FreeCalypso > hg > fc-magnetite

view src/cs/drivers/drv_app/ffs/board/drv.h @ 695:530f71d65c20

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
uartfax.c: pull from Tourmaline (GTM900 RI output) In addition to the primary intent of bringing in GTM900 RI output support, pulling uartfax.c wholesale from Tourmaline also changes the initial_time argument in the two NU_Create_Timer() calls from 0 to 1. This change is required for the new version of Nucleus used in Tourmaline and Selenite (and apparently also used by TI in LoCosto), and it is harmless (no effect) for the original TCS211 version of Nucleus used in Magnetite. The new philosophical model being adopted is that Tourmaline is our new development head firmware, whereas Magnetite will now be maintained similarly to how Linux maintainers treat stable kernels: changes will be backported from Tourmaline if they are deemed appropriate for stable modem firmware.
author Mychaela Falconia <falcon@freecalypso.org>
date Sat, 24 Oct 2020 17:33:10 +0000
parents 945cf7f506b2
children
line wrap: on
line source

/******************************************************************************
 * Flash File System (ffs)
 * Idea, design and coding by Mads Meisner-Jensen, mmj@ti.com
 *
 * ffs low level flash driver
 *
 * $Id: drv.h 1.15.1.25.1.1.1.20 Mon, 17 Nov 2003 08:51:37 +0100 tsj $
 *
 ******************************************************************************/

#ifndef TARGET
#include "ffs.cfg"
#endif

#if (TARGET == 1)
#include "chipset.cfg"
#endif


/******************************************************************************
 * Compile constants
 ******************************************************************************/

// FFS driver version (in four-digit BCD format). Format is MMID, where MM
// is major revision number, incremented e.g. for major revision or support
// for new flash family/driver. I is minor revision that is incremented for
// minor changes or when a bug is corrected. D is incremented when support
// of another device is added.
#define FFS_DRV_VERSION ((uint16) 0x1011)

// Default Allocation granularity of ffs data sectors (as power of two)
#define FFS_ATOM_LOG2 4


/******************************************************************************
 * Macros
 ******************************************************************************/

// Convert between address and block index. Only works if all blocks are the
// same size!
#define block2addr(block) (dev.base + dev.binfo[block].offset)

// Note that it is *VERY* important that pointers to hardware and flash are
// declared volatile, otherwise the compiler optimizes some reads and writes
// out and this results in non-working code!
#define FLASH_WRITE_HALFWORD(addr, data) *(volatile uint16 *) (addr) = (data)
#define FLASH_READ_HALFWORD(addr) *((volatile uint16 *) (addr))

#if (TARGET == 1)

#include "memif/mem.h"
#if (CHIPSET == 12)
  #include "sys_inth.h"
#else
#include "inth/inth.h" 
#endif

#if (CHIPSET == 3)
#define INT_REQUESTED (*(volatile uint16 *) INTH_IT_REG) & \
                        ~(*(volatile uint16 *) INTH_MASK_REG)
#elif (CHIPSET == 4 || CHIPSET == 5 || CHIPSET == 6 || CHIPSET == 7 || CHIPSET == 8 || CHIPSET == 9 || CHIPSET == 10 || CHIPSET == 11)
#define INT_REQUESTED ((*(volatile uint16 *) INTH_IT_REG1) & \
                         ~(*(volatile uint16 *) INTH_MASK_REG1)) || \
                        ((*(volatile uint16 *) INTH_IT_REG2) & \
                         ~(*(volatile uint16 *) INTH_MASK_REG2))
#elif (CHIPSET == 12)
#define INT_REQUESTED ((*(volatile uint16 *) C_INTH_IT_REG1) & \
                         ~(*(volatile uint16 *) C_INTH_MASK_REG1)) || \
                        ((*(volatile uint16 *) C_INTH_IT_REG2) & \
                         ~(*(volatile uint16 *) C_INTH_MASK_REG2))
#endif
#endif // (TARGET == 1)


