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/*
* This file is part of the flashrom project.
*
* Copyright (C) 2000 Silicon Integrated System Corporation
* Copyright (C) 2000 Ronald G. Minnich <rminnich@gmail.com>
* Copyright (C) 2005-2009 coresystems GmbH
* Copyright (C) 2006-2009 Carl-Daniel Hailfinger
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#ifndef __FLASH_H__
#define __FLASH_H__ 1
#include <inttypes.h>
#include <stdio.h>
#include <stdint.h>
#include <stddef.h>
#include <stdarg.h>
#include <stdbool.h>
#if IS_WINDOWS
#include <windows.h>
#undef min
#undef max
#endif
#include "libflashprog.h"
#include "layout.h"
#include "writeprotect.h"
#define KiB (1024)
#define MiB (1024 * KiB)
#define BIT(x) (1<<(x))
/* Assumes `n` and `a` are at most 64-bit wide (to avoid typeof() operator). */
#define ALIGN_DOWN(n, a) ((n) & ~((uint64_t)(a) - 1))
#define ERROR_PTR ((void*)-1)
/* Error codes */
#define ERROR_OOM -100
#define TIMEOUT_ERROR -101
/* TODO: check using code for correct usage of types */
typedef uintptr_t chipaddr;
#define PRIxPTR_WIDTH ((int)(sizeof(uintptr_t)*2))
int register_shutdown(int (*function) (void *data), void *data);
int shutdown_free(void *data);
void *programmer_map_flash_region(const char *descr, uintptr_t phys_addr, size_t len);
void programmer_unmap_flash_region(void *virt_addr, size_t len);
void programmer_delay(unsigned int usecs);
#define ARRAY_SIZE(a) (sizeof(a) / sizeof((a)[0]))
enum chipbustype {
BUS_NONE = 0,
BUS_PARALLEL = 1 << 0,
BUS_LPC = 1 << 1,
BUS_FWH = 1 << 2,
BUS_SPI = 1 << 3,
BUS_PROG = 1 << 4,
BUS_NONSPI = BUS_PARALLEL | BUS_LPC | BUS_FWH,
};
/*
* The following enum defines possible write granularities of flash chips. These tend to reflect the properties
* of the actual hardware not necessarily the write function(s) defined by the respective struct flashchip.
* The latter might (and should) be more precisely specified, e.g. they might bail out early if their execution
* would result in undefined chip contents.
*/
enum write_granularity {
/* We assume 256 byte granularity by default. */
write_gran_256bytes = 0,/* If less than 256 bytes are written, the unwritten bytes are undefined. */
write_gran_1bit, /* Each bit can be cleared individually. */
write_gran_1byte, /* A byte can be written once. Further writes to an already written byte cause
* its contents to be either undefined or to stay unchanged. */
write_gran_128bytes, /* If less than 128 bytes are written, the unwritten bytes are undefined. */
write_gran_264bytes, /* If less than 264 bytes are written, the unwritten bytes are undefined. */
write_gran_512bytes, /* If less than 512 bytes are written, the unwritten bytes are undefined. */
write_gran_528bytes, /* If less than 528 bytes are written, the unwritten bytes are undefined. */
write_gran_1024bytes, /* If less than 1024 bytes are written, the unwritten bytes are undefined. */
write_gran_1056bytes, /* If less than 1056 bytes are written, the unwritten bytes are undefined. */
write_gran_1byte_implicit_erase, /* EEPROMs and other chips with implicit erase and 1-byte writes. */
};
size_t gran_to_bytes(enum write_granularity);
/*
* How many different contiguous runs of erase blocks with one size each do
* we have for a given erase function?
*/
#define NUM_ERASEREGIONS 5
/*
* How many different erase functions do we have per chip?
* Macronix MX25L25635F has 8 different functions.
