FreeCalypso > hg > freecalypso-sw
view gsm-fw/services/ffs/drv.c @ 504:7b2ceea92a2e
osx.c: osx_alloc_prim() done
| author | Michael Spacefalcon <msokolov@ivan.Harhan.ORG> |
|---|---|
| date | Tue, 01 Jul 2014 19:08:20 +0000 |
| parents | 4d706a4134b0 |
| children | 0fb9b7f2ef87 |
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/****************************************************************************** * Flash File System (ffs) * Idea, design and coding by Mads Meisner-Jensen, mmj@ti.com * * ffs low level flash driver * * $Id: drv.c 1.30.1.6.1.51.1.1.1.13.1.11 Tue, 06 Jan 2004 14:36:52 +0100 tsj $ * ******************************************************************************/ #include "../../include/config.h" #include "ffs.h" #include "drv.h" #include "core.h" /* for FFS_BLOCKS_MAX */ #include "ffstrace.h" #include "intctl.h" #include "ramffs.h" #include <string.h> /****************************************************************************** * "Block info" stupidity ******************************************************************************/ static struct block_info_s block_info[FFS_BLOCKS_MAX]; /****************************************************************************** * Macros ******************************************************************************/ #define addr2offset(address) ( (int) (address) - (int) dev.base ) /****************************************************************************** * Generic Driver Functions ******************************************************************************/ // Note: This function is designed for little-endian memory addressing! void ffsdrv_write_byte(void *dst, uint8 value) { uint16 halfword; tw(tr(TR_FUNC, TrDrvWrite, "ffsdrv_write_byte(0x%05x, 0x%x)\n", (int) (addr2offset(dst)), value)); ttw(str(TTrDrvWrite, "wb" NL)); if ((int) dst & 1) halfword = (value << 8) | *((uint8 *) dst - 1); else halfword = (*((uint8 *) dst + 1) << 8) | (value); ffsdrv.write_halfword((uint16 *) ((int) dst & ~1), halfword); } void ffsdrv_generic_write(void *dst, const void *src, uint16 size) { uint8 *mydst = dst; const uint8 *mysrc = src; if (size > 0) { if ((unsigned int) mydst & 1) { ffsdrv_write_byte(mydst++, *mysrc++); size--; } while (size >= 2) { ffsdrv.write_halfword((uint16 *) mydst, mysrc[0] | (mysrc[1] << 8)); size -= 2; mysrc += 2; mydst += 2; } if (size == 1) ffsdrv_write_byte(mydst++, *mysrc++); } } /****************************************************************************** * Dummy Functions ******************************************************************************/ int ffsdrv_null_init(void) { ttw(ttr(TTrDrvOther, "ffsdrv_null_init()" NL)); return 0; } void ffsdrv_null_erase(uint8 block) { ttw(ttr(TTrDrvErase, "ffsdrv_null_erase(%d)" NL, block)); } void ffsdrv_null_write_halfword(volatile uint16 *addr, uint16 value) { ttw(ttr(TTrDrvWrite, "ffsdrv_null_write_halfword(0x%x, 0x%x)" NL, addr, value)); } void ffsdrv_null_write(void *dst, const void *src, uint16 size) { ttw(ttr(TTrDrvWrite, "ffsdrv_null_write(0x%x, 0x%x, %d)" NL, dst, src, size)); } void ffsdrv_null_erase_suspend(void) { ttw(str(TTrDrvErase, "ffsdrv_null_erase_suspend()" NL)); } void ffsdrv_null_erase_resume(void) { ttw(str(TTrDrvErase, "ffsdrv_null_erase_resume()" NL)); } void