From: Mike Frysinger Date: Wed, 5 May 2010 05:08:53 +0000 (-0400) Subject: Blackfin: bf537-stamp: drop old spi_flash driver X-Git-Url: http://git.dujemihanovic.xyz/?a=commitdiff_plain;h=7393a09800599b1aa90e23288c82e6ca2d8294b4;p=u-boot.git Blackfin: bf537-stamp: drop old spi_flash driver The new common spi framework and spi flash subsystem provides all the same functionality as the old Blackfin-specific driver, so punt the old one as it has been sticking around long enough. Signed-off-by: Mike Frysinger --- diff --git a/board/bf537-stamp/Makefile b/board/bf537-stamp/Makefile index f728e2c0da..0e15062ba8 100644 --- a/board/bf537-stamp/Makefile +++ b/board/bf537-stamp/Makefile @@ -31,7 +31,6 @@ LIB = $(obj)lib$(BOARD).a COBJS-y := $(BOARD).o cmd_bf537led.o COBJS-$(CONFIG_BFIN_IDE) += ide-cf.o -COBJS-$(CONFIG_CMD_EEPROM) += spi_flash.o COBJS-$(CONFIG_POST) += post.o post-memory.o SRCS := $(SOBJS-y:.o=.S) $(COBJS-y:.o=.c) diff --git a/board/bf537-stamp/spi_flash.c b/board/bf537-stamp/spi_flash.c deleted file mode 100644 index 7b753ad6a2..0000000000 --- a/board/bf537-stamp/spi_flash.c +++ /dev/null @@ -1,996 +0,0 @@ -/* - * SPI flash driver - * - * Enter bugs at http://blackfin.uclinux.org/ - * - * Copyright (c) 2005-2008 Analog Devices Inc. - * - * Licensed under the GPL-2 or later. - */ - -/* Configuration options: - * CONFIG_SPI_BAUD - value to load into SPI_BAUD (divisor of SCLK to get SPI CLK) - * CONFIG_SPI_FLASH_SLOW_READ - force usage of the slower read - * WARNING: make sure your SCLK + SPI_BAUD is slow enough - */ - -#include -#include -#include -#include -#include - -/* Forcibly phase out these */ -#ifdef CONFIG_SPI_FLASH_NUM_SECTORS -# error do not set CONFIG_SPI_FLASH_NUM_SECTORS -#endif -#ifdef CONFIG_SPI_FLASH_SECTOR_SIZE -# error do not set CONFIG_SPI_FLASH_SECTOR_SIZE -#endif - -#if defined(CONFIG_SPI) - -struct flash_info { - char *name; - uint16_t id; - uint16_t ext_id; - unsigned sector_size; - unsigned num_sectors; -}; - -/* SPI Speeds: 50 MHz / 33 MHz */ -static struct flash_info flash_spansion_serial_flash[] = { - { "S25FL016", 0x0215, 0, 64 * 1024, 32 }, - { "S25FL032", 0x0216, 0, 64 * 1024, 64 }, - { "S25FL064", 0x0217, 0, 64 * 1024, 128 }, - { "S25FL128-00", 0x2018, 0x0301, 64 * 1024, 256 }, /* Package marking FL128PIF */ - { "S25FL128-01", 0x2018, 0x0300, 128 * 1024, 64 }, /* Package marking FL128PIFL */ - { NULL, 0, 0, 0, 0 } -}; - -/* SPI Speeds: 50 MHz / 20 MHz */ -static struct flash_info flash_st_serial_flash[] = { - { "m25p05", 0x2010, 0, 32 * 1024, 2 }, - { "m25p10", 0x2011, 0, 32 * 1024, 4 }, - { "m25p20", 0x2012, 0, 64 * 1024, 4 }, - { "m25p40", 0x2013, 0, 64 * 1024, 8 }, - { "m25p80", 0x20FF, 0, 64 * 1024, 16 }, - { "m25p16", 0x2015, 0, 64 * 1024, 32 }, - { "m25p32", 0x2016, 0, 64 * 1024, 64 }, - { "m25p64", 0x2017, 0, 64 * 1024, 128 }, - { "m25p128", 0x2018, 0, 256 * 1024, 64 }, - { NULL, 0, 0, 0, 0 } -}; - -/* SPI Speeds: 20 MHz / 40 MHz */ -static struct flash_info flash_sst_serial_flash[] = { - { "SST25WF512", 0x2501, 0, 4 * 1024, 128 }, - { "SST25WF010", 0x2502, 0, 4 * 1024, 256 }, - { "SST25WF020", 0x2503, 0, 4 * 1024, 512 }, - { "SST25WF040", 0x2504, 0, 4 * 1024, 1024 }, - { NULL, 0, 0, 0, 0 } -}; - -/* SPI Speeds: 66 MHz / 33 MHz */ -static struct flash_info