xCAT/xNBA
2
0
Fork 0
mirror of https://github.com/xcat2/xNBA.git synced 2024-12-14 07:11:32 +00:00
Code Issues Projects Releases Wiki Activity

Generalised the SPI abstraction layer to also be able to handle interfaces

Browse Source 
that don't provide the full flexibility of a bit-bashing interface.

Temporarily hacked rtl8139.c to use the new interface.
This commit is contained in:
Michael Brown 2006-12-04 15:36:51 +00:00
parent 2e41bfd268
commit 931f94dca3
10 changed files with 397 additions and 211 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

4
src/drivers/bitbash/bitbash.c
View File

@ -37,7 +37,7 @@
*/
void write_bit ( struct bit_basher *basher, unsigned int bit_id,
unsigned long data ) {
basher->write ( basher, bit_id, ( data ? -1UL : 0 ) );
basher->op->write ( basher, bit_id, ( data ? -1UL : 0 ) );
}
/**
@ -52,5 +52,5 @@ void write_bit ( struct bit_basher *basher, unsigned int bit_id,
* it needs to apply.
*/
int read_bit ( struct bit_basher *basher, unsigned int bit_id ) {
return ( basher->read ( basher, bit_id ) ? -1UL : 0 );
return ( basher->op->read ( basher, bit_id ) ? -1UL : 0 );
}

4
src/drivers/bitbash/i2c_bit.c
View File

@ -314,8 +314,8 @@ static int i2c_bit_write ( struct i2c_interface *i2c,
void init_i2c_bit_basher ( struct i2c_bit_basher *i2cbit ) {
struct bit_basher *basher = &i2cbit->basher;
assert ( basher->read != NULL );
assert ( basher->write != NULL );
assert ( basher->op->read != NULL );
assert ( basher->op->write != NULL );
i2cbit->i2c.read = i2c_bit_read;
i2cbit->i2c.write = i2c_bit_write;
i2c_stop ( basher );