*/
#define NUM_ERASEFUNCTIONS 8
#define MAX_CHIP_RESTORE_FUNCTIONS 4
/* Feature bits used for non-SPI only */
#define FEATURE_REGISTERMAP (1 << 0)
#define FEATURE_LONG_RESET (0 << 4)
#define FEATURE_SHORT_RESET (1 << 4)
#define FEATURE_EITHER_RESET FEATURE_LONG_RESET
#define FEATURE_RESET_MASK (FEATURE_LONG_RESET | FEATURE_SHORT_RESET)
#define FEATURE_ADDR_FULL (0 << 2)
#define FEATURE_ADDR_MASK (3 << 2)
#define FEATURE_ADDR_2AA (1 << 2)
#define FEATURE_ADDR_AAA (2 << 2)
#define FEATURE_ADDR_SHIFTED (1 << 5)
/* Feature bits used for SPI only */
#define FEATURE_WRSR_EWSR (1 << 6)
#define FEATURE_WRSR_WREN (1 << 7)
#define FEATURE_WRSR_EITHER (FEATURE_WRSR_EWSR | FEATURE_WRSR_WREN)
#define FEATURE_OTP (1 << 8)
#define FEATURE_QPI (1 << 9)
#define FEATURE_4BA_ENTER (1 << 10) /**< Can enter/exit 4BA mode with instructions 0xb7/0xe9 w/o WREN */
#define FEATURE_4BA_ENTER_WREN (1 << 11) /**< Can enter/exit 4BA mode with instructions 0xb7/0xe9 after WREN */
#define FEATURE_4BA_ENTER_EAR7 (1 << 12) /**< Can enter/exit 4BA mode by setting bit7 of the ext addr reg */
#define FEATURE_4BA_EAR_C5C8 (1 << 13) /**< Regular 3-byte operations can be used by writing the most
significant address byte into an extended address register
(using 0xc5/0xc8 instructions). */
#define FEATURE_4BA_EAR_1716 (1 << 14) /**< Like FEATURE_4BA_EAR_C5C8 but with 0x17/0x16 instructions. */
#define FEATURE_4BA_READ (1 << 15) /**< Native 4BA read instruction (0x13) is supported. */
#define FEATURE_4BA_FAST_READ (1 << 16) /**< Native 4BA fast read instruction (0x0c) is supported. */
#define FEATURE_4BA_WRITE (1 << 17) /**< Native 4BA byte program (0x12) is supported. */
/* 4BA Shorthands */
#define FEATURE_4BA_EAR_ANY (FEATURE_4BA_EAR_C5C8 | FEATURE_4BA_EAR_1716)
#define FEATURE_4BA_NATIVE (FEATURE_4BA_READ | FEATURE_4BA_FAST_READ | FEATURE_4BA_WRITE)
#define FEATURE_4BA (FEATURE_4BA_ENTER | FEATURE_4BA_EAR_C5C8 | FEATURE_4BA_NATIVE)
#define FEATURE_4BA_WREN (FEATURE_4BA_ENTER_WREN | FEATURE_4BA_EAR_C5C8 | FEATURE_4BA_NATIVE)
#define FEATURE_4BA_EAR7 (FEATURE_4BA_ENTER_EAR7 | FEATURE_4BA_EAR_C5C8 | FEATURE_4BA_NATIVE)
/*
* Most flash chips are erased to ones and programmed to zeros. However, some
* other flash chips, such as the ENE KB9012 internal flash, work the opposite way.
*/
#define FEATURE_ERASED_ZERO (1 << 18)
#define FEATURE_NO_ERASE (1 << 19)
#define FEATURE_WRSR_EXT2 (1 << 20)
#define FEATURE_WRSR2 (1 << 21)
#define FEATURE_WRSR_EXT3 ((1 << 22) | FEATURE_WRSR_EXT2)
#define FEATURE_WRSR3 (1 << 23)
#define ERASED_VALUE(flash) (((flash)->chip->feature_bits & FEATURE_ERASED_ZERO) ? 0x00 : 0xff)
enum test_state {
OK = 0,
NT = 1, /* Not tested */
BAD, /* Known to not work */
DEP, /* Support depends on configuration (e.g. Intel flash descriptor) */
NA, /* Not applicable (e.g. write support on ROM chips) */
};
#define TEST_UNTESTED (struct tested){ .probe = NT, .read = NT, .erase = NT, .write = NT, .wp = NT }
#define TEST_OK_PROBE (struct tested){ .probe = OK, .read = NT, .erase = NT, .write = NT, .wp = NT }
#define TEST_OK_PR (struct tested){ .probe = OK, .read = OK, .erase = NT, .write = NT, .wp = NT }
#define TEST_OK_PRE (struct tested){ .probe = OK, .read = OK, .erase = OK, .write = NT, .wp = NT }
#define TEST_OK_PREW (struct tested){ .probe = OK, .read = OK, .erase = OK, .write = OK, .wp = NT }
#define TEST_OK_PREWB (struct tested){ .probe = OK, .read = OK, .erase = OK, .write = OK, .wp = OK }
#define TEST_BAD_PROBE (struct tested){ .probe = BAD, .read = NT, .erase = NT, .write = NT, .wp = NT }
#define TEST_BAD_PR (struct tested){ .probe = BAD, .read = BAD, .erase = NT, .write = NT, .wp = NT }
#define TEST_BAD_PRE (struct tested){ .probe = BAD, .read = BAD, .erase = BAD, .write = NT, .wp = NT }
#define TEST_BAD_PREW (struct tested){ .probe = BAD, .read = BAD, .erase = BAD, .write = BAD, .wp = NT }
#define TEST_BAD_PREWB (struct tested){ .probe = BAD, .read = BAD, .erase = BAD, .write = BAD, .wp = BAD }
struct flashprog_flashctx;
#define flashctx flashprog_flashctx /* TODO: Agree on a name and convert all occurrences. */
typedef int (erasefunc_t)(struct flashctx *flash, unsigned int addr, unsigned int blocklen);
enum flash_reg {
INVALID_REG = 0,
STATUS1,
STATUS2,
STATUS3,
MAX_REGISTERS
};
struct reg_bit_info {
/* Register containing the bit */
enum flash_reg reg;
/* Bit index within register */
uint8_t bit_index;
/*
* Writability of the bit. RW does not guarantee the bit will be
* writable, for example if status register protection is enabled.
