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// Copyright 2019 The Abseil Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "absl/strings/internal/cordz_info.h"
#include "absl/base/config.h"
#include "absl/base/internal/spinlock.h"
#include "absl/container/inlined_vector.h"
#include "absl/debugging/stacktrace.h"
#include "absl/strings/internal/cord_internal.h"
#include "absl/strings/internal/cord_rep_btree.h"
#include "absl/strings/internal/cord_rep_ring.h"
#include "absl/strings/internal/cordz_handle.h"
#include "absl/strings/internal/cordz_statistics.h"
#include "absl/strings/internal/cordz_update_tracker.h"
#include "absl/synchronization/mutex.h"
#include "absl/types/span.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace cord_internal {
using ::absl::base_internal::SpinLockHolder;
constexpr int CordzInfo::kMaxStackDepth;
ABSL_CONST_INIT CordzInfo::List CordzInfo::global_list_{absl::kConstInit};
namespace {
// CordRepAnalyzer performs the analysis of a cord.
//
// It computes absolute node counts and total memory usage, and an 'estimated
// fair share memory usage` statistic.
// Conceptually, it divides the 'memory usage' at each location in the 'cord
// graph' by the cumulative reference count of that location. The cumulative
// reference count is the factored total of all edges leading into that node.
//
// The top level node is treated specially: we assume the current thread
// (typically called from the CordzHandler) to hold a reference purely to
// perform a safe analysis, and not being part of the application. So we
// substract 1 from the reference count of the top node to compute the
// 'application fair share' excluding the reference of the current thread.
//
// An example of fair sharing, and why we multiply reference counts:
// Assume we have 2 CordReps, both being a Substring referencing a Flat:
// CordSubstring A (refcount = 5) --> child Flat C (refcount = 2)
// CordSubstring B (refcount = 9) --> child Flat C (refcount = 2)
//
// Flat C has 2 incoming edges from the 2 substrings (refcount = 2) and is not
// referenced directly anywhere else. Translated into a 'fair share', we then
// attribute 50% of the memory (memory / refcount = 2) to each incoming edge.
// Rep A has a refcount of 5, so we attribute each incoming edge 1 / 5th of the
// memory cost below it, i.e.: the fair share of Rep A of the memory used by C
// is then 'memory C / (refcount C * refcount A) + (memory A / refcount A)'.
// It is also easy to see how all incoming edges add up to 100%.
class CordRepAnalyzer {
public:
// Creates an analyzer instance binding to `statistics`.
explicit CordRepAnalyzer(CordzStatistics& statistics)
: statistics_(statistics) {}
// Analyzes the memory statistics and node counts for the provided `rep`, and
// adds the results to `statistics`. Note that node counts and memory sizes
// are not initialized, computed values are added to any existing values.
void AnalyzeCordRep(const CordRep* rep) {
// Process all linear nodes.
// As per the class comments, use refcout - 1 on the top level node, as the
// top level node is assumed to be referenced only for analysis purposes.
size_t refcount = rep->refcount.Get();
RepRef repref{rep, (refcount > 1) ? refcount - 1 : 1};
// Process all top level linear nodes (substrings and flats).
repref = CountLinearReps(repref, memory_usage_);
if (repref.rep != nullptr) {
if (repref.rep->tag == RING) {
AnalyzeRing(repref);
} else if (repref.rep->tag == BTREE) {
AnalyzeBtree(repref);
} else if (repref.rep->tag == CONCAT) {
AnalyzeConcat(repref);
} else {
// We should have either a concat, btree, or ring node if not null.
assert(false);
}
}
// Adds values to output
statistics_.estimated_memory_usage += memory_usage_.total;
statistics_.estimated_fair_share_memory_usage +=
static_cast<size_t>(memory_usage_.fair_share);
}
private:
// RepRef identifies a CordRep* inside the Cord tree with its cumulative
// refcount including itself. For example, a tree consisting of a substring
// with a refcount of 3 and a child flat with a refcount of 4 will have RepRef
// refcounts of 3 and 12 respectively.
struct RepRef {
const CordRep* rep;
size_t refcount;
// Returns a 'child' RepRef which contains the cumulative reference count of
// this instance multiplied by the child's reference count.
