drivers/net/atp.h - android_kernel_oneplus_sm8150 - Gitiles

 /* Linux header file for the ATP pocket ethernet adapter. */
 /* v1.09 8/9/2000 becker@scyld.com. */

 #include <linux/if_ether.h>
 #include <linux/types.h>

 /* The header prepended to received packets. */
 struct rx_header {
     ushort pad;			/* Pad. */
     ushort rx_count;
     ushort rx_status;		/* Unknown bit assignments :-<.  */
     ushort cur_addr;		/* Apparently the current buffer address(?) */
 };

 #define PAR_DATA	0
 #define PAR_STATUS	1
 #define PAR_CONTROL 2

 enum chip_type { RTL8002, RTL8012 };

 #define Ctrl_LNibRead	0x08	/* LP_PSELECP */
 #define Ctrl_HNibRead	0
 #define Ctrl_LNibWrite	0x08	/* LP_PSELECP */
 #define Ctrl_HNibWrite	0
 #define Ctrl_SelData	0x04	/* LP_PINITP */
 #define Ctrl_IRQEN	0x10	/* LP_PINTEN */

 #define EOW	0xE0
 #define EOC	0xE0
 #define WrAddr	0x40	/* Set address of EPLC read, write register. */
 #define RdAddr	0xC0
 #define HNib	0x10

 enum page0_regs
 {
     /* The first six registers hold the ethernet physical station address. */
     PAR0 = 0, PAR1 = 1, PAR2 = 2, PAR3 = 3, PAR4 = 4, PAR5 = 5,
     TxCNT0 = 6, TxCNT1 = 7,		/* The transmit byte count. */
     TxSTAT = 8, RxSTAT = 9,		/* Tx and Rx status. */
     ISR = 10, IMR = 11,			/* Interrupt status and mask. */
     CMR1 = 12,				/* Command register 1. */
     CMR2 = 13,				/* Command register 2. */
     MODSEL = 14,			/* Mode select register. */
     MAR = 14,				/* Memory address register (?). */
     CMR2_h = 0x1d, };

 enum eepage_regs
 { PROM_CMD = 6, PROM_DATA = 7 };	/* Note that PROM_CMD is in the "high" bits. */


 #define ISR_TxOK	0x01
 #define ISR_RxOK	0x04
 #define ISR_TxErr	0x02
 #define ISRh_RxErr	0x11	/* ISR, high nibble */

 #define CMR1h_MUX	0x08	/* Select printer multiplexor on 8012. */
 #define CMR1h_RESET	0x04	/* Reset. */
 #define CMR1h_RxENABLE	0x02	/* Rx unit enable.  */
 #define CMR1h_TxENABLE	0x01	/* Tx unit enable.  */
 #define CMR1h_TxRxOFF	0x00
 #define CMR1_ReXmit	0x08	/* Trigger a retransmit. */
 #define CMR1_Xmit	0x04	/* Trigger a transmit. */
 #define	CMR1_IRQ	0x02	/* Interrupt active. */
 #define	CMR1_BufEnb	0x01	/* Enable the buffer(?). */
 #define	CMR1_NextPkt	0x01	/* Enable the buffer(?). */

 #define CMR2_NULL	8
 #define CMR2_IRQOUT	9
 #define CMR2_RAMTEST	10
 #define CMR2_EEPROM	12	/* Set to page 1, for reading the EEPROM. */

 #define CMR2h_OFF	0	/* No accept mode. */
 #define CMR2h_Physical	1	/* Accept a physical address match only. */
 #define CMR2h_Normal	2	/* Accept physical and broadcast address. */
 #define CMR2h_PROMISC	3	/* Promiscuous mode. */

 /* An inline function used below: it differs from inb() by explicitly return an unsigned
    char, saving a truncation. */
 static inline unsigned char inbyte(unsigned short port)
 {
     unsigned char _v;
     __asm__ __volatile__ ("inb %w1,%b0" :"=a" (_v):"d" (port));
     return _v;
 }