125
src/drivers/bitbash/spi_bit.c
View File

@ -19,11 +19,12 @@
#include <stddef.h>
#include <stdint.h>
#include <string.h>
#include <byteswap.h>
#include <errno.h>
#include <assert.h>
#include <timer.h>
#include <gpxe/bitbash.h>
#include <gpxe/spi.h>
#include <gpxe/spi_bit.h>
/** @file
*
@ -32,65 +33,43 @@
*/
/** Delay between SCLK changes and around SS changes */
static void spi_delay ( void ) {
udelay ( SPI_UDELAY );
static void spi_bit_delay ( void ) {
udelay ( SPI_BIT_UDELAY );
}
/** Chip select line will be asserted */
#define SELECT_SLAVE 0
/** Chip select line will be deasserted */
#define DESELECT_SLAVE SPI_MODE_SSPOL
/**
* Select/deselect slave
*
* @v spi SPI bit-bashing interface
* @v spibit SPI bit-bashing interface
* @v slave Slave number
* @v state Slave select state
*
* @c state must be set to zero to select the specified slave, or to
* @c SPI_MODE_SSPOL to deselect the slave.
* @c state must be @c SELECT_SLAVE or @c DESELECT_SLAVE.
*/
static void spi_bit_set_slave_select ( struct spi_bit_basher *spibit,
unsigned int slave,
unsigned int state ) {
struct bit_basher *basher = &spibit->basher;
state ^= ( spibit->spi.mode & SPI_MODE_SSPOL );
state ^= ( spibit->bus.mode & SPI_MODE_SSPOL );
DBG ( "Setting slave %d select %s\n", slave,
( state ? "high" : "low" ) );
spi_delay();
spi_bit_delay();
write_bit ( basher, SPI_BIT_SS ( slave ), state );
spi_delay();
spi_bit_delay();
}
/**
* Select slave
* Transfer bits over SPI bit-bashing bus
*
* @v spi SPI interface
* @v slave Slave number
*/
static void spi_bit_select_slave ( struct spi_interface *spi,
unsigned int slave ) {
struct spi_bit_basher *spibit
= container_of ( spi, struct spi_bit_basher, spi );
spibit->slave = slave;
spi_bit_set_slave_select ( spibit, slave, 0 );
}
/**
* Deselect slave
*
* @v spi SPI interface
*/
static void spi_bit_deselect_slave ( struct spi_interface *spi ) {
struct spi_bit_basher *spibit
= container_of ( spi, struct spi_bit_basher, spi );
spi_bit_set_slave_select ( spibit, spibit->slave, SPI_MODE_SSPOL );
}
/**
* Transfer bits over SPI bit-bashing interface
*
* @v spi SPI interface
* @v bus SPI bus
* @v data_out TX data buffer (or NULL)
* @v data_in RX data buffer (or NULL)
* @v len Length of transfer (in @b bits)
@ -101,19 +80,19 @@ static void spi_bit_deselect_slave ( struct spi_interface *spi ) {
* NULL, then the data sent will be all zeroes. If @c data_in is
* NULL, then the incoming data will be discarded.
*/
static void spi_bit_transfer ( struct spi_interface *spi, const void *data_out,
void *data_in, unsigned int len ) {
struct spi_bit_basher *spibit
= container_of ( spi, struct spi_bit_basher, spi );
static void spi_bit_transfer ( struct spi_bit_basher *spibit,
const void *data_out, void *data_in,
unsigned int len ) {
struct spi_bus *bus = &spibit->bus;
struct bit_basher *basher = &spibit->basher;
unsigned int sclk = ( ( spi->mode & SPI_MODE_CPOL ) ? 1 : 0 );
unsigned int cpha = ( ( spi->mode & SPI_MODE_CPHA ) ? 1 : 0 );
unsigned int sclk = ( ( bus->mode & SPI_MODE_CPOL ) ? 1 : 0 );
unsigned int cpha = ( ( bus->mode & SPI_MODE_CPHA ) ? 1 : 0 );
unsigned int offset;
unsigned int mask;
unsigned int bit;
int step;
DBG ( "Transferring %d bits in mode %x\n", len, spi->mode );
DBG ( "Transferring %d bits in mode %x\n", len, bus->mode );
for ( step = ( ( len * 2 ) - 1 ) ; step >= 0 ; step-- ) {
/* Calculate byte offset within data and bit mask */
@ -145,21 +124,65 @@ static void spi_bit_transfer ( struct spi_interface *spi, const void *data_out,
}
/* Toggle clock line */
spi_delay();
spi_bit_delay();
sclk = ~sclk;
write_bit ( basher, SPI_BIT_SCLK, sclk );
}
}
/**
* Read/write data via SPI bit-bashing bus
*
* @v bus SPI bus
* @v device SPI device
* @v command Command
* @v address Address to read/write (<0 for no address)
* @v data_out TX data buffer (or NULL)
* @v data_in RX data buffer (or NULL)
* @v len Length of transfer (in @b words)
* @ret rc Return status code
*/
static int spi_bit_rw ( struct spi_bus *bus, struct spi_device *device,
unsigned int command, int address,
const void *data_out, void *data_in,
unsigned int len ) {
struct spi_bit_basher *spibit
= container_of ( bus, struct spi_bit_basher, bus );
struct spi_device_type *devtype = device->type;
uint32_t tmp;
/* Assert chip select on specified slave */
spi_bit_set_slave_select ( spibit, device->slave, SELECT_SLAVE );
/* Transmit command */
assert ( devtype->command_len <= ( 8 * sizeof ( tmp ) ) );
tmp = cpu_to_le32 ( command );
spi_bit_transfer ( spibit, &tmp, NULL, devtype->command_len );
/* Transmit address, if present */
if ( address >= 0 ) {
assert ( devtype->address_len <= ( 8 * sizeof ( tmp ) ) );
tmp = cpu_to_le32 ( address );
spi_bit_transfer ( spibit, &tmp, NULL, devtype->address_len );
}
/* Transmit/receive data */
spi_bit_transfer ( spibit, data_out, data_in,
( len * devtype->word_len ) );
/* Deassert chip select on specified slave */
spi_bit_set_slave_select ( spibit, device->slave, DESELECT_SLAVE );
return 0;
}
/**
* Initialise SPI bit-bashing interface
*
* @v spibit SPI bit-bashing interface
*/
void init_spi_bit_basher ( struct spi_bit_basher *spibit ) {
assert ( &spibit->basher.read != NULL );
assert ( &spibit->basher.write != NULL );
spibit->spi.select_slave = spi_bit_select_slave;
spibit->spi.deselect_slave = spi_bit_deselect_slave;
spibit->spi.transfer = spi_bit_transfer;
assert ( &spibit->basher.op->read != NULL );
assert ( &spibit->basher.op->write != NULL );
spibit->bus.rw = spi_bit_rw;
}

