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[kvmfornfv.git] / qemu / roms / u-boot / drivers / net / smc91111.h

/*------------------------------------------------------------------------
 . smc91111.h - macros for the LAN91C111 Ethernet Driver
 .
 . (C) Copyright 2002
 . Sysgo Real-Time Solutions, GmbH <www.elinos.com>
 . Rolf Offermanns <rof@sysgo.de>
 . Copyright (C) 2001 Standard Microsystems Corporation (SMSC)
 .       Developed by Simple Network Magic Corporation (SNMC)
 . Copyright (C) 1996 by Erik Stahlman (ES)
 .
  * SPDX-License-Identifier:    GPL-2.0+
 .
 . This file contains register information and access macros for
 . the LAN91C111 single chip ethernet controller.  It is a modified
 . version of the smc9194.h file.
 .
 . Information contained in this file was obtained from the LAN91C111
 . manual from SMC.  To get a copy, if you really want one, you can find
 . information under www.smsc.com.
 .
 . Authors
 .      Erik Stahlman                           ( erik@vt.edu )
 .      Daris A Nevil                           ( dnevil@snmc.com )
 .
 . History
 . 03/16/01             Daris A Nevil   Modified for use with LAN91C111 device
 .
 ---------------------------------------------------------------------------*/
#ifndef _SMC91111_H_
#define _SMC91111_H_

#include <asm/types.h>
#include <config.h>

/*
 * This function may be called by the board specific initialisation code
 * in order to override the default mac address.
 */

void smc_set_mac_addr (const unsigned char *addr);


/* I want some simple types */

typedef unsigned char                   byte;
typedef unsigned short                  word;
typedef unsigned long int               dword;

struct smc91111_priv{
        u8 dev_num;
};

/*
 . DEBUGGING LEVELS
 .
 . 0 for normal operation
 . 1 for slightly more details
 . >2 for various levels of increasingly useless information
 .    2 for interrupt tracking, status flags
 .    3 for packet info
 .    4 for complete packet dumps
*/
/*#define SMC_DEBUG 0 */

/* Because of bank switching, the LAN91xxx uses only 16 I/O ports */

#define SMC_IO_EXTENT   16

#ifdef CONFIG_CPU_PXA25X

#ifdef CONFIG_XSENGINE
#define SMC_inl(a,r)    (*((volatile dword *)((a)->iobase+((r)<<1))))
#define SMC_inw(a,r)    (*((volatile word *)((a)->iobase+((r)<<1))))
#define SMC_inb(a,p)  ({ \
        unsigned int __p = (unsigned int)((a)->iobase + ((p)<<1)); \
        unsigned int __v = *(volatile unsigned short *)((__p) & ~2); \
        if (__p & 2) __v >>= 8; \
        else __v &= 0xff; \
        __v; })
#elif defined(CONFIG_XAENIAX)
#define SMC_inl(a,r)    (*((volatile dword *)((a)->iobase+(r))))
#define SMC_inw(a,z)    ({ \
        unsigned int __p = (unsigned int)((a)->iobase + (z)); \
        unsigned int __v = *(volatile unsigned int *)((__p) & ~3); \
        if (__p & 3) __v >>= 16; \
        else __v &= 0xffff; \
        __v; })
#define SMC_inb(a,p)    ({ \
        unsigned int ___v = SMC_inw((a),(p) & ~1); \
        if ((p) & 1) ___v >>= 8; \
        else ___v &= 0xff; \
        ___v; })
#else
#define SMC_inl(a,r)    (*((volatile dword *)((a)->iobase+(r))))
#define SMC_inw(a,r)    (*((volatile word *)((a)->iobase+(r))))
#define SMC_inb(a,p)    ({ \
        unsigned int __p = (unsigned int)((a)->iobase + (p)); \
        unsigned int __v = *(volatile unsigned short *)((__p) & ~1); \
        if (__p & 1) __v >>= 8; \
        else __v &= 0xff; \
        __v; })
#endif

#ifdef CONFIG_XSENGINE
#define SMC_outl(a,d,r) (*((volatile dword *)((a)->iobase+(r<<1))) = d)
#define SMC_outw(a,d,r) (*((volatile word *)((a)->iobase+(r<<1))) = d)
#elif defined (CONFIG_XAENIAX)
#define SMC_outl(a,d,r) (*((volatile dword *)((a)->iobase+(r))) = d)
#define SMC_outw(a,d,p) ({ \
        dword __dwo = SMC_inl((a),(p) & ~3); \
        dword __dwn = (word)(d); \
        __dwo &= ((p) & 3) ? 0x0000ffff : 0xffff0000; \
        __dwo |= ((p) & 3) ? __dwn << 16 : __dwn; \
        SMC_outl((a), __dwo, (p) & ~3); \
})
#else
#define SMC_outl(a,d,r) (*((volatile dword *)((a)->iobase+(r))) = d)
#define SMC_outw(a,d,r) (*((volatile word *)((a)->iobase+(r))) = d)
#endif

