*
* -->
*
- * \brief Micron MT29F serial NAND driver for SAM3's static memory controller.
+ * \brief NAND driver hardware implementation for SAM3's static memory controller.
*
* \author Stefano Fedrigo <aleph@develer.com>
*/
-#include "mt29f_sam3.h"
-#include <drv/mt29f.h>
+#include <drv/nand.h>
#include <cfg/log.h>
-#include <cfg/macros.h>
#include <io/sam3.h>
#include <drv/timer.h>
-#include <cpu/power.h> /* cpu_relax() */
-#include <cpu/types.h>
-
-#include <string.h> /* memcpy, memset */
+#include <cpu/power.h> // cpu_relax()
/*
* PIO definitions.
*/
-#define MT29F_PIN_CE BV(6)
-#define MT29F_PIN_RB BV(2)
-#define MT29F_PINS_PORTA (MT29F_PIN_CE | MT29F_PIN_RB)
-#define MT29F_PERIPH_PORTA PIO_PERIPH_B
+#define NAND_PIN_CE BV(6)
+#define NAND_PIN_RB BV(2)
+#define NAND_PINS_PORTA (NAND_PIN_CE | NAND_PIN_RB)
+#define NAND_PERIPH_PORTA PIO_PERIPH_B
-#define MT29F_PIN_OE BV(19)
-#define MT29F_PIN_WE BV(20)
-#define MT29F_PIN_IO 0x0000FFFF
-#define MT29F_PINS_PORTC (MT29F_PIN_OE | MT29F_PIN_WE | MT29F_PIN_IO)
-#define MT29F_PERIPH_PORTC PIO_PERIPH_A
+#define NAND_PIN_OE BV(19)
+#define NAND_PIN_WE BV(20)
+#define NAND_PIN_IO 0x0000FFFF
+#define NAND_PINS_PORTC (NAND_PIN_OE | NAND_PIN_WE | NAND_PIN_IO)
+#define NAND_PERIPH_PORTC PIO_PERIPH_A
-#define MT29F_PIN_CLE BV(9)
-#define MT29F_PIN_ALE BV(8)
-#define MT29F_PINS_PORTD (MT29F_PIN_CLE | MT29F_PIN_ALE)
-#define MT29F_PERIPH_PORTD PIO_PERIPH_A
+#define NAND_PIN_CLE BV(9)
+#define NAND_PIN_ALE BV(8)
+#define NAND_PINS_PORTD (NAND_PIN_CLE | NAND_PIN_ALE)
+#define NAND_PERIPH_PORTD PIO_PERIPH_A
/*
* signal.
* Return true for edge detection, false in case of timeout.
*/
-bool mt29f_waitReadyBusy(UNUSED_ARG(Mt29f *, chip), time_t timeout)
+bool nand_waitReadyBusy(UNUSED_ARG(Nand *, chip), time_t timeout)
{
time_t start = timer_clock();
cpu_relax();
if (timer_clock() - start > timeout)
{
- LOG_INFO("mt29f: R/B timeout\n");
+ LOG_INFO("nand: R/B timeout\n");
return false;
}
}
return true;
}
+
/*
* Wait for transfer to complete until timeout.
* If transfer completes return true, false in case of timeout.
*/
-bool mt29f_waitTransferComplete(UNUSED_ARG(Mt29f *, chip), time_t timeout)
+bool nand_waitTransferComplete(UNUSED_ARG(Nand *, chip), time_t timeout)
{
time_t start = timer_clock();
cpu_relax();
if (timer_clock() - start > timeout)
{
- LOG_INFO("mt29f: xfer complete timeout\n");
+ LOG_INFO("nand: xfer complete timeout\n");
return false;
}
}
/*
* Send command to NAND and wait for completion.
