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#ifndef SRC_MEMORY_TRACKER_INL_H_
#define SRC_MEMORY_TRACKER_INL_H_
#if defined(NODE_WANT_INTERNALS) && NODE_WANT_INTERNALS
#include "memory_tracker.h"
namespace node {
// Fallback edge_name if node_name is not available, or "" if edge_name
// is not available either.
inline const char* GetNodeName(const char* node_name, const char* edge_name) {
if (node_name != nullptr) {
return node_name;
}
if (edge_name != nullptr) {
return edge_name;
}
return "";
}
class MemoryRetainerNode : public v8::EmbedderGraph::Node {
public:
inline MemoryRetainerNode(MemoryTracker* tracker,
const MemoryRetainer* retainer)
: retainer_(retainer) {
CHECK_NOT_NULL(retainer_);
v8::HandleScope handle_scope(tracker->isolate());
v8::Local<v8::Object> obj = retainer_->WrappedObject();
if (!obj.IsEmpty()) wrapper_node_ = tracker->graph()->V8Node(obj);
name_ = retainer_->MemoryInfoName();
size_ = retainer_->SelfSize();
}
inline MemoryRetainerNode(MemoryTracker* tracker,
const char* name,
size_t size,
bool is_root_node = false)
: retainer_(nullptr) {
name_ = name;
size_ = size;
is_root_node_ = is_root_node;
}
const char* Name() override { return name_.c_str(); }
const char* NamePrefix() override { return "Node /"; }
size_t SizeInBytes() override { return size_; }
// TODO(addaleax): Merging this with the "official" WrapperNode() method
// seems to lose accuracy, e.g. SizeInBytes() is disregarded.
// Figure out whether to do anything about that.
Node* JSWrapperNode() { return wrapper_node_; }
bool IsRootNode() override {
if (retainer_ != nullptr) {
return retainer_->IsRootNode();
}
return is_root_node_;
}
private:
friend class MemoryTracker;
// If retainer_ is not nullptr, then it must have a wrapper_node_,
// and we have
// name_ == retainer_->MemoryInfoName()
// size_ == retainer_->SelfSize()
// is_root_node_ == retainer_->IsRootNode()
const MemoryRetainer* retainer_;
Node* wrapper_node_ = nullptr;
// Otherwise (retainer == nullptr), we set these fields in an ad-hoc way
bool is_root_node_ = false;
std::string name_;
size_t size_ = 0;
};
void MemoryTracker::TrackFieldWithSize(const char* edge_name,
size_t size,
const char* node_name) {
if (size > 0) AddNode(GetNodeName(node_name, edge_name), size, edge_name);
}
void MemoryTracker::TrackField(const char* edge_name,
const MemoryRetainer& value,
const char* node_name) {
TrackField(edge_name, &value);
}
void MemoryTracker::TrackField(const char* edge_name,
const MemoryRetainer* value,
const char* node_name) {
if (value == nullptr) return;
auto it = seen_.find(value);
if (it != seen_.end()) {
graph_->AddEdge(CurrentNode(), it->second, edge_name);
} else {
Track(value, edge_name);
}
}
template <typename T>
void MemoryTracker::TrackField(const char* edge_name,
const std::unique_ptr<T>& value,
const char* node_name) {
if (value.get() == nullptr) {
return;
}
TrackField(edge_name, value.get(), node_name);
}
template <typename T, typename Iterator>
void MemoryTracker::TrackField(const char* edge_name,
const T& value,
const char* node_name,
const char* element_name,
bool subtract_from_self) {
// If the container is empty, the size has been accounted into the parent's
// self size
if (value.begin() == value.end()) return;
// Fall back to edge name if node names are not provided
if (CurrentNode() != nullptr && subtract_from_self) {
// Shift the self size of this container out to a separate node
CurrentNode()->size_ -= sizeof(T);
}
PushNode(GetNodeName(node_name, edge_name), sizeof(T), edge_name);
for (Iterator it = value.begin(); it != value.end(); ++it) {
// Use nullptr as edge names so the elements appear as indexed properties
TrackField(nullptr, *it, element_name);
}
PopNode();
}
template <typename T>
void MemoryTracker::TrackField(const char* edge_name,
const std::queue<T>& value,
const char* node_name,
const char* element_name) {
struct ContainerGetter : public std::queue<T> {
static const typename std::queue<T>::container_type& Get(
const std::queue<T>& value) {
return value.*&ContainerGetter::c;
}
};
const auto& container = ContainerGetter::Get(value);
TrackField(edge_name, container, node_name, element_name);
}
template <typename T, typename test_for_number, typename dummy>
void MemoryTracker::TrackField(const char* edge_name,
const T& value,
const char* node_name) {
// For numbers, creating new nodes is not worth the overhead.
