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- #ifndef SPIFLASH_H
- #define SPIFLASH_H
- #include <inttypes.h>
- #include <stddef.h>
- #include <string.h>
- #include "fwimg.h"
- /* SPI flash command opcodes */
- enum romcmd {
- /* Standard SPI mode commands */
- ROM_WRITE_ENABLE = 0x06,
- ROM_VOLATILE_SR_WRITE_ENABLE = 0x50,
- ROM_WRITE_DISABLE = 0x04,
- ROM_RELEASE_POWERDOWN_ID = 0xab,
- ROM_MANUFACTURER_DEVICE_ID = 0x90,
- ROM_JEDEC_ID = 0x9f,
- ROM_READ_UNIQUE_ID = 0x4b,
- ROM_READ_DATA = 0x03, /* DO NOT USE */
- ROM_READ_DATA_32BIT = 0x13, /* DO NOT USE */
- ROM_FAST_READ = 0x0b,
- ROM_FAST_READ_32BIT = 0x0c,
- ROM_PAGE_PROGRAM = 0x02,
- ROM_PAGE_PROGRAM_32BIT = 0x12,
- ROM_ERASE_4K = 0x20,
- ROM_ERASE_4K_32BIT = 0x21,
- ROM_ERASE_32K = 0x52,
- ROM_ERASE_64K = 0xd8,
- ROM_ERASE_64K_32BIT = 0xdc,
- ROM_ERASE_ALL = 0xc7,
- ROM_READ_SR1 = 0x05,
- ROM_WRITE_SR1 = 0x01,
- ROM_READ_SR2 = 0x35,
- ROM_WRITE_SR2 = 0x31,
- ROM_READ_SR3 = 0x15,
- ROM_WRITE_SR3 = 0x11,
- ROM_READ_EAR = 0xc8, /* Extended address register */
- ROM_WRITE_EAR = 0xc5,
- ROM_READ_SFDP = 0x5a,
- ROM_ERASE_SECURITY = 0x44,
- ROM_PROGRAM_SECURITY = 0x42,
- ROM_READ_SECURITY = 0x48,
- ROM_GLOBAL_BLOCK_LOCK = 0x7e,
- ROM_GLOBAL_BLOCK_UNLOCK = 0x98,
- ROM_READ_BLOCK_LOCK = 0x3d,
- ROM_ONE_BLOCK_LOCK = 0x36,
- ROM_ONE_BLOCK_UNLOCK = 0x39,
- ROM_ERASE_PROGRAM_SUSPEND = 0x75,
- ROM_ERASE_PROGRAM_RESUME = 0x7a,
- ROM_POWER_DOWN = 0xb9,
- ROM_ENTER_32BIT = 0xb7,
- ROM_LEAVE_32BIT = 0xe9,
- ROM_ENTER_QPI = 0x48,
- ROM_ENABLE_RESET = 0x66,
- ROM_RESET = 0x99,
- /* Dual SPI commands */
- ROM_FAST_READ_DUAL = 0x3b,
- ROM_FAST_READ_DUAL_32BIT = 0x3c
- };
- #define SPIFLASH_SFDP_SIZE 256
- /*
- * A page is an amount that can be programmed in one operation.
- * A sector is the minimum amount that can be erased in one operation.
- * A block is the optimal amount that can be erased in one operation.
- *
- * These are defined in hardware!
- */
- #define SPIFLASH_PAGE_SHIFT 8 /* May be smaller than an actual page */
- #define SPIFLASH_PAGE_SIZE (1 << SPIFLASH_PAGE_SHIFT)
- #define SPIFLASH_SECTOR_SHIFT 12
- #define SPIFLASH_SECTOR_SIZE (1 << SPIFLASH_SECTOR_SHIFT)
- #define SPIFLASH_BLOCK_SHIFT 16
- #define SPIFLASH_BLOCK_SIZE (1 << SPIFLASH_BLOCK_SHIFT)
- /*
- * Interface to the host. This structure should be passed in to the
- * initialization routine and will not be modified by the spiflash
- * routines.
- *
- * The spiflash code is reentrant if there are multiple SPI flash
- * devices. None are timing critical and may be preempted at any
- * time if applicable. When CS# is active (during spi_read or spi_write),
- * it MUST NOT be deasserted; if the bus is shared HOLD# can be asserted
- * (without deasserting CS#) to make the device release the bus without
- * affecting the state of the device.
- *
- * CS# will not be asserted while running in the core code or when
- * blocking for I/O; the host is obviously allowed to prefetch I/O
- * within the above constraints if the bus is shared.
- *
- * A private cookie pointer is passed to each function; this can be a
- * pointer back to the spiflash_ops structure, but does not have to
- * be.
- */
- struct spiflash_ops {
- /*
- * Perform a SPI write operation. The SPI write operation consists of:
- * 1. Assert CS# (and deassert HOLD# if applicable)
- * 2. Transmit the command bytes (discard MISO input)
- * 3. Transmit the data bytes (discard MISO input)
- * 4. Deassert CS#
- * 5. Wait tCHSL (see SPI data table below)
- *
- * The number of data bytes may be zero. Note that the command
- * and data operations are identical and are separated only to
- * avoid unnecessary data copies.
- *
- * If this returns nonzero, no further operations are performed
- * and the top-level flash routine terminates immediately with
- * the returned value as a status code.
- *
- * It is not required that this routine blocks until tCHSL
- * is satisfied, however, the host is responsible to not assert
- * CS# again until tCHSL is satisfied. The SPI clock may run
- * or not during that time period.
- *
- * The SPI flash supports SPI modes 0 and 3.
