Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Matthew Sakai | 815 | 99.88% | 1 | 50.00% |
Mike Snitzer | 1 | 0.12% | 1 | 50.00% |
Total | 816 | 2 |
/* SPDX-License-Identifier: GPL-2.0-only */ /* * Copyright 2023 Red Hat */ #ifndef VDO_TYPES_H #define VDO_TYPES_H #include <linux/bio.h> #include <linux/blkdev.h> #include <linux/device-mapper.h> #include <linux/list.h> #include <linux/compiler_attributes.h> #include <linux/types.h> #include "funnel-queue.h" /* A size type in blocks. */ typedef u64 block_count_t; /* The size of a block. */ typedef u16 block_size_t; /* A counter for data_vios */ typedef u16 data_vio_count_t; /* A height within a tree. */ typedef u8 height_t; /* The logical block number as used by the consumer. */ typedef u64 logical_block_number_t; /* The type of the nonce used to identify instances of VDO. */ typedef u64 nonce_t; /* A size in pages. */ typedef u32 page_count_t; /* A page number. */ typedef u32 page_number_t; /* * The physical (well, less logical) block number at which the block is found on the underlying * device. */ typedef u64 physical_block_number_t; /* A count of tree roots. */ typedef u8 root_count_t; /* A number of sectors. */ typedef u8 sector_count_t; /* A sequence number. */ typedef u64 sequence_number_t; /* The offset of a block within a slab. */ typedef u32 slab_block_number; /* A size type in slabs. */ typedef u16 slab_count_t; /* A slot in a bin or block map page. */ typedef u16 slot_number_t; /* typedef thread_count_t - A thread counter. */ typedef u8 thread_count_t; /* typedef thread_id_t - A thread ID, vdo threads are numbered sequentially from 0. */ typedef u8 thread_id_t; /* A zone counter */ typedef u8 zone_count_t; /* The following enums are persisted on storage, so the values must be preserved. */ /* The current operating mode of the VDO. */ enum vdo_state { VDO_DIRTY = 0, VDO_NEW = 1, VDO_CLEAN = 2, VDO_READ_ONLY_MODE = 3, VDO_FORCE_REBUILD = 4, VDO_RECOVERING = 5, VDO_REPLAYING = 6, /* VDO_REPLAYING is never set anymore, but retained for upgrade */ VDO_REBUILD_FOR_UPGRADE = 7, /* Keep VDO_STATE_COUNT at the bottom. */ VDO_STATE_COUNT }; /** * vdo_state_requires_read_only_rebuild() - Check whether a vdo_state indicates * that a read-only rebuild is required. * @state: The vdo_state to check. * * Return: true if the state indicates a rebuild is required */ static inline bool __must_check vdo_state_requires_read_only_rebuild(enum vdo_state state) { return ((state == VDO_FORCE_REBUILD) || (state == VDO_REBUILD_FOR_UPGRADE)); } /** * vdo_state_requires_recovery() - Check whether a vdo state indicates that recovery is needed. * @state: The state to check. * * Return: true if the state indicates a recovery is required */ static inline bool __must_check vdo_state_requires_recovery(enum vdo_state state) { return ((state == VDO_DIRTY) || (state == VDO_REPLAYING) || (state == VDO_RECOVERING)); } /* * The current operation on a physical block (from the point of view of the recovery journal, slab * journals, and reference counts. */ enum journal_operation { VDO_JOURNAL_DATA_REMAPPING = 0, VDO_JOURNAL_BLOCK_MAP_REMAPPING = 1, } __packed; /* Partition IDs encoded in the volume layout in the super block. */ enum partition_id { VDO_BLOCK_MAP_PARTITION = 0, VDO_SLAB_DEPOT_PARTITION = 1, VDO_RECOVERY_JOURNAL_PARTITION = 2, VDO_SLAB_SUMMARY_PARTITION = 3, } __packed; /* Metadata types for the vdo. */ enum vdo_metadata_type { VDO_METADATA_RECOVERY_JOURNAL = 1, VDO_METADATA_SLAB_JOURNAL = 2, VDO_METADATA_RECOVERY_JOURNAL_2 = 3, } __packed; /* A position in the block map where a block map entry is stored. */ struct