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kvthread.hh
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kvthread.hh
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/* Masstree
* Eddie Kohler, Yandong Mao, Robert Morris
* Copyright (c) 2012-2016 President and Fellows of Harvard College
* Copyright (c) 2012-2016 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.
*/
#ifndef KVTHREAD_HH
#define KVTHREAD_HH 1
#include "mtcounters.hh"
#include "compiler.hh"
#include "circular_int.hh"
#include "timestamp.hh"
#include "memdebug.hh"
#include <assert.h>
#include <pthread.h>
#include <sys/mman.h>
#include <stdlib.h>
class threadinfo;
class loginfo;
typedef uint64_t mrcu_epoch_type;
typedef int64_t mrcu_signed_epoch_type;
extern relaxed_atomic<mrcu_epoch_type> globalepoch; // global epoch, updated regularly
extern relaxed_atomic<mrcu_epoch_type> active_epoch;
struct limbo_group {
typedef mrcu_epoch_type epoch_type;
typedef mrcu_signed_epoch_type signed_epoch_type;
struct limbo_element {
void* ptr_;
union {
memtag tag;
epoch_type epoch;
} u_;
};
enum { capacity = (4076 - sizeof(epoch_type) - sizeof(limbo_group*)) / sizeof(limbo_element) };
unsigned head_;
unsigned tail_;
epoch_type epoch_;
limbo_group* next_;
limbo_element e_[capacity];
limbo_group()
: head_(0), tail_(0), next_() {
}
epoch_type first_epoch() const {
assert(head_ != tail_);
return e_[head_].u_.epoch;
}
void push_back(void* ptr, memtag tag, mrcu_epoch_type epoch) {
assert(tail_ + 2 <= capacity);
if (head_ == tail_ || epoch_ != epoch) {
e_[tail_].ptr_ = nullptr;
e_[tail_].u_.epoch = epoch;
epoch_ = epoch;
++tail_;
}
e_[tail_].ptr_ = ptr;
e_[tail_].u_.tag = tag;
++tail_;
}
inline unsigned clean_until(threadinfo& ti, mrcu_epoch_type epoch_bound, unsigned count);
};
template <int N> struct has_threadcounter {
static bool test(threadcounter ci) {
return unsigned(ci) < unsigned(N);
}
};
template <> struct has_threadcounter<0> {
static bool test(threadcounter) {
return false;
}
};
struct mrcu_callback {
virtual ~mrcu_callback() {
}
virtual void operator()(threadinfo& ti) = 0;
};
class threadinfo {
public:
enum {
TI_MAIN, TI_PROCESS, TI_LOG, TI_CHECKPOINT
};
static threadinfo* allthreads;
threadinfo* next() const {
return next_;
}
static threadinfo* make(int purpose, int index);
// XXX destructor
// thread information
int purpose() const {
return purpose_;
}
int index() const {
return index_;
}
loginfo* logger() const {
return logger_;
}
void set_logger(loginfo* logger) {
assert(!logger_ && logger);
logger_ = logger;
}
// timestamps
kvtimestamp_t operation_timestamp() const {
return timestamp();
}
kvtimestamp_t update_timestamp() const {
return ts_;
}
kvtimestamp_t update_timestamp(kvtimestamp_t x) const {
if (circular_int<kvtimestamp_t>::less_equal(ts_, x))
// x might be a marker timestamp; ensure result is not
ts_ = (x | 1) + 1;
return ts_;
}
template <typename N> void observe_phantoms(N* n) {
if (circular_int<kvtimestamp_t>::less(ts_, n->phantom_epoch_[0]))
ts_ = n->phantom_epoch_[0];
}
// event counters
void mark(threadcounter ci) {
if (has_threadcounter<int(ncounters)>::test(ci))
++counters_[ci];
}
void mark(threadcounter ci, int64_t delta) {
if (has_threadcounter<int(ncounters)>::test(ci))
counters_[ci] += delta;
}
void set_counter(threadcounter ci, uint64_t value) {
if (has_threadcounter<int(ncounters)>::test(ci))
counters_[ci] = value;
}
bool has_counter(threadcounter ci) const {
return has_threadcounter<int(ncounters)>::test(ci);
}
uint64_t counter(threadcounter ci) const {
return has_threadcounter<int(ncounters)>::test(ci) ? counters_[ci] : 0;
}
struct accounting_relax_fence_function {
threadinfo* ti_;
threadcounter ci_;
accounting_relax_fence_function(threadinfo* ti, threadcounter ci)
: ti_(ti), ci_(ci) {
}
void operator()() {
relax_fence();
ti_->mark(ci_);
}
};
/** @brief Return a function object that calls mark(ci); relax_fence().
*
* This function object can be used to count the number of relax_fence()s
* executed. */
accounting_relax_fence_function accounting_relax_fence(threadcounter ci) {
return accounting_relax_fence_function(this, ci);
}
struct stable_accounting_relax_fence_function {
threadinfo* ti_;
stable_accounting_relax_fence_function(threadinfo* ti)
: ti_(ti) {
}
template <typename V>
void operator()(V v) {
relax_fence();
ti_->mark(threadcounter(tc_stable + (v.isleaf() << 1) + v.splitting()));
}
};
/** @brief Return a function object that calls mark(ci); relax_fence().