flash_atmel_dataflash[] = { - { "AT45DB011x", 0x0c, 0, 264, 512 }, - { "AT45DB021x", 0x14, 0, 264, 1025 }, - { "AT45DB041x", 0x1c, 0, 264, 2048 }, - { "AT45DB081x", 0x24, 0, 264, 4096 }, - { "AT45DB161x", 0x2c, 0, 528, 4096 }, - { "AT45DB321x", 0x34, 0, 528, 8192 }, - { "AT45DB642x", 0x3c, 0, 1056, 8192 }, - { NULL, 0, 0, 0, 0 } -}; - -/* SPI Speed: 50 MHz / 25 MHz or 40 MHz / 20 MHz */ -static struct flash_info flash_winbond_serial_flash[] = { - { "W25X10", 0x3011, 0, 16 * 256, 32 }, - { "W25X20", 0x3012, 0, 16 * 256, 64 }, - { "W25X40", 0x3013, 0, 16 * 256, 128 }, - { "W25X80", 0x3014, 0, 16 * 256, 256 }, - { "W25P80", 0x2014, 0, 256 * 256, 16 }, - { "W25P16", 0x2015, 0, 256 * 256, 32 }, - { NULL, 0, 0, 0, 0 } -}; - -struct flash_ops { - uint8_t read, write, erase, status; -}; - -#ifdef CONFIG_SPI_FLASH_SLOW_READ -# define OP_READ 0x03 -#else -# define OP_READ 0x0B -#endif -static struct flash_ops flash_st_ops = { - .read = OP_READ, - .write = 0x02, - .erase = 0xD8, - .status = 0x05, -}; - -static struct flash_ops flash_sst_ops = { - .read = OP_READ, - .write = 0x02, - .erase = 0x20, - .status = 0x05, -}; - -static struct flash_ops flash_atmel_ops = { - .read = OP_READ, - .write = 0x82, - .erase = 0x81, - .status = 0xD7, -}; - -static struct flash_ops flash_winbond_ops = { - .read = OP_READ, - .write = 0x02, - .erase = 0x20, - .status = 0x05, -}; - -struct manufacturer_info { - const char *name; - uint8_t id; - struct flash_info *flashes; - struct flash_ops *ops; -}; - -static struct { - struct manufacturer_info *manufacturer; - struct flash_info *flash; - struct flash_ops *ops; - uint8_t manufacturer_id, device_id1, device_id2, device_extid1, device_extid2; - unsigned int write_length; - unsigned long sector_size, num_sectors; -} flash; - -enum { - JED_MANU_SPANSION = 0x01, - JED_MANU_ST = 0x20, - JED_MANU_SST = 0xBF, - JED_MANU_ATMEL = 0x1F, - JED_MANU_WINBOND = 0xEF, -}; - -static struct manufacturer_info flash_manufacturers[] = { - { - .name = "Spansion", - .id = JED_MANU_SPANSION, - .flashes = flash_spansion_serial_flash, - .ops = &flash_st_ops, - }, - { - .name = "ST", - .id = JED_MANU_ST, - .flashes = flash_st_serial_flash, - .ops = &flash_st_ops, - }, - { - .name = "SST", - .id = JED_MANU_SST, - .flashes = flash_sst_serial_flash, - .ops = &flash_sst_ops, - }, - { - .name = "Atmel", - .id = JED_MANU_ATMEL, - .flashes = flash_atmel_dataflash, - .ops = &flash_atmel_ops, - }, - { - .name = "Winbond", - .id = JED_MANU_WINBOND, - .flashes = flash_winbond_serial_flash, - .ops = &flash_winbond_ops, - }, -}; - -#define TIMEOUT 5000 /* timeout of 5 seconds */ - -/* If part has multiple SPI flashes, assume SPI0 as that is - * the one we can boot off of ... - */ -#ifndef pSPI_CTL -# define pSPI_CTL pSPI0_CTL -# define pSPI_BAUD pSPI0_BAUD -# define pSPI_FLG pSPI0_FLG -# define pSPI_RDBR pSPI0_RDBR -# define pSPI_STAT pSPI0_STAT -# define pSPI_TDBR pSPI0_TDBR -#endif - -/* Default to the SPI SSEL that we boot off of: - * BF54x, BF537, (everything new?): SSEL1 - * BF51x, BF533, BF561: SSEL2 - */ -#ifndef CONFIG_SPI_FLASH_SSEL -# define CONFIG_SPI_FLASH_SSEL BFIN_BOOT_SPI_SSEL -#endif -#define SSEL_MASK (1 << CONFIG_SPI_FLASH_SSEL) - -static void SPI_INIT(void) -{ - /* [#3541] This delay appears to be necessary, but