RepRef Child(const CordRep* child) const {
return RepRef{child, refcount * child->refcount.Get()};
}
};
// Memory usage values
struct MemoryUsage {
size_t total = 0;
double fair_share = 0.0;
// Adds 'size` memory usage to this class, with a cumulative (recursive)
// reference count of `refcount`
void Add(size_t size, size_t refcount) {
total += size;
fair_share += static_cast<double>(size) / refcount;
}
};
// Returns `rr` if `rr.rep` is not null and a CONCAT type.
// Asserts that `rr.rep` is a concat node or null.
static RepRef AssertConcat(RepRef repref) {
const CordRep* rep = repref.rep;
assert(rep == nullptr || rep->tag == CONCAT);
return (rep != nullptr && rep->tag == CONCAT) ? repref : RepRef{nullptr, 0};
}
// Counts a flat of the provide allocated size
void CountFlat(size_t size) {
statistics_.node_count++;
statistics_.node_counts.flat++;
if (size <= 64) {
statistics_.node_counts.flat_64++;
} else if (size <= 128) {
statistics_.node_counts.flat_128++;
} else if (size <= 256) {
statistics_.node_counts.flat_256++;
} else if (size <= 512) {
statistics_.node_counts.flat_512++;
} else if (size <= 1024) {
statistics_.node_counts.flat_1k++;
}
}
// Processes 'linear' reps (substring, flat, external) not requiring iteration
// or recursion. Returns RefRep{null} if all reps were processed, else returns
// the top-most non-linear concat or ring cordrep.
// Node counts are updated into `statistics_`, memory usage is update into
// `memory_usage`, which typically references `memory_usage_` except for ring
// buffers where we count children unrounded.
RepRef CountLinearReps(RepRef rep, MemoryUsage& memory_usage) {
// Consume all substrings
while (rep.rep->tag == SUBSTRING) {
statistics_.node_count++;
statistics_.node_counts.substring++;
memory_usage.Add(sizeof(CordRepSubstring), rep.refcount);
rep = rep.Child(rep.rep->substring()->child);
}
// Consume possible FLAT
if (rep.rep->tag >= FLAT) {
size_t size = rep.rep->flat()->AllocatedSize();
CountFlat(size);
memory_usage.Add(size, rep.refcount);
return RepRef{nullptr, 0};
}
// Consume possible external
if (rep.rep->tag == EXTERNAL) {
statistics_.node_count++;
statistics_.node_counts.external++;
size_t size = rep.rep->length + sizeof(CordRepExternalImpl<intptr_t>);
memory_usage.Add(size, rep.refcount);
return RepRef{nullptr, 0};
}
return rep;
}
// Analyzes the provided concat node in a flattened recursive way.
void AnalyzeConcat(RepRef rep) {
absl::InlinedVector<RepRef, 47> pending;
while (rep.rep != nullptr) {
const CordRepConcat* concat = rep.rep->concat();
RepRef left = rep.Child(concat->left);
RepRef right = rep.Child(concat->right);
statistics_.node_count++;
statistics_.node_counts.concat++;
memory_usage_.Add(sizeof(CordRepConcat), rep.refcount);
right = AssertConcat(CountLinearReps(right, memory_usage_));
rep = AssertConcat(CountLinearReps(left, memory_usage_));
if (rep.rep != nullptr) {
if (right.rep != nullptr) {
pending.push_back(right);
}
} else if (right.rep != nullptr) {
rep = right;
} else if (!pending.empty()) {
rep = pending.back();
pending.pop_back();
}
}
}
// Analyzes the provided ring.
