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(173-166-2-198-newengland.hfc.comcastbusiness.net. [173.166.2.198]) by smtp.gmail.com with ESMTPSA id f25-20020a05620a15b900b0075b196ae392sm1489722qkk.104.2023.05.23.14.46.48 (version=TLS1_3 cipher=TLS_AES_256_GCM_SHA384 bits=256/256); Tue, 23 May 2023 14:46:49 -0700 (PDT) From: "J. corwin Coburn" To: dm-devel@redhat.com, linux-block@vger.kernel.org Date: Tue, 23 May 2023 17:45:34 -0400 Message-Id: <20230523214539.226387-35-corwin@redhat.com> In-Reply-To: <20230523214539.226387-1-corwin@redhat.com> References: <20230523214539.226387-1-corwin@redhat.com> MIME-Version: 1.0 X-Scanned-By: MIMEDefang 3.1 on 10.11.54.5 Subject: [dm-devel] [PATCH v2 34/39] Add the on-disk formats and marshalling of vdo structures. X-BeenThere: dm-devel@redhat.com X-Mailman-Version: 2.1.29 Precedence: list List-Id: device-mapper development List-Unsubscribe: , List-Archive: List-Post: List-Help: List-Subscribe: , Cc: vdo-devel@redhat.com, "J. corwin Coburn" Errors-To: dm-devel-bounces@redhat.com Sender: "dm-devel" X-Scanned-By: MIMEDefang 3.1 on 10.11.54.9 X-Mimecast-Spam-Score: 0 X-Mimecast-Originator: redhat.com Signed-off-by: J. corwin Coburn --- drivers/md/dm-vdo/encodings.c | 1523 +++++++++++++++++++++++++++++++++ drivers/md/dm-vdo/encodings.h | 1307 ++++++++++++++++++++++++++++ 2 files changed, 2830 insertions(+) create mode 100644 drivers/md/dm-vdo/encodings.c create mode 100644 drivers/md/dm-vdo/encodings.h diff --git a/drivers/md/dm-vdo/encodings.c b/drivers/md/dm-vdo/encodings.c new file mode 100644 index 00000000000..0666f00e1e7 --- /dev/null +++ b/drivers/md/dm-vdo/encodings.c @@ -0,0 +1,1523 @@ +// SPDX-License-Identifier: GPL-2.0-only +/* + * Copyright Red Hat + */ + +#include "encodings.h" + +#include + +#include "logger.h" +#include "memory-alloc.h" +#include "permassert.h" + +#include "constants.h" +#include "release-versions.h" +#include "status-codes.h" +#include "types.h" + +struct geometry_block { + char magic_number[VDO_GEOMETRY_MAGIC_NUMBER_SIZE]; + struct packed_header header; + u32 checksum; +} __packed; + +static const struct header GEOMETRY_BLOCK_HEADER_5_0 = { + .id = VDO_GEOMETRY_BLOCK, + .version = { + .major_version = 5, + .minor_version = 0, + }, + /* + * Note: this size isn't just the payload size following the header, like it is everywhere + * else in VDO. + */ + .size = sizeof(struct geometry_block) + sizeof(struct volume_geometry), +}; + +static const struct header GEOMETRY_BLOCK_HEADER_4_0 = { + .id = VDO_GEOMETRY_BLOCK, + .version = { + .major_version = 4, + .minor_version = 0, + }, + /* + * Note: this size isn't just the payload size following the header, like it is everywhere + * else in VDO. + */ + .size = sizeof(struct geometry_block) + sizeof(struct volume_geometry_4_0), +}; + +const u8 VDO_GEOMETRY_MAGIC_NUMBER[VDO_GEOMETRY_MAGIC_NUMBER_SIZE + 1] = "dmvdo001"; + +static const release_version_number_t COMPATIBLE_RELEASE_VERSIONS[] = { + VDO_MAGNESIUM_RELEASE_VERSION_NUMBER, + VDO_ALUMINUM_RELEASE_VERSION_NUMBER, +}; + +enum { + PAGE_HEADER_4_1_SIZE = 8 + 8 + 8 + 1 + 1 + 1 + 1, +}; + +static const struct version_number BLOCK_MAP_4_1 = { + .major_version = 4, + .minor_version = 1, +}; + +const struct header VDO_BLOCK_MAP_HEADER_2_0 = { + .id = VDO_BLOCK_MAP, + .version = { + .major_version = 2, + .minor_version = 0, + }, + .size = sizeof(struct block_map_state_2_0), +}; + +const struct header VDO_RECOVERY_JOURNAL_HEADER_7_0 = { + .id = VDO_RECOVERY_JOURNAL, + .version = { + .major_version = 7, + .minor_version = 0, + }, + .size = sizeof(struct recovery_journal_state_7_0), +}; + +const struct header VDO_SLAB_DEPOT_HEADER_2_0 = { + .id = VDO_SLAB_DEPOT, + .version = { + .major_version = 2, + .minor_version = 0, + }, + .size = sizeof(struct slab_depot_state_2_0), +}; + +const struct header VDO_LAYOUT_HEADER_3_0 = { + .id = VDO_LAYOUT, + .version = { + .major_version = 3, + .minor_version = 0, + }, + .size = sizeof(struct layout_3_0) + (sizeof(struct partition_3_0) * VDO_PARTITION_COUNT), +}; + +static const enum partition_id REQUIRED_PARTITIONS[] = { + VDO_BLOCK_MAP_PARTITION, + VDO_SLAB_DEPOT_PARTITION, + VDO_RECOVERY_JOURNAL_PARTITION, + VDO_SLAB_SUMMARY_PARTITION, +}; + +/* + * The current version for the data encoded in the super block. This must be changed any time there + * is a change to encoding of the component data of any VDO component. + */ +static const struct version_number VDO_COMPONENT_DATA_41_0 = { + .major_version = 41, + .minor_version = 0, +}; + +const struct version_number VDO_VOLUME_VERSION_67_0 = { + .major_version = 67, + .minor_version = 0, +}; + +static const struct header SUPER_BLOCK_HEADER_12_0 = { + .id = VDO_SUPER_BLOCK, + .version = { + .major_version = 12, + .minor_version = 0, + }, + + /* This is the minimum size, if the super block contains no components. */ + .size = VDO_SUPER_BLOCK_FIXED_SIZE - VDO_ENCODED_HEADER_SIZE, +}; + +/** + * validate_version() - Check whether a version matches an expected version. + * @expected_version: The expected version. + * @actual_version: The version being validated. + * @component_name: The name of the component or the calling function (for error logging). + * + * Logs an error describing a mismatch. + * + * Return: VDO_SUCCESS if the versions are the same, + * VDO_UNSUPPORTED_VERSION if the versions don't match. + */ +static int __must_check validate_version(struct version_number expected_version, + struct version_number actual_version, + const char *component_name) +{ + if (!vdo_are_same_version(expected_version, actual_version)) + return uds_log_error_strerror(VDO_UNSUPPORTED_VERSION, + "%s version mismatch, expected %d.%d, got %d.%d", + component_name, + expected_version.major_version, + expected_version.minor_version, + actual_version.major_version, + actual_version.minor_version); + return VDO_SUCCESS; +} + +/** + * vdo_validate_header() - Check whether a header matches expectations. + * @expected_header: The expected header. + * @actual_header: The header being validated. + * @exact_size: If true, the size fields of the two headers must be the same, otherwise it is + * required that actual_header.size >= expected_header.size. + * @name: The name of the component or the calling function (for error logging). + * + * Logs an error describing the first mismatch found. + * + * Return: VDO_SUCCESS if the header meets expectations, + * VDO_INCORRECT_COMPONENT if the component ids don't match, + * VDO_UNSUPPORTED_VERSION if the versions or sizes don't match. + */ +int vdo_validate_header(const struct header *expected_header, + const struct header *actual_header, + bool exact_size, + const char *name) +{ + int result; + + if (expected_header->id != actual_header->id) + return uds_log_error_strerror(VDO_INCORRECT_COMPONENT, + "%s ID mismatch, expected %d, got %d", + name, + expected_header->id, + actual_header->id); + + result = validate_version(expected_header->version, actual_header->version, name); + if (result != VDO_SUCCESS) + return result; + + if ((expected_header->size > actual_header->size) || + (exact_size && (expected_header->size < actual_header->size))) + return uds_log_error_strerror(VDO_UNSUPPORTED_VERSION, + "%s size mismatch, expected %zu, got %zu", + name, + expected_header->size, + actual_header->size); + + return VDO_SUCCESS; +} + +static void encode_version_number(u8 *buffer, size_t *offset, struct version_number version) +{ + struct packed_version_number packed = vdo_pack_version_number(version); + + memcpy(buffer + *offset, &packed, sizeof(packed)); + *offset += sizeof(packed); +} + +void vdo_encode_header(u8 *buffer, size_t *offset, const struct header *header) +{ + struct packed_header packed = vdo_pack_header(header); + + memcpy(buffer + *offset, &packed, sizeof(packed)); + *offset += sizeof(packed); +} + +static void decode_version_number(u8 *buffer, size_t *offset, struct version_number *version) +{ + struct packed_version_number packed; + + memcpy(&packed, buffer + *offset, sizeof(packed)); + *offset += sizeof(packed); + *version = vdo_unpack_version_number(packed); +} + +void vdo_decode_header(u8 *buffer, size_t *offset, struct header *header) +{ + struct packed_header packed; + + memcpy(&packed, buffer + *offset, sizeof(packed)); + *offset += sizeof(packed); + + *header = vdo_unpack_header(&packed); +} + +/** + * is_loadable_release_version() - Determine whether the supplied release version can be understood + * by the VDO code. + * @version: The release version number to check. + * + * Return: True if the given version can be loaded. + */ +static inline bool is_loadable_release_version(release_version_number_t version) +{ + unsigned int i; + + if (version == VDO_CURRENT_RELEASE_VERSION_NUMBER) + return true; + + for (i = 0; i < ARRAY_SIZE(COMPATIBLE_RELEASE_VERSIONS); i++) + if (version == COMPATIBLE_RELEASE_VERSIONS[i]) + return true; + + return false; +} + +/** + * decode_volume_geometry() - Decode the on-disk representation of a volume geometry from a buffer. + * @buffer: A buffer to decode from. + * @offset: The offset in the buffer at which to decode. + * @geometry: The structure to receive the decoded fields. + * @version: The geometry block version to decode. + */ +static void +decode_volume_geometry(u8 *buffer, size_t *offset, struct volume_geometry *geometry, u32 version) +{ + release_version_number_t release_version; + enum volume_region_id id; + nonce_t nonce; + block_count_t bio_offset = 0; + u32 mem; + bool sparse; + + decode_u32_le(buffer, offset, &release_version); + decode_u64_le(buffer, offset, &nonce); + geometry->release_version = release_version; + geometry->nonce = nonce; + + memcpy((unsigned char *) &geometry->uuid, buffer + *offset, sizeof(uuid_t)); + *offset += sizeof(uuid_t); + + if (version > 4) + decode_u64_le(buffer, offset, &bio_offset); + geometry->bio_offset = bio_offset; + + for (id = 0; id < VDO_VOLUME_REGION_COUNT; id++) { + physical_block_number_t start_block; + enum volume_region_id saved_id; + + decode_u32_le(buffer, offset, &saved_id); + decode_u64_le(buffer, offset, &start_block); + + geometry->regions[id] = (struct volume_region) { + .id = saved_id, + .start_block = start_block, + }; + } + + decode_u32_le(buffer, offset, &mem); + *offset += sizeof(u32); + sparse = buffer[(*offset)++]; + + geometry->index_config = (struct index_config) { + .mem = mem, + .sparse = sparse, + }; +} + +/** + * vdo_parse_geometry_block() - Decode and validate an encoded geometry block. + * @block: The encoded geometry block. + * @geometry: The structure to receive the decoded fields. + */ +int __must_check vdo_parse_geometry_block(u8 *block, struct volume_geometry *geometry) +{ + u32 checksum, saved_checksum; + struct header header; + size_t offset = 0; + int result; + + if (memcmp(block, VDO_GEOMETRY_MAGIC_NUMBER, VDO_GEOMETRY_MAGIC_NUMBER_SIZE) != 0) + return VDO_BAD_MAGIC; + offset += VDO_GEOMETRY_MAGIC_NUMBER_SIZE; + + vdo_decode_header(block, &offset, &header); + if (header.version.major_version <= 4) + result = vdo_validate_header(&GEOMETRY_BLOCK_HEADER_4_0, &header, true, __func__); + else + result = vdo_validate_header(&GEOMETRY_BLOCK_HEADER_5_0, &header, true, __func__); + if (result != VDO_SUCCESS) + return result; + + decode_volume_geometry(block, &offset, geometry, header.version.major_version); + + result = ASSERT(header.size == offset + sizeof(u32), + "should have decoded up to the geometry checksum"); + if (result != VDO_SUCCESS) + return result; + + /* Decode and verify the checksum. */ + checksum = vdo_crc32(block, offset); + decode_u32_le(block, &offset, &saved_checksum); + + if (!is_loadable_release_version(geometry->release_version)) + return uds_log_error_strerror(VDO_UNSUPPORTED_VERSION, + "release