 /* Read register OFFSET.
    This command should always be terminated with read_end(). */
 static inline unsigned char read_nibble(short port, unsigned char offset)
 {
     unsigned char retval;
     outb(EOC+offset, port + PAR_DATA);
     outb(RdAddr+offset, port + PAR_DATA);
     inbyte(port + PAR_STATUS);		/* Settling time delay */
     retval = inbyte(port + PAR_STATUS);
     outb(EOC+offset, port + PAR_DATA);

     return retval;
 }

 /* Functions for bulk data read.  The interrupt line is always disabled. */
 /* Get a byte using read mode 0, reading data from the control lines. */
 static inline unsigned char read_byte_mode0(short ioaddr)
 {
     unsigned char low_nib;

     outb(Ctrl_LNibRead, ioaddr + PAR_CONTROL);
     inbyte(ioaddr + PAR_STATUS);
     low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
     outb(Ctrl_HNibRead, ioaddr + PAR_CONTROL);
     inbyte(ioaddr + PAR_STATUS);	/* Settling time delay -- needed!  */
     inbyte(ioaddr + PAR_STATUS);	/* Settling time delay -- needed!  */
     return low_nib | ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
 }

 /* The same as read_byte_mode0(), but does multiple inb()s for stability. */
 static inline unsigned char read_byte_mode2(short ioaddr)
 {
     unsigned char low_nib;

     outb(Ctrl_LNibRead, ioaddr + PAR_CONTROL);
     inbyte(ioaddr + PAR_STATUS);
     low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
     outb(Ctrl_HNibRead, ioaddr + PAR_CONTROL);
     inbyte(ioaddr + PAR_STATUS);	/* Settling time delay -- needed!  */
     return low_nib | ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
 }

 /* Read a byte through the data register. */
 static inline unsigned char read_byte_mode4(short ioaddr)
 {
     unsigned char low_nib;

     outb(RdAddr | MAR, ioaddr + PAR_DATA);
     low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
     outb(RdAddr | HNib | MAR, ioaddr + PAR_DATA);
     return low_nib | ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
 }

 /* Read a byte through the data register, double reading to allow settling. */
 static inline unsigned char read_byte_mode6(short ioaddr)
 {
     unsigned char low_nib;

     outb(RdAddr | MAR, ioaddr + PAR_DATA);
     inbyte(ioaddr + PAR_STATUS);
     low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
     outb(RdAddr | HNib | MAR, ioaddr + PAR_DATA);
     inbyte(ioaddr + PAR_STATUS);
     return low_nib | ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
 }

 static inline void
 write_reg(short port, unsigned char reg, unsigned char value)
 {
     unsigned char outval;
     outb(EOC | reg, port + PAR_DATA);
     outval = WrAddr | reg;
     outb(outval, port + PAR_DATA);
     outb(outval, port + PAR_DATA);	/* Double write for PS/2. */

     outval &= 0xf0;
     outval |= value;
     outb(outval, port + PAR_DATA);
     outval &= 0x1f;
     outb(outval, port + PAR_DATA);
     outb(outval, port + PAR_DATA);

     outb(EOC | outval, port + PAR_DATA);
 }

 static inline void
 write_reg_high(short port, unsigned char reg, unsigned char value)
 {
     unsigned char outval = EOC | HNib | reg;

     outb(outval, port + PAR_DATA);
     outval &= WrAddr | HNib | 0x0f;
     outb(outval, port + PAR_DATA);
     outb(outval, port + PAR_DATA);	/* Double write for PS/2. */

     outval = WrAddr | HNib | value;
     outb(outval, port + PAR_DATA);
     outval &= HNib | 0x0f;		/* HNib | value */
     outb(outval, port + PAR_DATA);
     outb(outval, port + PAR_DATA);

     outb(EOC | HNib | outval, port + PAR_DATA);
 }

 /* Write a byte out using nibble mode.  The low nibble is written first. */
 static inline void
 write_reg_byte(short port, unsigned char reg, unsigned char value)
 {
     unsigned char outval;
     outb(EOC | reg, port + PAR_DATA); 	/* Reset the address register. */
     outval = WrAddr | reg;
     outb(outval, port + PAR_DATA);
     outb(outval, port + PAR_DATA);	/* Double write for PS/2. */

     outb((outval & 0xf0) | (value & 0x0f), port + PAR_DATA);
     outb(value & 0x0f, port + PAR_DATA);
     value >>= 4;
     outb(value, port + PAR_DATA);
     outb(0x10 | value, port + PAR_DATA);
     outb(0x10 | value, port + PAR_DATA);

     outb(EOC  | value, port + PAR_DATA); 	/* Reset the address register. */
 }

 /*
  * Bulk data writes to the packet buffer.  The interrupt line remains enabled.
  * The first, faster method uses only the dataport (data modes 0, 2 & 4).
  * The second (backup) method uses data and control regs (modes 1, 3 & 5).
  * It should only be needed when there is skew between the individual data
  * lines.
  */
 static inline void write_byte_mode0(short ioaddr, unsigned char value)
 {
     outb(value & 0x0f, ioaddr + PAR_DATA);
     outb((value>>4) | 0x10, ioaddr + PAR_DATA);
 }

 static inline void write_byte_mode1(short ioaddr, unsigned char value)
 {
     outb(value & 0x0f, ioaddr + PAR_DATA);
     outb(Ctrl_IRQEN | Ctrl_LNibWrite, ioaddr + PAR_CONTROL);
     outb((value>>4) | 0x10, ioaddr + PAR_DATA);
     outb(Ctrl_IRQEN | Ctrl_HNibWrite, ioaddr + PAR_CONTROL);
 }