#define SMC_outb(a,d,r) ({      word __d = (byte)(d);  \
                                word __w = SMC_inw((a),(r)&~1);  \
                                __w &= ((r)&1) ? 0x00FF : 0xFF00;  \
                                __w |= ((r)&1) ? __d<<8 : __d;  \
                                SMC_outw((a),__w,(r)&~1);  \
                        })

#define SMC_outsl(a,r,b,l)      ({      int __i; \
                                        dword *__b2; \
                                        __b2 = (dword *) b; \
                                        for (__i = 0; __i < l; __i++) { \
                                            SMC_outl((a), *(__b2 + __i), r); \
                                        } \
                                })

#define SMC_outsw(a,r,b,l)      ({      int __i; \
                                        word *__b2; \
                                        __b2 = (word *) b; \
                                        for (__i = 0; __i < l; __i++) { \
                                            SMC_outw((a), *(__b2 + __i), r); \
                                        } \
                                })

#define SMC_insl(a,r,b,l)       ({      int __i ;  \
                                        dword *__b2;  \
                                        __b2 = (dword *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inl((a),(r));  \
                                          SMC_inl((a),0);  \
                                        };  \
                                })

#define SMC_insw(a,r,b,l)               ({      int __i ;  \
                                        word *__b2;  \
                                        __b2 = (word *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inw((a),(r));  \
                                          SMC_inw((a),0);  \
                                        };  \
                                })

#define SMC_insb(a,r,b,l)       ({      int __i ;  \
                                        byte *__b2;  \
                                        __b2 = (byte *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inb((a),(r));  \
                                          SMC_inb((a),0);  \
                                        };  \
                                })

#elif defined(CONFIG_LEON)      /* if not CONFIG_CPU_PXA25X */

#define SMC_LEON_SWAP16(_x_) ({ word _x = (_x_); ((_x << 8) | (_x >> 8)); })

#define SMC_LEON_SWAP32(_x_)                    \
    ({ dword _x = (_x_);                        \
       ((_x << 24) |                            \
       ((0x0000FF00UL & _x) <<  8) |            \
       ((0x00FF0000UL & _x) >>  8) |            \
       (_x  >> 24)); })

#define SMC_inl(a,r)    (SMC_LEON_SWAP32((*(volatile dword *)((a)->iobase+((r)<<0)))))
#define SMC_inl_nosw(a,r)       ((*(volatile dword *)((a)->iobase+((r)<<0))))
#define SMC_inw(a,r)    (SMC_LEON_SWAP16((*(volatile word *)((a)->iobase+((r)<<0)))))
#define SMC_inw_nosw(a,r)       ((*(volatile word *)((a)->iobase+((r)<<0))))
#define SMC_inb(a,p)    ({ \
        word ___v = SMC_inw((a),(p) & ~1); \
        if ((p) & 1) ___v >>= 8; \
        else ___v &= 0xff; \
        ___v; })

#define SMC_outl(a,d,r) (*(volatile dword *)((a)->iobase+((r)<<0))=SMC_LEON_SWAP32(d))
#define SMC_outl_nosw(a,d,r)    (*(volatile dword *)((a)->iobase+((r)<<0))=(d))
#define SMC_outw(a,d,r) (*(volatile word *)((a)->iobase+((r)<<0))=SMC_LEON_SWAP16(d))
#define SMC_outw_nosw(a,d,r)    (*(volatile word *)((a)->iobase+((r)<<0))=(d))
#define SMC_outb(a,d,r) do{     word __d = (byte)(d);  \
                                word __w = SMC_inw((a),(r)&~1);  \
                                __w &= ((r)&1) ? 0x00FF : 0xFF00;  \
                                __w |= ((r)&1) ? __d<<8 : __d;  \
                                SMC_outw((a),__w,(r)&~1);  \
                        }while(0)
#define SMC_outsl(a,r,b,l)      do{     int __i; \
                                        dword *__b2; \
                                        __b2 = (dword *) b; \
                                        for (__i = 0; __i < l; __i++) { \
                                            SMC_outl_nosw((a), *(__b2 + __i), r); \
                                        } \
                                }while(0)
#define SMC_outsw(a,r,b,l)      do{     int __i; \
                                        word *__b2; \
                                        __b2 = (word *) b; \
                                        for (__i = 0; __i < l; __i++) { \
                                            SMC_outw_nosw((a), *(__b2 + __i), r); \
                                        } \
                                }while(0)
#define SMC_insl(a,r,b,l)       do{     int __i ;  \
                                        dword *__b2;  \
                                        __b2 = (dword *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inl_nosw((a),(r));  \
                                        };  \
                                }while(0)