ffsdrv_null_write_end(void) { ttw(str(TTrDrvWrite, "ffsdrv_null_write_end()" NL)); } void ffsdrv_null_erase_end(void) { ttw(str(TTrDrvErase, "ffsdrv_null_erase_end()" NL)); } /* * FreeCalypso change from TI: we only compile one flash "driver" type * based on the build configuration. */ #if FFS_IN_RAM /****************************************************************************** * RAM Family Functions ******************************************************************************/ void ffsdrv_ram_write_halfword(volatile uint16 *dst, uint16 value) { *dst = value; } #if 0 /* duplicates ffsdrv_generic_write */ void ffsdrv_ram_write(void *dst, const void *src, uint16 size) { uint8 *mydst = dst; const uint8 *mysrc = src; if (size == 0) return; else if (size == 1) ffsdrv_write_byte(mydst, *mysrc); else { if ((int) mydst & 1) { ffsdrv_write_byte(mydst++, *mysrc++); size--; } while (size >= 2) { ffsdrv_ram_write_halfword((uint16 *) mydst, mysrc[0]|(mysrc[1] << 8)); size -= 2; mysrc += 2; mydst += 2; } if (size == 1) ffsdrv_write_byte(mydst++, *mysrc++); } } #endif void ffsdrv_ram_erase(uint8 block) { int i; char *addr; addr = block2addr(block); for (i = 0; i < (1 << dev.binfo[block].size_ld); i++) { *addr++ = 0xFF; } } const struct ffsdrv_s ffsdrv = { ffsdrv_null_init, ffsdrv_ram_erase, ffsdrv_ram_write_halfword, ffsdrv_generic_write, ffsdrv_null_write_end, ffsdrv_null_erase_suspend, ffsdrv_null_erase_resume }; #elif CONFIG_FLASH_WRITE /****************************************************************************** * AMD Dual/Multi Bank Driver Functions ******************************************************************************/ // All erase and write operations are performed atomically (interrupts // disabled). Otherwise we cannot trust the value of dev.state and we cannot // determine exactly how many of the command words have already been // written. // in ffs_end() when we resume an erasure that was previously suspended, how // does that affect multiple tasks doing that simultaneously? void ffsdrv_amd_write_end(void); void ffsdrv_amd_erase_end(void); void ffsdrv_amd_write_halfword(volatile uint16 *addr, uint16 value) { volatile char *flash = dev.base; uint32 cpsr; tlw(led_on(LED_WRITE)); ttw(ttr(TTrDrvWrite, "wh(%x,%x)" NL, addr, value)); dev.addr = addr; dev.data = value; if (~*addr & value) { ttw(ttr(TTrFatal, "wh(%x,%x->%x) fatal" NL, addr, *addr, value)); return; } cpsr = int_disable(); tlw(led_toggle(LED_WRITE_SUSPEND)); dev.state = DEV_WRITE; flash[0xAAAA] = 0xAA; // unlock cycle 1 flash[0x5555] = 0x55; // unlock cycle 2 flash[0xAAAA] = 0xA0; *addr = value; int_enable(cpsr); tlw(led_toggle(LED_WRITE_SUSPEND)); ffsdrv_amd_write_end(); } #if 0 /* duplicates ffsdrv_generic_write */ void ffsdrv_amd_write(void *dst, const void *src, uint16 size) { uint8 *mydst = dst; const uint8 *mysrc = src; if (size > 0) { if ((unsigned int) mydst & 1) { ffsdrv_write_byte(mydst++, *mysrc++); size--; } while (size >= 2) { ffsdrv_amd_write_halfword((uint16 *) mydst, mysrc[0] | (mysrc[1] << 8)); size -= 2; mysrc += 2; mydst += 2; } if (size == 1) ffsdrv_write_byte(mydst++, *mysrc++); } } #endif void ffsdrv_amd_write_end(void) { while ((*dev.addr ^ dev.data) & 0x80) tlw(led_toggle(LED_WRITE_SUSPEND)); dev.state = DEV_READ; tlw(led_off(LED_WRITE)); } void ffsdrv_amd_erase(uint8 block) { volatile