8
src/drivers/net/etherfabric.c
View File

@ -1058,9 +1058,13 @@ static int ef1002_i2c_read_bit ( struct bit_basher *basher,
return ( EFAB_DWORD_FIELD ( reg, EF1_EEPROM ) & mask );
}
static struct bit_basher_operations ef1002_basher_ops = {
.read = ef1002_i2c_read_bit,
.write = ef1002_i2c_write_bit,
};
static void ef1002_init_eeprom ( struct efab_nic *efab ) {
efab->ef1002_i2c.basher.write = ef1002_i2c_write_bit;
efab->ef1002_i2c.basher.read = ef1002_i2c_read_bit;
efab->ef1002_i2c.basher.op = &ef1002_basher_ops;
init_i2c_bit_basher ( &efab->ef1002_i2c );
efab->ef1002_eeprom.address = EF1_EEPROM_I2C_ID;
}

50
src/drivers/net/rtl8139.c
View File

@ -77,7 +77,7 @@
#include <gpxe/ethernet.h>
#include <gpxe/pkbuff.h>
#include <gpxe/netdevice.h>
#include <gpxe/spi.h>
#include <gpxe/spi_bit.h>
#include <gpxe/threewire.h>
#define TX_RING_SIZE 4
@ -97,7 +97,7 @@ struct rtl8139_nic {
struct rtl8139_tx tx;
struct rtl8139_rx rx;
struct spi_bit_basher spibit;
struct threewire_device eeprom;
struct spi_device eeprom;
};
/* Tuning Parameters */
@ -204,11 +204,6 @@ enum RxConfigBits {
/* Offsets within EEPROM (these are word offsets) */
#define EE_MAC 7
static inline struct rtl8139_nic *
basher_to_rtl ( struct bit_basher *basher ) {
return container_of ( basher, struct rtl8139_nic, spibit.basher );
}
static const uint8_t rtl_ee_bits[] = {
[SPI_BIT_SCLK] = EE_SK,
[SPI_BIT_MOSI] = EE_DI,
@ -218,7 +213,8 @@ static const uint8_t rtl_ee_bits[] = {
static int rtl_spi_read_bit ( struct bit_basher *basher,
unsigned int bit_id ) {
struct rtl8139_nic *rtl = basher_to_rtl ( basher );
struct rtl8139_nic *rtl = container_of ( basher, struct rtl8139_nic,
spibit.basher );
uint8_t mask = rtl_ee_bits[bit_id];
uint8_t eereg;
@ -228,7 +224,8 @@ static int rtl_spi_read_bit ( struct bit_basher *basher,
static void rtl_spi_write_bit ( struct bit_basher *basher,
unsigned int bit_id, unsigned long data ) {
struct rtl8139_nic *rtl = basher_to_rtl ( basher );
struct rtl8139_nic *rtl = container_of ( basher, struct rtl8139_nic,
spibit.basher );
uint8_t mask = rtl_ee_bits[bit_id];
uint8_t eereg;
@ -238,6 +235,14 @@ static void rtl_spi_write_bit ( struct bit_basher *basher,
outb ( eereg, rtl->ioaddr + Cfg9346 );
}
static struct bit_basher_operations rtl_basher_ops = {
.read = rtl_spi_read_bit,
.write = rtl_spi_write_bit,
};
static struct spi_device_type rtl_ee9346 = AT93C46 ( 16 );
static struct spi_device_type rtl_ee9356 = AT93C56 ( 16 );
/**
* Set up for EEPROM access
*
@ -247,19 +252,15 @@ static void rtl_init_eeprom ( struct rtl8139_nic *rtl ) {
int ee9356;
/* Initialise three-wire bus */
rtl->spibit.basher.read = rtl_spi_read_bit;
rtl->spibit.basher.write = rtl_spi_write_bit;
rtl->spibit.spi.mode = SPI_MODE_THREEWIRE;