#define SMC_insw(a,r,b,l)               do{     int __i ;  \
                                        word *__b2;  \
                                        __b2 = (word *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inw_nosw((a),(r));  \
                                        };  \
                                }while(0)

#define SMC_insb(a,r,b,l)               do{     int __i ;  \
                                        byte *__b2;  \
                                        __b2 = (byte *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inb((a),(r));  \
                                        };  \
                                }while(0)

#else                   /* if not CONFIG_CPU_PXA25X and not CONFIG_LEON */

#ifndef CONFIG_SMC_USE_IOFUNCS /* these macros don't work on some boards */
/*
 * We have only 16 Bit PCMCIA access on Socket 0
 */

#ifdef CONFIG_ADNPESC1
#define SMC_inw(a,r)    (*((volatile word *)((a)->iobase+((r)<<1))))
#elif CONFIG_BLACKFIN
#define SMC_inw(a,r)    ({ word __v = (*((volatile word *)((a)->iobase+(r)))); SSYNC(); __v;})
#elif CONFIG_ARM64
#define SMC_inw(a, r)   (*((volatile word*)((a)->iobase+((dword)(r)))))
#else
#define SMC_inw(a, r)   (*((volatile word*)((a)->iobase+(r))))
#endif
#define  SMC_inb(a,r)   (((r)&1) ? SMC_inw((a),(r)&~1)>>8 : SMC_inw((a),(r)&0xFF))

#ifdef CONFIG_ADNPESC1
#define SMC_outw(a,d,r) (*((volatile word *)((a)->iobase+((r)<<1))) = d)
#elif CONFIG_BLACKFIN
#define SMC_outw(a, d, r)       \
                        ({      (*((volatile word*)((a)->iobase+((r)))) = d); \
                                SSYNC(); \
                        })
#elif CONFIG_ARM64
#define SMC_outw(a, d, r)       \
                        (*((volatile word*)((a)->iobase+((dword)(r)))) = d)
#else
#define SMC_outw(a, d, r)       \
                        (*((volatile word*)((a)->iobase+(r))) = d)
#endif
#define SMC_outb(a,d,r) ({      word __d = (byte)(d);  \
                                word __w = SMC_inw((a),(r)&~1);  \
                                __w &= ((r)&1) ? 0x00FF : 0xFF00;  \
                                __w |= ((r)&1) ? __d<<8 : __d;  \
                                SMC_outw((a),__w,(r)&~1);  \
                        })
#if 0
#define SMC_outsw(a,r,b,l)      outsw((a)->iobase+(r), (b), (l))
#else
#define SMC_outsw(a,r,b,l)      ({      int __i; \
                                        word *__b2; \
                                        __b2 = (word *) b; \
                                        for (__i = 0; __i < l; __i++) { \
                                            SMC_outw((a), *(__b2 + __i), r); \
                                        } \
                                })
#endif

#if 0
#define SMC_insw(a,r,b,l)       insw((a)->iobase+(r), (b), (l))
#else
#define SMC_insw(a,r,b,l)       ({      int __i ;  \
                                        word *__b2;  \
                                        __b2 = (word *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inw((a),(r));  \
                                          SMC_inw((a),0);  \
                                        };  \
                                })
#endif

#endif  /* CONFIG_SMC_USE_IOFUNCS */

#if defined(CONFIG_SMC_USE_32_BIT)

#ifdef CONFIG_XSENGINE
#define SMC_inl(a,r)    (*((volatile dword *)((a)->iobase+(r<<1))))
#else
#define SMC_inl(a,r)    (*((volatile dword *)((a)->iobase+(r))))
#endif

#define SMC_insl(a,r,b,l)       ({      int __i ;  \
                                        dword *__b2;  \
                                        __b2 = (dword *) b;  \
                                        for (__i = 0; __i < l; __i++) {  \
                                          *(__b2 + __i) = SMC_inl((a),(r));  \
                                          SMC_inl((a),0);  \
                                        };  \
                                })

#ifdef CONFIG_XSENGINE
#define SMC_outl(a,d,r) (*((volatile dword *)((a)->iobase+(r<<1))) = d)
#else
#define SMC_outl(a,d,r) (*((volatile dword *)((a)->iobase+(r))) = d)
#endif
#define SMC_outsl(a,r,b,l)      ({      int __i; \
                                        dword *__b2; \
                                        __b2 = (dword *) b; \
                                        for (__i = 0; __i < l; __i++) { \
                                            SMC_outl((a), *(__b2 + __i), r); \
                                        } \
                                })

