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- /* SPDX-License-Identifier: GPL-2.0-only */
- /*
- * Copyright 2023 Red Hat
- */
- #ifndef VDO_MEMORY_ALLOC_H
- #define VDO_MEMORY_ALLOC_H
- #include <linux/cache.h>
- #include <linux/io.h> /* for PAGE_SIZE */
- #include "permassert.h"
- #include "thread-registry.h"
- /* Custom memory allocation function that tracks memory usage */
- int __must_check vdo_allocate_memory(size_t size, size_t align, const char *what, void *ptr);
- /*
- * Allocate storage based on element counts, sizes, and alignment.
- *
- * This is a generalized form of our allocation use case: It allocates an array of objects,
- * optionally preceded by one object of another type (i.e., a struct with trailing variable-length
- * array), with the alignment indicated.
- *
- * Why is this inline? The sizes and alignment will always be constant, when invoked through the
- * macros below, and often the count will be a compile-time constant 1 or the number of extra bytes
- * will be a compile-time constant 0. So at least some of the arithmetic can usually be optimized
- * away, and the run-time selection between allocation functions always can. In many cases, it'll
- * boil down to just a function call with a constant size.
- *
- * @count: The number of objects to allocate
- * @size: The size of an object
- * @extra: The number of additional bytes to allocate
- * @align: The required alignment
- * @what: What is being allocated (for error logging)
- * @ptr: A pointer to hold the allocated memory
- *
- * Return: VDO_SUCCESS or an error code
- */
- static inline int __vdo_do_allocation(size_t count, size_t size, size_t extra,
- size_t align, const char *what, void *ptr)
- {
- size_t total_size = count * size + extra;
- /* Overflow check: */
- if ((size > 0) && (count > ((SIZE_MAX - extra) / size))) {
- /*
- * This is kind of a hack: We rely on the fact that SIZE_MAX would cover the entire
- * address space (minus one byte) and thus the system can never allocate that much
- * and the call will always fail. So we can report an overflow as "out of memory"
- * by asking for "merely" SIZE_MAX bytes.
- */
- total_size = SIZE_MAX;
- }
- return vdo_allocate_memory(total_size, align, what, ptr);
- }
- /*
- * Allocate one or more elements of the indicated type, logging an error if the allocation fails.
- * The memory will be zeroed.
- *
- * @COUNT: The number of objects to allocate
- * @TYPE: The type of objects to allocate. This type determines the alignment of the allocation.
- * @WHAT: What is being allocated (for error logging)
- * @PTR: A pointer to hold the allocated memory
- *
- * Return: VDO_SUCCESS or an error code
- */
- #define vdo_allocate(COUNT, TYPE, WHAT, PTR) \
- __vdo_do_allocation(COUNT, sizeof(TYPE), 0, __alignof__(TYPE), WHAT, PTR)
- /*
- * Allocate one object of an indicated type, followed by one or more elements of a second type,
- * logging an error if the allocation fails. The memory will be zeroed.
- *
- * @TYPE1: The type of the primary object to allocate. This type determines the alignment of the
- * allocated memory.
- * @COUNT: The number of objects to allocate
- * @TYPE2: The type of array objects to allocate
- * @WHAT: What is being allocated (for error logging)
- * @PTR: A pointer to hold the allocated memory
- *
- * Return: VDO_SUCCESS or an error code
- */
- #define vdo_allocate_extended(TYPE1, COUNT, TYPE2, WHAT, PTR) \
- __extension__({ \
- int _result; \
- TYPE1 **_ptr = (PTR); \
- BUILD_BUG_ON(__alignof__(TYPE1) < __alignof__(TYPE2)); \
- _result = __vdo_do_allocation(COUNT, \
- sizeof(TYPE2), \
- sizeof(TYPE1), \
- __alignof__(TYPE1), \
- WHAT, \
- _ptr); \
- _result; \
- })
- /*
- * Allocate memory starting on a cache line boundary, logging an error if the allocation fails. The
- * memory will be zeroed.
- *
- * @size: The number of bytes to allocate
- * @what: What is being allocated (for error logging)
- * @ptr: A pointer to hold the allocated memory
- *
- * Return: VDO_SUCCESS or an error code
- */
- static inline int __must_check vdo_allocate_cache_aligned(size_t size, const char *what, void *ptr)
- {
- return vdo_allocate_memory(size, L1_CACHE_BYTES, what, ptr);
- }
- /*
- * Allocate one element of the indicated type immediately, failing if the required memory is not
- * immediately available.
- *
- * @size: The number of bytes to allocate
- * @what: What is being allocated (for error logging)
- *
- * Return: pointer to the memory, or NULL if the memory is not available.
- */
- void *__must_check vdo_allocate_memory_nowait(size_t size, const char *what);
- int __must_check vdo_reallocate_memory(void *ptr, size_t old_size, size_t size,
- const char *what, void *new_ptr);
- int __must_check vdo_duplicate_string(const char *string, const char *what,
- char **new_string);
- /* Free memory allocated with vdo_allocate(). */
- void vdo_free(void *ptr);
- static inline void *__vdo_forget(void **ptr_ptr)
- {
- void *ptr = *ptr_ptr;
- *ptr_ptr = NULL;
- return ptr;
- }
- /*
- * Null out a pointer and return a copy to it. This macro should be used when passing a pointer to
- * a function for which it is not safe to access the pointer once the function returns.
- */
- #define vdo_forget(ptr) __vdo_forget((void **) &(ptr))
- void vdo_memory_init(void);
- void vdo_memory_exit(void);
- void vdo_register_allocating_thread(struct registered_thread *new_thread,
- const bool *flag_ptr);
- void vdo_unregister_allocating_thread(void);
- void vdo_get_memory_stats(u64 *bytes_used, u64 *peak_bytes_used);
- void vdo_report_memory_usage(void);
- #endif /* VDO_MEMORY_ALLOC_H */
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