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construct/include/ircd/prof.h
2019-05-08 05:19:04 -07:00

306 lines
7 KiB
C++

// Matrix Construct
//
// Copyright (C) Matrix Construct Developers, Authors & Contributors
// Copyright (C) 2016-2019 Jason Volk <jason@zemos.net>
//
// Permission to use, copy, modify, and/or distribute this software for any
// purpose with or without fee is hereby granted, provided that the above
// copyright notice and this permission notice is present in all copies. The
// full license for this software is available in the LICENSE file.
#pragma once
#define HAVE_IRCD_PROF_H
namespace ircd::prof
{
struct init;
struct type;
struct event;
struct times;
struct system;
struct resource;
struct syscall_timer;
struct instructions;
enum dpl :uint8_t;
using group = std::vector<std::unique_ptr<event>>;
IRCD_OVERLOAD(sample)
IRCD_EXCEPTION(ircd::error, error)
uint64_t cycles(); ///< Monotonic reference cycles (since system boot)
uint64_t time_user(); ///< Nanoseconds of CPU time in userspace.
uint64_t time_kern(); ///< Nanoseconds of CPU time in kernelland.
uint64_t time_real(); ///< Nanoseconds of CPU time real.
uint64_t time_proc(); ///< Nanoseconds of CPU time for process.
uint64_t time_thrd(); ///< Nanoseconds of CPU time for thread.
system &hotsample(system &) noexcept;
system &operator+=(system &a, const system &b);
system &operator-=(system &a, const system &b);
system operator+(const system &a, const system &b);
system operator-(const system &a, const system &b);
resource &operator+=(resource &a, const resource &b);
resource &operator-=(resource &a, const resource &b);
resource operator+(const resource &a, const resource &b);
resource operator-(const resource &a, const resource &b);
using read_closure = std::function<void (const type &, const uint64_t &val)>;
void for_each(const const_buffer &read, const read_closure &);
// Control
void stop(group &);
void start(group &);
void reset(group &);
}
/// X86 platform related
namespace ircd::prof::x86
{
unsigned long long rdpmc(const uint &);
unsigned long long rdtscp();
unsigned long long rdtsc();
}
/// Callgrind hypercall suite
namespace ircd::prof::vg
{
struct enable;
struct disable;
bool enabled();
void dump(const char *const reason = nullptr);
void toggle();
void reset();
void start() noexcept;
void stop() noexcept;
}
// Exports to ircd::
namespace ircd
{
using prof::cycles;
}
/// Enable callgrind profiling for the scope
struct ircd::prof::vg::enable
{
enable() noexcept;
~enable() noexcept;
};
/// Disable any enabled callgrind profiling for the scope; then restore.
struct ircd::prof::vg::disable
{
disable() noexcept;
~disable() noexcept;
};
/// Gadget for hardware profiling of instructions for a scope.
///
struct ircd::prof::instructions
{
prof::group group;
uint64_t retired {0};
public:
const uint64_t &at() const;
const uint64_t &sample();
instructions() noexcept;
instructions(instructions &&) = delete;
instructions(const instructions &) = delete;
~instructions() noexcept;
};
/// This suite of devices is intended to figure out when a system call is
/// really slow or "blocking." The original use-case is for io_submit() in
/// fs::aio.
///
/// The sample is conducted with times(2) which is itself a system call
/// though reasonably fast, and the result has poor resolution meaning
/// the result of at() is generally 0 unless the system call was very slow.