- */
- int (*spi_write)(void *cookie,
- const void *cmd, unsigned int cmd_len,
- const void *data, unsigned int data_len,
- int tshsl);
- /*
- * Perform a SPI read operation. The SPI read operation consists of:
- * 1. Assert CS# (and deassert HOLD# if applicable)
- * 2. Transmit the command bytes (discard MISO input)
- * 3. Receive the data bytes (MOSI is don't care)
- * 4. Deassert CS#
- * 5. Wait tCHSL (see SPI data table below)
- *
- * The number of data bytes may be zero. Note that the command
- * and data operations are identical and are separated only to
- * avoid unnecessary data copies.
- *
- * If this returns nonzero, no further operations are performed
- * and the top-level flash routine terminates immediately with
- * the returned value as a status code.
- *
- * It is not required that this routine blocks until tCHSL
- * is satisfied, however, the host is responsible to not assert
- * CS# again until tCHSL is satisfied. The SPI clock may run
- * or not during that time period.
- *
- * The SPI flash supports SPI modes 0 and 3.
- */
- int (*spi_read)(void *cookie,
- const void *cmd, unsigned int cmd_len,
- void *data, unsigned int data_len,
- int tshsl);
- /*
- * Inform the host that the spiflash code is waiting for an
- * program or erase operation to complete. This can be used to
- * yield the host for other operations.
- *
- * The value passed in is the corresponding from the SPI data
- * table below; these are arbitrary cookies/units as far as the
- * spiflash code is concerned.
- *
- * This function may be NULL, in which case the SPI flash is polled
- * continously.
- */
- void (*yield)(void *cookie, int delay);
- };
- /*
- * This table provides some parameters for the SPI flash.
- */
- enum spiflash_addr_mode {
- SPIFLASH_ADDR_DYNAMIC, /* 24-bit for < 16 MB, otherwise 32 bit */
- SPIFLASH_ADDR_24BIT, /* 24-bit addressing only */
- SPIFLASH_ADDR_32BIT /* 32-bit addressing only */
- };
- struct spiflash_param {
- /*
- * Addressing mode (see above.) If SPIFLASH_ADDR_DYNAMIC is
- * specified (default), the chip is assumed to be in 24-bit-default
- * mode, and 32-bit opcodes will be used as needed.
- */
- enum spiflash_addr_mode addr;
- /*
- * CS# deselect times passed to spi_read() and spi_write().
- * Arbitrary units or cookies that are only interpreted by
- * the spi_read and spi_write routines.
- */
- int tshsl; /* All other operations */
- int tshsl1; /* Read operations */
- int tshsl2; /* Erase, Program, and Write operations */
- /*
- * Delay values to pass to the yield operation. Arbitrary units
- * or cookies that are only interpreted by the yield routine.
- *
- * Not all of these are used by the current code, but are specified
- * for future-proofing reasons.
- */
- int trst; /* Reset command to next instruction */
- int tw; /* Write Status Register Time */
- int tpp; /* Page Program Time */
- int tse; /* Sector Erase Time (4K) */
- int tbe1; /* Block Erase Time (32K) */
- int tbe2; /* Block Erase Time (64K) */
- int tce; /* Chip Erase Time */
- };
- /* Common structure for the above */
- struct spiflash {
- /*
- * Read input data for flash write. Return the number of bytes
- * read. A short read or a 0 byte return value represents end of
- * file/end of data; a negative value is treated as 0, and will be
- * returned from the top-level operation as a status code.
- *
- * It is not required to detect end of input if and only if the
- * input is a gzip file, as in that case the gzip data will contain
- * an end of stream indicator.
- *
- * The buffer initially passed to this function will always be
- * aligned to a malloc() alignment boundary; it will preserve
- * alignment boundaries if and only if short read returns only byte
- * counts in multiple of those alignment boundaries.
- *
- * If there is a memory buffer available containing full or
- * partial input data on entry, pass it to spiflash_flash_file();
- * If this memory buffer contains all available input, this
- * function can be NULL.
- *
- * A partial memory buffer must contain a full stream header block.
- */
- int (*read_data)(void *cookie, void *buf, unsigned int bufsize);
- void *cookie; /* Pointer passed to spiflash_ops functions */
- /*
- * Operations on the SPI flash itself; if ops == NULL then this is a
- * dry run operation.
- */
- const struct spiflash_ops *ops;
- const struct spiflash_param *param;
- const char *target; /* What are we programming? */
- };
- /*
- * Additional error codes
- */
- #define SPIFLASH_ERR_ERASE_FAILED (-7)
- #define SPIFLASH_ERR_PROGRAM_FAILED (-8)
- #define SPIFLASH_ERR_WRITE_PROTECT (-9)
- #define SPIFLASH_ERR_NOT_READY (-10)
- #define SPIFLASH_ERR_DETECT (-11)
- /*
- * Top-level operations. These may return an error value from the ops
- * functions, any of the negative error values defined in zlib.h,
- * or one of the above error codes.
- */
- int spiflash_flash_file(const struct spiflash *flash,
- void *data, size_t datalen);
- /*
- * Flash a single region of data to the SPI flash.
- */
- int spiflash_flash_data(const struct spiflash *flash, uint32_t addr,
- const void *data, size_t datalen);
- /*
- * Read identifying data from SPI flash.
- */
- #define SPIFLASH_ID_LEN 8
- int spiflash_read_id(const struct spiflash *flash, void *id);
- #define SPIFLASH_VDID_LEN 2
- int spiflash_read_vdid(const struct spiflash *flash, void *vdid);
- #endif
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