/******************************************************************************
 * Types
 ******************************************************************************/

// Flash driver identifiers.
enum FFS_DRIVER {
    FFS_DRIVER_NULL          =  0, // Null driver

    FFS_DRIVER_AMD           =  2, // AMD dual/multi-bank driver
    FFS_DRIVER_AMD_SB        =  3, // AMD single-bank driver

    FFS_DRIVER_SST           =  8, // SST dual/multi-bank driver
    FFS_DRIVER_SST_SB        =  9, // SST single-bank driver

    FFS_DRIVER_INTEL         = 16, // Intel dual/multi-bank driver
    FFS_DRIVER_INTEL_SB      = 17, // Intel single-bank driver

    FFS_DRIVER_AMD_PSEUDO_SB = 32, // Test driver
    FFS_DRIVER_TEST          = 34, // Test driver

    FFS_DRIVER_RAM           = 64  // Ram driver
};


// Manufacturer identifiers. These should never have to be changed. They are
// ordered in alphabetically ascending order.
enum FFS_MANUFACTURER {
    MANUFACT_AMD     = 0x01,
    MANUFACT_ATMEL   = 0x1F,
    MANUFACT_FUJITSU = 0x04,
    MANUFACT_INTEL   = 0x89,
    MANUFACT_MXIC    = 0xC2,
    MANUFACT_SAMSUNG = 0xEC,
    MANUFACT_SHARP   = 0xB0,
    MANUFACT_SST     = 0xBF,
    MANUFACT_TOSHIBA = 0x98,
    MANUFACT_RAM     = 0xFE, // Ram 
    MANUFACT_TEST    = 0x54  // 'T'est manufacturer
};


// Flash block information for one ffs block (flash sector). Note that the
// ffs block definition might be of a smaller size then the physical flash
// sector. The ffs blocks must be defined in ascending order of addresses.
struct block_info_s {
    uint32 offset;
    uint8  size_ld;   // log2 of block size
    uint8  unused1;
    uint8  unused2;
    uint8  unused3;
};


// General flash information for one flash device
struct flash_info_s {
    const struct block_info_s *binfo; // block info array for this device
    char   *base;      // base flash address of ffs blocks
    uint16 manufact;   // read with flash A0 = 0
    uint16 device;     // read with flash A0 = 1
    uint8  driver;     // flash driver type
    uint8  numblocks;  // number of blocks defined for use by ffs
};
extern const struct flash_info_s flash_info[];

enum DEVICE_STATE {
    DEV_READ,
    DEV_ERASE,
    DEV_ERASE_SUSPEND,
    DEV_WRITE
};


// Note that it is *VERY* important that pointers to hardware and flash are
// declared volatile, otherwise the compiler optimizes some reads and writes
// out and this results in non-working code!
struct dev_s {
    char   *base;       // base flash address of ffs blocks
    struct block_info_s *binfo;
    uint16 manufact;
    uint16 device;
    volatile uint16 *addr; // address being written or erased
    uint16 data;           // data currently being written (dev.state = WRITE)
    uint32 blocksize;
    uint8  blocksize_ld;
    uint8  atomlog2;
    uint8  driver;
    uint8  state;       // state of device (DEVICE_STATE)
    uint8  numblocks;
    uint8  atomsize;
    uint8  atomnotmask;
};
extern struct dev_s dev;

    
// Flash low level driver function pointers
struct ffsdrv_s {
    int  (* init)(void);
    void (* erase)(uint8 block);
    void (* write_halfword)(volatile uint16 *dst, uint16 value);
    void (* write)(void *dst, const void *src, uint16 size);
    void (* write_end)(void);
    void (* erase_suspend)(void);
    void (* erase_resume)(void);
};
extern struct ffsdrv_s ffsdrv;


/******************************************************************************
 * Function Prototypes
 ******************************************************************************/

void ffsdrv_write_byte(void *dst, uint8 value);
effs_t ffsdrv_init(void);

extern int ffs_ram_image_address;