#endif /* CONFIG_SMC_USE_32_BIT */

#endif

/*---------------------------------------------------------------
 .
 . A description of the SMSC registers is probably in order here,
 . although for details, the SMC datasheet is invaluable.
 .
 . Basically, the chip has 4 banks of registers ( 0 to 3 ), which
 . are accessed by writing a number into the BANK_SELECT register
 . ( I also use a SMC_SELECT_BANK macro for this ).
 .
 . The banks are configured so that for most purposes, bank 2 is all
 . that is needed for simple run time tasks.
 -----------------------------------------------------------------------*/

/*
 . Bank Select Register:
 .
 .              yyyy yyyy 0000 00xx
 .              xx              = bank number
 .              yyyy yyyy       = 0x33, for identification purposes.
*/
#define BANK_SELECT             14

/* Transmit Control Register */
/* BANK 0  */
#define TCR_REG         0x0000  /* transmit control register */
#define TCR_ENABLE      0x0001  /* When 1 we can transmit */
#define TCR_LOOP        0x0002  /* Controls output pin LBK */
#define TCR_FORCOL      0x0004  /* When 1 will force a collision */
#define TCR_PAD_EN      0x0080  /* When 1 will pad tx frames < 64 bytes w/0 */
#define TCR_NOCRC       0x0100  /* When 1 will not append CRC to tx frames */
#define TCR_MON_CSN     0x0400  /* When 1 tx monitors carrier */
#define TCR_FDUPLX      0x0800  /* When 1 enables full duplex operation */
#define TCR_STP_SQET    0x1000  /* When 1 stops tx if Signal Quality Error */
#define TCR_EPH_LOOP    0x2000  /* When 1 enables EPH block loopback */
#define TCR_SWFDUP      0x8000  /* When 1 enables Switched Full Duplex mode */

#define TCR_CLEAR       0       /* do NOTHING */
/* the default settings for the TCR register : */
/* QUESTION: do I want to enable padding of short packets ? */
#define TCR_DEFAULT     TCR_ENABLE


/* EPH Status Register */
/* BANK 0  */
#define EPH_STATUS_REG  0x0002
#define ES_TX_SUC       0x0001  /* Last TX was successful */
#define ES_SNGL_COL     0x0002  /* Single collision detected for last tx */
#define ES_MUL_COL      0x0004  /* Multiple collisions detected for last tx */
#define ES_LTX_MULT     0x0008  /* Last tx was a multicast */
#define ES_16COL        0x0010  /* 16 Collisions Reached */
#define ES_SQET         0x0020  /* Signal Quality Error Test */
#define ES_LTXBRD       0x0040  /* Last tx was a broadcast */
#define ES_TXDEFR       0x0080  /* Transmit Deferred */
#define ES_LATCOL       0x0200  /* Late collision detected on last tx */
#define ES_LOSTCARR     0x0400  /* Lost Carrier Sense */
#define ES_EXC_DEF      0x0800  /* Excessive Deferral */
#define ES_CTR_ROL      0x1000  /* Counter Roll Over indication */
#define ES_LINK_OK      0x4000  /* Driven by inverted value of nLNK pin */
#define ES_TXUNRN       0x8000  /* Tx Underrun */


/* Receive Control Register */
/* BANK 0  */
#define RCR_REG         0x0004
#define RCR_RX_ABORT    0x0001  /* Set if a rx frame was aborted */
#define RCR_PRMS        0x0002  /* Enable promiscuous mode */
#define RCR_ALMUL       0x0004  /* When set accepts all multicast frames */
#define RCR_RXEN        0x0100  /* IFF this is set, we can receive packets */
#define RCR_STRIP_CRC   0x0200  /* When set strips CRC from rx packets */
#define RCR_ABORT_ENB   0x0200  /* When set will abort rx on collision */
#define RCR_FILT_CAR    0x0400  /* When set filters leading 12 bit s of carrier */
#define RCR_SOFTRST     0x8000  /* resets the chip */

/* the normal settings for the RCR register : */
#define RCR_DEFAULT     (RCR_STRIP_CRC | RCR_RXEN)
#define RCR_CLEAR       0x0     /* set it to a base state */

