/* <:copyright-BRCM:2012:DUAL/GPL:standard Copyright (c) 2012 Broadcom All Rights Reserved This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License, version 2, as published by the Free Software Foundation (the "GPL"). 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. A copy of the GPL is available at http://www.broadcom.com/licenses/GPLv2.php, or by writing to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. :> */ /** Includes. **/ #ifdef _CFE_ #include "lib_types.h" #include "lib_printf.h" #include "lib_string.h" #include "bcm_map_part.h" #define printk printf #else // linux #include #include #include #include #include #include #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,29) #include #endif #include #include #endif #include "bcmtypes.h" #include "bcm_hwdefs.h" #include "flash_api.h" #include "bcmSpiRes.h" #ifndef INC_BTRM_BUILD #define INC_BTRM_BUILD 0 #endif /** Defines. **/ #define OSL_DELAY(X) \ do { { int i; for( i = 0; i < (X) * 500; i++ ) ; } } while(0) #define MAX_RETRY 3 #ifndef NULL #define NULL 0 #endif #if (INC_BTRM_BUILD==1) /* reduce the memory usage for BTRM which only need to access up to 512KB */ #define MAXSECTORS 128 #else #define MAXSECTORS 8192 /* maximum number of sectors supported */ #endif #define FLASH_PAGE_256 256 #define SECTOR_SIZE_4K (4 * 1024) #define SECTOR_SIZE_64K (64 * 1024) /* Standard Boolean declarations */ #define TRUE 1 #define FALSE 0 /* Command codes for the flash_command routine */ #define FLASH_WRST 0x01 /* write status register */ #define FLASH_PROG 0x02 /* program data into memory array */ #define FLASH_READ 0x03 /* read data from memory array */ #define FLASH_WRDI 0x04 /* reset write enable latch */ #define FLASH_RDSR 0x05 /* read status register */ #define FLASH_WREN 0x06 /* set write enable latch */ #define FLASH_READ_FAST 0x0B /* read data from memory array */ #define FLASH_SERASE 0x20 /* erase one sector in memory array */ #define FLASH_BERASE 0xD8 /* erase one block in memory array */ #define FLASH_RDID 0x9F /* read manufacturer and product id */ #define FLASH_EN4B 0xB7 /* Enable 4 byte address mode */ #define FLASH_EXIT4B 0xE9 /* Exit 4 byte address mode */ #define FLASH_READ_DOR 0x3B /* dual output read */ #define FLASH_READ_DIOR 0xBB /* dual i/o read */ /* Spansion Extended Addressing opcodes for 4byte addresses */ #define FLASH_4PROG 0x12 /* program data into memory array */ #define FLASH_4READ 0x13 /* read data from memory array */ #define FLASH_4READ_FAST 0x0C /* read data from memory array */ #define FLASH_4SERASE 0x21 /* erase one sector in memory array */ #define FLASH_4BERASE 0xDC /* erase one block in memory array */ #define FLASH_4READ_DOR 0x3C /* dual output read */ #define FLASH_4READ_DIOR 0xBC /* dual i/o read */ /* Spansion specific commands */ #define FLASH_RDCR 0x35 /* Read Configuration Register */ /* RDSR return status bit definition */ #define SR_WPEN 0x80 #define SR_BP3 0x20 #define SR_BP2 0x10 #define SR_BP1 0x08 #define SR_BP0 0x04 #define SR_WEN 0x02 #define SR_RDY 0x01 /* Return codes from flash_status */ #define STATUS_READY 0 /* ready for action */ #define STATUS_BUSY 1 /* operation in progress */ #define STATUS_TIMEOUT 2 /* operation timed out */ #define STATUS_ERROR 3 /* unclassified but unhappy status */ /* Define different type of flash */ #define FLASH_UNDEFINED 0 #define FLASH_SPAN 2 /* SST's manufacturer ID */ #define SSTPART 0xBF /* A list of SST device IDs */ #define ID_SST25VF016 0x41 #define ID_SST25VF032 0x4A #define ID_SST25VF064 0x4B /* SPANSION manufacturer IDs */ #define SPANPART 0x01 /* SPANSION device ID's */ #define ID_SPAN25FL016 0x14 #define ID_SPAN25FL032 0x15 #define ID_SPAN25FL064 0x16 #define ID_SPAN25FL164 0x17 #define ID_SPAN25FL128 0x18 #define ID_SPAN25FL256 0x19 /* EON manufacturer ID */ #define EONPART 0x1C /* NUMONYX/Micron manufacturer ID */ #define NUMONYXPART 0x20 /* AMIC manufacturer ID */ #define AMICPART 0x37 /* Macronix manufacturer ID */ #define MACRONIXPART 0xC2 /* Gigadevice manufacturer ID */ #define GIGAPART 0xC8 /* Winbond's manufacturer ID */ #define WBPART 0xEF /* JEDEC device IDs */ #define ID_M25P8 0x14 #define ID_M25P16 0x15 #define ID_M25P32 0x16 #define ID_M25P64 0x17 #define ID_M25P128 0x18 #define ID_M25P256 0x19 /* flash memory type, the second byte returned from the READ ID instruction*/ #define FLASH_MEMTYPE_NULL 0x00 #define FLASH_MEMTYPE_20 0x20 #define FLASH_MEMTYPE_BA 0xBA #define SPI_MAKE_ID(A,B) \ (((unsigned short) (A) << 8) | ((unsigned short) B & 0xff)) #define SPI_FLASH_DEVICES \ {{SPI_MAKE_ID(SSTPART, ID_SST25VF016), "SST25VF016"}, \ {SPI_MAKE_ID(SSTPART, ID_SST25VF032), "SST25VF032"}, \ {SPI_MAKE_ID(SSTPART, ID_SST25VF064), "SST25VF064"}, \ {SPI_MAKE_ID(SPANPART, ID_SPAN25FL016), "S25FL016"}, \ {SPI_MAKE_ID(SPANPART, ID_SPAN25FL032), "S25FL032"}, \ {SPI_MAKE_ID(SPANPART, ID_SPAN25FL064), "S25FL064"}, \ {SPI_MAKE_ID(SPANPART, ID_SPAN25FL164), "S25FL164"}, \ {SPI_MAKE_ID(SPANPART, ID_SPAN25FL128), "S25FL128"}, \ {SPI_MAKE_ID(SPANPART, ID_SPAN25FL256), "S25FL256"}, \ {SPI_MAKE_ID(WBPART, ID_M25P16), "ID_W25X16"}, \ {SPI_MAKE_ID(WBPART, ID_M25P32), "ID_W25X32"}, \ {SPI_MAKE_ID(WBPART, ID_M25P64), "ID_W25X64"}, \ {SPI_MAKE_ID(WBPART, ID_M25P128), "ID_W25X128"}, \ {SPI_MAKE_ID(WBPART, ID_M25P256), "ID_W25X256"}, \ {SPI_MAKE_ID(EONPART, ID_M25P16), "EN25P16"}, \ {SPI_MAKE_ID(EONPART, ID_M25P32), "EN25P32"}, \ {SPI_MAKE_ID(EONPART, ID_M25P64), "EN25P64"}, \ {SPI_MAKE_ID(EONPART, ID_M25P128), "EN25P128"}, \ {SPI_MAKE_ID(AMICPART, ID_M25P16), "A25L016"}, \ {SPI_MAKE_ID(AMICPART, ID_M25P32), "A25L032"}, \ {SPI_MAKE_ID(NUMONYXPART, ID_M25P16), "NMNXM25P16"}, \ {SPI_MAKE_ID(NUMONYXPART, ID_M25P32), "NMNXM25P32"}, \ {SPI_MAKE_ID(NUMONYXPART, ID_M25P64), "NMNXM25P64"}, \ {SPI_MAKE_ID(NUMONYXPART, ID_M25P128), "NMNXM25P128"}, \ {SPI_MAKE_ID(NUMONYXPART, ID_M25P256), "MCRNN25Q256"}, \ {SPI_MAKE_ID(MACRONIXPART, ID_M25P8), "MX25L8"}, \ {SPI_MAKE_ID(MACRONIXPART, ID_M25P16), "MX25L16"}, \ {SPI_MAKE_ID(MACRONIXPART, ID_M25P32), "MX25L32"}, \ {SPI_MAKE_ID(MACRONIXPART, ID_M25P64), "MX25L64"}, \ {SPI_MAKE_ID(MACRONIXPART, ID_M25P128), "MX25L128"}, \ {SPI_MAKE_ID(MACRONIXPART, ID_M25P256), "MX25L256"}, \ {SPI_MAKE_ID(GIGAPART, ID_M25P64), "GD25Q64"}, \ {SPI_MAKE_ID(GIGAPART, ID_M25P128), "GD25LQ128"}, \ {SPI_MAKE_ID(GIGAPART, ID_M25P256), "GD25Q256"}, \ {0,""} \ } /** Structs. **/ /* A structure for identifying a flash part. There is one for each * of the flash part definitions. We need to keep track of the * sector organization, the address register used, and the size * of the sectors. */ struct flashinfo { char *name; /* "AT25F512", etc. */ unsigned long addr; /* physical address, once translated */ int nsect; /* # of sectors */ struct { long size; /* # of bytes in this sector */ long base; /* offset from beginning of device */ } sec[MAXSECTORS]; /* per-sector info */ }; #ifndef INC_BTRM_BOOT #define INC_BTRM_BOOT 0 #endif /** Prototypes. **/ static int my_spi_read( struct spi_transfer *xfer ); static int my_spi_write( unsigned char *msg_buf, int nbytes ); int spi_flash_init(flash_device_info_t **flash_info); static int spi_flash_sector_erase_int(unsigned short sector); static int spi_flash_reset(void); #if (INC_BTRM_BOOT==0) && defined(_CFE_) && defined(CFG_RAMAPP) static #endif int spi_flash_read_buf(unsigned short sector, int offset, unsigned char *buffer, int nbytes); static int spi_flash_ub(unsigned short sector); static int spi_flash_write(unsigned short sector, int offset, unsigned char *buffer, int nbytes); static int spi_flash_write_buf(unsigned short sector, int offset, unsigned char *buffer, int nbytes); static int spi_flash_get_numsectors(void); #if (INC_BTRM_BOOT==0) && defined(_CFE_) && defined(CFG_RAMAPP) static #endif int spi_flash_get_sector_size(unsigned short sector); static unsigned char *spi_get_flash_memptr(unsigned short sector); static unsigned char *spi_flash_get_memptr(unsigned short sector); static int spi_flash_status(void); static unsigned short spi_flash_get_device_id(unsigned int* memtype); static int spi_flash_get_blk(int addr); static int spi_flash_get_total_size(void); static int spi_flash_en4b(void); static int spi_flash_disable4b(void); static void spi_flash_multibit_en(void); /** Variables. **/ static flash_device_info_t flash_spi_dev = { 0xffff, FLASH_IFC_SPI, "", spi_flash_sector_erase_int, spi_flash_read_buf, spi_flash_write_buf, spi_flash_get_numsectors, spi_flash_get_sector_size, spi_flash_get_memptr, spi_flash_get_blk, spi_flash_get_total_size }; static struct flash_name_from_id fnfi[] = SPI_FLASH_DEVICES; /* the controller will handle operati0ns that are greater than the FIFO size code that relies on READ_BUF_LEN_MAX, READ_BUF_LEN_MIN or spi_max_op_len could be changed */ #define READ_BUF_LEN_MAX 544 /* largest of the maximum transaction sizes for SPI */ #define READ_BUF_LEN_MIN 60 /* smallest of the maximum transaction sizes for SPI */ /* this is the slave ID of the SPI flash for use with the SPI controller */ #define SPI_FLASH_SLAVE_DEV_ID 0 /* clock defines for the flash */ #define SPI_FLASH_DEF_CLOCK 781000 /* default to smallest transaction size - updated later */ static unsigned int spi_max_op_len = READ_BUF_LEN_MIN; static int spi_read_cmd = FLASH_READ_FAST; static int spi_dualOut_read_cmd = FLASH_READ_DOR; static int spi_dualIO_read_cmd = FLASH_READ_DIOR; static int spi_write_cmd = FLASH_PROG; static int spi_erase_cmd = FLASH_BERASE; static int spi_serase_cmd = FLASH_SERASE; static int spi_dummy_bytes = 1; static int spi_multibit_en = 0; static int flash_page_size = FLASH_PAGE_256; /* default to legacy controller - updated later */ static int spi_flash_clock = SPI_FLASH_DEF_CLOCK; static int spi_flash_busnum = LEG_SPI_BUS_NUM; #ifndef _CFE_ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 36) static DEFINE_SEMAPHORE(spi_flash_lock); #else static DECLARE_MUTEX(spi_flash_lock); #endif static bool bSpiFlashSlaveRes = FALSE; #endif static struct flashinfo meminfo; /* Flash information structure */ static int totalSize = 0; static int addr32 = FALSE; static int flashManufacturer = SPANPART; static int flashMemtype = FLASH_MEMTYPE_NULL; static int my_spi_read(struct spi_transfer *xfer) { int status; #ifndef _CFE_ if ( FALSE == bSpiFlashSlaveRes ) #endif { status = BcmSpi_MultibitRead(xfer, spi_flash_busnum, SPI_FLASH_SLAVE_DEV_ID); } #ifndef _CFE_ else { status = BcmSpiSyncMultTrans(xfer, 1, spi_flash_busnum, SPI_FLASH_SLAVE_DEV_ID); } #endif return status; } static int my_spi_write(unsigned char *msg_buf, int nbytes) { int status; #ifndef _CFE_ if ( FALSE == bSpiFlashSlaveRes ) #endif { status = BcmSpi_Write(msg_buf, nbytes, spi_flash_busnum, SPI_FLASH_SLAVE_DEV_ID, spi_flash_clock); } #ifndef _CFE_ else { status = BcmSpiSyncTrans(msg_buf, NULL, 0, nbytes, spi_flash_busnum, SPI_FLASH_SLAVE_DEV_ID); } #endif return status; } /*********************************************************************/ /* Init_flash is used to build a sector table. This information is */ /* translated from erase_block information to base:offset information*/ /* for each individual sector. This information is then stored */ /* in the meminfo structure, and used throughout the driver to access*/ /* sector information. */ /* */ /* This is more efficient than deriving the sector base:offset */ /* information every time the memory map switches (since on the */ /* development platform can only map 64k at a time). If the entire */ /* flash memory array can be mapped in, then the addition static */ /* allocation for the meminfo structure can be eliminated, but the */ /* drivers will have to be re-written. */ /* */ /* The meminfo struct occupies 44 bytes of heap space, depending */ /* on the value of the define MAXSECTORS. Adjust to suit */ /* application */ /*********************************************************************/ int spi_flash_init(flash_device_info_t **flash_info) { struct flash_name_from_id *fnfi_ptr; int i=0, count=0; int basecount=0L; unsigned short device_id; int sectorsize = 0; int numsector = 0; int spiCtrlState; #if defined(_BCM963268_) || defined(CONFIG_BCM963268) uint32 miscStrapBus = MISC->miscStrapBus; spi_flash_busnum = HS_SPI_BUS_NUM; if ( miscStrapBus & MISC_STRAP_BUS_HS_SPIM_CLK_SLOW_N_FAST ) spi_flash_clock = 50000000; else spi_flash_clock = 20000000; #endif #if defined(_BCM96838_) || defined(CONFIG_BCM96838) || defined(_BCM96848_) || defined(CONFIG_BCM96848) spi_flash_busnum = HS_SPI_BUS_NUM; spi_flash_clock = 20000000; // reset value #endif #if defined(_BCM960333_) || defined(CONFIG_BCM960333) spi_flash_busnum = HS_SPI_BUS_NUM; spi_flash_clock = 20000000; // reset value #endif #if defined(_BCM963138_) || defined(CONFIG_BCM963138) || defined(_BCM963381_) || defined(CONFIG_BCM963381) || defined(_BCM963148_) || defined(CONFIG_BCM963148) uint32 miscStrapBus = MISC->miscStrapBus; if( miscStrapBus & MISC_STRAP_BUS_HS_SPIM_CLK_SLOW_N_FAST ) spi_flash_clock = 50000000; else spi_flash_clock = 20000000; // reset value spi_flash_busnum = HS_SPI_BUS_NUM; #endif #if defined(_BCM94908_) || defined(CONFIG_BCM94908) || defined(_BCM96858_) || defined(CONFIG_BCM96858) || defined(_BCM6836_) || defined(CONFIG_BCM96836) || defined(_BCM963158_) || defined(CONFIG_BCM963158) spi_flash_busnum = HS_SPI_BUS_NUM; spi_flash_clock = 50000000; #endif /* retrieve the maximum read/write transaction length from the SPI controller */ spi_max_op_len = BcmSpi_GetMaxRWSize( spi_flash_busnum, 1 ); /* set the controller state, spi_mode_0 */ spiCtrlState = SPI_CONTROLLER_STATE_DEFAULT; if ( spi_flash_clock > SPI_CONTROLLER_MAX_SYNC_CLOCK ) spiCtrlState |= SPI_CONTROLLER_STATE_ASYNC_CLOCK; BcmSpi_SetCtrlState(spi_flash_busnum, SPI_FLASH_SLAVE_DEV_ID, SPI_MODE_DEFAULT, spiCtrlState); if (HS_SPI_BUS_NUM == spi_flash_busnum) flash_spi_dev.flash_type = FLASH_IFC_HS_SPI; *flash_info = &flash_spi_dev; #if 0 /* * in case of flash corrupt, the following steps can erase the flash * 1. jumper USE_SPI_SLAVE to make SPI in slave mode * 2. start up JTAG debuger and remove