 /* Write 16bit VALUE to the packet buffer: the same as above just doubled. */
 static inline void write_word_mode0(short ioaddr, unsigned short value)
 {
     outb(value & 0x0f, ioaddr + PAR_DATA);
     value >>= 4;
     outb((value & 0x0f) | 0x10, ioaddr + PAR_DATA);
     value >>= 4;
     outb(value & 0x0f, ioaddr + PAR_DATA);
     value >>= 4;
     outb((value & 0x0f) | 0x10, ioaddr + PAR_DATA);
 }

 /*  EEPROM_Ctrl bits. */
 #define EE_SHIFT_CLK	0x04	/* EEPROM shift clock. */
 #define EE_CS		0x02	/* EEPROM chip select. */
 #define EE_CLK_HIGH	0x12
 #define EE_CLK_LOW	0x16
 #define EE_DATA_WRITE	0x01	/* EEPROM chip data in. */
 #define EE_DATA_READ	0x08	/* EEPROM chip data out. */

 /* Delay between EEPROM clock transitions. */
 #define eeprom_delay(ticks) \
 do { int _i = 40; while (--_i > 0) { __SLOW_DOWN_IO; }} while (0)

 /* The EEPROM commands include the alway-set leading bit. */
 #define EE_WRITE_CMD(offset)	(((5 << 6) + (offset)) << 17)
 #define EE_READ(offset) 	(((6 << 6) + (offset)) << 17)
 #define EE_ERASE(offset)	(((7 << 6) + (offset)) << 17)
 #define EE_CMD_SIZE	27	/* The command+address+data size. */
	/* Linux header file for the ATP pocket ethernet adapter. */
	/* v1.09 8/9/2000 becker@scyld.com. */

	#include <linux/if_ether.h>
	#include <linux/types.h>

	/* The header prepended to received packets. */
	struct rx_header {
	ushort pad; /* Pad. */
	ushort rx_count;
	ushort rx_status; /* Unknown bit assignments :-<. */
	ushort cur_addr; /* Apparently the current buffer address(?) */
	};

	#define PAR_DATA 0
	#define PAR_STATUS 1
	#define PAR_CONTROL 2

	enum chip_type { RTL8002, RTL8012 };

	#define Ctrl_LNibRead 0x08 /* LP_PSELECP */
	#define Ctrl_HNibRead 0
	#define Ctrl_LNibWrite 0x08 /* LP_PSELECP */
	#define Ctrl_HNibWrite 0
	#define Ctrl_SelData 0x04 /* LP_PINITP */
	#define Ctrl_IRQEN 0x10 /* LP_PINTEN */

	#define EOW 0xE0
	#define EOC 0xE0
	#define WrAddr 0x40 /* Set address of EPLC read, write register. */
	#define RdAddr 0xC0
	#define HNib 0x10

	enum page0_regs
	{
	/* The first six registers hold the ethernet physical station address. */
	PAR0 = 0, PAR1 = 1, PAR2 = 2, PAR3 = 3, PAR4 = 4, PAR5 = 5,
	TxCNT0 = 6, TxCNT1 = 7, /* The transmit byte count. */
	TxSTAT = 8, RxSTAT = 9, /* Tx and Rx status. */
	ISR = 10, IMR = 11, /* Interrupt status and mask. */
	CMR1 = 12, /* Command register 1. */
	CMR2 = 13, /* Command register 2. */
	MODSEL = 14, /* Mode select register. */
	MAR = 14, /* Memory address register (?). */
	CMR2_h = 0x1d, };

	enum eepage_regs
	{ PROM_CMD = 6, PROM_DATA = 7 }; /* Note that PROM_CMD is in the "high" bits. */


	#define ISR_TxOK 0x01
	#define ISR_RxOK 0x04
	#define ISR_TxErr 0x02
	#define ISRh_RxErr 0x11 /* ISR, high nibble */