*/
enum {
RO, /* Read only */
RW, /* Readable and writable */
OTP /* One-time programmable */
} writability;
};
struct wp_bits;
enum preparation_steps {
PREPARE_FULL,
};
struct flashchip {
const char *vendor;
const char *name;
enum chipbustype bustype;
/*
* With 32bit manufacture_id and model_id we can cover IDs up to
* (including) the 4th bank of JEDEC JEP106W Standard Manufacturer's
* Identification code.
*/
uint32_t manufacture_id;
uint32_t model_id;
/* Total chip size in kilobytes */
unsigned int total_size;
/* Chip page size in bytes */
unsigned int page_size;
int feature_bits;
/* Indicate how well flashprog supports different operations of this flash chip. */
struct tested {
enum test_state probe;
enum test_state read;
enum test_state erase;
enum test_state write;
enum test_state wp;
} tested;
/*
* Group chips that have common command sets. This should ensure that
* no chip gets confused by a probing command for a very different class
* of chips.
*/
enum {
/* SPI25 is very common. Keep it at zero so we don't have
to specify it for each and every chip in the database.*/
SPI25 = 0,
SPI95,
SPI_EDI,
} spi_cmd_set;
int (*probe) (struct flashctx *flash);
/* Delay after "enter/exit ID mode" commands in microseconds.
* NB: negative values have special meanings, see TIMING_* below.
*/
signed int probe_timing;
/*
* Erase blocks and associated erase function. Any chip erase function
* is stored as chip-sized virtual block together with said function.
* The first one that fits will be chosen. There is currently no way to
* influence that behaviour. For testing just comment out the other
* elements or set the function pointer to NULL.
*/
struct block_eraser {
struct eraseblock {
unsigned int size; /* Eraseblock size in bytes */
unsigned int count; /* Number of contiguous blocks with that size */
} eraseblocks[NUM_ERASEREGIONS];
/* a block_erase function should try to erase one block of size
* 'blocklen' at address 'blockaddr' and return 0 on success. */
int (*block_erase) (struct flashctx *flash, unsigned int blockaddr, unsigned int blocklen);
} block_erasers[NUM_ERASEFUNCTIONS];
int (*printlock) (struct flashctx *flash);
int (*unlock) (struct flashctx *flash);
int (*write) (struct flashctx *flash, const uint8_t *buf, unsigned int start, unsigned int len);
int (*read) (struct flashctx *flash, uint8_t *buf, unsigned int start, unsigned int len);
struct voltage {
uint16_t min;
uint16_t max;
} voltage;
enum write_granularity gran;
struct reg_bit_map {
/* Status register protection bit (SRP) */
struct reg_bit_info srp;
/* Status register lock bit (SRP) */
struct reg_bit_info srl;
/*
* Note: some datasheets refer to configuration bits that
* function like TB/SEC/CMP bits as BP bits (e.g. BP3 for a bit
* that functions like TB).
*
* As a convention, any config bit that functions like a
* TB/SEC/CMP bit should be assigned to the respective
* tb/sec/cmp field in this structure, even if the datasheet
* uses a different name.