*/
-void mt29f_sendCommand(Mt29f *chip,
+void nand_sendCommand(Nand *chip,
uint32_t cmd1, uint32_t cmd2,
int num_cycles, uint32_t cycle0, uint32_t cycle1234)
{
| cmd2 << 10;
// Check for commands transferring data
- if (cmd1 == MT29F_CMD_WRITE_1 || cmd1 == MT29F_CMD_READ_1 || cmd1 == MT29F_CMD_READID)
+ if (cmd1 == NAND_CMD_WRITE_1 || cmd1 == NAND_CMD_READ_1 || cmd1 == NAND_CMD_READID)
cmd_val |= NFC_CMD_NFCEN;
// Check for commands writing data
- if (cmd1 == MT29F_CMD_WRITE_1)
+ if (cmd1 == NAND_CMD_WRITE_1)
cmd_val |= NFC_CMD_NFCWR;
// Check for two command cycles
* NOTE: this is global between different chip selects, so returns
* the status register of the last used NAND chip.
*/
-uint8_t mt29f_getChipStatus(UNUSED_ARG(Mt29f *, chip))
+uint8_t nand_getChipStatus(UNUSED_ARG(Nand *, chip))
{
return (uint8_t)HWREG(NFC_CMD_BASE_ADDR);
}
-void *mt29f_dataBuffer(UNUSED_ARG(Mt29f *, chip))
+/*
+ * Return pointer to buffer where data are read to or written from
+ * by nand_sendCommand().
+ */
+void *nand_dataBuffer(UNUSED_ARG(Nand *, chip))
{
return (void *)NFC_SRAM_BASE_ADDR;
}
-bool mt29f_checkEcc(Mt29f *chip)
+/*
+ * Extract ECC data from ECC_PRx registers.
+ */
+bool nand_checkEcc(UNUSED_ARG(Nand *, chip))
{
uint32_t sr1 = SMC_ECC_SR1;
if (sr1)
{
LOG_INFO("ECC error, ECC_SR1=0x%lx\n", sr1);
- chip->status |= MT29F_ERR_ECC;
return false;
}
else
* \param ecc pointer to buffer where computed ECC is stored
* \param ecc_size max size for ecc buffer
*/
-void mt29f_computeEcc(UNUSED_ARG(Mt29f *, chip),
+void nand_computeEcc(UNUSED_ARG(Nand *, chip),
UNUSED_ARG(const void *, buf), UNUSED_ARG(size_t, size), uint32_t *ecc, size_t ecc_size)
{
size_t i;
}
-void mt29f_hwInit(UNUSED_ARG(Mt29f *, chip))
+/*
+ * Low-level hardware driver initialization.
+ */
+void nand_hwInit(UNUSED_ARG(Nand *, chip))
{
// FIXME: Parameters specific for MT29F8G08AAD
pmc_periphEnable(PIOC_ID);
pmc_periphEnable(PIOD_ID);
- PIO_PERIPH_SEL(PIOA_BASE, MT29F_PINS_PORTA, MT29F_PERIPH_PORTA);
- PIOA_PDR = MT29F_PINS_PORTA;
- PIOA_PUER = MT29F_PINS_PORTA;
+ PIO_PERIPH_SEL(PIOA_BASE, NAND_PINS_PORTA, NAND_PERIPH_PORTA);
+ PIOA_PDR = NAND_PINS_PORTA;
+ PIOA_PUER = NAND_PINS_PORTA;
- PIO_PERIPH_SEL(PIOC_BASE, MT29F_PINS_PORTC, MT29F_PERIPH_PORTC);
- PIOC_PDR = MT29F_PINS_PORTC;
- PIOC_PUER = MT29F_PINS_PORTC;
+ PIO_PERIPH_SEL(PIOC_BASE, NAND_PINS_PORTC, NAND_PERIPH_PORTC);
+ PIOC_PDR = NAND_PINS_PORTC;
+ PIOC_PUER = NAND_PINS_PORTC;
- PIO_PERIPH_SEL(PIOD_BASE, MT29F_PINS_PORTD, MT29F_PERIPH_PORTD);
- PIOD_PDR = MT29F_PINS_PORTD;
- PIOD_PUER = MT29F_PINS_PORTD;
+ PIO_PERIPH_SEL(PIOD_BASE, NAND_PINS_PORTD, NAND_PERIPH_PORTD);
+ PIOD_PDR = NAND_PINS_PORTD;
+ PIOD_PUER = NAND_PINS_PORTD;
pmc_periphEnable(SMC_SDRAMC_ID);