version %d cannot be loaded", + geometry->release_version); + + return ((checksum == saved_checksum) ? VDO_SUCCESS : VDO_CHECKSUM_MISMATCH); +} + +struct block_map_page *vdo_format_block_map_page(void *buffer, + nonce_t nonce, + physical_block_number_t pbn, + bool initialized) +{ + struct block_map_page *page = (struct block_map_page *) buffer; + + memset(buffer, 0, VDO_BLOCK_SIZE); + page->version = vdo_pack_version_number(BLOCK_MAP_4_1); + page->header.nonce = __cpu_to_le64(nonce); + page->header.pbn = __cpu_to_le64(pbn); + page->header.initialized = initialized; + return page; +} + +enum block_map_page_validity +vdo_validate_block_map_page(struct block_map_page *page, + nonce_t nonce, + physical_block_number_t pbn) +{ + STATIC_ASSERT_SIZEOF(struct block_map_page_header, PAGE_HEADER_4_1_SIZE); + + if (!vdo_are_same_version(BLOCK_MAP_4_1, vdo_unpack_version_number(page->version)) || + !page->header.initialized || + (nonce != __le64_to_cpu(page->header.nonce))) + return VDO_BLOCK_MAP_PAGE_INVALID; + + if (pbn != vdo_get_block_map_page_pbn(page)) + return VDO_BLOCK_MAP_PAGE_BAD; + + return VDO_BLOCK_MAP_PAGE_VALID; +} + +static int +decode_block_map_state_2_0(u8 *buffer, size_t *offset, struct block_map_state_2_0 *state) +{ + size_t initial_offset; + block_count_t flat_page_count, root_count; + physical_block_number_t flat_page_origin, root_origin; + struct header header; + int result; + + vdo_decode_header(buffer, offset, &header); + result = vdo_validate_header(&VDO_BLOCK_MAP_HEADER_2_0, &header, true, __func__); + if (result != VDO_SUCCESS) + return result; + + initial_offset = *offset; + + decode_u64_le(buffer, offset, &flat_page_origin); + result = ASSERT(flat_page_origin == VDO_BLOCK_MAP_FLAT_PAGE_ORIGIN, + "Flat page origin must be %u (recorded as %llu)", + VDO_BLOCK_MAP_FLAT_PAGE_ORIGIN, + (unsigned long long) state->flat_page_origin); + if (result != UDS_SUCCESS) + return result; + + decode_u64_le(buffer, offset, &flat_page_count); + result = ASSERT(flat_page_count == 0, + "Flat page count must be 0 (recorded as %llu)", + (unsigned long long) state->flat_page_count); + if (result != UDS_SUCCESS) + return result; + + decode_u64_le(buffer, offset, &root_origin); + decode_u64_le(buffer, offset, &root_count); + + result = ASSERT(VDO_BLOCK_MAP_HEADER_2_0.size == *offset - initial_offset, + "decoded block map component size must match header size"); + if (result != VDO_SUCCESS) + return result; + + *state = (struct block_map_state_2_0) { + .flat_page_origin = flat_page_origin, + .flat_page_count = flat_page_count, + .root_origin = root_origin, + .root_count = root_count, + }; + + return VDO_SUCCESS; +} + +static void +encode_block_map_state_2_0(u8 *buffer, size_t *offset, struct block_map_state_2_0 state) +{ + size_t initial_offset; + + vdo_encode_header(buffer, offset, &VDO_BLOCK_MAP_HEADER_2_0); + + initial_offset = *offset; + encode_u64_le(buffer, offset, state.flat_page_origin); + encode_u64_le(buffer, offset, state.flat_page_count); + encode_u64_le(buffer, offset, state.root_origin); + encode_u64_le(buffer, offset, state.root_count); + + ASSERT_LOG_ONLY(VDO_BLOCK_MAP_HEADER_2_0.size == *offset - initial_offset, + "encoded block map component size must match header size"); +} + +/** + * vdo_compute_new_forest_pages() - Compute the number of pages which must be allocated at each + * level in order to grow the forest to a new number of entries. + * @entries: The new number of entries the block map must address. + * + * Return: The total number of non-leaf pages required. + */ +block_count_t vdo_compute_new_forest_pages(root_count_t root_count, + struct boundary *old_sizes, + block_count_t entries, + struct boundary *new_sizes) +{ + page_count_t leaf_pages = max(vdo_compute_block_map_page_count(entries), 1U); + page_count_t level_size = DIV_ROUND_UP(leaf_pages, root_count); + block_count_t total_pages = 0; + height_t height; + + for (height = 0; height < VDO_BLOCK_MAP_TREE_HEIGHT; height++) { + block_count_t new_pages; + + level_size = DIV_ROUND_UP(level_size, VDO_BLOCK_MAP_ENTRIES_PER_PAGE); + new_sizes->levels[height] = level_size; + new_pages = level_size; + if (old_sizes != NULL) + new_pages -= old_sizes->levels[height]; + total_pages += (new_pages * root_count); + } + + return total_pages; +} + +/** + * encode_recovery_journal_state_7_0() - Encode the state of a recovery journal. + * + * Return: VDO_SUCCESS or an error code. + */ +static void +encode_recovery_journal_state_7_0(u8 *buffer, + size_t *offset, + struct recovery_journal_state_7_0 state) +{ + size_t initial_offset; + + vdo_encode_header(buffer, offset, &VDO_RECOVERY_JOURNAL_HEADER_7_0); + + initial_offset = *offset; + encode_u64_le(buffer, offset, state.journal_start); + encode_u64_le(buffer, offset, state.logical_blocks_used); + encode_u64_le(buffer, offset, state.block_map_data_blocks); + + ASSERT_LOG_ONLY(VDO_RECOVERY_JOURNAL_HEADER_7_0.size == *offset - initial_offset, + "encoded recovery journal component size must match header size"); +} + +/** + * decode_recovery_journal_state_7_0() - Decode the state of a recovery journal saved in a buffer. + * @buffer: The buffer containing the saved state. + * @state: A pointer to a recovery journal state to hold the result of a successful decode. + * + * Return: VDO_SUCCESS or an error code. + */ +static int __must_check +decode_recovery_journal_state_7_0(u8 *buffer, + size_t *offset, + struct recovery_journal_state_7_0 *state) +{ + struct header header; + int result; + size_t initial_offset; + sequence_number_t journal_start; + block_count_t logical_blocks_used, block_map_data_blocks; + + vdo_decode_header(buffer, offset, &header); + result = vdo_validate_header(&VDO_RECOVERY_JOURNAL_HEADER_7_0, &header, true, __func__); + if (result != VDO_SUCCESS) + return result; + + initial_offset = *offset; + decode_u64_le(buffer, offset, &journal_start); + decode_u64_le(buffer, offset, &logical_blocks_used); + decode_u64_le(buffer, offset, &block_map_data_blocks); + + result = ASSERT(VDO_RECOVERY_JOURNAL_HEADER_7_0.size == *offset - initial_offset, + "decoded recovery journal component size must match header size"); + if (result != UDS_SUCCESS) + return result; + + *state = (struct recovery_journal_state_7_0) { + .journal_start = journal_start, + .logical_blocks_used = logical_blocks_used, + .block_map_data_blocks = block_map_data_blocks, + }; + + return VDO_SUCCESS; +} + +/** + * vdo_get_journal_operation_name() - Get the name of a journal operation. + * @operation: The operation to name. + * + * Return: The name of the operation. + */ +const char *vdo_get_journal_operation_name(enum journal_operation operation) +{ + switch (operation) { + case VDO_JOURNAL_DATA_REMAPPING: + return "data remapping"; + + case VDO_JOURNAL_BLOCK_MAP_REMAPPING: + return "block map remapping"; + + default: + return "unknown journal operation"; + } +} + +/** + * encode_slab_depot_state_2_0() - Encode the state of a slab depot into a buffer. + * + * Return: UDS_SUCCESS or an error. + */ +static void +encode_slab_depot_state_2_0(u8 *buffer, size_t *offset, struct slab_depot_state_2_0 state) +{ + size_t initial_offset; + + vdo_encode_header(buffer, offset, &VDO_SLAB_DEPOT_HEADER_2_0); + + initial_offset = *offset; + encode_u64_le(buffer, offset, state.slab_config.slab_blocks); + encode_u64_le(buffer, offset, state.slab_config.data_blocks); + encode_u64_le(buffer, offset, state.slab_config.reference_count_blocks); + encode_u64_le(buffer, offset, state.slab_config.slab_journal_blocks); + encode_u64_le(buffer, offset, state.slab_config.slab_journal_flushing_threshold); + encode_u64_le(buffer, offset, state.slab_config.slab_journal_blocking_threshold); + encode_u64_le(buffer, offset, state.slab_config.slab_journal_scrubbing_threshold); + encode_u64_le(buffer, offset, state.first_block); + encode_u64_le(buffer, offset, state.last_block); + buffer[(*offset)++] = state.zone_count; + + ASSERT_LOG_ONLY(VDO_SLAB_DEPOT_HEADER_2_0.size == *offset - initial_offset, + "encoded block map component size must match header size"); +} + +/** + * decode_slab_depot_state_2_0() - Decode slab depot component state version 2.0 from a buffer. + * + * Return: UDS_SUCCESS or an error code. + */ +static int +decode_slab_depot_state_2_0(u8 *buffer, size_t *offset, struct slab_depot_state_2_0 *state) +{ + struct header header; + int result; + size_t initial_offset; + struct slab_config slab_config; + block_count_t count; + physical_block_number_t first_block, last_block; + zone_count_t zone_count; + + vdo_decode_header(buffer, offset, &header); + result = vdo_validate_header(&VDO_SLAB_DEPOT_HEADER_2_0, &header, true, __func__); + if (result != VDO_SUCCESS) + return result; + + initial_offset = *offset; + decode_u64_le(buffer, offset, &count); + slab_config.slab_blocks = count; + + decode_u64_le(buffer, offset, &count); + slab_config.data_blocks = count; + + decode_u64_le(buffer, offset, &count); + slab_config.reference_count_blocks = count; + + decode_u64_le(buffer, offset, &count); + slab_config.slab_journal_blocks = count; + + decode_u64_le(buffer, offset, &count); + slab_config.slab_journal_flushing_threshold = count; + + decode_u64_le(buffer, offset, &count); + slab_config.slab_journal_blocking_threshold = count; + + decode_u64_le(buffer, offset, &count); + slab_config.slab_journal_scrubbing_threshold = count; + + decode_u64_le(buffer, offset, &first_block); + decode_u64_le(buffer, offset, &last_block); + zone_count = buffer[(*offset)++]; + + result = ASSERT(VDO_SLAB_DEPOT_HEADER_2_0.size == *offset - initial_offset, + "decoded slab depot component size must match header size"); + if (result != UDS_SUCCESS) + return result; + + *state = (struct slab_depot_state_2_0) { + .slab_config = slab_config, + .first_block = first_block, + .last_block = last_block, + .zone_count = zone_count, + }; + + return VDO_SUCCESS; +} + +/** + * vdo_configure_slab_depot() - Configure the slab depot. + * @partition: The slab depot partition + * @slab_config: The configuration of a single slab. + * @zone_count: The number of zones the depot will use. + * @state: The state structure to be configured. + * + * Configures the slab_depot for the specified storage capacity, finding the number of data blocks + * that will fit and still leave room for the depot metadata, then return the saved state for that + * configuration. + * + * Return: VDO_SUCCESS or an error code. + */ +int vdo_configure_slab_depot(const struct partition *partition, + struct slab_config slab_config, + zone_count_t zone_count, + struct slab_depot_state_2_0 *state) +{ + block_count_t total_slab_blocks, total_data_blocks; + size_t slab_count; + physical_block_number_t last_block; + block_count_t slab_size = slab_config.slab_blocks; + + uds_log_debug("slabDepot %s(block_count=%llu, first_block=%llu, slab_size=%llu, zone_count=%u)", + __func__, + (unsigned long long) partition->count, + (unsigned long long) partition->offset, + (unsigned long long) slab_size, + zone_count); + + /* We do not allow runt slabs, so we waste up to a slab's worth. */ + slab_count = (partition->count / slab_size); + if (slab_count == 0) + return VDO_NO_SPACE; + + if (slab_count > MAX_VDO_SLABS) + return VDO_TOO_MANY_SLABS; + + total_slab_blocks = slab_count * slab_config.slab_blocks; + total_data_blocks = slab_count * slab_config.data_blocks; + last_block = partition->offset + total_slab_blocks; + + *state = (struct slab_depot_state_2_0) { + .slab_config = slab_config, + .first_block = partition->offset, + .last_block = last_block, + .zone_count = zone_count, + }; + + uds_log_debug("slab_depot last_block=%llu, total_data_blocks=%llu, slab_count=%zu, left_over=%llu", + (unsigned long