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#ifndef FILE_CACHE_H
#define FILE_CACHE_H
/* Create a new file cache. It works very much like file-backed mmap()ed
memory, but it works more nicely with remote filesystems (no SIGBUS). */
struct file_cache *file_cache_new(int fd);
struct file_cache *file_cache_new_path(int fd, const char *path);
/* Destroy the cache and set cache pointer to NULL. */
void file_cache_free(struct file_cache **cache);
/* Change cached file descriptor. Invalidates the whole cache. */
void file_cache_set_fd(struct file_cache *cache, int fd);
/* Change the memory allocated for the cache. This can be used to immediately
set the maximum size so there's no need to grow the memory area with
possibly slow copying. */
int file_cache_set_size(struct file_cache *cache, uoff_t size);
/* Read data from file, returns how many bytes was actually read or -1 if
error occurred. */
ssize_t file_cache_read(struct file_cache *cache, uoff_t offset, size_t size);
/* Returns pointer to beginning of cached file. Only parts of the returned
memory that are valid are the ones that have been file_cache_read().
Note that the pointer may become invalid after calling file_cache_read(). */
const void *file_cache_get_map(struct file_cache *cache, size_t *size_r);
/* Update cached memory area. Mark fully written pages as cached. */
void file_cache_write(struct file_cache *cache, const void *data, size_t size,
uoff_t offset);
/* Invalidate cached memory area. It will be read again next time it's tried
to be accessed. */
void file_cache_invalidate(struct file_cache *cache,
uoff_t offset, uoff_t size);
#endif
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