the USE_SPI_SLAVE jumper * 3. run the following code to erase the flash */ spi_flash_sector_erase_int(0); spi_flash_sector_erase_int(1); printk("flash_init: erase all sectors\n"); return FLASH_API_OK; #endif flash_spi_dev.flash_device_id = device_id = spi_flash_get_device_id((unsigned int*)&flashMemtype); flashManufacturer = device_id >> 8; switch( device_id >> 8 ) { case SSTPART: sectorsize = SECTOR_SIZE_4K; switch ((unsigned char)(device_id & 0x00ff)) { case ID_SST25VF016: numsector = 512; break; case ID_SST25VF032: numsector = 1024; break; case ID_SST25VF064: numsector = 2048; break; } break; case SPANPART: sectorsize = SECTOR_SIZE_64K; switch ((unsigned short)(device_id & 0x00ff)) { case ID_SPAN25FL016: numsector = 32; break; case ID_SPAN25FL032: numsector = 64; break; case ID_SPAN25FL064: case ID_SPAN25FL164: numsector = 128; break; case ID_SPAN25FL128: numsector = 256; break; case ID_SPAN25FL256: numsector = 512; addr32 = TRUE; break; } break; case EONPART: case GIGAPART: sectorsize = SECTOR_SIZE_64K; switch ((unsigned short)(device_id & 0x00ff)) { case ID_M25P8: numsector = 16; break; case ID_M25P16: numsector = 32; break; case ID_M25P32: numsector = 64; break; case ID_M25P64: numsector = 128; break; case ID_M25P128: numsector = 256; break; case ID_M25P256: numsector = 512; addr32 = TRUE; break; } break; case NUMONYXPART: case MACRONIXPART: case WBPART: case AMICPART: sectorsize = SECTOR_SIZE_4K; switch ((unsigned short)(device_id & 0x00ff)) { case ID_M25P8: numsector = 256; break; case ID_M25P16: numsector = 512; break; case ID_M25P32: numsector = 1024; break; case ID_M25P64: numsector = 2048; break; case ID_M25P128: numsector = 4096; break; case ID_M25P256: addr32 = TRUE; numsector = 8192; #if 1 // WARNING_13588 // This will speed up large flash devices but // only enable this change if it will be in CFE and // in EVERY version of Linux to be used. // If this is not consistent between CFE and Linux, // and an AUXFS is defined with a size that is not // an exact multiple of 64KB, bad things will happen. if( (((device_id >> 8) == NUMONYXPART) && flashMemtype == FLASH_MEMTYPE_BA) || ((device_id >> 8) == MACRONIXPART) ) { /* use 64K sector size to speed up the large flash part image update*/ sectorsize = SECTOR_SIZE_64K; numsector = 512; } #endif break; } break; #if defined(CONFIG_BRCM_IKOS) case 0x0e: sectorsize = SECTOR_SIZE_4K; numsector = 1024; printk("simulator spi flash dev id 0x%x\n", device_id); break; #endif default: #if (INC_BTRM_BUILD==1) /* make best effort to allow btrm to read first 512KB for unknown dev */ sectorsize = SECTOR_SIZE_4K; numsector = MAXSECTORS; break; #else meminfo.addr = 0L; meminfo.nsect = 1; meminfo.sec[0].size = SECTOR_SIZE_4K; meminfo.sec[0].base = 0x00000; return FLASH_API_ERROR; #endif } if( numsector > MAXSECTORS ) numsector = MAXSECTORS; meminfo.addr = 0L; meminfo.nsect = numsector; for (i = 0; i < numsector; i++) { meminfo.sec[i].size = sectorsize; meminfo.sec[i].base = basecount; basecount += meminfo.sec[i].size; count++; } totalSize = meminfo.sec[count-1].base + meminfo.sec[count-1].size; for( fnfi_ptr = fnfi; fnfi_ptr->fnfi_id != 0; fnfi_ptr++ ) { if( fnfi_ptr->fnfi_id == device_id ) { strcpy( flash_spi_dev.flash_device_name, fnfi_ptr->fnfi_name ); break; } } /* check to see if multibit mode is supported */ switch( device_id >> 8 ) { case SPANPART: if ( HS_SPI_BUS_NUM == spi_flash_busnum ) { spi_flash_multibit_en(); } break; default: break; } /* controller XIP mode does not support multibit io on 63138 */ #if !defined(_BCM963138_) && !defined(CONFIG_BCM963138) && !defined(_BCM963148_) && !defined(CONFIG_BCM963148) && !defined(_BCM94908_) && !defined(CONFIG_BCM94908) BcmSpi_SetFlashCtrl(spi_read_cmd, 1, spi_dummy_bytes, spi_flash_busnum, SPI_FLASH_SLAVE_DEV_ID, spi_flash_clock, spi_multibit_en); #endif return (FLASH_API_OK); } /*********************************************************************/ /* Flash_sector_erase_int() wait until the erase is completed before */ /* returning control to the calling function. This can be used in */ /* cases which require the program to hold until a sector is erased, */ /* without adding the wait check external to this function. */ /*********************************************************************/ static int spi_flash_sector_erase_int(unsigned short sector) { unsigned char buf[6]; unsigned int cmd_length; unsigned int addr; #ifndef _CFE_ down(&spi_flash_lock); #endif if ( addr32 ) spi_flash_en4b(); /* set device to write enabled */ spi_flash_ub(sector); /* erase the sector */ addr = (uintptr_t) spi_get_flash_memptr(sector); cmd_length = 0; if (meminfo.sec[sector].size == SECTOR_SIZE_4K) buf[cmd_length++] = spi_serase_cmd; else buf[cmd_length++] = spi_erase_cmd; if ( addr32 ) buf[cmd_length++] = (unsigned char)((addr & 0xff000000) >> 24); buf[cmd_length++] = (unsigned char)((addr & 0x00ff0000) >> 16); buf[cmd_length++] = (unsigned char)((addr & 0x0000ff00) >> 8); buf[cmd_length++] = (unsigned char)(addr & 0x000000ff); /* check device is ready */ if (my_spi_write(buf, cmd_length) == SPI_STATUS_OK) { while (spi_flash_status() != STATUS_READY); } spi_flash_reset(); if ( addr32 ) { spi_flash_disable4b(); } #ifndef _CFE_ up(&spi_flash_lock); #endif return(FLASH_API_OK); } /*********************************************************************/ /* spi_flash_en4b() will enable the flash part to start using 4 byte addressing mode. */ /*********************************************************************/ static int spi_flash_en4b(void) { unsigned char buf[4]; static int initialized = 0; if (flashManufacturer == SPANPART) { int latencyCode = 0; struct spi_transfer xfer; if (!initialized) { initialized = 1; spi_read_cmd = FLASH_4READ_FAST; spi_dualOut_read_cmd = FLASH_4READ_DOR; spi_dualIO_read_cmd = FLASH_4READ_DIOR; spi_write_cmd = FLASH_4PROG; spi_erase_cmd = FLASH_4BERASE; spi_serase_cmd = FLASH_4SERASE; memset(&xfer, 0, sizeof(struct spi_transfer)); buf[0] = FLASH_RDCR; xfer.tx_buf = buf; xfer.rx_buf = buf; xfer.len = 1; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = 1; my_spi_read(&xfer); while (spi_flash_status() != STATUS_READY); latencyCode = (buf[0] & 0xC0) >> 6; if (latencyCode == 0x3) { spi_dummy_bytes = 0; } } } else { /* Micron require WRITE ENABLE cmd to enter 4 byte mode */ if (flashManufacturer == NUMONYXPART) { buf[0] = FLASH_WREN; my_spi_write(buf, 1); } /* set device to enter 4 byte addressing mode */ buf[0] = FLASH_EN4B; my_spi_write(buf, 1); while (spi_flash_status() != STATUS_READY); } return(FLASH_API_OK); } /*********************************************************************/ /* spi_flash_disable4b() will disable the 4byte addressing mode on the flash part. */ /*********************************************************************/ static int spi_flash_disable4b(void) { if (flashManufacturer != SPANPART) { unsigned char buf[4]; /* Micron require WRITE ENABLE cmd to exit 4 byte mode */ if (flashManufacturer == NUMONYXPART) { buf[0] = FLASH_WREN; my_spi_write(buf, 1); } buf[0] = FLASH_EXIT4B; my_spi_write(buf, 1); while (spi_flash_status() != STATUS_READY); } return(FLASH_API_OK); } /*********************************************************************/ /* flash_reset() will reset the flash device to reading array data. */ /* It is good practice to call this function after autoselect */ /* sequences had been performed. */ /*********************************************************************/ static int spi_flash_reset(void) { unsigned char buf[4]; /* set device to write disabled */ buf[0] = FLASH_WRDI; my_spi_write(buf, 1); while (spi_flash_status() != STATUS_READY); return(FLASH_API_OK); } /*********************************************************************/ /* flash_read_buf() reads buffer of data from the specified */ /* offset from the sector parameter. */ /*********************************************************************/ #if (INC_BTRM_BOOT==0) && defined(_CFE_) && defined(CFG_RAMAPP) static #endif int spi_flash_read_buf(unsigned short sector, int offset, unsigned char *buffer, int nbytes) { unsigned char buf[READ_BUF_LEN_MAX]; unsigned int cmd_length; unsigned int addr; int maxread; int size_read = 0; int multiOffset = 0; struct spi_transfer xfer; memset(&xfer, 0, sizeof(struct spi_transfer)); #ifndef _CFE_ down(&spi_flash_lock); #endif addr = (uintptr_t) spi_get_flash_memptr(sector); addr += offset; if ( addr32 ) { spi_flash_en4b(); } while (nbytes > 0) { maxread = (nbytes < spi_max_op_len) ? nbytes : spi_max_op_len; cmd_length = 0; buf[cmd_length++] = spi_read_cmd; if ( addr32 ) buf[cmd_length++] = (unsigned char)((addr & 0xff000000) >> 24); buf[cmd_length++] = (unsigned char)((addr & 0x00ff0000) >> 16); buf[cmd_length++] = (unsigned char)((addr & 0x0000ff00) >> 8); buf[cmd_length++] = (unsigned char)(addr & 0x000000ff); if (spi_dummy_bytes) buf[cmd_length++] = (unsigned char)0xff; if (spi_multibit_en) { if ( spi_read_cmd == spi_dualOut_read_cmd ) multiOffset = cmd_length; /* only read data is multibit */ else multiOffset = 1; /* addr and data is multibit */ } xfer.tx_buf = buf; xfer.rx_buf = buffer; xfer.len = maxread; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = cmd_length; xfer.multi_bit_en = spi_multibit_en; xfer.multi_bit_start_offset = multiOffset; xfer.addr_len = (addr32 ? 