long) last_block, + (unsigned long long) total_data_blocks, + slab_count, + (unsigned long long) (partition->count - (last_block - partition->offset))); + + return VDO_SUCCESS; +} + +/** + * vdo_configure_slab() - Measure and initialize the configuration to use for each slab. + * @slab_size: The number of blocks per slab. + * @slab_journal_blocks: The number of blocks for the slab journal. + * @slab_config: The slab configuration to initialize. + * + * Return: VDO_SUCCESS or an error code. + */ +int vdo_configure_slab(block_count_t slab_size, + block_count_t slab_journal_blocks, + struct slab_config *slab_config) +{ + block_count_t ref_blocks, meta_blocks, data_blocks; + block_count_t flushing_threshold, remaining, blocking_threshold; + block_count_t minimal_extra_space, scrubbing_threshold; + + if (slab_journal_blocks >= slab_size) + return VDO_BAD_CONFIGURATION; + + /* + * This calculation should technically be a recurrence, but the total number of metadata + * blocks is currently less than a single block of ref_counts, so we'd gain at most one + * data block in each slab with more iteration. + */ + ref_blocks = vdo_get_saved_reference_count_size(slab_size - slab_journal_blocks); + meta_blocks = (ref_blocks + slab_journal_blocks); + + /* Make sure test code hasn't configured slabs to be too small. */ + if (meta_blocks >= slab_size) + return VDO_BAD_CONFIGURATION; + + /* + * If the slab size is very small, assume this must be a unit test and override the number + * of data blocks to be a power of two (wasting blocks in the slab). Many tests need their + * data_blocks fields to be the exact capacity of the configured volume, and that used to + * fall out since they use a power of two for the number of data blocks, the slab size was + * a power of two, and every block in a slab was a data block. + * + * TODO: Try to figure out some way of structuring testParameters and unit tests so this + * hack isn't needed without having to edit several unit tests every time the metadata size + * changes by one block. + */ + data_blocks = slab_size - meta_blocks; + if ((slab_size < 1024) && !is_power_of_2(data_blocks)) + data_blocks = ((block_count_t) 1 << ilog2(data_blocks)); + + /* + * Configure the slab journal thresholds. The flush threshold is 168 of 224 blocks in + * production, or 3/4ths, so we use this ratio for all sizes. + */ + flushing_threshold = ((slab_journal_blocks * 3) + 3) / 4; + /* + * The blocking threshold should be far enough from the flushing threshold to not produce + * delays, but far enough from the end of the journal to allow multiple successive recovery + * failures. + */ + remaining = slab_journal_blocks - flushing_threshold; + blocking_threshold = flushing_threshold + ((remaining * 5) / 7); + /* The scrubbing threshold should be at least 2048 entries before the end of the journal. */ + minimal_extra_space = 1 + (MAXIMUM_VDO_USER_VIOS / VDO_SLAB_JOURNAL_FULL_ENTRIES_PER_BLOCK); + scrubbing_threshold = blocking_threshold; + if (slab_journal_blocks > minimal_extra_space) + scrubbing_threshold = slab_journal_blocks - minimal_extra_space; + if (blocking_threshold > scrubbing_threshold) + blocking_threshold = scrubbing_threshold; + + *slab_config = (struct slab_config) { + .slab_blocks = slab_size, + .data_blocks = data_blocks, + .reference_count_blocks = ref_blocks, + .slab_journal_blocks = slab_journal_blocks, + .slab_journal_flushing_threshold = flushing_threshold, + .slab_journal_blocking_threshold = blocking_threshold, + .slab_journal_scrubbing_threshold = scrubbing_threshold}; + return VDO_SUCCESS; +} + +/** + * vdo_decode_slab_journal_entry() - Decode a slab journal entry. + * @block: The journal block holding the entry. + * @entry_count: The number of the entry. + * + * Return: The decoded entry. + */ +struct slab_journal_entry +vdo_decode_slab_journal_entry(struct packed_slab_journal_block *block, + journal_entry_count_t entry_count) +{ + struct slab_journal_entry entry = + vdo_unpack_slab_journal_entry(&block->payload.entries[entry_count]); + + if (block->header.has_block_map_increments && + ((block->payload.full_entries.entry_types[entry_count / 8] & + ((u8)1 << (entry_count % 8))) != 0)) + entry.operation = VDO_JOURNAL_BLOCK_MAP_REMAPPING; + + return entry; +} + +/** + * allocate_partition() - Allocate a partition and add it to a layout. + * @layout: The layout containing the partition. + * @id: The id of the partition. + * @offset: The offset into the layout at which the partition begins. + * @size: The size of the partition in blocks. + * + * Return: VDO_SUCCESS or an error. + */ +static int allocate_partition(struct layout *layout, + u8 id, + physical_block_number_t offset, + block_count_t size) +{ + struct partition *partition; + int result; + + result = UDS_ALLOCATE(1, struct partition, __func__, &partition); + if (result != UDS_SUCCESS) + return result; + + partition->id = id; + partition->offset = offset; + partition->count = size; + partition->next = layout->head; + layout->head = partition; + + return VDO_SUCCESS; +} + +/** + * make_partition() - Create a new partition from the beginning or end of the unused space in a + * layout. + * @layout: The layout. + * @id: The id of the partition to make. + * @size: The number of blocks to carve out; if 0, all remaining space will be used. + * @beginning: True if the partition should start at the beginning of the unused space. + * + * Return: A success or error code, particularly VDO_NO_SPACE if there are fewer than size blocks + * remaining. + */ +static int __must_check +make_partition(struct layout *layout, + enum partition_id id, + block_count_t size, + bool beginning) +{ + int result; + physical_block_number_t offset; + block_count_t free_blocks = layout->last_free - layout->first_free; + + if (size == 0) { + if (free_blocks == 0) + return VDO_NO_SPACE; + size = free_blocks; + } else if (size > free_blocks) { + return VDO_NO_SPACE; + } + + result = vdo_get_partition(layout, id, NULL); + if (result != VDO_UNKNOWN_PARTITION) + return VDO_PARTITION_EXISTS; + + offset = beginning ? layout->first_free : (layout->last_free - size); + + result = allocate_partition(layout, id, offset, size); + if (result != VDO_SUCCESS) + return result; + + layout->num_partitions++; + if (beginning) + layout->first_free += size; + else + layout->last_free = layout->last_free - size; + + return VDO_SUCCESS; +} + +/** + * vdo_initialize_layout() - Lay out the partitions of a vdo. + * @size: The entire size of the vdo. + * @origin: The start of the layout on the underlying storage in blocks. + * @block_map_blocks: The size of the block map partition. + * @journal_blocks: The size of the journal partition. + * @summary_blocks: The size of the slab summary partition. + * @layout: The layout to initialize. + * + * Return: VDO_SUCCESS or an error. + */ +int vdo_initialize_layout(block_count_t size, + physical_block_number_t offset, + block_count_t block_map_blocks, + block_count_t journal_blocks, + block_count_t summary_blocks, + struct layout *layout) +{ + int result; + block_count_t necessary_size = + (offset + block_map_blocks + journal_blocks + summary_blocks); + + if (necessary_size > size) + return uds_log_error_strerror(VDO_NO_SPACE, "Not enough space to make a VDO"); + + *layout = (struct layout) { + .start = offset, + .size = size, + .first_free = offset, + .last_free = size, + .num_partitions = 0, + .head = NULL, + }; + + result = make_partition(layout, VDO_BLOCK_MAP_PARTITION, block_map_blocks, true); + if (result != VDO_SUCCESS) { + vdo_uninitialize_layout(layout); + return result; + } + + result = make_partition(layout, VDO_SLAB_SUMMARY_PARTITION, summary_blocks, false); + if (result != VDO_SUCCESS) { + vdo_uninitialize_layout(layout); + return result; + } + + result = make_partition(layout, VDO_RECOVERY_JOURNAL_PARTITION, journal_blocks, false); + if (result != VDO_SUCCESS) { + vdo_uninitialize_layout(layout); + return result; + } + + result = make_partition(layout, VDO_SLAB_DEPOT_PARTITION, 0, true); + if (result != VDO_SUCCESS) + vdo_uninitialize_layout(layout); + + return result; +} + +/** + * vdo_uninitialize_layout() - Clean up a layout. + * @layout: The layout to clean up. + * + * All partitions created by this layout become invalid pointers. + */ +void vdo_uninitialize_layout(struct layout *layout) +{ + while (layout->head != NULL) { + struct partition *part = layout->head; + + layout->head = part->next; + UDS_FREE(part); + } + + memset(layout, 0, sizeof(struct layout)); +} + +/** + * vdo_get_partition() - Get a partition by id. + * @layout: The layout from which to get a partition. + * @id: The id of the partition. + * @partition_ptr: A pointer to hold the partition. + * + * Return: VDO_SUCCESS or an error. + */ +int vdo_get_partition(struct layout *layout, + enum partition_id id, + struct partition **partition_ptr) +{ + struct partition *partition; + + for (partition = layout->head; partition != NULL; partition = partition->next) { + if (partition->id == id) { + if (partition_ptr != NULL) + *partition_ptr = partition; + return VDO_SUCCESS; + } + } + + return VDO_UNKNOWN_PARTITION; +} + +/** + * vdo_get_known_partition() - Get a partition by id from a validated layout. + * @layout: The layout from which to get a partition. + * @id: The id of the partition. + * + * Return: the partition + */ +struct partition *vdo_get_known_partition(struct layout *layout, enum partition_id id) +{ + struct partition *partition; + int result = vdo_get_partition(layout, id, &partition); + + ASSERT_LOG_ONLY(result == VDO_SUCCESS, "layout has expected partition: %u", id); + + return partition; +} + +static void encode_layout(u8 *buffer, size_t *offset, const struct layout *layout) +{ + const struct partition *partition; + size_t initial_offset; + struct header header = VDO_LAYOUT_HEADER_3_0; + + STATIC_ASSERT_SIZEOF(enum partition_id, sizeof(u8)); + ASSERT_LOG_ONLY(layout->num_partitions <= U8_MAX, + "layout partition count must fit in a byte"); + + vdo_encode_header(buffer, offset, &header); + + initial_offset = *offset; + encode_u64_le(buffer, offset, layout->first_free); + encode_u64_le(buffer, offset, layout->last_free); + buffer[(*offset)++] = layout->num_partitions; + + ASSERT_LOG_ONLY(sizeof(struct layout_3_0) == *offset - initial_offset, + "encoded size of a layout header must match structure"); + + for (partition = layout->head; partition != NULL; partition = partition->next) { + buffer[(*offset)++] = partition->id; + encode_u64_le(buffer, offset, partition->offset); + /* This field only exists for backwards compatibility */ + encode_u64_le(buffer, offset, 0); + encode_u64_le(buffer, offset, partition->count); + } + + ASSERT_LOG_ONLY(header.size == *offset - initial_offset, + "encoded size of a layout must match header size"); +} + +static int +decode_layout(u8 *buffer, + size_t *offset, + physical_block_number_t start, + block_count_t size, + struct layout *layout) +{ + struct header header; + struct layout_3_0 layout_header; + struct partition *partition; + size_t initial_offset; + physical_block_number_t first_free, last_free; + u8 partition_count; + u8 i; + int result; + + vdo_decode_header(buffer, offset, &header); + /* Layout is variable size, so only do a minimum size check here. */ + result = vdo_validate_header(&VDO_LAYOUT_HEADER_3_0, &header, false, __func__); + if (result != VDO_SUCCESS) + return result; + + initial_offset = *offset; + decode_u64_le(buffer, offset, &first_free); + decode_u64_le(buffer, offset, &last_free); + partition_count = buffer[(*offset)++]; + layout_header = (struct layout_3_0) { + .first_free = first_free, + .last_free = last_free, + .partition_count = partition_count, + }; + + result = ASSERT(sizeof(struct