*/
/* Block protection bits (BP) */
/* Extra element for terminator */
struct reg_bit_info bp[MAX_BP_BITS + 1];
/* Top/bottom protection bit (TB) */
struct reg_bit_info tb;
/* Sector/block protection bit (SEC) */
struct reg_bit_info sec;
/* Complement bit (CMP) */
struct reg_bit_info cmp;
/* Write Protect Selection (per sector protection when set) */
struct reg_bit_info wps;
} reg_bits;
/* Function that takes a set of WP config bits (e.g. BP, SEC, TB, etc) */
/* and determines what protection range they select. */
void (*decode_range)(size_t *start, size_t *len, const struct wp_bits *, size_t chip_len);
int (*prepare_access)(struct flashctx *, enum preparation_steps);
void (*finish_access)(struct flashctx *);
};
typedef int (*chip_restore_fn_cb_t)(struct flashctx *flash, uint8_t status);
struct flashprog_flashctx {
struct flashchip *chip;
/* FIXME: The memory mappings should be saved in a more structured way. */
/* The physical_* fields store the respective addresses in the physical address space of the CPU. */
uintptr_t physical_memory;
/* The virtual_* fields store where the respective physical address is mapped into flashprog's address
* space. A value equivalent to (chipaddr)ERROR_PTR indicates an invalid mapping (or none at all). */
chipaddr virtual_memory;
/* Some flash devices have an additional register space; semantics are like above. */
uintptr_t physical_registers;
chipaddr virtual_registers;
struct registered_master *mst;
const struct flashprog_layout *layout;
struct flashprog_layout *default_layout;
struct {
bool force;
bool force_boardmismatch;
bool verify_after_write;
bool verify_whole_chip;
} flags;
/* We cache the state of the extended address register (highest byte
of a 4BA for 3BA instructions) and the state of the 4BA mode here.
If possible, we enter 4BA mode early. If that fails, we make use
of the extended address register. */
int address_high_byte;
bool in_4ba_mode;
int chip_restore_fn_count;
struct chip_restore_func_data {
chip_restore_fn_cb_t func;
uint8_t status;
} chip_restore_fn[MAX_CHIP_RESTORE_FUNCTIONS];
};
/* Timing used in probe routines. ZERO is -2 to differentiate between an unset
* field and zero delay.
*
* SPI devices will always have zero delay and ignore this field.
*/
#define TIMING_FIXME -1
/* this is intentionally same value as fixme */
#define TIMING_IGNORED -1
#define TIMING_ZERO -2
extern const struct flashchip flashchips[];
extern const unsigned int flashchips_size;
/* parallel.c */
void chip_writeb(const struct flashctx *flash, uint8_t val, chipaddr addr);
void chip_writew(const struct flashctx *flash, uint16_t val, chipaddr addr);
void chip_writel(const struct flashctx *flash, uint32_t val, chipaddr addr);
void chip_writen(const struct flashctx *flash, const uint8_t *buf, chipaddr addr, size_t len);
uint8_t chip_readb(const struct flashctx *flash, const chipaddr addr);
uint16_t chip_readw(const struct flashctx *flash, const chipaddr addr);
uint32_t chip_readl(const struct flashctx *flash, const chipaddr addr);
void chip_readn(const struct flashctx *flash, uint8_t *buf, const chipaddr addr, size_t len);
/* print.c */
void print_buildinfo(void);
void print_version(void);
void print_banner(void);
int print_supported(void);
void print_supported_wiki(void);
/* helpers.c */
uint32_t address_to_bits(uint32_t addr);
unsigned int bitcount(unsigned long a);
#undef MIN
#define MIN(a, b) ((a) < (b) ? (a) : (b))
#undef MAX
#define MAX(a, b) ((a) > (b) ? (a) : (b))
int max(int a, int b);
int min(int a, int b);
char *strcat_realloc(char *dest, const char *src);
void tolower_string(char *str);
uint8_t reverse_byte(uint8_t x);
void reverse_bytes(uint8_t *dst, const uint8_t *src, size_t length);
#ifdef __MINGW32__
char* strtok_r(char *str, const char *delim, char **nextp);
char *strndup(const char *str, size_t size);
#endif
#if defined(__DJGPP__) || (!defined(__LIBPAYLOAD__) && !defined(HAVE_STRNLEN))
size_t strnlen(const char *str, size_t n);
#endif
/* flashprog.c */
extern const char flashprog_version[];
extern const char *chip_to_probe;
char *flashbuses_to_text(enum chipbustype bustype);
int map_flash(struct flashctx *flash);
void unmap_flash(struct flashctx *flash);
int read_memmapped(struct flashctx *flash, uint8_t *buf, unsigned int start, unsigned int len);
int erase_flash(struct flashctx *flash);
int probe_flash(struct registered_master *mst, int startchip, struct flashctx *fill_flash, int force);
int verify_range(struct flashctx *flash, const uint8_t *cmpbuf, unsigned int start, unsigned int len);
void emergency_help_message(void);
void list_programmers_linebreak(int startcol, int cols, int paren);
int selfcheck(void);
int read_buf_from_file(unsigned char *buf, unsigned long size, const char *filename);
int write_buf_to_file(const unsigned char *buf, unsigned long size, const char *filename);
int prepare_flash_access(struct flashctx *, bool read_it, bool write_it, bool erase_it, bool verify_it);
void finalize_flash_access(struct flashctx *);
int register_chip_restore(chip_restore_fn_cb_t func, struct flashctx *flash, uint8_t status);
/* Something happened that shouldn't happen, but we can go on. */
#define ERROR_NONFATAL 0x100
/* Something happened that shouldn't happen, we'll abort. */
#define ERROR_FATAL -0xee
#define ERROR_FLASHPROG_BUG -200
/* We reached one of the hardcoded limits of flashprog. This can be fixed by
* increasing the limit of a compile-time allocation or by switching to dynamic
* allocation.