not sure - * exactly why as the history behind it is non-existant. - */ - *pSPI_CTL = 0; - udelay(CONFIG_CCLK_HZ / 25000000); - - /* enable SPI pins: SSEL, MOSI, MISO, SCK */ -#ifdef __ADSPBF54x__ - *pPORTE_FER |= (PE0 | PE1 | PE2 | PE4); -#elif defined(__ADSPBF534__) || defined(__ADSPBF536__) || defined(__ADSPBF537__) - *pPORTF_FER |= (PF10 | PF11 | PF12 | PF13); -#elif defined(__ADSPBF52x__) - bfin_write_PORTG_MUX((bfin_read_PORTG_MUX() & ~PORT_x_MUX_0_MASK) | PORT_x_MUX_0_FUNC_3); - bfin_write_PORTG_FER(bfin_read_PORTG_FER() | PG1 | PG2 | PG3 | PG4); -#elif defined(__ADSPBF51x__) - bfin_write_PORTG_MUX((bfin_read_PORTG_MUX() & ~PORT_x_MUX_7_MASK) | PORT_x_MUX_7_FUNC_1); - bfin_write_PORTG_FER(bfin_read_PORTG_FER() | PG12 | PG13 | PG14 | PG15); -#endif - - /* initate communication upon write of TDBR */ - *pSPI_CTL = (SPE | MSTR | CPHA | CPOL | TDBR_CORE); - *pSPI_BAUD = CONFIG_SPI_BAUD; -} - -static void SPI_DEINIT(void) -{ - *pSPI_CTL = 0; - *pSPI_BAUD = 0; - SSYNC(); -} - -static void SPI_ON(void) -{ - /* toggle SSEL to reset the device so it'll take a new command */ - *pSPI_FLG = 0xFF00 | SSEL_MASK; - SSYNC(); - - *pSPI_FLG = ((0xFF & ~SSEL_MASK) << 8) | SSEL_MASK; - SSYNC(); -} - -static void SPI_OFF(void) -{ - /* put SPI settings back to reset state */ - *pSPI_FLG = 0xFF00; - SSYNC(); -} - -static uint8_t spi_write_read_byte(uint8_t transmit) -{ - *pSPI_TDBR = transmit; - SSYNC(); - - while ((*pSPI_STAT & TXS)) - if (ctrlc()) - break; - while (!(*pSPI_STAT & SPIF)) - if (ctrlc()) - break; - while (!(*pSPI_STAT & RXS)) - if (ctrlc()) - break; - - /* Read dummy to empty the receive register */ - return *pSPI_RDBR; -} - -static uint8_t read_status_register(void) -{ - uint8_t status_register; - - /* send instruction to read status register */ - SPI_ON(); - spi_write_read_byte(flash.ops->status); - /* send dummy to receive the status register */ - status_register = spi_write_read_byte(0); - SPI_OFF(); - - return status_register; -} - -static int wait_for_ready_status(void) -{ - ulong start = get_timer(0); - - while (get_timer(0) - start < TIMEOUT) { - switch (flash.manufacturer_id) { - case JED_MANU_SPANSION: - case JED_MANU_ST: - case JED_MANU_SST: - case JED_MANU_WINBOND: - if (!(read_status_register() & 0x01)) - return 0; - break; - - case JED_MANU_ATMEL: - if (read_status_register() & 0x80) - return 0; - break; - } - - if (ctrlc()) { - puts("\nAbort\n"); - return -1; - } - } - - puts("Timeout\n"); - return -1; -} - -static int enable_writing(void) -{ - ulong start; - - if (flash.manufacturer_id == JED_MANU_ATMEL) - return 0; - - /* A write enable instruction must previously have been executed */ - SPI_ON(); - spi_write_read_byte(0x06); - SPI_OFF(); - - /* The status register will be polled to check the write enable latch "WREN" */ - start = get_timer(0); - while (get_timer(0) - start < TIMEOUT) { - if (read_status_register() & 0x02) - return 0; - - if (ctrlc()) { - puts("\nAbort\n"); - return -1; - } - } - - puts("Timeout\n"); - return -1; -} - -static void write_status_register(uint8_t val) -{ - if (flash.manufacturer_id != JED_MANU_SST) - hang(); - - if (enable_writing()) - return; - - /* send instruction to write status register */ - SPI_ON(); - spi_write_read_byte(0x01); - /* and clear it! */ - spi_write_read_byte(val); - SPI_OFF(); -} - -/* Request and read the manufacturer and device id of parts which - * are compatible with the JEDEC standard (JEP106) and use that to - * setup other operating conditions. - */ -static int spi_detect_part(void) -{ - uint16_t dev_id, dev_extid; - size_t i; - - static char called_init; - if (called_init) - return 0; - -#ifdef CONFIG_SPI_FLASH_M25P80 - flash.manufacturer_id = JED_MANU_ST; - flash.device_id1 = 0x20; - flash.device_id2 = 0xFF; -#else - SPI_ON(); - - /* Send the request for the part identification */ - spi_write_read_byte(0x9F); - - /* Now read in the manufacturer id bytes */ - do { - flash.manufacturer_id = spi_write_read_byte(0); - if (flash.manufacturer_id == 0x7F) - puts("Warning: unhandled manufacturer continuation byte!\n"); - } while (flash.manufacturer_id == 0x7F); - - /* Now read in the first device id byte */ - flash.device_id1 = spi_write_read_byte(0); - - /* Now read in the second device id byte */ - flash.device_id2 = spi_write_read_byte(0); - - /* Read extended device ids */ - flash.device_extid1 = spi_write_read_byte(0); - flash.device_extid2 = spi_write_read_byte(0); - - SPI_OFF(); -#endif - - dev_id = (flash.device_id1 << 8) | flash.device_id2; - dev_extid = (flash.device_extid1 << 8) | flash.device_extid2; - - for (i = 0; i < ARRAY_SIZE(flash_manufacturers); ++i) { - if (flash.manufacturer_id == flash_manufacturers[i].id) - break; - } - if (i == ARRAY_SIZE(flash_manufacturers)) - goto unknown; - - flash.manufacturer = &flash_manufacturers[i]; - flash.ops = flash_manufacturers[i].ops; - - switch (flash.manufacturer_id) { - case JED_MANU_SPANSION: - case JED_MANU_ST: - case JED_MANU_SST: - case JED_MANU_WINBOND: - for (i = 0; flash.manufacturer->flashes[i].name; ++i) { - if (dev_id == flash.manufacturer->flashes[i].id && - (flash.manufacturer->flashes[i].ext_id == 0 || - flash.manufacturer->flashes[i].ext_id == dev_extid)) - break; - } - if (!flash.manufacturer->flashes[i].name) - goto unknown; - - flash.flash = &flash.manufacturer->flashes[i]; - flash.sector_size = flash.flash->sector_size; - flash.num_sectors = flash.flash->num_sectors; - - if (flash.manufacturer_id == JED_MANU_SST) - flash.write_length = 1; /* pwnt :( */ - else - flash.write_length = 256; - break; - - case JED_MANU_ATMEL: { - uint8_t status = read_status_register(); - - for (i = 0; flash.manufacturer->flashes[i].name; ++i) { - if ((status & 0x3c) == flash.manufacturer->flashes[i].id) - break; - } - if (!flash.manufacturer->flashes[i].name) - goto unknown; - - flash.flash = &flash.manufacturer->flashes[i]; - flash.sector_size = flash.flash->sector_size; - flash.num_sectors = flash.flash->num_sectors; - - /* see if flash is in "power of 2" mode */ - if (status & 0x1) - flash.sector_size &= ~(1 << (ffs(flash.sector_size) - 1)); - - flash.write_length = flash.sector_size; - break; - } - } - - /* the SST parts power up with software protection enabled by default */ - if (flash.manufacturer_id == JED_MANU_SST) - write_status_register(0); - - called_init = 1; - return 0; - - unknown: - printf("Unknown SPI device: 0x%02X 0x%02X 0x%02X\n", - flash.manufacturer_id, flash.device_id1, flash.device_id2); - return 1; -} - -/* - * Function: spi_init_f - * Description: Init