layout_3_0) == *offset - initial_offset, + "decoded size of a layout header must match structure"); + if (result != VDO_SUCCESS) + return result; + + layout->start = start; + layout->size = size; + layout->first_free = layout_header.first_free; + layout->last_free = layout_header.last_free; + layout->num_partitions = layout_header.partition_count; + + if (layout->num_partitions > VDO_PARTITION_COUNT) + return uds_log_error_strerror(VDO_UNKNOWN_PARTITION, + "layout has extra partitions"); + + for (i = 0; i < layout->num_partitions; i++) { + u8 id; + u64 partition_offset, count; + + id = buffer[(*offset)++]; + decode_u64_le(buffer, offset, &partition_offset); + *offset += sizeof(u64); + decode_u64_le(buffer, offset, &count); + + result = allocate_partition(layout, id, partition_offset, count); + if (result != VDO_SUCCESS) { + vdo_uninitialize_layout(layout); + return result; + } + } + + /* Validate that the layout has all (and only) the required partitions */ + for (i = 0; i < VDO_PARTITION_COUNT; i++) { + result = vdo_get_partition(layout, REQUIRED_PARTITIONS[i], &partition); + if (result != VDO_SUCCESS) { + vdo_uninitialize_layout(layout); + return uds_log_error_strerror(result, + "layout is missing required partition %u", + REQUIRED_PARTITIONS[i]); + } + + start += partition->count; + } + + if (start != size) { + vdo_uninitialize_layout(layout); + return uds_log_error_strerror(UDS_BAD_STATE, "partitions do not cover the layout"); + } + + return VDO_SUCCESS; +} + +/** + * pack_vdo_config() - Convert a vdo_config to its packed on-disk representation. + * @config: The vdo config to convert. + * + * Return: The platform-independent representation of the config. + */ +static struct packed_vdo_config pack_vdo_config(struct vdo_config config) +{ + return (struct packed_vdo_config) { + .logical_blocks = __cpu_to_le64(config.logical_blocks), + .physical_blocks = __cpu_to_le64(config.physical_blocks), + .slab_size = __cpu_to_le64(config.slab_size), + .recovery_journal_size = __cpu_to_le64(config.recovery_journal_size), + .slab_journal_blocks = __cpu_to_le64(config.slab_journal_blocks), + }; +} + +/** + * pack_vdo_component() - Convert a vdo_component to its packed on-disk representation. + * @component: The VDO component data to convert. + * + * Return: The platform-independent representation of the component. + */ +static struct packed_vdo_component_41_0 pack_vdo_component(const struct vdo_component component) +{ + return (struct packed_vdo_component_41_0) { + .state = __cpu_to_le32(component.state), + .complete_recoveries = __cpu_to_le64(component.complete_recoveries), + .read_only_recoveries = __cpu_to_le64(component.read_only_recoveries), + .config = pack_vdo_config(component.config), + .nonce = __cpu_to_le64(component.nonce), + }; +} + +static void encode_vdo_component(u8 *buffer, size_t *offset, struct vdo_component component) +{ + struct packed_vdo_component_41_0 packed; + + encode_version_number(buffer, offset, VDO_COMPONENT_DATA_41_0); + packed = pack_vdo_component(component); + memcpy(buffer + *offset, &packed, sizeof(packed)); + *offset += sizeof(packed); +} + +/** + * unpack_vdo_config() - Convert a packed_vdo_config to its native in-memory representation. + * @config: The packed vdo config to convert. + * + * Return: The native in-memory representation of the vdo config. + */ +static struct vdo_config unpack_vdo_config(struct packed_vdo_config config) +{ + return (struct vdo_config) { + .logical_blocks = __le64_to_cpu(config.logical_blocks), + .physical_blocks = __le64_to_cpu(config.physical_blocks), + .slab_size = __le64_to_cpu(config.slab_size), + .recovery_journal_size = __le64_to_cpu(config.recovery_journal_size), + .slab_journal_blocks = __le64_to_cpu(config.slab_journal_blocks), + }; +} + +/** + * unpack_vdo_component_41_0() - Convert a packed_vdo_component_41_0 to its native in-memory + * representation. + * @component: The packed vdo component data to convert. + * + * Return: The native in-memory representation of the component. + */ +static struct vdo_component +unpack_vdo_component_41_0(struct packed_vdo_component_41_0 component) +{ + return (struct vdo_component) { + .state = __le32_to_cpu(component.state), + .complete_recoveries = __le64_to_cpu(component.complete_recoveries), + .read_only_recoveries = __le64_to_cpu(component.read_only_recoveries), + .config = unpack_vdo_config(component.config), + .nonce = __le64_to_cpu(component.nonce), + }; +} + +/** + * vdo_decode_component() - Decode the component data for the vdo itself out of the super block. + * + * Return: VDO_SUCCESS or an error. + */ +static int decode_vdo_component(u8 *buffer, size_t *offset, struct vdo_component *component) +{ + struct version_number version; + struct packed_vdo_component_41_0 packed; + int result; + + decode_version_number(buffer, offset, &version); + result = validate_version(version, VDO_COMPONENT_DATA_41_0, "VDO component data"); + if (result != VDO_SUCCESS) + return result; + + memcpy(&packed, buffer + *offset, sizeof(packed)); + *offset += sizeof(packed); + *component = unpack_vdo_component_41_0(packed); + return VDO_SUCCESS; +} + +/** + * vdo_validate_config() - Validate constraints on a VDO config. + * @config: The VDO config. + * @physical_block_count: The minimum block count of the underlying storage. + * @logical_block_count: The expected logical size of the VDO, or 0 if the logical size may be + * unspecified. + * + * Return: A success or error code. + */ +int vdo_validate_config(const struct vdo_config *config, + block_count_t physical_block_count, + block_count_t logical_block_count) +{ + struct slab_config slab_config; + int result; + + result = ASSERT(config->slab_size > 0, "slab size unspecified"); + if (result != UDS_SUCCESS) + return result; + + result = ASSERT(is_power_of_2(config->slab_size), "slab size must be a power of two"); + if (result != UDS_SUCCESS) + return result; + + result = ASSERT(config->slab_size <= (1 << MAX_VDO_SLAB_BITS), + "slab size must be less than or equal to 2^%d", + MAX_VDO_SLAB_BITS); + if (result != VDO_SUCCESS) + return result; + + result = ASSERT(config->slab_journal_blocks >= MINIMUM_VDO_SLAB_JOURNAL_BLOCKS, + "slab journal size meets minimum size"); + if (result != UDS_SUCCESS) + return result; + + result = ASSERT(config->slab_journal_blocks <= config->slab_size, + "slab journal size is within expected bound"); + if (result != UDS_SUCCESS) + return result; + + result = vdo_configure_slab(config->slab_size, config->slab_journal_blocks, &slab_config); + if (result != VDO_SUCCESS) + return result; + + result = ASSERT((slab_config.data_blocks >= 1), + "slab must be able to hold at least one block"); + if (result != UDS_SUCCESS) + return result; + + result = ASSERT(config->physical_blocks > 0, "physical blocks unspecified"); + if (result != UDS_SUCCESS) + return result; + + result = ASSERT(config->physical_blocks <= MAXIMUM_VDO_PHYSICAL_BLOCKS, + "physical block count %llu exceeds maximum %llu", + (unsigned long long) config->physical_blocks, + (unsigned long long) MAXIMUM_VDO_PHYSICAL_BLOCKS); + if (result != UDS_SUCCESS) + return VDO_OUT_OF_RANGE; + + if (physical_block_count != config->physical_blocks) { + uds_log_error("A physical size of %llu blocks was specified, not the %llu blocks configured in the vdo super block", + (unsigned long long) physical_block_count, + (unsigned long long) config->physical_blocks); + return VDO_PARAMETER_MISMATCH; + } + + if (logical_block_count > 0) { + result = ASSERT((config->logical_blocks > 0), "logical blocks unspecified"); + if (result != UDS_SUCCESS) + return result; + + if (logical_block_count != config->logical_blocks) { + uds_log_error("A logical size of %llu blocks was specified, but that differs from the %llu blocks configured in the vdo super block", + (unsigned long long) logical_block_count, + (unsigned long long) config->logical_blocks); + return VDO_PARAMETER_MISMATCH; + } + } + + result = ASSERT(config->logical_blocks <= MAXIMUM_VDO_LOGICAL_BLOCKS, + "logical blocks too large"); + if (result != UDS_SUCCESS) + return result; + + result = ASSERT(config->recovery_journal_size > 0, "recovery journal size unspecified"); + if (result != UDS_SUCCESS) + return result; + + result = ASSERT(is_power_of_2(config->recovery_journal_size), + "recovery journal size must be a power of two"); + if (result != UDS_SUCCESS) + return result; + + return result; +} + +/** + * vdo_destroy_component_states() - Clean up any allocations in a vdo_component_states. + * @states: The component states to destroy. + */ +void vdo_destroy_component_states(struct vdo_component_states *states) +{ + if (states == NULL) + return; + + vdo_uninitialize_layout(&states->layout); +} + +/** + * decode_components() - Decode the components now that we know the component data is a version we + * understand. + * @buffer: The buffer being decoded. + * @offset: The offset to start decoding from. + * @geometry: The vdo geometry + * @states: An object to hold the successfully decoded state. + * + * Return: VDO_SUCCESS or an error. + */ +static int __must_check decode_components(u8 *buffer, + size_t *offset, + struct volume_geometry *geometry, + struct vdo_component_states *states) +{ + int result; + + decode_vdo_component(buffer, offset, &states->vdo); + + result = decode_layout(buffer, + offset, + vdo_get_data_region_start(*geometry) + 1, + states->vdo.config.physical_blocks, + &states->layout); + if (result != VDO_SUCCESS) + return result; + + result = decode_recovery_journal_state_7_0(buffer, offset, &states->recovery_journal); + if (result != VDO_SUCCESS) + return result; + + result = decode_slab_depot_state_2_0(buffer, offset, &states->slab_depot); + if (result != VDO_SUCCESS) + return result; + + result = decode_block_map_state_2_0(buffer, offset, &states->block_map); + if (result != VDO_SUCCESS) + return result; + + ASSERT_LOG_ONLY(*offset == VDO_COMPONENT_DATA_OFFSET + VDO_COMPONENT_DATA_SIZE, + "All decoded component data was used"); + return VDO_SUCCESS; +} + +/** + * vdo_decode_component_states() - Decode the payload of a super block. + * @buffer: The buffer containing the encoded super block contents. + * @geometry: The vdo geometry + * @states: A pointer to hold the decoded states. + * + * Return: VDO_SUCCESS or an error. + */ +int vdo_decode_component_states(u8 *buffer, + struct volume_geometry *geometry, + struct vdo_component_states *states) +{ + int result; + size_t offset = VDO_COMPONENT_DATA_OFFSET; + + /* Get and check the release version against the one from the geometry. */ + decode_u32_le(buffer, &offset, &states->release_version); + if (states->release_version != geometry->release_version) + return uds_log_error_strerror(VDO_UNSUPPORTED_VERSION, + "Geometry release version %u does not match super block release version %u", + geometry->release_version, + states->release_version); + + /* Check the VDO volume version */ + decode_version_number(buffer, &offset, &states->volume_version); + result = validate_version(VDO_VOLUME_VERSION_67_0, states->volume_version, "volume"); + if (result != VDO_SUCCESS) + return result; + + result = decode_components(buffer, &offset, geometry, states); + if (result != VDO_SUCCESS) + vdo_uninitialize_layout(&states->layout); + + return result; +} + +/** + * vdo_validate_component_states() - Validate the decoded super block configuration. + * @states: The state decoded from the super block. + * @geometry_nonce: The nonce from the geometry block. + * @physical_size: The minimum block count of the underlying storage. + * @logical_size: The expected logical size of the VDO, or 0 if the logical size may be + * unspecified. + * + * Return: VDO_SUCCESS or an error if the configuration