/* Counter Register */
/* BANK 0  */
#define COUNTER_REG     0x0006

/* Memory Information Register */
/* BANK 0  */
#define MIR_REG         0x0008

/* Receive/Phy Control Register */
/* BANK 0  */
#define RPC_REG         0x000A
#define RPC_SPEED       0x2000  /* When 1 PHY is in 100Mbps mode. */
#define RPC_DPLX        0x1000  /* When 1 PHY is in Full-Duplex Mode */
#define RPC_ANEG        0x0800  /* When 1 PHY is in Auto-Negotiate Mode */
#define RPC_LSXA_SHFT   5       /* Bits to shift LS2A,LS1A,LS0A to lsb */
#define RPC_LSXB_SHFT   2       /* Bits to get LS2B,LS1B,LS0B to lsb */
#define RPC_LED_100_10  (0x00)  /* LED = 100Mbps OR's with 10Mbps link detect */
#define RPC_LED_RES     (0x01)  /* LED = Reserved */
#define RPC_LED_10      (0x02)  /* LED = 10Mbps link detect */
#define RPC_LED_FD      (0x03)  /* LED = Full Duplex Mode */
#define RPC_LED_TX_RX   (0x04)  /* LED = TX or RX packet occurred */
#define RPC_LED_100     (0x05)  /* LED = 100Mbps link dectect */
#define RPC_LED_TX      (0x06)  /* LED = TX packet occurred */
#define RPC_LED_RX      (0x07)  /* LED = RX packet occurred */
#if defined(CONFIG_DK1C20) || defined(CONFIG_DK1S10)
/* buggy schematic: LEDa -> yellow, LEDb --> green */
#define RPC_DEFAULT     ( RPC_SPEED | RPC_DPLX | RPC_ANEG       \
                        | (RPC_LED_TX_RX << RPC_LSXA_SHFT)      \
                        | (RPC_LED_100_10 << RPC_LSXB_SHFT)     )
#elif defined(CONFIG_ADNPESC1)
/* SSV ADNP/ESC1 has only one LED: LEDa -> Rx/Tx indicator */
#define RPC_DEFAULT     ( RPC_SPEED | RPC_DPLX | RPC_ANEG       \
                        | (RPC_LED_TX_RX << RPC_LSXA_SHFT)      \
                        | (RPC_LED_100_10 << RPC_LSXB_SHFT)     )
#else
/* SMSC reference design: LEDa --> green, LEDb --> yellow */
#define RPC_DEFAULT     ( RPC_SPEED | RPC_DPLX | RPC_ANEG       \
                        | (RPC_LED_100_10 << RPC_LSXA_SHFT)     \
                        | (RPC_LED_TX_RX << RPC_LSXB_SHFT)      )
#endif

/* Bank 0 0x000C is reserved */

/* Bank Select Register */
/* All Banks */
#define BSR_REG 0x000E


/* Configuration Reg */
/* BANK 1 */
#define CONFIG_REG      0x0000
#define CONFIG_EXT_PHY  0x0200  /* 1=external MII, 0=internal Phy */
#define CONFIG_GPCNTRL  0x0400  /* Inverse value drives pin nCNTRL */
#define CONFIG_NO_WAIT  0x1000  /* When 1 no extra wait states on ISA bus */
#define CONFIG_EPH_POWER_EN 0x8000 /* When 0 EPH is placed into low power mode. */

/* Default is powered-up, Internal Phy, Wait States, and pin nCNTRL=low */
#define CONFIG_DEFAULT  (CONFIG_EPH_POWER_EN)


/* Base Address Register */
/* BANK 1 */
#define BASE_REG        0x0002


/* Individual Address Registers */
/* BANK 1 */
#define ADDR0_REG       0x0004
#define ADDR1_REG       0x0006
#define ADDR2_REG       0x0008


/* General Purpose Register */
/* BANK 1 */
#define GP_REG          0x000A


/* Control Register */
/* BANK 1 */
#define CTL_REG         0x000C
#define CTL_RCV_BAD     0x4000 /* When 1 bad CRC packets are received */
#define CTL_AUTO_RELEASE 0x0800 /* When 1 tx pages are released automatically */
#define CTL_LE_ENABLE   0x0080 /* When 1 enables Link Error interrupt */
#define CTL_CR_ENABLE   0x0040 /* When 1 enables Counter Rollover interrupt */
#define CTL_TE_ENABLE   0x0020 /* When 1 enables Transmit Error interrupt */
#define CTL_EEPROM_SELECT 0x0004 /* Controls EEPROM reload & store */
#define CTL_RELOAD      0x0002 /* When set reads EEPROM into registers */
#define CTL_STORE       0x0001 /* When set stores registers into EEPROM */
#define CTL_DEFAULT     (0x1A10) /* Autorelease enabled*/

