gpxe/src/drivers/bitbash/spi_bit.c - platform/external/syslinux - Git at Google

 /*
  * Copyright (C) 2006 Michael Brown <mbrown@fensystems.co.uk>.
  *
  * This program is free software; you can redistribute it and/or
  * modify it under the terms of the GNU General Public License as
  * published by the Free Software Foundation; either version 2 of the
  * License, or any later version.
  *
  * 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.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
  */

 FILE_LICENCE ( GPL2_OR_LATER );

 #include <stddef.h>
 #include <stdint.h>
 #include <string.h>
 #include <byteswap.h>
 #include <errno.h>
 #include <assert.h>
 #include <unistd.h>
 #include <gpxe/bitbash.h>
 #include <gpxe/spi_bit.h>

 /** @file
  *
  * SPI bit-bashing interface
  *
  */

 /** Delay between SCLK changes and around SS changes */
 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 spibit		SPI bit-bashing interface
  * @v slave		Slave number
  * @v state		Slave select state
  *
  * @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->bus.mode & SPI_MODE_SSPOL );
 	DBGC2 ( spibit, "SPIBIT %p setting slave %d select %s\n",
 		spibit, slave, ( state ? "high" : "low" ) );

 	spi_bit_delay();
 	write_bit ( basher, SPI_BIT_SS ( slave ), state );
 	spi_bit_delay();
 }

 /**
  * Transfer bits over SPI bit-bashing bus
  *
  * @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)
  * @v endianness	Endianness of this data transfer
  *
  * This issues @c len clock cycles on the SPI bus, shifting out data
  * from the @c data_out buffer to the MOSI line and shifting in data
  * from the MISO line to the @c data_in buffer.  If @c data_out is
  * 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_bit_basher *spibit,
 			       const void *data_out, void *data_in,
 			       unsigned int len, int endianness ) {
 	struct spi_bus *bus = &spibit->bus;
 	struct bit_basher *basher = &spibit->basher;
 	unsigned int sclk = ( ( bus->mode & SPI_MODE_CPOL ) ? 1 : 0 );
 	unsigned int cpha = ( ( bus->mode & SPI_MODE_CPHA ) ? 1 : 0 );
 	unsigned int bit_offset;
 	unsigned int byte_offset;
 	unsigned int byte_mask;
 	unsigned int bit;
 	unsigned int step;

 	DBGC2 ( spibit, "SPIBIT %p transferring %d bits in mode %#x\n",
 		spibit, len, bus->mode );

 	for ( step = 0 ; step < ( len * 2 ) ; step++ ) {
 		/* Calculate byte offset and byte mask */
 		bit_offset = ( ( endianness == SPI_BIT_BIG_ENDIAN ) ?
 			       ( len - ( step / 2 ) - 1 ) : ( step / 2 ) );
 		byte_offset = ( bit_offset / 8 );
 		byte_mask = ( 1 << ( bit_offset % 8 ) );

 		/* Shift data in or out */
 		if ( sclk == cpha ) {
 			const uint8_t *byte;

 			/* Shift data out */
 			if ( data_out ) {
 				byte = ( data_out + byte_offset );
 				bit = ( *byte & byte_mask );
 				DBGCP ( spibit, "SPIBIT %p wrote bit %d\n",
 					spibit, ( bit ? 1 : 0 ) );
 			} else {
 				bit = 0;
 			}
 			write_bit ( basher, SPI_BIT_MOSI, bit );
 		} else {
 			uint8_t *byte;

 			/* Shift data in */
 			bit = read_bit ( basher, SPI_BIT_MISO );
 			if ( data_in ) {
 				DBGCP ( spibit, "SPIBIT %p read bit %d\n",
 					spibit, ( bit ? 1 : 0 ) );
 				byte = ( data_in + byte_offset );
 				*byte &= ~byte_mask;
 				*byte |= ( bit & byte_mask );
 			}
 		}

 		/* Toggle clock line */
 		spi_bit_delay();
 		sclk ^= 1;
 		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
  * @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, size_t len ) {
 	struct spi_bit_basher *spibit
 		= container_of ( bus, struct spi_bit_basher, bus );
 	uint32_t tmp_command;
 	uint32_t tmp_address;
 	uint32_t tmp_address_detect;