is invalid. + */ +int vdo_validate_component_states(struct vdo_component_states *states, + nonce_t geometry_nonce, + block_count_t physical_size, + block_count_t logical_size) +{ + if (geometry_nonce != states->vdo.nonce) + return uds_log_error_strerror(VDO_BAD_NONCE, + "Geometry nonce %llu does not match superblock nonce %llu", + (unsigned long long) geometry_nonce, + (unsigned long long) states->vdo.nonce); + + return vdo_validate_config(&states->vdo.config, physical_size, logical_size); +} + +/** + * vdo_encode_component_states() - Encode the state of all vdo components in the super block. + */ +static void +vdo_encode_component_states(u8 *buffer, size_t *offset, const struct vdo_component_states *states) +{ + encode_u32_le(buffer, offset, states->release_version); + encode_version_number(buffer, offset, states->volume_version); + encode_vdo_component(buffer, offset, states->vdo); + encode_layout(buffer, offset, &states->layout); + encode_recovery_journal_state_7_0(buffer, offset, states->recovery_journal); + encode_slab_depot_state_2_0(buffer, offset, states->slab_depot); + encode_block_map_state_2_0(buffer, offset, states->block_map); + + ASSERT_LOG_ONLY(*offset == VDO_COMPONENT_DATA_OFFSET + VDO_COMPONENT_DATA_SIZE, + "All super block component data was encoded"); +} + +/** + * vdo_encode_super_block() - Encode a super block into its on-disk representation. + */ +void vdo_encode_super_block(u8 *buffer, struct vdo_component_states *states) +{ + u32 checksum; + struct header header = SUPER_BLOCK_HEADER_12_0; + size_t offset = 0; + + header.size += VDO_COMPONENT_DATA_SIZE; + vdo_encode_header(buffer, &offset, &header); + vdo_encode_component_states(buffer, &offset, states); + + checksum = vdo_crc32(buffer, offset); + encode_u32_le(buffer, &offset, checksum); + + /* + * Even though the buffer is a full block, to avoid the potential corruption from a torn + * write, the entire encoding must fit in the first sector. + */ + ASSERT_LOG_ONLY(offset <= VDO_SECTOR_SIZE, "entire superblock must fit in one sector"); +} + +/** + * vdo_decode_super_block() - Decode a super block from its on-disk representation. + */ +int vdo_decode_super_block(u8 *buffer) +{ + struct header header; + int result; + u32 checksum, saved_checksum; + size_t offset = 0; + + /* Decode and validate the header. */ + vdo_decode_header(buffer, &offset, &header); + result = vdo_validate_header(&SUPER_BLOCK_HEADER_12_0, &header, false, __func__); + if (result != VDO_SUCCESS) + return result; + + if (header.size > VDO_COMPONENT_DATA_SIZE + sizeof(u32)) + /* + * We can't check release version or checksum until we know the content size, so we + * have to assume a version mismatch on unexpected values. + */ + return uds_log_error_strerror(VDO_UNSUPPORTED_VERSION, + "super block contents too large: %zu", + header.size); + + /* Skip past the component data for now, to verify the checksum. */ + offset += VDO_COMPONENT_DATA_SIZE; + + checksum = vdo_crc32(buffer, offset); + decode_u32_le(buffer, &offset, &saved_checksum); + + result = ASSERT(offset == VDO_SUPER_BLOCK_FIXED_SIZE + VDO_COMPONENT_DATA_SIZE, + "must have decoded entire superblock payload"); + if (result != VDO_SUCCESS) + return result; + + return ((checksum != saved_checksum) ? VDO_CHECKSUM_MISMATCH : VDO_SUCCESS); +} diff --git a/drivers/md/dm-vdo/encodings.h b/drivers/md/dm-vdo/encodings.h new file mode 100644 index 00000000000..a0592f2300c --- /dev/null +++ b/drivers/md/dm-vdo/encodings.h @@ -0,0 +1,1307 @@ +/* SPDX-License-Identifier: GPL-2.0-only */ +/* + * Copyright Red Hat + */ + +#ifndef VDO_ENCODINGS_H +#define VDO_ENCODINGS_H + +#include +#include +#include +#include + +#include "numeric.h" +#include "uds.h" + +#include "constants.h" +#include "types.h" + +/* + * An in-memory representation of a version number for versioned structures on disk. + * + * A version number consists of two portions, a major version and a minor version. Any format + * change which does not require an explicit upgrade step from the previous version should + * increment the minor version. Any format change which either requires an explicit upgrade step, + * or is wholly incompatible (i.e. can not be upgraded to), should increment the major version, and + * set the minor version to 0. + */ +struct version_number { + u32 major_version; + u32 minor_version; +}; + +/* + * A packed, machine-independent, on-disk representation of a version_number. Both fields are + * stored in little-endian byte order. + */ +struct packed_version_number { + __le32 major_version; + __le32 minor_version; +} __packed; + +/* The registry of component ids for use in headers */ +#define VDO_SUPER_BLOCK 0 +#define VDO_LAYOUT 1 +#define VDO_RECOVERY_JOURNAL 2 +#define VDO_SLAB_DEPOT 3 +#define VDO_BLOCK_MAP 4 +#define VDO_GEOMETRY_BLOCK 5 + +/* The header for versioned data stored on disk. */ +struct header { + u32 id; /* The component this is a header for */ + struct version_number version; /* The version of the data format */ + size_t size; /* The size of the data following this header */ +}; + +/* A packed, machine-independent, on-disk representation of a component header. */ +struct packed_header { + __le32 id; + struct packed_version_number version; + __le64 size; +} __packed; + +enum { + VDO_GEOMETRY_BLOCK_LOCATION = 0, + VDO_GEOMETRY_MAGIC_NUMBER_SIZE = 8, + VDO_DEFAULT_GEOMETRY_BLOCK_VERSION = 5, +}; + +struct index_config { + u32 mem; + u32 unused; + bool sparse; +} __packed; + +enum volume_region_id { + VDO_INDEX_REGION = 0, + VDO_DATA_REGION = 1, + VDO_VOLUME_REGION_COUNT, +}; + +struct volume_region { + /* The ID of the region */ + enum volume_region_id id; + /* + * The absolute starting offset on the device. The region continues until the next region + * begins. + */ + physical_block_number_t start_block; +} __packed; + +struct volume_geometry { + /* The release version number of this volume */ + release_version_number_t release_version; + /* The nonce of this volume */ + nonce_t nonce; + /* The uuid of this volume */ + uuid_t uuid; + /* The block offset to be applied to bios */ + block_count_t bio_offset; + /* The regions in ID order */ + struct volume_region regions[VDO_VOLUME_REGION_COUNT]; + /* The index config */ + struct index_config index_config; +} __packed; + +/* This volume geometry struct is used for sizing only */ +struct volume_geometry_4_0 { + /* The release version number of this volume */ + release_version_number_t release_version; + /* The nonce of this volume */ + nonce_t nonce; + /* The uuid of this volume */ + uuid_t uuid; + /* The regions in ID order */ + struct volume_region regions[VDO_VOLUME_REGION_COUNT]; + /* The index config */ + struct index_config index_config; +} __packed; + +extern const u8 VDO_GEOMETRY_MAGIC_NUMBER[VDO_GEOMETRY_MAGIC_NUMBER_SIZE + 1]; + +/** + * DOC: Block map entries + * + * The entry for each logical block in the block map is encoded into five bytes, which saves space + * in both the on-disk and in-memory layouts. It consists of the 36 low-order bits of a + * physical_block_number_t (addressing 256 terabytes with a 4KB block size) and a 4-bit encoding of + * a block_mapping_state. + * + * Of the 8 high bits of the 5-byte structure: + * + * Bits 7..4: The four highest bits of the 36-bit physical block number + * Bits 3..0: The 4-bit block_mapping_state + * + * The following 4 bytes are the low order bytes of the physical block number, in little-endian + * order. + * + * Conversion functions to and from a data location are provided. + */ +struct block_map_entry { +#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ + unsigned mapping_state : 4; + unsigned pbn_high_nibble : 4; +#else + unsigned pbn_high_nibble : 4; + unsigned mapping_state : 4; +#endif + + __le32 pbn_low_word; +} __packed; + +struct block_map_page_header { + __le64 nonce; + __le64 pbn; + + /** May be non-zero on disk */ + u8 unused_long_word[8]; + + /* Whether this page has been written twice to disk */ + bool initialized; + + /* Always zero on disk */ + u8 unused_byte1; + + /* May be non-zero on disk */ + u8 unused_byte2; + u8 unused_byte3; +} __packed; + +struct block_map_page { + struct packed_version_number version; + struct block_map_page_header header; + struct block_map_entry entries[]; +} __packed; + +enum block_map_page_validity { + VDO_BLOCK_MAP_PAGE_VALID, + VDO_BLOCK_MAP_PAGE_INVALID, + /* Valid page found in the wrong location on disk */ + VDO_BLOCK_MAP_PAGE_BAD, +}; + +struct block_map_state_2_0 { + physical_block_number_t flat_page_origin; + block_count_t flat_page_count; + physical_block_number_t root_origin; + block_count_t root_count; +} __packed; + +struct boundary { + page_number_t levels[VDO_BLOCK_MAP_TREE_HEIGHT]; +}; + +extern const struct header VDO_BLOCK_MAP_HEADER_2_0; + +/* The state of the recovery journal as encoded in the VDO super block. */ +struct recovery_journal_state_7_0 { + /** Sequence number to start the journal */ + sequence_number_t journal_start; + /** Number of logical blocks used by VDO */ + block_count_t logical_blocks_used; + /** Number of block map pages allocated */ + block_count_t block_map_data_blocks; +} __packed; + +extern const struct header VDO_RECOVERY_JOURNAL_HEADER_7_0; + +typedef u16 journal_entry_count_t; + +/* + * A recovery journal entry stores three physical locations: a data location that is the value of a + * single mapping in the block map tree, and the two locations of the block map pages and slots + * that are acquiring and releasing a reference to the location. The journal entry also stores an + * operation code that says whether the mapping is for a logical block or for the block map tree + * itself. + */ +struct recovery_journal_entry { + struct block_map_slot slot; + struct data_location mapping; + struct data_location unmapping; + enum journal_operation operation; +}; + +/* The packed, on-disk representation of a recovery journal entry. */ +struct packed_recovery_journal_entry { + /* + * In little-endian bit order: + * Bits 15..12: The four highest bits of the 36-bit physical block number of the block map + * tree page + * Bits 11..2: The 10-bit block map page slot number + * Bit 1..0: The journal_operation of the entry (this actually only requires 1 bit, but + * it is convenient to keep the extra bit as part of this field. + */ +#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ + unsigned operation : 2; + unsigned slot_low : 6; + unsigned slot_high : 4; + unsigned pbn_high_nibble : 4; +#else + unsigned slot_low : 6; + unsigned operation : 2; + unsigned pbn_high_nibble : 4; + unsigned slot_high : 4; +#endif + + /* + * Bits 47..16: The 32 low-order bits of the block map page PBN, in little-endian byte + * order + */ + __le32 pbn_low_word; + + /* + * Bits 87..48: The five-byte block map entry encoding the location that will be stored in + * the block map page slot + */ + struct block_map_entry mapping; + + /* + * Bits 127..88: The five-byte block map entry encoding the location that was stored in the + * block map page slot + */ + struct block_map_entry unmapping; +} __packed; + +/* The packed, on-disk representation of an old format recovery journal entry. */ +struct packed_recovery_journal_entry_1 { + /* + * In little-endian bit order: + * Bits 15..12: The four highest bits of the 36-bit physical block number of the block map + * tree page + * Bits 11..2: The 10-bit block map page slot number + * Bits 1..0: The 2-bit journal_operation of the entry + * + */ +#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ + unsigned operation : 2; + unsigned slot_low : 6; + unsigned slot_high : 4; + unsigned pbn_high_nibble : 4; +#else + unsigned slot_low : 6; + unsigned operation : 2; + unsigned pbn_high_nibble : 