MySQL 8.0.39
Source Code Documentation
managed_buffer.h
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23
24/// @addtogroup Replication
25/// @{
26///
27/// @file managed_buffer.h
28///
29/// Container class that provides a contiguous memory buffer to
30/// the caller, which the caller can request to grow.
31///
32/// The growth rate is determined by a Grow_calculator.
33
34#ifndef MYSQL_BUFFER_MANAGED_BUFFER_H_
35#define MYSQL_BUFFER_MANAGED_BUFFER_H_
36
37#include <limits>
38
39#include "grow_calculator.h" // buffer::Grow_calculator
40#include "grow_status.h" // buffer::Grow_status
41#include "libbinlogevents/include/nodiscard.h" // NODISCARD
44#include "rw_buffer.h" // buffer::Rw_buffer
45
47
48namespace mysqlns::buffer {
49
50/// Owned, growable, contiguous memory buffer.
51///
52/// This class provides a single contiguous buffer. Therefore, it may
53/// have to move data when it grows. It is implemented as a Buffer
54/// that is resized using realloc.
55///
56/// The caller can provide a user-defined, pre-allocated buffer, which
57/// will then be used as long as it suffices; a new buffer will be
58/// allocated if not. This can be used to remove the need for
59/// allocation in use cases where the object is small.
60///
61/// Objects have a growable total capacity, which is split into two
62/// parts; the read part and the write part, each represented as a
63/// `Buffer_view`. The intended use case is where the user interacts
64/// with an API that produces data into a user-provided buffer. The
65/// user can then: (1) grow the buffer before invoking the API; (2)
66/// invoke the API to write data to the write part; (3) tell the
67/// Managed_buffer to move the written bytes to the read part.
68///
69/// Generally, std::stringstream or std::vector<char> are safer and
70/// simpler interfaces for buffers and should be preferred when
71/// possible. However they do not fit all use cases:
72///
73/// - std::stringstream is preferrable and more convenient when
74/// appending existing data to the stream. But it is not suitable
75/// for interaction with C-like APIs that produce data in a char*
76/// given by the caller. The user would need to allocate a buffer
77/// outside the stringsteam and then append the buffer to the
78/// stringstream, which would imply unnecessary memory and cpu
79/// overheads.
80///
81/// - When using a C-like API that produces data in a char* given by
82/// the caller, std::vector is often good. The user can reserve as
83/// much memory as needed and then pass the underlying data array to
84/// the API. However, the following properties are sometimes
85/// advantageous for Managed_buffer:
86///
87/// - Vector has no practical way to put an exact bound on the
88/// memory usage. Managed_buffer uses a Grow_calculator which
89/// allows exact control on memory usage, including a maximum
90/// capacity.
91///
92/// - Even for small buffer sizes, vector needs at least one heap
93/// allocation. Managed_buffer allows the use of a default buffer
94/// of fixed size, for example allocated on the stack. This can
95/// reduce the need for heap allocation in use patterns where the
96/// required buffer capacity is *usually* small.
97///
98/// The main drawback of Managed_buffer is that it is non-standard and
99/// has a minimal feature set.
100///
101/// The main difference between Buffer_sequence and Managed_buffer, is
102/// that Managed_buffer keeps data in a contiguous buffer, whereas
103/// Buffer_sequence never copies data.
104///
105/// This class never throws any exception.
106///
107/// @tparam Char_t The char type; usually char or unsigned char.
108///
109/// @tparam builtin_capacity Size of pre-allocated initial buffer.
110template <class Char_tp = unsigned char>
111class Managed_buffer : public buffer::Rw_buffer<Char_tp> {
112 public:
113 using Char_t = Char_tp;
116 using typename Rw_buffer_t::Const_iterator_t;
117 using typename Rw_buffer_t::Iterator_t;
118 using typename Rw_buffer_t::Size_t;
119 // As soon as all platforms support it, change to:
120 // using Allocator_t = std::pmr::polymorphic_allocator<Char_t>;
124
125 /// Construct a new object without a default buffer.
126 // Nolint: clang-tidy does not recognize that m_owns_default_buffer
127 // is initialized, despite it is initialized in the targed
128 // constructor.
129 // NOLINTBEGIN(cppcoreguidelines-pro-type-member-init)
131 const Memory_resource_t &memory_resource = Memory_resource_t())
132 : Managed_buffer(Size_t(0), memory_resource) {}
133 // NOLINTEND(cppcoreguidelines-pro-type-member-init)
134
135 /// Construct a new object that owns a default buffer.