4 : 3); xfer.addr_offset = 1; xfer.hdr_len = cmd_length; xfer.unit_size = 1; my_spi_read(&xfer); #if defined(CONFIG_BRCM_IKOS) /* simulator only support read cmd */ { int i; for( i = 0; i < 256; i++ ); } #else while (spi_flash_status() != STATUS_READY); #endif buffer += maxread; nbytes -= maxread; addr += maxread; size_read += maxread; } if ( addr32 ) { spi_flash_disable4b(); } #ifndef _CFE_ up(&spi_flash_lock); #endif return size_read; } /*********************************************************************/ /* flash_ub() places the flash into unlock bypass mode. This */ /* is REQUIRED to be called before any of the other unlock bypass */ /* commands will become valid (most will be ignored without first */ /* calling this function. */ /*********************************************************************/ static int spi_flash_ub(unsigned short sector) { unsigned char buf[4]; struct spi_transfer xfer; do { buf[0] = FLASH_RDSR; memset(&xfer, 0, sizeof(struct spi_transfer)); xfer.tx_buf = buf; xfer.rx_buf = buf; xfer.len = 1; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = 1; if (my_spi_read(&xfer) == SPI_STATUS_OK) { while (spi_flash_status() != STATUS_READY); if (buf[0] & (SR_BP3|SR_BP2|SR_BP1|SR_BP0)) { /* Sector is write protected. Unprotect it */ buf[0] = FLASH_WREN; if (my_spi_write(buf, 1) == SPI_STATUS_OK) { buf[0] = FLASH_WRST; buf[1] = 0; if (my_spi_write(buf, 2) == SPI_STATUS_OK) while (spi_flash_status() != STATUS_READY); } } else { break; } } else { break; } } while (1); /* set device to write enabled */ buf[0] = FLASH_WREN; /* check device is ready */ if (my_spi_write(buf, 1) == SPI_STATUS_OK) { while (spi_flash_status() != STATUS_READY); do { buf[0] = FLASH_RDSR; memset(&xfer, 0, sizeof(struct spi_transfer)); xfer.tx_buf = buf; xfer.rx_buf = buf; xfer.len = 1; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = 1; if (my_spi_read(&xfer) == SPI_STATUS_OK) { while (spi_flash_status() != STATUS_READY); if (buf[0] & SR_WEN) { break; } } else { break; } } while (1); } return(FLASH_API_OK); } /*********************************************************************/ /* flash_write_buf() utilizes */ /* the unlock bypass mode of the flash device. This can remove */ /* significant overhead from the bulk programming operation, and */ /* when programming bulk data a sizeable performance increase can be */ /* observed. */ /*********************************************************************/ static int spi_flash_write(unsigned short sector, int offset, unsigned char *buffer, int nbytes) { unsigned char buf[FLASH_PAGE_256 + 6]; unsigned int cmd_length; unsigned int addr; int maxwrite; int pagelimit; int bytes_written = 0; #ifndef _CFE_ down(&spi_flash_lock); #endif addr = (uintptr_t) spi_get_flash_memptr(sector); addr += offset; if ( addr32 ) { spi_flash_en4b(); } while (nbytes > 0) { spi_flash_ub(sector); /* enable write */ cmd_length = 0; buf[cmd_length++] = spi_write_cmd; if ( addr32 ) buf[cmd_length++] = (unsigned char)((addr & 0xff000000) >> 24); buf[cmd_length++] = (unsigned char)((addr & 0x00ff0000) >> 16); buf[cmd_length++] = (unsigned char)((addr & 0x0000ff00) >> 8); buf[cmd_length++] = (unsigned char)(addr & 0x000000ff); /* set length to the smaller of controller limit (spi_max_op_len) or nbytes spi_max_op_len considers both controllers */ maxwrite = (nbytes < (spi_max_op_len - cmd_length)) ? nbytes : (spi_max_op_len - cmd_length); /* maxwrite is limit to page boundary */ pagelimit = flash_page_size - (addr & (flash_page_size - 1)); maxwrite = (maxwrite < pagelimit) ? maxwrite : pagelimit; memcpy(&buf[cmd_length], buffer, maxwrite); my_spi_write(buf, maxwrite + cmd_length); while (spi_flash_status() != STATUS_READY); buffer += maxwrite; nbytes -= maxwrite; addr += maxwrite; bytes_written += maxwrite; } spi_flash_reset(); if ( addr32 ) { spi_flash_disable4b(); } #ifndef _CFE_ up(&spi_flash_lock); #endif return( bytes_written ); } /*********************************************************************/ /* flash_write_buf() utilizes */ /* the unlock bypass mode of the flash device. This can remove */ /* significant overhead from the bulk programming operation, and */ /* when programming bulk data a sizeable performance increase can be */ /* observed. */ /*********************************************************************/ static int spi_flash_write_buf(unsigned short sector, int offset, unsigned char *buffer, int nbytes) { int ret; ret = spi_flash_write(sector, offset, buffer, nbytes); #if (INC_BTRM_BOOT==0) if( ret == FLASH_API_ERROR ) printk( "Flash write error. Verify failed\n" ); #endif return( ret ); } /*********************************************************************/ /* Usefull funtion to return