*
* This function object can be used to count the number of relax_fence()s
* executed. */
stable_accounting_relax_fence_function stable_fence() {
return stable_accounting_relax_fence_function(this);
}
accounting_relax_fence_function lock_fence(threadcounter ci) {
return accounting_relax_fence_function(this, ci);
}
// memory allocation
void* allocate(size_t sz, memtag tag) {
void* p = malloc(sz + memdebug_size);
p = memdebug::make(p, sz, tag);
if (p)
mark(threadcounter(tc_alloc + (tag > memtag_value)), sz);
return p;
}
void deallocate(void* p, size_t sz, memtag tag) {
// in C++ allocators, 'p' must be nonnull
assert(p);
p = memdebug::check_free(p, sz, tag);
free(p);
mark(threadcounter(tc_alloc + (tag > memtag_value)), -sz);
}
void deallocate_rcu(void* p, size_t sz, memtag tag) {
assert(p);
memdebug::check_rcu(p, sz, tag);
record_rcu(p, tag);
mark(threadcounter(tc_alloc + (tag > memtag_value)), -sz);
}
void* pool_allocate(size_t sz, memtag tag) {
int nl = (sz + memdebug_size + CACHE_LINE_SIZE - 1) / CACHE_LINE_SIZE;
assert(nl <= pool_max_nlines);
if (unlikely(!pool_[nl - 1]))
refill_pool(nl);
void* p = pool_[nl - 1];
if (p) {
pool_[nl - 1] = *reinterpret_cast<void **>(p);
p = memdebug::make(p, sz, memtag(tag + nl));
mark(threadcounter(tc_alloc + (tag > memtag_value)),
nl * CACHE_LINE_SIZE);
}
return p;
}
void pool_deallocate(void* p, size_t sz, memtag tag) {
int nl = (sz + memdebug_size + CACHE_LINE_SIZE - 1) / CACHE_LINE_SIZE;
assert(p && nl <= pool_max_nlines);
p = memdebug::check_free(p, sz, memtag(tag + nl));
if (use_pool()) {
*reinterpret_cast<void **>(p) = pool_[nl - 1];
pool_[nl - 1] = p;
} else
free(p);
mark(threadcounter(tc_alloc + (tag > memtag_value)),
-nl * CACHE_LINE_SIZE);
}
void pool_deallocate_rcu(void* p, size_t sz, memtag tag) {
int nl = (sz + memdebug_size + CACHE_LINE_SIZE - 1) / CACHE_LINE_SIZE;
assert(p && nl <= pool_max_nlines);
memdebug::check_rcu(p, sz, memtag(tag + nl));
record_rcu(p, memtag(tag + nl));
mark(threadcounter(tc_alloc + (tag > memtag_value)),
-nl * CACHE_LINE_SIZE);
}
// RCU
enum { rcu_free_count = 128 }; // max # of entries to free per rcu_quiesce() call
void rcu_start() {
auto ge = globalepoch.load();
if (gc_epoch_ != ge)
gc_epoch_ = ge;
}
void rcu_stop() {
if (perform_gc_epoch_ != active_epoch.load())
hard_rcu_quiesce();
gc_epoch_ = 0;
}
void rcu_quiesce() {
rcu_start();
if (perform_gc_epoch_ != active_epoch.load())
hard_rcu_quiesce();
}
typedef ::mrcu_callback mrcu_callback;
void rcu_register(mrcu_callback* cb) {
record_rcu(cb, memtag(-1));
}
// thread management
pthread_t& pthread() {
return pthreadid_;
}
pthread_t pthread() const {
return pthreadid_;
}
void report_rcu(void* ptr) const;
static void report_rcu_all(void* ptr);
static inline mrcu_epoch_type min_active_epoch();
private:
union {
struct {
mrcu_epoch_type gc_epoch_;
mrcu_epoch_type perform_gc_epoch_;
loginfo *logger_;
threadinfo *next_;
int purpose_;
int index_; // the index of a udp, logging, tcp,
// checkpoint or recover thread
pthread_t pthreadid_;
};
char padding1[CACHE_LINE_SIZE];
};
enum { pool_max_nlines = 20 };
void* pool_[pool_max_nlines];
limbo_group* limbo_head_;
limbo_group* limbo_tail_;
mutable kvtimestamp_t ts_;
//enum { ncounters = (int) tc_max };
enum { ncounters = 0 };
uint64_t counters_[ncounters];
void refill_pool(int nl);
void refill_rcu();
void free_rcu(void *p, memtag tag) {
if ((tag & memtag_pool_mask) == 0) {
p = memdebug::check_free_after_rcu(p, tag);
::free(p);
} else if (tag == memtag(-1))
(*static_cast<mrcu_callback*>(p))(*this);
else {
p = memdebug::check_free_after_rcu(p, tag);
int nl = tag & memtag_pool_mask;
*reinterpret_cast<void**>(p) = pool_[nl - 1];
pool_[nl - 1] = p;
}
}
void record_rcu(void* ptr, memtag tag) {
if (limbo_tail_->tail_ + 2 > limbo_tail_->capacity)
refill_rcu();
auto epoch = globalepoch.load();
limbo_tail_->push_back(ptr, tag, epoch);
}
#if ENABLE_ASSERTIONS
static int no_pool_value;
#endif
static bool use_pool() {
#if ENABLE_ASSERTIONS
return !no_pool_value;
#else
return true;
#endif
}
inline threadinfo(int purpose, int index);
threadinfo(const threadinfo&) = delete;
~threadinfo() {}
threadinfo& operator=(const threadinfo&) = delete;
void hard_rcu_quiesce();
friend struct limbo_group;
};
inline mrcu_epoch_type threadinfo::min_active_epoch() {
auto ae = globalepoch.load();
for (threadinfo* ti = allthreads; ti; ti = ti->next()) {
prefetch((const void*) ti->next());
mrcu_epoch_type te = ti->gc_epoch_;
if (te && mrcu_signed_epoch_type(te - ae) < 0)
ae = te;
}
return ae;
}
#endif