4; + unsigned slot_high : 4; +#endif + + /* + * Bits 47..16: The 32 low-order bits of the block map page PBN, in little-endian byte + * order + */ + __le32 pbn_low_word; + + /* + * Bits 87..48: The five-byte block map entry encoding the location that was or will be + * stored in the block map page slot + */ + struct block_map_entry block_map_entry; +} __packed; + +enum journal_operation_1 { + VDO_JOURNAL_DATA_DECREMENT = 0, + VDO_JOURNAL_DATA_INCREMENT = 1, + VDO_JOURNAL_BLOCK_MAP_DECREMENT = 2, + VDO_JOURNAL_BLOCK_MAP_INCREMENT = 3, +} __packed; + +struct recovery_block_header { + sequence_number_t block_map_head; /* Block map head sequence number */ + sequence_number_t slab_journal_head; /* Slab journal head seq. number */ + sequence_number_t sequence_number; /* Sequence number for this block */ + nonce_t nonce; /* A given VDO instance's nonce */ + block_count_t logical_blocks_used; /* Logical blocks in use */ + block_count_t block_map_data_blocks; /* Allocated block map pages */ + journal_entry_count_t entry_count; /* Number of entries written */ + u8 check_byte; /* The protection check byte */ + u8 recovery_count; /* Number of recoveries completed */ + enum vdo_metadata_type metadata_type; /* Metadata type */ +}; + +/* + * The packed, on-disk representation of a recovery journal block header. All fields are kept in + * little-endian byte order. + */ +struct packed_journal_header { + /* Block map head 64-bit sequence number */ + __le64 block_map_head; + + /* Slab journal head 64-bit sequence number */ + __le64 slab_journal_head; + + /* The 64-bit sequence number for this block */ + __le64 sequence_number; + + /* A given VDO instance's 64-bit nonce */ + __le64 nonce; + + /* 8-bit metadata type (should always be one for the recovery journal) */ + u8 metadata_type; + + /* 16-bit count of the entries encoded in the block */ + __le16 entry_count; + + /* 64-bit count of the logical blocks used when this block was opened */ + __le64 logical_blocks_used; + + /* 64-bit count of the block map blocks used when this block was opened */ + __le64 block_map_data_blocks; + + /* The protection check byte */ + u8 check_byte; + + /* The number of recoveries completed */ + u8 recovery_count; +} __packed; + +struct packed_journal_sector { + /* The protection check byte */ + u8 check_byte; + + /* The number of recoveries completed */ + u8 recovery_count; + + /* The number of entries in this sector */ + u8 entry_count; + + /* Journal entries for this sector */ + struct packed_recovery_journal_entry entries[]; +} __packed; + +enum { + /* The number of entries in each sector (except the last) when filled */ + RECOVERY_JOURNAL_ENTRIES_PER_SECTOR = + ((VDO_SECTOR_SIZE - sizeof(struct packed_journal_sector)) / + sizeof(struct packed_recovery_journal_entry)), + RECOVERY_JOURNAL_ENTRIES_PER_BLOCK = RECOVERY_JOURNAL_ENTRIES_PER_SECTOR * 7, + /* The number of entries in a v1 recovery journal block. */ + RECOVERY_JOURNAL_1_ENTRIES_PER_BLOCK = 311, + /* The number of entries in each v1 sector (except the last) when filled */ + RECOVERY_JOURNAL_1_ENTRIES_PER_SECTOR = + ((VDO_SECTOR_SIZE - sizeof(struct packed_journal_sector)) / + sizeof(struct packed_recovery_journal_entry_1)), + /* The number of entries in the last sector when a block is full */ + RECOVERY_JOURNAL_1_ENTRIES_IN_LAST_SECTOR = + (RECOVERY_JOURNAL_1_ENTRIES_PER_BLOCK % RECOVERY_JOURNAL_1_ENTRIES_PER_SECTOR), +}; + +/* A type representing a reference count of a block. */ +typedef u8 vdo_refcount_t; + +/* The absolute position of an entry in a recovery journal or slab journal. */ +struct journal_point { + sequence_number_t sequence_number; + journal_entry_count_t entry_count; +}; + +/* A packed, platform-independent encoding of a struct journal_point. */ +struct packed_journal_point { + /* + * The packed representation is the little-endian 64-bit representation of the low-order 48 + * bits of the sequence number, shifted up 16 bits, or'ed with the 16-bit entry count. + * + * Very long-term, the top 16 bits of the sequence number may not always be zero, as this + * encoding assumes--see BZ 1523240. + */ + __le64 encoded_point; +} __packed; + +/* Special vdo_refcount_t values. */ +#define EMPTY_REFERENCE_COUNT 0 +enum { + MAXIMUM_REFERENCE_COUNT = 254, + PROVISIONAL_REFERENCE_COUNT = 255, +}; + +enum { + COUNTS_PER_SECTOR = + ((VDO_SECTOR_SIZE - sizeof(struct packed_journal_point)) / sizeof(vdo_refcount_t)), + COUNTS_PER_BLOCK = COUNTS_PER_SECTOR * VDO_SECTORS_PER_BLOCK, +}; + +/* The format of each sector of a reference_block on disk. */ +struct packed_reference_sector { + struct packed_journal_point commit_point; + vdo_refcount_t counts[COUNTS_PER_SECTOR]; +} __packed; + +struct packed_reference_block { + struct packed_reference_sector sectors[VDO_SECTORS_PER_BLOCK]; +}; + +struct slab_depot_state_2_0 { + struct slab_config slab_config; + physical_block_number_t first_block; + physical_block_number_t last_block; + zone_count_t zone_count; +} __packed; + +extern const struct header VDO_SLAB_DEPOT_HEADER_2_0; + +/* + * vdo_slab journal blocks may have one of two formats, depending upon whether or not any of the + * entries in the block are block map increments. Since the steady state for a VDO is that all of + * the necessary block map pages will be allocated, most slab journal blocks will have only data + * entries. Such blocks can hold more entries, hence the two formats. + */ + +/* A single slab journal entry */ +struct slab_journal_entry { + slab_block_number sbn; + enum journal_operation operation; + bool increment; +}; + +/* A single slab journal entry in its on-disk form */ +typedef struct { + u8 offset_low8; + u8 offset_mid8; + +#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ + unsigned offset_high7 : 7; + unsigned increment : 1; +#else + unsigned increment : 1; + unsigned offset_high7 : 7; +#endif +} __packed packed_slab_journal_entry; + +/* The unpacked representation of the header of a slab journal block */ +struct slab_journal_block_header { + /* Sequence number for head of journal */ + sequence_number_t head; + /* Sequence number for this block */ + sequence_number_t sequence_number; + /* The nonce for a given VDO instance */ + nonce_t nonce; + /* Recovery journal point for last entry */ + struct journal_point recovery_point; + /* Metadata type */ + enum vdo_metadata_type metadata_type; + /* Whether this block contains block map increments */ + bool has_block_map_increments; + /* The number of entries in the block */ + journal_entry_count_t entry_count; +}; + +/* + * The packed, on-disk representation of a slab journal block header. All fields are kept in + * little-endian byte order. + */ +struct packed_slab_journal_block_header { + /* 64-bit sequence number for head of journal */ + __le64 head; + /* 64-bit sequence number for this block */ + __le64 sequence_number; + /* Recovery journal point for the last entry, packed into 64 bits */ + struct packed_journal_point recovery_point; + /* The 64-bit nonce for a given VDO instance */ + __le64 nonce; + /* 8-bit metadata type (should always be two, for the slab journal) */ + u8 metadata_type; + /* Whether this block contains block map increments */ + bool has_block_map_increments; + /* 16-bit count of the entries encoded in the block */ + __le16 entry_count; +} __packed; + +enum { + VDO_SLAB_JOURNAL_PAYLOAD_SIZE = + VDO_BLOCK_SIZE - sizeof(struct packed_slab_journal_block_header), + VDO_SLAB_JOURNAL_FULL_ENTRIES_PER_BLOCK = (VDO_SLAB_JOURNAL_PAYLOAD_SIZE * 8) / 25, + VDO_SLAB_JOURNAL_ENTRY_TYPES_SIZE = + ((VDO_SLAB_JOURNAL_FULL_ENTRIES_PER_BLOCK - 1) / 8) + 1, + VDO_SLAB_JOURNAL_ENTRIES_PER_BLOCK = + (VDO_SLAB_JOURNAL_PAYLOAD_SIZE / sizeof(packed_slab_journal_entry)), +}; + +/* The payload of a slab journal block which has block map increments */ +struct full_slab_journal_entries { + /* The entries themselves */ + packed_slab_journal_entry entries[VDO_SLAB_JOURNAL_FULL_ENTRIES_PER_BLOCK]; + /* The bit map indicating which entries are block map increments */ + u8 entry_types[VDO_SLAB_JOURNAL_ENTRY_TYPES_SIZE]; +} __packed; + +typedef union { + /* Entries which include block map increments */ + struct full_slab_journal_entries full_entries; + /* Entries which are only data updates */ + packed_slab_journal_entry entries[VDO_SLAB_JOURNAL_ENTRIES_PER_BLOCK]; + /* Ensure the payload fills to the end of the block */ + u8 space[VDO_SLAB_JOURNAL_PAYLOAD_SIZE]; +} __packed slab_journal_payload; + +struct packed_slab_journal_block { + struct packed_slab_journal_block_header header; + slab_journal_payload payload; +} __packed; + +/* The offset of a slab journal tail block. */ +typedef u8 tail_block_offset_t; + +struct slab_summary_entry { + /* Bits 7..0: The offset of the tail block within the slab journal */ + tail_block_offset_t tail_block_offset; + +#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ + /* Bits 13..8: A hint about the fullness of the slab */ + unsigned int fullness_hint : 6; + /* Bit 14: Whether the ref_counts must be loaded from the layer */ + unsigned int load_ref_counts : 1; + /* Bit 15: The believed cleanliness of this slab */ + unsigned int is_dirty : 1; +#else + /* Bit 15: The believed cleanliness of this slab */ + unsigned int is_dirty : 1; + /* Bit 14: Whether the ref_counts must be loaded from the layer */ + unsigned int load_ref_counts : 1; + /* Bits 13..8: A hint about the fullness of the slab */ + unsigned int fullness_hint : 6; +#endif +} __packed; + +enum { + VDO_SLAB_SUMMARY_FULLNESS_HINT_BITS = 6, + VDO_SLAB_SUMMARY_ENTRIES_PER_BLOCK = VDO_BLOCK_SIZE / sizeof(struct slab_summary_entry), + VDO_SLAB_SUMMARY_BLOCKS_PER_ZONE = MAX_VDO_SLABS / VDO_SLAB_SUMMARY_ENTRIES_PER_BLOCK, + VDO_SLAB_SUMMARY_BLOCKS = VDO_SLAB_SUMMARY_BLOCKS_PER_ZONE * MAX_VDO_PHYSICAL_ZONES, +}; + +struct layout { + physical_block_number_t start; + block_count_t size; + physical_block_number_t first_free; + physical_block_number_t last_free; + size_t num_partitions; + struct partition *head; +}; + +struct partition { + enum partition_id id; /* The id of this partition */ + physical_block_number_t offset; /* The offset into the layout of this partition */ + block_count_t count; /* The number of blocks in the partition */ + struct partition *next; /* A pointer to the next partition in the layout */ +}; + +struct layout_3_0 { + physical_block_number_t first_free; + physical_block_number_t last_free; + u8 partition_count; +} __packed; + +struct partition_3_0 { + enum partition_id id; + physical_block_number_t offset; + physical_block_number_t base; /* unused but retained for backwards compatibility */ + block_count_t count; +} __packed; + +/* + * The configuration of the VDO service. + */ +struct vdo_config { + block_count_t logical_blocks; /* number of logical blocks */ + block_count_t physical_blocks; /* number of physical blocks */ + block_count_t slab_size; /* number of blocks in a slab */ + block_count_t recovery_journal_size; /* number of recovery journal blocks */ + block_count_t slab_journal_blocks; /* number of slab journal blocks */ +}; + +/* This is the structure that captures the vdo fields saved as a super block component. */ +struct vdo_component { + enum vdo_state state; + u64 complete_recoveries; + u64 read_only_recoveries; + struct vdo_config config; + nonce_t nonce; +}; + +/* + * A packed, machine-independent, on-disk representation of the vdo_config in the VDO component + * data in the super block. + */ +struct packed_vdo_config { + __le64 logical_blocks; + __le64 physical_blocks; + __le64 slab_size; + __le64 recovery_journal_size; + __le64 slab_journal_blocks; +} __packed; + +/* + * A packed, machine-independent, on-disk representation of version 41.0 of the VDO component data + * in the super block. + */ +struct packed_vdo_component_41_0 { + __le32 state; + __le64 complete_recoveries; + __le64 read_only_recoveries; + struct packed_vdo_config config; + __le64 nonce; +} __packed; + +/* + * The version of the on-disk format of a VDO volume. This should be incremented any time the + * on-disk representation of any VDO structure changes. Changes which require only online upgrade + * steps should increment the minor version. Changes which require an offline upgrade or which can + * not be upgraded to at all should increment the major version and set the minor version to 0. + */ +extern const struct version_number VDO_VOLUME_VERSION_67_0; + +enum { + VDO_ENCODED_HEADER_SIZE = sizeof(struct packed_header), + BLOCK_MAP_COMPONENT_ENCODED_SIZE = + VDO_ENCODED_HEADER_SIZE + sizeof(struct block_map_state_2_0), + RECOVERY_JOURNAL_COMPONENT_ENCODED_SIZE = + VDO_ENCODED_HEADER_SIZE + sizeof(struct recovery_journal_state_7_0), + SLAB_DEPOT_COMPONENT_ENCODED_SIZE = + VDO_ENCODED_HEADER_SIZE + sizeof(struct slab_depot_state_2_0), + VDO_PARTITION_COUNT = 4, + VDO_LAYOUT_ENCODED_SIZE = (VDO_ENCODED_HEADER_SIZE + + sizeof(struct layout_3_0) + + (sizeof(struct partition_3_0) * VDO_PARTITION_COUNT)), + VDO_SUPER_BLOCK_FIXED_SIZE = VDO_ENCODED_HEADER_SIZE + sizeof(u32), + VDO_MAX_COMPONENT_DATA_SIZE = VDO_SECTOR_SIZE - VDO_SUPER_BLOCK_FIXED_SIZE, + VDO_COMPONENT_ENCODED_SIZE = + (sizeof(struct packed_version_number) + sizeof(struct packed_vdo_component_41_0)), + VDO_COMPONENT_DATA_OFFSET = VDO_ENCODED_HEADER_SIZE, + VDO_COMPONENT_DATA_SIZE = (sizeof(release_version_number_t) + + sizeof(struct packed_version_number) + + VDO_COMPONENT_ENCODED_SIZE + + VDO_LAYOUT_ENCODED_SIZE + + RECOVERY_JOURNAL_COMPONENT_ENCODED_SIZE + + SLAB_DEPOT_COMPONENT_ENCODED_SIZE + + BLOCK_MAP_COMPONENT_ENCODED_SIZE), +}; + +/* The entirety of the component data encoded in the VDO super block. */ +struct vdo_component_states { + /* The release version */ + release_version_number_t release_version; + + /* The VDO volume version */ + struct version_number volume_version; + + /* Components */ + struct vdo_component vdo; + struct block_map_state_2_0 block_map; + struct recovery_journal_state_7_0 recovery_journal; + struct slab_depot_state_2_0 slab_depot; + + /* Our partitioning of the underlying storage */ + struct layout layout; +}; + +/** + * vdo_are_same_version() - Check whether two version numbers are the same. + * @version_a: The first version. + * @version_b: The second version. + * + * Return: true if the two versions are the same. + */ +static inline bool +vdo_are_same_version(struct version_number version_a, struct version_number version_b) +{ + return ((version_a.major_version == version_b.major_version) && + (version_a.minor_version == version_b.minor_version)); +} + +/** + * vdo_is_upgradable_version() - Check whether an actual version is upgradable to an expected + * version. + * @expected_version: The expected version. + * @actual_version: The version being validated. + * + * An actual version is upgradable if its major number is expected but its minor number differs, + * and the expected version's minor number is greater than the actual version's minor number. + * + * Return: true if the actual version is upgradable. + */ +static inline bool vdo_is_upgradable_version(struct version_number expected_version, + struct version_number actual_version) +{ + return ((expected_version.major_version == actual_version.major_version) && + (expected_version.minor_version > actual_version.minor_version)); +} + +int __must_check vdo_validate_header(const struct header *expected_header, + const struct header *actual_header, + bool exact_size, + const char *component_name); + +void vdo_encode_header(u8 *buffer, size_t *offset, const struct header *header); +void vdo_decode_header(u8 *buffer, size_t *offset, struct header *header); + +/** + * vdo_pack_version_number() - Convert a version_number to its packed on-disk representation. + * @version: The version number to convert. + * + * Return: the platform-independent representation of the version + */ +static inline struct packed_version_number vdo_pack_version_number(struct version_number version) +{ + return (struct packed_version_number) { + .major_version = __cpu_to_le32(version.major_version), + .minor_version = __cpu_to_le32(version.minor_version), + }; +} + +/** + * vdo_unpack_version_number() - Convert a packed_version_number to its native in-memory + * representation. + * @version: The version number to convert. + * + * Return: The platform-independent representation of the version. + */ +static inline struct version_number vdo_unpack_version_number(struct packed_version_number version) +{ + return (struct version_number) { + .major_version = __le32_to_cpu(version.major_version), + .minor_version = __le32_to_cpu(version.minor_version), + }; +} + +/** + * vdo_pack_header() - Convert a component header to its packed on-disk representation. + * @header: The header to convert. + * + * Return: the platform-independent representation of the header + */ +static inline struct packed_header vdo_pack_header(const struct header *header) +{ + return (struct packed_header) { + .id = __cpu_to_le32(header->id), + .version = vdo_pack_version_number(header->version), + .size = __cpu_to_le64(header->size), + }; +} + +/** + * vdo_unpack_header() - Convert a packed_header to its native in-memory representation. + * @header: The header to convert. + * + * Return: The platform-independent representation of the version. + */ +static inline struct header vdo_unpack_header(const struct packed_header *header) +{ + return (struct header) { + .id = __le32_to_cpu(header->id), + .version = vdo_unpack_version_number(header->version), + .size = __le64_to_cpu(header->size), + }; +} + +/** + * vdo_get_index_region_start() - Get the start of the index region from a geometry. + * @geometry: The geometry. + * + * Return: The start of the index region. + */ +static inline physical_block_number_t __must_check +vdo_get_index_region_start(struct volume_geometry geometry) +{ + return geometry.regions[VDO_INDEX_REGION].start_block; +} + +/** + * vdo_get_data_region_start() - Get the start of the data region from a geometry. + * @geometry: The geometry. + * + * Return: The start of the data region. + */ +static inline physical_block_number_t __must_check +vdo_get_data_region_start(struct volume_geometry geometry) +{ + return geometry.regions[VDO_DATA_REGION].start_block; +} + +/** + * vdo_get_index_region_size() - Get the size of the index region from a geometry. + * @geometry: The geometry. + * + * Return: The size of the index region. + */ +static inline physical_block_number_t __must_check +vdo_get_index_region_size(struct volume_geometry geometry) +{ + return vdo_get_data_region_start(geometry) - + vdo_get_index_region_start(geometry); +} + +int __must_check vdo_parse_geometry_block(unsigned char *block, struct volume_geometry *geometry); + +static inline bool vdo_is_state_compressed(const enum block_mapping_state mapping_state) +{ + return (mapping_state > VDO_MAPPING_STATE_UNCOMPRESSED); +} + +static inline struct block_map_entry +vdo_pack_block_map_entry(physical_block_number_t pbn, enum block_mapping_state mapping_state) +{ + return (struct block_map_entry) { + .mapping_state = (mapping_state & 0x0F), + .pbn_high_nibble = ((pbn >> 32) & 0x0F), + .pbn_low_word = __cpu_to_le32(pbn & UINT_MAX), + }; +} + +static inline struct data_location vdo_unpack_block_map_entry(const struct block_map_entry *entry) +{ + physical_block_number_t low32 = __le32_to_cpu(entry->pbn_low_word); + physical_block_number_t high4 = entry->pbn_high_nibble; + + return (struct data_location) { + .pbn = ((high4 << 32) | low32), + .state = entry->mapping_state, + }; +} + +static inline bool vdo_is_mapped_location(const struct data_location *location) +{ + return (location->state != VDO_MAPPING_STATE_UNMAPPED); +} + +static inline bool vdo_is_valid_location(const struct data_location *location) +{ + if (location->pbn == VDO_ZERO_BLOCK) + return !vdo_is_state_compressed(location->state); + else + return vdo_is_mapped_location(location); +} + +static inline physical_block_number_t __must_check +vdo_get_block_map_page_pbn(const struct block_map_page *page) +{ + return __le64_to_cpu(page->header.pbn); +} + +struct block_map_page *vdo_format_block_map_page(void *buffer, + nonce_t nonce, + physical_block_number_t pbn, + bool initialized); + +enum block_map_page_validity __must_check +vdo_validate_block_map_page(struct block_map_page *page, + nonce_t nonce, + physical_block_number_t pbn); + +static inline page_count_t vdo_compute_block_map_page_count(block_count_t entries) +{ + return DIV_ROUND_UP(entries, VDO_BLOCK_MAP_ENTRIES_PER_PAGE); +} + +block_count_t __must_check +vdo_compute_new_forest_pages(root_count_t root_count, + struct boundary *old_sizes, + block_count_t entries, + struct boundary *new_sizes); + +/** + * vdo_pack_recovery_journal_entry() - Return the packed, on-disk representation of a recovery + * journal entry. + * @entry: The journal entry to pack. + * + * Return: The packed representation of the journal entry. + */ +static inline struct packed_recovery_journal_entry +vdo_pack_recovery_journal_entry(const struct recovery_journal_entry *entry) +{ + return (struct packed_recovery_journal_entry) { + .operation = entry->operation, + .slot_low = entry->slot.slot & 0x3F, + .slot_high = (entry->slot.slot >> 6) & 0x0F, + .pbn_high_nibble = (entry->slot.pbn >> 32) & 0x0F, + .pbn_low_word = __cpu_to_le32(entry->slot.pbn & UINT_MAX), + .mapping = vdo_pack_block_map_entry(entry->mapping.pbn, entry->mapping.state), + .unmapping = vdo_pack_block_map_entry(entry->unmapping.pbn, + entry->unmapping.state), + }; +} + +/** + * vdo_unpack_recovery_journal_entry() - Unpack the on-disk representation of a recovery journal + * entry. + * @entry: The recovery journal entry to unpack. + * + * Return: The unpacked entry. + */ +static inline struct recovery_journal_entry +vdo_unpack_recovery_journal_entry(const struct packed_recovery_journal_entry *entry) +{ + physical_block_number_t low32 = __le32_to_cpu(entry->pbn_low_word); + physical_block_number_t high4 = entry->pbn_high_nibble; + + return (struct recovery_journal_entry) { + .operation = entry->operation, + .slot = { + .pbn = ((high4 << 32) | low32), + .slot = (entry->slot_low | (entry->slot_high << 6)), + }, + .mapping = vdo_unpack_block_map_entry(&entry->mapping), + .unmapping = vdo_unpack_block_map_entry(&entry->unmapping), + }; +} + +const char * __must_check vdo_get_journal_operation_name(enum journal_operation operation); + +/** + * vdo_is_valid_recovery_journal_sector() - Determine whether the header of the given sector could + * describe a valid sector for the given journal block + * header. + * @header: The unpacked block header to compare against. + * @sector: The packed sector to check. + * @sector_number: The number of the sector being checked. + * + * Return: true if the sector matches the block header. + */ +static inline bool __must_check +vdo_is_valid_recovery_journal_sector(const struct recovery_block_header *header, + const struct packed_journal_sector *sector, + u8 sector_number) +{ + if ((header->check_byte != sector->check_byte) || + (header->recovery_count != sector->recovery_count)) + return false; + + if (header->metadata_type == VDO_METADATA_RECOVERY_JOURNAL_2) + return sector->entry_count <= RECOVERY_JOURNAL_ENTRIES_PER_SECTOR; + + if (sector_number == 7) + return sector->entry_count <= RECOVERY_JOURNAL_1_ENTRIES_IN_LAST_SECTOR; + + return sector->entry_count <= RECOVERY_JOURNAL_1_ENTRIES_PER_SECTOR; +} + +/** + * vdo_compute_recovery_journal_block_number() - Compute