rtl->spibit.basher.op = &rtl_basher_ops;
rtl->spibit.bus.mode = SPI_MODE_THREEWIRE;
init_spi_bit_basher ( &rtl->spibit );
/* Detect EEPROM type and initialise three-wire device */
ee9356 = ( inw ( rtl->ioaddr + RxConfig ) & Eeprom9356 );
DBG ( "EEPROM is an %s\n", ee9356 ? "AT93C56" : "AT93C46" );
rtl->eeprom.adrsize =
( ee9356 ? AT93C56_ORG16_ADRSIZE : AT93C46_ORG16_ADRSIZE );
rtl->eeprom.datasize =
( ee9356 ? AT93C56_ORG16_DATASIZE : AT93C46_ORG16_DATASIZE );
rtl->eeprom.spi = &rtl->spibit.spi;
DBG ( "EEPROM is an %s\n", ( ee9356 ? "AT93C56" : "AT93C46" ) );
rtl->eeprom.type = ( ee9356 ? &rtl_ee9356 : &rtl_ee9346 );
rtl->eeprom.bus = &rtl->spibit.bus;
}
/**
@ -269,18 +270,15 @@ static void rtl_init_eeprom ( struct rtl8139_nic *rtl ) {
* @v mac_addr Buffer to contain MAC address (ETH_ALEN bytes)
*/
static void rtl_read_mac ( struct rtl8139_nic *rtl, uint8_t *mac_addr ) {
union {
uint16_t word;
uint8_t bytes[2];
} u;
struct spi_device *device = &rtl->eeprom;
int i;
DBG ( "MAC address is " );
for ( i = EE_MAC ; i < ( EE_MAC + ( ETH_ALEN / 2 ) ) ; i++ ) {
u.word = cpu_to_le16 ( threewire_read ( &rtl->eeprom, i ) );
*mac_addr++ = u.bytes[0];
*mac_addr++ = u.bytes[1];
DBG ( "%02x%02x", u.bytes[0], u.bytes[1] );
device->type->read ( device, i, mac_addr, 1 );
DBG ( "%02x%02x", mac_addr[0], mac_addr[1] );
mac_addr += 2;
}
DBG ( "\n" );
}

39
src/drivers/nvs/threewire.c
View File

@ -17,8 +17,7 @@
*/
#include <stddef.h>
#include <byteswap.h>
#include <gpxe/spi.h>
#include <assert.h>
#include <gpxe/threewire.h>
/** @file
@ -27,31 +26,23 @@
*
*/
/**
* Read from a three-wire device
/** Read data from three-wire device
*
* @v three Three-wire device
* @v address Address
* @ret data Data
* @v device SPI device
* @v address Address from which to read
* @v data Data buffer
* @v len Length of data to read, in @b words
* @ret rc Return status code
*/
unsigned long threewire_read ( struct threewire_device *three,
unsigned long address ) {
struct spi_interface *spi = three->spi;
uint32_t data;
int threewire_read ( struct spi_device *device, unsigned int address,
void *data, unsigned int len ) {
struct spi_bus *bus = device->bus;
/* Activate chip select line */
spi->select_slave ( spi, three->slave );
assert ( bus->mode == SPI_MODE_THREEWIRE );
/* Send command and address */
data = cpu_to_le32 ( threewire_cmd_read ( three, address ) );
spi->transfer ( spi, &data, NULL, threewire_cmd_len ( three ) );
/* Read back data */
data = 0;
spi->transfer ( spi, NULL, &data, three->datasize );
DBG ( "3wire %p reading words [%04x,%04x)\n", device,
address, ( address + len ) );
/* Deactivate chip select line */
spi->deselect_slave ( spi );
return le32_to_cpu ( data );;
return bus->rw ( bus, device, THREEWIRE_READ, address,
NULL, data, len );
}