SPI-Controller (ROM part) - * return: --- - */ -void spi_init_f(void) -{ -} - -/* - * Function: spi_init_r - * Description: Init SPI-Controller (RAM part) - - * The malloc engine is ready and we can move our buffers to - * normal RAM - * return: --- - */ -void spi_init_r(void) -{ -#if defined(CONFIG_POST) && (CONFIG_POST & CONFIG_SYS_POST_SPI) - /* Our testing strategy here is pretty basic: - * - fill src memory with an 8-bit pattern - * - write the src memory to the SPI flash - * - read the SPI flash into the dst memory - * - compare src and dst memory regions - * - repeat a few times - * The variations we test for: - * - change the 8-bit pattern a bit - * - change the read/write block size so we know: - * - writes smaller/equal/larger than the buffer work - * - writes smaller/equal/larger than the sector work - * - change the SPI offsets so we know: - * - writing partial sectors works - */ - uint8_t *mem_src, *mem_dst; - size_t i, c, l, o; - size_t test_count, errors; - uint8_t pattern; - - SPI_INIT(); - - if (spi_detect_part()) - goto out; - eeprom_info(); - - ulong lengths[] = { - flash.write_length, - flash.write_length * 2, - flash.write_length / 2, - flash.sector_size, - flash.sector_size * 2, - flash.sector_size / 2 - }; - ulong offsets[] = { - 0, - flash.write_length, - flash.write_length * 2, - flash.write_length / 2, - flash.write_length / 4, - flash.sector_size, - flash.sector_size * 2, - flash.sector_size / 2, - flash.sector_size / 4, - }; - - /* the exact addresses are arbitrary ... they just need to not overlap */ - mem_src = (void *)(0); - mem_dst = (void *)(max(flash.write_length, flash.sector_size) * 2); - - test_count = 0; - errors = 0; - pattern = 0x00; - - for (i = 0; i < 16; ++i) { /* 16 = 8 bits * 2 iterations */ - for (l = 0; l < ARRAY_SIZE(lengths); ++l) { - for (o = 0; o < ARRAY_SIZE(offsets); ++o) { - ulong len = lengths[l]; - ulong off = offsets[o]; - - printf("Testing pattern 0x%02X of length %5lu and offset %5lu: ", pattern, len, off); - - /* setup the source memory region */ - memset(mem_src, pattern, len); - - test_count += 4; - for (c = 0; c < 4; ++c) { /* 4 is just a random repeat count */ - if (ctrlc()) { - puts("\nAbort\n"); - goto out; - } - - /* make sure background fill pattern != pattern */ - memset(mem_dst, pattern ^ 0xFF, len); - - /* write out the source memory and then read it back and compare */ - eeprom_write(0, off, mem_src, len); - eeprom_read(0, off, mem_dst, len); - - if (memcmp(mem_src, mem_dst, len)) { - for (c = 0; c < len; ++c) - if (mem_src[c] != mem_dst[c]) - break; - printf(" FAIL @ offset %u, skipping repeats ", c); - ++errors; - break; - } - - /* XXX: should shrink write region here to test with - * leading/trailing canaries so we know surrounding - * bytes don't get screwed. - */ - } - puts("\n"); - } - } - - /* invert the pattern every other run and shift out bits slowly */ - pattern ^= 0xFF; - if (i % 2) - pattern = (pattern | 0x01) << 1; - } - - if (errors) - printf("SPI FAIL: Out of %i tests, there were %i errors ;(\n", test_count, errors); - else - printf("SPI PASS: %i tests worked!