 	/* Set clock line to idle state */
 	write_bit ( &spibit->basher, SPI_BIT_SCLK,
 		    ( bus->mode & SPI_MODE_CPOL ) );

 	/* Assert chip select on specified slave */
 	spi_bit_set_slave_select ( spibit, device->slave, SELECT_SLAVE );

 	/* Transmit command */
 	assert ( device->command_len <= ( 8 * sizeof ( tmp_command ) ) );
 	tmp_command = cpu_to_le32 ( command );
 	spi_bit_transfer ( spibit, &tmp_command, NULL, device->command_len,
 			   SPI_BIT_BIG_ENDIAN );

 	/* Transmit address, if present */
 	if ( address >= 0 ) {
 		assert ( device->address_len <= ( 8 * sizeof ( tmp_address )));
 		tmp_address = cpu_to_le32 ( address );
 		if ( device->address_len == SPI_AUTODETECT_ADDRESS_LEN ) {
 			/* Autodetect address length.  This relies on
 			 * the device responding with a dummy zero
 			 * data bit before the first real data bit.
 			 */
 			DBGC ( spibit, "SPIBIT %p autodetecting device "
 			       "address length\n", spibit );
 			assert ( address == 0 );
 			device->address_len = 0;
 			do {
 				spi_bit_transfer ( spibit, &tmp_address,
 						   &tmp_address_detect, 1,
 						   SPI_BIT_BIG_ENDIAN );
 				device->address_len++;
 			} while ( le32_to_cpu ( tmp_address_detect ) & 1 );
 			DBGC ( spibit, "SPIBIT %p autodetected device address "
 			       "length %d\n", spibit, device->address_len );
 		} else {
 			spi_bit_transfer ( spibit, &tmp_address, NULL,
 					   device->address_len,
 					   SPI_BIT_BIG_ENDIAN );
 		}
 	}

 	/* Transmit/receive data */
 	spi_bit_transfer ( spibit, data_out, data_in, ( len * 8 ),
 			   spibit->endianness );

 	/* 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.op->read != NULL );
 	assert ( &spibit->basher.op->write != NULL );
 	spibit->bus.rw = spi_bit_rw;
 }
	/*
	* Copyright (C) 2006 Michael Brown <mbrown@fensystems.co.uk>.
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License as
	* published by the Free Software Foundation; either version 2 of the
	* License, or any later version.
	*
	* 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.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
	*/

	FILE_LICENCE ( GPL2_OR_LATER );

	#include <stddef.h>
	#include <stdint.h>
	#include <string.h>
	#include <byteswap.h>
	#include <errno.h>
	#include <assert.h>
	#include <unistd.h>
	#include <gpxe/bitbash.h>
	#include <gpxe/spi_bit.h>

	/** @file
	*
	* SPI bit-bashing interface
	*
	*/

	/** Delay between SCLK changes and around SS changes */
	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 spibit SPI bit-bashing interface
	* @v slave Slave number
	* @v state Slave select state
	*
	* @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->bus.mode & SPI_MODE_SSPOL );
	DBGC2 ( spibit, "SPIBIT %p setting slave %d select %s\n",
	spibit, slave, ( state ? "high" : "low" ) );

	spi_bit_delay();
	write_bit ( basher, SPI_BIT_SS ( slave ), state );
	spi_bit_delay();
	}

	/**
	* Transfer bits over SPI bit-bashing bus
	*
	* @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)
	* @v endianness Endianness of this data transfer
	*
	* This issues @c len clock cycles on the SPI bus, shifting out data
	* from the @c data_out buffer to the MOSI line and shifting in data
	* from the MISO line to the @c data_in buffer. If @c data_out is
	* 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_bit_basher *spibit,
	const void data_out, void data_in,
	unsigned int len, int endianness ) {
	struct spi_bus *bus = &spibit->bus;
	struct bit_basher *basher = &spibit->basher;
	unsigned int sclk = ( ( bus->mode & SPI_MODE_CPOL ) ? 1 : 0 );
	unsigned int cpha = ( ( bus->mode & SPI_MODE_CPHA ) ? 1 : 0 );
	unsigned int bit_offset;
	unsigned int byte_offset;
	unsigned int byte_mask;
	unsigned int bit;
	unsigned int step;