the physical block number of the recovery + * journal block which would have a given sequence + * number. + * @journal_size: The size of the journal. + * @sequence_number: The sequence number. + * + * Return: The pbn of the journal block which would the specified sequence number. + */ +static inline physical_block_number_t __must_check +vdo_compute_recovery_journal_block_number(block_count_t journal_size, + sequence_number_t sequence_number) +{ + /* + * Since journal size is a power of two, the block number modulus can just be extracted + * from the low-order bits of the sequence. + */ + return (sequence_number & (journal_size - 1)); +} + +/** + * vdo_get_journal_block_sector() - Find the recovery journal sector from the block header and + * sector number. + * @header: The header of the recovery journal block. + * @sector_number: The index of the sector (1-based). + * + * Return: A packed recovery journal sector. + */ +static inline struct packed_journal_sector * __must_check +vdo_get_journal_block_sector(struct packed_journal_header *header, int sector_number) +{ + char *sector_data = ((char *) header) + (VDO_SECTOR_SIZE * sector_number); + + return (struct packed_journal_sector *) sector_data; +} + +/** + * vdo_pack_recovery_block_header() - Generate the packed representation of a recovery block + * header. + * @header: The header containing the values to encode. + * @packed: The header into which to pack the values. + */ +static inline void vdo_pack_recovery_block_header(const struct recovery_block_header *header, + struct packed_journal_header *packed) +{ + *packed = (struct packed_journal_header) { + .block_map_head = __cpu_to_le64(header->block_map_head), + .slab_journal_head = __cpu_to_le64(header->slab_journal_head), + .sequence_number = __cpu_to_le64(header->sequence_number), + .nonce = __cpu_to_le64(header->nonce), + .logical_blocks_used = __cpu_to_le64(header->logical_blocks_used), + .block_map_data_blocks = __cpu_to_le64(header->block_map_data_blocks), + .entry_count = __cpu_to_le16(header->entry_count), + .check_byte = header->check_byte, + .recovery_count = header->recovery_count, + .metadata_type = header->metadata_type, + }; +} + +/** + * vdo_unpack_recovery_block_header() - Decode the packed representation of a recovery block + * header. + * @packed: The packed header to decode. + * + * Return: The unpacked header. + */ +static inline struct recovery_block_header +vdo_unpack_recovery_block_header(const struct packed_journal_header *packed) +{ + return (struct recovery_block_header) { + .block_map_head = __le64_to_cpu(packed->block_map_head), + .slab_journal_head = __le64_to_cpu(packed->slab_journal_head), + .sequence_number = __le64_to_cpu(packed->sequence_number), + .nonce = __le64_to_cpu(packed->nonce), + .logical_blocks_used = __le64_to_cpu(packed->logical_blocks_used), + .block_map_data_blocks = __le64_to_cpu(packed->block_map_data_blocks), + .entry_count = __le16_to_cpu(packed->entry_count), + .check_byte = packed->check_byte, + .recovery_count = packed->recovery_count, + .metadata_type = packed->metadata_type, + }; +} + +/** + * vdo_compute_slab_count() - Compute the number of slabs a depot with given parameters would have. + * @first_block: PBN of the first data block. + * @last_block: PBN of the last data block. + * @slab_size_shift: Exponent for the number of blocks per slab. + * + * Return: The number of slabs. + */ +static inline slab_count_t +vdo_compute_slab_count(physical_block_number_t first_block, + physical_block_number_t last_block, + unsigned int slab_size_shift) +{ + return (slab_count_t) ((last_block - first_block) >> slab_size_shift); +} + +int __must_check vdo_configure_slab_depot(const struct partition *partition, + struct slab_config slab_config, + zone_count_t zone_count, + struct slab_depot_state_2_0 *state); + +int __must_check vdo_configure_slab(block_count_t slab_size, + block_count_t slab_journal_blocks, + struct slab_config *slab_config); + +/** + * vdo_get_saved_reference_count_size() - Get the number of blocks required to save a reference + * counts state covering the specified number of data + * blocks. + * @block_count: The number of physical data blocks that can be referenced. + * + * Return: The number of blocks required to save reference counts with the given block count. + */ +static inline block_count_t +vdo_get_saved_reference_count_size(block_count_t block_count) +{ + return DIV_ROUND_UP(block_count, COUNTS_PER_BLOCK); +} + +/** + * vdo_get_slab_journal_start_block() - Get the physical block number of the start of the slab + * journal relative to the start block allocator partition. + * @slab_config: The slab configuration of the VDO. + * @origin: The first block of the slab. + */ +static inline physical_block_number_t __must_check +vdo_get_slab_journal_start_block(const struct slab_config *slab_config, + physical_block_number_t origin) +{ + return origin + slab_config->data_blocks + slab_config->reference_count_blocks; +} + +/** + * vdo_advance_journal_point() - Move the given journal point forward by one entry. + * @point: The journal point to adjust. + * @entries_per_block: The number of entries in one full block. + */ +static inline void +vdo_advance_journal_point(struct journal_point *point, journal_entry_count_t entries_per_block) +{ + point->entry_count++; + if (point->entry_count == entries_per_block) { + point->sequence_number++; + point->entry_count = 0; + } +} + +/** + * vdo_before_journal_point() - Check whether the first point precedes the second point. + * @first: The first journal point. + * @second: The second journal point. + * + * Return: true if the first point precedes the second point. + */ +static inline bool +vdo_before_journal_point(const struct journal_point *first, const struct journal_point *second) +{ + return ((first->sequence_number < second->sequence_number) || + ((first->sequence_number == second->sequence_number) && + (first->entry_count < second->entry_count))); +} + +/** + * vdo_pack_journal_point() - Encode the journal location represented by a + * journal_point into a packed_journal_point. + * @unpacked: The unpacked input point. + * @packed: The packed output point. + */ +static inline void +vdo_pack_journal_point(const struct journal_point *unpacked, struct packed_journal_point *packed) +{ + packed->encoded_point = + __cpu_to_le64((unpacked->sequence_number << 16) | unpacked->entry_count); +} + +/** + * vdo_unpack_journal_point() - Decode the journal location represented by a packed_journal_point + * into a journal_point. + * @packed: The packed input point. + * @unpacked: The unpacked output point. + */ +static inline void +vdo_unpack_journal_point(const struct packed_journal_point *packed, struct journal_point *unpacked) +{ + u64 native = __le64_to_cpu(packed->encoded_point); + + unpacked->sequence_number = (native >> 16); + unpacked->entry_count = (native & 0xffff); +} + +/** + * vdo_pack_slab_journal_block_header() - Generate the packed representation of a slab block + * header. + * @header: The header containing the values to encode. + * @packed: The header into which to pack the values. + */ +static inline void +vdo_pack_slab_journal_block_header(const struct slab_journal_block_header *header, + struct packed_slab_journal_block_header *packed) +{ + packed->head = __cpu_to_le64(header->head); + packed->sequence_number = __cpu_to_le64(header->sequence_number); + packed->nonce = __cpu_to_le64(header->nonce); + packed->entry_count = __cpu_to_le16(header->entry_count); + packed->metadata_type = header->metadata_type; + packed->has_block_map_increments = header->has_block_map_increments; + + vdo_pack_journal_point(&header->recovery_point, &packed->recovery_point); +} + +/** + * vdo_unpack_slab_journal_block_header() - Decode the packed representation of a slab block + * header. + * @packed: The packed header to decode. + * @header: The header into which to unpack the values. + */ +static inline void +vdo_unpack_slab_journal_block_header(const struct packed_slab_journal_block_header *packed, + struct slab_journal_block_header *header) +{ + *header = (struct slab_journal_block_header) { + .head = __le64_to_cpu(packed->head), + .sequence_number = __le64_to_cpu(packed->sequence_number), + .nonce = __le64_to_cpu(packed->nonce), + .entry_count = __le16_to_cpu(packed->entry_count), + .metadata_type = packed->metadata_type, + .has_block_map_increments = packed->has_block_map_increments, + }; + vdo_unpack_journal_point(&packed->recovery_point, &header->recovery_point); +} + +/** + * vdo_pack_slab_journal_entry() - Generate the packed encoding of a slab journal entry. + * @packed: The entry into which to pack the values. + * @sbn: The slab block number of the entry to encode. + * @is_increment: The increment flag. + */ +static inline void vdo_pack_slab_journal_entry(packed_slab_journal_entry *packed, + slab_block_number sbn, + bool is_increment) +{ + packed->offset_low8 = (sbn & 0x0000FF); + packed->offset_mid8 = (sbn & 0x00FF00) >> 8; + packed->offset_high7 = (sbn & 0x7F0000) >> 16; + packed->increment = is_increment ? 1 : 0; +} + +/** + * vdo_unpack_slab_journal_entry() - Decode the packed representation of a slab journal entry. + * @packed: The packed entry to decode. + * + * Return: The decoded slab journal entry. + */ +static inline struct slab_journal_entry __must_check +vdo_unpack_slab_journal_entry(const packed_slab_journal_entry *packed) +{ + struct slab_journal_entry entry; + + entry.sbn = packed->offset_high7; + entry.sbn <<= 8; + entry.sbn |= packed->offset_mid8; + entry.sbn <<= 8; + entry.sbn |= packed->offset_low8; + entry.operation = VDO_JOURNAL_DATA_REMAPPING; + entry.increment = packed->increment; + return entry; +} + +struct slab_journal_entry __must_check +vdo_decode_slab_journal_entry(struct packed_slab_journal_block *block, + journal_entry_count_t entry_count); + +/** + * vdo_get_slab_summary_hint_shift() - Compute the shift for slab summary hints. + * @slab_size_shift: Exponent for the number of blocks per slab. + * + * Return: The hint shift. + */ +static inline u8 __must_check vdo_get_slab_summary_hint_shift(unsigned int slab_size_shift) +{ + return ((slab_size_shift > VDO_SLAB_SUMMARY_FULLNESS_HINT_BITS) ? + (slab_size_shift - VDO_SLAB_SUMMARY_FULLNESS_HINT_BITS) : + 0); +} + +int __must_check vdo_initialize_layout(block_count_t size, + physical_block_number_t offset, + block_count_t block_map_blocks, + block_count_t journal_blocks, + block_count_t summary_blocks, + struct layout *layout); + +void vdo_uninitialize_layout(struct layout *layout); + +int __must_check vdo_get_partition(struct layout *layout, + enum partition_id id, + struct partition **partition_ptr); + +struct partition * __must_check +vdo_get_known_partition(struct layout *layout, enum partition_id id); + +int vdo_validate_config(const struct vdo_config *config, + block_count_t physical_block_count, + block_count_t logical_block_count); + +void vdo_destroy_component_states(struct vdo_component_states *states); + +int __must_check +vdo_decode_component_states(u8 *buffer, + struct volume_geometry *geometry, + struct vdo_component_states *states); + +int __must_check +vdo_validate_component_states(struct vdo_component_states *states, + nonce_t geometry_nonce, + block_count_t physical_size, + block_count_t logical_size); + +void vdo_encode_super_block(u8 *buffer, struct vdo_component_states *states); +int __must_check vdo_decode_super_block(u8 *buffer); + +/* We start with 0L and postcondition with ~0L to match our historical usage in userspace. */ +static inline u32 vdo_crc32(const void *buf, unsigned long len) +{ + return (crc32(0L, buf, len) ^ ~0L); +} + +#endif /* VDO_ENCODINGS_H */