/* MMU Command Register */
/* BANK 2 */
#define MMU_CMD_REG     0x0000
#define MC_BUSY         1       /* When 1 the last release has not completed */
#define MC_NOP          (0<<5)  /* No Op */
#define MC_ALLOC        (1<<5)  /* OR with number of 256 byte packets */
#define MC_RESET        (2<<5)  /* Reset MMU to initial state */
#define MC_REMOVE       (3<<5)  /* Remove the current rx packet */
#define MC_RELEASE      (4<<5)  /* Remove and release the current rx packet */
#define MC_FREEPKT      (5<<5)  /* Release packet in PNR register */
#define MC_ENQUEUE      (6<<5)  /* Enqueue the packet for transmit */
#define MC_RSTTXFIFO    (7<<5)  /* Reset the TX FIFOs */


/* Packet Number Register */
/* BANK 2 */
#define PN_REG          0x0002


/* Allocation Result Register */
/* BANK 2 */
#define AR_REG          0x0003
#define AR_FAILED       0x80    /* Alocation Failed */


/* RX FIFO Ports Register */
/* BANK 2 */
#define RXFIFO_REG      0x0004  /* Must be read as a word */
#define RXFIFO_REMPTY   0x8000  /* RX FIFO Empty */


/* TX FIFO Ports Register */
/* BANK 2 */
#define TXFIFO_REG      RXFIFO_REG      /* Must be read as a word */
#define TXFIFO_TEMPTY   0x80    /* TX FIFO Empty */


/* Pointer Register */
/* BANK 2 */
#define PTR_REG         0x0006
#define PTR_RCV         0x8000 /* 1=Receive area, 0=Transmit area */
#define PTR_AUTOINC     0x4000 /* Auto increment the pointer on each access */
#define PTR_READ        0x2000 /* When 1 the operation is a read */
#define PTR_NOTEMPTY    0x0800 /* When 1 _do not_ write fifo DATA REG */


/* Data Register */
/* BANK 2 */
#define SMC91111_DATA_REG       0x0008


/* Interrupt Status/Acknowledge Register */
/* BANK 2 */
#define SMC91111_INT_REG        0x000C


/* Interrupt Mask Register */
/* BANK 2 */
#define IM_REG          0x000D
#define IM_MDINT        0x80 /* PHY MI Register 18 Interrupt */
#define IM_ERCV_INT     0x40 /* Early Receive Interrupt */
#define IM_EPH_INT      0x20 /* Set by Etheret Protocol Handler section */
#define IM_RX_OVRN_INT  0x10 /* Set by Receiver Overruns */
#define IM_ALLOC_INT    0x08 /* Set when allocation request is completed */
#define IM_TX_EMPTY_INT 0x04 /* Set if the TX FIFO goes empty */
#define IM_TX_INT       0x02 /* Transmit Interrrupt */
#define IM_RCV_INT      0x01 /* Receive Interrupt */


/* Multicast Table Registers */
/* BANK 3 */
#define MCAST_REG1      0x0000
#define MCAST_REG2      0x0002
#define MCAST_REG3      0x0004
#define MCAST_REG4      0x0006


/* Management Interface Register (MII) */
/* BANK 3 */
#define MII_REG         0x0008
#define MII_MSK_CRS100  0x4000 /* Disables CRS100 detection during tx half dup */
#define MII_MDOE        0x0008 /* MII Output Enable */
#define MII_MCLK        0x0004 /* MII Clock, pin MDCLK */
#define MII_MDI         0x0002 /* MII Input, pin MDI */
#define MII_MDO         0x0001 /* MII Output, pin MDO */


/* Revision Register */
/* BANK 3 */
#define REV_REG         0x000A /* ( hi: chip id   low: rev # ) */


/* Early RCV Register */
/* BANK 3 */
/* this is NOT on SMC9192 */
#define ERCV_REG        0x000C
#define ERCV_RCV_DISCRD 0x0080 /* When 1 discards a packet being received */
#define ERCV_THRESHOLD  0x001F /* ERCV Threshold Mask */

/* External Register */
/* BANK 7 */
#define EXT_REG         0x0000


#define CHIP_9192       3
#define CHIP_9194       4
#define CHIP_9195       5
#define CHIP_9196       6
#define CHIP_91100      7
#define CHIP_91100FD    8
#define CHIP_91111FD    9

#if 0
static const char * chip_ids[ 15 ] =  {
        NULL, NULL, NULL,
        /* 3 */ "SMC91C90/91C92",
        /* 4 */ "SMC91C94",
        /* 5 */ "SMC91C95",
        /* 6 */ "SMC91C96",
        /* 7 */ "SMC91C100",
        /* 8 */ "SMC91C100FD",
        /* 9 */ "SMC91C111",
        NULL, NULL,
        NULL, NULL, NULL};
#endif

