/* mbed Microcontroller Library * Copyright (c) 2016 ARM Limited * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef MBED_SPIF_BLOCK_DEVICE_H #define MBED_SPIF_BLOCK_DEVICE_H #include #include "BlockDevice.h" namespace mbed { /** Enum qspif standard error codes * * @enum qspif_bd_error */ enum qspif_bd_error { SPIF_BD_ERROR_OK = 0, /*!< no error */ SPIF_BD_ERROR_DEVICE_ERROR = BD_ERROR_DEVICE_ERROR, /*!< device specific error -4001 */ SPIF_BD_ERROR_PARSING_FAILED = -4002, /* SFDP Parsing failed */ SPIF_BD_ERROR_READY_FAILED = -4003, /* Wait for Mem Ready failed */ SPIF_BD_ERROR_WREN_FAILED = -4004, /* Write Enable Failed */ }; #define SPIF_MAX_REGIONS 10 #define MAX_NUM_OF_ERASE_TYPES 4 /** BlockDevice for SFDP based flash devices over SPI bus * * @code * // Here's an example using SPI flash device on K82F target * #include "mbed.h" * #include "SPIFBlockDevice.h" * * // Create flash device on SPI bus with PTE5 as chip select * SPIFBlockDevice spif(PTE2, PTE4, PTE1, PTE5); * * int main() { * printf("spif test\n"); * * // Initialize the SPI flash device and print the memory layout * spif.init(); * printf("spif size: %llu\n", spif.size()); * printf("spif read size: %llu\n", spif.get_read_size()); * printf("spif program size: %llu\n", spif.get_program_size()); * printf("spif erase size: %llu\n", spif.get_erase_size()); * * // Write "Hello World!" to the first block * char *buffer = (char*)malloc(spif.get_erase_size()); * sprintf(buffer, "Hello World!\n"); * spif.erase(0, spif.get_erase_size()); * spif.program(buffer, 0, spif.get_erase_size()); * * // Read back what was stored * spif.read(buffer, 0, spif.get_erase_size()); * printf("%s", buffer); * * // Deinitialize the device * spif.deinit(); * } * @endcode */ class SPIFBlockDevice : public BlockDevice { public: /** Creates a SPIFBlockDevice on a SPI bus specified by pins * * @param mosi SPI master out, slave in pin * @param miso SPI master in, slave out pin * @param sclk SPI clock pin * @param csel SPI chip select pin * @param freq Clock speed of the SPI bus (defaults to 40MHz) */ SPIFBlockDevice(PinName mosi, PinName miso, PinName sclk, PinName csel, int freq=40000000); /** Initialize a block device * * @return 0 on success or a negative error code on failure */ virtual int init(); /** Deinitialize a block device * * @return 0 on success or a negative error code on failure */ virtual int deinit(); /** Read blocks from a block device * * @param buffer Buffer to write blocks to * @param addr Address of block to begin reading from * @param size Size to read in bytes, must be a multiple of read block size * @return 0 on success, negative error code on failure */ virtual int read(void *buffer, bd_addr_t addr, bd_size_t size); /** Program blocks to a block device * * The blocks must have been erased prior to being programmed * * @param buffer Buffer of data to write to blocks * @param addr Address of block to begin writing to * @param size Size to write in bytes, must be a multiple of program block size * @return 0 on success, negative error code on failure */ virtual int program(const void *buffer, bd_addr_t addr, bd_size_t size); /** Erase blocks on a block device * * The state of an erased block is undefined until it has been programmed * * @param addr Address of block to begin erasing * @param size Size to erase in bytes, must be a multiple of erase block size * @return 0 on success, negative error code on failure */ virtual int erase(bd_addr_t addr, bd_size_t size); /** Get the size of a readable block * * @return Size of a readable block in bytes */ virtual bd_size_t get_read_size() const; /** Get the size of a programable block * * @return Size of a programable block in bytes * @note Must be a multiple of the read size */ virtual bd_size_t get_program_size() const; /** Get the size of a eraseable block * * @return Size of a eraseable block in bytes * @note Must be a multiple of the program size */ virtual bd_size_t get_erase_size() const; /** Get the size of an erasable block given address * * @param addr Address within the erasable block * @return Size of an erasable block in bytes * @note Must be a multiple of the program size */ virtual bd_size_t get_erase_size(bd_addr_t addr) const; /** Get the size of minimal eraseable sector size of given address * * @param