Claude-skill-registry cpp-smart-pointers
Use when managing memory safely in C++ with smart pointers including unique_ptr, shared_ptr, weak_ptr, and RAII patterns.
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T=$(mktemp -d) && git clone --depth=1 https://github.com/majiayu000/claude-skill-registry "$T" && mkdir -p ~/.claude/skills && cp -r "$T/skills/data/cpp-smart-pointers" ~/.claude/skills/majiayu000-claude-skill-registry-cpp-smart-pointers && rm -rf "$T"
manifest:
skills/data/cpp-smart-pointers/SKILL.mdsource content
C++ Smart Pointers and RAII
Master C++ smart pointers and Resource Acquisition Is Initialization (RAII) patterns for automatic, exception-safe resource management. This skill covers unique_ptr, shared_ptr, weak_ptr, custom deleters, and best practices for modern C++ memory management.
RAII Principles
Resource Acquisition Is Initialization is a fundamental C++ idiom where resource lifetime is tied to object lifetime.
Core Concept
// Bad: Manual resource management void process_file_bad() { FILE* file = fopen("data.txt", "r"); if (!file) return; // ... process file ... // If exception occurs, file never closed! fclose(file); } // Good: RAII with smart pointer void process_file_good() { auto deleter = [](FILE* f) { if (f) fclose(f); }; std::unique_ptr<FILE, decltype(deleter)> file(fopen("data.txt", "r"), deleter); if (!file) return; // ... process file ... // File automatically closed when unique_ptr destroyed } // Even better: Custom RAII wrapper class FileHandle { FILE* file; public: explicit FileHandle(const char* filename, const char* mode) : file(fopen(filename, mode)) { if (!file) throw std::runtime_error("Failed to open file"); } ~FileHandle() { if (file) fclose(file); } // Delete copy operations FileHandle(const FileHandle&) = delete; FileHandle& operator=(const FileHandle&) = delete; // Allow move operations FileHandle(FileHandle&& other) noexcept : file(other.file) { other.file = nullptr; } FileHandle& operator=(FileHandle&& other) noexcept { if (this != &other) { if (file) fclose(file); file = other.file; other.file = nullptr; } return *this; } FILE* get() const { return file; } };
RAII Benefits
// Exception safety void transaction() { std::lock_guard<std::mutex> lock(mutex); // RAII lock std::unique_ptr<Resource> resource = acquire_resource(); // RAII memory // If exception thrown, lock released and memory freed automatically risky_operation(); } // Automatic cleanup in all paths std::unique_ptr<int[]> create_buffer(size_t size) { auto buffer = std::make_unique<int[]>(size); if (size > max_size) { return nullptr; // buffer cleaned up } initialize(buffer.get(), size); return buffer; // ownership transferred }
Unique Ptr
std::unique_ptrUnique Ptr Basic Usage
#include <memory> // Creating unique_ptr std::unique_ptr<int> ptr1(new int(42)); auto ptr2 = std::make_unique<int>(100); // Preferred (C++14) // Array unique_ptr std::unique_ptr<int[]> arr(new int[10]); auto arr2 = std::make_unique<int[]>(10); // Preferred // Custom types class MyClass { public: MyClass(int x, std::string s) : value(x), name(s) {} void print() const { std::cout << name << ": " << value << std::endl; } private: int value; std::string name; }; auto obj = std::make_unique<MyClass>(42, "Test"); obj->print();
Ownership Transfer
// Unique_ptr is move-only, not copyable std::unique_ptr<int> ptr1 = std::make_unique<int>(42); // std::unique_ptr<int> ptr2 = ptr1; // ERROR: copying deleted // Move ownership std::unique_ptr<int> ptr2 = std::move(ptr1); // ptr1 is now nullptr, ptr2 owns the resource // Function accepting ownership void consume(std::unique_ptr<int> ptr) { std::cout << *ptr << std::endl; // ptr destroyed here, resource deleted } consume(std::move(ptr2)); // Transfer ownership to function // Function returning ownership std::unique_ptr<int> create() { auto ptr = std::make_unique<int>(100); return ptr; // Move semantics, no explicit std::move needed } auto result = create(); // Ownership transferred to result
Custom Deleters
