/* * this file included by nicstar.c */ /* * nicstarmac.c * Read this ForeRunner's MAC address from eprom/eeprom */ #include <linux/kernel.h> typedef void __iomem *virt_addr_t; #define CYCLE_DELAY 5 /* This was the original definition #define osp_MicroDelay(microsec) \ do { int _i = 4*microsec; while (--_i > 0) { __SLOW_DOWN_IO; }} while (0) */ #define osp_MicroDelay(microsec) {unsigned long useconds = (microsec); \ udelay((useconds));} /* The following tables represent the timing diagrams found in * the Data Sheet for the Xicor X25020 EEProm. The #defines below * represent the bits in the NICStAR's General Purpose register * that must be toggled for the corresponding actions on the EEProm * to occur. */ /* Write Data To EEProm from SI line on rising edge of CLK */ /* Read Data From EEProm on falling edge of CLK */ #define CS_HIGH 0x0002 /* Chip select high */ #define CS_LOW 0x0000 /* Chip select low (active low)*/ #define CLK_HIGH 0x0004 /* Clock high */ #define CLK_LOW 0x0000 /* Clock low */ #define SI_HIGH 0x0001 /* Serial input data high */ #define SI_LOW 0x0000 /* Serial input data low */ /* Read Status Register = 0000 0101b */ #if 0 static u_int32_t rdsrtab[] = { CS_HIGH | CLK_HIGH, CS_LOW | CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW | SI_HIGH, CLK_HIGH | SI_HIGH, /* 1 */ CLK_LOW | SI_LOW, CLK_HIGH, /* 0 */ CLK_LOW | SI_HIGH, CLK_HIGH | SI_HIGH /* 1 */ }; #endif /* 0 */ /* Read from EEPROM = 0000 0011b */ static u_int32_t readtab[] = { /* CS_HIGH | CLK_HIGH, */ CS_LOW | CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW, CLK_HIGH, /* 0 */ CLK_LOW | SI_HIGH, CLK_HIGH | SI_HIGH, /* 1 */ CLK_LOW | SI_HIGH, CLK_HIGH | SI_HIGH /* 1 */ }; /* Clock to read from/write to the eeprom */ static u_int32_t clocktab[] = { CLK_LOW, CLK_HIGH, CLK_LOW, CLK_HIGH, CLK_LOW, CLK_HIGH, CLK_LOW, CLK_HIGH, CLK_LOW, CLK_HIGH, CLK_LOW, CLK_HIGH, CLK_LOW, CLK_HIGH, CLK_LOW, CLK_HIGH, CLK_LOW }; #define NICSTAR_REG_WRITE(bs, reg, val) \ while ( readl(bs + STAT) & 0x0200 ) ; \ writel((val),(base)+(reg)) #define NICSTAR_REG_READ(bs, reg) \ readl((base)+(reg)) #define NICSTAR_REG_GENERAL_PURPOSE GP /* * This routine will clock the Read_Status_reg function into the X2520 * eeprom, then pull the result from bit 16 of the NicSTaR's General Purpose * register. */ #if 0 u_int32_t nicstar_read_eprom_status( virt_addr_t base ) { u_int32_t val; u_int32_t rbyte; int32_t i, j; /* Send read instruction */ val = NICSTAR_REG_READ( base, NICSTAR_REG_GENERAL_PURPOSE ) & 0xFFFFFFF0; for (i=0; i<sizeof rdsrtab/sizeof rdsrtab[0]; i++) { NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | rdsrtab[i]) ); osp_MicroDelay( CYCLE_DELAY ); } /* Done sending instruction - now pull data off of bit 16, MSB first */ /* Data clocked out of eeprom on falling edge of clock */ rbyte = 0; for (i=7, j=0; i>=0; i--) { NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | clocktab[j++]) ); rbyte |= (((NICSTAR_REG_READ( base, NICSTAR_REG_GENERAL_PURPOSE) & 0x00010000) >> 16) << i); NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | clocktab[j++]) ); osp_MicroDelay( CYCLE_DELAY ); } NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, 2 ); osp_MicroDelay( CYCLE_DELAY ); return rbyte; } #endif /* 0 */ /* * This routine will clock the Read_data function into the X2520 * eeprom, followed by the address to read from, through the NicSTaR's General * Purpose register. */ static u_int8_t read_eprom_byte(virt_addr_t base, u_int8_t offset) { u_int32_t val = 0; int i,j=0; u_int8_t tempread = 0; val = NICSTAR_REG_READ( base, NICSTAR_REG_GENERAL_PURPOSE ) & 0xFFFFFFF0; /* Send READ instruction */ for (i=0; i<ARRAY_SIZE(readtab); i++) { NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | readtab[i]) ); osp_MicroDelay( CYCLE_DELAY ); } /* Next, we need to send the byte address to read from */ for (i=7; i>=0; i--) { NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | clocktab[j++] | ((offset >> i) & 1) ) ); osp_MicroDelay(CYCLE_DELAY); NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | clocktab[j++] | ((offset >> i) & 1) ) ); osp_MicroDelay( CYCLE_DELAY ); } j = 0; /* Now, we can read data from the eeprom by clocking it in */ for (i=7; i>=0; i--) { NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | clocktab[j++]) ); osp_MicroDelay( CYCLE_DELAY ); tempread |= (((NICSTAR_REG_READ( base, NICSTAR_REG_GENERAL_PURPOSE ) & 0x00010000) >> 16) << i); NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, (val | clocktab[j++]) ); osp_MicroDelay( CYCLE_DELAY ); } NICSTAR_REG_WRITE( base, NICSTAR_REG_GENERAL_PURPOSE, 2 ); osp_MicroDelay( CYCLE_DELAY ); return tempread; } static void nicstar_init_eprom( virt_addr_t base ) { u_int32_t val; /* * turn chip select off */ val = NICSTAR_REG_READ(base, NICSTAR_REG_GENERAL_PURPOSE) & 0xFFFFFFF0; NICSTAR_REG_WRITE(base, NICSTAR_REG_GENERAL_PURPOSE, (val | CS_HIGH | CLK_HIGH)); osp_MicroDelay( CYCLE_DELAY ); NICSTAR_REG_WRITE(base, NICSTAR_REG_GENERAL_PURPOSE, (val | CS_HIGH | CLK_LOW)); osp_MicroDelay( CYCLE_DELAY ); NICSTAR_REG_WRITE(base, NICSTAR_REG_GENERAL_PURPOSE, (val | CS_HIGH | CLK_HIGH)); osp_MicroDelay( CYCLE_DELAY ); NICSTAR_REG_WRITE(base, NICSTAR_REG_GENERAL_PURPOSE, (val | CS_HIGH | CLK_LOW)); osp_MicroDelay( CYCLE_DELAY ); } /* * This routine will be the interface to the ReadPromByte function * above. */ static void nicstar_read_eprom( virt_addr_t base, u_int8_t prom_offset, u_int8_t *buffer, u_int32_t nbytes ) { u_int i; for (i=0; i<nbytes; i++) { buffer[i] = read_eprom_byte( base, prom_offset ); ++prom_offset; osp_MicroDelay( CYCLE_DELAY ); } } /* void osp_MicroDelay(int x) { } */