136 ///
137 /// The default buffer is created when needed. Once
138 /// created, it survives calls to @c reset and will only be deleted
139 /// when the Managed_buffer is deleted.
140 ///
141 /// @param default_capacity The capacity of the default buffer.
142 ///
143 /// @param memory_resource Memory_resource used to allocate memory.
145 Size_t default_capacity,
146 const Memory_resource_t &memory_resource = Memory_resource_t())
147 : Rw_buffer<Char_t>(),
148 m_char_allocator(memory_resource),
150 m_default_capacity(default_capacity),
151 m_owns_default_buffer(true) {}
152
153 /// Construct a new object that uses the given default buffer.
154 ///
155 /// The default buffer is owned by the caller, so the caller must
156 /// ensure that it outlives the Managed_buffer.
157 ///
158 /// @param default_buffer The default buffer.
159 ///
160 /// @param memory_resource Memory_resource used to allocate memory.
162 Buffer_view_t default_buffer,
163 const Memory_resource_t &memory_resource = Memory_resource_t())
164 : Rw_buffer<Char_t>(default_buffer),
165 m_char_allocator(memory_resource),
166 m_default_buffer(default_buffer.begin()),
167 m_default_capacity(default_buffer.size()),
168 m_owns_default_buffer(false) {}
169
171 Managed_buffer(Managed_buffer &&other) noexcept = default;
173 Managed_buffer &operator=(Managed_buffer &&other) noexcept = default;
174
175 ~Managed_buffer() override {
176 auto *ptr = this->read_part().begin();
177 bool delete_default_buffer =
179 bool delete_buffer = ptr != nullptr && ptr != m_default_buffer;
180 if (delete_default_buffer)
182 if (delete_buffer) m_char_allocator.deallocate(ptr, this->capacity());
183 }
184
185 /// Reserve space so that the total buffer size is at least the
186 /// given number.
187 ///
188 /// The buffer will be resized if necessary. So, on successful
189 /// return, the caller should call begin() to get the new buffer
190 /// pointer.
191 ///
192 /// @note This may move existing data to a new address; consider any
193 /// existing pointers into the buffer as invalid after this call.
194 ///
195 /// @param requested_size The requested total size of the read part
196 /// and the write part.
197 ///
198 /// @retval Grow_status::success The object now has at least the
199 /// given size; either it was successfully re-allocated, or it
200 /// already had the requested size.
201 ///
202 /// @retval Grow_status::exceeds_max_size if requested_size
203 /// exceeds the configured maximum size.
204 ///
205 /// @retval Grow_status::out_of_memory Memory allocation failed.
208 auto capacity = this->capacity();
209 auto [error, new_capacity] =
212 if (new_capacity > capacity) {
213 if (new_capacity <= m_default_capacity) {
214 // We have capacity < new_capacity <= m_default_capacity.
215 // Since we never allocate capacity less than the default
216 // capacity, this situation only occurs when the capacity is
217 // 0. And since we make use of the default buffer as soon as
218 // we allocate it, it also means that the default buffer is
219 // nullptr.
220 assert(capacity == 0);
221 assert(m_default_buffer == nullptr);
223 if (m_default_buffer == nullptr) return Grow_status::out_of_memory;
225 } else {
226 // Use dynamic buffer.
227 Char_t *new_buffer = allocate_buffer(new_capacity);
228 if (new_buffer == nullptr) return Grow_status::out_of_memory;
229 replace_buffer(new_buffer, new_capacity);
230 }
231 }
233 }
234
235 /// Reserve space so that the write size is at least the given
236 /// number.
237 ///
238 /// @param requested_write_size The requested size of the write
239 /// part.
240 ///
241 /// @retval Grow_status::success The write part now has at least the
242 /// given size; either it was successfully re-allocated, or it
243 /// already had the requested size.
244 ///
245 /// @retval Grow_status::exceeds_max_size if the existing read size
246 /// plus requested_write_size exceeds the max size configured in the
247 /// Grow_calculator.
248 ///
249 /// @retval Grow_status::out_of_memory Memory allocation failed.
250 [[NODISCARD]] Grow_status reserve_write_size(Size_t requested_write_size) {
251 auto read_size = this->read_part().size();
252 if (requested_write_size > std::numeric_limits<Size_t>::max() - read_size)
254 return reserve_total_size(read_size + requested_write_size);
255 }
256
257 /// Reset the buffer.
258 ///
259 /// This makes the read part empty. The write part will point to
260 /// the default buffer if there is one; otherwise the write part
261 /// will be empty.