// Function pointer deleter void custom_delete(int* ptr) { std::cout << "Deleting: " << *ptr << std::endl; delete ptr; } std::unique_ptr<int, decltype(&custom_delete)> ptr(new int(42), custom_delete); // Lambda deleter auto deleter = [](int* ptr) { std::cout << "Lambda delete: " << *ptr << std::endl; delete ptr; }; std::unique_ptr<int, decltype(deleter)> ptr2(new int(100), deleter); // FILE* with custom deleter auto file_deleter = [](FILE* f) { if (f) { std::cout << "Closing file" << std::endl; fclose(f); } }; std::unique_ptr<FILE, decltype(file_deleter)> file( fopen("data.txt", "r"), file_deleter ); // Socket with custom deleter struct SocketDeleter { void operator()(int* socket) const { if (socket && *socket >= 0) { close(*socket); delete socket; } } }; std::unique_ptr<int, SocketDeleter> socket(new int(create_socket()));
Unique Ptr Operations
std::unique_ptr<int> ptr = std::make_unique<int>(42); // Access int value = *ptr; // Dereference int* raw = ptr.get(); // Get raw pointer (doesn't transfer ownership) // Check if owns object if (ptr) { std::cout << "Owns resource" << std::endl; } // Release ownership (returns raw pointer, unique_ptr becomes nullptr) int* released = ptr.release(); // Must manually delete released pointer delete released; // Reset (delete current object, optionally take ownership of new one) ptr.reset(); // Delete and become nullptr ptr.reset(new int(100)); // Delete old, own new // Swap std::unique_ptr<int> ptr1 = std::make_unique<int>(1); std::unique_ptr<int> ptr2 = std::make_unique<int>(2); ptr1.swap(ptr2); // or std::swap(ptr1, ptr2);
Shared Ptr
std::shared_ptrShared Ptr Basic Usage
#include <memory> // Creating shared_ptr std::shared_ptr<int> ptr1(new int(42)); auto ptr2 = std::make_shared<int>(100); // Preferred (more efficient) // Shared ownership auto ptr3 = ptr2; // Reference count = 2 auto ptr4 = ptr2; // Reference count = 3 std::cout << "Use count: " << ptr2.use_count() << std::endl; // 3 // Last shared_ptr destroyed deletes the object { auto ptr5 = ptr2; // Reference count = 4 } // ptr5 destroyed, reference count = 3
Make Shared
// Prefer make_shared over new auto ptr1 = std::make_shared<MyClass>(arg1, arg2); // Why? Single allocation instead of two: // new: allocates object + separate control block // make_shared: single allocation for both // Exception safety func(std::shared_ptr<int>(new int(1)), std::shared_ptr<int>(new int(2))); // Risky func(std::make_shared<int>(1), std::make_shared<int>(2)); // Safe // Array support (C++17 and later may vary by implementation) std::shared_ptr<int[]> arr(new int[10]); // Note: make_shared for arrays added in C++20
Shared Ptr Operations
std::shared_ptr<int> ptr1 = std::make_shared<int>(42); std::shared_ptr<int> ptr2 = ptr1; // Access int value = *ptr1; int* raw = ptr1.get(); // Reference counting std::cout << "Count: " << ptr1.use_count() << std::endl; std::cout << "Unique: " << ptr1.unique() << std::endl; // true if count == 1 // Check if owns object if (ptr1) { std::cout << "Owns resource" << std::endl; } // Reset ptr1.reset(); // Decrement ref count, become nullptr ptr1.reset(new int(100)); // Decrement old ref count, own new object ptr1 = nullptr; // Same as reset() // Swap ptr1.swap(ptr2); std::swap(ptr1, ptr2);
Aliasing Constructor
struct Data { int x; int y; }; auto data = std::make_shared<Data>(); data->x = 10; data->y = 20; // Create shared_ptr to member, but shares ownership of whole object std::shared_ptr<int> x_ptr(data, &data->x); std::shared_ptr<int> y_ptr(data, &data->y); // data's reference count is 3 // When data, x_ptr, and y_ptr all destroyed, Data object deleted
Weak Ptr
std::weak_ptrWeak Ptr Basic Usage
std::shared_ptr<int> shared = std::make_shared<int>(42); std::weak_ptr<int> weak = shared; // weak reference, doesn't increase ref count std::cout << "Shared count: " << shared.use_count() << std::endl; // 1 std::cout << "Weak count: " << weak.use_count() << std::endl; // 1 // Check if object still exists if (!weak.expired()) { // Try to get shared_ptr if (auto locked = weak.lock()) { std::cout << "Value: " << *locked << std::endl; // locked is shared_ptr, safe to use } } // After shared destroyed shared.reset(); if (weak.expired()) { std::cout << "Object no longer exists" << std::endl; }
Breaking Circular References