char *flash = dev.base; uint32 cpsr; tlw(led_on(LED_ERASE)); ttw(ttr(TTrDrvErase, "e(%d)" NL, block)); dev.addr = (uint16 *) block2addr(block); cpsr = int_disable(); dev.state = DEV_ERASE; flash[0xAAAA] = 0xAA; // unlock cycle 1 flash[0x5555] = 0x55; // unlock cycle 2 flash[0xAAAA] = 0x80; flash[0xAAAA] = 0xAA; // unlock cycle 1 flash[0x5555] = 0x55; // unlock cycle 2 *dev.addr = 0x30; // AMD erase sector command int_enable(cpsr); ffsdrv_amd_erase_end(); } void ffsdrv_amd_erase_end(void) { while ((*dev.addr & 0x80) == 0) ; dev.state = DEV_READ; tlw(led_off(LED_ERASE)); } void ffsdrv_amd_erase_suspend(void) { uint32 cpsr; tlw(led_on(LED_ERASE_SUSPEND)); ttw(str(TTrDrvErase, "es" NL)); // if erase has finished then all is ok if (*dev.addr & 0x80) { ffsdrv_amd_erase_end(); tlw(led_off(LED_ERASE_SUSPEND)); return; } // NOTEME: As there is no way to be absolutely certain that erase // doesn't finish between last poll and the following erase suspend // command, we assume that the erase suspend is safe even though the // erase IS actually already finished. cpsr = int_disable(); dev.state = DEV_ERASE_SUSPEND; *dev.addr = 0xB0; // Wait for erase suspend to finish while ((*dev.addr & 0x80) == 0) ; int_enable(cpsr); } void ffsdrv_amd_erase_resume(void) { uint32 cpsr; ttw(str(TTrDrvErase, "er" NL)); // NOTEME: See note in erase_suspend()... We assume that the erase // resume is safe even though the erase IS actually already finished. cpsr = int_disable(); dev.state = DEV_ERASE; *dev.addr = 0x30; int_enable(cpsr); tlw(led_off(LED_ERASE_SUSPEND)); } const struct ffsdrv_s ffsdrv = { ffsdrv_null_init, ffsdrv_amd_erase, ffsdrv_amd_write_halfword, ffsdrv_generic_write, ffsdrv_amd_write_end, ffsdrv_amd_erase_suspend, ffsdrv_amd_erase_resume }; #else /* * This part will get compiled if we have real FFS (FFS_IN_RAM=0), * but not allowed to write to flash (CONFIG_FLASH_WRITE=0). */ const struct ffsdrv_s ffsdrv = { ffsdrv_null_init, ffsdrv_null_erase, ffsdrv_null_write_halfword, ffsdrv_null_write, ffsdrv_null_write_end, ffsdrv_null_erase_suspend, ffsdrv_null_erase_resume }; #endif /****************************************************************************** * Initialization * * Significantly simplified in FreeCalypso. * ******************************************************************************/ effs_t ffsdrv_init(void) { int error; unsigned i; uint32 offset; tw(tr(TR_BEGIN, TrDrvInit, "drv_init() {\n")); ttw(str(TTrDrvOther, "ffsdrv_init() {" NL)); dev.state = DEV_READ; dev.atomlog2 = FFS_ATOM_LOG2; dev.atomsize = 1 << dev.atomlog2; dev.atomnotmask = dev.atomsize - 1; offset = 0; for (i = 0; i < dev.numblocks; i++) { block_info[i].offset = offset; block_info[i].size_ld = dev.blocksize_ld; offset += dev.blocksize; } dev.binfo = block_info; error = ffsdrv.init(); tw(tr(TR_FUNC, TrDrvInit, "dev.binfo = 0x%x\n", (unsigned int) dev.binfo)); tw(tr(TR_FUNC, TrDrvInit, "dev.base = 0x%x\n", (unsigned int) dev.base)); tw(tr(TR_FUNC, TrDrvInit, "dev.numblocks = %d\n", dev.numblocks)); tw(tr(TR_FUNC, TrDrvInit, "dev.blocksize = %d\n", dev.blocksize)); tw(tr(TR_FUNC, TrDrvInit, "dev.atomlog2/atomsize/atomnotmask = %d/%d/%x\n", dev.atomlog2, dev.atomsize, dev.atomnotmask)); tw(tr(TR_END, TrDrvInit, "} %d\n", error)); ttw(ttr(TTrDrvOther, "} %d" NL, error)); return error; }