CurrentNode()->size_ += sizeof(T);
}
template <typename T, typename U>
void MemoryTracker::TrackField(const char* edge_name,
const std::pair<T, U>& value,
const char* node_name) {
PushNode(node_name == nullptr ? "pair" : node_name,
sizeof(const std::pair<T, U>),
edge_name);
// TODO(joyeecheung): special case if one of these is a number type
// that meets the test_for_number trait so that their sizes don't get
// merged into the pair node
TrackField("first", value.first);
TrackField("second", value.second);
PopNode();
}
template <typename T>
void MemoryTracker::TrackField(const char* edge_name,
const std::basic_string<T>& value,
const char* node_name) {
TrackFieldWithSize(edge_name, value.size() * sizeof(T), "std::basic_string");
}
template <typename T, typename Traits>
void MemoryTracker::TrackField(const char* edge_name,
const v8::Persistent<T, Traits>& value,
const char* node_name) {
TrackField(edge_name, value.Get(isolate_));
}
template <typename T>
void MemoryTracker::TrackField(const char* edge_name,
const v8::Local<T>& value,
const char* node_name) {
if (!value.IsEmpty())
graph_->AddEdge(CurrentNode(), graph_->V8Node(value), edge_name);
}
template <typename T>
void MemoryTracker::TrackField(const char* edge_name,
const MallocedBuffer<T>& value,
const char* node_name) {
TrackFieldWithSize(edge_name, value.size, "MallocedBuffer");
}
void MemoryTracker::TrackField(const char* name,
const uv_buf_t& value,
const char* node_name) {
TrackFieldWithSize(name, value.len, "uv_buf_t");
}
void MemoryTracker::TrackField(const char* name,
const uv_timer_t& value,
const char* node_name) {
TrackFieldWithSize(name, sizeof(value), "uv_timer_t");
}
void MemoryTracker::TrackField(const char* name,
const uv_async_t& value,
const char* node_name) {
TrackFieldWithSize(name, sizeof(value), "uv_async_t");
}
template <class NativeT, class V8T>
void MemoryTracker::TrackField(const char* name,
const AliasedBuffer<NativeT, V8T>& value,
const char* node_name) {
TrackField(name, value.GetJSArray(), "AliasedBuffer");
}
void MemoryTracker::Track(const MemoryRetainer* retainer,
const char* edge_name) {
v8::HandleScope handle_scope(isolate_);
auto it = seen_.find(retainer);
if (it != seen_.end()) {
if (CurrentNode() != nullptr) {
graph_->AddEdge(CurrentNode(), it->second, edge_name);
}
return; // It has already been tracked, no need to call MemoryInfo again
}
MemoryRetainerNode* n = PushNode(retainer, edge_name);
retainer->MemoryInfo(this);
CHECK_EQ(CurrentNode(), n);
CHECK_NE(n->size_, 0);
PopNode();
}
MemoryRetainerNode* MemoryTracker::CurrentNode() const {
if (node_stack_.empty()) return nullptr;
return node_stack_.top();
}
MemoryRetainerNode* MemoryTracker::AddNode(const MemoryRetainer* retainer,
const char* edge_name) {
auto it = seen_.find(retainer);
if (it != seen_.end()) {
return it->second;
}
MemoryRetainerNode* n = new MemoryRetainerNode(this, retainer);
graph_->AddNode(std::unique_ptr<v8::EmbedderGraph::Node>(n));
seen_[retainer] = n;
if (CurrentNode() != nullptr) graph_->AddEdge(CurrentNode(), n, edge_name);
if (n->JSWrapperNode() != nullptr) {
graph_->AddEdge(n, n->JSWrapperNode(), "wrapped");
graph_->AddEdge(n->JSWrapperNode(), n, "wrapper");
}
return n;
}
MemoryRetainerNode* MemoryTracker::AddNode(const char* node_name,
size_t size,
const char* edge_name) {
MemoryRetainerNode* n = new MemoryRetainerNode(this, node_name, size);
graph_->AddNode(std::unique_ptr<v8::EmbedderGraph::Node>(n));
if (CurrentNode() != nullptr) graph_->AddEdge(CurrentNode(), n, edge_name);
return n;
}
MemoryRetainerNode* MemoryTracker::PushNode(const MemoryRetainer* retainer,
const char* edge_name) {
MemoryRetainerNode* n = AddNode(retainer, edge_name);
node_stack_.push(n);
return n;
}
MemoryRetainerNode* MemoryTracker::PushNode(const char* node_name,
size_t size,
const char* edge_name) {
MemoryRetainerNode* n = AddNode(node_name, size, edge_name);
node_stack_.push(n);
return n;
}
void MemoryTracker::PopNode() {
node_stack_.pop();
}
} // namespace node
#endif // defined(NODE_WANT_INTERNALS) && NODE_WANT_INTERNALS
#endif // SRC_MEMORY_TRACKER_INL_H_
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