// Problem: Circular reference causes memory leak struct Node { std::shared_ptr<Node> next; ~Node() { std::cout << "Node destroyed" << std::endl; } }; void memory_leak() { auto node1 = std::make_shared<Node>(); auto node2 = std::make_shared<Node>(); node1->next = node2; node2->next = node1; // Circular reference! // node1 and node2 go out of scope but objects never deleted // ref counts never reach zero } // Solution: Use weak_ptr for back references struct NodeFixed { std::shared_ptr<NodeFixed> next; std::weak_ptr<NodeFixed> prev; // Break cycle with weak_ptr ~NodeFixed() { std::cout << "NodeFixed destroyed" << std::endl; } }; void no_leak() { auto node1 = std::make_shared<NodeFixed>(); auto node2 = std::make_shared<NodeFixed>(); node1->next = node2; node2->prev = node1; // weak_ptr doesn't increase ref count // Objects properly deleted when shared_ptrs destroyed }
Observer Pattern
class Subject; class Observer { std::weak_ptr<Subject> subject; public: void observe(std::shared_ptr<Subject> s) { subject = s; } void check() { if (auto s = subject.lock()) { std::cout << "Subject still exists" << std::endl; // Use s safely } else { std::cout << "Subject destroyed" << std::endl; } } }; class Subject { public: void do_something() { std::cout << "Subject doing something" << std::endl; } }; // Usage auto observer = std::make_shared<Observer>(); { auto subject = std::make_shared<Subject>(); observer->observe(subject); observer->check(); // Subject exists } observer->check(); // Subject destroyed
Cache Pattern
class ResourceCache { std::unordered_map<std::string, std::weak_ptr<Resource>> cache; public: std::shared_ptr<Resource> get(const std::string& key) { // Try to get from cache auto it = cache.find(key); if (it != cache.end()) { if (auto resource = it->second.lock()) { return resource; // Cache hit } else { cache.erase(it); // Expired entry } } // Cache miss: load resource auto resource = std::make_shared<Resource>(load_resource(key)); cache[key] = resource; // Store weak reference return resource; } void cleanup() { // Remove expired entries for (auto it = cache.begin(); it != cache.end(); ) { if (it->second.expired()) { it = cache.erase(it); } else { ++it; } } } };
Custom Deleters and Allocators
Advanced Deleter Patterns
// Logging deleter template<typename T> struct LoggingDeleter { void operator()(T* ptr) const { std::cout << "Deleting object at " << ptr << std::endl; delete ptr; } }; std::unique_ptr<int, LoggingDeleter<int>> ptr(new int(42)); // Array deleter for unique_ptr template<typename T> struct ArrayDeleter { void operator()(T* ptr) const { delete[] ptr; } }; std::unique_ptr<int, ArrayDeleter<int>> arr(new int[10]); // Conditional deleter template<typename T> class ConditionalDeleter { bool should_delete; public: explicit ConditionalDeleter(bool del = true) : should_delete(del) {} void operator()(T* ptr) const { if (should_delete) { delete ptr; } } }; // Resource pool deleter template<typename T> class PoolDeleter { std::shared_ptr<ResourcePool<T>> pool; public: explicit PoolDeleter(std::shared_ptr<ResourcePool<T>> p) : pool(p) {} void operator()(T* ptr) const { pool->return_to_pool(ptr); // Return to pool instead of delete } };
Custom Allocators
// Custom allocator for shared_ptr template<typename T> class TrackingAllocator { public: using value_type = T; TrackingAllocator() = default; template<typename U> TrackingAllocator(const TrackingAllocator<U>&) {} T* allocate(std::size_t n) { std::cout << "Allocating " << n << " objects" << std::endl; return static_cast<T*>(::operator new(n * sizeof(T))); } void deallocate(T* ptr, std::size_t n) { std::cout << "Deallocating " << n << " objects" << std::endl; ::operator delete(ptr); } }; // Usage with shared_ptr auto ptr = std::allocate_shared<int>(TrackingAllocator<int>(), 42);
Smart Pointer Conversions
Safe Conversions
// unique_ptr to shared_ptr (ownership transfer) std::unique_ptr<int> unique = std::make_unique<int>(42); std::shared_ptr<int> shared = std::move(unique); // unique is now nullptr // shared_ptr to weak_ptr std::weak_ptr<int> weak = shared; // weak_ptr to shared_ptr (with null check) if (auto locked = weak.lock()) { // Use locked shared_ptr } // Raw pointer to shared_ptr (dangerous - see pitfalls) int* raw = new int(42); // std::shared_ptr<int> shared(raw); // Dangerous!