	#define CMR1h_MUX 0x08 /* Select printer multiplexor on 8012. */
	#define CMR1h_RESET 0x04 /* Reset. */
	#define CMR1h_RxENABLE 0x02 /* Rx unit enable. */
	#define CMR1h_TxENABLE 0x01 /* Tx unit enable. */
	#define CMR1h_TxRxOFF 0x00
	#define CMR1_ReXmit 0x08 /* Trigger a retransmit. */
	#define CMR1_Xmit 0x04 /* Trigger a transmit. */
	#define CMR1_IRQ 0x02 /* Interrupt active. */
	#define CMR1_BufEnb 0x01 /* Enable the buffer(?). */
	#define CMR1_NextPkt 0x01 /* Enable the buffer(?). */

	#define CMR2_NULL 8
	#define CMR2_IRQOUT 9
	#define CMR2_RAMTEST 10
	#define CMR2_EEPROM 12 /* Set to page 1, for reading the EEPROM. */

	#define CMR2h_OFF 0 /* No accept mode. */
	#define CMR2h_Physical 1 /* Accept a physical address match only. */
	#define CMR2h_Normal 2 /* Accept physical and broadcast address. */
	#define CMR2h_PROMISC 3 /* Promiscuous mode. */

	/* An inline function used below: it differs from inb() by explicitly return an unsigned
	char, saving a truncation. */
	static inline unsigned char inbyte(unsigned short port)
	{
	unsigned char _v;
	__asm__ __volatile__ ("inb %w1,%b0" :"=a" (_v):"d" (port));
	return _v;
	}

	/* Read register OFFSET.
	This command should always be terminated with read_end(). */
	static inline unsigned char read_nibble(short port, unsigned char offset)
	{
	unsigned char retval;
	outb(EOC+offset, port + PAR_DATA);
	outb(RdAddr+offset, port + PAR_DATA);
	inbyte(port + PAR_STATUS); /* Settling time delay */
	retval = inbyte(port + PAR_STATUS);
	outb(EOC+offset, port + PAR_DATA);

	return retval;
	}

	/* Functions for bulk data read. The interrupt line is always disabled. */
	/* Get a byte using read mode 0, reading data from the control lines. */
	static inline unsigned char read_byte_mode0(short ioaddr)
	{
	unsigned char low_nib;

	outb(Ctrl_LNibRead, ioaddr + PAR_CONTROL);
	inbyte(ioaddr + PAR_STATUS);
	low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
	outb(Ctrl_HNibRead, ioaddr + PAR_CONTROL);
	inbyte(ioaddr + PAR_STATUS); /* Settling time delay -- needed! */
	inbyte(ioaddr + PAR_STATUS); /* Settling time delay -- needed! */
	return low_nib \| ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
	}

	/* The same as read_byte_mode0(), but does multiple inb()s for stability. */
	static inline unsigned char read_byte_mode2(short ioaddr)
	{
	unsigned char low_nib;

	outb(Ctrl_LNibRead, ioaddr + PAR_CONTROL);
	inbyte(ioaddr + PAR_STATUS);
	low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
	outb(Ctrl_HNibRead, ioaddr + PAR_CONTROL);
	inbyte(ioaddr + PAR_STATUS); /* Settling time delay -- needed! */
	return low_nib \| ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
	}

	/* Read a byte through the data register. */
	static inline unsigned char read_byte_mode4(short ioaddr)
	{
	unsigned char low_nib;

	outb(RdAddr \| MAR, ioaddr + PAR_DATA);
	low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
	outb(RdAddr \| HNib \| MAR, ioaddr + PAR_DATA);
	return low_nib \| ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
	}

	/* Read a byte through the data register, double reading to allow settling. */
	static inline unsigned char read_byte_mode6(short ioaddr)
	{
	unsigned char low_nib;

	outb(RdAddr \| MAR, ioaddr + PAR_DATA);
	inbyte(ioaddr + PAR_STATUS);
	low_nib = (inbyte(ioaddr + PAR_STATUS) >> 3) & 0x0f;
	outb(RdAddr \| HNib \| MAR, ioaddr + PAR_DATA);
	inbyte(ioaddr + PAR_STATUS);
	return low_nib \| ((inbyte(ioaddr + PAR_STATUS) << 1) & 0xf0);
	}

	static inline void
	write_reg(short port, unsigned char reg, unsigned char value)
	{
	unsigned char outval;
	outb(EOC \| reg, port + PAR_DATA);
	outval = WrAddr \| reg;
	outb(outval, port + PAR_DATA);
	outb(outval, port + PAR_DATA); /* Double write for PS/2. */