12
src/include/gpxe/bitbash.h
View File

@ -7,8 +7,10 @@
*
*/
/** A bit-bashing interface */
struct bit_basher {
struct bit_basher;
/** Bit-bashing operations */
struct bit_basher_operations {
/**
* Set/clear output bit
*
@ -35,6 +37,12 @@ struct bit_basher {
int ( * read ) ( struct bit_basher *basher, unsigned int bit_id );
};
/** A bit-bashing interface */
struct bit_basher {
/** Bit-bashing operations */
struct bit_basher_operations *op;
};
extern void write_bit ( struct bit_basher *basher, unsigned int bit_id,
unsigned long data );
extern int read_bit ( struct bit_basher *basher, unsigned int bit_id );

239
src/include/gpxe/spi.h
View File

@ -9,8 +9,170 @@
#include <gpxe/bitbash.h>
/** An SPI interface */
struct spi_interface {
/**
* @defgroup spicmds SPI commands
* @{
*/
/** Write status register */
#define SPI_WRSR 0x01
/** Write data to memory array */
#define SPI_WRITE 0x02
/** Read data from memory array */
#define SPI_READ 0x03
/** Reset write enable latch */
#define SPI_WRDI 0x04
/** Read status register */
#define SPI_RDSR 0x05
/** Set write enable latch */
#define SPI_WREN 0x06
/**
* @defgroup atmelcmds Atmel-specific SPI commands
* @{
*/
/** Erase one sector in memory array (Not supported on all devices) */
#define ATMEL_SECTOR_ERASE 0x52
/** Erase all sections in memory array (Not supported on all devices) */
#define ATMEL_CHIP_ERASE 0x62
/** Read manufacturer and product ID (Not supported on all devices) */
#define ATMEL_RDID 0x15
/** @} */
/** @} */
/**
* @defgroup spistatus SPI status register bits (not present on all devices)
* @{
*/
/** Write-protect pin enabled */
#define SPI_STATUS_WPEN 0x80
/** Block protection bit 2 */
#define SPI_STATUS_BP2 0x10
/** Block protection bit 1 */
#define SPI_STATUS_BP1 0x08
/** Block protection bit 0 */
#define SPI_STATUS_BP0 0x04
/** State of the write enable latch */
#define SPI_STATUS_WEN 0x02
/** Device busy flag */
#define SPI_STATUS_NRDY 0x01
/** @} */
struct spi_device;
/**
* An SPI device type
*
* This data structure represents all the characteristics belonging to
* a particular type of SPI device, e.g. "an Atmel 251024 serial flash",
* or "a Microchip 25040 serial EEPROM".
*/
struct spi_device_type {
/** Word length, in bits */
unsigned int word_len;
/** Device size (in words) */
unsigned int size;
/** Data block size (in words)
*
* This is the block size used by the device. It must be a
* power of two. Data reads and writes must not cross a block
* boundary.
*
* Many devices allow reads to cross a block boundary, and
* restrict only writes. For the sake of simplicity, we
* assume that the same restriction applies to both reads and
* writes.
*/
unsigned int block_size;
/** Command length, in bits */
unsigned int command_len;
/** Address length, in bits */
unsigned int address_len;
/** Address is munged
*
* Some devices with 9-bit addresses (e.g. AT25040A EEPROM)
* use bit 3 of the command byte as address bit A8, rather
* than having a two-byte address. If this flag is set, then
* commands should be munged in this way.
*/
unsigned int munge_address : 1;
/** Read data from device
*
* @v device SPI device
* @v address Address from which to read
* @v data Data buffer
* @v len Length of data to read, in @b words
* @ret rc Return status code
*/
int ( * read ) ( struct spi_device *device, unsigned int address,