* Note: If this warning is triggered, check first for runaway registrations.
*/
#define ERROR_FLASHPROG_LIMIT -201
/* cli_common.c */
void print_chip_support_status(const struct flashchip *chip);
/* cli_output.c */
extern enum flashprog_log_level verbose_screen;
extern enum flashprog_log_level verbose_logfile;
int open_logfile(const char * const filename);
int close_logfile(void);
void start_logging(void);
int flashprog_print_cb(enum flashprog_log_level level, const char *fmt, va_list ap);
/* Let gcc and clang check for correct printf-style format strings. */
int print(enum flashprog_log_level level, const char *fmt, ...)
#ifdef __MINGW32__
# ifndef __MINGW_PRINTF_FORMAT
# define __MINGW_PRINTF_FORMAT gnu_printf
# endif
__attribute__((format(__MINGW_PRINTF_FORMAT, 2, 3)));
#else
__attribute__((format(printf, 2, 3)));
#endif
#define msg_gerr(...) print(FLASHPROG_MSG_ERROR, __VA_ARGS__) /* general errors */
#define msg_perr(...) print(FLASHPROG_MSG_ERROR, __VA_ARGS__) /* programmer errors */
#define msg_cerr(...) print(FLASHPROG_MSG_ERROR, __VA_ARGS__) /* chip errors */
#define msg_gwarn(...) print(FLASHPROG_MSG_WARN, __VA_ARGS__) /* general warnings */
#define msg_pwarn(...) print(FLASHPROG_MSG_WARN, __VA_ARGS__) /* programmer warnings */
#define msg_cwarn(...) print(FLASHPROG_MSG_WARN, __VA_ARGS__) /* chip warnings */
#define msg_ginfo(...) print(FLASHPROG_MSG_INFO, __VA_ARGS__) /* general info */
#define msg_pinfo(...) print(FLASHPROG_MSG_INFO, __VA_ARGS__) /* programmer info */
#define msg_cinfo(...) print(FLASHPROG_MSG_INFO, __VA_ARGS__) /* chip info */
#define msg_gdbg(...) print(FLASHPROG_MSG_DEBUG, __VA_ARGS__) /* general debug */
#define msg_pdbg(...) print(FLASHPROG_MSG_DEBUG, __VA_ARGS__) /* programmer debug */
#define msg_cdbg(...) print(FLASHPROG_MSG_DEBUG, __VA_ARGS__) /* chip debug */
#define msg_gdbg2(...) print(FLASHPROG_MSG_DEBUG2, __VA_ARGS__) /* general debug2 */
#define msg_pdbg2(...) print(FLASHPROG_MSG_DEBUG2, __VA_ARGS__) /* programmer debug2 */
#define msg_cdbg2(...) print(FLASHPROG_MSG_DEBUG2, __VA_ARGS__) /* chip debug2 */
#define msg_gspew(...) print(FLASHPROG_MSG_SPEW, __VA_ARGS__) /* general debug spew */
#define msg_pspew(...) print(FLASHPROG_MSG_SPEW, __VA_ARGS__) /* programmer debug spew */
#define msg_cspew(...) print(FLASHPROG_MSG_SPEW, __VA_ARGS__) /* chip debug spew */
/* spi.c */
struct spi_command {
unsigned int writecnt;
unsigned int readcnt;
const unsigned char *writearr;
unsigned char *readarr;
};
#define NULL_SPI_CMD { 0, 0, NULL, NULL, }
int spi_send_command(const struct flashctx *flash, unsigned int writecnt, unsigned int readcnt, const unsigned char *writearr, unsigned char *readarr);
int spi_send_multicommand(const struct flashctx *flash, struct spi_command *cmds);
enum chipbustype get_buses_supported(void);
#endif /* !__FLASH_H__ */