///
/// It is started on construction. The user must later call sample()
/// which returns the value of at() as well.
struct ircd::prof::syscall_timer
{
struct high_resolution;
uint64_t started, stopped;
public:
uint64_t at() const;
uint64_t sample();
syscall_timer() noexcept;
};
/// This is a higher resolution alternative. The sample may be conducted
/// with getrusage() or perf events; the exact method is TBD and may be
/// expensive/intrusive. This device should be used temporarily by developers
/// and not left in place in committed code.
struct ircd::prof::syscall_timer::high_resolution
{
uint64_t started, stopped;
public:
uint64_t at() const;
uint64_t sample();
high_resolution() noexcept;
};
/// Frontend to times(2). This has low resolution in practice, but it's
/// very cheap as far as syscalls go; x-platform implementation courtesy
/// of boost::chrono.
struct ircd::prof::times
{
uint64_t real {0};
uint64_t kern {0};
uint64_t user {0};
times(sample_t);
times() = default;
};
/// Frontend to getrusage(2). This has higher resolution than prof::times
/// in practice with slight added expense.
struct ircd::prof::resource
:std::array<uint64_t, 9>
{
enum
{
TIME_USER, // microseconds
TIME_KERN, // microseconds
RSS_MAX,
PF_MINOR,
PF_MAJOR,
BLOCK_IN,
BLOCK_OUT,
SCHED_YIELD,
SCHED_PREEMPT,
};
resource(sample_t);
resource()
:std::array<uint64_t, 9>{{0}}
{}
};
/// Frontend to perf_event_open(2). This has the highest resolution.
struct ircd::prof::system
:std::array<std::array<uint64_t, 2>, 7>
{
using array_type = std::array<std::array<uint64_t, 2>, 7>;
static prof::group group;
// [N][0] = KERNEL, [N][1] = USER
//
// 0: TIME_PROF,
// 1: TIME_CPU,
// 2: TIME_TASK,
// 3: PF_MINOR,
// 4: PF_MAJOR,
// 5: SWITCH_TASK,
// 6: SWITCH_CPU,
system(sample_t) noexcept;
system()
:array_type{{0}}
{}
};
/// Type descriptor for prof events. This structure is used to aggregate
/// information that describes a profiling event type, including whether
/// the kernel or the user is being profiled (dpl), the principal counter
/// type being profiled (counter) and any other contextual attributes.
struct ircd::prof::type
{
enum dpl dpl {0};
uint8_t type_id {0};
uint8_t counter {0};
uint8_t cacheop {0};
uint8_t cacheres {0};
type(const event &);
type(const enum dpl & = (enum dpl)0,
const uint8_t &attr_type = 0,
const uint8_t &counter = 0,
const uint8_t &cacheop = 0,
const uint8_t &cacheres = 0);
};
enum ircd::prof::dpl
:std::underlying_type<ircd::prof::dpl>::type
{
KERNEL = 0,
USER = 1,
};
struct ircd::prof::init
{
init();
~init() noexcept;
};
#if defined(__x86_64__) || defined(__i386__)
inline uint64_t
__attribute__((flatten, always_inline, gnu_inline, artificial))
ircd::prof::cycles()
{
return x86::rdtsc();
}
#else
ircd::prof::cycles()
{
static_assert(false, "Select reference cycle counter for platform.");
return 0;
}
#endif
#if defined(__x86_64__) || defined(__i386__)
inline unsigned long long
__attribute__((always_inline, gnu_inline, artificial))
ircd::prof::x86::rdtsc()
{
return __builtin_ia32_rdtsc();
}
#else
inline unsigned long long
ircd::prof::x86::rdtsc()
{
return 0;
}
#endif
#if defined(__x86_64__) || defined(__i386__)
inline unsigned long long
__attribute__((always_inline, gnu_inline, artificial))
ircd::prof::x86::rdtscp()
{
uint32_t ia32_tsc_aux;
return __builtin_ia32_rdtscp(&ia32_tsc_aux);
}
#else
inline unsigned long long
ircd::prof::x86::rdtscp()
{
return 0;
}
#endif
#if defined(__x86_64__) || defined(__i386__)
inline unsigned long long
__attribute__((always_inline, gnu_inline, artificial))
ircd::prof::x86::rdpmc(const uint &c)
{
return __builtin_ia32_rdpmc(c);
}
#else
inline unsigned long long
ircd::prof::x86::rdpmc(const uint &c)
{
return 0;
}
#endif