/*
 . Transmit status bits
*/
#define TS_SUCCESS 0x0001
#define TS_LOSTCAR 0x0400
#define TS_LATCOL  0x0200
#define TS_16COL   0x0010

/*
 . Receive status bits
*/
#define RS_ALGNERR      0x8000
#define RS_BRODCAST     0x4000
#define RS_BADCRC       0x2000
#define RS_ODDFRAME     0x1000  /* bug: the LAN91C111 never sets this on receive */
#define RS_TOOLONG      0x0800
#define RS_TOOSHORT     0x0400
#define RS_MULTICAST    0x0001
#define RS_ERRORS       (RS_ALGNERR | RS_BADCRC | RS_TOOLONG | RS_TOOSHORT)


/* PHY Types */
enum {
        PHY_LAN83C183 = 1,      /* LAN91C111 Internal PHY */
        PHY_LAN83C180
};


/* PHY Register Addresses (LAN91C111 Internal PHY) */

/* PHY Control Register */
#define PHY_CNTL_REG            0x00
#define PHY_CNTL_RST            0x8000  /* 1=PHY Reset */
#define PHY_CNTL_LPBK           0x4000  /* 1=PHY Loopback */
#define PHY_CNTL_SPEED          0x2000  /* 1=100Mbps, 0=10Mpbs */
#define PHY_CNTL_ANEG_EN        0x1000 /* 1=Enable Auto negotiation */
#define PHY_CNTL_PDN            0x0800  /* 1=PHY Power Down mode */
#define PHY_CNTL_MII_DIS        0x0400  /* 1=MII 4 bit interface disabled */
#define PHY_CNTL_ANEG_RST       0x0200 /* 1=Reset Auto negotiate */
#define PHY_CNTL_DPLX           0x0100  /* 1=Full Duplex, 0=Half Duplex */
#define PHY_CNTL_COLTST         0x0080  /* 1= MII Colision Test */

/* PHY Status Register */
#define PHY_STAT_REG            0x01
#define PHY_STAT_CAP_T4         0x8000  /* 1=100Base-T4 capable */
#define PHY_STAT_CAP_TXF        0x4000  /* 1=100Base-X full duplex capable */
#define PHY_STAT_CAP_TXH        0x2000  /* 1=100Base-X half duplex capable */
#define PHY_STAT_CAP_TF         0x1000  /* 1=10Mbps full duplex capable */
#define PHY_STAT_CAP_TH         0x0800  /* 1=10Mbps half duplex capable */
#define PHY_STAT_CAP_SUPR       0x0040  /* 1=recv mgmt frames with not preamble */
#define PHY_STAT_ANEG_ACK       0x0020  /* 1=ANEG has completed */
#define PHY_STAT_REM_FLT        0x0010  /* 1=Remote Fault detected */
#define PHY_STAT_CAP_ANEG       0x0008  /* 1=Auto negotiate capable */
#define PHY_STAT_LINK           0x0004  /* 1=valid link */
#define PHY_STAT_JAB            0x0002  /* 1=10Mbps jabber condition */
#define PHY_STAT_EXREG          0x0001  /* 1=extended registers implemented */

/* PHY Identifier Registers */
#define PHY_ID1_REG             0x02    /* PHY Identifier 1 */
#define PHY_ID2_REG             0x03    /* PHY Identifier 2 */

/* PHY Auto-Negotiation Advertisement Register */
#define PHY_AD_REG              0x04
#define PHY_AD_NP               0x8000  /* 1=PHY requests exchange of Next Page */
#define PHY_AD_ACK              0x4000  /* 1=got link code word from remote */
#define PHY_AD_RF               0x2000  /* 1=advertise remote fault */
#define PHY_AD_T4               0x0200  /* 1=PHY is capable of 100Base-T4 */
#define PHY_AD_TX_FDX           0x0100  /* 1=PHY is capable of 100Base-TX FDPLX */
#define PHY_AD_TX_HDX           0x0080  /* 1=PHY is capable of 100Base-TX HDPLX */
#define PHY_AD_10_FDX           0x0040  /* 1=PHY is capable of 10Base-T FDPLX */
#define PHY_AD_10_HDX           0x0020  /* 1=PHY is capable of 10Base-T HDPLX */
#define PHY_AD_CSMA             0x0001  /* 1=PHY is capable of 802.3 CMSA */

/* PHY Auto-negotiation Remote End Capability Register */
#define PHY_RMT_REG             0x05
/* Uses same bit definitions as PHY_AD_REG */

