/* Copyright 2016 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef __CROS_EC_NVMEM_UTILS_H #define __CROS_EC_NVMEM_UTILS_H /* * In order to provide maximum robustness for NvMem operations, the NvMem space * is divided into two equal sized partitions. A partition contains a tag * and a buffer for each NvMem user. * * NvMem Partiion * --------------------------------------------------------------------- * |0x8 tag | User Buffer 0 | User Buffer 1 | .... | User Buffer N-1 | * --------------------------------------------------------------------- * * Physical Block Tag details * --------------------------------------------------------------------- * | sha | version | reserved | * --------------------------------------------------------------------- * sha -> 4 bytes of sha1 digest * version -> 1 byte version number (0 - 0xfe) * reserved -> 3 bytes * * At initialization time, each partition is scanned to see if it has a good sha * entry. One of the two partitions being valid is a supported condition. If * however, neither partiion is valid, then a check is made to see if NvMem * space is fully erased. If this is detected, then the tag for partion 0 is * populated and written into flash. If neither partition is valid and they * aren't fully erased, then NvMem is marked corrupt and this failure condition * must be reported back to the caller. * * Note that the NvMem partitions can be placed anywhere in flash space, but * must be equal in total size. A table is used by the NvMem module to get the * correct base address and offset for each partition. * * A version number is used to distinguish between two valid partitions with * the newsest version number (in a circular sense) marking the correct * partition to use. The parition number 0/1 is tracked via a static * variable. When the NvMem contents need to be updated, the flash erase/write * of the updated partition will use the inactive partition space in NvMem. This * way if there is a critical failure (i.e. loss of power) during the erase or * write operation, then the contents of the active partition prior the most * recent writes will still be preserved. * * The following CONFIG_FLASH_NVMEM_ defines are required for this module: * CONFIG_FLASH_NVMEM -> enable/disable the module * CONFIG_FLASH_NVMEM_OFFSET_(A|B) -> offset to start of each partition * CONFIG_FLASH_NVMEM_BASE_(A|B) -> address of start of each partition * * The board.h file must define a macro or enum named NVMEM_NUM_USERS. * The board.c file must include 1 function and an array of user buffer lengths * nvmem_user_sizes[] -> array of user buffer lengths * nvmem_compute_sha() -> function used to compute 4 byte sha (or equivalent) * * Note that total length of user buffers must satisfy the following: * sum(user sizes) <= (NVMEM_PARTITION_SIZE) - sizeof(struct nvmem_tag) */ /* NvMem user buffer length table */ extern uint32_t nvmem_user_sizes[NVMEM_NUM_USERS]; #define NVMEM_NUM_PARTITIONS 2 #define NVMEM_SHA_SIZE 4 #define NVMEM_VERSION_BITS 8 #define NVMEM_VERSION_MASK ((1 << NVMEM_VERSION_BITS) - 1) /* Struct for NV block tag */ struct nvmem_tag { uint8_t sha[NVMEM_SHA_SIZE]; uint8_t version; uint8_t reserved[3]; }; /* Structure MvMem Partition */ struct nvmem_partition { struct nvmem_tag tag; uint8_t buffer[NVMEM_PARTITION_SIZE - sizeof(struct nvmem_tag)]; }; /** * Initialize NVMem translation table and state variables * * @return EC_SUCCESS if a valid translation table is constructed, else * error code. */ int nvmem_init(void); /** * Get Nvmem internal error state * * @return nvmem_error_state variable. */ int nvmem_get_error_state(void); /** * Compare 'size' amount of bytes in NvMem * * @param offset: Offset (in bytes) into NVmem logical space * @param size: Number of bytes to compare * @param data: Pointer to data to be compared with * @param user: Data section within NvMem space * @return 0 if the data is same, non-zero if data is different */ int nvmem_is_different(uint32_t offset, uint32_t size, void *data, enum nvmem_users user); /** * Read 'size' amount of bytes from NvMem * * @param startOffset: Offset (in bytes) into NVmem logical space * @param size: Number of bytes to read * @param data: Pointer to destination buffer * @param user: Data section within NvMem space * @return EC_ERROR_OVERFLOW (non-zero) if the read operation would exceed the * buffer length of the given user, otherwise EC_SUCCESS. */ int nvmem_read(uint32_t startOffset, uint32_t size, void *data, enum nvmem_users user); /** * Write 'size' amount of bytes to NvMem * * @param startOffset: Offset (in bytes) into NVmem logical space * @param size: Number of bytes to write * @param data: Pointer to source buffer * @param user: Data section within NvMem space * @return EC_ERROR_OVERFLOW if write exceeds buffer length * EC_ERROR_TIMEOUT if nvmem cache buffer is not available * EC_SUCCESS if no errors. */ int nvmem_write(uint32_t startOffset, uint32_t size, void *data, enum nvmem_users user); /** * Move 'size' amount of bytes within NvMem * * @param src_offset: source offset within NvMem logical space * @param dest_offset: destination offset within NvMem logical space * @param size: Number of bytes to move * @param user: Data section within NvMem space * @return EC_ERROR_OVERFLOW if write exceeds buffer length * EC_ERROR_TIMEOUT if nvmem cache buffer is not available * EC_SUCCESS if no errors. */ int nvmem_move(uint32_t src_offset, uint32_t dest_offset, uint32_t size, enum nvmem_users user); /** * Commit all previous NvMem writes to flash * * @return EC_SUCCESS if flash erase/operations are successful. * EC_ERROR_UNKNOWN otherwise. */ int nvmem_commit(void); /** * One time initialization of NvMem partitions * @param version: Starting version number of partition 0 * * @return EC_SUCCESS if flash operations are successful. * EC_ERROR_UNKNOWN otherwise. */ int nvmem_setup(uint8_t version); /** * Compute sha1 (lower 4 bytes or equivalent checksum) for NvMem tag * * @param p_buf: pointer to beginning of data * @param num_bytes: length of data in bytes * @param p_sha: pointer to where computed sha will be stored * @param sha_len: length in bytes to use from sha computation */ void nvmem_compute_sha(uint8_t *p_buf, int num_bytes, uint8_t *p_sha, int sha_len); #endif /* __CROS_EC_NVMEM_UTILS_H */