	outval &= 0xf0;
	outval \|= value;
	outb(outval, port + PAR_DATA);
	outval &= 0x1f;
	outb(outval, port + PAR_DATA);
	outb(outval, port + PAR_DATA);

	outb(EOC \| outval, port + PAR_DATA);
	}

	static inline void
	write_reg_high(short port, unsigned char reg, unsigned char value)
	{
	unsigned char outval = EOC \| HNib \| reg;

	outb(outval, port + PAR_DATA);
	outval &= WrAddr \| HNib \| 0x0f;
	outb(outval, port + PAR_DATA);
	outb(outval, port + PAR_DATA); /* Double write for PS/2. */

	outval = WrAddr \| HNib \| value;
	outb(outval, port + PAR_DATA);
	outval &= HNib \| 0x0f; /* HNib \| value */
	outb(outval, port + PAR_DATA);
	outb(outval, port + PAR_DATA);

	outb(EOC \| HNib \| outval, port + PAR_DATA);
	}

	/* Write a byte out using nibble mode. The low nibble is written first. */
	static inline void
	write_reg_byte(short port, unsigned char reg, unsigned char value)
	{
	unsigned char outval;
	outb(EOC \| reg, port + PAR_DATA); /* Reset the address register. */
	outval = WrAddr \| reg;
	outb(outval, port + PAR_DATA);
	outb(outval, port + PAR_DATA); /* Double write for PS/2. */

	outb((outval & 0xf0) \| (value & 0x0f), port + PAR_DATA);
	outb(value & 0x0f, port + PAR_DATA);
	value >>= 4;
	outb(value, port + PAR_DATA);
	outb(0x10 \| value, port + PAR_DATA);
	outb(0x10 \| value, port + PAR_DATA);

	outb(EOC \| value, port + PAR_DATA); /* Reset the address register. */
	}

	/*
	* Bulk data writes to the packet buffer. The interrupt line remains enabled.
	* The first, faster method uses only the dataport (data modes 0, 2 & 4).
	* The second (backup) method uses data and control regs (modes 1, 3 & 5).
	* It should only be needed when there is skew between the individual data
	* lines.
	*/
	static inline void write_byte_mode0(short ioaddr, unsigned char value)
	{
	outb(value & 0x0f, ioaddr + PAR_DATA);
	outb((value>>4) \| 0x10, ioaddr + PAR_DATA);
	}

	static inline void write_byte_mode1(short ioaddr, unsigned char value)
	{
	outb(value & 0x0f, ioaddr + PAR_DATA);
	outb(Ctrl_IRQEN \| Ctrl_LNibWrite, ioaddr + PAR_CONTROL);
	outb((value>>4) \| 0x10, ioaddr + PAR_DATA);
	outb(Ctrl_IRQEN \| Ctrl_HNibWrite, ioaddr + PAR_CONTROL);
	}

	/* Write 16bit VALUE to the packet buffer: the same as above just doubled. */
	static inline void write_word_mode0(short ioaddr, unsigned short value)
	{
	outb(value & 0x0f, ioaddr + PAR_DATA);
	value >>= 4;
	outb((value & 0x0f) \| 0x10, ioaddr + PAR_DATA);
	value >>= 4;
	outb(value & 0x0f, ioaddr + PAR_DATA);
	value >>= 4;
	outb((value & 0x0f) \| 0x10, ioaddr + PAR_DATA);
	}

	/* EEPROM_Ctrl bits. */
	#define EE_SHIFT_CLK 0x04 /* EEPROM shift clock. */
	#define EE_CS 0x02 /* EEPROM chip select. */
	#define EE_CLK_HIGH 0x12
	#define EE_CLK_LOW 0x16
	#define EE_DATA_WRITE 0x01 /* EEPROM chip data in. */
	#define EE_DATA_READ 0x08 /* EEPROM chip data out. */

	/* Delay between EEPROM clock transitions. */
	#define eeprom_delay(ticks) \
	do { int _i = 40; while (--_i > 0) { __SLOW_DOWN_IO; }} while (0)

	/* The EEPROM commands include the alway-set leading bit. */
	#define EE_WRITE_CMD(offset) (((5 << 6) + (offset)) << 17)
	#define EE_READ(offset) (((6 << 6) + (offset)) << 17)
	#define EE_ERASE(offset) (((7 << 6) + (offset)) << 17)
	#define EE_CMD_SIZE 27 /* The command+address+data size. */