	DBGC2 ( spibit, "SPIBIT %p transferring %d bits in mode %#x\n",
	spibit, len, bus->mode );

	for ( step = 0 ; step < ( len * 2 ) ; step++ ) {
	/* Calculate byte offset and byte mask */
	bit_offset = ( ( endianness == SPI_BIT_BIG_ENDIAN ) ?
	( len - ( step / 2 ) - 1 ) : ( step / 2 ) );
	byte_offset = ( bit_offset / 8 );
	byte_mask = ( 1 << ( bit_offset % 8 ) );

	/* Shift data in or out */
	if ( sclk == cpha ) {
	const uint8_t *byte;

	/* Shift data out */
	if ( data_out ) {
	byte = ( data_out + byte_offset );
	bit = ( *byte & byte_mask );
	DBGCP ( spibit, "SPIBIT %p wrote bit %d\n",
	spibit, ( bit ? 1 : 0 ) );
	} else {
	bit = 0;
	}
	write_bit ( basher, SPI_BIT_MOSI, bit );
	} else {
	uint8_t *byte;

	/* Shift data in */
	bit = read_bit ( basher, SPI_BIT_MISO );
	if ( data_in ) {
	DBGCP ( spibit, "SPIBIT %p read bit %d\n",
	spibit, ( bit ? 1 : 0 ) );
	byte = ( data_in + byte_offset );
	*byte &= ~byte_mask;
	*byte \|= ( bit & byte_mask );
	}
	}

	/* Toggle clock line */
	spi_bit_delay();
	sclk ^= 1;
	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
	* @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, size_t len ) {
	struct spi_bit_basher *spibit
	= container_of ( bus, struct spi_bit_basher, bus );
	uint32_t tmp_command;
	uint32_t tmp_address;
	uint32_t tmp_address_detect;

	/* Set clock line to idle state */
	write_bit ( &spibit->basher, SPI_BIT_SCLK,
	( bus->mode & SPI_MODE_CPOL ) );

	/* Assert chip select on specified slave */
	spi_bit_set_slave_select ( spibit, device->slave, SELECT_SLAVE );

	/* Transmit command */
	assert ( device->command_len <= ( 8 * sizeof ( tmp_command ) ) );
	tmp_command = cpu_to_le32 ( command );
	spi_bit_transfer ( spibit, &tmp_command, NULL, device->command_len,
	SPI_BIT_BIG_ENDIAN );

	/* Transmit address, if present */
	if ( address >= 0 ) {
	assert ( device->address_len <= ( 8 * sizeof ( tmp_address )));
	tmp_address = cpu_to_le32 ( address );
	if ( device->address_len == SPI_AUTODETECT_ADDRESS_LEN ) {
	/* Autodetect address length. This relies on
	* the device responding with a dummy zero
	* data bit before the first real data bit.
	*/
	DBGC ( spibit, "SPIBIT %p autodetecting device "
	"address length\n", spibit );
	assert ( address == 0 );
	device->address_len = 0;
	do {
	spi_bit_transfer ( spibit, &tmp_address,
	&tmp_address_detect, 1,
	SPI_BIT_BIG_ENDIAN );
	device->address_len++;
	} while ( le32_to_cpu ( tmp_address_detect ) & 1 );
	DBGC ( spibit, "SPIBIT %p autodetected device address "
	"length %d\n", spibit, device->address_len );
	} else {
	spi_bit_transfer ( spibit, &tmp_address, NULL,
	device->address_len,
	SPI_BIT_BIG_ENDIAN );
	}
	}

	/* Transmit/receive data */
	spi_bit_transfer ( spibit, data_out, data_in, ( len * 8 ),
	spibit->endianness );

	/* 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.op->read != NULL );
	assert ( &spibit->basher.op->write != NULL );
	spibit->bus.rw = spi_bit_rw;
	}