262 void reset() {
264 auto *rb = this->read_part().begin();
265 if (rb != nullptr && rb != m_default_buffer)
266 m_char_allocator.deallocate(this->read_part().begin(), this->capacity());
268 if (m_default_buffer == nullptr)
269 this->write_part() = Buffer_view_t();
270 else
272 }
273
274 /// Set the grow calculator.
275 ///
276 /// Details:
277 ///
278 /// - If the new Grow_calculator's maximum size is less than the
279 /// current buffer size, it does not change the existing buffer, but
280 /// subsequent calls to reserve will fail.
281 ///
282 /// - In case the new Grow_calculator's maximum size is less than
283 /// the default capacity, this object will provide capacity equal to
284 /// the default_size, exceeding the Grow_calculator's maximum size.
285 void set_grow_calculator(const Grow_calculator_t &grow_calculator) {
286 m_grow_calculator = grow_calculator;
287 }
288
289 /// Return a const reference to the grow calculator.
291 return m_grow_calculator;
292 }
293
294 /// Return the size of the default buffer.
296
297 private:
298 /// Allocate a new buffer and return it.
299 ///
300 /// This never throws; it returns nullptr on out of memory.
301 ///
302 /// @param new_size The size of the buffer.
303 ///
304 /// @returns the new buffer on success, nullptr on out of memory.
306 try {
307 return m_char_allocator.allocate(new_size);
308 } catch (std::bad_alloc &) {
309 return nullptr;
310 }
311 }
312
313 /// Replace the underlying data buffer by the given one.
314 ///
315 /// @param new_buffer The new buffer. This must be different from
316 /// the old buffer.
317 ///
318 /// @param new_size The size of the new buffer.
319 void replace_buffer(Char_t *new_buffer, Size_t new_size) {
320 assert(new_buffer != this->read_part().data());
321 auto &r = this->read_part();
322 auto &w = this->write_part();
323 auto read_size = r.size();
324 if (read_size) memcpy(new_buffer, r.begin(), read_size);
325 if (r.begin() != m_default_buffer && r.begin() != nullptr)
326 m_char_allocator.deallocate(r.begin(), this->capacity());
327 r = Buffer_view_t(new_buffer, read_size);
328 w = Buffer_view_t(new_buffer + read_size, new_size - read_size);
329 }
330
331 /// Calculator for growing the buffer.
333
334 /// Allocator to grow the buffer.
336
337 /// User-provided, user-owned buffer.
339
340 /// Size of user-provided, user-owned buffer.
342
343 /// If true, the default buffer will be deallocated by the destructor.
345};
346
348 std::size_t(8 * 1024);
349
350/// @see Managed_buffer
351///
352/// This class pre-allocates a fixed-size initial buffer,
353/// which is beneficial in use patterns where managed buffers are
354/// allocated on the stack and are usually only given small amount of
355/// data.
356template <class Char_t = unsigned char,
357 std::size_t preallocated_size =
360 public:
364
366 const Memory_resource_t &memory_resource = Memory_resource_t())
368 Buffer_view_t(m_preallocated_buffer, preallocated_size),
369 memory_resource) {}
370
371 private:
372 /// Preallocated buffer.
373 Char_t m_preallocated_buffer[preallocated_size == 0 ? 1 : preallocated_size];
374};
375
376} // namespace mysqlns::buffer
377
378/// @} (end of group Replication)
379#endif // MYSQL_BUFFER_MANAGED_BUFFER_H_
Iterator_t begin()
Return pointer to the first character of the data.
Definition: buffer_view.h:94
Size_t size() const
Return the number of bytes.
Definition: buffer_view.h:112
Description of a heuristic to determine how much memory to allocate.
Definition: grow_calculator.h:67
Result_t compute_new_size(Size_t old_size, Size_t requested_size) const
Compute the new size.
Definition: grow_calculator.cpp:39
Owned, growable, contiguous memory buffer.
Definition: managed_buffer.h:111
Managed_buffer & operator=(Managed_buffer &&other) noexcept=default
Managed_buffer(Managed_buffer &other)=delete
Char_t * allocate_buffer(Size_t new_size)
Allocate a new buffer and return it.
Definition: managed_buffer.h:305
Managed_buffer(Buffer_view_t default_buffer, const Memory_resource_t &memory_resource=Memory_resource_t())
Construct a new object that uses the given default buffer.
Definition: managed_buffer.h:161
Char_tp Char_t
Definition: managed_buffer.h:113
Grow_calculator_t m_grow_calculator
Calculator for growing the buffer.