Downcasting with Smart Pointers
class Base { public: virtual ~Base() = default; virtual void foo() = 0; }; class Derived : public Base { public: void foo() override {} void bar() {} }; // static_pointer_cast (like static_cast) std::shared_ptr<Base> base = std::make_shared<Derived>(); std::shared_ptr<Derived> derived = std::static_pointer_cast<Derived>(base); // dynamic_pointer_cast (like dynamic_cast, returns nullptr on failure) std::shared_ptr<Base> base2 = std::make_shared<Derived>(); if (auto derived2 = std::dynamic_pointer_cast<Derived>(base2)) { derived2->bar(); // Safe to call Derived methods } // const_pointer_cast (like const_cast) std::shared_ptr<const int> const_ptr = std::make_shared<const int>(42); std::shared_ptr<int> mutable_ptr = std::const_pointer_cast<int>(const_ptr);
Performance Considerations
Memory Overhead
// sizeof comparisons sizeof(int*) // 8 bytes (64-bit) sizeof(std::unique_ptr<int>) // 8 bytes (same as raw pointer) sizeof(std::shared_ptr<int>) // 16 bytes (pointer + control block ptr) sizeof(std::weak_ptr<int>) // 16 bytes (same as shared_ptr) // Control block overhead for shared_ptr // Contains: reference count, weak count, deleter, allocator // Size varies but typically 24-32 bytes // make_shared vs new for shared_ptr auto ptr1 = std::make_shared<int>(42); // 1 allocation std::shared_ptr<int> ptr2(new int(42)); // 2 allocations
Performance Optimization
// Prefer unique_ptr when possible std::unique_ptr<Resource> create_resource() { return std::make_unique<Resource>(); } // Convert to shared_ptr only if needed auto unique = create_resource(); std::shared_ptr<Resource> shared = std::move(unique); // Avoid unnecessary copies of shared_ptr void process(const std::shared_ptr<Resource>& res) { // Pass by const ref // Use res, doesn't increase ref count } // Move when transferring ownership std::shared_ptr<Resource> transfer(std::shared_ptr<Resource> res) { return res; // RVO or move } // Use weak_ptr for non-owning references class Observer { std::weak_ptr<Subject> subject; // Doesn't increase ref count };
Exception Safety
Strong Exception Guarantee
class ExceptionSafe { std::unique_ptr<Resource1> res1; std::unique_ptr<Resource2> res2; public: void update(int value) { // Create new resources auto new_res1 = std::make_unique<Resource1>(value); auto new_res2 = std::make_unique<Resource2>(value); // If exception thrown above, no changes made (strong guarantee) // Commit changes (noexcept operations) res1 = std::move(new_res1); res2 = std::move(new_res2); } };
RAII for Transactions
class Transaction { std::unique_ptr<Connection> conn; bool committed = false; public: explicit Transaction(std::unique_ptr<Connection> c) : conn(std::move(c)) { conn->begin_transaction(); } ~Transaction() { if (!committed) { try { conn->rollback(); } catch (...) { // Log error, don't throw from destructor } } } void commit() { conn->commit(); committed = true; } }; // Usage void perform_transaction() { auto conn = std::make_unique<Connection>(); Transaction txn(std::move(conn)); // Do work // If exception thrown, transaction automatically rolled back txn.commit(); // Explicit commit on success }
Smart Pointers in Containers
Vectors of Smart Pointers
// Vector of unique_ptr std::vector<std::unique_ptr<Widget>> widgets; // Add elements (must move) widgets.push_back(std::make_unique<Widget>(1)); widgets.push_back(std::make_unique<Widget>(2)); // Can't copy vector // auto vec2 = widgets; // ERROR // Can move vector auto vec2 = std::move(widgets); // widgets now empty // Iterate for (const auto& widget : vec2) { widget->process(); } // Remove element (automatically deleted) vec2.erase(vec2.begin()); // Vector of shared_ptr std::vector<std::shared_ptr<Widget>> shared_widgets; shared_widgets.push_back(std::make_shared<Widget>(1)); // Can copy vector (increases ref counts) auto shared_vec2 = shared_widgets;
Maps with Smart Pointers
// Map with unique_ptr values std::map<std::string, std::unique_ptr<Resource>> resource_map; // Insert resource_map["key1"] = std::make_unique<Resource>(1); resource_map.emplace("key2", std::make_unique<Resource>(2)); // Find and use auto it = resource_map.find("key1"); if (it != resource_map.end()) { it->second->process(); } // Extract ownership auto extracted = std::move(resource_map["key1"]); resource_map.erase("key1"); // Map with shared_ptr for shared ownership std::map<std::string, std::shared_ptr<Resource>> shared_map; shared_map["key"] = std::make_shared<Resource>(1); // Multiple maps can share same resource std::map<std::string, std::shared_ptr<Resource>> shared_map2; shared_map2["key"] = shared_map["key"]; // Shares ownership