\n", test_count); - - out: - SPI_DEINIT(); - -#endif -} - -static void transmit_address(uint32_t addr) -{ - /* Send the highest byte of the 24 bit address at first */ - spi_write_read_byte(addr >> 16); - /* Send the middle byte of the 24 bit address at second */ - spi_write_read_byte(addr >> 8); - /* Send the lowest byte of the 24 bit address finally */ - spi_write_read_byte(addr); -} - -/* - * Read a value from flash for verify purpose - * Inputs: unsigned long ulStart - holds the SPI start address - * int pnData - pointer to store value read from flash - * long lCount - number of elements to read - */ -#ifdef CONFIG_SPI_READFLASH_NODMA -static int read_flash(unsigned long address, long count, uchar *buffer) -{ - size_t i, j; - - /* Send the read command to SPI device */ - SPI_ON(); - spi_write_read_byte(flash.ops->read); - transmit_address(address); - -#ifndef CONFIG_SPI_FLASH_SLOW_READ - /* Send dummy byte when doing SPI fast reads */ - spi_write_read_byte(0); -#endif - - /* After the SPI device address has been placed on the MOSI pin the data can be */ - /* received on the MISO pin. */ - j = flash.sector_size << 1; - for (i = 1; i <= count; ++i) { - *buffer++ = spi_write_read_byte(0); - if (!j--) { - puts("."); - j = flash.sector_size; - } - } - - SPI_OFF(); - - return 0; -} -#else - -#ifdef __ADSPBF54x__ -#define bfin_write_DMA_SPI_IRQ_STATUS bfin_write_DMA4_IRQ_STATUS -#define bfin_read_DMA_SPI_IRQ_STATUS bfin_read_DMA4_IRQ_STATUS -#define bfin_write_DMA_SPI_CURR_DESC_PTR bfin_write_DMA4_CURR_DESC_PTR -#define bfin_write_DMA_SPI_CONFIG bfin_write_DMA4_CONFIG -#elif defined(__ADSPBF533__) || defined(__ADSPBF532__) || defined(__ADSPBF531__) || \ - defined(__ADSPBF538__) || defined(__ADSPBF539__) -#define bfin_write_DMA_SPI_IRQ_STATUS bfin_write_DMA5_IRQ_STATUS -#define bfin_read_DMA_SPI_IRQ_STATUS bfin_read_DMA5_IRQ_STATUS -#define bfin_write_DMA_SPI_CURR_DESC_PTR bfin_write_DMA5_CURR_DESC_PTR -#define bfin_write_DMA_SPI_CONFIG bfin_write_DMA5_CONFIG -#elif defined(__ADSPBF561__) -#define bfin_write_DMA_SPI_IRQ_STATUS bfin_write_DMA16_IRQ_STATUS -#define bfin_read_DMA_SPI_IRQ_STATUS bfin_read_DMA16_IRQ_STATUS -#define bfin_write_DMA_SPI_CURR_DESC_PTR bfin_write_DMA16_CURR_DESC_PTR -#define bfin_write_DMA_SPI_CONFIG bfin_write_DMA16_CONFIG -#elif defined(__ADSPBF537__) || defined(__ADSPBF536__) || defined(__ADSPBF534__) || \ - defined(__ADSPBF52x__) || defined(__ADSPBF51x__) -#define bfin_write_DMA_SPI_IRQ_STATUS bfin_write_DMA7_IRQ_STATUS -#define bfin_read_DMA_SPI_IRQ_STATUS bfin_read_DMA7_IRQ_STATUS -#define bfin_write_DMA_SPI_CURR_DESC_PTR bfin_write_DMA7_CURR_DESC_PTR -#define bfin_write_DMA_SPI_CONFIG bfin_write_DMA7_CONFIG -#else -#error "Please provide SPI DMA channel defines" -#endif - -struct dmadesc_array { - unsigned long start_addr; - unsigned short cfg; - unsigned short x_count; - short x_modify; - unsigned short y_count; - short y_modify; -} __attribute__((packed)); - -/* - * Read a value from flash for verify purpose - * Inputs: unsigned long ulStart - holds the SPI start address - * int pnData - pointer to store value read from flash - * long lCount - number of elements to read - */ - -static int read_flash(unsigned long address, long count, uchar *buffer) -{ - unsigned int ndsize; - struct dmadesc_array dma[2]; - /* Send the read command to SPI device */ - - if (!count) - return 0; - - dma[0].start_addr = (unsigned long)buffer; - dma[0].x_modify = 1; - if (count <= 65536) { - blackfin_dcache_flush_invalidate_range(buffer, buffer + count); - ndsize = NDSIZE_5; - dma[0].cfg = NDSIZE_0 | WNR | WDSIZE_8 | FLOW_STOP | DMAEN | DI_EN; - dma[0].x_count = count; - } else { - blackfin_dcache_flush_invalidate_range(buffer, buffer + 65536 - 1); - ndsize = NDSIZE_7; - dma[0].cfg = NDSIZE_5 | WNR | WDSIZE_8 | FLOW_ARRAY | DMAEN | DMA2D; - dma[0].x_count = 0; /* 2^16 */ - dma[0].y_count = count >> 16; /* count / 2^16 */ - dma[0].y_modify = 1; - dma[1].start_addr = (unsigned long)(buffer + (count & ~0xFFFF)); - dma[1].cfg = NDSIZE_0 | WNR | WDSIZE_8 | FLOW_STOP | DMAEN | DI_EN; - dma[1].x_count = count & 0xFFFF; /* count % 2^16 */ - dma[1].x_modify = 1; - } - - bfin_write_DMA_SPI_CONFIG(0); - bfin_write_DMA_SPI_IRQ_STATUS(DMA_DONE | DMA_ERR); - bfin_write_DMA_SPI_CURR_DESC_PTR(dma); - - SPI_ON(); - - spi_write_read_byte(flash.ops->read); - transmit_address(address); - -#ifndef CONFIG_SPI_FLASH_SLOW_READ - /* Send dummy byte when doing SPI fast reads */ - spi_write_read_byte(0); -#endif - - bfin_write_DMA_SPI_CONFIG(ndsize | FLOW_ARRAY | DMAEN); - *pSPI_CTL = (MSTR | CPHA | CPOL | RDBR_DMA | SPE | SZ); - SSYNC(); - - /* - * We already invalidated the first 64k, - * now while we just wait invalidate the remaining part. - * Its not likely that the DMA is going to overtake - */ - if (count > 65536) - blackfin_dcache_flush_invalidate_range(buffer + 65536, - buffer + count); - - while (!(bfin_read_DMA_SPI_IRQ_STATUS() & DMA_DONE)) - if (ctrlc()) - break; - - SPI_OFF(); - - *pSPI_CTL = 0; - - bfin_write_DMA_SPI_CONFIG(0); - - *pSPI_CTL = (SPE | MSTR | CPHA | CPOL | TDBR_CORE); - - return 0; -} -#endif - -static long address_to_sector(unsigned long address) -{ - if (address > (flash.num_sectors * flash.sector_size) - 1) - return -1; - return address / flash.sector_size; -} - -static int erase_sector(int address) -{ - /* sector gets checked in higher function, so assume it's valid - * here and figure out the offset of the sector in flash - */ - if (enable_writing()) - return -1; - - /* - * Send the erase block command to the flash followed by the 24 address - * to point to the start of a sector - */ - SPI_ON(); - spi_write_read_byte(flash.ops->erase); - transmit_address(address); - SPI_OFF(); - - return wait_for_ready_status(); -} - -/* Write [count] bytes out of [buffer] into the given SPI [address] */ -static long write_flash(unsigned long address, long count, uchar *buffer) -{ - long i, write_buffer_size; - - if (enable_writing()) - return -1; - - /* Send write command followed by the 24 bit address */ - SPI_ON(); - spi_write_read_byte(flash.ops->write); - transmit_address(address); - - /* Shoot out a single write buffer */ - write_buffer_size = min(count, flash.write_length); - for (i = 0; i < write_buffer_size; ++i) - spi_write_read_byte(buffer[i]); - - SPI_OFF(); - - /* Wait for the flash to do its thing */ - if (wait_for_ready_status()) { - puts("SPI Program Time out! "); - return -1; - } - - return i; -} - -/* Write [count] bytes out of [buffer] into the given SPI [address] */ -static int write_sector(unsigned long address, long count, uchar *buffer) -{ - long write_cnt; - - while (count != 0) { - write_cnt = write_flash(address, count, buffer); - if (write_cnt == -1) - return -1; - - /* Now that we've sent some bytes out to the flash, update - * our counters a bit - */ - count -= write_cnt; - address += write_cnt; - buffer += write_cnt; - } - - /* return the appropriate error code */ - return 0; -} - -/* - * Function: spi_write - */ -ssize_t spi_write(uchar *addr, int alen, uchar *buffer, int len) -{ - unsigned long offset; - int start_sector, end_sector; - int start_byte, end_byte; - uchar *temp = NULL; - int num, ret = 0; - - SPI_INIT(); - - if (spi_detect_part()) - goto out; - - offset = addr[0] << 16 | addr[1] << 8 | addr[2]; - - /* Get the start block number */ - start_sector = address_to_sector(offset); - if (start_sector == -1) { - puts("Invalid sector! "); - goto out; - } - end_sector = address_to_sector(offset + len - 1); - if (end_sector == -1) { - puts("Invalid sector! "); - goto out; - } - - /* Since flashes operate in sector units but the eeprom command - * operates as a continuous stream of bytes, we need to emulate - * the eeprom behavior. So here we read in the sector, overlay - * any bytes we're actually modifying, erase the sector, and - * then write back out the new sector. - */ - temp = malloc(flash.sector_size); - if (!temp) { - puts("Malloc for sector failed! "); - goto out; - } - - for (num = start_sector; num <= end_sector; num++) { - unsigned long address = num * flash.sector_size; - - /* XXX: should add an optimization when spanning sectors: - * No point in reading in a sector if we're going to be - * clobbering the whole thing. Need to also add a test - * case to make sure the optimization is correct. - */ - if (read_flash(address, flash.sector_size, temp)) { - puts("Read sector failed! "); - len = 0; - break; - } - - start_byte = max(address, offset); - end_byte = address + flash.sector_size - 1; - if (end_byte > (offset + len)) - end_byte = (offset + len - 1); - - memcpy(temp + start_byte - address, - buffer + start_byte - offset, - end_byte - start_byte + 1); - - if (erase_sector(address)) { - puts("Erase sector failed! "); - goto out; - } - - if (write_sector(address, flash.sector_size, temp)) { - puts("Write sector failed! "); - goto out; - } - - puts("."); - } - - ret = len; - - out: - free(temp); - - SPI_DEINIT(); - - return ret; -} - -/* - * Function: spi_read - */ -ssize_t spi_read(uchar *addr, int alen, uchar *buffer, int len) -{ - unsigned long offset; - - SPI_INIT(); - - if (spi_detect_part()) - len = 0; - else { - offset = addr[0] << 16 | addr[1] << 8 | addr[2]; - read_flash(offset, len, buffer); - } - - SPI_DEINIT(); - - return len; -} - -/* - * Spit out some useful information about the SPI eeprom - */ -int eeprom_info(void) -{ - int ret = 0; - - SPI_INIT(); - - if (spi_detect_part()) - ret = 1; - else - printf("SPI Device: %s 0x%02X (%s) 0x%02X 0x%02X\n" - "Parameters: num sectors = %lu, sector size = %lu, write size = %i\n" - "Flash Size: %lu mbit (%lu mbyte)\n" - "Status: 0x%02X\n", - flash.flash->name, flash.manufacturer_id, flash.manufacturer->name, - flash.device_id1, flash.device_id2, flash.num_sectors, - flash.sector_size, flash.write_length, - (flash.num_sectors * flash.sector_size) >> 17, - (flash.num_sectors * flash.sector_size) >> 20, - read_status_register()); - - SPI_DEINIT(); - - return ret; -} - -#endif