Definition: managed_buffer.h:332
void replace_buffer(Char_t *new_buffer, Size_t new_size)
Replace the underlying data buffer by the given one.
Definition: managed_buffer.h:319
Grow_status reserve_total_size(Size_t requested_size)
Reserve space so that the total buffer size is at least the given number.
Definition: managed_buffer.h:206
void reset()
Reset the buffer.
Definition: managed_buffer.h:262
const Grow_calculator_t & get_grow_calculator() const
Return a const reference to the grow calculator.
Definition: managed_buffer.h:290
Managed_buffer(Size_t default_capacity, const Memory_resource_t &memory_resource=Memory_resource_t())
Construct a new object that owns a default buffer.
Definition: managed_buffer.h:144
Size_t get_default_capacity()
Return the size of the default buffer.
Definition: managed_buffer.h:295
Char_t * m_default_buffer
User-provided, user-owned buffer.
Definition: managed_buffer.h:338
Char_allocator_t m_char_allocator
Allocator to grow the buffer.
Definition: managed_buffer.h:335
Managed_buffer(const Memory_resource_t &memory_resource=Memory_resource_t())
Construct a new object without a default buffer.
Definition: managed_buffer.h:130
bool m_owns_default_buffer
If true, the default buffer will be deallocated by the destructor.
Definition: managed_buffer.h:344
mysqlns::resource::Memory_resource Memory_resource_t
Definition: managed_buffer.h:121
Size_t m_default_capacity
Size of user-provided, user-owned buffer.
Definition: managed_buffer.h:341
std::size_t Size_t
Definition: rw_buffer.h:63
Managed_buffer(Managed_buffer &&other) noexcept=default
void set_grow_calculator(const Grow_calculator_t &grow_calculator)
Set the grow calculator.
Definition: managed_buffer.h:285
~Managed_buffer() override
Definition: managed_buffer.h:175
Grow_status reserve_write_size(Size_t requested_write_size)
Reserve space so that the write size is at least the given number.
Definition: managed_buffer.h:250
Buffer_view< Char_t > Buffer_view_t
Definition: managed_buffer.h:114
Managed_buffer & operator=(Managed_buffer &other)=delete
Definition: managed_buffer.h:359
Preallocated_managed_buffer(const Memory_resource_t &memory_resource=Memory_resource_t())
Definition: managed_buffer.h:365
Char_t m_preallocated_buffer[preallocated_size==0 ? 1 :preallocated_size]
Preallocated buffer.
Definition: managed_buffer.h:373
Non-owning read/write memory buffer manager with a fixed size.
Definition: rw_buffer.h:60
const Char_t * Const_iterator_t
Definition: rw_buffer.h:66
Char_t * Iterator_t
Definition: rw_buffer.h:65
const Buffer_view_t & read_part() const
Return the read part.
Definition: rw_buffer.h:95
Size_t capacity() const
Return the total size of the read part and the write part.
Definition: rw_buffer.h:107
const Buffer_view_t & write_part() const
Return the write part.
Definition: rw_buffer.h:101
std::size_t Size_t
Definition: rw_buffer.h:63
constexpr T * allocate(size_type n)
Use the Memory_resource to allocate the given number of elements of type T.
Definition: allocator.h:84
constexpr void deallocate(T *p, size_type size)
Use the Memory_resource to deallocate the given pointer.
Definition: allocator.h:95
Polymorphism-free memory resource class with custom allocator and deallocator functions.
Definition: memory_resource.h:88
Fido Client Authentication nullptr
Definition: fido_client_plugin.cc:222
Allocator class that uses a polymorphic Memory_resource to allocate memory.
Class that wraps resources in a polymorphic manner.
Log error(cerr, "ERROR")
Definition: buffer_sequence_view.h:51
Grow_status
Error statuses for classes that use Grow_calculator.
Definition: grow_status.h:37
@ exceeds_max_size
A grow operation could not be performed because there is a configured maximum size.
@ success
A grow operation succeeded.
@ out_of_memory
A grow operation failed because memory allocation failed.
constexpr std::size_t default_preallocated_managed_buffer_size
Definition: managed_buffer.h:347
#define NODISCARD
The function attribute [[NODISCARD]] is a replacement for [[nodiscard]] to workaround a gcc bug.
Definition: nodiscard.h:47
const mysql_service_registry_t * r
Definition: pfs_example_plugin_employee.cc:86
Non-owning manager for a fixed memory buffer, which is split into a read part and a write part,...
Contains wrapper functions for memory allocation and deallocation.
#define BAPI_TRACE
Definition: wrapper_functions.h:66