Common Patterns
Factory Pattern
class Product { public: virtual ~Product() = default; virtual void use() = 0; }; class ConcreteProductA : public Product { public: void use() override { std::cout << "Using A" << std::endl; } }; class ConcreteProductB : public Product { public: void use() override { std::cout << "Using B" << std::endl; } }; class Factory { public: static std::unique_ptr<Product> create(const std::string& type) { if (type == "A") { return std::make_unique<ConcreteProductA>(); } else if (type == "B") { return std::make_unique<ConcreteProductB>(); } return nullptr; } }; // Usage auto product = Factory::create("A"); if (product) { product->use(); }
Pimpl Idiom
// Widget.h class Widget { public: Widget(); ~Widget(); // Must declare but not define in header Widget(Widget&&) noexcept; Widget& operator=(Widget&&) noexcept; void do_something(); private: class Impl; // Forward declaration std::unique_ptr<Impl> pimpl; }; // Widget.cpp class Widget::Impl { public: void do_something_impl() { // Implementation details hidden } private: // Private members not in public header std::vector<int> data; std::string name; }; Widget::Widget() : pimpl(std::make_unique<Impl>()) {} // Define destructor in .cpp after Impl is complete Widget::~Widget() = default; Widget::Widget(Widget&&) noexcept = default; Widget& Widget::operator=(Widget&&) noexcept = default; void Widget::do_something() { pimpl->do_something_impl(); }
Singleton Pattern
class Singleton { public: static Singleton& instance() { static Singleton instance; // Thread-safe in C++11 return instance; } // Delete copy and move Singleton(const Singleton&) = delete; Singleton& operator=(const Singleton&) = delete; Singleton(Singleton&&) = delete; Singleton& operator=(Singleton&&) = delete; void do_something() { std::cout << "Singleton method" << std::endl; } private: Singleton() = default; ~Singleton() = default; }; // Alternative: Smart pointer for explicit control class ManagedSingleton { public: static std::shared_ptr<ManagedSingleton> instance() { static auto inst = std::make_shared<ManagedSingleton>(PrivateTag{}); return inst; } private: struct PrivateTag {}; public: explicit ManagedSingleton(PrivateTag) {} };
Best Practices
- Prefer make_unique and make_shared: More efficient and exception-safe than using new directly
- Use unique_ptr by default: Only use shared_ptr when you actually need shared ownership
- Pass smart pointers by const reference: Avoid unnecessary reference count changes with shared_ptr
- Use weak_ptr to break cycles: Prevent memory leaks from circular shared_ptr references
- Return by value for ownership transfer: Let move semantics handle efficient transfer
- Never create multiple shared_ptrs from same raw pointer: Causes double deletion
- Custom deleters for non-memory resources: Use for files, sockets, mutexes, etc.
- Mark move operations noexcept: Enables optimizations in standard containers
- Use smart pointers in containers: Allows containers of polymorphic objects
- Don't mix smart pointers with raw pointer ownership: Choose one ownership model
Common Pitfalls
- Creating shared_ptr from raw this pointer: Use enable_shared_from_this instead
- Circular shared_ptr references: Use weak_ptr for back references or parent pointers
- Creating multiple shared_ptrs from same raw pointer: Causes double deletion
- Using get() to create new smart pointer: Breaks ownership model
- Forgetting to use move with unique_ptr: unique_ptr is not copyable
- Mixing smart pointers with manual delete: Use one ownership model consistently
- Using shared_ptr when unique_ptr suffices: Unnecessary overhead
- Not checking weak_ptr.lock() return value: May return nullptr if object deleted
- Custom deleter issues: Wrong deleter type or not handling nullptr
- Slicing with smart pointers: Store base class pointers to preserve polymorphism
When to Use
Use this skill when:
- Managing dynamically allocated memory in C++
- Implementing RAII patterns for resource management
- Working with polymorphic objects in containers
- Preventing memory leaks and dangling pointers
- Implementing exception-safe code
- Creating factory patterns or object hierarchies
- Managing shared resources with reference counting
- Breaking circular dependencies with weak references
- Wrapping C APIs with automatic cleanup
- Teaching or learning modern C++ memory management