void AnalyzeRing(RepRef rep) {
statistics_.node_count++;
statistics_.node_counts.ring++;
const CordRepRing* ring = rep.rep->ring();
memory_usage_.Add(CordRepRing::AllocSize(ring->capacity()), rep.refcount);
ring->ForEach([&](CordRepRing::index_type pos) {
CountLinearReps(rep.Child(ring->entry_child(pos)), memory_usage_);
});
}
// Analyzes the provided btree.
void AnalyzeBtree(RepRef rep) {
statistics_.node_count++;
statistics_.node_counts.btree++;
memory_usage_.Add(sizeof(CordRepBtree), rep.refcount);
const CordRepBtree* tree = rep.rep->btree();
if (tree->height() > 0) {
for (CordRep* edge : tree->Edges()) {
AnalyzeBtree(rep.Child(edge));
}
} else {
for (CordRep* edge : tree->Edges()) {
CountLinearReps(rep.Child(edge), memory_usage_);
}
}
}
CordzStatistics& statistics_;
MemoryUsage memory_usage_;
};
} // namespace
CordzInfo* CordzInfo::Head(const CordzSnapshot& snapshot) {
ABSL_ASSERT(snapshot.is_snapshot());
// We can do an 'unsafe' load of 'head', as we are guaranteed that the
// instance it points to is kept alive by the provided CordzSnapshot, so we
// can simply return the current value using an acquire load.
// We do enforce in DEBUG builds that the 'head' value is present in the
// delete queue: ODR violations may lead to 'snapshot' and 'global_list_'
// being in different libraries / modules.
CordzInfo* head = global_list_.head.load(std::memory_order_acquire);
ABSL_ASSERT(snapshot.DiagnosticsHandleIsSafeToInspect(head));
return head;
}
CordzInfo* CordzInfo::Next(const CordzSnapshot& snapshot) const {
ABSL_ASSERT(snapshot.is_snapshot());
// Similar to the 'Head()' function, we do not need a mutex here.
CordzInfo* next = ci_next_.load(std::memory_order_acquire);
ABSL_ASSERT(snapshot.DiagnosticsHandleIsSafeToInspect(this));
ABSL_ASSERT(snapshot.DiagnosticsHandleIsSafeToInspect(next));
return next;
}
void CordzInfo::TrackCord(InlineData& cord, MethodIdentifier method) {
assert(cord.is_tree());
assert(!cord.is_profiled());
CordzInfo* cordz_info = new CordzInfo(cord.as_tree(), nullptr, method);
cord.set_cordz_info(cordz_info);
cordz_info->Track();
}
void CordzInfo::TrackCord(InlineData& cord, const InlineData& src,
MethodIdentifier method) {
assert(cord.is_tree());
assert(src.is_tree());
// Unsample current as we the current cord is being replaced with 'src',
// so any method history is no longer relevant.
CordzInfo* cordz_info = cord.cordz_info();
if (cordz_info != nullptr) cordz_info->Untrack();
// Start new cord sample
cordz_info = new CordzInfo(cord.as_tree(), src.cordz_info(), method);
cord.set_cordz_info(cordz_info);
cordz_info->Track();
}
void CordzInfo::MaybeTrackCordImpl(InlineData& cord, const InlineData& src,
MethodIdentifier method) {
if (src.is_profiled()) {
TrackCord(cord, src, method);
} else if (cord.is_profiled()) {
cord.cordz_info()->Untrack();
cord.clear_cordz_info();
}
}
CordzInfo::MethodIdentifier CordzInfo::GetParentMethod(const CordzInfo* src) {
if (src == nullptr) return MethodIdentifier::kUnknown;
return src->parent_method_ != MethodIdentifier::kUnknown ? src->parent_method_
: src->method_;
}
int CordzInfo::FillParentStack(const CordzInfo* src, void** stack) {
assert(stack);
if (src == nullptr) return 0;
if (src->parent_stack_depth_) {
memcpy(stack, src->parent_stack_, src->parent_stack_depth_ * sizeof(void*));
return src->parent_stack_depth_;
}
memcpy(stack, src->stack_, src->stack_depth_ * sizeof(void*));
return src->stack_depth_;
}
CordzInfo::CordzInfo(CordRep* rep, const CordzInfo* src,
MethodIdentifier method)
: rep_(rep),
stack_depth_(absl::GetStackTrace(stack_, /*max_depth=*/kMaxStackDepth,
/*skip_count=*/1)),
parent_stack_depth_(FillParentStack(src, parent_stack_)),
method_(method),
parent_method_(GetParentMethod(src)),
create_time_(absl::Now()) {
update_tracker_.LossyAdd(method);
if (src) {
// Copy parent counters.