the number of sectors in the device. */ /* Can be used for functions which need to loop among all the */ /* sectors, or wish to know the number of the last sector. */ /*********************************************************************/ static int spi_flash_get_numsectors(void) { return meminfo.nsect; } /*********************************************************************/ /* flash_get_sector_size() is provided for cases in which the size */ /* of a sector is required by a host application. The sector size */ /* (in bytes) is returned in the data location pointed to by the */ /* 'size' parameter. */ /*********************************************************************/ #if (INC_BTRM_BOOT==0) && defined(_CFE_) && defined(CFG_RAMAPP) static #endif int spi_flash_get_sector_size(unsigned short sector) { return meminfo.sec[sector].size; } /*********************************************************************/ /* The purpose of get_flash_memptr() is to return a memory pointer */ /* which points to the beginning of memory space allocated for the */ /* flash. All function pointers are then referenced from this */ /* pointer. */ /* */ /* Different systems will implement this in different ways: */ /* possibilities include: */ /* - A direct memory pointer */ /* - A pointer to a memory map */ /* - A pointer to a hardware port from which the linear */ /* address is translated */ /* - Output of an MMU function / service */ /* */ /* Also note that this function expects the pointer to a specific */ /* sector of the device. This can be provided by dereferencing */ /* the pointer from a translated offset of the sector from a */ /* global base pointer (e.g. flashptr = base_pointer + sector_offset)*/ /* */ /* Important: Many AMD flash devices need both bank and or sector */ /* address bits to be correctly set (bank address bits are A18-A16, */ /* and sector address bits are A18-A12, or A12-A15). Flash parts */ /* which do not need these bits will ignore them, so it is safe to */ /* assume that every part will require these bits to be set. */ /*********************************************************************/ static unsigned char *spi_get_flash_memptr(unsigned short sector) { unsigned char *memptr = (unsigned char*) (meminfo.sec[sector].base); return (memptr); } static unsigned char *spi_flash_get_memptr(unsigned short sector) { return( FLASH_BASE + spi_get_flash_memptr(sector) ); } /*********************************************************************/ /* Flash_status return an appropriate status code */ /*********************************************************************/ static int spi_flash_status(void) { unsigned char buf[4]; int retry = 10; struct spi_transfer xfer; /* check device is ready */ memset(&xfer, 0, sizeof(struct spi_transfer)); do { buf[0] = FLASH_RDSR; xfer.tx_buf = buf; xfer.rx_buf = buf; xfer.len = 1; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = 1; if (my_spi_read(&xfer) == SPI_STATUS_OK) { if (!(buf[0] & SR_RDY)) { return STATUS_READY; } } else { return STATUS_ERROR; } OSL_DELAY(10); } while (retry--); return STATUS_TIMEOUT; } /*********************************************************************/ /* flash_get_device_id() return the device id of the component. */ /*********************************************************************/ static unsigned short spi_flash_get_device_id(unsigned int* memtype) { #if defined(CONFIG_BRCM_IKOS) return 0x0e0e; #else unsigned char buf[4]; unsigned char *pBuf = buf; struct spi_transfer xfer; memset(&xfer, 0, sizeof(struct spi_transfer)); buf[0] = FLASH_RDID; xfer.tx_buf = buf; xfer.rx_buf = buf; xfer.len = 3; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = 1; my_spi_read(&xfer); while (spi_flash_status() != STATUS_READY); *memtype = (unsigned int)(buf[1]); #if defined(__MIPSEL) || defined(__ARMEL__) || defined(__AARCH64EL__) buf[1] = buf[0]; buf[0] = buf[2]; #else buf[1] = buf[2]; #endif /* return manufacturer code and device code */ return( *((unsigned short *)pBuf) ); #endif } /*********************************************************************/ /* The purpose of flash_get_blk() is to return a the block number */ /* for a given memory address. */ /*********************************************************************/ static int spi_flash_get_blk(int addr) { int blk_start, i; int last_blk = spi_flash_get_numsectors(); int relative_addr = addr - (int) FLASH_BASE; for(blk_start=0, i=0; i < relative_addr && blk_start < last_blk; blk_start++) i += spi_flash_get_sector_size(blk_start); if( (unsigned int)i > (unsigned int)relative_addr ) { blk_start--; // last blk, dec by 1 } else { if( blk_start == last_blk ) { #if (INC_BTRM_BOOT==0) printk("Address is too big.