) {
if (!s[i])
continue;
T v = *reinterpret_cast<const T *>(reinterpret_cast<const char *>(s[i]) + offset);
sum.add(v);
}
return sum;
}
template <typename T>
kvstats
sum_one_chip(const stat **s, int n, const int offset, const int chipidx) {
kvstats sum;
for (int i = 0; i < n; i++) {
if (!s[i] || s[i]->cid / (MaxCores / MaxNumaNode) != chipidx)
continue;
T v = *reinterpret_cast<const T *>(reinterpret_cast<const char *>(s[i]) + offset);
sum.add(v);
}
return sum;
}
template <typename T>
kvstats
sum_all_per_chip(const stat **s, int n, const int offset) {
kvstats per_chip[MaxNumaNode];
for (int i = 0; i < n; i++) {
if (!s[i])
continue;
T v = *reinterpret_cast<const T *>(reinterpret_cast<const char *>(s[i]) + offset);
per_chip[i / CoresPerChip].add(v);
}
kvstats sum;
for (int i = 0; i < MaxNumaNode; i++)
if (per_chip[i].count)
sum.add(per_chip[i].avg());
return sum;
}
void
stat::print(const stat **s, int n) {
(void)n;
(void)s;
#define sum_all_cores_of(field) \
sum_all_cores<typeof(s[0]->field)>(s, n, offsetof(Perf::stat, field))
#define sum_one_chip_of(field, c) \
sum_one_chip<typeof(s[0]->field)>(s, n, offsetof(Perf::stat, field), c)
#define sum_all_per_chip_of(field) \
sum_all_per_chip<typeof(s[0]->field)>(s, n, offsetof(Perf::stat, field))
#define sum_all_cores_of_array(field, oa) \
sum_all_cores<typeof(s[0]->field[0])>(s, n, offsetof(Perf::stat, field) + \
sizeof(s[0]->field[0]) * oa)
#define sum_one_chip_of_array(field, oa, c) \
sum_one_chip<typeof(s[0]->field[0])>(s, n, offsetof(Perf::stat, field) + \
sizeof(s[0]->field[0]) * oa, c)
#define sum_all_per_chip_of_array(field, oa) \
sum_all_per_chip<typeof(s[0]->field[0])>(s, n, offsetof(Perf::stat, field) + \
sizeof(s[0]->field[0]) * oa)
#if GETSTATS && 0
for (int i = 0; i < n; i++)
if (s[i]->ngets < 1000) {
s[i] = NULL;
continue;
}
kvstats ngets = sum_all_cores_of(ngets);
kvstats ntsc = sum_all_cores_of(ntsc);
kvstats np = sum_all_cores_of(nprobe);
if (np.sum >= 1)
fprintf(stderr, "Total probe %.0f, probe/get %.2f\n", np.sum, np.sum / ngets.sum);
#if PMC_ENABLED
fprintf(stderr, "(Inaccurate because PMC is Enabled!)");
#endif
fprintf(stderr, "Cycles/get (between mark_get_begin and mark_get_end): %.0f\n",
ntsc.sum / ngets.sum);
#if PMC_ENABLED
for (int i = 0; i < n; i++) {
if (!s[i])
continue;
fprintf(stderr, "Core %d:\n", i);
for (int pi = 0; pi < 4; pi++) {
fprintf(stderr, "\tpmc[%d]: %016" PRIx64 "->%016" PRIx64 "\n",
pi, s[i]->pmc_firstget[pi], s[i]->pmc_start[pi]);
always_assert(s[i]->pmc_start[pi] >= s[i]->pmc_firstget[pi]);
always_assert(s[i]->t1_lastget >= s[i]->t0_firstget);
}
}
// Compute the start and end time of get phase
kvstats getstart = sum_all_cores_of(t0_firstget);
kvstats getend = sum_all_cores_of(t1_lastget);
getstart.print_report("time of first get");
getend.print_report("time of last get");
// Compute per-chip pmc during the whole get phase
double pcpmc_phase[MaxNumaNode][4];
for (int i = 0; i < MaxNumaNode; i++)
for (int pi = 0; pi < 4; pi++)
pcpmc_phase[i][pi] = sum_one_chip_of_array(pmc_start, pi, i).avg() -
sum_one_chip_of_array(pmc_firstget, pi, i).avg();
// Compute cputime and realtime during get phase
kvstats t_firstget = sum_all_cores_of(t0_firstget);
kvstats t_lastget = sum_all_cores_of(t1_lastget);
double realtime = t_lastget.avg() - t_firstget.avg();
for (int pi = 0; pi < 4; pi++) {
fprintf(stderr, "DRAM access to node (pmc %d)\n", pi);
double sum = 0;
for (int i = 0; i < MaxNumaNode; i++) {
fprintf(stderr, "\tFrom chip %2d: %8.1f GB/s\n", i,
pcpmc_phase[i][pi] * 64 / (realtime * (1 << 30)));
sum += pcpmc_phase[i][pi];
}
fprintf(stderr, "\tSum: %8.1f GB/s\n",
sum * 64 / (realtime * (1 << 30)));
}
// Print per-get pmc_lookup
fprintf(stderr, "Per get statistics (counted between mark_get_begin and mark_get_end):\n");
for (int pi = 0; (ngets.sum > 0) && pi < 4; pi ++) {
kvstats pmc_lookup = sum_all_cores_of_array(pmc_lookup, pi);
kvstats pcpmc_lookup = sum_all_per_chip_of_array(pmc_lookup, pi);
fprintf(stderr, "\tpmc%d/get: %6.1f, per_chip_pmc%d/get: %6.1f\n",
pi, (double) pmc_lookup.sum / ngets.sum, pi,
(double) pcpmc_lookup.sum / ngets.sum);
}
#endif
#endif
#if MEMSTATS && HAVE_NUMA_H && HAVE_LIBNUMA && 0
// collect tree memory
kvstats tree_mem = sum_all_cores_of(tree_mem);
kvstats tree_keys = sum_all_cores_of(tree_keys);
fprintf(stderr, "Memory statistics\n");
fprintf(stderr, "\tAllocated per key: %.0f bytes, %.0f\n", tree_mem.sum / tree_keys.sum, tree_keys.sum);
if (numa_available() != -1) {
unsigned long total_alloc = 0;
for (int i = 0; i <= numa_max_node(); i++) {
kvstats chip = sum_one_chip_of(tree_mem, i);
long long nowfree;
long long size = numa_node_size64(i, &nowfree);
total_alloc += numa[i].free - nowfree;
fprintf(stderr, "\tNode %d (MB): size %6lld, allocated = %6lld - "
"%6lld = %6lld, tree_mem %6.0f\n",
i, size >> 20, numa[i].free >> 20, nowfree >> 20,
(numa[i].free - nowfree) / (1 << 20),
chip.sum / (1 << 20));
}
fprintf(stderr, "Total allocated memory %ld MB\n", total_alloc >> 20);
}
#endif
#if GCSTATS
// collect memory used by epoch based garbage collector
kvstats gc_nfree = sum_all_cores_of(gc_nfree);
kvstats gc_nalloc = sum_all_cores_of(gc_nalloc);
fprintf(stderr, "reuse per gc slot: %.0f, freed: %.0f, allocated: %.0f\n",
gc_nfree.sum / gc_nalloc.sum, gc_nfree.sum, gc_nalloc.sum);
#endif
}
}