block_map_slot { physical_block_number_t pbn; slot_number_t slot; }; /* * Four bits of each five-byte block map entry contain a mapping state value used to distinguish * unmapped or discarded logical blocks (which are treated as mapped to the zero block) from entries * that have been mapped to a physical block, including the zero block. * * FIXME: these should maybe be defines. */ enum block_mapping_state { VDO_MAPPING_STATE_UNMAPPED = 0, /* Must be zero to be the default value */ VDO_MAPPING_STATE_UNCOMPRESSED = 1, /* A normal (uncompressed) block */ VDO_MAPPING_STATE_COMPRESSED_BASE = 2, /* Compressed in slot 0 */ VDO_MAPPING_STATE_COMPRESSED_MAX = 15, /* Compressed in slot 13 */ }; enum { VDO_MAX_COMPRESSION_SLOTS = (VDO_MAPPING_STATE_COMPRESSED_MAX - VDO_MAPPING_STATE_COMPRESSED_BASE + 1), }; struct data_location { physical_block_number_t pbn; enum block_mapping_state state; }; /* The configuration of a single slab derived from the configured block size and slab size. */ struct slab_config { /* total number of blocks in the slab */ block_count_t slab_blocks; /* number of blocks available for data */ block_count_t data_blocks; /* number of blocks for reference counts */ block_count_t reference_count_blocks; /* number of blocks for the slab journal */ block_count_t slab_journal_blocks; /* * Number of blocks after which the slab journal starts pushing out a reference_block for * each new entry it receives. */ block_count_t slab_journal_flushing_threshold; /* * Number of blocks after which the slab journal pushes out all reference_blocks and makes * all vios wait. */ block_count_t slab_journal_blocking_threshold; /* Number of blocks after which the slab must be scrubbed before coming online. */ block_count_t slab_journal_scrubbing_threshold; } __packed; /* * This structure is memcmp'd for equality. Keep it packed and don't add any fields that are not * properly set in both extant and parsed configs. */ struct thread_count_config { unsigned int bio_ack_threads; unsigned int bio_threads; unsigned int bio_rotation_interval; unsigned int cpu_threads; unsigned int logical_zones; unsigned int physical_zones; unsigned int hash_zones; } __packed; struct device_config { struct dm_target *owning_target; struct dm_dev *owned_device; struct vdo *vdo; /* All configs referencing a layer are kept on a list in the layer */ struct list_head config_list; char *original_string; unsigned int version; char *parent_device_name; block_count_t physical_blocks; /* * This is the number of logical blocks from VDO's internal point of view. It is the number * of 4K blocks regardless of the value of the logical_block_size parameter below. */ block_count_t logical_blocks; unsigned int logical_block_size; unsigned int cache_size; unsigned int block_map_maximum_age; bool deduplication; bool compression; struct thread_count_config thread_counts; block_count_t max_discard_blocks; }; enum vdo_completion_type { /* Keep VDO_UNSET_COMPLETION_TYPE at the top. */ VDO_UNSET_COMPLETION_TYPE, VDO_ACTION_COMPLETION, VDO_ADMIN_COMPLETION, VDO_BLOCK_ALLOCATOR_COMPLETION, VDO_DATA_VIO_POOL_COMPLETION, VDO_DECREMENT_COMPLETION, VDO_FLUSH_COMPLETION, VDO_FLUSH_NOTIFICATION_COMPLETION, VDO_GENERATION_FLUSHED_COMPLETION, VDO_HASH_ZONE_COMPLETION, VDO_HASH_ZONES_COMPLETION, VDO_LOCK_COUNTER_COMPLETION, VDO_PAGE_COMPLETION, VDO_READ_ONLY_MODE_COMPLETION, VDO_REPAIR_COMPLETION, VDO_SYNC_COMPLETION, VIO_COMPLETION, } __packed; struct vdo_completion; /** * typedef vdo_action_fn - An asynchronous VDO operation. * @completion: The completion of the operation. */ typedef void (*vdo_action_fn)(struct vdo_completion *completion); enum vdo_completion_priority { BIO_ACK_Q_ACK_PRIORITY = 0, BIO_ACK_Q_MAX_PRIORITY = 0, BIO_Q_COMPRESSED_DATA_PRIORITY = 0, BIO_Q_DATA_PRIORITY = 0, BIO_Q_FLUSH_PRIORITY = 2, BIO_Q_HIGH_PRIORITY = 2, BIO_Q_METADATA_PRIORITY = 1, BIO_Q_VERIFY_PRIORITY = 1, BIO_Q_MAX_PRIORITY = 2, CPU_Q_COMPLETE_VIO_PRIORITY = 0, CPU_Q_COMPLETE_READ_PRIORITY = 0, CPU_Q_COMPRESS_BLOCK_PRIORITY = 0, CPU_Q_EVENT_REPORTER_PRIORITY = 0, CPU_Q_HASH_BLOCK_PRIORITY = 0, CPU_Q_MAX_PRIORITY = 0, UDS_Q_PRIORITY = 0, UDS_Q_MAX_PRIORITY = 0, VDO_DEFAULT_Q_COMPLETION_PRIORITY = 1, VDO_DEFAULT_Q_FLUSH_PRIORITY = 2, VDO_DEFAULT_Q_MAP_BIO_PRIORITY = 0, VDO_DEFAULT_Q_SYNC_PRIORITY = 2, VDO_DEFAULT_Q_VIO_CALLBACK_PRIORITY = 1, VDO_DEFAULT_Q_MAX_PRIORITY = 2, /* The maximum allowable priority */ VDO_WORK_Q_MAX_PRIORITY = 2, /* A value which must be out of range for a valid priority */ VDO_WORK_Q_DEFAULT_PRIORITY = VDO_WORK_Q_MAX_PRIORITY + 1, }; struct vdo_completion { /* The type of completion this is */ enum vdo_completion_type type; /* * <code>true</code> once the processing of the operation is complete. This flag should not * be used by waiters external to the VDO base as it is used to gate calling the callback. */ bool complete; /* * If true, queue this completion on the next callback invocation, even if it is already * running on the correct thread. */ bool requeue; /* The ID of the thread which should run the next callback */ thread_id_t callback_thread_id; /* The result of the operation */ int result; /* The VDO on which this completion operates */ struct vdo *vdo; /* The callback which will be called once the operation is complete */ vdo_action_fn callback; /* Callback which, if set, will be called if an error result is set */ vdo_action_fn error_handler; /* The parent object, if any, that spawned this completion */ void *parent; /* Entry link for lock-free work queue */ struct funnel_queue_entry work_queue_entry_link; enum vdo_completion_priority priority; struct vdo_work_queue *my_queue; }; struct block_allocator; struct data_vio; struct vdo; struct vdo_config; /* vio types for statistics and instrumentation. */ enum vio_type { VIO_TYPE_UNINITIALIZED = 0, VIO_TYPE_DATA, VIO_TYPE_BLOCK_ALLOCATOR, VIO_TYPE_BLOCK_MAP, VIO_TYPE_BLOCK_MAP_INTERIOR, VIO_TYPE_GEOMETRY, VIO_TYPE_PARTITION_COPY, VIO_TYPE_RECOVERY_JOURNAL, VIO_TYPE_SLAB_JOURNAL, VIO_TYPE_SLAB_SUMMARY, VIO_TYPE_SUPER_BLOCK, } __packed; /* Priority levels for asynchronous I/O operations performed on a vio. */ enum vio_priority { VIO_PRIORITY_LOW = 0, VIO_PRIORITY_DATA = VIO_PRIORITY_LOW, VIO_PRIORITY_COMPRESSED_DATA = VIO_PRIORITY_DATA, VIO_PRIORITY_METADATA, VIO_PRIORITY_HIGH, } __packed; /* * A wrapper for a bio. All I/O to the storage below a vdo is conducted via vios. */ struct vio { /* The completion for this vio */ struct vdo_completion completion; /* The bio zone in which I/O should be processed */ zone_count_t bio_zone; /* The queueing priority of the vio operation */ enum vio_priority priority; /* The vio type is used for statistics and instrumentation. */ enum vio_type type; /* The size of this vio in blocks */ unsigned int block_count; /* The data being read or written. */ char *data; /* The VDO-owned bio to use for all IO for this vio */ struct bio *bio; /* * A list of enqueued bios with consecutive block numbers, stored by vdo_submit_bio() under * the first-enqueued vio. The other vios are found via their bio entries in this list, and * are not added to the work queue as separate completions. */ struct bio_list bios_merged; }; #endif /* VDO_TYPES_H */
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