\n"); #endif blk_start = -1; } } return( blk_start ); } /************************************************************************/ /* The purpose of flash_get_total_size() is to return the total size of */ /* the flash */ /************************************************************************/ static int spi_flash_get_total_size(void) { return totalSize; } static void spi_flash_multibit_en( void ) { unsigned char buf[16]; unsigned char bufCmp[16]; unsigned int cmd_length; unsigned int addr; struct spi_transfer xfer; int i; memset(&xfer, 0, sizeof(struct spi_transfer)); #ifndef _CFE_ down(&spi_flash_lock); #endif /* read 16 bytes of data form the first sector of flash this will be used to compare to the data read using the DOR and DIOR commands */ addr = (uintptr_t) spi_get_flash_memptr(NVRAM_SECTOR); cmd_length = 0; buf[cmd_length++] = spi_read_cmd; if ( addr32 ) { spi_flash_en4b(); buf[cmd_length++] = (unsigned char)((addr & 0xff000000) >> 24); } buf[cmd_length++] = (unsigned char)((addr & 0x00ff0000) >> 16); buf[cmd_length++] = (unsigned char)((addr & 0x0000ff00) >> 8); buf[cmd_length++] = (unsigned char)(addr & 0x000000ff); if ( spi_dummy_bytes ) buf[cmd_length++] = (unsigned char)0xff; xfer.tx_buf = buf; xfer.rx_buf = buf; xfer.len = 16; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = cmd_length; my_spi_read(&xfer); while (spi_flash_status() != STATUS_READY); /* if the data read above is all 1's then we cannot determine if multibit is supported by the flash so just return */ for ( i = 0; i < 16; i++) { if ( buf[i] != 0xFF ) { break; } if ( 15 == i ) { if ( addr32 ) { spi_flash_disable4b(); } #ifndef _CFE_ up(&spi_flash_lock); #endif return; } } /* try the DIOR instruction if the data matches the previously read data then it is supported */ addr = (uintptr_t) spi_get_flash_memptr(NVRAM_SECTOR); cmd_length = 0; bufCmp[cmd_length++] = spi_dualIO_read_cmd; if ( addr32 ) bufCmp[cmd_length++] = (unsigned char)((addr & 0xff000000) >> 24); bufCmp[cmd_length++] = (unsigned char)((addr & 0x00ff0000) >> 16); bufCmp[cmd_length++] = (unsigned char)((addr & 0x0000ff00) >> 8); bufCmp[cmd_length++] = (unsigned char)(addr & 0x000000ff); if (spi_dummy_bytes) { bufCmp[cmd_length++] = (unsigned char)0xff; } xfer.tx_buf = bufCmp; xfer.rx_buf = bufCmp; xfer.len = 16; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = cmd_length; xfer.multi_bit_en = 1; xfer.multi_bit_start_offset = 1; my_spi_read(&xfer); while (spi_flash_status() != STATUS_READY); if ( 0 == memcmp(buf, bufCmp, 16) ) { /* DIOR command is supported */ spi_read_cmd = spi_dualIO_read_cmd; spi_multibit_en = 1; if ( addr32 ) { spi_flash_disable4b(); } #ifndef _CFE_ up(&spi_flash_lock); #endif return; } /* try the DOR command if the data matches the previously read data then it is supported */ addr = (uintptr_t) spi_get_flash_memptr(NVRAM_SECTOR); cmd_length = 0; bufCmp[cmd_length++] = spi_dualOut_read_cmd; if ( addr32 ) bufCmp[cmd_length++] = (unsigned char)((addr & 0xff000000) >> 24); bufCmp[cmd_length++] = (unsigned char)((addr & 0x00ff0000) >> 16); bufCmp[cmd_length++] = (unsigned char)((addr & 0x0000ff00) >> 8); bufCmp[cmd_length++] = (unsigned char)(addr & 0x000000ff); if (spi_dummy_bytes) { bufCmp[cmd_length++] = (unsigned char)0xff; } xfer.tx_buf = bufCmp; xfer.rx_buf = bufCmp; xfer.len = 16; xfer.speed_hz = spi_flash_clock; xfer.prepend_cnt = cmd_length; xfer.multi_bit_en = 1; xfer.multi_bit_start_offset = cmd_length; my_spi_read(&xfer); while (spi_flash_status() != STATUS_READY); if ( 0 == memcmp(buf, bufCmp, 16) ) { /* DOR command is supported */ spi_read_cmd = spi_dualOut_read_cmd; spi_multibit_en = 1; if ( addr32 ) { spi_flash_disable4b(); } #ifndef _CFE_ up(&spi_flash_lock); #endif return; } if ( addr32 ) { spi_flash_disable4b(); } #ifndef _CFE_ up(&spi_flash_lock); #endif } #ifndef _CFE_ static int __init BcmSpiflash_init(void) { int flashType; int spiCtrlState; /* If serial flash is present then register the device. Otherwise do nothing */ flashType = flash_get_flash_type(); if ((FLASH_IFC_SPI == flashType) || (FLASH_IFC_HS_SPI == flashType)) { /* register the device */ spiCtrlState = SPI_CONTROLLER_STATE_DEFAULT; if ( spi_flash_clock > SPI_CONTROLLER_MAX_SYNC_CLOCK ) spiCtrlState |= SPI_CONTROLLER_STATE_ASYNC_CLOCK; BcmSpiReserveSlave2(spi_flash_busnum, SPI_FLASH_SLAVE_DEV_ID, spi_flash_clock, SPI_MODE_DEFAULT, spiCtrlState); bSpiFlashSlaveRes = TRUE; spi_max_op_len = BcmSpi_GetMaxRWSize( spi_flash_busnum, 1 ); } return 0; } module_init(BcmSpiflash_init); static void __exit BcmSpiflash_exit(void) { bSpiFlashSlaveRes = FALSE; } module_exit(BcmSpiflash_exit); #endif