addr Any address within block queried for erase sector size (can be any address within flash size offset) * @return Size of minimal erase sector size, in given address region, in bytes * @note Must be a multiple of the program size */ virtual bd_size_t get_erase_size(bd_addr_t addr); /** Get the value of storage byte after it was erased * * If get_erase_value returns a non-negative byte value, the underlying * storage is set to that value when erased, and storage containing * that value can be programmed without another erase. * * @return The value of storage when erased, or -1 if you can't * rely on the value of erased storage */ virtual int get_erase_value() const; /** Get the total size of the underlying device * * @return Size of the underlying device in bytes */ virtual bd_size_t size() const; private: /* SFDP Detection and Parsing Functions */ /****************************************/ // Parse SFDP Headers and retrieve Basic Param and Sector Map Tables (if exist) int _sfdp_parse_sfdp_headers(uint32_t& basic_table_addr, size_t& basic_table_size, uint32_t& sector_map_table_addr, size_t& sector_map_table_size); // Parse and Detect required Basic Parameters from Table int _sfdp_parse_basic_param_table(uint32_t basic_table_addr, size_t basic_table_size); // Parse and read information required by Regions Secotr Map int _sfdp_parse_sector_map_table(uint32_t sector_map_table_addr, size_t sector_map_table_size); // Detect fastest read Bus mode supported by device int _sfdp_detect_best_bus_read_mode(uint8_t *basic_param_table_ptr, bool& set_quad_enable, bool& is_qpi_mode, unsigned int& read_inst); // Set Page size for program int _sfdp_detect_page_size(uint8_t *basic_param_table_ptr); // Detect all supported erase types int _sfdp_detect_erase_types_inst_and_size(uint8_t *basic_param_table_ptr, unsigned int& erase4k_inst, unsigned int *erase_type_inst_arr, unsigned int *erase_type_size_arr); /* Utilities Functions */ /***********************/ // Find the region to which the given offset belong to int _utils_find_addr_region(bd_size_t offset); // Iterate on all supported Erase Types of the Region to which the offset belong to. // Iterates from highest type to lowest int _utils_iterate_next_largest_erase_type(uint8_t& bitfield, int size, int offset, int boundry); // Internal functions int _wren(); int _sync(); void _cmdread(uint8_t op, uint32_t addrc, uint32_t retc, uint32_t addr, uint8_t *rets); void _cmdwrite(uint8_t op, uint32_t addrc, uint32_t argc, uint32_t addr, const uint8_t *args); private: // Master side hardware SPI _spi; DigitalOut _cs; // Device configuration discovered through sfdp bd_size_t _size; bool _is_initialized; uint32_t _init_ref_count; bool _is_initialized; // Mutex is used to protect Flash device for some QSPI Driver commands that must be done sequentially with no other commands in between // e.g. (1)Set Write Enable, (2)Program, (3)Wait Memory Ready PlatformMutex _mutex; // Command Instructions unsigned int _read_instruction; unsigned int _prog_instruction; unsigned int _erase_instruction; unsigned int _erase4k_inst; // Legacy 4K erase instruction (default 0x20h) // Up To 4 Erase Types are supported by SFDP (each with its own command Instruction and Size) unsigned int _erase_type_inst_arr[MAX_NUM_OF_ERASE_TYPES]; unsigned int _erase_type_size_arr[MAX_NUM_OF_ERASE_TYPES]; // Sector Regions Map int _regions_count; //number of regions int _region_size_bytes[QSPIF_MAX_REGIONS]; //regions size in bytes bd_size_t _region_high_boundary[QSPIF_MAX_REGIONS]; //region high address offset boundary //Each Region can support a bit combination of any of the 4 Erase Types uint8_t _region_erase_types_bitfield[QSPIF_MAX_REGIONS]; int _min_common_erase_size; // minimal common erase size for all regions (0 if none exists) int _page_size_bytes; // Page size - 256 Bytes default bd_size_t _device_size_bytes; // Bus speed configuration qspi_bus_width_t _inst_width; //Bus width for Instruction phase qspi_bus_width_t _address_width; //Bus width for Address phase qspi_address_size_t _address_size; // number of bytes for address qspi_bus_width_t _data_width; //Bus width for Data phase int _dummy_and_mode_cycles; // Number of Dummy and Mode Bits required by Current Bus Mode }; } //namespace mbed #endif /* MBED_SPIF_BLOCK_DEVICE_H */