sun3/dev/if_ievar.h

1.8  gwr /*	$NetBSD: if_ievar.h,v 1.8 1997/02/13 20:43:18 gwr Exp $	*/
1.1  gwr
1.1  gwr /*
1.1  gwr  * Machine-dependent glue for the Intel Ethernet (ie) driver.
1.1  gwr  */
1.1  gwr
1.8  gwr #define	MXFRAMES	128	/* max number of frames to allow for receive */
1.8  gwr #define	MXRXBUF 	192	/* max number of buffers to allocate */
1.1  gwr #define	IE_RBUF_SIZE	256	/* size of each buffer, MUST BE POWER OF TWO */
1.1  gwr #define	NTXBUF		2	/* number of transmit buffer/command pairs */
1.6  gwr #define	IE_TBUF_SIZE	(3*512)	/* length of transmit buffer */
1.1  gwr
1.1  gwr enum ie_hardware {
1.1  gwr 	IE_VME,			/* multibus to VME ie card */
1.1  gwr 	IE_OBIO,		/* on board */
1.1  gwr 	IE_VME3E,		/* sun 3e VME card */
1.1  gwr 	IE_UNKNOWN
1.1  gwr };
1.1  gwr
1.1  gwr /*
1.1  gwr  * Ethernet status, per interface.
1.1  gwr  *
1.1  gwr  * hardware addresses/sizes to know (all KVA):
1.1  gwr  *   sc_iobase = base of chip's 24 bit address space
1.1  gwr  *   sc_maddr  = base address of chip RAM as stored in ie_base of iscp
1.1  gwr  *   sc_msize  = size of chip's RAM
1.1  gwr  *   sc_reg    = address of card dependent registers
1.1  gwr  *
1.1  gwr  * the chip uses two types of pointers: 16 bit and 24 bit
1.1  gwr  *   16 bit pointers are offsets from sc_maddr/ie_base
1.1  gwr  *      KVA(16 bit offset) = offset + sc_maddr
1.1  gwr  *   24 bit pointers are offset from sc_iobase in KVA
1.1  gwr  *      KVA(24 bit address) = address + sc_iobase
1.1  gwr  *
1.1  gwr  * on the vme/multibus we have the page map to control where ram appears
1.1  gwr  * in the address space.   we choose to have RAM start at 0 in the
1.1  gwr  * 24 bit address space.   this means that sc_iobase == sc_maddr!
1.1  gwr  * to get the phyiscal address of the board's RAM you must take the
1.1  gwr  * top 12 bits of the physical address of the register address
1.1  gwr  * and or in the 4 bits from the status word as bits 17-20 (remember that
1.1  gwr  * the board ignores the chip's top 4 address lines).
1.1  gwr  * For example:
1.1  gwr  *   if the register is @ 0xffe88000, then the top 12 bits are 0xffe00000.
1.1  gwr  *   to get the 4 bits from the the status word just do status & IEVME_HADDR.
1.1  gwr  *   suppose the value is "4".   Then just shift it left 16 bits to get
1.1  gwr  *   it into bits 17-20 (e.g. 0x40000).    Then or it to get the
1.1  gwr  *   address of RAM (in our example: 0xffe40000).   see the attach routine!
1.1  gwr  *
1.4  gwr  * In the onboard ie interface, the 24 bit address space is hardwired
1.1  gwr  * to be 0xff000000 -> 0xffffffff of KVA.   this means that sc_iobase
1.1  gwr  * will be 0xff000000.   sc_maddr will be where ever we allocate RAM
1.1  gwr  * in KVA.    note that since the SCP is at a fixed address it means
1.4  gwr  * that we have to use some memory at a fixed KVA for the SCP.
1.4  gwr  * The Sun PROM leaves a page for us at the end of KVA space.