void *data, unsigned int len );
/** Write data to device
*
* @v device SPI device
* @v address Address to which to write
* @v data Data buffer
* @v len Length of data to write, in @b words
* @ret rc Return status code
*/
int ( * write ) ( struct spi_device *device, unsigned int address,
const void *data, unsigned int len );
};
/**
* @defgroup spidevs SPI device types
* @{
*/
/** Atmel AT25010 serial EEPROM */
#define AT25010 { \
.word_len = 8, \
.size = 128, \
.block_size = 8, \
.command_len = 8, \
.address_len = 8, \
}
/** @} */
/**
* An SPI device
*
* This data structure represents a real, physical SPI device attached
* to an SPI controller. It comprises the device type plus
* instantiation-specific information such as the slave number.
*/
struct spi_device {
/** SPI device type */
struct spi_device_type *type;
/** SPI bus to which device is attached */
struct spi_bus *bus;
/** Slave number */
unsigned int slave;
};
/**
* An SPI bus
*
*
*/
struct spi_bus {
/** SPI interface mode
*
* This is the bitwise OR of zero or more of @c SPI_MODE_CPHA
@ -22,29 +184,26 @@ struct spi_interface {
*/
unsigned int mode;
/**
* Select slave
* Read/write data via SPI bus
*
* @v spi SPI interface
* @v slave Slave number
*/
void ( * select_slave ) ( struct spi_interface *spi,
unsigned int slave );
/**
* Deselect slave
*
* @v spi SPI interface
*/
void ( * deselect_slave ) ( struct spi_interface *spi );
/**
* Transfer bits over SPI bit-bashing interface
*
* @v spi SPI interface
* @v bus SPI bus
* @v device SPI device
* @v command Command
* @v address Address to read/write (<0 for no address)
* @v data_out TX data buffer (or NULL)
* @v data_in RX data buffer (or NULL)
* @v len Length of transfer (in @b bits)
* @v len Length of transfer (in @b words)
*
* This issues the specified command and optional address to
* the SPI device, then reads and/or writes data to/from the
* data buffers. Note that the transfer length is measured in
* words, not in bytes. Some SPI devices have 16-bit word
* lengths; take care with these devices not to accidentally
* read or write twice as much data as intended.
*/
void ( * transfer ) ( struct spi_interface *spi, const void *data_out,
void *data_in, unsigned int len );
int ( * rw ) ( struct spi_bus *bus, struct spi_device *device,
unsigned int command, int address,
const void *data_out, void *data_in, unsigned int len );
};
/** Clock phase (CPHA) mode bit
@ -91,42 +250,4 @@ struct spi_interface {
*/
#define SPI_MODE_THREEWIRE ( SPI_MODE_MICROWIRE_PLUS | SPI_MODE_SSPOL )
/** A bit-bashing SPI interface */
struct spi_bit_basher {
/** SPI interface */
struct spi_interface spi;
/** Bit-bashing interface */
struct bit_basher basher;
/** Currently selected slave
*
* Valid only when a slave is actually selected.
*/
unsigned int slave;
};
/** Bit indices used for SPI bit-bashing interface */
enum {
/** Serial clock */
SPI_BIT_SCLK = 0,
/** Master Out Slave In */
SPI_BIT_MOSI,
/** Master In Slave Out */
SPI_BIT_MISO,
/** Slave 0 select */
SPI_BIT_SS0,
};
/**
* Determine bit index for a particular slave
*
* @v slave Slave number
* @ret index Bit index (i.e. SPI_BIT_SSN, where N=slave)
*/
#define SPI_BIT_SS( slave ) ( SPI_BIT_SS0 + (slave) )
/** Delay between SCLK transitions */
#define SPI_UDELAY 1
extern void init_spi_bit_basher ( struct spi_bit_basher *spibit );
#endif /* _GPXE_SPI_H */