update_tracker_.LossyAdd(src->update_tracker_);
}
}
CordzInfo::~CordzInfo() {
// `rep_` is potentially kept alive if CordzInfo is included
// in a collection snapshot (which should be rare).
if (ABSL_PREDICT_FALSE(rep_)) {
CordRep::Unref(rep_);
}
}
void CordzInfo::Track() {
SpinLockHolder l(&list_->mutex);
CordzInfo* const head = list_->head.load(std::memory_order_acquire);
if (head != nullptr) {
head->ci_prev_.store(this, std::memory_order_release);
}
ci_next_.store(head, std::memory_order_release);
list_->head.store(this, std::memory_order_release);
}
void CordzInfo::Untrack() {
ODRCheck();
{
SpinLockHolder l(&list_->mutex);
CordzInfo* const head = list_->head.load(std::memory_order_acquire);
CordzInfo* const next = ci_next_.load(std::memory_order_acquire);
CordzInfo* const prev = ci_prev_.load(std::memory_order_acquire);
if (next) {
ABSL_ASSERT(next->ci_prev_.load(std::memory_order_acquire) == this);
next->ci_prev_.store(prev, std::memory_order_release);
}
if (prev) {
ABSL_ASSERT(head != this);
ABSL_ASSERT(prev->ci_next_.load(std::memory_order_acquire) == this);
prev->ci_next_.store(next, std::memory_order_release);
} else {
ABSL_ASSERT(head == this);
list_->head.store(next, std::memory_order_release);
}
}
// We can no longer be discovered: perform a fast path check if we are not
// listed on any delete queue, so we can directly delete this instance.
if (SafeToDelete()) {
UnsafeSetCordRep(nullptr);
delete this;
return;
}
// We are likely part of a snapshot, extend the life of the CordRep
{
absl::MutexLock lock(&mutex_);
if (rep_) CordRep::Ref(rep_);
}
CordzHandle::Delete(this);
}
void CordzInfo::Lock(MethodIdentifier method)
ABSL_EXCLUSIVE_LOCK_FUNCTION(mutex_) {
mutex_.Lock();
update_tracker_.LossyAdd(method);
assert(rep_);
}
void CordzInfo::Unlock() ABSL_UNLOCK_FUNCTION(mutex_) {
bool tracked = rep_ != nullptr;
mutex_.Unlock();
if (!tracked) {
Untrack();
}
}
absl::Span<void* const> CordzInfo::GetStack() const {
return absl::MakeConstSpan(stack_, stack_depth_);
}
absl::Span<void* const> CordzInfo::GetParentStack() const {
return absl::MakeConstSpan(parent_stack_, parent_stack_depth_);
}
CordzStatistics CordzInfo::GetCordzStatistics() const {
CordzStatistics stats;
stats.method = method_;
stats.parent_method = parent_method_;
stats.update_tracker = update_tracker_;
if (CordRep* rep = RefCordRep()) {
stats.size = rep->length;
CordRepAnalyzer analyzer(stats);
analyzer.AnalyzeCordRep(rep);
CordRep::Unref(rep);
}
return stats;
}
} // namespace cord_internal
ABSL_NAMESPACE_END
} // namespace absl
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