/* PHY Configuration Register 1 */
#define PHY_CFG1_REG            0x10
#define PHY_CFG1_LNKDIS         0x8000  /* 1=Rx Link Detect Function disabled */
#define PHY_CFG1_XMTDIS         0x4000  /* 1=TP Transmitter Disabled */
#define PHY_CFG1_XMTPDN         0x2000  /* 1=TP Transmitter Powered Down */
#define PHY_CFG1_BYPSCR         0x0400  /* 1=Bypass scrambler/descrambler */
#define PHY_CFG1_UNSCDS         0x0200  /* 1=Unscramble Idle Reception Disable */
#define PHY_CFG1_EQLZR          0x0100  /* 1=Rx Equalizer Disabled */
#define PHY_CFG1_CABLE          0x0080  /* 1=STP(150ohm), 0=UTP(100ohm) */
#define PHY_CFG1_RLVL0          0x0040  /* 1=Rx Squelch level reduced by 4.5db */
#define PHY_CFG1_TLVL_SHIFT     2       /* Transmit Output Level Adjust */
#define PHY_CFG1_TLVL_MASK      0x003C
#define PHY_CFG1_TRF_MASK       0x0003  /* Transmitter Rise/Fall time */


/* PHY Configuration Register 2 */
#define PHY_CFG2_REG            0x11
#define PHY_CFG2_APOLDIS        0x0020  /* 1=Auto Polarity Correction disabled */
#define PHY_CFG2_JABDIS         0x0010  /* 1=Jabber disabled */
#define PHY_CFG2_MREG           0x0008  /* 1=Multiple register access (MII mgt) */
#define PHY_CFG2_INTMDIO        0x0004  /* 1=Interrupt signaled with MDIO pulseo */

/* PHY Status Output (and Interrupt status) Register */
#define PHY_INT_REG             0x12    /* Status Output (Interrupt Status) */
#define PHY_INT_INT             0x8000  /* 1=bits have changed since last read */
#define PHY_INT_LNKFAIL         0x4000  /* 1=Link Not detected */
#define PHY_INT_LOSSSYNC        0x2000  /* 1=Descrambler has lost sync */
#define PHY_INT_CWRD            0x1000  /* 1=Invalid 4B5B code detected on rx */
#define PHY_INT_SSD             0x0800  /* 1=No Start Of Stream detected on rx */
#define PHY_INT_ESD             0x0400  /* 1=No End Of Stream detected on rx */
#define PHY_INT_RPOL            0x0200  /* 1=Reverse Polarity detected */
#define PHY_INT_JAB             0x0100  /* 1=Jabber detected */
#define PHY_INT_SPDDET          0x0080  /* 1=100Base-TX mode, 0=10Base-T mode */
#define PHY_INT_DPLXDET         0x0040  /* 1=Device in Full Duplex */

/* PHY Interrupt/Status Mask Register */
#define PHY_MASK_REG            0x13    /* Interrupt Mask */
/* Uses the same bit definitions as PHY_INT_REG */


/*-------------------------------------------------------------------------
 .  I define some macros to make it easier to do somewhat common
 . or slightly complicated, repeated tasks.
 --------------------------------------------------------------------------*/

/* select a register bank, 0 to 3  */

#define SMC_SELECT_BANK(a,x)  { SMC_outw((a), (x), BANK_SELECT ); }

/* this enables an interrupt in the interrupt mask register */
#define SMC_ENABLE_INT(a,x) {\
                unsigned char mask;\
                SMC_SELECT_BANK((a),2);\
                mask = SMC_inb((a), IM_REG );\
                mask |= (x);\
                SMC_outb( (a), mask, IM_REG ); \
}

/* this disables an interrupt from the interrupt mask register */

#define SMC_DISABLE_INT(a,x) {\
                unsigned char mask;\
                SMC_SELECT_BANK(2);\
                mask = SMC_inb( (a), IM_REG );\
                mask &= ~(x);\
                SMC_outb( (a), mask, IM_REG ); \
}

/*----------------------------------------------------------------------
 . Define the interrupts that I want to receive from the card
 .
 . I want:
 .  IM_EPH_INT, for nasty errors
 .  IM_RCV_INT, for happy received packets
 .  IM_RX_OVRN_INT, because I have to kick the receiver
 .  IM_MDINT, for PHY Register 18 Status Changes
 --------------------------------------------------------------------------*/
#define SMC_INTERRUPT_MASK   (IM_EPH_INT | IM_RX_OVRN_INT | IM_RCV_INT | \
        IM_MDINT)

#endif  /* _SMC_91111_H_ */