45
src/include/gpxe/spi_bit.h Normal file
View File

@ -0,0 +1,45 @@
#ifndef _GPXE_SPI_BIT_H
#define _GPXE_SPI_BIT_H
/** @file
*
* SPI bit-bashing interface
*
*/
#include <gpxe/spi.h>
/** A bit-bashing SPI bus */
struct spi_bit_basher {
/** SPI bus */
struct spi_bus bus;
/** Bit-bashing interface */
struct bit_basher basher;
};
/** Bit indices used for SPI bit-bashing interface */
enum {
/** Serial clock */
SPI_BIT_SCLK = 0,
/** Master Out Slave In */
SPI_BIT_MOSI,
/** Master In Slave Out */
SPI_BIT_MISO,
/** Slave 0 select */
SPI_BIT_SS0,
};
/**
* Determine bit index for a particular slave
*
* @v slave Slave number
* @ret index Bit index (i.e. SPI_BIT_SSN, where N=slave)
*/
#define SPI_BIT_SS( slave ) ( SPI_BIT_SS0 + (slave) )
/** Delay between SCLK transitions */
#define SPI_BIT_UDELAY 1
extern void init_spi_bit_basher ( struct spi_bit_basher *spibit );
#endif /* _GPXE_SPI_BIT_H */

82
src/include/gpxe/threewire.h
View File

@ -10,56 +10,52 @@
* support.
*/
struct spi_interface;
/** A three-wire device */
struct threewire_device {
/** SPI interface to which device is attached */
struct spi_interface *spi;
/** SPI slave number */
unsigned int slave;
/** Address size (in bits) */
unsigned int adrsize;
/** Data size (in bits) */
unsigned int datasize;
};
#include <gpxe/spi.h>
/**
* Calculate read command for a specified address
*
* @v three Three-wire interface
* @v address Address
* @ret cmd Command
* @defgroup tcmds Three-wire commands
* @{
*/
static inline __attribute__ (( always_inline )) unsigned long
threewire_cmd_read ( struct threewire_device *three, unsigned long address ) {
return ( ( 0x6 << three->adrsize ) | address );
}
/** Read data from memory array */
#define THREEWIRE_READ 0x6
/** @} */
/**
* Calculate command length
*
* @v three Three-wire interface
* @ret len Command length, in bits
* @defgroup spidevs SPI device types
* @{
*/
static inline __attribute__ (( always_inline )) unsigned int
threewire_cmd_len ( struct threewire_device *three ) {
return ( three->adrsize + 3 );
}
/* Constants for some standard parts */
#define AT93C46_ORG8_ADRSIZE 7
#define AT93C46_ORG8_DATASIZE 8
#define AT93C46_ORG16_ADRSIZE 6
#define AT93C46_ORG16_DATASIZE 16
#define AT93C46_UDELAY 1
#define AT93C56_ORG8_ADRSIZE 9
#define AT93C56_ORG8_DATASIZE 8
#define AT93C56_ORG16_ADRSIZE 8
#define AT93C56_ORG16_DATASIZE 16
#define AT93C56_UDELAY 1
/** Atmel AT93C46 serial EEPROM
*
* @v org Word size (8 or 16)
*/
#define AT93C46( org ) { \
.word_len = (org), \
.size = ( 1024 / (org) ), \
.block_size = 1, \
.command_len = 3, \
.address_len = ( ( (org) == 8 ) ? 7 : 6 ), \
.read = threewire_read, \
}
extern unsigned long threewire_read ( struct threewire_device *three,
unsigned long address );
/** Atmel AT93C56 serial EEPROM
*
* @v org Word size (8 or 16)
*/
#define AT93C56( org ) { \
.word_len = (org), \
.size = ( 2048 / (org) ), \
.block_size = 1, \
.command_len = 3, \
.address_len = ( ( (org) == 8 ) ? 9 : 8 ), \
.read = threewire_read, \
}
/** @} */
extern int threewire_read ( struct spi_device *device, unsigned int address,
void *data, unsigned int len );
#endif /* _GPXE_THREEWIRE_H */