1.1  gwr  */
1.1  gwr struct ie_softc {
1.1  gwr 	struct device sc_dev;	/* device structure */
1.1  gwr
1.1  gwr 	struct arpcom sc_arpcom;/* system arpcom structure */
1.1  gwr #define	sc_if	sc_arpcom.ac_if 		/* network-visible interface */
1.1  gwr #define	sc_addr	sc_arpcom.ac_enaddr		/* hardware Ethernet address */
1.1  gwr
1.8  gwr 	int     sc_debug;	/* See IEDEBUG */
1.7  gwr
1.7  gwr 	/* card dependent functions: */
1.7  gwr 	void    (*reset_586) __P((struct ie_softc *));
1.7  gwr 	void    (*chan_attn) __P((struct ie_softc *));
1.7  gwr 	void    (*run_586)   __P((struct ie_softc *));
1.4  gwr 	void (*sc_bcopy) __P((const void *, void *, u_int));
1.4  gwr 	void (*sc_bzero) __P((void *, u_int));
1.1  gwr
1.8  gwr 	caddr_t sc_iobase;	/* KVA of base of 24bit addr space */
1.8  gwr 	caddr_t sc_maddr;	/* KVA of base of chip's RAM */
1.8  gwr 	u_int   sc_msize;	/* how much RAM we have/use */
1.8  gwr 	caddr_t sc_reg;		/* KVA of card's register */
1.8  gwr
1.8  gwr 	enum ie_hardware hard_type;	/* card type */
1.8  gwr
1.1  gwr 	int     want_mcsetup;	/* flag for multicast setup */
1.1  gwr 	int     promisc;	/* are we in promisc mode? */
1.1  gwr
1.8  gwr 	int ntxbuf;       /* number of tx frames/buffers */
1.8  gwr 	int nframes;      /* number of recv frames in use */
1.8  gwr 	int nrxbuf;       /* number of recv buffs in use */
1.8  gwr
1.1  gwr 	/*
1.1  gwr 	 * pointers to the 3 major control structures
1.1  gwr 	 */
1.1  gwr 	volatile struct ie_sys_conf_ptr *scp;
1.1  gwr 	volatile struct ie_int_sys_conf_ptr *iscp;
1.1  gwr 	volatile struct ie_sys_ctl_block *scb;
1.1  gwr
1.1  gwr 	/*
1.1  gwr 	 * pointer and size of a block of KVA where the buffers
1.1  gwr 	 * are to be allocated from
1.1  gwr 	 */
1.8  gwr 	char * buf_area;
1.1  gwr 	int     buf_area_sz;
1.1  gwr
1.1  gwr 	/*
1.8  gwr 	 * Transmit commands, descriptors, and buffers
1.4  gwr 	 */
1.1  gwr 	volatile struct ie_xmit_cmd *xmit_cmds[NTXBUF];
1.1  gwr 	volatile struct ie_xmit_buf *xmit_buffs[NTXBUF];
1.8  gwr 	char *xmit_cbuffs[NTXBUF];
1.4  gwr 	int xmit_busy;
1.4  gwr 	int xmit_free;
1.4  gwr 	int xchead, xctail;
1.1  gwr
1.8  gwr 	/*
1.8  gwr 	 * Receive frames, descriptors, and buffers
1.8  gwr 	 */
1.8  gwr 	volatile struct ie_recv_frame_desc *rframes[MXFRAMES];
1.8  gwr 	volatile struct ie_recv_buf_desc *rbuffs[MXRXBUF];
1.8  gwr 	char *cbuffs[MXRXBUF];
1.8  gwr 	int     rfhead, rftail, rbhead, rbtail;
1.8  gwr
1.8  gwr 	/* Multi-cast stuff */
1.8  gwr 	int     mcast_count;
1.1  gwr 	struct ie_en_addr mcast_addrs[MAXMCAST + 1];
1.1  gwr };
1.1  gwr
1.1  gwr
1.6  gwr extern void    ie_attach __P((struct ie_softc *));
1.6  gwr extern int  ie_intr __P((void *));